Protection Prjoect
PAGE
1
EEE470 PROTECTION PROJECT
1. Problem and Report
2
1
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.013 + j.14
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3
.02 + j.146
.2 + j.44
.03 + j.18
.02 +
j.15
.3 + j.54
.2 + j.45
6
7
4
5
.05 + j.33
.5 + j.99
.03 + j.2
.3 + j.6
.03 + j.18
.02 + j.15
.3 + j.54
.2 + j.45
1
230kV
2
22kV
4
345kV
10
345kV
3
22kV
7
230k
V
8
230kV
5
230kV
9
230kV
Legend:
Where the impedance values shown
are in per unit on
100MVA base and the
appropriate
kV base
Z
1
Z
0
Figure 2. Single line diagram for the 230V and 345 kV system
6
Enclosed as Figure 1 is a diagram of an Arizona looped 230 kV transmission system which is typical of a system serving a large city. There is remote generation whose power is input to the loop over 2 – 345 kV lines. The voltage is transformed from 345 kV to 230 kV by 3-phase transformer banks T3 and T4. Transformer T1 and T2 step the voltage up at the remote generating site. Figure 2 is a single line diagram of the 230 kV and 345 kV systems, including the series impedance. Note that the data is in per unit on a 100 MVA base, 230 kV and 345 kV bases. The generator and transformer data is given in Section 2.
Damp Earth
45
ft
.
10
ft
.
10
ft
.
15
ft
.
Phase Conductors
:
4
/
0
Cu
,
19
Strand
Completely Transposed
.
Ground Conductor
: (
0
.
375
EBB
)
6
.
0
Ohms
/
Mi
,
gmr
=
10
-
9
ft
.
,
O
.
D
.=
3
/
8
in
.
You may ignore the
presence of earth and
overhead ground
conductor
.
The Project is divided into 3 parts as follows:
1.0 Build the above system using PowerWorld
Build a simulation of the above system using PowerWorld.
1.1 Time-Over-Current Relay Scheme for a 69 kV Radial System
Design a coordinated time-over-current relay scheme for the radial 69 kV system shown in Figure 3. This radial system is connected to bus 5 of the system shown in Figures 1 and 2. The 69 kV structure configuration and line data is shown in Figure 4. Assume the zero sequence impedance is three times the positive sequence impedance. For minimum fault current calculations assume that the line from bus 5 and bus 9 is out.
Include:
The necessary short circuit studies.
The breaker ratings for B11-B13.
The CT ratios associated with B11-B13.
The tap and time dial settings for CO-8 relays associated with B11-B13.
The basis for the selections in the form of a report.
5
9
8
7
1
6
10
4
3
2
Gen
1
Gen
2
Gen
6
,
7
Gen
3
,
4
,
5
Figure
1
.
Topology and for a looped
230
kV transmission system
T
1
T
2
T
3
T
4
345
kV
230
kV
15 miles
25 miles
10 miles
D
Y
230
-
69Kv
60MVA, 3 phase
X= 0.1x (where ‘x’ is the last digit of your student ID number.)
Bus 5
230kV
11
12
13
14
B
11
B
12
B
13
8MW
4MVAR
8MW
4MVAR
10MW
5MVAR
Figure 3. Radial
-
system schematic for time
-
overcurrent relay coordination problem
Figure 4. 69kV line layout.
1.2 Distance Relay Protection System
Design a distance (impedance) protection system to protect the 230 kV line between busses 5 and 9 and to provide remote backup protection for line from bus 5 to bus 6. The 230 kV lines have 954 KCM ACSR conductors. You will need both an impedance ground fault relay and an impedance phase relay. Use mho units.
Include:
Circuit breaker selection.
Instrument transformer selection and connections.
Relay selections and settings.
Validation of your settings for all fault types by calculating the apparent impedance at bus 9 from computer studies for faults at bus 5. Revise your initial settings, if required.
The basis for the selections in the form of an engineering report.
Pertinent computer studies.
2. Generator and Transformer Data
Gen. No. MVA kV___ ____x”d=X1=X2__ _____x0______ Connection
1 333 22kV .08 pu .10 pu Note 2
2 “ “ “ “ “
3 210 230kV .14 pu (Note 1) .24 pu (Note 1) Note 3
4 “ “ “ “ “
5 “ “ “ “ “
6 353 “ .34 pu (Note 1) .28 pu (Note 1) “
7 “ “ “ “ “
Notes:
1. This impedance includes the step-up transformer impedance on the generator MVA
bases.
2. Ungrounded wye for generators 1 and 2.
3. Assume generators are connected grounded wye and the generator step-up transformers are connected grounded wye – grounded wye.
Transformers:
Transformers 1 and 2 are 3-phase rated at 350 MVA, 22 kV delta to 345 kV grounded wye, 8% reactance.
Transformers 3 and 4 are 3-phase rated at 400 MVA, 345 kV grounded wye to 230 kV grounded wye, 6% reactance
The template for the report is included in a separate file. Include all the material asked for in the project in the provided template.
� EMBED Visio.Drawing.6 ���
� EMBED Visio.Drawing.6 ���
Damp Earth
45
ft
.
10
ft
.
10
ft
.
15
ft
.
Phase Conductors
:
4
/
0
Cu
,
19
Strand
Completely Transposed
.
Ground Conductor
: (
0
.
375
EBB
)
6
.
0
Ohms
/
Mi
,
gmr
=
10
-
9
ft
.
,
O
.
D
.=
3
/
8
in
.
You may ignore the
presence of earth and
overhead ground
conductor
.
5
9
8
7
1
6
10
4
3
2
Gen
1
Gen
2
Gen
6
,
7
Gen
3
,
4
,
5
Figure
1
.
Topology and for a looped
230
kV transmission system
T
1
T
2
T
3
T
4
345
kV
230
kV
_1322136126.vsd
T1
T2
T3
5
9
8
345 kV
7
230 kV
1
6
10
4
3
2
Gen 1
Gen 2
Gen 6,7
Gen 3,4,5
Figure 1. Topology and for a looped 230kV transmission system
T4
_1322136437.doc
2
1
.013 + j.14
.018 + j.49
.013 + j.14
.018 + j.49
3
.02 + j.146
.2 + j.44
.03 + j.18
.02 + j.15
.3 + j.54
.2 + j.45
6
7
4
5
.05 + j.33
.5 + j.99
.03 + j.2
.3 + j.6
.03 + j.18
.02 + j.15
.3 + j.54
.2 + j.45
1
230kV
2
22kV
4
345kV
10
345kV
3
22kV
7
230kV
8
230kV
5
230kV
9
230kV
Legend:
Where the impedance values shown
are in per unit on
100MVA base and the
appropriate
kV base
Z
1
Z
0
Figure 2. Single line diagram for the 230V and 345 kV system
6
_1065946659.doc
15 miles
25 miles
10 miles
Y
230
- 69Kv
60MVA, 3 phase
X= 0.1x (where ‘x’ is the last digit of your student ID number.)
Bus 5
230kV
11
12
13
14
B
11
B
12
B
13
8MW
4MVAR
8MW
4MVAR
10MW
5MVAR
Figure 3. Radial-system schematic for time-overcurrent relay coordination problem
_1197880986.vsd
Damp Earth
45 ft.
10 ft.
10 ft.
15 ft.
Phase Conductors: 4/0 Cu, 19 Strand Completely Transposed.
Ground Conductor: (0.375 EBB) 6.0 Ohms/Mi, gmr=10-9 ft., O.D.=3/8 in.
You may ignore the presence of earth and overhead ground conductor.