盾构输水隧道C-T快速连接件纵缝受弯特性试验研究

doi:10.3973/j.issn.2096-4498.2024.S1.024

隧道建设（中英文） ›› 2024, Vol. 44 ›› Issue (S1): 224-229.DOI: 10.3973/j.issn.2096-4498.2024.S1.024

盾构输水隧道C-T快速连接件纵缝受弯特性试验研究

王健¹，熊碧露¹，吴昱东^{2， 3， *}

（1. 深圳中广核工程设计有限公司，广东深圳 518172； 2. 同济大学土木工程学院地下建筑与工程系，上海 200092； 3. 同济大学岩土及地下工程教育部重点实验室，上海 200092）

出版日期:2024-08-20 发布日期:2024-09-02
作者简介:王健（1989—），男，内蒙古呼伦贝尔人，2012年毕业于北京交通大学，土木工程专业，本科，工程师，主要从事核电厂水工构筑物和地下管廊结构设计工作。E-mail： dycewang@163.com。*通信作者：吴昱东， E-mail： 2111002@tongji.edu.cn。

Experimental Study on Flexural Characteristics of Longitudinal Joints with C-T Quick Connectors in Shield Water Conveyance Tunnel

WANG Jian¹, XIONG Bilu¹, WU Yudong^{2, 3, *}

(1. China Nuclear Power Design Company Ltd., Shenzhen 518172, Guangdong, China； 2. Department of Geotechnical Engineering, College of Civil Engineering, Tongji University, Shanghai 200092, China； 3. Key Laboratory of Geotechnical and Underground Engineer of Ministry of Education, Tongji University, Shanghai 200092, China)

Online:2024-08-20 Published:2024-09-02

摘要/Abstract

摘要： C-T快速连接件纵缝应用于盾构输水隧道时，隧道中的内水压使接缝处轴力减小，进而影响接缝的抗弯性能，但轴力变化对快速连接件纵缝抗弯性能的影响研究还不充分。因此，开展较小轴力正弯矩下C-T快速连接件接缝足尺压弯试验，并将试验结果与既有相同接缝的较大轴力工况试验对比，总结不同轴力下C-T件纵缝压弯力学特性。结果表明： 1）较小轴力下，C-T件纵缝的受弯过程可以分为混凝土单独承弯阶段和混凝土连接件共同承弯阶段。单独承弯阶段弯矩首先呈线性增长，之后接缝抗弯刚度不断减小。当C-T件搭接时接缝抗弯刚度增大，之后连接件快速屈服，抗弯刚度不断降低直至连接件断裂接缝破坏。2）较小轴力下，影响接缝抗弯能力的主要因素为C-T件的搭接、屈服及断裂，需要提高C-T件的抗拉性能以防止其过早屈服；较大轴力下，外侧混凝土的搭接和压溃是影响接缝抗弯能力的主要因素点。在不同轴力下连接件周围均出现裂缝。

关键词: 盾构隧道, 快速连接件, 轴力大小, 纵缝受弯行为, 足尺试验

Abstract: When the longitudinal joints with C-T quick connectors are used in shield water conveyance tunnels, the internal water pressure in the tunnel decreases the axial force at the joints, which in turn affects the flexural performance of the joints. However, the axial force effect on the flexural performance of the joints with C-T quick connectors has not been adequately investigated. Therefore, a full-scale compression-bending experiment of C-T quick connector joints under a smaller axial force was carried out in this study. The experiment results were compared with those of the larger axial force experiment with the same joint, and the flexural characteristics of the joint with CT connectors under different axial forces were summarized. The results show that: (1) Under smaller axial force, the flexural process of CT connectors joints can be divided into concrete bending stage and concrete and connectors bending stage. In the concrete bending stage, the moment firstly increases linearly, and then the flexural stiffness of the joint decreases continuously. The flexural stiffness of the joint increases when the C-T connectors are lapped, after which the connectors yields rapidly and the flexural stiffness decreases until the joint failure. (2) Under smaller axial forces, the factors affecting the flexural capacity of the joints are lap, yield, and fracture of the C-T connectors; the tensile properties of C-T connectors need to be improved to prevent premature yielding; while under larger axial forces, the lap and crush of the outer concrete are the critical nodes in the flexural process of the joints. Cracks were observed around the connectors under different axial forces.

Key words: shield tunnel, quick connector, axial force magnitude, longitudinal joint flexural behavior, full-scale experiment

王健, 熊碧露, 吴昱东. 盾构输水隧道C-T快速连接件纵缝受弯特性试验研究[J]. 隧道建设, 2024, 44(S1): 224-229.

WANG Jian, XIONG Bilu, WU Yudong. Experimental Study on Flexural Characteristics of Longitudinal Joints with C-T Quick Connectors in Shield Water Conveyance Tunnel[J]. Tunnel Construction, 2024, 44(S1): 224-229.

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盾构输水隧道C-T快速连接件纵缝受弯特性试验研究

Experimental Study on Flexural Characteristics of Longitudinal Joints with C-T Quick Connectors in Shield Water Conveyance Tunnel

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