Method for analyzing waterproof tunnels considering the effect of a thin water layer behind the lining

IF 7.4 1区工程技术 Q1 CONSTRUCTION & BUILDING TECHNOLOGY

Tunnelling and Underground Space Technology Pub Date : 2025-09-17 DOI:10.1016/j.tust.2025.107046

Naotoshi Yasuda , Jun Saito , Takeshi Matsunaga , Yasuo Sawamura , Kiyoshi Kishida

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引用次数: 0

Abstract

Waterproof tunnels are designed by assuming that water pressure acts on the lining uniformly. This assumption is made because the waterproof membrane and geotextile ensure that a thin water layer forms behind the lining. In designing waterproof tunnels with the conventionally used beam–spring model, the effect of the thin layer is considered by applying depth-dependent water pressure to the outer surface of the lining and using no-tension springs. When designing tunnels by adopting numerical analyses such as finite element analysis, the thin water layer is often ignored. Even considering the thin water layer, it is difficult to model it directly. Hence, a simplified method considering the effect indirectly is needed to estimate the stresses in the lining. This paper presents a method for analyzing waterproof tunnels. A thin water layer with zero thickness was assumed to exist at the boundary between the ground and waterproof lining. The effect of the thin layer was modeled by considering the contact–separation conditions at the ground and lining boundaries using contact elements and applying a pressure loading equivalent to the pore pressure at the interface to both boundaries. In addition, an analytical solution for a circular tunnel lining subjected to depth-dependent water pressure was derived assuming that the contact between the ground and lining was only at the crown, to clarify the basic response of the waterproof lining and to validate the numerical results. The results show that the magnitude of the bending stress varied greatly depending on the contact area of the ground and lining, and the bending stress in the lining was non-negligible relative to the axial stress. Therefore, estimating the bending stress is important in the design of waterproof tunnels. The main cause of the bending stress was the difference in buoyancy due to the depth-dependent water pressure and the total weight inside the tunnel structure. Minimizing this difference contributes to the rational design of waterproof tunnels.

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考虑衬砌后薄水层影响的隧道防水分析方法

假定水压力均匀作用于衬砌，设计防水隧道。这种假设是因为防水膜和土工布确保衬里后面形成一层薄薄的水层。在采用传统的梁-弹簧模型进行隧道防水设计时，通过在衬砌外表面施加随深度变化的水压和使用无张力弹簧来考虑薄层的影响。在采用有限元等数值分析方法进行隧道设计时，往往会忽略薄水层的存在。即使考虑到薄水层，也很难直接对其进行建模。因此，需要一种考虑间接影响的简化方法来估计衬砌应力。本文提出了一种分析防水隧道的方法。假定在地面与防水衬砌的交界处存在厚度为零的薄水层。考虑地面和衬砌边界的接触分离条件，采用接触单元，并在两个边界上施加相当于界面孔隙压力的压力载荷，对薄层的影响进行了建模。此外，推导了圆形隧道衬砌在随深水压作用下，假设地面与衬砌仅在顶部接触的解析解，阐明了防水衬砌的基本响应，并验证了数值结果。结果表明：随着地基与衬砌接触面积的增大，衬砌内的弯曲应力变化幅度较大，相对于轴向应力，衬砌内的弯曲应力不可忽略；因此，弯应力的估算在防水隧道设计中具有重要意义。弯应力产生的主要原因是随深度变化的水压力和隧道结构内部总重量引起的浮力差异。尽量减少这种差异有助于合理设计防水隧道。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

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.