Title: Semi-active control of magneto-rheological variable stiffness and damping seat suspension with human-body model
Authors: Xiao-min Dong
Addresses: State Key Laboratory of Mechanical Transmission, Chongqing University, Chongqing 400044, China
Abstract: The potential benefits of an MR seat suspension in improving ride quality are investigated. Two magneto-rheological (MR) dampers are devised and manufactured to realise the variable damping and equivalent stiffness capacities of a seat suspension, respectively. After evaluating field-dependent damping characteristics of the MR seat damper, the equation of equivalent variable stiffness is also shown. A seat suspension model with a four-DOF human body model is then formulated. A Human Simulated Intelligent Controller (HSIC) is proposed to attenuate the unwanted vibration of the variable stiffness and damping seat suspension. To validate the control performance of the proposed seat suspension and the control scheme, a numerical simulation is performed under the bump, random and chirp excitations. The result indicates that the proposed seat suspension system with HSIC can significantly improve the driver's ride quality compared to the passive one.
Keywords: MR damper; magnetorheological damping; seat suspension; HSIC; human simulated intelligent control; semi-active control; passive control; numerical simulation; ride quality; suspension modelling; human body models; vehicle design; vehicle vibration; variable stiffness.
International Journal of Vehicle Design, 2013 Vol.63 No.2/3, pp.119 - 136
Received: 02 Nov 2011
Accepted: 21 May 2012
Published online: 16 Oct 2014 *