
handle: 11424/293398
The purpose of this study is to optimize the package geometry in wheel motors for an electric vehicle. In this context, it is aimed to analyze and design in-wheel asynchronous motor with a conical geometry for an electric vehicle. Thus, an asynchronous motor with a conical geometry and in-wheel asynchronous motor with a radial flux have been evaluated by comparing performance against each other within the package boundaries. An asynchronous motor design for the required performance requirements was realized by using the Ansys RMXprt program. The package analysis for the designed asynchronous motor was performed and the minimum and maximum package sizes for in-wheel asynchronous motor. The motor with conical geometry which is designed as a tapered geometry in 3D according to the minimum and maximum dimensions. In the Ansys Maxwell program, these 3 type motors were analyzed in terms of the rated torque, the rated revolution, the starting torque, the breakdown torque, the power factor, the efficiency and the magnetic flux on the rotor and the stator. It has been seen that every motor has advantages and disadvantages in the study. In this context, an asynchronous motor with a conical geometry may provide optimization for the desired properties.
Thepurpose of this study is to optimize the package geometry in wheel motors foran electric vehicle. In this context, it is aimed to analyze and designin-wheel asynchronous motor with a conical geometry for an electric vehicle.Thus, an asynchronous motor with a conical geometry and in-wheel asynchronousmotor with a radial flux have been evaluated by comparing performance againsteach other within the package boundaries. An asynchronous motor design for therequired performance requirements was realized by using the Ansys RMXprtprogram. The package analysis for the designed asynchronous motor was performedand the minimum and maximum package sizes for in-wheel asynchronous motor. Themotor with conical geometry which is designed as a tapered geometry in 3Daccording to the minimum and maximum dimensions. In the Ansys Maxwell program, these3 type motors were analyzed in terms of the rated torque, the rated revolution,the starting torque, the breakdown torque, the power factor, the efficiency andthe magnetic flux on the rotor and the stator. It has been seen that everymotor has advantages and disadvantages in the study. In this context, anasynchronous motor with a conical geometry may provide optimization for thedesired properties.
electrical machines, Conical Motor;Finite Element Method;Electrical machines;Asynchronous motor;In-wheel motor, QH301-705.5, Chemical technology, finite element method, asynchronous motor, TP1-1185, in-wheel motor, In-wheel motor, Asynchronous motor, Finite Element Method, Electrical machines, Conical Motor, Biology (General), conical motor
electrical machines, Conical Motor;Finite Element Method;Electrical machines;Asynchronous motor;In-wheel motor, QH301-705.5, Chemical technology, finite element method, asynchronous motor, TP1-1185, in-wheel motor, In-wheel motor, Asynchronous motor, Finite Element Method, Electrical machines, Conical Motor, Biology (General), conical motor
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