Fault Analysis of IEEE 14 (2)

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Load flow analysis has always been used in determining the steady-state operation of an electric power or distribution system. For conventional power system without wind turbine generator, the method for load flow analysis has been well established. However, for modern system embedded with wind turbine generator, the investigation of analysis method is still an active research area. This paper proposed a new method to integrate fixed-speed wind turbine generator into distribution system load flow analysis. The proposed method is derived based on two-port network theory where the parameters of induction generator of the wind turbine generator are embedded in general constants of the two-port network. The proposed method has been tested and verified using a representative electric distribution system.

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Fault Analysis of IEEE 14 (2)

1. © 2015 YOGESH KUMAR SOME RIGHTS RESERVED Yogesh Kumar, NE2042/Computer Aided Design and Simulation Lab Electrical Engineering and Computer Science Department University of Toledo Fault Analysis of IEEE 14-Bus System with Three Phase Faults G-1 G-2 C C C Bus-1 Bus-2 Bus-3 Bus-4 Bus-8 Bus-9 Bus-6 Bus-5 Bus-7 Bus-10 Bus-11 Bus-12 Bus-13 Bus-14 Fault at bus 2 Fig. 1: IEEE 14-bus system with three phase faults at bus 2. Fig. 2: Bus voltages at each bus when faults occurred at different buses. The voltages are obtained from PowerWorld for three phase faults occurred at from bus 1 to bus 14 independently. The values are for phase A, because of balanced fault, the value of voltages is same for all three phases. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1 Faulted Bus Number BusVoltage(p.u) Bus-1 Bus-2 Bus-3 Bus-4 Bus-5 Bus-6 Bus-7 Bus-8 Bus-9 Bus-10 Bus-11 Bus-12 Bus-13 Bus-14

Fault Analysis of IEEE 14 (2)

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