Electric hydraulic hybrid vehicle powertrain design and optimization-based power distribution control to extend driving range and battery life cycle

Eckert Jony Javorski; Barbosa Tarsis Prado; da Silva Samuel FilgueiraSilva Fabricio LeonardoSilva Ludmila C. A.Dedini Franco Giuseppe

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Electric hydraulic hybrid vehicle powertrain design and optimization-based power distribution control to extend driving range and battery life cycle

机译：Electric hydraulic hybrid vehicle powertrain design and optimization-based power distribution control to extend driving range and battery life cycle

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摘要

This paper presents a comprehensive optimization procedure of a series electric hydraulic hybrid vehicle powertrain and control through the interactive adaptive-weight genetic algorithm method. The optimization simultaneously maximizes the driving range and battery lifespan, while minimizing onboard energy storage system mass. In this context, the design variables of the overall hydraulic drivetrain and the electric system were optimized. Moreover, a fuzzy-logic controller, which outputs the electric motor start-stop state and the torque applied to the pump which pressurizes the accumulator, is likewise considered in the formulation of the optimization problem to tune its membership functions, rules and weights. To ensure robust solutions, the electric-hydraulic vehicle was optimized under a combination of three standard driving cycles, which have antagonistic characteristics. Among the obtained optimum solutions, two configurations stood out with the driving range of 167.95 km and 199.73 km when using a battery of 320.23 kg and 384.12 kg and obtaining a battery life cycle of 53177 h and 46531 h, respectively. Moreover, these solutions were also tested under four different real-world driving cycles to evaluate their autonomy and performance, reaching driving ranges from 147 km in highway scenarios to over 262 km in urban cycles. The optimum configurations were compared with an also optimum electric vehicle powered by a battery-ultracapacitor hybrid energy storage system, obtaining a reduction of up to 9.57% in the ratio between powertrain cost and driving range. Finally, the optimization results indicate that electric hydraulic hybrid vehicle powertrain architectures can be a very attractive propulsion technology regarding both sustainable and economical aspects, effectively reducing battery aging by the use of a high power density hydraulic accumulator, which acts as a peak power buffer unit.

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来源
《Energy conversion & management》 |2022年第1期|115094.1-115094.19|共19页
作者
Eckert Jony Javorski; Barbosa Tarsis Prado; da Silva Samuel FilgueiraSilva Fabricio LeonardoSilva Ludmila C. A.Dedini Franco Giuseppe;
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作者单位

Univ Campinas UNICAMP, Mech Engn Fac FEM, Integrated Syst Lab, Campinas, Brazil;

Fed Univ Sao Joao del Rei UFSJ, Dept Telecommun & Mechatron Engn, Ouro Branco, Brazil;

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收录信息美国《科学引文索引》(SCI);美国《工程索引》(EI);
原文格式 PDF
正文语种英语
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关键词
Electric hybrid hydraulic vehicles; Driving range; Fuzzy logic control; Powertrain synergy; Battery life-cycle; Multi-objective optimization;

Electric hydraulic hybrid vehicle powertrain design and optimization-based power distribution control to extend driving range and battery life cycle

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