Modeling Analysis on Combined Effects of VVT/VCR Engine Technology to Reduce Fuel Consumption of Light-Duty Parallel Hybrid CNG Trucks

Volume 6: Energy Pub Date : 2022-10-30 DOI:10.1115/imece2022-96282

R. Sok, Jin Kusaka, H. Nakashima, Hidetaka Minagata

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Abstract

Potential fuel consumption (FC) improvements of a parallel hybrid, light-duty, compressed natural gas (CNG) truck are numerically predicted using the combined benefits of a variable valve timing (VVT) and variable compression ratio (VCR) engine. A CNG hybrid electric vehicle (CNG-HEV) simulation model is developed in commercial software based on conventional delivery trucks in the Japanese market. The hybrid powertrain model includes a pre-transmission e-motor, high voltage battery, and production-typed 3.0 L CNG engine. Power splitting between e-motor and engine is controlled by a rule-based control strategy. Under the JE05 drive-cycle, engine maps such as torque, fuel and flow rate, and engine friction were measured under different intake valve timings in the 4-cylinder, twin-turbocharged spark-ignition engine with customized pistons to reach a compression ratio (CR) of 17. For VCR operations, the performance maps were recorded under CR14, CR15, and CR17 using standard valve timings. Simulated FC of the CNG-HEV under the JE05 driving cycle is improved by 10.9% and 15.7% using standard and optimal intake valve timings, respectively, against a conventional powertrain vehicle. By combining optimal VVT/VCR engine operations with a selected battery sizing, the predicted FC of the CNG-HEV could be achieved up to 18.2% against the conventional powertrain.

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VVT/VCR发动机技术对轻型并联混合动力CNG卡车降低油耗的联合效应建模分析

利用可变气门正时(VVT)和可变压缩比(VCR)发动机的综合优势，对并联混合动力轻型压缩天然气(CNG)卡车的潜在燃油消耗(FC)改进进行了数值预测。以日本市场上的传统货车为例，在商用软件中建立了CNG混合动力汽车(CNG- hev)仿真模型。混合动力系统模型包括变速箱前电机、高压电池和量产型3.0 L CNG发动机。采用基于规则的控制策略控制电机和发动机之间的功率分配。在JE05驾驶工况下，采用定制活塞的4缸双涡轮增压火花点火发动机在不同进气门正时下测量了扭矩、燃油和流量以及发动机摩擦等发动机图，以达到17的压缩比(CR)。对于VCR作业，使用标准气门正时在CR14、CR15和CR17下记录性能图。在JE05工况下，采用标准进气正时和优化进气正时的CNG-HEV模拟FC分别比传统动力总成车辆提高了10.9%和15.7%。通过将最佳的VVT/VCR发动机操作与选定的电池尺寸相结合，预计与传统动力系统相比，CNG-HEV的FC可达到18.2%。

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

Volume 6: Energy

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