Sage Journals: Discover world-class research

Abstract

Addressing prevalent issues such as substantial size and inadequate precision in the air gap adjustment mechanisms of adjustable-speed magnetic couplers, this study introduces an innovative controllable electromagnetic hybrid magnetic coupler. This coupler utilizes electromagnetic gap adjustment for precise, non-contact speed regulation. A comprehensive electro-magnetic-thermal-stress coupling model is established, grounded on the principles of electromagnetic induction and heat transfer under variable air gaps. Numerical simulations are conducted, assessing temperature and stress variations under different scenarios involving permanent magnet width, air gap length, winding slot depth, and coil turn count. The optimal parameters of the core device-electromagnetic gap adjuster are obtained by orthogonal experimental method, and the results show that when the width of the permanent magnet is 5 mm, the length of the air gap is 1.5 mm, the depth of the winding slot is 10 mm, and the number of turns of the coil is 14, the mechanism has the lowest steady-state field temperature rise of 23.689 °C. This research lays a foundational basis for advanced mastery of controllable electromagnetic hybrid variable air-gap transmission technology.

Keywords

magnetic coupler electromagnetic gap adjustment eddy current losses temperature rise characteristics thermal stress

Get full access to this article

View all access options for this article.

References

Meng

Zhu

Sun

. 3-D analysis for the torque of permanent magnet coupler. IEEE Trans. Magn. 2014; 51: 1–8.

Florio

Sinha

Sundararaman

. Designing high-accuracy permanent magnets for low-power magnetic resonance imaging. IEEE Trans. Magn. 2018; 54: 1–9.

Kang

Choi

. Parametric analysis and experimental testing of radial flux type synchronous permanent magnet coupling based on analytical torque calculations. J Electr Eng Technol 2014; 9: 926–931.

Lubin

Mezani

Rezzoug

. Simple analytical expressions for the force and torque of axial magnetic couplings. IEEE Trans Energy Convers 2012; 27: 536–546.

Yan

Yuan

Jia

, et al. Mechanical characteristics and tests of cage type asynchronous magnetic couplers. Trans. Chin. Soc. Agric. Eng. 2016; 32: 68–74.

Kim

Choi

. Parametric analysis of tubular-type linear magnetic couplings with halbach array magnetized permanent magnet by using analytical force calculation. J. Magn. 2016; 21: 110–114.

Tsai

Chiou

Wang

, et al. Characteristics measurement of electric motors by contactless eddy-current magnetic coupler. IEEE Trans. Magn. 2014; 50: 1–4.

Wang

Guo

Wang

, et al. Design and experimental study of composite magnetic coupler. J. XI'AN Jiaotong Univers. 2017; 51: 115–123.

Högberg

Jensen

Bendixen

. Design and demonstration of a test-rig for static per formance-studies of permanent magnet couplings. IEEE Trans. Magn. 2013; 49: 5664–5670.

10.

Chen

Liu

. Temperature stability of magnetic field for periodic permanent-magnet focusing system. Rare Metals 2014; 33: 180–184.

11.

Qian

Yan

Wang

, et al. Effect of thermal barrier coatings and integrated cooling on the conjugate heat transfer and thermal stress distribution of nickel-based superalloy turbine vanes. Energy 2023; 277: 127774.

12.

Wang

, et al. Fracture analysis of superconducting composites with a sandwich structure based on electromagnetic–thermal coupled mode. Acta Mechanica 2019; 230: 4435–4451.

13.

Cheng

Liu

Luo

, et al. Semi-analytical model for temperature estimation of permanent magnet couplers. IEEE Trans Energy Convers 2020; 36: 2068–2078.

14.

Marignetti

Colli

. Thermal analysis of an axial flux permanent-magnet synchronous machine. IEEE Trans. Magn. 2009; 45: 2970–2975.

15.

Guo

Fang

Wang

, et al. Temperature field study of permanent magnets in adjustable-speed disk magnetic couplers. J. Mine Autom. 2017; 43: 61–66.

16.

Fan

Xie

. Thermal characteristics analysis of a new compound electromagnetic linear actuator based on multi-physical coupling method. Sens. Actuators A: Phys. 2024; 365: 114851.

17.

Zhou

Liu

, et al. Magnetic coupler speed control mechanism study. J. Dalian Jiaotong Univers. 2014; 35: 32–36.

18.

Wang

. Design and Simulation Analysis of Magnetic Coupler Based on Screw Differential Mechanism for Speed Regulation, Masters Dissertation. Dalian, China: Dalian Jiaotong University, 2021.

19.

Cheng

Zhai

Zhang

, et al. Self-learning nonlinear PID-based precision positioning system for voice coil motor. Trans. China Electrotech Soc 2023; 38: 1519–1530.

20.

Debruyne

Polikarpova

Derammelaer

, et al. Evaluation of the efficiency of line-start permanent-magnet machines as a function of the operating temperature. IEEE Trans. Ind. Electron. 2013; 61: 4443–4454.

21.

Jia

Liu

Nie

, et al. Temperature field analysis of back-to-back Ω stator transverse flux permanent magnet linear motor. J. Nanjing Univers. Inf. Sci. Technol. 2025; 17: 117–124.

22.

Shin

Watanabe

Koseki

, et al. Transverse-Flux-Type cylindrical linear syn-chronous motor using generic armature cores for rotary machinery. IEEE Trans. Ind. Electron. 2014; 61: 4346–4355.

23.

Chang

. Design and multi-objective optimization of cylindrical permanent magnet linear synchronous motor, Masters Dissertation. Jilin, China: Jilin University, 2023.

24.

Yan

Mao

, et al. Magneto-Thermal bidirectional coupling of tubular permanent magnet linear motor. Journal of Wuhan Inst. Technol. 2022; 44: 551–555+590.

Controllable electromagnetic hybrid magnetic coupler: An electro-magnetic-thermal-stress coupling model and numerical simulation study

Abstract

Keywords

Get full access to this article

References