Optimal energy management and shift scheduling control of a parallel plug-in hybrid electric vehicle

Q3 Engineering

International Journal of Powertrains Pub Date : 2020-09-07 DOI:10.1504/ijpt.2020.10031902

Jure Soldo, B. Škugor, J. Deur

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引用次数: 7

Abstract

This paper deals with design of a control strategy for a parallel powertrain configuration of a plug-in hybrid electric vehicle (PHEV). The control strategy is aimed at minimising fuel consumption and number of gear shift events for a wide range of driving cycles, while keeping the battery state-of-charge within allowable range. A control-oriented backward-looking model of PHEV powertrain is used as a design basis. The control strategy combines a rule-based controller with an equivalent consumption minimisation strategy (ECMS). The ECMS uses both transmission gear ratio and engine torque as control variables, thus eliminating a need for designing a separate gear shift scheduling strategy and exploiting a full potential of powertrain efficiency improvement. The overall control strategy is designed for different characteristic operating regimes including charge depleting, charge sustaining, and blended regimes. The strategy is verified by computer simulations against globally optimal benchmark obtained by using the dynamic programming-based optimisation, whose results are also used for fine tuning of controller parameters.

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并联插电式混合动力汽车最优能量管理与班次调度控制

研究了插电式混合动力汽车并联动力系统的控制策略设计。该控制策略旨在最大限度地减少燃油消耗和大范围驾驶循环的换挡次数，同时将电池的充电状态保持在允许的范围内。采用以控制为导向的插电式混合动力系统回溯模型作为设计依据。控制策略结合了基于规则的控制器和等效消耗最小化策略(ECMS)。ECMS采用变速器传动比和发动机扭矩作为控制变量，因此无需设计单独的换挡调度策略，并充分发挥动力系统效率提高的潜力。总体控制策略是针对不同的特征运行状态设计的，包括电荷耗尽、电荷维持和混合状态。利用基于动态规划的优化方法得到全局最优基准，并通过计算机仿真验证了该策略的有效性，其结果也用于控制器参数的微调。

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

International Journal of Powertrains Engineering-Automotive Engineering

CiteScore

1.20

自引率

0.00%

发文量

期刊介绍： IJPT addresses novel scientific/technological results contributing to advancing powertrain technology, from components/subsystems to system integration/controls. Focus is primarily but not exclusively on ground vehicle applications. IJPT''s perspective is largely inspired by the fact that many innovations in powertrain advancement are only possible due to synergies between mechanical design, mechanisms, mechatronics, controls, networking system integration, etc. The science behind these is characterised by physical phenomena across the range of physics (multiphysics) and scale of motion (multiscale) governing the behaviour of components/subsystems.