Mechanical behavior and damage evolution of tunnel lining structure under the impact of derailment of high-speed train

IF 6.7 1区 工程技术 Q1 CONSTRUCTION & BUILDING TECHNOLOGY Tunnelling and Underground Space Technology Pub Date : 2024-11-09 DOI:10.1016/j.tust.2024.106198
Yuqi Wang , Xiaopei Cai , Lei Zhao , Tao Wang , Yuan Xin , Yi Liu
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Abstract

In deep-buried long tunnels, train derailment accidents pose a serious threat to the stability of the tunnel lining structures and the safety of personnel along the line. To address the impact damage to the secondary lining caused by high-speed train derailments, a three-dimensional nonlinear dynamic analysis model of the Electric Multiple Unit (EMU) − lining − soil system was established. The advantages of this model include: it fully considers the complex streamlined design of the EMU front end, the nonlinearity of lining materials, and the M−C elastic structural model of the soil, allowing for accurate simulation of the contact and deformation between the EMU and the lining. The results indicate that the first 30 ms of the collision process are extremely intense, primarily involving the first three train vehicles. Among these, the head vehicle experiences the greatest reduction in kinetic energy and plastic dissipated energy, resulting in the most severe plastic deformation of the vehicle body. The impact load exhibits a distinct multi-peak characteristic, mainly composed of lateral impact force components. The area of displacement change in the lining expands continuously along the direction of the train, with peak displacements stabilizing after 30 ms. The lining primarily suffers from tensile failure, with multiple tensile cracks appearing in areas distant from the collision, while compressive damage is mainly concentrated at the point of direct impact. As the collision angle increases, the range of compressive damage along the longitudinal direction becomes narrower. The ratio of tensile damage area to compressive damage area is mainly influenced by the collision angle. In the design of tunnel structures for impact resistance, special attention should be paid to the lateral impact resistance and tensile failure capacity of the tunnel structure.
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高速列车脱轨冲击下隧道衬砌结构的力学行为和损伤演变
在深埋长隧道中,列车脱轨事故对隧道衬砌结构的稳定性和沿线人员的安全构成严重威胁。针对高速列车脱轨对二次衬砌造成的冲击破坏,建立了电动多联机组(EMU)-衬砌-土体系统的三维非线性动态分析模型。该模型的优点包括:充分考虑了电力动车组前端复杂的流线型设计、衬里材料的非线性以及土壤的 M-C 弹性结构模型,可精确模拟电力动车组与衬里之间的接触和变形。结果表明,碰撞过程的前 30 毫秒极为剧烈,主要涉及前三辆列车。其中,头部车辆的动能和塑性耗散能量减少最多,导致车体塑性变形最严重。冲击载荷表现出明显的多峰特征,主要由横向冲击力分量组成。衬片的位移变化区域沿列车方向不断扩大,峰值位移在 30 毫秒后趋于稳定。衬片主要受到拉伸破坏,在远离碰撞的区域出现多条拉伸裂缝,而压缩破坏主要集中在直接碰撞点。随着碰撞角度的增大,沿纵向的压缩破坏范围变窄。拉伸破坏面积与压缩破坏面积之比主要受碰撞角的影响。在隧道结构的抗冲击设计中,应特别注意隧道结构的横向抗冲击能力和抗拉破坏能力。
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来源期刊
Tunnelling and Underground Space Technology
Tunnelling and Underground Space Technology 工程技术-工程:土木
CiteScore
11.90
自引率
18.80%
发文量
454
审稿时长
10.8 months
期刊介绍: Tunnelling and Underground Space Technology is an international journal which publishes authoritative articles encompassing the development of innovative uses of underground space and the results of high quality research into improved, more cost-effective techniques for the planning, geo-investigation, design, construction, operation and maintenance of underground and earth-sheltered structures. The journal provides an effective vehicle for the improved worldwide exchange of information on developments in underground technology - and the experience gained from its use - and is strongly committed to publishing papers on the interdisciplinary aspects of creating, planning, and regulating underground space.
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