复杂地质条件下TBM撑靴液压缸导向铜套微动损伤分析

doi:10.3901/JME.2018.01.074

机械工程学报 ›› 2018, Vol. 54 ›› Issue (1): 74-81.doi: 10.3901/JME.2018.01.074

• 特邀专栏:硬岩掘进装备(TBM)的关键基础问题 • 上一篇下一篇

复杂地质条件下TBM撑靴液压缸导向铜套微动损伤分析

余海东^1,2, 李琳², 赵勇¹, 陶建峰²

1. 上海交通大学上海市复杂薄板结构数字化制造重点实验室上海 200240;
2. 上海交通大学机械系统与振动国家重点实验室上海 200240

收稿日期:2017-03-02 修回日期:2017-07-02 出版日期:2018-01-05 发布日期:2018-01-05
通讯作者: 余海东(通信作者),男,1975年出生,副教授。主要研究方向为材料和结构的力学行为、疲劳损伤与失效。E-mail:hdyu@sjtu.edu.cn
基金资助:
国家重点基础研究发展计划（973计划，2013CB035403）和国家自然科学基金（51275292）资助项目。

Fretting Damage of Copper Sleeve Gasket in Gripper Cylinder of TBM Excavating in Complex Geological Structures

YU Haidong^1,2, LI Lin², ZHAO Yong¹, TAO Jianfeng²

1. Shanghai Key Laboratory of Digital Manufacture for Thin-Walled Structure Technology, Shanghai Jiao Tong University, Shanghai 200240;
2. School of Mechanical Engineering, Shanghai Jiao Tong University, Shanghai 200240

Received:2017-03-02 Revised:2017-07-02 Online:2018-01-05 Published:2018-01-05

摘要/Abstract

摘要： 为分析硬岩掘进机的撑靴液压缸在强振动工作环境下内衬铜套断裂的损伤机理，建立考虑撑靴与围岩接触刚度、缸筒和活塞杆接触面处等效刚度和液压油等效刚度的撑靴液压缸系统的集中参数动力学模型。研究不同支撑刚度条件下，撑靴液压缸导向套和内衬铜套接触面的法向力、切向力、法向压缩量和切向滑移量的变化规律。基于Hertz理论，分析掘进机在不确定地质条件下掘进时导向套与内衬铜套界面之间的接触载荷分布规律。根据连续介质损伤力学建立了内衬铜套结构含损伤材料本构模型，以液压缸动力学模型得到不同接触刚度下的内衬铜套接触面处的微动载荷为初始条件，分析了撑靴液压缸的内衬铜套的损伤演化规律。结果表明随着支撑刚度的增大，切向力和切向滑移减小，损伤的萌生和演化速率降低。适当提高围岩和撑靴之间的接触刚度，降低撑靴液压缸导向铜套的损伤概率。

关键词: 变载荷, 撑靴液压缸, 界面刚度, 损伤演化, 微动模型

Abstract: The damage mechanism of copper sleeve gasket in the gripper cylinder of TBM subjected to strong vibration is the main concern. A lumped mass parameter dynamic model of the gripper cylinder in TBM is firstly established considering the contact stiffness between the rock and the gripper shoes, the equivalent stiffness at the contact interface of the barrel and the piston rod, and the equivalent stiffness of the hydraulic oil. The changing rules of the normal force, the tangential force, the normal compression displacement and the tangential slip at the contact interface between the guide sleeve and the copper sleeve gasket are studied under different contact stiffness at the rock interface. The contact load distribution at the interface between the guide sleeve and the copper sleeve gasket is calculated based on the Hertz theory when TBM excavated in the uncertain geological strata. Then the damage constitutive model of copper sleeve gasket is developed. The damage evolution rules of the copper sleeve gasket in the gripper cylinder are investigated based on the fretting loads at the contact interface that are obtained from the dynamic model under different contact stiffness between the rock and the gripper shoes. Furthermore, the influences of the tangential force and the tangential slip on the damage evolution rules of the copper sleeve gasket are analyzed. The results show that both the tangential force and the tangential slip decrease with the increasing contact stiffness at the rock interface. Moreover, the damage initiation and evolution rate of the copper sleeve gasket also decrease with the contact stiffness. It could be concluded that the damage of the copper sleeve gasket of the gripper cylinder can be reduced when the contact stiffness of the surrounding rock and the gripper shoes can be increased.

Key words: contact stiffness, damage evolution, fretting model, gripper cylinder, variable loads

中图分类号:

TB112

余海东, 李琳, 赵勇, 陶建峰. 复杂地质条件下TBM撑靴液压缸导向铜套微动损伤分析[J]. 机械工程学报, 2018, 54(1): 74-81.

YU Haidong, LI Lin, ZHAO Yong, TAO Jianfeng. Fretting Damage of Copper Sleeve Gasket in Gripper Cylinder of TBM Excavating in Complex Geological Structures[J]. Journal of Mechanical Engineering, 2018, 54(1): 74-81.

参考文献

[1] ZHANG Z,MENG L,SUN F. Wear analysis of disc cutters of full face rock tunnel boring machine[J]. Chinese Journal of Mechanical Engineering,2014,27(6):1294-1300.
[2] LING J,SUN W,HUO J,et al. Study of TBM cutterhead fatigue crack propagation life based on multi-degree of freedom coupling system dynamics[J]. Computers & Industrial Engineering,2015,83:1-14.
[3] HUO J,ZHU D,HOU N,et al. Application of a small-timescale fatigue,crack-growth model to the plane stress/strain transition in predicting the lifetime of a tunnel-boring-machine cutter head[J]. Engineering Failure Analysis,2016,71:11-30.
[4] HILLS D A,DINI D. A review of the use of the asymptotic framework for quantification of fretting fatigue[J]. The Journal of Strain Analysis for Engineering Design,2016,51(4):240-246.
[5] JAHANMIR S,SUH N P. Mechanics of subsurface void nucleation in delamination wear[J]. Wear,1977,44(1):17-38.
[6] GODET M. The third-body approach:A mechanical view of wear[J]. Wear,1984,100(1):437-452.
[7] VINGSBO O,SÖDERBERG S. On fretting maps[J]. Wear,1988,126(2):131-147.
[8] XU G Z,LIU J J,ZhOU Z R. Prediction of the fretting fatigue resistance of various surface-modification layers on 1045 steel:the role of fretting maps[J]. Tribology International,2001,34(8):569-575.
[9] HOJJATI-TALEMI R,ZAHEDI A,BAETS P D. Fretting fatigue failure mechanism of automotive shock absorber valve[J]. International Journal of Fatigue,2015,73:58-65.
[10] WANG D,ZhANG D,GE S. Finite element analysis of fretting fatigue behavior of steel wires and crack initiation characteristics[J]. Engineering Failure Analysis,2013,28(3):47-62.
[11] NOWELL D,DINI D. Stress gradient effects in fretting fatigue[J]. Tribology International,2003,36(2):71-78.
[12] MAKINO T,KATO T,HIRARKAWA K. The effect of slip ratio on the rolling contact fatigue property of railway wheel steel[J]. International Journal of Fatigue,2012,36(1):68-79.
[13] GHOSH A,LEONARD B,SADEGHI F. A stress based damage mechanics model to simulate fretting wear of Hertzian line contact in partial slip[J]. Wear,2013,307(1-2):87-89.
[13] FAJDIGA G,RAML M. Fatigue crack initiation and propagation under cyclic contact loading[J]. Engineering Fracture Mechanics,2009,76(9):1320-1335.
[14] 周思阳,亢一澜,苏翠侠,等. 基于力学分析的TBM掘进总推力预测模型研究[J]. 机械工程学报,2016,52(20):76-82. ZHOU Siyang,KANG Yilan,SU Cuixia,et al. Prediction of thrust force requirements for TBMs based on mechanical analysis[J]. Journal of Mechanical Engineering,2016,52(20):76-82.
[15] 余海东,郝培,赵勇,等. 硬岩掘进装备支撑系统界面接触刚度非线性特性[J]. 机械工程学报,2014,50(21):54-59. YU Haidong,HAO Pei,ZHAO Yong,et al. Non-linear behavior of normal contact stiffness of tunnel surface and supporting system of tunnel boring machines[J]. Journal of Mechanical Engineering,2014,50(21):54-59.
[16] 谢启江,余海东,郑辉,等. 变约束条件下硬岩掘进机推进系统动态特性[J]. 机械设计与研究,2015(3):152-156. XIE Qijiang,YU Haidong,ZHENG Hui,et al. Dynamic behavior of thrusting system of tunnel boring machines with variable constraint conditions[J]. Machine Design & Research,2015(3):152-156.
[17] LEMAITRE J. Evaluation of dissipation and damage in metals submitted to dynamic loading[J]. Mechanical Behavior of Materials,1972,1:540-549.
[18] LEMAITRE J. A course on damage mechanics[M]. Wiesbaden:Springer-Verlag,1998.

复杂地质条件下TBM撑靴液压缸导向铜套微动损伤分析

Fretting Damage of Copper Sleeve Gasket in Gripper Cylinder of TBM Excavating in Complex Geological Structures

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