基于磁流变材料的一体式悬架减振支柱研究#br#

doi:10.3969/j.issn.1671-7775.2022.05.006

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摘要为了提升汽车的行驶平顺性及其适应路面时变的能力，针对电控空气悬架刚度分级调控问题，提出一种基于磁流变材料的新型一体式悬架减振支柱设计方案，在电控主动空气悬架的减振支柱基础上进行改进，利用磁流变材料的特性达到悬架系统无级调控刚度和阻尼的要求.介绍了减振支柱的结构组成及工作原理，分别建立了刚度和阻尼特性数学模型.搭建试验台架，进行了力学特性试验，得到减振支柱刚度和阻尼特性曲线，并利用试验结果对模型进行参数辨识.将仿真结果与试验结果进行对比分析，结果表明该减振支柱的数学模型较准确，设计方案可行.

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	黄晨
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关键词 ：磁流变材料, 电控空气悬架；一体式悬架, 减振支柱, 空气弹簧, 台架试验

Abstract：To improve the ride comfort of car and the adapting ability to the time-varying road surface, a new integrated suspension design scheme based on magnetorheological materials was proposed to realize the graded regulation of stiffness for the electronically controlled air suspension. The damping pillar of the air suspension was improved based on the characteristics of magnetorheological materials to achieve the infinite regulating of stiffness and the damping of suspension system. The structural composition and working principle of the damping pillar were introduced, and the mathematical models of stiffness and damping characteristics were established respectively. An experimental bench was set up to identify the model parameters according to the experimental results, and the simulation results were compared with the experimental results. The results show the mathematical model of damping pillar is accurate, and the design scheme is suitable.

Key words： magnetorheological material electronically controlled air suspension integrated suspension damping pillar air spring bench test

收稿日期: 2021-01-29

基金资助: 汽车仿真与控制国家重点实验室开放基金资助项目（20201206）

作者简介: 黄晨(1984—),男,江苏镇江人,副教授 (huangchen@ujs.edu.cn),主要从事车辆动态性能分析控制与系统设计研究. 张智宇(1994—),男,江苏南通人,硕士研究生(zhangzhiyu_max@163.com),主要从事车辆动力学建模与控制研究.

引用本文:

黄晨，张智宇，孙晓强. 基于磁流变材料的一体式悬架减振支柱研究#br#[J]. 江苏大学学报（自然科学版）, 2022, 43(5): 533-538. HUANG Chen, ZHANG Zhiyu, SUN Xiaoqiang. Research on one-piece suspension damping pillar based on magnetorheological materials[J]. Journal of Jiangsu University(Natural Science Eidtion) , 2022, 43(5): 533-538.

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http://zzs.ujs.edu.cn/xbzkb/CN/10.3969/j.issn.1671-7775.2022.05.006 或 http://zzs.ujs.edu.cn/xbzkb/CN/Y2022/V43/I5/533

［1］	李仲兴,沈安诚,江洪.电控空气悬架多智能体博弈控制系统研究[J].汽车工程,2020,42(6):793-800，831.
	LI Z X, SHEN A C, JIANG H.Research on multiagent game control system of an electronic air suspension[J]. Automotive Engineering, 2020, 42(6): 793-800，831.（in Chinese）
［2］	ZHAO R, XIE W, WONG P K, et al. Adaptive vehicle posture and height synchronization control of active air suspension systems with multiple uncertainties[J]. Nonlinear Dynamics, 2020, 99(3): 2109-2127.
［3］	刘立超,詹庆峰,陈黎卿, 等.电控空气悬架系统硬件在环仿真测试研究[J].机械设计,2017,34(9):48-53.
	LIU L C, ZHAN Q F, CHEN L Q, et al.Research on hardwareintheloop simulation test for electronically controlled air suspension[J]. Journal of Machine Design,2017,34(9):48-53. (in Chinese)
［4］	TANG G, ZHU H J, ZHANG Y Q, et al. Studies of air spring mathematical model and its performance in cab suspension system of commercial vehicle[J]. SAE Technical Papers, doi:10.4271/2015-01-0608.
［5］	陆文昌,杨帆,汪少华,等. 气动可调阻尼同轴一体式减振支柱阻尼特性研究[J]. 振动与冲击, 2015, 34(20): 115-119,128.
	LU W C, YANG F, WANG S H, et al. Damping characteristics of a coaxial integrated strut with adjustable pneumatic damping[J]. Journal of Vibration and Shock, 2015, 34(20): 115-119,128. (in Chinese)
［6］	李罡,张晗,王彧,等.基于电磁阀式阻尼连续可调减振器的半主动悬架试验研究[J].汽车技术,2016(9):35-38,42.
	LI G, ZHANG H, WANG X, et al. Test research on semiactive suspension based on solenoidactuated damping continuously variable shock absorber[J]. Automobile Technology,2016(9):35-38,42. (in Chinese)
［7］	江浩斌, 刘庆利. 刚度阻尼联动减振支柱的NJ2045型车后悬架参数优化[J].广西大学学报(自然科学版),2017,42(3):809-815.
	JIANG H B, LIU Q L. Rear suspension parameter optimization of offroad vehicle NJ2045 equipped with an adjustable stiffness and damping strut[J]. Journal of Guangxi University(Natural Science Edition),2017,42(3):809-815. (in Chinese)
［8］	LI W, CHEN Y, ZHANG S, et al. Damping characteristic analysis and experiment of air suspension with auxiliary chamber[J]. IFACPapersOnLine, 2018, 51(17):166-172.
［9］	张志勇,王建波,胡林, 等.考虑路面预瞄信息和参数不确定性的空气悬架半主动控制[J].振动与冲击,2020,39(23):21-29.
	ZHANG Z Y, WANG J B, HU L, et al. Semiactive control of air suspension considering pavement preview information and parametric uncertainty[J]. Journal of Vibration and Shock,2020,39(23):21-29. (in Chinese)
［10］	NIETO A J, MORALES A L, TRAPERO J R, et al. An adaptive pneumatic suspension based on the estimation of the excitation frequency[J]. Journal of Sound Vibration, 2011, 330(9):1891-1903.
［11］	MOHEYELDEIN M M, ABDELTAWWAB A M, ABDEIGWWAD K A, et al. An analytical study of the performance indices of air springsuspensions over the passive suspension[J]. BeniSuef University Journal of Basic and Applied Sciences, 2018,7(4)：525-534.
［12］	李仲兴, 琚龙玉, 江洪,等. 可变容积附加气室空气悬架的参数优化与控制[J]. 汽车工程, 2015, 37(8):941-945，969.
	LI Z X, JU L Y, JIANG H, et al. Parameter optimization and control of air suspension with adjustable auxiliary chamber[J]. Automotive Engineering, 2015, 37(8):941-945，969. (in Chinese)
［13］	SUN S S, YANG J, LI W H, et al. Development of an isolator working with magnetorheological elastomers and fluids[J]. Mechanical Systems and Signal Processing, 2017, 83(13):371-384.
［14］	BASTOLA A K, LI L. A new type of vibration isolator based on magnetorheological elastomer[J]. Materials and Design, 2018, 157:431-436.
［15］	NGUYEN X B, KOMATSUZAKI T, IWATA Y, et al. Modeling and semiactive fuzzy control of magnetorheological elastomerbased isolator for seismic response reduction[J]. Mechanical Systems and Signal Processing, 2018, 101(15):449-466.