lecture 21 symmetrical components, unbalanced fault analysis professor tom overbye department of...
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![Page 1: Lecture 21 Symmetrical Components, Unbalanced Fault Analysis Professor Tom Overbye Department of Electrical and Computer Engineering ECE 476 POWER SYSTEM](https://reader030.vdocuments.us/reader030/viewer/2022033020/56649c745503460f94927489/html5/thumbnails/1.jpg)
Lecture 21Symmetrical Components, Unbalanced Fault Analysis
Professor Tom OverbyeDepartment of Electrical and
Computer Engineering
ECE 476
POWER SYSTEM ANALYSIS
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Announcements
Be reading Chapters 9 and 10 HW 8 is due now. HW 9 is 8.4, 8.12, 9.1,9.2 (bus 2), 9.14; due Nov 10 in class Start working on Design Project. Tentatively due Nov 17 in
class Second exam is on Nov 15 in class. Same format as first
exam, except you can bring two note sheets (e.g., the one from the first exam and another)
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Single Line-to-Ground (SLG) Faults
Unbalanced faults unbalance the network, but only at the fault location. This causes a coupling of the sequence networks. How the sequence networks are coupled depends upon the fault type. We’ll derive these relationships for several common faults.
With a SLG fault only one phase has non-zero fault current -- we’ll assume it is phase A.
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SLG Faults, cont’d
?
0
0
fa
fb
fc
I
I
I
0
2 0
2
Then since
1 1 1 ?1 1
1 03 3
01
f
ff f f f a
f
I
I I I I I
I
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SLG Faults, cont’d
0
2
2
0
1 1 1
1
1
This means
The only way these two constraints can be satisified
is by coupling the sequence networks in series
f fa f a
ffa
ffb
fc f
fa f f f
V Z I
VV
V V
V V
V V V V
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SLG Faults, cont’d
With the sequence networks inseries we cansolve for the fault currents(assume Zf=0)
01.05 01.964
(0.1389 0.1456 0.25 3 )
5.8 (of course, 0)
f f ff
ff fs a cb
I j I Ij Z
I j I I
I A I
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Example 9.3
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Line-to-Line (LL) Faults
The second most common fault is line-to-line, which occurs when two of the conductors come in contact with each other. With out loss of generality we'll assume phases b and c.
0
bg
Current Relationships: 0, , 0
Voltage Relationships: V
f f fa c fb
cg
I I I I
V
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LL Faults, cont'd
0
2
2
0
2 2
Using the current relationships we get
1 1 1 01
13
1
0
1 1
3 3
Hence
f
ff b
fbf
f
f ff fb b
f f
I
I I
II
I
I I I I
I I
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LL Faults, con'td
0
2
2
2
2
Using the voltage relationships we get
1 1 11
13
1
Hence
1313
ff ag
ff bg
ff cg
f ff ag bg
f ff ag f fbg
V V
V V
V V
V V V
V V V V V
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LL Faults, cont'd
To satisfy &
the positive and negative sequence networks must
be connected in parallel
f f f fI I V V
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LL Faults, cont'd
2
2
Solving the network for the currents we get
1.05 03.691 90
0.1389 0.1456
1 1 1 0 0
1 3.691 90 6.39
3.691 90 6.391
f
fa
fb
fc
Ij j
I
I
I
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LL Faults, cont'd
2
2
Solving the network for the voltages we get
1.05 0 0.1389 3.691 90 0.537 0
0.1452 3.691 90 0.537 0
1 1 1 0 1.074
1 0.537 0.537
0.537 0.5371
f
f
fa
fb
fc
V j
V j
V
V
V
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Double Line-to-Ground Faults
With a double line-to-ground (DLG) fault two line conductors come in contact both with each other and ground. We'll assume these are phases b and c.
0 ( )f f f f fa cg f cbg bI V V Z I I
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DLG Faults, cont'd
0
2
2
0
From the current relationships we get
1 1 1
1
1
Since 0 0
Note, because of the path to ground the zero
sequence current is no longer
ffa
ffb
fc f
fa f f f
II
I I
I I
I I I I
zero.
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DLG Faults, cont'd
0
2
2
0 2
2 2
0
From the voltage relationships we get
1 1 11
13
1
Since
Then ( )
But since 1 0 1
ff ag
ff bg
ff bg
f fcg f fbg
ff fbg
ff fbg
V V
V V
V V
V V V V
V V V
V V V
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DLG Faults, cont'd
0
0 2
0 2
2
0 0
0 0
( )
Also, since
Adding these together (with -1)
(2 ) with
3
ff fbg
f ff cb
ff f fb
fc f f f
ff f f f f f fbg
f f f f
V V V
Z I I
I I I I
I I I I
V Z I I I I I I
V V Z I
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DLG Faults, cont'd
The three sequence networks are joined as follows
0
1.05 00.1389 0.092( 3 )
4.547 0
ff
VI
j jZ Z Z Z
Assuming Zf=0, then
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DLG Faults, cont'd
0
1.05 4.547 90 0.1389 0.4184
0.4184/ 0.1456 2.874
4.547 2.874 1.673
Converting to phase: 1.04 6.82
1.04 6.82
f
f
f f f
fb
fc
V j
I j j
I I I j j j
I j
I j
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Unbalanced Fault Summary
SLG: Sequence networks are connected in series, parallel to three times the fault impedance
LL: Positive and negative sequence networks are connected in parallel; zero sequence network is not included since there is no path to ground
DLG: Positive, negative and zero sequence networks are connected in parallel, with the zero sequence network including three times the fault impedance
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Generalized System Solution
Assume we know the pre-fault voltages The general procedure is then
1. Calculate Zbus for each sequence
2. For a fault at bus i, the Zii values are the thevenin equivalent impedances; the pre-fault voltage is the positive sequence thevenin voltage
3. Connect and solve the thevenin equivalent sequence networks to determine the fault current
4. Sequence voltages throughout the system are
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Generalized System Solution, cont’d
4. Sequence voltages throughout the system are given by 0
0
0
0
prefaultfIZ
V V
This is solvedfor each sequence network!
5. Phase values are determined from the sequence values
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Unbalanced System Example
For the generators assume Z+ = Z = j0.2; Z0 = j0.05For the transformers assume Z+ = Z =Z0 = j0.05For the lines assume Z+ = Z = j0.1; Z0 = j0.3
Assume unloaded pre-fault, with voltages =1.0 p.u.
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Positive/Negative Sequence Network
24 10 10 0.1397 0.1103 0.125
10 24 10 0.1103 0.1397 0.125
10 10 20 0.1250 0.1250 0.175bus busj j
Y Z
Negative sequence is identical to positive sequence
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Zero Sequence Network
0 0
16.66 3.33 3.33 0.0732 0.0148 0.0440
3.33 26.66 3.33 0.0148 0.0435 0.0.292
3.33 3.33 6.66 0.0440 0.0292 0.1866bus busj j
Y Z
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For a SLG Fault at Bus 3
The sequence networks are created using the pre-faultvoltage for the positive sequence thevenin voltage,and the Zbus diagonals for the thevenin impedances
Positive Seq. Negative Seq. Zero Seq.
The fault type then determines how the networks areinterconnected
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Bus 3 SLG Fault, cont’d
0
1.0 01.863
(0.1750 0.1750 0.1866)
1.863
1.0 0 0 0.7671
1.0 0 0 0.7671
1.0 0 1.863 0.6740
0 0.2329
0 0.2329
1.863 0.3260
f
f f f
bus
bus
I jj
I I I j
j
j
V Z
V Z
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Bus 3 SLG Fault, cont’d
0 0
3
1
0 0.0820
0 0.0544
1.863 0.3479
We can then calculate the phase voltages at any bus
0.3479 0
0.6740 0.522 0.866
0.3260 0.522 0.866
0.0820
0.7671
bus
j
j
j
V Z
V A
V A
0.4522
0.3491 0.866
0.2329 0.3491 0.866
j
j
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Faults on Lines
The previous analysis has assumed that the fault is at a bus. Most faults occur on transmission lines, not at the buses
For analysis these faults are treated by including a dummy bus at the fault location. How the impedance of the transmission line is then split depends upon the fault location
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Line Fault Example
Assume a SLG fault occurs on the previous system on the line from bus 1 to bus 3, one third of the wayfrom bus 1 to bus 3. To solve the system we add adummy bus, bus 4, at the fault location
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Line Fault Example, cont’d
44 10 0 30
10 24 10 0
0 10 25 15
30 0 15 45
Adding the dummy bus only changes the new
row/column entries associated with the dummy bus
0.1397 0.1103 0.1250 0.1348
0.1103 0.1397 0.1250 0.1152
0.125
bus
bus
j
j
Y
Z0 0.1250 0.1750 0.1417
0.1348 0.1152 0.1417 0.1593
The Ybus
now has4 buses
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Power System Protection
Main idea is to remove faults as quickly as possible while leaving as much of the system intact as possible
Fault sequence of events1. Fault occurs somewhere on the system, changing the
system currents and voltages
2. Current transformers (CTs) and potential transformers (PTs) sensors detect the change in currents/voltages
3. Relays use sensor input to determine whether a fault has occurred
4. If fault occurs relays open circuit breakers to isolate fault
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Power System Protection
Protection systems must be designed with both primary protection and backup protection in case primary protection devices fail
In designing power system protection systems there are two main types of systems that need to be considered:
1. Radial: there is a single source of power, so power always flows in a single direction; this is the easiest from a protection point of view
2. Network: power can flow in either direction: protection is much more involved
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Radial Power System Protection
Radial systems are primarily used in the lower voltage distribution systems. Protection actions usually result in loss of customer load, but the outages are usually quite local.
The figure showspotential protectionschemes for a radial system. Thebottom scheme ispreferred since itresults in less lost load
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Radial Power System Protection
In radial power systems the amount of fault current is limited by the fault distance from the power source: faults further done the feeder have less fault current since the current is limited by feeder impedance
Radial power system protection systems usually use inverse-time overcurrent relays.
Coordination of relay current settings is needed toopen the correct breakers
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Inverse Time Overcurrent Relays
Inverse time overcurrent relays respond instan-taneously to a current above their maximum setting
They respond slower to currents below this value but above the pickup current value