Numerical Study of an AC MHD Generation with Double-side Exciting Winding
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概要
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This paper studies physical phenomena, performance and optimal operating point of an AC MHD generator under the slip value by using a numerical simulation. The double-side exciting winding of the generator is considered. Its structure consists of a channel, an insulator and stators. Channel type is a flat rectangular and the liquid flows along the channel as a conductor. Channel wall acted as an insulator separates metal fluid and stator coils. The top and bottom stator winding of the generator is connected to polyphase system. Under this condition, it can produce a magnetic field by means of time harmonic function in the same direction of the metal fluid. An interaction between traveling wave and metal fluid is explained by finite element method under Maxwells equation and Ohm law. The distribution of magnetic vector potential and magnetic flux density throughout channel is evidently shown in xy-plane. Power flow in AC MHD generator is evaluated by slip value. The optimal operating point of an AC MHD generator performance is reported by active power 0.99kW, reactive power 50kVAR, mechanical power 1.58kW, power dissipation 0.59kW and electrical efficiency 62.5%.
- 社団法人 電気学会の論文
著者
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KIKUCHI Takashi
Nagaoka University of Technology
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SASAKI Toru
Nagaoka University of Technology
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Harada Nobuhiro
Nagaoka Univ. Technol. Nagaoka
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BUTTAPENG Chainarong
University of the Thai Chamber of Commerce
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Intani Pattana
Nagaoka University of Technology
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Harada Nobuhiro
Nagaoka Univ. Of Technol.
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