Development of low‐torque‐ripple motor with high rotational speed to downsize electrical systems-Reference-Cited by-同舟云学术

Development of low‐torque‐ripple motor with high rotational speed to downsize electrical systems

Published:2024-05-25 Issue:2 Volume:217 Page:
ISSN:0424-7760
Container-title:Electrical Engineering in Japan
language:en
Short-container-title:Electrical Engineering Japan

Author:

Hori Masahiro¹,Sawahata Masanori¹,Hara Takafumi¹,Nagata Minori¹

Affiliation:

1. Research & Development Group Hitachi Ibaraki Japan

Abstract

AbstractElectrification is progressing across different fields such as automobiles and construction machinery. Motors for electric systems are required to be compact and achieve high power density. In this study, we developed a small motor with rotation speed of 22,000 r/min by reducing stress concentration. Each pole has three magnets in the circumferential direction, and the magnets are arranged in a U‐shape. The magnet insert slots are comprised of expanded flux barriers on the inner diameter side and a guide‐less structure. The magnet slots reduce stress concentration. Additionally, the rotor has two dents on the outer diameter surface and expanded flux barriers on the outer diameter side. The dents have different shapes between the North (N) and South (S) poles. The structures reduce the torque ripple.

Publisher

Wiley

Link

https://onlinelibrary.wiley.com/doi/pdf/10.1002/eej.23470

Reference11 articles.

1. AikiK DeimlM ErikssonT SchneckM JafarianP Development of High Speed Electric Drive Unit. 2022 JSAE Congress (Spring) Publication code 20195157 Pacifico Yokohama Conference Center Japan 25‐27 May 2022.Society of Automotive Engineers of Japan;2019.

2. AzusawaK KajinoD MatsuuraH Development of Low Loss Motor for Small Hybrid System. 2020 JSAE Annual Congress (Autumn) Publication code 20206063;2020.

3. Design Method of a Rotor Structure with Notch for Reducing the Cogging Torque of a Double-Layered IPMSM

4. YamazakiK OhiwaH UtsunomiyaK Studies on rotor shape optimization of interior permanent magnet synchronous motors based on mechanism of torque ripple generation by time and space harmonic air gap flux densities.Joint Technical Meeting on Motor Drive/Rotating Machinery/Vehicle Technology. MD‐20‐069.2020.

5. Magnetic Field Analysis by the Edge Element FEM