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GE M60 UR Series, Instruction Manual

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5-146

M60 Motor Protection System

GE Multilin

5.6 GROUPED ELEMENTS

5 SETTINGS

5

I

b

 = Motor rated current specified by the MOTOR FULL LOAD AMPS setting.

THERMAL MODEL CURVE EFFECT:

 This setting affects the time-to-trip thermal curves when the 

THERMAL MODEL

CURVE

 is selected as “Motor”. This setting takes into account the design of the machine with respect to overload capa-

bility as determined by the overload (service) factor. For motor designs where temperature rise above ambient is
based on full load current, this setting should be selected as “Cutoff”. The time to trip is then calculated using the fol-
lowing equation:

(EQ 5.10)

In the above equation, the motor stator current (

I

motor

) and motor rated current (FLA) are expressed in per units of

relay current.

For specialized motor designs where temperature rise above ambient is based on the product of the service factor and
full load current (OF × FLA), this setting should be selected as “Shifted”. The time to trip is then calculated using the
following equation:

(EQ 5.11)

In the above equation, the motor stator current (

I

motor

) and motor rated current (FLA) are expressed in per units of

relay current.

In case of uncertainty, the more conservative “Cutoff” value should be used.

The following figure illustrates the impact of this setting on the time to trip thermal curves.

Figure 5–55: IMPACT OF THE THERMAL MODEL CURVE EFFECT SETTING

IEC CURVE k FACTOR

: This setting applies only to the IEC motor curve and is applied as described in the 

THERMAL

MODEL CURVE

 setting description. Refer to the IEC 255-8 standard for additional details on its application.

trip time

TD 2.2116623

0.02530337

I

motor

FLA

--------------

1

2

0.05054758

I

motor

FLA

--------------

1

+

------------------------------------------------------------------------------------------------------------------------------------------------

=

trip time

TD 2.2116623

0.02530337

I

motor

OF FLA

-------------------------

1

2

0.05054758

I

motor

OF FLA

-------------------------

1

+

----------------------------------------------------------------------------------------------------------------------------------------------------------------------

=

1

10

100

1000

10000

0

5

8

Stator current (multiples of FLA)

SF = 1.15, EFFECT = shift

T

rip

time

(seconds)

SF = 1.15, EFFECT = cutoff

Summary of Contents for M60 UR Series

Page 1: ...uction Manual GE Digital Energy 650 Markland Street Markham Ontario Canada L6C 0M1 Tel 1 905 927 7070 Fax 1 905 927 5098 Internet http www GEDigitalEnergy com GE Multilin s Quality Management System is registered to ISO 9001 2008 QMI 005094 UL A3775 1601 0108 AA1 LISTED 52TL IND CONT EQ E83849 GE Digital Energy ...

Page 2: ...gital Energy Multilin and GE Multilin are trademarks or registered trademarks of GE Multilin Inc The contents of this manual are the property of GE Multilin Inc This documentation is furnished on license and may not be reproduced in whole or in part without the permission of GE Multilin The content of this manual is for informational use only and is subject to change without notice Part number 160...

Page 3: ...AVIGATION 1 18 1 5 3 MENU HIERARCHY 1 18 1 5 4 RELAY ACTIVATION 1 18 1 5 5 RELAY PASSWORDS 1 19 1 5 6 FLEXLOGIC CUSTOMIZATION 1 19 1 5 7 COMMISSIONING 1 20 2 PRODUCT DESCRIPTION 2 1 INTRODUCTION 2 1 1 OVERVIEW 2 1 2 1 2 SECURITY 2 2 2 1 3 IEC 870 5 103 PROTOCOL 2 7 2 2 ORDER CODES 2 2 1 OVERVIEW 2 8 2 2 2 ORDER CODES WITH ENHANCED CT VT MODULES 2 8 2 2 3 ORDER CODES WITH PROCESS BUS MODULES 2 11 2...

Page 4: ...SETUP MAIN WINDOW 4 3 4 2 EXTENDED ENERVISTA UR SETUP FEATURES 4 2 1 SETTINGS TEMPLATES 4 4 4 2 2 SECURING AND LOCKING FLEXLOGIC EQUATIONS 4 8 4 2 3 SETTINGS FILE TRACEABILITY 4 10 4 2 4 AUTOMATIC CONFIGURATOR 4 12 4 3 FACEPLATE INTERFACE 4 3 1 FACEPLATE 4 13 4 3 2 LED INDICATORS 4 14 4 3 3 CUSTOM LABELING OF LEDS 4 17 4 3 4 DISPLAY 4 23 4 3 5 KEYPAD 4 23 4 3 6 BREAKER CONTROL 4 23 4 3 7 MENUS 4 2...

Page 5: ... 5 6 7 NEUTRAL CURRENT 5 184 5 6 8 GROUND CURRENT 5 190 5 6 9 BREAKER FAILURE 5 198 5 6 10 VOLTAGE ELEMENTS 5 207 5 7 CONTROL ELEMENTS 5 7 1 OVERVIEW 5 215 5 7 2 TRIP BUS 5 215 5 7 3 SETTING GROUPS 5 217 5 7 4 SELECTOR SWITCH 5 219 5 7 5 UNDERFREQUENCY 5 225 5 7 6 OVERFREQUENCY 5 226 5 7 7 MOTOR START SUPERVISION 5 227 5 7 8 REDUCED VOLTAGE STARTING 5 230 5 7 9 DIGITAL ELEMENTS 5 232 5 7 10 DIGITA...

Page 6: ...18 EGD PROTOCOL STATUS 6 11 6 2 19 TELEPROTECTION CHANNEL TESTS 6 12 6 2 20 REMAINING CONNECTION STATUS 6 12 6 2 21 PARALLEL REDUNDANCY PROTOCOL PRP 6 13 6 3 METERING 6 3 1 METERING CONVENTIONS 6 14 6 3 2 STATOR DIFFERENTIAL 6 17 6 3 3 MOTOR 6 17 6 3 4 SOURCES 6 18 6 3 5 SENSITIVE DIRECTIONAL POWER 6 21 6 3 6 BROKEN ROTOR BAR 6 22 6 3 7 TRACKING FREQUENCY 6 23 6 3 8 FLEXELEMENTS 6 23 6 3 9 IEC 615...

Page 7: ...EAD ACTUAL VALUES OR SETTINGS FUNCTION CODE 03 04H B 3 B 2 3 EXECUTE OPERATION FUNCTION CODE 05H B 4 B 2 4 STORE SINGLE SETTING FUNCTION CODE 06H B 4 B 2 5 STORE MULTIPLE SETTINGS FUNCTION CODE 10H B 5 B 2 6 EXCEPTION RESPONSES B 5 B 3 FILE TRANSFERS B 3 1 OBTAINING RELAY FILES VIA MODBUS B 6 B 3 2 MODBUS PASSWORD OPERATION B 7 B 4 MEMORY MAPPING B 4 1 MODBUS MEMORY MAP B 8 B 4 2 DATA FORMATS B 74...

Page 8: ...17 C 5 5 ABOUT SCD FILES C 17 C 5 6 IMPORTING AN SCD FILE WITH ENERVISTA UR SETUP C 20 C 6 ACSI CONFORMANCE C 6 1 ACSI BASIC CONFORMANCE STATEMENT C 22 C 6 2 ACSI MODELS CONFORMANCE STATEMENT C 22 C 6 3 ACSI SERVICES CONFORMANCE STATEMENT C 23 C 7 LOGICAL NODES C 7 1 LOGICAL NODES TABLE C 26 D IEC 60870 5 103 COMMUNICATIONS D 1 IEC 60870 5 103 D 1 1 OVERVIEW D 1 D 1 2 FACTOR AND OFFSET CALCULATION...

Page 9: ... M60 Motor Protection System ix TABLE OF CONTENTS H 1 1 REVISION HISTORY H 1 H 1 2 CHANGES TO THE M60 MANUAL H 2 H 2 ABBREVIATIONS H 2 1 STANDARD ABBREVIATIONS H 5 H 3 WARRANTY H 3 1 GE MULTILIN WARRANTY H 7 INDEX ...

Page 10: ...x M60 Motor Protection System GE Multilin TABLE OF CONTENTS ...

Page 11: ... of the specified limits Only qualified personnel are to operate the device Such personnel must be thoroughly familiar with all safety cau tions and warnings in this manual and with applicable country regional utility and plant safety regulations Hazardous voltages can exist in the power supply and at the device connection to current transformers voltage transformers control and test circuit termi...

Page 12: ...up software and manuals in PDF format Mounting screws 4 If there is any noticeable physical damage or any of the contents listed are missing contact GE Digital Energy as fol lows GE DIGITAL ENERGY CONTACT INFORMATION AND CALL CENTER FOR PRODUCT SUPPORT GE Digital Energy 650 Markland Street Markham Ontario Canada L6C 0M1 TELEPHONE Worldwide 1 905 927 7070 Europe Middle East Africa 34 94 485 88 54 N...

Page 13: ...ogic signals generated by the relay into digital or analog signals that are used to control field devices The unit and software are backwards compatible with UR devices b UR SIGNAL TYPES The contact inputs and outputs are digital signals associated with connections to hard wired contacts Both wet and dry contacts are supported The virtual inputs and outputs are digital signals associated with UR s...

Page 14: ... use of objects and classes An object is defined as a logical entity that contains both data and code that manipulates data A class is the generalized form of similar objects By using this approach one can create a protection class with the protection elements as objects of the class such as time overcurrent instantaneous overcurrent current differential undervoltage overvoltage underfrequency and...

Page 15: ...Modem 5686 US Robotics external Sportster 56K X2 PCTEL 2304WT V 92 MDC internal modem 1 3 2 INSTALLATION After ensuring that the requirements for using EnerVista UR Setup software are met install the software from the GE EnerVista DVD Or download the UR EnerVista software from http www gedigitalenergy com multilin and install it If you are upgrading from version 7 0 or 7 1 to 7 2 or later some CPU...

Page 16: ... of installed intelligent electronic devices IEDs in the EnerVista Launchpad window as shown Figure 1 5 UR DEVICE ADDED TO LAUNCHPAD WINDOW 1 3 3 CONFIGURING THE M60 FOR SOFTWARE ACCESS a OVERVIEW You connect remotely to the M60 through the rear RS485 or Ethernet port with a computer running the EnerVista UR Setup software The M60 can also be accessed locally with a laptop computer through the fro...

Page 17: ...to re open the Device Setup window 6 Click the Add Device button to define the new device 7 Enter a name in the Device Name field and a description optional of the site 8 Select Serial from the Interface drop down list This displays a number of interface parameters that must be entered for serial communications Figure 1 6 CONFIGURING SERIAL COMMUNICATIONS 9 Enter the relay slave address COM port b...

Page 18: ...e Device Setup window 16 Click the Add Device button to define the new device 17 Enter the desired name in the Device Name field and a description optional of the site 18 Select Ethernet from the Interface drop down list This displays a number of interface parameters that must be entered for proper Ethernet functionality Figure 1 7 CONFIGURING ETHERNET COMMUNICATIONS 19 Enter the relay IP address ...

Page 19: ...lick the Quick Connect button to establish direct communi cations to the M60 device This ensures that configuration of the EnerVista UR Setup software matches the M60 model number b USING QUICK CONNECT VIA THE REAR ETHERNET PORTS To use the Quick Connect feature to access the M60 from a computer through Ethernet first assign an IP address to the relay from the front panel keyboard 1 Press the MENU...

Page 20: ...ows desktop right click the My Network Places icon and select Properties to open the network con nections window 2 Right click the Local Area Connection icon and select Properties 3 Select the Internet Protocol TCP IP item from the list and click the Properties button 4 Click the Use the following IP address box ...

Page 21: ...TTL vary depending on local network configuration 5 If the following sequence of messages appears when entering the C WINNT ping 1 1 1 1 command Pinging 1 1 1 1 with 32 bytes of data Request timed out Request timed out Request timed out Request timed out Ping statistics for 1 1 1 1 Packets Sent 4 Received 0 Lost 4 100 loss Approximate round trip time in milliseconds Minimum 0ms Maximum 0ms Average...

Page 22: ...ection specific DNS suffix IP Address 0 0 0 0 Subnet Mask 0 0 0 0 Default Gateway Ethernet adapter Local Area Connection Connection specific DNS suffix IP Address 1 1 1 2 Subnet Mask 255 0 0 0 Default Gateway C WINNT Before using the Quick Connect feature through the Ethernet port disable any configured proxy settings in Internet Explorer 1 Start the Internet Explorer software 2 Select the Tools I...

Page 23: ...e Windows desktop right click the My Network Places icon and select Properties to open the network con nections window 2 Right click the Local Area Connection icon and select the Properties item 3 Select the Internet Protocol TCP IP item from the list provided and click the Properties button 4 Set the computer to Obtain a relay address automatically as shown If this computer is used to connect to ...

Page 24: ...an now be edited printed or changed See chapter 4 in this manual or the EnerVista UR Setup Help File for information about the using the EnerVista UR Setup software interface QUICK ACTION HOT LINKS The EnerVista UR Setup software has several quick action buttons to provide instant access to several functions that are often performed when using M60 relays From the online window users can select the...

Page 25: ...entication can be chosen on the login screen but the choice is available only in EnerVista Use device authentication to log in using the five pre configured roles Administrator Supervisor Engineer Operator Observer When using a serial connection only device authentication is supported When server authentication is required characteristics for communication with a RADIUS server must be configured o...

Page 26: ...g EnerVista navigate to Settings Product Setup Security Change the Local Administrator Password for example It is strongly recommended that the password for the Administrator be changed from the default Changing the passwords for the other three roles is optional Figure 1 10 CHANGING THE DEFAULT PASSWORD ...

Page 27: ...5 port from a computer RS232 port the GE Multilin RS232 RS485 converter box is required This device catalog number F485 connects to the computer using a straight through serial cable A shielded twisted pair 20 22 or 24 AWG connects the F485 converter to the M60 rear communications port The converter terminals GND are connected to the M60 communication module COM terminals See the CPU Communica tio...

Page 28: ... title appears momentarily followed by a header display page menu item Each press of the MENU key advances through the following main heading pages Actual values Settings Commands Targets User displays when enabled 1 5 3 MENU HIERARCHY The setting and actual value messages are arranged hierarchically The header display pages are indicated by double scroll bar characters while sub header pages are ...

Page 29: ...m making any settings changes but allows the user to perform the fol lowing operations Change state of virtual inputs Clear event records Clear oscillography records Operate user programmable pushbuttons 2 SETTING The SETTING access level allows the user to make any changes to any of the setting values See the Changing Settings section in Chapter 4 for complete instructions on setting security lev...

Page 30: ...tions 3 LED test 4 Visual inspection for any damage corrosion dust or loose wires 5 Event recorder file download with further events analysis Out of service maintenance 1 Check wiring connections for firmness 2 Analog values currents voltages RTDs analog inputs injection test and metering accuracy verification Calibrated test equipment is required 3 Protection elements setting verification analog ...

Page 31: ...uce troubleshooting time and simplify report generation in the event of a system fault Several options are available for communication A faceplate RS232 port can be used to connect to a computer for the pro gramming of settings and the monitoring of actual values The RS232 port has a fixed baud rate of 19 2 kbps The rear RS485 port allows independent access by operating and engineering staff It ca...

Page 32: ...ions Time synchronization over IRIG B or IEEE 1588 Contact Inputs up to 96 IEC 60870 5 103 Communications optional Time Synchronization over SNTP Contact Outputs up to 96 IEC 61850 Communications optional Transducer Inputs Outputs Control Pushbuttons Metering Current Voltage Power and Frequency Trip Bus CT Failure Detector Modbus Communications Two Speed Motor CyberSentry Security Modbus User Map ...

Page 33: ...st mode operation The command and setting passwords are defaulted to 0 when the relay is shipped from the factory When a password is set to 0 the password security feature is disabled As shown in the figures the window indicates when the password is at the default and when the password has been set Figure 2 2 WINDOW INDICATES DEFAULT PASSWORD LEFT AND PASSWORD SET RIGHT The M60 supports password e...

Page 34: ...lined in the next section Figure 2 3 CYBERSENTRY USER ROLES There are two types of authentication supported by CyberSentry that can be used to access the UR device Device Authentication local UR device authenticates Server Authentication RADIUS server authenticates The EnerVista software allows access to functionality that is determined by the user role which comes either from the local UR device ...

Page 35: ...phy RW RW R R R Data Logger RW RW R R R Demand RW RW R R R User Programmable LEDs RW RW R R R User Programmable self test RW RW R R R Control Pushbuttons RW RW R R R User programmable Pushbuttons RW RW R R R Flex states RW RW R R R User definable dis plays RW RW R R R Direct I O RW RW R R R Tele protection RW RW R R R Installation RW RW R R R System Setup RW RW R R R FlexLogic RW RW R R R Grouped ...

Page 36: ...ovided If a RADIUS server is provided but is unreachable over the network server authentication requests are denied In this situ ation use local UR accounts to gain access to the UR system Direct Inputs RW RW R R R Direct Outputs RW RW R R R Teleprotection RW RW R R R Direct Analogs RW RW R R R Direct Integers RW RW R R R IEC61850 GOOSE Analogs RW RW R R R IEC61850 GOOSE Integers RW RW R R R Trans...

Page 37: ...he IEC 60870 5 103 is an unbalanced master slave protocol for coded bit serial communication exchanging information with a control system In the context of this protocol the protection equipment is the slave and the control system is the master The communication is based on a point to point principle The master must be able to interpret the IEC 60870 5 103 communication messages The UR implementat...

Page 38: ... Global Data EGD and IEC 61850 CS PRP and Rotor broken bar CT PRP Rotor broken bar and Ethernet Global Data EGD CU PRP Rotor broken bar and IEC 61850 CV PRP Rotor broken bar Ethernet Global Data EGD and IEC 61850 D0 IEEE 1588 and Broken rotor bar detection D1 IEEE 1588 and Broken rotor bar detection and Ethernet Global Data EGD D3 IEEE 1588 and Broken rotor bar detection and IEC 61850 D4 IEEE 1588...

Page 39: ... and 4 Form C outputs 4 digital inputs 6C 6C 6C 6C 6C 8 Form C outputs 6D 6D 6D 6D 6D 16 digital inputs 6E 6E 6E 6E 6E 4 Form C outputs 8 digital inputs 6F 6F 6F 6F 6F 8 Fast Form C outputs 6G 6G 6G 6G 6G 4 Form A voltage with optional current outputs 8 digital inputs 6H 6H 6H 6H 6H 6 Form A voltage with optional current outputs 4 digital inputs 6K 6K 6K 6K 6K 4 Form C and 4 Fast Form C outputs 6L...

Page 40: ...CyberSentry Lvl 1 and Ethernet Global Data EGD F3 PRP CyberSentry Lvl 1 and IEC 61850 F4 PRP CyberSentry Lvl 1 Ethernet Global Date EGD and IEC 61850 FS PRP CyberSentry Lvl 1 and Rotor broken bar FT PRP CyberSentry Lvl 1 Rotor broken bar and Ethernet Global Data EGD FU PRP CyberSentry Lvl 1 Rotor broken bar and IEC 61850 FV PRP CyberSentry Lvl 1 Rotor broken bar Ethernet Global Data EGD and IEC 61...

Page 41: ... Channel 1 IEEE C37 94 MM 64 128 kbps Channel 2 1300 nm single mode Laser 2J Channel 1 IEEE C37 94 MM 64 128 kbps Channel 2 1550 nm single mode Laser 72 1550 nm single mode Laser 1 Channel 73 1550 nm single mode Lsser 2 Channel 74 Channel 1 RS422 Channel 2 1550 nm single mode Laser 75 Channel 1 G 703 Channel 2 1550 nm single mode Laser 76 IEEE C37 94 820 nm 64 kbps multimode LED 1 Channel 77 IEEE ...

Page 42: ...broken bar JT IEC 60870 5 103 Rotor broken bar EGD JU IEC 60870 5 103 Rotor broken bar IEC 61850 JV IEC 60870 5 103 Rotor broken bar EGD IEC 61850 K0 IEEE 1588 PRP IEC 60870 5 103 K1 IEEE 1588 PRP IEC 60870 5 103 EGD K3 IEEE 1588 PRP IEC 60870 5 103 IEC 61850 K4 IEEE 1588 PRP IEC 60870 5 103 EGD IEC 61850 KS IEEE 1588 PRP IEC 60870 5 103 Rotor broken bar KT IEEE 1588 PRP IEC 60870 5 103 Rotor brok...

Page 43: ...ltimode LED 2 Channels 7I 1300 nm multimode LED 2 Channels 7J 1300 nm single mode ELED 2 Channels 7K 1300 nm single mode Laser 2 Channels 7L Channel 1 RS422 Channel 2 820 nm multimode LED 7M Channel 1 RS422 Channel 2 1300 nm multimode LED 7N Channel 1 RS422 Channel 2 1300 nm single mode ELED 7P Channel 1 RS422 Channel 2 1300 nm single mode Laser 7Q Channel 1 G 703 Channel 2 1300 nm single mode Las...

Page 44: ...8 V DC only power supply PROCESS BUS MODULE 81 Eight port digital process bus module DIGITAL INPUTS OUTPUTS XX XX XX No Module 4A 4 Solid State no monitoring MOSFET outputs 4B 4 Solid State voltage with optional current MOSFET outputs 4C 4 Solid State current with optional voltage MOSFET outputs 4D 16 digital inputs with Auto Burnishing maximum of three modules within a case 4L 14 Form A no monito...

Page 45: ...utputs 8 digital inputs 6B 2 Form A voltage with optional current and 4 Form C outputs 4 digital inputs 6C 8 Form C outputs 6D 16 digital inputs 6E 4 Form C outputs 8 digital inputs 6F 8 Fast Form C outputs 6G 4 Form A voltage with optional current outputs 8 digital inputs 6H 6 Form A voltage with optional current outputs 4 digital inputs 6K 4 Form C and 4 Fast Form C outputs 6L 2 Form A current w...

Page 46: ...uts 6N 4 Form A current with optional voltage outputs 8 digital inputs 6P 6 Form A current with optional voltage outputs 4 digital inputs 6R 2 Form A no monitoring and 2 Form C outputs 8 digital inputs 6S 2 Form A no monitoring and 4 Form C outputs 4 digital inputs 6T 4 Form A no monitoring outputs 8 digital inputs 6U 6 Form A no monitoring outputs 4 digital inputs 6V 2 Form A outputs 1 Form C out...

Page 47: ...y exponential Hot cold safe stall ratio 0 01 to 1 00 in steps of 0 01 Current accuracy per phase current inputs Current source true RMS Timer accuracy 100 ms or 2 whichever is greater Timer accuracy for voltage dependent overload 100 ms or 4 whichever is greater STATOR DIFFERENTIAL Pickup 0 050 to 1 00 pu in steps of 0 01 Slope 1 and 2 1 to 100 in steps of 1 Break 1 1 00 to 1 50 pu in steps of 0 0...

Page 48: ...evel 97 to 98 of pickup Level accuracy at 0 1 to 2 0 CT 0 5 of reading at 2 0 CT rating 1 5 of reading Pickup delay 0 10 to 600 00 s in steps of 0 01 Reset delay 0 00 to 600 00 s in steps of 0 01 Timer accuracy 3 of operate time or 20 ms which ever is greater ACCELERATION TIME Acceleration current 1 00 to 10 00 FLA in steps of 0 01 Acceleration time 0 00 to 180 00 s in steps of 0 01 Operating mode...

Page 49: ...0 s in steps of 0 01 Timer accuracy 3 of operate time or 1 4 cycle whichever is greater Operate time 30 ms at 1 10 pickup at 60 Hz NEGATIVE SEQUENCE OVERVOLTAGE Pickup level 0 000 to 1 250 pu in steps of 0 001 Dropout level 97 to 98 of pickup Level accuracy 0 5 of reading from 10 to 208 V Pickup delay 0 to 600 00 s in steps of 0 01 Reset delay 0 to 600 00 s in steps of 0 01 Timer accuracy 3 of ope...

Page 50: ...e contact or virtual input FLEXELEMENTS Number of elements 16 Operating signal any analog actual value or two values in differential mode Operating signal mode signed or absolute value Operating mode level delta Comparator direction over under Pickup Level 90 000 to 90 000 pu in steps of 0 001 Hysteresis 0 1 to 50 0 in steps of 0 1 Delta dt 20 ms to 60 days Pickup dropout delay 0 000 to 65 535 s i...

Page 51: ...er of elements 2 Pre fault trigger any FlexLogic operand Fault trigger any FlexLogic operand Recorder quantities 32 any FlexAnalogTM value DATA LOGGER Number of channels 1 to 16 Parameters any available analog actual value Sampling rate 15 to 3600000 ms in steps of 1 Trigger any FlexLogic operand Mode continuous or triggered Storage capacity NN is dependent on memory 1 second rate 01 channel for N...

Page 52: ...sholds 17 V 33 V 84 V 166 V Tolerance 10 Contacts per common return 4 Recognition time 1 ms Debounce time 0 0 to 16 0 ms in steps of 0 5 Continuous current draw 3 mA when energized CONTACT INPUTS WITH AUTO BURNISHING Dry contacts 1000 maximum Wet contacts 300 V DC maximum Selectable thresholds 17 V 33 V 84 V 166 V Tolerance 10 Contacts per common return 2 Recognition time 1 ms Debounce time 0 0 to...

Page 53: ...r 400 V check power supply mod ule Nominal AC voltage 100 to 240 V at 50 60 Hz Minimum AC voltage 88 V at 25 to 100 Hz Maximum AC voltage 265 V at 25 to 100 Hz Voltage loss hold up 200 ms duration at nominal ALL RANGES Volt withstand 2 Highest Nominal Voltage for 10 ms Power consumption typical 15 to 20 W VA maximum 50 W VA contact factory for exact order code con sumption INTERNAL FUSE RATINGS Lo...

Page 54: ...CMA OUTPUTS Range 1 to 1 mA 0 to 1 mA 4 to 20 mA Max load resistance 12 k for 1 to 1 mA range 12 k for 0 to 1 mA range 600 for 4 to 20 mA range Accuracy 0 75 of full scale for 0 to 1 mA range 0 5 of full scale for 1 to 1 mA range 0 75 of full scale for 0 to 20 mA range 99 Settling time to a step change 100 ms Isolation 1 5 kV Driving signal any FlexAnalog quantity Upper and lower limit for the dri...

Page 55: ...facturer s worst case transmitter power and worst case receiver sensitivity The power budgets for the 1300 nm ELED are calcu lated from the manufacturer s transmitter power and receiver sensitivity at ambient temperature At extreme temperatures these values deviate based on component tolerance On average the output power decreases as the temperature is increased by a factor 1dB 5 C MAXIMUM OPTICAL...

Page 56: ...0 back EMITTER TYPE CABLE TYPE CONNECTOR TYPE TYPICAL DISTANCE 820 nm LED multimode 62 5 125 μm ST 1 65 km 1300 nm LED multimode 62 5 125 μm ST 3 8 km 1300 nm ELED single mode 9 125 μm ST 11 4 km 1300 nm Laser single mode 9 125 μm ST 64 km 1550 nm Laser single mode 9 125 μm ST 105 km Typical distances listed are based on the follow ing assumptions for system loss As actual losses vary from one ins...

Page 57: ...s A and B Voltage interruption and ripple DC IEC60255 11 12 ripple 200 ms interrupts Radiated and conducted emissions CISPR11 CISPR22 IEC60255 25 Class A Sinusoidal vibration IEC60255 21 1 Class 1 Shock and bump IEC60255 21 2 Class 1 Seismic IEC60255 21 3 Class 1 Power magnetic immunity IEC61000 4 8 Level 5 Pulse magnetic immunity IEC61000 4 9 Level 4 Damped magnetic immunity IEC61000 4 10 Level 4...

Page 58: ...eaning is not required but for situations where dust has accumulated on the faceplate display a dry cloth can be used To avoid deterioration of electrolytic capacitors power up units that are stored in a de energized state once per year for one hour continuously COMPLIANCE APPLICABLE COUNCIL DIRECTIVE ACCORDING TO CE Low voltage directive EN 60255 5 EMC directive EN 60255 26 EN 50263 EN 61000 6 5 ...

Page 59: ...removable modules and is itself removable to allow mounting on doors with limited rear depth The case dimensions are shown below along with panel cutout details for panel mounting When planning the location of your panel cutout ensure that provision is made for the faceplate to swing open without interference to or from adjacent equipment The relay must be mounted such that the faceplate sits semi...

Page 60: ...ional user programmable pushbuttons and LED indicators The modular design allows the relay to be easily upgraded or repaired by a qualified service person The faceplate is hinged to allow easy access to the removable modules and is itself removable to allow mounting on doors with limited rear depth The case dimensions are shown below along with panel cutout details for panel mounting When planning...

Page 61: ...its semi flush with the panel or switchgear door allowing the operator access to the keypad and the RS232 communications port The relay is secured to the panel with the use of four screws supplied with the relay Figure 3 4 M60 VERTICAL DIMENSIONS ENHANCED PANEL 14 025 7 482 15 000 4 000 9 780 11 015 1 329 13 560 843809A1 CDR ...

Page 62: ...ments available online from the GE Multilin website GEK 113180 UR series UR V side mounting front panel assembly instructions GEK 113181 Connecting the side mounted UR V enhanced front panel to a vertical UR series device GEK 113182 Connecting the side mounted UR V enhanced front panel to a vertically mounted horizontal UR series device For details on side mounting M60 devices with the standard fr...

Page 63: ...GE Multilin M60 Motor Protection System 3 5 3 HARDWARE 3 1 DESCRIPTION 3 Figure 3 6 M60 VERTICAL SIDE MOUNTING INSTALLATION STANDARD PANEL ...

Page 64: ...3 6 M60 Motor Protection System GE Multilin 3 1 DESCRIPTION 3 HARDWARE 3 Figure 3 7 M60 VERTICAL SIDE MOUNTING REAR DIMENSIONS STANDARD PANEL 3 1 2 REAR TERMINAL LAYOUT Figure 3 8 REAR TERMINAL VIEW ...

Page 65: ...Ethernet slot else damage can occur The relay follows a convention with respect to terminal number assignments which are three characters long assigned in order by module slot position row number and column letter Two slot wide modules take their slot designation from the first slot position nearest to CPU module which is indicated by an arrow marker on the terminal block See the following figure ...

Page 66: ...3 8 M60 Motor Protection System GE Multilin 3 2 WIRING 3 HARDWARE 3 3 2WIRING 3 2 1 TYPICAL WIRING Figure 3 10 TYPICAL WIRING DIAGRAM T MODULE SHOWN FOR CPU ...

Page 67: ... contact input connections and a critical failure relay see the Typical wiring diagram earlier The critical failure relay is a form C device that is energized once control power is applied and the relay has successfully booted up with no critical self test failures If on going self test diagnostic checks detect a critical failure see the Self test Errors section in chapter 7 or control power is lo...

Page 68: ...ion CT VT modules can be ordered with a standard ground current input that is the same as the phase current input Each AC current input has an isolating transformer and an automatic shorting mechanism that shorts the input when the module is withdrawn from the chassis There are no internal ground connections on the current inputs Current transformers with 1 to 50000 A primaries and 1 A or 5 A seco...

Page 69: ... symbol with the slot position of the module in the following figure Figure 3 13 CT VT MODULE WIRING NOTE 1a 1b 1c 2a 2b 2c 3a 4a 5a 6a 7a 8a 3b 4b 5c 6c 7c 8c 3c 4c Current inputs 8F 8G 8L and 8M modules 4 CTs and 4 VTs Voltage inputs VA VB VC VX VA VB VC VX IA IC IB IG IA5 IC5 IB5 IG5 IA1 IC1 IB1 IG1 1a 5a 1b 5b 1c 5c 2a 6a 2b 6b 2c 6c 3a 7a 4a 8a 3b 7b 4b 8b 3c 7c 4c 8c Current inputs 842766A3 ...

Page 70: ...different for the two applications The contact inputs are grouped with a common return The M60 has two versions of grouping four inputs per common return and two inputs per common return When a contact input output module is ordered four inputs per common is used The four inputs per common allows for high density inputs in combination with outputs with a compromise of four inputs sharing one commo...

Page 71: ... has closed and subsequently opened when measured as an impedance The solution is to use the voltage measuring trigger input of the relay test set and connect the form A contact through a voltage dropping resistor to a DC voltage source If the 48 V DC output of the power supply is used as a source a 500 10 W resistor is appropriate In this configuration the voltage across either the form A contact...

Page 72: ...a 6c 2 Inputs 6 Fast Form C 6a 6c 2 Inputs 6 Form A 7a 7c 2 Inputs 7 Fast Form C 7a 7c 2 Inputs 7a 7c 2 Inputs 8a 8c 2 Inputs 8 Fast Form C 8a 8c 2 Inputs 8a 8c 2 Inputs 6K MODULE 6L MODULE 6M MODULE 6N MODULE TERMINAL ASSIGNMENT OUTPUT TERMINAL ASSIGNMENT OUTPUT OR INPUT TERMINAL ASSIGNMENT OUTPUT OR INPUT TERMINAL ASSIGNMENT OUTPUT OR INPUT 1 Form C 1 Form A 1 Form A 1 Form A 2 Form C 2 Form A 2...

Page 73: ...Solid State 7a 7c 2 Inputs 7a 7c 2 Inputs 7 Form A 7 Not Used 8a 8c 2 Inputs 8a 8c 2 Inputs 8 Form A 8 Solid State 4B MODULE 4C MODULE 4D MODULE 4L MODULE TERMINAL ASSIGNMENT OUTPUT TERMINAL ASSIGNMENT OUTPUT TERMINAL ASSIGNMENT OUTPUT TERMINAL ASSIGNMENT OUTPUT 1 Not Used 1 Not Used 1a 1c 2 Inputs 1 2 Outputs 2 Solid State 2 Solid State 2a 2c 2 Inputs 2 2 Outputs 3 Not Used 3 Not Used 3a 3c 2 Inp...

Page 74: ...3 16 M60 Motor Protection System GE Multilin 3 2 WIRING 3 HARDWARE 3 Figure 3 15 CONTACT INPUT AND OUTPUT MODULE WIRING 1 of 2 ...

Page 75: ...3b 4b 5b 6b 1a 2a 3a 4a 5a 6a 1c 2c 3c 4c 5c 6c 1 5 2 6 3 4 8a 7b 7a CONTACT IN 7a CONTACT IN 7c CONTACT IN 8a CONTACT IN 8c COMMON 7b SURGE 8c 7c 8b I V I V I V I V DIGITAL I O 6N 1b 2b 3b 4b 6c 1a 2a 3a 4a 5a 6a 1c 2c 3c 4c 5c 5b 1 2 3 4 8a 7b 7a CONTACT IN 7a CONTACT IN 5a CONTACT IN 7c CONTACT IN 5c CONTACT IN 8a CONTACT IN 6a CONTACT IN 8c CONTACT IN 6c COMMON 7b COMMON 5b SURGE 8c 7c 8b DIGI...

Page 76: ...voltage for this arrangement is 300 V DC The voltage threshold at which each group of four contact inputs detects a closed contact input is programmable as 17 V DC for 24 V sources 33 V DC for 48 V sources 84 V DC for 110 to 125 V sources and 166 V DC for 250 V sources Figure 3 17 DRY AND WET CONTACT INPUT CONNECTIONS Wherever a tilde symbol appears substitute with the slot position of the module ...

Page 77: ...nge of state was sensed Then within 25 to 50 ms this current is slowly reduced to 3 mA as indicated above The 50 to 70 mA peak current burns any film on the con tacts allowing for proper sensing of state changes If the external device contact is bouncing the auto burnishing starts when external device contact bouncing is over Another important difference between the auto burnishing input module an...

Page 78: ...tions These connections are arranged as three ter minals per row with a total of eight rows A given row can be used for either inputs or outputs with terminals in column a having positive polarity and terminals in column c having negative polarity Since an entire row is used for a single input output channel the name of the channel is assigned using the module slot position and row number Each mod...

Page 79: ...nning the EnerVista UR Setup software provided with the relay Cabling for the RS232 port is shown in the following figure for both 9 pin and 25 pin connectors The baud rate for this port is fixed at 19200 bps Figure 3 21 RS232 FACEPLATE PORT CONNECTION 3 2 9 CPU COMMUNICATION PORTS a OPTIONS In addition to the faceplate RS232 port the M60 provides a rear RS485 communication port The CPU modules do...

Page 80: ...shared reference or common voltage This common voltage is implied to be a power supply common Some systems allow the shield drain wire to be used as common wire and to connect directly to the M60 COM terminal 3 others function cor rectly only if the common wire is connected to the M60 COM terminal but insulated from the shield To avoid loop currents ground the shield at only one point If other sys...

Page 81: ...85 SERIAL CONNECTION c 100BASE FX FIBER OPTIC PORTS Ensure that the dust covers are installed when the fiber is not in use Dirty or scratched connectors can lead to high losses on a fiber link Observing any fiber transmitter output can injure the eye The fiber optic communication ports allow for fast and efficient communications between relays at 100 Mbps Optical fiber can be connected to the rela...

Page 82: ...are serial width modulated codes that can be either DC level shifted or ampli tude modulated AM Third party equipment is available for generating the IRIG B signal this equipment can use a GPS satellite system to obtain the time reference so that devices at different geographic locations can be synchronized Figure 3 24 OPTIONS FOR THE IRIG B CONNECTION Using an amplitude modulated receiver causes ...

Page 83: ...OUTPUT SINGLE CHANNEL CONNECTION The interconnection for dual channel Type 7 communications modules is shown as follows Two channel modules allow for a redundant ring configuration That is two rings can be created to provide an additional independent data path The required connections are UR1 Tx1 to UR2 Rx1 UR2 Tx1 to UR3 Rx1 UR3 Tx1 to UR4 Rx1 and UR4 Tx1 to UR1 Rx1 for the first ring and UR1 Tx2...

Page 84: ... channel 2H IEEE C37 94 820 nm 128 kbps multimode LED 2 channels 2I Channel 1 IEEE C37 94 MM 64 128 kbps Channel 2 1300 nm single mode 2J Channel 1 IEEE C37 94 MM 64 128 kbps Channel 2 1550 nm single mode 72 1550 nm single mode laser 1 channel 73 1550 nm single mode laser 2 channels 74 Channel 1 RS422 channel 2 1550 nm single mode laser 75 Channel 1 G 703 channel 2 1550 nm single mode laser 76 IEE...

Page 85: ...ANSMITTERS The following figure shows the configuration for the 72 73 7D and 7K fiber laser module Figure 3 29 LASER FIBER MODULES 7N Channel 1 RS422 channel 2 1300 nm single mode ELED 7P Channel 1 RS422 channel 2 1300 nm single mode laser 7Q Channel 1 G 703 channel 2 1300 nm single mode laser 7R G 703 1 channel 7S G 703 2 channels 7T RS422 1 channel 7V RS422 2 channels 2 clock inputs N60 only 7W ...

Page 86: ...RATION The following figure shows the typical pin interconnection between two G 703 interfaces For the actual physical arrange ment of these pins see the Rear Terminal Layout section earlier in this chapter All pin interconnections are to be main tained for a connection to a multiplexer Figure 3 31 TYPICAL PIN INTERCONNECTION BETWEEN TWO G 703 INTERFACES Pin nomenclature can differ from one manufa...

Page 87: ... of bit 8 LSB necessary for connecting to higher order systems When M60s are connected back to back octet timing is disabled OFF d G 703 TIMING MODES There are two timing modes for the G 703 module internal timing mode and loop timing mode default Internal Timing Mode The system clock is generated internally Therefore the G 703 timing selection should be in the internal timing mode for back to bac...

Page 88: ... G 703 line side of the interface Figure 3 33 G 703 MINIMUM REMOTE LOOPBACK MODE In dual loopback mode the multiplexers are active and the functions of the circuit are divided into two with each receiver transmitter pair linked together to deconstruct and then reconstruct their respective signals Differential Manchester data enters the Differential Manchester receiver module and then is returned t...

Page 89: ...nd send timing ST connections However when used in two channel applications certain cri teria must be followed since there is one clock input for the two RS422 channels The system functions correctly when the following connections are observed and your data module has a terminal timing feature Terminal timing is a common fea ture to most synchronous data units that allows the module to accept timi...

Page 90: ...Tx clock in the center of the Tx data bit Figure 3 38 CLOCK AND DATA TRANSITIONS d RECEIVE TIMING The RS422 interface utilizes NRZI MARK modulation code and therefore does not rely on an Rx clock to recapture data NRZI MARK is an edge type invertible self clocking code Data module 1 Data module 2 Signal name Signal name SD A Send data TT A Terminal timing TT B Terminal timing SD B Send data RD A R...

Page 91: ...r the direct fiber channel address power budget issues properly When using a LASER Interface attenuators can be necessary to ensure that you do not exceed maximum optical input power to the receiver Figure 3 39 RS422 AND FIBER INTERFACE CONNECTION Connections shown above are for multiplexers configured as DCE data communications equipment units 3 3 7 G 703 AND FIBER INTERFACE The figure below show...

Page 92: ... at a frame rate of 8000 Hz with a resultant bit rate of 2048 kbps The specifications for the module are as follows IEEE standard C37 94 for 1 128 kbps optical fiber interface for 2G and 2H modules or C37 94 for 2 64 kbps opti cal fiber interface for 76 and 77 modules Fiber optic cable type 50 mm or 62 5 mm core diameter optical fiber Fiber optic mode multimode Fiber optic cable length up to 2 km ...

Page 93: ...placement module is inserted into the correct slot 2 Simultaneously pull the ejector inserter clips located at the top and at the bottom of each module in order to release the module for removal 3 Remove the module cover screw 4 Remove the top cover by sliding it towards the rear and then lift it upwards 5 Set the timing selection switches channel 1 channel 2 to the desired timing modes see descri...

Page 94: ...is as follows Flashing green loop timing mode while receiving a valid data packet Flashing yellow internal mode while receiving a valid data packet Solid red switch to internal timing mode while not receiving a valid data packet The link activity LED status is as follows Flashing green FPGA is receiving a valid data packet Solid yellow FPGA is receiving a yellow bit and remains yellow for each yel...

Page 95: ...t rate of 2048 kbps The specifications for the module are as follows Emulated IEEE standard emulates C37 94 for 1 64 kbps optical fiber interface modules set to n 1 or 64 kbps Fiber optic cable type 9 125 m core diameter optical fiber Fiber optic mode single mode ELED compatible with HP HFBR 1315T transmitter and HP HFBR 2316T receiver Fiber optic cable length up to 11 4 km Fiber optic connector t...

Page 96: ...and at the bottom of each module in order to release the module for removal 3 Remove the module cover screw 4 Remove the top cover by sliding it towards the rear and then lift it upwards 5 Set the timing selection switches channel 1 channel 2 to the desired timing modes see description above 6 Replace the top cover and the cover screw 7 Re insert the C37 94SM module Take care to ensure that the co...

Page 97: ...is as follows Flashing green loop timing mode while receiving a valid data packet Flashing yellow internal mode while receiving a valid data packet Solid red switch to internal timing mode while not receiving a valid data packet The link activity LED status is as follows Flashing green FPGA is receiving a valid data packet Solid yellow FPGA is receiving a yellow bit and remains yellow for each yel...

Page 98: ...3 40 M60 Motor Protection System GE Multilin 3 3 DIRECT INPUT OUTPUT COMMUNICATIONS 3 HARDWARE 3 ...

Page 99: ...required See the EnerVista UR Setup Help File or refer to the EnerVista UR Setup Software section in Chapter 1 for details 4 1 3 ENERVISTA UR SETUP OVERVIEW a ENGAGING A DEVICE The EnerVista UR Setup software can be used in online mode relay connected to directly communicate with the M60 relay Communicating relays are organized and grouped by communication interfaces and into sites Sites can conta...

Page 100: ...settings file has a URS extension that had been removed from the Settings List tree menu it is added back to the Settings List tree menu Drag and Drop The Site List and Settings List control bar windows are each mutually a drag source and a drop target for device order code compatible files or individual menu items Also the Settings List control bar window and any Windows Explorer directory folder...

Page 101: ...s 1 Title bar that shows the pathname of the active data view 2 Main window menu bar 3 Main window tool bar 4 Site list control bar window 5 Settings list control bar window 6 Device data view windows with common tool bar 7 Settings file data view windows with common tool bar 8 Workspace area with data view tabs 9 Status bar 10 Quick action hot links Figure 4 1 ENERVISTA UR SETUP SOFTWARE MAIN WIN...

Page 102: ... by default The following procedure describes how to enable the settings tem plate for UR series settings files 1 Select a settings file from the offline window of the EnerVista UR Setup main screen 2 Right click the selected device or settings file and select the Template Mode Create Template option The settings file template is now enabled and the file tree displayed in light blue The settings f...

Page 103: ... by clicking them The setting available to view is displayed against a yellow background as shown below Figure 4 3 SETTINGS TEMPLATE VIEW TWO SETTINGS SPECIFIED AS EDITABLE 6 Click on Save to save changes to the settings template 7 Proceed through the settings tree to specify all viewable settings c ADDING PASSWORD PROTECTION TO A TEMPLATE It is highly recommended that templates be saved with pass...

Page 104: ...those settings available for editing Display all settings with settings not available for editing greyed out Use the following procedure to only display settings available for editing 1 Select an installed device or a settings file from the tree menu on the left of the EnerVista UR Setup main screen 2 Apply the template by selecting the Template Mode View In Template Mode option 3 Enter the templa...

Page 105: ...fied by the template but all settings are shown The effect of applying the template to the phase time overcurrent settings is shown below Figure 4 6 APPLYING TEMPLATES VIA THE VIEW ALL SETTINGS COMMAND e REMOVING THE SETTINGS TEMPLATE It can be necessary at some point to remove a settings template Once a template is removed it cannot be reapplied and it is necessary to define a new settings templa...

Page 106: ...TRIES The following procedure describes how to lock individual entries of a FlexLogic equation 1 Right click the settings file or online device and select the Template Mode Create Template item to enable the set tings template feature 2 Select the FlexLogic FlexLogic Equation Editor settings menu item By default all FlexLogic entries are specified as viewable and displayed against a yellow backgro...

Page 107: ...w and on the front panel display Figure 4 9 SECURED FLEXLOGIC IN GRAPHICAL VIEW b LOCKING FLEXLOGIC EQUATIONS TO A SERIAL NUMBER A settings file and associated FlexLogic equations can also be locked to a specific UR serial number Once the desired FlexLogic entries in a settings file have been secured use the following procedure to lock the settings file to a specific serial number 1 Select the set...

Page 108: ... changed since the time of installation from a settings file When a settings file is transferred to a M60 device the date time and serial number of the M60 are sent back to EnerVista UR Setup and added to the settings file on the local PC This information can be compared with the M60 actual values at any later date to determine if security has been compromised The traceability information is only ...

Page 109: ...configuration since the settings file was saved a SETTINGS FILE TRACEABILITY INFORMATION The serial number and file transfer date are saved in the settings files when they are sent to a M60 device The M60 serial number and file transfer date are included in the settings file device definition within the EnerVista UR Setup offline window as shown in the example below Figure 4 12 DEVICE DEFINITION S...

Page 110: ...ply for the traceability feature If the user changes any settings within the settings file in the offline window then the traceability information is removed from the settings file If the user creates a new settings file then no traceability information is included in the settings file If the user converts an existing settings file to another revision then any existing traceability information is ...

Page 111: ...rVista UR Setup software The front panel interface consists of LED panels an RS232 port keypad LCD display control pushbuttons and optional user programmable pushbuttons The faceplate is hinged to allow easy access to the removable modules There is also a removable dust cover that fits over the faceplate that must be removed in order to access the keypad panel The following figure shows the horizo...

Page 112: ...next four columns contain the 48 user programmable LEDs The RESET key is used to reset any latched LED indicator or target message once the condition has been cleared these latched conditions can also be reset via the SETTINGS INPUT OUTPUTS RESETTING menu The RS232 port is intended for connection to a portable PC The USER keys are not used in this unit Figure 4 18 TYPICAL LED INDICATOR PANEL FOR E...

Page 113: ...rotection elements are ORed to turn on or off the phase A B or C LEDs VOLTAGE This LED indicates voltage was involved CURRENT This LED indicates current was involved FREQUENCY This LED indicates frequency was involved OTHER This LED indicates a composite function was involved PHASE A This LED indicates phase A was involved PHASE B This LED indicates phase B was involved PHASE C This LED indicates ...

Page 114: ...ent is asserted and remain on until the RESET button on the front panel is pressed after the operand is reset All elements that are able to discriminate faulted phases can independently turn off or on the phase A B or C LEDs This includes phase instantaneous overcurrent phase undervoltage etc This means that the phase A B and C operate oper ands for individual protection elements are ORed to turn ...

Page 115: ...must be entered as shown in the User programmable LEDs section of chapter 5 The LEDs are fully user programmable The default labels can be replaced by user printed labels for both panels as explained in the following section Figure 4 21 LED PANEL 2 DEFAULT LABELS 4 3 3 CUSTOM LABELING OF LEDS a ENHANCED FACEPLATE The following procedure requires these pre requisites EnerVista UR Setup software is ...

Page 116: ...t tool from the package and bend the tabs as described in the following procedures These tabs are used for removal of the default and custom LED labels It is important that the tool be used EXACTLY as shown below with the printed side containing the GE part number facing the user The label package shipped with every M60 contains the three default labels shown below the custom label template sheet ...

Page 117: ...ocedure describes how to remove the LED labels from the M60 enhanced front panel and insert the custom labels 1 Use the knife to lift the LED label and slide the label tool underneath Make sure the bent tabs are pointing away from the relay 2 Slide the label tool under the LED label until the tabs snap out as shown below This attaches the label tool to the LED label ...

Page 118: ...pocket until the text is properly aligned with the LEDs as shown below The following procedure describes how to remove the user programmable pushbutton labels from the M60 enhanced front panel and insert the custom labels 1 Use the knife to lift the pushbutton label and slide the tail of the label tool underneath as shown below Make sure the bent tab is pointing away from the relay ...

Page 119: ...LATE INTERFACE 4 2 Slide the label tool under the user programmable pushbutton label until the tabs snap out as shown below This attaches the label tool to the user programmable pushbutton label 3 Remove the tool and attached user programmable pushbutton label as shown below ...

Page 120: ...oadable file The panel templates provide relative LED locations and located example text x edit boxes The following procedure demonstrates how to install uninstall the custom panel labeling 1 Remove the clear Lexan Front Cover GE Multilin part number 1501 0014 2 Pop out the LED module and or the blank module with a screwdriver as shown below Be careful not to damage the plastic covers 3 Place the ...

Page 121: ...ps The VALUE keys increment or decrement numerical setting values when in programming mode These keys also scroll through alphanumeric values in the text edit mode Alternatively val ues can be entered with the numeric keypad The decimal key initiates and advances to the next character in text edit mode or enters a decimal point The HELP key can be pressed at any time for context sensitive help mes...

Page 122: ...g pages Actual values Settings Commands Targets User displays when enabled ENTER COMMAND PASSWORD This message appears when the USER 1 USER 2 or USER 3 key is pressed and a COMMAND PASSWORD is required i e if COMMAND PASSWORD is enabled and no com mands have been issued within the last 30 minutes Press USER 1 To Select Breaker This message appears if the correct password is entered or if none is r...

Page 123: ...the other actual value headers SETTINGS PRODUCT SETUP Press the MENU key until the header for the first page of Settings appears This page contains settings to configure the relay SETTINGS SYSTEM SETUP Press the MESSAGE DOWN key to move to the next Settings page This page con tains settings for System Setup Repeatedly press the MESSAGE UP and DOWN keys to display the other setting headers and then...

Page 124: ...he VALUE DOWN key displays the previous selection c ENTERING ALPHANUMERIC TEXT Text settings have data values which are fixed in length but user defined in character They can be upper case letters lower case letters numerals and a selection of special characters FLASH MESSAGE TIME 1 0 s For example select the SETTINGS PRODUCT SETUP DISPLAY PROPERTIES FLASH MESSAGE TIME setting MINIMUM 0 5 MAXIMUM ...

Page 125: ...he PASSWORD SECURITY message appears on the display 3 Press the MESSAGE DOWN key until the INSTALLATION message appears on the display 4 Press the MESSAGE RIGHT key until the RELAY SETTINGS Not Programmed message is displayed 5 After the RELAY SETTINGS Not Programmed message appears on the display press the VALUE keys change the selection to Programmed 6 Press the ENTER key 7 When the NEW SETTING ...

Page 126: ... characters and press the ENTER key 8 When the VERIFY NEW PASSWORD is displayed re type in the same password and press ENTER 9 When the NEW PASSWORD HAS BEEN STORED message appears your new Setting or Command Password will be active f CHANGING EXISTING PASSWORD To change an existing password follow the instructions in the previous section with the following exception A message prompts you to type ...

Page 127: ...the any external communications inter face three times within a three minute time span the REMOTE ACCESS DENIED FlexLogic operand is set to On and the M60 does not allow Settings or Command access via the any external communications interface for the next ten minutes The REMOTE ACCESS DENIED FlexLogic operand is set to Off after the expiration of the ten minute timeout ...

Page 128: ...4 30 M60 Motor Protection System GE Multilin 4 3 FACEPLATE INTERFACE 4 HUMAN INTERFACES 4 ...

Page 129: ... USER PROGRAMMABLE FAULT REPORT See page 5 69 OSCILLOGRAPHY See page 5 70 DATA LOGGER See page 5 72 USER PROGRAMMABLE LEDS See page 5 73 USER PROGRAMMABLE SELF TESTS See page 5 76 CONTROL PUSHBUTTONS See page 5 77 USER PROGRAMMABLE PUSHBUTTONS See page 5 79 FLEX STATE PARAMETERS See page 5 84 USER DEFINABLE DISPLAYS See page 5 85 DIRECT I O See page 5 87 TELEPROTECTION See page 5 94 INSTALLATION S...

Page 130: ...FLEXELEMENTS See page 5 134 NON VOLATILE LATCHES See page 5 138 SETTINGS GROUPED ELEMENTS SETTING GROUP 1 See page 5 140 SETTING GROUP 2 SETTING GROUP 6 SETTINGS CONTROL ELEMENTS TRIP BUS See page 5 215 SETTING GROUPS See page 5 217 SELECTOR SWITCH See page 5 219 UNDERFREQUENCY See page 5 225 OVERFREQUENCY See page 5 226 START SUPERVISION See page 5 227 REDUCED VOLTAGE STARTING See page 5 230 DIGI...

Page 131: ... REMOTE DPS INPUTS See page 5 259 REMOTE OUTPUTS DNA BIT PAIRS See page 5 259 REMOTE OUTPUTS UserSt BIT PAIRS See page 5 260 RESETTING See page 5 260 DIRECT INPUTS See page 5 261 DIRECT OUTPUTS See page 5 261 TELEPROTECTION See page 5 264 IEC 61850 GOOSE ANALOGS See page 5 266 IEC 61850 GOOSE UINTEGERS See page 5 267 SETTINGS TRANSDUCER I O DCMA INPUTS See page 5 268 RTD INPUTS See page 5 269 RRTD...

Page 132: ...c diagrams are defined in Appendix F Some settings for current and voltage elements are specified in per unit pu calculated quantities pu quantity actual quantity base quantity For current elements the base quantity is the nominal secondary or primary current of the CT Where the current source is the sum of two CTs with different ratios the base quantity will be the common secondary or pri mary cu...

Page 133: ... currents one associated with each breaker can be used as an input to a breaker fail ure element The sum of both breaker phase currents and 3I_0 residual currents may be required for the circuit relaying and metering functions For a three winding transformer application it may be required to calculate watts and vars for each of three windings using voltage from different sets of VTs These requirem...

Page 134: ... For example in the scheme shown in the above diagram the user configures one source to be the sum of CT1 and CT2 and can name this source as Wdg1 I Once the sources have been configured the user has them available as selections for the choice of input signal for the pro tection elements and as metered quantities b CT VT MODULE CONFIGURATION CT and VT input channels are contained in CT VT modules ...

Page 135: ... set of three channels Upon startup the CPU configures the settings required to characterize the current and voltage inputs and will display them in the appropriate section in the sequence of the banks as described above as follows for a maximum configuration F1 F5 M1 M5 U1 and U5 The above section explains how the input channels are identified and configured to the specific application instrument...

Page 136: ...ts 2 Enter the reset code on the front panel under Commands Commands Relay Maintenance Service Command 3 Change the default password of ChangeMe1 as outlined in the Setting Up CyberSentry and Changing Default Pass word section in the first chapter c PASSWORD REQUIREMENTS A user account requires an alpha numeric password that meets the following requirements Password is case sensitive Password cann...

Page 137: ...rted when local command access is disabled ACCESS LOC CMND ON Asserted when local command access is enabled ACCESS REM SETG OFF Asserted when remote setting access is disabled ACCESS REM SETG ON Asserted when remote setting access is enabled ACCESS REM CMND OFF Asserted when remote command access is disabled ACCESS REM CMND ON Asserted when remote command access is enabled A command or setting wri...

Page 138: ... PATH SETTINGS PRODUCT SETUP SECURITY ACCESS SUPERVISION The following access supervision settings are available INVALID ATTEMPTS BEFORE LOCKOUT This setting specifies the number of times an incorrect password can be entered within a three minute time span before lockout occurs When lockout occurs the LOCAL ACCESS DENIED or REMOTE ACCESS DENIED FlexLogic operands are set to On These operands are r...

Page 139: ...s functions as normal that is a local setting password is required If this setting is any contact input on FlexLogic operand then the operand must be asserted set as on prior to providing the local setting password to gain setting access If setting access is not authorized for local operation front panel or RS232 interface and the user attempts to obtain setting access then the UNAUTHORIZED ACCESS...

Page 140: ...g is applicable when the Remote Settings Authorized setting is programmed to any operand except On or Off The state of the Flex Logic operand is continuously monitored for an off to on transition When this occurs remote setting access is permitted and the timer programmed with the Access Authorized Timeout setting value is started When this timer expires remote setting access is immediately denied...

Page 141: ...to enter a username and password ADDING A NEW USER The following pre requisites are required to add user accounts to the EnerVista security management system The user adding the account must have administrator rights The EnerVista security management system must be enabled previous section To add user accounts 1 Select the Security User Management menu item to open the user management window 2 Ent...

Page 142: ...l values Settings Allows the user to read setting values Commands Allows the user to execute commands Event Recorder Allows the user to use the digital fault recorder FlexLogic Allows the user to read FlexLogic values Update Info Allows the user to write to any function to which they have read privileges When any of the Settings Event Recorder and FlexLogic check boxes are enabled by themselves th...

Page 143: ...ase access is not user attributable In cases where user attributable access is required especially for auditable processes for compliance reasons use server authenti cation RADIUS only No password or security information is displayed in plain text by the EnerVista software or UR device nor are they ever transmitted without cryptographic protection Event Recorder Allows the user to use the digital ...

Page 144: ...ction System GE Multilin 5 2 PRODUCT SETUP 5 SETTINGS 5 CYBERSENTRY SETTINGS THROUGH ENERVISTA CyberSentry security settings are configured under Device Settings Product Setup Security Figure 5 3 CYBERSENTRY SECURITY PANEL ...

Page 145: ...35 1812 Administrator Primary Accounting Port RADIUS accounting port 1 65535 1813 Administrator Vendor ID An identifier that specifies RADIUS vendor specific attributes used with the protocol Value that represents General Electric Administrator RADIUS Authentication Shared Secret Shared secret used in authentication It displays as asterisks This setting must meet the CyberSentry password requireme...

Page 146: ...bled To re enable device authentication the Supervisor unlocks the device for setting changes and then the Administrator can re enable device authentication Disabled Enabled Enabled Administrator Firmware Locked Indicates if the device receives firmware upgrades If Yes and the firmware upgrade attempt is made the device denies the upgrade and displays an error message that the lock is set On each ...

Page 147: ...ervisor role authenticates to unlock the UR relay for setting changes and not approve changes after the fact Only Supervisor can set the Settings and Firmware Lock in the Security Settings This role also has the ability to forcefully logoff any other role and clear the security event log This role can also be disabled but only through a Supervisor authentication When this role is disabled its perm...

Page 148: ...rvisor approval can change the role associated password In CyberSentry password encryption is not supported Session Settings PATH SETTINGS PRODUCT SETUP SECURITY SESSION SETTINGS The following session settings are available SESSION LOCKOUT This setting specifies the number of failed authentications the default is three and the maxi mum is 99 before the device blocks subsequent authentication attem...

Page 149: ... setting changes and whether the device can receive a firmware upgrade This setting can be changed only by the Supervisor role if it is enabled or by the Administrator if the Supervisor role is disabled The Supervisor role enables this setting for the relay to start accepting setting changes or command changes or firmware upgrade After all the setting changes are applied or com mands executed the ...

Page 150: ...ry security use the following procedure for set up 1 Log in to the relay as Administrator by using the Value keys on the front panel to enter the default password ChangeMe1 Note that the Lock relay setting needs to be disabled in the Security Supervisory menu When this setting is disabled configuration and firmware upgrade are possible By default this setting is disabled 2 Enable the Supervisor ro...

Page 151: ... buttons and user programmable buttons located on the front panel can be pressed by an Administrator or Engineer role This also applies to the reset button which resets targets where targets are errors dis played on the front panel or the Targets panel of the EnerVista software The reset button has special behavior in that it allows these two roles to press it even when they are logged in through ...

Page 152: ...tuted with zero This applies to phase and ground current phasors as well as true RMS values and symmetrical compo nents The cut off operation applies to quantities used for metering protection and control as well as those used by communications protocols Note that the cut off level for the sensitive ground input is 10 times lower that the CURRENT CUT OFF LEVEL setting value Raw current samples ava...

Page 153: ...east 50 ms to take effect Clearing records with user programmable operands is not protected by the command password However user program mable pushbuttons are protected by the command password Thus if they are used to clear records the user programma ble pushbuttons can provide extra security if required For example to assign user programmable pushbutton 1 to clear demand records the following set...

Page 154: ...ther RS485 or RRTD communications COMMUNICATIONS SERIAL PORTS See page 5 26 MESSAGE NETWORK See page 5 30 MESSAGE ROUTING See page 5 32 MESSAGE MODBUS PROTOCOL See page 5 34 MESSAGE PROTOCOL DNP 3 0 Range DNP 3 0 IEC 60870 5 104 IEC 60870 5 103 MESSAGE DNP PROTOCOL See page 5 36 MESSAGE DNP IEC104 POINT LISTS See page 5 39 MESSAGE IEC 61850 PROTOCOL See page 5 40 MESSAGE WEB SERVER HTTP PROTOCOL S...

Page 155: ...evices connected in the daisy chain for any other purpose The port is strictly dedicated to RRTD usage when COM2 USAGE is selected as RRTD Power must be cycled to the M60 for changes to the COM2 USAGE setting to take effect c ETHERNET NETWORK TOPOLOGY When using more than one Ethernet port configure each to belong to a different network or subnet using the IP addresses and mask else communication ...

Page 156: ...0 used for the three IP addresses makes them belong to the same network of 10 x x x Single LAN No Redundancy The topology shown in the following figure allows communications to SCADA local configuration monitoring through EnerVista and access to the public network shared on the same LAN No redundancy is provided Figure 5 5 NETWORK CONFIGURATION FOR SINGLE LAN ...

Page 157: ... through LAN2 and LAN3 to which P2 and respectively P3 are connected and configured to work in redundant mode In this configuration P3 uses the IP and MAC address of P2 Figure 5 6 MULTIPLE LANS WITH REDUNDANCY Multiple LANS No Redundancy The following topology provides local configuration monitoring through EnerVista software on LAN1 to which port 1 P1 is connected access to the public network on ...

Page 158: ...or independent mode If a license for PRP was purchased the options are None Failover and PRP If a license for PRP was not purchased the available options are None and Failover In non redundant mode REDUNDANCY set to None ports 2 and 3 operate independently with their own MAC IP and mask addresses If REDUNDANCY is set to Failover the operation of ports 2 and 3 is as follows Ports 2 and 3 use the po...

Page 159: ... PROTOCOL PRP The Parallel Redundancy Protocol PRP defines a redundancy protocol for high availability in substation automation net works It applies to networks based on Ethernet technology ISO IEC 8802 3 and is based on the second edition July 2012 of the IEC 62439 3 clause 4 PRP is designed to provide seamless recovery in case of a single failure in the network by using a combination of LAN dupl...

Page 160: ...hoice when no other route towards a given destination is found Configure the network IP and subnet settings before configuring the routing settings ADDING AND DELETING STATIC ROUTES Host routes are not supported at present The routing table configuration is available on the serial port and front panel This is a deliberate decision to avoid loss of connectivity when remotely configuring the UR By d...

Page 161: ...RtDestination 10 1 1 0 Rt Mask 255 255 255 0 Example of bad configuration RtDestination 10 1 1 1 Rt Mask 255 255 255 0 ROUTING BEHAVIOR COMPARED TO PREVIOUS RELEASES Prior to release 7 10 the UR did not have an explicit manner of configuring routes The only available route was the default route configured as part of the network settings port gateway IP address This limited the ability to route to ...

Page 162: ...rent gateway 10 1 2 1 than the default route This gate way is the address of Router 2 which has knowledge about 10 1 3 0 and is able to route packets coming from UR and des tined to EnerVista SHOW ROUTES AND ARP TABLES This feature is available on the Web interface where the main menu contains an additional Communications menu and two submenus Routing Table ARP Table The tables outline the informa...

Page 163: ...effect when the M60 is restarted h PROTOCOL Select among DNP3 0 IEC60870 104 and IEC60870 103 with DNP being the default For any change to take effect restart the unit The table captures all possible combinations of protocols Table 5 5 PORT AND PROTOCOL COMBINATIONS PROTOCOL PORT CHANNEL RS232 RS485 ETHERNET DNP Channel 1 Eth TCP Channel 2 Eth TCP Modbus Modbus DNP Modbus IEC 61850 Channel 1 Eth T...

Page 164: ...000 MESSAGE DNP VOLTAGE SCALE FACTOR 1 Range 0 001 0 01 0 1 1 10 100 1000 10000 100000 MESSAGE DNP POWER SCALE FACTOR 1 Range 0 001 0 01 0 1 1 10 100 1000 10000 100000 MESSAGE DNP ENERGY SCALE FACTOR 1 Range 0 001 0 01 0 1 1 10 100 1000 10000 100000 MESSAGE DNP PF SCALE FACTOR 1 Range 0 001 0 01 0 1 1 10 100 1000 10000 100000 MESSAGE DNP OTHER SCALE FACTOR 1 Range 0 001 0 01 0 1 1 10 100 1000 1000...

Page 165: ...ffect When this setting is set to Network TCP the DNP protocol can be used over TCP IP on channels 1 or 2 When this value is set to Network UDP the DNP protocol can be used over UDP IP on channel 1 only See the DNP appendix for information on the DNP protocol Changes to these settings take effect when power has been cycled to the relay The DNP NETWORK CLIENT ADDRESS settings can force the M60 to r...

Page 166: ...used to change deadband values from the default for each individual DNP analog input point Whenever power is removed and re applied to the M60 the default deadbands will be in effect The DNP TIME SYNC IIN PERIOD setting determines how often the Need Time Internal Indication IIN bit is set by the M60 Changing this time allows the DNP master to send time synchronization commands more or less often a...

Page 167: ...by assigning FlexLogic operands for binary inputs MSP points or FlexAnalog parameters for analog inputs MME points The menu for the binary input points DNP or MSP points IEC 60870 5 104 is shown below PATH SETTINGS PRODUCT SETUP COMMUNICATIONS DNP IEC104 POINT LISTS BINARY INPUT MSP POINTS Up to 256 binary input points can be configured for the DNP or IEC 60870 5 104 protocols The points are confi...

Page 168: ...else loss of protection or misoperation of the relay can result The M60 supports the Manufacturing Message Specification MMS protocol as specified by IEC 61850 MMS is supported over two protocol stacks TCP IP over Ethernet The M60 operates as an IEC 61850 server The Remote Inputs and Out puts section in this chapter describe the peer to peer GSSE GOOSE message scheme The GSSE GOOSE configuration m...

Page 169: ...plicable to GSSE fixed M60 GOOSE and configurable GOOSE The GSSE settings are shown below PATH SETTINGS PRODUCT SETUP COMMUNICATIONS IEC 61850 PROTOCOL GSSE GOOSE CONFIGURATION TRANSMISSION GSEE These settings are applicable to GSSE only If the fixed GOOSE function is enabled GSSE messages are not transmitted The GSSE ID setting represents the IEC 61850 GSSE application ID name string sent as part...

Page 170: ...ious to 5 0x the destination Ethernet MAC address was determined automatically by taking the sending MAC address that is the unique local MAC address of the M60 and setting the multicast bit The GOOSE VLAN PRIORITY setting indicates the Ethernet priority of GOOSE messages This allows GOOSE messages to have higher priority than other Ethernet data The GOOSE ETYPE APPID setting allows the selection ...

Page 171: ...s 1 through 8 the integrity GOOSE message will still continue to be sent at the pre configured rate even if no changes in the data items are detected The GOOSE functionality was enhanced to prevent the relay from flooding a communications network with GOOSE mes sages due to an oscillation being created that is triggering a message The M60 has the ability of detecting if a data item in one of the G...

Page 172: ...fer IEC 61850 data items between two devices The general steps required for transmission configuration are 1 Configure the transmission dataset 2 Configure the GOOSE service settings 3 Configure the data The general steps required for reception configuration are 1 Configure the reception dataset 2 Configure the GOOSE service settings 3 Configure the data Table 5 6 GOOSE RETRANSMISSION SCHEMES SCHE...

Page 173: ...ust match the configuration on the receiver the default value is 0 Set the CONFIG GSE 1 CONFREV value This value changes automatically as described in IEC 61850 part 7 2 For this example it can be left at its default value 3 Configure the data by making the following changes in the PRODUCT SETUP COMMUNICATION IEC 61850 PROTO COL GGIO1 STATUS CONFIGURATION settings menu Set GGIO1 INDICATION 1 to a ...

Page 174: ... by the GGIO1 ST Ind1 stVal value in the sending device The above settings will be automatically populated by the EnerVista UR Setup software when a com plete SCD file is created by third party substation configurator software For intercommunication between M60 IEDs the fixed DNA UserSt dataset can be used The DNA UserSt dataset con tains the same DNA and UserSt bit pairs that are included in GSSE...

Page 175: ...two data items The Boolean status values from these data items can be utilized as remote input FlexLogic operands First the REMOTE DEVICE 1 16 DATASET setting must be set to contain dataset GOOSEIn 1 that is the first configurable dataset Then REMOTE IN 1 16 ITEM settings must be set to Dataset Item 1 and Dataset Item 2 These remote input FlexLogic operands will then change state in accordance wit...

Page 176: ...anges to the IEC MMS TCP PORT NUMBER setting take effect when the M60 is restarted The SERVER SCANNING feature should be set to Disabled when IEC 61850 client server functionality is not required IEC 61850 has two modes of functionality GOOSE GSSE inter device communication and client server communication If the GOOSE GSSE functionality is required without the IEC 61850 client server feature then ...

Page 177: ... values used to determine when the update the MMXU mag and cVal values from the associated instmag and instcVal values The mag and cVal values are used for the IEC 61850 buffered and unbuffered reports These settings correspond to the associated db data items in the CF functional con straint of the MMXU logical node as per the IEC 61850 standard According to IEC 61850 7 3 the db value shall repre ...

Page 178: ... control the M60 virtual inputs The GGIO4 analog configuration points are shown below PATH SETTINGS PRODUCT SETUP COMMUNICATIONS IEC 61850 PROTOCOL GGIO4 ANALOG CONFIGURATION The NUMBER OF ANALOG POINTS setting determines how many analog data points will exist in GGIO4 When this value is changed the M60 must be rebooted in order to allow the GGIO4 logical node to be re instantiated and contain the...

Page 179: ... all values can be stored Some values may be rounded to the closest possible floating point number The GGIO5 integer configuration points are shown below PATH SETTINGS PRODUCT SETUP COMMUNICATIONS IEC 61850 PROTOCOL GGIO5 ANALOG CONFIGURATION The GGIO5 logical node allows IEC 61850 client access to integer data values This allows access to as many as 16 unsigned integer value points associated tim...

Page 180: ... value from the list of IEC 61850 data attributes supported by the M60 Changes to the dataset will only take effect when the M60 is restarted It is recommended to use reporting service from logical node LLN0 if a user needs some but not all data from already existing GGIO1 GGIO4 and MMXU4 points and their quantity is not greater than 64 minus the number items in this dataset REPORT 1 DATASET ITEMS...

Page 181: ...n result in very large OpCnt values over time This setting allows the OpCnt to be reset to 0 for XCBR1 XCBR CONFIGURATION XCBR1 ST LOC OPERAND Off Range FlexLogic operand MESSAGE XCBR6 ST LOC OPERAND Off Range FlexLogic operand MESSAGE CLEAR XCBR1 OpCnt No Range No Yes MESSAGE CLEAR XCBR6 OpCnt No Range No Yes MESSAGE XCBR1 SYNCCHECK CLS Off Range FlexLogic operand MESSAGE XCBR6 SYNCCHECK CLS Off ...

Page 182: ...e details on these control models The XCBR1 Pos sboTimeout setting is used to select SBO timeout value To be successful the IEC 61850 operate com mand must be executed after the select command within the XCBR1 Pos sboTimeout setting value The disconnect switch configuration settings are shown below Changes to these values will not take effect until the UR is restarted PATH SETTINGS PRODUCT SETUP C...

Page 183: ...t is set to 0 the change takes effect when the M60 is restarted m TFTP PROTOCOL PATH SETTINGS PRODUCT SETUP COMMUNICATIONS TFTP PROTOCOL The Trivial File Transfer Protocol TFTP can be used to transfer files from the M60 over a network The M60 operates as a TFTP server TFTP client software is available from various sources including Microsoft Windows NT The dir txt file obtained from the M60 contai...

Page 184: ...al M_ME_NC_1 analog point Whenever power is removed and re applied to the M60 the default thresholds are in effect The IEC REDUNDANCY setting decides whether multiple client connections are accepted or not If redundancy is set to Yes two simultaneous connections can be active at any given time When the IEC port number is set to 0 the change takes effect when the M60 is restarted The IEC 60870 5 10...

Page 185: ...sed for the real time transfer of data for display and control purposes The relay can be configured to produce EGD data exchanges and other devices can be configured to consume EGD data exchanges The number of produced exchanges up to three the data items in each exchange up to 50 and the exchange production rate can be configured EGD cannot be used to transfer data between UR series relays The re...

Page 186: ... exchange 1 has a setting range of 50 to 1000 ms Exchanges 2 and 3 have a setting range of 500 to 1000 ms FAST PROD EXCH 1 CONFIGURATION EXCH 1 FUNCTION Disable Range Disable Enable MESSAGE EXCH 1 DESTINATION 0 0 0 0 Range standard IP address MESSAGE EXCH 1 DATA RATE 1000 ms Range 50 to 1000 ms in steps of 1 MESSAGE EXCH 1 DATA ITEM 1 0 Range 0 to 65535 in steps of 1 Modbus register address range ...

Page 187: ...the time of ordering See the Order Codes section in chap ter 2 for details IEC103 COMMON ADDRESS OF ASDU This setting uniquely defines this M60 on the serial line Select an ID between 0 and 254 This ID does not need to be in sequential order for all stations that communicate with a controller but it is recom mended Note that RS485 only allows a maximum of 32 slave stations on a communication line ...

Page 188: ...ent either as a response to a general interrogation received from the controller or reported spontaneously Spontaneous transmission occurs as a response to cyclic Class 2 requests If the M60 wants to transmit Class 1 data at that time it demands access for Class 1 data transmission ACD 1 in the con trol field of the response PATH SETTINGS PRODUCT SETUP COMMUNICATIONS IEC60870 5 103 IEC103 INPUTS M...

Page 189: ...E ASDU 1 ANALOG 9 FACTOR 1 000 Range 0 000 to 65 535 in steps of 0 001 MESSAGE ASDU 1 ANALOG 9 OFFSET 0 Range 32768 to 32767 in steps of 1 ASDU 4 ASDU 4 TYP 9 Range 3 or 9 MESSAGE ASDU 4 FUN 0 Range 0 to 255 in steps of 1 MESSAGE ASDU 4 INF 0 Range 0 to 255 in steps of 1 MESSAGE ASDU 4 SCAN TOUT 0 Range 0 to 1000 s in steps of 1 MESSAGE ASDU 4 ANALOG 1 Off Range FlexAnalog parameter MESSAGE ASDU 4...

Page 190: ... allowed to skip ASDU2 and configure measurands in ASDU3 ANALOG FACTOR AND OFFSET For each measurand included in the ASDU a factor and offset can also be configured The factor and offset allow for scaling to be performed on measurands The final measurement sent to the IEC60870 103 mas ter is then a x b where x is the measurand a is the multiplying factor and b is the offset The master has to perfo...

Page 191: ...ent virtual inputs Each command is identified by the unique combination made by the function type FUN and information number INF If the master sends an ASDU command that does not have the FUN and INF of any configured command the relay rejects it Table 5 7 COMMANDS MAPPING TABLE IEC103 COMMANDS COMMAND 0 Range see sub menu below MESSAGE COMMAND 1 Range see sub menu below MESSAGE COMMAND 31 Range s...

Page 192: ...nce the RTC is synchronized with the Precision Time Protocol PTP IRIG B or SNTP its accuracy approaches that of the synchroniz ing time delivered to the relay The SYNCHRONIZING SOURCE setting configures the priority sequence of the time synchronization source to determine which of the available external time sources to use for time synchronization A setting of None causes the RTC and the syn chrop...

Page 193: ...e PTP and or SNTP or to set local time parameters for example time zone daylight savings use the following sections b PRECISION TIME PROTOCOL 1588 PATH SETTINGS PRODUCT SETUP REAL TIME CLOCK PRECISION TIME PROTOCOL 1588 PATH SETTINGS PRODUCT SETUP REAL TIME CLOCK PRECISION TIME PROTOCOL 1588 PTP PORT 1 3 The UR supports the Precision Time Protocol PTP specified in IEEE Std 1588 2008 using the Powe...

Page 194: ...d for and the time received at the end device could be in error by more than 100 µs See the Settings Product Setup Real Time Clock section of this manual for a description of when time values received via PTP are used to update the relay s real time clock The following settings are available for configuring the relay for PTP STRICT POWER PROFILE Power profile IEEE Std C37 238 2011 requires that th...

Page 195: ...rent in different directions this setting should be set to the number of nanoseconds the Ethernet propagation delay to the relay is longer than the mean of path propagation delays to and from the relay For instance if it is known say from the physical length of the fibers and the propagation speed in the fibers that the delay from the relay to the Ethernet switch it is connected to is 9 000 ns and...

Page 196: ...e UTC from the local time these provide When the RTC is synchronized with a communications protocol providing only UTC such as PTP or SNTP the time offset setting is used to determine local time from the UTC provided PTP ALTERNATE_TIME_OFFSET_INDICATOR TLVs are not used to calculate local time When a communications protocol other than PTP provides UTC to local time offset meaning IRIG B that offse...

Page 197: ...ault reports to enable capture of two types of trips for example trip from ther mal protection with the report configured to include temperatures and short circuit trip with the report configured to include voltages and currents Both reports feed the same report file queue The last record is available as individual data items via communications protocols PRE FAULT 1 TRIGGER Specifies the FlexLogic...

Page 198: ... A trigger position of 25 consists of 25 pre and 75 post trigger data The TRIGGER SOURCE is always captured in oscillography and may be any FlexLogic parameter element state contact input virtual output etc The relay sampling rate is 64 samples per cycle The AC INPUT WAVEFORMS setting determines the sampling rate at which AC input signals that is current and voltage are stored Reducing the samplin...

Page 199: ...ed to expedite the selection of the parameter on the relay display It can be quite time consuming to scan through the list of parameters via the relay keypad and display entering this number via the relay keypad will cause the corresponding parameter to be displayed All eight CT VT module channels are stored in the oscillography file The CT VT module channels are named as follows slot_letter termi...

Page 200: ...DATA LOGGER DATA LOGGER MODE Continuous Range Continuous Trigger MESSAGE DATA LOGGER TRIGGER Off Range FlexLogic operand MESSAGE DATA LOGGER RATE 60000 ms Range 15 to 3600000 ms in steps of 1 MESSAGE DATA LOGGER CHNL 1 Off Range Off any FlexAnalog parameter See Appendix A FlexAnalog Parameters for complete list MESSAGE DATA LOGGER CHNL 2 Off Range Off any FlexAnalog parameter See Appendix A FlexAn...

Page 201: ...eters available in a given relay are dependent on the type of relay the type and number of CT VT hardware modules installed and the type and number of Analog Input hardware modules installed Upon startup the relay will automatically prepare the parameter list A list of all possible analog metering actual value parameters is shown in Appendix A FlexAnalog Parameters The parameter index number shown...

Page 202: ...are controlled by the test sequence rather than the protection control and monitor ing features However the LED control mechanism accepts all the changes to LED states generated by the relay and stores the actual LED states on or off in memory When the test completes the LEDs reflect the actual state resulting from relay response during testing The reset pushbutton will not clear any targets when ...

Page 203: ...sary to test all LEDs Next release the pushbutton to automatically start stage 2 Once stage 2 has started the pushbutton can be released When stage 2 is completed stage 3 will automatically start The test may be aborted at any time by pressing the pushbutton c TRIP AND ALARM LEDS PATH SETTINGS PRODUCT SETUP USER PROGRAMMABLE LEDS TRIP ALARM LEDS The trip and alarm LEDs are in the first LED column ...

Page 204: ...Off LED 2 operand SETTING GROUP ACT 2 LED 14 operand Off LED 3 operand SETTING GROUP ACT 3 LED 15 operand Off LED 4 operand SETTING GROUP ACT 4 LED 16 operand Off LED 5 operand SETTING GROUP ACT 5 LED 17 operand Off LED 6 operand SETTING GROUP ACT 6 LED 18 operand Off LED 7 operand Off LED 19 operand Off LED 8 operand Off LED 20 operand Off LED 9 operand Off LED 21 operand Off LED 10 operand Off L...

Page 205: ...etting groups and invoking and scrolling though user programmable displays The location of the control pushbuttons are shown in the following figures Figure 5 11 CONTROL PUSHBUTTONS ENHANCED FACEPLATE An additional four control pushbuttons are included on the standard faceplate when the M60 is ordered with the 12 user programmable pushbutton option Figure 5 12 CONTROL PUSHBUTTONS STANDARD FACEPLAT...

Page 206: ...use control pushbuttons as inputs An event is logged in the event record as per user setting when a control pushbutton is pressed No event is logged when the pushbutton is released The faceplate keys including control keys cannot be operated simultaneously a given key must be released before the next one can be pressed Figure 5 13 CONTROL PUSHBUTTON LOGIC 842010A2 CDR CONTROL PUSHBUTTON 1 FUNCTION...

Page 207: ... user programmable pushbuttons are under the control level of password protection The user configurable pushbuttons for the enhanced faceplate are shown below USER PUSHBUTTON 1 PUSHBUTTON 1 FUNCTION Disabled Range Self Reset Latched Disabled MESSAGE PUSHBTN 1 ID TEXT Range Up to 20 alphanumeric characters MESSAGE PUSHBTN 1 ON TEXT Range Up to 20 alphanumeric characters MESSAGE PUSHBTN 1 OFF TEXT R...

Page 208: ...in non volatile memory and maintained through a loss of control power The pushbutton is reset deactivated in latched mode by asserting the operand assigned to the PUSHBTN 1 RESET set ting or by directly pressing the associated active front panel pushbutton It can also be programmed to reset automatically through the PUSHBTN 1 AUTORST and PUSHBTN 1 AUTORST DELAY set tings These settings enable the ...

Page 209: ...e memory Should the power supply be lost the correct state of the pushbutton is retained upon subsequent power up of the relay PUSHBTN 1 ID TEXT This setting specifies the top 20 character line of the user programmable message and is intended to provide ID information of the pushbutton See the User definable Displays section for instructions on how to enter alphanumeric characters from the keypad ...

Page 210: ...o the PUSHBTN 1 OFF TEXT setting This message can be temporary removed if any front panel keypad button is pressed However ten seconds of keypad inactivity will restore the message if the PUSHBUTTON 1 ON operand is still active If the PUSHBTN 1 MESSAGE is set to Normal the message programmed in the PUSHBTN 1 ID and PUSHBTN 1 ON TEXT settings will be displayed as long as PUSHBUTTON 1 ON operand is ...

Page 211: ...k SETTING Off 0 Local Lock SETTING Off 0 Set SETTING Off 0 Reset SETTING Enabled Disabled Autoreset Function FLEXLOGIC OPERAND PUSHBUTTON 1 ON FLEXLOGIC OPERAND PUSHBUTTON 1 OFF TIMER 200 ms 0 AND AND AND AND AND TIMER 50 ms 0 TIMER 50 ms 0 SETTING Autoreset Delay TPKP 0 TIMER 200 ms 0 AND AND SETTING Drop Out Timer TRST 0 PUSHBUTTON ON To user programmable pushbuttons logic sheet 2 842024A2 LATCH...

Page 212: ...UTTON 1 LED LOGIC OR AND AND SETTING Disabled High Priority Message Priority Normal FLEXLOGIC OPERAND PUSHBUTTON 1 ON Pushbutton 1 LED SETTING any FlexLogic operand PUSHBTN 1 LED CTL AND SETTING Flash Message Time TRST 0 PUSHBUTTON ON LATCHED LATCHED SELF RESET AND From user programmable pushbuttons logic sheet 1 842021A3 FLEXLOGIC OPERAND PUSHBUTTON 1 ON FLEXLOGIC OPERAND PUSHBUTTON 1 OFF SETTING...

Page 213: ...play note that only the programmed screens are displayed The screens can be scrolled using the UP and DOWN keys The display disappears after the default message time out period specified by the PRODUCT SETUP DISPLAY PROPER TIES DEFAULT MESSAGE TIMEOUT setting USER PROGRAMMABLE CONTROL INPUT The user definable displays also respond to the INVOKE AND SCROLL setting Any FlexLogic operand in particula...

Page 214: ...hrough the characters A space is selected like a character 4 Press the decimal key to advance the cursor to the next position 5 Repeat step 3 and continue entering characters until the desired text is displayed 6 The HELP key may be pressed at any time for context sensitive help information 7 Press the ENTER key to store the new settings To enter a numerical value for any of the five items the dec...

Page 215: ...decimal form of user selected Modbus register address corresponding to second tilde marker MESSAGE DISP 1 ITEM 3 0 This item is not being used There is no corresponding tilde marker in top or bottom lines MESSAGE DISP 1 ITEM 4 0 This item is not being used There is no corresponding tilde marker in top or bottom lines MESSAGE DISP 1 ITEM 5 0 This item is not being used There is no corresponding til...

Page 216: ...d output settings The equivalent of the remote device name strings for direct inputs and outputs is the DIRECT OUTPUT DEVICE ID The DIRECT OUTPUT DEVICE ID setting identifies the relay in all direct output messages All UR series IEDs in a ring should have unique numbers assigned The IED ID is used to identify the sender of the direct input and output message If the direct input and output scheme i...

Page 217: ... exceed the capabilities of a single UR series chassis The problem is solved by adding an extra UR series IED such as the C30 to satisfy the additional input and output and programmable logic requirements The two IEDs are connected via single channel digital communication cards as shown in the figure below Figure 5 18 INPUT AND OUTPUT EXTENSION VIA DIRECT INPUTS AND OUTPUTS In the above applicatio...

Page 218: ... application the following settings should be applied For UR series IED 1 DIRECT OUTPUT DEVICE ID 1 DIRECT I O CH1 RING CONFIGURATION Yes DIRECT I O CH2 RING CONFIGURATION Yes For UR series IED 2 DIRECT OUTPUT DEVICE ID 2 DIRECT I O CH1 RING CONFIGURATION Yes DIRECT I O CH2 RING CONFIGURATION Yes For UR series IED 3 DIRECT OUTPUT DEVICE ID 3 DIRECT I O CH1 RING CONFIGURATION Yes DIRECT I O CH2 RIN...

Page 219: ... adaptively increased to 0 6 of a power system cycle The complete application requires addressing a number of issues such as failure of both the communications rings failure or out of service conditions of one of the relays etc Self monitoring flags of the direct inputs and outputs feature would be primarily used to address these concerns EXAMPLE 3 PILOT AIDED SCHEMES Consider the three terminal l...

Page 220: ...ion as shown here Figure 5 23 DUAL CHANNEL CLOSED LOOP DUAL RING CONFIGURATION In the above application the following settings should be applied For UR series IED 1 DIRECT OUTPUT DEVICE ID 1 DIRECT I O CH1 RING CONFIGURATION Yes DIRECT I O CH2 RING CONFIGURATION Yes For UR series IED 2 DIRECT OUTPUT DEVICE ID 2 DIRECT I O CH1 RING CONFIGURATION Yes DIRECT I O CH2 RING CONFIGURATION Yes For UR seri...

Page 221: ...toring window To monitor communications integrity the relay sends 1 message per second at 64 kbps or 2 messages per second 128 kbps even if there is no change in the direct outputs For example setting the CRC ALARM CH1 MESSAGE COUNT to 10000 corresponds a time window of about 160 minutes at 64 kbps and 80 minutes at 128 kbps If the messages are sent faster as a result of direct outputs activity th...

Page 222: ...e total number of unreturned input and output messages is available as the ACTUAL VALUES STATUS DIRECT INPUTS UNRETURNED MSG COUNT CH1 actual value 5 2 17 TELEPROTECTION PATH SETTINGS PRODUCT SETUP TELEPROTECTION Digital teleprotection functionality is designed to transfer protection commands between two or three relays in a secure fast dependable and deterministic fashion Possible applications ar...

Page 223: ...elay by checking the ID on a received channel If an incorrect ID is found on a channel during normal operation the TELEPROT CH1 ID FAIL or TELEPROT CH2 ID FAIL FlexLogic operand is set driving the event with the same name and blocking the teleprotection inputs For commis sioning purposes the result of channel identification is also shown in the STATUS CHANNEL TESTS VALIDITY OF CHANNEL CONFIGURATIO...

Page 224: ...onsists of the following steps Configure the field units This establishes the point to point connection between a specific port on the relay process bus module and a specific digital core on a specific Brick This is a necessary first step in configuring a process bus relay Configure the AC banks This sets the primary and secondary quantities and connections for currents and voltages AC bank config...

Page 225: ...ground CT primary rating must be entered To detect low level ground fault currents the sensitive ground input may be used In this case the sensitive ground CT primary rating must be entered Refer to chapter 3 for more details on CT connections Enter the rated CT primary current values For both 1000 5 and 1000 1 CTs the entry would be 1000 For correct opera tion the CT secondary rating must match t...

Page 226: ...age which would be 115 66 4 On a 14 4 kV system with a delta connection and a VT primary to secondary turns ratio of 14400 120 the voltage value entered would be 120 that is 14400 120 5 4 2 POWER SYSTEM PATH SETTINGS SYSTEM SETUP POWER SYSTEM The power system NOMINAL FREQUENCY value is used as a default to set the digital sampling rate if the system frequency cannot be measured from available sign...

Page 227: ... The frequency tracking feature functions only when the M60 is in the Programmed mode If the M60 is Not Pro grammed then metering values are available but can exhibit significant errors 5 4 3 SIGNAL SOURCES PATH SETTINGS SYSTEM SETUP SIGNAL SOURCES SOURCE 1 4 Identical menus are available for each source The SRC 1 text can be replaced by with a user defined name appropriate for the associated sour...

Page 228: ...alues Only the phasor quantities associated with the actual AC physical input channels will be dis played here All parameters contained within a configured source are displayed in the sources section of the actual values EXAMPLE USE OF SOURCES An example of the use of sources is shown in the diagram below A relay could have the following hardware configuration This configuration could be used on a...

Page 229: ...e MOTOR OVERLOAD FACTOR should be set to 1 1 or 1 25 respectively If the average load current is between full load and the overload factor the thermal capacity remains constant If the average current is less than the full load current the thermal capacity decays exponentially MOTOR NAMEPLATE VOLTAGE This setting represents the rated phase to phase motor voltage The MOTOR NAME PLATE VOLTAGE setting...

Page 230: ...lue to 0 so that a hot motor may be restarted However trip conditions that are still present for example hot RTD will still cause a trip In the event of a real emergency the EMERGENCY RESTART oper and should remain at logic 1 until the emergency is over Any EMERGENCY RESTART operand transition will be logged as an event MOTOR LINE SOURCE This setting selects the source connected to phase current t...

Page 231: ...oad cur rent value at the second speed entered in the SPEED2 MOTOR FLA setting If separate CTs with different ratios or sec ondary currents are required for speed 2 then the relay should be ordered with two CT banks SPEED2 MOTOR FLA This setting specifies the motor full load current for speed 2 Figure 5 26 TWO SPEED MOTOR CONNECTIONS 833723A1 CDR MOTOR T1 T2 T3 T4 T5 T6 L1 L2 L3 CT bank 2 Contact ...

Page 232: ...E Off Range FlexLogic operand MESSAGE BREAKER 1 A 3P CLSD Off Range FlexLogic operand MESSAGE BREAKER 1 A 3P OPND Off Range FlexLogic operand MESSAGE BREAKER 1 B CLOSED Off Range FlexLogic operand MESSAGE BREAKER 1 B OPENED Off Range FlexLogic operand MESSAGE BREAKER 1 C CLOSED Off Range FlexLogic operand MESSAGE BREAKER 1 C OPENED Off Range FlexLogic operand MESSAGE BREAKER 1 Toperate 0 070 s Ran...

Page 233: ...and used to track the breaker open or closed position If the mode is selected as 1 Pole the input mentioned above is used to track phase A and the BREAKER 1 B and BREAKER 1 C settings select operands to track phases B and C respectively BREAKER 1 A 3P OPND This setting selects an operand usually a contact input that should be a normally closed 52 b status input to create a logic 1 when the breaker...

Page 234: ...tion System GE Multilin 5 4 SYSTEM SETUP 5 SETTINGS 5 Figure 5 27 DUAL BREAKER CONTROL SCHEME LOGIC Sheet 1 of 2 IEC 61850 functionality is permitted when the M60 is in Programmed mode and not in the local control mode NOTE ...

Page 235: ... BREAKER 1 OPEN BREAKER 1 DISCREP FLEXLOGIC OPERAND BREAKER 1 TROUBLE FLEXLOGIC OPERAND BREAKER 1 BAD STATUS FLEXLOGIC OPERANDS BREAKER 1 ΦA BAD ST BREAKER 1 ΦA CLSD BREAKER 1 ΦA OPEN BREAKER 1 INTERM ΦA FLEXLOGIC OPERANDS BREAKER 1 ANY P OPEN BREAKER 1 1P OPEN BREAKER 1 OOS SETTING 3 Pole 1 Pole BREAKER 1 MODE SETTING Off BREAKER 1 EXT ALARM SETTING Off BREAKER 1 OUT OF SV AND OR OR SETTING BREAK...

Page 236: ...o disconnect switch 1 SWITCH 1 MODE This setting selects 3 Pole mode where disconnect switch poles have a single common auxiliary switch or 1 Pole mode where each disconnect switch pole has its own auxiliary switch SWITCH 1 SWITCH 1 FUNCTION Disabled Range Disabled Enabled MESSAGE SWITCH 1 NAME SW 1 Range up to 6 alphanumeric characters MESSAGE SWITCH 1 MODE 3 Pole Range 3 Pole 1 Pole MESSAGE SWIT...

Page 237: ...t to create a logic 1 when the disconnect switch is open If a separate 89 b contact input is not available then an inverted 89 a status signal can be used SWITCH 1 B CLOSED If the mode is selected as three pole this setting has no function If the mode is selected as single pole this input is used to track the disconnect switch phase B closed position as above for phase A SWITCH 1 B OPENED If the m...

Page 238: ...5 110 M60 Motor Protection System GE Multilin 5 4 SYSTEM SETUP 5 SETTINGS 5 Figure 5 29 DISCONNECT SWITCH SCHEME LOGIC ...

Page 239: ... to 0 98 and 1 03 to 20 00 This data is converted into two continuous curves by linear interpolation between data points To enter a custom FlexCurve enter the reset and operate times using the VALUE keys for each selected pickup point using the MESSAGE UP DOWN keys for the desired protection curve A B C or D FLEXCURVE A FLEXCURVE A TIME AT 0 00 xPKP 0 ms Range 0 to 65535 ms in steps of 1 Table 5 1...

Page 240: ... a minimum response time and a fixed time above a specified pickup multiples There are 41 recloser curve types supported These definite oper ating times are useful to coordinate operating times typically at higher currents and where upstream and downstream pro tective devices have different operating characteristics The recloser curve configuration window shown below appears when the Initialize Fr...

Page 241: ...s see below Figure 5 31 COMPOSITE RECLOSER CURVE WITH HCT DISABLED With the HCT feature enabled the operating time reduces to 30 ms for pickup multiples exceeding 8 times pickup Figure 5 32 COMPOSITE RECLOSER CURVE WITH HCT ENABLED Configuring a composite curve with an increase in operating time at increased pickup multiples is not allowed If this is attempted the EnerVista UR Setup software gener...

Page 242: ... CURVES GE113 GE120 GE138 AND GE142 GE104 1 1 2 1 5 2 2 5 3 4 5 6 7 8 9 10 12 15 20 0 01 0 02 0 05 0 1 0 2 0 5 1 2 CURRENT multiple of pickup TIME sec GE101 GE102 GE103 GE106 GE105 842723A1 CDR 1 1 2 1 5 2 2 5 3 4 5 6 7 8 9 10 12 15 20 0 05 0 1 0 2 0 5 1 2 5 10 20 50 CURRENT multiple of pickup TIME sec GE113 GE142 GE138 GE120 842725A1 CDR ...

Page 243: ...D GE201 Figure 5 36 RECLOSER CURVES GE131 GE141 GE152 AND GE200 1 1 2 1 5 2 2 5 3 4 5 6 7 8 9 10 12 15 20 0 5 1 2 5 10 20 50 CURRENT multiple of pickup TIME sec GE134 GE151 GE140 GE137 GE201 842730A1 CDR 1 1 2 1 5 2 2 5 3 4 5 6 7 8 9 10 12 15 20 2 5 10 20 50 CURRENT multiple of pickup TIME sec GE131 GE200 GE152 GE141 842728A1 CDR ...

Page 244: ...GE116 GE117 GE118 GE132 GE136 AND GE139 842729A1 CDR 1 1 2 1 5 2 2 5 3 4 5 6 7 8 9 10 12 15 20 0 01 0 02 0 05 0 1 0 2 0 5 1 2 5 10 20 50 CURRENT multiple of pickup TIME sec GE133 GE163 GE162 GE161 GE165 GE164 842726A1 CDR 1 1 2 1 5 2 2 5 3 4 5 6 7 8 9 10 12 15 20 0 01 0 02 0 05 0 1 0 2 0 5 1 2 5 10 20 CURRENT multiple of pickup TIME sec GE116 GE132 GE118 GE117 GE139 GE136 ...

Page 245: ...igure 5 40 RECLOSER CURVES GE119 GE135 AND GE202 842724A1 CDR 1 1 2 1 5 2 2 5 3 4 5 6 7 8 9 10 12 15 20 0 01 0 02 0 05 0 1 0 2 0 5 1 2 5 10 20 CURRENT multiple of pickup TIME sec GE121 GE114 GE112 GE122 GE107 GE115 GE111 842727A1 CDR 1 1 2 1 5 2 2 5 3 4 5 6 7 8 9 10 12 15 20 0 2 0 5 1 2 5 10 20 50 CURRENT multiple of pickup TIME sec GE119 GE202 GE135 ...

Page 246: ...ntact output The state of the contact input can be displayed locally or viewed remotely via the communications facilities provided If a simple scheme where a contact input is used to block an element is desired this selection is made when programming the element This capability also applies to the other features that set flags elements virtual inputs remote inputs schemes and human operators If mo...

Page 247: ... ON IF Contact Input On Cont Ip On Voltage is presently applied to the input external contact closed Off Cont Ip Off Voltage is presently not applied to the input external contact open Contact Output type Form A contact only Current On Cont Op 1 Ion Current is flowing through the contact Voltage On Cont Op 1 VOn Voltage exists across the contact Voltage Off Cont Op 1 VOff Voltage does not exists a...

Page 248: ...UX OV1 DPO AUX OV1 OP Auxiliary overvoltage element has picked up Auxiliary overvoltage element has dropped out Auxiliary overvoltage element has operated AUX OV2 to AUX OV3 Same set of operands as shown for AUX OV1 ELEMENT Auxiliary undervoltage AUX UV1 PKP AUX UV1 DPO AUX UV1 OP Auxiliary undervoltage element has picked up Auxiliary undervoltage element has dropped out Auxiliary undervoltage ele...

Page 249: ...ter 1 output is less than comparison value Counter 2 to Counter 8 Same set of operands as shown for Counter 1 ELEMENT Digital elements Dig Element 1 PKP Dig Element 1 OP Dig Element 1 DPO Digital Element 1 is picked up Digital Element 1 is operated Digital Element 1 is dropped out Dig Element 2 to Dig Element 48 Same set of operands as shown for Dig Element 1 ELEMENT Sensitive directional power DI...

Page 250: ... NEUTRAL OV1 PKP NEUTRAL OV1 DPO NEUTRAL OV1 OP Neutral overvoltage element 1 has picked up Neutral overvoltage element 1 has dropped out Neutral overvoltage element 1 has operated ELEMENT Neutral directional overcurrent NTRL DIR OC1 FWD NTRL DIR OC1 REV Neutral directional overcurrent 1 forward has operated Neutral directional overcurrent 1 reverse has operated NTRL DIR OC2 Same set of operands a...

Page 251: ... RTD protection RRTD COMM FAIL RRTD RTD 1 ALARM DPO RRTD RTD 1 ALARM OP RRTD RTD 1 ALARM PKP RRTD RTD 1 OPEN RRTD RTD 1 SHORTED RRTD RTD 1 TRIP DPO RRTD RTD 1 TRIP OP RRTD RTD 1 TRIP PKP Asserted when RRTD loss of communications is detected Asserted when the RRTD RTD 1 alarm stage drops out Asserted when the RRTD RTD 1 alarm stage operates Asserted when the RRTD RTD 1 alarm stage picks up Asserted...

Page 252: ...A STATOR DIFF DIR B STATOR DIFF DIR C At least one phase of stator differential has operated Phase A of stator differential has picked up Phase B of stator differential has picked up Phase C of stator differential has picked up Phase A of stator differential has operated Phase B of stator differential has operated Phase C of stator differential has operated Phase A of stator differential has dropp...

Page 253: ... Undercurrent for speed 2 U CURR SP2 ALARM PKP U CURR SP2 ALARM OP U CURR SP2 TRIP PKP U CURR SP2 TRIP OP Asserted when the speed 2 undercurrent alarm picks up Asserted when the speed 2 undercurrent alarm operates Asserted when the speed 2 undercurrent trip picks up Asserted when the speed 2 undercurrent trip operates ELEMENT Underfrequency UNDERFREQ 1 PKP UNDERFREQ 1 OP UNDERFREQ 1 DPO Underfrequ...

Page 254: ...en the front panel PICKUP LED is on Asserted when the front panel VOLTAGE LED is on Asserted when the front panel CURRENT LED is on Asserted when the front panel FREQUENCY LED is on Asserted when the front panel OTHER LED is on Asserted when the front panel PHASE A LED is on Asserted when the front panel PHASE B LED is on Asserted when the front panel PHASE C LED is on Asserted when the front pane...

Page 255: ...ctioning Return power supply module to manufacturer Relay is not synchronized to the international time standard A direct device is configured but not connected The Direct I O settings is for a connection that is not in a ring The configuration of modules does not match the stored order code A FlexLogic equation is incorrect A difference is detected between the desired and actual latch contact sta...

Page 256: ...s the last entry in the list of processed FlexLogic parameters One shot POSITIVE ONE SHOT One shot that responds to a positive going edge A one shot refers to a single input gate that generates a pulse in response to an edge on the input The output from a one shot is True positive for only one pass through the FlexLogic equation There is a maximum of 64 one shots NEGATIVE ONE SHOT One shot that re...

Page 257: ...17 through 25 to AND 9 and the outputs from these two gates to AND 2 Inspect each operator between the initial operands and final virtual outputs to determine if the output from the operator is used as an input to more than one following operator If so the operator output must be assigned as a virtual output For the example shown above the output of the AND gate is used as an input to both OR 1 an...

Page 258: ...to start at the out put end of the equation and work back towards the input as shown in the following steps It is also recommended to list operator inputs from bottom to top For demonstration the final output will be arbitrarily identified as parameter 99 and each preceding parameter decremented by one in turn Until accustomed to using FlexLogic it is suggested that a worksheet with a series of ce...

Page 259: ...et of parame ters into a logic diagram The result of this process is shown below which is compared to the logic for virtual output 3 dia gram as a check Figure 5 47 FLEXLOGIC EQUATION FOR VIRTUAL OUTPUT 3 6 Repeating the process described for virtual output 3 select the FlexLogic parameters for Virtual Output 4 99 The final output of the equation is virtual output 4 which is parameter Virt Op 4 98...

Page 260: ...es where a lot of processing is required to perform logic this may be difficult to achieve but in most cases will not cause problems as all logic is calculated at least four times per power frequency cycle The possibility of a problem caused by sequential processing emphasizes the necessity to test the performance of FlexLogic before it is placed in service In the following equation virtual output...

Page 261: ...C EQUATION EDITOR PATH SETTINGS FLEXLOGIC FLEXLOGIC EQUATION EDITOR There are 512 FlexLogic entries available numbered from 1 to 512 with default END entry settings If a Disabled Element is selected as a FlexLogic entry the associated state flag will never be set to 1 The key may be used when editing FlexLogic equations from the keypad to quickly scan through the major parameter types 5 5 6 FLEXLO...

Page 262: ...Disabled Range Disabled Enabled MESSAGE FLEXELEMENT 1 NAME FxE1 Range up to 6 alphanumeric characters MESSAGE FLEXELEMENT 1 IN Off Range Off any analog actual value parameter MESSAGE FLEXELEMENT 1 IN Off Range Off any analog actual value parameter MESSAGE FLEXELEMENT 1 INPUT MODE Signed Range Signed Absolute MESSAGE FLEXELEMENT 1 COMP MODE Level Range Level Delta MESSAGE FLEXELEMENT 1 DIRECTION Ov...

Page 263: ...mple applications for the Absolute setting include monitoring the angular difference between two phasors with a symmetrical limit angle in both directions monitoring power regardless of its direction or monitoring a trend regardless of whether the signal increases of decreases The element responds directly to its operating signal as defined by the FLEXELEMENT 1 IN FLEXELEMENT 1 IN and FLEX ELEMENT...

Page 264: ...on with the FLEXELEMENT 1 INPUT MODE setting the element could be programmed to provide two extra charac teristics as shown in the figure below FlexElement 1 OpSig FLEXELEMENT 1 PKP FLEXELEMENT DIRECTION Over PICKUP HYSTERESIS of PICKUP FlexElement 1 OpSig FLEXELEMENT 1 PKP FLEXELEMENT DIRECTION Under PICKUP HYSTERESIS of PICKUP 842705A1 CDR ...

Page 265: ... with all analog actual values measured by the relay The FLEXELEMENT 1 PICKUP setting is entered in per unit values using the following definitions of the base units Table 5 17 FLEXELEMENT BASE UNITS CURRENT UNBALANCE Amp Unbalance BASE 100 dcmA BASE maximum value of the DCMA INPUT MAX setting for the two transducers configured under the IN and IN inputs DELTA TIME BASE 1 µs FREQUENCY fBASE 1 Hz P...

Page 266: ...ENSITIVE DIR POWER Sns Dir Power PBASE maximum value of 3 VBASE IBASE for the IN and IN inputs of the sources configured for the sensitive power directional element s SOURCE CURRENT IBASE maximum nominal primary RMS value of the IN and IN inputs SOURCE ENERGY Positive and Negative Watthours Positive and Negative Varhours EBASE 10000 MWh or MVAh respectively SOURCE POWER PBASE maximum value of VBAS...

Page 267: ...ION TABLE N 1 to 16 AND LOGIC 842005A2 CDR LATCH 1 FUNCTION LATCH 1 TYPE LATCH 1 SET LATCH 1 SET RUN SET RESET SETTING SETTING SETTING SETTING FLEXLOGIC OPERANDS Off 0 Off 0 Enabled 1 LATCH 1 ON LATCH 1 OFF LATCH N TYPE LATCH N SET LATCH N RESET LATCH N ON LATCH N OFF Reset Dominant ON OFF ON OFF OFF OFF Previous State Previous State ON ON OFF ON OFF ON OFF ON Set Dominant ON OFF ON OFF ON ON ON O...

Page 268: ...set or selected via the SETTING GROUPS menu see the Control Elements section later in this chapter See also the Introduction to Elements section at the beginning of this chap ter 5 6 2 SETTING GROUP PATH SETTINGS GROUPED ELEMENTS SETTING GROUP 1 6 Each of the six setting group menus is identical Setting group 1 the default active group automatically becomes active if no other group is active see t...

Page 269: ...rmal model element Both the signal source and thermal pro tection must be configured properly in order for the acceleration time protection to operate The figure below shows examples of constant and variable acceleration currents and explains measurement of the acceler ation time and current Part A represents a constant current start and part B represents a variable current start MOTOR ACCELERATIO...

Page 270: ...ation time element When set to Def inite Time the element times duration of the motor start and operates when the starting time exceeds the ACCELERA TION TIME setting When set to Adaptive the element uses the effective accelerating current to adapt to the starting conditions The operating equation assumes that the accelerating power is proportional to the square of the current and neglects any cur...

Page 271: ... TIME CONSTANT RUNNING 15 min Range 1 to 65000 min in steps of 1 MESSAGE COOL TIME CONSTANT STOPPED 30 min Range 1 to 65000 min in steps of 1 MESSAGE HOT COLD SAFE STALL RATIO 1 00 Range 0 01 to 1 00 in steps of 0 01 MESSAGE RTD BIAS Disabled Range Disabled Enabled MESSAGE RTD BIAS MINIMUM 40 C Range 0 to 250 C in steps of 1 MESSAGE RTD BIAS CENTER POINT 130 C Range 0 to 250 C in steps of 1 MESSAG...

Page 272: ...tor heating in both the stator and rotor during stall acceleration and running conditions The overload curve can take one of six formats Motor FlexCurve A FlexCurve B FlexCurve C FlexCurve D or IEC The selected curve can also serve as a base for a voltage dependent overload curve if the VOLTAGE DEPEN DENT FUNCTION setting is Enabled The algorithm uses memory in the form of a register called Therma...

Page 273: ...3 26 262 42 291 58 320 74 349 90 379 05 408 21 437 37 2 25 21 53 43 06 64 59 86 12 107 65 129 18 150 72 172 25 193 78 215 31 236 84 258 37 279 90 301 43 322 96 2 50 16 66 33 32 49 98 66 64 83 30 99 96 116 62 133 28 149 94 166 60 183 26 199 92 216 58 233 24 249 90 2 75 13 33 26 65 39 98 53 31 66 64 79 96 93 29 106 62 119 95 133 27 146 60 159 93 173 25 186 58 199 91 3 00 10 93 21 86 32 80 43 73 54 6...

Page 274: ...on the product of the service factor and full load current OF FLA this setting should be selected as Shifted The time to trip is then calculated using the following equation EQ 5 11 In the above equation the motor stator current Imotor and motor rated current FLA are expressed in per units of relay current In case of uncertainty the more conservative Cutoff value should be used The following figur...

Page 275: ...ues programmed for the COOL TIME CONSTANT RUNNING and COOL TIME CONSTANT STOPPED settings If the IEC curve is selected then the following applies 1 For two speed motor applications the IEC CURVE K FACTOR and IEC CURVE TIME CONSTANT settings are used at both speeds 2 Voltage dependent overload curves are not applicable 3 The motor status is evaluated using motor FLA Ib and the IEC CURVE K FACTOR se...

Page 276: ...y deviates from the standard Further more the characteristics of the starting locked rotor and acceleration and running thermal damage curves may not correspond smoothly In these cases it may be necessary to use a custom curve so the motor can be started success fully and used to its full potential without compromising protection For these conditions it is recommended that the OF x FLA 8 x OF x FL...

Page 277: ... based on per unit current values The equivalent primary amperes and multiplier of full load current are also indicated above UNBALANCE BIAS K FACTOR Unbalanced phase currents will cause rotor heating that is not shown in the motor thermal damage curve When the motor is running the rotor will rotate in the direction of the positive sequence current at near synchronous speed Negative sequence curre...

Page 278: ... of 1 2 3 4 and 5 equals current unbalances of 6 12 18 24 and 30 respectively Based on this assumption the amount of motor derating for different values of k entered for setting UNBALANCE BIAS K FACTOR is also shown below Note that the curve created when k 8 is almost identical to the NEMA derating curve Figure 5 58 MEDIUM MOTOR DERATING FACTOR DUE TO UNBALANCED VOLTAGE If a value of k 0 is entere...

Page 279: ...When the motor is running at a level that is below this limit thermal capacity used will rise or fall to a value based on Iequivalent average three phase RMS and the selected setting Thermal capacity used will either rise at the fixed rate of 5 per minute or fall as dictated by the running cool time constant EQ 5 16 808705A2 CDR 0 25 50 75 100 0 30 60 90 120 150 180 Time in Minutes Thermal Capacit...

Page 280: ...res of the thermal model is compared to the RTD bias thermal capacity used If the value of the RTD bias thermal capacity used is higher then this value is used from that point onward The RTD BIAS CENTER setting should be selected to the rated running temperature of the motor The relay will automatically determine the RTD bias thermal capacity used value for the center point using the HOT COLD SAFE...

Page 281: ...e MOTOR START INHIBIT operand will be asserted either when motor is tripped by thermal protection TCU 100 or tripped stopped by any other reason TCU 100 Each time motor is tripped stopped by a means other than thermal protection TCU 100 the available thermal capacity 100 TCU is evaluated and compared to the TC required for starting the motor If the available thermal capacity is not sufficient to p...

Page 282: ...cked rotor condition is differ ent than an acceleration condition The voltage dependent overload curve feature is tailored to protect these types of motors This curve is composed of the three characteristic of thermal limit curve shapes as determined by the stall or locked rotor condition acceleration and running overload The figure below presents the typical thermal limit curve for high inertia a...

Page 283: ...e line voltage applied to the motor during the acceleration if VOLTAGE DEPENDENT FUNCTION is enabled This voltage is expressed as a percentage of the SYSTEM SETUP MOTOR MOTOR NAMEPLATE VOLTAGE setting If the measured line voltage drops below this setting during acceleration the thermal curve is switched to one based on the programmed minimum voltage ther mal limit EQ 5 24 VD VOLTAGE LOSS This sett...

Page 284: ...d from the motor acceleration curves The current value at the breakdown torque for the 100 voltage start is recommended for this setting The voltage dependent overload curves are shown below Figure 5 62 VOLTAGE DEPENDENT OVERLOAD CURVES 1 00 10 00 100 00 1000 00 10000 00 0 1 2 3 4 5 6 7 8 PER UNIT CURRENT TIME TO TRIP SECONDS THERMAL MODEL CURVE LOCKED ROTOR LINE MIN V ACCELERATE 100 ACCELERATE 11...

Page 285: ...point 4 6 Draw the locked rotor thermal limit point for the 100 voltage motor start The coordinates of this point are the multiplier of the rated current value FLA of the VD STALL CURRENT 100 V setting and the time value of the VD SAFE STALL TIME 100 V setting see point 3 7 The line connecting points 3 and 4 constructs the acceleration curve for the motor rated system voltage The acceleration time...

Page 286: ...AD CURVE PROTECTION AT MINIMUM VOLTAGE Figure 5 64 VOLTAGE DEPENDENT OVERLOAD CURVE PROTECTION AT 100 VOLTAGE 1 00 10 00 100 00 1000 00 10000 00 0 1 2 3 4 5 6 7 8 PER UNIT CURRENT TIME TO TRIP SECONDS 833716A1 CDR 1 00 10 00 100 00 1000 00 10000 00 0 1 2 3 4 5 6 7 8 PER UNIT CURRENT TIME TO TRIP SECONDS 833717A1 CDR ...

Page 287: ...rves for the following abnormal conditions line voltages below the minimum above 110 and the situation for voltage loss Figure 5 66 VOLTAGE DEPENDENT OVERLOAD CURVE PROTECTION AT LESS THAN MINIMUM VOLTAGE 1 00 10 00 100 00 1000 00 10000 00 0 1 2 3 4 5 6 7 8 PER UNIT CURRENT TIME TO TRIP SECONDS 833718A1 CDR 1 00 10 00 100 00 1000 00 10000 00 0 1 2 3 4 5 6 7 8 PER UNIT CURRENT TIME TO TRIP SECONDS ...

Page 288: ... PROTECTION AT VOLTAGE LOSS CONDITION Figure 5 68 VOLTAGE DEPENDENT OVERLOAD CURVE PROTECTION AT MORE THAN 110 VOLTAGE 1 00 10 00 100 00 1000 00 10000 00 0 1 2 3 4 5 6 7 8 PER UNIT CURRENT TIME TO TRIP SECONDS 833720A1 CDR 1 00 10 00 100 00 1000 00 10000 00 0 1 2 3 4 5 6 7 8 PER UNIT CURRENT TIME TO TRIP SECONDS 833721A1 CDR ...

Page 289: ...al capacity will remain unchanged when control power is restored If the motor status is offline when control power is lost the thermal capacity will decay for the duration of the loss of control power based on the stopped motor cooling rate NOTE 833018A2 CDR OR AND AND AND AND AND AND AND AND AND Voltage dependent motor curve SETTING Motor FlexCurve Curve SETTING Disabled 0 Enabled 1 Voltage Depen...

Page 290: ...0 MOTOR LINE SOURCE STATOR TEMP SENSOR 1 STATOR TEMP SENSOR 2 STATOR TEMP SENSOR 3 STATOR TEMP SENSOR 4 STATOR TEMP SENSOR 5 STATOR TEMP SENSOR 6 COOL TIME CONSTANT RUNNING RTD BIAS CENTER POINT THERMAL MODEL TD MULTIPLIER RTD BIAS MINIMUM THERMAL MODEL CURVE RTD BIAS IA RMS IB RMS IC RMS Pos Seq I Neg Seq I Off 0 Off 0 Enabled 1 TCU Margin 0 TCU Margin 0 AND AND AND AND AND AND AND OR COOL TIME C...

Page 291: ...unbalanced current level exceeds 40 or the average current is above 25 of FLA and the current in any one phase is less than 2 of FLA AMP UNBAL 1 2 PICKUP This setting selects the level of unbalanced current that generates a stage 1 intended to alarm output Note that a supply voltage unbalance of 1 creates a current unbalance of 6 in a typical three phase induction motor a supply voltage unbalance ...

Page 292: ...d under SYSTEM SETUP MOTOR MOTOR LINE SOURCE and motor status asserted by the thermal model element Both the signal source and thermal protection must be configured properly in order for the mechanical jam protection to operate MECHANICAL JAM MECHANICAL JAM FUNCTION Disabled Range Disabled Enabled MESSAGE MECH JAM OVERCURRENT PICKUP 2 00 x FLA Range 1 00 to 10 00 x FLA in steps of 0 01 MESSAGE MEC...

Page 293: ...RCE setting Phase currents must be configured on this source otherwise the undercurrent function will not be operational The ele ment responds to a per phase current UNDERCURRENT UNDERCURRENT FUNCTION Disabled Range Enabled Disabled MESSAGE UNDERCURRENT START BLOCK DLY 0 50 s Range 0 00 to 600 00 s in steps of 0 01 MESSAGE UNDERCURRENT ALARM PICKUP 0 70 x FLA Range 0 10 to 0 95 FLA in steps of 0 0...

Page 294: ... threshold should be less than the motor load current during normal operations UNDERCURRENT ALARM PICKUP DLY This setting specifies a time delay for the alarm stage The time delay should long enough to overcome any short lowering of the current for example during system faults UNDERCURRENT TRIP PICKUP This setting specifies a pickup threshold for the trip stage This setting should be less than the...

Page 295: ...ED2 THERMAL MODEL See page 5 167 MESSAGE SPEED2 ACCELERATION TIME See page 5 168 MESSAGE SPEED2 UNDERCURRENT See page 5 169 SPEED2 THERMAL MODEL SPEED2 THERMAL MODEL CURVE Motor Range Motor FlexCurve A FlexCurve B FlexCurve C FlexCurve D IEC MESSAGE SPEED2 THERMAL MODEL TD MULTIPLIER 1 00 Range 0 00 to 16 00 in steps of 0 01 when speed 2 thermal modle curve is Motor otherwise 0 00 to 600 00 in ste...

Page 296: ...tion time When motor is switched from high speed to low speed the SPEED2 TRANS 2 1 OP FlexLogic operand is set for time defined by the SPEED2 SWITCH 2 1 DELAY setting to allow inputs for control logic of contactors and breakers at both speeds FlexLogic operands required for contactor and breaker control are provided The acceleration time at speed 2 becomes functional only if the acceleration time ...

Page 297: ...a time to block the undercurrent function when motor is starting directly at speed 2 Prior to starting the motor state is determined from the MOTOR OFFLINE operand Refer to the Motor setup section for additional information on the motor offline state determination The speed 2 undercurrent SPEED2 UNDERCURRENT SPEED2 U CURR START BLOCK DLY 0 50 s Range 0 00 to 600 00 s in steps of 0 01 MESSAGE SPEED...

Page 298: ...ng setting for the alarm stage SPEED2 U CURR TRIP PICKUP DLY This setting specifies a time delay for the trip stage This time delay should be long enough to overcome any short lowering of the current for example during system faults SPEED2 U CURR TRIP RESET DLY This setting specifies a time delay to reset the trip command This time delay should be long enough to allow the breaker or contactor to d...

Page 299: ...OR DIFF FUNCTION Disabled Range Disabled Enabled MESSAGE STATOR DIFF LINE END SOURCE SRC 1 Range SRC 1 SRC 2 SRC 3 SRC 4 MESSAGE STATOR DIFF NEUTRAL END SOURCE SRC 1 Range SRC 1 SRC 2 SRC 3 SRC 4 MESSAGE STATOR DIFF PICKUP 0 100 pu Range 0 050 to 1 000 pu in steps of 0 001 MESSAGE STATOR DIFF SLOPE 1 10 Range 1 to 100 in steps of 1 MESSAGE STATOR DIFF BREAK 1 1 15 pu Range 1 00 to 1 50 pu in steps...

Page 300: ...to ensure sensitivity to internal faults at normal operating current levels The criteria for setting this slope is to allow for maximum expected CT mismatch error when operating at the maximum permitted current This maximum error is generally in the range of 5 to 10 of CT rating STATOR DIFF BREAK 1 This setting defines the end of the Slope 1 region and the start of the transition region It should ...

Page 301: ...thm returns to the NORMAL state if the differential current is below the first slope SL for more than 200 ms When in the EXTERNAL FAULT state the algorithm goes into the EXTERNAL FAULT CT SATU RATION state if the differential flag is set DIF 1 When in the EXTERNAL FAULT CT SATURATION state the algo rithm keeps the saturation flag set SAT 1 The state machine returns to the EXTERNAL FAULT state if t...

Page 302: ...R See page 5 175 MESSAGE UNDERPOWER See page 5 178 842707A1 CDR AND AND AND OR OR OR OR STATOR DIFF OP STATOR DIFF OP C STATOR DIFF OP B STATOR DIFF OP A STATOR DIFF PKP A STATOR DIFF PKP B STATOR DIFF PKP C STATOR DIFF SAT A STATOR DIFF SAT B STATOR DIFF SAT C STATOR DIFF DIR A STATOR DIFF DIR B STATOR DIFF DIR C FLEXLOGIC OPERAND FLEXLOGIC OPERANDS FLEXLOGIC OPERANDS FLEXLOGIC OPERANDS FLEXLOGIC...

Page 303: ...ive powers as measured per the UR series metering convention is a sum of the element characteristic DIR POWER 1 RCA and calibration DIR POWER 1 CALIBRATION angles and SMIN is the minimum operating power The operating quantity is displayed in the ACTUAL VALUES METERING SENSITIVE DIRECTIONAL POWER 1 2 actual value The element has two independent as to the pickup and delay settings stages for alarm a...

Page 304: ...d in the figure below For example section a in the figure below shows settings for reverse power while section b shows settings for low forward power applications Figure 5 82 DIRECTIONAL POWER ELEMENT SAMPLE APPLICATIONS RESTRAIN SMIN RCA CALIBRATION OPERATE D i r e c t i o n Q P 842702A1 CDR P Q OPERATE RESTRAIN RCA 0o SMIN 0 d P Q OPERATE RESTRAIN RCA 180o SMIN 0 a P Q OPERATE RESTRAIN RCA 0o SM...

Page 305: ...e restrain region along the RCA line Refer to the Directional power sample applications figure for details Together with the RCA this setting enables a wide range of operating characteristics This setting applies to three phase power and is entered in per unit pu values The base quantity is 3 phase power on primary side which is calculated as x Phase CT Primary x Phase VT Ratio x Phase VT Secondar...

Page 306: ...value of 0 specifies that the feature is not blocked from start For values other than 0 the feature is disabled when the motor is stopped and also from the time a start is detected until the time entered expires UNDERPOWER 1 ALARM PWR PICKUP This setting specifies a pickup threshold for the alarm stage The base per unit power quantity is 3 VT pu base CT pu base per source selected as a motor line ...

Page 307: ...Figure 5 84 UNDERPOWER LOGIC 833025A1 CDR Sop sum Sa Sb Sc SETTING Ia Ib MOTOR LINE SOURCE Ic VOLTAGE CONNECTION Vab Wye Delta Vca Vbc Vag Vcg Vbg CALCULATE FLEXLOGIC OPERAND MOTOR OFFLINE AND AND AND Off UNDERPOWER 1 BLOCK SETTINGS Enabled UNDERPOWER 1 FUNCTION COMPARATORS magnitude Ia 0 1 FLA magnitude Ib 0 1 FLA magnitude Va 0 25 pu magnitude Ic 0 1 FLA magnitude Vb 0 25 pu magnitude Vc 0 25 pu...

Page 308: ... elements dependent on CT VT modules ordered and two 2 phase directional overcurrent elements PHASE CURRENT PHASE IOC1 See page 5 181 MESSAGE PHASE IOC2 See page 5 181 MESSAGE PHASE IOC3 See page 5 181 MESSAGE PHASE IOC4 See page 5 181 MESSAGE PHASE IOC5 See page 5 181 MESSAGE PHASE IOC6 See page 5 181 MESSAGE PHASE IOC7 See page 5 181 MESSAGE PHASE IOC8 See page 5 181 MESSAGE PHASE DIRECTIONAL 1 ...

Page 309: ...GET 8400A Figure 5 85 PHASE INSTANTANEOUS OVERCURRENT 1 SCHEME LOGIC PHASE IOC1 PHASE IOC1 FUNCTION Disabled Range Disabled Enabled MESSAGE PHASE IOC1 SIGNAL SOURCE SRC 1 Range SRC 1 SRC 2 SRC 3 SRC 4 MESSAGE PHASE IOC1 PICKUP 1 000 pu Range 0 000 to 30 000 pu in steps of 0 001 MESSAGE PHASE IOC1 PICKUP DELAY 0 00 s Range 0 00 to 600 00 s in steps of 0 01 MESSAGE PHASE IOC1 RESET DELAY 0 00 s Rang...

Page 310: ... quadrature connection If there is a requirement to supervise overcurrent elements for flows in opposite directions such as can happen through a bus tie breaker two phase directional elements should be programmed with opposite element characteristic angle ECA settings PHASE DIRECTIONAL 1 PHASE DIR 1 FUNCTION Disabled Range Disabled Enabled MESSAGE PHASE DIR 1 SIGNAL SOURCE SRC 1 Range SRC 1 SRC 2 ...

Page 311: ...lect the source for the operating and polarizing signals The operating current for the phase directional element is the phase current for the selected current source The polar izing voltage is the line voltage from the phase VTs based on the 90 or quadrature connection and shifted in the leading direction by the element characteristic angle ECA PHASE DIR 1 ECA This setting is used to select the el...

Page 312: ...e page 5 185 MESSAGE NEUTRAL DIRECTIONAL 1 See page 5 186 MESSAGE NEUTRAL DIRECTIONAL 2 See page 5 186 FLEXLOGIC OPERAND FLEXLOGIC OPERAND FLEXLOGIC OPERAND FLEXLOGIC OPERAND SETTING SETTING SETTING SETTING SETTING SETTING PHASE DIR 1 FUNCTION PHASE DIR 1 SOURCE PHASE DIR 1 BLOCK OC WHEN V MEM EXP PHASE DIR 1 BLOCK PHASE DIR 1 ECA PHASE DIR 1 POL V THRESHOLD PH DIR1 BLK A PH DIR1 BLK B PH DIR1 BLK...

Page 313: ...vy load conditions Transformation errors of current transformers CTs during double line and three phase faults Switch off transients during double line and three phase faults The positive sequence restraint must be considered when testing for pickup accuracy and response time multiple of pickup The operating quantity depends on how test currents are injected into the relay single phase injection t...

Page 314: ...y EQ 5 30 The positive sequence restraint allows for more sensitive settings by counterbalancing spurious zero sequence currents resulting from System unbalances under heavy load conditions NEUTRAL DIRECTIONAL OC1 NEUTRAL DIR OC1 FUNCTION Disabled Range Disabled Enabled MESSAGE NEUTRAL DIR OC1 SOURCE SRC 1 Range SRC 1 SRC 2 SRC 3 SRC 4 MESSAGE NEUTRAL DIR OC1 POLARIZING Voltage Range Voltage Curre...

Page 315: ...rrent The following tables define the neutral directional overcurrent element where ECA element characteristic angle and IG ground current When NEUTRAL DIR OC1 POL VOLT is set to Measured VX one third of this voltage is used in place of V_0 The following figure explains the usage of the voltage polarized directional unit of the element The figure below shows the voltage polarized phase angle compa...

Page 316: ...polarization The ground CT must be connected between the ground and neutral point of an adequate local source of ground current The ground current must be greater than 0 05 pu to be vali dated as a polarizing signal If the polarizing signal is not valid neither forward nor reverse indication is given In addition the zero sequence current I_0 must be greater than the PRODUCT SETUP DISPLAY PROPERTIE...

Page 317: ...C1 POS SEQ RESTRAINT This setting controls the amount of the positive sequence restraint Set to 0 063 for backward compatibility with firmware revision 3 40 and older Set to zero to remove the restraint Set higher if large system unbalances or poor CT performance are expected NEUTRAL DIR OC1 OFFSET This setting specifies the offset impedance used by this protection The primary appli cation for the...

Page 318: ...EV LIMIT ANGLE NEUTRAL DIR OC1 OFFSET NEUTRAL DIR OC1 FWD PICKUP NEUTRAL DIR OC1 REV PICKUP NEUTRAL DIR OC1 OP CURR NEUTRAL DIR OC1 OP CURR NEUTRAL DIR OC1 FWD NEUTRAL DIR OC1 REV Measured VX Voltage Calculated V_0 Current Ground Crt IG Zero Seq Crt I_0 Dual Dual V Dual I NOTE 1 CURRENT POLARIZING IS POSSIBLE ONLY IN RELAYS WITH THE GROUND CURRENT INPUTS CONNECTED TO AN ADEQUATE CURRENT POLARIZING...

Page 319: ...tic relays which set the energy capacity directly to zero when the current falls below the reset threshold The Timed selection can be used where the relay must coordinate with electromechanical relays IEEE CURVES The IEEE time overcurrent curve shapes conform to industry standards and the IEEE C37 112 1996 curve classifications for extremely very and moderately inverse The IEEE curves are derived ...

Page 320: ...387 10 465 8 410 7 196 6 418 5 889 5 513 10 0 161 790 70 277 29 423 17 983 13 081 10 513 8 995 8 023 7 361 6 891 IEEE MODERATELY INVERSE 0 5 3 220 1 902 1 216 0 973 0 844 0 763 0 706 0 663 0 630 0 603 1 0 6 439 3 803 2 432 1 946 1 688 1 526 1 412 1 327 1 260 1 207 2 0 12 878 7 606 4 864 3 892 3 377 3 051 2 823 2 653 2 521 2 414 4 0 25 756 15 213 9 729 7 783 6 753 6 102 5 647 5 307 5 041 4 827 6 0 ...

Page 321: ... 280 3 837 3 528 3 297 3 116 2 971 IEC CURVE B 0 05 1 350 0 675 0 338 0 225 0 169 0 135 0 113 0 096 0 084 0 075 0 10 2 700 1 350 0 675 0 450 0 338 0 270 0 225 0 193 0 169 0 150 0 20 5 400 2 700 1 350 0 900 0 675 0 540 0 450 0 386 0 338 0 300 0 40 10 800 5 400 2 700 1 800 1 350 1 080 0 900 0 771 0 675 0 600 0 60 16 200 8 100 4 050 2 700 2 025 1 620 1 350 1 157 1 013 0 900 0 80 21 600 10 800 5 400 3...

Page 322: ...8 1 239 1 060 0 926 IAC VERY INVERSE 0 5 1 451 0 656 0 269 0 172 0 133 0 113 0 101 0 093 0 087 0 083 1 0 2 901 1 312 0 537 0 343 0 266 0 227 0 202 0 186 0 174 0 165 2 0 5 802 2 624 1 075 0 687 0 533 0 453 0 405 0 372 0 349 0 331 4 0 11 605 5 248 2 150 1 374 1 065 0 906 0 810 0 745 0 698 0 662 6 0 17 407 7 872 3 225 2 061 1 598 1 359 1 215 1 117 1 046 0 992 8 0 23 209 10 497 4 299 2 747 2 131 1 813...

Page 323: ...able from instanta neous to 600 00 seconds in steps of 10 ms EQ 5 37 EQ 5 38 where T Operate Time sec TDM Multiplier setting I Input Current Ipickup Pickup Current setting TRESET Reset Time in seconds assuming energy capacity is 100 and RESET Timed RECLOSER CURVES The M60 uses the FlexCurve feature to facilitate programming of 41 recloser curves See the FlexCurve section in this chapter for detail...

Page 324: ...ediately These elements measure the current that is connected to the ground channel of a CT VT module The conversion range of a standard channel is from 0 02 to 46 times the CT rating This channel may be also equipped with a sensitive input The conversion range of a sensitive channel is from 0 002 to 4 6 times the CT rating Figure 5 91 GROUND TOC1 SCHEME LOGIC GROUND TOC1 GROUND TOC1 FUNCTION Disa...

Page 325: ...nnel is from 0 02 to 46 times the CT rating This channel may be equipped with a standard or sensitive input The conversion range of a sensitive channel is from 0 002 to 4 6 times the CT rating Figure 5 92 GROUND IOC1 SCHEME LOGIC GROUND IOC1 GROUND IOC1 FUNCTION Disabled Range Disabled Enabled MESSAGE GROUND IOC1 SIGNAL SOURCE SRC 1 Range SRC 1 SRC 2 SRC 3 SRC 4 MESSAGE GROUND IOC1 PICKUP 1 000 pu...

Page 326: ...CKUP 1 050 pu Range 0 001 to 30 000 pu in steps of 0 001 MESSAGE BF1 USE TIMER 1 Yes Range Yes No MESSAGE BF1 TIMER 1 PICKUP DELAY 0 000 s Range 0 000 to 65 535 s in steps of 0 001 MESSAGE BF1 USE TIMER 2 Yes Range Yes No MESSAGE BF1 TIMER 2 PICKUP DELAY 0 000 s Range 0 000 to 65 535 s in steps of 0 001 MESSAGE BF1 USE TIMER 3 Yes Range Yes No MESSAGE BF1 TIMER 3 PICKUP DELAY 0 000 s Range 0 000 t...

Page 327: ...f a current supervised initiate results in the breaker failure ele ment not being initiated for a breaker that has very little or no current flowing through it which may be the case for trans former faults For those situations where it is required to maintain breaker fail coverage for fault levels below the BF1 PH AMP SUPV PICKUP or the BF1 N AMP SUPV PICKUP setting a current supervised initiate s...

Page 328: ...serts an opening resistor into the faulted circuit to a lower level after resistor insertion The high set detector is enabled after timeout of timer 1 or 2 along with a timer that will enable the low set detector after its delay interval The delay interval between high set and low set is the expected breaker opening time Both current detectors provide a fast operating time for currents at small mu...

Page 329: ...or three pole tripping schemes BF1 USE TIMER 1 If set to Yes the early path is operational BF1 TIMER 1 PICKUP DELAY Timer 1 is set to the shortest time required for breaker auxiliary contact Status 1 to open from the time the initial trip signal is applied to the breaker trip circuit plus a safety margin BF1 USE TIMER 2 If set to Yes the main path is operational BF1 TIMER 2 PICKUP DELAY Timer 2 is...

Page 330: ...ximately 90 of the resistor current This setting is valid only for three pole breaker failure schemes BF1 LOSET TIME DELAY Sets the pickup delay for current detection after opening resistor insertion BF1 TRIP DROPOUT DELAY This setting is used to set the period of time for which the trip output is sealed in This timer must be coordinated with the automatic reclosing scheme of the failed breaker to...

Page 331: ...NG Off 0 Use Seal In SETTING Yes 1 Use Amp Supervision SETTING Yes 1 Phase C Initiate SETTING Off 0 SETTING RUN IC Pickup RUN IA Pickup RUN IB Pickup Initiated phase A to breaker failure single pole logic sheet 2 BKR FAIL 1 RETRIP A FLEXLOGIC OPERAND Initiated to breaker failure single pole logic sheet 2 Phase Current Supervision Pickup Source SETTING IA IB IC SETTING Initiated phase B to breaker ...

Page 332: ... 1 QLWLDWHG SKDVH IURP VLQJOH SROH EUHDNHU IDLOXUH ORJLF VKHHW 7LPHU 3LFNXS HOD 6 77 1 1 8VH 7LPHU 6 77 1 6 HV UHDNHU 3RV 3KDVH 3 2II UHDNHU 3RV 3KDVH 2II UHDNHU 3RV 3KDVH 2II UHDNHU 7HVW 2Q 2II 1 QLWLDWHG IURP VLQJOH SROH EUHDNHU IDLOXUH ORJLF VKHHW 7LPHU 3LFNXS HOD 6 77 1 1 1 25 1 25 25 6 77 1 3KDVH XUUHQW L6HW 3LFNXS 581 R6HW 7LPH HOD 6 77 1 6 77 1 3KDVH XUUHQW L6HW 3LFNXS 581 R6HW 7LPH HOD 6 7...

Page 333: ...GE Multilin M60 Motor Protection System 5 205 5 SETTINGS 5 6 GROUPED ELEMENTS 5 Figure 5 97 THREE POLE BREAKER FAILURE INITIATE ...

Page 334: ...5 206 M60 Motor Protection System GE Multilin 5 6 GROUPED ELEMENTS 5 SETTINGS 5 Figure 5 98 THREE POLE BREAKER FAILURE TIMERS ...

Page 335: ...ents through the block feature of those elements Source Transfer Schemes In the event of an undervoltage a transfer signal may be generated to transfer a load from its normal source to a standby or emergency power source The undervoltage elements can be programmed to have a definite time delay characteristic The definite time curve oper ates when the voltage drops below the pickup level for a spec...

Page 336: ...wn below EQ 5 39 where T operating time D undervoltage delay setting D 0 00 operates instantaneously V secondary voltage applied to the relay Vpickup pickup level Figure 5 99 INVERSE TIME UNDERVOLTAGE CURVES At 0 of pickup the operating time equals the UNDERVOLTAGE DELAY setting T D 1 V Vpickup 842788A1 CDR of voltage pickup Time seconds NOTE ...

Page 337: ...ting voltage below which the element is blocked a setting of 0 will allow a dead source to be considered a fault condition Figure 5 100 PHASE UNDERVOLTAGE1 SCHEME LOGIC PHASE UNDERVOLTAGE1 PHASE UV1 FUNCTION Disabled Range Disabled Enabled MESSAGE PHASE UV1 SIGNAL SOURCE SRC 1 Range SRC 1 SRC 2 SRC 3 SRC 4 MESSAGE PHASE UV1 MODE Phase to Ground Range Phase to Ground Phase to Phase MESSAGE PHASE UV...

Page 338: ...RCE SRC 1 Range SRC 1 SRC 2 SRC 3 SRC 4 MESSAGE PHASE OV1 PICKUP 1 000 pu Range 0 000 to 3 000 pu in steps of 0 001 MESSAGE PHASE OV1 PICKUP DELAY 1 00 s Range 0 00 to 600 00 s in steps of 0 01 MESSAGE PHASE OV1 RESET DELAY 1 00 s Range 0 00 to 600 00 s in steps of 0 01 MESSAGE PHASE OV1 BLOCK Off Range FlexLogic Operand MESSAGE PHASE OV1 TARGET Self reset Range Self reset Latched Disabled MESSAGE...

Page 339: ...s element must be configured for a phase VT VT errors and normal voltage unbalance must be considered when setting this element This function requires the VTs to be wye connected Figure 5 102 NEUTRAL OVERVOLTAGE1 SCHEME LOGIC NEUTRAL OV1 NEUTRAL OV1 FUNCTION Disabled Range Disabled Enabled MESSAGE NEUTRAL OV1 SIGNAL SOURCE SRC 1 Range SRC 1 SRC 2 SRC 3 SRC 4 MESSAGE NEUTRAL OV1 PICKUP 0 300 pu Ran...

Page 340: ...EQ OV1 SIGNAL SOURCE SRC 1 Range SRC 1 SRC 2 SRC 3 SRC 4 MESSAGE NEG SEQ OV1 PICKUP 0 300 pu Range 0 000 to 1 250 pu in steps of 0 001 MESSAGE NEG SEQ OV1 PICKUP DELAY 0 50 s Range 0 00 to 600 00 s in steps of 0 01 MESSAGE NEG SEQ OV1 RESET DELAY 0 50 s Range 0 00 to 600 00 s in steps of 0 01 MESSAGE NEG SEQ OV1 BLOCK Off Range FlexLogic operand MESSAGE NEG SEQ OV1 TARGET Self reset Range Self res...

Page 341: ...stics The operating characteristics and equations for both definite and inverse time delay are as for the phase undervoltage element The element resets instantaneously The minimum voltage setting selects the operating voltage below which the element is blocked Figure 5 104 AUXILIARY UNDERVOLTAGE SCHEME LOGIC AUXILIARY UV1 AUX UV1 FUNCTION Disabled Range Disabled Enabled MESSAGE AUX UV1 SIGNAL SOUR...

Page 342: ...r delta VT connection Figure 5 105 AUXILIARY OVERVOLTAGE SCHEME LOGIC AUXILIARY OV1 AUX OV1 FUNCTION Disabled Range Disabled Enabled MESSAGE AUX OV1 SIGNAL SOURCE SRC 1 Range SRC 1 SRC 2 SRC 3 SRC 4 MESSAGE AUX OV1 PICKUP 0 300 pu Range 0 000 to 3 000 pu in steps of 0 001 MESSAGE AUX OV1 PICKUP DELAY 1 00 s Range 0 00 to 600 00 s in steps of 0 01 MESSAGE AUX OV1 RESET DELAY 1 00 s Range 0 00 to 60...

Page 343: ...cific protection or control protection element and checking the desired bus box Once the desired element is selected for a specific bus a list of element operate type operands are displayed and can be assigned to a trip bus If more than one operate type operand is required it may be assigned directly from the trip bus menu TRIP BUS 1 TRIP BUS 1 FUNCTION Disabled Range Enabled Disabled MESSAGE TRIP...

Page 344: ...P BUS 1 LATCHING This setting enables or disables latching of the trip bus output This is typically used when lockout is required or user acknowledgement of the relay response is required TRIP BUS 1 RESET The trip bus output is reset when the operand assigned to this setting is asserted Note that the RESET OP operand is pre wired to the reset gate of the latch As such a reset command the front pan...

Page 345: ...ing Group shown as follows On power up or restart the previously selected 61850 SG Level x is re instated Similarly the input to the setting group control in the UR can be designed with Non Volatile latches to achieve the same effect The setting groups menu controls the activation and deactivation of up to six possible groups of settings in the GROUPED ELEMENTS settings menu The faceplate Settings...

Page 346: ... SETTING GROUP 1 NAME to SETTING GROUP 6 NAME settings allows the user to assign a name to each of the six settings groups Once programmed this name appears on the second line of the GROUPED ELEMENTS SETTING GROUP 1 6 menu display The relay can be set up via a FlexLogic equation to receive requests to activate or de activate a particular non default set tings group The following FlexLogic equation...

Page 347: ... RANGE This setting defines the upper position of the selector When stepping up through avail able positions of the selector the upper position wraps up to the lower position position 1 When using a direct three bit control word for programming the selector to a desired position the change would take place only if the control word is within the range of 1 to the SELECTOR FULL RANGE If the control ...

Page 348: ...does not accept the change and an alarm is established by setting the SELECTOR STP ALARM output FlexLogic operand for 3 seconds SELECTOR 1 ACK This setting specifies an acknowledging input for the stepping up control input The pre selected position is applied on the rising edge of the assigned operand This setting is active only under Acknowledge mode of operation The acknowledging signal must app...

Page 349: ...he selector synchronizes to the position dictated by the three bit control input This operation does not wait for time out or the acknowledging input When the synchronization attempt is unsuccessful that is the three bit input is not available 0 0 0 or out of range then the selector switch output is set to position 0 no output operand selected and an alarm is established SELECTOR 1 PWR ALARM The o...

Page 350: ...e diagrams T represents a time out setting Figure 5 109 TIME OUT MODE 842737A1 CDR STEP UP 3BIT A0 3BIT A1 3BIT A2 POS 1 POS 2 POS 3 POS 4 POS 5 POS 6 POS 7 BIT 0 BIT 1 BIT 2 pre existing position 2 changed to 4 with a pushbutton changed to 1 with a 3 bit input changed to 2 with a pushbutton T T T T changed to 7 with a 3 bit input STP ALARM BIT ALARM ALARM ...

Page 351: ...t should synchronize the setting group to the three bit control input Make the following changes to setting group control in the SETTINGS CONTROL ELEMENTS SETTING GROUPS menu SETTING GROUPS FUNCTION Enabled GROUP 4 ACTIVATE ON SELECTOR 1 POS 4 SETTING GROUPS BLK Off GROUP 5 ACTIVATE ON Off GROUP 2 ACTIVATE ON SELECTOR 1 POS 2 GROUP 6 ACTIVATE ON Off GROUP 3 ACTIVATE ON SELECTOR 1 POS 3 Make the fo...

Page 352: ...ing changes in the SETTINGS PRODUCT SETUP USER PROGRAMMABLE PUSHBUTTONS USER PUSHBUTTON 1 menu PUSHBUTTON 1 FUNCTION Self reset PUSHBUTTON 1 DROP OUT TIME 0 10 s The logic for the selector switch is shown below Figure 5 111 SELECTOR SWITCH LOGIC 842012A2 CDR step up acknowledge 3 bit position out ON FLEXLOGIC OPERANDS SELECTOR 1 POS 1 SELECTOR 1 POS 2 SELECTOR 1 POS 3 SELECTOR 1 POS 4 SELECTOR 1 P...

Page 353: ...meter below the minimum voltage current setting The UNDERFREQ 1 MIN VOLT AMP setting selects the minimum per unit voltage or current level required to allow the underfre quency element to operate This threshold is used to prevent an incorrect operation because there is no signal to measure This UNDERFREQ 1 PICKUP setting is used to select the level at which the underfrequency element is to pickup ...

Page 354: ...e overfrequency element can be used to control the turbine frequency ramp down at a generating location This element can also be used for feeder reclosing as part of the after load shedding restoration The OVERFREQ 1 SOURCE setting selects the source for the signal to be measured The OVERFREQ 1 PICKUP setting selects the level at which the overfrequency element is to pickup Figure 5 113 OVERFREQUE...

Page 355: ...rolled and not the time in between The latter is controlled by the time between starts element When the motor is stopped after the last allowed start the energizing or closing control circuit is disabled until the end of the defined interval Every start initiate a new interval in which the start number is limited A typical starting frequency is three starts per hour 2 Time between starts This func...

Page 356: ...UR DPO operand indicates that the maximum permitted starting rate has not been reached When stopped the motor could be restarted immediately The element uses motor status asserted by the Thermal Model element The thermal protection must be configured prop erly in order for this function to operate Figure 5 114 MAXIMUM STARTING RATE SCHEME LOGIC MAXIMUM STARTING RATE STARTS HR STARTS HR FUNCTION Di...

Page 357: ...nd should be used to inhibit the start command The TIME BTWN STARTS DPO operand indicates that the time between last two starts was long enough When stopped the motor could be restarted immediately The element uses motor status asserted by the thermal model element The thermal protection must be configured properly in order for this function to operate Figure 5 115 TIME BETWEEN STARTS SCHEME LOGIC...

Page 358: ...0 to 50000 s in steps of 1 MESSAGE RESTART DELAY BLOCK Off Range FlexLogic operand MESSAGE RESTART DELAY TARGET Self reset Range Self reset Latched Disabled MESSAGE RESTART DELAY EVENTS Disabled Range Disabled Enabled REDUCED VOLTAGE STARTING REDUCED VOLTAGE STARTING Disabled Range Disabled Enabled MESSAGE TRANSITION MODE Current Only Range Current Only Current or Timer Current and Timer MESSAGE R...

Page 359: ...ent Only When the motor load falls below the REDUCED VOLTAGE FLA setting prior to the expiration of the reduced voltage timer a transition will be initiated by asserting the REDUCED VOLT CTRL operand for a period of one second Any contact output assigned to this operand will operate for this period of time If the reduced voltage timer expires prior to the motor load dropping below the REDUCED VOLT...

Page 360: ... Element 1 Range 16 alphanumeric characters MESSAGE DIG ELEM 1 INPUT Off Range FlexLogic operand MESSAGE DIG ELEM 1 PICKUP DELAY 0 000 s Range 0 000 to 999999 999 s in steps of 0 001 MESSAGE DIG ELEM 1 RESET DELAY 0 000 s Range 0 000 to 999999 999 s in steps of 0 001 MESSAGE DIG ELEMENT 1 PICKUP LED Enabled Range Disabled Enabled MESSAGE DIG ELEM 1 BLOCK Off Range FlexLogic operand MESSAGE DIGITAL...

Page 361: ...s include an active voltage monitor circuit connected across form A contacts The voltage monitor circuit limits the trickle current through the output circuit see technical specifications for form A As long as the current through the voltage monitor is above a threshold see technical specifications for form A the Cont Op 1 VOn FlexLogic operand will be set for contact input 1 corresponding operand...

Page 362: ...ontact output settings this output will be given an ID name for example Cont Op 1 Assume a 52a breaker auxiliary contact is connected to contact input H7a to monitor breaker status Using the contact input settings this input will be given an ID name for example Cont Ip 1 and will be set On when the breaker is closed The settings to use digital element 1 to monitor the breaker trip circuit are indi...

Page 363: ... figure below across the auxiliary contact in the trip circuit In this case it is not required to supervise the monitoring circuit with the breaker position the BLOCK setting is selected to Off In this case the settings are as follows EnerVista UR Setup example shown Figure 5 121 TRIP CIRCUIT EXAMPLE 2 The wiring connection for two examples above is applicable to both form A contacts with voltage ...

Page 364: ...o EQL or less than LO the set value COUNTER 1 UP Selects the FlexLogic operand for incrementing the counter If an enabled UP input is received when the accumulated value is at the limit of 2 147 483 647 counts the counter will rollover to 2 147 483 648 COUNTER 1 DOWN Selects the FlexLogic operand for decrementing the counter If an enabled DOWN input is received when the accumulated value is at the...

Page 365: ...mmand is sent to the counter and the CNT1 SET TO PRESET operand has the value 0 the counter will be set to 0 COUNTER 1 RESET Selects the FlexLogic operand for setting the count to either 0 or the preset value depending on the state of the CNT1 SET TO PRESET operand COUNTER 1 FREEZE RESET Selects the FlexLogic operand for capturing freezing the accumulated count value into a separate register with ...

Page 366: ...RING ELEMENTS MONITORING ELEMENTS BREAKER FLASHOVER 1 See page 5 239 MESSAGE BREAKER FLASHOVER 2 See page 5 239 MESSAGE CT FAILURE DETECTOR See page 5 244 MESSAGE VT FUSE FAILURE 1 See page 5 246 MESSAGE VT FUSE FAILURE 2 See page 5 246 MESSAGE VT FUSE FAILURE 3 See page 5 246 MESSAGE VT FUSE FAILURE 4 See page 5 246 MESSAGE BROKEN ROTOR BAR See page 5 247 ...

Page 367: ...e SRC 1 SRC 2 SRC 3 SRC 4 MESSAGE BKR 1 STATUS CLSD A Off Range FlexLogic operand MESSAGE BKR 1 STATUS CLSD B Off Range FlexLogic operand MESSAGE BKR 1 STATUS CLSD C Off Range FlexLogic operand MESSAGE BKR 1 FLSHOVR V PKP 0 850 pu Range 0 000 to 1 500 pu in steps of 0 001 MESSAGE BKR 1 FLSHOVR DIFF V PKP 1000 V Range 0 to 100000 V in steps of 1 MESSAGE BKR 1 FLSHOVR AMP PKP 0 600 pu Range 0 000 to...

Page 368: ... prior to flashover detection are 1 52a status 0 2 VAg VBg or VCg is greater than the pickup setting 3 IA IB IC 0 no current flows through the breaker 4 VA is greater than pickup not applicable in this scheme The conditions at flashover detection are 1 52a status 0 2 IA IB or IC is greater than the pickup current flowing through the breaker 3 VA is greater than pickup not applicable in this scheme...

Page 369: ... of the breaker A separate FlexLogic operand can be selected to detect individual breaker pole status and pro vide flashover detection The recommended setting is 52a breaker contact or another operand defining the breaker poles open status BRK 1 FLSHOVR V PKP This setting specifies a pickup level for the phase voltages from both sides of the breaker If six VTs are available opening the breaker lea...

Page 370: ...CDR AND AND AND SET dominant RESET SET dominant RESET OR OR OR OR OR BREAKER FLASHOVER FUNCTION BRK 1 FLSHOVR V PKP BRK 1 STATUS CLSD A BRK 1 FLSHOVR PKP DELAY BRK 1 FLSHOVR DPO A BRK 1 FLSHOVR PKP A BRK 1 FLSHOVR OP BRK 1 FLSHOVR PKP BRK 1 FLSHOVR DPO BRK 1 FLSHOVR OP A BRK 1 FLSHOVR DPO B BRK 1 FLSHOVR PKP B BRK 1 FLSHOVR OP B BRK 1 FLSHOVR DPO C BRK 1 FLSHOVR PKP C BRK 1 FLSHOVR OP C BRK 1 FLSH...

Page 371: ...these conditions This could occur when an element is incorrectly set so that it may misoperate under load The continuous monitor can detect this state and issue an alarm and or block the trip ping of the relay Figure 5 124 CONTINUOUS MONITOR SCHEME LOGIC SETTING CONT MONITOR FUNCTION Enabled 1 SETTING CONSTANT CONT MONITOR TIMER t pkp 1 sec t RST 0 CONT MONITOR I_SUPV Off 0 SETTING CONT MONITOR I_...

Page 372: ...ing operation of some remote current protection elements via communication chan nels can also be chosen CT FAIL 3I0 INPUT 1 This setting selects the current source for input 1 The most critical protection element should also be assigned to the same source CT FAIL 3I0 INPUT 1 PICKUP This setting selects the 3I_0 pickup value for input 1 the main supervised CT source CT FAIL 3I0 INPUT 2 This setting...

Page 373: ...SETTINGS 5 7 CONTROL ELEMENTS 5 CT FAIL 3V0 INPUT PICKUP This setting specifies the pickup value for the 3V_0 source CT FAIL PICKUP DELAY This setting specifies the pickup delay of the CT failure element Figure 5 125 CT FAILURE DETECTOR SCHEME LOGIC ...

Page 374: ...rrent can indicate a VT fuse fail conditions These noted indications of fuse failure can also be present when faults are present on the system so a means of detecting faults and inhibiting fuse failure decla rations during these events is provided Once the fuse failure condition is declared it is sealed in until the cause that generated it disappears An additional condition is introduced to inhibi...

Page 375: ...EME LOGIC Base voltage for this element is PHASE VT SECONDARY setting in the case of WYE VTs and PHASE VT SECONDARY in case of DELTA VTs e BROKEN ROTOR BAR DETECTION PATH SETTINGS CONTROL ELEMENTS MONITORING ELEMENTS BROKEN ROTOR BAR BROKEN ROTOR BAR BROKEN ROTOR BAR FUNCTION Disabled Range Disabled Enabled 3 ...

Page 376: ...while the motor load is small there is not enough resolution to accurately calculate a miniscule spectral component caused by a rotor bar fail ure The motor load is steady Variations in motor load cause spectral components that can be misinterpreted as rotor bar failure Instantaneous motor load values are collected alongside with data for the broken rotor bar algorithm to prevent this from happeni...

Page 377: ... motor slip at full load EQ 5 46 For example if the full load slip is 0 01 program this setting as follows for a 60 Hz power system EQ 5 47 If the lower sideband is to be measured this setting should be programmed as follows where f1 is the system fre quency and s is the motor slip at full load EQ 5 48 Using the same values from previous example this value should be programmed as follows EQ 5 49 B...

Page 378: ...etting specifies the pickup threshold for the broken rotor bar detection feature The pickup threshold should normally be set to a level between 54 dB very likely a cracked rotor bar and 50 dB probably a broken rotor bar BROKEN ROTOR BAR RESET DLY This setting specifies a time delay to reset the broken rotor bar detection fea ture This setting can be left at its default value since the element upda...

Page 379: ...user settable debounce time in order for the M60 to validate the new contact state In the figure below the debounce time is set at 2 5 ms thus the 6th sample in a row validates the change of state mark no 1 in the diagram Once validated de bounced the contact input asserts a corresponding FlexLogic operand and logs an event as per user setting A time stamp of the first sample in the sequence that ...

Page 380: ...ilter the LOW HIGH marks no 1 2 3 and 4 in the figure below and HIGH LOW marks no 5 6 7 and 8 below transitions Figure 5 127 INPUT CONTACT DEBOUNCING MECHANISM AND TIME STAMPING SAMPLE TIMING Contact inputs are isolated in groups of four to allow connection of wet contacts from different voltage sources for each group The CONTACT INPUT THRESHOLDS determine the minimum voltage required to detect a ...

Page 381: ...ut operand will be set to on for only one evaluation of the FlexLogic equations and then return to off If set to Latched the virtual input sets the state of the output operand to the same state as the most recent received input The self reset operating mode generates the output operand for a single evaluation of the FlexLogic equations If the operand is to be used anywhere other than internally in...

Page 382: ...damage to the less robust initiating contact This can be done by monitoring an auxiliary contact on the breaker which opens when the breaker has tripped but this scheme is subject to incorrect oper ation caused by differences in timing between breaker auxiliary contact change of state and interruption of current in the trip circuit The most dependable protection of the initiating contact is provid...

Page 383: ...pecifies the contact response under conflicting control inputs that is when both the OPERATE and RESET signals are applied With both control inputs applied simultaneously the contact will close if set to Operate dominant and will open if set to Reset dominant Application Example 1 A latching output contact H1a is to be controlled from two user programmable pushbuttons buttons number 1 and 2 The fo...

Page 384: ...ista UR Setup example shown Program the Latching Outputs by making the following changes in the SETTINGS INPUTS OUTPUTS CONTACT OUT PUTS CONTACT OUTPUT H1a menu assuming an H4L module OUTPUT H1a OPERATE VO1 OUTPUT H1a RESET VO2 5 8 4 VIRTUAL OUTPUTS PATH SETTINGS INPUTS OUTPUTS VIRTUAL OUTPUTS VIRTUAL OUTPUT 1 96 There are 96 virtual outputs that may be assigned via FlexLogic If not assigned the o...

Page 385: ...n includes features that are used to cope with the loss of communication between transmitting and receiving devices Each transmitting device will send a GSSE GOOSE message upon a successful power up when the state of any included point changes or after a specified interval the default update time if a change of state has not occurred The transmitting device also sends a hold time which is set grea...

Page 386: ...UserSt 32 and Dataset Item 1 through Dataset Item 32 The function of DNA inputs is defined in the IEC 61850 specification and is presented in the IEC 61850 DNA Assignments table in the Remote Outputs section The function of UserSt inputs is defined by the user selection of the FlexLogic operand whose state is represented in the GSSE GOOSE message A user must program a DNA point from the appropriat...

Page 387: ...mote double point status input REM DPS IN 1 DEV This setting selects a remote device ID to indicate the origin of a GOOSE message The range is selected from the remote device IDs specified in the Remote Devices section REM DPS IN 1 ITEM This setting specifies the required bits of the GOOSE message The configurable GOOSE dataset items must be changed to accept a double point status item from a GOOS...

Page 388: ...LED event indicators and the target message on the display Once set the latching mechanism will hold all of the latched indicators or messages in the set state after the initiating condition has cleared until a RESET command is received to return these latches not including FlexLogic latches to the reset state The RESET command can be sent from the faceplate Reset button a remote device via a comm...

Page 389: ...t communication exchange the input will default to Logic 1 When communication resumes the input becomes fully operational Setting DIRECT INPUT 1 DEFAULT STATE to Latest Off freezes the input in case of lost communications If the latest state is not known such as after relay power up but before the first communication exchange the input will default to Logic 0 When communication resumes the input b...

Page 390: ...gnal from downstream devices say 2 3 and 4 to the upstream device that monitors a single incomer of the busbar as shown in the figure below Figure 5 130 SAMPLE INTERLOCKING BUSBAR PROTECTION SCHEME Assume that Phase Instantaneous Overcurrent 1 is used by Devices 2 3 and 4 to block Device 1 If not blocked Device 1 would trip the bus upon detecting a fault and applying a short coordination time dela...

Page 391: ...rchitecture shown below The scheme output operand HYB POTT TX1 is used to key the permission Figure 5 132 SINGLE CHANNEL OPEN LOOP CONFIGURATION In the above architecture Devices 1 and 3 do not communicate directly Therefore Device 2 must act as a bridge The fol lowing settings should be applied UR IED 1 DIRECT OUT 2 OPERAND HYB POTT TX1 DIRECT INPUT 5 DEVICE ID 2 DIRECT INPUT 5 BIT NUMBER 2 this ...

Page 392: ...xLogic operands to be sent via the selected communications channel This allows the user to create distributed protec tion and control schemes via dedicated communications channels Some examples are directional comparison pilot schemes and direct transfer tripping It should be noted that failures of communications channels will affect teleprotection functionality The teleprotection function must be...

Page 393: ...tputs is dependent on the number of com munication channels and terminals On two terminal two channel systems they are processed continuously on each chan nel and mapped separately per channel Therefore to achieve redundancy the user must assign the same operand on both channels teleprotection outputs at the sending end or corresponding teleprotection inputs at the receiving end On three terminal ...

Page 394: ...og values in other M60 features such as FlexElements The base factor is applied to the GOOSE analog input Flex Analog quantity to normalize it to a per unit quantity The base units are described in the following table GOOSE ANALOG INPUT 1 ANALOG 1 DEFAULT 1000 000 Range 1000000 000 to 1000000 000 in steps of 0 001 MESSAGE ANALOG 1 DEFAULT MODE Default Value Range Default Value Last Known MESSAGE G...

Page 395: ...etting for the two transducers configured under the IN and IN inputs FREQUENCY fBASE 1 Hz PHASE ANGLE BASE 360 degrees see the UR angle referencing convention POWER FACTOR PFBASE 1 00 RTDs BASE 100 C SENSITIVE DIR POWER Sns Dir Power PBASE maximum value of 3 VBASE IBASE for the IN and IN inputs of the sources configured for the sensitive power directional element s SOURCE CURRENT IBASE maximum nom...

Page 396: ... automatically generated for every channel available in the specific relay as shown above for the first channel of a type 5F transducer module installed in slot H The function of the channel may be either Enabled or Disabled If Disabled no actual values are created for the chan nel An alphanumeric ID is assigned to each channel this ID will be included in the channel actual value along with the pr...

Page 397: ... function of the channel may be either Enabled or Disabled If set to Disabled there will not be an actual value created for the channel RTD INPUT H1 ID An alphanumeric ID is assigned to the channel This ID will be included in the channel actual val ues It is also used to reference the channel as the input parameter to features designed to measure this type of parameter RTD INPUT H1 RTD INPUT H1 FU...

Page 398: ...NPUT H1 TRIP TEMPERATURE This setting specifies the temperature pickup level for the trip stage RTD INPUT H1 TRIP PKP DELAY This setting specifies time delay for the trip stage until the output can be asserted Table 5 31 RTD TEMPERATURE VS RESISTANCE TEMPERATURE RESISTANCE IN OHMS C F 100 OHM PT DIN 43760 120 OHM NI 100 OHM NI 10 OHM CU 50 58 80 31 86 17 71 81 7 10 40 40 84 27 92 76 77 30 7 49 30 ...

Page 399: ...operation when a broken sensor is detected If targets are enabled a message will appear on the display identifying the broken RTD If this feature is used it is rec ommended that the alarm be programmed as latched so that intermittent RTDs are detected and corrective action may be taken RTD INPUT H1 BLOCK This setting is used to block RTD operation Figure 5 135 RTD INPUT PROTECTION LOGIC 5 9 3 RRTD...

Page 400: ... rules are followed If the RRTD 1 FUNCTION setting is Enabled then the RRTD 1 APPLICATION setting value will be written to RRTD device If the RRTD 1 FUNCTION setting is Disabled then RRTD1 APPLICATION setting value is set as None If the RRTD 1 APPLICATION or RRTD 1 TYPE settings are changes then these settings are immediately written to the RRTD device RRTD 1 RRTD 1 FUNCTION Disabled Range Disable...

Page 401: ... type Four different RTD types are available 100 Nickel 10 Copper 100 Platinum and 120 Nickel The RRTD converts resistance to temperature as per the values in the following table The M60 reads the RTD tem peratures from the RRTD once every five seconds and applies protection accordingly The RRTDs can be used to pro vide RTD bias in the existing thermal model An RRTD open condition is detected when...

Page 402: ... range of the RRTD unit RRTD 1 TRIP PKP DELAY This setting specifies time delay for the trip stage until the output can be asserted The range of 5 to 600 seconds differs from the existing RTD settings to correspond to the range of the RRTD unit RRTD 1 TRIP RST DELAY This setting specifies the reset delay to seal in the trip signal RRTD 1 TRIP VOTING This setting allows securing trip signal by voti...

Page 403: ...ks the driving signal x in equations below for the minimum and maximum limits and subsequently re scales so the limits defined as MIN VAL and MAX VAL match the output range of the hardware defined as RANGE The follow ing equation is applied EQ 5 50 DCMA OUTPUT H1 DCMA OUTPUT H1 SOURCE Off Range Off any analog actual value parameter MESSAGE DCMA OUTPUT H1 RANGE 1 to 1 mA Range 1 to 1 mA 0 to 1 mA 4...

Page 404: ...current The setting is entered in per unit values The base units are defined in the same manner as the FlexElement base units DCMA OUTPUT H1 MAX VAL This setting allows setting the maximum limit for the signal that drives the output This setting is used to control the mapping between an internal analog value and the output current The setting is entered in per unit values The base units are define...

Page 405: ...al details is EQ 5 57 The minimum and maximum power values to be monitored in pu are EQ 5 58 The following settings should be entered DCMA OUTPUT H2 SOURCE SRC 1 Ia RMS DCMA OUTPUT H2 RANGE 4 to 20 mA DCMA OUTPUT H2 MIN VAL 0 000 pu DCMA OUTPUT H2 MAX VAL 1 260 pu The worst case error for this application could be calculated by superimposing the following two sources of error 0 5 of the full scale...

Page 406: ...if the VTs are connected in Delta see the Metering Conventions section in chapter 6 while at the same time the VT nominal voltage is 1 pu for the settings Consequently the settings required in this example differ from naturally expected by the factor of The worst case error for this application could be calculated by superimposing the following two sources of error 0 5 of the full scale for the an...

Page 407: ...based inputs and outputs remain fully operational in test mode If a control action is programmed using direct inputs and outputs or remote inputs and outputs then the test procedure must take this into account When in Forcible mode the operand selected by the TEST MODE FORCING setting dictates further response of the M60 to testing conditions To force contact inputs and outputs through relay setti...

Page 408: ...voltage across the input terminals The force contact inputs feature provides a method of performing checks on the function of all contact inputs Once enabled the relay is placed into test mode allowing this feature to override the normal function of contact inputs The Test Mode LED will be on indicating that the relay is in test mode The state of each contact input may be programmed as Dis abled O...

Page 409: ...3 should open and digital input 4 should close Also contact output 1 should freeze contact output 2 should open contact output 3 should close and contact output 4 should remain fully operational The required settings are shown below To enable user programmable pushbutton 1 to initiate the test mode make the following changes in the SETTINGS TESTING TEST MODE menu TEST MODE FUNCTION Enabled and TES...

Page 410: ...5 282 M60 Motor Protection System GE Multilin 5 10 TESTING 5 SETTINGS 5 ...

Page 411: ...e page 6 6 CONTACT OUTPUTS See page 6 6 VIRTUAL OUTPUTS See page 6 7 REMOTE DEVICES STATUS See page 6 7 REMOTE DEVICES STATISTICS See page 6 8 DIGITAL COUNTERS See page 6 8 SELECTOR SWITCHES See page 6 8 FLEX STATES See page 6 9 ETHERNET See page 6 9 REAL TIME CLOCK SYNCHRONIZING See page 6 9 DIRECT INPUTS See page 6 10 DIRECT DEVICES STATUS See page 6 11 IEC 61850 GOOSE UINTEGERS See page 6 11 EG...

Page 412: ...ROKEN ROTOR BAR See page 6 22 TRACKING FREQUENCY See page 6 23 FLEXELEMENTS See page 6 23 IEC 61850 GOOSE ANALOGS See page 6 24 TRANSDUCER I O DCMA INPUTS See page 6 24 TRANSDUCER I O RTD INPUTS See page 6 24 ACTUAL VALUES RECORDS USER PROGRAMMABLE FAULT REPORTS See page 6 25 STARTING RECORDS See page 6 25 MOTOR LEARNED DATA See page 6 26 EVENT RECORDS See page 6 27 OSCILLOGRAPHY See page 6 28 DAT...

Page 413: ...GE Multilin M60 Motor Protection System 6 3 6 ACTUAL VALUES 6 1 OVERVIEW 6 FIRMWARE REVISIONS See page 6 29 ...

Page 414: ...r details of lockout time calculations see the Thermal Model section of Chapter 5 The START HOUR LOCKOUT TIME TIME BTWN STARTS LO TIME and RESTART DELAY LO TIME lockout time values are calcu lated from the Maximum Starting Rate Time Between Starts and Restart Delay elements respectively The TOTAL MOTOR LOCKOUT TIME value is calculated as the maximum of all lockout times shown in this menu 6 2 2 CO...

Page 415: ... Offline in which case the value shown is the programmed default state for the remote input 6 2 5 REMOTE DOUBLE POINT STATUS INPUTS PATH ACTUAL VALUES STATUS REMOTE DPS INPUTS The present state of the remote double point status inputs is shown here The actual values indicate if the remote double point status inputs are in the on close off open intermediate or bad state VIRTUAL INPUTS Virt Ip 1 Off...

Page 416: ... in terms of the default name array index The second line of the display indicates the logic state of the contact output For form A contact outputs the state of the voltage and current detectors is displayed as Off VOff IOff On IOn and VOn For form C contact outputs the state is displayed as Off or On TELEPROTECTION INPUTS TELEPROTECTION INPUT 1 1 Off Range Off On MESSAGE TELEPROTECTION INPUT 1 2 ...

Page 417: ...put 6 2 9 REMOTE DEVICES a STATUS PATH ACTUAL VALUES STATUS REMOTE DEVICES STATUS The present state of the programmed remote devices is shown here The ALL REMOTE DEVICES ONLINE message indicates whether or not all programmed remote devices are online If the corresponding state is No then at least one required remote device is not online VIRTUAL OUTPUTS Virt Op 1 Off Range On Off MESSAGE Virt Op 2 ...

Page 418: ...OUNTERS DIGITAL COUNTERS Counter 1 8 The present status of the eight digital counters is shown here The status of each counter with the user defined counter name includes the accumulated and frozen counts the count units label will also appear Also included is the date and time stamp for the frozen count The COUNTER 1 MICROS value refers to the microsecond portion of the time stamp 6 2 11 SELECTOR...

Page 419: ...o The grandmasterIdentity code is specified by PTP to be globally unique so one can always know which clock is grandmaster in a system with multiple grandmaster capable clocks FLEX STATES PARAM 1 Off Off Range Off On MESSAGE PARAM 2 Off Off Range Off On MESSAGE PARAM 256 Off Off Range Off On ETHERNET ETHERNET PRI LINK STATUS Fail Range Fail OK MESSAGE ETHERNET SEC LINK STATUS Fail Range Fail OK ME...

Page 420: ... ACTUAL VALUES STATUS DIRECT INPUTS The AVERAGE MSG RETURN TIME is the time taken for direct output messages to return to the sender in a direct input output ring configuration this value is not applicable for non ring configurations This is a rolling average calculated for the last ten messages There are two return times for dual channel communications modules The UNRETURNED MSG COUNT values one ...

Page 421: ...ints are displayed in this menu The GGIO5 integer data values are received via IEC 61850 GOOSE messages sent from other devices 6 2 18 EGD PROTOCOL STATUS a FAST EXCHANGE PATH ACTUAL VALUES STATUS EGD PROTOCOL STATUS PRODUCER STATUS FAST EXCHANGE 1 These values provide information that may be useful for debugging an EGD network The EGD signature and packet size for the fast EGD exchange is display...

Page 422: ...transmission this count can be reset to 0 through the COMMANDS CLEAR RECORDS menu VALIDITY OF CHANNEL CONFIGURATION This value displays the current state of the communications channel identification check and hence validity If a remote relay ID does not match the programmed ID at the local relay the FAIL message will be displayed The N A value appears if the local relay ID is set to a default valu...

Page 423: ...UAL VALUES STATUS PRP The M60 Motor Protection System is provided with optional PRP capability This feature is specified as a software option at the time of ordering See the Order Codes section in chapter 2 for details TOTAL RECEIVED PORT A is a counter for total messages received either from DANPs or from SANs on Port A TOTAL RECEIVED PORT B is a counter for total messages received either from DA...

Page 424: ...e PF Lag Current Voltage WATTS Positive VARS Negative PF Lead Current Voltage WATTS Negative VARS Negative PF Lag Current Voltage WATTS Negative VARS Positive PF Lead Current Generator Generator Inductive Inductive Resistive Resistive Generator Generator UR RELAY UR RELAY UR RELAY UR RELAY G G M M G G VCG IC VAG IA VBG IB 1 VCG IC VAG IA VBG IB 2 VCG IC VAG IA VBG IB 3 VCG IC VAG IA VBG IB 4 Q Q Q...

Page 425: ... measurable the phase angles are not referenced The phase angles are assigned as positive in the leading direction and are presented as negative in the lagging direction to more closely align with power system metering conventions This is illustrated below Figure 6 2 UR PHASE ANGLE MEASUREMENT CONVENTION c UR CONVENTION FOR MEASURING SYMMETRICAL COMPONENTS The UR series of relays calculate voltage...

Page 426: ...ated in the following figure Figure 6 3 MEASUREMENT CONVENTION FOR SYMMETRICAL COMPONENTS ABC phase rotation ACB phase rotation Table 6 1 SYMMETRICAL COMPONENTS CALCULATION EXAMPLE SYSTEM VOLTAGES SEC V VT CONN RELAY INPUTS SEC V SYMM COMP SEC V VAG VBG VCG VAB VBC VCA F5AC F6AC F7AC V0 V1 V2 13 9 0 76 2 125 79 7 250 84 9 313 138 3 97 85 4 241 WYE 13 9 0 76 2 125 79 7 250 19 5 192 56 5 7 23 3 187 ...

Page 427: ...l Load Amps setting in per unit MOTOR UNBALANCE This value is the amount of unbalance in the motor currents A full explanation of the calcula tion of this value is presented for the Amp Unbalance element U B BIASED MOTOR LOAD Unbalance Bias Motor Load shows the equivalent motor heating current caused by the unbalance k factor STATOR DIFFERENTIAL STATOR DIFF OPERATE Iad 0 00 A MESSAGE STATOR DIFF R...

Page 428: ...ATH ACTUAL VALUES METERING SOURCE SRC 1 PHASE CURRENT SOURCE SRC 1 PHASE CURRENT SRC 1 See page 6 18 MESSAGE GROUND CURRENT SRC 1 See page 6 19 MESSAGE PHASE VOLTAGE SRC 1 See page 6 19 MESSAGE AUXILIARY VOLTAGE SRC 1 See page 6 20 MESSAGE POWER SRC 1 See page 6 20 MESSAGE ENERGY SRC 1 See page 6 21 MESSAGE FREQUENCY SRC 1 See page 6 21 PHASE CURRENT SRC 1 SRC 1 RMS Ia 0 000 b 0 000 c 0 000 A MESS...

Page 429: ...rce see SETTINGS SYSTEM SETUP SIGNAL SOURCES d PHASE VOLTAGE METERING PATH ACTUAL VALUES METERING SOURCE SRC 1 PHASE VOLTAGE MESSAGE SRC 1 POS SEQ I1 0 000 A 0 0 MESSAGE SRC 1 NEG SEQ I2 0 000 A 0 0 GROUND CURRENT SRC 1 SRC 1 RMS Ig 0 000 A MESSAGE SRC 1 PHASOR Ig 0 000 A 0 0 MESSAGE SRC 1 PHASOR Igd 0 000 A 0 0 PHASE VOLTAGE SRC 1 SRC 1 RMS Vag 0 00 V MESSAGE SRC 1 RMS Vbg 0 00 V MESSAGE SRC 1 RM...

Page 430: ...TINGS SYSTEM SETUP SIGNAL SOURCES f POWER METERING PATH ACTUAL VALUES METERING SOURCE SRC 1 POWER MESSAGE SRC 1 ZERO SEQ V0 0 000 V 0 0 MESSAGE SRC 1 POS SEQ V1 0 000 V 0 0 MESSAGE SRC 1 NEG SEQ V2 0 000 V 0 0 AUXILIARY VOLTAGE SRC 1 SRC 1 RMS Vx 0 00 V MESSAGE SRC 1 PHASOR Vx 0 000 V 0 0 POWER SRC 1 SRC 1 REAL POWER 3 0 000 W MESSAGE SRC 1 REAL POWER a 0 000 W MESSAGE SRC 1 REAL POWER b 0 000 W M...

Page 431: ...y whatever name was pro grammed by the user for the associated source see SETTINGS SYSTEM SETUP SIGNAL SOURCES SOURCE FREQUENCY is measured via software implemented zero crossing detection of an AC signal The signal is either a Clarke transformation of three phase voltages or currents auxiliary voltage or ground current as per source configuration see the SYSTEM SETUP POWER SYSTEM settings The sig...

Page 432: ...ar data acquisition stage TIME OF BRB CALC This value indicates the time stamp of the broken rotor bar calculation MAXIMUM COMPONENT LEVEL This value indicates the learned maximum level of the broken rotor bar spectral component since the last data clear MAXIMUM COMPONENT FREQ This value indicates the frequency of the learned maximum broken rotor bar spec tral component MOTOR LOAD AT BRB MAX This ...

Page 433: ...PFBASE 1 00 RTDs BASE 100 C SENSITIVE DIR POWER Sns Dir Power PBASE maximum value of 3 VBASE IBASE for the IN and IN inputs of the sources configured for the sensitive power directional element s SOURCE CURRENT IBASE maximum nominal primary RMS value of the IN and IN inputs SOURCE ENERGY Positive and Negative Watthours Positive and Negative Varhours EBASE 10000 MWh or MVAh respectively SOURCE POWE...

Page 434: ...ual values for each dcmA input channel that is enabled are displayed with the top line as the programmed channel ID and the bottom line as the value followed by the programmed units PATH ACTUAL VALUES METERING TRANSDUCER I O RTD INPUTS RTD INPUT xx Actual values for each RTD input channel that is enabled are displayed with the top line as the programmed channel ID and the bottom line as the value ...

Page 435: ...RECORDS STARTING RECORDS MOTOR START 1 5 Up to five motor starts are displayed When the buffer is full the newest record overwrites the oldest record USER PROGRAMMABLE FAULT REPORT NEWEST RECORD NUMBER 0 MESSAGE LAST CLEARED DATE 2002 8 11 14 23 57 MESSAGE LAST REPORT DATE 2002 10 09 08 25 27 NO STARTING RECORDS TO REPORT or MOTOR START 1 START 1 DATE 2002 08 11 Range Date in format YYYY MM DD MES...

Page 436: ...age motor load in multiples of full load current Learned run time after start in hours The learned values for acceleration time and effective starting current are the maximum of the individual values acquired for the last N successful starts where N is defined by the NUMBER OF STARTS TO LEARN setting The learned value for the starting thermal capacity is calculated using the maximum of the last mo...

Page 437: ...e starting thermal capacity Idle Capture starting effective current nSTRT I 0 and I overload PKP Capture acceleration time Capture thermal capacity used Motor stopped status Capture run time after start Store learned acceleration time Store average run time after start IRun In 1 Run In N Run N Every 1 minute capture load current Store last acceleration time Store learned thermal capacity used Stor...

Page 438: ... section of chapter 5 for additional details A trigger can be forced here at any time by setting Yes to the FORCE TRIGGER command Refer to the COMMANDS CLEAR RECORDS menu for information on clearing the oscillography records 6 4 6 DATA LOGGER PATH ACTUAL VALUES RECORDS DATA LOGGER The OLDEST SAMPLE TIME represents the time at which the oldest available samples were taken It will be static until th...

Page 439: ...andard Ethernet MAC address format MESSAGE MANUFACTURING DATE 0 Range YYYY MM DD HH MM SS MESSAGE CT VT ADVANCED DIAG ACTIVE No Range Yes No MESSAGE OPERATING TIME 0 00 00 Range operating time in HH MM SS MESSAGE LAST SETTING CHANGE 1970 01 01 23 11 19 Range YYYY MM DD HH MM SS FIRMWARE REVISIONS M60 Motor Relay REVISION 7 2x Range 0 00 to 655 35 Revision number of the application firmware MESSAGE...

Page 440: ...6 30 M60 Motor Protection System GE Multilin 6 5 PRODUCT INFORMATION 6 ACTUAL VALUES 6 ...

Page 441: ... entry 7 1 2 VIRTUAL INPUTS PATH COMMANDS VIRTUAL INPUTS The states of up to 64 virtual inputs are changed here The first line of the display indicates the ID of the virtual input The second line indicates the current or selected status of the virtual input This status will be a state off logic 0 or on logic 1 COMMANDS MESSAGE COMMANDS VIRTUAL INPUTS MESSAGE COMMANDS CLEAR RECORDS MESSAGE COMMANDS...

Page 442: ...the ENTER key is pressed When the relay is synchronizing to an external time source such as PTP IRIG B or SNTP the manually entered time is over written The timescale of the entered time is local time including daylight savings time where and when applicable COMMANDS CLEAR RECORDS CLEAR USER FAULT REPORTS No Range No Yes CLEAR EVENT RECORDS No Range No Yes CLEAR OSCILLOGRAPHY No Range No Yes CLEAR...

Page 443: ...unning and diagnostic information is stored on the non volatile memory from time to time based on the self checking result Although the diagnostic information is cleared before the M60 is shipped from the factory the user may want to clear the diagnostic information for themselves under certain circumstances For example it may be desirable to clear diagnostic information after replacement of hardw...

Page 444: ... allows the Supervisor to forcefully logoff an engineer session Operator Logoff Selecting Yes allows the Supervisor to forcefully logoff an operator session Clear Security Data Selecting Yes allows the Supervisor to forcefully clear all the security logs and clears all the operands associated with the self tests ...

Page 445: ...s have not been programmed 7 2 3 RELAY SELF TESTS a DESCRIPTION The relay performs a number of self test diagnostic checks to ensure device integrity The two types of self tests major and minor are listed in the tables below When either type of self test error occurs the Trouble LED Indicator will turn on and a target message displayed All errors record an event in the event recorder Latched error...

Page 446: ...w often the test is performed On power up Afterwards the backplane is checked for missing cards every five sec onds What to do Check all modules against the order code ensure they are inserted properly and cycle control power If the problem persists contact the factory Latched target message No Description of problem A FlexLogic equation is incorrect How often the test is performed The test is eve...

Page 447: ...e EnerVista UR Setup software will list the valid items An IEC61850 client will also show which nodes are available for the M60 Latched target message Yes Description of problem The battery is not functioning How often the test is performed The battery is monitored every five seconds The error message displays after 60 sec onds if the problem persists What to do Replace the battery as outlined in ...

Page 448: ...liant The network is delivering PTP messages to the relay Latched target message No Description of problem An Ethernet connection has failed How often the test is performed Monitored every five seconds What to do Check Ethernet connections Port 1 is the primary port and port 2 is the secondary port Latched target message No Description of problem The SNTP server is not responding How often the tes...

Page 449: ...s performed when a device programmed to receive GOOSE messages stops receiving This can be from 1 to 60 seconds depending on GOOSE packets What to do Check GOOSE setup Latched target message Yes Description of problem The ambient temperature is greater than the maximum operating temperature 80 C How often the test is performed Every hour What to do Remove the M60 from service and install in a loca...

Page 450: ...t is activated HARDFIBER SELF TEST ERROR MESSAGES In addition to those provided by the standard UR series devices the UR devices implement HardFiber self tests These are listed below Any abnormal diagnostic condition indicated by the LEDs or the critical failure relay also results in a self test message so troubleshooting is described here For other relays such at the B95Plus see that product s in...

Page 451: ...gle origin Process Bus Trouble Minor Self Test Description Communications problems with one or more Bricks The text of the message identifies the affected field units This self test is initiated by low received signal levels at either the Brick or Process Card end and by the sustained failure to receive poll responses from the proper Brick Severity This self test error does not directly inhibit pr...

Page 452: ...7 12 M60 Motor Protection System GE Multilin 7 2 TARGETS 7 COMMANDS AND TARGETS 7 ...

Page 453: ...ce component As such the same signal must not be injected to all three phases or the injected signal will be completely filtered out For an underfrequency element using phase quantities the phase A signal must be above the MIN VOLT AMP setting value There fore either inject into phase A only or inject a balanced three phase signal Figure 8 1 TYPICAL UNDERFREQUENCY ELEMENT TEST TIMING The static ac...

Page 454: ...r This is exclusive of the time taken by the frequency responding component to pickup The M60 oscillography can be used to measure the time between the calculated source frequency crossing the threshold and element operation however this method omits the delay in the calculated source frequency The security features of the source frequency measurement algorithm result in the calculated frequency b...

Page 455: ...umb screw has been removed as shown below This allows for easy accessibility of the modules for withdrawal The new wide angle hinge assembly in the enhanced front panel opens completely and allows easy access to all modules in the M60 Figure 9 1 UR MODULE WITHDRAWAL AND INSERTION ENHANCED FACEPLATE The standard faceplate can be opened to the left once the sliding latch on the right side has been p...

Page 456: ... clips have cleared the raised edge of the chassis engage the clips simultaneously When the clips have locked into position the module will be fully inserted CPU connections must be individually disconnected from the module before the module can be removed from the chassis The new CT VT modules can only be used with new CPUs similarly old CT VT modules can only be used with old CPUs In the event t...

Page 457: ... and opening the panel to the left 4 Unscrew the bracket on the front left of the unit so that you can open fully the front panel to access the power supply module which is typically in the first slot on the left side 5 Simultaneously pull the ejector clips at the top and bottom of the power supply module and remove the module 6 Unscrew the screw that attaches the metal cover to the module 7 Slide...

Page 458: ... module which is typically in the first slot on the left side 5 Simultaneously pull the ejector clips at the top and bottom of the power supply module and remove the module 6 Unscrew all four screws not three that attach the metal cover to the module 7 Slide the metal cover away from the clips about 1 cm 1 4 inch and remove the cover 8 Unclip the black plastic holder that keeps the battery in plac...

Page 459: ...ταρία που δεν πρέπει να απορρίπτεται σε δημόσια συστήματα απόρριψης στην Ευρωπαϊκή Κοινότητα είτε την τεκμηρίωση του προϊόντος για συγκεκριμένες πληροφορίες που αφορούν τη μπαταρία Η μπαταρία είναι φέρει σήμανση με αυτό το σύμβολο το οποίο μπορεί να περιλαμβάνει γράμματα για να δηλώσουν το κάδμιο Cd τον μόλυβδο Pb ή τον υδράργυρο Hg Για την κατάλληλη ανακύκλωση επιστρέψτε την μπαταρία στον προμηθε...

Page 460: ...tte produkt inneholder et batteri som ikke kan kastes med usortert kommunalt søppel i den Europeiske Unionen Se produktdokumentasjonen for spesifikk batteriinformasjon Batteriet er merket med dette symbolet som kan inkludere symboler for å indikere at kadmium Cd bly Pb eller kvikksølv Hg forekommer Returner batteriet til leverandøren din eller til et dedikert oppsamlingspunkt for korrekt gjenvinni...

Page 461: ...edd deponering För mer information se www recyclethis info TR Pil Geri Dönüşümü Bu ürün Avrupa Birliği genel atık sistemlerine atılmaması gereken pil içermektedir Daha detaylı pil bilgisi için ürünün kataloğunu inceleyiniz Bu sembolle işaretlenmiş piller Kadmiyum Cd Kurşun Pb ya da Civa Hg içerebilir Doğru geri dönüşüm için ürünü yerel tedarikçinize geri veriniz ya da özel işaretlenmiş toplama nok...

Page 462: ...9 8 M60 Motor Protection System GE Multilin 9 2 BATTERIES 9 MAINTENANCE 9 ...

Page 463: ... 5 value 5829 Field RTD 6 Value Field RTD 6 value 5830 Field RTD 7 Value Field RTD 7 value 5831 Field RTD 8 Value Field RTD 8 value 5832 Field TDR 1 Value Field TDR 1 value 5834 Field TDR 2 Value Field TDR 2 value 5836 Field TDR 3 Value Field TDR 3 value 5838 Field TDR 4 Value Field TDR 4 value 5840 Field TDR 5 Value Field TDR 5 value 5842 Field TDR 6 Value Field TDR 6 value 5844 Field TDR 7 Value...

Page 464: ...5 SRC 2 I_0 Angle Amps Source 2 zero sequence current angle 6236 SRC 2 I_1 Mag Degrees Source 2 positive sequence current magnitude 6238 SRC 2 I_1 Angle Amps Source 2 positive sequence current angle 6239 SRC 2 I_2 Mag Degrees Source 2 negative sequence current magnitude 6241 SRC 2 I_2 Angle Amps Source 2 negative sequence current angle 6242 SRC 2 Igd Mag Degrees Source 2 differential ground curren...

Page 465: ..._1 Mag Degrees Source 4 positive sequence current magnitude 6366 SRC 4 I_1 Angle Amps Source 4 positive sequence current angle 6367 SRC 4 I_2 Mag Degrees Source 4 negative sequence current magnitude 6369 SRC 4 I_2 Angle Amps Source 4 negative sequence current angle 6370 SRC 4 Igd Mag Degrees Source 4 differential ground current magnitude 6372 SRC 4 Igd Angle Amps Source 4 differential ground curre...

Page 466: ... angle 6744 SRC 2 Vbc Mag Volts Source 2 phase BC voltage magnitude 6746 SRC 2 Vbc Angle Degrees Source 2 phase BC voltage angle 6747 SRC 2 Vca Mag Volts Source 2 phase CA voltage magnitude 6749 SRC 2 Vca Angle Degrees Source 2 phase CA voltage angle 6750 SRC 2 Vx RMS Volts Source 2 auxiliary voltage RMS 6752 SRC 2 Vx Mag Volts Source 2 auxiliary voltage magnitude 6754 SRC 2 Vx Angle Degrees Sourc...

Page 467: ...Source 4 phase BG voltage angle 6860 SRC 4 Vcg Mag Volts Source 4 phase CG voltage magnitude 6862 SRC 4 Vcg Angle Degrees Source 4 phase CG voltage angle 6863 SRC 4 Vab RMS Volts Source 4 phase AB voltage RMS 6865 SRC 4 Vbc RMS Volts Source 4 phase BC voltage RMS 6867 SRC 4 Vca RMS Volts Source 4 phase CA voltage RMS 6869 SRC 4 Vab Mag Volts Source 4 phase AB voltage magnitude 6871 SRC 4 Vab Angle...

Page 468: ...phase B apparent power 7222 SRC 2 Sc VA Source 2 phase C apparent power 7224 SRC 2 PF Source 2 three phase power factor 7225 SRC 2 Phase A PF Source 2 phase A power factor 7226 SRC 2 Phase B PF Source 2 phase B power factor 7227 SRC 2 Phase C PF Source 2 phase C power factor 7232 SRC 3 P Watts Source 3 three phase real power 7234 SRC 3 Pa Watts Source 3 phase A real power 7236 SRC 3 Pb Watts Sourc...

Page 469: ...input 6 actual value 13516 DCMA Inputs 7 Value mA dcmA input 7 actual value 13518 DCMA Inputs 8 Value mA dcmA input 8 actual value 13520 DCMA Inputs 9 Value mA dcmA input 9 actual value 13522 DCMA Inputs 10 Value mA dcmA input 10 actual value 13524 DCMA Inputs 11 Value mA dcmA input 11 actual value 13526 DCMA Inputs 12 Value mA dcmA input 12 actual value 13528 DCMA Inputs 13 Value mA dcmA input 13...

Page 470: ...t 28 actual value 13580 RTD Inputs 29 Value RTD input 29 actual value 13581 RTD Inputs 30 Value RTD input 30 actual value 13582 RTD Inputs 31 Value RTD input 31 actual value 13583 RTD Inputs 32 Value RTD input 32 actual value 13584 RTD Inputs 33 Value RTD input 33 actual value 13585 RTD Inputs 34 Value RTD input 34 actual value 13586 RTD Inputs 35 Value RTD input 35 actual value 13587 RTD Inputs 3...

Page 471: ...actual value 39170 FlexElement 2 Value FlexElement 2 actual value 39172 FlexElement 3 Value FlexElement 3 actual value 39174 FlexElement 4 Value FlexElement 4 actual value 39176 FlexElement 5 Value FlexElement 5 actual value 39178 FlexElement 6 Value FlexElement 6 actual value 39180 FlexElement 7 Value FlexElement 7 actual value 39182 FlexElement 8 Value FlexElement 8 actual value 39184 FlexElemen...

Page 472: ...n 4 IEC 61850 GOOSE analog input 4 45592 GOOSE Analog In 5 IEC 61850 GOOSE analog input 5 45594 GOOSE Analog In 6 IEC 61850 GOOSE analog input 6 45596 GOOSE Analog In 7 IEC 61850 GOOSE analog input 7 45598 GOOSE Analog In 8 IEC 61850 GOOSE analog input 8 45600 GOOSE Analog In 9 IEC 61850 GOOSE analog input 9 45602 GOOSE Analog In 10 IEC 61850 GOOSE analog input 10 45604 GOOSE Analog In 11 IEC 6185...

Page 473: ...4 GOOSE UInt Input 4 IEC61850 GOOSE UInteger input 4 9976 GOOSE UInt Input 5 IEC61850 GOOSE UInteger input 5 9978 GOOSE UInt Input 6 IEC61850 GOOSE UInteger input 6 9980 GOOSE UInt Input 7 IEC61850 GOOSE UInteger input 7 9982 GOOSE UInt Input 8 IEC61850 GOOSE UInteger input 8 9984 GOOSE UInt Input 9 IEC61850 GOOSE UInteger input 9 9986 GOOSE UInt Input 10 IEC61850 GOOSE UInteger input 10 9988 GOOS...

Page 474: ...A 12 M60 Motor Protection System GE Multilin A 1 PARAMETER LISTS APPENDIX A A ...

Page 475: ...00 4800 9600 14400 19200 28800 33600 38400 57600 or 115200 bps are available Even odd and no parity are avail able See the Communications section of chapter 5 for details The master device in any system must know the address of the slave device with which it is to communicate The relay will not act on a request from a master if the address in the request does not match the relay s slave address un...

Page 476: ...aves start listening for a new packet from the master except for the addressed slave B 1 4 CRC 16 ALGORITHM The CRC 16 algorithm essentially treats the entire data stream data bits only start stop and parity ignored as one contin uous 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 ap...

Page 477: ...ing address will determine the type of data being read Function codes 03h and 04h are therefore identical The following table shows the format of the master and slave packets The example shows a master device requesting three register values starting at address 4050h from slave device 11h 17 decimal the slave device responds with the val ues 40 300 and 0 from registers 4050h 4051h and 4052h respec...

Page 478: ...ION EXAMPLE MASTER TRANSMISSION SLAVE RESPONSE PACKET FORMAT EXAMPLE HEX PACKET FORMAT EXAMPLE HEX SLAVE ADDRESS 11 SLAVE ADDRESS 11 FUNCTION CODE 05 FUNCTION CODE 05 OPERATION CODE high 00 OPERATION CODE high 00 OPERATION CODE low 01 OPERATION CODE low 01 CODE VALUE high FF CODE VALUE high FF CODE VALUE low 00 CODE VALUE low 00 CRC low DF CRC low DF CRC high 6A CRC high 6A Table B 5 SUMMARY OF OP...

Page 479: ... function code set to 1 The following table shows the format of the master and slave packets The example shows a master device sending the unsupported function code 39h to slave device 11 Table B 7 MASTER AND SLAVE DEVICE PACKET TRANSMISSION EXAMPLE MASTER TRANSMISSION SLAVE RESPONSE PACKET FORMAT EXAMPLE HEX PACKET FORMAT EXAMPLE HEX SLAVE ADDRESS 11 SLAVE ADDRESS 11 FUNCTION CODE 10 FUNCTION COD...

Page 480: ...ecific file transfer information so files may be read simultaneously on multiple Modbus connections b OTHER PROTOCOLS All the files available via Modbus may also be retrieved using the standard file transfer mechanisms in other protocols for example TFTP or MMS c COMTRADE OSCILLOGRAPHY AND DATA LOGGER FILES Oscillography and data logger files are formatted using the COMTRADE file format per IEEE C...

Page 481: ... set up at memory location 4000 Command security is required to change the command pass word Similarly the setting password is set up at memory location 4002 These are the same settings found in the SETTINGS PRODUCT SETUP PASSWORD SECURITY menu via the keypad Enabling password security for the faceplate display will also enable it for Modbus and vice versa To gain command level security access the...

Page 482: ...tems 0 to 4294967295 0 1 F143 0 Front Panel Read Only 0208 LED Column n State n 1 to 10 10 items 0 to 65535 1 F501 0 0220 Display Message F204 none 0248 Last Key Pressed 0 to 47 1 F530 0 None Keypress Emulation Read Write 0280 Simulated keypress write zero before each keystroke 0 to 46 1 F190 0 No key use between real keys Virtual Input Commands Read Write Command 64 Modules 0400 Virtual Input 1 S...

Page 483: ... F108 0 Off 042D Virtual Input 46 State 0 to 1 1 F108 0 Off 042E Virtual Input 47 State 0 to 1 1 F108 0 Off 042F Virtual Input 48 State 0 to 1 1 F108 0 Off 0430 Virtual Input 49 State 0 to 1 1 F108 0 Off 0431 Virtual Input 50 State 0 to 1 1 F108 0 Off 0432 Virtual Input 51 State 0 to 1 1 F108 0 Off 0433 Virtual Input 52 State 0 to 1 1 F108 0 Off 0434 Virtual Input 53 State 0 to 1 1 F108 0 Off 0435...

Page 484: ...ed for Binary Input 29 05F8 Repeated for Binary Input 30 05FC Repeated for Binary Input 31 0600 Repeated for Binary Input 32 0604 Repeated for Binary Input 33 0608 Repeated for Binary Input 34 060C Repeated for Binary Input 35 0610 Repeated for Binary Input 36 0614 Repeated for Binary Input 37 0618 Repeated for Binary Input 38 061C Repeated for Binary Input 39 0620 Repeated for Binary Input 40 062...

Page 485: ... 06E0 Repeated for Binary Input 88 06E4 Repeated for Binary Input 89 06E8 Repeated for Binary Input 90 06EC Repeated for Binary Input 91 06F0 Repeated for Binary Input 92 06F4 Repeated for Binary Input 93 06F8 Repeated for Binary Input 94 06FC Repeated for Binary Input 95 0700 Repeated for Binary Input 96 IEC103 ASDU Settings Read Write Setting 4 Modules 0704 IEC103 ASDU1 TYP 0 to 1 1 F630 1 9 070...

Page 486: ... 0780 IEC103 Command 1 FUN 0 to 255 1 F001 0 0781 IEC103 Command 1 INF 0 to 255 1 F001 0 0782 IEC103 Command 1 Param ON 0 to 64 1 F631 0 OFF 0783 IEC103 Command 1 Param OFF 0 to 64 1 F631 0 OFF 0784 Repeated for IEC103 Command 2 0788 Repeated for IEC103 Command 3 078C Repeated for IEC103 Command 4 0790 Repeated for IEC103 Command 5 0794 Repeated for IEC103 Command 6 0798 Repeated for IEC103 Comman...

Page 487: ... Contact Input States 6 items 0 to 65535 1 F500 0 1508 Virtual Input States 8 items 0 to 65535 1 F500 0 1510 Contact Output States 4 items 0 to 65535 1 F500 0 1518 Contact Output Current States 4 items 0 to 65535 1 F500 0 1520 Contact Output Voltage States 4 items 0 to 65535 1 F500 0 1528 Virtual Output States 6 items 0 to 65535 1 F500 0 1530 Contact Output Detectors 4 items 0 to 65535 1 F500 0 In...

Page 488: ...tatus 0 to 2 1 F134 0 Fail 1612 Ethernet Tertiary Fibre Channel Status 0 to 2 1 F134 0 Fail Data Logger Actuals Read Only 1618 Data Logger Channel Count 0 to 16 channel 1 F001 0 1619 Time of Oldest Available Samples 0 to 4294967295 seconds 1 F050 0 161B Time of Newest Available Samples 0 to 4294967295 seconds 1 F050 0 161D Data Logger Duration 0 to 999 9 days 0 1 F001 0 Stator Differential Actuals...

Page 489: ...urce 1 Negative Sequence Current Angle 359 9 to 0 degrees 0 1 F002 0 1822 Source 1 Differential Ground Current Magnitude 0 to 999999 999 A 0 001 F060 0 1824 Source 1 Differential Ground Current Angle 359 9 to 0 degrees 0 1 F002 0 1825 Reserved 27 items F001 0 1840 Repeated for Source 2 1880 Repeated for Source 3 18C0 Repeated for Source 4 1900 Repeated for Source 5 1940 Repeated for Source 6 Sourc...

Page 490: ...Phase A Reactive Power 1000000000000 to 1000000000000 var 0 001 F060 0 1C0C Source 1 Phase B Reactive Power 1000000000000 to 1000000000000 var 0 001 F060 0 1C0E Source 1 Phase C Reactive Power 1000000000000 to 1000000000000 var 0 001 F060 0 1C10 Source 1 Three Phase Apparent Power 1000000000000 to 1000000000000 VA 0 001 F060 0 1C12 Source 1 Phase A Apparent Power 1000000000000 to 1000000000000 VA ...

Page 491: ...294967295 1 F300 0 21AA Breaker Flashover 1 Block 0 to 4294967295 1 F300 0 21AC Breaker Flashover 1 Events 0 to 1 1 F102 0 Disabled 21AD Breaker Flashover 1 Target 0 to 2 1 F109 0 Self Reset 21AE Reserved 4 items F001 0 21B2 Repeated for breaker flashover 2 Passwords Unauthorized Access Read Write Command 2230 Reset Unauthorized Access 0 to 1 1 F126 0 No Field Unit Raw Data Settings Read Write Set...

Page 492: ...0 FlexStates one per register 256 items 0 to 1 1 F108 0 Off Expanded Digital Input Output States Read Only 2D00 Contact Input States one per register 96 items 0 to 1 1 F108 0 Off 2D80 Contact Output States one per register 64 items 0 to 1 1 F108 0 Off 2E00 Virtual Output States one per register 96 items 0 to 1 1 F108 0 Off Expanded Remote Input Output Status Read Only 2F00 Remote Device States one...

Page 493: ...sword Entry F202 none Security Read Write Setting 32BF Operator Alphanumeric Password Setting F202 none Security Read Only 32C9 Operator Alphanumeric Password Status 0 to 1 1 F102 0 Disabled Security Read Write 32CA Operator Alphanumeric Password Entry F202 none Security Read Write Setting 32D4 Observer Alphanumeric Password Setting F202 none Security Read Only 32DE Observer Alphanumeric Password ...

Page 494: ...99999 1 F004 0 34CA DCMA Inputs 6 Value 9999999 to 9999999 1 F004 0 34CC DCMA Inputs 7 Value 9999999 to 9999999 1 F004 0 34CE DCMA Inputs 8 Value 9999999 to 9999999 1 F004 0 34D0 DCMA Inputs 9 Value 9999999 to 9999999 1 F004 0 34D2 DCMA Inputs 10 Value 9999999 to 9999999 1 F004 0 34D4 DCMA Inputs 11 Value 9999999 to 9999999 1 F004 0 34D6 DCMA Inputs 12 Value 9999999 to 9999999 1 F004 0 34D8 DCMA I...

Page 495: ...8 to 32767 C 1 F002 0 3511 RTD Input 34 Value 32768 to 32767 C 1 F002 0 3512 RTD Input 35 Value 32768 to 32767 C 1 F002 0 3513 RTD Input 36 Value 32768 to 32767 C 1 F002 0 3514 RTD Input 37 Value 32768 to 32767 C 1 F002 0 3515 RTD Input 38 Value 32768 to 32767 C 1 F002 0 3516 RTD Input 39 Value 32768 to 32767 C 1 F002 0 3517 RTD Input 40 Value 32768 to 32767 C 1 F002 0 3518 RTD Input 41 Value 3276...

Page 496: ...its Read Write Setting 8 Modules 3800 Field Unit 1 ID 0 to 1 1 F205 U1 3806 Field Unit 1 Function 0 to 1 1 F102 0 Disabled 3807 Field Unit 1 Type 0 to 3 1 F243 0 CC 05 3808 Field Unit 1 Serial Number 1 to1 1 F205 000000000000 380E Field Unit 1 Port 1 to 4 1 F001 1 380F Repeated for Field Unit 2 381E Repeated for Filed Unit 3 382D Repeated for Filed Unit 4 383C Repeated for Filed Unit 5 384B Repeat...

Page 497: ...ed for Field Contact Input 2 3916 Repeated for Field Contact Input 3 3921 Repeated for Field Contact Input 4 392C Repeated for Field Contact Input 5 3937 Repeated for Field Contact Input 6 3942 Repeated for Field Contact Input 7 394D Repeated for Field Contact Input 8 3958 Repeated for Field Contact Input9 3963 Repeated for Field Contact Input 10 396E Repeated for Field Contact Input 11 3979 Repea...

Page 498: ...Input 16 Field Unit Contact Outputs Read Write Setting 8 Modules 3B90 Field Contact Output 1 ID 6 items F205 FCO U OUT 3BB4 Field Output 1 Operate 6 items 0 to 4294967295 1 F300 0 3BC0 Field Output 1 Seal In 6 items 0 to 4294967295 1 F300 0 3BCC Field Output 1 Events 6 items 0 to 1 1 F102 1 Enabled 3BD2 Repeated for Field Contact Output 2 3C14 Repeated for Field Contact Output 3 3C56 Repeated for ...

Page 499: ...RTD 1 Type 0 to 2 1 F259 0 100 Ohm Nickel 3F08 Repeated for Field Unit RTD 2 3F10 Repeated for Field Unit RTD 3 3F18 Repeated for Field Unit RTD 4 3F20 Repeated for Field Unit RTD 5 3F28 Repeated for Field Unit RTD 6 3F30 Repeated for Field Unit RTD 7 3F38 Repeated for Field Unit RTD 8 Field Unit Transducers Read Write Setting 8 Modules 3F40 Field Unit Transducer 1 Name 0 to 1 1 F205 TRD 1 3F46 Fi...

Page 500: ... Setting 4040 Invoke and Scroll Through User Display Menu Operand 0 to 4294967295 1 F300 0 LED Test Read Write Setting 4048 LED Test Function 0 to 1 1 F102 0 Disabled 4049 LED Test Control 0 to 4294967295 1 F300 0 Preferences Read Write Setting 404F Language 0 to 3 1 F531 0 English 4050 Flash Message Time 0 5 to 10 s 0 1 F001 10 4051 Default Message Timeout 10 to 900 s 1 F001 300 4052 Default Mess...

Page 501: ... to 100000000 1 F003 30000 40B8 DNP Power Default Deadband 0 to 100000000 1 F003 30000 40BA DNP Energy Default Deadband 0 to 100000000 1 F003 30000 40BC DNP Power Factor Default Deadband 0 to 100000000 1 F003 30000 40BE DNP Other Default Deadband 0 to 100000000 1 F003 30000 40C0 DNP IIN Time Synchronization Bit Period 1 to 10080 min 1 F001 1440 40C1 DNP Message Fragment Size 30 to 2048 1 F001 240 ...

Page 502: ...001 4 4161 DNP Available TCP IP Connections 0 to 2 1 F001 2 4162 IEC Available TCP IP Connections 0 to 2 1 F001 2 4163 MMS Available TCP IP Connections 0 to 5 1 F001 5 4164 PMU Available TCP IP Connections 0 to 4 1 F001 4 Simple Network Time Protocol Read Write Setting 4168 Simple Network Time Protocol SNTP Function 0 to 1 1 F102 0 Disabled 4169 Simple Network Time Protocol SNTP Server IP Address ...

Page 503: ...er Programmable LED 3 42C9 Repeated for User Programmable LED 4 42CC Repeated for User Programmable LED 5 42CF Repeated for User Programmable LED 6 42D2 Repeated for User Programmable LED 7 42D5 Repeated for User Programmable LED 8 42D8 Repeated for User Programmable LED 9 42DB Repeated for User Programmable LED 10 42DE Repeated for User Programmable LED 11 42E1 Repeated for User Programmable LED ...

Page 504: ...e 5 438E Repeated for Route 6 Installation Read Write Setting 43E0 Relay Programmed State 0 to 1 1 F133 0 Not Programmed 43E1 Relay Name F202 Relay 1 User Programmable Self Tests Read Write Setting 4441 User Programmable Detect Ring Break Function 0 to 1 1 F102 1 Enabled 4442 User Programmable Direct Device Off Function 0 to 1 1 F102 1 Enabled 4443 User Programmable Remote Device Off Function 0 to...

Page 505: ...ng Function 0 to 1 1 F102 1 Enabled Breaker Control Read Write Settings 4 Modules 47D0 Breaker 1 Function 0 to 1 1 F102 0 Disabled 47D1 Breaker 1 Name F206 Bkr 1 47D4 Breaker 1 Mode 0 to 1 1 F157 0 3 Pole 47D5 Breaker 1 Open 0 to 4294967295 1 F300 0 47D7 Breaker 1 Close 0 to 4294967295 1 F300 0 47D9 Breaker 1 Phase A Three pole Closed 0 to 4294967295 1 F300 0 47DB Breaker 1 Phase B Closed 0 to 429...

Page 506: ...ield Data AC1 Angle 0 to 0 1 degree 0 1 F002 0 4E03 Raw Field Data AC2 Mag 0 to 0 001 A 0 001 F003 0 4E05 Raw Field Data AC2 Angle 0 to 0 1 degree 0 1 F002 0 4E06 Raw Field Data AC3 Mag 0 to 0 001 A 0 001 F003 0 4E08 Raw Field Data AC3 Angle 0 to 0 01 degree 0 1 F002 0 4E09 Raw Field Data AC4 Mag 0 to 0 001 A 0 001 F003 0 4E0B Raw Field Data AC4 Angle 0 to 0 01 degree 0 1 F002 0 4E0C Raw Field Dat...

Page 507: ...409 RTD Input 1 Alarm Temperature 1 to 249 C 1 F001 130 540A RTD Input 1 Alarm Pickup Delay 0 to 600 s 0 01 F001 0 540B RTD Input 1 Trip Temperature 1 to 249 C 1 F001 130 540C RTD Input 1 Trip Pickup Delay 0 to 600 s 0 01 F001 0 540D RTD Input 1 Trip Reset Delay 0 to 600 s 0 01 F001 0 540E RTD Input 1 Trip Voting 0 to 48 1 F551 0 540F RTD Input 1 Open 0 to 2 1 F552 0 None 5410 RTD Input 1 Block 0 ...

Page 508: ...0 millisecond 5801 FlexLogic Timer 1 Pickup Delay 0 to 60000 1 F001 0 5802 FlexLogic Timer 1 Dropout Delay 0 to 60000 1 F001 0 5803 Reserved 5 items 0 to 65535 1 F001 0 5808 Repeated for FlexLogic Timer 2 5810 Repeated for FlexLogic Timer 3 5818 Repeated for FlexLogic Timer 4 5820 Repeated for FlexLogic Timer 5 5828 Repeated for FlexLogic Timer 6 5830 Repeated for FlexLogic Timer 7 5838 Repeated f...

Page 509: ... for Phase Instantaneous Overcurrent 12 Neutral Instantaneous Overcurrent Read Write Grouped Setting up to 12 Modules 5C00 Neutral Instantaneous Overcurrent 1 Function 0 to 1 1 F102 0 Disabled 5C01 Neutral Instantaneous Overcurrent 1 Signal Source 0 to 5 1 F167 0 SRC 1 5C02 Neutral Instantaneous Overcurrent 1 Pickup 0 to 30 pu 0 001 F001 1000 5C03 Neutral Instantaneous Overcurrent 1 Delay 0 to 600...

Page 510: ...or Ground Instantaneous Overcurrent 2 5DC2 Repeated for Ground Instantaneous Overcurrent 3 5DD3 Repeated for Ground Instantaneous Overcurrent 4 5DE4 Repeated for Ground Instantaneous Overcurrent 5 5DF5 Repeated for Ground Instantaneous Overcurrent 6 5E06 Repeated for Ground Instantaneous Overcurrent 7 5E17 Repeated for Ground Instantaneous Overcurrent 8 5E28 Repeated for Ground Instantaneous Overc...

Page 511: ...5 to 30 pu 0 01 F001 800 6426 Stator Differential Block 0 to 4294967295 1 F300 0 6428 Stator Differential Targets 0 to 2 1 F109 0 Self reset 6429 Stator Differential Events 0 to 1 1 F102 0 Disabled 642A Stator Differential Line End Source 0 to 5 1 F167 0 SRC 1 642B Stator Differential Neutral End Source 0 to 5 1 F167 0 SRC 1 Negative Sequence Overvoltage Read Write Grouped Setting 3 Modules 6440 N...

Page 512: ... 0 to 40 x FLA 0 01 F001 0 663C Start Hour Lockout Time 0 to 65000 min 1 F001 0 663D Time Between Starts Lockout Time 0 to 65000 min 1 F001 0 663E Restart Delay Lockout Time 0 to 50000 s 1 F001 0 663F Total Motor Lockout Time 0 to 65000 min 1 F001 0 Sensitive Directional Power Read Write Grouped Setting 2 Modules 6680 Sensitive Directional Power 1 Function 0 to 1 1 F102 0 Disabled 6681 Sensitive D...

Page 513: ...ommand 691F Motor Acceleration Clear Data Command 0 to 1 1 F126 0 No Motor Maximum Starting Rate Read Write Setting 6920 Starts Per Hour Function 0 to 1 1 F102 0 Disabled 6921 Starts Per Hour Time Interval 1 to 300 min 1 F001 60 6922 Starts Per Hour Maximum Number Of Starts 1 to 16 1 F001 3 6923 Starts Per Hour Block 0 to 4294967295 1 F300 0 6925 Starts Per Hour Target 0 to 2 1 F109 0 Self reset 6...

Page 514: ...f reset 7009 Phase Undervoltage 1 Events 0 to 1 1 F102 0 Disabled 700A Phase Undervoltage 1 Measurement Mode 0 to 1 1 F186 0 Phase to Ground 700B Reserved 6 items 0 to 1 1 F001 0 7011 Repeated for Phase Undervoltage 2 7022 Repeated for Phase Undervoltage 3 Phase Overvoltage Read Write Grouped Setting 3 Modules 7040 Phase Overvoltage 1 Function 0 to 1 1 F102 0 Disabled 7041 Phase Overvoltage 1 Sour...

Page 515: ... 1 F102 0 Disabled 74A1 Disconnect Switch 1 Name F206 SW 1 74A4 Disconnect Switch 1 Mode 0 to 1 1 F157 0 3 Pole 74A5 Disconnect Switch 1 Open 0 to 4294967295 1 F300 0 74A7 Disconnect Switch 1 Block Open 0 to 4294967295 1 F300 0 74A9 Disconnect Switch 1 Close 0 to 4294967295 1 F300 0 74AB Disconnect Switch 1 Block Close 0 to 4294967295 1 F300 0 74AD Disconnect Switch 1 Phase A Three pole Closed 0 t...

Page 516: ...odel TD Multiplier 0 to 600 0 01 F001 100 7B03 Thermal Model Bias K Factor 0 to 19 1 F001 0 7B04 Thermal Model Time Constant Running 1 to 65000 min 1 F001 15 7B05 Thermal Model Time Constant Stopped 1 to 65000 min 1 F001 30 7B06 Thermal Model Hot Cold Ratio 0 01 to 1 0 01 F001 100 7B07 Thermal Model RTD Bias 0 to 1 1 F102 0 Disabled 7B08 Thermal Model RTD Bias Minimum 0 to 250 C 1 F001 40 7B09 The...

Page 517: ...ration Mode 0 to 1 1 F097 0 Definite Time 7B4B Speed 2 Motor Acceleration Speed 1 2 0 05 to 180 00 s 0 01 F001 1000 7B4C Speed 2 Motor Acceleration Block 0 to 4294967295 1 F300 0 7B4E Reserved 9 items F001 0 User Programmable Pushbuttons Read Write Setting 16 Modules 7B60 User Programmable Pushbutton 1 Function 0 to 2 1 F137 0 Disabled 7B61 User Programmable Pushbutton 1 Top Line F202 none 7B6B Us...

Page 518: ...7F65 Auxiliary Undervoltage 1 Minimum Voltage 0 to 3 pu 0 001 F001 100 7F66 Auxiliary Undervoltage 1 Block 0 to 4294967295 1 F300 0 7F68 Auxiliary Undervoltage 1 Target 0 to 2 1 F109 0 Self reset 7F69 Auxiliary Undervoltage 1 Events 0 to 1 1 F102 0 Disabled 7F6A Reserved 7 items 0 to 65535 1 F001 0 7F71 Repeated for Auxiliary Undervoltage 2 7F82 Repeated for Auxiliary Undervoltage 3 Auxiliary Over...

Page 519: ... 1 Amp Supervision 0 to 1 1 F126 1 Yes 8604 Breaker Failure 1 Use Seal In 0 to 1 1 F126 1 Yes 8605 Breaker Failure 1 Three Pole Initiate 0 to 4294967295 1 F300 0 8607 Breaker Failure 1 Block 0 to 4294967295 1 F300 0 8609 Breaker Failure 1 Phase Amp Supv Pickup 0 001 to 30 pu 0 001 F001 1050 860A Breaker Failure 1 Neutral Amp Supv Pickup 0 001 to 30 pu 0 001 F001 1050 860B Breaker Failure 1 Use Tim...

Page 520: ...etting 48 Modules 8A00 Digital Element 1 Function 0 to 1 1 F102 0 Disabled 8A01 Digital Element 1 Name F203 Dig Element 1 8A09 Digital Element 1 Input 0 to 4294967295 1 F300 0 8A0B Digital Element 1 Pickup Delay 0 to 999999 999 s 0 001 F003 0 8A0D Digital Element 1 Reset Delay 0 to 999999 999 s 0 001 F003 0 8A0F Digital Element 1 Block 0 to 4294967295 1 F300 0 8A11 Digital Element 1 Target 0 to 2 ...

Page 521: ... Bus Read Write Setting 6 Modules 8ED0 Trip Bus 1 Function 0 to 1 1 F102 0 Disabled 8ED1 Trip Bus 1 Block 0 to 4294967295 F300 0 8ED3 Trip Bus 1 Pickup Delay 0 to 600 s 0 01 F001 0 8ED4 Trip Bus 1 Reset Delay 0 to 600 s 0 01 F001 0 8ED5 Trip Bus 1 Input 16 items 0 to 4294967295 1 F300 0 8EF5 Trip Bus 1 Latching 0 to 1 1 F102 0 Disabled 8EF6 Trip Bus 1 Reset 0 to 65535 1 F300 0 8EF8 Trip Bus 1 Targ...

Page 522: ...lication 0 to 5 1 F550 0 None 9269 RRTD RTD 1 Alarm Temp 1 to 200 C 1 F001 130 926A RRTD RTD 1 Alarm Pickup Delay 5 to 600 s 5 F001 5 926B RRTD RTD 1 Trip Temp 1 to 200 C 1 F001 130 926C RRTD RTD 1 Trip Pickup Delay 5 to 600 s 5 F001 5 926D RRTD RTD 1 Trip Reset Delay 5 to 600 s 5 F001 5 926E RRTD RTD 1 Trip Voting 0 to 13 1 F603 0 None 926F RRTD RTD 1 Block 0 to 4294967295 1 F300 0 9271 RRTD RTD ...

Page 523: ...rect Input Output 3 9424 Repeated for Direct Input Output 4 9430 Repeated for Direct Input Output 5 943C Repeated for Direct Input Output 6 9448 Repeated for Direct Input Output 7 9454 Repeated for Direct Input Output 8 9460 Repeated for Direct Input Output 9 946C Repeated for Direct Input Output 10 9478 Repeated for Direct Input Output 11 9484 Repeated for Direct Input Output 12 9490 Repeated for...

Page 524: ...C FlexElement 7 Actual 2147483 647 to 2147483 647 0 001 F004 0 990E FlexElement 8 Actual 2147483 647 to 2147483 647 0 001 F004 0 9910 FlexElement 9 Actual 2147483 647 to 2147483 647 0 001 F004 0 9912 FlexElement 10 Actual 2147483 647 to 2147483 647 0 001 F004 0 9914 FlexElement 11 Actual 2147483 647 to 2147483 647 0 001 F004 0 9916 FlexElement12 Actual 2147483 647 to 2147483 647 0 001 F004 0 9918 ...

Page 525: ...0 9F0F Undercurrent Speed 2 Trip Reset Delay 0 00 to 600 00 s 0 01 F001 100 9F10 Undercurrent Speed 2 Block 0 to 4294967295 1 F300 0 9F11 Reserved 2 items F001 0 Broken Rotor Bar Detection Read Only Actual Values A020 Broken rotor bar component level 100 to 0 dB 0 1 F002 1000 A021 Broken rotor bar component frequency 0 to 76 Hz 0 01 F001 0 A022 Motor load at broken rotor bar calculation 0 to 1 5 F...

Page 526: ... 0 A285 Selector 1 Step Mode 0 to 1 1 F083 0 Time out A286 Selector 1 Acknowledge 0 to 4294967295 1 F300 0 A288 Selector 1 Bit0 0 to 4294967295 1 F300 0 A28A Selector 1 Bit1 0 to 4294967295 1 F300 0 A28C Selector 1 Bit2 0 to 4294967295 1 F300 0 A28E Selector 1 Bit Mode 0 to 1 1 F083 0 Time out A28F Selector 1 Bit Acknowledge 0 to 4294967295 1 F300 0 A291 Selector 1 Power Up Mode 0 to 2 1 F084 0 Re...

Page 527: ...atile Latch 11 A784 Repeated for Non Volatile Latch 12 A790 Repeated for Non Volatile Latch 13 A79C Repeated for Non Volatile Latch 14 A7A8 Repeated for Non Volatile Latch 15 A7B4 Repeated for Non Volatile Latch 16 IEC 61850 Received Analog Settings Read Write 32 Modules AA00 IEC 61850 GOOSE analog 1 default value 1000000 to 1000000 0 001 F060 1000 AA02 IEC 61850 GOOSE analog input 1 mode 0 to 1 1...

Page 528: ...prefix 0 to 65534 1 F206 none AB4B IEC 61850 logical node PIOCx name prefix 72 items 0 to 65534 1 F206 none AC23 IEC 61850 logical node PTOCx name prefix 24 items 0 to 65534 1 F206 none AC6B IEC 61850 logical node PTUVx name prefix 13 items 0 to 65534 1 F206 none AC92 IEC 61850 logical node PTOVx name prefix 10 items 0 to 65534 1 F206 none ACB0 IEC 61850 logical node PDISx name prefix 10 items 0 t...

Page 529: ...put 24 AFB8 Repeated for IEC 61850 GGIO4 analog input 25 AFBF Repeated for IEC 61850 GGIO4 analog input 26 AFC6 Repeated for IEC 61850 GGIO4 analog input 27 AFCD Repeated for IEC 61850 GGIO4 analog input 28 AFD4 Repeated for IEC 61850 GGIO4 analog input 29 AFDB Repeated for IEC 61850 GGIO4 analog input 30 AFE2 Repeated for IEC 61850 GGIO4 analog input 31 AFE9 Repeated for IEC 61850 GGIO4 analog in...

Page 530: ... 0 001 to 100 0 001 F003 10000 B0E2 IEC 61850 MMXU W phsC Deadband 1 0 001 to 100 0 001 F003 10000 B0E4 IEC 61850 MMXU VAr phsA Deadband 1 0 001 to 100 0 001 F003 10000 B0E6 IEC 61850 MMXU VAr phsB Deadband 1 0 001 to 100 0 001 F003 10000 B0E8 IEC 61850 MMXU VAr phsC Deadband 1 0 001 to 100 0 001 F003 10000 B0EA IEC 61850 MMXU VA phsA Deadband 1 0 001 to 100 0 001 F003 10000 B0EC IEC 61850 MMXU VA...

Page 531: ...ed for module number 4 B37C Repeated for module number 5 B37F Repeated for module number 6 B382 Repeated for module number 7 B385 Repeated for module number 8 B388 Repeated for module number 9 B38B Repeated for module number 10 B38E Repeated for module number 11 B391 Repeated for module number 12 B394 Repeated for module number 13 B397 Repeated for module number 14 B39A Repeated for module number ...

Page 532: ...ted for Module 11 BA60 Repeated for Module 12 BA80 Repeated for Module 13 BAA0 Repeated for Module 14 BAC0 Repeated for Module 15 BAE0 Repeated for Module 16 Contact Inputs Read Write Setting 96 Modules BB00 Contact Input 1 Name F205 Cont Ip 1 BB06 Contact Input 1 Events 0 to 1 1 F102 0 Disabled BB07 Contact Input 1 Debounce Time 0 to 16 ms 0 5 F001 20 BB08 Repeated for Contact Input 2 BB10 Repeat...

Page 533: ...d for Contact Input 47 BC78 Repeated for Contact Input 48 BC80 Repeated for Contact Input 49 BC88 Repeated for Contact Input 50 BC90 Repeated for Contact Input 51 BC98 Repeated for Contact Input 52 BCA0 Repeated for Contact Input 53 BCA8 Repeated for Contact Input 54 BCB0 Repeated for Contact Input 55 BCB8 Repeated for Contact Input 56 BCC0 Repeated for Contact Input 57 BCC8 Repeated for Contact I...

Page 534: ...isabled BE31 Virtual Input 1 Name F205 Virt Ip 1 BE37 Virtual Input 1 Programmed Type 0 to 1 1 F127 0 Latched BE38 Virtual Input 1 Events 0 to 1 1 F102 0 Disabled BE39 Reserved 3 items F001 0 BE3C Repeated for Virtual Input 2 BE48 Repeated for Virtual Input 3 BE54 Repeated for Virtual Input 4 BE60 Repeated for Virtual Input 5 BE6C Repeated for Virtual Input 6 BE78 Repeated for Virtual Input 7 BE84...

Page 535: ...Input 52 C0A0 Repeated for Virtual Input 53 C0AC Repeated for Virtual Input 54 C0B8 Repeated for Virtual Input 55 C0C4 Repeated for Virtual Input 56 C0D0 Repeated for Virtual Input 57 C0DC Repeated for Virtual Input 58 C0E8 Repeated for Virtual Input 59 C0F4 Repeated for Virtual Input 60 C100 Repeated for Virtual Input 61 C10C Repeated for Virtual Input 62 C118 Repeated for Virtual Input 63 C124 R...

Page 536: ...or Virtual Output 39 C268 Repeated for Virtual Output 40 C270 Repeated for Virtual Output 41 C278 Repeated for Virtual Output 42 C280 Repeated for Virtual Output 43 C288 Repeated for Virtual Output 44 C290 Repeated for Virtual Output 45 C298 Repeated for Virtual Output 46 C2A0 Repeated for Virtual Output 47 C2A8 Repeated for Virtual Output 48 C2B0 Repeated for Virtual Output 49 C2B8 Repeated for V...

Page 537: ...ing C430 Test Mode Function 0 to 2 1 F245 0 Disabled C431 Force VFD and LED 0 to 1 1 F126 0 No C432 Test Mode Initiate 0 to 4294967295 1 F300 1 Clear Commands Read Write C434 Clear All Relay Records Command 0 to 1 1 F126 0 No Mandatory Read Only C435 DSP Advanced Diagnostics Active 0 to 1 1 F126 0 No C436 Synchrophasor Feature Active 0 to 1 1 F126 0 No Mandatory Read Write Command C437 Relay Reboo...

Page 538: ... Write Setting C750 FlexLogic operand which initiates a reset 0 to 4294967295 1 F300 0 Control Pushbuttons Read Write Setting 7 Modules C760 Control Pushbutton 1 Function 0 to 1 1 F102 0 Disabled C761 Control Pushbutton 1 Events 0 to 1 1 F102 0 Disabled C762 Repeated for Control Pushbutton 2 C764 Repeated for Control Pushbutton 3 C766 Repeated for Control Pushbutton 4 C768 Repeated for Control Pus...

Page 539: ...Alarms Read Write Setting CAD0 Direct Input Output Channel 1 CRC Alarm Function 0 to 1 1 F102 0 Disabled CAD1 Direct I O Channel 1 CRC Alarm Message Count 100 to 10000 1 F001 600 CAD2 Direct Input Output Channel 1 CRC Alarm Threshold 1 to 1000 1 F001 10 CAD3 Direct Input Output Channel 1 CRC Alarm Events 0 to 1 1 F102 0 Disabled CAD4 Reserved 4 items 1 to 1000 1 F001 10 CAD8 Direct Input Output Ch...

Page 540: ... Repeated for Device 20 CDE4 Repeated for Device 21 CE09 Repeated for Device 22 CE2E Repeated for Device 23 CE53 Repeated for Device 24 CE78 Repeated for Device 25 CE9D Repeated for Device 26 CEC2 Repeated for Device 27 CEE7 Repeated for Device 28 CF0C Repeated for Device 29 CF31 Repeated for Device 30 CF56 Repeated for Device 31 CF7B Repeated for Device 32 Remote Inputs Read Write Setting 64 Modu...

Page 541: ...nput 35 D0FE Repeated for Remote Input 36 D108 Repeated for Remote Input 37 D112 Repeated for Remote Input 38 D11C Repeated for Remote Input 39 D126 Repeated for Remote Input 40 D130 Repeated for Remote Input 41 D13A Repeated for Remote Input 42 D144 Repeated for Remote Input 43 D14E Repeated for Remote Input 44 D158 Repeated for Remote Input 45 D162 Repeated for Remote Input 46 D16C Repeated for ...

Page 542: ... Remote Output 22 D278 Repeated for Remote Output 23 D27C Repeated for Remote Output 24 D280 Repeated for Remote Output 25 D284 Repeated for Remote Output 26 D288 Repeated for Remote Output 27 D28C Repeated for Remote Output 28 D290 Repeated for Remote Output 29 D294 Repeated for Remote Output 30 D298 Repeated for Remote Output 31 D29C Repeated for Remote Output 32 Remote Output UserSt Pairs Read ...

Page 543: ...C 61850 GGIO2 CF SPCSO13 ctlModel Value 0 to 2 1 F001 1 D32D IEC 61850 GGIO2 CF SPCSO14 ctlModel Value 0 to 2 1 F001 1 D32E IEC 61850 GGIO2 CF SPCSO15 ctlModel Value 0 to 2 1 F001 1 D32F IEC 61850 GGIO2 CF SPCSO16 ctlModel Value 0 to 2 1 F001 1 D330 IEC 61850 GGIO2 CF SPCSO17 ctlModel Value 0 to 2 1 F001 1 D331 IEC 61850 GGIO2 CF SPCSO18 ctlModel Value 0 to 2 1 F001 1 D332 IEC 61850 GGIO2 CF SPCSO...

Page 544: ...o 2 1 F001 1 D359 IEC 61850 GGIO2 CF SPCSO58 ctlModel Value 0 to 2 1 F001 1 D35A IEC 61850 GGIO2 CF SPCSO59 ctlModel Value 0 to 2 1 F001 1 D35B IEC 61850 GGIO2 CF SPCSO60 ctlModel Value 0 to 2 1 F001 1 D35C IEC 61850 GGIO2 CF SPCSO61 ctlModel Value 0 to 2 1 F001 1 D35D IEC 61850 GGIO2 CF SPCSO62 ctlModel Value 0 to 2 1 F001 1 D35E IEC 61850 GGIO2 CF SPCSO63 ctlModel Value 0 to 2 1 F001 1 D35F IEC ...

Page 545: ... Output 9 D467 Repeated for Contact Output 10 D476 Repeated for Contact Output 11 D485 Repeated for Contact Output 12 D494 Repeated for Contact Output 13 D4A3 Repeated for Contact Output 14 D4B2 Repeated for Contact Output 15 D4C1 Repeated for Contact Output 16 D4D0 Repeated for Contact Output 17 D4DF Repeated for Contact Output 18 D4EE Repeated for Contact Output 19 D4FD Repeated for Contact Outp...

Page 546: ...dcmA Inputs Read Write Setting 24 Modules D7A0 dcmA Inputs 1 Function 0 to 1 1 F102 0 Disabled D7A1 dcmA Inputs 1 ID F205 DCMA I 1 D7A7 Reserved 1 4 items 0 to 65535 1 F001 0 D7AB dcmA Inputs 1 Units F206 mA D7AE dcmA Inputs 1 Range 0 to 6 1 F173 6 4 to 20 mA D7AF dcmA Inputs 1 Minimum Value 9999 999 to 9999 999 0 001 F004 4000 D7B1 dcmA Inputs 1 Maximum Value 9999 999 to 9999 999 0 001 F004 20000...

Page 547: ...EC 60870 5 104 Analog Input Points 256 items 0 to 65535 1 F600 0 Settings File Template Read Write Setting ED00 FlexLogic Displays Active 0 to 1 1 F102 1 Enabled ED01 Template Access F205 none Setting File Template Read Only ED07 Last Settings Change Date 0 to 4294967295 1 F050 0 Settings File Template Read Write Setting ED09 Template Bitmask 750 items 0 to 65535 1 F001 0 Table B 9 MODBUS MEMORY M...

Page 548: ...INTEGER Gives the current time in seconds elapsed since 00 00 00 January 1 1970 F051 UR_UINT32 DATE in SR format alternate format for F050 First 16 bits are Month Day MM DD xxxx Month 1 January 2 February 12 December Day 1 to 31 in steps of 1 Last 16 bits are Year xx xx YYYY 1970 to 2106 in steps of 1 F052 UR_UINT32 TIME in SR format alternate format for F050 First 16 bits are Hours Minutes HH MM ...

Page 549: ...ne 1 DC Shift 2 Amplitude Modulated F116 ENUMERATION NEUTRAL OVERVOLTAGE CURVES 0 Definite Time 1 FlexCurve A 2 FlexCurve B 3 FlexCurve C F118 ENUMERATION OSCILLOGRAPHY MODE 0 Automatic Overwrite 1 Protected F122 ENUMERATION ELEMENT INPUT SIGNAL TYPE 0 Phasor 1 RMS F123 ENUMERATION CT SECONDARY 0 1 A 1 5 A F124 ENUMERATION LIST OF ELEMENTS Bitmask Curve shape Bitmask Curve shape 0 IEEE Mod Inv 9 I...

Page 550: ...lexElement 1 401 FlexElement 2 402 FlexElement 3 403 FlexElement 4 404 FlexElement 5 405 FlexElement 6 406 FlexElemen 7 407 FlexElement 8 408 FlexElement 9 Bitmask Element 409 FlexElement 10 410 FlexElement 11 411 FlexElemen 12 412 FlexElement 13 413 FlexElemen 14 414 FlexElemen 15 415 FlexElement 16 420 Non volatile Latch 1 421 Non volatile Latch 2 422 Non volatile Latch 3 423 Non volatile Latch ...

Page 551: ...7 866 RTD Input 18 Bitmask Element 867 RTD Input 19 868 RTD Input 20 869 RTD Input 21 870 RTD Input 22 871 RTD Input 23 872 RTD Input 24 873 RTD Input 25 874 RTD Input 26 875 RTD Input 27 876 RTD Input 28 877 RTD Input 29 878 RTD Input 30 879 RTD Input 31 880 RTD Input 32 881 RTD Input 33 882 RTD Input 34 883 RTD Input 35 884 RTD Input 36 885 RTD Input 37 886 RTD Input 38 887 RTD Input 39 888 RTD ...

Page 552: ...Breaker 2 970 Breaker 3 971 Breaker 4 991 Remote RTD Input 1 992 Remote RTD Input 2 993 Remote RTD Input 3 994 Remote RTD Input 4 995 Remote RTD Input 5 996 Remote RTD Input 6 997 Remote RTD Input 7 998 Remote RTD Input 8 999 Remote RTD Input 9 1000 Remote RTD Input 10 1001 Remote RTD Input 11 1002 Remote RTD Input 12 1004 Broken Rotor Bar Bitmask Element Bitmask Error 0 Any Self Tests 1 IRIG B Fa...

Page 553: ...GM Failure 93 FGM Failure 94 FGM Failure 95 FGM Error 96 Maintenance Alert 97 PHY Monitor 98 Storage Media Alarm 99 Wrong Transceiver Bitmask Error Bitmask Definition 0 Events Cleared 1 Oscillography Triggered 2 Date time Changed 3 Default Settings Loaded 4 Test Mode Forcing On 5 Test Mode Forcing Off 6 Power On 7 Power Off 8 Relay In Service 9 Relay Out Of Service 10 Watchdog Reset 11 Oscillograp...

Page 554: ...RTD 26 42 RTD 42 10 RTD 10 27 RTD 27 43 RTD 43 11 RTD 11 28 RTD 28 44 RTD 44 12 RTD 12 29 RTD 29 45 RTD 45 13 RTD 13 30 RTD 30 46 RTD 46 14 RTD 14 31 RTD 31 47 RTD 47 15 RTD 15 32 RTD 32 48 RTD 48 16 RTD 16 Bitmask Value Bitmask Value 0 NONE 35 UserSt 3 1 DNA 1 36 UserSt 4 2 DNA 2 37 UserSt 5 3 DNA 3 38 UserSt 6 4 DNA 4 39 UserSt 7 5 DNA 5 40 UserSt 8 6 DNA 6 41 UserSt 9 7 DNA 7 42 UserSt 10 8 DNA...

Page 555: ...samples cycle 3 32 samples cycle 4 64 samples cycle Value GOOSE dataset 0 Off 1 GooseIn 1 2 GooseIn 2 3 GooseIn 3 4 GooseIn 4 5 GooseIn 5 6 GooseIn 6 7 GooseIn 7 8 GooseIn 8 9 GooseIn 9 10 GooseIn 10 11 GooseIn 11 12 GooseIn 12 13 GooseIn 13 14 GooseIn 14 15 GooseIn 15 16 GooseIn 16 Bitmask Keypress Bitmask Keypress 0 use between real keys 23 Reset 24 User 1 1 1 25 User 2 2 2 26 User 3 3 3 27 User...

Page 556: ...30 ENUMERATION DIRECTIONAL POLARIZING 0 Voltage 1 Current 2 Dual 3 Dual V 4 Dual I F231 ENUMERATION POLARIZING VOLTAGE 0 Calculated V0 1 Measured VX F232 ENUMERATION CONFIGURABLE GOOSE DATASET ITEMS FOR TRANSMISSION 22 50 User 7 control pushbutton Bitmask Keypress Bitmask Keypress Value Priority 0 Disabled 1 Normal 2 High Priority Value GOOSE dataset item 0 None 1 GGIO1 ST Ind1 q 2 GGIO1 ST Ind1 s...

Page 557: ...XU2 MX VAr phsC cVal mag f 325 MMXU2 MX VA phsA cVal mag f 326 MMXU2 MX VA phsB cVal mag f 327 MMXU2 MX VA phsC cVal mag f Value GOOSE dataset item 328 MMXU2 MX PF phsA cVal mag f 329 MMXU2 MX PF phsB cVal mag f 330 MMXU2 MX PF phsC cVal mag f 331 MMXU3 MX TotW mag f 332 MMXU3 MX TotVAr mag f 333 MMXU3 MX TotVA mag f 334 MMXU3 MX TotPF mag f 335 MMXU3 MX Hz mag f 336 MMXU3 MX PPV phsAB cVal mag f ...

Page 558: ...t cVal ang f 430 MMXU5 MX W phsA cVal mag f 431 MMXU5 MX W phsB cVal mag f 432 MMXU5 MX W phsC cVal mag f 433 MMXU5 MX VAr phsA cVal mag f Value GOOSE dataset item 434 MMXU5 MX VAr phsB cVal mag f 435 MMXU5 MX VAr phsC cVal mag f 436 MMXU5 MX VA phsA cVal mag f 437 MMXU5 MX VA phsB cVal mag f 438 MMXU5 MX VA phsC cVal mag f 439 MMXU5 MX PF phsA cVal mag f 440 MMXU5 MX PF phsB cVal mag f 441 MMXU5 ...

Page 559: ...10 stVal 531 GGIO5 ST UIntIn11 q 532 GGIO5 ST UIntIn11 stVal 533 GGIO5 ST UIntIn12 q 534 GGIO5 ST UIntIn12 stVal 535 GGIO5 ST UIntIn13 q 536 GGIO5 ST UIntIn13 stVal 537 GGIO5 ST UIntIn14 q 538 GGIO5 ST UIntIn14 stVal 539 GGIO5 ST UIntIn15 q Value GOOSE dataset item 540 GGIO5 ST UIntIn15 stVal 541 GGIO5 ST UIntIn16 q 542 GGIO5 ST UIntIn16 stVal Value GOOSE dataset item 0 None 1 GGIO3 ST Ind1 q 2 GG...

Page 560: ... GGIO3 ST UIntIn6 stVal 178 GGIO3 ST UIntIn7 q 179 GGIO3 ST UIntIn7 stVal 180 GGIO3 ST UIntIn8 q 181 GGIO3 ST UIntIn8 stVal 182 GGIO3 ST UIntIn9 q 183 GGIO3 ST UIntIn9 stVal 184 GGIO3 ST UIntIn10 q 185 GGIO3 ST UIntIn10 stVal 186 GGIO3 ST UIntIn11 q 187 GGIO3 ST UIntIn11 stVal 188 GGIO3 ST UIntIn12 q 189 GGIO3 ST UIntIn12 stVal 190 GGIO3 ST UIntIn13 q 191 GGIO3 ST UIntIn13 stVal 192 GGIO3 ST UIntI...

Page 561: ...xLogic type is associated with a protection element state and T represents bits for the BASE type and D represents bits for the descriptor The values in square brackets indicate the base type with P prefix PTTTTTTT and the values in round brackets indicate the descrip tor range The right most T bit indicates whether the type is an ON or OFF type There can be a total of 64 types plus protection ele...

Page 562: ...NT16 PACKED BITFIELD First register indicates input output state with bits 0 MSB to 15 LSB corresponding to input output state 1 to 16 The second reg ister indicates input output state with bits 0 to 15 corresponding to input output state 17 to 32 if required The third register indicates input output state with bits 0 to 15 corresponding to input output state 33 to 48 if required The fourth regist...

Page 563: ...1 1 2 2 3 3 4 4 5 5 7 Valu e Keypress Valu e Keypress Valu e Keypress 0 None 15 3 33 User PB 3 1 Menu 16 Enter 34 User PB 4 2 Message Up 17 Message Down 35 User PB 5 3 7 18 0 36 User PB 6 4 8 19 Decimal 37 User PB 7 5 9 20 38 User PB 8 6 Help 21 Value Up 39 User PB 9 7 Message Left 22 Value Down 40 User PB 10 8 4 23 Reset 41 User PB 11 9 5 24 User 1 42 User PB 12 10 6 25 User 2 44 User 4 11 Escape...

Page 564: ...13 RTD Input 12 Enumeration RTD open 0 None 1 Alarm 2 Block Enumeration COM2 port usage 0 RS485 1 RRTD 2 GPM F 3 RRTD and GPM F Enumeration RRTD baud rate 0 1200 bps 1 2400 bps 2 4800 bps 3 9600 bps 4 19200 bps Enumeration RRTD trip voting 0 None 1 Group 2 Remote RTD 1 3 Remote RTD 2 4 Remote RTD 3 5 Remote RTD 4 6 Remote RTD 5 7 Remote RTD 6 8 Remote RTD 7 9 Remote RTD 8 10 Remote RTD 9 11 Remote...

Page 565: ... PIOC16 ST Op general 61 PIOC17 ST Str general 62 PIOC17 ST Op general Enumeration IEC 61850 report dataset items 63 PIOC18 ST Str general 64 PIOC18 ST Op general 65 PIOC19 ST Str general 66 PIOC19 ST Op general 67 PIOC20 ST Str general 68 PIOC20 ST Op general 69 PIOC21 ST Str general 70 PIOC21 ST Op general 71 PIOC22 ST Str general 72 PIOC22 ST Op general 73 PIOC23 ST Str general 74 PIOC23 ST Op ...

Page 566: ...ral 165 PIOC69 ST Str general 166 PIOC69 ST Op general 167 PIOC70 ST Str general 168 PIOC70 ST Op general Enumeration IEC 61850 report dataset items 169 PIOC71 ST Str general 170 PIOC71 ST Op general 171 PIOC72 ST Str general 172 PIOC72 ST Op general 173 PTOC1 ST Str general 174 PTOC1 ST Op general 175 PTOC2 ST Str general 176 PTOC2 ST Op general 177 PTOC3 ST Str general 178 PTOC3 ST Op general 17...

Page 567: ...1 ST Str general 274 PTUV11 ST Op general Enumeration IEC 61850 report dataset items 275 PTUV12 ST Str general 276 PTUV12 ST Op general 277 PTUV13 ST Str general 278 PTUV13 ST Op general 279 RBRF1 ST OpEx general 280 RBRF1 ST OpIn general 281 RBRF2 ST OpEx general 282 RBRF2 ST OpIn general 283 RBRF3 ST OpEx general 284 RBRF3 ST OpIn general 285 RBRF4 ST OpEx general 286 RBRF4 ST OpIn general 287 R...

Page 568: ... stVal 377 CSWI16 ST Loc stVal 378 CSWI16 ST Pos stVal 379 CSWI17 ST Loc stVal 380 CSWI17 ST Pos stVal Enumeration IEC 61850 report dataset items 381 CSWI18 ST Loc stVal 382 CSWI18 ST Pos stVal 383 CSWI19 ST Loc stVal 384 CSWI19 ST Pos stVal 385 CSWI20 ST Loc stVal 386 CSWI20 ST Pos stVal 387 CSWI21 ST Loc stVal 388 CSWI21 ST Pos stVal 389 CSWI22 ST Loc stVal 390 CSWI22 ST Pos stVal 391 CSWI23 ST ...

Page 569: ...77 stVal 484 GGIO1 ST Ind78 stVal 485 GGIO1 ST Ind79 stVal 486 GGIO1 ST Ind80 stVal Enumeration IEC 61850 report dataset items 487 GGIO1 ST Ind81 stVal 488 GGIO1 ST Ind82 stVal 489 GGIO1 ST Ind83 stVal 490 GGIO1 ST Ind84 stVal 491 GGIO1 ST Ind85 stVal 492 GGIO1 ST Ind86 stVal 493 GGIO1 ST Ind87 stVal 494 GGIO1 ST Ind88 stVal 495 GGIO1 ST Ind89 stVal 496 GGIO1 ST Ind90 stVal 497 GGIO1 ST Ind91 stVa...

Page 570: ...A cVal mag f 590 MMXU2 MX A phsA cVal ang f 591 MMXU2 MX A phsB cVal mag f 592 MMXU2 MX A phsB cVal ang f Enumeration IEC 61850 report dataset items 593 MMXU2 MX A phsC cVal mag f 594 MMXU2 MX A phsC cVal ang f 595 MMXU2 MX A neut cVal mag f 596 MMXU2 MX A neut cVal ang f 597 MMXU2 MX W phsA cVal mag f 598 MMXU2 MX W phsB cVal mag f 599 MMXU2 MX W phsC cVal mag f 600 MMXU2 MX VAr phsA cVal mag f 6...

Page 571: ... MX PhV phsB cVal mag f 697 MMXU5 MX PhV phsB cVal ang f 698 MMXU5 MX PhV phsC cVal mag f Enumeration IEC 61850 report dataset items 699 MMXU5 MX PhV phsC cVal ang f 700 MMXU5 MX A phsA cVal mag f 701 MMXU5 MX A phsA cVal ang f 702 MMXU5 MX A phsB cVal mag f 703 MMXU5 MX A phsB cVal ang f 704 MMXU5 MX A phsC cVal mag f 705 MMXU5 MX A phsC cVal ang f 706 MMXU5 MX A neut cVal mag f 707 MMXU5 MX A ne...

Page 572: ...4 XSWI3 ST Pos stVal 795 XSWI4 ST Loc stVal 796 XSWI4 ST Pos stVal 797 XSWI5 ST Loc stVal 798 XSWI5 ST Pos stVal 799 XSWI6 ST Loc stVal 800 XSWI6 ST Pos stVal 801 XSWI7 ST Loc stVal 802 XSWI7 ST Pos stVal 803 XSWI8 ST Loc stVal 804 XSWI8 ST Pos stVal Enumeration IEC 61850 report dataset items 805 XSWI9 ST Loc stVal 806 XSWI9 ST Pos stVal 807 XSWI10 ST Loc stVal 808 XSWI10 ST Pos stVal 809 XSWI11 S...

Page 573: ...d22 stVal 45 GGIO1 ST Ind23 q 46 GGIO1 ST Ind23 stVal 47 GGIO1 ST Ind24 q 48 GGIO1 ST Ind24 stVal 49 GGIO1 ST Ind25 q 50 GGIO1 ST Ind25 stVal 51 GGIO1 ST Ind26 q 52 GGIO1 ST Ind26 stVal 53 GGIO1 ST Ind27 q 54 GGIO1 ST Ind27 stVal 55 GGIO1 ST Ind28 q 56 GGIO1 ST Ind28 stVal 57 GGIO1 ST Ind29 q 58 GGIO1 ST Ind29 stVal 59 GGIO1 ST Ind30 q 60 GGIO1 ST Ind30 stVal 61 GGIO1 ST Ind31 q 62 GGIO1 ST Ind31 ...

Page 574: ...T Ind75 stVal 151 GGIO1 ST Ind76 q 152 GGIO1 ST Ind76 stVal 153 GGIO1 ST Ind77 q 154 GGIO1 ST Ind77 stVal Enumeration GOOSE dataset items 155 GGIO1 ST Ind78 q 156 GGIO1 ST Ind78 stVal 157 GGIO1 ST Ind79 q 158 GGIO1 ST Ind79 stVal 159 GGIO1 ST Ind80 q 160 GGIO1 ST Ind80 stVal 161 GGIO1 ST Ind81 q 162 GGIO1 ST Ind81 stVal 163 GGIO1 ST Ind82 q 164 GGIO1 ST Ind82 stVal 165 GGIO1 ST Ind83 q 166 GGIO1 S...

Page 575: ...63 MMXU1 MX PPV phsAB cVal ang f 264 MMXU1 MX PPV phsBC cVal mag f 265 MMXU1 MX PPV phsBC cVal ang f 266 MMXU1 MX PPV phsCA cVal mag f 267 MMXU1 MX PPV phsCA cVal ang f 268 MMXU1 MX PhV phsA cVal mag f 269 MMXU1 MX PhV phsA cVal ang f 270 MMXU1 MX PhV phsB cVal mag f 271 MMXU1 MX PhV phsB cVal ang f 272 MMXU1 MX PhV phsC cVal mag f 273 MMXU1 MX PhV phsC cVal ang f 274 MMXU1 MX A phsA cVal mag f 27...

Page 576: ...X VA phsB cVal mag f 364 MMXU3 MX VA phsC cVal mag f 365 MMXU3 MX PF phsA cVal mag f 366 MMXU3 MX PF phsB cVal mag f Enumeration GOOSE dataset items 367 MMXU3 MX PF phsC cVal mag f 368 MMXU4 MX TotW mag f 369 MMXU4 MX TotVAr mag f 370 MMXU4 MX TotVA mag f 371 MMXU4 MX TotPF mag f 372 MMXU4 MX Hz mag f 373 MMXU4 MX PPV phsAB cVal mag f 374 MMXU4 MX PPV phsAB cVal ang f 375 MMXU4 MX PPV phsBC cVal m...

Page 577: ... MX A neut cVal mag f 466 MMXU6 MX A neut cVal ang f 467 MMXU6 MX W phsA cVal mag f 468 MMXU6 MX W phsB cVal mag f 469 MMXU6 MX W phsC cVal mag f 470 MMXU6 MX VAr phsA cVal mag f 471 MMXU6 MX VAr phsB cVal mag f 472 MMXU6 MX VAr phsC cVal mag f Enumeration GOOSE dataset items 473 MMXU6 MX VA phsA cVal mag f 474 MMXU6 MX VA phsB cVal mag f 475 MMXU6 MX VA phsC cVal mag f 476 MMXU6 MX PF phsA cVal m...

Page 578: ...l 575 PIOC3 ST Str general 576 PIOC3 ST Op general 577 PIOC4 ST Str general 578 PIOC4 ST Op general Enumeration GOOSE dataset items 579 PIOC5 ST Str general 580 PIOC5 ST Op general 581 PIOC6 ST Str general 582 PIOC6 ST Op general 583 PIOC7 ST Str general 584 PIOC7 ST Op general 585 PIOC8 ST Str general 586 PIOC8 ST Op general 587 PIOC9 ST Str general 588 PIOC9 ST Op general 589 PIOC10 ST Str gener...

Page 579: ... ST Op general 681 PIOC56 ST Str general 682 PIOC56 ST Op general 683 PIOC57 ST Str general 684 PIOC57 ST Op general Enumeration GOOSE dataset items 685 PIOC58 ST Str general 686 PIOC58 ST Op general 687 PIOC59 ST Str general 688 PIOC59 ST Op general 689 PIOC60 ST Str general 690 PIOC60 ST Op general 691 PIOC61 ST Str general 692 PIOC61 ST Op general 693 PIOC62 ST Str general 694 PIOC62 ST Op gene...

Page 580: ... 787 PTRC3 ST Tr general 788 PTRC3 ST Op general 789 PTRC4 ST Tr general 790 PTRC4 ST Op general Enumeration GOOSE dataset items 791 PTRC5 ST Tr general 792 PTRC5 ST Op general 793 PTRC6 ST Tr general 794 PTRC6 ST Op general 795 PTUV1 ST Str general 796 PTUV1 ST Op general 797 PTUV2 ST Str general 798 PTUV2 ST Op general 799 PTUV3 ST Str general 800 PTUV3 ST Op general 801 PTUV4 ST Str general 802...

Page 581: ...T Loc stVal 890 CSWI1 ST Pos stVal 891 CSWI2 ST Loc stVal 892 CSWI2 ST Pos stVal 893 CSWI3 ST Loc stVal 894 CSWI3 ST Pos stVal 895 CSWI4 ST Loc stVal 896 CSWI4 ST Pos stVal Enumeration GOOSE dataset items 897 CSWI5 ST Loc stVal 898 CSWI5 ST Pos stVal 899 CSWI6 ST Loc stVal 900 CSWI6 ST Pos stVal 901 CSWI7 ST Loc stVal 902 CSWI7 ST Pos stVal 903 CSWI8 ST Loc stVal 904 CSWI8 ST Pos stVal 905 CSWI9 S...

Page 582: ...ST Loc stVal 980 XSWI16 ST Pos stVal 981 XSWI17 ST Loc stVal 982 XSWI17 ST Pos stVal 983 XSWI18 ST Loc stVal 984 XSWI18 ST Pos stVal 985 XSWI19 ST Loc stVal 986 XSWI19 ST Pos stVal 987 XSWI20 ST Loc stVal 988 XSWI20 ST Pos stVal 989 XSWI21 ST Loc stVal 990 XSWI21 ST Pos stVal 991 XSWI22 ST Loc stVal 992 XSWI22 ST Pos stVal 993 XSWI23 ST Loc stVal 994 XSWI23 ST Pos stVal 995 XSWI24 ST Loc stVal 996...

Page 583: ...tem B 109 APPENDIX B B 4 MEMORY MAPPING B F626 ENUMERATION NETWORK PORT FOR REMOTE DEVICE F627 ENUMERATION REDUNDANCY MODE Enumeration Item 0 None 1 Network Port 1 2 Network Port 2 3 Network Port 3 Enumeration Item 0 None 1 Failover 2 PRP ...

Page 584: ...B 110 M60 Motor Protection System GE Multilin B 4 MEMORY MAPPING APPENDIX B B ...

Page 585: ...hat all those involved with any IEC 61850 implementation obtain this document set C 1 2 COMMUNICATION PROFILES IEC 61850 specifies the use of the Manufacturing Message Specification MMS at the upper application layer for transfer of real time data This protocol has been in existence for several of years and provides a set of services suitable for the transfer of data within a substation LAN enviro...

Page 586: ...be used for SOE logs since the buffering capability reduces the chances of missing data state changes Unbuffered reporting should generally be used for local status display C 2 3 GGIO2 DIGITAL CONTROL VALUES The GGIO2 logical node is available to provide access to the M60 virtual inputs Virtual inputs are single point control binary values that can be written by clients They are generally used as ...

Page 587: ...MMXU1 MX Hz frequency MMXU1 MX PPV phsAB phase AB voltage magnitude and angle MMXU1 MX PPV phsBC phase BC voltage magnitude and angle MMXU1 MX PPV phsCA Phase CA voltage magnitude and angle MMXU1 MX PhV phsA phase AG voltage magnitude and angle MMXU1 MX PhV phsB phase BG voltage magnitude and angle MMXU1 MX PhV phsC phase CG voltage magnitude and angle MMXU1 MX A phsA phase A current magnitude and...

Page 588: ...ocator function The XCBR logical node is directly associated with the breaker control feature XCBR1 ST Loc This is the state of the XCBR1 local remote switch A setting is provided to assign a FlexLogic operand to determine the state When local mode is true IEC 61850 client commands will be rejected XCBR1 ST Opcnt This is an operation counter as defined in IEC 61850 Command settings are provided to...

Page 589: ...of the last change of either the value or quality flags of the data item To accomplish this functionality all IEC 61850 data items must be regularly scanned for data changes and the timestamp updated when a change is detected regardless of the connection status of any IEC 61850 cli ents For applications where there is no IEC 61850 client in use the IEC 61850 SERVER SCANNING setting can be pro gram...

Page 590: ...tion for greater than two minutes the connection will be aborted by the M60 This frees up the con nection to be used by other clients Therefore when using IEC 61850 reporting clients should configure report control block items such that an integrity report will be issued at least every 2 minutes 120000 ms This ensures that the M60 will not abort the connection If other MMS data is being polled on ...

Page 591: ...wo pre defined data structures named DNA and UserSt Each DNA and UserSt item is referred to as a bit pair GSSE messages are transmit ted in response to state changes in any of the data points contained in the message GSSE messages always contain the same number of DNA and UserSt bit pairs Depending the on the configuration only some of these bit pairs may have val ues that are of interest to recei...

Page 592: ...ded for applications that require GOOSE data transfer between UR series IEDs and devices from other manufacturers Fixed GOOSE is recommended for applications that require GOOSE data transfer between UR series IEDs IEC 61850 GOOSE messaging contains a number of configurable parameters all of which must be correct to achieve the successful transfer of data It is critical that the configured datasets...

Page 593: ...ATION IEC 61850 PROTOCOL GSSE GOOSE CONFIGURATION RECEPTION CONFIGURABLE GOOSE CONFIGURABLE GOOSE 1 CONFIG GSE 1 DATASET ITEMS settings menu Set ITEM 1 to GGIO3 ST Ind1 q to indicate quality flags for GGIO3 status indication 1 Set ITEM 2 to GGIO3 ST Ind1 stVal to indicate the status value for GGIO3 status indication 1 The reception dataset now contains a set of quality flags a single point status ...

Page 594: ...figured to use an automated multicast MAC scheme If the M60 destination MAC address setting is not a valid multicast address that is the least significant bit of the first byte is not set the address used as the destina tion MAC will be the same as the local MAC address but with the multicast bit set Thus if the local MAC address is 00 A0 F4 01 02 03 then the destination MAC address will be 01 A0 ...

Page 595: ...h other ICD files for other IEDs from GE or other ven dors for system configuration 3 The result is saved to a SCD file which is then imported back to EnerVista UR Setup to create one or more settings file s The settings file s can then be used to update the relay s with the new configuration information The configuration process is illustrated below Figure C 1 IED CONFIGURATION PROCESS The follow...

Page 596: ...SCD to set communication configuration parame ters that is required addresses reception GOOSE datasets IDs of incoming GOOSE datasets etc for the IED The IED configurator functionality is implemented in the GE Multilin EnerVista UR Setup software C 5 2 CONFIGURING IEC 61850 SETTINGS Before creating an ICD file the user can customize the IEC 61850 related settings for the IED For example the IED na...

Page 597: ...ors we recommend configuring transmission GOOSE for GE Multilin IEDs before creating the ICD and strictly within EnerVista UR Setup software or the front panel display access through the Settings Product Setup Com munications IEC 61850 GSSE GOOSE Configuration Transmission Tx Configurable GOOSE menu tree in EnerVista UR Setup Configurable reception GOOSE which includes eight configurable datasets ...

Page 598: ...s node contains the address parameters of the access point The GSE node provides the address element for stat ing the control block related address parameters where IdInst is the instance identification of the logical device within the IED on which the control block is located and cbName is the name of the control block The IED node describes the pre configuration of an IED its access points the l...

Page 599: ...taSet name Other DataSet elements FCDA fc doName daName IdInst prefix InClass InInst Other FCDA elements DOI name SDI name Val Text Other DOI elements GSEControl name datSet type confRev appID LN InType InClass prefix inst DataSet name FCDA IdInst prefix InClass InInst doName fc Other FCDA elements ReportControl name datSet intgPd rptID confRev buffered TrgOps dchg OptFields seqNum RptEnabled Othe...

Page 600: ...O The attribute DA has a func tional constraint and can either have a basic type be an enumeration or a structure of a DAType The DAType is built from BDA elements defining the structure elements which again can be BDA elements of have a base type such as DA Figure C 5 ICD FILE STRUCTURE DATATYPETEMPLATES NODE 842798A1 CDR DataTypeTemplates LNodeType id InClass DO name type Other LNodeType element...

Page 601: ...rocedure is pretty much the same First a substation project must be created either as an empty template or with some system information by importing a system specification file SSD Then IEDs are added to the substation Since each IED is represented by its associated ICD the ICD files are imported into the substation project and the system configurator validates the ICD files during the importing p...

Page 602: ...le and its version and specifies options for the mapping of names to signals The Substation node describes the substation parameters Figure C 7 SCD FILE STRUCTURE SUBSTATION NODE 842791A1 CDR SCL Header id version revision toolID nameStructure IED Section IED 2 Communication IED Section IED 1 Substation Other IED Sections DataTypeTemplates 842792A1 CDR Substation EquipmentContainer VoltageLevel Fu...

Page 603: ...tedAP node describes the IED access point connected to this sub network The Address node contains the address parameters of the access point The GSE node provides the address element for stat ing the control block related address parameters where IdInst is the instance identification of the logical device within the IED on which the control block is located and cbName is the name of the control bl...

Page 604: ...te the M60 with the new configuration from an SCD file with the EnerVista UR Setup software 1 Right click anywhere in the files panel and select the Import Contents From SCD File item 2 Select the saved SCD file and click Open 842794A1 CDR IED Section IED 1 AccessPoint name Server Authentication none LDevice inst LN0 InType InClass inst DataSet elements DOI elements Inputs GSEControl elements Repo...

Page 605: ...ne GE Multilin IED defined in the SCD file the software prompt the user to save a UR series set tings file for each IED 4 After the URS file is created modify any settings if required 5 To update the relay with the new settings right click on the settings file in the settings tree and select the Write Set tings File to Device item 6 The software will prompt for the target device Select the target ...

Page 606: ...SM IEC 61850 9 2 used B24 SCSM other GENERIC SUBSTATION EVENT MODEL GSE B31 Publisher side O Yes B32 Subscriber side Yes TRANSMISSION OF SAMPLED VALUE MODEL SVC B41 Publisher side O B42 Subscriber side SERVICES SERVER PUBLISHER UR FAMILY IF SERVER SIDE B11 SUPPORTED M1 Logical device c2 Yes M2 Logical node c3 Yes M3 Data c4 Yes M4 Data set c5 Yes M5 Substitution O M6 Setting group control O REPORT...

Page 607: ... name M8 5 data reference M8 6 BufTm M8 7 IntgPd M8 8 GI Logging O M9 Log control O M9 1 IntgPd M10 Log O M11 Control M Yes IF GSE B31 32 IS SUPPORTED GOOSE O Yes M12 1 entryID M12 2 DataReflnc M13 GSSE O Yes IF SVC B41 B42 IS SUPPORTED M14 Multicast SVC O M15 Unicast SVC O M16 Time M Yes M17 File transfer O Yes SERVICES AA TP MC SERVER PUBLISHER UR FAMILY SERVER CLAUSE 7 S1 ServerDirectory TP M Y...

Page 608: ... S26 SetBRCBValues TP c6 Yes UNBUFFERED REPORT CONTROL BLOCK URCB S27 Report TP c6 Yes S27 1 data change dchg Yes S27 2 qchg change qchg S27 3 data update dupd S28 GetURCBValues TP c6 Yes S29 SetURCBValues TP c6 Yes LOGGING CLAUSE 17 LOG CONTROL BLOCK S30 GetLCBValues TP M S31 SetLCBValues TP M LOG S32 QueryLogByTime TP M S33 QueryLogByEntry TP M S34 GetLogStatusValues TP M GENERIC SUBSTATION EVEN...

Page 609: ...dMSVMessage MC c10 S46 GetMSVCBValues TP O S47 SetMSVCBValues TP O UNICAST SVC S48 SendUSVMessage MC c10 S49 GetUSVCBValues TP O S50 SetUSVCBValues TP O CONTROL CLAUSE 20 S51 Select O Yes S52 SelectWithValue TP O S53 Cancel TP O Yes S54 Operate TP M Yes S55 Command Termination TP O S56 TimeActivated Operate TP O FILE TRANSFER CLAUSE 23 S57 GetFile TP M Yes S58 SetFile TP O S59 DeleteFile TP O S60 ...

Page 610: ...g A LOGICAL NODES FOR AUTOMATIC CONTROL ANCR Neutral current regulator ARCO Reactive power control ATCC Automatic tap changer controller AVCO Voltage control C LOGICAL NODES FOR CONTROL CALH Alarm handling CCGR Cooling group control CILO Interlocking CPOW Point on wave switching CSWI Switch controller Yes CSYN Synchronizer controller F LOGICAL NODES FOR FUNCTIONAL BLOCKS FCNT Counter FCSD Curve sh...

Page 611: ...MSQI Sequence and imbalance Yes MSTA Metering statistics P LOGICAL NODES FOR PROTECTION FUNCTIONS PDIF Differential Yes PDIR Direction comparison PDIS Distance Yes PDOP Directional overpower PDUP Directional underpower PFRC Rate of change of frequency PHAR Harmonic restraint PHIZ Ground detector PIOC Instantaneous overcurrent Yes PMRI Motor restart inhibition PMSS Motor starting time supervision P...

Page 612: ...ential measurements RPSB Power swing detection blocking Yes RREC Autoreclosing Yes RSYN Synchronism check or synchronizing S LOGICAL NODES FOR SENSORS AND MONITORING SARC Monitoring and diagnostics for arcs SCBR Circuit breaker supervision SIMG Insulation medium supervision gas SIML Insulation medium supervision liquid SLTC Tap changer supervision SOPM Supervision of operating mechanism SPDC Monit...

Page 613: ...h fault neutralizer Petersen coil YLTC Tap changer YPSH Power shunt YPTR Power transformer Z LOGICAL NODES FOR FURTHER POWER SYSTEM EQUIPMENT ZAXN Auxiliary network ZBAT Battery ZBSH Bushing ZCAB Power cable ZCAP Capacitor bank ZCON Converter ZGEN Generator ZGIL Gas insulated line ZLIN Power overhead line ZMOT Motor ZREA Reactor ZRES Resistor ZRRC Rotating reactive component ZSAR Surge arrestor ZS...

Page 614: ...C 30 M60 Motor Protection System GE Multilin C 7 LOGICAL NODES APPENDIX C C ...

Page 615: ...operability table Interoperability means that any required applica tion data in the device which can be coded into an IEC 60870 5 103 data type can be mapped into the IEC 60870 5 103 address space This data is recognized by any IEC 60870 5 103 master D 1 2 FACTOR AND OFFSET CALCULATION TO TRANSMIT MEASURAND The general formula for the transmitted value is Xt a X b where X is the measurand a is the...

Page 616: ...YER Transmission mode for application data Mode 1 least significant octet first as defined in 4 10 of IEC 60870 5 4 is used exclusively in this companion stan dard Common address of ASDU One COMMON ADDRESS OF ASDU identical with station address More than one COMMON ADDRESS OF ASDU Selection of standard information numbers in monitor direction System functions in monitor direction INF Semantics 0 E...

Page 617: ...quence supervision 36 Trip circuit supervision 37 I back up operation 38 VT fuse failure 39 Teleprotection disturbed 46 Group warning 47 Group alarm Earth fault indications in monitor direction INF Semantics 48 Earth fault L1 49 Earth fault L2 50 Earth fault L3 51 Earth fault forward meaning line 52 Earth fault reverse meaning busbar Fault indications in monitor direction INF Semantics 64 Start pi...

Page 618: ...IN Auto reclosure indications in monitor direction INF Semantics 128 CB on by AR 129 CB on by long time AR 130 AR blocked Measurands in monitor direction INF Semantics 144 Measurand I 145 Measurands I V 146 Measurands I V P Q 147 Measurands IN VEN 148 Measurands IL123 VL123 P Q f Generic functions in monitor direction INF Semantics 240 Read headings of all defined groups 241 Read values or attribu...

Page 619: ...25 Activate characteristic 3 26 Activate characteristic 4 Generic functions in control direction INF Semantics 240 Read headings of all defined groups 241 Read values or attributes of all entries of one group 243 Read directory of a single entry 244 Read value or attribute of a single entry 245 General interrogation of generic data 248 Write entry 249 Write entry with confirmation 250 Write entry ...

Page 620: ...D 6 M60 Motor Protection System GE Multilin D 1 IEC 60870 5 103 APPENDIX D D Voltage L3 E Active power P Reactive power Q Frequency f Voltage L1 L2 MEASURAND MAX MVAL TIMES RATED VALUE 1 2 OR 2 4 ...

Page 621: ...nge Circuit V 24 V 28 Recommended if 1200 bits s Balanced Interchange Circuit X 24 X 27 100 bits sec 200 bits sec 300 bits sec 600 bits sec 1200 bits sec 2400 bits sec 4800 bits sec 9600 bits sec 2400 bits sec 4800 bits sec 9600 bits sec 19200 bits sec 38400 bits sec 56000 bits sec 64000 bits sec Unbalanced Interchange Circuit V 24 V 28 Standard Unbalanced Interchange Circuit V 24 V 28 Recommended...

Page 622: ...wing used in standard direction not used cannot be selected in IEC 60870 5 104 standard Process information in monitor direction 1 Single point information M_SP_NA_1 2 Single point information with time tag M_SP_TA_1 3 Double point information M_DP_NA_1 4 Double point information with time tag M_DP_TA_1 5 Step position information M_ST_NA_1 6 Step position information with time tag M_ST_TA_1 7 Bit...

Page 623: ...s of protection equipment with time tag CP56Time2a M_EP_TE_1 40 Packed output circuit information of protection equipment with time tag CP56Time2a M_EP_TF_1 45 Single command C_SC_NA_1 46 Double command C_DC_NA_1 47 Regulating step command C_RC_NA_1 48 Set point command normalized value C_SE_NA_1 49 Set point command scaled value C_SE_NB_1 50 Set point command short floating point value C_SE_NC_1 ...

Page 624: ... directory select file call file call section F_SC_NA_1 123 Last section last segment F_LS_NA_1 124 Ack file ack section F_AF_NA_1 125 Segment F_SG_NA_1 126 Directory blank or X available only in monitor standard direction C_CD_NA_1 TYPE IDENTIFICATION CAUSE OF TRANSMISSION NO MNEMONIC 1 2 3 4 5 6 7 8 9 10 11 12 13 20 to 36 37 to 41 44 45 46 47 1 M_SP_NA_1 X X X X X 2 M_SP_TA_1 3 M_DP_NA_1 4 M_DP_...

Page 625: ...NA_1 48 C_SE_NA_1 49 C_SE_NB_1 50 C_SE_NC_1 51 C_BO_NA_1 58 C_SC_TA_1 X X X X X 59 C_DC_TA_1 60 C_RC_TA_1 TYPE IDENTIFICATION CAUSE OF TRANSMISSION NO MNEMONIC 1 2 3 4 5 6 7 8 9 10 11 12 13 20 to 36 37 to 41 44 45 46 47 PERIODIC CYCLIC BACKGROUND SCAN SPONTANEOUS INITIALIZED REQUEST OR REQUESTED ACTIVATION ACTIVATION CONFIRMATION DEACTIVATION DEACTIVATION CONFIRMATION ACTIVATION TERMINATION RETURN...

Page 626: ...112 P_ME_NC_1 X X X 113 P_AC_NA_1 120 F_FR_NA_1 121 F_SR_NA_1 122 F_SC_NA_1 123 F_LS_NA_1 124 F_AF_NA_1 125 F_SG_NA_1 126 F_DR_TA_1 TYPE IDENTIFICATION CAUSE OF TRANSMISSION NO MNEMONIC 1 2 3 4 5 6 7 8 9 10 11 12 13 20 to 36 37 to 41 44 45 46 47 PERIODIC CYCLIC BACKGROUND SCAN SPONTANEOUS INITIALIZED REQUEST OR REQUESTED ACTIVATION ACTIVATION CONFIRMATION DEACTIVATION DEACTIVATION CONFIRMATION ACT...

Page 627: ...point number M_ME_NC_1 M_ME_TC_1 and M_ME_TF_1 Station interrogation Clock synchronization Clock synchronization optional see Clause 7 6 Command transmission Direct command transmission Direct setpoint command transmission Select and execute command Select and execute setpoint command C_SE ACTTERM used No additional definition Short pulse duration duration determined by a system parameter in the o...

Page 628: ...ences of events Transmission of sequences of recorded analog values File transfer in control direction Transparent file Background scan Background scan Acquisition of transmission delay Acquisition of transmission delay Definition of time outs Maximum range of values for all time outs 1 to 255 s accuracy 1 s Maximum number of outstanding I format APDUs k and latest acknowledge APDUs w PARAMETER DE...

Page 629: ...et as determined by the Internet Architecture Board IAB It offers a broad spectrum of actual standards used in the Inter net The suitable selection of documents from RFC 2200 defined in this standard for given projects has to be chosen by the user of this standard Ethernet 802 3 Serial X 21 interface Other selection s from RFC 2200 list below if selected E 1 2 POINT LIST The IEC 60870 5 104 data p...

Page 630: ...E 10 M60 Motor Protection System GE Multilin E 1 IEC 60870 5 104 PROTOCOL APPENDIX E E ...

Page 631: ...in addition to the Highest DNP Levels Supported the complete list is described in the attached table Binary Inputs Object 1 Binary Input Changes Object 2 Binary Outputs Object 10 Control Relay Output Block Object 12 Binary Counters Object 20 Frozen Counters Object 21 Counter Change Event Object 22 Frozen Counter Event Object 23 Analog Inputs Object 30 Analog Input Changes Object 32 Analog Deadband...

Page 632: ...ary Outputs Never Always Sometimes Configurable SELECT OPERATE Never Always Sometimes Configurable DIRECT OPERATE Never Always Sometimes Configurable DIRECT OPERATE NO ACK Never Always Sometimes Configurable Count 1 Never Always Sometimes Configurable Pulse On Never Always Sometimes Configurable Pulse Off Never Always Sometimes Configurable Latch On Never Always Sometimes Configurable Latch Off Ne...

Page 633: ...nfigurable Only certain objects Sometimes attach explanation ENABLE DISABLE unsolicited Function codes supported Sends Static Data in Unsolicited Responses Never When Device Restarts When Status Flags Change No other options are permitted Default Counter Object Variation No Counters Reported Configurable attach explanation Default Object 20 Default Variation 1 Point by point list attached Counters...

Page 634: ...p 17 28 index 3 Binary Input Change with Relative Time 1 read 06 no range or all 07 08 limited quantity 10 0 Binary Output Status Variation 0 is used to request default variation 1 read 00 01 start stop 06 no range or all 07 08 limited quantity 17 28 index 2 Binary Output Status 1 read 00 01 start stop 06 no range or all 07 08 limited quantity 17 28 index 129 response 00 01 start stop 17 28 index ...

Page 635: ...ariation 0 is used to request default variation 1 read 06 no range or all 07 08 limited quantity 1 32 Bit Counter Change Event 1 read 06 no range or all 07 08 limited quantity 129 response 130 unsol resp 17 28 index 2 16 Bit Counter Change Event 1 read 06 no range or all 07 08 limited quantity 129 response 130 unsol resp 17 28 index 5 32 Bit Counter Change Event with Time 1 read 06 no range or all...

Page 636: ...sponse 130 unsol resp 17 28 index 3 32 Bit Analog Change Event with Time 1 read 06 no range or all 07 08 limited quantity 129 response 130 unsol resp 17 28 index 4 16 Bit Analog Change Event with Time 1 read 06 no range or all 07 08 limited quantity 129 response 130 unsol resp 17 28 index 5 short floating point Analog Change Event without Time 1 read 06 no range or all 07 08 limited quantity 129 r...

Page 637: ...close 30 abort 5b free format 129 response 130 unsol resp 5b free format 5 File transfer 1 read 2 write 5b free format 129 response 130 unsol resp 5b free format 6 File transfer status 129 response 130 unsol resp 5b free format 7 File descriptor 28 get file info 5b free format 129 response 130 unsol resp 5b free format 80 1 Internal Indications 1 read 00 01 start stop index 7 129 response 00 01 st...

Page 638: ...med on a binary counter point the frozen value is available in the corresponding frozen counter point BINARY INPUT POINTS Static Steady State Object Number 1 Change Event Object Number 2 Request Function Codes supported 1 read 22 assign class Static Variation reported when variation 0 requested 2 Binary Input with status Configurable Change Event Variation reported when variation 0 requested 2 Bin...

Page 639: ...al Input 15 15 Virtual Input 16 16 Virtual Input 17 17 Virtual Input 18 18 Virtual Input 19 19 Virtual Input 20 20 Virtual Input 21 21 Virtual Input 22 22 Virtual Input 23 23 Virtual Input 24 24 Virtual Input 25 25 Virtual Input 26 26 Virtual Input 27 27 Virtual Input 28 28 Virtual Input 29 29 Virtual Input 30 30 Virtual Input 31 31 Virtual Input 32 32 Virtual Input 33 33 Virtual Input 34 34 Virtu...

Page 640: ...eze and clear noack 22 assign class Static Variation reported when variation 0 requested 1 32 Bit Binary Counter with Flag Change Event Variation reported when variation 0 requested 1 32 Bit Counter Change Event without time Change Event Buffer Size 10 Default Class for all points 3 FROZEN COUNTERS Static Steady State Object Number 21 Change Event Object Number 23 Request Function Codes supported ...

Page 641: ... Input points are in the same units as the Analog Input quantity For example an Analog Input quantity measured in volts has a corresponding deadband in units of volts This is in conformance with DNP Technical Bul letin 9809 001 Analog Input Reporting Deadband Relay settings are available to set default deadband values according to data type Deadbands for individual Analog Input Points can be set u...

Page 642: ...F 12 M60 Motor Protection System GE Multilin F 2 DNP POINT LISTS APPENDIX F F ...

Page 643: ...configured on the UR device for successful authentication and the shortname is a short optional alias that can be used in place of the IP address client 10 0 0 2 24 secret testing123 shortname private network 1 5 In the Path_to_Radius etc raddb folder create a file called dictionary ge and add the following content GE VSAs VENDOR GE 2910 Management authorization BEGIN VENDOR GE Role ID ATTRIBUTE G...

Page 644: ...G 2 M60 Motor Protection System GE Multilin G 1 RADIUS SERVER CONFIGURATION APPENDIX G G ...

Page 645: ... May 2004 URX 136 1601 0108 H1 4 2x 30 June 2004 URX 145 1601 0108 H2 4 2x 23 July 2004 URX 151 1601 0108 J1 4 4x 15 September 2004 URX 156 1601 0108 K1 4 6x 15 February 2005 URX 176 1601 0108 L1 4 8x 05 August 2005 URX 202 1601 0108 M1 4 9x 15 December 2005 URX 208 1601 0108 M2 4 9x 27 February 2006 URX 214 1601 0108 N1 5 0x 31 March 2006 URX 217 1601 0108 N2 5 0x 26 May 2006 URX 220 1601 0108 P1...

Page 646: ... PRP and Appendix B Modbus table and F627 and F628 enumeration tables Add Added CT failure feature to Table 2 2 Other Device Functions to chapter 5 Settings Control Elements Monitoring Elements CT Failure Detector and Appendix B table F124 List of Elements as bitmask element 246 CT Failure 1 1 1 1 Add Added General Cautions and Warnings to section 1 1 1 1 5 1 5 Update Revised section 1 3 1 on syst...

Page 647: ...h day hour from Real Time Clock menu 5 5 40 Add Added submenus Precision Time Protocol SNTP Protocol and Local Time and Synchronizing Source settings to Real Time Clock menu 5 5 41 Add Added new Precision Time Protocol 1588 menu and setting descriptions 5 5 Update Changed Communication to Real Time Clock in SNTP protocol settings path Moved SNTP Protocol menu and settings descriptions to Real Time...

Page 648: ...curity alarm settings 10 10 2 Add Added Figure 10 1 Security Settings Menu A A Add Added Flexanalog item PTP IRIG B Delta to Table A 1 FlexAnalog Data Items B 8 B 8 Update Updated Modbus memory map table to include port 0 for Modbus slave address TCP DNP HTTP TFTP MMS and removed references to COM 1 RS485 port C 23 C 23 Update Updated tables in sections C 6 3 ACSI Services Conformance Statement an...

Page 649: ...or FDH Fault Detector high set FDL Fault Detector low set FLA Full Load Current FO Fiber Optic FREQ Frequency FSK Frequency Shift Keying FTP File Transfer Protocol FxE FlexElement FWD Forward G Generator GE General Electric GND Ground GNTR Generator GOOSE General Object Oriented Substation Event GPS Global Positioning System HARM Harmonic Harmonics HCT High Current Time HGF High Impedance Ground F...

Page 650: ... Terminal Unit RX Rx Receive Receiver s second S Sensitive SAT CT Saturation SBO Select Before Operate SCADA Supervisory Control and Data Acquisition SEC Secondary SEL Select Selector Selection SENS Sensitive SEQ Sequence SIR Source Impedance Ratio SNTP Simple Network Time Protocol SRC Source SSB Single Side Band SSEL Session Selector STATS Statistics SUPN Supervision SUPV Supervise Supervision SV...

Page 651: ...ed with all transportation charges prepaid to an authorized service centre or the factory Repairs or replacement under war ranty 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 ...

Page 652: ...H 8 M60 Motor Protection System GE Multilin H 3 WARRANTY APPENDIX H H ...

Page 653: ...6 20 B BANKS 5 6 5 97 5 98 BATTERY disposal 9 5 failure 7 7 replace 9 3 BATTERY FAILURE 7 7 BINARY INPUT POINTS F 8 BINARY OUTPUT POINTS F 9 BLOCK DIAGRAM 1 3 BLOCK SETTING 5 5 BREAKER CONTROL control of 2 breakers 4 24 description 4 23 dual breaker logic 5 106 5 107 FlexLogic operands 5 121 Modbus registers B 31 settings 5 104 BREAKER FAILURE description 5 199 determination 5 200 FlexLogic operan...

Page 654: ...6 ALGORITHM B 2 CRITICAL FAILURE RELAY 2 24 3 9 CSA APPROVAL 2 28 CT BANKS settings 5 97 CT FAILURE logic 5 245 settings 5 244 CT INPUTS 3 11 5 6 5 97 CT WIRING 3 11 CURRENT BANK 5 97 CURRENT DIFFERENTIAL Modbus registers B 17 CURRENT METERING actual values 6 18 Modbus registers B 15 specifications 2 21 CURRENT UNBALANCE 6 17 logic 5 164 Modbus registers B 37 B 52 settings 5 163 CURVES definite ti...

Page 655: ... 4 EMAIL ADDRESS FOR SUPPORT 1 2 ENERGY METERING actual values 6 21 Modbus registers B 16 B 17 specifications 2 21 ENERGY METERING CLEARING 5 25 7 2 ENERVISTA UR SETUP creating a site list 4 1 event recorder 4 2 firmware upgrades 4 2 installation 1 5 introduction 4 1 oscillography 4 2 overview 4 1 requirements 1 5 EQUATIONS definite time curve 5 195 5 207 FlexCurve 5 195 I t curves 5 195 IAC curve...

Page 656: ...or GROUND TOC GROUND TOC FlexLogic operands 5 121 logic 5 196 Modbus registers B 35 settings 5 196 specifications 2 17 GROUPED ELEMENTS 5 140 GSSE 5 258 5 259 5 260 6 8 H HALF DUPLEX B 1 HELP 1 2 HOT COLD SAFE STALL RATIO 5 151 HTTP PROTOCOL 5 55 I I2T CURVES 5 195 IAC CURVES 5 194 IEC 60870 5 103 settings 5 59 IEC 60870 5 103 PROTOCOL interoperability document D 1 IEC 60870 5 104 PROTOCOL interop...

Page 657: ... recorder B 7 exception responses B 5 execute operation B 4 flex state parameters 5 85 function code 03 04h B 3 function code 05h B 4 function code 06h B 4 function code 10h B 5 introduction B 1 memory map data formats B 74 obtaining files B 6 oscillography B 6 passwords B 7 read write settings actual values B 3 settings 5 34 5 64 store multiple settings B 5 store single setting B 4 supported func...

Page 658: ...ts 5 256 OVERCURRENT CURVE TYPES 5 191 OVERCURRENT CURVES definite time 5 195 FlexCurves 5 195 I2T 5 195 IAC 5 194 IEC 5 193 IEEE 5 191 OVERFREQUENCY FlexLogic operands 5 122 logic 5 226 settings 5 226 specifications 2 19 OVERFRQUENCY Modbus registers B 37 OVERVOLTAGE auxiliary 2 19 5 214 negative sequence 5 212 negative sequence 2 19 neutral 2 19 5 211 phase 2 19 5 210 P PANEL CUTOUT 3 1 3 2 PARA...

Page 659: ... DEVICES actual values 6 7 device ID 5 258 error messages 7 9 FlexLogic operands 5 126 Modbus registers B 13 B 18 B 66 B 70 settings 5 257 statistics 6 8 REMOTE DPS INPUTS actual values 6 5 settings 5 259 REMOTE INPUTS actual values 6 5 FlexLogic operands 5 126 Modbus registers B 13 B 18 B 66 settings 5 258 specifications 2 22 REMOTE OUTPUTS DNA 1 bit pair 5 259 Modbus registers B 68 UserSt 1 bit ...

Page 660: ...ATOR DIFFERENTIAL actual values 6 17 characteristic 5 171 description 5 171 FlexLogic operands 5 124 logic 5 172 Modbus registers B 14 B 37 settings 5 171 specifications 2 17 STATUS INDICATORS 4 14 4 16 STORAGE TEMPERATURE 2 26 SUB HARMONIC STATOR GROUND FAULT FlexLogic operands 5 124 SUMMATOR Modbus registers B 44 B 52 SUPPORT TECHNICAL 1 2 SURGE IMMUNITY 2 27 SYMMETRICAL COMPONENTS METERING 6 15...

Page 661: ... 87 invoking and scrolling 5 85 Modbus registers B 26 B 32 settings 5 85 5 87 specifications 2 20 USER PROGRAMMABLE FAULT REPORT actual values 6 25 clearing 5 25 7 2 Modbus registers B 18 settings 5 69 USER PROGRAMMABLE LEDs custom labeling 4 22 defaults 4 16 description 4 15 4 16 Modbus registers B 29 settings 5 75 specifications 2 20 USER PROGRAMMABLE PUSHBUTTONS FlexLogic operands 5 127 Modbus ...

Page 662: ...x M60 Motor Protection System GE Multilin INDEX ...

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