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Abstract

To address the issue of active suspensions requiring additional energy sources and the low vibration energy recovery efficiency of semi-active suspensions, this paper proposes a new electromagnetic linear power-feeding semi-active suspension and verifies its energy recovery efficiency. The study is carried out from four aspects: theoretical research, simulation model establishment, prototype assembly, and experimental data analysis. The results show that under a 1 Hz, 120 mm vibration input, the simulation recovery voltage peak of the Electromagnetic Linear Actuation-Energy Reclaiming Device (ELA-ERD) reaches 80.7 V, and the average power feeding in the simulation is 89.8 W. The performance test of the physical ELA-ERD is carried out using a damper comprehensive performance test bench paired with the Dspace testing system, under the same 1 Hz, 120 mm input. The test recovery voltage peak reaches 66.2 V, and the average power feeding is 73.6 W, the energy recovery effect has been enhanced by 75%, which means the experimental power feeding effect reaches 82% of the simulation result. The electromagnetic linear power-feeding semi-active suspension can effectively improve the low vibration energy recovery efficiency of semi-active suspensions, providing important technical support for the improvement of vehicle suspension performance.

Keywords

electromagnetic linear actuator energy recovery device energy recovery simulation experiment

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References

Jiang

Song

, et al. Energy-harvesting characteristics of a dual-mode magnetic suspension for vehicles: analysis and experimental verification. Actuators 2022; 11: 363.

Čorić

Deur

Kasać

, et al. Optimisation of active suspension control inputs for improved vehicle handling performance. Veh Syst Dyn 2016; 54: 1574–1600.

Lato

Zhao

Lin

, et al. An energy-regenerative suspension system. In: Proceedings of the ASME 2018 international mechanical engineering congress and exposition IMECE 2018, Pittsburg, PA, USA, 9–15 November 2018.

Gong

Yan

. Robust control strategy of heavy vehicle active suspension based on road level estimation. Int J Automot Technol 2021; 22: 141–153.

Zheng

Wang

Gao

. A comprehensive review on regenerative shock absorber systems. J Vib Eng Technol 2020; 8: 225–246.

Long

Ding

Zhang

, et al. Regenerative active suspension system with residual energy for in-wheel motor driven electric vehicle. Appl Energy 2020; 260: 114–180.

Salman

Zhu

, et al. A high-efficiency energy regenerative shock absorber using helical gears for powering low-wattage electrical device of electric vehicles. Energy 2018; 159: 361–372.

, et al. A review of electromagnetic energy regenerative suspension system & key technologies. Comput Model Eng Sci 2022; 135: 1779.

Yin

Luo

, et al. Performance-oriented controls of a novel rocker-pushrod electromagnetic active vehicle suspension. Mech Syst Signal Process 2018; 109: 1–14.

10.

Zou

Guo

Abdelkareem

MAA

, et al. Modelling and ride analysis of a hydraulic interconnected suspension based on the hydraulic energy regenerative shock absorbers. Mech Syst Signal Process 2019; 127: 345–369.

11.

Zheng

Gao

. Damping force and energy recovery analysis of regenerative hydraulic electric suspension system under road excitation: modelling and numerical simulation. Math Biosci Eng 2019; 16: 6298–6318.

12.

, et al. Energy-harvesting variable/constant damping suspension system with motor based electromagnetic damper. Energy 2019; 189: 116199.

13.

Zhang

Xue

, et al. A comprehensive review of permanent magnet synchronous linear motors in automotive electromagnetic suspension system. In: 2021 IEEE 4th advanced information management, communicates, electronic and automation control conference (IMCEC), Chongqing, China, 18–20 June 2021, vol. 4, pp. 792–796. New York: IEEE.

14.

Liu

, et al. Optimal design of magneto-force-thermal parameters for electromagnetic actuators with Halbach array. Actuators 2021; 10: 231.

15.

Wei

Sun

Jin

, et al. Proposal of energy-recycle type active suspension using magnetic force. Int J Appl Electromagn Mech 2019; 59: 577–585.

16.

Sun

Yin

, et al. Model predictive thrust-force control of linear motors for active suspensions. IEEE Trans Energy Convers 2021; 36: 3063–3072.

17.

Yang

Guo

. Present situation and development tendency of shock absorbers in vehicle suspensions. Eng Test 2019; 59: 97–100 + 103.

18.

Dai

Chang

Qin

, et al. Design and analysis of electromagnetic linear actuation-energy-reclaiming device applied to a new-type energy-reclaiming suspension. Actuators 2023; 12: 142.

19.

Deubel

Prokop

. Friction of a MacPherson suspension system at various load cases. J Vib Control 2022; 30: 14–26.

Design,simulation,and experimental research of a new electromagnetic linear power feeding semi-active suspension

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