Instruction Bulletin
63220-080-200/B1
August 2002
Using MICROLOGIC® Electronic Trip Units in a
POWERLOGIC® System
(includes Type A, Type P, and Type H trip units)
Retain for future use
NOTICE
Read these instructions carefully and look at the equipment to become
familiar with the device before trying to install, operate, service, or maintain
it. The following special messages may appear throughout this bulletin or on
the equipment to warn of potential hazards or to call attention to information
that clarifies or simplifies a procedure.
The addition of either symbol to a “Danger” or “Warning” safety label
indicates that an electrical hazard exists which will result in personal injury if
the instructions are not followed.
This is the safety alert symbol. It is used to alert you to potential personal
injury hazards. Obey all safety messages that follow this symbol to avoid
possible injury or death.
DANGER
DANGER indicates an imminently hazardous situation which, if not
avoided, will result in death or serious injury.
WARNING
WARNING indicates a potentially hazardous situation which, if not
avoided, can result in death or serious injury.
CAUTION
CAUTION indicates a potentially hazardous situation which, if not
avoided, can result in minor or moderate injury.
CAUTION
CAUTION, used without the safety alert symbol, indicates a potentially
hazardous situation which, if not avoided, can result in property damage.
NOTE: Provides additional information to clarify or simplify a procedure.
PLEASE NOTE
Electrical equipment should be installed, operated, serviced, and maintained
only by qualified personnel. No responsibility is assumed by Schneider
Electric for any consequences arising out of the use of this manual.
CLASS A FCC STATEMENT
This equipment has been tested and found to comply with the limits for a
Class A digital device, pursuant to part 15 of the FCC Rules. These limits are
designated to provide reasonable protection against harmful interference
when the equipment is operated in a commercial environment. This
equipment generates, uses, and can radiate radio frequency energy and, if
not installed and used in accordance with the instruction manual, may cause
harmful interference to radio communications. Operation of this equipment in
a residential area is likely to cause harmful interference in which case the
user will be required to correct the interference at his own expense.
© 2002 Schneider Electric All Rights Reserved
Bulletin No. 63220-080-200/B1
August 2002
CONTENTS
Contents
Using MICROLOGIC Electronic Trip Units in a POWERLOGIC system
ABOUT THIS DOCUMENT . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1
FEATURE SUPPORT FOR MICROLOGIC ELECTRONIC TRIP UNITS . . 1
REQUIREMENTS FOR USING MICROLOGIC ELECTRONIC
TRIP UNITS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1
TECHNICAL SUPPORT . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2
SYSTEM DESCRIPTION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2
Trip Unit System Modules . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2
Network Communication . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
Hardware Setup Checklist . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6
Setting Type A Communications Parameters . . . . . . . . . . . . . . . . . . . 6
Setting Type P and Type H Communications Parameters . . . . . . . . . 7
INSTALLATION AND DEVICE SETUP IN SMS . . . . . . . . . . . . . . . . . . . . . 8
Installing the Software . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
Adding and Setting Up Trip Units . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
VIEWING REAL-TIME INFORMATION IN SMS . . . . . . . . . . . . . . . . . . . . 10
USING QUANTITIES . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10
USING SMS ALARMS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10
Alarm Levels . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11
Pre-assigned PC-based Alarms and Events . . . . . . . . . . . . . . . . . . . 12
Type P and Type H Pre-assigned On-board Alarms . . . . . . . . . . . . . 13
Pre-assigned Task—Resetting the Device Clock . . . . . . . . . . . . . . . 13
USING CONTROL OUTPUTS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13
DEVICE RESETS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14
METERING CAPABILITIES . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15
Real-Time Metering . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15
Min/Max Values . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16
Power Factor Min/Max Conventions . . . . . . . . . . . . . . . . . . . . . . . . . 16
Demand Readings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18
Demand Power and Current Calculation Methods (Type P) . . . . . . . 19
Demand Power and Current Calculation Methods (Type H) . . . . . . . 20
Predicted Demand . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21
Peak Demands . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22
Energy Readings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22
Harmonic Readings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23
Real-Time Power Quality Quantities . . . . . . . . . . . . . . . . . . . . . . . . . 23
Waveform Capture . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23
ADVANCED TOPICS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23
Changing the VAR and Power Factor Sign Convention . . . . . . . . . . 23
Changing VAR Sign Convention Within SMS . . . . . . . . . . . . . . . . . . 24
Changing VAR and PF Sign Conventions from the Trip Unit HMI . . . 25
Time Synchronization . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25
TROUBLESHOOTING . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27
APPENDIX A—TYPE A STANDARD QUANTITIES . . . . . . . . . . . . . . . . . 29
APPENDIX B—TYPE P STANDARD QUANTITIES . . . . . . . . . . . . . . . . . 31
APPENDIX C—TYPE H STANDARD QUANTITIES . . . . . . . . . . . . . . . . 39
© 2002 Schneider Electric All Rights Reserved
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Contents
Using MICROLOGIC Electronic Trip Units in a POWERLOGIC system
Bulletin No. 63220-080-200/B1
August 2002
APPENDIX D—MICROLOGIC TRIP UNIT ERROR CODES . . . . . . . . . . 63
APPENDIX E—SMS TABLE SUPPORT . . . . . . . . . . . . . . . . . . . . . . . . . 65
APPENDIX F—COMMUNICATIONS CONSIDERATIONS . . . . . . . . . . . 67
INDEX . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 69
ii
© 2002 Square D All Rights Reserved
63220-080-200/B1
August 2002
ABOUT THIS DOCUMENT
Using MICROLOGIC Electronic Trip Units in a POWERLOGIC System
This document provides the following information:
• adding MICROLOGIC electronic trip units to your POWERLOGIC© system
• using alarms and events, control outputs, and device resets in SMS for
MICROLOGIC electronic trip units
• creating custom quantities and custom tables to view data in SMS from
MICROLOGIC electronic trip units
NOTE: This document contains specific information about the Type A,
Type P, and Type H MICROLOGIC electronic trip units only.
Use this bulletin along with these other manuals:
• MICROLOGIC electronic trip unit instruction bulletin
• instruction bulletins for related devices, such as the MODBUS Breaker
Communication Module and the MODBUS Cradle Communication Module
• SMS online help file and other SMS documentation
FEATURE SUPPORT FOR MICROLOGIC
ELECTRONIC TRIP UNITS
This section describes the features that SMS supports for MICROLOGIC
electronic trip units and related devices. For specific instructions on using
these features in SMS, refer to the SMS online help file and the SMS
documentation.
SMS supports the following features for MICROLOGIC electronic trip units
and related devices:
• real-time data in tables, bar charts, and meters
• device resets (such as min/max, operational counter, energy, peak demands)
• automatically assigned control outputs (circuit breaker open and close)
• historical logging/trending
• automatically assigned PC-based alarms
• automatically assigned on-board device alarms (protection)
• interactive graphics (optional; GFX-1000 software required)
• pre-configured software logging templates
• standard and custom quantities
• on-board data and alarm log uploads
• device health checks and system communications test
• diagnostic register reads and writes
• on-board circuit breaker event log uploads
• metering alarms setup
• on-board waveform capture uploads
REQUIREMENTS FOR USING
MICROLOGIC ELECTRONIC TRIP UNITS
To use MICROLOGIC electronic trip units in SMS, the following requirements
must be met:
• Type A and P: You must have installed the SMS version 3.2 upgrade.
Type H: You must have installed the SMS version 3.3.1 maintenance release.
To determine the installed version, click About on the Help menu in the SMS
client.
• If your system has MICROLOGIC electronic trip units daisy-chained to a
port of a POWERLOGIC® Ethernet Gateway, the gateway must use
Ethernet Gateway firmware version 2.5.0. or later.
• The ECM-2000 and ECM-RM are not compatible with the MICROLOGIC
trip unit system. Use the POWERLOGIC Ethernet Gateway or Series 4000
© 2002 Schneider Electric All Rights Reserved
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Using MICROLOGIC Electronic Trip Units in a POWERLOGIC System
63220-080-200/B1
August 2002
Circuit Monitor with an Ethernet Communication Card (ECC) when
connecting to an Ethernet network.
• If your system includes a mixed-mode daisy chain (POWERLOGIC devices
and MICROLOGIC electronic trip units on the same daisy chain), Series
2000 Circuit Monitors on the daisy chain must have firmware version
17.008 or later.
• If your system includes a mixed-mode daisy chain (POWERLOGIC and
MODBUS or Jbus devices), do not assign address 1 to any POWERLOGIC
device on the daisy chain; do not assign address 16 to any MODBUS or
Jbus device on the daisy chain.
• See “Appendix F—Communications Considerations” on page 67, for
2-wire and 4-wire distance and baud rate limitations.
TECHNICAL SUPPORT
If you have questions about any POWERLOGIC product, contact your local
sales representative. For the address and telephone number for technical
support in your country, see the Product Registration and Technical Support
Contacts sheet; a PDF copy of this document is contained on the SMS
installation CD.
SYSTEM DESCRIPTION
All of the trip units described in this bulletin provide adjustable tripping
functions for circuit breakers, including long-time and instantaneous
adjustments for overloads and short circuits. There are three types of trip
units:
• Type A, which provides basic trip features and ammeter measurements
• Type P, which provides basic and advanced features and power/energy
measurements
• Type H, which combines the features of the Type P unit with waveform
capture and harmonic measurements
All trip units are self-powered by the circuit they protect, or they can be
powered by an external 24-Vdc control power supply. The external power
supply is recommended to ensure that metering and communication
continue, even if the circuit breaker is opened or tripped.
Drawout circuit breakers may include an optional cradle communication
module (CCM) that provides information about the position of the circuit
breaker in the cradle. This module automatically assigns correct
communications parameters to the circuit breaker when it’s racked into the
test or connected positions.
Trip Unit System Modules
The MICROLOGIC trip unit system consists of three separate communicating
modules (plus a fourth optional module), described below. Each module has
an independent function. Together, they are viewed as a single device from
both the human-machine interface (HMI) and SMS. This simplifies data
reporting, recording, alarming, and general user interface.
The trip unit system includes:
• Trip Unit Protection Module (PM)—circuit protection feature of the trip
unit; the main function of the trip unit is the adjustable tripping function, so
the PM has priority over the other three modules. The PM can meter
current to 20 times the sensor plug rating. For example, for a 400 A sensor
plug, the PM can meter current up to 8,000 A.
• Trip Unit Metering Module (MM)—metering feature of the trip unit
provides true rms-metered data for energy management, and event
detection. The MM can record data up to 1.5 times the sensor plug. For
example, for a 400 A sensor plug, the MM can record data up to 600 A.
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© 2002 Schneider Electric All Rights Reserved
63220-080-200/B1
August 2002
Using MICROLOGIC Electronic Trip Units in a POWERLOGIC System
• MODBUS Breaker Communication Module (BCM)—required module for
communication between the trip unit and a MODBUS communication
network; the BCM acts as a communication gateway between the external
MODBUS network protocol and a peer-to-peer protocol used within the trip
unit system. The BCM provides circuit breaker status information—open,
closed, tripped, spring charged, spring discharged, ready to close, and
mechanism unlatched.
• The BCM also contains:
— an alarm log of date/time stamps for recorded events
— circuit breaker maintenance information
— the means to control the circuit breaker remotely via MODBUS; this
feature requires optional communicating open/close coil(s)
The BCM requires an external 24-Vdc power supply.
NOTE: If the trip unit is externally powered, the power supply for the BCM
must be separate from the one used by the trip unit. This ensures that
electrical isolation between the trip unit and the communications network
is maintained.
An optional communicating module can be used with drawout circuit
breakers:
• Cradle Communication Module (CCM)—optional when a drawout circuit
breaker has a trip unit that communicates via MODBUS; the CCM reads
the position of the circuit breaker: connected, disconnected, or test. The
CCM automatically assigns communication parameters to a circuit
breaker when it’s racked into the test position from the disconnected
position—a feature that allows you to exchange circuit breakers between
compartments without having to change network communication
parameters. The CCM requires an external 24-Vdc power supply.
NOTE: The CCM may share the same power supply as the BCM, but it
must be separate from the one used by the trip unit.
The trip unit modules communicate using a dedicated peer-to-peer protocol
that is designed specifically for the MICROLOGIC Trip Unit system. This
protocol provides the communication link between the PM, MM, and BCM.
© 2002 Schneider Electric All Rights Reserved
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63220-080-200/B1
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Using MICROLOGIC Electronic Trip Units in a POWERLOGIC System
Figure 1 shows how the pieces of the circuit breaker and trip unit fit together.
Modbus (IRS-485) Communication
Cradle
Cradle
Communication
Module (optional)
Cradle Secondary Connections
Circuit Breaker Secondary Connections
Breaker
Communication
Module
IR Communications
Circuit
Breaker
0
ic 2.
olog
Micr
Trip Unit
Meter
Module
Peer-to-Peer
Protocol
Protection
Module
Test Kit
Port
Figure 1:
Network Communication
Trip Unit Architecture
MICROLOGIC trip units communicate via RS-485 MODBUS RTU protocol.
This protocol provides serial communications using either 2-wire or 4-wire
connections at speeds up to 19.2k baud. You can connect up to 32 devices
on a single daisy chain, at distances up to 10,000 feet (3,050 meters).
NOTE: To prevent communication errors, the scan rate should not exceed
500 ms. Faster scan rates may cause internal communication issues
between the trip unit sub-devices.
The trip unit connects to the POWERLOGIC system through one of three
standard communication methods:
• Serial (RS-485 MODBUS RTU), using an MCI-101 converter kit
• Ethernet (MODBUS TCP), using a CM4000 with Ethernet Communication
Card (ECC) or using an Ethernet Gateway (such as EGX-400)
Figures 2, 3, and 4, on the following pages, illustrate simple systems using
each of these communication types. Other architectures are possible;
contact your local sales office for assistance.
For detailed information about system architecture, refer to the
POWERLOGIC System Architecture and Application Guide (order no.
3000DB0001).
4
© 2002 Schneider Electric All Rights Reserved
63220-080-200/B1
August 2002
Using MICROLOGIC Electronic Trip Units in a POWERLOGIC System
POWERLOGIC
System Manager
Software
MCI-101
Converter Kit
RS-485 Daisy Chain
RS-232
MCT-485 or
MCTAS-485
Terminator
MICROLOGIC
Electronic Trip Unit
Figure 2:
Series 4000
Circuit Monitor
Circuit Breaker
Series 2000
Circuit Monitor
or Power Meter
Communication via a PC Serial Port (RS-485 MODBUS RTU)
POWERLOGIC
System Manager
Software
Series 4000
Circuit Monitor
with ECC
RS-485 Daisy Chain
Ethernet (Modbus TCP)
MCT-485 or
MCTAS-485
Terminator
Series 4000
Circuit Monitor
MICROLOGIC
Electronic Trip Unit
Figure 3:
Circuit Breaker
Series 2000
Circuit Monitor
or Power Meter
Communication via a CM4000 Ethernet Communication Card (CM4000 with ECC)
© 2002 Schneider Electric All Rights Reserved
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63220-080-200/B1
August 2002
Using MICROLOGIC Electronic Trip Units in a POWERLOGIC System
POWERLOGIC
System Manager
Software
POWERLOGIC
Ethernet Gateway EGX400
Ethernet (Modbus/TCP))
RS-485 Daisy Chain
MCT-485 or
MCTAS-485
Terminator
Series 4000
Circuit Monitor
MICROLOGIC
Electronic Trip Unit
Figure 4:
Circuit Breaker
Series 2000
Circuit Monitor
or Power Meter
Communication via an Ethernet Gateway
Hardware Setup Checklist
Before you add the MICROLOGIC trip unit to SMS, be sure that you have
completed all of the required hardware setup steps:
1. Be sure that all equipment shipping splits are connected.
2. Confirm that an external 24-Vdc power supply is connected to the BCM
(and CCM, if present).
3. Confirm that a second external 24-Vdc power supply is connected to the
trip unit, if it is not to be self-powered.
Setting Type A Communications Parameters
NOTE: If the trip unit is externally powered, the power supply for the BCM
must be separate from the one used by the trip unit. If you have a CCM,
it can share the BCM’s power supply.
4. Rack the circuit breaker to the Test or Connected position.
5. Confirm that the trip unit has control power (the display will be powered).
6. Set the device address, baud rate, and parity from the HMI.
For the Type A trip unit, follow these steps:
a. From the default Current menu, simultaneously press and hold both
and
until the Communications Address menu displays. The
display will read Ad47.
b. To set the device address, press and release
repeatedly until the
correct address displays. Address range = 01 through 47
(default = 47 ).
c. When the correct address displays, hold down
until the display
begins to flash, then release. The baud rate menu displays
(default = b 19.2).
d. To set the baud rate, press and release
repeatedly until the
correct rate displays. Baud rate range = 1,200 to 19,200.
e. When the correct baud rate displays, hold down
until the display
begins to flash, then release. The parity menu displays (the default =
P E for even parity).
f. To set the parity, press and release
repeatedly until the correct
parity displays. Possible entries are E or n (even or none)
g. When the correct parity displays, hold down
until the display
menu
6
© 2002 Schneider Electric All Rights Reserved
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August 2002
Using MICROLOGIC Electronic Trip Units in a POWERLOGIC System
begins to flash, then release. After several seconds, the trip unit
automatically returns to the Current menu.
Setting Type P and Type H Communications
Parameters
For the Type P or Type H trip unit, follow these steps:
a. From the default Main menu (providing real-time current display),
press
; the Setup menu displays.
); the Communb. Press
or
to select Com Setup. Press (
ication Setup menu displays with Com. parameters selected.
c. Press
to open the Com. parameters window. The MODBUS Com
window displays with the Address selected (default = 47 ).
d. Press
to highlight the address. Press
or
to change the
address to the one that the trip unit will use. Press
to enter the
change.
e. Press
or
to select Baud Rate (default = 19.2k).
f. Press
to highlight the baud rate.
g. Press
or
to change the baud rate to the one that the trip
system modules will use.
h. Press
to enter the change.
i. Press
to select Parity (default = Even).
j. Press
to highlight the parity.
k. Press
or
to change the parity to the one that the trip unit
will use (even or none).
l. Press
to enter the change.
m. Press
to leave the menu. The prompt “Do you want to save new
settings?” displays.
n. Press
to select Yes. Press
to save all of the changes that
you’ve made.
o. Press
to return to the default Main menu.
7. Press the Address sync push button on the CCM (adjacent to the green
LED marked “Comm”). This causes the CCM to read the communications
setup (for this circuit breaker location) from the BCM.
8. Connect the trip system (trip unit, CCM, BCM) to the MODBUS network.
Follow instructions in the MASTERPACT® NW Low-voltage Power Circuit
Breaker instruction bulletin (order no. 48049-106-01) and the instruction
bulletin that was shipped with your MICROLOGIC electronic trip unit. See
the figure on page 68 of this manual for a wiring diagram
9. Connect the MODBUS network to a PC workstation via Ethernet
(Ethernet Gateway connection or CM4000 with ECC) or RS-485 (serial
connection). Follow instructions in the POWERLOGIC System
Architecture and Application Guide (order no. 3000DB0001). See figures
2, 3, and 4 on pages 5 and 6 of this manual for general illustrations of
communication setup.
© 2002 Schneider Electric All Rights Reserved
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Using MICROLOGIC Electronic Trip Units in a POWERLOGIC System
INSTALLATION AND DEVICE SETUP
IN SMS
If you encounter problems with any instructions in this section, refer to
“Troubleshooting” on page 27 for troubleshooting help.
Installing the Software
With SMS version 3.3, you have support for Type A and Type P trip units. With
SMS version 3.3.1, you also have support for Type H trip units. When you
install the SMS software, the corresponding MICROLOGIC device type
software is also installed. To install SMS and its device type software, follow
the installation instructions:
• See the System Manager Software Setup Guide for version 3.3.
• See the Installation Instructions document for version 3.3.1.
Once SMS is installed, you’ll need to add and set up the MICROLOGIC trip
units. See “Adding and Setting Up Trip Units,” below.
If you have any questions, contact your local sales representative. For the
address and telephone number for technical support in your country, see the
Product Registration and Technical Support Contacts sheet. Once SMS is
installed, the list is located at Start > Programs > SMS-nnnn > Tech Support.
Adding and Setting Up Trip Units
After the software is installed, you’ll need to add and set up the MICROLOGIC
trip unit(s) in your SMS system. Instructions for adding and setting up devices
are in the SMS online help file. See the Quick Starts for step-by-step
instructions, which are organized by communication connection type.
The tasks you’ll need to complete are listed below.
1. Add and set up a serial connection in SMS.
2. Add the device.
3. Add the device address (sometimes called device route). This address
must match the address you assigned to the device at the HMI. This step
requires that you plan your addressing in advance.
When you add a MODBUS device in SMS, you add one address or route,
which SMS uses to communicate with that device. For the MICROLOGIC
trip unit, you add the address that you entered at the trip unit HMI; SMS
creates the additional device addresses that are required for the rest of
the trip unit system:
•
•
•
BCM (breaker communication module)—the BCM address is set at the
trip unit HMI
PM (trip unit protection module)—the system adds 100 to the BCM
address
MM (trip unit metering module)—the system adds 200 to the BCM
address
•
CCM (cradle communication module)—installed only if you are using a
drawout circuit breaker : the system adds 50 to the BCM address
NOTE: When entering a MICROLOGIC device in SMS, using an Ethernet
Gateway connection, the device ID should match the address of the BCM
(the address entered at the trip unit HMI).
4. After you add the address, SMS displays a dialog asking you whether you
have a CCM in your trip unit system. If the trip unit system includes a
CCM, check the box.
8
© 2002 Schneider Electric All Rights Reserved
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August 2002
Using MICROLOGIC Electronic Trip Units in a POWERLOGIC System
Figure 5 illustrates how these addresses are determined, when the trip unit
is installed in a drawout circuit breaker.
.
Daisy Chain Connecting Devices
Address
(51)
CCM
(1)
BCM
POWERLOGIC
System Manager
Software
POWERLOGIC
Ethernet Gateway EGX400
(101)
PM
(201)
MM
Circuit
Breaker Cradle
Circuit
Breaker
Circuit Breaker/Trip Unit:
Address 1 (51, 101, 201)
Circuit Monitors and/or
Other Devices:
In this example, do not
assign address
number 51, 101, or 201
to any remaining device
In this example, you might give the trip unit address #1. This step assigns address #1 to the
breaker communication module (BCM). SMS will automatically assign these addresses for the trip unit modules:
• #51 to the crade communication module (CCM)
• #101 to the trip unit protection module (PM)
• #201 to the trip unit meter module (MM)
Figure 5:
Adding a Device Address for the MICROLOGIC Trip Unit
When adding the MICROLOGIC trip unit to an SMS system, you must plan for
the additional addresses of the trip unit system. For example, when
communicating via an Ethernet Gateway (such as an EGX400), be sure that
other devices are not assigned an address that will be automatically
assigned to part of the trip unit system.
The benefit of having the four addresses is that SMS polls the individual parts
of the trip unit system separately. Should an event occur to one part of the
trip unit system, the remaining parts will continue to function and deliver data
to SMS. For example, when the circuit breaker is racked out, the BCM and trip
unit modules cannot communicate, but the CCM continues to provide circuit
breaker position information.
The multiple addresses also help you when you’re troubleshooting the trip
unit system.
© 2002 Schneider Electric All Rights Reserved
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Using MICROLOGIC Electronic Trip Units in a POWERLOGIC System
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VIEWING REAL-TIME INFORMATION
IN SMS
Once you have added the trip unit to your system, you can view real-time
data in SMS as you would for any other POWERLOGIC system compatible
device. See the SMS online help file for information about displaying bar
charts, meters, tables, and function tables for devices within SMS.
USING QUANTITIES
Standard Quantities
For each POWERLOGIC device type, including the MICROLOGIC trip unit,
SMS maintains a database of standard quantities available in the device.
When you define a logging template or display a quick table for a trip unit,
SMS knows the quantities that are available for that device type.
Custom Quantities
In addition to these standard quantities, SMS gives you the option of setting
up additional quantities, called custom quantities. To use these custom
quantities, you must identify them by specifying their location (register
number). When you define custom quantities and assign them to the
device type, you are adding to the database of quantities available for that
device type.
For instructions on adding and assigning custom quantities, see the SMS
online help file.
USING SMS ALARMS
Global alarms are automatically assigned when the trip unit is added to SMS.
However, you can add custom alarms to SMS. The process of setting up
alarms includes these steps:
• creating global analog or digital functions that are to be used to monitor
power system conditions. When you define an analog or digital function,
you select a quantity, then define the conditions (or setpoints) under which
SMS generates the alarm. You also determine the severity of the alarm,
for example, whether the alarm will annunciate (give visual or audible
indication from within SMS) and whether a user must acknowledge it.
• assigning the function to a specific device within the SMS system.
Because you might not want the same alarms for each trip unit, you can
specify the alarms for each one.
For complete instructions on adding global functions and assigning them to
a device, see the SMS online help file.
10
© 2002 Schneider Electric All Rights Reserved
63220-080-200/B1
August 2002
Alarm Levels
Using MICROLOGIC Electronic Trip Units in a POWERLOGIC System
SMS uses a feature called Alarm Severity to determine the level of an alarm
and the information that the alarm provides. There are ten levels of alarm,
0 through 9 (0 is the most severe, 9 the least severe). Although
MICROLOGIC alarms and levels are pre-assigned, you can change the level
(severity) of any alarm. However, keep in mind that changes to a level will
change the amount of information that you will receive when the alarm
becomes active.The following table lists the default alarm severity levels
and their characteristics:
Table 1:
Severity
Level
➄
© 2002 Schneider Electric All Rights Reserved
Audible ➀ Visible ➁
Acknowledge
Required ➂
Password
Required ➃
Alarm
Log ➄
0
X
X
X
X
X
1
X
X
X
X
X
2
X
X
X
X
3
X
X
X
X
4
X
X
X
X
5
X
X
X
6
X
X
7
X
X
8
X
X
9
➀
➁
➂
➃
SMS Default Alarm Levels
X
X
Alarm will sound when it becomes active.
Alarm will make the Active Alarms dialog pop up when it becomes active.
Operator must acknowledge the alarm before it will disappear.
Alarm is password-protected: operator must enter a password (assigned
when adding the user ID) to acknowledge the alarm.
Alarm information displays in the SMS Alarm Log.
11
63220-080-200/B1
August 2002
Using MICROLOGIC Electronic Trip Units in a POWERLOGIC System
Pre-assigned PC-based Alarms and Events
Table 2:
The MICROLOGIC trip unit includes automatically assigned alarms. However,
you can unassign or modify any pre-assigned alarm for a specific device.
Table 2 describes these pre-assigned alarms. Unless otherwise indicated in
the Remarks column, all alarms operate for Type A, Type P, and Type H trip
units.
MICROLOGIC Trip Unit Pre-assigned PC-based Alarms
Digital Function Module2
Name1
Pickup Text /
Alarm Level3
Dropout Text /
Alarm Level3
Polling
Interval
Remarks
Long Delay Pickup
PM
In Progress
(level 1)
Not Picked Up
(no alarm)
15 sec.
Type P and Type H trip units only. Long delay pickup setpoint is exceeded and
trip is imminent if current is not reduced.
Protection Settings
Change
PM
Detected
(level 4)
Not Detected
(no alarm)
300 sec.
Alarm appears when any trip unit protection setpoint is changed.
Rating/Sensor Plug
Changeout
PM
Detected
(level 4)
Not Detected
(no alarm)
300 sec.
Alarm appears when the rating plug type or sensor plug current rating
changes from the last time SMS communicated with the circuit breaker.
Trip Unit Changeout PM
Detected
(level 4)
Not Detected
(no alarm)
300 sec.
Alarm appears when the PM serial number changes from the last time SMS
communicated with the circuit breaker.
Trip Unit Door
Status
Open
(level 5)
Closed
(no alarm)
300 sec.
Type P and Type H trip units only. Indicates trip unit door is open and basic
protection settings switches are exposed.
Breaker Changeout BCM
Detected
(level 4)
Not Detected
(no alarm)
300 sec.
Alarm appears when the BCM serial number changes from the last time
SMS communicated with the circuit breaker.
Breaker Status
BCM
Closed
(no alarm)
Open
(no alarm)
N/A4
Loss of Logging
and Alarming
Capability
BCM
Detected
(level 1)
Not Detected
(no alarm)
60 sec.
Ready to Close
BCM
Yes
(no alarm)
No
(no alarm)
N/A4
Remote Closing
Enabled
BCM
Yes
(no alarm)
No
(no alarm)
N/A4
If Remote Closing is disabled, an attempt to close the circuit breaker in SMS
will result in error code 4500. See Appendix D—MICROLOGIC Trip Unit Error
Codes for information.
Remote Control
Enabled
BCM
Yes
(no alarm)
No
(no alarm)
N/A4
Remote control is enabled/disabled at the trip unit HMI by placing the unit in
Auto/ Manual.
PM
Indicates loss of internal communication to the trip unit. Could be caused by
trip unit being removed or by loss of trip unit auxiliary power.
When remote control is disabled, the SMS pre-defined control outputs
(enable/disable remote closing and opening, and close/ open the circuit
breaker will not operate.
Remote Opening
Enabled
BCM
Yes
(no alarm)
No
(no alarm)
N/A4
If Remote Opening is disabled, an attempt to open the circuit breaker in SMS
will result in error code 4500. See Appendix D—MICROLOGIC Trip Unit Error
Codes for information.
Spring Charged
BCM
Yes
(no alarm)
No
(no alarm)
N/A4
Indicates status of motor-charged closing springs.
Time Loss (BCM)
BCM
Detected
(level 9)
Not Detected
(no alarm)
60 sec.
Indicates that the BCM lost power. An SMS clock reset task automatically
performs the reset with no user action required.
Trip Unit Internal
Comms Failure
BCM
Detected
(level 1)
Not Detected
(no alarm)
60 sec.
Indicates loss of internal communication to the trip unit. Could be caused by
trip unit being removed or by loss of trip unit auxiliary power.
Trip Unit Status
(SDE)
BCM
Fault Tripped
(level 1)
Not Tripped
(no alarm)
15 sec.
Protective trip alarm. This alarm remains until the trip unit is reset. If the trip
unit is Type P or Type H, onboard alarms also appear with the type of trip.
Breaker Between
Positions
CCM
True
(level 5)
False
(no alarm)
60 sec.
Only for models with CCM.
Indicates that the circuit breaker is between Connected and Test or between
Test and Disconnected positions.
Breaker Connected
(CE)
CCM
True
(level 9)
False
(no alarm)
60 sec.
Only for models with a CCM.
Indicates that the circuit breaker is in Connected position.
Breaker
Disconnected (CD)
CCM
True
(level 5)
False
(no alarm)
60 sec.
Only for models with CCM.
Indicates that the circuit breaker is in Disconnected position.
Breaker in Test (CT) CCM
True
(level 5)
False
(no alarm)
60 sec.
Only for models with a CCM.
Indicates that the circuit breaker is in Test position.
Time Loss (CCM)
Detected
(level 9)
Not Detected
(no alarm)
60 sec.
Only for models with a CCM.
Indicates that the CCM lost power. An SMS clock reset task automatically
performs the reset with no user action required.
1.
2.
3.
4.
12
CCM
This name displays in the SMS Activity Log and Active Alarm log.
The module that generates the alarm; BCM = breaker communication module, CCM = cradle communication module, PM = protection module
Although you can change the level for an alarm, keep in mind that each alarm level has specific characteristics: For example, alarm level 9 displays an entry in
the SMS Activity Log, but does not display in the Active Alarms Log.
These functions are polled only when they are included in a file such as a real-time table. The polling is updated according to the interval chosen for that display.
© 2002 Schneider Electric All Rights Reserved
63220-080-200/B1
August 2002
Type P and Type H Pre-assigned On-board
Alarms
Using MICROLOGIC Electronic Trip Units in a POWERLOGIC System
Table 3 lists on-board alarms for Type P and Type H trip units. To enable them
and to enter pickup and dropout setpoints, you must use the HMI. See the trip
unit instruction bulletin for instructions.
The settings and present status of each alarm can be viewed in the
MICROLOGIC Protection Settings table. See “Appendix E—SMS Table
Support” on page 65 for a list of tables included in SMS. See the SMS online
file for help viewing tables.
Table 3:
Type P and Type H Trip Unit On-board Alarms
Function Name
Alarm Level
Long Time Trip (Ir)
2
Short Time Trip (Isd)
2
Instantaneous Trip (Ii)
2
Residual Ground Fault (Ig)
2
Ground Fault - Residual Alarm
4
Current Unbalance
4
Over Current Demand Phase A
4
Over Current Demand Phase B
4
Over Current Demand Phase C
4
Over Current Demand Neutral
4
Under Voltage
2
Over Voltage
4
Voltage Unbalance
4
Reverse Power
4
Under Frequency
4
Over Frequency
4
Phase Rotation
4
Current Load Shedding
4
Power Load Shedding
4
Pre-assigned Task—Resetting the
Device Clock
The clock reset is the only pre-assigned task for a device reset. For more
information about the automatic device clock reset, see “Device Resets” on
page 14. For instructions on using tasks to perform resets, see the SMS
online help file.
USING CONTROL OUTPUTS
SMS uses control outputs to provide remote manual control of devices. For
example, you can use SMS as an interface to open or close a circuit breaker
via a serial, MODBUS, or Ethernet communications network.
Table 4 lists the predefined MICROLOGIC control outputs used in SMS.
Table 4:
MICROLOGIC Control Outputs
Control
© 2002 Schneider Electric All Rights Reserved
Target Device
Circuit Breaker (close/open)
BCM
Open Permissive (enable/disable)
BCM
Close Permissive (enable/disable)
BCM
13
63220-080-200/B1
August 2002
Using MICROLOGIC Electronic Trip Units in a POWERLOGIC System
For any output to be controlled from SMS, you must enable:
• the remote control (Auto/Manual) from the trip unit HMI
• the SMS open/close feature (Setup > Control Outputs) for the control.
If the HMI remote control is enabled, but the SMS open/close feature is
disabled for a control, that control output will not operate. You will see this
message in SMS:
“Control Output Failed!” Communication Error 4500 occurred while
sending the control to the target device. Visual inspection of the
device is recommended.”
The solution is to enable the desired control from the SMS control output
feature as well as from the trip unit HMI.
If remote control (Auto/Manual) is disabled from the trip unit HMI, the attempt
to operate the control from SMS will not work. You will see this message:
“Control Output Failed!”
The solution is to enable the remote control from the trip unit HMI.
DEVICE RESETS
The device reset feature allows you to reset certain data entries for a device
or group of devices. Reset options vary, depending on the device type. You
can perform a reset manually or as a scheduled task. Resets are logged in
the SMS Activity Log.
Table 5 lists the resets that SMS supports for the Type A, Type P, and Type H
trip units:
Table 5:
Micrologic Type A, Type P, and Type H Device Resets
Device Reset
Type A
Type P
Type H
Breaker Event Log
Device Date/Time1
X
X
X
X
x
X
Min/Max
X
X
X
Accumulated Energy
X
X
Trip Unit Alarm Log
X
X
Peak Demand Current
X
X
Peak Demand Power
X
X
Set Alternate (CM2) PF/Var Sign Convention 2
X
X
Set IEC PF/Var Sign Convention 2
X
X
X
X
X
X
Set IEEE PF/Var Sign Convention 2
Operations Counter
X
Four-cycle waveform
X
Metering alarm log
X
1. Device date/time is reset in one of two ways
• At 12:30 a.m., a scheduled task in SMS resets the trip unit’s time.
• When the trip unit loses and regains power, a pre-assigned PC-based alarm
performs the reset with no user action required.
2. Available if the optional VAR sign utility is installed.
14
© 2002 Schneider Electric All Rights Reserved
63220-080-200/B1
August 2002
Using MICROLOGIC Electronic Trip Units in a POWERLOGIC System
METERING CAPABILITIES
The MICROLOGIC Trip Unit system provides real-time readings, demand
readings, and energy readings. Each reading type is discussed fully in the
following paragraphs.
Real-Time Metering
All MICROLOGIC trip units measure currents and report rms values for all
three phases, including neutral/ground current. In addition to these values,
the Type P trip unit measures voltage and calculates power factor, real power,
reactive power, and more. Table 6 lists the real-time readings and shows
which parameters are available.
Table 6:
Real-Time Readings
Current
Range
Per-Phase
0 to 32,767 A (or 0–100% capacity)
Neutral
0 to 32,767 A (or 0–100% capacity)
Ground
0 to 32,767 A (or 0–100% capacity)
Max of 3 Phases and Neutral
0 to 32,767 A
3-Phase Average (Type P and Type H)
0 to 32,767 A
Current Unbalance (Type P and Type H)
–100% to +100%
Voltage (Type P and Type H)
Line–to–Line, per-phase
Range
0 to 1,200 V
3-Phase Average, Line-to-Line
0 to 1,200 V
Line-to-Neutral, per-phase
0 to 1,200 V
3-Phase Average, Line-to-Neutral
0 to 1,200 V
Voltage Unbalance
–100% to +100%
Real Power (Type P and Type H)
3-Phase Total
Per-Phase
Reactive Power (Type P and Type H)
Range
0 to +/–32,767 kW
0 to +/–32,767 kW
Range
3-Phase Total
0 to +/–32,767 kVAR
Per-Phase
0 to +/–32,767 kVAR
Apparent Power (Type P and Type H)
3-Phase Total
Power Factor—True (Type P and Type H)
3-Phase Total
Per Phase
Power Quality (Type H)
Range
0 to 32,767 kVA
Range
–1.00 to +1.00
–1.00 to +1.00
Range
Current Crest Factor, per phase
0 to 100 A
Voltage Crest Factor, per phase
0 to 100 V
Distortion Power, per phase and total
0 to 32,767 kVAR
K-Factor, per phase
0 to 100 A
THD Current, per phase
0 to 500 A
THD Voltage, per phase
0 to 500 V
thd Current, per phase
0 to 1000 A
thd Voltage, per phase
0 to 1000 V
Frequency (Type P and Type H)
System Frequency
Range
50-60 Hz or 400 Hz
Harmonics: Fundamental—31st (Type H only) Range
Voltage Angle
© 2002 Schneider Electric All Rights Reserved
0–360 degrees
Voltage Magnitude
0–100 percent of fundamental
Current Angle
0–360 degrees
Current Magnitude
0–100 percent of fundamental
15
Using MICROLOGIC Electronic Trip Units in a POWERLOGIC System
Min/Max Values
63220-080-200/B1
August 2002
The trip unit stores minimum and maximum (min/max) values for all real-time
readings in nonvolatile memory.
Using SMS, you can:
• view all min/max values
• reset all min/max values
For instructions on using SMS software to view, save, and reset min/max
data, refer to the SMS online help file.
Power Factor Min/Max Conventions
Running min/max values, with the exception of power factor, are arithmetic
minimums and maximums. For example, the minimum phase A–B voltage is
simply the lowest value in the range 0 to 1200 V that has occurred since the
min/max values were last reset. In contrast, because midpoint for a power
factor meters is unity (illustrated in Figure 6), power factor min/max values
are not true arithmetic minimums and maximums. Instead, the minimum
value represents the measurement closest to –0 (most lagging) on a
continuous scale of –0 to 1.00 to +0. The maximum value is the
measurement closest to +0 (most leading) on the same scale.
See “Advanced Topics” on page 23 for information about changing sign
conventions.
16
© 2002 Schneider Electric All Rights Reserved
63220-080-200/B1
August 2002
Using MICROLOGIC Electronic Trip Units in a POWERLOGIC System
Figure 6 shows the power factor min/max values in a typical environment,
assuming a positive power flow. In Figure 6, the minimum power factor is –
0.70 (lagging) and the maximum is +0.80 (leading). It is important to note that
the maximum power factor need not be leading. For example, if the power
factor values ranged from –0.75 (lagging) to –0.95 (lagging), then the
minimum power factor would be –0.75 (lagging) and the maximum power
factor would be –0.95 (lagging). Likewise, if the power factor ranged from
+0.90 to +0.95, the minimum would be +0.95 (leading) and the maximum
would be +0.90 (leading).
Figure 7 shows a sign convention chart for the default IEEE sign convention.
Minimum
Power Factor
–0.7 (lagging)
Maximum
Power Factor
0.8 (leading)
Range of Power
Factor Values
Unity
1.00
.8
.8
.6
.6
Lead
(+)
Lag
(–)
.4
.4
.2
.2
+0
-0
Figure 6:
Power Factor Min/Max Values
Reactive
Power
Quadrant
2
Quadrant
1
Watts Negative (–)
VARs Positive (+)
Watts Positive (+)
VARs Positive (+)
PF Leading (+)
Reverse Power Flow
Watts Negative (–)
VARs Negative (–)
Watts Positive (+)
VARs Negative (–)
PF Lagging (–)
PF Leading (+)
Quadrant
3
Figure 7:
© 2002 Schneider Electric All Rights Reserved
PF Lagging (–)
Normal Power Flow
Real
Power
Quadrant
4
IEEE Sign Convention (default)
17
63220-080-200/B1
August 2002
Using MICROLOGIC Electronic Trip Units in a POWERLOGIC System
Demand Readings
The Type P and Type H trip units provide a variety of demand readings,
including coincident readings and predicted demands. Table 7 lists the
available demand readings.
Table 7:
Type P and Type H Trip Unit Demand Readings
Demand Current
Type P
Type H
Present, Per-Phase and Neutral
0 to 32,767 A
X
X
Peak, Per-Phase and Neutral
0 to 32,767 A
X
X
Peak K-Factor Demand, Per-Phase and Neutral
0 to 32,767 A
Predicted, Per-Phase and Neutral
0 to 32,767 A
Average Power Factor (True), 3-Phase Total
X
Type P
Type H
X
Present
–1.00 to +1.00
X
Coincident with kW Peak
–1.00 to +1.00
X
X
Coincident with kVAR Peak
–1.00 to +1.00
X
X
Coincident with kVA Peak
–1.00 to +1.00
X
X
Type P
Type H
K-Factor Demand
Present, Per-Phase and Neutral
0 to 100 (no units)
At Peak Demand Current, Per-Phase and Neutral
0 to 100
X
Peak, Per-Phase and Neutral
0 to 100
X
Predicted, Per-Phase and Neutral
0 to 100
Demand Real Power, 3-Phase Total
X
X
Type P
Type H
Present
0 to 32,767 kW
X
X
Predicted
0 to 32,767 kW
X
X
Peak
0 to 32,767 kW
X
X
Coincident kVAR
0 to 32,767 kVAR
X
X
Coincident kVA
0 to 32,767 kVA
X
X
Type P
Type H
Demand Reactive Power, 3-Phase Total
Present
0 to 32,767 kVAR
X
X
Predicted
0 to 32,767 kVAR
X
X
Peak
0 to 32,767 kVAR
X
X
Coincident kW
0 to 32,767 kW
X
X
Coincident kVA
0 to 32,767 kVA
Demand Apparent Power, 3-Phase Total
18
X
X
X
Type P
Type H
Present
0 to 32,767 kVA
X
X
Predicted
0 to 32,767 kVA
X
X
Peak
0 to 32,767 kVA
X
X
Coincident kW
0 to 32,767 kW
X
X
Coincident kVAR
0 to 32,767 kVAR
X
X
© 2002 Schneider Electric All Rights Reserved
63220-080-200/B1
August 2002
Demand Power and Current
Calculation Methods (Type P)
Using MICROLOGIC Electronic Trip Units in a POWERLOGIC System
To be compatible with electric utility billing practices, the Type P trip unit
provides the following types of demand power calculations:
• sliding demand
• block interval demand
A brief description of each demand method follows:
Sliding Demand (default)
The sliding demand method calculates the demand based on a running
average value and updates its demand calculation every 15 seconds on a
sliding window basis. You can select the demand interval from 5 to 60
minutes in 1-minute increments.
Block Interval Demand
The block interval demand mode supports a standard block interval
calculation for compatibility with electric utility electronic demand registers.
In standard block interval mode, you can select a demand interval from 5 to
60 minutes in 1-minute increments. The demand calculation is performed at
the end of each interval. The present demand value displayed by the trip unit
is the value for the last completed demand interval.
The demand calculation method and interval are set up from the HMI. To
change the demand method or interval, follow these steps:
Changing the Type P Demand Power Method or Interval
1. From the default Main menu of a Type P trip unit, press
; the Setup
menu displays.
2. Press
or
to select Metering Setup.
3. Press
; the Metering Setup menu displays.
4. Press
or
to select Power Demand.
5. Press
; the Power Demand window displays with the window type
selected (default = Sliding Window).
6. To change the window type, press
to highlight the type.
7. Press
or
to change the type; the two options are Block and
Sliding.
8. Press
to enter the change.
9. Press
to select the interval time.
10. Press
to highlight the interval time (default = 15 minutes).
11. To change the default, press
or
until the correct interval
displays. The interval range is 5–60 minutes.
12. Press
then press
to set the desired interval. The prompt “Do you
want to save new settings?” displays.
13. Press
to select Yes. Press
to save the change that you’ve
made.
14. Press
to return to the default Main menu.
Changing the Type P Demand Current Method or Interval
1. From the default Main menu of a Type P trip unit, press (
); the Setup
menu displays.
2. Press
or
to select Metering Setup.
3. Press
; the Metering Setup menu displays.
4. Press
or
to select Current Demand.
5. Press
to display the current demand window. The default method
(Sliding Window) cannot be changed. Demand interval is selected.
© 2002 Schneider Electric All Rights Reserved
19
Using MICROLOGIC Electronic Trip Units in a POWERLOGIC System
63220-080-200/B1
August 2002
6. Press
to highlight the interval time (default = 5 minutes).
7. To change the default, press
or
until the correct interval
displays. The interval range is 5–60 minutes.
8. Press
then press
to set the desired interval. The prompt “Do you
want to save new settings?” displays.
9. Press
to select Yes. Press
to save the change that you’ve
made.
10. Press
to return to the default Main menu.
Demand Power and Current
Calculation Methods (Type H)
The Type H trip unit provides the following types of demand power
calculations:
• block interval
• thermal calculation
• sync to comms
Block Interval Demand (default)
The block interval demand method supports two window types for
compatibility with electric utility electronic demand registers:
• In the standard block window type, you can select a demand interval from
5 to 60 minutes in 1-minute increments. The demand calculation is
performed at the end of each interval. The present demand value
displayed by the trip unit is the value for the last completed demand
interval.
• The sliding block window type calculates the demand based on a running
average value and updates its demand calculation every 15 seconds on a
sliding window basis. You can select the demand interval from 5 to 60
minutes in 1-minute increments.
Thermal Calculation Demand
The thermal calculation demand method calculates the demand based on a
thermal response and updates its demand calculation every 15 seconds on
a sliding window basis. The user can select the demand interval from 5 to 60
minutes in 1-minute intervals.
Sync to Comms Demand
The sync to comms method is available only with the communication option.
This function determines demand power based on a signal from the
communication module.
The demand calculation method, window type, and interval are set up for the
Type H trip unit from either SMS or the HMI. To make these changes, follow
these steps:
Changing the Type H Demand Power Method or Interval
1. From the default Main menu of a Type H trip unit, press
; the Setup
menu displays.
2. Press
or
to select Metering Setup.
3. Press
; the Metering Setup menu displays.
4. Press
or
to select Power Demand.
5. Press
; the Power Demand window displays with the calculation
method selected (default = Block Interval).
20
© 2002 Schneider Electric All Rights Reserved
63220-080-200/B1
August 2002
Using MICROLOGIC Electronic Trip Units in a POWERLOGIC System
6. To change the calculation method, press
to highlight the method.
7. Press
or
to change the method.
8. Press
to enter the change.
9. Press
to select the window type.
10. To change the window type (only for Block Interval Demand), press
to highlight the window type.
11. Press
or
to change the window type.
12. Press
to enter the change.
13. Press
to select the interval time.
14. Press
to highlight the interval time (default = 15 minutes).
15. To change the default, press
or
until the correct interval displays.
The interval range is 5–60 minutes.
16. Press
then press
to set the desired interval. The prompt “Do you
want to save new settings?” displays.
17. Press
to select Yes. Press
to save the change that you’ve made.
18. Press
to return to the default Main menu.
Changing the Type H Demand Current Method or Interval
1. From the default Main menu of a Type H trip unit, press (
); the Setup
menu displays.
2. Press
or
to select Metering Setup.
3. Press
; the Metering Setup menu displays.
4. Press
or
to select Current Demand.
5. Press
to display the current demand window. The default method
(Sliding Window) cannot be changed. Demand interval is selected.
6. To change the calculation method, press
to highlight the method.
7. Press
or
to change the method.
8. Press
to enter the change.
9. Press
to highlight the window type (only for Sliding Block Window
type).
10. Press
to highlight the interval time (default = 5 minutes).
11. To change the default, press
or
until the correct interval displays.
The interval range is 5–60 minutes.
12. Press
then press
to set the desired interval. The prompt “Do you
want to save new settings?” displays.
13. Press
to select Yes. Press
to save the change that you’ve made.
14. Press
to return to the default Main menu.
Predicted Demand
© 2002 Schneider Electric All Rights Reserved
Type P and Type H trip units calculate predicted demand for kW, kVAR, and
kVA. The predicted demand is calculated by extrapolating the present value
of demand to the end of the interval. This calculation method responds very
quickly and provides an excellent approximation of the actual demand at the
end of the interval. The predicted demand values are updated every 15
seconds.
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Using MICROLOGIC Electronic Trip Units in a POWERLOGIC System
Figure 8 shows how a change in load can affect predicted demand.
Beginning
of interval
Demand for
last completed
interval
15-minute interval
Predicted demand if load is
added during interval,
predicted demand increases
to reflect increased demand
Partial Interval
Demand
Predicted demand if no load
is added
Time
1:00
1:06
1:15
Change in Load
Predicted demand is updated every second until the interval is complete.
Figure 8:
Peak Demands
MICROLOGIC Trip Unit Predicted Demand
Type P and Type H trip units maintain, in nonvolatile memory, a running
maximum—called peak demand—for each demand current and demand
power value. They also store the date and time of each peak demand. In
addition to the peak demand, the trip unit stores the coinciding average
(demand) 3-phase power factor. The average 3-phase power factor is
defined as “demand kW / demand kVA” for the demand interval.
Peak demand values can be reset over the communications link using SMS.
Energy Readings
Type P and Type H trip units provide total accumulated energy values for
kWh, kVARh, and kVAh. The trip unit also calculates and stores in nonvolatile
memory accumulated values for real energy (kWh) and reactive energy
(kVARh) both into and out of the load. These values can be displayed on the
trip unit, or read over the communications link.
Type P and Type H trip units can accumulate energy values in one of two
modes: signed or absolute (unsigned). In signed mode, the trip unit considers
the direction of power flow, allowing the accumulated energy magnitude to
both increase and decrease. In absolute mode, the trip unit accumulates
energy as positive, regardless of the direction of power flow; in other words,
the energy value increases, even during reverse power flow. The default
accumulation mode is absolute.
Table 8 lists available accumulated energy values.
Table 8:
Type P and Type H Energy Readings
Energy Type
22
Accumulated Energy Values
Real (Signed/Absolute)
0 to 9,999,999,999,999,999 kWh
Reactive (Signed/Absolute)
0 to 9,999,999,999,999,999 kVARh
Apparent (Absolute)
0 to 9,999,999,999,999,999 kVAh
Real (In)
0 to 9,999,999,999,999,999 kWh
Real (Out)
0 to 9,999,999,999,999,999 kWh
Reactive (In)
0 to 9,999,999,999,999,999 kVARh
Reactive (Out)
0 to 9,999,999,999,999,999 kVARh
© 2002 Schneider Electric All Rights Reserved
63220-080-200/B1
August 2002
Using MICROLOGIC Electronic Trip Units in a POWERLOGIC System
Harmonic Readings
The Type H trip unit includes on-board harmonic analysis through the 31st
harmonic. Harmonic variables are refreshed every 30 seconds. A spectrum
can be viewed from the trip unit HMI.
Real-Time Power Quality Quantities
The Type H trip unit captures the following real-time power quality quantities:
•
•
•
•
•
•
•
•
•
•
apparent current per phase
P, Q, S per phase
P, Q, S demand per phase
power factor per phase
crest factor (I, V)
K-factor
K-factor demand
THD, thd (line-to-line for 3-wire; line-to-neutral for 4-wire)
distortion power per phase
fundamental magnitudes (I, V)
(line-to-line for 3-wire; line-to-neutral for 4-wire)
Waveform Capture
The Type H trip unit includes a 4-cycle waveform capture. This waveform
capture can be acquired automatically or manually. After you assign it to one
of the 53 metering alarms, the waveform capture is acquired when the
metering alarm is activated. To manually trigger a capture, click the Display
Waveform Plots button on the SMS main toolbar.
ADVANCED TOPICS
This section includes discussion of these advanced topics:
• VAR sign and power factor sign conventions
• time synchronization
Changing the VAR and Power Factor
Sign Convention
The trip unit offers two reactive power (VAR) sign conventions and three
power factor sign conventions. The trip unit allows three combinations of the
VAR sign convention and the power factor (PF) sign convention.
The IEEE sign convention, shown in Figure 9, is achieved by combining the
IEEE VAR sign convention with the IEEE power factor sign convention. The
IEEE sign convention is the default.
Reactive
Power
Quadrant
2
Quadrant
1
Watts Negative (–)
VARs Positive (+)
Watts Positive (+)
VARs Positive (+)
PF Leading (+)
Reverse Power Flow
Watts Negative (–)
VARs Negative (–)
Watts Positive (+)
VARs Negative (–)
PF Lagging (–)
PF Leading (+)
Quadrant
3
Figure 9:
© 2002 Schneider Electric All Rights Reserved
PF Lagging (–)
Normal Power Flow
Real
Power
Quadrant
4
IEEE Sign Convention (default)
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August 2002
Using MICROLOGIC Electronic Trip Units in a POWERLOGIC System
The IEC sign convention, shown in Figure 10, is achieved by combining the
IEEE VAR sign convention with the IEC power factor sign convention.
Reactive
Power
Quadrant
2
Quadrant
1
Watts Negative (–)
VARs Positive (+)
Watts Positive (+)
VARs Positive (+)
PF Leading (–)
PF Lagging (+)
Reverse Power Flow
Normal Power Flow
Watts Negative (–)
VARs Negative (–)
Watts Positive (+)
VARs Negative (–)
PF Lagging (–)
PF Leading (+)
Quadrant
3
Real
Power
Quadrant
4
Figure 10: IEC Sign Convention
The third sign convention is identified as Alternate (CM2). The Alternate sign
convention allows the MICROLOGIC trip unit reactive power and power factor
data to match existing POWERLOGIC circuit monitors and power meters.
The Alternate sign convention shown in Figure 11, is achieved by combining
the Alternate (CM2) VAR sign convention with the IEEE power factor
sign convention.
Quadrant
2
Quadrant
1
Watts Negative (–)
VARs Negative (–)
Watts Positive (+)
VARs Negative (–)
PF Lagging (–)
PF Leading (+)
Reverse Power Flow
Normal Power Flow
Watts Negative (–)
VARs Positive (+)
Watts Positive (+)
VARs Positive (+)
PF Lagging (–)
PF Leading (+)
Quadrant
3
Real
Power
Quadrant
4
Reactive
Power
Figure 11: Alternate (CM2) Sign Convention
Changing VAR Sign Convention Within SMS
To change the VAR sign convention within SMS, use the Reset feature
(Control > Resets). Select the MICROLOGIC device type, then select the
reset for the desired sign convention. For a list of MICROLOGIC device
resets within SMS, see Table 5 on page 14.
24
© 2002 Schneider Electric All Rights Reserved
63220-080-200/B1
August 2002
Using MICROLOGIC Electronic Trip Units in a POWERLOGIC System
Changing VAR and PF Sign Conventions from the Trip Unit HMI
For the Type P and Type H trip units, you can change the VAR/PF sign
conventions from the trip unit HMI. Follow these instructions:
1. From the default Main menu of a Type P or Type H trip unit, press (
);
the Setup menu displays.
2. Press
or
to select Metering Setup.
3. Press
; the Metering Setup menu displays.
4. Press
or
to select Sign convention.
5. Press
to highlight the choices.
6. Press
to display the Sign Convention window (default = IEEE).
7. To change the default, press
or
until the correct convention
displays. Selections are IEEE, IEC, and Alternate (CM2).
8. Press
then press
to set the desired convention. The prompt “Do
you want to save new settings?” displays.
9. Press
to select Yes. Press
to save the change that you’ve made.
10. Press
Time Synchronization
to return to the default Main menu.
The MICROLOGIC trip unit system modules rely on external sources to set
and synchronize their internal clocks.
If either the SMS Alarm Log or the Trip Unit Alarm Log displays a date that is
25 years earlier than the correct date, the trip unit has lost, and then
regained, power. You do not need to take any action; SMS will reset the
date/time the next time it communicates with the trip unit.
Bit 15 of the Month/Day register for the trip unit (register 9001), BCM (register
679), and CCM (register 679) indicates that the date/time has not been set in
the module since it was last powered. To clear this bit, use one of the
following methods:
BCM and Trip Unit:
Use the MODBUS network (SMS Resets or a MODBUS master device) or the
trip unit HMI.
CCM:
Use the MODBUS network (SMS Resets or a MODBUS master device).
Instructions for using each method follow.
Setting Date/Time via SMS Resets
1. From the SMS Main menu, click Control > Resets. The Reset Device
Data dialog box displays.
2. At the Device Types field, click the type of device you want to reset
(MicroLogic Type H, MicroLogic Type A, or MicroLogic Type P). The
resets for that device type are listed in the Resets Available box at the
bottom left of the dialog box.
3. At the Devices Available field, select the specific device(s) that you want
to reset. To select a device, click the device name, then click >; or drag
and drop the device in the Devices Chosen box.
4. At the Resets Available field, select the reset(s) you want to include. To
select a reset, click the reset name, then click >; or drag and drop the
reset in the Resets Chosen box.
5. Click Reset. The message Reset Operation(s) passed displays. Click
Close to return to the SMS main window.
See Table 5 on page 14 for a list of resets that you can perform for
MICROLOGIC trip units.
© 2002 Schneider Electric All Rights Reserved
25
63220-080-200/B1
August 2002
Using MICROLOGIC Electronic Trip Units in a POWERLOGIC System
Setting Date/Time via MODBUS Master Device
Write the following values to the BCM and trip unit via the MODBUS network
(BCM address is set through and shown on the trip unit HMI).
Table 9:
BCM/Trip Unit Values for Setting Date/Time
Register
Data
7700
61541 (0xF065)
Command to set date/time
7701
5
Number of parameters included with the command
7702
4
Trip system module ID (BCM = 4, PM = 2, MM = 8)
MM = month (1-12)1, DD = day (1-31)2
7703
MM:DD
7704
YY:HH
7705
MM:SS
1. high byte
Description
YY = year (0-199)1, HH = hour (0-23)2
MM = minute (0-59)1, SS = second (0-59)2
2. low byte
Write the following values to the CCM via the MODBUS network (CCM
address is equal to the BCM address plus 50; example: BCM address = 1,
CCM address = 51).
Table 10: CCM Values for Setting Date/Time
Register
Data
Description
7700
61541 (0xF065)
7703
MM:DD
7704
YY:HH
Command to set date/time
MM = month (1-12)1, DD = day (1-31)2
YY = year (0-199)1, HH = hour (0-23)2
7705
MM:SS
MM = minute (0-59)1, SS = second (0-59)2
1. high byte
2. low byte
Changing the Date/Time via the HMI
To set the date/time in the BCM and Type P or Type H trip unit via the trip unit
HMI, follow these steps.
1. From the default Main menu of a Type P or Type H trip unit, press
the Setup menu displays.
2. Press
or
to select Micrologic setup.
3. Press
; the Micrologic setup menu displays.
4. Press
or
to select Date/time.
5. Press
; the Date/Time dialog displays.
6. Press
or
to select the Date.
7. Press
to highlight the Month.
8. Press
or
to select the two-digit month (01–12).
9. Press
to highlight the Date field.
10. Press
or
to select the two-digit date (01–31).
11. Press
to highlight the Year field.
12. Press
or
to select the four-digit year.
13. Press
to select the Hour.
14. Press
to highlight the Hour field.
15. Press
or
to select the two-digit hour (01–24).
16. Press
to highlight the Minute field.
17. Press
or
to select the two-digit minute (01–60).
26
);
© 2002 Schneider Electric All Rights Reserved
63220-080-200/B1
August 2002
Using MICROLOGIC Electronic Trip Units in a POWERLOGIC System
18. Press
to highlight the Second field.
19. Press
or
to select the two-digit seconds (01–60).
20. When you’ve finished setting the date/time, press
twice to return to
the default Main menu.
TROUBLESHOOTING
If the trip unit is not communicating with SMS, follow the list below to ensure
that the equipment is properly installed and configured.
DANGER
HAZARD OF ELECTRIC SHOCK, BURN, OR EXPLOSION
• This equipment must be installed and serviced only by qualified
personnel.
• Qualified persons performing diagnostics or troubleshooting that
require electrical conductors to be energized must comply with
NFPA 70 E - Standard for Electrical Safety Requirements for Employee
Workplaces and OSHA Standards - 29 CFR Part 1910 Subpart
S - Electrical.
• Carefully inspect the work area for tools and objects that may have
been left inside the equipment.
• Use caution while removing or installing panels so that they do not
extend into the energized bus; avoid handling the panels, which could
cause personal injury.
Failure to follow these instructions will result in death or serious
injury.
1. If the trip unit and BCM are communicating in SMS, but the CCM is not
communicating, it’s likely that you didn’t press the Address sync push
button when you set up the hardware. See “Hardware Setup Checklist”
on page 6 for complete instructions.
2. View the position indicator on the front panel of the circuit breaker to
ensure that the circuit breaker is in the test or connected position.
3. Referring to the drawings included with the equipment, confirm that all
equipment shipping splits are connected.
4. Confirm that 24-Vdc power sources are connected for the CCM, BCM,
and trip unit. Follow these procedures:
• View the LEDs on the CCM (see steps 7 and 8 in this list for an
explanation of LED combinations)
• measure the voltage on the “Comms” secondary on terminals E1 and E2
• examine the trip unit display
5. Examine the communications cabling at the CCM and circuit breaker
secondaries; make sure the communications wires are correctly
connected (see Figure 1 on page 68 for wire color coding).
6. Check the address, baud rate, and parity of the trip unit at the HMI, in
SMS, and, if applicable, in the Ethernet Gateway. Make sure that you’ve
assigned the same settings in each place.
© 2002 Schneider Electric All Rights Reserved
27
63220-080-200/B1
August 2002
Using MICROLOGIC Electronic Trip Units in a POWERLOGIC System
7. View the LEDs on the CCM to be sure there is MODBUS activity on the
network and at the device. The options are:
LED Display
Condition
No LEDs
24-Vdc control power not present.
One solid green LED:
24-Vdc control power is present, but there is no traffic on the
MODBUS network.
One solid red LED:
CCM has failed its self test.
One solid green LED with
short voids:
CCM is receiving good MODBUS packets.
One solid green LED with
short red flashes:
CCM is receiving MODBUS packets with errors.
Red and green LEDs flash
intermittently:
In a mixed-mode system (POWERLOGIC and
MODBUS / Jbus devices), this is normal.
8. After pressing the “Address sync” push button on the CCM, or after
racking a circuit breaker into Test position, the red and green LEDs will
blink simultaneously while the system attempts to synchronize
communications parameters. This could take up to ten seconds.
Then, the LEDs will indicate the success of the process. Possible status
indications are:
Three flashes of the green LED, followed by a quick flash of the red LED:
Communications information was successfully transferred.
Three flashes of the red LED:
An error occurred in transferring communications information.
9. When a control output does not operate, consider the following causes:
• non-communicating shunt trip and close coils
• remote control is not enabled (must be done from the HMI)
• the circuit breaker is tripped
• when attempting to close, remote close is not enabled
• when attempting to open, remote open is not enabled
10. If you see error 4608 in the SMS Alarm Log, one or more sub-devices are
not communicating.
The alarm information in the Alarm Log displays the trip unit device and
the words “Communication Loss.”
The SMS Activity Log displays in the following manner:
Figure 12: Activity Log
In this example, the error 401 entries show that communication was lost
with the trip unit and the BCM.
28
© 2002 Schneider Electric All Rights Reserved
63220-080-200/B1
August 2002
Appendix A–Type A Standard Quantities
Using MICROLOGIC Electronic Trip Units in a POWERLOGIC System
APPENDIX A—TYPE A STANDARD
QUANTITIES
SMS Topic Name
User Description
This is an abbreviated list of standard quantities. Use these quantities in the
Windows program Dynamic Data Exchange (DDE)—to set up spreadsheets,
drawings, reports, and custom tables for viewing SMS data. For a complete
list of registers, contact your local sales representative. The quantities are
listed in alphabetical order according to the SMS topic name. Unless
otherwise noted, all topics are signed integers. The table below lists the
quantities for the Type A trip unit.
Number of
Registers
Register1
Module
Units
Scale/Bitmask
810DBrkrStatus
Breaker Status
1
661
BCM
Bit 0; ON = closed, OFF = open
810DBrkrTripStat
Breaker Trip Unit Status
1
661
BCM
Bit 2 ON = tripped, OFF = not tripped
BCM_SN
BCM Serial Number
4
516
BCM
ASCII text
BkrPos
Breaker Position
1
661
CCM
Bit 8 = disconnected
Bit 9 = connected
Bit 10 = test position
DT_3Regs
Device Clock Date/Time
3
679
BCM
3-register date/time format2
EnableCloseBkr
Remote Closing Enabled
1
669
BCM
Bit 2; ON = enabled, OFF = not enabled
EnableOpenBkr
Remote Opening Enabled
1
669
BCM
Bit 1; ON = enabled; OFF = not enabled
EnableRemCtrl
Remote Control Enabled
1
669
BCM
Bit 3; ON = auto (enabled);
OFF = manual (not enabled)
IA
Current A
1
8821
PM
A
IA_PCT
Current A % Load
1
8837
PM
%
Unity
IB
Current B
1
8822
PM
A
Unity
IB_PCT
Current B % Load
1
8838
PM
%
Unity
IC
Current C
1
8823
PM
A
Unity
IC_PCT
Current C % Load
1
8839
PM
%
Unity
IG
Current G
1
8825
PM
A
Unity
IG_PCT
Current G % Load
1
8841
PM
%
Unity
IG_PCT_VIGI
Current G (VIGI) % Load
1
8842
PM
%
Hundredths
IG_VIGI
Current G (VIGI)
1
8826
PM
A
Thousandths
IMax
Current Max Present
1
8820
PM
A
Unity
IN
Current N
1
8824
PM
A
Unity
IN_PCT
Current N % Load
1
8840
PM
%
LDPUValue
Long Delay Pickup Value
2
8756
PM
A
Unity
Modulo 10,000 format3
MaxIA
Max Current A
1
8827
PM
A
Unity
MaxIB
Max Current B
1
8828
PM
A
Unity
MaxIC
Max Current C
1
8829
PM
A
Unity
MaxIG
Max Current G
1
8831
PM
A
Unity
MaxIG_VIGI
Max Current G (VIGI)
1
8832
PM
A
Thousandths
MaxIN
Max Current N
1
8830
PM
A
Unity
NominalCurrent
Breaker Nominal Current
1
8750
PM
A
Unity
ReadyToClose
Breaker Ready to Close
1
661
BCM
TU_BATT_PCT
Trip Unit % Battery
1
8843
PM
%
Unity
TU_SN
Trip Unit Serial Number
4
8700
PM
ASCII text
TUCommStatus
Trip Unit Internal Comms Status
1
552
BCM
Bit 11; ON = not responding, OFF = OK
1.
2.
3.
Unity
Bit 5; ON = yes, OFF = no
For register entries that are not listed, please refer to the MICROLOGIC device type register list. Contact your local sales representative.
3-register date/time format:
register 1: month (byte 1) = 1–12; day (byte 2) = 1–31
register 2: year (byte 1) = 0–199 (add to 1900 to determine the actual year); hour (byte 2) = 0–23
register 3: minutes (byte 1) = 0–59; seconds (byte 2) = 0–59
Note: Bits 14 and 15 of the month/day register must be masked.
Modulo 10,000 format: 1 to 4 sequential registers. Each register is Modulo 10,000 (range = –9,999 to +9,999).
Result is [R4*10,000^3 + R3*10,000^2 + R2*10,000^1] + R1. Range is zero to 9,999,999,999,999,999.
© 2002 Schneider Electric All Rights Reserved
29
Appendix A–Type A Standard Quantities
Using MICROLOGIC Electronic Trip Units in a POWERLOGIC System
30
63220-080-200/B1
August 2002
© 2002 Schneider Electric All Rights Reserved
63220-080-200/B1
August 2002
Appendix B–Type P Standard Quantities
Using MICROLOGIC Electronic Trip Units in a POWERLOGIC System
APPENDIX B—TYPE P STANDARD
QUANTITIES
SMS Topic Name
User Description
This is an abbreviated list of standard quantities. You can use these
quantities in the Windows program Dynamic Data Exchange (DDE)—to set
up spreadsheets, drawings, reports, and custom tables for viewing SMS
data. For a complete list of registers, contact your local sales representative.
The quantities are listed in alphabetical order according to the SMS topic
name. Unless otherwise noted, all topics are signed integers. The table
below lists the quantities for the Type P trip unit.
Number of
Registers
Register1
Module
Units
Scale/Bitmask
810D_LDPU
Breaker LDPU in Progress
1
8862
PM
Scaling N/A
810DBrkrStatus
Breaker Status
1
661
BCM
Bit 0; ON = closed, OFF = open
810DBrkrTripStat
Breaker Trip Unit Status
1
661
BCM
Bit 2; ON = tripped; OFF = not tripped
AccumMode
Energy Accumulation Mode
1
3324
MM
0 = Absolute
1 = Signed
BCM_SN
BCM Serial Number
4
516
BCM
ASCII text
BkrPos
Breaker Position
1
661
CCM
Bit 8 = disconnected
Bit 9 = connected
Bit 10 = test position
CurrentDmdInt
Current/K-Factor Demand Interval
1
3352
MM
DT_3Regs
Device Clock Date/Time
3
679
BCM
DTLastTrip
D/T of Last Trip
3
693
BCM
DTPkIAD
D/T Peak Demand Current A
3
3005
MM
DTPkIBD
D/T Peak Demand Current B
3
3008
MM
DTPkICD
D/T Peak Demand Current C
3
3011
MM
DTPkIND
D/T Peak Demand Current N
3
3014
MM
DTPkkVAD
D/T Peak Demand Apparent Power
3
3023
MM
DTPkkVARD
D/T Peak Demand Reactive Power
3
3020
MM
DTPkkWD
D/T Peak Demand Real Power
3
3017
MM
DTResetEnergy
D/T Last Reset Accum. Energies
3
3038
MM
DTResetMinMax
D/T Last Reset Min/Max
3
9010
PM
Minutes
Unity
3-register date/time format2
3-register date/time format2
3-register date/time format2
3-register date/time format2
3-register date/time format2
3-register date/time format2
3-register date/time format2
3-register date/time format2
3-register date/time format2
3-register date/time format2
DTResetPkID
D/T Last Reset Peak Dmd Currents
3
3026
MM
3-register date/time format2
3-register date/time format2
DTResetPkkWD
D/T Last Reset Peak Dmd Power
3
3029
MM
3-register date/time format2
EnableCloseBkr
Remote Closing Enabled
1
669
BCM
Bit 2; ON = enabled; OFF = not enabled
EnableOpenBkr
Remote Opening Enabled
1
669
BCM
Bit 1; ON = enabled; OFF = not enabled
EnableRemCtrl
Remote Control Enabled
1
669
BCM
Bit 3; ON = auto (enabled);
OFF = manual (not enabled)
GFAlarmStatus
GF Alarm Status
1
8860
PM
Bit 0; ON = active; OFF = inactive
GFPreAlarmStatus
GF Alarm Pre-Alarm Status
1
8864
PM
Hz
Frequency
1
1054
MM
Hz
Bit 0; ON = active; OFF = inactive
IA
Current A
1
1016
MM
A
Unity
IA_PCT
Current A % Load
1
8837
PM
%
Unity
Tenths
IAD
Demand Current A
1
2200
MM
A
Unity
IAvg
Current Avg
1
1027
MM
A
Unity
IB
Current B
1
1017
MM
A
Unity
IB_PCT
Current B % Load
1
8838
PM
%
Unity
1.
2.
3.
4.
For register entries that are not listed, please refer to the MICROLOGIC device type register list. Contact your local sales representative.
3-register date/time format:
register 1: month (byte 1) = 1–12; day (byte 2) = 1–31
register 2: year (byte 1) = 0–199 (add to 1900 to determine the actual year); hour (byte 2) = 0–23
register 3: minutes (byte 1) = 0–59; seconds (byte 2) = 0–59
Note: Bits 14 and 15 of the month/day register must be masked.
Modulo 10,000 format: 1 to 4 sequential registers. Each register is Modulo 10,000 (range = –9,999 to +9,999).
Result is [R4*10,000^3 + R3*10,000^2 + R2*10,000^1] + R1. Range is zero to 9,999,999,999,999,999.
Power factor format: –1 to –999 for lagging power factors, 1000 for unity power factor 1.000, and 1 to 999 for leading power factors.
© 2002 Schneider Electric All Rights Reserved
31
Appendix B–Type P Standard Quantities
Using MICROLOGIC Electronic Trip Units in a POWERLOGIC System
Number of
Registers
63220-080-200/B1
August 2002
Register1
Module
1
2201
MM
A
Current C
1
1018
MM
A
Unity
IC_PCT
Current C % Load
1
8839
PM
%
Unity
ICD
Demand Current C
1
2202
MM
A
IDCalcMeth
Current Demand Calculation Method
1
3351
MM
IG
Current G
1
1021
MM
A
Unity
IG_PCT
Current G % Load
1
8841
PM
%
Unity
IG_PCT_VIGI
Current G (VIGI) % Load
1
8842
PM
%
Hundredths
IG_VIGI
Current G (VIGI)
1
8826
PM
A
Thousandths
SMS Topic Name
User Description
IBD
Demand Current B
IC
Units
Scale/Bitmask
Unity
Unity
0 = Sliding
1 = Thermal
IMax
Current Max Present
1
1020
MM
A
Unity
IN
Current N
1
1019
MM
A
Unity
IN_PCT
Current N % Load
1
8840
PM
%
Unity
IND
Demand Current N
1
2203
MM
A
Unity
IUnbalA
Current Unbalance A
1
1028
MM
%
IUnbalAlrm
Current Unbalance Alarm Status
1
8859
PM
IUnbalB
Current Unbalance B
1
1029
MM
%
Tenths
IUnbalC
Current Unbalance C
1
1030
MM
%
Tenths
IUnbalPreAlrm
Current Unbalance Pre-Alarm Status
1
8863
PM
IUnbalW
Current Unbalance Worst
1
1032
MM
%
Tenths
kVAA
Apparent Power A
1
1042
MM
kVA
Unity
kVAB
Apparent Power B
1
1043
MM
kVA
Unity
kVAC
Apparent Power C
1
1044
MM
kVA
Unity
kVAD
Demand Apparent Power (KVAD)
1
2236
MM
kVA
Unity
kVAD_PkkVARD
KVA Dmd Coincident w/Peak KVAR Dmd
1
2235
MM
kVA
Unity
kVAD_PkkWD
KVA Dmd Coincident w/Peak KW Dmd
1
2229
MM
kVA
Unity
kVAHr
Apparent Energy
4
2024
MM
kVAH
Modulo 10,000 format3
kVARA
Reactive Power A
1
1038
MM
kVAR
Unity
kVARB
Reactive Power B
1
1039
MM
kVAR
Unity
kVARC
Reactive Power C
1
1040
MM
kVAR
Unity
kVARD
Demand Reactive Power (KVARD)
1
2230
MM
kVAR
Unity
kVARD_PkkVAD
KVAR Dmd Coincident w/Peak KVA Dmd
1
2241
MM
kVAR
Unity
kVARD_PkkWD
KVAR Dmd Coincident w/Peak KW Dmd
1
2228
MM
kVAR
Unity
kVARHr
Reactive Energy
4
2004
MM
kVARH
kVARHr_I
Reactive Energy Into the Load
4
2016
MM
kVARH
Modulo 10,000 format3
Modulo 10,000 format3
kVARHr_O
Reactive Energy Out of the Load
4
2020
MM
kVARH
Modulo 10,000 format3
kVARTtl
Reactive Power Total
1
1041
MM
kVAR
Unity
kVATtl
Apparent Power Total
1
1045
MM
kVA
Unity
kWA
Real Power A
1
1034
MM
kW
Unity
kWB
Real Power B
1
1035
MM
kW
Unity
kWC
Real Power C
1
1036
MM
kW
Unity
kWD
Demand Real Power (KWD)
1
2224
MM
kW
Unity
1.
2.
3.
4.
32
Tenths
Bit 0; ON = active; OFF = inactive
Bit 0; ON = active, OFF = inactive
For register entries that are not listed, please refer to the MICROLOGIC device type register list. Contact your local sales representative.
3-register date/time format:
register 1: month (byte 1) = 1–12; day (byte 2) = 1–31
register 2: year (byte 1) = 0–199 (add to 1900 to determine the actual year); hour (byte 2) = 0–23
register 3: minutes (byte 1) = 0–59; seconds (byte 2) = 0–59
Note: Bits 14 and 15 of the month/day register must be masked.
Modulo 10,000 format: 1 to 4 sequential registers. Each register is Modulo 10,000 (range = –9,999 to +9,999).
Result is [R4*10,000^3 + R3*10,000^2 + R2*10,000^1] + R1. Range is zero to 9,999,999,999,999,999.
Power factor format: –1 to –999 for lagging power factors, 1000 for unity power factor 1.000, and 1 to 999 for leading power factors.
© 2002 Schneider Electric All Rights Reserved
63220-080-200/B1
August 2002
Appendix B–Type P Standard Quantities
Using MICROLOGIC Electronic Trip Units in a POWERLOGIC System
Number of
Registers
Register1
Module
1
2240
MM
kW
KW Dmd Coincident w/Peak KVAR Dmd
1
2234
MM
kW
Unity
kWHr
Real Energy
4
2000
MM
kWH
kWHr_I
Real Energy Into the Load
4
2008
MM
kWH
Modulo 10,000 format3
Modulo 10,000 format3
kWHr_O
Real Energy Out of the Load
4
2012
MM
kWH
Modulo 10,000 format3
SMS Topic Name
User Description
kWD_PkkVAD
KW Dmd Coincident w/Peak KVA Dmd
kWD_PkkVARD
Units
Scale/Bitmask
Unity
kWTtl
Real Power Total
1
1037
MM
kW
Unity
LDPUValue
Long Delay Pickup Value
2
8756
PM
A
Modulo 10,000 format3
LSCurrAlrm
Load Shed Current Alarm Status
1
8859
PM
LSCurrPreAlrm
Load Shed Current Pre-Alarm Status
1
8863
PM
Bit 13; ON = active; OFF = inactive
Bit 13; ON = active; OFF = inactive
LSPwrAlrm
Load Shed Power Alarm Status
1
8859
PM
Bit 14; ON = active; OFF = inactive
LSPwrPreAlrm
Load Shed Power Pre-Alarm Status
1
8863
PM
Bit 14; ON = active; OFF = inactive
Bit 0; ON = on; OFF = off
M2C_M6CR1Status
Relay Module R1 Status
1
8857
PM
M2C_M6CR2Status
Relay Module R2 Status
1
8857
PM
Bit 1; ON = on; OFF = off
M2C_M6CR3Status
Relay Module R3 Status
1
8857
PM
Bit 2; ON = on; OFF = off
M2C_M6CR4Status
Relay Module R4 Status
1
8857
PM
Bit 3; ON = on; OFF = off
Bit 4; ON = on; OFF = off
M2C_M6CR5Status
Relay Module R5 Status
1
8857
PM
M2C_M6CR6Status
Relay Module R6 Status
1
8857
PM
MaxHz
Max Frequency
1
1654
MM
Hz
Tenths
MaxIA
Max Current A
1
1616
MM
A
Unity
Unity
Bit 5; ON = on; OFF = off
MaxIAvg
Max Current Avg
1
1627
MM
A
MaxIB
Max Current B
1
1617
MM
A
Unity
MaxIC
Max Current C
1
1618
MM
A
Unity
MaxIG
Max Current G
1
8831
PM
A
Unity
Thousandths
MaxIG_VIGI
Max Current G (VIGI)
1
8832
PM
A
MaxIN
Max Current N
1
1619
MM
A
Unity
MaxIUnbalA
Max Current Unbalance A
1
1628
MM
%
Tenths
MaxIUnbalB
Max Current Unbalance B
1
1629
MM
%
Tenths
Tenths
MaxIUnbalC
Max Current Unbalance C
1
1630
MM
%
MaxIUnbalW
Max Current Unbalance Worst
1
1632
MM
%
Tenths
MaxkVAA
Max Apparent Power A
1
1642
MM
kVA
Unity
MaxkVAB
Max Apparent Power B
1
1643
MM
kVA
Unity
Unity
MaxkVAC
Max Apparent Power C
1
1644
MM
kVA
MaxkVARA
Max Reactive Power A
1
1638
MM
kVAR
Unity
MaxkVARB
Max Reactive Power B
1
1639
MM
kVAR
Unity
MaxkVARC
Max Reactive Power C
1
1640
MM
kVAR
Unity
Unity
MaxkVARTtl
Max Reactive Power Total
1
1641
MM
kVAR
MaxkVATtl
Max Apparent Power Total
1
1645
MM
kVA
Unity
MaxkWA
Max Real Power A
1
1634
MM
kW
Unity
MaxkWB
Max Real Power B
1
1635
MM
kW
Unity
MaxkWC
Max Real Power C
1
1636
MM
kW
Unity
MaxkWTtl
Max Real Power Total
1
1637
MM
kW
MaxPFA
Max Power Factor A
1
1646
MM
Unity
PF format4
1.
2.
3.
4.
For register entries that are not listed, please refer to the MICROLOGIC device type register list. Contact your local sales representative.
3-register date/time format:
register 1: month (byte 1) = 1–12; day (byte 2) = 1–31
register 2: year (byte 1) = 0–199 (add to 1900 to determine the actual year); hour (byte 2) = 0–23
register 3: minutes (byte 1) = 0–59; seconds (byte 2) = 0–59
Note: Bits 14 and 15 of the month/day register must be masked.
Modulo 10,000 format: 1 to 4 sequential registers. Each register is Modulo 10,000 (range = –9,999 to +9,999).
Result is [R4*10,000^3 + R3*10,000^2 + R2*10,000^1] + R1. Range is zero to 9,999,999,999,999,999.
Power factor format: –1 to –999 for lagging power factors, 1000 for unity power factor 1.000, and 1 to 999 for leading power factors.
© 2002 Schneider Electric All Rights Reserved
33
Appendix B–Type P Standard Quantities
Using MICROLOGIC Electronic Trip Units in a POWERLOGIC System
Number of
Registers
63220-080-200/B1
August 2002
Register1
Module
1
1647
MM
Max Power Factor C
1
1648
MM
Scale/Bitmask
PF format4
PF format4
Max Power Factor Total
1
1649
MM
PF format4
SMS Topic Name
User Description
MaxPFB
Max Power Factor B
MaxPFC
MaxPFTtl
Units
MaxVAB
Max Voltage A-B
1
1600
MM
V
MaxVAN
Max Voltage A-N
1
1603
MM
V
Unity
Unity
MaxVBC
Max Voltage B-C
1
1601
MM
V
Unity
MaxVBN
Max Voltage B-N
1
1604
MM
V
Unity
Unity
MaxVCA
Max Voltage C-A
1
1602
MM
V
MaxVCN
Max Voltage C-N
1
1605
MM
V
Unity
MaxVLLAvg
Max Voltage L-L Avg
1
1606
MM
V
Unity
MaxVLNAvg
Max Voltage L-N Avg
1
1607
MM
V
Unity
Tenths
MaxVUnbalAB
Max Voltage Unbalance A-B
1
1608
MM
%
MaxVUnbalAN
Max Voltage Unbalance A-N
1
1611
MM
%
Tenths
MaxVUnbalBC
Max Voltage Unbalance B-C
1
1609
MM
%
Tenths
MaxVUnbalBN
Max Voltage Unbalance B-N
1
1612
MM
%
Tenths
Tenths
MaxVUnbalCA
Max Voltage Unbalance C-A
1
1610
MM
%
MaxVUnbalCN
Max Voltage Unbalance C-N
1
1613
MM
%
Tenths
MaxVUnbalLLW
Max Voltage Unbalance L-L Worst
1
1614
MM
%
Tenths
MaxVUnbalLNW
Max Voltage Unbalance L-N Worst
1
1615
MM
%
Tenths
Tenths
MinHz
Min Frequency
1
1354
MM
Hz
MinIA
Min Current A
1
1316
MM
A
Unity
MinIAvg
Min Current Avg
1
1327
MM
A
Unity
MinIB
Min Current B
1
1317
MM
A
Unity
Unity
MinIC
Min Current C
1
1318
MM
A
MinIN
Min Current N
1
1319
MM
A
Unity
MinIUnbalA
Min Current Unbalance A
1
1328
MM
%
Tenths
MinIUnbalB
Min Current Unbalance B
1
1329
MM
%
Tenths
Tenths
MinIUnbalC
Min Current Unbalance C
1
1330
MM
%
MinIUnbalW
Min Current Unbalance Worst
1
1332
MM
%
Tenths
MinkVAA
Min Apparent Power A
1
1342
MM
kVA
Unity
MinkVAB
Min Apparent Power B
1
1343
MM
kVA
Unity
MinkVAC
Min Apparent Power C
1
1344
MM
kVA
Unity
MinkVARA
Min Reactive Power A
1
1338
MM
kVAR
Unity
MinkVARB
Min Reactive Power B
1
1339
MM
kVAR
Unity
MinkVARC
Min Reactive Power C
1
1340
MM
kVAR
Unity
Unity
MinkVARTtl
Min Reactive Power Total
1
1341
MM
kVAR
MinkVATtl
Min Apparent Power Total
1
1345
MM
kVA
Unity
MinkWA
Min Real Power A
1
1334
MM
kW
Unity
MinkWB
Min Real Power B
1
1335
MM
kW
Unity
MinkWC
Min Real Power C
1
1336
MM
kW
Unity
MinkWTtl
Min Real Power Total
1
1337
MM
kW
MinPFA
Min Power Factor A
1
1346
MM
Unity
PF format4
1.
2.
3.
4.
34
For register entries that are not listed, please refer to the MICROLOGIC device type register list. Contact your local sales representative.
3-register date/time format:
register 1: month (byte 1) = 1–12; day (byte 2) = 1–31
register 2: year (byte 1) = 0–199 (add to 1900 to determine the actual year); hour (byte 2) = 0–23
register 3: minutes (byte 1) = 0–59; seconds (byte 2) = 0–59
Note: Bits 14 and 15 of the month/day register must be masked.
Modulo 10,000 format: 1 to 4 sequential registers. Each register is Modulo 10,000 (range = –9,999 to +9,999).
Result is [R4*10,000^3 + R3*10,000^2 + R2*10,000^1] + R1. Range is zero to 9,999,999,999,999,999.
Power factor format: –1 to –999 for lagging power factors, 1000 for unity power factor 1.000, and 1 to 999 for leading power factors.
© 2002 Schneider Electric All Rights Reserved
63220-080-200/B1
August 2002
Appendix B–Type P Standard Quantities
Using MICROLOGIC Electronic Trip Units in a POWERLOGIC System
Number of
Registers
Register1
Module
1
1347
MM
Min Power Factor C
1
1348
MM
Min Power Factor Total
1
1349
MM
SMS Topic Name
User Description
MinPFB
Min Power Factor B
MinPFC
MinPFTtl
Units
Scale/Bitmask
PF format4
PF format4
PF format4
MinVAB
Min Voltage A-B
1
1300
MM
V
MinVAN
Min Voltage A-N
1
1303
MM
V
Unity
Unity
MinVBC
Min Voltage B-C
1
1301
MM
V
Unity
MinVBN
Min Voltage B-N
1
1304
MM
V
Unity
Unity
MinVCA
Min Voltage C-A
1
1302
MM
V
MinVCN
Min Voltage C-N
1
1305
MM
V
Unity
MinVLLAvg
Min Voltage L-L Avg
1
1306
MM
V
Unity
MinVLNAvg
Min Voltage L-N Avg
1
1307
MM
V
Unity
MinVUnbalAB
Min Voltage Unbalance A-B
1
1308
MM
%
Tenths
MinVUnbalAN
Min Voltage Unbalance A-N
1
1311
MM
%
Tenths
MinVUnbalBC
Min Voltage Unbalance B-C
1
1309
MM
%
Tenths
MinVUnbalBN
Min Voltage Unbalance B-N
1
1312
MM
%
Tenths
MinVUnbalCA
Min Voltage Unbalance C-A
1
1310
MM
%
Tenths
MinVUnbalCN
Min Voltage Unbalance C-N
1
1313
MM
%
Tenths
MinVUnbalLLW
Min Voltage Unbalance L-L Worst
1
1314
MM
%
Tenths
MinVUnbalLNW
Min Voltage Unbalance L-N Worst
1
1315
MM
%
Tenths
A
Unity
NominalCurrent
Breaker Nominal Current
1
8750
PM
OverFreqAlrm
Over Frequency Alarm Status
1
8859
PM
Bit 11; ON = active, OFF = inactive
OverFreqPreAlrm
Over Frequency Pre-Alarm Status
1
8863
PM
Bit 11; ON = active, OFF = inactive
OverIAAlrm
Over IA Demand Alarm Status
1
8859
PM
Bit 1; ON = active, OFF = inactive
Bit 1; ON = active, OFF = inactive
OverIAPreAlrm
Over IA Demand Pre-Alarm Status
1
8863
PM
OverIBAlrm
Over IB Demand Alarm Status
1
8859
PM
Bit 2; ON = active, OFF = inactive
OverIBPreAlrm
Over IB Demand Pre-Alarm Status
1
8863
PM
Bit 2; ON = active, OFF = inactive
OverICAlrm
Over IC Demand Alarm Status
1
8859
PM
Bit 3; ON = active, OFF = inactive
OverICPreAlrm
Over IC Demand Pre-Alarm Status
1
8863
PM
Bit 3; ON = active, OFF = inactive
OverINAlrm
Over IN Demand Alarm Status
1
8859
PM
Bit 4; ON = active, OFF = inactive
OverINPreAlrm
Over IN Demand Pre-Alarm Status
1
8863
PM
Bit 4; ON = active, OFF = inactive
OverVoltAlrm
Over Voltage Alarm Status
1
8859
PM
Bit 6; ON = active, OFF = inactive
Bit 6; ON = active, OFF = inactive
PF format4
OverVoltPreAlrm
Over Voltage Pre-Alarm Status
1
8863
PM
PF_PkkVAD
PF Coincident w/Peak KVA Demand
1
2239
MM
PF_PkkVARD
PF Coincident w/Peak KVAR Demand
1
2233
MM
PF_PkkWD
PF Coincident w/Peak KW Demand
1
2227
MM
PFA
Power Factor A
1
1046
MM
PF format4
PF format4
PFB
Power Factor B
1
1047
MM
PF format4
PF format4
PFC
Power Factor C
1
1048
MM
PF format4
PFSignConv
Power Factor Sign Convention
1
3318
MM
PFTtl
Power Factor Total
1
1049
MM
0 = IEC
1 = Alternate (CMI)
2 = IEEE
PF format4
1.
2.
3.
4.
For register entries that are not listed, please refer to the MICROLOGIC device type register list. Contact your local sales representative.
3-register date/time format:
register 1: month (byte 1) = 1–12; day (byte 2) = 1–31
register 2: year (byte 1) = 0–199 (add to 1900 to determine the actual year); hour (byte 2) = 0–23
register 3: minutes (byte 1) = 0–59; seconds (byte 2) = 0–59
Note: Bits 14 and 15 of the month/day register must be masked.
Modulo 10,000 format: 1 to 4 sequential registers. Each register is Modulo 10,000 (range = –9,999 to +9,999).
Result is [R4*10,000^3 + R3*10,000^2 + R2*10,000^1] + R1. Range is zero to 9,999,999,999,999,999.
Power factor format: –1 to –999 for lagging power factors, 1000 for unity power factor 1.000, and 1 to 999 for leading power factors.
© 2002 Schneider Electric All Rights Reserved
35
Appendix B–Type P Standard Quantities
Using MICROLOGIC Electronic Trip Units in a POWERLOGIC System
Number of
Registers
63220-080-200/B1
August 2002
Register1
Module
1
8859
PM
Peak Demand Current A
1
2204
MM
A
Unity
Peak Demand Current B
1
2205
MM
A
Unity
Unity
SMS Topic Name
User Description
PhaRotAlrm
Phase Rotation Alarm Status
PkIAD
PkIBD
Units
Scale/Bitmask
Bit 12; ON = active, OFF = inactive
PkICD
Peak Demand Current C
1
2206
MM
A
PkIND
Peak Demand Current N
1
2207
MM
A
Unity
PkkVAD
Peak Demand Apparent Power (KVAD)
1
2237
MM
kVA
Unity
PkkVARD
Peak Demand Reactive Power (KVARD)
1
2231
MM
kVAR
Unity
Unity
PkkWD
Peak Demand Real Power (KWD)
1
2225
MM
kW
PowerDmdInt
Power Demand Interval
1
3355
MM
Minutes
Unity
PredkVAD
Predicted KVA Demand
1
2238
MM
kVA
Unity
PredkVARD
Predicted KVAR Demand
1
2232
MM
kVAR
Unity
kW
Unity
PredkWD
Predicted KW Demand
1
2226
MM
PwrDmdMethod
Power Demand Method
1
3354
MM
0 = Sliding
1 = Thermal
2 = Block
5 = Sync to Comms
PwrFlowDirMet
Power Flow Direction - Metering
1
3316
MM
0 = Bottom Fed
1 = Top Fed
R1OpsCounter
Relay 1 Operations Counter
1
9081
PM
Unity
Unity
R2OpsCounter
Relay 2 Operations Counter
1
9082
PM
R3OpsCounter
Relay 3 Operations Counter
1
9083
PM
Unity
R4OpsCounter
Relay 4 Operations Counter
1
9084
PM
Unity
R5OpsCounter
Relay 5 Operations Counter
1
9085
PM
Unity
R6OpsCounter
Relay 6 Operations Counter
1
9086
PM
Unity
ReadyToClose
Breaker Ready to Close
1
661
BCM
Bit 5; ON = yes, OFF = no
RevPwrAlrm
Reverse Power Alarm Status
1
8859
PM
Bit 9; ON = active; OFF = inactive
RevPwrPreAlrm
Reverse Power Pre-Alarm Status
1
8863
PM
Bit 9; ON = active; OFF = inactive
System Type
System Type
1
3314
MM
TimeToTrip
Time Remaining to LT Trip
2
8865
PM
System 31 = 3-phase, 3-wire, 3CT
System 40 = 3-phase, 4-wire, 3CT
System 41 = 3-phase, 4-wire, 4 CT
Seconds Tenths, Modulo 10,000 format3
TU_BATT_PCT
Trip Unit % Battery
1
8843
PM
%
TU_SN
Trip Unit Serial Number
4
8700
PM
ASCII text
Bit 11; ON = not responding; OFF = OK
Unity
TUCommStatus
Trip Unit Internal Comms Status
1
552
BCM
UnderFreqAlrm
Under Frequency Alarm Status
1
8859
PM
Bit 10; ON = active; OFF = inactive
UnderFreqPreAlrm
Under Frequency Pre-Alarm Status
1
8863
PM
Bit 10; ON = active; OFF = inactive
UnderVoltAlrm
Under Voltage Alarm Status
1
8859
PM
Bit 5; ON = active; OFF = inactive
UnderVoltPreAlrm
Under Voltage Pre-Alarm Status
1
8863
PM
VAB
Voltage A-B
1
1000
MM
V
Unity
VAN
Voltage A-N
1
1003
MM
V
Unity
VARSignConv
VAR (Reactive Power) Sign Convention
1
3317
MM
VBC
Voltage B-C
1
1001
MM
V
Unity
VBN
Voltage B-N
1
1004
MM
V
Unity
1.
2.
3.
4.
36
Bit 5; ON = active; OFF = inactive
0 = Alternate (CMI)
1 = IEEE/IEC
For register entries that are not listed, please refer to the MICROLOGIC device type register list. Contact your local sales representative.
3-register date/time format:
register 1: month (byte 1) = 1–12; day (byte 2) = 1–31
register 2: year (byte 1) = 0–199 (add to 1900 to determine the actual year); hour (byte 2) = 0–23
register 3: minutes (byte 1) = 0–59; seconds (byte 2) = 0–59
Note: Bits 14 and 15 of the month/day register must be masked.
Modulo 10,000 format: 1 to 4 sequential registers. Each register is Modulo 10,000 (range = –9,999 to +9,999).
Result is [R4*10,000^3 + R3*10,000^2 + R2*10,000^1] + R1. Range is zero to 9,999,999,999,999,999.
Power factor format: –1 to –999 for lagging power factors, 1000 for unity power factor 1.000, and 1 to 999 for leading power factors.
© 2002 Schneider Electric All Rights Reserved
63220-080-200/B1
August 2002
Appendix B–Type P Standard Quantities
Using MICROLOGIC Electronic Trip Units in a POWERLOGIC System
Number of
Registers
Register1
Module
1
1002
MM
V
Voltage C-N
1
1005
MM
V
VigiAlarm
Vigi Alarm Status
1
8860
PM
VigiPreAlrm
Vigi Pre-Alarm Status
1
8864
PM
VLLAvg
Voltage L-L Avg
1
1006
MM
V
VLNAvg
Voltage L-N Avg
1
1007
MM
V
Unity
VUnbalAB
Voltage Unbalance A-B
1
1008
MM
%
Tenths
%
Tenths
SMS Topic Name
User Description
VCA
Voltage C-A
VCN
Units
Scale/Bitmask
Unity
Unity
Bit 1; ON = active; OFF = inactive
Bit 1; ON = active; OFF = inactive
Unity
VUnbalAlrm
Voltage Unbalance Alarm Status
1
8859
PM
VUnbalAN
Voltage Unbalance A-N
1
1011
MM
VUnbalBC
Voltage Unbalance B-C
1
1009
MM
%
Tenths
VUnbalBN
Voltage Unbalance B-N
1
1012
MM
%
Tenths
VUnbalCA
Voltage Unbalance C-A
1
1010
MM
%
Tenths
VUnbalCN
Voltage Unbalance C-N
1
1013
MM
%
Tenths
VUnbalLLW
Voltage Unbalance L-L Worst
1
1014
MM
%
Tenths
VUnbalLNW
Voltage Unbalance L-N Worst
1
1015
MM
%
Tenths
VUnbalPreAlrm
Voltage Unbalance Pre-Alarm Status
1
8863
PM
1.
2.
3.
4.
Bit 7; ON = active, OFF = inactive
Bit 7; ON = active, OFF = inactive
For register entries that are not listed, please refer to the MICROLOGIC device type register list. Contact your local sales representative.
3-register date/time format:
register 1: month (byte 1) = 1–12; day (byte 2) = 1–31
register 2: year (byte 1) = 0–199 (add to 1900 to determine the actual year); hour (byte 2) = 0–23
register 3: minutes (byte 1) = 0–59; seconds (byte 2) = 0–59
Note: Bits 14 and 15 of the month/day register must be masked.
Modulo 10,000 format: 1 to 4 sequential registers. Each register is Modulo 10,000 (range = –9,999 to +9,999).
Result is [R4*10,000^3 + R3*10,000^2 + R2*10,000^1] + R1. Range is zero to 9,999,999,999,999,999.
Power factor format: –1 to –999 for lagging power factors, 1000 for unity power factor 1.000, and 1 to 999 for leading power factors.
© 2002 Schneider Electric All Rights Reserved
37
Appendix B–Type P Standard Quantities
Using MICROLOGIC Electronic Trip Units in a POWERLOGIC System
38
63220-080-200/B1
August 2002
© 2002 Schneider Electric All Rights Reserved
63220-080-200/B1
August 2002
Appendix C–Type H Standard Quantities
Using MICROLOGIC Trip Units in a POWERLOGIC System
APPENDIX C—TYPE H STANDARD
QUANTITIES
SMS Topic Name1
User Description
This is an abbreviated list of standard quantities. You can use these
quantities in the Windows program Dynamic Data Exchange (DDE)—to set
up spreadsheets, drawings, reports, and custom tables for viewing SMS
data. For a complete list of registers, contact your local sales representative.
The quantities are listed in alphabetical order according to the SMS topic
name. Unless otherwise noted, all topics are signed integers. The table
below lists the quantities for the Type H trip unit.
Number of
Registers
Register2
Module
Units
Scale
810D_LDPU
Breaker LDPU in Progress
1
8862
PM
Scaling N/A
810DBrkrStatus
Breaker Status
1
661
BCM
Bit 0; ON = closed; OFF = open
810DBrkrTripStat
Breaker Trip Unit Status
1
661
BCM
Bit 2; ON = tripped; OFF = not tripped
AccumMode
Energy Accumulation Mode
1
3324
MM
0 = Absolute
1 = Signed
BCM_SN
BCM Serial Number
4
516
BCM
ASCII text
BkrPos
Breaker Position
1
661
CCM
Bit 8 = disconnected
Bit 9 = connected
Bit 10 = test position
CFVAB
Crest Factor Voltage A-B
1
1119
MM
Hundredths
CFVAN
Crest Factor Voltage A-N
1
1122
MM
Hundredths
CFVBC
Crest Factor Voltage B-C
1
1120
MM
Hundredths
CFVBN
Crest Factor Voltage B-N
1
1123
MM
Hundredths
CFVCA
Crest Factor Voltage C-A
1
1121
MM
Hundredths
CFVCN
Crest Factor Voltage C-N
1
1124
MM
Hundredths
CurrentDmdInt
Current/K-Factor Demand Interval
1
3352
MM
DT_3Regs
Device Clock Date/Time
4
679
BCM
DTLastTrip
D/T of Last Trip
3
693
BCM
DTPkIAD
D/T Peak Demand Current A
3
3005
MM
DTPkIBD
D/T Peak Demand Current B
3
3008
MM
DTPkICD
D/T Peak Demand Current C
3
3011
MM
DTPkIND
D/T Peak Demand Current N
3
3014
MM
DTPkKFDA
D/T K-Factor Dmd Peak A
3
3041
MM
DTPkKFDB
D/T K-Factor Dmd Peak B
3
3044
MM
DTPkKFDC
D/T K-Factor Dmd Peak C
3
3047
MM
DTPkKFDN
D/T K-Factor Dmd Peak N
3
3050
MM
DTPkkVAD
D/T Peak Demand Apparent Power
3
3023
MM
DTPkkVARD
D/T Peak Demand Reactive Power
3
3020
MM
DTPkkWD
D/T Peak Demand Real Power
3
3017
MM
DTResetEnergy
D/T Last Reset Accum. Energies
3
3038
MM
DTResetMinMax
D/T Last Reset Min/Max
3
3032
MM
DTResetPkID
D/T Last Reset Peak Dmd Currents
3
3026
MM
3-register date/time format3
3-register date/time format3
DTResetPkkWD
D/T Last Reset Peak Dmd Power
3
3029
MM
3-register date/time format3
EnableCloseBkr
Remote Closing Enabled
1
669
BCM
Bit 2; ON = enabled, OFF = not enabled
EnableOpenBkr
Remote Opening Enabled
1
669
BCM
Bit 1; ON = enabled; OFF = not enabled
1.
2.
3.
4.
5.
Minutes
Unity
3-register date/time format3
3-register date/time format3
3-register date/time format3
3-register date/time format3
3-register date/time format3
3-register date/time format3
3-register date/time format3
3-register date/time format3
3-register date/time format3
3-register date/time format3
3-register date/time format3
3-register date/time format3
3-register date/time format3
3-register date/time format3
SMS Topic Names beginning with “H” are Type H harmonic topics.
For register entries that are not listed, please refer to the MICROLOGIC device type register list. Contact your local sales representative.
3-register date/time format: register 1: month (byte 1) = 1–12; day (byte 2) = 1–31
register 2: year (byte 1) = 0–199 (add to 1900 to determine the actual year); hour (byte 2) = 0–23
register 3: minutes (byte 1) = 0–59; seconds (byte 2) = 0–59
Note: Bits 14 and 15 of the month/day register must be masked.
Modulo 10,000 format: 1 to 4 sequential registers. Each register is Modulo 10,000 (range = –9,999 to +9,999).
Result is [R4*10,000^3 + R3*10,000^2 + R2*10,000^1] + R1. Range is zero to 9,999,999,999,999,999.
Power factor format: –1 to –999 for lagging power factors, 1000 for unity power factor 1.000, and 1 to 999 for leading power factors.
© 2002 Schneider Electric All Rights Reserved
39
Appendix C–Type H Standard Quantities
Using MICROLOGIC Trip Units in a POWERLOGIC System
63220-080-200/B1
August 2002
SMS Topic Name1
User Description
Number of
Registers
Register2
Module
EnableRemCtrl
Remote Control Enabled
1
669
BCM
Units
Scale
Bit 3; ON = auto (enabled);
OFF = manual (not enabled)
fkVAA
Fundamental Apparent Power A
1
1084
MM
kVA
Unity
fkVAB
Fundamental Apparent Power B
1
1085
MM
kVA
Unity
fkVAC
Fundamental Apparent Power C
1
1086
MM
kVA
Unity
fkVATtl
Fundamental Apparent Power Total
1
1087
MM
kVA
Unity
fVAngA
Fundamental Voltage Ang A-B/A-N
1
1133
MM
Deg
Tenths
fVAngB
Fundamental Voltage Ang B-C/B-N
1
1134
MM
Deg
Tenths
Deg
Tenths
fVAngC
Fundamental Voltage Ang C-A/C-N
1
1135
MM
GFAlarmStatus
GF Alarm Status
1
8860
PM
Bit 0; ON = active; OFF = inactive
GFPreAlarmStatus
GF Alarm Pre-Alarm Status
1
8864
PM
Bit 0; ON = active; OFF = inactive
H10IA_Ang
H10 Current A Angle
1
4656
MM
Deg
Tenths
H10IA_Mag
H10 Current A Magnitude
1
4506
MM
%
Hundredths
H10IB_Ang
H10 Current B Angle
1
4657
MM
Deg
Tenths
H10IB_Mag
H10 Current B Magnitude
1
4507
MM
%
Hundredths
H10IC_Ang
H10 Current C Angle
1
4658
MM
Deg
Tenths
H10IC_Mag
H10 Current C Magnitude
1
4508
MM
%
Hundredths
H10IN_Ang
H10 Current N Angle
1
4659
MM
Deg
Tenths
H10IN_Mag
H10 Current N Magnitude
1
4509
MM
%
Hundredths
H10VAB_Ang
H10 Voltage A-B Angle
1
4574
MM
Deg
Tenths
H10VAB_Mag
H10 Voltage A-B Magnitude
1
4424
MM
%
Hundredths
H10VAN_Ang
H10 Voltage A-N Angle
1
4577
MM
Deg
Tenths
H10VAN_Mag
H10 Voltage A-N Magnitude
1
4427
MM
%
Hundredths
H10VBC_Ang
H10 Voltage B-C Angle
1
4575
MM
Deg
Tenths
H10VBC_Mag
H10 Voltage B-C Magnitude
1
4425
MM
%
Hundredths
H10VBN_Ang
H10 Voltage B-N Angle
1
4578
MM
Deg
Tenths
H10VBN_Mag
H10 Voltage B-N Magnitude
1
4428
MM
%
Hundredths
H10VCA_Ang
H10 Voltage C-A Angle
1
4576
MM
Deg
Tenths
H10VCA_Mag
H10 Voltage C-A Magnitude
1
4426
MM
%
Hundredths
H10VCN_Ang
H10 Voltage C-N Angle
1
4579
MM
Deg
Tenths
H10VCN_Mag
H10 Voltage C-N Magnitude
1
4429
MM
%
Hundredths
H11IA_Ang
H11 Current A Angle
1
4356
MM
Deg
Tenths
H11IA_Mag
H11 Current A Magnitude
1
4206
MM
%
Hundredths
H11IB_Ang
H11 Current B Angle
1
4357
MM
Deg
Tenths
H11IB_Mag
H11 Current B Magnitude
1
4207
MM
%
Hundredths
H11IC_Ang
H11 Current C Angle
1
4358
MM
Deg
Tenths
H11IC_Mag
H11 Current C Magnitude
1
4208
MM
%
Hundredths
H11IN_Ang
H11 Current N Angle
1
4359
MM
Deg
Tenths
H11IN_Mag
H11 Current N Magnitude
1
4209
MM
%
Hundredths
H11VAB_Ang
H11 Voltage A-B Angle
1
4274
MM
Deg
Tenths
H11VAB_Mag
H11 Voltage A-B Magnitude
1
4124
MM
%
Hundredths
1.
2.
3.
4.
5.
40
SMS Topic Names beginning with “H” are Type H harmonic topics.
For register entries that are not listed, please refer to the MICROLOGIC device type register list. Contact your local sales representative.
3-register date/time format: register 1: month (byte 1) = 1–12; day (byte 2) = 1–31
register 2: year (byte 1) = 0–199 (add to 1900 to determine the actual year); hour (byte 2) = 0–23
register 3: minutes (byte 1) = 0–59; seconds (byte 2) = 0–59
Note: Bits 14 and 15 of the month/day register must be masked.
Modulo 10,000 format: 1 to 4 sequential registers. Each register is Modulo 10,000 (range = –9,999 to +9,999).
Result is [R4*10,000^3 + R3*10,000^2 + R2*10,000^1] + R1. Range is zero to 9,999,999,999,999,999.
Power factor format: –1 to –999 for lagging power factors, 1000 for unity power factor 1.000, and 1 to 999 for leading power factors.
© 2002 Schneider Electric All Rights Reserved
63220-080-200/B1
August 2002
Appendix C–Type H Standard Quantities
Using MICROLOGIC Trip Units in a POWERLOGIC System
SMS Topic Name1
User Description
Number of
Registers
Register2
Module
Units
H11VAN_Ang
H11 Voltage A-N Angle
1
4277
MM
Deg
Tenths
H11VAN_Mag
H11 Voltage A-N Magnitude
1
4127
MM
%
Hundredths
H11VBC_Ang
H11 Voltage B-C Angle
1
4275
MM
Deg
Tenths
H11VBC_Mag
H11 Voltage B-C Magnitude
1
4125
MM
%
Hundredths
H11VBN_Ang
H11 Voltage B-N Angle
1
4278
MM
Deg
Tenths
H11VBN_Mag
H11 Voltage B-N Magnitude
1
4128
MM
%
Hundredths
H11VCA_Ang
H11 Voltage C-A Angle
1
4276
MM
Deg
Tenths
Scale
H11VCA_Mag
H11 Voltage C-A Magnitude
1
4126
MM
%
Hundredths
H11VCN_Ang
H11 Voltage C-N Angle
1
4279
MM
Deg
Tenths
H11VCN_Mag
H11 Voltage C-N Magnitude
1
4129
MM
%
Hundredths
H12IA_Ang
H12 Current A Angle
1
4660
MM
Deg
Tenths
H12IA_Mag
H12 Current A Magnitude
1
4510
MM
%
Hundredths
H12IB_Ang
H12 Current B Angle
1
4661
MM
Deg
Tenths
H12IB_Mag
H12 Current B Magnitude
1
4511
MM
%
Hundredths
H12IC_Ang
H12 Current C Angle
1
4662
MM
Deg
Tenths
H12IC_Mag
H12 Current C Magnitude
1
4512
MM
%
Hundredths
H12IN_Ang
H12 Current N Angle
1
4663
MM
Deg
Tenths
H12IN_Mag
H12 Current N Magnitude
1
4513
MM
%
Hundredths
H12VAB_Ang
H12 Voltage A-B Angle
1
4580
MM
Deg
Tenths
H12VAB_Mag
H12 Voltage A-B Magnitude
1
4430
MM
%
Hundredths
H12VAN_Ang
H12 Voltage A-N Angle
1
4583
MM
Deg
Tenths
H12VAN_Mag
H12 Voltage A-N Magnitude
1
4433
MM
%
Hundredths
H12VBC_Ang
H12 Voltage B-C Angle
1
4581
MM
Deg
Tenths
H12VBC_Mag
H12 Voltage B-C Magnitude
1
4431
MM
%
Hundredths
H12VBN_Ang
H12 Voltage B-N Angle
1
4584
MM
Deg
Tenths
H12VBN_Mag
H12 Voltage B-N Magnitude
1
4434
MM
%
Hundredths
H12VCA_Ang
H12 Voltage C-A Angle
1
4582
MM
Deg
Tenths
H12VCA_Mag
H12 Voltage C-A Magnitude
1
4432
MM
%
Hundredths
H12VCN_Ang
H12 Voltage C-N Angle
1
4585
MM
Deg
Tenths
H12VCN_Mag
H12 Voltage C-N Magnitude
1
4435
MM
%
Hundredths
H13IA_Ang
H13 Current A Angle
1
4360
MM
Deg
Tenths
H13IA_Mag
H13 Current A Magnitude
1
4210
MM
%
Hundredths
H13IB_Ang
H13 Current B Angle
1
4361
MM
Deg
Tenths
H13IB_Mag
H13 Current B Magnitude
1
4211
MM
%
Hundredths
H13IC_Ang
H13 Current C Angle
1
4362
MM
Deg
Tenths
H13IC_Mag
H13 Current C Magnitude
1
4212
MM
%
Hundredths
H13IN_Ang
H13 Current N Angle
1
4363
MM
Deg
Tenths
H13IN_Mag
H13 Current N Magnitude
1
4213
MM
%
Hundredths
H13VAB_Ang
H13 Voltage A-B Angle
1
4280
MM
Deg
Tenths
H13VAB_Mag
H13 Voltage A-B Magnitude
1
4130
MM
%
Hundredths
H13VAN_Ang
H13 Voltage A-N Angle
1
4283
MM
Deg
Tenths
1.
2.
3.
4.
5.
SMS Topic Names beginning with “H” are Type H harmonic topics.
For register entries that are not listed, please refer to the MICROLOGIC device type register list. Contact your local sales representative.
3-register date/time format: register 1: month (byte 1) = 1–12; day (byte 2) = 1–31
register 2: year (byte 1) = 0–199 (add to 1900 to determine the actual year); hour (byte 2) = 0–23
register 3: minutes (byte 1) = 0–59; seconds (byte 2) = 0–59
Note: Bits 14 and 15 of the month/day register must be masked.
Modulo 10,000 format: 1 to 4 sequential registers. Each register is Modulo 10,000 (range = –9,999 to +9,999).
Result is [R4*10,000^3 + R3*10,000^2 + R2*10,000^1] + R1. Range is zero to 9,999,999,999,999,999.
Power factor format: –1 to –999 for lagging power factors, 1000 for unity power factor 1.000, and 1 to 999 for leading power factors.
© 2002 Schneider Electric All Rights Reserved
41
Appendix C–Type H Standard Quantities
Using MICROLOGIC Trip Units in a POWERLOGIC System
5
63220-080-200/B1
August 2002
SMS Topic Name1
User Description
Number of
Registers
Register2
Module
Units
Scale
H13VAN_Mag
H13 Voltage A-N Magnitude
1
4133
MM
%
Hundredths
H13VBC_Ang
H13 Voltage B-C Angle
1
4281
MM
Deg
Tenths
H13VBC_Mag
H13 Voltage B-C Magnitude
1
4131
MM
%
Hundredths
H13VBN_Ang
H13 Voltage B-N Angle
1
4284
MM
Deg
Tenths
H13VBN_Mag
H13 Voltage B-N Magnitude
1
4134
MM
%
Hundredths
H13VCA_Ang
H13 Voltage C-A Angle
1
4282
MM
Deg
Tenths
H13VCA_Mag
H13 Voltage C-A Magnitude
1
4132
MM
%
Hundredths
H13VCN_Ang
H13 Voltage C-N Angle
1
4285
MM
Deg
Tenths
H13VCN_Mag
H13 Voltage C-N Magnitude
1
4135
MM
%
Hundredths
H14IA_Ang
H14 Current A Angle
1
4664
MM
Deg
Tenths
H14IA_Mag
H14 Current A Magnitude
1
4514
MM
%
Hundredths
Tenths
H14IB_Ang
H14 Current B Angle
1
4665
MM
Deg
H14IB_Mag
H14 Current B Magnitude
1
4515
MM
%
Hundredths
H14IC_Ang
H14 Current C Angle
1
4666
MM
Deg
Tenths
H14IC_Mag
H14 Current C Magnitude
1
4516
MM
%
Hundredths
Tenths
H14IN_Ang
H14 Current N Angle
1
4667
MM
Deg
H14IN_Mag
H14 Current N Magnitude
1
4517
MM
%
Hundredths
H14VAB_Ang
H14 Voltage A-B Angle
1
4586
MM
Deg
Tenths
H14VAB_Mag
H14 Voltage A-B Magnitude
1
4436
MM
%
Hundredths
H14VAN_Ang
H14 Voltage A-N Angle
1
4589
MM
Deg
Tenths
H14VAN_Mag
H14 Voltage A-N Magnitude
1
4439
MM
%
Hundredths
H14VBC_Ang
H14 Voltage B-C Angle
1
4587
MM
Deg
Tenths
H14VBC_Mag
H14 Voltage B-C Magnitude
1
4437
MM
%
Hundredths
H14VBN_Ang
H14 Voltage B-N Angle
1
4590
MM
Deg
Tenths
H14VBN_Mag
H14 Voltage B-N Magnitude
1
4440
MM
%
Hundredths
H14VCA_Ang
H14 Voltage C-A Angle
1
4588
MM
Deg
Tenths
H14VCA_Mag
H14 Voltage C-A Magnitude
1
4438
MM
%
Hundredths
H14VCN_Ang
H14 Voltage C-N Angle
1
4591
MM
Deg
Tenths
H14VCN_Mag
H14 Voltage C-N Magnitude
1
4441
MM
%
Hundredths
H15IA_Ang
H15 Current A Angle
1
4364
MM
Deg
Tenths
H15IA_Mag
H15 Current A Magnitude
1
4214
MM
%
Hundredths
Tenths
H15IB_Ang
H15 Current B Angle
1
4365
MM
Deg
H15IB_Mag
H15 Current B Magnitude
1
4215
MM
%
Hundredths
H15IC_Ang
H15 Current C Angle
1
4366
MM
Deg
Tenths
H15IC_Mag
H15 Current C Magnitude
1
4216
MM
%
Hundredths
Tenths
H15IN_Ang
H15 Current N Angle
1
4367
MM
Deg
H15IN_Mag
H15 Current N Magnitude
1
4217
MM
%
Hundredths
H15VAB_Ang
H15 Voltage A-B Angle
1
4286
MM
Deg
Tenths
H15VAB_Mag
H15 Voltage A-B Magnitude
1
4136
MM
%
Hundredths
H15VAN_Ang
H15 Voltage A-N Angle
1
4289
MM
Deg
Tenths
H15VAN_Mag
H15 Voltage A-N Magnitude
1
4139
MM
%
Hundredths
1.
2.
3.
4.
5.
42
SMS Topic Names beginning with “H” are Type H harmonic topics.
For register entries that are not listed, please refer to the MICROLOGIC device type register list. Contact your local sales representative.
3-register date/time format: register 1: month (byte 1) = 1–12; day (byte 2) = 1–31
register 2: year (byte 1) = 0–199 (add to 1900 to determine the actual year); hour (byte 2) = 0–23
register 3: minutes (byte 1) = 0–59; seconds (byte 2) = 0–59
Note: Bits 14 and 15 of the month/day register must be masked.
Modulo 10,000 format: 1 to 4 sequential registers. Each register is Modulo 10,000 (range = –9,999 to +9,999).
Result is [R4*10,000^3 + R3*10,000^2 + R2*10,000^1] + R1. Range is zero to 9,999,999,999,999,999.
Power factor format: –1 to –999 for lagging power factors, 1000 for unity power factor 1.000, and 1 to 999 for leading power factors.
© 2002 Schneider Electric All Rights Reserved
63220-080-200/B1
August 2002
Appendix C–Type H Standard Quantities
Using MICROLOGIC Trip Units in a POWERLOGIC System
SMS Topic Name1
User Description
Number of
Registers
Register2
Module
Units
H15VBC_Ang
H15 Voltage B-C Angle
1
4287
MM
Deg
Tenths
H15VBC_Mag
H15 Voltage B-C Magnitude
1
4137
MM
%
Hundredths
H15VBN_Ang
H15 Voltage B-N Angle
1
4290
MM
Deg
Tenths
H15VBN_Mag
H15 Voltage B-N Magnitude
1
4140
MM
%
Hundredths
H15VCA_Ang
H15 Voltage C-A Angle
1
4288
MM
Deg
Tenths
H15VCA_Mag
H15 Voltage C-A Magnitude
1
4138
MM
%
Hundredths
H15VCN_Ang
H15 Voltage C-N Angle
1
4291
MM
Deg
Tenths
H15VCN_Mag
H15 Voltage C-N Magnitude
1
4141
MM
%
Hundredths
H16IA_Ang
H16 Current A Angle
1
4668
MM
Deg
Tenths
H16IA_Mag
H16 Current A Magnitude
1
4518
MM
%
Hundredths
H16IB_Ang
H16 Current B Angle
1
4669
MM
Deg
Tenths
Scale
H16IB_Mag
H16 Current B Magnitude
1
4519
MM
%
Hundredths
H16IC_Ang
H16 Current C Angle
1
4670
MM
Deg
Tenths
H16IC_Mag
H16 Current C Magnitude
1
4520
MM
%
Hundredths
H16IN_Ang
H16 Current N Angle
1
4671
MM
Deg
Tenths
H16IN_Mag
H16 Current N Magnitude
1
4521
MM
%
Hundredths
H16VAB_Ang
H16 Voltage A-B Angle
1
4592
MM
Deg
Tenths
H16VAB_Mag
H16 Voltage A-B Magnitude
1
4442
MM
%
Hundredths
H16VAN_Ang
H16 Voltage A-N Angle
1
4595
MM
Deg
Tenths
H16VAN_Mag
H16 Voltage A-N Magnitude
1
4445
MM
%
Hundredths
H16VBC_Ang
H16 Voltage B-C Angle
1
4593
MM
Deg
Tenths
H16VBC_Mag
H16 Voltage B-C Magnitude
1
4443
MM
%
Hundredths
H16VBN_Ang
H16 Voltage B-N Angle
1
4596
MM
Deg
Tenths
H16VBN_Mag
H16 Voltage B-N Magnitude
1
4446
MM
%
Hundredths
H16VCA_Ang
H16 Voltage C-A Angle
1
4594
MM
Deg
Tenths
H16VCA_Mag
H16 Voltage C-A Magnitude
1
4444
MM
%
Hundredths
H16VCN_Ang
H16 Voltage C-N Angle
1
4597
MM
Deg
Tenths
H16VCN_Mag
H16 Voltage C-N Magnitude
1
4447
MM
%
Hundredths
H17IA_Ang
H17 Current A Angle
1
4368
MM
Deg
Tenths
H17IA_Mag
H17 Current A Magnitude
1
4218
MM
%
Hundredths
H17IB_Ang
H17 Current B Angle
1
4369
MM
Deg
Tenths
H17IB_Mag
H17 Current B Magnitude
1
4219
MM
%
Hundredths
H17IC_Ang
H17 Current C Angle
1
4370
MM
Deg
Tenths
H17IC_Mag
H17 Current C Magnitude
1
4220
MM
%
Hundredths
H17IN_Ang
H17 Current N Angle
1
4371
MM
Deg
Tenths
H17IN_Mag
H17 Current N Magnitude
1
4221
MM
%
Hundredths
H17VAB_Ang
H17 Voltage A-B Angle
1
4292
MM
Deg
Tenths
H17VAB_Mag
H17 Voltage A-B Magnitude
1
4142
MM
%
Hundredths
H17VAN_Ang
H17 Voltage A-N Angle
1
4295
MM
Deg
Tenths
H17VAN_Mag
H17 Voltage A-N Magnitude
1
4145
MM
%
Hundredths
H17VBC_Ang
H17 Voltage B-C Angle
1
4293
MM
Deg
Tenths
1.
2.
3.
4.
5.
SMS Topic Names beginning with “H” are Type H harmonic topics.
For register entries that are not listed, please refer to the MICROLOGIC device type register list. Contact your local sales representative.
3-register date/time format: register 1: month (byte 1) = 1–12; day (byte 2) = 1–31
register 2: year (byte 1) = 0–199 (add to 1900 to determine the actual year); hour (byte 2) = 0–23
register 3: minutes (byte 1) = 0–59; seconds (byte 2) = 0–59
Note: Bits 14 and 15 of the month/day register must be masked.
Modulo 10,000 format: 1 to 4 sequential registers. Each register is Modulo 10,000 (range = –9,999 to +9,999).
Result is [R4*10,000^3 + R3*10,000^2 + R2*10,000^1] + R1. Range is zero to 9,999,999,999,999,999.
Power factor format: –1 to –999 for lagging power factors, 1000 for unity power factor 1.000, and 1 to 999 for leading power factors.
© 2002 Schneider Electric All Rights Reserved
43
Appendix C–Type H Standard Quantities
Using MICROLOGIC Trip Units in a POWERLOGIC System
63220-080-200/B1
August 2002
SMS Topic Name1
User Description
Number of
Registers
Register2
Module
Units
Scale
H17VBC_Mag
H17 Voltage B-C Magnitude
1
4143
MM
%
Hundredths
H17VBN_Ang
H17 Voltage B-N Angle
1
4296
MM
Deg
Tenths
H17VBN_Mag
H17 Voltage B-N Magnitude
1
4146
MM
%
Hundredths
H17VCA_Ang
H17 Voltage C-A Angle
1
4294
MM
Deg
Tenths
H17VCA_Mag
H17 Voltage C-A Magnitude
1
4144
MM
%
Hundredths
H17VCN_Ang
H17 Voltage C-N Angle
1
4297
MM
Deg
Tenths
H17VCN_Mag
H17 Voltage C-N Magnitude
1
4147
MM
%
Hundredths
H18IA_Ang
H18 Current A Angle
1
4672
MM
Deg
Tenths
H18IA_Mag
H18 Current A Magnitude
1
4522
MM
%
Hundredths
H18IB_Ang
H18 Current B Angle
1
4673
MM
Deg
Tenths
H18IB_Mag
H18 Current B Magnitude
1
4523
MM
%
Hundredths
Tenths
H18IC_Ang
H18 Current C Angle
1
4674
MM
Deg
H18IC_Mag
H18 Current C Magnitude
1
4524
MM
%
Hundredths
H18IN_Ang
H18 Current N Angle
1
4675
MM
Deg
Tenths
H18IN_Mag
H18 Current N Magnitude
1
4525
MM
%
Hundredths
H18VAB_Ang
H18 Voltage A-B Angle
1
4598
MM
Deg
Tenths
H18VAB_Mag
H18 Voltage A-B Magnitude
1
4448
MM
%
Hundredths
H18VAN_Ang
H18 Voltage A-N Angle
1
4601
MM
Deg
Tenths
H18VAN_Mag
H18 Voltage A-N Magnitude
1
4451
MM
%
Hundredths
H18VBC_Ang
H18 Voltage B-C Angle
1
4599
MM
Deg
Tenths
H18VBC_Mag
H18 Voltage B-C Magnitude
1
4449
MM
%
Hundredths
H18VBN_Ang
H18 Voltage B-N Angle
1
4602
MM
Deg
Tenths
H18VBN_Mag
H18 Voltage B-N Magnitude
1
4452
MM
%
Hundredths
H18VCA_Ang
H18 Voltage C-A Angle
1
4600
MM
Deg
Tenths
H18VCA_Mag
H18 Voltage C-A Magnitude
1
4450
MM
%
Hundredths
H18VCN_Ang
H18 Voltage C-N Angle
1
4603
MM
Deg
Tenths
H18VCN_Mag
H18 Voltage C-N Magnitude
1
4453
MM
%
Hundredths
H19IA_Ang
H19 Current A Angle
1
4372
MM
Deg
Tenths
H19IA_Mag
H19 Current A Magnitude
1
4222
MM
%
Hundredths
H19IB_Ang
H19 Current B Angle
1
4373
MM
Deg
Tenths
H19IB_Mag
H19 Current B Magnitude
1
4223
MM
%
Hundredths
Tenths
H19IC_Ang
H19 Current C Angle
1
4374
MM
Deg
H19IC_Mag
H19 Current C Magnitude
1
4224
MM
%
Hundredths
H19IN_Ang
H19 Current N Angle
1
4375
MM
Deg
Tenths
H19IN_Mag
H19 Current N Magnitude
1
4225
MM
%
Hundredths
H19VAB_Ang
H19 Voltage A-B Angle
1
4298
MM
Deg
Tenths
H19VAB_Mag
H19 Voltage A-B Magnitude
1
4148
MM
%
Hundredths
H19VAN_Ang
H19 Voltage A-N Angle
1
4301
MM
Deg
Tenths
H19VAN_Mag
H19 Voltage A-N Magnitude
1
4151
MM
%
Hundredths
H19VBC_Ang
H19 Voltage B-C Angle
1
4299
MM
Deg
Tenths
H19VBC_Mag
H19 Voltage B-C Magnitude
1
4149
MM
%
Hundredths
1.
2.
3.
4.
5.
44
SMS Topic Names beginning with “H” are Type H harmonic topics.
For register entries that are not listed, please refer to the MICROLOGIC device type register list. Contact your local sales representative.
3-register date/time format: register 1: month (byte 1) = 1–12; day (byte 2) = 1–31
register 2: year (byte 1) = 0–199 (add to 1900 to determine the actual year); hour (byte 2) = 0–23
register 3: minutes (byte 1) = 0–59; seconds (byte 2) = 0–59
Note: Bits 14 and 15 of the month/day register must be masked.
Modulo 10,000 format: 1 to 4 sequential registers. Each register is Modulo 10,000 (range = –9,999 to +9,999).
Result is [R4*10,000^3 + R3*10,000^2 + R2*10,000^1] + R1. Range is zero to 9,999,999,999,999,999.
Power factor format: –1 to –999 for lagging power factors, 1000 for unity power factor 1.000, and 1 to 999 for leading power factors.
© 2002 Schneider Electric All Rights Reserved
63220-080-200/B1
August 2002
Appendix C–Type H Standard Quantities
Using MICROLOGIC Trip Units in a POWERLOGIC System
SMS Topic Name1
User Description
Number of
Registers
Register2
Module
Units
H19VBN_Ang
H19 Voltage B-N Angle
1
4302
MM
Deg
Tenths
H19VBN_Mag
H19 Voltage B-N Magnitude
1
4152
MM
%
Hundredths
H19VCA_Ang
H19 Voltage C-A Angle
1
4300
MM
Deg
Tenths
Scale
H19VCA_Mag
H19 Voltage C-A Magnitude
1
4150
MM
%
Hundredths
H19VCN_Ang
H19 Voltage C-N Angle
1
4303
MM
Deg
Tenths
H19VCN_Mag
H19 Voltage C-N Magnitude
1
4153
MM
%
Hundredths
H20IA_Ang
H20 Current A Angle
1
4676
MM
Deg
Tenths
H20IA_Mag
H20 Current A Magnitude
1
4526
MM
%
Hundredths
H20IB_Ang
H20 Current B Angle
1
4677
MM
Deg
Tenths
H20IB_Mag
H20 Current B Magnitude
1
4527
MM
%
Hundredths
H20IC_Ang
H20 Current C Angle
1
4678
MM
Deg
Tenths
H20IC_Mag
H20 Current C Magnitude
1
4528
MM
%
Hundredths
H20IN_Ang
H20 Current N Angle
1
4679
MM
Deg
Tenths
H20IN_Mag
H20 Current N Magnitude
1
4529
MM
%
Hundredths
H20VAB_Ang
H20 Voltage A-B Angle
1
4604
MM
Deg
Tenths
H20VAB_Mag
H20 Voltage A-B Magnitude
1
4454
MM
%
Hundredths
H20VAN_Ang
H20 Voltage A-N Angle
1
4607
MM
Deg
Tenths
H20VAN_Mag
H20 Voltage A-N Magnitude
1
4457
MM
%
Hundredths
H20VBC_Ang
H20 Voltage B-C Angle
1
4605
MM
Deg
Tenths
H20VBC_Mag
H20 Voltage B-C Magnitude
1
4455
MM
%
Hundredths
H20VBN_Ang
H20 Voltage B-N Angle
1
4608
MM
Deg
Tenths
H20VBN_Mag
H20 Voltage B-N Magnitude
1
4458
MM
%
Hundredths
H20VCA_Ang
H20 Voltage C-A Angle
1
4606
MM
Deg
Tenths
H20VCA_Mag
H20 Voltage C-A Magnitude
1
4456
MM
%
Hundredths
H20VCN_Ang
H20 Voltage C-N Angle
1
4609
MM
Deg
Tenths
H20VCN_Mag
H20 Voltage C-N Magnitude
1
4459
MM
%
Hundredths
H21IA_Ang
H21 Current A Angle
1
4376
MM
Deg
Tenths
H21IA_Mag
H21 Current A Magnitude
1
4226
MM
%
Hundredths
H21IB_Ang
H21 Current B Angle
1
4377
MM
Deg
Tenths
H21IB_Mag
H21 Current B Magnitude
1
4227
MM
%
Hundredths
H21IC_Ang
H21 Current C Angle
1
4378
MM
Deg
Tenths
H21IC_Mag
H21 Current C Magnitude
1
4228
MM
%
Hundredths
H21IN_Ang
H21 Current N Angle
1
4379
MM
Deg
Tenths
H21IN_Mag
H21 Current N Magnitude
1
4229
MM
%
Hundredths
H21VAB_Ang
H21 Voltage A-B Angle
1
4304
MM
Deg
Tenths
H21VAB_Mag
H21 Voltage A-B Magnitude
1
4154
MM
%
Hundredths
H21VAN_Ang
H21 Voltage A-N Angle
1
4307
MM
Deg
Tenths
H21VAN_Mag
H21 Voltage A-N Magnitude
1
4157
MM
%
Hundredths
H21VBC_Ang
H21 Voltage B-C Angle
1
4305
MM
Deg
Tenths
H21VBC_Mag
H21VBN_An5
H21 Voltage B-C Magnitude
1
4155
MM
%
Hundredths
H21 Voltage B-N Angle
1
4308
MM
Deg
Tenths
1.
2.
3.
4.
5.
SMS Topic Names beginning with “H” are Type H harmonic topics.
For register entries that are not listed, please refer to the MICROLOGIC device type register list. Contact your local sales representative.
3-register date/time format: register 1: month (byte 1) = 1–12; day (byte 2) = 1–31
register 2: year (byte 1) = 0–199 (add to 1900 to determine the actual year); hour (byte 2) = 0–23
register 3: minutes (byte 1) = 0–59; seconds (byte 2) = 0–59
Note: Bits 14 and 15 of the month/day register must be masked.
Modulo 10,000 format: 1 to 4 sequential registers. Each register is Modulo 10,000 (range = –9,999 to +9,999).
Result is [R4*10,000^3 + R3*10,000^2 + R2*10,000^1] + R1. Range is zero to 9,999,999,999,999,999.
Power factor format: –1 to –999 for lagging power factors, 1000 for unity power factor 1.000, and 1 to 999 for leading power factors.
© 2002 Schneider Electric All Rights Reserved
45
Appendix C–Type H Standard Quantities
Using MICROLOGIC Trip Units in a POWERLOGIC System
63220-080-200/B1
August 2002
SMS Topic Name1
User Description
Number of
Registers
Register2
Module
Units
Scale
H21VBN_Mag
H21 Voltage B-N Magnitude
1
4158
MM
%
Hundredths
H21VCA_Ang
H21 Voltage C-A Angle
1
4306
MM
Deg
Tenths
H21VCA_Mag
H21 Voltage C-A Magnitude
1
4156
MM
%
Hundredths
H21VCN_Ang
H21 Voltage C-N Angle
1
4309
MM
Deg
Tenths
H21VCN_Mag
H21 Voltage C-N Magnitude
1
4159
MM
%
Hundredths
H22IA_Ang
H22 Current A Angle
1
4680
MM
Deg
Tenths
H22IA_Mag
H22 Current A Magnitude
1
4530
MM
%
Hundredths
Tenths
H22IB_Ang
H22 Current B Angle
1
4681
MM
Deg
H22IB_Mag
H22 Current B Magnitude
1
4531
MM
%
Hundredths
H22IC_Ang
H22 Current C Angle
1
4682
MM
Deg
Tenths
H22IC_Mag
H22 Current C Magnitude
1
4532
MM
%
Hundredths
Tenths
H22IN_Ang
H22 Current N Angle
1
4683
MM
Deg
H22IN_Mag
H22 Current N Magnitude
1
4533
MM
%
Hundredths
H22VAB_Ang
H22 Voltage A-B Angle
1
4610
MM
Deg
Tenths
H22VAB_Mag
H22 Voltage A-B Magnitude
1
4460
MM
%
Hundredths
H22VAN_Ang
H22 Voltage A-N Angle
1
4613
MM
Deg
Tenths
H22VAN_Mag
H22 Voltage A-N Magnitude
1
4463
MM
%
Hundredths
H22VBC_Ang
H22 Voltage B-C Angle
1
4611
MM
Deg
Tenths
H22VBC_Mag
H22 Voltage B-C Magnitude
1
4461
MM
%
Hundredths
H22VBN_Ang
H22 Voltage B-N Angle
1
4614
MM
Deg
Tenths
H22VBN_Mag
H22 Voltage B-N Magnitude
1
4464
MM
%
Hundredths
H22VCA_Ang
H22 Voltage C-A Angle
1
4612
MM
Deg
Tenths
H22VCA_Mag
H22 Voltage C-A Magnitude
1
4462
MM
%
Hundredths
H22VCN_Ang
H22 Voltage C-N Angle
1
4615
MM
Deg
Tenths
H22VCN_Mag
H22 Voltage C-N Magnitude
1
4465
MM
%
Hundredths
H23IA_Ang
H23 Current A Angle
1
4380
MM
Deg
Tenths
H23IA_Mag
H23 Current A Magnitude
1
4230
MM
%
Hundredths
Tenths
H23IB_Ang
H23 Current B Angle
1
4381
MM
Deg
H23IB_Mag
H23 Current B Magnitude
1
4231
MM
%
Hundredths
H23IC_Ang
H23 Current C Angle
1
4382
MM
Deg
Tenths
H23IC_Mag
H23 Current C Magnitude
1
4232
MM
%
Hundredths
Tenths
H23IN_Ang
H23 Current N Angle
1
4383
MM
Deg
H23IN_Mag
H23 Current N Magnitude
1
4233
MM
%
Hundredths
H23VAB_Ang
H23 Voltage A-B Angle
1
4310
MM
Deg
Tenths
H23VAB_Mag
H23 Voltage A-B Magnitude
1
4160
MM
%
Hundredths
H23VAN_Ang
H23 Voltage A-N Angle
1
4313
MM
Deg
Tenths
H23VAN_Mag
H23 Voltage A-N Magnitude
1
4163
MM
%
Hundredths
H23VBC_Ang
H23 Voltage B-C Angle
1
4311
MM
Deg
Tenths
H23VBC_Mag
H23 Voltage B-C Magnitude
1
4161
MM
%
Hundredths
H23VBN_Ang
H23 Voltage B-N Angle
1
4314
MM
Deg
Tenths
H23VBN_Mag
H23 Voltage B-N Magnitude
1
4164
MM
%
Hundredths
1.
2.
3.
4.
5.
46
SMS Topic Names beginning with “H” are Type H harmonic topics.
For register entries that are not listed, please refer to the MICROLOGIC device type register list. Contact your local sales representative.
3-register date/time format: register 1: month (byte 1) = 1–12; day (byte 2) = 1–31
register 2: year (byte 1) = 0–199 (add to 1900 to determine the actual year); hour (byte 2) = 0–23
register 3: minutes (byte 1) = 0–59; seconds (byte 2) = 0–59
Note: Bits 14 and 15 of the month/day register must be masked.
Modulo 10,000 format: 1 to 4 sequential registers. Each register is Modulo 10,000 (range = –9,999 to +9,999).
Result is [R4*10,000^3 + R3*10,000^2 + R2*10,000^1] + R1. Range is zero to 9,999,999,999,999,999.
Power factor format: –1 to –999 for lagging power factors, 1000 for unity power factor 1.000, and 1 to 999 for leading power factors.
© 2002 Schneider Electric All Rights Reserved
63220-080-200/B1
August 2002
Appendix C–Type H Standard Quantities
Using MICROLOGIC Trip Units in a POWERLOGIC System
SMS Topic Name1
User Description
Number of
Registers
Register2
Module
Units
H23VCA_Ang
H23 Voltage C-A Angle
1
4312
MM
Deg
Tenths
H23VCA_Mag
H23 Voltage C-A Magnitude
1
4162
MM
%
Hundredths
H23VCN_Ang
H23 Voltage C-N Angle
1
4315
MM
Deg
Tenths
H23VCN_Mag
H23 Voltage C-N Magnitude
1
4165
MM
%
Hundredths
H24IA_Ang
H24 Current A Angle
1
4684
MM
Deg
Tenths
H24IA_Mag
H24 Current A Magnitude
1
4534
MM
%
Hundredths
H24IB_Ang
H24 Current B Angle
1
4685
MM
Deg
Tenths
Scale
H24IB_Mag
H24 Current B Magnitude
1
4535
MM
%
Hundredths
H24IC_Ang
H24 Current C Angle
1
4686
MM
Deg
Tenths
H24IC_Mag
H24 Current C Magnitude
1
4536
MM
%
Hundredths
H24IN_Ang
H24 Current N Angle
1
4687
MM
Deg
Tenths
H24IN_Mag
H24 Current N Magnitude
1
4537
MM
%
Hundredths
H24VAB_Ang
H24 Voltage A-B Angle
1
4616
MM
Deg
Tenths
H24VAB_Mag
H24 Voltage A-B Magnitude
1
4466
MM
%
Hundredths
H24VAN_Ang
H24 Voltage A-N Angle
1
4619
MM
Deg
Tenths
H24VAN_Mag
H24 Voltage A-N Magnitude
1
4469
MM
%
Hundredths
H24VBC_Ang
H24 Voltage B-C Angle
1
4617
MM
Deg
Tenths
H24VBC_Mag
H24 Voltage B-C Magnitude
1
4467
MM
%
Hundredths
H24VBN_Ang
H24 Voltage B-N Angle
1
4620
MM
Deg
Tenths
H24VBN_Mag
H24 Voltage B-N Magnitude
1
4470
MM
%
Hundredths
H24VCA_Ang
H24 Voltage C-A Angle
1
4618
MM
Deg
Tenths
H24VCA_Mag
H24 Voltage C-A Magnitude
1
4468
MM
%
Hundredths
H24VCN_Ang
H24 Voltage C-N Angle
1
4621
MM
Deg
Tenths
H24VCN_Mag
H24 Voltage C-N Magnitude
1
4471
MM
%
Hundredths
H25IA_Ang
H25 Current A Angle
1
4384
MM
Deg
Tenths
H25IA_Mag
H25 Current A Magnitude
1
4234
MM
%
Hundredths
H25IB_Ang
H25 Current B Angle
1
4385
MM
Deg
Tenths
H25IB_Mag
H25 Current B Magnitude
1
4235
MM
%
Hundredths
H25IC_Ang
H25 Current C Angle
1
4386
MM
Deg
Tenths
H25IC_Mag
H25 Current C Magnitude
1
4236
MM
%
Hundredths
H25IN_Ang
H25 Current N Angle
1
4387
MM
Deg
Tenths
H25IN_Mag
H25 Current N Magnitude
1
4237
MM
%
Hundredths
H25VAB_Ang
H25 Voltage A-B Angle
1
4316
MM
Deg
Tenths
H25VAB_Mag
H25 Voltage A-B Magnitude
1
4166
MM
%
Hundredths
H25VAN_Ang
H25 Voltage A-N Angle
1
4319
MM
Deg
Tenths
H25VAN_Mag
H25 Voltage A-N Magnitude
1
4169
MM
%
Hundredths
H25VBC_Ang
H25 Voltage B-C Angle
1
4317
MM
Deg
Tenths
H25VBC_Mag
H25 Voltage B-C Magnitude
1
4167
MM
%
Hundredths
H25VBN_Ang
H25 Voltage B-N Angle
1
4320
MM
Deg
Tenths
H25VBN_Mag
H25 Voltage B-N Magnitude
1
4170
MM
%
Hundredths
H25VCA_Ang
H25 Voltage C-A Angle
1
4318
MM
Deg
Tenths
1.
2.
3.
4.
5.
SMS Topic Names beginning with “H” are Type H harmonic topics.
For register entries that are not listed, please refer to the MICROLOGIC device type register list. Contact your local sales representative.
3-register date/time format: register 1: month (byte 1) = 1–12; day (byte 2) = 1–31
register 2: year (byte 1) = 0–199 (add to 1900 to determine the actual year); hour (byte 2) = 0–23
register 3: minutes (byte 1) = 0–59; seconds (byte 2) = 0–59
Note: Bits 14 and 15 of the month/day register must be masked.
Modulo 10,000 format: 1 to 4 sequential registers. Each register is Modulo 10,000 (range = –9,999 to +9,999).
Result is [R4*10,000^3 + R3*10,000^2 + R2*10,000^1] + R1. Range is zero to 9,999,999,999,999,999.
Power factor format: –1 to –999 for lagging power factors, 1000 for unity power factor 1.000, and 1 to 999 for leading power factors.
© 2002 Schneider Electric All Rights Reserved
47
Appendix C–Type H Standard Quantities
Using MICROLOGIC Trip Units in a POWERLOGIC System
63220-080-200/B1
August 2002
SMS Topic Name1
User Description
Number of
Registers
Register2
Module
Units
Scale
H25VCA_Mag
H25 Voltage C-A Magnitude
1
4168
MM
%
Hundredths
H25VCN_Ang
H25 Voltage C-N Angle
1
4321
MM
Deg
Tenths
H25VCN_Mag
H25 Voltage C-N Magnitude
1
4171
MM
%
Hundredths
H26IA_Ang
H26 Current A Angle
1
4688
MM
Deg
Tenths
H26IA_Mag
H26 Current A Magnitude
1
4538
MM
%
Hundredths
H26IB_Ang
H26 Current B Angle
1
4689
MM
Deg
Tenths
H26IB_Mag
H26 Current B Magnitude
1
4539
MM
%
Hundredths
Tenths
H26IC_Ang
H26 Current C Angle
1
4690
MM
Deg
H26IC_Mag
H26 Current C Magnitude
1
4540
MM
%
Hundredths
H26IN_Ang
H26 Current N Angle
1
4691
MM
Deg
Tenths
H26IN_Mag
H26 Current N Magnitude
1
4541
MM
%
Hundredths
H26VAB_Ang
H26 Voltage A-B Angle
1
4622
MM
Deg
Tenths
H26VAB_Mag
H26 Voltage A-B Magnitude
1
4472
MM
%
Hundredths
H26VAN_Ang
H26 Voltage A-N Angle
1
4625
MM
Deg
Tenths
H26VAN_Mag
H26 Voltage A-N Magnitude
1
4475
MM
%
Hundredths
H26VBC_Ang
H26 Voltage B-C Angle
1
4623
MM
Deg
Tenths
H26VBC_Mag
H26 Voltage B-C Magnitude
1
4473
MM
%
Hundredths
H26VBN_Ang
H26 Voltage B-N Angle
1
4626
MM
Deg
Tenths
H26VBN_Mag
H26 Voltage B-N Magnitude
1
4476
MM
%
Hundredths
H26VCA_Ang
H26 Voltage C-A Angle
1
4624
MM
Deg
Tenths
H26VCA_Mag
H26 Voltage C-A Magnitude
1
4474
MM
%
Hundredths
H26VCN_Ang
H26 Voltage C-N Angle
1
4627
MM
Deg
Tenths
H26VCN_Mag
H26 Voltage C-N Magnitude
1
4477
MM
%
Hundredths
H27IA_Ang
H27 Current A Angle
1
4388
MM
Deg
Tenths
H27IA_Mag
H27 Current A Magnitude
1
4238
MM
%
Hundredths
H27IB_Ang
H27 Current B Angle
1
4389
MM
Deg
Tenths
H27IB_Mag
H27 Current B Magnitude
1
4239
MM
%
Hundredths
Tenths
H27IC_Ang
H27 Current C Angle
1
4390
MM
Deg
H27IC_Mag
H27 Current C Magnitude
1
4240
MM
%
Hundredths
H27IN_Ang
H27 Current N Angle
1
4391
MM
Deg
Tenths
H27IN_Mag
H27 Current N Magnitude
1
4241
MM
%
Hundredths
H27VAB_Ang
H27 Voltage A-B Angle
1
4322
MM
Deg
Tenths
H27VAB_Mag
H27 Voltage A-B Magnitude
1
4172
MM
%
Hundredths
H27VAN_Ang
H27 Voltage A-N Angle
1
4325
MM
Deg
Tenths
H27VAN_Mag
H27 Voltage A-N Magnitude
1
4175
MM
%
Hundredths
H27VBC_Ang
H27 Voltage B-C Angle
1
4323
MM
Deg
Tenths
H27VBC_Mag
H27 Voltage B-C Magnitude
1
4173
MM
%
Hundredths
H27VBN_Ang
H27 Voltage B-N Angle
1
4326
MM
Deg
Tenths
H27VBN_Mag
H27 Voltage B-N Magnitude
1
4176
MM
%
Hundredths
H27VCA_Ang
H27 Voltage C-A Angle
1
4324
MM
Deg
Tenths
H27VCA_Mag
H27 Voltage C-A Magnitude
1
4174
MM
%
Hundredths
1.
2.
3.
4.
5.
48
SMS Topic Names beginning with “H” are Type H harmonic topics.
For register entries that are not listed, please refer to the MICROLOGIC device type register list. Contact your local sales representative.
3-register date/time format: register 1: month (byte 1) = 1–12; day (byte 2) = 1–31
register 2: year (byte 1) = 0–199 (add to 1900 to determine the actual year); hour (byte 2) = 0–23
register 3: minutes (byte 1) = 0–59; seconds (byte 2) = 0–59
Note: Bits 14 and 15 of the month/day register must be masked.
Modulo 10,000 format: 1 to 4 sequential registers. Each register is Modulo 10,000 (range = –9,999 to +9,999).
Result is [R4*10,000^3 + R3*10,000^2 + R2*10,000^1] + R1. Range is zero to 9,999,999,999,999,999.
Power factor format: –1 to –999 for lagging power factors, 1000 for unity power factor 1.000, and 1 to 999 for leading power factors.
© 2002 Schneider Electric All Rights Reserved
63220-080-200/B1
August 2002
Appendix C–Type H Standard Quantities
Using MICROLOGIC Trip Units in a POWERLOGIC System
SMS Topic Name1
User Description
Number of
Registers
Register2
Module
Units
Scale
H27VCN_Ang
H27 Voltage C-N Angle
1
4327
MM
Deg
Tenths
H27VCN_Mag
H27 Voltage C-N Magnitude
1
4177
MM
%
Hundredths
H28IA_Ang
H28 Current A Angle
1
4692
MM
Deg
Tenths
H28IA_Mag
H28 Current A Magnitude
1
4542
MM
%
Hundredths
H28IB_Ang
H28 Current B Angle
1
4693
MM
Deg
Tenths
H28IB_Mag
H28 Current B Magnitude
1
4543
MM
%
Hundredths
H28IC_Ang
H28 Current C Angle
1
4694
MM
Deg
Tenths
H28IC_Mag
H28 Current C Magnitude
1
4544
MM
%
Hundredths
H28IN_Ang
H28 Current N Angle
1
4695
MM
Deg
Tenths
H28IN_Mag
H28 Current N Magnitude
1
4545
MM
%
Hundredths
H28VAB_Ang
H28 Voltage A-B Angle
1
4628
MM
Deg
Tenths
H28VAB_Mag
H28 Voltage A-B Magnitude
1
4478
MM
%
Hundredths
H28VAN_Ang
H28 Voltage A-N Angle
1
4631
MM
Deg
Tenths
H28VAN_Mag
H28 Voltage A-N Magnitude
1
4481
MM
%
Hundredths
H28VBC_Ang
H28 Voltage B-C Angle
1
4629
MM
Deg
Tenths
H28VBC_Mag
H28 Voltage B-C Magnitude
1
4479
MM
%
Hundredths
H28VBN_Ang
H28 Voltage B-N Angle
1
4632
MM
Deg
Tenths
H28VBN_Mag
H28 Voltage B-N Magnitude
1
4482
MM
%
Hundredths
H28VCA_Ang
H28 Voltage C-A Angle
1
4630
MM
Deg
Tenths
H28VCA_Mag
H28 Voltage C-A Magnitude
1
4480
MM
%
Hundredths
H28VCN_Ang
H28 Voltage C-N Angle
1
4633
MM
Deg
Tenths
H28VCN_Mag
H28 Voltage C-N Magnitude
1
4483
MM
%
Hundredths
H29IA_Ang
H29 Current A Angle
1
4392
MM
Deg
Tenths
H29IA_Mag
H29 Current A Magnitude
1
4242
MM
%
Hundredths
H29IB_Ang
H29 Current B Angle
1
4393
MM
Deg
Tenths
H29IB_Mag
H29 Current B Magnitude
1
4243
MM
%
Hundredths
H29IC_Ang
H29 Current C Angle
1
4394
MM
Deg
Tenths
H29IC_Mag
H29 Current C Magnitude
1
4244
MM
%
Hundredths
H29IN_Ang
H29 Current N Angle
1
4395
MM
Deg
Tenths
H29IN_Mag
H29 Current N Magnitude
1
4245
MM
%
Hundredths
H29VAB_Ang
H29 Voltage A-B Angle
1
4328
MM
Deg
Tenths
H29VAB_Mag
H29 Voltage A-B Magnitude
1
4178
MM
%
Hundredths
H29VAN_Ang
H29 Voltage A-N Angle
1
4331
MM
Deg
Tenths
H29VAN_Mag
H29 Voltage A-N Magnitude
1
4181
MM
%
Hundredths
H29VBC_Ang
H29 Voltage B-C Angle
1
4329
MM
Deg
Tenths
H29VBC_Mag
H29 Voltage B-C Magnitude
1
4179
MM
%
Hundredths
H29VBN_Ang
H29 Voltage B-N Angle
1
4332
MM
Deg
Tenths
H29VBN_Mag
H29 Voltage B-N Magnitude
1
4182
MM
%
Hundredths
H29VCA_Ang
H29 Voltage C-A Angle
1
4330
MM
Deg
Tenths
H29VCA_Mag
H29 Voltage C-A Magnitude
1
4180
MM
%
Hundredths
H29VCN_Ang
H29 Voltage C-N Angle
1
4333
MM
Deg
Tenths
1.
2.
3.
4.
5.
SMS Topic Names beginning with “H” are Type H harmonic topics.
For register entries that are not listed, please refer to the MICROLOGIC device type register list. Contact your local sales representative.
3-register date/time format: register 1: month (byte 1) = 1–12; day (byte 2) = 1–31
register 2: year (byte 1) = 0–199 (add to 1900 to determine the actual year); hour (byte 2) = 0–23
register 3: minutes (byte 1) = 0–59; seconds (byte 2) = 0–59
Note: Bits 14 and 15 of the month/day register must be masked.
Modulo 10,000 format: 1 to 4 sequential registers. Each register is Modulo 10,000 (range = –9,999 to +9,999).
Result is [R4*10,000^3 + R3*10,000^2 + R2*10,000^1] + R1. Range is zero to 9,999,999,999,999,999.
Power factor format: –1 to –999 for lagging power factors, 1000 for unity power factor 1.000, and 1 to 999 for leading power factors.
© 2002 Schneider Electric All Rights Reserved
49
Appendix C–Type H Standard Quantities
Using MICROLOGIC Trip Units in a POWERLOGIC System
63220-080-200/B1
August 2002
SMS Topic Name1
User Description
Number of
Registers
Register2
Module
Units
Scale
H29VCN_Mag
H29 Voltage C-N Magnitude
1
4183
MM
%
Hundredths
H2IA_Ang
H2 Current A Angle
1
4640
MM
Deg
Tenths
H2IA_Mag
H2 Current A Magnitude
1
4490
MM
%
Hundredths
H2IB_Ang
H2 Current B Angle
1
4641
MM
Deg
Tenths
H2IB_Mag
H2 Current B Magnitude
1
4491
MM
%
Hundredths
H2IC_Ang
H2 Current C Angle
1
4642
MM
Deg
Tenths
H2IC_Mag
H2 Current C Magnitude
1
4492
MM
%
Hundredths
H2IN_Ang
H2 Current N Angle
1
4643
MM
Deg
Tenths
H2IN_Mag
H2 Current N Magnitude
1
4493
MM
%
Hundredths
H2VAB_Ang
H2 Voltage A-B Angle
1
4550
MM
Deg
Tenths
H2VAB_Mag
H2 Voltage A-B Magnitude
1
4400
MM
%
Hundredths
Tenths
H2VAN_Ang
H2 Voltage A-N Angle
1
4553
MM
Deg
H2VAN_Mag
H2 Voltage A-N Magnitude
1
4403
MM
%
Hundredths
H2VBC_Ang
H2 Voltage B-C Angle
1
4551
MM
Deg
Tenths
H2VBC_Mag
H2 Voltage B-C Magnitude
1
4401
MM
%
Hundredths
H2VBN_Ang
H2 Voltage B-N Angle
1
4554
MM
Deg
Tenths
H2VBN_Mag
H2 Voltage B-N Magnitude
1
4404
MM
%
Hundredths
H2VCA_Ang
H2 Voltage C-A Angle
1
4552
MM
Deg
Tenths
H2VCA_Mag
H2 Voltage C-A Magnitude
1
4402
MM
%
Hundredths
H2VCN_Ang
H2 Voltage C-N Angle
1
4555
MM
Deg
Tenths
H2VCN_Mag
H2 Voltage C-N Magnitude
1
4405
MM
%
Hundredths
H30IA_Ang
H30 Current A Angle
1
4696
MM
Deg
Tenths
H30IA_Mag
H30 Current A Magnitude
1
4546
MM
%
Hundredths
Tenths
H30IB_Ang
H30 Current B Angle
1
4697
MM
Deg
H30IB_Mag
H30 Current B Magnitude
1
4547
MM
%
Hundredths
H30IC_Ang
H30 Current C Angle
1
4698
MM
Deg
Tenths
H30IC_Mag
H30 Current C Magnitude
1
4548
MM
%
Hundredths
Tenths
H30IN_Ang
H30 Current N Angle
1
4699
MM
Deg
H30IN_Mag
H30 Current N Magnitude
1
4549
MM
%
Hundredths
H30VAB_Ang
H30 Voltage A-B Angle
1
4634
MM
Deg
Tenths
H30VAB_Mag
H30 Voltage A-B Magnitude
1
4484
MM
%
Hundredths
H30VAN_Ang
H30 Voltage A-N Angle
1
4637
MM
Deg
Tenths
H30VAN_Mag
H30VBC_Ang5
H30 Voltage A-N Magnitude
1
4487
MM
%
Hundredths
H30 Voltage B-C Angle
1
4635
MM
Deg
Tenths
H30VBC_Mag5
H30VBN_Ang5
H30 Voltage B-C Magnitude
1
4485
MM
%
Hundredths
H30 Voltage B-N Angle
1
4638
MM
Deg
Tenths
H30VBN_Mag5
H30VCA_Ang5
H30 Voltage B-N Magnitude
1
4488
MM
%
Hundredths
H30 Voltage C-A Angle
1
4636
MM
Deg
Tenths
H30VCA_Mag5
H30VCN_Ang5
H30 Voltage C-A Magnitude
1
4486
MM
%
Hundredths
H30 Voltage C-N Angle
1
4639
MM
Deg
Tenths
H30VCN_Mag5
H30 Voltage C-N Magnitude
1
4489
MM
%
Hundredths
1.
2.
3.
4.
5.
50
SMS Topic Names beginning with “H” are Type H harmonic topics.
For register entries that are not listed, please refer to the MICROLOGIC device type register list. Contact your local sales representative.
3-register date/time format: register 1: month (byte 1) = 1–12; day (byte 2) = 1–31
register 2: year (byte 1) = 0–199 (add to 1900 to determine the actual year); hour (byte 2) = 0–23
register 3: minutes (byte 1) = 0–59; seconds (byte 2) = 0–59
Note: Bits 14 and 15 of the month/day register must be masked.
Modulo 10,000 format: 1 to 4 sequential registers. Each register is Modulo 10,000 (range = –9,999 to +9,999).
Result is [R4*10,000^3 + R3*10,000^2 + R2*10,000^1] + R1. Range is zero to 9,999,999,999,999,999.
Power factor format: –1 to –999 for lagging power factors, 1000 for unity power factor 1.000, and 1 to 999 for leading power factors.
© 2002 Schneider Electric All Rights Reserved
63220-080-200/B1
August 2002
Appendix C–Type H Standard Quantities
Using MICROLOGIC Trip Units in a POWERLOGIC System
SMS Topic Name1
H31IA_Ang5
User Description
Number of
Registers
Register2
Module
Units
H31 Current A Angle
1
4396
MM
Deg
Tenths
H31IA_Mag5
H31IB_Ang5
H31 Current A Magnitude
1
4246
MM
%
Hundredths
H31 Current B Angle
1
4397
MM
Deg
Tenths
H31IB_Mag5
H31 Current B Magnitude
1
4247
MM
%
Hundredths
H31IC_Ang5
H31IC_Mag5
H31 Current C Angle
1
4398
MM
Deg
Tenths
H31 Current C Magnitude
1
4248
MM
%
Hundredths
H31IN_Ang5
H31IN_Mag5
H31 Current N Angle
1
4399
MM
Deg
Tenths
H31 Current N Magnitude
1
4249
MM
%
Hundredths
H31VAB_Ang5
H31VAB_Mag5
H31 Voltage A-B Angle
1
4334
MM
Deg
Tenths
H31 Voltage A-B Magnitude
1
4184
MM
%
Hundredths
H31VAN_Ang5
H31VAN_Mag5
H31 Voltage A-N Angle
1
4337
MM
Deg
Tenths
H31 Voltage A-N Magnitude
1
4187
MM
%
Hundredths
H31VBC_Ang5
H31VBC_Mag5
H31 Voltage B-C Angle
1
4335
MM
Deg
Tenths
H31 Voltage B-C Magnitude
1
4185
MM
%
Hundredths
H31VBN_Ang5
H31VBN_Mag5
H31 Voltage B-N Angle
1
4338
MM
Deg
Tenths
H31 Voltage B-N Magnitude
1
4188
MM
%
Hundredths
H31VCA_Ang5
H31VCA_Mag5
H31 Voltage C-A Angle
1
4336
MM
Deg
Tenths
H31 Voltage C-A Magnitude
1
4186
MM
%
Hundredths
H31VCN_Ang5
H31VCN_Mag5
H31 Voltage C-N Angle
1
4339
MM
Deg
Tenths
H31 Voltage C-N Magnitude
1
4189
MM
%
Hundredths
H3IA_Ang5
H3IA_Mag5
H3 Current A Angle
1
4340
MM
Deg
Tenths
H3 Current A Magnitude
1
4190
MM
%
Hundredths
H3IB_Ang5
H3IB_Mag5
H3 Current B Angle
1
4341
MM
Deg
Tenths
H3 Current B Magnitude
1
4191
MM
%
Hundredths
H3IC_Ang5
H3IC_Mag5
H3 Current C Angle
1
4342
MM
Deg
Tenths
H3 Current C Magnitude
1
4192
MM
%
Hundredths
H3IN_Ang5
H3IN_Mag5
H3 Current N Angle
1
4343
MM
Deg
Tenths
H3 Current N Magnitude
1
4193
MM
%
Hundredths
H3VAB_Ang5
H3VAB_Mag5
H3 Voltage A-B Angle
1
4250
MM
Deg
Tenths
H3 Voltage A-B Magnitude
1
4100
MM
%
Hundredths
H3VAN_Ang5
H3VAN_Mag5
H3 Voltage A-N Angle
1
4253
MM
Deg
Tenths
H3 Voltage A-N Magnitude
1
4103
MM
%
Hundredths
H3VBC_Ang
H3 Voltage B-C Angle
1
4251
MM
Deg
Tenths
H3VBC_Mag
H3 Voltage B-C Magnitude
1
4101
MM
%
Hundredths
H3VBN_Ang
H3 Voltage B-N Angle
1
4254
MM
Deg
Tenths
H3VBN_Mag
H3 Voltage B-N Magnitude
1
4104
MM
%
Hundredths
H3VCA_Ang
H3 Voltage C-A Angle
1
4252
MM
Deg
Tenths
H3VCA_Mag
H3 Voltage C-A Magnitude
1
4102
MM
%
Hundredths
H3VCN_Ang
H3 Voltage C-N Angle
1
4255
MM
Deg
Tenths
H3VCN_Mag
H3 Voltage C-N Magnitude
1
4105
MM
%
Hundredths
H4IA_Ang
H4 Current A Angle
1
4644
MM
Deg
Tenths
1.
2.
3.
4.
5.
Scale
SMS Topic Names beginning with “H” are Type H harmonic topics.
For register entries that are not listed, please refer to the MICROLOGIC device type register list. Contact your local sales representative.
3-register date/time format: register 1: month (byte 1) = 1–12; day (byte 2) = 1–31
register 2: year (byte 1) = 0–199 (add to 1900 to determine the actual year); hour (byte 2) = 0–23
register 3: minutes (byte 1) = 0–59; seconds (byte 2) = 0–59
Note: Bits 14 and 15 of the month/day register must be masked.
Modulo 10,000 format: 1 to 4 sequential registers. Each register is Modulo 10,000 (range = –9,999 to +9,999).
Result is [R4*10,000^3 + R3*10,000^2 + R2*10,000^1] + R1. Range is zero to 9,999,999,999,999,999.
Power factor format: –1 to –999 for lagging power factors, 1000 for unity power factor 1.000, and 1 to 999 for leading power factors.
© 2002 Schneider Electric All Rights Reserved
51
Appendix C–Type H Standard Quantities
Using MICROLOGIC Trip Units in a POWERLOGIC System
63220-080-200/B1
August 2002
SMS Topic Name1
User Description
Number of
Registers
Register2
Module
Units
Scale
H4IA_Mag
H4IB_An5
H4 Current A Magnitude
1
4494
MM
%
Hundredths
H4 Current B Angle
1
4645
MM
Deg
Tenths
H4IB_Mag
H4 Current B Magnitude
1
4495
MM
%
Hundredths
H4IC_Ang
H4 Current C Angle
1
4646
MM
Deg
Tenths
H4IC_Mag
H4 Current C Magnitude
1
4496
MM
%
Hundredths
H4IN_Ang
H4 Current N Angle
1
4647
MM
Deg
Tenths
H4IN_Mag
H4 Current N Magnitude
1
4497
MM
%
Hundredths
H4VAB_Ang
H4 Voltage A-B Angle
1
4556
MM
Deg
Tenths
H4VAB_Mag
H4 Voltage A-B Magnitude
1
4406
MM
%
Hundredths
H4VAN_Ang
H4 Voltage A-N Angle
1
4559
MM
Deg
Tenths
H4VAN_Mag
H4 Voltage A-N Magnitude
1
4409
MM
%
Hundredths
Tenths
H4VBC_Ang
H4 Voltage B-C Angle
1
4557
MM
Deg
H4VBC_Mag
H4 Voltage B-C Magnitude
1
4407
MM
%
Hundredths
H4VBN_Ang
H4 Voltage B-N Angle
1
4560
MM
Deg
Tenths
H4VBN_Mag
H4 Voltage B-N Magnitude
1
4410
MM
%
Hundredths
H4VCA_Ang
H4 Voltage C-A Angle
1
4558
MM
Deg
Tenths
H4VCA_Mag
H4 Voltage C-A Magnitude
1
4408
MM
%
Hundredths
H4VCN_Ang
H4 Voltage C-N Angle
1
4561
MM
Deg
Tenths
H4VCN_Mag
H4 Voltage C-N Magnitude
1
4411
MM
%
Hundredths
H5IA_Ang
H5 Current A Angle
1
4344
MM
Deg
Tenths
H5IA_Mag
H5 Current A Magnitude
1
4194
MM
%
Hundredths
H5IB_Ang
H5 Current B Angle
1
4345
MM
Deg
Tenths
H5IB_Mag
H5 Current B Magnitude
1
4195
MM
%
Hundredths
H5IC_Ang
H5 Current C Angle
1
4346
MM
Deg
Tenths
H5IC_Mag
H5 Current C Magnitude
1
4196
MM
%
Hundredths
H5IN_Ang
H5 Current N Angle
1
4347
MM
Deg
Tenths
H5IN_Mag
H5 Current N Magnitude
1
4197
MM
%
Hundredths
H5VAB_Ang
H5 Voltage A-B Angle
1
4256
MM
Deg
Tenths
H5VAB_Mag
H5 Voltage A-B Magnitude
1
4106
MM
%
Hundredths
H5VAN_Ang
H5 Voltage A-N Angle
1
4259
MM
Deg
Tenths
H5VAN_Mag
H5 Voltage A-N Magnitude
1
4109
MM
%
Hundredths
Tenths
H5VBC_Ang
H5 Voltage B-C Angle
1
4257
MM
Deg
H5VBC_Mag
H5 Voltage B-C Magnitude
1
4107
MM
%
Hundredths
H5VBN_Ang
H5 Voltage B-N Angle
1
4260
MM
Deg
Tenths
H5VBN_Mag
H5 Voltage B-N Magnitude
1
4110
MM
%
Hundredths
H5VCA_Ang
H5 Voltage C-A Angle
1
4258
MM
Deg
Tenths
H5VCA_Mag
H5 Voltage C-A Magnitude
1
4108
MM
%
Hundredths
H5VCN_Ang
H5 Voltage C-N Angle
1
4261
MM
Deg
Tenths
H5VCN_Mag
H5 Voltage C-N Magnitude
1
4111
MM
%
Hundredths
H6IA_Ang
H6 Current A Angle
1
4648
MM
Deg
Tenths
H6IA_Mag
H6 Current A Magnitude
1
4498
MM
%
Hundredths
1.
2.
3.
4.
5.
52
SMS Topic Names beginning with “H” are Type H harmonic topics.
For register entries that are not listed, please refer to the MICROLOGIC device type register list. Contact your local sales representative.
3-register date/time format: register 1: month (byte 1) = 1–12; day (byte 2) = 1–31
register 2: year (byte 1) = 0–199 (add to 1900 to determine the actual year); hour (byte 2) = 0–23
register 3: minutes (byte 1) = 0–59; seconds (byte 2) = 0–59
Note: Bits 14 and 15 of the month/day register must be masked.
Modulo 10,000 format: 1 to 4 sequential registers. Each register is Modulo 10,000 (range = –9,999 to +9,999).
Result is [R4*10,000^3 + R3*10,000^2 + R2*10,000^1] + R1. Range is zero to 9,999,999,999,999,999.
Power factor format: –1 to –999 for lagging power factors, 1000 for unity power factor 1.000, and 1 to 999 for leading power factors.
© 2002 Schneider Electric All Rights Reserved
63220-080-200/B1
August 2002
Appendix C–Type H Standard Quantities
Using MICROLOGIC Trip Units in a POWERLOGIC System
SMS Topic Name1
User Description
Number of
Registers
Register2
Module
Units
H6IB_Ang
H6 Current B Angle
1
4649
MM
Deg
Tenths
H6IB_Mag
H6 Current B Magnitude
1
4499
MM
%
Hundredths
H6IC_Ang
H6 Current C Angle
1
4650
MM
Deg
Tenths
H6IC_Mag
H6 Current C Magnitude
1
4500
MM
%
Hundredths
H6IN_Ang
H6 Current N Angle
1
4651
MM
Deg
Tenths
H6IN_Mag
H6 Current N Magnitude
1
4501
MM
%
Hundredths
H6VAB_Ang
H6 Voltage A-B Angle
1
4562
MM
Deg
Tenths
Scale
H6VAB_Mag
H6 Voltage A-B Magnitude
1
4412
MM
%
Hundredths
H6VAN_Ang
H6 Voltage A-N Angle
1
4565
MM
Deg
Tenths
H6VAN_Mag
H6 Voltage A-N Magnitude
1
4415
MM
%
Hundredths
H6VBC_Ang
H6 Voltage B-C Angle
1
4563
MM
Deg
Tenths
H6VBC_Mag
H6 Voltage B-C Magnitude
1
4413
MM
%
Hundredths
H6VBN_Ang
H6 Voltage B-N Angle
1
4566
MM
Deg
Tenths
H6VBN_Mag
H6 Voltage B-N Magnitude
1
4416
MM
%
Hundredths
H6VCA_Ang
H6 Voltage C-A Angle
1
4564
MM
Deg
Tenths
H6VCA_Mag
H6 Voltage C-A Magnitude
1
4414
MM
%
Hundredths
H6VCN_Ang
H6 Voltage C-N Angle
1
4567
MM
Deg
Tenths
H6VCN_Mag
H6 Voltage C-N Magnitude
1
4417
MM
%
Hundredths
H7IA_Ang
H7 Current A Angle
1
4348
MM
Deg
Tenths
H7IA_Mag
H7 Current A Magnitude
1
4198
MM
%
Hundredths
H7IB_Ang
H7 Current B Angle
1
4349
MM
Deg
Tenths
H7IB_Mag
H7 Current B Magnitude
1
4199
MM
%
Hundredths
H7IC_Ang
H7 Current C Angle
1
4350
MM
Deg
Tenths
H7IC_Mag
H7 Current C Magnitude
1
4200
MM
%
Hundredths
H7IN_Ang
H7 Current N Angle
1
4351
MM
Deg
Tenths
H7IN_Mag
H7 Current N Magnitude
1
4201
MM
%
Hundredths
H7VAB_Ang
H7 Voltage A-B Angle
1
4262
MM
Deg
Tenths
H7VAB_Mag
H7 Voltage A-B Magnitude
1
4112
MM
%
Hundredths
H7VAN_Ang
H7 Voltage A-N Angle
1
4265
MM
Deg
Tenths
H7VAN_Mag
H7 Voltage A-N Magnitude
1
4115
MM
%
Hundredths
H7VBC_Ang
H7 Voltage B-C Angle
1
4263
MM
Deg
Tenths
H7VBC_Mag
H7 Voltage B-C Magnitude
1
4113
MM
%
Hundredths
H7VBN_Ang
H7 Voltage B-N Angle
1
4266
MM
Deg
Tenths
H7VBN_Mag
H7 Voltage B-N Magnitude
1
4116
MM
%
Hundredths
H7VCA_Ang
H7 Voltage C-A Angle
1
4264
MM
Deg
Tenths
H7VCA_Mag
H7 Voltage C-A Magnitude
1
4114
MM
%
Hundredths
H7VCN_Ang
H7 Voltage C-N Angle
1
4267
MM
Deg
Tenths
H7VCN_Mag
H7 Voltage C-N Magnitude
1
4117
MM
%
Hundredths
H8IA_Ang
H8 Current A Angle
1
4652
MM
Deg
Tenths
H8IA_Mag
H8 Current A Magnitude
1
4502
MM
%
Hundredths
H8IB_Ang
H8 Current B Angle
1
4653
MM
Deg
Tenths
1.
2.
3.
4.
5.
SMS Topic Names beginning with “H” are Type H harmonic topics.
For register entries that are not listed, please refer to the MICROLOGIC device type register list. Contact your local sales representative.
3-register date/time format: register 1: month (byte 1) = 1–12; day (byte 2) = 1–31
register 2: year (byte 1) = 0–199 (add to 1900 to determine the actual year); hour (byte 2) = 0–23
register 3: minutes (byte 1) = 0–59; seconds (byte 2) = 0–59
Note: Bits 14 and 15 of the month/day register must be masked.
Modulo 10,000 format: 1 to 4 sequential registers. Each register is Modulo 10,000 (range = –9,999 to +9,999).
Result is [R4*10,000^3 + R3*10,000^2 + R2*10,000^1] + R1. Range is zero to 9,999,999,999,999,999.
Power factor format: –1 to –999 for lagging power factors, 1000 for unity power factor 1.000, and 1 to 999 for leading power factors.
© 2002 Schneider Electric All Rights Reserved
53
Appendix C–Type H Standard Quantities
Using MICROLOGIC Trip Units in a POWERLOGIC System
63220-080-200/B1
August 2002
SMS Topic Name1
User Description
Number of
Registers
Register2
Module
Units
Scale
H8IB_Mag
H8 Current B Magnitude
1
4503
MM
%
Hundredths
H8IC_Ang
H8 Current C Angle
1
4654
MM
Deg
Tenths
H8IC_Mag
H8 Current C Magnitude
1
4504
MM
%
Hundredths
H8IN_Ang
H8 Current N Angle
1
4655
MM
Deg
Tenths
H8IN_Mag
H8 Current N Magnitude
1
4505
MM
%
Hundredths
H8VAB_Ang
H8 Voltage A-B Angle
1
4568
MM
Deg
Tenths
H8VAB_Mag
H8 Voltage A-B Magnitude
1
4418
MM
%
Hundredths
Tenths
H8VAN_Ang
H8 Voltage A-N Angle
1
4571
MM
Deg
H8VAN_Mag
H8 Voltage A-N Magnitude
1
4421
MM
%
Hundredths
H8VBC_Ang
H8 Voltage B-C Angle
1
4569
MM
Deg
Tenths
H8VBC_Mag
H8 Voltage B-C Magnitude
1
4419
MM
%
Hundredths
H8VBN_Ang
H8 Voltage B-N Angle
1
4572
MM
Deg
Tenths
H8VBN_Mag
H8 Voltage B-N Magnitude
1
4422
MM
%
Hundredths
H8VCA_Ang
H8 Voltage C-A Angle
1
4570
MM
Deg
Tenths
H8VCA_Mag
H8 Voltage C-A Magnitude
1
4420
MM
%
Hundredths
H8VCN_Ang
H8 Voltage C-N Angle
1
4573
MM
Deg
Tenths
H8VCN_Mag
H8 Voltage C-N Magnitude
1
4423
MM
%
Hundredths
H9IA_Ang
H9 Current A Angle
1
4352
MM
Deg
Tenths
H9IA_Mag
H9 Current A Magnitude
1
4202
MM
%
Hundredths
H9IB_Ang
H9 Current B Angle
1
4353
MM
Deg
Tenths
H9IB_Mag
H9 Current B Magnitude
1
4203
MM
%
Hundredths
H9IC_Ang
H9 Current C Angle
1
4354
MM
Deg
Tenths
H9IC_Mag
H9 Current C Magnitude
1
4204
MM
%
Hundredths
H9IN_Ang
H9 Current N Angle
1
4355
MM
Deg
Tenths
H9IN_Mag
H9 Current N Magnitude
1
4205
MM
%
Hundredths
H9VAB_Ang
H9 Voltage A-B Angle
1
4268
MM
Deg
Tenths
H9VAB_Mag
H9 Voltage A-B Magnitude
1
4118
MM
%
Hundredths
Tenths
H9VAN_Ang
H9 Voltage A-N Angle
1
4271
MM
Deg
H9VAN_Mag
H9 Voltage A-N Magnitude
1
4121
MM
%
Hundredths
H9VBC_Ang
H9 Voltage B-C Angle
1
4269
MM
Deg
Tenths
H9VBC_Mag
H9 Voltage B-C Magnitude
1
4119
MM
%
Hundredths
H9VBN_Ang
H9 Voltage B-N Angle
1
4272
MM
Deg
Tenths
H9VBN_Mag
H9 Voltage B-N Magnitude
1
4122
MM
%
Hundredths
H9VCA_Ang
H9 Voltage C-A Angle
1
4270
MM
Deg
Tenths
H9VCA_Mag
H9 Voltage C-A Magnitude
1
4120
MM
%
Hundredths
Tenths
H9VCN_Ang
H9 Voltage C-N Angle
1
4273
MM
Deg
H9VCN_Mag
H9 Voltage C-N Magnitude
1
4123
MM
%
Hundredths
Hz
Frequency
1
1054
MM
Hz
Tenths
IA
Current A
1
1016
MM
A
Unity
IA_PCT
Current A % Load
1
8837
PM
%
Unity
IAD
Demand Current A
1
2200
MM
A
Unity
1.
2.
3.
4.
5.
54
SMS Topic Names beginning with “H” are Type H harmonic topics.
For register entries that are not listed, please refer to the MICROLOGIC device type register list. Contact your local sales representative.
3-register date/time format: register 1: month (byte 1) = 1–12; day (byte 2) = 1–31
register 2: year (byte 1) = 0–199 (add to 1900 to determine the actual year); hour (byte 2) = 0–23
register 3: minutes (byte 1) = 0–59; seconds (byte 2) = 0–59
Note: Bits 14 and 15 of the month/day register must be masked.
Modulo 10,000 format: 1 to 4 sequential registers. Each register is Modulo 10,000 (range = –9,999 to +9,999).
Result is [R4*10,000^3 + R3*10,000^2 + R2*10,000^1] + R1. Range is zero to 9,999,999,999,999,999.
Power factor format: –1 to –999 for lagging power factors, 1000 for unity power factor 1.000, and 1 to 999 for leading power factors.
© 2002 Schneider Electric All Rights Reserved
63220-080-200/B1
August 2002
Appendix C–Type H Standard Quantities
Using MICROLOGIC Trip Units in a POWERLOGIC System
SMS Topic Name1
User Description
Number of
Registers
Register2
Module
Units
IAppA
Current Apparent A
1
1023
MM
A
Unity
IAppB
Current Apparent B
1
1024
MM
A
Unity
IAppC
Current Apparent C
1
1025
MM
A
Unity
Unity
Scale
IAppN
Current Apparent N
1
1026
MM
A
IAvg
Current Avg
1
1027
MM
A
Unity
IB
Current B
1
1017
MM
A
Unity
IB_PCT
Current B % Load
1
8838
PM
%
Unity
Unity
IBD
Demand Current B
1
2201
MM
A
IC
Current C
1
1018
MM
A
Unity
IC_PCT
Current C % Load
1
8839
PM
%
Unity
ICD
Demand Current C
1
2202
MM
A
Unity
Unity
IDatPkKFD_A
Current Demand at Peak K-Factor Demand A
1
2270
MM
A
IDatPkKFD_B
Current Demand at Peak K-Factor Demand B
1
2271
MM
A
Unity
IDatPkKFD_C
Current Demand at Peak K-Factor Demand C
1
2272
MM
A
Unity
IDatPkKFD_N
Current Demand at Peak K-Factor Demand N
1
2273
MM
A
Unity
IDCalcMeth
Current Demand Calculation Method
1
3351
MM
IG
Current G
1
1021
MM
A
Unity
IG_PCT
Current G % Load
1
8841
PM
%
Unity
IG_PCT_VIGI
Current G (VIGI) % Load
1
8842
PM
%
Hundredths
0 = Sliding
1 = Thermal
IG_VIGI
Current G (VIGI)
1
8826
PM
A
Thousandths
IMax
Current Max Present
1
1020
MM
A
Unity
IN
Current N
1
1019
MM
A
Unity
IN_PCT
Current N % Load
1
8840
PM
%
Unity
IND
Demand Current N
1
2203
MM
A
Unity
IUnbalA
Current Unbalance A
1
1028
MM
%
Tenths
Tenths
IUnbalAlrm
Current Unbalance Alarm Status
1
8859
PM
IUnbalB
Current Unbalance B
1
1029
MM
%
%
IUnbalC
Current Unbalance C
1
1030
MM
IUnbalPreAlrm
Current Unbalance Pre-Alarm Status
1
8863
PM
IUnbalW
Current Unbalance Worst
1
1032
MM
KFDatPkID_A
K-Factor Demand at Peak Demand Current A
1
2254
MM
Bit 0; ON = active; OFF = inactive
Tenths
Bit 0; ON = active, OFF = inactive
%
Tenths
Tenths
KFDatPkID_B
K-Factor Demand at Peak Demand Current B
1
2255
MM
Tenths
KFDatPkID_C
K-Factor Demand at Peak Demand Current C
1
2256
MM
Tenths
KFDatPkID_N
K-Factor Demand at Peak Demand Current N
1
2257
MM
Tenths
KFDN
K-Factor Demand N
1
2215
MM
Tenths
KFN
K-Factor N
1
1118
MM
kVAA
Apparent Power A
1
1042
MM
kVA
Unity
kVAB
Apparent Power B
1
1043
MM
kVA
Unity
kVAC
Apparent Power C
1
1044
MM
kVA
Unity
kVAD
Demand Apparent Power
1
2236
MM
kVA
Unity
1.
2.
3.
4.
5.
Tenths
SMS Topic Names beginning with “H” are Type H harmonic topics.
For register entries that are not listed, please refer to the MICROLOGIC device type register list. Contact your local sales representative.
3-register date/time format: register 1: month (byte 1) = 1–12; day (byte 2) = 1–31
register 2: year (byte 1) = 0–199 (add to 1900 to determine the actual year); hour (byte 2) = 0–23
register 3: minutes (byte 1) = 0–59; seconds (byte 2) = 0–59
Note: Bits 14 and 15 of the month/day register must be masked.
Modulo 10,000 format: 1 to 4 sequential registers. Each register is Modulo 10,000 (range = –9,999 to +9,999).
Result is [R4*10,000^3 + R3*10,000^2 + R2*10,000^1] + R1. Range is zero to 9,999,999,999,999,999.
Power factor format: –1 to –999 for lagging power factors, 1000 for unity power factor 1.000, and 1 to 999 for leading power factors.
© 2002 Schneider Electric All Rights Reserved
55
Appendix C–Type H Standard Quantities
Using MICROLOGIC Trip Units in a POWERLOGIC System
63220-080-200/B1
August 2002
SMS Topic Name1
User Description
Number of
Registers
Register2
Module
Units
Scale
kVAD_PkkVARD
KVA Dmd Coincident w/Peak KVAR Dmd
1
2235
MM
kVA
Unity
kVAD_PkkWD
KVA Dmd Coincident w/Peak KW Dmd
1
2229
MM
kVA
Unity
kVAHr
Apparent Energy
4
2024
MM
kVAH
Modulo 10,0004
kVARA
Reactive Power A
1
1038
MM
kVAR
Unity
kVARB
Reactive Power B
1
1039
MM
kVAR
Unity
kVARC
Reactive Power C
1
1040
MM
kVAR
Unity
kVARD
Demand Reactive Power
1
2230
MM
kVAR
Unity
kVARD_PkkVAD
KVAR Dmd Coincident w/Peak KVA Dmd
1
2241
MM
kVAR
Unity
kVARD_PkkWD
KVAR Dmd Coincident w/Peak KW Dmd
1
2228
MM
kVAR
Unity
kVARHr
Reactive Energy
4
2004
MM
kVARH
kVARHr_I
Reactive Energy Into the Load
4
2016
MM
kVARH
Modulo 10,0004
Modulo 10,0004
kVARHr_O
Reactive Energy Out of the Load
4
2020
MM
kVARH
Modulo 10,0004
kVARTtl
Reactive Power Total
1
1041
MM
kVAR
Unity
kVATtl
Apparent Power Total
1
1045
MM
kVA
Unity
kWA
Real Power A
1
1034
MM
kW
Unity
kWB
Real Power B
1
1035
MM
kW
Unity
kWC
Real Power C
1
1036
MM
kW
Unity
kWD
Demand Real Power
1
2224
MM
kW
Unity
kWD_PkkVAD
KW Dmd Coincident w/Peak KVA Dmd
1
2240
MM
kW
Unity
kWD_PkkVARD
KW Dmd Coincident w/Peak KVAR Dmd
1
2234
MM
kW
kWHr
Real Energy
4
2000
MM
kWH
kWHr_I
Real Energy Into the Load
4
2008
MM
kWH
Unity
Modulo 10,0004
Modulo 10,0004
kWHr_O
Real Energy Out of the Load
4
2012
MM
kWH
Modulo 10,0004
kWTtl
Real Power Total
1
1037
MM
kW
LDPUValue
Long Delay Pickup Value
2
8756
PM
A
Unity
Modulo 10,0004
LSCurrAlrm
Load Shed Current Alarm Status
1
8859
PM
Bit 13; ON = active; OFF = inactive
LSCurrPreAlrm
Load Shed Current Pre-Alarm Status
1
8863
PM
Bit 13; ON = active; OFF = inactive
LSPwrAlrm
Load Shed Power Alarm Status
1
8859
PM
Bit 14; ON = active; OFF = inactive
LSPwrPreAlrm
Load Shed Power Pre-Alarm Status
1
8863
PM
Bit 14; ON = active; OFF = inactive
M2C_M6CR1Status
Relay Module R1 Status
1
8857
PM
Bit 0; ON = on; OFF = off
M2C_M6CR2Status
Relay Module R2 Status
1
8857
PM
Bit 1; ON = on; OFF = off
M2C_M6CR3Status
Relay Module R3 Status
1
8857
PM
Bit 2; ON = on; OFF = off
M2C_M6CR4Status
Relay Module R4 Status
1
8857
PM
Bit 3; ON = on; OFF = off
M2C_M6CR5Status
Relay Module R5 Status
1
8857
PM
Bit 4; ON = on; OFF = off
M2C_M6CR6Status
Relay Module R6 Status
1
8857
PM
Bit 5; ON = on; OFF = off
MaxCFVAB
Maximum Crest Factor Voltage A-B
1
1719
MM
Hundredths
MaxCFVAN
Maximum Crest Factor Voltage A-N
1
1722
MM
Hundredths
MaxCFVBC
Maximum Crest Factor Voltage B-C
1
1720
MM
Hundredths
MaxCFVBN
Maximum Crest Factor Voltage B-N
1
1723
MM
Hundredths
MaxCFVCA
Maximum Crest Factor Voltage C-A
1
1721
MM
Hundredths
MaxCFVCN
Maximum Crest Factor Voltage C-N
1
1724
MM
Hundredths
1.
2.
3.
4.
5.
56
SMS Topic Names beginning with “H” are Type H harmonic topics.
For register entries that are not listed, please refer to the MICROLOGIC device type register list. Contact your local sales representative.
3-register date/time format: register 1: month (byte 1) = 1–12; day (byte 2) = 1–31
register 2: year (byte 1) = 0–199 (add to 1900 to determine the actual year); hour (byte 2) = 0–23
register 3: minutes (byte 1) = 0–59; seconds (byte 2) = 0–59
Note: Bits 14 and 15 of the month/day register must be masked.
Modulo 10,000 format: 1 to 4 sequential registers. Each register is Modulo 10,000 (range = –9,999 to +9,999).
Result is [R4*10,000^3 + R3*10,000^2 + R2*10,000^1] + R1. Range is zero to 9,999,999,999,999,999.
Power factor format: –1 to –999 for lagging power factors, 1000 for unity power factor 1.000, and 1 to 999 for leading power factors.
© 2002 Schneider Electric All Rights Reserved
63220-080-200/B1
August 2002
Appendix C–Type H Standard Quantities
Using MICROLOGIC Trip Units in a POWERLOGIC System
SMS Topic Name1
User Description
Number of
Registers
Register2
Module
Units
MaxfkVAA
Maximum Fundamental Apparent Power A
1
1684
MM
kVA
Unity
MaxfkVAB
Maximum Fundamental Apparent Power B
1
1685
MM
kVA
Unity
MaxfkVAC
Maximum Fundamental Apparent Power C
1
1686
MM
kVA
Unity
MaxfkVATtl
Maximum Fundamental Apparent Power Total
1
1687
MM
kVA
Unity
MaxfVMagAB
Maximum Fundamental Voltage Mag A-B
1
1656
MM
V
Unity
MaxfVMagAN
Maximum Fundamental Voltage Mag A-N
1
1659
MM
V
Unity
MaxfVMagBC
Maximum Fundamental Voltage Mag B-C
1
1657
MM
V
Unity
MaxfVMagBN
Maximum Fundamental Voltage Mag B-N
1
1660
MM
V
Unity
MaxfVMagCA
Maximum Fundamental Voltage Mag C-A
1
1658
MM
V
Unity
MaxfVMagCN
Maximum Fundamental Voltage Mag C-N
1
1661
MM
V
Unity
MaxHz
Max Frequency
1
1654
MM
Hz
Tenths
MaxIA
Max Current A
1
1616
MM
A
Unity
MaxIAppA
Maximum Current Apparent A
1
1623
MM
A
Unity
MaxIAppB
Maximum Current Apparent B
1
1624
MM
A
Unity
MaxIAppC
Maximum Current Apparent C
1
1625
MM
A
Unity
Scale
MaxIAppN
Maximum Current Apparent N
1
1626
MM
A
Unity
MaxIAvg
Max Current Avg
1
1627
MM
A
Unity
MaxIB
Max Current B
1
1617
MM
A
Unity
MaxIC
Max Current C
1
1618
MM
A
Unity
MaxIG
Max Current G
1
1621
MM
A
Unity
MaxIG_VIGI
Max Current G (VIGI)
1
8832
PM
A
Thousandths
MaxIN
Max Current N
1
1619
MM
A
Unity
MaxIUnbalA
Max Current Unbalance A
1
1628
MM
%
Tenths
MaxIUnbalB
Max Current Unbalance B
1
1629
MM
%
Tenths
MaxIUnbalC
Max Current Unbalance C
1
1630
MM
%
Tenths
MaxIUnbalW
Max Current Unbalance Worst
1
1632
MM
%
Tenths
MaxKFN
Maximum K-Factor N
1
1718
MM
MaxkVAA
Max Apparent Power A
1
1642
MM
kVA
MaxkVAB
Max Apparent Power B
1
1643
MM
kVA
Unity
MaxkVAC
Max Apparent Power C
1
1644
MM
kVA
Unity
MaxkVARA
Max Reactive Power A
1
1638
MM
kVAR
Unity
MaxkVARB
Max Reactive Power B
1
1639
MM
kVAR
Unity
MaxkVARC
Max Reactive Power C
1
1640
MM
kVAR
Unity
MaxkVARTtl
Max Reactive Power Total
1
1641
MM
kVAR
Unity
MaxkVATtl
Max Apparent Power Total
1
1645
MM
kVA
Unity
Tenths
Unity
MaxkWA
Max Real Power A
1
1634
MM
kW
Unity
MaxkWB
Max Real Power B
1
1635
MM
kW
Unity
MaxkWC
Max Real Power C
1
1636
MM
kW
Unity
MaxkWTtl
Max Real Power Total
1
1637
MM
kW
Unity
MaxPFA
Max Power Factor A
3
1646
MM
MaxPFB
Max Power Factor B
3
1647
MM
1.
2.
3.
4.
5.
PF format5
PF format5
SMS Topic Names beginning with “H” are Type H harmonic topics.
For register entries that are not listed, please refer to the MICROLOGIC device type register list. Contact your local sales representative.
3-register date/time format: register 1: month (byte 1) = 1–12; day (byte 2) = 1–31
register 2: year (byte 1) = 0–199 (add to 1900 to determine the actual year); hour (byte 2) = 0–23
register 3: minutes (byte 1) = 0–59; seconds (byte 2) = 0–59
Note: Bits 14 and 15 of the month/day register must be masked.
Modulo 10,000 format: 1 to 4 sequential registers. Each register is Modulo 10,000 (range = –9,999 to +9,999).
Result is [R4*10,000^3 + R3*10,000^2 + R2*10,000^1] + R1. Range is zero to 9,999,999,999,999,999.
Power factor format: –1 to –999 for lagging power factors, 1000 for unity power factor 1.000, and 1 to 999 for leading power factors.
© 2002 Schneider Electric All Rights Reserved
57
Appendix C–Type H Standard Quantities
Using MICROLOGIC Trip Units in a POWERLOGIC System
63220-080-200/B1
August 2002
SMS Topic Name1
User Description
Number of
Registers
Register2
Module
MaxPFC
Max Power Factor C
3
1648
MM
Units
Scale
PF format5
PF format5
MaxPFTtl
Max Power Factor Total
3
1649
MM
MaxVAB
Max Voltage A-B
1
1600
MM
V
Unity
MaxVAN
Max Voltage A-N
1
1603
MM
V
Unity
MaxVBC
Max Voltage B-C
1
1601
MM
V
Unity
MaxVBN
Max Voltage B-N
1
1604
MM
V
Unity
MaxVCA
Max Voltage C-A
1
1602
MM
V
Unity
MaxVCN
Max Voltage C-N
1
1605
MM
V
Unity
MaxVLLAvg
Max Voltage L-L Avg
1
1606
MM
V
Unity
MaxVLNAvg
Max Voltage L-N Avg
1
1607
MM
V
Unity
MaxVUnbalAB
Max Voltage Unbalance A-B
1
1608
MM
%
Tenths
MaxVUnbalAN
Max Voltage Unbalance A-N
1
1611
MM
%
Tenths
MaxVUnbalBC
Max Voltage Unbalance B-C
1
1609
MM
%
Tenths
MaxVUnbalBN
Max Voltage Unbalance B-N
1
1612
MM
%
Tenths
MaxVUnbalCA
Max Voltage Unbalance C-A
1
1610
MM
%
Tenths
MaxVUnbalCN
Max Voltage Unbalance C-N
1
1613
MM
%
Tenths
MaxVUnbalLLW
Max Voltage Unbalance L-L Worst
1
1614
MM
%
Tenths
MaxVUnbalLNW
Max Voltage Unbalance L-N Worst
1
1615
MM
%
Tenths
MinCFVAB
Minimum Crest Factor Voltage A-B
1
1419
MM
Hundredths
MinCFVAN
Minimum Crest Factor Voltage A-N
1
1422
MM
Hundredths
MinCFVBC
Minimum Crest Factor Voltage B-C
1
1420
MM
Hundredths
MinCFVBN
Minimum Crest Factor Voltage B-N
1
1423
MM
Hundredths
MinCFVCA
Minimum Crest Factor Voltage C-A
1
1421
MM
Hundredths
MinCFVCN
Minimum Crest Factor Voltage C-N
1
1424
MM
MinfkVAA
Minimum Fundamental Apparent Power A
1
1384
MM
kVA
Unity
MinfkVAB
Minimum Fundamental Apparent Power B
1
1385
MM
kVA
Unity
MinfkVAC
Minimum Fundamental Apparent Power C
1
1386
MM
kVA
Unity
MinfkVATtl
Minimum Fundamental Apparent Power Total
1
1387
MM
kVA
Unity
MinfVMagAB
Minimum Fundamental Voltage Mag A-B
1
1356
MM
V
Unity
MinfVMagAN
Minimum Fundamental Voltage Mag A-N
1
1359
MM
V
Unity
MinfVMagBC
Minimum Fundamental Voltage Mag B-C
1
1357
MM
V
Unity
MinfVMagBN
Minimum Fundamental Voltage Mag B-N
1
1360
MM
V
Unity
MinfVMagCA
Minimum Fundamental Voltage Mag C-A
1
1358
MM
V
Unity
MinfVMagCN
Minimum Fundamental Voltage Mag C-N
1
1361
MM
V
Unity
MinHz
Min Frequency
1
1354
MM
Hz
Tenths
MinIA
Min Current A
1
1316
MM
A
Unity
MinIAppA
Minimum Current Apparent A
1
1323
MM
A
Unity
MinIAppB
Minimum Current Apparent B
1
1324
MM
A
Unity
MinIAppC
Minimum Current Apparent C
1
1325
MM
A
Unity
MinIAppN
Minimum Current Apparent N
1
1326
MM
A
Unity
MinIAvg
Min Current Avg
1
1327
MM
A
Unity
1.
2.
3.
4.
5.
58
Hundredths
SMS Topic Names beginning with “H” are Type H harmonic topics.
For register entries that are not listed, please refer to the MICROLOGIC device type register list. Contact your local sales representative.
3-register date/time format: register 1: month (byte 1) = 1–12; day (byte 2) = 1–31
register 2: year (byte 1) = 0–199 (add to 1900 to determine the actual year); hour (byte 2) = 0–23
register 3: minutes (byte 1) = 0–59; seconds (byte 2) = 0–59
Note: Bits 14 and 15 of the month/day register must be masked.
Modulo 10,000 format: 1 to 4 sequential registers. Each register is Modulo 10,000 (range = –9,999 to +9,999).
Result is [R4*10,000^3 + R3*10,000^2 + R2*10,000^1] + R1. Range is zero to 9,999,999,999,999,999.
Power factor format: –1 to –999 for lagging power factors, 1000 for unity power factor 1.000, and 1 to 999 for leading power factors.
© 2002 Schneider Electric All Rights Reserved
63220-080-200/B1
August 2002
Appendix C–Type H Standard Quantities
Using MICROLOGIC Trip Units in a POWERLOGIC System
SMS Topic Name1
User Description
Number of
Registers
Register2
Module
Units
Scale
MinIB
Min Current B
1
1317
MM
A
Unity
MinIC
Min Current C
1
1318
MM
A
Unity
MinIN
Min Current N
1
1319
MM
A
Unity
MinIUnbalA
Min Current Unbalance A
1
1328
MM
%
Tenths
MinIUnbalB
Min Current Unbalance B
1
1329
MM
%
Tenths
MinIUnbalC
Min Current Unbalance C
1
1330
MM
%
Tenths
MinIUnbalW
Min Current Unbalance Worst
1
1332
MM
%
Tenths
kVA
Unity
MinKFN
Minimum K-Factor N
1
1418
MM
MinkVAA
Min Apparent Power A
1
1342
MM
Tenths
MinkVAB
Min Apparent Power B
1
1343
MM
kVA
Unity
MinkVAC
Min Apparent Power C
1
1344
MM
kVA
Unity
MinkVARA
Min Reactive Power A
1
1338
MM
kVAR
Unity
MinkVARB
Min Reactive Power B
1
1339
MM
kVAR
Unity
MinkVARC
Min Reactive Power C
1
1340
MM
kVAR
Unity
MinkVARTtl
Min Reactive Power Total
1
1341
MM
kVAR
Unity
MinkVATtl
Min Apparent Power Total
1
1345
MM
kVA
Unity
MinkWA
Min Real Power A
1
1334
MM
kW
Unity
MinkWB
Min Real Power B
1
1335
MM
kW
Unity
MinkWC
Min Real Power C
1
1336
MM
kW
Unity
MinkWTtl
Min Real Power Total
1
1337
MM
kW
MinPFA
Min Power Factor A
3
1346
MM
MinPFB
Min Power Factor B
3
1347
MM
MinPFC
Min Power Factor C
3
1348
MM
Unity
PF format5
PF format5
PF format5
PF format5
MinPFTtl
Min Power Factor Total
3
1349
MM
MinVAB
Min Voltage A-B
1
1300
MM
V
MinVAN
Min Voltage A-N
1
1303
MM
V
Unity
MinVBC
Min Voltage B-C
1
1301
MM
V
Unity
MinVBN
Min Voltage B-N
1
1304
MM
V
Unity
MinVCA
Min Voltage C-A
1
1302
MM
V
Unity
MinVCN
Min Voltage C-N
1
1305
MM
V
Unity
MinVLLAvg
Min Voltage L-L Avg
1
1306
MM
V
Unity
MinVLNAvg
Min Voltage L-N Avg
1
1307
MM
V
Unity
MinVUnbalAB
Min Voltage Unbalance A-B
1
1308
MM
%
Tenths
MinVUnbalAN
Min Voltage Unbalance A-N
1
1311
MM
%
Tenths
MinVUnbalBC
Min Voltage Unbalance B-C
1
1309
MM
%
Tenths
MinVUnbalBN
Min Voltage Unbalance B-N
1
1312
MM
%
Tenths
MinVUnbalCA
Min Voltage Unbalance C-A
1
1310
MM
%
Tenths
MinVUnbalCN
Min Voltage Unbalance C-N
1
1313
MM
%
Tenths
MinVUnbalLLW
Min Voltage Unbalance L-L Worst
1
1314
MM
%
Tenths
MinVUnbalLNW
Min Voltage Unbalance L-N Worst
1
1315
MM
%
Tenths
NominalCurrent
Breaker Nominal Current
1
8750
PM
A
Unity
1.
2.
3.
4.
5.
Unity
SMS Topic Names beginning with “H” are Type H harmonic topics.
For register entries that are not listed, please refer to the MICROLOGIC device type register list. Contact your local sales representative.
3-register date/time format: register 1: month (byte 1) = 1–12; day (byte 2) = 1–31
register 2: year (byte 1) = 0–199 (add to 1900 to determine the actual year); hour (byte 2) = 0–23
register 3: minutes (byte 1) = 0–59; seconds (byte 2) = 0–59
Note: Bits 14 and 15 of the month/day register must be masked.
Modulo 10,000 format: 1 to 4 sequential registers. Each register is Modulo 10,000 (range = –9,999 to +9,999).
Result is [R4*10,000^3 + R3*10,000^2 + R2*10,000^1] + R1. Range is zero to 9,999,999,999,999,999.
Power factor format: –1 to –999 for lagging power factors, 1000 for unity power factor 1.000, and 1 to 999 for leading power factors.
© 2002 Schneider Electric All Rights Reserved
59
Appendix C–Type H Standard Quantities
Using MICROLOGIC Trip Units in a POWERLOGIC System
63220-080-200/B1
August 2002
SMS Topic Name1
User Description
Number of
Registers
Register2
Module
OverFreqAlrm
Over Frequency Alarm Status
1
8859
PM
Bit 11; ON = active, OFF = inactive
OverFreqPreAlrm
Over Frequency Pre-Alarm Status
1
8863
PM
Bit 11; ON = active, OFF = inactive
OverIAAlrm
Over IA Demand Alarm Status
1
8859
PM
Bit 1; ON = active, OFF = inactive
Bit 1; ON = active, OFF = inactive
Units
Scale
OverIAPreAlrm
Over IA Demand Pre-Alarm Status
1
8863
PM
OverIBAlrm
Over IB Demand Alarm Status
1
8859
PM
Bit 2; ON = active, OFF = inactive
OverIBPreAlrm
Over IB Demand Pre-Alarm Status
1
8863
PM
Bit 2; ON = active, OFF = inactive
OverICAlrm
Over IC Demand Alarm Status
1
8859
PM
Bit 3; ON = active, OFF = inactive
OverICPreAlrm
Over IC Demand Pre-Alarm Status
1
8863
PM
Bit 3; ON = active, OFF = inactive
OverINAlrm
Over IN Demand Alarm Status
1
8859
PM
Bit 4; ON = active, OFF = inactive
OverINPreAlrm
Over IN Demand Pre-Alarm Status
1
8863
PM
Bit 4; ON = active, OFF = inactive
OverVoltAlrm
Over Voltage Alarm Status
1
8859
PM
Bit 6; ON = active, OFF = inactive
OverVoltPreAlrm
Over Voltage Pre-Alarm Status
1
8863
PM
Bit 6; ON = active, OFF = inactive
PF_PkkVAD
PF Coincident w/Peak KVA Demand
3
2239
MM
Thousandths
PF_PkkVARD
PF Coincident w/Peak KVAR Demand
3
2233
MM
Thousandths
PF_PkkWD
PF Coincident w/Peak KW Demand
3
2227
MM
Thousandths
PF format5
PFA
Power Factor A
3
1046
MM
PFB
Power Factor B
3
1047
MM
PFC
Power Factor C
3
1048
MM
PFSignConv
Power Factor Sign Convention
1
3318
MM
PFTtl
Power Factor Total
3
1049
MM
PhaRotAlrm
Phase Rotation Alarm Status
1
8859
PM
PkIAD
Peak Demand Current A
1
2204
MM
A
Unity
PkIBD
Peak Demand Current B
1
2205
MM
A
Unity
PkICD
Peak Demand Current C
1
2206
MM
A
Unity
PkIND
Peak Demand Current N
1
2207
MM
A
PkKFDA
Peak K-Factor Demand A
1
2216
MM
Tenths
PkKFDB
Peak K-Factor Demand B
1
2217
MM
Tenths
Tenths
PF format5
PF format5
0 = IEC
1 = Alternate (CMI)
2 = IEEE
PF format5
Bit 12; ON = active, OFF = inactive
Unity
PkKFDC
Peak K-Factor Demand C
1
2218
MM
PkKFDN
Peak K-Factor Demand N
1
2219
MM
PkkVAD
Peak Demand Apparent Power
1
2237
MM
kVA
Unity
PkkVARD
Peak Demand Reactive Power
1
2231
MM
kVAR
Unity
PkkWD
Peak Demand Real Power
1
2225
MM
kW
Unity
PowerDmdInt
Power Demand Interval
1
3355
MM
Minutes
Unity
PredIAD
Predicted Demand Current A
1
2208
MM
A
Unity
PredIBD
Predicted Demand Current B
1
2209
MM
A
Unity
PredICD
Predicted Demand Current C
1
2210
MM
A
Unity
PredIND
Predicted Demand Current N
1
2211
MM
A
PredKFDA
Predicted K-Factor Demand A
1
2220
MM
Tenths
PredKFDB
Predicted K-Factor Demand B
1
2221
MM
Tenths
PredKFDC
Predicted K-Factor Demand C
1
2222
MM
Tenths
1.
2.
3.
4.
5.
60
Tenths
Unity
SMS Topic Names beginning with “H” are Type H harmonic topics.
For register entries that are not listed, please refer to the MICROLOGIC device type register list. Contact your local sales representative.
3-register date/time format: register 1: month (byte 1) = 1–12; day (byte 2) = 1–31
register 2: year (byte 1) = 0–199 (add to 1900 to determine the actual year); hour (byte 2) = 0–23
register 3: minutes (byte 1) = 0–59; seconds (byte 2) = 0–59
Note: Bits 14 and 15 of the month/day register must be masked.
Modulo 10,000 format: 1 to 4 sequential registers. Each register is Modulo 10,000 (range = –9,999 to +9,999).
Result is [R4*10,000^3 + R3*10,000^2 + R2*10,000^1] + R1. Range is zero to 9,999,999,999,999,999.
Power factor format: –1 to –999 for lagging power factors, 1000 for unity power factor 1.000, and 1 to 999 for leading power factors.
© 2002 Schneider Electric All Rights Reserved
63220-080-200/B1
August 2002
Appendix C–Type H Standard Quantities
Using MICROLOGIC Trip Units in a POWERLOGIC System
SMS Topic Name1
User Description
Number of
Registers
Register2
Module
PredKFDN
Predicted K-Factor Demand N
1
2223
MM
PredkVAD
Predicted KVA Demand
1
2238
PredkVARD
Predicted KVAR Demand
1
PredkWD
Predicted KW Demand
PwrDmdMethod
Power Demand Method
PwrFlowDirMet
Units
Scale
MM
kVA
Unity
2232
MM
kVAR
Unity
1
2226
MM
kW
Unity
1
3354
MM
0 = Sliding
1 = Thermal
2 = Block
5 = Sync to Comms
Power Flow Direction - Metering
1
3316
MM
0 = Bottom Fed
1 = Top Fed
R1OpsCounter
Relay 1 Operations Counter
1
9081
PM
Unity
R2OpsCounter
Relay 2 Operations Counter
1
9082
PM
Unity
R3OpsCounter
Relay 3 Operations Counter
1
9083
PM
Unity
R4OpsCounter
Relay 4 Operations Counter
1
9084
PM
Unity
R5OpsCounter
Relay 5 Operations Counter
1
9085
PM
Unity
R6OpsCounter
Relay 6 Operations Counter
1
9086
PM
Unity
ReadyToClose
Breaker Ready to Close
1
661
BCM
Bit 5; ON = yes, OFF = no
Tenths
RevPwrAlrm
Reverse Power Alarm Status
1
8859
PM
Bit 9; ON = active; OFF = inactive
RevPwrPreAlrm
Reverse Power Pre-Alarm Status
1
8863
PM
Bit 9; ON = active; OFF = inactive
System Type
System Type
1
3314
MM
System 31 = 3-phase, 3-wire, 3CT
System 40 = 3-phase, 4-wire, 3CT
System 41 = 3-phase, 4-wire, 4 CT
TimeToTrip
Time Remaining to LT Trip
2
8865
PM
TU_BATT_PCT
Trip Unit % Battery
1
8843
PM
TU_SN
Trip Unit Serial Number
4
8700
PM
ASCII text
TUCommStatus
Trip Unit Internal Comms Status
1
552
BCM
Bit 11; ON = not responding; OFF = OK
UnderFreqAlrm
Under Frequency Alarm Status
1
8859
PM
Bit 10; ON = active; OFF = inactive
UnderFreqPreAlrm
Under Frequency Pre-Alarm Status
1
8863
PM
Bit 10; ON = active; OFF = inactive
UnderVoltAlrm
Under Voltage Alarm Status
1
8859
PM
Bit 5; ON = active; OFF = inactive
UnderVoltPreAlrm
Under Voltage Pre-Alarm Status
1
8863
PM
VAB
Voltage A-B
1
1000
MM
V
Unity
VAN
Voltage A-N
1
1003
MM
V
Unity
VARSignConv
VAR (Reactive Power) Sign Convention
1
3317
MM
Tenths
%
Unity
Bit 5; ON = active; OFF = inactive
0 = Alternate (CMI)
1 = IEEE/IEC
VBC
Voltage B-C
1
1001
MM
V
VBN
Voltage B-N
1
1004
MM
V
Unity
Unity
VCA
Voltage C-A
1
1002
MM
V
Unity
VCN
Voltage C-N
1
1005
MM
V
Unity
VigiAlarm
Vigi Alarm Status
1
8860
PM
Bit 1; ON = active; OFF = inactive
VigiPreAlrm
Vigi Pre-Alarm Status
1
8864
PM
Bit 1; ON = active; OFF = inactive
VLLAvg
Voltage L-L Avg
1
1006
MM
V
Unity
VLNAvg
Voltage L-N Avg
1
1007
MM
V
Unity
VUnbalAB
Voltage Unbalance A-B
1
1008
MM
%
VUnbalAlrm
Voltage Unbalance Alarm Status
1
8859
PM
1.
2.
3.
4.
5.
Tenths
Bit 7; ON = active, OFF = inactive
SMS Topic Names beginning with “H” are Type H harmonic topics.
For register entries that are not listed, please refer to the MICROLOGIC device type register list. Contact your local sales representative.
3-register date/time format: register 1: month (byte 1) = 1–12; day (byte 2) = 1–31
register 2: year (byte 1) = 0–199 (add to 1900 to determine the actual year); hour (byte 2) = 0–23
register 3: minutes (byte 1) = 0–59; seconds (byte 2) = 0–59
Note: Bits 14 and 15 of the month/day register must be masked.
Modulo 10,000 format: 1 to 4 sequential registers. Each register is Modulo 10,000 (range = –9,999 to +9,999).
Result is [R4*10,000^3 + R3*10,000^2 + R2*10,000^1] + R1. Range is zero to 9,999,999,999,999,999.
Power factor format: –1 to –999 for lagging power factors, 1000 for unity power factor 1.000, and 1 to 999 for leading power factors.
© 2002 Schneider Electric All Rights Reserved
61
Appendix C–Type H Standard Quantities
Using MICROLOGIC Trip Units in a POWERLOGIC System
63220-080-200/B1
August 2002
SMS Topic Name1
User Description
Number of
Registers
Register2
Module
Units
Scale
VUnbalAN
Voltage Unbalance A-N
1
1011
MM
%
Tenths
VUnbalBC
Voltage Unbalance B-C
1
1009
MM
%
Tenths
VUnbalBN
Voltage Unbalance B-N
1
1012
MM
%
Tenths
VUnbalCA
Voltage Unbalance C-A
1
1010
MM
%
Tenths
VUnbalCN
Voltage Unbalance C-N
1
1013
MM
%
Tenths
VUnbalLLW
Voltage Unbalance L-L Worst
1
1014
MM
%
Tenths
VUnbalLNW
Voltage Unbalance L-N Worst
1
1015
MM
%
Tenths
VUnbalPreAlrm
Voltage Unbalance Pre-Alarm Status
1
8863
PM
1.
2.
3.
4.
5.
62
Bit 7; ON = active, OFF = inactive
SMS Topic Names beginning with “H” are Type H harmonic topics.
For register entries that are not listed, please refer to the MICROLOGIC device type register list. Contact your local sales representative.
3-register date/time format: register 1: month (byte 1) = 1–12; day (byte 2) = 1–31
register 2: year (byte 1) = 0–199 (add to 1900 to determine the actual year); hour (byte 2) = 0–23
register 3: minutes (byte 1) = 0–59; seconds (byte 2) = 0–59
Note: Bits 14 and 15 of the month/day register must be masked.
Modulo 10,000 format: 1 to 4 sequential registers. Each register is Modulo 10,000 (range = –9,999 to +9,999).
Result is [R4*10,000^3 + R3*10,000^2 + R2*10,000^1] + R1. Range is zero to 9,999,999,999,999,999.
Power factor format: –1 to –999 for lagging power factors, 1000 for unity power factor 1.000, and 1 to 999 for leading power factors.
© 2002 Schneider Electric All Rights Reserved
63220-080-200/B1
August 2002
Appendix D—MICROLOGIC Trip Unit Error Codes
Using MICROLOGIC Electronic Trip Units in a POWERLOGIC System
Table 1 shows the most common error codes that occur for the MICROLOGIC
Trip Unit in SMS. The error code number (but not the description) displays in
the SMS Activity Log.
APPENDIX D—MICROLOGIC TRIP UNIT
ERROR CODES
Table 1:
MICROLOGIC Trip Unit Error Codes in SMS
Error Code
Description
Solution
4500
An attempt was made to close, but remote close was
not enabled;
OR
An attempt was made to open, but remote open was
not enabled.
Enable the desired control from the SMS control
output feature.
4608
Comms error with a sub-device within the trip unit system. One
or more sub-devices are not communicating. See the SMS
Activity Log for details.
The Activity Log lists the sub-device that is not
communicating. Use this information and read the
Troubleshooting section for details.
The sample Activity Log in Figure 1 illustrates an error 4500 condition. Note
that both the trip unit and BCM have lost communication.
Figure 1:
© 2002 Schneider Electric All Rights Reserved
Activity Log illustration
63
Appendix D–MICROLOGIC Trip Unit Error Codes
Using MICROLOGIC Electronic Trip Units in a POWERLOGIC System
64
63220-080-200/B1
August 2002
© 2002 Schneider Electric All Rights Reserved
63220-080-200/B1
August 2002
APPENDIX E—SMS TABLE SUPPORT
Appendix E—SMS Table Support
Using MICROLOGIC Electronic Trip Units in a POWERLOGIC System
These are the standard real-time data tables included in SMS for
MICROLOGIC trip units. To learn how to use tables in SMS, see the SMS
online help file.
Table 1 lists existing and new SMS tables that MICROLOGIC trip
units support.
Table 1:
SMS Tables Supported by MICROLOGIC Devices
Table Name
Type A
Type P
Type H
Existing SMS Tables Supported by MICROLOGIC Trip Units
Instantaneous Ratings
X
X
X
Basic Readings Summary
X
X
X
Load Current Summary
X
X
X
System Voltage Summary
X
X
Demand Current Summary
X
X
Demand Readings
X
X
Energy Readings
X
X
Reactive Energy Contribution Summary
X
X
Real Energy Contribution Summary
X
X
Energy Summary
X
X
Phase Unbalance Readings
X
X
Power Factor Readings
X
X
Power Factor Summary
X
X
Power Flow Summary
X
X
Power Readings
X
X
Power Capacity Utilization Summary
X
X
THD Current Summary
X
THD Voltage Summary
X
New SMS Tables Supported by MICROLOGIC Trip Units
MicroLogic Protection Settings
X
X
X
MicroLogic Trip Curve
X
X
X
MicroLogic Circuit Loading Capacity Summary
X
X
X
MicroLogic Maintenance Information
X
X
X
Circuit Breaker Status Summary (Low Voltage)
X
X
X
X
X
X
X
MicroLogic Metering Configuration
MicroLogic Trip History
MicroLogic Type A Trip Unit Data
© 2002 Schneider Electric All Rights Reserved
X
Harmonic Apparent Power Flows—ELH
X
Harmonic Reactive Power Flows—ELH
X
Harmonic Real Power Flows—ELH
X
Spectral Components—Currents—ELH
X
Spectral Components—Voltages—ELH
X
65
Appendix E—SMS Table Support
Using MICROLOGIC Electronic Trip Units in a POWERLOGIC System
66
63220-080-200/B1
August 2002
© 2002 Schneider Electric All Rights Reserved
63220-080-200/B1
August 2002
APPENDIX F—COMMUNICATIONS
CONSIDERATIONS
Appendix F—Communications Considerations
Using MICROLOGIC Electronic Trip Units in a POWERLOGIC System
The following tables show the maximum distances of the communications
link at different baud rates. The maximum distances are measured from the
PC to the farthest device on the communications link.
Table 1:
Maximum Distances for 4-Wire Bus Topologies
(SY/MAX, MODBUS, Jbus devices)
Maximum Distances
Baud Rate
1–16 Devices
17–32 Devices
1200
10,000 ft. (3,050 m)
10,000 ft. (3,050 m)
2400
10,000 ft. (3,050 m)
5,000 ft. (1,525 m)
4800
10,000 ft. (3,050 m)
5,000 ft. (1,525 m)
9600
10,000 ft. (3,050 m)
4,000 ft. (1,220 m)
19200
10,000 ft. (3,050 m)
2,500 ft. (762.5 m)
Table 2:
Maximum Distances for 2-Wire Bus Topologies
(MODBUS, Jbus devices)
Maximum Distances
1–8 Devices 1
9–16 Devices 1
1200
10,000 ft. (3,050 m)
10,000 ft. (3,050 m)
2400
10,000 ft. (3,050 m)
5,000 ft. (1,525 m)
4800
10,000 ft. (3,050 m)
5,000 ft. (1,525 m)
9600
10,000 ft. (3,050 m)
4,000 ft. (1,220 m)
19200
10,000 ft. (3,050 m)
2,500 ft. (762.5 m)
Baud Rate
1 The number of devices shown applies to daisy chains that include
4-wire devices that are wired as 2-wire devices. If the daisy chain
contains only true 2-wire devices (and therefore no 4-wire
devices), refer to the device manufacturer’s instruction book for
device number and distance limitations.
NOTE: To wire 4-wire devices as 2-wire, connect the Rx+ and Tx+ terminals
together, then connect the Rx- and the Tx- terminals together. The Rx+/Tx+
terminals connect to the Lx+ line, and the Rx-/Tx- terminals connect to the
Lx- line. Refer to the device’s instruction manual for device pinouts and other
communications specifications.
© 2002 Schneider Electric All Rights Reserved
67
Appendix F—Communications Considerations
Using MICROLOGIC Electronic Trip Units in a POWERLOGIC System
63220-080-200/B1
August 2002
The figure below illustrates the communications wiring for the MICROLOGIC
trip unit system.
Cradle Communication Module
Shield
Out– (Black)
Previous Device
Out+ (Red)
In–
(White)
In+
(Green)
Next Device
+24 V
+24 V
24 Vdc
Previous Device
Ground
Ground
Ground
Next Device
Black Red White Green
Circuit Breaker
Secondary
Connections
F2+
F1–
24 Vdc #2
(optional, but recommended)
UC3
Comm
E1
E2
E3
E4
E5
E6
Protection
Module
In+
In–
Out+
Out–
Ground
+24 Vdc
Trip Unit
IR
Breaker
Communication
Module
Peer-to-Peer
Internal
Communication
Meter
Module
Primary
Circuit Breaker
Disconnect
(top)
Figure 1:
68
Current Sensor
Voltage pickup
Primary
Circuit Breaker
Disconnect
(bottom)
MICROLOGIC System Communication Wiring
© 2002 Schneider Electric All Rights Reserved
63220-080-200/B1
August 2002
INDEX
described 3
custom and standard quantities 10
A
D
accumulated energy 22
address
for the MICROLOGIC trip unit, illustration 9
Address sync push button 7, 27–28
advanced topics 23
alarms
levels (severities)
described 11
pre-assigned 12
setup 10
alternate (CM2) sign convention 24
architecture
trip unit 4
B
date/time
changing via HMI 26
synchronization 25
via Modbus master device 26
default alarm level characteristics (table) 11
demand
current, changing method or interval 19, 21
methods 19
peak 22
predicted 21
readings 18
demand power calculation methods 19–20
device
address limitations, mixed-mode daisy chain
2
baud rate (from the HMI) 6
BCM (Modbus breaker communication module)
described 3
block interval demand 19
C
CCM (cradle communication module)
described 2–3
changing the demand current 19, 21
changing the demand power 21
changing the demand power method or interval
19–20
changing the VAR and power factor sign convention 23
checklist
hardware setup 6
CM2 sign convention 24
CM2000 Circuit Monitors
firmware version 2
CM4000
communication through 5
communication
(RS-485 Modbus RTU) 4
link (peer-to-peer protocol) 3
with SMS
types 4
communication error 4
Communications Considerations 67
communications considerations 67
communications parameters
setting 6
composite device
defined 2
control outputs
errors 14
using 13
cradle communication module (CCM) 2
© 2002 Schneider Electric All Rights Reserved
address, from the HMI 6
resets 14
setup in SMS 8
setup tasks, overview 8
E
energy readings 22–23
Error Codes 63
error codes, list 63
Ethernet
(Modbus TCP) communication, CM-4000
with Ethernet Communication Card 4
Ethernet Gateway
firmware version 1
F
features
MICROLOGIC Electronic Trip Units 1
functions
global, analog and digital 10
H
hardware
setup 6
HMI
defined 2
setting the address, baud rate, and parity 6
setting the demand calculation method and
interval 19
trip unit 28
human-machine interface
see HMI 2
I
IEC sign convention 24
IEEE sign convention 17, 23
installation
SMS 8
installation and device setup in SMS 8
69
63220-080-200/B1
August 2002
instruction bulletin
MICROLOGIC trip unit 1
protection module (PM)
described 2
M
Q
metering
capabilities 15
module (MM)
described 2
real-time 15
MICROLOGIC
electronic trip unit instruction bulletin 1
MICROLOGIC Protection Settings table 13
MICROLOGIC Trip Unit Error Codes 63
min/max
conventions (power factor) 16
values 16
mixed-mode daisy chain
device address limitations 2
MM (trip unit metering module)
described 2
quantities
using 10
Quick Starts
SMS 8
N
nonvolatile memory 16, 22
O
on-board alarms
Type P and Type H 13
on-board harmonic analysis
Type H 23
P
parity (from the HMI) 6
peak demands 22
peer-to-peer protocol 3
PM (trip unit protection module)
described 2
power factor
changing the sign 23
min/max conventions 16
power supply
BCM 3
BCM and CCM 6
CCM 3
isolation of 3
trip unit 2
POWERLOGIC Ethernet Gateway
version 1
POWERLOGIC System Architecture and
Application Guide 4
ppendix 31
pre-assigned alarms 12
pre-assigned alarms (table) 12
pre-assigned alarms and events 12
pre-assigned task
device clock reset 13
predicted demand 21
Product Registration and Technical Support
Contacts document 2, 8
70
R
real-time metering 15
real-time power quality quantities
Type H 23
Requirements for Using MICROLOGIC Devices
1
reset
MICROLOGIC trip units 14
resetting the device clock 13
RS-485 Modbus RTU protocol (trip unit
communication) 4
S
scan rate 4
serial (RS-485 Modbus RTU)
communication 4
Series 2000 Circuit Monitors
firmware 2
setpoints, on-board alarms 13
setting communications parameters 6
setup
hardware 6
setup in SMS 8
severity (alarm level) 11
sign conventions 17
VAR sign and power factor 23
sliding demand 19
SMS 1
Activity Log 28, 63
Alarm Log 28
installation 8
online help file 1
version requirement 1
standard quantities
list 29, 39
system architecture 4
T
Technical Support 2, 29, 31, 39
time synchronization 25
trip unit
address, illustration 9
described 2
errror codes 63
metering module (MM), described 2
power supply 2
protection module (PM), described 2
trip unit system 2, 9
troubleshooting 27
© 2002 Schneider Electric All Rights Reserved
63220-080-200/B1
August 2002
Type A Standard Quantities 29
Type H harmonic analysis 23
Type H real-time power quality quantities 23
Type H Standard Quantities 39
Type H waveform capture 23
Type P and Type H on-board alarms 13
Type P Energy Readings (table) 22
Type P Standard Quantities 31
U
using control outputs 13
using custom quantities 10
V
VAR and PF sign conventions
changing from HMI 25
VAR sign convention
changing 23
changing in SMS 24
viewing information in SMS 10
W
waveform capture
Type H 23
wiring distances 67
© 2002 Schneider Electric All Rights Reserved
71
Bulletin No. 63220-080-200/B1 August 2002 © 2002 Schneider Electric All Rights Reserved.
Class 612