Research on Vibration Characteristics and Fatigue Damage of Sanding Device of High Speed Train

doi:10.3901/JME.2025.04.229

Abstract

Abstract: With the continuous improvement of train operating speed, the sanding device connected at the end of the bogie frame of a high-speed train is subjected to complex loads and vibrates violently during service, which easily leads to vibration fatigue failure. To study the vibration fatigue damage of the sanding device, the finite element model is established by ANSYS software to analyse the modal characteristics and vibration transfer law of the sanding device and the frame end. Combined with the Dirlik method and Miner linear cumulative damage law, the structural damage under the standard acceleration spectrum and line acceleration spectrum is simulated, and verified by bench tests. The vibration fatigue damage calculation process is established to predict the damage of 15 million km. The results show that the first-order modal frequency of the sanding device is close to the first-order dominant frequency of the bench sweep test, and the error is 2%. From the frame end to the sanding device, the displacement response under unit acceleration excitation is magnified and the vibration is intensified. Under two kinds of acceleration spectrum, the fatigue damage error obtained by simulation and bench tests is less than 20%, and the larger damage position is mainly distributed at the outer welding seam of the axle box spring cap barrel at the frame end and the circular base metal of the upper part of the sanding device. The maximum damage of the structure at 15 million km under the line acceleration spectrum is 0.71, which is much higher than the standard acceleration spectrum. Therefore, when designing and evaluating the end and connecting parts of the bogie frame, the influence of line conditions and structural modes should be fully considered to avoid the occurrence of insufficient service life caused by standards design and evaluation only.

Key words: sanding device, random vibration, power spectral density, frequency domain characteristics, fatigue damage

CLC Number:

U266

WANG Wenjing, DONG Ziyu, DAI Sen, LI Guangquan, ZHANG Zhenxian. Research on Vibration Characteristics and Fatigue Damage of Sanding Device of High Speed Train[J]. Journal of Mechanical Engineering, 2025, 61(4): 229-238.

References

[1] WANG W J，LIU T F，WANG H Y，et al. Influence of friction modifiers on improving adhesion and surface damage of wheel/rail under low adhesion conditions[J]. Tribology International，2014，75:16-23.
[2] 陈姝枚. 地铁车辆制动模块疲劳强度研究[D]. 北京:北京交通大学，2017. CHEN Shumei. Study on the fatigue strength of metro vehicles brake module[D]. Beijing:Beijing Jiaotong University，2017.
[3] 申政，方吉，汤黎明，等. 基于频域结构应力法的牵引电机结构振动疲劳分析[J]. 铁道科学与工程学报，2022，19(3):814-821. SHEN Zheng，FANG Ji，TANG Liming，et al. Vibration fatigue analysis of traction motor structure based on frequency domain structural stress method[J]. Journal of Railway Science and Engineering，2022，19(3):814-821.
[4] YOU Taiwen，ZHOU Jinsong，GONG Dao，et al. Synthesis of random vibration environment spectra for the fatigue analysis and optimization of railway vehicles[J]. International Journal of Fatigue，2022，159:106752.
[5] WANG Wenjing，BAI Jinyi，WU Shengchuan，et al. Experimental investigations on the effects of fatigue crack in urban metro welded bogie frame[J]. Applied Sciences，2020，10(4):1537.
[6] 毛冉成. 车轮多边形激励下高速转向架构架振动特性及疲劳损伤分析[D]. 成都:西南交通大学，2020. MAO Rancheng. Vibration behaviour and damage analysis of high speed bogie frame under wheel polygonal excitations[D]. Chengdu:Southwest Jiaotong University，2020.
[7] 姚起杭，姚军. 工程结构的振动疲劳问题[J]. 应用力学学报，2006，23(1):12-15. YAO Qihang，YAO Jun. Vibration fatigue in engineering structures[J]. Chinese Journal of Applied Mechanics，2006，23(1):12-15.
[8] GE J，SUN Y，ZHOU L，et al. A hybrid frequency-time domain method for predicting multiaxial fatigue life of 7075-T6 aluminium alloy under random loading[J]. Fatigue & Fracture of Engineering Materials & Structures，2015，38(3):247-256.
[9] MRSNIK M，SLAVIC J，BOLTEZAR M. Multiaxial vibration fatigue-A theoretical and experimental comparison[J]. Mechanical Systems and Signal Processing，2016，76-77:409-423.
[10] BENASCIUTTI D，SHERRATT F，CRISTOFORI A. Recent developments in frequency domain multi-axial fatigue analysis[J]. International Journal of Fatigue，2016，91:397-413.
[11] NIESLONY A，BÖHM M，OWSIŃSKI R. Formulation of multiaxial fatigue failure criteria for spectral method[J]. International Journal of Fatigue，2020，135:105519.
[12] GAO Daiyang，YAO Weixing，WEN Weidong，et al. A multiaxial fatigue life prediction method for metallic material under combined random vibration loading and mean stress loading in the frequency domain[J]. International Journal of Fatigue，2021，148:106235.
[13] CIMA M，SOLAZZI L. Experimental and analytical study of random fatigue，in time and frequencies domain，on an industrial wheel[J]. Engineering Failure Analysis，2021，120:105029.
[14] 杨燕，贺启林，朱海洋，等. 带预载的钢丝网套补偿器振动疲劳损伤分析[J]. 机械工程学报，2021，57(15):129-137. YANG Yan，HE Qilin，ZHU Haiyang，et al. Vibration fatigue damage analysis of compensator reinforced by wire cloth with preload[J]. Journal of Mechanical Engineering，2021，57(15):129-137.
[15] JUNG H S，KIM K S，KIM J S，et al. Fatigue life evaluation in frequency domain of aircraft equipment exposed to random vibration[J]. Journal of the Korean Society for Aeronautical and Space Sciences，2017，45(8):627-638.
[16] JOO Y S，LEE J C. Vibration fatigue analysis for structural durability evaluation under vibratory loads[J]. International Journal of Aeronautical and Space Sciences，2021，22(3):578-589.
[17] 秦飞，别晓锐，陈思，等. 随机振动载荷下塑封球栅阵列含铅焊点疲劳寿命模型[J]. 振动与冲击，2021，40(2):164-170. QIN Fei，BIE Xiaorui，CHEN Si，et al. Vibration lifetime modelling of PBGA solder joints under random vibration loading[J]. Journal of Vibration and Shock，2021，40(2):164-170.
[18] ZENG Liangbin，ZHAO Jinliang，MENG Yongshuai. Vibrational fatigue failure prediction of a brake caliper used for railway vehicles based on frequency domain method[J]. Journal of Physics:Conference Series. IOP Publishing，2021，1948(1):012091.
[19] 王萌，李强，孙守光. 基于应力响应的多频率激励载荷识别研究[J]. 铁道学报，2015，37(2):27-33. WANG Meng，LI Qiang，SUN Shouguang. Study of multi-frequency exciting load identification based on dynamic stress response[J]. Journal of the China Railway Society，2015，37(2):27-33.
[20] 李相杰，阳光武，肖守讷，等. 基于疲劳试验和断裂仿真的地铁障碍物检测装置寿命预测[J]. 机械强度，2021，43(6):1442-1449. LI Xiangjie，YANG Guangwu，XIAO Shoune，et al. Life prediction of metro obstacle detector based on fatigue test and fracture simulation[J]. Journal of Mechanical Strength，2021，43(6):1442-1449.
[21] 李广全，刘志明，呙如兵，等. 高速列车齿轮箱应力响应与疲劳损伤评估[J]. 交通运输工程学报，2018，18(1):79-88. LI Guangquan，LIU Zhiming，GUO Rubing，et al. Stress response and fatigue damage assessment of high-speed train gearbox[J]. Journal of Traffic and Transportation Engineering，2018，18(1):79-88.
[22] 周航博. 基于临界面法的多轴频域随机振动疲劳研究[D]. 成都:西南交通大学，2018. ZHOU Hangbo. Research on frequency domain method of multiaxial random fatigue based on the critical[D]. Chengdu:Southwest Jiaotong University，2018.
[23] PRASAD S R，SEKHAR A S. Life estimation of shafts using vibration based fatigue analysis[J]. Journal of Mechanical Science and Technology，2018，32(9):4071-4078.
[24] AL-BAHKALI E A，ELKENANI H，SOULI M，et al. Failure and fatigue life estimate of a pre-stressed aircraft seat support tube[J]. Engineering Failure Analysis，2015，54:120-130.
[25] 韩博. 地铁车辆转向架天线梁疲劳强度研究[D]. 北京:北京交通大学，2020. HAN Bo. Research on fatigue strength of antenna beam of subway bogies[D]. Beijing:Beijing Jiaotong University，2020.
[26] 陈超朋，阳光武，肖守讷，等. 基于疲劳寿命预测的齿轮箱箱体结构优化[J]. 机械强度，2021，43(2):447-452. CHEN Chaopeng，YANG Guangwu，XIAO Shoune，et al. Structural optimization of gearbox cases based on fatigue life prediction[J]. Journal of Mechanical Strength，2021，43(2):447-452.
[27] 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 Qinglin，LIU Zhiming，WANG Wenjing. 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.
[28] 王文静，张莹，曲俊生，等. 高速列车齿轮箱箱体动应力响应及疲劳可靠性研究[J]. 中国铁道科学，2018，39(6):90-97. WANG Wenjing，ZHANG Ying，QU Junsheng，et al. Dynamic stress response and fatigue reliability of gearbox housing for G-series high-speed train[J]. China Railway Science，2018，39(6):90-97.