Modeling of Sliding Electrical Contact Friction under Wave Loading

被引：0

作者：

Chen Z. ^{[1
]}

Dang W. ^{[1
]}

Shi G. ^{[1
]}

Wang X. ^{[1
]}

Liu F. ^{[2
]}

机构：

[1] Faculty of Electrical and Control Engineering, Liaoning Technical University, Huludao

[2] The East of Inner Monggol Electrical Power Company Kezuozhongqi Power Supply Company, Tongliao

来源：

Diangong Jishu Xuebao/Transactions of China Electrotechnical Society | 2019年 / 34卷 / 24期

关键词：

Coulomb+Viscous friction model; Fluctuating load; Friction model; Particle swarm optimization; Sliding electrical contact;

D O I：

10.19595/j.cnki.1000-6753.tces.181488

中图分类号：

学科分类号：

摘要：

During the sliding electrical contact of the pantograph catenary, the wear of the pantograph slide is intensified, which greatly shortens the service life of the pantograph slide. Since the wear problem of the pantograph slide is directly related to the sliding friction, it is important to study the sliding friction of the slide. In this paper, the Coulomb+Viscous static friction model was used to the model of sliding electrical contact friction. A new friction model was established by modifying the viscous friction part of the original friction model and introducing the factors, such as the contact current, contact force, and their fluctuation amplitude and fluctuation frequency. The experiment was carried out by self-developed sliding electrical contact experimental machine. Then the parameters of the new friction model were identified by particle swarm optimization and Matlab, and the improved friction model was verified. From the fitting effect diagram and residual plot, the improved friction model could reasonably predict the sliding electrical contact sliding friction force of pantograph catenary under the fluctuating load. © 2019, Electrical Technology Press Co. Ltd. All right reserved.

引用

页码：5126 / 5134

页数：8

共 23 条

[1] Bona B., Indri M., Smaldone N., Rapid prototyping of a model-based control with friction compensation for a direct-drive robot, IEEE/ASME Transactions on Mechatronics, 11, 5, pp. 576-584, (2006)
[2] Hola J., Cid Alfaro M.V., Rooij M.B.D.E., Et al., Advanced friction modeling for sheet metal forming, Wear, 286-287, 11, pp. 66-78, (2012)
[3] He Q., Lu Y., Yuan W., Et al., Modified friction model applied to servo system, Machine Tool & Hydraulics, 43, 11, pp. 148-151, (2015)
[4] Ling J., Du Z., Water film thickness- based dynamic pavementtire friction model, Journal of Tongji University: Natural Science, 44, 10, (2016)
[5] Tan W., Li X., Zhao X., Et al., Nonlinear friction modeling for servo systems in changed temperatures, Optics and Precision Engineering, 22, 8, pp. 2135-2141, (2014)
[6] Xu Z., Huang P., Calculating atomic scale frictional force with composite oscillator model, China Mechanical Engineering, 18, 21, pp. 2592-2596, (2007)
[7] Wei L., Liu Q., Zhang P., Sliding friction surface contact mechanics model based on fractal theory, Journal of Mechanical Engineering, 48, 17, pp. 106-113, (2012)
[8] Zhu S., Huang P., Calculation model of friction force of nano-scale rough surface on the basis of LJ potential and stochastic processes, Journal of South China University of Technology: Natural Science Edition, 44, 7, (2016)
[9] Xu Z., Huang P., Study on the energy method of calculating friction force, Science Technology and Engineering, 6, 15, (2006)
[10] Yuan D., Liu L., Liu H., Et al., Progress of pre-sliding friction model, Journal of System Simulation, 21, 4, pp. 1142-1147, (2009)

← 1 2 3 →