FlexPak 3000 Digital DC Drive Software Reference

FlexPak 3000 Digital DC Drive
Software Reference Manual
Version 4.3
Instruction Manual D2-3405-2
The information in this manual is subject to change without notice.
Throughout this manual, the following notes are used to alert you to safety considerations:
!
ATTENTION: Identifies information about practices or circumstances that can lead to personal
injury or death, property damage, or economic loss.
Important: Identifies information that is critical for successful application and understanding of the product.
The thick black bar shown on the outside margin of this page will be used throughout this instruction manual to
signify new or revised text or figures.
!
ATTENTION: Only qualified electrical personnel familiar with the construction and operation of
this equipment and the hazards involved should install, operate, or service this equipment. Read
and understand this manual in its entirety before proceeding. Failure to observe this precaution
could result in severe bodily injury or loss of life.
ATTENTION: This drive can operate at and maintain zero speed. The user is responsible for
assuring safe conditions for operating personnel by providing suitable guards, audible or visual
alarms, or other devices to indicate that the drive is operating at or near zero speed. Failure to
observe this precaution could result in severe bodily injury or loss of life.
Reliance, FlexPak, AutoMax, and E.S.P. are trademarks of Rockwell Automation.
DeviceNet is a trademark of the Open DeviceNet Vendor Association.
ControlNet is a trademark of ControlNet International, Ltd.
©2001 Rockwell Automation. All rights reserved.
CONTENTS
Contents
Chapter 1
Introduction
1.1 Before You Start .............................................................................................. 1-1
1.2 Where to Find Information ............................................................................... 1-1
1.3 Conventions..................................................................................................... 1-1
1.4 Getting Assistance from Reliance Electric....................................................... 1-2
1.5 Drive Description ............................................................................................. 1-2
Chapter 2
Drive Sequencing
2.1 Run and Jog Sequencing ................................................................................ 2-2
2.2 Stop Sequencing ............................................................................................. 2-2
Chapter 3
Initial Configuration
3.1 Selecting a Control Source .............................................................................. 3-1
3.2 Configuring the AC Line Parameters ............................................................... 3-2
3.3 Self-Tuning Parameters................................................................................... 3-3
Chapter 4
Configuring the Speed Reference
4.1 Configuring the Speed Reference Source Block ............................................. 4-2
4.1.1 Configuring the Keypad (OIM) Speed Reference.................................. 4-4
4.1.2 Configuring the Analog Auto Reference................................................ 4-4
4.1.3 Configuring the Analog Manual Reference ........................................... 4-6
4.1.4 Configuring the Serial Speed Reference............................................... 4-8
4.1.5 Configuring the Network Speed Reference........................................... 4-8
4.1.6 Configuring the Motor-Operated Potentiometer (MOP) Reference ....... 4-8
4.1.7 Configuring the Preset Speed References.......................................... 4-11
4.2 Configuring Trim ............................................................................................ 4-13
4.3 Speed Reference Ramp ................................................................................ 4-16
4.3.1 Configuring the Speed Reference Ramp ............................................ 4-18
4.4 Final Speed Reference Logic ........................................................................ 4-23
4.4.1 Configuring Jog ................................................................................... 4-25
4.4.2 Configuring Current Compounding...................................................... 4-28
Chapter 5
Configuring the Speed/Voltage Loop
5.1 Configuring the Speed Loop Scan Time.......................................................... 5-2
5.2 Configuring the Speed Loop Feedback ........................................................... 5-3
5.2.1 Configuring Armature Voltage Feedback .............................................. 5-3
5.2.2 Configuring AC or DC Analog Tachometer Feedback .......................... 5-6
5.2.3 Configuring the Pulse Encoder Feedback............................................. 5-9
5.2.4 Configuring Speed Loop Feedback Lead/Lag Block ........................... 5-11
5.3 Reading the Speed Loop Error Signal ........................................................... 5-12
5.4 Configuring the Speed Loop Forward Path Lag Block .................................. 5-13
5.5 Configuring the Speed Loop Current Limits .................................................. 5-14
5.6 Configuring the Speed Loop PI Block............................................................ 5-17
5.7 Configuring Parameters for Winding Applications ......................................... 5-20
I
Chapter 6
Configuring the Current Minor Loop
6.1 Configuring Inertia Compensation....................................................................6-2
6.2 Selecting and Conditioning CML Reference Selection ....................................6-3
6.3 Configuring the Armature Current Feedback ...................................................6-6
6.4 Configuring the CML Forward Path..................................................................6-9
Chapter 7
Configuring the Metering Outputs
Chapter 8
Configuring the Field Supply
8.1 Configuring Field Economy ..............................................................................8-2
8.2 Configuring the Enhanced Field Supply...........................................................8-4
8.3 Configuring the Field Current Regulated Supply..............................................8-5
8.3.1 Configuring Automatic Field Weakening................................................8-8
Chapter 9
Configuring the Outer Control Loop
9.1 Enabling the Outer Control Loop......................................................................9-2
9.2 Outer Control Loop Signal Processing.............................................................9-4
9.2.1 Configuring the OCL Reference Path ....................................................9-4
9.2.2 Configuring the Outer Control Loop Forward Path ................................9-6
9.3 Configuring the Outer Control Loop Feedback Path ........................................9-9
Chapter 10
Configuring a Network
10.1 Configuration for All Networks........................................................................10-2
10.2 Configuring Parameters for DeviceNet ..........................................................10-7
10.3 Configuring Parameters for the AutoMax Network.........................................10-8
10.4 Configuring Parameters for the ControlNet Network......................................10-9
Chapter 11
Configuring Parameters for the I/O Expansion Kit
11.1 Configuring the Digital Outputs ......................................................................11-2
11.2 Configuring the Analog Inputs........................................................................11-5
11.3 Configuring the Analog Outputs .....................................................................11-8
11.4 Configuring the Frequency Input..................................................................11-10
11.5 Configuring the Frequency Output ...............................................................11-11
Chapter 12
Configuring the Drive to Use Level Detectors
Chapter 13
Troubleshooting the FlexPak 3000 Drive
13.1 Fault and Alarm Messages, Descriptions, and Code Numbers .....................13-1
13.2 Adjusting the Tachometer or Encoder Loss Sensitivity................................13-12
13.3 Phase Locked Loop (PLL) Maximum Error ..................................................13-13
13.4 SCR Diagnostics and Adjusting Open SCR Sensitivity................................13-14
13.5 Armature Phase Fire Test ............................................................................13-16
13.6 Setting Reversed Tachometer or Reversed Encoder Lead Detection .........13-19
13.7 Setting Up Inverting Fault Avoidance...........................................................13-20
13.8 Checking the AC Line Period and Voltage...................................................13-22
13.9 Checking Drive Information..........................................................................13-23
Appendix A Block Diagrams ........................................................................................................ A-1
Appendix B New Features in Version 4.3.................................................................................... B-1
Appendix C Parameter Settings Record...................................................................................... C-1
II
FlexPak 3000 DC Drive Software Reference
Appendix D Numeric Parameter List ............................................................................................D-1
Contents
Glossary
...................................................................................................................... Glossary-1
Index
........................................................................................................................... Index-1
III
IV
FlexPak 3000 DC Drive Software Reference
List of Figures
Figure 1.1 – Block Diagram of the FlexPak 3000 Drive............................................ 1-2
Figure 2.1 – Drive Sequencing Overview ................................................................. 2-1
Figure 4.1 – Speed Reference Overview.................................................................. 4-1
Figure 4.2 – Speed Reference Source Select Block Diagram.................................. 4-3
Figure 4.3 – MOP Block Diagram ............................................................................. 4-9
Figure 4.4 – Preset Speed Block Diagram ............................................................. 4-11
Figure 4.5 – Speed Reference Ramp Block Diagram............................................. 4-17
Figure 4.6 – S-Curve Rounding .............................................................................. 4-21
Figure 4.7 – Speed Reference Mode Select Block Diagram .................................. 4-23
Figure 5.1 – Speed Loop Block Diagram.................................................................. 5-1
Figure 5.2 – Armature Voltage Block Diagram ......................................................... 5-3
Figure 5.3 – AC or DC Analog Tachometer Feedback Block Diagram..................... 5-6
Figure 5.4 – Pulse Encoder Feedback Block Diagram ............................................. 5-9
Figure 6.1 – Current Minor Loop Reference Path Block Diagram ............................ 6-1
Figure 6.2 – Current Minor Loop Block Diagram ...................................................... 6-6
Figure 7.1 – Metering Outputs Block Diagram......................................................... 7-1
Figure 8.1 – Field Block DIagram if Field Current Regulator Kit is Installed............. 8-5
Figure 9.1 – Outer Control Loop Block Diagram....................................................... 9-1
Figure 9.2 – Outer Control Loop Enable Logic ......................................................... 9-2
Figure 9.3 – OCL Reference Signal Rounding ......................................................... 9-6
Figure 11.1 – Digital Outputs Block Diagram.......................................................... 11-2
Figure 11.2 – Analog Inputs Block Diagram ........................................................... 11-5
Figure 11.3 – Analog and Frequency Outputs Block Diagram ............................... 11-8
Figure 11.4 – Frequency Input Block Diagram ..................................................... 11-10
Figure 12.1 – Level Detectors Block Diagram ........................................................ 12-1
Figure 13.1 – SCR Armature Current During Normal Operation .......................... 13-14
Figure 13.2 – Load SCRs Fail to Turn On ............................................................ 13-15
Figure 13.3 – Thyristors Fail to Conduct............................................................... 13-17
Contents
V
VI
FlexPak 3000 DC Drive Software Reference
List of Tables
Table 4.1 – Effect of Control Source and Reference Settings .................................. 4-2
Table 4.2 – Preset Speed Reference Selections.................................................... 4-11
Table 4.3 – Conditions Indicated by DIG IN 0 (P.490).............................................. 4-25
Table 7.1 – Options for Metering Parameters .......................................................... 7-4
Table 9.1 – OCL Enable Signal Source.................................................................... 9-2
Table 9.2 – Conditions Indicated by DIG IN 0 (P.490)................................................ 9-3
Table 11.1 – Options for Metering Parameters .................................................... 11-12
Table 13.1 – Fault Codes ...................................................................................... 13-1
Table 13.2 – Alarm Codes ..................................................................................... 13-9
Table 13.3 – Inverting Fault Avoidance Settings ................................................. 13-21
Contents
VII
VIII
FlexPak 3000 DC Drive Software Reference
CHAPTER 1
Introduction
1.1
Before You Start
This manual assumes that the hardware has already been installed. See the
FlexPak 3000 drive hardware manual, D2-3404, for detail.
Important: Before operating the drive, you must perform Quick Start and the
self-tuning procedure, described in the OIM manual. Quick Start lets you
configure the most commonly used parameters through one menu and
includes self-tuning. This helps you set up the drive as quickly as
possible.
See the OIM manual for information on configuring parameters and using Quick Start.
1.2
Where to Find Information
This manual describes the software of the FlexPak 3000 DC drive. It does not
describe hardware or the operator interface. To find information on:
•
Hardware, including installation and wiring information: See D2-3404,
FlexPak 3000 DC Drive Hardware Reference.
•
The Operator Interface Module (OIM), including setting parameters, saving
parameters, and using Quick Start: See D2-3344, FlexPak 3000 Drive Operator
Interface Module (OIM) User Guide.
•
Kits: See the instruction manual supplied with the kit.
This manual groups parameters by function. To find a specific parameter, see the
index or Appendix D, Numeric Parameter List, for a list of parameters with their page
numbers.
As you change parameter values, you can record them using the table in Appendix C,
Parameter Settings Record.
1.3
Conventions
Parameter names: In most instances, parameter names are shown as the parameter
name followed by the parameter number. For example: ACCELERATION TIME (P.001).
For text parameter options, the options are shown in all caps. For example: TERMBLK.
Introduction
1-1
1.4
Getting Assistance from Reliance Electric
If you have any questions or problems with the products described in this instruction
manual, contact your local Reliance Electric sales office. For technical assistance, call
1-800-726-8112.
1.5
Drive Description
The FlexPak 3000 drive is a full-wave power converter without back rectifier, complete
with a digital current minor loop and a digital major loop for armature voltage or speed
regulation by tachometer or encoder feedback. Figure 1.1 shows the block diagram of
the drive.
The drive employs a wireless construction and uses a keypad (OIM) for drive setup,
including parameter adjustments and measurement unit selection, monitoring, and
diagnostics. Multiple language capability in English, French, German, Spanish, and
Italian is built-in. Reference, feedback, and metering signals can be interfaced to the
drive.
The drive can be controlled:
•
Locally by the Operator Interface Module (OIM).
•
Remotely by using the terminals at the Regulator board terminal strip.
•
Remotely by the CS3000 software or a an optional network kit (AutoMax,
ControlNet, or others).
The reference source (KEYPAD, TERMBLK, NETWORK, or SERIAL) can be selected
through the OIM.
Figure 1.1 – Block Diagram of the FlexPak 3000 Drive
1-2
FlexPak 3000 DC Drive Software Reference
CHAPTER 2
Drive Sequencing
This chapter describes run, jog, and stop sequencing of the FlexPak 3000 drive.
Figure 2.1 shows an overview of the sequencing of the drive.
To Figure 4.5, Speed
Reference Ramp Block
Diagram, and Figure 4.7,
Speed Reference Mode Select
Block Diagram
To Figure 4.7, Speed
Reference Mode Select Block
Diagram
To Figure 6.1, Current Minor
Loop Reference Path Block
Diagram
To Figure 4.7, Speed
Reference Mode Select Block
Diagram
To Figure 4.7, Speed
Reference Mode Select Block
Diagram
To Figure 4.5, Speed Reference
Ramp Block Diagram, and
Figure 4.7, Speed Reference
Mode Select Block Diagram
To fault processing
To Figure 4.2, Speed
Reference Source Select Block
Diagram, and Figure 4.7,
Speed Reference Mode Select
Block Diagram
Figure 2.1 – Drive Sequencing Overview
Drive Sequencing
2-1
2.1
Run and Jog Sequencing
When powered, the drive is in one of three operating states:
• armature not active (main contactor open)
• run mode
• jog mode
The drive is in run mode if it was started by the RUN input. It remains in run mode until
the completion of a stop sequence.
Important: The drive is in jog mode if it was started by the JOG input. It remains in jog
mode until the completion of a stop sequence or until the RUN input is
asserted. If the RUN input is asserted, the drive switches from jog mode to
run mode. You cannot switch from run mode to jog mode by asserting the
JOG input. You must stop the drive before switching to jog mode.
If you switch from jog mode to run mode, the drive accelerates or decelerates to the
selected run reference as configured by ACCELERATION TIME (P.001) or DECELERATION
TIME (P.002).
2.2
Stop Sequencing
!
ATTENTION: The user must provide an external, hardwired emergency
stop circuit outside of the drive circuitry. This circuit must disable the
system in case of improper operation. Uncontrolled machine operation
can result if this procedure is not followed. Failure to observe this
precaution could result in bodily injury.
The FlexPak 3000 drive can be stopped by:
• Asserting an active stop input
• Opening a permissive input (coast/DB interlock or customer interlock)
• Deasserting the jog input if the drive is in jog mode. Deasserting the jog input will
not initiate the stop sequence until the speed feedback is less than or equal to STOP
SPEED THRESHOLD (P.113) or until the JOG OFF DELAY TIME (P.121) is exceeded,
whichever occurs last.
• Detecting a fault condition
There are three types of stop sequences: Coast/DB, ramp, and current limit. The type
of stop sequence used depends on the source of the stop and your parameter
configuration, as described below.
If a run or jog command is received while the drive is in a ramp or current limit stop
sequence, the stop sequence will be aborted and the drive will continue running or
jogging. Coast/DB stop sequences cannot be aborted.
2-2
FlexPak 3000 DC Drive Software Reference
Coast/DB Stop Sequencing
Coast/DB stop sequencing is used when one of these conditions occurs:
• an active stop input is asserted and STOP MODE SELECT (P.114) is set to COAST/DB
• a permissive input is opened
• a fault condition is detected
In a coast/DB stop sequence:
1. Armature firing angle is forced to a small non-zero value.
2. The drive waits until armature current reaches discontinuous conduction.
3. The main contactor is opened and the DB contactor is closed.
Ramp Stop Sequencing (Run Mode)
Run mode ramp stop sequencing is used when all of these conditions exist:
• an active stop input is asserted
•
STOP MODE SELECT
(P.114) is set to RAMP STOP
• the drive is in run mode
In a ramp stop sequence from run mode:
1. A zero reference is input to the S-curve block.
2. The speed reference ramps toward zero at the rate set by DECELERATION TIME
(P.002) or RAMP STOP DECEL TIME (P.018) (as determined by the setting of STOP
DECEL SELECT (P.122)).
3. The drive waits until speed feedback falls below STOP SPEED THRESHOLD (P.113).
4. A zero reference is input to the current minor loop reference path.
5. The drive waits until armature current reaches discontinuous conduction.
6. The main contactor is opened and the DB contactor is closed.
Ramp Stop Sequencing (Jog Mode)
In jog mode, ramp stop sequencing is used when all of these conditions exist
•
STOP MODE SELECT
(P.114) is set to RAMP STOP
• the drive is in jog mode
• the jog input is deasserted
• Speed feedback is less than or equal to STOP SPEED THRESHOLD (P.113) or JOG OFF
DELAY TIME
(P.121) is exceeded, whichever occurs last
In a ramp stop sequence from jog mode:
1. A zero reference is input to the jog reference ramp block.
2. The jog reference ramps toward zero at the rate set by JOG ACCEL/DECEL TIME
(P.013).
3. The drive waits until speed feedback falls below STOP SPEED THRESHOLD (P.113).
Drive Sequencing
2-3
4. A zero reference is input to the current minor loop reference path.
5. The drive waits until armature current reaches discontinuous conduction.
6. The main contactor is opened and the DB contactor is closed.
Current Limit Stop Sequencing
Current limit stop sequencing is used when one of these conditions occurs:
• an active stop input is asserted, STOP MODE SELECT (P.114) is set to CURRENT LIMIT,
and the drive is in run mode
• the jog input is deasserted when the drive is in jog mode and STOP MODE SELECT
(P.114) is set to CURRENT LIMIT. Deasserting the jog input will not initiate the stop
sequence until the speed feedback is less than or equal to STOP SPEED THRESHOLD
(P.113) or until the JOG OFF DELAY TIME (P.121) is exceeded, whichever occurs last.
In a current limit stop sequence:
1. From run mode: A zero reference is input to the speed loop reference path at the
speed loop summing junction.
From jog mode: A zero reference is input to the jog reference ramp block.
2. Jog mode only: The jog reference ramps toward zero at the rate set by JOG
ACCEL/DECEL TIME (P.013).
3. The drive waits until speed feedback falls below STOP SPEED THRESHOLD (P.113).
If the drive is regenerative (S6R), this phase of the current limit stop sequence
takes little time. If the drive is non-regenerative (S6), the motor coasts during this
phase of the current limit stop sequence.
4. A zero reference is input to the current minor loop reference path.
5. The drive waits until armature current reaches discontinuous conduction.
6. The main contactor is opened and the DB contactor is closed.
2-4
FlexPak 3000 DC Drive Software Reference
CHAPTER 3
Initial Configuration
This chapter describes settings you might need to make when initially starting your
drive, including selecting a control source and changing the settings of the AC line
parameters. Before using the parameters in this chapter, perform Quick Start (see the
OIM manual for detail).
3.1
Selecting a Control Source
The control source determines the source of drive control signals. Control signals
include drive operating signals, such as run and jog, and the drive reference.
You can select the control source on the OIM using the front panel key (
your OIM manual.
CONTROL SOURCE
(P.000)
Selects the source of
the drive control
signals.
Parameter Range:
). See
KEYPAD
SERIAL
TERMBLK
NETWORK
Default Setting:
KEYPAD
Parameter Type:
Configurable
OIM Menu Path(s):
On OIM keypad:
If the drive is configured as a current (torque) regulator (jumper J15 is set to
the control source can only be set to TERMBLK or NETWORK.
CURRENT),
The possible control sources are:
•
•
KEYPAD:
Control is through the keypad.
TERMBLK: Control is through Regulator board terminals 16 through 20. See the
hardware manual for terminal descriptions and wiring instructions.
•
NETWORK:
•
SERIAL:
Control is through a network such as the AutoMax Network
Communication kit, DeviceNet Interface kit, or ControlNet Network Communication
kit.
Control is through a personal computer running the CS3000 software.
Important: When switching the control source from NETWORK to any other option,
the internal multiplexor selection parameters that use NETW IN REG 1, 2,
and 3, are not affected. Therefore, any selection that was set to NETW IN
REG# will remain, and the data in NETW IN REG 1, 2, 3 will be the value
used in the control path. (Note that these parameters contain the last
data received from the network before the control source was switched
and will no longer be updated from the network.) To change this, you
must reconfigure any affected selection parameters.
Initial Configuration
3-1
3.2
Configuring the AC Line Parameters
In addition to performing Quick Start, you might need to configure the AC line
parameters for your application. Generally, you only need to configure these
parameters if the default values for these parameters are incorrect for your application.
These parameters should be configured before completing Quick Start. See the OIM
manual for information on Quick Start.
NOMINAL AC LINE FREQ
The nominal AC line
frequency (typically
50 or 60 Hz).
(P.306)
Parameter Range:
48 to 62 Hz
Default Setting:
60 Hz
Parameter Type:
Configurable
OIM Menu Path(s):
Current Minor Loop (CML) - Three Phase
AC Line
NOMINAL AC LINE VOLTS
The nominal AC line
RMS voltage.
3-2
(P.307)
Parameter Range:
200 to 575 VAC
Default Setting:
230 VAC
Parameter Type:
Configurable
OIM Menu Path(s):
Current Minor Loop (CML) - Three Phase
AC Line
FlexPak 3000 DC Drive Software Reference
3.3
Self-Tuning Parameters
See the OIM manual for detail on using self-tuning and the self-tuning parameters.
SELF TUNE BRIDGE
Determines the
direction the motor
shaft will rotate
during the speed loop
self-tune process by
selecting the SCR
bridge. If the reverse
bridge will be
predominant in the
application, select
REVERSE.
(P.220)
Parameter Range:
FORWARD
REVERSE
Default Setting:
FORWARD
Parameter Type:
Tunable
OIM Menu Path(s):
Current Minor Loop (CML) - Tuning - Self Tuning
Setup
Speed/Voltage Loop (SPD) - Tuning - Self Tuning
Setup
For non-regenerative (S6) drives, this is fixed to FORWARD.
Must be set before starting speed loop self-tuning.
SELF TUNE FIELD RANGE
Ratio of motor top
speed to base speed.
Typical value is 1.00,
where TOP SPEED
(P.011) is equal to
base speed. Applies
to speed loop tuning
only.
(P.218)
Parameter Range:
0.90 to 5.00
Default Setting:
1.00
Parameter Type:
Tunable
OIM Menu Path(s):
Current Minor Loop (CML) - Tuning - Self Tuning
Setup
Speed/Voltage Loop (SPD) - Tuning - Self Tuning
Setup
Must be set before starting speed loop self-tuning.
Initial Configuration
3-3
SELF TUNE STABILITY
Determines the
self-tune stability,
which configures the
performance of the
speed loop.
(P.219)
Parameter Range:
10 to 100
Default Setting:
25
Parameter Type:
Tunable
OIM Menu Path(s):
Current Minor Loop (CML) - Tuning - Self Tuning
Setup
Speed/Voltage Loop (SPD) - Tuning - Self Tuning
Setup
Low values increase the speed loop response. High values decrease the speed
response, but result in more stability. The typical value is 25. This parameter
applies to speed loop tuning only.
Must be set before starting speed loop self-tuning.
3-4
FlexPak 3000 DC Drive Software Reference
CHAPTER 4
Configuring the Speed Reference
The FlexPak 3000 drive can be configured as a speed regulator or as an armature
voltage regulator, depending on the value of FEEDBACK SELECT (P.200). In this chapter,
the phrase “speed loop” refers to either configuration unless otherwise noted.
The drive can also be configured as either a speed/voltage or current regulator. If the
drive is to be configured as a current regulator, skip this chapter and see Chapter 6.
The speed reference is the speed the speed loop tries to maintain. The drive
processes and scales the speed reference input for use by the speed loop.
The speed loop uses the selected reference value and attempts to keep the speed
feedback from the motor equal to the reference value. If the feedback is less than the
reference, the speed loop increases the motor speed by commanding more current to
the motor. If the reference is less than the feedback, the speed loop decreases the
motor speed by commanding less current to the motor. The speed loop tries to
minimize the amount of error between the speed reference and the speed feedback.
The speed and accuracy with which the speed loop responds to reference or motor
load changes is determined by the speed loop parameters.
Processing the speed reference consists of three major blocks, shown in figure 4.1.
To Figure 6.2,
Current Minor Loop
Block Diagram
(Figure 9.1)
To Figure 5.1,
Speed Loop Block
Diagram
(Figure 4.5)
(Figure 4.2)
(Figure 4.7)
Figure 4.1 – Speed Reference Overview
In the speed reference source select block, the selected reference is scaled and the
amplitude is limited. See section 4.1.
In the speed reference ramp block, the reference value from the speed reference
source select block is modified based on your parameter settings. For example, trim
and rate limiting are applied. See section 4.3.
In the speed reference mode select block, the ramped speed reference signal is
summed with current compounding and outer control loop outputs. See section 4.3.
Configuring the Speed Reference
4-1
4.1
Configuring the Speed Reference Source Block
The speed reference can be either automatic or manual. An automatic (auto)
reference usually comes from a device such as a PLC or a network master. A manual
reference typically comes from a speed potentiometer or the OIM keypad. See the OIM
manual for information on auto and manual references.
!
ATTENTION: When switching from auto to manual or from manual to
auto, the drive will ramp to the reference level provided by the new source
at the rate specified by ACCELERATION TIME (P.001) or DECELERATION TIME
(P.002). Be aware that an abrupt speed change might occur, depending
on the new reference and the rate specified in these parameters. Failure
to observe this precaution could result in bodily injury.
If an I/O Expansion kit is installed, the selected speed reference can be overridden by
a preset speed reference if selected (terminals 59 and 60). See section 4.1.7.
Table 4.1 shows the possible control source and reference source settings. It also
shows the display for the key indicator under
.
Most systems will use one primary reference source. For example, you might use a
network for your reference most of the time, but have the terminal strip reference
available for occasions when the network is not running or for troubleshooting.
The block diagram for the speed reference source is shown in figure 4.2.
Table 4.1 – Effect of Control Source and Reference Settings
Control Source
KEYPAD
Reference Set Through:
Automatic reference from the
terminal strip as set by AUTO
REFERENCE SELECT (P.103)
OIM
TERMBLK
(Regulator type is
speed/voltage)
Automatic reference from the
terminal strip as set by AUTO
REFERENCE SELECT (P.103)
Manual reference from the
terminal strip as set by
MANUAL REF SELECT (P.106)
SERIAL
Automatic reference from the
terminal strip as set by AUTO
REFERENCE SELECT (P.103)
Serial device (PC)
NETWORK
Network
OIM
Key Indicator
OIM Reference Display
(Monitor Mode)
AUTO
TERMBLK REF
MANUAL
KEYPAD REF
AUTO
TERMBLK REF
TERMBLK
4-2
Automatic reference from the
terminal strip as set by AUTO
REFERENCE SELECT (P.103)
RPM,
percentage,
or
user-defined
units
MANUAL
AUTO
MANUAL
SERIAL REF
AUTO (Manual
NETWORK REF
not available)
(Regulator type is
current/torque)
Units
AUTO (Manual
not available)
TORQUE REF
From
network
MOTOR LOAD
units
FlexPak 3000 DC Drive Software Reference
Figure 4.2 – Speed Reference Source Select Block Diagram
Configuring the Speed Reference
4-3
From Figure 11.2, Analog
Inputs Block Diagram
From Figure 11.4,
Frequency Input
Block Diagram
To Figure 4.5, Speed
Reference Ramp Block
Diagram
To Figure 4.5, Speed
Reference Ramp Block
Diagram
To Figure 6.1, Current
Minor Loop Reference
Path Block Diagram
4.1.1 Configuring the Keypad (OIM) Speed Reference
must be set to KEYPAD to use the keypad reference. When manual
mode is selected, you enter the speed reference manually through the OIM. See the
OIM manual for information on setting the speed reference through the OIM.
CONTROL SOURCE
The keypad reference cannot be configured to less than MINIMUM SPEED (P.003) or
greater than MAXIMUM SPEED (P.004). The default value of the keypad reference is
MINIMUM SPEED (P.003).
!
ATTENTION: When switching from auto to manual or from manual to
auto, the drive will ramp to the reference level provided by the new source
at the rate specified by ACCELERATION TIME (P.001) or DECELERATION TIME
(P.002). Be aware that an abrupt speed change might occur, depending
on the new reference and the rate specified in these parameters. Failure
to observe this precaution could result in bodily injury.
4.1.2 Configuring the Analog Auto Reference
CONTROL SOURCE must be set to TERMBLK, SERIAL, or KEYPAD to use the analog auto
input as a speed reference. When you use this speed reference, the signal is the
analog auto reference from terminals 19(+) and 20(–) of the Regulator board. Note
that this input can also be used as a current reference to the current minor loop.
You must specify the type of signal that is at terminals 19 and 20 by setting ANLG AUTO
SIGNAL TYPE (P.100) and jumpers J10 and J12 on the Regulator board. The settings of
ANLG AUTO SIGNAL TYPE (P.100) and the jumpers must be the same. See the hardware
manual for information on setting the jumpers.
The drive used the ANLG AUTO GAIN ADJ (P.101), ANLG AUTO SIGNAL TYPE (P.100), and
ANLG AUTO ZERO ADJ (P.102) to scale the analog auto reference signal from terminal 19
and 20 of the Regulator board to produce the ANALOG AUTO REFERENCE (P.188) signal.
ANALOG AUTO REFERENCE
The analog reference
value in auto mode.
This is the value
output by the drive
after all hardware and
software scaling.
4-4
(P.188)
Parameter Range:
n/a
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Drive Reference - Drive Reference Scaling
Drive Reference - Test Points
FlexPak 3000 DC Drive Software Reference
ANLG AUTO GAIN ADJ
Scales the analog
auto reference signal
after it is conditioned
by the drive
hardware.
(P.101)
Parameter Range:
0.750 to 1.250
Default Setting:
1.000
Parameter Type:
Tunable
OIM Menu Path(s):
Drive Reference - Drive Reference Scaling
Typically, this parameter is set to 1.000.
Example
If ANLG AUTO SIGNAL TYPE (P.100) is set to 0-10V, a 0 to 8.2VDC signal produces
only 82% of the drive’s full scale value. To produce the drive’s full scale value,
change ANLG AUTO GAIN ADJ to properly scale the signal to 1.22
10
 ------- = 1.22
 8.2

.
Important: Adjust the zero point (ANLG AUTO ZERO ADJ (P.102)) before setting the
gain adjust.
ANLG AUTO SIGNAL TYPE
Selects the type of
signal applied to the
drive analog auto
reference input. This
is the signal at
terminals 19 and 20
on the Regulator
board.
(P.100)
Parameter Range:
0–10V
+/–10V
4-20mA
10-50mA
Default Setting:
0–10V
Parameter Type:
Configurable
OIM Menu Path(s):
Drive Reference - Drive Reference Configure
Important: Jumpers J10 and J12 must be set for the type of analog auto reference
selected. See the hardware manual for instruction.
ANLG AUTO ZERO ADJ
Removes any offset
from the analog auto
reference signal.
(P.102)
Parameter Range:
–200 to 200
Default Setting:
0
Parameter Type:
Tunable
OIM Menu Path(s):
Drive Reference - Drive Reference Scaling
If ANALOG AUTO REFERENCE (P.188) is not equal to zero when the analog auto
reference signal is set to its minimum value (for example, 0 volts or 4mA), adjust
ANLG AUTO ZERO ADJ up or down until ANALOG AUTO REFERENCE (P.188) equals zero.
Configuring the Speed Reference
4-5
AUTO REFERENCE SELECT
AUTO REFERENCE
SELECT determines
(P.103)
Parameter Range:
if
the drive uses a
frequency or analog
input reference
source when the
drive is in AUTO mode
and CONTROL SOURCE
is set to KEYPAD,
TERMBLK, or SERIAL.
ANALOG
FREQUENCY IN
Default Setting:
ANALOG
Parameter Type:
Configurable
OIM Menu Path(s):
Drive Reference - Drive Reference Configure
When AUTO REFERENCE SELECT is set to FREQUENCY IN, the reference is from the
frequency input (terminals 39, 40, and 41 on the I/O Expansion kit).
When AUTO REFERENCE SELECT is set to ANALOG, the reference is from the analog
auto input (terminals 19 and 20 on the Regulator board).
If the I/O Expansion kit is not installed, this parameter is automatically configured to
ANALOG and cannot be changed.
4.1.3 Configuring the Analog Manual Reference
must be set to TERMBLK to use the analog manual reference input as
a speed reference. This reference can only be used when the drive is configured as a
speed regulator and MANUAL REF SELECT (P.106) is set to ANALOG.
CONTROL SOURCE
When you use this speed reference, the drive uses the analog manual reference from
terminals 16(+10V), 17(+), and 18(–) of the Regulator board.
The software uses the parameters described in this section to scale the analog
manual reference signal at terminal 16, 17, and 18 to produce the ANALOG MAN
REFERENCE (P.192) signal.
The analog manual reference input can also be used for the trim reference. Make sure
they are not being used for both functions at the same time.
ANALOG MAN REFERENCE
The analog reference
value in manual
mode. This is the
value output by the
drive after all
hardware and
software scaling.
(P.192)
Parameter Range:
n/a
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Drive Reference - Drive Reference Scaling
Drive Reference - Drive Reference Test Points
This parameter is only used when the drive is configured as a speed/voltage
regulator.
4-6
FlexPak 3000 DC Drive Software Reference
ANLG MAN REF GAIN ADJ
Scales the analog
manual speed
reference signal after
it is conditioned by
the drive hardware.
(P.104)
Parameter Range:
0.750 to 1.250
Default Setting:
1.000
Parameter Type:
Tunable
OIM Menu Path(s):
Drive Reference - Drive Reference Scaling
Typically, this parameter is set to 1.000.
Important: Adjust the zero point (ANLG MAN REF ZERO ADJ (P.105)) before setting
the gain adjust.
ANLG MAN REF ZERO ADJ
Removes any offset
from the analog
manual reference
signal.
(P.105)
Parameter Range:
–200 to 200
Default Setting:
0
Parameter Type:
Tunable
OIM Menu Path(s):
Drive Reference - Drive Reference Scaling
If ANALOG MAN REFERENCE (P.192) is not equal to zero when 0 volts is applied to
terminal 17 on the Regulator board, adjust the analog auto reference signal is set to
its minimum value (for example, 0 volts or 4mA), adjust ANLG MAN ZERO ADJ up or
down until ANALOG MAN REFERENCE (P.192) equals zero.
MANUAL REF SELECT
Sets the source of
the reference for the
speed loop when the
drive is in manual
mode and CONTROL
SOURCE is set to
TERMBLK.
(P.106)
Parameter Range:
ANALOG
MOP
Default Setting:
ANALOG
Parameter Type:
Configurable
OIM Menu Path(s):
Drive Reference - Drive Reference Configure
When set to ANALOG, the analog MANUAL reference input (terminals 16, 17 and 18
on the Regulator board) is the speed reference.
When set to MOP, MOP OUTPUT (P.191) is the speed reference. This reference can
be adjusted through terminals 62 and 63 on the I/O Expansion kit. See the I/O
Expansion kit manual for more information.
If the I/O Expansion kit is not installed, the parameter value is fixed to ANALOG.
Configuring the Speed Reference
4-7
4.1.4 Configuring the Serial Speed Reference
must be set to SERIAL (in the FlexPak 3000 drive or through the
CS3000 software) and AUTO/MANUAL must be set to MANUAL to use the serial speed
reference.
CONTROL SOURCE
If you are using the serial reference from a source such as the CS3000 software, the
reference is input directly from the serial source to the speed reference ramp. The only
parameter related to the serial speed reference is SPD SOURCE SELECT OUT (P.193).
You can use this parameter to check the reference value.
4.1.5 Configuring the Network Speed Reference
CONTROL SOURCE must be set to NETWORK to use the network speed reference. When
the control source is NETWORK, the drive is forced into automatic mode.
The only parameter related to the network speed reference is SPD SOURCE SELECT OUT
(P.193). You can use this parameter to check the reference value.
4.1.6 Configuring the Motor-Operated Potentiometer (MOP) Reference
The MOP function can be used as a manual reference for the speed loop. To use the
MOP function:
• The I/O Expansion kit must be installed.
•
CONTROL SOURCE
•
MANUAL REF SELECT
must be set to TERMBLK.
(P.106) must be set to MOP.
• Switches must be attached to digital inputs 3 and 4 (terminals 63 and 64) of the I/O
Expansion kit. These inputs decrement and increment, respectively, the MOP OUTPUT
(P.191) value.
• The MOP block is shown in figure 4.3.
The MOP output is incremented when digital input 4 (terminal 63) is ON and
decremented when digital input 3 (terminal 62) is ON. MOP OUTPUT is limited between
MAXIMUM SPEED (P.004) and MINIMUM SPEED (P.003). If both digital inputs are ON at the
same time, the MOP output remains at its present value.
(P.115) and MOP DECEL TIME (P.120) set the time in which the MOP
can change from zero to TOP SPEED and vice versa. To prevent the S-curve
block from limiting the rate of change from the MOP OUTPUT, MOP ACCEL TIME has a low
limit equal to ACCELERATION TIME. MOP DECEL TIME has a low limit equal to
DECELERATION TIME.
MOP ACCEL TIME
OUTPUT
To obtain a negative MOP reference, the reverse direction must be selected.
When MOP RESET ENABLE is ON, the MOP output goes to MINIMUM SPEED at the moment
when the drive is stopped following a run or jog. If it is OFF, the MOP OUTPUT remains at
its present level when the drive is stopped. MOP RESET ENABLE also affects the
operation of the keypad reference, even if the I/O Expansion kit is not installed.
4-8
FlexPak 3000 DC Drive Software Reference
To Figure 4.2, Speed
Reference Source
Select Block Diagram
* Default Selection
To Figure 4.2, Speed
Reference Source
Select Block Diagram
Figure 4.3 – MOP Block Diagram
DIG IN
3 (P.497)
The state of digital
input 3 (terminal 62
on the I/O Expansion
kit), which is the MOP
decrement input.
Parameter Range:
ON
OFF
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Input/Output - Digital I/O
The input is ON when +24VDC is applied for more than 10 msec. It is OFF when
0VDC is applied.
DIG IN
4 (P.498)
The state of digital
input 4 (terminal 63
on the I/O Expansion
kit), which is the MOP
increment input.
Parameter Range:
ON
OFF
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Input/Output - Digital I/O
The input is ON when +24VDC is applied for more than 10msec. It is OFF when
0VDC is applied.
Configuring the Speed Reference
4-9
MOP ACCEL TIME
Minimum time in
which MOP OUTPUT
can change from zero
to TOP SPEED.
MOP DECEL TIME
Minimum time in
which MOP OUTPUT
can change from TOP
SPEED to zero.
MOP OUTPUT
(P.115)
Parameter Range:
ACCELERATION TIME
Default Setting:
5.0 seconds
Parameter Type:
Tunable
OIM Menu Path(s):
Drive Reference - Drive Reference Ramp
to 300.0 seconds
(P.120)
Parameter Range:
DECELERATION TIME
Default Setting:
5.0 seconds
Parameter Type:
Tunable
OIM Menu Path(s):
Drive Reference - Drive Reference Ramp
to 300.0 seconds
(P.191)
The output of the
motor-operated
potentiometer (MOP).
Parameter Range:
MINIMUM SPEED
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Drive Reference - Drive Reference Test Points
to MAXIMUM SPEED
To get a negative MOP reference, the reverse direction must be selected.
If the I/O Expansion kit is not installed, MOP OUTPUT is meaningless.
MOP RESET ENABLE
Determines if MOP
OUTPUT (P.191) and
the keypad reference
values reset or stay
at the present level
when the drive stops.
(P.116)
Parameter Range:
OFF
ON
Default Setting:
OFF
Parameter Type:
Configurable
OIM Menu Path(s):
Drive Reference - Drive Reference Configure
When MOP RESET ENABLE is set to ON (enabled), MOP OUTPUT and the keypad
reference are reset to MINIMUM SPEED (P.003) when the drive is stopped, even if the
I/O Expansion kit is not installed. If it is set to OFF (disabled), MOP OUTPUT and the
keypad reference remain at their present levels when the drive is stopped.
4-10
FlexPak 3000 DC Drive Software Reference
4.1.7 Configuring the Preset Speed References
These parameters are only available if the I/O Expansion kit is installed.
The three preset speed references override the auto or manual speed/voltage loop
reference when CONTROL SOURCE is set to TERMBLK. Preset speed references are
selected using one or two digital inputs. When both digital inputs are in the OFF state,
no preset speed is selected. When one or both digital inputs are in the ON state, one of
the three preset speed references is selected as shown in table 4.2.
Table 4.2 – Preset Speed Reference Selections
Digital Input 1
(Terminal 59)
Digital Input 2
(Terminal 60)
OFF
OFF
Selected auto or manual reference
OFF
ON
PRESET SPEED
1 (P.117)
ON
OFF
PRESET SPEED
2 (P.118)
ON
ON
PRESET SPEED
3 (P.119)
Speed/Voltage Loop Reference
To Figure 4.5, Speed
Reference Ramp Block
Diagram
From Figure 4.2, Speed
Reference Source Select
Block Diagram
* Default Selection
Figure 4.4 – Preset Speed Block Diagram
DIG IN
1 (P.495)
The state of digital
input 1 (terminal 59
on the I/O Expansion
kit).
Parameter Range:
ON
OFF
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Input/Output - Digital I/O
Digital inputs 1 and 2 (terminals 59 and 60) select which, if any, PRESET SPEED is
used as the reference for the speed/voltage control loop.
The input is ON when +24 VDC is applied for more than 10 msec. It is OFF when
0VDC is applied.
Configuring the Speed Reference
4-11
DIG IN
2 (P.496)
The state of digital
input 2 (terminal 60
on the I/O Expansion
kit).
Parameter Range:
ON
OFF
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Input/Output - Digital I/O
Digital inputs 1 and 2 (terminals 59 and 60) select which, if any, preset speed is
used as the reference for the speed/voltage control loop.
The input is ON when +24 VDC is applied for more than 10 msec. It is OFF when
0 VDC is applied.
PRESET SPEED
1 (P.117)
PRESET SPEED
2 (P.118)
PRESET SPEED
3 (P.119)
These parameters
set up to three preset
speed references
when the REGULATOR
TYPE jumper (J15 on
the Regulator board)
is set for the
speed/voltage control
loop.
Parameter Range:
MINIMUM SPEED
Default Setting:
250 RPM
Parameter Type:
Tunable
OIM Menu Path(s):
Drive Reference - Drive Reference Configure
to MAXIMUM SPEED (RPM or
user-defined units)
To use these speeds, CONTROL SOURCE must be set to TERMBLK.
The preset speeds are selected through digital input 1 and digital input 2 on the I/O
Expansion kit, as shown in table 4.2.
If the I/O Expansion kit is not installed, the digital inputs are set to OFF and cannot
be changed. The selected auto or manual reference is used for the reference.
The preset speed reference passes through the same control blocks as other
speed references.
4-12
FlexPak 3000 DC Drive Software Reference
4.2
Configuring Trim
The trim feature allows an offset to be added to or subtracted from the speed
reference. The amount of trim can be proportional to the upstream speed reference or
incremental. An incremental trim signal is derived from the resultant DRAW
PERCENTAGE OUT (P.196) and the specified TOP SPEED (P.011).
Trim is based on the signal from the source you select in TRIM REFERENCE SELECT
(P.108). The choices are:
•
ANALOG MANUAL: The trim reference signal is based on the analog manual reference
signal (terminals 16, 17, and 18) after it has been limited and scaled.
•
REGISTER :
The trim reference signal is based on the value set in TRIM REF REGISTER
(P.107).
•
ANALOG IN 1 or 2: (I/O Expansion kit only.) The trim reference signal is based on
analog in 1 or 2 from the I/O Expansion kit.
•
NETW IN REG
1, 2, OR 3: (Network only.) The trim reference signal is based on
network input register 1, 2, or 3.
The selected trim reference is limited to within ±TOP SPEED and multiplied with TRIM
(P.109) to generate DRAW PERCENTAGE OUT (P.196). DRAW PERCENTAGE OUT
modifies DECELERATION TIME and ACCELERATION TIME when TRIM REFERENCE SELECT is
set to PROPORTIONAL.
RANGE
The input that can be used for the manual trim reference can also be used as the
analog manual reference. Make sure this input (terminals 16, 17, and 18 on the
Regulator board) is not being used for both functions at the same time.
Example
To use an analog manual reference to generate a 0 to 10% trim adjustment to the
speed reference setting, make these settings:
• Set TRIM REFERENCE SELECT (P.108) to ANALOG MANUAL
• Set TRIM RANGE (P.109) to 10%
• Set TRIM MODE SELECT (P.110) to INCREMENTAL
These settings will provide a 0 to 10% trim adjustment through the entire speed range.
Configuring the Speed Reference
4-13
ANALOG MAN TRIM REF
The trim reference
value used when
TRIM REFERENCE
SELECT (P.108) is set
to ANALOG MANUAL.
(P.194)
Parameter Range:
n/a
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Drive Reference - Drive Reference Scaling
Drive Reference - Drive Reference Test Points
DRAW PERCENTAGE OUT
The product of the
selected trim
reference value and
TRIM RANGE value.
(P.196)
Parameter Range:
n/a
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Drive Reference - Drive Reference Test Points
DRAW PERCENTAGE OUT dynamically changes the acceleration
rates when TRIM MODE SELECT is set to PROPORTIONAL.
and deceleration
DRAW PERCENTAGE OUT is also used to generate the TRIM OUTPUT signal, which
modifies the speed reference signal when TRIM MODE SELECT is set to
PROPORTIONAL or INCREMENTAL.
TRIM MODE SELECT
Selects the type of
trim mode to be used
by the drive.
(P.110)
Parameter Range:
NO TRIM
INCREMENTAL
PROPORTIONAL
Default Setting:
NO TRIM
Parameter Type:
Tunable
OIM Menu Path(s):
Drive Reference - Drive Reference Trim
•
NO TRIM:
•
INCREMENTAL:
•
PROPORTIONAL:
No trim is used.
Depending on the polarity of the trim reference, adds to or
subtracts from the speed reference a constant value that is proportional to TOP
SPEED (P.011).
Depending on the polarity of the trim reference, adds to or
subtracts from the speed reference a value that varies based on the speed
reference value. Proportional trim allows multiple drive sections with a common
reference to operate and ramp at different values.
Proportional is a type of draw. By using draw, one section can operate 10% faster
than an upstream section. When a ramp occurs on the common reference, the
two sections will support the 10% draw throughout the ramp. S-CURVE ROUNDING
will interfere with the acceleration and deceleration rates so that the draw will not
be constant. Therefore, it is recommended that S-CURVE ROUNDING be set to 0%
when TRIM MODE SELECT is set to PROPORTIONAL. Incremental trim is not affected
by this limitation.
4-14
FlexPak 3000 DC Drive Software Reference
TRIM OUTPUT
(P.197)
Actual signal used to
trim the selected
speed loop reference
signal.
TRIM RANGE
Parameter Range:
n/a
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Drive Reference - Drive Reference Test Points
(P.109)
Uses the selected
trim reference signal
to generate DRAW
Parameter Range:
0.0 to 100.0%
Default Setting:
0.0%
PERCENTAGE OUT
Parameter Type:
Tunable
OIM Menu Path(s):
Drive Reference - Drive Reference Trim
(P.196). Determines
how much the trim
signal will affect the
drive reference.
TRIM REF REGISTER
Drive register to
manually set the trim
reference value used
by the drive when is
TRIM REFERENCE
SELECT (P.108) is
to REGISTER.
set
(P.107)
Parameter Range:
±100.0%
Default Setting:
0%
Parameter Type:
Tunable
OIM Menu Path(s):
Drive Reference - Drive Reference Trim
Configuring the Speed Reference
4-15
TRIM REFERENCE SELECT
(P.108)
Parameter Range:
Trim reference
selection.
REGISTER
ANALOG MANUAL
ANALOG IN
1
1
2
NETW IN REG 3
ANALOG IN 2
NETW IN REG
NETW IN REG
Default Setting:
REGISTER
Parameter Type:
Tunable
OIM Menu Path(s):
Drive Reference - Drive Reference Trim
The choices are:
•
•
4.3
REGISTER :
The reference is TRIM REF REGISTER (P.107).
ANALOG MANUAL: The reference is the analog manual reference input from
terminals 16, 17, and 18 of the Regulator board. Do not select this option if this
input is being used for the analog manual speed reference.
•
ANALOG IN 1 or 2: The reference is from an I/O Expansion kit analog input. These
are only available if an I/O Expansion kit is installed.
•
NETW IN REG
1, 2, or 3: The reference is from a network input register. These
options are available only if a network kit is installed. Note that the network input
registers are updated only when CONTROL SOURCE (P.000) is set to NETWORK and
the network is active.
Speed Reference Ramp
From the speed reference source select block, the value of SPD SOURCE SELECT OUT
(P.193) is amplitude-limited by a minimum/maximum block. This block limits the
reference between MINIMUM SPEED (P.003) and MAXIMUM SPEED (P.004). You can
modify the results from this block using REVERSE DISABLE (P.015) and AUTO MODE MIN
BYPASS (P.111). The inverter block changes the sign of the signal based on the
forward/reverse signal.
If your automatic speed reference signal is already conditioned, you can bypass the
S-curve block by using AUTO MODE RAMP BYPASS (P.112). You can also bypass the
amplitude limit block while in auto mode by using AUTO MODE MIN BYPASS (P.111)
If you use the S-curve block, S-curve smoothing rounds the SPD SOURCE SELECT OUT
(P.193) signal. It provides a smoother transition from constant level speed to the
acceleration or deceleration condition. This helps reduce machine wear.
The S-curve block controls how fast the speed reference changes based on the
ACCELERATION TIME (P.001), DECELERATION TIME (P.002), and S-CURVE ROUNDING
(P.014). Within the S-curve block, S-CURVE ROUNDING specifies the maximum rate of
change allowed for ramping. When a step change occurs on the input, the output’s
rate of change increases by S-CURVE ROUNDING until the acceleration or deceleration
rate is reached. The rate is maintained until the output reaches a distance from the
input where the rate begins decreasing in S-CURVE ROUNDING intervals.
The speed reference ramp block diagram is shown in figure 4.5.
4-16
FlexPak 3000 DC Drive Software Reference
Figure 4.5 – Speed Reference Ramp Block Diagram
Configuring the Speed Reference
4-17
From Figure 4.2,
Speed Reference
Source Select
Block Diagram
From Figure 4.2,
Speed Reference
Source Select
Block Diagram
From Figure 4.2,
Speed Reference
Source Select
Block Diagram
From Figure 4.2, Speed
Reference Source
Select Block Diagram
To Figure 6.1,
Current Minor Loop
Reference Path
Block Diagram
To Figure 4.7,
Speed Reference
Mode Select Block
Diagram
4.3.1 Configuring the Speed Reference Ramp
ACCELERATION TIME
Sets the minimum
time that the selected
speed reference can
changed from zero to
TOP SPEED (P.011).
(P.001)
Parameter Range:
0.1 to 300.0 seconds
Default Setting:
5.0 seconds
Parameter Type:
Tunable
OIM Menu Path(s):
Drive Reference - Drive Reference Ramp
Quick Start
If TRIM MODE SELECT (P.110) is set to PROPORTIONAL, the actual time to accelerate
might be modified by DRAW PERCENTAGE OUT (P.196). See section 4.2, Configuring
Trim.
AUTO MODE MIN BYPASS
Disables the MINIMUM
SPEED (P.003) limit
while in auto mode. If
the drive is in manual
mode, this parameter
has no effect and the
MINIMUM SPEED
(P.003) limit cannot
be bypassed.
Parameter Range:
OFF
ON
Default Setting:
OFF
Parameter Type:
Tunable
OIM Menu Path(s):
Drive Reference - Drive Reference Limits
!
4-18
(P.111)
ATTENTION: This drive can operate at and maintain zero speed when
this parameter is set to ON. The user is responsible for assuring safe
conditions for operating personnel by providing suitable guards, audible
or visual alarms, or other devices to indicate that the drive is operating
at or near zero speed. Failure to observe this precaution could result in
severe bodily injury or loss of life.
FlexPak 3000 DC Drive Software Reference
AUTO MODE RAMP BYPASS
Bypasses the speed
loop S-curve block
while in auto mode. If
the drive is in manual
mode, this parameter
has no effect and the
S-curve block cannot
be bypassed.
(P.112)
Parameter Range:
OFF
ON
Default Setting:
OFF
Parameter Type:
Tunable
OIM Menu Path(s):
Drive Reference - Drive Reference Ramp
When AUTO RAMP BYPASS is ON and the drive is in auto mode, the speed loop ramp
function is bypassed. The bypass is automatically disabled during a ramp stop
sequence and the drive will always ramp to a stop.
!
DECELERATION TIME
Sets the minimum
time in which the
selected speed
reference can change
from TOP SPEED
(P.011) to 0.
ATTENTION: When switching from auto to manual or from manual to
auto, the drive will ramp to the reference level provided by the new source
at the rate specified by ACCELERATION TIME (P.001) or DECELERATION TIME
(P.002). Be aware that an abrupt speed change might occur, depending
on the new reference and the rate specified in these parameters. Failure
to observe this precaution could result in bodily injury.
(P.002)
Parameter Range:
0.1 to 300.0 seconds
Default Setting:
5.0 seconds
Parameter Type:
Tunable
OIM Menu Path(s):
Drive Reference - Drive Reference Ramp
Quick Start
If TRIM MODE SELECT (P.110) is set to PROPORTIONAL, the actual time to decelerate
might be modified by DRAW PERCENTAGE OUT (P.196). See section 4.2, Configuring
Trim.
Configuring the Speed Reference
4-19
MAXIMUM SPEED
The maximum speed
of the drive that can
be supported by the
application or
process.
(P.004)
Parameter Range:
1 to TOP SPEED (RPM or user-defined units)
Default Setting:
500 RPM
Parameter Type:
Tunable
OIM Menu Path(s):
Drive Reference - Drive Reference Limits
Quick Start
If raising this value causes MINIMUM SPEED to become less than 10% of MAXIMUM
an alarm is generated.
SPEED,
This is typically set to base speed from the motor nameplate.
!
MINIMUM SPEED
Selects the minimum
speed of the drive
without being
stopped. It is typically
greater than zero.
ATTENTION: Do not allow the motor to exceed the maximum safe speed,
as determined by the equipment manufacturer, of the motor or the driven
equipment. Failure to observe this precaution could result in bodily injury.
(P.003)
Parameter Range:
0 to MAXIMUM SPEED (RPM or user-defined units)
Default Setting:
250 RPM
Parameter Type:
Tunable
OIM Menu Path(s):
Drive Reference - Drive Limits
Quick Start
If it is less than 10% of MAXIMUM SPEED, an alarm is generated.
!
RAMP STOP DECEL TIME
The deceleration time
used during ramp
stop sequences
when STOP DECEL
SELECT is set to RAMP
STOP DECEL TIME.
ATTENTION: This drive can operate at and maintain zero speed when
this parameter is set to zero. The user is responsible for assuring safe
conditions for operating personnel by providing suitable guards, audible
or visual alarms, or other devices to indicate that the drive is operating
at or near zero speed. Failure to observe this precaution could result in
severe bodily injury or loss of life.
(P.018)
Parameter Range:
0.1 to 300.0 seconds
Default Setting:
5.0 seconds
Parameter Type:
Tunable
OIM Menu Path(s):
Additional Parameters (listed by parameter number)
This parameter allows you to configure separate deceleration times for stopping
and decelerating.
4-20
FlexPak 3000 DC Drive Software Reference
REVERSE DISABLE
(P.015)
When ON, REVERSE
DISABLE does not
allow the speed
reference to drop
below zero.
Parameter Range:
When OFF, the speed
reference can drop
below zero and the
drive can operate in
the reverse direction.
OFF
ON
Default Setting:
OFF
Parameter Type:
Configurable
OIM Menu Path(s):
Drive Reference - Drive Reference Limits
Quick Start
REVERSE DISABLE
applies only to regenerative drives.
REVERSE DISABLE
is forced to ON when:
• The drive has a non-regenerative (S6) power unit.
• FEEDBACK SELECT is set to AC TACH.
• FEEDBACK SELECT is PULSE TACH and PULSE TACH QUADRATURE (P.208) is OFF.
S-CURVE ROUNDING
The amount of
reference smoothing
(rounding) of the
speed loop S-curve
output.
(P.014)
Parameter Range:
0 to 50%
Default Setting:
0%
Parameter Type:
Tunable
OIM Menu Path(s):
Drive Reference - Drive Reference Ramp
S-CURVE ROUNDING
is set as a percentage of ACCELERATION TIME (P.001).
Rounding is performed at the beginning and end of a speed loop reference change.
If TRIM MODE SELECT (P.110) is set to PROPORTIONAL, S-CURVE ROUNDING should be
set to 0%. If there is S-curve rounding and proportional trim, the actual trim will
interfere with the ACCELERATION TIME and the DECELERATION TIME and draw will not
be constant. If TRIM MODE SELECT (P.110) is set to INCREMENTAL, ACCELERATION TIME
and the DECELERATION TIME are not affected.
If S-CURVE ROUNDING is set to 0%, the speed loop performs a linear ramp function. If
it is set to 50%, the entire ramp time is smoothed: 50% at the beginning and 50% at
the end. Refer to figure 4.6.
Figure 4.6 – S-Curve Rounding
Configuring the Speed Reference
4-21
SPD SOURCE SELECT OUT
The selected speed
reference source
value in RPM or the
units you defined. It is
an input to the speed
reference ramp
section.
Parameter Range:
n/a
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Drive Reference - Drive Reference Test Points
SPEED RAMP INPUT TP
The value of the
speed reference
signal immediately
before the speed loop
S-curve block.
n/a
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Drive Reference – Drive Reference Test Points
DECELERATION TIME
(P.002) or RAMP STOP
DECEL TIME (P.018).
(P.199)
Parameter Range:
n/a
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Drive Reference – Drive Reference Test Points
STOP DECEL SELECT
Selects which
deceleration time will
be used for ramp stop
sequences,
(P.198)
Parameter Range:
SPEED RAMP OUTPUT
The value of the
speed reference
signal immediately
after the speed loop
S-curve block.
(P.193)
(P.122)
Parameter Range:
1 = DECELERATION TIME
2 = RAMP STOP DECEL TIME
Default Setting:
1
Parameter Type:
Configurable
OIM Menu Path(s):
Additional Parameters (listed by parameter number)
This only affects ramp stop times. Speed changes when the drive is running use
regardless of the STOP DECEL SELECT choice.
DECELERATION TIME
4-22
FlexPak 3000 DC Drive Software Reference
STOP MODE SELECT
Selects how the drive
responds to a normal
stop command.
Opening a
permissive input will
always cause a coast
stop.
(P.114)
Parameter Range:
RAMP
COAST/DB
CURRENT LIMIT
Default Setting:
COAST/DB
Parameter Type:
Tunable
OIM Menu Path(s):
Drive Reference - Drive Reference Configure
If the drive is configured as a current regulator, only COAST/DB can be selected.
STOP SPEED THRESHOLD
Configures the
threshold speed
below which the main
contactor will
automatically open
after a ramp stop or
current limit stop is
asserted.
4.4
(P.113)
Parameter Range:
0 to MAXIMUM SPEED (RPM or user-defined units)
Default Setting:
50 RPM
Parameter Type:
Tunable
OIM Menu Path(s):
Drive Reference - Drive Reference Configure
Final Speed Reference Logic
In the last part of the speed reference, the signals from the speed reference ramp and
current minor loop are summed and limited by TOP SPEED to determine the speed
reference sent to the speed loop. The final value that is sent to the speed loop is the
SPD LOOP REFERENCE (P.295). The block diagram is shown in figure 4.7.
From Figure 9.1, Outer Control
Loop Block Diagram
From Figure 4.5, Speed Reference
Ramp Block Diagram
To Figure 5.1, Speed
Loop Block Diagram
Figure 4.7 – Speed Reference Mode Select Block Diagram
Configuring the Speed Reference
4-23
SPD LOOP REFERENCE
The final speed loop
reference value used
by the speed loop
regulator in the drive.
TOP SPEED
(P.295)
Parameter Range:
n/a
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
SPD - Speed/Voltage Loop (SPD) Test Points
Drive Reference - Drive Reference Test Points
(P.011)
The highest running
speed of the motor.
This input is the basis
of speed loop scaling.
Parameter Range:
5 to 5000 RPM
Default Setting:
500 RPM
Parameter Type:
Configurable
OIM Menu Path(s):
Drive Reference - Drive Reference Limits
Quick Start
TOP SPEED
depends on several factors:
• If there is no field weakening, the top speed is typically the same as the motor
nameplate base speed.
• If there is field weakening, the top speed is the same as the field-weakened
speed. Top speed is typically more than the base speed when field weakening is
applied.
Whenever TOP SPEED is changed, you should check the positions of jumpers J11
and J14 to make sure they are set as indicated by J11 ANLG TACH VLT SCL (P.792)
and J14 ANLG TACH VLT RNG (P.793). The tachometer wiring might also need to be
changed. See the hardware manual for more information.
!
ATTENTION: Before starting the drive, this parameter must be set to
base speed or (if the Field Current Regulator kit is installed) the field
weakened speed. The user is responsible for assuring safe conditions
for operating personnel by setting this parameter properly. Failure to
observe this precaution could result in bodily injury.
ATTENTION: Do not allow the motor to exceed the maximum safe speed
of the motor or driven equipment as determined by the equipment
manufacturer. Failure to observe this precaution could result in bodily
injury.
4-24
FlexPak 3000 DC Drive Software Reference
4.4.1 Configuring Jog
For information on jog sequencing, see section 2.1, Run and Jog Sequencing.
When you use a jog input (terminals 4 and 1 on the Regulator board or pressing
), the jog signal is conditioned as shown in figure 4.7.
If DIG IN 0 SELECT (P.428) is set to JOG SPEED SELECT, you can use digital input 0
(terminals 12 and 14 on the Regulator board) to choose between two jog speeds, as
set by JOG SPEED 1 (P.012) and JOG SPEED 2 (P.017).
When digital input 0 is:
• Off (0 V): JOG SPEED 1 (P.012) is selected.
• On (+24 V): JOG SPEED 2 (P.017) is selected.
Switching between the two jog speeds while jogging causes the drive to accelerate or
decelerate to the new jog speed at the rate set by JOG ACCEL/DECEL TIME (P.013).
Only JOG SPEED 1 (P.012) is used if DIG IN 0 SELECT is not set to JOG SPEED SELECT.
!
DIG IN
ATTENTION: This drive can operate at and maintain zero speed when
either of the jog speed parameters (JOG SPEED 1 (P.012) and JOG SPEED 2
(P.017)) is set to zero. The user is responsible for assuring safe conditions
for operating personnel by providing suitable guards, audible or visual
alarms, or other devices to indicate that the drive is operating at or near
zero speed. Failure to observe this precaution could result in severe
bodily injury or loss of life.
0 (P.490)
Indicates the state of
digital input 0
(terminal 12 on the
Regulator board).
Parameter Range:
ON
OFF
(see table 4.3 for detail)
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Additional Parameters (listed by parameter number)
0 is ON when +24VDC is applied for more than 10msec. It is OFF when 0VDC
is applied.
DIG IN
Table 4.3 – Conditions Indicated by DIG IN 0 (P.490)
DIG IN
0 SELECT (P.428)
Setting
BRUSH WEAR INPUT
JOG SPEED SELECT
OCL ENABLE
Configuring the Speed Reference
Condition if DIG IN 0 (P.490) Reads:
ON
OFF
Brushes OK
Brushes Worn
JOG SPEED
OCL
2 selected
enabled
JOG SPEED
OCL
1 selected
disabled
4-25
DIG IN
0 SELECT (P.428)
Determines which
function is controlled
by digital input 0
(terminal 12 on the
Regulator board).
Parameter Range:
1 = BRUSH WEAR INPUT
2 = JOG SPEED SELECT
3 = OCL ENABLE
Default Setting:
1
Parameter Type:
Configurable
OIM Menu Path(s):
Additional Parameters (listed by parameter number)
The functions can be:
•
BRUSH WEAR :
The input is from a brush wear indicator. If the input is OFF, the
alarm is generated. You must have the E.S.P. Brush
Monitor Detector kit installed to use this option.
MOTOR BRUSH WEAR LOW
•
JOG SPEED SELECT:
SPEED
•
The input determines whether JOG SPEED 1 (P.012) or JOG
2 (P.017) will be used when the drive is jogging.
OCL ENABLE:
Enables the outer control loop if CONTROL SOURCE is not set to
and if the I/O Expansion kit is not installed. If an I/O Expansion kit is
installed, the outer control loop enable signal is digital input 5. See section 9.1 for
information.
NETWORK
JOG ACCEL/DECEL TIME
Sets the minimum
time that the jog
reference can change
from zero to TOP
SPEED (P.011) and
from TOP SPEED to
zero.
(P.013)
Parameter Range:
0.1 to 300.0 seconds
Default Setting:
3.0 seconds
Parameter Type:
Tunable
OIM Menu Path(s):
Drive Reference - Drive Reference Ramp
Quick Start
The S-CURVE ROUNDING parameter does not affect the setting of this parameter.
4-26
FlexPak 3000 DC Drive Software Reference
JOG OFF DELAY TIME
Specifies the
minimum delay
between removing
the jog input and
opening of the main
contactor in the drive.
(P.121)
Parameter Range:
0.0 to 10.0 seconds
Default Setting:
1.0 second
Parameter Type:
Configurable
OIM Menu Path(s):
Drive Reference - Drive Reference Configure
Releasing the jog input will not cause the contactor to open until the speed
feedback is less than or equal to STOP SPEED THRESHOLD or until the JOG OFF DELAY
TIME is exceeded, whichever occurs last.
This delay reduces the wear on the contactor when repeatedly opening and closing
the JOG input in a short period of time.
JOG RAMP OUTPUT
The jog reference
value immediately
after the jog ramp
function.
JOG SPEED
Parameter Range:
n/a
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Drive Reference - Drive Reference Test Points
1 (P.012)
The operating speed
while the drive is
jogging if DIG IN 0
SELECT (P.428) is set
to JOG SPEED SELECT
and digital input 0
(terminal 12 on the
Regulator board) is
off.
JOG SPEED
(P.294)
Parameter Range:
0 to MAXIMUM SPEED (RPM or user-defined units)
Default Setting:
250 RPM
Parameter Type:
Tunable
OIM Menu Path(s):
Drive Reference - Drive Reference Configure
Quick Start
2 (P.017)
The operating speed
when the drive is
jogging if DIG IN 0
SELECT (P.428) is set
to JOG SPEED SELECT
and digital input 0
(terminal 12 on the
Regulator board) is
on.
Parameter Range:
0 to MAXIMUM SPEED (RPM or user-defined units)
Default Setting:
250 RPM
Parameter Type:
Tunable
OIM Menu Path(s):
Additional Parameters (listed by parameter number)
Configuring the Speed Reference
4-27
4.4.2 Configuring Current Compounding
Current compounding is used for load sharing between drives. If there is a change in
the CML feedback, current compounding either increases or decreases the speed
reference. See figure 4.7 for the block diagram.
CURRENT COMPOUND TP
The current
compounding value
that is subtracted
from the conditioned
speed reference.
Parameter Range:
n/a
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Speed/Voltage Loop (SPD) - Speed/Voltage Loop
(SPD) - Test Points
CURRENT COMPOUNDING
Sets the level of
current
compounding.
4-28
(P.293)
(P.209)
Parameter Range:
–50 to 50%
Default Setting:
0%
Parameter Type:
Tunable
OIM Menu Path(s):
Speed/Voltage Loop (SPD) - Speed Voltage Loop
(SPD) Tuning
FlexPak 3000 DC Drive Software Reference
CHAPTER 5
Configuring the Speed/Voltage Loop
This chapter describes configuring the speed/voltage loop functions. These include
jog, lead/lag, speed loop lag, current limits, the speed loop PI block, and winding.
The full speed loop block diagram, including these features, is shown in figure 5.1.
SPD LOOP CUR LIM
ANALOG IN 1
{
From Network
To figure 6.1, Current
Minor Loop Reference
Path Block Diagram
ANALOG IN 2
NETW IN REG 1, 2, 3
*ZERO
0
From Network
SPD LOOP PI INIT VAL
ANALOG MANUAL TRIM REF
ANALOG MANUAL TRIM REF
(SPD LOOP
REFERENCE
POS CURRENT
LIM SEL
*REGISTER
POSITIVE CURRENT LIM
From I/O Expansion Board
Inputs Block Diagram
SPD LOOP PI
PROP GAIN
SPD LOOP
PI INIT SEL
SPD LOOP
LAG FREQ
(SPD LOOP
OUTPUT)
INIT KP HI
(SPD LOOP ERROR)
SPD LOOP
LAG BYPASS
WLG
PI
+
From figure 4.7,
Speed Reference
Mode Select Block
Diagram
WLD
LO
*REGISTER
From I/O Expansion Board
Inputs Block Diagram
ANALOG IN 1
{
(SPD LOOP
LAG OUTPUT)
Internal Sequencing
(Drive Stopped)
NEG CURRENT
LIM SEL
OOR
R
Off
INV
ANALOG IN 2
*ON
RST
SPD LOOP PI
LEAD FREQ
NEGATIVE CURRENT LIM
OFF
La
g
NETWORK
(Other)
SPD LOOP PI
RESET (Network)
EN
CONTROL SOURCE
SELECT
NETW IN REG 1, 2, 3
From Network
SPD LOOP
PI LIMITS
To figure 6.1, Current
Minor Loop Reference
Path Block Diagram
NEG CUR LIM
INV EN
EN
UNDERWIND
ENABLE
MOTOR RATED
ARM VOLTS
Armature
Voltage
(internal)
ARM VOLTAGE
GAIN ADJ
ARM VOLTAGE
ZERO ADJ
SPEED FEEDBACK GAIN
(ARMATURE
VOLTAGE)
Software Scaling
A/D
MUL
+
IN
–
Gain
OUT
DIV
Software
Scaling
(CML FEEDBACK)
8 sample average
KEYPAD, TERMBLK,
or SERIAL
1000
CONTROL
SOURCE
SELECT
NETWORK
(IR COMPENSATION TP)
IR COMPENSATION
ANLG TACH
VOLTS/1000
Analog Tachometer
(+ hi) terminal 21
(+ lo) terminal 22
(–) terminal 23
ANALOG TACH
GAIN ADJ
ANALOG TACH
ZERO ADJ
FEEDBACK
SELECT
*BYPASS
DC TACH
A/D
Software Scaling
(ANALOG TACH FEEDBACK)
PULSE TACH
F/D
Software Scaling
PULSE TACH PPR
Lead/Lag
or
Lag/Lead
AC TACH
(PULSE TACH
FEEDBACK)
TOP SPEED
Pulse Encoder
(from optional
Pulse Encoder kit)
*ARMATURE VOLT
(SPD LOOP
FEEDBACK)
WLD
SPD LEADLAG
LOW FREQ
SPD LEADLAG
SELECT
LEAD/LAG
LAG/LEAD
WRATIO
SPD LEADLAG
RATIO
PULSE TACH
QUADRATURE
Figure 5.1 – Speed Loop Block Diagram
Configuring the Speed/Voltage Loop
5-1
5.1
Configuring the Speed Loop Scan Time
The scan time of the speed loop can be configured using parameter P.019 (SPEED
LOOP SCAN TIME). The drive must be stopped to modify the value of this parameter.
Note that P.019 applies only to closed loop speed control using actual measured
motor velocity via tachometer or encoder-type devices.
SPD LOOP SCAN TIME
Selects the speed
loop scan time for
closed loop
operation.
(P.019)
Parameter Range:
0 = 5 msec
1 = 10 msec
Default Setting:
5 msec
Parameter Type:
Configurable
OIM Menu Path(s):
Additional Parameters
When FEEDBACK SELECT (P.200) is set to armature voltage, the active speed loop
scan time is fixed at 10 msec regardless of the setting of P.019.
When FEEDBACK SELECT is changed from armature voltage to any other setting, the
active speed loop scan time is determined by the parameter setting of P.019.
5-2
FlexPak 3000 DC Drive Software Reference
5.2
Configuring the Speed Loop Feedback
Feedback can come from the armature voltage or from an encoder or tachometer. The
parameters you need to configure depend on which feedback source you are using,
as set by FEEDBACK SELECT (P.200).
FEEDBACK SELECT
Selects the type of
feedback signal that
is used for the
speed/voltage loop.
(P.200)
Parameter Range:
ARMATURE VOLT
DC TACH
PULSE TACH
AC TACH
Default Setting:
ARMATURE VOLT
Parameter Type:
Configurable
OIM Menu Path(s):
Speed/Voltage Loop (SPD) - Speed Voltage Loop
(SPD) Feedback
Quick Start
and AC TACH can only be selected if the appropriate kit is installed
(Pulse Encoder kit or AC Tachometer Feedback kit).
PULSE TACH
NEGATIVE CURRENT LIM
•
•
AC TACH
is selected.
PULSE TACH
!
(P.006) is set to 0 and REVERSE DISABLE (P.015) is set ON if:
is selected and PULSE TACH QUADRATURE (P.208) is set to OFF.
ATTENTION: The incorrect configuration of this parameter can cause an
overspeed condition. This parameter must be configured by a qualified
person who understands the significance of setting it. Failure to observe
this precaution could result in bodily injury.
5.2.1 Configuring Armature Voltage Feedback
If FEEDBACK SELECT is set to armature voltage, the drive reads the internal armature
voltage and scales it with the MOTOR RATED ARM VOLTS, ARM VOLTAGE GAIN, and ARM
VOLTAGE ZERO parameter values. These values are summed together to produce the
armature voltage signal. The armature voltage block is shown in figure 5.2.
To Figure 5.1, Speed
Loop Block Diagram
Figure 5.2 – Armature Voltage Block Diagram
Configuring the Speed/Voltage Loop
5-3
!
ARM VOLTAGE GAIN ADJ
Scales the armature
voltage signal after
the drive hardware
conditions the signal.
In most cases, this
parameter is set to
1.000.
ATTENTION: The incorrect configuration of these parameters can cause
an overspeed condition. They must be configured by a qualified person
who understands the significance of configuring them. Failure to observe
this precaution could result in bodily injury.
(P.204)
Parameter Range:
0.750 to 1.250
Default Setting:
1.000
Parameter Type:
Tunable
OIM Menu Path(s):
Speed/Voltage Loop (SPD) - Speed/Voltage Loop
(SPD) Feedback
Important: Adjust the zero point (ARM VOLTAGE ZERO ADJ (P.205)) before
configuring gain.
ARM VOLTAGE ZERO ADJ
Removes any offset
from the armature
voltage signal.
(P.205)
Parameter Range:
–200 to 200
Default Setting:
0
Parameter Type:
Tunable
OIM Menu Path(s):
Speed/Voltage Loop (SPD) - Speed/Voltage Loop
(SPD) Feedback
If ARMATURE VOLTAGE (P.289) is not equal to zero when the drive is stopped, adjust
ARM VOLTAGE ZERO ADJ up or down until ARMATURE VOLTAGE (P.289) equals zero.
ARMATURE VOLTAGE
Armature voltage
value after all
hardware and
software scaling but
before any IR
compensation.
5-4
(P.289)
Parameter Range:
n/a
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Speed/Voltage Loop (SPD) - Speed/Voltage Loop
(SPD) Test Points
Speed/Voltage Loop (SPD) - Speed/Voltage Loop
(SPD) Tuning - Speed/Voltage Loop (SPD) Feedback
Current Minor Loop (CML) - CML Feedback Scaling SCR Diagnostics - Armature Phase Fire Test
FlexPak 3000 DC Drive Software Reference
IR COMPENSATION
(P.206)
Sets the armature
voltage loss
compensation value
used when the drive
is configured as a
voltage regulator.
Parameter Range:
0 to 50%
Default Setting:
0%
Parameter Type:
Tunable
OIM Menu Path(s):
Speed/Voltage Loop (SPD) - Speed/Voltage Loop
(SPD) Tuning
Quick Start
Field - Field Current Regulator - Field Loop Tuning
This parameter is also used by the Field Current Regulator kit to set the
field-weakened threshold. See section 8.3.
IR COMPENSATION is normally determined from the motor data sheet. It should be
set to the percent IR drop of the motor.
If this data is not available on the motor data sheet, you can set this empirically so
that the no-load and full-load speeds are as close as possible when operating as a
voltage regulator.
IR COMPENSATION TP
The level of IR
being
subtracted from the
measured armature
voltage.
(P.290)
Parameter Range:
n/a
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Speed/Voltage Loop (SPD) - Speed/Voltage Loop
(SPD) Test Points
COMPENSATION
The value of IR COMPENSATION TP is determined by the equation:
IR COMPENSATION • CML FEEDBACK • MAXIMUM CURRENT
IR COMPENSATION TP = -----------------------------------------------------------------------------------------------------------------------------------------------------------------------------10, 000
MOTOR RATED ARM VOLTS
The rated armature
voltage as it is listed
on the motor
nameplate.
(P.009)
Parameter Range:
160 to 675 volts
Default Setting:
240 volts
Parameter Type:
Configurable
OIM Menu Path(s):
Speed/Voltage Loop (SPD) - Speed/Voltage Loop
(SPD) Feedback
Quick Start
This must always be set properly, regardless of the setting of FEEDBACK SELECT
(P.200).
Configuring the Speed/Voltage Loop
5-5
5.2.2 Configuring AC or DC Analog Tachometer Feedback
You only need to configure these parameters if your feedback device is an AC or DC
analog tachometer.
If FEEDBACK SELECT is set to DC TACH, feedback is from a DC tachometer. (See the
hardware manual and your tachometer manual for wiring information.)
If FEEDBACK SELECT (P.200) is set to AC TACH, feedback is from an AC tachometer
connected to an AC Tachometer Feedback kit. See the AC Tachometer Feedback kit
manual for information.
The gain and zero parameters for the analog tachometer are a method of eliminating
any offset introduced by the tachometer. You only need to set these parameters if you
need to adjust the tachometer feedback value.
The analog tachometer block diagram is shown in figure 5.3.
To Figure 5.1, Speed
Loop Block Diagram
Figure 5.3 – AC or DC Analog Tachometer Feedback Block Diagram
!
ANALOG TACH FEEDBACK
The digital value of
the analog
tachometer feedback
input after all
hardware and
software scaling. For
use with analog
tachometer feedback
(AC or DC) only.
5-6
ATTENTION: The incorrect configuration of these parameters can cause
an overspeed condition. These parameters must be configured by a
qualified person who understands the significance of configuring them.
Failure to observe this precaution could result in bodily injury.
(P.291)
Parameter Range:
n/a
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Speed/Voltage Loop (SPD) - Speed/Voltage Loop
(SPD) Test Points
Speed/Voltage Loop (SPD) Tuning - Speed/Voltage
Loop (SPD) Feedback
FlexPak 3000 DC Drive Software Reference
ANALOG TACH GAIN ADJ
Scales the analog
tachometer feedback
signal after it has
been conditioned by
the drive hardware.
Typically, it will be
1.000.
(P.201)
Parameter Range:
0.750 to 1.250
Default Setting:
1.000
Parameter Type:
Tunable
OIM Menu Path(s):
Speed/Voltage Loop (SPD)-Speed / Voltage Loop
(SPD) Feedback
Important: Adjust the zero point (ANALOG TACH ZERO ADJ (P.202)) before
configuring gain.
ANALOG TACH ZERO ADJ
Removes any offset
from the analog
tachometer feedback
signal.
(P.202)
Parameter Range:
–200 to + 200
Default Setting:
0
Parameter Type:
Tunable
OIM Menu Path(s):
Speed/Voltage Loop (SPD)-Speed / Voltage Loop
(SPD) Feedback
If ANALOG TACH FEEDBACK (P.291) is not equal to zero when the drive is stopped,
adjust ANALOG TACH ZERO ADJ up or down until ANALOG TACH FEEDBACK (P.291) is
equal to zero.
ANLG TACH VOLTS/1000
Analog tachometer
scaling from the
tachometer
nameplate in volts
per 1000 RPM.
(P.203)
Parameter Range:*
18.0 to 200.0 VOLTS/1000 RPM
Default Setting:
18.0 VOLTS/1000 RPM
Parameter Type:
Configurable
OIM Menu Path(s):
Speed/Voltage Loop (SPD) – Speed/Voltage Loop
(SPD) Feedback
Units are volts DC for DC tachometers or volts AC RMS for AC tachometers.
Use of an AC tachometer requires the AC Tachometer Feedback kit.
Whenever ANLG TACH VOLTS/1000 is changed, you should check the positions of
jumpers J11 and J14 to make sure they are set as indicated by J11 ANLG TACH VLT
SCL (P.792) and J14 ANLG TACH VLT RNG (P.793). The tachometer wiring might also
need to be changed. See the hardware manual for more information.
*Depending on the setting of TOP SPEED (P.011), the high limit might be less than
200.0 to prevent the tachometer voltage from exceeding 250V.
Configuring the Speed/Voltage Loop
5-7
J11 ANLG TACH VLT SCL (P.792)
Position in which to
set the J11 hardware
jumper based on the
values of TOP SPEED
(P.011) and ANLG
TACH VOLTS/1000
(P.203).
Parameter Range:
16
31
62
125
250
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Drive Information - Correct Scaling Jumper Positions
Quick Start
Speed/Voltage Loop (SPD) - Speed/Voltage Loop
(SPD) Feedback
J14 ANLG TACH VLT RNG (P.793)
Position in which to
set the J14 hardware
jumper based on the
values of TOP SPEED
(P.011) and ANLG
TACH VOLTS/1000
(P.203).
Parameter Range:
LOW
HIGH
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Drive Information - Correct Scaling Jumper Positions
Quick Start
Speed/Voltage Loop (SPD) - Speed/Voltage Loop
(SPD) Feedback
The tachometer wiring must match the setting shown here. See the hardware
manual for wiring information.
5-8
FlexPak 3000 DC Drive Software Reference
5.2.3 Configuring the Pulse Encoder Feedback
You only need to configure the pulse encoder feedback parameters if you have the
Pulse Encoder (Tachometer) kit installed. If you have a regenerative drive, you must
use a quadrature pulse encoder.
The pulse encoder block diagram is shown in figure 5.4.
To Figure 5.1, Speed
Loop Block Diagram
Figure 5.4 – Pulse Encoder Feedback Block Diagram
ATTENTION: The incorrect configuration of these parameters can cause
an overspeed condition. These parameters must be set by a qualified
person who understands the significance of setting them. Failure to
observe this precaution could result in bodily injury.
!
PULSE TACH FEEDBACK
The digital value from
the pulse encoder
after hardware and
software scaling. For
use with pulse
encoder feedback
only.
PULSE TACH PPR
Pulse encoder pulses
per revolution (PPR)
from the pulse
encoder nameplate.
(P.292)
Parameter Range:
n/a
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Speed/Voltage Loop (SPD) - Speed/Voltage Loop
(SPD) Test Points
(P.207)
Parameter Range:
18 to 2500 PPR
Default Setting:
18 PPR
Parameter Type:
Configurable
OIM Menu Path(s):
Speed/Voltage Loop (SPD) - Speed/Voltage Loop
(SPD) Feedback
Configuring the Speed/Voltage Loop
5-9
PULSE TACH QUADRATURE
Enables or disables
pulse encoder
quadrature.
A quadrature pulse
encoder must be
used on regenerative
drives that use a
pulse encoder.
(P.208)
Parameter Range:
ON
OFF
Default Setting:
ON
Parameter Type:
Configurable
OIM Menu Path(s):
Speed/Voltage Loop (SPD) - Speed/Voltage Loop
(SPD) Feedback
Set ON for a bidirectional pulse encoder.
Set OFF for a unidirectional pulse encoder.
If PULSE TACH QUADRATURE is set to OFF and PULSE TACH is the selected FEEDBACK
SELECT type, NEGATIVE CURRENT LIM (P.006) will be set to 0 and REVERSE DISABLE
(P.015) set to ON (preventing reverse direction).
PULSE TACHOMETER KIT
Indicates whether or
not the Pulse
Encoder
(Tachometer) kit is
installed in the drive
and if it has passed
diagnostics.
(P.798)
Parameter Range:
INSTALLED
NOT INSTALLED
FAILED DIAGS
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Drive Information
If the Pulse Encoder (Tachometer) kit has failed diagnostics, the drive is not
operable (the armature cannot become active).
5-10
FlexPak 3000 DC Drive Software Reference
5.2.4 Configuring Speed Loop Feedback Lead/Lag Block
Lead/lag adjustments compensate for backlash or coupling issues because of the
feedback device.
To enable this block, set SPD LEADLAG SELECT (P.216) to LEAD/LAG or LAG/LEAD. To
disable this block, set SPD LEADLAG SELECT (P.216) to BYPASS.
When this block is enabled, the selected feedback signal is fed into the lead/lag block.
The SPD LEADLAG LOW FREQ (P.214) and SPD LEADLAG RATIO (P.213) input values are
used to calculate the high break frequency. SPD LEADLAG LOW FREQ (P.214) specifies
the low break frequency and the SPD LEADLAG RATIO (P.213) is the ratio maintained
between the low break and high break frequencies. The low break frequency and ratio
settings are multiplied to determine the high break frequency. For example, if the low
break frequency is 0.50rad/s and the ratio is 10, high break frequency is 5.00rad/s.
The transfer functions for lead/lag and lag/lead are:
Lead/Lag:
Lag/Lead:
s
1 + ---------ω low
---------------------s
1 + -----------ω high
s
1 + -----------ω high
---------------------s
1 + ---------ω low
Where:
• ωlow = SPD LEADLAG LOW FREQ (P.214)
• ωhigh = SPD LEADLAG LOW FREQ (P.214) * SPD LEADLAG RATIO (P.213)
SPD LEADLAG LOW FREQ
Specifies the low
break frequency of
the speed feedback
lead/lag block.
(P.214)
Parameter Range:
0.01 to 69.81 RAD/S when:
• FEEDBACK SELECT (P.200) = ARMATURE VOLT
•
SPD LOOP SCAN TIME
(P.019) = 10 MS
0.01 to 139.62 RAD/S when:
• FEEDBACK SELECT (P.200) ≠ ARMATURE VOLT
•
SPD LOOP SCAN TIME
(P.019) = 5 MS
Default Setting:
1.00 RAD/S
Parameter Type:
Tunable
OIM Menu Path(s):
Speed/Voltage Loop (SPD) - Speed/Voltage Loop
(SPD) Tuning
If SPD LEADLAG SELECT is set to:
•
•
•
BYPASS:
This parameter has no effect.
LAG/LEAD:
This parameter specifies the lead break frequency.
LEAD/LAG:
This parameter specifies the lag break frequency.
Configuring the Speed/Voltage Loop
5-11
SPD LEADLAG RATIO
Specifies the ratio
between the low and
high break
frequencies of the
speed feedback
lead/lag block.
(P.213)
Parameter Range:
2 to 20
Default Setting:
2
Parameter Type:
Tunable
OIM Menu Path(s):
Speed/Voltage Loop (SPD) - Tuning
For example, if this parameter is set to 10, the high break frequency is 10 times the
low break frequency (set by SPD LEADLAG LOW FREQ).
If SPD LEADLAG SELECT is set to BYPASS, this parameter has no effect.
SPD LEADLAG SELECT
Determines if and
how the lead/lag
block will act on the
speed loop feedback
signal.
(P.216)
Parameter Range:
LEAD/LAG
BYPASS
LAG/LEAD
Default Setting:
BYPASS
Parameter Type:
Tunable
OIM Menu Path(s):
Speed/Voltage Loop (SPD) - Speed/Voltage Loop
(SPD) Tuning
If BYPASS is selected, the lead/lag block is bypassed and the feedback signal is
used directly by the speed loop summing junction.
5.3
Reading the Speed Loop Error Signal
The speed loop error signal is determined by subtracting SPD LOOP FEEDBACK (P.296)
from the SPD LOOP REFERENCE (P.295).
SPD LOOP ERROR
(P.297)
The speed loop error
signal, which is the
difference between
Parameter Range:
n/a
Default Setting:
n/a
SPD LOOP REFERENCE
(P.295) and SPD LOOP
FEEDBACK (P.296).
Parameter Type:
Output
OIM Menu Path(s):
SPD
SPD LOOP FEEDBACK
The final
speed/voltage loop
drive feedback value
after scaling.
5-12
- Speed/Voltage Loop (SPD) Test Points
(P.296)
Parameter Range:
n/a
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
SPD
- Speed/Voltage Loop (SPD) Test Points
FlexPak 3000 DC Drive Software Reference
5.4
Configuring the Speed Loop Forward Path Lag Block
Lag adjustments compensate for noisy feedback or reference signals. The speed loop
lag block serves as a low pass frequency compensation filter. A positive or negative
step input to the lag block drives the output to increase or decrease its value in the
direction of the input. A lower lag break frequency will exhibit a slower step response
than a higher one.
The lag transfer function is:
SPD LOOP LAG BYPASS
Determines if the
speed loop forward
path lag block will act
upon the speed loop
error signal.
1
-------------------s
1 + ---------ω lag
, where ωlag = SPD LOOP LAG FREQ (P.215).
(P.217)
Parameter Range:
ON
OFF
Default Setting:
ON
Parameter Type:
Tunable
OIM Menu Path(s):
Speed/Voltage Loop (SPD) - Speed/Voltage Loop
(SPD) Tuning
If ON, the lag block is bypassed and does not affect the speed loop forward path
signal.
SPD LOOP LAG FREQ
Specifies the lag
break frequency for
the speed loop
forward path lag
block.
If SPD LOOP LAG
BYPASS is ON, this
parameter has no
effect.
(P.215)
Parameter Range:
•
SPD LOOP SCAN TIME
(P.019) = 10 MS
0.01 to 279.25 RAD/S when
• FEEDBACK SELECT (P.200) ≠ ARMATURE VOLT
•
SPD LOOP SCAN TIME
(P.019) = 5 MS
Default Setting:
1.00 RAD/S
Parameter Type:
Tunable
OIM Menu Path(s):
Speed/Voltage Loop (SPD) - Speed/Voltage Loop
(SPD) Tuning
SPD LOOP LAG OUTPUT
The value
immediately after the
speed loop forward
path lag block.
0.01 to 139.62 RAD/S when
• FEEDBACK SELECT (P.200) = ARMATURE VOLT
(P.298)
Parameter Range:
n/a
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
SPD
Configuring the Speed/Voltage Loop
- Speed/Voltage Loop (SPD) Test Points
5-13
5.5
Configuring the Speed Loop Current Limits
Armature current is typically limited through two parameters, POSITIVE CURRENT LIM
(P.005) and NEGATIVE CURRENT LIM (P.006). Configure these parameters so they limit
armature current to a range that is consistent with normal operation of the application.
The current limits can also come from:
• Analog inputs 1 and 2 on the I/O Expansion kit.
• Network input registers 1, 2, or 3 from a network.
When POS CURRENT LIM SEL (P.223) or NEG CURRENT LIM SEL (P.224) is set to REGISTER,
the register values are automatically clamped to prevent a minimum (non-zero)
current condition.
Normally, the negative current limit is input as a positive value, then converted to a
negative value by an inverter. If needed, the inverter can be disabled by the NEG CUR
LIM INV EN (P.226) parameter. For example, if the inverter is enabled and the negative
current limit is 150.0% FLA, the actual negative current limit used is –150.0% FLA.
!
ATTENTION: When analog inputs or network registers are used to
control current limits, bipolar values are permitted for the postive and
negative current limits of the current and speed loops. Extreme care
must be exercised when setting the current limit values in this case. If
the negative current limit is set to a non-zero value, the current loop
reference will be clamped to this minimum value, possibly causing
unexpected motor or machine operation, including rapid acceleration or
overspeed. Failure to observe this precaution could result in bodily injury.
If you change NEG CUR LIM INV EN (P.226), POS CURRENT LIM SEL (P.223) and NEG
CURRENT LIM SEL (P.224) are automatically set to REGISTER. When this occurs, an
alarm is generated to notify you of a possible change in the current limits. Make sure
the settings of POS CURRENT LIM SEL (P.223), NEG CURRENT LIM SEL (P.224), POSITIVE
CURRENT LIM (P.005), and NEGATIVE CURRENT LIM (P.006) are correct for your
application before operating the drive.
5-14
FlexPak 3000 DC Drive Software Reference
NEG CURRENT LIM SEL
Selects the source for
the negative current
limit.
(P.224)
Parameter Range:
REGISTER
ANALOG IN
ANALOG IN
1
2
1
2
NETW IN REG 3
NETW IN REG
If REGISTER is
selected, NEGATIVE
CURRENT LIM (P.006)
is used as the limit.
NETW IN REG
Default Setting:
REGISTER
Parameter Type:
Configurable
OIM Menu Path(s):
Speed/Voltage Loop (SPD) - Speed/Voltage Loop
(SPD) Tuning
Current Minor Loop (CML) - CML Tuning
The I/O Expansion kit must be installed to use ANALOG IN 1 (terminals 50 and 51 on
the I/O Expansion board) or ANALOG IN 2 (terminals 52 and 53).
A network kit must be installed to select the network input registers (NETW IN REG 1,
2, or 3). Note that the network input registers are updated only when CONTROL
SOURCE (P.000) is set to NETWORK and the network is active.
This parameter is affected by NEG CUR LIM INV EN (P.226).
NEG CUR LIM INV EN
Enables or disables
the negative current
limit inverter to the
speed loop PI block
low limit input.
(P.226)
Parameter Range:
DISABLED
ENABLED
Default Setting:
ENABLED
Parameter Type:
Configurable
OIM Menu Path(s):
Additional Parameters (listed by parameter number)
When this parameter is set to ENABLED, POSITIVE CURRENT LIM (P.005) and NEGATIVE
(P.006) are restricted to positive values.
CURRENT LIM
When this parameter is set to DISABLED, the range of NEGATIVE CURRENT LIM (P.006)
is restricted to negative values.
When you change this parameter value:
• Alarm A00052 occurs.
• The parameters NEG CURRENT LIM SEL (P.224) and POS CURRENT LIM SEL (P.223)
are automatically set to REGISTER.
•
(P.006) is inverted. For example, if NEG CUR LIM INV EN is
set to ENABLE and NEGATIVE CURRENT LIM is set to 150% FLA, changing NEG CUR
LIM INV EN to DISABLED changes the value of NEGATIVE CURRENT LIM to –150% FLA.
NEGATIVE CURRENT LIM
Carefully check your current limit scheme and the values of POSITIVE CURRENT LIM
(P.005) and NEGATIVE CURRENT LIM (P.006) to avoid unintended drive operation.
Configuring the Speed/Voltage Loop
5-15
NEGATIVE CURRENT LIM
This parameter only
needs to be set for
regenerative drives.
Selects the highest
amount of current (%
full load amps) for the
reverse bridge. Used
as a low limit for the
speed loop PI block
when NEG CURRENT
LIM SEL (P.224) is set
to REGISTER.
(P.006)
Parameter Range:*
When NEG CUR LIM INV EN (P.226) = ENABLED:
0 to MAXIMUM CURRENT (%FLA)
When NEG CUR LIM INV EN (P.226) = DISABLED:
– MAXIMUM CURRENT to 0 (%FLA)
Default Setting:
±150 %FLA
Parameter Type:
Tunable
OIM Menu Path(s):
Speed/Voltage Loop (SPD) - Speed/Voltage Loop
(SPD) Tuning
Current Minor Loop (CML) - CML Tuning
Quick Start
*The range is clamped to zero:
• For non-regenerative drives.
• If FEEDBACK SELECT (P.200) is set to AC TACH.
• If FEEDBACK SELECT is PULSE TACH and PULSE TACH QUADRATURE (P.208) is OFF.
The range of NEGATIVE CURRENT LIM depends on the setting of NEG CUR LIM INV EN
(P.226).
POS CURRENT LIM SEL
Selects the source for
the positive current
limit.
(P.223)
Parameter Range:
REGISTER
ANALOG IN
ANALOG IN
1
2
1
2
NETW IN REG 3
NETW IN REG
If REGISTER is
selected, POSITIVE
CURRENT LIM (P.005)
is used as the limit.
NETW IN REG
Default Setting:
REGISTER
Parameter Type:
Configurable
OIM Menu Path(s):
Speed/Voltage Loop (SPD) - Speed/Voltage Loop
(SPD) Tuning
Current Minor Loop (CML) - CML Tuning
The I/O Expansion kit must be installed to use ANALOG IN 1 (terminals 50 and 51 on
the I/O Expansion board) or ANALOG IN 2 (terminals 52 and 53).
A network option board must be installed to select the network input registers
(NETW IN REG 1, 2, or 3). Note that the network input registers are updated only
when CONTROL SOURCE (P.000) is set to NETWORK and the network is active.
This parameter is affected by NEG CUR LIM INV EN (P.226).
5-16
FlexPak 3000 DC Drive Software Reference
POSITIVE CURRENT LIM
Sets the highest
amount of current (%
full load amps) for the
forward bridge. Used
as a high limit for the
speed loop PI block
when POS CURRENT
LIM SEL (P.223) is set
to REGISTER.
5.6
(P.005)
Parameter Range:
0 to MAXIMUM CURRENT (%FLA)
Default Setting:
150 %FLA
Parameter Type:
Tunable
OIM Menu Path(s):
Speed/Voltage Loop (SPD) - Speed/Voltage Loop
(SPD) Tuning
Current Minor Loop (CML) - CML Tuning
Quick Start
Configuring the Speed Loop PI Block
The proportional-integral transfer function is:
s + ωld
K p  ------------------
 s 
where:
• Kp= SPD LOOP PI PROP GAIN (P.211)
• ωld = SPD LOOP PI LEAD FREQ (P.212)
When CONTROL SOURCE is set to NETWORK, you can reset and assign initial values to
the speed loop PI block. This allows you to switch between current and speed
regulation without stopping the drive.
The PI block is reset when SPD LOOP PI RESET is asserted. The PI block is also held in
reset when the drive is stopped. While reset is asserted, the output of the PI block is
the initial value.
The initial value is determined by SPD LOOP PI INIT SEL and SPD LOOP PI INIT VAL.
If CONTROL SOURCE
LOOP PI INIT SEL set
is not set to NETWORK, the block uses an initial value of zero (SPD
to ZERO.)
When the PI block reset is used, the system must be set to minimize the error between
the actual reference and the commanded reference when changing regulation
schemes to minimize bumps in regulation. For example, when changing from speed to
current regulation, the speed loop PI block’s initial value should be updated with the
actual armature current feedback just before the change is made. The speed
reference should be set to speed feedback before changing from current to speed
regulation.
You can pretorque the speed regulator by setting the speed loop PI block’s initial value
to the desired starting torque value and releasing the block from reset after starting
the drive. The initial torque will be the initial value as the drive begins to ramp to the
reference speed.
Configuring the Speed/Voltage Loop
5-17
SPD LOOP OUTPUT
Speed loop PI block
output value.
(P.299)
Parameter Range:
n/a
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
SPD - Speed/Voltage Loop (SPD) Test Points
Current Minor Loop (CML) - CML Test Points
SPD LOOP PI INIT SEL
Selects the source for
the initial value of the
speed loop PI block
when CONTROL
SOURCE is set to
NETWORK.
If CONTROL SOURCE is
not set to NETWORK,
Parameter Range:
0 = ZERO
1 = SPD LOOP PI INIT VAL
2 = ANALOG MAN TRIM REF (P.194)
Default Setting:
0
Parameter Type:
Configurable
OIM Menu Path(s):
This parameter is available over the network, It
cannot be viewed through the OIM.
SPD LOOP PI INIT SEL
is forced to ZERO.
Refer to the appropriate network communication manual for register map
assignments.
SPD LOOP PI INIT VAL
The initial value of the
speed loop PI block
when CONTROL
SOURCE is set to
NETWORK and SPD
LOOP PI INIT SEL is set
to 1 (SPD LOOP PI INIT
VAL).
Parameter Range:
–32768 to 32767
Default Setting:
0
Parameter Type:
Tunable
OIM Menu Path(s):
This parameter is only available over the network, It
cannot be viewed through the OIM.
This parameter is forced to 0 if CONTROL SOURCE is not set to NETWORK.
Refer to the appropriate network communication manual for register map
assignments.
5-18
FlexPak 3000 DC Drive Software Reference
SPD LOOP PI LEAD FREQ
Speed loop PI block
lead break frequency.
(P.212)
Parameter Range:
0.00 to 282.74 RAD/S when
• FEEDBACK SELECT (P.200) = ARMATURE VOLT
• SPD LOOP SCAN TIME (P.019) = 10 MS
0.00 to 327.67 RAD/S when
• FEEDBACK SELECT (P.200) ≠ ARMATURE VOLT
• SPD LOOP SCAN TIME (P.019) = 5 MS
Default Setting:
3.00 RAD/S
Parameter Type:
Tunable
OIM Menu Path(s):
Speed/Voltage Loop (SPD) - Speed/Voltage Loop
(SPD) Tuning
A setting of 0.00 allows proportional-only speed loop control.
This parameter is set by the speed loop self-tuning procedure. You can also enter it
directly. Self-tuning will overwrite values entered manually.
SPD LOOP PI PROP GAIN
Speed loop PI block
proportional gain.
(P.211)
Parameter Range:
0.10 to 128.00
Default Setting:
4.40
Parameter Type:
Tunable
OIM Menu Path(s):
Speed/Voltage Loop (SPD) - Speed/Voltage Loop
(SPD) - Tuning
This parameter is set by the speed loop self-tuning procedure. You can also enter it
directly. Self-tuning will overwrite values entered manually.
SPD LOOP PI RESET
While this is ON, the
speed loop PI block is
held in reset and the
block’s output is the
initial value selected
by SPD LOOP PI INIT
VAL (Drop_1, register
39 of the alternate
network register
map).
Parameter Range:
0 = OFF
1 = ON
Default Setting:
0
Parameter Type:
Tunable
OIM Menu Path(s):
This parameter is only available over the network. It
cannot be viewed through the OIM.
SPD LOOP PI RESET
is forced OFF when CONTROL SOURCE is not NETWORK.
Refer to the appropriate network communication manual for register map
assignments.
Configuring the Speed/Voltage Loop
5-19
5.7
Configuring Parameters for Winding Applications
These options are only available when using the AutoMax Network Communication
board (CONTROL SOURCE is set to NETWORK and NETW REGISTER MAP SEL (P.914) is set
to 2 (ALTERNATE)) or when using the ControlNet Network Communication board.
For diameter-dependent loads, you can scale the feedback to the speed loop. The
feedback is scaled through a multiplier block. The operation of the multiplier block is:
A•B
------------1000
Where:
• A is a speed feedback multiplier (gain)
• B is the speed feedback from the lead/lag block output
When NETW REGISTER MAP SEL (P.914) is set to ALTERNATE, the source for A is the
network register SPEED FEEDBACK GAIN (alternate map, Drop_1, register 38). Even if
the multiplier block is not being used, you must write a value of 1000 to the SPEED
FEEDBACK GAIN register whenever writing to Drop_1. This sets the multiplier block to
unity gain.
If the web is underwound, set UNDERWIND ENABLE (alternate map, Drop_1, register 32,
bit 5) to ENABLE. This enables two inverters, one in the speed loop feedback path
immediately before the feedback summing junction, and one at the input to the CML
limit block.
Refer to the appropriate network communication manual for register map
assignments.
5-20
FlexPak 3000 DC Drive Software Reference
UNDERWIND ENABLE
Setting this bit to 1
enables two inverter
blocks that permit
underwind operation.
Parameter Range:
0 = DISABLED (overwind)
1 = ENABLED (underwind)
Default Setting:
0
Parameter Type:
Configurable
Setting this bit to 0
disables the two
inverter blocks and
permits overwind
operation.
OIM Menu Path(s):
This parameter is only available over the network. It
cannot be viewed through the OIM.
Refer to the appropriate network communication manual for register map
assignments.
To use this register, CONTROL SOURCE must be set to NETWORK and NETW REGISTER
(P.914) must be set to ALTERNATE.
MAP SEL
The inverters are located in the speed loop feedback path (see figure 5.1) and the
current minor loop reference path (see figure 6.1).
If CONTROL SOURCE is changed from NETWORK to any other control source, the
UNDERWIND ENABLE bit is set to the default of DISABLED. If the setting was ENABLED,
the motor can rotate in the opposite direction when the drive is restarted with a
control source other than the network.
!
Configuring the Speed/Voltage Loop
ATTENTION: When CONTROL SOURCE is changed from NETWORK to
another value, UNDERWIND ENABLE is forced to DISABLED. This could cause
the motor to rotate in the opposite direction than it did under network
control. The active speed reference should be set to zero before starting
the drive from the new control source. Slowly increase the speed
reference until the proper rotation direction can be determined. If it is
incorrect, change the setting of the FORWARD/REVERSE input. The active
speed reference is based on the new control source and the auto or
manual setting. Failure to observe this precaution could result in severe
bodily injury or loss of life.
5-21
SPEED FEEDBACK GAIN
Controls the gain of
the speed loop
feedback path.
This is typically a
value that is related
to the diameter of the
roll in a winder
application.
Parameter Range:
1000 to 32000
Default Setting:
1000
Parameter Type:
Tunable
OIM Menu Path(s):
This parameter is only available over the network. It
cannot be viewed through the OIM.
Refer to the appropriate network communication manual for register map
assignments.
1000 corresponds to a gain of 1.000 and 32,000 to a gain of 32.000.
To access this register, CONTROL SOURCE must be set to NETWORK and NETW
(P.914) must be set to ALTERNATE.
REGISTER MAP SEL
To bypass the multiplier block, set this register to 1000 (1.000). This is the also the
value SPEED FEEDBACK GAIN is forced to when NETW REGISTER MAP SEL (P.914) is set
to ORIGINAL. The SPEED FEEDBACK GAIN block is bypassed when CONTROL SOURCE is
not set to NETWORK.
If CONTROL SOURCE is changed from NETWORK to any other control source, the
UNDERWIND ENABLE bit is set to the default of DISABLED. If the setting was ENABLED,
the motor can rotate in the opposite direction when the drive is restarted with a
control source other than the network.
!
5-22
ATTENTION: When CONTROL SOURCE is changed from NETWORK to
another value, UNDERWIND ENABLE is forced to DISABLED. This could cause
the motor to rotate in the opposite direction than it did under network
control. The active speed reference should be set to zero before starting
the drive from the new control source. Slowly increase the speed
reference until the proper rotation direction can be determined. If it is
incorrect, change the setting of the FORWARD/REVERSE input. The active
speed reference is based on the new control source and the auto or
manual setting. Failure to observe this precaution could result in severe
bodily injury or loss of life.
FlexPak 3000 DC Drive Software Reference
CHAPTER 6
Configuring the Current Minor Loop
In all FlexPak 3000 drive configurations, the central control loop is the current minor
loop (CML). This is the control loop that regulates the amount of current flowing
through the motor armature.
The CML is a simple control loop composed of a reference path, a feedback path, and
a forward path that includes a proportional and integral (PI) block. See figure 6.2. The
input to the PI block, known as the error, is the difference between the reference and
feedback. The output of the PI block determines the level of current flowing through the
motor armature. When a reference change occurs, the error becomes non-zero,
causing the PI block output to change. This results in a higher or lower level of current
flowing through the armature until the feedback again becomes equal to the reference.
Figure 6.1 shows the details of the CML reference path. Figure 6.2 shows the details of
the CML regulator block diagram.
OCL TYPE3
POSN REG EN
FWD/REV
From Figure 9.1, Outer
Control Loop Block
Diagram
ENABLED
EN
From Figure 5.1, Speed Loop Block Diagram
*SPD LOOP CUR LIM
CML REF
LIMIT SELECT
REGISTER
POSITIVE
CURRENT LIM
From Figure 4.2, Speed
Reference Source Select
Block Diagram
*DISABLED
(SPD LOOP OUTPUT)
(J15 REGULATOR
TYPE)
CURRENT/TORQUE
From Figure 5.1,
Speed Loop Block
+
MAXIMUM NORMALIZED
CURRENT INERTIA
S-curve rate output from
Figure 4.5, Speed Reference
Ramp Block Diagram
Software
Scaling
0
*SPEED/VOLTAGE
EN
+
UNDERWIND
ENABLE
INERTIA
*NONE COMP
INTERNAL SELECT
LIMIT
LO
From Figure 5.1, Speed
Loop Block Diagram
*SPD LOOP PI LIMITS
NEGATIVE
CURRENT LIM
RATELIM
ACC
DEC
To
Figure 6.2,
Current
Minor Loop
Block
Diagram
CML REF
RATE LIMIT
ANALOG IN 1
From Figure 11.2,
ANALOG IN 2
Analog Inputs Block
Diagram
NETW IN REG 1, 2, 3
From Network
NEG CUR LIM
INV EN
(CML
REFERENCE)
HI
EN
CML REF
LIMIT SELECT
* = Default Selection
REGISTER
Figure 6.1 – Current Minor Loop Reference Path Block Diagram
Configuring the Current Minor Loop
6-1
6.1
Configuring Inertia Compensation
INERTIA COMP SELECT
Selects the source of
the inertia
compensation signal.
(P.221)
Parameter Range:
NONE
INTERNAL
ANALOG IN
ANALOG IN
The analog input
choices are only
available if the I/O
Expansion kit is
installed.
1
2
1
2
NETW IN REG 3
NETW IN REG
NETW IN REG
Default Setting:
NONE
Parameter Type:
Configurable
OIM Menu Path(s):
Speed/Voltage Loop (SPD) - Speed/Voltage Loop
(SPD) Tuning
When INTERNAL is selected, the inertia compensation signal is generated by scaling
the rate output from the speed/voltage loop S-curve block based on the combined
inertia of the motor and its connected load.
Inertia compensation circuit supports constant diameter, constant field current
applications. The compensation signal is summed with the speed/voltage loop PI
block output to form the reference to the CML.
When INTERNAL is selected, rate output from the speed/voltage loop S-curve block
is scaled based on the combined inertia of the motor and its connected load, as set
through the NORMALIZED INERTIA (P.222).
A network kit must be installed to select the network input registers (NETW IN REG 1,
2, or 3). Note that the network input registers are updated only when CONTROL
SOURCE (P.000) is set to NETWORK and the network is active.
MAXIMUM CURRENT
(P.007)
The highest amount
of current (positive or
negative) for a given
application.
Parameter Range:
25 to 200 %FLA
Default Setting:
150 %FLA
Parameter Type:
Configurable
This input is the basis
of armature current
scaling.
OIM Menu Path(s):
Current Minor Loop (CML) - CML Feedback Scaling
MAXIMUM CURRENT
is limited to 200% of MOTOR RATED ARM AMPS.
The setting of MAXIMUM CURRENT can affect the value of J18 ARM I FB RESISTOR
(P.395). Check J18 ARM I FB RESISTOR (P.395) and the setting of the J18 jumper if
you change MAXIMUM CURRENT.
6-2
FlexPak 3000 DC Drive Software Reference
NORMALIZED INERTIA
(P.222)
The time required to
accelerate the motor
and load inertia from
zero to motor base
speed at MOTOR
Parameter Range:
0.05 to 65.20 seconds
Default Setting:
1.00 second
Parameter Type:
Tunable
RATED ARM VOLTS
(P.009) and MOTOR
HOT FLD AMPS (P.510).
OIM Menu Path(s):
Speed/Voltage Loop (SPD) - Speed/Voltage Loop
(SPD) Tuning
This parameter is set by the speed loop self-tuning procedure. You can also enter it
directly. Self-tuning will overwrite values entered manually.
6.2
Selecting and Conditioning CML Reference Selection
A hardware jumper, J15, configures the drive as a current/torque or speed/voltage
regulator. When J15 is set to CURRENT, the input signal TORQUE REFERENCE (P.189) is
the CML reference. TORQUE REFERENCE can come from an analog input, frequency
input, or a network master. When J15 is set to SPEED, the signal SPD LOOP OUTPUT
(P.299) is the CML reference. The software reads the setting of hardware jumper J15
only at powerup. See the hardware manual for information on setting jumpers.
The selected CML reference passes through an amplitude limit block and a rate limit
block. See figure 6.1 for the block diagram.
The amplitude limit block prevents the reference signal from becoming greater than or
less than the limits selected by CML REF LIMIT SELECT (P.311). These limits can be
either the values set by parameters NEGATIVE CURRENT LIM (P.006) and POSITIVE
CURRENT LIM (P.005), or the limit values being used by the speed loop PI block.
The rate limit block limits the rate of change of the selected CML reference based on
value you input for CML REF RATE LIMIT (P.303). CML REF RATE LIMIT (P.303) defines the
minimum allowable time (in milliseconds) that the reference can change from zero to
MAXIMUM CURRENT (P.007). When the drive is stopped, the output of the rate limit block
is clamped to zero. The amplitude and rate-limited CML reference appears as the
output parameter CML REFERENCE (P.396).
CML REF LIMIT SELECT
Selects the source for
the CML positive and
negative current
limits.
(P.311)
Parameter Range:
1 = SPD LOOP PI LIMITS
2 = REGISTER
Default Setting:
1
Parameter Type:
Configurable
OIM Menu Path(s):
Additional Parameters (listed by parameter number)
If you select REGISTER, the CML
NEGATIVE CURRENT LIM (P.006).
loop limits are POSITIVE CURRENT LIM (P.005) and
If you select SPD LOOP PI LIMITS, the CML loop reference limits are the same as those
used by the speed loop PI block.
Configuring the Current Minor Loop
6-3
CML REF RATE LIMIT
Minimum time for CML
REFERENCE to change
from zero to MAXIMUM
CURRENT.
(P.303)
Parameter Range:
1 to 1000 msec
Default Setting:
40 msec
Parameter Type:
Tunable
OIM Menu Path(s):
Current Minor Loop (CML) - CML Tuning
This parameter is set by the CML self-tuning procedure. You can also enter it
directly. Self-tuning will overwrite values entered manually.
CML REFERENCE
The amplitude and
rate limited value of
the selected CML
reference.
(P.396)
Parameter Range:
n/a
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Current Minor Loop (CML) - CML Test Points
NEG CUR LIM INV EN
Enables or disables
the negative current
limit inverter to the
speed loop PI block
low limit input.
(P.226)
Parameter Range:
DISABLED
ENABLED
Default Setting:
ENABLED
Parameter Type:
Configurable
OIM Menu Path(s):
Additional Parameters (listed by parameter number)
When this parameter is set to ENABLED, POSITIVE CURRENT LIM (P.005) and NEGATIVE
(P.006) are restricted to positive values.
CURRENT LIM
When this parameter is set to DISABLED, the range of NEGATIVE CURRENT LIM (P.006)
is restricted to negative values.
When you change this parameter value:
• Alarm A00052 occurs.
• The parameters NEG CURRENT LIM SEL (P.224) and POS CURRENT LIM SEL (P.223)
are automatically set to REGISTER.
• The value of NEGATIVE CURRENT LIM (P.006) is inverted. For example, if NEG CUR
LIM INV EN is set to ENABLE and NEGATIVE CURRENT LIM is set to 150% FLA,
changing NEG CUR LIM INV EN to DISABLED causes the value of NEGATIVE CURRENT
LIM to change to –150% FLA.
Carefully check your current limit scheme and the values of POSITIVE CURRENT LIM
(P.005) and NEGATIVE CURRENT LIM (P.006) to avoid unintended drive operation.
6-4
FlexPak 3000 DC Drive Software Reference
TORQUE REFERENCE
Torque (current)
reference value.
(P.189)
Parameter Range:
n/a
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Current Minor Loop (CML) - CML Test Points
Used as the CML reference when the drive is configured as a current/torque
reference. See section 6.3.
UNDERWIND ENABLE
Setting this bit to 1
enables two inverter
blocks that permit
underwind operation.
Parameter Range:
0 = DISABLED (overwind)
1 = ENABLED (underwind)
Default Setting:
0
Setting this bit to 0
disables the two
inverter blocks and
permits overwind
operation.
Parameter Type:
Configurable
OIM Menu Path(s):
This parameter is only available over the network. It
cannot be viewed through the OIM.
Refer to the appropriate network communication manual for register map
assignments.
To use this register, CONTROL SOURCE must be set to NETWORK and NETW REGISTER
MAP SEL (P.914) must be set to ALTERNATE.
The inverters are located on the speed loop feedback path (figure 5.1) and the CML
reference path (figure 6.1).
If CONTROL SOURCE is changed from NETWORK to any other control source, the
UNDERWIND ENABLE bit is set to the default of DISABLED. If the setting was ENABLED,
the motor can rotate in the opposite direction when the drive is restarted with a
control source other than the network.
!
Configuring the Current Minor Loop
ATTENTION: When CONTROL SOURCE is changed from NETWORK to
another value, UNDERWIND ENABLE is forced to DISABLED. This could cause
the motor to rotate in the opposite direction than it did under network
control. The active speed reference should be set to zero before starting
the drive from the new control source. Slowly increase the speed
reference until the proper rotation direction can be determined. If it is
incorrect, change the setting of the FORWARD/REVERSE input. The active
speed reference is based on the new control source and the auto or
manual setting. Failure to observe this precaution could result in severe
bodily injury or loss of life.
6-5
6.3
Configuring the Armature Current Feedback
Current transformers and a rectifier bridge are used to determine the armature current
feedback signal that is scaled by a burden resistor (hardware scaling). Ideally, the
selected burden resistor would scale the feedback signal so that 3 volts corresponds
to MAXIMUM CURRENT (P.007). However, since burden resistor selection is limited to
one of four values, it is likely that none of the available burden resistors will result in
ideal scaling. Therefore, software scaling is used to adjust the output of the A/D
converter to the appropriate level. The FlexPak 3000 drive automatically calculates
and sets the software scale factor based on CT TURNS RATIO (P.010), MOTOR RATED
ARM AMPS (P.008), and MAXIMUM CURRENT (P.007). After these parameters have been
set appropriately, hardware jumper J18 must be set according to parameter J18 ARM I
FB RESISTOR (P.395).
An additional gain block in the feedback path allows you to adjust the current feedback
signal by a maximum of ±10% (gain range of 0.900 to 1.100). The CML FEEDBACK GAIN
ADJ (P.300) is typically set for unity gain.
The FlexPak 3000 drive limits the combination of the two gains (software and user
scale factors) to a range of 0.800 and 2.000. For example, suppose the FlexPak 3000
drive sets the software scale factor to 1.950. CML FEEDBACK GAIN ADJ (P.300) is limited
to a maximum value of 1.025 (2.000/1.950) to prevent the combined gain from
exceeding 2.000.
The scaled CML feedback value appears as CML FEEDBACK (P.397).
See figure 6.2 for block diagram.
From Figure 6.1, Current
Minor Loop Reference
Path Block Diagram
Figure 6.2 – Current Minor Loop Block Diagram
6-6
FlexPak 3000 DC Drive Software Reference
CML FEEDBACK
The CML feedback
signal after all
hardware and
software scaling.
(P.397)
Parameter Range:
n/a
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Current Minor Loop (CML) - SCR Diagnostics Armature Phase Fire Test
Current Minor Loop (CML) - CML Feedback Scaling
Current Minor Loop (CML) - CML Test Points
CML FEEDBACK GAIN ADJ
The CML feedback
gain adjustment. In
most cases, this is
set for unity gain.
Typically, it will be set
to 1.000.
(P.300)
Parameter Range:*
0.900 to 1.100
Default Setting:
1.000
Parameter Type:
Tunable
OIM Menu Path(s):
Current Minor Loop (CML) - CML Feedback Scaling
*The range might be affected by the software scaling factor calculated by the drive.
J18 ARM I FB RESISTOR
Indicates the burden
resistor position
required to properly
scale armature
current feedback.
(P.395)
Parameter Range:
1 (15 Ω)
2 (20 Ω)
3 (30 Ω)
4 (39 Ω)
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Drive Information – Correct Scaling Jumper Positions
Current Minor Loop (CML) – CML Feedback Scaling
Quick Start
The value of this parameter is based on the values of CT TURNS RATIO (P.010),
MAXIMUM CURRENT (P.007), and MOTOR RATED ARM AMPS (P.008). If you change any
one of these parameters, check the reading of J18 ARM I FB RESISTOR and make
sure the setting of jumper J18 on the Regulator board matches.
Configuring the Current Minor Loop
6-7
MOTOR RATED ARM AMPS
The rated armature
current from the
motor nameplate.
(P.008)
Parameter Range:
0 to 3000.0 amps
Default Setting:
8.0 amps
Parameter Type:
Configurable
OIM Menu Path(s):
Current Minor Loop (CML) - CML Feedback Scaling
Quick Start
The setting of MOTOR RATED ARM AMPS can affect the value of J18 ARM I FB RESISTOR
(P.395). Check J18 ARM I FB RESISTOR (P.395) and the setting of the J18 jumper if
you change MOTOR RATED ARM AMPS.
This value is used by the internal I2t motor thermal overload function. This function
allows for continuous operation at 100% current and 60 seconds of operation at
150% of rated MOTOR RATED ARM AMPS (P.008) following an inverse time overload
curve.
!
CT TURNS RATIO
The drive current
transformer turns
ratio (Tp/Tn).
See Regulator board
replacement
instructions for
information on
determining the CT
TURNS RATIO. This
parameter is not
restored if a Restore
Defaults is done.
ATTENTION: This parameter must be less than the motor rated armature
amps or drive current rating listed on the motor nameplate. If this is
configured incorrectly, overcurrent or excess heating of the motor could
result. Failure to observe this precaution could result in damage to, or
destruction of, the equipment.
(P.010)
Parameter Range:
139
208
417
833
2000
5230
OTHER
Default Setting:
n/a
(set at the factory based on the drive horsepower and
AC line voltage.)
Parameter Type:
Configurable
OIM Menu Path(s):
Current Minor Loop (CML) - CML Feedback Scaling
The setting of CT TURNS RATIO can affect the value of J18 ARM I FB RESISTOR (P.395).
Check J18 ARM I FB RESISTOR (P.395) and the setting of the J18 jumper if you change
CT TURNS RATIO.
!
6-8
ATTENTION: The CT TURNS RATIO parameter is used in the calculation
of the burden resistor value. Do not change the parameter from its factory
default value unless you are replacing the Regulator board. Failure to
observe this precaution could result in damage to, or destruction of, the
equipment.
FlexPak 3000 DC Drive Software Reference
Drive Current Transformer Turns Ratio (Tp/Tn)
Value to Enter
1.5 HP @ 230 VAC / 3 HP @ 460 VAC
139
2 thru 7.5 HP @ 230 VAC / 5 thru 15 HP @ 460 VAC
208
10 thru 15 HP @ 230 VAC / 20 thru 30 HP @ 460 VAC
417
20 thru 30 HP @ 230 VAC / 40 thru 60 HP @ 460 VAC
833
40 thru 75 HP @ 230 VAC / 75 thru 150 HP @ 460 VAC
2000
100 thru 150 HP @ 230 VAC / 200 thru 300 HP @ 460 VAC
5230
400 to 600 HP @ 460 VAC
7770
7A
139
29A
208
55A
417
110A
833
265A
2000
6.4
Configuring the CML Forward Path
The proportional-integral (PI) controller adjusts the armature firing angle, ARMATURE
DELTA (P.399), to compensate for any difference between the reference and the
feedback signals. When the drive is stopped, this block’s output is clamped to zero.
Proportional gain is set by CML PI PROP GAIN (P.301). The integral time constant can be
changed by adjusting CML PI LEAD FREQUENCY (P.302)
ARMATURE BRIDGE POL
Indicates which
bridge is currently
active. OFF indicates
the forward bridge.
ON indicates the
reverse bridge.
(P.394)
Parameter Range:
OFF
ON
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Current Minor Loop (CML) - CML Test Points
Configuring the Current Minor Loop
6-9
ARMATURE DELTA
(P.399)
Indicates the
armature firing angle
in microseconds.
Parameter Range:
n/a
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Current Minor Loop (CML) - CML Test Points
Current Minor Loop (CML) - SCR Diagnostics Armature Phase Fire Test
CML ERROR
(P.398)
The CML error signal.
It is the difference
between CML
REFERENCE (P.396)
and CML FEEDBACK
(P.397).
Parameter Range:
n/a
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Current Minor Loop (CML) - CML Test Points
CML PI LEAD FREQUENCY
The lead break
frequency for the CML
proportional-integral
(PI) block.
(P.302)
Parameter Range:
10 to 500 RAD/S
Default Setting:
100 RAD/S
Parameter Type:
Tunable
OIM Menu Path(s):
Current Minor Loop (CML) - CML Tuning
This parameter is set by the CML self-tuning procedure. You can also enter it
directly. Self-tuning will overwrite values entered manually.
CML PI PROP GAIN
(P.301)
Proportional gain for
the CML proportionalintegral (PI) block.
Parameter Range:
0.000 to 4.000
Default Setting:
0.250
Parameter Type:
Tunable
OIM Menu Path(s):
Current Minor Loop (CML) - CML Tuning
This parameter is set by the CML self-tuning procedure. You can also enter it
directly. Self-tuning will overwrite values entered manually.
6-10
FlexPak 3000 DC Drive Software Reference
CHAPTER 7
Configuring the Metering Outputs
The FlexPak 3000 drive offers two filtered outputs that can be used to source external
meters. These outputs are at terminals 24 through 26 on the Regulator board. See the
hardware manual for information on wiring these outputs.
These outputs can be modified by the parameters described in this chapter.
From Figure 6.2, Current Minor
Loop Block Diagram
From Figure 5.1, Speed Loop
Block Diagram
From Figure 4.5, Speed Reference
Ramp Block Diagram
From Figure 4.2, Speed Reference Source
Select Block Diagram
From Figure 4.5, Speed Reference Ramp Block Diagram
From Figure 5.1, Speed Loop Block Diagram
From Figure 9.1, Outer Control Loop Block Diagram
From Figure 8.1, Field Block DIagram if Field
Current Regulator Kit is Installed
Figure 7.1 – Metering Outputs Block Diagram
Configuring the Metering Outputs
7-1
METER OUT
1 GAIN ADJ (P.400)
Scales the meter
output 1 signal at the
Regulator board
terminal strip.
Parameter Range:
1.100 to 1.900
Default Setting:
1.000
Parameter Type:
Tunable
OIM Menu Path(s):
Input/Output - Meter Outputs
METER OUT 1 SELECT (P.404) can be set to FULL SCALE for an accurate gain
adjustment. See figure 7.1.
Adjust the zero point (METER OUT 1 ZERO ADJ (P.402)) before adjusting gain.
METER OUT
1 SELECT (P.404)
Selects the drive
output that will source
meter output 1
(terminals 24 and 25
on the Regulator
board).
METER OUT
Parameter Range:
See table 7.1 for options
Default Setting:
CML FEEDBACK
Parameter Type:
Tunable
OIM Menu Path(s):
Input/Output - Meter Outputs
1 ZERO ADJ (P.402)
Removes any offset
from the meter
output 1 signal at the
Regulator board
terminal strip.
Parameter Range:
–200 to 200
Default Setting:
0
Parameter Type:
Tunable
OIM Menu Path(s):
Input/Output - Meter Outputs
1 SELECT (P.404) can be set to ZERO for an accurate zero adjustment.
See figure 7.1.
METER OUT
7-2
FlexPak 3000 DC Drive Software Reference
METER OUT
2 GAIN ADJ (P.401)
Scales the meter
output 2 signal at the
Regulator board
terminal strip.
Parameter Range:
0.100 to 1.900
Default Setting:
1.000
Parameter Type:
Tunable
OIM Menu Path(s):
Input/Output - Meter Outputs
METER OUT 2 SELECT (P.405) can be set to FULL SCALE for an accurate gain
adjustment. See figure 7.1.
Adjust the zero point (METER OUT 2 ZERO ADJ (P.403)) before adjusting gain.
METER OUT
2 SELECT (P.405)
Selects the drive
output that will source
meter output 2
(terminals 25 and 26
on the Regulator
board).
METER OUT
Parameter Range:
See table 7.1 for options
Default Setting:
SPD LOOP FEEDBACK
Parameter Type:
Tunable
OIM Menu Path(s):
Input/Output - Meter Outputs
2 ZERO ADJ (P.403)
Removes any offset
from the meter
output 2 signal at the
Regulator board
terminal strip.
Parameter Range:
–200 to 200
Default Setting:
0
Parameter Type:
Tunable
OIM Menu Path(s):
Input/Output - Meter Outputs
2 SELECT (P.405) can be set to ZERO for an accurate zero adjustment.
See figure 7.1.
METER OUT
Configuring the Metering Outputs
7-3
Table 7.1 – Options for Metering Parameters
Signal Selected
(P.397)
(P.396)
CML ERROR (P.398)
SPD LOOP OUTPUT (P.299)
CML FEEDBACK
CML REFERENCE
Full Scale Value
MAXIMUM CURRENT
MOTOR RATED ARM AMPS × -----------------------------------------------------------100
or
MAXIMUM CURRENT
(P.296)
(P.295)
SPD LOOP ERROR (P.297)
SPEED RAMP OUTPUT (P.199)
SPEED RAMP INPUT TP (P.198)
SPD SOURCE SELECT OUT (P.193)
TRIM OUTPUT (P.197)
ANALOG TACH FEEDBACK (P.291)
PULSE TACH FEEDBACK (P.292)
OCL OUTPUT (P.848)
SPD LOOP FEEDBACK
(amps)
(% full load amps)
TOP SPEED (RPM)
SPD LOOP REFERENCE
ARMATURE VOLTAGE
(P.289)
POWER OUTPUT
(volts)
MAXIMUM CURRENT
MOTOR RATED ARM VOLTS × MOTOR RATED ARM AMPS × -----------------------------------------------------------100
(P.590)
(P.589)
FIELD REFERENCE
FIELD FEEDBACK
MOTOR RATED ARM VOLTS
(P.845)
(P.846)
OCL FEEDBACK (P.847)
NETW IN REG 1 (P.905)
NETW IN REG 2 (P.906)
NETW IN REG 3 (P.907)
OCL REFERENCE
MOTOR HOT FLD AMPS
watts
(amps)
4095 (counts)
OCL RAMP OUTPUT
FULL SCALE
ZERO
7-4
0
FlexPak 3000 DC Drive Software Reference
CHAPTER 8
Configuring the Field Supply
The FlexPak 3000 drive can be used with one of three types of field supplies:
• Standard Field Supply: Provides field control for the standard drive. All configuration
for the standard field supply is through hardware. There are no parameters related
to the standard field supply. This supply generates a fixed field voltage and does not
provide field economy.
• Optional Enhanced Field Supply: Provides electronic field trim, field economy, and
higher voltage field supplies than the standard field supply. The Enhanced Field
Supply kit must be installed to use this field supply.
• Field Current Regulated Supply: Replaces the standard or enhanced field excitation
supply with a current regulated supply. It provides user-adjustable field economy,
constant horsepower operation, and user-adjustable field loss. The Field Current
Regulator kit must be installed to use this field supply.
The Field Current Regulator kit is standard for drives that are 150 to 600HP @
460VAC or 75 to 300HP at 230VAC. It is optional for lower HP drives.
The parameters you will configure for the field supply depend on the supply that is
installed in your drive. You can check FLD CURRENT REGULATOR (P.586) to determine if
the Field Current Regulator kit is installed. If FLD CURRENT REGULATOR (P.586) reports
NOT INSTALLED, you have either the standard field supply, an Enhanced Field Supply
kit, or an incorrectly installed or failed Field Current Regulator kit. Check your drive
and installation notes to verify the type of field supply.
FLD CURRENT REGULATOR
Indicates whether or
not the Field Current
Regulator kit is
installed. If it is
installed, lists the
rating of the kit that is
installed.
Note that if “20 AMP”
is displayed, a
15 amp Field Current
Regulator kit is
installed.
Configuring the Field Supply
(P.586)
Parameter Range:
NOT INSTALLED
4 AMP
10 AMP
20 AMP
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Field - Field Current Regulator
Field - Standard/enhanced Field Supply
Drive Information
8-1
8.1
Configuring Field Economy
Field economy is available if the Enhanced Field Supply kit or Field Current Regulator
kit is installed. It is not available if you are using the standard field supply.
Field economy reduces the field voltage when the motor is at rest, reducing standby
power consumption and prolongs the insulation life of the motor field windings.
When the Field Current Regulator kit is installed, the drive enters field economy when
the drive is first powered up. When the armature becomes active, the drive goes to full
field. After the drive stops, field economy becomes active after the time specified by
FIELD ECONOMY DELAY (P.501). The field economy level is adjustable through FIELD
ECONOMY REF (P.511).
When the Enhanced Field Supply kit is installed, the drive powers up at full field. Field
economy is fixed at 45% of AC line voltage. After the drive stops, field economy
becomes active after the time specified by FIELD ECONOMY DELAY (P.501).
FIELD ECONOMY ACTIVE
(P.599) indicates when field economy is active.
The field current reference for the field loop changes depending on whether or not
field economy is active. If field economy is:
• Inactive: FIELD REF REGISTER (P.513) is limited and is the field current reference.
• Active: MOTOR HOT FLD AMPS (P.510) and FIELD ECONOMY REF (P.511) are multiplied
and used as the field current reference.
You can check the value of the field current reference by looking at FIELD REFERENCE
(P.590). This reference is summed with FIELD FEEDBACK and fed into the field PI block.
If the Field Current Regulator kit is installed, you can adjust the field economy current
level using FIELD ECONOMY REF (P.511). FIELD ECONOMY REF and/or FIELD REF REGISTER
(P.513) must be above FIELD LOSS THRESHOLD (P.512) to avoid field loss faults. The
field loss logic is disabled while in field economy.
!
FIELD ECONOMY ACTIVE
Indicates the present
state of field
economy.
This parameter has
no effect if the
standard field supply
is installed.
8-2
ATTENTION: The incorrect configuration of these parameters can cause
a motor overvoltage condition. Configure MOTOR HOT FLD AMPS (P.510)
to the motor’s nameplate value. Failure to observe this precaution can
result in bodily injury and damage to the equipment.
(P.599)
Parameter Range:
ON
OFF
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Field - Standard/enhanced Field Supply
Field - Field Current Regulator - Field Loop Test
Points
FlexPak 3000 DC Drive Software Reference
FIELD ECONOMY DELAY
After the motor stops,
the drive maintains
full field for FIELD
ECONOMY DELAY
minutes before
entering field
economy.
(P.501)
Parameter Range:
0 to 27 minutes
Default Setting:
5 minutes
Parameter Type:
Tunable
OIM Menu Path(s):
Field - Standard/enhanced Field Supply
Field - Field Current Regulator - Field Loop Configure
When the motor starts again, the drive immediately returns to full field. FIELD
does not affect operation of the standard field supply. Field
economy cannot be disabled.
ECONOMY DELAY
This parameter has no effect when the Enhanced Field Supply kit or standard field
supply is installed.
FIELD ECONOMY REF
Only available if the
Field Current
Regulator kit is
installed.
(P.511)
Parameter Range:
0 to 100%
Default Setting:
0%
Parameter Type:
Tunable
OIM Menu Path(s):
Field - Field Current Regulator - Field Loop Configure
The percentage of MOTOR HOT FLD AMPS (P.510) set as a reference for field
economy mode. This parameter must be set above the FIELD LOSS THRESHOLD
(P.512) value to avoid field loss faults.
This parameter has no effect when the Enhanced Field Supply kit or standard field
supply is installed.
FIELD REF REGISTER
Current reference for
the field control loop.
This is the field
current reference
when the drive is not
in field economy.
(P.513)
Parameter Range:
0 to MOTOR HOT FLD AMPS
Default Setting:
MOTOR HOT FLD AMPS
Parameter Type:
Tunable
OIM Menu Path(s):
Field - Field Current Regulator - Field Loop Tuning
FIELD REF REGISTER should be set greater than FIELD LOSS THRESHOLD (P.512) to
avoid FIELD LOSS faults.
Only available if the Field Current Regulator kit is installed.
Configuring the Field Supply
8-3
8.2
Configuring the Enhanced Field Supply
These parameters are available only if the Enhanced Field Supply kit is installed.
ENHANCED FLD VOLT ADJ
(P.500)
Adjusts the field
output voltage.
Parameter Range:
0 to 180 (J21 set to B-C)
0 to 120 (J21 set to A-C)
ENHANCED FLD VOLT
ADJ has no effect on
Default Setting:
84
0 when the Field Current Regulator kit is installed
Parameter Type:
Tunable
OIM Menu Path(s):
Field - Standard/enhanced Field Supply
the operation of the
standard field supply
or the Field Current
Regulator kit.
Increasing ENHANCED FLD VOLT ADJ increases the output voltage at the F1 and F2
terminals. Decreasing ENHANCED FLD VOLT ADJ decreases the output voltage.
ENHANCED FLD VOLT ADJ has no effect
ECONOMY ACTIVE (P.599) reads ON).
when the drive is in field economy (FIELD
See the Enhanced Field Supply kit manual for detail on setting this jumper.
J20 FIELD LOSS DETECT (P.597)
Indicates the position
of jumper J20, FIELD
LOSS DETECT, which
enables or disables
field current loss
detection. This
jumper is only read
on powerup.
Parameter Range:
ENABLE
DISABLE
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Drive Information
Field - Standard/enhanced Field Supply
J20 should only be set to the DISABLE position when an external field supply is used.
Important: Jumper J20 is ignored if the Field Current Regulator kit is installed.
Therefore, placing J20 in the DISABLE position will not disable field loss
detection. See manual D2-3336 for information on the Field Current
Regulator kit.
!
8-4
ATTENTION: The user must provide external field current loss detection
and inhibit drive operation using one of the drive interlocks when this
jumper is positioned to DISABLE. Misapplication of this jumper can cause
the motor to run at dangerously high speeds. Provide external field
current loss detection and inhibit drive operation using one of the drive
interlocks if this jumper is positioned to DISABLE. Failure to observe this
precaution could result in bodily injury.
FlexPak 3000 DC Drive Software Reference
J21 FLD SUPPLY JUMPER
Indicates the position
of Regulator board
jumper J21, FIELD
SUPPLY. It does not
indicate the position
of the jumper on the
Enhanced Field
Supply kit.
(P.598)
Parameter Range:
A -C
B -C
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Drive Information
Field - Standard/enhanced Field Supply
This jumper must be at the same setting as the jumper on the Enhanced Field
Supply kit, positions A-C or B-C.
This jumper is only available if the Enhanced Field Supply kit is installed. This
jumper is only read on powerup.
8.3
Configuring the Field Current Regulated Supply
These parameters are only available if the Field Current Regulator kit is installed.
The Field Current Regulator kit replaces the standard field excitation supply with a
current regulated supply. It provides field economy and constant horsepower (above
base speed) operation. See figure 8.1 for the block diagram. See the Field Current
Regulator kit manual, D2-3336, for a full description of the field block.
From Figure 11.2, Analog
Inputs Block Diagram
* Default Selection
Figure 8.1 – Field Block DIagram if Field Current Regulator Kit is Installed
Configuring the Field Supply
8-5
FIELD DELTA
(P.588)
The field firing angle
in degrees.
FIELD FEEDBACK
Motor field current
feedback signal after
scaling and gain.
Parameter Range:
0 to 180 DEGREE
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Field - Field Current Regulator - Field Loop Test
Points
(P.589)
Parameter Range:
+/-MOTOR HOT FLD AMPS
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Field - Field Current Regulator - Field Loop Feedback
Scaling
Field - Field Current Regulator - Field Loop Test
Points
FIELD PI LEAD FREQ
Lead frequency for
the field current PI
block.
Parameter Range:
0 to 282.70 RAD/S
Default Setting:
1.50 RAD/S
Parameter Type:
Tunable
OIM Menu Path(s):
Field - Field Current Regulator - Field Loop Tuning
FIELD PI PROP GAIN
Proportional gain
setting for the field
current PI block.
8-6
(P.515)
(P.514)
Parameter Range:
0.10 to 128.00
Default Setting:
0.50
Parameter Type:
Tunable
OIM Menu Path(s):
Field - Field Current Regulator - Field Loop Tuning
FlexPak 3000 DC Drive Software Reference
FIELD REF SELECT
(P.521)
Selects the reference
source for the field
current regulator.
Parameter Range:
1 = REGISTER
2 = ANALOG MAN TRIM REF
3 = ANALOG IN 1
4 = ANALOG IN 2
Default Setting:
1
Parameter Type:
Configurable
OIM Menu Path(s):
Additional Parameters (listed by parameter number)
An I/O Expansion kit must be installed to select ANALOG IN 1 or ANALOG IN 2.
is the FIELD REF REGISTER (P.513), which can also be modified through a
network register (drop_1, register 37).
REGISTER
FIELD REFERENCE
(P.590)
Field current
reference.
Parameter Range:
n/a
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Field - Field Current Regulator - Field Loop Test
Points
When FIELD ECONOMY ACTIVE (P.599) is OFF, it is the limited value of the selected
field reference.
When FIELD ECONOMY ACTIVE (P.599) is ON, it is the field economy reference.
FLD FEEDBACK GAIN ADJ
Gain adjustment for
the field current
feedback.
In most cases, this
will be set for unity
gain (1.000).
Configuring the Field Supply
(P.516)
Parameter Range:
0.900 to 1.100
Default Setting:
1.000
Parameter Type:
Tunable
OIM Menu Path(s):
Field - Field Current Regulator - Field Loop Feedback
Scaling
8-7
MOTOR HOT FLD AMPS
Motor nameplate
value of the rated hot
field amps. This input
is the basis of field
current scaling.
(P.510)
Parameter Range:
0.11 to installed supply rating (4.00, 10.00, or 20.00
amps)
Default Setting:
0.01 amps
Parameter Type:
Configurable
OIM Menu Path(s):
Field - Field Current Regulator - Field Loop Feedback
Scaling
If the factory defaults are restored, or if a valid value has not yet been entered for
this parameter, the DC field voltage is fixed at 150V on a 230VAC line, or at 300V
on a 460VAC line.
!
ATTENTION: The incorrect configuration of this parameter can cause a
motor overvoltage condition. Configure MOTOR HOT FLD AMPS (P.510) to
the motor nameplate value. Failure to observe this precaution can result
in bodily injury and damage to the equipment.
8.3.1 Configuring Automatic Field Weakening
The Field Current Regulator kit can provide automatic field weakening. Field
weakening can only be used with speed-regulated drives.
Important: Automatic field weakening cannot be used if FEEDBACK SELECT is set to
ARMATURE VOLT.
When ARMATURE VOLTAGE (P.289) exceeds FLD WEAKEN THRESHOLD (P.518), the field
begins to weaken and the field control loop begins regulating armature voltage. When
field auto weakening is enabled, the drive uses the values of ARMATURE VOLTAGE
(P.289) and FLD WEAKEN THRESHOLD (P.518) to try to maintain a zero input to the first PI
block. If armature voltage increases, a negative value is input to the PI block, which
decreases the high limit to the next PI block. This reduces field current, subsequently
lowering the armature voltage, bringing the input to the first PI block closer to zero.
If IR compensation is used, the threshold where the field control loop begins regulating
armature voltage is FLD WEAKEN THRESHOLD (P.518) less IR COMPENSATION (P.206) at
rated armature current.
To use automatic field weakening, set FIELD AUTO WEAKEN (P.517) to ENABLE.
To turn off automatic field weakening, set FIELD AUTO WEAKEN (P.517) to DISABLE. If
automatic field weakening is disabled, the field current PI block high limit is fixed at 180
degrees.
If needed, you can use FLD WEAKEN LEAD FREQ (P.520) and FLD WEAKEN PROP GAIN
(P.519) to modify the lead frequency and gain of the field auto weaken PI block.
!
8-8
ATTENTION: The incorrect configuration of the parameters for this loop
can cause a motor overvoltage condition. Configure MOTOR HOT FLD AMPS
(P.510) to the motor’s nameplate value. Failure to observe this precaution
can result in bodily injury and damage to the equipment.
FlexPak 3000 DC Drive Software Reference
FIELD AUTO WEAKEN
Enables or disables
automatic field
weakening by the
field control loop.
When it is disabled,
the field current PI
block high limit is
fixed at 180 degrees.
(P.517)
Parameter Range:
DISABLED
ENABLED
Default Setting:
DISABLED
Parameter Type:
Configurable
OIM Menu Path(s):
Field - Field Current Regulator - Field Loop Configure
If FEEDBACK SELECT is set to ARMATURE VOLT, this is automatically set to DISABLED
and cannot be changed.
FIELD DELTA HIGH LIM
High limit of the field
current PI block.
(P.587)
Parameter Range:
0 to 180 DEGREE
Default Setting:
130 DEGREE
Parameter Type:
Configurable
OIM Menu Path(s):
Field - Field Current Regulator - Field Loop Configure
FIELD LOSS THRESHOLD
The value that is
compared to FIELD
FEEDBACK (P.589) to
check for field loss.
(P.512)
Parameter Range:
50 to 100% of MOTOR HOT FLD AMPS (P.510) when
FEEDBACK SELECT (P.200) is set to ARMATURE
VOLT
0 to 100% of MOTOR HOT FLD AMPS (P.510) when
FEEDBACK SELECT (P.200) is set to DC TACH, PULSE
TACH, or AC TACH
Default Setting:
60% of MOTOR HOT FLD AMPS (P.510)
Parameter Type:
Configurable
OIM Menu Path(s):
Field – Field Current Regulator – Field Loop
Configure
is set as a percentage of MOTOR HOT FLD AMPS. It is usually
set to 85% of the motor nameplate field weaken current.
FIELD LOSS THRESHOLD
Configuring the Field Supply
8-9
FLD WEAKEN LEAD FREQ
block lead
frequency of the field
control loop’s
armature voltage
regulator.
PI
Parameter Range:
0.01 to 282.70 RAD/S
Default Setting:
0.50 RAD/S
Parameter Type:
Tunable
OIM Menu Path(s):
Field - Field Current Regulator - Field Loop Tuning
FLD WEAKEN PROP GAIN
The proportional gain
of the field control
loop’s armature
voltage regulator.
(P.520)
(P.519)
Parameter Range:
0.01 to 128.00
Default Setting:
1.60
Parameter Type:
Tunable
OIM Menu Path(s):
Field - Field Current Regulator - Field Loop Tuning
FLD WEAKEN THRESHOLD
Sets the point at
which the field control
loop begins
regulating armature
voltage and the field
begins to weaken.
(P.518)
Parameter Range:
0 to 120% of MOTOR RATED ARM VOLTS (P.009)
Default Setting:
95% of MOTOR RATED ARM VOLTS (P.009)
Parameter Type:
Tunable
OIM Menu Path(s):
Field - Field Current Regulator - Field Loop Tuning
If IR compensation is used, the threshold is FLD WEAKEN THRESHOLD at rated
armature current.
8-10
FlexPak 3000 DC Drive Software Reference
CHAPTER 9
Configuring the Outer Control Loop
The outer control loop (OCL) is typically used to provide dancer position or tension
control in a web processing system. The OCL trims the speed/voltage loop reference
signal. The block diagram for the OCL is shown in figure 9.1.
The OCL can be configured as a:
• Type 1 position regulator, which uses proportional-only control in the forward path.
• Type 2 position regulator, which uses proportional-plus-integral control to reduce
steady state error to zero.
• Type 3 position regulator, which inputs the OCL output directly into the current minor
loop.
• Other OCL schemes.
To configure the OCL as a type 1 position regulator, set the lead break frequency (OCL
PI LEAD FREQ (P.809)) equal to zero (this sets the PI block to proportional only).
To configure the OCL as a type 2 position regulator, set the lead break frequency (OCL
(P.809)) to a non-zero value.
PI LEAD FREQ
When enabled, the OCL executes every 20 msec.
Important: Scaling units of some OCL parameters are not predefined and must be set
by you. See the OIM manual to create OCL user-defined units.
OCL REF REGISTER
From Figure 11.2, Analog
Inputs Block Diagram and
Figure 11.4, Frequency
Input Block Diagram
{
From Network
*REGISTER
ANALOG IN 1
OCL PI
PROP GAIN
OCL REF
ROUNDING
OCL
REFERENCE
SELECT
OCL TRIM RANGE
SMOOTHING
(OCL REFERENCE)
ANALOG IN 2
(OCL RAMP
OUTPUT)
S-CURVE
FREQUENCY IN
output of OCL
enable logic
NETW IN REG 1, 2, 3
RST\
ACC
CML FEEDBACK
DEC
{
ANALOG IN 2
WLD
OCL PI
LEAD FREQ
WLD
(OCL OUTPUT)
*DISABLED
GAIN
ENABLED
RST\
LO
OCL PROP
TRIM SELECT
TOP SPEED
OCL PI
NEGATIVE LIMIT
OCL
LEADLAG
SELECT
MUL
To Figure 4.7,
Speed Reference
Mode Select
Block Diagram
To Figure 6.1,
CML Ref Block
Diagram
GAIN
DIV
LEAD/LAG
INITV
L/L
(OCL FEEDBACK)
output of OCL
enable logic
*BYPASS
ANALOG IN 1
RST\
LAG/LEAD
RATIO
SPEED RAMP OUTPUT
(in RPM)
ABS
SPD LOOP OUTPUT
SPD LOOP OUTPUT
ANALOG AUTO REFERENCE
MUL
PI
–
*NONE
OCL FEEDBACK
SELECT
HI
KP
INITV
+
INITV
OCL REF
RAMP TIME
(CML FEEDBACK)
8 sample average
From Figure 11.2, Analog
Inputs Block Diagram
OCL PI
POSITIVE LIMIT
ANALOG AUTO REFERENCE
From Network
OCL LEADLAG
LOW FREQ
OCL LEADLAG
RATIO
NETW IN REG 1, 2, 3
output of OCL
enable logic
Figure 9.1 – Outer Control Loop Block Diagram
Configuring the Outer Control Loop
9-1
9.1
Enabling the Outer Control Loop
!
ATTENTION: An abrupt speed change could occur when the outer
control loop is enabled. Make sure proper safeguards are in place before
enabling the outer control loop. Failure to observe this precaution can
result in severe bodily injury or loss of life.
To enable the OCL, either the I/O Expansion kit must be installed, CONTROL SOURCE
must be set to NETWORK, or DIG IN 0 SELECT (P.428) must set to OCL ENABLE.
The OCL enable signal (OCL ENABLE (P.849)) must be ON to execute the OCL. If it is OFF
or if the drive is not running, all OCL functions (S-curve, PI, and lead/lag) are held in
reset and OCL OUTPUT (P.848) is zero.
Table 9.1 shows the source of the OCL enable signal for the various control sources.
Table 9.1 – OCL Enable Signal Source
Control Source
I/O Expansion Board
Installed
OCL Enable Signal Source
NETWORK
n/a
Network OCL Enable
KEYPAD, TERMBLK,
Yes
I/O Expansion kit Digital Input
5 (terminal 64)
No
Regulator board Digital
Input 0 (terminal 12) set to 0
or SERIAL
To check the status of the OCL ENABLE, see parameter OCL ENABLE (P.849).
The OCL enable logic is shown in figure 9.2.
* Default Selection
Figure 9.2 – Outer Control Loop Enable Logic
9-2
FlexPak 3000 DC Drive Software Reference
DIG IN
0 (P.490)
Indicates the state of
digital input 0
(terminal 12 on the
Regulator board).
Parameter Range:
ON
OFF
(see table 9.2 for detail)
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Additional Parameters (listed by parameter number)
0 is ON when +24VDC is applied for more than 10msec. It is OFF when 0VDC
is applied.
DIG IN
Table 9.2 – Conditions Indicated by DIG IN 0 (P.490)
DIG IN
Condition if DIG IN 0 (P.490) Reads:
0 SELECT (P.428)
Setting
ON
OFF
BRUSH WEAR INPUT
OK
Worn
JOG SPEED SELECT
Jog Speed 2 active
Jog Speed 1 active
OCL ENABLE
DIG IN
OCL
enabled
OCL
disabled
0 SELECT (P.428)
Determines which
function is controlled
by digital input 0
(terminal 12 on the
Regulator board).
Parameter Range:
1 = BRUSH WEAR INPUT
2 = JOG SPEED SELECT
3 = OCL ENABLE
Default Setting:
1
Parameter Type:
Configurable
OIM Menu Path(s):
Additional Parameters (listed by parameter number)
The signal can be:
•
OCL ENABLE:
NETWORK
•
Enables the outer control loop if CONTROL SOURCE is not set to
and if the I/O Expansion kit is not installed.
BRUSH WEAR :
The input is from a brush wear indicator. If the input is OFF, the
alarm is generated. You must have the E.S.P. Brush
Monitor Detector kit installed to use this option.
MOTOR BRUSH WEAR LOW
•
JOG SPEED SELECT:
SPEED
Configuring the Outer Control Loop
The input determines whether JOG SPEED 1 (P.012) or JOG
2 (P.017) will be used when the drive is jogging.
9-3
DIG IN
5 (P.499)
State of the outer
control loop enable
input (terminal 64 on
the I/O Expansion
kit).
Parameter Range:
ON
OFF
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Input/Output - Digital I/O
5 is ON when +24VDC is applied for more than 10msec. It is OFF when 0VDC
is applied.
DIG IN
OCL ENABLE
(P.849)
The status of the OCL
enable signal. OFF
indicates the OCL is
disabled (held in
reset). ON means it is
operating.
9.2
Parameter Range:
ON
OFF
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Outer Control Loop (OCL) - OCL Test Points
Outer Control Loop Signal Processing
The OCL reference signal passes through a reference and a forward path.
9.2.1 Configuring the OCL Reference Path
You can configure the OCL to include an S-curve block. This prevents the
speed/voltage loop from being “jerked” when the OCL is enabled. The S-curve block
output ramps smoothly from the OCL FEEDBACK (P.847) value to the OCL reference
setpoint to reduce mechanical wear.
The OCL reference signal is fed into the S-curve block, where it is modified by OCL REF
RAMP TIME (P.802) and OCL REF ROUNDING (P.803). These parameters determine the
amount of rounding and minimum amount of time of the OCL reference ramp when the
OCL S-curve block output changes from 0 to full scale and vice versa. Rounding is
performed at the beginning and end of an OCL reference change.
You can check the output of the block through OCL RAMP OUTPUT (P.846).
OCL RAMP OUTPUT
The outer control
loop reference
S-curve block output
in OCL user-defined
units.
9-4
(P.846)
Parameter Range:
n/a
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Outer Control Loop (OCL) - OCL Test Points
FlexPak 3000 DC Drive Software Reference
OCL REFERENCE
The reference value
for the outer control
loop. Displayed in
OCL user-defined
units.
(P.845)
Parameter Range:
n/a
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Outer Control Loop (OCL) - OCL Test Points
OCL REFERENCE SELECT
Selects the reference
for the outer control
loop.
(P.800)
Parameter Range:
REGISTER
ANALOG IN
ANALOG IN
1
2
FREQUENCY IN
1
2
NETW IN REG 3
NETW IN REG
NETW IN REG
Default Setting:
REGISTER
Parameter Type:
Configurable
OIM Menu Path(s):
Outer Control Loop (OCL) - OCL Configure
If REGISTER is selected, the reference is from OCL REF REGISTER (P.801).
The I/O Expansion kit must be installed to use ANALOG IN 1 (terminals 50 and 51 on
the I/O expansion board), ANALOG IN 2 (terminals 52 and 53), or FREQUENCY IN
(terminals 39, 40, and 41).
A network kit must be installed to select the network input registers
(NETW IN REG 1, 2, or 3). Note that the network input registers are updated only
when CONTROL SOURCE (P.000) is set to NETWORK and the network is active.
OCL REF RAMP TIME
The ramp time for the
outer control loop
reference.
(P.802)
Parameter Range:
0.0 to 300.0 seconds
Default Setting:
10.0 seconds
Parameter Type:
Tunable
OIM Menu Path(s):
Outer Control Loop (OCL) - OCL Tuning
Sets the minimum amount of time for the OCL S-curve block output to change from 0
to full scale and vice versa. If set to 0.0, the S-curve block is bypassed.
Important: If the S-curve block is bypassed, rapid speed change can result.
Configuring the Outer Control Loop
9-5
OCL REF REGISTER
The reference for the
outer control loop that
is used when OCL
REFERENCE SELECT
(P.800) is set to
REGISTER.
(P.801)
Parameter Range:
–4095 to 4095
Default Setting:
0
Parameter Type:
Tunable
OIM Menu Path(s):
Outer Control Loop (OCL) - OCL Configure
Typically used in applications where a constant reference is needed.
OCL REF ROUNDING
Specifies the amount
of reference
smoothing (rounding)
for the outer control
loop.
(P.803)
Parameter Range:
0 to 50%
Default Setting:
0%
Parameter Type:
Tunable
OIM Menu Path(s):
Outer Control Loop (OCL) - OCL Tuning
It is set as a percentage of OCL REF RAMP TIME. Rounding is performed at the
beginning and end of an OCL reference change.
If OCL REF ROUNDING is set to 0%, the OCL performs a linear ramp function. If it is set
to 50%, the entire ramp time is smoothed: 50% at the beginning of the reference
change and 50% at the end. If OCL REF RAMP TIME (P.802) is 0.0 (S-curve block
bypassed), OCL REF ROUNDING has no effect on the OCL reference signal.
Figure 9.3 – OCL Reference Signal Rounding
9.2.2 Configuring the Outer Control Loop Forward Path
The difference between the OCL RAMP OUTPUT (P.846) and OCL feedback signal (after
lead/lag has been applied, if selected) is summed with the OCL feedback and then fed
into a PI block. In the PI block, gain (OCL PI PROP GAIN (P.808)) and lead frequency (OCL
PI LEAD FREQ (P.809)) are applied. The output of the PI block is clamped within the
values of OCL PI POSITIVE LIMIT (P.810) and OCL PI NEGATIVE LIMIT (P.811).
The signal from the PI block is fed into the OCL trim range block. Trim determines the
amount of control the OCL signal has on the speed/voltage loop reference. The amount
of trim is set through OCL TRIM RANGE (P.812).
9-6
FlexPak 3000 DC Drive Software Reference
If OCL PROP TRIM SELECT (P.813) is enabled, the signal from the trim range block is
passed through another gain block. The gain of this block is proportional to the
absolute value of the speed reference at the output of the speed loop S-curve block.
The gain of this block ranges from 0 at zero speed to unity gain when the reference is
equal to TOP SPEED (P.011).
You can check the final OCL value through OCL OUTPUT (P.848).
OCL OUTPUT
(P.848)
The output of the
outer control loop in
speed units. This is
the OCL trim that is
applied to the
speed/voltage control
loop.
OCL PI LEAD FREQ
The lead break
frequency of the
proportional integral
(PI) block of the outer
control loop.
Parameter Range:
n/a
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Outer Control Loop (OCL) - OCL Test Points
(P.809)
Parameter Range:
0.00 to 141.37 RAD/S
Default Setting:
1.00 RAD/S
Parameter Type:
Tunable
OIM Menu Path(s):
Outer Control Loop (OCL) - OCL Tuning
If the OCL is configured as a type 1 position regulator, set this equal to 0.00
(proportional only).
OCL PI NEGATIVE LIMIT
The negative limit of
the outer control loop
PI block.
Parameter Range:
0 to 100% of TOP SPEED (P.011)
Default Setting:
100%
Parameter Type:
Tunable
OIM Menu Path(s):
Outer Control Loop (OCL) - OCL Tuning
OCL PI POSITIVE LIMIT
The positive limit of
the outer control loop
PI block.
(P.811)
(P.810)
Parameter Range:
0 to 100% of TOP SPEED (P.011)
Default Setting:
100%
Parameter Type:
Tunable
OIM Menu Path(s):
Outer Control Loop (OCL) - OCL Tuning
Configuring the Outer Control Loop
9-7
OCL PI PROP GAIN
(P.808)
The proportional gain
of the outer control
loop PI block.
Parameter Range:
0.10 to 128.00
Default Setting:
2.00
Parameter Type:
Tunable
OIM Menu Path(s):
Outer Control Loop (OCL) - OCL Tuning
OCL PROP TRIM SELECT
When ENABLED is
selected, the OCL
output is proportional
to the absolute value
of the speed
reference at the
output of the speed
loop S-curve block.
OCL TRIM RANGE
The trim range for the
outer control loop.
(P.813)
Parameter Range:
DISABLED
ENABLED
Default Setting:
DISABLED
Parameter Type:
Configurable
OIM Menu Path(s):
Additional Parameters (listed by parameter number)
(P.812)
Parameter Range:
–100.0 to 100.0% of TOP SPEED (P.011)
Default Setting:
0.0%
Parameter Type:
Tunable
OIM Menu Path(s):
Outer Control Loop (OCL) - OCL Tuning
This parameter specifies the amount of control the OCL output signal has on the
speed/voltage loop reference or the CML reference when the drive is configured as
a Type III position regulator.
9-8
FlexPak 3000 DC Drive Software Reference
9.3
Configuring the Outer Control Loop Feedback Path
The OCL lead and lag options allow you to limit ratio errors when the primary ratio
variable changes quickly. Lead/lag adjustments compensate for backlash or coupling
issues with the feedback device.
!
ATTENTION: Lead/lag parameters must be adjusted by a qualified
control engineer. Failure to observe this precaution can result in severe
bodily injury or loss of life.
To enable lead/lag or lag/lead, set OCL LEADLAG SELECT to LEAD/LAG or LAG/LEAD,
respectively. To disable lead/lag or lag/lead, set OCL LEADLAG SELECT to BYPASS.
When lead/lag or lag/lead is selected, the OCL accepts a feedback signal from the
source selected by OCL FEEDBACK SELECT (P.804). You can check the value of this
signal through OCL FEEDBACK (P.847).
OCL FEEDBACK is fed into the lead/lag block. In this block, the OCL LEADLAG LOW FREQ
(P.806) and OCL LEADLAG RATIO (P.807) values are applied to the signal and the drive
calculates the high break frequency. OCL LEADLAG LOW FREQ sets where the signal will
break. The OCL LEADLAG RATIO is the ratio maintained between the low break and high
break frequency. The low frequency and ratio settings are multiplied to determine the
high break frequency. For example, if the low break frequency is 0.50 rad/s and the
ratio is 10, the high break frequency is 5.00 rad/s.
The transfer functions for lead/lag and lag/lead are:
Lead/Lag:
Lag/Lead:
s
1 + ---------ω low
---------------------s
1 + -----------ω high
OCL FEEDBACK
Where:
s
1 + -----------ω high
---------------------s
1 + ---------ω low
• ωlow = OCL LEADLAG LOW FREQ (P.806)
• ωhigh = OCL LEADLAG LOW FREQ (P.806)
* OCL LEADLAG RATIO (P.807)
(P.847)
The feedback value
of the outer control
loop. It is displayed in
OCL user-defined
units.
Parameter Range:
n/a
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Outer Control Loop (OCL) - OCL Test Points
Configuring the Outer Control Loop
9-9
OCL FEEDBACK SELECT
Selects the source of
the OCL feedback
signal.
(P.804)
Parameter Range:
NONE
CML FEEDBACK
ANALOG IN
ANALOG IN
1
2
5 = SPEED LOOP OUTPUT
6 = ANALOG AUTO REFERENCE
7 = NETWORK IN REG 1
8 = NETWORK IN REG 2
9 = NETWORK IN REG 3
Default Setting:
NONE
Parameter Type:
Configurable
OIM Menu Path(s):
Outer Control Loop (OCL) - OCL Configure
The choices are:
•
•
NONE:
•
ANALOG IN 1 or 2: Feedback is from an I/O Expansion kit analog input. These are
only available if an I/O Expansion kit is installed.
The OCL feedback signal is fixed at 0.
CML FEEDBACK:
Feedback is from an eight-sample average of the current minor
loop (CML) feedback signal.
The following options are available only if a network kit is installed:
• 5 (SPEED LOOP OUTPUT): Feedback is the SPD LOOP OUTPUT (P.299) value.
• 6 (ANALOG AUTO REFERENCE): Feedback is the ANALOG AUTO REFERENCE (P.188)
value.
• 7, 8, and 9 (NETWORK IN REG 1, 2, and 3): Feedback is the associated network
input register.
OCL LEADLAG LOW FREQ
Lead/lag block low
break frequency of
the outer control loop.
(P.806)
Parameter Range:
0.01 to 34.90 RAD/S
Default Setting:
1.00 RAD/S
Parameter Type:
Tunable
OIM Menu Path(s):
Outer Control Loop (OCL) - OCL Tuning
Sets the lead break frequency if OCL LEADLAG SELECT (P.805) is set to LEAD/LAG.
Sets the lag break frequency if OCL LEADLAG SELECT is set to LAG/LEAD.
9-10
FlexPak 3000 DC Drive Software Reference
OCL LEADLAG RATIO
The ratio between the
low break frequency
and high break
frequency of outer
control loop lead/lag
block.
(P.807)
Parameter Range:
2 to 20
Default Setting:
10
Parameter Type:
Tunable
OIM Menu Path(s):
Outer Control Loop (OCL) - OCL Tuning
The settings of this parameter and the OCL LEADLAG LOW FREQ determine the high
break frequency.
Increasing this value increases the ratio between the low and high frequencies. If
OCL LEADLAG SELECT (P.805) is set to LEAD/LAG, OCL LEADLAG RATIO sets the break
frequency for lag. If OCL LEADLAG SELECT (P.805) is set to LAG/LEAD, this sets the
break frequency for lead.
OCL LEADLAG SELECT
Selects the outer
control loop as
lead/lag, lag/lead, or
bypassed.
(P.805)
Parameter Range:
BYPASS
LAG/LEAD
Default Setting:
BYPASS
Parameter Type:
Tunable
OIM Menu Path(s):
Outer Control Loop (OCL) - OCL Configure
OCL TYPE3 POSN REG EN
Selects the source of
the Current Minor
Loop reference when
the drive is
configured as a
current regulator (i.e.,
when hardware
jumper J15 is set to
CURRENT).
LEAD/LAG
(P.814)
Parameter Range:
DISABLED
ENABLED
Default Setting:
DISABLED
Parameter Type:
Configurable
OIM Menu Path(s):
Outer Control Loop (OCL) - OCL Configure
When set to DISABLED, TORQUE REFERENCE (P.189) is used as the CML reference.
When set to ENABLED, OCL OUTPUT (P.848) is used as the CML reference.
Configuring the Outer Control Loop
9-11
9-12
FlexPak 3000 DC Drive Software Reference
CHAPTER 10
Configuring a Network
You can have a DeviceNet Interface board, AutoMax Network Communication board,
or ControlNet Network Communication board installed in the drive. This chapter
describes the parameters that you can configure for these networks. For information
on the networks, see the appropriate network manual.
Some parameters are only accessible over the network using the alternate register
map (NETW REGISTER MAP SEL (P.914) set to ALTERNATE).
Refer to the appropriate option board instruction manual for more information.
Configuring a Network
10-1
10.1 Configuration for All Networks
NETW COMM LOSS SELECT
Selects how the drive
will respond to
network
communication loss
when CONTROL
SOURCE is set to
NETWORK.
(P.901)
Parameter Range:
FAULT
USE LAST REF
USE TRMBLK REF
4 = USE TRMBLK CNTL
Default Setting:
FAULT
Parameter Type:
Tunable
OIM Menu Path(s):
Network Communications
The choices are:
•
FAULT:
•
USE LAST REF:
The drive continues to run if network communication is lost, using
the last reference value received over the network. The alarm A00004, NETWORK
COMMUNICATION TIMEOUT, is generated if network communication is lost.
•
USE TRMBLK REF: The drive continues to run if network communication is lost,
using the selected auto reference value from the Regulator board terminal strip
(terminals 19 and 20). The drive automatically switches back to the network
reference when network communication is re-established. The alarm A00004,
NETWORK COMMUNICATION TIMEOUT, is generated if network communication is lost.
A fault is generated when network communication is lost, causing the drive
to coast/DB stop.
• 4 (USE TRMBLK CNTL): The drive continues to run if network communication is lost.
The Regulator board terminal strip will become the source for all control (Run,
Jog, Stop, Fault Reset, Direction, and OCL Enable) and speed (auto) reference
signals. The Speed Loop PI Reset and Underwind/Overwind bits cannot be
changed while operating in this mode. They will remain at the last values received
from the network. The drive automatically switches back to the network reference
and control when network communication is re-established. Alarm A00004,
NETWORK COMMUNICATION TIMEOUT, is generated if network communication is lost.
This selection is available only when the ControlNet Network Communication
board is installed in the drive.
!
ATTENTION: When USE TRMBLK REF or USE TRMBLK CNTL are selected,
motor speed and direction changes can occur when network
communication is lost and restored. All terminal block reference and
control signals must be set to correct values for your application. Failure
to observe this precaution could result in damage to, or destruction of,
equipment.
Alarms do not cause the drive to stop. Therefore, some form of hardwired stop must
be available in case of network communication loss, since stopping the drive
through the network might not be possible. Once the drive is stopped, it cannot be
restarted until network communication is re-established or CONTROL SOURCE is
changed to something other than NETWORK.
If CONTROL SOURCE is not set to NETWORK, the loss of network communication does
not affect operation of the drive.
Important: The stop button on the OIM is aways functional, regardless of the vlaue
of this parameter.
10-2
FlexPak 3000 DC Drive Software Reference
!
NETW COMM STATUS
Indicates the status
of network
communication.
ATTENTION: The user must provide an external operator-accessible
coast/stop pushbutton at terminals 7 and 8 on the Regulator board to
disable the machine in case of improper operation or network loss.
Uncontrolled machine operation might result if this is not done. See the
hardware manual for wiring information. Failure to observe this
precaution could result in severe bodily injury or loss of life.
(P.908)
Parameter Range:
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Network Communications
NOT ACTIVE:
ACTIVE:
NETW CONNECT TYPE
Connection type of
the AutoMax Network
Communication kit or
DeviceNet Interface
kit.
This parameter has
no effect on the
operation of the
ControlNet Network
Communication kit.
NOT ACTIVE
ACTIVE
The network board is not communicating with the network master.
The network board is communicating with the network master.
(P.910)
Parameter Range:
BASIC
FULL
Default Setting:
BASIC
Parameter Type:
Configurable
OIM Menu Path(s):
Network Communications
When set to BASIC, only essential drive data (reference, sequencing, basic tuning,
and feedback data) are transferred over the network. This allows a higher density
network with moderate functionality.
When NETW CONNECT TYPE is set to FULL, the entire set of drive data that has been
assigned a network register is transferred over the network.
AutoMax Only: The large amount of data transferred in the full connection type
requires that the drive occupy multiple network drops, thus decreasing the potential
number of devices on the network. The drop depth is 4 when NETW CONNECT TYPE
is set to FULL. The drop depth is 1 when it is set to BASIC.
Configuring a Network
10-3
NETW DROP NUMBER
Network Drop
Number. Selects the
base drop number
the network option
board will respond to
on the network.
(P.900)
Parameter Range:
For AutoMax Network Communication kit:
1 to 55 if NETW CONNECT TYPE = BASIC;
1 to 52 if NETW CONNECT TYPE = FULL
For DeviceNet Interface kit: 0 to 63 (NETW CONNECT
TYPE value does not affect)
For ControlNet Network Communication kit: 1 to 99
(NETW CONNECT TYPE value does not affect)
Default Setting:
1
Parameter Type:
Configurable
OIM Menu Path(s):
Network Communications
NETW DROP NUMBER
cannot be changed
through the network.
When NETW CONNECT TYPE (P.910) is set to FULL, the AutoMax Network
Communication kit occupies multiple network drops beginning at NETW DROP
NUMBER. The number of drops occupied (drop depth) affects the upper limit of NETW
DROP NUMBER. See NETW CONNECT TYPE (P.910), to determine drop depth.
NETW OUT REG
Selects the
parameter to be
monitored.
1 SELECT (P.902)
Parameter Range:
–32768 to 32767
Default Setting:
0
Parameter Type:
Tunable
OIM Menu Path(s):
Network Communications
Select the parameter to monitor by configuring the parameter number. For example,
setting this parameter equal to 588 will write the value of parameter FIELD DELTA
(P.588) to the installed network register.
NETW OUT REG
Selects the
parameter to be
monitored.
2 SELECT (P.903)
Parameter Range:
–32768 to 32767
Default Setting:
0
Parameter Type:
Tunable
OIM Menu Path(s):
Network Communications
Select the parameter to monitor by configuring the parameter number. For example,
setting this parameter equal to 588 will write the value of parameter FIELD DELTA
(P.588) to the installed network register.
10-4
FlexPak 3000 DC Drive Software Reference
NETW OUT REG
Selects the
parameter to be
monitored.
3 SELECT (P.904)
Parameter Range:
–32768 to 32767
Default Setting:
0
Parameter Type:
Tunable
OIM Menu Path(s):
Network Communications
Select the parameter to monitor by configuring the parameter number. For example,
setting this parameter equal to 588 will write the value of parameter FIELD DELTA
(P.588) to the installed network register.
NETW IN REG
1 (P.905)
Indicates the value
being written by the
network master.
Parameter Range:
–32768 to 32767
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Network Communications
For the AutoMax network, this parameter writes to Drop_1, register 34. For the
ControlNet network, this parameter writes to file address N11:10.
NETW IN REG
2 (P.906)
Indicates the value
being written by the
network master.
Parameter Range:
–32768 to 32767
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Network Communications
For the AutoMax network, this parameter writes to Drop_1, register 35. For the
ControlNet network, this parameter writes to files address N11:11.
NETW IN REG
3 (P.907)
Indicates the value
being written by the
network master.
Parameter Range:
–32768 to 32767
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Network Communications
For the AutoMax network, this parameter writes to Drop_1, register 36. For the
ControlNet network, this parameter writes to file address N11:12.
Configuring a Network
10-5
NETW TYPE
& VERSION (P.909)
Indicates the type of
network card
installed and its
software version.
Parameter Range:
n/a
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Network Communications
Format is TV.VV where:
• T = Network Card type. 1 or 2 = AutoMax network. 4 = DeviceNet network.
5 = ControlNet network.
• V.VV = network board software version number.
NETWORK KIT
(P.796)
Indicates whether or
not a network kit is
installed in the drive
and if it has passed
diagnostics. If the
network kit has failed
diagnostics, the drive
is not operable (the
armature cannot
become active).
10-6
Parameter Range:
INSTALLED
NOT INSTALLED
FAILED DIAGS
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Network Communications
Drive Information
FlexPak 3000 DC Drive Software Reference
10.2 Configuring Parameters for DeviceNet
These parameters are specific to the DeviceNet network. For more information, see
the DeviceNet Network Communication manual (HE-FP3).
DEVNET POLL MSG TYPE
Selects which
predefined set of data
will be part of the
DeviceNet poll
connection
command/response
messages.
(P.913)
Parameter Range:
CONTROL ONLY
CONTROL+CONFIG
Default Setting:
CONTROL ONLY
Parameter Type:
Configurable
OIM Menu Path(s):
Network Communications
If the AutoMax network is being used, this parameter has no effect.
CONTROL ONLY: The smaller amount of data transmitted in the CONTROL ONLY poll
message type allows greater network density and performance.
CONTROL+CONFIG: The larger amount of data transmitted in the CONTROL+CONFIG
poll message type allows some degree of drive configuration but decreases the
network scan rate.
NETWORK BAUD RATE
Sets the baud rate for
the DeviceNet
Interface kit. Entering
a value of 0.0 Kbaud
disables DeviceNet
network
communication.
(P.912)
Parameter Range:
0.0 Kbaud
125.0 Kbaud
250.0 Kbaud
500.0 Kbaud
Default Setting:
0.0 Kbaud
Parameter Type:
Configurable
OIM Menu Path(s):
Network Communications
The baud rate for the AutoMax network is not adjustable. If AutoMax network is
being used, this parameter has no effect.
Configuring a Network
10-7
10.3 Configuring Parameters for the AutoMax Network
These parameters are only available if the AutoMax Network Communication board is
installed. For more information on the board and parameters, see the AutoMax
Network Communication board manual (D2-3318).
AMX NETW REF SELECT
AutoMax Network
reference selection.
(P.911)
Parameter Range:
DIRECT
n
where n = 1 to 8
BROADCAST
Default Setting:
DIRECT
Parameter Type:
Configurable
OIM Menu Path(s):
Network Communications
Selects whether the drive reference is from the designated register in the drop
register image or from one of the eight network broadcast registers when CONTROL
SOURCE is set to NETWORK.
NETW REGISTER MAP SEL
Indicates which
register map
configuration will be
used for the AutoMax
Network
Communication kit.
(P.914)
Parameter Range:
1 = ORIGINAL
2 = ALTERNATE
Default Setting:
1
Parameter Type:
Configurable
OIM Menu Path(s):
Additional Parameters (listed by parameter number)
ALTERNATE
selects the new register map, which permits use of additional functions.
should be used if you need to maintain compatibility with older FlexPak
drives that do not have a selectable register map (V3.12 and earlier).
ORIGINAL
10-8
FlexPak 3000 DC Drive Software Reference
10.4 Configuring Parameters for the ControlNet Network
These parameters are available only if the ControlNet Network Communication board
is installed. For more informatoin on this board and parameters, see the ControlNet
Network Communication board manual (D2-3425).
CNI PROGRAM RUN MODE
Selects how the drive
responds when
communicating with a
PLC and the PLC is
switched from run to
program mode.
(P.915)
Parameter Range:
1 = STOP
2 = USE LAST REF
3 = USE TRMBLK CNTL
Default Setting:
1 = STOP
Parameter Type:
Configurable
OIM Menu Path(s):
Network Communications
When the PLC is put into Program mode, alarm A00006, CONTROLNET PROGRAM
is generated to indicate the change in operation of the drive. An alarm is not
generated when the PLC is returned to Run mode, since that is considered normal
operation.
MODE,
1 (STOP): The drive will coast/DB stop (if running) when the PLC is put into Program
mode. When the PLC is in Program mode, the drive cannot be started while under
Network control.
2 (USE LAST REF): The drive will not stop (if running) or start (if stopped) when the
PLC is put into Program mode (or returned to Run mode). The drive will continue to
use the last network reference received as its speed reference. This will continue
until the PLC is returned to Run mode and a new reference value is received.
3 (USE TRMBLK CNTL): The drive will not stop (if running) or start (if stopped) when
the PLC is put into Program mode (or returned to Run mode). The drive’s Terminal
Block will become the source for all control (Run, Jog, Stop, Fault Reset, Direction,
and OCL Enable) and speed (auto) reference signals. The Speed Loop PI Reset
and Underwind/Overwind bits cannot be changed while operating in this mode.
They will remain at the last values received from the network. This will continue until
the PLC is returned to Run mode when control/reference will come from the
network, again.
!
Configuring a Network
ATTENTION: When USE TRMBLK CNTL is selected, motor speed and
direction changes can occur when the PLC is changed between Program
and Run modes. All terminal block reference and control signals must
be set to correct values for your application. Failure to observe this
precaution could result in damage to, or destruction of, equipment.
10-9
10-10
FlexPak 3000 DC Drive Software Reference
CHAPTER 11
Configuring Parameters for the
I/O Expansion Kit
This section provides descriptions for parameters that are available when the I/O
Expansion kit is installed. For a kit description, see the I/O Expansion kit manual
(D2-3301).
For information on the MOP options available through the I/O Expansion kit, see
section 4.1.6, Configuring the Motor-Operated Potentiometer (MOP) Reference.
For information on the outer control loop options available through the I/O Expansion
kit, see chapter 9, Configuring the Outer Control Loop.
These parameters are only available if the I/O Expansion kit is installed.
I/O EXPANSION KIT
Indicates whether or
not the I/O Expansion
kit is installed in the
drive and if it has
passed diagnostics. If
the I/O Expansion kit
has failed
diagnostics, the drive
is not operable (the
armature cannot
become active).
(P.797)
Parameter Range:
NOT INSTALLED
INSTALLED
FAILED DIAGS
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Input/Output - Frequency I/O
Input/Output - Analog I/O
Input/Output - Digital I/O
Drive Information
Configuring Parameters for the I/O Expansion Kit
11-1
11.1 Configuring the Digital Outputs
The I/O Expansion kit includes two digital outputs.
!
ATTENTION: These outputs are intended for use as an indication. Failure
to observe this precaution can result in severe bodily injury or loss of life.
If you use these outputs, you need to set parameters that select the source that drives
the output and whether the output is normally open or normally closed.
From Figure 12.1, Level
Detectors Block Diagram
Figure 11.1 – Digital Outputs Block Diagram
DIG OUT
1 CONTACT TYP (P.410)
Selects whether
digital output 1
(terminals 66 and 67
on I/O Expansion kit)
is normally open or
normally closed.
Parameter Range:
NORMAL OPEN
NORMAL CLOSED
Default Setting:
NORMAL OPEN
Parameter Type:
Configurable
OIM Menu Path(s):
Input/Output - Digital I/O
If NORMAL OPEN is selected, digital output 1 is open when
OUT 1 SELECT (P.409) is off and closed when it is on.
If NORMAL CLOSED is selected, digital output 1 is closed
DIG OUT 1 SELECT (P.409) is off and open when it is on.
!
11-2
the signal selected by DIG
when the signal selected by
ATTENTION: On a power cycle or reset, the contact is held open until
the drive software powerup diagnostics is complete. Make sure that this
condition does not result in a dangerous situation for your application.
Failure to observe this precaution can result in severe bodily injury or
loss of life.
FlexPak 3000 DC Drive Software Reference
DIG OUT
1 SELECT (P.409)
Selects the signal
that drives digital
output 1 (terminals
66 and 67 on the I/O
Expansion kit).
Parameter Range:
LEVEL DETECT 1 OUTPUT
LEVEL DETECT 2 OUTPUT
IN CURRENT LIMIT
DRIVE READY
NETW COMM STATUS
NETW IN REG 1 (bit 0)
NETW IN REG 2 (bit 0)
NETW IN REG 3 (bit 0)
Default Setting:
LEVEL DETECT
Parameter Type:
Configurable
OIM Menu Path(s):
Input/Output - Digital I/O
•
•
•
•
•
DIG OUT
1 OUTPUT
1 or 2 OUTPUT: The state of the selected level detector output is
used to drive digital output 1. The signal is from the I/O Expansion kit digital
output 1 or 2. See chapter 12, Configuring the Drive to Use Level Detectors.
IN CURRENT LIMIT: The armature in-current-limit signal is used to drive digital
output 1. The in-current-limit signal indicates whether or not the drive is operating
at the maximum allowable current. See CML REF LIMIT SELECT (P.311).
DRIVE READY: The drive-is-ready signal is used to drive digital output 1. The
drive-is-ready signal indicates that the drive will start when the next run or jog
command is received.
NETW COMM STATUS: The state of NETW COMM STATUS (P.908) is used to drive
digital output 1. See chapter 10 for description.
LEVEL DETECT
1, 2, or 3: Bit 0 of NETW IN REG 1 (P.905), 2 (P.906), or 3 (P.907) is
used to drive digital output 1. Note that the network input registers are updated
only when CONTROL SOURCE (P.000) is set to NETWORK and the network is active.
See chapter 10 for description.
NETW IN REG
2 CONTACT TYP (P.412)
Selects whether
digital output 2
(terminals 68 and 69
on the I/O Expansion
kit) is normally open
or normally closed.
Parameter Range:
NORMAL OPEN
NORMAL CLOSED
Default Setting:
NORMAL OPEN
Parameter Type:
Configurable
OIM Menu Path(s):
Input/Output - Digital I/O
If NORMAL OPEN is selected, digital output 2 is open when
OUT 2 SELECT (P.411) is off and closed when it is on.
If NORMAL CLOSED is selected, digital output 2 is closed
DIG OUT 2 SELECT (P.411) is off and open when it is on.
!
the signal selected by DIG
when the signal selected by
ATTENTION: On a power cycle or reset, the contact is held open until the
drive software powerup diagnostics are complete. Make sure this condition
does not result in a dangerous situation for your application. Failure to
observe this precaution can result in severe bodily injury or loss of life.
Configuring Parameters for the I/O Expansion Kit
11-3
DIG OUT
2 SELECT (P.411)
Selects the signal
used to drive digital
output 2 (terminals
68 and 69 on the I/O
Expansion kit).
Parameter Range:
LEVEL DETECT
LEVEL DETECT
1 OUTPUT
2 OUTPUT
IN CURRENT LIMIT
DRIVE READY
NETW COMM STATUS
1 (bit 1)
2 (bit 1)
NETW IN REG 3 (bit 1)
NETW IN REG
NETW IN REG
Default Setting:
LEVEL DETECT
Parameter Type:
Configurable
OIM Menu Path(s):
Input/Output - Digital I/O
2 OUTPUT
•
LEVEL DETECT 1
•
IN CURRENT LIMIT:
•
DRIVE READY:
•
NETW COMM STATUS: The state of NETW COMM STATUS (P.908) drives digital
output 2. See chapter 10 for description.
or 2 OUTPUT: The state of the selected level detector output drives
digital output 2. The signal is from the I/O Expansion kit digital output 1 or 2. See
chapter 12, Configuring the Drive to Use Level Detectors for information.
The armature in-current-limit signal, which indicates whether or
not the drive is operating at the maximum allowable current, drives digital
output 2. See CML REF LIMIT SELECT (P.311), for information.
The drive-is-ready signal drives digital output 2. This signal
indicates that the drive will start when the next run or jog command is received.
NETW IN REG 1, 2, or 3: Bit 0 of NETW IN REG 1 (P.905), 2 (P.906), or 3 (P.907) drives
digital output 2. Note that the network input registers are updated only when
CONTROL SOURCE (P.000) is set to NETWORK and the network is active. See chapter
10 for description.
11-4
FlexPak 3000 DC Drive Software Reference
11.2 Configuring the Analog Inputs
Important: Analog input 2 (terminals 52 and 53 on the I/O Expansion kit) only
accepts a ±10VDC input signal.
* Default Selection
Figure 11.2 – Analog Inputs Block Diagram
If you use the analog input 1 input, you need to set hardware jumpers and a parameter
that tells the drive what type of signal to expect at the input. For both analog inputs,
you can also set the gain and zero.
Analog inputs are read every 5msec when FEEDBACK SELECT (P.200) is set to DC TACH,
PULSE TACH, or AC TACH. They are read every 10msec when FEEDBACK SELECT (P.200)
is set to ARMATURE VOLT.
To check the scaled signal, use parameters ANLG IN 1 (P.492) or ANLG IN 2 (P.493).
ANLG IN
1 (P.492)
The digital value of
analog input 1
(terminals 50 and 51
on the I/O Expansion
kit) after gain and
zero have been
applied.
Parameter Range:
n/a
Default Setting:
Parameter Type:
Output
OIM Menu Path(s):
Input/Output - Analog I/O
Configuring Parameters for the I/O Expansion Kit
11-5
ANLG IN
1 GAIN ADJ (P.415)
Gain adjustment for
analog input 1
(terminals 50 and 51
on the I/O Expansion
kit).
Parameter Range:
0.750 to 2.250
Default Setting:
1.000
Parameter Type:
Tunable
OIM Menu Path(s):
Input/Output - Analog I/O
Adjust the gain to get full scale values from the A/D converter when the maximum
level of the applied input signal is different than that of the drive.
For example, if ANLG IN 1 SIG TYPE is set to 0-10 V, a 0-8 VDC signal produces 80%
of the drive’s full scale value. To produce the drive’s full scale value using the
0-8VDC signal, change ANLG IN 1 GAIN ADJ to 1.250 (8.0V x 1.25 = 10.0V). Gain
values less than 1.000 decrease the resolution of the analog input.
Adjust the zero point (ANLG IN 1 ZERO ADJ (P.414)) before setting gain.
ANLG IN
1 SIG TYPE (P.413)
Selects the type of
signal that the drive
will expect to be
connected to analog
input 1 (terminals 50
and 51 on the I/O
Expansion kit).
Parameter Range:
0–10 V
+/–10 V
4-20 mA
10-50 mA
Default Setting:
+/–10 V
Parameter Type:
Configurable
OIM Menu Path(s):
Input/Output - Analog I/O
This setting must match the setting of I/O Expansion kit jumpers J11 and J12.
If the input drops below the selected value, the drive uses the low point of the range
(for example, 0 V or 4mA).
ANLG IN
1 ZERO ADJ (P.414)
Adjusts the zero point
of analog input 1
(terminals 50 and 51
on the I/O Expansion
kit) to remove any
offset that might exist
on the input.
Parameter Range:
–200 to 200
Default Setting:
0
Parameter Type:
Tunable
OIM Menu Path(s):
Input/Output - Analog I/O
To adjust the zero point, make small changes to this parameter until ANLG IN 1 is
zero when the signal at terminals 50 and 51 is at its zero (0V, 4mA, or 10mA).
11-6
FlexPak 3000 DC Drive Software Reference
ANLG IN
2 (P.493)
The digital value of
analog input 2
(terminals 52 and 53
on the I/O Expansion
kit) after gain and
zero are applied.
ANLG IN
Parameter Range:
n/a
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Input/Output - Analog I/O
2 GAIN ADJ (P.417)
Gain adjustment for
analog input 2
(terminals 52 and 53
on the I/O Expansion
kit).
Parameter Range:
0.750 to 2.250
Default Setting:
1.000
Parameter Type:
Tunable
OIM Menu Path(s):
Input/Output - Analog I/O
Adjust the gain to get full scale values from the A/D converter when the maximum
level of the applied input signal is different than that of the drive.
For example, a –8 to +8 VDC signal produces 80% of the drive’s full scale value. To
produce the drive’s full scale value using the –8 to +8VDC signal, change ANLG IN 2
GAIN ADJ to 1.250 (8 V x 1.25 = 10 V). Note that gain values less than 1.000
decrease the resolution of the analog input.
Adjust the zero point (ANLG IN 2 ZERO ADJ (P.416)) before setting gain.
ANLG IN
2 ZERO ADJ (P.416)
Adjusts the zero point
of analog input 2
(terminals 52 and 53
on the I/O Expansion
kit) to remove any
offset that might exist
on the input.
Parameter Range:
–200 to 200
Default Setting:
0
Parameter Type:
Tunable
OIM Menu Path(s):
Input/Output - Analog I/O
To adjust the zero point, make small changes to this parameter until ANLG IN 2
equals zero when the signal at terminals 52 and 53 is at 0V.
Configuring Parameters for the I/O Expansion Kit
11-7
11.3 Configuring the Analog Outputs
The I/O Expansion kit has two unfiltered analog outputs. One can generate a bipolar
DC voltage only. The other can be configured to generate a DC voltage from a 0 to
±10 VDC, 4-20 mA, or 10-50 mA signal. These outputs can be scaled to generate DC
voltage signals as low as 5 V, but maximum resolution (0.025%) is obtained when the
full scale output signal is used. The full scale value (FSV) is determined based on the
selected parameter group; load, speed, voltage, power, field or other.
Analog outputs are read every 5msec when FEEDBACK SELECT (P.200) is set to DC
TACH, PULSE TACH, or AC TACH. They are read every 10msec when FEEDBACK SELECT
(P.200) is set to ARMATURE VOLT.
From Figure 6.2, Current Minor
Loop Block Diagram
From Figure 5.1, Speed Loop
Block Diagram
From Figure 4.5, Speed Reference
Ramp Block Diagram
From Figure 4.2, Speed Reference Source Select Block Diagram
From Figure 4.5, Speed Reference Ramp Block Diagram
From Figure 5.1, Speed Loop Block Diagram
See table 11.1 on page 11-12
From Figure 9.1, Outer Control
Loop Block Diagram
From Figure 8.1, Field Block DIagram if Field
Current Regulator Kit is Installed
*Default Selection
Figure 11.3 – Analog and Frequency Outputs Block Diagram
ANLG OUT
1 GAIN ADJ (P.420)
Adjusts the gain of
analog output 1
(terminals 54 and 55
of the I/O Expansion
kit) to allow it to
produce a signal from
5.0 to approximately
13.0VDC.
Parameter Range:
0.500 to 1.300
Default Setting:
1.000
Parameter Type:
Tunable
OIM Menu Path(s):
Input/Output - Analog I/O
The full scale value is determined by ANLG OUT 1 SELECT. See table 11.1.
This parameter is typically used to adjust the 10 V full scale output to match the
input voltage requirement of attached equipment. For example, you would set this
parameter to 0.800 for equipment that accepts a 0 to 8 VDC signal.
Analog output 1 and 2 are only rated to 10 VDC, so gain adjustment values greater
than 1.000 might cause the analog output circuit to saturate.
11-8
FlexPak 3000 DC Drive Software Reference
ANLG OUT
1 SELECT (P.418)
Selects the signal
used to drive analog
output 1 (terminals
54 and 55 on the I/O
Expansion kit).
Parameter Range:
See table 11.1 for options
Default Setting:
ZERO
Parameter Type:
Configurable
OIM Menu Path(s):
Input/Output - Analog I/O
When the analog output is at its maximum value, the selected signal is at its full
scale value.
ANLG OUT
1 SIG TYPE (P.419)
Selects the type of
signal to be
generated by analog
output 1 (terminals
54 and 55 on the I/O
Expansion kit).
Parameter Range:
0–10 V
+/–10 V
4-20 mA
Default Setting:
+/–10 V
Parameter Type:
Configurable
OIM Menu Path(s):
Input/Output - Analog I/O
This setting must match the I/O Expansion kit J14 and J15 settings.
ANLG OUT
2 GAIN ADJ (P.422)
Adjusts the gain of
analog output 2
(terminals 56 and 57
on the I/O Expansion
kit) to allow it to
produce a signal from
5.0 to the full scale
value of
approximately
13.0 VDC.
Parameter Range:
0.500 to 1.300
Default Setting:
1.000
Parameter Type:
Tunable
OIM Menu Path(s):
Input/Output - Analog I/O
The full scale value is determined by ANLG OUT 2 SELECT. See table 11.1.
This is typically used to adjust the 10 V full scale output to match the input voltage
requirements of attached equipment. For example, set this parameter to 0.800 for
equipment that accepts a ±8 VDC signal.
The outputs are rated to 10 VDC, so gain adjust values greater than 1.000 might
cause the analog output circuit to saturate.
Analog output 2 only generates a ±10 VDC input signal and cannot be changed.
Analog output 1 and 2 are only rated to 10 VDC, so gain adjustment values greater
than 1.000 might cause the analog output circuit to saturate.
Configuring Parameters for the I/O Expansion Kit
11-9
ANLG OUT
2 SELECT (P.421)
Selects the signal
used to drive analog
output 2 (terminals
56 and 57 on the I/O
Expansion kit).
Parameter Range:
See table 11.1 for options.
Default Setting:
ZERO
Parameter Type:
Configurable
OIM Menu Path(s):
Input/Output - Analog I/O
When the analog output is at its maximum value, the selected signal is at is full
scale value.
11.4 Configuring the Frequency Input
Figure 11.4 – Frequency Input Block Diagram
FREQ IN
(P.491)
The digital value of
the frequency input
(terminals 39, 40,
and 41 on the I/O
Expansion kit).
Parameter Range:
0 to 4095
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Input/Output - Frequency I/O
FREQ IN
is scaled between FREQ IN ZERO and FREQ IN FULL SCALE.
FREQ IN
ZERO. It
is zero when the frequency at the input is less than or equal to FREQ IN
is 4095 when the frequency equals FREQ IN FULL SCALE.
FREQ IN FULL SCALE
Specifies the
maximum input
frequency. This is the
frequency that
corresponds to full
scale value.
(P.424)
Parameter Range:
2.0 to 250.0 kHz
Default Setting:
250.0 kHz
Parameter Type:
Configurable
OIM Menu Path(s):
Input/Output - Frequency I/O
For example, if the frequency input will be used as the speed loop reference
(selected by AUTO REFERENCE SELECT (P.103)), this input frequency will correspond
to TOP SPEED (P.011), because TOP SPEED is the basis for speed loop scaling.
11-10
FlexPak 3000 DC Drive Software Reference
FREQ IN ZERO
(P.423)
Specifies the
minimum input
frequency. This is the
frequency that
corresponds to zero.
Parameter Range:
2.0 to FREQ IN FULL SCALE kHz
Default Setting:
2.0 kHz
Parameter Type:
Configurable
OIM Menu Path(s):
Input/Output - Frequency I/O
If the input frequency drops below the frequency specified by this parameter, the
resulting digital value remains zero (it will not go negative).
11.5 Configuring the Frequency Output
The I/O Expansion kit has one unipolar frequency output. The output is unfiltered. The
full scale value (FSV) is based on the selected parameter group: load, speed, voltage,
power, field, or other.
The frequency output is read every 5msec when FEEDBACK SELECT (P.200) is set to DC
It is read every 10msec when FEEDBACK SELECT (P.200)
TACH, PULSE TACH, or AC TACH.
is set to ARMATURE VOLT.
FREQ OUT FULL SCALE
The frequency
generated when the
signal driving the
frequency output is at
full scale, as detailed
in table 11.1.
(P.427)
Parameter Range:
2.0 to 250.0 kHz
Default Setting:
250.0 kHz
Parameter Type:
Configurable
OIM Menu Path(s):
Input/Output - Frequency I/O
For example, if FREQ OUT SELECT (P.425) is set to CML FEEDBACK, the FREQ OUT
FULL SCALE frequency value is output when armature current is at MAXIMUM
CURRENT (P.007). (MAXIMUM CURRENT is used as the basis for current minor
loop scaling.)
FREQ OUT SELECT
(P.425)
Selects the signal
used to drive the
frequency output
(terminals 42,43, and
44 on the I/O
Expansion kit).
Parameter Range:
See table 11.1 for options.
Default Setting:
ZERO
Parameter Type:
Configurable
OIM Menu Path(s):
Input/Output - Frequency I/O
Configuring Parameters for the I/O Expansion Kit
11-11
FREQ OUT ZERO
The frequency
generated when the
signal driving the
frequency output is
zero.
(P.426)
Parameter Range:
2.0 to FREQ OUT FULL SCALE kHz
Default Setting:
2.0 kHz
Parameter Type:
Configurable
OIM Menu Path(s):
Input/Output - Frequency I/O
If the signal goes negative, the frequency output maintains the frequency set
by this parameter.
Table 11.1 – Options for Metering Parameters
Signal Selected
(P.397)
(P.396)
CML ERROR (P.398)
SPD LOOP OUTPUT (P.299)
CML FEEDBACK
CML REFERENCE
Full Scale Value
MAXIMUM CURRENT
MOTOR RATED ARM AMPS × -----------------------------------------------------------100
or
MAXIMUM CURRENT
(P.296)
(P.295)
SPD LOOP ERROR (P.297)
SPEED RAMP OUTPUT (P.199)
SPEED RAMP INPUT TP (P.198)
SPD SOURCE SELECT OUT (P.193)
TRIM OUTPUT (P.197)
ANALOG TACH FEEDBACK (P.291)
PULSE TACH FEEDBACK (P.292)
OCL OUTPUT (P.848)
SPD LOOP FEEDBACK
(amps)
(% full load amps)
TOP SPEED (RPM)
SPD LOOP REFERENCE
ARMATURE VOLTAGE
(P.289)
POWER OUTPUT
(volts)
MAXIMUM CURRENT
MOTOR RATED ARM VOLTS × MOTOR RATED ARM AMPS × -----------------------------------------------------------100
(P.590)
(P.589)
FIELD REFERENCE
FIELD FEEDBACK
MOTOR RATED ARM VOLTS
(P.845)
(P.846)
OCL FEEDBACK (P.847)
NETW IN REG 1 (P.905)
NETW IN REG 2 (P.906)
NETW IN REG 3 (P.907)
OCL REFERENCE
MOTOR HOT FLD AMPS
watts
(amps)
4095 (counts)
OCL RAMP OUTPUT
FULL SCALE
ZERO
11-12
0
FlexPak 3000 DC Drive Software Reference
CHAPTER 12
Configuring the Drive to Use
Level Detectors
The level detectors detect when the absolute value of a signal becomes greater than
or equal to a specified threshold for longer than a specified period. They can be used
as zero-speed detectors, at-speed detectors, or limit switches. They are also used to
drive optional I/O Expansion kit digital output 1 or 2.
To use the level detectors, DIG OUT 1 SELECT (P.409) or DIG OUT 2 SELECT (P.411) must
be set to LEVEL DETECT 1 OUTPUT or LEVEL DETECT 2 OUTPUT. Level detector outputs
can also be monitored over the AutoMax network.
From Figure 5.1, Speed Loop Block Diagram
From Figure 4.5, Speed Reference
Ramp Block Diagram
To Figure 11.1, Digital
Outputs Block Diagram
From Figure 4.2, Speed Reference
Source Select Block Diagram
* Default Selection
Figure 12.1 – Level Detectors Block Diagram
LEVEL DETECT
1 DELAY (P.604)
The delay time in
seconds for the level
detector 1 circuit.
Parameter Range:
0.0 to 300.0 seconds
Default Setting:
10.0 seconds
Parameter Type:
Tunable
OIM Menu Path(s):
Input/Output - Level Detectors
Sets the amount of time between when the level detector timer is triggered and
when the output is set ON. If the input source signal goes below the detector’s
threshold value, the timer is immediately reset.
Configuring the Drive to Use Level Detectors
12-1
LEVEL DETECT
1 OUTPUT (P.648)
The output of level
detector 1. This
signal drives digital
output 1 (terminals
66 and 67 on the I/O
Expansion kit) if DIG
OUT 1 SELECT is set to
LEVEL DETECT 1
OUTPUT.
Parameter Range:
ON
OFF
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Input/Output - Level Detectors
ON when the input signal selected by LEVEL DETECT 1 SELECT (P.602) is greater than
or equal to LEVEL DETECT 1 THRESH (P.603) for longer than LEVEL DETECT 1 DELAY
(P.604).
OFF
LEVEL DETECT
Selects the signal
that drives level
detector 1.
whenever the input signal is less than LEVEL DETECT 1 THRESH.
1 SELECT (P.602)
Parameter Range:
CML FEEDBACK
SPD LOOP FEEDBACK
SPD RAMP INPUT TP
SPEED RAMP OUTPUT
SPD SOURCE SELECT OUT
LEVEL DETECT
The threshold for
level detector 1.
Default Setting:
SPD LOOP FEEDBACK
Parameter Type:
Configurable
OIM Menu Path(s):
Input/Output - Level Detectors
1 THRESH (P.603)
Parameter Range:*
0.1 to 100.0% or MAXIMUM CURRENT
Default Setting:
10.0%
Parameter Type:
Tunable
OIM Menu Path(s):
Input/Output - Level Detectors
When the absolute value of the signal driving level detector 1 is greater than or
equal to this threshold, the associated timer starts. If the input signal is less than
this threshold, the timer is immediately reset. The level detector output is set to OFF.
*The parameter range for the level detector is automatically rescaled for speed or
current based on the input selected by LEVEL DETECT 1 SELECT (P.602). If CML
FEEDBACK is selected for LEVEL DETECT 1 SELECT, the parameter range is 0.1 to
MAXIMUM CURRENT. For any other LEVEL DETECT 1 SELECT settings, the parameter
range is 0.1 to 100.0%.
12-2
FlexPak 3000 DC Drive Software Reference
LEVEL DETECT
2 DELAY (P.607)
The delay time in
seconds for the level
detector 2 circuit.
Parameter Range:
0.0 to 300.0 seconds
Default Setting:
10.0 seconds
Parameter Type:
Tunable
OIM Menu Path(s):
Input/Output - Level Detectors
Sets the amount of time between when the level detector timer is triggered and
when the output is set ON. If the input source signal goes below the detector’s
threshold value, the timer is immediately reset.
LEVEL DETECT
2 OUTPUT (P.649)
The output of level
detector 2. This
signal drives digital
output 2 (terminals
68 and 69 on the I/O
Expansion kit) if DIG
OUT 2 SELECT is set to
LEVEL DETECT 2
OUTPUT.
Parameter Range:
ON
OFF
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Input/Output - Level Detectors
ON when the input signal selected by LEVEL DETECT 2 SELECT (P.605) is greater than
or equal to LEVEL DETECT 2 THRESH (P.606) for longer than LEVEL DETECT 2 DELAY
(P.607).
OFF
LEVEL DETECT
Selects the signal
that drives level
detector 2.
whenever the input signal is less than LEVEL DETECT 2 THRESH.
2 SELECT (P.605)
Parameter Range:
CML FEEDBACK
SPD LOOP FEEDBACK
SPD RAMP INPUT TP
SPEED RAMP OUTPUT
SPD SOURCE SELECT OUT
Default Setting:
SPD RAMP INPUT TP
Parameter Type:
Configurable
OIM Menu Path(s):
Input/Output - Level Detectors
Configuring the Drive to Use Level Detectors
12-3
LEVEL DETECT
The threshold for
level detector 2.
2 THRESH (P.606)
Parameter Range:*
0.1 to 100.0% or MAXIMUM CURRENT
Default Setting:
10.0%
Parameter Type:
Tunable
OIM Menu Path(s):
Input/Output - Level Detectors
When the absolute value of the signal driving level detector 2 is greater than or
equal to this threshold, the associated timer starts. If the input signal is less than
this threshold, the timer is immediately reset and the level detector output is set to
OFF.
*The parameter range for the level detector is automatically rescaled for speed or
current based on the input selected by LEVEL DETECT 2 SELECT (P.605). If CML
FEEDBACK is selected for LEVEL DETECT 2 SELECT, the parameter range is 0.1 to
MAXIMUM CURRENT. For any other LEVEL DETECT 2 SELECT settings, the parameter
range is 0.1 to 100.0%.
12-4
FlexPak 3000 DC Drive Software Reference
CHAPTER 13
Troubleshooting the FlexPak 3000 Drive
!
ATTENTION: Only qualified electrical personnel familiar with the
construction and operation of this equipment and the hazards involved
should install, operate, or service this equipment. Read and understand
this section in its entirety before proceeding. Failure to observe this
precaution could result in severe bodily injury or loss of life.
This section provides lists of faults and alarms that can occur and the possible causes.
It also lists parameters that can be helpful when troubleshooting.
For instruction on how to clear faults and alarms, see the FlexPak 3000 Drive
Operator Interface Module (OIM) User Guide (D2-3344).
13.1 Fault and Alarm Messages, Descriptions,
and Code Numbers
Table 13.1 lists fault codes and table 13.2 lists alarm codes. The codes are in numeric
order by the number you see on the OIM display when an alarm or fault occurs.
Table 13.1 – Fault Codes
Code
F00001
OIM Display
IET (OVERCURRENT)
Description
Armature current instantaneously exceeded 180% of MAXIMUM CURRENT.
Possible causes:
• Incorrect armature current feedback scaling (MOTOR RATED ARM AMPS,
MAXIMUM CURRENT, CT TURNS RATIO,
or J18 not set properly).
• One or more thyristors not operating.
• Improper current minor loop tuning.
• Motor armature winding damaged.
Troubleshooting the FlexPak 3000 Drive
13-1
Table 13.1 – Fault Codes (Continued)
Code
F00002
OIM Display
TACHOMETER LOSS
Description
Tachometer or encoder feedback signal missing.
Possible causes:
• Tachometer or encoder coupling failure.
• Disconnected, loosely connected, or damaged tachometer or encoder
wires.
•
•
•
•
•
•
•
Pulse encoder supply voltage low.
Incorrect analog tachometer scaling.
Incorrect pulse encoder configuration.
Motor armature winding not connected or open circuit.
Blown inverting fault (DC) fuse.
Inverting fault breaker tripped.
High inertia loads and high inductance armature circuits. To reduce
nuisance faults, increase the firing angle threshold (see section 13.2).
• Tachometer or encoder failure.
F00003
OVERSPEED
Motor speed exceeded the 110% of TOP SPEED.
Possible causes:
• Incorrect tachometer or encoder scaling.
• Blown field supply fuse(s).
• Improper speed loop tuning.
•
PULSE TACH QUADRATURE
set to ON for a non-regenerative drive.
• Incorrect pulse encoder wiring.
F00004
FIELD CURRENT LOSS
Standard or enhanced field supplies: The field loss detection circuit does
not sense any field current flowing in the motor shunt field.
Field Current Regulator kit field supply: FIELD FEEDBACK (P.589) fell below
the FIELD LOSS THRESHOLD (P.512).
Possible causes:
• Motor field winding not connected or open circuit.
• Blown field supply fuse(s).
• Blown AC line fuse(s).
• Field supply failure.
• Disconnected, loosely connected, or damaged wiring harness.
• Field Current Regulator kit only: Improper field loop tuning.
13-2
FlexPak 3000 DC Drive Software Reference
Table 13.1 – Fault Codes (Continued)
Code
F00005
OIM Display
SUSTAINED OVERLOAD
Description
Inverse time overload circuit trip.
Possible causes:
• Incorrect armature current feedback scaling (MOTOR RATED ARM AMPS,
MAXIMUM CURRENT, CT TURNS RATIO,
and/or J18 not set properly).
• Blown field supply fuse(s).
• Mechanical binding preventing the motor shaft from rotating freely.
F00006
BLOWER MOTOR
STARTER OPEN
The blower motor starter is open. If a blower motor starter kit is not
installed, connector P8 must be fitted with the proper substitute connector
to inhibit this fault.
Possible causes:
• Blown blower motor starter fuse(s).
• Disconnected, loosely connected, or damaged blower motor starter
wiring.
• Blower motor overload.
F00007
OPEN ARMATURE
The motor armature circuit is open.
Possible causes:
• Motor armature winding not connected or open circuit.
• Blown inverting fault (DC) fuse.
• Inverting fault breaker tripped.
F00008
MOTOR THERMOSTAT
TRIP
Motor thermostat indicates high temperature. If a motor thermostat is not
used, customer terminal board pins 13 and 14 must be jumpered to inhibit
this fault.
Possible causes:
• Damaged or disconnected motor thermostat wiring.
• Inadequate ventilation.
• Blower motor failure.
• Incorrect blower rotation.
• Blocked ventilation slots.
• Clogged filters.
• Excessive armature current.
• One or more thyristors not operating.
Troubleshooting the FlexPak 3000 Drive
13-3
Table 13.1 – Fault Codes (Continued)
Code
F00009
OIM Display
CONTROLLER
Description
Drive thermostat indicates high temperature (>50°C)
THERMOSTAT TRIP
Possible causes:
•
•
•
•
F00010
AC LINE
Inadequate heat sink ventilation.
Inadequate cabinet ventilation.
Heat sink fan failure.
Damaged or disconnected drive thermostat wiring.
Three-phase AC line synchronization circuit failure.
SYNCHRONIZATION
FAULT
Possible causes:
•
•
•
•
•
F00011
OIM COMMUNICATIONS
TIMEOUT
Blown AC line fuse(s).
AC line frequency not within required range of 48 to 62Hz.
Excessive AC line noise or distortion.
Unstable AC line frequency. See PLL MAXIMUM ERROR (P.308).
Disconnected, loosely connected or damaged J6 ribbon cable.
The Regulator board was unable to communicate with the interface
module (OIM or DCM). (See the hardware manual for a description of
regulator status LEDs that can pinpoint whether or not the interface module
is communicating.)
Possible causes:
• Disconnected, loosely connected, or damaged interface module/serial
cable.
• Regulator board failure.
F00012
ARMATURE OVER
Armature voltage exceeded 125% of MOTOR RATED ARM VOLTS (P.009).
VOLTAGE
Possible causes:
• MOTOR RATED ARM VOLTS not set properly.
• Improper voltage loop tuning.
• ENHANCED FLD VOLT ADJ (P.500) set too high (Enhanced Field Supply kit
only).
F00013
NETWORK
COMMUNICATION
Network communications is missing or failed to communicate with master
(CONTROL SOURCE set to NETWORK).
TIMEOUT
Possible causes:
• NETW CONNECT TYPE (P.910) was changed from BASIC to FULL.
• NETW DROP NUMBER (P.900) was changed.
• Network option cable connections are loose or not connected.
• Network option board failed or master communications failed.
13-4
FlexPak 3000 DC Drive Software Reference
Table 13.1 – Fault Codes (Continued)
Code
F00014
OIM Display
REVERSED TACH
LEADS
Description
The difference between the speed reference and speed feedback was
greater than TACH LEAD FLT THRESH (P.227) for the time specified in TACH
LEAD FLT DELAY (P.228).
Possible causes:
• Tachometer or encoder leads are reversed.
• The motor armature leads are reversed.
• The motor field leads are reversed.
• There is an overhauling load.
• The drive was not tuned properly.
F00015
INVERTING FAULT
AVOIDED
F00016
PHASE LOSS
F00030 to
F00041
SCR
#n NOT
The inverting fault avoidance logic has detected conditions that could have
caused an inverting fault. The drive took action to avoid an actual inverting
fault. See section 13.7, Setting Up Inverting Fault Avoidance, for more
information on this fault.
The measured AC line voltage fell below 75% of the value specified by
NOMINAL AC LINE VOLTS (P.307).
“n” is the number of the SCR that is not operating. n = 1-6, 11-16.
OPERATING
Possible causes:
• Disconnected, loosely connected or damaged thyristor gating circuit.
• Improper current minor loop tuning.
• Improper speed/voltage loop tuning.
• Failed thyristor.
F00042
MULTIPLE SCRS NOT
One or more thyristor (SCR) is not carrying an equal load.
OPERATING
Possible causes:
• Disconnected, loosely connected or damaged thyristor gating circuit.
• Blown AC line fuse(s).
• Improper current minor loop tuning.
• Improper speed/voltage loop tuning.
• Failed thyristor.
Troubleshooting the FlexPak 3000 Drive
13-5
Table 13.1 – Fault Codes (Continued)
Code
F00060
OIM Display
SELF TUNING FAULT
Description
Self tune aborted by external input.
Possible causes:
• Operator stop asserted.
• Drive interlock(s) open.
• Drive fault became active.
F00061
SELF TUNING FAULT
Non-zero speed feedback at self-tune start.
Possible causes:
• Analog tachometer only: ANALOG TACH ZERO ADJ (P.202) not set properly.
• Incorrect speed feedback scaling or offset.
• Overhauling load causing motor shaft rotation.
F00062
SELF TUNING FAULT
Calculated armature inductance is out of range.
Possible causes:
•
•
•
•
F00063
SELF TUNING FAULT
Motor armature winding not connected or open circuit.
Blown inverting fault (DC) fuse.
Inverting fault breaker tripped.
Armature inductance too high. Tune current minor loop manually.
Maximum current with minimum rotation.
Possible causes:
• Motor cannot rotate freely.
• Motor load is too high.
• Motor field not at normal operating temperature.
F00064
SELF TUNING FAULT
Attached inertia is out of range.
Possible causes:
• Maximum self-tune speed reached.
• Overhauling load present.
• High mechanical friction present.
• The speed loop cannot be self-tuned. Tune speed loop manually.
13-6
FlexPak 3000 DC Drive Software Reference
Table 13.1 – Fault Codes (Continued)
Code
F00065
OIM Display
SELF TUNING FAULT
Description
Speed unstable.
Possible causes:
•
CML
not properly tuned before speed loop.
• Tachometer or encoder feedback device connected incorrectly.
F00066
SELF TUNING FAULT
SELF TUNE STABILITY
(P.219) is too low.
Possible causes:
• Specified stability is less than that calculated by CML self-tuning. Use 50
or more.
F00067
SELF TUNING FAULT
SELF TUNE STABILITY
(P.219) is too low.
Possible causes:
• Specified stability is less than that calculated by CML self-tuning. Use 75
or more.
F00089 to
F00099
SELF TUNING FAULT
Fatal self-tuning fault occurred.
Possible cause:
• Self-tuning was unable to complete. Tune manually.
F00100
MAIN CONTACTOR DID
NOT OPEN
The main (FN) contactor did not open following a run or jog request. If a
dynamic braking kit is used, the dynamic braking auxiliary contact is wired
in series with the FN auxiliary contact.
Possible causes:
• Disconnected, loosely connected, or damaged FN, FN auxiliary, dynamic
braking, or dynamic braking auxiliary wiring.
•
FN, FN auxiliary, dynamic braking, or dynamic braking auxiliary contactor
failure.
• Disconnected, loosely connected, or damaged main contactor or
dynamic braking control wiring (MCR or DBCR).
F00200
POWER FAILURE
The power supply input voltage momentarily went below tolerance.
Possible causes:
• AC line voltage dip.
• Disconnected, loosely connected, or damaged J7 ribbon cable or power
supply input wiring
Troubleshooting the FlexPak 3000 Drive
13-7
Table 13.1 – Fault Codes (Continued)
Code
F00700
OIM Display
FACTORY DEFAULTS
RESTORED
Description
The stored parameter values were determined to be invalid. Factory
default values have been restored. All parameter values (including any
factory set parameters) must be re-adjusted based on your application
before operating the drive. After all parameters have been set properly, a
memory save must be performed followed by a fault reset.
Possible causes:
• Power loss during a prior memory save.
• New Regulator board.
• Defective Regulator board.
F00701
FAULT LOG RESTORE
FAILURE
The fault log information stored in retentive memory was determined to be
invalid. The fault log has been cleared.
Possible causes:
• Power loss during a prior fault log save.
• Defective Regulator board.
F00702
KEYPAD REF RESTORE
FAILURE
The keypad reference value stored in retentive memory was determined to
be invalid. The keypad reference has been set to the MINIMUM SPEED
(P.003) value.
Possible causes:
• Power loss during a previous keypad reference save.
• Defective Regulator board.
F00703
OIM KEY RESTORE
FAILURE
The OIM key states stored in retentive memory are invalid. The
FORWARD/REVERSE key has been set to FORWARD and the AUTO/MANUAL key
has been set to MANUAL.
It is possible to get this fault on a drive equipped with a DCM. If so, replace
the Regulator board.
Possible cause: Defective Regulator board.
F00800
INVALID FIELD
Installed field supply is not supported by the regulator.
INSTALLED
Possible causes:
• Disconnected, loosely connected, or damaged field supply wires.
• Regulated field supply failure.
• Regulator board failure.
F00801
FIELD FEEDBACK
OFFSET TOO HIGH
Regulated field supply feedback offset is too high.
Possible causes:
• Disconnected, loosely connected, or damaged field supply wires.
• Regulated field supply failure.
• Regulator board failure.
13-8
FlexPak 3000 DC Drive Software Reference
Table 13.1 – Fault Codes (Continued)
Code
F01000 to
F01999
OIM Display
MICROBUS FAULT
Description
An error occurred on the Microbus.
Possible causes:
• Electrical noise due to improper wiring practices or unsuppressed brake
coils, relays, or contactors.
•
•
•
•
F00999
and
F02000 to
F03999
MICROPROCESSOR
Disconnected, loosely connected or damaged Microbus ribbon cable.
Defective Regulator board.
F01000-F01799: Defective Microbus peripheral or Regulator board.
F01810-F01816: A Microbus peripheral was found that is not supported
by the regulator software.
A microprocessor hardware or software fault occurred.
HW/SW FAULT
Possible causes:
• Electrical noise due to improper wiring practices or unsuppressed break
coils, relays, contactors.
• Defective Regulator board.
Table 13.2 – Alarm Codes 1
Code
A00001
Display
MOTOR BRUSH WEAR
LOW
Description
The motor brush wear detector indicates that the brushes are worn and
require replacement. If a motor brush wear detector is not used,
customer terminal strip terminals 12 and 14 must be jumpered to inhibit
this alarm when DIG IN 0 SELECT (P.428) is set to BRUSH WEAR.
Possible causes:
• Worn motor brushes.
• Disconnected, loosely connected, or damaged motor brush wear
indicator wiring.
• Motor brush wear indicator failure.
A00002
AC LINE VOLTAGE
The AC line voltage fell below 90% of NOMINAL AC LINE VOLTS (P.307).
LOW
Possible causes:
• Low AC line voltage.
• Incorrect value entered for NOMINAL AC LINE VOLTS (P.307).
• Blown AC line fuse(s).
A00003
AC LINE VOLTAGE
The AC line voltage rose above 115% of NOMINAL AC LINE VOLTS (P.307).
HIGH
Possible causes:
• High AC line voltage.
• Incorrect value entered for NOMINAL AC LINE VOLTS (P.307).
1To access the alarm log, press the FAULT key on the OIM twice.
Troubleshooting the FlexPak 3000 Drive
13-9
Table 13.2 – Alarm Codes (Continued)1
Code
A00004
Display
Description
COMMUNICATION
Network communications is missing or failed to communicate with
master (CONTROL SOURCE set to NETWORK).
TIMEOUT
Possible causes:
NETWORK
• NETW CONNECT TYPE (P.910) was changed from BASIC to FULL.
• NETW DROP NUMBER (P.900) was changed.
• Network option cable connections are loose or not connected.
• Network option device failed or master communications failed.
A00005
INVERTING FAULT
AVOIDED
A00006
CONTROL NET
PROGRAM MODE
A00030
MAIN CONTACTOR
DID NOT OPEN
The inverting fault avoidance logic has detected conditions that could
have caused an inverting fault. The drive took action to avoid an actual
inverting fault. See section 13.7, Setting Up Inverting Fault Avoidance, for
more information on this alarm.
The PLC communicating with the drive from ControlNet has entered
Program mode; drive operation is determined by CNI PROG/RUN MODE
(P.915).
The main (FN) contactor did not open following a stop. If a dynamic
braking kit is used, the dynamic braking auxiliary contact is wired in
series with the FN auxiliary contact.
Possible causes:
• Disconnected, loosely connected, or damaged FN, FN auxiliary,
dynamic braking, or dynamic braking auxiliary wiring.
•
FN, FN auxiliary, dynamic braking or dynamic braking auxiliary
contactor failure.
• Disconnected, loosely connected, or damaged main contactor or
dynamic brake control wiring (MCR or DBCR).
A00031
MAIN CONTACTOR
DID NOT CLOSE
The main (FN) contactor did not close following a run or jog command. If
a dynamic braking kit is used, the dynamic braking auxiliary contact is
wired in series with the FN auxiliary contact.
Possible causes:
• Disconnected, loosely connected, or damaged FN, FN auxiliary,
dynamic braking or dynamic braking auxiliary wiring.
•
FN, FN auxiliary, dynamic braking, or dynamic braking auxiliary
contactor failure.
• Disconnected, loosely connected or damaged main contactor or
dynamic brake control wiring (MCR or DBCR).
• If Dynamic Braking kit is not installed, missing jumper wire at terminals
3 and 4 on the field/DB terminal strip.
1 To access the alarm log, press the FAULT key on the OIM twice.
13-10
FlexPak 3000 DC Drive Software Reference
Table 13.2 – Alarm Codes (Continued)1
Code
A00032
Display
SUSTAINED SPEED
Description
Motor speed did not fall below STOP SPEED THRESHOLD (P.113) in the
required amount of time during a stop (this time is automatically set to
two times the DECELERATION TIME (P.002)).
Possible causes:
•
DECELERATION TIME
•
STOP SPEED THRESHOLD
(P.002) not set properly.
(P.113) not set properly.
• Overhauling load maintaining motor speed higher than the STOP SPEED
THRESHOLD
(P.113).
• Incorrect speed/voltage feedback scaling.
A00033
SUSTAINED
ARMATURE CURRENT
Armature current was unable to reach discontinuous conduction while
stopping the drive.
Possible cause:
• Motor CEMF too high or line voltage too low for proper commutation.
A00050
CML FEEDBACK
SCALING ERROR
A00051
LOW MINIMUM SPEED
Armature current feedback could not be scaled properly based on the
values entered for MOTOR RATED ARM AMPS and MAXIMUM CURRENT. Verify
that these parameter values are correct for your application. Verify that
CT TURNS RATIO has been set to the correct value for your drive.
The MINIMUM SPEED value is less than 10% of the MAXIMUM SPEED value.
This alarm will not be triggered on powerup. It only occurs when
maximum or minimum speed has changed.
Verify that these parameter values are correct for your application.
A00052
(no message)
(P.226) has changed state, either enabling or
disabling the negative current limit inverters. The parameters POS
CURRENT LIM SEL (P.223) and NEG CURRENT LIM SEL (P.224) have been set
to REGISTER. Carefully check your current limit scheme and the values of
POSITIVE CURRENT LIM (P.005) and NEGATIVE CURRENT LIM (P.006) to avoid
unintended drive operation. Also see section 5.4, Configuring the Speed
Loop Current Limits.
A00700
RETENTIVE MEMORY
An attempt to save information (parameter values, fault log data or the
keypad reference value) to retentive memory failed. The drive may
continue to be operated.
SAVE FAILURE
NEG CUR LIM INV EN
Possible cause:
• Regulator board failure.
1To
access the alarm log, press the FAULT key on the OIM twice.
Troubleshooting the FlexPak 3000 Drive
13-11
13.2 Adjusting the Tachometer or Encoder
Loss Sensitivity
Normally, tachometer or encoder loss is reported when the SCR firing angle reaches
109° when armature current is present and the speed feedback is less than 5% of TOP
SPEED (P.011). If you are getting nuisance trips associated with high inertia loads, you
can adjust the SCR angle at which tachometer or encoder loss is reported.
!
ATTENTION: This equipment is at line voltage when AC power is
connected to the drive. Disconnect and lock out incoming power to the
drive before proceeding. After power is removed, verify that no voltage
exists at power terminals 181, 182, and 183 before touching any internal
parts of the drive. Failure to observe this precaution could result in severe
bodily injury or loss of life.
If you are getting nuisance tachometer or encoder loss trips:
Step 1.
Lockout and tag power as necessary.
Step 2.
Turn off power to the drive.
Step 3.
Check all tachometer or encoder lead connections, including polarity.
Step 4.
If there is no problem with the connections, increase TACH LOSS SCR ANGLE
by 1 degree.
Step 5.
Restart the drive.
Step 6.
If a tachometer or encoder loss is reported and the angle is less than 127°,
repeat this procedure.
TACH LOSS SCR ANGLE
The SCR firing angle
at which tachometer
or encoder loss is
determined when
current is present and
motor speed is less
than 5% of TOP SPEED
(P.011).
(P.608)
Parameter Range:
0 to 127 DEGREE
Default Setting:
109 DEGREE
Parameter Type:
Tunable
OIM Menu Path(s):
Additional Parameters (listed by parameter number)
This parameter is also used to determine an open armature. An open armature is
detected when the:
• armature current is zero
• motor speed feedback is less than 5% of TOP SPEED (P.011)
•
SCR
!
13-12
firing angle is equal to TACH LOSS SCR ANGLE
ATTENTION: The incorrect setting of this parameter can cause an
overspeed condition. Set the value of this parameter only as high as
necessary to stop tachometer or encoder loss. Failure to observe this
precaution could result in bodily injury.
FlexPak 3000 DC Drive Software Reference
13.3 Phase Locked Loop (PLL) Maximum Error
If your drive power is supplied by a source that cannot maintain a suitable fixed
frequency output (such as an alternator), you can adjust this parameter to prevent
faults related to line synchronization.
PLL MAXIMUM ERROR
Maximum allowable
change in line period
per AC line cycle.
(P.308)
Parameter Range:
2 to 1000 µsec
Default Setting:
2 µsec
Parameter Type:
Tunable
OIM Menu Path(s):
Current Minor Loop (CML) - Three Phase
AC Line
This parameter should only be increased when drive power is supplied by a source
that cannot maintain a suitable fixed frequency output (such as an alternator) to
prevent faults related to line synchronization.
Troubleshooting the FlexPak 3000 Drive
13-13
13.4 SCR Diagnostics and Adjusting Open
SCR Sensitivity
Under normal drive operation, the load carried by each SCR is relatively equal, as
shown in figure 13.1.
Figure 13.1 – SCR Armature Current During Normal Operation
If one or more SCRs fail to turn to on, a unique pattern of insufficient or missing current
pulses results, as shown in figure 13.2.
Open SCR diagnostics detects SCRs that are not conducting by analyzing the level of
current produced by each SCR pair firing. If one or more SCR consistently fails to
produce current at a level approximately equal to other SCRs that fired, the drive
concludes that an open SCR has occurred.
The open SCR diagnostic calculates the percentage deviation of current feedback for
each pair of SCRs from the average current feedback. The percent deviation must
exceed the value set for OPEN SCR SENSITIVITY (P.600) before the diagnostic proceeds
to the next part of the diagnostic.
In the next part of the diagnostic, deviations from the average current are integrated
over time to eliminate transient effects from the calculation. When the integration
reaches the value of OPEN SCR TRIP THRESH (P.601), an open SCR fault is generated.
If you are experiencing nuisance SCR faults, you can use these parameters to increase
the tolerance to conditions that could trigger an open SCR fault.
13-14
FlexPak 3000 DC Drive Software Reference
Figure 13.2 – Load SCRs Fail to Turn On
OPEN SCR SENSITIVITY
Open SCR diagnostic
sensitivity
adjustment.
(P.600)
Parameter Range:
0 to 100%
Default Setting:
50%
Parameter Type:
Tunable
OIM Menu Path(s):
Current Minor Loop (CML) - SCR Diagnostics
Unbalanced AC lines can cause load sharing differences between SCRs. Increase
the value of this parameter to increase the tolerance of SCR load sharing differences
due to unbalanced lines.
OPEN SCR TRIP THRESH
Open SCR trip
threshold. Extremely
unusual load
conditions or severe
current loop
instability can cause
nuisance open SCR
faults.
(P.601)
Parameter Range:
800 to 4000
Default Setting:
1600
Parameter Type:
Tunable
OIM Menu Path(s):
Current Minor Loop (CML) - SCR Diagnostics
Increasing this parameter increases the tolerance of such disturbances.
Troubleshooting the FlexPak 3000 Drive
13-15
13.5 Armature Phase Fire Test
!
ATTENTION: Only qualified electrical personnel familiar with the
construction and operation of this equipment and the hazards involved
should perform this test. Read and understand this section in its entirety
before proceeding. Failure to observe this precaution could result in
severe bodily injury or loss of life.
ATTENTION: This is an open loop test. Lock the motor shaft or
disconnect the motor armature leads from the drive and replace them
with a dummy load. Failure to observe this precaution could result in
severe bodily injury or loss of life.
ATTENTION: If the field is disconnected, the armature must be locked
to prevent rotation. Failure to observe this precaution could result in bodily
injury.
ATTENTION: This equipment is at line voltage when AC power is
connected to the drive. Disconnect and lock out incoming power to the
drive before proceeding. After power is removed, verify that no voltage
exists at power terminals 181, 182, and 183 before touching any internal
parts of the drive. Failure to observe this precaution could result in severe
bodily injury or loss of life.
An armature phase fire test mode is available to verify the operation of the S6 or S6R
rectifier bridge. This test should only be performed by qualified personnel. Note that
this test is not available through the DCM.
To perform an armature phase fire test:
Step 1.
Lockout and tag power as necessary.
Step 2.
Turn off power to the drive.
Step 3.
Either lock the motor armature to prevent rotation or disconnect the motor
armature leads from the drive and replace with a dummy load.
When locking the motor armature, the motor field winding can be
disconnected to prevent excessive torque. If the motor field winding is
disconnected, jumper J20 should be set to DISABLE to inhibit field current
loss faults.
13-16
Step 4.
Turn on power to the drive. The drive must be stopped and the Drive Ready
Indicator must be ON.
Step 5.
Set CONTROL SOURCE to KEYPAD.
Step 6.
On the OIM, select Current Minor Loop (CML) – SCR Diagnostics – Armature
Phase Fire Test.
Step 7.
Set PHASE FIRE TST BRIDGE (P.310). This parameter must be set to the
appropriate value before activating the armature phase fire test mode.
Step 8.
Attach an oscilloscope to the armature current feedback test point (J17+,
J22– on the Regulator board). Note that the CS3000 software oscilloscope
mode does not have sufficient bandwidth for this test.
Step 9.
Press
. The armature phase fire test mode is now active. The OIM
Running indicator will be on.
FlexPak 3000 DC Drive Software Reference
Step 10. Set PHASE FIRE TEST DELTA (P.309) to 55 degrees. Slowly increase PHASE
FIRE TEST DELTA until a steady pattern of “bumps” appears on the
oscilloscope. If all thyristors in the selected bridge are operating, there will
be six bumps per AC line cycle, similar to the example in figure 13.1. If any
bumps are missing, one or more thyristors are not conducting, similar to the
example in figure 13.3.
Note that conduction will not begin until the firing angle is sufficiently
advanced (PHASE FIRE TEST DELTA (P.309) more than 60 degrees). A rate
limit block limits the rate of change of firing angle advances to prevent
sudden increases in current. To prevent the drive from entering continuous
conduction during this test, PHASE FIRE TEST DELTA (P.309) should not
exceed 89 degrees.
Figure 13.3 – Thyristors Fail to Conduct
Step 11. Press
to stop the armature phase fire test.
Step 12. Turn off power to the drive (lockout and tag as necessary).
Step 13. Either unlock the motor armature or remove the dummy load and reconnect
the motor armature leads.
If the motor field winding was disconnected, reconnect it and return jumper
J20 to its original position (typically ENABLE).
Troubleshooting the FlexPak 3000 Drive
13-17
PHASE FIRE TEST DELTA
The test firing
conduction angle of
the SCRs. If equal to
0, the armature
power bridge is off. If
it is set to 180, the
armature power
bridge is fully on.
Parameter Range:
0 to 180 DEGREE
Default Setting:
0 DEGREE
Parameter Type:
Tunable
OIM Menu Path(s):
Current Minor Loop (CML) – SCR Diagnostics –
Armature Phase Fire Test.
!
PHASE FIRE TST BRIDGE
Selects which
armature bridge
(forward or reverse) is
used during the
phase fire test. This
input can only be
changed while the
drive is stopped.
(P.309)
ATTENTION: The armature phase fire test is unregulated. To prevent
excess motor speed, either disconnect the armature leads from the drive
and replace with a similar load or disconnect the field leads from the
drive. Lock the motor armature shaft securely to prevent rotation in either
direction prior to selecting this test. Failure to observe this precaution
could result in severe bodily injury or loss of life.
(P.310)
Parameter Range:
ON
OFF
Default Setting:
OFF
Parameter Type:
Tunable
OIM Menu Path(s):
Current Minor Loop (CML) - SCR Diagnostics Armature Phase Fire Test
OFF selects the forward bridge (A1 positive with respect to A2). ON selects the
reverse bridge (A1 negative with respect to A2).
13-18
FlexPak 3000 DC Drive Software Reference
13.6 Setting Reversed Tachometer or Reversed Encoder
Lead Detection
The FlexPak 3000 drive includes an algorithm for detecting reversed speed feedback
wiring. The logic verifies that the difference between the speed reference and the
speed feedback is greater than the threshold set by TACH LEAD FLT THRESH (P.227) for
the amount of time set by TACH LEAD FLT DELAY (P.228). When the threshold is greater
than the difference for the specified delay, and the speed reference and speed
feedback are opposite in polarity, a REVERSED TACH LEADS fault is generated
(fault F00014).
Fault F00014 can also be caused by an overhauling load, improper drive tuning, or a
tachometer or encoder loss.
The tachometer lead fault parameters have default values that are set so that reversed
tachometer lead detection is effectively disabled. You must empirically determine
values for these parameters so that reversed tachometer or encoder wiring can be
detected without generating nuisance faults.
The ability to check for reversed tachometer lead faults is useful for machine
manufacturers that require their equipment to be disassembled for shipping and
reassembled and rewired at a customer site.
This option is not available for AC tachometers.
TACH LEAD FLT DELAY
(P.228)
The amount of time
that parameter P.227
(TACH LEAD FLT
THRESH) must be
exceeded before a
Parameter Range:
0 to 32767 msec
Default Setting:
10000 msec
Parameter Type:
Tunable
REVERSED TACH
LEADS fault (F00014)
OIM Menu Path(s):
Additional Parameters (listed by parameter number)
is generated.
TACH LEAD FLT THRESH
The threshold after
which a REVERSED
TACH LEADS fault
(F00014) is
generated.
(P.227)
Parameter Range:
0.0 to 250.0% of TOP SPEED
Default Setting:
200.0%
Parameter Type:
Tunable
OIM Menu Path(s):
Additional Parameters (listed by parameter number)
A REVERSED TACH LEADS fault is generated if the difference between the speed
reference and speed feedback is greater than this value for at least the amount of
time set by TACH LEAD FLT DELAY.
Troubleshooting the FlexPak 3000 Drive
13-19
13.7 Setting Up Inverting Fault Avoidance
An inverting fault is an uncontrollable high current resulting from commutation failure.
It is typically caused by an excessive armature-to-line voltage ratio, which can be
caused by situations such as a line voltage dip, a poorly tuned field regulator, or an
overhauling load. Inverting faults can also be caused by thyristor misfiring induced by
noise, or a current minor loop rate limit that is set too fast.
Inverting faults can cause:
•
•
•
•
•
clearing of the AC line fuses that protect the armature thyristors
tripping of an inverting fault circuit breaker
clearing of an armature DC fuse
loss of thyristors
degradation of commutator due to high current
• flashover in the motor or power unit
Inverting faults are only a concern in regenerative DC drive applications. Typically, a
regenerative drive application uses a regenerative power unit (S6R). Non-regenerative
power units (S6) can also be used in a regenerative configuration, such as an unwinder
using continuous regeneration or if the drive uses field reversing for stopping.
Inverting fault avoidance can be used in regenerative drive applications to prevent the
occurrence of an inverting fault. If inverting fault avoidance is used, the drive
recognizes conditions that could lead to an inverting fault and dynamically adjusts
drive operation to prevent an inverting fault.
INV FAULT AVOID SEL
(P.312)
Allows you to determine how
the drive responds to an
inverting fault.
Parameter Range:
1 = DISABLED
2 = FAULT IMMEDIATELY
3 = DELAY BEFORE FAULT
See table 13.3 for results of the
parameter settings.
Default Setting:
DISABLED
Parameter Type:
Configurable
OIM Menu Path(s):
Additional Parameters (listed by parameter
number)
!
ATTENTION: When activated, inverting fault avoidance takes control of
the current minor loop by either forcing the current reference to zero (if
the drive is regenerating) or by disabling the regenerative bridge (if the
drive is not regenerating). The user must analyze the application to
determine whether or not inverting fault avoidance should be used.
Failure to observe this precaution could result in bodily injury.
ATTENTION: Enabling the inverting fault avoidance logic does not
guarantee that an inverting fault will not occur in all instances. The user
must provide safeguards against inverting faults. Failure to observe this
precaution could result in bodily injury.
13-20
FlexPak 3000 DC Drive Software Reference
.
Table 13.3 – Inverting Fault Avoidance Settings
Parameter Setting
Is Drive
Regenerating
or Attempting
to Regenerate?
Drive Action
DISABLED
n/a
None.
FAULT IMMEDIATELY
Yes
• Immediately stops (coast/DB).
• Generates an INVERTING FAULT AVOIDED fault (F00015).
No (drive is
motoring)
• Generates an INVERTING FAULT AVOIDED alarm (A00005).
• Continues normal operation on the motoring bridge until a
request to regenerate is detected.
A request to regenerate occurs when the current minor loop
reference and feedback become opposite polarity. When a request
to regenerate is detected, the drive immediately stops (coast/DB)
and generates an INVERTING FAULT AVOIDED fault (F00015).
DELAY BEFORE FAULT
Yes
• Immediately forces the current minor loop reference to zero.
• Logs an INVERTING FAULT AVOIDED alarm (A00005).
• Continues operate normally for up to two seconds. The drive can
generate a motoring current as needed but will coast while a
demand for regenerative current exists.
• If the demand for regenerative current persists for approximately
two seconds, the drive:
• Stops (coast/DB).
• Generates an INVERTING FAULT AVOIDED fault (F00015).
• If the conditions that caused the alarm return to normal before
two seconds, the drive returns to normal operation (the
regenerative bridge is re-enabled) without stopping.
No (drive is
motoring)
• Logs an INVERTING FAULT AVOIDED alarm.
• Continues normal operation on the motoring bridge until a
request to regenerate is detected.
• When a request to regenerate is detected, the drive continues
operate normally for up to two seconds. The drive can generate a
motoring current as needed but will coast while a demand for
regenerative current exists.
• If the demand for regenerative current persists for approximately
two seconds, the drive:
• Stops (coast/DB).
• Generates an INVERTING FAULT AVOIDED fault (F00015).
• If the conditions that caused the alarm return to normal before
two seconds, the drive returns to normal operation (the
regenerative bridge is re-enabled) without stopping.
Troubleshooting the FlexPak 3000 Drive
13-21
13.8 Checking the AC Line Period and Voltage
AC LINE PERIOD
(P.393)
The AC line period as
measured by the drive in
microseconds. Line period =
1/line frequency in Hertz.
AC LINE VOLTAGE
Parameter Range:
n/a
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Current Minor Loop (CML) - Three Phase AC
Line
(P.392)
The AC line RMS voltage as
measured by the drive.
Parameter Range:
n/a
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Current Minor Loop (CML) - Three Phase AC
Line
PHASE LOSS DETECTION EN
Enables or disables phase loss
detection.
(P.609)
Parameter Range:
DISABLE
ENABLE
Default Setting:
ENABLE
Parameter Type:
Configurable
OIM Menu Path(s):
Current Minor Loop (CML) - Three Phase AC
Line
When set to ENABLE, a PHASE LOSS fault (F00016) is generated when the
measured AC line voltage drops below 75% of the value specified by
NOMINAL AC LINE VOLTS (P.307) for more than 2 seconds.
13-22
FlexPak 3000 DC Drive Software Reference
13.9 Checking Drive Information
You can use these parameters to determine your drive regulator type, if your power
unit is S6R (regenerative) or S6 (non-regenerative), and regulator software version.
J15 REGULATOR TYPE
(P.799)
Indicates the position of jumper
J15, REGULATOR TYPE. This
jumper selects the type of
regulator, SPEED/VOLTAGE or
CURRENT/TORQUE. This jumper
is only read at powerup.
Parameter Range:
SPEED/VOLTAGE
CURRENT/TORQUE
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Drive Information
Current Minor Loop (CML) - CML Test Points
When the drive is configured as a speed regulator (J15 on the Regulator
board set to SPEED), the input selected by AUTO REFERENCE SELECT (P.103)
is used as a speed reference.
When the drive is configured as a torque regulator, (J15 on the Regulator
board set to CURRENT), the input selected by AUTO REFERENCE SELECT
(P.103) is used as a torque reference to the current minor loop.
See the hardware manual for information on setting J15.
POWER UNIT TYPE
(P.795)
Indicates if the drive uses an
S6R (regenerative) or an S6
(non-regenerative) power unit.
Parameter Range:
S6 (NON-REGEN)
S6R (REGEN)
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Drive Information
If the power unit type is S6 (non-regenerative), NEGATIVE CURRENT LIM
(P.006) will be automatically fixed to 0, and REVERSE DISABLE (P.015) fixed
to DISABLE (preventing reverse direction).
REGULATOR SW VERSION
(P.794)
Lists the regulator software
version.
Parameter Range:
n/a
Default Setting:
n/a
Parameter Type:
Output
OIM Menu Path(s):
Drive Information
Troubleshooting the FlexPak 3000 Drive
13-23
13-24
FlexPak 3000 DC Drive Software Reference
APPENDIX A
Block Diagrams
In these block diagrams:
•
All caps indicate parameter names. For example: MOTOR RATED ARM AMPS.
•
Output parameters are in parenthesis. For example: (FIELD ECONOMY ACTIVE).
•
All caps and italics indicate selectable options. For example: REGISTER.
•
* indicates a default setting. For example: *REGISTER
Figure A.1 – Overview Block Diagram of the FlexPak 3000 Drive
Block Diagrams
A-1
To Figure A.8, Full
Block Diagram
To Figure A.8, Full
Block Diagram
Figure A.2 – Speed Reference Overview
To Figure A.8, Full Block Diagram
To Figure A.8, Full Block Diagram
To Figure A.8, Full Block Diagram
To Figure A.8, Full Block Diagram
To Figure A.8, Full Block Diagram
To Figure A.8, Full Block Diagram
To fault processing
To Figure A.8, Full Block Diagram
Figure A.3 – Drive Sequencing Overview
A-2
FlexPak 3000 DC Drive Software Reference
From Figure A.6
* Default Selection
Figure A.4 – Field Block Diagram if Field Current Regulator Kit is Installed
From Figure A.7, Level Detector Block Diagram
From Figure A.8, Full Block Diagram
From Figure A.8, Full Block Diagram
From Figure A.4, Field Block Diagram if Field
Current Regulator Kit is Installed
Figure A.5 – Digital, Metering, Frequency, and Analog Outputs Block Diagram
Block Diagrams
A-3
Figure A.6 – Block Diagram for Digital, Analog, and Frequency Inputs on the I/O Expansion Board
* Default Selection
Figure A.7 – Level Detector Block Diagram
A-4
FlexPak 3000 DC Drive Software Reference
ANLG AUTO
ZERO ADJ
ANLG AUTO
SIGNAL TYPE
TOP SPEED
ANLG AUTO
GAIN ADJ
SOFTWARE
SCALING
A/D
AUTO
REFERENCE
SELECT
(ANALOG AUTO
REFERENCE)
* ANALOG
HI
Analog Auto
Reference
(+)CTB-19
(-)CTB-20
FREQUENCY IN
EN
LO
* +/- 10V
-TOP SPEED
(TORQUE
REFERENCE)
NETWORK
Forward/Reverse
Command
0 - 10V
0
CONTROL
SOURCE
SELECT
* TERMBLK
LIMIT
4 - 20mA
10 - 50mA
From I/O
Exp. Inputs
Block Diagram
Network Reference
ANLG AUTO
SIG TYPE
Speed Reference Ramp
(SPEED RAMP INPUT TP)
To OCL Feedback
Serial Port
Reference
(CS3000)
MINIMUM SPEED
SERIAL
Keypad
Reference
(OIM/DCM)
CONTROL
SOURCE
SELECT
KEYPAD
RESET
CONTROL
Auto
LIMIT (w/hysteresis)
SERIAL
* TERMBLK
+
PROPORTIONAL
MOP Increment (CTB-63)
MOP Decrement (CTB-62)
INC
DEC
RST
(MOP OUTPUT)
MOP
MOP
O
MAXIMUM SPEED
MINIMUM SPEED
MAX
MIN
ACC
DEC
PRESET SPEED 1
A=OFF, B=ON
PRESET SPEED 2
A=ON, B=OFF
TRIM *
DRAW
PERCENT
* NO TRIM
0
Preset Speed
Select A/B
(CTB-59, 60)
A=OFF, B=OFF
* ANALOG
TRIM MODE
SELECT
INCREMENTAL
TOP SPEED
* OFF
(SPEED RAMP
OUTPUT)
OCL ENABLE
(DIG IN 0)
* BRUSH WEAR
disable
AUTO MODE MIN BYPASS
jogging
JOG SPEED SELECT
speed loop enable
DIG IN 0 SELECT
Internal Sequencing
(TRIM OUTPUT)
Internal Sequencing
jogging
On
PRESET SPEED 3
MOP DECEL TIME
0
(ANALOG MAN REFERENCE)
ANLG MAN
REF ZERO ADJ
Analog Manual
Reference
(+)CTB-17
(-)CTB-18
(10V)CTB-16
A/D
SOFTWARE
SCALING
ANLG MAN
REF GAIN ADJ
MAXIMUM
SPEED
RAMP STOP DECEL TIME
MINIMUM
SPEED
* NO TRIM
TRIM MODE SELECT
On
MAX/MIN
PROPORTIONAL
Off
From I/O Exp.
Inputs Block
Diagram
(OCL RAMP OUTPUT)
KP
_ocl_enable
(from below)
NETW IN REG 1, 2, 3
HI
INITV
S-CURVE
FREQUENCY IN
From Network
SPD SCALING
OCL PI
POSITIVE
LIMIT
OCL TRIM RANGE
JERK
(OCL REFERENCE)
ANALOG IN 2
* DECELERATION TIME
1 + DRAW PERCENT
OCL
REFERENCE
SELECT
* REGISTER
ANALOG IN 1
Ramp Stop
Command
RAMP STOP DECEL TIME
RAMP STOP DECEL TIME
OCL PI
PROP
GAIN
OCL REF
ROUNDING
Off
OCL REF REGISTER
INCREMENTAL
Speed Reference Source Select
_ocl_enable
(to above)
I/O Expansion Kit
A=ON, B=ON
MOP ACCEL TIME
(OCL ENABLE)
Not Running
OFF
SERIAL
Regulator Board
Digital Input (TB-12)
RATE
IV DEC ACC
Drive
Status
Running
* KEYPAD
Not Installed
RST
OR
CONTROL
SOURCE
SELECT
Installed
(DIG IN 5)
ON
SCURVE
REVERSE DISABLE
MINIMUM SPEED
SMOOTHING
On
0
BYPASS REV DIS
MIN
Ramp Stop
Command
Off
EN
O
+
* TERMBLK
MOP RESET ENABLE
MAX
IN
NETWORK
TERMBLK
AUTO MODE RAMP BYPASS
(see Note 1)
(SPD SOURCE SELECT OUT)
KEYPAD
I/O Expansion
Digital Input (CTB-64)
S-CURVE ROUNDING
Forward/Reverse
Command
MAXIMUM SPEED
CONTROL
SOURCE
SELECT
NETWORK
Manual
MANUAL
REF
SELECT
Network OCL Enable
Outer Control Loop Enable Logic
1>
Auto/Manual
Command
+
-
RST\
INITV
ACC DEC
_ocl_enable
(from below)
RST\
WLD
(OCL OUTPUT)
MUL
*DISABLED
GAIN
PI
ENABLED
LO
TOP SPEED
STOP DECEL SELECT
Outer Control Loop
To Field Loop
DECELERATION TIME
(ANALOG MAN TRIM REF)
* REGISTER
TRIM RANGE
TRIM REFERENCE
SELECT
(DRAW PERCENTAGE OUT)
DECEL TIME
HI
* NONE
LIMIT
TRIM MODE SELECT
LO
NETW IN REG 1, 2, 3
ACCELERATION TIME
-TOP SPEED
* NO TRIM
TRIM MODE SELECT
* BYPASS
LEAD/LAG
INITV
ANALOG IN 2
3
SPD LOOP OUTPUT
(OCL FEEDBACK)
L/L
WLO RST\ RAT
SPEED RAMP OUTPUT
(in RPM)
LAG/LEAD
OCL
LEADLAG
LOW FREQ
NETW IN REG 1, 2, 3
From Network
PROPORTIONAL
ABS
OCL
LEADLAG
SELECT
3 ANALOG AUTO REFERENCE
ANALOG AUTO REFERENCE
INCREMENTAL
ACCEL TIME
GAIN
MUL
OCL
FEEDBACK
SELECT
ANALOG IN 1
From I/O Exp.
Inputs Block
Diagram
SPD LOOP OUTPUT
ANALOG IN 2
From Network
CML FEEDBACK
8 sample average
OCL PROP
TRIM SELECT
DIV
0
(CML FEEDBACK)
PROPORTIONAL
1 + DRAW PERCENT
MUL
GAIN
ANALOG IN 1
From I/O
Exp. Inputs
Block Diagram
OCL REF RAMP TIME
* NO TRIM
INCREMENTAL
TOP SPEED
ANALOG MANUAL
TRIM REF REGISTER
OCL PI
OCL PI
LEAD NEGATIVE
FREQ
LIMIT
OCL
LEADLAG
RATIO
_ocl_enable
1 + DRAW PERCENT
(OCL OUTPUT)
(P.814)
OCL TYPE3
POSN REG EN
*DISABLED
Forward/Reverse command
ENABLED
EN
Current Minor Loop Reference
MAXIMUM CURRENT
* NONE
0
INTERNAL
Software
Scaling
ANALOG IN 1
From I/O
Exp. Inputs
Block Diagram
NORMALIZED INERTIA
ANALOG IN 2
NETW IN REG 1, 2, 3
From Network
* REGISTER
POSITIVE CURRENT LIM
Speed Reference Mode Select
Current Limit
Stop Command
Jogging Active
Off
Off
+
LO
-
0
ANALOG MANUAL TRIM REF
WLG
LAG
PI
CURRENT/TORQUE
OFF
+
+
* ON
REVERSE DISABLE
* OFF
-TOP SPEED
(Other)
ANALOG IN 2
EN
(CML REFERENCE)
RATELIM
(ARMATURE
BRIDGE POL)
(CML ERROR)
IN
+
*
OUT
PI
Drive Test Mode
Phase
Firing
Logic
-
LO
KI
ARM PHASE FIRE
UNDERWIND ENABLE
(ARMATURE
DELTA)
CML REF RATE LIMIT
(CML FEEDBACK)
PHASE FIRE
TST BRIDGE
Adaptive
Gain
Logic
Off
RATE LIM
NETWORK
From Network NETW IN REG 1, 2, 3
OUT
ON
0
OR
NEG CURRENT
LIMIT SEL
ANALOG IN 1
From I/O
Exp. Inputs
Block Diagram
LIMIT
* SPEED/VOLTAGE
(SPD LOOP LAG
OUTPUT)
Internal Sequencing
(drive stopped)
SPD LOOP PI LEAD FREQ
* REGISTER
NEGATIVE CURRENT LIM
KP
HI
EN
ACC/DEC
WLD LO RST
CURRENT COMPOUNDING
J15
REGULATOR
TYPE
SPD LOOP
LAG BYPASS
-
(CURRENT COMPOUND TP)
(JOG RAMP OUTPUT)
SPD LOOP
LAG FREQ
(SPD LOOP
OUTPUT)
INIT KP HI
(SPD LOOP ERROR)
+
On
Current Minor Loop
CML PI PROP GAIN
Software
Scaling
(CML FEEDBACK)
8 sample average
REGISTER
SPD LOOP PI INIT SEL
* ZERO
(SPD LOOP
REFERENCE)
On
POSITIVE CURRENT LIM
SPD LOOP PI INIT VAL
ANALOG MANUAL TRIM REF
HI
+
+
SPD LOOP PI
PROP GAIN
NETW IN REG 1, 2, 3
0
From Network
(SPEED RAMP OUTPUT)
CML REF LIMIT SELECT
* SPD LOOP CUR LIM
ANALOG IN 2
From Network
TOP SPEED
POS CURRENT
LIMIT SEL
ANALOG IN 1
From I/O
Exp. Inputs
Block Diagram
INERTIA
COMP
SELECT
NEG CUR LIM INV EN
CONTROL SOURCE
SELECT
CML FEEDBACK GAIN ADJ
SPD LOOP PI RESET
(Network)
MUL
CML PI
LEAD FREQ
GAIN
IN
PHASE FIRE
TEST DELTA
* SPD LOOP CUR LIM
S6/S6R
3-phase
AC line
NEGATIVE CURRENT LIM
DIG IN 0
JOG SPEED SELECT
DIG IN 0 SELECT
* BRUSH WEAR
CT TURNS RATIO
(see instruction manual
to determine
current transformer
turns ratio Tp/Tn)
Jog Request
On
OCL ENABLE
Software
Scaling
Off
EN
ACC
NEG CUR LIM INV EN
SPEED FEEDBACK GAIN
RATELIM
0
MOTOR RATED
ARM VOLTS
DEC
ARM VOLTAGE
ZERO ADJ
ARM VOLTAGE
GAIN ADJ
Forward/Reverse Command
Mul
SOFTWARE SCALING
A/D
In
Speed Loop Regulator
Div
-
*(Other)
SOFTWARE
SCALING
(CML FEEDBACK)
8 sample average
Out
UNDERWIND ENABLE
+
1000
NETWORK
CONTROL SOURCE SELECT
Analog
Tachometer
(+ hi)CTB-21
(+ lo)CTB-22
(-)CTB-23
A/D
Pulse
Tachometer
(From optional
pulse tach kit)
F/D
ANALOG TACH
GAIN ADJ
ANALOG TACH
ZERO ADJ
* ARMATURE VOLT
FEEDBACK
SELECT
* BYPASS
LEAD/LAG
or
LAG/LEAD
DC TACH
(ANALOG TACH FEEDBACK)
SOFTWARE SCALING
AC TACH
PULSE TACH
(PULSE TACH
FEEDBACK)
TOP SPEED
SOFTWARE SCALING
PULSE TACH
PPR
(SPD LOOP
FEEDBACK)
WLD
MOTOR
SPD LEADLAG
LOW FREQ
Rectifier
20K ohm
Ground
jumper J22
"GROUND"
LEAD/LAG
LAG/LEAD
WRATIO
Analog to
Digital
Converter
Current
Feedback
Test Point
jumper J17
"ARM I"
(IR COMPENSATION TP)
IR COMPENSATION
ANLG TACH
VOLTS/1000
A2
EN
GAIN
(ARMATURE VOLTAGE)
Armature
Voltage
(Internal)
JOG ACCEL/DECEL TIME
A1
1
2
3
4
(J18 ARM I FB RESISTOR)
Hardware scaling jumper
J18 "ARM I FB RB"
39 ohm
OFF
CML REF LIMIT SELECT
15 ohm
JOG SPEED 1
REGISTER
EN
30 ohm
ON
20 ohm
JOG SPEED 2
Power
Unit
SPD LEADLAG
SELECT
SPD LEADLAG
RATIO
PULSE TACH
QUADRATURE
Figure A.8 – Full Block Diagram
Block Diagrams
A-5
A-6
FlexPak 3000 DC Drive Software Reference
APPENDIX B
New Features in Version 4.3
The FlexPak 3000 drive Version 4.3 software adds a configurable scan loop time to
the previous version of the drive. See parameter P.019 in chapter 5.
Features Added to Version 4.2
The FlexPak 3000 drive Version 4.2 software added these features to the previous
version of the drive:
•
Support for ControlNet Network Communication Board
When the ControlNet Network Communication board is installed in the drive,
complete access to all drive functions is available. See the ControlNet Network
Communications Option Board manual, D2-3425, for information on setting up
and using the ControlNet Network Communication board.
•
Type III Position Regulator
The FlexPak 3000 firmware was modified to allow the Outer Control Loop to be
used as the Current Minor Loop reference. This allows the drive to be configured
as a Type III position regulator. To use this feature, the drive must also be
configured as a current regulator via hardware jumper J15. A new parameter, OCL
TYPE3 POSN REG EN (P.814), was added to support this feature.
•
AC Line Phase Loss Detection
The FlexPak 3000 drive can generate a phase loss fault when the AC line drops
below 75% of a value set by the operator. A new parameter, PHASE LOSS
DETECTION (P.609), was added to support this feature.
•
Changes to Contactor Sequencing Timing
The main contactor sequencing was changed to support drive operation with main
contactors whose opening and closing times are longer than normal (such as
those on higher horsepower drives). The drive now waits up to 1000 ms before
generating faults or alarms.
•
New Features in Version 4.3
Other Changes
•
Additional Outer Control Loop feedback signal sources
•
Extended limits for the Outer Control Loop Trim Range parameter
•
New parameters added to the AutoMax Network alternate register map
B-1
B-2
FlexPak 3000 DC Drive Software Reference
APPENDIX C
Parameter Settings Record
This table provides space for you to record input parameter settings for reference.
Table C.1 – Parameter Settings Quick Reference Table
Parameter Selection/
Adjustment Range
Parameter
ACCELERATION TIME
(P.001)
AMX NETW REF SELECT
(P.911)
ANALOG TACH GAIN ADJ
5.0 seconds
•
•
DIRECT
DIRECT
BROADCAST
1.000
(P.202)
–200 to 200
0
0.750 to 1.250
1.000
•
•
•
•
0–10V
(P.101)
(P.100)
(P.102)
0–10V
+/–10V
4-20mA
10-50mA
–200 to 200
0
ANLG IN
1 GAIN ADJ (P.415)
0.750 to 2.250
1.000
ANLG IN
1 SIG TYPE (P.413)
•
•
•
•
+/–10 V
ANLG IN
1 ZERO ADJ (P.414)
–200 to 200
0
ANLG IN
2 GAIN ADJ (P.417)
0.750 to 2.250
1.000
ANLG IN
2 ZERO ADJ (P.416)
–200 to 200
0
(P.104)
0.750 to 1.250
1.000
(P.105)
–200 to 200
0
0.500 to 1.300
1.000
ANLG MAN REF GAIN ADJ
ANLG MAN REF ZERO ADJ
ANLG OUT
1 GAIN ADJ (P.420)
Parameter Settings Record
Your Data
Date
Setting
n (n=1 to 8)
0.750 to 1.250
ANLG AUTO SIGNAL TYPE
ANLG AUTO ZERO ADJ
0.1 to 300.0 seconds
(P.201)
ANALOG TACH ZERO ADJ
ANLG AUTO GAIN ADJ
Initial Factory
Setting (Default)
0–10 V
+/–10 V
4-20 mA
10-50 mA
C-1
Table C.1 – Parameter Settings Quick Reference Table (Continued)
Parameter Selection/
Adjustment Range
Parameter
ANLG OUT
1 SELECT (P.418)
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
(P.397)
CML REFERENCE (P.396)
CML ERROR (P.398)
SPD LOOP FEEDBACK (P.296)
SPD LOOP REFERENCE (P.295)
SPD LOOP ERROR (P.297)
SPD LOOP OUTPUT (P.299)
SPEED RAMP OUTPUT (P.199)
SPEED RAMP INPUT TP (P.198)
SPD SOURCE SELECT OUT (P.193)
TRIM OUTPUT (P.197)
ARMATURE VOLTAGE (P.289)
ANALOG TACH FEEDBACK (P.291)
PULSE TACH FEEDBACK (P.292)
CML FEEDBACK
Initial Factory
Setting (Default)
Date
Setting
ZERO
ZERO
FULL SCALE
POWER OUTPUT
(P.845)
(P.846)
OCL FEEDBACK (P.847)
OCL OUTPUT (P.848)
FIELD REFERENCE (P.590)
FIELD FEEDBACK (P.589)
NETW IN REG 1 (P.905)
NETW IN REG 2 (P.906)
NETW IN REG 3 (P.907)
OCL REFERENCE
OCL RAMP OUTPUT
ANLG OUT
1 SIG TYPE (P.419)
• 0–10 V
• +/–10 V
• 4-20 mA
+/–10 V
ANLG OUT
2 GAIN ADJ (P.422)
0.500 to 1.300
1.000
C-2
Your Data
FlexPak 3000 DC Drive Software Reference
Table C.1 – Parameter Settings Quick Reference Table (Continued)
Parameter Selection/
Adjustment Range
Parameter
ANLG OUT
2 SELECT (P.421)
ANLG TACH VOLTS/1000
(P.203)
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
(P.397)
CML REFERENCE (P.396)
CML ERROR (P.398)
SPD LOOP FEEDBACK (P.296)
SPD LOOP REFERENCE (P.295)
SPD LOOP ERROR (P.297)
SPD LOOP OUTPUT (P.299)
SPEED RAMP OUTPUT (P.199)
SPEED RAMP INPUT TP (P.198)
SPD SOURCE SELECT OUT (P.193)
TRIM OUTPUT (P.197)
ARMATURE VOLTAGE (P.289)
ANALOG TACH FEEDBACK (P.291)
PULSE TACH FEEDBACK (P.292)
CML FEEDBACK
Initial Factory
Setting (Default)
Your Data
Date
Setting
ZERO
ZERO
FULL SCALE
POWER OUTPUT
(P.845)
(P.846)
OCL FEEDBACK (P.847)
OCL OUTPUT (P.848)
FIELD REFERENCE (P.590)
FIELD FEEDBACK (P.589)
NETW IN REG 1 (P.905)
NETW IN REG 2 (P.906)
NETW IN REG 3 (P.907)
OCL REFERENCE
OCL RAMP OUTPUT
18.0 to 200.0 VOLTS/1000 RPM
18.0 VOLTS/1000
RPM
(P.204)
0.750 to 1.250
1.000
ARM VOLTAGE ZERO ADJ
(P.205)
–200 to 200
0
AUTO MODE MIN BYPASS
(P.111)
•
•
OFF
OFF
(P.112) •
•
OFF
(P.103) •
•
ANALOG
ARM VOLTAGE GAIN ADJ
AUTO MODE RAMP BYPASS
AUTO REFERENCE SELECT
ON
OFF
ON
ANALOG
FREQUENCY IN
CML FEEDBACK GAIN ADJ
(P.300)
0.900 to 1.100
1.000
CML PI LEAD FREQUENCY
(P.302)
10 to 500 RAD/S
100 RAD/S
Parameter Settings Record
C-3
Table C.1 – Parameter Settings Quick Reference Table (Continued)
Parameter Selection/
Adjustment Range
Parameter
CML PI PROP GAIN
(P.301)
CML REF LIMIT SELECT
CML REF RATE LIMIT
(P.303)
CNI PROG/RUN MODE
CONTROL SOURCE
CT TURNS RATIO
(P.311)
(P.915)
(P.000)
(P.010)
CURRENT COMPOUNDING
DECELERATION TIME
(P.002)
DEVNET POLL MSG TYPE
DIG IN
(P.913)
0 SELECT (P.428)
DIG OUT
DIG OUT
C-4
(P.209)
1 CONTACT TYP (P.410)
1 SELECT (P.409)
Initial Factory
Setting (Default)
0.000 to 4.000
0.250
• 1 = SPD LOOP PI LIMITS
• 2 = REGISTER
1
1 to 1000 msec
40 msec
• 1 = STOP
• 2 = USE LAST REF
• 3 = USE TRMBLK CNTL
1
•
•
•
•
KEYPAD
KEYPAD
•
•
•
•
•
•
•
139
208
417
833
2000
5230
Your Data
Date
Setting
SERIAL
TERMBLK
NETWORK
n/a
OTHER
–50 to 50%
0%
0.1 to 300.0 seconds
5.0 seconds
•
•
CONTROL ONLY
CONTROL ONLY
CONTROL+CONFIG
• 1 = BRUSH WEAR INPUT
• 2 = JOG SPEED SELECT
• 3 = OCL ENABLE
1
•
•
NORMAL OPEN
NORMAL OPEN
•
•
•
•
•
•
•
•
LEVEL DETECT
NORMAL CLOSED
1 OUTPUT
LEVEL DETECT 2 OUTPUT
LEVEL DETECT
1
OUTPUT
IN CURRENT LIMIT
DRIVE READY
NETW COMM STATUS
1 (BIT 0)
2 (BIT 0)
NETW IN REG 3 (BIT 0)
NETW IN REG
NETW IN REG
FlexPak 3000 DC Drive Software Reference
Table C.1 – Parameter Settings Quick Reference Table (Continued)
Parameter Selection/
Adjustment Range
Parameter
DIG OUT
DIG OUT
2 CONTACT TYP (P.412)
2 SELECT (P.411)
ENHANCED FLD VOLT ADJ
FEEDBACK SELECT
(P.500)
(P.200)
FIELD AUTO WEAKEN
(P.517)
FIELD DELTA HIGH LIM
(P.587)
FIELD ECONOMY DELAY
FIELD ECONOMY REF
(P.501)
(P.511)
FIELD LOSS THRESHOLD
(P.512)
•
•
NORMAL OPEN
•
•
•
•
•
•
•
•
LEVEL DETECT
Initial Factory
Setting (Default)
Your Data
Date
Setting
NORMAL OPEN
NORMAL CLOSED
LEVEL DETECT
1 OUTPUT
2 OUTPUT
LEVEL DETECT
2
OUTPUT
IN CURRENT LIMIT
DRIVE READY
NETW COMM STATUS
1 (BIT 1)
NETW IN REG 2 (BIT 1)
NETW IN REG 3 (BIT 1)
NETW IN REG
• 0 to 180 (J21 set to B-C)
• 0 to 120 (J21 set to A-C)
84
0 when the Field
Current
Regulator kit is
installed
•
•
•
•
ARMATURE VOLT
ARMATURE VOLT
•
•
DISABLED
DC TACH
PULSE TACH
AC TACH
DISABLED
ENABLED
0 to 180 DEGREE
130 DEGREE
0 to 27 minutes
5 minutes
0 to 100%
0%
• 50 to 100% of MOTOR HOT FLD
AMPS (P.510) when FEEDBACK
SELECT (P.200) is set to ARMATURE
60% of MOTOR
HOT FLD AMPS
(P.510)
VOLT
• 0 to 100% of MOTOR HOT FLD AMPS
(P.510) when FEEDBACK SELECT
(P.200) is set to DC TACH, PULSE
TACH, or AC TACH
FIELD PI LEAD FREQ
(P.515)
0 to 282.70 RAD/S
1.50 RAD/S
FIELD PI PROP GAIN
(P.514)
0.10 to 128.00
0.50
0 to MOTOR HOT FLD AMPS
MOTOR HOT FLD
FIELD REF REGISTER
(P.513)
AMPS
Parameter Settings Record
C-5
Table C.1 – Parameter Settings Quick Reference Table (Continued)
Parameter Selection/
Adjustment Range
Parameter
FIELD REF SELECT
(P.521)
Initial Factory
Setting (Default)
1 = REGISTER
2 = ANALOG MAN TRIM REF
3 = ANALOG IN 1
4 = ANALOG IN 2
1
FLD FEEDBACK GAIN ADJ
(P.516)
0.900 to 1.100
1.000
FLD WEAKEN LEAD FREQ
(P.520)
0.01 to 282.70 RAD/S
0.50 rad/s
FLD WEAKEN PROP GAIN
(P.519)
0.01 to 128.00
1.60
0 to 120% of MOTOR RATED ARM
(P.009)
95% of MOTOR
FLD WEAKEN THRESHOLD
(P.518)
VOLTS
Your Data
Date
Setting
RATED ARM VOLTS
(P.009)
FREQ IN FULL SCALE
FREQ IN ZERO
(P.424)
(P.423)
FREQ OUT FULL SCALE
FREQ OUT SELECT
FREQ OUT ZERO
C-6
(P.427)
(P.425)
(P.426)
2.0 to 250.0 kHz
250.0 kHz
2.0 to FREQ IN FULL SCALE kHz
2.0 KHZ
2.0 to 250.0 kHz
250.0 kHz
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
(P.397)
(P.396)
CML ERROR (P.398)
SPD LOOP FEEDBACK (P.296)
SPD LOOP REFERENCE (P.295)
SPD LOOP ERROR (P.297)
SPD LOOP OUTPUT (P.299)
SPEED RAMP OUTPUT (P.199)
SPEED RAMP INPUT TP (P.198)
SPD SOURCE SELECT OUT (P.193)
TRIM OUTPUT (P.197)
ARMATURE VOLTAGE (P.289)
ANALOG TACH FEEDBACK (P.291)
PULSE TACH FEEDBACK (P.292)
CML FEEDBACK
ZERO
CML REFERENCE
ZERO
FULL SCALE
POWER OUTPUT
(P.845)
(P.846)
OCL FEEDBACK (P.847)
OCL OUTPUT (P.848)
FIELD REFERENCE (P.590)
FIELD FEEDBACK (P.589)
NETW IN REG 1 (P.905)
NETW IN REG 2 (P.906)
NETW IN REG 3 (P.907)
OCL REFERENCE
OCL RAMP OUTPUT
2.0 to FREQ OUT FULL SCALE kHz
2.0 kHz
FlexPak 3000 DC Drive Software Reference
Table C.1 – Parameter Settings Quick Reference Table (Continued)
Parameter Selection/
Adjustment Range
Parameter
INERTIA COMP SELECT
INV FAULT AVOID SEL
IR COMPENSATION
(P.221)
(P.312)
(P.206)
JOG ACCEL/DECEL TIME
JOG OFF DELAY TIME
(P.013)
(P.121)
•
•
•
•
•
•
•
NONE
Initial Factory
Setting (Default)
1
ANALOG IN 2
ANALOG IN
1
NETW IN REG 2
NETW IN REG 3
NETW IN REG
• 1 = DISABLED
• 2 = FAULT IMMEDIATELY
• 3 = DELAY BEFORE FAULT
DISABLED
0 to 50%
0%
0.1 to 300.0 seconds
3.0 seconds
0.0 to 10.0 seconds
1.0 second
0 to MAXIMUM SPEED (RPM or userdefined units)
250 RPM
JOG SPEED
2 (P.017)
0 to MAXIMUM SPEED (RPM or userdefined units)
250 RPM
10.0 seconds
LEVEL DETECT
1 DELAY (P.604)
0.0 to 300.0 seconds
LEVEL DETECT
1 SELECT (P.602)
•
•
•
•
•
CML FEEDBACK
SPD LOOP
SPD LOOP FEEDBACK
FEEDBACK
SPD RAMP INPUT TP
SPEED RAMP OUTPUT
SPD SOURCE SELECT OUT
LEVEL DETECT
1 THRESH (P.603)
0.1 to 100.0% or MAXIMUM CURRENT
10.0%
LEVEL DETECT
2 DELAY (P.607)
0.0 to 300.0 seconds
10.0 seconds
LEVEL DETECT
2 SELECT (P.605)
•
•
•
•
•
MANUAL REF SELECT
MAXIMUM CURRENT
(P.106)
(P.007)
Parameter Settings Record
Setting
INTERNAL
1 (P.012)
2 THRESH (P.606)
Date
NONE
JOG SPEED
LEVEL DETECT
Your Data
CML FEEDBACK
SPD RAMP INPUT
SPD LOOP FEEDBACK
TP
SPD RAMP INPUT TP
SPEED RAMP OUTPUT
SPD SOURCE SELECT OUT
0.1 to 100.0% or MAXIMUM CURRENT
10.0%
•
•
ANALOG
ANALOG
MOP
25 to 200 %FLA
150 %FLA
C-7
Table C.1 – Parameter Settings Quick Reference Table (Continued)
Parameter Selection/
Adjustment Range
Parameter
MAXIMUM SPEED
(P.004)
Initial Factory
Setting (Default)
1 to TOP SPEED (RPM or user-defined
units)
500 RPM
METER OUT
1 GAIN ADJ (P.400)
1.100 to 1.900
1.000
METER OUT
1 SELECT (P.404)
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
CML FEEDBACK
(P.397)
CML REFERENCE (P.396)
CML ERROR (P.398)
SPD LOOP FEEDBACK (P.296)
SPD LOOP REFERENCE (P.295)
SPD LOOP ERROR (P.297)
SPD LOOP OUTPUT (P.299)
SPEED RAMP OUTPUT (P.199)
SPEED RAMP INPUT TP (P.198)
SPD SOURCE SELECT OUT (P.193)
TRIM OUTPUT (P.197)
ARMATURE VOLTAGE (P.289)
ANALOG TACH FEEDBACK (P.291)
PULSE TACH FEEDBACK (P.292)
CML FEEDBACK
Date
Setting
ZERO
FULL SCALE
POWER OUTPUT
(P.845)
(P.846)
OCL FEEDBACK (P.847)
OCL OUTPUT (P.848)
FIELD REFERENCE (P.590)
FIELD FEEDBACK (P.589)
NETW IN REG 1 (P.905)
NETW IN REG 2 (P.906)
NETW IN REG 3 (P.907)
OCL REFERENCE
OCL RAMP OUTPUT
METER OUT
1 ZERO ADJ (P.402)
–200 to 200
0
METER OUT
2 GAIN ADJ (P.401)
0.100 to 1.900
1.000
C-8
Your Data
FlexPak 3000 DC Drive Software Reference
Table C.1 – Parameter Settings Quick Reference Table (Continued)
Parameter Selection/
Adjustment Range
Parameter
METER OUT
METER OUT
2 SELECT (P.405)
2 ZERO ADJ (P.403)
MINIMUM SPEED
(P.003)
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
(P.397)
CML REFERENCE (P.396)
CML ERROR (P.398)
SPD LOOP FEEDBACK (P.296)
SPD LOOP REFERENCE (P.295)
SPD LOOP ERROR (P.297)
SPD LOOP OUTPUT (P.299)
SPEED RAMP OUTPUT (P.199)
SPEED RAMP INPUT TP (P.198)
SPD SOURCE SELECT OUT (P.193)
TRIM OUTPUT (P.197)
ARMATURE VOLTAGE (P.289)
ANALOG TACH FEEDBACK (P.291)
PULSE TACH FEEDBACK (P.292)
CML FEEDBACK
Initial Factory
Setting (Default)
ZERO
FULL SCALE
POWER OUTPUT
(P.845)
(P.846)
OCL FEEDBACK (P.847)
OCL OUTPUT (P.848)
FIELD REFERENCE (P.590)
FIELD FEEDBACK (P.589)
NETW IN REG 1 (P.905)
NETW IN REG 2 (P.906)
NETW IN REG 3 (P.907)
OCL REFERENCE
OCL RAMP OUTPUT
–200 to 200
0
0 to MAXIMUM SPEED (RPM or userdefined units)
250 RPM
ACCELERATION TIME
to 300.0 seconds 5.0 seconds
MOP DECEL TIME
(P.120)
DECELERATION TIME
to 300.0 seconds 5.0 seconds
MOTOR HOT FLD AMPS
(P.510)
MOTOR RATED ARM AMPS
(P.008)
MOTOR RATED ARM VOLTS
Parameter Settings Record
•
•
Setting
FEEDBACK
(P.115)
(P.116)
Date
SPD LOOP
MOP ACCEL TIME
MOP RESET ENABLE
Your Data
OFF
OFF
ON
0.11 to installed supply rating (4.00,
10.00, or 20.00 amps)
0.01 amps
0 to 3000.0 amps
8.0 amps
(P.009) 160 to 675 volts
240 volts
C-9
Table C.1 – Parameter Settings Quick Reference Table (Continued)
Parameter Selection/
Adjustment Range
Parameter
NEG CURRENT LIM SEL
(P.224)
NEGATIVE CURRENT LIM
NEG CUR LIM INV EN
(P.006)
(P.226)
NETW COMM LOSS SELECT
NETW CONNECT TYPE
NETW DROP NUMBER
•
•
•
•
•
•
(P.900)
1
2
NETW IN REG 3
NETW IN REG
NETW IN REG
•
•
ENABLED
DISABLED
ENABLED
FAULT
FAULT
USE LAST REF
USE TRMBLK REF
USE TRMBLK CNTL
BASIC
BASIC
FULL
For AutoMax Network
Communication kit: 1 to 55 if NETW
CONNECT TYPE = BASIC; 1 to 52 if
NETW CONNECT TYPE = FULL
For DeviceNet Interface kit: 0 to 63
(NETW CONNECT TYPE value does
not affect)
For ControlNet Network
Communication kit: 1 to 99
(NETW CONNECT TYPE value does not
affect)
1
1 SELECT (P.902)
–32768 to 32767
0
NETW OUT REG
2 SELECT (P.903)
–32768 to 32767
0
NETW OUT REG
3 SELECT (P.904)
–32768 to 32767
0
(P.914)
• 1 = ORIGINAL
• 2 = ALTERNATE
1
•
•
•
•
0.0 Kbaud
NETWORK BAUD RATE
C-10
(P.912)
Setting
REGISTER
NETW OUT REG
NETW REGISTER MAP SEL
Date
1
ANALOG IN 2
±150 %FLA
•
•
Your Data
ANALOG IN
When NEG CUR LIM INV EN (P.226) =
0 to MAXIMUM CURRENT
ENABLED:
(%FLA)
When NEG CUR LIM INV EN (P.226) =
– MAXIMUM CURRENT to
DISABLED:
0 (%FLA)
(P.901) •
•
•
•
(P.910)
REGISTER
Initial Factory
Setting (Default)
0.0 Kbaud
125.0 Kbaud
250.0 Kbaud
500.0 Kbaud
FlexPak 3000 DC Drive Software Reference
Table C.1 – Parameter Settings Quick Reference Table (Continued)
Parameter Selection/
Adjustment Range
Parameter
NOMINAL AC LINE FREQ
(P.306)
(P.307)
NOMINAL AC LINE VOLTS
NORMALIZED INERTIA
(P.222)
(P.804)
OCL FEEDBACK SELECT
OCL LEADLAG LOW FREQ
OCL LEADLAG RATIO
(P.807)
(P.805)
OCL LEADLAG SELECT
OCL PI LEAD FREQ
(P.809)
OCL PI NEGATIVE LIMIT
OCL PI POSITIVE LIMIT
OCL PI PROP GAIN
(P.806)
(P.811)
(P.810)
(P.808)
OCL PROP TRIM SELECT
(P.813)
Initial Factory
Setting (Default)
48 to 62 Hz
60 HZ
200 to 575 VAC
230 VAC
0.05 to 65.20 seconds
1.00 second
•
•
•
•
•
•
•
•
•
NONE
NONE
Your Data
Date
Setting
CML FEEDBACK
1
ANALOG IN 2
5 = SPEED LOOP OUTPUT
6 = ANALOG AUTO REFERENCE
7 = NETWORK IN REG 1
8 = NETWORK IN REG 2
9 = NETWORK IN REG 3
ANALOG IN
0.01 to 34.90 RAD/S
1.00 RAD/S
2 to 20
10
•
•
•
BYPASS
LEAD/LAG
BYPASS
LAG/LEAD
0.00 to 141.37 RAD/S
1.00 RAD/S
0 to 100% of TOP SPEED (P.011)
100%
0 to 100% of TOP SPEED (P.011)
100%
0.10 to 128.00
2.00
DISABLED
DISABLED
ENABLED
0.0 to 300.0 seconds
10.0 seconds
(P.801)
–4095 to 4095
0
(P.803)
0 to 50%
0%
•
•
•
•
•
•
•
REGISTER
OCL REF RAMP TIME
OCL REF REGISTER
OCL REF ROUNDING
(P.802)
OCL REFERENCE SELECT
OCL TRIM RANGE
(P.812)
Parameter Settings Record
(P.800)
REGISTER
1
ANALOG IN 2
ANALOG IN
FREQUENCY IN
1
2
NETW IN REG 3
NETW IN REG
NETW IN REG
–100. to 100.0% of TOP SPEED
(P.011)
0.0%
C-11
Table C.1 – Parameter Settings Quick Reference Table (Continued)
Parameter Selection/
Adjustment Range
Parameter
OCL TYPE3 POSN REG EN
OPEN SCR SENSITIVITY
(P.814)
(P.600)
•
•
DISABLED
Initial Factory
Setting (Default)
0 to 100%
50%
800 to 4000
1600
PHASE FIRE TEST DELTA
(P.309)
0 to 180 DEGREE
0 DEGREE
PHASE FIRE TST BRIDGE
(P.310)
•
•
OFF
OFF
•
•
DISABLE
PLL MAXIMUM ERROR
(P.308)
POS CURRENT LIM SEL
POSITIVE CURRENT LIM
(P.223)
(P.005)
ON
ENABLE
ENABLE
2 to 1000 µsec
2 µsec
•
•
•
•
•
•
REGISTER
REGISTER
1
ANALOG IN 2
ANALOG IN
1
NETW IN REG 2
NETW IN REG 3
NETW IN REG
0 to MAXIMUM CURRENT (%FLA)
150 %FLA
PRESET SPEED
1 (P.117)
MINIMUM SPEED to MAXIMUM SPEED
(RPM or user-defined units)
250 RPM
PRESET SPEED
2 (P.118)
MINIMUM SPEED to MAXIMUM SPEED
(RPM or user-defined units)
250 RPM
PRESET SPEED
3 (P.119)
MINIMUM SPEED to MAXIMUM SPEED
(RPM or user-defined units)
250 RPM
18 to 2500 PPR
18 PPR
PULSE TACH PPR
(P.207)
PULSE TACH QUADRATURE
RAMP STOP DECEL TIME
REVERSE DISABLE
(P.018)
(P.015)
S-CURVE ROUNDING
SELF TUNE BRIDGE
(P.014)
(P.220)
SELF TUNE FIELD RANGE
C-12
(P.208) •
•
(P.218)
Setting
ENABLED
(P.601)
(P.609)
Date
DISABLED
OPEN SCR TRIP THRESH
PHASE LOSS DETECT EN
Your Data
ON
ON
OFF
0.1 to 300.0 seconds
5.0 seconds
•
•
OFF
OFF
ON
0 to 50%
0%
•
•
FORWARD
FORWARD
REVERSE
0.90 to 5.00
1.00
FlexPak 3000 DC Drive Software Reference
Table C.1 – Parameter Settings Quick Reference Table (Continued)
Parameter Selection/
Adjustment Range
Parameter
(P.219)
SELF TUNE STABILITY
SPD LEADLAG LOW FREQ
(P.214)
Initial Factory
Setting (Default)
10 to 100
25
0.01 to 69.81 RAD/S when:
• FEEDBACK SELECT (P.200) =
1.00 RAD/S
Your Data
Date
Setting
ARMATURE VOLT
• SPD LOOP SCAN TIME (P.019) = 10 MS
0.01 to 139.62 rad/s when:
• FEEDBACK SELECT (P.200) ≠
ARMATURE VOLT
•
SPD LEADLAG RATIO
(P.213)
SPD LEADLAG SELECT
(P.216)
SPD LOOP LAG BYPASS
SPD LOOP LAG FREQ
(P.217)
(P.215)
SPD LOOP SCAN TIME
(P.019) = 5 MS
2 to 20
2
•
•
•
LEAD/LAG
BYPASS
•
•
ON
BYPASS
LAG/LEAD
ON
OFF
.0.01 to 139.62 RAD/S when:
• FEEDBACK SELECT (P.200) =
1.00 RAD/S
ARMATURE VOLT
• SPD LOOP SCAN TIME (P.019) = 10 MS
0.01 to 279.67 rad/s when:
• FEEDBACK SELECT (P.200) ≠
ARMATURE VOLT
•
SPD LOOP SCAN TIME
(P.019) = 5 MS
SPD LOOP PI INIT SEL
• 0 = ZERO
• 1 = SPD LOOP PI INITI VAL
• 2 = ANALOG MAN TRIM REF (P.194)
0
SPD LOOP PI INIT VAL
–32768 to 32767
0
.0.01 to 282.74 RAD/S when:
• FEEDBACK SELECT (P.200) =
3.00 RAD/S
SPD LOOP PI LEAD FREQ
(P.212)
ARMATURE VOLT
• SPD LOOP SCAN TIME (P.019) = 10 MS
0.01 to 327.67 rad/s when:
• FEEDBACK SELECT (P.200) ≠
ARMATURE VOLT
•
SPD LOOP PI PROP GAIN
SPD LOOP PI RESET
Parameter Settings Record
(P.211)
SPD LOOP SCAN TIME
(P.019) = 5 MS
0.10 to 128.00
4.40
• 0 = OFF
• 1 = ON
0
C-13
Table C.1 – Parameter Settings Quick Reference Table (Continued)
Parameter Selection/
Adjustment Range
Parameter
Initial Factory
Setting (Default)
SPD LOOP SCAN TIME
• 5 msec
• 10 msec
5 msec
SPEED FEEDBACK GAIN
1000 to 32000
1000
(P.122)
• 1 = DECELERATION TIME
• 2 = RAMP STOP DECEL TIME
1
(P.114)
•
•
•
COAST/DB
STOP DECEL SELECT
STOP MODE SELECT
TACH LEAD FLT DELAY
TACH LEAD FLT THRESH
TACH LOSS SCR ANGLE
TOP SPEED
0 to 32767 msec
10000 msec
(P.227)
0.0 to 250.0% of TOP SPEED
200.0%
(P.608)
0 to 127 DEGREE
109 DEGREE
5 to 5000 RPM
500 RPM
•
•
•
NO TRIM
(P.011)
TRIM MODE SELECT
TRIM RANGE
(P.110)
(P.109)
TRIM REFERENCE SELECT
TRIM REF REGISTER
UNDERWIND ENABLE
C-14
(P.108)
(P.107)
Setting
CURRENT LIMIT
50 RPM
(P.228)
Date
COAST/DB
0 to MAXIMUM SPEED (RPM or userdefined units
STOP SPEED THRESHOLD
(P.113)
RAMP
Your Data
NO TRIM
INCREMENTAL
PROPORTIONAL
0.0 to 100.0%
0.0%
•
•
•
•
•
•
•
REGISTER
ANALOG MANUAL
REGISTER
ANALOG IN
1
1
2
NETW IN REG 3
ANALOG IN 2
NETW IN REG
NETW IN REG
±100.0%
0%
0 = DISABLED (overwind)
1 = ENABLED (underwind)
0
FlexPak 3000 DC Drive Software Reference
Table C.2 – Jumper Settings
Jumper Number
Jumper Name
Default Setting
J15
REGULATOR TYPE
SPEED
J16
OIM PROGRAM
ENABLE
J20
FIELD LOSS DETECT
ENABLE
J21
FIELD SUPPLY
NOT APPLICABLE1
J19
MANUAL REF
POT
J14
TACH V RANGE
62
J11
TACH V SCALE
16
J10
AUTO REF
VOLTS
J12
AUTO REF
VOLTS
J18
ARM I FB RB
Position 4
1Only
Parameter Settings Record
Final Setting
applicable when the optional Enhanced Field Supply kit is installed
C-15
C-16
FlexPak 3000 DC Drive Software Reference
APPENDIX D
Numeric Parameter List
This list is provided as a convenience for finding specific parameter descriptions. For an alphabetic listing, see
the index.
Table D.1 – Numeric List of Parameters
Number
Name
Table D.1 – Numeric List of Parameters (Continued)
Page
Number
3-1
105
ANLG MAN REF ZERO ADJ
4-7
Name
Page
000
CONTROL SOURCE
001
ACCELERATION TIME
4-18
106
MANUAL REF SELECT
4-7
002
DECELERATION TIME
4-19
107
TRIM REF REGISTER
4-15
003
MINIMUM SPEED
4-20
108
TRIM REFERENCE SELECT
4-16
004
MAXIMUM SPEED
4-20
109
TRIM RANGE
4-15
005
POSITIVE CURRENT LIM
5-17
110
TRIM MODE SELECT
4-14
006
NEGATIVE CURRENT LIM
5-16
111
AUTO MODE MIN BYPASS
4-18
007
MAXIMUM CURRENT
6-2
112
AUTO MODE RAMP BYPASS
4-19
008
MOTOR RATED ARM AMPS
6-8
113
STOP SPEED THRESHOLD
4-23
009
MOTOR RATED ARM VOLTS
5-5
114
STOP MODE SELECT
4-23
010
CT TURNS RATIO
6-8
115
MOP ACCEL TIME
4-10
011
TOP SPEED
4-24
116
MOP RESET ENABLE
4-10
012
JOG SPEED
4-27
117
PRESET SPEED
1
4-12
013
JOG ACCEL/DECEL TIME
4-26
118
PRESET SPEED
2
4-12
014
S-CURVE ROUNDING
4-21
119
PRESET SPEED
3
4-12
015
REVERSE DISABLE
4-21
120
MOP DECEL TIME
4-10
017
JOG SPEED
4-27
121
JOG OFF DELAY TIME
4-27
018
RAMP STOP DECEL TIME
4-20
122
STOP DECEL SELECT
4-22
019
SPD LOOP SCAN TIME
5-2
188
ANALOG AUTO REFERENCE
4-4
100
ANLG AUTO SIGNAL TYPE
4-5
189
TORQUE REFERENCE
6-5
101
ANLG AUTO GAIN ADJ
4-5
191
MOP OUTPUT
102
ANLG AUTO ZERO ADJ
4-5
192
ANALOG MAN REFERENCE
4-6
103
AUTO REFERENCE SELECT
4-6
193
SPD SOURCE SELECT OUT
4-22
104
ANLG MAN REF GAIN ADJ
4-7
194
ANALOG MAN TRIM REF
4-14
Numeric Parameter List
1
2
4-10
D-1
Table D.1 – Numeric List of Parameters (Continued)
Number
D-2
Name
Table D.1 – Numeric List of Parameters (Continued)
Page
Number
Name
Page
196
DRAW PERCENTAGE OUT
4-14
289
ARMATURE VOLTAGE
5-4
197
TRIM OUTPUT
4-15
290
IR COMPENSATION TP
5-5
198
SPEED RAMP INPUT TP
4-22
291
ANALOG TACH FEEDBACK
5-6
199
SPEED RAMP OUTPUT
4-22
292
PULSE TACH FEEDBACK
5-9
200
FEEDBACK SELECT
5-3
293
CURRENT COMPOUND TP
4-28
201
ANALOG TACH GAIN ADJ
5-7
294
JOG RAMP OUTPUT
4-27
202
ANALOG TACH ZERO ADJ
5-7
295
SPD LOOP REFERENCE
4-24
203
ANLG TACH VOLTS/1000
5-7
296
SPD LOOP FEEDBACK
5-12
204
ARM VOLTAGE GAIN ADJ
5-4
297
SPD LOOP ERROR
5-12
205
ARM VOLTAGE ZERO ADJ
5-4
298
SPD LOOP LAG OUTPUT
5-13
206
IR COMPENSATION
5-5
299
SPD LOOP OUTPUT
5-18
207
PULSE TACH PPR
5-9
300
CML FEEDBACK GAIN ADJ
208
PULSE TACH QUADRATURE
5-10
301
CML PI PROP GAIN
6-10
209
CURRENT COMPOUNDING
4-28
302
CML PI LEAD FREQUENCY
6-10
211
SPD LOOP PI PROP GAIN
5-19
303
CML REF RATE LIMIT
6-4
212
SPD LOOP PI LEAD FREQ
5-19
306
NOMINAL AC LINE FREQ
3-2
213
SPD LEADLAG RATIO
5-12
307
NOMINAL AC LINE VOLTS
3-2
214
SPD LEADLAG LOW FREQ
5-11
308
PLL MAXIMUM ERROR
13-13
215
SPD LOOP LAG FREQ
5-13
309
PHASE FIRE TEST DELTA
13-18
216
SPD LEADLAG SELECT
5-12
310
PHASE FIRE TST BRIDGE
13-18
217
SPD LOOP LAG BYPASS
5-13
311
CML REF LIMIT SELECT
218
SELF TUNE FIELD RANGE
3-3
312
INV FAULT AVOID SEL
13-20
219
SELF TUNE STABILITY
3-4
392
AC LINE VOLTAGE
13-22
220
SELF TUNE BRIDGE
3-3
393
AC LINE PERIOD
13-22
221
INERTIA COMP SELECT
6-2
394
ARMATURE BRIDGE POL
6-9
222
NORMALIZED INERTIA
6-3
395
J18 ARM I FB RESISTOR
6-7
223
POS CURRENT LIM SEL
5-16
396
CML REFERENCE
6-4
224
NEG CURRENT LIM SEL
5-15
397
CML FEEDBACK
6-7
226
NEG CUR LIM INV EN
5-15, 6-4
398
CML ERROR
6-10
227
TACH LEAD FLT THRESH
13-19
399
ARMATURE DELTA
6-10
228
TACH LEAD FLT DELAY
13-19
400
METER OUT
1 GAIN ADJ
6-7
6-3
7-2
FlexPak 3000 DC Drive Software Reference
Table D.1 – Numeric List of Parameters (Continued)
Number
Name
Table D.1 – Numeric List of Parameters (Continued)
Page
Number
Name
Page
401
METER OUT
2 GAIN ADJ
7-3
497
DIG IN
3
4-9
402
METER OUT
1 ZERO ADJ
7-2
498
DIG IN
4
4-9
403
METER OUT
2 ZERO ADJ
7-3
499
DIG IN
5
9-4
404
METER OUT
1 SELECT
7-2
500
ENHANCED FLD VOLT ADJ
8-4
405
METER OUT
2 SELECT
7-3
501
FIELD ECONOMY DELAY
8-3
409
DIG OUT
1 SELECT
11-3
510
MOTOR HOT FLD AMPS
8-8
410
DIG OUT
1 CONTACT TYP
11-2
511
FIELD ECONOMY REF
8-3
411
DIG OUT
2 SELECT
11-4
512
FIELD LOSS THRESHOLD
8-9
412
DIG OUT
2 CONTACT TYP
11-3
513
FIELD REF REGISTER
8-3
413
ANLG IN
1 SIG TYPE
11-6
514
FIELD PI PROP GAIN
8-6
414
ANLG IN
1 ZERO ADJ
11-6
515
FIELD PI LEAD FREQ
8-6
415
ANLG IN
1 GAIN ADJ
11-6
516
FLD FEEDBACK GAIN ADJ
8-7
416
ANLG IN
2 ZERO ADJ
11-7
517
FIELD AUTO WEAKEN
8-9
417
ANLG IN
2 GAIN ADJ
11-7
518
FLD WEAKEN THRESHOLD
8-10
418
ANLG OUT
1 SELECT
11-9
519
FLD WEAKEN PROP GAIN
8-10
419
ANLG OUT
1 SIG TYPE
11-9
520
FLD WEAKEN LEAD FREQ
8-10
420
ANLG OUT
1 GAIN ADJ
11-8
521
FIELD REF SELECT
8-7
421
ANLG OUT
2 SELECT
11-10
586
FLD CURRENT REGULATOR
8-1
422
ANLG OUT
2 GAIN ADJ
11-9
587
FIELD DELTA HIGH LIM
8-9
423
FREQ IN ZERO
11-11
588
FIELD DELTA
8-6
424
FREQ IN FULL SCALE
11-10
589
FIELD FEEDBACK
8-6
425
FREQ OUT SELECT
11-11
590
FIELD REFERENCE
8-7
426
FREQ OUT ZERO
11-12
597
J20 FIELD LOSS DETECT
8-4
427
FREQ OUT FULL SCALE
11-11
598
J21 FLD SUPPLY JUMPER
8-5
428
DIG IN
0 SELECT
4-26, 9-3
599
FIELD ECONOMY ACTIVE
8-2
490
DIG IN
0
4-25, 9-3
600
OPEN SCR SENSITIVITY
13-15
491
FREQ IN
11-10
601
OPEN SCR TRIP THRESH
13-15
492
ANLG IN
1
11-5
602
LEVEL DETECT
1 SELECT
12-2
493
ANLG IN
2
11-7
603
LEVEL DETECT
1 THRESH
12-2
495
DIG IN
1
4-11
604
LEVEL DETECT
1 DELAY
12-1
496
DIG IN
2
4-12
605
LEVEL DETECT
2 SELECT
12-3
Numeric Parameter List
D-3
Table D.1 – Numeric List of Parameters (Continued)
Number
D-4
Name
Table D.1 – Numeric List of Parameters (Continued)
Page
Number
Name
Page
606
LEVEL DETECT
2 THRESH
12-4
814
OCL TYPE3 POSN REG EN
607
LEVEL DETECT
2 DELAY
12-3
845
OCL REFERENCE
9-5
608
TACH LOSS SCR ANGLE
13-12
846
OCL RAMP OUTPUT
9-4
609
PHASE LOSS DETECTION EN
13-22
847
OCL FEEDBACK
9-9
648
LEVEL DETECT
1 OUTPUT
12-2
848
OCL OUTPUT
9-7
649
LEVEL DETECT
2 OUTPUT
12-3
849
OCL ENABLE
9-4
792
J11 ANLG TACH VLT SCL
5-8
900
NETW DROP NUMBER
10-4
793
J14 ANLG TACH VLT RNG
5-8
901
NETW COMM LOSS SELECT
10-2
794
REGULATOR SW VERSION
13-23
902
NETW OUT REG
1 SELECT
10-4
795
POWER UNIT TYPE
13-23
903
NETW OUT REG
2 SELECT
10-4
796
NETWORK KIT
10-6
904
NETW OUT REG
3 SELECT
10-5
797
I/O EXPANSION KIT
11-1
905
NETW IN REG
1
10-5
798
PULSE TACHOMETER KIT
5-10
906
NETW IN REG
2
10-5
799
J15 REGULATOR TYPE
13-23
907
NETW IN REG
3
10-5
800
OCL REFERENCE SELECT
9-5
908
NETW COMM STATUS
801
OCL REF REGISTER
9-6
909
NETW TYPE
802
OCL REF RAMP TIME
9-5
910
NETW CONNECT TYPE
10-3
803
OCL REF ROUNDING
9-6
911
AMX NETW REF SELECT
10-8
804
OCL FEEDBACK SELECT
9-10
912
NETWORK BAUD RATE
10-7
805
OCL LEADLAG SELECT
9-11
913
DEVNET POLL MSG TYPE
10-7
806
OCL LEADLAG LOW FREQ
9-10
914
NETW REGISTER MAP SEL
10-8
807
OCL LEADLAG RATIO
9-11
915
CNI PROGRAM RUN MODE
10-9
808
OCL PI PROP GAIN
9-8
n/a
SPD LOOP PI INIT SEL
5-18
809
OCL PI LEAD FREQ
9-7
n/a
SPD LOOP PI INIT VAL
5-18
810
OCL PI POSITIVE LIMIT
9-7
n/a
SPD LOOP PI RESET
5-19
811
OCL PI NEGATIVE LIMIT
9-7
n/a
SPEED FEEDBACK GAIN
5-22
812
OCL TRIM RANGE
9-8
n/a
UNDERWIND ENABLE
813
OCL PROP TRIM SELECT
9-8
& VERSION
9-11
10-3
10-6
5-21 & 6-5
FlexPak 3000 DC Drive Software Reference
GLOSSARY
altitude - The atmospheric altitude (height above sea level) at which the motor or
drive will be operating.
armature -The portion of the DC motor that rotates.
armature resistance - Measured in ohms at 25 degrees Celsius (cold).
base speed - T. he speed that a DC motor develops at rated armature voltage and
rated field current with rated load applied. Typically nameplate data.
configurable - Input parameter whose values can only be modified while the drive is
stopped (not running or jogging).
constant speed - Used to describe a motor that changes speed only slightly from a
no-load to a full-load condition.
DC motor - A motor using either generated or rectified DC power. A DC motor is
usually used when variable speed operation is required.
DB - Dynamic Braking.
default value - Parameter values that are stored in the drive’s read-only memory
(ROM).
drive - Power converting equipment supplying electrical power to a motor.
efficiency - The ratio of mechanical output to electrical input. It represents the
effectiveness with which the motor converts electrical energy to mechanical energy.
field - A term commonly used to describe the stationary (stator) member of a
DC motor. The field provides the magnetic field with which the mechanically rotating
(armature or rotor) member interacts.
horsepower - The measure of the rate of work. One horsepower is equivalent to lifting
33,000 pounds to a height of one foot in one minute. The horsepower of a motor is
expressed as a function of torque and RPM. For motors, you can approximate
horsepower using this formula:
RPM
HP = T × ------------5250
where:
Glossary
•
HP = horsepower
•
T = Torque (in lb-ft)
•
RPM = revolutions per minute
Glossary-1
inertial load - A load (such as flywheel or fan) that tends to cause the motor shaft to
continue to rotate after power has been removed (stored kinetic energy). If this
continued rotation cannot be tolerated, some mechanical or electrical braking means
must be applied. This application might require a special motor due to the energy
required to accelerate the inertia. Inertia is measured in either lb-ft2 or oz-in2.
Load RPM 2
Inertia Reflected to the Shaft of the Motor = Load Inertia ×  ------------------------------
 Motor RPM
input parameter - You can change the value of the parameter through the OIM.
LCD - Liquid Crystal Display.
LED - Light Emitting Diode.
motor - A device that converts electrical energy to mechanical energy to turn a shaft.
motor electrical time constant - The ratio of electrical inductance (La) to armature
resistance (Ra).
motor identification •
Frame designation (actual frame size in which the motor is built)
•
Horsepower, speed, design and enclosure
•
Voltage, frequency and number of phases of power supply
•
Class of insulation and time rating
•
Application
motor nameplate - The plate on the outside of a motor that describes the motor, HP,
voltage, RPM, efficiency, design, enclosure, etc.
motor thermostat - Unit applied directly to the motor’s windings that senses winding
temperature and might automatically break the circuit in an overheating situation.
non-retentive - Changes to the parameter value are not saved when power is
removed.
output parameter - Provides output information. Value cannot be changed through
the OIM.
power (P) in kW - The measure of the rate of work. One kilowatt (kW) is equivalent to
lifting 98 kg to a height of one meter in one second. The kW rating of a motor is
expressed as a function of torque and RPM. For motors, you can use this approximate
formula:
RPM
P = T × ------------9550
where:
Glossary-2
•
P = horsepower
•
T= Torque (in Nm)
•
RPM = revolutions per minute
FlexPak 3000 DC Drive Software Reference
rated full load current - Armature current in amperes.
retentive - Parameter value is stored in the drive even when power is off. To save
changes to the values, a Memory Save must be performed before removing power.
RPM - revolutions per minute. The number of times per minute the shaft of the motor
(machine) rotates.
service factor (SF) - hen used on a motor nameplate, a number that indicates how
much above the nameplate rating a motor can be loaded without causing serious
degradation. For example, a 1.15 SF can produce 15% greater torque than a 1.0 SF
rating of the same motor.
tachometer - Normally used as a rotation sensing device. Tachometers are typically
attached to the output shaft of a motor requiring close speed regulation. The
tachometer feeds its signal to a control loop, which adjusts its input to the motor
accordingly.
top speed - The highest speed a drive can achieve. Top speed equals base speed
when there is no field weakening.
torque - Turning force delivered by a motor or gearmotor shaft, usually expressed in
pounds-feet or newton-meters:
5250
lb-ft = HP × ------------- = Full Load Torque
RPM
9550
Nm = P(kW) × ------------- = Full Load Torque
RPM
tunable - Input parameter whose value can be modified at any time (when the drive is
stopped, running, or jogging).
Glossary
Glossary-3
Glossary-4
FlexPak 3000 DC Drive Software Reference
INDEX
A
(P.204), 5-4
ARM VOLTAGE GAIN ADJ
ARM VOLTAGE ZERO ADJ
AC
analog tachometer feedback block diagram,
5-6
checking line period and voltage, 13-22
line parameter configuration, 3-2
AC LINE PERIOD (P.393), 13-22
AC LINE VOLTAGE (P.392), 13-22
AC LINE VOLTAGE HIGH alarm, 3-2
AC LINE VOLTAGE LOW alarm, 3-2
ACCELERATION TIME (P.001), 4-18
alarm codes, 13-9 to 13-11
AMX NETW REF SELECT (P.911), 10-8
analog
auto speed reference, 4-4
inputs
block diagram, 11-5
setting parameters, 11-5
manual speed reference, 4-6
outputs
block diagram, 11-8
setting parameters, 11-8
ANALOG AUTO REFERENCE (P.188), 4-4
ANALOG MAN REFERENCE (P.192), 4-6
ANALOG MAN TRIM REF (P.194), 4-14
ANALOG TACH FEEDBACK (P.291), 5-6
ANALOG TACH GAIN ADJ (P.201), 5-7
ANALOG TACH ZERO ADJ (P.202), 5-7
ANLG AUTO GAIN ADJ (P.101), 4-5
ANLG AUTO SIGNAL TYPE (P.100), 4-5
ANLG AUTO ZERO ADJ (P.102), 4-5
ANLG IN 1 (P.492), 11-5
ANLG IN 1 GAIN ADJ (P.415), 11-6
ANLG IN 1 SIG TYPE (P.413), 11-6
ANLG IN 1 ZERO ADJ (P.414), 11-6
ANLG IN 2 (P.493), 11-7
ANLG IN 2 GAIN ADJ (P.417), 11-7
ANLG IN 2 ZERO ADJ (P.416), 11-7
ANLG MAN REF GAIN ADJ (P.104), 4-7
ANLG MAN REF ZERO ADJ (P.105), 4-7
ANLG OUT 1 GAIN ADJ (P.420), 11-8
ANLG OUT 1 SELECT (P.418), 11-9
ANLG OUT 1 SIG TYPE (P.419), 11-9
ANLG OUT 2 GAIN ADJ (P.422), 11-9
ANLG OUT 2 SELECT (P.421), 11-10
ANLG TACH VOLTS/1000 (P.203), 5-7
Index
(P.205), 5-4
armature
current feedback scaling, 6-6
phase fire test, 13-16
voltage block diagram, 5-3
ARMATURE BRIDGE POL
ARMATURE DELTA
(P.394), 6-9
(P.399), 6-10
ARMATURE VOLTAGE
(P.289), 5-4
assistance, 1-2
auto mode, 4-2
AUTO MODE MIN BYPASS
(P.111), 4-18
AUTO MODE RAMP BYPASS
(P.112), 4-19
AUTO REFERENCE SELECT
(P.103), 4-6
automatic field weakening, 8-8
AutoMax Network, 10-1
kit parameters, 10-8
C
CML
block diagram, 6-6
forward path, 6-9
reference path diagram, 6-1
reference selection and conditioning, 6-3
CML,
6-1
CML ERROR
(P.398), 6-10
CML FEEDBACK
(P.397), 6-7
CML FEEDBACK GAIN ADJ
(P.300), 6-7
CML PI LEAD FREQUENCY
(P.302), 6-10
CML PI PROP GAIN
(P.301), 6-10
CML REF LIMIT SELECT
CML REF RATE LIMIT
CML REFERENCE
(P.311), 6-3
(P.303), 6-4
(P.396), 6-4
CNI PROGRAM RUN MODE
(P.915), 10-9
coast/DB stop sequencing, 2-3
Index-1
configuration
AC line parameter, 3-2
AC or DC analog tachometer feedback, 5-6
analog auto speed reference, 4-4
analog manual speed reference, 4-6
armature voltage feedback, 5-3
automatic field weakening, 8-8
enhanced field supply, 8-4
field
current regulated supply, 8-5
economy, 8-2
supply, 8-1
initial drive, 3-1
jog, 4-25
metering outputs, 7-1
network, 10-1
speed reference, 4-8
pulse encoder feedback, 5-9
serial speed reference, 4-8
speed loop, 5-1
current limits, 5-14
lead/lag, 5-11
speed reference, 4-1
ramp, 4-18
source block, 4-2
control, 3-1
control source, 3-1
affect on reference, 4-2
CONTROL SOURCE (P.000), 3-1
CS3000 software, 4-8
CT TURNS RATIO (P.010), 6-8
CURRENT COMPOUND TP (P.293), 4-28
CURRENT COMPOUNDING (P.209), 4-28
current limit stop sequencing, 2-4
current minor loop See CML
D
DC analog tachometer feedback block diagram, 5-6
DECELERATION TIME (P.002), 4-19
DeviceNet
Interface, 10-1
parameters, 10-7
DEVNET POLL MSG TYPE (P.913), 10-7
DIG IN 0 (P.490), 4-25, 9-3
DIG IN 0 SELECT (P.428), 4-26, 9-3
DIG IN 1 (P.495), 4-11
DIG IN 2 (P.496), 4-12
DIG IN 3 (P.497), 4-9
DIG IN 4 (P.498), 4-9
DIG IN 5 (P.499), 9-4
DIG OUT 1 CONTACT TYP (P.410), 11-2
Index-2
1 SELECT (P.409), 11-3
2 CONTACT TYP (P.412), 11-3
DIG OUT 2 SELECT (P.411), 11-4
digital outputs
block diagram, 11-2
setting parameters, 11-2
DRAW PERCENTAGE OUT (P.196), 4-14
drive
checking information, 13-23
current transformer turns ratio, 6-9
description, 1-2
initial configuration, 3-1
sequencing, 2-1
DIG OUT
DIG OUT
E
ENHANCED FLD VOLT ADJ
(P.500), 8-4
F
fault codes, 13-1 to 13-9
FEEDBACK SELECT (P.200), 5-3
field
economy, 8-2
supply, 8-1
current regulated, 8-5
enhanced, 8-4
weakening, automatic, 8-8
FIELD AUTO WEAKEN (P.517), 8-9
FIELD DELTA (P.588), 8-6
FIELD DELTA HIGH LIM (P.587), 8-9
FIELD ECONOMY ACTIVE (P.599), 8-2
FIELD ECONOMY DELAY (P.501), 8-3
FIELD ECONOMY REF (P.511), 8-3
FIELD FEEDBACK (P.589), 8-6
FIELD LOSS THRESHOLD (P.512), 8-9
FIELD PI LEAD FREQ (P.515), 8-6
FIELD PI PROP GAIN (P.514), 8-6
FIELD REF REGISTER (P.513), 8-3
FIELD REF SELECT (P.521), 8-7
FIELD REFERENCE (P.590), 8-7
FLD CURRENT REGULATOR (P.586), 8-1
FLD FEEDBACK GAIN ADJ (P.516), 8-7
FLD WEAKEN LEAD FREQ (P.520), 8-10
FLD WEAKEN PROP GAIN (P.519), 8-10
FLD WEAKEN THRESHOLD (P.518), 8-10
FREQ IN (P.491), 11-10
FREQ IN FULL SCALE (P.424), 11-10
FREQ IN ZERO (P.423), 11-11
FREQ OUT FULL SCALE (P.427), 11-11
FREQ OUT SELECT (P.425), 11-11
FREQ OUT ZERO (P.426), 11-12
FlexPak 3000 DC Drive Software Reference
frequency
input
block diagram, 11-10
setting parameters, 11-10
output, setting parameters, 11-11
I
level detectors
block diagram, 12-1
set up, 12-1
M
manual mode, 4-2
(P.106), 4-7
(P.007), 6-2
MAXIMUM SPEED (P.004), 4-20
METER OUT 1 GAIN ADJ (P.400), 7-2
METER OUT 1 SELECT (P.404), 7-2
METER OUT 1 ZERO ADJ (P.402), 7-2
METER OUT 2 GAIN ADJ (P.401), 7-3
METER OUT 2 SELECT (P.405), 7-3
METER OUT 2 ZERO ADJ (P.403), 7-3
metering
outputs, 7-1
block diagram, 7-1
parameter options, 7-4, 11-12
MINIMUM SPEED (P.003), 4-20
mode
auto, 4-2
jog, 2-2
manual, 4-2
run, 2-2
MANUAL REF SELECT
I/O expansion board parameters, 11-1
I/O EXPANSION KIT (P.797), 11-1
INERTIA COMP SELECT (P.221), 6-2
INV FAULT AVOID SEL (P.312), 13-20
inverting fault avoidance, 13-20, 13-21
IR COMPENSATION (P.206), 5-5
IR COMPENSATION TP (P.290), 5-5
J
J11 ANLG TACH VLT SCL (P.792), 5-8
J14 ANLG TACH VLT RNG (P.793), 5-8
J15 REGULATOR TYPE (P.799), 13-23
J18 ARM I FB RESISTOR (P.395), 6-7
J20 FIELD LOSS DETECT (P.597), 8-4
J21 FLD SUPPLY JUMPER (P.598), 8-5
jog
mode, 2-2
sequencing, 2-2
JOG ACCEL/DECEL TIME (P.013), 4-26
JOG OFF DELAY TIME (P.121), 4-27
JOG RAMP OUTPUT (P.294), 4-27
JOG SPEED 1 (P.012), 4-27
JOG SPEED 2 (P.017), 4-27
jumpers
settings
table of adjustment settings, C-15
K
keypad speed reference, 4-23
MAXIMUM CURRENT
MOP
block diagram, 4-9
manual reference to speed/voltage loop, 4-8
MOP ACCEL TIME (P.115), 4-10
MOP DECEL TIME (P.120), 4-10
MOP OUTPUT (P.191), 4-10
MOP RESET ENABLE (P.116), 4-10
MOTOR HOT FLD AMPS (P.510), 8-8
MOTOR RATED ARM AMPS (P.008), 6-8
MOTOR RATED ARM VOLTS (P.009), 5-5
motor-operated potentiometer See MOP
N
(P.226), 5-15, 6-4
(P.224), 5-15
NEGATIVE CURRENT LIM (P.006), 5-16
NETW COMM LOSS SELECT (P.901), 10-2
NETW COMM STATUS (P.908), 10-3
NETW CONNECT TYPE (P.910), 10-3
NETW DROP NUMBER (P.900), 10-4
NETW IN REG 1 (P.905), 10-5
NETW IN REG 2 (P.906), 10-5
NETW IN REG 3 (P.907), 10-5
NETW OUT REG 1 SELECT (P.902), 10-4
NETW OUT REG 2 SELECT (P.903), 10-4
NEG CUR LIM INV EN
L
1 DELAY (P.604), 12-1
1 OUTPUT (P.648), 12-2
LEVEL DETECT 1 SELECT (P.602), 12-2
LEVEL DETECT 1 THRESH (P.603), 12-2
LEVEL DETECT 2 DELAY (P.607), 12-3
LEVEL DETECT 2 OUTPUT (P.649), 12-3
LEVEL DETECT 2 SELECT (P.605), 12-3
LEVEL DETECT 2 THRESH (P.606), 12-4
LEVEL DETECT
LEVEL DETECT
Index
NEG CURRENT LIM SEL
Index-3
3 SELECT (P.904), 10-5
(P.914), 10-8
NETW TYPE & VERSION (P.909), 10-6
network, 10-1
settings, 10-2
speed reference, 4-8
NETWORK BAUD RATE (P.912), 10-7
NETWORK KIT (P.796), 10-6
NOMINAL AC LINE FREQ (P.306), 3-2
NOMINAL AC LINE VOLTS (P.307), 3-2
NORMALIZED INERTIA (P.222), 6-3
NETW OUT REG
NETW REGISTER MAP SEL
O
OCL
block diagram, 9-1
enable logic block diagram, 9-2
feedback path setup, 9-9
forward path, 9-6
reference path, 9-4
reference signal rounding block diagram, 9-6
signal processing, 9-4
OCL, 9-1
OCL ENABLE (P.849), 9-4
OCL FEEDBACK (P.847), 9-9
OCL FEEDBACK SELECT (P.804), 9-10
OCL LEADLAG LOW FREQ (P.806), 9-10
OCL LEADLAG RATIO (P.807), 9-11
OCL LEADLAG SELECT (P.805), 9-11
OCL OUTPUT (P.848), 9-7
OCL PI LEAD FREQ (P.809), 9-7
OCL PI NEGATIVE LIMIT (P.811), 9-7
OCL PI POSITIVE LIMIT (P.810), 9-7
OCL PI PROP GAIN (P.808), 9-8
OCL PROP TRIM SELECT (P.813), 9-8
OCL RAMP OUTPUT (P.846), 9-4
OCL REF RAMP TIME (P.802), 9-5
OCL REF REGISTER (P.801), 9-6
OCL REF ROUNDING (P.803), 9-6
OCL REFERENCE (P.845), 9-5
OCL REFERENCE SELECT (P.800), 9-5
OCL TRIM RANGE (P.812), 9-8
OCL TYPE3 POSN REG EN (P.814), 9-11
OIM speed reference, 4-23
OPEN SCR SENSITIVITY (P.600), 13-15
OPEN SCR TRIP THRESH (P.601), 13-15
outer control loop See OCL
P
PHASE FIRE TEST DELTA
PHASE FIRE TST BRIDGE
Index-4
(P.309), 13-18
(P.310), 13-18
(P.609), 13-22
(P.308), 13-13
POS CURRENT LIM SEL (P.223), 5-16
POSITIVE CURRENT LIM (P.005), 5-17
POWER UNIT TYPE (P.795), 13-23
preset speed
block diagram, 4-11
references, 4-11
PRESET SPEED 1 (P.117)PRESET SPEED 2 (P.118),
4-12
PRESET SPEED 3 (P.119), 4-12
pulse encoder feedback, 5-9
block, 5-9
PULSE TACH FEEDBACK (P.292), 5-9
PULSE TACH PPR (P.207), 5-9
PULSE TACH QUADRATURE (P.208), 5-10
PULSE TACHOMETER KIT (P.798), 5-10
pulse tachometer See pulse encoder
PHASE LOSS DETECTION EN
PLL MAXIMUM ERROR
R
RAMP STOP DECEL TIME (P.018), 4-20
ramp stop sequencing, 2-3
reference
affect on control source, 4-2
regulator, 13-23
REGULATOR SW VERSION (P.794), 13-23
REVERSE DISABLE (P.015), 4-21
run
mode, 2-2
sequencing, 2-2
S
SCR
adjusting sensitivity, 13-14
diagnostics, 13-14
load during normal operation, 13-14
load SCRs fail to turn on, 13-15
S-CURVE ROUNDING (P.014), 4-21
SELF TUNE BRIDGE (P.220), 3-3
SELF TUNE FIELD RANGE (P.218), 3-3
SELF TUNE STABILITY (P.219), 3-4
serial speed reference, 4-8
SPD LEADLAG LOW FREQ (P.214), 5-11
SPD LEADLAG RATIO (P.213), 5-12
SPD LEADLAG SELECT (P.216), 5-12
SPD LOOP ERROR (P.297), 5-12
SPD LOOP FEEDBACK (P.296), 5-12
SPD LOOP LAG BYPASS (P.217), 5-13
SPD LOOP LAG FREQ (P.215), 5-13
SPD LOOP LAG OUTPUT (P.298), 5-13
FlexPak 3000 DC Drive Software Reference
(P.299), 5-18
5-18
SPD LOOP PI INIT VAL, 5-18
SPD LOOP PI LEAD FREQ (P.212), 5-19
SPD LOOP PI PROP GAIN (P.211), 5-19
SPD LOOP PI RESET, 5-19
SPD LOOP REFERENCE (P.295), 4-24
SPD LOOP SCAN TIME (P.019), 5-2
SPD SOURCE SELECT OUT (P.193), 4-22
SPEED FEEDBACK GAIN, 5-22
speed loop
block diagram, 5-1
current limits, 5-14
error signal, 5-12
feedback, 5-3
lag feature, 5-13
lead/lag, 5-11
PI block setup, 5-17
SPEED RAMP INPUT TP (P.198), 4-22
SPEED RAMP OUTPUT (P.199), 4-22
speed reference, 4-1
block diagram, final, 4-23
mode select, 4-23
OIM, 4-23
ramp, 4-16, 4-18
block diagram, 4-17
source block, 4-2
source select block diagram, 4-3
STOP DECEL SELECT (P.122), 4-22
STOP MODE SELECT (P.114), 4-23
stop sequencing, 2-2
coast/DB, 2-3
current limit, 2-4
ramp, 2-3
SPD LOOP OUTPUT
STOP SPEED THRESHOLD
(P.113), 4-23
SPD LOOP PI INIT SEL,
Index
T
(P.228), 13-19
(P.227), 13-19
TACH LOSS SCR ANGLE (P.608), 13-12
tachometer
adjusting loss sensitivity, 13-12
reversed lead detection, 13-19
technical assistance, 1-2
telephone support, 1-2
TOP SPEED (P.011), 4-24
TORQUE REFERENCE (P.189), 6-5
TRIM MODE SELECT (P.110), 4-14
TRIM OUTPUT (P.197), 4-15
TRIM RANGE (P.109), 4-15
TRIM REF REGISTER (P.107), 4-15
TRIM REFERENCE SELECT (P.108), 4-16
trim setup, 4-13
Troubleshooting, 13-1
troubleshooting
technical assistance, 1-2
TACH LEAD FLT DELAY
TACH LEAD FLT THRESH
U
UNDERWIND ENABLE,
5-21, 6-5
W
winding applications, 5-20
Index-5
Index-6
FlexPak 3000 DC Drive Software Reference
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Publication Name: FlexPak 3000 DC Drive Software Reference Version 4.3
Publication Number: D2-3405-2
Publication Date: September 2001
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Publication D2-3405-2 - September 2001
 2001 Rockwell Automation. All rights reserved. Printed in