Experimentally Based Methodology to Evaluate Fuel Saving and CO 2 Reduction of Electrical Engine Cooling Pump during Real Driving

IF 1.1 Q3 TRANSPORTATION SCIENCE & TECHNOLOGY

SAE International Journal of Engines Pub Date : 2023-03-09 DOI:10.4271/03-16-05-0041

M. Di Bartolomeo, D. Di Battista, R. Cipollone

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引用次数: 1

Abstract

Engine thermal management (ETM) is a promising technology that allows the reduction of harmful emissions and fuel consumption when the internal combustion engine (ICE) is started from a cold state. The key technology for ETM is the decoupling of the cooling pump from the crankshaft and the actuation of the pump independently. In this article, an electric engine cooling pump has been designed through a novel experimentally based procedure and operated on a vehicle equipped with an advanced turbocharged gasoline engine, particularly interesting for its hybridization potential. In the first phase, a dedicated experimental campaign was conducted off board on an engine identical to the one equipped in the vehicle to assess the characteristics of the cooling circuit and the reference pump performances. The experimental data have been used to design an electric pump with a best efficiency point (BEP) located in a region more representative of the real operating conditions faced by the vehicle during real driving. Once prototyped, the electric pump has been compared to the reference mechanical one on a real driving mission profile whose parameters have been experimentally evaluated. The comparison was made in the same operating conditions of flow rate and the pressure head acting on the revolution speed of the prototype to focus the attention on the effect of the different design choices made possible by the electric actuation. The procedure can evaluate the pump-related fuel consumption, whatever the real vehicle speed profile and the actuation of the pump. The results show that in a driving cycle with urban, extra-urban, and highway phases, the electric pump absorbs 66% less power compared to the mechanical one, which translates into a 0.55 gCO2/km specific emission reduction. This demonstrates the validity of the novel design procedure together with the benefits of the electric actuation.

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基于实验方法的电动发动机冷却泵在实际驾驶中的节油降耗评估

发动机热管理(ETM)是一项很有前途的技术，可以在内燃机(ICE)从冷状态启动时减少有害排放和燃料消耗。ETM的关键技术是冷却泵与曲轴的解耦和泵的独立驱动。在本文中，通过一种新颖的实验程序设计了一种电动发动机冷却泵，并在配备先进涡轮增压汽油发动机的车辆上运行，其混合动力潜力尤其令人感兴趣。在第一阶段，在与车辆配备相同的发动机上进行了专门的实验活动，以评估冷却回路的特性和参考泵的性能。利用实验数据设计了一种最佳效率点(BEP)位于更能代表车辆实际行驶时所面临的实际工况的区域的电泵。电泵一旦制成原型，就会在实际驾驶任务剖面上与参考机械泵进行比较，并对其参数进行实验评估。在相同工况下，对流量和压头作用于样机转速的情况进行了比较，重点考察了电动驱动不同设计选择所产生的影响。该程序可以评估与泵相关的燃油消耗，无论真实的车辆速度轮廓和泵的驱动。结果表明，在城市、城市外和高速公路阶段的驾驶循环中，电动泵比机械泵吸收的功率少66%，相当于每公里二氧化碳比排放量减少0.55 g。这证明了新设计程序的有效性以及电动驱动的优点。

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

SAE International Journal of Engines TRANSPORTATION SCIENCE & TECHNOLOGY-

CiteScore

2.70

自引率

8.30%

发文量