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GE F60 UR Series, Instruction Manual

The GE F60 UR Series Instruction Manual is available for free download on our website. This comprehensive manual provides detailed instructions and guidelines for operating and maintaining your GE F60 UR Series product. Find the manual you need on manualshive.com and make the most of your device's features.

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GE Multilin

F60 Feeder Protection System

5-185

5 SETTINGS

5.6 CONTROL ELEMENTS

5

Some faults in overhead distribution feeders are characterized by low fault current due to high ground resistance. If the fault
current is in the order of expected unbalance load or less, it cannot be reliably detected by overcurrent protection. These
faults are classified as high-impedance (Hi-Z) faults. Since a Hi-Z fault is not accompanied by excessive current, it is gener-
ally not dangerous to the electrical installation except for some damage to the overhead conductor at the fault location.
However, an undetected Hi-Z fault is a risk to people and property as well as having a potential to evolve into a full-blown
fault.

The following event types are associated with Hi-Z faults. It is assumed that for all cases that ground is involved.

High impedance fault: a fault with fault impedance sufficiently high such that it is not detected by overcurrent protection

High impedance, downed conductor fault: a high impedance fault for which the primary conductor is no longer intact on
pole top insulators, but instead is in contact with earth or a grounded object

Arcing fault: any high impedance fault which exhibits arcing

Combinations of these events are possible: for example, an arcing high impedance, downed conductor fault. The Hi-Z ele-
ment is intended to detect high impedance faults that arc and to differentiate those that are downed conductors from those
that are not. It should be noted that no known technology can detect all Hi-Z faults.

The Hi-Z element was primarily designed for solidly grounded systems. The similar Hi-Z element in the DFM200 relay has
been tested with some success on impedance grounded systems as well. However, there are no guarantees of certain
operation of the high impedance fault detection element on non-solidly grounded systems.

The Hi-Z data collection consists of RMS Data Capture and Hi-Z Data capture:

RMS Data Capture: 

The RMS data captures are triggered by two-cycle Hi-Z overcurrent conditions, loss of load con-

ditions, and high arc confidence conditions. Captures triggered by loss of load and high arc confidence conditions are
saved to a temporary capture table, and deleted if the event does not result in an Arcing or Downed Conductor condi-
tion. The relay maintains a history of four captures and utilizes a combination of age, priority and access for determin-
ing which capture to save.

The RMS data capture contains the two-cycle RMS values for the voltage and current for each of the phases and cur-
rent for the neutral channel. The capture frequency is half the system frequency. Each capture contains 1800 points.

High-Z Data Capture

: Hi-Z Data Captures are triggered and maintained in an identical manner as RMS Data Cap-

tures. The relay maintains four captures of 300 records each. The capture frequency is 1 Hz and the data collected is
defined in the following two tables.

MESSAGE

HI-Z NEUTRAL OC MIN

PICKUP: 1.00 

pu

Range: 0.01 to 10.00 pu in steps of 0.01

MESSAGE

HI-Z PHASE RATE OF

CHANGE: 150 A/2cycle

Range: 1 to 999 A/2cycle in steps of 1

MESSAGE

HI-Z NEUTRAL RATE OF

CHANGE: 150 A/2cycle

Range: 1 to 999 A/2cycle in steps of 1

MESSAGE

HI-Z LOSS OF LOAD

THRESHOLD: 15%

Range: 5 to 100% in steps of 1

MESSAGE

HI-Z 3-PHASE EVENT

THRESHOLD: 25 

A

Range: 1 to 1000 A in steps of 1

MESSAGE

HI-Z VOLTAGE SUPV

THRESHOLD: 5%

Range: 0 (off) to 100% in steps of 1

MESSAGE

HI-Z VOLTAGE SUPV

DELAY: 60 

cycles

Range: 0 to 300 cycles in steps of 2

MESSAGE

HI-Z EVEN HARMONIC

RESTRAINT: 20%

Range: 0 to 100% in steps of 1

MESSAGE

HI-Z TARGET:

Self-reset

Range: Self-reset, Latched, Disabled

MESSAGE

HI-Z EVENTS:

Disabled

Range: Disabled, Enabled

Summary of Contents for F60 UR Series

Page 1: ...tilin GE Multilin 215 Anderson Avenue Markham Ontario Canada L6E 1B3 Tel 905 294 6222 Fax 905 201 2098 Internet http www GEmultilin com g GE Industrial Systems Title Page IISO9001 2000 G E M ULTILI N R E GISTERE D GE Multilin s Quality Management System is registered to ISO9001 2000 QMI 005094 UL A3775 1601 0093 S3 LISTED 52TL IND CONT EQ E83849 ...

Page 2: ......

Page 3: ... module label colors are the same In the event that there is a mismatch between the CPU and CT VT module the relay will not function and a DSP ERROR or HARDWARE MISMATCH error will be displayed All other input output modules are compatible with the new hardware With respect to the firmware firmware versions 4 0x and higher are only compatible with the new CPU and CT VT mod ules Previous versions o...

Page 4: ......

Page 5: ... 5 4 RELAY ACTIVATION 1 17 1 5 5 RELAY PASSWORDS 1 18 1 5 6 FLEXLOGIC CUSTOMIZATION 1 18 1 5 7 COMMISSIONING 1 19 2 PRODUCT DESCRIPTION 2 1 INTRODUCTION 2 1 1 OVERVIEW 2 1 2 1 2 ORDERING 2 2 2 1 3 REPLACEMENT MODULES 2 4 2 2 SPECIFICATIONS 2 2 1 PROTECTION ELEMENTS 2 7 2 2 2 USER PROGRAMMABLE ELEMENTS 2 10 2 2 3 MONITORING 2 11 2 2 4 METERING 2 11 2 2 5 INPUTS 2 12 2 2 6 POWER SUPPLY 2 13 2 2 7 OU...

Page 6: ...1 4 1 2 CREATING A SITE LIST 4 1 4 1 3 ENERVISTA UR SETUP OVERVIEW 4 1 4 1 4 ENERVISTA UR SETUP MAIN WINDOW 4 3 4 1 5 SETTINGS TEMPLATES 4 3 4 1 6 SECURING AND LOCKING FLEXLOGIC EQUATIONS 4 8 4 1 7 SETTINGS FILE TRACEABILITY 4 10 4 2 FACEPLATE INTERFACE 4 2 1 FACEPLATE 4 13 4 2 2 LED INDICATORS 4 14 4 2 3 CUSTOM LABELING OF LEDS 4 17 4 2 4 DISPLAY 4 23 4 2 5 BREAKER CONTROL 4 23 4 2 6 KEYPAD 4 24 ...

Page 7: ...ENCE CURRENT 5 132 5 5 9 BREAKER FAILURE 5 138 5 5 10 VOLTAGE ELEMENTS 5 147 5 5 11 SENSITIVE DIRECTIONAL POWER 5 155 5 6 CONTROL ELEMENTS 5 6 1 OVERVIEW 5 158 5 6 2 SETTING GROUPS 5 158 5 6 3 SELECTOR SWITCH 5 159 5 6 4 UNDERFREQUENCY 5 165 5 6 5 OVERFREQUENCY 5 166 5 6 6 FREQUENCY RATE OF CHANGE 5 167 5 6 7 SYNCHROCHECK 5 169 5 6 8 AUTORECLOSE 5 173 5 6 9 DIGITAL ELEMENTS 5 179 5 6 10 DIGITAL CO...

Page 8: ...6 12 6 3 2 SOURCES 6 15 6 3 3 SENSITIVE DIRECTIONAL POWER 6 21 6 3 4 SYNCHROCHECK 6 21 6 3 5 TRACKING FREQUENCY 6 21 6 3 6 FREQUENCY RATE OF CHANGE 6 22 6 3 7 FLEXELEMENTS 6 22 6 3 8 IEC 61580 GOOSE ANALOG VALUES 6 23 6 3 9 WATTMETRIC GROUND FAULT 6 23 6 3 10 TRANSDUCER INPUTS OUTPUTS 6 23 6 4 RECORDS 6 4 1 FAULT REPORTS 6 24 6 4 2 EVENT RECORDS 6 24 6 4 3 OSCILLOGRAPHY 6 25 6 4 4 DATA LOGGER 6 25...

Page 9: ...3 DATA LINK LAYER B 1 B 1 4 CRC 16 ALGORITHM B 2 B 2 MODBUS FUNCTION CODES B 2 1 SUPPORTED FUNCTION CODES B 3 B 2 2 READ 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 ...

Page 10: ... ICD FILE WITH ENERVISTA UR SETUP C 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 5 104 COMMUNICATIONS D 1 IEC 60870 5 104 D 1 1 INTEROPERABI...

Page 11: ...ilin include the serial number located on the rear nameplate For product information instruction manual updates and the latest software updates please visit the GE Multilin web site at http www GEmultilin com If there is any noticeable physical damage or any of the contents listed are missing please contact GE Multilin immediately GE MULTILIN CONTACT INFORMATION AND CALL CENTER FOR PRODUCT SUPPORT...

Page 12: ...abling and auxiliary equipment installed in stations can be even further reduced to 20 to 70 of the levels common in 1990 to achieve large cost reductions This requires placing even more functions within the IEDs Users of power equipment are also interested in reducing cost by improving power quality and personnel productivity and as always in increasing system reliability and efficiency These obj...

Page 13: ... device Virtual outputs can also serve as virtual inputs to FlexLogic equations The analog inputs and outputs are signals that are associated with transducers such as Resistance Temperature Detec tors RTDs The CT and VT inputs refer to analog current transformer and voltage transformer signals used to monitor AC power lines The UR series relays support 1 A and 5 A CTs The remote inputs and outputs...

Page 14: ...etering input output control hmi communications or any functional entity in the system Employing OOD OOP in the software architecture of the F60 achieves the same features as the hardware architecture modularity scalability and flexibility The application software for any UR series device for example feeder protection transformer protection distance protection is constructed by combining objects f...

Page 15: ...ded 200 MB of available space on system drive and 200 MB of available space on installation drive Video capable of displaying 800 x 600 or higher in high color mode 16 bit color RS232 and or Ethernet port for communications to the relay The following qualified modems have been tested to be compliant with the F60 and the EnerVista UR Setup software US Robotics external 56K FaxModem 5686 US Robotics...

Page 16: ...ftware items for the F60 6 EnerVista Launchpad will obtain the software from the Web or CD and automatically start the installation program 7 Select the complete path including the new directory name where the EnerVista UR Setup will be installed 8 Click on Next to begin the installation The files will be installed in the directory indicated and the installation program will automatically create i...

Page 17: ...he back of the device The faceplate RS232 port is intended for local use and is not described in this section see the Using the Quick Connect Feature section for details on configuring the RS232 port A GE Multilin F485 converter or compatible RS232 to RS485 converter is will be required Refer to the F485 instruction manual for additional details 1 Verify that the latest version of the EnerVista UR...

Page 18: ... ETHERNET COMMUNICATIONS Before starting verify that the Ethernet network cable is properly connected to the Ethernet port on the back of the relay To setup the relay for Ethernet communications it will be necessary to define a Site then add the relay as a Device at that site 1 Verify that the latest version of the EnerVista UR Setup software is installed available from the GE EnerVista CD or onli...

Page 19: ...up values entered in the previous steps correspond to the relay setting values 12 Click OK when the relay order code has been received The new device will be added to the Site List window or Online window located in the top left corner of the main EnerVista UR Setup window The Site Device has now been configured for Ethernet communications Proceed to the Connecting to the F60 section to begin comm...

Page 20: ...the F60 from a laptop through Ethernet first assign an IP address to the relay from the front panel keyboard 1 Press the MENU key until the SETTINGS menu is displayed 2 Navigate to the SETTINGS Ö PRODUCT SETUP ÖØ COMMUNICATIONS ÖØ NETWORK Ö IP ADDRESS setting 3 Enter an IP address of 1 1 1 1 and select the ENTER key to save the value 4 In the same menu select the SUBNET IP MASK setting 5 Enter a s...

Page 21: ...esktop 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 provided and click the Properties button 4 Click on the Use the following IP address box ...

Page 22: ... 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 milli seconds Minimum 0ms Maximum 0ms Average 0 ms Pinging 1 1 1 1 with 32 bytes of data Verify...

Page 23: ...on specific DNS suffix IP Address 1 1 1 2 Subnet Mask 255 0 0 0 Default Gateway C WINNT It may be necessary to restart the laptop for the change in IP address to take effect Windows 98 or NT Before using the Quick Connect feature through the Ethernet port it is necessary to disable any configured proxy settings in Internet Explorer 1 Start the Internet Explorer software 2 Select the Tools Internet...

Page 24: ...indows 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 below If this computer is used to connect ...

Page 25: ...ed printed or changed according to user specifications Refer to chapter 4 in this manual and the EnerVista UR Setup Help File for more information about the using the EnerVista UR Setup software interface QUICK ACTION HOT LINKS The EnerVista UR Setup software has several new quick action buttons that provide users with instant access to several functions that are often performed when using F60 rel...

Page 26: ...e 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 F60 rear communications port The converter termi nals GND are connected to the F60 communication module COM terminals Refer to the CPU communica tions ports section in chapter 3 ...

Page 27: ... 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 indicated by single scroll bar characters The header display pages represent the highest level of the hierarchy and the sub header display pages fall below this level The MESSAGE UP and DOWN keys move within a group ...

Page 28: ... are two user password security access levels COMMAND and SETTING 1 COMMAND The COMMAND access level restricts the user from making any settings changes but allows the user to perform the fol lowing operations operate breakers via faceplate keypad change state of virtual inputs clear event records clear oscillography records operate user programmable pushbuttons 2 SETTING The SETTING access level ...

Page 29: ...and LED indications 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 verifi...

Page 30: ...1 20 F60 Feeder Protection System GE Multilin 1 5 USING THE RELAY 1 GETTING STARTED 1 ...

Page 31: ...or the programming of settings and the monitoring of actual val ues A variety of communications modules are available Two rear RS485 ports allow independent access by operating and engineering staff All serial ports use the Modbus RTU protocol The RS485 ports may be connected to system computers with baud rates up to 115 2 kbps The RS232 port has a fixed baud rate of 19 2 kbps Optional communicati...

Page 32: ...UNCTION Breaker arcing current I2 t Disconnect switches 8 Non volatile latches Breaker control 2 Event recorder Non volatile selector switch Breaker flashover Fault detector and fault report Oscillography Breaker restrike Fault locator Setting groups 6 Cold load pickup 2 FlexElements 8 Time synchronization over SNTP Contact inputs up to 96 FlexLogic equations Transducer inputs and outputs Contact ...

Page 33: ...al inputs 6B 6B 6B 6B 6B 2 Form A voltage with optional current 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 digi...

Page 34: ...s 8 digital inputs 6B 6B 6B 2 Form A voltage with optional current and 4 Form C outputs 4 digital inputs 6C 6C 6C 8 Form C outputs 6D 6D 6D 16 digital inputs 6E 6E 6E 4 Form C outputs 8 digital inputs 6F 6F 6F 8 Fast Form C outputs 6G 6G 6G 4 Form A voltage with optional current outputs 8 digital inputs 6H 6H 6H 6 Form A voltage with optional current outputs 4 digital inputs 6K 6K 6K 4 Form C and ...

Page 35: ...ring outputs 6A 2 Form A voltage with optional current and 2 Form C outputs 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 digit...

Page 36: ... with optional current outputs 4 digital inputs 6K 4 Form C and 4 Fast Form C outputs 6L 2 Form A current with optional voltage and 2 Form C outputs 8 digital inputs 6M 2 Form A current with optional voltage and 4 Form C outputs 4 digital inputs 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 monit...

Page 37: ...y 0 00 to 600 00 s in steps of 0 01 Operate time 16 ms at 3 pickup at 60 Hz Phase Ground IOC 20 ms at 3 pickup at 60 Hz Neutral IOC Timing accuracy Operate at 1 5 pickup 3 or 4 ms whichever is greater NEGATIVE SEQUENCE TOC Pickup level 0 000 to 30 000 pu in steps of 0 001 Dropout level 97 to 98 of pickup Level accuracy 0 5 of reading or 0 4 of rated whichever is greater from 0 1 to 2 0 x CT rating...

Page 38: ... whichever is greater Operate time 30 ms at 60 Hz SENSITIVE DIRECTIONAL POWER Measured power 3 phase true RMS Number of stages 2 Characteristic angle 0 to 359 in steps of 1 Calibration angle 0 00 to 0 95 in steps of 0 05 Minimum power 1 200 to 1 200 pu in steps of 0 001 Pickup level accuracy 1 or 0 001 pu whichever is greater Hysteresis 2 or 0 001 pu whichever is greater Pickup delay 0 to 600 00 s...

Page 39: ...r is greater 95 settling time for df dt 24 cycles Operate time 12 cycles at 2 pickup 8 cycles at 3 pickup 5 cycles at 5 pickup BREAKER FAILURE Mode 1 pole 3 pole Current supervision phase neutral current Current supv pickup 0 001 to 30 000 pu in steps of 0 001 Current supv dropout 97 to 98 of pickup Current supv accuracy 0 1 to 2 0 CT rating 0 75 of reading or 2 of rated whichever is greater above...

Page 40: ...hrough 1 of pickup Operate points 80 1 through 20 of pickup Time delay 0 to 65535 ms in steps of 1 FLEX STATES Number up to 256 logical variables grouped under 16 Modbus addresses Programmability any logical variable contact or virtual input FLEXELEMENTS Number of elements 8 Operating signal any analog actual value or two values in differential mode Operating signal mode signed or absolute value O...

Page 41: ...ents Data storage in non volatile memory 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 NN days 16 channels for NN days 60 minute rate 01 channel for NN days 16 channels for NN days FAULT...

Page 42: ...rents Accuracy 2 0 2 2 5 INPUTS AC CURRENT CT rated primary 1 to 50000 A CT rated secondary 1 A or 5 A by connection Nominal frequency 20 to 65 Hz Relay burden 0 2 VA at rated secondary Conversion range Standard CT 0 02 to 46 CT rating RMS symmetrical Sensitive Ground CT module 0 002 to 4 6 CT rating RMS symmetrical HI Z CT module 0 002 to 4 6 CT rating RMS symmetri cal Current withstand 20 ms at ...

Page 43: ... No Data rate 64 or 128 kbps CRC 32 bit 2 2 6 POWER SUPPLY LOW RANGE Nominal DC voltage 24 to 48 V Min max DC voltage 20 60 V Voltage loss hold up 20 ms duration at nominal NOTE Low range is DC only HIGH RANGE Nominal DC voltage 125 to 250 V Min max DC voltage 88 300 V Nominal AC voltage 100 to 240 V at 50 60 Hz Min max AC voltage 88 265 V at 25 to 100 Hz Voltage loss hold up 200 ms duration at no...

Page 44: ...o 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 driving signal 90 to 90 pu in steps of 0 001 ETHERNET SWITCH HIGH VOLTAGE TYPE 2S Nominal DC voltage 110 to 240 V DC Minimum DC voltage 88 V DC Maximum DC voltage 300 V DC Input Current 0 9 A DC maximum Nominal AC voltage 100 to 240 V AC 0 26 to 0 16 A 26 to ...

Page 45: ...al power budget between two type 2T or 2S modules using a single fiber cable is To calculate the maximum fiber length divide the worst case opti cal power budget by the cable attenuation per unit distance speci fied in the manufacturer data sheets For example typical attenuation for 62 5 125 μm glass fiber optic cable is approxi mately 2 8 dB per km In our example this would result in the fol lowi...

Page 46: ...tude Up to 2000 m Installation Category II INTERFACE TYPE TYPICAL DISTANCE RS422 1200 m G 703 100 m EMITTER FIBER TYPE TRANSMIT POWER RECEIVED SENSITIVITY POWER BUDGET 820 nm LED Multimode 20 dBm 30 dBm 10 dB 1300 nm LED Multimode 21 dBm 30 dBm 9 dB 1300 nm ELED Singlemode 23 dBm 32 dBm 9 dB 1300 nm Laser Singlemode 1 dBm 30 dBm 29 dB 1550 nm Laser Singlemode 5 dBm 30 dBm 35 dB EMITTER FIBER TYPE ...

Page 47: ...bration test sinusoidal IEC 60255 21 1 Shock and bump IEC 60255 21 2 Seismic IEC 60255 21 3 IEEE C37 98 Cold IEC 60028 2 1 16 h at 40 C Dry heat IEC 60028 2 2 16 h at 85 C Type test report available upon request 2 2 12 PRODUCTION TESTS THERMAL Products go through an environmental test based upon an Accepted Quality Level AQL sampling process 2 2 13 APPROVALS APPROVALS UL Listed for the USA and Can...

Page 48: ...2 18 F60 Feeder Protection System GE Multilin 2 2 SPECIFICATIONS 2 PRODUCT DESCRIPTION 2 ...

Page 49: ...mited rear depth There is also a removable dust cover that fits over the faceplate which must be removed when attempting to access the keypad or RS232 communications port 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 ...

Page 50: ...th There is also a removable dust cover that fits over the faceplate which must be removed when attempting to access the keypad or RS232 communications port 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 equip...

Page 51: ...GE Multilin F60 Feeder Protection System 3 3 3 HARDWARE 3 1 DESCRIPTION 3 Figure 3 4 F60 VERTICAL MOUNTING AND DIMENSIONS e UR SERIES UR SERIES ...

Page 52: ...3 4 F60 Feeder Protection System GE Multilin 3 1 DESCRIPTION 3 HARDWARE 3 Figure 3 5 F60 VERTICAL SIDE MOUNTING INSTALLATION ...

Page 53: ...ctrostatic discharge protection for example a static strap must be used when coming in con tact with modules while the relay is energized The relay being modular in design allows for the withdrawal and insertion of modules Modules must only be replaced with like modules in their original factory configured slots The enhanced faceplate can be opened to the left once the thumb screw has been removed...

Page 54: ...of the module to ensure that the same or replacement module is inserted into the correct slot Modules with current input provide automatic shorting of external CT circuits To properly insert a module ensure that the correct module type is inserted into the correct slot position The ejector inserter clips located at the top and at the bottom of each module must be in the disengaged position as the ...

Page 55: ...spect 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 for an example of rear terminal assignments NOTE X W V U T S P N M L K J H...

Page 56: ...3 8 F60 Feeder Protection System GE Multilin 3 1 DESCRIPTION 3 HARDWARE 3 Figure 3 10 EXAMPLE OF MODULES IN F AND H SLOTS ...

Page 57: ...2 M6 M3 M7 M4 M8 Optional 6C DIGITAL INPUTS OUTPUTS P1 P5 P2 P6 P3 P7 P4 P8 P7a P1a P2b P7c P1c P7b P1b P8c P8b P2c P8a P2a P4a P5b P4c P6b P3b P3a P6a P4b P5c P5a P3c P6c U6a U8a U5b U7b U5a U7a U6c U8c U5c U7c CONTACT INPUT U1a CONTACT INPUT U4c COMMON U5b COMMON U7b COMMON U1b COMMON U3b CONTACT INPUT U2a CONTACT INPUT U5a CONTACT INPUT U3c CONTACT INPUT U6a CONTACT INPUT U8a CONTACT INPUT U1c ...

Page 58: ...GE H8b 6C DIGITAL INPUTS OUTPUTS P1 P5 P2 P6 P3 P7 P4 P8 P7a P1a P2b P7c P1c P7b P1b P8c P8b P2c P8a P2a P4a P5b P4c P6b P3b P3a P6a P4b P5c P5a P3c P6c M7c M8c M8b M8a M5c M5b M5a M7b M7a M3c M4b M4a M4c M1c M2b M2a M6b M6a M6c M2c M1b M1a M3b M3a CURRENT INPUTS NOT USED 8Z IA IB IC IG IA5 IA1 IB5 IC5 IG5 IB1 IC1 IG1 CONNECTION AS REQUIRED OPEN DELTA VT CONNECTION ABC A B C POSITIVE WATTS 5 Amp C...

Page 59: ...contact input connections The power supply module provides 48 V DC power for dry contact input connections and a critical failure relay see the Typical wiring diagram earlier The critical failure relay is a form C device that will be 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 ...

Page 60: ...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 secondaries may be used CT VT modules with a sensitive ground input are also available The ground CT input of the sensitive ground modules is ten t...

Page 61: ...LOAD A B C N G Ground outside CT Source LOAD SHIELDED CABLE 996630A5 A B C Source To ground must be on load side Stress cone shields NOTE 1a 1b 1c 2a 2b 2c 3a 4a 5a 6a 7a 8a 3b 4b 5c 6c 7c 8c 3c 4c Current inputs 8F and 8G 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 Current inputs Not used 8Z module used for high impedance fault detect...

Page 62: ...ommon If the inputs must be isolated per row then two inputs per common return should be selected 4D module The tables and diagrams on the following pages illustrate the module types 6A etc and contact arrangements that may be ordered for the relay Since an entire row is used for a single contact output the name is assigned using the module slot position and row number However since there are two ...

Page 63: ...xx Von otherwise Cont Op xxx Voff Load I V b Current with optional voltage monitoring Current monitoring only Both voltage and current monitoring external jumper a b is required If Idc 80mA Cont Op xxx Ion otherwise Cont Op xxx Ioff Load I V If Idc 80mA Cont Op xxx Ion otherwise Cont Op xxx Ioff If Idc 1mA Cont Op xxx Von otherwise Cont Op xxx Voff Load c No monitoring a b c a b c a b c a b c Load...

Page 64: ...symbol appears substitute with the slot position of the module wherever a number sign appears substitute the contact number When current monitoring is used to seal in the form A and solid state relay contact outputs the Flex Logic operand driving the contact output should be given a reset delay of 10 ms to prevent damage of the output contact in situations when the element initiating the contact o...

Page 65: ... A 5a 5c 2 Inputs 5 Form C 5a 5c 2 Inputs 6 Form A 6a 6c 2 Inputs 6 Form C 6a 6c 2 Inputs 7a 7c 2 Inputs 7a 7c 2 Inputs 7a 7c 2 Inputs 7a 7c 2 Inputs 8a 8c 2 Inputs 8a 8c 2 Inputs 8a 8c 2 Inputs 8a 8c 2 Inputs 6U MODULE 67 MODULE 4A MODULE 4B MODULE TERMINAL ASSIGNMENT OUTPUT OR INPUT TERMINAL ASSIGNMENT OUTPUT TERMINAL ASSIGNMENT OUTPUT TERMINAL ASSIGNMENT OUTPUT 1 Form A 1 Form A 1 Not Used 1 No...

Page 66: ...3 18 F60 Feeder Protection System GE Multilin 3 2 WIRING 3 HARDWARE 3 Figure 3 19 DIGITAL INPUT OUTPUT MODULE WIRING 1 of 2 842762A2 CDR ...

Page 67: ...Protection System 3 19 3 HARDWARE 3 2 WIRING 3 Figure 3 20 DIGITAL INPUT OUTPUT MODULE WIRING 2 of 2 CORRECT POLARITY MUST BE OBSERVED FOR ALL CONTACT INPUT AND SOLID STATE OUTPUT CON NECTIONS FOR PROPER FUNCTIONALITY CAUTION ...

Page 68: ...s 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 21 DRY AND WET CONTACT INPUT CONNECTIONS Wherever a tilde symbol appears substitute with the slot position of the module Contact outputs may be ordered as form a or form C The form A contacts may be connected for external circuit supervi sion These contacts are provided with voltage and current moni...

Page 69: ...ange 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 a...

Page 70: ...tions These connections are arranged as three ter minals per row with a total of eight rows A given row may 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 71: ...RS232 FACEPLATE PORT CONNECTION 3 2 8 CPU COMMUNICATION PORTS a OPTIONS In addition to the faceplate RS232 port the F60 provides two additional communication ports or a managed six port Ether net switch depending on the installed CPU module The CPU modules do not require a surge ground connection Table 3 3 CPU MODULE COMMUNICATIONS CPU TYPE COM1 COM2 9E RS485 RS485 9G 10Base F and 10Base T RS485 9...

Page 72: ... F COMMON D1a D2a D3a D4b D4a BNC BNC IRIG B output IRIG B input CPU 9M Co axial cable Co axial cable Shielded twisted pairs SM fiber optic cable Ground at remote device RS485 COM2 COMMON D1a D2a D3a D4b D4a BNC BNC IRIG B output IRIG B input CPU 9E RS485 COM2 COMMON D1b D2b D3b RS485 COM1 Ground at remote device Co axial cable Co axial cable Shielded twisted pairs NORMAL ALTERNATE COM1 100Base FL...

Page 73: ...t only Each relay should also be daisy chained to the next one in the link A maximum of 32 relays can be connected in this manner without exceeding driver capability For larger systems additional serial channels must be added It is also possible to use commercially available repeaters to increase the number of relays on a single channel to more than 32 Star or stub connections should be avoided en...

Page 74: ...e 10 Mbps rate is available for CPU modules 9G and 9H 100Mbps is available for modules 9H 9J 9K 9L 9M 9N 9P and 9R The 9H 9K 9M and 9R modules have a second pair of identical optical fiber transmitter and receiver for redundancy The optical fiber sizes supported include 50 125 µm 62 5 125 µm and 100 140 µm for 10 Mbps The fiber optic port is designed such that the response times will not vary for ...

Page 75: ...c locations can also be synchronized Figure 3 28 IRIG B CONNECTION The IRIG B repeater provides an amplified DC shift IRIG B signal to other equipment By using one IRIG B serial connec tion several UR series relays can be synchronized The IRIG B repeater has a bypass function to maintain the time signal even when a relay in the series is powered down Figure 3 29 IRIG B REPEATER Using an amplitude ...

Page 76: ...lays can be connected in a single ring Figure 3 30 DIRECT INPUT AND OUTPUT SINGLE CHANNEL CONNECTION The interconnection for dual channel Type 7 communications modules is shown below 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 t...

Page 77: ... C37 94 820 nm 128 kbps multi mode LED 2 channels 2S Six port managed Ethernet switch with high voltage power supply 2T Six port managed Ethernet switch with low voltage power supply 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 IEEE C37 94 820 nm 64 kbp...

Page 78: ...rface attenuators may be necessary to ensure that you do not exceed the maxi mum optical input power to the receiver 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 7W RS422 2 channels Table ...

Page 79: ...facturer to another Therefore it is not uncommon to see pin outs numbered TxA TxB RxA and RxB In such cases it can be assumed that A is equivalent to and B is equivalent to b G 703 SELECTION SWITCH PROCEDURES 1 Remove the G 703 module 7R or 7S The ejector inserter clips located at the top and at the bottom of each module must be pulled simultaneously in order to release the module for removal Befo...

Page 80: ...d be 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 back UR to UR connections For back to back connections set for octet timing S1 OFF and timing mode to internal tim...

Page 81: ...EMOTE 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 to the differential Manchester transmitter module Likewise G 7...

Page 82: ...iming ST connections However when used in two channel applications certain criteria must be followed since there is one clock input for the two RS422 channels The system will function cor rectly if the following connections are observed and your data module has a terminal timing feature Terminal timing is a common feature to most synchronous data units that allows the module to accept timing from ...

Page 83: ...of the Tx clock in the center of the Tx data bit Figure 3 43 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...

Page 84: ...maximum optical input power to the receiver Figure 3 44 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 shows the combined G 703 plus fiber interface configuration at 64 kbps The 7E 7F 7G 7Q and 75 mod ules are used in configurations where channel 1 is employed v...

Page 85: ...is repeated 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 64 kbps optical fiber interface for 2G and 2H modules or C37 94 for 2 64 kbps optical fiber interface for 76 and 77 modules Fiber optic cable type 50 mm or 62 5 mm core diameter optical fiber Fiber optic mode multi mode Fiber optic cable length u...

Page 86: ...al Before performing this action control power must be removed from the relay The original location of the module should be recorded to help ensure that the same or replacement module is inserted into the correct slot 2 Remove the module cover screw 3 Remove the top cover by sliding it towards the rear and then lift it upwards 4 Set the timing selection switches channel 1 channel 2 to the desired ...

Page 87: ... 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 μm 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 10 km Fiber optic connector type ST ...

Page 88: ...ould be recorded to help ensure that the same or replacement module is inserted into the correct slot 2 Remove the module cover screw 3 Remove the top cover by sliding it towards the rear and then lift it upwards 4 Set the timing selection switches channel 1 channel 2 to the desired timing modes see description above 5 Replace the top cover and the cover screw 6 Re insert the C37 94SM module Take ...

Page 89: ...XXX self test warning will be issued 3 4 2 MANAGED ETHERNET SWITCH MODULE HARDWARE The type 2S and 2T managed Ethernet switch modules provide two 10 100Base T and four multimode ST 100Base FX external Ethernet ports accessible through the rear of the module In addition a serial console port is accessible from the front of the module requires the front panel faceplate to be open The pin assignment ...

Page 90: ...ur net work administrator to determine if the default IP address subnet mask or default gateway needs to be modified Do not connect to network while configuring the switch module a CONFIGURING THE SWITCH MODULE IP SETTINGS In our example configuration of both the Switch s IP address and subnet mask must be changed to 3 94 247 229 and 255 255 252 0 respectively The IP address subnet mask and defaul...

Page 91: ...ch module 1 Select the desired device from site tree in the online window 2 Select the Settings Product Setup Communications Ethernet Switch Ethernet Switch Settings File Retreive Settings File item from the device settings tree The system will request the name and destination path for the settings file 3 Enter an appropriate folder and file name and click Save All settings files will be saved as ...

Page 92: ...ware on a switch module Using the EnerVista UR Setup software Serially using the F60 switch module console port Using FTP or TFTP through the F60 switch module console port It is highly recommended to use the EnerVista UR Setup software to upgrade firmware on a F60 switch module Firmware upgrades using the serial port TFTP and FTP are described in detail in the switch module manual b SELECTING THE...

Page 93: ...ns Ethernet Switch Firmware Upload menu item The following popup screen will appear warning that the settings will be lost when the firmware is upgraded It is highly recommended that you save the switch settings before upgrading the firmware 3 After saving the settings file proceed with the firmware upload by selecting Yes to the above warning Another window will open asking you to point to the lo...

Page 94: ...The following window will pop up indicating that the firmware file transfer is in progress If the firmware load was successful the following window will appear Note The switch will automatically reboot after a successful firmware file transfer 5 Once the firmware has been successfully uploaded to the switch module load the settings file using the procedure described earlier NOTE ...

Page 95: ...attempts Loss of switch power IP gateway subnet Incompatibility between the CPU and the switch module UR port port 7 configured incorrectly or blocked Switch IP address assigned to another device in the same network PORT 1 EVENTS to PORT 6 EVENTS ETHERNET PORT 1 OFFLINE to ETHERNET PORT 6 OFFLINE An active Ethernet port has returned a FAILED status Ethernet connection broken An inactive port s eve...

Page 96: ...3 48 F60 Feeder Protection System GE Multilin 3 4 MANAGED ETHERNET SWITCH MODULES 3 HARDWARE 3 ...

Page 97: ...d device definition must first be created See the EnerV ista UR Setup Help File or refer to the Connecting EnerVista UR Setup with the F60 section in Chapter 1 for details 4 1 3 ENERVISTA UR SETUP OVERVIEW a ENGAGING A DEVICE The EnerVista UR Setup software may be used in on line mode relay connected to directly communicate with the F60 relay Communicating relays are organized and grouped by commu...

Page 98: ... 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 are each mutually a file drag source and drop target New files which are dropped into the Settings List window are added to the tree which is automatically sorted alphabet ically with respect to settings file names Files or individual me...

Page 99: ...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 WINDOW Extended EnerVista UR Setup Features 4 1 5 SETTINGS TEMPLATES Setting file templates simplify the configuration and commissioning of mu...

Page 100: ...elect a settings file from the offline window of the EnerVista UR Setup main screen 2 Right click on 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 file is now in template editing mode Alternatively the settings template can also be applied to online settings T...

Page 101: ... by clicking on them The setting available to view will be 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 w...

Page 102: ...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 103: ...fied by the template but all settings will be 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 may be necessary at some point to remove a settings template Once a template is removed it cannot be reapplied and it will be necessary to define a new settin...

Page 104: ...ENTRIES 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 backg...

Page 105: ...below 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...

Page 106: ...for mation can be compared with the F60 actual values at any later date to determine if security has been compromised The traceability information is only included in the settings file if a complete settings file is either transferred to the F60 device or obtained from the F60 device Any partial settings transfers by way of drag and drop do not add the traceability information to the settings file...

Page 107: ...elay 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 sent to an F60 device The F60 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...

Page 108: ...NFORMATION ÖØ SERIAL NUMBER ACTUAL VALUES ÖØ PRODUCT INFO Ö MODEL INFORMATION ÖØ LAST SETTING CHANGE c ADDITIONAL TRACEABILITY RULES The following additional rules apply 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 trace...

Page 109: ...interface being EnerVista 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 which must be removed in order to access the keypad panel The following fig...

Page 110: ...s been cleared these latched conditions can also be reset via the SETTINGS ÖØ INPUT OUTPUTS ÖØ RESETTING menu The RS232 port is intended for connection to a portable PC The USER keys are used by the breaker control feature Figure 4 18 TYPICAL LED INDICATOR PANEL FOR ENHANCED FACEPLATE The status indicators in the first column are described below IN SERVICE This LED indicates that control power is ...

Page 111: ...of 48 amber LED indicators in four columns The operation of these LEDs is user defined Support for applying a customized label beside every LED is provided Default labels are shipped in the label pack age of every F60 together with custom templates The default labels can be replaced by user printed labels User customization of LED operation is of maximum benefit in installations where languages ot...

Page 112: ...ound was involved USER PROGRAMMABLE INDICATORS The second and third provide 48 amber LED indicators whose operation is controlled by the user Support for applying a customized label beside every LED is provided User customization of LED operation is of maximum benefit in installations where languages other than English are used to communicate with operators Refer to the User programmable LEDs sect...

Page 113: ...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 2 3 CUSTOM LABELING OF LEDS a ENHANCED FACEPLATE The following procedure requires the pre requisites listed below EnerVista UR Setup software is installed and operati...

Page 114: ...sert tool from the package and bend the tabs as described in the following procedures These tabs will be 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 F60 contains the three default labels shown below the custom label template...

Page 115: ...cedure describes how to remove the LED labels from the F60 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 will attach the label tool to the LED label ...

Page 116: ... 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 F60 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 117: ...ATE INTERFACE 4 2 Slide the label tool under the user programmable pushbutton label until the tabs snap out as shown below This will attach the label tool to the user programmable pushbutton label 3 Remove the tool and attached user programmable pushbutton label as shown below ...

Page 118: ...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 left sid...

Page 119: ...ented on faceplate LEDs along with a breaker trouble indication Breaker operations can be manually initiated from faceplate keypad or automatically initiated from a FlexLogic operand A setting is provided to assign names to each breaker this user assigned name is used for the display of related flash messages These features are provided for two breakers the user may use only those portions of the ...

Page 120: ...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 required This mes sage will be maintained for 30 secon...

Page 121: ...l value headers Ø 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 Ø 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 back to th...

Page 122: ...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 may be comprised of upper case letters lower case letters numerals and a selection of special characters FLASH MESSAGE TIME 1 0 s For example select the SETTINGS Ö PRODUCT SETUP ÖØ DISPLAY PROPERTIES Ö FLASH MESSAGE TIME setting Ø MINIMUM 0 5 ...

Page 123: ... appears on the display 2 Press the MESSAGE RIGHT key until the 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 selectio...

Page 124: ... 7 Type in a numerical password up to 10 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 ...

Page 125: ...et to Off after the expiration of the ten minute timeout In the event that an incorrect Command or Setting password has been entered via the any external communications inter face three times within a three minute time span the REMOTE ACCESS DENIED FlexLogic operand will be set to On and the F60 will not allow Settings or Command access via the any external communications interface for the next te...

Page 126: ...4 30 F60 Feeder Protection System GE Multilin 4 2 FACEPLATE INTERFACE 4 HUMAN INTERFACES 4 ...

Page 127: ...CK See page 5 34 FAULT REPORTS See page 5 35 OSCILLOGRAPHY See page 5 37 DATA LOGGER See page 5 39 DEMAND See page 5 41 USER PROGRAMMABLE LEDS See page 5 42 USER PROGRAMMABLE SELF TESTS See page 5 45 CONTROL PUSHBUTTONS See page 5 46 USER PROGRAMMABLE PUSHBUTTONS See page 5 47 FLEX STATE PARAMETERS See page 5 52 USER DEFINABLE DISPLAYS See page 5 53 DIRECT I O See page 5 55 TELEPROTECTION See page...

Page 128: ...99 FLEXELEMENTS See page 5 101 NON VOLATILE LATCHES See page 5 105 SETTINGS GROUPED ELEMENTS SETTING GROUP 1 See page 5 106 SETTING GROUP 2 SETTING GROUP 6 SETTINGS CONTROL ELEMENTS SETTING GROUPS See page 5 158 SELECTOR SWITCH See page 5 159 UNDERFREQUENCY See page 5 165 OVERFREQUENCY See page 5 166 FREQUENCY RATE OF CHANGE See page 5 167 SYNCHROCHECK See page 5 169 AUTORECLOSE See page 5 173 DIG...

Page 129: ...210 REMOTE DEVICES See page 5 211 REMOTE INPUTS See page 5 212 REMOTE OUTPUTS DNA BIT PAIRS See page 5 213 REMOTE OUTPUTS UserSt BIT PAIRS See page 5 213 RESETTING See page 5 214 DIRECT INPUTS See page 5 214 DIRECT OUTPUTS See page 5 215 TELEPROTECTION See page 5 218 SETTINGS TRANSDUCER I O DCMA INPUTS See page 5 220 RTD INPUTS See page 5 221 DCMA OUTPUTS See page 5 222 SETTINGS TESTING TEST MODE ...

Page 130: ...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 primary current to which the sum is scaled that is normalized to the larger of the two rated CT inputs For example if CT1 300 5 A and CT2 100 5 A then in order to sum these CT2 is scaled to th...

Page 131: ...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 requirements can be satisfied with a single UR equipped with sufficient CT and VT input channels by selecting the parameter to measure A mechanism is provided to specify the AC parameter or group of parameters used as the inp...

Page 132: ... For example in the scheme shown in the above diagram the configures one Source to be the sum of CT1 and CT2 and can name this Source as Wdg 1 Current 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 module...

Page 133: ...e 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 instrumen...

Page 134: ... 0 the password security feature is disabled The F60 supports password entry from a local or remote connection Local access is defined as any access to settings or commands via the faceplate interface This includes both keypad entry and the through the faceplate RS232 port Remote access is defined as any access to settings or commands via any rear communications port This includes both Ethernet an...

Page 135: ...th the corresponding ENCRYPTED PASSWORD If the setting and command passwords are identical then this one password allows access to both com mands and settings c REMOTE PASSWORDS The remote password settings are only visible from a remote connection via the EnerVista UR Setup software Select the Settings Product Setup Password Security menu item to open the remote password settings window Figure 5 ...

Page 136: ...out password access after the number of invalid password entries specified by the INVALID ATTEMPS BEFORE LOCKOUT setting has occurred The F60 provides a means to raise an alarm upon failed password entry Should password verification fail while accessing a password protected level of the relay either settings or commands the UNAUTHORIZED ACCESS FlexLogic operand is asserted The operand can be progr...

Page 137: ...y time is modified via this setting to ensure messages remain on the screen long enough during programming or reading of actual values DEFAULT MESSAGE INTENSITY To extend phosphor life in the vacuum fluorescent display the brightness can be attenuated during default message display During keypad interrogation the display always operates at full brightness SCREEN SAVER FEATURE and SCREEN SAVER WAIT...

Page 138: ...t off operation applies to quantities used for metering protection and control as well as those used by communications protocols Raw samples of the voltages available via oscillography are not subject cut off The CURRENT CUT OFF LEVEL and the VOLTAGE CUT OFF LEVEL are used to determine the metered power cut off levels The power cut off level is calculated as shown below For Delta connections EQ 5 ...

Page 139: ...uld be applied 1 Assign the clear demand function to Pushbutton 1 by making the following change in the SETTINGS Ö PRODUCT SETUP ÖØ CLEAR RELAY RECORDS menu CLEAR DEMAND PUSHBUTTON 1 ON 2 Set the properties for User Programmable Pushbutton 1 by making the following changes in the SETTINGS Ö PRODUCT SETUP ÖØ USER PROGRAMMABLE PUSHBUTTONS Ö USER PUSHBUTTON 1 menu PUSHBUTTON 1 FUNCTION Self reset PUS...

Page 140: ...e page 5 16 MESSAGE DNP IEC104 POINT LISTS See page 5 19 MESSAGE IEC 61850 PROTOCOL See page 5 20 MESSAGE WEB SERVER HTTP PROTOCOL See page 5 29 MESSAGE TFTP PROTOCOL See page 5 29 MESSAGE IEC 60870 5 104 PROTOCOL See page 5 30 MESSAGE SNTP PROTOCOL See page 5 30 MESSAGE EGD PROTOCOL See page 5 31 MESSAGE ETHERNET SWITCH See page 5 32 SERIAL PORTS RS485 COM1 BAUD RATE 19200 Range 300 1200 2400 480...

Page 141: ...sed with DNP is changed it will not become active until power to the relay has been cycled off on Do not set more than one protocol to the same TCP UDP PORT NUMBER as this will result in unreliable opera tion of those protocols d MODBUS PROTOCOL PATH SETTINGS Ö PRODUCT SETUP ÖØ COMMUNICATIONS ÖØ MODBUS PROTOCOL The serial communication ports utilize the Modbus protocol unless configured for DNP or...

Page 142: ...000 100000 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 10...

Page 143: ...hannels 1 or 2 When this value is set to Network UDP the DNP protocol can be used over UDP IP on chan nel 1 only Refer to Appendix E for additional information on the DNP protocol Changes to the DNP CHANNEL 1 PORT and DNP CHANNEL 2 PORT settings will take effect only after power has been cycled to the relay The DNP NETWORK CLIENT ADDRESS settings can force the F60 to respond to a maximum of five s...

Page 144: ...change dead band values from the default for each individual DNP analog input point Whenever power is removed and re applied to the F60 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 F60 Changing this time allows the DNP master to send time synchronization commands more or less often as requi...

Page 145: ...g 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 Ö PRODUCT SETUP ÖØ COMMUNICATIONS ÖØ DNP IEC104 POINT LISTS Ö 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 config...

Page 146: ...if CPU type E is ordered The F60 supports the Manufacturing Message Specification MMS protocol as specified by IEC 61850 MMS is supported over two protocol stacks TCP IP over ethernet and TP4 CLNP OSI over ethernet The F60 operates as an IEC 61850 server The Remote inputs and outputs section in this chapter describe the peer to peer GSSE GOOSE message scheme The GSSE GOOSE configuration main menu ...

Page 147: ...d GSSE messages are not transmitted The GSSE ID setting represents the IEC 61850 GSSE application ID name string sent as part of each GSSE message This string identifies the GSSE message to the receiving device In F60 releases previous to 5 0x this name string was repre sented by the RELAY NAME setting The fixed GOOSE settings are shown below PATH SETTINGS Ö PRODUCT ÖØ COMMUNICATIONS ÖØ IEC 61850 ...

Page 148: ...0 The F60 supports the configuration of eight 8 transmission and reception datasets allowing for the optimization of data transfer between devices Items programmed for dataset 1 will have changes in their status transmitted as soon as the change is detected Dataset 1 should be used for high speed transmission of data that is required for applications such as transfer tripping blocking and breaker ...

Page 149: ...re 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 This example shows how to configure the transmission and reception of three IEC 61850 data items a single point status value its associated quality flags and a...

Page 150: ...ges in the INPUTS OUTPUTS ÖØ REMOTE INPUTS ÖØ REMOTE INPUT 1 settings menu Set REMOTE IN 1 DEVICE to GOOSEOut_1 Set REMOTE IN 1 ITEM to Dataset Item 2 This assigns the value of the GGIO3 ST Ind1 stVal single point status item to remote input 1 Remote input 1 can now be used in FlexLogic equations or other settings The F60 must be rebooted control power removed and re applied before these settings ...

Page 151: ...P ÖØ COMMUNICATIONS ÖØ IEC 61850 PROTOCOL ÖØ SERVER CONFIGURATION The IED NAME and LD INST settings represent the MMS domain name IEC 61850 logical device where all IEC MMS logical nodes are located Valid characters for these values are upper and lowercase letters numbers and the underscore _ character and the first character in the string must be a letter This conforms to the IEC 61850 standard T...

Page 152: ...U DEADBANDS The MMXU deadband settings represent the deadband 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 ...

Page 153: ...urity The GGIO2 control points are used to control the F60 virtual inputs The GGIO4 analog configuration points are shown below PATH SETTINGS Ö PRODUCT SETUP ÖØ COMMUNICATIONS ÖØ IEC 61850 ÖØ 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 F60 must be rebooted in order to allow the GGIO4 logica...

Page 154: ...e determi nation of the deadbanded magnitude from the instantaneous magnitude Note that the ANALOG IN 1 MIN and ANALOG IN 1 MAX settings are stored as IEEE 754 IEC 60559 floating point numbers Because of the large range of these settings not all values can be stored Some values may be rounded to the closest possible floating point number The report control configuration settings are shown below PA...

Page 155: ...can be accessed starting at the F60 Main Menu Web pages are available showing DNP and IEC 60870 5 104 points lists Modbus registers event records fault reports etc The web pages can be accessed by connecting the UR and a computer to an ethernet network The main menu will be displayed in the web browser on the computer simply by entering the IP address of the F60 into the Address box on the web bro...

Page 156: ...protocols cannot be used simultaneously When the IEC 60870 5 104 FUNCTION setting is set to Enabled the DNP protocol will not be operational When this setting is changed it will not become active until power to the relay has been cycled off to on k SNTP PROTOCOL PATH SETTINGS Ö PRODUCT SETUP ÖØ COMMUNICATIONS ÖØ SNTP PROTOCOL The F60 supports the Simple Network Time Protocol specified in RFC 2030 ...

Page 157: ...he time of ordering Refer to the Ordering sec tion of chapter 2 for additional details The Ethernet Global Data EGD protocol feature is not available if CPU Type E is ordered The relay supports one fast Ethernet Global Data EGD exchange and two slow EGD exchanges There are 20 data items in the fast produced EGD exchange and 50 data items in each slow produced exchange Ethernet Global Data EGD is a...

Page 158: ... memory map Note that the Modbus memory map displays shows addresses in hexadecimal format as such it will be neces sary to convert these values to decimal format before entering them as values for these setpoints To select a data item to be part of an exchange it is only necessary to choose the starting Modbus address of the item That is for items occupying more than one Modbus register for examp...

Page 159: ... 5 2 5 MODBUS USER MAP PATH SETTINGS Ö PRODUCT SETUP ÖØ MODBUS USER MAP The Modbus user map provides read only access for up to 256 registers To obtain a memory map value enter the desired address in the ADDRESS line this value must be converted from hex to decimal format The corresponding value is dis played in the VALUE line A value of 0 in subsequent register ADDRESS lines automatically returns...

Page 160: ...vings time DST settings can be used to allow the F60 clock can follow the DST rules of the local time zone Note that when IRIG B time synchronization is active the DST settings are ignored The DST settings are used when the F60 is synchronized with SNTP or when neither SNTP nor IRIG B is used Only timestamps in the event recorder and communications protocols are affected by the daylight savings ti...

Page 161: ...lt report source or the trigger operate Fault current and voltage phasors one cycle after the trigger Elements operated at the time of triggering Events 9 before trigger and 7 after trigger only available via the relay webpage Fault duration times for each breaker created by the breaker arcing current feature FAULT REPORT 1 FAULT REPORT 1 SOURCE SRC 1 Range SRC 1 SRC 2 MESSAGE FAULT REPORT 1 TRIG ...

Page 162: ...SOURCE setting selects the source for input currents and voltages and disturbance detection The FAULT 1 REPORT TRIG setting assigns the FlexLogic operand representing the protection element elements requiring operational fault location calculations The distance to fault calculations are initiated by this signal The FAULT REPORT 1 Z1 MAG and FAULT REPORT 1 Z0 MAG impedances are entered in secondary...

Page 163: ...size for example 10 50 75 etc 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 ar...

Page 164: ...ctual value parameters is presented in Appendix A FlexAnalog parameters The parameter index number shown in any of the tables is used 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 Al...

Page 165: ...xed sampling rate the data logger can be configured with a few channels over a long period or a larger number of channels for a shorter period The relay automatically partitions the available memory between the channels in use Exam ple storage capacities for a system frequency of 60 Hz are shown in the following table DATA LOGGER DATA LOGGER MODE Continuous Range Continuous Trigger MESSAGE DATA LO...

Page 166: ...s set to Trigger DATA LOGGER RATE This setting selects the time interval at which the actual value data will be recorded DATA LOGGER CHNL 1 16 This setting selects the metering actual value that is to be recorded in Channel 1 16 of the data log The parameters 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 numbe...

Page 167: ...ristic of 15 minutes is illustrated below A setpoint establishes the time to reach 90 of a steady state value just as the response time of an analog instrument A steady state value applied for twice the response time will indicate 99 of the value Figure 5 3 THERMAL DEMAND CHARACTERISTIC CALCULATION METHOD 2 BLOCK INTERVAL This method calculates a linear average of the quantity RMS current real pow...

Page 168: ...a quick test to verify if any of the LEDs is burned This stage lasts as long as the control input is on up to a maximum of 1 minute After 1 minute the test will end 2 All the LEDs are turned off and then one LED at a time turns on for 1 second then back off The test routine starts at the top left panel moving from the top to bottom of each LED column This test checks for hardware failures that lea...

Page 169: ... recognize user programmable pushbutton 1 by making the following entries in the SETTINGS Ö PRODUCT SETUP ÖØ USER PROGRAMMABLE LEDS Ö LED TEST menu LED TEST FUNCTION Enabled LED TEST CONTROL PUSHBUTTON 1 ON The test will be initiated when the user programmable pushbutton 1 is pressed The pushbutton should remain pressed for as long as the LEDs are being visually inspected When finished the pushbut...

Page 170: ...n the logic 1 state For the standard faceplate the LEDs are located as follows LED Panel 2 user programmable LEDs 1 through 24 LED Panel 3 user programmable LEDs 25 through 48 For the enhanced faceplate the LEDs are located as follows LED column 2 user programmable LEDs 1 through 12 LED column 3 user programmable LEDs 13 through 24 LED column 4 user programmable LEDs 25 through 36 LED column 5 use...

Page 171: ...BREAKER 2 CLOSED LED 4 operand SETTING GROUP ACT 4 LED 16 operand BREAKER 2 TROUBLE LED 5 operand SETTING GROUP ACT 5 LED 17 operand SYNC 1 SYNC OP LED 6 operand SETTING GROUP ACT 6 LED 18 operand SYNC 2 SYNC OP LED 7 operand Off LED 19 operand Off LED 8 operand Off LED 20 operand Off LED 9 operand BREAKER 1 OPEN LED 21 operand AR ENABLED LED 10 operand BREAKER 1 CLOSED LED 22 operand AR DISABLED ...

Page 172: ... Each control pushbutton asserts its own FlexLogic operand These operands should be configured appropriately to per form the desired function The operand remains asserted as long as the pushbutton is pressed and resets when the push button is released A dropout delay of 100 ms is incorporated to ensure fast pushbutton manipulation will be recognized by various features that may use control pushbut...

Page 173: ...PUSHBTN 1 RESET Off Range FlexLogic operand MESSAGE PUSHBTN 1 AUTORST Disabled Range Disabled Enabled MESSAGE PUSHBTN 1 AUTORST DELAY 1 0 s Range 0 2 to 600 0 s in steps of 0 1 MESSAGE PUSHBTN 1 REMOTE Off Range FlexLogic operand MESSAGE PUSHBTN 1 LOCAL Off Range FlexLogic operand MESSAGE PUSHBTN 1 DROP OUT TIME 0 00 s Range 0 to 60 00 s in steps of 0 05 MESSAGE PUSHBTN 1 LED CTL Off Range FlexLog...

Page 174: ... used to program specific actions If any pushbutton is active the ANY PB ON operand will be asserted Each pushbutton has an associated LED indicator By default this indicator displays the present status of the correspond ing pushbutton on or off However each LED indicator can be assigned to any FlexLogic operand through the PUSHBTN 1 LED CTL setting The pushbuttons can be automatically controlled ...

Page 175: ...selects the characteristic of the pushbutton If set to Disabled the push button is not active and the corresponding FlexLogic operands both On and Off are de asserted If set to Self Reset the control logic is activated by the pulse longer than 100 ms issued when the pushbutton is being physically pressed or virtually pressed via a FlexLogic operand assigned to the PUSHBTN 1 SET setting When in Sel...

Page 176: ...emains on has no effect on the pulse duration This setting is required to set the duration of the pushbutton operating pulse PUSHBTN 1 LED CTL This setting assigns the FlexLogic operand serving to drive pushbutton LED If this setting is Off then LED operation is directly linked to PUSHBUTTON 1 ON operand PUSHBTN 1 MESSAGE If pushbutton message is set to High Priority the message programmed in the ...

Page 177: ...PUSHBTN 1 LOCAL SETTING Off 0 PUSHBTN 1 SET SETTING Off 0 PUSHBTN 1 RESET SETTING Enabled Disabled PUSHBTN 1 AUTORST 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 PUSHBTN 1 AUTORST DELAY TPKP 0 TIMER 200 ms 0 AND AND SETTING PUSHBTN 1 DROP OUT DELAY TRST 0 PUSHBUTTON ON To user programmable pushbuttons lo...

Page 178: ...E PARAMETER 256 Off Range FlexLogic operand Pushbutton 1 LED Instantaneous reset OR 1 If pushbutton 1 LED control is set to off 2 If pushbutton 1 LED control is not set to off PUSHBUTTON 1 LED LOGIC OR AND AND SETTING Disabled High Priority PUSHBUTTON 1 MESSAGE Normal FLEXLOGIC OPERAND PUSHBUTTON 1 ON Pushbutton 1 LED SETTING any FlexLogic operand PUSHBTN 1 LED CTL AND SETTING FLASH MESSAGE TIME T...

Page 179: ...e PRODUCT SETUP ÖØ DISPLAY PROPER TIES ÖØ DEFAULT MESSAGE TIMEOUT setting USER PROGRAMMABLE CONTROL INPUT The user definable displays also respond to the INVOKE AND SCROLL setting Any FlexLogic operand in particular the user programmable pushbutton operands can be used to navi gate the programmed displays On the rising edge of the configured operand such as when the pushbutton is pressed the displ...

Page 180: ...oll through 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 th...

Page 181: ...cimal form of user selected Modbus Register Address corresponding to first Tilde marker MESSAGE DISP 1 ITEM 2 6357 Shows decimal form of user selected Modbus Register Address corresponding to 2nd 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...

Page 182: ...ice are not being received Direct input and output settings are similar to remote input and 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...

Page 183: ...perands flags bits to be exchanged Table 5 4 DIRECT INPUT AND OUTPUT DATA RATES MODULE CHANNEL SUPPORTED DATA RATES 74 Channel 1 64 kbps Channel 2 64 kbps 7L Channel 1 64 kbps 128 kbps Channel 2 64 kbps 128 kbps 7M Channel 1 64 kbps 128 kbps Channel 2 64 kbps 128 kbps 7P Channel 1 64 kbps 128 kbps Channel 2 64 kbps 128 kbps 7T Channel 1 64 kbps 128 kbps 7W Channel 1 64 kbps 128 kbps Channel 2 64 k...

Page 184: ... DIRECT I O CH1 RING CONFIGURATION Yes DIRECT I O DATA RATE 128 kbps For UR series IED 2 DIRECT OUTPUT DEVICE ID 2 DIRECT I O CH1 RING CONFIGURATION Yes DIRECT I O DATA RATE 128 kbps The message delivery time is about 0 2 of power cycle in both ways at 128 kbps that is from device 1 to device 2 and from device 2 to device 1 Different communications cards can be selected by the user for this back t...

Page 185: ... rings are healthy IED 1 to IED 2 0 2 of power system cycle IED 1 to IED 3 0 4 of power system cycle IED 1 to IED 4 0 2 of power system cycle IED 2 to IED 3 0 2 of power system cycle IED 2 to IED 4 0 4 of power system cycle IED 3 to IED 4 0 2 of power system cycle If one ring is broken say TX2 RX2 the delivery times are as follows IED 1 to IED 2 0 2 of power system cycle IED 1 to IED 3 0 4 of powe...

Page 186: ...PUT DEVICE ID 1 DIRECT I O CH1 RING CONFIGURATION Yes DIRECT I O CH2 RING CONFIGURATION Yes For UR series IED 3 DIRECT OUTPUT DEVICE ID 1 DIRECT I O CH1 RING CONFIGURATION Yes DIRECT I O CH2 RING CONFIGURATION Yes In this configuration the following delivery times are expected at 128 kbps IED 1 to IED 2 0 2 of power system cycle IED 1 to IED 3 0 5 of power system cycle IED 2 to IED 3 0 2 of power ...

Page 187: ... PATH SETTINGS Ö PRODUCT SETUP ÖØ DIRECT I O ÖØ CRC ALARM CH1 2 The F60 checks integrity of the incoming direct input and output messages using a 32 bit CRC The CRC alarm function is available for monitoring the communication medium noise by tracking the rate of messages failing the CRC check The monitoring function counts all incoming messages including messages that failed the CRC check A separa...

Page 188: ... the best case of only 1 bit error in a failed packet having 1 failed packet for every 63 received is about equal to a BER of 10 4 c UNRETURNED MESSAGES ALARM CH1 2 PATH SETTINGS Ö PRODUCT SETUP ÖØ DIRECT I O ÖØ UNRETURNED MESSAGES ALARM CH1 2 The F60 checks integrity of the direct input and output communication ring by counting unreturned messages In the ring configuration all messages originatin...

Page 189: ... 2 RELAY ID NUMBER In installa tions that use multiplexers or modems it is desirable to ensure that the data used by the relays protecting a given line is from the correct relays The teleprotection function performs this check by reading the message ID sent by transmit ting relays and comparing it to the programmed ID in the receiving relay This check is also used to block inputs if inad vertently...

Page 190: ...etting is defaulted to Not Programmed when at the factory The UNIT NOT PROGRAMMED self test error message is displayed until the relay is put into the Programmed state The RELAY NAME setting allows the user to uniquely identify a relay This name will appear on generated reports This name is also used to identify specific devices which are engaged in automatically sending receiving data over the Et...

Page 191: ...ration the 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 m...

Page 192: ...00 120 volt VT in a delta connec tion the secondary voltage would be 115 that is 13800 14400 120 For a wye connection the voltage value entered must be the phase to neutral voltage 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 If the PHASE VT F5 CONNECTION is set to...

Page 193: ...elected reference signal is not measurable at a given time the phase angles are not referenced The phase angle referencing is done via a phase locked loop which can synchronize independent UR series relays if they have the same AC signal reference These results in very precise correlation of time tagging in the event recorder between different UR series relays provided the relays have an IRIG B co...

Page 194: ...ed within a configured source are displayed in the sources section of the actual values DISTURBANCE DETECTORS INTERNAL The disturbance detector ANSI 50DD element is a sensitive current disturbance detector that detects any disturbance on the protected system The 50DD function is intended for use in conjunction with measuring elements blocking of current based elements to prevent maloperation as a ...

Page 195: ...ker and a half sys tem The following figure shows the arrangement of sources used to provide the functions required in this application and the CT VT inputs that are used to provide the data Figure 5 19 EXAMPLE USE OF SOURCES F 5 F 1 DSP Bank U 1 M 1 M 1 M 5 51BF 1 51BF 2 Source 4 87T 51P UR Relay A V V A W W Var Var Amps Source 1 Source 3 Volts Amps Amps Volts Amps Source 2 ...

Page 196: ... Range FlexLogic operand MESSAGE BREAKER 1 ΦA 3P CLSD Off Range FlexLogic operand MESSAGE BREAKER 1 ΦA 3P OPND Off Range FlexLogic operand MESSAGE BREAKER 1 ΦB CLOSED Off Range FlexLogic operand MESSAGE BREAKER 1 ΦB OPENED Off Range FlexLogic operand MESSAGE BREAKER 1 ΦC CLOSED Off Range FlexLogic operand MESSAGE BREAKER 1 ΦC OPENED Off Range FlexLogic operand MESSAGE BREAKER 1 Toperate 0 070 s Ra...

Page 197: ... 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 ΦB and BREAKER 1 ΦC settings select operands to track phases B and C respectively BREAKER 1 ΦA 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 198: ...ff 0 BREAKER 1 BLOCK OPEN FLEXLOGIC OPERANDS TRIP PHASE A TRIP PHASE B TRIP PHASE C TRIP 3 POLE SETTING Off 0 BREAKER 1 OPEN SETTING Enabled BREAKER 1 PUSHBUTTON CONTROL USER 2 OFF ON To open BRK1 Name SETTING Off 0 BREAKER 1 CLOSE FLEXLOGIC OPERAND AR CLOSE BKR 1 SETTING Off 0 BREAKER 1 BLOCK CLOSE SETTING MANUAL CLOSE RECAL1 TIME 0 FLEXLOGIC OPERAND BREAKER 1 MNL CLS FLEXLOGIC OPERAND BREAKER 1 ...

Page 199: ...TING Off BREAKER 1 OPENED ΦB SETTING Off BREAKER 1 OPENED ΦC SETTING Off BREAKER 1 OUT OF SV SETTING BREAKER 1 Toperate 0 SETTING BREAKER 1 Toperate 0 SETTING BREAKER 1 Toperate 0 from breaker control logic sheet 1 827061AR BKR ENABLED FLEXLOGIC OPERAND BREAKER 1 CLOSED FLEXLOGIC OPERAND BREAKER 1 OPEN FLEXLOGIC OPERAND BREAKER 1 DISCREP FLEXLOGIC OPERAND BREAKER 1 TROUBLE FLEXLOGIC OPERAND BREAKE...

Page 200: ...ect switch 1 SWITCH 1 MODE This setting selects 3 pole mode where all disconnect switch poles are operated simultaneously or 1 pole mode where all disconnect switch poles are operated either independently or simultaneously 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 MESS...

Page 201: ...hat should be a normally closed 52 b status input to create a logic 1 when the disconnect switch is open If a separate 52 b contact input is not avail able then the inverted SWITCH 1 CLOSED status signal can be used SWITCH 1 ΦB 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 c...

Page 202: ...0 SETTING SWITCH 1 Toperate 0 FLEXLOGIC OPERAND SWITCH 1 CLOSED FLEXLOGIC OPERAND SWITCH 1 OPEN FLEXLOGIC OPERAND SWITCH 1 DISCREP FLEXLOGIC OPERAND SWITCH 1 TROUBLE FLEXLOGIC OPERAND SWITCH 1 BAD STATUS FLEXLOGIC OPERANDS SWITCH 1 ΦA BAD ST SWITCH 1 ΦA CLSD SWITCH 1 ΦA OPEN SWITCH 1 ΦA INTERM FLEXLOGIC OPERANDS SWITCH 1 Φ BAD ST B SWITCH 1 B Φ CLSD SWITCH 1 B Φ OPEN SWITCH 1 B Φ INTERM FLEXLOGIC ...

Page 203: ...tiple of pickup of 1 that is 0 98 pu and 1 03 pu It is recommended to set the two times to a similar value otherwise the lin ear approximation may result in undesired behavior for the operating quantity that is close to 1 00 pu FLEXCURVE A FLEXCURVE A TIME AT 0 00 xPKP 0 ms Range 0 to 65535 ms in steps of 1 Table 5 5 FLEXCURVE TABLE RESET TIME MS RESET TIME MS OPERATE TIME MS OPERATE TIME MS OPERA...

Page 204: ...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 From EnerVista UR Setup setting is set to Recloser Curve and the Initialize FlexCurve button is clicked Figure 5 23 RECLOSER CURVE INITIALIZATION The multiplier and adder settings only affect the curve port...

Page 205: ...s see below Figure 5 24 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 25 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 206: ... 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 207: ...D GE201 Figure 5 29 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 208: ...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 209: ...igure 5 33 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 210: ...tact 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 ele ment This capability also applies to the other features that set flags elements virtual inputs remote inputs schemes and human operators If mo...

Page 211: ...oltage 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 Voltage On Cont Op 1 VOn Voltage exists across the contact Voltage Off Cont Op 1 VOff Voltage does not exists across the contact Current On Cont Op 1 IOn Current is flowing through the contact Current Off Cont O...

Page 212: ...OM MAN CLS AR1 CLOSE AR1 SHOT CNT 0 AR1 SHOT CNT 1 AR1 SHOT CNT 2 AR1 SHOT CNT 3 AR1 SHOT CNT 4 AR1 DISABLED Autoreclose 1 is enabled Autoreclose 1 is in progress Autoreclose 1 is locked out Autoreclose 1 is temporarily disabled Autoreclose 1 close command is issued Autoreclose 1 shot count is 0 Autoreclose 1 shot count is 1 Autoreclose 1 shot count is 2 Autoreclose 1 shot count is 3 Autoreclose 1...

Page 213: ...d transition from one position to another Breaker 1 phase B is closed Breaker 1 phase B is open Breaker 1 phase C bad status is detected discrepancy between the 52 a and 52 b contacts Breaker 1 phase A intermediate status is detected transition from one position to another Breaker 1 phase C is closed Breaker 1 phase C is open Breaker 1 bad status is detected on any pole Breaker 1 is closed Breaker...

Page 214: ...element has operated The high impedance fault arcing suspected phase A element has operated The high impedance fault arcing suspected phase B element has operated The high impedance fault arcing suspected phase C element has operated The high impedance fault arcing suspected neutral element has operated The high impedance instantaneous overcurrent A element has operated The high impedance instanta...

Page 215: ...or OVERFREQ 1 ELEMENT Phase directional overcurrent PH DIR1 BLK A PH DIR1 BLK B PH DIR1 BLK C PH DIR1 BLK Phase A directional 1 block Phase B directional 1 block Phase C directional 1 block Phase directional 1 block PH DIR2 Same set of operands as shown for PH DIR1 ELEMENT Phase instantaneous overcurrent PHASE IOC1 PKP PHASE IOC1 OP PHASE IOC1 DPO PHASE IOC1 PKP A PHASE IOC1 PKP B PHASE IOC1 PKP C...

Page 216: ...dervoltage 1 has dropped out Phase C of phase undervoltage 1 has dropped out PHASE UV2 Same set of operands as shown for PHASE UV1 ELEMENT Selector switch SELECTOR 1 POS Y SELECTOR 1 BIT 0 SELECTOR 1 BIT 1 SELECTOR 1 BIT 2 SELECTOR 1 STP ALARM SELECTOR 1 BIT ALARM SELECTOR 1 ALARM SELECTOR 1 PWR ALARM Selector switch 1 is in Position Y mutually exclusive operands First bit of the 3 bit word encodi...

Page 217: ...t Synchrocheck 1 in synchronization has operated Synchrocheck 1 in synchronization has dropped out Synchrocheck 1 close has operated Synchrocheck 1 close has dropped out Synchrocheck 1 V1 is above the minimum live voltage Synchrocheck 1 V1 is below the maximum dead voltage Synchrocheck 1 V2 is above the minimum live voltage Synchrocheck 1 V2 is below the maximum dead voltage SYNC 2 Same set of ope...

Page 218: ...LED PHASE B LED PHASE C LED NEUTRAL GROUND Asserted when the front panel IN SERVICE LED is on Asserted when the front panel TROUBLE LED is on Asserted when the front panel TEST MODE LED is on Asserted when the front panel TRIP LED is on Asserted when the front panel ALARM LED is on Asserted when the front panel PICKUP LED is on Asserted when the front panel VOLTAGE LED is on Asserted when the fron...

Page 219: ...scription in Chapter 7 Commands and targets See description in Chapter 7 Commands and targets See description in Chapter 7 Commands and targets See description in Chapter 7 Commands and targets See description in Chapter 7 Commands and targets See description in Chapter 7 Commands and targets See description in Chapter 7 Commands and targets See description in Chapter 7 Commands and targets See de...

Page 220: ... 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 res...

Page 221: ... 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 a...

Page 222: ...to start at the output 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 cel...

Page 223: ...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 40 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 224: ...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 225: ...ION EDITOR PATH SETTINGS ÖØ FLEXLOGIC Ö FLEXLOGIC EQUATION EDITOR There are 512 FlexLogic entries available numbered from 1 to 512 with default END entry settings If a Disabled Ele ment 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 4 6 FLEXLOG...

Page 226: ...5 100 F60 Feeder Protection System GE Multilin 5 4 FLEXLOGIC 5 SETTINGS 5 TIMER 1 DROPOUT DELAY Sets the time delay to dropout If a dropout delay is not required set this function to 0 ...

Page 227: ... 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 Over Range Over Under MESSAGE FLEXELEMENT 1 PICKUP 1 ...

Page 228: ...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 1 IN...

Page 229: ...PKP FLEXELEMENT DIRECTION Over PICKUP HYSTERESIS of PICKUP FlexElement 1 OpSig FLEXELEMENT 1 PKP FLEXELEMENT DIRECTION Under PICKUP HYSTERESIS of PICKUP 842705A1 CDR 842706A2 CDR FlexElement 1 OpSig FLEXELEMENT 1 PKP FLEXELEMENT DIRECTION Over FLEXELEMENT INPUT MODE Signed FlexElement 1 OpSig FLEXELEMENT 1 PKP FLEXELEMENT DIRECTION Over FLEXELEMENT INPUT MODE Absolute FlexElement 1 OpSig FLEXELEME...

Page 230: ... 1 COMP MODE is set to Delta The FLEXELEMENT 1 DT setting specifies duration of the time interval for the rate of change mode of operation This setting is applicable only if FLEXELEMENT 1 COMP MODE is set to Delta This FLEXELEMENT 1 PKP DELAY setting specifies the pickup delay of the element The FLEXELEMENT 1 RST DELAY setting specifies the reset delay of the element Table 5 10 FLEXELEMENT BASE UN...

Page 231: ...d the specified FlexLogic operand resets Latch 1 Figure 5 45 NON VOLATILE LATCH OPERATION TABLE N 1 to 16 AND LOGIC LATCH 1 LATCH 1 FUNCTION Disabled Range Disabled Enabled MESSAGE LATCH 1 TYPE Reset Dominant Range Reset Dominant Set Dominant MESSAGE LATCH 1 SET Off Range FlexLogic operand MESSAGE LATCH 1 RESET Off Range FlexLogic operand MESSAGE LATCH 1 TARGET Self reset Range Self reset Latched ...

Page 232: ...OUPS 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 5 2 SETTING GROUP PATH SETTINGS ÖØ GROUPED ELEMENTS Ö 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 the Control elements section f...

Page 233: ...quadrilateral distance element LOAD ENCROACHMENT LOAD ENCROACHMENT FUNCTION Disabled Range Disabled Enabled MESSAGE LOAD ENCROACHMENT SOURCE SRC 1 Range SRC 1 SRC 2 MESSAGE LOAD ENCROACHMENT MIN VOLT 0 250 pu Range 0 000 to 3 000 pu in steps of 0 001 MESSAGE LOAD ENCROACHMENT REACH 1 00 Ω Range 0 02 to 250 00 ohms in steps of 0 01 MESSAGE LOAD ENCROACHMENT ANGLE 30 Range 5 to 50 in steps of 1 MESS...

Page 234: ...element as shown in the Load encroachment characteristic diagram This setting should be entered in secondary ohms and be calculated as the pos itive sequence resistance seen by the relay under maximum load conditions and unity power factor LOAD ENCROACHMENT ANGLE This setting specifies the size of the blocking region as shown on the Load encroachment characteristic diagram and applies to the posit...

Page 235: ...the multiplier to zero results in an instantaneous response to all current levels above pickup Time overcurrent time calculations are made with an internal energy capacity memory variable When this variable indi cates that the energy capacity has reached 100 a time overcurrent element will operate If less than 100 energy capac ity is accumulated in this variable and the current falls below the dro...

Page 236: ...4 587 8 007 5 187 3 710 2 837 2 277 1 897 1 626 6 0 136 090 57 130 21 880 12 010 7 780 5 564 4 255 3 416 2 845 2 439 8 0 181 454 76 174 29 174 16 014 10 374 7 419 5 674 4 555 3 794 3 252 10 0 226 817 95 217 36 467 20 017 12 967 9 274 7 092 5 693 4 742 4 065 IEEE VERY INVERSE 0 5 8 090 3 514 1 471 0 899 0 654 0 526 0 450 0 401 0 368 0 345 1 0 16 179 7 028 2 942 1 798 1 308 1 051 0 900 0 802 0 736 0...

Page 237: ... 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 238: ...88 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 81...

Page 239: ...stanta neous to 600 00 seconds in steps of 10 ms EQ 5 14 EQ 5 15 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 F60 uses the FlexCurve feature to facilitate programming of 41 recloser curves Please refer to the FlexCurve sec tion in this chapter for addit...

Page 240: ...ically reduced by a voltage restraint feature when enabled This is accom plished via the multipliers Mvr corresponding to the phase phase voltages of the voltage restraint characteristic curve see the figure below the pickup level is calculated as Mvr times the PHASE TOC1 PICKUP setting If the voltage restraint feature is disabled the pickup level always remains at the setting value PHASE TOC1 PHA...

Page 241: ... PHASE TOC1 BLOCK B PHASE TOC1 VOLT RESTRAINT PHASE TOC1 A PKP PHASE TOC1 A DPO PHASE TOC1 A OP PHASE TOC1 B PKP PHASE TOC1 B DPO PHASE TOC1 B OP PHASE TOC1 C PKP PHASE TOC1 C DPO PHASE TOC1 C OP PHASE TOC1 PKP PHASE TOC1 OP PHASE TOC1 SOURCE PHASE TOC1 RESET PHASE TOC1 CURVE PHASE TOC1 PICKUP PHASE TOC1 INPUT IA Seq ABC Seq ACB Set Multiplier Set Multiplier Set Multiplier Set Pickup Multiplier Ph...

Page 242: ...PHASE IOC1 RESET DELAY 0 00 s Range 0 00 to 600 00 s in steps of 0 01 MESSAGE PHASE IOC1 BLOCK A Off Range FlexLogic operand MESSAGE PHASE IOC1 BLOCK B Off Range FlexLogic operand MESSAGE PHASE IOC1 BLOCK C Off Range FlexLogic operand MESSAGE PHASE IOC1 TARGET Self reset Range Self reset Latched Disabled MESSAGE PHASE IOC1 EVENTS Disabled Range Disabled Enabled IA PICKUP SETTING PHASE IOC1 FUNCTIO...

Page 243: ...0 or 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 SR...

Page 244: ...o select 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 th...

Page 245: ...C2 See page 5 121 MESSAGE NEUTRAL DIRECTIONAL OC1 See page 5 122 MESSAGE NEUTRAL DIRECTIONAL OC2 See page 5 122 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...

Page 246: ...n taneous and the element is blocked the time accumulator will be cleared immediately Figure 5 54 NEUTRAL TIME OVERCURRENT 1 SCHEME LOGIC NEUTRAL TOC1 NEUTRAL TOC1 FUNCTION Disabled Range Disabled Enabled MESSAGE NEUTRAL TOC1 SIGNAL SOURCE SRC 1 Range SRC 1 SRC 2 MESSAGE NEUTRAL TOC1 INPUT Phasor Range Phasor RMS MESSAGE NEUTRAL TOC1 PICKUP 1 000 pu Range 0 000 to 30 000 pu in steps of 0 001 MESSA...

Page 247: ... 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 three phase pure zero sequence injection Figure 5 55 NEUTRAL IOC1 SCHEME LOGIC NEUTRAL IOC1 NEUTRAL IOC1 FUNCTION Disabled Range Disabled Enabled MESSAGE NE...

Page 248: ...hen forming the operating quantity EQ 5 17 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 MESSAGE NEUTRAL DIR OC1 POLARIZING Voltag...

Page 249: ...lowing figure explains the usage of the voltage polarized directional unit of the element The figure below shows the voltage polarized phase angle comparator characteristics for a phase A to ground fault with ECA 90 element characteristic angle centerline of operating characteristic FWD LA 80 forward limit angle the angular limit with the ECA for operation REV LA 80 reverse limit angle the angular...

Page 250: ...pen delta connected secondary of VTs The zero sequence V_0 or auxiliary voltage Vx accordingly must be higher than the PRODUCT SETUP ÖØ DIS PLAY PROPERTIES ÖØ VOLTAGE CUT OFF LEVEL value to be validated for use as a polarizing signal If the polarizing signal is invalid neither forward nor reverse indication is given If Current polarizing is selected the element uses the ground current angle connec...

Page 251: ... 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 offset impedance is to guarantee correct identification of fault direction on series compensated lines In regular applications the offset impedance ensures proper operation even if the ze...

Page 252: ...EUTRAL DIR OC1 OP CURR NEUTRAL DIR OC1 FWD NEUTRAL DIR OC1 REV Disabled 0 Measured VX Voltage Calculated V_0 Current Ground Crt IG Zero Seq Crt I_0 Dual NOTE 1 CURRENT POLARIZING IS POSSIBLE ONLY IN RELAYS WITH THE GROUND CURRENT INPUTS CONNECTED TO AN ADEQUATE CURRENT POLARIZING SOURCE 2 GROUND CURRENT CAN NOT BE USED FOR POLARIZATION AND OPERATION SIMULTANEOUSLY 3 POSITIVE SEQUENCE RESTRAINT IS ...

Page 253: ...tion is made the auxiliary channel must be identified by the user as a neutral voltage under the VT bank settings This element will operate only if the aux iliary voltage is configured as neutral WATTMETRIC GROUND FAULT 1 WATTMETRIC GND FLT 1 FUNCTION Disabled Range Disabled Enabled MESSAGE WATTMETRIC GND FLT 1 SOURCE SRC 1 Range SRC 1 SRC 2 MESSAGE WATTMETRIC GND FLT 1 VOLT Calculated VN Range Ca...

Page 254: ... equations A value of 1 pu represents the product of a 1 pu voltage as specified in the overvolt age condition for this element and a 1 pu current as specified in the overcurrent condition for this element WATTMETRIC GND FLT 1 ECA This setting adjusts the maximum torque angle of the element The operating power is calculated as EQ 5 18 where indicates complex conjugate By varying the element charac...

Page 255: ...CDR SETTINGS WATTMETRIC GND FLT 1 FUNCTION Enabled 1 AND WATT GND FLT 1 BLK Off 0 SETTINGS WATTMETRIC GND FLT 1 SOURCE Neutral In Ground Ig Neutral Vn Auxiliary Vx WATTMETRIC GND FLT 1 CURRENT Calculated Measured WATTMETRIC GND FLT 1 VOLTAGE Calculated Measured SETTING WATTMETRIC GND FLT 1 ECA S V conj I exp j ECA SETTINGS WATTMETRIC GND FLT 1 OC PICKUP WATTMETRIC GND FLT 1 OV PICKUP SOP PWR PICKU...

Page 256: ...d 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 60 GROUND TOC1 SCHEME LOGIC GROUND TOC1 GROUND TOC1 FUNCTION Disabled Range Disabled Enabled MESSAGE GROUND TOC1 SIGNAL SOURCE SRC 1 Range SRC 1 SRC 2 MESSAGE GROUND TOC1 INPUT Phasor Range Phasor RMS...

Page 257: ...channel is from 0 002 to 4 6 times the CT rating Figure 5 61 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 MESSAGE GROUND IOC1 PICKUP 1 000 pu Range 0 000 to 30 000 pu in steps of 0 001 MESSAGE GROUND IOC1 PICKUP DELAY 0 00 s Range 0 00 to 600 00 s in steps of 0 01 MESSAGE GROUND IOC1 RESET DELAY ...

Page 258: ...egative sequence instantaneous overcurrent elements and two 2 negative sequence directional overcurrent elements For additional information on the negative sequence time overcurrent curves refer to the Inverse Time Overcurrent Curves section earlier NEGATIVE SEQUENCE CURRENT NEG SEQ TOC1 See page 5 133 MESSAGE NEG SEQ TOC2 See page 5 133 MESSAGE NEG SEQ IOC1 See page 5 134 MESSAGE NEG SEQ IOC2 See...

Page 259: ...r will be cleared immediately Figure 5 62 NEGATIVE SEQUENCE TOC1 SCHEME LOGIC NEG SEQ TOC1 NEG SEQ TOC1 FUNCTION Disabled Range Disabled Enabled MESSAGE NEG SEQ TOC1 SIGNAL SOURCE SRC 1 Range SRC 1 SRC 2 MESSAGE NEG SEQ TOC1 PICKUP 1 000 pu Range 0 000 to 30 000 pu in steps of 0 001 MESSAGE NEG SEQ TOC1 CURVE IEEE Mod Inv Range see OVERCURRENT CURVE TYPES table MESSAGE NEG SEQ TOC1 TD MULTIPLIER 1...

Page 260: ...hase faults The positive sequence restraint must be considered when testing for pickup accuracy and response time multiple of pickup The operating quantity depends on the way the test currents are injected into the relay single phase injection three phase injection opposite rotation Figure 5 63 NEGATIVE SEQUENCE IOC1 SCHEME LOGIC NEG SEQ IOC1 NEG SEQ IOC1 FUNCTION Disabled Range Disabled Enabled M...

Page 261: ...current magnitude respectively when form ing the element operating quantity EQ 5 22 The positive sequence restraint allows for more sensitive settings by counterbalancing spurious negative and zero sequence currents resulting from System unbalances under heavy load conditions Transformation errors of current transformers CTs Fault inception and switch off transients NEG SEQ DIR OC1 NEG SEQ DIR OC1...

Page 262: ...ith the ECA for operation The element incorporates a current reversal logic if the reverse direction is indicated for at least 1 25 of a power system cycle the prospective forward indication will be delayed by 1 5 of a power system cycle The element is designed to emu late an electromechanical directional device Larger operating and polarizing signals will result in faster directional discrimi nat...

Page 263: ...in the reverse direction is the angle set for the forward direction shifted by 180 NEG SEQ DIR OC1 FWD LIMIT ANGLE This setting defines a symmetrical in both directions from the ECA limit angle for the forward direction NEG SEQ DIR OC1 FWD PICKUP This setting defines the pickup level for the overcurrent unit in the forward direc tion Upon NEG SEQ DIR OC1 TYPE selection this pickup threshold applie...

Page 264: ...KUP 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 to...

Page 265: ... 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 sh...

Page 266: ...nserts 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 m...

Page 267: ...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 268: ...imately 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 269: ...NITIATE BF1 PH C INITIATE BKR FAIL 1 RETRIPA TRIP PHASE C In D60 L60 and L90 only From Trip Output TRIP PHASE B TRIP 3 POLE TRIP PHASE A BKR FAIL 1 RETRIPB BKR FAIL 1 RETRIPC BF1 SOURCE BF1 PH AMP SUPV PICKUP IA IA PICKUP RUN IB IB PICKUP RUN IC IC PICKUP RUN Off 0 Off 0 Off 0 Off 0 Enable 1 Off 0 YES 1 YES 1 Disable 0 NO 0 NO 0 AND OR OR OR OR OR AND OR OR OR OR OR OR AND AND AND AND OR AND AND T...

Page 270: ...F1 USE TIMER 1 BF1 USE TIMER 2 BF1 USE TIMER 3 BF1 BKR POS1 A 3P BF1 BKR POS2 A 3P BF1 BKR POS1 B BF1 BKR POS2 B BF1 BKR POS1 C BF1 BKR POS2 C BF1 TIMER 3 PICKUP DELAY BF1 TRIP DROPOUT DELAY BKR FAIL 1 TRIP OP BKR FAIL 1 T3 OP 827070A4 CDR BKR FAIL 1 T2 OP BKR FAIL 1 T1 OP BF1 TIMER 2 PICKUP DELAY BF1 TIMER 1 PICKUP DELAY BF1 BREAKER TEST ON FROM SHEET 1 OF 2 827069 CDR BF1 PH AMP HISET PICKUP BF1...

Page 271: ...GE Multilin F60 Feeder Protection System 5 145 5 SETTINGS 5 5 GROUPED ELEMENTS 5 Figure 5 70 BREAKER FAILURE 3 POLE INITIATE Sheet 1 of 2 ...

Page 272: ...5 146 F60 Feeder Protection System GE Multilin 5 5 GROUPED ELEMENTS 5 SETTINGS 5 Figure 5 71 BREAKER FAILURE 3 POLE TIMERS Sheet 2 of 2 ...

Page 273: ...sed to block the functioning of other elements 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 volta...

Page 274: ...own below EQ 5 23 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 72 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 275: ... Phase MESSAGE PHASE UV1 PICKUP 1 000 pu Range 0 000 to 3 000 pu in steps of 0 001 MESSAGE PHASE UV1 CURVE Definite Time Range Definite Time Inverse Time MESSAGE PHASE UV1 DELAY 1 00 s Range 0 00 to 600 00 s in steps of 0 01 MESSAGE PHASE UV1 MINIMUM VOLTAGE 0 100 pu Range 0 000 to 3 000 pu in steps of 0 001 MESSAGE PHASE UV1 BLOCK Off Range FlexLogic operand MESSAGE PHASE UV1 TARGET Self reset Ra...

Page 276: ...u 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 PHASE OV1 EVENTS Disabled Range Disabled Enabled PHASE OV1 SOURCE Sourc...

Page 277: ...xCurves A B or C or be used as a definite time element The NEUTRAL OV1 PICKUP DELAY setting applies only if the NEUTRAL OV1 CURVE setting is Definite time The source assigned to this 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 75 NEUTRAL OVERVOLTAGE1 SCHEME ...

Page 278: ...V1 SIGNAL SOURCE SRC 1 Range SRC 1 SRC 2 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 reset Latched Disab...

Page 279: ...racteristics 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 77 AUXILIARY UNDERVOLTAGE SCHEME LOGIC AUXILIARY UV1 AUX UV1 FUNCTION Disabled Range Disabled Enabled MESSAGE AUX UV1 SIGNA...

Page 280: ...corner delta VT connection Figure 5 78 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 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 600 00 s i...

Page 281: ... and reactive powers as measured per the UR series metering convention θ 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 Ö METERING ÖØ SENSITIVE DIRECTIONAL POWER 1 2 actual value The element has two independent as to the pickup and delay settings s...

Page 282: ...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 80 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 283: ...ly a shift towards the operate region along the RCA line the negative values imply a shift towards the 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 VT pu...

Page 284: ...group 1 the default active group because group 1 automatically becomes active if no other group is active The SETTING GROUP 1 NAME to SETTING GROUP 6 NAME settings allows to user to assign a name to each of the six settings groups Once programmed this name will appear on the second line of the GROUPED ELEMENTS Ö SETTING GROUP 1 6 menu display The relay can be set up via a FlexLogic equation to rec...

Page 285: ...Range Time out Acknowledge MESSAGE SELECTOR 1 ACK Off Range FlexLogic operand MESSAGE SELECTOR 1 3BIT A0 Off Range FlexLogic operand MESSAGE SELECTOR 1 3BIT A1 Off Range FlexLogic operand MESSAGE SELECTOR 1 3BIT A2 Off Range FlexLogic operand MESSAGE SELECTOR 1 3BIT MODE Time out Range Time out Acknowledge MESSAGE SELECTOR 1 3BIT ACK Off Range FlexLogic operand MESSAGE SELECTOR 1 POWER UP MODE Res...

Page 286: ...t take place and an alarm will be set SELECTOR 1 STEP UP This setting specifies a control input for the selector switch The switch is shifted to a new position at each rising edge of this signal The position changes incrementally wrapping up from the last SELECTOR 1 FULL RANGE to the first position 1 Consecutive pulses of this control operand must not occur faster than every 50 ms After each risin...

Page 287: ...ELEC TOR TIME OUT setting after the last activity of the three bit control inputs Note that the stepping up control input and three bit control input have independent acknowledging signals SELECTOR 1 ACK and SELECTOR 1 3BIT ACK accord ingly SELECTOR 1 POWER UP MODE This setting specifies the element behavior on power up of the relay When set to Restore the last position of the selector stored in t...

Page 288: ...se diagrams T represents a time out setting Figure 5 83 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 289: ...d synchronize the setting group to the three bit control input Make the following changes to setting group control in the SETTINGS ÖØ CONTROL ELEMENTS Ö 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 foll...

Page 290: ...wing changes in the SETTINGS Ö PRODUCT SETUP ÖØ USER PROGRAMMABLE PUSHBUTTONS Ö 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 85 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 SELEC...

Page 291: ...parameter 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 pic...

Page 292: ...rip The 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 87 OVERF...

Page 293: ...itive sequence voltage Overvoltage supervision should be used to pre vent operation under specific system conditions such as faults FREQ RATE 1 OC SUPV PICKUP This setting defines minimum current level required for operation of the element The supervising function responds to the positive sequence current Typical application includes load shedding Set the pickup threshold to zero if no overcurrent...

Page 294: ...n frequency For example if the intent is to mon itor a decreasing trend but only if the frequency is already below certain level such as for load shedding this setting should be set to the required frequency level Figure 5 88 FREQUENCY RATE OF CHANGE SCHEME LOGIC V_1 PICKUP FREQ RATE 1 BLOCK Off RUN FREQ RATE 1 SOURCE Pos seq voltage V_1 FREQ RATE 1 FUNCTION SETTINGS Enabled 1 Pos seq current I_1 ...

Page 295: ... equal to the frequency difference ΔF This time can be calculated by EQ 5 25 where ΔΦ phase angle difference in degrees ΔF frequency difference in Hz SYNCHROCHECK 1 SYNCHK1 FUNCTION Disabled Range Disabled Enabled MESSAGE SYNCHK1 BLOCK Off Range FlexLogic operand MESSAGE SYNCHK1 V1 SOURCE SRC 1 Range SRC 1 SRC 2 MESSAGE SYNCHK1 V2 SOURCE SRC 2 Range SRC 1 SRC 2 MESSAGE SYNCHK1 MAX VOLT DIFF 10000 ...

Page 296: ...the combination of dead and live sources that will by pass synchronism check function and permit the breaker to be closed when one or both of the two voltages V1 or and V2 are below the maximum voltage threshold A dead or live source is declared by monitoring the voltage level Six options are available None Dead Source function is disabled LV1 and DV2 Live V1 and Dead V2 DV1 and LV2 Dead V1 and Li...

Page 297: ...ith both phase voltages and an auxiliary voltage ensure that only the auxiliary voltage is programmed in one of the sources to be used for synchrocheck Exception Synchronism cannot be checked between Delta connected phase VTs and a Wye con nected auxiliary voltage 2 The relay measures frequency and Volts Hz from an input on a given source with priorities as established by the con figuration of inp...

Page 298: ...ESIS SYNCHK1 MAX FREQ DIFF Magnitude V2 SYNC1 SYNC1 V SYNC1 F Magnitude V1 Angle 2 Angle 1 827076AA CDR SYNC1 DEAD S OP SYNC1 V1 BELOW MAX SYNC1 V2 ABOVE MIN SYNC1 CLS OP SYNC1 SYNC OP SYNC1 DEAD S DPO SYNC1 V2 BELOW MAX SYNC1 V1 ABOVE MIN SYNC1 CLS DPO SYNC1 SYNC DPO SYNCHK1 LIVE V2 MIN VOLT SYNCHK1 LIVE V1 MIN VOLT SYNCHK1 DEAD V2 MAX VOLT SYNCHK1 DEAD V1 MAX VOLT SYNCHK1 DEAD SOURCE SELECT LV1 ...

Page 299: ...NL RST FRM LO Off Range FlexLogic operand MESSAGE AR1 RESET LOCKOUT IF BREAKER CLOSED Off Range Off On MESSAGE AR1 RESET LOCKOUT ON MANUAL CLOSE Off Range Off On MESSAGE AR1 BKR CLOSED Off Range FlexLogic operand MESSAGE AR1 BKR OPEN Off Range FlexLogic operand MESSAGE AR1 BLK TIME UPON MNL CLS 10 000 s Range 0 00 to 655 35 s in steps of 0 01 MESSAGE AR1 DEAD TIME 1 1 000 s Range 0 00 to 655 35 s ...

Page 300: ...e is initiated provided the circuit breaker is in the closed state before protection operation The reclose in progress RIP is set when a reclosing cycle begins following a reclose initiate signal Once the cycle is suc cessfully initiated the RIP signal will seal in and the scheme will continue through its sequence until one of the following conditions is satisfied The close signal is issued when t...

Page 301: ...me to reset from Lockout when the breaker is manually closed regardless if the breaker remains closed or not This setting overrides the previ ous setting AR1 RESET LOCKOUT IF BREAKER CLOSED AR1 BLK TIME UPON MNL CLS The autoreclose scheme can be disabled for a programmable time delay after the associated circuit breaker is manually closed This prevents reclosing onto a fault after a manual close T...

Page 302: ...1 On 1 Off 0 Off 0 Off 0 Disable 0 AR1 ENABLED AR1 DISABLED AR1 BLK FROM MAN CLS Enabled Default Disabled Default AR1 RIP AR1 LO LO AND AND AND AND OR O O O O O O O O Off 0 Off 0 SETTING SETTING SETTING SETTING SETTING SETTING SETTING SETTING SETTING SETTING SETTING AR1 BLK TIME UPON MNL CLOSE AR1 RESET LOCKOUT DELAY AR1 DEAD TIME 4 AR1 DELAY 1 AR1 DELAY 2 AR1 ADD DELAY 1 AR1 ADD DELAY 2 Shot cnt ...

Page 303: ...3 AR1 SHOT CNT 1 AR1 SHOT CNT 0 Increment shot counter Shot cnt 2 Shot cnt 1 Shot cnt 0 Reset shot counter Shot cnt 3 AUTORECLOSE 1 SHOT COUNT 0 1 2 3 4 AR1 CLOSE AND AND AND AND AND AND AND AND 100 ms AND OR OR OR OR OR OR OR OR SETTING SETTING SETTING SETTING SETTING AR1 RESET TIME AR1 MAX NUMBER OF SHOTS AR1 REDUCE MAX TO 1 AR1 REDUCE MAX TO 2 AR1 REDUCE MAX TO 3 MAX 1 Off 0 Off 0 Off 0 MAX 2 M...

Page 304: ...ARATE OPENING TIME CLOSING TIME PROT TIME OPENING TIME PROT TIME ARC EXTINGUISHES ARC EXTINGUISHES CLOSE COMMAND CLOSED COMMAND BKR CLOSED AR INITIATE AR GOES TO LOCKOUT SHOT COUNT MAX RESET FROM LOCKOUT AR ENABLED LOCKOUT RIP INCOMPL SEQ TIMING RESET TIMER IS TIMING INCOMPLETE SEQUENCE IS TIMING DEAD TIME RECLOSE IN PROGRESS CONTACTS CLOSE TRIP COMMAND CONTACTS SEPARATE BKR OPEN AR ENABLED AUTO R...

Page 305: ...GITAL ELEMENT SCHEME LOGIC CIRCUIT MONITORING APPLICATIONS Some versions of the digital input modules 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 DIGITAL ELEMENT 1 DIGITAL ELEMENT 1 FUNCTION Disabled Range Disabled Enabled MESSAGE DIG ELEM 1 NAME ...

Page 306: ...of the breaker trip coil If the circuit presents a high resis tance the trickle current will fall below the monitor threshold and an alarm would be declared In most breaker control circuits the trip coil is connected in series with a breaker auxiliary contact which is open when the breaker is open see diagram below To prevent unwanted alarms in this situation the trip circuit monitoring logic must...

Page 307: ...ved by connecting a suitable resistor see 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 95 TRIP CIRCUIT EXAMPLE 2 Trip Coil 52a V I H1a H1c H1b UR Relay Form A V Voltage ...

Page 308: ...al to 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...

Page 309: ...for capturing freezing the accumulated count value into a separate register with the date and time of the operation and resetting the count to 0 COUNTER 1 FREEZE COUNT Selects the FlexLogic operand for capturing freezing the accumulated count value into a separate register with the date and time of the operation and continuing counting The present accumulated value and captured frozen value with t...

Page 310: ...IPIENT FAULT 1 See page 5 198 MESSAGE INCIPIENT FAULT 2 See page 5 198 MESSAGE VT FUSE FAILURE 1 See page 5 200 MESSAGE VT FUSE FAILURE 2 See page 5 200 HI Z HI Z FUNCTION Disabled Range Disabled Enabled MESSAGE HI Z SOURCE SRC 1 Range SRC 1 SRC 2 MESSAGE HI Z ARCING SENSITIVITY 5 Range 1 to 10 in steps of 1 MESSAGE HI Z ARCING DET SOE RESET TIME 0 0 s Range 0 0 to 6000 0 s in steps of 0 1 MESSAGE...

Page 311: ...ver there are no guarantees of certain operation of the high impedance fault detection element on non solidly grounded systems The Hi Z data collection consists of RMS Data Capture and Hi Z Data capture RMS Data Capture The RMS data captures are triggered by two cycle Hi Z overcurrent conditions loss of load con ditions and high arc confidence conditions Captures triggered by loss of load and high...

Page 312: ...r the phase 3 RmsCurrent The 2 cycle RMS current for the phase 4 HighROC Flag indicating a high rate of change was detected 5 IOC Flag indicating an instantaneous 2 cycle overcurrent was detected 6 LossOfLoad Flag indicating a loss of load was detected 7 EadZeroed Flag indicating that this phase s EAD table was cleared 8 HighZArmed Flag indicating that this phase is armed for a high Z detection 9 ...

Page 313: ...Specifies how many individual belief in arcing indications for a phase current must be counted in a specified time period before it is determined that an arcing suspected event exists These belief in arcing indications are detected by arc detection algorithms energy and randomness for a specific set of non fundamental frequency component energies This setting affects only the Hi Z Arcing Suspected...

Page 314: ...tage drop in phase current between two successive two cycle RMS values that equals or exceeds the Loss of Load Threshold The amount the phase current must decrease between successive two cycle RMS values is based on this setting times the recent average phase current level The range is 5 to 100 5 being the most sensitive HI Z 3 PHASE EVENT THRESHOLD Establishes the level at which the Hi Z element ...

Page 315: ...ING EAD COUNT LIMIT HI Z GROUND EVENT COUNT INDIRECT SETTING EAD THRESHOLD HI Z EVENT COUNT TIME IA RMS VA RMS VB RMS VC RMS IB RMS IC RMS IG RMS Enabled 1 Disabled 0 OR OR RUN RUN RUN RUN RUN RUN RUN RUN RUN LOAD EVENT DETECTOR ALGORITHM EVEN HARM RESTR ALG VOLTAGE SUPERVISION ALG IA Threshold IB Threshold IC Threshold IA Threshold IB Threshold IC Threshold IA PKP IB PKP IC PKP IG PKP IA Threshol...

Page 316: ...ns Fault duration is defined as a time between operation of the disturbance detector occurring before initiation of this feature and reset of an internal low set overcurrent function Cor rection is implemented to account for a non zero reset time of the overcurrent function Breaker arcing currents and fault duration values are available under the ACTUAL VALUES ÖØ RECORDS ÖØ MAINTENANCE Ö BREAKER 1...

Page 317: ...MP BLOCK BREAKER 1 ARCING AMP INIT A BREAKER 1 ARCING AMP INIT B BREAKER 1 ARCING AMP INIT C BREAKER 1 ARCING AMP LIMIT CLEAR BREAKER 1 ARCING AMPS BKR 1 ARCING AMP A Φ BKR 1 OPERATING TIME A Φ BKR 1 OPERATING TIME B Φ BKR 1 OPERATING TIME C Φ BKR 1 OPERATING TIME BKR 1 ARCING AMP B Φ BKR 1 ARCING AMP C Φ BKR1 ARC OP BKR1 ARC DPO BREAKER 1 ARCING AMP SOURCE IA IB IC Off 0 Off 0 Off 0 Off 0 NO 0 YE...

Page 318: ...ESSAGE BKR 1 FLSHOVR SIDE 2 SRC None Range None SRC 1 SRC 2 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 FLSHO...

Page 319: ... VBg or VCg is greater than the pickup setting 3 IA IB IC 0 no current flows through the breaker 4 ΔVA is greater than pickup not applicable in this scheme The conditions at flashover detection are 1 52a status 0 2 VAg VBg or VCg is lower than the pickup setting 3 IA IB or IC is greater than the pickup current flowing through the breaker 4 ΔVA is greater than pickup not applicable in this scheme S...

Page 320: ...ds to indicate the open status of the breaker A separate FlexLogic operand can be selected to detect individual breaker pole status and provide 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 avai...

Page 321: ...BRK 1 FLSHOVR OP B BRK 1 FLSHOVR DPO C BRK 1 FLSHOVR PKP C BRK 1 FLSHOVR OP C BRK 1 FLSHOVR SUPV A BRK 1 STATUS CLSD B BRK 1 FLSHOVR SUPV B BRK 1 STATUS CLSD C BRK 1 FLSHOVR SUPV C BRK 1 FLSHOVR AMP PKP BRK 1 FLSHOVR DIFF V PKP BRK 1 FLSHOVR SIDE 1 SRC BRK 1 FLSHOVR SIDE 2 SRC Enable 1 RUN RUN RUN RUN RUN RUN SRC 1 SRC 2 SRC 6 SRC 1 SRC 2 SRC 6 none VB Vb IB Block OFF 0 VA PKP FlexLogic operand On...

Page 322: ...lared in the corresponding phase and the BRK RESTRIKE 1 OP operand is asserted for a short period of time The user can add coun ters and other logic to facilitate the decision making process as to the appropriate actions upon detecting a single restrike or a series of consecutive restrikes A restrike event FlexLogic operand is declared if all of the following hold BREAKER RESTRIKE 1 BREAKER RESTRI...

Page 323: ...AKER RESTRIKE 1 SOURCE This setting selects the source of the current for this element This source must have a valid CT bank assigned BREAKER RESTRIKE 1 PICKUP This setting specifies the pickup level of the overcurrent detector in per unit values of CT nominal current BREAKER RESTRIKE 1 RESET DELAY This setting specifies the reset delay for this element When set to 0 ms then FlexLogic operand will...

Page 324: ...NT FAULT 1 PICKUP 0 50 pu Range 0 10 to 10 00 pu in steps of 0 01 MESSAGE INCIPNT FLT 1 MODE Number of counts Range Number of counts Counts per window MESSAGE INCIPIENT FLT 1 TRIP COUNTS NUMBER 2 Range 1 to 10 in steps of 1 MESSAGE INCIPNT FLT 1 DETECT WINDOW 10 00 s Range 0 00 to 1000 00 s in steps of 0 01 MESSAGE INCIPIENT FAULT 1 RESET DELAY 0 100 s Range 0 000 to 65 535 s in steps of 0 001 MES...

Page 325: ...R ALGORITHM The following settings are available for each incipient cable fault detector INCIPIENT FAULT 1 FUNCTION This setting enable and disables operation of the incipient fault detection element INCIPNT FLT 1 BLOCK This setting is used to block operation of the incipient cable fault detector element Assertion of the FlexLogic operand assigned to this setting block operation INCIPIENT FAULT 1 ...

Page 326: ... be present when faults are present on the system so a means of detecting faults and inhibiting fuse failure declarations during these events is pro vided Once the fuse failure condition is declared it will be sealed in until the cause that generated it disappears An additional condition is introduced to inhibit a fuse failure declaration when the monitored circuit is de energized positive sequenc...

Page 327: ...l can be above the pickup setting of some protection elements so this feature can be used to prevent the tripping that would otherwise be caused by the normal settings COLD LOAD PICKUP 1 COLD LOAD 1 FUNCTION Disabled Range Disabled Enabled MESSAGE COLD LOAD 1 PICKUP SOURCE SRC 1 Range SRC 1 SRC 2 MESSAGE COLD LOAD 1 INIT Off Range FlexLogic operand MESSAGE COLD LOAD 1 BLK Off Range FlexLogic opera...

Page 328: ...ups are not changed for short duration outages After the delay interval the output operand is set The second initiation method is intended to automatically respond to an event that will set an operand such as an operator initiated virtual input This second method of initiation sets the output operand immediately Both initiating inputs can be inhibited by a blocking input Once cold load pickup is i...

Page 329: ... 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 BUS 1 BLOCK Off Range FlexLogic operand MESSAGE TRIP BUS 1 PICKUP DELAY 0 00 s Range 0 00 to 60...

Page 330: ...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 331: ...ser settable debounce time in order for the F60 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 v...

Page 332: ...lter 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 5 111 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 c...

Page 333: ...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 a ...

Page 334: ... prevent 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 ...

Page 335: ... 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 following sett...

Page 336: ...UR Setup example shown Program the Latching Outputs by making the following changes in the SETTINGS ÖØ INPUTS OUTPUTS ÖØ CONTACT OUT PUTS Ö CONTACT OUTPUT H1a menu assuming an H4L module OUTPUT H1a OPERATE VO1 OUTPUT H1a RESET VO2 5 7 4 VIRTUAL OUTPUTS PATH SETTINGS ÖØ INPUTS OUTPUTS ÖØ VIRTUAL OUTPUTS Ö VIRTUAL OUTPUT 1 96 There are 96 virtual outputs that may be assigned via FlexLogic If not ass...

Page 337: ...ovides 32 of the 96 available UserSt bit pairs The IEC 61850 specification 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 ...

Page 338: ...gh DNA 32 and UserSt 1 through UserSt 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 appropriate FlexLogic ...

Page 339: ... state of a specific FlexLogic oper and The above operand setting represents a specific DNA function as shown in the following table to be transmitted b USERST BIT PAIRS PATH SETTINGS ÖØ INPUTS OUTPUTS ÖØ REMOTE OUTPUTS UserSt BIT PAIRS Ö REMOTE OUTPUTS UserSt 1 32 BIT PAIR Remote outputs 1 to 32 originate as GSSE GOOSE messages to be transmitted to remote devices Each digital point in the message...

Page 340: ...ECT INPUT 1 DEVICE ID represents the source of direct input 1 The specified direct input is driven by the device identified here The DIRECT INPUT 1 BIT NUMBER is the bit number to extract the state for direct input 1 Direct Input 1 is driven by the bit identified as DIRECT INPUT 1 BIT NUMBER This corresponds to the direct output number of the sending device The DIRECT INPUT 1 DEFAULT STATE represe...

Page 341: ...quirements The two IEDs are connected via single channel digital communication cards as shown below Figure 5 113 INPUT AND OUTPUT EXTENSION VIA DIRECT INPUTS AND OUTPUTS Assume contact input 1 from UR IED 2 is to be used by UR IED 1 The following settings should be applied Direct Input 5 and bit number 12 are used as an example The Cont Ip 1 On operand of UR IED 2 is now available in UR IED 1 as D...

Page 342: ...RECT INPUT 8 DEFAULT STATE select On for security select Off for dependability DIRECT INPUT 9 DEVICE ID 4 DIRECT INPUT 9 BIT NUMBER 3 DIRECT INPUT 9 DEFAULT STATE select On for security select Off for dependability Now the three blocking signals are available in UR IED 1 as DIRECT INPUT 7 ON DIRECT INPUT 8 ON and DIRECT INPUT 9 ON Upon losing communications or a device the scheme is inclined to bl...

Page 343: ... DEVICE ID 1 DIRECT INPUT 5 BIT NUMBER 2 DIRECT INPUT 6 DEVICE ID 3 DIRECT INPUT 6 BIT NUMBER 2 DIRECT OUT 2 OPERAND HYB POTT TX1 DIRECT OUT 3 OPERAND DIRECT INPUT 5 forward a message from 1 to 3 DIRECT OUT 4 OPERAND DIRECT INPUT 6 forward a message from 3 to 1 Signal flow between the three IEDs is shown in the figure below Figure 5 117 SIGNAL FLOW FOR DIRECT INPUT AND OUTPUT EXAMPLE 3 In three te...

Page 344: ... The teleprotection function must be enabled to utilize the inputs b TELEPROTECTION INPUTS PATH SETTINGS ÖØ INPUTS OUTPUTS ÖØ TELEPROTECTION Ö TELEPROT INPUTS Setting the TELEPROT INPUT DEFAULT setting to On defaults the input to logic 1 when the channel fails A value of Off defaults the input to logic 0 when the channel fails The Latest On and Latest Off values freeze the input in case of lost co...

Page 345: ...EPROT OUTPUT 2 1 Off Range FlexLogic operand MESSAGE TELEPROT OUTPUT 2 2 Off Range FlexLogic operand MESSAGE TELEPROT OUTPUT 2 16 Off Range FlexLogic operand 842750A2 CDR TELEPROT OUTPUT 1 1 same for 1 2 1 16 TELEPROT INPUT 1 1 DEFAULT same for 1 2 1 16 Off Flexlogic Operand TELEPRO INPUT 1 1 On same for 1 2 1 16 UR 1 Teleprotection I O Enabled Communication channel 1 On Off ACTUAL VALUES CHANNEL ...

Page 346: ... 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 347: ...re automatically generated for every channel available in the specific relay as shown above for the first channel of a type 5C transducer module installed in the first available slot The function of the channel may be either Enabled or Disabled If Disabled there will not be an actual value created for the channel An alphanumeric ID is assigned to the channel this ID will be included in the channel...

Page 348: ...2 37 12 12 90 194 134 70 191 64 159 70 12 51 100 212 138 50 200 64 167 20 12 90 110 230 142 29 209 85 174 87 13 28 120 248 146 06 219 29 182 75 13 67 130 266 149 82 228 96 190 80 14 06 140 284 153 58 238 85 199 04 14 44 150 302 157 32 248 95 207 45 14 83 160 320 161 04 259 30 216 08 15 22 170 338 164 76 269 91 224 92 15 61 180 356 168 47 280 77 233 97 16 00 190 374 172 46 291 96 243 30 16 39 200 3...

Page 349: ...Q 5 27 The feature is intentionally inhibited if the MAX VAL and MIN VAL settings are entered incorrectly e g when MAX VAL MIN VAL 0 1 pu The resulting characteristic is illustrated in the following figure Figure 5 119 DCMA OUTPUT CHARACTERISTIC The dcmA output settings are described below DCMA OUTPUT H1 SOURCE This setting specifies an internal analog value to drive the analog output Actual value...

Page 350: ...llowing settings should be entered DCMA OUTPUT H1 SOURCE SRC 1 P DCMA OUTPUT H1 RANGE 1 to 1 mA DCMA OUTPUT H1 MIN VAL 1 247 pu DCMA OUTPUT H1 MAX VAL 1 247 pu With the above settings the output will represent the power with the scale of 1 mA per 20 65 MW The worst case error for this application can be calculated by superimposing the following two sources of error 0 5 of the full scale for the an...

Page 351: ...s chapter for additional details is EQ 5 36 The minimum and maximum voltage values to be monitored in pu are EQ 5 37 The following settings should be entered DCMA OUTPUT H3 SOURCE SRC 2 V_1 mag DCMA OUTPUT H3 RANGE 0 to 1 mA DCMA OUTPUT H3 MIN VAL 0 404 pu DCMA OUTPUT H3 MAX VAL 0 635 pu The limit settings differ from the expected 0 7 pu and 1 1 pu because the relay calculates the positive sequenc...

Page 352: ... and output using the force contact inputs and force contact outputs test functions described in the follow ing sections 5 9 2 FORCE CONTACT INPUTS PATH SETTINGS ÖØ TESTING ÖØ FORCE CONTACT INPUTS The relay digital inputs contact inputs could be pre programmed to respond to the test mode in the following ways If set to Disabled the input remains fully operational It is controlled by the voltage ac...

Page 353: ...pen 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 ÖØ TESTING Ö TEST MODE menu TEST MODE FUNCTION Enabled and TEST MOD...

Page 354: ...5 228 F60 Feeder Protection System GE Multilin 5 9 TESTING 5 SETTINGS 5 ...

Page 355: ...CONTACT OUTPUTS See page 6 4 VIRTUAL OUTPUTS See page 6 5 AUTORECLOSE See page 6 5 REMOTE DEVICES STATUS See page 6 5 REMOTE DEVICES STATISTICS See page 6 5 DIGITAL COUNTERS See page 6 7 SELECTOR SWITCHES See page 6 7 FLEX STATES See page 6 7 ETHERNET See page 6 7 HIZ STATUS See page 6 8 DIRECT INPUTS See page 6 8 DIRECT DEVICES STATUS See page 6 9 EGD PROTOCOL STATUS See page 6 9 TELEPROT CH TEST...

Page 356: ...XELEMENTS See page 6 22 IEC 61850 GOOSE ANALOGS See page 6 23 WATTMETRIC GROUND FAULT 1 See page 6 23 WATTMETRIC GROUND FAULT 2 See page 6 23 TRANSDUCER I O DCMA INPUTS See page 6 23 TRANSDUCER I O RTD INPUTS See page 6 23 ACTUAL VALUES RECORDS FAULT REPORTS See page 6 24 EVENT RECORDS See page 6 24 OSCILLOGRAPHY See page 6 25 DATA LOGGER See page 6 25 MAINTENANCE See page 6 26 HIZ RECORDS See pag...

Page 357: ...ates the ID of the virtual input For example Virt Ip 1 refers to the virtual input in terms of the default name The second line of the display indicates the logic state of the virtual input 6 2 3 REMOTE INPUTS PATH ACTUAL VALUES Ö STATUS ÖØ REMOTE INPUTS The present state of the 32 remote inputs is shown here The state displayed will be that of the remote point unless the remote device has been es...

Page 358: ...utput 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 VOn and IOn 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...

Page 359: ...e present state of up to 16 programmed remote devices is shown here The ALL REMOTE DEVICES ONLINE message indi cates 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 b STATISTICS PATH ACTUAL VALUES Ö STATUS ÖØ REMOTE DEVICES STATISTICS Ö REMOTE DEVICE 1 16 Statistical data two types for up to 16 programm...

Page 360: ...m the indicated remote device and is incremented whenever a change of state of at least one DNA or UserSt bit occurs The SqNum number is obtained from the indicated remote device and is incremented whenever a GSSE message is sent This number will rollover to zero when a count of 4 294 967 295 is incremented ...

Page 361: ...rent position only an integer from 0 through 7 is the actual value 6 2 11 FLEX STATES PATH ACTUAL VALUES Ö STATUS ÖØ FLEX STATES There are 256 FlexState bits available The second line value indicates the state of the given FlexState bit 6 2 12 ETHERNET PATH ACTUAL VALUES Ö STATUS ÖØ ETHERNET These values indicate the status of the primary and secondary Ethernet links DIGITAL COUNTERS Counter 1 Cou...

Page 362: ...ations channel count the direct output messages that do not make the trip around the communications ring The CRC FAIL COUNT values one per communications channel count the direct output messages that have been received but fail the CRC check High values for either of these counts may indicate on a problem with wiring the communication channel or one or more relays The UNRETURNED MSG COUNT and CRC ...

Page 363: ...t size for the fast EGD exchange is displayed b SLOW EXCHANGE PATH ACTUAL VALUES Ö STATUS ÖØ EGD PROTOCOL STATUS Ö PRODUCER STATUS ÖØ SLOW EXCHANGE 1 2 These values provide information that may be useful for debugging an EGD network The EGD signature and packet size for the slow EGD exchanges are displayed DIRECT DEVICES STATUS DIRECT DEVICE 1 STATUS Offline Range Offline Online MESSAGE DIRECT DEV...

Page 364: ... 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 value of 0 the chan nel is failed or if the teleprotection inputs outputs are not enabled 6 2 18 INCIPIENT FAULT DETECTOR PATH ACTUAL VALUES Ö STATUS ÖØ INCIPIENT FAULT Ö INCIPIENT FAULT 1 2 The number of detected inci...

Page 365: ...values represents the receiver status of each port on the Ethernet switch If the value is OK then data is being received from the remote terminal If the value is FAIL then data is not being received from the remote terminal or the port is not connected SWITCH MAC ADDRESS This value displays the MAC address assigned to the Ethernet switch module ETHERNET SWITCH SWITCH 1 PORT STATUS OK Range FAIL OK...

Page 366: ...ve 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 ...

Page 367: ...ion is not 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 SYMMETRICAL COMPONENTS The UR series of relays calculate voltage...

Page 368: ...lustrated 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...

Page 369: ...L VALUES ÖØ METERING Ö SOURCE SRC 1 Ö PHASE CURRENT SOURCE SRC 1 PHASE CURRENT SRC 1 See page 6 15 MESSAGE GROUND CURRENT SRC 1 See page 6 16 MESSAGE PHASE VOLTAGE SRC 1 See page 6 16 MESSAGE AUXILIARY VOLTAGE SRC 1 See page 6 17 MESSAGE POWER SRC 1 See page 6 17 MESSAGE ENERGY SRC 1 See page 6 18 MESSAGE DEMAND SRC 1 See page 6 18 MESSAGE FREQUENCY SRC 1 See page 6 19 MESSAGE CURRENT HARMONICS SR...

Page 370: ...ource see SETTINGS ÖØ SYSTEM SETUP ÖØ SIGNAL SOURCES d PHASE VOLTAGE METERING PATH ACTUAL VALUES ÖØ METERING Ö SOURCE SRC 1 Ö PHASE VOLTAGE MESSAGE SRC 1 PHASOR Ic 0 000 A 0 0 MESSAGE SRC 1 PHASOR In 0 000 A 0 0 MESSAGE SRC 1 ZERO SEQ I0 0 000 A 0 0 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 ...

Page 371: ...NGS ÖØ SYSTEM SETUP ÖØ SIGNAL SOURCES f POWER METERING PATH ACTUAL VALUES ÖØ METERING Ö SOURCE SRC 1 ÖØ POWER MESSAGE SRC 1 PHASOR Vab 0 000 V 0 0 MESSAGE SRC 1 PHASOR Vbc 0 000 V 0 0 MESSAGE SRC 1 PHASOR Vca 0 000 V 0 0 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...

Page 372: ...Ø SIGNAL SOURCES Because energy values are accumulated these values should be recorded and then reset immediately prior to changing CT or VT characteristics h DEMAND METERING PATH ACTUAL VALUES ÖØ METERING Ö SOURCE SRC 1 ÖØ DEMAND MESSAGE SRC 1 APPARENT PWR φa 0 000 VA MESSAGE SRC 1 APPARENT PWR φb 0 000 VA MESSAGE SRC 1 APPARENT PWR φc 0 000 VA MESSAGE SRC 1 POWER FACTOR 3φ 1 000 MESSAGE SRC 1 PO...

Page 373: ... ÖØ FREQUENCY The metered frequency values are displayed in this menu The SRC 1 text will be replaced by whatever name was pro grammed by the user for the associated source see SETTINGS ÖØ SYSTEM SETUP ÖØ 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 auxil...

Page 374: ...d on a per phase basis where N 64 is the number of samples per cycle ω0 2πf is the angular frequency based on the system frequency 50 or 60 Hz k 1 2 N 1 is the index over one cycle for the Fast Fourier Transform FFT m is the last sample number for the sliding window h 1 2 25 is the harmonic number The short time Fourier transform is applied to the unfiltered signal EQ 6 1 The harmonics are a perce...

Page 375: ...settings 6 3 4 SYNCHROCHECK PATH ACTUAL VALUES ÖØ METERING ÖØ SYNCHROCHECK Ö SYNCHROCHECK 1 2 The actual values menu for synchrocheck 2 is identical to that of synchrocheck 1 If a synchrocheck function setting is Dis abled the corresponding actual values menu item will not be displayed 6 3 5 TRACKING FREQUENCY PATH ACTUAL VALUES ÖØ METERING ÖØ TRACKING FREQUENCY The tracking frequency is displayed...

Page 376: ...d C BASE 2000 kA2 cycle dcmA BASE maximum value of the DCMA INPUT MAX setting for the two transducers configured under the IN and IN inputs FREQUENCY fBASE 1 Hz FREQUENCY RATE OF CHANGE df dtBASE 1 Hz s PHASE ANGLE ϕBASE 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 ...

Page 377: ...AL VALUES ÖØ METERING ÖØ WATTMETRIC GROUND FAULT 1 2 This menu displays the wattmetric zero sequence directional element operating power values 6 3 10 TRANSDUCER INPUTS OUTPUTS PATH ACTUAL VALUES ÖØ METERING ÖØ TRANSDUCER I O DCMA INPUTS Ö DCMA INPUT xx Actual 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 ...

Page 378: ...with up to the last 1024 events listed in chronological order from most recent to oldest If all 1024 event records have been filled the oldest record will be removed as a new record is added Each event record shows the event identifier sequence number cause and date time stamp associated with the event trigger Refer to the COMMANDS Ø CLEAR RECORDS menu for clearing event records NO FAULTS TO REPOR...

Page 379: ...cords 6 4 4 DATA LOGGER PATH ACTUAL VALUES ÖØ RECORDS ÖØ DATA LOGGER The OLDEST SAMPLE TIME represents the time at which the oldest available samples were taken It will be static until the log gets full at which time it will start counting at the defined sampling rate The NEWEST SAMPLE TIME represents the time the most recent samples were taken It counts up at the defined sampling rate If the data...

Page 380: ... condition then the records are displayed in the RMS 1 to RMS 4 actual values If the element is triggered by high impedance fault detection arcing algorithm then the records are dis played in the HIZ 1 to HIZ 4 actual values Refer to High impedance fault detection section in chapter 5 for more information BREAKER 1 BKR 1 ARCING AMP φA 0 00 kA2 cyc MESSAGE BKR 1 ARCING AMP φB 0 00 kA2 cyc MESSAGE B...

Page 381: ...SERIAL NUMBER Range standard GE multilin serial number format MESSAGE ETHERNET MAC ADDRESS 000000000000 Range standard 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 opearting time in HH MM SS MESSAGE LAST SETTING CHANGE 1970 01 01 23 11 19 Range YYYY MM DD HH MM SS FIRMWARE ...

Page 382: ...6 28 F60 Feeder Protection System GE Multilin 6 5 PRODUCT INFORMATION 6 ACTUAL VALUES 6 ...

Page 383: ...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 7 1 3 CLEAR RECORDS PATH COMMANDS ÖØ CLEAR RECORDS COMMANDS Ø MESSAGE COMMANDS VIRTUAL INPUTS MESSAGE COMMANDS CLEAR RECORDS MESSAGE COMMANDS SET DATE AND TIME MESSAGE COMMANDS RELAY ...

Page 384: ... command setting to Yes and pressing the ENTER key The command setting will then automatically revert to No The PERFORM LAMPTEST command turns on all faceplate LEDs and display pixels for a short duration The UPDATE ORDER CODE command causes the relay to scan the backplane for the hardware modules and update the order code to match If an update occurs the following message is shown CLEAR BREAKER 1...

Page 385: ...Feeder Protection System 7 3 7 COMMANDS AND TARGETS 7 1 COMMANDS 7 There is no impact if there have been no changes to the hardware modules When an update does not occur the ORDER CODE NOT UPDATED message will be shown ...

Page 386: ...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 387: ...n 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 event dri...

Page 388: ... switch How often the test is performed Monitored every five seconds An error is issued after five consecutive failures What to do Check the F60 device and switch IP configuration settings Check for incorrect UR port port 7 settings on the Ethernet switch Check the power to the switch Latched target message No Description of problem The Ethernet connection has failed for the specified port How oft...

Page 389: ... Upon initiation of a contact output state change What to do Verify the state of the output contact and contact the factory if the problem persists Latched target message No Description of problem A data item in a configurable GOOSE data set is oscillating How often the test is performed Upon scanning of each configurable GOOSE data set What to do The xxx text denotes the data item that has been d...

Page 390: ...ing 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 Abnormal restart from modules being removed or inserted while the F60 is powered up when there is an abnormal DC supply or as a result of internal relay failure How often the test is performed Event driven What to do Contact the factory UNEXPECTED RESTART P...

Page 391: ...tion of an hour to one or two hours lead the Hi Z element to recognize and flag an arcing suspected event None of these brief occurrences of arcing if taken individually are sufficient to indicate detection of a downed conductor or to set off an alarm indicating that persistent arcing has been detected When considered cumula tively however they do indicate a need for attention If an output contact...

Page 392: ... rithm and indications from multiple independent algorithms are more indicative of the presence of arcing than a single algo rithm giving a single indication 8 1 5 SPECTRAL ANALYSIS ALGORITHM The Spectral Analysis algorithm is the third and final confirmation algorithm performed only when a high impedance condi tion is suspected The Spectral Analysis algorithm receives five seconds of averaged non...

Page 393: ...in a signal which consists only of the fault component of the neutral current This informa tion is then provided as input to the Arc Burst Pattern Analysis Algorithm 8 1 9 ARC BURST PATTERN ANALYSIS ALGORITHM The Arc Burst Pattern Analysis algorithm attempts to provide faulted phase identification information based on a correlation between the fault component of the measured neutral current and th...

Page 394: ...l produce a decrease in the line load which can be mistaken by Hi Z element as Loss of Load Every two cycle the voltage on each phase is checked against the HI Z V SUPV THRESHOLD If the voltage on any phase has dropped by a percentage greater then or equal to this setting the Loss of Load flag will be blocked The blocking is not done on a per phase basis If one phase voltage shows a dip the block ...

Page 395: ...fault Z positive sequence impedance of the line The currents from the local and remote systems can be parted between their fault F and pre fault load pre components EQ 8 2 and neglecting shunt parameters of the line EQ 8 3 Inserting the IA and IB equations into the VA equation and solving for the fault resistance yields EQ 8 4 Assuming the fault components of the currents IAF and IBF are in phase ...

Page 396: ... 1 VT SUBSTITUTION setting value is V0 and the VTs are connected in a wye configuration the fault location is performed based on the actual phase to ground voltages If the VTs are connected in a delta configuration fault location is performed based on the delta voltages and externally supplied neutral voltage EQ 8 13 If the FAULT REPORT 1 VT SUBSTITUTION setting value is I0 and the VTs are connect...

Page 397: ...50DD OP X VA or VAB VC or VCA VB or VBC 827094A5 CDR Off 0 AND FAULT LOCATOR 1 RUN 0 3 SEC ACTUAL VALUES DATE TIME FAULT TYPE FAULT LOCATION FAULT RECLOSE SHOT FAULT REPORT Vn or V_0 FAULT REPORT 1 Z1 MAG FAULT REPORT 1 Z1 ANGLE FAULT REPORT 1 Z0 MAG FAULT REPORT 1 Z0 ANGLE FAULT REPORT 1 LENGTH UNITS FAULT REPORT 1 LENGTH FAULT REPORT 1 VT SUBSTITUTION FAULT REP 1 SYSTEM Z0 MAG FAULT REP 1 SYSTEM...

Page 398: ...8 8 F60 Feeder Protection System GE Multilin 8 2 FAULT LOCATOR 8 THEORY OF OPERATION 8 ...

Page 399: ...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 9 1 TYPICAL UNDERFREQUENCY ELEMENT TEST TIMING The static ac...

Page 400: ...r This is exclusive of the time taken by the frequency responding component to pickup The F60 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 401: ...t RMS 6166 SRC 1 Ig Mag Degrees Source 1 ground current magnitude 6168 SRC 1 Ig Angle Amps Source 1 ground current angle 6169 SRC 1 I_0 Mag Degrees Source 1 zero sequence current magnitude 6171 SRC 1 I_0 Angle Amps Source 1 zero sequence current angle 6172 SRC 1 I_1 Mag Degrees Source 1 positive sequence current magnitude 6174 SRC 1 I_1 Angle Amps Source 1 positive sequence current angle 6175 SRC ...

Page 402: ...e magnitude 6682 SRC 1 Vbc Angle Degrees Source 1 phase BC voltage angle 6683 SRC 1 Vca Mag Volts Source 1 phase CA voltage magnitude 6685 SRC 1 Vca Angle Degrees Source 1 phase CA voltage angle 6686 SRC 1 Vx RMS Volts Source 1 auxiliary voltage RMS 6688 SRC 1 Vx Mag Volts Source 1 auxiliary voltage magnitude 6690 SRC 1 Vx Angle Degrees Source 1 auxiliary voltage angle 6691 SRC 1 V_0 Mag Volts Sou...

Page 403: ... reactive power 7180 SRC 1 Qb Vars Source 1 phase B reactive power 7182 SRC 1 Qc Vars Source 1 phase C reactive power 7184 SRC 1 S VA Source 1 three phase apparent power 7186 SRC 1 Sa VA Source 1 phase A apparent power 7188 SRC 1 Sb VA Source 1 phase B apparent power 7190 SRC 1 Sc VA Source 1 phase C apparent power 7192 SRC 1 PF Source 1 three phase power factor 7193 SRC 1 Phase A PF Source 1 phas...

Page 404: ...enth harmonic 8075 SRC 1 Va Harm 10 Volts Source 1 phase A voltage twelfth harmonic 8076 SRC 1 Va Harm 11 Volts Source 1 phase A voltage thirteenth harmonic 8077 SRC 1 Va Harm 12 Volts Source 1 phase A voltage fourteenth harmonic 8078 SRC 1 Va Harm 13 Volts Source 1 phase A voltage fifteenth harmonic 8079 SRC 1 Va Harm 14 Volts Source 1 phase A voltage sixteenth harmonic 8080 SRC 1 Va Harm 15 Volt...

Page 405: ...RC 1 Vc Harm 5 Volts Source 1 phase C voltage seventh harmonic 8121 SRC 1 Vc Harm 6 Volts Source 1 phase C voltage eighth harmonic 8122 SRC 1 Vc Harm 7 Volts Source 1 phase C voltage ninth harmonic 8123 SRC 1 Vc Harm 8 Volts Source 1 phase C voltage tenth harmonic 8124 SRC 1 Vc Harm 9 Volts Source 1 phase C voltage eleventh harmonic 8125 SRC 1 Vc Harm 10 Volts Source 1 phase C voltage twelfth harm...

Page 406: ...RC 2 Vb Harm 2 Volts Source 2 phase B voltage fourth harmonic 8168 SRC 2 Vb Harm 3 Volts Source 2 phase B voltage fifth harmonic 8169 SRC 2 Vb Harm 4 Volts Source 2 phase B voltage sixth harmonic 8170 SRC 2 Vb Harm 5 Volts Source 2 phase B voltage seventh harmonic 8171 SRC 2 Vb Harm 6 Volts Source 2 phase B voltage eighth harmonic 8172 SRC 2 Vb Harm 7 Volts Source 2 phase B voltage ninth harmonic ...

Page 407: ... fault detection status 8785 HIZ Phase A Arc Conf High impedance fault detection phase A arc confidence 8786 HIZ Phase B Arc Conf High impedance fault detection phase B arc confidence 8787 HIZ Phase C Arc Conf High impedance fault detection phase C arc confidence 8788 HIZ Neutral Arc Conf High impedance fault detection neutral arc confidence 9024 Prefault Ia Mag 0 Amps Fault 1 pre fault phase A cu...

Page 408: ...Amps Source 1 phase A current twelfth harmonic 10252 SRC 1 Ia Harm 11 Amps Source 1 phase A current thirteenth harmonic 10253 SRC 1 Ia Harm 12 Amps Source 1 phase A current fourteenth harmonic 10254 SRC 1 Ia Harm 13 Amps Source 1 phase A current fifteenth harmonic 10255 SRC 1 Ia Harm 14 Amps Source 1 phase A current sixteenth harmonic 10256 SRC 1 Ia Harm 15 Amps Source 1 phase A current seventeent...

Page 409: ... SRC 1 Ic Harm 6 Amps Source 1 phase C current eighth harmonic 10314 SRC 1 Ic Harm 7 Amps Source 1 phase C current ninth harmonic 10315 SRC 1 Ic Harm 8 Amps Source 1 phase C current tenth harmonic 10316 SRC 1 Ic Harm 9 Amps Source 1 phase C current eleventh harmonic 10317 SRC 1 Ic Harm 10 Amps Source 1 phase C current twelfth harmonic 10318 SRC 1 Ic Harm 11 Amps Source 1 phase C current thirteenth...

Page 410: ...SRC 2 Ib Harm 3 Amps Source 2 phase B current fifth harmonic 10377 SRC 2 Ib Harm 4 Amps Source 2 phase B current sixth harmonic 10378 SRC 2 Ib Harm 5 Amps Source 2 phase B current seventh harmonic 10379 SRC 2 Ib Harm 6 Amps Source 2 phase B current eighth harmonic 10380 SRC 2 Ib Harm 7 Amps Source 2 phase B current ninth harmonic 10381 SRC 2 Ib Harm 8 Amps Source 2 phase B current tenth harmonic 1...

Page 411: ...Source 2 phase C current twenty fourth harmonic 10429 SRC 2 Ic Harm 23 Amps Source 2 phase C current twenty fifth harmonic 13504 DCMA Inputs 1 Value mA dcmA input 1 actual value 13506 DCMA Inputs 2 Value mA dcmA input 2 actual value 13508 DCMA Inputs 3 Value mA dcmA input 3 actual value 13510 DCMA Inputs 4 Value mA dcmA input 4 actual value 13512 DCMA Inputs 5 Value mA dcmA input 5 actual value 13...

Page 412: ...ctual value 13576 RTD Inputs 25 Value RTD input 25 actual value 13577 RTD Inputs 26 Value RTD input 26 actual value 13578 RTD Inputs 27 Value RTD input 27 actual value 13579 RTD Inputs 28 Value RTD input 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 Valu...

Page 413: ...GOOSE Analog In 3 IEC 61850 GOOSE analog input 3 45590 GOOSE Analog In 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...

Page 414: ...A 14 F60 Feeder Protection System GE Multilin A 1 PARAMETER LIST APPENDIXA A ...

Page 415: ...00 4800 9600 14400 19200 28800 33600 38400 57600 or 115200 bps are available Even odd and no parity are avail able Refer to the Communications section of chapter 5 for further 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 sla...

Page 416: ...n all slaves 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 divisi...

Page 417: ...ting 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 respe...

Page 418: ...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 419: ...e 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 EXMAPLE HEX SLAVE ADDRESS 11 SLAVE ADDRESS 11 FUNCTION CODE 10 FUNCTION CO...

Page 420: ...ns connection specific 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 f...

Page 421: ... replace nnn with the desired starting record number To read from a specific record to another specific record use the following filename EVT TXT xxxxx yyyyy replace xxxxx with the starting record number and yyyyy with the ending record number g READING FAULT REPORT FILES Fault report data has been available via the F60 file retrieval mechanism since UR firmware version 2 00 The file name is fault...

Page 422: ...tings and encrypted values found in the SETTINGS Ö PRODUCT SETUP Ö 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 command password must be entered at memory location 4008 To gain setting level security access the setting password must be entered at memory location 400...

Page 423: ...mand 64 modules 0400 Virtual Input 1 State 0 to 1 1 F108 0 Off 0401 Virtual Input 2 State 0 to 1 1 F108 0 Off 0402 Virtual Input 3 State 0 to 1 1 F108 0 Off 0403 Virtual Input 4 State 0 to 1 1 F108 0 Off 0404 Virtual Input 5 State 0 to 1 1 F108 0 Off 0405 Virtual Input 6 State 0 to 1 1 F108 0 Off 0406 Virtual Input 7 State 0 to 1 1 F108 0 Off 0407 Virtual Input 8 State 0 to 1 1 F108 0 Off 0408 Vir...

Page 424: ...0 to 1 1 F108 0 Off 0434 Virtual Input 53 State 0 to 1 1 F108 0 Off 0435 Virtual Input 54 State 0 to 1 1 F108 0 Off 0436 Virtual Input 55 State 0 to 1 1 F108 0 Off 0437 Virtual Input 56 State 0 to 1 1 F108 0 Off 0438 Virtual Input 57 State 0 to 1 1 F108 0 Off 0439 Virtual Input 58 State 0 to 1 1 F108 0 Off 043A Virtual Input 59 State 0 to 1 1 F108 0 Off 043B Virtual Input 60 State 0 to 1 1 F108 0 ...

Page 425: ...count Ch 1 0 to 65535 1 F001 0 15CB Direct inputs outputs unreturned message count Ch 2 0 to 65535 1 F001 0 15D0 Direct device states 0 to 65535 1 F500 0 15D1 Reserved 0 to 65535 1 F001 0 15D2 Direct inputs outputs CRC fail count 1 0 to 65535 1 F001 0 15D3 Direct inputs outputs CRC fail count 2 0 to 65535 1 F001 0 Ethernet Fibre Channel Status Read Write 1610 Ethernet primary fibre channel status ...

Page 426: ... Voltage RMS V F060 0 1A02 Source 1 Phase BG Voltage RMS V F060 0 1A04 Source 1 Phase CG Voltage RMS V F060 0 1A06 Source 1 Phase AG Voltage Magnitude 0 to 999999 999 V 0 001 F060 0 1A08 Source 1 Phase AG Voltage Angle 359 9 to 0 degrees 0 1 F002 0 1A09 Source 1 Phase BG Voltage Magnitude 0 to 999999 999 V 0 001 F060 0 1A0B Source 1 Phase BG Voltage Angle 359 9 to 0 degrees 0 1 F002 0 1A0C Source ...

Page 427: ...Power 1000000000000 to 1000000000000 VA 0 001 F060 0 1C16 Source 1 Phase C Apparent Power 1000000000000 to 1000000000000 VA 0 001 F060 0 1C18 Source 1 Three Phase Power Factor 0 999 to 1 0 001 F013 0 1C19 Source 1 Phase A Power Factor 0 999 to 1 0 001 F013 0 1C1A Source 1 Phase B Power Factor 0 999 to 1 0 001 F013 0 1C1B Source 1 Phase C Power Factor 0 999 to 1 0 001 F013 0 1C1C Reserved 4 items F...

Page 428: ...0 to 4294967295 1 F050 0 1E90 Source 1 Demand Var 0 to 999999 999 var 0 001 F060 0 1E92 Source 1 Demand Var Maximum Date 0 to 4294967295 1 F050 0 1E94 Source 1 Demand Va Maximum 0 to 999999 999 VA 0 001 F060 0 1E96 Source 1 Demand Va Maximum Date 0 to 4294967295 1 F050 0 1E98 Reserved 8 items F001 0 1EA0 Repeated for Source 2 1EC0 Repeated for Source 3 1EE0 Repeated for Source 4 1F00 Repeated for ...

Page 429: ... Breaker 2 Arcing Current Clear Command 0 to 1 1 F126 0 No Passwords Unauthorized Access Read Write Command 2230 Reset Unauthorized Access 0 to 1 1 F126 0 No Hi Z High Impedance Fault Detection Commands Read Write Command 2240 Hi Z Clear Oscillography 0 to 1 1 F126 0 No 2241 Hi Z Oscillography Force Trigger 0 to 1 1 F126 0 No 2242 Hi Z Oscillography Force Algorithm Capture 0 to 1 1 F126 0 No 2243 ...

Page 430: ...9 V 0 001 F060 0 2363 Fault 1 Phase C Voltage Angle 359 9 to 0 degrees 0 1 F002 0 2364 Fault 1 Type 0 to 11 1 F148 0 NA 2365 Fault 1 Location based on Line length units km or miles 3276 7 to 3276 7 0 1 F002 0 2366 Repeated for Fault 2 238C Repeated for Fault 3 23B2 Repeated for Fault 4 23D8 Repeated for Fault 5 Synchrocheck Actuals Read Only 2 modules 2400 Synchrocheck 1 Delta Voltage 100000000000...

Page 431: ...port 5 Time 0 to 4294967295 1 F050 0 303A Fault Report 6 Time 0 to 4294967295 1 F050 0 303C Fault Report 7 Time 0 to 4294967295 1 F050 0 303E Fault Report 8 Time 0 to 4294967295 1 F050 0 3040 Fault Report 9 Time 0 to 4294967295 1 F050 0 3042 Fault Report 10 Time 0 to 4294967295 1 F050 0 3044 Fault Report 11 Time 0 to 4294967295 1 F050 0 3046 Fault Report 12 Time 0 to 4294967295 1 F050 0 3048 Fault...

Page 432: ...to 32767 C 1 F002 0 34F6 RTD Input 7 Value 32768 to 32767 C 1 F002 0 34F7 RTD Input 8 Value 32768 to 32767 C 1 F002 0 34F8 RTD Input 9 Value 32768 to 32767 C 1 F002 0 34F9 RTD Input 10 Value 32768 to 32767 C 1 F002 0 34FA RTD Input 11 Value 32768 to 32767 C 1 F002 0 34FB RTD Input 12 Value 32768 to 32767 C 1 F002 0 34FC RTD Input 13 Value 32768 to 32767 C 1 F002 0 34FD RTD Input 14 Value 32768 to ...

Page 433: ...isabled 4011 Setting password status 0 to 1 1 F102 0 Disabled Passwords read write settings 4012 Control password access timeout 5 to 480 min 1 F001 5 4013 Setting password access timeout 5 to 480 min 1 F001 30 4014 Invalid password attempts 2 to 5 1 F001 3 4015 Password lockout duration 5 to 60 min 1 F001 5 4016 Password access events 0 to 1 1 F102 0 Disabled User Display Invoke Read Write Settin...

Page 434: ...DNP voltage default deadband 0 to 65535 1 F001 30000 40B8 DNP power default deadband 0 to 65535 1 F001 30000 40BA DNP energy default deadband 0 to 65535 1 F001 30000 40BE DNP other default deadband 0 to 65535 1 F001 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 40C2 DNP client address 3 0 to 4294967295 1 F003 0 40...

Page 435: ...SNTP server IP address 0 to 4294967295 1 F003 0 416B Simple Network Time Protocol SNTP UDP port number 1 to 65535 1 F001 123 Data Logger Commands Read Write Command 4170 Data Logger Clear 0 to 1 1 F126 0 No Data Logger Read Write Setting 4181 Data Logger Channel Settings 16 items F600 0 4191 Data Logger Mode 0 to 1 1 F260 0 continuous 4192 Data Logger Trigger 0 to 65535 1 F300 0 4193 Data Logger R...

Page 436: ...ammable LEDs Read Write Setting 48 modules 4280 FlexLogic Operand to Activate LED 0 to 65535 1 F300 0 4281 User LED type latched or self resetting 0 to 1 1 F127 1 Self Reset 4282 Repeated for User Programmable LED 2 4284 Repeated for User Programmable LED 3 4286 Repeated for User Programmable LED 4 4288 Repeated for User Programmable LED 5 428A Repeated for User Programmable LED 6 428C Repeated fo...

Page 437: ...4 User Programmable Primary Ethernet Fail Function 0 to 1 1 F102 0 Disabled 4445 User Programmable Secondary Ethernet Fail Function 0 to 1 1 F102 0 Disabled 4446 User Programmable Battery Fail Function 0 to 1 1 F102 1 Enabled 4447 User Programmable SNTP Fail Function 0 to 1 1 F102 1 Enabled 4448 User Programmable IRIG B Fail Function 0 to 1 1 F102 1 Enabled 4449 User Programmable Ethernet Switch F...

Page 438: ...te settings 4700 Breaker 1 function 0 to 1 1 F102 0 Disabled 4701 Breaker 1 name F206 Bkr 1 4704 Breaker 1 mode 0 to 1 1 F157 0 3 Pole 4705 Breaker 1 open 0 to 65535 1 F300 0 4706 Breaker 1 close 0 to 65535 1 F300 0 4707 Breaker 1 phase A three pole closed 0 to 65535 1 F300 0 4708 Breaker 1 phase B closed 0 to 65535 1 F300 0 4709 Breaker 1 phase C closed 0 to 65535 1 F300 0 470A Breaker 1 external...

Page 439: ... 1 Items 5 items 0 to 65535 1 F001 0 4C19 Reserved 7 items F001 0 4C20 Repeated for User Definable Display 2 4C40 Repeated for User Definable Display 3 4C60 Repeated for User Definable Display 4 4C80 Repeated for User Definable Display 5 4CA0 Repeated for User Definable Display 6 4CC0 Repeated for User Definable Display 7 4CE0 Repeated for User Definable Display 8 4D00 Repeated for User Definable ...

Page 440: ...Function 0 to 1 1 F102 0 Disabled 5401 RTD Input 1 ID F205 RTD Ip 1 5407 RTD Input 1 Type 0 to 3 1 F174 0 100 ohm Platinum 5413 Repeated for RTD Input 2 5426 Repeated for RTD Input 3 5439 Repeated for RTD Input 4 544C Repeated for RTD Input 5 545F Repeated for RTD Input 6 5472 Repeated for RTD Input 7 5485 Repeated for RTD Input 8 5498 Repeated for RTD Input 9 54AB Repeated for RTD Input 10 54BE R...

Page 441: ...0 Repeated for FlexLogic Timer 9 5848 Repeated for FlexLogic Timer 10 5850 Repeated for FlexLogic Timer 11 5858 Repeated for FlexLogic Timer 12 5860 Repeated for FlexLogic Timer 13 5868 Repeated for FlexLogic Timer 14 5870 Repeated for FlexLogic Timer 15 5878 Repeated for FlexLogic Timer 16 5880 Repeated for FlexLogic Timer 17 5888 Repeated for FlexLogic Timer 18 5890 Repeated for FlexLogic Timer ...

Page 442: ...tantaneous Overcurrent 1 Events 0 to 1 1 F102 0 Disabled 5A0A Reserved 6 items 0 to 1 1 F001 0 5A10 Repeated for Phase Instantaneous Overcurrent 2 5A20 Repeated for Phase Instantaneous Overcurrent 3 5A30 Repeated for Phase Instantaneous Overcurrent 4 5A40 Repeated for Phase Instantaneous Overcurrent 5 5A50 Repeated for Phase Instantaneous Overcurrent 6 5A60 Repeated for Phase Instantaneous Overcur...

Page 443: ... 0 Phasor 5D03 Ground Time Overcurrent 1 Pickup 0 to 30 pu 0 001 F001 1000 5D04 Ground Time Overcurrent 1 Curve 0 to 16 1 F103 0 IEEE Mod Inv 5D05 Ground Time Overcurrent 1 Multiplier 0 to 600 0 01 F001 100 5D06 Ground Time Overcurrent 1 Reset 0 to 1 1 F104 0 Instantaneous 5D07 Ground Time Overcurrent 1 Block 0 to 65535 1 F300 0 5D08 Ground Time Overcurrent 1 Target 0 to 2 1 F109 0 Self reset 5D09...

Page 444: ...RC 1 6052 Wattmetric ground fault 1 voltage 0 to 1 1 F234 0 Calculated VN 6053 Wattmetric ground fault 1 overvoltage pickup 0 02 to 3 00 pu 0 01 F001 20 6054 Wattmetric ground fault 1 current 0 to 1 1 F235 Calculated IN 6055 Wattmetric ground fault 1 overcurrent pickup 0 002 to 30 000 pu 0 001 F001 60 6056 Wattmetric ground fault 1 overcurrent pickup delay 0 to 600 s 0 01 F001 20 6057 Wattmetric g...

Page 445: ... 0 to 5 1 F167 0 SRC 1 6302 Negative Sequence Time Overcurrent 1 Pickup 0 to 30 pu 0 001 F001 1000 6303 Negative Sequence Time Overcurrent 1 Curve 0 to 16 1 F103 0 IEEE Mod Inv 6304 Negative Sequence Time Overcurrent 1 Multiplier 0 to 600 0 01 F001 100 6305 Negative Sequence Time Overcurrent 1 Reset 0 to 1 1 F104 0 Instantaneous 6306 Negative Sequence Time Overcurrent 1 Block 0 to 65535 1 F300 0 6...

Page 446: ...rectional Power 1 STG2 Delay 0 to 600 s 0 01 F001 2000 66A8 Sensitive Directional Power 1 Block F001 0 66A9 Sensitive Directional Power 1 Target 0 to 2 1 F109 0 Self reset 66AA Sensitive Directional Power 1 Events 0 to 1 1 F102 0 Disabled 66AB Reserved 5 items 0 to 65535 1 F001 0 66B0 Repeated for Sensitive Directional Power 2 Load Encroachment Read Write Grouped Setting 6700 Load Encroachment Fun...

Page 447: ... 1 F001 90 7285 Neutral Directional Overcurrent 1 Forward Pickup 0 002 to 30 pu 0 001 F001 50 7286 Neutral Directional Overcurrent 1 Reverse Limit Angle 40 to 90 degrees 1 F001 90 7287 Neutral Directional Overcurrent 1 Reverse Pickup 0 002 to 30 pu 0 001 F001 50 7288 Neutral Directional Overcurrent 1 Target 0 to 2 1 F109 0 Self reset 7289 Neutral Directional Overcurrent 1 Block 0 to 65535 1 F300 0...

Page 448: ...0 to 6 1 F173 6 4 to 20 mA 730F dcmA Inputs 1 Minimum Value 9999 999 to 9999 999 0 001 F004 4000 7311 dcmA Inputs 1 Maximum Value 9999 999 to 9999 999 0 001 F004 20000 7313 Reserved 5 items 0 to 65535 1 F001 0 7318 Repeated for dcmA Inputs 2 7330 Repeated for dcmA Inputs 3 7348 Repeated for dcmA Inputs 4 7360 Repeated for dcmA Inputs 5 7378 Repeated for dcmA Inputs 6 7390 Repeated for dcmA Inputs ...

Page 449: ...up 0 01 to 10 pu 0 01 F001 100 7A0A Hi Z Phase Rate of Change 1 to 999 A 2cycle 1 F001 150 7A0B Hi Z Neutral Rate of Change 1 to 999 A 2cycle 1 F001 150 7A0C Hi Z Loss of Load Threshold 5 to 100 1 F001 15 7A0D Hi Z 3 Phase Event Threshold 1 to 1000 A 1 F001 25 7A0E Hi Z Voltage Supervision Threshold 0 to 100 1 F001 5 7A0F Hi Z Voltage Supervision Delay 0 to 300 cycles 2 F001 60 7A10 HIZ Even Harmo...

Page 450: ...2 1 F109 0 Self reset 7E19 Reserved 8 items 0 to 1 1 F001 0 7E21 Repeated for Underfrequency 2 7E32 Repeated for Underfrequency 3 7E43 Repeated for Underfrequency 4 7E54 Repeated for Underfrequency 5 7E65 Repeated for Underfrequency 6 Neutral Overvoltage Read Write Grouped Setting 3 modules 7F00 Neutral Overvoltage 1 Function 0 to 1 1 F102 0 Disabled 7F01 Neutral Overvoltage 1 Signal Source 0 to 5...

Page 451: ...Repeated for module number 2 EGD Fast Production Read Write Setting 8400 EGD Fast Producer Exchange 1 Function 0 to 1 1 F102 0 Disabled 8401 EGD Fast Producer Exchange 1 Destination 0 to 4294967295 1 F003 0 8403 EGD Fast Producer Exchange 1 Data Rate 50 to 1000 ms 50 F001 1000 8404 EGD Fast Producer Exchange 1 Data Item 1 20 items 0 to 65535 1 F001 0 8418 Reserved 80 items F001 0 EGD Slow Producti...

Page 452: ...eaker Status 2 Phase C 0 to 65535 1 F300 0 8621 Repeated for Breaker Failure 2 8642 Repeated for Breaker Failure 3 8663 Repeated for Breaker Failure 4 8684 Repeated for Breaker Failure 5 86A5 Repeated for Breaker Failure 6 FlexState Settings Read Write Setting 8800 FlexState Parameters 256 items F300 0 Digital Elements Read Write Setting 48 modules 8A00 Digital Element 1 Function 0 to 1 1 F102 0 D...

Page 453: ... Element 44 8D70 Repeated for Digital Element 45 8D84 Repeated for Digital Element 46 8D98 Repeated for Digital Element 47 8DAC Repeated for Digital Element 48 Trip Bus Read Write Setting 8E00 Trip Bus 1 Function 0 to 1 1 F102 0 Disabled 8E01 Trip Bus 1 Block F300 0 8E02 Trip Bus 1 Pickup Delay 0 to 600 s 0 01 F001 0 8E03 Trip Bus 1 Reset Delay 0 to 600 s 0 01 F001 0 8E04 Trip Bus 1 Input 1 0 to 6...

Page 454: ...s 0 to 1 1 F102 0 Disabled 9014 Repeated for FlexElement 2 9028 Repeated for FlexElement 3 903C Repeated for FlexElement 4 9050 Repeated for FlexElement 5 9064 Repeated for FlexElement 6 9078 Repeated for FlexElement 7 908C Repeated for FlexElement 8 90A0 Repeated for FlexElement 9 90B4 Repeated for FlexElement 10 90C8 Repeated for FlexElement 11 90DC Repeated for FlexElement 12 90F0 Repeated for ...

Page 455: ...ed for dcmA Output 21 937E Repeated for dcmA Output 22 9384 Repeated for dcmA Output 23 938A Repeated for dcmA Output 24 Direct Input Output Names Read Write Setting 96 modules 9400 Direct Input 1 Name 0 to 96 1 F205 Dir Ip 1 9406 Direct Output 1 Name 1 to 96 1 F205 Dir Out 1 940C Repeated for Direct Input Output 2 9418 Repeated for Direct Input Output 3 9424 Repeated for Direct Input Output 4 943...

Page 456: ... Input 1 n Default States 16 items 0 to 3 1 F086 0 Off 9B30 Teleprotection Input 2 n Default States 16 items 0 to 3 1 F086 0 Off 9B50 Teleprotection Output 1 n Operand 16 items 0 to 65535 1 F300 0 9B70 Teleprotection Output 2 n Operand 16 items 0 to 65535 1 F300 0 Teleprotection Inputs Outputs Commands Read Write Command 9B90 Teleprotection Clear Lost Packets 0 to 1 1 F126 0 No Teleprotection Chan...

Page 457: ...P IEC 60870 5 104 Binary Input Points 256 items 0 to 65535 1 F300 0 A400 DNP IEC 60870 5 104 Analog Input Points 256 items 0 to 65535 1 F300 0 Flexcurves C and D Read Write Setting A600 FlexCurve C 120 items 0 to 65535 ms 1 F011 0 A680 FlexCurve D 120 items 0 to 65535 ms 1 F011 0 Non Volatile Latches Read Write Setting 16 modules A700 Non Volatile Latch 1 Function 0 to 1 1 F102 0 Disabled A701 Non...

Page 458: ...5 s 0 001 F001 0 A905 Frequency Rate of Change 1 Reset Delay 0 to 65 535 s 0 001 F001 0 A906 Frequency Rate of Change 1 Block 0 to 65535 1 F300 0 A907 Frequency Rate of Change 1 Target 0 to 2 1 F109 0 Self reset A908 Frequency Rate of Change 1 Events 0 to 1 1 F102 0 Disabled A909 Frequency Rate of Change 1 Source 0 to 5 1 F167 0 SRC 1 A90A Frequency Rate of Change 1 Trend 0 to 2 1 F224 0 Increasin...

Page 459: ...tatus 0 to 65535 1 F300 0 AB27 Command to clear XCBR2 OpCnt operation counter 0 to 1 1 F126 0 No AB28 Operand for IEC 61850 XCBR3 ST Loc status 0 to 65535 1 F300 0 AB29 Command to clear XCBR3 OpCnt operation counter 0 to 1 1 F126 0 No AB2A Operand for IEC 61850 XCBR4 ST Loc status 0 to 65535 1 F300 0 AB2B Command to clear XCBR4 OpCnt operation counter 0 to 1 1 F126 0 No AB2C Operand for IEC 61850 ...

Page 460: ...t 18 AF8E Repeated for IEC 61850 GGIO4 analog input 19 AF95 Repeated for IEC 61850 GGIO4 analog input 20 AF9C Repeated for IEC 61850 GGIO4 analog input 21 AFA3 Repeated for IEC 61850 GGIO4 analog input 22 AFAA Repeated for IEC 61850 GGIO4 analog input 23 AFB1 Repeated for IEC 61850 GGIO4 analog input 24 AFB8 Repeated for IEC 61850 GGIO4 analog input 25 AFBF Repeated for IEC 61850 GGIO4 analog inpu...

Page 461: ... 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 phsB Deadband 1 0 001 to 100 0 001 F003 10000 B0EE IEC 61850 MMXU VA phsC Deadband 1 0 001 to 100 0 001 F003 10000 B0F0 IEC 61...

Page 462: ... B269 IEC 61850 GGIO2 CF SPCSO42 ctlModel Value 0 to 2 1 F001 2 B26A IEC 61850 GGIO2 CF SPCSO43 ctlModel Value 0 to 2 1 F001 2 B26B IEC 61850 GGIO2 CF SPCSO44 ctlModel Value 0 to 2 1 F001 2 B26C IEC 61850 GGIO2 CF SPCSO45 ctlModel Value 0 to 2 1 F001 2 B26D IEC 61850 GGIO2 CF SPCSO46 ctlModel Value 0 to 2 1 F001 2 B26E IEC 61850 GGIO2 CF SPCSO47 ctlModel Value 0 to 2 1 F001 2 B26F IEC 61850 GGIO2 ...

Page 463: ...E APPID 0 to 16383 1 F001 0 B5C8 IEC 61850 Configurable GOOSE ConfRev 1 to 4294967295 1 F003 1 B5CA Configurable GOOSE Dataset Items for Transmission 0 to 256 1 F232 0 None B60A Repeated for Module 2 B674 Repeated for Module 3 B6DE Repeated for Module 4 B748 Repeated for Module 5 B7B2 Repeated for Module 6 B81C Repeated for Module 7 B886 Repeated for Module 8 IEC 61850 Configurable GOOSE Reception...

Page 464: ...d for Contact Input 34 BC10 Repeated for Contact Input 35 BC18 Repeated for Contact Input 36 BC20 Repeated for Contact Input 37 BC28 Repeated for Contact Input 38 BC30 Repeated for Contact Input 39 BC38 Repeated for Contact Input 40 BC40 Repeated for Contact Input 41 BC48 Repeated for Contact Input 42 BC50 Repeated for Contact Input 43 BC58 Repeated for Contact Input 44 BC60 Repeated for Contact I...

Page 465: ...9 BDC8 Repeated for Contact Input 90 BDD0 Repeated for Contact Input 91 BDD8 Repeated for Contact Input 92 BDE0 Repeated for Contact Input 93 BDE8 Repeated for Contact Input 94 BDF0 Repeated for Contact Input 95 BDF8 Repeated for Contact Input 96 Contact Input Thresholds Read Write Setting BE00 Contact Input n Threshold n 1 to 24 24 items 0 to 3 1 F128 1 33 Vdc Virtual Inputs Read Write Setting 64...

Page 466: ...l Input 39 C004 Repeated for Virtual Input 40 C010 Repeated for Virtual Input 41 C01C Repeated for Virtual Input 42 C028 Repeated for Virtual Input 43 C034 Repeated for Virtual Input 44 C040 Repeated for Virtual Input 45 C04C Repeated for Virtual Input 46 C058 Repeated for Virtual Input 47 C064 Repeated for Virtual Input 48 C070 Repeated for Virtual Input 49 C07C Repeated for Virtual Input 50 C088...

Page 467: ...irtual Output 26 C200 Repeated for Virtual Output 27 C208 Repeated for Virtual Output 28 C210 Repeated for Virtual Output 29 C218 Repeated for Virtual Output 30 C220 Repeated for Virtual Output 31 C228 Repeated for Virtual Output 32 C230 Repeated for Virtual Output 33 C238 Repeated for Virtual Output 34 C240 Repeated for Virtual Output 35 C248 Repeated for Virtual Output 36 C250 Repeated for Virtu...

Page 468: ...ated for Virtual Output 82 C3C0 Repeated for Virtual Output 83 C3C8 Repeated for Virtual Output 84 C3D0 Repeated for Virtual Output 85 C3D8 Repeated for Virtual Output 86 C3E0 Repeated for Virtual Output 87 C3E8 Repeated for Virtual Output 88 C3F0 Repeated for Virtual Output 89 C3F8 Repeated for Virtual Output 90 C400 Repeated for Virtual Output 91 C408 Repeated for Virtual Output 92 C410 Repeated...

Page 469: ...Output 25 C56C Repeated for Contact Output 26 C578 Repeated for Contact Output 27 C584 Repeated for Contact Output 28 C590 Repeated for Contact Output 29 C59C Repeated for Contact Output 30 C5A8 Repeated for Contact Output 31 C5B4 Repeated for Contact Output 32 C5C0 Repeated for Contact Output 33 C5CC Repeated for Contact Output 34 C5D8 Repeated for Contact Output 35 C5E4 Repeated for Contact Outp...

Page 470: ...rent operand 0 to 65535 1 F300 0 C77B Clear Demand operand 0 to 65535 1 F300 0 C77D Clear Energy operand 0 to 65535 1 F300 0 C77E Clear Hi Z Records operand 0 to 65535 1 F300 0 C77F Clear Unauthorized Access operand 0 to 65535 1 F300 0 C781 Clear Platform Direct Input Output Statistics operand 0 to 65535 1 F300 0 C782 Reserved 13 items F001 0 Force Contact Inputs Outputs Read Write Settings C7A0 F...

Page 471: ...d for Direct Input 31 C90C Repeated for Direct Input 32 Platform Direct Outputs Read Write Setting 96 modules CA10 Direct Output 1 Operand 0 to 65535 1 F300 0 CA11 Direct Output 1 Events 0 to 1 1 F102 0 Disabled CA12 Repeated for Direct Output 2 CA14 Repeated for Direct Output 3 CA16 Repeated for Direct Output 4 CA18 Repeated for Direct Output 5 CA1A Repeated for Direct Output 6 CA1C Repeated for ...

Page 472: ...Ch 1 Unreturned Messages Alarm Events 0 to 1 1 F102 0 Disabled CAE4 Reserved 4 items 1 to 1000 1 F001 10 CAE8 Direct IO Ch 2 Unreturned Messages Alarm Function 0 to 1 1 F102 0 Disabled CAE9 Direct I O Ch 2 Unreturned Messages Alarm Msg Count 100 to 10000 1 F001 600 CAEA Direct I O Ch 2 Unreturned Messages Alarm Threshold 1 to 1000 1 F001 10 CAEB Direct I O Channel 2 Unreturned Messages Alarm Event...

Page 473: ...Output 20 D270 Repeated for Remote Output 21 Table B 9 MODBUS MEMORY MAP Sheet 51 of 53 ADDR REGISTER NAME RANGE UNITS STEP FORMAT DEFAULT D274 Repeated for 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 fo...

Page 474: ... for Remote Device 7 D39C Repeated for Remote Device 8 D3A0 Repeated for Remote Device 9 D3A4 Repeated for Remote Device 10 D3A8 Repeated for Remote Device 11 D3AC Repeated for Remote Device 12 D3B0 Repeated for Remote Device 13 D3B4 Repeated for Remote Device 14 D3B8 Repeated for Remote Device 15 D3BC Repeated for Remote Device 16 D3C0 Repeated for Remote Device 17 D3C4 Repeated for Remote Device...

Page 475: ... 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 xx xxx Hours 0 12am 1 1am 12 12pm 23 11pm Minutes 0 to 59 in steps of 1 Last 16 bits are Seconds xx xx SS SSS 0 00 000s 1 00 001 59999 59 999s F060 FLOATING_POINT IEEE FLOATING POINT 32...

Page 476: ...Odd 2 Even F114 ENUMERATION IRIG B SIGNAL TYPE 0 None 1 DC Shift 2 Amplitude Modulated F115 ENUMERATION BREAKER STATUS 0 Auxiliary A 1 Auxiliary B F116 ENUMERATION NEUTRAL OVERVOLTAGE CURVES 0 Definite Time 1 FlexCurve A 2 FlexCurve B 3 FlexCurve C F117 ENUMERATION NUMBER OF OSCILLOGRAPHY RECORDS 0 1 72 cycles 1 3 36 cycles 2 7 18 cycles 3 15 9 cycles F118 ENUMERATION OSCILLOGRAPHY MODE 0 Automati...

Page 477: ... Phase Instantaneous Overcurrent 9 9 Phase Instantaneous Overcurrent 10 10 Phase Instantaneous Overcurrent 11 11 Phase Instantaneous Overcurrent 12 16 Phase Time Overcurrent 1 17 Phase Time Overcurrent 2 18 Phase Time Overcurrent 3 19 Phase Time Overcurrent 4 20 Phase Time Overcurrent 5 21 Phase Time Overcurrent 6 24 Phase Directional Overcurrent 1 25 Phase Directional Overcurrent 2 32 Neutral Ins...

Page 478: ...e 3 307 Autoreclose 4 308 Autoreclose 5 309 Autoreclose 6 312 Synchrocheck 1 313 Synchrocheck 2 320 Cold load pickup 1 321 Cold load pickup 2 336 Setting Group 337 Reset 344 Overfrequency 1 345 Overfrequency 2 346 Overfrequency 3 bitmask element 347 Overfrequency 4 352 Underfrequency 1 353 Underfrequency 2 354 Underfrequency 3 355 Underfrequency 4 356 Underfrequency 5 357 Underfrequency 6 375 Auto...

Page 479: ...tal Element 42 734 Digital Element 43 735 Digital Element 44 736 Digital Element 45 737 Digital Element 46 738 Digital Element 47 739 Digital Element 48 842 Trip Bus 1 843 Trip Bus 2 844 Trip Bus 3 845 Trip Bus 4 846 Trip Bus 5 bitmask element 847 Trip Bus 6 849 RTD Input 1 850 RTD Input 2 851 RTD Input 3 852 RTD Input 4 853 RTD Input 5 854 RTD Input 6 855 RTD Input 7 856 RTD Input 8 857 RTD Input...

Page 480: ...ycles 3 3 x 64 cycles 4 1 x 128 cycles F137 ENUMERATION USER PROGRAMMABLE PUSHBUTTON FUNCTION 0 Disabled 1 Self Reset 2 Latched F138 ENUMERATION OSCILLOGRAPHY FILE TYPE 0 Data File 1 Configuration File 2 Header File F139 ENUMERATION DEMAND CALCULATIONS 0 Thermal Exponential 1 Block Interval 2 Rolling Demand 904 User Programmable Pushbutton 5 905 User Programmable Pushbutton 6 906 User Programmable...

Page 481: ...or 31 Any Major Error 32 DSP Error 33 No DSP Interrupts 34 Unit Not Calibrated 35 EEPROM Data Error 36 SRAM Data Error 37 Program Memory 38 Watchdog Error 39 Low On Memory 40 Prototype Firmware 41 Module Failure 01 42 Module Failure 02 43 Module Failure 03 44 Module Failure 04 45 Module Failure 05 46 Module Failure 06 47 Module Failure 07 48 Module Failure 08 49 Module Failure 09 50 Incompatible H...

Page 482: ... RTD 21 37 RTD 37 5 RTD 5 22 RTD 22 38 RTD 38 6 RTD 6 23 RTD 23 39 RTD 39 7 RTD 7 24 RTD 24 40 RTD 40 8 RTD 8 25 RTD 25 41 RTD 41 9 RTD 9 26 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 definition bitmask value bitmask value 0 NON...

Page 483: ...CATION PORT 0 None 1 COM1 RS485 2 COM2 RS485 3 Front Panel RS232 4 Network TCP 5 Network UDP F178 ENUMERATION DATA LOGGER RATES 0 1 sec 1 1 min 2 5 min 3 10 min 4 15 min 5 20 min 6 30 min 7 60 min 8 15 ms 9 30 ms 10 100 ms 11 500 ms F179 ENUMERATION NEGATIVE SEQUENCE DIRECTIONAL OVERCURRENT TYPE 0 Neg Sequence 1 Zero Sequence F180 ENUMERATION PHASE GROUND 0 PHASE 1 GROUND F181 ENUMERATION ODD EVEN...

Page 484: ...DOWNED CONDUCTOR bitmask trigger type 0 None 1 Loss Of Load 2 Arc Suspected 3 Arcing 4 Overcurrent 5 Down Conductor 6 External bitmsk keypress bitmsk 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 programmable key 1 4 4 28 User programmable key 2 5 5 29 User programmable key 3 6 6 30 User programmable key 4 7 7 31 User programmable key 5 8 8 32 User pro...

Page 485: ... None 1 SRC 1 2 SRC 2 3 SRC 3 4 SRC 4 5 SRC 5 6 SRC 6 F220 ENUMERATION PUSHBUTTON MESSAGE PRIORITY F222 ENUMERATION TEST ENUMERATION 0 Test Enumeration 0 1 Test Enumeration 1 F224 ENUMERATION RATE TREND FOR FREQ RATE OF CHANGE 0 Increasing 1 Decreasing 2 Bidirectional F226 ENUMERATION REMOTE INPUT OUTPUT TRANSFER METHOD 0 None 1 GSSE 2 GOOSE F227 ENUMERATION RELAY SERVICE STATUS 0 Unknown 1 Relay ...

Page 486: ...XU2 MX PhV phsC cVal ang f 311 MMXU2 MX A phsA cVal mag f 312 MMXU2 MX A phsA cVal ang f 313 MMXU2 MX A phsB cVal mag f value GOOSE dataset item 314 MMXU2 MX A phsB cVal ang f 315 MMXU2 MX A phsC cVal mag f 316 MMXU2 MX A phsC cVal ang f 317 MMXU2 MX A neut cVal mag f 318 MMXU2 MX A neut cVal ang f 319 MMXU2 MX W phsA cVal mag f 320 MMXU2 MX W phsB cVal mag f 321 MMXU2 MX W phsC cVal mag f 322 MMX...

Page 487: ...l mag f 417 MMXU5 MX PhV phsA cVal ang f 418 MMXU5 MX PhV phsB cVal mag f 419 MMXU5 MX PhV phsB cVal ang f value GOOSE dataset item 420 MMXU5 MX PhV phsC cVal mag f 421 MMXU5 MX PhV phsC cVal ang f 422 MMXU5 MX A phsA cVal mag f 423 MMXU5 MX A phsA cVal ang f 424 MMXU5 MX A phsB cVal mag f 425 MMXU5 MX A phsB cVal ang f 426 MMXU5 MX A phsC cVal mag f 427 MMXU5 MX A phsC cVal ang f 428 MMXU5 MX A n...

Page 488: ...mag f 498 GGIO4 MX AnIn20 mag f 499 GGIO4 MX AnIn21 mag f 500 GGIO4 MX AnIn22 mag f 501 GGIO4 MX AnIn23 mag f 502 GGIO4 MX AnIn24 mag f 503 GGIO4 MX AnIn25 mag f 504 GGIO4 MX AnIn26 mag f 505 GGIO4 MX AnIn27 mag f 506 GGIO4 MX AnIn28 mag f 507 GGIO4 MX AnIn29 mag f 508 GGIO4 MX AnIn30 mag f 509 GGIO4 MX AnIn31 mag f 510 GGIO4 MX AnIn32 mag f value GOOSE dataset item 0 None 1 GGIO3 ST Ind1 q 2 GGIO...

Page 489: ...L OUTPUT 1 to 96 52 SELF TEST ERROR see F141 for range 56 ACTIVE SETTING GROUP 1 to 6 62 MISCELLANEOUS EVENTS see F146 for range 64 to 127 ELEMENT STATES F400 UR_UINT16 CT VT BANK SELECTION F491 ENUMERATION ANALOG INPUT MODE 0 Default Value 1 Last Known F500 UR_UINT16 PACKED BITFIELD First register indicates input output state with bits 0 MSB to 15 LSB corresponding to input output state 1 to 16 T...

Page 490: ...FLEXELEMENT UNITS 0 Milliseconds 1 Seconds 2 Minutes F519 ENUMERATION NON VOLATILE LATCH 0 Reset Dominant 1 Set Dominant F522 ENUMERATION TRANSDUCER DCMA OUTPUT RANGE 0 1 to 1 mA 1 0 to 1 mA 2 4 to 20 mA F523 ENUMERATION DNP OBJECTS 20 22 AND 23 DEFAULT VARIATION F524 ENUMERATION DNP OBJECT 21 DEFAULT VARIATION F525 ENUMERATION DNP OBJECT 32 DEFAULT VARIATION bitmask element state 0 Pickup 1 Opera...

Page 491: ...sed as FlexAnalogs basically all metering quantities used in protection value keypress value keypress value 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 4...

Page 492: ...B 78 F60 Feeder Protection System GE Multilin B 4 MEMORY MAPPING APPENDIXB B ...

Page 493: ... 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 environment Actual MMS protocol services are mapped to IEC 61850 abstract ser vices in IEC 61850 8 1 The F60 relay supports IEC 61850 server services over both TCP I...

Page 494: ...d 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 F60 virtual inputs Virtual inputs are single point control binary values that can be written by clients They are generally used as contro...

Page 495: ...e power factor 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 curren...

Page 496: ...s in the fault locator 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 oper and 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 setting...

Page 497: ... 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 gra...

Page 498: ...tion for greater than two minutes the connection will be aborted by the F60 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 F60 will not abort the connection If other MMS data is being polled on ...

Page 499: ...two 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 rece...

Page 500: ...er 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 at the transmission and reception devices are an e...

Page 501: ...Boolean value and a floating point ana log value This matches the transmission dataset configuration above 2 Configure the GOOSE service settings by making the following changes in the INPUTS OUTPUTS ÖØ REMOTE DEVICES ÖØ REMOTE DEVICE 1 settings menu Set REMOTE DEVICE 1 ID to match the GOOSE ID string for the transmitting device Enter GOOSEOut_1 Set REMOTE DEVICE 1 ETYPE APPID to match the Etherty...

Page 502: ...et Thus if the local MAC address is 00 A0 F4 01 02 03 then the destination MAC address will be 01 A0 F4 01 02 03 C 4 6 GSSE ID AND GOOSE ID SETTINGS GSSE messages contain an identifier string used by receiving devices to identify the sender of the message defined in IEC 61850 part 8 1 as GsID This is a programmable 65 character string This string should be chosen to provide a descriptive name of t...

Page 503: ...ation process for IEC 61850 BDA Basic Data Attribute that is not structured DAI Instantiated Data Attribute DO Data Object type or instance depending on the context 842790A1 CDR Ethernet System configurator SCD file System specification tool SSD file System specification data ICD file 2 Process of creating ICD vendor 2 Creating ICD GE Multilin EnerVista UR Setup ICD file 1 IED UR series OR ICD fil...

Page 504: ...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 505: ...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 506: ...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 507: ...ataSet 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 Oth...

Page 508: ...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 0 5 ICD FILE STRUCTURE DATATYPETEMPLATES NODE 842798A1 CDR DataTypeTemplates LNodeType id InClass DO name type Other LNodeType element...

Page 509: ...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 510: ...le and its version and specifies options for the mapping of names to signals The Substation node describes the substation parameters Figure 0 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 511: ...ctedAP 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 b...

Page 512: ...te the F60 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 513: ...one 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 514: ...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 515: ...ta set 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 6 S1 ServerDirectory ...

Page 516: ...hange qchg S24 3 data update dupd S25 GetBRCBValues TP c6 Yes 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 14 LOG CONTROL BLOCK S30 GetLCBValues TP M S31 SetLCBValues TP M LOG S32 QueryLogByTime TP M S33 QueryLogByE...

Page 517: ...C CLAUSE 16 MULTICAST SVC S45 SendMSVMessage 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 16 4 8 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 20 S57 GetFile TP M Yes S58 ...

Page 518: ...ange of frequency PHAR Harmonic restraint PHIZ Ground detector PIOC Instantaneous overcurrent Yes PMRI Motor restart inhibition PMSS Motor starting time supervision POPF Over power factor PPAM Phase angle measuring PSCH Protection scheme PSDE Sensitive directional earth fault PTEF Transient earth fault PTOC Time overcurrent Yes PTOF Overfrequency PTOV Overvoltage Yes PTRC Protection trip condition...

Page 519: ...oltage control M LOGICAL NODES FOR METERING AND MEASUREMENT MDIF Differential measurements MHAI Harmonics or interharmonics MHAN Non phase related harmonics or interharmonic MMTR Metering MMXN Non phase related measurement Yes MMXU Measurement Yes MSQI Sequence and imbalance MSTA Metering statistics S LOGICAL NODES FOR SENSORS AND MONITORING SARC Monitoring and diagnostics for arcs SIMG Insulation...

Page 520: ...ry ZBSH Bushing ZCAB Power cable ZCAP Capacitor bank ZCON Converter ZGEN Generator ZGIL Gas insulated line ZLIN Power overhead line ZMOT Motor ZREA Reactor ZRRC Rotating reactive component ZSAR Surge arrestor ZTCF Thyristor controlled frequency converter ZTRC Thyristor controlled reactive component Table 0 1 IEC 61850 LOGICAL NODES Sheet 3 of 3 NODES UR FAMILY ...

Page 521: ...e 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 i...

Page 522: ...g 4 used in standard direction not used cannot be selected in IEC 60870 5 104 standard Process information in monitor direction 4 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 Bi...

Page 523: ...tion 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 4 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 51 Bitstr...

Page 524: ...ectory 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_TA_1...

Page 525: ... 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 INF...

Page 526: ...2 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 ACTIV...

Page 527: ...d M_ME_TF_1 Station interrogation Clock synchronization 4 Clock synchronization optional see Clause 7 6 Command transmission 4 Direct command transmission Direct setpoint command transmission 4 Select and execute command Select and execute setpoint command 4 C_SE ACTTERM used 4 No additional definition 4 Short pulse duration duration determined by a system parameter in the outstation 4 Long pulse ...

Page 528: ...sequences 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 PARAMETE...

Page 529: ...nternet 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 4 Ethernet 802 3 Serial X 21 interface Other selection s from RFC 2200 list below if selected D 1 2 IEC 60870 5 104 POINT LIST The IEC 60870 5 104 data points a...

Page 530: ...D 10 F60 Feeder Protection System GE Multilin D 1 IEC 60870 5 104 APPENDIXD D ...

Page 531: ...n 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 Deadbands...

Page 532: ...utputs 4 Never Always Sometimes Configurable SELECT OPERATE Never 4 Always Sometimes Configurable DIRECT OPERATE Never 4 Always Sometimes Configurable DIRECT OPERATE NO ACK Never 4 Always Sometimes Configurable Count 1 4 Never Always Sometimes Configurable Pulse On Never Always 4 Sometimes Configurable Pulse Off Never Always 4 Sometimes Configurable Latch On Never Always 4 Sometimes Configurable L...

Page 533: ...rable Only certain objects Sometimes attach explanation 4 ENABLE DISABLE unsolicited Function codes supported Sends Static Data in Unsolicited Responses 4 Never When Device Restarts When Status Flags Change No other options are permitted Default Counter Object Variation No Counters Reported Configurable attach explanation 4 Default Object 20 Default Variation 1 4 Point by point list attached Count...

Page 534: ...7 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 see...

Page 535: ...iation 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 0...

Page 536: ...nse 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 resp...

Page 537: ...ose 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 star...

Page 538: ...on is performed 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 req...

Page 539: ...ual 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 Virt...

Page 540: ...eeze 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 541: ...r all Analog 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 ...

Page 542: ...E 12 F60 Feeder Protection System GE Multilin E 2 DNP POINT LISTS APPENDIXE E ...

Page 543: ... URF 038 1601 0093 C5 3 0x 11 February 2003 URF 040 1601 0093 C6 3 1x 11 February 2003 URF 042 1601 0093 D1 3 2x 11 February 2003 URF 044 1601 0093 D2 3 2x 02 June 2003 URX 084 1601 0093 E1 3 3x 01 May 2003 URX 080 1601 0093 E2 3 3x 29 May 2003 URX 083 1601 0093 F1 3 4x 10 December 2003 URX 111 1601 0093 F2 3 4x 09 February 2004 URX 115 1601 0093 G1 4 0x 23 March 2004 URX 123 1601 0093 G2 4 0x 17 ...

Page 544: ...MWARE sub section 3 44 Add Added SELECTING THE PROPER SWITCH FIRMWARE VERSION sub section Table F 3 MAJOR UPDATES FOR F60 MANUAL REVISION S1 PAGE R3 PAGE S1 CHANGE DESCRIPTION Title Title Update Manual part number to 1601 0093 S1 2 2 2 2 Update Updated ORDERING section 2 4 2 4 Update Updated REPLACEMENT MODULES section 2 7 2 7 Update Updated PROTECTION ELEMENTS specifications section 2 15 2 13 Upd...

Page 545: ...L AND INSERTION section 4 4 4 4 Update Updated FACEPLATE section 4 5 4 5 Update Updated LED INDICATORS section 4 7 4 8 Update Updated CUSTOM LABELING OF LEDS section 4 13 4 20 Update Updated ENTERING INITIAL PASSWORDS section 5 8 5 8 Update Updated PASSWORD SECURITY section 5 37 5 38 Update Updated USER PROGRAMMABLE LEDS section 5 42 5 43 Update Updated CONTROL PUSHBUTTONS section 5 43 5 44 Update...

Page 546: ...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 Fault CT HIZ High Impedance ...

Page 547: ...nal 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 Super...

Page 548: ...nd it is returned 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 fac...

Page 549: ... B 37 settings 5 153 specifications 2 8 AUXILIARY VOLTAGE CHANNEL 3 13 AUXILIARY VOLTAGE METERING 6 17 B BANKS 5 6 5 65 5 66 BATTERY FAILURE 7 6 BINARY INPUT POINTS E 8 BINARY OUTPUT POINTS E 9 BLOCK DIAGRAM 1 3 BLOCK SETTING 5 5 BREAKER ARCING CURRENT actual values 6 26 clearing 5 13 7 2 FlexLogic operands 5 86 logic 5 191 measurement 5 191 Modbus registers B 15 B 34 settings 5 190 specifications...

Page 550: ... 14 CONTROL PUSHBUTTONS FlexLogic operands 5 86 Modbus registers B 56 settings 5 46 specifications 2 10 COUNTERS actual values 6 7 settings 5 182 CRC ALARM 5 61 CRC 16 ALGORITHM B 2 CRITICAL FAILURE RELAY 2 14 3 11 CSA APPROVAL 2 17 CT BANKS settings 5 65 CT INPUTS 3 13 5 6 5 65 CURRENT BANK 5 65 CURRENT DEMAND 5 41 CURRENT HARMONICS 2 12 6 20 CURRENT METERING actual values 6 15 Modbus registers B...

Page 551: ...ion table E 4 Modbus registers B 20 settings 5 16 DOWNED CONDUCTOR 2 11 6 8 DOWNED CONDUCTOR See HI Z DUPLEX HALF B 1 E EGD PROTOCOL actual values 6 9 Modbus registers B 37 settings 5 31 ELECTROSTATIC DISCHARGE 2 17 ELEMENTS 5 4 ENERGY ALOGRITHM FOR HI Z 8 1 ENERGY METERING actual values 6 18 Modbus registers B 13 specifications 2 11 2 12 ENERGY METERING CLEARING 5 13 7 2 ENERVISTA UR SETUP creati...

Page 552: ...uits 3 16 outputs 3 14 3 16 3 20 specifications 2 13 FORM C RELAY outputs 3 14 3 20 specifications 2 14 FREQUENCY METERING actual values 6 19 Modbus registers B 13 settings 5 67 specifications 2 12 FREQUENCY RATE OF CHANGE FlexLogic operands 5 88 Modbus registers B 11 B 44 settings 5 167 FREQUENCY TRACKING 5 67 6 21 FREQUENCY NOMINAL 5 67 FUNCTION SETTING 5 4 FUSE 2 13 FUSE FAILURE see VT FUSE FAI...

Page 553: ...AY COMMUNICATIONS 2 16 INTRODUCTION 1 2 INVERSE TIME UNDERVOLTAGE 5 148 IOC see PHASE GROUND and NEUTRAL IOC entries IP ADDRESS 5 15 IRIG B connection 3 27 error messages 7 6 settings 5 34 specifications 2 13 2 14 ISO 9000 REGISTRATION 2 17 K KEYPAD 1 17 4 24 L LAMPTEST 7 2 LANGUAGE 5 11 LASER MODULE 3 30 LATCHING OUTPUTS application example 5 209 5 210 error messages 7 7 settings 5 208 specificat...

Page 554: ...TANTANEOUS OVERCURRENT see entry for NEUTRAL IOC NEUTRAL IOC FlexLogic operands 5 89 logic 5 121 Modbus registers B 29 settings 5 121 specifications 2 7 NEUTRAL OVERVOLTAGE FlexLogic operands 5 89 logic 5 151 Modbus registers B 36 settings 5 151 specifications 2 8 NEUTRAL TIME OVERCURRENT see entry for NEUTRAL TOC NEUTRAL TOC FlexLogic operands 5 89 logic 5 120 Modbus registers B 28 settings 5 120...

Page 555: ...tings 5 149 specifications 2 8 PHONE NUMBERS 1 1 POWER METERING Modbus registers B 13 specifications 2 11 values 6 17 POWER SUPPLY description 3 11 low range 2 13 specifications 2 13 POWER SYSTEM Modbus registers B 24 PREFERENCES Modbus registers B 19 PRODUCT INFORMATION 6 27 B 9 PRODUCT SETUP 5 8 PRODUCTION TESTS 2 17 PROTECTION ELEMENTS 5 4 PU QUANTITY 5 4 PUSHBUTTONS USER PROGRAMMABLE see USER ...

Page 556: ...21 settings 5 30 SOFTWARE installation 1 5 see entry for ENERVISTA UR SETUP SOFTWARE ARCHITECTURE 1 4 SOFTWARE PC see entry for EnerVista UR Setup SOURCE FREQUENCY 6 19 SOURCE TRANSFER SCHEMES 5 147 SOURCES description 5 5 example use of 5 68 metering 6 15 Modbus registers B 23 settings 5 67 5 68 SPECIFICATIONS 2 7 SPECTRAL ANALYSIS ALGORITHM FOR HI Z 8 2 ST TYPE CONNECTORS 3 26 STANDARD ABBREVIAT...

Page 557: ...lts 4 16 description 4 15 4 16 Modbus registers B 22 settings 5 44 specifications 2 10 USER PROGRAMMABLE PUSHBUTTONS FlexLogic operands 5 93 Modbus registers B 25 B 35 settings 5 47 specifications 2 11 USER PROGRAMMABLE SELF TESTS Modbus registers B 23 settings 5 45 USERST 1 BIT PAIR 5 213 V VAR HOURS 2 12 6 18 VIBRATION TESTING 2 17 VIRTUAL INPUTS actual values 6 3 commands 7 1 FlexLogic operands...

Page 558: ...x F60 Feeder Protection System GE Multilin INDEX ...

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