«Previous Article|Table of Contents|Next Article»

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

Issue:

2019年04期

Page:

104-114

Research Field:

载运工具运用工程

Publishing date:

Info

Title:

High and low temperature characteristics of rubber component dynamic parameters of a bogie

Author(s):

TAN Fu-xing¹;  SHI Huai-long²;  WANG Wei²;  LIU Shi-hui¹;  LIU Hong-tao¹

(1. CRRC Changchun Railway Vehicles Co., Ltd., Changchun 130062, Jilin, China; 2. State Key Laboratory of Traction Power, Southwest Jiaotong University, Chengdu 610031, Sichuan, China)

Keywords:

vehicle engineering;  vehicle dynamics;  bogie;  rubber component;  dynamic characteristic;  high and low temperature test;  dynamics simulation

PACS:

U270.3

DOI:

-

Abstract:

For the rubber components in bogie suspension of a high-speed train, in order to master the frequency-dependent, amplitude-dependent and temperature-dependent characteristics of nonlinear stiffness and damping coefficient, the high and low temperature characteristic tests of dynamic parameters were conducted. The test method for dynamic characteristic of rubber components parameters was introduced. Both the static and dynamic tests at axial and radial directions were performed for the layer rubber spring mounted on axle box and the rubber joint mounted on the swing-arm. The stiffness and damping coefficient were calculated through the load-deflection hysteresis curve. Test result shows that under the normal ambient temperature of 23 ℃, the stiffness and damping coefficient of rubber components only show frequency-dependent and amplitude-dependent characteristics, but their changes are strongly dependent on the temperature. Compared with the normal ambient temperature of 23 ℃, the stiffness and damping coefficient of the rubber components rise significantly under extremely low temperature environment of -60 ℃. In the case of an excitation displacement of 0.50 mm, the stiffness increases by more than 1 times, and the damping coefficient increases by 4-6 times. The higher the excitation frequency, the greater the increasing rate of stiffness and damping coefficient. In case of high temperature environment of 60 ℃, the stiffness and damping coefficient decrease only 5% and 25%, respectively, with respect to that at 23 ℃. The frequency-dependent and amplitude-dependent of rubber components are nonlinear weakened under high temperature environment. Low temperature causes the change of stiffness and damping coefficient of vehicle suspension system, which in turn affects the vehicle dynamics behaviour. With respect to that at ambient temperature, the running safety index like derailment coefficient increases slightly about 5%, whereas the car body vibration accelerations significantly rise around 17%. 7 tabs, 13 figs, 30 refs.

References:

[1] KLOOW L. High-speed train operation in winter climate[R]. Stockholm: KTH Railway Group and Transrail, 2011.
[2] BETTEZ M. Winter technologies for high speed rail[R]. Trondheim: Norwegian University of Science and Technology, 2011.
[3] PAULUKUHN L,吴新民.俄罗斯高速列车Velaro RUS的低温技术方案及运营经验[J].国外铁道车辆,2012,49(3):16-19.
PAULUKUHN L, WU Xin-min. The low temperatures technology concepts and operational experience in Russian high speed train Velaro RUS[J]. Foreign Rolling Stock, 2012, 49(3): 16-19.(in Chinese)
[4] WANG Jia-bin, ZHANG Jie, XIE Fei, et al. A study of
snow accumulating on the bogie and the effects of deflectors on the de-icing performance in the bogie region of a high-speed train[J]. Cold Regions Science and Technology, 2018, 148: 121-130.
[5] XIE F, ZHANG J, GAO G, et al. Study of snow accumulation on a high-speed train's bogies based on the discrete phase model[J]. Journal of Applied Fluid Mechanics, 2017, 10(6): 1729-1745.
[6] SAITO M. Japanese railway safety and the technology of the day[J]. Japan Railway and Transport Review, 2002, 33: 4-13.
[7] SEBESAN I, ZAHARIA N L, SPIROIU M A, et al. Rubber suspension, a solution of the future for railway vehicles[J]. Materiale Plastice, 2015, 52(1): 93-96.
[8] 韩庆利.高寒高速动车组转向架耐低温防冰雪技术研究[J].铁道机车与动车,2016(12):29-31,46.
HAN Qing-li.Research of low temperature resistant and ice and snow protective technology for high-speed EMU's bogie[J]. Railway Locomotive and Motor Car, 2016(12): 29-31, 46.(in Chinese)
[9] SHI Huai-long, WANG Jian-bin, WU Ping-bo, et al. Field measurements of the evolution of wheel wear and vehicle dynamics for high-speed trains[J]. Vehicle System Dynamics, 2018, 56(8): 1187-1206.
[10] LI Guo-dong, LI Xiao-feng, SONG Chun-yuan. Influence of service environment on the wheel wear of high speed trains[C]∥CM. Proceedings of 11th International Conference on Contact Mechanics and Wear of Rail/Wheel Systems. Delft: CM, 2018: 536-542.
[11] 彭立群,林达文,王叶青,等.低温对橡胶弹性元件传递率和固有频率的影响[J].铁道机车车辆,2018,38(6):55-60.
PENG Li-qun, LIN Da-wen, WANG Ye-qing, et al. Influence of low temperature on the transmission rate and natural frequency of rubber elastic components[J]. Railway Locomotiveand Car, 2018, 38(6): 55-60.(in Chinese)
[12] 卢成壮,李静媛,周邦阳,等.金属橡胶的刚度特性和阻尼试验研究[J].振动与冲击,2017,36(8):203-208.
LU Cheng-zhuang, LI Jing-yuan, ZHOU bang-yang, et al. An experimental study on stiffness characteristics and damping of metal rubber[J]. Journal of Vibration and Shock, 2017, 36(8): 203-208.(in Chinese)
[13] 石怀龙,宋 烨,邬平波,等.高速动车组转向架悬挂刚度特性[J].吉林大学学报(工学版),2015,45(3):776-782.
SHI Huai-long, SONG Ye, WU Ping-bo, et al. Calculation and testing of suspension stiffness of a bogie of high speed EMU [J]. Journal of Jilin University(Engineering and Technology Edition), 2015, 45(3): 776-782.(in Chinese)
[14] 石怀龙,邬平波,罗 仁.客车转向架回转阻力矩特性[J].交通运输工程学报,2013,13(4):45-50.
SHI Huai-long, WU Ping-bo, LUO Ren. Bogie rotation resistance torque characteristics of passenger car[J]. Journal of Traffic and Transportation Engineering, 2013, 13(4): 45-50.(in Chinese)
[15] 罗 仁,李 然,胡俊波,等.考虑随机参数的高速列车动力学分析[J].机械工程学报,2015,51(24):90-96.
LUO Ren, LI Ran, HU Jun-bo, et al. Dynamic analysis of high-speed train with stochastic parameters[J]. Journal of Mechanical Engineering, 2015, 51(24): 90-96.(in Chinese)
[16] 罗 仁,胡俊波,王一平.考虑随机因素的高速列车动力学模拟方法及应用[J].铁道车辆,2016,54(10):1-6.
LUO Ren, HU Jun-bo, WANG Yi-ping. Dynamics simulation method and the application on high speed trains with consideration of random factors[J]. Rolling Stock, 2016, 54(10): 1-6.(in Chinese)
[17] LUO Ren, SHI Huai-long, TENG Wan-xiu, et al. Prediction of wheel profile wear and vehicle dynamics evolution considering stochastic parameters for high-speed train[J]. Wear, 2017, 392/393: 126-138.
[18] 李 密,邬平波,王 玮,等.轴箱转臂定位节点温变特性对车辆动力学性能的影响[J].噪声与振动控制,2018,38(4):111-115.
LI Mi, WU Ping-bo, WANG Wei, et al.Influence of temperature varying characteristic of axle-box tumbler rubber nodes on vehicle's dynamics performance[J]. Noise and Vibration Control, 2018, 38(4): 111-115.(in Chinese)
[19] 张隶新,魏 来,王 勇.变刚度转臂定位节点对车辆动力学性能的影响[J].铁道车辆,2016,54(12):1-4.
ZHANG Li-xin, WEI Lai, WANG Yong. Effect of the positioning nodal point of rotary arm with variable stiffness on the dynamics performance of vehicles[J]. Rolling Stock, 2016, 54(12): 1-4.(in Chinese)
[20] WEI Kai, WANG Feng, WANG Ping, et al. Effect of
temperature- and frequency-dependent dynamic properties of rail pads on high-speed vehicle-track coupled vibrations[J]. Vehicle System Dynamics, 2017, 55(3): 251-370.
[21] MA L, SHI L B, Guo J, et al. On the wear and damage characteristics of rail material under low temperature environment condition [J]. Wear, 2018, 394/395: 149-158.
[22] 孙 琳,林化强,林 鹏,等.北方高寒地区轨道车辆橡胶材料的力学特性分析[J].材料开发与应用,2016,31(6):88-92.
SUN Lin, LIN Hua-qiang, LIN Peng, et al. Mechanical properties analysis of rubber materials for rail vehicles in the North China[J]. Development and Application of Materials, 2016, 31(6): 88-92.(in Chinese)
[23] 王付胜,高新文,曹江勇,等.轨道车辆用耐低温橡胶减振元件的研究[J].铁道车辆,2012,50(11):22-24,33.
WANG Fu-sheng, GAO Xin-wen, CAO Jiang-yong, et al. Research on low temperature resistant rubber damping elements for rail vehicles[J]. Rolling Stock, 2012, 50(11): 22-24, 33.(in Chinese)
[24] 金耿日,管 欣,詹 军,等.底盘橡胶部件低温特性的试验研究[J].汽车工程,2017,39(3):364-368,350.
KIM Kyongil, GUAN Hsin, ZHAN Jun, et al. An experimental study on the low temperature characteristics of chassis rubber components[J]. Automotive Engineering, 2017, 39(3): 364-368, 350.(in Chinese)
[25] 大道休,刘艳芳.转向架橡胶件的变化与其运行性能的关系[J].国外机车车辆工艺,2003(4):25-29.
DA Dao-xiu, LIU Yan-Fang. The relationship between the change of the rubber parts of the bogie and its running performance[J]. Foreign Locomotive and Rolling Stock Technology, 2003(4): 25-29.(in Chinese)
[26] 宋春元,罗 仁.低温条件悬挂参数变化对动力学性能的影响研究[C]∥中国智能交通协会.第八届中国智能交通年会论文.合肥:电子工业出版社,2013:309-314.
SONG Chun-yuan, Luo Ren. Study on the effects of parameters on the dynamic performance of the low temperature suspension[C]∥ITS China. Proceedings of 8th Chinese Technological Transportation. Hefei: Publishing House of Electronics Industry, 2013: 309-314.(in Chinese)
[27] 陈清明,周 令.低温对转向架结构性能的影响[J].电力机车技术,2002,25(增):10-11.
CHEN Qing-ming, ZHOU Ling. Influence on structure and performance of bogie in low temperature[J]. Technology for Electric Locomotives, 2002, 25(S): 10-11.(in Chinese)
[28] 丁智平,穆龙海,卜继玲,等.橡胶弹性元件低温刚度预测[J]. 振动与冲击,2017,36(14):66-70.
DING Zhi-ping, MU Long-hai, BU Ji-ling, et al. Stiffness prediction of rubber springs at lower temperature[J]. Journal of Vibration and Shock, 2017, 36(14): 66-70.(in Chinese)
[29] LUO Ren, SHI Huai-long, GUO Jin-ying, et al. A nonlinear rubber spring model for the dynamics simulation of a high-speed train[J]. Vehicle System Dynamics, 2019, DOI: 10.1080/00423114.2019.1624788
[30] SHI Huai-long, WU Ping-bo. A nonlinear rubber spring
model containing fractional derivatives for use in railroad vehicle dynamic analysis[J]. Journal of Rail and Rapid Transit, 2016, 230(7): 1745-1759.

Memo

Memo:

-

Common functions

Last Update: 2019-09-03