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Hydraulic Hybrid Propulsion for Heavy Vehicles: Combining the Simulation and Engine-ln-the-Loop Techniques to Maximize the Fuel Economy and Emission Benefits

机译:重型车辆的液压混合动力:将模拟技术与发动机在环技术相结合,以最大限度地提高燃油经济性和排放效益

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摘要

The global energy situation, the dependence of the transportation sector on fossil fuels, and a need for a rapid response to the global warming challenge, provide a strong impetus for development of fuel efficient vehicle propulsion. The task is particularly challenging in the case of trucks due to severe weight/size constraints. Hybridization is the only approach offering significant breakthroughs in near and mid-term. In particular, the series configuration decouples the engine from the wheels and allows full flexibility in controlling the engine operation, while the hydraulic energy conversion and storage provides exceptional power density and efficiency. The challenge stems from a relatively low energy density of the hydraulic accumulator. This places particular emphasis on development of the supervisory controller. The conventional wisdom is to operate the engine at the "sweet spot", but the aggressive pursuit of engine efficiency as the sole objective can lead to frequent and rapid diesel engine transients, thus causing an adverse affect on the soot emissions and driver feel. Therefore, we propose a comprehensive methodology for considering a combined hybrid system fuel-economy and emissions objective. The fuel economy is addressed with the simulation-based approach, while investigating the impact of engine transients on particulate emission relies on the Engine-In-the-loop (EIL) capability. The EIL study confirms advantages of a modulated state-of-charge control over the thermostatic approach, and demonstrates the ability of the Series Hydraulic Hybrid to improve the fuel economy of the medium truck by 72%, while reducing the particulate emission by 74% compared to the conventional baseline over the city driving schedule.
机译:全球能源形势,交通运输部门对化石燃料的依赖以及对全球变暖挑战的快速响应的需求,为发展节油型车辆推进器提供了强大动力。由于重量/尺寸的严格限制,对于卡车而言,这项任务特别具有挑战性。杂交是唯一在近期和中期都有重大突破的方法。特别是,串联配置使发动机与车轮脱离连接,并在控制发动机运行时具有充分的灵活性,而液压能的转换和存储则提供了出色的功率密度和效率。挑战源于液压蓄能器的相对较低的能量密度。这特别强调了监督控制器的开发。传统的观点是在“最佳位置”操作发动机,但是积极追求发动机效率作为唯一目标可能导致频繁频繁的柴油发动机瞬变,从而对烟尘排放和驾驶员感觉产生不利影响。因此,我们提出了一种综合方法来考虑混合动力系统的燃油经济性和排放目标。燃油经济性通过基于仿真的方法解决,而调查发动机瞬变对颗粒物排放的影响则依赖于发动机在环(EIL)能力。 EIL研究证实了调节充电状态控制相对于恒温方法的优势,并证明了液压混合动力系列能够将中型卡车的燃油经济性提高72%,同时将颗粒物排放降低74%在城市驾驶时间表上达到常规基准。

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