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Development of an MR seat suspension with self-powered generation capability

journal contribution
posted on 2024-11-16, 03:59 authored by Shuaishuai SunShuaishuai Sun, Donghong Ning, Jie YangJie Yang, Haiping DuHaiping Du, Shiwu Zhang, Weihua LiWeihua Li, Masami Nakano
This paper proposes a self-powered magnetorheological (MR) seat suspension on the basis of a rotary MR damper and an electromagnetic induction device. By applying the self-powering component to the MR seat suspension, the operation cost of the semi-active seat is much cheaper because no external energy is required to control the MR damper. In this paper, the structure, design and analysis of the seat suspension were presented following the introduction section. The property tests of the self-powered seat suspension were conducted using an MTS machine. A robust control algorithm was developed to control the self-powered MR seat suspension and the vibration attenuation performance of the seat suspension was tested under two different vibration excitations, i.e. harmonic excitation and random excitation. The testing result verifies that the self-powered MR seat suspension under proper control can improve the ride comfort for passengers and drivers.

Funding

Comfort and ergonomics: Innovative seating solutions for commercial vehicles

Australian Research Council

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Innovative Magnetorheological Suspension Systems for Forklift Trucks

Australian Research Council

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History

Citation

Sun, S. S., Ning, D. H., Yang, J., Du, H., Zhang, S. W., Li, W. H. & Nakano, M. (2017). Development of an MR seat suspension with self-powered generation capability. Smart Materials and Structures, 26 (8), 085025-1-085025-15.

Journal title

Smart Materials and Structures

Volume

26

Issue

8

Language

English

RIS ID

115423

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