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2020 | OriginalPaper | Chapter

Performance of Dual-Input Storage Based Induction Motor Drive for Electric and Fuel Cell Hybrid Electrical Vehicle Applications

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Abstract

This paper presents the design and control of a two-input bi-directional DC-DC converter (BDC) and implements it for driving a Fuel-cell based three-phase induction motor drive. The Fuel-cell hybrid electric vehicle (FC-HEV) powertrain mainly consists of dc-source, DC-DC converter, inverter, and a driving motor. Usually the single source is used for powering electric vehicles (EVs). However, due to a single source the range of EVs is limited. In this study, two separate dc sources (battery and fuel-cell) are hybridized using a multiport BDC. This BDC is utilized to power FC-HEV drivetrain. The FC-HEVs have to operate in powering mode and braking mode, the performance of induction motor drive in forward powering mode and regenerative braking mode has been discussed. Moreover, for controlling purpose the v/f control is implemented to enhance the performance of EV drive and the simulation results have been obtained in MATLAB environment.
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Metadata
Title
Performance of Dual-Input Storage Based Induction Motor Drive for Electric and Fuel Cell Hybrid Electrical Vehicle Applications
Authors
Narayan Yadav
Sushma Gupta
Tripta Thakur
Copyright Year
2020
DOI
https://doi.org/10.1007/978-3-030-39875-0_18