Capacitor Switching - PowerPoint PPT Presentation

About This Presentation
Title:

Capacitor Switching

Description:

Capacitor Switching continued A 13.8 KV, 5000KVAR, 3ph bank,NGr Source Gr, inductance:1 mH Restrike at Vp: 1- c=5/(377x13.8 )=69.64 F 2- Z= 1000/69.64=3.789 – PowerPoint PPT presentation

Number of Views:97
Avg rating:3.0/5.0
Slides: 31
Provided by: MH87
Learn more at: https://ee.sharif.edu
Category:

less

Transcript and Presenter's Notes

Title: Capacitor Switching


1
Capacitor Switching continued
  • A 13.8 KV, 5000KVAR, 3ph bank,NGr
  • Source Gr, inductance1 mH
  • Restrike at Vp
  • 1- c5/(377x13.8?)69.64µF
  • 2- Zv1000/69.643.789O
  • 3-Ip2v2x13.8/(v3x3.789)5.947 KA
  • 4-f0603 Hz

2
Subsequent Occurences
  • C.B. Interr. H.F. current at its zero
  • 3Vp on Cap.at most 4Vp across C.B.
  • If 2nd B.D. occur, 2nd Osc.
  • I doubles, Vc from 3Vp to -5Vp
  • If C.B. opens, at most 8Vp across C.B.
  • further ESCALATION possible
  • Rs seq.Restrikes, Cs subseq.Clearing
  • Variation of VCB shown in FIG

3
Other Restriking Phenomena
  • Seq. restrik. clearing of C.B.
  • O.V.s (even inductive load)
  • low p.f. results in Vp at zero current
  • Dominant fTRV?0/2? 1/2?vL2C Fig.
  • Several KHz if C stray Cap. small
  • reigniting effect heuristic approach
  • Superposition of Vs(0) effect Vc(0) effect
  • IVm/?(L1L2) sin?t
  • I1(0)I2(0)I(0)It(during short duration)
  • I Vm/L1L2

4
Restriking cct
reignition after isolating inductive load
  • Equivalent CCT
  • Short interval ?t0
  • source sub. Battery
  • I1I2 rising ramp
  • as current restab.
  • Ramp component1 Vs(0).t/L1L2
  • f011/2? x vL1L2/L1L2C

5
Discussion Continued .
  • Now superposing effect of the Capacitance
  • Initial Voltage Vc(0) at reignition
  • Surge impedance
  • Z0vL1L2/c(L1L2)
  • The Osc_component2
  • IcVc(0)/vL1L2/c(L1L2)
  • fraction L1/(L1L2) of it pass L2
  • fraction L2/(L2L2)of it pass L1

6
Formal Solution
  • Two Loops Equation
  • L1 dI1/dtVc(0)1/c?(I1-I2)dtVs(0),
    (1)
  • Differ.(1) d?I1/dt?I1/L1C-I2/L1C0,
    (2)
  • Vc(0)1/C?(I1-I2)dtL2 dI2/dt, (3)
  • L.T. of Eqs (2) (3) respectively
  • (s??1?)i1(s)-?1? i2(s)s I1(0)I1(0)
    (4)
  • ?2?i1(s)-(s??2?)i2(s)sI2(0)I2(0)
    (5)
  • I1(0)Vs(0)-Vc(0)/L1, I2(0)Vc(0)/L2
  • ?1?1/L1C, ?2?1/L2C

7
Discussion of Formal Solution
  • Solving Eqs (4) (5) simultaneously
  • yields current 2 comp.s
  • 1- a ramp component
  • 2- a damped oscillating component with
    v(?1??2?) v(L1L2)/L1L2C
  • In first method assumed I2(0)0
  • true if Reignite at peak of TRV
  • sys Gr Neutral, this fault High Cur. cause
    Damage
  • All sys Gr directly or through some stray C
  • So ARCING Gr Next Discussion

8
ARCING GROUND
  • L-Gr faultarcph Gr stopReig.repeated
  • Fig of simple model without sources
  • C1 ph to ph cap.
  • C0 ph to Gr cap.
  • N at Gr potenial
  • A to Gr ?shift V Ep1pu
  • VA neg.peak at F. instant
  • Shift shown in phasor D.

9
Discussion of Arcing Gr. results
  • C0 of A dischargeN rise to Ep B,C rise
  • C1C0 share charges at B and C
  • not at once to Diagram values
  • Charge Conservation
  • V(C0C1)1/2C0Ep3/2C1Ep
  • VEp/2(C03C1)/(C0C1)
  • VBVC rise to 3/2Ep osc. C0,C1Ls
  • CCT shown in Fig.

10
Discussion Continued
  • Equivalent CCT
  • f01/2?v3L(c0C1)
  • Z0v3L/4(C0C1)
  • VBVC? above 3/2 Ep
  • Ip(3/2Ep-V)/Z0
  • subs. for VZ0
  • Ip2Ep(C0/C0C1)x
  • v(C0C1)/3L
  • ? IB pass out of node
    B?dividedIc1,Ic0
  • ? Ic1 pass the arc its frac.
  • C0/(C0C1)
  • ? Also a 60Hz current due to VA through CN

11
What Happens Afterward?
  • Depends on Arc behavior
  • 1-Iarc till next p.f. zero in 1/2cycle
  • 2-Iarc immed. Ceased in 1st zero of the IHF
  • If 1, occur after ½ cycle
  • since A is still at Gr levelN in -1pu
  • 3ph Phasors in next Fig a
  • N keeps -1pu and after 1/2cycle
  • VA rise to -2pu Fig b

12
Phasor Diagram after interrupting a reignition
current
  • Fig a b
  • If Reignite again
  • similar shift ?V2pu
  • Rather than 1pu
  • Transients higher
  • N -1pu? 1pu
  • Swings of A B
  • Then seq. can repeat

13
continued on case 1 then Case2
  • after 1/2cycle A,Gr however at peak
  • BC instant. -1.5pu to Gr
  • If now arc interrupts VN change -1pu
  • After ½ cycle exactly as last fig b
  • Case 2 If interrupt at 1st zero of IHF
  • occur at point P of curves
  • 1-Vc1,Vc2 attain Vp
  • 2-Arc extinguish C1 s rise to VLL(VACVAB1.5pu)
  • Vp1.5Ep(1.5Ep-V)3Ep-V

14
Continued on Case 2
  • i.e. Vp-3/2Ep3/2Ep-V across arc path
  • ? N has corresponding Disp.
  • ?Phasor Diag.Fig.a?
  • ?different from 1st fig
  • ?Then arc interruption
  • at p.f. current zero
  • when VmaxVAG,
  • 1/2cycle later, situation of figb

15
Discussion
  • transient following next reignit. Is greater
  • Arc is interrupted in 1st H.F. zero I
  • neutral displacement increases
  • increase in energy trapped on zero seq Cap
    escalate the voltage
  • How to suppress arcing Gr OVs
  • 1- an appropriate reactance in neutral
  • 2- Peterson coil , sensitive for fault
    detection

16
Assignment No. 3
  • Ques. 1
  • C12µF,C2.38µF
  • L800µH,R5O
  • VC1(0)75 KV
  • S closes, compute
  • 1-Max energy in L?
  • 2-t0 instant current flow in c2
  • 3-Vc1(t0)?
  • 4-Max of Vc2 ?

17
Solution of Question 1
  • Z0vL/C1 v800/220O
  • S close Ipeak(undamped)75/203.75KA
  • ?Z0/R4(fig 4.4)?
  • Ip0.83x3.75 3.112 KA
  • Emax0.0008x3.1122/24.12KJ
  • I flows in C2 when reverses?fig4.4 at t3.15
  • or t3.15vLC1126µs, (T40µs)
    fig4.6 ? Vc1-0.69x75-51.75 KV

18
Eq. CCT (Diode goes off)
  • series RLC CCT
  • At this instant
  • Vc1(0),Vc2(0) required
  • CCT diff. Eqs employed
  • Solved for Vc2

19
Solution of Question 1 continued
  • 2nd1/2cycle,Vc1(0)51.75KV,Vc2(0)0,I(0)0
  • C1C2 now in series CeqC1C2/(C1C2)
  • Z0v(800x2.38)/(2x0.38)50.05O ?50/510
  • Now for series C1,C2,R,L we have
  • Vc1Vc2RIL dI/dt
    (1)
  • I-C1 dVc1/dt-C2 dVc2/dt (2)
  • Vc1Vc1(0)-1/C1?IdtVc1(0)C2/C1Vc2 (3)
  • Solving Eqs 1,2,3 for Vc2
  • d?Vc2/dt?R/LdVc2/dt(C1C2)/LC1C2Vc2

  • -Vc1(0)/LC2
  • s?vc2(s)-sR/LVc2(0)-R/LVc2(0)sR/Lvc2(s)-v(c1C2
    )/LC1C2xVc2(s)-Vc1(0)/sLC2

20
Solution of Q1 ..continued
  • I(0)0?Vc2(0)0,TvLc1c2/(c1c2)
  • vc2(s)
  • -Vc1(0)/LC2 x 1/s(s2Rs/L1/LC)
  • where CC1C2/(C1C2)
  • ?10?fig4.7 Vpeak1.855
  • 1pu-T2.Vc1(0)/LC2
  • -C1/(C1C2)Vc1(0)-2/2.38 x (-51.7)43.48KV
  • Vpeak1.855x43.4880.7 KV

21
Question 2 , C.B. opening resistor
  • C.B. clear 28000 A sym fault
  • R800O, Cbus0.04µF,
  • Vsys138KV,f50Hz
  • 1-Peak of TRV?
  • 2-energy loss in R (it is 2 cycle in)?

22
Q2, Solution
  • X138/(v3x28)2.8455, L9.1 mH
  • Without R, TRV2x138xv(2/3) 225.4KV
  • Z0vL/Cv0.0091/0.04x10-6477O,
    ?800/4771.677
  • fig4.7? 1.38x 225.4/2155.5 KV
  • Energy dissipated in 2 cycles
  • VTRV112.71-exp(-t/2?)x sin.. cos
  • Integrating PlossVTRV?/R over ?t0 to ?t4?
  • for a (1-cosine) wave(1-cosx)?1cos?x-2cosx

23
Q2 continued
  • ?(1-cos?t)? dt
  • 3/2t1/(4?) sin2?t-2/?
    sin?t6?/?
  • t0,4?/?
  • Energy loss if TRV was a 1-cosine wave
  • V?/Rx6?/?112.7?/800x6?/3140.9526MJ

  • (952.6KJs)
  • However (1-cosine) is deformed and assuming
  • to be halved Energy loss952/2476 KJs

24
Question 3
  • 246 KW Load on a 3ph S.G., 13.8 KV
  • p.f.0.6 lag(load parallel RL) C?pf1
  • loadcap switch as a unit
  • S opened, Vpeak across C.B.?
  • Zs negligible

25
Q3, solution
  • V?/R246 KW, R(13.8/v3)?/246/3774O
  • p.f.0.6, F53.13
  • tanF1.333R/X? X580.6O,L1.84 H? Xc580.6
  • C1/(314.15x580.6)5.48µF
  • switch open at Is0, Vs0, when ILIC
  • are at peak (opposite sign)
  • Ipeak13.8v(2/3) /580.619.41 A

26
Q3, solution continued
  • CCT a parallel RLC
  • -cdVc/dtVc/R
  • 1/L?VcdtIL(0)
  • d?Vc/dt1/RCdVc/dt 1/LC 0
  • s?s/RC1/LCvc(s)(s1/RC)Vc(0)Vc(0)

27
Q3 continued
  • Vc(0)-Vc(0)/RC-IL(0)/C, Vc(0)0
  • ? vc(s)-IL(0)/cs2s/RC1/LC
  • without R ?-IL(0)/c x 1/(s2?02)
  • and Vc(t)-IL(0)/C?0 sin?0t
  • -IL(0) vL/C sin?0t
  • vL/Cv1.84/5.48579.5O,
  • IL(0)19.41 A? Vpeak11.27KV
  • ?R/Z01.333? fig 4.4 0.6x11.276.76KV

28
Transformer Magnetizing current
  • Mag. Inrush ? transient
  • Im0.5 to 2 rated, non-sinusoidal
  • Distortion B in core
  • Instant of energizing Residual Flux can
    cause Inrush
  • Continue several sec, small Transf.
  • several min, large Transf.
  • 1000KVA, 13.8KV load 42 A, Inrush peak 150 A
  • A DC declines and finaly mag. current

29
Ferroresonance
  • series Resonance
  • Very H.V. across CL (series LC)
  • if excited Natural Freq.

30
Example of Transformer Ferroresonance
  • simulate nonlinearity of core
  • LdF/dtA exp(-I/B)I0, LA IB, LA/e
  • A 13.8 KV step down T. resonance
  • with cables in primary CCT, A8H,B1.76 or
    LdF/dt8exp(-I/1.76)
  • if 60Hz res. Occur in L4H,
  • C1/??L1.75µF
  • neglecting resistance
  • L dI/dt1/C?I dtV sin(?tF)
  • 8 exp(I/1.76) dI/dt
  • 106/1.75?I dt13.8v2/3 sin(377tF)
  • A nonlinear Diff. Eq. solved for I and then V,
    F0,45
Write a Comment
User Comments (0)
About PowerShow.com