Littelfuse ProtectionRelays MPU 32 Manual

3714 Kinnear Place
Saskatoon, SK
Canada
S7P 0A6
Ph: (306) 373-5505
Fx: (306) 374-2245 www.littelfuse.com/relayscontrols
MPU-32 MANUAL
MOTOR PROTECTION UNIT
Revision 5-A-090514
LITTELFUSE STARTCO
TRIP
MOTOR PROTECTION UNIT
ALARM
RUN
MPU-32
MAIN MENU
Metering Ñ
²Messages Ñ
Setup Ñ
UPI
ESC
ENTER
RESET
Copyright  2014 by Littelfuse Startco
All rights reserved.
Document Number: PM-1115-EN
Printed in Canada.
Factory default password is 1111
New Password
See Section 4.5
Motor Identification
Page i
Rev. 5-A-090514
MPU-32 Motor Protection Unit
TABLE OF CONTENTS
SECTION
PAGE
List of Figures ........................................................................ ii
List of Tables ......................................................................... ii
1
Introduction ..........................................................1-1
1.1 General.....................................................................1-1
1.2 MPU-32 Features ....................................................1-1
1.2.1 Protection .....................................................1-1
1.2.2 Metering.......................................................1-1
1.2.3 Data Logging ...............................................1-1
1.2.4 Inputs and Outputs ......................................1-1
1.2.5 Operator Interface .......................................1-1
1.2.6 MPS-RTD Module (Optional)....................1-1
1.2.7 MPS-DIF Differential Module (Optional) .1-1
1.2.8 Communications .........................................1-1
1.3 Ordering Information ..............................................1-1
2
Installation..............................................................2-1
2.1 General.....................................................................2-1
2.2 MPU-32 Motor Protection Unit..............................2-1
2.3 MPU-CIM Current Input Module ..........................2-1
2.4 Earth-Fault CT’s ......................................................2-1
2.5 MPS-RTD RTD Module ........................................2-1
2.6 MPS-DIF Differential Module ...............................2-1
2.7 MPU-32/MPU-16A Compatibility.........................2-1
3
System Wiring .......................................................3-1
3.1 General.....................................................................3-1
3.2 Wiring Connections ................................................3-2
3.2.1 MPU-32 Connections .................................3-2
3.2.1.1 Supply Voltage...............................3-2
3.2.1.2 CIM Input .......................................3-2
3.2.1.3 Digital Input ...................................3-2
3.2.1.4 Analog Output................................3-2
3.2.1.5 PTC or RTD Input (Local) ............3-2
3.2.1.6 I/O Module Interface .....................3-2
3.2.1.7 RS/EIA/TIA-232
Communications .........................................3-3
3.2.2 MPU-CIM Connections..............................3-3
3.2.2.1 Standard..........................................3-4
3.2.2.2 Residual Earth-Fault ......................3-4
3.2.2.3 Two-CT ..........................................3-4
3.2.3 MPS-RTD Connections and Address
Selection ......................................................3-6
3.2.4 MPS-DIF Connections................................3-6
3.2.4.1 Core Balance ..................................3-6
3.2.4.2 MPU Summation ...........................3-6
3.2.4.3 DIF Summation..............................3-6
3.2.5 Cable Restraint........................................ 3-6
3.2.6 Dielectric-Strength Testing .........................3-6
4
Operation and Setup .............................................4-1
4.1 Display and Indication ............................................4-1
4.1.1 Front-Panel LED Indication .......................4-1
4.1.2 Rear-Panel LED Indication.........................4-2
4.1.3 Display Contrast and Test ...........................4-2
SECTION
PAGE
4.2 Setup ........................................................................ 4-2
4.2.1 Phase-CT Inputs .......................................... 4-2
4.2.2 Earth-Fault-CT Input .................................. 4-2
4.2.3 Motor Data .................................................. 4-2
4.2.4 Output Relay Assignment .......................... 4-2
4.2.5 Digital Input ................................................ 4-3
4.2.6 Analog Output............................................. 4-3
4.2.7 Miscellaneous Configuration ..................... 4-4
4.2.8 Communications ......................................... 4-4
4.3 Metering .................................................................. 4-4
4.4 Messages ................................................................. 4-5
4.4.1 Trip Reset .................................................... 4-5
4.4.2 Data Logging............................................... 4-5
4.4.3 Statistical Data ............................................ 4-6
4.4.4 Emergency Thermal Reset ......................... 4-6
4.5 Password Entry and Programming......................... 4-6
4.6 MPS-RTD ............................................................... 4-6
4.7 MPS-DIF ................................................................. 4-7
5
Protective Functions ........................................ 5-1
5.1 General............................................................... 5-1
5.2 Overload ............................................................ 5-1
5.2.1 Thermal Model ....................................... 5-1
5.2.2 Locked-Rotor Times ............................... 5-4
5.2.3 Emergency Thermal Reset...................... 5-4
5.3 Overcurrent ........................................................ 5-4
5.4 Auxiliary Overcurrent ........................................ 5-5
5.5 Reduced Overcurrent ......................................... 5-5
5.6 Jam ..................................................................... 5-5
5.7 Earth Fault ......................................................... 5-5
5.8 Current Unbalance ............................................. 5-6
5.9 Phase Loss ......................................................... 5-6
5.10 Phase Reverse .................................................... 5-6
5.11 Undercurrent ...................................................... 5-6
5.12 Differential Current Protection .......................... 5-6
5.13 Starts per Hour/Time Between Starts ................ 5-7
5.14 PTC Temperature (Local) .................................. 5-7
5.15 RTD Temperature (Local) ................................. 5-7
5.16 RTD Temperature (MPS-RTD Module) ............ 5-8
5.17 Hot-Motor Compensation .................................. 5-8
6
Theory of Operation ........................................ 6-1
6.1 Signal-Processing Algorithms ........................... 6-1
6.2 RTD Module (MPS-RTD) ................................. 6-1
6.3 Differential Module (MPS-DIF) ........................ 6-1
7
Communications .............................................. 7-1
7.1 Personal-Computer Interface ............................. 7-1
7.1.1 Firmware Upgrade .................................. 7-1
7.1.2 SE-Comm-RIS ........................................ 7-1
7.2 Network Interface .............................................. 7-1
7.2.1 TIA-485 Option ...................................... 7-1
7.2.2 DeviceNet Option ................................... 7-1
7.2.3 Ethernet Option ...................................... 7-1
Table of Contents
Page ii
Rev. 5-A-090514
MPU-32 Motor Protection Unit
SECTION
PAGE
8
Technical Specifications................................... 8-1
MPU-32.............................................................. 8-1
Current Input Module (MPU-CIM).................... 8-3
RTD Module (MPS-RTD) ................................. 8-3
Differential Module (MPS-DIF) ........................ 8-4
9
Warranty .......................................................... 8-4
Appendix A MPU-32 Menu Map ................................ A-1
Appendix B MPU-32 Setup Record ............................ B-1
Appendix C 1-A Direct-Input Configuration .............. C-1
Appendix D MPU-32 TIA-232 Modbus Protocol ....... D-1
Appendix E Communications Database Table ............ E-1
Appendix F Register Formats....................................... F-1
Appendix G MPU-32 Revision History ...................... G-1
8.1
8.2
8.3
8.4
LIST OF FIGURES
FIGURE
1.1
1.2
2.1
2.2
2.3
2.4
2.5
2.6
2.7
2.8
3.1
3.2
3.3
3.4
3.5
3.6
3.7
3.8
3.9
3.10
3.11
4.1
4.2
5.1
5.2
5.3
PAGE
LIST OF TABLES
TABLE
3.1
3.2
4.1
4.2
4.3
4.4
4.5
5.1
PAGE
CA-945 Adapter Pinout ......................................... 3-3
MPS-RTD Address Selection ................................ 3-6
UPI LED Functions ................................................ 4-1
Output-Relay Functions ......................................... 4-3
Digital-Input Functions .......................................... 4-3
Analog-Output Parameters..................................... 4-4
Metering Display .................................................... 4-5
Fault Duration Required for Trip or Alarm........... 5-4
DISCLAIMER
Specifications are subject to change without notice.
Littelfuse Startco is not liable for contingent or
consequential damages, or for expenses sustained as a
result of incorrect application, incorrect adjustment, or a
malfunction.
Motor Protection Unit Block Diagram ...................1-2
MPU-32 Ordering Information...............................1-3
MPU-32 Outline and Panel-Mounting Details .........2-2
MPU-32 Outline and Surface-Mounting Details......2-3
MPU-CIM Outline and Mounting Details .............2-4
EFCT-1 Outline and Mounting Details ..................2-5
EFCT-2 Outline and Mounting Details ..................2-6
EFCT-26 Outline and Mounting Details ................2-7
MPS-RTD Outline and Mounting Details .............2-8
MPS-DIF Outline and Mounting Details ...............2-9
Typical MPU-32 Connection Diagram ..................3-1
Analog-Output Connections ...................................3-2
Local Temperature-Sensor Connections ................3-2
I/O Module Connection Diagram ...........................3-2
MPU-CIM Schematic .............................................3-3
MPU-CIM Standard Connections ..........................3-4
Other MPU-CIM Connections ...............................3-5
MPS-RTD Connection Diagram ............................3-7
Core-Balance Connection .......................................3-7
MPU-Summation Connection ................................3-8
DIF-Summation Connection...................................3-8
Menu Example ........................................................4-1
Menu Symbols.........................................................4-1
Class-20 Overload Curve ........................................5-3
Asymmetrical-Current Multipliers .........................5-5
Used I2t Bias Curve .................................................5-8
Table of Contents
Page 1-1
Rev. 5-A-090514
MPU-32 Motor Protection Unit
1. INTRODUCTION
1.1 GENERAL
The MPU-32 is a motor-protection relay that provides
integrated protection, metering, and data-logging
functions for fixed- and variable-frequency applications.
The MPU-32 can be programmed using the front-panel
operator interface, the TIA-232 port, or an optional
communications network.
The MPU-32 configuration described in this manual
uses a current-input module (CIM) and is shown in
Fig. 1.1. The MPU-32 is also available in a 1-A-directinput configuration and Appendix C contains information
specific to this configuration.
1.2 MPU-32 FEATURES
1.2.1 PROTECTION
 Overload (49, 51)
 Overcurrent (50, 51)
 Earth fault (50G/N, 51G/N)
 Unbalance (46)
 Phase loss (46)
 Phase reverse (46)
 Jam
 Undercurrent (37)
 Starts per hour (66)
 Differential (87)
 PTC overtemperature (49)
 RTD temperature (38, 49)
1.2.2 METERING
 Line currents
 Current unbalance
 Positive-sequence current (I1)
 Negative-sequence current (I2)
 Zero-sequence current (3I0, calculated)
 Earth-leakage current (CT input)
 Differential currents
 Used thermal capacity
 Thermal trend
 RTD temperatures
 Frequency
1.2.3 DATA LOGGING
 One-hundred records
 Date and time of event
 Event type
 Cause of trip
 Line currents
 Current unbalance
 Earth-leakage current
 Differential currents


 Used thermal capacity
 Thermal capacity used during starts
 Start time
 RTD temperatures
Trip counters
Running hours
1.2.4 INPUTS AND OUTPUTS
 Phase-current inputs
 Earth-leakage-current input
 Programmable digital input (24 Vdc)
 24-Vdc source for digital input
 4–20-mA analog output, programmable
 Temperature-sensor input, Pt100 RTD or PTC
 I/O module interface
 Three output relays, programmable
 TIA-232 communications
 Network communications
1.2.5 OPERATOR INTERFACE
 4 x 20 backlit LCD display
 Display-control and programming keys
 LED status indication
1.2.6 MPS-RTD MODULE (OPTIONAL)
 Eight inputs per module
 Individually selectable RTD types
 RTD Voting
 Solid-state multiplexing
 Up to three modules per system
 Remote operation up to 1.2 km (4,000’)
 Powered by MPU-32
1.2.7 MPS-DIF DIFFERENTIAL MODULE (OPTIONAL)
 3-CT core balance connection
 6-CT summation connection
 Remote operation up to 1.2 km (4,000’)
 Powered by MPU-32
1.2.8 COMMUNICATIONS
The standard communications interface is a TIA-232
port using the Modbus RTU protocol. In addition to the
standard interface, network communications options
include TIA-485 with both Modbus RTU and A-B DF1
protocols , DeviceNetTM, and an IEEE 802.3 port with
Modbus TCP Ethernet protocol.
1.3 ORDERING INFORMATION
See Fig. 1.2 for MPU-32, MPU-CIM, MPS-RTD and
MPS-DIF model numbers.
Introduction
Page 1-2
Rev. 5-A-090514
MPU-32 Motor Protection Unit
A
13
B
14
C
15
COM
16
29
EF
22
21
20 NC
MPU-32
SUPPLY
L1
2
L2
3
8
PTC/RTD
INPUT
TA
TB
TC
17
18
19
ON
REAR
PANEL
13
14
15
16
4-20mA
ANALOG
OUTPUT
AB
AA
15
14
+24V
KEYPAD:
+
25
26
DIFFERENTIAL
MODULE
PWR
COMM
4 x 20 ALPHANUMERIC LCD,
LED BACKLIGHTING
24 V DC
DIGITAL
INPUT
0V
27
28
29
+
30
+24V
31
11
+
12
0V
10
+
I/O COMMUNICATIONS
+24V
15
MPS-RTD
16
17
RTD
MODULE
18
LED INDICATORS:
DTR
SG
OPTIONAL
NETWORK COM
RD
DCE
2
SHIELD
4
TIA-232
5
RTD 2
6
RTS
11
12
OUTPUT
RELAY 2
10 1
9
OUTPUT
RELAY 3
4
6
7
OUTPUT
RELAY 1
C
D
R
C
D
R
RTD 3
TD
CTS
C
D
R
RTD 4
3
SHIELD
7
8
7
6
5
1
PHASE CT
4
3
2
1
1
9
8
7
1
5
C
DIFFERENTIAL
CT
6
5
4
1
5
C
DIFFERENTIAL
CT
3
2
1
1
5
C
DIFFERENTIAL
CT
21
22
23
24
25
26
27
28
29
30
31
32
33
34
R
D
C
RTD 5
5
S
R
5
PHASE CT
S
R
13
-
0V
1
DCD
PHASE CT
LED INDICATORS:
DISPLAY:
UP
DOWN
LEFT
RIGHT
RESET
ESC
ENTER
12 1
11 5
10 S
9 R
MPS-DIF
SPG
ANALOG OUTPUT
SELF/LOOP
POWER SELECTOR
L
S
CURRENT
INPUT
MODULE
17
18
EF1 19
Y 20
CONFIGURATION
X 21
SELECTION
22
E 23
S 24
5 25
EARTH FAULT CT
R 26
1 27
LED INDICATORS:
TRIP
ALARM
RUN
UPI (USER PROG INDICATOR)
NS (NETWORK STATUS)
23
MS (MODULE STATUS)
24
ER (MPU-32 ERROR)
MPU-CIM
RTD 1
8
C
D
R
PWR
14
COMM
13
12
11
10
9
8
7
6
5
ADDRESS SWITCHES
4
3
20
2
1
19
SHIELD
R
D
C
R
D
C
RTD 6
RTD 7
SHIELD
R
D
C
RTD 8
SPG
5
OUTPUT RELAY CONTACTS SHOWN
WITH MPU-32 DE-ENERGIZED.
FIGURE 1.1 Motor Protection Unit Block Diagram.
Introduction
Page 1-3
Rev. 5-A-090514
MPU-32 Motor Protection Unit
MPU-32LITTELFUSE STARTCO
MOTOR PROTECTION UNIT
TRIP
-
MPU-32
Options:
00 CIM Input (1)
01 1-A CT Input
MAIN MENU
Metering Ñ
²Messages Ñ
Setup Ñ
ALARM
RUN
UPI
Network Communications:
0 None, TIA-232 only
1 TIA-485 c/w A-B®DF1 &
Modbus®RTU Protocols
2 DeviceNet™
4 IEEE 802.3 (Ethernet)
ESC
ENTER
RESET
Power Supply:
0 Universal ac/dc
(65 to 265 Vac and
80 to 275 Vdc)
(1)
Requires input from MPU-CIM or MPU-16A ICT-x
27 26 25 24 23 22 21 20 19 18 17 16 15 14 13
1 R 5 S E
X Y E
E C C B A
F
F O
EARTH FAULT
1
2 M
C U R R E NT I N P UT M O D U L E
R
1
PHASE A
S
2
5
3
1
4
R
5
MPU-CIM-
MPU
MPU-CIM
PHASE B
S
6
5
7
1
8
R
9
PHASE C
S
10
5
11
Future Options:
00 No Options
1
12
Configuration:
00 50/60 Hz
MPS-RTD-
-
34 33 32 31 30 29 28 27 26 25 24 23 22 21 20 19
C D R S C D R C D R S C D R S
H
P
H
INP 8
INP 7
INP 6
INP 5
G
INPUT MODULE
PWR
CTU/
MPU
COMM
INP 1
R
1
D
2
C
3
S
H
4
INP 4
COMM 2
4
S
0
V
D C H R D C V
9 10 11 12 13 14 15 16 17 18
INP 2
R
5
D
6
Future Options:
00 No Options
MPS-RTD
INP 3
C
7
R
8
Configuration:
01 8 Input
MPS-DIFPWR
Future Options:
00 No Options
15 14
S
P
G
DIFFERENTIAL MODULE
MPS-DIF
CTU/
MPU
PHASE A
C
1
5
2
-
COMM
1
3
PHASE B
C
4
5
5
PHASE C
1
6
C
7
5
8
1
9
+
COMM 2
4
0
V - + V
10 11 12 13
Configuration:
01 5/1A Isolated Input
Supplied Interconnect Cable:
S75-M16A-20030. . MPU-CIM to MPU-32 Interconnect Cable,
6 m (19’) Included with MPU-CIM
3124A . . . . . . . . . . I/O Module to MPU-32 Interconnect Cable,
4 m (13’) Included with MPS-RTD and MPS-DIF
FIGURE 1.2 MPU-32 Ordering Information.
Introduction
MPU-32 Motor Protection Unit
Page 1-4
Rev. 5-A-090514
Current Transformers:
EFCT-1 ......................... Earth-Fault CT,
5-A-primary rating,
82 mm (3.2”) window
EFCT-1FC .................... Flux Conditioner for EFCT-1,
70 mm (2.7”) window
EFCT-2 ......................... Earth-Fault CT with
Flux Conditioner, 5-A primary,
139 mm (5.5”) window
EFCT-26 ....................... Earth-Fault CT,
5-A-primary rating,
26 mm (1”) window
Other Earth-Fault CT’s .. Contact factory
Phase CT’s .................... Contact factory
Accessories:
MPU-32-SMK .............. Surface-mounting hardware
kit
MPU-16A-Y92A-96N .. Watertight faceplate cover
CA-945 ......................... DB9 to RJ-45 Adapter with
1.5 m (5’) cable
SE-ICUSB232 .............. USB to TIA-232 serial
converter
Software:
SE-Comm-RIS .............. PC Interface(1)
SE-Flash ....................... Firmware Upgrade(1)
(1)
Available at www.littelfuse.com/relayscontrols.
Introduction
MPU-32 Motor Protection Unit
2. INSTALLATION
2.1 GENERAL
A basic system consists of an MPU-32, an MPU-CIM,
and three 1-A- or 5-A-secondary line-current
transformers. See Appendix C for the 1-A-direct-input
configuration. Earth-fault protection can be provided
from a core-balance CT or from phase CT’s. A
core-balance CT (1-A, 5-A, or EFCT series) is
recommended. In addition to a single PTC/RTD input
provided on the MPU-32, up to three eight-input
MPS-RTD modules and one MPS-DIF differential
module can be connected to an MPU-32.
The MPU-32 switch-mode power supply is rated 65 to
265 Vac and 80 to 275 Vdc.
All modules can be mounted in any orientation.
2.2 MPU-32 MOTOR PROTECTION UNIT
Outline and details for MPU-32 panel-mounting are
shown in Fig. 2.1. The MPU-32 mounts in a 92 mm
(3.62”) ¼ DIN square cutout and is secured by a
panel-mount clamp. Insert the MPU-32 through the panel
cutout and slip the panel-mount clamp over the MPU-32
body. Slide the clamp forward until the latch tabs snap
into the mating holes. Lock the unit in place by
tightening the four clamp screws against the panel.
CAUTION:
Do not over tighten the clamp screws as this may deform
the clamp and release the latch tabs.
Outline and details for MPU-32 surface-mounting are
shown in Fig. 2.2. Ensure that the L/S switch is set before
installing surface-mounting brackets. See Section 3.2.1.4
for switch positions. A detailed installation instruction
sheet is included with the MPU-32-SMK, SurfaceMounting Hardware Kit.
2.3 MPU-CIM CURRENT INPUT MODULE
The MPU-CIM can be surface or DIN-rail mounted.
Outline and mounting details are shown in Fig. 2.3. To
minimize CT-lead burden, an MPU-CIM can be located
close to the CT’s. The MPU-CIM terminates phase- and
earth-fault-CT secondariesshorting blocks are not
required for MPU-CIM outputs.
2.4 EARTH-FAULT CT’S
Outline and mounting details for the EFCT-1, EFCT-2,
and EFCT-26 are shown in Figs. 2.4, 2.5, and 2.6.
2.5 MPS-RTD RTD MODULE
Outline and mounting details for the MPS-RTD are
shown in Fig. 2.7. The MPS-RTD will fit inside most
motor RTD-termination junction boxes and it is certified
for use in Class I, Zone 2 and Class 1, Division 2
Page 2-1
Rev. 5-A-090514
hazardous locations. The MPS-RTD can be surface or
DIN-rail mounted.
2.6 MPS-DIF DIFFERENTIAL MODULE
Outline and mounting details for the MPS-DIF are
shown in Fig 2.8. The MPS-DIF can be surface or
DIN-rail mounted.
2.7 MPU-32/MPU-16A COMPATIBILITY
The MPU-32 is hardware compatible with existing
MPU-16A installations. MPU-16A plug-in terminal
blocks mate with the MPU-32 and an MPU-32 can
directly replace an MPU-16A with minimal or no wiring
changes. I/O connections to MPU-32 terminals 13 to 24,
with the exception of terminal 20 which is not connected,
are identical to those on the MPU-16A. This allows the
MPU-16A upper terminal block to be plugged directly
into an MPU-32. If a switch was connected to the
MPU-16A program-enable terminal, the switch will not
function with the MPU-32. This is usually not a problem
since the MPU-32 set points are password protected. If a
hard-wired program enable is required, it can be
implemented using digital-input terminals 25 and 26 as
outlined in Section 4.2.5. If the MPU-16A analog output
was used, ensure that the MPU-32 analog output switch is
set to the ‘S’ (Self Powered) position.
Although MPU-32 terminals 1 to 12 have been
rearranged to provide a third relay output (terminals 1, 4,
and 9), the MPU-16A lower terminal block can be safely
plugged into the equivalent MPU-32 terminal locations.
CAUTION:
The keying plug installed in position 9 of the MPU-16A
lower terminal block must be removed before the terminal
block can be plugged into an MPU-32. Use a dental pick,
awl, or similar pointed tool to remove the keying plug. If
the keying plug is difficult to remove, use the terminal
blocks supplied with the MPU-32.
A TERMINAL BLOCK WITH A KEYING PLUG WILL
DAMAGE THE MPU-32.
If the MPU-32 does not power up, ensure that L1 is
connected to terminal 2 (not terminal 1) and L2/N is
connected to terminal 3 (not terminal 4). If the duplicate
L1 and L2 terminals on the MPU-16A are used to power
another device, disconnect the outgoing L1 and L2 leads
and power the next device directly from the power source.
This change is in compliance with current codes that do
not permit daisy chaining power connections at plug-in
terminals. MPU-32 default relay assignment is the same
as the MPU-16A trip- and alarm-relay configuration.
For additional information see www.littelfuse.com/
relayscontrols and refer to Technical Note MP-18
Replacing an MPU-16A with an MPU-32.
Installation
Page 2-2
Rev. 5-A-090514
MPU-32 Motor Protection Unit
132.0
(5.20)
91.1
(3.59)
LATCH TAB
CLAMP SCREWS
PANEL-MOUNT CLAMP
PANEL THICKNESS
1.6 (0.06) TO 4.8 (0.19)
SIDE
TOP
96.0
(3.78)
LITTELFUSE STARTCO
TRIP
MOTOR PROTECTION UNIT
96.0
(3.78)
ALARM
RUN
MPU-32
1 3 1 4 1 5 1 6 1 7 18 19 2 0 2 1 22 23 24
E A A
A B C C T T T
F B A L S
O A B C
M
TE M P
A N OU T
CIM
MAIN MENU
MAIN
MENU
Metering
— Ñ
Metering
≤Messages —
²Messages
Ñ
Setup —
Setup Ñ
E M N
R S S
UPI
ESC
ENTER
RESET
6-32 CABLING RESTRAINT
FASTENING POINT
4 PLACES
FRONT
3 1 30 2 9 28 2 7 2 6 2 5
S
0
2
H
V
4 C OMM
D IG I N
V
I /O MOD U LE
TIA-232 ONLY
RE LA Y 3
RELAY 2
RELAY 1
L
2 L
/
N 1
12 11 10 9 8 7 6 5 4 3 2 1
REAR
92.0
(3.62)
R=4.8 (0.19)
MAXIMUM
NOTES:
100.0 MINIMUM
(3.94)
92.0
(3.62)
1. DIMENSIONS IN MILLIMETRES (INCHES).
2. REAR VIEW SHOWN WITHOUT NETWORK
COMMUNICATIONS.
100.0 MINIMUM
(3.94)
PANEL CUTOUT DETAIL
FIGURE 2.1 MPU-32 Outline and Panel-Mounting Details.
Installation
Page 2-3
Rev. 5-A-090514
MPU-32 Motor Protection Unit
142.9
(5.63)
91.1
(3.59)
8.0
(0.32)
HOLE PLUGS
(TOP AND BOTTOM
SURFACES)
SIDE
96.0
(3.78)
(0.65)
16.6
TOP
LITTELFUSE STARTCO
TRIP
MOTOR PROTECTION UNIT
ALARM
122.5
(4.82)
RUN
MPU-32
1 3 1 4 1 5 1 6 1 7 18 19 2 0 2 1 22 23 24
E A A
A B C C T T T
F B A L S
O A B C
M
TE M P
A N OU T
CIM
MAIN MENU
MAIN
MENU
Metering
— Ñ
Metering
≤Messages — Ñ
²Messages
Setup —
E M N
R S S
Setup Ñ
3 1 30 2 9 28 2 7 2 6 2 5
S
0
2
H
V
4 C OMM
V
D IG I N
I /O MOD U LE
UPI
ESC
RE LA Y 3
RELAY 2
L
RELAY 1
2 L
/
N 1
12 11 10 9 8 7 6 5 4 3 2 1
ENTER
RESET
TIA-232 ONLY
NOTE 3
REAR
76.2
(3.00)
5.0
9.9
(0.39)
(0.20)
19.0
(0.75)
FRONT
1. DIMENSIONS IN MILLIMETRES (INCHES).
19.0
(0.75)
(NOTE 6)
112.0
2. REAR VIEW SHOWN WITHOUT NETWORK
COMMUNICATIONS.
(4.41)
(NOTE 5)
NOTES:
3. MOUNT SURFACE MOUNTING BRACKETS
WITH 6-32 x 0.375 PAN-HEAD SCREWS AND
LOCKWASHERS (INCLUDED WITH
SURFACE-MOUNTING KIT).
4. MPU-32 MOUNTING SCREWS: M4 OR
8-32 PAN HEAD.
M4 OR 8-32 TAP
(NOTE 5)
25.4
(1.00)
5. MINIMUM CLEARANCE TO ADJACENT
OBJECTS.
6. MOUNTING-HOLE PATTERN IDENTICAL TO
SURFACE-MOUNT MPU-16A.
MOUNTING DETAIL
FIGURE 2.2 MPU-32 Outline and Surface-Mounting Details.
Installation
Page 2-4
Rev. 5-A-090514
MPU-32 Motor Protection Unit
CABLE-TIE EYELET
4 PLACES
87.0
(3.43)
27 26 25 24 23 22 21 20 19 18 17 16 15 14 13
E C C B A
1 R 5 S E
X Y E
F O
F
EARTH FAULT
2 M
1
MPU
MPU-CIM
C U R R E NT I N P UT M O D U L E
R
1
PHASE A
S
2
5
3
1
4
R
5
PHASE B
S
6
5
7
1
8
R
9
PHASE C
S
10
5
11
1
12
112.5
(4.43)
52.5
(2.07)
56.0 (NOTE 3)
(2.20)
TOP
SIDE
SHORTING SCREWS
A, B, & C (NOTES 4 & 5)
NOTES:
1. DIMENSIONS IN MILLIMETRES (INCHES).
2. MOUNTING SCREWS: M4 OR 8-32.
(0.50)
3. OVERALL HEIGHT WHEN MOUNTED
ON DIN EN50022 35-mm x 7.5-mm
TOP-HAT RAIL.
4. SHORTING SCREWS ARE ACCESSIBLE
FROM BOTTOM OF MPU-CIM.
60.0
(2.36)
12.5
BOTTOM
5. SHORTING SCREWS: 6-32 x 0.375
NICKEL-PLATED-BRASS BINDING HEAD.
DO NOT SUBSTITUTE.
14.5
(0.57)
M4 OR 8-32 TAP
6.8
(0.27)
100.0
(3.94)
6.8
(0.27)
MOUNTING DETAIL
FIGURE 2.3 MPU-CIM Outline and Mounting Details.
Installation
Page 2-5
Rev. 5-A-090514
MPU-32 Motor Protection Unit
NOTES:
1. DIMENSIONS IN MILLIMETRES (INCHES).
2. MOUNTING SCREWS: M4 OR 8-32.
3. PRESS MOUNTING FEET IN PLACE USING
INSTALLATION TOOL PROVIDED.
4. RoHS COMPLIANT.
5. EN 60044-1 COMPLIANT.
121.0
(4.76)
121.0
(4.76)
20.5
(0.81)
56.0
(2.21)
46.0
(1.81)
30.0
(1.18)
80.0
(3.15)
NOTE 2
M5 SCREWS
TOP
MOUNTING DETAIL
25.0
(0.98)
30.0
(1.18)
EFCT-1 EARTH FA ULT CT
600 V CLASS, INSULATION CLASS A
R
R
LR 53428
5.0 (0.20) Ø
RECESSED FOR
8-mm HEX NUT
1.0 (0.04) DEEP
22.0
(0.87)
EFCT - 1FC
FLUX
CONDITIONER
(OPTIONAL)
.0
82 23)
.
(3
69
(2.7 .8
5)
126.0
(4.96)
US
(5.43)
138.0 MAX
C
5.5
(0.22)
110.0
(4.33)
FRONT
5.5
(0.22)
56.0
(2.21)
SIDE
FIGURE 2.4 EFCT-1 Outline and Mounting Details.
Installation
Page 2-6
Rev. 5-A-090514
MPU-32 Motor Protection Unit
NOTES:
1. DIMENSIONS IN MILLIMETRES (INCHES).
2. MOUNTING SCREWS: M5 OR 10-32.
3. RoHS COMPLIANT.
4. EN 60044-1 COMPLIANT.
215.0
(8.46)
26.5
(1.04)
52.3
(2.06)
P
S1 2S2
P1
31.0
(1.22)
64.0
(2.52)
215.0
(8.46)
162.0
(6.38)
M5 OR 10-32 TAP
M5 SCREWS
TOP
MOUNTING DETAIL
31.0
(1.22)
25.0
(0.98)
EFCT-2 EARTH FAULT CT
600 V CLASS, INSULATION CLASS A
R
R
LR 53428
139.7
(5.50)
FLUX CONDITIONER
(INCLUDED)
BONDING
SCREW
215.0
(8.46)
US
5.0 (0.20) DIA
60.0
(2.36)
236 MAX
(9.29)
C
8.5
(0.33)
198.0
(7.80)
FRONT
8.5
(0.33)
SIDE
FIGURE 2.5 EFCT-2 Outline and Mounting Details.
Installation
Page 2-7
Rev. 5-A-090514
MPU-32 Motor Protection Unit
68.0
(2.68)
68.0
(2.68)
17.0
(0.67)
P
S1 2 S2
P1
M4 OR 8-32 TAP
42.6
(1.68)
52.5
(2.07)
26.5
(1.04)
34.0
(1.34)
M5 SCREWS
110.0 MAX
(0.43)
TOP
MOUNTING DETAIL
26.5
(1.04)
25.0
(0.98)
E F C T- 2 6
E A R T H FA U LT C T
600 V CLASS, INSULATION CLASS A
R
R
C
LR 53428
US
RECESSED FOR
7-mm HEX NUT
3.0 (0.12) DEEP
7.0
(0.87)
34.0
(1.34)
72.0
(2.83)
4.0 (0.16) Ø
.0
26 2)
0
(1.
58.0
(2.28)
52.5
(2.07)
5.0
(0.20)
5.0
(0.20)
FRONT
SIDE
NOTES:
1. DIMENSIONS IN MILLIMETRES (INCHES).
2. MOUNTING SCREWS: M4 OR 8-32.
MOUNTING FOOT
INSTALLATION
TOOL
3. PRESS MOUNTING FEET IN PLACE USING
INSTALLATION TOOL PROVIDED.
(DETAIL ‘A’)
4. RoHS COMPLIANT.
DETAIL ‘A’
5. EN 60044-1 COMPLIANT.
6. NOT ALL CERTIFICATIONS SHOWN.
FIGURE 2.6 EFCT-26 Outline and Mounting Details.
Installation
Page 2-8
Rev. 5-A-090514
MPU-32 Motor Protection Unit
CABLE-TIE EYELET
4 LOCATIONS
34 33 32 31 30 29 28 27 26 25 24 23 22 21 20 19
C D R S C D R C D R S C D R S
H
P
H
INP 8
INP 7
INP 6
INP 5
G
INPUT MODULE
87.0
(3.43)
PWR
CTU/
MPU
COMM
INP 1
R
1
D
2
C
3
S
H
4
INP 2
R
5
D
6
MPS-RTD
2
4
S
0
V
D C H R D C V
9 10 11 12 13 14 15 16 17 18
INP 3
C
7
ADDRESS SWITCH
ACCESS COVER
R
8
INP 4
COMM
52.5
112.5
(4.43)
(2.07)
12.5
(0.50)
56.0 (NOTE 3)
(2.20)
1. DIMENSIONS IN MILLIMETRES
(INCHES).
(2.36)
60.0
NOTES:
2. MOUNTING SCREWS: M4 OR 8-32.
3. OVERALL HEIGHT WHEN MOUNTED ON
DIN EN50022 35-mm x 7.5-mm
TOP-HAT RAIL.
(0.57)
14.5
M4 OR 8-32 TAP
6.3
100.0
6.3
(0.25)
(3.94)
(0.25)
FIGURE 2.7 MPS-RTD Outline and Mounting Details.
Installation
Page 2-9
Rev. 5-A-090514
MPU-32 Motor Protection Unit
CABLE-TIE EYELET
4 PLACES
PWR
COMM
87.0
(3.43)
15 14
S
P
G
DIFFERENTIAL MODULE
MPS-DIF
CTU/
MPU
PHASE A
C
1
5
2
1
3
PHASE B
C
4
5
5
PHASE C
1
6
C
7
5
8
1
9
+
2
4
0
V - + V
10 11 12 13
COMM
52.5
(2.07)
56.0 (NOTE 3)
(2.20)
112.5
(4.43)
TOP
SIDE
NOTES:
1. DIMENSIONS IN MILLIMETRES
(INCHES).
2. MOUNTING SCREWS: M4 OR 8-32.
3. OVERALL HEIGHT WHEN MOUNTED ON
DIN EN50022 35-mm x 7.5-mm
TOP-HAT RAIL.
12.5
60.0
(2.36)
(0.50)
BOTTOM
14.5
(0.57)
M4 OR 8-32 TAP
6.8
(0.27)
100.0
(3.94)
6.8
(0.27)
MOUNTING DETAIL
FIGURE 2.8 MPS-DIF Outline and Mounting Details.
Installation
MPU-32 Motor Protection Unit
Page 2-10
Rev. 5-A-090514
This page intentionally left blank.
Installation
Page 3-1
Rev. 5-A-090514
MPU-32 Motor Protection Unit
3. SYSTEM WIRING
3.1 GENERAL
A typical connection diagram for an MPU-32 with an
MPU-CIM is shown in Fig. 3.1. See Sections 3.2.3 and
3.2.4 for MPS-RTD and MPS-DIF connections. See
Appendix C for the 1-A-direct-input configuration.
PHASE CT’S
(NOTE 9)
CONTACTOR
K1
A
EARTH-FAULT CT
MOTOR
(NOTE 6)
B
+t˚
t˚
C
12 11 10 9
1
5
S R
8
7
6
5
4
3
2
1
5
S R
1
5
S R
PHASE C
PHASE B
1
Pt100 RTD
SENSOR
PHASE A
MPU-CIM
(NOTE 8)
A
MPU
C E
O F
B C M 2
E
F
1 Y
EARTH FAULT
X
E
S
5
R
ALTERNATE
CONNECTION FOR
PTC-THERMISTOR
SENSOR(S)
1
BROWN
GREEN
BLUE
WHITE
RED
BLACK
13 14 15 16 17 18 19 20 21 22 23 24 25 26 27
(NOTE 10)
(NOTE 6)
(NOTE 3)
OUTPUT
(NOTE 4)
13 14 15 16 17 18 19 20 21 22 23 24
A
B C
S1
CIM
C T T T
O A B C
M
TEMP
E
F
A
B
A
A
L S
AN OUT
TIA-232 ONLY
(NOTE 7)
31 30 29 28 27 26 25
+ + S - 0 + 24
H
V
V
COMM
DIG IN
I/O MODULE
RELAY 2
12 11 10 9
E M N
R S S
RELAY 3
7
6
5
L1
L
2
4
N
L
1
3
2
1. MPU-32 REAR VIEW SHOWN.
1
MPU-32
RELAY 1
8
8
NOTES:
2. RELAYS SHOWN DE-ENERGIZED.
3. GROUND CABLE SHIELDS AT MPU-32 END ONLY.
1
4. GROUND OUTPUT-CABLE SHIELD AT RECEIVER
END ONLY.
5. ALTERNATE CONTACTOR-COIL LOCATION.
START
STOP
(NOTE 5)
6. ALTERNATE CONNECTION FOR PTC-THERMISTOR
SENSOR(S).
K1
7. PROGRAMMABLE DIGITAL INPUT.
K1
8. DOTTED LINES SHOW 1-A-CT CONNECTIONS.
ALARM
A
L2/N
K1
9. A-B-C PHASE ROTATION REQUIRED.
10. EARTH-FAULT INPUT IN NOT POLARITY SENSITIVE.
11. OPTIONAL NETWORK COMMUNICATIONS
NOT SHOWN.
FIGURE 3.1 Typical MPU-32 Connection Diagram.
System Wiring
Page 3-2
Rev. 5-A-090514
MPU-32 Motor Protection Unit
3.2 WIRING CONNECTIONS
3.2.1 MPU-32 CONNECTIONS
The MPU-32 wire-clamping terminal blocks accept 24
to 12 AWG (0.2 to 2.5 mm2) conductors. These terminal
blocks unplug to allow the MPU-32 to be easily
removed.
3.2.1.5 PTC or RTD INPUT (LOCAL)
The temperature-sensor input on the MPU-32 can be
configured for either PTC or Pt100 RTD operation as
shown in Fig. 3.3.
a) PTC
3.2.1.1 SUPPLY VOLTAGE
Derive supply voltage from the line side of the motor
controller or from an independent source. Connect
supply voltage to terminals 2 and 3 (L1 and L2/N) as
shown in Fig. 3.1. In 120-Vac systems, L2/N is
designated as the neutral conductor. For direct-current
power supplies, use L1 for the positive terminal and
L2/N as the negative terminal. Ground terminal 8 ( ).
3.2.1.4 ANALOG OUTPUT
The analog output is switch selectable as self powered
or loop powered.
For the self-powered connection, set the L/S switch to
the S position. The self-powered connection is shown in
Fig. 3.2 (a). The analog output is referenced to the I/O
module supply, terminal 27.
For the loop-powered connection, set the L/S switch to
the L position. The loop-powered connection is shown
in Fig. 3.2 (b). In loop-powered operation, the analogoutput is isolated from all other MPU-32 terminals.
a) SELF POWERED (S POSITION)
18
TB
17
TA
19
TC
18
TB
17
TA
b) Pt100 RTD
t˚
FIGURE 3.3 Local Temperature-Sensor Connections.
3.2.1.6 I/O MODULE INTERFACE
The I/O module interface supplies power and
communications to optional I/O modules such as the
MPS-RTD and MPS-DIF.
I/O module communication is based on the two-wire
multi-drop TIA-485 standard but uses a proprietary
protocol. Overall line length must not exceed 1.2 km
(4,000’). For line lengths exceeding 10 m (33’), 150-
terminations are required at the cable ends. I/O modules
are supplied with 4 m (13’) of interconnection cable. See
Fig. 3.4.
NOTE: I/O communication is shared with the display.
Incorrect wiring can cause the display and keypad to
freeze.
31
MPU-32
30
29
AA 24
28
RECEIVER
TERMINATION
TC
+t˚
3.2.1.2 CIM INPUT
Connect the MPU-32 to the MPU-CIM as shown in
Figs. 3.6 and 3.7 using the cable provided with the
MPU-CIM.
3.2.1.3 DIGITAL INPUT
A 24-Vdc digital input is provided on terminals 25 and
26. This input is polarity sensitive. For a logical 1,
terminal 26 must be positive with respect to terminal 25.
See Section 4.2.5.
The current-limited 24-Vdc source (terminals
27 & 31) can be used to power the digital input.
19
3
27
RED
+
GREEN
-
WHITE
+
-
18
17
MPS-RTD
RTD
MODULE
16
15
BLACK
11
Rt
19 20
AB 23
-
b) LOOP POWERED (L POSITION)
AA 24
AB 23
+
LOOP
SUPPLY
-
RECEIVER
TERMINATION
FIGURE 3.2 Analog-Output Connections.
+
Rt
10
11
MPS-DIF
12
DIFFERENTIAL
13
MODULE
14 15
NOTES:
1. INTERCONNECT CABLE BELDEN 3124A
OR EQUIVALENT.
2. Rt = 150 OHMS, 1/4 WATT. REQUIRED FOR LINE
LENGTHS EXCEEDING 10 M (33’).
FIGURE 3.4 I/O Module Connection Diagram.
System Wiring
Page 3-3
Rev. 5-A-090514
MPU-32 Motor Protection Unit
3.2.1.7 RS/EIA/TIA-232 COMMUNICATIONS
An RJ-45 TIA-232 connector is provided on the rear
panel of the MPU-32. This port uses Modbus RTU
protocol to communicate with SE-Comm-RIS
PC-interface software. For Modbus RTU protocol, see
Appendix D. The slave ID and communication baud rate
are set in the Setup  Hardware  Local Comms menu.
Table 3.1 shows the pinout for the optional CA-945
adapter for operation with SE-Comm-RIS.
See Fig 3.1 for RJ-45 pinout.
For a USB connection, use an SE-ICUSB232 adapter.
3.2.2 MPU-CIM CONNECTIONS
The MPU-CIM CT-input terminal blocks accept 22 to
10 AWG (0.3 to 4.0 mm2) conductors. The remaining
MPU-CIM clamping blocks accept 24 to 12 AWG
(0.2 to 2.5 mm2) conductors.
The MPU-CIM contains four signal-conditioning
interface transformers which are interconnected as shown
in Fig. 3.5. These transformers isolate the MPU-32 from
the phase and earth-fault CT's. The MPU-CIM eliminates
the need for CT shorting contacts when the MPU-32 is
disconnected. Phase-CT and earth-fault-CT secondaries
can be simultaneously grounded through terminal 22 and a
jumper to terminal 20. For applications where the CT
secondaries must be grounded at another location, the CT
secondaries can be isolated by removing shorting screws
A, B, and C through holes in the bottom of the MPU-CIM.
See Figs. 2.3 and 3.5.
TABLE 3.1 CA-945 ADAPTER PINOUT
SYMBOLIC NAME
RJ-45
DB9
RI/DSR
CD
DTR
SG
RD
TD
CTS
RTS
1
2
3
4
5
6
7
8
9
1
4
5
2
3
8
7
NOTE: A-B-C phase sequence and polarity must be
observed when connecting phase CT’s. See Section 4.2.1.
Connect the MPU-CIM to the MPU-32 as shown in
Figs. 3.6 and 3.7 using the cable provided with the
MPU-CIM.
TB3
TB2
27
26
25
24
23
1
R
5
S
E
22
20
19
X
Y
E
F
1
18
B
A
S
R
21
1
5
2
4
5
16
15
14
13
E
F
2
C
O
M
C
B
A
C
S
R
1
3
17
5
6
R
1
7
8
S
9
10
5
11
1
12
TB1
NOTES:
1. REMOVE SHORTING SCREWS A, B, AND C TO ISOLATE PHASE-CT
AND EARTH-FAULT-CT SECONDARIES FOR IN-LINE APPLICATIONS.
2. SHORTING SCREWS A, B, AND C: 6-32 x 0.375
NICKEL-PLATED-BRASS BINDING HEAD. DO NOT SUBSTITUTE.
3. SHORTING SCREWS A, B, AND C MUST NOT BE REMOVED FOR
RESIDUAL OR TWO-CT CONNECTIONS.
4. EACH TERMINAL ON TB1 AND TB3 WILL ACCEPT ONE
NO. 10 AWG CONDUCTOR.
FIGURE 3.5 MPU-CIM Schematic.
System Wiring
Page 3-4
Rev. 5-A-090514
MPU-32 Motor Protection Unit
3.2.2.1 STANDARD
Standard connections with earth-fault CTs are shown in
Fig. 3.6. Dotted lines indicate 1-A-CT connections. Use
shielded cable for EFCT-1 or EFCT-2 connections.
Ensure only current-carrying phase conductors pass
through the earth-fault-CT window and that ground
conductors do not.
This connection is a legacy from MPU-16A
applications. The MPU-32 calculates residual current.
See Section 4.2.2.
3.2.2.3 TWO-CT
The two-CT connection is shown in Figs. 3.7 (b) and
3.7 (c). Dotted lines indicate 1-A-CT connections.
Since this connection derives the current in the
unmonitored phase, it should be used only in retrofit
applications where it is not possible to install a third CT.
3.2.2.2 RESIDUAL EARTH-FAULT
The residual earth-fault connection is shown in
Fig. 3.7 (a). Dotted lines indicate 1-A-CT connections.
Use three identical CT's for this connection.
a) STANDARD CONNECTION
MPU-32
S
5
X
MPU-CIM
R
1
4
5A
1A
5
3
S
CT A
7
8
BLACK
15
14
13
A
S TERMINALS ARE GROUNDED
THROUGH TERMINAL 22
5
S
CT B
B
C
C
O
M
10
9
A
13
RED
16
R
1
5
6
5A
5
S
2
17
E
F
2
1A
R
1
18
E
F
1
Y
B
14
WHITE
19
BROWN
20
21
22
E
C
15
1
11
12
5A
R
23
24
25
26
1
BLUE
21
5A
1A
27
C
O
M
16
E
F
22
1A
S
H
29
GREEN
1-A OR 5-A
EARTH-FAULT
CT
CT C
b) STANDARD CONNECTION WITH EFCT-1 OR EFCT-2
MPU-32
X
3
4
5A
1A
CT A
6
1
5
S
R
5
7
8
5A
1
5
S
2
1A
R
CT B
16
15
14
13
C
O
M
E
F
2
E
F
1
MPU-CIM
1
17
BLACK
18
WHITE
19
Y
RED
20
21
22
E
R
9
S
10
A
13
GREEN
23
S
C
B
A
S AND E TERMINALS ARE GROUNDED.
S THROUGH TERMINAL 22,
E THROUGH TERMINAL 18.
5
1
11
12
5A
5
B
14
1A
R
21
BROWN
24
25
26
1
22
BLUE
27
C
O
M C
16 15
E
F
S
H
29
EFCT-X
CT C
FIGURE 3.6 MPU-CIM Standard Connections.
System Wiring
Page 3-5
Rev. 5-A-090514
MPU-32 Motor Protection Unit
a) RESIDUAL CONNECTION
MPU-32
WHITE
BLACK
RED
BLUE
GREEN
BROWN
C
E O
S
F M C B A
H
29 21 22 16 15 14 13
1A 5A
27 26 25 24 23 22 21 20 19 18 17 16 15 14 13
5
S
X
E
Y
E
F
1
MPU-CIM
3
4
5A
2
1A
1
R
1
5
5
S
6
CT A
R
1
7
8
1A
5
S
5A
R
C C
O
M
E
F
2
9
B
5
S
A
R TERMINALS ARE
GROUNDED THROUGH
TERMINAL 22.
1
10 11 12
CT B
SHORTING SCREWS
A, B, & C MUST
NOT BE REMOVED.
1A
R
5A
1
CT C
b) TWO-CT CONNECTION
MPU-32
BLACK
WHITE
RED
BLUE
BROWN
GREEN
C
E O
S
F M C B A
H
29 21 22 16 15 14 13
5A
1A
1-A OR 5-A
EARTH-FAULT
CT
27 26 25 24 23 22 21 20 19 18 17 16 15 14 13
5
S
X
E
Y
E
F
1
MPU-CIM
4
5
S
6
5
1
7
8
1A
3
R
5A
2
1
5A
1
5
1A
S
R
S
R
9
B
C C
O
M
E
F
2
5
A
R TERMINALS ARE
GROUNDED THROUGH
TERMINAL 22.
EARTH-FAULT CT MUST
NOT BE GROUNDED.
1
10 11 12
CT A
1A
R
5A
1
SHORTING SCREWS
A, B, & C MUST
NOT BE REMOVED.
CT C
c) TWO-CT CONNECTION WITH EFCT-1 OR EFCT-2
MPU-32
C
E O
S
F M C B A
H
29 21 22 16 15 14 13
EFCT-X
BLACK
WHITE
BLUE
RED
GREEN
BROWN
27 26 25 24 23 22 21 20 19 18 17 16 15 14 13
5
S
X
E
Y
MPU-CIM
CT A
R
5
S
6
5
1
7
8
1A
1
4
E
F
2
5A
5
3
5A
S
2
1A
R
1
E
F
1
R
9
S
C C
O
M
5
B
A
R TERMINALS ARE
GROUNDED THROUGH
TERMINAL 22.
1
10 11 12
1A
R
5A
1
SHORTING SCREWS
A, B, & C MUST
NOT BE REMOVED.
CT C
FIGURE 3.7 Other MPU-CIM Connections.
System Wiring
MPU-32 Motor Protection Unit
3.2.3 MPS-RTD CONNECTIONS AND ADDRESS SELECTION
Connect the MPS-RTD to the MPU-32 using the
four-conductor shielded cable (Belden 3124A or
equivalent) supplied with the MPS-RTD as shown in
Fig. 3.8. The MPU-32 24-Vdc supply can power up to
three MPS-RTD modules.
Connect RTD’s to the MPS-RTD as shown in Fig 3.8.
When the RTD module is installed in a motor junction
box, RTD-lead shielding is not required. MPS-RTD
terminal blocks accept 24 to 12 AWG (0.2 to 2.5 mm2)
conductors.
Connect surge-protection (SPG) terminal 20 to
terminal 19 ( ) and ground terminal 19.
The MPS-RTD has two switches to select its network
address. See Fig. 3.8. Up to three MPS-RTD modules
can be connected to the I/O MODULE bus, and each
RTD-module address must be unique. If one module is
used, address 1 must be used. If two RTD Modules are
used, addresses 1 and 2 must be used. If three RTD
Modules are used, addresses 1, 2, and 3 must be used.
Table 3.2 shows the address selection format.
TABLE 3.2 MPS-RTD ADDRESS SELECTION
ADDRESS
SWITCH 1
SWITCH 2
0
1
2
3
(Off Line)
(First RTD Module)
(Second RTD Module)
(Third RTD Module)
Open
Closed
Open
Closed
Open
Open
Closed
Closed
3.2.4 MPS-DIF CONNECTIONS
Connect the MPS-DIF to the MPU-32 using fourconductor shielded cable (Belden 3124A or equivalent)
as shown in Fig. 3.4.
Connect the surge-protection (SPG) terminal 15 to
terminal 14 ( ), and ground terminal 14.
The MPS-DIF CT-input terminal blocks accept 22 to
10 AWG (0.3 to 4.0 mm2) conductors. The remaining
MPS-DIF clamping blocks accept 24 to 12 AWG (0.2 to
2.5 mm2) conductors.
Page 3-6
Rev. 5-A-090514
3.2.4.2 MPU SUMMATION
The MPU-summation connection uses three phase
CT’s and three differential CT’s as shown in Fig. 3.10.
Both CT-ratio and CT-saturation characteristics must be
matched to avoid differential currents under motor
starting and running conditions. The MPS-DIF module
should be located near the MPU-CIM to minimize
CT-wire length. It is preferred to use three dedicated
phase CT’s and three core-balance differential CT’s as
described in Section 3.2.4.1.
For the delta connection, the FLA Rating is set equal
to the motor’s full-load current multiplied by 3.
3.2.4.3 DIF SUMMATION
The DIF-summation connection uses six differential
CT’s as shown in Fig. 3.11. Both CT-ratio and
CT-saturation characteristics must be matched to avoid
differential currents under motor starting and running
conditions. It is preferred to use three core-balance CT’s
as described in Section 3.2.4.1. This six-CT connection
allows the CT’s and MPS-DIF to be placed near the
motor to minimize power-cable and CT-lead length.
3.2.5 CABLE RESTRAINT
All conductors should be restrained within
100 mm (4”) of the terminal blocks. Four cablingrestraint points are provided on the MPU-32 rear panel.
Secure cables to the MPU-CIM, MPS-RTD and
MPS-DIF using the cable-tie eyelets and the cable ties
provided. See Figs. 2.1, 2.3, 2.7 and 2.8.
3.2.6 DIELECTRIC-STRENGTH TESTING
Dielectric-strength testing can be performed only on
CT inputs, supply-voltage input, and output relays.
Unplug all other I/O and remove the MPU-CIM
connection (terminal 22) during dielectric-strength
testing.
3.2.4.1 CORE BALANCE
The core-balance connection uses three differential
CT’s as shown in Fig. 3.9. To minimize power-cable
and CT secondary lead lengths, both the differential CT’s
and the MPS-DIF can be located near the motor. The
primary rating of the differential CT does not have to
match the phase-CT primary rating and is usually
selected with a lower ratio resulting in more sensitive
differential protection. The core-balance method avoids
CT-matching issues and is the preferred connection.
System Wiring
Page 3-7
Rev. 5-A-090514
MPU-32 Motor Protection Unit
3-WIRE RTD
CONNECTION
t°
t°
t°
34 33 32 31 30 29 28 27 26 25 24 23 22 21 20 19
C D R S C D R C D R S C D R S
H
P
H
INP 8
INP 7
INP 6
INP 5
G
INPUT MODULE
PWR
MPS-RTD
CTU/
MPU
COMM
R
1
OPEN
C
3
S
H
4
INP 2
R
5
D
6
COMM 2
INP 4
4
0
S
V
D C H R D C V
9 10 11 12 13 14 15 16 17 18
INP 3
C
7
R
8
BLACK
D
2
t°
1 3 1 4 1 5 1 6 1 7 1 8 1 9 2 0 2 1 22 23 24
t°
t°
L S
E M N
R S S
31 30 2 9 2 8 2 7 2 6 2 5
S
0
2
H
V
4
D IG IN
V C OMM
I/O MODU LE
t°
RED
INP 1
OPEN
GREEN
2
WHITE
1
CLOSED
t°
S C D R
H
ADDRESS
SELECTION
SWITCHES
OPEN
ALTERNATE
2-WIRE RTD
CONNECTION
t°
INTERCONNECT CABLE
BELDEN 3124A OR EQUIVALENT
TIA-232 ONLY
RE LAY 3
L
2 L
/
N 1
12 11 10 9 8 7 6 5 4 3 2 1
RELAY 2
RELAY 1
FIGURE 3.8 MPS-RTD Connection Diagram.
ØA
1
4
MOTOR
ØB
2
5
ØC
3
6
1
5
S
1
5
S
1
5
S
1
5
C
1
5
C
1
5
C
12
11
10
8
7
6
4
3
2
9
8
7
6
5
4
3
2
1
MPU-CIM
MPS-DIF
CONNECTIONS:
WYE: ØA & 1, ØB & 2, ØC & 3, 4 & 5 & 6
DELTA: ØA & 1 & 6, ØB & 2 & 4, ØC & 3 & 5
FIGURE 3.9 Core-Balance Connection.
System Wiring
Page 3-8
Rev. 5-A-090514
MPU-32 Motor Protection Unit
1
ØA
4
MOTOR
ØB
2
5
ØC
3
6
1
5
S
1
5
S
1
5
S
1
5
C
1
5
C
1
5
C
4
3
2
8
7
6
12
11
10
9
8
7
6
5
4
3
2
1
MPU-CIM
MPS-DIF
CONNECTIONS:
NOTES:
WYE: ØA & 1, ØB & 2, ØC & 3, 4 & 5 & 6
DELTA: ØA & 1 & 6, ØB & 2 & 4, ØC & 3 & 5
1. REMOVE MPU-CIM SHORTING SCREWS
A, B, & C.
FIGURE 3.10 MPU-Summation Connection.
ØA
1
4
MOTOR
1
5
S
1
5
S
1
5
S
12
11
10
8
7
6
4
3
2
ØB
2
5
ØC
3
6
MPU-CIM
CONNECTIONS:
WYE: ØA & 1, ØB & 2, ØC & 3, 4 & 5 & 6
DELTA: ØA & 1 & 6, ØB & 2 & 4, ØC & 3 & 5
1
5
C
1
5
C
1
5
C
9
8
7
6
5
4
3
2
1
MPS-DIF
FIGURE 3.11 DIF-Summation Connection.
System Wiring
Page 4-1
Rev. 5-A-090514
MPU-32 Motor Protection Unit
4. OPERATION AND SETUP
4.1 DISPLAY AND INDICATION
All MPU-32 information displays and settings can be
accessed using the MPU-32 menu system, the TIA-232
interface, or a network-communications interface. Use
SE-Comm-RIS software to program with a personal
computer.
In the following sections, menu items and setup
parameters are listed in italics and are shown in the
format displayed on the alphanumeric LCD. The LCD
cannot display subscripts and superscripts.
Menu selection is in the following format:
Menu 1 | Sub Menu 1 | Sub Menu 2 | Sub Menu 3 |……
4.1.1 FRONT-PANEL LED INDICATION
Menu: Setup | System Config | UPI LED
The red TRIP and yellow ALARM LED’s indicate a
trip or alarm condition. The green RUN LED is OFF
when current is not detected, flashes when the motor is
starting, and is ON when the motor is running. The
yellow UPI LED is a user-programmable indicator and
its function is defined by one of the menu selections
shown in Table 4.1.
Example: For the menu item shown in Fig. 4.1, the
notation is Setup | System Ratings | CT Primary
Metering 
Messages 
Setup
Protection
System Ratings
Digital Input
•
•
•
CT Primary
EF Source
EF-CT-Primary
•
•
•
Fig. 4.2 shows the symbols that assist in navigating the
menu system and how these symbols relate to the arrow
keys on the MPU-32. See the MPU-32 menu map in
Appendix A.
These symbols indicate the
menu level. Up to five submenulevel symbols may be displayed.
Use left-arrow key or ESC to
move back one menu level.
Indicates top of list. Scroll
using down-arrow key.
Scroll using up- or downarrow keys.
Indicates bottom of list.
Scroll using up-arrow key.
None
Trip1
Trip2
Trip3
Alarm1
Alarm2
Alarm3
Relay1
Relay2
Relay3
Digital Input
Current Detected
Current > 125%
Run Mode
ETR
Start Inhibit
Network Run1
FIGURE 4.1 Menu Example.
Cursor indicates selected
menu item and shape
indicates available scrolling
directions.
TABLE 4.1 UPI LED FUNCTIONS
SELECTION
DEFINITION
¬¬¬¬¬ TITLE
Net Activity
Reduced OC
LED remains off.
Trip1 condition exists.
Trip2 condition exists.
Trip3 condition exists.
Alarm1 condition exists.
Alarm2 condition exists.
Alarm3 condition exists.
Relay1 is energized.
Relay2 is energized.
Relay3 is energized.
Digital Input is valid.
Current is above minimum
threshold.
Current is above 125% FLA.
MPU-32 is in Run mode.
MPU-32 is in Emergency Thermal
Reset state
In I2t or starts-per-hour inhibit state.
Run1 is issued by a network
command.
Activity is detected on the
communications interface.
Reduced Overcurrent protection is
active.
Indicates that there are related data
displays to the left or right of this
display. Use left- or right-arrow
keys to view adjacent data displays.
„
½ MENU ITEM 1 Ñ
² MENU ITEM 2 ¼
« MENU ITEM 3 *
Use right-arrow key to
select submenu.
Use right-arrow key to
display data.
Indicates active item in
list-type set-point
displays.
FIGURE 4.2 Menu Symbols.
Operation and Setup
MPU-32 Motor Protection Unit
4.1.2 REAR-PANEL LED INDICATION
The three LED’s on the rear panel are labeled ER, MS,
and NS. The red ER (Error) LED is OFF during normal
operation and is ON when there is a processor error or
during firmware-update operation. Output relays are
de-energized when this LED is ON.
The MS
(Module Status) and NS (Network Status) LED’s are
used for network-communications and firmware-update
annunciation. The specific colour and function of these
LED’s is defined by the network-communications option
installed in the MPU-32. For detailed information, see
the applicable communications manual.
4.1.3 DISPLAY CONTRAST AND TEST
Contrast control and test operator-interface features
are available when the display is in Local mode. To
prevent a Display Comm Trip, select Disabled in the
Setup  Hardware  OPI Display  Trip Action menu.
To enter Local mode, press the up-arrow, right-arrow,
and ENTER keys simultaneously.
In Local mode, all face-plate LED’s are ON and the
display indicates three menu items; Contrast, Address,
and Enter Test Mode. Use the up- and down-arrow keys
to select the menu item.
Contrast: Use the right- and left-arrow keys to
increase or decrease contrast.
Address: The display address indicates 1 and cannot
be changed.
Enter Test Mode: Press the right-arrow key to enter
test mode. In test mode, the LED test, Display test, and
Display-Heater test are automatically performed. The
Interactive-Key test is then entered and the following
symbols are displayed when a key is pressed.
Left Key:
¬
Right Key Ñ
Up Key
«
Down Key ½
ESC:
^
ENTER:
ª
RESET:
Press RESET to exit this menu.
Press the ESC key to exit Local mode and return to the
MPU-32 menu. Re-enable OPI Diplay Trip Action.
4.2 SETUP
Certain MPU-32 settings cannot be changed when the
motor is running. See Appendix B.
4.2.1 PHASE-CT INPUTS
Menu: Setup | System Ratings | CT Primary
The CT-primary setting range is 1 to 5,000 A. To
maintain specified accuracy, phase CT’s should be
selected with a primary rating between 100 and 300% of
motor full-load current.
For A-B-C sequence, the +Seq I1 display value is
larger than the –Seq I2 display value and positive current
unbalance is indicated. Negative current unbalance will
be indicated if the phase sequence is B-A-C. If negative
unbalance is indicated, correct the phase-CT connections.
Page 4-2
Rev. 5-A-090514
Severe current unbalance may be indicated when
phase-CT polarity is incorrect.
4.2.2 EARTH-FAULT-CT INPUT
Menu: Setup | System Ratings | EF Source
Menu: Setup | System Ratings | EF-CT Primary
The EF Source menu selects the earth-fault source as
Calculated (3I0) or Measured (Ict).
The Calculated (3I0) selection uses the 3I0 value
obtained from the sequence-component calculation and
is based on the phase currents only. Set the EF-CT
Primary to the phase-CT-primary rating when
Calculated (3I0) is selected.
The Measured (Ict) selection uses current measured by
an earth-fault CT or the residual connection. Set EF-CT
Primary to the earth-fault-CT-primary rating when an
earth-fault CT is used. For the EFCT-1 and EFCT-2
earth-fault CT’s, set EF-CT Primary to 5 A. Set EF-CT
Primary to the phase-CT-primary rating for the residualCT connection.
The setting range for the EF-CT-Primary rating is 1 to
5,000 A.
NOTE: Calculated 3I0 does not detect CT saturation.
Enable overcurrent protection when earth-fault current
can exceed 15 times the phase-CT primary rating.
NOTE: 3I0 and Ict values will be shown in the
Metering  Earth Leakage display regardless of the
EF Source selection or CT connections.
NOTE: For the residual connection and Calculated (3I0)
selection, the earth-fault-trip setting should be greater
than 5%.
4.2.3 MOTOR DATA
Menu: Setup | System Ratings
Menu: Setup | Protection  Overload
In the System Ratings menu, motor data must be
entered for the FLA Rating (full-load current),
Frequency, and Service Factor.
Set Frequency at 50 Hz, 60 Hz, or Variable. Use
Variable for adjustable-speed drive applications.
LR Current (locked-rotor current), LR Time Cold (cold
locked-rotor time), and LR Time Hot (hot locked-rotor
time) must be entered in the Setup | Protection 
Overload menu to provide customized overload
protection. See Section 5.2.
4.2.4 OUTPUT RELAY ASSIGNMENT
Menu: Setup | Relay Outputs | Relay x
Menu: Setup | Relay Outputs | RY Pulse Time
Each of the three output relays can be assigned to one
of the functions listed in Table 4.2. More than one relay
can be assigned the same function. Trip and alarm
assignments operate in the selected fail-safe or non-failsafe mode.
Operation and Setup
Page 4-3
Rev. 5-A-090514
MPU-32 Motor Protection Unit
FUNCTION
Trip1
Trip2
Trip3
Alarm1
Alarm2
Alarm3
Current
Run Mode
Start Inhibit
Trip 1 Pulse(1)
Run1
Watchdog
Reduced OC
None
(1)
TABLE 4.2 OUTPUT-RELAY FUNCTIONS
ASSIGNMENT OR ACTION
Relay operates when a trip occurs in a protective function assigned Trip1, Trip1&2, Trip1&3, or Trip1,2&3 trip
action. Fail-safe or non-fail-safe mode selection is active.
Relay operates when a trip occurs in a protective function assigned Trip2, Trip1&2, Trip2&3, or Trip1,2&3 trip
action. Fail-safe or non-fail-safe mode selection is active.
Relay operates when a trip occurs in a protective function assigned Trip3, Trip1&3, Trip2&3, or Trip1,2&3 trip
action. Fail-safe or non-fail-safe mode selection is active.
Relay operates when an alarm occurs in a protective function assigned Alarm1, Alarm1&2, Alarm1&3, or
Alarm1,2&3 alarm action. Fail-safe or non-fail-safe mode selection is active.
Relay operates when an alarm occurs in a protective function assigned Alarm2, Alarm1&2, Alarm2&3, or
Alarm1,2&3 alarm action. Fail-safe or non-fail-safe mode selection is active.
Relay operates when an alarm occurs in a protective function assigned Alarm3, Alarm1&3, Alarm2&3, or
Alarm1,2&3 alarm action. Fail-safe or non-fail-safe mode selection is active.
Relay is energized when current is detected.
Relay is energized when in run mode. (Current <125% FLA for Run-Mode Delay).
Relay is energized when in an I2t or starts-per-hour inhibit condition.
Trip 1 energizes relay for the time duration specified by the RY Pulse Time set point.
Relay is energized by a network “Run1 Set” command and de-energized by a “Run1 Clear” command.
Relay is energized when the MPU-32 is operating properly.
Relay is energized when in reduced overcurrent mode (ROC = On).
No Assignment
Assign this function to only one relay. Non-fail-safe operation only.
The default assignment for Relay 1 is Trip1, for Relay
2 is Alarm1, and for Relay 3 is None. This assignment is
compatible with the MPU-16A Motor Protection Unit.
The default mode setting for all three relays is Fail-Safe.
4.2.5 DIGITAL INPUT
Menu: Setup | Digital Input | Input Function
Menu: Setup | Digital Input | Start Bypass
Menu: Setup | Digital Input | Bypass Delay
Menu: Setup | Digital Input | Trip Delay
The digital input can be assigned to one of the
functions listed in Table 4.3.
TABLE 4.3 DIGITAL-INPUT FUNCTIONS
FUNCTION
STATE (1)
Trip1
Reset
Program Enable(2)
Reduced OC
None
(1)
(2)
1 = No Trip1
0 = Trip1 (Delay Selectable, Reset
Required)
1 = Reset Trips
1 = Program Changes Allowed
0 = Program Changes Not Allowed
1 = Reduced Overcurrent Set Point Not
Operational (ROC = Off)
0 = Reduced Overcurrent Set Point
Operational (ROC = On)
No Assignment (Default)
1 = 24 Vdc applied, 0 = 24 Vdc not applied
Password is disabled.
When the digital input is assigned the Trip1 function,
Start Bypass, Bypass Delay, and Trip Delay set points
become active. When Start Bypass is enabled, the digital
input is bypassed during a start for the duration specified
by Bypass Delay. Start detection is based on motor
current. After the Bypass Delay, the digital input is
enabled and a trip occurs if the digital-input voltage is
removed for the time specified by the Trip Delay. If
Start Bypass is disabled, Bypass Delay is not used and
the digital input Trip1 function is always enabled. The
bypass feature can be used in pump-control applications
to allow time for a pressure switch to close.
When the digital input is assigned to Reset, trips can
be reset using an external reset switch. The Reset input
is a “one-shot” reset and requires a transition from open
to closed. Maintaining a reset switch closure does not
inhibit trips.
When assigned to Program Enable, password
protection is disabled and program access is a function of
the digital-input state as defined in Table 4.3. This
assignment mimics MPU-16A programming access.
The Reduced OC selection operates in conjunction
with the reduced-overcurrent set point which must be
enabled. See Section 5.5.
When Reduced OC is selected and no digital-input
voltage is applied, the reduced-overcurrent set point is
operational. When digital-input voltage is applied, the
reduced-overcurrent set point is not operational
4.2.6 ANALOG OUTPUT
Menu: Setup | Analog Output
The 20-mA analog output can be programmed for one
of the parameters shown in Table 4.4.
The analog output is factory calibrated for zero equals
4.0 mA and full scale equals 20.0 mA.
If adjustment is required, use the Analog Output
menus.
Operation and Setup
Page 4-4
Rev. 5-A-090514
MPU-32 Motor Protection Unit
PARAMETER
Phase Current
EF (Ict Measured)
EF (3I0 Calculated)
Used I2t
Local RTD
Mod Stator RTD
Mod Bearing RTD
Mod Load RTD
Mod Ambient RTD
Unbalance
Zero
Full Scale
Differential
Phase Current (FLA)
(1)
(2)
TABLE 4.4 ANALOG-OUTPUT PARAMETERS
DESCRIPTION
Maximum of the three phase currents.
Measured earth-leakage current from EF-CT.
Calculated earth-leakage current from phase CT’s.
Used thermal capacity.
Local RTD temperature.(1)
RTD module maximum stator temperature.(1,2)
RTD module maximum bearing temperature.(1,2)
RTD module maximum load temperature.(1,2)
RTD module maximum ambient temperature.(1,2)
Current unbalance (I2/I1).
Zero calibration.
Full-scale calibration.
Maximum phase-differential current.
Maximum of the three phase currents.
FULL SCALE
Phase-CT-Primary Rating
Earth-Fault-CT-Primary Rating
Phase-CT-Primary Rating
100% I2t
200C
200°C
200°C
200°C
200°C
1 Per Unit or 100%
Not Applicable
Not Applicable
Differential-CT-Primary Rating
125% FLA
The output defaults to the calibrated zero output for an open or shorted RTD sensor.
Requires optional MPS-RTD module.
Zero Calibration:
Select Zero in the Output Parameter menu.
Measure the output current and adjust the Zero
Calibrate setting for the desired output.
The
calibration number for 4 mA will be in the range of
150 to 250.
Full-Scale Calibration:
 Select Full Scale in the Output Parameter menu.
 Measure the output current and adjust the FS
Calibrate setting for the desired output.
The
calibration number for 20 mA will be in the range of
800 to 990.
Calibration numbers are not changed when factory
defaults are loaded, or during a firmware update.


4.2.7 MISCELLANEOUS CONFIGURATION
Menu: Setup | System Config
System Name
Appears on many of the display
screens and can be set by the user
(18-character alphanumeric field).
Password
Used to change the 4-character
alphanumeric password.
Clock Setting
Used to set the date and 24-hour
clock.
Password Timeout
Used to set the password time-out
delay. Delay is measured from last
key press.
Run Mode Delay
Run mode is entered when current
is between 5 and 125% FLA for the
specified time.
UPI LED
Used to assign an internal
parameter to the UPI LED.
Maintenance
Used to clear event records, trip
counters, and run hours.
Used to load defaults.
Used to view firmware version, unit
serial number, and MAC address.
Used for firmware updates.
4.2.8 COMMUNICATIONS
Menu: Setup | Hardware
The TIA-232 interface uses the Modbus RTU
protocol. Set the ID and baud rate to match the
requirements of the communications device. Default
settings are the same as SE-Comm-RIS PC-interface
software defaults.
If equipped with an optional network-communications
interface, refer to the appropriate communicationsinterface manual.
NOTE:
RS-232, EIA-232 and TIA-232
specifications are compatible with the MPU-32.
signal
4.3 METERING
Menu: Metering
When Metering is selected in the main menu, press the
right-arrow key to access a list of metering displays. Use
the up- and down-arrow keys to scroll through the display
list. Pressing the right-arrow key displays the selected
metering information.
RESET is a “hot key” that is active in all meter
displays. Pressing RESET causes a jump to the Trip and
Alarm display to allow trips to be viewed and reset.
Pressing ESC or the left-arrow key causes a return to the
Metering display.
Many displays include per unit (pu) values where
1.0 pu is equal to 100%. Ia, Ib, Ic, I1, and I2 are in per unit
of full-load current. 3I0 is in per unit of phase-CTprimary rating and Ict is in per unit of earth-fault-CTprimary rating.
The unbalance display indicates minus (-) if current
inputs are not sequenced A-B-C.
Table 4.5 shows the information that can be displayed
in each metering display.
Operation and Setup
Page 4-5
Rev. 5-A-090514
MPU-32 Motor Protection Unit
TABLE 4.5 METERING DISPLAY
METERING MENU
INFORMATION DISPLAY (1)
Current
Unbalance
Earth Leakage
Thermal Capacity
Differential
RTD Module
Temperatures
Local Sensor
I/O Status
System Status
Network Status
Ia, Ib, Ic in A and per unit of Ip.
I1, I2, in per unit of Ip, I2/I1 in per unit.
Ict in A and per unit of Ip, 3I0 in A and
per unit of Ie.
Displays which earth-leakage-protection
input is active.
Used I2t in Percent
Trend I2t in Percent
Displays reset time when tripped on I2t.
Displays time to trip if in overload.
Displays time to I2t Inhibit removal.
Displays time to Starts-Per-Hour Inhibit
removal.
Displays number of available starts.
DIFa, DIFb, DiFc in A and per unit of Id.
Summary shows maximum and minimum
temperatures for stator, bearing, and load
RTD’s in C.
Module and input numbers, name,
function, termperature in C for each
enabled RTD.
Sensor Type: RTD or PTC.
Displays temperature in C when type is
RTD.
Displays Open or Short RTD failure.
Displays sensor status (Normal, Open,
Short) when type is PTC.
Digital input On or Off and relay
outputs in binary.
Date and time, motor mode (Stopped,
Start, Run).
Displays Reduced Overcurrent mode
(ROC: On, ROC: Off).
Displays ETR mode.
Displays Modbus state as online or
timed out.
Displays DeviceNet errors and status.
(1)
All but RTD Module metering displays show System
Name.
4.4 MESSAGES
Menu: Messages
Selecting Messages allows trip, alarm, and inhibit
messages, event records, and statistical data to be viewed
and resets to be performed.
4.4.1 TRIP RESET
Menu: Messages | Trip and Alarm
Up to fifteen trip and alarm messages can be displayed
in a scrollable-list format. Trips must be individually
selected and reset if the RESET key is used. All trips are
simultaneously reset by a digital-input reset or with a
communications-network command. Alarms are nonlatching and are displayed only for the time that the alarm
condition exists.
RESET is a “hot key” to the Trip and Alarm display,
except during set-point entry. In the Trip and Alarm
display, pressing ESC or the left-arrow key causes a
return to the display shown when RESET was pressed.
4.4.2 DATA LOGGING
Menu: Messages | Event Records
Trip-record data, start-record data, and Emergency
Thermal Resets (ETR) are logged. Trip-record data
includes the time of trip, cause of trip, and pre-trip data.
ETR records contain a snapshot of the data prior to an
ETR.
Trip- or ETR-records data include:
 Time Stamp YY/MM/DD HH:MM:SS,
 Ia, Ib, Ic, and Ig(1) at time of trip or ETR,
 Differential currents at time of trip or ETR,
 Unbalance (I2/I1) at time of trip or ETR,
 I2t at time of trip or ETR, and
 PTC/RTD temperature data if applicable.
Start records(2) are triggered by motor current and include:
 Time Stamp YY/MM/DD HH:MM:SS,
 maximum values of Ia, Ib, Ic, and Ig(1) during the start,
 maximum value of I2/I1 during the start(4),
 maximum values of differential currents during the
start,
 I2t used during the start(3),
 start duration, and
 PTC/RTD temperature data if applicable.
Each record includes a record number in the first line of
the record-data display.
The record number is
incremented when a new record is generated and has a
range from 0 to 65535. When the Event Record menu is
entered, the first record displayed is the latest record. The
right-arrow key scrolls through previous records. Record
scrolling stops when the 100th record has been reached or
an empty record is displayed.
Event records can be cleared in the Setup  System
Config  Maintenance menu.
Record Type .............................. Trip/ETR/Start
Number of Records ................... 100 (First In First Out)
(1)
(2)
(3)
(4)
Ig is calculated from phase-current data, when
EF Source is set to Calculated (3I0) and is the
measured EF-CT current when EF Source is set to
Measured (Ict).
Values updated at 0.5-s intervals during a start and
stored when the Run mode is entered.
Starting I2t can be used to determine the I2t Inhibit
Level. See Section 5.2.
Measurement enabled 0.5 s after start current is
detected.
Operation and Setup
Page 4-6
Rev. 5-A-090514
MPU-32 Motor Protection Unit
4.4.3 STATISTICAL DATA
Menu: Messages | Statistics
The MPU-32 records the following statistical data:
 Running hours,
 Counters for each trip type.
Statistical data can be cleared in the Setup | System
Config | Maintenance menu.
4.4.4 EMERGENCY THERMAL RESET
Menu: Messages | Emerg I2t Reset
The Emerg I2t Reset menu is used to set Used I2t to
zero. See Section 5.2.3.
4.5 PASSWORD ENTRY AND PROGRAMMING
Menu: Setup | System Config  Password Timeout
NOTE: The default password is 1111. When the digital
input is programmed for Program Enable, set-point access
via the menu system is controlled by the digital input state
and not by the password. Set points can always be
changed using communications and the password.
When password access is active, all set points are
locked from changes until the four-character password is
entered. If set-point access is locked, the user is prompted
to enter the password. Once entered, set-point access is
allowed and remains enabled until a key has not been
pressed for the time defined by the Password Timeout set
point.
Set points are selected either by entering alphanumeric
characters or by choosing from a list.
When the correct password is entered, a flashing cursor
is displayed, the set-point range and units are shown, and
the set point can be changed.
LR CURRENT
= 6.75 x FLA
(1.00 ¼ 10.00 x FLA)
[0005.25]
Use the up- and down-arrow keys to change a set-point
update-field character, and use the left- and right-arrow
keys to move between characters. Press ENTER to
update the set point, or press ESC to exit the display
without changing the set point. A set point is set to the
minimum or maximum value of its range if an out-ofrange value is entered. Press ESC to exit the set-pointupdate screen.
The sequence for set-point characters depends upon the
set-point type. The character sequence for numeric set
points is:
...0123456789.0123.....
The character sequence for string set points is:
. . . [0…9] [A…Z] [a…z] SP - . / [0…9] [A…Z] . . . . .
Characters forming a series are shown in brackets and
“SP” represents the space character.
For set points requiring selection from a list, the upand down-arrow keys are used to scroll through the items.
In the same manner as menu items, selections are
displayed using one of the three cursor symbols (½ « ²)
preceding the item. Pressing ENTER selects the item.
The selected item is indicated by the “” symbol to its
right.
EXAMPLE:
EXAMPLE:
Prior to password entry:
LR CURRENT
= 6.75 x FLA
Locked!Press ª To
Enter Password.
Press ENTER. The Password Entry display is shown:
PASSWORD ENTRY
Enter Password
And Press ª
[****]
Use the left- and right-arrow keys to select the position
of the flashing cursor. Use the up- and down-arrow keys
to select password characters. Press ENTER.
JAM TRIP ACTION
Disabled
²Trip 1
Trip 2
*
4.6 MPS-RTD
Menu: Setup | Hardware | RTD Modules
Menu: Setup | Protection | RTD Temperature
The MPS-RTD module extends MPU-32 protective
functions to include multiple-RTD temperature
monitoring. It has eight inputs that can be individually
configured for RTD type, trip and alarm settings, name,
and function. The RTD types are 10- copper, 100-
nickel, 120- nickel, and 100- platinum. Functions are
stator, bearing, load, and ambient.
Control voltage for the MPS-RTD (24 Vdc) is supplied
by the MPU-32 and communication is through a TIA-485
link. This allows the MPS-RTD to be mounted up to
1.2 km (4,000’) from the MPU-32.
Operation and Setup
MPU-32 Motor Protection Unit
Page 4-7
Rev. 5-A-090514
To enable RTD protection, the total number of modules
must be selected in the Total Modules menu. Up to three
modules can be used. In the RTD Modules menu, the
action to be taken by the MPU-32 in response to loss of
communication is selected.
When the hardware has been configured, temperature
set points in the RTD Temperature menu are used for
RTD temperature protection. See Section 5.16.
4.7 MPS-DIF
Menu: Setup | Hardware | DIF Module
Menu: Setup | Protection | Differential
The MPS-DIF Differential module extends MPU-32
protection functions to include phase-differential
monitoring. It has three differential-CT inputs that can be
used in a three-CT core-balance connection, a sixdifferential-CT connection, or a six-CT connection that
includes MPU-32 phase-CT inputs. The core-balance
three-CT connection is recommended.
Control voltage for the MPS-DIF (24 Vdc) is supplied
by the MPU-32 and communication is through an RS-485
link. This allows the MPS-DIF to be mounted up to
1.2 km (4,000’) from the MPU-32, and the link can be
shared by other MPU-32 I/O modules.
Enable the module and loss-of-communications
protection in the Hardware | Dif Module menu, and
choose protection settings in the Protection | Differential
menu. See Section 5.12.
Operation and Setup
MPU-32 Motor Protection Unit
Page 4-8
Rev. 5-A-090514
This page intentionally left blank.
Operation and Setup
Page 5-1
Rev. 5-A-090514
MPU-32 Motor Protection Unit
5. PROTECTIVE FUNCTIONS
5.1 GENERAL
The MPU-32 measures true RMS, peak, and
fundamental-frequency values of current. Fundamentalfrequency values (magnitude and phase angle) are
obtained using Discrete-Fourier Transform (DFT)
filtering that rejects dc and harmonics. The type of
measurement used for a protective function is indicated in
each section.
Unless otherwise indicated, protective functions have a
programmable definite-time characteristic.
Each
protective function can be assigned a trip action that
defines the output contact(s) used. Except for overload
protection which has auto-reset available, MPU-32 trips
are latched. Trip actions are logged.








Trip-action selections are:
Disable
Trip1
Trip2
Trip3
Trip1 and Trip2
Trip1 and Trip3
Trip1 and Trip2 and Trip3
Trip2 and Trip3
Most protection functions can be assigned an alarm
action. Alarm actions are auto-reset and are not logged.








Alarm-action selections are:
Disable
Alarm1
Alarm2
Alarm3
Alarm1 and Alarm2
Alarm1 and Alarm3
Alarm1 and Alarm2 and Alarm3
Alarm2 and Alarm3
To operate output contacts, trip and alarm actions must
be assigned to output relays using the Setup  Relay
Outputs menu. See Section 4.2.4.
When enabled, Jam and Undercurrent protection are
not active during a start and are active in the Run mode.
The Run mode is initiated when motor current is between
5 and 125% FLA for the duration of Run-Mode Delay.
NOTE: See Appendix B for default set-point values.
Per-unit notation (pu) is used. 1 pu = 100%.
5.2 OVERLOAD
5.2.1 THERMAL MODEL
Menu: Setup | Protection | Overload
Menu: Setup | System Ratings
A NEMA- or K-factor-based thermal-model algorithm
can be selected.
The NEMA-based algorithm uses the square of the
maximum RMS phase current as the thermal-model input:
I 2  I max rms
2
I in per unit
The K-factor-based algorithm uses a thermal-model
input based on true positive- and negative-sequence
component values:
I 2  I12  kI 2
2
I in per unit
Where :
I1  positive sequence current
I 2  negative sequence current
k  factor relating the heat produced by I 2 relative to I1
A conservative value for k is:
k
230
IL
2
Where :
locked rotor current
IL 
full load current
The thermal time constant () used by the thermal
model to provide starting and running I2t protection is:
TC
 sf 2 
 ln1  2 
IL 

Where :
TC  cold locked rotor time in seconds

sf  service factor in per unit
When the motor is stopped, the thermal model uses a
time constant that is user selectable as a multiple (Cooling
Factor) of the thermal time constant.
The cold-curve time-to-trip (t) for current above
FLA  sf is:
 sf 2 
t   ln1  2   
I 

The MPU-32 provides indication of thermal trend and
used thermal capacity. Thermal trend is the value that
used thermal capacity is tending toward and it is a
function of the square of motor current. For currents
Protective Functions
MPU-32 Motor Protection Unit
greater than or equal to FLA  sf, time-to-trip is displayed
in Metering | Thermal Capacity. The thermal trend value
(Trend I2t) is:
 I2 
Trend I 2t   2   100%
 sf 
For currents less than FLA  sf, the thermal trend value
is:
 I 2   T  TH 
  100%
Trend I 2t   2    C

 sf   TC 
Where :
TH  hot locked rotor time in seconds
The curve shown in Fig. 5.1 is a Class-20 thermalprotection curve (20-s trip @ 600% FLA) with a service
factor of 1.15. FLA multiplied by service factor is the
current at which used thermal capacity begins to tend
towards a trip. Time-to-trip approaches infinity when
I = FLA  sf. Service factor has little influence on timeto-trip when motor current is greater than 300% FLA.
MPU-32 thermal-overload protection is dynamic.
Time to trip at any overload current depends on the value
of Used I2tas Used I2t increases, time to trip decreases.
This is illustrated in Fig. 5.1 by the protection curves
labeled 25% Used I2t, 50% Used I2t, and 75% Used I2t.
An overload alarm occurs when Used I2t reaches the I2t
Alarm Level set point.
An overload trip occurs when Used I2t reaches 100%.
When an overload trip occurs, reset is not allowed until
Used I2t falls below the I2t Inhibit Level set point. The
time-to-reset in minutes is:
t = -  Cooling Factor  ln(I2t Inhibit Level)/60
Time-to-reset is displayed in the Metering  Thermal
Capacity menu.The thermal model has three reset modes;
Normal, Auto, and Multiple Motor Seq. The thermal
overload reset mode is set using the Setup  Protection 
Overload  I2t Reset Type menu.
In the Normal mode, a thermal-overload trip reset is not
allowed until Used I2t falls below the I2t Inhibit Level
setting. A manual reset is required to reset the trip.
Normal is the default reset mode.
In the Auto mode, a thermal-overload trip is
automatically reset when Used I2t falls below the I2t
Inhibit Level setting.
CAUTION:
If the starter circuit is configured for 2-wire control, the
motor can start without warning when Auto mode is
selected. A warning label may be required.
Page 5-2
Rev. 5-A-090514
In the Multiple Motor Seq. mode, Used I2t decreases
exponentially with a fixed two-second time constant when
there is no motor current. This mode is used in
applications where one overload relay is used to protect
several motors operating in sequence with only one motor
running at any one time. A two-second stop is required
between starts so that Used I2t decreases sufficiently to
allow the next motor to start. It is assumed that each
motor is allowed to cool between starts. Motor life may
be decreased if this feature is used in single-motor
applications.
When I2t Inhibit is enabled, the I2t Inhibit Level set
point can be used to prevent a start with insufficient I2t
available. Both trip and alarm selections are provided.
When Used I2t is above the I2t Inhibit Level set point and
motor current is not detected, a trip or alarm is issued and
the relay assigned to Start Inhibit is energized. The time
until a start is permitted is displayed in Metering |
Thermal Capacity, and I2t Inhibit Alarm is displayed in
the Trip and Alarm message window. When Used I2t
falls below the I2t Inhibit Level set point or when current
is detected the relay assigned to Start Inhibit is
de-energized, and the inhibit alarm is cancelled. Trips
require a manual reset unless the reset type is set to auto.
The Start-Inhibit relay is shared with the Starts-Per-Hour
function. See Section 5.13.
If the motor is equipped with RTD sensors, the thermal
model can compensate for high ambient temperature and
loss of ventilation. See Section 5.17.
I2t used during each start is recorded in Messages 
Event Records.
This information can be used to
determine the I2t Inhibit Level set point to ensure
sufficient I2t is available to complete a start, and to
minimize thermal-overload-reset time.
FLA Rating .......................... 1.00 to 5,000.00 A
Service Factor ...................... 1.00 to 1.25
Locked-Rotor Current .......... 1.50 to 10.00 x FLA
Hot Locked-Rotor Time ....... 0.10 to 100.00 s
Cold Locked-Rotor Time ..... 0.10 to 100.00 s
Cooling Factor ..................... 0.10 to 10.00
Model Type: ......................... NEMA, K-Factor
I2t Reset Type ....................... Normal, Auto,
Multiple Motor Sequence
K-Factor ............................... 1.00 to 10.00
I2t Trip .................................. 1.00 pu
I2t Alarm............................... 0.50 to 1.00 pu
I2t Inhibit Level .................... 0.10 to 0.90 pu
I2t Inhibit .............................. Enable/Disable Trip1, 2, 3
Enable/Disable Alarm1, 2, 3
Protection ............................. Enable/Disable Trip1, 2, 3
Enable/Disable Alarm1, 2, 3
Measurement Method .......... DFT or RMS
Protective Functions
Page 5-3
Rev. 5-A-090514
MPU-32 Motor Protection Unit
10000
8000
6000
5000
4000
3000
SERVICE FACTOR 1.00 TO 1.25
SHOWN AT 1.15
2000
1000
800
600
500
400
300
TIME-TO-TRIP (SECONDS)
200
TIME-TO-TRIP DECREASES
AS USED I2T INCREASES
100
80
60
50
40
30
0% USED I2t (cold)
20
25% USED I2t
50% USED I2t
75% USED I2t
10
8
6
5
4
3
2
1
0.8
0.6
0.5
0.4
0.3
0.2
0.1
0
100
200
300
400
500
600
700
800
900
1000
1100
1200
1300
1400
1500
MOTOR CURRENT (%FLA)
FIGURE 5.1 Class-20 Overload Curve.
Protective Functions
Page 5-4
Rev. 5-A-090514
MPU-32 Motor Protection Unit
5.2.2 LOCKED-ROTOR TIMES
In all cases, values for TH and TC should be obtained
from the motor manufacturer.
The following
information is provided to assist in selecting values for
TH and TC only if manufacturer data is not available.
Heater-style overload elements are available as Class
10, Class 20, or Class 30. Class 20 is recommended for
general applications, Class 10 is used for motors with
short locked-rotor time capability, and Class 30 is used
in high-inertia applications to allow additional
accelerating time where motors are within Class-30
performance requirements. These overloads can be
replicated by setting TC = 10, 20, or 30 s; TH = 0.1 s; and
Locked-Rotor Current = 6.00 x FLA.
An induction motor built to the NEMA MG 1 standard
is capable of
 two starts in succession (coasting to rest between
starts) with the motor initially at ambient temperature
(cold start), and
 one start with the motor initially at a temperature not
exceeding its rated-load operating temperature (hot
start).
Since the connected load has a direct influence on
motor heating during a start, NEMA MG 1 defines the
load torque and the load inertia (Wk2) for these starts as a
function of the motor’s rated power and synchronous
speed. To satisfy the cold-start requirement, a start must
not use more than 50% thermal capacity. To satisfy the
hot-start requirement, used thermal capacity at steady
state must be less than 50%.
If the thermal model in the MPU-32 has the correct
value of TC and if Used I2t increases by 50% during a
start, the load is equal to the NEMA-defined load and
two starts from cold will be permitted. If Used I2t
increases by more than 50% during a start, the load is
greater than the NEMA-defined load and two starts from
cold should not be permitted — a delay is required
between starts. The appropriate delay can be obtained by
enabling I2t Start Inhibit and setting the I2t Inhibit Level
equal to 100% minus the I2t used during a start (a slightly
lower level is recommended to allow for supply and load
variations). If Used I2t increases by less than 50% during
a start, the load is less than the NEMA-defined load and
two starts from cold will be permitted.
The magnitude of TH relative to TC determines if a hot
start will be permitted if I2t Start Inhibit is enabled and
the I2t Inhibit Level is set as described above. If Used I2t
increases by 50% or less during a start, a hot start will be
permitted if TH is equal to or greater than 50% of TC.
Increasing TH above 50% of TC is not recommended
unless specific information is available with respect to TH.
5.2.3 EMERGENCY THERMAL RESET
Menu: Messages | Emerg I2t Reset  Reset I2t Memory
Emergency Thermal Reset (ETR) sets Used I2t to 0%,
resets starts-per-hour variables, and disables PTC and
RTD temperature trips. Program access is required.
Disabled-temperature protection is indicated by
t Disabled by ETR in the System State display. If PTC
or RTD temperature protection is not enabled, t
Disabled by ETR will not be displayed. Stator RTD or
PTC trips are reset when ETR is performed regardless of
measured temperatures. Temperature protection must be
re-enabled in the Messages  Emerg I2t Reset  Reenable
Temp menu, or by cycling supply voltage. Disabledtemperature protection can be assigned to the userprogrammable indication LED. See Section 4.1.1
Temperature alarms and sensor verification remain
enabled during ETR.
CAUTION: Temperature protection is not automatically
re-enabled after an Emergency Thermal Reset.
5.3 OVERCURRENT
Menu: Setup | Protection | Overcurrent
Overcurrent protection is based on the largest
fundamental-frequency component (DFT) of the three
phase currents. An alarm-level setting is not provided.
When enabled, overcurrent protection is active at all
times  it is not bypassed during a start.
Fault duration required for a trip is a function of the
Trip Time setting and the fault level. Table 5.1 shows
the required fault duration for three fault-level values.
TABLE 5.1 FAULT DURATION REQUIRED FOR TRIP OR
ALARM
(1)
FAULT DURATION (2)
FAULT LEVEL
(1)
(2)
(multiples of triplevel setting)
(ms)
TD  30 ms
TD > 30 ms
2
5
10
10
5
2
TD – 20
TD – 25
TD – 28
For overcurrent less than 15 x CT-Primary Rating.
For earth faults less than 1 x EF-CT-Primary Rating.
Fixed frequency, 60 Hz.
The asymmetrical-current multipliers for RMS and
DFT measuring methods are shown in Fig. 5.2. To
prevent false overcurrent trips during starting, the Trip
Level setting must be above the product of locked-rotor
current and the multiplier. Typical X/R values are
6.6 for a low-voltage system, 15 for a medium-voltage
system, and can be as high as 25 for a high-voltage
system. The DFT filters the dc component so that the
overcurrent setting can be set closer to the symmetrical
fault value.
Protective Functions
MPU-32 Motor Protection Unit
ASYMMETRICAL MULTIPLYING FACTOR
1.8
1.7
RMS
1.6
1.5
1.4
1.3
1.2
DFT
1.1
1.0
0
2
4
6
8
10
12
14
16
18
20
X/R
FIGURE 5.2 Asymmetrical-Current Multipliers.
Trip Level ............................. 1.00 to 15.00  CT-Primary
Rating (Ip)
Trip Delay (TD) ................... 0.00 to 10.00 s
Trip Time ............................. (TD + 35 ms)  10 ms
See Table 5.1
Protection ............................. Enable/Disable Trip1, 2, 3
Measurement Method ........... DFT with CT-saturation
compensation
5.4 AUXILIARY OVERCURRENT
Menu: Setup | Protection | Aux Overcurrent
Auxiliary overcurrent provides an additional definitetime overcurrent element for the protection curve. It can
also be used to trip an up-stream device when backup
protection for the overcurrent function is required.
Setting ranges are the same as the overcurrent
function.
Trip Level ............................ 1.00 to 15.00  CT-Primary
Rating (Ip)
Trip Delay (TD) .................. 0.00 to 10.00 s
Trip Time ............................. (TD + 35 ms)  10 ms
See Table 5.1
Protection ............................ Enable/Disable Trip1, 2, 3
Measurement Method .......... DFT with CT-saturation
compensation
5.5 REDUCED OVERCURRENT
Menu: Setup | Protection | Reduced OC
Reduced overcurrent is used to reduce the overcurrent
set point when performing maintenance in a motor
circuit when the motor is running.
Reduced overcurrent is controlled by the digital input
assigned to Reduced OC. When the digital-input voltage
is not applied, this set point is operational and when the
digital input voltage is applied, this set point is not
operational. When reduced overcurrent is selected,
ROC:On is displayed in the Metering  System Status
menu, the relay assigned to Reduced OC will be
energized, and if assigned, the UPI LED will be on.
Page 5-5
Rev. 5-A-090514
The trip level should be set just above the full-load
current of the motor. To avoid trips on starting
Reduced OC should not be selected until the motor is
running.
The Protection selection must include Trip1, Trip2, or
Trip3. If Disable is selected, reduced overcurrent mode
is disabled.
Trip Level ............................. 1.00 to 15.00  CT-Primary
Rating (Ip)
Trip Delay ............................. Fixed at 0.00 (Instantaneous)
See Table 5.1
Protection .............................. Enable/Disable Trip1, 2, 3
5.6 JAM
Menu: Setup | Protection | Jam
A trip or alarm occurs if a jam condition is detected.
Jam protection is active when the motor is in the Run
mode, allowing protection to be set below motor-starting
current.
Trip Level ............................. 1.00 to 10.00  FLA
Trip Delay ............................. 1.00 to 100.00 s
Alarm Level .......................... 1.00 to 10.00  FLA
Alarm Delay ......................... 1.00 to 100.00 s
Protection .............................. Enable/Disable Trip1, 2, 3
Enable/Disable Alarm1, 2, 3
Measurement Method ........... DFT
5.7 EARTH FAULT
Menu: Setup | Protection | Earth Fault
Menu: Setup | System Ratings
The EF Source menu selects the earth-fault source as
Calculated (3I0) or Measured (Ict). The Calculated (3I0)
selection uses the 3I0 value obtained from the sequencecomponent calculation and is based on phase currents
only; an earth-fault CT is not required.
The
Measured (Ict) selection uses the CT input and should be
selected when an earth-fault-CT or the residual-CT
connection is used.
For the Calculated (3I0) selection and for the residual
connection, Ie corresponds to the CT-Primary Rating.
For the Measured (Ict) selection, Ie corresponds to the
EF-CT Primary Rating.
NOTE: Calculated 3I0 does not detect CT saturation.
Enable overcurrent protection when earth-fault current
can exceed 18 times the phase-CT primary rating.
Protective Functions
MPU-32 Motor Protection Unit
Trip Level ............................. 0.01 to 1.00  Earth-FaultCT-Primary Rating (Ie)
Trip Delay (TD) ................... 0.00 to 100.00 s
Trip Time ............................. (TD + 35 ms) ± 10 ms
See Table 5.1
Alarm Level ......................... 0.01 to 1.00  Ie
Alarm Delay ......................... 0.00 to 100.00 s
Alarm Time .......................... (TD + 35 ms) ± 10 ms
See Table 5.1
Protection ............................ Enable/Disable Trip1, 2, 3
Enable/Disable Alarm1, 2, 3
Measurement Method ........... DFT
Ie is 5 A for EFCT-1, EFCT-2 or EFCT-26.
5.8 CURRENT UNBALANCE
Menu: Setup | Protection | Unbalance
Positive-sequence current (I1) and negative-sequence
current (I2) are used to determine current unbalance
(I2/I1). The unbalance display range is 0.00 to 1.00
where 1.00 is 100% unbalancea single-phase
condition. Negative unbalance will be indicated if
current inputs are connected B-A-C. Severe unbalance
may be indicated if phase-CT polarity is incorrect.
Trip Level ............................. 0.05 to 1.00
Trip Delay ............................ 1.00 to 100.00 s
Alarm Level ......................... 0.05 to 1.00
Alarm Delay ......................... 1.00 to 100.00 s
Protection ............................. Enable/Disable Trip1, 2, 3
Enable/Disable Alarm1, 2, 3
Measurement Method ........... DFT
5.9 PHASE LOSS
Menu: Setup | Protection | Phase Loss
Phase loss is a severe form of unbalance. When phase
loss occurs, negative-sequence current (I2) is equal to
positive-sequence current (I1) and current unbalance is
100% or 1.00 pu. The phase-loss algorithm considers
I2/I1 from 0.90 to 1.00 to be a phase loss. Set the phaseloss trip delay lower than the unbalance trip delay to
avoid an unbalance trip in the event of a phase loss.
NOTE: Disconnecting a phase CT does not cause a phase
loss because proper rotation is still observed on the two
other phases.
Trip Delay ............................ 1.00 to 100.00 s
Alarm Delay ......................... 1.00 to 100.00 s
Protection ............................. Enable/Disable Trip1, 2, 3
Enable/Disable Alarm1, 2, 3
Measurement Method ........... DFT
Page 5-6
Rev. 5-A-090514
5.10 PHASE REVERSE
Menu: Setup | Protection | Phase Rev
If the current phase sequence is B-A-C, the magnitude
of negative-sequence current will be larger than the
magnitude of positive-sequence current.
Trip Delay ............................. 1.00 to 100.00 s
Alarm Delay ......................... 1.00 to 100.00 s
Protection .............................. Enable/Disable Trip1, 2, 3
Enable/Disable Alarm 1, 2, 3
Measurement Method ........... DFT
5.11 UNDERCURRENT
Menu: Setup | Protection | Undercurrent
Undercurrent protection is loss-of-load protection and
is active when the motor is in the Run mode. A trip or
alarm is initiated if current remains below the set point
for the programmed delay.
Trip Level ............................. 0.10 to 1.00 x FLA
Trip Delay ............................. 1.00 to 100.00 s
Alarm Level .......................... 0.10 to 1.00 x FLA
Alarm Delay ......................... 1.00 to 100.00 s
Protection .............................. Enable/Disable Trip1, 2, 3
Enable/Disable Alarm1, 2, 3
Measurement Method ........... DFT
5.12 DIFFERENTIAL CURRENT PROTECTION
Menu: Setup  Protection  Differential
Menu: Setup  Hardware  DIF Module
Menu: Setup  System Ratings  DF-CT Primary
The MPS-DIF provides three-phase differential
protection. It is intended to be used specifically for
motor protection and not intended for feeder or
transformer differential protection.
Enable the module and communications-loss protection
using the Setup  Hardware  DIF Module menu. The
module uses I/O module communications and both trip
and alarm actions are available in the event of
communications loss.
Set DF-CT Primary equal to the differential-CTprimary rating. For the MPU-summation connection,
phase-CT Primary must be equal to DF-CT Primary.
Trip and alarm settings are based on multiples of the
DF-CT Primary rating (Id).
Trip Level ............................. 0.10 to 15.00 x Id
Trip Delay ............................. 0.00 to 10.00 s
Alarm Level .......................... 0.10 to 15.00 x Id
Alarm Delay ......................... 0.00 to 10.00 s
Protection .............................. Enable/Disable Trip1, 2, 3
Enable/Disable Alarm1, 2, 3
Measurement Method .......... DFT c/w CT-saturation
compensation.
Protective Functions
Page 5-7
Rev. 5-A-090514
MPU-32 Motor Protection Unit
5.13 STARTS PER HOUR / TIME BETWEEN STARTS
Menu: Setup | Protection | Starts Per Hour
Starts-Per-Hour and Time-Between-Starts are useful
limits in a protective relay that incorrectly responds to
current below FLA. If the relay’s thermal model
accurately tracks a motor’s used thermal capacity under
all conditions, Starts-Per-Hour and Time-Between-Starts
are features that provide no additional protection. The
MPU-32 does not require these features to provide
protection, but they are included to satisfy protection
strategies designed for protective relays without dynamic
thermal modeling.
The Starts-Per-Hour feature ensures that the
programmed number of starts per hour is not exceeded
and the Time-Between-Starts feature ensures that the
programmed time has elapsed between starts. The
available number of starts and time between starts is also
a function of the thermal model’s Used I2t value.
Consequently, the number of starts may be less than the
starts-per-hour value and the time between starts may be
longer than the set-point value.
The number of starts and time between starts is
checked when the motor is stopped. A Starts/Hour Trip
or Starts/Hour Alarm is issued if a start will exceed the
# Starts Per Hour setting or if the time since the
previous start is less than the Time Between setting.
When a Starts/Hour Trip or Starts/Hour Alarm is
issued, the output relay assigned to Start Inhibit is
energized. The Start Inhibit relay is non-latching and
can be used as a start permissive. A Starts/Hour Trip
will remain latched until a reset is issued. The Start
Inhibit relay is shared with the thermal model’s I2t
Inhibit feature.
If motor current is detected regardless of the alarm or
trip condition, the Starts/Hour Alarm is removed, and
Starts/Hour Trip can be reset. The starts-per-hour
algorithm remains active but any trips or alarms are
suppressed until the motor is stopped.
The status of Starts-Per-Hour and Time-BetweenStarts is displayed in the Metering | Thermal Capacity
menu. If there are no trips or alarms, the number of
available starts (Sph Available) is displayed and if a trip
or alarm is present, the inhibit time (Sph Inhibit) is
displayed. Since the Metering | Thermal Capacity menu
is also used to display the thermal model status,
messages are prioritized as follows:
 I2t Reset Time(1)
 I2t Trip Time(1)
 I2t Inhibit Time(1)
 Starts Per Hour Inhibit Time(3)
 Starts Available(2) (3)
An Emergency Thermal Reset (ETR) can be used to
initialize all thermal and starts-per-hour variables and to
reset a starts-per-hour trip. See Section 5.2.3.
Time Between Starts ......... 0.00 to 500.00 Minutes
Starts Per Hour(2) .............. 1 to 10
Protection .......................... Enable/Disable Trip 1, 2, 3
Enable/Disable Alarm 1, 2, 3
(1)
(2)
(3)
Calculated from thermal model data.
The display range for the number of available starts
is –9 to +10.
Initialized when supply voltage is cycled.
5.14 PTC TEMPERATURE (LOCAL)
Menu: Setup | Hardware | Local Temp Sensor
Menu: Setup | Protection | PTC Temperature
The local-temperature-sensor input is configured for a
positive-temperature-coefficient (PTC) thermistor sensor
using the Setup | Hardware | Local Temp Sensor menu.
The total resistance of series-connected PTC
thermistors must be less than 1,500  at 20°C. A trip or
alarm will occur when series resistance exceeds 2,800 .
During Emergency Thermal Reset, a PTC trip is reset
and PTC-temperature protection is disabled. See Section
5.2.3.
Protection .......................... Enable/Disable Trip1, 2, 3
Enable/Disable Alarm1, 2, 3
5.15 RTD TEMPERATURE (LOCAL)
Menu: Setup | Hardware | Local Temp Sensor
Menu: Setup | Protection | RTD Temperature
The local-temperature-sensor input is configured for a
Pt100 RTD sensor using the Setup | Hardware | Local
Temp Sensor menu.
Sensor verification is enabled using the Sensor Trip
Act and Sensor Alarm Act Action menus. When a sensor
failure is detected, the corresponding protection is
disabled.
During Emergency Thermal Reset, an RTD trip is
reset and RTD-temperature protection is disabled. See
Section 5.2.3.
Trip Range ........................ 40.00 to 200.00°C (104 to
392°F)
Alarm Range ..................... 40.00 to 200.00°C (104 to
392°F)
Display Range .................. -40.00 to 260.00°C (-40 to
500°F)
Sensor Verification ........... Enable/Disable Trip 1, 2, 3
Enable/Disable Alarm 1, 2, 3
Protection .......................... Enable/Disable Trip 1, 2, 3
Enable/Disable Alarm 1, 2, 3
Error Codes ....................... -100 = No Sensor
-90 = Open Sensor
-80 = Shorted Sensor
-70 = No Data/ Module Error
(Codes accessed via network
communications)
Protective Functions
Page 5-8
Rev. 5-A-090514
MPU-32 Motor Protection Unit
Trip Range ........................ 40.00 to 200.00°C (104 to
392°F)
Alarm Range ..................... 40.00 to 200.00°C (104 to
392°F)
Display Range .................. -40.00 to 260.00°C (-40 to
500°F)
Sensor Verification ........... Enable/Disable Trip 1, 2, 3
Enable/Disable Alarm 1, 2, 3
NOTE: RTD-module temperature trip and alarm actions
are fixed as Trip1 and Alarm1.
NOTE: Local and module-connected RTDs can be used
simultaneously.
5.17 HOT-MOTOR COMPENSATION
Menu: Setup | Protection | RTD Temperature
If hot-motor compensation (HMC) is enabled, the
maximum stator-RTD temperature is used to bias the
thermal model by increasing Used I2t when the RTD
temperature is greater than the thermal-model
temperature.
Two set points define the compensation. HMC Low is
the stator temperature where compensation begins at
0% I2t. HMC High is the stator temperature where
compensation ends at 100% I2t. See Fig. 5.3.
Both local and module RTD temperatures are used to
determine the maximum stator temperature for the HMC
calculation.
Although the bias calculation is based on 0% and
100% I2t values, the Used I2t adjustment is limited to
90% I2t. An actual overload condition is required to
cause a trip at 100% I2t.
100%
BIAS I2t
5.16 RTD TEMPERATURE (MPS-RTD MODULE)
Menu: Setup | Hardware | RTD Modules
Menu: Setup | Protection | RTD Temperature
Up to three MPS-RTD modules can be connected to
an MPU-32. Select the number of modules and enable
communications-loss protection in the Setup | Hardware |
RTD Modules menu. Each module can monitor eight
RTD’s. RTD type, function, name, and trip and alarm
set points are programmable for each RTD.
When an RTD type is selected, both Trip1 and Alarm1
functions are enabled.
Sensor verification is enabled using the Sensor Trip
Act and Sensor Alarm Act Action menus. When a sensor
failure is detected, the corresponding protection is
disabled.
During Emergency Thermal Reset, an RTD trip is
reset and RTD-temperature protection is disabled. See
Section 5.2.3.
Each module RTD can be assigned to one of eight
function groups; Stator, Bearing, Load, Ambient, Stator
Voting, Bearing Voting, Load Voting, and Ambient
Voting. The specific assignment is set using the Setup |
Protection | RTD Temperature | Module x | Function
menu. Regardless of the assigned function, individual
RTD trip and alarm setpoints remain active. Note that
the RTD trip action is fixed as Trip1.
When an RTD is assigned to a voting group, it
participates in the voting logic. Within a voting group,
two RTD’s must indicate a temperature above their trip
setpoint in order to cause a trip. The first two RTD’s that
indicate a high temperature will generate a Trip1.
Subsequent trips resulting from other RTD’s in the group
are not locked out. Trips must be individually reset and
all trips must be reset to allow a start.
Failed sensors do not participate in the RTD voting
logic. For example if six sensors are set to Stator Voting
and two sensors fail, only four participate in RTD voting.
When RTD voting is used, it is assumed that continuity
of service is of high importance. In this case it is
recommended to set the sensor-failure action to alarm
only or to set the trip action to a value other than Trip1.
If only one RTD is assigned to a group, or if only one
RTD is active because of sensor failures, RTD protection
is the same as the corresponding non-voting function.
RTD voting is not available for alarm setpoints.
RTD voting is contained within the specific function
group and within the RTD module. An RTD in one
module does not participate in the voting logic of another
module.
Name ................................ 18 Character, Alphanumeric
Type.................................. Disable, Pt100, Ni100, Ni120,
Cu10
Function............................ Stator, Bearing, Load,
Ambient, Stator Voting,
Bearing Voting, Load Voting,
Ambient Voting
0%
HMC LOW
HMC HIGH
RTD TEMPERATURE
FIGURE 5.3 Used I2t Bias Curve.
Protective Functions
MPU-32 Motor Protection Unit
Page 5-9
Rev. 5-A-090514
HMC Low ............................ 40.00 to 200.00°C (104 to
392°F)
HMC High ............................ 40.00 to 200.00°C (104 to
392°F)
Protection ............................. Enable/Disable
NOTE: Hot-motor compensation will not be active
unless the HMC Low set point is at least 10°C (50°F)
below the HMC High set point. RTD temperature will
not reduce Used I2t.
Protective Functions
MPU-32 Motor Protection Unit
Page 5-10
Rev. 5-A-090514
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Protective Functions
MPU-32 Motor Protection Unit
Page 6-1
Rev. 5-A-090514
6. THEORY OF OPERATION
6.1 SIGNAL-PROCESSING ALGORITHMS
The MPU-32 obtains thirty-two samples per cycle of
each current signal  the sampling frequency is 1.6 kHz
in 50-Hz applications and 1.92 kHz in 60-Hz applications.
If variable frequency is selected, the phase-A-current
signal controls the sampling frequency to obtain
thirty-two samples per cycle of each current signal.
A Discrete-Fourier-Transform (DFT) algorithm is used
to obtain the magnitudes and phase angles of the
fundamental-frequency components of the current
waveforms.
These values provide true positive-,
negative-, and zero-sequence components. True RMS
values of phase currents include up to the 16th harmonic.
Fundamental-frequency values are displayed.
Peak-to-peak currents are measured and compared to
DFT values to compensate for CT saturation.
6.2 RTD MODULE (MPS-RTD)
The RTD module contains a microprocessor, A/D
converter, and a multiplexer to measure up to eight
RTD’s. The RTD-measuring circuit is isolated from the
I/O Module network. All eight RTD’s are scanned every
three seconds. RTD linearization, open/short detection,
and lead compensation are performed by the RTD
module. RTD temperature is sent to the MPU-32 where
temperature monitoring occurs.
6.3 DIFFERENTIAL MODULE (MPS-DIF)
The differential module obtains 32 samples per cycle of
the differential currents. A Discrete-Fourier-Transform
(DFT) algorithm is used to obtain the magnitude of the
three differential currents. Frequency of operation is set
by the MPU-32 and allows differential protection to be
used in variable-frequency drive applications. The DFT
values are sent to the MPU-32 where differentialprotection is performed.
Theory of Operation
MPU-32 Motor Protection Unit
Page 6-2
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Theory of Operation
MPU-32 Motor Protection Unit
7. COMMUNICATIONS
7.1 PERSONAL-COMPUTER INTERFACE
7.1.1 FIRMWARE UPGRADE
The MPU-32 control program is stored in flash
memory. Field updates can be made through the TIA-232
communication interface located on the rear panel. The
following are required:
 A Windows PC, a TIA-232 interface, and the
SE-Flash program,
 a file containing the MPU-32 control program
(.s19 file),
 a CA-945 DB9 to RJ-45 adapter, and
 an SE-ICUSB232 USB to TIA-232 converter (if
TIA-232 port not available).
SE-Flash is available at www.littelfuse.com/
relayscontrols and accessories are available from
Littelfuse Startco.
7.1.2 SE-COMM-RIS
SE-Comm-RIS is a Windows-based program used to
access MPU-32 functions with a personal computer (PC)
via the TIA-232 or optional TIA-485 and Ethernet
interfaces. Use SE-Comm-RIS to program an MPU-32
either by changing individual set points or by
downloading set-point files. Existing MPU-32 set points
can be transferred to the PC. Metered values can be
viewed and the MPU-32 can be controlled with the
computer.
SE-Comm-RIS extends the event-record
storage capability of the MPU-32 by allowing the user to
transfer data to PC memory at a programmable interval.
Protection curve plotting capability is included.
SE-Comm-RIS is available at www.littelfuse.com/
relayscontrols.
7.2 NETWORK INTERFACE
For detailed information see Appendices to this manual
and applicable communications manuals.
7.2.1 TIA-485 OPTION
The TIA-485 communications option supports
Modbus RTU and Allen-Bradley DF1 half-duplex
protocols. All set points and meter values are accessible.
Commands are provided to perform trips, resets, and
remote relay control.
Modbus RTU function codes supported:
 Read Holding Registers (Code 3)
 Read Input Registers (Code 4)
 Write Single Register (Code 6)
 Write Multiple Registers (Code 16)
 Command Instruction (Code 5)
Page 7-1
Rev. 5-A-090514
DF1 Commands Supported:
 Unprotected Read (CMD = 01)
 Unprotected Write (CMD = 08)
 Typed Read (CMD = 0F, FNC = 68)
 Typed Write (CMD = 0F, FNC = 67)
 Typed Logical Read (CMD = 0F, FNC = A2)
 Typed Logical Write (CMD = 0F, FNC = AA)
NOTE: The MPU-32 and MPU-16A can be connected to
the same network; however, the MPU-32 register map is
not compatible with the MPU-16A.
7.2.2 DEVICENET OPTION
The DeviceNet communications option supports
Explicit Messaging and Polled I/O. All set points and
meter values are accessible using Explicit Messaging.
The Polled I/O connection supports the following ODVA
input assemblies:
 Basic Overload (50)
 Extended Overload (51)
 Basic Motor Starter (52)
 Extended Motor Starter (53)
In addition to the ODVA assemblies, a userconfigurable fixed block of 64 bytes is available.
The Polled I/O connection supports the following
ODVA output assemblies:
 Basic Overload (2)
 Basic Motor Starter (3)
An Electronic Data Sheet (EDS) file is provided for use
with DeviceNet configuration tools such as RSNetWorx
and DeltaV.
7.2.3 ETHERNET OPTION
The Ethernet option supports the Modbus TCP and
EtherNet/IP protocols.
Modbus TCP uses TCP/IP to encapsulate the Modbus
RTU protocol. Up to five simultaneous connections are
supported. In addition to the Modbus RTU function
codes listed in Section 7.2.1 the Read Device
Identification Code (43) is supported.
The MPU-32 supports up to nine simultaneous
connections over EtherNet/IP. Both Explicit and Polled
I/O are supported.
The Modbus TCP and EtherNet/IP protocols are
compatible with SE-Comm-RIS (version 3.91) and above.
See Section 7.1.2.
Personal Computer Interface
MPU-32 Motor Protection Unit
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Personal Computer Interface
MPU-32 Motor Protection Unit
8. TECHNICAL SPECIFICATIONS
8.1 MPU-32
See Appendix C for 1-A direct-input configuration.
Supply ...................................... 30 VA, 120-240 Vac
(+10, -45%), 50/60 Hz,
25 W, 110-250 Vdc
(+10, -25%)
Power-Up Time ........................ 800 ms at 120 Vac
Ride-Through Time .................. 100 ms minimum
24-Vdc Source (1) ...................... 400 mA maximum
AC Measurements:
Methods .............................. True RMS, DFT, Peak,
and positive- and
negative- sequence
components of the
fundamental.
Sample Rate ........................ 32 samples/cycle
Frequency:
Fixed ................................... 50 or 60 Hz
Variable .............................. 10 to 90 Hz
Accuracy .......................... 0.5 Hz
Phase-Current Measurement: (2)
Metering Range .................. 15 x CT-Primary Rating
(Ip)
Protection Range................. 80 x Ip
Metering Accuracy: (3,4)
I < Ip ................................. 2% Ip
I > Ip ................................. 2% Reading
Unbalance Accuracy ........... 0.02 pu
Earth-Leakage Measurement:
Range .................................. 1.5 x Earth-Fault-CTPrimary Rating (Ie)
Accuracy (3, 4) ...................... 2% Ie
PTC-Thermistor Input: (5)
Cold Resistance .................. 1,500  maximum at
20C (68F)
Trip Level ........................... 2,800  ± 200 
Reset Level ......................... 1,500   200 
Sensor Current .................... 1 mA maximum
RTD Input: (5)
RTD Type ........................... 3-wire Pt100
Range .................................. -40 to 260C (-40 to
500F) with open and
short detection
Sensor Current .................... 1 mA
Page 8-1
Rev. 5-A-090514
Lead Compensation ............ 25  maximum
Accuracy ............................ 2C (-40 to 200C, -40 to
392F)
5C (200 to 260C, 392 to
500F)
4-20 mA Analog Output:
Type.................................... Self powered and loop
powered
Range.................................. 4 to 22 mA
Update Time ....................... 250 ms
Loop Supply Voltage ......... 8 to 26 Vdc
Load.................................... 500  (maximum with
24 Vdc supply)
Isolation (1) .......................... 120 Vac with L/S switch
in L position
Timing Accuracies:(6)
Set Point  1 s..................... +5% (minimum
25 to 45 ms)
Set Point > 1 s .................... +2%
Relay Contacts:
Configuration ..................... N.O. and N.C. (Form C)
CSA/UL Contact Rating ..... 8 A resistive 250 Vac,
8 A resistive 30 Vdc
Supplemental Contact Ratings:
Make/Carry 0.2 s ............. 20 A
Break:
dc .................................. 50 W resistive, 25 W
inductive (L/R = 0.04)
ac................................... 2,000 VA resistive,
1,500 VA inductive
(PF = 0.4)
Subject to maximums of 8 A and 250 V (ac or dc).
Digital Input:
Range.................................. 12 to 36 Vdc, 5 mA at
24 Vdc
Guaranteed On.................... 12 Vdc at 2 mA
Guaranteed Off ................... 3 Vdc at 0.5 mA
Isolation .............................. 120 Vac, terminals 25 and
26
I/O Module Interface (MPS-RTD, MPS-DIF):
Module Supply ................... 24 Vdc, 400 mA
maximum
Configuration ..................... TIA-485, 2-wire multidrop
Isolation .............................. 120 Vac
Bus Length ......................... 1.2 km (4,000’) maximum
Cable .................................. Belden 3124A or
equivalent
Technical Specifications
Page 8-2
Rev. 5-A-090514
MPU-32 Motor Protection Unit
TIA-232 Communications:
Baud Rate ........................... 9.6, 19.2, 38.4 kbit/s
Protocol .............................. Modbus RTU
Address ............................... 1 to 255
Real-Time Clock:
Power-Off Operation .......... 6 Months at 20C (68F)
Battery ................................ Rechargable lithium (no
service required)
Non-Volatile RAM:
Power-Off Retention........... 10 Years
Dimensions:
Height ...................................96 mm (3.8”)
Width ....................................96 mm (3.8”)
Depth ....................................132 mm (5.2”)
Shipping Weight ....................... 2.0 kg (4.4 lb)
PWB Conformal Coating ......... MIL-1-46058 qualified
UL QMJU2 recognized
Environment:
Operating Temperature .........-40 to 60°C (-40 to
140°F) (7)
Storage Temperature .............-55 to 80°C (-67 to 176°F)
Humidity ............................. 85% Non-Condensing
Surge Withstand ....................... ANSI/IEEE C37.90.11989 (Oscillatory and
Fast Transient)
EMC Tests:
Verification tested in accordance with EN 60255-26:2005.
Radiated RF ........................ IEC 60255-22-3 1
0 V/m, 80-1,000 MHz,
80% AM (1 kHz) 10
V/m, 900 MHz, 200 Hz
Pulse Modulated
Conducted RF ..................... IEC 60255-22-6
10 V, 0.15-80 MHz,
80% AM (1 kHz)
Fast Transient...................... IEC 60255-22-4
Class A: 4 kV,
2.5 kHz rpf
Class B: 2 kV, 5 kHz rpf
1 MHz Burst........................ IEC 60255-22-1
1 kV differential mode
(line-to-line)
2.5 kV common mode
Surge Immunity .................. IEC 60255-22-5
0.5 & 1.0 kV differential
mode (line-to-line) 0.5,
1.0, & 2.0 kV common
mode
DC Voltage Interruption ..... IEC 60255-22-11
100% for 5, 10, 20, 50,
100, & 200 ms
interruption time on
AC/DC power ports.
Certification .............................. CSA, Canada and USA
To:
CSA C22.2 No. 14 Industrial Control Equipment
UL 508 Industrial Control Equipment
UL 1053 Ground Fault Sensing and Relaying
Equipment
Australia
N11659
CE, European Union
UL Recognized
Electrostatic Discharge ....... IEC 60255-22-2
6 kV Constant Discharge
8 kV Air Discharge
Power Frequency ................ IEC 60255-22-7
Class A: differential mode
150 Vrms @
100 /0.1 F, 300 Vrms
@ 220 /0.47 F
Class B: differential mode
100 Vrms @
100 /0.047 F, 300 Vrms
@ 220 /0.47 F
Technical Specifications
Page 8-3
Rev. 5-A-090514
MPU-32 Motor Protection Unit
NOTES:
(1)
(2)
The I/O module supply and analog output are
referenced to the same supply when the L/S switch is
in the S position. In the L position, the analog
output’s isolation is 120 Vac.
Current threshold is 5% of FLA setting. To maintain
specified accuracy, phase CT's should be selected
with a primary rating between 100% and 300% of
motor full-load current.
(3)
Transformer accuracy not included.
(4)
Accuracy is a function of MPU-CIM to MPU-32
cable resistance: % Accuracy = 2 + 0.65 x cable
resistance ()
(5)
Local PTC and RTD sensors are mutually exclusive.
(6)
See Table 5.1.
(7)
Display readability decreases at temperatures below
-20C (-4F).
Storage Temperature .............-55 to 80°C (-67 to 176°F)
Humidity ............................. 85% Non-Condensing
Surge Withstand ....................... ANSI/IEEE C37.90.11989 (Oscillatory and
Fast Transient)
Certification .............................. CSA, Canada and USA
UL Recognized
To:
CSA C22.2 No. 14 Industrial Control Equipment
UL 508 Industrial Control Equipment
UL 1053 Ground Fault Sensing and Relaying
Equipment
8.3 RTD MODULE (MPS-RTD)
Supply ....................................... 2 W, 18 to 32 Vdc
8.2 CURRENT INPUT MODULE (MPU-CIM)
Configuration ............................ 8 inputs, 3-wire RTD
CT Inputs:
Thermal Withstand
Continuous ..........................5 x CT-Secondary Rating
1-Second .............................80 x CT-Secondary
Rating
Burden:
1- and 5-A inputs ................< 0.01 
EFCT-x input......................10 
RTD Types ............................... Pt100, Ni100, Ni120,
Cu10
Measurement Range ................. -40 to 200°C (-40 to
392°F), with open and
short detection
Sensor Current .......................... 2 mA
Interconnection Cable:
Type .................................... Littelfuse Startco
S75-M16A-20030
Resistance ........................... 5.3 /100 m (328’) (4)
Supplied Length.................. 6 m (19’)
Terminal-Block Ratings:
CT Inputs..............................25 A, 500 Vac, 10 AWG
(4.0 mm2)
Dimensions:
Height.....................................87 mm (3.4”)
Width .....................................113 mm (4.4”)
Depth ......................................53 mm (2.1”)
Shipping Weight ....................... 0.4 kg (0.9 lb)
PWB Conformal Coating ......... MIL-1-46058 qualified
UL QMJU2 recognized
Environment:
Operating Temperature .........-40 to 60°C (-40 to
140°F) (7)
Lead Compensation .................. 20  maximum
Accuracy:
Pt100, Ni100, Ni120 RTD .....1C
Cu10 RTD ........................... 3C
Interconnection Cable:
Type .................................... Belden 3124A or
equivalent
Maximum Length ................ 1.2 km (4,000’)
Supplied length.................... 4 m (13’)
Dimensions:
Height .....................................87 mm (3.4”)
Width......................................113 mm (4.4”)
Depth ......................................53 mm (2.1”)
Shipping Weight ....................... 0.4 kg (0.9 lb)
PWB Conformal Coating.......... MIL-1-46058 qualified
UL QMJU2 recognized
Technical Specifications
Page 8-4
Rev. 5-A-090514
MPU-32 Motor Protection Unit
Environment:
Operating Temperature .........-40 to 60°C (-40 to
140°F) (7)
Storage Temperature .............-55 to 80°C (-67 to 176°F)
Humidity ............................. 85% Non-Condensing
Surge Withstand ....................... ANSI/IEEE C37.90.11989 (Oscillatory and
Fast Transient)
Certification.............................. CSA, Canada and USA
UL Recognized
Timing Accuracy ................ 5%, minimum trip time
range is set point +20 ms
to set point +150 ms,
median 81 ms
Interconnection Cable:

Type .................................... Belden 3124A or
equivalent
Maximum Length................ 1.2 km (4,000’)
Dimensions:
Height .....................................87 mm (3.4”)
Width......................................113 mm (4.4”)
Depth ......................................53 mm (2.1”)
Shipping Weight ....................... 0.4 kg (0.9 lb)
Hazardous-Location ........... Class I Zone 2 Ex nA II
T6,
Class I, Division 2,
Groups A, B, C, D
To:
CSA C22.2 No. 14 Industrial Control Equipment
UL 508 Industrial Control Equipment
CSA E60079-15: 02 Electrical Apparatus for
Explosive Gas Atmospheres
CSA C22.2 No. 213-M1987 – Non-Incendive
Electrical Equipment for use in Class I,
Division 2 Hazardous Locations
UL 60079-15 Electrical Apparatus for Explosive
Gas Atmospheres
8.4 DIFFERENTIAL MODULE (MPS-DIF)
Supply ...................................... 2 W, 18 to 32 Vdc
20 V pull-in
17 V drop-out
CT Inputs:
Thermal Withstand:
Continuous ....................... 5 x CT-Rating
1-Second .......................... 80 x CT-Rating
Burden ................................ 0.01 
Terminal-Block Ratings:
CT Inputs ............................ 25 A, 500 Vac 10 AWG
(4.0 mm2)
PWB Conformal Coating.......... MIL-1-46058 qualified
UL QMJU2 recognized
Environment:
Operating Temperature .........-40 to 60°C (-40 to
140°F) (7)
Storage Temperature .............-55 to 80°C (-67 to 176°F)
Humidity ............................. 85% Non-Condensing
Surge Withstand ....................... ANSI/IEEE
C37.90.11989 (Oscillatory and
Fast Transient)
9. WARRANTY
The MPU-32 Motor Protection Unit is warranted to be
free from defects in material and workmanship for a
period of ten years from the date of purchase.
Littelfuse Startco will (at Littelfuse Startco’s option)
repair, replace, or refund the original purchase price of
an MPU-32 that is determined by to be defective if it is
returned to the factory, freight prepaid, within the
warranty period. This warranty does not apply to repairs
required as a result of misuse, negligence, an accident,
improper installation, tampering, or insufficient care.
Littelfuse Startco does not warrant products repaired or
modified by non-Littelfuse Startco personnel.
Differential-Current Measurement:
Metering Range .................. 15 x CT-Primary Rating
(Id)
Protection Range................. 80 x Id
Metering Accuracy:
I < Id ................................ 2% Id
I > Id ................................ 2% Reading
Technical Specifications
Page A-1
Rev. 5-A-090514
MPU-32 Motor Protection Unit
APPENDIX A
MPU-32 MENU MAP
MAIN MENU
METERING
CURRENT
(METERING Continued)
Ia
Ib
Ic
LOCAL SENSOR
PTC/RTD Reading
UNBALANCE
I/O STATUS
+ Sequence
- Sequence
Digital Input State
Output Relay States
Unbalance
SYSTEM STATUS
EARTH LEAKAGE
Date and Time
Motor State
(Stop/Run/Start)
Measured (Ict)
Calculated (3I0)
Active Protection
Reduced OC
(On/Off)
THERMAL CAPACITY
Used I2t
Trend I2t
Reset Time
Trip Time
Inhibit Time
Starts Available
ETR State
Measured Frequency
NETWORK STATUS
DIFFERENTIAL (A)
Ia
Ib
Ic
RTD MODULE TEMPERATURE
Summary (Max/Min)
Stator
Bearing
Load
Notes:
(1)
RTD Module 1 to 3
RTD #1 to 8
RTD Identification
Function
Temp./Messages
(METERING Continued above)
(2)
(3)
(4)
List indicates possible trips and alarms.
Password required.
Lists do not match MPU-32 menu order.
Locked when the motor is running.
Legend:
[x]
Enter numeric
[s]
Enter string
[E/D] Enable/Disable
[TA] Trip Action: Disable; Trip1; Trip2; Trip3
[AA] Alarm Action: Disable; Alarm1;
Alarm2; Alarm3
[Y/N] Yes/No
[EA] Ethernet address
Appendix A, MPU-32 Menu Map
Page A-2
Rev. 5-A-090514
MPU-32 Motor Protection Unit
MESSAGES
TRIP AND ALARM(1)
Overcurrent Trip
Aux. Overcurrent Trip
Reduced Overcurrent Trip
Overload Trip/Alarm
Earth-Fault Trip/Alarm
Differential Trip/Alarm
Unbalance Trip/Alarm
Jam Trip/Alarm
Undercurrent Trip/Alarm
PTC/RTD Local Trip/Alarm
Phase Loss Trip/Alarm
Phase ReverseTrip/Alarm
Digital Input
RTD M1 to 3 #1-8 Trip1
RTD M1 to 3 #1-8 Alarm1
RTD M1 to 3 Comm. Trip
RTD M1 to 3 Comm. Alarm
RTD Sensor Trip/Alarm
Display Comm. Trip
NV RAM Error
Diagnostic Error
Comm Trip/Alarm
I2t Start Inhibit Trip/Alarm
Starts/Hour Trip/Alarm
(MESSAGES Continued)
STATISTICS
Trip Counters
Overcurrent
Aux. Overcurrent
Reduced Overcurrent
Overload
Earth Fault
Differential
Unbalance
Jam
Undercurrent
Phase Loss
Phase Reverse
Digital Input
RTD M1 #1 to # 8
RTD M2 #1 to # 8
RTD M3 #1 to # 8
NV RAM
PTC Temperature
RTD Module Comm
RTD Sensor
Network Comm
Display Comm
Running Hours
Hours
EVENT RECORDS
Record Number
Date/Time
Source: Start/Trip/ETR
EMERG I2t RESET
Reset I2t Memory (2)
Re-enable Temp.
Trip: Trip Source
Currents: Ia, Ib, Ic, Ig
Differential: Ia, Ib, Ic
Unbalance
Start Time
Used I2t %
RTD Temperatures
(MESSAGES Continued above)
Appendix A, MPU-32 Menu Map
Page A-3
Rev. 5-A-090514
MPU-32 Motor Protection Unit
(SETUP Continued)
SETUP (3)
Starts/Hour
PROTECTION
[TA]
[AA]
Trip Action (2)
Alarm Action (2)
Overload
Trip Action (2)
Model Type (2)
[TA]
[x]
[x]
[x]
[x]
[x]
[x]
[TA]
[AA]
[x]
[AA]
[x]
Alarm Action (2)
Alarm Level (2)
Alarm Delay (2)
(SETUP Continued above)
[TA]
[x]
PTC Temperature
Trip Action (2)
Alarm Action (2)
[TA]
[AA]
RTD Temperature
RTD LocalTemp
[TA]
[x]
[AA]
[x]
RTD Local Trip Action (2)
RTD Local Trip Level (2)
RTD Local Alarm Action (2)
RTD Modules 1 to 3
RTD #1 to #8
Name (2)
Type (2)
[s]
Disable
Pt100
Ni100
Ni120
Cu10
Function (2)
[TA]
[x]
[x]
[AA]
[x]
[x]
Phase Loss
Phase Reverse
Trip Action (2)
Trip Delay (2)
Alarm Action (2)
Alarm Delay (2)
Reduced OC
Trip Action (2)
Trip Level (2)
[TA]
[x]
[x]
Earth Fault
Jam
Unbalance
Undercurrent
Differential
Trip Action (2)
Trip Level (2)
Trip Delay (2)
[x]
RTD Local Alarm Level (2)
Multiple Motor Sequence
Overcurrent
Aux. Overcurrent
Trip Action (2)
Trip Level (2)
Trip Delay (2)
1 to 10
Time Between (2)
NEMA Model
K-Factor Model
K-Factor (2)
LR Current (2)
LR Time Cold (2)
LR Time Hot (2)
Service Factor (2)
Cooling Factor (2)
I2t Inhibit Trip (2)
I2t Inhibit Alarm (2)
I2t Inhibit Level (2)
I2t Alarm Action (2)
I2t Alarm Level (2)
I2t Reset Type (2)
Normal
Auto
Numbers of Starts/Hour (2)
[TA]
[x]
[AA]
[x]
Stator
Bearing
Load
Ambient
Stator Voting
Bearing Voting
Load Voting
Ambient Voting
Trip Temp. (2)
Alarm Temp. (2)
RTD Sensor Trip Action (2)
RTD Sensor Alarm Action (2)
HMC Enable/Disable (2)
HMC High (2)
HMC Low (2)
[x]
[x]
[TA]
[AA]
[E/D]
[x]
[x]
(SETUP Continued on next page)
Appendix A, MPU-32 Menu Map
Page A-4
Rev. 5-A-090514
MPU-32 Motor Protection Unit
(SETUP Continued)
(SETUP Continued)
SYSTEM RATINGS
ANALOG OUTPUT
PH-CT Primary
EF Source (2)
Calculated
Measured
EF-CT Primary (2,4)
DF-CT Primary (2,4)
FLA Rating (2,4)
Frequency (2)
50 Hz
60 Hz
Variable
[x]
Service Factor (2)
[x]
(2,4)
[x]
[x]
[x]
Output Parameter (2)
Phase Current
EF (EFCT Input)
EF (3I0)
Thermal Capacity
RTD Local
Module Stator RTD
Module Bearing RTD
Module Load RTD
Module Ambient RTD
Unbalance
Zero
Full Scale
Differential Current
Phase Current (FLA)
DIGITAL INPUT
Function (2)
None
Trip1 (with Delay)
Reset
Program Enable
Reduced OC
[E/D]
[x]
[x]
Start Bypass (2)
Bypass Delay (2)
Trip Delay (2)
RELAY OUTPUTS
Zero Calibrate (2)
Full Scale Calibrate (2)
[x]
[x]
HARDWARE
OPI Display
OPI Loss Trip Action (2)
RTD Modules
Total Modules (2)
None/One/Two/Three
RTD-Module-Error Trip Action (2)
Relays 1 to 3
Function (2,4)
None
Trip1
Trip2
Trip3
Alarm1
Alarm2
Alarm3
Current Detected
Run Mode
Start Inhibit
Trip1 Pulse
Watchdog
Network Run1
Reduced OC
[TA]
RTD-Module-Error Alarm Action (2)
[TA]
[AA]
MPU Temp Sensor (2)
None
PTC Sensor
RTD Sensor
DIF Module
Enable/Disable
DIF-Module-Error Trip Action (2)
DIF-Module-Error Alarm Action (2)
[E/D]
[TA]
[AA]
Mode (2,4)
Fail Safe
Non Fail Safe
RY Pulse Time (2)
(SETUP Continued above)
[x]
(SETUP Continued on next page)
Appendix A, MPU-32 Menu Map
Page A-5
Rev. 5-A-090514
MPU-32 Motor Protection Unit
(SETUP Continued)
(SETUP Continued)
HARDWARE
SYSTEM CONFIG.
Network Comms.
System Name (2)
Password (2)
Run-Mode Delay (2)
RTC Date/Time (2)
Password Time Out (2)
UPI LED (2)
Network Type (2)
None
A-B DF1
DeviceNet
Modbus RTU
Modbus/TCP
None
Trip1
Trip2
Trip3
Alarm1
Alarm2
Alarm3
Relay1
Relay2
[x]
Network ID (2)
Baud Rate (2)
TIA 9,600/19,200/38,400
DNet 125k/250k/500k
Error Check (2)
None/CRC/BCC
Ethernet IP (2)
[EA]
Ethernet Mask (2)
[EA]
Network-Error Trip Action (2)
Network-Error Alarm Action (2)
Remote Trip Action (2)
Remote Alarm Action (2)
[TA]
[AA]
[TA]
[AA]
User Registers (2)
Registers 0-31 (2)
TIA-232 Comms.
TIA-232 Comm. ID
TIA-232 Comm. Baud
[x]
[x]
9,600/19,200/38,400
[s]
[s]
[x]
[x]
[x]
Relay3
Digital Input
Current Detected
Current > 125%
Run Mode
ETR On/Off
Start Inhibit
Network Run1
Net Activity
Reduced OC
Maintenance
(SETUP Continued above)
Clear Event Records (2,4)
Clear Run Hours (2,4)
Clear Trip Counts (2,4)
Load Defaults (2,4)
Restart MPU-32 (2,4)
Firmware Update (2,4)
Firmware Version
Ethernet MAC
Serial Number
[Y/N]
[Y/N]
[Y/N]
[Y/N]
[Y/N]
[Y/N]
Appendix A, MPU-32 Menu Map
MPU-32 Motor Protection Unit
Page A-6
Rev. 5-A-090514
This page intentionally left blank.
Appendix A, MPU-32 Menu Map
Page B-1
Rev. 5-A-090514
MPU-32 Motor Protection Unit
APPENDIX B
MPU-32 SETUP RECORD
Motor:______________________________ MPU-32 S/N: _______________________ Date: ______________________
Firmware Revision: _____________________________ Ethernet MAC ID: _____________________________________
PART I: SYSTEM AND MOTOR PARAMETERS
PARAMETER AND SETTINGS
System Ratings
PH-CT Primary (Ip) (1)
MIN
DEFAULT
MAX
UNIT
1
100.00
Measured
(Ict)
5.00
100.00
100.00
1.00
5,000
A
EF Source
EF-CT Primary (Ie) (1)
DF-CT Primary (Id)
Full-Load Current (1)
Service Factor
Frequency
1
1
1
1
60
PROGRAM SELECTION
 Calculated (3I0)
 Measured (Ict)
5,000
5,000
5,000
1.25
A
A
A
Hz
 50
 60
 Variable
 None
 Trip1
 Enabled
 Reset
 Program Enable
 Reduced OC
 Disabled
 Fail Safe
 Non-Fail Safe
 Fail Safe
 Non-Fail Safe
 Fail Safe
 Non-Fail Safe
 Disabled
 Trip2
 Trip1
 Trip3
0
1
 Disabled
 Trip2
 Disabled
 Alarm2
2
3
 Trip1
 Trip3
 Alarm1
 Alarm3
Digital Input
Function
Start Bypass
Bypass Delay
Trip Delay
Relay Outputs
Relay 1: Function
Mode (1)
Relay 2: Function
Mode (1)
Relay 3: Function
Mode (1)
RY Pulse Time
Analog Output
None
(1)
(1)
(1)
Output Parameter
Zero Calibrate
Full-Scale Calibrate
HARDWARE
OPI Display
OPI-Loss Trip
Disabled
0.5
5.00
100
s
0.01
0.10
100
s
See Table 4.2 Output-Relay Functions
Trip1
Fail Safe
Alarm1
Fail Safe
None
Fail Safe
0.05
0.25
10
s
See Table 4.4 Analog-Output Parameters
Phase
Current
Factory Calibrated
Factory Calibrated
Trip1
RTD Modules
Total Modules
RTD-Module-Error Trip
Action
RTD-Module-Error Alarm
Action
0
Disabled
Alarm1
Appendix B, MPU-32 Setup Record
Page B-2
Rev. 5-A-090514
MPU-32 Motor Protection Unit
PARAMETER AND SETTINGS
MIN
DEFAULT
MPU Temperature Sensor
Disabled
DIF Module
Enable/Disable
Disabled
DIF-Module-Error Trip Action
DIF-Module-Error Alarm
Action
TIA-232 Communications
TIA-232 Comm ID
MAX
UNIT
Disabled
Disabled
0
TIA-232 Comm Baud
254
PROGRAM SELECTION
 Disabled
 PTC Sensor
 RTD Sensor
 Enabled
 Disabled
 Trip2
 Disabled
 Alarm2
 Disabled
 Trip1
 Trip3
 Alarm1
 Alarm3
 9,600
 19,200
 38,400
 None
 A-B DF1
 Modbus RTU
 Modbus TCP
 DeviceNet
 TIA 9600
 TIA 19k2
 TIA 38k4
 Not Selected
 CRC
 DN125
 DN250
 DN500
 BCC
 Disabled
 Trip2
 Disabled
 Alarm2
 Disabled
 Trip2
 Disabled
 Alarm2
 0 x 32
 0 x 33
 0 x 34
 0 x 02
 Trip1
 Trip3
 Alarm1
 Alarm3
 Trip1
 Trip3
 Alarm1
 Alarm3
 0 x 35
 0 x 64
255
9,600
bit/s
Network Communications
Network Type
Network ID
None
0
Baud Rate
254
255
TIA 9600
Error Checking (A-B DF1 Only)
Not Selected
Ethernet IP
192.168.
000.001
Ethernet Mask
255.255.
255.000
Network-Error Trip Action
Disabled
Network-Error Alarm Action
Disabled
Remote Trip Action
Disabled
Remote Alarm Action
Disabled
DeviceNet Producing Assembly
0 x 64
DeviceNet Consuming Assembly
User Registers
User Register 0
User Register 1
User Register 2
User Register 3
User Register 4
User Register 5
User Register 6
User Register 7
User Register 8
User Register 9
User Register 10
0 x 03
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
 0 x 03
1399
1399
1399
1399
1399
1399
1399
1399
1399
1399
1399
Appendix B, MPU-32 Setup Record
Page B-3
Rev. 5-A-090514
MPU-32 Motor Protection Unit
PARAMETER AND SETTINGS
User Register 11
User Register 12
User Register 13
User Register 14
User Register 15
User Register 16
User Register 17
User Register 18
User Register 19
User Register 20
User Register 21
User Register 22
User Register 23
User Register 24
User Register 25
User Register 26
User Register 27
User Register 28
User Register 29
User Register 30
User Register 31
SYSTEM CONFIG
System Name
Password
Run-Mode Delay
Password Timeout
UPI LED
MIN
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
5
1
DEFAULT
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
MPU-32
1111
10.00
10.00
None
MAX
1399
1399
1399
1399
1399
1399
1399
1399
1399
1399
1399
1399
1399
1399
1399
1399
1399
1399
1399
1399
1399
60
60
UNIT
PROGRAM SELECTION
`
s
min
See Table 4.1 UPI LED Functions
PART II: PROTECTION SET POINTS
FUNCTION & SET POINT
Overload
MIN
I2t Trip Action
I2t Model Type
K-Factor
Locked-Rotor Current
Locked-Rotor Time Cold
Locked-Rotor Time Hot
Service Factor
Cooling Factor
DEFAULT
MAX
UNIT
Trip1
1
1.5
0.10
0.10
1
0.10
NEMA
6.00
6.00
10.00
5.00
1.00
2.00
I2t Inhibit Trip
Disabled
I2t Inhibit Alarm
Disabled
10
10
100
100
1.25
10
PROGRAM SELECTION
 Disabled
 Trip2
 NEMA
 Trip1
 Trip3
 K-Factor
 Disabled
 Trip2
 Disabled
 Alarm2
 Trip1
 Trip3
 Alarm1
 Alarm3
 Disabled
 Alarm2
 Alarm1
 Alarm3
x FLA
s
s
2
I t Inhibit Level
(Per unit based on 100% I2t)
I2t Alarm Action
0.10
0.30
Alarm1
0.90
pu
Appendix B, MPU-32 Setup Record
Page B-4
Rev. 5-A-090514
MPU-32 Motor Protection Unit
FUNCTION & SET POINT
I t Alarm level
(Per Unit Based on 100% I2t)
MIN
DEFAULT
MAX
UNIT
0.50
1.00
1
pu
PROGRAM SELECTION
2
I2t Reset Type
 Normal
 Auto
 Multiple Motor Sequence
Normal
Overcurrent
Trip Action
Trip Level
(Ip is Phase-CT-Primary Rating)
Trip Delay
Auxiliary Overcurrent
Trip1
1
10.00
15
x Ip
0
0.05
10
s
Trip Action
Trip Level
(Ip is Phase-CT-Primary Rating)
Trip Delay
Reduced Overcurrent (4)
Disabled
1
10.00
15
x Ip
0
0.05
10
s
Trip Action
Trip Level
(Ip is Phase-CT-Primary Rating)
Earth Fault
Trip1
1
Trip Action
Trip Level
(Ie is EF-CT-Primary Rating)
Trip Delay
0.40
1
x Ie
0
0.25
100
s
Alarm1
0.01
0
1
1
1
1
10
100
3.00
5.00
10
100
 Trip1
 Trip3
 Disabled
 Trip2
 Trip1
 Trip3
 Disabled
 Trip2
 Trip1
 Trip3
 Disabled
 Alarm2
 Alarm1
 Alarm3
 Disabled
 Trip2
 Trip1
 Trip3
 Disabled
 Alarm2
 Alarm1
 Alarm3
 Disabled
 Trip2
 Trip1
 Trip3
 Disabled
 Alarm2
 Alarm1
 Alarm3
x FLA
s
x FLA
s
Trip1
0.05
0.25
1
pu
1
15.00
100
s
Alarm Action
Alarm Level
(Per Unit Based on I2/I1)
Alarm Delay
6.00
5.00
 Disabled
 Trip2
x Ie
s
Alarm1
Trip Action
Trip Level
(Per Unit Based on I2/I1)
Trip Delay
1
100
Trip1
Alarm Action
Alarm Level
Alarm Delay
Unbalance
0.20
1.00
 Trip1
 Trip3
x Ip
0.01
Trip Action
Trip Level
Trip Delay
15
Trip1
Alarm Action
Alarm Level
Alarm Delay
Jam
2.00
 Disabled
 Trip2
Alarm1
0.05
0.10
1
pu
1
10.00
100
s
Appendix B, MPU-32 Setup Record
Page B-5
Rev. 5-A-090514
MPU-32 Motor Protection Unit
FUNCTION & SET POINT
Phase Loss
MIN
Trip Action
Trip Delay
1
1
Trip Delay
1
1
2.00
0.1
1
5.00
100
2.00
100
0.50
10.00
1
100
0.1
1
0.80
20.00
1
100
x Id
0
0.10
10
s
Disabled
Trip Action
Disabled
Alarm Action
Disabled
1
0
5
0.00
Trip Action
Disabled
Alarm Action
Disabled
10
500
 Disabled
 Trip2
 Trip1
 Trip3
 Disabled
 Alarm2
 Alarm1
 Alarm3
 Disabled
 Trip2
 Trip1
 Trip3
 Disabled
 Alarm2
 Alarm1
 Alarm3
 Disabled
 Trip2
 Trip1
 Trip3
 Disabled
 Alarm2
 Alarm1
 Alarm3
 Disabled
 Trip2
 Disabled
 Alarm2
 Trip1
 Trip3
 Alarm1
 Alarm3
 Disabled
 Trip2
 Disabled
 Alarm2
 Trip1
 Trip3
 Alarm1
 Alarm3
 Disabled
 Trip2
 Trip1
 Trip3
 Disabled
 Alarm2
 Alarm1
 Alarm3
x FLA
s
15
15
10
 Alarm1
 Alarm3
x FLA
s
1.00
0.50
0.10
 Disabled
 Alarm2
s
0.1
0.1
0
 Trip1
 Trip3
s
Disabled
Alarm Action
 Disabled
 Trip2
s
Disabled
Trip Action
Number of Starts/Hour
Time Between Starts
PTC Temperature
100
PROGRAM SELECTION
s
Disabled
Alarm Action
Alarm Level
Alarm Delay
Starts/Hour
100
Disabled
Trip Action
Trip Level
(Id is DF-CT-Primary Current)
Trip Delay
5.00
Disabled
Alarm Action
Alarm Level
Alarm Delay
Differential
UNIT
Disabled
Alarm Delay
Phase Reverse
Trip Action
Trip Level
Trip Delay
MAX
Disabled
Alarm Action
Alarm Delay
Undercurrent
DEFAULT
x Id
s
min
RTD Temperature (Local)
Trip Action
Trip Level
Disabled
40
Alarm Action
Alarm Level
130.00
200
°C
Disabled
40
130.00
200
°C
Appendix B, MPU-32 Setup Record
Page B-6
Rev. 5-A-090514
MPU-32 Motor Protection Unit
MIN DEFAULT MAX
FUNCTION & SET POINT
RTD Temperature (MPS-RTD Module) (2)
RTD M1 #1:
Name
RTD Module 1 #1
Type
Disabled
Function
Trip
Alarm
RTD M1 #2:
Name
Stator
40
40
 Disabled
 Pt100
 Ni100
 Stator
 Bearing
 Stator Voting
 Bearing Voting
 Ni120
 Cu10
 Disabled
 Pt100
 Ni100
 Stator
 Bearing
 Stator Voting
 Bearing Voting
 Ni120
 Cu10
 Disabled
 Pt100
 Ni100
 Stator
 Bearing
 Stator Voting
 Bearing Voting
 Ni120
 Cu10
 Disabled
 Pt100
 Ni100
 Stator
 Bearing
 Stator Voting
 Bearing Voting
 Ni120
 Cu10
 Load
 Ambient
 Load Voting
 Ambient Voting
°C
°C
Stator
40
40
130.00
110.00
200
200
 Load
 Ambient
 Load Voting
 Ambient Voting
°C
°C
RTD Module 1 #3
Type
Disabled
Function
Stator
40
40
130.00
110.00
200
200
 Load
 Ambient
 Load Voting
 Ambient Voting
°C
°C
RTD Module 1 #4
Type
Disabled
Function
Trip
Alarm
200
200
Disabled
Function
Trip
Alarm
RTD M1 #4:
Name
130.00
110.00
PROGRAM SELECTION
RTD Module 1 #2
Type
Trip
Alarm
RTD M1 #3:
Name
UNIT
Stator
40
40
130.00
110.00
200
200
 Load
 Ambient
 Load Voting
 Ambient Voting
°C
°C
Appendix B, MPU-32 Setup Record
Page B-7
Rev. 5-A-090514
MPU-32 Motor Protection Unit
FUNCTION & SET POINT
RTD M1 #5:
Name
MIN
Stator
40
40
130.00
110.00
200
200
 Disabled
 Pt100
 Ni100
 Stator
 Bearing
 Stator Voting
 Bearing Voting
 Ni120
 Cu10
 Disabled
 Pt100
 Ni100
 Stator
 Bearing
 Stator Voting
 Bearing Voting
 Ni120
 Cu10
 Disabled
 Pt100
 Ni100
 Stator
 Bearing
 Stator Voting
 Bearing Voting
 Ni120
 Cu10
 Disabled
 Pt100
 Ni100
 Stator
 Bearing
 Stator Voting
 Bearing Voting
 Ni120
 Cu10
 Load
 Ambient
 Load Voting
 Ambient Voting
°C
°C
Disabled
Function
Stator
40
40
130.00
110.00
200
200
 Load
 Ambient
 Load Voting
 Ambient Voting
°C
°C
RTD Module 1 #7
Type
Disabled
Function
Stator
40
40
130.00
110.00
200
200
 Load
 Ambient
 Load Voting
 Ambient Voting
°C
°C
RTD Module 1 #8
Type
Disabled
Function
Trip
Alarm
PROGRAM SELECTION
RTD Module 1 #6
Type
Trip
Alarm
RTD M1 #8:
Name
UNIT
Disabled
Function
Trip
Alarm
RTD M1 #7:
Name
MAX
RTD Module 1 #5
Type
Trip
Alarm
RTD M1 #6:
Name
DEFAULT
Stator
40
40
130.00
110.00
200
200
 Load
 Ambient
 Load Voting
 Ambient Voting
°C
°C
Appendix B, MPU-32 Setup Record
Page B-8
Rev. 5-A-090514
MPU-32 Motor Protection Unit
FUNCTION & SET POINT
RTD M2 #1:
Name
MIN
Stator
40
40
130.00
110.00
200
200
 Disabled
 Pt100
 Ni100
 Stator
 Bearing
 Stator Voting
 Bearing Voting
 Ni120
 Cu10
 Disabled
 Pt100
 Ni100
 Stator
 Bearing
 Stator Voting
 Bearing Voting
 Ni120
 Cu10
 Disabled
 Pt100
 Ni100
 Stator
 Bearing
 Stator Voting
 Bearing Voting
 Ni120
 Cu10
 Disabled
 Pt100
 Ni100
 Stator
 Bearing
 Stator Voting
 Bearing Voting
 Ni120
 Cu10
 Load
 Ambient
 Load Voting
 Ambient Voting
°C
°C
Disabled
Function
Stator
40
40
130.00
110.00
200
200
 Load
 Ambient
 Load Voting
 Ambient Voting
°C
°C
RTD Module 2 #3
Type
Disabled
Function
Stator
40
40
130.00
110.00
200
200
 Load
 Ambient
 Load Voting
 Ambient Voting
°C
°C
RTD Module 2 #4
Type
Disabled
Function
Trip
Alarm
PROGRAM SELECTION
RTD Module 2 #2
Type
Trip
Alarm
RTD M2 #4:
Name
UNIT
Disabled
Function
Trip
Alarm
RTD M2 #3:
Name
MAX
RTD Module 2 #1
Type
Trip
Alarm
RTD M2 #2:
Name
DEFAULT
Stator
40
40
130.00
110.00
200
200
 Load
 Ambient
 Load Voting
 Ambient Voting
°C
°C
Appendix B, MPU-32 Setup Record
Page B-9
Rev. 5-A-090514
MPU-32 Motor Protection Unit
FUNCTION & SET POINT
RTD M2 #5:
Name
MIN
Stator
40
40
130.00
110.00
200
200
 Disabled
 Pt100
 Ni100
 Stator
 Bearing
 Stator Voting
 Bearing Voting
 Ni120
 Cu10
 Disabled
 Pt100
 Ni100
 Stator
 Bearing
 Stator Voting
 Bearing Voting
 Ni120
 Cu10
 Disabled
 Pt100
 Ni100
 Stator
 Bearing
 Stator Voting
 Bearing Voting
 Ni120
 Cu10
 Disabled
 Pt100
 Ni100
 Stator
 Bearing
 Stator Voting
 Bearing Voting
 Ni120
 Cu10
 Load
 Ambient
 Load Voting
 Ambient Voting
°C
°C
Disabled
Function
Stator
40
40
130.00
110.00
200
200
 Load
 Ambient
 Load Voting
 Ambient Voting
°C
°C
RTD Module 2 #7
Type
Disabled
Function
Stator
40
40
130.00
110.00
200
200
 Load
 Ambient
 Load Voting
 Ambient Voting
°C
°C
RTD Module 2 #8
Type
Disabled
Function
Trip
Alarm
PROGRAM SELECTION
RTD Module 2 #6
Type
Trip
Alarm
RTD M2 #8:
Name
UNIT
Disabled
Function
Trip
Alarm
RTD M2 #7:
Name
MAX
RTD Module 2 #5
Type
Trip
Alarm
RTD M2 #6:
Name
DEFAULT
Stator
40
40
130.00
110.00
200
200
 Load
 Ambient
 Load Voting
 Ambient Voting
°C
°C
Appendix B, MPU-32 Setup Record
Page B-10
Rev. 5-A-090514
MPU-32 Motor Protection Unit
FUNCTION & SET POINT
RTD M3 #1:
Name
MIN
Stator
40
40
130.00
110.00
200
200
 Disabled
 Pt100
 Ni100
 Stator
 Bearing
 Stator Voting
 Bearing Voting
 Ni120
 Cu10
 Disabled
 Pt100
 Ni100
 Stator
 Bearing
 Stator Voting
 Bearing Voting
 Ni120
 Cu10
 Disabled
 Pt100
 Ni100
 Stator
 Bearing
 Stator Voting
 Bearing Voting
 Ni120
 Cu10
 Disabled
 Pt100
 Ni100
 Stator
 Bearing
 Stator Voting
 Bearing Voting
 Ni120
 Cu10
 Load
 Ambient
 Load Voting
 Ambient Voting
°C
°C
Disabled
Function
Stator
40
40
130.00
110.00
200
200
 Load
 Ambient
 Load Voting
 Ambient Voting
°C
°C
RTD Module 3 #3
Type
Disabled
Function
Stator
40
40
130.00
110.00
200
200
 Load
 Ambient
 Load Voting
 Ambient Voting
°C
°C
RTD Module 3 #4
Type
Disabled
Function
Trip
Alarm
PROGRAM SELECTION
RTD Module 3 #2
Type
Trip
Alarm
RTD M3 #4:
Name
UNIT
Disabled
Function
Trip
Alarm
RTD M3 #3:
Name
MAX
RTD Module 3 #1
Type
Trip
Alarm
RTD M3 #2:
Name
DEFAULT
Stator
40
40
130.00
110.00
200
200
 Load
 Ambient
 Load Voting
 Ambient Voting
°C
°C
Appendix B, MPU-32 Setup Record
Page B-11
Rev. 5-A-090514
MPU-32 Motor Protection Unit
FUNCTION & SET POINT
RTD M3 #5:
Name
MIN
Stator
40
40
130.00
110.00
200
200
 Disabled
 Pt100
 Ni100
 Stator
 Bearing
 Stator Voting
 Bearing Voting
 Ni120
 Cu10
 Disabled
 Pt100
 Ni100
 Stator
 Bearing
 Stator Voting
 Bearing Voting
 Ni120
 Cu10
 Disabled
 Pt100
 Ni100
 Stator
 Bearing
 Stator Voting
 Bearing Voting
 Ni120
 Cu10
 Disabled
 Pt100
 Ni100
 Stator
 Bearing
 Stator Voting
 Bearing Voting
 Ni120
 Cu10
 Load
 Ambient
 Load Voting
 Ambient Voting
°C
°C
Disabled
Function
Stator
40
40
130.00
110.00
200
200
 Load
 Ambient
 Load Voting
 Ambient Voting
°C
°C
RTD Module 3 #7
Type
Disabled
Function
Stator
40
40
130.00
110.00
200
200
 Load
 Ambient
 Load Voting
 Ambient Voting
°C
°C
RTD Module 3 #8
Type
Disabled
Function
Trip
Alarm
PROGRAM SELECTION
RTD Module 3 #6
Type
Trip
Alarm
RTD M3 #8:
Name
UNIT
Disabled
Function
Trip
Alarm
RTD M3 #7:
Name
MAX
RTD Module 3 #5
Type
Trip
Alarm
RTD M3 #6:
Name
DEFAULT
Stator
40
40
130.00
110.00
200
200
 Load
 Ambient
 Load Voting
 Ambient Voting
°C
°C
Appendix B, MPU-32 Setup Record
Page B-12
Rev. 5-A-090514
MPU-32 Motor Protection Unit
FUNCTION & SET POINT
RTD-Sensor-Error Trip Action (3)
RTD-Sensor-Error Alarm
Action (3)
Hot-Motor Compensation (3)
(HMC)
MIN
DEFAULT
MAX
UNIT
Disabled
Alarm1
Disabled
PROGRAM SELECTION
 Disabled
 Trip1
 Trip2
 Trip3
 Disabled
 Alarm1
 Alarm2
 Alarm3
 Enabled
 Disabled
(3)
40
150.00
200
°C
HMC High
40
40.00
200
°C
HMC Low (3)
(1)
Locked when the motor is running
(2)
MPS-RTD Module temperature actions are fixed as Trip1 and Alarm1.
(3)
Applies to both local and module RTD’s.
(4)
Requires Digital Input set to Reduced OC for operation.
Appendix B, MPU-32 Setup Record
Page C-1
Rev. 5-A-090514
MPU-32 Motor Protection Unit
APPENDIX C
1-A DIRECT-INPUT CONFIGURATION
C.1 GENERAL
C.2 CONNECTIONS
The MPU-32 is available in a 1-A direct-input
configuration to support direct connection to
1-A-secondary phase CT’s (MPU-32-XX-01).
An
MPU-CIM is not required.
CAUTION:
Do not connect an MPU-32-XX-00 directly to phase CT’s.
This unit requires an MPU-CIM current input module.
Damage will result.
NOTES:
1. The earth-fault terminals support direct connection to
sensitive EFCT-x sensors only. 1-A- and 5-Asecondary earth-fault CT connections require an
interposing EFCT-x. In the case of a 1-A ground-fault
CT, the secondary leads of the 1-A CT must be
wrapped five times through the primary of the
EFCT-x.
2. Unlike the MPU-32-XX-00 that uses an MPU-CIM,
the CT inputs are not isolated.
3. The phase-CT inputs have a common reference. As a
result, residual- and 2-CT connections are not
possible.
4. Phase-CT input burden is about five times that of the
MPU-CIM configuration.
5. In-line CT connections require the MPU-32 to be the
last unit in the connection chain.
The block diagram of the MPU-32-XX-01 is shown in
Fig. C.1 and a typical connection diagram is shown in
Fig. C.2.
Connect each CT secondary to the MPU-32 terminal
block as shown in Fig. C.2. Although COM terminals 16,
17, and 18 are connected in the MPU-32, three independent
CT common leads must be used to prevent exceeding the
terminal-block current rating under fault conditions.
COM terminals are internally connected to the MPU-32
enclosure, which is grounded. As a result, in-line CT
applications where multiple devices are connected to one
CT require the MPU-32 to be the last (grounded) device.
CAUTION:
Connecting a 1-A- or 5-A-secondary earth-fault CT directly
to the MPU-32 earth-fault input will damage the unit.
The earth-fault input at terminals 18 (COM) and19 (EF)
supports only the 5-A-primary rated EFCT-x series of
current transformers. Using the shielded cable provided
with the EFCT-x, connect the EFCT-x as shown in
Fig. C.2. For earth-fault settings above 5 A, the EFCT-x
can be used as an interposing CT or the MPU-32 can be
set to calculate the residual earth-fault current based on
phase-current measurement.
In the latter case, an
earth-fault CT is not required. When using the calculated
method, the trip setting should be above 5% of the
phase-CT-primary rating. See Sections 4.2.2 and 5.6.
For differential protection, only the core balance and DIF
summation connections are supported. See Section 3.2.4.
C.3 DIELECTRIC-STRENGTH TESTING
Dielectric-strength testing can be performed only on
supply voltage inputs and relay outputs. Unplug all other
I/O during dielectric-strength testing.
Appendix C, 1-A Direct-Input Configuration
Page C-2
Rev. 5-A-090514
MPU-32 Motor Protection Unit
MPU-32
SUPPLY
L1
2
L2
3
13
14
15
16
17
18
19
20
8
PTC/RTD
INPUT
TA
TB
TC
17
18
19
PHASE A 1A INPUT
PHASE B 1A INPUT
PHASE C 1A INPUT
CT COMMON
CT COMMON
CT COMMON
EFCT-1/EFCT-2 INPUT
NC
MPS-DIF
SPG
15
14
PWR
COMM
TRIP
ALARM
RUN
UPI (USER PROG INDICATOR)
NS (NETWORK STATUS)
MS (MODULE STATUS)
ER (MPU-32 ERROR)
TERMINALS 16,17, AND 18
ARE CONNECTED TOGETHER
0V
27
28
4 x 20 ALPHANUMERIC LCD,
29
LED BACKLIGHTING
+
30
+24V
31
+24V
11
+
12
0V
10
+
I/O COMMUNICATIONS
+24V
15
MPS-RTD
16
17
RTD
MODULE
18
LED INDICATORS:
KEYPAD:
25
26
1
5
C
DIFFERENTIAL
CT
6
5
4
1
5
C
DIFFERENTIAL
CT
3
2
1
1
5
C
DIFFERENTIAL
CT
21
22
23
24
25
26
27
28
29
30
31
32
33
34
R
D
C
RTD 5
13
-
0V
DISPLAY:
+
9
8
7
LED INDICATORS:
LED INDICATORS:
ON
REAR
PANEL
24 V DC
DIGITAL
INPUT
DIFFERENTIAL
MODULE
UP
DOWN
LEFT
RIGHT
RESET
ESC
ENTER
23
AB
24
AA
4-20mA
ANALOG
OUTPUT
ANALOG OUTPUT
SELF/LOOP
POWER SELECTOR
L
S
C
D
R
RTD 4
SHIELD
C
D
R
C
D
R
RTD 3
RTD 2
SHIELD
RTD 1
C
D
R
PWR
14
COMM
13
12
11
10
9
8
7
6
5
ADDRESS SWITCHES
4
3
20
2
1
19
SHIELD
R
D
C
R
D
C
RTD 6
RTD 7
SHIELD
R
D
C
RTD 8
SPG
1
DCD
DTR
SG
OPTIONAL
NETWORK COM
RD
DCE
2
3
4
5
TIA-232
TD
6
CTS
RTS
11
12
OUTPUT
RELAY 2
10 1
9
OUTPUT
RELAY 3
4
6
7
OUTPUT
RELAY 1
7
8
5
OUTPUT RELAY CONTACTS SHOWN
WITH MPU-32 DE-ENERGIZED.
FIGURE C.1 MPU-32-XX-01 Block Diagram.
Appendix C, 1-A Direct-Input Configuration
Page C-3
Rev. 5-A-090514
MPU-32 Motor Protection Unit
xxx:1
PHASE CT’S
(NOTE 7)
CONTACTOR
K1
ØA
EFCT-1
MOTOR
(NOTE 6)
ØB
+t˚
t˚
ØC
RTD
SENSOR
ALTERNATE
CONNECTION FOR
PTC-THERMISTOR
SENSOR
(NOTE 8)
(NOTE 6)
OUTPUT
(NOTE 3)
(NOTE 4)
13 14 15 16 17 18 19 20 21 22 23 24
A
B C
C C C
O O O
M M M
E T
F A
31 30 29 28 27 26 25
12 11 10 9
E M N
R S S
7
6
NOTES:
2. RELAYS SHOWN DE-ENERGIZED.
RELAY 3
5
L
2
4
L1
3. GROUND CABLE SHIELDS AT MPU-32 END ONLY.
N
L
1
3
2
1
4. GROUND OUTPUT-CABLE SHIELD AT RECEIVER
END ONLY.
5. ALTERNATE CONTACTOR-COIL LOCATION.
(NOTE 5)
START
L S
1. MPU-32 REAR VIEW SHOWN.
MPU-32
RELAY 1
8
A
A
TEMP AN OUT
TIA-232 ONLY
+ + S - 0 + 24
H
V
V
COMM
DIG IN
I/O MODULE
RELAY 2
T A
C B
T
B
6. ALTERNATE CONNECTION FOR UNITS
CONFIGURED FOR PTC-THERMISTOR SENSOR.
K1
STOP
K1
7. A-B-C PHASE ROTATION REQUIRED.
ALARM
A
K1
L2/N
8. EARTH-FAULT INPUT IN NOT POLARITY SENSITIVE.
9. OPTIONAL NETWORK COMMUNICATIONS
NOT SHOWN.
FIGURE C.2 MPU-32-XX-01 Typical Connection Diagram.
Appendix C, 1-A Direct-Input Configuration
MPU-32 Motor Protection Unit
C.4 SPECIFICATIONS
C.4.1 MPU-32-XX-01
Supply ...................................... 30 VA, 120-240 Vac
(+10, -45%), 50/60 Hz,
25 W, 110-250 Vdc
(+10, -25%)
Power-Up Time ........................ 800 ms at 120 Vac
Ride-Through Time .................. 100 ms minimum
24-Vdc Source (1) ...................... 400 mA maximum
AC Measurements:
Methods .............................. True RMS, DFT, Peak,
and positive- and
negative-sequence
components of the
fundamental
Sample Rate ...........................32 samples/cycle
Frequency:
Fixed ................................... 50 to 60 Hz
Variable .............................. 10 to 90 Hz
Accuracy .......................... 0.5 Hz
Phase-Current Inputs: (2)
Range .................................. 15 x CT-Primary Rating
(Ip)
Accuracy: (3)
I < Ip ................................. 2% Ip
I > Ip ................................. 2% Reading
Burden ................................ 0.05 
Unbalance Accuracy ........... 0.02 pu
Thermal Withstand:
Continuous ....................... 5 x CT Rating
1-Second .......................... 80 x CT Rating
Earth-Leakage Input:
Range .................................. 1.5 x Earth-Fault-CTPrimary Rating (Ie = 5 A)
Accuracy (3) ......................... 2% Ie
Burden ................................ 10 
Thermal Withstand:
Continuous ....................... 5 x CT Rating
1-Second .......................... 80 x CT Rating
PTC-Thermistor Input: (5)
Cold Resistance .................. 1500  maximum at
20C (68°F)
Trip Level ........................... 2800  ± 200 
Reset Level ......................... 1500   200 
Sensor Current .................... 1 mA maximum
Page C-4
Rev. 5-A-090514
RTD Input: (5)
RTD Type ........................... 3-wire Pt100
Range ................................. -40 to 260C (-40 to
500F) with open and
short detection
Sensor Current ................... 1 mA
Lead Compensation ........... 25  maximum
Accuracy ............................. 2C (-40 to 200C, -40 to
392F)
5C (200 to 260C, 392
to 500F)
4-20 mA Analog Output:
Type .................................... Self powered and loop
powered
Range .................................. 4 to 22 mA
Update Time ....................... 250 ms
Loop Voltage ...................... 8 to 26 Vdc
Load .................................... 500  (maximum with
24 Vdc supply)
Isolation (1) .......................... 120 Vac with L/S switch
in “L” position
Timing Accuracies: (4)
Set Point  1 s ..................... +5% (minimum 25 to
45 ms)
Set Point > 1 s ..................... +2%
Relay Contacts:
Configuration ...................... N.O. and N.C. (Form C)
CSA/UL Contact Rating ....... 8 A resistive 250 Vac,
8 A resistive 30 Vdc
Supplemental Contact Ratings:
Make/Carry ...................... 20 A (0.2 s)
Break:
dc ................................... 50 W resistive, 25 W
inductive (L/R = 0.04)
ac ................................... 2,000 VA resistive, 1,500
VA inductive (PF = 0.4)
Subject to maximums of 8 A and 250 V (ac or dc).
Digital Input:
Range .................................. 12 to 36 Vdc, 5 mA at
24 Vdc
Guaranteed On .................... 12 Vdc at 2 mA
Guaranteed Off ................... 3 Vdc at 0.5 mA
Isolation .............................. 120 Vac, terminals 25
and 26
I/O Module Interface (MPS-RTD & MPS-DIF):
Module Supply .................... 24 Vdc, 400 mA
maximum
Configuration ...................... TIA-485, 2-wire multidrop
Isolation .............................. 120 Vac
Bus Length .......................... 1.2 km (4000’) maximum
Appendix C, 1-A Direct-Input Configuration
Page C-5
Rev. 5-A-090514
MPU-32 Motor Protection Unit
Conducted RF ..................... IEC 60255-22-6
10 V, 0.15-80 MHz,
80% AM (1 kHz)
Cable ................................... Belden 3124A or
equivalent
Standard TIA-232 Communications:
Baud Rate ........................... 9.6, 19.2, or 38.4 kbit/s
Protocol .............................. Modbus RTU
Address ............................... 1 to 255
Fast Transient ...................... IEC 60255-22-4
Class A: 4 kV,
2.5 kHz rpf
Class B: 2 kV, 5 kHz rpf
Real-Time Clock:
Power-Off Operation .......... 6 Months at 20C (68F)
Battery ................................ Rechargable lithium (no
service required)
1 MHz Burst........................ IEC 60255-22-1
1 kV differential mode
(line-to-line)
2.5 kV common mode
Non-Volatile RAM:
Power-Off Retention........... 10 Years
Surge Immunity .................. IEC 60255-22-5
0.5 & 1.0 kV differential
mode (line-to-line)
0.5, 1.0, & 2.0 kV
common mode
Shipping Weight ....................... 2.0 kg (4.4 lb)
PWB Conformal Coating ......... MIL-1-46058 qualified
UL QMJU2 recognized
DC Voltage Interruption ..... IEC 60255-22-11
100% for 5, 10, 20, 50,
100, & 200 ms
interruption time on
AC/DC power ports.
Environment:
Operating Temperature .........-40 to 60°C (-40 to
140°F) (6)
Storage Temperature .............-55 to 80°C (-67 to 176°F)
Humidity ............................. 85% Non-Condensing
Certification .............................. CSA, Canada and USA
Surge Withstand ....................... ANSI/IEEE C37.90.11989 (Oscillatory and
Fast Transient)
To:
CSA C22.2 No. 14 Industrial Control Equipment
UL 508 Industrial Control Equipment
UL 1053 Ground Fault Sensing and Relaying
Equipment
Australia
EMC Tests:
Verification tested in accordance with EN 60255-26:2005.
Radiated RF ........................ IEC 60255-22-3
10 V/m, 80-1,000 MHz,
80% AM (1 kHz)
10 V/m, 900 MHz,
200 Hz Pulse Modulated
N11659
CE, European Union
Electrostatic Discharge ....... IEC 60255-22-2
6 kV Constant Discharge
8 kV Air Discharge
Power Frequency ................ IEC 60255-22-7
Class A: differential mode
150 Vrms @ 100 /
0.1 F, 300 Vrms @
220 /0.47 F
Class B: differential mode
100 Vrms @ 100 /
0.047 F, 300 Vrms @
220 /0.47 F
UL Recognized
NOTES:
The I/O module supply and analog output are
referenced to the same supply when the L/S switch is
in the “S” position. In the “L” position, the analog
output’s isolation is 120 Vac.
(1)
(2)
Current threshold is 5% of FLA setting. To maintain
specified accuracy, phase CT's should be selected
with a primary rating between 100% and 300% of
motor full-load current.
(3)
Transformer accuracy not included.
(4)
See Table 5.1.
Appendix C, 1-A Direct-Input Configuration
Page C-6
Rev. 5-A-090514
MPU-32 Motor Protection Unit
(5)
Local PTC and RTD sensors are mutually exclusive.
(6)
Display readability decreases at temperatures below
-20C (-4F)
C.4.2 RTD MODULE (MPS-RTD):
Supply (1) .................................. 2 W, 18 to 32 Vdc
Configuration ........................... 8 inputs, 3-wire RTD
RTD Types ............................... Pt100, Ni100, Ni120,
Cu10
Measurement Range ................. -40 to 200°C (-40 to
392°F), with open and
short detection
Sensor Current .......................... 2 mA
Lead Compensation .................. 20  maximum
Accuracy:
Pt100, Ni100, Ni120 RTD .....1C
Cu10 RTD ........................... 3C
Interconnection Cable:
Type .................................... Belden 3124A or
equivalent
Maximum Length................ 1.2 km (4,000’)
Supplied length ................... 4 m (13’)
Shipping Weight ....................... 0.4 kg (0.9 lb)
PWB Conformal Coating ......... MIL-1-46058 qualified
UL QMJU2 recognized
Environment:
Operating Temperature .........-40 to 60°C (-40 to
140°F) (6)
Storage Temperature .............-55 to 80°C (-67 to 176°F)
Humidity ............................. 85% Non-Condensing
Surge Withstand ....................... ANSI/IEEE C37.90.11989 (Oscillatory and
Fast Transient)
Certification.............................. CSA, Canada and USA
UL Recognized
To:
CSA C22.2 No. 14 Industrial Control Equipment
UL 508 Industrial Control Equipment
CSA E60079-15: 02 Electrical Apparatus for
Explosive Gas Atmospheres
CSA C22.2 No. 213-M1987 – Non-Incendive
Electical Equipment for use in Class I, Division 2
Hazardous Locations
UL 60079-15 Electrical Apparatus for Explosive
Gas Atmospheres
C.4.3 DIFFERENTIAL MODULE (MPS-DIF)
Supply ....................................... 2 W, 18 to 32 Vdc
CT Inputs:
Thermal Withstand:
Continuous ....................... 5 x CT-Rating
1-Second........................... 80 x CT-Rating
Burden................................. 0.01 
Differential-Current Measurement:
Metering Range................... 15 x CT-Primary Rating
(Id)
Protection Range ................. 80 x Id
Metering Accuracy:
I < Id ................................. 2% Id
I > Id ................................. 2% Reading
Timing Accuracy ................. 5%, minimum trip time
range is set point +20 ms
to set point +150 ms,
median 81 ms
Communication Cable:

Type .................................... Belden 3124A or
equivalent
Maximum Length ............... 1.2 km (4,000’)
Shipping Weight ....................... 0.4 kg (0.9 lb)
PWB Conformal Coating.......... MIL-1-46058 qualified
UL QMJU2 recognized
Environment:
Operating Temperature .........-40 to 60°C (-40 to
140°F) (6)
Storage Temperature .............-55 to 80°C (-67 to 176°F)
Humidity ............................. 85% Non-Condensing
Surge Withstand ....................... ANSI/IEEE C37.90.11989 (Oscillatory and
Fast Transient)
Hazardous-Location ........... Class I Zone 2 Ex nA II
T6, Class I, Division 2,
Groups A, B, C, D
Appendix C, 1-A Direct-Input Configuration
Page D-1
Rev. 5-A-090514
MPU-32 Motor Protection Unit
APPENDIX D
MPU-32 TIA-232 MODBUS PROTOCOL
D.1 PROTOCOL
The MPU-32 implements the Modbus® RTU protocol as
described in the Gould Modbus Reference Guide,
Publication PI-MBUS-300 Rev. B.
Only the master can initiate a message transaction.
Messages can be addressed to individual slaves or they can
be broadcast messages. Broadcast messages are executed
on the slaves but unlike individually addressed messages,
the slaves do not generate a reply message.
Modicon Modbus® is a registered trademark of Schneider
Electric.
D.1.1 PROTOCOL SETUP
Setup options are available in the Setup  Hardware 
Local Comms menu. Select Local Comm ID and Local
Comm Baud.
D.2 MESSAGE SYNCHRONIZATION
Message synchronization is accomplished by detection of
an idle communication line. The communication line is
considered idle when no communication exists for an
equivalent delay of 3.5 characters.
The first byte received after idle-line detection is
interpreted as the address byte of the next message.
Message bytes must be transmitted in a continuous stream
until the complete message has been sent. If a delay of
more than 3.5 characters exists within the message, the
message is discarded.
Response messages from the MPU-32 are delayed by at
least 3.5 character delays.
D.3 ERROR CHECKING
Modbus RTU uses a 16-bit cyclic redundancy check
(CRC). The error check includes all of the message bytes,
starting with the first address byte.
When a CRC error is detected, the message is discarded
and there will be no response.
If the CRC check is correct but the internal data in the
message is not correct, the MPU-32 will respond with an
exception response code.
D.4 FUNCTION CODES SUPPORTED
The MPU-32 Modbus Protocol supports the following
function codes:
 Read Holding Registers (Function Code 3)
 Read Input Registers (Function Code 4)



Write Single Register (Function Code 6)
Write Multiple Registers (Function Code 16)
Command Instruction (Function Code 5)
Function Codes 3 and 4 perform the same function in the
MPU-32.
Registers in Modbus start at 40001 decimal and the
register address generated for this register is 0.
D.4.1 APPLICATION LAYER
The hexadecimal system is used. Value representations
use the “C” convention. For hexadecimal, 0x precedes
the value.
D.4.2 READ INPUT/HOLDING REGISTERS (CODE 04/03)
The first byte of the read message is the slave address.
The second byte is the function code. Bytes three and four
indicate the starting register. The next two bytes specify the
number of 16-bit registers to read. The last two bytes
contain the CRC code for the message.
TABLE D.1 READ REGISTERS (CODE 04/03)
HEX BYTE
DESCRIPTION
Byte 1
Byte 2
Byte 3
Byte 4
Byte 5
Byte 6
Byte 7
Byte 8
Slave Address
Function Code
MSB Register Address
LSB Register Address
MSB Number of Registers
LSB Number of Registers
LSB CRC
MSB CRC
The two-byte values of starting register and number of
registers to read are transmitted with the high-order byte
followed by the low-order byte.
The CRC value is sent with the LSB followed by the
MSB.
The following message will obtain the value of register 1
(Modbus 40002) from slave 1. Note that Modbus registers
are numbered from zero (40001 = zero, 40002 = one, etc.):
0x01  0x03  0x00  0x01  0x00  0x01  0xD5  0xCA
The addressed slave responds with its address and
Function Code 3, followed by the information field. The
information field contains an 8-bit byte count and the 16-bit
data from the slave. The byte count specifies the number of
bytes of data in the information field. The data in the
information field consists of 16-bit data arranged so that the
MSB is followed by the LSB.
Appendix D, MPU-32 TIA-232 Modbus Protocol
Page D-2
Rev. 5-A-090514
MPU-32 Motor Protection Unit
D.4.3 WRITE TO REGISTER
Function Code 6 or 16 is used to make set-point changes.
D.4.3.1 WRITE SINGLE REGISTER (CODE 6)
The function code format for writing a single register is
shown in Table D.2.
The message consists of the slave address followed by the
Function Code 6 and two 16-bit values. The first 16-bit
value specifies the register to be modified and the second
value is the 16-bit data.
Provided no errors occurred, the slave will re-send the
original message to the master. The response message is
returned only after the command has been executed by the
slave.
The following message will set register 3 to 300 in
slave 5:
0x05  0x06  0x00  0x03  0x01  0x2C  0x78  0x03
TABLE D.2 WRITE SINGLE REGISTER (CODE 6)
HEX BYTE
DESCRIPTION
Byte 1
Byte 2
Byte 3
Byte 4
Byte 5
Byte 6
Byte 7
Byte 8
Slave Address
Function Code
MSB Register Address
LSB Register Address
MSB of Data
LSB of Data
LSB of CRC
MSB of CRC
D.4.3.2 WRITE MULTIPLE REGISTERS (CODE 16)
The function-code format in Table D.3 can be used for
writing single or multiple registers.
TABLE D.3 WRITE MULTIPLE REGISTERS (CODE 16)
BYTE #
DESCRIPTION
Byte 1
Byte 2
Byte 3
Byte 4
Byte 5
Byte 6
Byte 7
.
.
.
Byte n
Slave Address
Function Code
MSB Register Address
LSB Register Address
MSB of Quantity
LSB of Quantity
Byte Count
MSB of Data
LSB of Data
LSB of CRC
MSB of CRC
TABLE D.4 COMMAND FORMAT (CODE 5)
HEX BYTE
DESCRIPTION
Byte 1
Byte 2
Byte 3
Byte 4
Byte 5
Byte 6
Byte 7
Byte 8
Slave Address
Function Code
MSB of Command Code
LSB of Command Code
Fixed at 0xFF
Fixed at 00
LSB of CRC
MSB of CRC
TABLE D.5 SUPPORTED COMMANDS
COMMAND
CODE
0x0003
0x0004
0x0005
0x0006
0x0008
0x0009
0x000C
0x000D
0x000E
0x000F
0x0010
0x0011
0x0012
COIL
NUMBER
4
5
6
7
9
10
13
14
15
16
17
18
19
ACTION
Reset Trips
Set Real-Time Clock
Clear Data-Logging Records
Clear Trip Counters
Clear Running Hours
Emergency I2t and Trip Reset
Re-enable Temperature Protection
Remote/Net Trip Set
Remote/Net Trip Clear
Remote/Net Alarm Set
Remote/Net Alarm Clear
Run1 Set
Run1 Clear
Except for a broadcast address, the slave will return the
original packet to the master.
D.4.5 COMMAND INSTRUCTIONS USING WRITE
COMMANDS
For PLC's not supporting Function Code 5, commands
can be issued using Write Single Register (Code 6) and
Write Multiple Register (Code 16).
Commands are written to MPU-32 register 6 (Modbus
register 40007). Supported commands are listed in the
COMMAND CODE column in Table D.5.
When using the Write Multiple Registers function code,
the write should be to the single MPU-32 Register 6. If
multiple registers are written starting at MPU-32 Register 6,
the first data element will be interpreted as the command
code but no other registers will be written. If the command
is successful, the MPU-32 will return a valid response
message.
The slave will reply with the slave address, function code,
register address, and the quantity followed by the CRC code
for a total of 8 bytes.
D.4.4 COMMAND INSTRUCTION (CODE 5)
Modbus Function Code 5 (Force Single Coil) is used to
issue commands to the MPU-32. The format for the
message is listed in Table D.4 and the command code
actions and corresponding coil number are listed in
Table D.5.
Appendix D, MPU-32 TIA-232 Modbus Protocol
Page D-3
Rev. 5-A-090514
MPU-32 Motor Protection Unit
D.4.6 EXCEPTION RESPONSES
The MPU-32 supports the following exception
responses:
 Boundry Error (1)—Applies to writes of 32-bit
values. The high-order word must be written first
followed by the write to the low-order word. If this
sequence is not followed, a Boundry Error is returned
and the value will not be stored. This does not apply
on read requests.
 Address Error (2)—All accesses to communication
registers must be within the specified address range
or the Address Error code is returned.
 Command Error (3)—This error code is returned if the
command code is not supported.
 Illegal Function Code (4)—The function code (Byte 2)
is not supported.
The exception message consists of the slave address
followed by a retransmission of the original function code.
The function code will have the most-significant bit set to
indicate an error. The 8-bit byte following the function code
is the exception response code. The 16-bit CRC is at the
end of the message.
D.5 MPU-32 DATABASE
D.5.2 CUSTOM DATA ACCESS
Data access can be customized with the User-Defined
Registers and the User-Data Registers.
User-Defined Registers are located in non-volatile
memory and contain the register numbers from which data
is required. To access the data, read the corresponding
User-Data Registers.
The format of the User Data is a function of the
corresponding register entered in the User-Defined-Register
area.
D.6 SPECIFICATIONS
Interface ....................................... Non-Isolated
RS/EIA/TIA-232, RJ-45
Protocol........................................ Modbus RTU
Baud Rate .................................... 9,600, 19,200, or 38,400
bit/s
Bit Format.................................... 8 bits, no parity, one stop
bit
NOTE: A network communication interface has priority
over the TIA-232 interface. To minimize TIA-232 errors
when both network and TIA-232 communications are used,
set the TIA-232 baud rate to 9,600 bit/s.
Appendix E contains the Modbus Register in the
Communications Database Table. The table starts at
register 0 (Modbus 40001) and each register is 16-bits wide.
Types “long” and “float” are 32-bit values. For both long
and float types, the low-order word is transmitted first
followed by the high-order word. Word values have the
high byte followed by the low byte. Float types as per IEEE
754 Floating-Point Standard. All bytes of long and float
types must be written using one message or an error will
result. This does not apply for read commands.
D.5.1 DATA RECORDS
Only one event record can be read at a time. Record data
is for the record indicated by the Record Selector. To select
a record, write the record number to Record Selector and
then read the values in the record. Record Head points to
the next available record. The last event record captured is
at Record Head minus one.
Both Record Selector and Record Head values are in the
range of 0 to 99. Values outside this range will select
record 0.
Appendix D, MPU-32 TIA-232 Modbus Protocol
MPU-32 Motor Protection Unit
Page D-4
Rev. 5-A-090514
This page intentionally left blank.
Appendix D, MPU-32 TIA-232 Modbus Protocol
Page E-1
Rev. 5-A-090514
MPU-32 Motor Protection Unit
APPENDIX E
COMMUNICATIONS DATABASE TABLE
MPU-32
MODBUS DEVICENET A-B FILE
REGISTER REGISTER
(DECIMAL)
(Hex)
(DECIMAL) (DECIMAL) (NOTE 10) (NOTE 4)
Model Information
0
40001
1-1-3
3:000
1
1-1-64
2
1-1-6
3
4
5
6
N/A
29-1-64
Overload
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
Overcurrent
32
33
34
35
36
40009
40033
DESCRIPTION
ACCESS
RANGE
TYPE
(NOTE 2)
Model Code
Software Version
Serial Number
Read Only
Read Only
Read Only
T3
T3
T2 (Low)
T2 (High)
Command Register
Write Only 0 – 18
T64
R/W
R/W
0–7
0–1
T42
T33
2C-1-66
I2t Trip Action
I2t Model Type
Reserved
K-Factor
R/W
1 – 10
2C-1-67
Locked-Rotor Current
R/W
1.5 – 10 x
FLA
T1 (Low)
T1 (High)
T1 (Low)
2C-1-68
Locked-Rotor Time Cold
R/W
0.1 – 100 s
2C-1-69
Locked-Rotor Time Hot
R/W
0.1 – 100 s
2C-1-6A
Cooling Factor
R/W
0.1 – 10
2C-1-6B
I2t Inhibit and Reset Level
R/W
0.1 – 0.9
2C-1-6C
I2t Alarm Level
R/W
0.5 – 1.0
2C-1-6D
2C-1-6E
2C-1-6F
2C-1-9D
I2t Alarm Action
I2t Inhibit Trip Action
I2t Inhibit Alarm Action
I2t Reset Type
R/W
R/W
R/W
R/W
0–7
0–7
0–7
0–2
Trip Action
Trip Level
R/W
R/W
0–7
1 – 15 x Ip
Trip Delay
R/W
0 – 10 s
2C-1-64
2C-1-65
64-01-01
64-01-03
64-01-04
3:8
3:32
T1 (High)
T1 (Low)
T1 (High)
T1 (Low)
T1 (High)
T1 (Low)
T1 (High)
T1 (Low)
T1 (High)
T1 (Low)
T1 (High)
T43
T42
T43
T38
T42
T1 (Low)
T1 (High)
T1 (Low)
T1 (High)
Appendix E, Communications Database Table
Page E-2
Rev. 5-A-090514
MPU-32 Motor Protection Unit
MODBUS
MPU-32
REGISTER REGISTER
(DECIMAL) (DECIMAL)
Aux Overcurrent
40
40041
41
42
43
44
Reduced Overcurrent
45
40046
46
47
Earth Fault
48
40049
49
50
51
52
53
54
55
56
57
58
DEVICENET A-B FILE
(DECIMAL) DESCRIPTION
(Hex)
(NOTE 10) (NOTE 4)
64-02-01
64-02-03
3:40
ACCESS
RANGE
TYPE
(NOTE 2)
Trip Action
Trip Level
R/W
R/W
0–7
1 – 15 x Ip
Trip Delay
R/W
0 – 10 s
3:45
Trip Action
Trip Level
R/W
R/W
0–7
1 – 15 x Ip
T42
T1 (Low)
T1 (High)
3:48
R/W
0–7
T42
64-03-03
Trip Action
Spare
Trip Level
R/W
64-03-04
Trip Delay
R/W
64-03-05
Alarm Level
R/W
64-03-06
Alarm Delay
R/W
64-03-02
Alarm Action
R/W
0.01 – 1.0 x Ie T1(Low)
T1(High)
0 – 100 s
T1(Low)
T1(High)
0.01 – 1.0 x Ie T1(Low)
T1(High)
0 – 100 s
T1(Low)
T1(High)
0–7
T43
Trip Action
Trip Level
R/W
R/W
64-04-04
Trip Delay
R/W
64-04-05
Alarm Level
R/W
64-04-06
Alarm Delay
R/W
64-04-02
Alarm Action
R/W
0–7
T42
1 – 10 x FLA T1(Low)
T1(High)
1 – 100 s
T1(Low)
T1(High)
1 – 10 x FLA T1(Low)
T1(High)
1 – 100 s
T1(Low)
T1(High)
0–7
T43
Trip Action
Trip Level
(Per Unit Based on I2/I1)
R/W
R/W
0–7
0.05 – 1.0
T42
T1(Low)
Trip Delay
R/W
1.0 – 100 s
T1(High)
T1(Low)
T1(High)
64-02-04
64-0B-01
64-0B-03
64-03-01
T42
T1 (Low)
T1 (High)
T1 (Low)
T1 (High)
Jam
64
65
66
67
68
69
70
71
72
73
40065
Current Unbalance
80
40081
81
82
83
84
64-04-01
64-04-03
64-05-01
64-05-03
64-05-04
3:64
3:80
Appendix E, Communications Database Table
Page E-3
Rev. 5-A-090514
MPU-32 Motor Protection Unit
MODBUS DEVICENET A-B FILE
MPU-32
(DECIMAL) DESCRIPTION
(Hex)
REGISTER REGISTER
(DECIMAL) (DECIMAL) (NOTE 10) (NOTE 4)
85
64-05-05
Alarm Level
(Per Unit Based on I2/I1)
86
87
64-05-06
Alarm Delay
88
89
64-05-02
Alarm Action
Phase Reverse
93
40094
94
95
96
97
98
Phase Loss
99
40100
100
101
102
103
104
Undercurrent
128
40129
129
130
131
132
133
134
135
136
137
Remote Network Control
140
141
PTC Temperature
143
144
145
ACCESS
RANGE
TYPE
(NOTE 2)
R/W
0.05 – 1.0
R/W
1.0 – 100 s
R/W
0–7
Alarm Action
Alarm Delay
R/W
R/W
07
1 – 100 s
Trip Action
Trip Delay
R/W
R/W
0–7
1 – 100 s
Trip Action
Trip Delay
R/W
R/W
0–7
1 – 100 s
Alarm Action
Alarm Delay
R/W
R/W
0-7
1 – 100 s
Trip Action
Trip Level
R/W
R/W
64-08-04
Trip Delay
R/W
1 – 100 s
64-08-05
Alarm Level
R/W
0.1 – 1.0 x
FLA
64-08-06
Alarm Delay
R/W
1 – 100 s
64-08-02
Alarm Action
R/W
0–7
T1(High)
T1(Low)
T1(High)
T43
Remote Net Trip Action
Remote Net Alarm Action
R/W
R/W
0–7
0–7
T42
T43
Sensor Select
Trip Action
Alarm Action
R/W
R/W
R/W
0–2
0–7
0–7
T68
T42
T43
64-06-02
64-06-06
3:93
64-06-01
64-06-04
64-07-01
64-07-04
3:99
64-07-02
64-07-06
64-08-01
64-08-03
29-01-7F
64-09-01
64-09-02
3:128
0–7
0.1 – 1.0 x
FLA
T1(Low)
T1(High)
T1(Low)
T1(High)
T43
T43
T1(Low)
T1(High)
T42
T1(Low)
T1(High)
T42
T1(Low)
T1(High)
T43
T1(Low)
T1(High)
T42
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
Appendix E, Communications Database Table
Page E-4
Rev. 5-A-090514
MPU-32 Motor Protection Unit
MODBUS DEVICENET A-B FILE
MPU-32
(DECIMAL)
(Hex)
REGISTER REGISTER
(DECIMAL) (DECIMAL) (NOTE 10) (NOTE 4)
RTD Temperature (Local)
146
40147
64-0A-01
3:146
147
64-0A-03
148
149
64-0A-05
150
151
64-0A-02
Differential Module
160
40161
29-01-7C
3:160
161
29-01-85
162
29-01-86
Differential Protection
170
40171
65-0C-01
3:170
171
65-0C-03
172
173
65-0C-04
174
175
65-0C-05
176
177
65-0C-06
178
179
65-0C-02
System Ratings
208
40209
2C-01-71
3:208
210
211
212
213
216
217
218
219
224
225
226
40217
233
234
ACCESS
RANGE
TYPE
(NOTE 2)
Trip Action
Trip Level
R/W
R/W
Alarm Level
R/W
Alarm Action
R/W
0–7
T42
40 – 200 C T1(Low)
T1(High)
40 – 200 C T1(Low)
T1(High)
0–7
T43
DIF Module Enable
DIF Module Trip Action
DIF Module Alarm Action
R/W
R/W
R/W
0–1
0–7
0–7
T6
T42
T43
Trip Action
Trip Level
R/W
R/W
0–7
0.1-15 x Id
Trip Delay
R/W
0 – 10 s
Alarm Level
R/W
0.1-15 x Id
Alarm Delay
R/W
0 – 10 s
Alarm Action
R/W
0–7
T42
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T43
Earth-Fault-CT Source
R/W
0–1
T60
2C-01-72
CT Primary
R/W
2C-01-73
EF-CT Primary
R/W
Run-Mode Delay
R/W
Differential CT Primary Rating
R/W
1 – 5,000 A T1(Low)
T1(High)
1 – 5,000 A T1(Low)
T1(High)
5 – 60 s
T1(Low)
T1(High)
1 – 5,000 A T1(Low)
T1(High)
Frequency
Full-Load Rating
R/W
R/W
0–2
T70
1 – 5,000 A T1(Low)
T1(High)
Service Factor
R/W
1 – 1.25
T1(Low)
T1(High)
Display-Loss Trip Action
R/W
0–7
T42
01-01-67
Password Timeout
R/W
1 – 60 m
29-01-84
UPI LED
R/W
0 – 18
T1 (Low)
T1 (High)
T71
2C-01-74
3:216
2C-01-77
40225
DESCRIPTION
2C-01-75
2C-01-76
3:224
2C-01-78
OPI
237
239
240
241
40238
29-01-7D
3:237
Appendix E, Communications Database Table
Page E-5
Rev. 5-A-090514
MPU-32 Motor Protection Unit
MODBUS DEVICENET A-B FILE
MPU-32
(DECIMAL)
(Hex)
REGISTER REGISTER
(DECIMAL) (DECIMAL) (NOTE 10) (NOTE 4)
Digital Input
264
40265
29-01-76
3:264
265
29-01-77
266
29-01-78
267
268
29-01-79
269
Relay Output Function
334
40335
29-01-6F
3:334
335
29-01-70
336
29-01-71
337
29-01-72
338
29-01-73
339
29-01-74
344
29-01-75
345
Analog Output
373
40374
29-01-7B
3:373
Network and TIA-232 Communications
374
40375
05-00-65
375
05-00-64
376
40377
377
378
379
380
381
382
383
384
385
RTD Module
386
40387
65-00-68
387
65-00-67
388
65-00-65
389
65-00-66
390
40391
65-00-64
RTD Type
391
40392
65-01-01
392
65-01-02
393
65-01-03
394
65-01-04
395
65-01-05
396
65-01-06
3:374
3:376
3:385
4:0
4:1
ACCESS
DESCRIPTION
Input 1 Function
Input 1 Bypass Enable
Input 1 Bypass Delay
R/W
R/W
R/W
Input 1 Trip Delay
R/W
Relay 1 Output Function
Relay 1 Mode
Relay 2 Output Function
Relay 2 Mode
Relay 3 Output Function
Relay 3 Mode
RY Pulse Time
R/W
R/W
R/W
R/W
R/W
R/W
R/W
RANGE
TYPE
(NOTE 2)
0–4
0–1
0.5 – 100 s
T61
T6
T1(Low)
T1(High)
0.01 – 100 s T1(Low)
T1(High)
0 – 13
0–1
0 – 13
0–1
0 – 13
0–1
0.05 – 10 s
T62
T14
T62
T14
T62
T14
T1(Low)
T1(High)
Output Parameter
R/W
0 – 13
(See Registers 856-859 for Analog Output Calibration)
T63
DeviceNet Producing Instance
DeviceNet Consuming Instance
Network Type
Network Baud Rate
Network Error Check
Network ID
R/W
R/W
R/W
R/W
R/W
R/W
0-5
0-2
0–6
0–5
0–2
0 – 255
Network Trip Action
Network Alarm Action
TIA-232 Baud Rate
TIA-232 ID
R/W
R/W
R/W
R/W
0–7
0–7
0–2
0 – 255
T84
T85
T65
T69
T18
T1(Low)
T1(High)
T42
T43
T66
T1(Low)
T1(High)
RTD-Module-Error Alarm Action
RTD-Module-Error Trip Action
RTD-Sensor-Error Trip Action(9)
RTD-Sensor-Error Alarm Action(9)
Number of RTD Modules
R/W
R/W
R/W
R/W
R/W
0–7
0–7
0–7
0–7
0–3
T43
T42
T42
T43
T19
Module 1 #1 Type
Module 1 #2 Type
Module 1 #3 Type
Module 1 #4 Type
Module 1 #5 Type
Module 1 #6 Type
R/W
R/W
R/W
R/W
R/W
R/W
0–4
0–4
0–4
0–4
0–4
0–4
T20
T20
T20
T20
T20
T20
Appendix E, Communications Database Table
Page E-6
Rev. 5-A-090514
MPU-32 Motor Protection Unit
MODBUS DEVICENET A-B FILE
MPU-32
(DECIMAL)
(Hex)
REGISTER REGISTER
(DECIMAL) (DECIMAL) (NOTE 10) (NOTE 4)
397
65-01-07
398
65-01-08
399
65-02-01
400
65-02-02
401
65-02-03
402
65-02-04
403
65-02-05
404
65-02-06
405
65-02-07
406
65-02-08
407
65-03-01
408
65-03-02
409
65-03-03
410
65-03-04
411
65-03-05
412
65-03-06
413
65-03-07
414
65-03-08
RTD Function
415
40416
65-01-09
4:25
416
65-01-0A
417
65-01-0B
418
65-01-0C
419
65-01-0D
420
65-01-0E
421
65-01-0F
422
65-01-10
423
65-02-09
424
65-02-0A
425
65-02-0B
426
65-02-0C
427
65-02-0D
428
65-02-0E
429
65-02-0F
430
65-02-10
431
65-03-09
432
65-03-0A
433
65-03-0B
434
65-03-0C
435
65-03-0D
436
65-03-0E
437
65-03-0F
438
65-03-10
DESCRIPTION
ACCESS
RANGE
TYPE
(NOTE 2)
Module 1 #7 Type
Module 1 #8 Type
Module 2 #1 Type
Module 2 #2 Type
Module 2 #3 Type
Module 2 #4 Type
Module 2 #5 Type
Module 2 #6 Type
Module 2 #7 Type
Module 2 #8 Type
Module 3 #1 Type
Module 3 #2 Type
Module 3 #3 Type
Module 3 #4 Type
Module 3 #5 Type
Module 3 #6 Type
Module 3 #7 Type
Module 3 #8 Type
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
0–4
0–4
0–4
0–4
0–4
0–4
0–4
0–4
0–4
0–4
0–4
0–4
0–4
0–4
0–4
0–4
0–4
0–4
T20
T20
T20
T20
T20
T20
T20
T20
T20
T20
T20
T20
T20
T20
T20
T20
T20
T20
Module 1 #1 Function
Module 1 #2 Function
Module 1 #3 Function
Module 1 #4 Function
Module 1 #5 Function
Module 1 #6 Function
Module 1 #7 Function
Module 1 #8 Function
Module 2 #1 Function
Module 2 #2 Function
Module 2 #3 Function
Module 2 #4 Function
Module 2 #5 Function
Module 2 #6 Function
Module 2 #7 Function
Module 2 #8 Function
Module 3 #1 Function
Module 3 #2 Function
Module 3 #3 Function
Module 3 #4 Function
Module 3 #5 Function
Module 3 #6 Function
Module 3 #7 Function
Module 3 #8 Function
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
0–7
0–7
0–7
0–7
0–7
0–7
0–7
0–7
0–7
0–7
0–7
0–7
0–7
0–7
0–7
0–7
0–7
0–7
0–7
0–7
0–7
0–7
0–7
0–7
T21
T21
T21
T21
T21
T21
T21
T21
T21
T21
T21
T21
T21
T21
T21
T21
T21
T21
T21
T21
T21
T21
T21
T21
Appendix E, Communications Database Table
Page E-7
Rev. 5-A-090514
MPU-32 Motor Protection Unit
MODBUS DEVICENET A-B FILE
MPU-32
(DECIMAL)
(Hex)
REGISTER REGISTER
(DECIMAL) (DECIMAL) (NOTE 10) (NOTE 4)
RTD Trip1/Alarm1 Setpoints
446
40447
65-01-11
4:56
447
448
65-01-12
449
450
65-01-13
451
452
65-01-14
453
454
65-01-15
455
456
65-01-16
457
458
65-01-17
459
460
65-01-18
461
462
65-01-19
463
464
65-01-1A
465
466
65-01-1B
467
468
65-01-1C
469
470
65-01-1D
471
472
65-01-1E
473
474
65-01-1F
475
476
65-01-20
477
478
65-02-11
479
480
65-02-12
481
482
65-02-13
483
484
65-02-14
485
486
65-02-15
487
488
65-02-16
489
DESCRIPTION
ACCESS
Module 1 #1 Trip Level
R/W
Module 1 #1 Alarm Level
R/W
Module 1 #2 Trip Level
R/W
Module 1 #2 Alarm Level
R/W
Module 1 #3 Trip Level
R/W
Module 1 #3 Alarm Level
R/W
Module 1 #4 Trip Level
R/W
Module 1 #4 Alarm Level
R/W
Module 1 #5 Trip Level
R/W
Module 1 #5 Alarm Level
R/W
Module 1 #6 Trip Level
R/W
Module 1 #6 Alarm Level
R/W
Module 1 #7 Trip Level
R/W
Module 1 #7 Alarm Level
R/W
Module 1 #8 Trip Level
R/W
Module 1 #8 Alarm Level
R/W
Module 2 #1 Trip Level
R/W
Module 2 #1 Alarm Level
R/W
Module 2 #2 Trip Level
R/W
Module 2 #2 Alarm Level
R/W
Module 2 #3 Trip Level
R/W
Module 2 #3 Alarm Level
R/W
RANGE
TYPE
(NOTE 2)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
Appendix E, Communications Database Table
Page E-8
Rev. 5-A-090514
MPU-32 Motor Protection Unit
MODBUS DEVICENET A-B FILE
MPU-32
(DECIMAL)
(Hex)
REGISTER REGISTER
(DECIMAL) (DECIMAL) (NOTE 10) (NOTE 4)
490
65-02-17
491
492
65-02-18
493
494
65-02-19
495
496
65-02-1A
497
498
65-02-1B
499
500
65-02-1C
501
502
65-02-1D
503
504
65-02-1E
505
506
65-02-1F
507
508
65-02-20
509
510
65-03-11
511
512
65-03-12
513
514
65-03-13
515
516
65-03-14
517
518
65-03-15
519
520
65-03-16
521
522
65-03-17
523
524
65-03-18
525
526
65-03-19
527
528
65-03-1A
529
530
65-03-1B
531
532
65-03-1C
533
534
65-03-1D
DESCRIPTION
ACCESS
Module 2 #4 Trip Level
R/W
Module 2 #4 Alarm Level
R/W
Module 2 #5 Trip Level
R/W
Module 2 #5 Alarm Level
R/W
Module 2 #6 Trip Level
R/W
Module 2 #6 Alarm Level
R/W
Module 2 #7 Trip Level
R/W
Module 2 #7 Alarm Level
R/W
Module 2 #8 Trip Level
R/W
Module 2 #8 Alarm Level
R/W
Module 3 #1 Trip Level
R/W
Module 3 #1 Alarm Level
R/W
Module 3 #2 Trip Level
R/W
Module 3 #2 Alarm Level
R/W
Module 3 #3 Trip Level
R/W
Module 3 #3 Alarm Level
R/W
Module 3 #4 Trip Level
R/W
Module 3 #4 Alarm Level
R/W
Module 3 #5 Trip Level
R/W
Module 3 #5 Alarm Level
R/W
Module 3 #6 Trip Level
R/W
Module 3 #6 Alarm Level
R/W
Module 3 #7 Trip Level
R/W
RANGE
TYPE
(NOTE 2)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
Appendix E, Communications Database Table
Page E-9
Rev. 5-A-090514
MPU-32 Motor Protection Unit
MODBUS
MPU-32
REGISTER REGISTER
(DECIMAL) (DECIMAL)
535
536
537
538
539
540
541
Hot Motor Compensation
550
40551
551
552
553
554
Clock Reading
574
40575
575
576
577
Strings
580
40581
590
600
610
620
630
640
650
660
670
680
690
700
710
720
730
740
750
760
770
780
790
800
810
820
830
840
DEVICENET A-B FILE
(DECIMAL) DESCRIPTION
(Hex)
(NOTE 10) (NOTE 4)
ACCESS
65-03-1E
Module 3 #7 Alarm Level
R/W
65-03-1F
Module 3 #8 Trip Level
R/W
65-03-20
Module 3 #8 Alarm Level
R/W
HMC Enable
HMC High
R/W
R/W
HMC Low
R/W
RTC Date
Read Only
RTC Time
Read Only
Clock String (Setting Only)
Password (First Four Characters)
System Name
RTD Module 1 #1 Name
RTD Module 1 #2 Name
RTD Module 1 #3 Name
RTD Module 1 #4 Name
RTD Module 1 #5 Name
RTD Module 1 #6 Name
RTD Module 1 #7 Name
RTD Module 1 #8 Name
RTD Module 2 #1 Name
RTD Module 2 #2 Name
RTD Module 2 #3 Name
RTD Module 2 #4 Name
RTD Module 2 #5 Name
RTD Module 2 #6 Name
RTD Module 2 #7 Name
RTD Module 2 #8 Name
RTD Module 3 #1 Name
RTD Module 3 #2 Name
RTD Module 3 #3 Name
RTD Module 3 #4 Name
RTD Module 3 #5 Name
RTD Module 3 #6 Name
RTD Module 3 #7 Name
RTD Module 3 #8 Name
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
65-00-6D
65-00-6E
4:160
65-00-6F
66-01-01
5:0
66-01-02
66-01-03
01-01-66
01-01-65
65-01-21
65-01-22
65-01-23
65-01-24
65-01-25
65-01-26
65-01-27
65-01-28
65-02-21
65-02-22
65-02-23
65-02-24
65-02-25
65-02-26
65-02-27
65-02-28
65-03-21
65-03-22
65-03-23
65-03-24
65-03-25
65-03-26
65-03-27
65-03-28
5:6
RANGE
TYPE
(NOTE 2)
T1(High)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
0–1
T6
40 – 200°C T1(Low)
T1(High)
40 – 200°C T1(Low)
T1(High)
T23(Low)
T23(High)
T24(Low)
T24(High)
T31
T22
T22
T22
T22
T22
T22
T22
T22
T22
T22
T22
T22
T22
T22
T22
T22
T22
T22
T22
T22
T22
T22
T22
T22
T22
T22
Appendix E, Communications Database Table
Page E-10
Rev. 5-A-090514
MPU-32 Motor Protection Unit
MODBUS DEVICENET A-B FILE
MPU-32
(DECIMAL) DESCRIPTION
(Hex)
REGISTER REGISTER
(DECIMAL) (DECIMAL) (NOTE 10) (NOTE 4)
Analog Output Calibration
856
40857
5:282
Analog-Output Calibration
(Zero)
857
858
Analog-Output Calibration (FS)
859
Meter Values
860
40861
2C-01-90
6:0
Ia (A)
861
862
2C-01-91
Ib (A)
863
864
2C-01-92
Ic (A)
865
866
2C-01-93
Ict (A) Earth Fault Measured
867
868
2C-01-94
3I0 (A) Earth Fault Calculated
869
870
2C-01-95
Positive-Sequence Current (pu)
871
872
2C-01-96
Negative-Sequence Current (pu)
873
874
2C-01-97
Unbalance in pu
875
876
2C-01-98
Used I2t (pu)
877
878
2C-01-99
Trend I2t (pu)
879
880
2C-01-9A
Frequency
881
882
2C-01-9E
I2t Reset/Trip Time/Inhibit Time
(min)
883
884
40885
C2-01-9F
Differential Current Phase A (A)
885
886
C2-01-A0
Differential Current Phase B (A)
887
888
C2-01-A1
Differential Current Phase C (A)
889
900
2C-01-9B
MPU RTD Reading
901
902
65-01-29
Module 1 #1 Temperature C(12)
903
904
65-01-2A
Module 1 #2 Temperature C(12)
905
906
65-01-2B
Module 1 #3 Temperature C(12)
907
ACCESS
RANGE
TYPE
(NOTE 2)
R/W
0 – 1000
T1(Low)
R/W
0 – 1000
T1(High)
T1(Low)
T1(High)
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1 (Low)
T1 (High)
T1 (Low)
T1 (High)
T1 (Low)
T1 (High)
T1 (Low)
T1 (High)
T1 (Low)
T1 (High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
Appendix E, Communications Database Table
Page E-11
Rev. 5-A-090514
MPU-32 Motor Protection Unit
MODBUS DEVICENET A-B FILE
MPU-32
(DECIMAL)
(Hex)
REGISTER REGISTER
(DECIMAL) (DECIMAL) (NOTE 10) (NOTE 4)
908
65-01-2C
909
910
65-01-2D
911
912
65-01-2E
913
914
65-01-2F
915
916
65-01-30
917
918
65-02-29
919
920
65-02-2A
921
922
65-02-2B
923
924
65-02-2C
925
926
65-02-2D
927
928
65-02-2E
929
930
65-02-2F
931
932
65-02-30
933
934
65-03-29
935
936
65-03-2A
937
938
65-03-2B
939
940
65-03-2C
941
942
65-03-2D
943
944
65-03-2E
945
946
65-03-2F
947
948
65-03-30
949
950
65-00-70
951
ACCESS
DESCRIPTION
Module 1 #4 TemperatureC (12) Read Only
Module 1 #5 Temperature C(12) Read Only
Module 1 #6 Temperature C(12) Read Only
Module 1 #7 Temperature C(12) Read Only
Module 1 #8 Temperature C(12) Read Only
Module 2 #1 Temperature C(12) Read Only
Module 2 #2 Temperature C(12) Read Only
Module 2 #3 Temperature C(12) Read Only
Module 2 #4 Temperature C(12) Read Only
Module 2 #5 Temperature C(12) Read Only
Module 2 #6 Temperature C(12) Read Only
Module 2 #7 Temperature C(12) Read Only
Module 2 #8 Temperature C(12) Read Only
Module 3 #1 Temperature C(12) Read Only
Module 3 #2 Temperature C(12) Read Only
Module 3 #3 Temperature C(12) Read Only
Module 3 #4 Temperature C(12) Read Only
Module 3 #5 Temperature C(12) Read Only
Module 3 #6 Temperature C(12) Read Only
Module 3 #7 Temperature C(12) Read Only
Module 3 #8 Temperature C(12) Read Only
Max Stator Temperature C
(6)
Read Only
RANGE
TYPE
(NOTE 2)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
Appendix E, Communications Database Table
Page E-12
Rev. 5-A-090514
MPU-32 Motor Protection Unit
MODBUS DEVICENET A-B FILE
MPU-32
(DECIMAL)
(Hex)
REGISTER REGISTER
(DECIMAL) (DECIMAL) (NOTE 10) (NOTE 4)
952
65-00-71
953
954
65-00-72
955
956
65-00-73
957
958
65-00-74
959
960
65-00-75
961
962
65-00-76
963
964
65-00-77
965
Event Records
973
40974
68-01-01
7:0
974
68-01-02
975
68-01-03
976
68-01-04
977
978
68-01-05
979
980
68-01-06
981
68-01-07
982
68-01-08
983
984
68-01-09
985
986
68-01-0A
987
988
68-01-0B
989
990
68-01-0C
991
992
68-01-0D
993
994
68-01-0E
995
996
68-01-0F
997
998
68-01-10
999
1000
68-01-11
1001
1002
68-01-12
DESCRIPTION
ACCESS
RANGE
Max Bearing Temperature C (6) Read Only
Max Load Temperature C (6)
Read Only
Max Ambient Temperature C (6) Read Only
Min Stator Temperature C (7)
Read Only
Min Bearing Temperature C (7) Read Only
Min Load Temperature C (7)
Read Only
Min Ambient Temperature C (7) Read Only
Number of Records
Record Head (Next Record)
Record Selector
Record Date
Read Only 0 – 65535
Read Only 0 – 99
R/W
0 – 99
Read Only
Record Time
Read Only
Record Type
Message Code
Ia (1)
Read Only
Read Only
Read Only
Ib (1)
Read Only
Ic (1)
Read Only
Ig (1, 11)
Read Only
Differential Current Phase A (A) Read Only
Differential Current Phase B (A) Read Only
Differential Current Phase C (A) Read Only
Reserved
Read Only
Current Unbalance (1)
Read Only
MPU RTD Reading
Read Only
Start Time
Read Only
TYPE
(NOTE 2)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T3
T3
T3
T23(Low)
T23(High)
T24(Low)
T24(High)
T26
T27
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T3
Appendix E, Communications Database Table
Page E-13
Rev. 5-A-090514
MPU-32 Motor Protection Unit
MODBUS DEVICENET A-B FILE
MPU-32
(DECIMAL)
(Hex)
REGISTER REGISTER
(DECIMAL) (DECIMAL) (NOTE 10) (NOTE 4)
1003
68-01-13
1004
1005
68-01-14
1006
1007
68-01-15
1008
1009
68-01-16
1010
1011
68-01-17
1012
1013
68-01-18
1014
1015
68-01-19
1016
1017
68-01-1A
1018
1019
68-01-1B
1020
1021
68-01-1C
1022
1023
68-01-1D
1024
1025
68-01-1E
1026
1027
68-01-1F
1028
1029
68-01-20
1030
1031
68-01-21
1032
1033
68-01-22
1034
1035
68-01-23
1036
1037
68-01-24
1038
1039
68-01-25
1040
1041
68-01-26
1042
1043
68-01-27
1044
1045
68-01-28
1046
DESCRIPTION
ACCESS
Used I2t (3)
Read Only
Module 1 #1 Temperature(12)
Read Only
Module 1 #2 Temperature(12)
Read Only
Module 1 #3 Temperature(12)
Read Only
Module 1 #4 Temperature(12)
Read Only
Module 1 #5 Temperature(12)
Read Only
Module 1 #6 Temperature(12)
Read Only
Module 1 #7 Temperature(12)
Read Only
Module 1 #8 Temperature(12)
Read Only
Module 2 #1 Temperature(12)
Read Only
Module 2 #2 Temperature(12)
Read Only
Module 2 #3 Temperature(12)
Read Only
Module 2 #4 Temperature(12)
Read Only
Module 2 #5 Temperature(12)
Read Only
Module 2 #6 Temperature(12)
Read Only
Module 2 #7 Temperature(12)
Read Only
Module 2 #8 Temperature(12)
Read Only
Module 3 #1 Temperature(12)
Read Only
Module 3 #2 Temperature(12)
Read Only
Module 3 #3 Temperature(12)
Read Only
Module 3 #4 Temperature(12)
Read Only
Module 3 #5 Temperature(12)
Read Only
RANGE
TYPE
(NOTE 2)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
Appendix E, Communications Database Table
Page E-14
Rev. 5-A-090514
MPU-32 Motor Protection Unit
MODBUS DEVICENET A-B FILE
MPU-32
(DECIMAL)
(Hex)
REGISTER REGISTER
(DECIMAL) (DECIMAL) (NOTE 10) (NOTE 4)
1047
68-01-29
1048
1049
68-01-2A
1050
1051
68-01-2B
1052
1053
1054
1055
1056
1057
1058
1059
1060
1061
1062
Status
1096
41097
29-01-65
8:0
1097
29-01-66
Message Stack
1104
41105
29-01-67
8:8
1105
29-01-68
1106
29-01-69
1107
29-01-6A
1108
29-01-6B
1109
29-01-6C
1110
29-01-6D
1111
29-01-6E
1112
29-01-88
Trip Counters
1130
41131
64-01-07
8:34
1131
64-02-07
1132
2C-01-79
1133
64-03-07
1134
64-05-07
1136
64-04-07
1137
64-08-07
1138
29-01-87
1139
65-0C-07
1140
65-0B-07
1142
64-09-07
1143
64-07-07
1144
64-06-07
1149
29-01-7A
1156
65-01-31
DESCRIPTION
ACCESS
RANGE
TYPE
(NOTE 2)
Module 3 #6 Temperature(12)
Read Only
Module 3 #7 Temperature(12)
Read Only
Module 3 #8 Temperature(12)
Read Only
Reserved
Read Only 0
Reserved
Read Only 0
Reserved
Read Only 0
Reserved
Read Only 0
Reserved
Read Only 0
Trip and Alarm Summary
MPU-32 Status
Read Only
Read Only
T67
T44
Group0 Code Bits(8) 15.. 0
Group1 Code Bits(8) 31 .. 16
Group2 Code Bits(8) 47 .. 32
Group3 Code Bits(8) 63 .. 48
Group4 Code Bits(8) 79 .. 64
Group5 Code Bits(8) 95 .. 80
Group6 Code Bits(8) 111 .. 96
Group7 Code Bits(8) 127 .. 112
Group8 Code Bits(8) 143 .. 128
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
T45
T46
T47
T48
T49
T50
T51
T52
T53
Overcurrent
AUX Overcurrent
Overload
Earth Fault
Current Unbalance
Jam
Undercurrent
Differential Module Trip
Differential Current Trip
Reduced Overcurrent Trip
PTC
Phase-Loss
Phase-Reverse
Digital Trip
RTD Module 1 #1
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
T1(Low)
T1(High)
Appendix E, Communications Database Table
Page E-15
Rev. 5-A-090514
MPU-32 Motor Protection Unit
MODBUS DEVICENET A-B FILE
MPU-32
(DECIMAL)
(Hex)
REGISTER REGISTER
(DECIMAL) (DECIMAL) (NOTE 10) (NOTE 4)
1157
65-01-32
1158
65-01-33
1159
65-01-34
1160
65-01-35
1161
65-01-36
1162
65-01-37
1163
65-01-38
1164
65-02-31
1165
65-02-32
1166
65-02-33
1167
65-02-34
1168
65-02-35
1169
65-02-36
1170
65-02-37
1171
65-02-38
1172
65-03-31
1173
65-03-32
1174
65-03-33
1175
65-03-34
1176
65-03-35
1177
65-03-36
1178
65-03-37
1179
65-03-38
1180
65-00-69
1181
65-00-6A
1182
65-00-6B
1183
65-00-6C
1185
29-01-7E
1190
1191
03-01-66
1193
2C-01-7E
1194
64-0A-07
1195
29-01-80
1196
2C-01-70
1197
29-01-82
Running Time
1210
41211
2C-01-9C
9:0
1211
Starts per Hour
1270
41271
2C-01-7A
9:60
1271
2C-01-7B
1272
2C-01-7C
1273
2C-01-7D
1274
DESCRIPTION
ACCESS
RANGE
TYPE
(NOTE 2)
RTD Module 1 #2
RTD Module 1 #3
RTD Module 1 #4
RTD Module 1 #5
RTD Module 1 #6
RTD Module 1 #7
RTD Module 1 #8
RTD Module 2 #1
RTD Module 2 #2
RTD Module 2 #3
RTD Module 2 #4
RTD Module 2 #5
RTD Module 2 #6
RTD Module 2 #7
RTD Module 2 #8
RTD Module 3 #1
RTD Module 3 #2
RTD Module 3 #3
RTD Module 3 #4
RTD Module 3 #5
RTD Module 3 #6
RTD Module 3 #7
RTD Module 3 #8
RTD Module 1 Comm
RTD Module 2 Comm
RTD Module 3 Comm
RTD Module Sensor
Display Comm
A/D
Network
Start per Hour
RTD Temperature (Local)
RTD Sensor (Local)
I2t Inhibit
Remote/Network
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
Running Seconds
Read Only
T2(Low)
T2(High)
Trip Action
Alarm Action
Starts per Hour Setting
Time Between Starts
R/W
R/W
R/W
R/W
0–7
0–7
0–9
0 – 500m
T42
T43
T25
T1(Low)
T1(High)
Appendix E, Communications Database Table
Page E-16
Rev. 5-A-090514
MPU-32 Motor Protection Unit
MODBUS DEVICENET A-B FILE
MPU-32
(DECIMAL)
(Hex)
REGISTER REGISTER
(DECIMAL) (DECIMAL) (NOTE 10) (NOTE 4)
Ethernet
1280
41281
9:70
1290
1300
1310
User Defined Registers
1400
41401
67-01-01
9:190
1401
67-01-02
1402
67-01-03
1403
67-01-04
1404
67-01-05
1405
67-01-06
1406
67-01-07
1407
67-01-08
1408
67-01-09
1409
67-01-0A
1410
67-01-0B
1411
67-01-0C
1412
67-01-0D
1413
67-01-0E
1414
67-01-0F
1415
67-01-10
1416
67-01-11
1417
67-01-12
1418
67-01-13
1419
67-01-14
1420
67-01-15
1421
67-01-16
1422
67-01-17
1423
67-01-18
1424
67-01-19
1425
67-01-1A
1426
67-01-1B
1427
67-01-1C
1428
67-01-1D
1429
67-01-1E
1430
67-01-20
1431
67-01-21
User Data
1432
41433
9:222
1433
1434
1435
1436
1437
DESCRIPTION
ACCESS
RANGE
TYPE
(NOTE 2)
IP Address
Address Mask
Gateway Address
MAC Address
R/W
R/W
R/W
Read Only
T22
T22
T22
T22
User Register 0
User Register 1
User Register 2
User Register 3
User Register 4
User Register 5
User Register 6
User Register 7
User Register 8
User Register 9
User Register 10
User Register 11
User Register 12
User Register 13
User Register 14
User Register 15
User Register 16
User Register 17
User Register 18
User Register 19
User Register 20
User Register 21
User Register 22
User Register 23
User Register 24
User Register 25
User Register 26
User Register 27
User Register 28
User Register 29
User Register 30
User Register 31
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
R/W
User Register 0 Data
User Register 1 Data
User Register 2 Data
User Register 3 Data
User Register 4 Data
User Register 5 Data
Read Only Range and Type defined
Read Only by user register value.
Read Only
Read Only
Read Only
Read Only
0 - 1399
0 - 1399
0 - 1399
0 - 1399
0 - 1399
0 - 1399
0 - 1399
0 - 1399
0 - 1399
0 – 1399
0 – 1399
0 – 1399
0 – 1399
0 – 1399
0 – 1399
0 - 1399
0 – 1399
0 – 1399
0 – 1399
0 – 1399
0 – 1399
0 – 1399
0 – 1399
0 – 1399
0 – 1399
0 – 1399
0 – 1399
0 - 1399
0 – 1399
0 – 1399
0 – 1399
0 - 1399
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
T3
Appendix E, Communications Database Table
Page E-17
Rev. 5-A-090514
MPU-32 Motor Protection Unit
MODBUS DEVICENET A-B FILE
MPU-32
(DECIMAL)
(Hex)
REGISTER REGISTER
(DECIMAL) (DECIMAL) (NOTE 10) (NOTE 4)
1438
1439
1440
1441
1442
1443
1444
1445
1446
1447
1448
1449
1450
1451
1452
1453
1454
1455
1456
1457
1458
1459
1460
1461
1462
1463
41464
9:253
DESCRIPTION
User Register 6 Data
User Register 7 Data
User Register 8 Data
User Register 9 Data
User Register 10 Data
User Register 11 Data
User Register 12 Data
User Register 13 Data
User Register 14 Data
User Register 15 Data
User Register 16 Data
User Register 17 Data
User Register 18 Data
User Register 19 Data
User Register 20 Data
User Register 21 Data
User Register 22 Data
User Register 23 Data
User Register 24 Data
User Register 25 Data
User Register 26 Data
User Register 27 Data
User Register 28 Data
User Register 29 Data
User Register 30 Data
User Register 31 Data
ACCESS
RANGE
TYPE
(NOTE 2)
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
Read Only
NOTES:
If the record type is START, these are the maximum values during the start.
(2)
See Appendix F, Register Formats.
(3)
If the record type is START, this is the I2t used during the start.
(4)
The A-B File is coded as FILE:ELEMENT. To read or write the element as floats, the PLC 5 or SLC 500 address
would be <F><FILE>:<ELEMENT> (Example F9:222). To read or write the element as integers using PLC 5 Typed
Read and Typed Write commands, add 20 to the file number and precede with N, <N><FILE+20>:<ELEMENT>
(Example N29:222). File offset is not required for the SLC 500 Protected Typed Logical Read and Write commands.
See MPU-32 TIA-485 Network Manual.
(5)
Maximum number of registers per read/write is 100 (200 bytes).
(6)
Reading is –40 if there is no maximum value available.
(7)
Reading is 300 if there is no minimum value available.
(8)
The bit number corresponds to the T27 Message Code. The LSB corresponds to the lower message code in the 16-bit
number.
(9)
Applies to MPU-32 or module MPS-RTD sensor.
(10)
Designation is Class – Instance –Attribute.
(11)
Measured value when EF Source is set to Measured (Ict), and calculated value when EF Source is set to calculated (3I0).
(12)
The following MPS-RTD error codes are supported:
-100 = No RTD Sensor
-90 = Open Sensor
-80 = Shorted Sensor
-70 = No Data/Module Communication Error
(1)
Appendix E, Communications Database Table
MPU-32 Motor Protection Unit
Page E-18
Rev. 5-A-090514
This page intentionally left blank.
Appendix E, Communications Database Table
Page F-1
Rev. 5-A-090514
MPU-32 Motor Protection Unit
APPENDIX F
REGISTER FORMATS
TYPE
T1
C TYPE
Float
DESCRIPTION (1)
IEEE 32-Bit Floating-Point Number
Bit 31: Sign
Bits 30..23: Exponent
Bits 22..0: Mantissa
Float (High): Bits 31..16
Float (Low): Bits 15..0
T2
Long
32-Bit Integer
T3
Short
16-Bit Integer
T4
Double
IEEE 64-Bit Floating-Point Number
Bit 63: Sign
Bits 62..52: Exponent
Bits 51..0: Mantissa
Word 1 (Least Significant Word) … Word 4 (Most Significant Word)
T6
Short
Enable/Disable
0: Enabled
1: Disabled
T14
Short
Relay Trip/Alarm Mode
0: Fail Safe
1: Non Fail Safe
T18
Short
Error Checking
0: Not Selected
1: CRC Check
2: BCC Check
T19
Short
Number of RTD Modules
0: No RTD Module
1: 1 RTD Module
2: 2 RTD Modules
3: 3 RTD Modules
T20
Short
RTD Type
0: Disable
1: Platinum 100
2: Nickel 100
3: Nickel 120
4: Copper 10
Appendix F, Register Formats
MPU-32 Motor Protection Unit
Page F-2
Rev. 5-A-090514
DESCRIPTION (1)
RTD Function
0: Stator
1: Bearing
2: Load
3: Ambient
4: Stator Voting
5: Bearing Voting
6: Load Voting
7: Ambient Voting
20 ASCII Characters
Register +0: Char[0] and Char[1]
Register +1: Char[2] and Char[3]
Register +2: Char[4] and Char[5]
Register +3: Char[6] and Char[7]
Register +4: Char[8] and Char[9]
Register +6: Char[10] and Char[11]
Register +7: Char[12] and Char[13]
Register +8: Char[14] and Char[15]
Register +9: Char[16] and Char[17]
Register +10: Char[18] and Char[19]
A character value of 0 (Null) will terminate the string and the following characters will be
ignored.
Ethernet address strings are of the form: “ddd.ddd.ddd.ddd”.
The MAC address is a hex string of the form: “hhhhhhhhhhhh”.
TYPE
T21
C TYPE
Short
T22
Char
T23
Long
Date
Bits 31…16: Year in Binary
Bits 15..8: 1-12 Months in Binary
Bits 7..0: 1-31 Days in Binary
T24
Long
Time
Bits 31..24: 0-23 Hours in Binary
Bits 23..16: 0-60 Minutes in Binary
Bits 15..8: 0-60 Seconds in Binary
Bits 7..0: 0-99 Hundredths of a Second in Binary
T25
Short
Starts-Per-Hour
0 = 1 Start Per Hour
1 = 2 Starts Per Hour
2 = 3 Starts Per Hour
3 = 4 Starts Per Hour
4 = 5 Starts Per Hour
5 = 6 Starts Per Hour
6 = 7 Starts Per Hour
7 = 8 Starts Per Hour
8 = 9 Starts Per Hour
9 = 10 Starts Per Hour
Appendix F, Register Formats
MPU-32 Motor Protection Unit
TYPE
T26
C TYPE
Short
DESCRIPTION (1)
Record Type
0: Empty Record
1: Trip Record
2: Start Record
3: ETR Record
T27
Short
Message Code
00: Main Overcurrent Trip
01: Auxiliary Overcurrent Trip
02: Overload Trip
03: Overload Alarm
04: Earth-Fault Trip
05: Earth-Fault Alarm
06: Current-Unbalance Trip
07: Current-Unbalance Alarm
08: Reserved
09: Reserved
10: Jam Trip
11: Jam Alarm
12: Undercurrent Trip
13: Undercurrent Alarm
14: Reserved
15: Reserved
16: Reserved
17: Reserved
18: Reserved
19: Reserved
20: Reserved
21: Reserved
22: PTC Temperature Trip
23: PTC Temperature Alarm
24: Phase-Loss (Current) Trip
25: Phase-Reverse (Current) Trip
26: Reserved
27: Reserved
28: Reserved
29: Reserved
30: Digital 1 Trip
31: Reserved
32: Reserved
33: Reserved
34: Reserved
35: Reserved
36: Reserved
37: RTD Module 1 INP 1 Trip
38: RTD Module 1 INP 1 Alarm
39: RTD Module 1 INP 2 Trip
Page F-3
Rev. 5-A-090514
Appendix F, Register Formats
MPU-32 Motor Protection Unit
TYPE
T27
C TYPE
Page F-4
Rev. 5-A-090514
DESCRIPTION (1)
40: RTD Module 1 INP 2 Alarm
41: RTD Module 1 INP 3 Trip
42: RTD Module 1 INP 3 Alarm
43: RTD Module 1 INP 4 Trip
44: RTD Module 1 INP 4 Alarm
45: RTD Module 1 INP 5 Trip
46: RTD Module 1 INP 5 Alarm
47: RTD Module 1 INP 6 Trip
48: RTD Module 1 INP 6 Alarm
49: RTD Module 1 INP 7 Trip
50: RTD Module 1 INP 7 Alarm
51: RTD Module 1 INP 8 Trip
52: RTD Module 1 INP 8 Alarm
53: RTD Module 2 INP 1 Trip
54: RTD Module 2 INP 1 Alarm
55: RTD Module 2 INP 2 Trip
56: RTD Module 2 INP 2 Alarm
57: RTD Module 2 INP 3 Trip
58: RTD Module 2 INP 3 Alarm
59: RTD Module 2 INP 4 Trip
60: RTD Module 2 INP 4 Alarm
61: RTD Module 2 INP 5 Trip
62: RTD Module 2 INP 5 Alarm
63: RTD Module 2 INP 6 Trip
64: RTD Module 2 INP 6 Alarm
65: RTD Module 2 INP 7 Trip
66: RTD Module 2 INP 7 Alarm
67: RTD Module 2 INP 8 Trip
68: RTD Module 2 INP 8 Alarm
69: RTD Module 3 INP 1 Trip
70: RTD Module 3 INP 1 Alarm
71: RTD Module 3 INP 2 Trip
72: RTD Module 3 INP 2 Alarm
73: RTD Module 3 INP 3 Trip
74: RTD Module 3 INP 3 Alarm
75: RTD Module 3 INP 4 Trip
76: RTD Module 3 INP 4 Alarm
77: RTD Module 3 INP 5 Trip
78: RTD Module 3 INP 5 Alarm
79: RTD Module 3 INP 6 Trip
80: RTD Module 3 INP 6 Alarm
81: RTD Module 3 INP 7 Trip
82: RTD Module 3 INP 7 Alarm
83: RTD Module 3 INP 8 Trip
84: RTD Module 3 INP 8 Alarm
85: RTD Module 1 Comm Trip
86: RTD Module 1 Comm Alarm
Appendix F, Register Formats
MPU-32 Motor Protection Unit
TYPE
T27
C TYPE
Page F-5
Rev. 5-A-090514
DESCRIPTION (1)
87: RTD Module 2 Comm Trip
88: RTD Module 2 Comm Alarm
89: RTD Module 3 Comm Trip
90: RTD Module 3 Comm Alarm
91: RTD Sensor-Failure Trip
92: RTD Sensor-Failure Alarm
93: Reserved
94: All Defaults Loaded
95: Non-Volatile Memory (NV) Enum Error
96: NV Numeric Error
97: NV String Error
98: NV Event-Record Error
99: NV I²t Error
100: Reserved
101: Display-Communication Trip
102: Diagnostic Error
103: Reserved
104: Network-Communication Trip
105: Network-Communication Alarm
106: Reserved
107: Reserved
108: Reserved
109: Reserved
110: Reserved
111: Reserved
112: Reserved
113: Reserved
114: Phase Reverse Alarm
115: Reserved
116: Starts per Hour Trip
117: Starts per Hour Alarm
118: Reserved
119: Remote/Network Alarm
120: Remote/Network Trip
121: Phase Loss Alarm
122: Local RTD Trip
123: Local RTD Alarm
124: Local RTD Sensor Fault
125: Local RTD Sensor Alarm
126: I2t Inhibit Trip
127: I2t Inhibit Alarm
128: Differential Communication Trip
129: Differential Communication Alarm
130: Differential Trip
131: Differential Alarm
132: Reduced Overcurrent Trip
Appendix F, Register Formats
MPU-32 Motor Protection Unit
TYPE
C TYPE
DESCRIPTION (1)
252: ETR Request (2)
253: Normal Start (2)
254: Incomplete Start (2)
255: No Trip or Alarm Code (2)
T31
Char
RTC ASCII-Character Setting String:
YY/MM/DD HH:mm:SS
YY: 2-digit Year (Year 2000 – 2099)
MM: Month 1-12
DD: Day 1-31
HH: Hour 0-23
mm: Minute 0-59
SS: Seconds 0-59
RTC is updated when “Set RTC” command is issued.
T32
Short
Free Record Pointer
Subtract to obtain last record.
Range is 0 to 99.
T33
Short
Thermal-Model Type
0: NEMA (Max RMS)
1: K-Factor
T38
Short
I2t Reset Type
0: Normal
1: Autoreset
2: Multiple-Motor Sequence
T42
Short
Trip Action
0: Disabled
1: Trip1
2: Trip2
3: Trip3
4: Trip1 & Trip2
5: Trip1 & Trip3
6: Trip1 & Trip2 & Trip3
7: Trip2 & Trip3
Page F-6
Rev. 5-A-090514
Appendix F, Register Formats
Page F-7
Rev. 5-A-090514
MPU-32 Motor Protection Unit
TYPE
T43
C TYPE
Short
DESCRIPTION (1)
Alarm Action
0: Disabled
1: Alarm1
2: Alarm2
3: Alarm3
4: Alarm1 & Alarm2
5: Alarm1 & Alarm3
6: Alarm1 & Alarm2 & Alarm3
7: Alarm2 & Alarm3
T44
Short
MPU-32 Status
Bit0: 1 = Motor Current Detected
Bit1: 1 = Motor in Run Mode
Bit2: 1 = Reduced OC On (ROC:On)
Bit3: 1 = Motor Current 125%
Bit4: 1 = ETR On
Bit5: 1 = PTC Open
Bit6, Bit7: Spare
Bit8: 1 = Digital Input Valid
Bit9: 1 = RY1 Energized
Bit10: 1 = RY2 Energized
Bit11: 1 = RY3 Energized
T45
T46
T47
T48
T49
T50
T51
T52
T53
Short
Short
Short
Short
Short
Short
Short
Short
Short
Trip/Alarm Message Code Bits (3)
Trip/Alarm Message Code Bits (3)
Trip/Alarm Message Code Bits (3)
Trip/Alarm Message Code Bits (3)
Trip/Alarm Message Code Bits (3)
Trip/Alarm Message Code Bits (3)
Trip/Alarm Message Code Bits (3)
Trip/Alarm Message Code Bits (3)
Trip/Alarm Message Code Bits (3)
T60
Short
Earth-Fault CT Source
0: Calculated (3I0)
1: Measured (Ict)
T61
Short
Digital Input Function
0: None
1: Trip
2: Reset
3: Program Enable
4: Reduced OC
15..0
31..16
47..32
63..48
79..64
95..80
111..96
127..112
143..128
Appendix F, Register Formats
MPU-32 Motor Protection Unit
TYPE
T62
C TYPE
Short
DESCRIPTION (1)
Relay Function
0: None
1: Trip1
2: Trip2
3: Trip3
4: Alarm1
5: Alarm2
6: Alarm3
7: Current Detected
8: Run
9: Start Inhibit
10: Trip1 Pulse
11: Watchdog
12: Network Run1
13: Reduced OC
T63
Short
T64
Short
Analog Output Parameter
0: Phase Current
1: Earth Leakage Measured From CT Input
2: Earth Leakage Calculated From Phase CT Input
3: Thermal Capacity
4: Local RTD
5: RTD Module Maximum Stator Temperature
6: RTD Module Maximum Bearing Temperature
7: RTD Module Maximum Load Temperature
8: RTD Module Maximum Ambient Temperature
9: Current Unbalance
10: Zero Output (4 mA)
11: Full Scale Output (20 mA)
12: Differential Current
13: Phase Current (FLA)
MPU-32 Command
0: Reserved
1: Reserved
2: Reserved
3: Reset Trips (does not reset Remote/Network Trip)
4: Set Real-Time Clock
5: Clear Data-Logging Records
6: Clear Trip Counters
7: Reserved
8: Clear Running Hours
9: Emergency Thermal Reset
10: Reserved
11: Reserved
12: Re-enable Temperature Protection
13: Remote/Network Trip Set
14: Remote/Network Trip Reset
Page F-8
Rev. 5-A-090514
Appendix F, Register Formats
MPU-32 Motor Protection Unit
TYPE
C TYPE
DESCRIPTION (1)
15: Remote/Network Alarm Set
16: Remote/Network Alarm Reset
17: Run1 Set
18: Run1 Clear
T65
short
T66
short
Network Communication Type
0: None
1: A-B DF1
2: DeviceNet
3: Reserved
4: Modbus RTU
5: Modbus TCP
6: Reserved
Local Communication Baud Rates
0: 9,600 bit/s
1: 19,200 bit/s
2: 38,400 bit/s
T67
short
Trip and Alarm Summary
Bit0: 0
Bit1: 0
Bit2: 0
Bit3: 0
Bit4: Trip1
Bit5: Trip2
Bit6: Trip3
Bit7: Alarm1
Bit8: Alarm2
Bit9: Alarm3
Bit10: 0
Bit11: 0
Bit12: 0
Bit13: 0
Bit14: 0
Bit15: 0
T68
short
Local Temperature Sensor
0: Disabled
1: RTD Sensor
2: PTC Sensor
T69
short
Network Baud Rate
0: TIA 9,600 bit/s
1: TIA 19,200 bit/s
2: TIA 38,400 bit/s
3: DeviceNet 125 kbit/s
4: DeviceNet 250 kbit/s
5: DeviceNet 500 kbit/s
Page F-9
Rev. 5-A-090514
Appendix F, Register Formats
MPU-32 Motor Protection Unit
TYPE
T70
C TYPE
short
DESCRIPTION (1)
Frequency
0: 50 Hz
1: 60 Hz
2: Variable Frequency
T71
short
User Programmable Indicator Selection
0: None (LED Off)
1: Trip1
2: Trip2
3: Trip3
4: Alarm1
5: Alarm2
6: Alarm3
7: Relay1
8: Relay2
9: Relay3
10: Digital Input
11: Current Detected
12: Current > 125% FLA
13: Motor in Run Mode
14: ETR State
15: Start Inhibit
16: Network Run1
17: Net Activity
18: Reduced OC
T84
DeviceNet Producing Instance
0: None
1: 0x32 Basic Overload
2: 0x33 Extended Overload
3: 0x34 Basic Motor Starter
4: 0x35 Extended Motor Starter1
5: 0x64 User Registers
T85
DeviceNet Consuming Instance
0: None
1: 0x02 Basic Overload
2: 0x03 Basic Motor Starter
Page F-10
Rev. 5-A-090514
NOTES:
(1)
All values are integers unless indicated by “Bit x”, where x represents bit location and 0 = LSB.
(2)
Not a trip code. Used by event records to indicate start record type.
(3)
The bit number corresponds to the T27 Message Code. The LSB corresponds to the lower message code in the 16-bit
number.
Appendix F, Register Formats
Page G-1
Rev. 5-A-090514
MPU-32 Motor Protection Unit
MANUAL
RELEASE DATE
APPENDIX G
MPU-32 REVISION HISTORY
HARDWARE
MANUAL
REVISION(1)
(REVISION NUMBER
REVISION
ON PRODUCT LABEL)
September 5, 2014
5-A-090514
December 5, 2012
4
03
02A
02
2011
3
2009
(1)
01D
01C
01B
2008
2
01A
2007
1
0
01
At time of release.
MANUAL REVISION HISTORY
REVISION 5-A-090514
SECTION 1
RTD Voting added to MPS-RTD features list.
SECTION 2
EFCT-x figures updated.
SECTION 4
Phase Current (FLA) added to Table 4.4.
SECTION 5
RTD Voting added to Section 5.16.
HMC compensation limit added to Section 5.17.
SECTION 8
Added UL Certification.
APPENDIX A
Phase Current (FLA) added to Analog Output menu.
APPENDIX C
Added UL Certification.
APPENDIX E
Analog output parameter maximum range increased to 13.
APPENDIX F
Phase Current (FLA) added to T63.
APPENDIX G
Added revision history.
HARDWARE REVISION HISTORY
HARDWARE REVISION 03
Updated power supply.
HARDWARE REVISION 02A
Updated power supply.
FIRMWARE REVISION
2.20
2.11
2.10
2.10
2.02
2.01
2.00
2.10
2.00
2.00
1.91
1.90
1.83
1.83
1.81
1.71
1.61
MPU-32 Motor Protection Unit
HARDWARE REVISION 02
Ethernet PHY updated.
HARDWARE REVISION 01D
Updated power supply.
HARDWARE REVISION 01C
Updated power supply.
HARDWARE REVISION 01B
LCD display updated.
HARDWARE REVISION 01A
Key switches updated.
HARDWARE REVISION 01
LCD display updated.
HARDWARE REVISION 00
Initial release.
FIRMWARE REVISION HISTORY
FIRMWARE REVISION 2.20
RTD Voting and Gateway Address added.
HMC compensation limit set to 90%.
FIRMWARE REVISION 2.11
Unused RTDs now indicate “Unused” in database readings area.
FIRMWARE REVISION 2.10
Analog filter added.
FIRMWARE REVISION 2.02
Spanish menu order option added.
FIRMWARE REVISION 2.01
Added support for new Ethernet PHY.
FIRMWARE REVISION 2.00
Added MPU-16A analog-output selection.
FIRMWARE REVISION 1.91
Powr-Gard version added.
FIRMWARE REVISION 1.90
Default menu selection added.
Overload reset time added.
FIRMWARE REVISION 1.83
Fixed DeviceNet reset issue.
FIRMWARE REVISION 1.81
Fixed analog-output roll-over issue.
DeviceNet assembly selections added.
FIRMWARE REVISION 1.71
Added support for MPS-DIF and reduced overcurrent.
FIRMWARE REVISION 1.61
DeviceNet Bus-Off feature revised.
Page G-2
Rev. 5-A-090514