Ride comfort analysis of vehicle seat suspension systems: A co-simulation study

Q3 Physics and Astronomy

Noise and Vibration Worldwide Pub Date : 2023-09-25 DOI:10.1177/09574565231203246

Ramalingam M, Arun K T, Davidson Jebaseelan, Seung-Bok Choi, Jebaraj C

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引用次数: 1

Abstract

In this study, the vehicle seat suspension system installed with a semi-active magnetorheological (MR) damper is excited by the power spectral density (PSD) and its vibration control performance is evaluated using finite element analysis (FEA). The control system receives the velocity of the sprung and unsprung mass from the seat mounting locations and calculates the desired controllable damping forces available from MR damper. The effectiveness of the control systems is demonstrated by adopting ride quality evaluation method. To predict a better ride comfort and ride quality, co-simulation methodology is utilized considering the dynamic behavior of the real-world seat system. In this case, the multi-body dynamics and control system are coupled by solving the mechanical equations and the control logic. Then, the computed damping force is exchanged between the dynamics and controller in an iterative manner by passing state variables. The simulation results achieved from co-simulation methodology associated with the controller are analyzed by comparing with ISO 2631-1. The co-simulation results studied using vibration dose value (VDV), crest factor (CF) and seat effective amplitude transmissibility (SEAT) in terms of percentage improvement were found to be 44.33%, 26.66% and 17.65% respectively which were better than that for the passive suspension for a random rough road profile. Modified skyhook controller delivers superior performance for vibration suppression of the vehicle seat suspension as compared to other control policies. The application of co-simulation methodology can reduce time and cost for the development of a semi-active seat suspension system.

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汽车座椅悬架系统的平顺性分析:联合仿真研究

以安装了半主动磁流变阻尼器的汽车座椅悬架系统为研究对象，采用功率谱密度(PSD)对其进行激励，并利用有限元分析对其振动控制性能进行评价。控制系统从座椅安装位置接收簧载和非簧载质量的速度，并计算MR阻尼器所需的可控阻尼力。采用平顺性评价方法验证了控制系统的有效性。为了预测更好的乘坐舒适性和乘坐质量，考虑到现实世界座椅系统的动态行为，采用了联合仿真方法。在这种情况下，通过求解力学方程和控制逻辑将多体动力学和控制系统耦合起来。然后，通过传递状态变量，将计算得到的阻尼力在动力学和控制器之间进行迭代交换。通过与ISO 2631-1的比较，分析了与控制器相关的联合仿真方法的仿真结果。采用振动剂量值(VDV)、波峰系数(CF)和座椅有效幅值传递率(seat)的联合仿真结果表明，在随机粗糙路面上，被动悬架的改进百分比分别为44.33%、26.66%和17.65%，优于被动悬架。与其他控制策略相比，改进后的天钩控制器在抑制汽车座椅悬架振动方面具有优越的性能。联合仿真方法的应用可以减少半主动座椅悬架系统的开发时间和成本。

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

Noise and Vibration Worldwide Physics and Astronomy-Acoustics and Ultrasonics

CiteScore

1.90

自引率

0.00%

发文量

期刊介绍： Noise & Vibration Worldwide (NVWW) is the WORLD"S LEADING MAGAZINE on all aspects of the cause, effect, measurement, acceptable levels and methods of control of noise and vibration, keeping you up-to-date on all the latest developments and applications in noise and vibration control.