micom p433,p435(technical manual2) (pdf, 2884kb)

MiCOM P433, P435

Distance Protection Devices

P43x/EN M/Am7

Version P433 -308 -410/411 -612 P433 -308 -410/411 -614 P433 -308 -410/411 -615 P433 -308 -410/411 -630 P433 -308 -410/411 -631

P435 -308 -413/414/415 -612 P435 -308 -413/414/415 -614 P435 -308 -413/414/415 -615 P435 -308 -413/414/415 -630 P435 -308 -413/414/415 -631

Technical Manual Content P43x/EN M/Ac7 (-612) P43x/EN AD/Ae7 (-614) P43x/EN AD/Af7 (-615) P43x/EN AD/Ak7 (-630) P43x/EN AD/Am7 (-631)

Volume 2 of 2

MiCOM P433, P435


P43x/EN M/Ac7 (AFSV.12.10220 D) Version P433 -308 -410/411 -612 P435 -308 -413/414/415 -612

Technical Manual Volume 2 of 2

Appendix

P43x/EN M/Ac7 // AFSV.12.10220 D /// P433-308-410/411-612 // P435-308-413/414/415-612 AN-1

A Glossary

B Signal List

C List of Bay Types

D Overview of Changes

Terminal Connection Diagrams: See Chapter 5 “Installation and Connection”.

Appendix (continued)

AN-2 P43x/EN M/Ac7 // AFSV.12.10220 D /// P433-308-410/411-612 // P435-308-413/414/415-612

A Glossary A-1A 1 Function Groups A-1A 2 Modules A-2A 3 Symbols A-3A 4 Examples of Signal Names A-10A 5 Symbols used A-11

B List of Signals B-1B 1 Internal Signal Names B-1B 2 Telecontrol Interface per EN 60870-5-101 or

IEC 870-5-101 (Companion Standard) B-7

B 2.1 Interoperability B-7B 2.1.1 Network Configuration (Network-Specific Parameters) B-7B 2.1.2 Physical Layer (Network-Specific Parameters) B-8B 2.1.3 Link Layer (Network-Specific Parameters) B-9B 2.1.4 Application Layer B-10B 2.1.5 Basic Application Functions B-16

B 3 Communication Interface per IEC 60870-5-103 B-19B 3.1 Interoperability B-19B 3.1.1 Physical Layer B-19B 3.1.1.1 Electrical Interface B-19B 3.1.1.2 Optical Interface B-19B 3.1.1.3 Transmission Rate B-18B 3.1.2 Link Layer B-20B 3.1.3 Application Layer B-20B 3.1.3.1 Transmission Mode for Application Data B-20B 3.1.3.2 Common Address of ASDU B-20B 3.1.3.3 Selection of Standard Information Numbers in Monitor

Direction B-20

B 3.1.3.3.1 System Functions in Monitor Direction B-20B 3.1.3.3.2 Status Indications in Monitor Direction B-21B 3.1.3.3.3 Monitoring Signals (Supervision Indications) in Monitor

Direction B-22

B 3.1.3.3.4 Earth Fault Indications in Monitor Direction B-23B 3.1.3.3.5 Fault Indications in Monitor Direction B-24B 3.1.3.3.6 Auto-Reclosure Indications in Monitor Direction B-26B 3.1.3.3.7 Measured values in Monitor Direction B-26B 3.1.3.3.8 Generic Functions in Monitor Direction B-27B 3.1.3.4 Selection of Standard Information Numbers in Control

Direction B-28

B 3.1.3.4.1 System Functions in Control Direction B-28B 3.1.3.4.2 General Commands in Control Direction B-28B 3.1.3.4.3 Generic Functions in Control Direction B-29B 3.1.3.5 Basic Application Functions B-30B 3.1.3.6 Miscellaneous B-30

C List of Bay Types C-1

D Upgrade overview for P433 and P435 D-1

Appendix A - Glossary

P43x/EN M/Ac7 // AFSV.12.10220 D /// P433-308-410/411-612 // P435-308-413/414/415-612 A-1

A 1 Function Groups

P433 P435 ARC: Auto-Reclosing Control X X ASC: Automatic Synchronism Check X X BUOC: Backup Overcurrent-Time Protection (BUOC) X X CBF: Circuit Breaker Failure Protection X X CMD_1: Single-Pole Commands X X COMM1: Communication Interface 1 X X COMM2: Communication Interface 2 X X COMM3: Communication Interface 3 X X DEV01 to

DEV03: External devices X X

DIST: Distance Protection X X DTOC: Definite-Time Overcurrent Protection X X DVICE: Device X X F_KEY: Function keys X X f<>: Over-/Underfrequency Protection X X FT_DA: Fault Data Acquisition X X FT_RC: Fault Recording X X GF_DA: Ground Fault Data Acquisition X X GF_RC: Ground Fault Recording X X GFDSS: Ground Fault Direction Determination Using Steady-State

Values X X

GFSC: Ground Fault (Short-Circuit) Protection X GFSIG: Ground Fault Protective Signaling X X GFTRP: Ground Fault Tripping X X GSCSG: Ground Fault (Short-Circuit) Protection Signaling X IDMT: Inverse-Time Overcurrent Protection X X ILOCK: Interlocking Logic X X INP: Binary Input X X IRIGB: IRIG-B interface X X LED: LED Indicators X X LIMIT: Limit Value Monitoring X X LOC: Local Control Panel X X LOGIC: Logic X X MAIN: Main Function X X MCMON: Measuring-Circuit Monitoring X X MEASI: Measured Data Input X X MEASO: Measured Data Output X X MT_RC: Monitoring Signal Recording X X OL_DA: Overload Data Acquisition X X OL_RC: Overload Recording X X OP_RC: Operating Data Recording X X OUTP: Binary Outputs X X P<>: Power Directional Protection X X PC: PC Link X X PSB: Power Swing Blocking X X PSIG: Protective Signaling X X PSS: Parameter Subset Selection X X SFMON: Self-Monitoring X X SIG_1: Single-Pole Signals X X SOTF: Switch on to Fault Protection X X TGFD: Transient Ground Fault Direction Determination X X THERM: Thermal Overload Protection X X V<>: Time-Voltage Protection X X

Appendix A - Glossary (continued)

A-2 P43x/EN M/Ac7 // AFSV.12.10220 D /// P433-308-410/411-612 // P435-308-413/414/415-612

A 2 Modules

A: Communication module B: Digital bus module L: MMI module P: Processor module T: Transformer module V: Power supply module X: Binary I/O module Y: Analog I/O module



A 3 Symbols

Graphic symbols for block diagrams Binary elements in compliance with DIN 40900 part 12, September 1992, IEC 617-12: modified 1991 Analogue information processing in compliance with DIN 40900 part 13, January 1981 To document the linking of analogue and binary signals, additional symbols have been used, taken from several DIN documents. As a rule, direction of the signal flow is from left to right and from top to bottom. Other flow directions are marked by an arrow. Input signals are listed on the left side of the signal flow, output signals on the right side.

Symbol Description

=

To obtain more space for representing a group of related elements, contours of the elements may be joined or cascaded if the following rules are met: There is no functional linkage between elements whose common contour line is oriented in the signal flow direction. Note: This rule does not necessarily apply to configurations with two or more signal flow directions, such as for symbols with a control block and an output block. There exists at least one logical link between elements whose common contour line runs perpendicularly to the signal flow direction.

Components of a symbol A symbol consists of a contour or contour combination and one or more qualifiers.



Symbol Description

Control block A control block contains an input function common to several symbols. It is used for the collective setting of several trigger elements, for example.

Output block An output block contains an output function common to several symbols.

MAIN: Inom Device

[ 010 003 ]

D5Z08X5B

Settable control block The 6 digits in square brackets represent the address under which the function shown in the text is implemented.

MAIN: Inom Device

[ 010 003 ]

1.0

1.0: 1.0 A 5.0: 5.0 A

5.0

D5Z08X6B

Settable control block with function blocks The digits in the function block show the settings that are possible for this function. The text below the symbol assigns the corresponding unit or meaning to each setting.



Symbol Description

Static input Only the state of the binary input variable is effective.

Dynamic input Only the transition from value 0 to value 1 is effective.

Negation of an output The value up to the border line is negated at the output.

Negation of an input The input value is negated before the border line.

Dynamic input with negation Only the transition from value 1 to value 0 is effective.

AND element The output variable will be 1 only if all input variables are 1.

OR element The output variable will be 1 only if at least one input variable is 1.

Threshold element The output variable will be 1 only if at least two input variables are 1. The number in the symbol may be replaced by any other number.

(m out of n) element The output variable will be 1 only if just one input variable is 1. The number in the symbol may be replaced by any other number if the number of inputs is increased or decreased accordingly.



Symbol Description

Delay element The transition from value 0 to 1 at the output occurs after a time delay of t1 relative to the corresponding transition at the input. The transition from value 1 to 0 at the output occurs after a time delay of t2 relative to the corresponding transition at the input. t1 and t2 may be replaced by the actual delay values (in seconds or strobe ticks).

Monostable flip-flop The output variable will be 1 only if the input variable changes to 1. The output variable will remain 1 for 100 ms, regardless of the duration of the input value 1 (non-retriggerable). Without a 1 in the function block, the monostable flip-flop is retriggerable. The time is 100 ms in this example, but it may be changed to any other duration.

Analog-digital converter An analog input signal is converted to a binary signal.

Subtractor The output variable is the difference between the two input variables. A summing element is obtained by changing the minus sign to a plus sign at the symbol input.

Schmitt Trigger with binary output signal The binary output variable will be 1 if the input signal exceeds a specific threshold. The output variable remains 1 until the input signal drops below the threshold again.

Memory, general Storage of a binary or analog signal.



Symbol Description

Non-stable flip-flop When the input variable changes to 1, a pulse sequence is generated at the output. The ! to the left of the G indicates that the pulse sequence starts with the input variable transition (synchronized start). If there is a ! to the right of the G, the pulse sequence ends with the ending of the 1 signal at the input (synchronized stop).

Amplifier The output variable is 1 only if the input variable is also 1.

Band pass filter The output only transmits the 50 Hz component of the input signals. All other frequencies (above and below 50 Hz) are attenuated.

Counter At the + input the input variable transitions from 0 to 1 are counted and stored in the function block. At the R(eset) input a transition of the input variable from 0 to 1 resets the counter to 0.

Electromechanical drive in general, here a relay, for example.

Signal level converter with electrical isolation between input and output. L+ = pos. voltage input L- = neg. voltage input U1 = device identifier



Symbol Description

Input transformer with phase and item identifiers (according to DIN EN 60445) Phase identifiers for current inputs: for A: A1 and A2 for B: B1 and B2 for C: C1 and C2 for N: N1 and N2 Phase identifiers for voltage inputs via transformer 1: for A: 1U for B: 1V for C: 1W for N: 1N via transformer 2: for A: 2U for B: 2V Item identifiers for current transformers: for A: T1 for B: T2 for C: T3 for N: T4 for voltage transformer 1: for A: T5 for B: T6 for C: T7 for N: T8 for VG-N transformer: T90 for voltage transformer 2: for A: T15

Change-over contact with item identifier

Special symbol Output relay in normally-energized arrangement (‘closed-circuit operation’).



Symbol Description

PC interface with pin connections

Multiplier The output variable is the result of the multiplication of the two input variables.

Divider The output variable is the result of the division of the two input variables.

Comparator The output variable becomes 1 only if the input variable(s) are equal to the function in the function block.

Formula block The output variable becomes 1 only if the input variable(s) satisfy the equation in the function block



A 4 Examples of Signal Names

All settings and signals relevant for protection are shown in the block diagrams of Chapter 3 as follows:

Signal Name Description

FT_RC: Fault recording n 305 100

Internal signal names are not coded by a data model address. In the block diagrams they are marked with a diamond. The small figure underneath the signal name represents a code that is irrelevant to the user. The internal signal names used and their origins are listed in Appendix B.

DIST: VNG>> triggered [ 036 015 ]

Signal names coded by a data model address are represented by their address (shown in square brackets). Their origin is given in Chapters 7 and 8.

MAIN: General reset [ 003 002 ]

1: execute

A specific setting to be used later on is shown with its signal name, address, and the setting preceded by the setting arrow.



A 5 Symbols used

Symbol Meaning

t Time duration

V Voltage, potential difference

V Complex voltage

I Electrical current

I Complex current

Z Complex impedance

Z Modulus of complex impedance

f Frequency

δ Temperature in °C

Σ Sum, result

Ω Unit of electrical resistance

α Angle

ϕ Phase angle. With subscripts: specific angle between a defined current and a defined voltage.

τ Time constant

∆T Temperature difference in K

Appendix B - Signal List (continued)

P43x/EN M/Ac7 // AFSV.12.10220 D /// P433-308-410/411-612 // P435-308-413/414/415-612 B-1

B 1 Internal Signal Names

ARC: External trip A Fig. 3-236 ARC: 3-pole RRC Fig. 3-236 ARC: 3-pole transfer int. Fig. 3-236 ARC: CB closed Fig. 3-208, 3-222 ARC: Close command Fig. 3-218, 3-236 ARC: External trip Fig. 3-218 ARC: External trip B Fig. 3-236 ARC: External trip C Fig. 3-236 ARC: HSR A Fig. 3-236 ARC: HSR A-B-C Fig. 3-218, 3-236 ARC: HSR B Fig. 3-236 ARC: HSR C Fig. 3-236 ARC: Switch to tPmax Fig. 3-217, 3-235, 3-236 ARC: TDR Fig. 3-218, 3-236 ARC: TDR permitted Fig. 3-218, 3-236 ARC: Test HSR A, internal Fig. 3-230 ARC: Test HSR A-B-C int. Fig. 3-212 ARC: Test HSR B, internal Fig. 3-230 ARC: Test HSR C, internal Fig. 3-230 ARC: Trip time elapsed Fig. 3-210, 3-224 ARC: tRRC running Fig. 3-218, 3-236 ARC: V> for RRC triggered Fig. 3-214, 3-232 ARC: Zone extension HSR Fig. 3-216, 3-234 ARC: Zone extension RC Fig. 3-216, 3-234 ARC: Zone extension TDR Fig. 3-216, 3-234 ASC: AC active for DEV01 Fig. 3-249 ASC: Active Fig. 3-240 ASC: Close enable DEV01 AC Fig. 3-249 ASC: Close enable w.block Fig. 3-240 ASC: Close reject.w.block Fig. 3-240 ASC: Gen. close request Fig. 3-241 ASC: Manual close request Fig. 3-241 ASC: Select. meas.loop PG Fig. 3-238 ASC: Test Fig. 3-241 ASC: VMeas Fig. 3-238 BUOC: IA> triggered Fig. 3-169, 3-170 BUOC: IB> triggered Fig. 3-169, 3-170 BUOC: IC> triggered Fig. 3-169, 3-170 BUOC: IN> triggered Fig. 3-169, 3-170 BUOC: SN Fig. 3-169, 3-170 BUOC: Trip A Fig. 3-170 BUOC: Trip B Fig. 3-170 BUOC: Trip C Fig. 3-170 CBF: Start >1p Fig. 3-361 CBF: Start A Fig. 3-361 COMM1: Communication error Fig. 3-9, 3-10, 3-11, 3-13, 3-14, COMM1: Debounced signal Fig. 3-40

B-2 P43x/EN M/Ac7 // AFSV.12.10220 D /// P433-308-410/411-612 // P435-308-413/414/415-612

COMM1: Selected protocol Fig. 3-8 DEV01: Close cmd. rejection Fig. 3-386 DEV01: Close request Fig. 3-385 DEV01: Enable BI Close Fig. 3-386 DEV01: Enable BI Open Fig. 3-386 DEV01: Enable SI Close Fig. 3-387 DEV01: Enable SI Open Fig. 3-387 DEV01: End close command Fig. 3-390 DEV01: End open command Fig. 3-390 DEV01: Latching time elaps. Fig. 3-385 DEV01: Latching time runn. Fig. 3-385 DEV01: Open cmd. rejection Fig. 3-386 DEV01: Open request Fig. 3-385 DEV01: Protect. close cmd. Fig. 3-388 DEV01: Protection trip cmd. Fig. 3-388 DEV01: Switch. device runn. Fig. 3-390 DIST: φF Fig. 3-127 DIST: φX Fig. 3-127 DIST: φZ Fig. 3-129 DIST: Enable ZC-G starting Fig. 3-119 DIST: I>> triggered Fig. 3-114 DIST: I>>> triggered Fig. 3-114 DIST: IA>(Ibl) trigg. Fig. 3-117 DIST: IA>> triggered Fig. 3-114 DIST: IB>(Ibl) trigg. Fig. 3-117 DIST: IB>> triggered Fig. 3-114 DIST: IC>(Ibl) trigg. Fig. 3-117, 3-139 DIST: IC>> triggered Fig. 3-114 DIST: N1,bw Fig. 3-142 DIST: N1,fw Fig. 3-142 DIST: N2,bw Fig. 3-142 DIST: N2,fw Fig. 3-142 DIST: N3,bw Fig. 3-142 DIST: N3,fw Fig. 3-142 DIST: N4,bw Fig. 3-142 DIST: N4,fw Fig. 3-142 DIST: N5,bw Fig. 3-142 DIST: N5,fw Fig. 3-142 DIST: N6,bw Fig. 3-142 DIST: N6,fw Fig. 3-142 DIST: N7,bw Fig. 3-142 DIST: N7,fw Fig. 3-142 DIST: ºA-kG Fig. 3-121 DIST: ºB-kG Fig. 3-121 DIST: ºC-kG Fig. 3-121 DIST: ºkG Fig. 3-121 DIST: ºmeas Fig. 3-125 DIST: RF Fig. 3-135 DIST: Timer st. 1 elapsed Fig. 3-140



DIST: tIN> elapsed Fig. 3-115 DIST: tVNG>> elapsed Fig. 3-115 DIST: VA< triggered Fig. 3-118 DIST: VB< triggered Fig. 3-118 DIST: VC< triggered Fig. 3-118 DIST: VNG>> exceeded Fig. 3-115 DIST: VPP< triggered Fig. 3-118 DIST: XF Fig. 3-135 DIST: |¾meas| Fig. 3-131 DIST: φcorr Fig. 3-126 DIST: 1-pole starting Fig. 3-123 DIST: ARC blocked Fig. 3-148, 3-150, DIST: Dist.decision Z1 Fig. 3-134, 3-138 DIST: Dist.decision Z1,ze Fig. 3-134, 3-138 DIST: Enable V<, Z<, A Fig. 3-117 DIST: Enable V<, Z<, B Fig. 3-117 DIST: Enable V<, Z<, C Fig. 3-117 DIST: Enable ZA-B starting Fig. 3-119 DIST: Enable ZA-G starting Fig. 3-119 DIST: Enable ZB-C starting Fig. 3-119 DIST: Enable ZB-G starting Fig. 3-119 DIST: Enable ZC-A starting Fig. 3-119 DIST: Enable ZP-G Fig. 3-119 DIST: General starting Fig. 3-123 DIST: Multipole starting Fig. 3-123 DIST: Select.meas.loop A-B Fig. 3-125 DIST: Select.meas.loop A-G Fig. 3-125 DIST: Select.meas.loop B-C Fig. 3-125 DIST: Select.meas.loop B-G Fig. 3-125 DIST: Select.meas.loop C-A Fig. 3-125 DIST: Select.meas.loop C-G Fig. 3-125 DIST: Select.meas.loop P-G Fig. 3-125 DIST: Select.meas.loop P-P Fig. 3-125 DIST: Signal block start.G Fig. 3-157 DIST: Start. IN> triggered Fig. 3-115 DIST: Start. VNG> triggered Fig. 3-115 DIST: Start.ZPP< triggered Fig. 3-122 DIST: Starting A Fig. 3-123 DIST: Starting B Fig. 3-123 DIST: Starting blocked Fig. 3-113 DIST: Starting C Fig. 3-123 DIST: Starting G Fig. 3-116 DIST: Starting N1 Fig. 3-123 DIST: Trip enable zone 1 Fig. 3-157 DIST: Trip enable zone 1,A Fig. 3-157 DIST: Trip enable zone 1,B Fig. 3-157 DIST: Trip enable zone 1,C Fig. 3-157 DIST: Trip zone 1,ze Fig. 3-143, 3-146, 3-148, 3-150, 3-152,

3-154, 3-157


DIST: Trip zone 1 Fig. 3-143, 3-146, 3-148, 3-150, 3-152, 3-154, 3-157



DIST: Trip zone 4 Fig. 3-143, 3-148, 3-150, 3-152, 3-157 DIST: Trip zone 5 Fig. 3-143, 3-146, 3-148, 3-150, 3-152,

3-154, 3-157




DIST: VA-B (stored) Fig. 3-126 DIST: Vmeas Fig. 3-125 DIST: Voltage mem. enabled Fig. 3-126 DIST: ZA< start. triggered Fig. 3-122 DIST: ZB< start. triggered Fig. 3-122 DIST: ZC< start. triggered Fig. 3-122 DIST:Dist.decis.Z1 stored Fig. 3-134, 3-138 DTOC: IN Fig. 3-279 DTOC: Pulse prolong. runn. Fig. 3-284 DTOC: t2 N Fig. 3-284 f<>: fMeas Fig. 3-340 f<>: Vmeas Fig. 3-339 f<>: No. periods reached Fig. 3-340 FT_DA: Outp. fault location Fig. 3-106 FT_DA: Output meas. values Fig. 3-106 GFDSS: ¼NG filtered Fig. 3-301 GFDSS: IN> triggered Fig. 3-305 GFDSS: ºN filtered Fig. 3-305 GFDSS: VNG Fig. 3-300 GFDSS: Direction BS Fig. 3-301 GFDSS: Direction LS Fig. 3-301 GFDSS: Op. delay IN elapsed Fig. 3-305 GFDSS: P Fig. 3-301 GFDSS: Q Fig. 3-301 GFDSS: VNG> triggered Fig. 3-301 GFDSS: VNG> triggered Fig. 3-301 GFSC: ¼NG filtered Fig. 3-253 GFSC: ºN filtered Fig. 3-253 GFSC: Curr.-dep. trip sig. Fig. 3-261 GFSC: Volt.-dep. trip sig. Fig. 3-256 GFSC: Voltage present Fig. 3-253 GSCSG: Frequ.mon. triggered Fig. 3-268 GSCSG: Send internal signal Fig. 3-270, 3-271, 3-274, 3-275 GSCSG: Trip A Fig. 3-273 GSCSG: Trip B Fig. 3-273 GSCSG: Trip C Fig. 3-273



GSCSG: Bl. PSIG weak infeed Fig. 3-270 GSCSG: Blocking ARC Fig. 3-273 GSCSG: Transient blocking Fig. 3-269 IDMT: ºmeas Fig. 3-288 LOC: Remote&local control Fig. 3-6 LOGIC: Output n Fig. 3-378, 3-379, 3-380, 3-381, 3-382 LOGIC: Output n (t) Fig. 3-378, 3-379, 3-380, 3-381, 3-382 MAIN: Σ(VPG)/3 Fig. 3-49 MAIN: Trip A Fig. 3-74 MAIN: Trip B Fig. 3-74 MAIN: Trip C Fig. 3-74 MAIN: Trip signal Fig. 3-72 MAIN: Trip signal 1 Fig. 3-73, 3-75 MAIN: 1-pole trip Fig. 3-74 MAIN: 3-pole trip Fig. 3-72, 3-74 MAIN: Blck.1 sel.functions Fig. 3-61 MAIN: Blck.2 sel.functions Fig. 3-61 MAIN: DEVxx is a C.B. Fig. 3-43 MAIN: Hardware fault Fig. 3-45, -53, MAIN: Inrush stabil. trigg Fig. 3-59 MAIN: Meas.r.extd. ext./RC Fig. 3-134, 3-138 MAIN: Protection active Fig. 3-58 MAIN: Reset LED Fig. 3-86 MAIN: Time tag Fig. 3-85 MCMON: Set FF, V Fig. 3-166 MCMON: Vneg>, FF trigg. Fig. 3-166 MEASO: Enable Fig. 3-33 MEASO: Reset meas.val.outp. Fig. 3-34 P<>: P Fig. 3-345 P<>: P- Fig. 3-345 P<>: P+ Fig. 3-345 P<>: Q Fig. 3-345 P<>: Q- Fig. 3-345 P<>: Q+ Fig. 3-345 PSB: Ready Fig. 3-158 PSB: Spos Fig. 3-159 PSB: Asyn. power swing Fig. 3-159 PSB: Block. sel. zone Fig. 3-161 PSIG: Frequ. monit. trigg. Fig. 3-176 PSIG: Timer stage elapsed Fig. 3-173 PSIG: Trip channel 1 Fig. 3-186, 3-189, 3-192 PSIG: Trip channel 2 Fig. 3-186, 3-189, 3-192 PSIG: Trip channel 3 Fig. 3-186, 3-189, 3-192 PSIG: Trip enable Fig. 3-185, 3-186, 3-188, 3-189, 3-191,

3-192, 3-195, 3-197, 3-198

PSIG: Trip V< Fig. 3-200, 3-201 PSIG: Trip V<, A Fig. 3-202 PSIG: Trip V<, B Fig. 3-202 PSIG: Trip V<, C Fig. 3-202


PSIG: V< triggered Fig. 3-200, 3-201 PSIG: Weak inf. ready Fig. 3-200 PSIG: Receive weak inf. Fig. 3-200 PSIG: Telecom. faulty int. Fig. 3-197, 3-198 PSIG: Transient blocking Fig. 3-177 PSIG: Trip 1 Fig. 3-180, 3-175, 3-185, 3-188, 3-181 PSIG: Trip 2 Fig. 3-182, 3-183, 3-199 PSIG: Trip time elapsed Fig. 3-173 SOTF: ARC blocked Fig. 3-171 TGFD: VNG Fig. 3-317 TGFD: Direction BS Fig. 3-318 TGFD: Direction LS Fig. 3-318 TGFD: Hardware fault Fig. 3-316 TGFD: IN,p> triggered Fig. 3-318 TGFD: Reset signal Fig. 3-320 TGFD: VNG> (f0) triggered Fig. 3-318 TGFD: VNG> triggered Fig. 3-318 THERM: Block. by CTA error Fig. 3-325 THERM: I Fig. 3-326 THERM: With CTA Fig. 3-325 V<>: Vneg Fig. 3-332 V<>: VNG Fig. 3-335 V<>: Vpos Fig. 3-332 V<>: VNG not ready Fig. 3-335



B 2 Telecontrol Interface per EN 60870-5-101 or IEC 870-5-101 (Companion Standard)

This section incorporates Section 8 of EN 60870-5-101 (1996), which includes a general definition of the telecontrol interface for substation control systems.

B 2.1 Interoperability

This application-based standard (companion standard) specifies parameter sets and other options from which subsets are to be selected in order to implement specific telecontrol systems.Certain parameters such as the number of bytes (octets) in the COMMON ADDRESS of the ASDU are mutually exclusive. This means that only one value of the defined parameter is allowed per system. Other parameters, such as the listed set of different process information in the command and monitor direction, permit definition of the total number or of subsets that are suitable for the given application. This section combines the parameters given in the previous sections in order to facilitate an appropriate selection for a specific application. If a system is made up of several system components supplied by different manufacturers, then it is necessary for all partners to agree on the selected parameters.

The boxes for the selected parameters should be checked. 1

Note: The overall definition of a system may also require individual selection of certain parameters for specific parts of a system such as individual selection of scaling factors for individually addressable measured values.

B 2.1.1 Network Configuration (Network-Specific Parameters)

x Point-to-point configuration x Multipoint-party line configuration

x Multiple point-to-point configuration Multipoint-star configuration

1 See National Preface of EN 60870-5-101.


B 2.1.2 Physical Layer 1 (Network-Specific Parameters)

Transmission Rate (Control Direction) 2

Unbalanced

interface V.24/V.28

Standardized

Unbalanced

interface V.24/V.28

Recommended with > 1 200 bit/s

Balanced interface X.24/X.27

100 bit/s x 2,400 bit/s 2,400 bit/s 56,000 bit/s

200 bit/s x 4,800 bit/s 4,800 bit/s 64,000 bit/s

300 bit/s x 9,600 bit/s 9,600 bit/s

x 600 bit/s 19,200 bit/s

x 1,200 bit/s 38,400 bit/s

Transmission Rate (Monitor Direction) 3

Unbalanced

interface V.24/V.28

Standardized

Unbalanced

interface V.24/V.28

Recommended with > 1 200 bit/s

Balanced interface X.24/X.27

100 bit/s x 2,400 bit/s 2,400 bit/s 56,000 bit/s 200 bit/s x 4,800 bit/s 4,800 bit/s 64,000 bit/s 300 bit/s x 9,600 bit/s 9,600 bit/s x 600 bit/s 19,200 bit/s x 1,200 bit/s 38,400 bit/s

1 See National Preface of EN 60870-5-101. 2 The transmission rates for control direction and monitor direction must be identical.



B 2.1.3 Link Layer (Network-Specific Parameters) 1

Frame format FT 1.2, single character 1, and the fixed time-out interval are used exclusively in this companion standard.

Link Transmission Procedure Address Field of the Link x Balanced transmission x Not present

(balanced transmission only) x Unbalanced transmission x One octet x Two octets 2 Frame Length x Structured 240 Maximum length L (number of octets) x Unstructured

1See National Preface of EN 60870-5-101. 2 Balanced only.


B 2.1.4 Application Layer 1

Transmission mode for application data

Mode 1 (least significant octet first), as defined in clause 4.10 of IEC 870-5-4, is used exclusively in this companion standard.

Common Address of ASDU (System-Specific Parameter)

x One octet x Two octets

Information Object Address (System-Specific Parameter)

x One octet x Structured x Two octets x Unstructured x Three octets

Cause of Transmission (System-Specific Parameter)

x One octet x Two octets (with originator address)




Selection of Standard ASDUs

Process Information in Monitor Direction (Station-Specific Parameter)

x <1> = Single-point information M_SP_NA_1

x <2> = Single-point information with time tag M_SP_TA_1

x <3> = Double-point information M_DP_NA_1

x <4> = Double-point information with time tag M_DP_TA_1

x <5> = Step position information M_ST_NA_1

x <6> = Step position information with time tag M_ST_TA_1

x <7> = Bit string of 32 bit M_BO_NA_1

x <8> = Bit string of 32 bit with time tag M_BO_TA_1

x <9> = Measured value, normalized value M_ME_NA_1

x <10> = Measured value, normalized value with time tag M_ME_TA_1

x <11> = Measured value, scaled value M_ME_NB_1

x <12> = Measured value, scaled value with time tag M_ME_TB_1

<13> = Measured value, short floating point value M_ME_NC_1

<14> = Measured value, short floating point value with time tag M_ME_TC_1

x <15> = Integrated totals M_IT_NA_1

x <16> = Integrated totals with time tag M_IT_TA_1


x <17> = Event of protection equipment with time tag M_EP_TA_1

x <18> = Packed start events of protection equipment with time tag ME_EP_TB_1

x <19> = Packed output circuit information of protection equipment with time tag M_EP_TC_1

<20> = Packed single-point information with status change detection M_PS_NA_1

<21> = Measured value, normalized value without quality descriptor M_ME_ND_1



Process Information in Monitor Direction 1 (Station-Specific Parameter)

x <45> = Single command C_SC_NA_1 x <46> = Double command C_DC_NA_1 x <47> = Regulating step command C_IT_NA_1 <48> = Set point command, normalized value C_RC_NA_1 <49> = Set point command, scaled value C_SE_NB_1 <50> = Set point command, short floating point value C_SE_NC_1 <51> = Bit string of 32 bit C_BO_NA_1

System Information in Monitor Direction (Station-Specific Parameter)

x <70> = End of initialization ME_EI_NA_1

1 Incorrectly identified with control direction in IEC 870-5-101.


System Information in Control Direction (Station-Specific Parameter)

x <100> = Interrogation command C_IC_NA_1 x <101> = Counter interrogation command C_CI_NA_1 x <102> = Read command C_RD_NA_1 x <103> = Clock synchronization command 1 C_CS_NA_1 x <104> = Test command C_TS_NB_1 <105> = Reset process command C_RP_NC_1 <106> = Delay acquisition command C_CD_NA_1

1 The command procedure is formally processed, but there is no change in the local time in the station. 2 See National Preface of EN 60870-5-101.



Parameter in Control Direction (Station-Specific Parameter)

x <110> = Parameter of measured value, normalized value P_ME_NA_1

x <111> = Parameter of measured value, scaled value P_ME_NB_1 <112> = Parameter of measured value, short floating point value P_ME_NC_1 <113> = Parameter activation P_AC_NA_1

File Transfer (Station-Specific Parameter)

<120> = File ready F_FR_NA_1 <121> = Section ready F_SR_NA_1 <122> = Call directory, select file, call file, call section F_SC_NA_1 <123> = Last section, last segment F_LS_NA_1 <124> = Ack file, ack section F_AF_NA_1 <125> = Segment F_SG_NA_1 <126> = Directory F_DR_TA_1


B 2.1.5 Basic Application Functions 1

Station Initialization (Station-Specific Parameter)

x Remote initialization

General Interrogation (System- or Station-Specific Parameter)

x Global

x Group 1 x Group 7 x Group 13 x Group 2 x Group 8 x Group 14 x Group 3 x Group 9 x Group 15 x Group 4 x Group 10 x Group 16 x Group 5 x Group 11 x Group 6 x Group 12 Addresses per group have to be defined.

Clock Synchronization (Station-Specific Parameter)

x Clock synchronization




Command Transmission (Object-Specific Parameter)

x Direct command transmission Select and execute command Direct set point command transmission Select and execute set point command C_SE ACTTERM used x No additional definition

Short pulse duration

(Execution duration determined by a system parameter in the outstation) Long pulse duration

(Execution duration determined by a system parameter in the outstation) Persistent output

Transmission of Integrated Totals (Station- or Object-Specific Parameter)

Counter request x General request counter

x Counter freeze without reset x Request counter group 1 Counter freeze with reset x Request counter group 2 Counter reset x Request counter group 3 Addresses per group have to be specified x Request counter group 4


Parameter Loading (Object-Specific Parameter)

x Threshold value

Smoothing value Low limit for transmission of measured value High limit for transmission of measured value

Parameter Activation (Object-Specific Parameter)

Act/deact of persistent cyclic or periodic transmission of the addressed object

File Transfer (Station-Specific Parameter)

File transfer in monitor direction F_FR_NA_1 File transfer in control direction F_FR_NA_1



B 3 Communication Interface per IEC 60870-5-103

This section incorporates Section 8 of IEC 60870-5-103, including definitions applicable to the P43x.

B 3.1 Interoperability

B 3.1.1 Physical Layer

B 3.1.1.1 Electrical Interface

x EIA RS 485

x No. of loads 32 for one device

Note: EIA RS 485 defines the loads in such a way that 32 of such loads can be operated on one line. For detailed information see EIA RS 485, Section 3.

B 3.1.1.2 Optical Interface

x Glass fiber

x Plastic fiber

x F-SMA connector

BFOC/2.5 connector

B 3.1.1.3 Transmission Rate

x 9,600 bit/s

x 19,200 bit/s


B 3.1.2 Link Layer

There are no selection options for the link layer.

B 3.1.3 Application Layer

B 3.1.3.1 Transmission Mode for Application Data

Mode 1 (least significant octet first) as defined in clause 4.10 of IEC 60870-5-4 is used exclusively in this companion standard.

B 3.1.3.2 Common Address of ASDU

x One COMMON ADDRESS of ASDU (identical to the station address)

More than one COMMON ADDRESS of ASDU

B 3.1.3.3 Selection of Standard Information Numbers in Monitor Direction

B 3.1.3.3.1 System Functions in Monitor Direction

INF Description

x <0> End of general interrogation

x <0> Time synchronization

x <2> Reset FCB

x <3> Reset CU

x <4> Start / restart

<5> Power on


P43x/EN M/Ac7-S // AFSV.12.10220 D /// P433-308-410/411-612 // P435-308-413/414/415-612 B-21

B 3.1.3.3.2 Status Indications in Monitor Direction

Schneider Electric Designations INF Description Address Description

x <16> Auto-recloser active 015 064 ARC: Enabled

x <17> Teleprotection active 015 008 PSIG: Enabled

x <18> Protection active 003 030 MAIN: Device on-line

x <19> LED reset 021 010 MAIN: Reset indicat. USER

x <20> Blocking of monitor direction 037 075 COMM1: Sig./meas.val.block.

x <21> Test mode 037 071 MAIN: Test mode

<22> Local setting parameter

x <23> Characteristic 1 036 090 PSS: PS 1 active




x <27> Auxiliary input 1 034 000 LOGIC: Input 1 EXT




B-22 P43x/EN M/Ac7-S // AFSV.12.10220 D /// P433-308-410/411-612 // P435-308-413/414/415-612

B 3.1.3.3.3 Monitoring Signals (Supervision Indications) in Monitor Direction


x <32> Measured value supervision I 040 087 MCMON: Meas. circ. I faulty

x <33> Measured value supervision V 038 023 MCMON: Meas. circ. V faulty

x <35> Phase sequence supervision 038 049 MCMON: Phase sequ. V faulty

x <36>1 Trip circuit supervision 041 200 SFMON: Relay Kxx faulty

x <37> I>> back-up operation 037 021 BUOC: Active

x <38> VT fuse failure 004 061 MAIN: M.c.b. trip V EXT

x <39> Teleprotection disturbed 036 060 PSIG: Telecom. faulty

x <46> Group warning 036 100 SFMON: Warning (relay)

x <47> Group alarm 004 065 MAIN: Blocked/Faulty

1 The message content is formed from the OR operation of the individual signals.



B 3.1.3.3.4 Earth Fault Indications in Monitor Direction


x <48> Earth fault L1 041 054 MAIN: Ground fault A

x <49> Earth fault L2 041 055 MAIN: Ground fault B

x <50> Earth fault L3 041 056 MAIN: Ground fault B

x <51> Earth fault forward, i.e. line 041 088 MAIN: Gnd. fault forw./LS

x <52> Earth fault reverse, i.e. busbar 041 089 MAIN: Gnd. fault backw./BS


B 3.1.3.3.5 Fault Indications in Monitor Direction

Schneider Electric Designations INF Description Address Device Description

x <64> Start /pick-up L1 036 001 MAIN: Starting A

x <65> Start /pick-up L2 036 002 MAIN: Starting B

x <66> Start /pick-up L3 036 003 MAIN: Starting C

x <67> Starting N 036 004 MAIN: Starting GF

x <68> General trip 036 071 MAIN: Gen. trip command 1

x <69> Trip L1 036 072 MAIN: Trip command 1, A

x <70> Trip L2 036 073 MAIN: Trip command 1, B

x <71> Trip L3 036 074 MAIN: Trip command 1, C

x <72> Trip I>> (back-up operation) 036 014 BUOC: Trip signal

x <73> Fault location X in ohms 004 029 FT_DA: Fault react., prim.

x <74> Fault forward/line 036 018 DIST: Fault forward / LS

x <75> Fault reverse/busbar 036 019 DIST: Fault backward / BS

x <76> Teleprotection signal transmitted 036 035 PSIG: Send (signal)

x <77> Teleprotection signal received 037 029 PSIG: Receive (signal)

x <78> Zone 1 036 026 DIST: t1 elapsed








Schneider Electric Designations INF Description Address Device Description

x <84> General starting 036 000 MAIN: General starting

x <85> Breaker failure 036 017 CBF: CB failure

<86> Trip measuring system L1



<89> Trip measuring system N

<90> Trip I>

<91> Trip I>>

<92> Trip IN>

<93> Trip IN>>


B 3.1.3.3.6 Auto-Reclosure Indications in Monitor Direction


x <128> CB ‘on’ by AR 037 007 ARC: (Re)close signal HSR

x <129> CB ‘on’ by long-time AR 037 006 ARC: (Re)close signal TDR

x <130> AR blocked 037 008 ARC: Not ready

B 3.1.3.3.7 Measured values in Monitor Direction


x <144>1 Measured value I 006 041 MAIN: Current B p.u.

x <145>2 Measured values I, V 006 041 005 045

MAIN: Current B p.u. MAIN: Voltage A-B p.u.

x <146>3 Measured values I, V, P, Q 006 041 005 045 004 051 004 053

MAIN: Current B p.u. MAIN: Voltage A-B p.u. MAIN: Active power P p.u. MAIN: Reac. power Q p.u.

x <147>4 Measured values IN, VEN 005 011 005 013

MAIN: Current Σ(IP) p.u. MAIN: Volt. Σ(VPG)/√3 p.u.

x <148>5 Measured values IL1,2,3, VL1,2,3, P, Q, f 005 041 006 041 007 041 005 043 006 043 007 043 004 051 004 053 004 040

MAIN: Current A p.u. MAIN: Current B p.u. MAIN: Current C p.u. MAIN: Voltage A-G p.u. MAIN: Voltage B-G p.u. MAIN: Voltage C-G p.u. MAIN: Active power P p.u. MAIN: Reac. power Q p.u. MAIN: Frequency f

1 only when C O M M 1 : T r a n s m . e n a b . c y c l . d a t is set to 'ASDU 3.1 p. IEC' 2 only when C O M M 1 : T r a n s m . e n a b . c y c l . d a t is set to 'ASDU 3.2 p. IEC' 3 only when C O M M 1 : T r a n s m . e n a b . c y c l . d a t is set to 'ASDU 3.3 p. IEC' 4 only when C O M M 1 : T r a n s m . e n a b . c y c l . d a t is set to 'ASDU 3.4 p. IEC' 5 only when C O M M 1 : T r a n s m . e n a b . c y c l . d a t is set to 'ASDU 9 p. IEC'



B 3.1.3.3.8 Generic Functions in Monitor Direction

INF Description

<240> Read headings of all defined groups

<241> Read values or attributes of all entries of one group

<243> Read directory of a single entry

<244> Read value or attribute of a single entry

<245> General interrogation of generic data

<249> Write entry with confirmation

<250> Write entry with execution

<251> Write entry abort


B 3.1.3.4 Selection of Standard Information Numbers in Control Direction

B 3.1.3.4.1 System Functions in Control Direction

INF Description

x <0> Initiation of general interrogation

x <0> Time synchronization

B 3.1.3.4.2 General Commands in Control Direction


x <16> Auto-recloser on/off 015 064 ARC: Enabled

x <17> Teleprotection on/off 015 008 PSIG: Enabled

x <18> Protection on/off 003 030 MAIN: Device on-line

x <19> LED reset 021 010 MAIN: Reset indicat. USER

x <23>1 Activate characteristic 1 003 060 PSS: Param.subs.sel. USER




1 Switches P S S : P a r a m . s u b s . s e l . U S E R to 'Parameter set 1' 2 Switches P S S : P a r a m . s u b s . s e l . U S E R to 'Parameter set 2' 3 Switches P S S : P a r a m . s u b s . s e l . U S E R to 'Parameter set 3' 4 Switches P S S : P a r a m . s u b s . s e l . U S E R to 'Parameter set 4'



B 3.1.3.4.3 Generic Functions in Control Direction

INF Description

<240> Read headings of all defined groups

<241> Read values or attributes of all entries of one group

<243> Read directory of a single entry

<244> Read value or attribute of a single entry

<245> General interrogation of generic data

<248> Write entry

<249> Write entry with confirmation

<250> Write entry with execution

<251> Write entry abort


B 3.1.3.5 Basic Application Functions

x Test mode

x Blocking of monitor direction

x Disturbance data

Generic services

x Private data

B 3.1.3.6 Miscellaneous

Measured values are transmitted both with ASDU 3 and ASDU 9. As defined in Sec. 7.2.6.8, the maximum MVAL can be either 1.2 or 2.4 times the rated value. In ASDU 3 and ASDU 9, different ratings may not be used; in other words, there is only one choice for each measured value.

Measured value Max. MVAL = nom. value multiplied by

1.2 or 2.4

Current A x

Current B x

Current C x

Voltage A-G x

Voltage B-G x

Voltage C-G x

Enabled power P x

Reactive power Q x

Frequency f x

Voltage A-B x

Appendix C - List of Bay Types

P43x/EN M/Ac7 // AFSV.12.10220 D /// P433-308-410/411-612 // P435-308-413/414/415-612 C-1

Key

Sorting the Bay Types The bay types are sorted by the criteria listed below. These criteria are encoded in the first three characters of the bay type code (example: A11.100.R01) given in brackets after the Bay Type No. (example: Sorting is first by "Type of bay" in the order given below, then within each group by the second and third character in ascending order.

Type of bay A – Feeder Bay L – Longitudinal Coupler Q – Transversal Coupler K – Bus coupler and sectionalizer bay M – Busbar Measurement E – Busbar Grounding X – Other bay type

Number of busbars 1 – Single busbar 2 – Double busbar 9 – Without busbar / Other configurations

Equipment 1 – Bays with switch truck or withdrawable switchgear assembly 2 – Bays with two circuit breakers or switch disconnectors on switch trucks or withdrawable switchgear assembly 3 – Bays with stationary switchgear units 5 – Bays with stationary switchgear units and three-position disconnector 9 – Other bay types

Bay Type No.: This number indicates the value to be set at M A I N : T y p e o f b a y (folder "Par/Conf") in order to configure the unit for the selected bay type.

Special Designations for External Devices: Mot.relay: Motor relay Shunt wd. Shunt winding

Appendix C - List of Bay Types (continued)

C-2 P43x/EN M/Ac7 // AFSV.12.10220 D /// P433-308-410/411-612 // P435-308-413/414/415-612

Table "Assignment of Binary Inputs and Output Relays"

"Switchgear unit" column: This column begins with the designation for the external device (switchgear unit).). The function group follows in brackets. The function group encompasses all setting options for monitoring the switchgear unit and its signals. "Open" and "Close(d)" indicate the signal message or control direction of the switchgear unit.

"Binary Input" Column: The "Open" or "Closed" signal should be connected to binary input U xxxx. The connection points of binary input U xxxx are shown in the terminal connection diagrams. With the P43X fitted into the 40TE case the designations of the binary inputs refer to the following slots: A: Slot 6 B: Slot 7 C: Slot 8

"Output relay" column: The connection points of output relay K xxxx are shown in the terminal connection diagrams. The connection points of output relay K xxxx are shown in the terminal connection diagrams. With the P43X fitted into the 40TE case the designations of the binary outputs refer to the following slots: A: Slot 6 B: Slot 7

Tables Entitled 'Bay Interlock Equations for Operation with (or without) Station Interlocking'

Note: The interlock equations are stored at substation control level, not at unit level.

Symbols used in the Boolean interlock equations: /: Negation 0: Switchgear unit 'Open' I: Switchgear unit 'Closed' X: Switchgear unit in intermediate position

FctBl1: Function block 1, configuration at M A I N : F c t . a s g . f c t . b l o c k . 1 ('Par/Func/Cont' folder)

FctBl2: Function block 2, configuration at M A I N : F c t . a s g . f c t . b l o c k . 2 ('Par/Func/Cont' folder)



Bay Type List for the P43x

Bay type (Identification):

A – Feeder Bay 2 (A11.100.R01) 3 (A11.100.R02) 4 (A11.101.R01) 5 (A11.101.R02) 6 (A11.101.R03) 523 (A11.108.R01) 7 (A11.200.R01) 8 (A11.200.R02) 9 (A11.201.R01) 10 (A11.201.R02) 11 (A11.201.R03) 12 (A11.400.R01) 13 (A11.400.R02) 14 (A11.401.R01) 15 (A11.401.R02) 16 (A11.401.R03) 17 (A11.900.R01) 504 (A11.901.R00) 541 (A13.104.R01) 19 (A13.105.R01) 20 (A13.105.R02) 21 (A13.105.R03) 557 (A13.106.R03) 26 (A13.200.R01) 28 (A13.201.R01) 29 (A13.201.R02) 31 (A13.205.R01) 32 (A13.205.R02) 33 (A13.205.R03) 34 (A13.400.R01) 36 (A13.401.R01) 37 (A13.401.R02) 39 (A13.405.R01) 40 (A13.405.R02) 41 (A13.405.R03) 503 (A13.432.R02) 507 (A13.433.R02) 43 (A15.105.R01) 221 (A15.105.R02) 44 (A15.105.R03) 87 (A23.104.R01) 88 (A23.104.R03) 101 (A23.204.R01) 102 (A23.204.R03) 115 (A23.404.R01) 116 (A23.404.R03)

L – Longitudinal Coupler 133 (L11.100.R01) 553 (L11.100.R01.2) 134 (L11.100.R02) 528 (L11.102.R01) 542 (L11.102.R01.2) 135 (L11.104.R01) 136 (L11.104.R02) 137 (L11.104.R03) 138 (L11.116.R01) 545 (L11.116.R01.2) 139 (L11.116.R03) 148 (L11.200.R01) 149 (L11.202.R01) 150 (L11.202.R03) 164 (L23.901.R02)

Q – Transversal Coupler 505 (Q21.100.R01) 563 (Q21.133.R01) 205 (Q23.101.R01) 206 (Q23.101.R03)

M – Busbar Measurement 171 (M11.300.R00) 172 (M11.300.R01) 540 (M11.304.R02) 173 (M11.900.R00) 174 (M11.900.R01) 176 (M13.312.R01) 177 (M13.312.R02) 506 (M13.902.R00) 233 (M15.903.R01) 179 (M15.903.R02) 188 (M23.302.R02) 189 (M23.312.R02) 193 (M23.902.R02) 559 (M23.904.R00) 560 (M23.908.R00) 194 (M23.912.R02)

E – Busbar Grounding 130 (E13.901.R01) 132 (E23.903.R02)

X – Other Bay Type 1 (X99.901.R00)

Customized Bay 999 (Customized)

Appendix C - List of Bay Types


Bay Type No. 2 (A11.100.R01) Feeder bay with circuit breaker, single busbar

Assignment of Binary Inputs and Output Relays

Switchgear unit Binary input Output relay

Q0 (DEV01) X0 (DEV02)

Open Close(d) Open Close(d)

U A01 U A02 U A03 U A04

K A01 K A02/ /

Bay Interlock Equations for Operation without Station Interlocking

Switchgear unit Control O/C Interlock equation

Q0 Close(d) /(X0=X) & /(FctBl1=I) & /(FctBl2=I)

Bay Interlock Equations for Operation with Station Interlocking








Q0 (DEV01) X0 (DEV02)


U A01 U A02 U A03 U A04

K A01 K A02K A03 K A04




X0 Open (Q0=0)

Close(d) (Q0=0)




X0 Open (Q0=0)

Close(d) (Q0=0)






Q0 (DEV01) X0 (DEV02) Q8 (DEV03)

Open Close(d) Open Close(d) Open Close(d)

U A01 U A02 U A03 U A04 U A05 U A06

K A01 K A02/ // /












Q0 (DEV01) X0 (DEV02) Q8 (DEV03)


U A01 U A02 U A03 U A04 U A05 U A06

K A01 K A02K A03 K A04/ /




X0 Open (Q0=0)

Close(d) (Q0=0) & (Q8=0)




X0 Open (Q0=0)

Close(d) (Q0=0) & (Q8=0)






Q0 (DEV01) X0 (DEV02) Q8 (DEV03)


U A01 U A02 U A03 U A04 U A05 U A06

K A01 K A02K A03 K A04K A05 K A06




Q8 Close(d) (X0=0)

X0 Open (Q0=0)

Close(d) (Q0=0) & (Q8=0)




Q8 Close(d) (X0=0)

X0 Open (Q0=0)

Close(d) (Q0=0) & (Q8=0)






Q0 (DEV01) X0 (DEV02) Q15 (DEV03)


U A01 U A02 U A03 U A04 U A05 U A06

K A01 K A02/ // /



Q0 Close(d) /(X0=X) & (Q15=0) & /(FctBl1=I) & /(FctBl2=I)






Bay Type No. 7 (A11.200.R01) Feeder bay with switch disconnector, single busbar



Q0 (DEV01) X0 (DEV02)


U A01 U A02 U A03 U A04

K A01 K A02/ /












Q0 (DEV01) X0 (DEV02)


U A01 U A02 U A03 U A04

K A01 K A02K A03 K A04




X0 Open (Q0=0)

Close(d) (Q0=0)




X0 Open (Q0=0)

Close(d) (Q0=0)






Q0 (DEV01) X0 (DEV02) Q8 (DEV03)


U A01 U A02 U A03 U A04 U A05 U A06

K A01 K A02/ // /












Q0 (DEV01) X0 (DEV02) Q8 (DEV03)


U A01 U A02 U A03 U A04 U A05 U A06

K A01 K A02K A03 K A04/ /




X0 Open (Q0=0)

Close(d) (Q0=0) & (Q8=0)




X0 Open (Q0=0)

Close(d) (Q0=0) & (Q8=0)






Q0 (DEV01) X0 (DEV02) Q8 (DEV03)


U A01 U A02 U A03 U A04 U A05 U A06

K A01 K A02K A03 K A04K A05 K A06




Q8 Close(d) (X0=0)

X0 Open (Q0=0)

Close(d) (Q0=0) & (Q8=0)




Q8 Close(d) (X0=0)

X0 Open (Q0=0)

Close(d) (Q0=0) & (Q8=0)



Bay Type No. 12 (A11.400.R01) Feeder bay with switch disconnector / fuse unit, single busbar



Q0 (DEV01) X0 (DEV02) F (SIG_1: Signal S011)


U A01 U A02 U A03 U A04 U B05

K A01 K A02/ //














U A01 U A02 U A03 U A04 U B05

K A01 K A02K A03 K A04/




X0 Open (Q0=0)

Close(d) (Q0=0)




X0 Open (Q0=0)

Close(d) (Q0=0)






Q0 (DEV01) X0 (DEV02) Q8 (DEV03) F (SIG_1: Signal S011)


U A01 U A02 U A03 U A04 U A05 U A06 U B05

K A01 K A02/ // //














U A01 U A02 U A03 U A04 U A05 U A06 U B05

K A01 K A02K A03 K A04/ //




X0 Open (Q0=0)

Close(d) (Q0=0) & (Q8=0)




X0 Open (Q0=0)

Close(d) (Q0=0) & (Q8=0)








U A01 U A02 U A03 U A04 U A05 U A06 U B05

K A01 K A02K A03 K A04K A05 K A06/




Q8 Close(d) (X0=0)

X0 Open (Q0=0)

Close(d) (Q0=0) & (Q8=0)




Q8 Close(d) (X0=0)

X0 Open (Q0=0)

Close(d) (Q0=0) & (Q8=0)



Bay Type No. 17 (A11.900.R01) Feeder bay with other switchgear unit, single busbar



X0 (DEV01)

Open Close(d)

U A01 U A02

K A01 K A02



Interlock equations not defined






Bay Type No. 504 (A11.901.R00) Feeder bay with other switchgear unit, single busbar



X0 (DEV02) Q8 (DEV03)


U A03 U A04 U A05 U A06

/ // /












Q0 (DEV01) Q1 (DEV02)


U A01 U A02 U A03 U A04

K A01 K A02/ /



Q0 Close(d) /(FctBl1=I) & /(FctBl2=I)



Q0 Close(d) /(FctBl1=I) & /(FctBl2=I)






Q0 (DEV01) Q1 (DEV02) Q8 (DEV03)


U A01 U A02 U A03 U A04 U A05 U A06

K A01 K A02/ // /



Q0 Close(d) /(Q1=X) & (Q8=0) & /(FctBl1=I) & /(FctBl2=I)









Q0 (DEV01) Q1 (DEV02) Q8 (DEV03)


U A01 U A02 U A03 U A04 U A05 U A06

K A01 K A02K A03 K A04/ /




Q1 Open (Q0=0)

Close(d) (Q0=0) & (Q8=0)




Q1 Open (Q0=0)

Close(d) (Q0=0) & (Q8=0)






Q0 (DEV01) Q1 (DEV02) Q8 (DEV03)


U A01 U A02 U A03 U A04 U A05 U A06

K A01 K A02K A03 K A04K A05 K A06




Q1 Open (Q0=0)

Close(d) (Q0=0) & (Q8=0)

Q8 Close(d) (Q0=0) & (Q1=0)




Q1 Open (Q0=0)

Close(d) (Q0=0) & (Q8=0)

Q8 Close(d) (Q0=0) & (Q1=0)






Q0 (DEV01) Q1 (DEV02) Q9 (DEV03)


U A01 U A02 U A03 U A04 U A05 U A06

K A01 K A02K A03 K A04K A05 K A06



Q0 Close(d) /(Q1=X) & /(Q9=X) & /(FctBl1=I) & /(FctBl2=I)

Q1 Open (Q0=0)

Close(d) (Q0=0)

Q9 Open (Q0=0)

Close(d) (Q0=0)




Q1 Open (Q0=0)

Close(d) (Q0=0)

Q9 Open (Q0=0)

Close(d) (Q0=0)






Q0 (DEV01)

Open Close(d)

U A01 U A02

K A01 K A02












Q0 (DEV01) Q8 (DEV02)


U A01 U A02 U A03 U A04

K A01 K A02/ /



Q0 Close(d) (Q8=0) & /(FctBl1=I) & /(FctBl2=I)









Q0 (DEV01) Q8 (DEV02)


U A01 U A02 U A03 U A04

K A01 K A02K A03 K A04




Q8 Close(d) (Q0=0)




Q8 Close(d) (Q0=0)






Q0 (DEV01) Q1 (DEV02) Q8 (DEV03)


U A01 U A02 U A03 U A04 U A05 U A06

K A01 K A02/ // /












Q0 (DEV01) Q1 (DEV02) Q8 (DEV03)


U A01 U A02 U A03 U A04 U A05 U A06

K A01 K A02K A03 K A04/ /




Q1 Open (Q0=0)

Close(d) (Q0=0) & (Q8=0)




Q1 Open (Q0=0)

Close(d) (Q0=0) & (Q8=0)






Q0 (DEV01) Q1 (DEV02) Q8 (DEV03)


U A01 U A02 U A03 U A04 U A05 U A06

K A01 K A02K A03 K A04K A05 K A06




Q1 Open (Q0=0)

Close(d) (Q0=0) & (Q8=0)

Q8 Close(d) (Q0=0) & (Q1=0)




Q1 Open (Q0=0)

Close(d) (Q0=0) & (Q8=0)

Q8 Close(d) (Q0=0) & (Q1=0)






Q0 (DEV01) F (SIG_1: Signal S011)

Open Close(d)

U A01 U A02 U B05

K A01 K A02/












Q0 (DEV01) Q8 (DEV02) F (SIG_1: Signal S011)


U A01 U A02 U A03 U A04 U B05

K A01 K A02/ //














U A01 U A02 U A03 U A04 U B05

K A01 K A02K A03 K A04/




Q8 Close(d) (Q0=0)




Q8 Close(d) (Q0=0)






Q0 (DEV01) Q1 (DEV02) Q8 (DEV03) F (SIG_1: Signal S011)


U A01 U A02 U A03 U A04 U A05 U A06 U B05

K A01 K A02/ // //














U A01 U A02 U A03 U A04 U A05 U A06 U B05

K A01 K A02K A03 K A04/ //




Q1 Open (Q0=0)

Close(d) (Q0=0) & (Q8=0)




Q1 Open (Q0=0)

Close(d) (Q0=0) & (Q8=0)








U A01 U A02 U A03 U A04 U A05 U A06 U B05

K A01 K A02K A03 K A04K A05 K A06/




Q1 Open (Q0=0)

Close(d) (Q0=0) & (Q8=0)

Q8 Close(d) (Q0=0) & (Q1=0)




Q1 Open (Q0=0)

Close(d) (Q0=0) & (Q8=0)

Q8 Close(d) (Q0=0) & (Q1=0)








U A01 U A02 U A03 U A04 U B05

K A01 K A02K A03 K A04/




Q8 Close(d) (Q0=0)




Q8 Close(d) (Q0=0)








U A01 U A02 U A03 U A04 U A05 U A06 U B05

K A01 K A02K A03 K A04/ //



Q0 Close(d) (Q8=0) & (Q15=0) & /(FctBl1=I) & /(FctBl2=I)

Q8 Close(d) (Q0=0)




Q8 Close(d) (Q0=0)






Q0 (DEV01) Q1 (DEV02) Q8 (DEV03)


U A01 U A02 U A03 U A04 U A05 U A06

K A01 K A02/ // /



Q0 Open (Q8=0)

Close(d) /(Q1=X) & (Q8=0) & /(FctBl1=I) & /(FctBl2=I)



Q0 Open (Q8=0)







Q0 (DEV01) Q1 (DEV02) Q8 (DEV03)


U A01 U A02 U A03 U A04 U A05 U A06

K A01 K A02K A03 K A04/ /



Q0 Open (Q8=0)


Q1 Open (Q0=0)

Close(d) (Q0=0) & (Q8=0)



Q0 Open (Q8=0)


Q1 Open (Q0=0)

Close(d) (Q0=0)






Q0 (DEV01) Q1 (DEV02) Q8 (DEV03)


U A01 U A02 U A03 U A04 U A05 U A06

K A01 K A02K A03 K A04K A05 K A06



Q0 Open (Q8=0)


Q1 Open (Q0=0)

Close(d) (Q0=0) & (Q8=0)

Q8 Open (Q0=I)

Close(d) (Q0=0) & (Q1=0) & /(FctBl1=I) & /(FctBl2=I)



Q0 Open (Q8=0)


Q1 Open (Q0=0)

Close(d) (Q0=0)

Q8 Open (Q0=I)

Close(d) (Q0=0) & (Q1=0) & /(FctBl1=I) & /(FctBl2=I)



Bay Type No. 87 (A23.104.R01) Feeder bay with circuit breaker, double busbar



Q0 (DEV01) Q1 (DEV02) Q2 (DEV03)


U A01 U A02 U A03 U A04 U A05 U A06

K A01 K A02/ // /









Bay Type No. 88 (A23.104.R03) Feeder bay with circuit breaker, double busbar



Q0 (DEV01) Q1 (DEV02) Q2 (DEV03)


U A01 U A02 U A03 U A04 U A05 U A06

K A01 K A02K A03 K A04K A05 K A06




Q1 Open (Q0=0) & (Q2=0)

Close(d) (Q0=0) & (Q2=0)

Q2 Open (Q0=0) & (Q1=0)

Close(d) (Q0=0) & (Q1=0)






Bay Type No. 101 (A23.204.R01) Feeder bay with switch disconnector, double busbar



Q0 (DEV01) Q1 (DEV02) Q2 (DEV03)


U A01 U A02 U A03 U A04 U A05 U A06

K A01 K A02/ // /









Bay Type No. 102 (A23.204.R03) Feeder bay with switch disconnector, double busbar



Q0 (DEV01) Q1 (DEV02) Q2 (DEV03)


U A01 U A02 U A03 U A04 U A05 U A06

K A01 K A02K A03 K A04K A05 K A06




Q1 Open (Q0=0) & (Q2=0)

Close(d) (Q0=0) & (Q2=0)

Q2 Open (Q0=0) & (Q1=0)

Close(d) (Q0=0) & (Q1=0)






Bay Type No. 115 (A23.404.R01) Feeder bay with switch disconnector / fuse unit, double busbar





U A01 U A02 U A03 U A04 U A05 U A06 U B05

K A01 K A02/ // //









Bay Type No. 116 (A23.404.R03) Feeder bay with switch disconnector / fuse unit, double busbar





U A01 U A02 U A03 U A04 U A05 U A06 U B05

K A01 K A02K A03 K A04K A05 K A06/




Q1 Open (Q0=0) & (Q2=0)

Close(d) (Q0=0) & (Q2=0)

Q2 Open (Q0=0) & (Q1=0)

Close(d) (Q0=0) & (Q1=0)






Bay Type No. 133 (L11.100.R01) Bus sectionalizer bay with circuit breaker, single busbar



Q0 (DEV01) X01 (DEV02)


U A01 U A02 U A03 U A04

K A01 K A02/ /









Bay Type No. 553 (L11.100.R01.2) Bus sectionalizer bay with circuit breaker, single busbar



Q0 (DEV01) X01 (DEV02)


U A01 U A02 U A03 U A04

K A01 K A02/ /












Q0 (DEV01) X01 (DEV02)


U A01 U A02 U A03 U A04

K A01 K A02K A03 K A04




X01 Open (Q0=0)

Close(d) (Q0=0)




X01 Open (Q0=0)

Close(d) (Q0=0)






Q0 (DEV01) X0 (DEV02) Q15 (DEV03)


U A01 U A02 U A03 U A04 U A05 U A06

K A01 K A02/ // /












Q0 (DEV01) X01 (DEV02) Q8 (DEV03)


U A01 U A02 U A03 U A04 U A05 U A06

K A01 K A02/ // /












Q0 (DEV01) X01 (DEV02) Q8 (DEV03)


U A01 U A02 U A03 U A04 U A05 U A06

K A01 K A02K A03 K A04/ /




X01 Open (Q0=0)

Close(d) (Q0=0) & (Q8=0)




X01 Open (Q0=0)

Close(d) (Q0=0) & (Q8=0)






Q0 (DEV01) X01 (DEV02) Q8 (DEV03)


U A01 U A02 U A03 U A04 U A05 U A06

K A01 K A02K A03 K A04K A05 K A06




Q8 Close(d) (X01=0) & (Q8=I)

X01 Open (Q0=0)

Close(d) (Q0=0) & (Q8=0)




Q8 Close(d) (X01=0)

X01 Open (Q0=0)

Close(d) (Q0=0) & (Q8=0)






Q0 (DEV01) X01 (DEV02) X02 (DEV03)


U A01 U A02 U A03 U A04 U A05 U A06

K A01 K A02/ // /



Q0 Close(d) /(X01=X) & /(X02=X) & /(FctBl1=I) & /(FctBl2=I)









Q0 (DEV01) X01 (DEV02) X02 (DEV03)


U A01 U A02 U A03 U A04 U A05 U A06

K A01 K A02/ // /












Q0 (DEV01) X01 (DEV02) X02 (DEV03)


U A01 U A02 U A03 U A04 U A05 U A06

K A01 K A02K A03 K A04K A05 K A06




X01 Open (Q0=0)

Close(d) (Q0=0)

X02 Open (Q0=0)

Close(d) (Q0=0)




X01 Open (Q0=0)

Close(d) (Q0=0)

X02 Open (Q0=0)

Close(d) (Q0=0)



Bay Type No. 148 (L13.200.R01) Bus sectionalizer bay with switch disconnector, single busbar



Q0 (DEV01)

Open Close(d)

U A01 U A02

K A01 K A02












Q0 (DEV01) Q15 (DEV02) Q16 (DEV03)


U A01 U A02 U A03 U A04 U A05 U A06

K A01 K A02/ // /












Q0 (DEV01) Q15 (DEV02) Q16 (DEV03)


U A01 U A02 U A03 U A04 U A05 U A06

K A01 K A02K A03 K A04K A05 K A06




Q15 Close(d) (Q0=0) & (Q15=I)

Q16 Close(d) (Q0=0) & (Q16=I)




Q15 Close(d) (Q0=0)

Q16 Close(d) (Q0=0)



Bay Type No. 164 (L23.901.R02) Bus sectionalizer bay with other switchgear unit, double busbar



Q11 (DEV01) Q21 (DEV02)


U A01 U A02 U A03 U A04

K A01 K A02K A03 K A04



Q11 Open (Q11=0)

Close(d) (Q11=I)

Q21 Open (Q21=0)

Close(d) (Q21=I)






Bay Type No. 505 (Q21.100.R01) Bus coupler bay with circuit breaker, double busbar



Q0 (DEV01) X0 (DEV02)


U A01 U A02 U A03 U A04

K A01 K A02/ /












Q0 (DEV01) X01 (DEV02) X02 (DEV03)


U A01 U A02 U A03 U A04 U A05 U A06

K A01 K A02/ // /












Q0 (DEV01) Q10 (DEV02) Q20 (DEV03)


U A01 U A02 U A03 U A04 U A05 U A06

K A01 K A02/ // /












Q0 (DEV01) Q10 (DEV02) Q20 (DEV03)


U A01 U A02 U A03 U A04 U A05 U A06

K A01 K A02K A03 K A04K A05 K A06




Q10 Open (Q0=0)

Close(d) (Q0=0)

Q20 Open (Q0=0)

Close(d) (Q0=0)




Q10 Open (Q0=0)

Close(d) (Q0=0)

Q20 Open (Q0=0)

Close(d) (Q0=0)



Bay Type No. 171 (M11.300.R00) Busbar measurement bay with fuse unit, single busbar



X0 (DEV01) F (SIG_1: Signal S011)

Open Close(d)

U A01 U A02 U B05

/ //












X0 (DEV01) F (SIG_1: Signal S011)

Open Close(d)

U A01 U A02 U B05

K A01 K A02/














U A01 U A02 U A03 U A04 U B05

K A01 K A02K A03 K A04/



Q15 Close(d) (Q15=I)






Bay Type No. 173 (M11.900.R00) Busbar measurement bay with other switchgear unit, single busbar



X0 (DEV01)

Open Close(d)

U A01 U A02

/ /












X0 (DEV01)

Open Close(d)

U A01 U A02

K A01 K A02














U A01 U A02 U A03 U A04 U B05

K A01 K A02/ //














U A01 U A02 U A03 U A04 U B05

K A01 K A02K A03 K A04/












Q1 (DEV01)

Open Close(d)

U A01 U A02

/ /












Q1 (DEV01) Q8 (DEV02)


U A01 U A02 U A03 U A04

K A01 K A02/ /



Q1 Close(d) (Q8=0)



Q1 Close(d) (Q8=0)






Q1 (DEV01) Q8 (DEV02)


U A01 U A02 U A03 U A04

K A01 K A02K A03 K A04



Q1 Close(d) (Q8=0)

Q8 Close(d) (Q1=0)



Q1 Close(d) (Q8=0)

Q8 Close(d) (Q1=0)



Bay Type No. 188 (M23.302.R02) Busbar measurement bay with fuse unit, double busbar



Q1 (DEV01) Q2 (DEV02) F1 (SIG_1: Signal S011) F2 (SIG_1: Signal S012)


U A01 U A02 U A03 U A04 U B05 U B06

K A01 K A02K A03 K A04/

/









Bay Type No. 189 (M23.312.R02) Busbar measurement bay with fuse unit, double busbar



Q15 (DEV01) Q25 (DEV02) F1 (SIG_1: Signal S011) F2 (SIG_1: Signal S012)


U A01 U A02 U A03 U A04 U B05 U B06

K A01 K A02K A03 K A04/

/










Bay Type No. 193 (M23.902.R02) Busbar measurement bay with other switchgear unit, double busbar



Q1 (DEV01) Q2 (DEV02)


U A01 U A02 U A03 U A04

K A01 K A02K A03 K A04












Q15 (DEV01)

Open Close(d)

U A01 U A02

/ /












Q25 (DEV01)

Open Close(d)

U A01 U A02

/ /












Q15 (DEV01) Q25 (DEV02)


U A01 U A02 U A03 U A04

K A01 K A02K A03 K A04










Bay Type No. 130 (E13.901.R01) Busbar grounding bay with other switchgear unit, single busbar



Q15 (DEV01)

Open Close(d)

U A01 U A02

K A01 K A02









Bay Type No. 132 (E23.903.R02) Busbar grounding bay with other switchgear unit, double busbar



Q15 (DEV01) Q25 (DEV02)


U A01 U A02 U A03 U A04

K A01 K A02K A03 K A04










Bay Type No. 1 (X99.901.R00) Other bay type with other switchgear unit, without busbar









Appendix D - Overview of Changes

P43x/EN M/Ac7 // AFSV.12.10220 D /// P433-308-410/411-612 // P435-308-413/414/415-612 D-1

Version Changes

P433-301-401-601 P435-301-401/-402-601 Release: 05.02.2001

Initial product release

Hardware No changes P433-301-401-602-701 P435-301-401/402-602-701 Release: 18.07.2001

Diagram No changes

Software

COMM2 There is a second communication channel available.

IRIGB P435: In software version -610 the IRIG-B interface was not supported. This error has now been corrected.

THERM The thermal overload protection function has been enhanced by adding coolant temperature monitoring.

OL_DA The overload data acquisition function has been enhanced.

Hardware No changes P433-302-402/403-603 P435-302-401/402/403-603 Diagram No changes

Software

MAIN The procedure to determine the energy value was changed.

P433: The measured reference voltage value has been added.

FT_RC P433: The reference voltage value is recorded.

DIST Minimum starting time is now reduced to less than 10 ms. The distance zones may now be blocked individually via appropriately configured binary signal inputs. Distance zones may also be blocked individually from the newly added power swing blocking function.

PSB P433: The power swing blocking function has been added.

P435: The power swing blocking function has been modified.

MCMON P433: "Fuse Failure" monitoring has been added.

ARC P433: If required ARC can now operate together with the automatic synchronism check (ASC).

ASC P433: The automatic synchronism check function has been added.

Appendix D - Overview of Changes (continued)

D-2 P43x/EN M/Ac7 // AFSV.12.10220 D /// P433-308-410/411-612 // P435-308-413/414/415-612

Version Changes

Hardware A new communication module A, providing InterMiCOM protection signaling interface COMM3, can now be fitted on slot 3, instead of the transient ground fault detection module N.

P433-303-404/405-604 P435-303-404/405/406-604

Release: 21.03.2003 Diagram The new terminal connection diagrams include the COMM3 interfaces:

P433 -404 (for 40TE case, pin-terminal connection) P433 -405 (for 84TE case, ring-terminal connection)

P435 -404 (for 40TE case, pin-terminal connection) P435 -405 (for 84TE case, pin-terminal connection) P435 -406 (for 84TE case, ring-terminal connection)

Software

COMM1(2) Bug fixing concerning the IEC60870-5-103 communication protocol: For reclose commands of high-speed and time-delayed reclosing

(function type 80h, information nos. 80h and 81h), the status changes 'ON' to 'OFF' were signaled spontaneously and were transmitted as part of the response to a general interrogation.

The trip signal of back-up overcurrent (BUOC) was transmitted with ASDU 1 (instead of ASDU 2).

The fault location output X in Ohms (F T _ D A : F a u l t r e a c t . , p r i m . (004 029), function type 80h, information no. 49h) is now suppressed at the interfaces (i.e. the telegram is not sent), if its value is determined as 'Not measured‘.

COMM3 New function group: COMM3 (InterMiCOM protection signaling interface) permits end-end channel-aided schemes to be configured, without requiring discrete carrier equipment.

MEASO Scaling of the BCD output of measured values now allows the setting of an output values range. This feature is required if signed event measured values are assigned to the BCD output (like fault location or short-circuit reactance,...).

MAIN New input signals allow direct transfer tripping without use of protective signaling scheme logic (function group PSIG).

The determination of the faulty phase during a ground fault in Petersen coil compensated power systems is improved to avoid incorrect signaling at the end of the ground fault.

The BUOC-trip signal now forms part of the configuration list for the general trip commands. (Please note, that this trip signal forms a fixed part of general trip command 1 and may only assigned to general trip command 2.)

Bug fixing: In the selection table for M A I N : F c t . a s s i g n . f a u l t (021031) output relays K14x, K16x and K18x were missing.



Version Changes

FT_DA Bug fixing: The fault location output is now correctly given in accordance with its setting.

Bug fixing: Fault locations of numerical values > 655.35% were falsely displayed as small values.

The output of the primary short-circuit reactance is now made in the same way as the fault location.

The measuring window for fault data acquisition is determined by the distance element only if the fault duration is shorter than 55 ms.

DIST The directional element was further improved in order to cope with transient errors seen with synthetic test signals for faults close to the directional line.

MCMON Bug fixing: The M.C.B. trip signal was stored without the 300 ms pick-up delay in the monitoring signal memory. This caused false entries in case of switching-off of the auxiliary supply, if at the same time the auxiliary voltage of the binary signal input was also switched-off (input operated as 'active low').

Bug fixing: The Vneg comparator for monitoring the voltage measuring circuits was not initialized if the operating mode at M C M O N : O p . m o d e v o l t . m o n . was set to 'Vneg with curr. enab'as long as the load current was below 5% Inom.

PSIG ARC ASC GFSC (P435) GSCSG (P435)

The functionality of equal-priority enabling or disabling a function via any device interface is now modified in such a way that the functions are enabled by default.

GFSC P435: Accuracy of the current-dependent tripping times is improved. Particularly the characteristic 'IEC extremely inverse' is now within the claimed tolerance range.

GSCSG P435: The status signal G S C S G : T e l e c o m . f a u l t y was made available in conjunction with the implementation of the InterMiCOM protective interface.

DTOC DTOC ground fault protection is now able to operate in directional mode.

IDMT Accuracy of tripping time is improved. Particularly the characteristic 'IEC extremely inverse' is now within the claimed tolerance range.

The direction characteristic for short circuit direction measurement based on negative-sequence current and voltage is now corrected.

TGFD The setting range for the parameter at T G F D : I N , p > (016 042) has been extended to 0.03 Inom.

The pick-up delay of the measuring circuit monitoring signal at S F M O N : T G F D m o n . t r i g g e r e d (093 094) is now increased from 5 s to 65 s.



Version Changes

Hardware The new hardware variants now offer, per ordering option, additional operating thresholds for the binary signal inputs:

>18 V (standard variant) (no order ext. No.) >90 V (60...70% of VA,nom = 125..00.150 V) (Order ext. No. 461) >155 V (60...70% of VA,nom = 220..0.250 V) (Order ext. No. 462) >73 V (67% of VA,nom = 110 V) (Order ext. No. 463) (new) >146 V (67% of VA,nom = 220 V) (Order ext. No. 464) (new)

Installation of the standard variant is generally recommended if the application does not specifically require such binary signal inputs with higher operating thresholds.

P433-304-404/405-605 P435-304-404/405/406-605

Release: 31.01.2005

Diagram No changes

Software

COMM1 Bug fixing in the IEC 60870-5-101 protocol:

o Support of the 7-byte time tag length has been corrected: C O M M 1 : T i m e t a g l e n g t h = 7 byte (003 198).

o Transmission of negative cyclic measured values has been corrected.

o Acknowledgment of the general scan command has been corrected.

o Signals in the general scan are now transmitted correctly without a time tag.

o Command rejections issued internally by the protection device (between the processor module and communication module) are no longer signaled by the communication interface.

o Commands are now transmitted correctly, even when the ASDU address length is 2 byte: C O M M 1 : A d d r e s s l e n g t h A S D U = 2 byte (003 193).

SFMON The "Memory function" of the monitoring signal memory can now be set. After the associated timer stage has elapsed, a renewed occurrence of a warning is processed the same way as if it where a first occurrence.

FT_RC The recording duration for binary tracks is now limited to 1 minute in order to prevent recording of endless events.

MEASI Open-circuit monitoring of the 20 mA input has been improved.

The maximum temperature value since the last reset is now displayed by the new measured operating value at M E A S I : T e m p e r a t u r e T m a x (004 233). This measured operating value is reset by the new triggering parameter M E A S I : R e s e t t e m p e r a t . T m a x (003 045).



Version Changes

MAIN Parameters, which could previously only be set in the "General Functions" branch of the menu tree, have been transferred to the parameter subsets.

M A I N : N e u t r . p t . t r e a t . P S x M A I N : P h a s e p r i o . 2 p G P S x M A I N : T r a n s f e r f o r 1 p P S x M A I N : O p . m o d e r u s h r . P S x M A I N : I > l i f t r u s h r . P S x M A I N : I ( 2 * f n ) / I ( f n ) P S x

With this improvement it is now possible to consider operational changes in the system's neutral grounding by selecting the appropriate parameter subset.

The general trip command is now available as a multiple signal made up by the two trip commands 1 and 2. M A I N : G e n . t r i p c o m m a n d (035 071)

The CB close time (e.g. time from close command to closing of CB contacts) can now be set at M A I N : t C B , c l o s e (000 032). This time duration may be applied in the function ASC for the new functionality "switch on at point of synchronism".

The following per unit measured operating values have been added: M A I N : A p p a r . P o w e r S p r i m . (005 025) M A I N : A p p a r . p o w e r S p . u . (005 026) M A I N : A n g l e ΣV P G v s . I N (005 009)

Bug fixing: All energy counters where reset by a general starting (GS).

The BUOC-trip signal now forms part of the configuration list for the general trip commands. (Please note, that this trip signal forms a fixed part of general trip command 1 and may only assigned to general trip command 2.)

Bugs discovered after release: The setting parameter M A I N : I N , n o m , p a r d e v i c e (010 023) of the parallel line neutral current input, used for mutual compensation, is visible in the data model but has no function. The parameter becomes invisible – which is correct – after reading-out the setting from the device, as the necessary CT is not available with the P433/P435.

DIST Bug fixing: Frequency compensation at 60 Hz nominal frequency is now correct.

Bug fixing: When an inclined reactance characteristic (σ ≠ 0°) was set, the set angle with an opposite sign was used in determining the zone decision (e.g. setting a negative angle σ < 0° would lead to a larger characteristic).

Bug fixing: Undervoltage starting could tend to overreact when switching on to an idle feeder with line side VT. The joint action with the function SOTF, set to operating mode "trip with starting", would lead to unwanted tripping.



Version Changes

PSB Extension of the power swing detection function by the operating mode ∆Z. Here the rate of change of the resistance component of positive-sequence impedance, when entering the power swing polygon, is interpreted.

PSIG The blocking condition for the weak-infeed logic was extended.

ARC This function now also operates with a direct transfer trip from the remote end M A I N : T r a n s f e r t r i p . E X T (120 046).

ASC New functionality "Switch on at point of synchronism": In slightly asynchronous networks the reclose command can be controlled in such a way that it will be issued at the exact point of synchronism.

The close command conditions can now be set individually for ARC and manual closing.

The reference voltage Vref and the voltage from the corresponding measuring loop are stored as event data.

GFDSS The setting parameters for the function GFDSS are now included in the parameter subsets and can be changed, according to operating conditions, by selecting the appropriate parameter subset. It is also possible to individually enable this function in each parameter subset.

Processing of the function GFDSS now occurs with a higher priority in order to obtain reduced reaction times with less fluctuation. This is a response to the increased application of ground fault direction signaling as a tripping condition.

'Admittance processing' was added to the function GFDSS.

Bug fixing: The cause for faulty or unstable directional decisions with the operate delay tVNG> set below 60 ms has been removed.

Bug fixing: The operate delays LS and BS are now accurate, even with set values > 65 s.



Version Changes

TGFD The setting parameters for the function TGFD are now included in the parameter subsets and can be changed, according to operating conditions, by selecting the appropriate parameter subset. It is also possible to individually enable this function in each parameter subset.

Bug fixing: As of version -604 the setting range for the current stage T G F D : I N , p > (016 042) has been extended to 0.03 Inom. Such a sensitive setting of the current stage at T G F D : I N , p > P S x could lead to triggering of the self-monitoring function which would then issue the S F M O N : M o d u l e N D A C f a u l t y (093 095) warning signal.

Bug fixing: As of version –602 there was a bug, where it was not checked that necessary TGFD hardware was present when a setting file, with the TGFD configured, was downloaded to the device. This check was only carried out after a warm restart of the device and therefore lead to an entry to the monitoring signal memory, which could not be acknowledged.

f<> The length of the evaluation window is now limited internally to 5 cycles.

P<> The underpower stages P</<< und Q</<< were added to the function. Further starting signals were added which will only trigger when power values have been determined and the power direction is detected to correspond with the setting.

LOGIC Bug fixing: The LOGIC timer stages are no longer reset with a parameter subset selection.

Bug fixing: The function "Minimum duration" was corrected.

Bug fixing: The function LOGIC can now be correctly inactivated (e.g. all outputs are set to the logic state ‘low'), when the protection is set off-line (either by setting the relevant parameter or as a reaction to a triggering of the self-monitoring function).



Version Changes

Hardware The new Ethernet module for communication per IEC 61850 is now available and may be fitted to slot 2 as an alternative to communication module A.

P433-305-406/407-610 P435-305-407/408/409-610

Release: 20.02.2006 Diagram The updated connection diagrams now include the Ethernet module

communication interface.



The designation texts of the binary signal inputs and output relays have been replaced by the standard Px3x texts, i.e. the designation comprises the board location number (1 or 2 digits) followed by a consecutive number (2 digits). Example: K2001 replaces K201 (= first relay in slot 20).

Software

IEC Initial implementation of the IEC 61850 communication protocol.

GSSE In conjunction with the IEC 61850 communication protocol a communication procedure has been implemented that is compatible with previous UCA2 GOOSE for the exchange of binary information within an Ethernet network section.

GOOSE For the exchange of binary information in an Ethernet network section the IEC 61850 communication procedure (IEC-GOOSE) has been implemented.

ASC Bug fixing: In version -608 the internal timer clock was corrupted during the ASC operative time. This led to implausible time tags added to binary signals, which in turn made fault records difficult to interpret. Protection functions were in no way affected.

Bug fixing: In version -605 the offset angle (ASC: Phi of fset PSx) was taken into account but by a factor of 10 less than required (for instance when set to 90° an internal value of only 9° was taken into account).



Version Changes

Hardware As an ordering option for the 40TE and 84TE model versions there is now a variant available with a detachable HMI. The detachable HMI is always supplied with a case width of 40TE.

The following new functions are available independently of the ordering option for the control panel type (e.g. detachable HMI or permanently mounted LOC):

Six freely configurable LEDs (H18 to H23) are situated next to six freely configurable function keys.

All of the freely configurable LEDs (H4 to H16 and H18 to H23) are provided as multi-color type LEDs.

P433-306-408/409-611 P435-306-410/411/412-611

Release: 19.04.2007

Diagram The updated connection diagrams now include the interfaces to connect the detachable HMI.



Software

DVICE Because of the "detachable HMI" ordering option these additional 'Device Identification' parameters are now available:

D V I C E : S W v e r s i o n D H M I (002 131) D V I C E : SW vers ion DHMI DM (002 132)

LOC Because of the "detachable HMI" ordering option this additional 'Device Identification' parameter is now available: L O C : L o c a l H M I e x i s t s (221 099).

LOC MAIN

Respective binary signal inputs (if previously unavailable) are assigned to all default reset functions. These binary input functions are now available in the configuration list for the two newly implemented group resetting functions as well as the extended functional assignment for the CLEAR key ('C'):

M A I N : F c t . a s s i g n . r e s e t 1 ( 005 248) M A I N : F c t . a s s i g n . r e s e t 2 ( 005 249) L O C : F c t . r e s e t k e y (005 251)

Two menu jump lists may now be configured. These menu jump lists make it possible to select individual menu points (i.e. set values, counters, triggering functions, event logs) in a freely definable sequence.

L O C : F c t . m e n u j m p l i s t 1 (030 238) L O C : F c t . m e n u j m p l i s t 2 (030 239)

IEC Implementation of the communication protocol has been extended:

A second SNTP server is supported

VLAN priority can be set

Implementation of the communication protocol IEC 61850 in this version of the P433/P435 is certified by KEMA.



Version Changes

OUTP MAIN LOGIC

Bug fixing:

In the selection list for the configuration of the output relays, for the function assignment of the Boolean equations and in the configuration of the trip commands these two signals were missing:

L O G I C : O u t p u t 3 2 (042 094) and L O G I C : O u t p u t 3 2 ( t ) (042 095).

SFMON Bug notice: Programmable signals S F M O N : O u t p u t 3 0 (098 053) to S F M O N : O u t p u t 3 2 ( t ) (098 058) will not issue a warning signal, even if they have been selected at S F M O N : F c t . a s s i g n . W a r n i n g (021 030)

LED The new detachable control panel (HMI) provides the following display functionalities:

The operating mode for the LED indicators has been extended by the operating mode LED flashing.

The freely configurable LED indicators, H4 to H16 and H18 to H23, may now have two signals assigned to them, each controlling a different colored light emission (red or green). If both assigned signals are active the resulting LED color will be 'amber' (yellow).

Configuration, operating mode and physical state of the H1 and H17 permanently configured LED indicators are now displayed via configuration parameters and physical state signals.

F_KEY The new detachable control panel (HMI) is fitted with 6 freely configurable function keys which may be used either as switches or keys, and are password protected.

FT_DA Bug fixing:

When the primary short circuit impedance was calculated, the set secondary nominal voltage was not taken into account (the calculation was always carried out with the value for Vnom = 100 V).

FT_RC The P S B : Z w i t h i n p o l y g o n (036 024) signal is now entered into the fault recording.



Version Changes

MAIN Implementation of CB status signal monitoring has been extended. Optionally the P435 can process pole-selective status signals. Similar to the P433 the signals 'CB 3-pole open' or 'CB 3-pole closed' can be processed as an alternative. This extension feature was required for the new circuit breaker failure protection function and, furthermore, it also affects other functions (MCMON, ARC, PSIG, GSCSG, and GFTRP). The implementation is backward-compatible, e.g. if only the 'CB 3-pole closed' signal is available, as previously, there are no apparent functional modifications.

If the system star point is low-impedance grounded the ground fault starting condition for distance protection has been made settable: M A I N : G r o u n d s t a r t i n g P S 1 (001 249) = IN> OR VNG>' or 'IN> AND VNG>' Here the MAIN setting value 'OR' corresponds to the previous operation.

The selection table for the function assignment of the blocking functions, for example M A I N : F c t . a s s i g n . b l o c k . 1 (021 021), has been extended.

Bug fixing:

The M A I N : M i n - p u l s e c l o c k E X T (060 060) state signal is now displayed correctly with the "read only" attribute by the MiCOM S1/S&R-103 support software.

PSB Settable counters for stable and instable power swings have been added to the function. An additional signal is issued when set counter values are reached, and such a signal may also be used for tripping.

Bug fixing:

The measurement of Delta Z was not always carried out correctly when the positive-sequence impedance moved into the power swing polygon "from left to right".

The maximum blocking time is now re-started again with each entry into the power swing polygon.

The display text for the dimension of the setting value at P S B : I P > (014 058) has been corrected.

MCMON A copy of the current version of "Fuse Failure" monitoring from the P437-611 has been implemented. This includes the following functional changes:

The default setting for M C M O N : V n e g > , F F (031 056) has been increased to 0.16 Vnom. This value is generally recommended. Note: Such modifications must be carried out manually when converting existing setting files.

There is no voltage monitoring while the ARC dead time is running and with an open circuit breaker (acquisition from the CB’s auxiliary contacts).

Additionally the function can be blocked by a binary input function at M C M O N : B l o c k i n g F F , V E X T (002 182)



Version Changes

BUOC The setting range for the overcurrent stages has been extended:

B U O C : I > P S 1 (010 058) = 0.10 … 1.00 … 20.00 Inom B U O C : IN> PS1 (010 064) = 0.10 … 0.20 … 20.00 Inom

PSIG Bug fixing:

When the parameter P S I G : E c h o o n r e c e i v e P S 1 (015 003) was set to 'On receive' an echo signal was issued only if a voltage drop was detected before the receive signal was attained.

ARC When the parameter A R C : Z o n e e x t . d u r . R C P S 1 (015 088) = 'Following HSR' or 'Always' the ARC function now permits distance tripping by the overreach zone, with reclosing having failed, regardless of whether PSIG is ready or not. The overreach zone is enabled for the duration of the set reclose command time even when the command is terminated together with the CB closed position signal.

ASC An additional operating mode was implemented with the voltage checking function which makes reclosing possible only if one of the two ends is already carrying voltage (the respective other end must be de-energized) such as:

ASC: AR Op.mode v-chk. PS1 (018 029) = 'N V&Vref or V&n Vref'

The meaning of abbreviation 'N V&Vref or V&n Vref' is "[(NOT V) AND Vref] OR [V AND (NOT Vref)]".

When the operating mode is set to 'Vref & Z1 but not V' the significance of 'Z1' is extended so that with a trip from distance zone 1 OR a PSIG trip the condition is met. This then makes reclosing possible if the primary fault was on the protected line.

The default values for which the voltage thresholds determine that 'voltage is present' (V>) or 'voltage is not present' (V<) have been set to more realistic values:

A S C : A R V > v o l t . c h e c k P S 1 (026 017) = 0.80 Vnom(/√3) A S C : A R V < v o l t . c h e c k P S 1 (018 017) = 0.20 Vnom(/√3)

DTOC The intermittent ground fault protection function was added to the residual overcurrent timer stages (hold-time stage, pulse extension and separately set accumulated tripping time).

IDMT The residual current stage has been enhanced by functionalities available with the P437 -610:

Extended (sensitive) setting range for the reference current at the measured value for the residual current.

Minimum current value to be exceeded before time measurement will start.

Minimum trip time

Compensation reactance value to be set with the protection of series compensated lines.



Version Changes

V<> The over-/undervoltage function may now be optionally operated with an enable threshold based on the minimum current monitor for the undervoltage stages (V<, V<<, Vpos<, Vpos<<). The undervoltage stages are blocked if during active monitoring the set threshold of at least one phase is not exceeded by the phase currents. There are two new setting parameters to activate the operating mode for minimum current monitoring and to set the enable threshold:

V<>: Op. mode V< mon. PSx V<>: I enable V< PSx

CBF The complete revision of the circuit breaker failure protection function now includes a current reset criterion.



Version Changes

Hardware Additional binary input/output modules are now available:

X (24I) fitted with 24 binary signal inputs, X (6xI, 6xO) to control up to 3 switchgear units, X (6xI, 3xO) fitted with 6 binary signal inputs and 3 output relays, X (4xOH) fitted with 4 heavy duty contacts.

P433-308-410/411-612 P435-308-413/414/415-612

Release: 19.07.2008

Diagram The updated connection diagrams now include the terminal connection diagrams for the new binary I/O modules.



Software

DVICE Up to 3 switchgear units may now be controlled but this requires that the device be fitted with module X (6xI, 6xO) (see "Hardware" above) as well as with a communications module (COMM1+COMM2 or Ethernet+COMM2).

Parameter D V I C E : A F S O r d e r N o . (001 000) is to be used instead of D V I C E : O r d e r N o . (000 001).

IEC Bug fixing: The incorrect scaling factor for Inom = 5A in the Comtrade files was corrected. A comma in the channel designation text would lead to an error message in Eview and has therefore been replaced by a decimal point. A faulty Comtrade file name could have been generated in specific situations.

I E C : D e a d b a n d v a l u e (104 051) was divided into several individual settings:

IEC: Dead band IP (104 230) IEC: Dead band IN (104 231) IEC: Dead band VPP (104 232) IEC: Dead band VPG (104 233) IEC: Dead band f (104 234) IEC: Dead band P (104 235) IEC: Dead band phi (104 236) IEC: Dead band Z (104 237) IEC: Dead band min/max (104 238) IEC: Dead band ASC (104 239) IEC: D e a d b a n d t e m p . (104 240) IEC: Dead band 20mA (104 241)

IEC: Update Measurements (104 229): Time period between two transmissions of all the measured Report Control Blocks (RCB) except the measured value for energy.

Various operating modes can be set at I E C : D E V c o n t r o l m o d e l (221 081) to control external devices from the clients.



Version Changes

GOOSE Several GOOSE signals have been added because of the newly-implemented control functionality. For details, see section "Configuration Parameters" in Chapter "Settings" and section "Logic State Signals" in Chapter "Information and Control Functions".

COMMx An error in the handling of time tags has been corrected.

Data points C O M M 1 : - 1 0 3 p r o t . v a r i a n t (003 178) and C O M M 1 : A d d r e s s m o d e (003 168) are now also available with the setting for the communications protocol per IEC 60870-5-103.

INP The I N P : F i l t e r (010 220) setting parameter is now available for conformity with standard IEC 60255-22-7, class A.

Further reset commands were added to the function assignment of binary signal inputs: C O M M 3 : R e s e t N o . t l g e r r E X T ( 006 054) M E A S I : R s t . t e m p . T m a x E X T ( 006 076) A S C : R e s e t c o u n t e r s E X T ( 006 074) f < > : R e s e t m e a s . v a l s E X T ( 006 075)

F_KEY Data points F _ K E Y : F c t . a s s i g n m . F x (x=1 to 6) have been renamed to F _ K E Y : F u n c t i o n a s s i g n m . F x .

LED By default (unchanged) the H4 LED indicator is assigned to M A I N : G e n . t r i p s i g n a l ( 036 251), but its operating mode is now set at L E D : O p e r a t i n g m o d e H 4 (085 008) to ES reset (fault) by default.

MAIN The designation text of the following data point has been changed: M A I N : D e v i c e o n - l i n e (003 030) (was previously: M A I N : P r o t e c t i o n e n a b l e d )

In order to assign control functions to function keys the following parameters are now available and may be assigned to four of the six function keys:

M A I N : D e v i c e s e l e c t i o n k e y (006 001) M A I N : D e v i c e O P E N k e y (006 002) M A I N : D e v i c e C L O S E k e y (006 003) M A I N : L o c a l / R e m o t e k e y (006 004)

Also available is the acquisition of binary signals with the debouncing feature to use with the control function and the parameter M A I N : T i m e t a g (221 098).

Because of the control functionality these data parameters are now provided: M A I N : T y p e o f b a y (220 001) M A I N : C u s t o m i z e d b a y t y p e (221 062)

The M A I N : M e a s . d i r e c t i o n P , Q (006 096) setting now allows sign inversion for the display of the following measured operating values:

M A I N : A c t i v e p o w e r P p r i m . (004 050) M A I N : R e a c . p o w e r Q p r i m . (004 052) M A I N : A c t i v e p o w e r P p . u . (004 051) M A I N : R e a c . p o w e r Q p . u . (004 053)



Version Changes

MAIN The following logic state signals are issued depending on the respective control point position: M A I N : C m d . f r . c o m m . i n t e r f (221 101) M A I N : C o m m a n d f r o m H M I (221 102) M A I N : C m d . f r . e l e c t r . c t r l (221 103)

New measured operating values:

MAIN: Load angle phi A p.u. (005 073) MAIN: Load angle phi B p.u. (005 074) MAIN: Load angle phi C p.u. (005 075) MAIN: Angle phi N p.u. (005 076) MAIN: Angle ΣVPG/IN p.u. (005 072) MAIN: Frequency f p.u. (004 070) MAIN: IA pr im,demand/IA p.u.demand (006 226 / 006 235) MAIN: IB pr im,demand/IB p.u.demand (006 227 / 006 236) MAIN: IC pr im,demand/IC p.u.demand (006 228 / 006 237) MAIN: IA pr im,demand stor. / IA p.u. ,demand stor. (006 223 / 006 232) MAIN: IB pr im,demand stor. / IB p.u. ,demand stor. (006 224 / 006 233) MAIN: IC pr im,demand stor . / IC p.u. ,demand stor . (006 225 / 006 234)

SFMON Bug fixing: Programmable signals S F M O N : O u t p u t 3 0 (098 053) etc. did not issue their respective alarm signals when they had been selected at S F M O N : F c t . A s s i g n . w a r n i n g (021 030).

The S F M O N : T G F D m o n . t r i g g e r e d (093 094) signal can now be selected at S F M O N : F c t . A s s i g n . w a r n i n g (021 030) but it does not automatically issue an alarm signal on its own.

DIST The monitoring speed and accuracy of the tripping time in isolated neutral and resonant grounding systems has been improved.

MCMON The following new signals are now available: M C M O N : M . c i r c . V r e f f l t y . (007 213) M C M O N : M . c i r c . V N G f l t y . (007 214) This permits blocking of only the associated voltage timer stages in V<>, without blocking the entire V<> function group.

PSIG The former parameter P S I G : R e c e i v e E X T (036 048) is now featured as two signals: P S I G : R e c e i v e ( A ) E X T (036 048) P S I G : R e c e i v e ( B ) E X T (006 037) By setting P S I G : 3 e n d e d l i n e p r o t P S x it is determined whether both signals are linked in an 'AND' or an 'OR' gate to form the P S I G : R e c e i v e (006 036) combined signal.

ARC Operative time 2 (A R C : O p e r a t i v e t i m e 2 P S x ) is now featured by the P433 as well as by the P435.

When A R C : M o n . P S I G r e c v . P S x is set to 'Yes' then the signals received between the operative time and the dead time are counted, and when the result in the counter is not 1 then the device switches to the tPmax mode.

Bug fixing: Up to now the 'kze' factor was always applied with the HSR (i.e. this also applied to a TDR).



Version Changes

ASC The cycle time at which the measured values from the automatic synchronism check are transmitted may be set at A S C : T r a n s m . c y c l e , m e a s . v . (101 212).The meaning of “Z1” for the 'Vref & Z1 but not V' operating mode has been enhanced, so that the close request is also enabled if a PSIG based Z1e trip occurs (because in this case, too, a fault on the line is detected).

DTOC Bug fixing: Up to now blocking of the tIN timer stage (by setting D T O C : t I N > P S x (072 027) to 'Blocked') also resulted in the blocking of the direction determination by the residual current stages tIN>>, tIN>>> and tIN>>>.

V<> There are now time voltage protection stages available for Vref.

P<> Bug fixing: In certain situations an overflow could occur with very large values for P<, Q<.

CBF The parameter designation for C B F : I > (022 160) was changed to C B F : I < (022 160).

Now the P433 also features the following parameters: C B F : C u r r e n t f l o w A (038 230) C B F : C u r r e n t f l o w B (038 231) C B F : C u r r e n t f l o w C (038 232) C B F : C B s y n c . s u p e r v A o p e n (038 227) C B F : C B s y n c . s u p e r v B o p e n (038 228) C B F : C B s y n c . s u p e r v C o p e n (038 229)

CBM These new data points signal the sum of trip currents:

C B M : Σ I t r i p A (009 071) C B M : Σ I t r i p B (009 073) C B M : Σ I t r i p C (009 076)

LIMIT Monitoring of the reference voltage is now provided.

DEV01 to DEV03

The new "External device xx" (xx: 01, 02, 03) function group is now available because control functions have been implemented.

ILOCK The new "Interlocking logic" function group is now available because control functions have been implemented.

CMD_1 The new "Single-pole commands" function group is now available because control functions have been implemented.

SIG_1 The new "Single-pole signals" function group is now available because control functions have been implemented.

Schneider Electric 35 rue Joseph Monier 92506 Rueil-Malmaison FRANCE

Phone: +33 (0) 1 41 29 70 00 Fax: +33 (0) 1 41 29 71 00 www.schneider-electric.com Publishing: Schneider Electric

Publication: P43x/EN M/Ac7 Version: -612 11/2010

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MiCOM P433/P435


P43x/EN AD/Ae7 (AFSV.12.10550 D)

Version P433 -308 -410/411 -612 ⇒ P433 -308 -410/411 -614 Version P435 -308 -413/414/415 -612 ⇒ P435 -308 -413/414/415 -614

Upgrade Documentation

P433/P435 Upgrade Documentation

In these latest versions of the P433 and P435 several new features and changes on existing features have been added. These are described with reference to the documentation listed below:

Reference Released Version Documentation

19.07.2008 P433-308-410/411-612 P435-308-413/414/415-612

Technical Manual P43x/EN M/Ac7 (AFSV.12.10220.D)

P43x/EN AD/Ae7 // AFSV.12.10550 EN /// P433-308-410/411-614 // P435-308-413/414/415-614 U-3

P433/P435 Upgrade Documentation (continued)

Overview

Version Changes

Hardware No changes P433-308-410/411-612-710 P435-308-413/414/415-612

-710 Diagram No changes

Release: 26.02.2009 Software

DVICE Bug fixing: If the device was fitted with the communication module that operates with just one interface supporting the IEC 60870-5-103 protocol, then it was blocked when the control function was used. The hardware self-identification has been enhanced by the addition of a feature that checks at startup whether the binary I/O module X (6xI, 6xO) is fitted; in such a case the control function is enabled only when either no communication module is fitted or a communication module with two interfaces is fitted (furthermore order extension numbers for communication modules do not contain the figures "-91x").

IEC Bug fixing: • The correct number of binary channels is now entered in the

COMTRADE configuration file (*.cfg). In the previous version the number of binary channels was given as n*16+1 when, because of the function configuration, n*16 binary information signals were recorded. Therefore values stored in the *.cfg file and the *.dat file did not match.

• It is now guaranteed that no communication error will occur when several clients simultaneously request fault files.

• Reports from SIG1 to SIG40 were lost when events changed in just a few milli-seconds.

• If bays for direct motor control were used a communication fault would occur when fast successive command signals were received (SPC’s system/ SPCOx).

• After approximately 15,000 switching commands an internal memory fault would cause the rejection of further commands. Furthermore no GOOSE messages could be sent in that faulty memory state.

GOOSE The TAL (time allowed to live) for GOOSE messages has been increased so that during normal operation the loss of one single message would have no consequences.

COMM1 Bug fixing in DNP3 protocol: Contact positions were transmitted twice.

LOC Bug fixing: With version -612 the following display settings were without function: (221 070) L O C : D i s p l a y L / R = without (221 071) L O C : D i s p l . i n t e r l . s t a t . = without

MAIN Bug fixing: Random changes in the internal clock setting (typically 7 hours) were observed when external time synchronization (IRIG-B or by a communication protocol) was missing.

U-4 P43x/EN AD/Ae7 // AFSV.12.10550 EN /// P433-308-410/411-614 // P435-308-413/414/415-614

P433/P435 Upgrade Documentation (continued)

Version Changes

DIST Bug fixing: As of version -610 zero-sequence starting only (IE> AND VNE>) could no longer be determined when neutral point treatment was set to isolated/compensated (setting at M A I N : N e u t r . p t . t r e a t . P S x = Isol./res.w.start.PG).

This version is project-specific and only available on request! P433-308-410/411-613 P435-308-413/414/415-613

Release: ---

Hardware No changes P433-308-410/411-614 P435-308-413/414/415-614

Release: 01.02.2010 Diagram No changes

Software

F_KEY With the default setting a password is no longer required when a function key is to be pressed. If required a password may be set, as previously, from the local control panel.

MAIN It is now possible to set the reset time of the manual close command enable using this parameter: (003 088) MAIN: Rel . t . enab. man.cmd

DIST The calculation of the short circuit impedance angle is now always carried out using the filtered fundamental fault voltage value.

PSIG With triple-ended applications the fault signals of both communication channels are now available for separate use. (004 064) PSIG: Telecom. faul ty EXT (008 094) PSIG: Telec. faul ty (B) EXT

The signal (004 064) represents the fault signal for communication channel A, and in the next version the text will be modified accordingly to: (004 064) PSIG: Telec. faul ty (A) EXT

P<> The minimum operate values for the active and reactive power thresholds, with the maximum dynamic range being used, have been extended to 1% Snom so that the setting ranges required to set the Q/V protection functions are now available.

P43x/EN AD/Ae7 // AFSV.12.10550 EN /// P433-308-410/411-614 // P435-308-413/414/415-614 U-5

U-6 P43x/EN AD/Ae7 // AFSV.12.10550 D /// P433-308-410/411-614 // P435-308-413/414/415-614


Phone: +33 (0) 1 41 29 70 00 Fax: +33 (0) 1 41 29 71 00 www.schneider-electric.com Publishing: Schneider Electric

Publication: P43x/EN AD/Ae7 // AFSV.12.10550 D /// P433-308-410/411-614 // P435-308-413/414/415-614 11/2010

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MiCOM P433, P435


P43x/EN AD/Af7 (AFSV.12.10940 D)

Version P433 -308 -410/411 -614 ⇒ P433 -308 -410/411 -615 P435 -308 -413/414/415 -614 ⇒ P435 -308 -413/414/415 -615


P43x, Changes in software version -614 to -615

In the new versions of the Distance Protection Devices MiCOM P43x, several enhanced features and changes on existing features have been included. These are described with reference to the documentation listed below:

References Version Documentation Released

19.07.2008 P433-308-410/411-612 P435-308-413/414/415-612

Technical Manual P43x/EN AD/Ac7 (AFSV.12.10220.D) Upgrade Documentation P43x/EN AD/Ae7 (AFSV.12.10550 D)

01.02.2010 P433-308-410/411-614 P435-308-413/414/415-614

Note:

The software versions P43x-61x constitute a product line that was developed independent to versions P43x-63x. (The main difference is that the device versions with software versions P43x-63x feature the “phase 2” implementation of function group IEC whereas software versions P43x-61x continue with the “phase 1” implementation.)

P43x/EN AD/Af7 // AFSV.12.10940 D /// P433-308-410/411-615 // P435-308-413/414/415-615 3

P43x, Changes in software version -614 to -615 (continued)

1 Overview

Version Changes

Hardware No change P433-308-410/411-615 P435-308-413/414/415-615

Diagram No change

Release: 07.01.2011 Software PC The following menu point has been removed:

P C : N a m e o f m a n u f a c t u r e r (003 183) Note: Compatibility even with older versions of the operating program continues to be guaranteed.

IEC In order to guarantee full compatibility with PACiS the neutral-point displacement voltage (calculated and measured) as well as the residual current (calculated and measured) were assigned to the node MMXU so that the node MSQI now includes only the positive-sequence and negative-sequence values.

COMM1 The data point C O M M 1 : - 1 0 3 p r o t . v a r i a n t (003 178) may now be used to select between the 103 protocol variants Private and Compatible. The protocol variant Compatible corresponds to the VDEW implementation. Note: As before this setting is hidden unless an IEC 60870-5 protocol is enabled.

COMM1 The data point C O M M 1 : M O D B U S p r o t . v a r i a n t (003 214) may now be used to select between the MODBUS protocol variants Private and Compatible. The protocol variant Compatible corresponds to the MODBUS implementation in the MiCOM Px20 and Px40 protection devices. The protocol variant Private corresponds to the first implementation of the MODBUS protocol. Note: As before this setting is hidden unless the MODBUS protocol is enabled.

COMM1, COMM2

The menu points C O M M 1 : N a m e o f m a n u f a c t u r e r (003 161) and C O M M 2 : N a m e o f m a n u f a c t u r e r (103 161) can no longer be set by using a selection list but, for reasons of compatibility, they may now be defined as free text. The default is SE but, in individual cases, it may become necessary to enter texts differing from the default. Notes: These parameters can only be set using the operating program and it is not possible to set them locally using the integrated local control panel (HMI). The maximum text length is 8 characters and designations exceeding this will be truncated. The parameter C O M M 1 : N a m e o f m a n u f a c t u r e r is hidden unless an IEC 60870-5 protocol is enabled.

F_KEY The default setting of passwords for function keys has been changed. A password is now no longer required when pressing a function key. However, it remains possible to configure a password for each individual function key.

INP Bug fixing: Inputs provided by the binary (I/O) module X (6Ix3O) could not be used.

PSIG Bug fixing: The receive signal was not updated.

4 P43x/EN AD/Af7 // AFSV.12.10940 D /// P433-308-410/411-615 // P435-308-413/414/415-615


P43x/EN AD/Af7 // AFSV.12.10940 D /// P433-308-410/411-615 // P435-308-413/414/415-615 5

Version Changes LIMIT Bug fixing:

The overvoltage stages Vref> and Vref>> for the reference voltage did not operate when the data point A S C : M e a s u r e m e n t l o o p P S x was set to Loop yG (y = A, B, C).

Customer Care Centre

http://www.schneider-electric.com/CCC

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Phone: +33 (0) 1 41 29 70 00 Fax: +33 (0) 1 41 29 71 00 www.schneider-electric.com Publishing: Schneider ElectricPublication: P43x/EN AD/Af7 // AFSV.12.10940 D /// P433-308-410/411-615 // P435-308-413/414/415-615 06/2011

MiCOM P433, P435


P43x/EN AD/Ak7 (AFSV.12.10590 D)

Version P433 -308 -410/411 -614 ⇒ P433 -308 -410/411 -630 P435 -308 -413/414/415 -614 ⇒ P435 -308 -413/414/415 -630


P43x, Changes between Software Versions -614 and -630

In these latest versions of the P433 and P435 several new features and changes on existing features have been added. These are described with reference to the documentation listed below:

References Released Version Documentation

19.07.2008 P433-308-410/411-612 P435-308-413/414/415-612

Technical Manual P43x/EN M/Ac7 (AFSV.12.10220 D)

01.02.2010 P433-308-410/411-614 P435-308-413/414/415-614

Upgrade Documentation P43x/EN AD/Ae7 (AFSV.12.10550 D)

P43x/EN AD/Ak7 // AFSV.12.10590 D /// P433-308-410/411-630 // P435-308-413/414/415-630 3

P43x, Changes between Software Versions -614 and -630 (continued)

1 Overview

Version Changes

Hardware No change P433-308-410/411-614-711 P435-308-413/414/415-614

-711 Diagram No change


IEC Bug fixing:

In version –614, the IEC 61850 communication protocol was not usable.

At high loads it could happen that further select commands were rejected with the signal 'command already in execution'.

GOOSE The protocol's internal parameter Time Allowed to Live was increased from 4000 ms to 4100 ms.

Bug fixing: The internal counters "sqNum" and "stNum" were not initialized correctly (after GOOSE activation).

Hardware No change P433-308-410/411-630 P435-308-413/414/415-630 Diagram No change


DVICE The new data point (008 233) D V I C E : S W v e r s . C h i n . D H M I D M is a purely internal version number (for the order option "Chinese display").

LOC New address for the hold-time of the measured value display added.

(031 072) L O C : H o l d - t . m e a s . v . d i s p l

Values range from 1 to 60 seconds or 'Blocked'.

In the default setting the hold-time is 'Blocked', therefore the behavior is backwards-compatible (new functionality disabled).

LOC It is now possible to assign a custom designation to the busbar (similarly to user-defined names for external devices). The designation wanted may be defined as open text at:

(218 191) L O C : B u s b a r 1 N a m e b y U s e r

LOC Bug fixing:

The Detachable HMI could freeze in case of a warm restart with activated LED reset.

The signals L E D : S t a t e H 1 8 r e d and L E D : S t a t e H 1 8 g r e e n assigned to LEDs located to the right of the function keys were not always updated, i.e. did not always match the actual state.

Process cycle times were often extended to approximately 100 to 150 ms when the device was operated without a local control panel (HMI) being attached.

When LED indicators were reset externally, some characters on the LC display could be shown incorrectly or not at all.

4 P43x/EN AD/Ak7 // AFSV.12.10590 D /// P433-308-410/411-630 // P435-308-413/414/415-630


Version Changes

IEC GOOSE

Phase 2 of the IEC 61850 communications protocol has been implemented. See section "Communication Interface IEC 61850 (Function Group IEC)" for a detailed description of the numerous function enhancements carried out.

GOOSE The protocol's internal parameter Time Allowed to Live was increased from 4000 ms to 4100 ms.

Bug fixing:

Some GOOSE records could be partially transmitted.

The internal counters "sqNum" and "stNum" were not initialized correctly (after GOOSE activation).

The position of switchgear units (XSWI,XCBR) was transmitted by GOOSE with the attribute ‘invalid’.

Measured operating values were not updated in GOOSE messages.

IEC Bug fixing:

After approximately 15,000 close and trip commands the client would cut-off the data communication.

After an abort command with a wrong frame format the state of external devices was no longer transmitted.

The cause for the signal “Undefined opcode” during rapid successive switching commands has been fixed.

When transmitted via the IEC 61850 protocol, valid voltage measured values could be labeled as "invalid".

During a warm restart incorrect date and time data (initialization values) was transmitted for a short time.

COMM1 Communications protocol IEC 60870-5-103: When checking during test operations it is now possible to trigger signals (SIG) and contact positions (DEV) from the control part (previously only possible from the protection part).

These new addresses were added:

Oper/CtrlTest/COMM1

(221 105) C O M M 1 : S e l . p o s . d e v . t e s t – Not assigned – DEV01 to DEV03

(221 106) C O M M 1 : T e s t p o s i t i o n d e v . – don't execute – execute open – execute close – execute intermed.



Version Changes

MAIN New addresses with a 32-bit measured value display have been added for the 4 energy measured values: (008 065) M A I N : A c t . e n e r g y o u t p . p r i m 0 ... 6,553,500.00 MWh (008 066) M A I N : A c t . e n e r g y i n p . p r i m 0 ... 6,553,500.00 MWh (008 067) M A I N : R e a c t . e n . o u t p . p r i m 0 ... 6,553,500.00 Mvar h(008 068) M A I N : R e a c t . e n . i n p . p r i m 0 ... 6,553,500.00 Mvar h

The 8 addresses with the 16-bit displays and overrun counters have been removed.

New logic state signals for clock synchronization: The parameter: M A I N : T i m e s y n c h r o n i z e d (009 109) shows whether an external clock synchronization had been carried out. This signal is reset after 10 minutes.

PSIG Bug fixing: When the PSIG function is not ready, control of the extended zone 1 is transferred to the ARC function, see Figures 3-195 and 3-134 in the P43x –612's Technical Manual. This did not work correctly in the "DC loop" and this problem has now been fixed.

DEVxx Device identifiers can now be edited.

In the "Designat. ext. dev." parameters the 'Device Name User' setting should be selected. Then the text for the device's name, entered by the user at each of the "DEV-Name User" parameters, will be used as the device’s designation. The maximum number of 4 characters was not changed from the previous permanent default setting.

Parameters (DEV01/DEV02/DEV03):

D E V x x : D E V - N a m e U s e r (218 101, 218 102, 218 103)

CMD_1, SIG_1

Bug fixing: Function groups CMD_1 and SIG_1 were enabled after a restart, even if they had been manually disabled.

ILOCK As the interlock conditions are also transmitted together with reporting in the newly implemented phase 2 of the IEC 61850 communication protocol (see above), it is now a requirement that these interlock conditions are cyclically checked and not, as before, only with the request for a switching operation. Therefore this new parameter has been introduced: (221 104) I L O C K : C y c l e t i n t e r l . c h e c k The cycle time (range from 100 ms to 10 s) is set here, after which a check of the interlock conditions is carried out. As additional processor capacity must be provided for each of these checks it must be ensured that a favorable compromise is found for the cycle time setting value. On the one hand it is desirable to select a cycle time value which is as short as possible so that changes in the interlock conditions are updated without any notable delays, but on the other hand this cycle time value should not be so short that the P43x system will be under too much strain. As the P43x CPU load is dependent on the total number of function groups having been configured it is not possible to suggest a generally acceptable cycle time value.



Version Changes LIMIT Bug fixing:

When switching the ASC measurement between phase-to-phase and phase-to-earth loops, the limit values for reference voltage monitoring were not updated until the device was restarted. applies to: (042 144) LIMIT: Vref> (042 145) LIMIT: Vref>> (042 146) LIMIT: Vref< (042 147) LIMIT: Vref<<

CBF The parameter (011 067) C B F : t C B F has been removed. This time-delay is no longer required by the new circuit breaker failure function which includes the undercurrent criterion (available as of version -612).

Bug fixing: The associated signal C B F : C u r r e n t f l o w P h x would sometimes jitter during an open command.



2 Functional Details

2.1 Communication Interface IEC 61850 (Function Group IEC)

As a further option the device is provided with the interface protocol according to the Ethernet based communication standard IEC 61850. As of firmware version P43x -630 the implementation and configuration of the IEC communication interface are now different from previous design versions.

IEC 61850 IEC 61850 was created jointly by users and manufacturers as an international standard. The main target of IEC 61850 is interoperability of devices. This includes the capability for two or more intelligent electronic devices (IED), manufactured by the same company or different companies, to exchange data for combined operation.

This communication standard IEC 61850 has now created an open and common basis for communication from the process control level down to the network control level, for the exchange of signals, data, measured values and commands.

For a standardized description of all information and services available in a field device a data model, which lists all visible functions, is created. Such a data model, specifically created for each device, is used as a basis for an exchange of data between the devices and all process control installations interested in such information. In order to facilitate engineering at the process control level a standardized description file of the device, based on XML, is created with the help of the data model. This file can be imported and processed further by the relevant configuration program used by the process control device. This makes possible an automated creation of process variables, substations and signal images.

The following documentation providing the description of the IEC 61850 data model used with this unit is available:

An XML-based IDC file in the SCL (Substation Configuration Description Language) with a description of data, properties and services, available from the unit, that are to be imported into the configuration tool "IED Configurator” or into a system configurator.

A PICS_MICS_ADL file with the following contents:

PICS (Protocol Implementation Conformance Statement) with an overview of available services.

MICS (Model Implementation Conformance Statement) with an overview of available object types.

ADL (Address Assignment List) with an overview of the assignment of parameter addresses (signals, measuring values, commands, etc.) used by the device with the device data model as per IEC 61850.



Ethernet Module The optional Ethernet module provides an RJ45 connection and a fiber optic interface where an Ethernet network can be connected. The selection of which of the two interfaces is to be used to connect to the Ethernet network is made by setting the parameter [IC]: Media.

Note: Setting parameters from the IEC function group and identified by "[ IC]: . . . " provide information only. They are set with the "IED Configurator", but they cannot be modified from the local control panel (HMI) or with the operating program.

There are two ordering variants available for the fiber-optic interface: the ST connector and the SC connector both for 100 Mbit/s and 1300 nm (a third variant ST connector for 100 Mbit/s and 1300 nm is pending). The RJ45 connector supports 10 Mbit/s and 100 Mbit/s.

The optional Ethernet module additionally provides an RS485 interface for remote access with the MiCOM S1 operating program (function group COMM2).

Notes: The unit may be equipped with the optional Ethernet module only as an alternative to the standard optional communication module. Therefore the Ethernet-based communication protocol IEC 61850 is available only as an alternative to function group COMM1.

Configuration and enabling

The IEC function group can be included in the configuration by setting the parameter I E C : F u n c t i o n g r o u p I E C . This parameter is visible only if the optional Ethernet communication module is fitted to the device. After having included the parameter I E C : F u n c t i o n g r o u p I E C in the configuration the parameter I E C : G e n e r a l e n a b l e U S E R and the parameters for internal clock tracking are visible and freely configurable.

The function can then be enabled or disabled by setting I E C : G e n e r a l e n a b l e U S E R .

The setting parameters from the IEC function group as well as the related function groups GOOSE and GSSE are not automatically active in the unit. The unit features two memory "banks" one of which includes the active setting parameters. The other memory bank is used with the configuration procedure for parameters from the IED Configurator and the operating system. Specific project-related extensions of the IEC 61850 parameters from the IED Configurator are loaded into the unit by downloading a .MCL file. The inactive communication parameters are activated by executing the command I E C : S w i t c h C o n f i g . B a n k . This command may also be issued from the IED Configurator.



U-1 Configuration according to IEC 61850-6



IED

Processor module

IEC 61850 parameters separate from protection device parameters!

New approach to IED parameter management

Control PC

Parameter download

Parameter upload

Operating program

IEDConfigurator

Deviceparameters

Ethernet module

IEC 61850parameter

Bank 1 Bank 2

Bank switching to enable the device parameters

Parameter switch

IEC 61850parameter

19Z7002A_EN U-2 Saving configuration parameters

Client Log-on Communication in Ethernet no longer occurs in a restrictive master slave system, as is common with other protocols. Instead, server or client functionalities, as defined in the 'Abstract Communication Service Interface' (ACSI, IEC 61870-7-2), are assigned to the devices. A 'server' is always that unit which provides information to other units. A client may log on to this server in order to receive information, for instance 'reports'. In its function as server the unit can supply up to 16 clients, linked into the network, with spontaneous or cyclic information.



Clock Synchronization With IEC 61850 clock synchronization is effected via the SNTP protocol, defined as standard for Ethernet. Here the unit functions as an SNTP client.

For clock synchronization one can choose between the operating modes Anycast from SNTP Server or Request from Server. With the first operating mode synchronization occurs by a broadcast message sent from the SNTP server to all units in the network, and in the second operating mode the unit requests a unit-specific time signal during a settable cycle.

Two SNTP servers may be set. In this case, clock synchronization is preferably performed by the first server. The second server is reverted to only if no signal is received from the first server.

When looking at the source priority for clock synchronization, which is set at the MAIN function then, by selecting "COMM1/IEC", synchronization per IEC 61850 is automatically active but only if this communication protocol is applied.

Generating datasets, reporting

The specific project related feature of the unit’s communications behavior is determined by the configuration of datasets, reports and high priority transmission methods. A piece of information must be included in a dataset so as to be transmitted as a signal. A dataset is a list to transmit certain data objects. The selection of data objects and the resulting length of the dataset are determined by the application; merely the maximum size of a dataset to be transmitted by GOOSE (see next section) is limited to 1500 bytes. Data objects provided by the unit are available for selection with a structure as specified by IEC 61850. Within the quality descriptor for each piece of information the invalid bit and the test bit are served according to the unit’s state; the other attributes are not set. Any number of datasets may be created with the IED Configurator. Saving datasets at System\LLN0 is compulsory. The knowledge of dataset content is imperative for decoding and evaluating received signals. Configuration files possess a listing of all datasets with a description of all data objects included.

Next to their use with high priority transmission methods (see following section) datasets are used mainly for reporting. The unit provides up to sixteen unbuffered reports and eight buffered reports independent of the number of clients logged-on. Management is arranged into sixteen Unbuffered Report Control Blocks (urcbA to urcbP) and eight Buffered Report Control Blocks (brcbA to brcbH). Whereas with unbuffered reporting pieces of information may be lost during a communications failure, the buffered report control blocks support a buffered transmission which is required for the uninterrupted writing of events. A pre-defined dataset may be assigned to each report which will then determine which data object will be transmitted with the relevant report. Assigning datasets is not limited; the same dataset may be referenced in various reports or even in GOOSEs.

The unit can serve up to sixteen clients. Each client can log-on to any number of available reports, but one report is always allocated exclusively to only one client. The client is then able to activate the wanted report for himself and to set the transmission behavior to his requirements. The system concept with intended clients must be taken into account when datasets are assigned to the reports.

Reports are not received by the unit.



Transmitting modeled signals not provided by the IEC 61850 data model

In addition to the information included in the IEC 61850 data model an optional number of up to 16 signals can be selected from all the signals available in the unit to be transmitted via reporting. A selection of state signals (shuttling to communications) is made by setting I E C : S i g G G I O 1 s e l e c t i o n . The data object indexes defined for SigGGIO1 must follow the sequence given for the ‘m out of n’ selection for the state signals. The indexes SigGGIO1.ST.ind1 to SigGGIO1.ST.ind16 may then be included in the datasets just as the other data objects.

Single commands Single commands (e.g. short command, long command, persistent command) are configured with the operating program. Sending commands to the unit can be carried out from all clients that have previously logged-on to the unit. But only one command at a time is carried out. The operating mode Direct control with normal security is provided for single commands.

Control and monitoring of switchgear units

Configuration of control of switchgear devices for the IEC 61850 is only possible with the IED Configurator.

Control of switchgear devices can be carried out from all clients that have previously logged-on to the unit. Only one control command is executed at a time, i.e. further control requests issued by other clients during the execution of such a command are rejected. The following operating modes [ I C ] : c t l M o d e l are available to control external devices by clients and they can be individually set for each switchgear device:

Status only

Direct control with enhanced security

SBO (Select before operate) with enhanced security

When set to the operating mode Select before operate the switchgear unit is selected by the client before the control command is issued. Because of this selection the switchgear unit is reserved for the client. Control requests issued by other clients are rejected. If after a selection no control command is issued by the client the unit resets this selection after a settable timeout period [ IC]: sboTimeout (default: 2 minutes) has elapsed.

If with a system application it must be ensured that only one control command at a time is being processed system wide ("uniqueness") then interlocking of secondary units among themselves is setup with GOOSE. For further details see description of function group GOOSE.

The switchgear device’s contact positions are signaled to the clients with the reports.

Fault transmission Including fault transmission for IEC 61850 in the configuration is possible only with the IED Configurator.

Transmission of fault files is supported per "File Transfer". COMTRADE fault files in the unit are transmitted uniformly either as ASCII or binary formatted files. Fault transmission can be cancelled from the configuration.



High priority transmission of information

Whereas normal server-client services are transmitted at the MMS and TCP/IP level the high priority transmission of information is carried out directly at Ethernet level. Furthermore messages in such a particular form can be received by all participants in the relevant sub-network, independent of their server or client function. They are deployed in instances where high-speed transmission of information is wanted between two or more devices. Applications, for example, are reverse interlocking, transfer trip or decentralized substation interlock.

The IEC 61850 standard provides two modes for high priority transmission of information: the GSSE and the GOOSE. The GSSE (also named UCA2-GOOSE) is used to transmit binary information with a simple configuration by 'bit pairs', and it is compatible with UCA2. The GOOSE enables transmission of all data formats available in the data model, such as binary information, integer values, two-pole contact position signals or analog measured values. The unit supports receipt and evaluation of GOOSE including binary information and two-pole contact position signals from external devices.

Communication with the MiCOM S1 operating program via the Ethernet interface

Direct access by the MiCOM S1 operating program via the Ethernet interface on the device may occur through the "tunneling principle". Transmission is carried out by an Ethernet Standard Protocol, but this is supported only by the associated MiCOM S1 operating program (specific manufacturer solution). Such transmission is accomplished over the same hardware for the network, which is used for server-client communication. Available are all the familiar functions offered by the MiCOM S1 operating program such as reading/writing of setting parameters or retrieving stored data.



Function group IEC presents the following parameters, measured values and signals:

Parameters listed in italic letters provide information only. They are set with

the IEC 61850 configuration tool "IED Configurator", but they cannot be modified from the local control panel (HMI) or with the operating program.

Configuration parameters in the operating program

IEC: Function group IEC 056 059

Cancelling function group IEC or including it in the configuration. If the function group is cancelled from the configuration, then all associated settings and signals are hidden.

IEC: General enable USER 104 000

Enabling and disabling function group IEC. IEC: S w i t c h C o n f i g . B a n k 104 043

This parameter can only be sent individually. Accepting the previously set communication parameters as the active communication settings.

IEC: Active Config. Name 104 045

Name of the configuration bank currently valid. Setting is carried out with the IED Configurator.

IEC: Active Config. Vers. 104 046

Version number of the configuration bank currently valid. Setting is carried out with the IED Configurator.

IEC: Inact. Config. Name 104 047

Name of the inactive configuration bank. Setting is carried out with the IED Configurator.

IEC: Inact. Config. Vers. 104 048

Version number of the inactive configuration bank. Setting is carried out with the IED Configurator.

IEC: IED Name 104 057

Explicitly assigned unit name for the function in the system (IED); is part of the Logical Device Name. Setting is carried out with the IED Configurator.

IEC: IP address 104 001

IP address of the unit set for the server function in the system. Note: With software versions previous to P439 -630 this parameter was used to set the IP address. Now it is only an information parameter ('read only'), for which a value can be set by using the "IED configurator" with Communications: IP Address.

IEC: Subnet mask 104 005

The subnet mask defines which part of the IP address is addressed by the sub-network and which part by the device that is logged-on to the network. Note: With software versions previous to P439 -630 this parameter was used to set the sub-network. Now it is only an information parameter ('read only'), for which a value can be set by using the "IED configurator" with Communications: SubNet Mask.

IEC: Gateway address 104 011

This parameter shows the IPv4 address of the network gateway for communication links to clients outside of the local network. Note: With software versions previous to P439 -630 this parameter was used to set the network gateway. Now it is only an information parameter ('read only'), for which a value can be set by using the "IED configurator" with Communications: Gateway Address.



IEC: SNTP Server 1 IP 104 202

IP address of the preferred server used for clock synchronization. IEC: SNTP Server 2 IP 104 202

IP address of the backup server used for clock synchronization IEC: SigGGIO1 selection 104 064

Optional signal assignment for a transmission per communication protocol IEC 61850 based on the selection table of the binary inputs (opto coupler inputs).

IEC: Diff. local time 104 206

Time difference between UTC and local time at the unit’s substation. IEC: Diff. dayl.sav. time 104 207

Time difference of the daylight saving time to standard time. IEC: Switch.dayl.sav.time 104 219

This setting defines whether an automatic switching to daylight saving time is wanted.

IEC: Dayl.sav.time start 104 220

IEC: Dayl.sav.time st. d 104 221

IEC: Dayl.sav.time st. m 104 222

These three parameters define the date for switching from standard time over to daylight saving time. By combining the three parameters I E C : D a y l . s a v . t i m e s t a r t (values "first", "second", "third", "fourth", "last"), I E C : D a y l . s a v . t i m e s t . d (seven weekdays) and I E C : D a y l . s a v . t i m e s t . m (month) a setting, for example, such as "on the last Sunday in March" can be carried out.

IEC: Dayl.sav.t.st.0:00 + 104 223

Time period in minutes after midnight when daylight saving time is switched to standard time. If for example the clock is advanced one hour from 2:00 AM to 3:00 AM the parameter I E C : D a y l . s a v . t . s t . 0 : 0 0 + is set to 120 (minutes).

IEC: Dayl.sav.time end 104 225

IEC: Dayl.sav.time end d 104 226

IEC: Dayl.sav.time end m 104 227

IEC: Dayl.sav.t.end 0:00+ 104 228

These parameters define the date and time of day for the clock changeover from daylight saving time to standard time. Settings are made similar to the changeover to daylight saving time.

Parameter, unit identification DVICE: MAC address module A 104 061

MAC address for the network hardware of the Ethernet module. This address is set during manufacture and can only be read.

Function parameters associated with IEC 61850, general function

COUNT: Iec61850 pulsQty 221 096

Setting the scaling factor for the count value’s transmission via IEC 61850. According to the standard the resulting value is calculated as: Value transmitted = updated value * pulsQty.



Operation, cyclic values, logic state signals

IEC: Comm. link faulty 105 180

Display when an Ethernet module is not operational, i.e. if the MAC address is missing or there is an implausible parameter setting.

IEC: Control reservation 221 082

Display if a client has made a reservation to control an external device ("select" for control by control mode "select before operate").

Configuration parameters in the IED Configurator

IED Details: SCL File ID

Identification of the .mcl configuration file. The preset value may be changed on demand by, for example, entering a bay name.

IED Details: SCL File Version

Specific value to identify the IEC 61850 data model and configuration. The preset value may be changed on demand by, for example, identifying the revision states during engineering.

IED Details: Name

Explicitly assigned unit name for the function in the system (IED); is part of the Logical Device Name.

Further specific values listed in the column "Template Details" only provide

information. They are preset and cannot be modified.

Communications: Connected Sub-Network

Optional name available to identify the Ethernet. Communications: Access Point

Part of the communications control; preset, cannot be modified. Communications: IP Address

Explicitly assigned IP address of the unit for the server function in the system.

Communications: SubNet Mask

The subnet mask defines which part of the IP address is addressed by the sub-network and which part by the device that is logged-on to the network.

Communications: Gateway Address

This parameter defines the IPv4 address of the network gateway for communication links to clients outside of the local network.

Communications: Media

Network hardware provided as fiber optics or twisted pair copper wires. Communications: TCP Keepalive

Communication monitoring at TCP level; preset. Communications: Database Lock Timeout

Return time period for setting procedures that have commenced; preset. SNTP: Poll Rate (seconds)

Polling interval for clock synchronization; preset. SNTP: Accepted Stratum level

Quality criterion to accept an SNTP server for clock synchronization; preset, cannot be modified.

SNTP: IP Address

IP address of the preferred server used for clock synchronization.



SNTP: virtual key "Use Anycast"

Appointing any server in the local network to provide clock synchronization.

Further specific values listed in the column "External server parameters" may be accepted when imported from an XML configuration file.

Dataset Definitions: Name

Explicitly assigned name for the dataset. Dataset Definitions: Location

Saving datasets at System\LLN0 is compulsory. Dataset Definitions: Contents

Content (data objects, data attributes) of a dataset Dataset Definitions: Display “GOOSE Capacity”

Checking the length of a dataset for less than 1500 bytes to permit transmission in GOOSE messages. The display is irrelevant when the dataset is only used in reports.

Report Control Blocks: Report Type

Report type Unbuffered updating

Buffered saving

Report Control Blocks: Report ID

Report ID consisting of the Device Name and the Report Control Block. Report Control Blocks: Dataset Reference

Name of the dataset assigned to the report. Report Control Blocks: Configuration Revision

Revision status of the configuration. Controls: ctlModel

To control external devices the following operating modes can be set: Status only

manually operated switching device

Direct control with enhanced security direct command issue with extended monitoring of command effecting

SBO (Select before operate) with enhanced security switching device selection procedure with extended monitoring of command effecting

Controls: sboTimeout

Return time period after selection without having issued a command. Controls: Uniqueness of Control: Multicast MAC Address

Virtual MAC address used as a receive filter; preset. Controls, Uniqueness of Control: Application ID (hex)

ID-number of the GOOSE. Controls, Uniqueness of Control: Source Path

Information data attribute in the transmitting device. Controls, Uniqueness of Control: GOOSE Identifier

ID of the GOOSE in the transmitting device. Controls, Uniqueness of Control: Dataset Reference

Name of the dataset assigned to the GOOSE in the transmitting device.



Controls, Uniqueness of Control: Configuration Revision

Configuration revision status of the transmitting device. Controls, Uniqueness of Control: Data Obj Index

Position index of the data object within the GOOSE. Controls, Uniqueness of Control: Default Input Value

Default value for the information in case GOOSE receipt has failed: False Default: not set

True Default: set

Last Known Value Default: retain last value received

Double Point: intermediate (00) Default: switching device in intermediate position

Double Point: Off (01) Default: switching device open

Double Point: On (10) Default: switching device closed

Double Point: Bad state (11) Default: switching device in intermediate position

Measurements: Unit multiplier

Multiplication factor; not supported. Measurements: Scaled measurement range Min

Lower measuring range limit value; not supported. Measurements: Scaled measurement range Max

Upper measuring range limit value; not supported. Measurements: Deadband

Multiplier for the smallest display value of the measured value. In order to have the current measured value sent when it has changed from the value last sent the result of the set dead band value multiplied by the smallest display value must exceed the smallest display value.

Configurable Data Attributes: Mod.measCyc: Value

Transmission of measured values: Time interval in seconds between two dead band evaluations.

Configurable Data Attributes: Mod.enCyc: Value

Cyclic transmission of measured values without dead band check: Time interval in seconds between transmissions of two energy count values.

Configurable Data Attributes: Mod.comtrade: Value

Transmission of COMTRADE fault files formatted either as ASCII or binary files.

Configurable Data Attributes: Mod.distExtr: Value

Cancelling fault transmission or including it in the configuration.

Further specific values listed in the column "Data type” only provide information. They are preset and cannot be modified.



2.2 Generic Object Oriented Substation Event (Function Group GOOSE)

For high priority exchange of information between individual units (IEDs) in a local network, the unit provides the function group GOOSE as defined in the standard IEC 61850. GOOSE features high-speed and secure transmission of information for reverse interlocking, decentralized substation interlock, trip commands, blocking, enabling, contact position signals and other signals.

GOOSE Messages are only transmitted by switches but not by routers. GOOSE messages therefore remain in the local network to which the unit is connected.

Configuration and enabling

Function group GOOSE can be configured using the parameter G O O S E : F u n c t i o n g r o u p G O O S E . This parameter is visible only if the optional Ethernet communication module is fitted to the device. Once the GOOSE is configured, all parameters associated to this function group are then visible and settable.

Further setting parameters from function group GOOSE are set with the IED Configurator, but they cannot be modified from the local control panel (HMI) or with the operating program.

The function can then be enabled or disabled by setting G O O S E : G e n e r a l e n a b l e U S E R .



» »Device A Device B

GOOSE: Input 1 ... 32

S1 Studio

GOOSE: Output 1 ... 32

S1 Studio System/GosGGIO2IEC 61850

Mapping

System/LLN0/gcb01 ... 08

System/LLN0/Datasetx

System/GosGGIO2.ST.ind1 ... 32

Pos1.stVal ... Pos32.stVal

System/GosGGIO1

MCL

Pos1.stVal ... Pos32.stVal

System/DevGosGGIO3

Ext.Dev 1 … 32

S1 Studio

19Z7003A_EN

IED Configurator

IED ConfiguratorIED Configurator

IED Configurator

Fixed assignment

U-3 GOOSE configuration



Sending GOOSE The unit can send up to eight different GOOSE messages that are managed in eight GOOSE Control Blocks (gcb01 to gcb08). Information content depends on the respective dataset assigned to GOOSE. The maximum size of a dataset to be sent by GOOSE is limited to 1500 bytes. A control display is shown by the IED Configurator to check this limit.

When defining the datasets for GOOSE it is advised to select the individual data attributes and not the overlapping data objects. By this the amount of data is kept within a limit and decoding is guaranteed on the receiving end.

In addition to the information included in the IEC 61850 data model an optional number of up to 32 signals can be selected from all the signals available in the unit to be transmitted via GOOSE, as it is also possible with reporting. Selection of binary state signals (shuttling to communications) is made by setting G O O S E : O u t p u t n f c t . a s s i g . (n = 1 to 32). The data object indexes defined for SigGGIO1 must follow the function assignments for the GOOSE outputs. The indexes GosGGIO2.ST.ind1 to GosGGIO2.ST.ind32 may then be included in the datasets just as the other data objects.

When a state change occurs with a selected state signal or a measured value changes which is greater than the dead band set for the relevant data point then the complete GOOSE is sent. There will be multiple send repetitions at ascending time periods. The first send repetition occurs at the given cycle time set with the parameter [ I C ] : M i n i m u m C y c l e T i m e . The cycles for the following send repetitions result from a conditional equation with the increment set with the parameter [ I C ] : I n c r e m e n t . Should no further state changes occur up to the time when the maximum cycle time has elapsed [ IC]: Maximum Cycle Time, then GOOSE will be sent cyclically at intervals as set for the maximum cycle time.

In order to have unambiguous identification of a GOOSE sent, characteristics such as [ IC]: Mult icast MAC Address, [ IC]: Appl icat ion ID (hex), [ IC]: VLAN Ident i f ier (hex), [ IC]: VLAN Pr ior i ty and [ IC]: GOOSE Identi f ier must be entered in the IED Configurator settings. Further characteristics are [ IC]: Dataset Reference and [ IC]: Configurat ion Revis ion.

Each GOOSE is given the state change index and the number of send repetitions.



Receiving GOOSE With GOOSE up to 32 logic binary state signals as well as 32 two-pole contact position signals from external devices (Ext.Devxx) can be received. For each state signal or contact position signal to be received a specific GOOSE message is to be selected, which will contain the information wanted, by setting [ IC]: Mult icast MAC Address, [ IC]: Appl icat ion ID (hex), [ IC]: Source Path, [ IC]: GOOSE Ident i f ier and [ IC] : DataSet Reference. With the further setting of [ IC]: Data Obj Index / Type, which corresponds to the GOOSE position index and the information structure of the sending unit, the required information from the chosen GOOSE will be selected. The identification features "VLAN identifier" and [ I C ] : C o n f i g u r a t i o n R e v i s i o n that are also included in the GOOSE received will not be evaluated.

These parameters characterizing the information may be taken either from unit or project planning documentation of the sending unit or from a configuration file which is conform to IEC 61850. The IED Configurator will support the import of .IID, .SCD and .MCL files when the "browse function" (virtual key) is applied. The selection and acceptance of parameters from an existing project planning is distinguished by a simplified and very reliable data input.

Should the data type of the selected data object provide quality information then this can be evaluated. When activating [ I C ] : Q u a l i t y O b j I n d e x, the distance of the quality descriptor to the data object (if not preset) must be given as well as the quality criterion, which is to be tested. A signal is rejected when one of the bits ([ IC]: Inval id i ty Qual i ty b i ts , see displayed bar with bit state) is received as a set bit. These parameters are usually described in a configuration file and are accepted from there during an import action.

Each GOOSE includes time information on the duration of validity of its information. This corresponds to the double time period to the next GOOSE repetition. If the duration of validity has elapsed without this GOOSE having been received again (e.g. because of a fault in communications), the received signals will automatically be set to their respective default values [ I C ] : D e f a u l t I n p u t V a l u e . Which of the possible state values will set the desired security grade depends on the relevant application.

The following configuration (shuttling to the device functions) of the logic state signals received from the logic node GosGGIO1 (G O O S E : I n p u t n f c t . a s s i g . , where n = 1 to 32) is based on the selection table of the binary inputs, identical to that of the opto-coupler inputs. Contact position signals received from external devices (LN: DevGosGGIO3) are listed in the selection table for interlocking equations of the function group ILOCK, which are available to design a decentralized substation interlock.

The virtual key "Unmap" may be used to remove the link of a binary signal input to an external data point. In such a case all entries for this binary signal input are deleted.



Uniqueness of control within a system

If with a system application it must be ensured that only one control command at a time is being processed system wide ("uniqueness") then interlocking of secondary units among themselves is setup with GOOSE. The unit sets the status information Control/LLN0.ST.OrdRun.stVal. when it has received a control command. This information - stored in a dataset – is distributed in the system by GOOSE and is therefore available to all other units as an interlocking condition. The state information is reset and accordingly signaled after termination of the command sequence.

The unit is capable to monitor the command status of up to 32 further units. With the IED Configurator OrdRunGGIO1.ind1.stVal to OrdRunGGIO1.ind32.stVal are configured in a similar way to the other GOOSE inputs. A shuttling to the interlocking equations is not necessary as their consideration within command checking is automatically enabled when the first binary signal input is configured. During a signaling receipt phase command execution will be rejected.

Ä-4 Uniqueness of Control



The function group GOOSE presents the following parameters, measured values and signals:

Configuration parameters in the operating program

GOOSE: Function group GOOSE 056 068

Cancelling function group GOOSE or including it in the configuration. If the function group is cancelled from the configuration, then all associated settings and signals are hidden.

Parameters included in this function group are only effective when function group IEC is configured and enabled and when the parameters in this function group have been activated by setting the parameter IEC: S w i t c h C o n f i g . B a n k .

GOOSE: General enable USER 106 001

Enabling and disabling function group GOOSE. GOOSE: Output 1 fct.assig. 106 011

GOOSE: Output 2 fct.assig. 106 013































Function assignment of a binary logical state signal to the virtual GOOSE outputs. Signals configured here can be included as GosGGIO2.ST.ind1 to GosGGIO2.ST.ind32 in the datasets.



GOOSE: Input 1 fct.assig. 107 006
































Function assignment of the virtual binary GOOSE inputs (GosGGIO1\Pos1.stVal to GosGGIO1\Pos32.stVal) to a binary logical state signal on the unit so that they can be processed further by the protection, control or logic functions. Signals configured here contain the received and pre-processed state of data attributes configured for GOOSE receipt.



Physical state signals GOOSE: Output 1 state 106 010

GOOSE: Output 2 state 106 012































Display of the virtual binary GOOSE output state.



GOOSE: Input 1 state 106 200
































Display of the virtual binary GOOSE input state.



Logic state signals GOOSE: Ext.Dev01 position 109 000

State of the virtual two-pole GOOSE input, representing the state of an external device.

(Addresses 109 000,109 005…109 175 for the external devices Dev01 to Dev32.)

GOOSE: Ext.Dev01 open 109 001

Binary open state of the virtual two-pole GOOSE input, representing the state of an external device.


GOOSE: Ext.Dev01 closed 109 002

Binary closed state of the virtual two-pole GOOSE input, representing the state of an external device.


GOOSE: Ext.Dev01 interm.pos 109 003

Binary intermediate position state of the virtual two-pole GOOSE input, representing the state of an external device.


GOOSE: IED01 link faulty 107 180

Display whether GOOSE receipt of the configured signal is faulty or not available. To each GOOSE the GOOSE sending device will attach a validity stamp, up to which a repetition of GOOSE will be carried out independently of a change of state. Thus the unit monitors the time interval before the reception of the next state signal.

(Addresses 107 180…107 215 for IED01 to IED32.)

GOOSE: ExtDev01 link faulty 107 216

Display whether GOOSE receipt of the configured external device is faulty or not available. To each GOOSE the GOOSE sending device will attach a validity stamp, up to which a repetition of GOOSE will be carried out independently of a change of state. Thus the unit monitors the time interval before the reception of the next state signal.

(Addresses 107 216…107 247 for the external devices Dev01 to Dev32.)

GOOSE: IED link faulty 107 250

Display that appears as soon as receipt of at least one of the configured GOOSEs is faulty or not available. To each GOOSE the GOOSE sending device will attach a validity stamp, up to which a repetition of GOOSE will be carried out independently of a change of state. Thus the unit monitors the time interval before the reception of the next state signal.



Configuration parameters in the IED Configurator

GOOSE Publishing: Multicast MAC Address

Virtual MAC address that the sending unit provides as the destination; preset.

GOOSE Publishing: Application ID (hex)

Explicitly assigned ID number of the GOOSE. GOOSE Publishing: VLAN Identifier (hex)

ID number of the virtual LAN with which the GOOSE is sent; preset. GOOSE Publishing: VLAN Priority

Priority with which the GOOSE is sent in the virtual LAN; preset. GOOSE Publishing: Minimum Cycle Time

First send repetition of the GOOSE occurring after the set time period; preset.

GOOSE Publishing: Maximum Cycle Time

Continuous send repetition of the GOOSE occurring after the set time period; preset.

GOOSE Publishing: Increment

Specification factor for the transition of time intervals for GOOSE send repetitions from the first to the continuous repetition.

GOOSE Publishing: GOOSE Identifier

GOOSE ID consisting of the Device Name and the GOOSE Control Block. GOOSE Publishing: Dataset Reference

Name of the dataset assigned to the GOOSE. GOOSE Publishing: Configuration Revision

Revision status of the configuration.

GOOSE Subscribing: Multicast MAC Address

Virtual MAC address used as a receive filter; preset. GOOSE Subscribing: Application ID (hex)

ID-number of the GOOSE. GOOSE Subscribing: Source Path

Information data attribute in the transmitting device. GOOSE Subscribing: GOOSE Identifier

ID of the GOOSE in the transmitting device. GOOSE Subscribing: Dataset Reference

Name of the dataset assigned to the GOOSE in the transmitting device. GOOSE Subscribing: Configuration Revision

Configuration revision status of the transmitting device. GOOSE Subscribing: Data Obj Index

Position index of the data object within the GOOSE.



GOOSE Subscribing: Data Type

Structure of the data object; possible settings:

Unknown Unknown Boolean Boolean Int8 integer, 8 bits (binary digits) Int16 integer, 16 bits (binary digits) Int32 integer, 32 bits (binary digits) UInt8 positive integer, 8 bits (binary digits) UInt16 positive integer, 16 bits (binary digits) UInt32 positive integer, 32 bits (binary digits) Float floating-point number BStr2 binary state, with 2 bits SPS single-pole signal DPS two-pole signal

GOOSE Subscribing: Quality Obj Index

Distance of the quality descriptor to the data object if not preset. The quality of the received information is to be tested if such has been configured.

GOOSE Subscribing: Invalidity Quality bits

Quality criterion, which is to be tested.

Invalid / Questionable Invalid / questionable Source Information source is faulty Relay test Sending unit is set to test mode OperatorBlocked Blocked by operator

and

Overflow Measured value has exceeded its capacity

OutofRange Measured value has exceeded its range BadReference Referenced value is faulty Oscillatory Value is volatile Failure Faulty OldData Information is out-of-date Inconsistent Information is unreliable Inaccurate Information is inaccurate

GOOSE Subscribing: Evaluation Expression

Criteria to check the received information content by comparing it with a set integer value; the parameter is not supported in the unit.

Equal to Compared to: equal Not equal to Compared to: unequal Greater than Compared to: greater Less than Compared to: less Pass through Do not compare



GOOSE Subscribing: Default Input Value

Default value for the information in case GOOSE receipt has failed False Default: not set True Default: set Last Known Value Default: retain last value received Double Point: intermediate (00) Default: switching device in

intermediate position Double Point: Off (01) Default: switching device open Double Point: On (10) Default: switching device closed Double Point: Bad state (11) Default: switching device in

intermediate position


P43x, Changes between Software Versions -614 and -630




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Phone: +33 (0) 1 41 29 70 00 Fax: +33 (0) 1 41 29 71 00 www.schneider-electric.com Publishing: Schneider ElectricPublication: P43x/EN AD/Ak7 // AFSV.12.10590 D /// P433-308-410/411-630 // P435-308-413/414/415-630 04/2011

MiCOM P433, P435


P43x/EN AD/Am7 (AFSV.12.10950 D)

Version P433 -308 -410/411 -630 ⇒ P433 -308 -410/411 -631 P435 -308 -413/414/415 -630 ⇒ P435 -308 -413/414/415 -631


P43x, Changes in software version -630 to -631

In the new versions of the Distance Protection Devices MiCOM P43x, several enhanced features and changes on existing features have been included. These are described with reference to the documentation listed below:

References Version Documentation Released

19.07.2008 P433-308-410/411-612 P435-308-413/414/415-612

Technical Manual P43x/EN AD/Ac7 (AFSV.12.10220.D)

01.02.2010 P433-308-410/411-614 P435-308-413/414/415-614

Upgrade Documentation P43x/EN AD/Ae7 (AFSV.12.10550 D) Upgrade Documentation P43x/EN AD/Ak7 (AFSV.12.10590 D)

17.09.2010 P433-308-410/411-630 P435-308-413/414/415-630

Note:

The software versions P43x-61x constitute a product line that was developed independent to versions P43x-63x. (The main difference is that the device versions with software versions P43x-63x feature the “phase 2” implementation of function group IEC whereas software versions P43x-61x continue with the “phase 1” implementation.)

P43x/EN AD/Am7 // AFSV.12.10950 D /// P433-308-410/411-631 // P435-308-413/414/415-631 3


1 Overview

Version Changes

Hardware No change P433-308-410/411-631 P435-308-413/414/415-631

Diagram No change

Release: 07.01.2011 Software PC The following menu point has been removed:

P C : N a m e o f m a n u f a c t u r e r (003 183) Note: Compatibility even with older versions of the operating program continues to be guaranteed.

IEC In order to guarantee full compatibility with PACiS the neutral-point displacement voltage (calculated and measured) as well as the residual current (calculated and measured) were assigned to the node MMXU so that the node MSQI now includes only the positive-sequence and negative-sequence values.

COMM1 The data point C O M M 1 : - 1 0 3 p r o t . v a r i a n t (003 178) may now be used to select between the 103 protocol variants Private and Compatible. The protocol variant Compatible corresponds to the VDEW implementation. Note: As before this setting is hidden unless an IEC 60870-5 protocol is enabled.

COMM1 The data point C O M M 1 : M O D B U S p r o t . v a r i a n t (003 214) may now be used to select between the MODBUS protocol variants Private and Compatible. The protocol variant Compatible corresponds to the MODBUS implementation in the MiCOM Px20 and Px40 protection devices. The protocol variant Private corresponds to the first implementation of the MODBUS protocol. Note: As before this setting is hidden unless the MODBUS protocol is enabled.

COMM1, COMM2

The menu points C O M M 1 : N a m e o f m a n u f a c t u r e r (003 161) and C O M M 2 : N a m e o f m a n u f a c t u r e r (103 161) can no longer be set by using a selection list but, for reasons of compatibility, they may now be defined as free text. The default is SE but, in individual cases, it may become necessary to enter texts differing from the default. Notes: These parameters can only be set using the operating program and it is not possible to set them locally using the integrated local control panel (HMI). The maximum text length is 8 characters and designations exceeding this will be truncated. The parameter C O M M 1 : N a m e o f m a n u f a c t u r e r is hidden unless an IEC 60870-5 protocol is enabled.

F_KEY The default setting of passwords for function keys has been changed. A password is now no longer required when pressing a function key. However, it remains possible to configure a password for each individual function key.

INP Bug fixing: Inputs provided by the binary (I/O) module X (6Ix3O) could not be used.

4 P43x/EN AD/Am7 // AFSV.12.10950 D /// P433-308-410/411-631 // P435-308-413/414/415-631


P43x/EN AD/Am7 // AFSV.12.10950 D /// P433-308-410/411-631 // P435-308-413/414/415-631 5

Version Changes MAIN The internal range for the primary measured power values was extended

from 1000 MW, 1000 MVAr and 1300 MVA to 3200 MW, 3200 MVAr and 3200 MVA, respectively. This applies to the following data points: (005 025) M A I N : A p p a r . p o w e r S p r i m . (004 050) M A I N : A c t i v e p o w e r P p r i m . (004 052) M A I N : R e a c . p o w e r Q p r i m .

The designation text for signal (036 051) has been changed from M A I N C B c l o s e d s i g . E X T to M A I N C B c l o s e d 3 p E X T without changes in its functionality.

DTOC The setting range of the characteristic angle D T O C : A n g l e p h i G P S x (004 092, 004 247, 004 248, 004 249) has been extended to -90°...+90° so that capacitive ground fault currents in systems with current-limited grounding and in isolated systems may now be taken into account.

PSIG Bug fixing: The receive signal was not updated.

DEVxx Bug fixing: The feature, introduced with version -630, where the designation for devices could be defined in free text was not applicable, as the data model did not support the associated selection option DEV-Name User.



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Phone: +33 (0) 1 41 29 70 00 Fax: +33 (0) 1 41 29 71 00 www.schneider-electric.com Publishing: Schneider ElectricPublication: P43x/EN AD/Am7 // AFSV.12.10950 D /// P433-308-410/411-631 // P435-308-413/414/415-631 06/2011



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Phone: +33 (0) 1 41 29 70 00 Fax: +33 (0) 1 41 29 71 00 www.schneider-electric.com Publishing: Schneider ElectricPublication: P43x/EN M/Am7 Version: -612 -614 -615 -630 -631, Vol. 2 06/2011

micom p433,p435(technical manual2) (pdf, 2884kb)

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