吉林大学学报(工学版) ›› 2015, Vol. 45 ›› Issue (3): 806-813.doi: 10.13229/j.cnki.jdxbgxb201503018

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Electro-magnetic-thermal coupling of GDI injector

CHENG Qiang1, ZHANG Zhen-dong1, GUO Hui2, XIE Nai-liu1   

  1. 1.Institute of Automotive Engineering, University of Shanghai for Science and Technology, Shanghai 200093,China;
    2.College of Automotive Engineering, Shanghai University of Engineering Science, Shanghai 201620,China
  • Received:2013-08-19 Online:2015-05-01 Published:2015-05-01

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Abstract: Temperature rise greatly impacts the performance of the GDI injector and causes the ECU of an engine difficult to control fuel quantity accurately. According to the coupling relationship of electric, magnetic and thermal subsystems of the GDI injector, the physical model of the coupling process was established. The energy loss and transformation of the GDI injector in working process was explored. It is revealed that the loss of electromagnetic conversion is a key factor to cause the temperature rise of the GDI injector. The energy dissipation as heat source and the temperature field of the GDI injector was analyzed based on the finite element equation of the heat conduction and thermal radiation. The temperature field of the injector was simulated using ANSYS software; then the simulation results were verified by experiment. The effects of the temperature field distribution and the temperature rise variation on the performance of the GDI injector were analyzed. Results show that higher temperature rise is concentrated on the coil and core part, the response time of GDI injector gets longer as the temperature rises, and the injection quantity becomes lower. The value and the pulse width of the holding current have great impact on the GDI injector performance and temperature rise.

Key words: power machinery and engineering, gasoline direct injection(GDI) injector, electric-magnetic-thermal coupling, finite element simulation, dynamic response

CLC Number: 

  • TK413
[1] Naseradinmousavi P,Nataraj C. Nonlinear mathematical modeling of butterfly valves driven by solenoid actuators[J]. Applied Mathematical Modeling,2011,35(5):2324-2335.
[2] Taghizadeh M,Ghaffari A,Najafi F. Modeling and identification of a solenoid valve for PWM control applications[J]. Comptes Rendus Mecanique,2009,337(3):131-140.
[3] Cvetkovic D,Cosic I,Subic A. Improved performance of the electromagnetic fuel injector solenoid actuator using a modelling approach[J]. International Journal of Applied Electromagnetics and Mechanics,2008,27(4):251-273.
[4] Wang T, Silaen A,Hsu H W,et al. Investigation of heat transfer and gasification of two different fuel injectors in an entrained flow coal gasifier[J]. Journal of Thermal Science and Engineering Applications,2010,3(2):1-10.
[5] Befrui B, Corbinelli G,Spiekermann P. Large eddy simulation of GDI single-hole flow and near-field spray[C]∥SAE Paper,2012-01-0392.
[6] Zhang Yu-jiao,Ruan Jiang-jun,Huang Tao, et al. Calculation of temperature rise in air-cooled induction motors through 3-D coupled electromagnetic fluid- dynamical and thermal finite-element analysis[J]. IEEE Transactions on Magnetics,2012,48(2):1047-1050.
[7] Ricco M, De Matthaeis S,Olabi A G. Simulation of the magnetic properties for common rail electro-injector[J]. Journal of Materials Processing Technology,2004,155-156:1611-1615.
[8] Zhao N N,Zhu Z Q, Liu W G. Rotor eddy current loss calculation and thermal analysis of permanent magnet motor and generator[J]. IEEE Transactions on Magnetics,2011,47(10):4199-4202.
[9] 张雪彪,杨玉龙,刘玉君. 钢板高频感应加热过程电磁-热耦合场分析[J]. 大连理工大学学报,2012,52(5):676-682.
Zhang Xue-biao,Yang Yu-long,Liu Yu-jun. Analyses of electromagnetic-thermal coupling field for high frequency induction heating process of steel plat[J]. Journal of Dalian University of Technology,2012,52(5):676-682.
[10] 梁振光,唐任远. 电磁阀铁心涡流损耗的解析解[J]. 中国电机工程学报,2005,25(9):153-157.
Liang Zhen-guang, Tang Ren-yuan. Analytical solution of eddy current loss in core of an electromagnetic valve[J]. Proceedings of the CSEE,2005,25(9):153-157.
[11] 宋睿智,李丽,夏少华,等. 汽油直喷高压泵电磁阀线圈设计与电磁特性仿真[J]. 现代车用动力,2012,11(4):10-13.
Song Rui-zhi,Li Li,Xia Shao-hua,et al. Coil design and electromagnetic characteristics simulation of solenoid valve for high-pressure pump of gasoline direct injection system[J]. Moden Vhicle Power,2012,11(4):10-13.
[12] 林抒毅,许志红. 交流电磁阀三维温度特性仿真分析[J]. 中国电机工程学报,2012,32(36),156-164.
Lin Shu-yi, Xu Zhi-hong. Simulation and analysis on three-dimensional temperature field of AC solenoid valves[J]. Proceedings of the CSEE,2012,32(36),156-164.
[13] Naseradinmousavi P, Nataraj C. Transient chaos and crisis phenomena in butterfly valves driven by solenoid actuators[J]. Communications in Nonlinear Science and Numerical Simulation,2012,17(11):4336-4345.
[14] Zhao J F,Seethaler R J. Compensating combustion forces for automotive electromagnetic valves[J]. Mechatronics,2010,20(4):433-441.
[15] Staton D,Šušnjic L. Induction motors thermal analysis[J]. Strojarstvo,2009,51(6):623-631.
[16] 沈建新,李鹏,郝鹤,等. 高速永磁无刷电机电磁损耗的研究概况[J]. 中国电机工程学报,2013,33(3):62-74.
Shen Jian-xin, Li Peng, Hao He,et al. Study on electromagnetic losses in high-speed permanent magnet brushless machines-the state of the art[J]. Proceedings of the CSEE,2013,33(3):62-74.
[17] Baranski M,Szelag W. Finite-element analysis of transient electromagnetic-thermal phenomena in a squirrel-cage motor working at cryogenic temperature[J]. IET Science Measurement & Technology,2011,6(5):357-363.
[18] Wang Q L,Yang F Y,Yang Q A,et al. Experimental analysis of new high-speed powerful digital solenoid valves[J]. Energy Conversion and Management,2011,52(5):2309-2313.
[19] Liu Qiang-feng,Bo Han-liang,Qin Ben-ke . Design and analysis of direct action solenoid valve based on computational intelligence[J]. Nuclear Engineering and Design,2010,240(10):2890-2896.
[20] 纽春萍,陈德桂,刘颖异,等.计及主回路和电磁系统发热的交流接触器数值热分析[J].中国电机工程学报,2007,27(15):53-58.
Niu Chun-ping,Chen De-gui,Liu Ying-yi,et al.Thermal simulation of AC contactor considering the heat generated by main circuit and electromagnet system[J].Proceedings of the CSEE,2007,27(15):53-58.
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