STEADY-STATE AND IDLE OPTIMIZA-TION OF INTERNAL COMBUSTION ENGINE CONTROL STRATEGIES FOR HYBRID ELECTRIC VEHICLES 被引量：6

STEADY-STATE AND IDLE OPTIMIZA-TION OF INTERNAL COMBUSTION ENGINE CONTROL STRATEGIES FOR HYBRID ELECTRIC VEHICLES

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摘要 A novel steady-state optimization （SSO） of internal combustion engine （ICE） strategy is proposed to maximize the efficiency of the overall powertrain for hybrid electric vehicles, in which the ICE efficiency, the efficiencies of the electric motor （EM） and the energy storage device are all explicitly taken into account. In addition, a novel idle optimization of ICE strategy is implemented to obtain the optimal idle operating point of the ICE and corresponding optimal parking generation power of the EM using the view of the novel SSO of ICE strategy. Simulations results show that potential fuel economy improvement is achieved relative to the conventional one which only optimized the ICE efficiency by the novel SSO of ICE strategy, and fuel consumption per voltage increment decreases a lot during the parking charge by the novel idle optimization of ICE strategy. A novel steady-state optimization （SSO） of internal combustion engine （ICE） strategy is proposed to maximize the efficiency of the overall powertrain for hybrid electric vehicles, in which the ICE efficiency, the efficiencies of the electric motor （EM） and the energy storage device are all explicitly taken into account. In addition, a novel idle optimization of ICE strategy is implemented to obtain the optimal idle operating point of the ICE and corresponding optimal parking generation power of the EM using the view of the novel SSO of ICE strategy. Simulations results show that potential fuel economy improvement is achieved relative to the conventional one which only optimized the ICE efficiency by the novel SSO of ICE strategy, and fuel consumption per voltage increment decreases a lot during the parking charge by the novel idle optimization of ICE strategy.

作者 WANG Feng MAO Xiaojian YANG Lin ZHUO Bin

机构地区 School of Mechanical Engineering

出处《Chinese Journal of Mechanical Engineering》 SCIE EI CAS CSCD 2008年第2期58-64,共7页 中国机械工程学报（英文版）

基金 National Hi-tech Research end Development Program of China (863 Program,No.2002AA501700,No.2003AA501012)

关键词 Hybrid electric vehicle Internal combustion engine Steady-state optimization Idle optimization Energy conversion Hybrid electric vehicle Internal combustion engine Steady-state optimization Idle optimization Energy conversion

分类号 U469.1 [机械工程—车辆工程]

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参考文献1

1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10

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10

1殷承良,浦金欢,张建武.并联混合动力汽车的模糊转矩控制策略[J].上海交通大学学报,2006,40(1):157-162. 被引量：25
2浦金欢,殷承良,张建武.并联型混合动力汽车燃油经济性最优控制[J].上海交通大学学报,2006,40(6):947-951. 被引量：31
3黄贤广,何洪文.混合动力车辆动力系统建模与仿真[J].车辆与动力技术,2008(2):43-48. 被引量：4
4董悦航,殷承良,张建武,陈俐.基于AMT的变速驱动单元及在混合动力汽车中应用[J].系统仿真学报,2008,20(13):3553-3557. 被引量：2
5王臣涛.基于记忆学习矩阵的混合动力控制策略[J].北京汽车,2010(4):17-19.
6李鹏,周云山,王楠.并联式混合动力再生制动系统控制策略研究[J].计算机仿真,2011,28(12):361-365. 被引量：6
7胡斐,赵治国.基于能量管理的混合动力城市客车建模及实车验证[J].汽车工程,2013,35(1):2-6. 被引量：1
8楼狄明,曹卢,宋业栋,谭丕强,胡志远.串联式混合动力推土机控制策略的优化[J].中国工程机械学报,2013,11(2):133-137. 被引量：1
9孙永将.纯电动载货汽车的匹配研究[J].轻型汽车技术,2013(5):7-11. 被引量：1
10张雪松,李雪亭,刘有朋.并联混合动力汽车离合器的逻辑门限控制研究[J].机械传动,2018,42(8):39-45.

同被引文献76

1张翔,钱立军,张炳力,赵韩.电动汽车仿真软件进展[J].系统仿真学报,2004,16(8):1621-1623. 被引量：46
2张毅,杨林,李立明,卓斌.电动汽车无刷直流电动机的回馈制动控制[J].上海交通大学学报,2005,39(9):1457-1460. 被引量：22
3何忠波,白鸿柏,张培林,孔庆春.发动机动态特性及其对车辆换档特性的影响[J].军械工程学院学报,2005,17(5):17-20. 被引量：10
4叶明,秦大同,刘振军.基于AMT的轻度混合动力系统再生制动控制[J].机械工程学报,2006,42(10):156-160. 被引量：10
5秦大同,颜静,杨阳,胡建军,杨亚联.HEV再生制动过程中CVT速比控制策略[J].重庆大学学报（自然科学版）,2007,30(1):1-5. 被引量：8
6JOHANNESSON L, ASBOGARD M, EGARDT B. Assessing the Potential of Predictive Control for Hy brid Vehicle Powertrains Using Stochastic Dynamic Programming[J]. IEEE Transactions on Intelligent Transportation Systems, 2007,8 ( 1 ):71-83.
7RODATZ P, PAGANELLI G, SCIARRETTA A, et al. Optimal Power Management of an Experimental Fuel Cell/Supercapacitor-powered Hybrid Vehicle [J]. Control Engineering Practice, 2005, 13 (1) : 41-53.
8ZHONG Hu,WANG Feng, AO Guo-qiang, et al. An Optimal Torque Distribution Strategy for an Integrated Starter-generator Parallel Hybrid Electric Vehicle Based on Fuzzy Logic Control[J]. Journal of Automobile Engineering, 2008,222 ( 1 ): 79-92.
9WANG Feng, MAO Xiao j ian, ZHUO Bin. Integrated Starter Generator Hybrid Electric Car Torque Distribution Control[J]. SAE Paper 2008-01-1554.
10WANG Feng, ZHONG Hu, MAO Xiao jian, et al. Regenerative Braking Algorithm for a Parallel Hybrid Electric Vehicle with Continuously Variable Transmission[C]//IEEE. IEEE International Conference on Vehicular Electronics and Safety. Beijing: IEEE, 2007:55-58.

引证文献6

1王锋,冒晓建,卓斌,钟虎,马兹林.AMT混合动力系统驱动模式能量优化控制[J].吉林大学学报（工学版）,2009,39(S1):14-17. 被引量：3
2王锋,冒晓建,卓斌,钟虎,马兹林.电磁耦合混合动力公交车运行点协调控制[J].中国公路学报,2009,22(1):109-115. 被引量：1
3王锋,钟虎,马兹林,冒晓建,卓斌.滑行工况下混合动力系统的再生制动[J].华南理工大学学报（自然科学版）,2009,37(7):62-68. 被引量：5
4林歆悠,孙冬野,尹燕莉,郝允志.混联式混合动力客车发动机优化控制策略[J].重庆大学学报（自然科学版）,2012,35(7):13-18. 被引量：3
5WANG Cunlei,ZHANG Jianlong,YIN Chengliang.Novel Application-oriented Transient Fuel Model of a Port Fuel Injection S. I. Engine[J].Chinese Journal of Mechanical Engineering,2014,27(2):348-357. 被引量：1
6林歆悠,翟柳清,林海波.基于行驶工况的混合动力电动汽车能量管理策略研究现状分析[J].河北科技大学学报,2016,37(5):457-463. 被引量：8

二级引证文献21

1朱玙熹,崔海峰,马加奇,夏天.新能源车再生制动系统制动踏板感觉研究[J].传动技术,2020(2):12-16.
2董翔宇,陈慧岩,李春芾.重型商用混合动力车自动变速技术综述[J].机械传动,2010,34(12):75-79. 被引量：3
3周健豪,袁银男,陈笃红,邵斌,王存磊.混合动力汽车动力总成试验台测控系统[J].农业机械学报,2011,42(7):36-40. 被引量：8
4金纯,郑舒阳,田海永.电传动车辆反拖系统设计与分层控制策略研究[J].农业机械学报,2014,45(4):22-27. 被引量：8
5胡登兴,饶建伟.新普锐斯混合动力汽车系统结构与故障诊断[J].中国高新技术企业,2015(6):117-119. 被引量：4
6曹杰,汪华章,陈超.基于MATLAB仿真的电动车滑行自充电系统设计[J].电源技术,2015,39(12):2626-2630. 被引量：1
7林歆悠,翟柳清,林海波.基于行驶工况的混合动力电动汽车能量管理策略研究现状分析[J].河北科技大学学报,2016,37(5):457-463. 被引量：8
8黄永军,陈国华,郎静,魏冰.基于组合油膜模型的PFI汽油机瞬态油膜补偿策略研究[J].内燃机工程,2017,38(2):151-156.
9曹磊,陈长文,孙强.基于马尔可夫链的汽车行驶工况预测[J].内燃机与动力装置,2017,34(3):13-17. 被引量：5
10孙哲浩,张彤.混合动力汽车动力系统和策略研究发展现状[J].时代汽车,2018(8):36-37. 被引量：2

1东风本田CR—V两款入门车型增配[J].汽车与驾驶维修（汽车版）,2016,0(4):20-20.
2余卓平,陈礼璠,彭晓勇,林志兴,施宗城.缩尺模型风洞试验及其在汽车开发中的作用[J].同济大学学报（自然科学版）,1997,25(5):532-536.
3劳远盛.汽车装用的动力装置在变化中——为节能减排创造条件[J].交通与运输,2010(1):20-21.
4张彩萍,Zhang Chengning,Liu Jiazhong,Sharkh S M.Identification of dynamic model parameters for lithium-ion batteries used in hybrid electric vehicles[J].High Technology Letters,2010,16(1):6-12. 被引量：4
5谢永和.船体舱段优化设计[J].船舶工程,2005,27(2):29-32. 被引量：6
6Sheng JIN,Zhi-yi HUANG,Peng-fei TAO,Dian-hai WANG.Car-following theory of steady-state traffic flow using time-to-collision[J].Journal of Zhejiang University-Science A(Applied Physics & Engineering),2011,12(8):645-654. 被引量：3
7李海艳,He Yijun.Detection of weak ship signals with the optimization of polarimetric contrast enhancement[J].High Technology Letters,2008,14(1):85-91. 被引量：6
8曹建国,廖然,杨利花.燃料电池电动汽车发展现状与前景[J].新材料产业,2015(4):58-63. 被引量：20
9王颖亮,于海生,张欣.混合动力电动汽车性能的优化研究(续1)[J].天津汽车,2006(5):20-22.
10隗寒冰,LIU Xiao-fei,HE Yi-tuan,PENG Zhi-yuan.Multi-objective comprehensive optimization of fuel consumption and emission for hybrid electric vehicles[J].Journal of Chongqing University,2014,13(4):131-141. 被引量：1

Chinese Journal of Mechanical Engineering

2008年第2期

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