为揭示行星变速机构内部激励与振动特性的映射关系,通过设计行星变速机构振动测试方案,建立了行星变速机构振动加速度测试系统,并进行了典型挡位2 500 r/min行星变速机构振动特性的测试与分析。结果表明:行星变速机构振动的均方根(RMS)值与测点的位置相关联,测点位置在行星齿轮啮合位置,其振动幅值较大;随着转矩增大,其振动RMS值也增大。行星变速机构的频谱分析结果表明,其振动能量主要集中于行星齿轮啮合的啮合频率及倍频,且轴向的频谱和径向上的频谱比较相似。通过行星变速机构振动RMS的测定和频谱值的分析,得到了各位置啮合振动的最大幅值。本研究对行星变速机构的优化设计具有一定的参考价值。
Abstract
In order to reveal the mapping relationship between internal excitation and vibration characteristics of planetary transmission mechanism, a vibration acceleration measurement system of planetary transmission mechanism was established by designing a vibration test scheme, and the vibration characteristics of typical gearshift 2 500 r/min planetary transmission mechanism were measured and analyzed. The results show that the vibration root mean square (RMS) value of planetary transmission mechanism is correlated with the position of measuring point. The measuring point is in the meshing position of planetary gear, and its vibration amplitude is larger. The vibration RMS value increases with the increase in the torque. The frequency spectrum analysis results show that the vibration energy mainly concentrates on the meshing frequency and multiple frequencies of planetary gears, and the axial frequency spectrum is similar to the radial frequency spectrum. The maximum amplitude of meshing vibration is obtained by measuring the vibration of planetary transmission mechanism and analyzing its frequency spectrum. Key
关键词
履带车辆 /
行星变速机构 /
振动测试 /
振动特性分析 /
频谱分析
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Key words
trackedvehicle /
planetarytransmissionmechanism /
vibrationmeasurement /
vibrationcharacteristicsanalysis /
spectrumanalysis
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基金
国家国防科技工业局车用动力专项基金项目(VTDP-3202)
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参考文献
[1]生辉,盖江涛,李春明,等. 高速电驱动履带车辆联合制动转矩动态协调控制研究[J].兵工学报, 2017, 38(5):1028-1034.
SHENG H, GAI J T, LI C M, et al. Coordinated control of high speed electric drive tracked vehicle[J]. Acta Armamentarii, 2017, 38(5):1028-1034.(in Chinese)
[2]CHENZ G, SHAO Y M. Dynamic simulation of spur gear with tooth root crack propagating along tooth width and crack depth[J]. Engineering Failure Analysis, 2011, 18(8): 2149-2164.
[3]王钦龙,王红岩,芮强. 基于多目标遗传算法的高速履带车辆动力学模型参数修正研究[J]. 兵工学报, 2016, 37(6):969-978.
WANG Q L, WANG H Y, RUI Q. Research on parameter updating of high mobility tracked vehicle dynamic model based on multi-objective genetic algorithm[J]. Acta Armamentarii, 2016, 37(6):969-978. (in Chinese)
[4]ZIEGLERP, EBERHARD P, SCHWEIZER B. Simulative and experimental investigation of impacts on gear wheels[J]. Computer Methods in Applied Mechanics and Engineering, 2008, 197(51/52):4653-4662.
[5]张晓萍,王玉林,杜明刚,等. 综合传动装置内部激励与箱体振动特征的试验研究[J].兵工学报, 2016, 37(3):535-540.
ZHNG X P,WANG Y L,DU M G. Experimental study of internal excitation and vibration of an integrated transmission device[J]. Acta Armamentarii, 2016, 37(3):535-540. (in Chinese)
[6]PETRY-JOHNSONT T, KAHRAMAN A, ANDERSON N E, et al.An experimental investigation of spur gear effciency[J]. Journal of Mechanical Design, 2008, 130(6): 062601.
[7]OTTEWILL J R, NEILD S A, WILSON R E. Intermittent gear rattle due to interactions between forcing and manufacturing errors[J]. Journal of Sound and Vibration, 2009, 321(3/4/5): 913-935.
[8]BOTMAN M. Vibration measurements on planetary gears of aircraft turbine engines [J]. Journal of Aircraft, 2015, 17(5): 351-357.
[9]INALPOLAT M, KAHRAMAN A. A dynamic model to predict modulation sidebands of a planetary gear set having manufacturing errors[J]. Journal of Sound and Vibration, 2010, 329(4):371-393.
[10]ERICSONT M, PARKER R G. Planetary gear modal vibration experiments and correlation against lumped-parameter and finite element models[J]. Journal of Sound and Vibration, 2013, 332(9): 2350-2375.
第40卷第6期
2019年6月兵工学报ACTA
ARMAMENTARIIVol.40No.6Jun.2019
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脚注
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