Combined Design and Control Optimization for a Series Hybrid Electric Vehicle With an Opposed Piston Engine

IF 2.4 Q2 AUTOMATION & CONTROL SYSTEMS

IEEE Control Systems Letters Pub Date : 2024-12-19 DOI:10.1109/LCSYS.2024.3520415

Meridian Haas;Joseph Drallmeier;Robert Middleton;Jason B. Siegel;Shima Nazari

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Abstract

Hybrid electric vehicles (HEV) enable reduction of emissions without sacrificing consumer expected range and drivability. The diversification of the powertrain with multiple power sources allows downsizing the internal combustion engine and implementing optimal energy management strategies. The interaction among components of an HEV are key to the overall efficiency. Therefore, efficiency potential is lost if this interdependence is neglected during the powertrain design by focusing on individual optimization of component specifications. This letter formulates and solves a co-design problem by integrating the energy management with the optimal powertrain and drivetrain component sizing for a hybrid powertrain equipped with an opposed piston (OP) engine in a series architecture. Our novel approach develops a model for an OP engine and integrates battery capacity degradation into the co-design problem. The optimal solution allows for a minimally sized engine that accounts for the average power requirements, and a large enough battery to provide fast power dynamics.

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对置活塞发动机串联式混合动力汽车组合设计与控制优化

混合动力电动汽车（HEV）能够在不牺牲消费者预期续航里程和驾驶性能的情况下减少排放。采用多种动力源的动力系统的多样化，可以缩小内燃机的体积，并实现最佳的能源管理策略。混合动力汽车各部件之间的相互作用是整体效率的关键。因此，如果在动力总成设计过程中忽略了这种相互依赖性，而只关注组件规格的个别优化，则会失去效率潜力。本文阐述并解决了一个协同设计问题，将能量管理与最佳动力总成和传动系统部件尺寸相结合，用于在串联架构中配备对置活塞（OP）发动机的混合动力总成。我们的新方法为OP引擎开发了一个模型，并将电池容量退化集成到协同设计问题中。最优的解决方案是使用最小尺寸的发动机来满足平均功率要求，以及足够大的电池来提供快速的动力。

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

IEEE Control Systems Letters Mathematics-Control and Optimization

CiteScore

4.40

自引率

13.30%

发文量

471