Topological Optimization of Vehicle ISD Suspension under Steering Braking Condition

IF 2.6 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC
Yanling Liu, Dongyin Shi, Fu Du, Xiaofeng Yang, Kerong Zhu
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Abstract

Anti-roll and anti-pitch are important directions in the comprehensive research of automobiles. In order to improve the anti-roll and anti-pitch performance of the vehicle, an inerter was applied to the vehicle suspension system, and a 14 DOF vehicle nonlinear dynamics model was established. The influence of the change in inertance in the eight kinds of improved ISD (Inerter-Spring-Damper) suspension structures on the RMS (root mean square) value of performance indexes of roll, vertical, and pitch motion of the vehicle was studied. Based on this, the vehicle’s ISD structure with better performance was selected, and the NSGA-Ⅱ algorithm was adopted to optimize the selected structural parameters. The simulation results showed that the four kinds of suspension hadbetter comprehensive performance, and their structureswere, respectively, excluding the supporting spring in parallel, (1) an inerter in series with a spring and a damper in parallel, (2) a damper in series with a spring and an inerter in parallel, (3) an inerter and a damper in series, and (4) the damper in parallel with a spring and an inerter in series. The ISD suspension structure had better comprehensive performance under step steering braking, which was obviously better than the passive suspension, and effectively improved the vehicle ride comfort, anti-roll and anti-pitch performance. Under the hook steering braking, the lateral load transfer rate was used to evaluate the vehicle’s anti-rollover ability. The results showed that the ride comfort and anti-rollover ability of ISD suspension were better than those of passive suspension. Under the condition of taking into account the anti-pitching ability, the suspension consists of a supporting spring in parallel with an inerter, and a damper in series was better.
转向制动工况下汽车ISD悬架拓扑优化
防侧倾和防俯仰是汽车综合研究的重要方向。为了提高车辆的抗侧倾和抗俯仰性能,在车辆悬架系统中加入了一个干涉器,建立了14自由度车辆非线性动力学模型。研究了8种改进型ISD (inter - spring -阻尼器)悬架结构的惯性变化对车辆横倾、垂直和俯仰运动性能指标均方根值的影响。在此基础上,选取性能较好的车辆ISD结构,并采用NSGA-Ⅱ算法对选取的结构参数进行优化。仿真结果表明,四种悬架综合性能较好,其结构分别为:不支持弹簧并联、(1)减振器与弹簧并联、(2)减振器与弹簧并联、减振器与减振器并联、(3)减振器与减振器串联、(4)减振器与弹簧并联、减振器串联。ISD悬架结构在台阶转向制动下具有较好的综合性能,明显优于被动悬架,有效提高了车辆的平顺性、抗侧倾和抗俯仰性能。在钩式转向制动下,采用横向载荷传递率评价车辆的抗侧翻能力。结果表明,ISD悬架的平顺性和抗侧翻能力均优于被动悬架。在考虑抗俯仰能力的情况下,悬架采用支撑弹簧与惯性器并联的方式,减振器串联的方式较好。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
World Electric Vehicle Journal
World Electric Vehicle Journal Engineering-Automotive Engineering
CiteScore
4.50
自引率
8.70%
发文量
196
审稿时长
8 weeks
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