«Previous Article|Table of Contents|Next Article»

《交通运输工程学报》[ISSN:1671-1637/CN:61-1369/U]

Issue:

2021年03期

Page:

311-322

Research Field:

载运工具运用工程

Publishing date:

Info

Title:

Characteristics of wind-snow flow around motor and trailer bogies of high-speed train

Author(s):

CAI Lu;  LOU Zhen;  LI Tian;  ZHANG Ji-ye

(State Key Laboratory of Traction Power, Southwest Jiaotong University, Chengdu 610031, Sichuan, China)

Keywords:

high-speed train;  bogie;  wind-snow flow;  discrete phase model;  snow accumulation

PACS:

U270.32

DOI:

10.19818/j.cnki.1671-1637.2021.03.023

Abstract:

When a high-speed train runs on a snow-covered track in winter, wind-snow flow calculation models of a motor bogie and a trailer bogie were established by using the Euler-Lagrange gas-solid two-phase flow approach to investigate the difference in snow particles motion characteristics between the motor and trailer bogie. The motion characteristics of snow particles in bogie region and the impact characteristics between snow particles and walls were analyzed. Research results show that the airflow paths in the trailer and motor bogie regions are similar. The airflow in the rear of wheelsets rolls up into the bogie region and rotates around the two wheelsets. The positive pressure generated by the reverse flow in the trailer bogie region exceeds that of the motor bogie. When the traction motor is ventilated, the reverse flow around the front and rear wheelsets in the bogie region significantly increases compared with the case without ventilation. The snow particle residence time in the motor bogie region increases from 1.10 s up to 1.13 s owing to the exhaust air of the traction motor. It is unconducive for snow particles to flow out of the motor bogie region. The snow particles easily enter the upper space of trailer bogie region and are captured by the trailer bogie is 42.8% more than that of the motor bogie region during the same period. Except for the axle box, the snow particles captured by the rear part of motor bogie are lower than those captured by the front part. Except for the wheelsets, the snow particles captured by the rear part of trailer bogie exceed those captured by the front part. The airflow at the traction motor outlet increases the incident snow particles on the front parts of the bogie and decreases the incident snow particles on the middle parts of the bogie. The partial airflow exhausted out by the traction motor rotates around the wheelsets, causing more snow particles underneath the bogie to roll up into the bogie region. Therefore, the snow particles hitting the front axle box and brake components increase by 20% and 17%, respectively. The incident area of snow particles on bogie is mainly distributed to the parts directly impacted by the incoming flow underneath the vehicle and by the backflow from the rear of bogie. 4 tabs, 18 figs, 30 refs.

References:

[1] 姚起杭,姚 军.结构振动疲劳问题的特点与分析方法[J].机械科学与技术,2000,19(增1):56-58.
YAO Qi-hang,YAO Jun. The behavior and analysis of structure vibration fatigue[J]. Mechanical Science and Technology, 2000, 19(S1): 56-58.(in Chinese)
[2] 林晓斌.基于功率谱密度信号的疲劳寿命估计[J].中国机械工程,1998,9(11):16-19.
LIN Xiao-bin. An engineering approach for the prediction of multiaxial fatigue life[J]. China Mechanical Engineering, 1998, 9(11): 16-19.(in Chinese)
[3] WIRSCHING P H, SHEHATA A M. Fatigue under wide band random stresses using the rain-flow method[J]. Journal of Engineering Materials and Technology, 1977, 99(3): 205-211.
[4] TUNNA J M. Fatigue life prediction for Gaussian random
loads at the design stage[J]. Fatigue and Fracture of Engineering Materials and Structures, 1986, 9(3): 169-184.
[5] DIRLIK T. Application of computers in fatigue analysis[D]. Coventry: University of Warwick, 1985.
[6] ZHAO W, BAKER M J. On the probability density function of rainflow stress range for stationary Gaussian processes[J]. International Journal of Fatigue, 1992, 14(2): 121-135.
[7] TOVO R. Cycle distribution and fatigue damage under broad-band random loading[J]. International Journal of Fatigue, 2002, 24(11): 1137-1147.
[8] BENASCIUTTI D, TOVO R. Spectral methods for lifetime prediction under wide-band stationary random processes[J]. International Journal of Fatigue, 2005, 27(8): 867-877.
[9] 韩鲁明.基于CAE技术的某半挂车车架疲劳寿命预估研究[D].南京:南京理工大学,2007.
HAN Lu-ming.A prediction approach for fatigue life of a semi-trailer frame based on finite element analysis(FEA)and dynamics multibody system[D]. Nanjing: Nanjing University of Science and Technology, 2007.(in Chinese)
[10] 石怀龙,王建斌, 戴焕云,等.地铁车辆轴箱吊耳断裂机理和试验研究[J].机械工程学报,2019,55(6):122-128.
SHI Huai-long, WANG Jian-bin, DAI Huan-yun, et al. Crack mechanism and field test of the metro safety hanger[J]. Journal of Mechanical Engineering, 2019, 55(6): 122-128.(in Chinese)
[11] 连青林,刘志明,王文静.提速客车转向架安全吊座疲劳失效机理与改进方法[J].交通运输工程学报,2018,18(1):71-78.
LIAN Qing-lin, LIU Zhi-ming, WANG Wen-jing. Fatigue failure mechanism and improvement method of safety suspender mounting base of speed-up passenger car bogie[J]. Journal of Traffic and Transportation Engineering, 2018, 18(1): 71-78.(in Chinese)
[12] 薛 海,李 强.地铁车辆天线梁振动加速度及动应力试验[J].北京交通大学学报,2015,39(4):33-36.
XUE Hai, LI Qiang. Test study on vibration and dynamic stress of subway vehicle's antenna beam[J]. Journal of Beijing Jiaotong University, 2015, 39(4): 33-36.(in Chinese)
[13] 张 丽,任尊松,孙守光,等.考虑齿轮传动影响的高速动车组电机吊架载荷及动应力研究[J].机械工程学报,2016,52(4):133-140.
ZHANG Li, REN Zun-song, SUN Shou-guang, et al. Research on dynamic load and stress of high-speed EMU motor hanger considering influence of gear transmission system[J]. Journal of Mechanical Engineering, 2016, 52(4): 133-140.(in Chinese)
[14] ZHI Peng-peng, XU Yue, CHEN Bing-zhi. Time-dependent reliability analysis of the motor hanger for EMU based on stochastic process[J]. International Journal of Structural Integrity, 2019, 11(3): 453-469.
[15] LI Fan-song, WU Ping-bo, ZENG Jing, et al. Vibration
fatigue dynamic stress simulation under multi-load input condition: application to metro lifeguard[J]. Engineering Failure Analysis, 2019, 99(1): 141-152.
[16] 沈彩瑜.铁道车辆转向架构架疲劳强度研究[D].成都:西南交通大学,2014.
SHEN Cai-yu. Fatigue strength analysis of the welded bogie frame for railway vehicle[D]. Chengdu: Southwest Jiaotong University, 2014.(in Chinese)
[17] 赵永翔,杨 冰,彭佳纯,等.铁道车辆疲劳可靠性设计Goodman-Smith图的绘制与应用[J].中国铁道科学,2005,26(6):8-14.
ZHAO Yong-xiang, YANG Bing, PENG Jia-chun, et al. Drawing and application of Goodman-Smith diagram for the design of railway vehicle fatigue reliability[J]. China Railway Science, 2005, 26(6): 8-14.(in Chinese)
[18] 张锁怀,李永春,孙军帅.地铁车辆转向架构架有限元强度计算与分析[J].机械设计与制造,2009,43(1):45-47.
ZHANG Suo-huai, LI Yong-chun, SUN Jun-shuai. Strength calculation and analysis on the bogie frame of metro trains based on FEM[J]. Machinery Design and Manufacture, 2009, 43(1): 45-47.(in Chinese)
[19] 王斌杰,孙守光,李 强,等.基于载荷谱提升转向架构架疲劳可靠性研究[J].铁道学报,2019,41(2):23-30.
WANG Bin-jie, SUN Shou-guang, LI Qiang, et al. Research on the improvement of speed increased passenger car bogie frame reliability based on load spectrum[J]. Journal of the China Railway Society, 2019, 41(2): 23-30.(in Chinese)
[20] 咸晓雨.动应力数据处理及疲劳评估软件系统开发[D].北京:北京交通大学,2017.
XIAN Xiao-yu. Systematic development of dynamic stress data processing and fatigue evaluation software[D]. Beijing: Beijing Jiaotong University, 2017.(in Chinese)
[21] 袁 熙,李舜酩.疲劳寿命预测方法的研究现状与发展[J].航空制造技术,2005,48(12):80-84.
YUAN Xi, LI Shun-ming. Research status and development of forecast method of fatigue life[J]. Aeronautical Manufacturing Technology, 2005, 48(12): 80-84.(in Chinese)
[22] 任尊松,谢基龙.采用等效载荷预测轴重对货车交叉支撑装置疲劳寿命的影响[J].机械工程学报,2008,44(3):16-21.
REN Zun-song, XIE Ji-long. Influence on axle load to the service life of the crossbar set of railway freight car with equivalent load[J]. Journal of Mechanical Engineering, 2008, 44(3): 16-21.(in Chinese)
[23] 郑如军.长期服役运行条件下动车组转向架构架结构疲劳试验分析[J].铁道车辆,2018,56(3):14-16.
ZHENG Ru-jun. Fatigue test and analysis of bogie frame structure of multiple units under long term service operation conditions[J]. Rolling Stock, 2018, 56(3): 14-16.(in Chinese)
[24] 张 丽,任尊松,孙守光,等.构架弹性振动对疲劳寿命影响研究[J].铁道机车车辆,2015,35(2):115-119.
ZHANG Li, REN Zun-song, SUN Shou-guang, et al. Research on the influence of railway bogie elastic vibration to fatigue life[J]. Railway Locomotive and Car, 2015, 35(2): 115-119.(in Chinese)
[25] 韩 鹏,张卫华.轮对结构弯曲及型面磨耗对高速列车振动性能的影响[J].振动与冲击,2015,34(5):207-212.
HAN Peng, ZHANG Wei-hua. Influences of structural bending deformation and profile wear of wheelsets on vibration performance of high-speed trains[J]. Journal of Vibration and Shock, 2015, 34(5): 207-212.(in Chinese)
[26] 王 萌.焊接转向架构架线路载荷的特征与应用研究[D].北京:北京交通大学,2016.
WANG Meng. Study on characteristics and applications of on-track load of welded bogie frame[D]. Beijing: Beijing Jiaotong University, 2016.(in Chinese)
[27] 于 洋,刘丙林,马桂财,等.城市轨道车辆振动损伤分析与研究[J].机车电传动,2019,48(4):120-125.
YU Yang, LIU Bing-lin, MA Gui-cai, et al. Research on vibration damage of urban rail vehicles[J]. Electric Drive for Locomotives, 2019, 48(4): 120-125.(in Chinese)
[28] KASSNER M. Fatigue strength analysis of a welded railway vehicle structure by different methods[J]. International Journal of Fatigue, 2012, 34(1): 103-111.
[29] 梁 君,赵登峰.模态分析方法综述[J].现代制造工程,2006,28(8):139-141.
LIANG Jun, ZHAO Deng-feng. Summary of the model analysis method[J]. Modern Manufacturing Engineering,2006, 28(8): 139-141.(in Chinese)
[30] 肖守讷,李华丽,阳光武,等.轮轨冲击对构架疲劳的影响[J].交通运输工程学报,2008,8(3):6-9.
XIAO Shou-ne, LI Hua-li, YANG Guang-wu, et al. Influence of wheel-rail impact on fatigue of bogie frame[J]. Journal of Traffic and Transportation Engineering, 2008, 8(3): 6-9.(in Chinese)

Memo

Memo:

-

Common functions

Last Update: 2021-07-20