1. Lesson 8 Symmetrical Components
Notes on Power System Analysis

2. Symmetrical Components
Due to C. L. Fortescue (1918): a set of n unbalanced phasors in an n-phase system can be resolved into n balanced phasors by a linear transformation
The n sets are called symmetrical components
One of the n sets is a single-phase set and the others are n-phase balanced sets
Here n = 3 which gives the following case:
8 Symmetrical Components
Notes on Power System Analysis

3. Symmetrical component definition
Three-phase voltages Va, Vb, and Vc (not necessarily balanced, with phase sequence a-b-c) can be resolved into three sets of sequence components:
Zero sequence Va0=Vb0=Vc0
Positive sequence Va1, Vb1, Vc1 balanced with phase sequence a-b-c
Negative sequence Va2, Vb2, Vc2 balanced with phase sequence c-b-a
8 Symmetrical Components
Notes on Power System Analysis

4. Notes on Power System Analysis
8 Symmetrical Components
Notes on Power System Analysis

5. Notes on Power System AnalysisVa = 1 V0 Vb a2 a V1 Vc V2
where
a = 1/120° = (-1 + j 3)/2
a2 = 1/240° = 1/-120°
a3 = 1/360° = 1/0 °
8 Symmetrical Components
Notes on Power System Analysis

6. Notes on Power System Analysis1 a2 a
Vs = V0 V1 V2
Vp = Va Vb Vc
Vp = A Vs Vs = A-1 Vp
8 Symmetrical Components
Notes on Power System Analysis

7. Notes on Power System Analysis
(1/3) 1 a a2
We used voltages for example, but the result applies to current or any other phasor quantity
Vp = A Vs Vs = A-1 Vp
Ip = A Is Is = A-1 Ip
8 Symmetrical Components
Notes on Power System Analysis

8. Notes on Power System Analysis
Va = V0 + V1 + V2
Vb = V0 + a2V1 + aV2
Vc = V0 + aV1 + a2V2
V0 = (Va + Vb + Vc)/3
V1 = (Va + aVb + a2Vc)/3
V2 = (Va + a2Vb + aVc)/3
These are the phase a symmetrical (or sequence) components. The other phases follow since the sequences are balanced.
8 Symmetrical Components
Notes on Power System Analysis

9. Notes on Power System Analysis
Sequence networks
A balanced Y-connected load has
three impedances Zy connected line to neutral
and one impedance Zn connected neutral to ground Zy g c b a Zn
8 Symmetrical Components
Notes on Power System Analysis

10. Notes on Power System Analysis
Sequence networks
Vag =
Zy+Zn Zn Ia
Vbg Ib
Vcg Ic
or in more compact notation Vp = Zp Ip
8 Symmetrical Components
Notes on Power System Analysis

11. Notes on Power System AnalysisZy
Vp = Zp Ip
Vp = AVs = Zp Ip = ZpAIs
AVs = ZpAIs
Vs = (A-1ZpA) Is
Vs = Zs Is where
Zs = A-1ZpA Zy g c b a Zn n
8 Symmetrical Components
Notes on Power System Analysis

12. Notes on Power System AnalysisZs =
Zy+3Zn Zy
V0 = (Zy + 3Zn) I0 = Z0 I0
V1 = Zy I1 = Z1 I1
V2 = Zy I2 = Z2 I2
8 Symmetrical Components
Notes on Power System Analysis

13. Notes on Power System AnalysisZy n a V2 I2
Negative-
sequence
network Zy n g a
3 Zn V0 I0
Zero-
sequence
network Zy n a V1 I1
Positive-
sequence
network
Sequence networks for Y-connected load impedances
8 Symmetrical Components
Notes on Power System Analysis

14. Notes on Power System Analysis
ZD/3 n a V2 I2
Negative-
sequence
network
ZD/3 n g a V0 I0
Zero-
sequence
network
ZD/3 n a V1 I1
Positive-
sequence
network
Sequence networks for D-connected load impedances.
Note that these are equivalent Y circuits.
8 Symmetrical Components
Notes on Power System Analysis

15. Notes on Power System Analysis
Remarks
Positive-sequence impedance is equal to negative-sequence impedance for symmetrical impedance loads and lines
Rotating machines can have different positive and negative sequence impedances
Zero-sequence impedance is usually different than the other two sequence impedances
Zero-sequence current can circulate in a delta but the line current (at the terminals of the delta) is zero in that sequence
8 Symmetrical Components
Notes on Power System Analysis

16. Notes on Power System Analysis
General case unsymmetrical impedances Zp =
Zaa
Zab
Zca
Zbb
Zbc
Zcc
Zs=A-1ZpA = Z0
Z01
Z02
Z10 Z1
Z12
Z20
Z21 Z2
8 Symmetrical Components
Notes on Power System Analysis

17. Notes on Power System Analysis
Z0 = (Zaa+Zbb+Zcc+2Zab+2Zbc+2Zca)/3
Z1 = Z2 = (Zaa+Zbb +Zcc–Zab–Zbc–Zca)/3
Z01 = Z20 = (Zaa+a2Zbb+aZcc–aZab–Zbc–a2Zca)/3
Z02 = Z10 = (Zaa+aZbb+a2Zcc–a2Zab–Zbc–aZca)/3
Z12 = (Zaa+a2Zbb+aZcc+2aZab+2Zbc+2a2Zca)/3
Z21 = (Zaa+aZbb+a2Zcc+2a2Zab+2Zbc+2aZca)/3
8 Symmetrical Components
Notes on Power System Analysis

18. Notes on Power System Analysis
Special case symmetrical impedances Zp =
Zaa
Zab Zs = Z0 Z1 Z2
8 Symmetrical Components
Notes on Power System Analysis

19. Notes on Power System Analysis
Z0 = Zaa + 2Zab
Z1 = Z2 = Zaa – Zab
Z01=Z20=Z02=Z10=Z12=Z21= 0
Vp = Zp Ip Vs = Zs Is
This applies to impedance loads and to series impedances (the voltage is the drop across the series impedances)
8 Symmetrical Components
Notes on Power System Analysis

20. Power in sequence networks
Sp = Vag Ia* + Vbg Ib* + Vcg Ic*
Sp = [Vag Vbg Vcg] [Ia* Ib* Ic*]T
Sp = VpT Ip*
= (AVs)T (AIs)*
= VsT ATA* Is*
8 Symmetrical Components
Notes on Power System Analysis

21. Power in sequence networks
Sp = VpT Ip* = VsT ATA* Is*
ATA* = 1 = 3 a2 a
Sp = 3 VsT Is*
8 Symmetrical Components
Notes on Power System Analysis

22. Notes on Power System Analysis
Sp = 3 (V0 I0* + V1 I1* +V2 I2*) = 3 Ss
In words, the sum of the power calculated in the three sequence networks must be multiplied by 3 to obtain the total power.
This is an artifact of the constants in the transformation. Some authors divide A by 3 to produce a power-invariant transformation. Most of the industry uses the form that we do.
8 Symmetrical Components
Notes on Power System Analysis

23. Sequence networks for power apparatus
Slides that follow show sequence networks for generators, loads, and transformers
Pay attention to zero-sequence networks, as all three phase currents are equal in magnitude and phase angle
8 Symmetrical Components
Notes on Power System Analysis

24. Notes on Power System AnalysisV1 I1
Positive Z1 N V2 I2
Negative Zn Z2 G
Y generator V0
3Zn
Zero I0 Z0 N
8 Symmetrical Components
Notes on Power System Analysis

25. Notes on Power System AnalysisV1 I1
Positive Z N V2 I2
Negative
Ungrounded Y load Z G V0
Zero I0 Z N
8 Symmetrical Components
Notes on Power System Analysis

26. Notes on Power System Analysis
Zero-sequence networks for loads G V0
3Zn
Y-connected load grounded through Zn I0 Z N G
D-connected load ungrounded V0 Z
8 Symmetrical Components
Notes on Power System Analysis

27. Notes on Power System Analysis
Y-Y transformer H1 X1 A a
Zeq+3(ZN+Zn) A a B
VA0 I0
Va0 b g c C
Zero-sequence
network (per unit) N n ZN Zn
8 Symmetrical Components
Notes on Power System Analysis

28. Notes on Power System Analysis
Y-Y transformer
Zeq H1 X1 A a A a
VA1 I1
Va1 B b n c C
Positive-sequence
network (per unit)
Negative sequence
is same network N n ZN Zn
8 Symmetrical Components
Notes on Power System Analysis

29. Notes on Power System Analysis
D-Y transformer H1 X1 A a
Zeq+3Zn A a B
VA0 I0
Va0 b g c C
Zero-sequence
network (per unit) n Zn
8 Symmetrical Components
Notes on Power System Analysis

30. Notes on Power System Analysis
D-Y transformer H1 X1 A a
Zeq A a B
VA1 I1
Va1 b n c C
Positive-sequence
network (per unit)
Delta side leads wye
side by 30 degrees n Zn
8 Symmetrical Components
Notes on Power System Analysis

31. Notes on Power System Analysis
D-Y transformer H1 X1 A a
Zeq A a B
VA2 I2
Va2 b n c C
Negative-sequence
network (per unit)
Delta side lags wye
side by 30 degrees n Zn
8 Symmetrical Components
Notes on Power System Analysis

32. Three-winding (three-phase) transformers Y-Y-D
H and X in grounded Y and T in delta
Zero sequence
Positive and negative
Ground
Neutral ZT X H ZH H ZH ZX ZX X ZT T T
8 Symmetrical Components
Notes on Power System Analysis

33. Notes on Power System Analysis
Three-winding transformer data:
Windings Z Base MVA
H-X 5.39% 150
H-T 6.44% 56.6
X-T 4.00% 56.6
Convert all Z's to the system base of 100 MVA:
Zhx = 5.39% (100/150) = 3.59%
ZhT = 6.44% (100/56.6) = 11.38%
ZxT = 4.00% (100/56.6) = 7.07%
8 Symmetrical Components
Notes on Power System Analysis

34. Notes on Power System Analysis
Calculate the equivalent circuit parameters:
Solving:
ZHX = ZH + ZX
ZHT = ZH + ZT
ZXT = ZX +ZT
Gives:
ZH = (ZHX + ZHT - ZXT)/2 = 3.95%
ZX = (ZHX + ZXT - ZHT)/2 = %
ZT = (ZHT + ZXT - ZHX)/2 = 7.43%
8 Symmetrical Components
Notes on Power System Analysis

35. Typical relative sizes of sequence impedance values
Balanced three-phase lines:
Z0 > Z1 = Z2
Balanced three-phase transformers (usually):
Z1 = Z2 = Z0
Rotating machines: Z1  Z2 > Z0
8 Symmetrical Components
Notes on Power System Analysis

36. Unbalanced Short Circuits
Procedure:
Set up all three sequence networks
Interconnect networks at point of the fault to simulate a short circuit
Calculate the sequence I and V
Transform to ABC currents and voltages
8 Symmetrical Components
Notes on Power System Analysis