Analysis of Snow Distribution and Displacement in the Bogie Region of a High-Speed Train

被引：0

作者：

Du, Zhihui ^{[1
]}

Yu, Mengge ^{[1
]}

Liu, Jiali ^{[2
]}

Yao, Xiulong ^{[1
]}

机构：

[1] College of Mechanical and Electrical Engineering, Qingdao University, Qingdao

[2] National Engineering Research Center for High-Speed EMU, CRRC Qingdao Sifang Co., Ltd., Qingdao

来源：

Fluid Dynamics and Materials Processing | 2024年 / 20卷 / 07期

基金：

中国国家自然科学基金;

关键词：

Bogie; particle diameter distribution; the wind-snow multiphase flow model;

D O I：

10.32604/FDMP.2024.047315

中图分类号：

学科分类号：

摘要：

Snow interacting with a high-speed train can cause the formation of ice in the train bogie region and affect its safety. In this study, a wind-snow multiphase numerical approach is introduced for high-speed train bogies on the basis of the Euler-Lagrange discrete phase model. A particle-wall impact criterion is implemented to account for the presence of snow particles on the surface. Subsequently, numerical simulations are conducted, considering various snow particle diameter distributions and densities. The research results indicate that when the particle diameter is relatively small, the distribution of snow particles in the bogie cavity is relatively uniform. However, as the particle diameter increases, the snow particles in the bogie cavity are mainly located in the rear wheel pairs of the bogie. When the more realistic Rosin-Rammler diameter distribution is applied to snow particles, the positions of snow particles with different diameters vary in the bogie cavity. More precisely, smaller diameter particles are primarily located in the front and upper parts of the bogie cavity, while larger diameter snow particles accumulate at the rear and in the lower parts of the bogie cavity. © (2024), (Tech Science Press). All rights reserved.

引用

页码：1687 / 1701

页数：14

共 38 条

[1] Li T, Liang H, Zhang J, Zhang J., Numerical study on aerodynamic resistance reduction of high-speed train using vortex generator, Eng Appl Comp Fluid, 17, 1, (2023)
[2] Kloow L, Jenstav M., High-speed train operation in winter climate, Transrail Publication BVF5, 2, pp. 1-77, (2011)
[3] Guo Z, Liu T, Chen Z, Xia Y, Li W, Li L., Aerodynamic influences of bogie’s geometric complexity on high-speed trains under crosswind, J Wind Eng Ind Aerod, 196, (2020)
[4] You J, Chen Y, Yang Z., Influence of the wheel rotation on underbody flow and aerodynamic forces of high speed train, Procedia Eng, 126, pp. 399-404, (2015)
[5] Xia C, Wang H, Shan X, Yang Z, Li Q., Effects of ground configurations on the slipstream and near wake of a high-speed train, J Wind Eng Ind Aerod, 168, pp. 177-189, (2017)
[6] Zhang J, Li JJ, Tian HQ, Gao GJ, Sheridan J., Impact of ground and wheel boundary conditions on numerical simulation of the high-speed train aerodynamic performance, J Fluid Struct, 61, pp. 249-261, (2016)
[7] Paz C, Suarez E, Gil C, Cabarcos A., Effect of realistic ballasted track in the underbody flow of a high-speed train via CFD simulations, J Wind Eng Ind Aerod, 184, pp. 1-9, (2019)
[8] Garcia J, Crespo A, Berasarte A, Goikoetxea J., Study of the flow between the train underbody and the ballast track, J Wind Eng Ind Aerod, 99, 10, pp. 1089-1098, (2011)
[9] Tominaga Y., Computational fluid dynamics simulation of snowdrift around buildings: past achievements and future perspectives, Cold Reg Sci Technol, 150, pp. 2-14, (2018)
[10] Beyers M, Waechter B., Modeling transient snowdrift development around complex three-dimensional structures, J Wind Eng Ind Aerod, 96, 10–11, pp. 1603-1615, (2008)

← 1 2 3 4 →