期刊文献+

并联混合动力汽车的模糊转矩控制策略 被引量:25

The Fuzzy Torque Control Strategy for Parallel Hybrid Electric Vehicles
下载PDF
导出
摘要 提出了一种新的并联混合动力汽车(PHEV)模糊转矩控制策略(FTCS)及其设计方法.以并联混合动力系统的工作模式为基础,利用请求转矩与发动机最佳转矩的比值和电池电荷状态(SOC)为输入、电机归一化转矩指令为输出,构建了有22条规则的模糊推理器,用以确定发动机和电机的最佳转矩分配,实现系统的总体能量转换效率最高.仿真结果表明,与采用精确门限参数的策略相比,FTCS的燃油经济性有较大提高,并能更好地控制电池SOC在工作区变化. A novel fuzzy torque control strategy (FTCS) for parallel hybrid electric vehicles (PHEV) and its design method were presented. Based upon the operating modes of the hybrid powertrain, a fuzzy infer ence engine with 22 rules is constructed using the ratio of the driver torque request to the optimal engine torque and the battery state of charge (SOC) as the inputs, and the normalized electric machine (EM) torque as the output. It works as the kernel of a fuzzy torque distribution controller to determine the optimal distribution of the driver torque request between the engine and the EM to optimize the overall energy conversion efficiency of the PHEV. The simulation results reveal that, compared with the conventional strategy which uses precise threshold parameters, the proposed FTCS improves fuel economy and maintains battery SOC within its operation range more effectively.
出处 《上海交通大学学报》 EI CAS CSCD 北大核心 2006年第1期157-162,共6页 Journal of Shanghai Jiaotong University
基金 国家高技术研究发展计划(863)项目(2001AA501211 2003AA501200)
关键词 并联混合动力汽车 混合动力系统 控制策略 模糊控制 转矩分配 parallel hybrid electric vehicle(PHEV) torque distribution hybrid powertrain control strategy fuzzy control
  • 相关文献

参考文献9

  • 1Jalil N, Kheir N A, Salman M. A rule-based energy management strategy for a series hybrid vehicle[A].Proc of the American Control Conference[C]. Albuquerque, New Mexico:IEEE, 1997. 689-693.
  • 2Johnson V H, Wipke K B, Rausen D J. HEV control strategy for real-time optimization of fuel economy and emissions[R]. SAE Paper, 2000-01-1543, 2000.
  • 3Lin C-C, Peng Huei, Grizzle J W, et al. Power management strategy for a parallel hybrid electric truck[J]. IEEE Transactions on Control Systems Technology, 2003, 11(6): 839-849.
  • 4Passino K M, Yurkovich S. Fuzzy control[M]. Menlo Park, Calif: Addison-Wesley, 1998.
  • 5Baumann B M, Washington G, Glenn B C, et al.Mechatronic design and control of hybrid electric vehicles[J]. IEEE/ASME Transactions on Mechatronics, 2000, 5(1): 58-72.
  • 6Schouten N J, Salman M A, Kheir N A. Fuzzy logic control for parallel hybrid vehicles[J]. IEEE Transactions on Control Systems Technology, 2002, 10 (3):460-468.
  • 7Gerhardt J, Honninger H, Bisehof H. A new approach to functional and software structure for engine management systems-BOSCH ME7[R]. SAE Paper,98P 178(49),1998.
  • 8PuJinhuan YinChengliang ZhangJianwu.ENERGY MANAGEMENT STRATEGY FOR PARALLEL HYBRID ELECTRIC VEHICLES[J].Chinese Journal of Mechanical Engineering,2005,18(2):215-219. 被引量:4
  • 9浦金欢,殷承良,张建武,马登哲.混合动力轿车的控制策略与建模[J].上海交通大学学报,2004,38(11):1917-1921. 被引量:11

二级参考文献19

  • 1Kazuo O. Overview of current and future hybrid technology [A]. Proceedings of the Symposium on Advanced Automotive Powerplants & Energy Resources[C]. Beijing: China SAE, 2002.89- 94.
  • 2Morita K. Automotive power source in 21st century[J]. JSAE Review, 2003, (24): 1- 7.
  • 3Zhang Rongjun, Chen Yaobin. Control of dybrid hynamic systems for electric vehicles[A]. Proceedings of the American Control Conference[C]. Arlington,VA: IEEE, 2001. 2884- 2889.
  • 4Wang A H, Chen Y B, Zhang R J. A novel design of energy management system of hybrid electric vehicles using evolutionary computation[A]. Proceedings of the 18th International Electric Vehicle Symposium[DB/CD]. Berlin,Germany:World Electric Vehicle Associa
  • 5Zhu Yuan, Chen Yaobin, Chen Quanshi. Analysis and design of an optimal energy management and control system for hybrid electric vehicles[A]. Proceedings of the 19th International Electric Vehicle Symposium[DB/CD]. Busan, Korea: World Electric Vehicle Asso
  • 6Paganelli G, Ercole G, Brahma A, et al. General supervisory control policy for the energy optimization of charge-sustaining hybrid electric vehicles [J].JSAE Review,2001, (22) :511-518.
  • 7Powell B K, Bailey K E, Cikanek S R. Dynamic modeling and control of hybrid electric vehicle powertrain systems [J]. IEEE Control Systems Magazine, 1998,18(5): 17- 33.
  • 8Johnson V H, Wipke K B, Rausen D J. HEV control strategy for real-time optimization of fuel economy and emissions[DB/OL]. SAE Paper 2000-01-1543,2000.
  • 9Sasaki S, Takaoka T, Matsui H, et al. Toyota's newly developed electric-gasoline engine hybrid powertrain system[A]. Proceedings of the 14th International Electric Vehicle Symposium[DB/CD]. Orlando, Florida, USA: World Electric Vehicle Association,1997.
  • 10Paganelli G, Tateno M. Control development for a hybrid-electric sport-utility vehicle: strategy, implementation and field test results[A]. Proceedings of the American Control Conference [C]. Arlington.VA:IEEE,2001. 5064-5069.

共引文献12

同被引文献199

引证文献25

二级引证文献234

相关作者

内容加载中请稍等...

相关机构

内容加载中请稍等...

相关主题

内容加载中请稍等...

浏览历史

内容加载中请稍等...
;
使用帮助 返回顶部