重庆理工大学学报(自然科学) ›› 2023, Vol. 37 ›› Issue (2): 77-85.doi: 10.3969/j.issn.1674-8425(z).2023.02.009

• “新能源汽车能量管理技术研究”专栏 • 上一篇    下一篇

混合动力商用车能量流测试

冯仁华,陈昆阳,赵智超   

  1. 1.重庆理工大学 车辆工程学院,重庆 400054; 2.中国汽车工程研究院有限公司,重庆 401122; 3.重庆理工大学 汽车零部件先进制造技术教育部重点实验室,重庆 400054
  • 出版日期:2023-03-21 发布日期:2023-03-21
  • 作者简介:冯仁华,男,博士,讲师,主要从事发动机性能优化、新能源汽车能量管理研究,Email:fengrenhua@cqut.edu.cn; 通讯作者 赵智超,男,博士,主要从事新能源汽车能量管理研究,Email:155151750@qq.com。

Experimental study on energy flow of a hybrid commercial vehicle

  • Online:2023-03-21 Published:2023-03-21

摘要: 以某重型混合动力商用车为研究对象,基于 CWTVC循环工况,在带环境仓的底盘 测功机上进行整车能量流试验,研究了该车辆的能量流特性、具体驱动方式、动力系统及关键部 件的工况和能效等。试验结果表明:用于驱动车辆的能量占总能量的 30.99%;散热器和电机 冷却回路的换热损失分别占总能量的 8.89%和 2.6%;发动机泵气损失、摩擦损失、燃烧损失、 排气焓增等的余项损失占总能量的 50.67%;在驱动模式中,纯电驱动、并联驱动、驱动发电和 能量回收分别占总循环时间的 9.1%、29.56%、18.51%和 23.61%;整车制动能量回收效率为 81.95%;约有65%的发动机工作点在200g/(kW·h)以下区域,发动机在试验循环的热效率为 36.81%;约有 24%的电机工作点工作在效率大于 94%的区域;约有 53%的电机工作点工作在 效率小于 92%的区域,且主要集中在发动机驱动电机发电和能量回收时。本研究可为该混合 动力汽车能效的提高提供指导。

关键词: 混合动力商用车, 能量流测试, CWTVC, 工况, 效率

Abstract: In this paper, the vehicle energy flow test of a heavy hybrid commercial vehicle is carried out on the chassis dynamometer with an ambient chamber under the C-WTVC test cycle. Energy flow characteristics, driving modes, the power system and key component working status and efficiency of the vehicle are studied. The test results show that the energy used to drive the vehicle accounts for 30.99% of the total energy. Heat transfer loss of the radiator and the motor cooling loop accounts for 8.89% and 2.6% of the total energy respectively. The remainder loss accounts for 50.67% of the total energy which includes engine pump gas loss, friction loss, combustion loss and exhaust enthalpy increase. In the driving mode, pure electric drive, parallel drive, drive power generation and the energy recovery mode account for 9.1%, 29.56%, 18.51% and 23.61% of the total cycle time respectively. The recovery efficiency of braking energy is 81.95%. There are about 65% of the engine working points located below 200 g/(kW·h) areas, and the thermal efficiency of the engine is 36.81% during the whole test cycle. About 24% of the motor working points are located in areas with a mechanical efficiency exceeding 94%. About 53% of the motor working points are located in areas with a mechanical efficiency below 92%, which mainly appear when the motor is driven by the engine to generate electricity or recover energy. This study provides guidance for improving the energy efficiency of hybrid commercial electric vehicles, and the following research can be focused on reduction of engine remainder loss and optimization of engines and motor working points.

中图分类号: 

  • U467.1+2