Enhanced Seat Suspension Performance Through Positive Real Network Optimization and Skyhook Inertial Control

Enhanced Seat Suspension Performance Through Positive Real Network Optimization and Skyhook Inertial Control

To solve the low frequency vibration problem faced by heavy truck drivers, a positive real network inertial suspension structure combined with a skyhook inertial control strategy is adopted. This integrated approach effectively reduces low-frequency vibrations at the seat and human body levels. Spec...

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Bibliographic Details
Main Authors: Xiaofeng Yang, Rui Sun, Yi Yang, Yanling Liu, Jingchen Hong, Changning Liu
Format: Article
Language:English
Published: MDPI AG 2025-03-01
Series:Machines
Subjects:
seat inertial suspension
vibration control
structural optimization
positive real network
skyhook inertial control
Online Access:https://www.mdpi.com/2075-1702/13/3/222
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Summary:To solve the low frequency vibration problem faced by heavy truck drivers, a positive real network inertial suspension structure combined with a skyhook inertial control strategy is adopted. This integrated approach effectively reduces low-frequency vibrations at the seat and human body levels. Specifically, this research aims to mitigate the acceleration experienced on the seat surface within the low-frequency range. Firstly, a human–seat dynamics model is established. Subsequently, based on the principles of network synthesis, the derivation of transfer functions for both first- and second-order systems is discussed, and the network parameters are also optimized. This paper further compares the optimization outcomes of first- and second-order skyhook seat inertial suspensions. An adaptive fuzzy sliding-mode controller (AFSMC) has been developed for an electromechanical inerter, ensuring it closely tracks optimal control performance. The findings demonstrate that the new suspension system achieves a 29.9% reduction in the root-mean-square value of seat surface acceleration and a 43.1% decrease in the road-bump peak acceleration compared to a conventional suspension system. The results show that the inertial suspension with skyhook inertial control is highly effective in completely suppressing seat surface acceleration within the low-frequency domain.
ISSN:2075-1702

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