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GE B90 Instruction Manual

Ur series low impedance bus differential system.
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GE
Digital Energy
GE Digital Energy
650 Markland Street
Markham, Ontario
Canada L6C 0M1
Tel: +1 905 927 7070 Fax: +1 905 927 5098
Internet:
http://www.GEDigitalEnergy.com
*1601-0115-X3*
B90 Low Impedance Bus
Differential System
UR Series Instruction Manual
B90 revision: 6.0x
Manual P/N: 1601-0115-X3 (GEK-113612A)
E83849
LISTED
IND.CONT. EQ.
52TL
836771A2.CDR
GE Multilin's Quality Management
System is registered to ISO
9001:2008
QMI # 005094
UL # A3775

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  • Page 1

    Digital Energy B90 Low Impedance Bus Differential System UR Series Instruction Manual B90 revision: 6.0x Manual P/N: 1601-0115-X3 (GEK-113612A) 836771A2.CDR E83849 GE Digital Energy LISTED 650 Markland Street IND.CONT. EQ. 52TL Markham, Ontario GE Multilin's Quality Management Canada L6C 0M1...

  • Page 2

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

  • Page 3: Table Of Contents

    1.3 ENERVISTA UR SETUP SOFTWARE 1.3.1 REQUIREMENTS ....................1-6 1.3.2 SOFTWARE INSTALLATION ................1-6 1.3.3 CONFIGURING THE B90 FOR SOFTWARE ACCESS ........1-7 1.3.4 USING THE QUICK CONNECT FEATURE............. 1-10 1.3.5 CONNECTING TO THE B90 RELAY............... 1-16 1.4 UR HARDWARE 1.4.1...

  • Page 4: Table Of Contents

    DIRECT INPUTS AND OUTPUTS..............5-52 5.2.17 INSTALLATION ....................5-59 5.3 SYSTEM SETUP 5.3.1 AC INPUTS.......................5-60 5.3.2 POWER SYSTEM ....................5-61 5.3.3 FLEXCURVES™ ....................5-62 5.3.4 BUS ........................5-69 5.4 FLEXLOGIC™ 5.4.1 INTRODUCTION TO FLEXLOGIC™..............5-71 5.4.2 FLEXLOGIC™ RULES ..................5-77 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 5: Table Of Contents

    METERING CONVENTIONS ................6-8 6.3.2 BUS ZONE......................6-8 6.3.3 CURRENTS ....................... 6-9 6.3.4 VOLTAGES......................6-9 6.3.5 FREQUENCY..................... 6-9 6.3.6 IEC 61580 GOOSE ANALOG VALUES............6-10 6.4 RECORDS 6.4.1 USER-PROGRAMMABLE FAULT REPORTS ..........6-11 GE Multilin B90 Low Impedance Bus Differential System...

  • Page 6: Table Of Contents

    CT SATURATION DETECTION .................9-8 9.6 OUTPUT LOGIC AND EXAMPLES 9.6.1 OUTPUT LOGIC ....................9-10 9.6.2 INTERNAL AND EXTERNAL FAULT EXAMPLE ..........9-10 10. APPLICATION OF 10.1 OVERVIEW SETTINGS 10.1.1 INTRODUCTION ....................10-1 10.1.2 SAMPLE BUSBAR AND DATA ................10-1 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 7: Table Of Contents

    STORE SINGLE SETTING (FUNCTION CODE 06H) ........B-5 B.2.5 STORE MULTIPLE SETTINGS (FUNCTION CODE 10H) ........B-6 B.2.6 EXCEPTION RESPONSES ................B-6 B.3 FILE TRANSFERS B.3.1 OBTAINING RELAY FILES VIA MODBUS ............B-7 B.4 MEMORY MAPPING GE Multilin B90 Low Impedance Bus Differential System...

  • Page 8: Table Of Contents

    INTEROPERABILITY DOCUMENT..............D-1 D.1.2 IEC 60870-5-104 POINTS ................. D-9 E. DNP COMMUNICATIONS E.1 DEVICE PROFILE DOCUMENT E.1.1 DNP V3.00 DEVICE PROFILE ................E-1 E.1.2 IMPLEMENTATION TABLE ................E-4 E.2 DNP POINT LISTS viii B90 Low Impedance Bus Differential System GE Multilin...

  • Page 9: Table Of Contents

    BINARY AND CONTROL RELAY OUTPUT ............E-9 E.2.3 ANALOG INPUTS ....................E-10 F. MISCELLANEOUS F.1 CHANGE NOTES F.1.1 REVISION HISTORY ..................F-1 F.1.2 CHANGES TO THE B90 MANUAL..............F-1 F.2 ABBREVIATIONS F.2.1 STANDARD ABBREVIATIONS ................. F-5 F.3 WARRANTY F.3.1 GE MULTILIN WARRANTY ................F-7 GE Multilin...

  • Page 10

    TABLE OF CONTENTS B90 Low Impedance Bus Differential System GE Multilin...

  • Page 11: Cautions And Warnings

    1 GETTING STARTED 1.1 IMPORTANT PROCEDURES 1 GETTING STARTED 1.1IMPORTANT PROCEDURES Please read this chapter to help guide you through the initial setup of your new B90 Low Impedance Bus Differential Sys- tem. 1.1.1 CAUTIONS AND WARNINGS Before attempting to install or use the device, review all safety indicators in this document to help prevent injury, equipment damage, or downtime.

  • Page 12: Inspection Procedure

    For product information, instruction manual updates, and the latest software updates, please visit the GE Digital Energy website at http://www.gedigitalenergy.com. If there is any noticeable physical damage, or any of the contents listed are missing, please contact GE Digital Energy immediately.

  • Page 13: Introduction To The Ur

    This new generation of equipment must also be easily incorporated into automation systems, at both the station and enterprise levels. The GE Multilin Universal Relay (UR) has been developed to meet these goals. GE Multilin...

  • Page 14: Hardware Architecture

    (dual) ring configuration. This feature is optimized for speed and intended for pilot- aided schemes, distributed logic applications, or the extension of the input/output capabilities of a single relay chassis. B90 Low Impedance Bus Differential System GE Multilin...

  • Page 15: Ur Software Architecture

    Employing OOD/OOP in the software architecture of the B90 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 from the various functionality classes.

  • Page 16: Requirements

    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 B90 and the EnerVista UR Setup software. • US Robotics external 56K FaxModem 5686 •...

  • Page 17: Configuring The B90 For Software Access

    OVERVIEW The user can connect remotely to the B90 through the rear RS485 port or the rear Ethernet port with a PC running the EnerVista UR Setup software. The B90 can also be accessed locally with a computer through the front panel RS232 port or the rear Ethernet port using the Quick Connect feature.

  • Page 18

    RS232 port. A computer with an RS232 port and a serial cable is required. To use the RS485 port at the back of the relay, a GE Multilin F485 converter (or compatible RS232-to-RS485 converter) is required. See the F485 instruction manual for details.

  • Page 19

    11. Click the Read Order Code button to connect to the B90 device and upload the order code. If a communications error occurs, ensure that the EnerVista UR Setup serial communications values entered in the previous step correspond to the relay setting values.

  • Page 20: Using The Quick Connect Feature

    MODBUS PROTOCOL 11. Click the Read Order Code button to connect to the B90 device and upload the order code. If an communications error occurs, ensure that the three EnerVista UR Setup values entered in the previous steps correspond to the relay setting values.

  • Page 21

    B90. This ensures that configuration of the EnerVista UR Setup software matches the B90 model number. b) USING QUICK CONNECT VIA THE REAR ETHERNET PORTS To use the Quick Connect feature to access the B90 from a computer through Ethernet, first assign an IP address to the relay from the front panel keyboard.

  • Page 22

    Right-click the Local Area Connection icon and select Properties. Select the Internet Protocol (TCP/IP) item from the list provided and click the Properties button. Click on the “Use the following IP address” box. 1-12 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 23

    1 GETTING STARTED 1.3 ENERVISTA UR SETUP SOFTWARE Enter an IP address with the first three numbers the same as the IP address of the B90 relay and the last number different (in this example, 1.1.1.2). Enter a subnet mask equal to the one set in the B90 (in this example, 255.0.0.0).

  • Page 24

    If this computer is used to connect to the Internet, re-enable any proxy server settings after the laptop has been discon- nected from the B90 relay. Verify that the latest version of the EnerVista UR Setup software is installed (available from the GE enerVista CD or online from http://www.gedigitalenergy.com/multilin). See the Software Installation section for installation details.

  • Page 25

    Each time the EnerVista UR Setup software is initialized, click the Quick Connect button to establish direct communica- tions to the B90. This ensures that configuration of the EnerVista UR Setup software matches the B90 model number. When direct communications with the B90 via Ethernet is complete, make the following changes: From the Windows desktop, right-click the My Network Places icon and select Properties to open the network connections window.

  • Page 26: Connecting To The B90 Relay

    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 B90 relays. From the online window, users can select which relay to interro- gate from a pull-down window, then click on the button for the action they wish to perform. The following quick action func- tions are available: •...

  • Page 27: Mounting And Wiring

    Figure 1–7: RELAY COMMUNICATIONS OPTIONS To communicate through the B90 rear RS485 port from a PC RS232 port, the GE Multilin RS232/RS485 converter box is required. This device (catalog number F485) connects to the computer using a “straight-through” serial cable. A shielded twisted-pair (20, 22, or 24 AWG) connects the F485 converter to the B90 rear communications port.

  • Page 28: Faceplate Keypad

    LED off. The relay in the “Not Programmed” state will block signaling of any output relay. These conditions will remain until the relay is explicitly put in the “Programmed” state. Select the menu message    SETTINGS PRODUCT SETUP INSTALLATION RELAY SETTINGS RELAY SETTINGS: Not Programmed 1-18 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 29: Relay Passwords

    NOTE 1.5.6 FLEXLOGIC™ CUSTOMIZATION FlexLogic™ equation editing is required for setting up user-defined logic for customizing the relay operations. See the Flex- Logic™ section in Chapter 5 for additional details. GE Multilin B90 Low Impedance Bus Differential System 1-19...

  • Page 30: Commissioning

    1.5.7 COMMISSIONING The B90 requires a minimum amount of maintenance when it is commissioned into service. Since the B90 is a micropro- cessor-based relay, its characteristics do not change over time. As such, no further functional tests are required. Expected service life is 20 years for UR devices manufactured June 2014 or later when applied in a controlled indoors environment and electrical conditions within specification.

  • Page 31: Overview

    24 feeders. The B90 protection system is a centralized architecture built on three, four, or more B90 IEDs as per requirements of a particular application. Each IED of the B90 system is a full-featured B90 and as such can be accessed and programmed individually.

  • Page 32

    Setting groups (6) DNP 3.0 or IEC 60870-5-104 communications Time synchronization over SNTP Dynamic bus replica User definable displays End fault protection User-programmable fault reports Event recorder User-programmable LEDs FlexLogic™ equations User-programmable pushbuttons B90 Low Impedance Bus Differential System GE Multilin...

  • Page 33

    Virtual outputs (96 per IED) The main protection functions of the B90 are provided on a per-phase basis. The AC signals of a given phase, both cur- rents and voltages, are connected and processed by a single IED. These IEDs provide for all the protection and monitoring functions that require the AC information.

  • Page 34

    2.1 INTRODUCTION 2 PRODUCT DESCRIPTION Figure 2–2: THREE-, FOUR-, AND FIVE-IED B90 ARCHITECTURE The following figures show sample applications of the B90 protection system: Figure 2–3: SINGLE BUS B90 Low Impedance Bus Differential System GE Multilin...

  • Page 35

    2 PRODUCT DESCRIPTION 2.1 INTRODUCTION Figure 2–4: DOUBLE BUS Figure 2–5: TRIPLE BUS GE Multilin B90 Low Impedance Bus Differential System...

  • Page 36

    2.1 INTRODUCTION 2 PRODUCT DESCRIPTION Figure 2–6: DOUBLE BUS WITH TRANSFER Figure 2–7: BREAKER-AND-A-HALF CONFIGURATION BUS B90 Low Impedance Bus Differential System GE Multilin...

  • Page 37

    2 PRODUCT DESCRIPTION 2.1 INTRODUCTION Figure 2–8: SINGLE BUS WITH A SINGLE TIE BREAKER Figure 2–9: DOUBLE BUS WITH ONE TIE BREAKER ON EACH BUS GE Multilin B90 Low Impedance Bus Differential System...

  • Page 38

    2.1 INTRODUCTION 2 PRODUCT DESCRIPTION Figure 2–10: APPLICATION INVOLVING TWO OR MORE B90 SYSTEMS Figure 2–11: APPLICATION TO 8-FEEDER BUSBARS B90 Low Impedance Bus Differential System GE Multilin...

  • Page 39: Ordering

    Before ordering the B90 system, an analysis of the required protection and monitoring functions is required. Please refer to the UR overview section in chapter 1 for details of the B90 architecture. Also, detailed analyses of required AC inputs and input/output contacts must be performed to select appropriate hardware configurations for each of the B90's IEDs.

  • Page 40

    Channel 1 - RS422; Channel 2 - 1300 nm, single-mode, LASER Channel 1 - G.703; Channel 2 - 1300 nm, single-mode LASER G.703, 1 Channel G.703, 2 Channels RS422, 1 Channel RS422, 2 Channels 2-10 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 41: Replacement Modules

    Replacement modules can be ordered separately as shown below. When ordering a replacement CPU module or face- plate, please provide the serial number of your existing unit. Not all replacement modules may be applicable to the B90 relay. Only the modules specified in the order codes are available as replacement modules.

  • Page 42: Protection Elements

    Operate time: <2 ms at 60 Hz Reset type: Instantaneous or Timed (per IEEE) Time accuracy: ±3% or 10 ms, whichever is greater Time accuracy: ±3% or ±40 ms, whichever is greater 2-12 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 43: User-programmable Elements

    Pre-fault trigger: any FlexLogic™ operand input state; digital output state Fault trigger: any FlexLogic™ operand Data storage: in non-volatile memory Recorder quantities: 32 (any FlexAnalog value) EVENT RECORDER Capacity: 1024 events GE Multilin B90 Low Impedance Bus Differential System 2-13...

  • Page 44: Metering

    Unreturned message alarm: Responding to: Rate of unreturned messages in the ring configuration Monitoring message count: 10 to 10000 in steps of 1 Alarm threshold: 1 to 1000 in steps of 1 2-14 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 45: Power Supply

    Operate time: < 0.6 ms FORM-A VOLTAGE MONITOR Internal Limiting Resistor: 100 Ω, 2 W Applicable voltage: approx. 15 to 250 V DC Trickle current: approx. 1 to 2.5 mA GE Multilin B90 Low Impedance Bus Differential System 2-15...

  • Page 46: Communication Protocols

    Maximum input –7.6 dBm –14 dBm –7 dBm power Typical distance 1.65 km 2 km 15 km Duplex full/half full/half full/half Redundancy The UR-2S and UR-2T only support 100 Mb multimode 2-16 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 47: Inter-relay Communications

    – Overvoltage category: 20°C Ingress protection: IP20 front, IP10 back HUMIDITY Noise 0 dB Humidity: operating up to 95% (non-condensing) at 55°C (as per IEC60068-2-30 variant 1, 6days). GE Multilin B90 Low Impedance Bus Differential System 2-17...

  • Page 48: Type Tests

    UL508 e83849 NKCR Safety UL C22.2-14 e83849 NKCR7 Safety UL1053 e83849 NKCR 2.2.12 PRODUCTION TESTS THERMAL Products go through an environmental test based upon an Accepted Quality Level (AQL) sampling process. 2-18 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 49: Approvals

    Units that are stored in a de-energized state should be powered up once per year, for one hour continuously, to avoid deterioration of electrolytic capacitors. GE Multilin B90 Low Impedance Bus Differential System 2-19...

  • Page 50

    2.2 SPECIFICATIONS 2 PRODUCT DESCRIPTION 2-20 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 51: Panel Cutout

    3.1.1 PANEL CUTOUT The B90 Low Impedance Bus Differential System is available as a 19-inch rack horizontal mount unit with a removable faceplate. The faceplate can be specified as either standard or enhanced at the time of ordering. The enhanced faceplate contains additional user-programmable pushbuttons and LED indicators.

  • Page 52

    3.1 DESCRIPTION 3 HARDWARE Figure 3–2: B90 HORIZONTAL MOUNTING (ENHANCED PANEL) Figure 3–3: B90 HORIZONTAL MOUNTING AND DIMENSIONS (STANDARD PANEL) B90 Low Impedance Bus Differential System GE Multilin...

  • Page 53: Rear Terminal Layout

    (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. Figure 3–5: EXAMPLE OF MODULES IN F AND H SLOTS GE Multilin B90 Low Impedance Bus Differential System...

  • Page 54: Typical Wiring

    3.2 WIRING 3 HARDWARE 3.2WIRING 3.2.1 TYPICAL WIRING Figure 3–6: B90 IS A MULTI-IED PROTECTION SYSTEM B90 Low Impedance Bus Differential System GE Multilin...

  • Page 55

    The wiring diagrams on the next four pages are based on the following order code: B90-K02-HCL-F8H-H6H-L8H-N6A-S8H-U6H-W7H. The purpose of these diagrams is to provide examples of how the B90 is typically wired, not specifically how to wire your own relay. Please refer to the sections following the wiring dia- grams for examples on connecting your relay correctly based on your relay configuration and order code.

  • Page 56

    3.2 WIRING 3 HARDWARE Figure 3–7: TYPICAL WIRING DIAGRAM (PHASE A) B90 Low Impedance Bus Differential System GE Multilin...

  • Page 57

    3 HARDWARE 3.2 WIRING Figure 3–8: TYPICAL WIRING DIAGRAM (PHASE B) GE Multilin B90 Low Impedance Bus Differential System...

  • Page 58

    3.2 WIRING 3 HARDWARE Figure 3–9: TYPICAL WIRING DIAGRAM (PHASE C) B90 Low Impedance Bus Differential System GE Multilin...

  • Page 59

    3 HARDWARE 3.2 WIRING Figure 3–10: TYPICAL WIRING DIAGRAM (BREAKER FAIL AND ISOLATOR MONITORING) GE Multilin B90 Low Impedance Bus Differential System...

  • Page 60: Dielectric Strength

    (see the Self-test errors section in chapter 7) or control power is lost, the relay will de-energize. For high reliability systems, the B90 has a redundant option in which two B90 power supplies are placed in parallel on the bus.

  • Page 61: Ct And Vt Modules

    1 to 50000 A primaries and 1 A or 5 A secondaries may be used. Each B90 voltage input is intended for monitoring a single-phase voltage. The may include phase voltages or neutral volt- age from the open-delta VT.

  • Page 62: Contact Inputs And Outputs

    The terminal configuration for contact inputs is different for the two applications. The contact inputs are grouped with a common return. The B90 has two versions of grouping: four inputs per common return and two inputs per common return. When a contact input/output module is ordered, four inputs per common is used.

  • Page 63

    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 output is bouncing, at val- ues in the region of the pickup value). GE Multilin B90 Low Impedance Bus Differential System 3-13...

  • Page 64

    ~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 3-14 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 65

    ~5a, ~5c 2 Inputs 2 Outputs Solid-State Solid-State ~6a, ~6c 2 Inputs 2 Outputs Not Used Not Used ~7a, ~7c 2 Inputs 2 Outputs Solid-State Solid-State ~8a, ~8c 2 Inputs Not Used GE Multilin B90 Low Impedance Bus Differential System 3-15...

  • Page 66

    3.2 WIRING 3 HARDWARE Figure 3–14: CONTACT INPUT AND OUTPUT MODULE WIRING (1 of 2) 3-16 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 67

    3.2 WIRING Figure 3–15: CONTACT INPUT AND OUTPUT MODULE WIRING (2 of 2) For proper functionality, observe the polarity shown in the figures for all contact input and output con- nections. GE Multilin B90 Low Impedance Bus Differential System 3-17...

  • Page 68

    Wherever a tilde “~” symbol appears, substitute with the slot position of the module. NOTE There is no provision in the relay to detect a DC ground fault on 48 V DC control power external output. We recommend using an external DC supply. 3-18 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 69

    = ON 842751A1.CDR Figure 3–18: AUTO-BURNISH DIP SWITCHES The auto-burnish circuitry has an internal fuse for safety purposes. During regular maintenance, the auto-burnish functionality can be checked using an oscilloscope. NOTE GE Multilin B90 Low Impedance Bus Differential System 3-19...

  • Page 70: Rs232 Faceplate Port

    3.2.6 RS232 FACEPLATE PORT A 9-pin RS232C serial port is located on the B90 faceplate for programming with a personal computer. All that is required to use this interface is a personal computer running the EnerVista UR Setup software provided with the relay. Cabling for the RS232 port is shown in the following figure for both 9-pin and 25-pin connectors.

  • Page 71

    For instance, the relays must be connected with all RS485 “+” terminals connected together, and all RS485 “–” terminals connected together. Though data is transmitted over a two-wire twisted pair, all RS485 devices require a shared GE Multilin B90 Low Impedance Bus Differential System 3-21...

  • Page 72

    This common voltage is implied to be a power supply common. Some systems allow the shield (drain wire) to be used as common wire and to connect directly to the B90 COM terminal (#3); others function cor- rectly only if the common wire is connected to the B90 COM terminal, but insulated from the shield.

  • Page 73: Irig-b

    IRIG-B is a standard time code format that allows stamping of events to be synchronized among connected devices. The IRIG-B code allows time accuracies of up to 100 ns. Using the IRIG-B input, the B90 operates an internal oscillator with 1 µs resolution and accuracy.

  • Page 74

    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 3–23: IRIG-B REPEATER Using an amplitude modulated receiver will cause errors up to 1 ms in event time-stamping. NOTE 3-24 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 75: Description

    3.3.1 DESCRIPTION The B90 direct inputs and outputs feature makes use of the type 7 series of communications modules. These modules are also used by the L90 Line Differential Relay for inter-relay communications. The direct input and output feature uses the communications channels provided by these modules to exchange digital state information between relays.

  • Page 76

    These modules are listed in the following table. All fiber modules use ST type connectors. Not all the direct input and output communications modules outlined in the table are applicable to the B90. Use your order code with the tables in chapter 2 to determine applicable options.

  • Page 77: Fiber: Led And Eled Transmitters

    The following figure shows the configuration for the 7A, 7B, 7C, 7H, 7I, and 7J fiber-only modules. Figure 3–27: LED AND ELED FIBER MODULES 3.3.3 FIBER-LASER TRANSMITTERS The following figure shows the configuration for the 72, 73, 7D, and 7K fiber-laser module. Figure 3–28: LASER FIBER MODULES GE Multilin B90 Low Impedance Bus Differential System 3-27...

  • Page 78

    Observing any fiber transmitter output can injure the eye. When using a laser Interface, attenuators may be necessary to ensure that you do not exceed the maximum optical input power to the receiver. 3-28 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 79: G.703 Interface

    Remove the top cover by sliding it towards the rear and then lift it upwards. Set the timing selection switches (channel 1, channel 2) to the desired timing modes. Replace the top cover and the cover screw. GE Multilin B90 Low Impedance Bus Differential System 3-29...

  • Page 80

    For connection to a higher order system (UR- to-multiplexer, factory defaults), set to octet timing (S1 = ON) and set timing mode to loop timing (S5 = OFF and S6 = OFF). 3-30 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 81

    G.703 line side of the interface while the other lies on the differential Manchester side of the interface. DMR = Differential Manchester Receiver DMX = Differential Manchester Transmitter G7X = G.703 Transmitter G7R = G.703 Receiver 842775A1.CDR Figure 3–33: G.703 DUAL LOOPBACK MODE GE Multilin B90 Low Impedance Bus Differential System 3-31...

  • Page 82: Rs422 Interface

    1 as shown below. If the terminal timing feature is not available or this type of connection is not desired, the G.703 interface is a viable option that does not impose timing restrictions. 3-32 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 83

    Figure 3–36: TIMING CONFIGURATION FOR RS422 TWO-CHANNEL, 3-TERMINAL APPLICATION Data module 1 provides timing to the B90 RS422 interface via the ST(A) and ST(B) outputs. Data module 1 also provides timing to data module 2 TT(A) and TT(B) inputs via the ST(A) and AT(B) outputs. The data module pin numbers have been omitted in the figure above since they may vary depending on the manufacturer.

  • Page 84: Rs422 And Fiber Interface

    When using a laser Interface, attenuators may be necessary to ensure that you do not exceed the maximum optical input power to the receiver. Figure 3–39: G.703 AND FIBER INTERFACE CONNECTION 3-34 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 85: Ieee C37.94 Interface

    5.60. For customers using firmware release 5.60 and higher, the module can be identified with "Rev D" printed on the module and is to be used on all ends of B90 communi- cation for two and three terminal applications.

  • Page 86

    Once the clips have cleared the raised edge of the chassis, engage the clips simultaneously. When the clips have locked into position, the module will be fully inserted. 3-36 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 87

    3 HARDWARE 3.3 DIRECT INPUT/OUTPUT COMMUNICATIONS Figure 3–40: IEEE C37.94 TIMING SELECTION SWITCH SETTING GE Multilin B90 Low Impedance Bus Differential System 3-37...

  • Page 88

    Solid yellow — FPGA is receiving a "yellow bit" and remains yellow for each "yellow bit" • Solid red — FPGA is not receiving a valid packet or the packet received is invalid 3-38 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 89: C37.94sm Interface

    5.60. For customers using firmware release 5.60 and higher, the module can be identified with "Rev D" printed on the module and is to be used on all ends of B90 communi- cation for two and three terminal applications.

  • Page 90

    Once the clips have cleared the raised edge of the chassis, engage the clips simultaneously. When the clips have locked into position, the module will be fully inserted. 3-40 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 91

    Modules shipped from January 2012 have status LEDs that indicate the status of the DIP switches, as shown in the follow- ing figure. Figure 3–43: STATUS LEDS The clock configuration LED status is as follows: • Flashing green — loop timing mode while receiving a valid data packet GE Multilin B90 Low Impedance Bus Differential System 3-41...

  • Page 92

    Solid yellow — FPGA is receiving a "yellow bit" and remains yellow for each "yellow bit" • Solid red — FPGA is not receiving a valid packet or the packet received is invalid 3-42 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 93: Introduction

    To start using the EnerVista UR Setup software, a site definition and device definition must first be created. See the EnerV- ista UR Setup Help File or refer to the Connecting EnerVista UR Setup with the B90 section in Chapter 1 for details.

  • Page 94

    Site List window will automatically be sent to the on-line communicating device. g) FIRMWARE UPGRADES The firmware of a B90 device can be upgraded, locally or remotely, via the EnerVista UR Setup software. The correspond- ing instructions are provided by the EnerVista UR Setup Help file under the topic “Upgrading Firmware”.

  • Page 95: Enervista Ur Setup Main Window

    Settings list control bar window. Device data view windows, with common tool bar. Settings file data view windows, with common tool bar. Workspace area with data view tabs. Status bar. 10. Quick action hot links. GE Multilin B90 Low Impedance Bus Differential System...

  • Page 96

    4.1 ENERVISTA UR SETUP SOFTWARE INTERFACE 4 HUMAN INTERFACES 842786A2.CDR Figure 4–1: ENERVISTA UR SETUP SOFTWARE MAIN WINDOW B90 Low Impedance Bus Differential System GE Multilin...

  • Page 97: Settings Templates

    (settings file templates) and online devices (online settings templates). The func- tionality is identical for both purposes. The settings template feature requires that both the EnerVista UR Setup software and the B90 firmware are at ver- sions 5.40 or higher.

  • Page 98

    The following procedure describes how to add password protection to a settings file template. Select a settings file from the offline window on the left of the EnerVista UR Setup main screen. Selecting the Template Mode > Password Protect Template option. B90 Low Impedance Bus Differential System GE Multilin...

  • Page 99

    The template specifies that only the Pickup Curve Phase time overcurrent settings window without template applied. settings be available. 842858A1.CDR Figure 4–4: APPLYING TEMPLATES VIA THE VIEW IN TEMPLATE MODE COMMAND GE Multilin B90 Low Impedance Bus Differential System...

  • Page 100

    Select an installed device or settings file from the tree menu on the left of the EnerVista UR Setup main screen. Select the Template Mode > Remove Settings Template option. Enter the template password and click OK to continue. B90 Low Impedance Bus Differential System GE Multilin...

  • Page 101: Securing And Locking Flexlogic™ Equations

    Click on Save to save and apply changes to the settings template. Select the Template Mode > View In Template Mode option to view the template. Apply a password to the template then click OK to secure the FlexLogic™ equation. GE Multilin B90 Low Impedance Bus Differential System...

  • Page 102

    FlexLogic™ entries in a settings file have been secured, use the following procedure to lock the settings file to a specific serial number. Select the settings file in the offline window. Right-click on the file and select the Edit Settings File Properties item. 4-10 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 103: Settings File Traceability

    When a settings file is transferred to a B90 device, the date, time, and serial number of the B90 are sent back to EnerVista UR Setup and added to the settings file on the local PC. This infor- mation can be compared with the B90 actual values at any later date to determine if security has been compromised.

  • Page 104

    4 HUMAN INTERFACES The transfer date of a setting file written to a B90 is logged in the relay and can be viewed via EnerVista UR Setup or the front panel display. Likewise, the transfer date of a setting file saved to a local PC is logged in EnerVista UR Setup.

  • Page 105

    ONLINE DEVICE TRACEABILITY INFORMATION The B90 serial number and file transfer date are available for an online device through the actual values. Select the Actual Values > Product Info > Model Information menu item within the EnerVista UR Setup online window as shown in the example below.

  • Page 106: Faceplate

    The following figure shows the horizontal arrangement of the faceplate panels. Figure 4–16: UR-SERIES STANDARD HORIZONTAL FACEPLATE PANELS 4-14 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 107: Led Indicators

    CURRENT: This LED indicates current was involved. • FREQUENCY: This LED indicates frequency was involved. • OTHER: This LED indicates a composite function was involved. • PHASE A: Not used. • PHASE B: Not used. GE Multilin B90 Low Impedance Bus Differential System 4-15...

  • Page 108

    Support for applying a customized label beside every LED is provided. Default labels are shipped in the label pack- age of every B90, 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 other than English are used to communicate with operators.

  • Page 109

    LED settings must be entered as shown in the User-programmable LEDs section of chapter 5. The LEDs are fully user-programmable. The default labels can be replaced by user-printed labels for both panels as explained in the following section. Figure 4–20: LED PANEL 2 (DEFAULT LABELS) GE Multilin B90 Low Impedance Bus Differential System 4-17...

  • Page 110: Custom Labeling Of Leds

    Enter the text to appear next to each LED and above each user-programmable pushbuttons in the fields provided. Feed the B90 front panel label cutout sheet into a printer and press the Print button in the front panel report window.

  • Page 111

    Bend the tabs at the left end of the tool upwards as shown below. Bend the tab at the center of the tool tail as shown below. The following procedure describes how to remove the LED labels from the B90 enhanced front panel and insert the custom labels.

  • Page 112

    Slide the new LED label inside the 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 B90 enhanced front panel and insert the custom labels.

  • Page 113

    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. Remove the tool and attached user-programmable pushbutton label as shown below. GE Multilin B90 Low Impedance Bus Differential System 4-21...

  • Page 114: Display

    Each press of the MENU key advances through the following main heading pages: • Actual values. • Settings. • Commands. • Targets. • User displays (when enabled). 4-22 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 115

     PROPERTIES ciated with the Product Setup header.  Press the MESSAGE RIGHT key once more and this will display the first setting for FLASH MESSAGE Display Properties. TIME: 1.0 s GE Multilin B90 Low Impedance Bus Differential System 4-23...

  • Page 116: Changing Settings

    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. 4-24 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 117

    When the "NEW SETTING HAS BEEN STORED" message appears, the relay will be in "Programmed" state and the In Service LED will turn on. e) ENTERING INITIAL PASSWORDS The B90 supports password entry from a local or remote connection. GE Multilin B90 Low Impedance Bus Differential System...

  • Page 118

    By default, when an incorrect Command or Setting password has been entered via the faceplate interface three times within three minutes, the FlexLogic™ operand is set to “On” and the B90 does not allow settings or LOCAL ACCESS DENIED command level access via the faceplate interface for the next five minutes.

  • Page 119

    FlexLogic™ operand is set to “Off” after five minutes for a Command password or 30 minutes for a Settings pass- DENIED word. These default settings can be changed in EnerVista under Settings > Product Setup > Security. GE Multilin B90 Low Impedance Bus Differential System 4-27...

  • Page 120

    4.3 FACEPLATE INTERFACE 4 HUMAN INTERFACES 4-28 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 121: Settings Menu

      SETTINGS  AC INPUTS See page 5-60.  SYSTEM SETUP   POWER SYSTEM See page 5-61.   FLEXCURVES See page 5-62.   BUS See page 5-69.  GE Multilin B90 Low Impedance Bus Differential System...

  • Page 122

    See page 5-121.   VIRTUAL OUTPUTS See page 5-123.   REMOTE DEVICES See page 5-124.   REMOTE INPUTS See page 5-125.   REMOTE DPS INPUTS See page 5-126.  B90 Low Impedance Bus Differential System GE Multilin...

  • Page 123: Introduction To Elements

    Where the current source is from a single CT, the base quantity is the nominal secondary or primary current of the CT. Use the secondary current base to convert per-unit current settings to/from a secondary current value, and use the primary cur- rent base to convert to/from a primary current value. GE Multilin B90 Low Impedance Bus Differential System...

  • Page 124

    Not every operand of a given element in a UR relay generates events, only the major output operands. Elements, asserting output per phase, log operating phase output only, without asserting the common three-phase operand event. B90 Low Impedance Bus Differential System GE Multilin...

  • Page 125: B90 Function

    (both protection B90 FUNCTION and logic), download the same file to all the B90 IEDs, and modify the settings accordingly to finalize the application. Com- munications and settings are typically modified when downloading the common B90 setting file.

  • Page 126

    When entering a settings or command password via EnerVista or any serial interface, the user must enter the correspond- ing connection password. If the connection is to the back of the B90, the remote password must be used. If the connection is to the RS232 port of the faceplate, the local password must be used.

  • Page 127

    The new password is accepted and a value is assigned to the item. ENCRYPTED PASSWORD If a command or setting password is lost (or forgotten), consult the factory with the corresponding Encrypted Password value. GE Multilin B90 Low Impedance Bus Differential System...

  • Page 128

    INVALID ATTEMPTS BEFORE LOCKOUT The B90 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 FlexLogic operand is UNAUTHORIZED ACCESS asserted.

  • Page 129

    If access is permitted and an off-to-on transition of the FlexLogic operand is detected, the timeout is restarted. The status of this timer is updated every 5 seconds. GE Multilin B90 Low Impedance Bus Differential System...

  • Page 130: Display Properties

    Some customers prefer very low currents to display as zero, while others prefer the current be displayed even when the value reflects noise rather than the actual signal. The B90 applies a cut- off value to the magnitudes and angles of the measured currents.

  • Page 131: Clear Relay Records

    Selected records can be cleared from user-programmable conditions with FlexLogic™ operands. Assigning user-program- mable pushbuttons to clear specific records are typical applications for these commands. Since the B90 responds to rising edges of the configured FlexLogic™ operands, they must be asserted for at least 50 ms to take effect.

  • Page 132: Communications

    0 ms The B90 is equipped with up to three independent serial communication ports. The faceplate RS232 port is intended for local use and is fixed at 19200 baud and no parity. The rear COM1 port type is selected when ordering: either an Ethernet or RS485 port.

  • Page 133

    This allows the EnerVista UR Setup software to be used on the port. The UR operates as a Modbus slave device only. When using Modbus protocol on the RS232 port, the B90 responds regardless of the pro- MODBUS SLAVE ADDRESS grammed.

  • Page 134

    MESSAGE DEADBAND: 30000 Range: 0 to 100000000 in steps of 1 DNP VOLTAGE DEFAULT MESSAGE DEADBAND: 30000 Range: 0 to 100000000 in steps of 1 DNP POWER DEFAULT MESSAGE DEADBAND: 30000 5-14 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 135

    TIMEOUT: 120 s The B90 supports the Distributed Network Protocol (DNP) version 3.0. The B90 can be used as a DNP slave device con- nected to multiple DNP masters (usually an RTU or a SCADA master station). Since the B90 maintains two sets of DNP data change buffers and connection information, two DNP masters can actively communicate with the B90 at one time.

  • Page 136

    DNP analog input points that are voltages will be returned with values 1000 times smaller (for example, a value of 72000 V on the B90 will be returned as 72). These settings are useful when analog input values must be adjusted to fit within cer- tain ranges in DNP masters.

  • Page 137

    When the DNP data points (analog inputs and/or binary inputs) are configured for Ethernet-enabled relays, check the “DNP Points Lists” B90 web page to view the points lists. This page can be viewed with a web browser by enter- ing the B90 IP address to access the B90 “Main Menu”, then by selecting the “Device Information Menu” > “DNP NOTE Points Lists”...

  • Page 138

    60870-5-104 point lists must be in one continuous block, any points assigned after the first “Off” point are ignored. NOTE Changes to the DNP / IEC 60870-5-104 point lists will not take effect until the B90 is restarted. NOTE 5-18...

  • Page 139

    The B90 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 B90 operates as an IEC 61850 server. The Remote inputs and outputs section in this chapter describe the peer-to-peer GSSE/GOOSE message scheme.

  • Page 140

    IEC 61850 GSSE application ID name string sent as part of each GSSE message. This GSSE ID string identifies the GSSE message to the receiving device. In B90 releases previous to 5.0x, this name string was repre- sented by the setting.

  • Page 141

    DESTINATION MAC address; the least significant bit of the first byte must be set. In B90 releases previous to 5.0x, the destination Ethernet MAC address was determined automatically by taking the sending MAC address (that is, the unique, local MAC address of the B90) and setting the multicast bit.

  • Page 142

    The B90 has the ability of detecting if a data item in one of the GOOSE datasets is erroneously oscillating. This can be caused by events such as errors in logic programming, inputs improperly being asserted and de-asserted, or failed station components.

  • Page 143

    Configure the transmission dataset. Configure the GOOSE service settings. Configure the data. The general steps required for reception configuration are: Configure the reception dataset. Configure the GOOSE service settings. Configure the data. GE Multilin B90 Low Impedance Bus Differential System 5-23...

  • Page 144

    MMXU1 HZ DEADBAND change greater than 45 mHz, from the previous MMXU1.MX.mag.f value, in the source frequency. The B90 must be rebooted (control power removed and re-applied) before these settings take effect. The following procedure illustrates the reception configuration. Configure the reception dataset by making the following changes in the ...

  • Page 145

    IEC61850 GOOSE ANALOG INPUT 1 UNITS The GOOSE analog input 1 can now be used as a FlexAnalog™ value in a FlexElement™ or in other settings. The B90 must be rebooted (control power removed and re-applied) before these settings take effect.

  • Page 146

    DNA and UserSt bit pairs that are included in GSSE messages. To set up a B90 to receive a configurable GOOSE dataset that contains two IEC 61850 single point status indications, the following dataset items can be selected (for example, for configurable GOOSE dataset 1): “GGIO3.ST.Ind1.stVal” and “GGIO3.ST.Ind2.stVal”.

  • Page 147

    CPU resources. When server scanning is disabled, there will be not updated to the IEC 61850 logical node sta- tus values in the B90. Clients will still be able to connect to the server (B90 relay), but most data values will not be updated.

  • Page 148

    The GGIO2 control configuration settings are used to set the control model for each input. The available choices are “0” (status only), “1” (direct control), and “2” (SBO with normal security). The GGIO2 control points are used to control the B90 virtual inputs.

  • Page 149

    GGIO4. When this value is NUMBER OF ANALOG POINTS changed, the B90 must be rebooted in order to allow the GGIO4 logical node to be re-instantiated and contain the newly configured number of analog points.

  • Page 150

    Internet Explorer or Mozilla Firefox. This feature is available only if the B90 has the ethernet option installed. The web pages are organized as a series of menus that can be accessed starting at the B90 “Main Menu”. Web pages are available...

  • Page 151

    NUMBER: The Trivial File Transfer Protocol (TFTP) can be used to transfer files from the B90 over a network. The B90 operates as a TFTP server. TFTP client software is available from various sources, including Microsoft Windows NT. The dir.txt file obtained from the B90 contains a list and description of all available files (event records, oscillography, etc.).

  • Page 152

    B90 clock is closely synchronized with the SNTP/NTP server. It may take up to two minutes for the B90 to signal an SNTP self-test error if the server is offline.

  • Page 153: Modbus User Map

    Range: Sunday to Saturday (all days of the week) DST STOP DAY: MESSAGE Sunday Range: First, Second, Third, Fourth, Last DST STOP DAY MESSAGE INSTANCE: First Range: 0:00 to 23:00 DST STOP HOUR: MESSAGE 2:00 GE Multilin B90 Low Impedance Bus Differential System 5-33...

  • Page 154: User-programmable Fault Report

    SNTP, the offset is used to determine the local time for the B90 clock, since SNTP provides UTC time. The daylight savings time (DST) settings can be used to allow the B90 clock can follow the DST rules of the local time zone.

  • Page 155: Oscillography

    See the  ACTUAL VALUES  menu to view the number of cycles captured per record. The following table provides sam- RECORDS OSCILLOGRAPHY ple configurations with corresponding cycles/record. GE Multilin B90 Low Impedance Bus Differential System 5-35...

  • Page 156

    DIGITAL 1(63) CHANNEL each oscillography trace depends in part on the number of parameters selected here. Parameters set to “Off” are ignored. Upon startup, the relay will automatically prepare the parameter list. 5-36 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 157: User-programmable Leds

     TRIP & ALARM LEDS MESSAGE See page 5–40.   USER-PROGRAMMABLE MESSAGE See page 5–40.  LED 1  USER-PROGRAMMABLE MESSAGE  LED 2 ↓  USER-PROGRAMMABLE MESSAGE  LED 48 GE Multilin B90 Low Impedance Bus Differential System 5-37...

  • Page 158

    The test responds to the position and rising edges of the control input defined by the set- LED TEST CONTROL ting. The control pulses must last at least 250 ms to take effect. The following diagram explains how the test is executed. 5-38 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 159

    2. Once stage 2 has started, the pushbutton can be released. When stage 2 is completed, stage 3 will automatically start. The test may be aborted at any time by pressing the pushbutton. GE Multilin B90 Low Impedance Bus Differential System 5-39...

  • Page 160

    LED 19 operand LED 8 operand LED 20 operand LED 9 operand LED 21 operand LED 10 operand LED 22 operand LED 11 operand LED 23 operand LED 12 operand LED 24 operand 5-40 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 161: User-programmable Self Tests

    Refer to the Relay self-tests section in chapter 7 for additional information on major and minor self-test alarms. self-test is not applicable to the B90 device. ETHERNET SWITCH FAIL FUNCTION NOTE 5.2.12 CONTROL PUSHBUTTONS...

  • Page 162

    The location of the control pushbuttons are shown in the following figures. Control pushbuttons 842813A1.CDR Figure 5–3: CONTROL PUSHBUTTONS (ENHANCED FACEPLATE) An additional four control pushbuttons are included on the standard faceplate when the B90 is ordered with the twelve user- programmable pushbutton option. STATUS EVENT CAUSE...

  • Page 163: User-programmable Pushbuttons

    FlexLogic™ equations, protection elements, and control elements. Typical applications include breaker control, autorecloser blocking, and setting groups changes. The user-programmable pushbuttons are under the control level of password protection. The user-configurable pushbuttons for the enhanced faceplate are shown below. GE Multilin B90 Low Impedance Bus Differential System 5-43...

  • Page 164

    BTN 1 SET The pushbutton is reset (deactivated) in self-reset mode when the dropout delay specified in the PUSHBTN 1 DROP-OUT setting expires. TIME 5-44 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 165

    • PUSHBTN 1 REMOTE: This setting assigns the FlexLogic™ operand serving to inhibit pushbutton operation from the operand assigned to the settings. PUSHBTN 1 SET PUSHBTN 1 RESET GE Multilin B90 Low Impedance Bus Differential System 5-45...

  • Page 166

    “High Priority” or “Normal”. PUSHBTN 1 MESSAGE • PUSHBUTTON 1 EVENTS: If this setting is enabled, each pushbutton state change will be logged as an event into event recorder. 5-46 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 167

    SETTING SETTING Autoreset Delay Autoreset Function = Enabled = Disabled SETTING Drop-Out Timer TIMER FLEXLOGIC OPERAND 200 ms PUSHBUTTON 1 ON 842021A3.CDR Figure 5–8: USER-PROGRAMMABLE PUSHBUTTON LOGIC (Sheet 1 of 2) GE Multilin B90 Low Impedance Bus Differential System 5-47...

  • Page 168

    User-programmable pushbuttons require a type HP or HQ faceplate. If an HP or HQ type faceplate was ordered separately, the relay order code must be changed to indicate the correct faceplate option. This can be done via EnerVista UR Setup with the Maintenance > Enable Pushbutton command. NOTE 5-48 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 169: Flex State Parameters

    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. GE Multilin B90 Low Impedance Bus Differential System 5-49...

  • Page 170

    (setting, actual value, or command) which has a Modbus address, to view the hexadecimal form of the Modbus address, then manually convert it to decimal form before entering it (EnerVista UR Setup usage conveniently facilitates this conversion). 5-50 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 171

    If the parameters for the top line and the bottom line items have the same units, then the unit is displayed on the bottom line only. The units are only displayed on both lines if the units specified both the top and bottom line items are different. NOTE GE Multilin B90 Low Impedance Bus Differential System 5-51...

  • Page 172: Direct Inputs And Outputs

    “Yes”), all direct output messages should be received back. If not, the direct input/output ring CH2 RING CONFIGURATION break self-test is triggered. The self-test error is signaled by the FlexLogic™ operand. DIRECT RING BREAK 5-52 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 173

    DIRECT I/O CHANNEL CROSSOVER over messages from channel 1 to channel 2. This places all UR-series IEDs into one direct input and output network regardless of the physical media of the two communication channels. GE Multilin B90 Low Impedance Bus Differential System 5-53...

  • Page 174

    BLOCK UR IED 4 UR IED 2 UR IED 3 842712A1.CDR Figure 5–11: SAMPLE INTERLOCKING BUSBAR PROTECTION SCHEME For increased reliability, a dual-ring configuration (shown below) is recommended for this application. 5-54 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 175

    The complete application requires addressing a number of issues such as failure of both the communications rings, failure or out-of-service conditions of one of the relays, etc. Self-monitoring flags of the direct inputs and outputs feature would be primarily used to address these concerns. GE Multilin B90 Low Impedance Bus Differential System 5-55...

  • Page 176

    Inputs and outputs section. A blocking pilot-aided scheme should be implemented with more security and, ideally, faster message delivery time. This could be accomplished using a dual-ring configuration as shown below. 5-56 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 177

    EVENTS: Disabled The B90 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.

  • Page 178

    MESSAGE EVENTS: Disabled The B90 checks integrity of the direct input and output communication ring by counting unreturned messages. In the ring configuration, all messages originating at a given device should return within a pre-defined period of time. The unreturned messages alarm function is available for monitoring the integrity of the communication ring by tracking the rate of unre- turned messages.

  • Page 179: Installation

    "Programmed" state. UNIT NOT PROGRAMMED setting allows the user to uniquely identify a relay. This name will appear on generated reports. RELAY NAME GE Multilin B90 Low Impedance Bus Differential System 5-59...

  • Page 180: Ac Inputs

    CT F1 SECONDARY: MESSAGE This menu configures the AC current inputs. Upon power up, the B90 recognizes all the AC modules loaded in its chassis and populates the above menu accordingly. The current terminals are denoted in the following format: Xa, where X = {F, L, S} and a = (1, 2,..., 8}. X represents the chassis slot containing the AC input module and a represents the AC channel of each module.

  • Page 181: Power System

    UR-series relays provided the relays have an IRIG-B connection. should only be set to "Disabled" in very unusual circumstances; consult the factory for spe- FREQUENCY TRACKING cial variable-frequency applications. NOTE GE Multilin B90 Low Impedance Bus Differential System 5-61...

  • Page 182: Flexcurves™

    1.03 pu. It is recommended to set the two times to a similar value; otherwise, the linear approximation may NOTE result in undesired behavior for the operating quantity that is close to 1.00 pu. 5-62 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 183

    The multiplier and adder settings only affect the curve portion of the characteristic and not the MRT and HCT set- tings. The HCT settings override the MRT settings for multiples of pickup greater than the HCT ratio. NOTE GE Multilin B90 Low Impedance Bus Differential System 5-63...

  • Page 184

    EnerVista UR Setup software generates an error message and discards the proposed changes. NOTE e) STANDARD RECLOSER CURVES The standard recloser curves available for the B90 are displayed in the following graphs. 5-64 B90 Low Impedance Bus Differential System...

  • Page 185

    Figure 5–19: RECLOSER CURVES GE101 TO GE106 GE142 GE138 GE120 GE113 0.05 7 8 9 10 12 CURRENT (multiple of pickup) 842725A1.CDR Figure 5–20: RECLOSER CURVES GE113, GE120, GE138 AND GE142 GE Multilin B90 Low Impedance Bus Differential System 5-65...

  • Page 186

    Figure 5–21: RECLOSER CURVES GE134, GE137, GE140, GE151 AND GE201 GE152 GE141 GE131 GE200 7 8 9 10 12 CURRENT (multiple of pickup) 842728A1.CDR Figure 5–22: RECLOSER CURVES GE131, GE141, GE152, AND GE200 5-66 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 187

    Figure 5–23: RECLOSER CURVES GE133, GE161, GE162, GE163, GE164 AND GE165 GE132 GE139 GE136 GE116 0.05 GE117 GE118 0.02 0.01 7 8 9 10 12 CURRENT (multiple of pickup) 842726A1.CDR Figure 5–24: RECLOSER CURVES GE116, GE117, GE118, GE132, GE136, AND GE139 GE Multilin B90 Low Impedance Bus Differential System 5-67...

  • Page 188

    Figure 5–25: RECLOSER CURVES GE107, GE111, GE112, GE114, GE115, GE121, AND GE122 GE202 GE135 GE119 7 8 9 10 12 CURRENT (multiple of pickup) 842727A1.CDR Figure 5–26: RECLOSER CURVES GE119, GE135, AND GE202 5-68 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 189

    Please refer to the Ordering section in chapter 2 for detailed infor- mation on the maximum number of zones and inputs for a given B90 model. Four bus differential zones are available. Each zone is associated with its own bus differential protection and CT trouble monitoring elements.

  • Page 190

    5.3 SYSTEM SETUP 5 SETTINGS For example, assume that B90 IED 4 is used for isolator monitoring while IEDs 1, 2, and 3 are used for protection. Conse- quently, the setting of IED 4 must be set to “Logic” while...

  • Page 191: Introduction To Flexlogic™

    Figure 5–29: UR ARCHITECTURE OVERVIEW The states of all digital signals used in the B90 are represented by flags (or FlexLogic™ operands, which are described later in this section). A digital “1” is represented by a 'set' flag. Any external contact change-of-state can be used to block an element from operating, as an input to a control feature in a FlexLogic™...

  • Page 192

    Some types of operands are present in the relay in multiple instances; e.g. contact and remote inputs. These types of oper- ands are grouped together (for presentation purposes only) on the faceplate display. The characteristics of the different types of operands are listed in the table below. Table 5–6: B90 FLEXLOGIC™ OPERAND TYPES OPERAND TYPE STATE...

  • Page 193

    5 SETTINGS 5.4 FLEXLOGIC™ The operands available for this relay are listed alphabetically by types in the following table. Table 5–7: B90 FLEXLOGIC™ OPERANDS (Sheet 1 of 4) OPERAND TYPE OPERAND SYNTAX OPERAND DESCRIPTION CONTROL CONTROL PUSHBTN 1 ON Control pushbutton 1 is being pressed...

  • Page 194

    5.4 FLEXLOGIC™ 5 SETTINGS Table 5–7: B90 FLEXLOGIC™ OPERANDS (Sheet 2 of 4) OPERAND TYPE OPERAND SYNTAX OPERAND DESCRIPTION ELEMENT LATCH 1 ON Non-volatile latch 1 is ON (Logic = 1) Non-volatile latches LATCH 1 OFF Non-volatile latch 1 is OFF (Logic = 0)

  • Page 195

    5 SETTINGS 5.4 FLEXLOGIC™ Table 5–7: B90 FLEXLOGIC™ OPERANDS (Sheet 3 of 4) OPERAND TYPE OPERAND SYNTAX OPERAND DESCRIPTION INPUTS/OUTPUTS: Virt Op 1 Flag is set, logic=1 Virtual outputs Virt Op 2 Flag is set, logic=1 Virt Op 3 Flag is set, logic=1 ↓...

  • Page 196

    5.4 FLEXLOGIC™ 5 SETTINGS Table 5–7: B90 FLEXLOGIC™ OPERANDS (Sheet 4 of 4) OPERAND TYPE OPERAND SYNTAX OPERAND DESCRIPTION SELF- ANY MAJOR ERROR Any of the major self-test errors generated (major error) DIAGNOSTICS ANY MINOR ERROR Any of the minor self-test errors generated (minor error)

  • Page 197: Flexlogic™ Rules

    When making changes to FlexLogic entries in the settings, all FlexLogic equations are re-compiled whenever any new FlexLogic entry value is entered, and as a result of the re-compile all latches are reset automatically. GE Multilin B90 Low Impedance Bus Differential System 5-77...

  • Page 198: Flexlogic™ Example

    Dropout State=Pickup (200 ms) DIGITAL ELEMENT 2 Timer 1 State=Operated Time Delay on Pickup (800 ms) CONTACT INPUT H1c State=Closed VIRTUAL OUTPUT 3 827026A2.VSD Figure 5–31: LOGIC EXAMPLE WITH VIRTUAL OUTPUTS 5-78 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 199

    Following the procedure outlined, start with parameter 99, as follows: 99: The final output of the equation is virtual output 3, which is created by the operator "= Virt Op n". This parameter is therefore "= Virt Op 3." GE Multilin B90 Low Impedance Bus Differential System 5-79...

  • Page 200

    87: The input just below the upper input to OR #1 is operand “Virt Op 2 On". 86: The upper input to OR #1 is operand “Virt Op 1 On". 85: The last parameter is used to set the latch, and is operand “Virt Op 4 On". 5-80 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 201

    In the following equation, virtual output 3 is used as an input to both latch 1 and timer 1 as arranged in the order shown below: DIG ELEM 2 OP Cont Ip H1c On AND(2) GE Multilin B90 Low Impedance Bus Differential System 5-81...

  • Page 202: Flexlogic™ Equation Editor

    TIMER 1 TYPE: This setting is used to select the time measuring unit. • TIMER 1 PICKUP DELAY: Sets the time delay to pickup. If a pickup delay is not required, set this function to "0". 5-82 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 203: Non-volatile Latches

    LATCH N LATCH N LATCH N TYPE RESET Reset Dominant Previous Previous State State Dominant Previous Previous State State Figure 5–37: NON-VOLATILE LATCH OPERATION TABLE (N = 1 to 16) AND LOGIC GE Multilin B90 Low Impedance Bus Differential System 5-83...

  • Page 204

    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 Section 5.6.3: Setting Groups on page 5–110 for further details). 5-84 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 205: Bus Differential

    The biased bus differential function has a dual-slope operating characteristic (see figure below) operating in conjunction with saturation detection and a directional comparison principle (refer to the Bus zone 1 differential scheme logic figure in this section). GE Multilin B90 Low Impedance Bus Differential System 5-85...

  • Page 206

    CTs operating in their linear mode, i.e. in load conditions and during distant external faults. When adjusting this setting, 5-86 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 207

    BF function to iso- late the entire zone of busbar protection. More information on the bus zone differential settings can be found in the Application of settings chapter. GE Multilin B90 Low Impedance Bus Differential System 5-87...

  • Page 208

    5.5 GROUPED ELEMENTS 5 SETTINGS Figure 5–39: BUS ZONE 1 DIFFERENTIAL SCHEME LOGIC 5-88 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 209: Breaker Failure

    Range: Yes, No BF1 USE TIMER 2: MESSAGE Range: 0.000 to 65.535 s in steps of 0.001 BF1 TIMER 2 PICKUP MESSAGE DELAY: 0.000 s Range: Yes, No BF1 USE TIMER 3: MESSAGE GE Multilin B90 Low Impedance Bus Differential System 5-89...

  • Page 210

    Range: Enabled, Disabled BF1 EVENTS: MESSAGE Disabled  BREAKER FAILURE  CURRENT SUPV 2  BREAKER FAILURE 2  ↓  BREAKER FAILURE  CURRENT SUPV 24  BREAKER FAILURE 24  5-90 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 211

    PRODUCT SETUP B90 FUNCTION setting is “Logic”. The Breaker failure element requires B90 fiber optic interconnection and proper configura- B90 FUNCTION tion of the breaker failure and direct input/output settings. Refer to the Application of settings chapter for additional details.

  • Page 212

    BF1 USE SEAL-IN: If set to "Yes", the element will only be sealed-in if current flowing through the breaker is above the supervision pickup level. • BF1 AMP SUPV OP A through C: This setting selects the B90 Remote Inputs that represent operation of the current supervision elements on phase A, B, or C. •...

  • Page 213

    BF1 AMP LOSET PICKUP: This setting is used to set the phase current fault detection level. Generally this setting should detect the lowest expected fault current on the protected breaker, after a breaker opening resistor is inserted approximately 90% of resistor current). Figure 5–40: BREAKER FAILURE CURRENT SUPERVISION LOGIC GE Multilin B90 Low Impedance Bus Differential System 5-93...

  • Page 214

    5.5 GROUPED ELEMENTS 5 SETTINGS Figure 5–41: BREAKER FAILURE LOGIC 5-94 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 215

    DIRECT INPUT 6 BIT NUMBER : "3" (message received from IED 3) DIRECT INPUT 7 DEVICE : "13" (this is BKRSUPV 3 SUPV OP for Phase C) DIRECT INPUT 7 BIT NUMBER GE Multilin B90 Low Impedance Bus Differential System 5-95...

  • Page 216

    BF 3 AMP LOSET OP C The B90 current supervision elements reset in less than 0.7 of a power cycle up to the multiple of pickup of 100 (threshold set at 0.01 of the actual fault current) as shown below.

  • Page 217: Voltage Elements

    The undervoltage element supervises (low-voltage check) current based main protection (that is, differential, breaker fail- ure, end fault, and time overcurrent backup protection). The B90 accepts phase-to-ground or phase-to-phase voltage input configurations. If the intention is to operate all three phases for any one phase voltage collapse, appropriate FlexLogic™...

  • Page 218: Current Elements

    See page 5-103.  OVERCURRENT 24  TIME MESSAGE See page 5-104.  OVERCURRENT  TIME MESSAGE See page 5-104.  OVERCURRENT ↓  TIME MESSAGE See page 5-104.  OVERCURRENT 24 5-98 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 219

    5.5 GROUPED ELEMENTS b) INVERSE TOC CURVE CHARACTERISTICS The inverse time overcurrent curves used by the time overcurrent elements are the IEEE, IEC, GE Type IAC, and I t stan- dard curve shapes. This allows for simplified coordination with downstream devices.

  • Page 220

    38.634 22.819 14.593 11.675 10.130 9.153 8.470 7.960 7.562 7.241 51.512 30.426 19.458 15.567 13.507 12.204 11.294 10.614 10.083 9.654 10.0 64.390 38.032 24.322 19.458 16.883 15.255 14.117 13.267 12.604 12.068 5-100 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 221

    1.067 0.668 0.526 0.451 0.404 0.371 0.346 0.327 0.311 0.80 2.446 1.423 0.890 0.702 0.602 0.538 0.494 0.461 0.435 0.415 1.00 3.058 1.778 1.113 0.877 0.752 0.673 0.618 0.576 0.544 0.518 GE Multilin B90 Low Impedance Bus Differential System 5-101...

  • Page 222

    = characteristic constant, and T = reset time in seconds (assuming energy capacity is 100% RESET is “Timed”) RESET Table 5–15: GE TYPE IAC INVERSE TIME CURVE CONSTANTS IAC CURVE SHAPE IAC Extreme Inverse 0.0040 0.6379 0.6200 1.7872 0.2461...

  • Page 223

    Range: 0.000 to 65.535 s in steps of 0.001 IOC1 RESET DELAY: MESSAGE 0.000 s Range: FlexLogic™ operand IOC1 BLOCK: MESSAGE Range: Self-Reset, Latched, Disabled IOC1 TARGET: MESSAGE Self-Reset Range: Enabled, Disabled IOC1 EVENTS: MESSAGE Disabled GE Multilin B90 Low Impedance Bus Differential System 5-103...

  • Page 224

    FlexLogic™ operands are passed between the IEDs using the B90 fiber optic communications (Direct I/Os). Instantaneous Overcurrent supervision can also be used to prevent tripping feeders with low currents or for definite time backup protection.

  • Page 225: End Fault Protection

    The End Fault Protection (EFP) element operates for dead-zone faults; i.e., faults between the CT and an open feeder breaker. Since a bus protection zone terminates on the CTs, faults between the CT and breaker require special consider- ation. GE Multilin B90 Low Impedance Bus Differential System 5-105...

  • Page 226

    • EFP1 BREAKER OPEN: This setting is a FlexLogic™ operand indicating an open breaker. The operand shall be "On" when the breaker is open. Typically, this setting is a position of an appropriately wired input contact of the B90. •...

  • Page 227

    Off = 0 EFP 1 OP SETTINGS EFP 1 DPO SETTING EFP 1 BRK DELAY: EFP PKP EFP 1 BREAKER OPEN: Off = 0 836004A1.vsd Figure 5–49: END FAULT PROTECTION LOGIC GE Multilin B90 Low Impedance Bus Differential System 5-107...

  • Page 228

    If more than one operate-type operand is required, it may be assigned directly from the trip bus menu. 5-108 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 229

    = Enabled TRIP BUS 1 BLOCK = Off SETTINGS TRIP BUS 1 LATCHING = Enabled TRIP BUS 1 RESET = Off FLEXLOGIC OPERAND RESET OP 842023A1.CDR Figure 5–51: TRIP BUS LOGIC GE Multilin B90 Low Impedance Bus Differential System 5-109...

  • Page 230: Setting Groups

    SETTING GROUP 1 NAME SETTING GROUP 6 NAME groups. Once programmed, this name will appear on the second line of the  GROUPED ELEMENTS SETTING GROUP 1(6) menu display. 5-110 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 231: Digital Elements

    DIGITAL ELEMENT 1 RESET DELAY: Sets the time delay to reset. If a reset delay is not required, set to “0”. • DIGITAL ELEMENT 1 PICKUP LED: This setting enables or disabled the digital element pickup LED. When set to “Disabled”, the operation of the pickup LED is blocked. GE Multilin B90 Low Impedance Bus Differential System 5-111...

  • Page 232

    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 include the breaker position. Figure 5–53: TRIP CIRCUIT EXAMPLE 1 5-112 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 233

    In this case, it is not required to supervise the monitoring circuit with the breaker position – the setting is BLOCK selected to “Off”. In this case, the settings are as follows (EnerVista UR Setup example shown). Figure 5–54: TRIP CIRCUIT EXAMPLE 2 GE Multilin B90 Low Impedance Bus Differential System 5-113...

  • Page 234: Monitoring Elements

    CT Trouble is declared for the given phase by setting the appropriate FlexLogic™ output operand. The operand may be configured to raise an alarm and block the bus differential function for the corresponding zone of protection. 5-114 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 235

    EVENTS: Disabled Bus protection zone discrimination depends heavily on reliable isolator position feedback. Therefore, two isolator auxiliary contacts – normally open and normally closed – must confirm the status of the isolator via the B90 contact inputs. GE Multilin B90 Low Impedance Bus Differential System...

  • Page 236

    ISOLATOR 1 ALARM DELAY: This setting specifies a time delay after which an isolator alarm is issued by asserting the operand assigned to . The delay shall be longer than the slowest operation (transition) time of ISOLATOR 1 ALARM the isolator. 5-116 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 237

    ISOLATOR 1 BLOCK delay isolator position valid alarm ISOLATOR 1 ALARM acknowledged alarm acknowledging ISOLATOR 1 RESET signal 836744A1.vsd Figure 5–58: ISOLATOR MONITORING SAMPLE TIMING DIAGRAM GE Multilin B90 Low Impedance Bus Differential System 5-117...

  • Page 238: Contact Inputs

    The DC input voltage is compared to a user-settable threshold. A new contact input state must be maintained for a user- settable debounce time in order for the B90 to validate the new contact state. In the figure below, the debounce time is set at 2.5 ms;...

  • Page 239

    "Breaker Closed (52b)" CONTACT INPUT H5A ID: "Enabled" CONTACT INPUT H5A EVENTS: Note that the 52b contact is closed when the breaker is open and open when the breaker is closed. GE Multilin B90 Low Impedance Bus Differential System 5-119...

  • Page 240: Virtual Inputs

    “Virtual Input 1 to OFF = 0” VIRTUAL INPUT 1 ID: (Flexlogic Operand) SETTING Virt Ip 1 VIRTUAL INPUT 1 TYPE: Latched Self - Reset 827080A2.CDR Figure 5–60: VIRTUAL INPUTS SCHEME LOGIC 5-120 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 241: Contact Outputs

    The most dependable protection of the initiating contact is provided by directly measuring current in the tripping circuit, and using this parameter to control resetting of the initiating relay. This scheme is often called trip seal-in. This can be realized in the B90 using the FlexLogic™ operand to seal-in the contact output as follows: CONT OP 1 ION “Cont Op 1"...

  • Page 242

    5 SETTINGS The B90 latching output contacts are mechanically bi-stable and controlled by two separate (open and close) coils. As such they retain their position even if the relay is not powered up. The relay recognizes all latching output contact cards and pop- ulates the setting menu accordingly.

  • Page 243: Virtual Outputs

    FlexLogic™ equations. Any change of state of a virtual output can be logged as an event if programmed to do so. For example, if Virtual Output 1 is the trip signal from FlexLogic™ and the trip relay is used to signal events, the settings would be programmed as follows: GE Multilin B90 Low Impedance Bus Differential System 5-123...

  • Page 244: Remote Devices

    The remote input/output facility provides for 32 remote inputs and 64 remote outputs. b) LOCAL DEVICES: ID OF DEVICE FOR TRANSMITTING GSSE/GOOSE MESSAGES In a B90 relay, the device ID that represents the IEC 61850 GOOSE application ID (GoID) name string sent as part of each GOOSE message is programmed in the ...

  • Page 245: Remote Inputs

    This setting identifies the Ethernet application identification in the GOOSE message. It should match the corre- sponding settings on the sending device. setting provides for the choice of the B90 fixed (DNA/UserSt) dataset (that is, containing REMOTE DEVICE 1 DATASET DNA and UserSt bit pairs), or one of the configurable datasets.

  • Page 246: Remote Double-point Status Inputs

    REMOTE OUTPUTS DNA BIT PAIRS REMOTE OUTPUTS DNA- 1(32) BIT PAIR Range: FlexLogic™ operand  REMOTE OUTPUTS DNA- 1 OPERAND:  DNA- 1 BIT PAIR Range: Disabled, Enabled DNA- 1 EVENTS: MESSAGE Disabled 5-126 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 247: Resetting

    The setting RESET OP (PUSHBUTTON) RESET OP (COMMS) RESET OP (OPERAND) shown above selects the operand that will create the operand. RESET OP (OPERAND) GE Multilin B90 Low Impedance Bus Differential System 5-127...

  • Page 248

    APPLICATION EXAMPLES The examples introduced in the earlier Direct inputs and outputs section (part of the Product Setup section) are continued below to illustrate usage of the direct inputs and outputs. 5-128 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 249

    5 SETTINGS 5.7 INPUTS/OUTPUTS EXAMPLE 1: EXTENDING INPUT/OUTPUT CAPABILITIES OF A B90 RELAY Consider an application that requires additional quantities of digital inputs or output contacts or lines of programmable logic that exceed the capabilities of a single UR-series chassis. The problem is solved by adding an extra UR-series IED, such as the C30, to satisfy the additional inputs/outputs and programmable logic requirements.

  • Page 250

    DIRECT INPUT 6 BIT NUMBER: UR IED 2: "1" DIRECT INPUT 5 DEVICE ID: "2" DIRECT INPUT 5 BIT NUMBER: "3" DIRECT INPUT 6 DEVICE ID: "2" DIRECT INPUT 6 BIT NUMBER: 5-130 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 251: Iec 61850 Goose Analogs

    The following text must be used in the UNITS setting, to represent these types of analogs: A, V, W, var, VA, Hz, deg, and no text (blank setting) for power factor. GE Multilin B90 Low Impedance Bus Differential System 5-131...

  • Page 252: Iec 61850 Goose Integers

    GOOSE ANALOG 1 PU: This setting specifies the per-unit base factor when using the GOOSE analog input FlexAna- log™ values in other B90 features, such as FlexElements™. The base factor is applied to the GOOSE analog input FlexAnalog quantity to normalize it to a per-unit quantity. The base units are described in the following table.

  • Page 253: Test Mode

    TEST MODE FORCING: MESSAGE The B90 provides a test facility to verify the functionality of contact inputs and outputs, some communication channels and the phasor measurement unit (where applicable), using simulated conditions. The test mode is indicated on the relay face- plate by a Test Mode LED indicator.

  • Page 254: Force Contact Inputs

    Following a restart, power up, settings TEST MODE FUNCTION upload, or firmware upgrade, the test mode will remain at the last programmed value. This allows a B90 that has been placed in isolated mode to remain isolated during testing and maintenance activities. On restart, the TEST MODE FORCING setting and the force contact input and force contact output settings all revert to their default states.

  • Page 255: Force Contact Outputs

    PUSHBUTTON 1 FUNCTION input 1 to initiate the Test mode, make the following changes in the   menu: SETTINGS TESTING TEST MODE “Enabled” and “ ” TEST MODE FUNCTION: TEST MODE INITIATE: GE Multilin B90 Low Impedance Bus Differential System 5-135...

  • Page 256

    5.8 TESTING 5 SETTINGS 5-136 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 257: Actual Values Menu

    See page 6-9.   IEC 61850 See page 6-10.  GOOSE ANALOGS  ACTUAL VALUES  USER-PROGRAMMABLE See page 6-11.  RECORDS  FAULT REPORTS  EVENT RECORDS See page 6-11.  GE Multilin B90 Low Impedance Bus Differential System...

  • Page 258

    6.1 OVERVIEW 6 ACTUAL VALUES  OSCILLOGRAPHY See page 6-11.   ACTUAL VALUES  MODEL INFORMATION See page 6-13.  PRODUCT INFO   FIRMWARE REVISIONS See page 6-13.  B90 Low Impedance Bus Differential System GE Multilin...

  • Page 259

    The state displayed will be that of the remote point unless the remote device has been established to be “Offline” in which case the value shown is the programmed default state for the remote input. GE Multilin B90 Low Impedance Bus Differential System...

  • Page 260

    For example, ‘Virt Op 1’ refers to the virtual output in terms of the default name-array index. The second line of the display indicates the logic state of the virtual output, as calculated by the FlexLogic™ equation for that output. B90 Low Impedance Bus Differential System GE Multilin...

  • Page 261

    Range: Off, On PARAM 2: Off MESSAGE ↓ Range: Off, On PARAM 256: Off MESSAGE There are 256 FlexState bits available. The second line value indicates the state of the given FlexState bit. GE Multilin B90 Low Impedance Bus Differential System...

  • Page 262: Ethernet

    UINT INPUT 16 MESSAGE The B90 Low Impedance Bus Differential System is provided with optional IEC 61850 communications capability. This feature is specified as a software option at the time of ordering. Refer to the Ordering sec- tion of chapter 2 for additional details. The IEC 61850 protocol features are not available if CPU type E is ordered.

  • Page 263: Direct Inputs

    STATUS: Offline Range: Offline, Online DIRECT DEVICE 2 MESSAGE STATUS: Offline ↓ Range: Offline, Online DIRECT DEVICE 16 MESSAGE STATUS: Offline These actual values represent the state of direct devices 1 through 16. GE Multilin B90 Low Impedance Bus Differential System...

  • Page 264: Metering Conventions

    (see chapter 8: Theory of operation for additional details). There is no cutoff level applied to the differential and restraint currents computed by the B90. Therefore, a small dif- ferential current reflecting CT inaccuracies and bus leakage current could be present during balanced conditions.

  • Page 265: Currents

     FREQUENCY AND PHASE REFERENCE SETTINGS  menu. Refer to the Power System section of chapter 5 for additional details. SYSTEM SETUP POWER SYSTEM GE Multilin B90 Low Impedance Bus Differential System...

  • Page 266: Iec 61580 Goose Analog Values

    MESSAGE 0.000 The B90 Low Impedance Bus Differential System is provided with optional IEC 61850 communications capability. This feature is specified as a software option at the time of ordering. Refer to the Ordering sec- tion of chapter 2 for additional details. The IEC 61850 protocol features are not available if CPU type E is ordered.

  • Page 267: User-programmable Fault Reports

    This menu allows the user to view the number of triggers involved and number of oscillography traces available. The value is calculated to account for the fixed amount of data storage for oscillography. See the Oscillog- CYCLES PER RECORD raphy section of chapter 5 for additional details. GE Multilin B90 Low Impedance Bus Differential System 6-11...

  • Page 268

    A trigger can be forced here at any time by setting “Yes” to the command. Refer to the  FORCE TRIGGER? COMMANDS menu for information on clearing the oscillography records. CLEAR RECORDS 6-12 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 269: Model Information

    6.5PRODUCT INFORMATION 6.5.1 MODEL INFORMATION   PATH: ACTUAL VALUES PRODUCT INFO MODEL INFORMATION Range: standard GE Multilin order code format;  MODEL INFORMATION ORDER CODE LINE 1: example order code shown  B90-E00-HCL-F8H-H6A Range: standard GE Multilin order code format...

  • Page 270

    6.5 PRODUCT INFORMATION 6 ACTUAL VALUES 6-14 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 271: Commands Menu

    The states of up to 64 virtual inputs are changed here. The first line of the display indicates the ID of the virtual input. The second line indicates the current or selected status of the virtual input. This status will be a state off (logic 0) or on (logic 1). GE Multilin B90 Low Impedance Bus Differential System...

  • Page 272: Clear Records

    24-hour clock. The complete date, as a minimum, must be entered to allow execution of this com- mand. The new time will take effect at the moment the ENTER key is clicked. B90 Low Impedance Bus Differential System GE Multilin...

  • Page 273: Relay Maintenance

    Various self-checking diagnostics are performed in the background while the B90 is running, and diagnostic information is stored on the non-volatile memory from time to time based on the self-checking result. Although the diagnostic information is cleared before the B90 is shipped from the factory, the user may want to clear the diagnostic information for themselves under certain circumstances.

  • Page 274: Targets Menu

     MESSAGE Each B90 element with a TARGET setting has a target message that when activated by its element is displayed in sequence with any other currently active target messages in the menu. In the example shown, the Phase TOC4 TARGETS and Digital Element 48 target settings are active and so have their targets displayed.

  • Page 275

    Contact Factory (xxx) • Latched target message: Yes. • Description of problem: One or more installed hardware modules is not compatible with the B90 order code. • How often the test is performed: Module dependent. • What to do: Contact the factory and supply the failure code noted in the display. The “xxx” text identifies the failed mod- ule (for example, F8L).

  • Page 276

    • What to do: Verify that all the items in the GOOSE data set are supported by the B90. The EnerVista UR Setup soft- ware will list the valid items. An IEC61850 client will also show which nodes are available for the B90.

  • Page 277

    • How often the test is performed: Every second. • What to do: Check direct input and output configuration and wiring. REMOTE DEVICE FAIL: COMM Path Incomplete • Latched target message: No. GE Multilin B90 Low Impedance Bus Differential System...

  • Page 278

    Description of problem: The ambient temperature is greater than the maximum operating temperature (+80°C). • How often the test is performed: Every hour. • What to do: Remove the B90 from service and install in a location that meets operating temperature standards. UNEXPECTED RESTART: Press “RESET” key •...

  • Page 279

    When entering a settings or command password via EnerVista or any serial interface, the user must enter the correspond- ing connection password. If the connection is to the back of the B90, the remote password must be used. If the connection is to the RS232 port of the faceplate, the local password must be used.

  • Page 280: Password Security Menu

    If the setting and command passwords are identical, then this one password allows access to both commands and settings. NOTE If a remote connection is established, local passcodes are not visible. NOTE B90 Low Impedance Bus Differential System GE Multilin...

  • Page 281: Remote Passwords

    If a command or setting password is lost (or forgotten), consult the factory with the corresponding Encrypted Password value. If you establish a local connection to the relay (serial), you cannot view remote passcodes. NOTE GE Multilin B90 Low Impedance Bus Differential System...

  • Page 282: Access Supervision

    INVALID ATTEMPTS BEFORE LOCKOUT The B90 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 FlexLogic operand is UNAUTHORIZED ACCESS asserted.

  • Page 283

    If access is permitted and an off-to-on transition of the FlexLogic operand is detected, the timeout is restarted. The status of this timer is updated every 5 seconds. GE Multilin B90 Low Impedance Bus Differential System...

  • Page 284

    Select the Security > User Management menu item to open the user management configuration window. Enter a username in the User field. The username must be between 4 and 20 characters in length. B90 Low Impedance Bus Differential System GE Multilin...

  • Page 285: Modifying User Privileges

    The EnerVista security management system must be enabled. The following procedure describes how to modify user privileges. Select the Security > User Management menu item to open the user management configuration window. Locate the username in the User field. GE Multilin B90 Low Impedance Bus Differential System...

  • Page 286

    When this box is checked, the user will become an EnerVista URPlus Setup administrator, therefore receiving all of the administrative rights. Exercise caution when granting administrator rights. Click OK to save the changes to user to the security management system. B90 Low Impedance Bus Differential System GE Multilin...

  • Page 287: Bus Differential Protection

    9 THEORY OF OPERATION 9.1INTRODUCTION 9.1.1 BUS DIFFERENTIAL PROTECTION Referring to the figure below, input currents defining (through the dynamic bus replica) the bus differential zone are received by the B90 from current transformers (CTs) associated with the power system. Unbiased Differential Measuring Unit...

  • Page 288: Dynamic Bus Replica Mechanism

    9.2.1 DYNAMIC BUS REPLICA MECHANISM The bus differential zones of the B90 allow for protecting bus sections that include circuits that are switchable between dif- ferent sections. Proper relay operation is achieved by associating a status signal with each input current. This mechanism is referred to as a dynamic bus replica.

  • Page 289: Biased Differential Characteristic

    Figure 9–2: BIASED OPERATING CHARACTERISTIC The higher slope used by the B90 acts as an actual percentage bias regardless of the value of the restraining signal. This is so because the boundary of the operating characteristic in the higher slope region is a straight line intersecting the origin of the ‘differential - restraining’...

  • Page 290: Differential And Restraining Currents

    HIGH BPNT 5000A : 1000A = 5 pu (1000A is the base unit; see page 8–2 for the example). The same approach applies to the setting of the lower breakpoint, LOW BPNT B90 Low Impedance Bus Differential System GE Multilin...

  • Page 291: Enhanced Security

    9.3 DIFFERENTIAL PRINCIPLE 9.3.3 ENHANCED SECURITY In order to enhance the performance of the B90, the differential characteristic is divided into two regions having diverse operating modes as shown in following diagram. The first region applies to comparatively low differential currents and has been introduced to deal with CT saturation on low- current external faults.

  • Page 292: Current Directional Protection

    9.4.1 CURRENT DIRECTIONAL PROTECTION For better security, the B90 uses the current directional protection principle to dynamically supervise the main current differ- ential function. The directional principle is in effect permanently for low differential currents (Region 1 in Figure 9–3: Two Regions of Differential Characteristic) and is switched on dynamically for large differential currents (Region 2 in the same figure) by the saturation detector (see Section 9.5: Saturation Detector) upon detecting CT saturation.

  • Page 293

    9.4 DIRECTIONAL PRINCIPLE The B90 implementation calculates the maximum angle for the considered currents and compares it against a fixed thresh- old of 90°. The flag indicating whether the directional protection principle is satisfied is available as the FlexLogic™ oper-...

  • Page 294: Ct Saturation Detection

    9.5.1 CT SATURATION DETECTION The saturation detector of the B90 takes advantage of the fact that any CT operates correctly for a short period of time even under very large primary currents that would subsequently cause a very deep saturation. As a result of that, in the case of an external fault, the differential current stays very low during the initial period of linear operation of the CTs while the restraining signal develops rapidly.

  • Page 295

    The differential out of the differential characteristic characteristic for a entered certain period of time EXTERNAL FAULT and CT SATURATION SAT := 1 836729A1.CDR Figure 9–7: SATURATION DETECTOR STATE MACHINE GE Multilin B90 Low Impedance Bus Differential System...

  • Page 296: Output Logic

    Figure 8-10 presents the bus currents and the most important logic signals for the case of an external fault. Despite very fast and severe CT saturation, the B90 remains stable. Figure 8-11 presents the same signals but for the case of an internal fault. The B90 trips in 10 ms (fast form-C output con- tact).

  • Page 297

    9 THEORY OF OPERATION 9.6 OUTPUT LOGIC AND EXAMPLES Figure 9–9: EXTERNAL FAULT EXAMPLE GE Multilin B90 Low Impedance Bus Differential System 9-11...

  • Page 298

    9.6 OUTPUT LOGIC AND EXAMPLES 9 THEORY OF OPERATION Figure 9–10: INTERNAL FAULT EXAMPLE 9-12 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 299

    It is also assumed that the CTs have been selected without considering a B90 application, but the B90 settings are to be calculated for proper relay application. The CT data used in this example are kept to a minimum and in a generic form. The CT data does not reflect any particular notation or national standards.

  • Page 300

    (Ω) LEADS (M) CTSEC CT-1 600:5 0.34 CT-2 600:5 0.34 CT-3 1200:5 0.64 CT-4 1000:5 0.54 CT-5, CT-6 1000:5 0.54 CT-7, CT-8 1200:5 0.64 836732A4.CDR Figure 10–2: APPROXIMATE CT MAGNETIZING CHARACTERISTICS 10-2 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 301: North Bus Zone

    CT-6 and CT-7. The South bus protection should operate the following breakers: B-2 (if S-2 closed), B-3 (if S-4 closed), B-4 (if S-6 closed), B-6 and B-7. NORTH BUS CT-1 CT-7 CT-2 CT-4 CT-3 CT-5 CT-6 CT-8 SOUTH BUS 836734A1.CDR Figure 10–4: SOUTH BUS ZONE GE Multilin B90 Low Impedance Bus Differential System 10-3...

  • Page 302

    Assuming 0.003 Ω/m lead resistance and approximating the B90 input resistance for the 5A input CTs as 0.2 VA / (5 A) 0.008 Ω, the limits of the linear operation of the CTs have been calculated and presented in the Limits of Linear Operations of the CTs table.

  • Page 303: Low Breakpoint

    A combination of very high residual magnetism and a DC component with a long time constant may saturate a given CT even with the AC current below the suggested value of the lower breakpoint. The relay copes with this threat by using a 2- out-of-2 operating mode for low differential currents. GE Multilin B90 Low Impedance Bus Differential System 10-5...

  • Page 304

    CT voltage at 10 A exciting current obtained from the CT excitation curve CT limiting factor K is defined by the following equation: S_LIM × ------------- - (EQ 10.7) S…LIM × 10-6 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 305

    Method 1 — Download the "CT Time-to-Saturate Estimator.xlsm" spreadsheet from the GE Multilin web site, located under Support > Support Documents > B90 Low Impedance Bus Differential System. Enter the required system and CT parameters to obtain the CT time-to-saturate.

  • Page 306: External Faults On C-2

    The saturation does not occur before 23.68 ms and is detected by the Sat- uration Detector. Table 10–6: CALCULATIONS FOR THE EXTERNAL FAULTS ON C-3 (KA) (A SEC) (MS) (MS) FAULT FAULT SATURATION SATURATION CT-1 0.00 10-8 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 307: External Faults On C-4

    Table 10–8: EXTERNAL FAULT CALCULATIONS ON C-5 (KA) (A SEC) (MS) (MS) FAULT FAULT SATURATION SATURATION CT-1 0.00 CT-2 0.00 CT-3 25.00 CT-4 25.00 26.37 CT-5 11.0 55.00 9.45 CT-7, CT-8 11.0 45.83 11.54 GE Multilin B90 Low Impedance Bus Differential System 10-9...

  • Page 308

    HIGH BPNT 8.96 None of the CTs will saturate for ac currents below 8.96 pu. The dc component, however, may saturate some CTs even for currents below 8.96 pu. The B90 copes with saturation using the current directional principle. HIGH SET 5.94...

  • Page 309: Using Setting Groups

    CTs in any particular bus configuration. GE Multilin B90 Low Impedance Bus Differential System 10-11...

  • Page 310

    10.6 ENHANCING RELAY PERFORMANCE 10 APPLICATION OF SETTINGS 10-12 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 311: Replace A Module

    The enhanced faceplate can be opened to the left, once the thumb screw has been removed, as shown below. This allows for easy accessibility of the modules for withdrawal. The new wide-angle hinge assembly in the enhanced front panel opens completely and allows easy access to all modules in the B90. 842812A1.CDR Figure 11–1: UR MODULE WITHDRAWAL AND INSERTION (ENHANCED FACEPLATE)

  • Page 312

    NOTE NOTE The 4.0x release of the B90 relay includes new hardware modules.The new CPU modules are specified with codes 9E and higher. The new CT/VT modules are specified with the codes 8F and higher. NOTE The new CT/VT modules can only be used with new CPUs; similarly, old CT/VT modules can only be used with old CPUs.

  • Page 313: Replace Battery

    10. Reinstall the battery clip and the metal cover, and reinsert the power supply module into the unit. 11. Power on the unit. 12. Dispose of the old battery as outlined in the next section. GE Multilin B90 Low Impedance Bus Differential System 11-3...

  • Page 314: Dispose Of Battery

    La batterie est marqué de ce symbole, qui comprennent les indications cadmium (Cd), plomb (Pb), ou mercure (Hg). Pour le recyclage, retourner la batterie à votre fournisseur ou à un point de collecte. Pour plus d'informations, voir: www.recyclethis.info. 11-4 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 315

    Baterija je označena s tem simbolom, ki lahko vključuje napise, ki označujejo kadmij (Cd), svinec (Pb) ali živo srebro (Hg). Za ustrezno recikliranje baterijo vrnite dobavitelju ali jo odstranite na določenem zbirališču. Za več informacij obiščite spletno stran: www.recyclethis.info. GE Multilin B90 Low Impedance Bus Differential System 11-5...

  • Page 316

    905-294-6222 Latin America +55 11 3614 1700 Europe, Middle East, Africa +(34) 94 485 88 00 Asia +86-21-2401-3208 India +91 80 41314617 From GE Part Number 1604-0021-A1, GE Publication Number GEK-113574 11-6 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 317: Uninstall And Clear Files And Data

    You cannot erase directly the flash memory, but all records and settings in that memory can be deleted. Do this using the   command. SETTINGS PRODUCT SETUP CLEAR RELAY RECORDS GE Multilin B90 Low Impedance Bus Differential System 11-7...

  • Page 318: Repairs

    Customers are responsible for shipping costs to the factory, regardless of whether the unit is under warranty. • Fax a copy of the shipping information to the GE Digital Energy service department in Canada at +1 905 927 5098. Use the detailed return procedure outlined at https://www.gedigitalenergy.com/multilin/support/ret_proc.htm...

  • Page 319: Storage

    Store the unit indoors in a cool, dry place. If possible, store in the original packaging. Follow the storage temperature range outlined in the Specifications. To avoid deterioration of electrolytic capacitors, power up units that are stored in a de-energized state once per year, for one hour continuously. GE Multilin B90 Low Impedance Bus Differential System 11-9...

  • Page 320: Disposal

    European Union, dispose of the battery as outlined earlier. To prevent non-intended use of the unit, remove the modules as outlined earlier, dismantle the unit, and recycle the metal when possible. 11-10 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 321: A.1.1 Flexanalog Items

    Amps Terminal 17 current magnitude 28466 S1 Curr Ang Degrees Terminal 17 current angle 28467 S2 Curr Mag Amps Terminal 18 current magnitude 28469 S2 Curr Ang Degrees Terminal 18 current angle GE Multilin B90 Low Impedance Bus Differential System...

  • Page 322

    GOOSE Analog In 1 IEC 61850 GOOSE analog input 1 45586 GOOSE Analog In 2 IEC 61850 GOOSE analog input 2 45588 GOOSE Analog In 3 IEC 61850 GOOSE analog input 3 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 323: A.1.2 Flexinteger Items

    IEC61850 GOOSE UInteger input 13 9994 GOOSE UInt Input 14 IEC61850 GOOSE UInteger input 14 9996 GOOSE UInt Input 15 IEC61850 GOOSE UInteger input 15 9998 GOOSE UInt Input 16 IEC61850 GOOSE UInteger input 16 GE Multilin B90 Low Impedance Bus Differential System...

  • Page 324

    A.1 PARAMETER LISTS APPENDIX A B90 Low Impedance Bus Differential System GE Multilin...

  • Page 325: B.1.1 Introduction

    See the Supported Function Codes section for complete details. An exception response from the slave is indi- cated by setting the high order bit of the function code in the response packet. See the Exception Responses section for further details. GE Multilin B90 Low Impedance Bus Differential System...

  • Page 326: B.1.4 Modbus Rtu Crc-16 Algorithm

    A C programming language implementation of the CRC algorithm will be provided upon request. B90 Low Impedance Bus Differential System GE Multilin...

  • Page 327

    No: go to 8; Yes: G (+) A --> A and continue. Is j = 8? No: go to 5; Yes: continue i + 1 --> i Is i = N? No: go to 3; Yes: continue A --> CRC GE Multilin B90 Low Impedance Bus Differential System...

  • Page 328: B.2.1 Supported Function Codes

    NUMBER OF REGISTERS - low DATA #2 - high CRC - low DATA #2 - low CRC - high DATA #3 - high DATA #3 - low CRC - low CRC - high B90 Low Impedance Bus Differential System GE Multilin...

  • Page 329: B.2.3 Execute Operation (function Code 05h)

    DATA STARTING ADDRESS - low DATA STARTING ADDRESS - low DATA - high DATA - high DATA - low DATA - low CRC - low CRC - low CRC - high CRC - high GE Multilin B90 Low Impedance Bus Differential System...

  • Page 330: B.2.5 Store Multiple Settings (function Code 10h)

    EXAMPLE (HEX) SLAVE ADDRESS SLAVE ADDRESS FUNCTION CODE FUNCTION CODE CRC - low order byte ERROR CODE CRC - high order byte CRC - low order byte CRC - high order byte B90 Low Impedance Bus Differential System GE Multilin...

  • Page 331: B.3.1 Obtaining Relay Files Via Modbus

    To read binary COMTRADE oscillography files, read the following filenames: OSCnnnn.CFG and OSCnnn.DAT Replace “nnn” with the desired oscillography trigger number. For ASCII format, use the following file names OSCAnnnn.CFG and OSCAnnn.DAT GE Multilin B90 Low Impedance Bus Differential System...

  • Page 332

    EVTnnn.TXT (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) B90 Low Impedance Bus Differential System GE Multilin...

  • Page 333: B.4.1 Modbus Memory Map

    Virtual Input 19 State 0 to 1 F108 0 (Off) 0413 Virtual Input 20 State 0 to 1 F108 0 (Off) 0414 Virtual Input 21 State 0 to 1 F108 0 (Off) GE Multilin B90 Low Impedance Bus Differential System...

  • Page 334

    Modbus User Map Actuals (Read Only) 1200 User Map Values (256 items) 0 to 65535 F001 Element Targets (Read Only) 14C0 Target Sequence 0 to 65535 F001 14C1 Number of Targets 0 to 65535 F001 B-10 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 335

    Remote Double-Point Status Input 1 Events 0 to 1 F102 0 (Disabled) 2629 ... Repeated for Double-Point Status Input 2 2632 ... Repeated for Double-Point Status Input 3 263B ... Repeated for Double-Point Status Input 4 GE Multilin B90 Low Impedance Bus Differential System B-11...

  • Page 336

    Oscillography Force Trigger 0 to 1 F126 0 (No) 3011 Oscillography Clear Data 0 to 1 F126 0 (No) Oscillography Analog Values (Read Only) 3012 Oscillography Number of Triggers 0 to 32767 F001 B-12 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 337

    Reserved for password settings of future roles (63 items) 0 to 65535 F001 3328 Security Status Indicator 0 to 65535 F618 Security (Read/Write Setting) 3329 Session Lockout 0 to 99 F001 GE Multilin B90 Low Impedance Bus Differential System B-13...

  • Page 338

    0.5 to 10 F001 4051 Default Message Timeout 10 to 900 F001 4052 Default Message Intensity 0 to 3 F101 0 (25%) 4053 Screen Saver Feature 0 to 1 F102 0 (Disabled) B-14 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 339

    DNP Communications Reserved (22 items) 0 to 1 F001 40E0 TCP Port Number for the IEC 60870-5-104 Protocol 1 to 65535 F001 2404 40E1 IEC 60870-5-104 Protocol Function 0 to 1 F102 0 (Disabled) GE Multilin B90 Low Impedance Bus Differential System B-15...

  • Page 340

    0 to 1 F102 0 (Disabled) 41AA Daylight Savings Time (DST) Start Month 0 to 11 F237 0 (January) 41AB Daylight Savings Time (DST) Start Day 0 to 6 F238 0 (Sunday) B-16 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 341

    ...Repeated for User-Programmable LED 30 42BC ...Repeated for User-Programmable LED 31 42BE ...Repeated for User-Programmable LED 32 42C0 ...Repeated for User-Programmable LED 33 42C2 ...Repeated for User-Programmable LED 34 42C4 ...Repeated for User-Programmable LED 35 GE Multilin B90 Low Impedance Bus Differential System B-17...

  • Page 342

    ...Repeated for User-Definable Display 9 4D20 ...Repeated for User-Definable Display 10 4D40 ...Repeated for User-Definable Display 11 4D60 ...Repeated for User-Definable Display 12 4D80 ...Repeated for User-Definable Display 13 4DA0 ...Repeated for User-Definable Display 14 B-18 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 343

    Setting Group Names (Read/Write Setting) 5F8C Setting Group 1 Name F203 (none) 5F94 Setting Group 2 Name F203 (none) 5F9C Setting Group 3 Name F203 (none) 5FA4 Setting Group 4 Name F203 (none) GE Multilin B90 Low Impedance Bus Differential System B-19...

  • Page 344

    ...Repeated for Undervoltage 3 6B51 ...Repeated for Undervoltage 4 6B5C ...Repeated for Undervoltage 5 6B67 ...Repeated for Undervoltage 6 6B72 ...Repeated for Undervoltage 7 6B7D ...Repeated for Undervoltage 8 6B88 ...Repeated for Undervoltage 9 B-20 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 345

    ...Repeated for Isolator 2 6CD0 ...Repeated for Isolator 3 6CDA ...Repeated for Isolator 4 6CE4 ...Repeated for Isolator 5 6CEE ...Repeated for Isolator 6 6CF8 ...Repeated for Isolator 7 6D02 ...Repeated for Isolator 8 GE Multilin B90 Low Impedance Bus Differential System B-21...

  • Page 346

    ...Repeated for Terminal Current 7 6F15 ...Repeated for Terminal Current 8 6F18 ...Repeated for Terminal Current 9 6F1B ...Repeated for Terminal Current 10 6F1E ...Repeated for Terminal Current 11 6F21 ...Repeated for Terminal Current 12 B-22 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 347

    ...Repeated for Terminal Current 22 6F98 ...Repeated for Terminal Current 23 6F9A ...Repeated for Terminal Current 24 VT Terminal Settings (Read/Write Setting) (12 modules) 6F9C Terminal Voltage 1 Ratio 1 to 24000 0.01 F060 GE Multilin B90 Low Impedance Bus Differential System B-23...

  • Page 348

    Breaker Failure 1 Use Seal In 0 to 1 F126 1 (Yes) 7104 Breaker Failure 1 Amp Supervision OpA 0 to 65535 F300 7105 Breaker Failure 1 Amp Supervision OpB 0 to 65535 F300 B-24 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 349

    7404 Instantaneous Overcurrent 1 Reset Delay 0 to 65.535 0.001 F001 7405 Instantaneous Overcurrent 1 Block 0 to 65535 F300 7406 Instantaneous Overcurrent 1 Target 0 to 2 F109 0 (Self-reset) GE Multilin B90 Low Impedance Bus Differential System B-25...

  • Page 350

    ...Repeated for Time Overcurrent 14 75A8 ...Repeated for Time Overcurrent 15 75B4 ...Repeated for Time Overcurrent 16 75C0 ...Repeated for Time Overcurrent 17 75CC ...Repeated for Time Overcurrent 18 75D8 ...Repeated for Time Overcurrent 19 B-26 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 351

    0 (Disabled) 8A01 Digital Element 1 Name F203 “Dig Element 1“ 8A09 Digital Element 1 Input 0 to 65535 F300 8A0A Digital Element 1 Pickup Delay 0 to 999999.999 0.001 F003 GE Multilin B90 Low Impedance Bus Differential System B-27...

  • Page 352

    ...Repeated for Digital Element 43 8D5C ...Repeated for Digital 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 B-28 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 353

    ...Repeated for Direct Input/Output 16 94C0 ...Repeated for Direct Input/Output 17 94CC ...Repeated for Direct Input/Output 18 94D8 ...Repeated for Direct Input/Output 19 94E4 ...Repeated for Direct Input/Output 20 94F0 ...Repeated for Direct Input/Output 21 GE Multilin B90 Low Impedance Bus Differential System B-29...

  • Page 354

    ...Repeated for Direct Input/Output 70 9748 ...Repeated for Direct Input/Output 71 9754 ...Repeated for Direct Input/Output 72 9760 ...Repeated for Direct Input/Output 73 976C ...Repeated for Direct Input/Output 74 9778 ...Repeated for Direct Input/Output 75 B-30 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 355

    Non-Volatile Latch 1 Target 0 to 2 F109 0 (Self-reset) A705 Non-Volatile Latch 1 Events 0 to 1 F102 0 (Disabled) A706 Reserved (4 items) F001 A70A ...Repeated for Non-Volatile Latch 2 GE Multilin B90 Low Impedance Bus Differential System B-31...

  • Page 356

    Operand for IEC 61850 XCBR1.ST.Loc Status 0 to 65535 F300 AB25 Command to Clear XCBR1 OpCnt (Operation Counter) 0 to 1 F126 0 (No) AB26 Operand for IEC 61850 XCBR2.ST.Loc Status 0 to 65535 F300 B-32 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 357

    Repeated for IEC 61850 XSWI18 AEF3 Repeated for IEC 61850 XSWI19 AEF5 Repeated for IEC 61850 XSWI20 AEF7 Repeated for IEC 61850 XSWI21 AEF9 Repeated for IEC 61850 XSWI22 AEFB Repeated for IEC 61850 XSWI23 GE Multilin B90 Low Impedance Bus Differential System B-33...

  • Page 358

    0 to 16383 F001 B06A Reserved (2 items) 0 to 1 F001 IEC 61850 Server Configuration (Read/Write Settings/Commands) B06C TCP Port Number for the IEC 61850 / MMS Protocol 1 to 65535 F001 B-34 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 359

    ...Repeated for Received Analog 8 B220 ...Repeated for Received Analog 9 B222 ...Repeated for Received Analog 10 B224 ...Repeated for Received Analog 11 B226 ...Repeated for Received Analog 12 B228 ...Repeated for Received Analog 13 GE Multilin B90 Low Impedance Bus Differential System B-35...

  • Page 360

    ...Repeated for Module 3 B960 ...Repeated for Module 4 B980 ...Repeated for Module 5 B9A0 ...Repeated for Module 6 B9C0 ...Repeated for Module 7 B9E0 ...Repeated for Module 8 BA00 ...Repeated for Module 9 B-36 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 361

    ...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 GE Multilin B90 Low Impedance Bus Differential System B-37...

  • Page 362

    ...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 48 (48 items) 0 to 3 F128 1 (33 Vdc) B-38 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 363

    ...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 GE Multilin B90 Low Impedance Bus Differential System B-39...

  • Page 364

    ...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 B-40 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 365

    ...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 GE Multilin B90 Low Impedance Bus Differential System B-41...

  • Page 366

    ...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 B-42 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 367

    Force Contact Inputs/Outputs (Read/Write Settings) C7A0 Force Contact Input x State (96 items) 0 to 2 F144 0 (Disabled) C800 Force Contact Output x State (64 items) 0 to 3 F131 0 (Disabled) GE Multilin B90 Low Impedance Bus Differential System B-43...

  • Page 368

    ...Repeated for Direct Input 37 C924 ...Repeated for Direct Input 38 C928 ...Repeated for Direct Input 39 C92C ...Repeated for Direct Input 40 C930 ...Repeated for Direct Input 41 C934 ...Repeated for Direct Input 42 B-44 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 369

    ...Repeated for Direct Input 91 C9FC ...Repeated for Direct Input 92 CA00 ...Repeated for Direct Input 93 CA04 ...Repeated for Direct Input 94 CA08 ...Repeated for Direct Input 95 CA0C ...Repeated for Direct Input 96 GE Multilin B90 Low Impedance Bus Differential System B-45...

  • Page 370

    ...Repeated for Direct Output 47 CA6E ...Repeated for Direct Output 48 CA70 ...Repeated for Direct Output 49 CA72 ...Repeated for Direct Output 50 CA74 ...Repeated for Direct Output 51 CA76 ...Repeated for Direct Output 52 B-46 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 371

    0 to 1 F102 0 (Disabled) CAD9 Direct Input/Output Channel 2 CRC Alarm Message 100 to 10000 F001 Count CADA Direct Input/Output Channel 2 CRC Alarm Threshold 1 to 1000 F001 GE Multilin B90 Low Impedance Bus Differential System B-47...

  • Page 372

    ...Repeated for Remote Input 7 CFE6 ...Repeated for Remote Input 8 CFF0 ...Repeated for Remote Input 9 CFFA ...Repeated for Remote Input 10 D004 ...Repeated for Remote Input 11 D00E ...Repeated for Remote Input 12 B-48 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 373

    ...Repeated for Remote Output 26 D288 ...Repeated for Remote Output 27 D28C ...Repeated for Remote Output 28 D290 ...Repeated for Remote Output 29 D294 ...Repeated for Remote Output 30 D298 ...Repeated for Remote Output 31 GE Multilin B90 Low Impedance Bus Differential System B-49...

  • Page 374

    0 to 2 F001 D32E IEC 61850 GGIO2.CF.SPCSO15.ctlModel Value 0 to 2 F001 D32F IEC 61850 GGIO2.CF.SPCSO16.ctlModel Value 0 to 2 F001 D330 IEC 61850 GGIO2.CF.SPCSO17.ctlModel Value 0 to 2 F001 B-50 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 375

    Remote Device 1 SqNum 0 to 4294967295 F003 D384 ...Repeated for Remote Device 2 D388 ...Repeated for Remote Device 3 D38C ...Repeated for Remote Device 4 D390 ...Repeated for Remote Device 5 GE Multilin B90 Low Impedance Bus Differential System B-51...

  • Page 376

    F205 (none) Setting File Template (Read Only Non-Volatile) ED07 Last Settings Change Date 0 to 4294967295 F050 Settings File Template (Read/Write Setting) ED09 Template Bitmask (750 items) 0 to 65535 F001 B-52 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 377: B.4.2 Data Formats

    Minutes: 0 to 59 in steps of 1. 0 = Instantaneous, 1 = Timed Last 16 bits are Seconds (xx:xx:.SS.SSS): 0=00.000s, 1=00.001,...,59999=59.999s). F108 ENUMERATION: OFF/ON 0 = Off, 1 = On GE Multilin B90 Low Impedance Bus Differential System B-53...

  • Page 378

    ENUMERATION: LIST OF ELEMENTS Bitmask Element Bus Zone 1 Bus Zone 2 Bus Zone 3 Bus Zone 4 CT Trouble 1 CT Trouble 2 CT Trouble 3 CT Trouble 4 Setting Group Reset B-54 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 379

    End of Fault Protection 2 Isolator 19 End of Fault Protection 3 Isolator 20 End of Fault Protection 4 Isolator 21 End of Fault Protection 5 Isolator 22 End of Fault Protection 6 Isolator 23 GE Multilin B90 Low Impedance Bus Differential System B-55...

  • Page 380

    Digital Element 4 Breaker Failure 24 Digital Element 5 Instantaneous Overcurrent 1 Digital Element 6 Instantaneous Overcurrent 2 Digital Element 7 Instantaneous Overcurrent 3 Digital Element 8 Instantaneous Overcurrent 4 Digital Element 9 B-56 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 381

    User-Programmable Pushbutton 2 F141 User-Programmable Pushbutton 3 ENUMERATION: SELF TEST ERRORS User-Programmable Pushbutton 4 User-Programmable Pushbutton 5 Bitmask Error User-Programmable Pushbutton 6 Any Self Tests User-Programmable Pushbutton 7 IRIG-B Failure User-Programmable Pushbutton 8 GE Multilin B90 Low Impedance Bus Differential System B-57...

  • Page 382

    F155 UR_UINT32: 32 BIT ERROR CODE (F141 specifies bit number) ENUMERATION: REMOTE DEVICE STATE A bit value of 0 = no error, 1 = error 0 = Offline, 1 = Online B-58 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 383

    User-programmable key 12 0 = None, 1 = COM1-RS485, 2 = COM2-RS485, Message Up User 4 (control pushbutton) 3 = Front Panel-RS232, 4 = Network - TCP, 5 = Network - UDP GE Multilin B90 Low Impedance Bus Differential System B-59...

  • Page 384

    F207 MMXU1.MX.A.phsA.cVal.ang.f TEXT4: 4-CHARACTER ASCII TEXT MMXU1.MX.A.phsB.cVal.mag.f MMXU1.MX.A.phsB.cVal.ang.f F209 MMXU1.MX.A.phsC.cVal.mag.f TEXT65: 65-CHARACTER ASCII TEXT MMXU1.MX.A.phsC.cVal.ang.f MMXU1.MX.A.neut.cVal.mag.f MMXU1.MX.A.neut.cVal.ang.f F210 ENUMERATION: DIRECT ENUMERATION MMXU1.MX.W.phsA.cVal.mag.f MMXU1.MX.W.phsB.cVal.mag.f 0 = IN, 1 = OUT MMXU1.MX.W.phsC.cVal.mag.f MMXU1.MX.VAr.phsA.cVal.mag.f B-60 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 385

    MMXU4.MX.PPV.phsBC.cVal.ang.f MMXU2.MX.VAr.phsC.cVal.mag.f MMXU4.MX.PPV.phsCA.cVal.mag.f MMXU2.MX.VA.phsA.cVal.mag.f MMXU4.MX.PPV.phsCA.cVal.ang.f MMXU2.MX.VA.phsB.cVal.mag.f MMXU4.MX.PhV.phsA.cVal.mag.f MMXU2.MX.VA.phsC.cVal.mag.f MMXU4.MX.PhV.phsA.cVal.ang.f MMXU2.MX.PF.phsA.cVal.mag.f MMXU4.MX.PhV.phsB.cVal.mag.f MMXU2.MX.PF.phsB.cVal.mag.f MMXU4.MX.PhV.phsB.cVal.ang.f MMXU2.MX.PF.phsC.cVal.mag.f MMXU4.MX.PhV.phsC.cVal.mag.f MMXU3.MX.TotW.mag.f MMXU4.MX.PhV.phsC.cVal.ang.f MMXU3.MX.TotVAr.mag.f MMXU4.MX.A.phsA.cVal.mag.f MMXU3.MX.TotVA.mag.f MMXU4.MX.A.phsA.cVal.ang.f MMXU3.MX.TotPF.mag.f MMXU4.MX.A.phsB.cVal.mag.f MMXU3.MX.Hz.mag.f MMXU4.MX.A.phsB.cVal.ang.f MMXU3.MX.PPV.phsAB.cVal.mag.f MMXU4.MX.A.phsC.cVal.mag.f MMXU3.MX.PPV.phsAB.cVal.ang.f MMXU4.MX.A.phsC.cVal.ang.f MMXU3.MX.PPV.phsBC.cVal.mag.f MMXU4.MX.A.neut.cVal.mag.f GE Multilin B90 Low Impedance Bus Differential System B-61...

  • Page 386

    GGIO4.MX.AnIn4.mag.f MMXU5.MX.W.phsA.cVal.mag.f GGIO4.MX.AnIn5.mag.f MMXU5.MX.W.phsB.cVal.mag.f GGIO4.MX.AnIn6.mag.f MMXU5.MX.W.phsC.cVal.mag.f GGIO4.MX.AnIn7.mag.f MMXU5.MX.VAr.phsA.cVal.mag.f GGIO4.MX.AnIn8.mag.f MMXU5.MX.VAr.phsB.cVal.mag.f GGIO4.MX.AnIn9.mag.f MMXU5.MX.VAr.phsC.cVal.mag.f GGIO4.MX.AnIn10.mag.f MMXU5.MX.VA.phsA.cVal.mag.f GGIO4.MX.AnIn11.mag.f MMXU5.MX.VA.phsB.cVal.mag.f GGIO4.MX.AnIn12.mag.f MMXU5.MX.VA.phsC.cVal.mag.f GGIO4.MX.AnIn13.mag.f MMXU5.MX.PF.phsA.cVal.mag.f GGIO4.MX.AnIn14.mag.f MMXU5.MX.PF.phsB.cVal.mag.f GGIO4.MX.AnIn15.mag.f MMXU5.MX.PF.phsC.cVal.mag.f GGIO4.MX.AnIn16.mag.f MMXU6.MX.TotW.mag.f GGIO4.MX.AnIn17.mag.f MMXU6.MX.TotVAr.mag.f GGIO4.MX.AnIn18.mag.f MMXU6.MX.TotVA.mag.f GGIO4.MX.AnIn19.mag.f B-62 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 387

    GGIO3.ST.IndPos2.stVal GGIO5.ST.UIntIn15.q GGIO3.ST.IndPos3.stVal GGIO5.ST.UIntIn15.stVal GGIO3.ST.IndPos4.stVal GGIO5.ST.UIntIn16.q GGIO3.ST.IndPos5.stVal GGIO5.ST.UIntIn16.stVal GGIO3.ST.UIntIn1.q GGIO3.ST.UIntIn1.stVal F233 GGIO3.ST.UIntIn2.q ENUMERATION: CONFIGURABLE GOOSE Rx GGIO3.ST.UIntIn2.stVal DATASET ITEMS GGIO3.ST.UIntIn3.q GGIO3.ST.UIntIn3.stVal Value IEC 61850 GOOSE Rx dataset item GGIO3.ST.UIntIn4.q None GGIO3.ST.UIntIn4.stVal GE Multilin B90 Low Impedance Bus Differential System B-63...

  • Page 388

    [12] CONTACT OUTPUTS CURRENT DETECTED (1 to 64) [13] CONTACT OUTPUTS CURRENT OFF DETECTED (1 to 64) Tuesday [14] REMOTE INPUTS (1 to 32) Wednesday [16] DIRECT INPUTS (1 to 96) B-64 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 389

    0 to 15 corresponding to input/output state 33 to 48 (if required). The fourth register indicates input/out- put state with bits 0 to 15 corresponding to input/output state 49 to 64 (if required). GE Multilin B90 Low Impedance Bus Differential System B-65...

  • Page 390

    PDIF4.ST.Op.general RRTD & GPM-F PDIS1.ST.Str.general PDIS1.ST.Op.general F605 PDIS2.ST.Str.general ENUMERATION: REMOTE DOUBLE-POINT STATUS INPUT PDIS2.ST.Op.general STATUS PDIS3.ST.Str.general PDIS3.ST.Op.general Enumeration Remote DPS input status PDIS4.ST.Str.general Intermediate PDIS4.ST.Op.general PDIS5.ST.Str.general PDIS5.ST.Op.general PDIS6.ST.Str.general PDIS6.ST.Op.general PDIS7.ST.Str.general PDIS7.ST.Op.general B-66 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 391

    PIOC43.ST.Str.general PIOC17.ST.Str.general PIOC43.ST.Op.general PIOC17.ST.Op.general PIOC44.ST.Str.general PIOC18.ST.Str.general PIOC44.ST.Op.general PIOC18.ST.Op.general PIOC45.ST.Str.general PIOC19.ST.Str.general PIOC45.ST.Op.general PIOC19.ST.Op.general PIOC46.ST.Str.general PIOC20.ST.Str.general PIOC46.ST.Op.general PIOC20.ST.Op.general PIOC47.ST.Str.general PIOC21.ST.Str.general PIOC47.ST.Op.general PIOC21.ST.Op.general PIOC48.ST.Str.general PIOC22.ST.Str.general PIOC48.ST.Op.general PIOC22.ST.Op.general PIOC49.ST.Str.general PIOC23.ST.Str.general PIOC49.ST.Op.general PIOC23.ST.Op.general PIOC50.ST.Str.general PIOC24.ST.Str.general PIOC50.ST.Op.general GE Multilin B90 Low Impedance Bus Differential System B-67...

  • Page 392

    PTOC24.ST.Str.general PIOC70.ST.Str.general PTOC24.ST.Op.general PIOC70.ST.Op.general PTOV1.ST.Str.general PIOC71.ST.Str.general PTOV1.ST.Op.general PIOC71.ST.Op.general PTOV2.ST.Str.general PIOC72.ST.Str.general PTOV2.ST.Op.general PIOC72.ST.Op.general PTOV3.ST.Str.general PTOC1.ST.Str.general PTOV3.ST.Op.general PTOC1.ST.Op.general PTOV4.ST.Str.general PTOC2.ST.Str.general PTOV4.ST.Op.general PTOC2.ST.Op.general PTOV5.ST.Str.general PTOC3.ST.Str.general PTOV5.ST.Op.general PTOC3.ST.Op.general PTOV6.ST.Str.general PTOC4.ST.Str.general PTOV6.ST.Op.general PTOC4.ST.Op.general PTOV7.ST.Str.general PTOC5.ST.Str.general PTOV7.ST.Op.general B-68 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 393

    RBRF24.ST.OpEx.general PTUV11.ST.Str.general RBRF24.ST.OpIn.general PTUV11.ST.Op.general RFLO1.MX.FltDiskm.mag.f PTUV12.ST.Str.general RFLO2.MX.FltDiskm.mag.f PTUV12.ST.Op.general RFLO3.MX.FltDiskm.mag.f PTUV13.ST.Str.general RFLO4.MX.FltDiskm.mag.f PTUV13.ST.Op.general RFLO5.MX.FltDiskm.mag.f RBRF1.ST.OpEx.general RPSB1.ST.Str.general RBRF1.ST.OpIn.general RPSB1.ST.Op.general RBRF2.ST.OpEx.general RPSB1.ST.BlkZn.stVal RBRF2.ST.OpIn.general RREC1.ST.Op.general RBRF3.ST.OpEx.general RREC1.ST.AutoRecSt.stVal RBRF3.ST.OpIn.general RREC2.ST.Op.general RBRF4.ST.OpEx.general RREC2.ST.AutoRecSt.stVal RBRF4.ST.OpIn.general RREC3.ST.Op.general RBRF5.ST.OpEx.general RREC3.ST.AutoRecSt.stVal GE Multilin B90 Low Impedance Bus Differential System B-69...

  • Page 394

    GGIO1.ST.Ind25.stVal CSWI17.ST.Loc.stVal GGIO1.ST.Ind26.stVal CSWI17.ST.Pos.stVal GGIO1.ST.Ind27.stVal CSWI18.ST.Loc.stVal GGIO1.ST.Ind28.stVal CSWI18.ST.Pos.stVal GGIO1.ST.Ind29.stVal CSWI19.ST.Loc.stVal GGIO1.ST.Ind30.stVal CSWI19.ST.Pos.stVal GGIO1.ST.Ind31.stVal CSWI20.ST.Loc.stVal GGIO1.ST.Ind32.stVal CSWI20.ST.Pos.stVal GGIO1.ST.Ind33.stVal CSWI21.ST.Loc.stVal GGIO1.ST.Ind34.stVal CSWI21.ST.Pos.stVal GGIO1.ST.Ind35.stVal CSWI22.ST.Loc.stVal GGIO1.ST.Ind36.stVal CSWI22.ST.Pos.stVal GGIO1.ST.Ind37.stVal CSWI23.ST.Loc.stVal GGIO1.ST.Ind38.stVal CSWI23.ST.Pos.stVal GGIO1.ST.Ind39.stVal CSWI24.ST.Loc.stVal GGIO1.ST.Ind40.stVal B-70 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 395

    MMXU1.MX.TotVA.mag.f GGIO1.ST.Ind79.stVal MMXU1.MX.TotPF.mag.f GGIO1.ST.Ind80.stVal MMXU1.MX.Hz.mag.f GGIO1.ST.Ind81.stVal MMXU1.MX.PPV.phsAB.cVal.mag.f GGIO1.ST.Ind82.stVal MMXU1.MX.PPV.phsAB.cVal.ang.f GGIO1.ST.Ind83.stVal MMXU1.MX.PPV.phsBC.cVal.mag.f GGIO1.ST.Ind84.stVal MMXU1.MX.PPV.phsBC.cVal.ang.f GGIO1.ST.Ind85.stVal MMXU1.MX.PPV.phsCA.cVal.mag.f GGIO1.ST.Ind86.stVal MMXU1.MX.PPV.phsCA.cVal.ang.f GGIO1.ST.Ind87.stVal MMXU1.MX.PhV.phsA.cVal.mag.f GGIO1.ST.Ind88.stVal MMXU1.MX.PhV.phsA.cVal.ang.f GGIO1.ST.Ind89.stVal MMXU1.MX.PhV.phsB.cVal.mag.f GGIO1.ST.Ind90.stVal MMXU1.MX.PhV.phsB.cVal.ang.f GGIO1.ST.Ind91.stVal MMXU1.MX.PhV.phsC.cVal.mag.f GGIO1.ST.Ind92.stVal MMXU1.MX.PhV.phsC.cVal.ang.f GGIO1.ST.Ind93.stVal MMXU1.MX.A.phsA.cVal.mag.f GE Multilin B90 Low Impedance Bus Differential System B-71...

  • Page 396

    MMXU3.MX.PF.phsA.cVal.mag.f MMXU2.MX.A.phsB.cVal.mag.f MMXU3.MX.PF.phsB.cVal.mag.f MMXU2.MX.A.phsB.cVal.ang.f MMXU3.MX.PF.phsC.cVal.mag.f MMXU2.MX.A.phsC.cVal.mag.f MMXU4.MX.TotW.mag.f MMXU2.MX.A.phsC.cVal.ang.f MMXU4.MX.TotVAr.mag.f MMXU2.MX.A.neut.cVal.mag.f MMXU4.MX.TotVA.mag.f MMXU2.MX.A.neut.cVal.ang.f MMXU4.MX.TotPF.mag.f MMXU2.MX.W.phsA.cVal.mag.f MMXU4.MX.Hz.mag.f MMXU2.MX.W.phsB.cVal.mag.f MMXU4.MX.PPV.phsAB.cVal.mag.f MMXU2.MX.W.phsC.cVal.mag.f MMXU4.MX.PPV.phsAB.cVal.ang.f MMXU2.MX.VAr.phsA.cVal.mag.f MMXU4.MX.PPV.phsBC.cVal.mag.f MMXU2.MX.VAr.phsB.cVal.mag.f MMXU4.MX.PPV.phsBC.cVal.ang.f MMXU2.MX.VAr.phsC.cVal.mag.f MMXU4.MX.PPV.phsCA.cVal.mag.f MMXU2.MX.VA.phsA.cVal.mag.f MMXU4.MX.PPV.phsCA.cVal.ang.f MMXU2.MX.VA.phsB.cVal.mag.f MMXU4.MX.PhV.phsA.cVal.mag.f MMXU2.MX.VA.phsC.cVal.mag.f MMXU4.MX.PhV.phsA.cVal.ang.f B-72 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 397

    MMXU6.MX.VAr.phsB.cVal.mag.f MMXU5.MX.PhV.phsB.cVal.ang.f MMXU6.MX.VAr.phsC.cVal.mag.f MMXU5.MX.PhV.phsC.cVal.mag.f MMXU6.MX.VA.phsA.cVal.mag.f MMXU5.MX.PhV.phsC.cVal.ang.f MMXU6.MX.VA.phsB.cVal.mag.f MMXU5.MX.A.phsA.cVal.mag.f MMXU6.MX.VA.phsC.cVal.mag.f MMXU5.MX.A.phsA.cVal.ang.f MMXU6.MX.PF.phsA.cVal.mag.f MMXU5.MX.A.phsB.cVal.mag.f MMXU6.MX.PF.phsB.cVal.mag.f MMXU5.MX.A.phsB.cVal.ang.f MMXU6.MX.PF.phsC.cVal.mag.f MMXU5.MX.A.phsC.cVal.mag.f GGIO4.MX.AnIn1.mag.f MMXU5.MX.A.phsC.cVal.ang.f GGIO4.MX.AnIn2.mag.f MMXU5.MX.A.neut.cVal.mag.f GGIO4.MX.AnIn3.mag.f MMXU5.MX.A.neut.cVal.ang.f GGIO4.MX.AnIn4.mag.f MMXU5.MX.W.phsA.cVal.mag.f GGIO4.MX.AnIn5.mag.f MMXU5.MX.W.phsB.cVal.mag.f GGIO4.MX.AnIn6.mag.f MMXU5.MX.W.phsC.cVal.mag.f GGIO4.MX.AnIn7.mag.f MMXU5.MX.VAr.phsA.cVal.mag.f GGIO4.MX.AnIn8.mag.f GE Multilin B90 Low Impedance Bus Differential System B-73...

  • Page 398

    XSWI7.ST.Pos.stVal GGIO1.ST.Ind1.stVal XSWI8.ST.Loc.stVal GGIO1.ST.Ind2.q XSWI8.ST.Pos.stVal GGIO1.ST.Ind2.stVal XSWI9.ST.Loc.stVal GGIO1.ST.Ind3.q XSWI9.ST.Pos.stVal GGIO1.ST.Ind3.stVal XSWI10.ST.Loc.stVal GGIO1.ST.Ind4.q XSWI10.ST.Pos.stVal GGIO1.ST.Ind4.stVal XSWI11.ST.Loc.stVal GGIO1.ST.Ind5.q XSWI11.ST.Pos.stVal GGIO1.ST.Ind5.stVal XSWI12.ST.Loc.stVal GGIO1.ST.Ind6.q XSWI12.ST.Pos.stVal GGIO1.ST.Ind6.stVal XSWI13.ST.Loc.stVal GGIO1.ST.Ind7.q XSWI13.ST.Pos.stVal GGIO1.ST.Ind7.stVal XSWI14.ST.Loc.stVal GGIO1.ST.Ind8.q XSWI14.ST.Pos.stVal GGIO1.ST.Ind8.stVal XSWI15.ST.Loc.stVal B-74 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 399

    GGIO1.ST.Ind54.q GGIO1.ST.Ind28.q GGIO1.ST.Ind54.stVal GGIO1.ST.Ind28.stVal GGIO1.ST.Ind55.q GGIO1.ST.Ind29.q GGIO1.ST.Ind55.stVal GGIO1.ST.Ind29.stVal GGIO1.ST.Ind56.q GGIO1.ST.Ind30.q GGIO1.ST.Ind56.stVal GGIO1.ST.Ind30.stVal GGIO1.ST.Ind57.q GGIO1.ST.Ind31.q GGIO1.ST.Ind57.stVal GGIO1.ST.Ind31.stVal GGIO1.ST.Ind58.q GGIO1.ST.Ind32.q GGIO1.ST.Ind58.stVal GGIO1.ST.Ind32.stVal GGIO1.ST.Ind59.q GGIO1.ST.Ind33.q GGIO1.ST.Ind59.stVal GGIO1.ST.Ind33.stVal GGIO1.ST.Ind60.q GGIO1.ST.Ind34.q GGIO1.ST.Ind60.stVal GGIO1.ST.Ind34.stVal GGIO1.ST.Ind61.q GGIO1.ST.Ind35.q GGIO1.ST.Ind61.stVal GE Multilin B90 Low Impedance Bus Differential System B-75...

  • Page 400

    GGIO1.ST.Ind107.q GGIO1.ST.Ind81.q GGIO1.ST.Ind107.stVal GGIO1.ST.Ind81.stVal GGIO1.ST.Ind108.q GGIO1.ST.Ind82.q GGIO1.ST.Ind108.stVal GGIO1.ST.Ind82.stVal GGIO1.ST.Ind109.q GGIO1.ST.Ind83.q GGIO1.ST.Ind109.stVal GGIO1.ST.Ind83.stVal GGIO1.ST.Ind110.q GGIO1.ST.Ind84.q GGIO1.ST.Ind110.stVal GGIO1.ST.Ind84.stVal GGIO1.ST.Ind111.q GGIO1.ST.Ind85.q GGIO1.ST.Ind111.stVal GGIO1.ST.Ind85.stVal GGIO1.ST.Ind112.q GGIO1.ST.Ind86.q GGIO1.ST.Ind112.stVal GGIO1.ST.Ind86.stVal GGIO1.ST.Ind113.q GGIO1.ST.Ind87.q GGIO1.ST.Ind113.stVal GGIO1.ST.Ind87.stVal GGIO1.ST.Ind114.q GGIO1.ST.Ind88.q GGIO1.ST.Ind114.stVal B-76 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 401

    MMXU2.MX.W.phsA.cVal.mag.f MMXU1.MX.PPV.phsCA.cVal.ang.f MMXU2.MX.W.phsB.cVal.mag.f MMXU1.MX.PhV.phsA.cVal.mag.f MMXU2.MX.W.phsC.cVal.mag.f MMXU1.MX.PhV.phsA.cVal.ang.f MMXU2.MX.VAr.phsA.cVal.mag.f MMXU1.MX.PhV.phsB.cVal.mag.f MMXU2.MX.VAr.phsB.cVal.mag.f MMXU1.MX.PhV.phsB.cVal.ang.f MMXU2.MX.VAr.phsC.cVal.mag.f MMXU1.MX.PhV.phsC.cVal.mag.f MMXU2.MX.VA.phsA.cVal.mag.f MMXU1.MX.PhV.phsC.cVal.ang.f MMXU2.MX.VA.phsB.cVal.mag.f MMXU1.MX.A.phsA.cVal.mag.f MMXU2.MX.VA.phsC.cVal.mag.f MMXU1.MX.A.phsA.cVal.ang.f MMXU2.MX.PF.phsA.cVal.mag.f MMXU1.MX.A.phsB.cVal.mag.f MMXU2.MX.PF.phsB.cVal.mag.f MMXU1.MX.A.phsB.cVal.ang.f MMXU2.MX.PF.phsC.cVal.mag.f MMXU1.MX.A.phsC.cVal.mag.f MMXU3.MX.TotW.mag.f MMXU1.MX.A.phsC.cVal.ang.f MMXU3.MX.TotVAr.mag.f MMXU1.MX.A.neut.cVal.mag.f MMXU3.MX.TotVA.mag.f MMXU1.MX.A.neut.cVal.ang.f MMXU3.MX.TotPF.mag.f GE Multilin B90 Low Impedance Bus Differential System B-77...

  • Page 402

    MMXU5.MX.A.phsB.cVal.ang.f MMXU4.MX.PPV.phsAB.cVal.mag.f MMXU5.MX.A.phsC.cVal.mag.f MMXU4.MX.PPV.phsAB.cVal.ang.f MMXU5.MX.A.phsC.cVal.ang.f MMXU4.MX.PPV.phsBC.cVal.mag.f MMXU5.MX.A.neut.cVal.mag.f MMXU4.MX.PPV.phsBC.cVal.ang.f MMXU5.MX.A.neut.cVal.ang.f MMXU4.MX.PPV.phsCA.cVal.mag.f MMXU5.MX.W.phsA.cVal.mag.f MMXU4.MX.PPV.phsCA.cVal.ang.f MMXU5.MX.W.phsB.cVal.mag.f MMXU4.MX.PhV.phsA.cVal.mag.f MMXU5.MX.W.phsC.cVal.mag.f MMXU4.MX.PhV.phsA.cVal.ang.f MMXU5.MX.VAr.phsA.cVal.mag.f MMXU4.MX.PhV.phsB.cVal.mag.f MMXU5.MX.VAr.phsB.cVal.mag.f MMXU4.MX.PhV.phsB.cVal.ang.f MMXU5.MX.VAr.phsC.cVal.mag.f MMXU4.MX.PhV.phsC.cVal.mag.f MMXU5.MX.VA.phsA.cVal.mag.f MMXU4.MX.PhV.phsC.cVal.ang.f MMXU5.MX.VA.phsB.cVal.mag.f MMXU4.MX.A.phsA.cVal.mag.f MMXU5.MX.VA.phsC.cVal.mag.f MMXU4.MX.A.phsA.cVal.ang.f MMXU5.MX.PF.phsA.cVal.mag.f MMXU4.MX.A.phsB.cVal.mag.f MMXU5.MX.PF.phsB.cVal.mag.f B-78 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 403

    GGIO5.ST.UIntIn11.q GGIO4.MX.AnIn1.mag.f GGIO5.ST.UIntIn11.stVal GGIO4.MX.AnIn2.mag.f GGIO5.ST.UIntIn12.q GGIO4.MX.AnIn3.mag.f GGIO5.ST.UIntIn12.stVal GGIO4.MX.AnIn4.mag.f GGIO5.ST.UIntIn13.q GGIO4.MX.AnIn5.mag.f GGIO5.ST.UIntIn13.stVal GGIO4.MX.AnIn6.mag.f GGIO5.ST.UIntIn14.q GGIO4.MX.AnIn7.mag.f GGIO5.ST.UIntIn14.stVal GGIO4.MX.AnIn8.mag.f GGIO5.ST.UIntIn15.q GGIO4.MX.AnIn9.mag.f GGIO5.ST.UIntIn15.stVal GGIO4.MX.AnIn10.mag.f GGIO5.ST.UIntIn16.q GGIO4.MX.AnIn11.mag.f GGIO5.ST.UIntIn16.stVal GGIO4.MX.AnIn12.mag.f PDIF1.ST.Str.general GGIO4.MX.AnIn13.mag.f PDIF1.ST.Op.general GGIO4.MX.AnIn14.mag.f PDIF2.ST.Str.general GGIO4.MX.AnIn15.mag.f PDIF2.ST.Op.general GE Multilin B90 Low Impedance Bus Differential System B-79...

  • Page 404

    PIOC34.ST.Str.general PIOC8.ST.Str.general PIOC34.ST.Op.general PIOC8.ST.Op.general PIOC35.ST.Str.general PIOC9.ST.Str.general PIOC35.ST.Op.general PIOC9.ST.Op.general PIOC36.ST.Str.general PIOC10.ST.Str.general PIOC36.ST.Op.general PIOC10.ST.Op.general PIOC37.ST.Str.general PIOC11.ST.Str.general PIOC37.ST.Op.general PIOC11.ST.Op.general PIOC38.ST.Str.general PIOC12.ST.Str.general PIOC38.ST.Op.general PIOC12.ST.Op.general PIOC39.ST.Str.general PIOC13.ST.Str.general PIOC39.ST.Op.general PIOC13.ST.Op.general PIOC40.ST.Str.general PIOC14.ST.Str.general PIOC40.ST.Op.general PIOC14.ST.Op.general PIOC41.ST.Str.general PIOC15.ST.Str.general PIOC41.ST.Op.general B-80 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 405

    PTOC15.ST.Str.general PIOC61.ST.Str.general PTOC15.ST.Op.general PIOC61.ST.Op.general PTOC16.ST.Str.general PIOC62.ST.Str.general PTOC16.ST.Op.general PIOC62.ST.Op.general PTOC17.ST.Str.general PIOC63.ST.Str.general PTOC17.ST.Op.general PIOC63.ST.Op.general PTOC18.ST.Str.general PIOC64.ST.Str.general PTOC18.ST.Op.general PIOC64.ST.Op.general PTOC19.ST.Str.general PIOC65.ST.Str.general PTOC19.ST.Op.general PIOC65.ST.Op.general PTOC20.ST.Str.general PIOC66.ST.Str.general PTOC20.ST.Op.general PIOC66.ST.Op.general PTOC21.ST.Str.general PIOC67.ST.Str.general PTOC21.ST.Op.general PIOC67.ST.Op.general PTOC22.ST.Str.general PIOC68.ST.Str.general PTOC22.ST.Op.general GE Multilin B90 Low Impedance Bus Differential System B-81...

  • Page 406

    RBRF15.ST.OpEx.general PTUV2.ST.Str.general RBRF15.ST.OpIn.general PTUV2.ST.Op.general RBRF16.ST.OpEx.general PTUV3.ST.Str.general RBRF16.ST.OpIn.general PTUV3.ST.Op.general RBRF17.ST.OpEx.general PTUV4.ST.Str.general RBRF17.ST.OpIn.general PTUV4.ST.Op.general RBRF18.ST.OpEx.general PTUV5.ST.Str.general RBRF18.ST.OpIn.general PTUV5.ST.Op.general RBRF19.ST.OpEx.general PTUV6.ST.Str.general RBRF19.ST.OpIn.general PTUV6.ST.Op.general RBRF20.ST.OpEx.general PTUV7.ST.Str.general RBRF20.ST.OpIn.general PTUV7.ST.Op.general RBRF21.ST.OpEx.general PTUV8.ST.Str.general RBRF21.ST.OpIn.general PTUV8.ST.Op.general RBRF22.ST.OpEx.general PTUV9.ST.Str.general RBRF22.ST.OpIn.general B-82 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 407

    XSWI4.ST.Loc.stVal CSWI8.ST.Loc.stVal XSWI4.ST.Pos.stVal CSWI8.ST.Pos.stVal XSWI5.ST.Loc.stVal CSWI9.ST.Loc.stVal XSWI5.ST.Pos.stVal CSWI9.ST.Pos.stVal XSWI6.ST.Loc.stVal CSWI10.ST.Loc.stVal XSWI6.ST.Pos.stVal CSWI10.ST.Pos.stVal XSWI7.ST.Loc.stVal CSWI11.ST.Loc.stVal XSWI7.ST.Pos.stVal CSWI11.ST.Pos.stVal XSWI8.ST.Loc.stVal CSWI12.ST.Loc.stVal XSWI8.ST.Pos.stVal CSWI12.ST.Pos.stVal XSWI9.ST.Loc.stVal CSWI13.ST.Loc.stVal XSWI9.ST.Pos.stVal CSWI13.ST.Pos.stVal XSWI10.ST.Loc.stVal CSWI14.ST.Loc.stVal XSWI10.ST.Pos.stVal CSWI14.ST.Pos.stVal XSWI11.ST.Loc.stVal CSWI15.ST.Loc.stVal XSWI11.ST.Pos.stVal GE Multilin B90 Low Impedance Bus Differential System B-83...

  • Page 408

    Has been activated, whether the password has been set. XSWI21.ST.Loc.stVal 1 = Bit#0, Administrator password was set. The list is continued for XSWI21.ST.Pos.stVal all other roles (Engineer = bit#2, Operator = bit#3, Observer = XSWI22.ST.Loc.stVal bit#3). XSWI22.ST.Pos.stVal XSWI23.ST.Loc.stVal XSWI23.ST.Pos.stVal B-84 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 409: C.1.1 Introduction

    The B90 relay supports IEC 61850 server services over both TCP/IP and TP4/CLNP (OSI) communication protocol stacks. The TP4/CLNP profile requires the B90 to have a network address or Network Service Access Point (NSAP) to establish a communication link. The TCP/IP profile requires the B90 to have an IP address to establish communications. These addresses are located in the ...

  • Page 410: C.1.3 File Transfer By Iec 61850

    APPENDIX C C.1.3 FILE TRANSFER BY IEC 61850 The B90 supports file transfer by IEC 61850. The approach is as follows, using the SISCO AX-S4 61850 client software as an example. In the AX-S4 61850 Explorer window, click the Tools menu and access the SISCO File Transfer Utility.

  • Page 411: C.2.1 Overview

    C.2.2 GGIO1: DIGITAL STATUS VALUES The GGIO1 logical node is available in the B90 to provide access to as many 128 digital status points and associated time- stamps and quality flags. The data content must be configured before the data can be used. GGIO1 provides digital status points for access by clients.

  • Page 412: C.2.6 Mmxn: Analog Measured Values

    C.2.6 MMXN: ANALOG MEASURED VALUES A limited number of measured analog values are available through the MMXN logical nodes. Each MMXN logical node provides data from a B90 current and voltage terminal. There is one MMXN available for each configurable terminal (programmed in the ...

  • Page 413

    IEC 61850 control model. • XCBR1.CO.BlkCls: This is where IEC 61850 clients can issue block close commands to the breaker. Direct control with normal security is the only supported IEC 61850 control model. GE Multilin B90 Low Impedance Bus Differential System...

  • Page 414: C.3.1 Buffered And Unbuffered Reporting

    C.3.4 LOGICAL DEVICE NAME The logical device name is used to identify the IEC 61850 logical device that exists within the B90. This name is composed of two parts: the IED name setting and the logical device instance. The complete logical device name is the combination of the two character strings programmed in the settings.

  • Page 415: C.3.6 Logical Node Name Prefixes

    A built-in TCP/IP connection timeout of two minutes is employed by the B90 to detect ‘dead’ connections. If there is no data traffic on a TCP connection for greater than two minutes, the connection will be aborted by the B90. This frees up the con- nection to be used by other clients.

  • Page 416: C.4.1 Overview

    MAC address for GSSE messages. If GSSE DESTINATION MAC ADDRESS a valid multicast Ethernet MAC address is not entered (for example, 00 00 00 00 00 00), the B90 will use the source Ether- net MAC address as the destination, with the multicast bit set.

  • Page 417

    The B90 has the ability of detecting if a data item in one of the GOOSE datasets is erroneously oscillating. This can be caused by events such as errors in logic programming, inputs improperly being asserted and de-asserted, or failed station components.

  • Page 418: C.4.5 Ethernet Mac Address For Gsse/goose

    REMOTE IN 1 ITEM item to remote input 1. Remote input 1 can now be used in FlexLogic™ equations or other settings. The B90 must be rebooted (control power removed and re-applied) before these settings take effect. The value of remote input 1 (Boolean on or off) in the receiving device will be determined by the GGIO1.ST.Ind1.stVal value in the sending device.

  • Page 419: C.4.6 Gsse Id And Goose Id Settings

    GSSE and GOOSE messages must have multicast destination MAC addresses. By default, the B90 is configured to use an automated multicast MAC scheme. If the B90 destination MAC address setting is not a valid multicast address (that is, the least significant bit of the first byte is not set), the address used as the destina- tion MAC will be the same as the local MAC address, but with the multicast bit set.

  • Page 420: C.5.1 Overview

    An ICD file is generated for the B90 by the EnerVista UR Setup software that describe the capabilities of the IED. The ICD file is then imported into a system configurator along with other ICD files for other IEDs (from GE or other ven- dors) for system configuration.

  • Page 421: C.5.2 Configuring Iec 61850 Settings

    Transmission GOOSE dataset may be added or deleted, or prefixes of some logical nodes may be changed. While all new configurations will be mapped to the B90 settings file when importing an SCD file, all unchanged settings will preserve the same values in the new settings file.

  • Page 422: C.5.3 About Icd Files

    Although configurable transmission GOOSE can also be created and altered by some third-party system con- figurators, 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 >...

  • Page 423

    Furthermore, it defines the capabilities of an IED in terms of communication services offered and, together with its LNType, instantiated data (DO) and its default or configuration values. There should be only one IED section in an ICD since it only describes one IED. GE Multilin B90 Low Impedance Bus Differential System C-15...

  • Page 424

    Other ReportControl elements DOI (name) SDI (name) DAI (name) Text Other DOI elements SDI (name) DAI (name) Text Other LN elements Other LDevice elements 842797A1.CDR Figure C–4: ICD FILE STRUCTURE, IED NODE C-16 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 425

    Other BDA elements Other BDA elements Other DAType elements Other DAType elements EnumType (id) Text EnumVal (ord) Other EnumVal elements Other EnumType elements 842798A1.CDR Figure C–5: ICD FILE STRUCTURE, DATATYPETEMPLATES NODE GE Multilin B90 Low Impedance Bus Differential System C-17...

  • Page 426: C.5.4 Creating An Icd File With Enervista Ur Setup

    The EnerVista UR Setup will prompt to save the file. Select the file path and enter the name for the ICD file, then click OK to generate the file. The time to create an ICD file from the offline B90 settings file is typically much quicker than create an ICD file directly from the relay.

  • Page 427

    Like ICD files, the Header node identifies the SCD file and its version, and specifies options for the mapping of names to signals. The Substation node describes the substation parameters: Substation PowerSystemResource EquipmentContainer Power Transformer GeneralEquipment EquipmentContainer VoltageLevel Voltage PowerSystemResource Function SubFunction GeneralEquipment 842792A1.CDR Figure C–7: SCD FILE STRUCTURE, SUBSTATION NODE GE Multilin B90 Low Impedance Bus Differential System C-19...

  • Page 428

    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. C-20 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 429: C.5.6 Importing An Scd File With Enervista Ur Setup

    Figure C–9: SCD FILE STRUCTURE, IED NODE C.5.6 IMPORTING AN SCD FILE WITH ENERVISTA UR SETUP The following procedure describes how to update the B90 with the new configuration from an SCD file with the EnerVista UR Setup software. Right-click anywhere in the files panel and select the Import Contents From SCD File item.

  • Page 430

    The software will open the SCD file and then prompt the user to save a UR-series settings file. Select a location and name for the URS (UR-series relay settings) file. If there is more than 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.

  • Page 431: C.6.1 Acsi Basic Conformance Statement

    Buffered report control M7-1 sequence-number M7-2 report-time-stamp M7-3 reason-for-inclusion M7-4 data-set-name M7-5 data-reference M7-6 buffer-overflow M7-7 entryID M7-8 BufTm M7-9 IntgPd M7-10 Unbuffered report control M8-1 sequence-number M8-2 report-time-stamp M8-3 reason-for-inclusion GE Multilin B90 Low Impedance Bus Differential System C-23...

  • Page 432: C.6.3 Acsi Services Conformance Statement

    UR FAMILY PUBLISHER SERVER (CLAUSE 6) ServerDirectory APPLICATION ASSOCIATION (CLAUSE 7) Associate Abort Release LOGICAL DEVICE (CLAUSE 8) LogicalDeviceDirectory LOGICAL NODE (CLAUSE 9) LogicalNodeDirectory GetAllDataValues DATA (CLAUSE 10) GetDataValues SetDataValues GetDataDirectory GetDataDefinition C-24 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 433

    (dupd) GetURCBValues SetURCBValues LOGGING (CLAUSE 14) LOG CONTROL BLOCK GetLCBValues SetLCBValues QueryLogByTime QueryLogByEntry GetLogStatusValues GENERIC SUBSTATION EVENT MODEL (GSE) (CLAUSE 14.3.5.3.4) GOOSE-CONTROL-BLOCK SendGOOSEMessage GetReference GetGOOSEElementNumber GetGoCBValues SetGoCBValues GSSE-CONTROL-BLOCK SendGSSEMessage GetReference GE Multilin B90 Low Impedance Bus Differential System C-25...

  • Page 434

    (SendGOOSEMessage or SendGSSEMessage) NOTE c9: shall declare support if TP association is available c10: shall declare support for at least one (SendMSVMessage or SendUSVMessage) C-26 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 435: C.7.1 Logical Nodes Table

    RDRE: Disturbance recorder function RADR: Disturbance recorder channel analogue RBDR: Disturbance recorder channel binary RDRS: Disturbance record handling RBRF: Breaker failure RDIR: Directional element RFLO: Fault locator RPSB: Power swing detection/blocking RREC: Autoreclosing GE Multilin B90 Low Impedance Bus Differential System C-27...

  • Page 436

    T: LOGICAL NODES FOR INSTRUMENT TRANSFORMERS TCTR: Current transformer TVTR: Voltage transformer Y: LOGICAL NODES FOR POWER TRANSFORMERS YEFN: Earth fault neutralizer (Peterson coil) YLTC: Tap changer YPSH: Power shunt YPTR: Power transformer C-28 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 437

    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 GE Multilin B90 Low Impedance Bus Differential System C-29...

  • Page 438

    C.7 LOGICAL NODES APPENDIX C C-30 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 439: D.1.1 Interoperability Document

    Not Present (Balanced Transmission Only)   Unbalanced Transmission One Octet  Two Octets  Structured  Unstructured Frame Length (maximum length, number of octets): Not selectable in companion IEC 60870-5-104 standard GE Multilin B90 Low Impedance Bus Differential System...

  • Page 440

     <18> := Packed start events of protection equipment with time tag M_EP_TB_1  <19> := Packed output circuit information of protection equipment with time tag M_EP_TC_1  <20> := Packed single-point information with status change detection M_SP_NA_1 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 441

     <103> := Clock synchronization command (see Clause 7.6 in standard) C_CS_NA_1  <104> := Test command C_TS_NA_1  <105> := Reset process command C_RP_NA_1  <106> := Delay acquisition command C_CD_NA_1  <107> := Test command with time tag CP56Time2a C_TS_TA_1 GE Multilin B90 Low Impedance Bus Differential System...

  • Page 442

    •‘X’ if only used in the standard direction TYPE IDENTIFICATION CAUSE OF TRANSMISSION MNEMONIC <1> M_SP_NA_1 <2> M_SP_TA_1 <3> M_DP_NA_1 <4> M_DP_TA_1 <5> M_ST_NA_1 <6> M_ST_TA_1 <7> M_BO_NA_1 <8> M_BO_TA_1 <9> M_ME_NA_1 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 443

    <35> M_ME_TE_1 <36> M_ME_TF_1 <37> M_IT_TB_1 <38> M_EP_TD_1 <39> M_EP_TE_1 <40> M_EP_TF_1 <45> C_SC_NA_1 <46> C_DC_NA_1 <47> C_RC_NA_1 <48> C_SE_NA_1 <49> C_SE_NB_1 <50> C_SE_NC_1 <51> C_BO_NA_1 <58> C_SC_TA_1 <59> C_DC_TA_1 <60> C_RC_TA_1 GE Multilin B90 Low Impedance Bus Differential System...

  • Page 444

    <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*) BASIC APPLICATION FUNCTIONS Station Initialization:  Remote initialization Cyclic Data Transmission:  Cyclic data transmission Read Procedure:  Read procedure B90 Low Impedance Bus Differential System GE Multilin...

  • Page 445

     Mode B: Local freeze with counter interrogation  Mode C: Freeze and transmit by counter-interrogation commands  Mode D: Freeze by counter-interrogation command, frozen values reported simultaneously  Counter read  Counter freeze without reset GE Multilin B90 Low Impedance Bus Differential System...

  • Page 446

    Maximum number of outstanding I-format APDUs k and latest acknowledge APDUs (w): PARAMETER DEFAULT REMARKS SELECTED VALUE VALUE 12 APDUs Maximum difference receive sequence number to send state variable 12 APDUs 8 APDUs 8 APDUs Latest acknowledge after receiving I-format APDUs B90 Low Impedance Bus Differential System GE Multilin...

  • Page 447: D.1.2 Iec 60870-5-104 Points

    The IEC 60870-5-104 data points are configured through the    SETTINGS PRODUCT SETUP COMMUNICATIONS DNP / menu. Refer to the Communications section of Chapter 5 for additional details. IEC104 POINT LISTS GE Multilin B90 Low Impedance Bus Differential System...

  • Page 448

    D.1 IEC 60870-5-104 APPENDIX D D-10 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 449: E.1.1 Dnp V3.00 Device Profile

    Maximum Data Link Re-tries: Maximum Application Layer Re-tries:  None  None  Fixed at 3  Configurable  Configurable Requires Data Link Layer Confirmation:  Never  Always  Sometimes  Configurable GE Multilin B90 Low Impedance Bus Differential System...

  • Page 450

    FlexLogic™. The On/Off times and Count value are ignored. “Pulse Off” and “Latch Off” operations put the appropriate Virtual Input into the “Off” state. “Trip” and “Close” operations both put the appropriate Virtual Input into the “On” state. B90 Low Impedance Bus Differential System GE Multilin...

  • Page 451

     16 Bits (Counter 8) Default Variation: 1  32 Bits (Counters 0 to 7, 9)  Point-by-point list attached  Other Value: _____  Point-by-point list attached Sends Multi-Fragment Responses:  Yes  No GE Multilin B90 Low Impedance Bus Differential System...

  • Page 452: E.1.2 Implementation Table

    17 or 28 are always responded.) Note 3: Cold restarts are implemented the same as warm restarts – the B90 is not restarted, but the DNP process is restarted. B90 Low Impedance Bus Differential System GE Multilin...

  • Page 453

    17 or 28 are always responded.) Note 3: Cold restarts are implemented the same as warm restarts – the B90 is not restarted, but the DNP process is restarted. GE Multilin B90 Low Impedance Bus Differential System...

  • Page 454

    17 or 28 are always responded.) Note 3: Cold restarts are implemented the same as warm restarts – the B90 is not restarted, but the DNP process is restarted. B90 Low Impedance Bus Differential System GE Multilin...

  • Page 455

    17 or 28 are always responded.) Note 3: Cold restarts are implemented the same as warm restarts – the B90 is not restarted, but the DNP process is restarted. GE Multilin B90 Low Impedance Bus Differential System...

  • Page 456: E.2.1 Binary Input Points

    Change Event Variation reported when variation 0 requested: 2 (Binary Input Change with Time), Configurable Change Event Scan Rate: 8 times per power system cycle Change Event Buffer Size: 500 Default Class for All Points: 1 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 457: E.2.2 Binary And Control Relay Output

    Virtual Input 59 Virtual Input 28 Virtual Input 60 Virtual Input 29 Virtual Input 61 Virtual Input 30 Virtual Input 62 Virtual Input 31 Virtual Input 63 Virtual Input 32 Virtual Input 64 GE Multilin B90 Low Impedance Bus Differential System...

  • Page 458: E.2.3 Analog Inputs

    Change Event Variation reported when variation 0 requested: 1 (Analog Change Event without Time) Change Event Scan Rate: defaults to 500 ms Change Event Buffer Size: 256 Default Class for all Points: 2 E-10 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 459: F.1.1 Revision History

    6.0x 5 April 2012 12-3254 1601-0115-X3 6.0x 31 August 2015 12-0025 F.1.2 CHANGES TO THE B90 MANUAL Table F–2: MAJOR UPDATES FOR B90 MANUAL REVISION X3 (Sheet 1 of 2) PAGE PAGE CHANGE DESCRIPTION (X2) (X3) Update Updated content throughout document...

  • Page 460

    F.1 CHANGE NOTES APPENDIX F Table F–2: MAJOR UPDATES FOR B90 MANUAL REVISION X3 (Sheet 2 of 2) PAGE PAGE CHANGE DESCRIPTION (X2) (X3) 2-10 2-10 Update Updated Bus Differential Pickup Level specification from 2.000 to 6.000 pu Update Updated CPU module 9H in Figures 3-7 to 3-10 Typical Wiring Diagrams...

  • Page 461

    APPENDIX F F.1 CHANGE NOTES Table F–3: MAJOR UPDATES FOR B90 MANUAL REVISION X2 (Sheet 2 of 2) PAGE PAGE CHANGE DESCRIPTION (X1) (X2) 3-24 3-24 Update Updated Figure 3-23 RS485 Serial Connection to version AA 3-25 3-25 Update Updated Figure 3-24 IRIG-B Connection to version A6...

  • Page 462

    F.1 CHANGE NOTES APPENDIX F Table F–5: MAJOR UPDATES FOR B90 MANUAL REVISION W1 (Sheet 2 of 2) PAGE PAGE CHANGE DESCRIPTION (V2) (W1) 5-122 5-122 Update Updated REMOTE INPUTS section Update Updated MODBUS MEMORY MAP section Update Updated PROTECTION AND OTHER LOGICAL NODES section...

  • Page 463: F.2.1 Standard Abbreviations

    MTA ....Maximum Torque Angle FAIL....Failure MTR ....Motor FD ....Fault Detector MVA ....MegaVolt-Ampere (total 3-phase) FDH....Fault Detector high-set MVA_A....MegaVolt-Ampere (phase A) FDL ....Fault Detector low-set MVA_B....MegaVolt-Ampere (phase B) FLA....Full Load Current GE Multilin B90 Low Impedance Bus Differential System...

  • Page 464

    WRT....With Respect To RST ....Reset RSTR ..... Restrained X ....Reactance RTD ....Resistance Temperature Detector XDUCER..Transducer RTU ....Remote Terminal Unit XFMR..... Transformer RX (Rx) ..Receive, Receiver Z..... Impedance, Zone B90 Low Impedance Bus Differential System GE Multilin...

  • Page 465: F.3.1 Ge Multilin Warranty

    F.3 WARRANTY F.3WARRANTY F.3.1 GE MULTILIN WARRANTY If the B90 system is ordered as part of an engineered solution, the warranty is void if the relay logic is changed. NOTE For products shipped as of 1 October 2013, GE Digital Energy warrants most of its GE manufactured products for 10 years.

  • Page 466

    F.3 WARRANTY APPENDIX F B90 Low Impedance Bus Differential System GE Multilin...

  • Page 467

    ........5-13, 5-14, 5-20, 5-31, 5-33 BRIGHTNESS ..............5-10 specifications ............2-16, 2-17 UCA/MMS ..............5-126 web server ..............5-30 COMTRADE ..............B-7 CONDUCTED RFI ............2-18 CONTACT INFORMATION ..........1-2 GE Multilin B90 Low Impedance Bus Differential System...

  • Page 468

    ELEMENTS ............... 5-3 DESIGN ................1-4 END FAULT PROTECTION DEVICE ID ..............5-124 FlexLogic™ operands .............5-73 DEVICE PROFILE DOCUMENT ......... E-1 logic ................5-107 DIELECTRIC STRENGTH ..........3-10 settings ................ 5-105 specifications ..............2-12 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 469

    FLEXCURVES™ settings ................. 5-31 Modbus registers ..........B-18, B-31 IEC 61850 GOOSE ANALOGS settings ................. 5-62 settings ............... 5-131 specifications ..............2-13 IEC 61850 GOOSE UINTEGERS table ................5-62 settings ............... 5-132 GE Multilin B90 Low Impedance Bus Differential System...

  • Page 470

    ............3-27 KEYPAD ..............1-18, 4-22 insertion .................11-1 order codes ..............2-11 power supply ..............3-10 VT .................3-12 withdrawal ..............11-1 MONITORING ELEMENTS ..........5-114 LAMPTEST ................ 7-3 MOUNTING ............... 3-1 LANGUAGE ..............5-10 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 471

    DNA-1 bit pair .............. 5-126 Modbus registers ..........B-49, B-50 UserSt-1 bit pair ............5-127 REMOTE SETTING AUTHORIZATION ........ 4-3 REPAIR ..............11-8, F-7 REPLACEMENT MODULES ..........2-11 RESETTING ............5-75, 5-127 GE Multilin B90 Low Impedance Bus Differential System...

  • Page 472

    ............... 1-6 UNDERVOLTAGE see entry for ENERVISTA UR SETUP FlexLogic™ operands .............5-74 SOFTWARE ARCHITECTURE ..........1-5 Modbus registers ............B-20 SOFTWARE, PC settings ................5-97 see entry for EnerVista UR Setup specifications ..............2-12 B90 Low Impedance Bus Differential System GE Multilin...

  • Page 473

    G.703 interface .............. 3-29 settings ................. 5-41 RS422 and fiber interface ..........3-34 USERST-1 BIT PAIR ............5-127 RS422 interface ............. 3-32 WIRING DIAGRAM ............. 3-5 WITHDRAWAL FROM OPERATION ........11-7 VIBRATION TESTING ............2-18 GE Multilin B90 Low Impedance Bus Differential System...

  • Page 474

    INDEX viii B90 Low Impedance Bus Differential System GE Multilin...

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