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隧道衬砌空洞区域钢板加固的机理与优化设计方法

Mechanism and Optimized Design Methodology of Steel Plate Reinforcement for Tunnel Lining Void Zones.

作者信息

Shao Shuai, Wu Yimin, Fu Helin, Zhang Jiawei

机构信息

School of Hydraulic and Civil Engineering, Ludong University, Yantai 264025, China.

School of Civil Engineering, Central South University, Changsha 410075, China.

出版信息

Materials (Basel). 2025 Sep 8;18(17):4204. doi: 10.3390/ma18174204.

DOI:10.3390/ma18174204
PMID:40942630
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12429943/
Abstract

Voids behind tunnel linings are common hidden defects in underground engineering, leading to reduced structural capacity and potential safety hazards. To address the deficiencies in the understanding of the mechanism and the optimization of design of the existing steel plate reinforcement methods, this study systematically investigates the reinforcement mechanisms and proposes refined design strategies through numerical simulations and experimental validation. First, a comparative analysis of the Concrete Damage Plasticity (CDP) model and the Extended Finite Element Method (XFEM) revealed that the CDP model exhibits superior accuracy and computational efficiency in simulating large-scale void linings. Second, the effectiveness of different reinforcement schemes (chemical anchor bolts alone, structural adhesive alone, and combined systems) was evaluated, demonstrating that structural adhesive dominates stress transfer, while chemical anchor bolts primarily prevent plate detachment. Through further optimization simulations of the steel plate spacing, it was found that a spacing of 0.25 m can balance the reinforcement effect and cost. This spacing restricts the maximum principal stress (1.83 MPa) below the tensile strength of concrete while essentially eliminating damage to the lower surface of the lining. An optimized steel plate reinforcement structure was ultimately proposed. By reducing the number of chemical anchor bolts and decreasing their size (with only M12 chemical anchor bolts arranged at the edges), local damage is minimized while maintaining reinforcement efficiency. The research results provide theoretical support and engineering guidance for the safe repair of tunnel void areas.

摘要

隧道衬砌背后的空洞是地下工程中常见的隐蔽缺陷,会导致结构承载力降低并存在潜在安全隐患。为弥补现有钢板加固方法在机理认识和设计优化方面的不足,本研究通过数值模拟和实验验证系统地研究了加固机理并提出了精细化设计策略。首先,对混凝土损伤塑性(CDP)模型和扩展有限元法(XFEM)的对比分析表明,CDP模型在模拟大规模空洞衬砌时具有更高的精度和计算效率。其次,评估了不同加固方案(单独使用化学锚栓、单独使用结构胶粘剂以及组合系统)的有效性,结果表明结构胶粘剂主导应力传递,而化学锚栓主要防止钢板脱落。通过对钢板间距的进一步优化模拟,发现0.25 m的间距可以平衡加固效果和成本。该间距将最大主应力(1.83 MPa)限制在混凝土抗拉强度以下,同时基本消除了衬砌下表面的损伤。最终提出了一种优化的钢板加固结构。通过减少化学锚栓数量并减小其尺寸(仅在边缘布置M12化学锚栓),在保持加固效率的同时将局部损伤降至最低。研究结果为隧道空洞区域的安全修复提供了理论支持和工程指导。

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本文引用的文献

1
Numerical Investigation of Longitudinal through Voids in Tunnel Secondary Lining Vaults and Steel Plate Strengthening.隧道二次衬砌拱顶纵向贯穿空洞及钢板加固的数值研究
Materials (Basel). 2023 Jun 8;16(12):4248. doi: 10.3390/ma16124248.
2
Numerical Investigation on the Mechanical Properties of Vault Void Lining and Steel Plate Strengthening.拱顶空洞衬砌及钢板加固力学性能的数值研究
Materials (Basel). 2023 Jan 13;16(2):789. doi: 10.3390/ma16020789.