GEK-113493E - GE Digital Energy

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369 Motor Management RelayCommunications Guide

369 Revision: 3.6x

Manual P/N: 1601-9046-A6

Publication Number: GEK-113493E

Copyright © 2012 GE Digital Energy

GE Energy

*1601-9046-A6*

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registered to ISO9001:2000

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© 2012 GE Digital Energy Incorporated. All rights reserved.

GE Digital Energy 369 Motor Management Relay Communications Guide for revision 3.6x.

369 Motor Management Relay, is a registered trademark of GE Digital Energy Inc.

The contents of this manual are the property of GE Digital Energy Inc. This documentation is furnished on license and may not be reproduced in whole or in part without the permission of GE Digital Energy. The content of this manual is for informational use only and is subject to change without notice.

Part numbers contained in this manual are subject to change without notice, and should therefore be verified by GE Digital Energy before ordering.

Part number: 1601-9046-A6 (May 2012)

TABLE OF CONTENTS

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL TOC–1

Table of Contents

OVERVIEW .........................................................................................................................................1ELECTRICAL INTERFACE .....................................................................................................1PROFIBUS COMMUNICATIONS .........................................................................................2DEVICENET COMMUNICATIONS .......................................................................................2MODBUS COMMUNICATIONS ...........................................................................................2MODBUS/TCP COMMUNICATIONS .................................................................................3

PROFIBUS-DP COMMUNICATIONS .........................................................................................6PROFIBUS COMMUNICATION OPTIONS ..........................................................................6369 RELAY PROFIBUS-DP PARAMETERIZATION ...........................................................6369 RELAY PROFIBUS-DP CONFIGURATION ................................................................6369 RELAY PROFIBUS-DP DIAGNOSTICS ..................................................................11PROFIBUS-DP LOSS OF COMMUNICATION TRIP .......................................................18

PROFIBUS-DPV1 COMMUNICATIONS ................................................................................20369 RELAY PROFIBUS-DPV1 PARAMETERIZATION ..................................................20369 RELAY PROFIBUS CONFIGURATION .....................................................................20369 RELAY PROFIBUS INPUT DATA ............................................................................21369 RELAY PROFIBUS OUTPUT DATA ........................................................................22369 RELAY PROFIBUS DIAGNOSTICS ..........................................................................23369 RELAY PROFIBUS-DPV1 ACYCLICAL COMMUNICATION ..................................23369 RELAY PROFIBUS-DPV1 LOSS OF COMMUNICATION TRIP ............................24

DEVICENET PROTOCOL ............................................................................................................ 25DEVICENET COMMUNICATIONS ....................................................................................25POLL DATA ......................................................................................................................26CHANGE OF STATE (COS) .............................................................................................28IDENTITY OBJECT (CLASS CODE 01H) ..........................................................................29MESSAGE ROUTER (CLASS CODE 02H) ........................................................................29DEVICENET OBJECT (CLASS CODE 03H) .....................................................................29ASSEMBLY OBJECT (CLASS CODE 04H) .......................................................................30DEVICENET CONNECTION OBJECT (CLASS CODE 05H) ............................................31ACKNOWLEDGE HANDLER OBJECT (CLASS CODE 2BH) ...........................................32I/O DATA INPUT MAPPING OBJECT (CLASS CODE A0H) ..........................................33I/O DATA OUTPUT MAPPING OBJECT (CLASS CODE A1H) ......................................33PARAMETER DATA INPUT MAPPING OBJECT (CLASS CODE B0H) ............................34DEVICENET LOSS OF COMMUNICATION TRIP ............................................................41DEVICENET DATA FORMATS .........................................................................................42

MODBUS RTU PROTOCOL .......................................................................................................47DATA FRAME FORMAT AND DATA RATE .....................................................................47DATA PACKET FORMAT ..................................................................................................47ERROR CHECKING ..........................................................................................................48CRC-16 ALGORITHM ....................................................................................................48TIMING .............................................................................................................................49SUPPORTED MODBUS FUNCTIONS ..............................................................................49ERROR RESPONSES ........................................................................................................49MODBUS COMMANDS ...................................................................................................50

MEMORY MAP ...............................................................................................................................52MEMORY MAP INFORMATION .......................................................................................52USER DEFINABLE MEMORY MAP AREA .......................................................................52EVENT RECORDER ..........................................................................................................53WAVEFORM CAPTURE ....................................................................................................53

TOC–2 369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

TABLE OF CONTENTS

MOTOR START DATA LOGGER ......................................................................................56DATA LOGGER .................................................................................................................57MODBUS MEMORY MAP ................................................................................................58FORMAT CODES ........................................................................................................... 124

CHANGE NOTES ........................................................................................................................ 155REVISION HISTORY ...................................................................................................... 155

WARRANTY ................................................................................................................................. 157WARRANTY INFORMATION ......................................................................................... 157

369 MOTOR MANAGEMENT RELAY – COMMUNICATIONS GUIDE 1

369 Motor Management Relay

Communications Guide

GE Energy

Communications Guide

1 Overview

1.1 Electrical Interface

The hardware or electrical interface is one of the following:

• one of three 2-wire RS485 ports from the rear terminal connector,

• the RS232 from the front panel connector

• a fibre optic connection.

In a 2-wire RS485 link, data flow is bidirectional. Data flow is half-duplex for both the RS485 and the RS232 ports. That is, data is never transmitted and received at the same time. RS485 lines should be connected in a daisy chain configuration (avoid star connections) with a terminating network installed at each end of the link, i.e. at the master end and at the slave farthest from the master. The terminating network should consist of a 120 ohm resistor in series with a 1 nF ceramic capacitor when used with Belden 9841 RS485 wire. The value of the terminating resistors should be equal to the characteristic impedance of the line. This is approximately 120 ohms for standard #22 AWG twisted pair wire. Shielded wire should always be used to minimize noise. Polarity is important in RS485 communications. Each '+' terminal of every 369 must be connected together for the system to operate. See the 369 Instruction Manual, chapter 3 for details on correct serial port wiring.

When using a fibre optic link the Tx from the 369 should be connected to the Rx of the Master device and the Rx from the 369 should be connected to the Tx of the Master device.

2 369 MOTOR MANAGEMENT RELAY – COMMUNICATIONS GUIDE

OVERVIEW COMMUNICATIONS GUIDE

1.2 Profibus Communications

The 369 Motor Management Relay supports both Profibus-DP (order code P) and Profibus-DPV1 (order code P1) communication interfaces as slave that can be read and written to/from a Profibus-DP/V1 master. The Profibus-DP/V1 Master must read the GSD (Device Master Data) file of the 369 for the purposes of configuration and parameterization.

• The GSD file for the Profibus-DP option is 369_090C.gse.

• The GSD file for the Profibus-DPV1 option is 369_09E6.gse.

• The relay supports the following configurations and indications:

• Fieldbus type: PROFIBUS-DP (IEC 61158 Type 3, and IEC 61784)

• Auto baud rate detection 9.6Kbit - 12Mbit.

• Address range: 1-126, setting via EnerVista 369 Setup software or front keypad.

• Input data: 220 bytes - cyclical.

• Extended Diagnostic data: 26 bytes - non-cyclical.

• Sections 2.2 to 2.4 pertain to the Profibus-DP option.

• In addition to the above, the Profibus-DPV1 (P1) option supports:

• Fieldbus type: Profibus-DPV1 (IEC 61158 Type 3, and IEC 61784)

• Acyclic read/write between a Master (Class1/Class2) and the 369 slave according to the DPV1 extensions of IEC 61158.

• Output Data: 2 bytes - cyclical.

Sections 3.1 to 3.6 of this manual pertain to the Profibus-DPV1 option.

1.3 DeviceNet Communications

The 369 Motor Management Relay supports the optional DeviceNet protocol as slave that can be read by a DeviceNet master. The device can be added to a DeviceNet list by adding the 369.eds file in the scanner list. The EDS file can be generated using the EnerVista 369 Setup program.

The relay supports following configuration.

• Field bus type: DeviceNet

• Functions supported: Explicit, Polled, COS and Cyclic IO messaging

• Baud Rate: 125, 250 and 500 kbps, programmable through software or relay front keypad

• Mac ID: 0 to 63, programmable through software or relay front keypad

See section 4: DeviceNet Protocol, for complete details.

1.4 Modbus Communications

The 369 implements a subset of the AEG Modicon Modbus RTU serial communication standard. Many popular programmable controllers support this protocol directly with a suitable interface card allowing direct connection of relays. Although the Modbus protocol is hardware independent, the 369 interfaces include three 2-wire RS485 ports and one

COMMUNICATIONS GUIDE OVERVIEW


RS232 port. Modbus is a single master, multiple slave protocol suitable for a multi-drop configuration as provided by RS485 hardware. In this configuration up to 32 slaves can be daisy-chained together on a single communication channel.

The 369 is always a slave. It cannot be programmed as a master. Computers or PLCs are commonly programmed as masters. The Modbus protocol exists in two versions: Remote Terminal Unit (RTU, binary) and ASCII. Only the RTU version is supported by the 369. Monitoring, programming and control functions are possible using read and write register commands.

1.5 Modbus/TCP Communications

Modbus/TCP Option:

When configured with the “E” Option, the 369 can connect to Ethernet networks via the rear RJ45 connection, using the Modbus/TCP protocol as detailed in the document “Open Modbus / TCP Specification” by Andy Swales, Release 1.0, 29 March 1999 (a search via the internet can produce a free copy of this document).

This description contains information to the location of Setting registers for configuring the 369 for a LAN connection, and the physical connection of the 369. Information pertaining to the application of an IED over Ethernet is beyond the scope of this manual and users should consult their Network Administrators for configuration details.

Note The implementation of this option is for the intention of data retrieval and device configuration. The 369 does not support firmware upgrade via this connection.

Setpoints Configuration:

The user needs to configure the following settings for interface to a LAN: IP ADDRESS, SUBNET MASK, and GATEWAY ADDRESS. Each setting contains 4 octets. The user configures the octets as shown in the following example:

IP ADDRESS: “127.0.0.1”SUBNET MASK: “255.255.255.252”GATEWAY ADDRESS: “127.0.0.1”

SETPOINT MEMORY MAPADDRESS

DATA VALUE(DEC)

IP ADDRESS OCTET1 0x101C 127

IP ADDRESS OCTET2 0x101D 0

IP ADDRESS OCTET3 0x101E 0

IP ADDRESS OCTET4 0x101F 1

SUBNET MASK OCTET1 0x1020 255




GATEWAY ADDRESS OCTET1 0x1024 127



OVERVIEW COMMUNICATIONS GUIDE

These settings can also be configured via the keypad under the S1 369 SETUP 369

COMMUNICATIONS path.

Physical Connection:

The 369 can be connected to an Ethernet LAN via the RJ45 connector at the back of the 369.

Ethernet Loss Of Communication Trip

The 369 can detect a failure in communication activity with the MODBUS Master through Ethernet port. The Ethernet Loss of Communications feature can be used to trip any combination of output relays.

When equipped with the Ethernet option, the 369 can be configured to check for MODBUS TCP/IP activity, and raise an alarm and trip an output relay if activity is not detected within the configured delay. Delays of 0.25 to 10.00 seconds may be configured by the user.

If the “Fieldbus Loss of Comms” function is enabled , the 369 considers an Ethernet loss of communication to have occurred in the following conditions:

1. Link failure (break in physical connection)

2. If valid MODBUS packets are not received within the configured delay period. Invalid MODBUS packets, such as ones that contain the wrong slave ID, are not considered valid. Please note that an ICMP PING message is not a valid MODBUS packet

3. If packets cannot be received because of buffer overflows or lack of queue space, the delay timer will continue to decrement, and will not be reset until valid packets are received. If the queues / buffers cannot be recovered within the configured delay, the Loss of Communication alarm will be raised, and any configured relays shall trip.

A delay of 0.25 sec to 10.00 sec in steps of 0.25 sec can be programmed to delay the output relay activation. To avoid false trips, it is advised to set the trip delay greater than MODBUS timeout delay.

This feature can be programmed for Latched or Unlatched operation.

If programmed as Latched:

The “Fieldbus Loss of Comms” trip will remain latched until the communication with the Modbus Master through Ethernet port is (re) established AND the latched trip is manually reset or remotely reset via Modbus communications.

If programmed as Unlatched:

Any programmed output relays for this feature will be activated until communication with the Modbus master through Ethernet port is active. Once communication is active, the trip condition will be cleared and the assigned output relays will automatically de-activate.

The setpoints associated with this feature are:

1. Fieldbus Loss of Comms Enable



SETPOINT MEMORY MAPADDRESS

DATA VALUE(DEC)

COMMUNICATIONS GUIDE OVERVIEW


2. Fieldbus Loss of Comms Delay

3. Assign Loss of Comms Relay

Refer to the 369 Instruction Manual, chapter 5: 369 Relay Communications for more information on these setpoints.


PROFIBUS-DP COMMUNICATIONS COMMUNICATIONS GUIDE

2 Profibus-DP Communications

2.1 Profibus Communication Options

The 369 Motor Management Relay supports either Profibus-DP (order code P) or Profibus-DPV1 (order code P1) communication interfaces as slave that can be read and written to/from a Profibus-DP/V1 master. The Profibus-DP/V1 Master must read the GSD (Device Master Data) file of the 369 for the purposes of configuration and parameterization.

• The GSD file for the Profibus-DP option is 369_090C.GSE.

• The GSD file for the Profibus-DPV1 option is 369_09E6.GSE.

Sections 2.2 to 2.4 pertain to the Profibus-DP option.

Sections 3.1 to 3.6 of this manual pertain to the Profibus-DPV1 option.

2.2 369 Relay Profibus-DP Parameterization

The 369 Motor Management Relay supports mandatory parametrization. The relay keeps its user parameter data / setpoints in a non-volatile memory and does not need device related parametrization during startup of the DP master. The EnerVista 369 Setup software is the best tool for user parametrization of the 369 device.

2.3 369 Relay Profibus-DP Configuration

The Profibus-DP basic configuration has one DP master and one DP slave. In a typical bus segment up to 32 stations can be connected (a repeater has to be used if more than 32 stations operate on a bus). The end nodes on a Profibus-DP network must be terminated to avoid reflections on the bus line.

The bus address for the relay as Profibus-DP node can be set using the S1 369 RELAY SETUP

369 RELAY COMMUNICATIONS PROFIBUS ADDRESS setpoint or via the EnerVista 369 Setup software, which extends address range from 1 to 126. Address 126 is used only for commissioning purposes and should not be used to exchange user data.

The media for the fieldbus is a twisted pair copper cable along with 9-pin SUB-D connector, which connects the bus to the 369 socket on the back of the relay. The 369 Motor Management Relay has autobaud support. The baud rates and other slave specific information needed for configuration are contained in 369_090C.gs* which is used by a network configuration program.

The 369 Motor Management Relay as a DP slave transfers fast process data to the DP master according to master-slave principle. The 369 Motor Management Relay is a modular device, supporting up to 8 input modules.

During the configuration session, all modules have to be selected in order to get the entire area of 110 words of input data. There are no output data for processing. The following diagram shows the possible DP Master Class 2 configuration menu:

COMMUNICATIONS GUIDE PROFIBUS-DP COMMUNICATIONS


FIGURE 1–1: Slave Configuration

Table 1: Profibus Input Data (Sheet 1 of 5)

OFFSET CYCLIC DATA (ACTUAL VALUES)

LENGTH (BYTES)

MINIMUM MAXIMUMSTEP

VALUE UNITS FORMAT CODE DEFAULT

VALUE HEX VALUE HEX

0 MotorStatus 2 0 0000 4 0004 1 – F133 0

2 TC_Used 2 0 0000 100 0064 1 % F1 0

4 Time_to_Trip 2 –1 FFFF 65500 FFDC 1 s F20 –1

6 OverloadLT 2 0 0000 50000 C350 1 s F1 0

8 StartsHourLT[5] 2 0 0000 60 003C 1 min F1 0

10 TimeBetween StartsLT 2 0 0000 500 01F4 1 min F1 0

12 RestartBlock LT 2 0 0000 50000 C350 1 s F1 0

14 StartInhibitLT 2 0 0000 60 003C 1 min F1 0

16 AccessSwitch Status 2 0 0000 1 0001 1 – F131 0

18 SpeedSwitch Status 2 0 0000 1 0001 1 – F131 0

20 SpareSwitch Status 2 0 0000 1 0001 1 – F131 0

22 DiffSwitch Status 2 0 0000 1 0001 1 – F131 0

24 EmergencySwitch status

2 0 0000 1 0001 1 – F131 0



26 ResetSwitch Status 2 0 0000 1 0001 1 – F131 0

28 TripRelayStatus 2 0 0000 1 0001 1 N/A F150 2

30 AlarmRelayStatus 2 0 0000 1 0001 1 N/A F150 2

32 Aux1RelayStatus 2 0 0000 1 0001 1 N/A F150 2

34 Aux2RelayStatus 2 0 0000 1 0001 1 N/A F150 2

36 Ia 2 0 0000 65535 FFFF 1 A F1 0

38 Ib 2 0 0000 65535 FFFF 1 A F1 0

40 Ic 2 0 0000 65535 FFFF 1 A F1 0

42 AveragePhaseCurrent 2 0 0000 65535 FFFF 1 A F1 0

44 MotorLoad 2 0 0000 2000 07D0 1 xFLA F3 0

46 CurrentUnbalance 2 0 0000 100 0064 1 % F1 0

48 U/B Biased Motor Load

2 0 0000 2000 07D0 1 xFLC F3 0

50 GroundCurrent 2 0 0000 50000 C350 1 A F23 0

52 Vab 2 0 0000 65000 FDE8 1 V F1 0

54 Vbc 2 0 0000 65000 FDE8 1 V F1 0

56 Vca 2 0 0000 65000 FDE8 1 V F1 0

58 Van 2 0 0000 65000 FDE8 1 V F1 0

60 Vbn 2 0 0000 65000 FDE8 1 V F1 0

62 Vcn 2 0 0000 65000 FDE8 1 V F1 0

64 AvgLineVoltage 2 0 0000 65000 FDE8 1 V F1 0

66 AvgPhaseVoltage 2 0 0000 65000 FDE8 1 V F1 0

68 Frequency 2 0 0000 12000 2EE0 1 Hz F3 0

70 BackSpinFrequency 2 1 0001 12000 2EE0 1 Hz F3 0

72 PowerFactor 2 –99 FF9D 100 0064 1 – F21 0

74 RealPower–kW 2 –32000

8300 32000 7D00 1 kW F4 0

76 RealPower–hp 2 0 0000 65000 FDE8 1 hp F1 0

78 ReactivePower 2 –32000

8300 32000 7D00 1 kvar F4 0

80 ApparentPower 2 0 0000 65000 FDE8 1 kVA F1 0



LENGTH (BYTES)

MINIMUM MAXIMUMSTEP


VALUE HEX VALUE HEX



82 MWh 2 0 0000 65535 FFFF 1 MWh F1 0

84 PositiveMvarh 2 0 0000 65535 FFFF 1 Mvarh

F1 0

86 NegativeMvarh 2 0 0000 65535 FFFF 1 Mvarh

F1 0

88 HottestStatorRtd 2 0 0000 12 000C 1 F2 0

90 HottestStatorRtdTemp

2 –40 FFD8 200 00C8 1 °C F4 –42

92 LocalRtd1 2 –40 FFD8 200 00C8 1 °C F4 –42

94 LocalRtd2 2 –40 FFD8 200 00C8 1 °C F4 –42

96 LocalRtd3 2 –40 FFD8 200 00C8 1 °C F4 –42

98 LocalRtd4 2 –40 FFD8 200 00C8 1 °C F4 –42

100 LocalRtd5 2 –40 FFD8 200 00C8 1 °C F4 –42

102 LocalRtd6 2 –40 FFD8 200 00C8 1 °C F4 –42

104 LocalRtd7 2 –40 FFD8 200 00C8 1 °C F4 –42

106 LocalRtd8 2 –40 FFD8 200 00C8 1 °C F4 –42

108 LocalRtd9 2 –40 FFD8 200 00C8 1 °C F4 –42

110 LocalRtd10 2 –40 FFD8 200 00C8 1 °C F4 –42

112 LocalRtd11 2 –40 FFD8 200 00C8 1 °C F4 –42

114 LocalRtd12 2 –40 FFD8 200 00C8 1 °C F4 –42

116 CurrentDemand 2 0 0000 50000 C350 1 A F1 0

118 RealPowerDemand 2 0 0000 50000 C350 1 kW F1 0

120 ReactivePowerDemand

2 –32000

8300 32000 7D00 1 kvar F4 0

122 ApparentPowerDemand

2 0 0000 50000 C350 1 kVA F1 0

124 PeakCurrent 2 0 0000 65535 FFFF 1 A F1 0

126 PeakRealPower 2 0 0000 50000 C350 1 kW F1 0

128 PeakReactivePower 2 –32000

8300 32000 7D00 1 kvar F4 0

130 PeakApparentPower 2 0 0000 50000 C350 1 kVA F1 0

132 Va angle 2 0 0000 359 0167 1 o F1 0



LENGTH (BYTES)

MINIMUM MAXIMUMSTEP


VALUE HEX VALUE HEX



134 Vb angle 2 0 0000 359 0167 1 o F1 0

136 Vc angle 2 0 0000 359 0167 1 o F1 0

138 Ia angle 2 0 0000 359 0167 1 o F1 0

140 Ib angle 2 0 0000 359 0167 1 o F1 0

142 Ic angle 2 0 0000 359 0167 1 o F1 0

144 Learned AccelerationTime

2 1 0001 2500 09C4 1 s F2 0

146 Learned StartingCurrent

2 0 0000 65535 FFFF 1 A F1 0

148 Learned StartingCapacity

2 0 0000 100 0064 1 % F1 0

150 Learned RunningCoolTime Constant

2 0 0000 500 01F4 1 min F1 0

152 LearnedStoppedCoolTime Constant

2 0 0000 500 01F4 1 min F1 0

154 Last StartingCapacity 2 0 0000 100 0064 1 % F1 0

156 Learned UnbalanceKfactor

2 0 0000 29 001D 1 – F1 0

158 BSDState 2 0 0000 6 0006 1 – F27 0

160 RawPredictionTimer 2 0 0000 50000 C350 1 s F2 0

162 NumberOfStarts 2 0 0000 50000 C350 1 – F1 0

164 NumberOfRestarts 2 0 0000 50000 C350 1 – F1 0

166 DigitalCounter 2 0 0000 65535 FFFF 1 – F1 0

168 MotorRunningHours 2 0 0000 65535 FFFF 1 hr F1 0

170 RelayOperatingHours 2 0 0000 65535 FFFF 1 hr F1 0

172 Last trip Cause 2 0 0000 169 00A9 1 – F134 0

174 Last trip Date 4 N/A N/A N/A N/A N/A N/A F18 N/A

178 Last trip Time 4 N/A N/A N/A N/A N/A N/A F19 N/A

182 Last pre-trip Ia 2 0 0000 65535 FFFF 1 A F1 0

184 Last pre-trip Ib 2 0 0000 65535 FFFF 1 A F1 0

186 Last pre-trip Ic 2 0 0000 65535 FFFF 1 A F1 0



LENGTH (BYTES)

MINIMUM MAXIMUMSTEP


VALUE HEX VALUE HEX



2.4 369 Relay Profibus-DP Diagnostics

The 369 Motor Management Relay supports both slave mandatory (6 bytes system-wide standardized) and slave specific diagnostic data. If the diagnostics are considered high priority, the PLC/host program will be informed of the fault (alarm or trip) and can call a special error routine.

Diagnostic bytes 1 through 6 represent standard diagnostic data and are formatted as follows.

188 Last pre-trip MotorLoad

2 0 0000 2000 07D0 1 FLA F3 0

190 Last pre-trip Unbalance

2 0 0000 100 0064 1 % F1 0

192 Last pre-trip Ig 2 0 0000 50000 C350 1 A F23 0

194 Last trip HottestStatorRtd

2 0 0000 12 000C 1 – F1 0

196 Last trip HottestStatorTemp

2 –40 FFD8 200 00C8 1 °C F4 0

198 Last pre–trip Vab 2 0 0000 65000 FDE8 1 V F1 0

200 Last pre–trip Vbc 2 0 0000 65000 FDE8 1 V F1 0

202 Last pre–trip Vca 2 0 0000 65000 FDE8 1 V F1 0

204 Last pre–trip Van 2 0 0000 65000 FDE8 1 V F1 0

206 Last pre–trip Vbn 2 0 0000 65000 FDE8 1 V F1 0

208 Last pre–trip Vcn 2 0 0000 65000 FDE8 1 V F1 0

210 Last pre–trip Frequency

2 0 0000 12000 2EE0 1 Hz F3 0

212 Last pre–trip KiloWatts

2 –32000

8300 32000 7D00 1 kW F4 0

214 Last pre–trip KiloVAR 2 –32000

8300 32000 7D00 1 kvar F4 0

216 Last pre–trip KiloVA 2 0 0000 50000 C350 1 kVA F1 0

218 Last pre–trip PowerFactor

2 –99 FF9D 100 0064 1 – F21 0



LENGTH (BYTES)

MINIMUM MAXIMUMSTEP


VALUE HEX VALUE HEX



The extended diagnosis for the relay is composed of 26 bytes (bytes 7 to 32) and contains diagnostic information according to the following table.

Table 2: Diagnostic bytes 1 through 7

BYTE DESCRIPTION

1 Station Status 1

2 Station Status 2

3 Station Status 3

4 Diagnostic Master Address

5 Identification Number (High Byte)

6 Identification Number (Low Byte)

Table 3: Profibus Diagnostics (Sheet 1 of 7)

BIT BYTE FUNCTION

0 to 7 7 Number of Diagnostic Bytes

0 8 SinglePhasingTrip

1 8 SpareSwitchTrip

2 8 EmergencySwitchTrip

3 8 DifferentialSwitchTrip

4 8 SpeedSwitchTrip

5 8 ResetSwitchTrip

6 8 Reserved

7 8 OverloadTrip

8 9 ShortCircuitTrip

9 9 ShortCircuitBackupTrip

10 9 MechanicalJamTrip

11 9 UndercurrentTrip

12 9 CurrentUnbalanceTrip

13 9 GroundFaultTrip

14 9 GroundFaultBackupTrip

15 9 Reserved

16 10 AccelerationTimerTrip

17 10 Rtd1Trip



18 10 Rtd2Trip

19 10 Rtd3Trip

20 10 Rtd4Trip

21 10 Rtd5Trip

22 10 Rtd6Trip

23 10 Rtd7Trip

24 11 Rtd8Trip

25 11 Rtd9Trip

26 11 Rtd10Trip

27 11 Rtd11Trip

28 11 Rtd12Trip

29 11 UnderVoltageTrip

30 11 OverVoltageTrip

31 11 VoltagePhaseReversalTrip

32 12 UnderfrequencyTrip

33 12 OverfrequencyTrip

34 12 LeadPowerFactorTrip

35 12 LagPowerFactorTrip

36 12 PositivekvarTrip

37 12 NegativekvarTrip

38 12 UnderpowerTrip

39 12 ReversePowerTrip

40 13 IncompleteSequenceTrip

41 13 SpareSwitchAlarm

42 13 EmergencySwitchAlarm

43 13 DifferentialSwitchAlarm

44 13 SpeedSwitchAlarm

45 13 ResetSwitchAlarm

46 13 Reserved

47 13 ThermalCapacityAlarm

48 14 OverloadAlarm


BIT BYTE FUNCTION



49 14 MechanicalJamAlarm

50 14 UndercurrentAlarm

51 14 CurrentUnbalanceAlarm

52 14 GroundFaultAlarm

53 14 UndervoltageAlarm

54 14 OvervoltageAlarm

55 14 OverfrequencyAlarm

56 15 UnderfrequencyAlarm

57 15 LeadPowerFactorAlarm

58 15 LagPowerFactorAlarm

59 15 PositivekvarAlarm

60 15 NegativekvarAlarm

61 15 UnderpowerAlarm

62 15 ReversePowerAlarm

63 15 Rtd1Alarm

64 16 Rtd2Alarm

65 16 Rtd3Alarm

66 16 Rtd4Alarm

67 16 Rtd5Alarm

68 16 Rtd6Alarm

69 16 Rtd7Alarm

70 16 Rtd8Alarm

71 16 Rtd9Alarm

72 17 Rtd10Alarm

73 17 Rtd11Alarm

74 17 Rtd12Alarm

75 17 Rtd1HighAlarm

76 17 Rtd2HighAlarm

77 17 Rtd3HighAlarm

78 17 Rtd4HighAlarm

79 17 Rtd5HighAlarm


BIT BYTE FUNCTION



80 18 Rtd6HighAlarm

81 18 Rtd7HighAlarm

82 18 Rtd8HighAlarm

83 18 Rtd9HighAlarm

84 18 Rtd10HighAlarm



87 18 OpenRTDSensorAlarm

88 19 ShortRTDAlarm

89 19 TripCountersAlarm

90 19 StarterFailureAlarm

91 19 CurrentDemandAlarm

92 19 KWDemandAlarm

93 19 KVARDemandAlarm

94 19 KVADemandAlarm

95 19 DigitalCounterAlarm

96 20 OverloadLockoutBlock

97 20 StartInhibitBlock

98 20 StartsHourBlock

99 20 TimeBetweenStartsBlock

100 20 RestartBlock

101 20 Reserved

102 20 BackSpinBlock

103 20 LossofRemoteRTDCommunication

104 21 RemoteRTD1Rtd1Trip








BIT BYTE FUNCTION



































BIT BYTE FUNCTION













152 27 RemoteRTD1Rtd1Alarm






















BIT BYTE FUNCTION



2.5 Profibus-DP Loss Of Communication Trip

If the 369 detects a problem in communicating with the Profibus master, the Profibus Loss of Communications feature can be used to operate on any combination of output relays.





























BIT BYTE FUNCTION



During parameterization, a Profibus master sets up the communication and monitoring times for the slave including the watchdog time. A Profibus slave uses a watchdog timer to enable it to detect bus inactivity with its master. The watchdog timer is reset every time an error free message is received from the master. If no valid message is received within the time specified during parameterization, the slave assumes a communication error.

If the 369 Profibus communications is offline and not communicating with a master, then the “Fieldbus Loss of Comms” function (if enabled) will activate. This feature can be programmed for Latched or Unlatched operation.


The “Fieldbus Loss of Comms” output relay will remain latched until communication with the Master is (re) established AND the latched output relay is manually reset or remotely reset via Modbus communications.


Any output relays programmed for this feature will be de-activated once communication is restored; the Loss of Communication condition will be cleared and the assigned output relays will automatically de-activate.




3. Assigned Fieldbus Loss of Comms Relay



PROFIBUS-DPV1 COMMUNICATIONS COMMUNICATIONS GUIDE

3 Profibus-DPV1 Communications

3.1 369 Relay Profibus-DPV1 Parameterization

The 369 Motor Management Relay supports mandatory parametrization as well as three bytes of user parameter data necessary for DPV1 devices. The relay keeps its user parameter data/setpoints in a non-volatile memory and does not require device related parametrization during startup of the DP/V1 master, with the exception of the DPV1 Enable parameter. To enable the DPV1 acyclical functionality, the DPV1 parameter must be set to “Enable” when configuring the device in your master using the GSD file.

The EnerVista 369 Setup software is the best tool for editing user parametrization (setpoints) of the 369 Relay device.

FIGURE 1–2: User Parameter Setup – Enable DPV1

3.2 369 Relay Profibus Configuration

The Profibus-DPV1 basic configuration has one DP/V1 master and one DPV1 slave. In a typical bus segment up to 32 stations can be connected (a repeater has to be used if more then 32 stations operate on a bus). The end nodes on a Profibus-DPV1 network must be terminated to avoid reflections on the bus line.

The bus address for the relay as Profibus-DPV1 node can be set using the S1 369 SETUP

369 COMMUNICATIONS PROFIBUS ADDRESS setpoint or via the EnerVista 369 Setup software, which extends address range from 1 to 126. Address 126 is used only for commissioning purposes and should not be used to exchange user data.

COMMUNICATIONS GUIDE PROFIBUS-DPV1 COMMUNICATIONS


The Profibus media is a twisted-pair copper cable along with 9-pin Sub-D connector, which connects the bus to the 369 Relay socket on the back of the relay. The 369 Motor Management Relay has autobaud support. The baud rates and other slave specific information needed for configuration are contained in the 369_09E6.gse file, which is used by a network configuration program.

The 369 Motor Management Relay as a DPV1 slave transfers fast process data to the DP/V1 master according to master-slave principle. The 369 Relay is a modular device, supporting up to 111 input modules.

Modules define a block size of input data to be read by the master, starting from offset zero. Adding modules in your Master configuration increases the size of the total block of data that the Master will read, making it easy to choose a total block size of data that matches the user's requirements.

3.3 369 Relay Profibus Input Data

There are two options for configuring what data is made available through Profibus Input Data, based on the value of the PROFIBUS CYCLIC IN DATA setpoint (see 369 Instruction Manual, chapter 5 for details). If the PROFIBUS CYCLIC IN DATA setpoint is set to “0” (default map), then the data available to be read matches Table 1: Profibus Input Data on page 1–7.

The user can also exactly define the data provided and the order of that data. The Modbus User Definable Memory Map area and the PROFIBUS CYCLIC IN DATA setpoint are used to define this data. The PROFIBUS CYCLIC IN DATA setpoint determines the number of 16-bit registers available to be read through Profibus Input Data and the Modbus User Definable Memory Map is used to determine the data provided and the order of the data.

For example, if the user only wishes to read two 16-bit registers of data (4 bytes), the user selects a number of Input Modules from the GSD file that add up to a total of 4 bytes. When the Profibus Master is reading the Input data, only 4 bytes of Input data will be sent in the communication packet. The number of words should match the PROFIBUS CYCLIC IN DATA setpoint, but it's not necessary. If the number of Input data bytes read from the master is greater than the user has defined with the PROFIBUS CYCLIC IN DATA setpoint, the balance of the data will return zero values.



FIGURE 1–3: Slave Configuration Example 1 – 4 Bytes of Input Data

FIGURE 1–4: Slave Configuration Example 2 – 220 Bytes of Input Data

3.4 369 Relay Profibus Output Data

The capability to force the output relays states has been implemented in cyclic output data. As cyclic data is continuously written, the 369 looks for a change in the value to execute the force relays command. Refer to the 369 Instruction Manual, chapter 5 for more information about the force output relays feature.

COMMUNICATIONS GUIDE PROFIBUS-DPV1 COMMUNICATIONS


A slave configuration example for 4 bytes of input data and 2 bytes of output data is shown below.

FIGURE 1–5: Slave Configuration Example – 4 Bytes of Input Data, 2 bytes of Output Data

3.5 369 Relay Profibus Diagnostics

The diagnostic data available for the Profibus-DPV1 option matches Table 3: Profibus Diagnostics on page 1–12. When no diagnostic information is available and the master initiates a diagnostics read, the six slave mandatory bytes are read.

3.6 369 Relay Profibus-DPV1 Acyclical Communication

The following items have been made available through Profibus-DPV1 acyclical communication. Data is addressed through the use of “slot and index” addressing. Three parameters are required to read or write data from the 369 Relay using a Profibus-DPV1 master:

1. Slot number

2. Index number

3. Data length (number of 16-bit words)

Note The value that is written acyclically to either FORCE OUTPUT RELAYS or BLOCK PROTECTION

FUNCTIONS must be a 16-bit value. The lower byte contains the bitmask data (as per format codes noted) and the upper byte written must always contain a value of zero.

Table 4: Profibus Output Data


LENGTH (BYTES)

MINIMUM MAXIMUMFORMAT

CODEVALUE HEX VALUE HEX

0 Force Output Relays 2 0 0 15 F F141



Refer to the 369 Instruction Manual, chapter 5 for additional information about the force output relays feature. Refer to the 369 Instruction Manual, chapter 5.3.4 for additional information about the protection function blocking feature.

3.7 369 Relay Profibus-DPV1 Loss Of Communication Trip

If the 369 detects a problem in communicating with the Profibus master, the Profibus Loss of Communications feature can be used to operate on any combination of output relays. Refer to the following sections for more information regarding this feature:

369 Communications Guide: Section 2.5: Profibus-DP Loss Of Communication Trip

369 Instruction Manual: Chapter 5: 369 Communications (for information regarding the setpoints for this feature).

Table 5: Profibus-DPV1 Acyclic Write Data

OBJECT SLOT INDEX LENGTH DESCRIPTION FORMAT

0 0 0 2 bytes Force Output Relays F141

2 2 bytes Block Protection Functions F180

Table 6: Profibus-DPV1 Acyclic Read Data

OBJECT SLOT INDEX LENGTH DATA ITEM FORMAT

0 0

0 2 bytes Trip Relay Status F150

2 2 bytes Alarm Relay Status F150

4 2 bytes Aux1 Relay Status F150

6 2 bytes Aux2 Relay Status F150

8 2 bytes Functions Currently Blocked F141

COMMUNICATIONS GUIDE DEVICENET PROTOCOL


4 DeviceNet Protocol

4.1 DeviceNet Communications

The device profile is an extension of the Generic Device Profile (0x00). It is a group 2 only server. The MAC ID and baud rate are programmable through relay front panel or the EnerVista 369 Setup software. The polling function consumes one byte of control data (described under assembly object class 04, instance 96h) and produces data as per Poll Data Group 1, Poll Data Group 2, or the User-Defined poll data (described in assembly object class 04, instance 64h). The COS\CYC operation produces 4 bytes of data as per Class 4, Instance 66h, Attribute 3.

The EDS file for use with a DeviceNet master can be generated using the EnerVista 369 Setup program. The EDS file differs depending on which Poll Group is selected, and by the amount of data being returned for the User-Defined Poll Data. Note that only one version of the EDS file may be used for any one DeviceNet master.

The 369 Motor Management Relay supports following DeviceNet object classes.

DeviceNet Loss Of Communication Trip

If the 369 detects a failure in communicating with the DeviceNet master, the Fieldbus Loss of Communications feature can be used to trip any combination of output relays.

If the 369 DeviceNet communications is offline and not communicating with a master, then the “Fieldbus Loss of Comms” function (if enabled) will activate. This feature can be programmed for Latched or Unlatched operation.

If the “Fieldbus Loss of Comms” function is enabled , the 369 considers a DeviceNet loss of communication to have occurred in the following conditions:

1. Online; not connected

2. Critical link failure

3. Connection timeout.

Table 7: DeviceNet Object Classes

CLASS Object

01h Identity

02h Message Router

03h DeviceNet

04h Assembly

05h Connection

2Bh Acknowledge Handler

A0h IO data Input Mapping

A1h IO data Output Mapping

B0h Parameter Data input Mapping


DEVICENET PROTOCOL COMMUNICATIONS GUIDE

Note Critical link failure is caused by failure of CAN_H or CAN_L bus. To re-establish communication after recovery of critical link faliure, the 369 Fieldbus comms interface must be reset. This can be done without recycling the control power to the 369 by using "RESET FIELDBUS COMMS INTERFACE" command under setting S1 369 SETUP\369 COMMUNICATIONS\ . Refer to section 5.2.3 for more details.

A delay of 0.25 sec to 10.00 sec in steps of 0.25 sec can be programmed to delay the output relay activation.

This feature can be programmed for Latched or Unlatched operation.


The “DeviceNet Loss of Comms” trip will remain latched until the communication with the Master is (re) established AND the latched trip is manually reset or remotely reset via Modbus or DeviceNet communications.


Any programmed output relays for this feature will be activated until communication is active. Once communication is active, the trip condition will be cleared and the assigned output relays will automatically de-activate.




3. Assign Loss of Comms Relay


4.2 Poll Data

The polling function consumes one byte of control data and produces data as per Poll Data Group 1, Poll Data Group 2, or the User-Defined poll data. The control data format is as follows:

Bit Position Name Value

0 Motor Start 0.1

1 Motor Stop 0.1

2 Fault Reset 0.1

3 Reserved -

4 Reserved -

5 Reserved -

6 Reserved -

7 Reserved -



For execution of DeviceNet control commands, one of the switch assignments should be set to “DeviceNet Control” and be closed.

The motor start command energizes the output relay set with the START CONTROL RELAY setpoint. The motor stop command energizes the trip relay. The fault reset command resets the latched trip and alarm conditions, provided the cause of alarm/trip is removed. The commands are executed continuously as long as the control bits are high. When two or more commands are executed simultaneously, only one will be executed. The command hierarchy for execution is given below.

1. Motor stop

2. Fault reset

3. Motor start

Note The corresponding command bit should be high for more than 500 ms to execute the command.

The Polled input bytes can be selected from two predefined groups of parameters or one group of user-defined parameters with the “DeviceNet Input Poll Data Group” setpoint. The list of parameters in each group is given below:

Table 8: Poll Data Group 1

Byte Description Length Units Format Default

1 Motor Status 1 - F172 0

2 Digital Input Status 1 - F173 0

3 Digital Output Status 1 - F174 0

4 Flag Change State 1 - F175 0

5 Thermal Capacity Used 1 % UINT 0

6 (low), 7 (high) Time to Trip 2 seconds F20 -1



1 Motor Status - Stopped, Starting, Running, Tripped

1 - F172 0

2,3 Cause of Last Trip 2 - F134 0

4,5 Average Phase Current 2 A F1 0

6,7 Ground Current 2 A F23 0

8,9 Average Line Voltage 2 V F1 0

10,11 Real Power (kW) 2 kW F4 0

12,13 Power Factor 2 - F21 0



User-Defined Poll Data

The user can also define exactly which data will be provided and the order in which that data is given. The Modbus User Definable Memory Map area (refer to Section 9.6.2: User Definable Memory Map Area on page 9–34) and the “User-Defined Data Size” setpoint are used to define this data and data size. The “User-Defined Data Size” setpoint determines the number of 16-bit registers available to be read through DeviceNet Poll Input Data and the Modbus User Definable Memory Map is used to determine the data provided and the order of the data.

For example, if the user only wishes to read two 16-bit registers of data (4 bytes), the user sets the “DeviceNet Input Poll Data Group” setpoint to “User-Defined” and then programs a value of ‘2’ for the “User-Defined Data Size” setpoint. When the DeviceNet master reads the Poll Input data, 4 bytes of Input data will be read as follows.

Note that the Explicit message data provided both via Class 04, Instance 64h, Attribute 03 and Class A0h, Instance 01, Attribute 01 will match the the Poll data configuration.

4.3 Change of State (COS)

The COS data is described under class 4, instance 66h, attribute 3. The following data is provided:

14 Local Hottest Stator RTD Number 2 - F1 0

15,16 Local Hottest Stator RTD Temperature

2 °c F4 0

17 Digital Input Status - Access Switch, Speed Switch, Spare Switch, Differential Switch, Emergency Switch, Reset Switch

1 - F173 0

18 Digital Output Status - Trip Relay, Alarm Relay, Aux Relay 1, Aux Relay 2

1 - F174 0

Byte Description Length

1 (Hi), 2 (Lo) User Defined Memory Map Register 1 1 word

3 (Hi), 4 (lo) User Defined Memory Map Register 2 1 word




1 Motor Status 1 - F172 0

2 Digital Input Status 1 - F173 0

3 Digital Output Status 1 - F174 0

4 Flag Change State 1 - F175 0



4.4 Identity Object (class code 01h)

Identity object, Class code 01h, Services.

Identity object, Class code 01h, Attributes.

Identity object, Class code 01h, Instance 01h, Attributes.

The USINT and UINT data types are defined as follows: USINT = Unsigned integer byte (range 0 to 255); UINT = Unsigned integer word (range 0 to 65535).

4.5 Message Router (class code 02h)

The message router (class code 2) object provides a messaging connection point through which a client may address a service to any object or instance residing in the physical device. There is no external visible interface to the message router object.

4.6 DeviceNet Object (class code 03h)

DeviceNet object, Class code 03h, Services:

DeviceNet object, Class Code 03h, Attributes:

DeviceNet object, Class Code 03h, Instance 01h, Attributes:

CODESERVICES AVAILABLE TO THIS OBJECT

NAME DESCRIPTION

0x05 Reset Reset the device to power up configuration

0x0E Get_Attribute_Single Returns the contents of the given attribute

ATTRIBUTE ACCESS NAME/DESCRIPTION DATA TYPE VALUE

01h Get Revision of Identity object UINT 1


01h Get Vendor ID UINT 928

02h Get Device Type UINT 0

03h Get Product Code UINT 53

04h Get Revision (Major, Minor) USINT (2) 2.20

05h Get Status F178 ---

07h Get Product Name Short-String369 Motor Management Relay


NAME DESCRIPTION



01h Get Revision of DeviceNet object USINT 2


01h Get MAC ID USINT 0 to 63

02h Get Baud Rate USINT 0 = 125 kbps, 1 = 250 kbps,2 = 500 kbps



The USINT and UINT data types are defined as follows: USINT = Unsigned integer byte (range 0 to 255); UINT = Unsigned integer word (range 0 to 65535).

4.7 Assembly Object (class code 04h)

Assembly object, Class code 04h, Services:

Assembly object, Class code 04h, Attributes.

Assembly object, Class code 04h, Instance 64h, Attributes.



05h GetAllocation choice BYTE

Bit 0: explicit messagingBit 1: polled I/OBit 4: COS I/OBit 5: cyclic I/OBit 6: acknowledge suppression

Master’s MAC ID USINT 0 to 63: address;255 = unallocated



NAME DESCRIPTION


0X10 Set_Attribute_Single Sets the contents of the given attribute


01h Get Revision of Assembly object UINT 2

02h Get Maximum instance number UINT 150


03h Get Motor data1

1. The data available through this Class/Instance/Attribute will depend on which Poll Group is used (see section 4.2: Poll Data).

bytes (7) see below


03h Get Flag change state byte see below

DATA FORMATS, FLAG CHANGE STATE

BIT POSITION NAME VALUES

0 Trip/alarm flag 0 = no change; 1 = trip or alarm

1 to 7 Reserved ---


03h Get Digital data bytes (4) see below

DATA FORMATS, DIGITAL DATA

BYTE DESCRIPTION LENGTH UNITS FORMAT DEFAULT

1 Motor status 1 byte --- F172 0

2 Digital input status 1 byte --- F173 0

3 Digital output status 1 byte --- F174 0

4 Flag change state 1 byte --- F175 0






For execution of DeviceNet control commands, one of the switch assignments should be set to “DeviceNet Control” and be closed.

The motor start command energizes the output relay set with the START CONTROL RELAY setpoint. The motor stop command energizes the trip relay. The fault reset command resets the latched trip and alarm conditions, provided the cause of alarm/trip is removed. The commands are executed continuously as long as the control bits are high. When two or more commands are executed simultaneously, only one will be executed. The command hierarchy for execution is given below.

1. Motor stop2. Fault reset3. Motor start

The corresponding command bit should be high for more than 500 ms to execute the command.

4.8 DeviceNet Connection Object (class code 05h)

The connection objects manage the characteristics of each communication connection. There are two instances of the connection object in the device: explicit connection (<50 ms response) and input/output connection poll (<10 ms response).

Connection Object, Class Code 05h, Services:


03h Get Thermal capacity used USINT %

ATTRIBUTE ACCESS NAME/DESCRIPTION DATA TYPE DATA FORMAT VALUE

03h Get Time to trip Word F20 –1 second


03h Set Control byte 1 byte see below

DATA FORMATS, CONTROL BYTE

BIT POSITION NAME VALUE

0 Motor start 0, 1

1 Motor stop 0, 1

2 Fault reset 0, 1

3 Reserved ---

4 Reserved ---

5 Reserved ---

6 Reserved ---

7 Reserved ---

CODE NAME AND DESCRIPTION OF SERVICES AVAILABLE TO THIS OBJECT

0x05 Reset the connection - restart timer

0x0E Get_Attribute_Single: Returns the contents of the given attribute.

0x10 Set_Attribute_Single: Sets the contents of the given attribute



Connection Object, Class Code 05h, Instance 01h (explicit message connection):

Connection Object, Class Code 05h, Instance 02h (polled input/output connection):

4.9 Acknowledge Handler Object (class code 2Bh)

Acknowledge Handler Object, Class Code 2Bh, Services:

Acknowledge Handler object, Class code 2Bh, Attributes.


01h Get State BYTE 0x03

02h Get Instance_type BYTE 0x00, 0x01

03h Get Export class trigger BYTE 0x83

04h Get Produced connection ID UINT 10xxxxxx011, xxxxxx = MAC ID

05h Get Consumed connection ID UINT 10xxxxxx011, xxxxxx = MAC ID

06h Get Initial comm. characteristics UINT 0x21

07h Get Produced connection size UINT 0x12

08h Get Consumed connection size UINT 0x12

09h Get/Set Expected package rate UINT 0x00

0Ch Get/Set Watchdog timeout action USINT0 = transition to time-out1 = auto delete, 2 = auto reset3 = deferred delete

0Dh Get Produced path length UINT 0x0000

0Eh Get Produced path BYTE [6] <null>

0Fh Get Consumed path length UINT 0x0000

10h Get Consumed path BYTE [6] <null>

11h Get Production inhibit timer UINT 0x0000


01h Get State BYTE 0x03

02h Get Instance_type BYTE 0x01

03h Get Export class trigger BYTE 0x80, 0x82

04h Get Produced connection ID UINT MAC ID

05h Get Consumed connection ID UINT MAC ID

06h Get Initial comm. characteristics UINT 0x01, 0xF1

07h Get Produced connection size UINT 0x01

08h Get Consumed connection size UINT 0x01

09h Get/Set Expected package rate UINT 0x00

0Ch Get/Set Watchdog timeout action UINT 0x00

0Dh Get Produced path length UINT 0x0006

0Eh Get Produced path BYTE [6] <null>

0Fh Get Consumed path length UINT 0x0006

10h Get Consumed path BYTE [6] <null>

11h Get Production inhibit timer UINT 0x0000

CODE NAME DESCRIPTION


0x10 Set_Attribute_Single Sets the contents of the given attribute


01h Get Revision of Acknowledge Handler object UINT 1

02h Get Maximum instance number UINT 1



Acknowledge Handler object, Class code 2Bh, Instance 01h, Attributes:

4.10 I/O Data Input Mapping Object (class code A0h)

I/O Data Input Mapping Object, Class code A0h, Services:

Input/Output Data Input Mapping object, Class code A0h, Attributes.

I/O Data Input Mapping object, Class code A0h, Instance 01h, Attributes:

4.11 I/O Data Output Mapping Object (class code A1h)

I/O Data Output Mapping Object, Class code A1h, Services:

I/O Data Input Mapping object, Class code A0h, Instance 01h, Attributes:


01h Get Acknowledge timer UINT 16 ms

02h Get Retry limit USINT 1




01h Get Revision of I/O Data Input Mapping object UINT 1

ATTRIBUTE ACCESS NAME/DESCRIPTION DATA TYPE DATA FORMAT

01h Get Motor data1

1. The data available through this Class/Instance/Attribute will depend on which Poll Group is used (see section 4.2: Poll Data)

bytes (7) see below

02h Get Flag change state byte F175

03h Get Digital data bytes (4) see below

04h Get Thermal capacity used USINT %

05h Get Time to trip Word F20

DATA FORMATS, DIGITAL DATA

BYTE DESCRIPTION LENGTH UNITS FORMAT DEFAULT

1 Motor status 1 byte --- F172 0

2 Digital input status 1 byte --- F173 0

3 Digital output status 1 byte --- F174 0

4 Flag change state 1 byte --- F175 0



0x10 Set_Attribute_Single Sets the contents of the given attribute

ATTRIBUTE ACCESS NAME/DESCRIPTION DATA TYPE DATA FORMAT

01h Set Control byte 1 byte see below



0 Motor start 0, 1

1 Motor stop 0, 1

2 Fault reset 0, 1

3 Reserved ---



4.12 Parameter Data Input Mapping Object (class code B0h)

Parameter Data Input Mapping object, Class code B0h, Services:

Parameter Data Input Mapping object, Class code B0h, Attributes.

4 Reserved ---

5 Reserved ---

6 Reserved ---

7 Reserved ---






01h Get Revision of Identity object UINT 1



Parameter Data Input Mapping object, Class code B0h, Instance 01h, Attributes:ATTRIBUTE ACCESS NAME/DESCRIPTION DATA TYPE VALUE

01h Get Currents bytes (10) see below

02h Get Current angles bytes (6) see below

03h Get Motor load bytes (6) see below

04h Get Line voltages bytes (8) see below

05h Get Phase voltages bytes (8) see below

06h Get Phase voltage angles bytes (6) see below

07h Get Frequency bytes (2) see below

08h Get BSD state and frequency bytes (6) see below

09h Get Power bytes (10) see below

0Ah Get Energy bytes (6) see below

0Bh Get Local hottest stator RTD and temperature bytes (4) see below

0Ch Get Local RTD temperatures bytes (24) see below

0Dh Get Demand bytes (8) see below

0Eh Get Peak values bytes (8) see below

0Fh Get Learned data bytes (14) see below

10h Get Motor statistics bytes (8) see below

11h Get Cause of trip bytes (2) see below

12h Get Last trip date and time bytes (8) see below

13h Get Last pre-trip currents bytes (8) see below

14h Get Last pre-trip motor load bytes (4) see below

15h Get Pre-trip local hottest stator RTD and temperature bytes (4) see below

16h Get Last pre-trip line voltages bytes (6) see below

17h Get Last pre-trip phase voltages bytes (6) see below

18h Get Last pre-trip frequency bytes (2) see below

19h Get Last pre-trip power bytes (8) see below

1Ah Get Trip diagnostic data bytes (6) see below

1Bh Get Alarm diagnostic data bytes (8) see below

1Ch Get Start block status data bytes (18) see below

1Dh Get Actual values bytes (202) see below

DATA FORMATS FOR CLASS CODE B0H, INSTANCE 1 (Sheet 1 of 7)

ATTRIBUTE BYTES DESCRIPTION LENGTH FORMAT VALUE/UNIT

01hCURRENTS

1,2 (low, high) Phase Current Ia 16 bits UINT A

3,4 (low, high) Phase Current Ib 16 bits UINT A

5,6 (low, high) Phase Current Ic 16 bits UINT A

7,8 (low, high) Average phase current Iav 16 bits UINT A

9,10 (low, high) Ground current Ig 16 bits F23 0.1 × A or 0.01 × A

02hCURRENT ANGLES

1,2 (low, high) Ia angle 16 bits UINT degrees

3,4 (low, high) Ib angle 16 bits UINT degrees

5,6 (low, high) Ic angle 16 bits UINT degrees

03hMOTOR LOAD

1,2 (low, high) Motor load 16 bits F3 0.01 × FLA

3,4 (low, high) Current unbalance 16 bits UINT %

5,6 (low, high) Unbalanced biased motor load (Ieq) 16 bits F3 0.01 × FLA



04hLINE VOLTAGES

1,2 (low, high) Voltage Vab 16 bits UINT V

3,4 (low, high) Voltage Vbc 16 bits UINT V

5,6 (low, high) Voltage Vca 16 bits UINT V

7,8 (low, high) Average line voltage 16 bits UINT V

05hPHASE VOLTAGES

1,2 (low, high) Voltage Van 16 bits UINT V

3,4 (low, high) Voltage Vbn 16 bits UINT V

5,6 (low, high) Voltage Vcn 16 bits UINT V

7,8 (low, high) Average phase voltage 16 bits UINT V

06hPHASE VOLTAGE ANGLES

1,2 (low, high) Va angle 16 bits UINT degrees

3,4 (low, high) Vb angle 16 bits UINT degrees

5,6 (low, high) Vc angle 16 bits UINT degrees

07hFREQUENCY 1,2 (low, high) Frequency 16 bits F3 × 0.01 Hz

08hBSD STATE AND FREQ.

1,2 (low, high) BSD state 16 bits F27 --

3,4 (low, high) Backspin frequency 16 bits F3 × 0.01 Hz

5,6 (low, high) Backspin prediction timer 16 bits F1 s

09hPOWER

1,2 (low, high) Power factor 16 bits F21 × 0.01 PF

3,4 (low, high) Real power (kW) 16 bits F4 kW

5,6 (low, high) Real power (hp) 16 bits UINT hp

7,8 (low, high) Reactive power 16 bits F4 kvar

9,10 (low, high) Apparent power 16 bits UINT kVA

0AhENERGY

1,2 (low, high) MWh 16 bits UINT MWh

3,4 (low, high) Positive Mvarh 16 bits UINT Mvarh

5,6 (low, high) Negative Mvarh 16 bits UINT Mvarh

0BhRTD TEMP-ERATURE

1,2 (low, high) Local hottest stator RTD 16 bits UINT ---

3,4 (low, high) Local hottest stator RTD temperature 16 bits F4 °C

0ChLOCAL RTD TEMP-ERATURE

1,2 (low, high) Local RTD 1 temperature 16 bits F4 °C
















0DhDEMAND

1,2 (low, high) Current demand 16 bits UINT A

3,4 (low, high) Real power demand 16 bits UINT kW

5,6 (low, high) Reactive power demand 16 bits UINT kvar

7,8 (low, high) Apparent power demand 16 bits UINT kVA

0EhPEAK DEMAND

1,2 (low, high) Peak current demand 16 bits UINT A

3,4 (low, high) Peak real power demand 16 bits UINT kW

5,6 (low, high) Peak reactive power demand 16 bits UINT kvar

7,8 (low, high) Peak apparent power demand 16 bits UINT kVA

0FhLEARNED DATA

1,2 (low, high) Learned acceleration time 16 bits F2 x 0.1 seconds

3,4 (low, high) Learned starting current 16 bits UINT A

5,6 (low, high) Learned starting capacity 16 bits UINT %

7,8 (low, high) Learned running cool time constant 16 bits UINT minutes

9,10 (low, high) Learned stopped cool time constant 16 bits UINT minutes

11,12 (low, high) Last starting capacity 16 bits UINT %

13,14 (low, high) Learned unbalance k-factor 16 bits UINT --

10hMOTOR STATISTICS

1,2 (low, high) Number of starts 16 bits UINT --

3,4 (low, high) Number of restarts 16 bits UINT --

5,6 (low, high) Digital counter 16 bits UINT --

7,8 (low, high) Motor running hours 16 bits UINT hours

11hCAUSE OF LAST TRIP

1,2 (low, high) Cause of last trip 16 bits F134 --

12hLAST PRE-TRIP DATE AND TIME.

1 to 4(low, high) Last trip date 32 bits F18 --

5 to 8(low, high) Last trip time 32 bits F19 --

13hLAST PRE-TRIP CURRENTS

1,2 (low, high) Last pre-trip Ia 16 bits UINT A

3,4 (low, high) Last pre-trip Ib 16 bits UINT A

5,6 (low, high) Last pre-trip Ic 16 bits UINT A

7,8 (low, high) Last pre-trip Ig 16 bits F2 0.1 × A

14hLAST PRE-TRIP MOTOR LOAD

1,2 (low, high) Last pre-trip motor load 16 bits F3 × 0.01 FLA

3,4 (low, high) Last pre-trip unbalance 16 bits UINT %

15hPRE-TRIP STATOR RTD TEMP.

1,2 (low, high) Local pre-trip hottest stator RTD 16 bits UINT ---

3,4 (low, high) Local pre-trip hottest stator RTD temperature 16 bits F4 °C

16hLAST PRE-TRIP LINE VOLTAGES

1,2 (low, high) Last pre-trip Vab 16 bits UINT volts

3,4 (low, high) Last pre-trip Vbc 16 bits UINT volts

5,6 (low, high) Last pre-trip Vca 16 bits UINT volts

17hLAST PRE-TRIP PHASE VOLTAGES

1,2 (low, high) Last pre-trip Van 16 bits UINT volts

3,4 (low, high) Last pre-trip Vbn 16 bits UINT volts

5,6 (low, high) Last pre-trip Vcn 16 bits UINT volts





18hLAST PRE-TRIP FREQ.

1,2 (low, high) Last pre-trip frequency 16 bits F3 × 0.01 Hz

19hLAST PRE-TRIP POWER

1,2 (low, high) Last pre-trip kilowatts 16 bits F4 kW

3,4 (low, high) Last pre-trip kvar 16 bits F4 kvar

5,6 (low, high) Last pre-trip KVA 16 bits UINT kVA

7,8 (low, high) Last pre-trip power factor 16 bits F21 × 0.01 PF

1AhTRIP DIAG. 6 bytes Trip diagnostic data 48 bits F176

1BhALARM DIAG. 8 bytes Alarm diagnostic data 64 bits F177

1ChSTART BLOCK STATUS

1,2 (low, high) Overload lockout timer 16 bits UINT minutes

3,4 (low, high) Starts timer [1] 16 bits UINT minutes





13,14 (low, high) Time between starts timer 16 bits UINT minutes

15,16 (low, high) Restart block timer 16 bits UINT seconds

17,16 (low, high) Start inhibit timer 16 bits UINT minutes

1DhACTUAL VALUES

1,2 (low, high) Phase current Ia 16 bits UINT A

3,4 (low, high) Phase current Ib 16 bits UINT A

5,6 (low, high) Phase current Ic 16 bits UINT A

7,8 (low, high) Average phase current Iav 16 bits UINT A

9,10 (low, high) Ground current Ig 16 bits F23 0.1 × A or 0.01 × A

11,12 (low, high) Ia angle 16 bits UINT degrees

13,14 (low, high) Ib angle 16 bits UINT degrees

15,16 (low, high) Ic angle 16 bits UINT degrees

17,18 (low, high) Motor load 16 bits F3 × 0.01 FLA

19,20 (low, high) Current unbalance 16 bits UINT %

21,22 (low, high) Unbalanced biased motor load (Ieq) 16 bits F3 0.01 × FLA

23,24 (low, high) Voltage Vab 16 bits UINT V

1DhACTUAL VALUEScontinued

25,26 (low, high) Voltage Vbc 16 bits UINT V

27,28 (low, high) Voltage Vca 16 bits UINT V

29,30 (low, high) Average line voltage 16 bits UINT V

31,32 (low, high) Voltage Van 16 bits UINT V

33,34 (low, high) Voltage Vbn 16 bits UINT V

35,36 (low, high) Voltage Vcn 16 bits UINT V

37,38 (low, high) Average phase voltage 16 bits UINT V

39,40 (low, high) Va angle 16 bits UINT degrees

41,42 (low, high) Vb angle 16 bits UINT degrees

43,44 (low, high) Vc angle 16 bits UINT degrees

45,46 (low, high) Frequency 16 bits F3 × 0.01 Hz





47,48 (low, high) BSD state 16 bits F27 --

49,50 (low, high) Backspin frequency 16 bits F3 × 0.01 Hz

51,52 (low, high) Backspin prediction timer 16 bits F1 seconds

53,54 (low, high) Power factor 16 bits F21 × 0.01 PF

55,56 (low, high) Real power (kW) 16 bits F4 kW

57,58 (low, high) Real power (hp) 16 bits UINT hp

59,60 (low, high) Reactive power 16 bits F4 kvar

61,62 (low, high) Apparent power 16 bits UINT kVA

63,64 (low, high) MWh 16 bits UINT MWh

65,66 (low, high) Positive Mvarh 16 bits UINT Mvarh

67,68 (low, high) Negative Mvarh 16 bits UINT Mvarh

69,70 (low, high) Local Hottest stator RTD 16 bits UINT ---


71,72 (low, high) Local Hottest stator RTD temperature 16 bits F4 °C













97,98 (low, high) Current demand 16 bits UINT A

99,100 (low, high) Real power demand 16 bits UINT kW

101,102 (low, high) Reactive power demand 16 bits F4 kvar

103, 104 (low, high) Apparent power demand 16 bits UINT kVA

105, 106 (low, high) Peak current demand 16 bits UINT A

107, 108 (low, high) Peak real power demand 16 bits UINT kW

109, 110 (low, high) Peak reactive power demand 16 bits F4 kvar

111,112 (low, high) Peak apparent power demand 16 bits UINT kVA





113,114 (low, high) Learned acceleration time 16 bits F2 × 0.1 seconds

115,116 (low, high) Learned starting current 16 bits UINT A

117,118 (low, high) Learned starting capacity 16 bits UINT %


119,120 (low, high) Learned running cool time constant 16 bits UINT minutes

121,122 (low, high) Learned stopped cool time constant 16 bits UINT minutes

123,124 (low, high) Last starting capacity 16 bits UINT %

125,126 (low, high) Learned unbalance k-factor 16 bits UINT --

127,128 (low, high) Number of starts 16 bits UINT --

129,130 (low, high) Number of restarts 16 bits UINT --

131,132 (low, high) Digital counter 16 bits UINT --

133,134 (low, high) Motor running Hours 16 bits UINT hours

135,136 (low, high) Cause of last trip 16 bits F134 --

137 to 140 (low, high) Last trip date 32 bits F18 --

141 to 144 (low, high) Last trip time 32 bits F19 --

145, 146 (low, high) Last pre-trip Ia 16 bits UINT A

147, 148 (low, high) Last pre-trip Ib 16 bits UINT A

149, 150 (low, high) Last Pre-trip Ic 16 bits UINT A

151, 152 (low, high) Last Pre-trip Ig 16 bits F2 × 0.1 A

153, 154 (low, high) Last pre-trip motor load 16 bits F3 × 0.01 FLA

155, 156 (low, high) Last pre-trip unbalance 16 bits UINT %

157, 158 (low, high) Last pre-trip local hottest stator RTD 16 bits UINT ---

159, 160 (low, high)Last pre-trip local hottest stator RTD temperature

16 bits F4 °C

161, 162 (low, high) Last pre-trip Vab 16 bits UINT volts

163, 164 (low, high) Last pre-trip Vbc 16 bits UINT volts

165, 166 (low, high) Last pre-trip Vca 16 bits UINT volts

167, 168 (low, high) Last pre-trip Van 16 bits UINT volts


169, 170 (low, high) Last pre-trip Vbn 16 bits UINT volts

171, 172 (low, high) Last pre-trip Vcn 16 bits UINT volts

173, 174 (low, high) Last pre-trip frequency 16 bits F3 × 0.01 Hz

175, 176 (low, high) Last pre-trip kilowatts 16 bits F4 kW

177, 178 (low, high) Last pre-trip kvar 16 bits F4 kvar

179, 180 (low, high) Last pre-trip KVA 16 bits UINT kVA

181, 182 (low, high) Last pre-trip power factor 16 bits F21 × 0.01 PF

183 to 188 Trip diagnostic data 48 bits F176

189 to 196 Alarm diagnostic data 64 bits F177

197, 198 (low, high) Overload lockout timer 16 bits UINT minutes

199, 200 (low, high) Starts timer [1] 16 bits UINT minutes





4.13 DeviceNet Loss Of Communication Trip

If the 369 detects a problem in communicating with the DeviceNet master, the DeviceNet Loss of Communications feature can be used to operate on any combination of output relays.

If the 369 DeviceNet communications is offline and not communicating with a master, then the “Fieldbus Loss of Comms” function (if enabled) will activate. This feature can be programmed for Latched or Unlatched operation.


The “Fieldbus Loss of Comms” output relay will remain latched until communication with the Master is (re) established AND the latched output relay is manually reset or remotely reset via Modbus communications.


Any output relays programmed for this feature will be de-activated once communication is restored; the Loss of Communications condition will be cleared and the assigned output relays will automatically de-activate.




3. Assigned Fieldbus Loss of Comms Relay

Refer to the 369 Instruction Manual, Chapter 5: 369 Relay Communications for more information on these setpoints.





209, 210 (low, high) Time between starts timer 16 bits UINT minutes

211, 212 (low, high) Restart block timer 16 bits UINT seconds

213, 214 (low, high) Start inhibit timer 16 bits UINT minutes





4.14 DeviceNet Data Formats

FORMAT VALUE NAME/DESCRIPTION

F167

Network status: unsigned 16 bit integer

0 Power off / Not online

1 Online, Connected

2 Link failure

3 Not defined

F168

Connection status: unsigned 16 bit integer

0 Nonexistent

1 Configuring

2 (Not used)

3 Established

4 Timed out

5 Deferred delete

F170

DeviceNet baud rate: unsigned 16 bit integer

0 125 kbps

1 250 kbps

2 500 kbps

F172

Motor status: Unsigned 8 bit integer

Bit 0 Stopped

Bit 1 Starting

Bit 2 Running

Bit 3 Overloaded

Bit 4 Tripped

Bits 5 to 7 Reserved

F173

Digital input status: unsigned 8 bit integer

Bit 0 Access Switch Status0 = Open, 1= Closed

Bit 1 Speed Switch Status0 = Open, 1= Closed

Bit 2 Spare Switch Status0 = Open, 1= Closed

Bit 3 Differential Switch Status0 = Open, 1= Closed

Bit 4 Emergency Switch status0 = Open, 1= Closed

Bit 5 Reset Switch Status0 = Open, 1= Closed

Bit 6 Reserved

Bit 7 Reserved

F174

Output relay status: unsigned 8 bit integer

Bit 0 Trip Relay Status0 = De-energized, 1 = Energized

Bit 1 Alarm Relay Status0 = De-energized, 1 = Energized

Bit 2 Aux1 Relay Status0 = De-energized, 1 = Energized

Bit 3 Aux2 Relay Status0 = De-energized, 1 = Energized




F175

Flag change state: unsigned 8 bit integer

Bit 0 Trip/Alarm status; 1= operated





F176

Relay trips: bitmask

Byte 1 Bit 0 Single Phasing Trip

Bit 1 Spare Switch Trip

Bit 2 Emergency Switch Trip

Bit 3 Differential Switch Trip

Bit 4 Speed Switch Trip

Bit 5 Reset Switch Trip

Bit 6 Reserved

Bit 7 Overload Trip

Byte 2 Bit 0 Short Circuit Trip

Bit 1 Short Circuit Backup Trip

Bit 2 Mechanical Jam Trip

Bit 3 Undercurrent Trip

Bit 4 Current Unbalance Trip

Bit 5 Ground Fault Trip

Bit 6 Ground Fault Backup Trip

Bit 7 Reserved

Byte 3 Bit 0 Acceleration Timer Trip

Bit 1 RTD 1 Trip

Bit 2 RTD 2 Trip

Bit 3 RTD 3 Trip

Bit 4 RTD 4 Trip

Bit 5 RTD 5 Trip

Bit 6 RTD 6 Trip

Bit 7 RTD 7 Trip

Byte 4 Bit 0 RTD 8 Trip

Bit 1 RTD 9 Trip

Bit 2 RTD 10 Trip

Bit 3 RTD 11 Trip

Bit 4 RTD 12 Trip

Bit 5 Undervoltage Trip

Bit 6 Overvoltage Trip

Bit 7 Voltage Phase Reversal Trip

Byte 5 Bit 0 Underfrequency Trip

Bit 1 Overfrequency Trip

Bit 2 Lead Power Factor Trip

Bit 3 Lag Power Factor Trip

Bit 4 Positive kvar Trip

Bit 5 Negative kvar Trip

Bit 6 Underpower Trip

Bit 7 Reverse Power Trip

Byte 6 Bit 0 Incomplete Sequence Trip

Bit 1 Reserved

Bit 2 Reserved

Bit 3 Reserved

Bit 4 Reserved

Bit 5 Reserved

Bit 6 Reserved

Bit 7 Reserved




F177

Relay alarms: bitmask

Byte 1 Bit 0 Spare Switch Alarm

Bit 1 Emergency Switch Alarm

Bit 2 Differential Switch Alarm

Bit 3 Speed Switch Alarm

Bit 4 Reset Switch Alarm

Bit 5 Reserved

Bit 6 Thermal Capacity Alarm

Bit 7 Overload Alarm

Byte 2 Bit 0 Mechanical Jam Alarm

Bit 1 Undercurrent Alarm

Bit 2 Current Unbalance Alarm

Bit 3 Ground Fault Alarm

Bit 4 Undervoltage Alarm

Bit 5 Overvoltage Alarm

Bit 6 Overfrequency Alarm

Bit 7 Underfrequency Alarm

Byte 3 Bit 0 Lead Power Factor Alarm

Bit 1 Lag Power Factor Alarm

Bit 2 Positive kvar Alarm

Bit 3 Negative kvar Alarm

Bit 4 Underpower Alarm

Bit 5 Reverse Power Alarm

Bit 6 RTD 1 Alarm

Bit 7 RTD 2 Alarm

Byte 4 Bit 0 RTD 3 Alarm

Bit 1 RTD 4 Alarm

Bit 2 RTD 5 Alarm

Bit 3 RTD 6 Alarm

Bit 4 RTD 7 Alarm

Bit 5 RTD 8 Alarm

Bit 6 RTD 9 Alarm

Bit 7 RTD 10 Alarm

Byte 5 Bit 0 RTD 11 Alarm

Bit 1 RTD 12 Alarm

Bit 2 RTD 1 High Alarm






Byte 6 Bit 0 RTD 7 High Alarm






Bit 6 Open RTD Sensor Alarm

Bit 7 Short RTD Alarm




F178

DeviceNet Communication status: unsigned 16 bit integer

Bit 0 0 = not owned,1 = owned by master

Bit 1 Reserved

Bit 2 0 = factory default, 1= configured


Bit 8 1 = Minor recoverable fault

Bit 9 1 = Minor unrecoverable fault

Bit 10 1 = Major recoverable fault

Bit 11 1 = Major unrecoverable fault



COMMUNICATIONS GUIDE MODBUS RTU PROTOCOL


5 Modbus RTU Protocol

5.1 Data Frame Format and Data Rate

One data frame of an asynchronous transmission to or from an 369 is default to 1 start bit, 8 data bits, and 1 stop bit. This produces a 10 bit data frame. This is important for transmission through modems at high bit rates (11 bit data frames are not supported by Hayes modems at bit rates of greater than 300 bps). The parity bit is optional as odd or even. If it is programmed as odd or even, the data frame consists of 1 start bit, 8 data bits, 1 parity bit, and 1 stop bit.

Modbus protocol can be implemented at any standard communication speed. The 369 RS485, fiber optic and RS232 ports support operation at 1200, 2400, 4800, 9600, and 19200 baud.

5.2 Data Packet Format

A complete request/response sequence consists of the following bytes (transmitted as separate data frames):

Master Request Transmission:

SLAVE ADDRESS- 1 byteFUNCTION CODE- 1 byteDATA- variable number of bytes depending on FUNCTION CODECRC- 2 bytes

Slave Response Transmission:

SLAVE ADDRESS- 1 byteFUNCTION CODE- 1 byteDATA- variable number of bytes depending on FUNCTION CODECRC- 2 bytes

SLAVE ADDRESS: This is the first byte of every transmission. It represents the user-assigned address of the slave device that is to receive the message sent by the master. Each slave device must be assigned a unique address and only the addressed slave will respond to a transmission that starts with its address. In a master request transmission the SLAVE ADDRESS represents the address of the slave to which the request is being sent. In a slave response transmission the SLAVE ADDRESS represents the address of the slave that is sending the response. Note: A master transmission with a SLAVE ADDRESS of 0 indicates a broadcast command. Broadcast commands can be used for specific functions.

FUNCTION CODE: This is the second byte of every transmission. The modbus protocol defines function codes of 1 to 127. The 369 implements some of these functions. In a master request transmission the FUNCTION CODE tells the slave what action to perform. In a slave response transmission if the FUNCTION CODE sent from the slave is the same as the FUNCTION CODE sent from the master indicating the slave performed the function as requested. If the high order bit of the FUNCTION CODE sent from the slave is a 1 (i.e. if the FUNCTION CODE is > 127) then the slave did not perform the function as requested and is sending an error or exception response.


MODBUS RTU PROTOCOL COMMUNICATIONS GUIDE

DATA: This will be a variable number of bytes depending on the FUNCTION CODE. This may be actual values, setpoints, or addresses sent by the master to the slave or by the slave to the master. Data is sent MSByte first followed by the LSByte.

CRC: This is a two byte error checking code. CRC is sent LSByte first followed by the MSByte.

5.3 Error Checking

The RTU version of Modbus includes a two byte CRC-16 (16 bit cyclic redundancy check) with every transmission. The CRC-16 algorithm essentially treats the entire data stream (data bits only; start, stop and parity ignored) as one continuous binary number. This number is first shifted left 16 bits and then divided by a characteristic polynomial (11000000000000101B). The 16 bit remainder of the division is appended to the end of the transmission, LSByte first. The resulting message including CRC, when divided by the same polynomial at the receiver will give a zero remainder if no transmission errors have occurred.

If an 369 Modbus slave device receives a transmission in which an error is indicated by the CRC-16 calculation, the slave device will not respond to the transmission. A CRC-16 error indicates than one or more bytes of the transmission were received incorrectly and thus the entire transmission should be ignored in order to avoid the 369 performing any incorrect operation.

The CRC-16 calculation is an industry standard method used for error detection. An algorithm is included here to assist programmers in situations where no standard CRC-16 calculation routines are available.

5.4 CRC-16 Algorithm

Once the following algorithm is complete, the working register "A" will contain the CRC value to be transmitted. Note that this algorithm requires the characteristic polynomial to be reverse bit ordered. The MSbit of the characteristic polynomial is dropped since it does not affect the value of the remainder. The following symbols are used in the algorithm:

--> data transferA 16 bit working registerAL low order byte of AAH high order byte of ACRC 16 bit CRC-16 valuei, j loop counters(+) logical exclusive or operatorDi i-th data byte (i = 0 to N-1)G 16 bit characteristic polynomial = 1010000000000001 with MSbit dropped and bit order reversedshr(x) shift right (the LSbit of the low order byte of x shifts into a carry flag, a '0' is shifted into the

MSbit of the high order byte of x, all other bits shift right one location

The algorithm is as follows:

1. FFFF hex --> A



2. 0 --> i

3. 0 --> j

4. Di (+) AL --> AL

5. j+1 --> j

6. shr(A)

7. is there a carry?No: go to 8.Yes: G (+) A --> A

8. is j = 8?No: go to 5.Yes: go to 9.

9. i+1 --> i

10. is i = N?No: go to 3.Yes: go to 11.

11. A --> CRC

5.5 Timing

Data packet synchronization is maintained by timing constraints. The receiving device must measure the time between the reception of characters. If three and one half character times elapse without a new character or completion of the packet, then the communication link must be reset (i.e. all slaves start listening for a new transmission from the master). Thus at 9600 baud a delay of greater than 3.5 × 1 / 9600 × 10 = 3.65 ms will cause the communication link to be reset.

5.6 Supported Modbus Functions

The following Modbus functions are supported by the 369:

• 03 - Read Setpoints and Actual Values

• 04 - Read Setpoints and Actual Values

• 05 - Execute Operation

• 06 - Store Single Setpoint

• 07 - Read Device Status

• 08 - Loopback Test

• 16 - Store Multiple Setpoints

For detailed Modbus function code descriptions, refer to the Modicon Modbus Protocol Reference guide.

5.7 Error Responses

When an 369 detects an error other than a CRC error, a response will be sent to the master. The MSbit of the FUNCTION CODE byte will be set to 1 (i.e. the function code sent from the slave will be equal to the function code sent from the master plus 128). The following byte will be an exception code indicating the type of error that occurred.


MODBUS RTU PROTOCOL COMMUNICATIONS GUIDE

Transmissions received from the master with CRC errors will be ignored by the 369 Relay. The slave response to an error (other than CRC error) will be:

SLAVE ADDRESS - 1 byteFUNCTION CODE - 1 byte (with MSbit set to 1)EXCEPTION CODE - 1 byteCRC - 2 bytes

The 369 implements the following exception response codes.

• 01 - ILLEGAL FUNCTION:

The function code transmitted is not one of the functions supported by the 369 Relay.

• 02 - ILLEGAL DATA ADDRESS:

The address referenced in the data field transmitted by the master is not an allowable address for the 369 Relay.

• 03 - ILLEGAL DATA VALUE:

The value referenced in the data field transmitted by the master is not within range for the selected data address.

5.8 Modbus Commands

The following commands can be sent to Modbus address 0x0080 (format code F31). Commands 1 to 4 can also be sent using Modbus function code 5 (Execute Operation).

• Command 1 (Remote Reset 369): Modbus Command 1 will attempt to clear the status of protection elements and output relay states.

• Command 2 (Motor Start): Modbus Command 2 will activate the programmed start relay, as long as it is not currently active and the stop relay is not currently active.

• Command 3 (Motor Stop): Modbus Command 3 will activate the trip relay as long as it is not currently active and the start relay is not currently active.

• Command 4 (Waveform Trigger): Modbus Command 4 will trigger the waveform capture trace memory.

• Command 6 (Clear Trip Counters): Modbus Command 6 will clear all trip counters.

• Command 7 (Clear Last Trip Data): Modbus Command 7 will clear the last trip data.

• Command 10 (Clear RTD Maximums): Modbus Command 10 will initialize all RTD (and Remote RTD, if applicable) maximum data to default values.

• Command 11 (Reset Motor Info): Modbus Command 11 will clear the number of motor starts, number of motor restarts, motor running hours, and number of restart attempts. It will also clear all learned motor statistics and Data Logger data.

• Command 12 (Clear/Reset All Data): Modbus Command 12 will clear all event data, trip counters, last trip data, peak demand data, RTD maximums data, motor statistics data, Data Logger data, and all energy data.

• Command 20 (Protection Function Blocking): This command must be sent using Modbus function code 10h (Store Multiple Setpoints). This allows the 369 to accept the two required 16-bit values in one transmission. The first data word is the command



number (20). The 2nd data word contains the bitmask information for which functions to block/unblock as per format code F180.

When this command is sent to the 369, the protection function blocking setpoints (Modbus addresses 1520 to 1528) are updated accordingly. For example, for Bit 0 in the 2nd data word, the setpoint value for Block Undercurrent/Underpower at address 1521 will be modified to contain either a “1” or “0”, depending on the bit value.

Refer to the 369 Instruction Manual, chapter 5: Block Functions for additional information about the protection function blocking feature.

• Command 21 (Force Output Relays): Modbus Command 20 must be sent using Modbus function code 10h (Store Multiple Setpoints). This allows the 369 to accept the two required 16-bit values in one transmission. The first data word is the command number (21). The 2nd data word contains the bitmask information for which relays to energize/de-energize as per format code F141.

The purpose of this command is to allow the control of the output relay status, regardless of the motor status (running, stopped, etc.). Only relays that have been programmed under the ASSIGN COMMS FORCE RELAYS setpoint can be forced using this command.

Refer to the 369 Instruction Manual, chapter 5: Force Output Relays for more information about the force output relays feature.

• Command 24 (Clear Data Logger Data): This command will clear all the existing data presently available in the Data Logger feature. Please refer to the 369 Instruction Manual, chapter 6: Data Logger and 6.6: Data Logger for more information on the Data Logger feature.


MEMORY MAP COMMUNICATIONS GUIDE

6 Memory Map

6.1 Memory Map Information

The data stored in the 369 is grouped as setpoints and actual values. Setpoints can be read and written by a master computer. Actual Values are read-only. All setpoints and actual values are stored as two-byte values. That is, each register address is the address of a two-byte value. Addresses are listed in hexadecimal. Data values (setpoint ranges, increments, factory values) are in decimal.

Note Many Modbus communications drivers add 40001d to the actual address of the register addresses. For example: if address 0h was to be read, 40001d would be the address required by the Modbus communications driver; if address 320h (800d) was to be read, 40801d would be the address required by the Modbus communications driver.

6.2 User Definable Memory Map Area

The 369 has a powerful feature, called the User Definable Memory Map, which allows a computer to read up to 125 non-consecutive data registers (setpoints or actual values) by using one Modbus packet. It is often necessary for a master computer to continuously poll various values in each of the connected slave relays. If these values are scattered throughout the memory map, reading them would require numerous transmissions and would burden the communication link. The User Definable Memory Map can be programmed to join any memory map address to one in the block of consecutive User Map locations, so that they can be accessed by reading these consecutive locations.

The User Definable area has two sections:

1. A Register Index area (memory map addresses 0180h-01FCh) that contains 125 Actual Values or Setpoints registers.

2. A Register area (memory map addresses 0100h-017Ch) that contains the data at the addresses in the Register Index.

Register data that is separated in the rest of the memory map may be remapped to adjacent register addresses in the User Definable Registers area. This is accomplished by writing to register addresses in the User Definable Register Index area. This allows for improved through-put of data and can eliminate the need for multiple read command sequences. For example, if the values of Average Phase Current (register address 0306h) and Hottest Stator RTD Temperature (register address 0320h) are required to be read from an 369, their addresses may be remapped as follows:

1. Write 0306h to address 0180h (User Definable Register Index 0000) using function code 06 or 16.

2. Write 0320h to address 0181h (User Definable Register Index 0001) using function code 06 or 16.

A read (function code 03 or 04) of registers 0100h (User Definable Register 0000) will return the Phase A Current and register 0101h (User Definable Register 0001) will return Hottest Stator RTD Temperature.

COMMUNICATIONS GUIDE MEMORY MAP


6.3 Event Recorder

The 369 event recorder data starts at address 3000h. Address 3003h is a pointer to the event of interest (1 representing the oldest event and 512 representing the latest event. To retrieve event 1, write ‘1’ to the Event Record Selector (3003h) and read the data from 3004h to 3022h. To retrieve event 2, write ‘2’ to the Event Record Selector (3003h) and read the data from 3004h to 3022h. All 512 events may be retrieved in this manner. The time and date stamp of each event may be used to ensure that all events have been retrieved in order without new events corrupting the sequence of events (event 3 should be more recent than event 2, event 2 should be more recent than event 1, etc.).

The digital counter will be displayed when one of the digital inputs has been set up as a digital counter. The digital counter can be cleared with the S1 369 SETUP CLEAR/PRESET DATA

PRESET DIGITAL COUNTER setpoint. When the digital counter has exceeded 65535, it will automatically be reset by the 369 Relay relay to 0.

6.4 Waveform Capture

The 369 stores 16 cycles of A/D samples each time a trip occurs in a trace buffer. The Trace Memory Trigger is set up in S1 Preferences and determines how many pre-trip and post-trip cycles are stored. The trace buffer is time and date stamped and may be correlated to a trip in the event record. 7 waveforms are captured this way when a trip occurs. These are the 3 phase currents, ground current and 3 voltage waveforms. The last three captured records are retained by the 369. This information is stored in volatile memory and will be lost if power is cycled to the relay.

To access the captured waveforms, select the captured record by writing to the Trace Memory Buffer Selector (address 30F5h), then select waveform of interest by writing its trace memory channel (see following table) to the Trace Memory Channel Selector (address 30F6h). Then read the trace memory data from address 3100h to 31FFh. The values read are in actual amperes or volts.

INTERNAL UNITS SCALE

SR 369 presents modbus values for trace data in internal units.

The scale of internal units for phase currents is 1 x CT = 128.

The internal unit for ground current is 1 x CT = 2560, when using ground CT types 1A secondary or 5A secondary.

The internal unit for ground currents is 1 x CT =1900, when using ground CT type Multilin CT 50/0.025.

The scale of internal units for voltage is 1 x VT = 690.

Let SFcurrent represent scale factor for phase current.

TRACE MEMORYCHANNEL WAVEFORM TRACE MEMORY

CHANNEL WAVEFORM

0 Phase A current 4 Phase A voltage1

1. For an Open Delta VT connection channel 4 contains Vab data and channel 6 contains Vcb data.

1 Phase B current 5 Phase B voltage

2 Phase C current 6 Phase C voltage1

3 Ground current



Let SFground current represent scale factor for ground current.

Let SFground current MULITLIN represent scale factor for ground current with CT type MULTILIN.

Let SFvoltage represent scale factor for phase voltage.

SFcurrent = (CT primary )/ (128)

SFground current = (Ground CT primary )/ (2560)

SFground current MULTILIN = (1 Ampere )/ (1900)

SFvoltage = (120 V ) * (Voltage ratio) / (690)

To calculate a value in units of Ampere from a waveform trace sample for Current:

Phase current [ Ampere ] = (trace sample value) * SFcurrent

To calculate a value in units of Ampere from a waveform trace sample for Ground current, using CT type 1A secondary or 5A secondary:

Ground current [ Ampere ] = (trace sample value) * SFground current

To calculate a value in units of Ampere from a waveform trace sample for Ground current, using CT type Multilin CT 50/0.025:

Ground current [Ampere] = (trace sample value)* SFground current MULTILIN

To calculate a value in units of Volt from a waveform trace sample for Voltage:

Phase voltage [ Volt ] = (trace sample value) * SFvoltage

Table 10: Modbus registers related to trace value scale factor

Phase CT

The setpoint in modbus register 1180 provides an external factor for calculating phase current.

Let A represent external scale, where A = value of register 1180.

Let B represent internal scale, where B = 128 for Phase current on SR369.

SFcurrent = A/B.

Ground CT (type 1A Secondary or type 5A Secondary)

The setpoint in modbus register 1183 provides an external factor for calculating ground current.

The setpoint in modbus register 1182 has value 1 or value 2, indicating 1A or 5A secondary.

Let A represent external scale, where A = value of register 1183.

Let B represent internal scale, where B = 2560 for ground current on SR369.

Setpoint Description Units of measure

1180 CT primary Current [Ampere]

1182 Ground CT Type Current [Ampere]

1183 Ground CT primary Current [Ampere]

11A1 Voltage ratio Ratio [n:1]



SFground current = A/B.

Ground CT (type Multilin CT 50/0.025)

The setpoint in modbus register 1183 provides an external factor for calculating ground current.

The setpoint in modbus register 1182 has value 3, indicating Ground CT type Multilin CT.

Let A represent external scale, where A = 1 Ampere.

Let B represent internal scale, where B = 1900 for ground current (MULTILIN CT) on SR369.

SFground current MULTILIN = A/B = 0.000526316 Ampere.

Phase VT

The setpoint in modbus register 11A1 provides an external factor for calculating phase voltage.

Let A represent external scale, where A = (120 Volts) * (value of register 11A1).

Let B represent internal scale, where B = 690 for Phase voltage on SR369.

SFvoltage = A/B.

Table 11: SR 369 internal units per channel.

Channelnumber Input wiring Internal

units scaleNominal

UnitExternal Scale factorSFcurrent or SFvoltage

Modbus register

0 Phase A current 128 1 x CT CT primary /128 1180

1 Phase B current 128 1 x CT CT primary /128 1180

2 Phase C current 128 1 x CT CT primary /128 1180

3 Ground current , CT type = 1A or 5A secondary

2560 1 x CT Ground CT primary/2560 1183

3 Ground current , CT type = Multlin CT 50/0.025

1900 1 x CT 1 Ampere/1900 = 0. 000526316 A 1182

4 Phase A voltage 690 1 x VT 120 V * ( Phase VT ratio)/ 690 11A1

5 Phase B voltage 690 1 x VT 120 V * ( Phase VT ratio)/ 690 11A1

6 Phase C voltage 690 1 x VT 120 V * ( Phase VT ratio)/ 690 11A1



EXAMPLE CASES

Table 12: Example cases to demonstrate scaling factor in Phase current

Table 13: Example case to demonstrate scaling factor in Ground Current, CT type 1A secondary or CT type 5A secondary.

Table 14: Example case to demonstrate scaling factor in Ground Current, Multilin CT

6.5 Motor Start Data Logger

When a motor start status condition is detected by the 369 relay, the MOTOR START DATA

LOGGER is triggered and begins to sample and record the following parameters at a rate of 1 sample every 200ms:

• True RMS values of the Phase A, B and C Currents (Ia, Ib, and Ic).

• True RMS value of the Ground current (Ig).

• Current Unbalance (%).

• True RMS values of the Phase A-N, B-N, and C-N voltages (Van, Vbn, and Vcn) if VT

CONNECTION TYPE is set to Wye.True RMS values of the Phase A-B, B-C and C-A voltages (Vab, Vbc, and Vca) if VT

CONNECTION TYPE is set to Delta.

• Thermal Capacity Used (%).

• Frequency.

• Breaker/Contactor Contact Input Status

• Motor Speed (low/high).

1 second of pre-trigger data and 29 seconds of post-trigger data are recorded. The data logger ignores all subsequent triggers and continues to record data until the active record is finished.

Channel

Let A representModbus value

At register 1180,CT PRIMARY

ActualPrimary Current

Value in waveform capture trace data

register 3100 to 31FF

Scale factorSFcurrent = A / B

Ia 1500 A 1000 A 85.333 A/B = 11.71875 A

Ia 1000 A 1000 A 128 A/B = 7.8125 A

Ia 500 A 1000 A 256 A/B = 3.90625 A

Channel

Let A representModbus value

At register 1183,Ground CT PRIMARY





Ig 10 A 10 A 2560 A/B = 3.90625 A

Channel

Let A representGround CT Type

Multilin.Modbus register 1182 has value 3.





Ig 1 A 1 A 1900 A/B = 0.000526316 A



A total of 6 logs are stored in the relay. Log #1 is the baseline log, it is written only by the first start after clearing the MOTOR START DATA LOGGER (see the 369 Instruction Manual, chapter 5: Clear/Preset Data). Logs #2 to 6 are rolling buffers of the last 5 motor starts. Each new log automatically shifts the rolling buffer and overwrites the oldest log, #2.

Log files are formatted using CSV (comma delimited values). The files can be downloaded and displayed via EnerVista 369 Setup software. All files are stored in non-volatile memory; information is retained when power to the relay is lost.

6.6 Data Logger

The Data Logger allows up to 16 channels of data parameters (refer to Modbus format code F189 for the available parameters) to be continually recorded at a defined rate of between 1 and 3600 seconds. The 369 has allocated 32k bytes of RAM for Data Log storage. All data will be lost upon loss of the 369 control power.

Internal to the 369, the memory structure is partitioned into 256 blocks containing 64 two-byte registers. Blocks 0 and 1 have been allocated for the Header data, and Blocks 2-255 have been allocated to the logged data. In order to access the Log data and read it via the "Data Logger Data" Modbus addresses 0x3281 to 0x32C0, a Block index value is stored to the Data Log Memory Access Block Number at Modbus address 0x1E23. The data obtained from the Data Logger Data registers will differ depending on the Block index value stored.

Each entry into a Data Log is called a Record. The Record size will vary in size depending upon the how many channels the user wishes to use. In addition to the actual logged data itself, the Data Logger contains what is called the Header, which can be read from Modbus address 0x3200 to 0x3278. The Data Log Header contains the following read-only information:

• Log Time Interval: This is the interval at which the data log will store entries (1~3600s).

• Log Record Size: This is the size of each Record entry into the Data Log. It is based upon how many channels have been selected to use.

• Log Total Possible Records: This value indicates the maximum number of potential records available, which depends on the record size.

• Total Logs Since Last Clear: This value indicates the number of Logs that have been generated since the Data Logger was last cleared. Although it's maximum range is 65535, the 369 will only retain up to the latest 50 records.

• Total Logs Presently Used: This value indicates the total number of Logs that have been captured and are presently available in the 369.

• Total Records Presently Used: This is the number of records that have been written into the Data Log and are presently available in the 369.

• Log Status: This reports the current status of the Data Logger (Running or Stopped).

• Log Time Remaining Until Next Reading: This is a counter showing how much time remains until the next record is to be written into the Data Log (1~3600s).

• Data Logger Percentage Full: Indicates what percentage of the total available memory is used.

• Pointer To Next Record To Write: This value points to the internal data address of the location of the next record to be written.



• Pointer To Log (1-50) Starting Address : This value points to the internal data address of the location of each of the potential 50 records.

• Log (1-50) Number of Records: This value provides the number of records that each of the 50 potential Logs contain.

• Log (1-50) Start/Stop Method: This value is used to indicate the method by which each log was started and stopped. If the bit value for the Start is zero, it was started by a motor start event. Refer to Modbus format code F191 for more information on the format of this data.

6.7 Modbus Memory Map

Table 15: MEMORY MAP (Sheet 1 of 66)

ADDR (hex) DESCRIPTION MIN. MAX. STEP

VALUE UNITS FORMAT CODE

FACTORY DEFAULT

PRODUCT ID (ADDRESSES 0000 TO 007F)PRODUCT ID

0000 GE Multilin Product Code - - - - F1 530001 Product Hardware Revision 1 26 1 N/A F15 A0002 Firmware Revision N/A N/A N/A N/A F16 N/A0003 Installed Modifications N/A N/A N/A N/A F14 0000004 Boot Revision 0 999 1 - F1 00005 Boot Modification Number - - - - - -0006 Reserved - - - - - -0007 Reserved - - - - - -0008 Order Code 0 65535 1 N/A F13 0↓ ↓ - - - - - -000F Modify Options 0 N/A - N/A N/A -

0010 Modify Options Passcode Characters 1 and 2 32 127 1 - F1 " "

↓ ↓ - - - - - -

0017 Modify Options Passcode Characters 15 and 16 32 127 1 - F1 " "

--- --- - - - - - -0020 Serial Number character 1 and 2 N/A N/A N/A ASCII F22 N/A0021 Serial Number character 3 and 4 N/A N/A N/A ASCII F22 N/A0022 Serial Number character 5 and 6 N/A N/A N/A ASCII F22 N/A0023 Serial Number character 7 and 8 N/A N/A N/A ASCII F22 N/A0024 Serial Number character 9 and 10 N/A N/A N/A ASCII F22 N/A0025 Serial Number character 11 and 12 N/A N/A N/A ASCII F22 N/A0026 Main Firmware Build Date N/A N/A N/A - F18 N/A0028 Main Firmware Build Time N/A N/A N/A - F19 N/A... Reserved - - - - - -0040 Manufacturing Date 1995 2094 1 - F18 Jan.1,1999... Reserved - - - - - -

SETPOINT ACCESS0050 Keypad Access Level 0 1 1 N/A F162 00051 Comm Access Level 0 1 1 N/A F162 00052 Access Password Character 1 and 2 32 127 1 - F1 " "0053 Access Password Character 3 and 4 32 127 1 - F1 " "0054 Access Password Character 5 and 6 32 127 1 - F1 " "0055 Access Password Character 7 and 8 32 127 1 - F10056 Encrypted Access Password 1 and 2 32 127 1 - F1 “AI”0057 Encrypted Access Password 3 and 4 32 127 1 - F1 “KF”



0058 Encrypted Access Password 5 and 6 32 127 1 - F1 “BA”0059 Encrypted Access Password 7 and 8 32 127 1 - F1 IK”... Reserved - - - - - -

COMMANDS (ADDRESSES 0080 TO 00FB)0080 Command Function Code 0 21 1 - F31 00081 Reserved0082 RRTD 1 Command Function Code 0 4 1 - F31 00083 RRTD 2 Command Function Code 0 4 1 - F31 00084 RRTD 3 Command Function Code 0 4 1 - F31 00085 RRTD 4 Command Function Code 0 4 1 - F31 0... Reserved

REAL TIME CLOCK00F0 Time (2 words) valid time N/A - F19 -00F2 Date (2 words) valid date N/A - F18 -... Reserved

PROFIBUS COMMUNICATIONS00FC Fieldbus Loss of Comms Enable 0 2 1 - F115 0 (Off)00FD Fieldbus Loss of Comms Delay 25 1000 250 msec F2 25

00FE Assign Fieldbus Loss of Comms Relay 0 15 1 - F169 0 (None)

00FF Profibus Cyclic Input Data Configuration 0 110 1 - F1 0

USER MAP (ADDRESSES 0100 TO 017F)0100 User Map Value # 1 --- --- --- --- --- ---↓ ↓017C User Map Value # 125 --- --- --- --- --- ---... Reserved0180 User Map Address # 1 0 3FFF 1 hex F1 0↓ ↓01FC User Map Address # 125 0 3FFF 1 hex F1 0... Reserved

ACTUAL VALUES (ADDRESSES 0200 TO 0FFF)MOTOR STATUS

0200 Motor Status 0 4 1 - F133 00201 Motor Thermal Capacity Used 0 100 1 % F1 00202 Estimated Time to Trip on Overload -1 65500 1 s F20 -1

AUTORESTART0203 Restart Attempts 0 20000 1 - F1 -0204 Restart Total Delay 0 65535 1 sec. F1 -0205 Restart In Progress 0 1 1 Y/N F1 -0206 UVR Power Loss Time 0 40000 1 0.1 s F2 Read Only

MOTOR SPEED STATUS0207 Motor Speed Status 0 2 1 N/A F186 0... Reserved

LAST TRIP DATA0220 Cause of Last Trip 0 276 1 - F134 00221 Last Trip Time (2 words) N/A N/A N/A N/A F19 -0223 Last Trip Date (2 words) N/A N/A N/A N/A F18 -0225 Last Trip Motor Speed 0 2 1 N/A F186 -0226 Phase A Pre-Trip Current 0 65535 1 A F1 00228 Phase B Pre-Trip Current 0 65535 1 A F1 0022A Phase C Pre-Trip Current 0 65535 1 A F1 0022C Motor Load Pre - Trip 0 2000 1 FLA F3 0022D Current Unbalance Pre - Trip 0 100 1 % F1 0




FACTORY DEFAULT



022E Ground Current Pre - Trip 0 50000 1 A F2 0... Reserved - - - - - -

0233 Hottest Stator RTD Owner During Trip 0 5 1 N/A F165 0

0234 Hottest Stator RTD During Trip 0 12 1 - F1 0

0235 Pre-Trip Temperature of Hottest Stator RTD -40 200 1 °C F4 0

0236 Pre-Trip Voltage Vab 0 65000 1 V F1 00237 Pre-Trip Voltage Vbc 0 65000 1 V F1 00238 Pre-Trip Voltage Vca 0 65000 1 V F1 00239 Pre-Trip Voltage Van 0 65000 1 V F1 0023A Pre-Trip Voltage Vbn 0 65000 1 V F1 0023B Pre-Trip Voltage Vcn 0 65000 1 V F1 0023C Pre-Trip System Frequency 0 12000 1 Hz F3 0023D Pre-Trip Real Power -32000 32000 1 kW F4 0023E Pre-Trip Reactive Power -32000 32000 1 kvar F4 0023F Pre-Trip Apparent Power 0 50000 1 kVA F1 00240 Pre-Trip Power Factor -99 100 1 - F21 0... Reserved - - - - - -

ALARM STATUS

0260General Spare Switch Alarm Status orStarter Monitor Alarm/Trip Status

0 4 1 - F123 0

0261 General Emergency Restart Switch Alarm Status 0 4 1 - F123 0

0262 General Differential Switch Alarm Status 0 4 1 - F123 0

0263 General Speed Switch Alarm Status 0 4 1 - F123 00264 General Reset Switch Alarm Status 0 4 1 - F123 0... Reserved0267 Thermal Capacity Alarm 0 4 1 - F123 00268 Overload Alarm Status 0 4 1 - F123 00269 Mechanical Jam Alarm Status 0 4 1 - F123 0026A Undercurrent Alarm Status 0 4 1 - F123 0026B Current Unbalance Alarm Status 0 4 1 - F123 0026C Ground Fault Alarm Status 0 4 1 - F123 0... Reserved026F Undervoltage Alarm Status 0 4 1 - F123 00270 Overvoltage Alarm Status 0 4 1 - F123 00271 Overfrequency Alarm Status 0 4 1 - F123 00272 Underfrequency Alarm Status 0 4 1 - F123 0... Reserved0275 Lead Power Factor Alarm Status 0 4 1 - F123 00276 Lag Power Factor Alarm Status 0 4 1 - F123 00277 Positive kvar Alarm Status 0 4 1 - F123 00278 Negative kvar Alarm Status 0 4 1 - F123 00279 Underpower Alarm Status 0 4 1 - F123 0027A Reverse Power Alarm Status 0 4 1 - F123 0... Reserved027D Local RTD #1 Alarm Status 0 4 1 - F123 0027E Local RTD #2 Alarm Status 0 4 1 - F123 0027F Local RTD #3 Alarm Status 0 4 1 - F123 00280 Local RTD #4 Alarm Status 0 4 1 - F123 00281 Local RTD #5 Alarm Status 0 4 1 - F123 00282 Local RTD #6 Alarm Status 0 4 1 - F123 00283 Local RTD #7 Alarm Status 0 4 1 - F123 0




FACTORY DEFAULT



0284 Local RTD #8 Alarm Status 0 4 1 - F123 00285 Local RTD #9 Alarm Status 0 4 1 - F123 00286 Local RTD #10 Alarm Status 0 4 1 - F123 00287 Local RTD #11 Alarm Status 0 4 1 - F123 00288 Local RTD #12 Alarm Status 0 4 1 - F123 00289 Local RTD #1 High Alarm Status 0 4 1 - F123 0028A Local RTD #2 High Alarm Status 0 4 1 - F123 0028B Local RTD #3 High Alarm Status 0 4 1 - F123 0028C Local RTD #4 High Alarm Status 0 4 1 - F123 0028D Local RTD #5 High Alarm Status 0 4 1 - F123 0028E Local RTD #6 High Alarm Status 0 4 1 - F123 0028F Local RTD #7 High Alarm Status 0 4 1 - F123 00290 Local RTD #8 High Alarm Status 0 4 1 - F123 00291 Local RTD #9 High Alarm Status 0 4 1 - F123 00292 Local RTD #10 High Alarm Status 0 4 1 - F123 00293 Local RTD #11 High Alarm Status 0 4 1 - F123 00294 Local RTD #12 High Alarm Status 0 4 1 - F123 00295 Broken / Open RTD Alarm Status 0 4 1 - F1230296 Short / Low Temp Alarm Status 0 1 1 - F1230297 Reserved0298 Trip Counter Alarm Status 0 4 1 - F123 00299 Starter Failure Alarm 0 4 1 - F123 0029A Current Demand Alarm Status 0 4 1 - F123 0029B kW Demand Alarm Status 0 4 1 - F123 0029C kvar Demand Alarm Status 0 4 1 - F123 0029D kVA Demand Alarm Status 0 4 1 - F123 0029E Self Test Alarm 0 4 1 - F123 0

START BLOCK STATUS02C0 Overload Lockout Timer 0 9999 1 min F1 002C1 Start Timer 1 0 60 1 min F1 002C2 Start Timer 2 0 60 1 min F1 002C3 Start Timer 3 0 60 1 min F1 002C4 Start Timer 4 0 60 1 min F1 002C5 Start Timer 5 0 60 1 min F1 002C6 Time Between Starts Timer 0 500 1 min F1 002C7 Restart Block Timer 0 50000 1 s F1 002C8 Reserved02C9 Start Inhibit Timer 0 500 1 min F1 002CA Starts Per Hour Lockout Timer 0 60 1 min F1 0... Reserved

DIGITAL INPUT STATUS02D0 Access 0 1 1 - F131 002D1 Speed 0 1 1 - F131 002D2 Spare 0 1 1 - F131 002D3 Differential Relay 0 1 1 - F131 002D4 Emergency Restart 0 1 1 - F131 002D5 Reset 0 1 1 - F131 0... Reserved

OUTPUT RELAY STATUS02E0 Trip 0 1 1 N/A F150 002E1 Alarm 0 1 1 N/A F150 002E2 Aux.1 0 1 1 N/A F150 002E3 Aux.2 0 1 1 N/A F150 0... Reserved




FACTORY DEFAULT



369 DIGITAL INPUT AND OUTPUT RELAY STATUS02E6 Digital Input and Output Relay Status N/A N/A N/A N/A F192 0... Reserved

REAL TIME CLOCK02F0 Date (Read Only) N/A N/A N/A N/A F18 N/A02F4 Time (Read Only) N/A N/A N/A N/A F19 N/A... Reserved

FIELDBUS SPECIFICATION STATUS02F8 Explicit Connection Status 0 5 1 N/A F168 0

02F9 Input/Output Polled Connection Status 0 5 1 N/A F168 0

02FA Network Status 0 3 1 N/A F167 0... Reserved

CURRENT METERING0300 Phase A Current 0 65535 1 A F1 00302 Phase B Current 0 65535 1 A F1 00304 Phase C Current 0 65535 1 A F1 00306 Average Phase Current 0 65535 1 A F1 00308 Motor Load 0 2000 1 × FLA F3 00309 Current Unbalance 0 100 1 % F1 0030A Unbalaced Biased Motor Load 0 9999 1 × FLA F3 0030B Ground Current 0 65535 1 A F23 0... Reserved - - - - - -

OVERALL STATOR RTD031C Overall Hottest Stator RTD Owner 0 5 1 N/A F165 0031D Overall Hottest Stator RTD Number 0 12 1 N/A F1 0

031E Overall Hottest Stator RTD Temperature –40 200 1 °C F4 -

TEMPERATURE031F Local Hottest Stator RTD Number 0 12 1 - F1 0

0320 Local Hottest Stator RTD Temperature –40 200 1 °C F4 40

0321 Local RTD #1 Temperature –40 200 1 °C F4 400322 Local RTD #2 Temperature –40 200 1 °C F4 400323 Local RTD #3 Temperature –40 200 1 °C F4 400324 Local RTD #4 Temperature –40 200 1 °C F4 400325 Local RTD #5 Temperature –40 200 1 °C F4 400326 Local RTD #6 Temperature –40 200 1 °C F4 400327 Local RTD #7 Temperature –40 200 1 °C F4 400328 Local RTD #8 Temperature –40 200 1 °C F4 400329 Local RTD #9 Temperature –40 200 1 °C F4 40032A Local RTD #10 Temperature –40 200 1 °C F4 40032B Local RTD #11 Temperature –40 200 1 °C F4 40032C Local RTD #12 Temperature –40 200 1 °C F4 40... Reserved

VOLTAGE METERING0360 Vab 0 65535 1 V F1 00361 Vbc 0 65535 1 V F1 00362 Vca 0 65535 1 V F1 00363 Average Line Voltage 0 65535 1 V F1 00364 Van 0 65535 1 V F1 00365 Vbn 0 65535 1 V F1 00366 Vcn 0 65535 1 V F1 00367 Average Phase Voltage 0 65535 1 V F1 0




FACTORY DEFAULT



0368 System Frequency 0 12000 1 Hz F3 0BACKSPIN METERING

0369 Backspin Frequency (a value of “0” represents ‘low signal’) 0 12000 1 Hz F3 0

036A Backspin Detection State 0 6 1 - F27 0036B Backspin Prediction Timer 0 50000 1 s F1 0... Reserved

POWER METERING0370 Power Factor –99 100 1 - F21 00371 Real Power –32000 32000 1 kW F4 00373 Real Power 0 42912 1 hp F1 00374 Reactive Power –32000 32000 1 kvar F4 00376 Apparent Power 0 65000 1 kVA F1 00377 Positive MegaWatthours 0 65535 1 MWh F1 00379 Positive Megavarhours 0 65535 1 Mvarh F1 0037B Negative Megavarhours 0 65535 1 Mvarh F1 0037D Positive KiloWatthours 0 999 1 kWh F1 0037F Positive Kilovarhours 0 999 1 kvarh F1 00381 Negative Kilovarhours 0 999 1 kvarh F1 0... Reserved

DEMAND METERING0390 Current Demand 0 65535 1 A F1 00392 Real Power Demand 0 32000 1 kW F1 00394 Reactive Power Demand 0 32000 1 kvar F1 00396 Apparent Power Demand 0 65000 1 kVA F1 00397 Peak Current Demand 0 65535 1 A F1 00399 Peak Real Power Demand 0 32000 1 kW F1 0039B Peak Reactive Power Demand 0 32000 1 kvar F1 0039D Peak Apparent Power Demand 0 65000 1 kVA F1 0... Reserved

MOTOR DATA (0 = OFF)03C0 Learned Acceleration Time 1 2500 1 s F2 003C1 Learned Starting Current 0 65535 1 A F1 003C2 Learned Starting Capacity 0 100 1 % F1 0

03C3 Learned Running Cool Time Constant 0 500 1 min F1 0

03C4 Learned Stopped Cool Time Constant 0 500 1 min F1 0

03C5 Last Starting Current 0 65535 1 A F1 003C6 Last Starting Capacity 0 100 1 % F1 003C7 Last Acceleration Time 1 2500 1 s F2 003C8 Average Motor Load Learned 0 2000 1 x FLA F3 003C9 Learned Unbalance k factor 0 29 1 - F1 003CA Average Run Time After Start (Days) 0 65535 1 days F1 0

03CB Average Run Time After Start (Minutes) 1440 1 minutes F1 0

03CC Date of Record - - - - F19 -

03CE Number of Enhanced Learned Records 0 65535 1 F1 0

LOCAL RTD MAXIMUMS03E0 Local RTD # 1 Max. Temperature -40 200 1 °C F4 4003E1 Local RTD # 2 Max. Temperature -40 200 1 °C F4 4003E2 Local RTD # 3 Max. Temperature -40 200 1 °C F4 4003E3 Local RTD # 4 Max. Temperature -40 200 1 °C F4 4003E4 Local RTD # 5 Max. Temperature -40 200 1 °C F4 40




FACTORY DEFAULT



03E5 Local RTD # 6 Max. Temperature -40 200 1 °C F4 4003E6 Local RTD # 7 Max. Temperature -40 200 1 °C F4 4003E7 Local RTD # 8 Max. Temperature -40 200 1 °C F4 4003E8 Local RTD # 9 Max. Temperature -40 200 1 °C F4 4003E9 Local RTD # 10 Max. Temperature -40 200 1 °C F4 4003EA Local RTD # 11 Max. Temperature -40 200 1 °C F4 4003EB Local RTD # 12 Max. Temperature -40 200 1 °C F4 40... Reserved

TRIP COUNTERS0430 Total Number of Trips 0 50000 1 - F1 0... Reserved0433 Switch Trips 0 50000 1 - F1 0... Reserved0436 Overload Trips 0 50000 1 - F1 00437 Short Circuit Trips 0 50000 1 - F1 00438 Mechanical Jam Trips 0 50000 1 - F1 00439 Undercurrent Trips 0 50000 1 - F1 0043A Current Unbalance Trips 0 50000 1 - F1 0043B Single Phase Trips043C Ground Fault Trips 0 50000 1 - F1 0043D Acceleration Trips 0 50000 1 - F1 0... Reserved043F Undervoltage Trips 0 50000 1 - F1 00440 Overvoltage Trips 0 50000 1 - F1 00441 Phase Reversal Trips 0 50000 1 - F1 00442 Under Frequency Trips 0 50000 1 - F1 00443 Over Frequency Trips 0 50000 1 - F1 0... Reserved0446 Lead Power Factor Trips 0 50000 1 - F1 00447 Lag Power Factor Trips 0 50000 1 - F1 00448 Positive Reactive Power Trips 0 50000 1 - F1 00449 Negative Reactive Power Trips 0 50000 1 - F1 0044A Underpower Trips 0 50000 1 - F1 0044B Reverse Power Trips 0 50000 1 - F1 0... Reserved044E Stator RTD Trips 0 50000 1 - F1 0044F Bearing RTD Trips 0 50000 1 - F1 00450 Other RTD Trips 0 50000 1 - F1 00451 Ambient RTD Trips 0 50000 1 - F1 00452 UVR Undervoltage Trip Counters 0 50000 1 - F1 Read Only... Reserved0454 Incomplete Sequence Trips 0 50000 1 - F1 0... Reserved0457 Trip Counters Last Cleared N/A N/A N/A N/A F18 N/A... Reserved

MOTOR STATISTICS0470 Number of Motor Starts 0 50000 1 - F1 00471 Number of Emergency Restarts 0 50000 1 - F1 00472 Reserved - - - - - -0473 Digital Counter 0 65535 1 - F1 0... Reserved04A0 Motor Running Hours 0 65535 1 hr. F1 0... Reserved




FACTORY DEFAULT



PHASORS0500 Va Angle 0 359 1 degrees F1 00501 Vb Angle 0 359 1 degrees F1 00502 Vc Angle 0 359 1 degrees F1 00503 Ia Angle 0 359 1 degrees F1 00504 Ib Angle 0 359 1 degrees F1 00505 Ic Angle 0 359 1 degrees F1 0... Reserved

REMOTE RTD ACTUAL VALUES (ADDRESSES 0600 TO 1FFF)RRTD 1 TEMPERATURES

0600 RRTD 1 - Hottest Stator Number 0 12 1 - F1 00601 RRTD 1 - Hottest Stator Temperature -40 200 1 °C F4 400602 RRTD 1 - RTD #1 Temperature -40 200 1 °C F4 400603 RRTD 1 - RTD #2 Temperature -40 200 1 °C F4 400604 RRTD 1 - RTD #3 Temperature -40 200 1 °C F4 400605 RRTD 1 - RTD #4 Temperature -40 200 1 °C F4 400606 RRTD 1 - RTD #5 Temperature -40 200 1 °C F4 400607 RRTD 1 - RTD #6 Temperature -40 200 1 °C F4 400608 RRTD 1 - RTD #7 Temperature -40 200 1 °C F4 400609 RRTD 1 - RTD #8 Temperature -40 200 1 °C F4 40060A RRTD 1 - RTD #9 Temperature -40 200 1 °C F4 40060B RRTD 1 - RTD #10 Temperature -40 200 1 °C F4 40060C RRTD 1 - RTD #11 Temperature -40 200 1 °C F4 40060D RRTD 1 - RTD #12 Temperature -40 200 1 °C F4 40... Reserved

RRTD 2 TEMPERATURES

0610 RRTD 2 - RTD - Hottest Stator Number 0 12 1 - F1 0

0611 RRTD 2 - RTD - Hottest Stator Temperature -40 200 1 °C F4 40

0612 RRTD 2 - RTD #1Temperature -40 200 1 °C F4 400613 RRTD 2 - RTD #2 Temperature -40 200 1 °C F4 400614 RRTD 2 - RTD #3 Temperature -40 200 1 °C F4 400615 RRTD 2 - RTD #4 Temperature -40 200 1 °C F4 400616 RRTD 2 - RTD #5 Temperature -40 200 1 °C F4 400617 RRTD 2 - RTD #6 Temperature -40 200 1 °C F4 400618 RRTD 2 - RTD #7 Temperature -40 200 1 °C F4 400619 RRTD 2 - RTD #8 Temperature -40 200 1 °C F4 40061A RRTD 2 - RTD #9 Temperature -40 200 1 °C F4 40061B RRTD 2 - RTD #10 Temperature -40 200 1 °C F4 40061C RRTD 2 - RTD #11 Temperature -40 200 1 °C F4 40061D RRTD 2 - RTD #12 Temperature -40 200 1 °C F4 40... Reserved

RRTD 3 TEMPERATURES

0620 RRTD 3 - RTD - Hottest Stator Number 0 12 1 - F1 0

0621 RRTD 3 - RTD - Hottest Stator Temperature -40 200 1 °C F4 40

0622 RRTD 3 - RTD #1 Temperature -40 200 1 °C F4 400623 RRTD 3 - RTD #2 Temperature -40 200 1 °C F4 400624 RRTD 3 - RTD #3 Temperature -40 200 1 °C F4 400625 RRTD 3 - RTD #4 Temperature -40 200 1 °C F4 400626 RRTD 3 - RTD #5 Temperature -40 200 1 °C F4 400627 RRTD 3 - RTD #6 Temperature -40 200 1 °C F4 400628 RRTD 3 - RTD #7 Temperature -40 200 1 °C F4 40




FACTORY DEFAULT



0629 RRTD 3 - RTD #8 Temperature -40 200 1 °C F4 40062A RRTD 3 - RTD #9 Temperature -40 200 1 °C F4 40062B RRTD 3 - RTD #10 Temperature -40 200 1 °C F4 40062C RRTD 3 - RTD #11 Temperature -40 200 1 °C F4 40062D RRTD 3 - RTD #12 Temperature -40 200 1 °C F4 40... Reserved

RRTD 4 TEMPERATURES

0630 RRTD 4 - RTD- Hottest Stator Number 0 12 1 - F1 0

0631 RRTD 4 - RTD- Hottest Stator Temperature -40 200 1 °C F4 40

0632 RRTD 4 - RTD#1 Temperature -40 200 1 °C F4 400633 RRTD 4 - RTD#2 Temperature -40 200 1 °C F4 400634 RRTD 4 - RTD#3 Temperature -40 200 1 °C F4 400635 RRTD 4 - RTD#4 Temperature -40 200 1 °C F4 400636 RRTD 4 - RTD#5 Temperature -40 200 1 °C F4 400637 RRTD 4 - RTD#6 Temperature -40 200 1 °C F4 400638 RRTD 4 - RTD#7 Temperature -40 200 1 °C F4 400639 RRTD 4 - RTD#8 Temperature -40 200 1 °C F4 40063A RRTD 4 - RTD#9 Temperature -40 200 1 °C F4 40063B RRTD 4 - RTD#10 Temperature -40 200 1 °C F4 40063C RRTD 4 - RTD#11 Temperature -40 200 1 °C F4 40063D RRTD 4 - RTD#12 Temperature -40 200 1 °C F4 40

LOSS OF RRTD COMMUNICATIONS063E Lost RRTD Communications alarm 0 4 1 - F123 0063F Actively Communicating RRTDs 0 15 - - F183 -

RRTD 1 ALARM STATUS0650 RRTD 1 - RTD #1 Alarm Status 0 4 1 - F123 00651 RRTD 1 - RTD #2 Alarm Status 0 4 1 - F123 00652 RRTD 1 - RTD #3 Alarm Status 0 4 1 - F123 00653 RRTD 1 - RTD #4 Alarm Status 0 4 1 - F123 00654 RRTD 1 - RTD #5 Alarm Status 0 4 1 - F123 00655 RRTD 1 - RTD #6 Alarm Status 0 4 1 - F123 00656 RRTD 1 - RTD #7 Alarm Status 0 4 1 - F123 00657 RRTD 1 - RTD #8 Alarm Status 0 4 1 - F123 00658 RRTD 1 - RTD #9 Alarm Status 0 4 1 - F123 00659 RRTD 1 - RTD #10 Alarm Status 0 4 1 - F123 0065A RRTD 1 - RTD #11 Alarm Status 0 4 1 - F123 0065B RRTD 1 - RTD #12 Alarm Status 0 4 1 - F123 0065C RRTD 1 - RTD #1 High Alarm Status 0 4 1 - F123 0065D RRTD 1 - RTD #2 High Alarm Status 0 4 1 - F123 0065E RRTD 1 - RTD #3 High Alarm Status 0 4 1 - F123 0065F RRTD 1 - RTD #4 High Alarm Status 0 4 1 - F123 00660 RRTD 1 - RTD #5 High Alarm Status 0 4 1 - F123 00661 RRTD 1 - RTD #6 High Alarm Status 0 4 1 - F123 00662 RRTD 1 - RTD #7 High Alarm Status 0 4 1 - F123 00663 RRTD 1 - RTD #8 High Alarm Status 0 4 1 - F123 00664 RRTD 1 - RTD #9 High Alarm Status 0 4 1 - F123 00665 RRTD 1 - RTD #10 High Alarm Status 0 4 1 - F123 00666 RRTD 1 - RTD #11 High Alarm Status 0 4 1 - F123 00667 RRTD 1 - RTD #12 High Alarm Status 0 4 1 - F123 0

0668 RRTD 1 - Broken / Open RTD Alarm Status 0 4 1 - F123 0

0669 RRTD 1 - Short / Low Temp Alarm Status 0 1 1 - F123 0




FACTORY DEFAULT



066A RRTD 1 - Digital Input 6 Alarm Status 0 4 1 - F123 0066B RRTD 1 - Digital Input 2 Alarm Status 0 4 1 - F123 0066C RRTD 1 - Digital Input 5 Alarm Status 0 4 1 - F123 0066D RRTD 1 - Digital Input 4 Alarm Status 0 4 1 - F123 0066E RRTD 1 - Digital Input 1 Alarm Status 0 4 1 - F123 0066F RRTD 1 - Digital Input 3 Alarm Status 0 4 1 - F123 0

RRTD 2 ALARM STATUS0670 RRTD 2 - RTD #1 Alarm Status 0 4 1 - F123 00671 RRTD 2 - RTD #2 Alarm Status 0 4 1 - F123 00672 RRTD 2 - RTD #3 Alarm Status 0 4 1 - F123 00673 RRTD 2 - RTD #4 Alarm Status 0 4 1 - F123 00674 RRTD 2 - RTD #5 Alarm Status 0 4 1 - F123 00675 RRTD 2 - RTD #6 Alarm Status 0 4 1 - F123 00676 RRTD 2 - RTD #7 Alarm Status 0 4 1 - F123 00677 RRTD 2 - RTD #8 Alarm Status 0 4 1 - F123 00678 RRTD 2 - RTD #9 Alarm Status 0 4 1 - F123 00679 RRTD 2 - RTD #10 Alarm Status 0 4 1 - F123 0067A RRTD 2 - RTD #11 Alarm Status 0 4 1 - F123 0067B RRTD 2 - RTD #12 Alarm Status 0 4 1 - F123 0067C RRTD 2 - RTD #1 High Alarm Status 0 4 1 - F123 0067D RRTD 2 - RTD #2 High Alarm Status 0 4 1 - F123 0067E RRTD 2 - RTD #3 High Alarm Status 0 4 1 - F123 0067F RRTD 2 - RTD #4 High Alarm Status 0 4 1 - F123 00680 RRTD 2 - RTD #5 High Alarm Status 0 4 1 - F123 00681 RRTD 2 - RTD #6 High Alarm Status 0 4 1 - F123 00682 RRTD 2 - RTD #7 High Alarm Status 0 4 1 - F123 00683 RRTD 2 - RTD #8 High Alarm Status 0 4 1 - F123 00684 RRTD 2 - RTD #9 High Alarm Status 0 4 1 - F123 00685 RRTD 2 - RTD #10 High Alarm Status 0 4 1 - F123 00686 RRTD 2 - RTD #11 High Alarm Status 0 4 1 - F123 00687 RRTD 2 - RTD #12 High Alarm Status 0 4 1 - F123 0

0688 RRTD 2 - Broken / Open RTD Alarm Status 0 4 1 - F123 0

0689 RRTD 2 - Short / Low Temp Alarm Status 0 1 1 - F123 0

068A RRTD 2 - Digital Input 6 Alarm Status 0 4 1 - F123 0068B RRTD 2 - Digital Input 2 Alarm Status 0 4 1 - F123 0068C RRTD 2 - Digital Input 5 Alarm Status 0 4 1 - F123 0068D RRTD 2 - Digital Input 4 Alarm Status 0 4 1 - F123 0068E RRTD 2 - Digital Input 1 Alarm Status 0 4 1 - F123 0068F RRTD 2 - Digital Input 3 Alarm Status 0 4 1 - F123 0

RRTD 3 ALARM STATUS0690 RRTD 3 - RTD #1 Alarm Status 0 4 1 - F123 00691 RRTD 3 - RTD #2 Alarm Status 0 4 1 - F123 00692 RRTD 3 - RTD #3 Alarm Status 0 4 1 - F123 00693 RRTD 3 - RTD #4 Alarm Status 0 4 1 - F123 00694 RRTD 3 - RTD #5 Alarm Status 0 4 1 - F123 00695 RRTD 3 - RTD #6 Alarm Status 0 4 1 - F123 00696 RRTD 3 - RTD #7 Alarm Status 0 4 1 - F123 00697 RRTD 3 - RTD #8 Alarm Status 0 4 1 - F123 00698 RRTD 3 - RTD #9 Alarm Status 0 4 1 - F123 00699 RRTD 3 - RTD #10 Alarm Status 0 4 1 - F123 0069A RRTD 3 - RTD #11 Alarm Status 0 4 1 - F123 0069B RRTD 3 - RTD #12 Alarm Status 0 4 1 - F123 0




FACTORY DEFAULT



069C RRTD 3 - RTD #1 High Alarm Status 0 4 1 - F123 0069D RRTD 3 - RTD #2 High Alarm Status 0 4 1 - F123 0069E RRTD 3 - RTD #3 High Alarm Status 0 4 1 - F123 0069F RRTD 3 - RTD #4 High Alarm Status 0 4 1 - F123 006A0 RRTD 3 - RTD #5 High Alarm Status 0 4 1 - F123 006A1 RRTD 3 - RTD #6 High Alarm Status 0 4 1 - F123 006A2 RRTD 3 - RTD #7 High Alarm Status 0 4 1 - F123 006A3 RRTD 3 - RTD #8 High Alarm Status 0 4 1 - F123 006A4 RRTD 3 - RTD #9 High Alarm Status 0 4 1 - F123 006A5 RRTD 3 - RTD #10 High Alarm Status 0 4 1 - F123 006A6 RRTD 3 - RTD #11 High Alarm Status 0 4 1 - F123 006A7 RRTD 3 - RTD #12 High Alarm Status 0 4 1 - F123 0

06A8 RRTD 3 - Broken / Open RTD Alarm Status 0 4 1 - F123 0

06A9 RRTD 3 - Short / Low Temp Alarm Status 0 1 1 - F123 0

06AA RRTD 3 - Digital Input 6 Alarm Status 0 4 1 - F123 006AB RRTD 3 - Digital Input 2 Alarm Status 0 4 1 - F123 006AC RRTD 3 - Digital Input 5 Alarm Status 0 4 1 - F123 006AD RRTD 3 - Digital Input 4 Alarm Status 0 4 1 - F123 006AE RRTD 3 - Digital Input 1 Alarm Status 0 4 1 - F123 006AF RRTD 3 - Digital Input 3 Alarm Status 0 4 1 - F123 0

RRTD 4 ALARM STATUS06B0 RRTD 4 - RTD #1 Alarm Status 0 4 1 - F123 006B1 RRTD 4 - RTD #2 Alarm Status 0 4 1 - F123 006B2 RRTD 4 - RTD #3 Alarm Status 0 4 1 - F123 006B3 RRTD 4 - RTD #4 Alarm Status 0 4 1 - F123 006B4 RRTD 4 - RTD #5 Alarm Status 0 4 1 - F123 006B5 RRTD 4 - RTD #6 Alarm Status 0 4 1 - F123 006B6 RRTD 4 - RTD #7 Alarm Status 0 4 1 - F123 006B7 RRTD 4 - RTD #8 Alarm Status 0 4 1 - F123 006B8 RRTD 4 - RTD #9 Alarm Status 0 4 1 - F123 006B9 RRTD 4 - RTD #10 Alarm Status 0 4 1 - F123 006BA RRTD 4 - RTD #11 Alarm Status 0 4 1 - F123 006BB RRTD 4 - RTD #12 Alarm Status 0 4 1 - F123 006BC RRTD 4 - RTD #1 High Alarm Status 0 4 1 - F123 006BD RRTD 4 - RTD #2 High Alarm Status 0 4 1 - F123 006BE RRTD 4 - RTD #3 High Alarm Status 0 4 1 - F123 006BF RRTD 4 - RTD #4 High Alarm Status 0 4 1 - F123 006C0 RRTD 4 - RTD #5 High Alarm Status 0 4 1 - F123 006C1 RRTD 4 - RTD #6 High Alarm Status 0 4 1 - F123 006C2 RRTD 4 - RTD #7 High Alarm Status 0 4 1 - F123 006C3 RRTD 4 - RTD #8 High Alarm Status 0 4 1 - F123 006C4 RRTD 4 - RTD #9 High Alarm Status 0 4 1 - F123 006C5 RRTD 4 - RTD #10 High Alarm Status 0 4 1 - F123 006C6 RRTD 4 - RTD #11 High Alarm Status 0 4 1 - F123 006C7 RRTD 4 - RTD #12 High Alarm Status 0 4 1 - F123 0

06C8 RRTD 4 - Broken / Open RTD Alarm Status 0 4 1 - F123 0

06C9 RRTD 4 - Short / Low Temp Alarm Status 0 1 1 - F123 0

06CA RRTD 4 - Digital Input 6 Alarm Status 0 4 1 - F123 006CB RRTD 4 - Digital Input 2 Alarm Status 0 4 1 - F123 006CC RRTD 4 - Digital Input 5 Alarm Status 0 4 1 - F123 006CD RRTD 4 - Digital Input 4 Alarm Status 0 4 1 - F123 0




FACTORY DEFAULT



06CE RRTD 4 - Digital Input 1 Alarm Status 0 4 1 - F123 006CF RRTD 4 - Digital Input 3 Alarm Status 0 4 1 - F123 0

RRTD 1 MAXIMUM TEMPERATURES0700 RRTD 1 - RTD # 1 Max. Temperature -40 200 1 °C F4 400701 RRTD 1 - RTD # 2 Max. Temperature -40 200 1 °C F4 400702 RRTD 1 - RTD # 3 Max. Temperature -40 200 1 °C F4 400703 RRTD 1 - RTD # 4 Max. Temperature -40 200 1 °C F4 400704 RRTD 1 - RTD # 5 Max. Temperature -40 200 1 °C F4 400705 RRTD 1 - RTD # 6 Max. Temperature -40 200 1 °C F4 400706 RRTD 1 - RTD # 7 Max. Temperature -40 200 1 °C F4 400707 RRTD 1 - RTD # 8 Max. Temperature -40 200 1 °C F4 400708 RRTD 1 - RTD # 9 Max. Temperature -40 200 1 °C F4 400709 RRTD 1 - RTD # 10 Max. Temperature -40 200 1 °C F4 40070A RRTD 1 - RTD # 11 Max. Temperature -40 200 1 °C F4 40070B RRTD 1 - RTD # 12 Max. Temperature -40 200 1 °C F4 40... Reserved



RRTD 4 MAXIMUM TEMPERATURES0730 RRTD 4 - RTD # 1 Max. Temperature -40 200 1 °C F4 400731 RRTD 4 - RTD # 2 Max. Temperature -40 200 1 °C F4 400732 RRTD 4 - RTD # 3 Max. Temperature -40 200 1 °C F4 400733 RRTD 4 - RTD # 4 Max. Temperature -40 200 1 °C F4 400734 RRTD 4 - RTD # 5 Max. Temperature -40 200 1 °C F4 400735 RRTD 4 - RTD # 6 Max. Temperature -40 200 1 °C F4 400736 RRTD 4 - RTD # 7 Max. Temperature -40 200 1 °C F4 400737 RRTD 4 - RTD # 8 Max. Temperature -40 200 1 °C F4 400738 RRTD 4 - RTD # 9 Max. Temperature -40 200 1 °C F4 40




FACTORY DEFAULT



0739 RRTD 4 - RTD # 10 Max. Temperature -40 200 1 °C F4 40073A RRTD 4 - RTD # 11 Max. Temperature -40 200 1 °C F4 40073B RRTD 4 - RTD # 12 Max. Temperature -40 200 1 °C F4 40... Reserved

RRTD 1 TRIP COUNTER0800 RRTD 1 - Stator RTD Trips 0 50000 1 - F1 00801 RRTD 1 - Bearing RTD Trips 0 50000 1 - F1 00802 RRTD 1 - Other RTD Trips 0 50000 1 - F1 00803 RRTD 1 - Ambient RTD Trips 0 50000 1 - F1 00804 RRTD 1 - Digital Input Trips 0 50000 1 - F1 0... Reserved




RRTD 1 DIGITAL INPUT STATUS0840 Digital Input 3 0 1 1 - F131 00841 Digital Input 4 0 1 1 - F131 00842 Digital Input 6 0 1 1 - F131 00843 Digital Input 5 0 1 1 - F131 00844 Digital Input 2 0 1 1 - F131 00845 Digital Input 1 0 1 1 - F131 0... Reserved


RRTD 3 DIGITAL INPUT STATUS0860 Digital Input 3 0 1 1 - F131 00861 Digital Input 4 0 1 1 - F131 00862 Digital Input 6 0 1 1 - F131 00863 Digital Input 5 0 1 1 - F131 00864 Digital Input 2 0 1 1 - F131 0




FACTORY DEFAULT



0865 Digital Input 1 0 1 1 - F131 0... Reserved


RRTD 1 OUTPUT RELAY STATUS0880 RRTD 1 - Trip 0 2 1 N/A F150 20881 RRTD 1 - Alarm 0 2 1 N/A F150 20882 RRTD 1 - Aux. 1 0 2 1 N/A F150 20883 RRTD 1 - Aux. 2 0 2 1 N/A F150 2

RRTD 1 DIGITAL INPUT AND OUTPUT RELAY STATUS

0884 RRTD1 Digital Input & Output Relay Status N/A N/A N/A N/A F193 0

... ReservedRRTD 2 OUTPUT RELAY STATUS

0890 RRTD 2 - Trip 0 2 1 N/A F150 20891 RRTD 2 - Alarm 0 2 1 N/A F150 20892 RRTD 2 - Aux. 1 0 2 1 N/A F150 20893 RRTD 2 - Aux. 2 0 2 1 N/A F150 2


0894 RRTD2 Digital Input & Output Relay Status N/A N/A N/A N/A F193 0


08A0 RRTD 3 - Trip 0 2 1 N/A F150 208A1 RRTD 3 - Alarm 0 2 1 N/A F150 208A2 RRTD 3 - Aux. 1 0 2 1 N/A F150 208A3 RRTD 3 - Aux. 2 0 2 1 N/A F150 2


08A4 RRTD3 Digital Input & Output Relay Status N/A N/A N/A N/A F193 0


08B0 RRTD 4 - Trip 0 2 1 N/A F150 208B1 RRTD 4 - Alarm 0 2 1 N/A F150 208B2 RRTD 4 - Aux. 1 0 2 1 N/A F150 208B3 RRTD 4 - Aux. 2 0 2 1 N/A F150 2


08B4 RRTD4 Digital Input & Output Relay Status N/A N/A N/A N/A F193 0

... ReservedCOMMUNICATIONS MODULE

08C0 Ethernet Module Status 0 65535 1 N/A F164 -08C1 Fieldbus Module Software Revision - - - - F16 -... Reserved

PROTECTION FUNCTION BLOCKING

08D0 Protection Functions Currently Blocked 0 256 1 N/A F180 0

... Reserved




FACTORY DEFAULT



SETPOINTS (ADDRESSES 1000 TO 1FFF)DISPLAY PREFERENCES

1000 Default Message Cycle Time 5 100 1 s F1 201001 Default Message Timeout 10 900 1 s F1 3001002 Reserved1003 Flash Message 1 10 1 s F1 21004 Temperature Display Units 0 1 1 - F100 01005 Energy Unit Display 0 1 1 - F166 0... Reserved

EVENT RECORDS1006 Motor Running Events 0 1 1 - F103 01007 Motor Stopped Events 0 1 1 - F103 0

WAVEFORM CAPTURE1008 Trigger Position 0 100 1 % F1 20... Reserved

369 COMMUNICATIONS100F Reset Fieldbus Comms Interface 0 1 1 - F103 01010 Slave Address 1 254 1 - F1 2541011 Computer RS232 Baud Rate 0 4 1 - F101 41012 Computer RS232 Parity 0 2 1 - F102 01013 Channel 1 Parity 0 2 1 - F102 01014 Channel 1 Baud Rate 0 4 1 - F101 41015 Channel 2 Parity 0 2 1 - F102 01016 Channel 2 Baud Rate 0 4 1 - F101 41017 Channel 3 Parity 0 2 1 - F102 01018 Channel 3 Baud Rate 0 4 1 - F101 41019 Channel 3 Connection 0 1 1 - F151 0101A Channel 3 Application 0 1 1 - F149 0101B Profibus Slave Address 1 126 1 - F1 125101C IP Address Octet 1 0 255 1 - F1 127101D IP Address Octet 2 0 255 1 - F1 0101E IP Address Octet 3 0 255 1 - F1 0101F IP Address Octet 4 0 255 1 - F1 11020 Subnet Mask Octet 1 0 255 1 - F1 2551021 Subnet Mask Octet 2 0 255 1 - F1 2551022 Subnet Mask Octet 3 0 255 1 - F1 2551023 Subnet Mask Octet 4 0 255 1 - F1 01024 Gateway Address Octet 1 0 255 1 - F1 1271025 Gateway Address Octet 2 0 255 1 - F1 01026 Gateway Address Octet 3 0 255 1 - F1 01027 Gateway Address Octet 4 0 255 1 - F1 11028 DeviceNet MAC ID 0 63 1 - F1 631029 DeviceNet Baud Rate 0 2 1 - F170 0... Reserved

REAL TIME CLOCK1030 Date (2 words) valid date N/A - F18 -1034 Time (2 words) valid time N/A - F19 -... Reserved

DEFAULT MESSAGES1041 Default to Current Metering 0 1 1 - F103 01042 Default to Motor Load 0 1 1 - F103 01043 Default to Delta Voltage Metering 0 1 1 - F103 01044 Default to Power Factor 0 1 1 - F103 01045 Default to Positive Watthours 0 1 1 - F103 0




FACTORY DEFAULT



1046 Default to Real Power 0 1 1 - F103 01047 Default to Reactive Power 0 1 1 - F103 01048 Default to Hottest Stator RTD 0 1 1 - F103 01049 Default to Text Message 1 0 1 1 - F103 0104A Default to Text Message 2 0 1 1 - F103 0104B Default to Text Message 3 0 1 1 - F103 0104C Default to Text Message 4 0 1 1 - F103 0104D Default to Text Message 5 0 1 1 - F103 0

104E Default to Hottest Stator RTD Temperature 0 1 1 - F103 0

104F Default to Unbalace Biased Motor Load 0 1 1 - F103 0

... Reserved - - - - - -

MESSAGE SCRATCHPAD

1060 1st & 2nd Character of 1st Scratchpad Message 32 127 1 - F1 ’T’

↓ ↓

1073 39th & 40th Character of 1st Scratchpad Message 32 127 1 - F1 " "

1074 1st & 2nd Character of 2nd Scratchpad Message 32 127 1 - F1 ’T’

↓ ↓

1087 39th & 40th Character of 2nd Scratchpad Message 32 127 1 - F1 " "

1088 1st & 2nd Character of 3rd Scratchpad Message 32 127 1 - F1 ’T’

↓ ↓

109B 39th & 40th Character of 3rd Scratchpad Message 32 127 1 - F1 " "

109C 1st & 2nd Character of 4th Scratchpad Message 32 127 1 - F1 ’T’

↓ ↓

10AF 39th & 40th Character of 4th Scratchpad Message 32 127 1 - F1 " "

10B0 1st & 2nd Character of 5th Scratchpad Message 32 127 1 - F1 ’T’

↓ ↓

10C3 39th & 40th Character of 5th Scratchpad Message 32 127 1 - F1 " "

... Reserved

CLEAR PRESET DATA1130 Clear Last Trip Data 0 1 1 - F103 01131 Clear Peak Demand Data 0 1 1 - F103 01132 Clear RTD Maximums 0 1 1 - F103 01133 Preset Positive MWh 0 65535 1 MWh F1 01134 Clear Trip Counters 0 1 1 - F103 01135 Preset Digital Counter 0 65535 1 - F1 01136 Clear Event Records 0 1 1 - F103 01137 Preset Positive Mvarh 0 65535 1 Mvarh F1 01138 Preset Negative Mvarh 0 65535 1 Mvarh F1 01139 Preset Number Of Motor Starts 0 50000 1 - F1 0

113A Preset Number Of Emergency Restarts 0 50000 1 - F1 0

113B Preset Motor Running Hours 0 65535 1 - F1 0113C Preset Autorestart Start Attempts 0 50000 1 - F1 0... Reserved1140 Clear Motor Data 0 1 1 - F103 01141 Reserved - - - - - -




FACTORY DEFAULT



1142 Clear All Data 0 1 1 - F103 01143 RRTD 1 - Preset Digital Counter 0 65535 1 - F1 01144 RRTD 2 - Preset Digital Counter 0 65535 1 - F1 01145 RRTD 3 - Preset Digital Counter 0 65535 1 - F1 01146 RRTD 4 - Preset Digital Counter 0 65535 1 - F1 01147 Clear Energy Data 0 1 1 - F103 0... Reserved

CT/VT SETUP1180 Phase CT Primary 1 5000 1 A F1 5001181 Motor Full Load Amps 1 5000 1 A F1 101182 Ground CT Type 0 3 1 - F104 21183 Ground CT Primary 1 5000 1 A F1 100... Reserved1190 Enable Two Speed Motor Protection 0 1 1 N/A F103 01191 Speed 2 Phase CT Primary 1 5000 1 A F1 50001192 Speed 2 Motor Full Load Amps 1 5000 1 A F1 10... Reserved

11A0 Voltage Transformer Connection Type 0 2 1 - F106 0

11A1 Voltage Transformer Ratio 100 24000 1 - F3 3511A2 Motor Rated Voltage 100 20000 1 V F1 4160... Reserved11C0 Nominal Frequency 0 2 1 - F107 011C1 System Phase Sequence 0 1 1 - F124 011C2 Speed 2 System Phase Sequence 0 1 1 - F124 0... Reserved

SERIAL COMM CONTROL11C8 Serial Communication Control 0 1 1 - F103 011C9 Assign Start Control Relays 0 7 1 - F113 2... Reserved

REDUCED VOLTAGE11CF Start Control Relay Timer 10 100 5 s F2 1011D0 Reduced Voltage Starting 0 1 1 - F103 011D1 Assign Start Control Relays 0 7 1 - F113 411D2 Transition On 0 2 1 - F108 011D3 Incomplete Sequence Trip Relays 0 6 1 - F111 011D4 Reduced Voltage Start Level 25 300 1 % FLA F1 10011D5 Reduced Voltage Start Timer 1 500 1 s F1 200

AUTORESTART11D6 Autorestart 0 1 1 - F103 011D7 Total Restarts 0 65000 1 starts F1 111D8 Restart Delay 0 20000 1 sec. F1 6011D9 Progressive Delay 0 20000 1 sec. F1 011DA Hold Delay 0 20000 1 sec. F1 011DB Bus Valid 0 1 1 - F103 011DC Bus Valid Level 15 100 1 %VT F1 10011DD Reserved - - - - - -11DE Autorestart Attempt Events 0 1 1 - F103 011DF Autorestart Success Events 0 1 1 - F103 011E0 Autorestart Aborted Events 0 1 1 - F103 0... Reserved

UNDERVOLTAGE AUTORESTART11F0 Enable UVR 0 1 1 - F30 0 (Off)11F1 UVR Pickup Level 50 100 1 x RATED F3 65




FACTORY DEFAULT



11F2 UVR Assign Trip Relays 0 7 1 - F111 011F3 UVR Trip Delay 0 2550 1 x 0.1s F2 011F4 UVR Restoration Level 50 100 1 x RATED F3 9011F5 Immediate Restart Power Loss Time 0 500 100 ms F1 0 (Off)11F6 Delay1 Restart Power Loss Time 0 100 1 x 0.1s F2 0 (Off)

11F7 Delay2 Restart Power Loss Time 0 3601 1 s F1 (3601=Unlimited) 0 (Off)

11F8 Delay1 Restart Time Delay 0 12000 2 x 0.1s F2 2011F9 Delay2 Restart Time Delay 0 12000 2 x 0.1s F2 10011FA UVR Setup Time 0 12000 1 x 0.1s F2 100

DIGITAL COUNTER12E6 First Character of Counter Name 32 127 1 - F1 “G”

12F2 First Character of Counter Unit Name 32 127 1 - F1 ‘U’

12F8 Counter Type 0 1 1 - F114 012F9 Digital Counter Alarm 0 2 1 - F115 012FA Assign Alarm Relays 0 6 1 - F113 012FB Counter Alarm Level 0 65535 1 - F1 10012FD Reserved - - - - - -12FE Record Alarms as Events 0 1 1 - F103 0

EMERGENCY

1330 1st & 2nd Character of Emergency Switch Name 32 127 1 - F22 ’G’

1340 General Emergency Switch Type 0 1 1 - F116 0

1341 General Emergency Switch Block Input From Start 0 5000 1 s F1 0

1342 General Emergency Switch Alarm 0 2 1 - F115 0

1343 General Emergency Switch Alarm Relays 0 6 1 - F113 0

1344 General Emergency Switch Alarm Delay 1 50000 1 100ms F2 50

1345 General Emergency Switch Alarm Events 0 1 1 - F103 0

1346 General Emergency Switch Trip 0 2 1 - F115 0

1347 General Emergency Switch Trip Relays 0 6 1 - F111 0

1348 General Emergency Switch Trip Delay 1 50000 1 100ms F2 50

1349 Emergency Switch Assignable Function 0 7 1 - F110 0

... ReservedDIFFERENTIAL

1370 1st & 2nd Character of Differential Switch Name 32 127 1 - F22 ’G’

1380 General Differential Switch Type 0 1 1 - F116 0

1381 General Differential Switch Block Input From Start 0 5000 1 s F1 0

1382 General Differential Switch Alarm 0 2 1 - F115 0

1383 General Differential Switch Alarm Relays 0 7 1 - F113 1

1384 General Differential Switch Alarm Delay 1 50000 1 100ms F2 50

1385 General Differential Switch Alarm Events 0 1 1 - F103 0

1386 General Differential Switch Trip 0 2 1 - F115 0

1387 General Differential Switch Trip Relays 0 7 1 - F111 1

1388 General Differential Switch Trip Delay 1 50000 1 100ms F2 50




FACTORY DEFAULT



1389 Differential Switch Assignable Function 0 7 1 - F157 0

138A Assign Differential Switch Trip Relays 0 7 1 - F111 1... Reserved

SPEED

13A0 1st & 2nd Character of Speed Switch Name 32 127 1 - F22 ’G’

13B0 General Speed Switch Type 0 1 1 - F116 0

13B1 General Speed Switch Block Input from Start 0 5000 1 s F1 0

13B2 General Speed Switch Alarm 0 2 1 - F115 013B3 General Speed Switch Alarm Relays 0 7 1 - F113 113B4 General Speed Switch Alarm Delay 1 50000 1 100ms F2 5013B5 General Speed Switch Alarm Events 0 1 1 - F103 013B6 General Speed Switch Trip 0 2 1 - F115 013B7 General Speed Switch Trip Relays 0 7 1 - F111 113B8 General Speed Switch Trip Delay 1 50000 1 100ms F2 5013B9 Speed Switch Assignable Function 0 7 1 - F158 013BA Speed Switch Delay 5 1000 5 100ms F2 2013BB Assign Speed Switch Trip Relays 0 7 1 - F111 1... Reserved

RESET

13D0 1st & 2nd Character of Reset Switch Name 32 127 1 - F22 ’G’

13E0 General Reset Switch Type 0 1 1 - F116 0

13E1 General Reset Switch Block Input From Start 0 5000 1 s F1 0

13E2 General Reset Switch Alarm 0 2 1 - F115 013E3 General Reset Switch Alarm Relays 0 7 1 - F113 113E4 General Reset Switch Alarm Delay 1 50000 1 100ms F2 5013E5 General Reset Switch Alarm Events 0 1 1 - F103 013E6 General Reset Switch Trip 0 2 1 - F115 013E7 General Reset Switch Trip Relays 0 7 1 - F111 113E8 General Reset Switch Trip Delay 1 50000 1 100ms F2 5013E9 Reset Switch Assignable Function 0 7 1 - F160 0... Reserved

SPARE

1400 1st & 2nd Character of Spare Switch Name 32 127 1 - F22 ’G’

1410 General Spare Switch Type 0 1 1 - F116 0

1411 General Spare Switch Block Input From Start 0 5000 1 s F1 0

1412 General Spare Switch Alarm 0 2 1 - F115 01413 General Spare Switch Alarm Relays 0 7 1 - F113 11414 General Spare Switch Alarm Delay 1 50000 1 100ms F2 501415 General Spare Switch Alarm Events 0 1 1 - F103 01416 General Spare Switch Trip 0 1 1 - F115 01417 General Spare Switch Trip Relays 0 7 1 - F111 11418 General Spare Switch Trip Delay 1 50000 1 100 ms F2 501419 Spare Switch Assignable Function 0 7 1 - F159 0141A Starter Aux Contact Type 0 1 1 - F109 0

141B Starter Operation Monitor Delay Time 0 60 1 seconds F1 0 (Off)

141C Starter Operation Monitor Type 0 2 1 - F115 0 (Off)141D Starter Operation Monitor Relays 0 15 1 - F169 0 (None)... Reserved




FACTORY DEFAULT



OUTPUT RELAY SETUP1500 Trip Relay Reset Mode 0 2 1 - F117 01501 Alarm Relay Reset Mode 0 2 1 - F117 01502 Aux 1 Relay Reset Mode 0 2 1 - F117 01503 Aux 2 Relay Reset Mode 0 2 1 - F117 01504 Trip Relay Operation 0 1 1 - F161 01505 Alarm Relay Operation 0 1 1 - F161 11506 Aux1 Relay Operation 0 1 1 - F161 11507 Aux2 Relay Operation 0 1 1 - F161 0... Reserved

FORCE OUTPUT RELAYS

1510 Assign Communications Force Relays 0 15 1 N/A F169 0

1511 Trip Communications Force Relay Output Type 0 1 1 - F181 0

1512 Trip Pulsed Output Dwell Time 5 50000 1 100 ms F2 5

1513 Alarm Communications Force Relay Output Type 0 1 1 - F181 0

1514 Alarm Pulsed Output Dwell Time 5 50000 1 100 ms F2 5

1515 Aux1 Communications Force Relay Output Type 0 1 1 - F181 0

1516 Aux1 Pulsed Output Dwell Time 5 50000 1 100 ms F2 5

1517 Aux2 Communications Force Relay Output Type 0 1 1 - F181 0

1518 Aux2 Pulsed Output Dwell Time 5 50000 1 100 ms F2 5... Reserved

PROTECTION FUNCTION BLOCKING1520 Log Blocking Events 0 1 1 N/A F30 01521 Block Undercurrent/Underpower 0 1 1 N/A F30 01522 Block Current Unbalance 0 1 1 N/A F30 01523 Block Incomplete Sequence 0 1 1 N/A F30 01524 Block Thermal Model 0 1 1 N/A F30 01525 Block Short Circuit and Backup 0 1 1 N/A F30 01526 Block Overload Alarm 0 1 1 N/A F30 01527 Block Ground Fault 0 1 1 N/A F30 0

1528 Block Starts Per Hour and Time Between Starts 0 1 1 N/A F30 0

... Reserved

THERMAL MODEL (0 = Off)1581 Overload Pickup Level 101 125 1 0.01xFLA F3 1011582 Assign Thermal Capacity Trip Relay 0 7 1 - F111 11583 Unbalance k Factor (0=Learned) 0 29 1 - F1 01584 Running Cool Time Constant 1 500 1 min F1 151585 Stopped Cool Time Constant 1 500 1 min F1 301586 Hot/Cold Safe Stall Ratio 1 100 1 - F3 1001587 RTD Biasing 0 1 1 - F103 01588 RTD Bias Minimum 0 198 1 °C F1 401589 RTD Bias Mid Point 0 199 1 °C F1 120158A RTD Bias Maximum 0 200 1 °C F1 155158B Thermal Capacity Alarm 0 2 1 - F115 0

158C Assign Thermal Capacity Alarm Relays 0 7 1 - F113 1

158D Thermal Capacity Alarm Level 1 100 1 % used F1 75158E Thermal Capacity Alarm Events 0 1 1 - F103 0158F Enable Learned Cool Time 0 1 1 - F103 01590 Enable Unbalance Biasing 0 1 1 - F103 0




FACTORY DEFAULT



1591 Motor Load Averaging Interval 3 60 3 cycles F1 3... Reserved15AE Select Curve Style 0 1 1 - F128 0

O/L CURVE SETUP15AF Standard Overload Curve Number 1 15 1 - F1 415B0 Time to Trip at 1.01 x FLA 0 65534 1 s F1 1741515B2 Time to Trip at 1.05 x FLA 0 65534 1 s F1 341515B4 Time to Trip at 1.10 x FLA 0 65534 1 s F1 166715B6 Time to Trip at 1.20 x FLA 0 65534 1 s F1 79515B8 Time to Trip at 1.30 x FLA 0 65534 1 s F1 50715BA Time to Trip at 1.40 x FLA 0 65534 1 s F1 36515BC Time to Trip at 1.50 x FLA 0 65534 1 s F1 28015BE Time to Trip at 1.75 x FLA 0 65534 1 s F1 17015C0 Time to Trip at 2.00 x FLA 0 65534 1 s F1 11715C2 Time to Trip at 2.25 x FLA 0 65534 1 s F1 8615C4 Time to Trip at 2.50 x FLA 0 65534 1 s F1 6715C6 Time to Trip at 2.75 x FLA 0 65534 1 s F1 5315C8 Time to Trip at 3.00 x FLA 0 65534 1 s F1 4415CA Time to Trip at 3.25 x FLA 0 65534 1 s F1 3715CC Time to Trip at 3.50 x FLA 0 65534 1 s F1 3115CE Time to Trip at 3.75 x FLA 0 65534 1 s F1 2715D0 Time to Trip at 4.00 x FLA 0 65534 1 s F1 2315D2 Time to Trip at 4.25 x FLA 0 65534 1 s F1 2115D4 Time to Trip at 4.50 x FLA 0 65534 1 s F1 1815D6 Time to Trip at 4.75 x FLA 0 65534 1 s F1 1615D8 Time to Trip at 5.00 x FLA 0 65534 1 s F1 1515DA Time to Trip at 5.50 x FLA 0 65534 1 s F1 1215DC Time to Trip at 6.00 x FLA 0 65534 1 s F1 1015DE Time to Trip at 6.50 x FLA 0 65534 1 s F1 915E0 Time to Trip at 7.00 x FLA 0 65534 1 s F1 715E2 Time to Trip at 7.50 x FLA 0 65534 1 s F1 615E4 Time to Trip at 8.00 x FLA 0 65534 1 s F1 615E6 Time to Trip at 10.0 x FLA 0 65534 1 s F1 615E8 Time to Trip at 15.0 x FLA 0 65534 1 s F1 615EA Time to Trip at 20.0 x FLA 0 65534 1 s F1 6... Reserved

SHORT CIRCUIT TRIP (0 = INSTANTANEOUS TIME DELAY)1640 Short Circuit Trip 0 1 1 - F115 01641 Reserved1642 Assign Short Circuit Trip Relays 0 7 1 - F111 11643 Short Circuit Trip Level 20 200 1 × CT F2 1001644 Short Circuit Trip Delay 0 255.00 0.01 s F3 01645 Short Circuit Trip Backup 0 2 1 - F115 01646 Assign Short Circuit Backup Relays 0 3 1 - F119 11647 Add Short Circuit Trip Backup Delay 0 25500 0.01 s F3 20... Reserved

OVERLOAD ALARM1650 Overload Alarm 0 2 1 - F115 0

1651 Overload Alarm Level 101 150 1 0.01 × FLA F3 101

1652 Assign Overload Alarm Relays 0 7 1 - F113 11653 Overload Alarm Delay 0 600 1 s F2 101654 Overload Alarm Events 0 1 1 - F103 0... Reserved




FACTORY DEFAULT



MECHANICAL JAM1660 Mechanical Jam Alarm 0 2 1 - F115 01661 Assign Alarm Relays 0 7 1 - F113 1

1662 Mechanical Jam Alarm Level 101 600 1 0.01 × FLA F3 150

1663 Mechanical Jam Alarm Delay 5 1250 5 s F2 101664 Mechanical Jam Alarm Events 0 1 1 - F103 01665 Mechanical Jam Trip 0 2 1 - F115 01666 Assign Trip Relays 0 7 1 - F111 1

1667 Mechanical Jam Trip Level 101 600 1 0.01 × FLA F3 150

1668 Mechanical Jam Trip Delay 5 1250 5 s F2 10... Reserved - - - - - -

UNDERCURRENT1670 Block Undercurrent from Start 0 15000 1 s F1 01671 Undercurrent Alarm 0 2 1 - F115 01672 Assign Undercurrent Alarm Relays 0 7 1 - F113 1

1673 Undercurrent Alarm Level 10 99 1 0.01 × FLA F3 70

1674 Undercurrent Alarm Delay 1 255 1 s F1 11675 Undercurrent Alarm Events 0 1 1 - F103 01676 Undercurrent Trip 0 2 1 - F115 01677 Assign Undercurrent Trip Relays 0 7 1 - F111 1

1678 Undercurrent Trip Level 10 99 1 0.01 × FLA F3 70

1679 Undercurrent Trip Delay 1 255 1 s F1 1... Reserved

CURRENT UNBALANCE1680 Block Unbalance From Start 0 5000 1 s F1 01681 Current Unbalance Alarm 0 2 1 - F115 01682 Assign Unbalance Alarm Relays 0 7 1 - F113 11683 Unbalance Alarm Level 4 30 1 % F1 151684 Unbalance Alarm Delay 1 255 1 s F1 11685 Unbalance Alarm Events 0 1 1 - F103 01686 Current Unbalance Trip 0 2 1 - F115 01687 Assign Unbalance Trip Relays 0 7 1 - F111 11688 Unbalance Trip Level 4 30 1 % F1 201689 Unbalance Trip Delay 1 255 1 s F1 1... Reserved

GROUND FAULT16A1 Ground Fault Alarm 0 2 1 - F115 016A2 Assign Ground Fault Alarm Relays 0 7 1 - F113 116A3 Ground Fault Alarm Pickup 10 100 1 0.1 × CT F3 10

16A4 GF Alarm Pickup for GE Multilin 50:0.025 CT 25 2500 1 Amps F3 25

16A5 Ground Fault Alarm Delay 0.00 255.00 0.01 s F3 016A6 Ground Fault Alarm Events 0 1 1 - F103 016A7 Ground Fault Trip 0 2 1 - F 115 016A8 Assign Ground Fault Trip Relays 0 7 1 - F 111 116A9 Ground Fault Trip Pickup 10 100 1 0.1 × CT F3 20

16AA GF Trip Pickup for GE Multilin 50:0.025 CT 25 2500 1 0.1 × CT F3 25

16AB Ground Fault Trip Delay 0.00 255.00 0.01 s F3 016AC Ground Fault Trip Backup 0 1 1 - F115 016AD Ground Fault Trip Backup Relays 0 3 1 - F119 33




FACTORY DEFAULT



16AE Ground Fault Trip Backup Delay 0.00 255.00 0.01 s F3 016B0 Ground Fault Alarm Ext. Delay 254.9 1800.0 0.1 s F2 254.916B1 Ground Fault Trip Ext. Delay 254.9 1800.0 0.1 s F2 254.916B2 Ground Fault Trip Backup Ext. Delay 254.9 1800.0 0.1 s F2 254.9... Reserved

ACCELERATION TRIP16D0 Acceleration Trip 0 1 1 - F115 016D1 Assign Trip Relays 0 7 1 - F111 116D2 Acceleration Timer From Start 10 2500 1 1s F1 100... Reserved - - - - - -16E0 Enable Single Shot Restart 0 1 1 - F103 016E1 Enable Start Inhibit 0 1 1 - F103 016E2 Maximum Starts/Hour Permissible 0 5 1 - F1 016E3 Time Between Starts 0 500 1 min F1 1016E4 Restart Block 0 50000 1 s F1 016E5 Assign Block Relays 0 7 1 - F111 3... Reserved

BACKSPIN DETECTION1780 Enable Back-Spin Start Inhibit 0 1 1 - F103 01781 Minimum Permissible Frequency 0 999 1 Hz F3 100... Reserved1784 Enable Prediction Algorithm 0 1 1 - F103 11785 Assign Backspin Inhibit Relays 0 7 1 - F111 11786 Number of Motor Poles 2 16 2 - F1 2... Reserved

LOCAL RTD #11790 Local RTD #1 Application 0 4 1 - F121 01791 Local RTD #1 High Alarm 0 2 1 - F115 01792 Local RTD #1 High Alarm Relays 0 7 1 - F113 21793 Local RTD #1 High Alarm Level 1 200 1 °C F1 1301794 Local RTD #1 Alarm 0 2 1 - F115 01795 Local RTD #1 Alarm Relays 0 7 1 - F113 11796 Local RTD #1 Alarm Level 1 200 1 °C F1 1301797 Record RTD #1 Alarms as Events 0 1 1 - F103 01798 Local RTD #1 Trip 0 2 1 - F115 01799 Enable RTD #1 Trip Voting 0 13 1 - F122 1179A Local RTD #1 Trip Relays 0 7 1 - F111 1179B Local RTD #1 Trip Level 1 200 1 °C F1 130179C Local RTD #1 RTD Type 0 3 1 - F120 0

17A0 First Character of Local RTD #1 Name 32 127 1 - F1 ’R’

↓ ↓ - - - - - -17A3 8th Character of Local RTD #1 Name 32 127 1 - F1 " "... Reserved

LOCAL RTD #217B0 Local RTD #2 Application 0 4 1 - F121 017B1 Local RTD #2 High Alarm 0 2 1 - F115 017B2 Local RTD #2 High Alarm Relays 0 7 1 - F113 217B3 Local RTD #2 High Alarm Level 1 200 1 °C F1 13017B4 Local RTD #2 Alarm 0 2 1 - F115 017B5 Local RTD #2 Alarm Relays 0 7 1 - F113 117B6 Local RTD #2 Alarm Level 1 200 1 °C F1 13017B7 Record RTD #2 Alarms as Events 0 1 1 - F103 017B8 Local RTD #2 Trip 0 2 1 - F 115 0




FACTORY DEFAULT



17B9 Enable RTD #2 Trip Voting 0 13 1 - F122 117BA Local RTD #2 Trip Relays 0 7 1 - F111 117BB Local RTD #2 Trip Level 1 200 1 °C F1 13017BC Local RTD #2 RTD Type 0 3 1 - F120 0

17C0 First Character of Local RTD #2 Name 32 127 1 - F1 ’R’

↓ ↓17C3 8th Character of Local RTD #2 Name 32 127 1 - F1 " "... Reserved

LOCAL RTD #317D0 Local RTD #3 Application 0 4 1 - F121 017D1 Local RTD #3 High Alarm 0 2 1 - F115 017D2 Local RTD #3 High Alarm Relays 0 7 1 - F113 217D3 Local RTD #3 High Alarm Level 1 200 1 °C F1 13017D4 Local RTD #3 Alarm 0 2 1 - F115 017D5 Local RTD #3 Alarm Relays 0 7 1 - F113 117D6 Local RTD #3 Alarm Level 1 200 1 °C F1 13017D7 Record RTD #3 Alarms as Events 0 1 1 - F103 017D8 Local RTD #3 Trip 0 2 1 - F115 017D9 Enable RTD #3 Trip Voting 0 13 1 - F122 117DA Local RTD #3 Trip Relays 0 7 1 - F111 117DB Local RTD #3 Trip Level 1 200 1 °C F1 13017DC Local RTD #3 RTD Type 0 3 1 - F120 0

17E0 First Character of Local RTD #3 Name 32 127 1 - F1 ’R’

↓ ↓17E3 8th Character of Local RTD #3 Name 32 127 1 - F1 " "... Reserved

LOCAL RTD #417F0 Local RTD #4 Application 0 4 1 - F121 017F1 Local RTD #4 High Alarm 0 2 1 - F115 017F2 Local RTD #4 High Alarm Relays 0 7 1 - F113 217F3 Local RTD #4 High Alarm Level 1 200 1 °C F1 13017F4 Local RTD #4 Alarm 0 2 1 - F115 017F5 Local RTD #4 Alarm Relays 0 7 1 - F113 117F6 Local RTD #4 Alarm Level 1 200 1 °C F1 13017F7 Enable RTD #4 Alarms as Events 0 1 1 - F103 017F8 Local RTD #4 Trip 0 2 1 - F115 017F9 Enable RTD #4 Trip Voting 0 13 1 - F122 117FA Local RTD #4 Trip Relays 0 7 1 - F111 117FB Local RTD #4 Trip Level 1 200 1 °C F1 13017FC Local RTD #4 RTD Type 0 3 1 - F120 0

1800 First Character of Local RTD #4 Name 32 127 1 - F1 ’R’

↓ ↓1803 8th Character of Local RTD #4 Name 32 127 1 - F1 " "... Reserved

LOCAL RTD #51810 Local RTD #5 Application 0 4 1 - F121 01811 Local RTD #5 High Alarm 0 2 1 - F115 01812 Local RTD #5 High Alarm Relays 0 7 1 - F113 11813 Local RTD #5 High Alarm Level 1 250 1 °C / °F F1 1301814 Local RTD #5 Alarm 0 2 1 - F115 01815 Local RTD #5 Alarm Relays 0 7 1 - F113 11816 Local RTD #5 Alarm Level 1 200 1 °C F1 130




FACTORY DEFAULT



1817 Record RTD #5 Alarms as Events 0 1 1 - F103 01818 Local RTD #5 Trip 0 2 1 - F115 01819 Enable RTD #5 Trip Voting 0 13 1 - F122 1181A Local RTD #5 Trip Relays 0 7 1 - F111 1181B Local RTD #5 Trip Level 1 200 1 °C F1 130181C Local RTD #5 RTD Type 0 3 1 - F120 0








↓ ↓1863 8th Character of Local RTD #7 Name 32 127 1 - F1 " "1864 Reserved

LOCAL RTD #81870 Local RTD #8 Application 0 4 1 - F121 01871 Local RTD #8 High Alarm 0 2 1 - F115 01872 Local RTD #8 High Alarm Relays 0 7 1 - F113 21873 Local RTD #8 High Alarm Level 1 200 1 °C F1 1301874 Local RTD #8 Alarm 0 2 1 - F115 0




FACTORY DEFAULT



1875 Local RTD #8 Alarm Relays 0 7 1 - F113 11876 Local RTD #8 Alarm Level 1 200 1 °C F1 1301877 Record RTD #8 Alarms as Events 0 1 1 - F103 01878 Local RTD #8 Trip 0 2 1 - F115 01879 Enable RTD #8 Trip Voting 0 13 1 - F122 1187A Local RTD #8 Trip Relays 0 7 1 - F111 1187B Local RTD #8 Trip Level 1 200 1 °C F1 130187C Local RTD #8 RTD Type 0 3 1 - F120 0


↓ ↓1883 8th Character of Local RTD #8 Name 32 127 1 - F1 " "1884 Reserved


18A0 First Character of Local RTD #9 Name 32 127 1 - F1 ’R’

↓ ↓18A3 8th Character of Local RTD #9 Name 32 127 1 - F1 " "18A4 Reserved

LOCAL RTD #1018B0 Local RTD #10 Application 0 4 1 - F121 018B1 Local RTD #10 High Alarm 0 2 1 - F115 018B2 Local RTD #10 High Alarm Relays 0 7 1 - F113 218B3 Local RTD #10 High Alarm Level 1 200 1 °C F1 13018B4 Local RTD #10 Alarm 0 2 1 - F115 018B5 Local RTD #10 Alarm Relays 0 7 1 - F113 118B6 Local RTD #10 Alarm Level 1 200 1 °C F1 13018B7 Record RTD #10 Alarms as Events 0 1 1 - F103 018B8 Local RTD #10 Trip 0 2 1 - F115 018B9 Enable RTD #10 Trip Voting 0 13 1 - F122 118BA Local RTD #10 Trip Relays 0 7 1 - F111 118BB Local RTD #10 Trip Level 1 200 1 °C F1 13018BC Local RTD #10 RTD Type 0 3 1 - F120 0

18C0 First Character of Local RTD #10 Name 32 127 1 - F1 ’R’

↓ ↓18C3 8th Character of RTD #10 Name 32 127 1 - F1 " "... Reserved

LOCAL RTD #1118D0 Local RTD #11 Application 0 4 1 - F121 018D1 Local RTD #11 High Alarm 0 2 1 - F115 018D2 Local RTD #11 High Alarm Relays 0 7 1 - F113 2




FACTORY DEFAULT



18D3 Local RTD #11 High Alarm Level 1 200 1 °C F1 13018D4 Local RTD #11 Alarm 0 2 1 - F115 018D5 Local RTD #11 Alarm Relays 0 7 1 - F113 118D6 Local RTD #11 Alarm Level 1 200 1 °C F1 13018D7 Record RTD #11 Alarm Events 0 1 1 - F103 018D8 Local RTD #11 Trip 0 2 1 - F115 018D9 Enable RTD #11 Trip Voting 0 13 1 - F122 118DA Local RTD #11 Trip Relays 0 7 1 - F111 118DB Local RTD #11 Trip Level 1 200 1 °C F1 13018DC Local RTD #11 RTD Type 0 3 1 - F120 0

18E0 First Character of Local RTD #11 Name 32 127 1 - F1 ’R’

↓ ↓

18E3 8th Character of Local RTD #11 Name 32 127 1 - F1 " "

... Reserved

LOCAL RTD #1218F0 Local RTD #12 Application 0 4 1 - F121 018F1 Local RTD #12 High Alarm 0 2 1 - F115 018F2 Local RTD #12 High Alarm Relays 0 7 1 - F113 218F3 Local RTD #12 High Alarm Level 1 200 1 °C F1 13018F4 Local RTD #12 Alarm 0 2 1 - F115 018F5 Local RTD #12 Alarm Relays 0 7 1 - F113 118F6 Local RTD #12 Alarm Level 1 200 1 °C F1 13018F7 Record RTD #12 Alarms as Events 0 1 1 - F103 018F8 Local RTD #12 Trip 0 2 1 - F115 018F9 Enable RTD #12 Trip Voting 0 13 1 - F122 118FA Local RTD #12 Trip Relays 0 7 1 - F111 118FB Local RTD #12 Trip Level 1 200 1 °C F1 13018FC Local RTD #12 RTD Type 0 3 1 - F120 0


↓ ↓

1903 8th Character of Local RTD #12 Name 32 127 1 - F1 " "

... Reserved

OPEN RTD ALARM1B20 Open RTD Alarm 0 2 1 - F115 01B21 Assign Alarm Relays 0 7 1 - F113 11B22 Open RTD Alarm Events 0 1 1 - F103 0

SHORT/LOW TEMPERATURE RTD ALARM1B23 Short / Low Temp RTD Alarm 0 2 1 - F115 01B24 Assign Alarm Relays 0 7 1 - F113 11B25 Short / Low Temp Alarm Events 0 1 1 - F103 0... Reserved - - - - - -

LOSS OF REMOTE RTD COMMUNICATIONS1B30 Loss RRTD Comm Alarm 0 2 1 - F115 01B31 Loss RRTD Comm Alarm Relays 0 7 1 - F113 11B32 Loss RRTD Comm Alarm Events 0 1 1 - F103 0... Reserved

UNDERVOLTAGE

1B60 Undervoltage Active If Motor Stopped 0 1 1 - F103 0

1B61 Undervoltage Alarm 0 2 1 - F115 01B62 Assign Alarm Relays 0 7 1 - F113 1




FACTORY DEFAULT



1B63 Undervoltage Alarm Pickup 50 99 1 × Rated F3 851B64 Starting Undervoltage Alarm Pickup 50 99 1 × Rated F3 851B65 Undervoltage Alarm Delay 0 2550 1 0.1s F2 301B66 Undervoltage Alarm Events 0 1 1 - F103 01B67 Undervoltage Trip 0 2 1 - F115 01B68 Undervoltage Trip Relays 0 7 1 - F111 11B69 Undervoltage Trip Pickup 50 99 1 × Rated F3 801B6A Starting Undervoltage Trip Pickup 50 99 1 × Rated F3 801B6B Undervoltage Trip Delay 0 2550 1 0.1s F2 10... Reserved

OVERVOLTAGE1B80 Overvoltage Alarm 0 2 1 - F115 01B81 Overvoltage Alarm Relays 0 7 1 - F113 11B82 Overvoltage Alarm Pickup 101 125 1 x Rated F3 1051B83 Overvoltage Alarm Delay 0 2550 1 s F2 101B84 Overvoltage Alarm Events 0 1 1 - F103 01B85 Overvoltage Trip 0 1 1 - F103 01B86 Overvoltage Trip Relays 0 7 1 - F111 11B87 Overvoltage Trip Pickup 101 125 1 x Rated F3 1101B88 Overvoltage Trip Delay 0 2550 1 s F2 10... Reserved

PHASE REVERSAL1BA0 Phase Reversal Trip 0 2 1 - F115 01BA1 Assign Trip Relays 0 7 1 - F111 1... Reserved - - - - - -

OVERFREQUENCY1BB0 Block Overfrequency on Start 0 5000 1 s F1 11BB1 Overfrequency Alarm 0 2 1 - F115 01BB2 Assign Alarm Relays 0 7 1 - F113 11BB3 Overfrequency Alarm Level 2000 7000 1 Hz F3 60501BB4 Overfrequency Alarm Delay 0 2550 1 s F2 101BB5 Overfrequency Alarm Events 0 1 1 - F103 01BB6 Overfrequency Trip 0 1 1 - F103 01BB7 Assign Trip Relays 0 7 1 - F111 11BB8 Overfrequency Trip Level 2000 7000 1 Hz F3 60501BB9 Overfrequency Trip Delay 0 2550 1 s F2 10... Reserved - - - - - -

UNDERFREQUENCY1BC0 Block Underfrequency on Start 0 5000 1 s F1 11BC1 Underfrequency Alarm 0 2 1 - F115 01BC2 Assign Alarm Relays 0 7 1 - F113 11BC3 Underfrequency Alarm Level 2000 7000 1 Hz F3 59501BC4 Underfrequency Alarm Delay 0 2550 1 s F2 101BC5 Underfrequency Alarm Events 0 1 1 - F103 01BC6 Underfrequency Trip 0 2 1 - F115 01BC7 Assign Trip Relays 0 7 1 - F111 11BC8 Underfrequency Trip Level 2000 7000 1 Hz F3 59501BC9 Underfrequency Trip Delay 0 2550 1 s F2 10... Reserved

LEAD POWER FACTOR1BD0 Block Lead Power Factor From Start 0 5000 1 s F1 11BD1 Lead Power Factor Alarm 0 2 1 - F115 0

1BD2 Assign Lead Power Factor Alarm Relays 0 7 1 - F113 1




FACTORY DEFAULT



1BD3 Lead Power Factor Alarm Level 5 99 1 - F3 301BD4 Lead Power Factor Alarm Delay 1 2550 1 s F2 101BD5 Lead Power Factor Alarm Events 0 1 1 - F103 01BD6 Lead Power Factor Trip 0 2 1 - F115 01BD7 Lead Power Factor Trip Relays 0 7 1 - F111 11BD8 Lead Power Factor Trip Level 5 99 1 - F3 101BD9 Lead Power Factor Trip Delay 1 2550 1 s F2 10... Reserved

LAG POWER FACTOR1BE0 Block Lag Power Factor From Start 0 5000 1 s F1 11BE1 Lag Power Factor Alarm 0 2 1 - F115 0

1BE2 Assign Lag Power Factor Alarm Relays 0 7 1 - F113 1

1BE3 Lag Power Factor Alarm Level 5 99 1 - F3 851BE4 Lag Power Factor Alarm Delay 1 2550 1 s F2 101BE5 Lag Power Factor Alarm Events 0 1 1 - F103 01BE6 Lag Power Factor Trip 0 2 1 - F115 01BE7 Assign Lag Power Factor Trip Relays 0 7 1 - F111 11BE8 Lag Power Factor Trip Level 5 99 1 - F3 801BE9 Lag Power Factor Trip Delay 1 2550 1 s F2 10... Reserved

POSITIVE REACTIVE POWER

1BF0 Block Positive kvar Element From Start 0 5000 1 s F1 1

1BF1 Positive kvar Alarm 0 2 1 - F115 01BF2 Assign Alarm Relays 0 7 1 - F113 11BF3 Positive kvar Alarm Level 1 25000 1 kvar F1 101BF4 Positive kvar Alarm Delay 1 2550 1 s F2 101BF5 Positive kvar Alarm Events 0 1 1 - F103 01BF6 Positive kvar Trip 0 1 1 - F103 01BF7 Assign Trip Relays 0 7 1 - F111 11BF8 Positive kvar Trip Level 1 25000 1 kvar F1 251BF9 Positive kvar Trip Delay 1 2550 1 s F2 10... Reserved

NEGATIVE REACTIVE POWER

1C00 Block Negative kvar Element from Start 0 5000 1 s F1 1

1C01 Negative kvar Alarm 0 2 1 - F115 01C02 Assign Alarm Relays 0 7 1 - F113 11C03 Negative kvar Alarm Level 1 25000 1 kvar F1 101C04 Negative kvar Alarm Delay 1 2550 1 s F2 101C05 Negative kvar Alarm Events 0 1 1 - F103 01C06 Negative kvar Trip 0 1 1 - F103 01C07 Assign Trip Relays 0 7 1 - F111 11C08 Negative kvar Trip Level 1 25000 1 kvar F1 251C09 Negative kvar Trip Delay 1 2550 1 s F2 10... Reserved

UNDERPOWER1C10 Block Underpower From Start 0 15000 1 s F1 01C11 Underpower Alarm 0 2 1 - F115 01C12 Assign Alarm Relays 0 7 1 - F113 11C13 Underpower Alarm Level 1 25000 1 kW F1 21C14 Underpower Alarm Delay 5 2550 1 s F2 11C15 Underpower Alarm Events 0 1 1 - F103 01C16 Underpower Trip 0 2 1 - F115 0




FACTORY DEFAULT



1C17 Underpower Trip Relays 0 7 1 - F111 11C18 Underpower Trip Level 1 25000 1 kW F1 11C19 Underpower Trip Delay 5 2550 1 s F1 1... Reserved

REVERSE POWER1C20 Block Reverse Power From Start 0 50000 1 s F1 01C21 Reverse Power Alarm 0 2 1 - F115 01C22 Assign Alarm Relays 0 7 1 - F113 11C23 Reverse Power Alarm Level 1 25000 1 kW F1 21C24 Reverse Power Alarm Delay 5 300 1 s F2 11C25 Reverse Power Alarm Events 0 1 1 - F103 01C26 Reverse Power Trip 0 2 1 - F115 01C27 Assign Trip Relays 0 7 1 - F111 11C28 Reverse Power Trip Level 1 25000 1 kW F1 11C29 Reverse Power Trip Delay 5 300 1 s F2 1... Reserved

ENHANCED MOTOR LEARNED DATA1C70 Number of Starts to Average 1 5 1 - F1 5

1C71 Access Learned Data Record Number 0 65535 1 - F1 0

TRIP COUNTER1C80 Trip Counter Alarm 0 2 1 - F115 01C81 Assign Alarm Relays 0 7 1 - F113 11C82 Alarm Pickup Level 0 50000 1 - F1 251C83 Trip Counter Alarm Events 0 1 1 - F103 0... Reserved

STARTER FAILURE1C90 Starter Failure Alarm 0 2 1 - F115 01C91 Starter Type 0 1 1 - F125 01C92 Assign Alarm Relays 0 7 1 - F113 11C93 Starter Failure Delay 10 1000 10 ms F1 1001C94 Starter Failure Alarm Events 0 1 1 - F103 0... Reserved

CURRENT DEMAND1CD0 Current Demand Period 5 90 1 min F1 151CD1 Current Demand Alarm 0 2 1 - F115 01CD2 Assign Alarm Relays 0 7 1 - F113 11CD3 Current Demand Alarm Limit 0 65000 1 A F1 1001CD5 Current Demand Alarm Events 0 1 1 - F103 0... Reserved

KW DEMAND1CE0 kW Demand Period 5 90 1 min F1 151CE1 kW Demand Alarm 0 2 1 - F115 01CE2 Assign Alarm Relays 0 7 1 - F113 11CE3 kW Demand Alarm Limit 1 50000 1 kW F1 1001CE4 kW Demand Alarm Events 0 1 1 - F103 0... Reserved

KVAR DEMAND1CF0 kvar Demand Period 5 90 1 min F1 151CF1 kvar Demand Alarm 0 2 1 - F115 01CF2 Assign Alarm Relays 0 7 1 - F113 11CF3 kvar Demand Alarm Limit 1 50000 1 kvar F1 1001CF4 kvar Demand Alarm Events 0 1 1 - F103 0... Reserved




FACTORY DEFAULT



KVA DEMAND1D00 kVA Demand Period 5 90 1 min F1 151D01 kVA Demand Alarm 0 2 1 - F115 01D02 Assign Alarm Relays 0 7 1 - F113 11D03 kVA Demand Alarm Limit 1 50000 1 kVA F1 1001D04 kVA Demand Alarm Events 0 1 1 - F103 0... Reserved

SELF-TEST RELAY1D06 Assign Service Relay 0 7 1 - F113 0... Reserved

ANALOG OUTPUTS1D40 Enable Analog Output 1 0 1 1 - F103 0

1D41 Assign Analog Output 1 Output Range 0 2 1 - F26 0

1D42 Assign Analog Output 1 Parameter 0 35 1 - F127 01D43 Analog Output 1 Minimum TBD TBD 1 - F1 01D44 Analog Output 1 Maximum TBD TBD 1 - F1 01D45 Enable Analog Output 2 0 1 1 - F103 0


1D47 Assign Analog Output 2 Parameter 0 35 1 - F127 01D48 Analog Output 2 Minimum TBD TBD 1 - F1 01D49 Analog Output 2 Maximum TBD TBD 1 - F1 01D4A Enable Analog Output 3 0 1 1 - F103 0

1D4B Assign Analog Output 3 Output Range 0 2 1 - F26 0

1D4C Assign Analog Output 3 Parameter 0 35 1 - F127 01D4D Analog Output 3 Minimum TBD TBD 1 - F1 01D4E Analog Output 3 Maximum TBD TBD 1 - F1 01D4F Enable Analog Output 4 0 1 1 - F103 0


1D51 Assign Analog Output 4 Parameter 0 35 1 - F127 01D52 Analog Output 4 Minimum TBD TBD 1 - F1 01D53 Analog Output 4 Maximum TBD TBD 1 - F1 0

SPEED 2 O/L CURVE SETUP

1DC0 Speed 2 Standard Overload Curve Number 1 15 1 - F1 4

1DC1 Speed 2 Time to Trip at 1.01 x FLA 0 65534 1 s F1 174151DC2 Speed 2 Time to Trip at 1.05 x FLA 0 65534 1 s F1 34151DC3 Speed 2 Time to Trip at 1.10 x FLA 0 65534 1 s F1 16671DC4 Speed 2 Time to Trip at 1.20 x FLA 0 65534 1 s F1 7951DC5 Speed 2 Time to Trip at 1.30 x FLA 0 65534 1 s F1 5071DC6 Speed 2 Time to Trip at 1.40 x FLA 0 65534 1 s F1 3651DC7 Speed 2 Time to Trip at 1.50 x FLA 0 65534 1 s F1 2801DC8 Speed 2 Time to Trip at 1.75 x FLA 0 65534 1 s F1 1701DC9 Speed 2 Time to Trip at 2.00 x FLA 0 65534 1 s F1 1171DCA Speed 2 Time to Trip at 2.25 x FLA 0 65534 1 s F1 861DCB Speed 2 Time to Trip at 2.50 x FLA 0 65534 1 s F1 671DCC Speed 2 Time to Trip at 2.75 x FLA 0 65534 1 s F1 531DCD Speed 2 Time to Trip at 3.00 x FLA 0 65534 1 s F1 441DCE Speed 2 Time to Trip at 3.25 x FLA 0 65534 1 s F1 371DCF Speed 2 Time to Trip at 3.50 x FLA 0 65534 1 s F1 311DD0 Speed 2 Time to Trip at 3.75 x FLA 0 65534 1 s F1 271DD1 Speed 2 Time to Trip at 4.00 x FLA 0 65534 1 s F1 23




FACTORY DEFAULT



1DD2 Speed 2 Time to Trip at 4.25 x FLA 0 65534 1 s F1 211DD3 Speed 2 Time to Trip at 4.50 x FLA 0 65534 1 s F1 181DD4 Speed 2 Time to Trip at 4.75 x FLA 0 65534 1 s F1 161DD5 Speed 2 Time to Trip at 5.00 x FLA 0 65534 1 s F1 151DD6 Speed 2 Time to Trip at 5.50 x FLA 0 65534 1 s F1 121DD7 Speed 2 Time to Trip at 6.00 x FLA 0 65534 1 s F1 101DD8 Speed 2 Time to Trip at 6.50 x FLA 0 65534 1 s F1 91DD9 Speed 2 Time to Trip at 7.00 x FLA 0 65534 1 s F1 71DDA Speed 2 Time to Trip at 7.50 x FLA 0 65534 1 s F1 61DDB Speed 2 Time to Trip at 8.00 x FLA 0 65534 1 s F1 61DDC Speed 2 Time to Trip at 10.0 x FLA 0 65534 1 s F1 61DDD Speed 2 Time to Trip at 15.0 x FLA 0 65534 1 s F1 61DDE Speed 2 Time to Trip at 20.0 x FLA 0 65534 1 s F1 6... Reserved

SPEED 2 UNDERCURRENT

1DF0 Speed 2 Block Undercurrent from Start 0 15000 1 s F1 0

1DF1 Speed 2 Undercurrent Alarm 0 2 1 - F115 0

1DF2 Speed 2 Assign Undercurrent Alarm Relays 0 7 1 - F113 1

1DF3 Speed 2 Undercurrent Alarm Level 10 99 1 0.01 × FLA F3 70

1DF4 Speed 2 Undercurrent Alarm Delay 1 255 1 s F1 11DF5 Speed 2 Undercurrent Alarm Events 0 1 1 - F103 01DF6 Speed 2 Undercurrent Trip 0 2 1 - F115 0

1DF7 Speed 2 Assign Undercurrent Trip Relays 0 7 1 - F111 1

1DF8 Speed 2 Undercurrent Trip Level 10 99 1 0.01 × FLA F3 70

1DF9 Speed 2 Undercurrent Trip Delay 1 255 1 s F1 1... Reserved

SPEED 2 ACCELERATION

1E00 Speed 2 Acceleration Timer from Start 10 2500 10 s F2 100

1E01 Speed 2 Acceleration Timer from Speed 1 to 2 20 2500 1 s F2 200

1E02 Speed 2 Speed Switch Time Delay 5 1000 5 100 ms F2 20DATA LOGGER

1E20 Start/Stop Data Log 0 2 1 - F187 0 (=Select Command)

1E21 Log Interval 1 3600 1 - F1 3600

1E22 Recording Type 0 1 1 - F188 0 (=Run To Fill)

1E23 Data Log Memory Access Block Number 0 255 1 - F1 0, 1 (=null)

1E24 Channel 1 Log Assignment 0 102 1 - F189 0 (=None)1E25 Channel 2 Log Assignment 0 102 1 - F189 0 (=None)1E26 Channel 3 Log Assignment 0 102 1 - F189 0 (=None)1E27 Channel 4 Log Assignment 0 102 1 - F189 0 (=None)1E28 Channel 5 Log Assignment 0 102 1 - F189 0 (=None)1E29 Channel 6 Log Assignment 0 102 1 - F189 0 (=None)1E2A Channel 7 Log Assignment 0 102 1 - F189 0 (=None)1E2B Channel 8 Log Assignment 0 102 1 - F189 0 (=None)1E2C Channel 9 Log Assignment 0 102 1 - F189 0 (=None)1E2D Channel 10 Log Assignment 0 102 1 - F189 0 (=None)1E2E Channel 11 Log Assignment 0 102 1 - F189 0 (=None)1E2F Channel 12 Log Assignment 0 102 1 - F189 0 (=None)




FACTORY DEFAULT



1E30 Channel 13 Log Assignment 0 102 1 - F189 0 (=None)1E31 Channel 14 Log Assignment 0 102 1 - F189 0 (=None)1E32 Channel 15 Log Assignment 0 102 1 - F189 0 (=None)1E33 Channel 16 Log Assignment 0 102 1 - F189 0 (=None)... Reserved

TEST OUTPUT RELAYS1F80 Force Trip Relay 0 2 1 - F150 01F81 Force Trip Relay Duration 1 300 1 s F1 01F82 Force AUX1 Relay 0 2 1 - F150 01F83 Force AUX1 Relay Duration 1 300 1 s F1 01F84 Force AUX2 Relay 0 2 1 - F150 01F85 Force AUX2 Relay Duration 1 300 1 s F1 01F86 Force Alarm Relay 0 2 1 - F150 01F87 Force Alarm Relay Range 1 300 1 s F1 0... Reserved

TEST ANALOG OUTPUTS1F90 Force Analog Outputs 0 1 1 - F126 01F91 Analog Output 1 Forced Value 0 100 1 % range F1 01F92 Analog Output 2 Forced Value 0 100 1 % range F1 01F93 Analog Output 3 Forced Value 0 100 1 % range F1 01F94 Analog Output 4 Forced Value 0 100 1 % range F1 0... Reserved

REMOTE RTD SLAVE ADDRESSES1FF0 RRTD1 - Slave Address 0 254 1 - F1 01FF1 RRTD2 - Slave Address 0 254 1 - F1 01FF2 RRTD3 - Slave Address 0 254 1 - F1 01FF3 RRTD4 - Slave Address 0 254 1 - F1 0... Reserved

RRTD 1 – RTD #12000 RRTD 1 - RTD #1 Application 0 4 1 - F121 02001 RRTD 1 - RTD #1 High Alarm 0 2 1 - F115 02002 RRTD 1 - RTD #1 High Alarm Relays 0 7 1 - F113 22003 RRTD 1 - RTD #1 High Alarm Level 1 200 1 °C F1 1302004 RRTD 1 - RTD #1 Alarm 0 2 1 - F115 02005 RRTD 1 - RTD #1 Alarm Relays 0 7 1 - F113 12006 RRTD 1 - RTD #1 Alarm Level 1 200 1 °C F1 130

2007 Record RRTD 1 - RTD #1 Alarms as Events 0 1 1 - F103 0

2008 RRTD 1 - RTD #1 Trip 0 2 1 - F115 02009 Enable RRTD 1 - RTD #1 Trip Voting 0 13 1 - F122 1200A RRTD 1 - RTD #1 Trip Relays 0 7 1 - F111 1200B RRTD 1 - RTD #1 Trip Level 1 200 1 °C F1 130200C RRTD 1 - RTD #1 RTD Type 0 3 1 - F120 0... Reserved

2010 First Character of RRTD 1 - RTD #1 Name 32 127 1 - F1 ’R’

↓ ↓

2013 8th Character of RRTD 1 - RTD #1 Name 32 127 1 - F1 " "

2014 Reserved

RRTD 1 – RTD #22020 RRTD 1 - RTD #2 Application 0 4 1 - F121 02021 RRTD 1 - RTD #2 High Alarm 0 2 1 - F115 02022 RRTD 1 - RTD #2 High Alarm Relays 0 7 1 - F113 22023 RRTD 1 - RTD #2 High Alarm Level 1 200 1 °C F1 130




FACTORY DEFAULT



2024 RRTD 1 - RTD #2 Alarm 0 2 1 - F115 02025 RRTD 1 - RTD #2 Alarm Relays 0 7 1 - F113 12026 RRTD 1 - RTD #2 Alarm Level 1 200 1 °C F1 130


2028 RRTD 1 - RTD #2 Trip 0 2 1 - F115 02029 Enable A Remote RTD #2 Trip Voting 0 13 1 - F122 1202A RRTD 1 - RTD #2 Trip Relays 0 7 1 - F111 1202B RRTD 1 - RTD #2 Trip Level 1 200 1 °C F1 130202C RRTD 1 - RTD #2 RTD Type 0 3 1 - F120 0... Reserved


↓ ↓


2034 Reserved



2048 RRTD 1 - RTD #3 Trip 0 2 1 - F115 02049 Enable RRTD 1 - RTD #3 Trip Voting 0 13 1 - F122 1204A RRTD 1 - RTD #3 Trip Relays 0 7 1 - F111 1204B RRTD 1 - RTD #3 Trip Level 1 200 1 °C F1 130204C RRTD 1 - RTD #3 RTD Type 0 3 1 - F120 0

2050 First Character of RRTD 1 - RTD # Name 32 127 1 - F1 ’R’

↓ ↓


... Reserved





↓ ↓




FACTORY DEFAULT




2074 ReservedRRTD 1 – RTD #5

2080 RRTD 1 - RTD #5 Application 0 4 1 - F121 02081 RRTD 1 - RTD #5 High Alarm 0 2 1 - F115 02082 RRTD 1 - RTD #5 High Alarm Relays 0 7 1 - F113 22083 RRTD 1 - RTD #5 High Alarm Level 1 200 1 °C F1 1302084 RRTD 1 - RTD #5 Alarm 0 2 1 - F115 02085 RRTD 1 - RTD #5 Alarm Relays 0 7 1 - F113 12086 RRTD 1 - RTD #5 Alarm Level 1 200 1 °C F1 130




↓ ↓


... Reserved

RRTD 1 – RTD #620A0 RRTD 1 - RTD #6 Application 0 4 1 - F121 020A1 RRTD 1 - RTD #6 High Alarm 0 2 1 - F115 020A2 RRTD 1 - RTD #6 High Alarm Relays 0 7 1 - F113 120A3 RRTD 1 - RTD #6 High Alarm Level 1 200 1 °C F1 13020A4 RRTD 1 - RTD #6 Alarm 0 2 1 - F115 020A5 RRTD 1 - RTD #6 Alarm Relays 0 7 1 - F113 120A6 RRTD 1 - RTD #6 Alarm Level 1 200 1 °C F1 130

20A7 Record RRTD 1 - RTD #6 Alarms as Events 0 1 1 - F103 0

20A8 RRTD 1 - RTD #6 Trip 0 2 1 - F115 020A9 Enable RRTD 1 - RTD #6 Trip Voting 0 13 1 - F122 120AA RRTD 1 - RTD #6 Trip Relays 0 7 1 - F111 120AB RRTD 1 - RTD #6 Trip Level 1 200 1 °C F1 13020AC RRTD 1 - RTD #6 RTD Type 0 3 1 - F120 0

20B0 First Character of RRTD 1 - RTD #6 Name 32 127 1 - F1 ’R’

↓ ↓

20B3 8th Character of RRTD 1 - RTD #6 Name 32 127 1 - F1 " "

... Reserved

RRTD 1 – RTD #720C0 RRTD 1 - RTD #7 Application 0 4 1 - F121 020C1 RRTD 1 - RTD #7 High Alarm 0 2 1 - F115 020C2 RRTD 1 - RTD #7 High Alarm Relays 0 7 1 - F113 220C3 RRTD 1 - RTD #7 High Alarm Level 1 200 1 °C F1 13020C4 RRTD 1 - RTD #7 Alarm 0 2 1 - F115 020C5 RRTD 1 - RTD #7 Alarm Relays 0 7 1 - F113 120C6 RRTD 1 - RTD #7 Alarm Level 1 200 1 °C F1 130

20C7 Record RRTD 1 - RTD #7 Alarms as Events 0 1 1 - F103 0

20C8 RRTD 1 - RTD #7 Trip 0 2 1 - F115 0




FACTORY DEFAULT



20C9 Enable RRTD 1 - RTD #7 Trip Voting 0 13 1 - F122 120CA RRTD 1 - RTD #7 Trip Relays 0 7 1 - F111 120CB RRTD 1 - RTD #7 Trip Level 1 200 1 °C F1 13020CC RRTD 1 - RTD #7 RTD Type 0 3 1 - F120 0

20D0 First Character of RRTD 1 - RTD #7 Name 32 127 1 - F1 ’R’

↓ ↓

20D3 8th Character of RRTD 1 - RTD #7 Name 32 127 1 - F1 " "

... Reserved

RRTD 1 – RTD #820E0 RRTD 1 - RTD #8 Application 0 4 1 - F121 020E1 RRTD 1 - RTD #8 High Alarm 0 2 1 - F115 020E2 RRTD 1 - RTD #8 High Alarm Relays 0 7 1 - F113 220E3 RRTD 1 - RTD #8 High Alarm Level 1 200 1 °C F1 13020E4 RRTD 1 - RTD #8 Alarm 0 2 1 - F115 020E5 RRTD 1 - RTD #8 Alarm Relays 0 7 1 - F113 120E6 RRTD 1 - RTD #8 Alarm Level 1 200 1 °C F1 130

20E7 Record RRTD 1 - RTD #8 Alarms as Events 0 1 1 - F103 0

20E8 RRTD 1 - RTD #8 Trip 0 2 1 - F115 020E9 Enable RRTD 1 - RTD #8 Trip Voting 0 13 1 - F122 120EA RRTD 1 - RTD #8 Trip Relays 0 7 1 - F111 120EB RRTD 1 - RTD #8 Trip Level 1 200 1 °C F1 13020EC RRTD 1 - RTD #8 RTD Type 0 3 1 - F120 0

20F0 First Character of RRTD 1 - RTD #8 Name 32 127 1 - F1 ’R’

↓ ↓

20F3 8th Character of RRTD 1 - RTD #8 Name 32 127 1 - F1 " "

... ReservedRRTD 1 – RTD #9





↓ ↓


... Reserved

RRTD 1 – RTD #102120 RRTD 1 - RTD #10 Application 0 4 1 - F121 02121 RRTD 1 - RTD #10 High Alarm 0 2 1 - F115 02122 RRTD 1 - RTD #10 High Alarm Relays 0 7 1 - F113 2




FACTORY DEFAULT



2123 RRTD 1 - RTD #10 High Alarm Level 1 200 1 °C F1 1302124 RRTD 1 - RTD #10 Alarm 0 2 1 - F115 02125 RRTD 1 - RTD #10 Alarm Relays 0 7 1 - F113 12126 RRTD 1 - RTD #10 Alarm Level 1 200 1 °C F1 130


2128 RRTD 1 - RTD #10 Trip 0 2 1 - F115 02129 Enable RRTD 1 - RTD#10 Trip Voting 0 13 1 - F122 1212A RRTD 1 - RTD #10 Trip Relays 0 7 1 - F111 1212B RRTD 1 - RTD #10 Trip Level 1 200 1 °C F1 130212C RRTD 1 - RTD #10 RTD Type 0 3 1 - F120 0


↓ ↓


... Reserved





↓ ↓


... Reserved





↓ ↓




FACTORY DEFAULT




... ReservedRRTD 1 – OPEN RTD ALARM

2180 RRTD A - Open RTD Alarm 0 2 1 - F115 02181 RRTD A - Assign Alarm Relays 0 7 1 - F113 12182 RRTD A - Open RTD Alarm Events 0 1 1 - F103 0

RRTD 1 – SHORT/LOW TEMPERATURE RTD ALARM

2183 RRTD A - Short / Low Temp RTD Alarm 0 2 1 - F115 0

2184 RRTD A - Assign Alarm Relays 0 7 1 - F113 1

2185 RRTD A - Short / Low Temp Alarm Events 0 1 1 - F103 0

... Reserved - - - - - -RRTD 2 – RTD #1





↓ ↓





2228 RRTD 2 - RTD #2 Trip 0 2 1 - F115 02229 Enable A Remote RTD #2 Trip Voting 0 13 1 - F122 1222A RRTD 2 - RTD #2 Trip Relays 0 7 1 - F111 1222B RRTD 2 - RTD #2 Trip Level 1 200 1 °C F1 130222C RRTD 2 - RTD #2 RTD Type 0 3 1 - F120 0


↓ ↓


... Reserved




FACTORY DEFAULT







↓ ↓


... Reserved





↓ ↓


... Reserved



2288 RRTD 2 - RTD #5 Trip 0 2 1 - F115 02289 Enable RRTD 2 - RTD #5 Trip Voting 0 13 1 - F122 1228A RRTD 2 - RTD #5 Trip Relays 0 7 1 - F111 1228B RRTD 2 - RTD #5 Trip Level 1 200 1 °C F1 130




FACTORY DEFAULT



228C RRTD 2 - RTD #5 RTD Type 0 3 1 - F120 0


↓ ↓


... Reserved





↓ ↓



22C0 RRTD 2 - RTD #7 Application 0 4 1 - F121 022C1 RRTD 2 - RTD #7 High Alarm 0 2 1 - F115 022C2 RRTD 2 - RTD #7 High Alarm Relays 0 7 1 - F113 222C3 RRTD 2 - RTD #7 High Alarm Level 1 200 1 °C F1 13022C4 RRTD 2 - RTD #7 Alarm 0 2 1 - F115 022C5 RRTD 2 - RTD #7 Alarm Relays 0 7 1 - F113 122C6 RRTD 2 - RTD #7 Alarm Level 1 200 1 °C F1 130


22C8 RRTD 2 - RTD #7 Trip 0 2 1 - F115 022C9 Enable RRTD 2 - RTD #7 Trip Voting 0 13 1 - F122 122CA RRTD 2 - RTD #7 Trip Relays 0 7 1 - F111 122CB RRTD 2 - RTD #7 Trip Level 1 200 1 °C F1 13022CC RRTD 2 - RTD #7 RTD Type 0 3 1 - F120 0


↓ ↓

22D3 8th Character of RRTD 2 - RTD #7 Name 32 127 1 - F1 ’ ’

... Reserved

RRTD 2 – RTD #822E0 RRTD 2 - RTD #8 Application 0 4 1 - F121 022E1 RRTD 2 - RTD #8 High Alarm 0 2 1 - F115 022E2 RRTD 2 - RTD #8 High Alarm Relays 0 7 1 - F113 222E3 RRTD 2 - RTD #8 High Alarm Level 1 200 1 °C F1 13022E4 RRTD 2 - RTD #8 Alarm 0 2 1 - F115 022E5 RRTD 2 - RTD #8 Alarm Relays 0 7 1 - F113 1




FACTORY DEFAULT



22E6 RRTD 2 - RTD #8 Alarm Level 1 200 1 °C F1 130




↓ ↓

22F3 8th Character of RRTD 2 - RTD #8 Name 32 127 1 - F1 ’ ’

... Reserved





↓ ↓


... Reserved





↓ ↓


... Reserved




FACTORY DEFAULT







↓ ↓

2353 8th Character of RRTD 2 - RTD #11 Name 32 127 1 - F1 ’’

... Reserved





↓ ↓


... Reserved

RRTD 2 – OPEN RTD ALARM2380 RRTD B - Open RTD Alarm 0 2 1 - F115 02381 RRTD B - Assign Alarm Relays 0 7 1 - F113 12382 RRTD B - Open RTD Alarm Events 0 1 1 - F103 0


2383 RRTD B - Short / Low Temp RTD Alarm 0 2 1 - F115 0

2384 RRTD B - Assign Alarm Relays 0 7 1 - F113 1

2385 RRTD B - Short / Low Temp Alarm Events 0 1 1 - F103 0


2400 RRTD 3 - RTD #1 Application 0 4 1 - F121 02401 RRTD 3 - RTD #1 High Alarm 0 2 1 - F115 0




FACTORY DEFAULT



2402 RRTD 3 - RTD #1 High Alarm Relays 0 7 1 - F113 22403 RRTD 3 - RTD #1 High Alarm Level 1 200 1 °C F1 1302404 RRTD 3 - RTD #1 Alarm 0 2 1 - F115 02405 RRTD 3 - RTD #1 Alarm Relays 0 7 1 - F113 12406 RRTD 3 - RTD #1 Alarm Level 1 200 1 °C F1 130




↓ ↓


2414 Reserved





↓ ↓


... Reserved








FACTORY DEFAULT



↓ ↓







↓ ↓







↓ ↓


... Reserved






FACTORY DEFAULT





↓ ↓


... Reserved

RRTD 3 – RTD #724C0 RRTD 3 - RTD #7 Application 0 4 1 - F121 024C1 RRTD 3 - RTD #7 High Alarm 0 2 1 - F115 024C2 RRTD 3 - RTD #7 High Alarm Relays 0 7 1 - F113 224C3 RRTD 3 - RTD #7 High Alarm Level 1 200 1 °C F1 13024C4 RRTD 3 - RTD #7 Alarm 0 2 1 - F115 024C5 RRTD 3 - RTD #7 Alarm Relays 0 7 1 - F113 124C6 RRTD 3 - RTD #7 Alarm Level 1 200 1 °C F1 130




↓ ↓


... Reserved





↓ ↓


... Reserved

RRTD 3 – RTD #92500 RRTD 3 - RTD #9 Application 0 4 1 - F121 02501 RRTD 3 - RTD #9 High Alarm 0 2 1 - F115 0




FACTORY DEFAULT



2502 RRTD 3 - RTD #9 High Alarm Relays 0 7 1 - F113 22503 RRTD 3 - RTD #9 High Alarm Level 1 200 1 °C F1 1302504 RRTD 3 - RTD #9 Alarm 0 2 1 - F115 02505 RRTD 3 - RTD #9 Alarm Relays 0 7 1 - F113 12506 RRTD 3 - RTD #9 Alarm Level 1 200 1 °C F1 130




↓ ↓


... Reserved





↓ ↓


... Reserved








FACTORY DEFAULT



↓ ↓







↓ ↓


... ReservedRRTD 3 – OPEN RTD ALARM

2580 RRTD 3 - Open RTD Alarm 0 2 1 - F115 02581 RRTD 3 - Assign Alarm Relays 0 7 1 - F113 12582 RRTD 3 - Open RTD Alarm Events 0 1 1 - F103 0


2583 RRTD 3 - Short / Low Temp RTD Alarm 0 2 1 - F115 0

2584 RRTD 3 - Assign Alarm Relays 0 7 1 - F113 1

2585 RRTD 3 - Short / Low Temp Alarm Events 0 1 1 - F103 0






↓ ↓





FACTORY DEFAULT



.... ReservedRRTD 4 – RTD #2



2628 RRTD 4 - RTD #2 Trip 0 2 1 - F115 02629 Enable A Remote RTD #2 Trip Voting 0 13 1 - F122 1262A RRTD 4 - RTD #2 Trip Relays 0 7 1 - F111 1262B RRTD 4 - RTD #2 Trip Level 1 200 1 °C F1 130262C RRTD 4 - RTD #2 RTD Type 0 3 1 - F120 0


↓ ↓







↓ ↓


... Reserved



2668 RRTD 4 - RTD #4 Trip 0 2 1 - F115 02669 Enable RRTD 4 - RTD #4 Trip Voting 0 13 1 - F122 1266A RRTD 4 - RTD #4 Trip Relays 0 7 1 - F111 1




FACTORY DEFAULT



266B RRTD 4 - RTD #4 Trip Level 1 200 1 °C F1 130266C RRTD 4 - RTD #4 RTD Type 0 3 1 - F120 0


↓ ↓


... Reserved





↓ ↓


... Reserved





↓ ↓


... Reserved

RRTD 4 – RTD #726C0 RRTD 4 - RTD #7 Application 0 4 1 - F121 026C1 RRTD 4 - RTD #7 High Alarm 0 2 1 - F115 026C2 RRTD 4 - RTD #7 High Alarm Relays 0 7 1 - F113 226C3 RRTD 4 - RTD #7 High Alarm Level 1 200 1 °C F1 13026C4 RRTD 4 - RTD #7 Alarm 0 2 1 - F115 0




FACTORY DEFAULT



26C5 RRTD 4 - RTD #7 Alarm Relays 0 7 1 - F113 126C6 RRTD 4 - RTD #7 Alarm Level 1 200 1 °C F1 130




↓ ↓


... Reserved





↓ ↓


... Reserved





↓ ↓





FACTORY DEFAULT








↓ ↓







↓ ↓


... Reserved



2768 RRTD 4 - RTD #12 Trip 0 2 1 - F115 02769 Enable RRTD 4 - RTD #12 Trip Voting 0 13 1 - F122 1276A RRTD 4 - RTD #12 Trip Relays 0 7 1 - F111 1




FACTORY DEFAULT



276B RRTD 4 - RTD #12 Trip Level 1 200 1 °C F1 130276C RRTD 4 - RTD #12 RTD Type 0 3 1 - F120 0


↓ ↓


... Reserved

RRTD 4 – OPEN RTD ALARM2780 RRTD 4- Open RTD Alarm 0 2 1 - F115 02781 RRTD 4 - Assign Alarm Relays 0 7 1 - F113 12782 RRTD 4 - Open RTD Alarm Events 0 1 1 - F103 0


2783 RRTD 4 - Short / Low Temp RTD Alarm 0 2 1 - F115 0

2784 RRTD 4 - Assign Alarm Relays 0 7 1 - F113 1

2785 RRTD 4 - Short / Low Temp Alarm Events 0 1 1 - F103 0

... Reserved - - - - - -RRTD 1 – OUTPUT RELAY SETUP

27A0 Trip Relay Reset Mode 0 2 1 - F117 027A1 Alarm Relay Reset Mode 0 2 1 - F117 027A2 Aux 1 Relay Reset Mode 0 2 1 - F117 027A3 Aux 2 Relay Reset Mode 0 2 1 - F117 027A4 Trip Relay Operation 0 1 1 - F161 027A5 Alarm Relay Operation 0 1 1 - F161 127A6 Aux1 Relay Operation 0 1 1 - F161 127A7 Aux2 Relay Operation 0 1 1 - F161 0... Reserved

RRTD 2 – OUTPUT RELAY SETUP27B0 Trip Relay Reset Mode 0 2 1 - F117 027B1 Alarm Relay Reset Mode 0 2 1 - F117 027B2 Aux 1 Relay Reset Mode 0 2 1 - F117 027B3 Aux 2 Relay Reset Mode 0 2 1 - F117 027B4 Trip Relay Operation 0 1 1 - F161 027B5 Alarm Relay Operation 0 1 1 - F161 127B6 Aux1 Relay Operation 0 1 1 - F161 127B7 Aux2 Relay Operation 0 1 1 - F161 0... Reserved

RRTD 3 – OUTPUT RELAY SETUP27C0 Trip Relay Reset Mode 0 2 1 - F117 027C1 Alarm Relay Reset Mode 0 2 1 - F117 027C2 Aux 1 Relay Reset Mode 0 2 1 - F117 027C3 Aux 2 Relay Reset Mode 0 2 1 - F117 027C4 Trip Relay Operation 0 1 1 - F161 027C5 Alarm Relay Operation 0 1 1 - F161 127C6 Aux1 Relay Operation 0 1 1 - F161 127C7 Aux2 Relay Operation 0 1 1 - F161 0... Reserved

RRTD 4 – OUTPUT RELAY SETUP27D0 Trip Relay Reset Mode 0 2 1 - F117 027D1 Alarm Relay Reset Mode 0 2 1 - F117 027D2 Aux 1 Relay Reset Mode 0 2 1 - F117 027D3 Aux 2 Relay Reset Mode 0 2 1 - F117 027D4 Trip Relay Operation 0 1 1 - F161 0




FACTORY DEFAULT



27D5 Alarm Relay Operation 0 1 1 - F161 127D6 Aux1 Relay Operation 0 1 1 - F161 127D7 Aux2 Relay Operation 0 1 1 - F161 0... Reserved

RRTD 1 – ANALOG OUTPUTS27E0 Enable Analog Output 1 0 1 1 - F103 0

27E1 Assign Analog Output 1 Output Range 0 2 1 - F26 0

27E2 Assign Analog Output 1 Parameter 12 24 1 - F127 1327E3 Analog Output 1 Minimum -40 200 1 - F4 -4027E4 Analog Output 1 Maximum -40 200 1 - F4 20027E5 Enable Analog Output 2 0 1 1 - F103 0

27E6 Assign Analog Output 2 Output Range 0 2 1 - F26 0

27E7 Assign Analog Output 2 Parameter 12 24 1 - F127 1327E8 Analog Output 2 Minimum -40 200 1 - F4 -4027E9 Analog Output 2 Maximum -40 200 1 - F4 20027EA Enable Analog Output 3 0 1 1 - F103 0

27EB Assign Analog Output 3 Output Range 0 2 1 - F26 0

27EC Assign Analog Output 3 Parameter 12 24 1 - F127 1327ED Analog Output 3 Minimum -40 200 1 - F4 -4027EE Analog Output 3 Maximum -40 200 1 - F4 20027EF Enable Analog Output 4 0 1 1 - F103 0

27F0 Assign Analog Output 4 Output Range 0 2 1 - F26 0

27F1 Assign Analog Output 4 Parameter 12 24 1 - F127 1327F2 Analog Output 4 Minimum -40 200 1 - F4 -4027F3 Analog Output 4 Maximum -40 200 1 - F4 200... Reserved

RRTD 2 – ANALOG OUTPUTS2800 Enable Analog Output 1 0 1 1 - F103 0

2801 Assign Analog Output 1 Output Range 0 2 1 - F26 0

2802 Assign Analog Output 1 Parameter 12 24 1 - F127 132803 Analog Output 1 Minimum -40 200 1 - F4 -402804 Analog Output 1 Maximum -40 200 1 - F4 2002805 Enable Analog Output 2 0 1 1 - F103 0


2807 Assign Analog Output 2 Parameter 12 24 1 - F127 132808 Analog Output 2 Minimum -40 200 1 - F4 -402809 Analog Output 2 Maximum -40 200 1 - F4 200280A Enable Analog Output 3 0 1 1 - F103 0

280B Assign Analog Output 3 Output Range 0 2 1 - F26 0

280C Assign Analog Output 3 Parameter 12 24 1 - F127 13280D Analog Output 3 Minimum -40 200 1 - F4 -40280E Analog Output 3 Maximum -40 200 1 - F4 200280F Enable Analog Output 4 0 1 1 - F103 0


2811 Assign Analog Output 4 Parameter 12 24 1 - F127 132812 Analog Output 4 Minimum -40 200 1 - F4 -402813 Analog Output 4 Maximum -40 200 1 - F4 200... Reserved




FACTORY DEFAULT











2831 Assign Analog Output 4 Parameter 12 24 1 - F127 132832 Analog Output 4 Minimum -40 200 1 - F4 -402833 Analog Output 4 Maximum -40 200 1 - F4 200... Reserved









2851 Assign Analog Output 4 Parameter 12 24 1 - F127 132852 Analog Output 4 Minimum -40 200 1 - F4 -402853 Analog Output 4 Maximum -40 200 1 - F4 2002854 Reserved

RRTD 1 – DIGITAL INPUT 2

2860 1st & 2nd Character of Digital Input 2 Name 32 127 1 - F22 ’GE’

↓ ↓




FACTORY DEFAULT



2865 11th & 12th Character of Digital Input 2 Name 32 127 1 - F22 ’GE’

2870 Digital Input 2 Type 0 1 1 - F116 02871 Reserved2872 Digital Input 2 Alarm 0 2 1 - F115 02873 Digital Input 2 Alarm Relays 0 6 1 - F113 02874 Digital Input 2 Alarm Delay 1 50000 1 100ms F2 502875 Digital Input 2 Alarm Events 0 1 1 - F103 02876 Digital Input 2 Trip 0 2 1 - F115 02877 Digital Input 2 Trip Relays 0 6 1 - F111 02878 Digital Input 2 Trip Delay 1 50000 1 100ms F2 502879 Digital Input 2 Assignable Function 0 3 1 - F163 0--- Reserved



↓ ↓


2890 Digital Input 5 Type 0 1 1 - F116 02891 Reserved2892 Digital Input 5 Alarm 0 2 1 - F115 02893 Digital Input 5 Alarm Relays 0 6 1 - F113 02894 Digital Input 5 Alarm Delay 1 50000 1 100ms F2 502895 Digital Input 5 Alarm Events 0 1 1 - F103 02896 Digital Input 5 Trip 0 2 1 - F115 02897 Digital Input 5 Trip Relays 0 6 1 - F111 02898 Digital Input 5 Trip Delay 1 50000 1 100ms F2 502899 Digital Input 5 Assignable Function 0 3 1 - F163 0... Reserved


28A0 1st & 2nd Character of Digital Input 4 Name 32 127 1 - F22 ’GE’

↓ ↓

28A5 11th & 12th Character of Digital Input 4 Name 32 127 1 - F22 ’GE’

28B0 Digital Input 4 Type 0 1 1 - F116 028B1 Reserved28B2 Digital Input 4 Alarm 0 2 1 - F115 028B3 Digital Input 4 Alarm Relays 0 6 1 - F113 028B4 Digital Input 4 Alarm Delay 1 50000 1 100ms F2 5028B5 Digital Input 4 Alarm Events 0 1 1 - F103 028B6 Digital Input 4 Trip 0 2 1 - F115 028B7 Digital Input 4 Trip Relays 0 6 1 - F111 028B8 Digital Input 4 Trip Delay 1 50000 1 100ms F2 5028B9 Digital Input 4 Assignable Function 0 3 1 - F163 0... Reserved


28C0 1st & 2nd Character of Digital Input 1 Name 32 127 1 - F22 ’GE’

↓ ↓

28C5 11th & 12th Character of Digital Input 1 Name 32 127 1 - F22 ’GE’

28D0 Digital Input 1 Type 0 1 1 - F116 028D1 Reserved28D2 Digital Input 1 Alarm 0 2 1 - F115 0




FACTORY DEFAULT



28D3 Digital Input 1 Alarm Relays 0 6 1 - F113 028D4 Digital Input 1 Alarm Delay 1 50000 1 100ms F2 5028D5 Digital Input 1 Alarm Events 0 1 1 - F103 028D6 Digital Input 1 Trip 0 2 1 - F115 028D7 Digital Input 1 Trip Relays 0 6 1 - F111 028D8 Digital Input 1 Trip Delay 1 50000 1 100ms F2 5028D9 Digital Input 1 Assignable Function 0 3 1 - F163 0... Reserved


28E0 1st & 2nd Character of Digital Input 6 Name 32 127 1 - F22 ’GE’

↓ ↓

28E5 11th & 12th Character of Digital Input 6 Name 32 127 1 - F22 ’GE’

28F0 Digital Input 6 Type 0 1 1 - F116 028F1 Reserved28F2 Digital Input 6 Alarm 0 2 1 - F115 028F3 Digital Input 6 Alarm Relays 0 6 1 - F113 028F4 Digital Input 6 Alarm Delay 1 50000 1 100ms F2 5028F5 Digital Input 6 Alarm Events 0 1 1 - F103 028F6 Digital Input 6 Trip 0 2 1 - F115 028F7 Digital Input 6 Trip Relays 0 6 1 - F111 028F8 Digital Input 6 Trip Delay 1 50000 1 100ms F2 5028F9 Digital Input 6 Assignable Function 0 3 1 - F163 0... Reserved



↓ ↓





↓ ↓


2930 Digital Input 2 Type 0 1 1 - F116 02931 Reserved2932 Digital Input 2 Alarm 0 2 1 - F115 02933 Digital Input 2 Alarm Relays 0 6 1 - F113 02934 Digital Input 2 Alarm Delay 1 50000 1 100ms F2 502935 Digital Input 2 Alarm Events 0 1 1 - F103 02936 Digital Input 2 Trip 0 2 1 - F115 0




FACTORY DEFAULT



2937 Digital Input 2 Trip Relays 0 6 1 - F111 02938 Digital Input 2 Trip Delay 1 50000 1 100ms F2 502939 Digital Input 2 Assignable Function 0 3 1 - F163 0... Reserved



↓ ↓





↓ ↓





↓ ↓






FACTORY DEFAULT





↓ ↓




29C0 1st & 2nd Character of Digital Input 3 Name 32 127 1 - F22 ’GE’

↓ ↓

29C5 11th & 12th Character of Digital Input 3 Name 32 127 1 - F22 ’GE’

29D0 Digital Input 3 Type 0 1 1 - F116 029D1 Reserved29D2 Digital Input 3 Alarm 0 2 1 - F115 029D3 Digital Input 3 Alarm Relays 0 6 1 - F113 029D4 Digital Input 3 Alarm Delay 1 50000 1 100ms F2 5029D5 Digital Input 3 Alarm Events 0 1 1 - F103 029D6 Digital Input 3 Trip 0 2 1 - F115 029D7 Digital Input 3 Trip Relays 0 6 1 - F111 029D8 Digital Input 3 Trip Delay 1 50000 1 100ms F2 5029D9 Digital Input 3 Assignable Function 0 3 1 - F163 0... Reserved


29E0 1st & 2nd Character of Digital Input 2 Name 32 127 1 - F22 ’GE’

↓ ↓

29E5 11th & 12th Character of Digital Input 2 Name 32 127 1 - F22 ’GE’

29F0 Digital Input 2 Type 0 1 1 - F116 029F1 Reserved29F2 Digital Input 2 Alarm 0 2 1 - F115 029F3 Digital Input 2 Alarm Relays 0 6 1 - F113 029F4 Digital Input 2 Alarm Delay 1 50000 1 100ms F2 5029F5 Digital Input 2 Alarm Events 0 1 1 - F103 029F6 Digital Input 2 Trip 0 2 1 - F115 029F7 Digital Input 2 Trip Relays 0 6 1 - F111 029F8 Digital Input 2 Trip Delay 1 50000 1 100ms F2 5029F9 Digital Input 2 Assignable Function 0 3 1 - F163 0... Reserved



↓ ↓




FACTORY DEFAULT




2A10 Digital Input 5 Type 0 1 1 - F116 02A11 Reserved2A12 Digital Input 5 Alarm 0 2 1 - F115 02A13 Digital Input 5 Alarm Relays 0 6 1 - F113 02A14 Digital Input 5 Alarm Delay 1 50000 1 100ms F2 502A15 Digital Input 5 Alarm Events 0 1 1 - F103 02A16 Digital Input 5 Trip 0 2 1 - F115 02A17 Digital Input 5 Trip Relays 0 6 1 - F111 02A18 Digital Input 5 Trip Delay 1 50000 1 100ms F2 502A19 Digital Input 5 Assignable Function 0 3 1 - F163 0... Reserved



↓ ↓





↓ ↓





↓ ↓


2A70 Digital Input 6 Type 0 1 1 - F116 02A71 Reserved2A72 Digital Input 6 Alarm 0 2 1 - F115 0




FACTORY DEFAULT



2A73 Digital Input 6 Alarm Relays 0 6 1 - F113 02A74 Digital Input 6 Alarm Delay 1 50000 1 100ms F2 502A75 Digital Input 6 Alarm Events 0 1 1 - F103 02A76 Digital Input 6 Trip 0 2 1 - F115 02A77 Digital Input 6 Trip Relays 0 6 1 - F111 02A78 Digital Input 6 Trip Delay 1 50000 1 100ms F2 502A79 Digital Input 6 Assignable Function 0 3 1 - F163 0... Reserved



↓ ↓




2AA0 1st & 2nd Character of Digital Input 2 Name 32 127 1 - F22 ’GE’

↓ ↓

2AA5 11th & 12th Character of Digital Input 2 Name 32 127 1 - F22 ’GE’

2AB0 Digital Input 2 Type 0 1 1 - F116 02AB1 Reserved2AB2 Digital Input 2 Alarm 0 2 1 - F115 02AB3 Digital Input 2 Alarm Relays 0 6 1 - F113 02AB4 Digital Input 2 Alarm Delay 1 50000 1 100ms F2 502AB5 Digital Input 2 Alarm Events 0 1 1 - F103 02AB6 Digital Input 2 Trip 0 2 1 - F115 02AB7 Digital Input 2 Trip Relays 0 6 1 - F111 02AB8 Digital Input 2 Trip Delay 1 50000 1 100ms F2 502AB9 Digital Input 2 Assignable Function 0 3 1 - F163 0... Reserved


2AC0 1st & 2nd Character of Digital Input 5 Name 32 127 1 - F22 ’GE’

↓ ↓

2AC5 11th & 12th Character of Digital Input 5 Name 32 127 1 - F22 ’GE’

2AD0 Digital Input 5 Type 0 1 1 - F116 02AD1 Reserved2AD2 Digital Input 5 Alarm 0 2 1 - F115 02AD3 Digital Input 5 Alarm Relays 0 6 1 - F113 02AD4 Digital Input 5 Alarm Delay 1 50000 1 100ms F2 502AD5 Digital Input 5 Alarm Events 0 1 1 - F103 02AD6 Digital Input 5 Trip 0 2 1 - F115 0




FACTORY DEFAULT



2AD7 Digital Input 5 Trip Relays 0 6 1 - F111 02AD8 Digital Input 5 Trip Delay 1 50000 1 100ms F2 502AD9 Digital Input 5 Assignable Function 0 3 1 - F163 0... Reserved


2AE0 1st & 2nd Character of Digital Input 4 Name 32 127 1 - F22 ’GE’

↓ ↓

2AE5 11th & 12th Character of Digital Input 4 Name 32 127 1 - F22 ’GE’

2AF0 Digital Input 4 Type 0 1 1 - F116 02AF1 Reserved2AF2 Digital Input 4 Alarm 0 2 1 - F115 02AF3 Digital Input 4 Alarm Relays 0 6 1 - F113 02AF4 Digital Input 4 Alarm Delay 1 50000 1 100ms F2 502AF5 Digital Input 4 Alarm Events 0 1 1 - F103 02AF6 Digital Input 4 Trip 0 2 1 - F115 02AF7 Digital Input 4 Trip Relays 0 6 1 - F111 02AF8 Digital Input 4 Trip Delay 1 50000 1 100ms F2 502AF9 Digital Input 4 Assignable Function 0 3 1 - F163 0... Reserved


2B00 1st & 2nd Character of Digital Input 1 Name 32 127 1 - F22 ’GE’

↓ ↓

2B05 11th & 12th Character of Digital Input 1 Name 32 127 1 - F22 ’GE’




↓ ↓






FACTORY DEFAULT





↓ ↓



RRTD 1 – TEST OUPUT RELAYS2B60 Force Trip Relay 0 2 1 - F150 02B61 Force Trip Relay Duration 0 300 1 s F1 02B62 Force AUX1 Relay 0 2 1 - F150 02B63 Force AUX1 Relay Duration 0 300 1 s F1 02B64 Force AUX2 Relay 0 2 1 - F150 02B65 Force AUX2 Relay Duration 0 300 1 s F1 02B66 Force Alarm Relay 0 2 1 - F150 02B67 Force Alarm Relay Range 01 300 1 s F1 0... Reserved



RRTD 4 – TEST OUPUT RELAYS2B90 Force Trip Relay 0 2 1 - F150 02B91 Force Trip Relay Duration 0 300 1 s F1 02B92 Force AUX1 Relay 0 2 1 - F150 02B93 Force AUX1 Relay Duration 0 300 1 s F1 02B94 Force AUX2 Relay 0 2 1 - F150 02B95 Force AUX2 Relay Duration 0 300 1 s F1 0




FACTORY DEFAULT



2B96 Force Alarm Relay 0 2 1 - F150 02B97 Force Alarm Relay Range 0 300 1 s F1 0... Reserved

RRTD 1 – TEST ANALOG OUTPUTS2BA0 Force Analog Outputs 0 1 1 - F126 02BA1 Analog Output 1 Forced Value 0 100 1 % range F1 02BA2 Analog Output 2 Forced Value 0 100 1 % range F1 02BA3 Analog Output 3 Forced Value 0 100 1 % range F1 02BA4 Analog Output 4 Forced Value 0 100 1 % range F1 0... Reserved

RRTD 2 – TEST ANALOG OUTPUTS2BB0 Force Analog Outputs 0 1 1 - F126 02BB1 Analog Output 1 Forced Value 0 100 1 % range F1 02BB2 Analog Output 2 Forced Value 0 100 1 % range F1 02BB3 Analog Output 3 Forced Value 0 100 1 % range F1 02BB4 Analog Output 4 Forced Value 0 100 1 % range F1 0... Reserved

RRTD 3 – TEST ANALOG OUTPUTS2BC0 Force Analog Outputs 0 1 1 - F126 02BC1 Analog Output 1 Forced Value 0 100 1 % range F1 02BC2 Analog Output 2 Forced Value 0 100 1 % range F1 02BC3 Analog Output 3 Forced Value 0 100 1 % range F1 02BC4 Analog Output 4 Forced Value 0 100 1 % range F1 0... Reserved

RRTD 4 – TEST ANALOG OUTPUTS2BD0 Force Analog Outputs 0 1 1 - F126 02BD1 Analog Output 1 Forced Value 0 100 1 % range F1 02BD2 Analog Output 2 Forced Value 0 100 1 % range F1 02BD3 Analog Output 3 Forced Value 0 100 1 % range F1 02BD4 Analog Output 4 Forced Value 0 100 1 % range F1 0... Reserved

RRTD 1 – DIGITAL COUNTER2BE0 First Character of Counter Name 32 127 1 - F1 “G”

2BEC First Character of Counter Unit Name 32 127 1 - F1 ‘U’

2BF2 Counter Type 0 1 1 - F114 02BF3 Digital Counter Alarm 0 2 1 - F115 02BF4 Assign Alarm Relays 0 6 1 - F113 02BF5 Counter Alarm Level 0 65535 1 - F1 1002BF7 Reserved - - - - - -2BF8 Record Alarms as Events 0 1 1 - F103 0... Reserved

RRTD 2 – DIGITAL COUNTER2C00 First Character of Counter Name 32 127 1 - F1 “G”

2C0C First Character of Counter Unit Name 32 127 1 - F1 ‘U’

2C12 Counter Type 0 1 1 - F114 02C13 Digital Counter Alarm 0 2 1 - F115 02C14 Assign Alarm Relays 0 6 1 - F113 02C15 Counter Alarm Level 0 65535 1 - F1 1002C17 Reserved - - - - - -2C18 Record Alarms as Events 0 1 1 - F103 0... Reserved




FACTORY DEFAULT









EVENT RECORDER / TRACE MEMORY / MOTOR START DATA LOGGER (ADDRESSES 3000 TO 3FFF)EVENT RECORDER

3000 Event Recorder Last Reset (2 words) N/A N/A N/A N/A F18 N/A

3002 Total Number of Events Since Last Clear 0 65535 1 N/A F1 0

3003 Event Record Selector (1=oldest, 512=newest) 1 512 1 N/A F1 1

3004 Cause of Event 0 281 1 - F134 03005 Time of Event (2 words) N/A N/A N/A N/A F19 N/A3007 Date of Event (2 words) N/A N/A N/A N/A F18 N/A3009 Motor Speed During Event 0 2 1 N/A F186 N/A... Reserved300B Event Phase A Current 0 65535 1 A F1 0300C Event Phase B Current 0 65535 1 A F1 0300D Event Phase C Current 0 65535 1 A F1 0300E Event Motor Load 0 2000 1 FLA F3 0300F Event Current Unbalance 0 100 1 % F1 03010 Event Ground Current 0 50000 1 A F23 03011 Event Hottest Stator RTD Owner 0 5 1 N/A F165 03012 Event Hottest Stator RTD 0 12 1 - F1 0

3013 Event Temperature of Hottest Stator RTD -40 200 1 o C F4 0

... Reserved301A Event Voltage Vab 0 20000 1 V F1 0301B Event Voltage Vbc 0 20000 1 V F1 0301C Event Voltage Vca 0 20000 1 V F1 0301D Event Voltage Van 0 20000 1 V F1 0301E Event Voltage Vbn 0 20000 1 V F1 0301F Event Voltage Vcn 0 20000 1 V F1 03020 Event System Frequency 0 12000 1 Hz F3 03021 Event Real Power -32000 32000 1 kW F4 03022 Event Reactive Power -32000 32000 1 kvar F4 03023 Event Apparent Power 0 50000 1 kVA F1 0




FACTORY DEFAULT



3024 Event Power Factor -99 100 1 - F21 0... Reserved

WAVEFORM CAPTURE / MOTOR START DATA LOGGER

30EF Buffer Memory Access Type 0 2 1 - F184 0 (Trace Memory)

30F0 Trace Memory Clear Date N/A N/A N/A N/A F18 N/A30F2 Trace Memory Clear Time N/A N/A N/A N/A F19 N/A

30F4 Trace Memory Triggers Since Last Clear 0 65535 1 - F1 0

30F5Trace Memory Buffer Selector 0 3 1 - F1 0

Motor Start Log Buffer Selector 0 6 1 - F1 0 (None Selected)

30F6Trace Memory Channel Selector 0 6 1 - F1 0

Motor Start Log Channel Selector 0 11 1 - F1 0 (None Selected)

30F7Trace Memory Trigger Date N/A N/A N/A N/A F18 N/AMotor Start Log Trigger Date N/A N/A N/A N/A F18 N/A

30F9Trace Memory Trigger Time N/A N/A N/A N/A F19 N/AMotor Start Log Trigger Time N/A N/A N/A N/A F19 N/A

30FB1Trace Memory Trigger Cause 0 2 1 - F85 N/ANumber of Recorded Motor Start Logs 0 6 1 - F1 0

30FC1Trace Memory Trigger Index 0 100 1 % F1 N/AMotor Start Log Phase Voltage Type 0 1 1 - F185 N/A

... Reserved

3100First Trace Memory Sample -32767 32767 1 - F4 N/AFirst Memory Sample -32767 32767 1 - F4 N/A

↓ ↓

31FFLast Trace Memory Sample -32767 32767 1 - F4 N/ALast Memory Sample -32767 32767 1 - F4 N/A

DATA LOGGER LOG HEADER3200 Log Time Interval 1 3600 1 s F1 36003201 Log Record Size 0 16 - Words F1 N/A3202 Log Total Possible Records 0 16256 1 - F1 N/A3203 Total Logs Since Last Clear 0 65535 1 - F1 03204 Total Logs Presently Used 0 50 1 - F1 03205 Total Records Presently Used 0 16256 1 - F1 0

3206 Log Status 0 1 1 - F190 0 = Stopped

3207 Log Time Until next Reading 1 3600 1 s F1 36003208 Data Logger Percentage Full 0 100 1 % F1 03209 Date of Latest Record - - - - F18 -320B Time of Latest record - - - - F19 -

320D Address Pointer To Next Record To Write 0 16255 1 - F1 0

320E Pointer to 1st Log Start Address 0 16255 1 - F1 N/A320F 1st Log Number of Records 0 16256 1 - F1 N/A... ... ... ... ... ... ... ...3270 Pointer to 50th Log Start Address 0 16255 1 F1 N/A3271 50th Log Number of Records 0 16256 1 - F1 N/A3272 Log 1-8 Start/Stop Method 0 FFFF N/A - F191 N/A3273 Log 9-16 Start/Stop Method 0 FFFF N/A - F191 N/A3274 Log 17-24 Start/Stop Method 0 FFFF N/A - F191 N/A3275 Log 25-32 Start/Stop Method 0 FFFF N/A - F191 N/A3276 Log 33-40 Start/Stop Method 0 FFFF N/A - F191 N/A3277 Log 41-48 Start/Stop Method 0 FFFF N/A - F191 N/A




FACTORY DEFAULT



3278 Log 49-50 Start/Stop Method 0 FFFF N/A - F191 N/ADATA LOGGER DATA

3280 Data Log Memory Access Block Number 0 255 1 F1 0

3281 Data Log Register 1 - - - - F1 -3282 Data Log Register 2 - - - - F1 -3283 Data Log Register 3 - - - - F1 -3284 Data Log Register 4 - - - - F1 -... ... ... ... ... ... ... ...32BF Data Log Register 63 - - - - F1 -32C0 Data Log Register 64 - - - - F1 -32C1 Reserved... ... ... ... ... ... ... ...3FFF Reserved

1. Addresses 0x030FB and 0x30FC have different functionality, depending on which functionality is selected in address 0x30EF, Waveform Capture, Motor Start Data Logger




FACTORY DEFAULT



6.8 Format Codes

Table 16: Memory Map Data Formats (Sheet 1 of 26)

CODE TYPE DEFINITION

F1 16 bits UNSIGNED VALUEExample: 1234 stored as 1234

F2 16 bits UNSIGNED VALUE, 1 DECIMAL PLACEExample: 123.4 stored as 1234

F3 16 bits UNSIGNED VALUE, 2 DECIMAL PLACESExample: 12.34 stored as 1234

F4 16 bits 2’s COMPLEMENT SIGNED VALUEExample: -1234 stored as -1234 (i.e. 64302)

F5 16 bits 2’s COMPLEMENT SIGNED VALUE, 1 DECIMAL PLACESExample: -123.4 stored as -1234 (i.e. 64302)




F13 16 bits INSTALLED OPTIONS

xxxx xxxx xxxx xxx1 Profibus-DP (0 = Not Installed, 1 = Installed)

xxxx xxxx xxxx xx1x Fiber Optic (0 = Not Installed, 1 = Installed)

xxxx xxxx xxxx x1xx Metering (0 = Not Installed, 1 = Installed)

xxxx xxxx xxxx 1xxx Backspin (0 = Not Installed, 1 = Installed)

xxxx xxxx xxx1 xxxx Local RTD (0 = Not Installed, 1 = Installed)

xxxx xxxx xx1x xxxx Power Supply Type (0 = LO, 1 = HI)

xxxx xxxx 1xxx xxxx Modbus/TCP (0 = Not Installed, 1 = Installed)

xxxx xxx1 xxxx xxxx DeviceNet (0 = Not Installed, 1 = Installed)

xxxx xx1x xxxx xxxx Harsh Environment (0 = Not Installed, 1 = Installed)

xxxx x1xx xxxx xxxx Profibus-DPV1 (0 = Not Installed, 1 = Installed)

xxxx 1xxx xxxx xxxx Enhanced Diagnostics (0 = Not Installed, 1 = Installed)

F14 16 bits INSTALLED MODIFICATIONS

0000 0111 xxxx xxxx CT Configuration range from 1 to 4

0000 0xxx 1111 xxxx FS-NFS Configuration range from 1 to 8

0000 0xxx xxxx 1111 NO-NC Arrangement range from 1 to 8

0000 0000 0000 0000 No Installed Modification (Default)

F15 16 bits HARDWARE REVISION

0000 0000 0000 0001 1 = A



0000 0000 0000 0010 2 = B

0000 0000 0000 0011 3 = C

0000 0000 0001 1010 26 = Z

F16 16 bits SOFTWARE REVISION

1111 1111 xxxx xxxx Major Revision Number, 0 to 9 in steps of 1

xxxx xxxx 1111 1111 Minor Revision Number (two BCD digits), 00 to 99 in steps of 1Example: Revision 2.30 stored as 0230 hex

F18 32 bitsDATE (MM/DD/YYYY)Example: Feb. 20, 1995 stored as 34867142 (i.e. 1st word: 0214, 2nd word 07C6)

1st byte Month (1 to 12)

2nd byte Day (1 to 31)

3rd and 4th byte Year (1998 to 2097)

F19 32 bitsTIME (HH:MM:SS:hh)Example: 2:05pm stored as 235208704 (i.e. 1st word: 0E05, 2nd word 0000)

1st byte Hours (0 to 23)

2nd byte Minutes (0 to 59)

3rd byte Seconds (0 to 59)

4th byte Hundreds of seconds (0 to 99) - Not used by 369

F20 16 bits 2’s COMPLEMENT SIGNED LONG VALUEExample: 1234 stored as 1234. Note: -1 means “Never”

F21 16 bits2’s COMPLEMENT SIGNED VALUE, 2 DECIMAL PLACES (Power Factor)Example: Power Factor of 0.87 lag is used as 87 (i.e. 0057)

< 0 Leading Power Factor - Negative

> 0 Lagging Power Factor - Positive

F22 16 bits TWO 8-BIT CHARACTERS PACKED INTO 16-BIT UNSIGNEDExample: String "AB" stored as 4142 hex.

MSB First Character

LSB Second Character

F23 16 Bits

UNSIGNED VALUE (For 1A/5 A CT, 1Decimal Place) (For 50: 0.025 A CT, 2 Decimal Places)Example: For 1A/5A CT, G/F current = 1000.0 AExample: For 50: 0.025 A CT, G/F current = 25.00

F26 16 Bits ANALOG OUTPUT SELECTION

0 0 - 1mA

1 0 - 20 mA

2 4 - 20 mA

F27 16 Bits BACKSPIN DETECTION STATE





0 Motor Running

1 No Backspin

2 Slowdown

3 Acceleration

4 ---

5 Backspinning

6 Prediction

7 Soon to Restart

F30 16 Bits DISABLE/ENABLE SELECTION

0 Disabled

1 Enabled

F31 16 Bits COMMAND FUNCTION CODES

0 Not in use

1 Reset 369

2 Motor Start

3 Motor Stop

4 Waveform Trigger

5 Reserved

6 Clear Trip Counters

7 Clear Last Trip Data

8 Reserved

9 Reserved

10 Clear RTD Maximums

11 Reset Motor Info

12 Clear/Reset all Data

20 Block/Unblock Protection Functions

21 Force Output Relays

F85 Unsigned 16 bit integer WAVEFORM CAPTURE TRIGGER CAUSE

0 None

1 Manual

2 Automatic

F100 Unsigned 16 bit integer TEMPERATURE DISPLAY UNITS

0 Celsius

1 Fahrenheit





F101 Unsigned 16 bit integer BAUD RATE

0 1200 baud

1 2400 baud

2 4800 baud

3 9600 baud

4 19200 baud

F102 Unsigned 16 bit integer PARITY

0 None

1 Odd

2 Even

F103 Unsigned 16 bit integer OFF/ON OR NO/YES SELECTION

0 Off / No

1 On / Yes

F104 Unsigned 16 bit integer GROUND CT TYPE

0 None

1 1 A Secondary

2 5 A Secondary

3 Multilin CT 50/0.025

F105 Unsigned 16 bit integer CT TYPE

0 None

1 1 A Secondary

2 5 A Secondary

F106 Unsigned 16 bit integer VOLTAGE TRANSFORMER CONNECTION TYPE

0 None

1 Open Delta

2 Wye

F107 Unsigned 16 bit integer NOMINAL FREQUENCY

0 60 Hz

1 50 Hz

2 Variable

F108 Unsigned 16 bit integer REDUCED VOLTAGE STARTING TRANSITION ON

0 Current Only

1 Current or Timer

2 Current and Timer





F109 Unsigned 16 bit integer STARTER STATUS SWITCH

0 Starter Aux a (52a)

1 Starter Aux b (52b)

F110 Unsigned 16 bit integer EMERGENCY RESTART SWITCH INPUT FUNCTION

0 Off

1 Emergency Switch

2 General Switch

3 Digital Counter

4 Waveform Capture

5 DeviceNet Control

6 Speed Switch1

7 Reserved

F111 Unsigned 16 bit integer TRIP RELAYS

0 none

1 Trip

2 Aux1

3 Aux2

4 Trip & Aux1

5 Trip & Aux2

6 Aux1 & Aux2

7 Trip & Aux1 & Aux2

F112 Unsigned 16 bit integer NOT DEFINED

0

1

F113 Unsigned 16 bit integer ALARM RELAYS

0 None

1 Alarm

2 Aux1

3 Aux2

4 Alarm & Aux1

5 Alarm & Aux2

6 Aux1 & Aux2

7 Alarm & Aux1 & Aux2





F114 Unsigned 16 bit integer COUNTER TYPE

0 Increment

1 Decrement

F115 Unsigned 16 bit integer ALARM/TRIP TYPE SELECTION

0 Off

1 Latched

2 Unlatched

F116 Unsigned 16 bit integer SWITCH TYPE

0 Normally Open

1 Normally Closed

F117 Unsigned 16 bit integer RESET MODE

0 All Resets

1 Remote Reset Only

2 Local Reset Only

F119 Unsigned 16 bit integer BACKUP RELAYS

0 None

1 Aux 1

2 Aux1 & Aux2

3 Aux2

F120 Unsigned 16 bit integer RTD TYPE

0 100 Ohm Platinum

1 120 Ohm Nickel

2 100 Ohm Nickel

3 10 Ohm Copper

F121 Unsigned 16 bit integer RTD APPLICATION

0 None

1 Stator

2 Bearing

3 Ambient

4 Other

F122 Unsigned 16 bit integer LOCAL/REMOTE RTD VOTING SELECTION

0 Off

1 RTD #1

2 RTD #2





3 RTD #3

4 RTD #4

5 RTD #5

6 RTD #6

7 RTD #7

8 RTD #8

9 RTD #9

10 RTD #10

11 RTD #11

12 RTD #12

13 All Stator

F123 Unsigned 16 bit integer ALARM STATUS

0 Off

1 Not Active

2 Timing Out

3 Active

4 Latched

F124 Unsigned 16 bit integer PHASE ROTATION AT MOTOR TERMINALS

0 ABC

1 ACB

F125 Unsigned 16 bit integer STARTER TYPE

0 Breaker

1 Contactor

F127 Unsigned 16 bit integer ANALOG OUTPUT PARAMETER SELECTION

0 Phase A Current

1 Phase B Current

2 Phase C Current

3 Average Phase Current

4 AB Line Voltage

5 BC Line Voltage

6 CA Line Voltage

7 Average Line Voltage

8 Phase AN Voltage

9 Phase BN Voltage





10 Phase CN Voltage

11 Average Phase Voltage

12 Hottest Stator RTD

13 Local RTD #1

14 Local RTD #2

15 Local RTD #3

16 Local RTD #4

17 Local RTD #5

18 Local RTD #6

19 Local RTD #7

20 Local RTD #8

21 Local RTD #9

22 Local RTD #10

23 Local RTD #11

24 Local RTD #12

25 Power Factor

26 Reactive Power (kvar)

27 Real Power (kW)

28 Apparent Power (KVA)

29 Thermal Capacity Used

30 Relay Lockout Time

31 Reserved

32 Reserved

33 Reserved

34 Reserved

35 Motor Load

36 MWhrs

F128 Unsigned 16 bit integer CURVE STYLE

0 Standard

1 Custom

F130 Unsigned 16 bit integer DIGITAL INPUT PICKUP TYPE

0 Over

1 Under

F131 Unsigned 16 bit integer INPUT SWITCH STATUS





0 Open

1 Closed

F133 Unsigned 16 bit integer MOTOR STATUS

0 Stopped

1 Starting

2 Running

3 Overloaded

4 Tripped

F134 Unsigned 16 bit integer CAUSE OF EVENT

0 No Event

1 Forced Setpoints Dump

2 Speed Switch Trip

3 Differential Switch Trip

4 Reserved

5 Spare Switch Trip

6 Emergency Switch Trip

7 Unexpected Reset

8 EEPROM Memory

9 Reset Switch Trip

10 Upgrade Default Dump

11 Overload Trip

12 Short Circuit Trip

13 Short Circuit Backup Trip

14 Mechanical Jam Trip

15 Undercurrent Trip

16 Current Unbalance Trip

17 Single Phasing Trip

18 Ground Fault Trip

19 Ground Fault Backup Trip





20 Overload Block

21 Acceleration Timer Trip

22 Start Inhibit Block

23 Starts Hour Block

24 Time Between Starts Block

25 Restart Block

26 Backspin Block

27 Single Shot Restart

28 Undervoltage Trip

29 Overvoltage Trip

30 Voltage Phase Reversal Trip

31 Underfrequency Trip

32 Overfrequency Trip

33 Lead Power Factor Trip

34 Lag Power Factor Trip

35 Positive Kvar Trip

36 Negative Kvar Trip

37 Underpower Trip

38 Reverse Power Trip

39 RTD1 Trip

40 RTD2 Trip

41 RTD3 Trip

42 RTD4 Trip

43 RTD5 Trip

44 RTD6 Trip

45 RTD7 Trip

46 RTD8 Trip

47 RTD9 Trip





48 RTD10 Trip

49 RTD11 Trip

50 RTD12 Trip

51 Reserved

52 Reserved

53 Spare Switch Alarm

54 Emergency Switch Alarm

55 Diff Switch Alarm

56 Speed Switch Alarm

57 Reset Switch Alarm

58 Reserved

59 Thermal Capacity Alarm

60 Overload Alarm

61 Mechanical Jam Alarm

62 Undercurrent Alarm

63 Current Unbalance Alarm

64 Ground Fault Alarm

65 Undervoltage Alarm

66 Overvoltage Alarm

67 Overfrequency Alarm

68 Underfrequency Alarm

69 Lead Power Factor Alarm

70 Lag Power Factor Alarm

71 Positive Kvar Alarm

72 Negative Kvar Alarm

73 Underpower Alarm

74 Reverse Power Alarm

75 RTD1 Alarm





76 RTD2 Alarm

77 RTD3 Alarm

78 RTD4 Alarm

79 RTD5 Alarm

80 RTD6 Alarm

81 RTD7 Alarm

82 RTD8 Alarm

83 RTD9 Alarm

84 RTD10 Alarm

85 RTD11 Alarm

86 RTD12 Alarm

87 RTD1 Hi Alarm

88 RTD2 Hi Alarm

89 RTD3 Hi Alarm

90 RTD4 Hi Alarm

91 RTD5 Hi Alarm

92 RTD6 Hi Alarm

93 RTD7 Hi Alarm

94 RTD8 Hi Alarm

95 RTD9 Hi Alarm

96 RTD10 Hi Alarm

97 RTD11 Hi Alarm

98 RTD12 Hi Alarm

99 Reserved

100 Lost RTD Comm Alarm

101 Low RTD Alarm

102 Trip Counter Alarm

103 Current Demand Alarm





104 Kw Demand Alarm

105 Kvar Demand Alarm

106 Kva Demand Alarm

107 Digital Counter Alarm

108 Service Alarm

109 Control Power Lost

110 Control Power App

111 Emergency Restart Closed

112 Emergency Restart Open

113 Start While Blocked

114 Reserved

115 Breaker Failure

116 Welded Contactor

117 Incomplete Sequence Trip

118 Reserved

119 Reserved

120 Reserved

121 RRTD1 RTD1 Trip

122 RRTD1 RTD2 Trip

123 RRTD1 RTD3 Trip

124 RRTD1 RTD4 Trip

125 RRTD1 RTD5 Trip

126 RRTD1 RTD6 Trip

127 RRTD1 RTD7 Trip

128 RRTD1 RTD8 Trip

129 RRTD1 RTD9 Trip

130 RRTD1 RTD10 Trip







133 RRTD2 RTD1 Trip

134 RRTD2 RTD2 Trip

135 RRTD2 RTD3 Trip

136 RRTD2 RTD4 Trip

137 RRTD2 RTD5 Trip

138 RRTD2 RTD6 Trip

139 RRTD2 RTD7 Trip

140 RRTD2 RTD8 Trip

141 RRTD2 RTD9 Trip




145 RRTD3 RTD1 Trip

146 RRTD3 RTD2 Trip

147 RRTD3 RTD3 Trip

148 RRTD3 RTD4 Trip

149 RRTD3 RTD5 Trip

150 RRTD3 RTD6 Trip

151 RRTD3 RTD7 Trip

152 RRTD3 RTD8 Trip

153 RRTD3 RTD9 Trip




157 RRTD4 RTD1 Trip

158 RRTD4 RTD2 Trip

159 RRTD4 RTD3 Trip





160 RRTD4 RTD4 Trip

161 RRTD4 RTD5 Trip

162 RRTD4 RTD6 Trip

163 RRTD4 RTD7 Trip

164 RRTD4 RTD8 Trip

165 RRTD4 RTD9 Trip




169 RRTD1 RTD1 Alarm












181 RRTD1 RTD1 Hi Alarm
















193 RRTD1 Open RTD Alarm

194 RRTD1 Low RTD Alarm



























273 Power Failure

274 Software Reset

275 Clock Failure

276 A/D Failure

277 Autorestart Attempt

278 Autorestart Success

279 Autorestart Aborted 1





284 Motor Running

285 Motor Stopped

286 Fieldbus Comms Reset

287 RTD 1 Open Alarm












299 Starter Operation Monitor Alarm





300 Starter Operation Monitor Trip

301 Block Undercurrent/Underpower (37)

302 Unblock Undercurrent/Underpower (37)

303 Block Current Unbalance (46)

304 Unblock Current Unbalance (46)

305 Block Incomplete Sequence (48)

306 Unblock Incomplete Sequence (48)

307 Block Thermal Model (49)

308 Unblock Thermal Model (49)

309 Block Short Circuit and Backup (50)

310 Unblock Short Circuit and Backup (50)

311 Block Overload Alarm (51)

312 Unblock Overload Alarm (51)

313 Block Ground Fault (51G)

314 Unblock Ground Fault (51G)

315 Block Starts Per Hour and Time Between Starts (66)

316 Unblock Starts Per Hour and Time Between Starts (66)

317 Fieldbus Loss of Communications

318 UVR Trip

319 UVR Undervoltage On

320 UVR Undervoltage Off

321 UVR In Progress On

322 UVR In Progress Off

323 UVR Close On

324 UVR Close Off

325 UVR Imm. Restart On

326 UVR Imm. Restart Off

327 UVR Stop On

328 UVR Stop Off

329 Motor Starting





330 Firmware Downloaded

331 Diagnostic Message 1*








F138 Reserved Reserved

F139 Reserved Reserved

F141 Unsigned 16 bit integer OUTPUT RELAY STATUS

bit 0 Trip

bit 1 Alarm

bit 2 Auxiliary 1

bit 3 Auxiliary 2

F149 Unsigned 16 Bit Integer CHANNEL 3 APPLICATION

0 MODBUS

1 Remote RTD

F150 Unsigned 16 Bit Integer OUTPUT RELAY STATUS

0 De - Energized

1 Energized

F151 Unsigned 16 Bit Integer CHANNEL TYPE

0 RS 485

1 Fiber Optic

F152 Unsigned 16 Bit Integer NUMBER OF RECORDS

0 1 × 64 cycles

1 2 × 32 cycles

2 4 × 16 cycles

3 8 × 8 cycles

F156 Unsigned 16 Bit Integer REMOTE RTD COMMUNICATION STATUS

0 Remote RTD Module Communication Lost

1 Remote RTD Communication on Line





F157 Unsigned 16 Bit Integer DIFFERENTIAL SWITCH INPUT FUNCTION

0 OFF

1 Differential Switch

2 General Switch

3 Digital Counter

4 Waveform Capture

5 DeviceNet Control

6 Reserved

7 Reserved

F158 Unsigned 16 Bit Integer SPEED SWITCH INPUT FUNCTION

0 OFF

1 Speed Switch

2 General Switch

3 Digital Counter

4 Waveform Capture

5 DeviceNet Control

6 Two-speed Monitor1

7 Reserved

F159 Unsigned 16 Bit Integer SPARE SWITCH INPUT FUNCTION

0 OFF

1 Starter Status Switch

2 General Switch

3 Digital Counter

4 Waveform Capture

5 DeviceNet Control

6 Reserved

7 Reserved

F160 Unsigned 16 Bit Integer RESET SWITCH INPUT FUNCTION

0 OFF

1 Reset Switch

2 General Switch

3 Digital Counter

4 Waveform Capture





5 DeviceNet Control

6 Speed Switch1

7 Reserved

F161 Unsigned 16 Bit Integer OUTPUT RELAY FAILSAFE CODE

0 Failsafe

1 Non Failsafe

F162 Unsigned 16 Bit Integer ACCESS LEVEL

0 Read Only

1 Read / Write

2 Factory Service

F163 Unsigned 16 Bit Integer RRTD DIGITAL INPUT FUNCTION

0 Off

1 undefined

2 General Switch

3 Digital Counter

F164 Unsigned 16 Bit Integer COMMUNICATIONS MODULE STATUS

0x0001 Ethernet Connection OK

0x0002 IP Configuration OK

0x0004 IP Address Error

0x0008 Communications Module Error

0x0010 Network Activity Present

F165 Unsigned 16 Bit Integer OVERALL HOTTEST STATOR RTD OWNER

0 No RTDs programmed or available

1 Remote RTD #1

2 Remote RTD #2

3 Remote RTD #3

4 Remote RTD #4

5 Local 369

F166 Unsigned 16 Bit Integer ENERGY UNIT DISPLAY

0 Mega

1 Kilo

F169 Unsigned 16 Bit Integer TRIP AND ALARM RELAYS

0 None





1 Trip

2 Alarm

3 Aux1

4 Aux2

5 Trip and Alarm

6 Trip and Aux1

7 Trip and Aux2

8 Alarm and Aux1

9 Alarm and Aux2

10 Aux1 and Aux2

11 Trip and Alarm and Aux1

12 Trip and Alarm and Aux2

13 Trip and Aux1 and Aux2

14 Alarm and Aux1 and Aux2

15 All Relays

F180 Unsigned 16 Bit Integer ANSI/IEEE DEVICE

0 37 - Undercurrent/Underpower

1 46 - Current Unbalance

2 48 - Incomplete Sequence

3 49 - Thermal Model

4 50 - Short Circuit and Backup

5 51 - Overload Alarm

6 51G - Ground Fault

7 66 - Starts Per Hour / Time Between Starts

F181 Unsigned 16 Bit Integer OUTPUT RELAY TYPE

0 Latched

1 Pulsed

F182 Unsigned 16 Bit Integer PROTECTION FUNCTION BLOCKING STATUS

0 Not Blocked

1 Blocked

F183 16 bits ACTIVELY COMMUNICATING RRTDs

xxxx xxxx xxxx 0000 No RRTDs Actively Communicating

xxxx xxxx xxxx xxx1 RRTD1 Communicating

xxxx xxxx xxxx xx1x RRTD2 Communicating





xxxx xxxx xxxx x1xx RRTD3 Communicating

xxxx xxxx xxxx 1xxx RRTD4 Communicating

F184 Unsigned 16 bit Integer DATA RECORD ACCESS TYPE

0 Access Trace Memory data

1 Access Motor Start Data Logger data

F185 Unsigned 16 bit Integer VT CONNECTION TYPE

0 Phase-Neutral Voltage

1 Phase-Phase Voltage

F186 Unsigned 16 bit Integer MOTOR SPEED

0 Not Programmed

1 Speed 1 (Low Speed)

2 Speed 2 (High Speed)

F187 16 bitS START/STOP DATA LOG COMMAND

0 None (Select Command)

1 Start Log

2 Stop Log

F188 16 bitS DATA LOG RECORDING TYPE

0 Run To Fill

1 Circulate

F189 SEE TABLE 9-12 BELOW

F190 16 bitS DATA LOG STATUS

0 Stopped

1 Running

F191 16 bits DATA LOG START/STOP METHOD

xxxx xxxx xxxx xxx1 Log 1/9/17/25/33/41/49 Start Method

xxxx xxxx xxxx xx1x Log 1/9/17/25/33/41/49 Stop Method

xxxx xxxx xxxx x1xx Log 2/10/18/25/34/42/50 Start Method

xxxx xxxx xxxx 1xxx Log 2/10/18/25/34/42/50 Stop Method

xxxx xxxx xxx1 xxxx Log 3/11/19/25/35/43/ Start Method

xxxx xxxx xx1x xxxx Log 3/11/19/25/35/43/ Stop Method

xxxx xxxx x1xx xxxx Log 4/12/20/25/36/44/ Start Method

xxxx xxxx 1xxx xxxx Log 4/12/20/25/36/44/ Stop Method

xxxx xxx1 xxxx xxxx Log 5/13/21/25/37/45/ Start Method

xxxx xx1x xxxx xxxx Log 5/13/21/25/37/45/ Stop Method





xxxx x1xx xxxx xxxx Log 6/14/22/25/38/46/ Start Method

xxxx 1xxx xxxx xxxx Log 6/14/22/25/38/46/ Stop Method

xxx1 xxxx xxxx xxxx Log 7/15/23/25/39/47/ Start Method

xx1x xxxx xxxx xxxx Log 7/15/23/25/39/47/ Stop Method

x1xx xxxx xxxx xxxx Log 8/16/24/25/40/48/ Start Method

1xxx xxxx xxxx xxxx Log 8/16/24/25/40/48/ Stop Method

BIT VALUE

0 Log Started/Stopped From Motor Start/Stop or Run To Fill

1 Log Started/Stopped Manually

F192 Bitmask 369 DIGITAL INPUT AND OUTPUT RELAY STATUS

xxxx xxxx xxxx xxx1 Access Switch

xxxx xxxx xxxx xx1x Speed Switch

xxxx xxxx xxxx x1xx Spare Switch

xxxx xxxx xxxx 1xxx Differential Switch

xxxx xxxx xxx1 xxxx Emergency Switch

xxxx xxxx xx1x xxxx Remote Reset Switch

xxxx xxx1 xxxx xxxx Trip Relay Status

xxxx xx1x xxxx xxxx Alarm Relay Status

xxxx x1xx xxxx xxxx Aux1 Relay Status

xxxx 1xxx xxxx xxxx Aux2 Relay Status

F193 Bitmask RRTD DIGITAL INPUT AND OUTPUT RELAY STATUS

xxxx xxxx xxxx xxx1 Digital Input 3

xxxx xxxx xxxx xx1x Digital Input 4

xxxx xxxx xxxx x1xx Digital Input 6

xxxx xxxx xxxx 1xxx Digital Input 5

xxxx xxxx xxx1 xxxx Digital Input 2

xxxx xxxx xx1x xxxx Digital Input 1

xxxx xxx1 xxxx xxxx Trip Relay Status

xxxx xx1x xxxx xxxx Alarm Relay Status

xxxx x1xx xxxx xxxx Aux1 Relay Status

xxxx 1xxx xxxx xxxx Aux2 Relay Status





1. Only shown when “ENABLE 2-SPEED MOTOR PROTECTION” is set to “Yes”

* Explanation of Diagnostic Messages:

a. Messages 331 to 333 indicate that the 369 unit encountered and internal error during processing and has recovered properly by resetting.

b. Messages 334 to 338 indicate that the 369 unit detected hardware failure in the last operation. Please contact Technical Support.

Table 17: Format Code F189

CODE PARAMETER LIST VALUE

DATA ITEM FORMAT CODE

F189 0 None N/A

1 Motor Thermal Capacity Used F1

2 Digital Input and Output Relays Status F192

3 Phase A Current F1

4 Phase B Current F1

5 Phase C Current F1

6 Average Phase Current F1

7 Motor Load F3

8 Current Unbalance F1

9 Unbalanced Biased Motor Load F3

10 Ground Current F23

11 Vab* F1

12 Vbc* F1

13 Vca* F1

14 Average Line Voltage* F1

15 Van* F1

16 Vbn* F1

17 Vcn* F1

18 Average Phase Voltage* F1

19 System Frequency F3

20 Power Factor F21

21 Real Power (kW) F4

22 Real Power (hp) F1

23 Reactive Power F4

24 Apparent Power F1

25 Positive MegaWatthours F1

26 Positive Megavarhours F1



27 Negative Megavarhours F1

28 Positive KiloWatthours F1

29 Positive Kilovarhours F1

30 Negative Kilovarhours F1

31 Local RTD #1 Temperature F4












43 Current Demand F1

44 Real Power Demand F1

45 Reactive Power Demand F1

46 Apparent Power Demand F1

47 Peak Current Demand F1

48 Peak Real Power Demand F1

49 Peak Reactive Power Demand F1

50 Peak Apparent Power Demand F1

51 RRTD 1 - RTD #1 Temperature F4




















99 RRTD 1 – Digital Input and Output Relays Status F193

100 RRTD 2 – Digital Input and Output Relays Status F193

101 RRTD 3 Digital Input and Output Relays Status F193

102 RRTD 4 Digital Input and Output Relays Status F193




369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL A–155

369 Motor Management Relay

Appendix: Revisions

GE Energy

Revisions

A.1 Change Notes

A.1.1 Revision History

Table A–1: Revision History

MANUAL P/N RELEASE DATE ECO

1601-9046-A1 (New Manual) 31 March 2008

1601-9046-A2 17 October 2008

1601-9046-A3 13 March 2009

1601-9046-A4 3 June 2010

1601-9046-A5 17 May 2011

1601-9046-A6 17 May 2012

Table A–2: Major Updates for 369CG-A6

SECTION A4 SECTION A5 CHANGES

New manual revision number: A6

6.8 6.8 Additions to Format Code F134




6.5 6.5 New section added: Internal Units Scale

A–156 369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

CHANGE NOTES CHAPTER A: REVISIONS




4.1 4.1 New section added in DeviceNet section: DeviceNet Loss of Communication Trip

6.7 6.7 Minor Modbus Map (Fieldbus) changes.




N/A 1.6 New section: Ethernet Loss of Communication Trip

6.7 6.7 Modbus Map changes (from Profibus to Fieldbus) - three addresses only.


SECTION SECTION CHANGES


4.2 4.2 Tables CG 8 and CG 9 Format Code corrections

CHAPTER A: REVISIONS WARRANTY

369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL A–157

A.2 Warranty

A.2.1 Warranty Information

GE MULTILIN RELAY WARRANTY

General Electric Multilin (GE Multilin) warrants each relay it manufactures to be free from defects in material and workmanship under normal use and service for a period of 24 months from date of shipment from factory.

In the event of a failure covered by warranty, GE Multilin will undertake to repair or replace the relay providing the warrantor determined that it is defective and it is returned with all transportation charges prepaid to an authorized service centre or the factory. Repairs or replacement under warranty will be made without charge.

Warranty shall not apply to any relay which has been subject to misuse, negligence, accident, incorrect installation or use not in accordance with instructions nor any unit that has been altered outside a GE Multilin authorized factory outlet.

GE Multilin is not liable for special, indirect or consequential damages or for loss of profit or for expenses sustained as a result of a relay malfunction, incorrect application or adjustment.

For complete text of Warranty (including limitations and disclaimers), refer to GE Multilin Standard Conditions of Sale.

A–158 369 MOTOR MANAGEMENT RELAY– INSTRUCTION MANUAL

WARRANTY CHAPTER A: REVISIONS

GEK-113493E - GE Digital Energy

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