User's Manual, Model 348 Moore FieldPAC® Field Mounted Controller (UM348-1, Rev. 4; October 2000) PDF 2.0

Siemens Moore
Process Automation, Inc.
USER'S MANUAL
UM348-1
Rev: 4
October 2000
D
PB1
PB2
AUTO
MAN
ENTER
EXIT
CONF
TUNE
TAG
STORE
ACK
STEP
UP
ALARM
STEP
DOWN
FIELDPAC
Moore 348 FIELDPAC™
FIELD MOUNTED CONTROLLER
UM348-1
CONTENTS
TABLE OF CONTENTS
SECTION
TITLE
1.0
1.1
1.2
1.3
1.3.1
1.3.2
1.3.2.1
1.3.2.2
1.3.3
1.3.4
1.3.5
1.3.5.1
1.3.5.2
1.3.5.3
1.3.6
1.4
1.5
INTRODUCTION .............................................................................................................. 1-1
PRODUCT DESCRIPTION .......................................................................................... 1-1
MODEL DESIGNATION .............................................................................................. 1-2
SPECIFICATIONS ........................................................................................................ 1-2
Mechanical .............................................................................................................. 1-2
Electrical ................................................................................................................. 1-6
Power Requirements .......................................................................................... 1-6
2-Wire Transmitter Supply Power ...................................................................... 1-6
Input/Output Ports ................................................................................................... 1-6
Environmental ........................................................................................................ 1-10
Hazardous Area Classification ............................................................................... 1-11
FM/CSA Hazardous Location Precautions ....................................................... 1-11
CM (EMC) Compliant Considerations ............................................................. 1-12
BASEEFA Ex N IIC T5 Considerations............................................................. 1-13
Two-Wire Cable for HART® Communication ......................................................... 1-13
ACCESSORIES .......................................................................................................... 1-15
PRODUCT SUPPORT ................................................................................................ 1-16
2.0
2.1
2.2
2.3
2.3.1
2.3.2
2.3.3
2.4
2.4.1
2.4.2
2.4.3
2.4.3.1
2.4.3.2
2.5
2.5.1
2.5.2
2.5.3
2.6
2.7
INSTALLATION ............................................................................................................... 2-1
INSTALLATION CONSIDERATIONS ........................................................................ 2-1
ENVIRONMENTAL CONSIDERATIONS ................................................................... 2-1
MECHANICAL INSTALLATION ................................................................................ 2-5
Panel Mounting ........................................................................................................ 2-5
Pipe Mounting ......................................................................................................... 2-6
Wall Mounting ......................................................................................................... 2-6
ELECTRICAL INSTALLATION .................................................................................. 2-7
Conduit Installation .................................................................................................. 2-7
Wiring Guidelines .................................................................................................... 2-8
Terminal Connections .............................................................................................. 2-9
Power Connections .......................................................................................... 2-11
Signal Inputs And Outputs ............................................................................... 2-12
PNEUMATIC CONNECTIONS .................................................................................. 2-17
Pneumatic Inputs ................................................................................................... 2-17
Pneumatic Output .................................................................................................. 2-17
Direct Pressure Input ............................................................................................... 2.17
FACTORY CALIBRATION ....................................................................................... 2-20
CONFIGURATION ..................................................................................................... 2-21
3.0
3.1
3.1.1
3.1.1.1
OPERATION .....................................................................................................................
FACEPLATE .................................................................................................................
Liquid Crystal Display Panel ....................................................................................
Multifunction Alphanumeric Display ..................................................................
October 1998
PAGE
3-1
3-1
3-1
3-1
i
CONTENTS
UM348-1
TABLE OF CONTENTS
(Continued)
SECTION
3.1.1.2
3.1.1.3
3.1.1.4
3.1.1.5
3.1.2
3.1.2.1
3.1.2.2
3.1.2.3
3.1.2.4
3.1.2.5
3.1.2.6
3.1.3
3.1.3.1
3.1.3.2
3.1.3.3
3.1.3.4
3.1.3.5
3.2
3.3
3.4
3.5
4.0
4.1
4.2
4.3
4.4
4.5
4.6
4.6.1
4.6.2
4.7
4.7.1
4.7.2
4.7.3
4.7.4
4.7.5
4.8
4.9
ii
TITLE
PAGE
Setpoint And Process Vertical Bargraphs ...........................................................
Valve or Output Horizontal Bargraph ................................................................
PB1 And PB2 Triangle Indicators ......................................................................
AUTO/MAN Triangle Indicators .......................................................................
Control Pushbuttons ................................................................................................
PB1 ................................................................................................................. .
PB2 ..................................................................................................................
AUTO/MAN .....................................................................................................
D ......................................................................................................................
UP Arrow .........................................................................................................
DOWN Arrow ..................................................................................................
Dual Function Pushbuttons ......................................................................................
ENTER/EXIT CONF ........................................................................................
TUNE/---> ........................................................................................................
TAG/STORE ....................................................................................................
ACK/STEP UP .................................................................................................
ALARM/STEP DOWN ....................................................................................
OPERATING MODES .................................................................................................
DISPLAY TEST ...........................................................................................................
PUSHBUTTON CARE .................................................................................................
CONTRAST ADJUSTMENT .......................................................................................
3-2
3-2
3-2
3-2
3-3
3-3
3-4
3-4
3-4
3-4
3-4
3-5
3-5
3-5
3-5
3-6
3-6
3-6
3-6
3-7
3-7
CALIBRATION ................................................................................................................ 4-1
GENERAL CONSIDERATIONS .................................................................................. 4-1
REQUIRED EQUIPMENT ........................................................................................... 4-2
LOCKOUT SWITCHES ............................................................................................... 4-3
ESN ASSIGNMENT ..................................................................................................... 4-3
ANALOG INPUTS AND OUTPUTS ............................................................................ 4-4
PRESSURE SENSOR INPUT ....................................................................................... 4-8
Mounting Position Zero Shift Calibration ................................................................. 4-8
Calibration Verification ........................................................................................... 4-9
TEMPERATURE SENSOR INPUT ............................................................................ 4-10
Selecting Input Type .............................................................................................. 4-11
Specifying Measured Variable Units ...................................................................... 4-12
Millivolt Input Calibration ..................................................................................... 4-14
Thermocouple Input Calibration .............................................................................. 4-17
RTD Input Calibration ............................................................................................ 4-20
PNEUMATIC INPUT ................................................................................................. 4-24
I/P MODULE CALIBRATION ................................................................................... 4-26
October 1998
UM348-1
CONTENTS
TABLE OF CONTENTS
(Continued)
SECTION
TITLE
5.0
5.1
5.2
5.3
5.3.1
5.3.2
5.4
5.5
5.6
5.7
5.8
CIRCUIT DESCRIPTION ................................................................................................ 5-1
MPU CONTROLLER BOARD ..................................................................................... 5-3
PLUG-IN AC POWER SUPPLY ................................................................................... 5-6
DISPLAY/KEYBOARD ASSEMBLY ........................................................................... 5-6
Display/Interface Board ........................................................................................... 5-6
Keyboard ................................................................................................................. 5-7
TEMPERATURE SENSOR BOARD ............................................................................ 5-7
PNEUMATIC INPUT BOARD ..................................................................................... 5-8
I/P MODULE ................................................................................................................ 5-9
PRESSURE SENSOR ................................................................................................... 5-9
HART SIGNAL PORT ................................................................................................ 5-10
6.0
6.1
6.2
6.2.1
6.2.2
6.2.3
6.2.4
6.3
6.4
6.4.1
6.5
6.5.1
6.5.2
6.5.3
6.5.4
6.5.5
6.5.6
6.5.7
6.5.8
6.6
6.7
6.8
MAINTENANCE ............................................................................................................... 6-1
TOOL AND EQUIPMENT REQUIREMENTS ............................................................. 6-1
PREVENTIVE MAINTENANCE .................................................................................. 6-1
Environmental Considerations .................................................................................. 6-1
Visual Inspection ..................................................................................................... 6-1
Cleaning .................................................................................................................. 6-2
Circuit Board Handling ............................................................................................ 6-2
FUSE LOCATION ........................................................................................................ 6-2
TROUBLESHOOTING ................................................................................................. 6-2
Error Codes ............................................................................................................. 6-3
ASSEMBLY REPLACEMENT ..................................................................................... 6-5
Upper Door Assembly .............................................................................................. 6-7
Terminal Compartment Cover ................................................................................ 6-10
AC Power Supply .................................................................................................. 6-11
Temperature Sensor Board ..................................................................................... 6-12
Pneumatic Input Board ........................................................................................... 6-14
Pneumatic Output Board .......................................................................................... 6-16
Direct Pressure Sensor Input .................................................................................. 6-17
MPU Controller Board ........................................................................................... 6-18
RECOMMENDED SPARE AND REPLACEMENT PARTS ...................................... 6-21
MAINTENANCE RECORDS ..................................................................................... 6-21
TO RETURN EQUIPMENT ....................................................................................... 6-21
7.0
7.1
CONFIGURATION ........................................................................................................... 7-1
CONFIGURATION MODES ........................................................................................ 7-1
8.0
FUNCTION BLOCK DESCRIPTIONS ........................................................................... 8-1
October 1998
PAGE
iii
CONTENTS
UM348-1
TABLE OF CONTENTS
(Continued)
SECTION
TITLE
9.0
9.1
9.2
9.3
9.4
9.5
9.6
9.7
9.8
9.9
9.10
9.11
9.12
9.13
9.14
9.15
9.16
CONFIGURATION .......................................................................................................... 9-1
FCO 00 ESN Reset (ESN=00)......................................................................................... 9-2
FCO 01 Single-Loop PID Controller (TSP)...................................................................... 9-2
FCO 02 Single-Loop PID Controller (NTSP) ................................................................... 9-6
FCO 03 External-Set PID Controller (TSP) ................................................................... 9-10
FCO 04 External-Set PID Controller (NTSP)................................................................. 9-14
FCO 05 Ratio-Set PID Controller .................................................................................. 9-18
FCO 10 Default Configuration ..................................................................................... 9-22
FCO 11 Single-Loop PID Controller (TSP) - C/L Operation .......................................... 9-32
FCO 12 Single-Loop PID Controller (NTSP) - C/L Operation........................................ 9-36
FCO 13 External-Set PID Controller (TSP) - C/L Operation .......................................... 9-40
FCO 14 External-Set PID Controller (NTSP) - C/L Operation ....................................... 9-44
FCO 15 Ratio-Set PID Controller - C/L Operation ......................................................... 9-48
FCO 20 Single Station Cascade Controller (TSP)........................................................... 9-53
FCO 25 Dual-Loop PID Controllers (TSP) .................................................................... 9-58
FCO 26 Dual-Loop PID Controllers (NTSP).................................................................. 9-64
FCO 31 Single-Loop PID Controllers (TSP) with Pressure Input.................................... 9-70
A.0
B.0
C.0
APPENDIX A - FIELDPAC FUNCTION BLOCKS ...................................................... A-1
APPENDIX B - MODEL 348 CONFIGURATION DOCUMENTATION ..................... B-1
APPENDIX C - CABLE CAPACITANCE AND MAXIMUM LENGTH ...................... C-1
PAGE
WARRANTY ............................................................................................................................................. W-1
Parts List ............................................................................................................................................. 348-1PL
LIST OF ILLUSTRATIONS
PAGE
FIGURE
TITLE
1-1
1-2
Model 348 Field Mounted Controller (FIELDPAC) .............................................................. 1-3
Model 348 Dimensions, Process Pressure Input Models .......................................................... 1-4
2-1
2-2
2-3
2-4
2-5
Pipe Mounting Details............................................................................................................ 2-2
Panel Mounting Dimensions ................................................................................................... 2-3
Typical Wall Mounting ........................................................................................................ 2-4
Conductor Connection to Terminal Block ............................................................................. 2-9
Electrical Connections ........................................................................................................ 2-10
iv
October 1998
UM348-1
CONTENTS
TABLE OF CONTENTS
(Continued)
SECTION
TITLE
2-6
2-7
2-8
2-9
2-10
2-11
2-12
2-13
Model 348 Terminals ..........................................................................................................
Digital Output to Typical Loads .........................................................................................
RTD Wiring Connections ...................................................................................................
Model 340D Differential Pressure Sensor..............................................................................
Model 340A and Model 340G Pressure Sensors ....................................................................
Differential Flow Measurement Piping for Gas and Liquid ....................................................
Absolute or Gauge Pressure Measurement ............................................................................
Steam Service, Below the Line Mounting ..............................................................................
3-1
3-2
Operator Controls and Signal Displays ................................................................................. 3-3
Display Contrast Adjustment ................................................................................................ 3-7
4-1
4-2
Thermocouple and Millivolt Input Calibration Wiring ......................................................... 4-15
I/P Module ......................................................................................................................... 4-29
5-1
5-2
5-3
5-4
5-5
5-6
Model 348 Hardware Architecture ........................................................................................ 5-2
MPU Controller Board Inputs and Outputs ........................................................................... 5-4
MPU Controller Board Physical Layout ................................................................................ 5-5
Temperature Sensor Board Block Diagram ........................................................................... 5-8
Pneumatic Input Board ......................................................................................................... 5-9
Transducer Module Circuit Diagram ................................................................................... 5-11
6-1
6-2
6-3
6-4
6-5
6-6
6-7
6-8
6-9
Upper Door and Terminal Compartment Cover ..................................................................... 6-7
Upper Door Assembly .......................................................................................................... 6-8
Rear View of Hinge Assembly .............................................................................................. 6-9
Power Supply Removal/Installation ..................................................................................... 6-12
Temperature Sensor Board Removal/Installation .................................................................. 6-13
Pneumatic Input Board ....................................................................................................... 6-15
Pneumatic Output Board....................................................................................................... 6-16
Direct Pressure Sensor Input ............................................................................................... 6-18
MPU Controller Board ....................................................................................................... 6-20
PAGE
2-13
2-15
2-16
2-18
2-19
2-21
2-22
2-23
LIST OF TABLES
PAGE
TABLE
TITLE
1-1
1-2
1-3
Model Designation ................................................................................................................ 1-5
Accessories for the FIELDPAC .......................................................................................... 1-15
TIC Contact Information .................................................................................................... 1-17
October 1998
v
CONTENTS
UM348-1
TABLE OF CONTENTS
(Continued)
TABLE
TITLE
PAGE
3-1
Status Information ............................................................................................................... 3-2
4-1
4-2
4-3
Analog I/O Calibration Parameters ....................................................................................... 4-7
Input Types and Calibration Values .................................................................................... 4-12
List of Measured Variable Units ......................................................................................... 4-13
6-1
6-2
Power-Up Error Codes ......................................................................................................... 6-4
On-Line Error Codes ............................................................................................................ 6-5
8-1
Function Block by Type ....................................................................................................... 8-1
FB28-1
FB81-1
FB81-2
FB82-1
FB82-2
FB15-1
FB98-1
Pulse Width and Maximum Rate .......................................................................................... 8-9
Process Ranges .................................................................................................................. 8-10
MV Units ........................................................................................................................... 8-10
Input Types ........................................................................................................................ 8-11
Range Units ....................................................................................................................... 8-11
Status Conditions ............................................................................................................... 8-41
Variable Code Choices ....................................................................................................... 8-57
A-1
FIELDPAC Function Blocks ............................................................................................... A-1
CHANGES FOR REVISION 4, OCTOBER 1998/OCTOBER 2000
Following is a partial list of the changes incorporated in this revision. Editorial changes not affecting technical
content have also been made. Significant changes are marked by a change bar in the page outside margin, as shown
here. Page dates were not changed for the October 2000 revision. Unless otherwise dated, changes are for the
October 1998 version.
Cover..............................................................................APACS logo and text removed.
October 2000: banner changed to Siemens Moore.
Table of Contents............................................................Updated to include added section, illustration, and
revision information.
1.5 Product Support ........................................................October 2000: Text and contact information table
updated.
2.4.3.1 Power Connections, Section C. .......................... 2-WIRE TRANSMITTER SUPPLY OUTPUT (Model
348E only), was changed to clarify the power up status of
the terminals.
2.4.3.2 Signal Inputs and Outputs, Section D. ................ DIGITAL OUTPUTS, Figure 2-7 was changed to show
the Transmitter Power Supply as 22 Vdc.
vi
October 1998
UM348-1
CONTENTS
6.4.1 ERROR CODES, Table 6-1 Power Up
Error Codes. .................................................................. Error Codes E216 for FB81, E226 for FB82, and E236
for FB85/86/87 were added to the table.
6.5.7 DIRECT PRESSURE SENSOR INPUT .............. Installation instructions have been revised to clarify step
4 which is only needed for the Model 340 A/G Sensor.
8.5 PRESSURE SENSOR INPUT FB81 ...................... Output Identification 50 for Static Pressure and Output
Identification 55 for Capsule Temperature were added to
the function block.
8.18.5 INTEGRATOR/TOTALIZER FB16 ................. Changed to show correct block diagram.
8.19.13 HART Interface FB98 - Table FB98-1 ............. Variable Code Choices. Variable Code 9 for FB81 with
Static Pressure and Variable Code 10 for FB81 with
Capsule Temperature were added to the table.
9.16 FCO31 ................................................................. Single-Loop Controller (TSP) with Pressure Input FCO31, Single-Loop Controller (TSP) with Pressure
Input was added to the FCOs. This FCO covers a
Single-Loop PID Controller with Tracking Setpoint and a
Pressure Input.
UMA348-1-3 ................................................................. Removed since contents are included in the above
sections.
n
The Moore logo, VIEWPAC, MYCRO and XTC are trademarks of Siemens Moore Process Automation, Inc.
Other trademarks are the property of their respective owners.
Siemens Moore Process Automation, Inc. assumes no liability for errors or omissions in this document or for the application and use of information
included in this document. The information herein is subject to change without notice.
Procedures in this document have been reviewed for compliance with applicable approval agency requirements and are considered sound practice. Neither
Siemens Moore Process Automation, Inc. nor these agencies are responsible for repairs made by the user.
© Copyright 1998 Siemens Moore Process Automation, Inc. All rights reserved.
October 1998
vii
CONTENTS
viii
UM348-1
October 1998
UM348-1
INTRODUCTION
1.0 INTRODUCTION
This User’s Manual for the Moore 348 Field Mounted Controller, or 'FIELDPAC' (FIELD Process Automation
Controller), is divided into the following sections.
Introduction—Gives general information pertaining to product description, model designation, and specifications.
Installation—Provides general installation considerations, mounting and wiring guidelines, and specific mounting
procedures.
Operation—Defines the controls, signal displays, and operating modes.
Calibration—Provides field calibration procedures for analog inputs and outputs.
Circuit Description—Supplies general circuit descriptions of the MPU Controller Board, the Keyboard/Display
Assembly, and the optional Temperature Sensor and Pneumatic Input Boards.
Maintenance—Furnishes preventive maintenance guidelines, trouble-shooting, and subassembly replacement
procedures.
Configuration—Provides detailed procedures to properly configure the controller by selecting a Factory Configured
Option or from a “Design from Scratch” approach.
Function Block Descriptions—Provides a detailed description and specifications for each function block. Also
provides function block connection details and listings of all configuration parameters.
Factory Configured Options—Is a listing of all available “Factory Configured Options” (FCO). These are
contained in permanent memory and can be entered into configuration memory with just a few key strokes.
IMPORTANT
Save this User’s Manual and make it available for installation, configuration, and
maintenance of a Moore 348 Field Mounted Controller.
1.1 PRODUCT DESCRIPTION
The Model 348 Field Mounted Controller (i.e., FMC or FIELDPAC) is a microprocessor-based, self-contained,
stand alone industrial operator station. Its components, the power supply, operator faceplate, analog and digital
I/O, the optional direct process inputs, including the integral I/P and P/I transducers, are all mounted in a Type 4X
(dust tight, waterproof, and corrosion resistant) enclosure. FIELDPAC design provides for user configuration of
the desired station type and control strategy via software interconnection of function blocks.
FIELDPAC is available in two versions: the Model 348S (Intrinsically Safe design) and the Model 348E (NonIncendive design). The Model 348E FIELDPAC is identical to the Model 348S except for the Transmitter Power
October 1998
1-1
INTRODUCTION
UM348-1
Supply, relay outputs in place of opto-transistors, and additional available options such as the Backlighted Display
and AC Power Supply.
Figure 1-1 shows the FIELDPAC. The front panel contains all the control pushbuttons and signal displays required
for local operation and configuration. Hardware and software for a standard or an enhanced FIELDPAC and the
connectors for FIELDPAC options are located on the MPU Baseboard. All user electrical connections are made to
terminals in the terminal compartment. Figure 1-2 shows a Model 348 with the process pressure input option.
FIELDPAC configuration is performed by the user and consists of interconnecting user selected function blocks
(FBs) and entering the various required parameters to build the needed station configuration. A list of available
function blocks is given in Appendix A. The station's configuration is stored in a nonvolatile memory to prevent
loss of data should an electrical power interruption occur. Factory Configured Options (FCOs) are provided to
simplify configuration.
All the necessary entry keys and alphanumeric displays for configuration are located on the faceplate of the
FIELDPAC. Refer to the Model 348 Configuration Guide for details and procedures.
1.2 MODEL DESIGNATION
Each Model 348 FIELDPAC has a nameplate showing its model number and factory installed options. Use Table
1-1 to interpret the model number and the included options shown on the nameplate (located on left side of
enclosure).
IMPORTANT
Before installing, applying power, or servicing, confirm the station’s model number by
referring to the model designation on the nameplate and to Table 1-1.
1.3 SPECIFICATIONS
1.3.1 Mechanical
DIMENSIONS
FIELDPAC ........................ See Figures 1-1 and 1-2
MOUNTING
Pipe Mounting ................... See Figure 2-1
Panel Mounting ................. See Figure 2-2
Wall Mounting .................. See Figure 2-3
NET WEIGHT
Model 348S_ ..................... Consult Factory
Model 348E_ ..................... Consult Factory
1-2
October 1998
UM348-1
INTRODUCTION
Display/Keyboard
Cover Assembly
Pneumatic
Output
1/4 NPT
Air Supply
1/4 NPT
Top
Mounting
Plate
O
S
D
PB1
NEMA 4
Vent
1/2 NPT
PB2
8.30
(211)
AUTO
MAN
11.32
(287.4)
V
1
13.00
(330)
ENTER
EXIT
CONF
TUNE
TAG
STORE
ACK
STEP
UP
ALARM
STEP
DOWN
11.94
(303.4)
2
Pneumatic
Inputs
1/4 NPT
3
FIELDPAC
4.60
(117)
FRONT VIEW
Safety
Ground
Connection
Bottom
Mounting
Plate
Terminal
Compartment
Cover
6.70
(170)
5.4
(137)
2.60
(66)
SIDE VIEW
Panel
Mount
Surface
5.60
(142)
3.00
(76) REF.
X02949S3
A02471A0
Electrical Connections, Conduit,
1, 1/2 NPT or M20 x 1.5
3, 3/4 NPT or M25 x 1.5
Dimple,
2 Places,
Note 2
Mounting
Plate
2.81
(71.5)
9.82
(249)
11.20
(284)
11.50
(292)
Notes:
1. Dimensions are in
Inches (Millimeters).
2. Dimples indicate an
enclosure with metric
threads.
BOTTOM VIEW
FIGURE 1-1 MODEL 348 FIELD MOUNTED CONTROLLER (FIELDPAC)
October 1998
1-3
INTRODUCTION
UM348-1
Top Mounting
Plate, U-Bolt
Not Shown For
Clarity
3
(194)
Differential Pressure Sensor (Model 340D)
Absolute or Gauge Pressure Sensor
(Model 340A or 340G)
O
S
2.6
(15.9)
V
1
Notes:
1. Dimensions are in inches (millimeters).
2. Select a 'Direct Connect' Model 340 sensor.
2
3
Bottom
Mounting
Plate
Bottom
U-Bolt
MG000761
2" Pipe
(Supplied
By User)
FIGURE 1-2 MODEL 348 DIMENSIONS, PROCESS PRESSURE INPUT MODELS
1-4
October 1998
UM348-1
INTRODUCTION
TABLE 1-1 Model Designation
Basic Model Number
348S
Intrinsically Safe Field-Mounted Controller
348E Non-Incendive Field Mounted Controller
Power Supply
A 90-264 Vac, 47-63 Hz, Model 348E only
C 90-264 Vac, 47-63 Hz, Model 348E only (Use with CE or BASEEFA approval.)
D 14-28 Vdc, non-isolated
Operator’s Display
1 Full-Function
2 Full-Function with Backlight, Model 348E only
Backplate Option
D Direct-Connected D/P Sensor
P Direct-Connected Gauge & Absolute Pressure Sensor
R Removable plug for future sensor mounting
N Not Required
Analog Option Board
A (1) 15 PSIG Pneumatic Input
C (3) 15 PSIG Pneumatic Inputs
D (1) 30 PSIG Pneumatic Input
F (3) 30 PSIG Pneumatic Inputs
T Thermocouple/RTD/Millivolt Input
N Not Required
Analog Output No.1 Options
1 4-20 mA Current
2 15 PSIG Pneumatic
3 30 PSIG Pneumatic
Design Level
NOTE
B Current Design
Reserved
Other hazardous area certifications
N Not Required
pending. Contact your local Moore
X Special Modification
representative or the factory for latest
Reserved
certifications.
N Not Required
Communications
H HART ®
Electrical Connections
1 NPT
2 Metric
Hazardous Area Classification (See Note)
N Non-Approved
4 FM/CSA Div. 2, Class I, Groups A, B, C, D suitable for
non-incendive
Y CSA Intrinsically Safe Div. 1, Class I, Groups C & D, Class
II, Groups E, F, & G, Class III
E CE Compliant
L BASEEFA Ex N IIC (Includes CE)
348 E
D
October 1998
1
D
N
2
A
N
N
H
1
N
Sample Model Number
1-5
INTRODUCTION
UM348-1
1.3.2 Electrical
1.3.2.1 Power Requirements
AC POWER (Model 348EA)
Nominal Voltage and Frequency .. 115 or 230 Vac, 50/60 Hz
Voltage and Frequency Limits ..... 90 to 264 Vac, 47 to 63 Hz
Power Consumption .................... 32 VA maximum
Voltage Selection ........................ Universal (Auto-sensing, no setting required)
AC Power Terminals ................... L1 (H) - Terminal 'B1'
L2 (N) - Terminal 'A2'
G (Gnd) - Terminal 'B3'
DC POWER (Model 348_D)
Nominal Voltage ......................... Vps = 24 Vdc
Voltage Limits ............................ Vps = 14.0 to 28.0 Vdc
Power Consumption .................... 4.5 Watts maximum
DC Power Terminals .................. DC Power (+) - Terminal 'F1'
DC Power (-) - Terminal 'F2' (Gnd)
1.3.2.2 2-Wire Transmitter Supply Power (Model 348E only)
Nominal Output Voltage .................... +22 Vdc
Output Voltage (Model 348_D) ......... +(Vps-4.5) Vdc
Current .............................................. 80 mA (max.) at 22 Vdc (short-circuit protected)
XMTR Supply 1 ............................... Terminal 'F6'
XMTR Supply 2 ............................... Terminal 'F9'
XMTR Supply 3 ............................... Terminal 'F12'
(all terminals internally connected to the same current-limited power supply)
1.3.3 Input/Output Ports
ANALOG INPUTS
Input Channels .......................... 3
Input Range .............................. 0 to 5 Vdc
Standard Calibration ................. 1 to 5 Vdc
Zero Adjustment ....................... 0 to 1 Vdc
Span Adjustment ....................... 4 to 5 Vdc
Input Type ................................ Single-ended (non-isolated)
Input Impedance ....................... > 1 Megohm
Normal Mode Rejection ........... 3 dB typical @ 1.4 Hz, 64 dB typical @ 60 Hz ±3 Hz (2-pole filter with
breakpoint frequency @ 2 Hz)
Digital Filter Range .................. 0.001 to 10 Hz (breakpoint frequency)
Calibration Accuracy ................ < ±0.1% of span
A/D Resolution ......................... 12 bits
A/D Linearity ............................ ±1 LSB
1-6
October 1998
UM348-1
INTRODUCTION
Maximum Continuous Input ...... ±30 Vdc
Ambient Temperature Effect ..... < ±0.85% of span for a 50°C ambient temperature change (typical: ±0.5%)
DIGITAL INPUTS
Input Channels ......................... 2
Input Type ............................... Opto-coupler (isolated)
Input Impedance ...................... 3300 Ohms
Logic "1" Range ...................... 12 to 30 Vdc
Logic "0" Range ..................... 0 to 5 Vdc
Isolation ................................. 250 Vrms
Minimum "On Time" .............. 150 msec
Minimum "Off Time" ............. 150 msec
PNEUMATIC INPUTS (Models 348____A, -C, -D, -F)
Input Channels .......................... 1 or 3
15 psig Sensor (Models 348____A, -C)
Standard Calibration .......... 3 to 15 psig
Zero Adjustment ................ 0 to 4 psig
Full Scale Adjustment ........ 12 to 15 psig
30 psig Sensor (Models 348____D, -F)
Standard Calibration .......... 3 to 27 psig
Zero Adjustment ................ 0 to 8 psig
Full Scale Adjustment ........ 24 to 30 psig
Accuracy ................................... ±0.35% of span
Temperature Effect ................... Ambient: ±0.15% of span per °C
Calibrated: ±0.85% of full span
MILLIVOLT INPUT (Model 348____T)
Input Channels .......................... 1
Input Impedance ....................... > 1.0 Megohm
Wide Range
Range Limits ..................... -15 to +100 mVdc
Zero ................................... -15 to +100 mVdc
Span .................................. 5 to 115 mVdc
Narrow Range
Range Limits ..................... -10 to +25 mVdc
Zero ................................... -10 to +25 mVdc
Span .................................. 1 to 35 mVdc
October 1998
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INTRODUCTION
UM348-1
RTD INPUT (Model 348____T)
Input Channels .....................…….. 1
Platinum RTD Type ..............….... 2, 3, or 4 wire
Input Impedance .................…..…. > 1.0 Megohm
RTD Types ...........................…..... 100 Ohm, 200 Ohm, 500 Ohm
DIN .....................................……... =0.003850 //°C
US .......................................……... =0.003902 //°C
Accuracy ........................................ <+/- 0.25°C
Resolution ....................................... <0.10°C
Ambient Temperature Effect .......... <+/- 0.04°C/°C
THERMOCOUPLE INPUT (Model 348____T)
Input Channels ...........................…... 1
Input Impedance .....................…...... 1.0 Megohm
Reference Junction Compensation ... Automatic
Thermocouple Burnout Direction …. Selectable - UP or DOWN
Conformity ..............................…..... <= 0.06°C; NIST curve based on IPTS - 1968
Thermocouple Types ...............…..... B, E, J, K, N, R , S, T
Temperature Range …………….… Zero and Span configurable
Accuracy ..................................….... <+/- 0.75°C
Ambient Temperature Effect ........... <+/- 0.06°C/°C
PROCESS PRESSURE INPUT (Model 348___D)
Input Channels ...............……......... 1
Sensor Type .......................……..... Absolute, Gauge, or Differential
Connection Type .................…….... Direct or Remote
Accuracy ..............................……... < ±0.05% (Upper Range Limit)
Ambient Temperature Effect ……... < ±0.5% of span for a 50°C ambient temperature change (typical: ±0.3%)
ANALOG OUTPUTS
Output Channels ..............……...... 2
Standard Calibration ........……...... 4 to 20 mAdc
Zero ...........................……...... 4 mAdc ± trim
Span ..........................……...... 16 mAdc ± trim
Signal Reference .............……...... Negative (-) output terminal is station common
Accuracy ........................……....... < ±0.1% of span
Current Limit ..................……...... > 21.6 mA
Output Load ....................……..... 0 to Lm Ohms
DC Powered: Lm=[Vsupply - 6.83V]/21.6 mA
AC Powered: Lm=800 Ohms
Ambient Temperature Effect …... < ±0.5% of span for a 50°C ambient temperature change
1-8
October 1998
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INTRODUCTION
DIGITAL OUTPUTS
Output Channels ..................... 2
Output Type ........................... Open Collector Transistor (emitter tied to station common)
Load Voltage ......................... 30 Vdc maximum
Load Current .......................... 150 mA maximum
Transistor "ON" Voltage ........ 0.9V max. @ 100 mA load
Transistor "OFF" Leakage ..... 0.5 uA max. @ 30 Vdc
RELAY OUTPUTS (Model 348E)
Output Channels .................... 2
Relay Type ............................ Epoxy Sealed
Contact Configuration ........... SPDT (Form C)
Contact Rating ...................... 3A at 250 Vac
ISOLATED DIGITAL OUTPUTS (Model 348S)
Output Channels ..................... 2
Output Type ........................... Opto-Transistor
Load Voltage ......................... 30 Vdc maximum
Load Current .......................... 2 mA minimum @ 10 Vdc
Transistor "ON" Voltage ........ 10 V max. @ 2 mA load
Transistor "OFF" Leakage ...... 50.0 nA max. @ 10 Vdc
Isolation Voltage .................... 250 Vrms
PULSE INTEGRATOR OUTPUT
Output Channels ..................... 1
Output Type ........................... Open Collector Transistor (emitter tied to station common)
Load Voltage ......................... 30 Vdc maximum
Load Current ......................... 150 mA maximum
Transistor "ON" Voltage ....... 0.9V max. @ 100 mA load
Transistor "OFF" Leakage ..... 0.5 uA max. @ 30 Vdc
Maximum Frequency ............ Configurable in FB28
PNEUMATIC OUTPUT OPTION
Output Channels ..................... 1
15 PSIG
Standard Calibration ........ 3 to 15 psig
Supply Pressure ............... 20 psig, 18 psig minimum
30 PSIG
Standard Calibration........ 3 to 27 psig
Supply Pressure .............. 35 psig, 33 psig minimum
Accuracy ............................... ±0.35% of span
Repeatability ......................... 0.05% of span
Deadband ..................................... 0.05% of span
Ambient Temperature Effect ........ ±0.05% per °F
Air Consumption .......................... 0.1 SCFM
Supply Capacity ........................... 2.5 SCFM maximum at 20 psig
Exhaust Capacity ......................... 2.5 SCFM
October 1998
1-9
INTRODUCTION
UM348-1
Maximum Supply Pressure .......... 45 PSI
HART COMMUNICATIONS
Type ............................................. HART Slave
Coupling ....................................... AC (on +side only, -side tied to Signal Common)
Physical Layer .............................. HART Rev. 7.0
Commands .................................... HART Rev. 5 or 6
1.3.4 Environmental
Operating Temperature Limits ............ -40°C to +85°C (-40°F to +185°F)
Operating Humidity ............................ IEC 654-1 Class D2 (5 to 100%)
Transportation and Storage
Temperature Limits ...................... -40°C to +85°C (-40°F to +185°F)
Humidity Limits ........................... 0 to 100% RH, Non-Condensing
ESD Susceptibility ...............................15 kV to case
5 kV to any terminal connection
Surge Protection .................................. User Terminals: 1.5 kV per ANSI/IEEE C37.90
Corrosion Protection ........................... G3 per ISA S71.04-85
Coating ............................................... PC boards are conformally coated
Isolation
Primary to Secondary ................... 250 Vac
Terminal to Ground ...................... 250 Vac per BS6941:1988
Heat Dissipation
AC Powered ................................. 65 Btu/Hr
DC Powered ................................. 16 Btu/Hr
Enclosure ............................................ TYPE 4X
1-10
October 1998
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INTRODUCTION
1.3.5 Hazardous Area Classification
Before installing, applying power to, or servicing a station, see the station’s nameplate and Table 1-1 for electrical
classification. Other certifications are pending. Contact Moore for the latest approvals and certifications.
Model 348S
CSA .......................................... Class I, Division 1, Groups C & D
Class II, Division 1, Groups E, F & G
Class III, Division 1
Type 4X
Model 348E
FM/CSA ...................................... Class I, Division 2, Groups A, B, C & D
CE ............................................... EMC Compliant: EN50081-2 Emissions
EN50082-1 Immunity
EN50082-2 Immunity
1.3.5.1 FM/CSA Hazardous Location Precautions
This section provides FM/CSA hazardous location precautions that should be observed by the user when installing
or servicing the equipment described in this Manual. These statements supplement those given in the preceding
section.
WARNING
Failure to observe the following precautions could result in an explosion hazard.
Precautions - English
For Class I, Division 1, and Class II, Division 2 hazardous locations,
Use only factory-authorized replacement parts. Substitution of components can impair the suitability of this
equipment for hazardous locations.
For Division 2 hazardous locations:
When the equipment described in this Manual is installed without safety barriers, the following precautions should
be observed. Switch off electrical power at its source (in non-hazardous location) before connecting or
disconnecting power, signal, or other wiring.
October 1998
1-11
INTRODUCTION
UM348-1
Précautions - Français
Emplacements dangereux de classe I, division 1 et classe I, division 2:
•
Les pièces de rechange doivent être autorisées par l'usine. Les substitions peuvent rendre cet appareil impropre
à l'utilisation dans les emplacements dangereux.
Emplacement dangereux de division 2:
Lorsque l'appareil décrit dans la notice ci-jointe est installé sans barrières de sécurité, on doit couper l'alimentation
électrique a la source (hors de l'emplacement dangereux) avant d'effectuer les opérations suivantes branchment ou
débranchement d'un circuit de puissance, de signalisation ou autre.
1.3.5.2 CE (EMC) Compliant Considerations
A Declaration of Conformity in accordance with EN 45014 has been issued for Model 348 for compliance with the
European Union’s EMC directive. Testing was done in accordance with the following:
The European Union’s EMC Directive
EN50081-2: 1993 Generic Industrial Emissions
EN50082-1: 1992 Generic Light Industry Immunity
EN50082-2: 1995 Generic Industrial Immunity
Special Conditions*
Compliant stations will contain an ‘E’ in the Electrical Classification portion of the model designation.
FM/CSA electrical classification approval as non-incendive for Division 2 service applies to installations in North
America and where recognized. Check local approval requirements.
A Declaration of Conformance appears later in this section.
Environmental Conditions, Per IEC 664:
Installation Category II
Pollution Degree 2
Use of the equipment in a manner not specified by the manufacturer may impair the protection provided by the
equipment.
Route electrical power to the station through a clearly labeled circuit breaker or on-off switch that is located near
the station and accessible by the operator. The breaker or switch should be located in a non-explosive atmosphere
unless suitable for use in an explosive atmosphere.
Local Instrument Link twinaxial cable must be shielded.
1-12
October 1998
UM348-1
INTRODUCTION
All signal cables, including HART communications, use shielded cable. The case is connected to earth ground.
A sample Model 348 was tested and found to have a 3.6°C temperature shift between 95 and 100 MHz radiated
immunity disturbance, as much as a 2.5°C temperature shift at 110 MHz, 191 MHz, 195 MHz, and between 315
and 400 MHz, and a 2.5°C temperature shift for 417 to 500 MHz disturbances for a T-type thermocouple. The
same sample had narrow ohm RTD deviations of -0.5 Ω at a 116.5 MHz disturbance, -2.8 Ω shift at 340.7 MHz
and 450.0 MHz, a -1.0 Ω deviation at 345.7, 409.0 MHz and 461.0 MHz, a -7.7 Ω deviation at 420 MHz, and -6.9
Ω at 428.0 MHz.
1.3.5.3 BASEEFA Ex N IIC T5 Considerations
This section provides BASEEFA hazardous location precautions that should be observed by the user when
installing or servicing the equipment described in this manual. These statements supplement those given in the
preceding section(s).
The Model 348ExxxxxxxxxxL complies with the requirements of BS6941: 1988. The apparatus is certified for Ex
N IIC T5 (Tamb = -40ºC to +60ºC). For a copy of the certificate of assurance, contact Moore Products Co. at 215646-7400 ext. 4TIC.
Special Conditions
Install the controller such that the main enclosure cover is exposed to no greater than a low risk of mechanical
damage.
Protect the controller’s 90-264 Vac power supply with a 1A, 250V, HBC fuse.
Supply the controller’s pneumatic system with clean, dry air.
1.3.6 Two-Wire Cable for HART Communication
Type............................................................................... Twisted Single-Pair, Shielded, Copper
Conductor Size for Network Length
Less than 500 ft. (1524m)......................................... 24 AWG minimum
More than 500 ft. (1524m) ....................................... 20 AWG minimum, 16 AWG maximum
Cable Capacitance.......................................................... Refer to Appendix C
Recommendation ............................................................ Beldon 8641, 24 AWG
Beldon 8762, 20 AWG
Length Maximum ........................................................... Refer to Appendix C
October 1998
1-13
INTRODUCTION
1-14
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October 1998
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INTRODUCTION
1.4 ACCESSORIES
Table 1-2 lists some accessories that are available for use with the Model 348 Field Mounted Controller.
TABLE 1-2 Accessories for the FIELDPAC
PART
NUMBER
1593948VN.NN
PRODUCT
Configuration Software
----
Permanent Instrument Tag
16161-88
Extended Mounting Plate
(2 Required)
16055-312
HART® Modem
----
Test and Inspection
Certificate
14999-116
Test Fitting
16161-140
Stahl 9381/10-158-160-10
24 Vac/dc Barrier Supply
Kit
16161-141
Stahl 9381/10-158-160-50
120/240 Vac/dc Barrier
Supply Kit
16161-142
Stahl 9001/02-016-015-10
HART Signal Barrier Kit
October 1998
DESCRIPTION
IBM® personal computer based software
for configuring FIELDPAC direct through
a modem or through a Model 320 ICI and a
Model 385 LOS.
The instrument nameplate can be stamped
with up to three lines of text (at up to 30
characters/line)
Provides additional room for mounting.
Required when wall mounting a
FIELDPAC with a 3-valve manifold and a
D/P sensor. Do not use in area with
excessive vibration.
A Bell 202T style modem for use with the
above PC-based configuration software
package.
A certified test and inspection report on the
analog I/O performance of an individual
unit.
Use for in-service measurement of current
signals. It is weatherproof, includes 18" of
lead wire, and has 1/2 NPT threads for
mounting in a conduit tee or elbow.
This approved barrier/supply combination
powers the Model 348S when installed in
Class I, Div. 1, Groups C & D, Class II,
Groups E, F & G, and Class III areas.
This approved barrier/supply combination
powers the Model 348 S when installed in
Class I, Div. 1, Groups C & D, Class II,
Groups E, F & G, and Class III areas.
This approved barrier conditions HART
signals passing to the Model 348 S when
installed in Class I, Div. 1, Groups C & D,
Class II, Groups E, F & G, and Class III
areas.
1-15
INTRODUCTION
UM348-1
1.5 PRODUCT SUPPORT
Product support can be obtained from a Technical Information Center (TIC). Each regional TIC is a customer
service center that provides direct telephone support on technical issues related to the functionality, application, and
integration of all products supplied by Siemens Moore. Regional TIC contact information is provided in Table 1.1.
Your regional TIC is the first place you should call when seeking product support information. When calling, it is
helpful to have the following information ready:
•
Caller ID number, or name and company name—When someone calls for support for the first time, a personal caller
number is assigned. Having the number available when calling for support will allow the TIC representative taking the
call to use the central customer database to quickly identify the caller’s location and past support needs.
•
Product part number or model number and version
•
If there is a problem with product operation:
- Whether or not the problem is intermittent
- The steps performed before the problem occurred
- Any error messages or LED indications displayed
- Installation environment
Customers that have a service agreement (ServiceSuite or Field Service Agreement) are granted access to the secure
area of our Web site (www.smpa.siemens.com). This area contains a variety of product support information. To log
on, you will be prompted to enter your username and password.
1-16
October 1998
UM348-1
INTRODUCTION
TABLE 1-3 TIC Contact Information
TIC
NORTH AMERICA
Tel:
Fax:
E-mail:
Hours of Operation:
Secure Web Site:
Repair Service
TIC
ASIA
Tel:
Fax:
E-mail:
Hours of Operation:
Secure Web Site:
Repair Service:
TIC
EUROPE
Tel:
Fax:
E-mail:
Hours of Operation:
Public Web Site:
Repair Service
+1 215 646 7400, extension 4993
+1 215 283 6358
[email protected]
8 a.m. to 6 p.m. eastern time
Monday – Friday (except holidays)
www.smpa.siemens.com
+1 215 646 7400 extension 4993
+65 299 6051
+65 299 6053
[email protected]
9 a.m. to 6 p.m. Singapore time
Monday – Friday (except holidays)
www.smpa.siemens.com/techservices
+011 65 299 6051
+44 1935 470172
+44 1935 706969
[email protected]
8:30 a.m. to 5:15 p.m. GMT/BST
Monday – Thursday (except holidays)
8:30 a.m. to 4:00 p.m. GMT/BST
Friday (except holidays)
www.smpa.siemens.com
+44 1935 470172
n
October 1998
1-17
INTRODUCTION
1-18
UM348-1
October 1998
UM348-1
INSTALLATION
2.0 INSTALLATION
This section provides general information such as installation considerations and mounting and wiring guidelines
for the Moore FIELDPAC Field Mounted Controller. Detailed information on the mounting and the electrical and
pneumatic connections of the FIELDPAC is also provided in this section.
2.1 INSTALLATION CONSIDERATIONS
The FIELDPAC is intended for two-inch pipe mounting. It can be installed in an outdoor location, mounted either
in a panel cutout, on a two inch pipe, or on a wall. Pipe mounting details are shown in Figure 2-1, panel cutout
dimensions are given in Figure 2-2, and a typical wall mounting arrangement is depicted in Figure 2-3.
The FIELDPAC can be mounted in any position, with the front panel in a vertical or slanted position. Although
direct sunlight does not harm the FIELDPAC, it may make the display difficult to read. For this reason, an attempt
should be made to mount the FIELDPAC so that direct sunlight does not strike the display.
A FIELDPAC is usually shipped with all the circuit boards installed in the case.
2.2 ENVIRONMENTAL CONSIDERATIONS
See “Specification” section for FIELDPAC operating temperature limits and operating humidity and maximum
moisture content. The air surrounding any operating FIELDPAC must be kept below 85°C (185°F). The
temperature of the air should be checked to ensure that this specification is not being exceeded.
CAUTION
Exceeding specified operating temperature limits can adversely affect performance and
may cause damage.
Forced air ventilation may be required when FIELDPACs are mounted in a partially or completely enclosed panel
or cabinet. When clean air is present, exhaust fans are often mounted across the top of a panel and louvers formed
in the panel bottom. Air is drawn upward between the station cases. When air contains particulate matter, fans
and filters are often located at the panel bottom and louvers at the top. Filtered air is now forced upward between
the station cases. Filters must be serviced periodically.
October 1998
2-1
INSTALLATION
UM348-1
TOP MOUNTING
PLATE
TOP U-BOLT
O
S
PB1
D
PB2
AUTO
MAN
V
1
ENTER
EXIT
CONF
TUNE
TAG
STORE
ACK
STEP
UP
ALARM
STEP
DOWN
2
2" PIPE
(SUPPLIED
BY USER)
3
FIELDPAC
BOTTOM
MOUNTING
PLATE
BOTTOM
U-BOLT
A
SEE NOTE
5/16"-18NC X 1.13" BOLT (4 PL.)
5/16"-18NC NUT
5/16" LOCKWASHER
U-BOLT
NOTE:
DIMENSION ASTANDARD MOUNTING PLATE: 7.0(180)
EXTENDED MOUNTING PLATE: 8.8(225)
MOUNTING PLATE
FIELDPAC
MOUNTING DETAIL - TOP VIEW
A02473M0
DIMENSIONS ARE IN INCHES(MILLIMETERS).
FIGURE 2-1 Pipe Mounting Details
2-2
October 1998
UM348-1
INSTALLATION
Mounting Plate
Bolts (4)
FIELDPAC
Flange
Pressure Screw
Design Level "B"
1/4" - 20 NC X 3.5"
Design Level "A"
1/4" - 20 NC X 2.5"
See Note 2
Panel Thickness
3/16" (4.8) Max.
MOUNTING DETAIL - TOP VIEW
Top Mounting
Plate
O
S
Design Level "B"
11.51±0.1
(292±2.5)
See Note 2
V
PANEL
CUTOUT
Maximum
Panel
Thickness
3/16" (4.76)
Design Level "B"
10.0±0.1
(254±2.5)
See Note 2
1
Design Level "A"
11.410±0.01
(289.8±0.25)
See Note 2
2
3
Design Level "A"
9.910±0.01
(251.7±0.25)
See Note 2
Notes:
1. Dimensions are in Inches (Millimeters).
2. Design Level is designated by 10th character in model number.
See Controller nameplate.
Bottom
Mounting
Plate
X02943S2
FIGURE 2-2 Panel Mounting Dimensions
October 1998
2-3
INSTALLATION
UM348-1
TOP MOUNTING
PLATE
WALL
O
S
D
PB1
PB2
AUTO
V
MAN
WALL
1
ENTER
TUNE
EXIT
CONF
TAG
ACK
ALARM
STORE
STEP
UP
STEP
DOWN
2
3
FIELDPAC
BOTTOM
MOUNTING
PLATE
.375" CLEARANCE HOLE
A
MOUNTING PLATE
NOTE:
5/16"-18NC X 1.13" BOLT (4 PL.)
DIMENSION A:
STANDARD MOUNTING PLATE: 5.7(145)
EXTENDED MOUNTING PLATE: 7.5(190)
WALL
FIELDPAC
USER SUPPLIED
FASTENERS
DIMENSIONS ARE IN INCHES(MILLIMETERS).
MOUNTING DETAIL - TOP VIEW
A02474M0
FIGURE 2-3 Typical Wall Mounting
2-4
October 1998
UM348-1
INSTALLATION
Only high quality, quiet running fans should be used. Also, the fans should not generate electrical noise which
could interfere with electronic instruments.
A sealed cabinet (e.g., NEMA12) containing equipment that does not generate significant heat should contain a
recirculating fan for forcing air flow around equipment and throughout the cabinet preventing hot spots from
developing.
Forced air conditioning may be needed in panels and cabinets with high equipment density or significant heat
generating capability. Periodically change or clean air filters.
Industrial environments often contain particulate, liquid, and gaseous contaminants. Particulate matter, usually
dust and dirt, is abrasive and can cause intermittent connections. A layer of dust on circuit boards can inter-fere
with semiconductor heat dissipation. Liquid and gaseous contaminants can have a corrosive effect on metal,
rubber, plastic and circuit board components. Extended exposure to these contaminants may result in malfunctions.
To reduce contaminant related equipment malfunctions:
1. Identify contaminants and implement methods to reduce their presence.
2. When cleaning equipment and surrounding area, especially the floor, either vacuum away all dust and dirt or
use a dampened rag or mop. Sweeping or dry dusting recirculates dust and dirt.
3. Clean or replace all air conditioning filters, room air filters, and equipment filters regularly.
4. Inform all personnel with access to the equipment of the need for cleanliness.
2.3 MECHANICAL INSTALLATION
The following sections provide guidelines and procedures for mounting FIELDPACs in a panel, on two inch pipes,
and on wall surfaces. Each installation should be structurally rigid and free of vibration.
2.3.1 Panel Mounting
The panel face should provide a flat, rigid mounting surface. Stiffeners should be welded to the back of the panel if
there is a possibility that the panel face will bow. Figure 2-2 shows the needed cutout dimensions. The panel
cutout should be square and level, especially the bottom edge. Uneven cutting of the bottom edge can cause the
station case(s) to tilt and detract from front panel appearance.
Any nearby raceways, conduit, and wiring should not interfere with removing or accessing a FIELDPAC and other
associated instruments, control devices, alarms, and related equipment.
Refer to Figure 2-2, Panel Mounting, while proceeding with the following steps.
October 1998
2-5
INSTALLATION
UM348-1
1. Loosen and remove the top and bottom mounting plates from the FIELDPAC.
2. Insert FIELDPAC into panel cutout.
3. Install and tighten (4 bolts each) the top and bottom mounting plates to the FIELDPAC.
4. Square FIELDPAC with panel.
Alternately tighten the top and bottom pressure screws in the mounting plates until FIELDPAC is secured to panel.
Do not over tighten.
2.3.2 Pipe Mounting
The vertical two inch pipe should provide a rigid mounting structure. Figure 2-1 shows the mounting details. Any
nearby raceways, conduit, and wiring should not interfere with the mounting and accessibility of the FIELDPAC
and other associated instruments, control devices, alarms, and related equipment.
A FIELDPAC equipped with a three-valve manifold and a D/P sensor must use the Extended Mounting Plate kit
(see “Accessories” section). Use of the Extended Mounting Plate kit is not recommended in an area with excessive
vibration.
Refer to Figure 2-1, Pipe Mounting, while proceeding with the following steps.
1. Install the top and bottom mounting plates (4 bolts supplied with each unit) to the FIELDPAC cabinet. Leave
the U-bolts off the mounting plates.
2. Position the FIELDPAC against the pipe at the required height.
3. Insert a U-bolt around the pipe and into the top mounting plate.
4. Secure the U-bolt with two 5/16" lockwashers and two 5/16"-18 nuts. Do not over tighten.
5. Repeat steps 3 and 4 for the bottom mounting plate.
2.3.3 Wall Mounting
The wall should provide a flat, rigid mounting surface. Stiffeners should be added to the back of the wall if there is
a possibility that the wall panel is not strong enough to support the FIELDPAC. Figure 2-3 shows a typical wall
installation. Any nearby raceways, conduit, and wiring should not interfere with the installation and accessibility of
the FIELDPAC and other associated instruments, control devices, alarms, and related equipment.
A FIELDPAC equipped with a direct-connected D/P sensor must use the Extended Mounting Plate kit (see
“Accessories” section). Use of the Extended Mounting Plate kit is not recommended in an area with excessive
vibration.
2-6
October 1998
UM348-1
INSTALLATION
Refer to Figure 2-3, Wall Mounting, while proceeding with the following steps.
1. Install the top and bottom mounting plates (4 bolts supplied with each unit) to the FIELDPAC cabinet. Leave
the U-bolts off the mounting plates.
2. Position the FIELDPAC against the wall at the required height and mark the four holes that will be needed for
mounting.
3. Determine what type of fastener is most appropriate for the given wall and the 0.375" clearance holes in the
mounting plates.
4. Prepare the wall to accept the selected fasteners provided by user.
5. Position the FIELDPAC against the wall over the four prepared holes and secure it with the selected fasteners.
2.4 ELECTRICAL INSTALLATION
The following sections describe wiring guidelines that should be followed when wiring a FIELDPAC installation
and define the purpose of each terminal.
WARNING
Remove power from all involved wires and terminals to eliminate electrical shock hazard.
2.4.1 Conduit Installation
Consider the following guidelines for conduit installation:
• The Model 348 enclosure is provided with four conduit ports that will accept one ½"-14 NPT and three 3/4"-14
NPT or one M20 x 1.5 and three M25 x 1.5 conduit fittings.
•
Field wiring should be installed in conduit.
•
When routing conduit, avoid areas that might subject the conduit to chemical or physical abuse or areas with
high EMI/RFI conditions.
•
Be sure the conduit and its contained cable are not exposed to temperatures exceeding the cable's normal
operating temperature range.
October 1998
2-7
INSTALLATION
UM348-1
•
In a high humidity environment, with the FIELDPAC mounted at a low point in the conduit run, use a drain
seal at the conduit entrance to prevent condensation from entering the FIELDPAC enclosure.
•
Remove all sharp edges and burrs from conduit that may damage wires.
2.4.2 Wiring Guidelines
All wiring must conform to the National Electrical Code and local codes. DC wiring should be separated from AC
wiring, as much as possible, and away from AC powered pushbuttons, alarms, annunciators, motors, solenoids, and
similar devices. Metallic and non-metallic raceway and conduit are commonly used for routing panel wiring.
Wiring not installed in raceways or conduit should be clamped or supported approximately every 12 inches (300
mm).
Stranded wire is recommended. Carefully select the wire size, conductor material, and appropriate insulation.
Some selection considerations are:
•
•
•
•
•
•
•
•
Current and voltage to be carried
Total length of each wire run
Whether wire will be bundled or run singly
Indoor or outdoor installation
Temperature extremes
Exposure to sunlight
Vibration
Types of contaminants
Electrical connections are made to terminal blocks in the terminal compartment of the FIELDPAC. To make a
connection, insert a stripped wire end into the wire hole of the terminal block and tighten the pressure screw. When
preparing wires and making connections, refer to Figure 2-4 and the following:
•
•
•
Stranded Conductor: Strip wire end 3/8" (9 mm) to 7/16"(11 mm).
Solid Conductor: Strip wire 3/8" (9 mm) to 7/16"(11 mm).
Do not nick the conductor or cut away conductor strands when stripping insulation.
1. Carefully inspect each connection for mechanical strength and stray strands of wire that could short to an
adjacent terminal; conductor should not be visible outside the terminal block body.
2. Insert the stripped wire end into the side wire hole and under the pressure plate and tighten the top terminal
screw for a reliable electrical connection. Insulation should butt against the pressure plate and the conductor
should not be visible outside the terminal block body.
3. Inspect each completed connection for strands of wire that could short to an adjacent terminal, for connection to
the correct terminal, and for tightness of the terminal screw.
2-8
October 1998
UM348-1
INSTALLATION
TIGHTEN SCREW
TYPICAL TERMINAL BLOCK
INSERT WIRE
A02482T0
FIGURE 2-4 Conductor Connection to Terminal Block
2.4.3 Terminal Connections
All electrical connections are made to the terminals located at the front of the FIELDPAC case behind the terminal
access cover. The terminals are designated by a terminal block letter and a row number (e.g., A1, E8) as shown in
Figure 2-5. Recommended wire size for signal wiring is 18 gauge (AWG); power wiring, 14 gauge (AWG).
WARNING
Remove power from all involved wires and terminals to eliminate electrical shock hazard.
The terminal blocks accept stranded or solid wires. See Figure 2-4. For an electrical connection to be made, a
terminal screw must be tightened, clamping the wire between the pressure plate and base plate inside the terminal
block body to insure a good electrical contact.
October 1998
2-9
2-10
A
B
1
2
3
3
C
2
3
3
1 R2 COM
(OPTO2 -)
2 R2 NO
(OPTO2 +)
3 R2 NC
C
Relay/OPTO
Terminals
1
2
1
F
1
2
1 R1 COM
(OPTO1 -)
2 R1 NO
(OPTO1 +)
3 R1 NC
D
E
Note: The following terminals are tied together
F2, F4, F8, F11, F14, E2, E4, E6, E12, E14.
1 H (L1)
2 Not Used
3G
B
1
D
ASSY/PN
Label
AC Power
Terminals
1
2
E
3
4
4
5
5
1 DOUT1 +
2 DOUT1 3 DOUT2 +
4 DOUT2 5 Pulse Out +
6 Pulse Out 7 DIN1 +
8 DIN1 9 DIN2 +
10 DIN2 11 AOUT1 +
12 AOUT1 13 AOUT2 +
14 AOUT2 -
2
3
6
7
7
8
8
9
9
10
10
14
H
2
3
Ser. No.
Label
1
2 3
Optional I/O
Terminals
1
1 N/C
2 RTD I Source
3 N/C
H
G
X02944S0
Note: Terminals in blocks "G" and
"H" sre shown for TC/RTD input
option board only.
1 N/C
2 Input +
3 Input -
G
11 12 13
11 12 13 14
1 DC Power Supply +
2 DC Power Supply 3 HART +
4 HART 5 N/C
6 XMTR SUPPLY 1
7 AIN1 +
8 AIN1 9 XMTR SUPPLY 2
10 AIN2 +
11 AIN2 12 XMTR SUPPLY 3
13 AIN3 +
14 AIN3 -
F
Field Terminals
6
•
•
•
•
1 Not Used
2 N (L2)
3 Not Used
A
INSTALLATION
UM348-1
SIGNAL COMMON is at terminal 'F2' (DC Power -). It should be connected to the user's instrument bus
common. Within the FIELDPAC, station common is connected to:
A common reference point which in turn is connected to the XMTR power supply common
Digital output common (except the 2 opto-transistors in Model 348S)
All analog input and analog output commons
HART communications port common
FIGURE 2-5 Electrical Connections
October 1998
UM348-1
INSTALLATION
'F2' SIGNAL COMMON is isolated from case ground, terminal 'B3'. Digital input commons are also isolated
from the station common and case ground.
In summary, the following terminals are tied to 'F2'(SIGNAL COMMON): 'F4', 'F8', 'F11', 'F14', 'E2', 'E6', 'E12',
and 'E14'.
Analog inputs must be voltage inputs. When a current input (e.g., 4 to 20 mA) is to be applied to the FIELDPAC,
a precision range resistor must be placed across the input terminals. A range resistor may not be required if the
input is wired in parallel with other 1 to 5 Vdc receiving instruments.
Refer to loop diagrams and determine if a range resistor is required. Supplied range resistors are 250 ohms for 4 to
20 mA inputs.
2.4.3.1 Power Connections
A. AC POWER INPUT CONNECTIONS (Model 348EA)
Terminal 'B1' is the AC supply HOT terminal.
Terminal 'A2' is the AC supply NEUTRAL terminal.
Terminal 'B3' is strapped to the instrument case and is the SAFETY GROUND terminal. It is usually
connected to earth ground or to the power distribution safety ground (Green wire). Power input wires should
be No. 14 AWG or heavier.
Refer to the “Power Requirements” section for permitted supply voltage range.
B. DC POWER INPUT CONNECTIONS (Model 348_D)
Terminal 'F1' is the +24 Vdc power supply terminal.
Terminal 'F2' is SIGNAL COMMON (power supply return).
Power input wires should be No. 14 AWG or heavier.
Refer to the “Power Requirements” section for permitted supply voltage range.
C. 2-WIRE TRANSMITTER SUPPLY OUTPUT (Model 348E only)
The 22 Vdc (nominal) power supply, rated at 80 mA maximum (short circuit protected), has its positive (+)
output connected to terminals ‘F6’, ‘F12’ (negative side is SIGNAL COMMON). These terminals can be used
to power up to three two-wire transmitters or be used to power the digital and pulse output circuits as long as
the total current is limited to less than 80 mA. The terminals should not be used power up both a two-wire
transmitter and a digital and pulse output circuit. Note that when an inductive load is switched, such as a relay,
it may cause a momentary drop in transmitter output or an unexpected reset of the Smart Transmitter.
October 1998
2-11
INSTALLATION
UM348-1
2.4.3.2 Signal Inputs And Outputs
A. ANALOG INPUTS
Each analog input is connected between an Analog Input (+) terminal and the Analog Input (-) terminal.
NOTE
Note that the Analog Input (-) terminals are internally connected to other SIGNAL
COMMONs (analog output, digital output, and HART port common terminals) and
should be connected to the user's instrument bus common. See Figure 2-6. Loop isolators
are suggested when connecting 4-wire transmitters.
All analog inputs are factory calibrated 1 to 5 Vdc. For mA inputs, a range resistor must be connected across
the analog input terminals. This precision (0.1%) resistor should be wire wound, 1/2 watt. Supplied range
resistors are 250 ohms: quantity 3.
NOTE
250Ω Resistor recommended. Total network resistance must be greater than 230Ω or less
than 1100Ω to support communication. A single 250Ω resistor is used when connected to
multiple 348s.
2-12
October 1998
UM348-1
INSTALLATION
Model 348 Terminals
250
F
HART +
3
HART -
4
+
Transmitter
F
Transmitter Supply
6
Analog Input +
7
Analog Input -
8
F
Transmitter Supply
MASTER
_
250
12
E
Digital Input +
7
Digital Input -
8
E
Switch
Load
Analog Output +
11
+
Analog Output -
12
_
X02946S2
Common Ground Bus
System Earth Ground
FIGURE 2-6 Model 348 Terminals
B. ANALOG OUTPUTS
Each analog output is connected between the Analog Output (+) terminal and the Analog Output (-) terminal.
Note that Analog Output (-) terminals are internally connected to other SIGNAL COMMONs (analog input,
HART port, and digital output common terminals) and should be connected to the user's instrument bus
common. See Figure 2-6.
Standard analog output is factory calibrated for 4 to 20 mAdc referenced to station common.
October 1998
2-13
INSTALLATION
UM348-1
C. DIGITAL INPUTS
Each digital input is connected between the Digital Input (+) terminal and Digital Input (-) terminal. The
Digital Input
(-) terminals are isolated from each other, from other SIGNAL COMMONs, and from the station case (safety
ground) terminal 'B3'. See Figure 2-6.
An inductive source, such as a relay coil, must be shunted by either a transient suppression diode or
resistor/capacitor suppression network to prevent damage to the FIELDPAC digital input circuit.
D. DIGITAL OUTPUTS
FIELDPACs have two open-collector type digital outputs. Each output is connected between a Digital Output
(+) terminal and a Digital Output (-) terminal. Each Digital Output (-) terminal is internally connected to other
SIGNAL COMMONs (analog input, analog output, and HART port common terminals) and should be
connected to the user's instrument bus common.
These two digital output circuits use open-collector NPN transistors referenced to station common (see
“Specifications” section). The load must limit current to 150 mA or less for each digital output (maximum
transistor rating). An inductive load must be shunted by either a transient suppression diode or resistor/capacitor suppression network to prevent damage to the FIELDPAC output circuit. See Figure 2-7.
The voltage source for the external output loads can be the XMTR Supply terminals 'F6', 'F9', or 'F12' (able
to provide a total of 80 mA maximum), or a heavier capacity external power supply.
A Model 348S FIELDPAC has, in addition to the two digital outputs above, two opto-isolated open-collector
NPN transistor output ports. OPTO1 is accessed via terminals 'D1' (-) and 'D2' (+). OPTO2 is accessed via
terminals 'C1' (-) and 'C2' (+). Refer to “Specifications” section for detailed operating characteristics.
A Model 348E FIELDPAC is additionally equipped with two SPDT relay output ports. Relay 1 COM
(Common) is accessed at terminal 'D1', Relay 1 NO (Normally Open) at 'D2', and Relay NC (Normally
Closed) at 'D3'. Similarly, Relay 2 COM is accessed at terminal 'C1', Relay 2 NO at terminal 'C2', and Relay
2 NC at terminal 'C3'. Refer to “Specifications” section for detailed relay operating characteristics.
2-14
October 1998
UM348-1
INSTALLATION
User Supplied Items
Station Terminals
Relay Load
DO+
I
ON
E1
= 100 mA MAX
Low
Transient Suppression
Diode, 1N4005 or Equiv.
ON/OFF
E2
DOC-
_
FB04
Voltage
DC
+ 10 to + 30 VDC
Power Supply
+
Relay
Common
G round
Bus
Digital Output
System Earth Ground
A. Relay Load and Us er Power Supply
Station Terminals
User Supplied Items
F6,9, or 12
+22 Vdc @
80mA MAX
DO+
Relay Load
E1
Low
ON/OFF
DOC-
Transient Suppression
Diode, 1N4005 or Equiv.
E2
Voltage
DC
Relay
FB04
Digital Output
B. Relay Load and Station +26V Power Supply
User Supplied Items
Station Terminals
Pull-Up Resistor
10K,1/2W
+
DO+
E1
IN
DOC-
E2
_
Solid State Alarm
Annunciator
ON/OFF
FB04
Digital Output
+24V DC
Power
Supply
Common
G round
Bus
System Earth Ground
C. Solid State Loads (E.G., Alarm Annuniciator)
X02945SA
FIGURE 2-7 Digital Output to Typical Loads
October 1998
2-15
INSTALLATION
UM348-1
E. PULSE OUTPUT
All FIELDPACs are equipped with an open-collector type pulse output. The pulse output is connected between
the 'E5' (Pulse Output +) terminal and the 'E6' (Pulse Output -) terminal. Note that the Pulse Output (-)
terminal is internally connected to other SIGNAL COMMONs (analog input, analog output, digital output, and
HART port common terminals) and should be connected to the user's instrument bus common.
The pulse output circuit uses an open-collector NPN transistor referenced to station common (see section 1.3
for specifications). The load must limit current to 150 mA or less for each digital output (maximum transistor
rating). An inductive load must be shunted by either a transient suppression diode or resistor/capacitor
suppression network to prevent damage to the FIELDPAC output circuit.
The voltage source for the external output loads can be the XMTR Supply terminals 'F6', 'F9', or 'F12' (able
to provide a total of 80 mA maximum), or a heavier capacity external power supply.
F. HART COMMUNICATION
The HART Communication Link is connected between 'F3' (HART +) terminal and 'F4' (HART -) terminal.
Note that the 'F4' (HART -) terminal is internally connected to other SIGNAL COMMONs (analog input,
analog output, pulse output, and digital output common terminals) and should be connected to the user's
instrument bus common. See Figure 2-6.
G. MILLIVOLT/THERMOCOUPLE/RTD INPUT
Model 348____T FIELDPACs are equipped with the Temperature Sensor Board which accepts Millivolt, T/C,
or RTD input signals. These signals are applied to terminal 'G2' (Input +) and 'G3' (Input -). The RTD
current source is available at terminal 'H2' (RTD I Source). All three of these terminals are isolated from
other SIGNAL COMMONs (analog inputs, analog output, digital output, pulse output, and HART port
common terminals). Refer to “Specifications” section for detailed operating characteristics. See Figure
2-8.
H
2
G
2
G
3
2 - Wire
RTD
H
2
G
2
G
3
3 - Wire
RTD
H
2
G
2
G
3
4 - Wire
RTD
No Connection
2 - Wire Connection
3 - Wire Connection
4 - Wire Connection
X02947S0
FIGURE 2-8 RTD Wiring Connections
2-16
October 1998
UM348-1
INSTALLATION
Figure 2-5 shows the terminal compartment with terminal assignments and comments. Detailed electrical
specifications are in section 1.3.
2.5 PNEUMATIC CONNECTIONS
Observe the following general guidelines when making pneumatic connections.
Blow out all piping before making connections.
Use pipe sealant sparingly and then only on the male threads. A non-hardening sealant is strongly
recommended.
Leak-test all fittings and tube connections. There must be no leaks in any of the tubing.
2.5.1 Pneumatic Inputs
Some FIELDPAC models are equipped with pneumatic inputs (see “Specification” section). When appropriate,
such pneumatic connections are made to the pneumatic ports marked 1, 2, and 3 on the right side of the
FIELDPAC. Figure 1-1 shows the location of these ports.
2.5.2 Pneumatic Outputs
Some FIELDPAC models are equipped with pneumatic outputs (see “Specification” section). When appropriate,
this pneumatic connection is made to port marked O (Output). An air supply must be connected to port S (Supply)
for the pneumatic output option to work. Figure 1-1 shows the exact location of these ports.
2.5.3 Direct Pressure Input
Direct pressure sensors are shown in Figures 1-2 and 2-9 through 2-13. A sensor mounts on a FIELDPAC
backplate. Figure 2-9 shows a Model 340D differential pressure sensor or a Model 340A or G sensor with a
tantalum diaphragm, used for absolute or gauge pressure measurement. Note the embossed arrow that points to the
high pressure port. Figure 2-10 shows the other Model 340A and G sensors. For detailed information about a
sensor, see GC340 or UM340-1.
October 1998
2-17
INSTALLATION
UM348-1
Keyed Connector
X03149P0
Retaining Screw Hole
O-Ring Groove
Snap Ring
End Cap
H
Vent/Drain Plug
Notes:
Process Connection
Block, 1/2 NPT
Tapped Hole
(See Note 1)
Process Connection
1/4 NPT
Tapped Hole
Embossed Arrow
Points To High
Pressure Port
7/16-20 Tapped
Hole, 8 Places
1. Process Connection Blocks can be rotated 180º to give the following
connection centers: 2.00 (50.1), 2.13 (54.1), or 2.25 (57.2).
Dimensions are in inches (millimeters).
2. Also shows Models 340A and 340G with tantalum diaphragms.
FIGURE 2-9 Model 340D Differential Pressure Sensor (See Note 2)
2-18
October 1998
UM348-1
INSTALLATION
Keyed Connector
Retaining Screw Hole
O-Ring Groove
Snap Ring
Capsule
Assembly
X03150S1
1/2 NPT Process
Inlet Connection
Note:
1. For a Model 340A or G with tantalum
diaphragms, see Figure 2.
FIGURE 2-10 Model 340A and Model 340G Pressure Sensors (See Note 1)
Figures 2-11, 12, and 13 show various piping arrangements. While the figures show a complete transmitter (i.e.,
housing and sensor), piping to the sensor is identical.
PRESSURE SENSOR IMPULSE PIPING RECOMMENDATIONS
Impulse piping is the piping to be connected to the sensor’s process connection(s). For suggested flow and level
measurement piping arrangements, refer to Figures 4, 5, and 6. If additional information is needed, order UM3401, User’s Manual for XTC Transmitters, Series 340 Pressure Transmitter-Controllers. UM340-1 from either your
local Moore representative or the factory.
Note the following when planning and installing piping.
•
•
Install impulse piping in accordance with ANSI Code B31.1.0.
Make impulse piping length as short as possible to reduce frictional loss and temperature-induced pressure
variations. However, when using impulse lines on a high temperature process, locate the Model 348 far enough
October 1998
2-19
INSTALLATION
•
•
•
•
•
•
•
•
•
UM348-1
away from the heat source to keep it within temperature specifications [10°C (50ºF) per foot cooling to a
normal ambient is assumed for uninsulated impulse lines].
For lines between the process and sensor, use impulse piping of 3/8" OD or larger to avoid friction effects
(causes lagging) and blockage.
Use the least number of fittings and valves possible to minimize leakage problems. Teflon® tape is the
recommended thread sealant for process connections at the sensor.
Valves used in pressure service should be either globe or gate type. Valves used in gas service should be of a
type that does not permit condensate to build up behind the valve.
Install sediment chambers with drain valves to collect solids suspended in process liquids or moisture carried
with non-condensing gases.
Install air chambers with vent valves at high point in piping to vent gas entrained in process liquid.
Remote diaphragm seals can be used to keep corrosive liquid or gas from the sensor’s pressure inlets and
isolation diaphragm [see ITT Conoflow Diaphragm Seals (PI34-6) for details].
Alternatively, use sealing fluid to isolate the process from the sensor. Sealing fluid must be of greater density
than process fluid and non-miscible.
For a sensor located above the process, slope piping from the FIELDPAC at least 1 inch/foot (83 mm/M) down
toward process. For a sensor below the process, slope piping at least 1 inch/foot (83 mm/M) up to process.
Protect pressure lines (by shielding if necessary) from objects or equipment that may bend or kink the line
causing fluid flow restriction.
Protect the pressure lines from extreme temperature ranges. Lines should be protected from freezing by
installing a heat trace.
A three-valve manifold should be used with a Model 340D sensor. A two-valve manifold can be used with a Model
340A or G sensor to permit servicing and zero checks.
2.6 FACTORY CALIBRATION
Unless a special calibration is ordered, the factory calibration is as follows:
Analog input function blocks....1 to 5 Vdc
Analog output function blocks...4 to 20 mA
Digital input and output ports do not require calibration.
Factory calibration of pneumatic I/O ports depends on the FIELDPAC model number (refer to Table 1-1 for exact
specifications).
The Millivolt/thermocouple/RTD input board option is factory calibrated for all thermocouple and RTD input
types. Calibration as stored on the Thermocouple/RTD board.
2-20
October 1998
UM348-1
INSTALLATION
2.7 CONFIGURATION
The station must be configured before it can be placed on-line. Refer to “Configuration” and “Function Block
Description” sections for configuration information.
Low
Pressure
Side
Low
Pressure
Side
Flow
High
Pressure
Side
High
Pressure
Side
Model 340D
Model 340D
3-Valve
Manifold
Flow
3-Valve
Manifold
Horizontal Main Line Flow
Transmitter Below Orifice - Preferred for Liquids and Steam
Horizontal Main Line Flow
Transmitter Above Orifice - Preferred for Gas Flow
High
Pressure
Side
Low
Pressure
Side
Low
Pressure
Side
Flow
Flow
Model 340D
High
Pressure
Side
3-Valve
Manifold
Model 340D
3-Valve
Manifold
Vertical Main Line Flow
Transmitter Below Orifice
Vertical Main Line Flow
Transmitter Above Orifice
X03038S0
FIGURE 2-11 Differential Flow Measurement Piping for
Gas and Liquid
October 1998
2-21
INSTALLATION
UM348-1
For gases,
mounting
above the line
is preferred.
Model 340A
Safety
Shut-Off
Valve
(Gas)
Shut-Off
Valve
Union
Safety Shut-Off
Valve (Steam or
Liquid)
For liquids and
steam, mounting
below the line
is preferred.
Model 340A
OR
Shut-Off
Valve
OR
Air Chamber
with Vent Valve.
Install at high
point to collect
air entrained
in liquids.
Safety
Shut-Off
Valve
(Gas)
Union
Suppressed-Zero Range
Non-Corrosive Dry Gases and Liquids
Safety Shut-Off
Valve (Liquid)
Elevated Zero-Range
Non-Corrosive Dry Gases and Liquids
Model 340A
Sediment Chamber
and Drain Valve.
Used to collect solids
in liquid suspension
or moisture carried
with non-condensing
gas.
Shut-Off
Valve
Union
Safety
Shut-Off
Valve
(Gas)
X03040S0
Safety Shut-Off
Valve (Liquid)
OR
Model 340A
Safety
Shut-Off
Valve
(Gas)
OR
Safety Shut-Off
Valve (Liquid)
Elevated Zero-Range Wet Gases (Non-Condensing)
and Liquids with Solids in Suspension
Dripleg with Drain Valve,
Used to collect solids in
liquid suspension or
moisture carried with
non-condensing gases.
Shut-Off
Valve
Union
Suppressed Zero-Range Wet Gases (Non-Condensing)
and Liquids with Solids in Suspension
FIGURE 2-12 Absolute or Gauge Pressure Measurement Piping
2-22
October 1998
UM348-1
INSTALLATION
Safety
Shut-Off
Valve
Filling Tee with
Hex Plug
Model 340A
Shut-Off
Valve
X03041S0
Drain
Valve
To Drain
FIGURE 2-13 Steam Service, Below the Line Mounting
n
October 1998
2-23
INSTALLATION
2-24
UM348-1
October 1998
UM348-1
OPERATION
3.0 OPERATION
This section describes the faceplate of the Moore FIELDPAC Field Mounted Controller. The faceplate consists of
a centrally located Liquid Crystal Display (LCD) area surrounded by a keypad overlay. An optional LED
backlight is available for faceplate illumination.
Some display elements and pushbuttons are used for both operation and configuration. This section describes their
use for station operation only. For information about the display elements and pushbuttons used for configuring the
FIELDPAC, refer to “Configuration” section.
Figure 3-1 identifies the display elements and pushbuttons explained in the following subsections.
3.1 FACEPLATE
3.1.1 Liquid Crystal Display Panel
The LCD panel contains several display elements which are described in the following subsections.
3.1.1.1 Multifunction Alphanumeric Display
The alphanumeric display at the top of the LCD consists of three sections. The left character is a 14-segment
alphanumeric that identifies the numeric display variable as a process (P), a setpoint (S), a valve (V), or an output
(O), and variables X and Y obtained via FB15. The ratio (R) from FB07, bias (B) from FB08, count (C),
multiplier (M), preset 1 (1), and preset 2 (2) all from FB16 are also identified by this character.
The second section of the alphanumeric display consists of a minus sign and six 8-segment digits (with decimal
point) which are used to display the numeric value of the variable. This part of the display is also used after
pressing the TUNE or ALARM pushbutton to prompt the user to select Loop 1 or Loop 2.
The last section of the display consists of four full-segment alphanumeric characters that indicate engineering units,
tag, or other descriptor. During normal operation, this portion of the display indicates the engineering units of the
displayed variable. This display shows status information primarily related to function block states.
* U1 and U2 are alphanumeric characters specified by parameters ‘HU1S’ and ‘HU2S’.
The display also shows the number of active status codes, e.g. H1*2 (indicates two conditions) or M1*3 (indicates
three conditions). The ACK (acknowledge) pushbutton is used to scroll through the status display. Once a status
condition is acknowledged, the status condition will be stacked behind the engineering units and can be viewed by
the operator using the ACK pushbutton. The four decimal points in the display window will blink when a status is
present.
The multifunction alphanumeric display is also used to view and select parameters during the configuration of the
FIELDPAC.
October 1998
3-1
OPERATION
UM348-1
TABLE 3-1 Status Information
STATUS CODE
A1, A2, A3, A4
A5, A6, A7, A8
H1, H2
L1, L2
OR
S1, S2
M1, M2
U1*, U2*
E
P1
P2
STATUS TYPE
Alarms
Alarms
High Limit
Low Limit
Override
Standby Sync
Emergency Manual
User Defined Status
Station Error
Totalizer Preset #1
Totalizer Preset #2
FUNCTION BLOCK
NUMBER
FB12
FB73
FB09, FB51
FB09, FB51
FB10
FB14
FB14
FB15
See Section 6.0, Maintenance
FB16
FB16
3.1.1.2 Setpoint And Process Vertical Bargraphs
The two 20-segment vertical bargraphs located in the center of the LCD are normally used to display the setpoint
(S) and process (P) variables in a 0 to 100% analog format, but can be configured to show different variables of the
user’s choice. The bargraphs can be configured to blink if an active alarm condition is encountered.
3.1.1.3 Valve or Output Horizontal Bargraph
A 20-segment horizontal bargraph at the bottom of the LCD is normally used to display either the valve position
(closed or open) or the controller output (0 to 100%). When the bargraph is programmed to indicate valve position,
it can be configured as direct (ATO) or reverse (ATC) acting.
3.1.1.4 PB1 And PB2 Triangle Indicators
Two triangle shaped LCD segments are provided for each PB1 and PB2 pushbutton.
When FB11 and/or FB23 is configured, these segments indicate the state (HI/LO) of the IS and ES status lines of
each function block. Refer to FB11 and FB23 specifications in section 8 for additional information.
3.1.1.5 AUTO/MAN Triangle Indicators
Two triangle shaped LCD segments are provided for the AUTO/MAN pushbutton. When FB14 and/or FB55 is
configured, these segments indicate the state of the MS status line of the function block(s). Refer to FB14 and
FB55 specifications in section 8 for additional information.
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OPERATION
3.1.2 Control Pushbuttons
Six large control pushbuttons are provided for the operator. Pushbuttons PB1, PB2, and AUTO/MAN are located
on the left side of the LCD panel; pushbuttons D, UP ARROW, and DOWN ARROW are on the right side. The
following subsections describe these pushbuttons in detail. Pushbuttons PB1 and PB2 can be customized for your
application. Request Model 348 FIELDPACTM Label Set for Customizing Faceplate Pushbuttons (AD348-1) from
your local Moore representative.
PB1
D
P-888888 ABCD
S
P
100
-80
--
PB2
60
-40
-20
AUTO
MAN
-0
CLOSED
0
ENTER
EXIT
CONF
TUNE
VALVE
OUT
OPEN
100
TAG
ACK
ALARM
STORE
STEP
UP
STEP
DOWN
A02475D0
FIGURE 3-1 Operator Controls and Signal Displays
3.1.2.1 PB1
Pushbutton PB1 is a SPDT switch that can be configured to operate as a momentary or as a sustained action
switch. FB23 is used to configure this switch. Two triangle indicator segments are provided next to the switch on
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the LCD panel to show resultant switch action (see “PB1 and PB2 Triangle Indicators” section). If PB1 is not
selected via the FB23 configuration (ESN=0), neither triangle segment is activated (visible).
3.1.2.2 PB2
Pushbutton PB2 is a SPDT switch that can be configured to operate as a momentary or as a sustained action
switch. FB11 is used to configure this switch. Two triangle indicator segments are provided next to the switch on
the LCD panel to show resultant switch action (see “PB1 and PB2 Triangle Indicators” section). If PB2 is not
selected via the FB11 configuration (ESN=0), neither triangle segment is activated (visible).
3.1.2.3 AUTO/MAN
Pushbutton AUTO/MAN is a SPDT switch that toggles the controller's status between Automatic and Manual.
FB14 is used to configure this switch. Two triangle indicator segments are provided next to the switch on the LCD
panel to show resultant switch action (see “PB1 and PB2 Triangle Indicators” section). If the Auto/Manual
Transfer Block is not selected via the FB14 or FB55 configuration (ESN=0), neither triangle segment is activated
(visible).
3.1.2.4 D
The D pushbutton controls what type of information is displayed on the Multifunction Alphanumeric Display.
Each discrete push of this switch advances the display to the next display category such as P (Process), S
(Setpoint), V (Valve), or other variables that may be configured.
With the FIELDPAC in configuration mode, pushing D will move the decimal point during floating point entry and
it will change cursor direction during ASCII character entry.
3.1.2.5 UP Arrow
The UP ARROW pushbutton is used to increase the value of the shown variable displayed on the Multifunction
Alphanumeric Display (if this variable is allowed to be adjusted). These variables can be such settings as the
setpoint, valve, output, tuning parameters, and alarm limits. Each discrete push of the button will increment the
least significant digit on the display. If the button is held down for two seconds or more, the value will increment at
an increased rate. The rate will accelerate up to a maximum the longer the button is held down.
3.1.2.6 DOWN Arrow
The DOWN ARROW pushbutton is used to decrease the value of the shown variable displayed on the
Multifunction Alphanumeric Display (if this variable is allowed to be adjusted). These variables can be such
settings as the setpoint, valve, output, tuning parameters, and alarm limits. Each discrete push of the button will
3-4
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OPERATION
decrement the least significant digit on the display. If the button is held down for two seconds or more, the value
will decrement at an increased rate. The rate will accelerate up to a maximum the longer the button is held down.
3.1.3 Dual-Function Pushbuttons
A row of five smaller pushbuttons is located directly below the LCD display panel. These pushbuttons have dual
functions. With the FIELDPAC in normal operating mode, these buttons provide the operator with some secondary
operating functions. With the FIELDPAC switched to the configuration mode, these buttons provide some
functions for configuring the FIELDPAC.
3.1.3.1 ENTER/EXIT CONF
This pushbutton allows the user to enter and exit the configuration mode of the FIELDPAC. Each discrete push of
this button toggles between "enter" and "exit".
3.1.3.2 TUNE/--->
With FIELDPAC in normal operating mode, this button permits quick access to FB13 and/or FB45 tuning
parameters. After pressing the TUNE/---> button, LOOP 1 is displayed in the digital display. The user can toggle
between LOOP 1 (FB13 Controller #1) and LOOP 2 (FB45 Controller #2) by pressing the TUNE/---> button
again. The controller parameters accessible from this function are SA*, SPG*, STI*, STd*, SdG*, SMR*, SHL*,
and SLL* where the * is 1 or 2 representing LOOP 1 or LOOP 2. Parameters SA1 and SA2, controller action, can
only be viewed in this mode. All the other parameters can be viewed and changed.
With the FIELDPAC in configuration mode, each push of this button shifts the cursor to the right to the next
parameter entry position until the end of the line where the cursor shifts back to the beginning again.
If the D pushbutton was used to change cursor direction during ASCII character entry, then the TUNE/-->
pushbutton will shift the cursor to the left.
3.1.3.3 TAG/STORE
With FIELDPAC in normal operating mode, a push of this button will cause the four character display to scroll
through the tag name of Loop 1, Loop 2, or both Loops. See FB15, Operator’s Display parameters, for more
information.
With the FIELDPAC in configuration mode, pressing this pushbutton will store the entered parameter in the
configuration data. The controller blocks (FB13 and FB45) are reinitialized each time a parameter is stored in
configuration mode.
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3.1.3.4 ACK/STEP UP
With FIELDPAC in normal operating mode, pressing this button will open the status window to view any active
status conditions or it will acknowledge any flashing status conditions.
With the FIELDPAC in configuration mode, each push of this button will step the configuration menu up one level.
3.1.3.5 ALARM/STEP DOWN
With FIELDPAC in normal operating mode, pressing this button permits the operator to quickly access the alarm
limits, deadband, and enable parameters associated with the alarm function blocks. After pressing the
ALARM/STEP DOWN button, LOOP 1 is displayed in the digital display. The user can toggle between LOOP 1
(FB12 alarm parameters) and LOOP 2 (FB73 alarm parameters) by pressing the TUNE/---> button. Once the
appropriated LOOP is selected, press the ALARM/STEP DOWN button to access the alarm parameters.
With the FIELDPAC in configuration mode, each push of this button will step the configuration menu down one
level.
3.2 OPERATING MODES
The operating modes required for any FIELDPAC operation are dependent upon the user configuration of the
station type and the control strategy. All typical operating modes for standard industrial controller types can be
configured for use by the FIELDPAC.
Refer to sections 7 and 8 for more detailed information on all the FIELDPAC functions and its configuration
procedure.
The AUTO/MAN (Automatic/Manual), PB1 and PB2 pushbutton mode switches are used to establish the
operating modes locally. Any combination of these switches can be configured for use. Each mode switch has a
corresponding function block from which the switch function or functions are selected.
3.3 DISPLAY TEST
Pushing the ENTER/EXIT CONF button followed by a push of the D button will activate all display segments of
the Liquid Crystal Display. A three-step test is automatically performed on the alphanumeric display to activate all
its segments. The two-button push sequence must be initiated when the Station is in the operating mode. If the
Station is in the configuration mode when the ENTER/EXIT CONF and the D pushbuttons are pressed, the Station
will exit configuration without performing a display test.
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OPERATION
3.4 PUSHBUTTON CARE
Pushbuttons should be pressed by a finger, an unused eraser on a pencil, or a stick eraser. Use of a hard
implement, such as the cap end of a pen, a blunt tool, or a fingernail, may deform the dome switch and result in
pushbutton failure.
3.5 CONTRAST ADJUSTMENT
The LCD display has a contrast adjustment located at the top left of the display circuit board as shown in Figure 32. To adjust the contrast, rotate the contrast pot clockwise to make the display darker until the ‘off’ segments start
to “ghost” on, then back off a quarter turn.
Upper Door
Captive Screws
4 Places
To Secure Door
Connector
Eject Lever
2 Places
Contrast
Adjustment
Multi-Color
Ribbon Cable
Display Interface Board
Membrane Keyboard Cable
X02898S0
FIGURE 3-2 Display Contrast Adjustment
n
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CALIBRATION
4.0 CALIBRATION
This section covers the calibration and calibration verification of the following function blocks (FBs) used in the
Moore FIELDPAC Field Mounted Controllers.
FB01
FB02
FB03
FB25
FB29
FB81
FB82
FB85
FB86
FB87
Analog Input #1
Analog Input #2
Analog Output #1 / I/P Module
Analog Input #3
Analog Output #2
Pressure Sensor
Temperature Sensor
Pneumatic Input #1
Pneumatic Input #2
Pneumatic Input #3
Function blocks dealing with digital I/O do not have to be calibrated.
4.1 GENERAL CONSIDERATIONS
FIELDPAC units are calibrated at the factory will not have to be recalibrated for most applications. However, for
critical applications, consider the following.
If a current to voltage conversion resistor (typically 250 ohm ±0.1%) is used at a particular analog input, that
precision resistor should remain with the Station, installed across those particular terminals, to eliminate the
voltage drop variation due to resistor tolerance. Use a precision current source for calibration.
Allow the FIELDPAC to warm-up for one hour prior to calibrating. The ambient temperature should be close
to its expected operating temperature.
Periodic calibration is not necessary. However, calibration and verification should be performed under any of the
following circumstances.
To check or change the calibration of a new or in-service FIELDPAC.
Upon replacing one of the following Boards: MPU Controller Board, or Pneumatic Input Board.
Upon the replacing or the repositioning of a Remote Pressure Sensor.
As part of a troubleshooting or failure confirmation routine.
Standard factory calibrations of the electrical analog input and output ports are listed in section 2.6. Standard
calibrations of the pneumatic input and output ports can be determined from Table 1-1, Model Designation.
Specifications can be found in “Specification” section.
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A FIELDPAC is equipped with lockout switches which must be set to 'enabled' before certain calibration and
configuration procedures can be performed. Refer to section 4.3, Lockout Switches, to enable the needed modes.
Calibration requires that each involved function block (FB) be assigned an execution sequence number (ESN). It
can be any non-zero number. This procedure is described in section 4.4, ESN Assignment.
The bargraphs on the Display Assembly are not used during calibration. Ignore any bargraph indications.
Verify a FIELDPAC's model number and power input requirement before applying power. A FIELDPAC must be
off-line during calibration.
4.2 REQUIRED EQUIPMENT
Calibration of the FIELDPAC requires the use of some or all of the following test equipment:
1. A precision voltage source capable of supplying 0.000 to 5.000 Vdc for calibrating analog input function
blocks.
2. A precision current source capable of supplying 0.000 to 20.00 mAdc for calibrating analog inputs. Precision
range resistors must be connected across input terminals.
3. A precision milliammeter capable of displaying 4.000 to 20.00 mAdc for calibrating the analog output function
blocks.
OR
An electronic calibrator that combines the needed functions of the three instruments above.
4. A precision millivolt calibration source for required millivolt calibration range. The signal source must be
adjustable to an accuracy of ±0.01% or better and provide a source resistance of 100 or less.
5. A precision resistance decade box with a range of 0 to 2000 ohms in steps of 5 ohms maximum. This decade
box is used to calibrate the RTD input of the temperature sensor function block 82.
6. A precision test gauge with a 0 - 30 psig range and 0.02 psi per division resolution. This gauge is for
calibration and verification of the pneumatic input function blocks.
7. A regulated air supply, consisting of an adjustable (0 - 30 psig) pressure regulator and necessary tubing,
fittings, and valves. A Moore Model 40-30 or 41-30 Nullmatic® Pressure Regulator is recommended. This air
supply is for use with item 6 above.
8. A vacuum pump capable of providing a vacuum of 0.5 psig (minimum) is required for the mounting position
zero shift calibration of an absolute Pressure Sensor.
Select the required equipment from the above list and make it available for the planned calibration procedure.
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CALIBRATION
4.3 LOCKOUT SWITCHES
Five Lockout Switches are located at the top center of the MPU Controller Board as shown in Figure 5-3. The
following configuration modes can be locked out or enabled.
'SOFT' 'ALARM' 'TUNE' 'H/T/F' 'CAL' -
Soft configuration parameter settings
Alarm configuration settings
Autotune parameter settings
Hard configuration, ESN, and FCO settings
Calibration parameter settings
The lockout switches are factory set to lockout (disable) the above listed modes. This prevents inadvertent
changing of calibration and other configuration parameters from the front panel. To gain access to and set any of
the lockout switches, perform the following steps:
1. Open the top front cover (with the display panel) to reveal the MPU Controller Board. It will be necessary to
unscrew a captive screw in each corner of the front cover.
2. Refer to Figure 5-3 to locate the desired switch.
3. Press the RIGHT side of the switch to ENABLE the particular configuration mode.
4. Press the LEFT side of switch to LOCK OUT that configuration mode.
5. After setting all the desired lockout switches, close and secure (four screws) the front cover.
4.4 ESN ASSIGNMENT
Calibration and configuration procedures require that each involved function block (FB) be assigned an execution
sequence number (ESN). Use the following procedure to assign an ESN to each function block that will be used in
a subsequent calibration or configuration procedure. The following procedure is also useful for viewing, changing,
or deleting (setting to zero) a previously assigned ESN.
1. Verify FIELDPAC's input power requirement. Apply power to FIELDPAC.
2. Ensure that the 'H/T/F' lockout switch is in the 'enabled' position. Refer to “Lockout Switches” section and
Figure 5-3 to perform this task, if necessary.
3. Press ENTER/EXIT CONF pushbutton to enter configuration mode at the MENU level.
4. Push the DOWN/ARROW pushbutton to select 'T' (Table) on left digit position of alphanumeric display. (If
'TX' appears in the display, the 'H/T/F' lockout switch on the MPU Controller Board must be enabled, see
“Lockout Switches” section).
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5. Press ALARM/STEP DOWN pushbutton to enter FUNCTION BLOCK level.
6. Push the UP/ARROW or DOWN/ARROW pushbutton to select the desired function block number as
displayed on the right side digits of alphanumeric display.
7. Press ALARM/STEP DOWN pushbutton to enter PARAMETER level. The alphanumeric display should
show 'ESN' to the right of the already displayed 'T'. To the left of 'TESN' (in the center section of the display)
will appear the currently assigned ESN.
8. Push the UP/ARROW or DOWN/ARROW pushbutton to select the desired ESN appearing in the center
section of the display. It can be any positive whole number above 00. Use an ESN of 00 only to delete a
function block from the configuration.
9. Press the TAG/STORE pushbutton to store the selected ESN.
10. Press the ACK/STEP UP pushbutton to get back to the FUNCTION BLOCK level and perform steps 6
through 9 for the next needed function block. When all required ESN assignments have been completed, press
the ENTER/EXIT CONF pushbutton to exit the configuration mode.
4.5 ANALOG INPUTS AND OUTPUTS (FB01, FB02, FB03, FB25, FB29)
FIELDPAC analog input and analog output functions are factory calibrated: inputs, 1 to 5 Vdc; outputs, 4-20
mAdc. If calibration is necessary, use the following procedure.
Before proceeding with the calibration, refer to:
• “General Considerations” section for some general considerations.
• Obtain the necessary equipment from the list given in “Required Equipment” section
• Enable the appropriate lockout switches described in the “Lockout Switches” section.
1. Allow the FIELDPAC to warm-up for one hour prior to calibrating. The ambient temperature should be close
to its expected operating temperature.
2. Ensure that the 'CAL' lockout switch is in the 'enabled' position. Refer to “Lockout Switches” section and
Figure 5-3 to perform this task, if necessary.
3. Press ENTER/EXIT CONF pushbutton to enter configuration mode at the MENU level.
4. Push the UP/ARROW or DOWN/ARROW pushbutton to select 'C' (calibration) on left digit position of
alphanumeric display. (If 'CX' appears in the display, the lockout switch on the MPU Controller Board must
be enabled, see “Lockout Switches” section).
5. Press ALARM/STEP DOWN pushbutton to enter FUNCTION BLOCK level.
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CALIBRATION
6. Push the UP/ARROW or DOWN/ARROW pushbutton to select desired analog input or analog output function
block number on the right side digits of alphanumeric display. Refer to Table 4-1.
7. At FIELDPAC's terminals associated with the selected function block (see Table 4-1), connect either a voltage
source (A) or a milliammeter (B):
A. Precision voltage source for analog input calibration:
Connect to the appropriate analog input terminals. Ensure that terminal screws are tight.
B. Precision milliammeter for analog output calibration:
Connect to the appropriate analog output terminals. Ensure that terminal screws are tight.
8. Press ALARM/STEP DOWN pushbutton to enter PARAMETER level.
9. Push the UP/ARROW or DOWN/ARROW pushbutton to select desired parameter (e.g., 'CZI1' for zero input
1, 'CZO1' for zero output 1, etc.). Parameter is indicated on alphanumeric display. See Table 4-1.
10. Press ALARM/STEP DOWN pushbutton to enter VALUE level ('CAL' should appear in the center section of
the display).
11. For calibration, perform either A or B depending upon function block selected in step 6.
A. Analog Input:
1) Set precision voltage source to desired zero input value (0.000 to 1.000 Vdc).
2) Wait at least 15 seconds, then press TAG/STORE pushbutton to store the zero input value.
3) Press ACK/STEP UP pushbutton to get back to PARAMETER level.
4) Push the UP/ARROW or DOWN/ARROW pushbutton to select full scale parameter ('CFI1' for full
scale input 1, 'CFI2' for full scale input 2, etc.).
5) Press the ALARM/STEP DOWN pushbutton to enter VALUE level ('CAL' should appear in the center
section of the display).
6) Set voltage source to desired full scale input value (4.000 to 5.000 Vdc).
7) Wait at least 15 seconds, then press TAG/STORE pushbutton to store the full scale value.
8) Proceed to step 12.
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B. Analog Output
1) Push the UP/ARROW or DOWN/ARROW pushbutton to set zero output to 4.000 mA on digital
multimeter or electronic calibrator.
2) Wait at least 15 seconds, then press TAG/ STORE pushbutton to lock-in desired value.
3) Press ACK/STEP UP pushbutton.
4) Push the UP/ARROW or DOWN/ARROW pushbutton ('CFO1' for full scale output 1 or 'CFO2' for
full scale output 2).to select full scale parameter for the selected function block.
5) Press the ALARM/STEP DOWN pushbutton to enter VALUE level ('CAL' should appear in the center
section of the display).
6) Push the UP/ARROW or DOWN/ARROW pushbutton to set full scale output to 20.00 mA on digital
multimeter or electronic calibrator.
7) Wait at least 15 seconds, then press TAG/STORE pushbutton to store desired value.
12. To verify calibration, proceed to step 13. Verification is always recommended. If verification is not desired,
proceed to step 14.
13. For verification, perform either A or B depending upon function block selected in step 6.
A. Analog Input
1) Press ACK/STEP UP pushbutton to get back to PARAMETER level.
2) Push the UP/ARROW or DOWN/ARROW pushbutton to select verification parameter (e.g., 'CVI1' to
verify input 1, 'CVI2' for input 2, etc.). Parameter is shown on alphanumeric display. See Table 4-1.
3) Press ALARM/STEP DOWN pushbutton to enter VALUE level.
4) Set precision voltage source to zero input voltage value. The center section of the display should read
0.00% of input (tolerance: ±0.05%).
5) Set the voltage source to full scale input voltage value. The center section of the display should read
100.0% of input (tolerance: ±0.05%).
6) Proceed to step 14.
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CALIBRATION
TABLE 4-1 Analog I/O Calibration Parameters
FUNCTION
BLOCK
ANALOG
CHANNEL
CALIBRATION
PARAMETERS
ASSOCIATED
TERMINALS
01
Input 1
CZI1 - Zero, Input #1
CFI1 - Full Scale, Input #1
CVI1 - Verify Input #1
F7(+), F8(-)
02
Input 2
CZI2 - Zero, Input #2
CFI2 - Full Scale, Input #2
CVI2 - Verify Input #2
F10(+), F11(-)
25
Input 3
CZI3 - Zero, Input #3
CFI3 - Full Scale, Input #3
CVI3 - Verify Input #3
F13(+), F14(-)
03
Output 1
CZO1 - Zero, Output #1
CFO1 - Full Scale, Output #1
CVO1 - Verify Output #1
E11(+), E12(-)
29
Output 2
CZO2 - Zero, Output #2
CFO2 - Full Scale, Output #2
CVO2 - Verify Output #2
E13(+), E14(-)
B. Analog Output
1) Press ACK/STEP UP button to get back to PARAMETER level.
2) Push the UP/ARROW or DOWN/ARROW pushbutton to select verification parameter (e.g., 'CVO1'
verify analog output 1 or 'CVO2' for output 2). See Table 4-1.
3) Press ALARM/STEP DOWN pushbutton to enter VALUE level.
4) Push the UP/ARROW or DOWN/ARROW pushbutton to set the center section of the display to
0.00%. Output current should be 4.00 mA. (Acceptable tolerance: ±0.1%)
5) Push the UP/ARROW or DOWN/ARROW pushbutton to set 100.00%. Output current should read
20.00 mA. (Acceptable tolerance: ±0.1%)
6) Proceed to step 14.
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14. Select one of the following:
If all points have been calibrated and verified, press ENTER/EXIT CONF pushbutton to leave the calibration
mode and enter operation mode.
If additional function blocks are to be calibrated and verified, press ACK/STEP UP button twice to enter
FUNCTION BLOCK level. Perform steps 6 through 13 for each function block to be calibrated and verified.
15. Having finished calibrating and verifying all the required function blocks, it is prudent to lock out the
FIELDPAC's calibration mode via the MPU Controller Board's 'CAL' lockout switch.
This completes the calibration and verification procedure of the FIELDPAC's analog input and output functions.
4.6 PRESSURE SENSOR INPUT (FB81)
A Pressure Sensor may be installed in a FIELDPAC. Configuration of such a unit is handled by function block 81.
These units are normally factory calibrated and configured to operate in the digital mode.
For most applications, recalibration of the factory-set pressure range will not be necessary. However, the mounting
position zero shift calibration should be performed with the pressure sensor oriented in the expected field operating
position.
The following subsections describe the mounting position zero shift calibration (see “Mounting Position Zero Shift
Calibration” section) and an input pressure verification procedure ( see “Calibration Verification” section).
4.6.1 Mounting Position Zero Shift Calibration
A slight zero shift will occur when a Pressure Sensor is installed and used in a different orientation than it was
calibrated. The following calibration procedure corrects this shift.
Before proceeding with the calibration, refer to:
• “General Considerations” section for some general considerations.
• Obtain the necessary equipment (if needed) from the list given in the “Required Equipment” section.
• Enable the appropriate lockout switches described in “Lockout Switches” section
• Assign to FB81 a valid execution sequence number (ESN) as described in “ESN Assignment” section.
1. Orient the FIELDPAC with the attached Pressure Transmitter in the expected field operating position. With a
FIELDPAC using a Remote Pressure Transmitter, only the Pressure Transmitter has to be oriented in the
operating position.
2. Verify FIELDPAC's input power requirement. Apply power to the FIELDPAC. Allow the FIELDPAC and its
connected Pressure Transmitter to warm-up for ten minutes before performing the zero shift calibration. The
ambient temperature should be close to its expected operating temperature.
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CALIBRATION
3. Perform the following to the input pressure port of the Transmitter:
A. If it is a Absolute Pressure Transmitter sensor, connect a vacuum pump and draw a vacuum down to 0.5
psig minimum.
B. If it is a D/P or Gage Pressure Transmitter sensor, disconnect any pressure tubing from the input port of
the Transmitter, leaving it at atmospheric pressure.
4. Ensure that the 'CAL' lockout switch is in the 'enabled' position. Refer to “Lockout Switches” section and
Figure 5-3 to perform this task, if necessary.
5. Press ENTER/EXIT CONF pushbutton to enter configuration mode at the MENU level.
6. Push the DOWN/ARROW pushbutton to select 'C' (calibration) on left digit position of alphanumeric display.
(If 'CX' appears in the display, the lockout switch on the MPU Controller Board must be enabled, see “Lockout
Switches” section).
7. Press ALARM/STEP DOWN pushbutton to enter FUNCTION BLOCK level.
8. Push the UP/ARROW or DOWN/ARROW pushbutton to select function block number 81 in the right side
digits of alphanumeric display.
9. Press ALARM/STEP DOWN pushbutton to enter PARAMETER level. The alphanumeric display should
show 'CMP' which stands for calibration of mounting position. Use UP/ARROW or DOWN/ARROW
pushbuttons to make this selection if necessary.
10. Press ALARM/STEP DOWN pushbutton to enter VALUE level. The alphanumeric display should show 'CAL
CMP'.
11. Press the TAG/STORE pushbutton to complete the mounting position zero shift calibration. The 'CAL' display
will blink momentarily.
12. Press the ENTER/EXIT CONF pushbutton to leave the configuration mode.
13. Lock out the FIELDPAC's calibration mode via the MPU Controller Board's 'CAL' lockout switch.
This completes the mounting position zero shift calibration procedure.
4.6.2 Pressure Sensor Calibration Verification
The calibration of a Pressure Sensor connected to the FIELDPAC can be verified by the following procedure.
1. Check FIELDPAC's input power requirement. Apply power to the FIELDPAC. Allow the FIELDPAC and its
connected Pressure Transmitter to warm-up for ten minutes before performing the calibration verification. The
ambient temperature should be close to its expected operating temperature.
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2. Connect a precision pressure source (capable of producing the necessary pressure calibration points) to the
Pressure Sensor being verified.
3. Ensure that the 'CAL' lockout switch is in the 'enabled' position. Refer to “Lockout Switches” section and
Figure 5-3 to perform this task, if necessary.
4. Press ENTER/EXIT CONF pushbutton to enter configuration mode at the MENU level.
5. Push the DOWN/ARROW pushbutton to select 'C' (calibration) on left digit position of alphanumeric display.
(If 'CX' appears in the display, the lockout switch on the MPU Baseboard must be enabled, see “Lockout
Switches” section).
6. Press ALARM/STEP DOWN pushbutton to enter FUNCTION BLOCK level.
7. Push the UP/ARROW or DOWN/ARROW pushbutton to select function block 81 in the right-side digits of the
alphanumeric display.
8. Press ALARM/STEP DOWN pushbutton to enter PARAMETER level.
9. Press the UP/ARROW pushbutton to select the 'CVIP' parameter on alphanumeric display.
10. Press ALARM/STEP DOWN pushbutton to enter VALUE level. A digital value of the applied pressure
should appear in the center (numeric) section of the display, just to the left of 'CVIP'.
11. Set the precision pressure source to the desired low, mid-range, and high calibration points and check the
reading on the center section of the alphanumeric display. The reading is in % of calibrated range as set per
FB81 parameters SMVL, SMVH, and SMVU
12. After completing the calibration verification, press the ENTER/EXIT CONF pushbutton to leave the
calibration verification mode.
13. Lock out the FIELDPAC's calibration mode via the MPU Controller Board's 'CAL' lockout switch (see
“Lockout Switches” section).
This completes the calibration verification procedure. If the verification results show that a recalibration is
necessary, the Pressure Transmitter sensor should be replaced.
4.7 TEMPERATURE SENSOR INPUT (FB82)
The FIELDPAC may be equipped with a Temperature Sensor Board which can be configured to accept millivolt,
thermocouple, or RTD inputs. Configuration of such a FIELDPAC is handled by Function Block 82.
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CALIBRATION
These units are calibrated at the factory. The calibration data is stored on the Temperature Sensor Board
IMPORTANT
Temperature Board is factory calibrated using precision equipment. Do not
calibrate unless board fails verification.
To change and/or verify the configuration and calibration parameters, follow the procedures outlined in the
following subsections.
Before proceeding with the calibration, refer to:
• “Calibration section 4.1 for some general considerations
• Obtain the necessary equipment from the list given in “Required Equipment” section
• Enable the appropriate lockout switches described in “Lockout Switches” section
• Assign to FB82 a valid execution sequence number (ESN) as described in “ESN Assignment” section.
4.7.1 Selecting Input Type (MV, T/C, OHM, or RTD)
A FIELDPAC equipped with a Temperature Sensor Board can be configured to accept 18 types of input signals.
Use the following procedure to set the required input type or to determine the current input configuration.
1. Verify FIELDPAC's input power requirement. Apply power to the FIELDPAC.
2. Ensure that the 'H/T/F' lockout switch is in the 'enabled' position. Refer to “Lockout Switches” section and
Figure 5-3 to perform this task, if necessary.
3. Ensure that an ESN has been assigned to function block 82. Refer to “ESN Assignment: section to perform
this task, if necessary.
4. Press ENTER/EXIT CONF pushbutton to enter configuration mode at the MENU level.
5. Push the DOWN/ARROW pushbutton to select 'H' (Hard Configuration) on left digit position of alphanumeric
display. (If 'HX' appears in the display, the 'H/T/F' lockout switch on the MPU Controller Board must be
enabled, see “Lockout Switches” section).
6. Press ALARM/STEP DOWN pushbutton to enter FUNCTION BLOCK level.
7. Push the UP/ARROW or DOWN/ARROW pushbutton to select function block number 82 on the right side
digits of alphanumeric display.
8. Press ALARM/STEP DOWN pushbutton to enter PARAMETER level.
9. Push the UP/ARROW or DOWN/ARROW pushbutton until 'HIT' appears on the right side of the
alphanumeric display.
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10. Press ALARM/STEP DOWN pushbutton to enter VALUE level.
11. Push the UP/ARROW or DOWN/ARROW pushbutton to select the Input Type. It can be a number from 00 to
17 appearing on the center (numeric) section of the display. Calibration is performed using types 00, 05, 10,
and 13 depending on the type of T/C or RTD being used. Refer to Table 4-2.
12. Press the TAG/STORE pushbutton to lock-in the desired input type.
13. Press the ENTER/EXIT CONF pushbutton to leave the hard configuration mode.
This completes the selection of the input type for the Temperature Sensor Board.
TABLE 4-2 Input Types And Calibration Values
TYPE NO.
0
5
10
13
DESCRIPTION
Narrow Millivolt
(Used when calibrating for
Thermocouple Type R, S, T, or B)
Wide Millivolt
(Used when calibrating for
Thermocouple Type J, K, E, or N)
Narrow Ohm
(Use when calibrating for RTD
DIN 100, or RTD US 100)
Wide Ohm
(Used when calibrating for RTD
DIN 200, RTD DIN 500, RTD US
200, or RTD US 500)
CALIBRATION VALUE
ZERO
FULL SCALE
-11 mV
+26 mV
-18 mV
+103 mV
0
470
0
1875
4.7.2 Specifying Measured Variable Units
A FIELDPAC equipped with a Temperature Sensor Board must be configured to display specific Measured
Variable Units (MVUs) listed in Table 4-3. Use the following procedure to set the desired MVUs to be displayed.
1. Verify FIELDPAC's input power requirement. Apply power to the FIELDPAC.
2. Insure that the 'SOFT' lockout switch is in the 'enabled' position. Refer to “Lockout Switches” section and
Figure 5-3 to perform this task, if necessary.
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CALIBRATION
3. Insure that an ESN has been assigned to function block 82. Refer to “ESN Assignment” section to perform this
task, if necessary.
4. Press ENTER/EXIT CONF pushbutton to enter configuration mode at the MENU level.
5. Push the DOWN/ARROW pushbutton to select 'S' (Soft Configuration) on left digit position of alphanumeric
display. (If 'SX' appears in the display, the 'SOFT' lockout switch on the MPU Controller Board must be
enabled, see “Lockout Switches” section).
6. Press ALARM/STEP DOWN pushbutton to enter FUNCTION BLOCK level.
7. Push the UP/ARROW or DOWN/ARROW pushbutton to select function block number 82 in the right side
digits of alphanumeric display.
8. Press ALARM/STEP DOWN pushbutton to enter PARAMETER level.
9. Push the DOWN/ARROW pushbutton until 'SMVU' appears on the right side of the alphanumeric display.
10. Press ALARM/STEP DOWN pushbutton to enter VALUE level.
11. Push the UP/ARROW or DOWN/ARROW pushbutton to select the Measured Variable Units. It can be a
number from 32 to 37 appearing on the center (numeric) section of the display. Refer to Table 4-3 for the six
available Measured Variable Units.
12. Press the TAG/STORE pushbutton to lock-in the desired MVU.
13. Press the ENTER/EXIT CONF pushbutton to leave the soft configuration mode.
This completes the selection of the Measured Variable Units (MVUs) for the Temperature Sensor Board.
TABLE 4-3 List of Measured Variable Units
MVU NO.
October 1998
DESCRIPTION
32
degrees Celsius
33
degrees Fahrenheit
34
degrees Rankine
35
Kelvin
36
Millivolts
37
Ohms
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4.7.3 Millivolt Input Calibration
A FIELDPAC equipped with a Temperature Sensor Board can be calibrated to accept a narrow or a wide millivolt
input range. Calibration of the FIELDPAC for millivolt inputs is handled by function block 82.
The complete calibration procedure entails selecting either the Narrow Millivolt or Wide Millivolt input type
(Number 00 or 05, respectively), described in section 4.7.1, and carrying out the calibration steps listed below.
Before proceeding with the calibration, refer to:
• “General Considerations” section for some general considerations.
• Obtain the necessary equipment from the list given in “Required Equipment” section
• Enable the appropriate lockout switches described in “Lockout Switches” section
• Assign to FB82 a valid execution sequence number (ESN) as described in “ESN Assignment” section.
1. Verify FIELDPAC's input power requirement. Apply power to the FIELDPAC.
2. Allow the FIELDPAC to warm-up for one hour prior to calibrating. The ambient temperature should be close
to its expected operating temperature.
3. Insure that the 'CAL' lockout switch is in the 'enabled' position. Refer to “Lockout Switches” section and
Figure 5-3 to perform this task, if necessary.
4. Insure that an ESN has been assigned to function block 82. Refer to “ESN Assignment” section to perform this
task, if necessary.
4.a Insure that function block 82 has been configured for either the Narrow Millivolt or Wide Millivolt input type
in accordance with the intended application.
For calibrating the Narrow Millivolt input type, the input type number should be set to 00.
For calibrating the Wide Millivolt input type, the input type number should be set to 05.
Refer to sections 4.7.1 and 4.7.2 to perform this task, if necessary.
5. Connect the precision millivolt source to FIELDPAC's optional I/O terminals G2 (+) and G3 (-).
Refer to Figure 4-1 for a typical calibration hook-up diagram and to Figure 2-5 for the physical location of the
optional I/O terminals.
Get lengths of No. 18 or No. 16 AWG insulated copper wire just long enough to conveniently locate the
millivolt source near the FIELDPAC.
Turn off power to the millivolt source.
Make solid, low resistance connections. Do not use alligator or similar clips for connections. Observe polarity
as indicated.
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6. Press ENTER/EXIT CONF pushbutton to enter configuration mode at the MENU level.
7. Push the DOWN/ARROW pushbutton to select 'C' (calibration) on left digit position of alphanumeric display.
(If 'CX' appears in the display, the lockout switch on the MPU Controller Board must be enabled, see section
4.3).
8. Press ALARM/STEP DOWN pushbutton to enter FUNCTION BLOCK level.
MODEL 348
Preciaion
Millivolt
Source
mV
G2
+
G3
_
Optional I/O
Terminals
+
_
Insulated
Copper
Wires
X02948S0
FIGURE 4-1 Thermocouple and Millivolt Input Calibration Wiring
9. Push the UP/ARROW or DOWN/ARROW pushbutton to select function block number 82 on the right side
digits of alphanumeric display.
10. Press ALARM/STEP DOWN pushbutton to enter PARAMETER level.
11. Push the UP/ARROW or DOWN/ARROW pushbutton to select desired Zero parameter ('CWMZ' for wide
millivolt zero or 'CNMZ' for narrow millivolt zero).
12. Press ALARM/STEP DOWN pushbutton to enter VALUE level ('CAL' should appear in the center section of
the display).
13. Refer to Table 4-2 to obtain value in millivolts under Zero column for the type of millivolt input (Narrow or
Wide) selected in “Selecting Input Type” section.
14. Set the millivolt source to the Zero value obtained in previous step.
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15. Wait at least 15 seconds, then press TAG/STORE pushbutton to lock-in the Zero value. Wait until 'CAL' in
the center display blinks - this indicates that the Zero value was stored successfully.
16. Press ACK/STEP UP pushbutton to get back to PARAMETER level.
17. Push the UP/ARROW or DOWN/ARROW pushbutton to select desired Full Scale parameter ('CWMF' for
wide millivolt full scale or 'CNMF' for narrow millivolt full scale). This selection must agree with the input
type selection made in section 4.7.1. Parameter is indicated on alphanumeric display.
18. Press the ALARM/STEP DOWN pushbutton to enter VALUE level ('CAL' should appear in the center section
of the display).
19. Refer to Table 4-2 to obtain the value in millivolts under Full Scale column for the type of millivolt input
(Narrow or Wide) selected in “Selecting Input Type” section.
20. Set the millivolt source to Full Scale value obtained in previous step.
21. Wait at least 15 seconds, then press TAG/STORE pushbutton to lock-in the Full Scale value. Wait until 'CAL'
in the center display blinks - this indicates that the Full Scale value was stored successfully.
22. To verify calibration, proceed to step 23. Verification is always recommended. If verification is not desired,
proceed to step 28.
23. Press ACK/STEP UP pushbutton to get back to PARAMETER level.
24. Push the UP/ARROW or DOWN/ARROW pushbutton to select Verification parameter 'CVIP'. Parameter is
shown on alphanumeric display.
25. Press ALARM/STEP DOWN pushbutton to enter VALUE level.
26. Set precision millivolt source to Zero value (see step 13). The center (numeric) section of the display should
read 0.00% of the scaled Zero input value (tolerance: ±0.05%).
27. Set precision millivolt source to Full Scale value (see step 19). The center (numeric) section of the display
should read 100.0% of the scaled Full Scale input value (tolerance: ±0.05%).
28. After completing the calibration or calibration verification, press the ENTER/EXIT CONF pushbutton to leave
the calibration mode.
29. Lock out the FIELDPAC's calibration mode via the MPU Controller Board's 'CAL' lockout switch.
This completes the calibration and calibration verification procedure. If the verification results show that a
recalibration is necessary, perform steps 1 through 29 again.
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4.7.4 Thermocouple Input Calibration
A FIELDPAC equipped with a Temperature Sensor Board can be calibrated to accept a variety of thermocouple
types as shown in Table 4-2. Calibration of the FIELDPAC for any of the listed thermocouple types is handled by
FB82.
The complete calibration procedure entails selecting either the Narrow Millivolt or Wide Millivolt input type
(Number 00 or 05, respectively), described in “Selecting Input Type” section, and carrying out the calibration steps
listed below.
The actual operating temperature range is entered as a soft 'S' configuration parameter after the calibration is
completed. Once the FIELDPAC's thermocouple input is calibrated, FB82 Block Output 98 will produce a scaled
and linearized signal using the values entered in the soft configuration so that the 0-100% signal will represent a
specific operating temperature range. Refer to “Configuration” section for a detailed configuration procedure.
Before proceeding with the calibration, refer to:
• “General Considerations” section for some general considerations
• Obtain the necessary equipment from the list given in “Required Equipment” section
• Enable the appropriate lockout switches described in “Lockout Switches” section
• Assign to FB82 a valid execution sequence number (ESN) as described in “ESN Assignment” section.
1. Verify FIELDPAC's input power requirement. Apply power to the FIELDPAC.
2. Allow the FIELDPAC to warm-up for one hour prior to calibrating. The ambient temperature should be close
to its expected operating temperature.
3. Ensure that the 'CAL' lockout switch is in the 'enabled' position. Refer to “Lockout Switches” section and
Figure 5-3 to perform this task, if necessary.
4. Ensure that an ESN has been assigned to function block 82. Refer to “ESN Assignment” section to perform
this task, if necessary.
4.a Insure that function block 82 has been configured for either the Narrow Millivolt or Wide Millivolt input type
in accordance with the intended thermocouple type.
For calibrating thermocouple types ‘R,’ ‘S’, ‘T,’ and ‘B,’ the input type number should be set to 00.
For calibrating thermocouple types ‘J,’ ‘K’, ‘E,’ and ‘N,’ the input type number should be set to 05.
Refer to “Selecting Input Type” section and “Specifying Measured Variable Units” section to perform this task,
if necessary.
5. Connect the precision millivolt source to FIELDPAC's optional I/O terminals G2 (+) and G3 (-). Refer to
Figure 4-1 for a typical calibration hook-up diagram and to Figure 2-5 for the physical location of the optional
I/O terminals. Use No. 18 or No. 16 AWG insulated copper wires just long enough to conveniently locate the
millivolt source near the FIELDPAC. Observe polarity as indicated. (Power off at the millivolt source.) Make
sure all connections are solid, low resistance connections. Do not use alligator or similar clips for connections.
October 1998
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CALIBRATION
UM348-1
6. Press ENTER/EXIT CONF pushbutton to enter configuration mode at the MENU level.
7. Push the DOWN/ARROW pushbutton to select 'C' (calibration) in left digit position of alphanumeric display.
(If 'CX' appears in the display, the lockout switch on the MPU Controller Board must be enabled, see “Lockout
Switches” section).
8. Press ALARM/STEP DOWN pushbutton to enter FUNCTION BLOCK level.
9. Push the UP/ARROW or DOWN/ARROW pushbutton to select function block number 82 in the right side
digits of alphanumeric display.
10. Press ALARM/STEP DOWN pushbutton to enter PARAMETER level.
11. Push the UP/ARROW or DOWN/ARROW pushbutton as needed to select the Zero Input parameter ('CNMZ'
for thermocouples R, S, T, & B or 'CWMZ' for J, K, E, & N). This selection must agree with the input type
selection made in section 4.7.1. Parameter is indicated on alphanumeric display.
12. Press ALARM/STEP DOWN pushbutton to enter VALUE level ('CAL' should appear in the center section of
the display).
13. Refer to Table 4-2 to obtain value in millivolts under Zero column for the thermocouple type selected in
“Selecting input Type” section.
14. Set the millivolt source to Zero value obtained in previous step.
15. Wait at least 15 seconds, then press TAG/STORE pushbutton to lock-in the Zero Input value. Wait until
'CAL' in center display blinks - this indicates that the Zero value was stored successfully.
16. Press ACK/STEP UP pushbutton to get back to PARAMETER level.
17. Push the UP/ARROW or DOWN/ARROW pushbutton as needed to select the Full Scale parameter ('CNMF'
for thermocouples R, S, T, & B or 'CWMF' for J, K, E, & N). This selection must agree with the input type
selection made in “Selecting Input Type” section. Parameter is indicated on alphanumeric display.
18. Press the ALARM/STEP DOWN pushbutton to enter VALUE level ('CAL' should appear in the center section
of the display).
19. Refer to Table 4-2 to obtain value in millivolts under Full Scale column for the thermocouple type selected in
“selecting Input Type section.
20. Set the millivolt source to Full Scale value obtained in previous step.
21. Wait at least 15 seconds, then press TAG/STORE pushbutton to lock-in the Full Scale value. Wait until 'CAL'
in center display blinks - this indicates that the Full Scale value was stored successfully.
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CALIBRATION
22. To verify calibration, proceed to step 23. Verification is always recommended. If verification is not desired,
proceed to step 27.
23. Push the UP/ARROW or DOWN/ARROW pushbutton to select verification parameter ‘CVIP’. Parameter
‘CVIP’ is a 0 to 100% signal scaled by the range set in parameters ‘SMVL’ and ‘SMVH’ and in the
engineering units set in parameter ‘SMVU’. Refer to step 24A to verify calibration with Input Type (HIT) set
to 0 or 5. If verifying calibration in temperature units, refer to step 24B.
24A. Calibration verification in mV [with Input Type 0 (Narrow Millivolt) or 5 (Wide Millivolt)].
1. When verifying FB82 with Input Type 0 (Narrow Millivolt) or 5 (Wide Millivolt), parameter ‘SMVU’
should be set to 36 (mV) with ‘SMVL’ set to -11.0 mV and ‘SMVH’ set to +26.00 mV. Refer to
“Selecting Input Type” section and “Specifying Measured Variable Units” for how to select Input Type
and Measure Variable Units.
2. Continuing from step 23, press ALARM/STEP DOWN pushbutton to enter VALUE level of parameter
‘CVIP’.
3. Set the millivolt source to -11.00 mV. The center (numeric) section of the display should read 0.00%
(tolerance: ± 0.05%).
4. Set the millivolt source to +26.00 mV. The center (numeric) section of the display should read 100.00%
(tolerance: ± 0.05%).
5. Proceed to step 25
24B. Calibration Verification Temperature Units (with Input Type 11, 12, 14, 15, 16, 17).
1. When verifying FB82 in Temperature Units, the Input Type must match the thermocouple type (or curve)
being used. Refer to “Selecting Input Type” section to set the Input Type (parameter ‘HIT’, i.e. 6 for J
Type).
2. The Measure Variable Units should be set to the temperature scale desired (i.e. 32 for ºCelsius). Refer to
“Specifying Measured Variable Units” section for how to set parameter ‘SMVU’.
3. Set parameters ‘SMVL’ and ‘SMVH’ to your range low and high values (i.e. 0.00 and 500.00).
4. Continuing from step 23, press ALARM/STEP DOWN pushbutton to enter value level of parameter
‘CVIP’.
5. Choose a low temperature and high temperature value on your scale to verify the calibration and note there
respective voltages [i.e. 0º Celsius (0.00 mV) and 500º Celsius (27.388 mV)].
6. Set the millivolt source to the millivolt value corresponding to your chosen low range (i.e. 100.00 mV).
The center (numeric) section of the display should read the percentage corresponding to your chosen low
temperature scaled by parameters ‘SMVL’ and SMVH’ (i.e. 0.0%).. Tolerance: ± 0.05%.
October 1998
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CALIBRATION
UM348-1
7. Set precision decade box to the ohms value corresponding to your chosen high range (i.e. 27.388 mV). The
center (numeric) section of the display should read the percentage corresponding to your chosen high
temperature scaled by parameters ‘SMVL’ and SMVH’ (i.e. 100.00%). Tolerance: ± 0.05%.
8. Proceed to step 25.
25. After completing the calibration or calibration verification, press the ENTER/EXIT CONF pushbutton to leave
the calibration mode.
26. Lock out the FIELDPAC's calibration mode via the MPU Controller Board's 'CAL' lockout switch.
This completes the calibration and calibration verification procedure. If the verification results show that a
recalibration is necessary, perform steps 1 to 26 again.
4.7.5 RTD Input Calibration
A FIELDPAC equipped with a Temperature Sensor Board can be calibrated to accept a variety of platinum
resistance temperature detectors (RTDs). Calibration of the FIELDPAC for RTD input is handled by function
block 82.
The complete calibration procedure entails selecting either the Narrow Ohm or Wide Ohm input type (Number 10
or 13, respectively), described in “Selecting Input Type” section, and carrying out the calibration steps listed below.
The actual operating temperature range is entered as a soft 'S' configuration parameter after the RTD calibration is
completed. Once the FIELDPAC's RTD input is calibrated, FB82 Block Output 98 will produce a scaled and
linearized signal using the values entered in the soft configuration so that the 0-100% signal will represent a specific
operating temperature range. Refer to the “Configuration” section for detailed configuration information.
Before proceeding with the calibration, refer to:
• “General Considerations” section for some general considerations
• Obtain the necessary equipment from the list given in “Required Equipment” section
• Enable the appropriate lockout switches described in “Lockout Switches” section
• Assign to FB82 a valid execution sequence number (ESN) as described in “ESN Assignment” section.
1. Verify FIELDPAC's input power requirement. Apply power to the FIELDPAC.
2. Allow the FIELDPAC to warm up for one hour prior to calibrating. The ambient temperature should be close
to its expected operating temperature.
3. Ensure that the 'CAL' lockout switch is in the 'enabled' position. Refer to “Lockout Switches” section and
Figure 5-3 to perform this task, if necessary.
4. Ensure that an ESN has been assigned to function block 82. Refer to “ESN Assignment” section to perform
this task, if necessary.
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CALIBRATION
4.a Ensure that function block 82 has been configured for either the Narrow Ohm or Wide Ohm input type in
accordance with the RTD type.
For calibrating RTD types ‘DIN 100,’ and ‘US 100,’ the input type number should be set to 10.
For calibrating RTD types ‘DIN 200,’ ‘DIN 500’, ‘US 200,’ and ‘US 500,’ the input type number should be
set to 13.
Refer to “Selecting Input Type” section and “Specifying Measured Variable Input” section to perform this task,
if necessary.
5. Connect the precision resistance decade box to the FIELDPAC's optional I/O terminals G2 (+), G3 (-), and H2
(Current Source). To obtain proper lead resistance compensation during calibration, three equal lengths of No.
18 or No. 16 AWG wire must be used as in a 3-wire RTD connection shown in Figure 4-2.
Ensure that the three equal leads make good electrical contact both at the decade box and the optional I/O
terminals of the FIELDPAC. Do not use alligator clips for connections on either end, since contact resistance
may be present and alter the calibration accuracy.
6. Press ENTER/EXIT CONF pushbutton to enter configuration mode at the MENU level.
7. Push the DOWN/ARROW pushbutton to select 'C' (calibration) on left digit position of alphanumeric display.
(If 'CX' appears in the display, the lockout switch on the MPU Baseboard must be enabled, see “Lockout
Switches” section).
8. Press ALARM/STEP DOWN pushbutton to enter FUNCTION BLOCK level.
9. Push the UP/ARROW or DOWN/ARROW pushbutton to select function block number 82 in the right side
digits of alphanumeric display.
10. Press ALARM/STEP DOWN pushbutton to enter PARAMETER level.
11. Push the UP/ARROW or DOWN/ARROW pushbutton to select desired Zero parameter ('CWOZ' for 500 or
200 Ohm RTDs or 'CNOZ' for 100 Ohm RTD). This selection must agree with the input type selection made
in “Selecting Input Type” section. Parameter is indicated on alphanumeric display.
12. Press ALARM/STEP DOWN pushbutton to enter VALUE level ('CAL' should appear in the center section of
the display).
13. Set the precision resistance decade box to zero ohms.
14. Wait at least 15 seconds, then press TAG/STORE pushbutton to lock-in the Zero value. Wait until 'CAL' in
center display blinks - this indicates that the Zero value was stored successfully.
15. Press ACK/STEP UP pushbutton to get back to PARAMETER level.
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16. Push the UP/ARROW or DOWN/ARROW pushbutton to select desired Full Scale parameter ('CWOF' for 500
or 200 Ohm RTDs or 'CNOF' for 100 Ohm RTD). This selection must agree with the input type selection
made in “Selecting Input Type” section. Parameter is indicated on alphanumeric display.
17. Press the ALARM/STEP DOWN pushbutton to enter VALUE level ('CAL' should appear in the center section
of the display).
18. Refer to Table 4-2 to obtain value in ohms under the Full Scale column for the RTD type selected in “Selecting
Input Type” section.
19. Set the precision resistance decade box to the Full Scale value obtained in previous step.
20. Wait at least 15 seconds, then press TAG/STORE pushbutton to lock-in the Full Scale value. Wait until 'CAL'
in center display blinks - this indicates that the Full Scale value was stored successfully.
21. Press ACK/STEP UP pushbutton to get back to PARAMETER level.
22. To verify calibration, proceed to step 23. Verification is always recommended. If verification is not desired,
proceed to step 27.
23. Push the UP/ARROW or DOWN/ARROW pushbutton to select verification parameter ‘CVIP’. Parameter
‘CVIP’ is a 0 to 100% signal scaled by the range set in parameters ‘SMVL’ and ‘SMVH’ and in the
engineering units set in parameter ‘SMVU’. Refer to step 24A to verify calibration with Input Type (HIT) set
to 10 or 13. If verifying calibration in temperature units, refer to step 24B.
24A. Calibration verification in ohms [with Input Type 10 (Narrow Ohm) or 13 (Wide Ohm)].
1. When verifying FB82 with Input Type 10 (Narrow Ohm) or 13 (Wide Ohm), parameter ‘SMVU’ should
be set to 37 (Ohms) with ‘SMVL’ set to 0.00 and ‘SMVH’ set to 470.00. Refer to “Selecting Input
Type” section and “Specifying Measured Variable Units” section for how to select Input Type and
Measure Variable Units.
2. Continuing from step 23, press ALARM/STEP DOWN pushbutton to enter VALUE level of parameter
‘CVIP’.
3. Set precision decade box to zero ohms. The center (numeric) section of the display should read 0.00%.
Tolerance: ± 0.05%.
4. Set precision decade box to 470.00 ohms. The center (numeric) section of the display should read
100.00%. Tolerance: ± 0.05%.
5. Proceed to step 25
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CALIBRATION
24B. Calibration Verification in Temperature Units (with Input Type 11, 12, 14, 15, 16, 17).
1. When verifying FB82 in Temperature Units, the Input Type must match the RTD type (or curve) being
used. Refer to “Selecting Input Type” section to set the Input Type (parameter ‘HIT’, i.e. 11 for DIN 100
curve).
2. The Measure Variable Units should be set to the temperature scale desired (i.e. 32 for Celsius). Refer to
“Specifying Measured Variable Units” section for how to set parameter ‘SMVU’.
3. Set parameters ‘SMVL’ and ‘SMVH’ to your range low and high values (i.e. 0.00 and 300.00).
4. Continuing from step 23, press ALARM/STEP DOWN pushbutton to enter value level of parameter
‘CVIP’.
5. Choose a low temperature and high temperature value on your scale to verify the calibration and note
there respective resistances [i.e. 0º Celsius (100.00 ohms) and 100º Celsius (138.5 ohms)].
6. Set precision decade box to the ohms value corresponding to your chosen low range (i.e. 100.00 ohms).
The center (numeric) section of the display should read the percentage corresponding to your chosen low
temperature scaled by parameters ‘SMVL’ and SMVH’ (i.e. 0.0%).. Tolerance: ± 0.05%.
7. Set precision decade box to the ohms value corresponding to your chosen high range (i.e. 138.50 ohms).
The center (numeric) section of the display should read the percentage corresponding to your chosen high
temperature scaled by parameters ‘SMVL’ and SMVH’ (i.e. 33.33%). Tolerance: ± 0.05%.
8. Proceed to step 25.
25. After completing the calibration or calibration verification, press the ENTER/EXIT CONF pushbutton to leave
the calibration mode.
26. Lock out the FIELDPAC's calibration mode via the MPU Controller Board's 'CAL' lockout switch.
This completes the calibration and calibration verification procedure. If the verification results show that a
recalibration is necessary, perform steps 1 through 26 again.
October 1998
4-23
CALIBRATION
UM348-1
4.8 PNEUMATIC INPUT (FB85, FB86, FB87)
A FIELDPAC equipped with a Pneumatic Input Board can be calibrated to accept one or three (3-15 psig or 3-27
psig) pneumatic input signals. Four Pneumatic Input Boards are available:
1.
2.
3.
4.
P/N 16205-18 - Three inputs, 3-15 psig Board
P/N 16205-26 - Three inputs, 3-27 psig Board
P/N 16205-27 - One input, 3-15 psig Board
P/N 16205-28 - One input, 3-27 psig Board
FIELDPACs containing factory installed Pneumatic Input Boards are factory calibrated for either 3-15 psig or 3-27
psig, depending on Board used. For most applications, recalibration of the factory-set configuration and input
range will not be necessary. However, if calibration or calibration verification is necessary, use the following
procedure.
Calibration of the FIELDPAC for pneumatic input ports 1, 2, and 3 is handled by function blocks 85, 86, and 87,
respectively.
IMPORTANT
Pneumatic Input function blocks 85, 86, and 87 are available (operational) only if
Analog Input FB01 is not configured. Terminal 'F7' used for FB01 must be left
unconnected.
Refer to the Model 348 FILEDPAC Field Mounted Controller Configuration Guide (CG348A-2) for detailed
configuration information.
Before proceeding with the calibration, refer to:
• “General Considerations” section for some general considerations
• Obtain the necessary equipment from the list given in “Required Equipment” section
• Enable the appropriate lockout switches described in “Lockout Switches” section
• Assign to FB82 a valid execution sequence number (ESN) as described in “ESN Assignment” section.
1. Verify FIELDPAC's input power requirement. Apply power to the FIELDPAC.
2. Allow the FIELDPAC to warm up for one hour prior to calibrating. The ambient temperature should be close
to its expected operating temperature.
3. Ensure that the 'CAL' lockout switch is in the 'enabled' position. Refer to “Lockout Switches” section and
Figure 5-3 to perform this task, if necessary.
4. Ensure that an ESN of 00 (zero) has been assigned to Analog Input function block 01. Refer to “ESN
Assignment” section to perform this task, if necessary.
5. Ensure that an ESN has been assigned to function blocks 85, 86, and 87, as needed. Refer to “ESN
Assignment” section to perform this task, if necessary.
4-24
October 1998
UM348-1
CALIBRATION
6. Connect the precision 0-30 psig test gauge and the adjustable regulated air signal to the pneumatic input to be
calibrated. Figure 1-1 shows the location of the three pneumatic input ports.
7. Press ENTER/EXIT CONF pushbutton to enter configuration mode at the MENU level.
8. Push the DOWN/ARROW pushbutton to select 'C' (calibration) on left digit position of alphanumeric display.
(If 'CX' appears in the display, the lockout switch on the MPU Controller Board must be enabled, see “Lockout
Switches” section).
9. Press ALARM/STEP DOWN pushbutton to enter FUNCTION BLOCK level.
10. Push the UP/ARROW or DOWN/ARROW pushbutton to select function block 85, 86, or 87 in the right-side
digits of the alphanumeric display.
11. Press ALARM/STEP DOWN pushbutton to enter PARAMETER level.
12. Push the UP/ARROW or DOWN/ARROW pushbutton to select Zero Input parameter ('CZI1' for FB85, 'CZI2'
for FB86, etc.). Parameter is indicated on alphanumeric display.
13. Press ALARM/STEP DOWN pushbutton to enter VALUE level ('CAL' should appear in the center section of
the display).
14. Set the air pressure to the Zero Input value (for example, 3 psig). Refer to “Input/Output Ports” section for
pneumatic input specifications.
15. Wait at least 15 seconds, then press TAG/STORE pushbutton to lock-in the zero input value. Wait until 'CAL'
in center display blinks - this indicates that the Zero Input value was stored successfully.
16. Press ACK/STEP UP pushbutton to get back to PARAMETER level.
17. Push the UP/ARROW or DOWN/ARROW pushbutton to select desired Full Scale Input parameter ('CFI1' for
FB85, 'CFI2' for FB86, etc.). Parameter is indicated on alphanumeric display.
18. Press the ALARM/STEP DOWN pushbutton to enter VALUE level ('CAL' should appear in the center section
of the display).
19. Set the air pressure to the Full Scale Input value (for example, 15 psig). Refer to “Input/Output Ports” section
for pneumatic input specifications.
20. Wait at least 15 seconds, then press TAG/STORE pushbutton to lock-in the full scale value. Wait until 'CAL'
in center display blinks - this indicates that the Full Scale value was stored successfully.
21. To verify calibration, proceed to step 22. Verification is always recommended. If verification is not desired,
proceed to step 27.
22. Press ACK/STEP UP pushbutton to get back to PARAMETER level.
October 1998
4-25
CALIBRATION
UM348-1
23. Push the UP/ARROW or DOWN/ARROW pushbutton to select the Verification parameter ('CVI1' for FB85,
'CVI2' for FB86, etc.). Parameter is shown on alphanumeric display.
24. Press ALARM/STEP DOWN pushbutton to enter VALUE level.
25. Set the air pressure to the Zero Input value. The center (numeric) section of the display should read 0.00% of
input (tolerance: ±0.05%).
26. Set the air pressure to the Full Scale Input value. The center (numeric) section of the display should read
100.0% of input (tolerance: ±0.05%).
27. Select one of the following:
If all pneumatic input function blocks have been calibrated and verified, press ENTER/EXIT CONF
pushbutton to leave the calibration mode and enter operation mode.
If additional function blocks are to be calibrated and verified, press ACK/STEP UP button twice to enter
FUNCTION BLOCK level. Perform steps 10 through 26 for each function block to be calibrated and verified.
28. Having finished calibrating and verifying all the required function blocks, it is prudent to lock out the
FIELDPAC's calibration mode via the MPU Controller Board's 'CAL' lockout switch (see “Lockout Switches”
section).
4.9 I/P MODULE CALIBRATION (FB03)
The I/P Module in FIELDPAC is the same as the Model 773 I/PAC Transducer. To ensure continued accuracy of
the I/P Transducer, it is suggested that the calibration be checked after the first thirty days of operation and then at
six month intervals.
Function block 03 is used to configure and calibrate the I/P module. Because the I/P module replaces the current
output in FB03, do not make any connections to terminals E11 and E12 when an I/P module is installed in a
FIELDPAC.
Before proceeding with the calibration, refer to:
• “General Considerations” section for some general considerations
• Obtain the necessary equipment from the list given in “Required Equipment” section
• Enable the appropriate lockout switches described in “Lockout Switches” section
• Assign to FB82 a valid execution sequence number (ESN) as described in “ESN Assignment” section.
1. Verify FIELDPAC’s input power requirement. Apply power to the FIELDPAC. Allow the FIELDPAC to
warm up for 1 hour prior to calibrating. The ambient temperature should be close to its expected operating
temperature.
4-26
October 1998
UM348-1
CALIBRATION
2. Ensure that the ‘CAL’ lockout switch is in the ‘enabled’ position. Refer to “Lockout Switches” section and
Figure 5-3 to perform this task, if necessary.
3. Press ENTER/EXIT CONF pushbutton to enter FUNCTION BLOCK level.
4. Push the UP/ARROW or DOWN/ARROW pushbutton to select ‘C’ (calibration) on left digit position of
alphanumeric display. (If ‘CX’ appears in the display, the lockout switch on the MPU Controller Board must be
enabled, see “Lockout Switches” section).
5. Press ALARM/STEP DOWN pushbutton to enter FUNCTION BLOCK level.
6. Push the UP/ARROW or DOWN/ARROW pushbutton to select function block number 03 in the right side
digits of the alphanumeric display.
7. Disconnect pneumatic tubing present at the output port.
8. Connect an appropriate test gauge to the output port.
9. Connect an air supply to the supply port, if none is connected.
10. Turn on the air supply and set the regulator to the required pressure for the Transducer’s output range (see
“Input/Output Ports” section for the required supply pressure).
11. Push ALARM/STEP DOWN pushbutton to enter PARAMETER level.
12. Push the UP/ARROW or DOWN/ARROW pushbutton to select parameter ‘CZO1’. Parameter is indicated in
the alphanumeric display.
13. Press ALARM/STEP DOWN pushbutton to enter VALUE level (‘CAL’ should appear in the center section of
the display).
14. Press the UP/ARROW or DOWN/ARROW pushbutton to set zero output value on the test gauge (i.e. 3 PSI).
If you cannot adjust the output enough with the UP or DOWN/ARROW keys, use the ZERO trimpot located
on the I/P for more adjustment (Refer to Figure 4-2).
15. Wait at least 15 seconds, then press TAG/STORE pushbutton to lock-in desired value.
16. Press ACK/STEP UP pushbutton.
17. Push the UP/ARROW or DOWN/ARROW pushbutton (‘CFO1’ for full scale output).
18. Push the ALARM/STEP DOWN pushbutton to enter VALUE level (‘CAL’ should appear in the center section
of the display).
October 1998
4-27
CALIBRATION
UM348-1
19. Push the UP/ARROW or DOWN/ARROW pushbutton to set full scale output value on test gauge (i.e. 15
PSI). If you cannot adjust the output enough with the UP or DOWN/ARROW keys, use the SPAN trimpot
located on the I/P module for more adjustment (Refer to Figure 4-2).
20. Wait at least 15 seconds, then press TAG/STORE pushbutton to store the desired value.
21. To verify calibration, proceed to step 22. Verification is always recommended. If verification is not desired,
proceed to step 27.
22. Press ACK/STEP UP pushbutton to get back to PARAMTER level.
23. Push the UP/ARROW or DOWN/ARROW pushbutton to select verification parameter ‘CVI1’. Parameter is
shown on alphanumeric display.
24. Press ALARM/STEP DOWN pushbutton to enter VALUE level.
25. Push the UP/ARROW or DOWN/ARROW pushbutton to set 0.00%. The zero output value should be
displayed on the test gauge.
26. Push the UP/ARROW or DOWN/ARROW pushbutton to set 100.00%. The full scale output value should be
displayed on the test gauge.
27. Press ENTER/EXIT CONF pushbutton to leave the calibration mode and enter operation mode. Remember to
lock-out calibration switch.
This completes the calibration and calibration verification procedure. If the verification results show that a
recalibration is necessary, perform steps 1 through 7 again.
4-28
October 1998
UM348-1
CALIBRATION
Span
Restriction
Zero
XO2932SO
FIGURE 4-2 I/P Module
n
October 1998
4-29
CALIBRATION
4-30
UM348-1
October 1998
UM348-1
CIRCUIT DESCRIPTION
5.0 CIRCUIT DESCRIPTION
The hardware architecture of the FIELDPAC is shown in Figure 5-1. Notice that all plug-in assemblies interact
with the MPU Controller board.
The MPU Controller board oversees all of the FIELDPAC's internal operations. It interacts with the
display/keyboard assembly and all the included options such as the temperature sensor board, the pneumatic input
board, the I/P module, the pressure sensor, and the plug-in AC power supply. It also performs all of the
FIELDPAC's built-in signal processing operations. The controller board's on-board DC power supply furnishes
DC operating voltages to all plug-in assemblies and to external process transmitters connected to the terminal
block.
The plug-in AC power supply is used for powering the FIELDPAC from nominal 120 or 240 Vac power lines. It
converts a given AC line voltage to 24 Vdc which is the default power requirement of the MPU baseboard's onboard DC power supply.
The display/keyboard assembly provides LCD indication of process related signals, station operating mode, and
configuration parameters. It also accepts operator entered commands and data via the Panel's front panel
pushbuttons.
The temperature sensor board contains hardware which provides the interface circuitry to accept a thermocouple,
an RTD sensor, or a millivolt input signal as configured.
The pneumatic input board contains hardware which provides the interface circuitry for one or three pneumatic
input signals.
The I/P module contains the circuitry to convert a current signal (taken from the output of Analog Output #1) to a
proportional pneumatic signal. This module plugs directly into the controller board (for power and input signal)
and into an aluminum manifold (for air supply and pneumatic output).
A pressure sensor is attached to the rear of the FIELDPAC. Its electrical connections to the MPU controller board
are made by a small ribbon cable and connector directly to the dedicated connector located on the upper left side of
the controller board.
A functional description, a hardware block diagram and a physical layout drawing are provided for most of the
following circuit areas:
•
•
•
•
•
•
•
•
MPU Controller board
Plug-In AC Power Supply
Display/Keyboard Assembly
Temperature Sensor Board
Pneumatic Input Board
I/P Module
Pressure Sensor
HART Signal Port
October 1998
5-1
5-2
TB-B
J2
AC POWER
SUPPLY
(OPTIONAL)
TB-A
J3
DISPLAY/
INTERFACE
BOARD
KEYBOARD
PANEL
TB-D
TB-C
TB-F
TB-E
TERMINAL BLOCK
COMPARTMENT
MPU
CONTROLLER
BOARD
P4
TB-H
TB-G
J4
P13
P3
PJ1
TEMPERATURE
SENSOR
BOARD
(OPTIONAL)
PJ2
I/P
MODULE
(OPTIONAL)
OR
PNEUMATIC
INPUT
BOARD
(OPTIONAL)
A02516B0
PNEUMATIC MANIFOLD
(PART OF ENCLOSURE)
3
2
1
VENT
SUPPLY
OUTPUT
PNEUMATIC INPUTS
MODEL 340
TRANSMITTER
(OPTIONAL)
CIRCUIT DESCRIPTION
UM348-1
FIGURE 5-1 Model 348 Hardware Architecture
October 1998
UM348-1
CIRCUIT DESCRIPTION
5.1 MPU CONTROLLER BOARD
The MPU Controller board's hardware is supported by a large array of software based function blocks. During
station configuration, a group of function blocks are linked together to meet the control requirements of the station's
application.
As shown in Figure 5-2, the MPU controller board has three analog inputs, two analog outputs, two digital inputs,
two open-collector type digital outputs, two isolated digital outputs, an open-collector type pulse output, and a
HART interface port. In addition, the MPU controller board can also accept the optional temperature sensor board
or the pneumatic Input board (at J1), the I/P module (at P3), the pressure sensor (at P4), and the plug-in AC power
supply (at J2). The display assembly is connected to the controller board via a ribbon cable at J3. Which inputs
and outputs are active during station operation depends on which options are installed and how the FIELDPAC is
configured. To determine the actual I/O arrangement, refer to the appropriate configuration documentation.
The MPU controller board contains both analog and digital circuits. Analog circuitry operates in real time, the
microprocessor-based digital circuitry operates at high speed under program control. Figure 5-3 shows the physical
layout of the MPU controller board.
The MPU (microprocessor unit) is a single integrated circuit capable of arithmetical, logical, and support circuit
control functions. It directly or indirectly interacts with surrounding on-board and off-board circuitry to control the
internal operation of the FIELDPAC. To operate under program control, the MPU systematically fetches
instructions from the PROM area and executes them to control data flow and organize support circuit activities.
The Clock circuit contains a precision square wave oscillator which operates at 7.3728 MHz. It also contains
several flip-flop type of frequency dividers to down count the oscillator frequency to values required by the MPU
and other digital circuits. Timing pulses from the Clock are used to synchronize the MPU's computing activities.
On-board memory consists of PROM (programmable read only memory) and NVRAM (non-volatile random access
memory). The PROM stores the operating programs for the function blocks and Factory Configured Options
(FCOs) associated with a Model 348. It also stores the general operating programs for the on-board
microprocessor. The NVRAM stores hard configuration, the table of function blocks, soft configuration,
calibration data, and transient data.
During configuration and calibration, data is entered into NVRAM when the TAG/STORE button is pressed.
Transient data (process, station status, alarm, and error code data) is also stored in NVRAM.
The MPU's three bus lines are the address bus, the data bus, and the control bus. They interconnect the MPU, the
NVRAM, the PROM, and other support circuits. The address bus is unidirectional while the control and data
buses are bidirectional.
The Signal Selector circuit operates under MPU control to sequentially select one of the three analog signals and
feed it to the A/D Converter. It is essentially a solid state switch that repeatedly scans the three analog inputs.
The A/D Converter circuit converts the selected analog input signal into a digital value. Once digitized, the signal
value can easily be manipulated and stored in memory by the MPU.
October 1998
5-3
CIRCUIT DESCRIPTION
UM348-1
The D/A Converter circuit converts a digital value into an analog signal.
The Amplifier circuit provides gain and drive capability to the analog signal output of the D/A Converter.
The Opto-Coupler circuit provides signal isolation for the digital input signal.
The built-in DC power supply accepts a nominal 24 Vdc power input and provides +10, -10, and +5 voltage levels
needed by the FIELDPAC's analog and digital circuitry. The Model 348E FIELDPAC can also be equipped with
an additional plug-in AC power supply that will accept a nominal 120 or 240 Vac power input and convert it to 24
Vdc for input to the built-in DC power supply.
P13
J4
SW1
J3
MPU
TO MODEL 340
TRANSMITTER
TO I/P
MODULE
MODEM
HART
SIGNAL
SELECTOR
ANALOG
INPUT 1
ANALOG
INPUT 2
A/D
DIGITAL
INPUT 2
OPTOCOUPLER
XMTR
POWER
SUPPLY
CLOCK
DC
POWER
SUPPLY
+24
D/A
ANALOG
OUTPUT 1
D/A
ANALOG
OUTPUT 2
DATA BUS
OPTOCOUPLER
ADDRESS BUS
DIGITAL
INPUT 1
CONTROL BUS
ANALOG
INPUT 3
DC
POWER
INPUT
P4
TERMINAL
BLOCKS
E&F
TO DISPLAY
INTERFACE
BOARD
P3
TO TEMPERATURE SENSOR
BOARD OR PNEUMATIC
INPUT BOARD
OUTPUT
TRANSISTOR
DIGITAL
OUTPUT 1
OUTPUT
TRANSISTOR
DIGITAL
OUTPUT 2
OUTPUT
TRANSISTOR
PULSE
OUTPUT
TERMINAL
BLOCKS
E&F
+10
-10
PROM
+5
OPTOISOLATED
TRANSISTOR
OR RELAY
OPTOISOLATED
TRANSISTOR
OR RELAY
RAM
J2
TO AC
POWER
SUPPLY
TB A & B
AC POWER
INPUT
TB G & H
T/C, RTD
INPUT
TB C & D
ISOLATED
DIGITAL
OUTPUT 1
ISOLATED
DIGITAL
OUTPUT 2
A02496B0
FIGURE 5-2 MPU Controller board Inputs and Outputs
5-4
October 1998
UM348-1
CIRCUIT DESCRIPTION
PUSH TO
ENABLE
PUSH TO
LOCKOUT
SOFT
ALARM
TUNE
H/T/F
CAL
LOCKOUT
SWITCHES
DETAIL
I/P MODULE
FUSE
EPROM
TUNE
SW1
SOFT
ALARM
U48
H/T/F
CAL
P4
1
11
2
12
P3
J4
2
1
J3
26
AC
POWER
SUPPLY
25
RIBBON CABLE
TO DISPLAY/
INTERFACE
BOARD
39
40
TEMPERATURE
SENSOR
OR
PNEUMATIC
INPUT
BOARD
J2
2
1
8
2
P13
8
1
1
7
CONNECTORS ARE LOCATED UNDER
POWER SUPPLY AND BOARDS
TO DISPLAY
INTERFACE BOARD
I/P MODULE
MANIFOLD
AC
POWER
SUPPLY
TUBES PRESENT ONLY ON
PNEUMATIC INPUT BOARD
A02477E0
FIGURE 5-3 MPU Controller board Physical Layout
October 1998
5-5
CIRCUIT DESCRIPTION
UM348-1
The transmitter power supply regulator also accepts the +24 Vdc and provides a nominal +22 Vdc output at the
terminal block to power two-wire transmitters or other devices.
The reference voltage circuitry provides precision analog reference voltages of +5, -5, and +2.5 for the A/D and
D/A converters and other analog circuits.
Lock out switches are located at the top center of the controller board and can be set to prevent unauthorized
changes to selected configuration modes.
The station power fuse is located at the center top of the board.
5.2 PLUG-IN AC POWER SUPPLY
The plug-in AC power supply is used for powering the FIELDPAC from nominal 120 or 240 Vac power lines. It
converts a given ac line voltage to 24 Vdc which is the default power requirement of the MPU baseboard's on-board
DC power supply. It uses a 1 A fuse (P/N 7447-209) for circuit protection.
5.3 DISPLAY/KEYBOARD ASSEMBLY
The display/keyboard assembly is installed in the top cover of the FIELDPAC enclosure. It consists of the
following components:
•
•
Display/Interface Board
Keyboard
The display/keyboard assembly functions under the direction of the MPU located on the controller board. It
provides LCD indication (both analog and digital) of various process signals, accepts operator entered data during
hard and soft configuration and calibration procedures, and supports the front panel operator controls.
5.3.1 Display/Interface Board
The display/interface board performs several functions. It interfaces the whole display/keyboard assembly to the
MPU controller board and provides the electronic circuitry to operate the LCD panel and the keyboard. It scans the
keyboard for operator initiated keystrokes and forwards display data to the LCD panel.
The pulses generated by the UP ARROW and DOWN ARROW pushbuttons are counted by the digital up-down
counter which places binary pulse counts on the data bus where they can be retrieved and used by the MPU
controller board to adjust process signals (e.g., setpoint or valve) or adjust configuration selections.
The keyboard scanner circuit has a built-in oscillator and scans the keyboard at regular time intervals to sense a
complete keystroke. If a keystroke is detected, data identifying that key is placed on the data bus where it can be
interpreted by the MPU of the controller board.
5-6
October 1998
UM348-1
CIRCUIT DESCRIPTION
The segment and digit driver circuitry uses standard digital decoding and latching techniques. The display driver
circuit performs two main functions. It decodes display data received from the MPU controller board and forwards
decoded display data to the LCD panel. Refer to “Operation” section for description of each display's purpose.
5.3.2 Keyboard
The keyboard is a membrane keypad which contains eleven switches. The layout of these switches is shown in
Figure 3-1. Each switch has tactile feel. Operator initiated keystrokes are sensed by circuitry on the
display/interface board. The keyboard has a built-in shield to prevent false triggering from static or EMI
(electromagnetic interference). A flex-circuit ribbon cable connects the keyboard to the display/interface board.
5.4 TEMPERATURE SENSOR BOARD
The temperature sensor board can be configured to accept a variety of thermocouple types, various millivolt
sources, and several different RTD types. Refer to “Input/output Ports” section for detailed input specifications.
The temperature sensor board plugs into the MPU controller board via two connectors as shown in Figure 5-1,
Hardware Architecture. Connector PJ2 on the sensor board carries the input signals and PJ1 accommodates power,
control, and data lines.
Figure 5-4 shows a block diagram of the temperature sensor board. The circuitry on the sensor board is powered
by the controller board. The input stages are powered by an on-board isolated bipolar 5V power supply (Isolated
DC-DC Converter).
The thermocouple or millivolt input signal appears at the overvoltage protection and open T/C detection stage. The
components in this stage function as transient suppressors and protect the input circuitry from accidental
application of excessive plus or minus voltages. A constant current source is provided for RTD use. An automatic
cold junction compensation circuit is switched in for thermocouple inputs.
The amplified and filtered analog signal representing the thermocouple or millivolt signal appears at the input to the
A/D converter. The converter produces a digital output consisting of a train of pulses whose count is proportional
to the amplitude of the analog input. This output is routed through the isolation transformers to the interface
circuitry. The MPU retrieves this data for further processing. It performs the following functions:
•
•
•
•
Linearization
Calibration
Filtering
Output Scaling
October 1998
5-7
CIRCUIT DESCRIPTION
UM348-1
JP2
CONSTANT
CURRENT
SOURCE
OVERVOLTAGE
PROTECTION,
LP FILTER,
OPEN T/C
DETECTION
CJ
COLD JUNCTION
COMPENSATION
ISOLATION
TRANSFORMERS
A/D
CONVERTER
JP1
INTERFACE
+5
-5
TO J4
ON MPU
CONTROLLER
BOARD
ISOLATED
DC TO DC
CONVERTER
A02517B0
FIGURE 5-4 Temperature Sensor Board Block Diagram
5.5 PNEUMATIC INPUT BOARD
The pneumatic input board can be configured to accept one or three pneumatic input signals, depending on the
board installed. Refer to “Input/Output Ports” section for detailed pneumatic input specifications.
The board plugs into the MPU controller board via one connector as shown in Figure 5-1, Hardware Architecture.
This connector carries the output signal and accommodates power and control lines. Flexible tubing is used to
connect the pneumatic input port manifold to the pressure transducers on the Board.
Figure 5-5 shows a block diagram of the pneumatic input board. The circuitry on the board is powered by the
controller board.
The pneumatic input signals are brought in individually via the flexible tubing to their respective pressure
transducers. Three constant current sources provide the necessary current to the transducers. Signals from the
transducers are fed via individual gain stages to the signal selector.
The signal selector circuit operates under MPU control to sequentially select one of the three signals and feed it to
Analog Input 1. Note that to be able to configure pneumatic inputs for use, it is necessary that Analog Input 1 be assigned
an ESN of 00 (zero).
5-8
October 1998
UM348-1
CIRCUIT DESCRIPTION
TEMPERATURE
SENSOR
T
J1
U1C
U6
U5
P
U1A
PNEUMATIC
INPUT 2
U7
P
U10A
U13
P
U10C
SIGNAL SELECTOR U8
PNEUMATIC
INPUT 1
U2
TO J4
ON MPU
CONTROLLER
BOARD
PNEUMATIC
INPUT 3
CONSTANT
CURRENT
SUPPLIES
PRESSURE
SENSORS
U11
A02518B0
FIGURE 5-5 Pneumatic Input Board
5.6 I/P MODULE
The I/P transducer module consists of an electronic controller and a pneumatic booster unit. It is essentially a
Model 773D Current to Pneumatic Transducer without its enclosure. Figure 5-6 shows a simplified circuit diagram
of the transducer module.
A setpoint milliamp signal from analog output #1 on the MPU controller board and a process variable pneumatic
feedback signal from the booster unit are supplied to the electronic controller. The controller compares these inputs
and provides an electrical signal to a coil-driven pneumatic flapper/nozzle assembly. The pneumatic signal from
this assembly is routed to the booster unit which adjusts the transducer module pneumatic output in a direction to
track the setpoint signal.
5.7 PRESSURE SENSOR
The pressure sensor used with the FIELDPAC is essentially a Model Series 340 Pressure Transmitter without its
electronics module and housing. It uses the built-in circuitry in the FIELDPAC for all the required signal
processing.
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CIRCUIT DESCRIPTION
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5.8 HART SIGNAL PORT
The HART circuitry resides on the MPU controller board (see Figure 5-2). The bi-directional HART digital circuit
consists of a 500 Hz to 10 kHz bandpass filter, and a half-duplex modem. The HART protocol uses 1.2 and 2.2
kHz tones to communicate between devices.
Typically, an arriving HART signal is passed through the bandpass filter and fed to the modem. The modem
demodulates the tones and feeds the resultant signal to the MPU.
Conversely, an outgoing HART signal is initiated by the MPU by sending data to the modem. The modem
generates a corresponding two-tone HART protocol signal which is passed back on the line. A remote HART
device then receives the two-tone signal and processes it as needed.
5-10
October 1998
UM348-1
CIRCUIT DESCRIPTION
FIGURE 5-6 Transducer Module Circuit Diagram
n
October 1998
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CIRCUIT DESCRIPTION
5-12
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MAINTENANCE
6.0 MAINTENANCE
The Field Mounted Controller's (FIELDPAC's) maintenance requirements are minimal. Activities such as cleaning
and visual inspection should be performed at regular intervals. The severity of the FIELDPAC's operating
environment will determine the frequency of maintenance. Additional topics including troubleshooting, assembly
replacement, and software compatibility are also covered.
6.1 TOOL AND EQUIPMENT REQUIREMENTS
The following tools and equipment are necessary for servicing:
A. Common electronic hand tools
B. Digital Multimeter (DMM)
Voltmeter section
Accuracy ................ +/-0.01% of reading
Resolution .............. 1.0 millivolt
Input impedance ..... 10 Megohms
Ammeter section
Accuracy ................ +/-0.1% of reading
Resolution .............. 100 microamperes
C. Maintenance Kit, P/N 15545-110, containing wrist strap and conductive mat. This kit, or an equivalent, is
required when a circuit board is handled for any reason.
6.2 PREVENTIVE MAINTENANCE
The objective for establishing a preventive maintenance program is to provide maximum operating efficiency.
Every preventive maintenance operation should assist in realizing this objective. Unless a preventive measure
reduces a Station's down time, it is unnecessary.
6.2.1 Environmental Considerations
The FIELDPAC has been designed to operate within specified environmental parameters (temperature and
humidity). These parameters are listed in the “Specification” section of this Instruction. Additional information
concerning environmental contaminants is presented in the Installation section.
6.2.2 Visual Inspection
As part of a periodic maintenance program the FIELDPAC must be visually inspected. When viewing the
assembly, scan for abnormalities such as loose, broken or stressed ribbon cables. Look for damaged circuitry and
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MAINTENANCE
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heat stressed parts. Check for excessive dirt or dust build-up which may impede air flow and inhibit proper heat
dissipation.
6.2.3 Cleaning
Circuit boards should not be cleaned unless accumulated foreign material is causing a problem. The enclosed
station design should prevent particulate material from building up. If cleaning becomes necessary, remove debris
with either a soft brush or low velocity deionized air.
The bezel is cleaned with a mild, nonabrasive liquid cleaner and a soft, lint-free cloth. Do not use a paper towel.
6.2.4 Circuit Board Handling
Special handling procedures are required whenever a circuit board assembly is removed, tested, repaired, adjusted
or installed in the Station's case. These procedures are required to prevent component damage from the electrostatic
discharge hazard to which most semiconductors are vulnerable. When handling an assembly, follow the procedures
outlined in the “Assembly Replacement” section of this Instruction.
6.3 FUSE LOCATION
A power input fuse is located at the top center of the MPU baseboard. This is the FIELDPAC's main power fuse.
A replacement fuse may be obtained from any local electronics supplier or may be ordered from the factory. See
the FIELDPAC Parts List, in the back of this manual, for fuse part number and description.
After inserting a new fuse and assembling the station, apply power. Operate the station off-line for several minutes
to be sure that a condition does not exist which will cause the replacement fuse to fail.
The plug-in AC power supply is equipped with its own fuse. This fuse can be replaced easily only when the power
supply is removed from the FIELDPAC. Refer to “AC Power Supply” section for instructions to remove the power
supply, and the “FIELDPAC Parts List”, in the back of this manual, for fuse part number and description.
6.4 TROUBLESHOOTING
If a problem develops upon initial installation, check the following:
•
•
•
•
Station's nameplate for input power requirements and installed options - refer to “Introduction” section
Installation wiring - refer to “Installation” section
Station's hard and soft configuration parameters - refer to “Function Block Description” section
Wiring of any associated external devices such as process transmitters - refer to “Installation” section
Field servicing experience indicates that most initial service incidents involve one or more of the above items.
6-2
October 1998
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MAINTENANCE
Error codes appear on the alphanumeric display in response to a failed power-up diagnostic test or to an on-line
station error (see “Error Codes” section).
In the event that a malfunction within the FIELDPAC is suspected, trouble shooting by assembly substitution is
recommended to get the station back on-line in the shortest possible time. The plug-in design of the station
assemblies permits rapid removal and replacement to isolate a defect.
NOTE
When replacing an MPU controller board, all of the station's configuration and calibration
parameters must be reentered. Factory repaired stations must be configured before being
placed on-line. Refer to the configuration and calibration sections of this instruction.
Additional troubleshooting avenues are also possible. For example, a series of test configurations may be generated
and implemented to exercise different function block areas within the FIELDPAC. This type of troubleshooting
analysis is intended to be implemented in an off-line test bench situation.
6.4.1 Error Codes
The FIELDPAC will display one or more error codes in response to a failure during the power-up diagnostic test or
during its on-line operation.
Power-Up Error Codes
The error codes in Table 6-1 will appear on the alphanumeric display if a failure is encountered during the powerup diagnostic test.
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MAINTENANCE
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TABLE 6-1 Power-Up Error Codes
ERROR
CODE
E110
DIAGNOSTIC
TEST
RAM - Verifies that
each memory location
can be written to and
read from
ROM CHECKSUM Verifies factory
entered data
Verifies transient data
PROBLEM
CORRECTIVE
CONFIRMATION
ACTION
Remove and reapply Power down 348 and make sure
station power.
NVRAM chip and microcontroller chip
are properly seated in sockets.
E215
Verifies
Configuration and
Calibration Data
Remove and reapply
station power.
E216
FB81 is active but
there is no 340
capsule
FB82 is active but
there is no
temperature input
board
FB85/86/87 is active
but there is no
pneumatic input
board
Remove and reapply
station power.
E111
E214
E226
E236
6-4
Remove and reapply
station power.
Remove and reapply
station power.
Remove and reapply
station power.
Remove and reapply
station power.
Power down 348 and make sure ROM
chip and microcontroller are properly
seated in sockets.
Press ENTER/EXIT CONF button.
The station loads default transient data
and enters normal mode. Verify
configuration and re-enter if necessary.
This error may lead to an E215 error
as discussed below.
Press ENTER/EXIT CONF button.
The station defaults configuration and
calibration data. Reconfigure and
recalibrate all inputs and outputs.
Install option or press ENTER/EXIT
CONF button to remove FB from ESN
table.
Install option or press ENTER/EXIT
CONF button to remove FB from ESN
table.
Install option or press ENTER/EXIT
CONF button to remove FB from ESN
table.
October 1998
UM348-1
MAINTENANCE
On-Line Error Codes
The error codes in Table 6-2 will appear on the alphanumeric display if a failure is encountered during the
FIELDPAC's on-line operation.
TABLE 6-2 On-Line Error Codes
ERROR
CODE
E1
E2
E3
DEFINITION
MPU Board A/D
Error
340 Capsule A/D
Error
PROBLEM
CONFIRMATION
Remove and reapply
station power.
Remove and reapply
station power.
Temperature
Input A/D Error
Remove and reapply
station power.
CORRECTIVE
ACTION
Replace MPU board.
Verify that the flex cable from
340 pressure sensor is properly
and fully inserted into mating
connector on MPU board. Check
for visible damage. Power cycle
the 348 to see if it occurs again.
Problem may either be sensor
assembly or MPU board.
Replace either board to determine
which board it is or contact
Moore Products Co. for service
or replacement.
Verify the temperature input
board is properly and fully
inserted into MPU board
connectors. Check for damaged
or misaligned pins. Problem may
either be temperature board or
MPU board. Replace either
board to determine which board
it is or contact Moore Products
Co. for service or replacement.
6.5 ASSEMBLY REPLACEMENT
As is the case with most electronic assemblies populated with semiconductor components, precautions must be
observed to prevent component damage from ESD (i.e., electrostatic discharge). Accordingly, a maintenance kit
containing a wrist strap and a conductive mat must be used whenever an assembly, such as the display/keyboard
panel, is removed from or installed in the station case.
Whenever an assembly is not installed in a station, it must be stored in a static shielding bag. These bags are 8" x
12" (20.3cm x 45.7cm) and are available from the factory under material code X6080. The MPU controller board
requires a larger bag.
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MAINTENANCE
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When unplugging ribbon cable from an assembly be sure to grip the connector, not the ribbon wire. Care should be
exercised when seating and unseating circuit boards.
Station calibration must be verified and if necessary calibrated after replacing any of the following plug-in circuit
boards or modules:
•
•
•
•
6-6
MPU Controller Board
Pneumatic Input Board
Process Pressure Input Transducer
I/P Module (recommended)
October 1998
UM348-1
MAINTENANCE
6.5.1 Upper Door Assembly
The upper door assembly uses 2 metal hinges and 4 captive screws to attach to the enclosure (refer to Figure 6-1).
Earlier versions of the upper door assembly used plastic molded hinges instead of metal hinges.
Captive
Screw
4 Places
Upper
Door
Hinge
4 Places
4-40 X 0.375
4 Places
X02896S0
FIGURE 6-1 Upper Door and Terminal Compartment Cover
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6-7
MAINTENANCE
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REMOVAL:
1. Loosen the captive screw at each corner of the upper door and swing the door open.
2. Place a conductive wrist strap on your wrist and ground the strap to the controller casting to prevent
electrostatic discharge from damaging an electrical component.
3. Refer to Figure 6-2 and disconnect the multi-color ribbon cable by opening the eject levers and carefully pulling
the connector from the display interface board.
Upper Door
Captive Screws
4 Places
To Secure Door
Contrast Adjustment
(Backlit Display)
Connector Eject Lever
2 Places
Contrast Adjustment
(Non-Backlit Display)
Multi-Color
Ribbon Cable
Display Interface Board
(Non-Backlit Display)
Membrane Keyboard Cable
X02898S0
FIGURE 6-2 Upper Door Assembly
4. Refer to Figure 6-2 and disconnect the membrane keyboard flexible-circuit ribbon cable from the display
interface board by carefully pulling the black connector from the display interface board.
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October 1998
UM348-1
MAINTENANCE
5. Refer to Step A if door has metal hinges or Step B if door has molded hinges.
A. Remove the screws from the 2 metal hinges and take the door off.
B. Hold the controller in place and remove the upper door by continuing the door opening motion
Upper Door
Housing Casting
Metal U-Shaped Hinge
2 Places
4-40 X 0.375
Flat Head Screw
2 Places
X02897S1
FIGURE 6-3 Rear View of Hinge Assembly
HINGE INSTALLATION:
1. Ensure the wrist strap is connected to the ground screw on the right side of the FIELDPAC enclosure.
2. Place the new door in its closed position over the housing casting and gently tighten the four captive screws.
3. Refer to Figures 6-1 and 6-3, and insert a hinge into the back edge of the door at the top rectangular opening.
Align the threaded hole in the hinge with the countersunk hole in the side of the door and insert a #4 flat head
screw. Gently tighten the screw -- do not over tighten to avoid stripping hinge threads.
4. At the lower rectangular cutout in the door, insert and fasten the second hinge. Loosen the four captive screws
securing the door. The door should now open and close freely.
5. If the display interface board removed above is to be installed, fasten it to the inside of the door using the
original four screws. Be sure that the membrane keyboard ribbon cable connector extends to the left of the
board, as it did with the original door.
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MAINTENANCE
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6. Connect the membrane Keyboard cable and the multi-colored ribbon cable to the display interface board.
7. Close the door and gently tighten the four captive screws. Remove the wrist strap.
6.5.2 TERMINAL COMPARTMENT COVER
To replace the Terminal Compartment Cover use the following procedure:
REMOVAL:
1. Open the terminal compartment cover by unscrewing the four 10-32 x 5/8" captive screws and swinging it open
on its left hinges.
2. Refer to Figure 6-1 and carefully remove the two #4 screws from the hinges while holding on to the door..
3. Discard the defective cover.
INSTALLATION:
1. Remove the new terminal compartment cover from its shipping container. Place new cover in its closed position
over terminal board area of housing and gently tighten the four captive screws.
2. Refer to Figures 6-1 and 6-3 and insert a hinge into the back edge of the cover at the top rectangular opening.
Align the threaded hole in the hinge with the countersunk hole in the side of the cover and insert a #4 flat head
screw. Gently tighten the screw -- do not over tighten to avoid stripping the hinge threads.
3. At the lower rectangular cutout in the cover, insert and fasten the second hinge. Loosen the four captive screws
securing the cover to the housing. The cover should open and close freely.
6-10
October 1998
UM348-1
MAINTENANCE
6.5.3 AC Power Supply
To replace or install the AC power supply, refer to Figure 6-4 and use the following procedure:
REMOVAL:
1. Turn OFF power to the FIELDPAC.
WARNING
Electrical shock hazard - Remove power from the FIELDPAC before removing the AC
power supply.
2. Connect a wrist strap to the ground screw on the right side of the FIELDPAC enclosure.
3. Open the display/keyboard cover assembly by unscrewing the four 10-32 x 5/8" captive screws and swinging it
open to the left on its hinges.
4. Remove the four 4-40 x 1.5" screws that secure the AC power supply to the four stand-offs on the MPU
controller board.
5. Unplug the defective AC power supply module from its mating connector on the MPU controller board.
INSTALLATION:
1. Ensure power is OFF at the FIELDPAC and wrist strap is connected to the ground screw on right side of
FIELDPAC enclosure.
WARNING
Electrical shock hazard - Remove power from the FIELDPAC before installing the AC
power supply.
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6-11
MAINTENANCE
UM348-1
Controller Board
Power Suppply
Standoffs
X02952S0
FIGURE 6-4 Power Supply Removal/Installation
2. Remove the new AC power supply module from its static shielding bag.
3. Check the presence and security of the four 1" stand-offs on the MPU controller board. If necessary, install
and/or tighten the stand-offs.
4. Line up the connector pins of the new AC power supply with the mating connector on the MPU controller board
and push the power supply against the MPU controller board until the connector pins are properly engaged and
the Power Supply rests on the 1" stand-offs.
5. Insert the four 4-40 x 1.5" screws into the appropriate holes in the power supply and secure it to the four standoffs.
6.5.4 Temperature Sensor Board
To replace or install the temperature sensor board, refer to Figure 6-5 and use the following procedure:
REMOVAL:
1. Remove power from the FIELDPAC.
2. Connect a wrist strap to the ground screw on the right side of the FIELDPAC enclosure.
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October 1998
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MAINTENANCE
3. Open the display/keyboard cover Assembly by unscrewing the four 10-32 x 5/8" captive screws and swinging it
open on its left hinges.
4. Remove the four 4-40 x 0.25" screws and associated flat washers that secure the temperature sensor board to the four
standoffs on the MPU controller board.
5. Unplug the defective temperature sensor board from its mating connectors on the MPU controller board.
Controller Board
Temperature Sensor
Board
Temperature Sensor Board Installation
X02951S0
FIGURE 6-5 Temperature Sensor Board Removal/Installation
INSTALLATION:
1. Ensure power is OFF at the FIELDPAC and wrist strap is connected to the ground screw on right side of
FIELDPAC enclosure.
2. Remove the new temperature sensor board from its static shielding bag.
3. Check the presence and security of the four 1" standoffs on the MPU controller board. If necessary, install
and/or tighten the standoffs.
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MAINTENANCE
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4. Line up the connector pins of the temperature sensor board with the mating connectors on the MPU controller
board and push the temperature sensor board against the MPU controller board until both connectors are
properly engaged and the board rests on the 1" standoffs.
5. Insert four 4-40 x 0.25" screws (with flat washers) into holes in the temperature sensor board and secure to the
four standoffs.
6.5.5 Pneumatic Input Board
To replace or install a pneumatic input board, refer to Figure 6-6 and use the following procedure:
REMOVAL:
1. Remove power from the FIELDPAC.
2. Connect a wrist strap to the ground screw on the right side of the FIELDPAC enclosure.
3. Open the display/keyboard cover Assembly by unscrewing the four 10-32 x 5/8" captive screws and swinging it
open on its left hinges.
4. Remove the four 4-40 x 0.25" screws and associated flat washers that secure the pneumatic input board to the
four standoffs on the MPU controller board.
5. Disconnect the pneumatic tubing from the manifold.
6. Unplug the defective pneumatic input board from its mating connector on the MPU controller board.
INSTALLATION:
1. Ensure power is OFF at the FIELDPAC and wrist strap is connected to the ground screw on right side of
FIELDPAC enclosure.
2. Remove the new pneumatic input board from its static shielding bag.
3. Check the presence and security of the four 1" standoffs on the MPU controller board. If necessary, install
and/or tighten the stand-offs.
4. Line up the connector pins of the pneumatic input board with the mating connector on the MPU controller board
and push in the pneumatic input board until it rests on the 1" standoffs.
5. Insert the four #4-40 x 0.25" screws into the appropriate holes in the pneumatic input board and secure it to the
four stand-offs.
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October 1998
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MAINTENANCE
6. Check to see that a valve body (P/N 16161-80) is installed in the enclosure manifold for each pneumatic input
used (one or three). If this is a replacement installation, a valve body will already be in place for each input. In
upgrade installations, a valve body must be installed (using non-permanent Loctite) for each needed input.
7. Connect the pneumatic tubing originating at the pneumatic input board to the corresponding pneumatic
connection(s) at the enclosure manifold.
Controller Board
Connectors
Pnuematic Input
Board
Pnuematic Tubing
Pneumatic Input Board Installation
X02950S0
FIGURE 6-6 Pneumatic Input Board
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MAINTENANCE
UM348-1
6.5.6 Pneumatic Output Board
To replace or install the pneumatic output board, refer to Figure 6-7 and use the following procedure:
Pneumatic Output
Board
Pneumatic Output Board Installation
X02954S0
FIGURE 6-7 Pneumatic Output Board
REMOVAL:
1. Remove power from the FIELDPAC.
2. Connect a wrist strap to the ground screw on the right side of the FIELDPAC enclosure.
3. Open the display/keyboard cover assembly by unscrewing the four 10-32 x 5/8” captive screws and swinging it
open on its left hinges.
4. Remove the pneumatic output board by unscrewing the single captive screw, and unplug the board from its
mating connector on the MPU controller board.
INSTALLATION:
1. Ensure power is OFF at the FIELDPAC and wrist strap is connected to the ground screw on right side of
FIELDPAC enclosure.
2. Remove the new pneumatic output board from its static shielding bag.
6-16
October 1998
UM348-1
MAINTENANCE
3. Line up the connector pins of the pneumatic output board with the mating connector on the MPU controller
board and push the pneumatic output board against the MPU controller board until the connector is properly
engaged.
4. Tighten the single captive screw to secure the board to the enclosure.
6.5.7 Direct Pressure Sensor Input
To replace or install the direct pressure sensor input, refer to Figure 6-8 and use the following procedure.
REMOVAL:
1. Remove power from the FIELDPAC.
2. Ground the wrist strap.
3. If removing a Model 340D sensor, remove two screws securing the mounting bracket from the sensor.
4. Open the upper door assembly by unscrewing the four captive screws and swinging it open on its left hinges.
5. Unplug the sensor connector from the MPU controller board.
6. Remove the retaining screw.
7. Remove the 1/4 plug/set screw using an allen wrench.
8. Remove the sensor by carefully pulling it out of the enclosure.
INSTALLATION:
1. Ensure power is OFF at the FIELDPAC and the wrist strap is grounded.
2. Remove the sensor from its packaging.
3. Insert the sensor into the rear of the enclosure. Notice the orientation shown in the Figure.
4. When using a Model 340 A/G Sensor, install the retaining screw inside the enclosure.
5. Connect the cable to the MPU controller board. Notice that the connector is keyed.
6. Install the ¼ plug/setscrew, using an allen wrench, to secure the sensor.
7. If installing a Model 340D Sensor, install the mounting bracket.
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MAINTENANCE
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High Pressure Port Symbol
Backplate with Sensor
Mounting Hole and Plug
Upper Door Shown
U-Shaped Hinge
Sensor, Model 340D or
Model 340A/G with
Tantalum Diaphragm
Sensor, Model 340A/G
MPU Controller
Board
P4
Nameplate
Setscrew
4-40 X 0.375
Retaining Screw Hole,
O-Ring, Then Snap Ring
X03146S1
Power
Supply
Upper Door
Pneumatic
Input Board
I/P Module
Lower Door
FIGURE 6-8 Direct Pressure Sensor Input
6.5.8 MPU Controller Board
To replace or install the MPU controller board, refer to Figure 6-9 and use the following procedure:
REMOVAL:
1. Remove power from the FIELDPAC.
2. Ground the wrist strap.
3. Open the upper door assembly by unscrewing the four captive screws and swing it open on its left hinges.
Disconnect the MPU controller board ribbon cable from the display board.
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October 1998
UM348-1
MAINTENANCE
4. Remove and label all wiring connections. If a direct pressure sensor Input is installed, refer to “Direct Pressure
Sensor Input” section and remove the direct pressure sensor Input. If a pneumatic input board is installed,
disconnect the pneumatic tubing from the pneumatic connections at the enclosure manifold.
5. Remove the eight screws which attach the rear plate to the enclosure.
6. Remove the nine screws which attach the board to the case.
7. Lift the board from the case.
INSTALLATION:
1. Ground the wrist strap.
2. Remove the circuit board from the static shielding bag.
3. Lower the board onto the case and connect it by installing the nine screws.
4. Connect the rear plate to the enclosure by installing the eight screws.
5. Install the direct pressure sensor Input and the pneumatic tubing connections, if necessary.
6. Reconnect all wiring connections to the terminal blocks.
7. Connect the MPU controller board ribbon cable to the Display board.
8. Close the upper door assembly and secure it using the four captive screws.
9. Reconfigure and calibrate the MPU controller board.
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6-19
MAINTENANCE
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Enclosure
MPU Board
Back Plate
X03012S0
FIGURE 6-9 MPU Controller Board
6-20
October 1998
UM348-1
MAINTENANCE
6.6 RECOMMENDED SPARE AND REPLACEMENT PARTS
It is recommended that one spare of each of the following items be stocked for every 1 to 25 units in service:
•
•
•
•
•
•
•
•
Fuses
Display/Keyboard Cover Assembly
AC Power Supply
Temperature Sensor Board (if used)
Pneumatic Input Board (if used)
Pressure Sensor (if used)
I/P Module (if used)
MPU Controller Board
The Parts Lists in the back of this manual lists the Model 348 Field Mounted Controller module assemblies and
parts that are available from the factory.
IMPORTANT
When ordering a replacement or spare assembly, provide the following data from the
assembly to be replaced or spared: part number, software version, and serial number.
An item being returned to the factory should be packaged in its original shipping container. Otherwise, package for
safe shipment or contact the factory for shipping recommendation. Send package to one of the addresses given in
the Warranty Statement.
IMPORTANT
A circuit board must be placed in a static shielding bag before it is packaged for shipment.
6.7 MAINTENANCE RECORDS
An accurate record keeping system for maintenance operations should be established and kept up to date. Data
extracted from the record can serve as a basis for ordering supplies such as spare parts. In addition, it is useful as
a troubleshooting tool by providing historical maintenance data. Scheduled and unscheduled maintenance should be
recorded.
6.8 TO RETURN EQUIPMENT
•
Call the Service Department at +1 215 646 7400, ext. 4RMA (4762) weekdays between 8:00 a.m. and 4:45
p.m. Eastern Time to obtain an RMA number. Mark the RMA number prominently on the outside of the
shipment.
October 1998
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MAINTENANCE
•
UM348-1
When calling for an RMA number, provide the reason for the return. If returning equipment for repair, failure
information (e.g., error code, failure symptom, installation environment) will be requested. A purchase order
number will also be needed.
MATERIAL SAFETY DATA SHEET
•
A Material Safety Data Sheet (MSDS) must be included with each item being returned that was stored or used
anywhere hazardous materials were present.
PACKAGING
•
Package assembly in original shipping materials. Otherwise, package it for safe shipment or contact the factory
for shipping recommendations.
•
A module must be placed in a static shielding bag to protect it from electrostatic discharge.
n
6-22
October 1998
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CONFIGURATION
7.0 CONFIGURATION
Configuration is accomplished by designing and then entering a controller strategy into the FIELDPAC to meet an
individual process requirement. This is done by selecting function blocks from an available library, deciding how to
interconnect them, and entering this configuration into the FIELDPAC.
The simplest way is to select a Factory Configured Option (FCO) and make minor changes, as necessary, to meet
individual requirements. This approach will satisfy a large percentage of process control designs. The FCO's are
documented in section 9 of this manual.
In cases where a ‘Design From Scratch’ approach is used, the following guidelines will be useful in completing a
configuration:
Draw a diagram of the blocks and the interconnections. Include the identifying numbers and letters of all block
inputs and outputs that are used. The diagrams of the FCO's in “FCO” section are examples of these diagrams.
The main purpose of the diagram is to illustrate the operation of the controller design and assist in filling out the
Configuration Documentation in Appendix B.
Complete the configuration booklet, filling in the parameters for all the function blocks being used. Some
parameters, particularly the Soft (S), may not be know initially and can be filled-in at a later time.
7.1 CONFIGURATION MODES
T - Execution Sequence Numbers (ESN) should be assigned to each function block being used. The ESN is usually
not critical, but inputs to a block should normally be executed before the block executes. It is also recommended to
skip numbers to allow for future additions. Numbers 00 to 99 can be used, with 00 indicating that the block is not
being used. Only those blocks with non zero execution numbers are active in the other configuration modes, thus
limiting entry of configuration parameters to blocks of your choosing.
H - Hard Configuration, generally assigns specific block functions and interconnections (function blocks are 'wired'
together). Block inputs can be assigned numbers from 00 to 99 representing outputs from other blocks.
S - Soft Configuration, generally covers variable parameters such as tuning constants, gains, etc. that may change
periodically depending on the application.
C - Calibration is provided to standard requirements when shipped from the factory and should not be required
unless changes are necessary. Complete information regarding calibration can be found section 4.
V - View allows each block output to be viewed as a 0-100% value. This mode is useful in the troubleshooting of
configuration designs.
F - Factory Configured Options are available to simplify the entry of many standard configuration requirements.
These designs can also be used as guides for individual designs.
October 1998
7-1
CONFIGURATION
UM348-1
Enter the information from the configuration booklet into the FIELDPAC using the pushbuttons on the faceplate.
Detailed information on the use of the pushbuttons can be found under “Operator's Display” section.
P -888888 ABCD
PB1
S
100
D
P
80
PB2
60
40
AUTO
MAN
20
0
CLOSED
ENTER
EXIT
CONF
TUNE
VALVE
TAG
STORE
OPEN
ACK
STEP
UP
ALARM
STEP
DOWN
Check the configuration by simulating inputs and monitoring the outputs. Individual block outputs can be viewed
using the View Mode (V).
A Configuration Software Package is also available that simplifies the configuration process. This software will
enable the uploading of existing configurations, resident in the Field Mounted Controller, and provide the capability
of editing the configuration and saving it to disk. Configurations can also be printed in a form very similar to the
Configuration Booklet. The software also provides for the downloading of a configuration to a Field Mounted
Controller.
The configuration controls on the faceplate of the Model 348 are used to select a specific parameter and then enter
a value for that parameter. This page provides an overview of that procedure. For those familiar with the Model
352, the functions are very similar but there are some differences. Read this page carefully (e.g. the ----> button
changes the digit that will be changed by the UP/DOWN arrow buttons).
ENTER
EXIT
CONF
7-2
Push to enter the Configuration Mode. Enters at the menu level. The Step Down button will move
you to a new configuration level.
October 1998
UM348-1
CONFIGURATION
MENU LEVEL
Alphanumeric Display
S
Push Up/Down Buttons to change
ACK
STEP
UP
ALARM
STEP
DOWN
FUNCTION BLOCK LEVEL
0 1
S
Alphanumeric Display
Push Up/Down Buttons to change
ACK
STEP
UP
ALARM
STEP
DOWN
PARAMETER LEVEL
S d V
1
Alphanumeric Display
Push Up/Down Buttons to change
ACK
STEP
UP
ALARM
STEP
DOWN
VALUE LEVEL
1
2
0
S d V 1
Alphanumeric
Display
Push Up/Down Buttons to
change value
Push D Button to move Decimal
Point if applicable
TUNE
Use Arrow Button to select digit
to be changed
ACK
STEP
UP
October 1998
ALARM
STEP
DOWN
7-3
CONFIGURATION
TAG
STORE
ENTER
EXIT
CONF
UM348-1
Push to store value in the display
(only active at the Value Level)
Push to Exit Configuration
(Active at any level)
The operators display can be configured to meet individual requirements using the parameters available in FB15.
This page provides an overview of this display from an operator's perspective.
P -888888 ABCD
PB1
S
100
D
P
80
PB2
60
40
AUTO
MAN
20
0
CLOSED
ENTER
EXIT
CONF
TUNE
VALVE
TAG
STORE
OPEN
ACK
STEP
UP
ALARM
STEP
DOWN
Digital Display
Displays operator and configuration information. Located at the top of the faceplate, it includes: one alphanumeric
character to indicate the variable being displayed; a minus sign; six characters to indicate the numeric value of the
variable (also used in configuration for parameter selections); four alphanumeric characters to indicate engineering
units, status mnemonic, or configuration mnemonics.
D Pushbutton
Used to step the digital display through a sequence of the following variables which may be active depending on the
individual configuration.
7-4
October 1998
UM348-1
CONFIGURATION
P - Process. The digital value of the variable displayed in the vertical bargraph P. The 4-character alphanumeric,
displays the configured engineering units. In cases where 2 loops have been configured (e.g. Cascade) two process
variables are available and the configuration should provide a means (e.g. PB1, PB2, ...) to select the proper
process variable for display.
S - Setpoint. The digital value of the variable displayed in the vertical bargraph S. The 4-character alphanumeric
will display the configured engineering units, the same as the Process in a Loop configuration. When the setpoint is
displayed, the value can be changed, provided the setpoint is active and not in a tracking mode. In cases where 2
loops have been configured (e.g. Cascade) two setpoints may be available and the configuration should provide a
means (e.g. PB1, PB2, ...) to select the proper setpoint variable for display and change.
V/O - Valve/Output. The digital value of the variable displayed in the horizontal bargraph. The 4-character
alphanumeric will display PRCT for this variable. In cases where 2 loops have been configured two valve/output
signals may be available (e.g. Cascade, generally will only have one valve) and the configuration should provide the
means (e.g. PB1, PB2, ...) to select the proper valve variable for display and change. This variable is configurable
for display as VALVE or OUT. The figure shows the faceplate with VALVE configured. When OUT is
configured, the words over the bargraph will be blanked out and '0 OUT 100' will appear under the bargraph. The
horizontal bargraph action can also be configured as DIRECT or REVERSE. This is useful when the bargraph is
indicating the valve position and a full bargraph always indicates an OPEN valve. The digital display, in either
case, will display the value in percent.
X - The digital value of the variable X. The 4-character alphanumeric will display the configured engineering
units for this variable. This is active, only when INX is configured for FB15.
Y - The digital value of the variable Y. The 4-character alphanumeric will display the configured engineering units
for this variable. This is active, only when INY is configured for FB15.
R - The value of the RATIO. This will only be displayed when FB07 is active.
B - The value of the BIAS. This will only be displayed when FB08 is active. BIAS can be configured for display
as PRCT or the engineering units of the variables P1 (Process 1), P2 (Process 2), X, or Y.
C - The total counts of the totalizer block FB16. The 4-character alphanumeric will display the count units (e.g.
GAL).
M - The Multiplier to be used with the count (e.g. if the display has a value of 120 and M = 1000, the actual count
would be 120,000 GAL).
1 - The value of Preset 1 for the totalizer. This will have the same units and multiplier as COUNT.
2 - The value of Preset 2 for the totalizer. This will have the same units and multiplier as COUNT.
PB1 Pushbutton
A general purpose pushbutton associated with FB23 that can be configured as momentary or sustained and used in
a variety of applications from starting or stopping logic functions to switching between loops. LCD triangle
October 1998
7-5
CONFIGURATION
UM348-1
indicators show the position of the sustained pushbutton action. This particular button is also reserved for selecting
Console/Local control, if required.
PB2 Pushbutton
A general purpose pushbutton associated with FB11 that can be configured as momentary or sustained and used in
a variety of applications. LCD triangle indicators show the position of the sustained pushbutton action.
AUTO/MAN Pushbutton
This pushbutton is usually associated with A/M Transfer Switch #1 (FB14) and may also be associated with A/M
Transfer #2 (FB55) when two loops have been configured. The LCD triangle indicators show the position of the
sustained pushbutton action. This function should always be associated, through configuration, with the signal
being displayed as the Valve or Output.
UP/DOWN Pushbutton
These pushbuttons change the value of the displayed variable (e.g. when B is displayed, the buttons change the
BIAS value). The one exception is that the Valve/Output can still be changed while displaying the respective
Process variable.
Status Window
The four character display will normally show the engineering units of the displayed variable. When a status
condition occurs, such as an alarm, the status will stack up behind the engineering units and can be viewed by
pressing the ACK pushbutton. When a status is present, the decimal points in the four character display will blink.
This indicates that the window for the statuses, can be opened to view them. While viewing the statuses the
blinking will stop. If the ACK button is not pressed for 5 seconds, the window will close, again displaying the
engineering units.
The status display will have the following format:
A2*3
The first two characters indicate the status condition (e.g. A2 represents Alarm #2). The asterisk indicates that at
least one of the statuses is an active alarm and the number indicates the total number of statuses that can be
displayed. The complete list of status mnemonics is in table 1 of the FB15 description.
Bargraph Flashers
Any of the status conditions can be configured (parameters HFL1 to HFL5 in FB15) to cause the bargraphs to
flash. When a status condition occurs that has been configured, the bargraphs will flash on & off and the status
window will open automatically showing the status mnemonic that caused the flashing to occur. When the flashing
has been acknowledged and there are no more flashing statuses, the status window will return to normal operation,
and display any engineering units.
7-6
October 1998
UM348-1
CONFIGURATION
TUNE Pushbutton
Pressing the TUNE button will first cause 'LOOP 1 TUNE' to appear in the 4-character display if FB13 has been
configured. When 'LOOP _ TUNE' has been selected, repeated pressing of the STEP DOWN button will step
through the tuning parameters for that loop controller. STEP UP will reverse the sequence.
TAG Pushbutton
Pressing the TAG button will cause the loop tag\s (as configured in FB15) to scroll through the 4-character display.
The time required to scroll the tag is also configurable in FB15.
ALARM Pushbutton
Pressing the ALARM button will first cause 'LOOP 1 ALM' to appear in the 4-character display if FB12 has been
configured. Pressing the ---> button will cause 'LOOP 2 ALM' to appear if FB73 has been configured. Repeated
pressing of the STEP DOWN button will step through the tuning parameters for that loop alarm. STEP UP will
reverse the sequence.
ACK Pushbutton
The ACK button can be used to open the 4-character window to display and step through any active statuses (e.g.
Alarms). It is also used to acknowledge flashing bargraphs and the associated status.
n
October 1998
7-7
CONFIGURATION
7-8
UM348-1
October 1998
UM348-1
FUNCTION BLOCK DESCRIPTIONS
8.0 FUNCTION BLOCK DESCRIPTIONS
This section provides a detailed description and specifications for each function block type. It also provides
function block connection details and listings of all configuration parameters.
TABLE 8-1 Function Block by Type
FUNCTION BLOCK
TYPE
8.1 Analog Input
8.2 Analog Output
8.3 Digital Input
8.4 Digital Output
8.4.1
8.4.2
8.4.3
8.5 Pressure Sensor Input
8.6 Temperature Sensor
8.7 Pneumatic Input
8.8 Controller
8.8.1
8.8.2
8.8.3
8.8.4
8.9 Transfer
8.9.1
8.9.2
8.9.3
8.9.4
8.10 Track & Hold
8.10.1
8.10.2
8.10.3
8.11 Signal Selector
8.12 Logic
8.12.1
8.12.2
8.12.3
8.12.4
FUNCTION BLOCK
NAME
Analog Input #1, #2, #3
Analog Output #1, #2
Digital Input #1, #2
FUNCTION BLOCK
NUMBER
1, 2, 25
3, 29
6, 30
PAGE
NUMBER
8-4
8-5
8-6
Digital Output #1, #2
Isolated-Digital Output #1, #2
Pulse Integrator
Pressure Sensor Input
Temperature Sensor
Pneumatic Input #1, #2, #3
4, 5
32, 33
28
81
82
85, 86, 87
8-7
8-8
8-9
8-10
8-11
8-12
PID Controller #1, #2
PD Controller #1, #2
ID Controller #1, #2
PIDA Controller #1, #2
13, 45
13, 45
13, 45
13, 45
8-13
8-15
8-17
8-19
A/M Transfer #1, #2
PB Transfer #1, #2
General Purpose Transfer
Triple Transfer Switch
14, 55
23, 11
49
71
8-21
8-23
8-24
8-25
Setpoint Track & Hold #1, #2
General Purpose Track & Hold
General Purpose Hold
Override Selector
17, 46
18
19
10
8-26
8-27
8-28
8-29
Logic #1 - #9
Delay Timer
One Shot Timer
Repeat Cycle Timer
20, 21, 48, 50, 61, 62, 88, 89,
90
65
67
47
8-30
8-31
8-32
8-33
(continued on next page)
October 1998
8-1
FUNCTION BLOCK DESCRIPTIONS
UM348-1
TABLE 8-1 Function Block by Type (Continued)
8.13 Ratio & Bias
8.13.1
8.13.2
8.14 Hi/Lo Limit
8.15 Alarms
8.15.1
8.15.2
8.16 Operator’s Display
8.17 Dynamic
Compensation
8.17.1
8.17.2
8.17.3
8.17.4
8.18 Math
8.18.1
8.18.2
8.18.3
8.18.4
8.18.5
8.18.6
8.19 Miscellaneous
8.19.1
8.19.2
8.19.3
Ratio
Bias
Hi/Lo Setpoint Limit #1, #2
7
8
9, 51
8-34
8-35
8-36
Alarm #1, #2
Quad Comparator
Operators Display
12, 73
64
15
8-37
8-39
8-40
Lag
Lead
Rate Limiter
Dead Time Table
40
41
42
43
8-43
8-44
8-45
8-46
Math #1, #2, #3
Gain & Bias #1, #2
Deviation Amplifier
Square Root Extractor
Integrator/Totalizer
10 Segment Characterizer #1, #2
34, 35, 36
38, 39
22
24
16
44, 72
8-47
8-48
8-49
8-50
8-51
8-53
Batch Switch
Password Security
Hart Interface
53
75
98
8-54
8-55
8-56
Function Blocks (Numerical Order)
FB01
FB02
FB03
FB04
FB05
FB06
FB07
FB08
FB09
FB10
FB11
FB12
FB13
FB14
FB15
FB16
FB17
8-2
.................................................. Analog Input #1
.................................................. Analog Input #2
................................................ Analog Output #1
................................................. Digital Output #1
................................................. Digital Output #2
................................................... Digital Input #1
.................................................................... Ratio
..................................................................... Bias
....................................... Hi/Lo Setpoint Limit #1
................................................. Override Selector
.................................................... PB Transfer #2
.................................................... Alarm Block#1
................................................ PID Controller #1
.................................................. A/M Transfer #1
................................................. Operator Display
............................................. Integrator/Totalizer
.................................... Setpoint Track & Hold #1
FB18
FB19
FB20
FB21
FB22
FB23
FB24
FB25
FB28
FB29
FB30
FB32
FB33
FB34
FB35
FB36
FB38
........................... General Purpose Track & Hold
......................................... General Purpose Hold
.................................................... Logic Block #1
.................................................... Logic Block #2
............................................ Deviation Amplifier
.................................................... PB Transfer #1
......................................... Square Root Extractor
.................................................. Analog Input #3
................................................... Pulse Integrator
............................................... Analog Output #2
.................................................. Digital Input #2
................................... Isolated Digital Output #1
................................... Isolated Digital Output #2
.................................................... Math Block #1
.................................................... Math Block #2
.................................................... Math Block #3
................................................... Gain & Bias #1
October 1998
UM348-1
FB39
FB40
FB41
FB42
FB43
FB44
FB45
FB46
FB47
FB48
FB49
FB50
FB51
FB53
FB55
FB61
FB62
................................................... Gain & Bias #2
..................................................................... Lag
................................................................... Lead
....................................................... Rate Limiter
................................................ Dead Time Table
.............................. 10-Segment Characterizer #1
............................................... PID Controller #2
................................... Setpoint Track & Hold #2
............................................ Repeat Cycle Timer
................................................... Logic Block #3
................................... General Purpose Transfer
................................................... Logic Block #4
...................................... Hi/Lo Setpoint Limit #2
...................................................... Batch Switch
................................................. A/M Transfer #2
................................................... Logic Block #5
. .................................................. Logic Block #6
October 1998
FUNCTION BLOCK DESCRIPTIONS
FB64
FB65
FB67
FB71
FB72
FB73
FB75
FB81
FB82
FB85
FB86
FB87
FB88
FB89
FB90
FB98
................................................ Quad Comparator
........................................................ Delay Timer
.................................................. One Shot Timer
........................................ Triple Transfer Switch
.............................. 10-Segment Characterizer #2
................................................... Alarm Block #2
............................................... Password Security
................................................... Pressure Sensor
............................................ Temperature Sensor
............................................. Pneumatic input #1
............................................ . Pneumatic input #2
............................................. Pneumatic input #3
.................................................... Logic Block #7
.................................................... Logic Block #8
.................................................... Logic Block #9
...................................................... Hart Interface
8-3
FUNCTION BLOCK DESCRIPTIONS
UM348-1
8.1 ANALOG INPUT #1/#2/#3
FB01/FB02/FB25
ANALOG INPUT #1 / #2 / #3
FB01 / FB02 / FB25
These function blocks convert an analog voltage with
a range defined during calibration into a 0-100%
block output signal for interconnection to other
function blocks.
FB01 / FB02 / FB25
Also included is a digital filter, to dampen process
noise and a square root extractor to linearize a flow
signal from a DP transmitter. When the square root
extractor is enabled, the function block output is low
limited to 0%. See Function Block 24 for more
details on the square root extractor function.
Calibration details can be found in section 4, of this
manual.
AI*+
1-5 Vdc
AI*C
XTR
*
OUTPUT
ANALOG INPUT #1 / #2 / #3
S D V ** DAMPING VALUE ....................... 0 to 180 SEC
C Z I ** ZERO INPUT .............................. 0.0 to 1.0 Vdc
C F I ** FULL SCALE INPUT ................... 4.0 to 5.0 Vdc
C V I ** VERIFY INPUT .................... -10.00 to 110.00%
H S
R E SQUARE ROOT EXTRACTOR .......... NO/YES
* See Output Identifications and Terminal Designations
** FB01: 1, FB02: 2, FB25: 3
A verify mode is available in calibration to view the
input as a 0-100% block output signal over the full
calibrated range.
FB01 is not available when FB85, FB86, or FB87 is
configured.
FB25 is not available when FB87 is configured.
FB
Number
01
Output
Identification
01
Specifications
Calibration: Zero: 0 to 1 Vdc
Span: 4 to 5 Vdc
Standard Calibration: 1 to 5 Vdc
Hardware Filter: 2 Hz (2-pole)
Damping Filter: 0 to 180 sec.
Accuracy: +/- 0.05% of span
A/D Resolution: 12 bit
A/D Linearity: LSB
Ambient Temp. Effect:
+/-0.50% D50 deg. C
Max. Continuous Input:
AI1+
+/- 30 Vdc
Input Impedance: > 1
megohm
02
02
25
30
330K
NO
330K
A/D
.33uf
Terminal
Designations
AI1+: F7
AI1C: F8
AI2+: F10
AI2C: F11
AI3+: F13
AI3C: F14
.33uf
DAMPING
XTR
YES
01
AI1C
BLOCK DIAGRAM
8-4
October 1998
UM348-1
FUNCTION BLOCK DESCRIPTIONS
8.2 ANALOG OUTPUT #1/#2
FB03/FB29
ANALOG OUTPUT #1 / #2
FB03 / FB29
This function block converts a 0-100% block
interconnection signal into a 4-20 mAdc analog
output. Also included is a switch that will disconnect
the output from the load. This feature is useful when
two or more outputs are connected to the same load.
Calibration details can be found in section 4 of this
manual.
FB03 / FB29
Pneumatic Specifications
Accuracy: +/- 0.25% of span
Amb. Temp. Effect: +/- 1.0% 50 deg. C
ANALOG
OUTPUT
AO*C
4-20 mA dc
A
SIGNAL
B
ON/OFF
ANALOG OUTPUT #1/ #2
C Z O **
C F O **
C V O **
H I N A
Pneumatic Output Option (Analog Output #1
only)
A pneumatic output option is available that uses
Analog Output #1 to convert the block 0-100%
interconnection input signal into a pneumatic output
(3-15 PSIG or 3-27 PSIG). The current output
terminals should not be used when this option is
installed.
Specifications
Calibration: Zero: 4.0 mAdc +/- trim
Span: 16.0 mAdc +/- trim
Standard Calibration: 4-20 mAdc
Output Load: 0-800 ohm @ 24Vdc
Max. Output Current:
0 to Lm Ohms
DC Powered: Lm=[Vsupply-6.83v]/ 21.6 mA
AC Powered: Lm=800 Ohms
Min. Output Current: 3.5 mA
Accuracy: +/- 0.1% of span
Ambient Temp. Effect: <0.5% 50 deg. C
Output Switch: Closed B>= 80%
Open B< 75%
AO*+
H I
N B
ZERO OUTPUT ............................. 4.0 mAdc
FULL SCALE OUTPUT ............... 20.0 mAdc
VERIFY OUTPUT ............... -10.0 to 110.0%
INPUT A (SIGNAL) .......................... 00 to 99
INPUT B (ON/OFF) .......................... 00 to 99
* See Terminal Designations
** FB03: 1, FB29: 2
FB
Number
03
29
Terminal
Designations
AO1+: E11
AO1C: E12
AO2+: E13
AO2C: E14
A
AO*+
D/A
B
AO*C
I/P
PNEUMATIC OUTPUT OPTION
(used with Analog Output #1 only)
BLOCK DIAGRAM
October 1998
8-5
FUNCTION BLOCK DESCRIPTIONS
UM348-1
8.3 DIGITAL INPUT #1/ #2
FB06/FB30
DIGITAL INPUT #1 / #2
FB06 /FB30
This function block converts an ON/OFF input signal
into a block interconnection signal that is 0% when
the input is OFF and 100% when the input is ON.
The normal ON input voltage is 24Vdc.
FB06 / FB30
DI*+
*
OUTPUT
DI*C
This block is often used for connecting on/off
external signals to internal logic inputs such as
Acknowledge (FB15), Emergency Manual (FB14),
Standby Sync (FB14), ... .
Specifications
ON Voltage: 12-30 Vdc
OFF Voltage: 0-5 Vdc
Input Current @ 24Vdc: 10 mAdc
Overvoltage Protection: 30 Vdc
Isolation: 100 Vdc
Action: Input > 12 Vdc O=100%
Input < 5 Vdc O=0%
DIGITAL INPUT #1 / #2
* See Output Identifications and Terminal Designations
FB
Number
06
30
Output
Identifications
Digital Input
Signal: 16
Digital Input
Signal: 58
Terminal
Designations
DI1+: E7
DI1-: E8
DI2+: E9
DI2-: E10
DI*+
24 Vdc
POWER
SUPPLY
DI*TYPICAL EXTERNAL
CIRCUIT DIAGRAM
BLOCK DIAGRAM
8-6
October 1998
UM348-1
FUNCTION BLOCK DESCRIPTIONS
8.4 DIGITAL OUTPUT
DIGITAL OUTPUT #1 / #2
FB04 / FB05
8.4.1 DIGITAL OUTPUT #1/#2
FB04/FB05
FB04 / FB05
These function blocks provide a solid state output
switch that turns on when input A goes high (>=80%)
and will turn off when input A goes low (<75%) or is
not configured.
A
DO*+
ON/OFF
DO*C
DIGITAL OUTPUT #1 / #2
The digital output can be powered from the same
24Vdc supply powering the Model 348 noting that
the negative side of the power supply is tied to the
Model 348 COMMON. On AC powered units the
80mA transmitter supply can be used for small loads
or an external dc supply for larger loads.
H
I
N
A INPUT A (ON/OFF) ...........................00 to 99
* See Terminal Designations
Additional details for connecting solid state outputs
to various loads such as relays and solid state
annunciators can be found in section 2 of this
manual.
FB
Number
04
Specifications
Output Type: MOSFET Transistor
Min. Load Voltage: 0 Vdc
Max. Load Voltage: 30 Vdc
Max. Load Current: 150 mAdc
Switch Action: Closed INA >= 80%
Open INA < 75%
Transistor ON Voltage: 0.6 Vdv @ 100 mA
Transistor OFF Leakage: 0.5 uA @ 30 Vdc
Terminal
Designations
DO1+: E1
DO1C: E2
DO2+: E3
DO2C: E4
05
DO*+
RELAY
24Vdc
POWER
SUPPLY
A
INPUT
DO*C
TYPICAL EXTERNAL
RELAY CIRCUIT
COMMON
BLOCK DIAGRAM
October 1998
8-7
FUNCTION BLOCK DESCRIPTIONS
8.4.2 ISOLATED DIGITAL OUTPUT #1/#2
FB32/FB33
UM348-1
ISOLATED DIGITAL OUTPUT #1 / #2
FB32 / FB33
FB32 / FB33
This function block provides an isolated digital
output. The Model 348S has opto transistor outputs
and the Model 348E, relay outputs with SPDT
contacts. The action of this function block can be
configured as direct acting so that the output
energizes when Input A goes high (>=80%) or
reverse acting so that the output de-energizes when
Input A goes high. The output will return to its
normal condition when Input A goes low (<75%).
IO*A
IO*C
ISOLATION
CIRCUIT
A
ON/OFF
IO*B
N A INPUT A (ON/OFF) ............................. 00 to 99
ACTION ** .......................................... REV/DIR
H A **
* See Terminal Designtions
** FB32: 1, FB33: 2
H
I
Specifications
Opto Transistor
Max. Load Voltage: 30 Vdc
Max. Load Current: 50 mAdc
ON Voltage: 10 V maximum @ 2 mA load
OFF Leakage: 50 nA maximum @ 30 Vdc
IO*A
Relay
Type: Epoxy Sealed
Contact Configuration: SPDT (Form C)
Contact Rating: 3 amp @ 250 Vac
IO*B
N.O.
N.C.
BLOCK DIAGRAM - RELAY OUTPUT
A
IO*A
33
8-8
Terminal Designations
IO1A: D2 (Relay NO or Opto +)
IO1C: D1 (Relay COM or Opto -)
IO1B: D3 (Relay NC)
IO2A: C2 (Relay NO or Opto +)
IO2C: C1 (Relay COM or Opto -)
IO2B: C3 (Relay NC)
INPUT
IO*C
Action
Direct: Energized .. A>=80%
De-energized A< 75%
Reverse: De-energized A>=80%
Energized .. A< 75%
FB Number
32
A
INPUT
IO*C
IO*B
BLOCK DIAGRAM -OPTO TRANSISTOR OUTPUT
October 1998
UM348-1
8.4.3 PULSE INTEGRATOR
FB28
This function block integrates input signal A and
provides a pulse output for driving an external
counter. The Pulse Integrator is configured by
setting the Full Scale rate, the Time Base, and the
Count Multiplier (similar to FB16). In addition, a
pulse width can be selected to meet the many
requirements of different counters.
As an example, a 0-100% input represents a flow
rate of 0-400 gal/min. Select SFS = 400, STB =
MIN, SCM = 1. If the input equals 50% (200
gal/min) for 1 hour the number of pulses sent out in
that hour would be 12000.
When the signal is being sent to a high speed
electronic counter the Pulse Width can be set at 0.4
msec. In cases where the counter requires a wider
pulse width, a pulse width equal to or greater than the
counter requirement should be selected. However, it
is important that the pulse width has a corresponding
pulse rate higher than the output rate required by a
full scale input signal. In cases where the Integrator
Pulse rate may be momentarily faster than the output
rate, pulses will be banked and sent out when
possible. The banking register has a capacity of 10
million but in most cases (if the pulse width is
selected correctly) will not be needed. In our
example, the function block would be required to
send out 24000 pulses in an hour when at full scale.
This corresponds to 6.7 pulses/sec. In this case, we
could set the pulse width at 53 msec since the
corresponding maximum pulse rate is 8.7/sec. See
Table FB28-1 for the complete listing.
In cases where the signal will be integrated over a
long period of time the external counter may
overflow. In this case a Count Multiplier greater
than 1 can be used. For increased resolution a
multiplier less than 1 is used.
FUNCTION BLOCK DESCRIPTIONS
PULSE INTEGRATOR
FB28
FB28
INTEGRATOR
PO+
A
SIGNAL
S
STOP
POC
S F S
S T B
S C M
S Z D
S P W
H
H
I
I
FULL SCALE VALUE ........ .000000 to 999999
TIME BASE ................. SEC/MIN/HR/DAY/WK
COUNT MULTIPLIER ....... .000001 to 999999
ZERO DROP OUT ....................... 0.0 to 30.0%
PULSE WIDTH .. 0.4/0.8/1.6/3.2/13/26/53/106
N A INPUT A (SIGNAL) ............................. 00 to 99
N S INPUT S (STOP) ................................ 00 to 99
Input is asserted any banked pulses will be sent out,
but new ones will not be added.
Specifications
Output Type: MOSFET Transistor
Max. Load Voltage: 30 Vdc
Max. Load Current: 150 mAdc
Transistor ON Voltage: 0.6 Vdv @ 100 mA
Transistor OFF Leakage: 0.5 uA @ 30 Vdc
TABLE FB28-1 Pulse Width and
Maximum Rate
Pulse Width
0.4 msec
0.8 msec
1.6 msec
3.2 msec
13 msec
26 msec
53 msec
106 msec
Max. Rate
1120/sec
520/sec
240/sec
80/sec
25/sec
14/sec
8.7/sec
4.5/sec
Input S (STOP) will stop integration of the input
signal when it goes high (>=80%). If the STOP
October 1998
8-9
FUNCTION BLOCK DESCRIPTIONS
8.5 PRESSURE SENSOR INPUT
FB81
UM348-1
PRESSURE SENSOR
FB81
This function block is active when a Process Pressure
Input option has been installed and FB81 has an
active execution sequence number. The block
provides parameters for selecting the range of the 0100% block output signal, a damping time constant,
and the option of linear or square root
characterization. The square root option is only
available on P sensor types.
The range and span limits are determined by the
particular sensor being used. See Table FB81-1 for
the various ranges associated with the Process
Pressure models.
FB Number
81
Output Identification
97
50*
55*
TABLE FB81-1 Process Ranges
8-10
FB81
97
OUTPUT
PROCESS
PRESSURE
55
CAPSULE
TEMPERATURE
DAMPING
50
STATIC
PRESSURE
EXTRACTOR
PRESSURE SENSOR
S
S
S
S
C
C
H
D
M
M
M
M
V
S
V
V
V
V
P
I
R
DAMPING VALUE ............................ 0-180 sec
MEAS. VARIABLE UNITS .......... Table FB81-2
MV RANGE LOW ............... -999999 to 999999
MV RANGE HIGH .............. -999999 to 999999
MOUNTING POSITION ................ Section 4.6
P VERIFY INPUT ................... -10.00 to 110.00%
E SQUARE ROOT EXTRACTOR ......... NO/YES
P
U
L
H
TABLE FB81-2 MV Units
1-InH20
8-mbar
2-InHG
9-SqCm
3-FtH20
10-kg/SqCm
4-mmH20
11-PA
340AD
10-450"H20(abs)
340AF
350"H20-450PSIA
5-mmHg
12-kPA
340DB
0.75-15"H20
6-psi
13-torr
340DD
10-450"H20
7-bar
14-ATM
340DF
350"H20-150PSIG
340GD
10-450"H20
340GF
350"H20-450PSIG
340GG
300-5500PSIG
Static
Pressure
Capsule
Temperatur
e
0-1200PSI
-40 to +125º C
October 1998
UM348-1
FUNCTION BLOCK DESCRIPTIONS
8.6 TEMPERATURE SENSOR
FB82
TEMPERATURE SENSOR
FB82
This function block is active when Analog Input
Option 'T' has been installed and FB82 has an active
execution sequence number. The block provides
parameters for selecting the input type, the range of
the 0-100% block output signal, and a damping time
constant.
FB82
PROCESS
TEMPERATURE
TABLE FB82-1 Input Types
0
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
Narrow Millivolt
Thermocouple Type 'R'
Thermocouple Type 'S'
Thermocouple Type 'T'
Thermocouple Type 'B'
Wide Millivolt
Thermocouple Type 'J'
Thermocouple Type 'K'
Thermocouple Type 'E'
Thermocouple Type 'N'
Narrow Ohm
RTD DIN 100
RTD US 100
Wide Ohm
RTD DIN 200
RTD DIN 500
RTD US 200
RTD US 500
DAMPING VALUE
TEMPERATURE SENSOR
S
S
S
S
C
C
C
C
C
C
C
C
C
H
H
D V P
M V U
M V L
M V H
WM Z
WM F
N M Z
N M F
WO Z
WO F
N O Z
N O F
V I P
I T
B O D
DAMPING VALUE.....................0-180 sec
MEAS. VARIABLE UNITS....Table FB82-2
MV RANGE LOW........-999999 to 999999
MV RANGE HIGH........-999999 to 999999
WIDE MILLIVOLT ZERO.................-18 mv
WIDE MILLIVOLT FS......................103 mv
NARROW MILLIVOLT ZERO..........-11 mv
NARROW MILLIVOLT FS.................26 mv
WIDE OHM ZERO...........................0 ohm
WIDE OHM FS...........................1875 ohm
NARROW OHM ZERO....................0 ohm
NARROW OHM FS......................470 ohm
VERIFY INPUT..............-10.00 to 110.00%
INPUT SENSOR TYPE.........Table FB82-1
BURNOUT DIRECTION...........UP/DOWN
TABLE FB82-2 Range Units
32
33
34
35
36
37
Degrees Celsius
Degrees Fahrenheit
Degrees Rankine
Degrees Kelvin
Millivolts
Ohms
FB Number
82
October 1998
OUTPUT
SENSOR INPUT
TYPES
The range and span limits are determined by the
particular sensor (see Table FB82-1) being used. See
Table FB82-2 for the various ranges associated with
sensor types.
Specifications
98
Output
Identification
98
8-11
FUNCTION BLOCK DESCRIPTIONS
UM348-1
8.7 PNEUMATIC INPUT #1/#2/#3
FB85/FB86/FB87
This function block converts a pneumatic (3-15 PSIG
or 3-27 PSIG) input signal into a 0-100% block
output signal for interconnection to other function
blocks. The output can also be calibrated for
equivalent metric values (e.g. 20-100 kPa, ...). FB85
will be available when the 1 or 3-input pneumatic
option board is furnished. FB86 & FB87 will be
available when the 3-input pneumatic option board is
furnished
Also included is a digital filter, to dampen process
noise and a square root extractor to linearize a flow
signal from a P transmitter. See Function Block 24
for more details on the square root extractor function.
Calibration details can be found in section 4 of this
manual.
A verify mode is available in calibration to view the
input as a 0-100% block output signal over the full
calibrated range.
PNEUMATIC INPUT #1 / #2 / #3
FB85 / FB86 / FB87
FB85/FB86/FB87
**
OUTPUT
PNEUMATIC PRESSURE INPUT
S D V ** DAMPING VALUE ..................... 0 to 180 SEC
C Z I ** ZERO INPUT .................................. 0 to 4 PSIG
C F I ** FULL SCALE INPUT .................. 12 to 15 PSIG
C V I ** VERIFY INPUT ................... -10.00 to 110.00%
H S R E SQUARE ROOT EXTRACTOR .......... NO/YES
* See Output Identification
** If FB85: 1, FB86: 2, FB87: 3
86
87
P**
*
EXTRACTOR
FB Number
85
This function block is not available if FB01 is
configured.
Specifications
Calibration (15 psig sensor):
Zero: 0-4 psig
Full Scale: 12-15 psig
Calibration (30 psig sensor):
Zero: 0-8 psig
Full Scale: 24-30 psig
Accuracy: +/- 0.25% of span
Amb. Temp. Effect: +/- 0.75%
50 deg. C
PNEUMATIC
PRESSURE
DAMPING
Output Identification
Pneumatic Input #1 Signal:
85
Pneumatic Input #2 Signal:
86
Pneumatic Input #3 Signal:
87
NO
P/V
CONVERTER
A/D
*
DAMPING
XTR
YES
BLOCK DIAGRAM
8-12
October 1998
UM348-1
FUNCTION BLOCK DESCRIPTIONS
8.8 CONTROLLER
CONTROLLER #1 / #2
FB13 / FB45
8.8.1 PID CONTROLLER #1/#2
FB13/FB45
FB13 / FB45
P
PID Controller #1 and #2: Controller #1 and #2
function blocks each provide a selection of PID, PD,
ID, and PIDA (PID with adaptive gain) controller
types. This controller is associated with Loop 1 and
Loop 2 functions respectively.
CONTROLLER
#1 / #2
S
*
ERROR
*
OUTPUT
PID
PD
ID
PID(AG)
F
A
C
The PID controller is a reset type using external
feedback to establish integral action. External
feedback is necessary to permit interaction with
internal function blocks as well as external loop
devices (e.g. secondary controller, override controller,
shutoff devices, .....), pneumatic or electronic, while
eliminating reset windup and valve bumping that can
occur with other controller types.
ACTION ............................................... REV/DIR
S A **
S P G ** PROPORTIONAL GAIN ............ 0.01 to 100.00
S T I ** TIME - INTEGRAL .................. 0.01 to 1000.00
S T D ** TIME - DERIVATIVE ................. 0.00 to 100.00
S D G ** DERIVATIVE GAIN .......................1.00 to 30.00
S M R ** MANUAL RESET ........................ 0.0 to 100.0%
S H L ** HIGH OUTPUT LIMIT.......... -10.00 to 110.00%
S L L ** LOW OUTPUT LIMIT .......... -10.00 to 110.00%
H C ** T CONTROLLER TYPE ............. PID/PD/ID/PIDA
H M R T MANUAL RESET TRACKING ............ NO/YES
H I N P INPUT P (PROCESS) .......................... 00 to 99
H I N S INPUT S (SETPOINT) ......................... 00 to 99
H I N F INPUT F (FEEDBACK) ........................ 00 to 99
H I N A INPUT A (ADAPTIVE GAIN) ................ 00 to 99
The controller block has an adjustable limit that can
be used to set boundries on the controller output
signal.
Input C 'Track Command' when high (>=80%) will
force the controller output to track Input F
'Feedback'. While in the tracking mode the feedback
value will be limited to the values output limit
settings, so that the controller output will also not
exceed these values. The controller will return to
normal when Input C goes low (<75%).
H
I N C INPUT C (TRACK COMMAND) ........... 00 to 99
* See Output Identifications
** If Controller #1: 1, If Controller #2: 2
P
LEAD
Note: Time-Integral set in minutes/repeat.
Time Derivative set in minutes.
FB Number
13
45
+
TDs
TD + 1
s
DG
+
PID CONTROLLER
+/-
Output Identifications
Controller Output: 14
|ERROR| Signal: 15
Controller Output: 46
|ERROR| Signal: 47
+
PG
+
GE
-/+
LIMIT
+
ABS
LAG
-
R
TRACK
COMMAND
S
E
O
1
F
TIs + 1
C
BLOCK DIAGRAM
(continued on next page)
October 1998
8-13
FUNCTION BLOCK DESCRIPTIONS
UM348-1
Equations
O = GE + R
NORMAL (C=0%)
R=
F
TIs + 1
WHEN CONTROLLER OUTPUT IS CONNECTED
TO THE FEEDBACK
O = +/- PG [ P 1 +
TDs
(TD/DG)s + 1
TRACK (C=100%)
- S] [ 1 +
1
]
TIs
R = F - GE & O = F
Controller Initialization
Power Up: The controller will initialize with an
output of 0% unless FB14 for Loop 1 or FB55 for
Loop 2 was configured to power up in Auto and at
the last value. In this case the controller will track
for two scan cycles to insure that the output will be
set equal to the feedback. In most cases the feedback
will be the output of FB14 for Loop 1 or FB55 for
Loop 2 which under these conditions has held the
output value prior to a loss in power.
Switch Transfer: The controller will eliminate any
proportional gain action on the first scan cycle after a
transfer switch (i.e. FB11, FB23, FB49, FB71) has
changed position. This prevents any output bump
that could occur due to an abrupt change in the
setpoint.
8-14
October 1998
UM348-1
FUNCTION BLOCK DESCRIPTIONS
8.8.2 PD CONTROLLER #1/#2
FB13/FB45
PD Controller #1 and #2: PD Controller #1 and #2
is a proportional only with manual reset, selectable as
tracking or non-tracking. This controller is
associated with Loop 1 and Loop 2 functions
respectively.
Input C 'Tracking Command' when high (>=80%)
will force the output to track Input F 'Feedback'. If
manual reset tracking is selected MR will also track
the feedback. While in the tracking mode the
feedback value will be limited to the output limit
settings, so that the controller output will also not
exceed these values. The controller will return to
normal when Input C goes low (<75%). In either
case the controller always returns to normal action
with the output equal to the feedback. The Reset
value R then returns to the value of MR with a time
constant established by the TI setting. Since the
default setting of TI is set at 100 min./repeat it
should be reduced to a more reasonable time (e.g. .01
min.).
When the Derivative Time TD is set to 0.00 the
derivative action is eliminated. When set, TD is in
minutes.
FB Number
13
45
Output Identifications
Controller Output: 14
|ERROR| Signal: 15
Controller Output: 46
|ERROR| Signal: 47
CONTROLLER #1 / #2
FB13 / FB45
FB13 / FB45
P
S
F
A
CONTROLLER
#1 / #2
*
ERROR
*
OUTPUT
PID
PD
ID
PID(AG)
C
S A **
S P G **
S T I **
S T D **
S D G **
S M R **
ACTION ............................................... REV/DIR
PROPORTIONAL GAIN ............ 0.01 to 100.00
TIME - INTEGRAL .................. 0.01 to 1000.00
H
H
TIME - DERIVATIVE ................. 0.00 to 100.00
DERIVATIVE GAIN .......................1.00 to 30.00
MANUAL RESET ........................ 0.0 to 100.0%
H L ** HIGH OUTPUT LIMIT.......... -10.00 to 110.00%
L L ** LOW OUTPUT LIMIT .......... -10.00 to 110.00%
C ** T CONTROLLER TYPE ............. PID/PD/ID/PIDA
M R T MANUAL RESET TRACKING ............ NO/YES
I N P INPUT P (PROCESS) .......................... 00 to 99
I N S INPUT S (SETPOINT) ......................... 00 to 99
I N F INPUT F (FEEDBACK) ........................ 00 to 99
I N A INPUT A (ADAPTIVE GAIN) ................ 00 to 99
H
I
S
S
H
H
H
H
N C INPUT C (TRACK COMMAND) ........... 00 to 99
* See Output Identifications
** If Controller #1: 1, If Controller #2: 2
(continued on next page)
October 1998
8-15
FUNCTION BLOCK DESCRIPTIONS
UM348-1
Equations
Controller Initialization
Power Up: The controller will initialize with an
output of 0% unless FB14 for Loop 1 or FB55 for
Loop 2 was configured to power up in Auto and at
the last value. In this case the controller will track
for two scan cycles to insure that the output will be
set equal to the feedback. In most cases the feedback
will be the output of FB14 for Loop 1 or FB55 for
Loop 2 which under these conditions has held the
output value prior to a loss in power.
O = GE + R
MR
TIs + 1
NORMAL (C=0%)
R=
TRACK (C=100%)
R = F - GE
IF MRT = YES
MR = F
Switch Transfer: The controller will eliminate any
proportional gain action on the first scan cycle after a
transfer switch (i.e. FB11, FB23, FB49, FB71) has
changed position. This prevents any output bump
that could occur due to an abrupt change in the
setpoint.
P
LEAD
PD CONTROLLER
+
TDs
TD + 1
s
DG
+
+/PG
+
GE +
+
-/+
ABS
LAG
-
R
E
1
TIs + 1
TRACK
COMMAND
S
O
LIMIT
MR
C
BLOCK DIAGRAM
8-16
October 1998
UM348-1
FUNCTION BLOCK DESCRIPTIONS
8.8.3 ID CONTROLLER #1/#2
FB13/FB45
CONTROLLER #1 / #2
FB13 / FB45
FB13 / FB45
ID Controller #1 and #2: ID Controller #1 and #2
is an integral only controller using external feedback
to establish integral action. External feedback is
necessary to permit interaction with internal function
blocks or external devices (e.g. secondary controller,
override controller, shutoff valve, ...), pneumatic or
electronic, while eliminating windup that can occur
with other controller types. This controller is
associated with Loop 1 and Loop 2 functions
respectively.
Input C 'Track Command' when high (>=80%) will
force the controller output to track Input F
'Feedback'. While in the tracking mode the feedback
value will be limited to the output limit settings, so
that the controller output will also not exceed these
values. The controller will return to normal when
Input C goes low (<75%).
The Gain for this controller is fixed at 1.00. While
the parameter PG can be changed, it will not affect
the controller gain. When the Derivative Time is set
to 0.00 the derivative action is eliminated.
Note: Time-Integral set in minutes/repeat.
Time Derivative set in minutes.
FB Number
13
45
P
CONTROLLER
#1 / #2
S
*
ERROR
*
OUTPUT
PID
PD
ID
PID(AG)
F
A
C
S A **
S P G **
S T I **
S T D **
S D G **
S M R **
ACTION ............................................... REV/DIR
PROPORTIONAL GAIN ............ 0.01 to 100.00
TIME - INTEGRAL .................. 0.01 to 1000.00
TIME - DERIVATIVE ................. 0.00 to 100.00
DERIVATIVE GAIN .......................1.00 to 30.00
MANUAL RESET ........................ 0.0 to 100.0%
** HIGH OUTPUT LIMIT.......... -10.00 to 110.00%
** LOW OUTPUT LIMIT .......... -10.00 to 110.00%
T CONTROLLER TYPE ............. PID/PD/ID/PIDA
T MANUAL RESET TRACKING ............ NO/YES
P INPUT P (PROCESS) .......................... 00 to 99
S INPUT S (SETPOINT) ......................... 00 to 99
F INPUT F (FEEDBACK) ........................ 00 to 99
A INPUT A (ADAPTIVE GAIN) ................ 00 to 99
S H L
S L L
H C **
H M R
H I N
H I N
H I N
H I N
H I N C INPUT C (TRACK COMMAND) ........... 00 to 99
* See Output Identifications
** If Controller #1: 1, If Controller #2: 2
Output Identifications
Controller Output: 14
|ERROR| Signal: 15
Controller Output: 46
|ERROR| Signal: 47
(continued on next page)
October 1998
8-17
FUNCTION BLOCK DESCRIPTIONS
UM348-1
Equations
NORMAL (C=0%)
GE + F
O=
TIs + 1
WHEN CONTROLLER OUTPUT IS CONNECTED
TO THE FEEDBACK
O = +/- PG [ P 1 +
TDs
(TD/DG)s + 1
- S] [
1
]
TIs
O=F
TRACK (C=100%)
Controller Initialization
Power Up: The controller will initialize with an
output of 0% unless FB14 for Loop 1 or FB55 for
Loop 2 was configured to power up in Auto and at
the last value. In this case the controller will track
for two scan cycles to insure that the output will be
set equal to the feedback. In most cases the feedback
will be the output of FB14 for Loop 1 or FB55 for
Loop 2 which under these conditions has held the
output value prior to a loss in power.
P
LEAD
ID CONTROLLER
+
TDs
TD + 1
s
DG
+
LAG
+/PG
+
GE +
1
TIs + 1
LIMIT
O
+
-/+
ABS
-
F
TRACK
COMMAND
S
E
C
BLOCK DIAGRAM
8-18
October 1998
UM348-1
FUNCTION BLOCK DESCRIPTIONS
8.8.4 PIDA CONTROLLER #1/#2
FB13/FB45
CONTROLLER #1 / #2
FB13 / FB45
FB13 / FB45
PIDA Controller #1 and #2: PIDA (PID with
Adaptive Gain) Controller #1 and #2 is similar to the
PID except that a multiplier is placed after the
proportional gain section. The gain of this multiplier
varies from 0-1 as Input A varies from 0-100%. If
Input A is not configured the gain is set to 1 and the
controller is identical to the standard PID. This
controller is associated with Loop 1 and Loop 2
functions respectively.
FB NUMBER
13
45
P
CONTROLLER
#1 / #2
S
*
ERROR
*
OUTPUT
PID
PD
ID
PID(AG)
F
A
C
S A **
S P G **
S T I **
S T D **
S D G **
S M R **
Output
Identifications
Controller Output: 14
|ERROR| Signal: 15
Controller Output: 46
|ERROR| Signal: 47
ACTION ............................................... REV/DIR
PROPORTIONAL GAIN ............ 0.01 to 100.00
TIME - INTEGRAL .................. 0.01 to 1000.00
TIME - DERIVATIVE ................. 0.00 to 100.00
DERIVATIVE GAIN .......................1.00 to 30.00
MANUAL RESET ........................ 0.0 to 100.0%
** HIGH OUTPUT LIMIT.......... -10.00 to 110.00%
** LOW OUTPUT LIMIT .......... -10.00 to 110.00%
T CONTROLLER TYPE ............. PID/PD/ID/PIDA
T MANUAL RESET TRACKING ............ NO/YES
P INPUT P (PROCESS) .......................... 00 to 99
S INPUT S (SETPOINT) ......................... 00 to 99
F INPUT F (FEEDBACK) ........................ 00 to 99
A INPUT A (ADAPTIVE GAIN) ................ 00 to 99
S H L
S L L
H C **
H M R
H I N
H I N
H I N
H I N
H I N C INPUT C (TRACK COMMAND) ........... 00 to 99
Note:
Time-Integral set in minutes/repeat.
Time Derivative set in minutes.
* See Output Identifications
** If Controller #1: 1, If Controller #2: 2
P
LEAD
+
TDs
+
TD + 1
s
DG
+/-
AG
PG
+
+
LIMIT
X
GE
-/+
+
ABS
LAG
-
R
TRACK
COMMAND
S
E
O
1
F
TIs + 1
C
A
BLOCK DIAGRAM
October 1998
8-19
FUNCTION BLOCK DESCRIPTIONS
UM348-1
Equations
O = GE + R
F
TIs + 1
WHEN CONTROLLER OUTPUT IS CONNECTED
TO THE FEEDBACK
NORMAL (C=0%)
O = +/- PG x AG [ P 1 +
R=
TDs
(TD/DG)s + 1
TRACK (C=100%)
- S] [ 1 + 1 ]
TIs
R = F - GE & O = F
Controller Initialization
Power Up: The controller will initialize with an
output of 0% unless FB14 for Loop 1 or FB55 for
Loop 2 was configured to power up in Auto and at
the last value. In this case the controller will track
for two scan cycles to insure that the output will be
set equal to the feedback. In most cases the feedback
will be the output of FB14 for Loop 1 or FB55 for
Loop 2 which under these conditions has held the
output value prior to a loss in power.
Switch Transfer: The controller will eliminate any
proportional gain action on the first scan cycle after a
transfer switch (i.e. FB11, FB23, FB49, FB71) has
changed position. This prevents any output bump
that could occur due to an abrupt change in the
setpoint.
8-20
October 1998
UM348-1
FUNCTION BLOCK DESCRIPTIONS
A/M TRANSFER SWITCH #1 / #2
FB 14 / FB55
8.9. TRANSFER
8.9.1 A/M TRANSFER #1/#2
FB14/FB55
FB14 / FB55
A
A
A/M Transfer #1and #2 function blocks each consist
of 3 SPDT switches. Switch 1 is controlled by the
A/M pushbutton on the operator's display. Switch 2
is controlled by Input E 'Emergency Manual' and will
be connected to the Manual when Input E is high
(>=80%) and will return to its' normal position when
Input E goes low (<75%). Switch 3 is controlled by
Input S 'Standby Sync' and will be connected to Input
T when Input S is high (>=80%) and will return to
its' normal position when low (<75%). Neither
Emergency Manual or Standby Sync will affect the
operation of the A/M pushbutton and its' associated
LCD indicators.
The Manual Value M can be adjusted with the UP &
DOWN pushbuttons when it is the block output and
the displayed variable is either V (valve), O (output),
or P (process). When manual is not the block output,
it will track the output value.
The Loop Control Function, Input L in FB14, is used
to control the active A/M block when two loops are
used in a single configuration. This function is
controlled from FB14 by INL which when INL is
High (>=80%) the A/M button and the UP/DOWN
buttons are disabled from FB14 and enabled for
FB55. When INL goes Low or is not configured
these functions are enabled for FB14 and disabled for
FB55.
E
S
T
*
OUTPUT
OUTPUT
M
A/M
TRANSFER
SWITCH #1 / #2
*
STATUS MS
L
S P U M POWER UP MANUAL ....... -10.00 to 110.00%
AUTO ONLY ...................................... NO/YES
H A O
POWER UP ......................................... A/M/LP
H P U
H P U L POWER UP LAST OUTPUT ............ NO/YES
H I N A INPUT A (AUTO) ............................... 00 to 99
H I N T INPUT T (TRACK VARIABLE) .......... 00 to 99
H I N E INPUT E (EMERG. MANUAL) ........... 00 to 99
H I N S INPUT S (STANDBY SYNC) ............. 00 to 99
H I N L INPUT L (LOOP CONTROL) ............. 00 to 99
* See Output Identifications
The A/M transfer can be configured as auto only.
When selected, the A/M pushbutton (and switch 1)
will always remain in the Auto position. Emergency
Manual and Standby Sync will still function
normally.
The operator status window will display 'M1' when
Input E is high and 'S1' when Input S is high for A/M
Transfer #1 and 'M2' & 'S2' for A/M Transfer #2.
The operation of the status window is described in
Function Block 15.
The function block also has a status output 'MS' that
will be high (100%) whenever the block is in manual,
emergency manual or standby sync.
(continued on next page)
October 1998
8-21
FUNCTION BLOCK DESCRIPTIONS
FB Number
14
55
UM348-1
Output
Identifications
Output: 17
Status MS: 18
Output: 60
Status MS: 68
Configuration allows for selecting the A/M
pushbutton power up position (auto, manual, or last
position before power outage). When the function
block powers up in manual and HPUL is selected as
NO, the power up value can be configured for any
value from -10% to 110%. When the function block
powers up in AUTO or MANUAL and HPUL is
configured as YES, the output of the block on power
up is set to the last value. The block will hold it's
output for two scan cycles and the controller will
track this value.
A
M
LOOP CONTROL
L
A
1
2
3
OUTPUT
M
MS
E
T
S
BLOCK DIAGRAM
8-22
October 1998
UM348-1
8.9.2 PB TRANSFER #1/#2
FB23/FB11
FUNCTION BLOCK DESCRIPTIONS
TRANSFER SWITCH
FB23 / FB11
FB23 / FB11
Transfer Block #1 and #2 consists of 2 SPDT
switches. Switch 1 is controlled by PB1 for FB23
and by PB2 for FB11, and can be configured for
momentary or sustained action by parameter HS1A.
As momentary, switch 1 will transfer to the 'I'
position while PB1 or PB2 is pressed and return to 'E'
when released. As sustained, switch 1 will transfer to
'I' when PB1 or PB2 is pressed and remain in this
position until released and pressed again.
E
I
Two LCD segment indicators are used to indicate the
position of PB1 or PB2. These indicators can be
disabled by setting the parameter HDSD 'Disable
Segment Displays' to YES.
Two status outputs indicate the actual block output.
Status 'IS' will be high (100%) when the output is
Input I and status 'ES' will be high when the output is
Input E.
October 1998
TRANSFER
SWITCH
OUTPUT
*
STATUS IS
*
STATUS ES
H E O
E POSITION ONLY.............................. NO/YES
H P U
POWER UP ............................................. E/I/LP
H S 1 A SWITCH 1 ACTION.......................... MOM/SUS
H D S D DISABLE SEGMENT DISPLAYS......... NO/YES
H
H
H
I
I
I
N E INPUT E ............................................... 00 to 99
N I INPUT I ................................................ 00 to 99
N A INPUT A ............................................... 00 to 99
* See Output Identifications
FB Number
Output
Identifications
Output: 09
Status IS: 10
Status ES: 25
Output: 27
Status IS: 63
Status ES: 64
11
The pushbutton can also be operated by a HART
command. Additional information can be found
under FB98.
A transfer block can be used to transfer a setpoint to
the controller function block. As such, the controller
block will initialize on the next execution after a
transfer occurs to prevent bumping the controller
output.
OUTPUT
I
A
Input A controls switch 2 and will connect to 'I' when
Input A is high (>=80%) and then return to the
normal position when Input A goes low (<75%).
Input A does not affect Switch 1, nor the action of
PB2 and its' associated LCD position indicators.
Switch 1 can be configured as 'E Position Only' by
setting HEO as YES. In this case the top LCD PB1
or PB2 indicator will remain on and the pushbutton
will have no effect on the action of switch 1.
*
E
23
E
PB2
PB1
1
2
I
OUTPUT
*
IS
*
A
ES
*
BLOCK DIAGRAM
8-23
FUNCTION BLOCK DESCRIPTIONS
8.9.3 GENERAL PURPOSE TRANSFER
FB49
UM348-1
GENERAL PURPOSE TRANSFER
FB49
FB49
The General Purpose Transfer Switch will select as
its output Input A or Input B, depending on the level
on Input C.
A
B
C
When Input C is high (>=80%), it will transfer to
Input B and when low (<75%) will return to Input A.
FB Number
49
Output
Identification
Switched Output: 51
H I
H I
H I
A
OUTPUT
51
B
OUTPUT
TRANSFER
SWITCH
N A INPUT A ............................................... 00 to 99
N B INPUT B .............................................. 00 to 99
N C INPUT C (SWITCH COMMAND) ......... 00 to 99
A
OUTPUT
51
B
C
BLOCK DIAGRAM
8-24
October 1998
UM348-1
FUNCTION BLOCK DESCRIPTIONS
8.9.4 TRIPLE TRANSFER SWITCH
FB71
TRIPLE TRANSFER SWITCH
FB71
FB71
The Triple Transfer Switch will select INA or INB,
IND or INE, and INF or ING as block outputs
depending on the level of INC.
A
B
D
When INC is high (>=80%) the switch will transfer
from the normal positions shown in the block
diagram. When INC goes low (<75%) or is not
configured the switches will return to the normal
position.
E
F
G
If INA, IND, or INF are not configured the input
values will default to 100%. If INB, INE or ING are
not configured the input values will default to 0%.
C
H I
H I
H I
H I
H I
A
OUTPUT 1
31
OUTPUT 2
32
B
H I
H I
A
B
D
OUTPUT
G
OUTPUT 1
32
OUTPUT 2
33
OUTPUT 3
OUTPUT
E
F
31
OUTPUT
TRIPLE TRANSFER
SWITCH
N A INPUT A ............................................... 00 to 99
N B INPUT B .............................................. 00 to 99
N D INPUT D .............................................. 00 to 99
N E INPUT E .............................................. 00 to 99
N F INPUT F .............................................. 00 to 99
N G INPUT G .............................................. 00 to 99
N C INPUT C (SWITCH COMMAND) ......... 00 to 99
D
E
F
OUTPUT 3
G
33
FB
Number
71
Inputs
A&B
D&E
F&G
Output
Identifications
Output 1: 31
Output 2: 32
Output 3: 33
TRANSITION
INPUT C HIGH
C
BLOCK DIAGRAM
October 1998
8-25
FUNCTION BLOCK DESCRIPTIONS
UM348-1
8.10 TRACK & HOLD
SETPOINT TRACK & HOLD #1 / #2
FB17 / FB46
8.10.1 SETPOINT TRACK & HOLD #1/#2
FB17/FB46
FB17 / FB46
T
The Setpoint Track & Hold #1 or #2 is generally
used to change the setpoint of Controller #1 (FB13)
or Controller #2 (FB46) respectively. The hold value
of this block can be changed with the UP/DOWN
pushbuttons when the displayed variable is S. The
block output, however, does not have to be connected
to Input S. The hold range of this block is -10.00 to
+110.00% but will be displayed in the range of the
FB15 input being used for display.
C
Input L is used to control the active Setpoint block
when two loops are used in a single configuration.
When INL is high (>=80%) the UP/DOWN buttons
are disabled from FB17 and enabled for FB46.
When INL goes low or is not configured FB17 is
enabled and FB46 is disabled.
*
OUTPUT
L
H I
H I
H I
N T INPUT T (TRACK VARIABLE) ............ 00 to 99
N C INPUT C (TRACK COMMAND) ........... 00 to 99
N L INPUT L (LOOP COMMAND) .............. 00 to 99
* See Output Identifications
FB Number
17
An alternate method, which allows the block hold
value to be changed, is to connect the block output
(22) for FB17 or (48) for FB46, to the X or Y
display variables in FB15. Then, when X or Y is
displayed the hold value can be changed using the
UP/DOWN pushbuttons.
The function block can be placed in a tracking mode
by making Input C high (>=80%). While in the
tracking mode the hold value will track Input T. The
pushbuttons will have no effect on the hold value in
this mode.
SETPOINT
TRACK & HOLD
#1 / #2
Output Identification
Setpoint Signal Output:
22
Setpoint Signal Output:
48
46
L
LOOP CONTROL
T
TRACK INPUT
C
TRACK COMMAND
TRACK
&
HOLD
OUTPUT
*
BLOCK DIAGRAM
The Setpoint Track & Hold also has built-in
functions that can be initiated using communication
commands (e.g. Target Setpoint, Ramp Rate, Ramp
Time, Start & Stop ramp action). For more details
on accessing these functions, reference FB98 and the
appropriate manuals for the HART master used to
communicate to the Model 348 (i.e. UM325-1 when
communicating through the Model 325 URICA,
CG39-7 for the HFM, and CG385-4 for the Model
385 Loop Operator’s Station).
8-26
October 1998
UM348-1
FUNCTION BLOCK DESCRIPTIONS
8.10.2 GENERAL PURPOSE TRACK & HOLD
FB18
The General Purpose Track & Hold is similar to
FB17 except that a hold value (H1) can be entered in
soft configuration. The UP/DOWN pushbuttons can
also change the hold value if the block output (23) is
connected to the X or Y display variables. Then,
when X or Y is displayed the value can be changed
unless the parameter HHCD 'Hold Value Change
Disabled' is set to YES.
FB Number
18
GENERAL PURPOSE TRACK & HOLD
FB18
FB18
T
C
GEN. PURPOSE
TRACK & HOLD
23
OUTPUT
HOLD VALUE .................. -10.00 to +110.00%
S H 1
H I N T INPUT T (TRACK VARIABLE) ........... 00 to 99
H I N C INPUT C (TRACK COMMAND) .......... 00 to 99
H I N D HV CHANGE DISABLED .................... NO/YES
Output
Identification
Signal Output: 23
T
TRACK INPUT
C
TRACK COMMAND
TRACK
&
HOLD
OUTPUT
23
BLOCK DIAGRAM
October 1998
8-27
FUNCTION BLOCK DESCRIPTIONS
8.10.3 GENERAL PURPOSE HOLD
FB19
The General Purpose Hold value (H2) can be entered
in soft configuration. The UP/DOWN pushbuttons
can also change the hold value if the block output
(23) is connected to the X or Y display variables.
Then, when X or Y is displayed the value can be
changed unless the parameter HHCD 'Hold Value
Change Disabled' is set to YES.
FB Number
19
UM348-1
GENERAL PURPOSE HOLD
FB19
FB19
GEN. PURPOSE
HOLD
S H 2
H H C D
24
OUTPUT
HOLD VALUE .................. -10.00 to +110.00%
HV CHANGE DISABLED .................... NO/YES
Output
Identification
Output: 24
HOLD
OUTPUT
24
BLOCK DIAGRAM
8-28
October 1998
UM348-1
FUNCTION BLOCK DESCRIPTIONS
8.11 OVERRIDE SELECTOR
FB10
OVERRIDE SELECTOR
FB10
The override selector function block consists of two
signal selectors in series. Each can be configured as
LO or HI. Whenever the block output is not equal to
Input A, the block output 'OR Status' will go high
(100%) and the operator display status window, as
described in FB15, will display 'OR'.
FB10
A
B
07
OUTPUT
08
OR STATUS
C
The 'OR' status will not be displayed in the status
window if the configuration parameter HDSD
'Display Status Disabled' is set to YES.
H S 1 B B SELECTOR .......................................... LO/HI
H S 1 C C SELECTOR .......................................... LO/HI
H D S D DISPLAY STATUS DISABLED.... ....... NO/YES
H I N A INPUT A ............................................... 00 to 99
H I N B INPUT B ............................................... 00 to 99
Any selector having only one input will result in that
input being the selector output. No inputs will result
in an output of 0% and an 'OR' status of 0%.
FB
Number
10
OVERRIDE
SELECTOR
H
I
N C INPUT C ............................................... 00 to 99
Output
Identifications
Signal Output:
07
OR Status: 08
A
B
C
HI/LO
HI/LO
SELECTOR
SELECTOR
07
OUTPUT
08
OR STATUS
B
C
BLOCK DIAGRAM
October 1998
8-29
FUNCTION BLOCK DESCRIPTIONS
8.12. LOGIC
8.12.1 LOGIC BLOCKS #1 THRU #9
FB20/21/48/50/61/62/88/89/90
UM348-1
LOGIC BLOCK #1 THRU #9
FB20/21/48/50/61/62/88/89/90
FB20/21/48/50
61/62/88/89/90
This function block provides the ability to perform
logic operations on a pair of inputs. Functions
include AND/NAND/OR/NOR/EXOR (exclusive
OR).
8-30
B
#1 THRU #9
T ** LOGIC TYPE ......... AND/NAND/OR/NOR/EOR
H I N A INPUT A .............................................. 00 to 99
H I N B INPUT B .............................................. 00 to 99
* See Output Identification
** FB20: 1, FB21: 2, FB48: 3, FB50: 4, FB61: 5,
FB62: 6, FB88: 7, FB89: 8, FB90: 9
A logic 1 is a high input (>=80%) and a logic 0 a low
(<75%).
Output Identification
Logic #1 Signal Output: 20
Logic #2 Signal Output: 21
Logic #3 Signal Output: 52
Logic #4 Signal Output: 53
Logic #5 Signal Output: 61
Logic #6 Signal Output: 62
Logic #7 Signal Output: 65
Logic #8 Signal Output: 66
Logic #9 Signal Output: 67
LOGIC
H I
Unconfigured inputs for AND/NAND will be set to
100% and OR/NOR/EXOR to 0%.
FB Number
20
21
48
50
61
62
88
89
90
OUTPUT
*
A
A
LOGIC
B
OUTPUT
AND/NAND/OR/NOR/EOR
*
TRUTH TABLE
OUTPUTS
INPUTS
A
B
AND
NAND
OR
NOR
EOR
0
0
0
1
0
1
0
0
1
0
1
1
0
1
1
0
0
1
1
0
1
1
1
1
0
1
0
0
October 1998
UM348-1
FUNCTION BLOCK DESCRIPTIONS
8.12.2 DELAY TIMER
FB65
DELAYTIMER
FB65
This function block can be configured as an ONDELAY or OFF-DELAY timer.
FB65
A
ON-DELAY
When Input A is low (<75%), the output is low (0%).
If Input A goes high (>=80%), the timer will wait for
a delay period DT and will then go high (100%),
provided Input A is still high.
OFF-DELAY
When Input A is high (>=80%), the output is high
(100%). If Input A goes low (<75%), the timer will
wait for a delay period DT and will then go low
(0%), provided Input A is still low.
S
H
H
H
D
I
D
O
DELAY
TIMER
69
OUTPUT
DELAY TIME .....…..……... 0.0 to 99999.9 SEC
T
N A INPUT A ...................………................. 00 to 99
T T DELAY TIMER TYPE ....…….............. OFF/ON
P U OUTPUT POWER-UP @ 100% …….. NO/YES
OUTPUT
OFF-DELAY
DT
POWER-UP
When OFF-DELAY is selected and Input A is low on
power-up, the block can be configured to set its
output high (100%) by selecting HOPU = YES. In
this case the output will remain high for the delay
period DT and then go low, provided Input A is still
low.
When ON-DELAY is selected and Input A is high on
power-up, the block can be configured to set its
output high immediately by selecting HOPU = YES.
ON-DELAY
DT
OUTPUT
DT
INPUT
TIMING DIAGRAM EXAMPLE
The Delay Time in seconds will be resolved to the
closest 0.15 seconds which is the cycle time of the
Model 348.
FB Number
65
October 1998
Output
Identification
Timer Output: 69
8-31
FUNCTION BLOCK DESCRIPTIONS
8.12.3 ONE SHOT TIMER
FB67
The One Shot Timer output will go high (100%)
when Input A makes a positive transition (i.e. goes
from low to high). If another positive transition is
made while the timer output is still high, the timer
will restart. The output will then remain high for a
period equal to OT 'On Time'. The output will go
low (0%) after the OT period until a new positive
transition occurs.
UM348-1
ONE SHOT TIMER
FB67
FB67
A
S O T
H
I
ONE-SHOT
TIMER
84
OUTPUT
ON TIME ............................ 0.0 to 99999.9 SEC
N A INPUT A ............................................... 00 to 99
An input is considered high when equal to or greater
than 80%.
OUTPUT
OT
OT
The configuration time 'OT' will be resolved to the
closest 0.15 seconds which is the cycle time of the
Model 348.
INPUT
FB Name
67
Output
Identification
Timer Output: 84
TIMING DIAGRAM EXAMPLE
8-32
October 1998
UM348-1
FUNCTION BLOCK DESCRIPTIONS
8.12.4 REPEAT CYCLE TIMER
FB47
REPEAT CYCLE TIMER
FB47
FB47
Start
When Input B goes high (>=80%), the timer output
will go from 0% to 100% and remain there for time
TN, at which time the output returns to 0% for time
TF. When TF is set to 0.00 the output will not turn
off but stay on indefinitely. The timer will continue
to repeat this cycle until stopped.
A
B
S T F
S T N
H I
H I
Stop
When Input B goes low (<75%), the timer output
immediately goes to 0%.
Adaptive On Time
The Adaptive On Time function is only active when
Input A is configured. There are two separate
applications for this function:
When TF is set to 0.00 the TIME PERIOD
will remain fixed and equal to TN. The
ON time will vary from 0 to TN as Input A
goes from 0% to 100%.
49
REPEAT CYCLE
TIMER
OUTPUT
TIME- OFF ....................... 0.00 to 9999.99 MIN
TIME- ON ......................... 0.00 to 9999.99 MIN
N A INPUT A (ADAPTIVE ON TIME) ......... 00 to 99
N B INPUT B (START) ............................... 00 to 99
TIME
PERIOD
A
ADAPTIVE
ON TIME
B
START/STOP
TIMER
ON
OFF
TN
TF
100%
0%
START
O UT PU T
BLOCK DIAGRAM
When TF is set at a value greater than 0.00
the OFF time will remain fixed at that
value and the ON time will vary from 0 to
TN as Input A goes from 0% to 100%.
FB Number
47
October 1998
Output Identification
Repeat Cycle Signal: 49
8-33
FUNCTION BLOCK DESCRIPTIONS
UM348-1
8.13 RATIO & BIAS
RATIO
FB07
8.13.1 RATIO
FB07
FB07
A
The RATIO block multiplies two block inputs A&B
by R (Ratio). All 0-100% block input signals have a
real range of 0-1, and the resultant 0-1 computed
range represents a 0-100% block output. The output
of the Ratio block is not limited.
B
C
03
OUTPUT
89
TRACK
OUTPUT
O=RXAXB
D
RATIO .......................................0.00 to 30.00
S R
S R R L RATIO RANGE LOW ............... 0.00 to 30.00
S R R H RATIO RANGE HIGH .............. 0.00 to 30.00
H I N A INPUT A ........................................... 00 to 99
H I N B INPUT B ............................................ 00 to 99
H I N C INPUT C ........................................... 00 to 99
When Input C is high (>=80%), the output will track
Input D and the R (Ratio) value will be recalculated
as R=D/(AxB). R is limited to the values of the
Ratio Range established in configuration. Any
calculated value of R exceeding these limits will be
clamped at the limit.
H
I N D INPUT D ........................................... 00 to 99
R
C D RATIO CHANGE DISABLED .......... NO/YES
H
Parameter SR 'Ratio' will be limited within the
configured Ratio Range. Also SRRL 'Ratio Range
Low' can not be set higher than SR and SRRH 'Ratio
Range High' can not be set lower than SR.
The Ratio value can be viewed using the D button if
FB07 was selected in the T mode. The Ratio value
can be changed continuously with the UP/DOWN
arrow keys unless the Ratio Change Disabled
parameter was configured as YES.
R
RATIO
A
AXB
RXAXB
X
X
OUTPUT
B
X
.
FB
Number
07
8-34
Output
Identificatio
n
Ratio Output
Signal:03
Track
Output: 89
D
Unused Inputs
(Defaults)
AX B
C
Input A = 100%
(1.0)
Input B = 100%
(1.0)
Input C = 0% (0.0)
Input D = 100%
(1.0)
.
.
T
R
RATIO
C
D
A XR
.
.
TRACK
OUTPUT
D
BLOCK DIAGRAM
October 1998
UM348-1
FUNCTION BLOCK DESCRIPTIONS
8.13.2 BIAS
FB08
BIAS
FB08
FB08
The BIAS block sums input signals A and E together
with the BIAS value B. The output of the Bias block
is not limited.
OUTPUT
90
TRACK
OUTPUT
C
O=B+A+E
D
S B
H O B
H I N
H I N
H I N
The Bias value can be viewed using the D button if
FB08 was selected in the T mode. The Bias value
can be changed continuously using the UP/DOWN
arrow keys unless the Bias Change Disabled
parameter was configured as YES.
1 ............................ P1
2 ............................ P2
3 ............................ X
4 ............................ Y
5 ............................ %
04
BIAS
E
When Input C is high (>=80%), the output will track
Input D and the B (Bias) value will be recalculated as
B=D-(A+E). The value of B is limited to +/-150%
and any calculated Bias value exceeding these limits
will be clamped at a limit.
The Bias value that is viewed using the D pushbutton
(i.e. Operator Bias Range) can have an associated
engineering range, selectable from one of the ranges
configured in FB15. For example, it may be
preferable to view the Bias value in Process units in
place of % of range if it is the setpoint to the
controller. The selectable ranges are defined as
follows:
B
A
R
A
E
C
BIAS ............................. -150.00% to +150.00%
OPERATOR BIAS RANGE ............... 1/2/3/4/5
INPUT A ............................................... 00 to 99
INPUT E ............................................... 00 to 99
INPUT C .............................................. 00 to 99
H I N D INPUT D ............................................... 00 to 99
H B C D BIAS CHANGE DISABLED ................. NO/YES
A
+
E
A+E
+
+
T
C
B+A+E
+
+
+
OUTPUT
+
B
BIAS
C
+
D - (A + B)
TRACK
OUTPUT
D
BLOCK DIAGRAM
FB
Number
08
October 1998
Output
Identificatio
n
Bias Output
Signal: 04
Track
Output: 90
Unused
Inputs
Input A: 0%
Input E: 0%
Input C: 0%
Input D: 0%
8-35
FUNCTION BLOCK DESCRIPTIONS
UM348-1
8.14 HI/LO SETPOINT LIMIT #1/#2
FB09/FB51
HI/LO SETPOINT LIMIT #1 /#2
FB09 / FB51
FB09 / FB51
The HI/LO Setpoint Limit block accepts a block
interconnection signal and provides an output that is
limited within the high (HL) and low (LL) limit
settings. This block is normally used as a limit for
the setpoint to the Loop 1 controller (FB13 for FB09)
or Loop 2 Controller (FB45 for FB51), and will be
reported in the HART communications as part of the
Loop 1 or Loop 2 setpoint information. Note that
when the Setpoint display is configured to be the
output of the Limit block, pressing the UP/DOWN
arrows while the Setpoint is selected changes the
output of the Setpoint block, not the output of the
Limit block. The setpoint block output continues to
change even though the limit block (FB09/54) limits
the output and the displayed setpoint. This block can
be used for other than setpoint limiting noting that the
limit values and status will be reported as part of the
Loop 1 and Loop 2 information.
HI/LO
SETPOINT LIMIT
#1 / #2
A
S
L L
S H L
H D S
H I N
**
**
D
A
*
OUTPUT
LOW LIMIT ..................... -10.00% to +110.00%
HIGH LIMIT .................... -10.00% to +110.00%
DISPLAY STATUS DISABLED ........... NO/YES
INPUT A ............................................... 00 to 99
* See Output Identifications
** FB09: 1, FB51: 2
FB
Number
09
51
Output
Identifications
05
54
The status of this block can be displayed in the 4
character status window as described in FB15.
When the output is equal to the high limit setting, the
alphanumeric will display H1 for FB09 or H2 for
FB51. When the output is equal to the low limit
setting the alphanumeric will display L1 for Loop1 or
L2 for Loop2.
When a Hi Limit is set lower than a Lo Limit the
block output will equal the Hi Limit.
The alphanumeric statuses will not be displayed in
the status window if the configuration parameter
HDSD is set to YES.
A
HI
LO
SELECTOR
SELECTOR
LL
HL
*
OUTPUT
BLOCK DIAGRAM
8-36
October 1998
UM348-1
FUNCTION BLOCK DESCRIPTIONS
ALARM BLOCK #1 / #2
FB12 / FB73
8.15 ALARMS
FB12 / FB73
8.15.1 ALARM BLOCK #1/#2
FB12/FB73
Alarm Block #1 and #2 each contain four alarms.
This block normally associates with alarms that are
part of Loop 1 (i.e. Controller #1 and Setpoint #1)
and Loop 2 (i.e. Controller #2 and Setpoint #2)..
Each alarm may be configured as an absolute or
deviation type alarm. The action of each alarm can
be selected as a HI, LO, HDEV, LDEV, DEV, OR
or NONE during Hard configuration.
HI or LO will function as a high or low absolute
alarm that compares the input with Setpoint SSA_.
When the input (A,B,C,D) is higher than the Setpoint
for a Hi alarm or lower than the Setpoint for a Lo
alarm, the block output Status AS_ will go high
(100%).
OR (out of range) will function as a high and low
absolute alarm. The setpoints for this alarm are fixed
at 0% and 100%, and the SSA_ parameters are
ignored.
HDEV or LDEV will function as a high or low
difference alarm between two inputs for Loop
#1(Inputs A & B if alarm 1 or 2 is selected, Inputs C
& D if alarm 3 or 4 is selected) or Loop #2 (Inputs A
& B if alarm 5 or 6 is selected, Inputs C & D if
alarm 7 or 8 is selected). Note, when alarm 1 is
selected, alarm 2 can still be used as a HI, LO, or
OR using Input B.
DEV will function as an absolute difference alarm
between the corresponding inputs for Loop #1(Inputs
A & B if alarm 1 or 2 is selected, Inputs C & D if
alarm 3 or 4 is selected) or Loop #2 (Inputs A & B if
alarm 5 or 6 is selected, Inputs C & D if alarm 7 or 8
is selected).
(continued on next page)
*
A
ALARM 1 / 5
B
ALARM 2 / 6
C
ALARM 3 / 7
*
D
ALARM 4 / 8
*
*
STATUS AS1/AS5
STATUS AS2/AS6
STATUS AS3/AS7
STATUS AS4/AS8
S S A ** SETPOINT ALARM 1/5 ...... -10.00
S S A ** SETPOINT ALARM 2/6 ...... -10.00
S S A ** SETPOINT ALARM 3/7 ...... -10.00
S S A ** SETPOINT ALARM 4/8 ...... -10.00
to 110.00%
to 110.00%
to 110.00%
to 110.00%
A ** DEADBAND ALARM 1/5 ............... 0.1/0.5/1/5%
S D A ** DEADBAND ALARM 2/6 ............... 0.1/0.5/1/5%
S D A ** DEADBAND ALARM 3/7 ............... 0.1/0.5/1/5%
S D A ** DEADBAND ALARM 4/8 ............... 0.1/0.5/1/5%
S
D
E A ** ENABLE/DISABLE ALARM 1/5 ............. EN/DIS
S E A ** ENABLE/DISABLE ALARM 2/6 ............. EN/DIS
S E A ** ENABLE/DISABLE ALARM 3/7 ............. EN/DIS
S E A ** ENABLE/DISABLE ALARM 4/8 ............. EN/DIS
S
H Q ** R QUICK ALARM 1/5 RANGE ..... P-1/2-X/3-Y/4-%
H Q ** R QUICK ALARM 2/6 RANGE ..... P-1/2-X/3-Y/4-%
H Q ** R QUICK ALARM 3/7 RANGE ..... P-1/2-X/3-Y/4-%
H Q ** R QUICK ALARM 4/8 RANGE ..... P-1/2-X/3-Y/4-%
H A ** T
A1T/A5T .... NONE/HI/LO/HDEV/LDEV/DEV/OR
H A ** T
A2T/A6T .... NONE/HI/LO/HDEV/LDEV/DEV/OR
A3T/A7T .... NONE/HI/LO/HDEV/LDEV/DEV/OR
H A ** T
H A ** T
H
I
H
H
I
I
A4T/A8T .... NONE/HI/LO/HDEV/LDEV/DEV/OR
N A INPUT A ............................................... 00 to 99
N B INPUT B ............................................... 00 to 99
N C INPUT C ............................................... 00 to 99
H I N D INPUT D ............................................... 00 to 99
H A ** I A1/A5 DELAY IN ......... 0/.4/1/2/5/15/30/60 SEC
H A ** I A2/A6 DELAY IN ......... 0/.4/1/2/5/15/30/60 SEC
H A ** I A3/A7 DELAY IN ......... 0/.4/1/2/5/15/30/60 SEC
H A ** I A4/A8 DELAY IN ......... 0/.4/1/2/5/15/30/60 SEC
H A ** O A1/A5 DELAY OUT ..... 0/.4/1/2/5/15/30/60 SEC
H A ** O A2/A6 DELAY OUT ..... 0/.4/1/2/5/15/30/60 SEC
H A ** O A3/A7 DELAY OUT ..... 0/.4/1/2/5/15/30/60 SEC
H A ** O A4/A8 DELAY OUT ..... 0/.4/1/2/5/15/30/60 SEC
H A ** R ALARM 1/5 RINGBACK ....................... NO/YES
R ALARM 2/6 RINGBACK ....................... NO/YES
R ALARM 3/7 RINGBACK ....................... NO/YES
A ** R ALARM 4/8 RINGBACK ....................... NO/YES
H A **
H A **
H
* See Output Identifications
** If Loop1: 1, 2, 3, 4 If Loop 2: 5, 6, 7, 8
October 1998
8-37
FUNCTION BLOCK DESCRIPTIONS
The Status of each alarm will be displayed in the
status window. The operation of the status window
is described in detail as part of FB15.
Each alarm can be Enabled or Disabled using the
appropriate SEA_ parameter. When an alarm is
disabled its' status output, status window, and flasher
(if configured) will be disabled.
Each alarm can have associated engineering units P1,
X, Y, or %, which can be selected during
configuration by setting parameter HQ_R to 1, 2, 3,
or 4 respectively. When an alarm is selected with the
Quick Alarm pushbutton, the 4 character
alphanumeric display will flash between the alarm
mnemonic (e.g. SSA1) for 2 sec. and the associated
engineering units (e.g. GPM) for 1 sec.
FB
Number
12
73
UM348-1
LO ALARM
INPUT 1 (A, B, C or D)
SSA_
All alarms have the following features:
Selectable Deadband, requires that the input signal
drop below (or above) the setpoint by the amount of
the deadband before the alarm clears (goes low).
Dely-In Time, requires that the input signal remain
above (or below) the setpoint for the delay time
before the alarm trips (goes high).
STATUS AS_
HI ALARM
INPUT 1 (A, B, C or D)
LO
INPUT 1 (A or C)
STATUS AS_
COMPARATOR
SSA_
HI DEV ALARM
+
HI
-
INPUT 2 (B or D)
INPUT 1 (A or C)
STATUS AS_
COMPARATOR
SSA_
LO DEV ALARM
+
LO
Output Identification
Alarm 1 Status AS1: 11
Alarm 2 Status AS2: 12
Alarm 3 Status AS3: 13
Alarm 4 Status AS4: 91
Alarm 5 Status AS5: 75
Alarm 6 Status AS6: 76
Alarm 7 Status AS7: 77
Alarm 8 Status AS8: 78
HI
COMPARATOR
INPUT 2 (B or D)
INPUT 1 (A or C)
STATUS AS_
COMPARATOR
SSA_
DEV ALARM
+
HI
ABS
INPUT 2 (B or D)
STATUS AS_
COMPARATOR
SSA_
OR ALARM
INPUT 1 (A, B, C or D)
100%
INPUT 1 (A, B, C or D)
0%
HI
COMPARATOR
LOGIC STATUS AS_
OR
LO
COMPARATOR
BLOCK DIAGRAM
Ringback, causes a previously acknowledged flashing
alarm to flash again when the alarm clears (goes
low).
Delay-Out Time, requires that the input signal remain
below (or above) the setpoint + deadband for the
delay time before the alarm clears (goes low).
8-38
October 1998
UM348-1
FUNCTION BLOCK DESCRIPTIONS
8.15.2 QUAD COMPARATOR
FB64
QUAD COMPARATOR
FB64
FB64
This block provides 4 Comparators that compare an
input signal with a trippoint and provide an ON/OFF
output. Each comparator also includes configurable
deadband (DB).
The trippoint of each comparator can be either an
input (i.e. E,F,G,H) or parameter STC_. If the input
is not configured, STC_ will be compared to the
signal input, otherwise the configured input will be
used.
Direct Acting:
I>=TP
I<(TP-DB)
(TP-DB)>=I<TP
O = 100%
O = 0%
O = (no change)
Reverse Acting:
I<=TP
I>(TP+DB)
(TP+DB)>=I>TP
O = 100%
O = 0%
O = (no change)
A,B,C,D
E,F,G,H
COMPARATOR 1
80
OUTPUT
E
B
COMPARATOR 2
81
OUTPUT
F
C
COMPARATOR 3
82
OUTPUT
G
D
COMPARATOR 4
83
OUTPUT
H
Equations
FB
Number
64
A
Comparator
Number
1
2
3
4
Input
A&E
B&F
C&G
D&H
SIGNAL
COMPARATOR
STC
S T C 1 TRIP COMP. 1 .................... -10.00 to 110.00%
TRIP COMP. 2 .................... -10.00 to 110.00%
TRIP COMP. 3 .................... -10.00 to 110.00%
S T C 2
S T C 3
S T C 4 TRIP COMP. 4 .................... -10.00 to 110.00%
S D C 1 DEADBAND COMP. 1 ................ 0.1 to 100.0%
S D C 2 DEADBAND COMP. 2 ................ 0.1 to 100.0%
S D C 3
DEADBAND COMP. 3 ................ 0.1 to 100.0%
S D C 4 DEADBAND COMP. 4 ................ 0.1 to 100.0%
H C 1 A COMP. 1 ACTION ............................. REV/DIR
H C 2 A COMP. 2 ACTION ............................. REV/DIR
H C 3 A COMP. 3 ACTION ............................. REV/DIR
Output
Identification
80
81
82
83
OUTPUT
H C 4 A COMP. 4 ACTION ............................. REV/DIR
H I N A INPUT A ............................................... 00 to 99
H I N B INPUT B ............................................... 00 to 99
H I N C INPUT C ............................................... 00 to 99
H I N D INPUT D ............................................... 00 to 99
H I N E INPUT E ............................................... 00 to 99
H I N F INPUT F ............................................... 00 to 99
H I N G INPUT G ............................................... 00 to 99
H I N H INPUT H ............................................... 00 to 99
80, 81,
82, 83
TRIPPOINT
BLOCK DIAGRAM
October 1998
8-39
FUNCTION BLOCK DESCRIPTIONS
8.16 OPERATOR’S DISPLAY
FB15
UM348-1
OPERATORS DISPLAY
FB15
FB15
The Operator Display function block controls the
function of the operator display panel on the front of
the Model 348.
P -888888 ABCD
S
P
100
80
60
50
40
20
P
S
Pushbuttons
V
PB1 - Active when FB23 has been selected in the T
mode. See function block description for operational
details.
X
PB2 - Active when FB11 has been selected in the T
mode. See function block description for operational
details.
A/M - Active when FB14 and/or FB55 has been
selected in the T mode. It will toggle the controller
between Auto & Manual as detailed in FB14 or
FB55 description. It interfaces with FB55 when the
Loop Command activates the block. The upper LCD
segment indicates Auto and the lower segment
Manual.
D - This pushbutton is used to change the displayed
variable. A single alphanumeric character will
indicate the displayed variable as P, S, V/O, X, Y, R,
B, C, M, 1, or 2. The units, if applicable, for each of
these will be displayed in the four character
alphanumeric display.
ACK - This pushbutton, when not in the
configuration mode will acknowledge a flashing
alarm or status and open the status window showing
the condition being acknowledged.
Repeated pressing of this button will step through
and acknowledge other statuses, if present. If this
button is not pressed, for 5 seconds, the four
character display will return to its' normal function of
displaying the engineering units of the displayed
variable.
Y
0
CLOSED VALVE
0
OPEN
OUT 100
OPERATOR
DISPLAY
1
2
A
L
06
ERROR
19
PULSE ON
26
PULSE OFF
S D P 1 DECIMAL POINT RANGE 1 ......... .0.0.0.0.0.0
S P L 1 PROCESS LO RANGE 1 ......... +/- 0 to 999999
S P H 1 PROCESS HI RANGE 1 ......... +/- 0 to 999999
S D P 2 DECIMAL POINT RANGE 2 ... ...... .0.0.0.0.0.0
S P L 2 PROCESS LO RANGE 2 ......... +/- 0 to 999999
S P H 2 PROCESS HI RANGE 2 .......... +/- 0 to 999999
S D P X DECIMAL POINT X ....................... .0.0.0.0.0.0
X LO RANGE .......................... +/- 0 to 999999
S X L
X HI RANGE ............................ +/- 0 to 999999
S X H
S D P Y DECIMAL POINT Y ........................ .0.0.0.0.0.0
Y LO RANGE ........................... +/- 0 to 999999
S Y L
Y HI RANGE ............................ +/- 0 to 999999
S Y H
S T S T TAG SCROLL TIME ...................... 5 to 20 SEC
S T S I TAG SCROLL INFO .................TN1/TN2/BOTH
H I N P INPUT P (PROCESS) .......................... 00 to 99
H I N S INPUT S (SETPOINT) ......................... 00 to 99
H I N V INPUT V (VALVE/OUTPUT) ............... 00 to 99
H I N X INPUT X ............................................... 00 to 99
H I N Y INPUT Y ............................................... 00 to 99
N A INPUT A (ACKNOWLEDGE) ............... 00 to 99
N L INPUT L (LOOP SELECT) .................. 00 to 99
H P D R PROCESS DISPLAY RANGE .................. 1/2/L
H S D R SETPOINT DISPLAY RANGE ................. 1/2/L
H H S 1 HORIZONTAL-BAR SELECT 1 .................. V/O
H H S 2 HORIZONTAL-BAR SELECT 2 ................. V/O
H H D 1 HORIZONTAL-BAR DIRECT 1 ........... NO/YES
H H D 2 HORIZONTAL-BAR DIRECT 2 ........... NO/YES
H
H
I
I
(cont'd on next page)
(continued on next page)
8-40
October 1998
UM348-1
FUNCTION BLOCK DESCRIPTIONS
H
H
H
H
H
H
H
H
S C F SELF CLEARING FLASHER .............. NO/YES
I N 1 INPUT 1 (USER 1 STATUS) ............... 00 to 99
I N 2 INPUT 2 (USER 2 STATUS) ............... 00 to 99
U 1 S USER 1 STATUS .................... 2 CHAR (ASCII)
U 2 S USER 2 STATUS .................... 2 CHAR (ASCII)
H
H
H
H
H
H
H
H
ENG. UNITS PROCESS 2 ..... 4 CHAR (ASCII)
T N 1
T N 2
E U 1
E U 2
E U X
E U Y
F L 1
F L 2
F L 3
F L 4
F L 5
TAG NAME PROCESS 1 ..... 12 CHAR (ASCII)
TAG NAME PROCESS 2 ..... 12 CHAR (ASCII)
ENG. UNITS PROCESS 1 ...... 4 CHAR (ASCII)
ENG. UNITS X ........................ 4 CHAR (ASCII)
ENG. UNITS Y ........................ 4 CHAR (ASCII)
FLASHER 1 .................................. (see table 1)
FLASHER 2 .................................. (see table 1)
FLASHER 3 .................................. (see table 1)
FLASHER 4 ................................... (see table 1)
FLASHER 5 ................................... (see table 1)
TAG - This button, when not in the configuration
mode, will cause the 4 character display to scroll,
displaying the following information as defined by
parameter 'STSI':
a) Tag Name 1 <Loop 1>
b) Tag Name 2 <Loop 2>
c) Tag Name 1/Tag Name 2
Configuration Pushbuttons: These buttons are
described in the configuration section of this manual.
This also includes the Quick Access buttons such as
ALARM, ... .
Status Window: The four character display
normally indicates the engineering units of the
displayed variable. When a status condition occurs it
will stack up behind the engineering units and can be
viewed by the operator using the ACK pushbutton.
The four decimal points in the display window will
blink when a status is present. This indicates that the
window can be opened using the ACK button to view
the statuses. While viewing statuses the blinking will
stop. If the ACK button is not pressed for 5 seconds
the window will close,
again displaying any engineering units and blinking
the decimal points as long as any statuses are present.
Bargraph Flashers: Any of the following status
conditions can be selected to flash the P/S bargraphs.
Pushing the UP ARROW button moves through the
list.
When a status occurs that causes flashing P/S
bargraphs, the status window will open
automatically. When the flashing is acknowledged
and there are no more flashing statuses the status
window will return to normal and display any
Engineering Units.
TABLE FB15-1 Status Conditions
Status Condition
(not used)
Alarm #1
Alarm #2
Alarm #3
Alarm #4
High Limit #1
Low Limit #1
Override
Standby Sync #1
Emerg Manual #1
User Status 1
User Status 2
Error
High Limit #2
Low Limit #2
Totalizer Preset 1
Totalizer Preset 2
Alarm #5
Alarm #6
Alarm #7
Alarm #8
Standby Sync #2
Emerg Manual #2
Designator
00 “NONE”
A1
A2
A3
A4
H1
L1
OR
S1
M1
U1*
U2*
E
H2
L2
P1
P2
A5
A6
A7
A8
S2
M2
(continued on next page)
October 1998
8-41
FUNCTION BLOCK DESCRIPTIONS
* When U1 and/or U2 status conditions occur, the
displayed status will be the ASCII characters
configured for parameters HU1S and HU2S,
respectively.
Overrange Display: When a displayed variable is
beyond the configured range the value will be
displayed, provided there are sufficient digits in the
display. When a value is overrange the decimal point
will flash indicating an overrange condition. This
feature will not apply when the display is ranged for
0-1.
UM348-1
L - Loop Select: When this input goes high
(>=80%), Range 2 will be used to scale the Process
(INP) if the parameter 'HPDR' is set to 'L' (LOOP)
and also scale the Setpoint if the parameter 'HSDR' is
set to 'L'. The horizontal bar (Valve/Output) will be
displayed as defined by the parameters 'HS1'/'HS2'
and 'HD1'/HD2'. If only one valve signal is to be
displayed, but 'INL' is being used, be sure that both
sets of parameters are configured identically. When
the input drops below 75% or is not configured,
Range 1 will be used to scale the respective inputs.
Outputs
Inputs
P - Process Variable, can be displayed in engineering
units or % of range.
S - Setpoint is displayed in the same units as P.
ERROR (06) - This output will go high (100%)
whenever an error status is displayed in the status
window.
Pulse-On (19) - This output will go high (100%) for
0.6 sec. whenever a flashing P/S bargraph is
initiated.
V/O - Valve/Output is displayed as %.
X - Variable X, can be displayed in engineering units
or % of range.
Pulse-Off (26) - This output will go high (100%) for
0.6 sec. whenever a flashing P/S bargraph is turned
off (i.e. acknowledged).
Y - Variable Y, can be displayed in engineering units
or % of range.
1 - Will cause User Status 1 to be displayed in the
status window when this input goes high (>=80%).
2 - Will cause User Status 2 to be displayed in the
status window when this input goes high (>=80%).
A - When this input goes high (>=80%), it will cause
any flashing P/S bargraphs and status mnemonic to
stop.
8-42
October 1998
UM348-1
FUNCTION BLOCK DESCRIPTIONS
8.17 DYNAMIC COMPENSATION
LAG
FB40
8.17.1 LAG
FB40
FB40
A
This function block provides Lag action with a time
constant 'TL' that can be set during soft
configuration.
When INB is high (>=80%) or not configured, the
function block will be in NORMAL operation. When
it is low (<75%) the lag function will be bypassed
and the output is set equal to INA.
FB Number
40
Output
Identification
Output: 40
40
LAG
OUTPUT
B
S T
H I
L
N A
H
N B
I
TIME - LAG ..................... 0.00 to 1000.00 MIN
INPUT A .............................................. 00 to 99
INPUT B .............................................. 00 to 99
A
SIGNAL
1
B
NORMAL
TLs + 1
OUTPUT
40
BLOCK DIAGRAM
October 1998
8-43
FUNCTION BLOCK DESCRIPTIONS
8.17.2 LEAD
FB41
UM348-1
LEAD
FB41
FB41
This function block provides Lead action with a time
constant TH that can be set during soft configuration.
When INB is high (>=80%) or not configured, the
function block will be in NORMAL operation. When
it is low (<75%) the lead function will be bypassed
and the output is set equal to INA.
FB
Number
41
A
LEAD
41
OUTPUT
B
TIME - LEAD ................. 0.00 to 1000.00 MIN
S T H
H I N A INPUT A ............................................. 00 to 99
H I N B INPUT B .............................................. 00 to 99
Output
Identification
Output: 41
A
SIGNAL
THs +1
B
NORMAL
0.1THs + 1
OUTPUT
41
BLOCK DIAGRAM
8-44
October 1998
UM348-1
FUNCTION BLOCK DESCRIPTIONS
8.17.3 RATE LIMITER
FB42
RATE LIMITER
FB 42
FB42
The Rate Limiter will limit the rate at which the
block output changes. Both the full scale time to
ramp up 'TRU' and ramp down 'TRD' can be set
independently during configuration.
A
B
RATE
LIMITER
42
OUTPUT
C
When Input B goes high (>=80%), the Rate Limiter
will be in NORMAL operation, and when low
(<75%), the rate limit function will be bypassed
which sets the output equal to Input A. If Input A is
not configured, the output will be set to 0%. If Input
B is not configured it will be set to 100% placing the
block in the NORMAL mode.
Input C, adaptive rate input, will vary the actual time
set in configuration between 0% and 100% as the
input signal varies from 0% to 100%.
The Rate Limiter can be used to limit the rate of
change of the valve signal or the rate at which the
local setpoint can be changed.
Unused Inputs
Input A: 0%
Input B: 100%
Input C: 100%
Input D: 100%
FB Number
42
October 1998
D
S T R U TIME- RATE UP ............. 0.00 to 9999.99 MIN
S T R D TIME- RATE DOWN ....... 0.00 to 9999.99 MIN
H I N A INPUT A ............................................. 00 to 99
H I N B INPUT B (NORMAL/BYPASS) ........... 00 to 99
H I N C INPUT C (ADAPTIVE RATE-UP) ....... 00 to 99
H I N D INPUT D (ADAPTIVE RATE-DN) ....... 00 to 99
A
SIGNAL INPUT
B
NORMAL
C
ADAPTIVE RATE-UP
D
ADAPTIVE RATE-DOWN
OUTPUT
42
BLOCK DIAGRAM
Output
Identification
Output: 42
8-45
FUNCTION BLOCK DESCRIPTIONS
8.17.4 DEAD TIME TABLE
FB43
The Dead Time Table includes 50 shift registers.
The Input INA will be held for a period of time and
then each register value will be transferred to the next
register. The maximum delay time 'TM' can be set in
soft configuration. The time for each shift to occur is
therefore equal to 0.02 x TM.
When INB is high (>=80%) or not configured the
function block will be in NORMAL operation. When
low (<75%) the dead time function is bypassed which
means that all registers and the output will be set
equal to INA.
Input C 'INC' is the adaptive dead time input. When
used it causes the output to pick the signal from the
register closest to the level of INC (e.g. Input C =
53% Output = Register 27, Input C = 56% Output =
Register 28, ..).
FB Number
43
UM348-1
DEAD TIME TABLE
FB43
FB43
A
DEAD TIME
TABLE
B
43
OUTPUT
C
S
H
H
H
T
I
I
I
TIME - MAX. DELAY ............... 0 to 10000 MIN
M
N A INPUT A .............................................. 00 to 99
N B INPUT B .............................................. 00 to 99
N C INPUT C .............................................. 00 to 99
A
0
1
S
H
I
F
T
Output
Identification
Output: 43
R
E
G
I
S
T
E
R
S
2
3
4
5
6
48
43
OUTPUT
49
50
B
BYPASS
C
BLOCK DIAGRAM
8-46
October 1998
UM348-1
FUNCTION BLOCK DESCRIPTIONS
8.18 MATH
8.18.1 MATH #1/#2/#3
FB34/FB35/FB36
MATH BLOCK #1 / #2 / #3
FB34 / FB35 / FB36
FB34 / FB35 / FB36
A
This function block provides general purpose
mathematical capabilities required in many control
applications (e.g. pressure/temperature
compensation, ratio computing, signal averaging,
.....). All 0-100% block inputs have a real range of
0-1, with the resultant 0-1 computed range
representing a 0-100% block output. The output of
the math block is not limited which allows
interconnection of math blocks for more complex
equations without any loss of accuracy.
B
C
S G O ** GAIN-OUTPUT ........... +/- .000000 to 999999
S G A ** GAIN-A INPUT ............ +/- .000000 to 999999
S G B ** GAIN-B INPUT ............ +/- .000000 to 999999
S G C ** GAIN-C INPUT ............ +/- .000000 to 999999
S B O ** BIAS-OUTPUT ............ +/- .000000 to 999999
S B A ** BIAS-A INPUT ............. +/- .000000 to 999999
S B B ** BIAS-B INPUT.............. +/- .000000 to 999999
S B C ** BIAS-C INPUT ............. +/- .000000 to 999999
Unused Inputs
Input A: 0% (0.0)
Input B: 0% (0.0)
Input C: 0% (0.0)
FB
Number
34
35
36
OUTPUT
*
MATH BLOCK
#1 / #2 / #3
H O ** A OPERATION A ................. SUB/ADD/MUL/DIV
H O ** B OPERATION B ................. SUB/ADD/MUL/DIV
H I N A INPUT A ............................................. 00 to 99
H I N B INPUT B .............................................. 00 to 99
H I N C INPUT C .............................................. 00 to 99
* See Output Identification
** FB34: 1, FB35: 2, FB36: 3
Output
Identification
Output: 34
Output: 35
Output: 36
Signal Equation
SO = GO {[(GA* SA+BA) OPERATION A (GB*SB+BB)] OPERATION B[GC*SC+BC]} + BO
(-/+/*/¸)
(-/+/*/¸)
SA, SB, and SC are input A, B, and C.
SO is the signal output.
If all three inputs are not used:
When used to multiply or divide A and B set BC = 1.00
When used to multiply or divide A and B set BB = 1.00
B
A
+
G
A
+
B
B
G
B
G
C
+
B
+
+
B
C
A
-/+
x/ :
B
C
+
-/+
x/ :
G
+
O
O
+
OUTPUT
BLOCK DIAGRAM
October 1998
8-47
FUNCTION BLOCK DESCRIPTIONS
8.18.2 GAIN & BIAS #1/#2
FB38/FB39
UM348-1
GAIN & BIAS #1 / #2
FB38 / FB39
FB38 / FB39
The Gain & Bias function block provides general
purpose scaling capabilities required in many control
applications (e.g. valve split ranging, signal scaling,
.....). All 0-100% block inputs have a real range of
0-1, with the resultant 0-1 computed range
representing a 0-100% block output. The output of
the Gain & Bias block is not limited allowing
interconnection with other math blocks for more
complex equations without loss of accuracy.
A
OUTPUT
*
#1 / #2
S
S
S
S
G
G
B
B
H I
O
A
O
A
N
*
*
*
*
A
GAIN-OUTPUT ........... +/- .000000 to 999999
GAIN-A INPUT ............ +/- .000000 to 999999
BIAS-OUTPUT ............ +/- .000000 to 999999
BIAS-A INPUT ............ +/- .000000 to 999999
INPUT A ............................................. 00 to 99
* See Output Identification
** FB38: 5, FB39: 6
Unused Inputs
Input A: 0% (0.0)
FB Number
38
39
GAIN & BIAS
Output Identification
Output: 38
Output: 39
B
A
G
+
A
B
A
+
G
+
O
+
OUTPUT
O
BLOCK DIAGRAM
8-48
October 1998
UM348-1
FUNCTION BLOCK DESCRIPTIONS
8.18.3 DEVIATION AMPLIFIER
FB22
DEVIATION AMPLIFIER
FB22
FB22
This function block computes the difference between
two inputs A & B and multiplies it by a configurable
Gain value. The result is summed with a third input
C and a configurable Bias value.
All 0-100% block inputs have a real range of 0-1,
with the resultant 0-1 computed range representing a
0-100% block output. The output of the Deviation
Amplifier block is not limited.
Unused Inputs (defaults)
Input A = 100% (1.0)
Input B = 0% (0.0)
Input C = 0% (0.0)
FB Number
22
Output
Identification
Signal Output: 29
A
B
DEVIATION
AMPLIFIER
OUTPUT
29
C
S G 1
S B 1
H
I
H
H
I
I
GAIN .......................... +/- .000001 to 999999
BIAS ........................... +/- .000001 to 999999
N A INPUT A ............................................. 00 to 99
N B INPUT B ............................................. 00 to 99
N C INPUT C ............................................. 00 to 99
B1
A
+
+
G1
+
OUTPUT
+
B
C
BLOCK DIAGRAM
October 1998
8-49
FUNCTION BLOCK DESCRIPTIONS
UM348-1
8.18.4 SQUARE ROOT EXTRACTOR
FB24
SQUARE ROOT EXTRACTOR
FB24
FB24
This function block will extract the square root of
any block input signal greater than zero. A
normalized 0-100% signal will result in a normalized
0-100% block output.
Graph 1 illustrates the function of this block over the
full 0-100% input and output range. Graph 2
illustrates the block function over the first 2% of the
input range. It has a built-in low limit to insure a
'fixed zero' at no flow conditions and a linearized
function up to 1% of input to minimize the high gain
associated with the square root function near zero.
A
H
I
44
OUTPUT
N A INPUT A ............................................. 00 to 99
A
FB Number
24
EXTRACTOR
Output Identification
Linear Signal Output: 44
0%
LO
LIMIT
EXTRACTOR
OUTPUT
BLOCK DIAGRAM
OUTPUT
20.00%
OUTPUT
120.00%
100.00%
15.00%
80.00%
60.00%
i0.00%
40.00%
5.00%
20.00%
0.00%
0.00%
-20.00%
0.00% 25.00%
50.00% 75.00%
INPUT
GRAPH 1 Full Range Function
8-50
100.00%
-5.00%
.
..
..
.. .
.
..
..
0.00%
..
. ..
. ..
... .
0.50% 1.00% 1.50%
INPUT
2.00%
GRAPH 2 Function @ Low End
October 1998
UM348-1
FUNCTION BLOCK DESCRIPTIONS
8.18.5 INTEGRATOR/TOTALIZER
FB16
This function block integrates input signal A and
increments the count accordingly. The Integrator is
configured by setting the Full Scale rate, the Time
Base, and Count Multiplier.
As an example, a 0-100% input represents a flow
rate of 0-400 gal/min. Select SFS = 400, STB =
MIN, SCM = 1, HCU = GAL. If, in this example,
the input equals 50% (200 gal/min) for 1 hour the
count would read 12000. In cases where the signal
will be integrated over a long period of time the count
may overflow the 6 digit counter. In this case a
Count Multiplier greater than 1 should be used. If
the Count Multiplier were set to 1000 the actual
count in this example would equal 12 (indicating 12 x
1000 = GAL). In other cases it may be desirable to
use a Count Multiplier less than 1 to increase
resolution for small batches. If a Count Multiplier of
0.1 were used, the Count in the example would equal
120000 (indicating 120000 x 0.1 GAL).
The function block also has two presets. The block
outputs for these presets will go to 100% when the
Count equals or exceeds the preset value. For INC
action, Count >= Preset. For DEC action, Count <=
Preset.
The COUNT will stop at 999999. To configure a
counter that rolls over, one of the presets can be set
to 999999 and the preset status connected to Input R.
Input S (STOP) will cause the integrator to stop
incrementing the COUNT when it goes high
(>=80%). Any accumulated value in the integrator
will be retained while in the STOP mode.
Input R (RESET) will cause the COUNT and any
accumulated value in the integrator to be reset to 0.
The reset action will occur when Input R goes high
(>=80%) and will be executed first in the block
INTEGRATOR/TOTALIZER
FB16
FB16
SIGNAL
A
STOP
S
RESET
R
INTEGRATOR
9 9 9 9 9 9
S
S
S
S
F S
T B
C M
Z D O
S S V
S P 1
9 9 9 9 9 9
PRESET 1
9 9 9 9 9 9
PRESET 2
92
P1 STATUS
93
P2 STATUS
FULL SCALE VALUE ......... 0.00001 to 999999
TIME BASE ................... SEC/MIN/HR/DAY/WK
COUNT MULTIPLIER ........ 0.00001 to 999999
ZERO DROP OUT .................... 0.0% to 30.0%
STARTING VALUE ........................ 0 to 999999
PRESET 1 ...................................... 0 to 999999
PRESET 2 ...................................... 0 to 999999
S P 2
S D I R DIRECTION ........................................ INC/DEC
COUNT UNITS .......................................... (****)
H C U
H T D D TOTALIZER DISPLA'Y DISABLE ....... NO/YES
H P C D PRESET CHANGE DISABLE .............. NO/YES
H I N A INPUT A (SIGNAL) .............................. 00 to 99
H I N S INPUT S (STOP) .................................. 00 to 99
H I N R INPUT R (RESET) ............................... 00 to 99
cycle so that any Input A will also be integrated
during the same cycle.
All Integrator/Totalizer displays (C, M, 1, & 2) will
be available for display using the D pushbutton,
unless the parameter HTDD is set to YES. Also the
values of the Presets can be changed when they are
displayed unless the parameter HPCD 'Presets
Change Disabled' is set to YES.
The counter will hold the count when the station has
a power outage. When starting a new batch, the
counter should be reset using INR.
(continued on next page)
October 1998
8-51
FUNCTION BLOCK DESCRIPTIONS
FB Number
16
Output
Identifications
P1 Status: 92
P2 Status: 93
PULSE
INTEGRATOR
A (0-100%)
S
STOP
R
RESET
UM348-1
ZERO DROP OUT
999999
COUNT
999999
PRESET 1
STATUS
PRESET 1
999999
PRESET 2
STATUS
PRESET 2
BLOCK DIAGRAM
8-52
October 1998
UM348-1
FUNCTION BLOCK DESCRIPTIONS
8.18.6 10 SEGMENT CHARACTERIZER
#1/#2
FB44/FB72
10-SEGMENT CHARACTERIZER #1 / #2
FB44 / FB72
FB44 / FB72
The 10-Segment Characterizer provides X,Y coordinate selections that can be used to obtain various
input/output characterizations.
S X 0
S X 1
Input A is the X variable, and the Output is Y.
This function block can be used for linearizing
signals in many process applications, including pH,
compressor surge, .... . All 10 segments must have
valid configuration values. Each Xn must be greater
or equal to Xn-1. Inputs that are less than X0 or
greater than X10 will have outputs equal to Y0 or
Y10.
FB Number
44
72
Output Identification
Characterized Signal:
45
Characterized Signal:
57
X5,Y5
100%
X4,Y4
O
U
T
P
U
T
A
X6,Y6
S X 2
S X 3
S X 4
S X 5
S X 6
S X 7
S X 8
S X 9
10-SEGMENT
CHARACTERIZER
#1 / #2
*
OUTPUT
INPUT CO-ORDINATE X0 ...... 0.00 to 100.00%
INPUT CO-ORDINATE X1 ...... 0.00 to 100.00%
INPUT CO-ORDINATE X2 ...... 0.00 to 100.00%
INPUT CO-ORDINATE X3 ...... 0.00 to 100.00%
INPUT CO-ORDINATE X4 ...... 0.00 to 100.00%
INPUT CO-ORDINATE X5 ...... 0.00 to 100.00%
INPUT CO-ORDINATE X6 ...... 0.00 to 100.00%
INPUT CO-ORDINATE X7 ...... 0.00 to 100.00%
INPUT CO-ORDINATE X8 ...... 0.00 to 100.00%
INPUT CO-ORDINATE X9 ...... 0.00 to 100.00%
S X 1 0 INPUT CO-ORDINATE X10 ..... 0.00 to 100.00%
OUTPUT CO-ORDINATE Y0 .. 0.00 to 100.00%
S Y 0
OUTPUT CO-ORDINATE Y1 .. 0.00 to 100.00%
S Y 1
OUTPUT CO-ORDINATE Y2 .. 0.00 to 100.00%
S Y 2
S Y 3
OUTPUT CO-ORDINATE Y3 .. 0.00 to 100.00%
S Y 4
OUTPUT CO-ORDINATE Y4 .. 0.00 to 100.00%
S Y 5
OUTPUT CO-ORDINATE Y5 .. 0.00 to 100.00%
S Y 6
OUTPUT CO-ORDINATE Y6 .. 0.00 to 100.00%
S Y 7
OUTPUT CO-ORDINATE Y7 .. 0.00 to 100.00%
OUTPUT CO-ORDINATE Y8 .. 0.00 to 100.00%
S Y 8
S Y 9
OUTPUT CO-ORDINATE Y9 .. 0.00 to 100.00%
S Y 1 0 OUTPUT CO-ORDINATE Y10 . 0.00 to 100.00%
H I N A INPUT A ............................................... 00 to 99
* See Output Identifications
X3,Y3
X7,Y7
X2,Y2
X8,Y8
X9,Y9
X1,Y1
0%
X10,Y10
X0,Y0
0%
October 1998
INPUT
100%
8-53
FUNCTION BLOCK DESCRIPTIONS
8.19 MISCELLANEOUS
8.19.1 BATCH SWITCH
FB53
The Batch Switch is normally used in the feedback
path of a controller to reduce the amount of overshoot
in a batch startup situation. When the signal input
INA is within the 0-100% range the signal will be
passed normally to the controller feedback and cause
normal reset action.
If INA (normally the controller output) equals or
exceeds a limit, the feedback signal to the controller
will be modified to keep the controller output at the
limit setting (e.g. if INA exceeds 100% the feedback
signal will be reduced).
In some cases, as with a large gain error, the
feedback can be reduced too much. This will
eliminate any overshoot, but may have the opposite
effect of a very sluggish startup. To overcome this,
the Batch Switch has a preload parameter 'SBPL' that
can be set in soft configuration. The setting puts a
limit on the amount of change that can be made to the
feedback signal.
Typical Application
When the valve signal is <0% or >100% FB53
adjusts the controller feedback signal to keep the
controller output at the limit setting (i.e. 0% or
100%). However, FB53 will not adjust not adjust the
feedback signal above the PreLoad when the 0% limit
is reached or below the PreLoad when the 100% limit
is reached.
FB Number
53
8-54
Output
Identification
Switch Output: 56
UM348-1
BATCH SWITCH
FB53
FB53
S
B P L
H
I
OUTPUT
56
BATCH SWITCH
A
BATCH PRE-LOAD .............. 0.0 to 100%
N A INPUT A ...................................... 00 to 99
A
100%
100%
+
-
32
+
+
HS
LS
LS
HS
BPL
-
+
32
+
56
+
0%
0%
BLOCK DIAGRAM
PROCESS
P
FB13
PID #1
14
A
FB14
A/M #1
17 VALVE
F FEEDBACK
56
FB53
BATCH SWITCH
A
TYPICAL APPLICATION
October 1998
UM348-1
8.19.2 PASSWORD SECURITY
FB75
FUNCTION BLOCK DESCRIPTIONS
PASSWORD SECURITY
FB75
FB75
This function block works in combination with the
dip switch located on the MPU board to provide
various levels of configuration security. The dip
switch has the following lockout positions:
SW1 .. S (soft configuration)
SW2 .. ALARM (quick alarm)
SW3 .. TUNE (quick tune)
SW4 .. H/F/T (configuration)
SW5 .. C (calibration)
When the lockout switch is on, that portion of
configuration can be viewed but not changed. One
exception is FB75 which can only viewed/changed
when SW4 is off.
SECURITY
H T P W 'TUNE' PASSWORD .................................... ****
H A P W 'ALARM' PASSWORD ................................. ****
H S P W 'S CONFIGURATION' PASSWORD ............ ****
H H P W 'H CONFIGURATION' PASSWORD ............ ****
H C P W 'CALIBRATION' PASSWORD ...................... ****
The purpose of the Password Security function block
is to permit changing configuration parameters when
the lockout switches are on. Configuration
parameters can always be viewed by stepping down
past the password entry prompt.
When a configuration parameter is locked out, and
password security is active, a special prompt (four
underscore characters with the left one blinking) will
appear in the 4 character display. The UP/DOWN
arrows are used to select a character and the --->
pushbutton to move to the next position. Once all
characters are in place the STORE button is pressed.
If the correct password has been entered
configuration changes can then be entered. Unless
EXIT is pressed, any number of changes can be made
without re-entering the password. When an incorrect
password has been entered the special prompt will
again appear. The EXIT pushbutton can be pressed
to return to normal operation.
Password security is active, if FB75 has an ESN
'Execution Sequence Number' and a password has
been configured.
October 1998
8-55
FUNCTION BLOCK DESCRIPTIONS
8.19.3 HART® INTERFACE
FB98
UM348-1
HART INTERFACE
FB98
FB98
This function block groups parameters associated
with HART communication functions. It should be
used whenever higher level devices are intended to
interface with the Model 348.
Parameters 'H1P', 'H1S', & 'H1V' allow specific
block outputs to be configured as the LOOP 1
variables. In most cases these will be the same as the
loop variable inputs to the Operator Display block.
Parameters 'H2P', H2S', & 'H2V' are the LOOP 2
variables.
79
HART
STATUS
H1S
70
OUTPUT 70
H1V
71
OUTPUT 71
H2P
72
OUTPUT 72
73
OUTPUT 73
74
OUTPUT 74
H1P
FIELD COMMUNICATIONS PROTOCOL
H2S
8-56
COMMUNICATIONS
INTERFACE BLOCK
H2V
D
E
The polling address can be configured from 1 to 15,
whenever the Model 348's are used in a multi-drop
configuration. Otherwise the address should be set to
0.
Other Moore Products Co. controller products (i.e.
MYCRO, 352, ...) have a C/L function which allows
the Console operator and the Local operator to
arbitrate control of the loop functions. If it is desired
to utilize this function with the Model 348, parameter
HP1F should be set to CL. In this case PB1 (upper
position C, lower position L) is used to switch the
Model 348 between Console and Local from the
faceplate. When in Local, changes can only be made
from the Model 348 faceplate, except for a 'Go To
Console' command. If the Model 348 is in Console,
changes will only be accepted over the HART
fieldbus except for local operation of PB1, the D &
ACK pushbuttons. Also, in order for the C/L PB1
function to operate, FB98 must have a valid ESN,
PB1 must have a valid ESN, and parameter HP1F
must equal CL. In the case where the C/L function
is not used, the status that gets reported to the higher
level device will always reflect Console so that the
higher level device will be aware that changes can be
made. The one exception, is when the Model 348
goes into configuration, then the status will be
reported as Local and HOLD. When the CL function
is not used changes can be made locally or over the
HART fieldbus.
(continued on next page)
HART
F
G
H H 1
H H 1
H H 1
H H 2
H H 2
H H 2
H P O
H P 1
H
H
H
H
P 2
I N
I N
I N
P HART - LOOP 1 PROCESS ................ 00 to 99
S HART - LOOP 1 SETPOINT ................ 00 to 99
V HART - LOOP 1 VALVE ...................... 00 to 99
P HART - LOOP 2 PROCESS ................ 00 to 99
S HART - LOOP 2 SETPOINT ................ 00 to 99
V HART - LOOP 2 VALVE ...................... 00 to 99
L POLLING ADDRESS ............................. 0 to 15
F PB1 FUNCTION ................ USER/L1EI/L2EI/CL
F PB2 FUNCTION ..................... USER/L1EI/L2EI
D INPUT D .............................................. 00 to 99
E INPUT E ............................................... 00 to 99
F INPUT F ............................................... 00 to 99
G INPUT G .............................................. 00 to 99
H I N
H H T N
H
H
H
H
H
H
D
M
D
D
V
V
E
S
A
S
C
C
S
G
T
N
1
2
HART TAG NAME .................. 8 CHAR (ASCII)
HART DESCRIPTOR ............ 16 CHAR (ASCII)
H V C 3
H V C 4
HART MESSAGE ................. 32 CHAR (ASCII)
HART DATE ....................................DD/MM/YY
HART DEVICE SER. # .................. 0 to 999999
HART VARIABLE CODE 1 ...................... 0 to 8
HART VARIABLE CODE 2 ...................... 0 to 8
HART VARIABLE CODE 3 ...................... 0 to 8
HART VARIABLE CODE 4 ...................... 0 to 8
H R P
HART RESP. PREAMBLES ................... 5 to 50
October 1998
UM348-1
FUNCTION BLOCK DESCRIPTIONS
If it is desired to use External/Internal Setpoint (e.g.
FCO13) and have control of the E/I switching from a
higher level device, then either PB1 or PB2 should be
tied to the individual loop commands that control the
E/I switching. In this case parameters HP1F or
HP2F should be configured for Loop1 E/I 'L1EI' or
Loop 2 E/I 'L2EI'. In the case where the E/I function
is not selected for a loop, the Loop Status reported to
the Link will be I.
If a pushbutton is not intended for operation from a
higher level device then parameter HP_F should be
set to USER.
TABLE FB98-1 Variable Code Choices
HART Variable Code Choices
348 Function Block
Description
Units
0
UNASSIGNED
1
FB81
FB82
Direct Process
Pressure
Temperature
3
FB01
Analog Input #1
(see
FB81)
(see
FB82)
%
2
4
FB02
Analog Input #2
%
5
FB25
Analog Input #3
%
6
FB85
Pneumatic Input #1
%
7
FB86
Pneumatic Input #2
%
8
FB87
Pneumatic Input #3
%
9
FB81
Static Pressure
%
10
FB81
Capsule
Temperature
%
The Model 348 has two controller function blocks
that may also require interfacing with higher level
operator stations. As such, certain information and
commands are grouped into LOOPS (i.e. Loop 1 or
Loop 2). For example, A/M HART commands for
Loop 1 are always associated with FB14, while Loop
2 with FB55; E/I HART commands can be associated
as defined above. Setpoint commands for Loop 1 are
associated with FB17, while Loop 2
FB46; Alarm functions for Loop 1 are associated
with FB12, while Loop 2 with FB73; ...... .
Other Function Block outputs can be connected to
Inputs D-G for communication to higher level devices
via HART. Also, higher level devices can send
signals to the Model 348 for interconnection with
other function blocks using FB98 outputs 70-74.
Parameters HVC1, HVC2, HVC3, and HVC4 do not
need to be set when communicating with Moore
Products Co. master devices, such as the APACS
(continued on next page)
October 1998
8-57
FUNCTION BLOCK DESCRIPTIONS
UM348-1
HFM, Model 325 URICA, and Model 385 Loop
Operator’s Station.
The HART communication protocol includes
standard commands that can request variables as
primary, secondary, tertiary, or fourth. Parameters
HVC_ can be used to assign them to variables within
the Model 348. See Table FB98-1 for a complete
listing. Certain variables can only be assigned when
the options are installed.
8-58
n
October 1998
UM348-1
FACTORY CONFIGURED OPTIONS
9.0 FACTORY CONFIGURED OPTIONS
These are configurations stored in permanent memory (ROM) that can be transferred to the configuration memory
(battery backed RAM) with just a few keystrokes. A complete listing off all the factory configured options is given
below. The complete documentation for all FCOs is listed on the following pages.
9.1 FCO 00 ..................................................................................................................... ESN Reset (ESN=00)
9.2 FCO 01 ................................................................................................. Single-Loop PID Controller (TSP)*
9.3 FCO 02 ............................................................................................ Single-Loop PID Controller (NTSP)**
9.4 FCO 03 .................................................................................................. External-Set PID Controller (TSP)
9.5 FCO 04 ............................................................................................... External-Set PID Controller (NTSP)
9.6 FCO 05 ................................................................................................................. Ratio-Set PID Controller
9.7 FCO 10 ..................................................................................................................... Default Configuration
9.8 FCO 11 ......................................................................... Single-Loop PID Controller (TSP) - C/L Operation
9.9 FCO 12 ...................................................................... Single-Loop PID Controller (NTSP) - C/L Operation
9.10 FCO 13 ....................................................................... External-Set PID Controller (TSP) - C/L Operation
9.11 FCO 14 .................................................................... External-Set PID Controller (NTSP) - C/L Operation
9.12 FCO 15 ...................................................................................... Ratio-Set PID Controller - C/L Operation
9.13 FCO 20 ........................................................................................ Single Station Cascade Controller(TSP)
9.14 FCO 25 ................................................................................................. Dual-Loop PID Controllers (TSP)
9.15 FCO 26 .............................................................................................. Dual-Loop PID Controllers (NTSP)
9.16 FCO 31 ....................................................................... Single-Loop PID Controller (TSP) – Pressure Input
* TSP = Tracking Setpoint
** NTSP = Not-Tracking Setpoint
October 1998
9-1
FACTORY CONFIGURED OPTIONS
UM348-1
9.1 FCO 00 ESN RESET (ESN=00)
Sets all ESNs to 00 except FB15 which is set to 40
9.2 FCO 01 Single-Loop PID Controller (TSP)
With:
Hi/Lo Process Alarms
Deviation Alarm
Tracking Setpoint
Setpoint Limits
4-20 mA Input/Output
PROCESS
AI1+ (F7)
AI1C (F8)
FB01
INPUT
01
INP
A/B/D FB12
ALARM
C
INS
P
F FB13
PID
S
05 FB09
LIMIT
C
14
T
A
22
FB17
SET
C
A
FB14 18
A/M
17
INV
A
AO1+ (E11)
AO1C (E12)
FB03
OUT
VALVE
CONNECTION TO FB15 OPERATOR DISPLAY BLOCK
9-2
October 1998
UM348-1
FACTORY CONFIGURED OPTIONS
CONFIGURATION PARAMETERS
T
H
S
C
FB01
ESN 05
SRE NO
DV1 0.00 SEC
..............................................................................................................................................................................
FB03
ESN 45
INA 17
INB 00
..............................................................................................................................................................................
FB09
ESN 14
DSD NO
LL1
0.00%
INA 22
HL1 100.00%
..............................................................................................................................................................................
FB12
ESN 15
Q1R 4 (%)
SA1 100.00%
Q2R 4 (%)
SA2 0.00%
Q3R 4 (%)
SA3 100.00%
Q4R 4 (%)
SA4 0.00%
A1T HI
DA1 0.5%
A2T LO
DA2 0.5%
A3T DEV
DA3 0.5%
A4T NONE
DA4 0.5%
INA 01
EA1 EN
INB 01
EA2 EN
INC 05
EA3 EN
IND 01
EA4 DIS
A1I 0.0 SEC
A2I 0.0 SEC
A3I 0.0 SEC
A4I 0.0 SEC
A1O 0.0 SEC
A2O 0.0 SEC
A3O 0.0 SEC
A4O 0.0 SEC
A1R NO
A2R NO
A3R NO
A4R NO
...............................................................................................................................................................................
FB13
ESN 30
C1T PID
A1 REV
MRT NO
PG1 1.00
INP 01
TI1 100.00 M/R
INS 05
TD1 0.00 MIN
INF 17
DG1 10.00
INA 00
MR1 0.0%
INC 18
HL1 100.00%
LL1 0.00%
..............................................................................................................................................................................
(continued on next page)
October 1998
9-3
FACTORY CONFIGURED OPTIONS
UM348-1
H
S
C
AO NO
PUM 0.00%
PU LP
PUL NO
INA 14
INT 00
INE 00
INS 00
INL 00
..............................................................................................................................................................................
FB15
ESN 40
INP 01
DP1 0.00
INS 05
PL1 0.00000
INV 17
PH1 100.000
INX 00
DP2 0.00
INY 00
PL2 0.00000
INA 00
PH2 100.000
INL 00
DPX 0.00
PDR L
XL 0.00000
SDR L
XH 100.000
HS1 VALVE
DPY 0.00
HS2 VALVE
YL 0.0000
HD1 YES
YH 100.000
HD2 YES
TST 10 SEC
SCF YES
TSI TN1
IN1 00
IN2 00
U1S U1
U2S U2
TN1 TAG NAME 1
TN2 TAG NAME 2
EU1 PRCT
EU2 PRCT
EUX PRCT
EUY PRCT
FL1 A1
FL2 A2
FL3 A3
FL4 NONE
FL5 NONE
..............................................................................................................................................................................
FB17
ESN 10
INT 01
INC 18
INL 00
..............................................................................................................................................................................
FB14
T
ESN 35
(continued on next page)
9-4
October 1998
UM348-1
FACTORY CONFIGURED OPTIONS
H
S
C
H1P 01
H1S 05
H1V 17
H2P 00
H2S 00
H2V 00
POL 0
P1F USER
P2F USER
IND 00
INE 00
INF 00
ING 00
HTN HART TAG
DES HART DESCRIPTOR
MSG HART MESSAGE
DAT 01/01/93
DSN 0
VC1 3
VC2 4
VC3 5
VC4 0
RP 5
..............................................................................................................................................................................
FB98
October 1998
T
ESN 90
9-5
FACTORY CONFIGURED OPTIONS
UM348-1
9.3 FCO 02 SINGLE-LOOP PID CONTROLLER (NTSP)
With:
Hi/Lo Process Alarms
Deviation Alarm
Non-Tracking Setpoint
Setpoint Limits
4-20 mA Input/Output
PROCESS
AI1+ (F7)
AI1C (F8)
FB01
INPUT
01
INP
A/B/D FB12
ALARM
C
INS
P
F FB13 S
PID C
14
05 FB09 A
LIMIT
22
FB17
SET
A
FB14 18
A/M
17
A
AO1+ (E11)
AO1C (E12)
INV
FB03
OUT
VALVE
CONNECTION TO FB15 OPERATOR DISPLAY BLOCK
9-6
October 1998
UM348-1
FACTORY CONFIGURED OPTIONS
CONFIGURATION PARAMETERS
T
H
S
C
FB01
ESN 05
SRE NO
DV1 0.00 SEC
..............................................................................................................................................................................
FB03
ESN 45
INA 17
INB 00
..............................................................................................................................................................................
FB09
ESN 14
DSD NO
LL1
0.00%
INA 22
HL1 100.00%
..............................................................................................................................................................................
FB12
ESN 15
Q1R 4 (%)
SA1 100.00%
Q2R 4 (%)
SA2 0.00%
Q3R 4 (%)
SA3 100.00%
Q4R 4 (%)
SA4 0.00%
A1T HI
DA1 0.5%
A2T LO
DA2 0.5%
A3T DEV
DA3 0.5%
A4T NONE
DA4 0.5%
INA 01
EA1 EN
INB 01
EA2 EN
INC 05
EA3 EN
IND 01
EA4 DIS
A1I 0.0 SEC
A2I 0.0 SEC
A3I 0.0 SEC
A4I 0.0 SEC
A1O 0.0 SEC
A2O 0.0 SEC
A3O 0.0 SEC
A4O 0.0 SEC
A1R NO
A2R NO
A3R NO
A4R NO
..............................................................................................................................................................................
FB13
ESN 30
C1T PID
A1 REV
MRT NO
PG1 1.00
INP 01
TI1 100.00 M/R
INS 05
TD1 0.00 MIN
INF 17
DG1 10.00
INA 00
MR1 0.00%
INC 18
HL1 100.00%
LL1 0.00%
.......................................................................................................................................…...................................
(continued on next page)
October 1998
9-7
FACTORY CONFIGURED OPTIONS
UM348-1
H
S
C
AO NO
PUM 0.00%
PU LP
PUL NO
INA 14
INT 00
INE 00
INS 00
INL 00
..............................................................................................................................................................................
FB15
ESN 40
INP 01
DP1 0.00
INS 05
PL1 0.00000
INV 17
PH1 100.000
INX 00
DP2 0.00
INY 00
PL2 0.00000
INA 00
PH2 100.000
INL 00
DPX 0.00
PDR L
XL 0.00000
SDR L
XH 100.000
HS1 VALVE
DPY 0.00
HS2 VALVE
YL 0.00000
HD1 YES
YH 100.000
HD2 YES
TST 10 SEC
SCF YES
TSI TN1
IN1 00
U1S U1
U2S U2
TN1 TAG NAME 1
TN2 TAG NAME 2
EU1 PRCT
EU2 PRCT
EUX PRCT
EUY PRCT
FL1 A1
FL2 A2
FL3 A3
FL4 NONE
FL5 NONE
..............................................................................................................................................................................
FB17
ESN 10
INT 00
INC 00
INL 00
.................................................................................................................................................................….........
FB14
T
ESN 35
(continued on next page)
9-8
October 1998
UM348-1
FACTORY CONFIGURED OPTIONS
H
S
C
H1P 01
H1S 05
H1V 17
H2P 00
H2S 00
H2V 00
POL 00
P1F USER
P2F USER
IND 00
INE 00
INF 00
ING 00
HTN HART TAG
DES HART DESCRIPTOR
MSG HART MESSAGE
DAT 01/01/93
DSN 0
VC1 3
VC2 4
VC3 5
VC4 0
RP 5
..............................................................................................................................................................................
FB98
October 1998
T
ESN 90
9-9
FACTORY CONFIGURED OPTIONS
UM348-1
9.4 FCO 03 EXTERNAL-SET PID CONTROLLER (TSP)
With:
HI/Lo Process Alarms
Deviation Alarm
Tracking Setpoint
Setpoint Limits
4-20 mA Inputs/Output
EXTERNAL SETPOINT
PROCESS
AI1+ (F7)
AI1C (F8)
AI2+ (F10)
AI2C (F11)
FB01
INPUT
01
A/B/D
FB02
INPUT
02
FB12
ALARM
INX
C
INP
INS
P
F FB13
PID
S
E
05 FB09
LIMIT
C
14
17
T
FB17
SET
A
FB14
A/M
A
A FB21
OR
18
INV
21
09 FB11
E/I
22
25
I
C
B
A
AO1+ (E11)
AO1C (E12)
FB03
OUT
VALVE
CONNECTION TO FB15 OPERATOR DISPLAY BLOCK
9-10
October 1998
UM348-1
FACTORY CONFIGURED OPTIONS
CONFIGURATION PARAMETERS
T
H
S
C
FB01
ESN 05
SRE NO
DV1 0.00 SEC
......................................................................................................................................................……................
FB02
ESN 07
SRE NO
DV2 0.00 SEC
........................................................................................................................................................……..............
FB03
ESN 45
INA 17
INB 00
..........................................................................................................................................................……............
FB09
ESN 14
DSD NO
LL1
0.00%
INA 09
HL1 100.00%
.............................................................................................................................................................…….........
FB11
ESN 13
EO NO
PU LP
S1A SUS
DSD NO
INE 02
INI 22
INA 00
..............................................................................................................................................................................
FB12
ESN 15
Q1R 4 (%)
SA1 100.00%
Q2R 4 (%)
SA2 0.00%
Q3R 4 (%)
SA3 100.00%
Q4R 4 (%)
SA4 0.00%
A1T HI
DA1 0.5%
A2T LO
DA2 0.5%
A3T DEV
DA3 0.5%
A4T NONE
DA4 0.5%
INA 01
EA1 EN
INB 01
EA2 EN
INC 05
EA3 EN
IND 01
EA4 DIS
A1I 0.0 SEC
A2I 0.0 SEC
A3I 0.0 SEC
A4I 0.0 SEC
A1O 0.0 SEC
A2O 0.0 SEC
A3O 0.0 SEC
A4O 0.0 SEC
A1R NO
A2R NO
A3R NO
A4R NO
..............................................................................................................................................................................
(continued on next page)
October 1998
9-11
FACTORY CONFIGURED OPTIONS
S
C
A1 REV
PG1 1.00
TI1 100.00 M/R
TD1 0.00 MIN
DG1 10.00
MR1 0.00%
HL1 100.00%
LL1 0.00%
..............................................................................................................................................................................
FB14
ESN 35
AO NO
PUM 0.0%
PU LP
PUL NO
INA 14
INT 00
INE 00
INS 00
INL 00
..............................................................................................................................................................................
FB15
ESN 40
INP 01
DP1 0.00
INS 05
PL1 0.00000
INV 17
PH1 100.000
INX 02
DP2 0.00
INY 00
PL2 0.00000
INA 00
PH2 100.000
INL 00
DPX 0.00
PDR L
XL 0.00000
SDR L
XH 100.000
HS1 VALVE
DPY 0.00
HS2 VALVE
YL 0.00000
HD1 YES
YH 100.000
HD2 YES
TST 10 SEC
SCF YES
TSI TN1
IN1 00
IN2 00
U1S U1
U2S U2
TN1 TAG NAME 1
TN2 TAG NAME 2
EU1 PRCT
EU2 PRCT
EUX PRCT
EUY PRCT
FL1 A1
FL2 A2
(continued on next page)
FB13
9-12
T
ESN 30
UM348-1
H
C1T PID
MRT NO
INP 01
INS 05
INF 17
INA 00
INC 18
October 1998
UM348-1
FACTORY CONFIGURED OPTIONS
H
S
C
FL3 A3
FL4 NONE
FL5 NONE
..............................................................................................................................................................................
FB17
ESN 10
INT 01
INC 21
INL 00
..............................................................................................................................................................................
FB21
ESN 38
LT2 OR
INA 18
INB 25
..............................................................................................................................................................................
FB98
ESN 90
H1P 01
H1S 05
H1V 17
H2P 00
H2S 00
H2V 00
POL 0
P1F USER
P2F USER
IND 00
INE 00
INF 00
ING 00
HTN HART TAG
DES HART DESCRIPTOR
MSG HART MESSAGE
DAT 01/01/93
DSN 0
VC1 3
VC2 4
VC3 5
VC4 0
RP 5
..............................................................................................................................................................................
FB15
(cont’d)
October 1998
T
ESN 40
9-13
FACTORY CONFIGURED OPTIONS
UM348-1
9.5 FCO 04 EXTERNAL-SET PID CONTROLLER (NTSP)
With:
HI/Lo Process Alarms
Deviation Alarm
Non-Tracking Setpoint
Setpoint Limits
4-20 mA Inputs/Output
PROCESS
EXTERNAL SETPOINT
FB01
INPUT
AI1+ (F7)
AI1C (F8)
01
INP
02
A/B/D FB12
ALARM
C
P
F FB13
PID
INX
INS
05
S
C
FB09
LIMIT
E
A
14
AO1+ (E11)
AO1C (E12)
FB11
E/I
I
FB17
SET
FB14 18
A/M
A
09
22
A
17
FB02
INPUT
AI2+ (F10)
AI2C (F11)
INV
FB03
OUT
VALVE
CONNECTION TO FB15 OPERATOR DISPLAY BLOCK
9-14
October 1998
UM348-1
FACTORY CONFIGURED OPTIONS
CONFIGURATION PARAMETERS
T
H
S
C
FB01
ESN 05
SRE NO
DV1 0.00 SEC
..............................................................................................................................................................................
FB02
ESN 07
SRE NO
DV2 0.00 SEC
..............................................................................................................................................................................
FB03
ESN 45
INA 17
INB 00
..............................................................................................................................................................................
FB09
ESN 14
DSD NO
LL1
0.00%
INA 09
HL1 100.00%
..............................................................................................................................................................................
FB11
ESN 13
EO NO
PU LP
S1A SUS
DSD NO
INE 02
INI 22
INA 00
..............................................................................................................................................................................
FB12
ESN 15
Q1R 4 (%)
SA1 100.00%
Q2R 4 (%)
SA2 0.00%
Q3R 4 (%)
SA3 100.00%
Q4R 4 (%)
SA4 0.00%
A1T HI
DA1 0.5%
A2T LO
DA2 0.5%
A3T DEV
DA3 0.5%
A4T NONE
DA4 0.5%
INA 01
EA1 EN
INB 01
EA2 EN
INC 05
EA3 EN
IND 01
EA4 DIS
A1I 0.0 SEC
A2I 0.0 SEC
A3I 0.0 SEC
A4I 0.0 SEC
A1O 0.0 SEC
A2O 0.0 SEC
A3O 0.0 SEC
A4O 0.0 SEC
A1R NO
A2R NO
A3R NO
A4R NO
..............................................................................................................................................................................
(continued on next page)
October 1998
9-15
FACTORY CONFIGURED OPTIONS
S
C
A1 REV
PG1 1.00
TI1 100.00 M/R
TD1 0.00 MIN
DG1 10.00
MR1 0.0%
HL1 100.00%
LL1 0.00%
..............................................................................................................................................................................
FB14
ESN 35
AO NO
PUM 0.00%
PU LP
PUL NO
INA 14
INT 00
INE 00
INS 00
INL 00
..............................................................................................................................................................................
FB15
ESN 40
INP 01
DP1 0.00
INS 05
PL1 0.00000
INV 17
PH1 100.000
INX 02
DP2 0.00
INY 00
PL2 0.00000
INA 00
PH2 100.000
INL 00
DPX 0.00
PDR L
XL 0.00
SDR L
XH 100.00
HS1 VALVE
DPY 0.00
HS2 VALVE
YL 0.00
HD1 YES
YH 100.00
HD2 YES
TST 10 SEC
SFC YES
TSI TN1
IN1 00
IN2 00
U1S U1
U2S U2
TN1 TAG NAME 1
TN2 TAG NAME 2
EU1 PRCT
EU2 PRCT
EUX PRCT
EUY PRCT
FL1 A1
FL2 A2
(continued on next page)
FB13
9-16
T
ESN 30
UM348-1
H
C1T PID
MRT NO
INP 01
INS 05
INF 17
INA 00
INC 18
October 1998
UM348-1
FACTORY CONFIGURED OPTIONS
H
S
C
FL3 A3
FL4 NONE
FL5 NONE
..............................................................................................................................................................................
FB17
ESN 10
INT 00
INC 00
INL 00
..............................................................................................................................................................................
FB98
ESN 90
H1P 01
H1S 05
H1V 17
H2P 00
H2S 00
H2V 00
POL 0
P1F USER
P2F USER
IND 00
INE 00
INF 00
ING 00
HTN HART TAG
DES HART DESCRIPTOR
MSG HART MESSAGE
DAT 01/01/93
DSN 0
VC1 3
VC2 4
VC3 5
VC4 0
RP 5
..............................................................................................................................................................................
FB15
(cont’d)
October 1998
T
ESN 40
9-17
FACTORY CONFIGURED OPTIONS
UM348-1
9.6 FCO 05 RATIO-SET PID CONTROLLER
With:
HI/Lo Process Alarms
Deviation Alarm
Tracking Setpoint
Setpoint Limits
4-20 mA Inputs/Output
PROCESS
AI1+ (F7)
AI1C (F8)
EXTERNAL INPUT
FB01
INPUT
01
FB02
INPUT
AI2+ (F10)
AI2C (F11)
INX
A/B/D FB12
ALARM
FB07
RATIO
C
INP
F FB13
PID
03 E
INS
P
S
05 FB09
LIMIT
C
14
A
17
A
T
FB17
SET
FB14 18
A/M
A FB21
OR
INV
02
A
21
09 FB11
E/I
22
25
I
C
B
A
AO1+ (E11)
AO1C (E12)
FB03
OUT
VALVE
CONNECTION TO FB15 OPERATOR DISPLAY BLOCK
9-18
October 1998
UM348-1
FACTORY CONFIGURED OPTIONS
CONFIGURATION PARAMETERS
T
H
S
C
FB01
ESN 05
SRE NO
DV1 0 SEC
..............................................................................................................................................................................
FB02
ESN 07
SRE NO
DV2 0 SEC
..............................................................................................................................................................................
FB03
ESN 45
INA 17
INB 00
..............................................................................................................................................................................
FB07
ESN 08
INA 02
R 1.00
INB 00
RRL 0.50
INC 00
RRH 1.50
IND 00
RCD NO
..............................................................................................................................................................................
FB09
ESN 14
DSD NO
LL1
0.00%
INA 09
HL1 100.00%
..............................................................................................................................................................................
FB11
ESN 13
EO NO
PU LP
S1A SUS
DSD NO
INE 03
INI 22
INA 00
..............................................................................................................................................................................
FB12
ESN 15
Q1R 4 (%)
SA1 100.0%
Q2R 4 (%)
SA2 0.0%
Q3R 4 (%)
SA3 100.0%
Q4R 4 (%)
SA4 0.0%
A1T HI
DA1 0.5%
A2T LO
DA2 0.5%
A3T DEV
DA3 0.5%
A4T NONE
DA4 0.5%
INA 01
EA1 EN
INB 01
EA2 EN
INC 05
EA3 EN
IND 01
EA4 DIS
A1I 0.0 SEC
A2I 0.0 SEC
A3I 0.0 SEC
A4I 0.0 SEC
A1O 0.0 SEC
A2O 0.0 SEC
(continued on next page)
October 1998
9-19
FACTORY CONFIGURED OPTIONS
UM348-1
H
S
C
A3O 0.0 SEC
A4O 0.0 SEC
A1R NO
A2R NO
A3R NO
A4R NO
..............................................................................................................................................................................
FB13
ESN 30
C1T PID
A1 REV
MRT NO
PG1 1.00
INP 01
TI1 100 M/R
INS 05
TD1 0.00 MIN
INF 17
DG1 10.00
INA 00
MR1 0.0%
INC 18
HL1 100.00%
LL1 0.00%
..............................................................................................................................................................................
FB14
ESN 35
AO NO
PUM 0.0%
PU LP
PUL NO
INA 14
INT 00
INE 00
INS 00
INL 00
..............................................................................................................................................................................
FB15
ESN 40
INP 01
DP1 0.00
INS 05
PL1 0.00
INV 17
PH1 100.00
INX 02
DP2 0.00
INY 00
PL2 0.00
INA 00
PH2 100.00
INL 00
DPX 0.00
PDR L
XL 0.00
SDR L
XH 100.00
HS1 VALVE
DPY 0.00
HS2 VALVE
YL 0.00
HD1 YES
YH 100.00
HD2 YES
TST 10 SEC
SCF YES
TSI TN1
IN1 00
IN2 00
U1S U1
U2S U2
FB12
(cont’d)
T
ESN 15
(continued on next page)
9-20
October 1998
UM348-1
FACTORY CONFIGURED OPTIONS
H
S
C
TN1 TAG NAME 1
TN2 TAG NAME 2
EU1 PRCT
EU2 PRCT
EUX PRCT
EUY PRCT
FL1 A1
FL2 A2
FL3 A3
FL4 NONE
FL5 NONE
..............................................................................................................................................................................
FB17
ESN 10
INT 01
INC 21
INL 00
..............................................................................................................................................................................
FB21
ESN 38
LT2 OR
INA 18
INB 25
..............................................................................................................................................................................
FB98
ESN 90
H1P 01
H1S 05
H1V 17
H2P 00
H2S 00
H2V 00
POL 0
P1F USER
P2F USER
IND 00
INE 00
INF 00
ING 00
HTN HART TAG
DES HART DESCRIPTOR
MSG HART MESSAGE
DAT 01/01/93
DSN 0
VC1 3
VC2 4
VC3 5
VC4 0
RP 5
..............................................................................................................................................................................
FB15
(cont’d)
October 1998
T
ESN 40
9-21
FACTORY CONFIGURED OPTIONS
UM348-1
9.7 FCO 10 DEFAULT CONFIGURATION
CONFIGURATION PARAMETERS
T
H
S
C
FB01
ESN 00
SRE NO
DV1 0 SEC
..............................................................................................................................................................................
FB02
ESN 00
SRE NO
DV2 0 SEC
..............................................................................................................................................................................
FB03
ESN 00
INA 00
INB 00
..............................................................................................................................................................................
FB04
ESN 00
INA 00
..............................................................................................................................................................................
FB05
ESN 00
INA 00
..............................................................................................................................................................................
FB06
ESN 00
..............................................................................................................................................................................
FB07
ESN 00
INA 00
R 1.00
INB 00
RRL 0.50
INC 00
RRH 1.50
IND 00
RCD NO
..............................................................................................................................................................................
FB08
ESN 00
OBR 5 (%)
B 0.00%
INA 00
INE 00
INC 00
IND 00
BCD NO
..............................................................................................................................................................................
FB09
ESN 00
DSD NO
LL1 0.00%
INA 00
HL1 100.00%
..............................................................................................................................................................................
FB10
ESN 00
S1B HI
S1C HI
DSD NO
INA 00
INB 00
INC 00
................................................................................................................................................................……......
FB11
ESN 00
EO NO
PU LP
S1A SUS
DSD NO
INE 00
(continued on next page)
9-22
October 1998
UM348-1
FACTORY CONFIGURED OPTIONS
T
H
S
C
FB11
ESN 00
INI 00
(cont’d)
INA 00
..............................................................................................................................................................……........
FB12
ESN 00
Q1R 4 (%)
SA1 100.0%
Q2R 4 (%)
SA2 0.0%
Q3R 4 (%)
SA3 100.0%
Q4R 4 (%)
SA4 0.0%
A1T HI
DA1 0.5%
A2T LO
DA2 0.5%
A3T DEV
DA3 0.5%
A4T NONE
DA4 0.5%
INA 00
EA1 EN
INB 00
EA2 EN
INC 00
EA3 EN
IND 00
EA4 DIS
A1I 0.0 SEC
A2I 0.0 SEC
A3I 0.0 SEC
A4I 0.0 SEC
A1O 0.0 SEC
A2O 0.0 SEC
A3O 0.0 SEC
A4O 0.0 SEC
A1R NO
A2R NO
A3R NO
A4R NO
..............................................................................................................................................................................
FB13
ESN 00
C1T PID
A1 REV
MRT NO
PG1 1.00
INP 00
TI1 100 M/R
INS 00
TD1 0.00 MIN
INF 00
DG1 10.00
INA 00
MR1 0.0%
INC 00
HL1 100.00%
LL1 0.00%
..............................................................................................................................................................................
FB14
ESN 00
AO NO
PUM 0.0%
PU LP
PUL NO
INA 00
INT 00
INE 00
INS 00
INL 00
October 1998
9-23
FACTORY CONFIGURED OPTIONS
UM348-1
H
S
C
INP 00
DP1 0.00
INS 00
PL1 0.00
INV 00
PH1 100.00
INX 00
DP2 0.00
INY 00
PL2 0.00
INA 00
PH2 100.00
INL 00
DPX 0.00
PDR L
XL 0.00
SDR L
XH 100.00
HS1 VALVE
DPY 0.00
HS2 VALVE
YL 0.00
HD1 YES
YH 100.00
HD2 YES
TST 10 SEC
SCF YES
TSI TN1
IN1 00
IN2 00
U1S U1
U2S U2
TN1 TAG NAME 1
TN2 TAG NAME 2
EU1 PRCT
EU2 PRCT
EUX PRCT
EUY PRCT
FL1 NONE
FL2 NONE
FL3 NONE
FL4 NONE
FL5 NONE
.......................................................................................................................................…...................................
FB16
ESN 00
CU PRCT
FS 100
TDD NO
TB MIN
PCD NO
CM 1
INA 00
ZDO 0.0%
INS 00
SV 0
INR 00
P1 0
P2 0
DIR INC
..............................................................................................................................................................................
FB17
ESN 00
INT 00
INC 00
INL 00
..............................................................................................................................................................................
FB15
9-24
T
ESN 40
October 1998
UM348-1
FACTORY CONFIGURED OPTIONS
H
S
C
INT 00
H1 0.00%
INC 00
HCD NO
..............................................................................................................................................................................
FB19
ESN 00
HCD NO
H2 0.00%
..............................................................................................................................................................................
FB20
ESN 00
LT1 AND
INA 00
INB 00
..............................................................................................................................................................................
FB21
ESN 00
LT2 OR
INA 00
INB 00
..............................................................................................................................................................................
FB22
ESN 00
INA 00
G1 1
INB 00
B1 0
INC 00
..............................................................................................................................................................................
FB23
ESN 00
EO NO
PU LP
S1A SUS
DSD NO
INE 00
INI 00
INA 00
.............................................................................................................................................................................
FB24
ESN 00
INA 00
.............................................................................................................................................................................
FB25
ESN 00
SRE NO
DV3 0 SEC
..............................................................................................................................................................................
FB28
ESN 00
INA 00
FS 100
INS 00
TB MIN
CM 1
ZD 0.0%
PW 106 MSEC
..............................................................................................................................................................................
FB29
ESN 00
INA 00
INB 00
..............................................................................................................................................................................
FB30
ESN 00
..............................................................................................................................................................................
FB32
ESN 00
INA 00
A1 DIR
..............................................................................................................................................................................
FB18
October 1998
T
ESN 00
9-25
FACTORY CONFIGURED OPTIONS
UM348-1
H
S
C
INA 00
A2 DIR
..............................................................................................................................................................................
FB34
ESN 00
O1A MUL
GO1 1
O1B DIV
GA1 1
INA 00
GB1 1
INB 00
GC1 1
INC 00
BO1 0
BA1 0
BB1 0
BC1 0
..............................................................................................................................................................................
FB35
ESN 00
O2A MUL
GO2 1
O2B DIV
GA2 1
INA 00
GB2 1
INB 00
GC2 1
INC 00
BO2 0
BA2 0
BB2 0
BC2 0
..............................................................................................................................................................................
FB36
ESN 00
O3A MUL
GO3 1
O3B DIV
GA3 1
INA 00
GB3 1
INB 00
GC3 1
INC 00
BO3 0
BA3 0
BB3 0
BC3 0
..............................................................................................................................................................................
FB38
ESN 00
INA 00
GO5 1
GA5 1
BO5 0
BA5 0
..............................................................................................................................................................................
FB39
ESN 00
INA 00
GO6 1
GA6 1
BO6 0
BA6 0
..............................................................................................................................................................................
FB40
ESN 00
INA 00
TL 0.00 MIN
INB 00
..............................................................................................................................................................................
FB41
ESN 00
INA 00
TH 0.00 MIN
INB 00
FB33
9-26
T
ESN 00
October 1998
UM348-1
FACTORY CONFIGURED OPTIONS
H
S
C
INA 00
TRU 1.00 MIN
INB 00
TRD 1.00 MIN
INC 00
IND 00
..............................................................................................................................................................................
FB43
ESN 00
INA 00
TM 1 MIN
INB 00
INC 00
..............................................................................................................................................................................
FB44
ESN 00
INA 00
X0 0.00%
X1 10.00%
X2 20.00%
X3 30.00%
X4 40.00%
X5 50.00%
X6 60.00%
X7 70.00%
X8 80.00%
X9 90.00%
X10 100.00%
Y0 0.00%
Y1 10.00%
Y2 20.00%
Y3 30.00%
Y4 40.00%
Y5 50.00%
Y6 60.00%
Y7 70.00%
Y8 80.00%
Y9 90.00%
Y10 100.00%
.............................................................................................................................................................................
FB45
ESN 00
C2T PID
A2 REV
MRT NO
PG2 1.00
INP 00
TI2 100 M/R
INS 00
TD2 0.00 MIN
INF 00
DG2 10.00
INA 00
MR2 0.0%
INC 00
HL2 100.00%
LL2 0.00%
..............................................................................................................................................................................
FB46
ESN 00
INT 00
INC 00
..............................................................................................................................................................................
FB42
October 1998
T
ESN 00
9-27
FACTORY CONFIGURED OPTIONS
UM348-1
H
S
C
INA 00
TF 0.00 MIN
INB 00
TN 0.00 MIN
..............................................................................................................................................................................
FB48
ESN 00
LT3 AND
INA 00
INB 00
..............................................................................................................................................................................
FB49
ESN 00
INA 00
INB 00
INC 00
..............................................................................................................................................................................
FB50
ESN 00
LT4 OR
INA 00
INB 00
..............................................................................................................................................................................
FB51
ESN 00
DSD NO
LL2 0.00%
INA 00
HL2 100.00%
..............................................................................................................................................................................
FB53
ESN 00
INA 00
BPL 0.0%
..............................................................................................................................................................................
FB55
ESN 00
AO NO
PUM 0.0%
PU LP
PUL NO
INA 00
INT 00
INE 00
INS 00
...............................................................................................................................................................................
FB61
ESN 00
LT5 AND
INA 00
INB 00
..............................................................................................................................................................................
FB62
ESN 00
LT6 OR
INA 00
INB 00
..............................................................................................................................................................................
FB64
ESN 00
C1A DIR
TC1 100.00%
C2A DIR
TC2 100.00%
C3A DIR
TC3 100.00%
C4A DIR
TC4 100.00%
INA 00
DC1 0.5%
INB 00
DC2 0.5%
INC 00
DC3 0.5%
FB47
T
ESN 00
(continued on next page)
9-28
October 1998
UM348-1
FACTORY CONFIGURED OPTIONS
H
S
C
IND 00
DC4 0.5%
INE 00
INF 00
ING 00
INH 00
..............................................................................................................................................................................
FB65
ESN 00
INA 00
DT 0.00 SEC
DTT OFF
OPU YES
..............................................................................................................................................................................
FB67
ESN 00
INA 00
OT 0.00 SEC
..............................................................................................................................................................................
FB71
ESN 00
INA 00
INB 00
IND 00
INE 00
INF 00
ING 00
INC 00
..............................................................................................................................................................................
FB72
ESN 00
INA 00
X0 0.00%
X1 10.00%
X2 20.00%
X3 30.00%
X4 40.00%
X5 50.00%
X6 60.00%
X7 70.00%
X8 80.00%
X9 90.00%
X10 100.00%
Y0 0.00%
Y1 10.00%
Y2 20.00%
Y3 30.00%
Y4 40.00%
Y5 50.00%
Y6 60.00%
Y7 70.00%
Y8 80.00%
Y9 90.00%
Y10 100.00%
.............................................................................................................................................................................
FB64
October 1998
T
ESN 00
9-29
FACTORY CONFIGURED OPTIONS
UM348-1
H
S
C
Q5R 4 (%)
SA5 100.0%
Q6R 4 (%)
SA6 0.0%
Q7R 4 (%)
SA7 100.0%
Q8R 4 (%)
SA8 0.0%
A5T HI
DA5 0.5%
A6T LO
DA6 0.5%
A7T DEV
DA7 0.5%
A8T NONE
DA8 0.5%
INA 00
EA5 EN
INB 00
EA6 EN
INC 00
EA7 EN
IND 00
EA8 DIS
A5I 0.0 SEC
A6I 0.0 SEC
A7I 0.0 SEC
A8I 0.0 SEC
A5O 0.0 SEC
A6O O.O SEC
A7O 0.0 SEC
A8O 0.0 SEC
A5R NO
A6R NO
A7R NO
A8R NO
..............................................................................................................................................................................
FB75
ESN 00
TPW ____
APW ____
SPW ____
HPW ____
CPW ____
..............................................................................................................................................................................
FB81
ESN 00
SRE NO
DVP 0 SEC
MVU *
MVL *
MVH *
..............................................................................................................................................................................
FB82
ESN 00
IT *
DVP 0 SEC
BOD UP
MVU *
MVL *
MVH *
..................................................................................................................................….........................................
FB85
ESN 00
SRE NO
DV1 0 SEC
...............................................................................................................................................................................
FB86
ESN 00
SRE NO
DV2 0 SEC
...............................................................................................................................................................................
FB73
9-30
T
ESN 00
October 1998
UM348-1
FACTORY CONFIGURED OPTIONS
H
S
C
LT7 AND
INA 00
INB 00
...............................................................................................................................................................................
FB89
ESN 00
LT8 AND
INA 00
INB 00
...............................................................................................................................................................................
FB90
ESN 00
LT9 AND
INA 00
INB 00
...............................................................................................................................................................................
FB98
ESN 00
H1P 00
H1S 00
H1V 00
H2P 00
H2S 00
H2V 00
POL 0
P1F USER
P2F USER
IND 00
INE 00
INF 00
ING 00
HTN HART TAG
DES HART DESCRIPTOR
MSG HART MESSAGE
DAT 01/01/93
DSN 0
VC1 3
VC2 4
VC3 5
VC4 0
RP 5
...............................................................................................................................................................................
FB88
October 1998
T
ESN 00
9-31
FACTORY CONFIGURED OPTIONS
UM348-1
9.8 FCO 11 SINGLE-LOOP PID CONTROLLER (TSP) C/L OPERATION
With:
Hi/Lo Process Alarms
Deviation Alarm
Tracking Setpoint
Setpoint Limits
4-20 mA Input/Output
PROCESS
AI1+ (F7)
AI1C (F8)
FB01
INPUT
01
INP
A/B/D FB12
ALARM
C
INS
P
T
05 FB09 A
FB17
LIMIT
22 SET
F FB13 S
PID C
C
14
A
FB14
A/M
17
A
AO1+ (E11)
AO1C (E12)
FB03
OUT
18
INV
C
64
FB98
HART
FB23
PBT#1
L
63
CONSOLE
LOCAL
VALVE
CONNECTION TO FB15 OPERATOR DISPLAY BLOCK
9-32
October 1998
UM348-1
FACTORY CONFIGURED OPTIONS
CONFIGURATION PARAMETERS
T
H
S
C
FB01
ESN 05
SRE NO
DV1 0 SEC
...............................................................................................................................................................................
FB03
ESN 45
INA 17
INB 00
...............................................................................................................................................................................
FB09
ESN 14
DSD NO
LL1
0.00%
INA 22
HL1 100.00%
...............................................................................................................................................................................
FB12
ESN 15
Q1R 4 (%)
SA1 100.0%
Q2R 4 (%)
SA2 0.0%
Q3R 4 (%)
SA3 100.0%
Q4R 4 (%)
SA4 0.0%
A1T HI
DA1 0.5%
A2T LO
DA2 0.5%
A3T DEV
DA3 0.5%
A4T NONE
DA4 0.5%
INA 01
EA1 EN
INB 01
EA2 EN
INC 05
EA3 EN
IND 01
EA4 DIS
A1I 0.0 SEC
A2I 0.0 SEC
A3I 0.0 SEC
A4I 0.0 SEC
A1O 0.0 SEC
A2O 0.0 SEC
A3O 0.0 SEC
A4O 0.0 SEC
A1R NO
A2R NO
A3R NO
A4R NO
..............................................................................................................................................................................
FB13
ESN 30
C1T PID
A1 REV
MRT NO
PG1 1.00
INP 01
TI1 100 M/R
INS 05
TD1 0.00 MIN
INF 17
DG1 10.00
INA 00
MR1 0.0%
INC 18
HL1 100.00%
LL1 0.0%
...............................................................................................................................................................................
October 1998
9-33
FACTORY CONFIGURED OPTIONS
UM348-1
H
S
C
AO NO
PUM 0.0%
PU LP
PUL NO
INA 14
INT 00
INE 00
INS 00
INL 00
...............................................................................................................................................................................
FB15
ESN 40
INP 01
DP1 0.00
INS 05
PL1 0.00
INV 17
PH1 100.00
INX 00
DP2 0.00
INY 00
PL2 0.00
INA 00
PH2 100.00
INL 00
DPX 0.00
PDR L
XL 0.00
SDR L
XH 100.00
HS1 VALVE
DPY 0.00
HS2 VALVE
YL 0.00
HD1 YES
YH 100.00
HD2 YES
TST 10 SEC
SCF YES
TSI TN1
IN1 00
IN2 00
U1S U1
U2S U2
TN1 TAG NAME 1
TN2 TAG NAME 2
EU1 PRCT
EU2 PRCT
EUX PRCT
EUY PRCT
FL1 A1
FL2 A2
FL3 A3
FL4 NONE
FL5 NONE
...............................................................................................................................................................................
FB17
ESN 10
INT 01
INC 18
INL 00
...............................................................................................................................................................................
FB14
9-34
T
ESN 35
October 1998
UM348-1
FACTORY CONFIGURED OPTIONS
H
S
C
EO NO
PU LP
S1A SUS
DSD NO
INE 00
INI 00
INA 00
...............................................................................................................................................................................
FB98
ESN 90
H1P 01
H1S 05
H1V 17
H2P 00
H2S 00
H2V 00
POL 0
P1F CL
P2F USER
IND 00
INE 00
INF 00
ING 00
HTN HART TAG
DES HART DESCRIPTOR
MSG HART MESSAGE
DAT 01/01/93
DSN 0
VC1 3
VC2 4
VC3 5
VC4 0
RP 5
..............................................................................................................................................................................
FB23
October 1998
T
ESN 86
9-35
FACTORY CONFIGURED OPTIONS
UM348-1
9.9 FCO 12 SINGLE-LOOP PID CONTROLLER (NTSP)- C/L OPERATION
With:
Hi/Lo Process Alarms
Deviation Alarm
Non-Tracking Setpoint
Setpoint Limits
4-20 mA Input/Output
PROCESS
AI1+ (F7)
AI1C (F8)
FB01
INPUT
01
A/B/D FB12
ALARM
C
INP
INS
P
F FB13 S
PID C
05 FB09 A
FB17
LIMIT
22 SET
14
A
FB14
A/M
17
A
AO1+ (E11)
AO1C (E12)
18
INV
C
64
FB98
HART
FB23
PBT#1
L
63
CONSOLE
LOCAL
FB03
OUT
VALVE
CONNECTION TO FB15 OPERATOR DISPLAY BLOCK
9-36
October 1998
UM348-1
FACTORY CONFIGURED OPTIONS
CONFIGURATION PARAMETERS
T
H
S
C
FB01
ESN 05
SRE NO
DV1 0 SEC
...............................................................................................................................................................................
FB03
ESN 45
INA 17
INB 00
...............................................................................................................................................................................
FB09
ESN 14
DSD NO
LL1
0.00%
INA 22
HL1 100.00%
...............................................................................................................................................................................
FB12
ESN 15
Q1R 4 (%)
SA1 100.0%
Q2R 4 (%)
SA2 0.0%
Q3R 4 (%)
SA3 100.0%
Q4R 4 (%)
SA4 0.0%
A1T HI
DA1 0.5%
A2T LO
DA2 0.5%
A3T DEV
DA3 0.5%
A4T NONE
DA4 0.5%
INA 01
EA1 EN
INB 01
EA2 EN
INC 05
EA3 EN
IND 01
EA4 DIS
A1I 0.0 SEC
A2I 0.0 SEC
A3I 0.0 SEC
A4I 0.0 SEC
A1O 0.0 SEC
A2O 0.0 SEC
A3O 0.0 SEC
A4O 0.0 SEC
A1R NO
A2R NO
A3R NO
A4R NO
...............................................................................................................................................................................
FB13
ESN 30
C1T PID
A1 REV
MRT NO
PG1 1.00
INP 01
TI1 100 M/R
INS 05
TD1 0.00 MIN
INF 17
DG1 10.00
INA 00
MR1 0.0%
INC 18
HL1 100.00%
LL1 0.0%
...............................................................................................................................................................................
October 1998
9-37
FACTORY CONFIGURED OPTIONS
UM348-1
H
S
C
AO NO
PUM 0.0%
PU LP
PUL NO
INA 14
INT 00
INE 00
INS 00
INL 00
...............................................................................................................................................................................
FB15
ESN 40
INP 01
DP1 0.00
INS 05
PL1 0.00
INV 17
PH1 100.00
INX 00
DP2 0.00
INY 00
PL2 0.00
INA 00
PH2 100.00
INL 00
DPX 0.00
PDR L
XL 0.00
SDR L
XH 100.00
HS1 VALVE
DPY 0.00
HS2 VALVE
YL 0.00
HD1 YES
YH 100.00
HD2 YES
TST 10 SEC
SCF YES
TSI TN1
IN1 00
IN2 00
U1S U1
U2S U2
TN1 TAG NAME 1
TN2 TAG NAME 2
EU1 PRCT
EU2 PRCT
EUX PRCT
EUY PRCT
FL1 A1
FL2 A2
FL3 A3
FL4 NONE
FL5 NONE
...............................................................................................................................................................................
FB17
ESN 10
INT 00
INC 00
INL 00
...............................................................................................................................................................................
FB14
9-38
T
ESN 35
October 1998
UM348-1
FACTORY CONFIGURED OPTIONS
H
S
C
EO NO
PU LP
S1A SUS
DSD NO
INE 00
INI 00
INA 00
...............................................................................................................................................................................
FB98
ESN 90
H1P 01
H1S 05
H1V 17
H2P 00
H2S 00
H2V 00
POL 0
P1F CL
P2F USER
IND 00
INE 00
INF 00
ING 00
HTN HART TAG
DES HART DESCRIPTOR
MSG HART MESSAGE
DAT 01/01/93
DSN 0
VC1 3
VC2 4
VC3 5
VC4 0
RP 5
..............................................................................................................................................................................
FB23
October 1998
T
ESN 86
9-39
FACTORY CONFIGURED OPTIONS
UM348-1
9.10 FCO 13 EXTERNAL-SET PID CONTROLLER (TSP) - C/L OPERATION
With:
Hi/Lo Process Alarms
Deviation Alarm
Tracking Setpoint
Setpoint Limits
4-20 mA Inputs/Output
PROCESS
AI1+ (F7)
AI1C (F8)
FB01
INPUT
01
INP
EXTERNAL SETPOINT
A/B/D
02
FB12
ALARM
INX
C
INS
P
F FB13
PID
S
E
05
C
FB09
LIMIT
14
FB14
A/M
17
A
FB03
OUT
A
T
FB17
SET
A
AO1+ (E11)
AO1C (E12)
FB02
INPUT
AI2+ (F10)
AI2C (F11)
A
18
INV
FB21
OR
21
09 FB11
E/I
25
I
22
C
B
C
64
FB98
HART
FB23
PBT#1
L
63
CONSOLE
LOCAL
VALVE
CONNECTION TO FB15 OPERATOR DISPLAY BLOCK
9-40
October 1998
UM348-1
FACTORY CONFIGURED OPTIONS
CONFIGURATION PARAMETERS
T
H
S
C
FB01
ESN 05
SRE NO
DV1 0 SEC
...............................................................................................................................................................................
FB02
ESN 07
SRE NO
DV2 0 SEC
...............................................................................................................................................................................
FB03
ESN 45
INA 17
INB 00
...............................................................................................................................................................................
FB09
ESN 14
DSD NO
LL1
0.00%
INA 09
HL1 100.00%
...............................................................................................................................................................................
FB11
ESN 13
EO NO
PU LP
S1A SUS
DSD NO
INE 02
INI 22
INA 00
...............................................................................................................................................................................
FB12
ESN 15
Q1R 4 (%)
SA1 100.0%
Q2R 4 (%)
SA2 0.0%
Q3R 4 (%)
SA3 100.0%
Q4R 4 (%)
SA4 0.0%
A1T HI
DA1 0.5%
A2T LO
DA2 0.5%
A3T DEV
DA3 0.5%
A4T NONE
DA4 0.5%
INA 01
EA1 EN
INB 01
EA2 EN
INC 05
EA3 EN
IND 01
EA4 DIS
A1I 0.0 SEC
A2I 0.0 SEC
A3I 0.0 SEC
A4I 0.0 SEC
A1O 0.0 SEC
A2O 0.0 SEC
A3O 0.0 SEC
A4O 0.0 SEC
A1R NO
A2R NO
A3R NO
A4R NO
...............................................................................................................................................................................
October 1998
9-41
FACTORY CONFIGURED OPTIONS
S
C
A1 REV
PG1 1.00
TI1 100 M/R
TD1 0.00 MIN
DG1 10.00
MR1 0.0%
HL1 100.00%
LL1 0.0%
...............................................................................................................................................................................
FB14
ESN 35
AO NO
PUM 0.0%
PU LP
PUL NO
INA 14
INT 00
INE 00
INS 00
INL 00
...............................................................................................................................................................................
FB15
ESN 40
INP 01
DP1 0.00
INS 05
PL1 0.00
INV 17
PH1 100.00
INX 02
DP2 0.00
INY 00
PL2 0.00
INA 00
PH2 100.00
INL 00
DPX 0.00
PDR L
XL 0.00
SDR L
XH 100.00
HS1 VALVE
DPY 0.00
HS2 VALVE
YL 0.00
HD1 YES
YH 100.00
HD2 YES
TST 10 SEC
SCF YES
TSI TN1
IN1 00
IN2 00
U1S U1
U2S U2
TN1 TAG NAME 1
TN2 TAG NAME 2
EU1 PRCT
EU2 PRCT
EUX PRCT
EUY PRCT
FL1 A1
FB13
T
ESN 30
UM348-1
H
C1T PID
MRT NO
INP 01
INS 05
INF 17
INA 00
INC 18
(continued on next page)
9-42
October 1998
UM348-1
FACTORY CONFIGURED OPTIONS
H
S
C
FL2 A2
FL3 A3
FL4 NONE
FL5 NONE
...............................................................................................................................................................................
FB17
ESN 10
INT 01
INC 21
INL 00
.......................................................................................................…....................................................................
FB21
ESN 38
LT2 OR
INA 18
INB 25
...............................................................................................................................................................................
FB23
ESN 86
EO NO
PU LP
S1A SUS
DSD NO
INE 00
INI 00
INA 00
...............................................................................................................................................................................
FB98
ESN 90
H1P 01
H1S 05
H1V 17
H2P 00
H2S 00
H2V 00
POL 0
P1F CL
P2F L1EI
IND 00
INE 00
INF 00
ING 00
HTN HART TAG
DES HART DESCRIPTOR
MSG HART MESSAGE
DAT 01/01/93
DSN 0
VC1 3
VC2 4
VC3 5
VC4 0
RP 5
...............................................................................................................................................................................
FB15
October 1998
T
ESN 40
9-43
FACTORY CONFIGURED OPTIONS
UM348-1
9.11 FCO 14 EXTERNAL SET PID CONTROLLER (NTSP) - C/L OPERATION
With:
Hi/Lo Process Alarms
Deviation Alarm
Non-Tracking Setpoint
Setpoint Limits
4-20 mA Inputs/Output
EXTERNAL SETPOINT
PROCESS
AI1+ (F7)
AI1C (F8)
FB01
INPUT
01
A/B/D
P
S
02
FB12
ALARM
C
INP
F FB13
PID
INX
INS
05 FB09
LIMIT
C
E
A
09 FB11
E/I
14
22
A
FB14
A/M
17
A
AO1+ (E11)
AO1C (E12)
FB03
OUT
FB02
INPUT
AI2+ (F10)
AI2C (F11)
I
FB17
SET
18
INV
C
64
FB98
HART
FB23
PBT#1
L
63
CONSOLE
LOCAL
VALVE
CONNECTION TO FB15 OPERATOR DISPLAY BLOCK
9-44
October 1998
UM348-1
FACTORY CONFIGURED OPTIONS
CONFIGURATION PARAMETERS
T
H
S
C
FB01
ESN 05
SRE NO
DV1 0 SEC
...............................................................................................................................................................................
FB02
ESN 07
SRE NO
DV2 0 SEC
...............................................................................................................................................................................
FB03
ESN 45
INA 17
INB 00
...............................................................................................................................................................................
FB09
ESN 14
DSD NO
LL1
0.00%
INA 09
HL1 100.00%
...............................................................................................................................................................................
FB11
ESN 13
EO NO
PU LP
S1A SUS
DSD NO
INE 02
INI 22
INA 00
...............................................................................................................................................................................
FB12
ESN 15
Q1R 4 (%)
SA1 100.0%
Q2R 4 (%)
SA2 0.0%
Q3R 4 (%)
SA3 100.0%
Q4R 4 (%)
SA4 0.0%
A1T HI
DA1 0.5%
A2T LO
DA2 0.5%
A3T DEV
DA3 0.5%
A4T NONE
DA4 0.5%
INA 01
EA1 EN
INB 01
EA2 EN
INC 05
EA3 EN
IND 01
EA4 DIS
A1I 0.0 SEC
A2I 0.0 SEC
A3I 0.0 SEC
A4I 0.0 SEC
A1O 0.0 SEC
A2O 0.0 SEC
A3O 0.0 SEC
A4O 0.0 SEC
A1R NO
A2R NO
A3R NO
A4R NO
...............................................................................................................................................................................
October 1998
9-45
FACTORY CONFIGURED OPTIONS
S
C
A1 REV
PG1 1.00
TI1 100 M/R
TD1 0.00 MIN
DG1 10.00
MR1 0.0%
HL1 100.00%
LL1 0.00%
...............................................................................................................................................................................
FB14
ESN 35
AO NO
PUM 0.0%
PU LP
PUL NO
INA 14
INT 00
INE 00
INS 00
INL 00
..............................................................................................................................................................................
FB15
ESN 40
INP 01
DP1 0.00
INS 05
PL1 0.00
INV 17
PH1 100.00
INX 02
DP2 0.00
INY 00
PL2 0.00
INA 00
PH2 100.00
INL 00
DPX 0.00
PDR L
XL 0.00
SDR L
XH 100.00
HS1 V
DPY 0.00
HS2 V
YL 0.00
HD1 YES
YH 100.00
HD2 YES
TST 10 SEC
SCF YES
TSI TN1
IN1 00
IN2 00
U1S U1
U2S U2
TN1 TAG NAME 1
TN2 TAG NAME 2
EU1 PRCT
EU2 PRCT
EUX PRCT
EUY PRCT
FL1 A1
FB13
T
ESN 30
UM348-1
H
C1T PID
MRT NO
INP 01
INS 05
INF 17
INA 00
INC 18
(continued on next page)
9-46
October 1998
UM348-1
FACTORY CONFIGURED OPTIONS
H
S
C
FL2 A2
FL3 A3
FL4 NONE
FL5 NONE
..............................................................................................................................................................................
FB17
ESN 10
INT 00
INC 00
INL 00
...............................................................................................................................................................................
FB23
ESN 86
EO NO
PU LP
S1A SUS
DSD NO
INE 00
INI 00
INA 00
...............................................................................................................................................................................
FB98
ESN 90
H1P 01
H1S 05
H1V 17
H2P 00
H2S 00
H2V 00
POL 0
P1F CL
P2F L1EI
IND 00
INE 00
INF 00
ING 00
HTN HART TAG
DES HART DESCRIPTOR
MSG HART MESSAGE
DAT 01/01/93
DSN 0
VC1 3
VC2 4
VC3 5
VC4 0
RP 5
...............................................................................................................................................................................
FB15
October 1998
T
ESN 40
9-47
FACTORY CONFIGURED OPTIONS
UM348-1
9.12 FCO 15 RATIO SET PID CONTROLLER - C/L OPERATION
With:
Hi/Lo Process Alarms
Deviation Alarm
Tracking Setpoint
Setpoint Limits
4-20 mA Inputs/Output
PROCESS
AI1+ (F7)
AI1C (F8)
AI2+ (F10)
AI2C (F11)
FB01
INPUT
01
INP
EXTERNAL INPUT
A/B/D
FB07
RATIO
03
INS
P
05
S
FB09
LIMIT
C
14
17
A
FB03
OUT
VALVE
A
09
T
FB17
SET
A
FB14
A/M
A
18
INV
02
A
INX
FB12
ALARM
C
F FB13
PID
AO1+ (E11)
AO1C (E12)
FB02
INPUT
21
FB21
OR
E
FB11
E/I
25
I
22
C
B
C
64
FB98
HART
FB23
PBT#1
L
63
CONSOLE
LOCAL
CONNECTION TO FB15 OPERATOR DISPLAY BLOCK
9-48
October 1998
UM348-1
FACTORY CONFIGURED OPTIONS
CONFIGURATION PARAMETERS
T
H
S
C
FB01
ESN 05
SRE NO
DV1 0 SEC
...............................................................................................................................................................................
FB02
ESN 07
SRE NO
DV2 0 SEC
...............................................................................................................................................................................
FB03
ESN 45
INA 17
INB 00
...............................................................................................................................................................................
FB07
ESN 08
INA 02
R 1.00
INB 00
RRL 0.50
INC 00
RRH 1.50
IND 00
RCD NO
...............................................................................................................................................................................
FB09
ESN 14
DSD NO
LL1
0.00%
INA 09
HL1 100.00%
...............................................................................................................................................................................
FB11
ESN 13
EO NO
PU LP
S1A SUS
DSD NO
INE 03
INI 22
INA 00
...............................................................................................................................................................................
FB12
ESN 15
Q1R 4 (%)
SA1 100.0%
Q2R 4 (%)
SA2 0.0%
Q2R 4 (%)
SA3 100.0%
Q4R 4 (%)
SA4 0.0%
A1T HI
DA1 0.5%
A2T LO
DA2 0.5%
A3T DEV
DA3 0.5%
A4T NONE
DA4 0.5%
INA 01
EA1 EN
INB 01
EA2 EN
INC 05
EA3 EN
IND 01
EA4 DIS
A1I 0.0 SEC
A2I 0.0 SEC
A3I 0.0 SEC
A4I 0.0 SEC
A1O 0.0 SEC
A2O 0.0 SEC
(continued on next page)
October 1998
9-49
FACTORY CONFIGURED OPTIONS
UM348-1
H
S
C
A3O 0.0 SEC
A4O 0.0 SEC
A1R NO
A2R NO
A3R NO
A4R NO
...............................................................................................................................................................................
FB13
ESN 30
C1T PID
A1 REV
MRT NO
PG1 1.00
INP 01
TI1 100 M/R
INS 05
TD1 0.00 MIN
INF 17
DG1 10.00
INA 00
MR1 0.0%
INC 18
HL1 100.00%
LL1 0.0%
...............................................................................................................................................................................
FB14
ESN 35
AO NO
PUM 0.0%
PU LP
PUL NO
INA 14
INT 00
INE 00
INS 00
INL 00
...............................................................................................................................................................................
FB15
ESN 40
INP 01
DP1 0.00
INS 05
PL1 0.00
INV 17
PH1 100.00
INX 02
DP2 0.00
INY 00
PL2 0.00
INA 00
PH2 100.00
INL 00
DPX 0.00
PDR L
XL 0.00
SDR L
XH 100.00
HS1 VALVE
DPY 0.00
HS2 VALVE
YL 0.00
HD1 YES
YH 100.00
HD2 YES
TST 10 SEC
SCF YES
TSI TN1
IN1 00
IN2 00
U1S U1
U2S U2
FB12
(cont’d)
T
ESN 15
(continued on next page)
9-50
October 1998
UM348-1
FACTORY CONFIGURED OPTIONS
H
S
C
TN1 TAG NAME 1
TN2 TAG NAME 2
EU1 PRCT
EU2 PRCT
EUX PRCT
EUY PRCT
FL1 A1
FL2 A2
FL3 A3
FL4 NONE
FL5 NONE
...............................................................................................................................................................................
FB17
ESN 10
INT 01
INC 21
INL 00
...............................................................................................................................................................................
FB21
ESN 38
LT2 OR
INA 18
INB 25
...............................................................................................................................................................................
FB23
ESN 86
EO NO
PU LP
S1A SUS
DSD NO
INE 00
INI 00
INA 00
...............................................................................................................................................................................
FB98
ESN 90
H1P 01
H1S 05
H1V 17
H2P 00
H2S 00
H2V 00
POL 0
P1F CL
P2F L1EI
IND 00
INE 00
INF 00
ING 00
HTN HART TAG
DES HART DESCRIPTOR
FB15
T
ESN 40
(continued on next page)
October 1998
9-51
FACTORY CONFIGURED OPTIONS
UM348-1
H
S
C
MSG HART MESSAGE
DAT 01/01/93
DSN 0
VC1 3
VC2 4
VC3 5
VC4 0
RP 5
..............................................................................................................................................................................
FB98
9-52
T
ESN 90
October 1998
UM348-1
FACTORY CONFIGURED OPTIONS
9.13 FCO 20 SINGLE STATION CASCADE PID CONTROLLER (TSP)
With:
Hi/Lo Process Alarms (Both Loops)
Deviation Alarm (Both Loops)
Tracking Setpoints (Both Loops)
Setpoint Limits (Both Loops)
4-20 mA Inputs/Output
LOOP 1
PRIMARY PROCESS
AI1+ (F7)
AI1C (F8)
LOOP 2
SECONDARY PROCESS
AI2+ (F10)
AI2C (F11)
FB01
INPUT
01
C FB71 E
X'FER
INP
F FB13 S
PID C
14
CAS.
SEC.
INS
E
B
FB50 53
OR
A
INY
C
P
32
02
A/B/D FB12
ALARM
INX
D
10 FB11 I
E/I
25
09
31
FB02
INPUT
T
L
05 FB09 A FB17
LIMIT 22 SET
A
FB71
X'FER
B
C
FB51
LIMIT
C
48
FB46 T
SET
FB73
ALARM
C
A/B/D
54
S
F FB45 P
PID
C
46
B
A
FB55
A/M
60
A
AO1+ (E11)
AO1C (E12)
A FB21 21
OR
68
INV
FB03
OUT
VALVE
CONNECTION TO FB15 OPERATOR DISPLAY BLOCK
October 1998
9-53
FACTORY CONFIGURED OPTIONS
UM348-1
CONFIGURATION PARAMETERS
T
H
S
C
FB01
ESN 05
SRE NO
DV1 0 SEC
...............................................................................................................................................................................
FB02
ESN 07
SRE NO
DV2 0 SEC
...............................................................................................................................................................................
FB03
ESN 70
INA 60
INB 00
...............................................................................................................................................................................
FB09
ESN 44
DSD NO
LL1
0.00%
INA 22
HL1 100.00%
...............................................................................................................................................................................
FB11
ESN 55
EO NO
PU LP
S1A SUS
DSD NO
INE 14
INI 48
INA 00
...............................................................................................................................................................................
FB12
ESN 77
Q1R 4 (%)
SA1 100.0%
Q2R 4 (%)
SA2 0.0%
Q3R 4 (%)
SA3 100.0%
Q4R 4 (%)
SA4 0.0%
A1T HI
DA1 0.5%
A2T LO
DA2 0.5%
A3T DEV
DA3 0.5%
A4T NONE
DA4 0.5%
INA 01
EA1 EN
INB 01
EA2 EN
INC 05
EA3 EN
IND 01
EA4 DIS
A1I 0.0 SEC
A2I 0.0 SEC
A3I 0.0 SEC
A4I 0.0 SEC
A1O 0.0 SEC
A2O 0.0 SEC
A3O 0.0 SEC
A4O 0.0 SEC
A1R NO
A2R NO
A3R NO
A4R NO
...............................................................................................................................................................................
9-54
October 1998
UM348-1
FACTORY CONFIGURED OPTIONS
S
C
A1 REV
PG1 1.00
TI1 100 M/R
TD1 0.00 MIN
DG1 10.00
MR1 0.0%
HL1 100.00%
LL1 0.00%
...............................................................................................................................................................................
FB15
ESN 40
INP 32
DP1 0.00
INS 31
PL1 0.00
INV 60
PH1 100.00
INX 01
DP2 0.00
INY 02
PL2 0.00
INA 00
PH2 100.00
INL 10
DPX 0.00
PDR L
XL 0.00
SDR L
XH 100.00
HS1 VALVE
DPY 0.00
HS2 VALVE
YL 0.00
HD1 YES
YH 100.00
HD2 YES
TST 10 SEC
SCF YES
TSI BOTH
IN1 00
IN2 00
U1S U1
U2S U2
TN1 PRIMARY
TN2 SECONDARY
EU1 PRCT
EU2 PRCT
EUX PRCT
EUY PRCT
FL1 A1
FL2 A2
FL3 A5
FL4 A6
FL5 NONE
...............................................................................................................................................................................
FB17
ESN 43
INT 01
INC 53
INL 10
...............................................................................................................................................................................
FB13
October 1998
T
ESN 45
H
C1T PID
MRT NO
INP 01
INS 05
INF 02
INA 00
INC 53
9-55
FACTORY CONFIGURED OPTIONS
UM348-1
H
S
C
LT2 OR
INA 68
INB 25
...............................................................................................................................................................................
FB45
ESN 60
C2T PID
A2 REV
MRT NO
PG2 1.00
INP 02
TI2 100 M/R
INS 54
TD2 0.00 MIN
INF 60
DG2 10.00
INA 00
MR2 0.0%
INC 68
HL2 100.00%
LL2 0.00%
...............................................................................................................................................................................
FB46
ESN 53
INT 02
INC 21
...............................................................................................................................................................................
FB50
ESN 15
LT4 OR
INA 68
INB 10
...............................................................................................................................................................................
FB51
ESN 56
DSD NO
LL2
0.00%
INA 09
HL2 100.00%
...............................................................................................................................................................................
FB55
ESN 65
AO NO
PUM 0.0%
PU LP
PUL NO
INA 46
INT 00
INE 00
INS 00
...............................................................................................................................................................................
FB71
ESN 36
INA 05
INB 54
IND 01
INE 02
INF 00
ING 00
INC 10
...............................................................................................................................................................................
FB73
ESN 78
Q5R 4 (%)
SA5 100.0%
Q6R 4 (%)
SA6 0.0%
Q7R 4 (%)
SA7 100.0%
Q8R 4 (%)
SA8 0.0%
FB21
T
ESN 20
(continued on next page)
9-56
October 1998
UM348-1
FACTORY CONFIGURED OPTIONS
H
S
C
A5T HI
DA5 0.5%
A6T LO
DA6 0.5%
A7T DEV
DA7 0.5%
A8T NONE
DA8 0.5%
INA 02
EA5 EN
INB 02
EA6 EN
INC 54
EA7 EN
IND 02
EA8 DIS
A5I 0.0 SEC
A6I 0.0 SEC
A7I 0.0 SEC
A8I 0.0 SEC
A5O 0.0 SEC
A6O O.O SEC
A7O 0.0 SEC
A8O 0.0 SEC
A5R NO
A6R NO
A7R NO
A8R NO
...............................................................................................................................................................................
FB98
ESN 90
H1P 01
H1S 05
H1V 14
H2P 02
H2S 54
H2V 60
POL 0
P1F USER
P2F L1EI
IND 00
INE 00
INF 00
ING 00
HTN HART TAG
DES HART DESCRIPTOR
MSG HART MESSAGE
DAT 01/01/93
DSN 0
VC1 3
VC2 4
VC3 5
VC4 0
RP 5
...............................................................................................................................................................................
FB73
October 1998
T
ESN 78
9-57
FACTORY CONFIGURED OPTIONS
UM348-1
9.14 FCO 25 2-LOOP PID CONTROLLER (TSP)
With:
Hi/Lo Process Alarms (Both Loops)
Deviation Alarm (Both Loops)
Tracking Setpoints (Both Loops)
Setpoint Limits (Both Loops)
4-20 mA Inputs/Output
Model 348E Required for FCO25
LOOP 1
PROCESS 1
AI1+ (F7)
AI1C (F8)
LOOP 2
PROCESS 2
FB01
INPUT
LOOP 1
01
LOOP 2
AI2+ (F10)
AI2C (F11)
FB11
PBT#2
FB02
INPUT
02
10
INP
A/B/D
D FB71 E
X'FER
FB12
ALARM
INX
C
C
FB13 S
PID
C
14
A/B/D
A
FB09
5 LIMIT 22
FB17 L
SET
INS
C
FB73
ALARM
INY
T
P
F
32
C
P
F FB45 S
PID
C
46
T
54
FB46
FB51 A
LIMIT
48 SET
C
31
A
A
L
FB14 18
A/M
17
INV
F
FB71 B
X'FER
33
FB71 G
X'FER
FB03
OUT
VALVE 1
FB55 68
A/M
60
A
A
AO1+ (E11)
AO1C (E12)
A
AO2+ (E13)
AO2C (E14)
FB29
OUT
VALVE 2
CONNECTION TO FB15 OPERATOR DISPLAY BLOCK
9-58
October 1998
UM348-1
FACTORY CONFIGURED OPTIONS
CONFIGURATION PARAMETERS
T
H
S
C
FB01
ESN 05
SRE NO
DV1 0 SEC
...............................................................................................................................................................................
FB02
ESN 07
SRE NO
DV2 0 SEC
...............................................................................................................................................................................
FB03
ESN 70
INA 17
INB 00
...............................................................................................................................................................................
FB09
ESN 34
DSD NO
LL1
0.00%
INA 22
HL1 100.00%
..............................................................................................................................................................................
FB11
ESN 55
EO NO
PU LP
S1A SUS
DSD NO
INE 00
INI 00
INA 00
...............................................................................................................................................................................
FB12
ESN 75
Q1R 4 (%)
SA1 100.0%
Q2R 4 (%)
SA2 0.0%
Q3R 4 (%)
SA3 100.0%
Q4R 4 (%)
SA4 0.0%
A1T HI
DA1 0.5%
A2T LO
DA2 0.5%
A3T DEV
DA3 0.5%
A4T NONE
DA4 0.5%
INA 01
EA1 EN
INB 01
EA2 EN
INC 05
EA3 EN
IND 01
EA4 DIS
A1I 0.0 SEC
A2I 0.0 SEC
A3I 0.0 SEC
A4I 0.0 SEC
A1O 0.0 SEC
A2O 0.0 SEC
A3O 0.0 SEC
A4O 0.0 SEC
A1R NO
A2R NO
A3R NO
A4R NO
...............................................................................................................................................................................
October 1998
9-59
FACTORY CONFIGURED OPTIONS
S
C
A1 REV
PG1 1.00
TI1 100 M/R
TD1 0.00 MIN
DG1 10.00
MR1 0.0%
HL1 100.00%
LL1 0.0%
...............................................................................................................................................................................
FB14
ESN 65
AO NO
PUM 0.0%
PU LP
PUL NO
INA 14
INT 00
INE 00
INS 00
INL 10
...............................................................................................................................................................................
FB15
ESN 40
INP 32
DP1 0.00
INS 31
PL1 0.00
INV 33
PH1 100.00
INX 01
DP2 0.00
INY 02
PL2 0.00
INA 00
PH2 100.00
INL 10
DPX 0.00
PDR L
XL 0.00
SDR L
XH 100.00
HS1 VALVE
DPY 0.00
HS2 VALVE
YL 0.00
HD1 YES
YH 100.00
HD2 YES
TST 10 SEC
SCF YES
TSI BOTH
IN1 00
IN2 00
U1S U1
U2S U2
TN1 LOOP 1
TN2 LOOP 2
EU1 PRCT
EU2 PRCT
EUX PRCT
EUY PRCT
FL1 A1
FB13
T
ESN 60
UM348-1
H
C1T PID
MRT NO
INP 01
INS 05
INF 17
INA 00
INC 18
(continued on next page)
9-60
October 1998
UM348-1
FACTORY CONFIGURED OPTIONS
H
S
C
FL2 A2
FL3 A5
FL4 A6
FL5 NONE
...............................................................................................................................................................................
FB17
ESN 30
INT 01
INC 18
INL 10
...............................................................................................................................................................................
FB29
ESN 71
INA 60
INB 00
...............................................................................................................................................................................
FB45
ESN 45
C2T PID
A2 REV
MRT NO
PG2 1.00
INP 02
TI2 100 M/R
INS 54
TD2 0.00 MIN
INF 60
DG2 10.00
INA 00
MR2 0.0%
INC 68
HL2 100.00%
LL2 0.0%
...............................................................................................................................................................................
FB46
ESN 25
INT 02
INC 68
...............................................................................................................................................................................
FB51
ESN 26
DSD NO
LL2
0.00%
INA 48
HL2 100.00%
...............................................................................................................................................................................
FB55
ESN 66
AO NO
PUM 0.0%
PU LP
PUL NO
INA 46
INT 00
INE 00
INS 00
...............................................................................................................................................................................
FB71
ESN 36
INA 05
INB 54
IND 01
INE 02
INF 17
ING 60
INC 10
...............................................................................................................................................................................
FB15
(cont’d)
T
ESN 40
(continued on next page)
October 1998
9-61
FACTORY CONFIGURED OPTIONS
UM348-1
H
S
C
Q5R 4 (%)
SA5 100.0%
Q6R 4 (%)
SA6 0.0%
Q7R 4 (%)
SA7 100.0%
Q8R 4 (%)
SA8 0.0%
A5T HI
DA5 0.5%
A6T LO
DA6 0.5%
A7T DEV
DA7 0.5%
A8T NONE
DA8 0.5%
INA 02
EA5 EN
INB 02
EA6 EN
INC 54
EA7 EN
IND 02
EA8 DIS
A5I 0.0 SEC
A6I 0.0 SEC
A7I 0.0 SEC
A8I 0.0 SEC
A5O 0.0 SEC
A6O O.O SEC
A7O 0.0 SEC
A8O 0.0 SEC
A5R NO
A6R NO
A7R NO
A8R NO
...............................................................................................................................................................................
FB98
ESN 90
H1P 01
H1S 05
H1V 17
H2P 02
H2S 54
H2V 60
POL 0
P1F USER
P2F USER
IND 00
INE 00
INF 00
ING 00
HTN HART TAG
DES HART DESCRIPTOR
MSG HART MESSAGE
DAT 01/01/93
DSN 0
FB73
T
ESN 76
(continued on next page)
9-62
October 1998
UM348-1
FACTORY CONFIGURED OPTIONS
H
S
C
VC1 3
VC2 4
VC3 5
VC4 0
RP 5
..............................................................................................................................................................................
FB98
October 1998
T
ESN 90
9-63
FACTORY CONFIGURED OPTIONS
UM348-1
9.15 FCO 26 2-LOOP PID CONTROLLER
With:
Hi/Lo Process Alarms (Both Loops)
Deviation Alarm (Both Loops)
Non-Tracking Setpoints (Both Loops)
Setpoint Limits (Both Loops)
4-20 mA Inputs/Output
Model 348E Required for FCO26
LOOP 1
PROCESS 1
AI1+ (F7)
AI1C (F8)
LOOP 2
PROCESS 2
FB01
INPUT
LOOP 1
01
LOOP 2
AI2+ (F10)
AI2C (F11)
FB11
PBT#2
FB02
INPUT
02
10
INP
A/B/D
D FB71 E
X'FER
FB12
ALARM
INX
32
C
C
A/B/D
INY
P
F
FB13 S
PID
C
14
FB73
ALARM
C
P
A
FB09
5 LIMIT 22
FB17 L
SET
INS
F FB45 S
PID
C
46
FB46
FB51 A
LIMIT
48 SET
54
31
A
A
L
FB14 18
A/M
17
INV
FB71 B
X'FER
33
F FB71 G
X'FER
FB03
OUT
VALVE 1
FB55 68
A/M
60
A
A
AO1+ (E11)
AO1C (E12)
A
AO2+ (E13)
AO2C (E14)
FB29
OUT
VALVE 2
CONNECTION TO FB15 OPERATOR DISPLAY BLOCK
9-64
October 1998
UM348-1
FACTORY CONFIGURED OPTIONS
CONFIGURATION PARAMETERS
T
H
S
C
FB01
ESN 05
SRE NO
DV1 0 SEC
...............................................................................................................................................................................
FB02
ESN 07
SRE NO
DV2 0 SEC
.............................................................................................................................................................…..............
FB03
ESN 70
INA 17
INB 00
..............................................................................................................................................................….............
FB09
ESN 34
DSD NO
LL1
0.00%
INA 22
HL1 100.00%
...............................................................................................................................................................................
FB11
ESN 55
EO NO
PU LP
S1A SUS
DSD NO
INE 00
INI 00
INA 00
...............................................................................................................................................................................
FB12
ESN 75
Q1R 4 (%)
SA1 100.0%
Q2R 4 (%)
SA2 0.0%
Q3R 4 (%)
SA3 100.0%
Q4R 4 (%)
SA4 0.0%
A1T HI
DA1 0.5%
A2T LO
DA2 0.5%
A3T DEV
DA3 0.5%
A4T NONE
DA4 0.5%
INA 01
EA1 EN
INB 01
EA2 EN
INC 05
EA3 EN
IND 01
EA4 DIS
A1I 0.0 SEC
A2I 0.0 SEC
A3I 0.0 SEC
A4I 0.0 SEC
A1O 0.0 SEC
A2O 0.0 SEC
A3O 0.0 SEC
A4O 0.0 SEC
A1R NO
A2R NO
A3R NO
A4R NO
..............................................................................................................................................................................
October 1998
9-65
FACTORY CONFIGURED OPTIONS
S
C
A1 REV
PG1 1.00
TI1 100 M/R
TD1 0.00 MIN
DG1 10.00
MR1 0.0%
HL1 100.00%
LL1 0.0%
.............................................................................................................................................................................
FB14
ESN 65
AO NO
PUM 0.0%
PU LP
PUL NO
INA 14
INT 00
INE 00
INS 00
INL 10
...............................................................................................................................................................................
FB15
ESN 40
INP 32
DP1 0.00
INS 31
PL1 0.00
INV 33
PH1 100.00
INX 01
DP2 0.00
INY 02
PL2 0.00
INA 00
PH2 100.00
INL 10
DPX 0.00
PDR L
XL 0.00
SDR L
XH 100.00
HS1 VALVE
DPY 0.00
HS2 VALVE
YL 0.00
HD1 YES
YH 100.00
HD2 YES
TST 10 SEC
SCF YES
TSI BOTH
IN1 00
IN2 00
U1S U1
U2S U2
TN1 LOOP 1
TN2 LOOP 2
EU1 PRCT
EU2 PRCT
EUX PRCT
EUY PRCT
FL1 A1
FB13
T
ESN 60
UM348-1
H
C1T PID
MRT NO
INP 01
INS 05
INF 17
INA 00
INC 18
(continued on next page)
9-66
October 1998
UM348-1
FACTORY CONFIGURED OPTIONS
H
S
C
FL2 A2
FL3 A5
FL4 A6
FL5 NONE
...............................................................................................................................................................................
FB17
ESN 30
INT 00
INC 00
INL 10
...............................................................................................................................................................................
FB29
ESN 71
INA 60
INB 00
...............................................................................................................................................................................
FB45
ESN 45
C2T PID
A2 REV
MRT NO
PG2 1.00
INP 02
TI2 100 M/R
INS 54
TD2 0.00 MIN
INF 60
DG2 10.00
INA 00
MR2 0.0%
INC 68
HL2 100.00%
LL2 0.0%
..............................................................................................................................................................................
FB46
ESN 25
INT 00
INC 00
...............................................................................................................................................................................
FB51
ESN 26
DSD NO
LL2
0.00%
INA 48
HL2 100.00%
...............................................................................................................................................................................
FB55
ESN 66
AO NO
PUM 0.0%
PU LP
PUL NO
INA 46
INT 00
INE 00
INS 00
...............................................................................................................................................................................
FB71
ESN 36
INA 05
INB 54
IND 01
INE 02
INF 17
ING 60
INC 10
...............................................................................................................................................................................
FB15
October 1998
T
ESN 40
9-67
FACTORY CONFIGURED OPTIONS
UM348-1
H
S
C
Q5R 4 (%)
SA5 100.0%
Q6R 4 (%)
SA6 0.0%
Q7R 4 (%)
SA7 100.0%
Q8R 4 (%)
SA8 0.0%
A5T HI
DA5 0.5%
A6T LO
DA6 0.5%
A7T DEV
DA7 0.5%
A8T NONE
DA8 0.5%
INA 02
EA5 EN
INB 02
EA6 EN
INC 54
EA7 EN
IND 02
EA8 DIS
A5I 0.0 SEC
A6I 0.0 SEC
A7I 0.0 SEC
A8I 0.0 SEC
A5O 0.0 SEC
A6O O.O SEC
A7O 0.0 SEC
A8O 0.0 SEC
A5R NO
A6R NO
A7R NO
A8R NO
..............................................................................................................................................................................
FB98
ESN 90
H1P 01
H1S 05
H1V 17
H2P 02
H2S 54
H2V 60
POL 0
P1F USER
P2F USER
IND 00
INE 00
INF 00
ING 00
HTN HART TAG
DES HART DESCRIPTOR
MSG HART MESSAGE
DAT 01/01/93
DSN 0
FB73
T
ESN 76
(continued on next page)
9-68
October 1998
UM348-1
FACTORY CONFIGURED OPTIONS
H
S
C
VC1 3
VC2 4
VC3 5
VC4 0
RP 5
..............................................................................................................................................................................
FB98
October 1998
T
ESN 90
9-69
FACTORY CONFIGURED OPTIONS
UM348-1
9.16 FCO 31 Single-Loop PID Controller (TSP) – Pressure Input
With:
Hi/Lo Process Alarms
Deviation Alarm
Tracking Setpoint
Setpoint Limits
4-20 mA Output
PROCESS
FB81
INPUT
97
A/B/D FB12
ALARM
C
INP
INS
P
F FB13
PID
S
05 FB09
LIMIT
C
14
T
A
FB17
22 SET
C
A
FB14
A/M
17
18
INV
A
AO1+ (E11)
AO1C (E12)
FB03
OUT
VALVE
CONNECTION TO FB15 OPERATOR DISPLAY BLOCK
9-70
October 1998
UM348-1
FACTORY CONFIGURED OPTIONS
CONFIGURATION PARAMETERS
H
S
C
INA 17
INB 00
...................................................................................................................................………………………........
FB09
ESN 14
DSD NO
LL1
0.00%
INA 22
HL1 100.00%
...................................................................................................................................………………………........
FB12
ESN 15
Q1R 4 (%)
SA1 100.00%
Q2R 4 (%)
SA2 0.00%
Q3R 4 (%)
SA3 100.00%
Q4R 4 (%)
SA4 0.00%
A1T HI
DA1 0.5%
A2T LO
DA2 0.5%
A3T DEV
DA3 0.5%
A4T NONE
DA4 0.5%
INA 97
EA1 EN
INB 97
EA2 EN
INC 05
EA3 EN
IND 97
EA4 DIS
A1I 0.0 SEC
A2I 0.0 SEC
A3I 0.0 SEC
A4I 0.0 SEC
A1O 0.0 SEC
A2O 0.0 SEC
A3O 0.0 SEC
A4O 0.0 SEC
A1R NO
A2R NO
A3R NO
A4R NO
...................................................................................................................................................……………….....
FB13
ESN 30
C1T PID
A1 REV
MRT NO
PG1 1.00
INP 97
TI1 100.00 M/R
INS 05
TD1 0.00 MIN
INF 17
DG1 10.00
INA 00
MR1 0.0%
INC 18
HL1 100.00%
LL1 0.00%
...............................................................................................................................................…………………....
FB03
October 1998
T
ESN 45
9-71
FACTORY CONFIGURED OPTIONS
UM348-1
H
S
C
AO NO
PUM 0.00%
PU LP
PUL NO
INA 14
INT 00
INE 00
INS 00
INL 00
.......................................................................................................................................………………………....
FB15
ESN 40
INP 97
DP1 0.00
INS 05
PL1 0.00000
INV 17
PH1 100.000
INX 00
DP2 0.00
INY 00
PL2 0.00000
INA 00
PH2 100.000
INL 00
DPX 0.00
PDR L
XL 0.00000
SDR L
XH 100.000
HS1 VALVE
DPY 0.00
HS2 VALVE
YL 0.0000
HD1 YES
YH 100.000
HD2 YES
TST 10 SEC
SCF YES
TSI TN1
IN1 00
IN2 00
U1S U1
U2S U2
TN1 TAG NAME 1
TN2 TAG NAME 2
EU1 PRCT
EU2 PRCT
EUX PRCT
EUY PRCT
FL1 A1
FL2 A2
FL3 A3
FL4 NONE
FL5 NONE
..................................................................................................................................................………….............
FB17
ESN 10
INT 97
INC 18
INL 00
................................................................................................................................................…………...............
FB14
9-72
T
ESN 35
October 1998
UM348-1
FACTORY CONFIGURED OPTIONS
T
H
S
C
FB81
ESN 05
SRE NO
....................................................................................................................................…………...........................
FB98
ESN 90
H1P 97
H1S 05
H1V 17
H2P 00
H2S 00
H2V 00
POL 0
P1F USER
P2F USER
IND 00
INE 00
INF 00
ING 00
HTN HART TAG
DES HART DESCRIPTOR
MSG HART MESSAGE
DAT 01/01/93
DSN 0
VC1 3
VC2 4
VC3 5
VC4 0
RP 5
......................................................................................................................................…………………..............
n
October 1998
9-73
FACTORY CONFIGURED OPTIONS
9-74
UM348-1
October 1998
UM348-1
APPENDIX A
A.0 APPENDIX A - FIELDPAC FUNCTION BLOCKS
TABLE A-1 FIELDPAC Function Blocks
FB#
DESCRIPTION
OUTPUT
IDENTIFICATION
COMMENTS
MODEL
01
Analog Input #1
Output: 01
N/A if 1/3-input P/I
S&E
02
Analog Input #2
Output: 02
N/A if 3-input P/I
S&E
03
Analog Output #1
Used by I/P option
S&E
04
Digital Output #1
S&E
05
Digital Output #2
S&E
06
Digital Input #1
Output: 16
S&E
07
Ratio
Output: 03
Track Output: 89
S&E
08
Bias
Output: 04
Track Output: 90
S&E
09
Hi/Lo Limit #1
Output: 05
S&E
10
Override Selector
Output: 07
OR Status: 08
S&E
11
PB Transfer #2
Output: 09
Status IS: 10
Status ES: 25
S&E
12
Alarm #1
Status AS1: 11
Status AS2: 12
Status AS3: 13
Status AS4: 91
S&E
13
PID Controller #1
Controller Output: 14
Error: 15
S&E
13
PD Controller #1
Controller Output: 14
Error: 15
S&E
13
ID Controller #1
Controller Output: 14
Error: 15
S&E
(continued on next page)
October 1998
A-1
APPENDIX A
UM348-1
TABLE A-1 FIELDPAC Function Blocks (continued)
FB#
DESCRIPTION
OUTPUT
IDENTIFICATION
COMMENTS
MODEL
13
PIDA Controller #1
Controller Output: 14
Error: 15
S&E
14
A/M Transfer #1
Output: 17
Status MS: 18
S&E
15
Operator Display
Error: 06
Pulse On: 19
Pulse Off: 26
S&E
16
Totalizer
P1 Status: 92
P2 Status: 93
S&E
17
Setpoint Track & Hold #1
Output: 22
S&E
18
General Purpose Track/Hold
Output: 23
S&E
19
General Purpose Hold
Output: 24
S&E
20
Logic #1
Output: 20
S&E
21
Logic #2
Output: 21
S&E
22
Deviation Amplifier
Output: 29
S&E
23
PB Transfer #1
Output: 27
Status IS: 63
Status ES: 64
S&E
24
Square Root Extractor
Output: 44
S&E
25
Analog Input #3
Output: 30
S&E
28
Pulse Integrator
S&E
29
Analog Output #2
E
30
Digital Input #2
32
Iso-Digital Output #1
Opto-Transistor in S
Relay Contact in E
S&E
33
Iso-Digital Output #2
Opto-Transistor in S
Relay Contact in E
S&E
34
Math Block #1
Output: 34
S&E
35
Math Block #2
Output: 35
S&E
Output: 58
S&E
(continued on next page)
A-2
October 1998
UM348-1
APPENDIX A
TABLE A-1 FIELDPAC Function Blocks (continued)
FB#
DESCRIPTION
OUTPUT
IDENTIFICATION
COMMENTS
MODEL
36
Math Block #3
Output: 36
S&E
38
Gain & Bias #1
Output: 38
S&E
39
Gain & Bias #2
Output: 39
S&E
40
Lag
Output: 40
S&E
41
Lead
Output: 41
S&E
42
Rate Limiter
Output: 42
S&E
43
Dead Time Table
Output: 43
S&E
44
10-Segment Characterizer #1
Output: 45
S&E
45
PID Controller #2
Controller Output: 46
Error: 47
S&E
45
PD Controller #2
Controller Output: 46
Error: 47
S&E
45
ID Controller #2
Controller Output: 46
Error: 47
S&E
45
PIDA Controller #2
Controller Output: 46
Error: 47
S&E
46
Setpoint Track & Hold #2
Output: 48
S&E
47
Repeat Cycle Timer
Output: 49
S&E
48
Logic #3
Output: 52
S&E
49
General Purpose Transfer
Output: 51
S&E
50
Logic #4
Output: 53
S&E
51
Hi/Lo Limit #2
Output: 54
S&E
53
Batch Switch
Output: 56
S&E
55
A/M Transfer #2
Output: 60
Status MS: 68
S&E
61
Logic #5
Output: 61
S&E
62
Logic #6
Output: 62
S&E
(continued on next page)
October 1998
A-3
APPENDIX A
UM348-1
TABLE A-1 FIELDPAC Function Blocks (continued)
FB#
DESCRIPTION
OUTPUT
IDENTIFICATION
COMMENTS
MODEL
64
Quad Comparator
Comparator 1: 80
Comparator 2: 81
Comparator 3: 82
Comparator 4: 83
S&E
65
Delay Timer
Output: 69
S&E
67
One Shot Timer
Output: 84
S&E
71
Dual Transfer Switch
Output 1: 31
Output 2: 32
Output 3: 33
S&E
72
10 Segment Characterizer #2
Output: 57
S&E
73
Alarm #2
Status AS5: 75
Status AS6: 76
Status AS7: 77
Status AS8: 78
S&E
75
Password Security
81
Pressure Sensor
Output: 97
Optional in S or E
82
Temperature Sensor
Output: 98
Optional in S or E
85
Pneumatic Input #1
Output: 85
Optional in S or E
86
Pneumatic Input #2
Output: 86
Optional in S or E
87
Pneumatic Input #3
Output: 87
Optional in S or E
88
Logic #7
Output: 65
S&E
89
Logic #8
Output: 66
S&E
90
Logic #9
Output: 67
S&E
98
HART Communication
HART Status: 79
Output 70: 70
Output 71: 71
Output 72: 72
Output 73: 73
Output 74: 74
S&E
S&E
n
A-4
October 1998
UM348-1
APPENDIX B
APPENDIX B.0 MODEL 348 CONFIGURATION DOCUMENTATION
INSTRUMENT IDENTIFICATION
MODEL NO. _______________________________ B/M NO. ______________________________________
SERIAL NO. ________________________________ SENSOR MODEL NO. __________________________
SENSOR B/M NO. ___________________________ SENSOR SERIAL NO.
___________________________
TAG NO. ___________________________________
NOTES: ___________________________________________________________________________________________
____________________________________________________________________________________________________
____________________________________________________________________________________________________
This appendix serves as a source document of configuration data for the Model 348 FIELDPAC Field Mounted
Controller. All hard, soft, calibration and execution sequence parameters off all function blocks are listed on the
following pages. However, the actual function blocks available in an individual controller will depend on the model
number (including options). Enter your configuration data in the appropriate blocks and retain this document for
future reference. Refer to Section 8 of this manual for further details of the function block parameter variables.
Space is provided at the end of this section to draw your configuration diagram. A sample diagram and a
completed page is shown below.
T
PROCESS
AI1+ (F7)
AI1C (F8)
FB01 ESN
FB01
INPUT
01
H
S
SRE
DV1
SRE
DV2
C
0 SEC
ZI
FI
FB02 ESN
ZI2
FI2
A/B/D
FB12
ALARM
FB03 ESN
C
INP
INS
P
F
05
FB13
PID
S
05 FB09
LIMIT
C
T
A
FB17
22 SET
14
45
INA
17
ZO1
INB
00
FO1
FB04 ESN
INA
FB05 ESN
INA
FB06 ESN
FB07 ESN
C
INA
R
INB
RRL
INC
RRH
IND
RCD
A
FB14
A/M
17
FB08 ESN
AO1C (E12)
B
INA
INE
INC
IND
INV
A
AO1+ (E11)
OBR
18
FB03
OUT
VALVE
BCD
FB09 ESN
FB10 ESN
14
DSD
NO
LL1
0.00%
INA
22
HL1
100.00%
S1B
S1C
DSD
INA
INB
CONNECTION TO FB15 OPERATOR DISPLAY BLOCK
October 1998
INC
B-1
APPENDIX B
UM348-1
T
FB01
ESN
H
SRE
S
DV1
C
ZI1
FI1
FB02
ESN
SRE
DV2
ZI2
FI2
FB03
ESN
INA
ZO1
INB
FO1
FB04
ESN
INA
FB05
ESN
INA
FB06
ESN
FB07
ESN
INA
R
INB
RRL
INC
RRH
IND
RCD
FB08
ESN
OBR
B
INA
INE
INC
IND
BCD
FB09
FB10
ESN
ESN
DSD
LL1
INA
HL1
S1B
S1C
DSD
INA
INB
INC
B-2
October 1998
UM348-1
APPENDIX B
T
FB11
ESN
H
S
C
EO
PU
S1A
DSD
INE
INI
INA
FB12
ESN
Q1R
SA1
Q2R
SA2
Q3R
SA3
Q4R
SA4
A1T
DA1
A2T
DA2
A3T
DA3
A4T
DA4
INA
EA1
INB
EA2
INC
EA3
IND
EA4
A1I
A2I
A3I
A4I
A1O
A2O
A3O
A4O
A1R
A2R
(continued on next page)
October 1998
B-3
APPENDIX B
UM348-1
T
H
FB12
A3R
(cont’d)
A4R
FB13
ESN
S
C1T
A1
MRT
PG1
INP
TI1
INS
TD1
INF
DG1
INA
MR1
INC
HL1
C
LL1
FB14
ESN
AO
PUM
PU
PUL
INA
INT
INE
INS
INL
FB15
ESN
40
INP
DP1
INS
PL1
INV
PH1
INX
DP2
INY
PL2
INA
PH2
INL
DPX
PDR
XL
SDR
XH
HS1
DPY
HS2
YL
(continued on next page)
B-4
October 1998
UM348-1
APPENDIX B
T
H
S
FB15
HD1
YH
(cont’d)
HD2
TST
SCF
TSI
C
IN1
IN2
U1S
U2S
TN1
TN2
EU1
EU2
EUX
EUY
FL1
FL2
FL3
FL4
FL5
FB16
ESN
CU
FS
TDD
TB
PCD
CM
INA
ZDO
INS
SV
INR
P1
P2
DIR
FB17
ESN
INT
LS1
INC
HS1
INL
October 1998
B-5
APPENDIX B
UM348-1
T
FB18
ESN
H
INT
S
C
H1
INC
HCD
FB19
ESN
HCD
FB20
ESN
LT1
H2
INA
INB
FB21
ESN
LT2
INA
INB
FB22
ESN
INA
G1
INB
B1
INC
FB23
ESN
EO
PU
S1A
DSD
INE
INI
INA
FB24
ESN
INA
FB25
ESN
SRE
DV3
ZI3
FI3
FB28
ESN
INA
FS
INS
TB
CM
ZD
PW
B-6
October 1998
UM348-1
APPENDIX B
T
FB29
ESN
FB30
ESN
FB32
ESN
H
S
C
INA
ZO2
INB
FO2
INA
A1
FB33
ESN
INA
A2
FB34
ESN
O1A
GO1
O1B
GA1
INA
GB1
INB
GC1
INC
BO1
BA1
BB1
BC1
FB35
ESN
O2A
GO2
O2B
GA2
INA
GB2
INB
GC2
INC
BO2
BA2
BB2
BC2
FB36
ESN
O3A
GO3
O3B
GA3
INA
GB3
INB
GC3
INC
BO3
BA3
(continued on next page)
October 1998
B-7
APPENDIX B
UM348-1
T
H
S
FB36
BB3
(cont’d)
BC3
FB38
ESN
INA
C
GO5
GA5
BO5
BA5
FB39
ESN
INA
GO6
GA6
BO6
BA6
FB40
ESN
INA
TL
INB
FB41
ESN
INA
TH
INB
FB42
ESN
INA
TRU
INB
TRD
INC
IND
FB43
ESN
INA
TM
INB
INC
FB44
ESN
INA
X0
X1
X2
X3
X4
X5
X6
X7
(continued on next page)
B-8
October 1998
UM348-1
APPENDIX B
T
H
S
FB44
X8
(cont’d)
X9
C
X10
Y0
Y1
Y2
Y3
Y4
Y5
Y6
Y7
Y8
Y9
Y10
FB45
ESN
C2T
A2
MRT
PG2
INP
TI2
INS
TD2
INF
DG2
INA
MR2
INC
HL2
LL2
FB46
FB47
FB48
ESN
ESN
ESN
INT
LS2
INC
HS2
INA
TF
INB
TN
LT3
INA
INB
October 1998
B-9
APPENDIX B
UM348-1
T
FB49
ESN
H
S
C
INA
INB
INC
FB50
ESN
LT4
INA
INB
FB51
ESN
DSD
LL2
INA
HL2
FB53
ESN
INA
BPL
FB55
ESN
AO
PUM
PU
PUL
INA
INT
INE
INS
FB61
ESN
LT5
INA
INB
FB62
ESN
LT6
INA
INB
FB64
ESN
C1A
TC1
C2A
TC2
C3A
TC3
C4A
TC4
INA
DC1
INB
DC2
(continued on next page)
B-10
October 1998
UM348-1
APPENDIX B
T
H
S
FB64
INC
DC3
(cont’d)
IND
DC4
C
INE
INF
ING
INH
FB65
ESN
INA
DT
DTT
OPU
FB67
ESN
INA
FB71
ESN
INA
OT
INB
IND
INE
INF
ING
INC
FB72
ESN
INA
X0
X1
X2
X3
X4
X5
X6
X7
X8
X9
X10
(continued on next page)
October 1998
B-11
APPENDIX B
UM348-1
T
H
S
FB72
Y0
(cont’d)
Y1
C
Y2
Y3
Y4
Y5
Y6
Y7
Y8
Y9
Y10
FB73
ESN
Q5R
SA5
Q6R
SA6
Q7R
SA7
Q8R
SA8
A5T
DA5
A6T
DA6
A7T
DA7
A8T
DA8
INA
EA5
INB
EA6
INC
EA7
IND
EA8
A5I
A6I
A7I
A8I
A50
(continued on next page)
B-12
October 1998
UM348-1
APPENDIX B
T
H
FB73
A6O
(cont’d)
A7O
S
C
A8O
A5R
A6R
A7R
FB75
ESN
TPW
APW
SPW
HPW
CPW
FB81
ESN
SRE
DVP
MVU
MVL
MVH
FB82
ESN
IT
DVP
BOD
MVU
MVL
MVH
FB85
ESN
SRE
DV1
ZI1
FI1
FB86
ESN
SRE
DV2
ZI2
FI2
FB87
ESN
SRE
DV3
ZI3
FI3
FB88
ESN
LT7
INA
INB
October 1998
B-13
APPENDIX B
UM348-1
T
FB89
ESN
H
S
C
LT8
INA
INB
FB90
ESN
LT9
INA
INB
FB98
ESN
H1P
H1S
H1V
H2P
H2S
H2V
POL
P1F
P2F
IND
INE
ING
HTN
DES
MSG
DAT
DSN
VC1
VC2
VC3
VC4
RP
B-14
October 1998
UM348-1
APPENDIX B
T
October 1998
H
S
C
B-15
APPENDIX B
UM348-1
CONFIGURATION DIAGRAM
B-16
October 1998
UM348-1
APPENDIX C
C.0 APPENDIX C - CABLE CAPACITANCE AND MAXIMUM LENGTH
A cable length calculation is necessary when HART communication is to be employed. Cable capacitance directly
affects maximum Network length.
C.1 CABLE CAPACITANCE
Cable type, conductor size, and recommended cable model numbers are stated in Section 8.3.3 Two-Wire Cable.
Cable capacitance is a parameter used in the calculation of the maximum length of cable that can be used to
construct the Network. The lower the cable capacitance the longer the Network can be. Manufacturers typically
list two capacitance values for an instrumentation cable:
1. Capacitance between the two conductors.
2. Capacitance between one conductor and the other conductor(s) connected to shield. This capacitance is the
worst case value and is to be used in the cable length formula.
C.2 MAXIMUM CABLE LENGTH CALCULATION
The maximum permissible single-pair cable length is 10,000 feet (3000 meters) or less as determined by the
following formula:
65,000,000
L=
Cf + 10,000
-
RxC
C
Formula Definitions:
L:
The maximum total length of cable permitted to construct the Network. L = Feet when C is in pF/ft. L =
meters when C is in pF/meter.
R:
The Network Resistance which is the ohmic sum of the Current Sense Resistance and Barrier Resistance
(both Return and Supply), if any, in the Network and the resistance of the wire.
C:
Cable capacitance per unit length between one conductor and the other conductor connected to the shield.
C may be in pF/ft or pF/meter.
Total input terminal capacitance of Field Instruments; the Primary Master is excluded. Cf is given by the
following formula:
Cf:
Cf = (sum of all Cn values) x (5000)
October 1998
C-1
APPENDIX C
UM348-1
Where Cn is an integer (e.g., 1, 2, 3) corresponding to the input terminal capacitance of a Field
Instrument. Cn values are read from the following table. For Field Instruments without Cn values, use Cn
=1
FIELD INSTRUMENT CAPACITANCE
Less than 5000 pF
5000 pF to less than 10000 pF
10000 pF to less than 15000 pF
15000 pF to less than 20000 pF
20000 pF to less than 25000 pF
25000 pF to less than 30000 pF
Cn VALUE
1
2
3
4
5
6
Example Calculation:
Assume a Network consists of a 344 and a Field Instrument (Cn = 1 and Cn = 6).
Let R = 250W, C = 40 pF/ft., Cf = (1 + 6) x 5000 = 35,000
65,000,000
Then L =
35,000 + 10,000
-
(250)(40)
= 5375 feet (1612.5 meters)
40
n
C-2
October 1998
WARRANTY
The Company warrants all equipment manufactured by it and bearing its nameplate, and all repairs made by it, to
be free from defects in material and workmanship under normal use and service. If any part of the equipment
herein described, and sold by the Company, proves to be defective in material or workmanship and if such part is
within twelve months from date of shipment from the Company’s factory, returned to such factory, transportation
charges prepaid, and if the same is found by the Company to be defective in material or workmanship, it will be
replaced or repaired, free of charge, f.o.b. Company’s factory. The Company assumes no liability for the
consequence of its use or misuse by Purchaser, his employees or others. A defect in the meaning of this warranty in
any part of said equipment shall not, when such part is capable of being renewed, repaired or replaced, operate to
condemn such equipment. This warranty is expressly in lieu of all other warranties, guaranties, obligations, or
liabilities, expressed or implied by the Company or its representatives. All statutory or implied warranties other
than title are hereby expressly negated and excluded.
Warranty repair or replacement requires the equipment to be returned to one of the following addresses:
Equipment manufactured or sold by MOORE PRODUCTS CO.
MOORE PRODUCTS CO.
Sumneytown Pike
Spring House, PA 19477 U.S.A.
Tel: +1 215 646 7400
Fax: +1 215 283 6340
Equipment manufactured or sold by MOORE PRODUCTS CO. (Canada) Inc.
MOORE INSTRUMENT LTD/LTEE
P.O. Box 370
Brampton, Ontario L6V 2L3, Canada
Tel: +1 905 457 9638
Fax: + 1 905 457 4182
Equipment manufactured or sold by MOORE PRODUCTS CO. (UK) LTD.
MOORE PRODUCTS CO. (UK) LTD
Copse Road,
Lufton Industrial Estate
Yeovil, Somerset BA22 8RN, England
Tel: +44 1935 706262
Fax: +44 1935 706969
The warranty will be null and void if repair is attempted without authorization by a member of the MOORE
PRODUCTS CO. Service Department.
MODEL 348 FIELDPAC™
FIELD MOUNTED CONTROLLER
Drawing No. 348-1PL
PL348-1
Rev. 3
October 1998
MODEL 348 FIELDPAC™
FIELD MOUNTED CONTROLLER
13
14
Upper Door Shown
12
U-Shaped Hinge
11
10
Nameplate
4-40 X 0.375
X03022S0
4
1
3
9
6
7
5
8
2
PL348-1
PARTS LIST
ITEM
PART NUMBER
DESCRIPTION
QUANTITY
1
2
3
4
5*
6
7
8
9
10
11
12*
13
-
16161-181
16161-226
16161-227
16161-134
16161-223
16161-222
16161-25
16161-239
7447-209
16186-17
16205-51
16205-52
16205-53
16205-54
16205-55
16205-56
16205-57
16205-58
15972-128
15972-133
16161-197
16161-88
16161-26
16161-188
16288-1
16288-21
16288-31
7447-167
16161-12
16161-82
-
16161-83
16161-186
14
16161-187
16161-122
-----
-----
1-0716
16161-211
Upper Door w/Keyboard, No Display
Upper Door w/Keyboard, Non-Backlit Display
Upper Door w/Keyboard, Backlit Display
Lower Door (Terminal Compartment)
Display with Backlight
Display without Backlight
90-264 Vac Power Supply Kit for all models except as follows
90-264 Vac Power Supply Kit for CE and Type N approved models
Power Supply Fuse 120/240 Vac
Thermocouple Board Kit
Pneumatic 3-Input 3-15 psig Kit, Design Level B
Pneumatic 3-Input 3-27 psig Kit, Design Level B
Pneumatic 1-Input 3-15 psig Kit, Design Level B
Pneumatic 1-Input 3-27 psig Kit, Design Level B
Pneumatic 3-Input 3-15 psig Kit, Design Level A
Pneumatic 3-Input 3-27 psig Kit, Design Level A
Pneumatic 1-Input 3-15 psig Kit, Design Level A
Pneumatic 1-Inout 3-27 psig Kit, Design Level A
I/P Module 3-15 psig
I/P Module 3-27 psig
Mounting Bracket Kit, Standard Length
Extended Mounting Bracket
NEMA Type 4X Vent
Software Update Kit (current controller software)
Standard MPU Board
Enhanced MPU Board
Enhanced MPU Board for Type N approved models
MPU Board Fuse 500 mA
Back Cover Plate, No Sensor
Pressure Sensor Kit 340D or 340A/G with Tantalum Diaphragm,
includes Backplate**
Pressure Sensor Kit 340A/G, includes Backplate**
Pressure Sensor Kit 340D or 340A/G with Tantalum Diaphragm, no
Backplate**
Pressure Sensor Kit 340A/G, no Backplate**
Sensor Mounting Hole Plug Kit
XTC Pressure Sensor - see GC MC-1, XTC Model 340, direct
connect selections
4-40 x 0.375 Flat Head SST Screw
U-Shaped Metal Hinge
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
2
1
1
1
1
1
1
1
1
1
1
1
1
1
4
4
Notes to Parts List:
•
Refer to Model 348 User’s Manual UM348-1 before servicing the controller.
•
See drawings above for controller disassembly and Item number reference.
•
An * in the Item column identifies a recommended on-hand spare part. When ordering a spare or replacement part, provide the
controller’s complete model number, serial number and other nameplate information.
•
** - Separately order a Model 340 ‘direct connect’ pressure sensor.
2
Ref. UM348-1
SOFTWARE RELEASE MEMO
SR348-3
Rev: 1
August 1998
Model 348 Moore FIELDPAC®
Software Version 1.05
PRODUCT INVOLVED
A Model 348 Moore FIELDPAC Field-Mounted Controller with MPU controller board V1.05 software
(firmware).
INTRODUCTION
This Software Release Memo discusses functional and performance enhancements incorporated in MPU
Controller board software (firmware) version 1.05. It also contains a list of materials needed to upgrade a
controller having earlier software. If this paper accompanies a controller shipment, V1.05 is installed on
the MPU Controller Board.
Software version 1.05 replaces all previous versions (V1.01, V1.02, V1.03 and V1.04). Configurations
created with the previous versions are compatible with V1.05.
Contact your local sales office for price and delivery if you have a controller with earlier MPU Controller
Board software.
ENHANCEMENTS
The primary purpose of this V1.05 software is to support new Analog to Digital (ADC) & Digital to
Analog (DAC) Converters included on the MPU board shipped after June, 1998. Some enhancements and
operational considerations from previous releases were also addressed.
•
Factory Configured Option (FCO31) was added. This is a Single-Loop PID Controller (TSP) with a
direct process pressure input (FB81).
•
Two outputs were added to FB81, Process Pressure Sensor function block: Capsule Temperature (55)
and Static Pressure (50). These parameters must be entered from the front faceplate.
•
Two HART® Variable Codes, Static Pressure (9) and Capsule Temperature (10) were added to
FB98.
•
New power up error codes were added to the error code table.
SR348-3
•
Function Block FB42 now has a valid ramp down time of 0.0.
•
Ratio is now displayed on-line & during configuration with two decimal places.
•
Optional sensor inputs will now power up with error codes and will not remove the configuration until
the user acknowledges the error.
•
The LEDs associated with the E/I switch now show the correct position of the E/I switch, and not the
status of the E/I function block.
OTHER ENHANCEMENTS
Version 1.05 software includes the following previous software enhancements. Version 1.05 software will
update any of the previous versions to version 1.05 without having to install each previous software
version.
Version 1.04 software enables a Model 348 to accept a Model 340 pressure capsule that has an EMO
(Enhanced Multi-Mode Oscillator). The new EMO compensation method provided by the software
improves the ambient temperature performance when using a new EMO capsule. V1.04 software is
compatible with older 340 capsules which use an MMO.
V1.03 enhancements to V1.02 release provides greater reliability and more robust operation of the HART
communications circuit.
•
VIEW mode will display NAN when the block output is the IEEE representation of “not a number.”
•
When both A/M blocks are used, FIELDPAC displays the appropriate A/M annunciator for the
current loop being viewed. When one of the A/M blocks is removed from execution, that annunciator
is no longer displayed with its associated loop.
•
When an FCO is stored and alarms are active, alarm status words are updated.
•
User 1 and User 2 Status bits can be accessed via HART. A higher level device can now access these
status bits.
•
Valve action is now included in the Loop Status Word via HART.
V1.03 enhancements to V1.01 include the above plus the following:
•
FB98 parameters (Outputs 70, 71, 72, 73, & 74) are now non-volatile.
•
The VIEW mode now times out after 3 minutes.
•
Setpoint function blocks FB17 and FB46 will respond to a HART command from a higher level
device to START A RAMP.
•
Rate Limiter FB42 can limit the RAMP RATE DOWN at times other than 0.0 minutes.
•
The B HI/LO Selector in FB10 can now function as a LOW selector when configured as such.
2
SR348-3
•
The following changes have been made to FCO 20:
- FB45 HINS = 54 , not 09
- FB73 HINC = 54, not 09
- FB51 HINA= 09, not 48
- FB98 H2S= 09, not 54
•
Rate Limiter FB42 will now track when the Adaptive input = 0%.
•
The Configuration Hold bit is now reset after a display test.
•
Several Alarm enhancements and corrections were made:
- Alarm trip points are set in % in the configuration mode.
- Alarm Not Acknowledged (NAK) bit now functions properly.
- Alarms no longer ring after the function block is removed from configuration.
- The decimal point position in Quick Alarm matches the position in engineering units when
configured to display in engineering units.
UPGRADE MATERIALS NEEDED
•
•
•
FIELDPAC Software Update Kit P/N16161-188 with the following three items:
- ROM extraction tool (P/N16161-183)
- V1.05 ROM
- Software Release Memo (SR348-3)
Model 348 User’s Manual (UM348-1)
Phillips-head screwdriver to open upper door
INSTALLATION PROCEDURE
Refer to the Model 348 User’s Manual (UM348-1) and proceed with the following:
1. Remove power from the controller.
WARNING
Electrical shock hazard. Remove electrical power before proceeding.
2. Open the upper door.
3. Snap on a wrist strap grounded to an unpainted area on the controller. Refer to Figure 1 and locate
U48.
3
SR348-3
Upper
Door,
Open
ROM to be updated.
See Detail and Figure 2
for removal.
DIP Switch
Label shows ROM part number
and revision number.
Pin 1 Flat
SW1
U48
U48
U39
U25
MPU Baseboard,
Upper Left Corner
ROM
Label
ROM
Chip
Socket
Power
Supply
ROM Detail
CAUTION
85-264 VAC
X02907S0
ROM Location
FIGURE 1 ROM Location and Labeling
4. Carefully remove the installed ROM (U48) using the extraction tool provided. See Figure 2 for details.
IMPORTANT
If care is not taken, the ROM’s socket may be damaged. Such damage
cannot be repaired in the field.
X02908S0
AMP 822154-1
Fit tip of tool under ROM body.
Carefully pry ROM from socket.
Insert tool in corner of socket
with a rectangular cutout.
of the ROM then the opposite
corner. Continue until the chip
is free.
FIGURE 2 ROM Removal
4
SR348-3
5. Using the “Pin 1 Flat” on the ROM for reference, carefully orient the supplied V1.05 ROM with the
socket and press it in. Be certain that the ROM is fully and evenly inserted in the socket.
6. Remove the wrist strap and close and secure the upper door.
The update is complete. The Controller’s configuration and calibration will not be affected by this
update.
7. Apply power to the Controller and verify that it is operational. Edit the configuration as desired to take
advantage of the enhancements. Discard the V1.01, 1.02, V1.03 or V1.04 ROM.
8. Complete and mail the software registration card.
n
Procedures in this document have been reviewed for compliance with applicable approval agency requirements and are considered sound
practice. Neither Moore Products Co. nor these agencies are responsible for repairs made by the user.
Moore Products Co. assumes no liability for errors or omissions in this document or for the application and use of information included in this
document. The information herein is subject to change without notice.
The Moore logo and Moore FIELDPAC are registered trademarks of Moore Products Co.
All other trademarks are the property of the respective owners.
© Copyright 1998 Moore Products Co. All rights reserved
5
Siemens
Energy & Automation
USER'S MANUAL ADDENDUM
UMA348-1-3
Rev: 1
December 2003
MODEL 348E FIELD MOUNTED CONTROLLER
INSTALLATION IN THE PRESENCE OF ACETIC ACID
INVOLVED MANUAL
UM348-1, Model 348 Field Mounted Controller User’s Manual, Issue 4
DISCUSSION
The following statement modifies Sections 1.3.4 Environment, 1.3.5 Hazardous Area Classification, and
2.0 Installation of the above manual and applies to U.S. installations only:
A Model 348E may not be installed in a Division 2 hazardous area when acetic acid is present.
„