Research on dynamic characteristics of a multi-motor electric driving system caused by parasitic power

IF 0.6 4区 工程技术 Q4 MECHANICS Mechanika Pub Date : 2023-04-19 DOI:10.5755/j02.mech.32097
Ruizhi Shu, Zhengqiu Xie, Shuaishuai Ge, Qin Yin, Zhengyao Zou, Rulong Tan, Jianghua Fu
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Abstract

      To reduce greenhouse gas emissions in dealing with climate change, raplacing fule vehicles with electric vehicles (EVs) is one of the most effective measures. The multi-motor electric drive system (MMEDS), which is widely used in EVs, is driven by two or more permanent magnet synchronous motors (PMSM) by parallel shaft gear set (PSGS). Due to the action of forced synchronization of PSGS, once there is a rotational speed difference (∆V) between PMSMs, this will break the balance of output power between PMSMs and cause the increase in output power of some PMSMs while others decrease or even become negative, and eventually generate parasitic power. Parasitic power in MMEDS is bound to cause an autoexcitation vibration and a variation in dynamic characteristics of MMEDS. Therefore, in this paper, an electro-mechanical coupled dynamic model of MMEDS is set up, including a dynaimc model of PSGS and a dynaimc model of PMSM. Then, the affect of the forced synchronization action of PSGS on the dynamic characteristic of MMEDS is investigated under different ∆V. The results show that under the action of the forced synchronization of PSGS, the output power of the PMSM with a fast speed (or a slow speed) increase (or decreases) with the increasing of ∆V, and when ∆V ≤5 rpm, the increment rate or decrement rate of the output power of PMSM is obviously greater than that when ∆V>5 rpm. Meanwhile, ∆V has a singnificant effect on the nonlinearity of the vibration of the wheel, which increases first and then decreases with ∆V increases. The dominated frequencies of dynamic meshing force (DMF) of gear pair do not change with ∆V, but their contributions to the amplitude of the DMF change with ∆V. Moreover, the modulation frequencies also appear in the spectrum of the DMF, but their contributions to the amplitude of the DMF are singnificantly less than that of the dominated frequencies
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寄生功率引起的多电机电力驱动系统动态特性研究
在应对气候变化的过程中,减少温室气体排放,以电动汽车取代纯电动汽车是最有效的措施之一。多电机电驱动系统(MMEDS)是由两台或多台永磁同步电机(PMSM)通过并联轴齿轮组(PSGS)驱动,广泛应用于电动汽车中。由于PSGS的强制同步作用,一旦pmsm之间存在转速差(∆V),就会打破pmsm之间输出功率的平衡,导致部分pmsm输出功率增大,部分pmsm输出功率减小甚至变为负值,最终产生寄生功率。寄生功率必然会引起mmed的自激振动和动态特性的变化。为此,本文建立了mmed的机电耦合动态模型,包括PSGS的动态模型和PMSM的动态模型。然后,研究了不同∆V下PSGS的强制同步作用对mmed动态特性的影响。结果表明:在PSGS强制同步作用下,快速(或慢速)PMSM的输出功率随∆V的增大而增大(或减小),且当∆V≤5 rpm时,PMSM输出功率的增量或减少率明显大于∆V>5 rpm时。同时,∆V对车轮振动的非线性有显著影响,随∆V的增大,非线性先增大后减小。齿轮副动态啮合力(DMF)的主导频率不随∆V变化,但其对DMF幅值的贡献随∆V变化。此外,调制频率也出现在DMF的频谱中,但它们对DMF振幅的贡献明显小于主导频率
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来源期刊
Mechanika
Mechanika 物理-力学
CiteScore
1.30
自引率
0.00%
发文量
50
审稿时长
3 months
期刊介绍: The journal is publishing scientific papers dealing with the following problems: Mechanics of Solid Bodies; Mechanics of Fluids and Gases; Dynamics of Mechanical Systems; Design and Optimization of Mechanical Systems; Mechanical Technologies.
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