Abstract
This paper reports a new and simple method of supplying and controlling electrical energy from a hydro-powered multiphase, i.e., six-phase induction generator (SPIG) under different operating conditions. This proposed generating system is capable to supply AC and DC power simultaneously with the help of two different closed-loop control units, first one is known as PWM-based rectifier and second one as IGBT-based inverter. The entire six-phase generated power by the SPIG is converted into three-phase power by a transformer. Then this converted three-phase power is fed to the rectifier unit, and DC power is generated. This DC power is not only supplied to DC load but also is given as input power to IGBT-based inverter unit. The AC side control unit generates a constant frequency AC power. It is then supplied to AC load. The mathematical modeling and control strategy of this proposed system have been implemented with the help of MATLAB/Simulink software and found that the satisfactory performance is obtained for various operating conditions.
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Appendix
Appendix
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Stator resistances (R1 = R2 = 4.12 Ω), Stator leakage inductances (L1 and L2 = 0.0256H),
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Rotor resistance (Rr = 8.79 Ω), Rotor leakage inductance (Lr = 0.043H),
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Mutual inductance between two set of stator (Llm = 0.0736H), Moment of inertia (J = 0.033 kg m2).
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Ghosh, S., Mahato, S.N. (2021). Modeling and Control Topology of Multiphase Induction Generator for Supplying AC and DC Power Simultaneously. In: Mohapatro, S., Kimball, J. (eds) Proceedings of Symposium on Power Electronic and Renewable Energy Systems Control. Lecture Notes in Electrical Engineering, vol 616. Springer, Singapore. https://doi.org/10.1007/978-981-16-1978-6_29
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DOI: https://doi.org/10.1007/978-981-16-1978-6_29
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