Innovative design and construction of a closure joint for inland-river immersed tunnels via dry-land construction methods: A case study of the Yuliangzhou tunnel in China

IF 6.7 1区 工程技术 Q1 CONSTRUCTION & BUILDING TECHNOLOGY Tunnelling and Underground Space Technology Pub Date : 2024-08-14 DOI:10.1016/j.tust.2024.106026
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Abstract

Closure joints constructed to fill the spaces between immersed tunnel elements or between the tunnel elements and adjacent cut-and-cover tunnels are crucial for the longitudinal stability of immersed tunnels and affect the overall cost and duration of tunnel construction. To avoid the obstruction of navigation and reduce the difficulty of constructing closure joints, dry-land construction methods have been widely applied to construct closure joints for inland-river immersed tunnels, in particular using procedures involving axial dry docks. However, the traditional dry-land construction method has many inherent drawbacks. For example, the construction of underwater large-scale reinforced concrete antiretreat structures involves many underwater works, complicated construction processes, long operation time spans and high costs. Based on the Yuliangzhou immersed tunnel in China, a new dry-land construction method for closure joints of inland-river immersed tunnels based on tunnel–soil interface friction was developed to address the abovementioned problems. Considering the adverse influences of back-silting sediment on tunnel–soil interface friction, large-scale laboratory and onsite shear tests were carried out to derive the interface friction coefficients between the tunnel element base slabs and prelaid pebble foundation beds. A composite concrete steel sandwich (CCSS) water-retaining system was designed and assembled to separate the water in the dry dock from the river course. A simplified analysis method based on numerical simulations for the determination of the equivalent horizontal thrust P applied to element ES caused by the dewatering of the axial dry dock was proposed. Based on horizontal antisliding stability analyses of the tunnel elements during the axial dry dock dewatering stage, equations for the key design parameters of the new dry-land construction method were established. Through examination of the static equilibrium of the tunnel elements in the tunnel longitudinal direction, temporary longitudinal displacement constraint (LDC) structures at the immersion joints were designed. Furthermore, the following key construction techniques for the new dry-land construction method were systematically designed: installation of a CCSS water-retaining system at the entrance of the axial dry dock, water sealing at contact gaps, installation of finish-rolled screw-thread (FRST) steel bars as the LDC structures at the immersion joints, and construction of rigid connections between tunnel element ES and the cut-and-cover tunnel. Finally, onsite observation of the deformation states of Gina gaskets and monitoring of the tensile forces of FRST steel bars at the immersion joints verified the successful implementation of the new dry-land construction method, supporting the use of these techniques in closure joint design and construction for inland-river immersed tunnels.

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通过旱地施工方法创新设计和建造内陆河沉管隧道的封闭接头:中国鱼梁洲隧道案例研究
为填充沉管隧道构件之间或隧道构件与相邻明挖隧道之间的空间而建造的封闭缝对沉管隧道的纵向稳定性至关重要,并影响隧道施工的总体成本和工期。为了避免妨碍通航和降低封闭缝施工难度,内陆河沉管隧道的封闭缝施工广泛采用了旱地施工方法,特别是使用轴向旱坞的程序。然而,传统的旱地施工方法存在许多固有缺陷。例如,水下大型钢筋混凝土抗渗结构施工涉及的水下工程多、施工工艺复杂、作业时间跨度长、成本高。针对上述问题,在中国鱼梁洲沉管隧道的基础上,开发了一种基于隧道-土壤界面摩擦力的新型陆河沉管隧道闭合缝旱地施工方法。考虑到反淤泥沙对隧道土界面摩擦力的不利影响,进行了大规模的实验室和现场剪切试验,得出了隧道构件底板与预铺卵石基床之间的界面摩擦系数。设计并组装了一个复合混凝土钢夹层(CCSS)挡水系统,以将干船坞中的水与河道分开。提出了一种基于数值模拟的简化分析方法,用于确定轴向干船坞脱水对元素 ES 所产生的等效水平推力 P。根据轴向干船坞脱水阶段隧道构件的水平防滑稳定性分析,建立了新干地施工方法的关键设计参数方程。通过对隧道构件在隧道纵向的静力平衡进行研究,设计了浸入式接缝处的临时纵向位移约束(LDC)结构。此外,还系统地设计了新型旱地施工方法的以下关键施工技术:在轴向旱坞入口处安装 CCSS 挡水系统、在接触间隙处进行水封、在浸入式接缝处安装精轧螺纹钢筋(FRST)作为 LDC 结构,以及在隧道构件 ES 和明挖回填式隧道之间建立刚性连接。最后,通过现场观察吉娜垫片的变形状态和监测浸入式接头处精轧螺纹钢筋的拉力,验证了新型旱地施工方法的成功实施,支持在内陆河浸入式隧道的封闭接头设计和施工中使用这些技术。
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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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