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Abstract

Maritime wave energy movement is characterized by low operating speed and low frequency, which leads to problems such as large volume and weight, high cost, low power density, and large fluctuations of positioning force in a permanent magnet linear generator. In response to above issues, magnetic gear composite linear generator (MGCLG) for wave energy with single salient pole permanent magnet and integrated magnetic adjusting ring is proposed with high power density and low positioning force fluctuation. The working principle of the MGCLG is analyzed based on the magnetic field modulation principle of magnetic gears and the theory of permanent magnet generators; Then, the finite element method (FEM) is employed to simulate the performance of the MGCLG. Finally, a comparative analysis and verification of the performance between the proposed generator and the traditional generator is performed. It is shown that the amplitude of induced electromotive force in MGCLG has increased by 54.5%, and the fluctuation of positioning force has decreased by 51%. The novel MGCLG can greatly improve the induced electromotive force of the generator, and reduce positioning force fluctuations. The research provides insights for the development of new wave energy linear generator.

Keywords

electromotive force linear generator magnetic adjusting ring MGCLG positioning force single salient

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References

Rabbi

Popp

Máté

, et al. Energy security and energy transition to achieve carbon neutrality. Energies 2022; 15. doi:https://doi.org/10.3390/en15218126

Ahn

Neary

Haas

. Global wave energy resource classification system for regional energy planning and project development. Renewable Sustainable Energy Rev 2022; 162. doi:https://doi.org/10.1016/j.rser.2022.112438

Cai

Huo

Shi

, et al. Numerical and experimental research on a resonance-based wave energy converter. Energy Convers Manage 2022; 269. doi:https://doi.org/10.1016/j.enconman.2022.116152

Zhou

N-P

, et al. Wind wave coupling model for wave energy forecast. IEEE Trans Sustainable Energy 2019; 10: 586–595.

Yang

Yao

Ren

, et al. Design and dynamic simulation of a novel traveling wave linear ultrasonic generator. Micromachines 2022; 13: 14.

Zhang

Luo

Duan

J-A

, et al. Design and analysis of a novel frequency modulation secondary for high-speed permanent magnet linear synchronous generator. IEEE/ASME Trans Mechatron 2022; 27: 790–799.

Jiang

Park

, et al. Analysis method development of hybrid linear generator considering cogging force effect. Actuators 2023; 12: 13.

Xing

Kwon

J-W

, et al. A rotary-linear SPM voice coil generator with PM flux bridges for output performance improvement. IEEE Access 2021; 9: 57054–57063.

Zhao

Zhu

, et al. Improvement of power factor in a double-Side linear flux-modulation permanent-magnet generator for long stroke applications. IEEE Trans Ind Electron 2019; 66: 3391–3400.

10.

Chung

S-U

Kim

J-W

Woo

B-C

, et al. Design and experimental validation of doubly salient permanent magnet linear synchronous generator for precision position control. Mechatronics 2013; 23: 172–181.

11.

Cao

Cheng

, et al. A linear doubly salient permanent-magnet generator with modular and complementary structure. IEEE Trans Magn 2011; 47: 4809–4821.

12.

Cao

Shen

Hua

. Research on detent force characteristics of a linear flux-switching permanent-magnet generator. IEEE Trans Energy Convers 2021; 36: 2998–3006.

13.

Wang

Niu

, et al. A novel magnetic-geared tubular linear machine with halbach permanent-magnet arrays for tidal energy conversion. IEEE Trans Magn 2015; 51. doi:https://doi.org/10.1109/TMAG.2015.2450720

14.

Ghods

Faiz

Bazrafshan

, et al. A mesh design technique for double stator linear PM vernier machine based on equivalent magnetic network modeling. IEEE Trans Energy Convers 2022; 37: 1087–1095.

15.

Rahideh

Ghaffari

Barzegar

, et al. Analytical model of slotless brushless PM linear generators considering different magnetization patterns. IEEE Trans Energy Convers 2018; 33: 1797–1804.

16.

Chau

Cheng

, et al. Design and analysis of linear stator permanent magnet vernier machines. IEEE Trans Magn 2011; 47: 4219–4222.

17.

Zhao

Mou

, et al. Research on torque characteristics of a modular arc-linear flux switching permanent-magnet generator. IEEE Access 2019; 7: 57312–57320.

18.

Liu

Zhang

Niu

. A permanent magnet linear generator with complementary flux and its optimization. IEEE Trans Magn 2019; 55: 5.

19.

Cao

Jiang

, et al. Comparison between linear induction generator and linear flux-switching permanent-magnet generator for railway transportation. IEEE Trans Ind Electron 2019; 66: 9394–9405.

20.

Dong

Huang

, et al. Modeling and optimization of a tubular permanent magnet linear generator using transverse-flux flux-reversal topology. IEEE Trans Ind Appl 2019; 55: 1382–1391.

21.

Jiang

Liang

. Characteristics of a novel moving magnet linear generator for linear compressor. Mech Syst Signal Process 2019; 121: 828–840.

22.

Wang

Yan

. Optimal design of high-speed double-sided linear permanent magnet generators with segmented trapezoidal magnetic Poles. IEEE Access 2021; 9: 78315–78323.

23.

Sun

Lan

. Optimal design of electromagnetic force of hidden—pole magnetic suspension linear generator. IEEE Access 2019; 7: 153675–153682.

24.

Zhao

Mou

Zhu

, et al. Study on a double-sided permanent-magnet linear synchronous generator with reversed slots. IEEE/ASME Trans Mechatron 2021; 26: 3–12.

Performance analysis of magnetic gear composite linear generator with single salient pole permanent magnet and integrated magnetic adjusting ring

Abstract

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