BEGIN NEW DATA CASE C BENCHMARK DCNEW-20 C This data was received from Dr. Hiroshi Okamoto of Tokyo Electric Power Co. C (TEPCO) in Japan. This was by E-mail from on C 25 March 1997 as described in a story of the April, 1997, newsletter. C This data serves to compare the old Type-59 S.M. with the new Type-58 as C provided to ATP by TEPCO. C INF 1-GEN SYSTEM FOR SYNCHRONOUS MACHINE MODEL C DATA SET 'L0000530.SOU.EMTP2(GE2GC1)' C The time step size of 95 usec is especially chosen to illustrate stability C problems of the Type-59 S.M. (MACH 1 of the plot). The new Type-58 S.M. C (MACH 2 of the plot) is perfectly stable through the 100 msec shown, but C the old Type-59 clearly is beginning to diverge at the end of the plot. If C dT is increased from 95 to just 100 usec, the old Type-59 becomes a bomb. C On the other hand, if dT is decreased from 95 to 90 usec, the old Type-59 C becomes almost indistinguishable from the new Type-58 over the short time C span considered. But increase T-max to find later trouble. The original C data had dT = 10 usec and T-max = 1.0 sec. Consider increasing IPLOT C in such a case, and maybe using TPPLOT on a saved .PL4 file. If C IPLOT is not increased, the result is a 20.401-Mbyte disk file. C Answers change 10 February 1999 following the massive changes from C TEPCO (Tokyo Electric Power Company) in Japan. See April newsletter. .000095 .100 60. 60. 1 1 1 1 -1 5 5 20 20 100 100 1GA IA 8.707 197.6 3.308 2GB IB 5.704 65.29 -.061 8.591 196.8 3.384 3GC IC 5.466 47.29 -.171 5.704 65.29 -.061 8.707 197.6 3.308 1GAA IAA 8.707 197.6 3.308 2GBB IBB 5.704 65.29 -.061 8.591 196.8 3.384 3GCC ICC 5.466 47.29 -.171 5.704 65.29 -.061 8.707 197.6 3.308 BLANK ENDING OF BRANCH CARDS BLANK ENDING SWITCH CARD 14IA 408241.76 60.0 0.0 -1.0 14IB 408241.76 60.0 -120.0 -1.0 14IC 408241.76 60.0 +120.0 -1.0 14IAA 408241.76 60.0 0.0 -1.0 14IBB 408241.76 60.0 -120.0 -1.0 14ICC 408241.76 60.0 +120.0 -1.0 59GA 408248.29 60.0 1.0 -1.0 59GB 59GC 2 2 10 1000. 500.0 800.0 BLANK CARD 1.097 0.847 0.847 1. 0.847 1.007 0.767 0.507 0.0 0.66 0.0 1.0 0.005 0.000392 0.027 0.034 0.0 1 1.0 10.3677 1101.16 EU_MG 2 0.0 17.2795 EU_MS BLANK CARD 11 21 31 41 51 BLANK CARD FINISH C --------- End old Type-59 S.M. data; begin new Type-58 S.M. data: 58GAA 408248.29 60.0 1.0 -1.0 58GBB 58GCC 2 2 10 1000. 500.0 800.0 BLANK CARD 1.097 0.847 0.847 1. 0.847 1.007 0.767 0.507 0.0 0.66 0.0 1.0 0.005 0.000392 0.027 0.034 0.0 1 1.0 10.3677 1101.16 2 0.0 17.2795 BLANK CARD 11 21 31 41 51 BLANK CARD FINISH BLANK card ending source cards C GCC -210263.4133669 408248.29 -22.86029096659 50.481419449425 .102784436273E8 -21472.85033321 C 349937.08475555 121.0000000 45.008674792217 116.9264047 732007.00771024 -105731.5844176 C ICC -204120.88 408241.76 21.675662657966 50.626515259414 -.10299916478E8 C 353547.73504567 120.0000000 -45.75160866734 -64.6498883 -837738.5921279 C Total network loss P-loss by summing injections = 2.470730685868E+04 GA GB GC IA IB IC { Old Type-59 S.M. GAA GBB GCC IAA IBB ICC { New Type-58 S.M. C First 12 output variables are electric-network voltage differences (upper voltage minus lower voltage); C Next 38 output variables pertain to Type-59 S.M. components (names are generated internally); C Step Time GA GB GC IA IB IC GAA GBB GCC IAA C C IBB ICC MACH 1 MACH 1 MACH 1 MACH 1 MACH 1 MACH 1 MACH 1 MACH 1 C ID IQ I0 IF IKD IG IKQ IA C MACH 1 MACH 1 MACH 1 MACH 1 MACH 1 MACH 1 MACH 1 MACH 1 MACH 1 MACH 1 C IB IC EFD MFORCE MANG TQ GEN ANG 1 ANG 2 VEL 1 VEL 2 C C MACH 1 MACH 2 MACH 2 MACH 2 MACH 2 MACH 2 MACH 2 MACH 2 MACH 2 MACH 2 C TOR 1 ID IQ I0 IF IKD IG IKQ IA IB C C MACH 2 MACH 2 MACH 2 MACH 2 MACH 2 MACH 2 MACH 2 MACH 2 MACH 2 MACH 2 C IC EFD MFORCE MANG TQ GEN ANG 1 ANG 2 VEL 1 VEL 2 TOR 1 C 0 0.0 408186.112 -197922.7 -210263.41 408241.76 -204120.88 -204120.88 408186.112 -197922.7 -210263.41 408241.76 C -204120.88 -204120.88 -4.4130942 60.5639838 .772660912 800.402708 .852074217 .742801855 0.0 49.9984321 C -25.799853 -22.860291 -682.86299 799.860885 .015912194 .401972289 18.4574189 18.4411968 0.0 .14211E-13 C .422856651 49.9984321 -25.799853 -22.860291 800.402835 .852298612 .742428139 0.0 -4.4130942 60.5639838 C .772660912 -682.86299 799.861233 .015911908 .401972457 18.4574189 18.4411968 0.0 0.0 .422856651 C 1 .95E-4 407893.672 -185217.11 -222679.75 407979.972 -191330.68 -216649.29 408111.529 -185307.24 -222807.51 407979.972 C -191330.68 -216649.29 -4.2041412 60.3879406 .714862646 800.379672 .811106299 .781017269 0.0 49.7613998 C -24.063847 -24.459374 -682.86299 799.86747 .015896025 .400786124 18.4574189 18.4411968 .216E-10 .2802E-5 C .422856453 49.8095208 -24.085131 -24.485985 800.380399 .812262842 .788588762 0.0 -4.2091863 60.3524392 C .714993055 -682.86299 799.867602 .015892687 .400551293 18.4574189 18.4411968 .21714E-10 .281731E-5 .422856451 C 2 .19E-3 406867.982 -172041.84 -234825.96 407194.942 -178295.09 -228899.85 406998.315 -172084.21 -234913.87 407194.942 C -178295.09 -228899.85 -3.9507996 60.1570077 .659527672 800.35128 .762038113 .831454902 0.0 49.4294498 C -22.260505 -26.026609 -682.86299 799.875576 .015875056 .39923208 18.4574189 18.4411968 .131024E-9 .57827E-5 C .422855844 49.4707826 -22.278391 -26.047605 800.352354 .763726476 .854919597 0.0 -3.95874 60.0504313 C .660942841 -682.86299 799.875528 .015865594 .398526145 18.4574189 18.4411968 .132076E-9 .585937E-5 .422855836 BLANK card ending output requests C 1053 .100035 415280.068 -197293.88 -217987.68 408206.223 -199438.29 -208767.93 408235.937 -193516.73 -214722.13 408206.223 C -199438.29 -208767.93 -4.1350245 61.3028263 .690403958 800.370438 .799733436 .56388449 0.0 50.7259147 C -25.427344 -24.102756 -682.86299 799.871164 .015965431 .406847425 18.457757 18.4415815 .573744E-4 .395066E-4 C .421640989 50.3438664 -25.04608 -24.297981 800.350146 .676467979 .59869684 0.0 -3.6952162 61.1409442 C .577238085 -682.86299 799.876422 .015950332 .405730061 18.4577388 18.4415591 .556036E-4 .380861E-4 .421750163 C Variabl max: 415280.068 412229.576 411850.366 408241.76 408240.005 408241.321 408635.133 408471.267 408253.524 408241.76 C 408240.005 408241.321 5.12456969 68.4279518 1.78316215 800.48001 1.02182904 1.18160057 0.0 51.7606628 C 54.6088512 52.6553712 -682.86299 800.203141 .016566167 .453784705 18.457757 18.4415815 .108985E-3 .154242E-3 C .424309833 50.8562508 53.8835515 52.2481039 800.498224 1.00871794 1.15996876 0.0 4.8599028 67.7090154 C 1.87680621 -682.86299 800.19173 .01650918 .44903137 18.4577388 18.4415591 .101535E-3 .149203E-3 .424182575 C Times of max: .100035 .088635 .09424 0.0 .02223 .011115 .083315 .038855 .044365 0.0 C .02223 .011115 .08702 .097185 .09709 .01577 .01577 .001425 0.0 .09975 C .088825 .09443 0.0 .08702 .097185 .097185 .100035 .100035 .046265 .08702 C .06783 .09975 .08873 .01121 .01577 .01577 .00133 0.0 .00361 .013585 C .0969 0.0 .00361 .013585 .013585 .100035 .100035 .046455 .086925 .06783 193.01 0.0 .1 .30 .50MACH 1TQ GENMACH 2TQ GEN BLANK card ending plot cards BEGIN NEW DATA CASE C 2nd of 3 subcases was added 18 February 1999. The data came from TEPCO, C but has been modified to minimize the computational burden. As should be C described in the April, 1999, newsletter, NEW LOAD FLOW is illustrated. C INF 1-GEN SYSTEM FOR SYNCHRONOUS MACHINE MODEL C DATA SET 'L0000530.SOU.EMTP2(GE2GC1)' NEW LOAD FLOW { Request for new TEPCO load flow, used if unbalanced C The preceding old form of the request is being reactivated 3 June 2001 C to demonstrate the new warning message. It also reminds developers that C the old form continues to be honored (and eventually should be removed). C It is recommended that others use CAO instead of NEW as follows: C CAO LOAD FLOW { Alternate, preferred form of request beginning 21 March 99 C 10.E-6 1. 60. 60. ---- original simulation is demanding 40.E-6 .100 60. 60. { Shorter, faster simulation for this use 1 1 1 1 1 -1 5 5 20 20 100 100 500 500 1GA IA 8.707 197.6 3.308 2GB IB 5.704 65.29 -.061 8.591 196.8 3.384 3GC IC 5.466 47.29 -.171 5.704 65.29 -.061 8.707 197.6 3.308 BLANK ENDING OF BRANCH CARDS BLANK ENDING SWITCH CARD 14IA 408241.76 60.0 0.0 -1.0 14IB 408241.76 60.0 -120.0 -1.0 14IC 408241.76 60.0 +120.0 -1.0 58GA 408248.29 60.0 1.0 -1.0 58GB 58GC 2 2 10 1000. 500.0 800.0 BLANK CARD for Q axis 1.097 0.847 0.847 1. 0.847 1.007 0.767 0.507 0.0 0.66 0.0 1.0 0.005 0.000392 0.027 0.034 0.0 1 1.0 10.3677 1101.16 EU_MG 2 0.0 17.2795 EU_MS BLANK CARD 11 21 31 41 51 BLANK CARD ending S.M. output requests FINISH BLANK CARD ending sources GA GB GC 10000000. 0. 1 0.01 GA GB GC IA IB IC BLANK CARD FOR ENDING OUTPUT REQUEST PRINTER PLOT 144 2. 0.0 20. GA GB GC 194 2. 0.0 20. MACH 1TQ GENMACH 1I0 BLANK card ending plot cards BEGIN NEW DATA CASE C 3rd of 3 subcases involving modeling from TEPCO (Tokyo Electric Power Co.) C --- data that demonstrated trouble with the Type-58 S.M. model prior to C correction of the UTPF on 22 January 2003. Data is from Dr. Eiichi C Haginomori of Kyushu Institute of Technology in Kita-Kyushu, Japan. C Ending time T-max has been shortened to 5 * dT because the switching C that caused trouble has been advanced to the 3rd time step. Following C correction, execution no longer hangs during the step following switching. NEW LIST SIZES { Overflow of 3 times default without expanded List 19 below: 350 0 0 80 4000 BLANK 240000 742 ABSOLUTE TACS DIMENSIONS C Expand TACS Table 1 from 57 to 120 on 1 April 2007. Force the data thru. C Reduce preceding 8000 of List 19 to 4000 since TACS is not very demanding C The effect on case-summary statistics is to reduce 7644 to 3271. C 57 256 285 36 85 713 998 171 --- default 120 30 50 40 70 1200 120 115 C USING TPBIG-96/7 --- DIRECT CONNECTION OF UM AND INVERTER C CALCULATED THETAE FROM EL. INFORMATIONS ACTURALLY --- 3*THETAM=THETAE FOR 6P C <<< ONE-GEN --- INF BUS SYSTEM WITH FLYWHEEL COMPENSATOR>>> C SYNCH. GENERATOR 1200MVA 6P / FLYWHEEL COMPENSATOR 200MVA 6P DOUBLY FED MACH. C <> SYNC. GEN. FIX FLOW CAN NOT C A-SYMMETRICAL FAULT CURRENT, UNDER UPPER LIMIT POWER FLOW C <> POWER FREQUENCY, 50. UM TO TACS .000200 .001 { Just 5 steps. Original data had Tmax = 3.0 and IPLOT = 10 1 1 1 3 TACS HYBRID C INPUTTING VALUES 92IE3 {UM SECONDARY CURRENT PHASE A --- UM TO TACS PARAMETERS 92IE1 {DITTO B 92IE2 {DITTO C 92IPA {UM PRIMARY CURRENT PHASE A 92IPB {DITTO B 92IPC {DITTO C 90G1RX {UM PRIMARY SIDE TERMINAL VOLTAGE PHASE R 90G1SX {DITTO S 90G1TX {DITTO T C MEASURING DELTA F OF THE HIGH-VOLTAGE BUS 90B271R {HIGH VOLTAGE BUS VOLTAGE 90B271S {HIGH VOLTAGE BUS VOLTAGE 90B271T {HIGH VOLTAGE BUS VOLTAGE C INVERTER CONTROLLING 91VAP { phase-A current } 91VBP { phase-B current } 91VCP { phase-C current } 93VDA { Leg-A top switch status } 93VDB { Leg-B top switch status } 93VDC { Leg-C top switch status } C CONSTANTS 11X0 1.6642 -1. {UM PARAMETER 11X1 .08635 -1. {DITTO 11PP1 -600000. -1. {OUTPUT CONST. 11PP2 -2.5E08 .44 {DITTO 11QQ1 -1000000. -1. {DITTO 11QQ2 -2.5E08 .44 {DITTO C BUS VOLTAGE FREQUENCY METER 98BUSV = B271R - .5 *(B271S + B271T) 1VOLT +BUSV 1. 1. .005 98FREQ 50+VOLT 50. 500. 88DELFR1 = (FREQ - 50.)/ .5 DELFR +DELFR1 -1. 1. 2DELFZ +DELFR 1. 1. .06 .0009 C COMMAND CALCULATION --- FIRSTLY UM PRIMARY SIDE VECTORS VRSQ +G1RX -1. 1. 98SIG 59+VRSQ 99IN1 = 100 * PI * DELTAT 98TH0 65+IN1 SIG 98PP = PP1 + (PP2 * DELFZ) {ACTIVE POWER CONTROLLING 98QQ = QQ1 + (QQ2 * DELFZ) {REACTIVE POWER CONTROLLING 99V1PS =SQRT((G1RX * G1RX) + ((G1SX - G1TX) * (G1SX - G1TX)/3.)) 1V1P +V1PS 1. 1. .002 98I1P =2 * SQRT((PP * PP) + (QQ * QQ)) / V1P 98TH11 =ATAN(QQ / PP) 98TH12 =TH11 + PI 98TH1 60+TH12 +TH11 +TH11 0.0 PP 98I1 =I1P * SIN(TH0 + TH1) 98XXX =COS(TH1) / (V1P/(X1*I1P) - SIN(TH1)) 98TH2 =ATAN(XXX) 98E1P =X1 * I1P * COS(TH1)/SIN(TH2) 98I0P =E1P / X0 98I0 =I0P * SIN(TH0 + TH2 - (PI/2)) 98I21 =I1 + I0 C CALCULATION CORRESPONDING TO POSITION SENCER C PRIMARY SIDE VIEW OF THE SECONDARY CURRENT 98V1 = 0.5 * (G1RX - G1SX - G1TX) 98JV1 = (G1TX - G1SX) / 1.7320508 98I11 = 0.5 * (IPA - IPB - IPC) 98JI11 = (IPC - IPB) / 1.7320508 98I21A = (I11 * (1. + (X1/X0))) - (JV1/X0) 98JI21A = (V1/X0) + (JI11 * (1. + X1/X0)) 98THI210 = -(ATAN(JI21A/I21A)) 98THI211 = THI210 + PI 98THI21A60+THI211 +THI210 +THI210 0.0 I21A C SECONDARY SIDE VIEW OF THE SECONDARY INJECTING CURRENT C IN UM, IE3, IE1, IE2 ARE Ia, Ib, Ic OF RESPECTIVE OUTGOING CURRENT, THEN: 98I22 = 0.5 * (IE1 + IE2 - IE3) 98JI22 = (IE1 - IE2) / 1.7320508 98THI220 = -(ATAN(JI22/I22)) 98THI221 = THI220 + PI 98THI22 60+THI221 +THI220 +THI220 0.0 I22 C CALCULATION OF THETAE 98THETAE = THI21A- THI22 {BASED ON UM POSITION IN EMTP} C SECONDARY SIDE CURRENTS --- FOR COMMANDING 98I2A1 =I1P * SIN(TH0 + TH1 - THETAE) 98I2A0 =I0P * SIN(TH0 + TH2 - (0.5*PI) - THETAE) 88S2AS =I2A1 + I2A0 98I2B1 =I1P * SIN(TH0 + TH1 - (0.66667*PI) - THETAE) 98I2B0 =I0P * SIN(TH0 + TH2 - (1.16667*PI) - THETAE) 88S2BS =I2B1 + I2B0 98I2C1 =I1P * SIN(TH0 + TH1 + (0.66667*PI) - THETAE) 98I2C0 =I0P * SIN(TH0 + TH2 + (0.16667*PI) - THETAE) 88S2CS =I2C1 + I2C0 1S2AIN +S2AS 1. 1. .005 1S2BIN +S2BS 1. 1. .005 1S2CIN +S2CS 1. 1. .005 C --------- SINUSOIDAL REFERENCE CURRENTS 98IREFA = S2AIN 98IREFB = S2BIN 98IREFC = S2CIN 98DELTAI = 200. { one-half of the difference between the upper and the lower C tolerance bands } C 98REFPOS = IREFA + DELTAI { POSITIVE REFERENCE BAND FOR PHASE-A } C 98REFNEG = IREFA - DELTAI { NEGATIVE REFERENCE BAND FOR PHASE-B } C --------- ERROR BETWEEN THE MEASURED AND THE REFERENCE CURRENTS 98ERRORA = VAP - IREFA 98ERRORB = VBP - IREFB 98ERRORC = VCP - IREFC C --------- SIGNL = 0 IF THE CURRENT IS WITHIN THE TOLERANCE BANDS C = 1 IF THE CURRENT EXCEEDS THE UPPER TOLERANCE BAND C =-1 IF THE CURRENT FALLS BELOW THE LOWER TOLERANCE BAND 98SIGNLA = SIGN( ERRORA ) * ( ABS( ERRORA ) .GT. DELTAI ) 98SIGNLB = SIGN( ERRORB ) * ( ABS( ERRORB ) .GT. DELTAI ) 98SIGNLC = SIGN( ERRORC ) * ( ABS( ERRORC ) .GT. DELTAI ) C --------- SIGA AND SIGAP CONTROL LEG-A SWITCHES; SIGB AND SIGBP CONTROL LEG-B C SIGC AND SIGCP CONTROL LEG-C C --------- SIG = NO CHANGE, IF SIGNL = 0 C = 0 , IF SIGNL = 1 C = 1 , IF SIGNL =-1 98SIGA 60+UNITY +VDA +ZERO SIGNLA 98SIGB 60+UNITY +VDB +ZERO SIGNLB 98SIGC 60+UNITY +VDC +ZERO SIGNLC 98SIGAP = .NOT. SIGA 98SIGBP = .NOT. SIGB 98SIGCP = .NOT. SIGC 33THI210THI22 THETAEDELFZ IREFA BLANK card ending TACS data C POWER SYSTEM CIRCUITS C TRANSFORMER FOR UM TRANSFORMER TR1RX 5.00E3 1.5 205. 7. 232. 333. 271. 3333. 386. 9999 1G1RX G1SX .0001 .01 11. 2B271R NNX .5 90. 158.8 TRANSFORMER TR1RX TR1SX 1G1SX G1TX 2B271S NNX TRANSFORMER TR1RX TR1TX 1G1TX G1RX 2B271T NNX C AROUND TRANSFORMER PARAMETERS G1RX 100. .5 G1SX G1RX G1TX G1RX B271R .2 .02 B271S B271R B271T B271R NNX 1. C MACHANICAL NETWORK COMPONENTS MG .00366 {1.5%} MG 1.8E11 MS MG .10E-3 1 C UM SECONDARY SIDE PARAMETERS S2A CL2A .001 1 S2B CL2B S2A CL2A 1 S2C CL2C S2A CL2A 1 CL2A 100. CL2B CL2A CL2C CL2A C GENERATOR STEP-UP TRANSFORMER TRANSFORMER 1. 747.6 TR1R 60.0E3 1. 747.6 4. 971. 16. 1196. 1000. 1300. 9999 1B271R 27N1 .2 33. 166. 2G1R G1S .001 .076 24. TRANSFORMER TR1R TR1S 1B271S 27N1 2G1S G1T TRANSFORMER TR1R TR1T 1B271T 27N1 2G1T G1R C AROUND TRANSFORMER PARAMETERS 27N1 .5 .005 G1R .01 .05 G1S G1R G1T G1R B271R G1R B271S G1R B271T G1R C LONG TRANSMISSION LINE parameters in English due to bug in TP20 $VINTAGE, 1 -1B271R B272R 2.26285E+00 9.55548E+02 1.26663E+05 4.25000E+01 1 -2B271S B272S 3.10872E-02 2.76280E+02 1.81024E+05 4.25000E+01 1 -3B271T B272T -4L271S L272S -5L271T L272T -6L271R L272R -1B272R B273R 2.26285E+00 9.55548E+02 1.26663E+05 4.50000E+01 1 -2B272S B273S 3.10872E-02 2.76280E+02 1.81024E+05 4.50000E+01 1 -3B272T B273T -4B272S B273S -5B272T B273T -6B272R B273R $VINTAGE, 0 B273R .01 .05 B273S B273R B273T B273R B273R SWGR .1 17.5 1 B273S SWGS B273R SWGR 1 B273T SWGT B273R SWGR 1 C INVERTER CIRCUITS, WITH 1.5MH VA VAP .001 1.5 3 VB VBP VA VAP 3 VC VCP VA VAP 3 C --------- SMALL RESISTANCES ARE ADDED VD VDA 0.001 VD VDB VD VDA VD VDC VD VDA VDN VDNA VD VDA VDN VDNB VD VDA VDN VDNC VD VDA C ANOTHER HIGH OHMIC RESISTORS VD 90000. VDN VD VAPG VD VBPG VD VCPG VD VA VD VB VD VC VD C SNUBBER VDA VA 5. 10. VDB VB VDA VA VDC VC VDA VA VA VDNA VDA VA VB VDNB VDA VA VC VDNC VDA VA C INVERTER INITIAL DUMMY LOAD VAPGL .003 VBPGL VAPGL VCPGL VAPGL BLANK card ending branch cards C FAULT INITIATION AND CLEARING SWITCHES C ---------------- Begin modification for use with T-max = 5 * dT. C First, omit the 3 original fault switches to ground: C L271R .303 10. 1 C L271S .299 10. 1 C L271T .2965 10. 1 C Only the phase "a" switch is needed. This was the one C that caused trouble (a tight loop 1 step after closure). C Advance closing time to 2.5 * dT ==> closure on step 3. C Without correction to OVER16, execution would hang with C the last output on the screen being that for step 3: L271R .000500 10.0 1 C ---------------- End of modification made 22 January 2003 B271R L271R -1. .4 B271S L271S -1. .4 B271T L271T -1. .4 L272R B272R -1. .4 L272S B272S -1. .4 L272T B272T -1. .4 C SWITCHES TURN OVER THE INVERTER OUTPUT FROM DUMMY TO UM SECONDARY VAPG VAPGL -1. .201 9.E10 {SHALL BE BEFORE MEASURING SW VBPG VBPGL -1. .201 9.E10 VCPG VCPGL -1. .201 9.E10 VAPG CL2A .20 10. VBPG CL2B .20 10. VCPG CL2C .20 10. C SWITCHES IN THE INVERTER AND AC SIDE CIRCUITS VAP VAPG MEASURING VBP VBPG MEASURING VCP VCPG MEASURING C CONNECTED DIODE 13VDA VA SIGA 1 13VDB VB SIGB 1 13VDC VC SIGC 1 13VDNA VA SIGAP 1 13VDNB VB SIGBP 1 13VDNC VC SIGCP 1 BLANK card ending switch cards 14SWGR 225000. 50. 0. -1. 14SWGS 225000. 50. -120. -1. 14SWGT 225000. 50. 120. -1. C 14S2A -15600. .005 5. -1. .201 14S2B -15600. .005 -115. -1. .201 14S2C -15600. .005 125. -1. .201 C DC VOLTAGE CAN BE REDUCED TO +/- 700 VOLTS WITHOUT CHANGING OTHERS 14VD 750. .00001 -1. 14VDN -750. .00001 -1. C MECHANICAL TORQUE (ACTUAL VALUE WILL BE SET BY INITIAL CONDITION) 14MS -1.0001 .000001 -1. C ------ UNIVERSAL MACHINE PARAMETERS 19 UM 1 {COMPENSATION, SLIP INITIALIZATION IS INTRODUCED} BLANK RECORD ENDING GENERAL UNIVERSAL MACHINE SPECIFICATION C UM MACHINE-TABLE C UM TYPE 4 (DOUBLY FED INDUCTION MACHINE) 4 311MG 3 .1047 .0053 .0053 C INITIAL CONDITION ---- ONLY SLIP IS SPECIFIED AS .01% .01 MS C MOTOR COIL PARAMETERS C THE POWER (ARMATURE/STATOR) COILS G1RX 1 .003 .000275 G1SX 1 .003 .000275 G1TX 1 C THE ROTOR COILS .003 .000275 CL2B 1 .003 .000275 CL2C 1 CL2A 1 BLANK ENDING ALL WINDING ROTOR INDUCTION MOTOR DATA 58G1R 20000. 50. 4.3 58G1S 58G1T C TOLERANCES {DEFAULT} PARAMETER FITTING 1.0 C 1 1 61.0 1.0 1200. 24.0 -500. 550. 900. -1. .003 .2033 1.048 .640 .299 .640 .214 .278 6.4 0.0 .033 .04 .214 .01 .1 C 1 1.0 25. 5. BLANK {FOR END OF CLASS 4 CARDS} 11 21 31 51 BLANK {FOR END OF OUTPUT REQUEST} C 71VFG1 C 73TEG1 14 FINISH BLANK card ending electric network source cards C - - INITIAL CONDITIONS C 03VA VAP 16200. C 03VB VBP -12000. C 03VC VCP -4400. B271R B271S B271T G1R G1S G1T G1RX G1SX G1TX CL2A CL2B CL2C C First 15 output variables are electric-network voltage differences (upper voltage minus lower voltage); C Next 17 output variables are branch currents (flowing from the upper node to the lower node); C Next 16 output variables pertain to Type-59 S.M. components (names are generated internally); C Next 5 output variables belong to TACS (with "TACS" an internally-added upper name of pair). C Final 11 output variables pertain to Type-19 U.M. components (names are generated internally); C Step Time VA VB VC B271R B271S B271T G1R G1S G1T G1RX C VAP VBP VCP C C G1SX G1TX CL2A CL2B CL2C L271R VDA VDB VDC VDNA C TERRA VA VB VC VA C C VDNB VDNC MS S2A S2B S2C B273R B273S B273T VA C VB VC MG CL2A CL2B CL2C SWGR SWGS SWGT VAP C C VB VC MACH 1 MACH 1 MACH 1 MACH 1 MACH 1 MACH 1 MACH 1 MACH 1 C VBP VCP IA IB IC IF IKD IG IKQ ID C C MACH 1 MACH 1 MACH 1 MACH 1 MACH 1 MACH 1 MACH 1 MACH 1 TACS TACS C IQ I0 EFD MFORCE MANG TQ GEN ANG 1 VEL 1 THI210 THI22 C C TACS TACS TACS UM-1 UM-1 UM-1 UM-1 UM-1 UM-1 UM-1 C THETAE DELFZ IREFA TQGEN FLUXMD IMD OMEGM THETAM IPA IPB C C UM-1 UM-1 UM-1 UM-1 C IPC IE1 IE2 IE3 C *** Phasor I(0) = 1.7481189E+03 Switch "B271R " to "L271R " closed in the steady-state. C *** Phasor I(0) = -4.5243456E+02 Switch "B271S " to "L271S " closed in the steady-state. C *** Phasor I(0) = -1.2956844E+03 Switch "B271T " to "L271T " closed in the steady-state. C *** Phasor I(0) = 1.7686094E+03 Switch "L272R " to "B272R " closed in the steady-state. C *** Phasor I(0) = -5.1164059E+02 Switch "L272S " to "B272S " closed in the steady-state. C *** Phasor I(0) = -1.2569688E+03 Switch "L272T " to "B272T " closed in the steady-state. C *** Phasor I(0) = 7.8597942E-28 Switch "VAPG " to "VAPGL " closed in the steady-state. C *** Phasor I(0) = 7.8597942E-28 Switch "VBPG " to "VBPGL " closed in the steady-state. C *** Phasor I(0) = 7.8597942E-28 Switch "VCPG " to "VCPGL " closed in the steady-state. C *** Phasor I(0) = 7.8597944E-28 Switch "VAP " to "VAPG " closed in the steady-state. C *** Phasor I(0) = 7.8597944E-28 Switch "VBP " to "VBPG " closed in the steady-state. C *** Phasor I(0) = 7.8597944E-28 Switch "VCP " to "VCPG " closed in the steady-state. C 0 0.0 -.2259E-29 -.2259E-29 -.2259E-29 208158.64 -21846.037 -186312.6 19943.7027 -8673.1817 -11270.521 9113.64098 C -5276.1428 -3837.4982 16.8063328 -6.3031915 -10.503141 0.0 0.0 0.0 0.0 0.0 C 0.0 0.0 152316.004 5578.69031 -2366.6623 -3212.028 3559.62137 -1144.404 -2415.2173 .78598E-27 C .78598E-27 .78598E-27 41715.1084 -30191.8 -11523.308 1001.80789 .487618E-5 0.0 .20218E-5 -35892.416 C 38680.9534 .170478E-9 -3332.2787 718.756062 .237235816 11.7236335 39.4571339 .46896E-12 0.0 0.0 C 0.0 0.0 0.0 123706.91 35.5738008 6712.03789 104.709283 .523598776 938.381553 -554.20525 C -384.1763 2366.59923 3211.92301 -5578.5222 C 1 .2E-3 -.1339E-13 -.1339E-13 -.1339E-13 201977.519 -7722.5921 -194254.03 19823.8315 -7579.7442 -12244.087 9151.45131 C -4804.5629 -4346.8884 23.814177 -7.6609777 -16.153199 0.0 0.0 0.0 0.0 0.0 C 0.0 0.0 152316.004 5578.68724 -2366.6304 -3212.0569 3505.7501 -925.34683 -2580.4033 -.8926E-15 C -.8926E-15 -.8926E-15 42307.6898 -28187.048 -14120.641 1001.59093 -2.0122485 0.0 -.8358523 -35874.126 C 38689.6613 -.1969E-11 -3332.2787 716.646844 .237381679 11.7267018 39.4571339 -.29124E-6 -1.4215961 .087267731 C -1.5088638 0.0 -62.836554 123698.108 35.5747011 6712.20775 104.709283 .544540632 942.608173 -504.94928 C -437.6589 2366.55377 3211.89533 -5578.4491 C 2 .4E-3 -749.75008 -749.75008 -749.75008 194885.42 6602.83234 -201489.52 19598.7968 -6330.0077 -13268.789 9151.94877 C -4310.2982 -4841.6506 28.6859178 -9.1396133 -19.546304 0.0 0.0 0.0 0.0 -149.97834 C -149.97834 -149.97834 152316.004 5578.68418 -2366.5985 -3212.0857 3437.41314 -702.48667 -2734.9265 -49.980007 C -49.980007 -49.980007 42730.2018 -26082.723 -16647.479 1001.36092 -4.0385211 0.0 -1.6446481 -35870.068 C 38686.6306 -.3212E-11 -3332.2787 714.385728 .237526201 11.7277418 39.4571339 -.97244E-6 -1.3592587 .087272806 C -1.4465315 0.0 -145.63073 123685.026 35.5770492 6712.65079 104.709283 .565482489 943.011488 -453.49067 C -489.52082 2366.50709 3211.89023 -5578.3973 C *** Close switch "L271R " to " " after 6.00000000E-04 sec. C 3 .6E-3 -749.41701 -749.41701 750.083142 186906.226 20907.6164 -207813.87 19310.7466 -5217.9361 -14092.81 9111.193 C -3792.8021 -5318.3909 27.9503294 -12.236022 -15.714307 0.0 0.0 0.0 183.36497 -116.59171 C -116.59171 0.0 152316.004 5578.68111 -2366.5666 -3212.1145 3356.73113 -477.93728 -2878.7937 -149.91115 C -149.91115 -49.951141 42979.6997 -23882.395 -19097.305 1001.16741 -5.618633 0.0 -2.210096 -35872.276 C 38671.8269 .52551E-11 -3332.2787 712.559772 .23763113 11.7257636 39.4571339 -.15646E-5 -1.2963263 .087286091 C -1.3836124 0.0 -177.30291 123687.716 35.579885 6713.18584 104.709283 .586424345 939.747207 -400.25471 C -539.4925 2366.44424 3211.95737 -5578.4016 BLANK card ending names of nodes for node voltage PRINTER PLOT C 4 .8E-3 -748.99533 -748.99533 749.838688 0.0 13506.5876 -233952.01 14577.5321 277.974209 -14855.506 5550.20833 C 194.206101 -5744.4144 -2556.0075 -910.96566 3466.97318 1441.53156 0.0 0.0 -27.703214 -260.88663 C -260.88663 0.0 152316.004 5578.67804 -2366.5347 -3212.1433 3263.9781 -252.44548 -3011.5318 -249.77866 C -249.77866 50.0436418 44314.9041 -22892.215 -21422.689 1001.6319 -1.0119264 0.0 -8.8523256 -37619.202 C 39135.5529 -.705E-11 -3332.2787 702.815796 .238926785 11.9567249 39.4571338 -.23891E-4 -.8024862 .091369899 C -.8938561 0.0 -215.55492 133220.775 35.2574518 6652.3494 104.709283 .607366202 1023.64204 -438.56934 C -585.0727 2357.42505 3246.81306 -5604.2381 C 5 .1E-2 -748.60353 -748.60353 749.387134 0.0 81277.3789 -183207.78 12900.5692 2610.61804 -15511.187 4283.41475 C 1858.75941 -6142.1742 -4023.6743 -783.70104 4807.37529 2017.68499 0.0 0.0 175.891852 -345.88141 C -345.88141 0.0 152316.004 5578.67497 -2366.5028 -3212.1722 3157.97507 -25.604427 -3132.3703 -349.57863 C -349.57863 149.978695 47142.2759 -23517.378 -23624.897 1004.52269 25.8533897 0.0 -15.562683 -41739.361 C 39892.6407 .51464E-11 -3332.2787 697.874488 .240411365 12.3998762 39.457133 -.1102E-3 -.56146341 .092374845 C -.65383825 0.0 -274.01893 147358.665 34.4425429 6498.593 104.709283 .628308059 1170.0168 -540.67448 C -629.34232 2358.66581 3260.24591 -5618.9117 BLANK card ending batch-mode plot cards BEGIN NEW DATA CASE BLANK