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General  Information 

1.1 

Description 

The  Siemens  Communicating  Overcurrent  Relay  (SCOR)  is  a 

microprocessor -based , time overcurrent relay designed for easy 
incorporation  into  a  computer-monitored  power  system.  It  is 

available  in  a  number  of  styles  to  supply  single-phase,  two­
phase-with-ground, three-phase, and three-phase-with-ground 
protection for 60 

Hz 

power systems. 

The  relay  provides for the incorporation of an optional  plug-in 

communications  board  to  interface  with  the  Siemens  Power 
Monitor™  display  and  monitoring  unit.  The  communications 
interface, when fully implemented,  allows remote monitoring of 
real-time system and circuit breaker information and the trans­
mission of event and historical data, as well as remote configu­
ration of operating parameters. 

1.2 

Application 

The SCOR relay is utility grade and is provided in a draw-out case 

with built -in test facilities. It is used for the protection of medium 
voltage electrical power systems.  It is designed to monitor the 
outputs of standard (5 A secondary) current transformers and, 

when it operates, to close an output contact that may be used 
to trip a circuit breaker. 

The relay requires control power for its internal circuits. A number 
of ac and de voltage options are available for this purpose that 

match the  usual ac  or de  control  power  used for tripping  the 
circuit breaker. 

1.3 

The  Time  Overcurrent  Function 

1 .3.1 

Pickup 

A  coarse  incremental  selection  of  overcurrent  pickup  tap  is 
provided  by front panel  rotary  switches.  One  switch  simulta­

neously sets the pickup tap for all the monitored phases. If ground 

is also monitored, a second rotary switch independently sets the 
ground overcurrent pickup tap. 

A  fine  incremental  adjustment  that  provides  99  intermediate 

pickup points between adjacent positions of the rotary switches 

is  provided  by  entering  data  into  the  memory  of  the  internal 
microcomputer tap calibration registers. 

1 .3.2 

Timing 

A time delay is initiated when a pickup point is exceeded. When 
the  current  drops  below  pickup,  the  timing  circuit  is  reset 

immediately.  The  amount  of  delay  required  before  trip  is  a 

function of the overcurrent magnitude. 

Page  1 

One of  1 6  families of time overcurrent characteristics may be 

selected for the monitored  phases. These families are graphi­

cally illustrated  in 

Figures A.1 

through 

A.1 6  

in 

Appendix 

A. 

If  ground  current  is  monitored,  its  timing  characteristic  is 
independently selected from the  16 families. 

Selection of the timing characteristics is made at the front panel 
or via one of the two communications links. After a characteristic 
is selected , it is adjusted to specific requirements by choosing 

the TIME DIAL number. (These are the numbers in a vertical row 
along the right hand  margin of 

Figures A.1 

through 

A.16.) 

This 

TIME DIALnumber (Oto 99) selects oneofthe 1 OOcharacteristic 
curves  available for  each  characteristic.  (Only  1 4  of  the  1 00 

curves in the relay's memory are shown on each graph because 
of space limitations.) 

The  selected  TIME  DIAL  number  is  entered  into  the  relay's 

memory, again using either the frontpanel data entry controls, 

or one of the two communications links. The available charac­

teristic curves include one definite time,  six inverse time,  and 

nine IZT curves. (Refer to 

Table 

4.) 

1 .3.3 Trip  and  Reset 

When the monitored current exceeds the overcurrent  pickup 

point,  the TMG  LED  illuminates as timing begins. The timing 
process continues until the interval calculated by the selected 
time overcurrent  characteristic  is  completed  (thereby tripping 

the associated output contact and target indicators}, or until the 

sensed  overcurrent  drops  below  the  pickup  setting  (which 
causes the timer to reset). In either case (trip or reset), the timing 
process is terminated. The TMG LED extinguishes at reset, but 

remains on at trip as an indication of contact closure. 

If  a  relay  output  is  closed,  it  is  immediately  reset  when  the 

monitored  current  drops  below the  pickup  setting.  Targets, 
however, remain tripped until manually reset at the front panel. 
(Control power is required to reset the targets.) 

1.4 

RMS Sensing 

·:ff 

The SCOR protective relay uses RMS Sensing, a technology first 

introduced  by  Siemens in  1 985,  to  sample  the  current wave 

shape  and  quickly calculate the  effective heating value of the 
current.  SCOR  relays  evaluate the impact of harmonics  and 
provide accurate circuit protection. The SCOR relay uses a sum 
of  squares  algorithm  for both  determining  trip  level  and  for 
calculating metered values of the relay current level. The input 

waveform is sampled several times to determine instantaneous 
values. These instananeous values are processed to obtain the 
true RMS value of the input current. 

www 

. ElectricalPartManuals 

. com 

Summary of Contents for SCOR

Page 1: ...elay I J TapA B H C G D F E AB C FunctionI Data 1 lll 1 1 Ll 1 I I Manual No SG 9228 01 t Time lnst 1 A B c G Instruction Installation Operation Maintenance Hardware 3 11 Software 3 40 w w w E l e c t r i c a l P a r t M a n u a l s c o m ...

Page 2: ... t fill fill g I M edium voltage switchgear withAccessTM system field devices SCOR overcurrentorotective relav 1r II c I i w w w E l e c t r i c a l P a r t M a n u a l s c o m ...

Page 3: ...ese families are graphi cally illustrated in Figures A 1 through A 16 in Appendix A If ground current is monitored its timing characteristic is independently selected from the 16 families Selection ofthetiming characteristics is made at the front panel orviaoneofthetwocommunications links Afteracharacteristic is selected it is adjusted to specific requirements by choosing theTIME DIAL number These...

Page 4: ...d instantaneous overcurrent pickup values for phase and for ground are entered via the data entry controls at the front panel This can also be done remotely by the data link if the communications option is present 1 6 The Ground Time Overcurrent and Instantaneous Functions When the sensing input type includes ground current sensing the relay is supplied with a separate and independent time overcur...

Page 5: ... It is necessary in some applica tions to trip a separate lockout relayfor ground faults This can be achieved by selecting Option 1 2 and configuring the relay to cause tripping through this separate relay contact for ground faults The ground tripping can be for operation ofboththetime and instantaneouselements but either can be configured to be disabled if desired Page 3 1 9 Communications Option...

Page 6: ...vercurrentfunction andcurveselected pickup settings and current transformer ratios Whicheverport is used all communications must be initiated by the Power Monitor unit or computer When addressed all ofthe relay s storage registers mayberead bythePowerMonitor unit and many of them can be altered Password protected 1 10 Breaker Failure Whentherelay includestheCommunicationsOption a Breaker Failuare ...

Page 7: ...hreefeatures provided by Option 1 2 is desired the eighth character of the style number is 2 The ninth character must be C to specify the communications board option This would allow communica tion with a Power Monitor unit or a local terminal Thetenth characterofthe style number is 0 ifthe control power for the power supply is DC However if 1 20 volt AC control power is to be used then this chara...

Page 8: ... and assigned a locator letter Table2supplies a description foreach Data is displayed D c Q p 0 Page 6 in primary kilo amperes The Time Target and Element BTarget areshadeddarker indicatingthatthe relaycausedan overcurrent timed trip due to a fault on Phase B and the targets have not been reset E F G H J K L N Figure 3 Controls and Indicators w w w E l e c t r i c a l P a r t M a n u a l s c o m ...

Page 9: ...registers that control operation of the relay The instrumentation registers monitor the input current and the demand current in kilo amperes A row of dashes indicates an out of range condition Dashes along the bottom of the display indicate that the current is somewhere below 1 0 of TAP dashes along the top indicate a current above 1 50 of TAP When the relay is powered up the display will default ...

Page 10: ...ion up for approximately 5 seconds when the word dAtA is exhibited on the FUNCTION DATA display locator D selects the CONFiguration mode Holding the switch in the MODE position for 5 seconds when ConF is displayed selects the DATA mode and also loads data changes if any into memory When neither dAtA nor ConF is on the display holding the switch up in the MODE position identifies the register whose...

Page 11: ...a relay output has tripped Note that the current through the associated output contact must exceed 0 2 A to actuate the target For reset see M Depending upon the style number some of the illustrated targets may not be present Indicates that a trip was caused by a TIME overcurrent function INST 11ndicates a trip initiated by the INSTantaneous 1 function Only provided if Option 1 2 is selected Indic...

Page 12: ... repeatedly until the word dAtA is in view on the front panel display Then hold the switch up for approximatelyfive seconds during which time the display Page 10 becomes blank Release the switch after ConF appears in the display Upon release of the MODE switch the STATUS LED will be lit and ConF will be in view on the FUNCTION DATA display Releasing the MODE switch before 5 seconds has expired ret...

Page 13: ...ndary Amps Grou_r 1d CT Primary Amps Grou_r 1d CT SEcondary Amps Phase rAnge Grou_r 1d rAnge demand Period ground trip Enable If 20 is YES the following options are provided Ground instantaneous trip 50 g Ground time trip 51 g If the relay includestne auxiliary output relay 20C is provided Q ili ut relay to be tripped by the ground function breaker Failure enable Wraps to the top i e to the Mode s...

Page 14: ...emens Power Monitor unit the address will be used to identify the particular SCOR Relays initiallyareconfiguredwiththeaddress 222 Ifthishasnot been changed it must be done prior to accessing from the PowerMonitorunit It issuggested thata listofdevices be made with the information shown in Table 4 3 2 7 Setting the Baud Rate Using the procedures described above for entering the CONFiguration mode d...

Page 15: ...gures A 1 through A 16 in Appendix A for graphic representations of these curves Page 1 3 3 2 12 Selecting the CT Ratios Registers 1 3 through 1 6 provide a multiplier that allows the microprocessorto match the relay s response to the turns ratio of the external CTs The relative turns ratio of the CTs is expressed as a fraction whose denominator is 5 3 2 13 Current Sensing Range The 1 7th and 1 8t...

Page 16: ...obtain the average demand value The latter is then displayed in the Demand Current registerfortheappropriatephase The demand current values may also be read over the data link Alloftheinstrumentation registers registers 1 through 7 display their data in real time Note that if the amperes are over or under theoperationalscaleoftheammeter the display will showa row of four dashes The position of the...

Page 17: ...culated as follows Given Pickup value Tap C HIGH Tap D HIGH 4 7 A 4 0 A 5 0 A Page 15 Then Set Phase Tap Switch Front Panel on C Span Tap D Tap C 1 00 Difference Pickup value Tap C 0 70 Tap Cal value phase Difference Span x 1 00 0 70 1 00 X 1 00 70 3 The ground time overcurrent pickup 1 6 A falls between tap C and tap D of the LOW range Figure 3 The ground Tap Cal value is Pickup value Tap C LOW T...

Page 18: ...ase Tap Cal register and 20 into the ground Tap Cal register 4 Enter 4 7 into the phase instantaneous 1 overcurrent register and 4 27 into the ground Instantaneous 1 Over current register 5 Enter07 into the phase TIME DIAL register and 05 intothe ground TIME DIAL register Page 16 w w w E l e c t r i c a l P a r t M a n u a l s c o m ...

Page 19: ...ront cover 5 Be sure that the relay case is hard wired to earth ground using no smaller than 1 2 AWG copper wire to the ground terminal on the rear of the unit It is desirable to use a separate ground wiretothe ground busforeach relay Ifthis is not practical the number of relays sharing a ground wire should be kept to a minimum Page 17 4 3 Dielectric Test In accordance with ANSI IEEE C37 90 1 989 ...

Page 20: ... 72 r o 0 8 63 I I I I I I I I 8 25 219 1 I I 209 6 1 nl ct 4 31 109 5 ct i 4 13 104 8 ii i I 0 0 __ J 6 7 _ 5P Js LA 154 0 MOUNT RELAY USING 4 10 SCREWS DIMENSIONS IN INCHES AND CENTIMETERS Figure 5 Panel Drilling and Cutout Dimensions For Semi Flush Mounting Page 18 w w w E l e c t r i c a l P a r t M a n u a l s c o m ...

Page 21: ... TRIP DIODES AND RESISTOR ARE INTERNAL COMPONENTS OF THE RELAY THEY ARE SHOWN HERE TO INDICATE THE SOURCE OF DIRECT CURRENT FOR 52b SENSING POWER D THE RS 232 PORT IS ON FRONT PANEL ALL OTHER 2 CONNECTIONS ARE AT REAR OF CASE Figure 6 Relay Connections 51 cr 3 51 4 51 9 11 51 12 52b Figure 7 Control Circuits LEGEND 51 OVERCURRENT RELAY 52 BREAKER TRIP COIL TC 52a BREAKER AUXILIARY CONTACTS INST 1 ...

Page 22: ...cceptance Page 20 procedure for a newly delivered relay Succeeding tests can be reduced in scope to conserve time and thereby permit more frequent tests Such an operational test may be accomplished by scaling down the verification tests of this subsection as follows 1 Byconcentrating ontheparameters actually required in the assigned application 2 Byusing spot teststhatcheck forexample onlyoneortwo...

Page 23: ... the POWER LED is lit and that the relay disabled contact is open 4 Load 00 into the Phase Tap Cal register 5 Load 99 into the Time Dial register 4 7 3 Time Overcurrent Pickup Test The phase current pickup of the relay will be set at the factory to operate on one of the two available ranges HIGH or LOW If ground current is monitored it will also be set for one ofthe two ranges Determine which rang...

Page 24: ... phase with ground relay perform steps 6 7 1 0 and 1 1 below If three phase with ground perform all of the following steps 6 Disconnect the input current source from terminals 7 and 8 Phase A and connect it to terminals 1 4 and 1 5 Phase B 7 Repeat steps 2 through 5 above for Phase B 8 Disconnect the input current sourcefrom terminals 1 4 and 1 5 Phase B and connect itto terminals 1 7 and 1 8 Phas...

Page 25: ... to output contact closureforcurrents that areadjusted to the following multiples of TAP a 2 0 x TAP and b 5 0 x TAP Check the results against the graphed values 5 Adjust the TIME DIALto 20 and repeat step 4 NOTE If this is a single phase relay this concludes a minimal Timing Test Other TAP switch positions may be tried within the limitations of the current source If this is a three phase relay wi...

Page 26: ... H I and J successively 7 If Option 1 2 is present and is used as lnst 2 follow the procedures of steps 2 through 6 for testing the Instanta neous 2 pickup and output Page 24 NOTE If this is a single phase relay this completes the Instantaneous Overcurrent Pickup Test If this is a three phase relay perform steps 8 through 1 2 below If a two phase with ground relay perform steps 8 9 1 2 and 1 3 lft...

Page 27: ...ncy of the capacitor is cut in half for every 1oo C rise in temperature Storage life can be extended if at one year inter vals power is applied to the relay for a period of 30 minutes Page 25 5 3 Timekeeping The real time clock within the relay once set by the Power Monitor unitafterpower up maintainstimetoa resolution of0 01 second however drift within the clock can be as much as 0 5 seconds per ...

Page 28: ...ciation April 1 983 2 Siemens Power Monitor Display and Monitoring Unit Manual No SG 401 8 01 3 Siemens SCOR Protocol Page 26 4 Siemens Isolated Multi Drop RS 232 to RS 485 Converter Manual No SG 6048 5 Siemens Power Monitor PC User s Guide Manual No SG 4028 w w w E l e c t r i c a l P a r t M a n u a l s c o m ...

Page 29: ... memory ofthis relay Refer to Table 1 on Page 5 for a listing of the 1 6 characteristic curves Notethatadrawing number isgiven undereach caption Usethis number to order a full size 1 0 x 1 2 Characteristic Curve set The Phase and Ground Instantaneous Time Curves are pre sented in Figures A 17 and A 18 respectively w w w E l e c t r i c a l P a r t M a n u a l s c o m ...

Page 30: ... A 1 Timing Type b1 Short Inverse Time Owg No 1 8 752 294 001 07 83 02 01 00 8 z 0 _ w f z w lOO 200 100 10 10 10 10 50 40 lO 20 10 I 7 5 1 L l I I l I f 1 I I L 1 1 II I I 1 1 1 I I I 1 I _ r r t r r t r r r I I r r r r r 2 i 7 I 5 4 3 2 1 01 01 07 01 Oil 04 OJ 02 01 I 5 7 1 J 4 5 I 7 8 t 1 0 MULTIPLES OF PICKUP SETIING r J oo 20 Figure A 2 Timing Type b2 Long Inverse Time Dwg No 1 8 752 294 002 ...

Page 31: ...Time Dwg No 1 8 752 294 003 T I E 0 I A L 99 80 60 50 40 30 20 10 07 05 03 02 01 00 20 0 z 0 _ UJ z UJ 200 100 10 10 70 10 40 20 0 7 5 4 J 2 1 Y t iii iii r I r r I r t I F 7 I 5 4 3 2 1 oe oe 07 oe oa 04 03 02 01 7 1 f ii liiiO 1 r 1 r r l 4 I 7 I 110 20 MULTIPLES OF PICKUP SETIING Figure A 4 Timing Type b4 Moderately Inverse Dwg No 1 8 752 294 004 T I E 0 I A l 99 80 60 50 40 30 20 1 0 07 05 03 ...

Page 32: ...Figure A 5 Timing Type b5 Inverse Time Dwg No 1 8 752 294 005 T I E 0 I A L 99 80 60 50 40 30 20 1 0 07 05 03 02 01 00 z 0 0 llJ z llJ ID ID 40 10 I I 7 I I i 7 I I 4 2 t oi Ill 07 01 o4 7 1 1 1 _ _ 1 _ _ n M L _ I l I l l IV l 1 1 l I N too F L _ l iii 1 I ll l 1 1 J 4 I I 7 I 110 MULTIPLES OF PICKUP SETIING Figure A 6 Timing Type b6 Very Inverse Time Dwg No 1 8 752 294 006 T I E 0 I A L 99 80 80...

Page 33: ...ing Type b7 Extremely Inverse Owg No 1 8 752 294 007 T I E 0 I A L 99 80 60 50 40 30 20 1 0 07 05 8 01 00 f 100 10 ID 111 10 50 40 20 10 I I 7 I s 0 3 z 0 i 1 l l l 1 I I n _ w f w 1 I F I 1 3 2 1 01 01 rn oa Oil 04 OJ 02 01 1 1 1 1 1 a I 7 1 1 1 3 5 1 7 1 110 MULTIPLES OF PICKUP SETIING Figure A 8 Timing Type b8 H Owg No 1 8 752 294 008 _ Ill T I E 0 I A L 99 80 80 50 40 30 20 1 0 8A 01 00 w w w ...

Page 34: ...ULTIPLES OF PICKUP SETIING Figure A 9 Timing Type c1 J2T w Limit 1 Dwg No 1 8 752 294 009 Ill Cf 0 z 0 0 w Cf z w F 1 l 10 10 50 40 1 50 l 20 l r 10 I I 7 5 I 1 l l 1 1 1 1 1 I 1 1 1 1 1 I 1 I 7 _ l 1 1 1 1 4 111 1 J 1 1 2 1 1 CII CII 07 01 00 04 03 01 01 7 1 J 4 5 t 1 I 110 MULTIPLES OF PICKUP SETIING Figure A 10 Timing Type c2 12 f w Limit 2 Dwg No 1 8 752 294 01 0 T I M E 0 I A L 99 80 60 50 40...

Page 35: ...ES OF PICKUP SETIING Figure A 1 1 Timing Type c3 FT w Umit 3 Dwg No 1 8 752 294 01 1 T I M E 0 I A L gg eo 80 50 40 30 20 10 U 0 z 0 _ LU U LU i D n 1 1 f l 1 I 2 H t H 1 Ht MM T I M E 80 80 50 40 30 20 10 I 01 00 01 L J L l LL L_J_ L L LLJ _J L L LJ L L A 7 A I 1 J 4 5 7 111 MULTIPLES OF PICKUP SETIING Figure A 12 Timing Type c4 FT w Limit 4 Dwg No 1 8 752 294 01 2 Ill w w w E l e c t r i c a l P...

Page 36: ...LES OF PICKUP SETIING Figure A 13 Timing Type c5 12T w Limit 5 Dwg No 1 8 752 294 013 T I E D I A L 80 eo 50 40 30 20 1 0 z 0 u UJ z UJ t 11 Ill 10 I 7 I J 1 I I 7 I I 4 3 I ai 01 01 01 I l 1 1 1 t 1n L 1 1 1 I I 7 1 1 1 J 4 I I 1 I 111 MULTIPLES OF PICKUP SETIING Figure A 14 Timing Type c6 12T w Limit 6 Dwg No 1 8 752 294 01 4 T I E D I A L 10 eo 50 40 30 20 10 I 00 w w w E l e c t r i c a l P a ...

Page 37: ...TIING Figure A 15 Timing Type c7 2T w Umit 7 Dwg No 1 8 752 294 01 5 T I M E D A I L gg 80 e0 50 40 30 0 2 1 0 I z 0 _ UJ f UJ F 100 10 10 7V 10 so 40 20 10 I I 7 I 1 I 4 3 2 1 01 01 07 01 01 04 Ol 02 01 1 c _ i t I ll I I 7 1 1 1 l 4 I I 7 I 1 10 20 MULTIPLES OF PICKUP SETIING Figure A 16 Timing Type c8 FT w Limit 8 Dwg No 1 8 752 294 01 6 T I E D I A L gg 80 eo 50 40 30 20 10 w w w E l e c t r i...

Page 38: ... t t t t t 1 1 22 92 _L_L _L_L _L L _L 2 4 6 8 10 12 14 16 MULTIPLE OF TAP 18 20 Figure A 1 7 SCOR Instantaneous Time Curve Phase Timings 70 60 1 50 s w 0 w 30 SCOR INSTANTANEOUS TIME CURVE GROUND TIMINGS 2 1 I 4 6 8 10 12 14 16 18 20 MULTIPLE OF TAP Figure A 18 SCOR Instantaneous Time Curve Ground Timings w w w E l e c t r i c a l P a r t M a n u a l s c o m ...

Page 39: ...erprovidesanadjustmentfrom 0 50 to 1 00Aforthe LOWrange andfrom 2 00to3 00Aforthe HIGH range EXCEPTION At the highest TAP position i e J the setting of the Tap Cal register is ignored Therefore the J values of 5 0 and 1 1 00 representthe upper limits oftheLOWand HIGH ranges respectively 8 3 Power Supply B 3 1 General The solid state power supply is a low burden flyback switching design which deliv...

Page 40: ...he computer s memory Operating Power POWER SUPPLY Loss Of Power Detector The current inputs are continuously polled and the calculations updated once for every 60 Hz line cycle As long as the sensed current is above the pickup point the elapsed time is accumu latedtoward trip However once the sensed current falls below pickup the relay is reset and all accumulated time is cancelled When thevalue o...

Page 41: ...n 3 Operation by Front Panel When two instantaneous outputsareselected one ofthem can be programmed to operate directlyfrom the system computer assumingthatthe Communications Option is also present The programming information is supplied in the Siemens Power Monitor Display and Monitoring Unit Manual SG 401 8 01 The second output relay when controlled by the computer cannot simultaneously serve as...

Page 42: ...lableon the SCOR display such as system diagrams with real time amperes and circuit breaker position detailed datafor all phases and ground simultaneously which changes to a trip log with time stamped currents at the time oftrip relaytargetoperation plus watchdog status a MIN MAX log and an event log with a time stamped chronological listing of events of all devices on the bus The event log is a p...

Page 43: ...se at nominal 60 Hz see Table 3 60 Hz Two ranges are available HIGH 2 0 1 1 0 A and LOW 0 5 5 0 A Range is independently specified for phase and ground by the second digit of the Style Number The TAP range windows on the front panel indicate which range HIGH or LOW is specified Selection of the desired tap is made using the rotary selector switch s on the front panel Refer to the table on the fron...

Page 44: ...ision is made to monitor primary current on a real time basis Accuracy is within 1 2 Range is from 1 0 of TAP at the low end to 1 50 of TAP at the high end Includes an RS 232 port on the front panel for local testing and configuration and an RS 485 port at rear of unit for operation by a Siemens Power Monitor unit at distances up to 4000 feet using baud rates up to 1 9 200 Power for the internal c...

Page 45: ...ofthree mutually perpendicular axes without structural damage or degradation of performance In standard tests the relay has withstood 2 g in each of three mutually perpendicular axes swept over the range of 10 to 500 Hz for a total of six sweeps 1 5 minutes each sweep without structural damage or degradation of performance 1 500 Vac at 60 Hz for one minute in accordance with IEC 255 5 and ANSI IEE...

Page 46: ...53 2 30 1 1 1 0 2 20 1 0 71 5 41 D 1 1 33 2 25 1 0 82 5 46 10 87 5 46 E 10 94 5 54 1 0 69 5 41 1 1 57 5 86 F 1 0 71 5 41 1 0 86 5 49 1 0 70 5 41 G 1 0 88 5 52 1 0 70 5 41 1 0 69 5 41 H 1 0 87 5 49 1 0 70 5 41 1 0 64 5 38 I 10 84 5 49 1 0 69 5 41 1 0 66 5 38 J 10 83 5 49 10 69 5 41 1 0 67 5 41 A HIGH 5 78 1 14 5 50 2 79 5 61 1 1 1 B 5 70 1 1 4 5 57 1 1 1 5 58 1 1 1 c 5 66 1 14 5 49 1 09 D 5 69 1 14...

Page 47: ...w w w E l e c t r i c a l P a r t M a n u a l s c o m ...

Page 48: ... EM ENS Siemens Energy Automation Inc Electrical Apparatus Division P O Box 29503 I Raleigh NC 27626 91 9 365 6660 SG 9228 01 8 92 2M PRINTED IN U S A w w w E l e c t r i c a l P a r t M a n u a l s c o m ...

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