电动汽车“驱动-充电”一体化拓扑研究
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摘要
以减少电动汽车电机驱动器与电池充电器总体成本为目标,结合半功率升压技术提出了一种集成的电动汽车"驱动-充电"一体化拓扑结构及MTPA的弱磁控制策略。该一体化拓扑结构具有正向驱动和反向充电两种工作状态,在反向充电时共用正向驱动系统的主电路与控制电路,无需额外增加拓扑电路及功率器件,具有尺寸优势与成本优势。最后搭建仿真模型进行验证,结果表明,驱动状态下,满足驱动电机性能要求;充电状态下,也满足电池组在大功率充电模式下电流快速充电的要求,而且快速性与稳定性得以保证。研究通过仿真验证了"驱动-充电"一体化拓扑结构及相应控制策略的正确性与可行性,具有一定的推广价值与应用前景。
In order to reduce the total cost of electric motor drive and battery charger,an integrated driving and charging topology structure and MTPA's weak magnetic control strategy are proposed.The integration of topological structure has two working states,a positive driving and reverse charging,main circuit and control circuit in the reverse charge sharing positive driving system,with no need for additional circuit topology and power devices,and has the size advantage and cost advantage.Finally,a simulation model is built to verify the results.The results show that,under the driving condition,the motor can meet the performance requirements;under the state of charging,it can also meet the requirements of fast charging of the battery in the high power charging mode,and the rapidity and stability can be guaranteed.The simulation results verify the correctness and feasibility of the integrated structure and the corresponding control strategy,which is of great significance in application.
In order to reduce the total cost of electric motor drive and battery charger,an integrated driving and charging topology structure and MTPA's weak magnetic control strategy are proposed.The integration of topological structure has two working states,a positive driving and reverse charging,main circuit and control circuit in the reverse charge sharing positive driving system,with no need for additional circuit topology and power devices,and has the size advantage and cost advantage.Finally,a simulation model is built to verify the results.The results show that,under the driving condition,the motor can meet the performance requirements;under the state of charging,it can also meet the requirements of fast charging of the battery in the high power charging mode,and the rapidity and stability can be guaranteed.The simulation results verify the correctness and feasibility of the integrated structure and the corresponding control strategy,which is of great significance in application.
引文
[1] 崔玉峰,杨晴,张林山,等.国内外电动汽车发展现状及充电技术研究[J].云南电力技术,2010,38(2):9-12.
[2] 李耀华,马建,刘晶郁,等.电动汽车用永磁同步电机驱动系统控制策略比较研究[J].汽车工程,2013,35(5):413-417.
[3] 王必荣,郭兴众,王硕,等.半功率DCDC变换器自适应反演滑膜控制器设计[J].安徽工程大学学报,2016,31(2):60-63.
[4] 张硕,张承宁,王志福,等.电动汽车多动力耦合系统结构与分析[J].大功率变流技术,2012(5):47-50.
[5] 封焯文,粟梅,孙尧,等.用于电动汽车的双向交错式DC/DC变换器的设计[J].电力电子技术,2010,44(9):16-17.
[6] 朱黎丽,杜雄,刘延东.电动汽车用电机驱动控制器的设计与实现[J].电工技术,2013(12):79-81.
[7] 张奇,李珂,张承慧,等.电动汽车用永磁同步电机特性试验设计与研究[J].实验室研究与探索,2015,34(10):47-50.
[8] 丁硕,崔总泽,巫庆辉,等.基于SVPWM的永磁同步电机矢量控制仿真研究[J].国外电子测量技术,2014,33(6):81-85.
[9] 王庆龙,张兴,张崇巍.永磁同步电机矢量控制双滑模模型参考自适应系统转速辨识[J].中国电机工程学报,2014,34(6):897-902.
[10] 冯继营,李向超,李家武.基于SVPWM的永磁同步电机矢量控制系统设计[J].电子元器件应用,2010,12(9):50-52.
[2] 李耀华,马建,刘晶郁,等.电动汽车用永磁同步电机驱动系统控制策略比较研究[J].汽车工程,2013,35(5):413-417.
[3] 王必荣,郭兴众,王硕,等.半功率DCDC变换器自适应反演滑膜控制器设计[J].安徽工程大学学报,2016,31(2):60-63.
[4] 张硕,张承宁,王志福,等.电动汽车多动力耦合系统结构与分析[J].大功率变流技术,2012(5):47-50.
[5] 封焯文,粟梅,孙尧,等.用于电动汽车的双向交错式DC/DC变换器的设计[J].电力电子技术,2010,44(9):16-17.
[6] 朱黎丽,杜雄,刘延东.电动汽车用电机驱动控制器的设计与实现[J].电工技术,2013(12):79-81.
[7] 张奇,李珂,张承慧,等.电动汽车用永磁同步电机特性试验设计与研究[J].实验室研究与探索,2015,34(10):47-50.
[8] 丁硕,崔总泽,巫庆辉,等.基于SVPWM的永磁同步电机矢量控制仿真研究[J].国外电子测量技术,2014,33(6):81-85.
[9] 王庆龙,张兴,张崇巍.永磁同步电机矢量控制双滑模模型参考自适应系统转速辨识[J].中国电机工程学报,2014,34(6):897-902.
[10] 冯继营,李向超,李家武.基于SVPWM的永磁同步电机矢量控制系统设计[J].电子元器件应用,2010,12(9):50-52.
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