Research on two-dimensional fluid vibration axial transmission path model of axial piston pump

被引：0

作者：

Quan L. ^{[1
,2
]}

Bai R. ^{[1
]}

Zhang Q. ^{[1
]}

Liu S. ^{[1
]}

Lu Y. ^{[3
]}

机构：

[1] College of Mechanical Engineering, Yanshan University, Qinhuangdao

[2] Hebei Provincial Key Laboratory of Heavy Machinery Fluid Power Transmission and Control, Qinhuangdao

[3] Nanjing Engineering Institute of Aircraft System Jincheng AVIC, Nanjing

来源：

High Technology Letters | 2019年 / 25卷 / 01期

基金：

中国国家自然科学基金;

关键词：

Axial piston pump; Fluid vibration; Vibration response; Vibration transmission path;

D O I：

10.3772/j.issn.1006-6748.2019.01.007

中图分类号：

学科分类号：

摘要：

High speed and high pressure can enhance the vibration of axial piston pump. A fluid vibration transmission law of axial piston pump is studied in this paper. According to harmonic response analysis results, a transmission path analysis is used to establish a two-dimensional fluid vibration transmission path model in the vertical plane, which has characteristics of multi excitation sources, multi-path and multi-receptors. Model parameters are obtained by experimental and numerical analysis. Matlab is used to solve the model, and acceleration vibration response of three shells is got. To reduce the effect of mechanical vibration, the surface acceleration of pump is tested under low speed condition. Results show that the model can accurately reveal transmission law of fluid vibration and the accuracy is more than 90%. The research lays a foundation for exploring vibration transmission law and vibration control. Copyright © by HIGH TECHNOLOGY LETTERS PRESS.

引用

页码：48 / 56

页数：8

共 17 条

[1]

Quan L.X., Guo M., Shi J., Et al., Friction coupling vibration characteristics analysis of aviation hydraulic pipelines considering multi factors, High Technology Letters, 24, 2, pp. 180-188, (2018)

[2]

Liu W., Liu Y.S., Jiang Z.F., Et al., Pressure pulsation reliability analysis of hydraulic power pipelines, Journal of Vibration and Shock, 30, 6, pp. 265-268, (2011)

[3]

Vacca A., Klop R., Ivantysynova M., A numerical approach for the evaluation of the effects of air release and vapour cavitation on effective flow rate of axial piston machines, International Journal of Fluid Power, 11, 1, pp. 33-45, (2010)

[4]

Pelosi M., Ivantysynova M., Heat transfer and thermal elastic deformation analysis on the piston/cylinder interface of axial piston machines, Journal of Tribology, 134, 4, (2012)

[5]

Xu B., Song Y.C., Yang H.Y., Optimization of Swash-Plate Cross Angle Noise-Reduction Structure for Swash-Plate-Type Axial Piston pump, Journal of Zhejiang University (Engineering Science), 47, 6, pp. 1043-1050, (2013)

[6]

Xu B., Chao Q., Zhang J.H., Et al., Slipper optimization model based on equilibrium coefficient, Journal of Zhejiang University (Engineering Science), 49, 6, pp. 1009-1014, (2015)

[7]

Ozdemir O., Rienacker A., Fischer F., Et al., Thermo-Elastohydrodynamics of the Piston-Cylinder Contact in High-Pressure pumps, Mtz Worldwide, 79, 3, pp. 60-63, (2018)

[8]

Kim T., Ivantysynova M., Active vibration/noise control of axial piston machine using swash plate control, Proceedings of the ASME/BATH 2017 Symposium on Fluid Power and Motion Control, (2017)

[9]

Zhang J., Chao Q., Xu B., Analysis of the cylinder block tilting inertia moment and its effect on the performance of high-speed electro-hydrostatic actuator pumps of aircraft, Chinese Journal of Aeronautics, 31, 1, pp. 169-177, (2018)

[10]

Chao Q., Zhang J., Xu B., Et al., Discussion on the Reynolds equation for the slipper bearing modeling in axial piston pumps, Tribology International, 118, pp. 140-147, (2018)

← 1 2 →