Integrated model for battery Electric Vehicles with energy harvesting active suspension system

2017 Twelfth International Conference on Ecological Vehicles and Renewable Energies (EVER) Pub Date : 2017-04-11 DOI:10.1109/EVER.2017.7935863

T. Pham, J. Jacob, S. Wilkins, C. Lauwerys, M. Dhaens

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引用次数: 6

Abstract

This paper presents an integrated vehicle model to simulate simultaneously the driver, powertrains, chassis, body, road condition, vehicle dynamics and the Active Suspension (AS) system with/without an energy harvesting module. The developed model is used to investigate the ride comfort and influences of energy harvesting AS system on the total energy consumption of battery Electric Vehicles (EVs) relative to EVs with a passive suspension system. Preliminary simulation results show that compared to EVs with a passive suspension system, the ones with AS system improve ride comfort, up to 31% reduction of the vehicle body acceleration RMS value, with an expense of higher energy consumption. This expense can be reduced to about 2.8% when using an energy harvesting AS system. Simulation results also demonstrate that the available energy for recuperation during the AS system operation is significant in relation to the regenerative braking energy of the propulsion system, up to approx. 70% on bumpy road surfaces.

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具有能量收集主动悬架系统的纯电动汽车集成模型

本文提出了一个集成的车辆模型，可以同时模拟驾驶员、动力系统、底盘、车身、路况、车辆动力学和有/没有能量收集模块的主动悬架(AS)系统。利用所建立的模型，对比被动悬架电动汽车的平顺性和能量收集系统对电动汽车总能耗的影响进行了研究。初步仿真结果表明，与采用被动悬架系统的电动汽车相比，采用被动悬架系统的电动汽车平顺性得到改善，车身加速度RMS值降低幅度高达31%，但能耗较高。当使用能量收集AS系统时，这一费用可以减少到2.8%左右。仿真结果还表明，AS系统运行过程中用于回收的可用能量与推进系统的再生制动能量相比是显著的，可达约。70%在凹凸不平的路面上。

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

2017 Twelfth International Conference on Ecological Vehicles and Renewable Energies (EVER)

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