Download Now GE Multilin releases the F650 Feeder Managem ent Relay Bay Controller Firm w are. The F650 Instruction Manual is available at the GE Multilin w ebsite.
Instructions Manual GEK-113000Z GE Digital Energy Avda. provided with every F650 relay. GEK-113000Z F650 Digital Bay Controller 3-27.
GE Digital Energy Online Store. Alert. T60 Transformer Protection Relay;. URPlus Manual; Bus. Overview; B90 Bus Differential Relay;.
F650 Bay Controller. Protection, control, metering, monitoring, analysis and energy management numerical system.
Ge F650 Relay Manuals
User manual GEK-113000T GE Multilin Avda. Pinoa, 10 48170 Zamudio SPAIN. provided with every F650 relay, can be run from any computer supporting Microsoft.
3.1.1 INTRODUCTION 3.1.2 ENERVISTA 650 SETUP SOFTWARE OVERVIEW 3.1.3 MAIN SCREEN 3.1.4 COMMUNICATION MENU 3.1.5 FILE MANAGEMENT 3.1.6 ENERVISTA 650 SETUP MENU STRUCTURE 3.1.7 FILE MENU OVERVIEW 3.1.8 SETPOINT MENU OVERVIEW 3.1.9 ACTUAL VALUES MENU OVERVIEW 3.1.10 OPERATIONS MENU OVERVIEW 3.1.11 COMMUNICATION MENU OVERVIEW 3.1.12 SECURITY MENU OVERVIEW 3.1.13 VIEW MENU OVERVIEW 3.1.14 HELP MENU OVERVIEW COMMUNICATIONS Q1. Does the F650 support DNP and ModBus over the Ethernet port? A1. F650 units support both protocols over both the asynchronous serial ports and the Ethernet LAN synchronous port using TCP/IP and UDP/IP layers over the Ethernet. Q2. Does this equipment support dual IP access? A2. Yes, it supports two independent IP addresses in aliasing mode. Those address go in the communications settings Network0 and Network1. Q3. Is the protocol IEC 870-103 supported by the F650? A3. Yes, IEC 870-103 is supported by the F650 in firmware version 5.00 and higher. Q4. Can the F650 be used as a DNP master station? A4. Not at this moment. It works as a slave IED station for all protocols. Q5. How many communication ports are included in the F650? A5. The equipment has 2 different boards, one for asynchronous serial ports and another for a high-speed synchronous Ethernet port. The first board has 2 comm ports, COM1 and COM2. COM2 is multiplexed with the front serial RS232 port, whereas the COM... Q6. Are there one or two Ethernet ports? A6. The equipment has only 1 Ethernet port. For redundant fiber optic versions, redundancy is done at the physical level (fiber optic) but there is just one port. Q7. How many different communication Ethernet sessions can be opened through the LAN port? A7. ModBus TCP/IP: 4 sockets Q8. May I use the cooper 10/100 BaseTX connection included in the basic model with all protocols? A8. Yes, it may be used with all protocols. In noisy substation environments and/or long distances, it is recommended to use fiber optic options due to much better EMC performance and immunity. For fiber optic models, it is necessary to adjust an int... Q9. Remote I/O CAN bus. Does it support DeviceNet protocol? A9. No it does not support DeviceNet. Q10. Which functions are available in the relay web server? A10. Currently, it includes several functions for viewing measures and retrieving information. Q11. Q11 May I use URPC to program the relay? A11. Only oscillography records may be viewed with URPC once downloaded to a file using the ENERVISTA 650 Setup software. Q12. May I connect URs and F650s to the same Ethernet? A12. Yes, either in cable as in fiber, or even mix them. Q13. How do I connect with fiber 10-BASE-FL UR relays with 100-BASE-FX F650 relays? A13. Take into account that an UR is never connected directly to a F650 (neither two UR nor two F650 with each other) but they are always connected through a hub or switch. The hub or switch where the URs are connected must be 10-BASE-FL and the hub ... Q14. How do I connect with cable 10_BASE-T UR relays with 10/100-BASE-TX F650 relays? A14. The answer to this question is as described before but also in this case there is an advantage added, because the hub 10-BASE-TX port is able to understand a 10-BASE-T port. This means that a hub 10-BASE-T port may be connected to an UR or a F65... Q15. What happens with fiber optic connectors compatibility, because the hub that I have has a different connector to the one of the F650, although both are 100-BASE-FX? A15. Just buy fiber cables with the appropriate male connectors. For the UR and F650 side we need the same connectors, ST type, for the hub side, the correspondent ones. And in what concerns to the fiber type, it is used the same for 10 as for 100, i... Q16. What is the difference between a hub and a switch? A16. In a repeater type hub (shared hub), one unit talks and the rest listen. If all the units are talking at the same time there may be collisions in the messages, what may produce certain communication delays. Q17. Why do we have 10/100 compatibility for cable but not for fiber? A17. The cable has some advantages that the fiber does not have, and it is that the signal attenuation in short and medium distances, is worthless and this is truth for low and high frequency signals. By the contrary, the light in one fiber optic is ... PROTECTION Q1. Does the F650 support IRIG-B signals? Which type and accuracy? How many units may be connected to the same source? A1. Yes, the F650 includes an IRIG-B input for all models, including the basic ones. Q2. Does the equipment work with dry inputs in both AC and DC? A2. The equipment works only with DC inputs. Q3. Is it oscillography programmable? A3. Yes, the sampling rate is programmable (4, 8, 16, 32 or 64 samples per input). The depth will depend on the sampling rate. Q4. Do I have to select a different model for 1 or 5 A? A4. No. The same model is able to work with either /1 A or /5 A rated secondary currents. There are high accuracy sensing transformers that allow the use of any current input through the same terminals to reduce the spares and simplify wiring. Q5. In my installation, several digital inputs become active when I energize the transformer. How can I reduce sensitivity? A5. By selecting debounce time and/or voltage threshold, the relay may adapt its sensitivity to different applications. Please select the maximum voltage threshold and debounce time (recommended 15 ms) to minimize AC coupling effects. CONTROL AND HMI Q1. What is the difference between Get/Send info from/to relay and Upload/Download info files to/from relay? A1. Get/Send are used for settings and configuration storage that although both are in a unique file, are sent separately in two times. Upload/Download are used for project or PLC files group storage. These files are the setting_configuration file so... Q2. Could I program interlocks? A2. Yes, via ENERVISTA 650 Setup interlocks may be programmed from very simple to advanced schemes. Q3. Can we rotate the display 90 degrees to show feeders vertically? A3. No. The product has been designed to view it in horizontal mode (landscape) due to the following reasons: Q4. Do I need a laptop or handheld to program the unit? A4. No, all main operations can easily be performed with just the incorporated HMI. Handheld or laptops may be required to download large quantities of information (such as oscillograms, etc.) but they are not mandatory for a conventional user that j... Q5. Is there password security for protection and control? A5. Yes, there are two passwords. An independent password for protection changes and control operations is available since version 1.44 Q6. Is it possible to have a remote HMI installed in the front of the panel with the rest of the relay in the rear side? A6. Not in the present version. Q7. Is it possible to program a default screen for the HMI? A7. In graphic display versions the user may program a custom screen with the single-line diagram, measurements, etc. In text display models, there is a choice of logo, measurements, or scrolling both screens. Q8. May I force inputs and outputs to ease commissioning and testing? A8. Yes. Q9. How can I disable the rotary knob buzzer? A9. Press ESC key for more than 3 seconds and then press the knob during a short pulse. Q10. Why do appear strange texts on the display when switching on the relay? A10. You will have pressed any button and the HMI has entered in a test mode. RELAY CONFIGURATION Q1. Does the "Service" contact on the Power Supply board cover all possible failures or do I have to create an output on the I/O board that includes all the internal errors I can access in the logic? A1. The power supply ready contact only monitor hardware failures in the power supply, to monitor the internal error of the unit it is necessary to configure a virtual output to and the assign it to the device desired (contact output, LED, etc.). Q2. I set an output contact as "Latched". If I do not set a "reset" condition, will it reset from the "ESC" key? A2. No, you have to configure the contact output reset signal (in Setpoint>Relay Configuration>Outputs). GE MULTILIN WARRANTY g Digital Energy Digital Bay Controller Instructions Manual GEK-113000Z F650 Firmware version: 5.4X EnerVista F650 Setup version: 5.4X Copyright © 2010 GE Digital Energy GE Digital Energy 215 Anderson Avenue L6E 1B3 Markham, ON -CANADA T (905) 294 6222 F (905) 294 8512 E [email protected] GE Digital Energy Avda. Pinoa, 10 48170 Zamudio ESPAÑA T +34 94 485 88 00 F +34 94 485 88 45 E [email protected] www.GEDigitalEnergy.com TABLE OF CONTENTS 1. GETTING STARTED 1.1 IMPORTANT PROCEDURES 1.1.1 1.1.2 1.1.3 1.2.1 1.2.2 1.2.3 1.2.4 1.3.1 1.3.2 1.3.3 1.4.1 1.4.2 1.4.3 1.4.4 CAUTIONS AND WARNINGS ........................................................................... 1-1 INSPECTION CHECKLIST ................................................................................ 1-4 SAFETY INSTRUCTIONS ................................................................................. 1-6 INTRODUCTION TO 650 FAMILY OF RELAYS ............................................... 1-8 HARDWARE ARCHITECTURE ......................................................................... 1-8 SOFTWARE ARCHITECTURE........................................................................ 1-10 COMMUNICATIONS ARCHITECTURE .......................................................... 1-10 SYSTEM REQUIREMENTS ............................................................................ 1-12 INSTALLATION................................................................................................ 1-12 CONNECTING ENERVISTA 650 SETUP WITH F650 .................................... 1-16 MOUNTING & WIRING .................................................................................... 1-18 650 COMMUNICATIONS................................................................................. 1-18 FACEPLATE DISPLAY .................................................................................... 1-19 MAINTENANCE ............................................................................................... 1-19 1.2 OVERVIEW 1.3 ENERVISTA 650 SETUP SOFTWARE 1.4 650 HARDWARE 2. PRODUCT DESCRIPTION 2.1 OVERVIEW 2.1.1 2.2.1 2.2.2 F650 OVERVIEW............................................................................................... 2-1 ANSI DEVICE NUMBERS AND FUNCTIONS ................................................... 2-2 OTHER DEVICE FUNCTIONS ......................................................................... 2-3 2.2 SUMMARY 2.3 ORDERING CODE 2.4 TECHNICAL SPECIFICATIONS 2.4.1 2.4.2 2.4.3 2.4.4 2.4.5 2.4.6 2.4.7 2.4.8 2.4.9 2.4.10 2.4.11 2.4.12 2.4.13 2.4.14 2.4.15 PROTECTION ELEMENTS ............................................................................... 2-6 CONTROL........................................................................................................ 2-16 MONITORING .................................................................................................. 2-20 USER-PROGRAMMABLE ELEMENTS ........................................................... 2-22 METERING ...................................................................................................... 2-23 INPUTS ............................................................................................................ 2-24 REAL TIME CLOCK ......................................................................................... 2-26 OUTPUTS ........................................................................................................ 2-26 CONTROL POWER SUPPLY .......................................................................... 2-27 COMMUNICATIONS........................................................................................ 2-27 OPTIC FEATURES .......................................................................................... 2-29 ENVIRONMENTAL CHARACTERISTICS ....................................................... 2-30 PACKAGING AND WEIGHT ............................................................................ 2-30 TYPE TESTS ................................................................................................... 2-30 APPROVALS ................................................................................................... 2-30 2.5 EXTERNAL CONNECTIONS 3. HUMAN INTERFACES. SETTINGS & ACTUAL VALUES 3.1 ENERVISTA 650 SETUP SOFTWARE INTERFACE 3.1.1 INTRODUCTION................................................................................................ 3-1 3.1.2ENERVISTA 650 SETUP SOFTWARE OVERVIEW3-1 3.1.3 MAIN SCREEN .................................................................................................. 3-3 3.1.4 COMMUNICATION MENU ................................................................................ 3-4 3.1.5 FILE MANAGEMENT ......................................................................................... 3-6 3.1.6 ENERVISTA 650 SETUP MENU STRUCTURE .............................................. 3-10 3.1.7 FILE MENU OVERVIEW.................................................................................. 3-11 3.1.8 SETPOINT MENU OVERVIEW ....................................................................... 3-16 3.1.9 ACTUAL VALUES MENU OVERVIEW ............................................................ 3-25 3.1.10 OPERATIONS MENU OVERVIEW.................................................................. 3-28 3.1.11 COMMUNICATION MENU OVERVIEW .......................................................... 3-29 3.1.12 SECURITY MENU OVERVIEW ....................................................................... 3-32 3.1.13 VIEW MENU OVERVIEW ................................................................................ 3-32 GEK-113000Z F650 Digital Bay Controller 1 TABLE OF CONTENTS 3.1.14 3.2.1 3.2.2 3.2.3 3.2.4 3.2.5 3.2.6 3.3.1 3.3.2 3.3.3 3.3.4 3.3.5 3.3.6 3.3.7 3.3.8 HELP MENU OVERVIEW ................................................................................3-32 DISPLAY...........................................................................................................3-34 FRONT LED INDICATORS ..............................................................................3-35 PUSHBUTTONS...............................................................................................3-35 FRONT PORT AND COVER SEALING SYSTEM............................................3-37 TEXT MENUS...................................................................................................3-38 GRAPHIC DISPLAY .........................................................................................3-57 HOME ...............................................................................................................3-66 SNAPSHOT EVENTS.......................................................................................3-67 CONTROL EVENTS .........................................................................................3-68 ALARMS ...........................................................................................................3-69 OSCILLOGRAPHY ...........................................................................................3-70 FAULT REPORT ..............................................................................................3-71 DATA LOGGER ................................................................................................3-72 METERING .......................................................................................................3-73 3.2 HUMAN MACHINE INTERFACE (HMI) 3.3 WEB SERVER 4. SECURITY 4.1 ADDING USERS 4.1.1 USER RIGHTS ...................................................................................................4-1 4.2 CHANGING PASSWORDS 4.3 ENABLING SECURITY 4.4 LOGING INTO ENERVISTA 650 SETUP 5. BOOTCODE AND FIRMWARE UPGRADE 5.1 INTRODUCTION 4 COMMUNICATION PARAMETERS 5.2 BOOTWARE UPGRADE 5.3 FIRMWARE VERSION UPGRADE 5.3.1 5.3.2 5.4.1 5.4.2 INTRODUCTION ..............................................................................................5-14 FIRMWARE UPGRADE ...................................................................................5-14 BOOT CODE UPGRADE (*).............................................................................5-24 FIRMWARE UPGRADE (*)...............................................................................5-24 5.4 SUMMARY OF MAIN STEPS 6. COMMISSIONING 6.1 VISUAL INSPECTION 6.2 OUT OF SERVICE SETTING 6.3 GENERAL CONSIDERATIONS ON THE POWER SUPPLY NETWORK 6.4 ISOLATION TESTS 6.5 INDICATORS 6.6 POWER SUPPLY TESTING 6.7 COMMUNICATIONS 6.8 VERIFICATION OF MEASUREMENT 6.8.1 6.8.2 6.8.3 6.8.4 6.9.1 6.9.2 6.9.3 VOLTAGES ........................................................................................................6-8 PHASE CURRENTS...........................................................................................6-8 ACTIVE, REACTIVE POWER, AND COSJ METERING ....................................6-9 FREQUENCY .....................................................................................................6-9 DIGITAL INPUTS..............................................................................................6-11 CONTACT OUTPUTS ......................................................................................6-12 CIRCUIT CONTINUITY SUPERVISION INPUTS.............................................6-12 6.9 INPUTS AND OUTPUTS 2 F650 Digital Bay Controller GEK-113000Z TABLE OF CONTENTS 6.9.4 LATCHING CIRCUITS ..................................................................................... 6-12 6.10 CONNECTIONS FOR TESTING PROTECTION ELEMENTS 6.11 INSTANTANEOUS OVERCURRENT (50PH, 50PL, 50N, 50G Y 50SG) 6.12 TIME OVERCURRENT (51PH, 51PL, 51N, 51G AND 46) 6.13 DIRECTIONAL ELEMENTS (67P, 67N, 67G, 67SG) 6.13.1 6.13.2 6.13.3 6.13.4 6.14.1 6.14.2 6.15.1 6.15.2 6.15.3 6.15.4 67P ELEMENT................................................................................................. 6-16 67N ELEMENT................................................................................................. 6-16 67G ELEMENT ................................................................................................ 6-18 67SG ELEMENT .............................................................................................. 6-19 27P ELEMENT................................................................................................. 6-20 27X ELEMENT................................................................................................. 6-20 59P ELEMENT................................................................................................. 6-21 59X ELEMENT................................................................................................. 6-21 59NH AND 59NL ELEMENTS ......................................................................... 6-22 47 ELEMENT - NEG SEQ OV ......................................................................... 6-23 6.14 UNDERVOLTAGE ELEMENTS (27P, 27X) 6.15 OVERVOLTAGE ELEMENTS (59P, 59X, 59NH, 59NL, 47) 6.16 FREQUENCY ELEMENTS (81O/81U) 6.17 RECLOSER (79) 6.17.1 6.17.2 6.17.3 RECLOSING CYCLE ....................................................................................... 6-25 RECLOSER STATUS ...................................................................................... 6-26 EXTERNAL RECLOSE INITIATION ................................................................ 6-26 6.18 THERMAL IMAGE ELEMENT (49) 7. FREQUENTLY ASKED QUESTIONS 7.1 COMMUNICATIONS 7.2 PROTECTION 7.3 CONTROL AND HMI 7.4 RELAY CONFIGURATION 8. F650TROUBLESHOOTING GUIDE 8.1 SYMPTOMS AND RECOMMENDED ACTIONS A. LOGIC OPERANDS A.1 LOGIC OPERANDS B. FACTORY DEFAULT LOGIC B.1 FACTORY DEFAULT LOGIC C. FACTORY DEFAULT CONFIGURATION C.1 FACTORY DEFAULT SETTINGS C.2 FACTORY DEFAULT CONFIGURATION D. MISCELLANEOUS D.1 GE MULTILIN WARRANTY GEK-113000Z F650 Digital Bay Controller 3 TABLE OF CONTENTS 4 F650 Digital Bay Controller GEK-113000Z 1 GETTING STARTED 1 GETTING STARTED 1.1IMPORTANT PROCEDURES 1.1 IMPORTANT PROCEDURES 1.1.1 CAUTIONS AND WARNINGS 1 To help ensure years of trouble free operation, please read through the following chapter for information to help guide you through the initial installation procedures of your new relay. BEFORE ATTEMPTING TO INSTALL OR USE THE RELAY, IT IS IMPERATIVE THAT ALL WARNINGS AND CAUTIONS IN THIS MANUAL ARE REVIEWED TO HELP PREVENT PERSONAL INJURY, EQUIPMENT DAMAGE, AND/OR DOWNTIME. CAUTION: THE OPERATOR OF THIS INSTRUMENT IS ADVISED THAT IF THE EQUIPMENT IS USED IN A MANNER NOT SPECIFIED IN THIS MANUAL, THE PROTECTION PROVIDED BY THE EQUIPMENT MAY BE IMPAIRED. Figure 1–1: FRONT VIEW OF F650 UNITS GEK-113000Z F650 Digital Bay Controller 1-1 1.1 IMPORTANT PROCEDURES 1.1.1.1 COMMUNICATION BOARDS WITHDRAWAL / INSERTION 1 GETTING STARTED 1 WARNING: MODULE WITHDRAWAL AND INSERTION SHALL ONLY BE PERFORMED BY DULY QUALIFIED SERVICE PERSONNEL. FOR PERSONAL SECURITY PURPOSES, BEFORE ACCOMPLISHING ANY WITHDRAWAL OR INSERTION OPERATION, THE RELAY MUST BE POWERED OFF AND ALL THE REAR TERMINALS MUST BE POTENTIAL FREE. THE RELAY MUST BE GROUNDED USING THE REAR GROUNDING SCREW. The modular design of the relayallows for the withdrawal and insertion of the communication module. Figure 1–2: shows the location of communication modules on the rear part of the relay. Qualified personnel must carry out the insertion or extraction of the communication boards only after interrupting the relay auxiliary voltage and ensuring that all the rear terminals are potential free. Communication boards are installed on the rear of the unit, the upper port being reserved for the asynchronous communications board and CAN, and the lower port for the ETHERNET board in any of its configurations. Before performing any of these actions, control power must be removed from the relay and all the rear terminals must be potential free. A grounded antistatic wristband must be used when manipulating the module in order to avoid electrostatic discharges that may cause damage to the electronic components. WITHDRAWAL: Loosen the small screws that keep the faceplate in place and extract the module. INSERTION: Insert the module and press it firmly in the case, until it is completely fixed. After this, bolt the faceplate screws and replace the control power. Check that the relay is fully operative. Figure 1–2: MODULE WITHDRAWAL/INSERTION GE Multilin will not be responsible for any damage of the relay, connected equipment or personnel whenever these safety rules are not followed. 1-2 F650 Digital Bay Controller GEK-113000Z 1 GETTING STARTED 1.1.1.2 MAGNETIC MODULE TERMINALS 1.1 IMPORTANT PROCEDURES 1 The transformer module for the VTs and CTs is already connected to a female connector screwed to the case. The current inputs incorporate shorting bars, so that the module can be extracted without the need to short-circuit the currents externally. It is very important, for safety reasons not to change or switch the terminals for CTs and VTs. AC Input Terminals Figure 1–3: REAR VIEW OF F650 UNIT GE Multilin will not be responsible for any damage of the relay, connected equipment or personnel whenever these safety rules are not followed. GEK-113000Z F650 Digital Bay Controller 1-3 1.1 IMPORTANT PROCEDURES 1 GETTING STARTED 1.1.2 INSPECTION CHECKLIST 1 Unwrap the relay and inspect the relay for physical damage. Verify that the model on the label on the side of the relay matches the model ordered. Figure 1–4: IDENTIFICATION LABEL (A4455P6) 1-4 F650 Digital Bay Controller GEK-113000Z 1 GETTING STARTED 1.1 IMPORTANT PROCEDURES Please ensure that you received the following items with your relay: • • • • Mounting screws for fixing the relay to a cabinet CD containing EnerVista 650 Setup software Wiring diagram Certificate of Compliance 1 For product information, instruction manual updates, and the latest software updates, please visit the GE Multilin Home Page www.geindustrial.com/multilin. Note: If there is any physical damage detected on the relay, or any of the contents listed are missing, please contact GE Multilin immediately at: EUROPE, MIDDLE EAST AND AFRICA: GE Digital Energy Av. Pinoa, 10 48170 Zamudio, Vizcaya (SPAIN) Tel.: (34) 94-485 88 54, Fax: (34) 94-485 88 38 E-mail: [email protected] AMERICA, ASIA AND AUSTRALIA: GE Digital Energy 215, Anderson Avenue L6E 1B3 Markham, ON (CANADA) Tel.: +1 905 294 6222, Fax: +1 905 201 2098 E-mail: [email protected] The information provided herein is not intended to cover all the details of the variations of the equipment, nor does it take into account the circumstances that may be present in your installation, operating or maintenance activities. Should you wish to receive additional information, or for any particular problem that cannot be solved by referring to the information contained herein, please contact GENERAL ELECTRIC DIGITAL ENERGY. GEK-113000Z F650 Digital Bay Controller 1-5 1.1 IMPORTANT PROCEDURES 1 GETTING STARTED 1.1.3 SAFETY INSTRUCTIONS 1 The F650 ground screw shown in Figure 1–5: must be correctly grounded. Figure 1–5: LOCATION OF GROUNDING SCREW Before communicating with a F650 unit through the front serial port, please ensure that the computer is grounded. In case of using a laptop, it is recommended not to have it connected to its power supply. In many cases it might not be correctly grounded either due to the power supply or to the connector cables used. This is required not only for personal protection, but also to avoid a potential voltage difference between the relay’s serial port and the computer’s port, which could produce permanent damage to the computer or the relay. GE Multilin will not be responsible for any damage to the relay or connected equipment whenever this elemental safety rule is not followed. 1-6 F650 Digital Bay Controller GEK-113000Z 1 GETTING STARTED 1.1.3.1 WARNING SYMBOLS 1.1 IMPORTANT PROCEDURES The following table explains the meaning of warning symbols that may appear on the device or in this manual 1 Symbol M eaning The relevant c ircuit is direct c urrent. The relevant c ircuit is alter nating curr ent. CAU TIO N: Refer to the docum entation for imp ortan t operating and m aintenanc e ins truc tions . Failure to take or a void a spec ified ac tion could result in los s of data or phys ical d am age. WARNING! Dange rous voltage c onstitutin g a risk of elec tric shoc k is pres ent within th e unit. Fa ilure to take or avoid a sp ec ified ac tion could result in phys ic al harm to the user. CAU TIO N: Class 1M La ser (IE C 60825-1 Safety of las er pr oducts) DO NOT VIEW D IRE CT LY W ITH OPT IC AL INST RUM E NTS CAU TIO N: Hot s urfac e E arth (G round) Terminal P rotectiv e E arth Term inal GEK-113000Z F650 Digital Bay Controller 1-7 1.2 OVERVIEW 1.2OVERVIEW 1 GETTING STARTED 1.2.1 INTRODUCTION TO 650 FAMILY OF RELAYS 1 Historically, substation protection, control and metering functions were performed with electromechanical equipment. This first generation of equipment was gradually replaced by analog electronic equipment (called static devices), most of which emulated the single-function approach of their electromechanical precursors. Both of these technologies required expensive cabling and auxiliary equipment to produce functioning systems. Recently, digital electronic equipment has begun to provide protection, control and metering functions. Initially, this equipment was either single function or had very limited multi-function capability, and did not significantly reduce the cabling and auxiliary equipment required. However, recent digital relays have become quite multi-functional, reducing cabling and auxiliaries significantly. These devices also transfer data to central control facilities and Human Machine Interfaces using electronic communications. The functions performed by these products have become so broad that many users prefer the term IED (Intelligent Electronic Device). It is obvious to station designers that the amount of cabling and auxiliary equipment installed in stations can be even further reduced, to 20% to 70% of the levels common in 1990, to achieve large cost reductions. This requires placing even more functions within the IEDs. Users of power equipment are also interested in reducing cost by improving power quality and personnel productivity, and as always, in increasing system reliability and efficiency. These objectives are realized through software which is used to perform functions at both the station and supervisory levels. The use of these systems is growing rapidly. High speed communications are required to meet the data transfer rates required by modern automatic control and monitoring systems. In the near future, very high speed communications will be required to perform protection signalling. This has been established by the IEC 61850 standard. IEDs with capabilities outlined above will also provided significantly more power system data than is presently available, enhance operations and maintenance, and permit the use of adaptive system configuration for protection and control systems. This new generation of equipment must also be easily incorporated into automation systems, at both the station and enterprise levels. 1.2.2 HARDWARE ARCHITECTURE 650 family of relays has been designed to meet the goals described above that are appearing nowadays in the environment of new substations. The 650 is a digital-based device containing a central processing unit (CPU) that handles multiple types of input and output signals. The 650 family can communicate over a local area network (LAN) with an operator interface, a programming device, or another 650 or UR device. The CPU module contains firmware that provides protection elements in the form of logic algorithms, as well as programming logic gates, timers, and latches for control features. It incorporates two internal processors, one for generic use and a second one dedicated for communications. Input Elements accept a variety of analog or digital signals from the field. The 650 isolates and converts these signals into logic signals used by the relay. Output Elements convert and isolate the logic signals generated by the relay into digital signals that can be used to control field devices. 1-8 F650 Digital Bay Controller GEK-113000Z 1 GETTING STARTED 1.2 OVERVIEW 1 Figure 1–6: 650 CONCEPT BLOCK DIAGRAM Contact Inputs/Outputs are signals associated to the physical input/output contacts in the relay CT and VT inputs are signals coming from the inputs of current and voltage transformers, used for monitoring the power system signals. CAN Bus Inputs/Outputs: are signals associated to physical input/output contacts from independent modules connected to the 650 unit via a CAN Bus. Not available for W650 models. PLC: Programmable Logic Controller. Control module that enables the unit configuration (assignment of inputs/outputs) and the implementation of logic circuits. Protection Elements: Relay protection elements, for example: Overcurrent, overvoltage, etc. Not available for C650 models. Remote inputs and outputs provide a means of sharing digital point state information between remote devices using IEC 61850 GSSE and GOOSE messages. Not available for G650 models. Analog Inputs are signals associated with transducers. GEK-113000Z F650 Digital Bay Controller 1-9 1.2 OVERVIEW 1 GETTING STARTED 1.2.3 SOFTWARE ARCHITECTURE 1 The firmware (software embedded in the relay) has been designed using object oriented programming techniques (OOP). These techniques are based on the use of objects and classes, and provide the software architecture with the same characteristics as the hardware architecture, i.e., modularity, scalability and flexibility. 1.2.4 COMMUNICATIONS ARCHITECTURE The main processor performs protection, control, and communication functions, incorporating two internal processors, one for generic use and a second one dedicated for communications. A dedicated serial port is used for communication between the main processor and the human-machine interface. The serial connection provides great immunity against electromagnetic disturbances, thus increasing system safety. All 650 units incorporate an RS232 serial port on the front of the relay. There is also a possibility to incorporate up to two additional communication modules on the rear. One of the modules provides asynchronous serial communications, using different physical media (RS485 + cable remote CAN bus I/O, plastic or glass fiber optic) depending on the selected model. The module incorporates two identical ports, COM1 and COM2. The COM2 port is multiplexed with the front port. Additionally, this module may incorporate a port for CAN BUS communications, used for the connection to the Remote CAN BUS I/O module. This feature allows increasing up to 100% the I/O capability, when the maximum number of I/Os available inside the relay is not enough for a specific application. Available options are: Table 1–1: REAR SERIAL COMMUNICATIONS BOARD 1 BOARD CODE F A P G X Y Z C M FUNCTIONALITY Without additional communication ports Two RS485 ports Two Plastic F.O. ports Two Glass F.O. ports Two RS485 ports and a CAN port for remote CAN Bus Inputs/Outputs Two Plastic F.O. ports and a CAN port for remote CAN Bus Inputs/Outputs (fiber) Two Glass F.O. ports and a CAN port for remote CAN Bus Inputs/Outputs (fiber) CAN port for remote CAN Bus I/O (cable) RS485 + RS485 port and a CAN port for remote CAN bus I/O (cable) The other module provides Ethernet communications (COM3 port), using 10/100BaseTX (self-negotiable speed) or 100BaseFX connectors, depending on the selected model. The most complete models include a double redundant 100BaseFX fiber optic port. Redundancy is provided at the physical level; the unit incorporates internally duplicated and independent controllers for extended system reliability and accessibility. Available Options are: Table 1–2: REAR ETHERNET COMMUNICATIONS BOARD 2 BOARD CODE B C D E FUNCTIONALITY One 10/100BaseTX port (self-negotiable speed) One 10/100BaseTX port and one 100BaseFX port. One 10/100BaseTX port and redundant 100BaseFX ports Redundant 10/100BaseTX ports For options C and D it is required to select the active physical media, by means of an internal selector inside the module. The factory configuration for this selection is the 10/100BaseTX port. 1-10 F650 Digital Bay Controller GEK-113000Z 1 GETTING STARTED 1.2 OVERVIEW Finally, internal communication with input and output modules is performed via an internal CAN bus, independent from the one used for remote CAN BUS I/Os. This fact provides increased communication speed, as well as the possibility of acknowledgement of modules, abnormalities, etc. As this is a serial port supporting a communications protocol, it provides extraordinary immunity against external or internal disturbances. 1 Figure 1–7: COMMUNICATIONS ARCHITECTURE (B6816F1) GEK-113000Z F650 Digital Bay Controller 1-11 1.3 ENERVISTA 650 SETUP SOFTWARE 1.3ENERVISTA 650 SETUP SOFTWARE 1 GETTING STARTED 1.3.1 SYSTEM REQUIREMENTS 1 The EnerVista 650 Setup software interface is the preferred method to edit settings and view actual values because the PC monitor can display more information in a simple comprehensible format. The following minimum requirements must be met for the EnerVista 650 Setup software to properly operate on a PC: • • • • • • Pentium® class or higher processor (Pentium® II 300 MHz or higher recommended) Windows® NT 4.0 (Service Pack 3 or higher), Windows® 2000, Windows® XP Internet Explorer® 5.0 or higher 64 MB of RAM (128 MB recommended) 40 MB of available space on system drive and 40 MB of available space on installation drive RS232C serial and/or Ethernet port for communications to the relay 1.3.2 INSTALLATION After ensuring the minimum requirements for using EnerVista 650 Setup are met (see previous section), use the following procedure to install the EnerVista 650 Setup from the GE EnerVista CD. 1. 2. 3. 4. Insert the GE EnerVista CD into your CD-ROM drive. Click the Install Now button and follow the installation instructions to install the no-charge EnerVista software. When installation is complete, start the EnerVista Launchpad application. Click the IED Setup section of the Launch Pad window. Figure 1–8: LAUNCHPAD WINDOW 1-12 F650 Digital Bay Controller GEK-113000Z 1 GETTING STARTED 5. 1.3 ENERVISTA 650 SETUP SOFTWARE In the EnerVista Launch Pad window, click the Add Product button and select the “F650 Bay Controller” relay from the Install Software window as shown below. Select the “Web” option to ensure the most recent software release, or select “CD” if you do not have a web connection, then click the Add Now button to list software items for the F650. 1 Figure 1–9: ADD PRODUCT WINDOW 6. If “Web” option is selected, choose the F650 software program and release notes (if desired) from the list and click the Download Now button to obtain the installation program. Figure 1–10: WEB UPGRADE WINDOW GEK-113000Z F650 Digital Bay Controller 1-13 1.3 ENERVISTA 650 SETUP SOFTWARE 7. 1 GETTING STARTED 1 EnerVista Launchpad will obtain the installation program from the Web or CD. Once the download is complete, doubleclick the installation program to install the EnerVista 650 Setup software. Select the complete path, including the new directory name, where the EnerVista 650 Setup will be installed. Click on Next to begin the installation. The files will be installed in the directory indicated and the installation program will automatically create icons and add EnerVista 650 Setup to the Windows start menu. 8. 9. 10. Follow the on-screen instructions to install the EnerVista 650 Setup software. When the Welcome window appears, click on Next to continue with the installation procedure. Figure 1–11: ENERVISTA 650 SETUP INSTALLATION 11. When the Choose Destination Location window appears, and if the software is not to be located in the default directory, click Change… and type in the complete path name including the new directory name and click Next to continue with the installation procedure. Figure 1–12: ENERVISTA 650 SETUP INSTALLATION CONT. 1-14 F650 Digital Bay Controller GEK-113000Z 1 GETTING STARTED 1.3 ENERVISTA 650 SETUP SOFTWARE 12. The default program group where the application will be added to is shown in the Selected Program Folder window. Click Next to begin the installation process, and all the necessary program files will be copied into the chosen directory. 1 Figure 1–13: SELECT PROGRAM FOLDER 13. To finish with the installation process, select the desired language for startup. Figure 1–14: LANGUAGE WINDOW GEK-113000Z F650 Digital Bay Controller 1-15 1.3 ENERVISTA 650 SETUP SOFTWARE 1 GETTING STARTED 1 14. Click Finish to end the installation. The F650 device will be added to the list of installed IEDs in the EnerVista Launchpad window, as shown below. Figure 1–15: ENERVISTA LAUNCHPAD 1.3.3 CONNECTING ENERVISTA 650 SETUP WITH F650 This section is intended as a quick start guide to using the EnerVista 650 Setup software. Please refer to section 4.1 in this manual for more information about the EnerVista 650 Setup software interface. a) CONFIGURING AN ETHERNET CONNECTION Before starting, verify that the Ethernet network cable is properly connected to the Ethernet port on the back of the relay. 1. 2. 3. 4. 5. 6. 7. Install and start the latest version of the EnerVista 650 Setup software (available from the GE EnerVista CD or online from http://www.GEindustrial.com/multilin (see previous section for installation instructions). Go to “Communication>Computer” and enter the following data referring to communications: Select Control Type as MODBUS TCP/IP from the drop-down list. This option will display a number of interface parameters that must be entered for proper Ethernet communications. Enter the relay IP address (from “Setpoint>Product Setup >Communication Settings>Network>IP ADDRESS”) in the IP Address field in MODBUS TCP/IP SETUP. Enter the relay ModBus address (from “Setpoint>Product Setup >Communication Settings>ModBus Protocol>ModBus Address COM1/COM2 setting”) in the Unit Identifier (Slave Address) field. Enter the ModBus port address (from “Setpoint>Product Setup >Communication Settings>ModBus Protocol>ModBus Port Number” setting) in the ModBus Port field. The Device has now been configured for Ethernet communications. Proceed to press the ON button to begin communicating. 1-16 F650 Digital Bay Controller GEK-113000Z 1 GETTING STARTED 1.3 ENERVISTA 650 SETUP SOFTWARE b) CONFIGURING AN RS232 CONNECTION Before starting, verify that the RS232 serial cable, or the USB Cable, is properly connected to the RS232 port or the USB port on the front panel of the relay. 1. 2. 3. 4. 5. Install and start the latest version of the EnerVista 650 Setup software (available from the GE EnerVista CD or online from http://www.GEindustrial.com/multilin (see previous section for installation instructions). Go to “Communication>Computer” and enter the following data referred to communications: Select Control Type as No Control Type from the drop-down list. This option will display a number of interface parameters that must be entered for proper serial communications. Enter the relay Slave Address (“Setpoint>Product Setup >Communication Settings>ModBus Protocol” menu) in the Slave Address field. The default value is 254. Enter the physical communications parameters (Baudrate and parity settings) from the “Setpoint>Product Setup >Communication Settings>Serial Ports” menu, in their respective fields. Default values are 19200 for baudrate and none for parity. The Device has now been configured for RS232 communicating. communications. Proceed to press the ON button to begin 1 6. GEK-113000Z F650 Digital Bay Controller 1-17 1.4 650 HARDWARE 1.4650 HARDWARE 1 GETTING STARTED 1.4.1 MOUNTING & WIRING 1 Please refer to Chapter 3. Hardware for detailed mounting and wiring instructions. 1.4.2 650 COMMUNICATIONS The Enervista 650 Setup software communicates to the relay via the faceplate USB port in hardware 04(E in ordering code) or RS232port or the rear RS485/Ethernet ports. To communicate via the faceplate , RS232 port, a standard “straightthrough” serial cable is used. The DB-9 male end is connected to the relay and the DB-9 or DB-25 female end is connected to the PC COM1 or COM2 port as described in Figure 1–16:. To communicate via USB port a male A / male B USB shielded wire is needed To communicate through the F650 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 according to American standards; 0.25, 0.34 or 0.5 mm2 according to European standards) connects the F485 converter to the F650 rear communication port. In order to minimize communication errors that could be caused by external noise, it is recommended to use a shielded twist pair. In order to avoid loops where external currents could flow, the cable shield must be grounded only at one end. The converter box (-, +, GND) terminals are connected to the relay (SDA, SDB, GND) terminals respectively. For long communications cables (longer than 1 km), the RS485 circuit must be terminated in an RC network (i.e. 120 ohm, 1 nF). This circuit is shown on Figure 1–17: RS485 CONNECTION FOR 650 UNITS, associated to text Zt(*). Figure 1–16: RELAY- PC CONNECTION FOR RS232 FRONT PORT To minimize errors from noise, the use of shielded twisted pair wire is recommended. For correct operation, polarity must be respected, although a different polarity will not damage the unit. For instance, the relays must be connected with all RS485 SDA terminals connected together, and all SDB terminals connected together. This may result confusing sometimes, as the RS485 standard refers only to terminals named “A” and “B”, although many devices use terminals named “+” and “-“. As a general rule, terminals “A” should be connected to terminals “-“, and terminals “B” to “+”. The GND terminal should be connected to the common wire inside the shield, when provided. Otherwise, it should be connected to the shield. Each relay should also be daisy chained to the next one in the link. A maximum of 32 relays can be connected in this manner 1-18 F650 Digital Bay Controller GEK-113000Z 1 GETTING STARTED 1.4 650 HARDWARE without exceeding driver capability. For larger systems, additional serial channels must be added. It is also possible to use commercially available repeaters to increase the number of relays on a single channel to more than 32. Do not use other connection configurations different to the recommended. Lightening strikes and ground surge currents can cause large momentary voltage differences between remote ends of the communication link. For this reason, surge protection devices are internally provided. To ensure maximum reliability, all equipment should have similar transient protection devices installed. 1 Figure 1–17: RS485 CONNECTION FOR 650 UNITS To communicate through the F650 rear Ethernet port from a PC a crossover cable is required. If the connection is performed through a hub or a switch, a direct Ethernet cable is required. 1.4.3 FACEPLATE DISPLAY All messages are displayed on a 20x4 character LCD display. An optional graphic display is also available. Messages are displayed in different languages according to selected model. 1.4.4 MAINTENANCE F650 requires a minimum amount of maintenance when it is commissioned into service. F650 is a microprocessor based relay and its characteristics do not change over time. As such no further functional tests are required. However, it is recommended that maintenance on the F650 be scheduled with other system maintenance. The maintenance may involve the following: In-service maintenance: 1. 2. 3. Visual verification of the analog values integrity such as voltage and current (in comparison to other devices on the corresponding system). Visual verification of active alarms, relay display messages and LED indications. Visual inspection for any damage, corrosion, dust or loose wires. GEK-113000Z F650 Digital Bay Controller 1-19 1.4 650 HARDWARE 4. Event recorder file download with further event analysis. 1 GETTING STARTED 1 Out-of-service maintenance: 1. 2. 3. 4. 5. 6. Check wiring connections for firmness. Analog values (current, voltages, analog inputs) injection test and metering accuracy verification. Calibrated test equipment is required. Protection elements setpoints verification (analog values injection or visual verification of setting file entries against relay settings schedule). Contact inputs and outputs verification. This test can be conducted by direct change of state forcing or as part of the system functional testing. Visual inspection for any damage, corrosion or dust. Event recorder file download with further events analysis. Unscheduled maintenance such as during a disturbance causing system interruption: 1. View the event recorder and oscillography or fault report for correct operation of inputs,outputs and elements. If it is concluded that the relay or one of its modules is of concern, contact GE Multilin or one of its representative for prompt service. 1-20 F650 Digital Bay Controller GEK-113000Z 2 PRODUCT DESCRIPTION 2 PRODUCT DESCRIPTION 2.1OVERVIEW 2.1 OVERVIEW 2.1.1 F650 OVERVIEW F650 is a protection, control, monitoring, metering and registering unit, suitable for many different applications, such as main protection for distribution feeders and transmission lines, as well as backup protection for transformers, busbars, capacitor banks, etc. Overvoltage and undervoltage protection, overfrequency and underfrequency protection, breaker failure protection, directional current supervision fault diagnostics and programmable logic functions are provided. This relay also provides phase, neutral, ground and sensitive ground, instantaneous and time overcurrent protection. The time overcurrent function provides multiple curve shapes or FlexCurves™ for optimum co-ordination. Automatic reclosing, synchrocheck, and line fault locator features are also provided. Voltage, current, power, and energy metering is built into the relay as a standard feature. Current parameters are available as total waveform RMS magnitude, or as fundamental frequency only RMS magnitude and angle (phasor). Diagnostic features include a sequence of records. The internal clock used for time-tagging can be synchronized with an IRIG-B signal or via the SNTP protocol over the Ethernet port. This precise time stamping allows the sequence of events to be determined throughout the system. Oscillography data capture may be set to record the measured parameters before and after the event for viewing on a personal computer (PC). These tools significantly reduce troubleshooting time and simplify report generation in the event of a system fault. 2 A faceplate RS232 or USB port may be used to connect to a PC for the programming of settings and the monitoring of actual values. A variety of communications modules are available. Two rear RS485 ports allow independent access by operating and engineering staff. All serial ports use the Modbus® RTU protocol. Optional communications modules include a 100BaseFX Ethernet interface which can be used to provide fast, reliable communications in noisy environments. Another option provides two 100BaseFX fiber optic ports for redundancy. The Ethernet port supports IEC 61850, Modbus®/ TCP, DNP 3.0 and TFTP protocols, and allows access to the relay via any standard web browser. The IEC 60870-5-104 protocol is supported on the Ethernet port. Rear port COM1 could be set to support IEC60870-5-103 protocol The F650 IEDs use flash memory technology which allows field upgrading as new features are added: Figure 2–1: FUNCTIONAL BLOCK DIAGRAM GEK-113000Z F650 Digital Bay Controller 2-1 2.2 SUMMARY 2.2SUMMARY 2 PRODUCT DESCRIPTION 2.2.1 ANSI DEVICE NUMBERS AND FUNCTIONS DEVICE NUMBER FUNCTION 25 27P 27X Synchronism Check Phase Undervoltage Auxiliary Undervoltage Directional Power Forward Power Wattmetric Zero-Sequence Directional Negative Sequence Time Overcurrent Negative Sequence Overvoltage Locked Rotor Protection against Overload by thermal model Breaker Failure Ground Instantaneous Overcurrent (measured from 4th current transformer) Neutral Instantaneous Overcurrent (calculated from the phase currents) Phase Instantaneous Overcurrent (two elements, High and Low) Ground Instantaneous Overcurrent for sensitive ground systems (measured from 5th current transformer) Isolated Ground Instantaneous Overcurrent (measured from 5th current transformer) Ground Time Overcurrent (measured from 4th current transformer) Neutral Time Overcurrent (calculated from the phase currents) Phase Time Overcurrent with Voltage Restraint (two elements, High and Low) Ground Time Overcurrent for sensitive ground systems (measured from 5th current transformer) Neutral Overvoltage (two elements, High and Low) Phase Overvoltage Auxiliary Overvoltage Phase Directional Neutral directional Ground Directional Sensitive Ground Directional Autoreclose (Four shot recloser) Overfrequency Underfrequency Frequency Rate of Change Broken Conductor VT Fuse Failure Load Encroachment 2 32 32FP 32N 46 47 48 49 50BF 50G 50N 50P 50SG 50ISG 51G 51N 51P 51SG 59N 59P 59X 67P 67N 67G 67SG 79 810 81U 81R I2/I1 VTFF 2-2 F650 Digital Bay Controller GEK-113000Z 2 PRODUCT DESCRIPTION 2.2 SUMMARY 2.2.2 OTHER DEVICE FUNCTIONS INPUTS/OUTPUTS 9 Analog Inputs: 5 current inputs (3 for phases, 1 for ground, 1 for sensitive ground), 4 voltage inputs (3 for phases, 1 for busbar or auxiliary voltage) Digital Programmable Contact Inputs (up to 64) Digital Programmable Contact Outputs (up to 16) 32 Latched Virtual Inputs 32 Self-Reset Virtual Inputs Virtual Outputs (up to 512) Tripping and closing circuit supervision Remote Inputs/Outputs (GSSE and GOOSE messages) Analog Inputs (dCmA) METERING Metering Current for phases, ground and sensitive ground inputs COMMUNICATIONS Front RS232 port, Two rear RS485/ fibre optic ports, 10/100 TX and 100 FX Mbps Ethernet port ModBus Communications RTU and over TCP/IP DNP Multimaster (3.0 Level 2) IEC 870-5-104 ModBus User Map IEC 61850 IEC 870-5-103 protocol Voltages phase to phase and phase to ground Real, Reactive and Apparent Power and Power Factor Three Phase Energy Frequency Sequence components of currents and voltages Pulse Counters Analog Comparators 2 USER INTERFACE Alphanumerical display (4x20) Graphic display (16 x 40) User Programmable LEDs (15) User Programmable Keys (up to 5) Easy menu management thanks to shuttle key Configurable model only) One-Line Diagram (Graphic RECORDS Data Logger Demand Event Recorder (up to 128 configurable events) Fault Locator and Fault report records) Oscillography (up to 20 records) Snapshot Events (up to 479) (up to 10 OTHERS Breaking Arcing Current (I2t) Breaker Control IRIG-B synchronization/SNTP Logic Equations (PLC Editor) Settings Groups (up to 3) Operations (up to 24) Web Server Application Phasor Diagram (available in EnerVista 650 Setup) GEK-113000Z F650 Digital Bay Controller 2-3 2.3 2 PRODUCT DESCRIPTION 2.3F650 units are supplied as ½ 19” rack, 6 units high, containing the following modules: power supply, CPU, I/O modules, communication modules. The required information to completely define an F650 model is shown on Table 2–1: Table 2–1: ORDERING CODE F650 B M F G DESCRIPTION Basic Display (See note 2) Graphic Display with Standard Symbols (See note 2) Graphic Display with IEC symbols (See note 2) REAR SERIAL COMMUNICATIONS BOARD 1 F A P G X Y Z C M B C D E 1 2 4 5 0 4 5 LO HI LOR HIR C F P S 3 6 None Redundant RS485 Redundant plastic fiber optic Redundant glass fiber optic Redundant RS485 + fiber remote CAN bus I/O Redundant plastic fiber optic + fiber remote CAN bus I/O Redundant glass fiber optic + fiber remote CAN bus I/O Cable Remote CAN Bus I/O RS485 + cable Remote CAN Bus I/O REAR ETHERNET COMMUNICATIONS BOARD 2 10/100 Base TX 10/100 Base TX + 100 Base FX 10/100 Base TX + Redundant 100 Base FX Redundant 10/100 Base TX I/O BOARD IN SLOT F 16 Digital Inputs + 8 Outputs 8 Digital Inputs + 8 Outputs + 2 trip/close circuit supervision circuits 32 Digital Inputs 16 Digital Inputs + 8 Analog Inputs I/O BOARD IN SLOT G None 32 Digital Inputs (see Note 1) 16 Digital Inputs + 8 Analog Inputs (See Note 1) AUXILIARY VOLTAGE 24-48 Vdc (range 19.2 – 57.6) 110-250 Vdc (range 88 – 300). 120-230 Vac (range 96 – 250) Redundant LO Redundant HI LANGUAGE English/English Chinese/English (See Note 2) French/English Russian/English (See Note 2) Spanish/English COMMUNICATION PROTOCOL Modbus® RTU, TCP/IP, DNP 3.0 Level 2, IEC 60870-5-104 IEC 60870-5-103, Modbus® RTU,TCP/IP IEC 61850, Modbus® RTU and TCP/IP,DNP 3.0 Level 2, IEC 60870-5-104 ENVIRONMENTAL PROTECTION H Without Harsh (Chemical) Environment Conformal Coating Harsh (Chemical) Environment Conformal Coating ENHANCED DISPLAY Display with RS232 E Enhanced Display with USB 2 N 2-4 F650 Digital Bay Controller GEK-113000Z 2 PRODUCT DESCRIPTION 2.3 SPECIAL MODELS: MOD001: 6A output contacts instead of 16A. Notes: (1) The digit selected for option G must be equal or higher than the digit selected for option F for models including boards 4 and 5. F1G5 is a valid selection and F5G1 is and invalid selection. (2) Display options with language selection: Graphic display: available for English, French, Spanish and Chinese languages. For chinese only IEC symbols option is available (N in ordering code). Basic display: available for all languages 2 For those applications requiring a high number of inputs and outputs, F650 units can be connected to a CIO module (Remote CAN Bus I/O module) for using up to 2 additional boards. F650 units allow monitoring and configuring these I/O boards as if they were internal boards, located on slots F and G. In this case, slots are labeled as H y J. The required information to completely define a CIO Module is shown on Table 2–2:. Table 2–2: ORDERING CODE FOR CIO MODULE CIO H 1 2 4 5 0 1 4 5 LO HI J DESCRIPTION I/O BOARD IN SLOT H 16 Digital inputs + 8 outputs 8 Digital Inputs + 8 Outputs + 2 trip/close circuit supervision circuits 32 Digital Inputs 16 Digital Inputs + 8 Analog Inputs I/O BOARD IN SLOT J None 16 Digital inputs + 8 outputs 32 Digital Inputs (See Note 1) 16 Digital Inputs + 8 Analog Inputs (See Note 1) AUXILIARY VOLTAGE 24-48 Vdc (range 19.2 – 57.6) 110-250 Vdc (range 88 – 300) 120-230 Vac (range 96 – 250) ENVIRONMENTAL PROTECTION H Harsh (Chemical) Environment Conformal Coating (1) The digit selected for option J must be equal or higher than the digit selected for option H for models including boards 4 and 5. CIOH1J5**: is a valid selection CIOH5J1**: is an invalid selection GEK-113000Z F650 Digital Bay Controller 2-5 2.4 TECHNICAL SPECIFICATIONS 2.4TECHNICAL SPECIFICATIONS 2 PRODUCT DESCRIPTION NOTE: TECHNICAL SPECIFICATIONS ARE SUBJECT TO CHANGE WITHOUT NOTICE 2.4.1 PROTECTION ELEMENTS Phase and ground units use as operation magnitude the current value received by the unit in current inputs, while the neutral unit uses the calculated current value from the three phase currents. The isolated ground unit will be used only for those applications where the neutral is completely isolated, and it uses the fifth CT of the unit. This CT has a sensitivity that is 10 times higher than the universal model (connected to 1A or 5A transformers). Therefore, it does not admit such a high permanent overload. 2 2.4.1.1 PHASE TIME OVERCURRENT (51PH/51PL) Current Input Rated current Pickup level Dropout level Level Accuracy Phasor (without harmonics) or RMS For connection to 1 or 5 A CTs. 0.05 to 160.00 A in steps of 0.01 A 97% to 98% of the pickup level Values at nominal frequency: ±0.5% of the reading ± 10 mA from 0.05 to 10 A ±1.5% of the reading for higher values. Curve Shapes IEEE extremely / very / moderately inverse IEC A/B/C/long-time inverse/short time inverse curve IAC extremely / very / moderately inverse ANSI extremely / very / normally / moderately inverse I2t Definite time Rectifier curve FlexCurve™ A/B/C/D user curve Curve Multiplier (Time Dial) Reset type Timing accuracy Voltage restraint Saturation Level Snapshot Events 0.00 to 900.00 s in steps of 0.01 s Instantaneous or time delayed according to IEEE Operate at > 1.03 times the pickup ±3% of operate time or 50 ms. (whichever is greater) Selectable by setting 48 times the pickup level Selectable by setting 2-6 F650 Digital Bay Controller GEK-113000Z 2 PRODUCT DESCRIPTION 2.4.1.2 GROUND TIME OVERCURRENT (51G) Current Input Rated current Pickup level Dropout level Level Accuracy 2.4 TECHNICAL SPECIFICATIONS Phasor (without harmonics) or RMS For connection to 1 or 5 A CTs. 0.05 to 160.00 A in steps of 0.01 A 97% to 98% of the pickup level Values at nominal frequency: ±0.5% of the reading ± 10 mA from 0.05 to 10 A ±1.5% of the reading for higher values. 2 Curve Shapes IEEE extremely / very / moderately inverse IEC A/B/C/long-time inverse/short time inverse curve IAC extremely / very / moderately inverse ANSI extremely / very / normally / moderately inverse I2t Definite time Rectifier curve FlexCurve™ A/B/C/D user curve Curve Multiplier (Time Dial) Reset type Timing accuracy Saturation Level Snapshot Events 0.00 to 900.00 s in steps of 0.01 s Instantaneous or time delayed according to IEEE Operate at > 1.03 times the pickup ±3% of operate time or 50 ms. (whichever is greater) 48 times the pickup level Selectable by setting 2.4.1.3 NEUTRAL TIME OVERCURRENT (51N) Current Input Pickup level Dropout level Level Accuracy Fundamental Phasor (without harmonics) 0.05 to 160.00 A in steps of 0.01 A 97% to 98% of the pickup level Values at nominal frequency: ±0.5% of the reading ± 10 mA from 0.05 to 10 A ±1.5% of the reading for higher values. Curve Shapes IEEE extremely / very / moderately inverse IEC A/B/C/long-time inverse/short time inverse curve IAC extremely / very / moderately inverse ANSI extremely / very / normally / moderately inverse I2t Definite time Rectifier curve FlexCurve™ A/B/C/D user curve Curve Multiplier (Time Dial) Reset type Timing accuracy Saturation Level Snapshot Events 0.00 to 900.00 s in steps of 0.01 s Instantaneous or time delayed according to IEEE Operate at > 1.03 times the pickup ±3% of operate time or 50 ms. (whichever is greater) 48 times the pickup level Selectable by setting GEK-113000Z F650 Digital Bay Controller 2-7 2.4 TECHNICAL SPECIFICATIONS 2.4.1.4 SENSITIVE GROUND TIME OVERCURRENT (51SG) Current Input Rated current Pickup level Dropout level 2 PRODUCT DESCRIPTION Phasor (without harmonics) or RMS For connection to 1 or 5 A CTs. 0.005 to 16.000 A in steps of 0.001 A 97% to 98% of the pickup level Values at nominal frequency: ±1.5% of the reading ± 1 mA from 0.005 to 16 A IEEE extremely / very / moderately inverse IEC A/B/C/long-time inverse/short time inverse curve IAC extremely / very / moderately inverse ANSI extremely / very / normally / moderately inverse I2t Definite time Rectifier curve FlexCurve™ A/B/C/D user curve 2 Level Accuracy Curve Shapes Curve Multiplier (Time Dial) Reset type Timing accuracy Saturation Level Snapshot Events 0.00 to 900.00 s in steps of 0.01 s Instantaneous or time delayed according to IEEE Operate at > 1.03 times the pickup ±3% of operate time or 50 ms. (whichever is greater) 48 times the pickup level Selectable by setting 2.4.1.5 PHASE AND GROUND INSTANTANEOUS OVERCURRENT (50PH/50PL/50G) Current Input Rated current Pickup level Dropout level Level Accuracy Phasor (without harmonics) or RMS For connection to 1 or 5 A CTs. 0.05 to 160.00 A in steps of 0.01 A 97% to 98% of the pickup level Values at nominal frequency: ±0.5% of the reading ± 10 mA from 0.05 to 10 A ±1.5% of the reading for higher values Overreach Trip delay Reset delay Operate time Timing accuracy < 2% 0.00 to 900.00 s. in steps of 0.01 s. 0.00 to 900.00 s. in steps of 0.01 s. <50 ms at 3 x Pickup at 50 Hz, typically at 0 ms time delay (no intentional delay): 50ms at non-zero time delay: ±3% of operate time or 50 ms (whichever is greater) Selectable by setting Snapshot Events 2-8 F650 Digital Bay Controller GEK-113000Z 2 PRODUCT DESCRIPTION 2.4.1.6 NEUTRAL INSTANTANEOUS OVERCURRENT (50N) Current Input Pickup level Dropout level Level Accuracy 2.4 TECHNICAL SPECIFICATIONS Fundamental Phasor (without harmonics) 0.05 to 160.00 A in steps of 0.01 A 97% to 98% of the pickup level Values at nominal frequency: ±0.5% of the reading ± 10 mA from 0.05 to 10 A ±1.5% of the reading for higher values 2 Overreach Trip delay Reset delay Operate time Timing accuracy < 2% 0.00 to 900.00 s. in steps of 0.01 s. 0.00 to 900.00 s. in steps of 0.01 s. <50 ms at 3 x Pickup at 50 Hz, typically at 0 ms time delay (no intentional delay): 50ms at non-zero time delay: ±3% of operate time or 50 ms (whichever is greater) Selectable by setting Snapshot Events 2.4.1.7 SENSITIVE GROUND INSTANTANEOUS OVERCURRENT (50SG) Current Input Rated current Pickup level Dropout level Level Accuracy Overreach Trip delay Reset delay Operate time Timing accuracy Phasor (without harmonics) or RMS For connection to 1 or 5 A CTs. 0.005 to 16.000 A in steps of 0.001 A 97% to 98% of the pickup level Values at nominal frequency: ±1.5% of the reading ± 1 mA from 0.005 to 16 A < 2% 0.00 to 900.00 s. in steps of 0.01 s. 0.00 to 900.00 s. in steps of 0.01 s. <50 ms at 3 x Pickup at 50 Hz, typically at 0 ms time delay (no intentional delay): 50ms at non-zero time delay: ±3% of operate time or 50 ms (whichever is greater) Selectable by setting Snapshot Events GEK-113000Z F650 Digital Bay Controller 2-9 2.4 TECHNICAL SPECIFICATIONS 2.4.1.8 ISOLATED GROUND INSTANTANEOUS OVERCURRENT (50IG) Current Input Voltage Input Current Pickup level Voltage Pickup level 2 PRODUCT DESCRIPTION Fundamental Phasor (without harmonics) Fundamental Phasor (without harmonics) 0.005 to 0.400 A in steps of 0.001 A 2 to 70 V in steps of 1 V 97 to 98% of the pickup level ±1.5% of the reading ± 1 mA from 0.005 to 16 A 0.00 to 900.00 s. in steps of 0.01 s. 0.00 to 900.00 s. in steps of 0.01 s. <50 ms at 3 x Pickup at 50 Hz, typically at 0 ms time delay (no intentional delay): 50ms at non-zero time delay: ±3% of operate time or 50 ms (whichever is greater) Selectable by setting 2 Dropout level Level Accuracy Trip delay Time to instantaneous Operate time Timing accuracy Snapshot Events 2.4.1.9 NEGATIVE SEQUENCE CURRENT (46) Current Input Pickup level Dropout level Level Accuracy Fundamental Phasor (without harmonics) 0.05 to 160.0 A in steps of 0.01 A 97% to 98% of the pickup level Values at nominal frequency: ±0.5% of the reading ± 10 mA from 0.05 to 10 A ±1.5% of the reading for higher values Curve Shapes IEEE extremely / very / moderately inverse IEC A/B/C/long-time inverse/short time inverse curve IAC extremely / very / moderately inverse ANSI extremely / very / normally / moderately inverse I2t Definite time Rectifier curve FlexCurve™ A/B/C/D user curve Curve Multiplier (Time Dial) Reset type Timing accuracy Saturation Level Snapshot Events 0.00 to 900.00 s in steps of 0.01 s Instantaneous or time delayed according to IEEE Operate at > 1.03 times the pickup ±3% of operate time or 50 ms. (whichever is greater) 48 times the pickup level Selectable by setting 2-10 F650 Digital Bay Controller GEK-113000Z 2 PRODUCT DESCRIPTION 2.4.1.10 PHASE DIRECTIONAL (67P) Directionality Polarizing 2.4 TECHNICAL SPECIFICATIONS Forward and reverse selectable by setting Quadrature Voltage: ABC seq: Phase A (VBC), Phase B (VCA), Phase C (VAB) ACB seq: Phase A (VCB), Phase B (VAC), Phase C (VBA) 0 to 300 Vac in steps of 1 V 50 mA -90º to +90º in steps of 1º Permission or Block selectable by setting ±3º for I>0.1 A and V>5 Vac <30ms, typically 2 Polarizing voltage threshold Current Sensitivity Threshold Characteristic angle Block Logic Angle accuracy Operate time 2.4.1.11 GROUND DIRECTIONAL (67G) Directionality Polarizing Polarizing Voltage Polarizing Current Operating Current Polarizing Voltage threshold Polarizing Current threshold Characteristic angle Block Logic Angle accuracy Operate time 2.4.1.12 NEUTRAL DIRECTIONAL (67N) Directionality Polarizing Polarizing Voltage Polarizing Current Operating Current Polarizing Voltage threshold Polarizing Current threshold Characteristic angle Block Logic Angle accuracy Operate time Forward and reverse selectable by setting Voltage, current, dual VN (measured or calculated, selected by setting) Isg (measured from 5th current transformer) IN 0 to 300 Vac in steps of 1 V 0.005 A -90º to +90º in steps of 1º Permission or Block selectable by setting ±3º for I>0.1 A and V>5 Vac <30ms, typically Forward and reverse selectable by setting Voltage, current, dual VN (measured or calculated, selected by setting) Isg (measured from 5th current transformer) Ig (measured from 4th current transformer) 0 to 300 Vac in steps of 1 V 0.005 A -90º to +90º in steps of 1º Permission or Block selectable by setting ±3º for I>0.1 A and V>5 Vac <30ms, typically GEK-113000Z F650 Digital Bay Controller 2-11 2.4 TECHNICAL SPECIFICATIONS 2.4.1.13 SENSITIVE GROUND DIRECTIONAL (67SG) Directionality Polarizing Polarizing Voltage Operating Current 2 PRODUCT DESCRIPTION Forward and reverse selectable by setting Voltage VN (measured or calculated, selected by setting) Isg (measured from 5th current transformer) 0 to 300 Vac in steps of 1 V -90º to +90º in steps of 1º Permission or Block selectable by setting ±2º for I>0.1 A and V>5 Vac <30ms, typically 2 Polarizing Voltage threshold Characteristic angle Block Logic Angle accuracy Operate time 2.4.1.14 THERMAL MODEL (49) Current Input Rated current Pickup level Dropout level Level Accuracy Fundamental Phasor (without harmonics) For connection to 1 or 5 A CTs. 0.05 to 160.0 A in steps of 0.01 A 97% to 98% of the pickup level Values at nominal frequency: ±0.5% of the reading ± 10 mA from 0.05 to 10 A ±1.5% of the reading for higher values Timing accuracy Heating constant Cooling constant Snapshot Events ±3.5% of operate time or 50 ms. (whichever is greater) 3.0 to 600.0 minutes in steps of 0.1 minute 1.00 to 6.00 times the heating constant in steps of 0.01 Selectable by setting 2.4.1.15 PHASE OVERVOLTAGE (59P) Voltage Input Pickup level Dropout level Level Accuracy Trip delay Reset delay Timing accuracy Logic Snapshot Events Fundamental Phasor (without harmonics) of phase-tophase voltages 3 to 300 in steps of 1 V 97% to 98% of the pickup level ±1% of reading from 10 to 208 V at Nominal Frequency 0.00 to 900.00 s. in steps of 0.01 s. 0.00 to 900.00 s. in steps of 0.01 s. ±3.5% of operate time or 50 ms. (whichever is greater) Any/Two/All phases logic selectable by setting Selectable by setting 2-12 F650 Digital Bay Controller GEK-113000Z 2 PRODUCT DESCRIPTION 2.4.1.16 PHASE UNDERVOLTAGE (27P) Voltage Input Pickup level Dropout level Level accuracy Curve Shapes Reset type Curve Multiplier (Time Dial) Timing accuracy Minimum Voltage Threshold Logic Supervised by Breaker Snapshot Events 2.4 TECHNICAL SPECIFICATIONS Fundamental Phasor of phase-to-ground or phase-tophase voltages (selectable by setting) 3 to 300 in steps of 1 V 102% to 103% of the pickup level ±1% of reading from 10 to 208 V at nominal frequency Fixed time or inverse curve Instantaneous 0.00 to 900.00 s. in steps of 0.01 s. ±3.5% of operate time or 50 ms. (whichever is greater) 0 to 300 in steps of 1 V Any/Two/All phases logic selectable by setting Selectable by setting Selectable by setting 2 2.4.1.17 NEUTRAL OVERVOLTAGE (59NH/59NL) Voltage Input Pickup level Dropout level Level accuracy Trip delay Reset delay Timing accuracy Snapshot Events Fundamental Phasor of the neutral voltage 3 to 300 in steps of 1 V 97% to 98% of the pickup level ±1% of reading from 10 to 208 V at nominal frequency 0.00 to 900.00 s. in steps of 0.01 s 0.00 to 900.00 s. in steps of 0.01 s ±3.5% of operate time or 50 ms. (whichever is greater) Selectable by setting 2.4.1.18 NEGATIVE SEQUENCE OVERVOLTAGE (47) Voltage Input Pickup level Dropout level Level accuracy Trip delay Reset delay Timing accuracy Snapshot Events Fundamental Phasor 3 to 300 in steps of 1 V 97% to 98% of the pickup level ±1% of reading from 10 to 208 V 0.00 to 900.00 s. in steps of 0.01 s 0.00 to 900.00 s. in steps of 0.01 s ±3.5% of operate time or 50 ms. (whichever is greater) Selectable by setting GEK-113000Z F650 Digital Bay Controller 2-13 2.4 TECHNICAL SPECIFICATIONS 2.4.1.19 AUXILIARY OVERVOLTAGE (59X) Voltage Input Pickup level Dropout level Level accuracy 2 PRODUCT DESCRIPTION Fundamental Phasor of the auxiliary voltage 3 to 300 in steps of 1 V 97% to 98% of the pickup level ±1% of reading from 10 to 208 V at nominal frequency 0.00 to 900.00 s. in steps of 0.01 s 0.00 to 900.00 s. in steps of 0.01 s ±3.5% of operate time or 50 ms. (whichever is greater) Selectable by setting 2 Trip delay Reset delay Timing accuracy Snapshot Events 2.4.1.20 AUXILIARY UNDERVOLTAGE (27X) Voltage Input Pickup level Dropout level Level accuracy Curve Shapes Reset type Curve Multiplier (Time Dial) Timing accuracy Snapshot Events Fundamental Phasor of the auxiliary voltage 3 to 300 V in steps of 1 V 97% to 98% of the pickup level ±1% of reading from 10 to 208 V at nominal frequency Fixed time or inverse curve Instantaneous 0.00 to 900.00 s. in steps of 0.01 s ±3.5% of operate time or 50 ms. (whichever is greater) Selectable by setting 2.4.1.21 UNDERFREQUENCY (81U) Pickup level Dropout level Level accuracy Trip delay Reset delay Minimum voltage threshold Timing accuracy Snapshot Events 20.00 to 65.00 Hz in steps of 0.01 Hz Pickup + 0.03 Hz ±0.05 Hz of the reading 0.00 to 900.00 s. in steps of 0.01 s 0.00 to 900.00 s. in steps of 0.01 s 20 to 300V in steps of 1 V ±3.5% of operate time or 100 ms. (whichever is greater) Selectable by setting 2-14 F650 Digital Bay Controller GEK-113000Z 2 PRODUCT DESCRIPTION 2.4.1.22 OVERFREQUENCY (81O) Pickup level Dropout level Level accuracy Trip delay Reset delay Minimum voltage threshold Timing accuracy Snapshot Events 2.4 TECHNICAL SPECIFICATIONS 20.00 to 65.00 Hz in steps of 0.01 Hz Pickup - 0.03 Hz ±0.05 Hz of the reading 0.00 to 900.00 s. in steps of 0.01 s 0.00 to 900.00 s. in steps of 0.01 s 20 to 300V in steps of 1 V ±3.5% of operate time or 100 ms. (whichever is greater) Selectable by setting 2 2.4.1.23 FORWARD POWER (32FP) Current, Voltage Number of stages Pickup level (two stages) Dropout level Level accuracy for primary magnitudes Trip delay (two stages) Timing accuracy Block Time after close Snapshot Events Fundamental Phasor (primary values) 2 0.00-10000.00 MW in steps of 0.01 MW 97% to 98% of the pickup level ±3% complete range. 0.00 to 900.00 s in steps of 0.01 s ±3.5% of operate time or 50 ms. (whichever is greater) 0.00 to 900.00 s in steps of 0.01 s Selectable by setting 2.4.1.24 DIRECTIONAL POWER (32) Current, Voltage Number of stages Pickup level (two stages) Characteristic Angle (two stages) Accuracy for primary magnitudes Trip delay (two stages) Timing accuracy Block Time after close Snapshot Events Operate time: Fundamental Phasor (primary values) 2 -10000.00 to 10000.00 MW (primary values) in steps of 0.01 MW 0.00 to 359.99 in steps of 0.01 ±3% complete range 0.00 to 900.00 s in steps of 0.01 s ±3.5% of operate time or 50 ms. (whichever is greater) 0.00 to 900.00 s in steps of 0.01 s Selectable by setting < 45 ms at 50 Hz, typically GEK-113000Z F650 Digital Bay Controller 2-15 2.4 TECHNICAL SPECIFICATIONS 2.4.1.25 WATTMETRIC ZERO-SEQUENCE DIRECTIONAL (32N) Measured Power Number of elements Voltage Pickup Level (VN) Zero sequence 2 PRODUCT DESCRIPTION 6 (3 High level, 3 Low level) 2.00 to 70.00 Volts in steps of 0.01 Voltage calculated from phases if Auxiliary voltage is set to Vx Voltage Measured directly from the fourth voltage transformer if Auxiliary voltage is set to VN. ±1% of reading from 10 to 208 V IN (calculated from phases) IG (measured directly from transformer) the fourth current 2 Level Accuracy for Voltage Current Selection OC Pickup Level Level Accuracy for current OC Pickup Delay Power Pickup Level Characteristic Angle (MTA) Power Pickup Delay Level Accuracy for Power Curve Shapes 0.005 to 0.400 Amps in steps of 0.001 ±0.5% of the reading ± 10 mA from 0.05 to 10 A ±1.5% of the reading for higher values 0.00 to 600.00 seconds in steps of 0.01 0.01 to 4.50 Watts in steps of 0.01 0 to 360º in steps of 1 0.00 to 600.00 seconds in steps of 0.01 ±2.5% of the reading at -0.8 = PF = -1 and 0.8 <PF=1 Inverse Curve Definite time FlexCurve™ A/B/C/D user curve 0.02 to 2.00 s in steps of 0.01 s ±3.5% of operate time or 50 ms whichever is greater Selectable by setting < 45 ms at 50 Hz, typically Curve Multiplier (Time Dial) Tripping time accuracy Snapshot Events Operate time 2.4.2 CONTROL 2.4.2.1 AUTORECLOSE (79) Schemes Number of shots Dead time Reclaim time Condition permission Hold time Reset time Snapshot Events Three-pole tripping schemes Up to 4 reclose attempts before lockout Independent dead time setting before each shot adjustable between 0 and 900 s in steps of 0.01 s 0.00 to 900.00 s in steps of 0.01 s Selectable by setting 0.00 to 900.00 s in steps of 0.01 s 0.00 to 900.00 s in steps of 0.01 s Selectable by setting Possibility to modify protection settings after each shot programmable through PLC (block signals available after each shot) 2-16 F650 Digital Bay Controller GEK-113000Z 2 PRODUCT DESCRIPTION 2.4.2.2 SYNCHROCHECK (25) Dead/live levels for line and bus Maximum voltage difference Maximum angle difference Maximum frequency slip Synchronism time Angle accuracy Dead Source function 2.4 TECHNICAL SPECIFICATIONS 0.00 to 300.00 in steps of 0.01 V 2.00 to 300.00 V in steps of 0.01 V 2.0º to 80.0º in steps of 0.1º 10 to 5000 mHz in steps of 10 mHz 0.01 to 600.00 s in steps of 0.01 s 3º None (DL-DB) Dead Line - Dead Bus (LL-DB) Live Line-Dead Bus (DL-LB) Dead Line – Live Bus Selectable by setting 2 Snapshot Events 2.4.2.3 FUSE FAILURE Algorithm based on positive sequence of voltage and current Activation by V2/V1 ratio 2.4.2.4 BREAKER FAILURE (50BF) Current Input Rated current Pickup level for supervision Pickup level for high level Pickup level for low level Pickup level for internal arcing Dropout level Level Accuracy Timing accuracy Snapshot Events 2.4.2.5 BROKEN CONDUCTOR (I2/I1) Pickup level Dropout level Trip delay Timing accuracy Snapshot Events Operation Threshold I2/I1 current inhibition level 20.0-100.0% (I2/I1 ratio) in steps of 0.1% 97% to 98% of the pickup level 0.00 to 900.00 s in steps of 0.01 s ±3.5% of operate time or 50 ms. (whichever is greater) Selectable by setting 0.000 to 1.000 A in steps of 0.001 A Selectable by setting from 0.000 to 1.000 in steps of 0.001 A Fundamental Phasor (without harmonics) For connection to 1 or 5 A CTs. 0.05 to 160.00 A in steps of 0.01 A 0.05 to 160.00 A in steps of 0.01 A 0.05 to 160.00 A in steps of 0.01 A 0.05 to 160.00 A in steps of 0.01 A 97% to 98% of the pickup level ±0.5% of the reading ± 10 mA from 0.05 to 10 A ±1.5% of the reading for higher values. ±3.5% of operate time or 50 ms. (whichever is greater) Selectable by setting GEK-113000Z F650 Digital Bay Controller 2-17 2.4 TECHNICAL SPECIFICATIONS 2.4.2.6 LOCKED ROTOR (48) Current Input Rated current Full Load Current Pickup level 2 PRODUCT DESCRIPTION Phasor (without harmonics) or RMS For connection to 1 or 5 A CTs. 0.10 to 10.00 kA in steps of 0.01 kA 1.01 to 109.00 in steps of 0.01 x FLC 97% to 98% of the pickup level ±3% complete range. 0.00 to 900.00 s. in steps of 0.01 s. 0.00 to 900.00 s. in steps of 0.01 s. 20 ms at 3 x Pickup at 50 Hz, typically ±3% of operate time or 50 ms. (whichever is greater) Selectable by setting 2 Dropout level Level accuracy for primary magnitudes Trip delay Reset delay Operate time Timing accuracy Snapshot Events 2.4.2.7 PULSE COUNTERS Number of Pulse counters available Multiplier factor Overload factor Board Origin Input origin 2.4.2.8 ANALOG COMPARATORS Analog Input Analog Maximum Threshold value Analog Minimum Threshold value Analog Delay Analog Hysteresis Analog Direction (for activation inside or outside the deadband) Up to 8 0.000 to 65000.000 in steps of 0.001 0 to 1000000 in steps of 1 All available input/outputs boards in the device. See ordering code [F, G, H, J] up to 32 [depending on the board type selection] Any analog value available in the device -100000.000 to 100000.000 in steps of 0.001 -100000.000 to 100000.000 in steps of 0.001 0.00 to 900.00 in steps of 0.01 0.0 to 50.00 in steps of 0.1 IN or OUT 2-18 F650 Digital Bay Controller GEK-113000Z 2 PRODUCT DESCRIPTION 2.4.2.9 FREQUENCY RATE OF CHANGE df/dt trend df/dt pickup level df/dt level accuracy Overvoltage supv. 95% settling time for df/dt Operate time: at 2 x pickup at 3 x pickup at 5 x pickup Frequency Rate min. Frequency Rate max. Frequency Rate delay Snapshot Events 2.4.2.10 LOAD ENCROACHMENT 12 cycles 8 cycles 6 cycles 2.4 TECHNICAL SPECIFICATIONS increasing, decreasing, bi-directional 0.10 to 10.00 Hz/s in steps of 0.01 80 mHz/s or 3.5%, whichever is greater 0.00 to 110.00 % in steps of 0.01 < 24 cycles 2 20.00 to 80.00 Hz in steps of 0.01 20.00 to 80.00 Hz in steps of 0.01 0.00 to 60.00 s in steps of 0.01 Selectable by setting Responds to: Minimum voltage: Reach (sec. Ω): Impedance accuracy: Angle: Angle accuracy: Pickup delay: Reset delay: Time accuracy: Operate time: Snapshot Events Positive-sequence quantities 0.00 to 300.00 V in steps of 0.01 0.02 to 250.00 Ω in steps of 0.01 ±3% 5 to 50º in steps of 1 ±3º 0.000 to 65.535 s in steps of 0.001 0.000 to 65.535 s in steps of 0.001 ±3.5% or ±60 ms, whichever is greater <60 ms at 50 Hz typically Selectable by setting 2.4.2.11 BREAKER SETTINGS Number of Switchgear Maximum KI 2t 1 to 16 (selection of switchgear for breaker control) 0.00 to 9999.99 in steps of 0.01 (kA)2 s 0.03 to 0.25 s in steps of 0.01 s 0 to 9999 in steps of 1 1 to 60 in steps of 1 Selectable by setting KI2t integration Time Maximum openings Maximum Openings in one hour Snapshot Events GEK-113000Z F650 Digital Bay Controller 2-19 2.4 TECHNICAL SPECIFICATIONS 2.4.2.12 BREAKER MAINTENANCE KI2t Breaker Counters for Phases A, B, C Breaker Openings Counter Breaker Closings Counter 0.00 to 9999.99 in steps of 0.01 (kA)2 s 0 to 9999 in steps of 1 0 to 9999 in steps of 1 2 PRODUCT DESCRIPTION 2 2.4.2.13 SWITCHGEAR Switchgear Snapshot Events 1 to16 (configurable in “relay configuration” screen). Selectable by setting (for each switchgear in “system setup”) 2.4.3 MONITORING 2.4.3.1 OSCILLOGRAPHY Maximum Records: Sampling rate: Capacity per record: Up to 20 Oscillography records. Programmable to 4, 8, 16, 32 or 64 samples per power cycle 27592 samples No of Oscillos * No of samples/cycle 5% to 95% of total length Programmable via PLC 5 current channels and 4 voltage channels Up to 16 digital channels programmable through PLC Data Storage: Format: Automatic Overwrite: Snapshot Events: In non volatile memory (flash) without battery International Standard COMTRADE ASCII - IEEE C37.111-1999. Selectable by setting. (Oscillography records can be concatenated) Selectable by setting Trigger position: Trigger: Data: 2.4.3.2 FAULT LOCATOR Method: Positive Sequence Module: Positive Sequence Angle: Zero Sequence Module: Zero Sequence Angle: Line Length: Accuracy: Show Fault on HMI: Snapshot Events: Maximum Records: Data: Single-ended 0.01 to 250.00 Ohm in steps of 0.01 Ohms 25 to 90º in steps of 1º 0.01 to 750.00 Ohms in steps of 0.01 Ohm 25 to 90º in steps of 1º 0.0 to 2000.0 in steps of 0.1 (miles or km) 5% (typical) Selectable by setting Selectable by setting Up to 10 fault report records. Fault date and time, pre-fault currents and voltages, fault currents and voltages, fault type, distance to the fault (fault location), line parameters, recloser and breaker status information. 2-20 F650 Digital Bay Controller GEK-113000Z 2 PRODUCT DESCRIPTION 2.4 TECHNICAL SPECIFICATIONS Data Storage: Format: In non volatile memory (flash) without battery available through communications In volatile memory (ram) available through HMI (if selectable by setting) Text in ASCII format 2.4.3.3 SNAPSHOT EVENTS Capacity: Time-tag Timing Accuracy: Triggers: 479 scrolling events 1 ms using an internal clock of 100 μs 1 ms (using the IRIG-B synchronization input) Any element pickup, dropout or operation Digital input /output change of state By virtual inputs and control events Data Storage In non volatile memory (flash) without battery The snapshot event recording procedure can be enabled or disabled by setting for each protection function 2 2.4.3.4 CONTROL EVENTS Capacity: Time-tag: Timing Accuracy: Triggers: Alarm 128 events programmable through PLC 1 ms plus one plc cycle using an internal clock of 100 μs. For Digital Inputs, the debounce time of these digital inputs must be added. 1 ms (using the IRIG-B synchronization input) By any digital signal programmable through PLC Possibility to display the event as an alarm on the alarms panel. Information available always through Communications for all models and also in HMI for models with graphical display (M in ordering code). In non volatile memory (flash) without battery Data Storage: Control events are also displayed in the snapshot events recording 2.4.3.5 DEMAND Channels: Parameters: Current and Power Method Measurements: Samples: Accuracy: Trigger Input Snapshot Events: 9 Ia (kA RMS), Ib (kA RMS), Ic (kA RMS), Ig (kA RMS), Isg (kA RMS), I2 (kA), P (MW), Q (MVAr) and S (MVA) Thermal Exponential, Block Interval, Rolling Demand Each channel shows the present and maximum measured value, with date and time for the maximum recorded value. 5, 10, 15, 20, 30, 60 minutes. ±2% Selectable by setting (operation mode selection for the Block Interval calculation method) Selectable by setting GEK-113000Z F650 Digital Bay Controller 2-21 2.4 TECHNICAL SPECIFICATIONS 2.4.3.6 DATA LOGGER Number of Channels: Parameters Samples Storage Capacity 1 to 16 Any available analog actual value 1 sec., 1, 5, 10, 15, 20, 30, 60 min. Fixed, 32768 measures 2 PRODUCT DESCRIPTION 2 2.4.4 USER-PROGRAMMABLE ELEMENTS 2.4.4.1 PLC LOGIC Programming language: Lines of code: Supported operations: The logical configuration is performed using graphical functions based on the IEC 61131-3 standard. 512 NOT, XOR, OR (2 to 8 inputs), AND (2 to 8 inputs), NOR (2 to 8 inputs), NAND (2 to 8 inputs), Latch (Reset Dominant), Edge Detectors, Timers. 2 inputs default gates, from 3 to 8 inputs provided in library format. Logical gates fully programmable by user. To create user-programmable logic to be distributed as a single object. Any logical variable, contact or virtual input 8 maximum in each logic scheme (provided in library format) Libraries: Inputs: Number of timers: 2.4.4.2 FLEXCURVES Number: Reset points: Operate points: Time delay: Saturation Level 4 (A through D) 40 (0 through 1 of pickup) 80 (1 through 20 of pickup) 0 to 65535 ms in steps of 1 20 times the pickup level 2.4.4.3 USER-PROGRAMMABLE LEDS Number: Programmability: Reset mode: 15 configurable LEDs plus a ready non configurable LED from any logical variable, contact, or virtual input Self-reset or Latched. The first 5 LED’s are latched by hardware (red color ones), usually configured for trip signals. The following 10 ones (yellow and green) are self-reset but can be latched through PLC configuration. The LED’s can be reset by hardware, pressing the front “esc” key during more than 3 seconds or using the LED reset signal through PLC configuration. Reset Signal: 2-22 F650 Digital Bay Controller GEK-113000Z 2 PRODUCT DESCRIPTION 2.4.4.4 USER-DEFINABLE DISPLAYS Number of configurable displays: Number of fixed displays: 2.4 TECHNICAL SPECIFICATIONS 1 (one line diagram fully configurable). In graphical displays only 6, Metering (in primary values), Snapshot events (all and new), Alarms, Inputs and outputs screen with test functionality for inputs and outputs. In graphical displays only Logotype, metering or both in scrolling mode, can be selectable as default screen in text display for all models (basic and mimic). The metering screen contains current and voltages for phases and ground in primary values. Number of selectable displays: 2 2.4.4.5 USER-PROGRAMMABLE FRONT KEYS Number of configurable Keys: Operation: 5 drive PLC operands 2.4.5 METERING 2.4.5.1 CURRENT Accuracy: (at nominal frequency) ±0.5% of the reading ± 10 mA from 0.05 to 10 A (for phases and ground) ±1.5% of the reading ± 1 mA from 0.005 to 5 A (for sensitive ground) ±1.5% of the reading for higher values ±0.5% of full-scale % of load-to-trip accuracy: 2.4.5.2 VOLTAGE Accuracy: 2.4.5.3 REAL POWER (WATTS) Accuracy: 2.4.5.4 REACTIVE POWER (VARS) Accuracy: 2.4.5.5 APPARENT POWER (VA) Accuracy: ±1% of reading from 10 to 208 V ±2.0% of the reading at -0.8 ≤ PF ≤ -1.0 and 0.8 <PF≤1.0 ±2.0% of the reading at-0.2 ≤ PF ≤ 0.2 ±2.0% of the reading 2.4.5.6 WATT-HOURS (POSITIVE AND NEGATIVE) Accuracy: Range: Parameters: Update rate: ±2.0% of the reading ±0 to 2147 MWh 3-phase only 100 ms GEK-113000Z F650 Digital Bay Controller 2-23 2.4 TECHNICAL SPECIFICATIONS 2.4.5.7 WAR-HOURS (POSITIVE AND NEGATIVE) Accuracy: Range: Parameters: Update rate: ±2.0% of the reading ±0 to 2147 MVArh 3-phase only 100 ms 2 PRODUCT DESCRIPTION 2 2.4.5.8 FREQUENCY Accuracy: 2.4.5.9 ANGLE Accuracy: ±3º +/- 0.03Hz 2.4.6 INPUTS 2.4.6.1 AC CURRENT INPUTS CT Ratio: Rated currents: Relay Burden: Current Withstand 1.0 to 6000.0 in steps of 0.1 Appropriate for 1 or 5 A. F650 has universal range for CT (valid for 1 or 5 A to only one terminal). < 0.04 Ohm Continuous at 20 A 1 second at 500 A for phases and ground 1 second at 50 A for sensitive ground 2-24 F650 Digital Bay Controller GEK-113000Z 2 PRODUCT DESCRIPTION 2.4.6.2 AC VOLTAGE INPUTS VT Ratio Rated Voltages Metering range: Relay Burden: Voltage Withstand: 1.0 to 6000.0 in steps of 0.1 275 Vac From 2 to 275 Vac 0.05 VA at 120 Vac (50 or 60 Hz) Continuous at 275 V to neutral 1 min/hr at 420 to neutral 2.4 TECHNICAL SPECIFICATIONS 2 VAC inputs do not need varistors, as the impulse test is applied to 100% of the transformers 2.4.6.3 CONTACT INPUTS Input Activation Voltage Threshold: Impedance: Maximum error: Load for voltage supervision inputs: Voltage threshold for voltage supervision inputs: Debounce Time: Recognition time: 10 to 230 Vdc in steps of 1 V (selectable by setting) > 100 kOhm ±10% setting or ± 5 V 2 mA + V/100 kOhm < 10 V (fixed) 1 to 50 in steps of 1 ms < 1ms Timing resolution: 1 ms For Input Activation Voltage Threshold and Debounce Time there is a single setting for all inputs in the same group (inputs sharing the same common). Input Type and Delay Input Time are not grouped; there is a different setting for each input. Input Type Delay Input Time Positive-Edge / Negative-Edge / Positive/ Negative 0 to 60000 ms in steps of 1 ms (Input signal time delay) 2.4.6.4 REMOTE INPUTS (IEC61850 GSSE/GOOSE) Number of input points: Number of remote devices: Default states on loss of comms: 2.4.6.5 ANALOG INPUTS 32, configured from 64 incoming bit pairs 16 On, Off, Latest/on, Latest/off Input impedance Current Input (mADC): Conversion Range: Accuracy: Type: 116Ω 0 to -1; 0 to +1; -1 to +1; 0 to 5; 0 to 10; 0 to 20; 4 to 20 (programmable) -1 to +20mA ±0.2% of full scale Passive GEK-113000Z F650 Digital Bay Controller 2-25 2.4 TECHNICAL SPECIFICATIONS 2.4.6.6 IRIG-B INPUT Amplitude modulation: Input Voltage: Input Burden: Input Impedance: DC SHIFT = Demodulated input (no carrier) TTL 1.5 mA 3.3 kOhm 2.4 V ± 24 V 2 PRODUCT DESCRIPTION 2 Minimum Input Voltage: Maximum Input Voltage: Formats: Isolation: B000 (*) B001, B002 and B003 (*) (*) Signal combinations recognized in accordance with IRIG Standard 200-95 2 kV 2.4.7 REAL TIME CLOCK Accuracy: Backup energy: Typical ±20 ppm More than 1 week 2.4.8 OUTPUTS Single Contact Carry continuous: Make and Carry for 1 sec. Break at L/R of 40 ms: Operate Time: Contact material: 16 A 60 A 0.3 A DC max. at 125 Vdc 0.25 A DC max. at 250 Vdc < 8 ms Silver Alloy Output Logic Type, Output Type and Pulse Output Time are selectable by setting for each output Output Logic Type Output Type Pulse Output Time Positive / Negative Normal / Pulse / Latch (Selectable by setting for each output) 0 to 60000 ms in steps of 1 ms (applicable only to signals set as pulse type) Separate operate and reset signal can be configured by any digital signal programmable through PLC Contact Outputs (F31-F33, F34-F36) for The current seal-in circuit is used for verifying the current condition in a circuit board type 2 (supervision) in slot F: during the time that the tripping contact remains closed. If the current in the tripping circuit is maintained over 500 mA, the function is sealed independently of the status of the function that caused the trip. 2.4.8.1 REMOTE OUTPUTS (IEC61850 GSSE/GOOSE) Standard output points User output points 32 32 2-26 F650 Digital Bay Controller GEK-113000Z 2 PRODUCT DESCRIPTION 2.4 TECHNICAL SPECIFICATIONS 2.4.9 CONTROL POWER SUPPLY LOW RANGE (LO) Nominal DC Voltage: Min/Max DC Voltage Note: HIGH RANGE (HI) Nominal DC Voltage: Min/Max DC Voltage Nominal AC Voltage: Min/Max AC Voltage ALL RANGES Voltage Loss hold-up time 200 ms typical, worst case 100 ms without unit reset Power consumption Typical =25 VA, Maximum =45 VA Display backlight auto power-off mode after 15 minutes without touching any key, in order to ensure long life and minimum consumption. 110 to 250 V 88 / 300 V 120 to 230 V 102 / 250 V 24 to 48 V 19.2 / 57.6 V Low range is DC only 2 2.4.10 COMMUNICATIONS FRONT PORT: Front port: Type Baud Rate Default Baud Rate Protocols available: Typical distance: Isolation: ASYNCHRONOUS REAR PORTS: None or two rear ports (depending on model): Type (depending on model): Model F Model A Model X Model P Model Y Model G Model Z Model C Model M Optic Features for ST connectors devices: Baud Rate: Default Baud Rate None Redundant RS485 Redundant RS485 + fiber CAN for inputs/outputs module Redundant 1mm-plastic F.O. Redundant 1mm-plastic F.O. + fiber CAN for inputs/outputs module Redundant multimode glass F.O. Redundant multimode glass F.O. + fiber CAN for inputs/outputs module Cable CAN port for I/O module Cable CAN port for I/O module (cable) + RS485 (ModBus RTU) Wave length: 1300nm Fiber type: multimode 62.5/125 μm or 50/125 μm 300, 600, 1200, 2400, 4800, 9600, 19200, 38400, 57600 y 115200 bauds 19200 COM1, COM2 (rear COM2 multiplexed with front port) COM2 RS232/USB 300, 600, 1200, 2400, 4800, 9600, 19200, 38400, 57600 y 115200 bauds 19200 ModBus® RTU / DNP 3.0 3m 2 kV GEK-113000Z F650 Digital Bay Controller 2-27 2.4 TECHNICAL SPECIFICATIONS ModBus® RTU / DNP 3.0/IEC103 2 PRODUCT DESCRIPTION Protocols available: Typical distance: Isolation: CAN PORT: Rear port: 1200 m for cooper cable, 1000 m for glass fiber and 50 m for plastic fiber 2 kV CAN port in models C, M, X, Y, Z for asynchronous rear ports Multimode glass F.O. port with ST connectors 820 nm multimode 62.5/125 μm or 50/125 μm 300m for cooper cable and glass fiber 2 kV COM3 10/100BaseTX self-negotiable 10/100BaseTX + 100Base FX 10/100BaseTX + redundant 100BaseFX (Physical media redundancy) Redundant 10/100BaseTX self-negotiable ports RJ45 connector ST connectors 1300 nm multimode 62.5/125 μm or 50/125 μm ModBus® TCP/IP DNP over TCP/IP and UDP/IP IEC 61850 Http, ftp, tftp (allow the use of a standard Internet browser) 2 Type: Fiber Wave length: Fiber type: Maximum recommended length Isolation: ETHERNET PORT: Rear port: Type (depending on model): Model B: Model C: Model D: Model E: 10/100BaseTX 100BaseFX Wave length: Fiber type: Protocols available: Typical distance: Response time to ModBus commands: Isolation: 1000 m for glass fiber and 300 m for RJ45 cable 10 ms Typical 2 kV In Models C and D, the 10/100BaseTX port is selected by an internal switch (see 3.3.3) Two witness LED’s for transmission and reception are included 2-28 F650 Digital Bay Controller GEK-113000Z 2 PRODUCT DESCRIPTION 2.4 TECHNICAL SPECIFICATIONS 2.4.11 OPTIC FEATURES Wave length: 1300nm Connector types: ST package style Fiber type: multimode 62.5/125 μm or 50/125 μm TRANSMITTER CHARACTERISTICS Parameter Output Optical Power 62.5/125 μm, NA = 0.275 Fiber Output Optical Power 50/125 μm, NA = 0.275 Fiber Output Optical Power at Logic “0” State RECEIVER CHARACTERISTICS Parameter Input Optical Power Minimum at Window Edge Input Optical Power Minimum at Eye Center Input Optical Power Maximum -14 Min. Typ. -33.9 -35.2 Max. -31 -31.8 Unit dBm avg. dBm avg. dBm avg. Reference Note 3 Note 4 Note 3 BOL EOL BOL EOL Min. -19 -20 -22.5 -23.5 Typ. Max. -14 -14 -45 Unit dBm avg. dBm avg. dBm avg. Reference Note 1 Note 1 Note 2 2 Notes: 1. These optical power values are measured with the following conditions: The Beginning of Live (BOL) to the End of Life (EOL) optical power degradation is typically 1.5 dB per industry convention for long wavelength LEDs. The actual degradation observed in Agilent’s 1300nm LED products is <1 dB, as specified in this data sheet. Over the specified operating voltage and temperature ranges. With HALT Line State, (12.5 MHz square-wave), input signal. At the end of one meter of noted optical fiber with cladding modes removed. The average power value can be converted to a peak power value by adding 3 dB. Higher output optical power transmitters are available on special request. 2. The transmitter provides compliance with the need for Transmit_Disable commands from the FDDI SMT layer by providing an Output Optical Power level of <-45 dBm average in response to a logic “0” input. This specification applies to either 62.5/125 μm or 50/125 μm fiber cables. This specification is intended to indicate the performance of the receiver section of the transceiver when Input Optical Power signal characteristics are present per the following definitions. The Input Optical Power dynamic range from the minimum level (with a window time-width) to the maximum level is the range over which the receiver is guaranteed to provide output data with a Bit Error Ratio (BER) better than or equal to 2.5e-10. At the Beginning of Life (BOL). Over the specified operating temperature and voltage ranges. 4. All conditions for Note 3 apply except that the measurement is made at the center of the symbol with no window timewidth. 3. GEK-113000Z F650 Digital Bay Controller 2-29 2.4 TECHNICAL SPECIFICATIONS 2 PRODUCT DESCRIPTION 2.4.12 ENVIRONMENTAL CHARACTERISTICS Operating temperature: Storage temperature: Humidity (non condensing): - 10°C to + 60°C - 40°C to + 80°C 95% Up to 2000 m II 2 Altitude Installation category 2.4.13 PACKAGING AND WEIGHT Net weight: Packaged: Package dimensions: 5 kg 6 kg 30x40x40 cm (DxWxH) 2.4.14 TYPE TESTS CATEGORY EMC STANDARD IEC 61000-4-1 IEC 60255-22-1 IEC 61000-4-2 IEC 60255-22-2 IEC 61000-4-3 IEC 60255-22-3 IEC 61000-4-4 IEC 60255-22-4 IEC 61000-4-5 IEC 60255-22-5 IEC 61000-4-6 IEC 60255-22-6 IEC 61000-4-8 EN 61000-4-8 ENV50204 CLASS III IV III IV IV III IV III A 2 kV 6kV .5J 100 ms I I II TEST Oscillatory waves immunity Electrostatic discharge immunity test Radiated electromagnetic field disturbance test Electrical fast transient Surge immunity test Conducted electromagnetic field disturbance test Power frequency magnetic field immunity Radiated electromagnetic field disturbance test – 1890 MHz. Conducted and radiated emissions Insulation resistance – dielectric test Impulse test Power supply Voltage dips/interruptions/variations: Vibration test (sinusoidal) Shock and bump Seismic EMC Emisivity Product IEC 60255-25 EN 61000-6-4 IEC 60255-5 IEC 60255-5 IEC 60255-11 Mechanical IEC 60255-21-1 IEC 60255-21-2 IEC 60255-21-3 Type test report available upon request. F650 has been designed to comply with the highest existing requirements. More specifically, UNIPEDE recommendations for high voltage substations are followed, even if for most applications such high classes are not required. The relay complies with ANSI C37.90 standards, and has been designed to comply with international standards. 2.4.15 APPROVALS ISO9001 Registered system. CE marking: Meets the CE standards relevant for protections. UL 508 Certified 2-30 F650 Digital Bay Controller GEK-113000Z 2 PRODUCT DESCRIPTION 2.5EXTERNAL CONNECTIONS 2.5 EXTERNAL CONNECTIONS 2 Figure 2–2: F650 WIRING DIAGRAM (189C4216H2) GEK-113000Z F650 Digital Bay Controller 2-31 2.5 EXTERNAL CONNECTIONS INPUTS / OUTPUTS CONFIGURATION FOR BOARDS F1 AND F2 SLOT F CONFIGURATION (BOARD TYPE 1) INPUTS F1 F1 + CC1 52b F2 + CC2 50P BLOCK F3 + CC3 51P BLOCK F4 + CC4 67P BLOCK F5 + CC5 50G BLOCK F6 + CC6 51G BLOCK F7 + CC7 79 INITIATE F8 + CC8 79 BLOCK F9 - COMMON 1/8 COMMON 1/8 F10 - COMMON 9/16 COMMON 9/16 F11 + CC9 NOT USED F12 + CC10 NOT USED F13 + CC11 NOT USED F14 + CC12 NOT USED F15 + CC13 NOT USED F16 + CC14 NOT USED F17 + CC15 NOT USED F18 + CC16 NOT USED USER CONFIGURABLE INPUTS 2 PRODUCT DESCRIPTION O1 USER CONFIGURABLE OUTPUTS 2 O2 O3 O4 O5 O6 O7 O8 OUTPUTS F1 F19 F20 79 BLOCK F21 F22 F23 27/59 PICKUP F24 F25 50/67G PICKUP F26 F27 51/67G PICKUP F28 F29 50/67P PICKUP F30 F31 51/67P PICKUP F32 F33 RECLOSE F34 F35 TRIP F36 SLOT F CONFIGURATION (BOARD TYPE 2) INPUTS F2 F1 + COIL 1 52/a SUPERVISION F2 52/a F3 + COIL 1 52/b SUPERVISION F4 52/b 52b F5 + CC1 50P BLOCK F6 + CC2 51P BLOCK F7 + CC3 67P BLOCK F8 + CC4 F9 - COMMON 1/4 COMMON 1/4 F10 - COMMON 5/8 COMMON 5/8 50G BLOCK F11 + CC5 51G BLOCK F12 + CC6 79 INITIATE F13 + CC7 79 BLOCK F14 + CC8 F15 + COIL 2 52/a SUPERVISION F16 52/a F17 + COIL 2 52/b SUPERVISION F18 52/b V V V V OUTPUTS F2 F19 O1 79 BLOCK F20 F21 O2 27/59 PICKUP F22 F23 O3 50/67G PICKUP F24 F25 O4 51/67G PICKUP F26 F27 50/67P PICKUP O5 F28 F29 51/67P PICKUP O6 F30 F31 I SENS F32 RECLOSE O7 F33 I SENS F34 F35 TRIP O8 F36 I I COIL 1 Figure 2–3: INPUT/OUTPUT CONFIGURATIONS FOR BOARDS F1 AND F2 (189C4216H1) 2-32 F650 Digital Bay Controller COIL 2 USER CONFIGURABLE OUTPUTS USER CONFIGURABLE INPUTS GEK-113000Z 3 HUMAN INTERFACES. SETTINGS & ACTUAL VALUES 3.1 ENERVISTA 650 SETUP SOFTWARE INTERFACE 3 HUMAN INTERFACES.
Relay GE Multilin f650 - Download as PDF File (.pdf), Text file (.txt) or read online.
Digital Bay Controller
Ge F650 Relay Manual Override
GE Multilin F650 Digital Bay Controller 1 TABLE OF CONTENTS 1. GETTING STARTED 1.1 IMPORTANT PROCEDURES 1.1.1 CAUTIONS AND WARNINGS.
RELAY 469-P5-HI-A20-E w/ manual. The G650 is a Distributed Generation Protection and Control Relay designed for The F60 includes GE Multilin's unique high.