Siemens Solkor 7PG2113 Technical Manual
Siemens Solkor 7PG2113 Technical Manual

Siemens Solkor 7PG2113 Technical Manual

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Summary of Contents for Siemens Solkor 7PG2113

  • Page 1 Reyrolle Protection Devices 7PG2113/4/5/6 Solkor Feeder Protection Answers for energy...
  • Page 2 Limited. No part of this document shall be reproduced or modified or stored in another form, in any data retrieval system, without the permission of Siemens Protection Devices Limited, nor shall any model or article be reproduced from this document unless Siemens Protection Devices Limited consent.
  • Page 3: Description Of Operation

    Limited. No part of this document shall be reproduced or modified or stored in another form, in any data retrieval system, without the permission of Siemens Protection Devices Limited, nor shall any model or article be reproduced from this document unless Siemens Protection Devices Limited consent.
  • Page 4: Table Of Contents

    Autoreclose Prot’n Menu......................61 5.1.4 Autoreclose Config Menu......................61 5.1.5 P/F Shots sub-menu ....................... 63 5.1.6 E/F Shots sub-menu ....................... 63 5.1.7 SEF Shots sub-menu ......................63 5.1.8 Extern Shots sub-menu......................64 ©2010 Siemens Protection Devices Limited Chapter 1 Page 2 of 80...
  • Page 5 7.7 Real Time Clock............................ 80 7.7.1 Time Synchronisation – Data Communication Interface ............80 7.7.2 Time Synchronisation – Binary Input ..................80 7.8 Settings Groups ............................ 80 7.9 Password Feature ..........................80 ©2010 Siemens Protection Devices Limited Chapter 1 Page 3 of 80...
  • Page 6 Figure 4.7-3 Logic Diagram: Thermal Overload Protection (49S) ................54 Figure 4.8-1 Logic Diagram: Under/Over Voltage Elements (27/59)..............55 Figure 4.9-1 Logic Diagram: NPS Overvoltage Protection (47)................56 Figure 4.10-1 Logic Diagram: Neutral Overvoltage Element (59N)................ 57 ©2010 Siemens Protection Devices Limited Chapter 1 Page 4 of 80...
  • Page 7 The following notational and formatting conventions are used within the remainder of this document: • Setting Menu Location MAIN MENU>SUB-MENU • Setting: Elem name -Setting • Setting value: value • Alternatives: [1st] [2nd] [3rd] ©2010 Siemens Protection Devices Limited Chapter 1 Page 5 of 80...
  • Page 8: Section 1: Introduction

    1.1.3 Front Cover The front cover provides additional securing of the relay element within the case. The relay cover should be in place during normal operating conditions. ©2010 Siemens Protection Devices Limited Chapter 1 Page 6 of 80...
  • Page 9: Table 1-1 7Pg2113/5 Ordering Options

    Inrush Restraint Programmable logic Standard version - plus Autoreclose Solkor Mode Solkor Rf Solkor R Spare Default mode when supplied, relay mode is easily changed later my internal links ©2010 Siemens Protection Devices Limited Chapter 1 Page 7 of 80...
  • Page 10: Figure 1.1-1 Functional Diagram Of 7Pg2113/5 Relay With Autoreclose

    7PG2113/4/5/6 Solkor Description of Operation Figure 1.1-1 Functional Diagram of 7PG2113/5 Relay with Autoreclose ©2010 Siemens Protection Devices Limited Chapter 1 Page 8 of 80...
  • Page 11: Figure 1.1-2 Connections Diagram For 7Pg2113 Relay

    7PG2113/4/5/6 Solkor Description of Operation Figure 1.1-2 Connections Diagram for 7PG2113 Relay ©2010 Siemens Protection Devices Limited Chapter 1 Page 9 of 80...
  • Page 12: Figure 1.1-3 Connections Diagram For 7Pg2115 Relay

    7PG2113/4/5/6 Solkor Description of Operation Figure 1.1-3 Connections Diagram for 7PG2115 Relay ©2010 Siemens Protection Devices Limited Chapter 1 Page 10 of 80...
  • Page 13: Table 1-2 7Pg2114/6 Ordering Options

    Inrush Restraint Programmable logic Standard version - plus Autoreclose Solkor Mode Solkor Rf Solkor R Spare Default mode when supplied, relay mode is easily changed later by internal links ©2010 Siemens Protection Devices Limited Chapter 1 Page 11 of 80...
  • Page 14: Figure 1.1-4 Functional Diagram Of 7Pg2114/6 Relay With Autoreclose

    (x4) (x4) (x4) (x4) (x4) (x4) (x2) (x4) (x3) (x3) NOTE: The use of some functions (x4) are mutually exclusive Figure 1.1-4 Functional Diagram of 7PG2114/6 Relay with Autoreclose ©2010 Siemens Protection Devices Limited Chapter 1 Page 12 of 80...
  • Page 15: Figure 1.1-5 Connections Diagram For 7Pg2114 Relay

    7PG2113/4/5/6 Solkor Description of Operation Figure 1.1-5 Connections Diagram for 7PG2114 Relay ©2010 Siemens Protection Devices Limited Chapter 1 Page 13 of 80...
  • Page 16: Figure 1.1-6 Connections Diagram For 7Pg2116 Relay

    7PG2113/4/5/6 Solkor Description of Operation Figure 1.1-6 Connections Diagram for 7PG2116 Relay ©2010 Siemens Protection Devices Limited Chapter 1 Page 14 of 80...
  • Page 17: Section 2: Hardware Description

    3 x Voltage (7PG2114) 3 x Voltage + 3 x Binary Input and 3 x Binary Output Module. (7PG2116) 5) Power Supply and 3 x Binary Input (BI) and RS485. ©2010 Siemens Protection Devices Limited Chapter 1 Page 15 of 80...
  • Page 18: Case

    Located at the top rear of the case is a screw clamp earthing point, this must be connected to terminal B28 and directly to the main panel earth. This connection point is indicated by the following symbol. Figure 2.2-3 Earth Symbol ©2010 Siemens Protection Devices Limited Chapter 1 Page 16 of 80...
  • Page 19: Front Cover

    Links are provided to allow setting of pilot padding resistance and test points are provided to allow operating spill current to be measured. Figure 2.5-1 Relay with Transparent cover removed ©2010 Siemens Protection Devices Limited Chapter 1 Page 17 of 80...
  • Page 20: Figure 2.5-2 Close Up Of Typical Relay Labels

    2) Purpose inscription label marked ‘Solkor’. Figure 2.5-2 Close up of typical relay labels A ‘template’ is available in Reydisp Software to allow users to create and print customised purpose inscription labels. ©2010 Siemens Protection Devices Limited Chapter 1 Page 18 of 80...
  • Page 21: Figure 2.5-3 Close Up Of Relay Identifier

    Reydisp to identify the relay. Pressing the Cancel button several times will always return the user to this screen. Figure 2.5-3 Close up of Relay Identifier ©2010 Siemens Protection Devices Limited Chapter 1 Page 19 of 80...
  • Page 22 The status of hand reset LEDs is maintained by a back up storage capacitor in the event of an interruption to the d.c. supply voltage. ©2010 Siemens Protection Devices Limited Chapter 1 Page 20 of 80...
  • Page 23: Current Inputs

    Voltage is sampled at 1600Hz for both 50Hz and 60Hz system frequencies. Protection and monitoring functions of the relay use fundamental frequency voltage measurement. The waveform recorder samples and displays voltage input waveforms at 1600Hz. ©2010 Siemens Protection Devices Limited Chapter 1 Page 21 of 80...
  • Page 24: Binary Inputs

    It is recommended that the trip signal to the circuit breaker is wired directly from the Solkor R/Rf module rather than via the numeric module for maximum speed and simplicity. ©2010 Siemens Protection Devices Limited Chapter 1 Page 22 of 80...
  • Page 25: Figure 2.9-1 Binary Output Logic

    On loss of the auxiliary supply hand-reset outputs will reset. When the auxiliary supply is re-established the binary output will remain in the reset state unless the initiating condition is still present. Binary Output Test Figure 2.9-1 Binary Output Logic ©2010 Siemens Protection Devices Limited Chapter 1 Page 23 of 80...
  • Page 26: Virtual Input/Outputs

    If the relay is withdrawn from the case, the case shorting contact will make across the normally closed contacts to provide and external alarm. ©2010 Siemens Protection Devices Limited Chapter 1 Page 24 of 80...
  • Page 27: Section 3: Current Differential Protection Function

    ) ohms, where R is the pilot resistance. The 500 ohm resistor should therefore never be fitted for the Solkor R and the link will always be fitted for this mode. ©2010 Siemens Protection Devices Limited Chapter 1 Page 25 of 80...
  • Page 28: Figure 3.1-3 Solkor Rf 15Kv Schematic

    ©2010 Siemens Protection Devices Limited Chapter 1 Page 26 of 80...
  • Page 29: Operation

    Thus the circuit may be redrawn to suit the polarities of summation transformer output as shown in Figure 3.2-1 & Figure 3.2-2 below. ©2010 Siemens Protection Devices Limited Chapter 1 Page 27 of 80...
  • Page 30: Figure 3.2-1 Through Fault, Zero Ohm Pilots, Positive Half Cycle

    This voltage bias must be overcome before operation can take place; consequently the effect is to enhance the stability of the protection against through faults. ©2010 Siemens Protection Devices Limited Chapter 1 Page 28 of 80...
  • Page 31: Figure 3.2-3 Through Fault, 1000 Ohm Pilots, Positive Half Cycle

    3.2-3 & Figure 3.2-4. with 500 ohms in each leg of the pilot circuit and zero padding resistors. As shown in Figure 3.2-3 & Figure 3.2-4 the resultant voltage distribution of this maximum pilot arrangement gives identical voltages across the relay points B-X and C-Y. ©2010 Siemens Protection Devices Limited Chapter 1 Page 29 of 80...
  • Page 32: Figure 3.2-5 Through Fault Rf Mode, Positive Half Cycle

    Solkor R arrangement. In other words, the balance of the full wave comparison gives the same value of bias for each polarity of half-cycle ©2010 Siemens Protection Devices Limited Chapter 1 Page 30 of 80...
  • Page 33: Figure 3.2-7 Through Fault Rf Mode, Positive Half Cycle

    Figure 3.2-7 & Figure 3.2-8. This shows that the same bias voltages are as obtained in Figure 3.2-5 & Figure 3.2-6 ©2010 Siemens Protection Devices Limited Chapter 1 Page 31 of 80...
  • Page 34: Figure 3.2-9 Internal Fault Rf Mode, Positive Half Cycle

    However, both ends operate at this level (which is the normal setting claim) so that the intertripping is not required for internal faults even those which may be fed from one end or have low infeed at one end ©2010 Siemens Protection Devices Limited Chapter 1 Page 32 of 80...
  • Page 35: Figure 3.2-11 Single End Fed Fault Rf Mode, Positive Half Cycle

    D4 on one half-cycle and D8 on the other half-cycle. ©2010 Siemens Protection Devices Limited Chapter 1 Page 33 of 80...
  • Page 36: Theory Of Summation Transformer

    = Ix. (n+1) I(nx) = Ix. (n) I(x) = Ix. (1) I(x) = Ix. (1) I(2x) = Ix. (2) I(√3x) = Ix. (√3) √3 Summation Transformer Output Table 3-1 ©2010 Siemens Protection Devices Limited Chapter 1 Page 34 of 80...
  • Page 37: Section 4: Numeric Protection Module Functions

    I are detected as forward flowing currents and I is detected as reverse current flow, phases L and L will operate forwards, while phase L will be inhibited. ©2010 Siemens Protection Devices Limited Chapter 1 Page 35 of 80...
  • Page 38: Figure 4.1-1 Logic Diagram: Directional Overcurrent Element (67)

    This prevents mal-operation under fuse failure/MCB tripped conditions where noise voltages can be present. Figure 4.1-1 Logic Diagram: Directional Overcurrent Element (67) ©2010 Siemens Protection Devices Limited Chapter 1 Page 36 of 80...
  • Page 39: Instantaneous Overcurrent Protection (50)

    Operation of the inrush current detector function. 50-n Inrush Action: Block Operation of the VT Supervision function (7PG2114/6). 50-n VTS Action: Inhibit Figure 4.1-2 Logic Diagram: Instantaneous Over-current Element ©2010 Siemens Protection Devices Limited Chapter 1 Page 37 of 80...
  • Page 40: Time Delayed Overcurrent Protection (51)

    (79 P/F Prot’n Trip n = Delayed). Activation of the cold load settings. Operation of the inrush current detector function. 51-n Inrush Action: Block Operation of the VT Supervision function (7PG2114/6). 51-n VTSAction: Inhibit ©2010 Siemens Protection Devices Limited Chapter 1 Page 38 of 80...
  • Page 41: Figure 4.1-3 Logic Diagram: Time Delayed Overcurrent Element

    L1 Dir En & IL2 Fwd & & IL2 Rev L2 Dir En & IL3 Fwd & & IL3 Rev L3 Dir En Figure 4.1-3 Logic Diagram: Time Delayed Overcurrent Element ©2010 Siemens Protection Devices Limited Chapter 1 Page 39 of 80...
  • Page 42: Current Protection: Voltage Controlled Overcurrent (51V) - 7Pg2114/6

    Control Voltage The Voltage Controlled Overcurrent function (51V) can be inhibited from: Operation of the VT Supervision function. VCO VTSAction: Inhibit Figure 4.1-4 Logic Diagram: Voltage Controlled Overcurrent Protection ©2010 Siemens Protection Devices Limited Chapter 1 Page 40 of 80...
  • Page 43: Current Protection: Derived Earth Fault (67N, 51N, 50N)

    For fault current of -15° (I lagging V by 15°) a 67N Char Angle of -15° is required for maximum sensitivity. For fault current of -45° (I lagging V by 45°) a 67 Char Angle of -45° is required for maximum sensitivity. ©2010 Siemens Protection Devices Limited Chapter 1 Page 41 of 80...
  • Page 44: Instantaneous Derived Earth Fault Protection (50N)

    79 E/F Inst Trips: 50N-n (79 E/F Prot’n Trip n = Delayed). Operation of the inrush current detector function. 50-n Inrush Action: Block Operation of the VT Supervision function (7PG2114/6). 50N-n VTSAction: Inhibit ©2010 Siemens Protection Devices Limited Chapter 1 Page 42 of 80...
  • Page 45: Time Delayed Derived Earth Fault Protection (51N)

    79 E/F Inst Trips: 51N-n (79 E/F Prot’n Trip n = Delayed). Operation of the inrush current detector function. 50-n Inrush Action: Block Operation of the VT Supervision function (7PG2114/6). 51N-n VTSAction: Inhibit ©2010 Siemens Protection Devices Limited Chapter 1 Page 43 of 80...
  • Page 46: Figure 4.2-3 Logic Diagram: Derived Time Delayed Earth Fault Protection

    7PG2113/4/5/6 Solkor Description of Operation Figure 4.2-3 Logic Diagram: Derived Time Delayed Earth Fault Protection ©2010 Siemens Protection Devices Limited Chapter 1 Page 44 of 80...
  • Page 47: Current Protection: Measured Earth Fault (67G, 51G, 50G)

    Operation of protection elements set as directional will be inhibited. This prevents mal-operation under fuse failure/MCB tripped conditions where noise voltages can be present. Figure 4.3-1 Logic Diagram: Measured Directional Earth Fault Protection ©2010 Siemens Protection Devices Limited Chapter 1 Page 45 of 80...
  • Page 48: Instantaneous Measured Earth Fault Protection (50G)

    Operation of the inrush current detector function. 50-n Inrush Action: Block Operation of the VT Supervision function (7PG2114/6). 50G-n VTSAction: Inhibit Figure 4.3-2 Logic Diagram: Measured Instantaneous Earth-fault Element ©2010 Siemens Protection Devices Limited Chapter 1 Page 46 of 80...
  • Page 49: Time Delayed Measured Earth Fault Protection (51G)

    79 E/F Inst Trips: 51G-n (79 E/F Prot’n Trip n = Delayed). Operation of the inrush current detector function. 50-n Inrush Action: Block Operation of the VT Supervision function (7PG2114/6). 51G-n VTSAction: Inhibit ©2010 Siemens Protection Devices Limited Chapter 1 Page 47 of 80...
  • Page 50: Figure 4.3-3 Logic Diagram: Measured Time Delayed Earth Fault Element (51G)

    7PG2113/4/5/6 Solkor Description of Operation Figure 4.3-3 Logic Diagram: Measured Time Delayed Earth Fault Element (51G) ©2010 Siemens Protection Devices Limited Chapter 1 Page 48 of 80...
  • Page 51: Current Protection: High Impedance Restricted Earth Fault - (64H)

    ‘Applications Guide’ for advice in specifying suitable component values. Operation of the high impedance element can be inhibited from: A binary or virtual input. Inhibit 64H Figure 4.4-1 Logic Diagram: High Impedance REF (64H) ©2010 Siemens Protection Devices Limited Chapter 1 Page 49 of 80...
  • Page 52: Current Protection: Cold Load (51C)

    < Pickup General Pickup L1 Dir En trip < Pickup L2 Dir En trip < Pickup 51-n L3 Dir En trip Figure 4.5-1 Logic Diagram: Cold Load Settings (51c) ©2010 Siemens Protection Devices Limited Chapter 1 Page 50 of 80...
  • Page 53: Current Protection: Negative Phase Sequence Overcurrent - (46Nps)

    Operation of the negative phase sequence overcurrent elements can be inhibited from: A binary or virtual input. Inhibit 46IT A binary or virtual input. Inhibit 46DT Figure 4.6-1 Logic Diagram: Negative Phase Sequence Overcurrent (46NPS) ©2010 Siemens Protection Devices Limited Chapter 1 Page 51 of 80...
  • Page 54: Current Protection: Under-Current (37)

    Inhibit 37-n & < < < Figure 4.7-1 Logic Diagram: Relays with 4 Current Inputs Undercurrent Detector (37) Figure 4.7-2 Logic Diagram: Relays with 1 Current Inputs Undercurrent Detector (37) ©2010 Siemens Protection Devices Limited Chapter 1 Page 52 of 80...
  • Page 55: Current Protection: Thermal Overload (49)

    IEC255-8 thermal operating characteristics. It is the value of current above which 100% of thermal capacity will be reached after a period of time and it is therefore normally set slightly above the full load current of the protected device. ©2010 Siemens Protection Devices Limited Chapter 1 Page 53 of 80...
  • Page 56: Figure 4.7-3 Logic Diagram: Thermal Overload Protection (49S)

    Enabled 49 Capacity Alarm Disabled & Inhibit 49 cap alarm trip 49 Alarm cap alarm trip 49 Trip cap alarm trip Figure 4.7-3 Logic Diagram: Thermal Overload Protection (49S) ©2010 Siemens Protection Devices Limited Chapter 1 Page 54 of 80...
  • Page 57: Voltage Protection: Phase Under/Over Voltage (27/59) - 7Pg2114/6

    A binary or virtual input. Inhibit 27/59-n Operation of the VT Supervision function (7PG2115/6). 27/59-n VTSInhibit: Yes Under voltage guard element. 27/59-n U/V Guarded Figure 4.8-1 Logic Diagram: Under/Over Voltage Elements (27/59) ©2010 Siemens Protection Devices Limited Chapter 1 Page 55 of 80...
  • Page 58: Voltage Protection: Negative Phase Sequence Overvoltage (47) - 7Pg2114/6

    A binary or virtual input. Inhibit 47-n 47-n Element Enabled Disabled 47-n Setting General Pickup & 47-n Hysteresis Inhibit 47-n 47-n Delay > 47-n Filter Figure 4.9-1 Logic Diagram: NPS Overvoltage Protection (47) ©2010 Siemens Protection Devices Limited Chapter 1 Page 56 of 80...
  • Page 59: Voltage Protection: Neutral Overvoltage (59N) - 7Pg2114/6

    5-limb VT or 3 single phase VTs. The VT primary winding neutral must be earthed to allow the flow of zero sequence current. Figure 4.10-1 Logic Diagram: Neutral Overvoltage Element (59N) ©2010 Siemens Protection Devices Limited Chapter 1 Page 57 of 80...
  • Page 60: Section 5: Control & Logic Functions

    Successful Close output issued. A single, common Reclaim time is used (Reclaim Timer). When an auto-reclose sequence does not result in a successful reclosure the relay goes to the lockout state. ©2010 Siemens Protection Devices Limited Chapter 1 Page 58 of 80...
  • Page 61 Manual Close CB 79 Successful AR 79 Lockout 79 Close Onto Fault 79 CB Fail to Close 79 Trip & Reclose 79 Trip & Lockout 79 Block External Successful Manual Close ©2010 Siemens Protection Devices Limited Chapter 1 Page 59 of 80...
  • Page 62: Auto Reclose Sequences

    The dead time is initiated when the trip output contact reset, the pickup is reset and the CB is open. The CB close output relay is energised after the dead time has elapsed. Figure 5.1-1 Typical AR Sequence with 3 Inst and 1 Delayed trip ©2010 Siemens Protection Devices Limited Chapter 1 Page 60 of 80...
  • Page 63: Autoreclose Prot'n Menu

    A protection operates during the final Reclaim time. • If a Close Pulse is given and the CB fails to close. • The 79 Lockout binary input is active. ©2010 Siemens Protection Devices Limited Chapter 1 Page 61 of 80...
  • Page 64 By the CB Closed binary input, provided there is no signal present which will cause Lockout. The Lockout condition has a delayed drop-off of 2s. The Lockout condition can not be reset if there is an active lockout input. ©2010 Siemens Protection Devices Limited Chapter 1 Page 62 of 80...
  • Page 65: P/F Shots Sub-Menu

    As above but E/F settings. 5.1.7 SEF Shots sub-menu This menu allows the Sensitive Earth trip/reclose sequence to be parameterized:- As above but SEF Settings, Note: - SEF does not have HighSets ©2010 Siemens Protection Devices Limited Chapter 1 Page 63 of 80...
  • Page 66: Extern Shots Sub-Menu

    External AutoReclose sequence can be applied for this purpose. By setting-up internal Quick Logic equation(s) the user can define and set what should occur when any one of these other elements operates. ©2010 Siemens Protection Devices Limited Chapter 1 Page 64 of 80...
  • Page 67: Figure 5.1-2 Basic Auto-Reclose Sequence Diagram

    7PG2113/4/5/6 Solkor Description of Operation Figure 5.1-2 Basic Auto-Reclose Sequence Diagram ©2010 Siemens Protection Devices Limited Chapter 1 Page 65 of 80...
  • Page 68: Manual Close

    The relay goes to the Lockout state if the CB is open at the end of the reclaim time or a protection operates during the final reclaim time. ©2010 Siemens Protection Devices Limited Chapter 1 Page 66 of 80...
  • Page 69: Figure 5.3-1 Logic Diagram: Circuit Breaker Status

    Hot Line In/Out When ‘Hot Line’ is enabled all auto reclose sequences are inhibited and any fault causes an instantaneous trip to lockout. Figure 5.3-1 Logic Diagram: Circuit Breaker Status ©2010 Siemens Protection Devices Limited Chapter 1 Page 67 of 80...
  • Page 70: Quick Logic

    En Counter Reset Mode = Multi Shot: The En Counter Reset Time is started each time the counter is incremented. Where En Counter Reset Time elapses without further count increments the count value is reset to zero. ©2010 Siemens Protection Devices Limited Chapter 1 Page 68 of 80...
  • Page 71: Figure 5.4-1 Sequence Diagram: Quick Logic Pu/Do Timers (Counter Reset Mode Off)

    Protection functions can be used in Quick Logic by mapping them to a Virtual Input / Output. Refer to Section 7 – Applications Guide for examples of Logic schemes. ©2010 Siemens Protection Devices Limited Chapter 1 Page 69 of 80...
  • Page 72: Section 6: Supervision Functions

    50BF-n Delay will be by-passed and the output given immediately. Operation of the CB Fail elements can be inhibited from: A binary or virtual input. Inhibit 50BF Figure 6.1-1 Logic Diagram: Circuit Breaker Fail Protection (50BF) ©2010 Siemens Protection Devices Limited Chapter 1 Page 70 of 80...
  • Page 73: Vt Supervision (60Vts) - 7Pg2114/6

    Voltage is restored to a healthy state i.e. above VPPS setting while NPS voltage is below VNPS setting. A binary or virtual input, or function key and a VT failure condition no longer Ext Reset 60VTS exists. A binary or virtual input. Inhibit 60VTS ©2010 Siemens Protection Devices Limited Chapter 1 Page 71 of 80...
  • Page 74: Figure 6.2-1 Logic Diagram: Vt Supervision Function (60Vts)

    7PG2113/4/5/6 Solkor Description of Operation Figure 6.2-1 Logic Diagram: VT Supervision Function (60VTS) ©2010 Siemens Protection Devices Limited Chapter 1 Page 72 of 80...
  • Page 75: Ct Supervision (60Cts)

    60CTS Delay then a CT failure output (60CTS Operated) is given. Operation of the CT supervision elements can be inhibited from: A binary or virtual input. Inhibit 60CTS ©2010 Siemens Protection Devices Limited Chapter 1 Page 73 of 80...
  • Page 76: Broken Conductor (46Bc)

    Setting an output is given after the 46BC Delay. The Broken Conductor function can be inhibited from A binary or virtual input. Inhibit 46BC Figure 6.4-1 Logic Diagram: Broken Conductor Function (46BC) ©2010 Siemens Protection Devices Limited Chapter 1 Page 74 of 80...
  • Page 77: Trip/ Close Circuit Supervision (74Tcs & 74Ccs)

    Figure 6.5-1 Logic Diagram: Trip Circuit Supervision Feature (74TCS) & ≥1 NOTE: Diagram shows two binary inputs mapped to the same Close Circuit Supervision element Figure 6.5-2 Logic Diagram: Close Circuit Supervision Feature (74CCS) ©2010 Siemens Protection Devices Limited Chapter 1 Page 75 of 80...
  • Page 78: 2Nd Harmonic Block/Inrush Restraint (81Hbl2) Phase Elements Only

    Updated Period. The statistics can be reset from a binary input or communication command, after a reset the update period and window are immediately restarted. ©2010 Siemens Protection Devices Limited Chapter 1 Page 76 of 80...
  • Page 79: Section 7: Other Features

    Alarm limit . The t value is the time between CB contacts separation when an arc is formed, Separation Time, and the CB Clearance time. ©2010 Siemens Protection Devices Limited Chapter 1 Page 77 of 80...
  • Page 80: Data Storage

    Fault records are stored in a rolling buffer, with the oldest faults overwritten. The fault storage can be cleared with the DATA STORAGE>Clear Faults setting or from Reydisp. ©2010 Siemens Protection Devices Limited Chapter 1 Page 78 of 80...
  • Page 81: Metering

    ENTER key. The user is prompted to confirm the action, again by pressing the ENTER key, before the command is executed. ©2010 Siemens Protection Devices Limited Chapter 1 Page 79 of 80...
  • Page 82: Real Time Clock

    The password validation screen also displays a numerical code. If the password is lost or forgotten, this code should be communicated to Siemens Protection Devices Ltd. and the password can be retrieved. ©2010 Siemens Protection Devices Limited Chapter 1 Page 80 of 80...
  • Page 83: The Copyright And Other Intellectual Property Rights In This Document, And In Any Model Or Article Produced From It

    Limited. No part of this document shall be reproduced or modified or stored in another form, in any data retrieval system, without the permission of Siemens Protection Devices Limited, nor shall any model or article be reproduced from this document unless Siemens Protection Devices Limited consent.
  • Page 84 Figure 2.1-2 RS485 connection to PC ........................18 Figure 2.1-3 PC Comm Port Selection........................19 Figure 2.1-4 PC Language File Editor........................20 Figure 2.1-5 Language File Editor Setting Texts....................21 ©2010 Siemens Protection Devices Limited Chapter 2 Page 2 of 21...
  • Page 85: Section 1: Introduction

    Fault Data Mode - allows the user to see type and data of any fault that the relay has detected. Control Mode - allows the user to control external plant under the relays control for example the CB ©2010 Siemens Protection Devices Limited Chapter 2 Page 3 of 21...
  • Page 86 To change the contrast on the LCD insert a flat bladed screwdriver into the screwhead below the contrast symbol, turning the screwhead left (anti-clockwase) lightens the contrast of the LCD and turning it right (clockwise) darkens the display. Figure 1.2-3 Fascia Contrast symbol ©2010 Siemens Protection Devices Limited Chapter 2 Page 4 of 21...
  • Page 87 7PG2113/4/5/6 Solkor Settings Figure 1.2-4 Fascia of a 7PG2113/4/5/6 relay ©2010 Siemens Protection Devices Limited Chapter 2 Page 5 of 21...
  • Page 88: Operation Guide

    LEDs will momentarily light up to indicate their correct operation. It also moves the cursor right ► when navigating through menus and settings. ©2010 Siemens Protection Devices Limited Chapter 2 Page 6 of 21...
  • Page 89: Setting Mode

    7PG2113/4/5/6 Solkor Settings Figure 1.3-2 Menu Structure Setting Mode The Settings Mode is reached by pressing the READ DOWN ▼ button from the relay identifier screen. ©2010 Siemens Protection Devices Limited Chapter 2 Page 7 of 21...
  • Page 90 Once editing is complete pressing the ENTER button stores the new setting into the non-volatile memory. The actual setting ranges and default values for each relay model and version of the numeric module can be found in the appendix to this manual. ©2010 Siemens Protection Devices Limited Chapter 2 Page 8 of 21...
  • Page 91: Instruments Mode

    This meter displays the Nominal current 0.00XIn---- 0.00XIn---- 0.00XIn---- Pri Earth Current This meter displays the Primary earth current. The value displayed will automatically adjust 0.00A between A and kA. 0.00A ©2010 Siemens Protection Devices Limited Chapter 2 Page 9 of 21...
  • Page 92 0.00xVn 0.00xVn Prim Ph-N Voltage This meter displays the Primary RMS Phase to Neutral Voltage 0.00kV 0.00kV 0.00kV Sec Ph-N Voltage This meter displays the Secondary Phase to Neutral ©2010 Siemens Protection Devices Limited Chapter 2 Page 10 of 21...
  • Page 93 Displays Power Factor PF B 0.00 PF C 0.00 PF (3P) 0.00 ENERGY METERS This is the sub-group that includes all the meters that are associated with Energy TEST/RESET allows ©2010 Siemens Protection Devices Limited Chapter 2 Page 11 of 21...
  • Page 94 Maintenance TEST/RESET →to view allows access to this sub-group CB Total Trips This meter shows the number of CB trips experienced by the CB Count Target ©2010 Siemens Protection Devices Limited Chapter 2 Page 12 of 21...
  • Page 95 This is the sub-group that includes all the meters that DEMAND METERS are associated with Demand. TEST/RESET allows →to view access to this sub-group I Phase A Demand 0.00A ©2010 Siemens Protection Devices Limited Chapter 2 Page 13 of 21...
  • Page 96 V Phase C Demand 0.00V 0.00V Mean 0.00V V Phase AB Demand 0.00V 0.00V Mean 0.00V V Phase BC Demand 0.00V 0.00V Mean 0.00V V Phase CA Demand 0.00V 0.00V ©2010 Siemens Protection Devices Limited Chapter 2 Page 14 of 21...
  • Page 97 COMMNICATIONS METERS Displays when the communication port is active →to view Com1 Com2 COM1 TRAFFIC COM1 Tx1 COM1 Rx Error COM1 Rx ©2010 Siemens Protection Devices Limited Chapter 2 Page 15 of 21...
  • Page 98: Fault Data Mode

    TEST/RESET► button. Each record contains data on the operated elements, analogue values and LED flag states at the time of the fault. The data is viewed by scrolling down using the ▼ button. ©2010 Siemens Protection Devices Limited Chapter 2 Page 16 of 21...
  • Page 99: Section 2: Setting & Configuring The Relay Using Reydisp Evolution

    Interface cable and converters are required depending which port is being used. 2.1.1 Front USB connection To connect your pc locally via the front USB port. Figure 2.1-1 USB connection to PC ©2010 Siemens Protection Devices Limited Chapter 2 Page 17 of 21...
  • Page 100: Rear Rs485 Connection

    RS485 port 75 110 150 300 600 1200 COM1-RS485 Baud 2400 4800 9600 19200 19200 Rate 38400 NONE, ODD, EVEN EVEN COM1-RS485 Parity OFF, IEC60870-5-103, IEC60870-5- MODBUS-RTU, COM2-USB Protocol ASCII,DNP3 ©2010 Siemens Protection Devices Limited Chapter 2 Page 18 of 21...
  • Page 101: Connecting To The Relay For Setting Via Reydisp

    The Reyrolle Language File Editor tool and its user manual are installed as part of the Reydisp Evolution software package. They can be found in your pc as sub menus of the Reydisp Evolution installation. ©2010 Siemens Protection Devices Limited Chapter 2 Page 19 of 21...
  • Page 102 Care should be taken to ensure a unique file name is given including a version control reference. The user will be prompted to restart the relay to activate the language file. Please refer to the Language Editor Manual for further guidance. ©2010 Siemens Protection Devices Limited Chapter 2 Page 20 of 21...
  • Page 103 7PG2113/4/5/6 Solkor Settings Figure 2.1-5 Language File Editor Setting Texts ©2010 Siemens Protection Devices Limited Chapter 2 Page 21 of 21...
  • Page 104: The Copyright And Other Intellectual Property Rights In This Document, And In Any Model Or Article Produced From It

    Limited. No part of this document shall be reproduced or modified or stored in another form, in any data retrieval system, without the permission of Siemens Protection Devices Limited, nor shall any model or article be reproduced from this document unless Siemens Protection Devices Limited consent.
  • Page 105 Operate and Reset Time......................21 2.7 50G Instantaneous Measured Earth Fault .................... 21 2.7.1 Reference ..........................21 2.7.2 Operate and Reset Level ......................21 2.7.3 Operate and Reset Time......................22 ©2010 Siemens Protection Devices Limited Chapter 3 Page 2 of 42...
  • Page 106 3.5 74TCS & 74CCS Trip & Close Circuit Supervision ................42 3.5.1 Reference ..........................42 3.5.2 Operate and Reset Time......................42 3.6 81HBL2 Inrush Detector........................42 3.6.1 Reference ..........................42 3.6.2 Operate and Reset Time......................42 ©2010 Siemens Protection Devices Limited Chapter 3 Page 3 of 42...
  • Page 107 Figure 2.5-1 Thermal Overload Protection Curves ................20 Figure 2.9-1 IEC IDMTL Curves (Time Multiplier=1)................25 Figure 2.9-2 ANSI IDMTL Operate Curves (Time Multiplier=1) .............26 Figure 2.9-3 ANSI Reset Curves (Time Multiplier=1)................27 ©2010 Siemens Protection Devices Limited Chapter 3 Page 4 of 42...
  • Page 108: Section 1: Common Functions

    See appropriate case outline and panel drilling drawing, as specified in Diagrams and Parameters of the Installation section, for complete dimensional specifications. 1.1.4 Weights Parameter Value 7PG21113/4/5/6 8.6kg Net weight E10 case ©2010 Siemens Protection Devices Limited Chapter 3 Page 5 of 42...
  • Page 109: Energising Quantities

    (1) Using fuses as on/off switches or allowing batteries to run at very low cell voltages for extended periods and then attempting to re-charge them are examples of such auxiliary supply conditions. ©2010 Siemens Protection Devices Limited Chapter 3 Page 6 of 42...
  • Page 110: Ac Current

    270 V 50, 60Hz 47 to 52Hz, 57 to 62Hz 1.2.3.1 Burden Attribute Value AC Burden ≤ 0.02 VA at 63.5 V , ≤ 0.06 VA at 110 V ©2010 Siemens Protection Devices Limited Chapter 3 Page 7 of 42...
  • Page 111: Binary (Digital) Outputs

    To comply with EATS 48-4, classes ESI 1 and ESI 2, external components / BI pick-up delays are required as shown in fig. 1-1. To achieve immunity from AC interference, a BI pick-up delay of typically one-cycle can be applied. ©2010 Siemens Protection Devices Limited Chapter 3 Page 8 of 42...
  • Page 112 7PG2113/4/5/6 Performance Specification Figure 1.2-1 Binary Input Configurations Providing Compliance with EATS 48-4 Classes ESI 1 and ESI 2 ©2010 Siemens Protection Devices Limited Chapter 3 Page 9 of 42...
  • Page 113: Functional Performance

    Tap 0.5 Tap 0.25 Peak Voltage applied to pilots 300v 450v 450v 330v 225v under fault conditions Maximum current carried by pilots 200mA 250mA 250mA 380mA 500mA under fault conditions ©2010 Siemens Protection Devices Limited Chapter 3 Page 10 of 42...
  • Page 114: Line Charging Current

    IP 5X, Category 2- Dust-protected Installed with cover off IP 4X, 1mm probe Solkor R/Rf Type Level Installed with cover on IP 51 Installed with cover removed IP 30 ©2010 Siemens Protection Devices Limited Chapter 3 Page 11 of 42...
  • Page 115: Emissions

    Restart with no mal-operation, loss of data or relay damage 1.5.3.2 High Frequency Disturbance IEC 60255-22-1 Type Level Common (longitudinal) mode 2.5 kV Series (transverse) mode 1.0 kV 1.5.3.3 Electrostatic Discharge IEC 60255-22-2 Class 4 ©2010 Siemens Protection Devices Limited Chapter 3 Page 12 of 42...
  • Page 116: Mechanical

    Bump test 10 gn, 16 ms 1.5.4.3 Seismic IEC 60255-21-3 Class I Type Level Variation X-plane - 3.5mm displacement below crossover freq ≤ 5 % Seismic response (8-9Hz) 1.0gn above ©2010 Siemens Protection Devices Limited Chapter 3 Page 13 of 42...
  • Page 117 7PG2113/4/5/6 Performance Specification Type Level Variation Y-plane - 1.5mm displacement below crossover freq (8-9Hz) 0.5gn above 1.5.4.4 Mechanical Classification Type Level Durability > 10 operations ©2010 Siemens Protection Devices Limited Chapter 3 Page 14 of 42...
  • Page 118: Section 2: Protection Functions

    ≤ 105 % I Reset level ± 1 % Repeatability ≤ 5 % -10 °C to +55 °C Variation ≤ 5 % - 3 Hz to f + 2 Hz ©2010 Siemens Protection Devices Limited Chapter 3 Page 15 of 42...
  • Page 119: 46Nps Negative Phase Sequence Overcurrent

    Setting 0.05, 0.06… 2.5xIn Applied Current (for operate time) 2 to 20 x Is IDMTL Delay setting 0, 0.01… 20 s Reset setting ANSI DECAYING, 0, 1… 60 s ©2010 Siemens Protection Devices Limited Chapter 3 Page 16 of 42...
  • Page 120: Operate And Reset Level (46It)

    ANSI-EI : R = 29.1 , ± 1 % or ± 20ms ± 1 % or ± 20ms Repeatability Overshoot time < 40 ms Disengaging time < 60 ms ©2010 Siemens Protection Devices Limited Chapter 3 Page 17 of 42...
  • Page 121: Negative Phase Sequence Voltage

    ≥ 95 % I Reset level ± 1 % Repeatability ≤ 5 % -10 °C to +55 °C Variation + 2 Hz ≤ 5 % - 3 Hz to f ©2010 Siemens Protection Devices Limited Chapter 3 Page 18 of 42...
  • Page 122 , ± 5 % absolute or ± 100ms, Overload trip operate time ⎩ ⎭ where I = prior current ± 100ms Repeatability Note:- Fastest operate time is at 10 xIs ©2010 Siemens Protection Devices Limited Chapter 3 Page 19 of 42...
  • Page 123 τ = 1000 mins 1000 Time (sec) τ = 100 mins τ = 10 mins τ = 1 min Current (multiple of setting) Figure 2.5-1 Thermal Overload Protection Curves ©2010 Siemens Protection Devices Limited Chapter 3 Page 20 of 42...
  • Page 124: Operate And Reset Level

    Repeatability Transient overreach ≤ -5 % (X/R ≤ 100) ≤ 5 % -10 °C to +55 °C Variation + 2 Hz ≤ 5 % - 3 Hz to f ©2010 Siemens Protection Devices Limited Chapter 3 Page 21 of 42...
  • Page 125: Instantaneous Derived Earth Fault

    , ± 1 % or ± 10ms Operate time following delay basic ± 1 % or ± 10ms Repeatability Overshoot time < 40 ms Disengaging time < 50 ms ©2010 Siemens Protection Devices Limited Chapter 3 Page 22 of 42...
  • Page 126: Time Delayed Overcurrent

    ANSI-VI : R = 21.6 ANSI-EI : R = 29.1 , ± 1 % or ± 20ms ± 1 % or ± 20ms Repeatability Overshoot time < 40 ms ©2010 Siemens Protection Devices Limited Chapter 3 Page 23 of 42...
  • Page 127 Figure 2.9-2 and Figure 2.9-3 show the ANSI operate and reset curves. These operate times apply to non- directional characteristics. Where directional control is applied then the directional element operate time should be added to give total maximum operating time. ©2010 Siemens Protection Devices Limited Chapter 3 Page 24 of 42...
  • Page 128 7PG2113/4/5/6 Performance Specification 1000 Time (sec) Long Time Inverse Normal Inverse Very Inverse Extremely Inverse 50 60 Current (multiples of setting) Figure 2.9-1 IEC IDMTL Curves (Time Multiplier=1) ©2010 Siemens Protection Devices Limited Chapter 3 Page 25 of 42...
  • Page 129 7PG2113/4/5/6 Performance Specification 1000 Time (sec) Moderately Inverse Very Inverse Extremely Inverse 50 60 Current (multiples of setting) Figure 2.9-2 ANSI IDMTL Operate Curves (Time Multiplier=1) ©2010 Siemens Protection Devices Limited Chapter 3 Page 26 of 42...
  • Page 130 7PG2113/4/5/6 Performance Specification 1000 Extremely Inverse Very Inverse Time (sec) Moderately Inverse 0.8 0.9 Current (multiples of setting) Figure 2.9-3 ANSI Reset Curves (Time Multiplier=1) ©2010 Siemens Protection Devices Limited Chapter 3 Page 27 of 42...
  • Page 131: Time Delayed Measured Earth Fault

    ≥ 95 % I Reset level ± 1 % Repeatability ≤ 5 % -10 °C to +55 °C Variation ≤ 5 % - 3 Hz to f + 2 Hz ©2010 Siemens Protection Devices Limited Chapter 3 Page 28 of 42...
  • Page 132: Operate And Reset Time

    Figures 2.10-2 and 2.10-3 show the ANSI operate and reset curves. These operate times apply to non-directional characteristics. Where directional control is applied then the directional element operate time should be added to give total maximum operating time. ©2010 Siemens Protection Devices Limited Chapter 3 Page 29 of 42...
  • Page 133: Time Delayed Derived Earth Fault

    ≥ 95 % I Reset level ± 1 % Repeatability ≤ 5 % -10 °C to +55 °C Variation + 2 Hz ≤ 5 % - 3 Hz to f ©2010 Siemens Protection Devices Limited Chapter 3 Page 30 of 42...
  • Page 134 Figures 2.10-2 and 2.10-3 show the ANSI operate and reset curves. These operate times apply to non-directional characteristics. Where directional control is applied then the directional element operate time should be added to give total maximum operating time. ©2010 Siemens Protection Devices Limited Chapter 3 Page 31 of 42...
  • Page 135: Operate And Reset Time

    Operate and Reset Time As per Phase Fault Shaped Characteristic Element (ANSI 51). Where Pickup Level = Is for Voltage > Vs Pickup Level = (Is x m) for Voltage < Vs ©2010 Siemens Protection Devices Limited Chapter 3 Page 32 of 42...
  • Page 136: Neutral Voltage Displacement

    ± 0.5 V Reset level ± 1 % Repeatability ≤ 5 % -10 °C to +55 °C Variation ≤ 5 % - 3 Hz to f + 2 Hz ©2010 Siemens Protection Devices Limited Chapter 3 Page 33 of 42...
  • Page 137: Operate And Reset Time (59Nit)

    Reset Time , ± 1 % or ± 40ms char = DTL ± 1 % or ± 20ms Repeatability Overshoot time < 40 ms Disengaging time < 100 ms ©2010 Siemens Protection Devices Limited Chapter 3 Page 34 of 42...
  • Page 138: Restricted Earth Fault Protection

    0 to 5 xIs, 35 ms, ± 10ms , ± 1% or ± 10ms Operate time following delay basic ± 1% or ± 10ms Repeatability Overshoot time < 40 ms Disengaging time < 50 ms ©2010 Siemens Protection Devices Limited Chapter 3 Page 35 of 42...
  • Page 139: 67/67N Directional Overcurrent & Earth Fault

    The following sensitivities are shown as a percentage of rated current and are directly applicable to the local relay of a connected pair when subjected to current injection at the local end only. Settings are typically within +-15% of quoted sensitivity. ©2010 Siemens Protection Devices Limited Chapter 3 Page 36 of 42...
  • Page 140: Operate Time

    R Mode 45ms Element typical basic 5kV Rf mode 45ms RfBasic operate time 15kV Rf mode 40ms 2.16.3 Stability Level Parameter Value Maximum Through fault Stability Level 50x In StabLimit ©2010 Siemens Protection Devices Limited Chapter 3 Page 37 of 42...
  • Page 141: Section 3: Supervision Functions

    , ± 1 % or ± 20ms Operate time basic ± 1 % or ± 20ms Repeatability - 3 Hz to f + 2 Hz ≤ 5 % Variation harmonics to f cutoff ©2010 Siemens Protection Devices Limited Chapter 3 Page 38 of 42...
  • Page 142: Operate And Reset Level

    Stage 1 CBF1 , ± 1 % or ± 20ms Stage 2 CBF2 ± 1 % or ± 20ms Repeatability Overshoot < 2 x 20ms Disengaging time < 20ms ©2010 Siemens Protection Devices Limited Chapter 3 Page 39 of 42...
  • Page 143: Operate And Reset Time

    Operate and Reset Time Attribute Value 50 ms ± 20ms Basic operate time basic , ± 1 % or ± 20ms Operate time basic ± 1 % or ± 20ms Repeatability ©2010 Siemens Protection Devices Limited Chapter 3 Page 40 of 42...
  • Page 144: 60Vts Voltage Transformer Supervision

    32 ms ± 10ms Basic operate time 0V to 2 x Vs basic ± 1 % or ± 10ms Operate time basic ± 1 % or ± 10ms Repeatability ©2010 Siemens Protection Devices Limited Chapter 3 Page 41 of 42...
  • Page 145: 74Tcs & 74Ccs Trip & Close Circuit Supervision

    Will pick-up before operation of any protection element due Element basic operate time basic to magnetic inrush Will operate until drop-off of any protection element due to Reset Time magnetic inrush ©2010 Siemens Protection Devices Limited Chapter 3 Page 42 of 42...
  • Page 146: The Copyright And Other Intellectual Property Rights In This Document, And In Any Model Or Article Produced From It

    Limited. No part of this document shall be reproduced or modified or stored in another form, in any data retrieval system, without the permission of Siemens Protection Devices Limited, nor shall any model or article be reproduced from this document unless Siemens Protection Devices Limited consent.
  • Page 147 Section 7: Glossary..............................38 List of Figures Figure 7.1-1 Communication to Front USB Port ....................4 Figure 1.1-2 Communication to Multiple Devices from Control System using RS485 ........... 5 ©2010 Siemens Protection Devices Limited Chapter 4 Page 2 of 38...
  • Page 148: Section 1: Introduction

    Communications Interface manual. The Communications Interface for dialogue communications by the Protection Engineer is provided by the Reydisp Evolution software package, also available from the website, using the IEC60870-5-103 protocol. ©2010 Siemens Protection Devices Limited Chapter 4 Page 3 of 38...
  • Page 149: Section 2: Physical Connection

    OFF in the relay settings.. The same protocol can be used simultaneously on both ports. SPDL. can provide a range of interface devices, please refer to product portfolio catalogue. Full details of the interface devices can be found by referring to the website www.siemens.com/energy. Communication ports 2.1.1...
  • Page 150 Setting is only visible 0 … 65534 As Required when COM1 Protocol is Destination Address set to DNP3 Figure 1.1-2 Communication to Multiple Devices from Control System using RS485 ©2010 Siemens Protection Devices Limited Chapter 4 Page 5 of 38...
  • Page 151: Section 3: Iec 60870-5-103 Definitions

    The following table lists information number and function definitions together with a description of the message and function type and cause of transmission that can result in that message. The table shows all events available from the relay range. ©2010 Siemens Protection Devices Limited Chapter 4 Page 6 of 38...
  • Page 152 Settings Group 1 Select Ack, Nak SE, GI Settings Group 2 Select Ack, Nak SE, GI Settings Group 3 Select Ack, Nak SE, GI Settings Group 4 Select Ack, Nak ©2010 Siemens Protection Devices Limited Chapter 4 Page 7 of 38...
  • Page 153 SE, GI 50N-3 SE, GI 51G-3 SE, GI 50G-3 SE, GI 51-4 SE, GI 50-4 SE, GI 51N-4 SE, GI 50N-4 SE, GI 51G-4 SE, GI 50G-4 SE, GI ©2010 Siemens Protection Devices Limited Chapter 4 Page 8 of 38...
  • Page 154 Inst Protection Out Ack, Nak CB Trip Count Maintenance SE, GI CB Trip Count Delta SE, GI CB Trip Count Lockout SE, GI Reset CB Trip Count Ack, Nak ©2010 Siemens Protection Devices Limited Chapter 4 Page 9 of 38...
  • Page 155 Trip & Reclose Ack, Nak Trip & Lockout Ack, Nak Blocked by Interlocking SE,GI Time Synchronisation Time Synchronisation GI Initiation End of GI End of GI End of GI ©2010 Siemens Protection Devices Limited Chapter 4 Page 10 of 38...
  • Page 156 Q (2.4 x) (7PG2114/6 only) F (1.2 x) (7PG2114/6 only) Disturbance Recorder Actual Channel (ACC) Numbers Function ACC Number Description Global Va (7PG2114/6 only) Vb (7PG2114/6 only) Vc (7PG2114/6 only) Not Used ©2010 Siemens Protection Devices Limited Chapter 4 Page 11 of 38...
  • Page 157 Trip L1 • • • • • • • • Trip L2 • • • • • • • • Trip L3 • • • • • • • • ©2010 Siemens Protection Devices Limited Chapter 4 Page 12 of 38...
  • Page 158 • • • Reset CB Total Trip Count • • • • • • • • Reset CB Delta Trip Count • • • • • • • • ©2010 Siemens Protection Devices Limited Chapter 4 Page 13 of 38...
  • Page 159 • • • • • • • • GI Initiation • • • • • • • • End of GI • • • • • • • • ©2010 Siemens Protection Devices Limited Chapter 4 Page 14 of 38...
  • Page 160: Section 4: Modbus Definitions

    Reset CB Total Trip Count 00119 Reset CB Delta Trip Count 00120 Reset CB Count To AR Block 00121 Reset CB Frequent Ops Count 00123 Reset I^2t CB Wear ©2010 Siemens Protection Devices Limited Chapter 4 Page 15 of 38...
  • Page 161 AR Active 10172 CB on by AR 10173 Reclaim 10174 Lockout 10175 Hot Line Working 10176 Inst Protection Out 10177 CB Trip Count Maint 10178 CB Trip Count Delta ©2010 Siemens Protection Devices Limited Chapter 4 Page 16 of 38...
  • Page 162 Phase A Primary Curr FP_32BITS_3DP Ia kA 30066 Phase B Primary Curr FP_32BITS_3DP Ib kA 30068 Phase C Primary Curr FP_32BITS_3DP Ic kA 30070 Phase a Secondary Curr FP_32BITS_3DP Ia A ©2010 Siemens Protection Devices Limited Chapter 4 Page 17 of 38...
  • Page 163 3) Sequence of 8 registers containing an event record. Read address 30002 for 8 registers (16 bytes), each read returns the earliest event record and removes it from the internal store. Repeat this process for the number of events in the register 30001, or until no more events are returned. (the error condition exception code 2) ©2010 Siemens Protection Devices Limited Chapter 4 Page 18 of 38...
  • Page 164 The format of the event record is defined by the zero byte. It signifies the type of record which is used to decode the event information. The zero byte can be one of the following. Type Description Event Event with Relative Time Measurand Event with Relative Time ©2010 Siemens Protection Devices Limited Chapter 4 Page 19 of 38...
  • Page 165: Section 5: Dnp3.0 Definitions

    When reporting Event Data (Slave devices only) When sending multi-fragment responses (Slave devices only) Sometimes Configurable as: “Only when reporting event data”, or “When reporting event data or multi-fragment messages.” ©2010 Siemens Protection Devices Limited Chapter 4 Page 20 of 38...
  • Page 166 Counters Roll Over at: No Counters Reported No Counters Reported Configurable Configurable (attach explanation) Default Object 16 Bits Default Variation: 32 Bits Point-by-point list attached Other Value: _____ Point-by-point list attached ©2010 Siemens Protection Devices Limited Chapter 4 Page 21 of 38...
  • Page 167 File Transfer Support Append File Mode Custom Status Code Strings Permissions Field File Events Assigned to Class File Events Send Immediately Multiple Blocks in a Fragment Max Number of Files Open ©2010 Siemens Protection Devices Limited Chapter 4 Page 22 of 38...
  • Page 168: Implementation Table

    Variation or all) 07, 08 (limited qty) Binary Input Change without 1 (read) 06 (no range, 17, 28 (index) Time or all) (response) 07, 08 (limited qty) (unsol. resp) ©2010 Siemens Protection Devices Limited Chapter 4 Page 23 of 38...
  • Page 169 07, 08 (limited qty) Binary Output Change 1 (read) 06 (no range, 17, 28 (index ) without Time or all) (default (response) – 07, 08 (limited see note qty) (unsol. resp) ©2010 Siemens Protection Devices Limited Chapter 4 Page 24 of 38...
  • Page 170 5 (direct op) 6 (dir. op, noack) Analog Input - Any Variation 1 (read) 00, 01 (start-stop) (assign 06 (no range, class) or all) 07, 08 (limited qty) 17, 27, 28(index) ©2010 Siemens Protection Devices Limited Chapter 4 Page 25 of 38...
  • Page 171 1 (read) 00, 01 00, 01 (start-stop) (response) (start-stop) 06 (no range, 17, 28(index – or all) see note 2) 07, 08 (limited qty) 17, 27, 28(index) ©2010 Siemens Protection Devices Limited Chapter 4 Page 26 of 38...
  • Page 172 07, 08 (limited qty) (unsol. resp) short floating point Analog 1 (read) 06 (no range, 17, 28 (index) Change Event with Time or all) (response) 07, 08 (limited qty) (unsol. resp) ©2010 Siemens Protection Devices Limited Chapter 4 Page 27 of 38...
  • Page 173 06 (no range, or all) Class 1 Data 1 (read) 06 (no range, or all) 07, 08 (limited qty) 06 (no range, or all) (enbl. unsol.) (dab. unsol.) (assign class) ©2010 Siemens Protection Devices Limited Chapter 4 Page 28 of 38...
  • Page 174 00 or 01. (For change-event objects, qualifiers 17 or 28 are always responded.) Note 3: Writes of Internal Indications are only supported for index 7 (Restart IIN1-7) ©2010 Siemens Protection Devices Limited Chapter 4 Page 29 of 38...
  • Page 175: Point List

    Trip Circuit Fail A-Starter B-Starter C-Starter General Starter VTS Alarm Earth Fault Forward/Line Earth Fault Reverse/Busbar Start/Pick-up N Fault Forward/Line Fault Reverse/Busbar 51-1 50-1 51G-1 50G-1 51-2 50-2 51N-2 50N-2 ©2010 Siemens Protection Devices Limited Chapter 4 Page 30 of 38...
  • Page 176 CB on by auto reclose Reclaim Lockout 51-3 50-3 51N-3 50N-3 51G-3 50G-3 51-4 50-4 51N-4 50N-4 51G-4 50G-4 Cold Load Active E/F Protection Out P/F Inst Protection Inhibited E/F Inst Protection Inhibited ©2010 Siemens Protection Devices Limited Chapter 4 Page 31 of 38...
  • Page 177 I^2t CB Wear Close Circuit Fail 1 Close Circuit Fail 2 Close Circuit Fail 3 Close Circuit Fail 50BF-1 50BF-2 49 Alarm 49 Trip 37-1 37-2 Trip Time Alarm ©2010 Siemens Protection Devices Limited Chapter 4 Page 32 of 38...
  • Page 178 Settings Group 1 Pulse On/Latch Off Settings Group 2 Pulse On/Latch Off Settings Group 3 Pulse On/Latch Off Settings Group 4 Pulse On/Latch Off Auto-reclose on/off Pulse On/Pulse Off/Latch On/Latch Off ©2010 Siemens Protection Devices Limited Chapter 4 Page 33 of 38...
  • Page 179 (1, 2, 3, or none) will the change event be reported. The default analog input event buffer size is set 30. ©2010 Siemens Protection Devices Limited Chapter 4 Page 34 of 38...
  • Page 180 100.0 Inps Nominal 100.0 Izps Nominal Ipps Nominal Inps Nominal Active Power A 0.001 1000 Active Power B 0.001 1000 Active Power C 0.001 1000 P (3P) 0.000001 100000 ©2010 Siemens Protection Devices Limited Chapter 4 Page 35 of 38...
  • Page 181 I Phase C Max 100.0 P 3P Max 100.0 Q 3P Max 100.0 Ig Max 100.0 Isef Max 100.0 Isef Primary 0.001 1000 Isef Secondary 100.0 Isef Nominal 100.0 ©2010 Siemens Protection Devices Limited Chapter 4 Page 36 of 38...
  • Page 182: Section 6: Configuration

    Reydisp software comms editor tool. The Comms Editor is provided to allow its users to configure the Communications Files Protocols in Reyrolle brand Relays manufactured by Siemens Protection Devices Limited (SPDL). The editor supports configuring DNP3, IEC60870-5-103 and MODBUS protocols.
  • Page 183: Section 7: Glossary

    Bit (logical 0) sent to signify the start of a byte during data transmission. Stop Bit Bit (logical 1) sent to signify the end Universal Serial Bus standard for the transfer of data. ©2010 Siemens Protection Devices Limited Chapter 4 Page 38 of 38...
  • Page 184: The Copyright And Other Intellectual Property Rights In This Document, And In Any Model Or Article Produced From It

    Limited. No part of this document shall be reproduced or modified or stored in another form, in any data retrieval system, without the permission of Siemens Protection Devices Limited, nor shall any model or article be reproduced from this document unless Siemens Protection Devices Limited consent.
  • Page 185 Figure 2. E4 Case ..............................6 Figure 3. E10 Case ..............................6 Figure 4. Vedette C1½ Case ........................... 7 Figure 5. 15kV Transformer Outline & Mounting Arrangement ................8 ©2010 Siemens Protection Devices Limited Chapter 5 Page 2 of 15...
  • Page 186: Section 1: Installation

    On receipt remove the relay from the container in which it was received and inspect it for obvious damage. It is recommended that the relay not be removed from its case at this stage. If damage has been sustained a claim should be immediately be made against the carrier, also inform Siemens Protection Devices Limited, and the nearest Siemens agent.
  • Page 187: Section 2: Equipment Operating Conditions

    Front Cover The front cover provides additional securing of the relay element within the case. The relay cover should be in place during normal operating conditions. ©2010 Siemens Protection Devices Limited Chapter 5 Page 4 of 15...
  • Page 188: Section 3: Dimensions And Panel Fixings

    Figure 5. The following drawings which are available from the website give panel cut-out and mounting details. Figure 1. E2 Case ©2010 Siemens Protection Devices Limited Chapter 5 Page 5 of 15...
  • Page 189 1.6mm thick and above. For other panels, holes to be M4 clearance (typically Ø4.5) and relays mounted using M4 machine screws, nuts and lockwashers (supplied in panel fixing kit). ©2010 Siemens Protection Devices Limited Chapter 5 Page 6 of 15...
  • Page 190 7PG2113/4/5/6 Installation Guide Figure 4. Vedette C1½ Case ©2010 Siemens Protection Devices Limited Chapter 5 Page 7 of 15...
  • Page 191 7PG2113/4/5/6 Installation Guide Figure 5. 15kV Transformer Outline & Mounting Arrangement ©2010 Siemens Protection Devices Limited Chapter 5 Page 8 of 15...
  • Page 192: Fixings

    Vedette case mounting arrangement is shown in Figure 4. 3.2.3 Back of Panel cases 3.2.3.1 Wiring Terminations M6 Ring tongued crimps are recommended. 3.2.3.2 Mounting arrangement Case mounting arrangement is shown in Figure 5 & 6 ©2010 Siemens Protection Devices Limited Chapter 5 Page 9 of 15...
  • Page 193: Section 4: Rear Terminal Drawings

    1) RS485 (Block ”B” Terms 14, 16, 18, 20) connection to this communication facility is by screened, twisted pair cable. On site when wiring other facilities ensure that these terminals are not obscured by other wiring runs. Cable should be RS485 compliant. ©2010 Siemens Protection Devices Limited Chapter 5 Page 10 of 15...
  • Page 194: Section 5: Connection/Wiring/Diagrams

    7PG2113/4/5/6 Installation Guide Section 5: Connection/Wiring/Diagrams Wiring Diagram: 7PG2113 OC/EF Relay with 3BI & 5BO ©2010 Siemens Protection Devices Limited Chapter 5 Page 11 of 15...
  • Page 195: Wiring Diagram: 7Pg2115 Oc/Ef Relay With 6Bi & 8Bo

    7PG2113/4/5/6 Installation Guide Wiring Diagram: 7PG2115 OC/EF Relay with 6BI & 8BO ©2010 Siemens Protection Devices Limited Chapter 5 Page 12 of 15...
  • Page 196: Wiring Diagram: 7Pg2114 Oc/Ef Relay With 3Bi & 5Bo

    7PG2113/4/5/6 Installation Guide Wiring Diagram: 7PG2114 OC/EF Relay with 3BI & 5BO ©2010 Siemens Protection Devices Limited Chapter 5 Page 13 of 15...
  • Page 197: Wiring Diagram: 7Pg2116 Oc/Ef Relay With 6Bi & 8Bo

    7PG2113/4/5/6 Installation Guide Wiring Diagram: 7PG2116 OC/EF Relay with 6BI & 8BO ©2010 Siemens Protection Devices Limited Chapter 5 Page 14 of 15...
  • Page 198: Section 6: Data Comms Connections

    The RS485 data communications link with a particular relay will be broken if the relay element is withdrawn from the case, all other relays will still communicate. Figure 6.1 RS485 Data Comms Connections Between Relays ©2010 Siemens Protection Devices Limited Chapter 5 Page 15 of 15...
  • Page 199: The Copyright And Other Intellectual Property Rights In This Document, And In Any Model Or Article Produced From It

    Limited. No part of this document shall be reproduced or modified or stored in another form, in any data retrieval system, without the permission of Siemens Protection Devices Limited, nor shall any model or article be reproduced from this document unless Siemens Protection Devices Limited consent.
  • Page 200 Directional Polarity ........................42 2.9.2 Definite Time Overcurrent (50SEF)..................42 2.9.3 Inverse Time Overcurrent (51SEF) ..................42 2.10 Restricted Earth fault (64H)......................... 45 2.11 Negative Phase Sequence Overcurrent (46NPS) ................. 47 ©2012 Siemens Protection Devices Limited Chapter 6 Page 2 of 77...
  • Page 201 Test of pilot supervision supply failure relay (where fitted)............75 6.3.9 Overall tests of pilot supervision equipment................75 6.3.10 Stability tests........................... 76 6.3.11 Putting into service........................76 6.3.12 Notes ............................76 ©2012 Siemens Protection Devices Limited Chapter 6 Page 3 of 77...
  • Page 202 51V VTS action ..........................28 Table 2.5-1 51c Test Results..........................30 Table 2.5-2 Standard Curve Timing........................31 Table 2.5-3 Standard ResetCurve Timing ......................31 Table 2.5-4 51c Reset Results .......................... 31 ©2012 Siemens Protection Devices Limited Chapter 6 Page 4 of 77...
  • Page 203 Troubleshooting Guide ........................72 Figure 6.3-1 Secondary Injection test of Pilot Supervision Receive Relay............. 75 Figure 6.3-2 Pilot Supervision Send Equipment ....................76 Figure 6.3-3 Pilot Supervision Receive Equipment....................77 ©2012 Siemens Protection Devices Limited Chapter 6 Page 5 of 77...
  • Page 204: Section 1: Common Functions

    The ‘Description of Operation’ section of this manual provides detailed information regarding the operation of each function of the relay. All functions are not available in all devices, please refer the ‘Description of Operation’ section to establish your function set. ©2012 Siemens Protection Devices Limited Chapter 6 Page 6 of 77...
  • Page 205: Test Equipment

    Do not open-circuit the secondary winding of a current-transformer while there is a current in its primary winding otherwise a high voltage will be produced in the secondary which may be dangerous to personnel and may also damage the secondary wiring insulation. ©2012 Siemens Protection Devices Limited Chapter 6 Page 7 of 77...
  • Page 206: Inspection

    Isolate the auxiliary D.C. supplies for alarm and tripping from the relay and remove the trip and intertrip links. Carry out injection tests for each relay function, as described in this document ©2012 Siemens Protection Devices Limited Chapter 6 Page 8 of 77...
  • Page 207: Primary Injection Tests

    Y. Also check that the polarity of the current-transformers, is correct by referring to ammeter X, the readings of which should be negligible compared with those in the individual phases. Repeat the tests for at least one other phase-to-phase fault condition. ©2012 Siemens Protection Devices Limited Chapter 6 Page 9 of 77...
  • Page 208: Pilot Insulation-Resistance Test

    This test should be carried out with an insulation resistance test set. Compare the readings obtained with the value quoted by the manufacturer of the pilot-cable. 1.3.6 Pilot-loop resistance tests ©2012 Siemens Protection Devices Limited Chapter 6 Page 10 of 77...
  • Page 209: Pilot Connection Check

    If isolating transformers are fitted check that transformers terminals S2 at both ends of the feeder are connected by one pilot core. Check that the other pilot core connects transformer terminal F2, T2 ©2012 Siemens Protection Devices Limited Chapter 6 Page 11 of 77...
  • Page 210: Putting Into Service

    Repeat the test for the other earth fault conditions and also for the phase fault conditions if sufficient test current is available. Tabulate the results as shown in Table 1.4-1. ©2012 Siemens Protection Devices Limited Chapter 6 Page 12 of 77...
  • Page 211 Table 1.3-2. Values of pilot capacitance higher than this have the effect of increasing the fault settings. Figure 1.4-1 -Connections for Overall Fault setting Tests by Primary Injection ©2012 Siemens Protection Devices Limited Chapter 6 Page 13 of 77...
  • Page 212: Stability Tests

    Remove the trip-links at both ends of the feeder but check that the remainder of the equipment, including the pilots, is connected for normal operation. ©2012 Siemens Protection Devices Limited Chapter 6 Page 14 of 77...
  • Page 213: Alternative Tests If Primary Injection Equipment Is Not Available

    If the pilots and current transformers are correctly connected the d.c. current in the operating coils of the relays should be negligible. If damage has been sustained a claim should immediately be made against the carrier and the local Siemens office should be informed.
  • Page 214: Current Transformer Ratio And Polarity Tests

    Check the polarity of the current transformers; the reading of ammeter X in the neutral circuit should be negligible compared with the secondary phase-currents. Some current may exist in the neutral circuit due to unbalance of primary load current and/or secondary burden. ©2012 Siemens Protection Devices Limited Chapter 6 Page 16 of 77...
  • Page 215: Check Of Secondary Connections

    Type of fault Primary current Secondary Tripping relay current (mA d.c.) current (A) Feeder end 1 Feeder end 2 Table 1.4-3 check of secondary connections using 3 Phase load current ©2012 Siemens Protection Devices Limited Chapter 6 Page 17 of 77...
  • Page 216: Ac Energising Quantities

    Tested Measured Measured Notes (method of initiation) Delay Delay Table 1.6-1 Binary Inputs test results ©2012 Siemens Protection Devices Limited Chapter 6 Page 18 of 77...
  • Page 217: Connections For Use In Solkor R Mode

    To operate a Solkor-Rf relay in the Solkor-R mode it is also necessary to change the internal terminal block connections and also link external relay terminals 18 and 20. When operating in the Solkor-R mode the maximum pilot loop resistance is 1,000 Ohms. ©2012 Siemens Protection Devices Limited Chapter 6 Page 19 of 77...
  • Page 218: Binary Outputs

    CT Shorting contacts checked Binary Output 1 terminals A1 & A2 Alarm Checked Binary Output 2 terminals A5 & A6 Alarm Checked Table 1.8-1 Case Shorting Contacts Test Results ©2012 Siemens Protection Devices Limited Chapter 6 Page 20 of 77...
  • Page 219: Section 2: Protection Functions

    3 phase nominal rated voltage to the VT inputs during testing to avoid inadvertent operation of other functions. Particular care should be taken when testing overcurrent functions that the thermal rating of the current inputs is not exceeded. ©2012 Siemens Protection Devices Limited Chapter 6 Page 21 of 77...
  • Page 220: Current Differential (87)

    (Reverse lead DO). and the ‘Fwd’ subsequently returns (Forward lead PU), recording the angles. Repeat the above tests, starting from the Characteristic Angle, but reducing the current phase angle to record the ©2012 Siemens Protection Devices Limited Chapter 6 Page 22 of 77...
  • Page 221 5. With the instrument reading ‘Fwd’ or ‘Rev’, reduce the voltage until the element resets. Record the minimum phase-phase operate voltage. Minimum Voltage Setting Measured Table 2.2-4 Minimum polarising Voltage Results ©2012 Siemens Protection Devices Limited Chapter 6 Page 23 of 77...
  • Page 222: Out Of 3 Logic

    It should be particularly noted that if the function is enabled, the 51C Cold Load settings may modify the normal 50-n and 51-n settings if the CB is open during testing. ©2012 Siemens Protection Devices Limited Chapter 6 Page 24 of 77...
  • Page 223: Definite Time Overcurrent (50)

    Table 2.3-3 Standard Timing Curve values Note that the operate time may be subject to the Minimum op time setting for the element and/or may have a Follower DTL applied. ©2012 Siemens Protection Devices Limited Chapter 6 Page 25 of 77...
  • Page 224 (calculated) (measured) Time time (measured) (expected) (calculated) (calculated) First test (c) Second Test (c) Table 2.3-6 Reset Time Results Check correct indication, trip output, alarm contacts, waveform record. ©2012 Siemens Protection Devices Limited Chapter 6 Page 26 of 77...
  • Page 225: Voltage Controlled Overcurrent (51V)

    Voltage setting. If the 51V-n current setting is above the continuous rating of the relay an alternative procedure should be used, apply test current in short duration shots with applied voltage being gradually reduced for each subsequent shot ©2012 Siemens Protection Devices Limited Chapter 6 Page 27 of 77...
  • Page 226 Increase 3P current until the element operates at its full setting, i.e. 51V settings are not used. Element VTS action 51-1 51-2 51-3 51-4 Table 2.4-4 51V VTS action Check correct indication, trip output, alarm contacts. ©2012 Siemens Protection Devices Limited Chapter 6 Page 28 of 77...
  • Page 227: Cold Load (51C)

    Current Level for more than the Reduced Current Time during testing. It may be convenient to set the Reduced Current setting to Disabled for the duration of the test. The Cold Load Active output is provided and can be used as an indication during testing. ©2012 Siemens Protection Devices Limited Chapter 6 Page 29 of 77...
  • Page 228: Inverse Time Overcurrent (51C)

    Operate Time (NI EI VI P.U. D.O. 2 x Is 5 x Is LTI, DTL) (Amps) (Amps) (sec) (sec) P.U. D.O. & TIMING TESTS Table 2.5-1 51c Test Results ©2012 Siemens Protection Devices Limited Chapter 6 Page 30 of 77...
  • Page 229 (calculated) (measured) Time time (measured) (expected) (calculated) (calculated) First test (c) Second Test (c) Table 2.5-4 51c Reset Results Check correct indication, trip output, alarm contacts, waveform record. ©2012 Siemens Protection Devices Limited Chapter 6 Page 31 of 77...
  • Page 230: Directional Earth Fault Polarity Check (67N)

    Alternatively, Verify correct directional indication at points a, +150 b, c and d (C.A +75 , +95 , -75 , -95 Figure 2.6-1 Directional Earth Fault Boundary System Angles ©2012 Siemens Protection Devices Limited Chapter 6 Page 32 of 77...
  • Page 231: Derived Earth Fault (67/50N, 67/51N)

    I Input. If any of these elements are defined as directional the correct voltage phase direction will be required to produce an operation of those elements. ©2012 Siemens Protection Devices Limited Chapter 6 Page 33 of 77...
  • Page 232: Directional Polarity

    Operate Current Operate Time D.O. (NI EI VI LTI, P.U. D.O. 2 x Is 5 x Is & DTL) (Amps) (Amps) (sec) (sec) TIMING TESTS Table 2.7-3 51N Results ©2012 Siemens Protection Devices Limited Chapter 6 Page 34 of 77...
  • Page 233 The Characteristic can be made non-directional by VT Supervision. This functionality should be checked. Element BI Inhibits VTS action Inrush Detector 51N-1 51N-2 51N-3 51N-4 50N-1 50N-2 50N-3 50N-4 Table 2.7-5 51N Element Blocking ©2012 Siemens Protection Devices Limited Chapter 6 Page 35 of 77...
  • Page 234 50% operate time time (calculated) (measured) Time time (measured) (expected) (calculated) (calculated) First test (c) Second Test (c) Table 2.7-7 Reset Results Check correct indication, trip output, alarm contacts, waveform record. ©2012 Siemens Protection Devices Limited Chapter 6 Page 36 of 77...
  • Page 235: Measured Earth Fault (67/50G,67/51G)

    I input circuit only. If any of these elements are defined as directional the correct voltage phase direction will be required to produce an operation of those elements. ©2012 Siemens Protection Devices Limited Chapter 6 Page 37 of 77...
  • Page 236: Directional Polarity

    Operate Current Operate Time D.O. (NI EI VI LTI, P.U. D.O. 2 x Is 5 x Is & DTL) (Amps) (Amps) (sec) (sec) TIMING TESTS Table 2.8-3 51G Results ©2012 Siemens Protection Devices Limited Chapter 6 Page 38 of 77...
  • Page 237 The Characteristic can be made non-directional by VT Supervision. This functionality should be checked. Element BI Inhibits VTS action Inrush Detector 51G-1 51G-2 51G-3 51G-4 50G-1 50G-2 50G-3 50G-4 Table 2.8-5 51G Element Blocking ©2012 Siemens Protection Devices Limited Chapter 6 Page 39 of 77...
  • Page 238 50% operate time time (calculated) (measured) Time time (measured) (expected) (calculated) (calculated) First test (c) Second Test (c) Table 2.8-7 Reset Results Check correct indication, trip output, alarm contacts, waveform record. ©2012 Siemens Protection Devices Limited Chapter 6 Page 40 of 77...
  • Page 239: Sensitive Earth Fault (67/50S,67/51S)

    Sensitive EF elements can be separated from Derived EF by secondary injection of current through the I input circuit only. If any of these elements are defined as directional the correct voltage phase direction will be required to produce an operation of those elements. ©2012 Siemens Protection Devices Limited Chapter 6 Page 41 of 77...
  • Page 240: Directional Polarity

    Operate Current Operate Time D.O. (NI EI VI LTI, P.U. D.O. 2 x Is 5 x Is & DTL) (Amps) (Amps) (sec) (sec) TIMING TESTS Table 2.9-3 51SEF Results ©2012 Siemens Protection Devices Limited Chapter 6 Page 42 of 77...
  • Page 241 VT Supervision. This functionality should be checked. Element BI Inhibits VTS action 51SEF-1 51SEF-2 51SEF-3 51SEF-4 50SEF-1 50SEF-2 50SEF-3 50SEF-4 Table 2.9-5 51SEF Element Blocking ©2012 Siemens Protection Devices Limited Chapter 6 Page 43 of 77...
  • Page 242 50% operate (expected) (calculated) (measured) Time time time (calculated) (calculated) (measured) First test (c) Second Test (c) Table 2.9-7 Reset Results Check correct indication, trip output, alarm contacts, waveform record. ©2012 Siemens Protection Devices Limited Chapter 6 Page 44 of 77...
  • Page 243: Restricted Earth Fault (64H)

    Since the DTL setting is generally small the pick-up setting can be tested by gradually increasing current until element operates. The relay should be disconnected from the current transformers for this test. Apply 2x setting current if possible and record operating time ©2012 Siemens Protection Devices Limited Chapter 6 Page 45 of 77...
  • Page 244 The Restricted Earth Fault element can be blocked by Binary Input Inhibit. This functionality should be checked. Element BI Inhibits Table 2.10-4 64H Inhibit Check correct indication, trip output, alarm contacts, waveform record. Check that any shorting links are removed after testing. ©2012 Siemens Protection Devices Limited Chapter 6 Page 46 of 77...
  • Page 245: Negative Phase Sequence Overcurrent (46Nps)

    NPS Overcurrent can be tested using a normal 3P balanced source. Two phase current connections should be reversed so that the applied balanced 3P current is Negative Phase Sequence. ©2012 Siemens Protection Devices Limited Chapter 6 Page 47 of 77...
  • Page 246: Definite Time Nps Overcurrent (46Dt)

    1.30 Table 2.11-3 Standard Timings Note that the operate time may be subject to the Minimum op time setting for the element and/or may have a Follower DTL applied. ©2012 Siemens Protection Devices Limited Chapter 6 Page 48 of 77...
  • Page 247 The NPS Overcurrent elements can be blocked by Binary Input Inhibit. This functionality should be checked. Element BI Inhibits 46IT 46DT Table 2.11-6 Element Blocking Check correct indication, trip output, alarm contacts, waveform record. When testing is complete reinstate any of the disabled functions. ©2012 Siemens Protection Devices Limited Chapter 6 Page 49 of 77...
  • Page 248: Undercurrent (37)

    Testing of this element phase by phase may cause inadvertent operation of the 46 NPS Overcurrent elements. Apply 0.5x setting current and record operating time Phas P.U. Current Tolerance Operate Time Tolerance (Amps) (sec) Amps 0.5 x Is Table 2.12-1 37 Results ©2012 Siemens Protection Devices Limited Chapter 6 Page 50 of 77...
  • Page 249 The Undercurrent elements can be blocked by Binary Input Inhibit. This functionality should be checked. Element BI Inhibits 37-1 37-2 Table 2.12-2 Element Blocking Check correct indication, trip output, alarm contacts, waveform record. ©2012 Siemens Protection Devices Limited Chapter 6 Page 51 of 77...
  • Page 250: Thermal Overload (49)

    The following table lists operate times for a range of Time Constant Settings for an applied current of 2x the Thermal Overload setting. Ensure that the thermal rating of the relay is not exceeded during this test. ©2012 Siemens Protection Devices Limited Chapter 6 Page 52 of 77...
  • Page 251 Table 2.13-3 Capacity Alarm 2.13.1.1 Element Blocking The Thermal element can be blocked by Binary Input Inhibit. This functionality should be checked. Element BI Inhibits Table 2.13-4 Element Blocking ©2012 Siemens Protection Devices Limited Chapter 6 Page 53 of 77...
  • Page 252: Over/Under Voltage

    Connect the relevant output contact(s) to stop the test set. Step the applied voltage to a level below the setting. The test set should be stopped at the operate time setting +/-5% Test inputs VL2 and VL3 by repeating the above if necessary. ©2012 Siemens Protection Devices Limited Chapter 6 Page 54 of 77...
  • Page 253 The NPS Overcurrent elements can be blocked by Binary Input Inhibit and VT Supervision. This functionality should be checked. Element BI Inhibits VT Supervision 27/59-1 27/59-2 27/59-3 27/59-4 Table 2.14-2 Element Blocking When testing is complete reinstate any of the disabled functions. ©2012 Siemens Protection Devices Limited Chapter 6 Page 55 of 77...
  • Page 254: Undervoltage Guard (27/59Uvg)

    Figure 2.15-1 NPS Overvoltage Voltage Inputs: ), V ), V Current Inputs: n/a apply zero current to stabilize other functions Disable: 27/59, 59N, 60VTS Map Pickup LED: 47-n - Self Reset ©2012 Siemens Protection Devices Limited Chapter 6 Page 56 of 77...
  • Page 255 The NPS Overvoltage element can be blocked by Binary Input Inhibit. This functionality should be checked. Element BI Inhibits 47-1 47-2 Table 2.15-2 Element Blocking Check correct indication, trip output, alarm contacts, waveform record. ©2012 Siemens Protection Devices Limited Chapter 6 Page 57 of 77...
  • Page 256: Neutral Overvoltage (59N)

    Apply 2x setting voltage if possible and record operating time Phase P.U. Current Operate Time Tolerence (Volts) (sec) Volts 2 x Vs Table 2.16-1 59NDT Test Results Check correct indication, trip output, alarm contacts, waveform record. ©2012 Siemens Protection Devices Limited Chapter 6 Page 58 of 77...
  • Page 257: Inverse Time (59Nit)

    Element BI Inhibits 59NIT 59NDT Table 2.16-3 59N Element Blocking Check correct indication, trip output, alarm contacts, waveform record. When testing is complete reinstate any of the disabled functions. ©2012 Siemens Protection Devices Limited Chapter 6 Page 59 of 77...
  • Page 258: Section 3: Supervision Functions

    Repeat the sequence with current at 90% of the 50BF Setting current level after the element trip and check for no CB Fail operation. Repeat the sequence by injecting the current to I4 and using the 50BF-I4 Setting. ©2012 Siemens Protection Devices Limited Chapter 6 Page 60 of 77...
  • Page 259: Element Blocking

    50BF Mech Trip 3.1.1 Element Blocking The CB Fail function can be blocked by Binary Input Inhibit. This functionality should be checked. Element BI Inhibits 50BF Table 3.1-3 50BF Element Blocking ©2012 Siemens Protection Devices Limited Chapter 6 Page 61 of 77...
  • Page 260: Voltage Transformer Supervision (60Vts)

    3x the 60VTS I setting. Reduce voltage as above and check for VTS operation 60VTS I Setting Setting x 3 110% of Setting x 3 90% of Setting x 3 No VTS □ VTS operation □ Table 3.2-2 60VTS Current Setting ©2012 Siemens Protection Devices Limited Chapter 6 Page 62 of 77...
  • Page 261: Phase Vt Fail

    Not Applicable □ 3.2.2.1 Element Blocking The VT Supervision can be blocked by Binary Input Inhibit. This functionality should be checked. Element BI Inhibits 60VTS Table 3.2-4 60VTS Element Blocking ©2012 Siemens Protection Devices Limited Chapter 6 Page 63 of 77...
  • Page 262: Current Transformer Supervision (60Cts)

    Measure the delay to operation. Gradually reduce the 3Phase current until the element resets. Setting Measured 60CTS Delay 60CTS Inps 60CTS Vnps Table 3.3-1 7SR11 60CTS Test Results ©2012 Siemens Protection Devices Limited Chapter 6 Page 64 of 77...
  • Page 263: 7Pg2114 & 7Pg2116

    Reduce the 3P voltage to cause CTS operation again. Gradually reduce the 3P current until the element resets. Setting Measured 60CTS Delay 60CTS Inps 60CTS Vnps Table 3.3-2 7SR12 60CTS Test Results ©2012 Siemens Protection Devices Limited Chapter 6 Page 65 of 77...
  • Page 264: Broken Conductor (46Bc)

    NPS to PPS will also increase. The levels of each sequence component current can be monitored in the Current Meters in Instruments Mode. ©2012 Siemens Protection Devices Limited Chapter 6 Page 66 of 77...
  • Page 265 46BC Operate Time 3.4.1.1 Element Blocking The Broken Conductor element can be blocked by Binary Input Inhibit. This functionality should be checked. Element BI Inhibits 46BC Table 3.4-4 46BC Element Blocking ©2012 Siemens Protection Devices Limited Chapter 6 Page 67 of 77...
  • Page 266: Trip/Close Circuit Supervision (74T/Ccs)

    The T/CCS-n Delay can be initiated by applying an inversion to the relevant status input and measured by monitoring of the alarm output. TCS-n Delay setting Measured CCS-n Delay setting Measured Table 3.5-1 74T/CCS Test Results ©2012 Siemens Protection Devices Limited Chapter 6 Page 68 of 77...
  • Page 267: Magnetising Inrush Detector (81Hbl)

    ), I ), I Disable: Map Pickup LED: Logical operation of the harmonic blocking can be tested by current injection at 100Hz to cause operation of the blocking signals. ©2012 Siemens Protection Devices Limited Chapter 6 Page 69 of 77...
  • Page 268: Section 4: Control & Logic Functions

    The function of the Quick Logic equations should be tested conjunctively with connected plant or by simulation to assess suitability and check for correct operation on an individual basis with tests specifically devised to suit the particular application. ©2012 Siemens Protection Devices Limited Chapter 6 Page 70 of 77...
  • Page 269: Section 5: Testing And Maintenance

    Numeric module failure will be indicated by the ‘Protection Healthy’ LED being off or flashing. A message may also be displayed on the LCD. In the event of failure Siemens Protection Devices Ltd. (or one of its agents) should be contacted The relay should be returned as a complete unit.
  • Page 270 Table 5.3-1 Troubleshooting Guide If the above checklist does not help in correcting the problem please contact the local Siemens office or contact PTD 24hr Customer Support, Tel: +49 180 524 7000, Fax: +49 180 524 2471, e-mail: support.energy@siemens.com.
  • Page 271: Section 6: Pilot Supervision Equipment

    Tests of Pilot Supervision Relays Overall Tests of Pilot Supervision Equipment Stability Tests 6.3.1 Check of connections Make a general check of connections as described in the appropriate Operating Recommendations ©2012 Siemens Protection Devices Limited Chapter 6 Page 73 of 77...
  • Page 272: Secondary Wiring Insulation Resistance Tests

    Test of guard relays (where fitted) If it has not been possible to check the operation of the guard relays by primary injection then the following tests should be done. ©2012 Siemens Protection Devices Limited Chapter 6 Page 74 of 77...
  • Page 273: Test Of Pilot Supervision Supply Failure Relay (Where Fitted)

    Check that the pilot supervision receive relay operates and that the current recorded by the d.c. milli-ammeter in the pilots is not less than 4 milli-amperes. Check the correct operation of the scheme by doing the following tests:- ©2012 Siemens Protection Devices Limited Chapter 6 Page 75 of 77...
  • Page 274: Stability Tests

    Pilots to A17/19 Remote End A21/23 28 3 26 10 24 4 27 9 Send Equipment AC Schematic Diagram Supervision Supply Fail relay B22 Figure 6.3-2 Pilot Supervision Send Equipment ©2012 Siemens Protection Devices Limited Chapter 6 Page 76 of 77...
  • Page 275 Solkor R connections are shown in the relay Installation Recommendations. An “E” above the connections indicates the Epsilon case terminal numbers. A “V” above the connections indicates the Vedette case terminal numbers. ©2012 Siemens Protection Devices Limited Chapter 6 Page 77 of 77...
  • Page 276: The Copyright And Other Intellectual Property Rights In This Document, And In Any Model Or Article Produced From It

    Limited. No part of this document shall be reproduced or modified or stored in another form, in any data retrieval system, without the permission of Siemens Protection Devices Limited, nor shall any model or article be reproduced from this document unless Siemens Protection Devices Limited consent.
  • Page 277 Settings Guidelines ......................... 42 6.2 Current Transformer Supervision ......................44 6.3 Voltage Transformer Supervision (60VTS) ................... 45 6.4 Trip/Close Circuit Supervision (74T/CCS)..................... 46 6.4.1 Trip Circuit Supervision Connections ..................46 ©2010 Siemens Protection Devices Limited Chapter 7 Page 2 of 49...
  • Page 278 Table 6-2 Determination of VT Failure (1 or 2 Phases) ................... 45 Table 6-3 Determination of VT Failure (3 Phases) ..................45 Table 6-4 Magnetic Inrush Bias ........................48 ©2010 Siemens Protection Devices Limited Chapter 7 Page 3 of 49...
  • Page 279: Section 1: Pilot Wire Current Differential Scheme

    System Frequency (50/60Hz) (used for B22 relay setting) Send or Receive End Insulation level (5/15kV) Auxiliary DC supply Intertripping Intertripping is not compatible with 7PG2113/4/5/6 used as Guard Relays ©2010 Siemens Protection Devices Limited Chapter 7 Page 4 of 49...
  • Page 280: Equipment Options

    15kV B75 relay, 1 per circuit B74 relay, 1 per circuit Note: Although the 5kV scheme utilises a combined B75/B74 unit, the additional isolation requirements at 15kV necessitate that separate units must be used. ©2010 Siemens Protection Devices Limited Chapter 7 Page 5 of 49...
  • Page 281: Application Diagrams

    Figure 1.4-1 Installation with Existing Solkor R, Rf or R/Rf relay. Figure 1.4-2 Standard 5kV Solkor R/Rf with Guard. Figure 1.4-3 Installation with existing 15kV Plain Solkor Rf with Guard. ©2010 Siemens Protection Devices Limited Chapter 7 Page 6 of 49...
  • Page 282 7PG2113/4/5/6 Solkor Applications Guide Figure 1.4-4 5kV Solkor Rf with Pilot Supervision. Figure 1.4-5 15kV Solkor Rf with Pilot Supervision. ©2010 Siemens Protection Devices Limited Chapter 7 Page 7 of 49...
  • Page 283: Essential External Wiring And Settings

    Guard but high enough to operate the differential protection. Time delay settings can be applied to avoid nuisance indications. Figure 1.5-1 Interconnection Wiring ©2010 Siemens Protection Devices Limited Chapter 7 Page 8 of 49...
  • Page 284: Description Of Typical Setting File

    This gives an alarm that the Solkor has tripped without the Guard E1 (=87L without This could indicate pilot open circuit Guard) (note that a fault occurs below the Guard setting but above the Rf setting will create an alarm) ©2010 Siemens Protection Devices Limited Chapter 7 Page 9 of 49...
  • Page 285 Operated by Backup EF & Guard EF, Self reset to match A,B&C indications Guard Override (Yellow) Self reset, follows binary input Backup inhibited (Yellow) Self reset, follows binary input ©2010 Siemens Protection Devices Limited Chapter 7 Page 10 of 49...
  • Page 286: Application Considerations

    It is also apparent that the effects are not easily analysed or modelled and thus in- service experience is the most reliable basis in deciding which types of pilot will be satisfactory. ©2010 Siemens Protection Devices Limited Chapter 7 Page 11 of 49...
  • Page 287: Pilot Supervision

    Injection Intertripping is generally difficult to apply successfully in conjunction with Overcurrent Guard relays since the remote Guard relay will block operations resulting from intertrip injection if the remote end CT current is below the Guard setting. ©2010 Siemens Protection Devices Limited Chapter 7 Page 12 of 49...
  • Page 288: Capacitive Charging Currents

    CTs will fail to cancel if the CTs are mismatched or if saturation occurs to different extents. This current may be higher than the through fault level upon which the CTs are usually sized ©2010 Siemens Protection Devices Limited Chapter 7 Page 13 of 49...
  • Page 289: Section 2: Additional Functions

    2 to reflect new load and fault currents RADIAL SUBSTATION Non-essential loads Figure 2.1-1 Example Use of Alternative Settings Groups The Current Differential protection has fixed settings which cannot be adjusted by settings groups. ©2010 Siemens Protection Devices Limited Chapter 7 Page 14 of 49...
  • Page 290: Binary Inputs

    LED indication and also have a parallel connection wired to directly trip the circuit via a blocking diode, see fig. 1.2-1: Figure 2.2-1 Example of Transformer Alarm and Trip Wiring ©2010 Siemens Protection Devices Limited Chapter 7 Page 15 of 49...
  • Page 291: The Effects Of Capacitance Current

    1.2-2. 2.2.3 AC Rejection The default pick-up time delay of 20ms provides immunity to ac current e.g. induced from cross site wiring. ©2010 Siemens Protection Devices Limited Chapter 7 Page 16 of 49...
  • Page 292 7PG2113/4/5/6 Solkor Applications Guide Figure 2.2-2 Binary Input Configurations Providing Compliance with EATS 48-4 Classes ESI 1 and ESI 2 ©2010 Siemens Protection Devices Limited Chapter 7 Page 17 of 49...
  • Page 293: Binary Outputs

    LEDs are used to display features which routinely change state, such as Circuit-Breaker open or close. The status of hand reset LEDs is retained in capacitor-backed memory in the event of supply loss. ©2010 Siemens Protection Devices Limited Chapter 7 Page 18 of 49...
  • Page 294: Section 3: Protection Functions

    100.00 10.00 10.00 1.00 1.00 0.10 0.10 0.01 0.01 1000 1000 Current (x Is) Current (x Is) Figure 3.1-1 IEC NI Curve with Time ultiplier and Follower DTL Applied ©2010 Siemens Protection Devices Limited Chapter 7 Page 19 of 49...
  • Page 295: Selection Of Overcurrent Characteristics

    The characteristic curve shape is selected to be the same type as the other relays on the same circuit or to grade with items of plant e.g. fuses or earthing resistors. The application of IDMTL characteristic is summarised in the following table: ©2010 Siemens Protection Devices Limited Chapter 7 Page 20 of 49...
  • Page 296: Reset Delay

    Figure 3.1-3 Reset Delay ©2010 Siemens Protection Devices Limited Chapter 7 Page 21 of 49...
  • Page 297: Voltage Dependent Overcurrent (51V)

    The relay will revert to its usual settings (51-n) after elapse of the cold load period. This is determined either by a user set delay, or by the current in all 3-phases falling below a set level (usually related to normal load levels) for a user set period. ©2010 Siemens Protection Devices Limited Chapter 7 Page 22 of 49...
  • Page 298: Instantaneous Overcurrent (50/50G/50N)

    LV side has a much lower level of fault current. The 50-n elements have a very low transient overreach i.e. their accuracy is not appreciably affected by the initial dc offset transient associated with fault inception. ©2010 Siemens Protection Devices Limited Chapter 7 Page 23 of 49...
  • Page 299: Directional Protection (67)

    A number of studies have been made to determine the optimum MTA settings e.g. W.K Sonnemann’s paper “A Study of Directional Element Connections for Phase Relays”. Figure 2.6-1 shows the most likely fault angle for phase faults on Overhead Line and Cable circuits. ©2010 Siemens Protection Devices Limited Chapter 7 Page 24 of 49...
  • Page 300 Note that the relays may be programmed with forward, reverse and non-directional elements simultaneously when required by the protection scheme. Load Figure 3.5-3 Application of Directional Overcurrent Protection ©2010 Siemens Protection Devices Limited Chapter 7 Page 25 of 49...
  • Page 301: Out Of 3 Logic

    OVERCURRENT> 67 2-out-of-3 Logic = ENABLED Enabling 2-out-of-3 logic will prevent operation of the directional phase fault protection for a single phase to earth fault. Dedicated earth-fault protection should therefore be used if required. ©2010 Siemens Protection Devices Limited Chapter 7 Page 26 of 49...
  • Page 302: Directional Earth-Fault (50/51G, 50/51N, 51/51Sef)

    Characteristic Angle will change if NPS Polarising is used. Once again the fault angle is completely predictable, though this is a little more complicated as the method of earthing must be considered. Figure 3.6-1 Earth Fault Angles ©2010 Siemens Protection Devices Limited Chapter 7 Page 27 of 49...
  • Page 303: High Impedance Restricted Earth Fault Protection (64H)

    The calculation of the value of the Stability Resistor is based on the worst case where one CT fully saturates and the other balancing CT does not saturate at all. A separate Siemens Protection Devices Limited Publication is available covering the calculation procedure for REF protection. To summarise this: The relay Stability (operating) Vs voltage is calculated using worst case lead burden to avoid relay operation for through-fault conditions where one of the CTs may be fully saturated.
  • Page 304: Negative Phase Sequence Overcurrent (46Nps)

    Their withstand is specified in two parts; continuous capability based on a figure of I , and short time capability based on a constant, K, where K = (I t. NPS overcurrent protection is therefore configured to match these two plant characteristics. ©2010 Siemens Protection Devices Limited Chapter 7 Page 29 of 49...
  • Page 305: Undercurrent (37)

    Phase Overcurrent. An Alarm is provided for θ at or above a set % of capacity to indicate that a potential trip condition exists and that the system should be scrutinised for abnormalities. ©2010 Siemens Protection Devices Limited Chapter 7 Page 30 of 49...
  • Page 306: Under/Over Voltage Protection (27/59)

    DTL also prevents operation during transient disturbances. The use of IDMTL protection is not recommended because of the difficulty of choosing settings to ensure correct co-ordination and security of supply. ©2010 Siemens Protection Devices Limited Chapter 7 Page 31 of 49...
  • Page 307: Neutral Overvoltage (59N)

    Typically NVD protection measures the residual voltage (3V ) directly from an open delta VT or from capacitor cones – see fig. 2.13-2 below. Figure 3.12-2 NVD Protection Connections ©2010 Siemens Protection Devices Limited Chapter 7 Page 32 of 49...
  • Page 308: Application With Capacitor Cone Units

    Remedial action can then be taken, such as introducing a Balancer network of capacitors and inductors. Very high levels of NPS Voltage indicate incorrect phase sequence due to an incorrect connection. ©2010 Siemens Protection Devices Limited Chapter 7 Page 33 of 49...
  • Page 309: Section 4: Ct Requirements

    The remote end fault level will be distorted by any parallel infeed or backfeed and is only equivalent to the through fault level for truly radial systems. The following example shows a simple through fault current estimate based on Busbar levels and commonly available data. ©2010 Siemens Protection Devices Limited Chapter 7 Page 34 of 49...
  • Page 310: Example Fault Current Estimation

    = 33000/√3 = 19.05kV Fault level per phase = 1000/3 = 333MVA 333x10 17.5kA 19.05kV 19.05x10 17.5kA Ω Also, since X/R at the busbar = 20, We can evaluate the source impedance: ©2010 Siemens Protection Devices Limited Chapter 7 Page 35 of 49...
  • Page 311 Through Fault Current = 19.05x10 4.68kA 4.071 Through fault current = 4.68kA compared to 17.5kA Busbar fault current due to the effect of the line impedance. 19.05kV 17.5kA 4.68kA ©2010 Siemens Protection Devices Limited Chapter 7 Page 36 of 49...
  • Page 312: Ct Requirements For Overcurrent And Earth Fault Protection

    Where the REF function is used then this dictates that the other protection functions are also used with class PX CTs. A full explanation of how to specify CTs for use with REF protection, and set REF relays is available on our website: www.siemens.com/energy. ©2010 Siemens Protection Devices Limited Chapter 7 Page 37 of 49...
  • Page 313: Section 5: Control Functions

    For this reason each relay in an ARC scheme must be set with identical Instantaneous and Delayed sequence of trips. Figure 5.1-1 Sequence Co-ordination ©2010 Siemens Protection Devices Limited Chapter 7 Page 38 of 49...
  • Page 314: Auto-Reclose Example 1

    79 E/F Prot’n Trip 1 : Delayed 79 E/F Prot’n Trip 2 : Delayed 79 E/F Delayed Trips to Lockout : 3 Note that Instantaneous’ trips are inhibited if the shot is defined as ‘Delayed’ ©2010 Siemens Protection Devices Limited Chapter 7 Page 39 of 49...
  • Page 315: Auto-Reclose Example 2 (Use Of Quicklogic With Ar)

    OUTPUT CONFIG>OUTPUT MATRIX: 51-1 = V1 OUTPUT CONFIG>OUTPUT MATRIX: 50-2 = V2 OUTPUT CONFIG>OUTPUT MATRIX: E1 = V3 CONTROL & LOGIC>QUICK LOGIC: E1 = V1.!V2 INPUT CONFIG>INPUT MATRIX: 79 Lockout = V3 ©2010 Siemens Protection Devices Limited Chapter 7 Page 40 of 49...
  • Page 316: Quick Logic Applications

    CONTROL & LOGIC>QUICK LOGIC: E1 = I1.I2.V1 If required a time delay can be added to the output using the CONTROL & LOGIC > QUICK LOGIC: E1 Pickup Delay setting . ©2010 Siemens Protection Devices Limited Chapter 7 Page 41 of 49...
  • Page 317: Section 6: Supervision Functions

    Any binary input can be mapped to this input, if it is energised when a trip initiation is received an output will be given immediately (the timers are by passed). ©2010 Siemens Protection Devices Limited Chapter 7 Page 42 of 49...
  • Page 318 Operation ms from occuri CB Operate Time Stage 1 CBF Timer (Retrip) = 120ms Stage 2 CBF Timer (Backtrip) = 250ms Figure 6.1-3 Two Stage Circuit Breaker Fail Timing ©2010 Siemens Protection Devices Limited Chapter 7 Page 43 of 49...
  • Page 319: Current Transformer Supervision

    Operation is subject to a time delay to prevent operation for transitory effects. A 3-phase CT failure is considered so unlikely (these being independent units) that this condition is not tested for. ©2010 Siemens Protection Devices Limited Chapter 7 Page 44 of 49...
  • Page 320: Voltage Transformer Supervision (60Vts)

    For this reason, the relay allows these protection elements - under-voltage, directional over-current, etc. - to be inhibited if a VT failure occurs. ©2010 Siemens Protection Devices Limited Chapter 7 Page 45 of 49...
  • Page 321: Trip/Close Circuit Supervision (74T/Ccs)

    Scheme 1 provides full Trip supervision with the circuit breaker Open or Closed. Where a ‘Hand Reset’ Trip contact is used measures must be taken to inhibit alarm indications after a CB trip. ©2010 Siemens Protection Devices Limited Chapter 7 Page 46 of 49...
  • Page 322 R = 3K3 typical BO 1 BO n Remote Alarm 7SR24 Figure 6.4-3 Trip Circuit Supervision Scheme 3 (H7) cheme 3 provides full Trip supervision with the circuit breaker Open or Closed. ©2010 Siemens Protection Devices Limited Chapter 7 Page 47 of 49...
  • Page 323 NPS (unbalance) current present. An NPS / PPS ratio > 50% will result from a Broken Conductor condition. Operation is subject to a time delay to prevent operation for transitory effects. ©2010 Siemens Protection Devices Limited Chapter 7 Page 48 of 49...
  • Page 324 Typically estimates obtained from previous circuit-breaker maintenance schedules or manufacturers data sheets are used for setting these alarm levels. The relay instrumentation provides the current values of these counters. ©2010 Siemens Protection Devices Limited Chapter 7 Page 49 of 49...
  • Page 325 Printed in Fürth Printed on elementary chlorine-free bleached paper. All rights reserved. Trademarks mentioned in this document are the property of Siemens AG, its affili- ates, or their respective owners. Subject to change without prior notice. The information in this document contains general descriptions of the technical options available, which may not apply in all cases.

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