Here is a power system, help me with please, I really need it In the system shown below, the generator is ideal (Xs 0) and the magnitude of theload bus voltage, VL is to be held at 110 kV. Working on a system base of 100 MVAand a base voltage of 115 kV in the load circuit:draw the single-phase equivalent pu reactance diagram, anda)b)determine the necessary generator terminal voltage Vg (kV).Transformer 1200 MVA25 kV : 600 kVX = 5%Transformer 2150 MVA500 kV: 115 kVX = 6%LineX 60 2LoadS 120 MVApf = 0.85 lagVGVT1VT2VL

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In the system shown below, the generator is ideal (Xs = 0) and the magnitude of the load bus voltage, V is to be held at 110 kV. Working on a system base of 100 MVA and a base voltage of 115 kV in the load circuit: %3D a) draw the single-phase equivalent pu reactance diagram, and b) determine the necessary generator terminal voltage VG (kV). Transformer 1 200 MVA 25 kV: 600 kV X = 5% Transformer 2 150 MVA 500 kV: 115 kV X 6% Line X 60 Load S = 120 MVA pf = 0.85 lag VG VT1 VT2 VL

In the system shown below, the generator is ideal (Xs = 0) and the magnitude of the load bus voltage, V is to be held at 110 kV. Working on a system base of 100 MVA and a base voltage of 115 kV in the load circuit: %3D a) draw the single-phase equivalent pu reactance diagram, and b) determine the necessary generator terminal voltage VG (kV). Transformer 1 200 MVA 25 kV: 600 kV X = 5% Transformer 2 150 MVA 500 kV: 115 kV X 6% Line X 60 Load S = 120 MVA pf = 0.85 lag VG VT1 VT2 VL

Power System Analysis and Design (MindTap Course List)

6th Edition

ISBN:9781305632134

Author:J. Duncan Glover, Thomas Overbye, Mulukutla S. Sarma

Publisher:J. Duncan Glover, Thomas Overbye, Mulukutla S. Sarma

Chapter7: Symmetrical Faults

Section: Chapter Questions

Problem 7.14P: Equipment ratings for the five-bus power system shown in Figure 7.15 are as follows: Generator G1:Â...

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