Multiphysics Design of a Wound Field Synchronous Machine with Magnetic Asymmetry

Dominik Grauvogl, Peter Stauder, B. Hopfensperger, D. Gerling
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引用次数: 1

Abstract

In this paper a multiphysics development method is used for designing a novel wound field synchronous machine of the future generation of high voltage traction drives. This method covers the domains of electromagnetics, the mechanical strength, thermal behavior and the magnetic noise. It is shown that the proposed novel asymmetric design with a circular flux barrier in combination with an asymmetric pole offset is fulfilling the requirements according to performance and torque ripple. A fatigue strength rotor mechanic concept is included. A hybrid cooling concept consisting of a water jacket cooled stator and air cooled rotor ensures the needed continuous power. Unacceptable noise levels are excluded by investigating the equivalent radiated power (ERP) level due to radial forces in the air gap. Finally, the multi-physical workflow resulted in a fully developed component with a high degree of maturity.
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磁不对称绕线场同步电机的多物理场设计
本文采用多物理场开发方法设计了一种新型的新一代高压牵引传动绕线场同步电机。该方法涵盖了电磁学、机械强度、热性能和磁噪声等领域。结果表明,采用圆形磁通屏障和非对称极差相结合的新型非对称设计能够满足性能和转矩脉动的要求。引入了疲劳强度转子力学概念。由水套冷却定子和风冷转子组成的混合冷却概念确保了所需的连续动力。通过调查气隙中径向力引起的等效辐射功率(ERP)水平,排除了不可接受的噪声水平。最后,多物理工作流程产生了一个高度成熟的完全开发的组件。
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