Consider the single-Line diagram of a power system shown in Figure 3.42 with equipment ratings given: Generator G 1 : 50 MVA, 13 .2 kV , x = 0.15 p .u . Generator G 2 : 20 MVA, 13 .8 kV , x = 0.15 p .u . Three-phase Δ-Y transformer T 1 : 80 MVA, 13 .2 Δ /165YkV , X = 0.1 p .u . Three-phase Y-Δ transformer T 2 : 40 MVA, 165 Y/13 .8 Δ kV , X = 0.1 p .u . Load: 40 MVA, 0.8 PF lagging, operating at 150 kV Choose a base of 100 MVA for the system and 132-kV base in the transmission-line circuit. Let the load be modeled as a parallel combination of resistance and inductance. Neglect transformer phase shifts. Draw a per-phase equivalent circuit of the system showing all impedances in per unit.
Consider the single-Line diagram of a power system shown in Figure 3.42 with equipment ratings given: Generator G 1 : 50 MVA, 13 .2 kV , x = 0.15 p .u . Generator G 2 : 20 MVA, 13 .8 kV , x = 0.15 p .u . Three-phase Δ-Y transformer T 1 : 80 MVA, 13 .2 Δ /165YkV , X = 0.1 p .u . Three-phase Y-Δ transformer T 2 : 40 MVA, 165 Y/13 .8 Δ kV , X = 0.1 p .u . Load: 40 MVA, 0.8 PF lagging, operating at 150 kV Choose a base of 100 MVA for the system and 132-kV base in the transmission-line circuit. Let the load be modeled as a parallel combination of resistance and inductance. Neglect transformer phase shifts. Draw a per-phase equivalent circuit of the system showing all impedances in per unit.
Solution Summary: The author calculates the base voltage for the generator 1 and transformer 1 circuit.
Consider the single-Line diagram of a power system shown in Figure 3.42 with equipment ratings given:
Generator
G
1
:
50
MVA,
13
.2
kV
,
x
=
0.15
p
.u
.
Generator
G
2
:
20
MVA,
13
.8
kV
,
x
=
0.15
p
.u
.
Three-phase
Δ-Y
transformer
T
1
:
80
MVA,
13
.2
Δ
/165YkV
,
X
=
0.1
p
.u
.
Three-phase
Y-Δ
transformer
T
2
:
40
MVA,
165
Y/13
.8
Δ
kV
,
X
=
0.1
p
.u
.
Load:
40
MVA,
0.8
PF
lagging,
operating
at
150
kV
Choose a base of 100 MVA for the system and 132-kV base in the transmission-line circuit. Let the load be modeled as a parallel combination of resistance and inductance. Neglect transformer phase shifts. Draw a per-phase equivalent circuit of the system showing all impedances in per unit.
SA
[(a) 5 V (b) 5 V]
13. Find the voltage V in the network shown in Fig. 2.44 (a) if R is 10 2 and (b) 20 2
14. In the network of Fig. 2.44 (b), calculate the voltage between points a and b i.e. Vab
[30 V] (Elect. Engg. I, Bombay Univ.)
4A
78A
4
h
10A
ww
3A
(a)
ΤΑ
6A
DC Network Theorems
SA
Is
1A
77
12A
www
12
6A
8A
Fig. 2.44
(b)
[Hint: In the above two cases, the two closed loops are independent and no current passes between them].
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