铁路隧道防排水系统主要问题及性能保障措施

doi:10.3973/j.issn.2096-4498.2024.12.012

隧道建设（中英文） ›› 2024, Vol. 44 ›› Issue (12): 2424-2441.DOI: 10.3973/j.issn.2096-4498.2024.12.012

铁路隧道防排水系统主要问题及性能保障措施

郭小雄^{1, 2}，马伟斌^{1, 2}，罗驰^{1, 2, *}，安哲立^{1, 2}，常凯^{1, 2}，郑泽福^{1, 2}，徐湉源^{1, 2}

（1. 中国铁道科学研究院集团有限公司铁道建筑研究所，北京 100081； 2. 高速铁路轨道系统全国重点实验室，北京 100081）

出版日期:2024-12-20 发布日期:2025-01-11
作者简介:郭小雄（1985—），男，陕西延安人，2011年毕业于中国铁道科学研究院，隧道工程专业，硕士，副研究员，主要从事隧道及地下工程方面研究工作。E-mail： 365073932@qq.com。*通信作者：罗驰， E-mail： luochi11@163.com。

Key Issues and Performance Assurance Measures of Waterproofing and Drainage Systems in Railway Tunnels

GUO Xiaoxiong^{1, 2}, MA Weibin^1,
2, LUO Chi^{1, 2, *}, AN Zheli^{1, 2}, CHANG Kai^{1, 2}, ZHENG Zefu^{1, 2}, XU Tianyuan^{1, 2}

(1. Railway Engineering Research Institute of China Academy of Railway Sciences Corporation Limited, Beijing 100081, China; 2. State Key Laboratory of High-speed Railway Track System, Beijing 100081, China)

Online:2024-12-20 Published:2025-01-11

摘要/Abstract

摘要： 渗漏水是铁路隧道防排水系统工作性能降低的直观体现，对铁路隧道安全运营影响显著。为降低隧道渗漏水病害的发生概率，采用文献调研、现场调研、模型试验和现场试验等研究方法，总结归纳铁路隧道防排水系统不同阶段存在的问题，探讨设计优化、施工质量控制、材料性能要求和排水系统维护等防排水性能保障措施。研究结果表明： 1）设计阶段应采用防排水板、排水型自粘背贴式止水带和仰拱下排水系统等措施，解决排水能力不足、中埋止水带切割衬砌的问题。2）施工阶段应推广粘贴式铺挂工艺，避免防水板热熔焊穿风险；应加强排水系统接头、止水带卡具固定等精细化施工要求，提高防排水系统施工质量。3）材料阶段应明确防水板阻燃性能、土工布防降解、排水盲管防结晶、耐高温等关键性能要求，以适应复杂环境隧道工程使用要求。4）运营阶段应采用U形防结晶密封器和微型机械疏通设备，作为保障排水系统通畅的主要手段。

关键词: 铁路隧道, 防排水系统, 设计优化, 施工质量控制, 材料性能, 排水系统疏通

Abstract: Water leakage in railway tunnels signifies a decline in the performance of tunnel waterproofing and drainage systems, which compromises their safe operation. To mitigate such water leakage issues, the authors identify existing challenges in tunnel waterproofing and drainage systems at various stages through a literature review, on-site investigations, model testing, and field testing. Subsequently, measures to ensure effective waterproofing and drainage are discussed, including design optimization, construction quality control, material performance specifications, and drainage system maintenance. The research findings are summarized as follows: (1) During the design phase, measures such as constructing waterproof drainage boards, drainage-type self-adhesive back-adhesive waterstops, and inverted arch drainage systems enhance drainage capacity and prevent the lining from being compromised by buried waterstops. (2) During the construction phase, promoting the adhesive laying and hanging process minimizes the risk of hot welding penetration of waterproof boards. Additionally, implementing precise construction practices, such as strengthening drainage system joints and securely fixing waterstop clamps, improves the overall construction quality of waterproofing and drainage systems. (3) During the material stage, distinctly outlining key performance requirements, including flame retardancy of waterproof boards, anti-degradation properties of geotextiles, anti-crystallization properties of drainage blind pipes, and high-temperature resistance, helps meet the demands of complex tunnel engineering environments. (4) During the operational phase, using U-shaped anti-crystallization seals and micro-mechanical dredging equipment helps maintain smooth and functional drainage systems.

Key words: railway tunnel, waterproofing and drainage system, design optimization, construction quality control, material properties, drainage system dredging

郭小雄, 马伟斌, 罗驰, 安哲立, 常凯, 郑泽福, 徐湉源. 铁路隧道防排水系统主要问题及性能保障措施[J]. 隧道建设, 2024, 44(12): 2424-2441.

GUO Xiaoxiong, MA Weibin, LUO Chi, AN Zheli, CHANG Kai, ZHENG Zefu, XU Tianyuan. Key Issues and Performance Assurance Measures of Waterproofing and Drainage Systems in Railway Tunnels[J]. Tunnel Construction, 2024, 44(12): 2424-2441.

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铁路隧道防排水系统主要问题及性能保障措施

Key Issues and Performance Assurance Measures of Waterproofing and Drainage Systems in Railway Tunnels

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