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张霄, 丁智, 王震, 夏唐代. 桥桩钢套管施工引起隧道管片横向变形与内力研究[J]. 岩土工程学报, 2022, 44(11): 2052-2062. DOI: 10.11779/CJGE202211011
引用本文: 张霄, 丁智, 王震, 夏唐代. 桥桩钢套管施工引起隧道管片横向变形与内力研究[J]. 岩土工程学报, 2022, 44(11): 2052-2062. DOI: 10.11779/CJGE202211011
ZHANG Xiao, DING Zhi, WANG Zhen, XIA Tang-dai. Transverse deformations and internal forces of tunnel segments caused by construction of steel casings of bridge piles[J]. Chinese Journal of Geotechnical Engineering, 2022, 44(11): 2052-2062. DOI: 10.11779/CJGE202211011
Citation: ZHANG Xiao, DING Zhi, WANG Zhen, XIA Tang-dai. Transverse deformations and internal forces of tunnel segments caused by construction of steel casings of bridge piles[J]. Chinese Journal of Geotechnical Engineering, 2022, 44(11): 2052-2062. DOI: 10.11779/CJGE202211011

桥桩钢套管施工引起隧道管片横向变形与内力研究

Transverse deformations and internal forces of tunnel segments caused by construction of steel casings of bridge piles

  • 摘要: 为了合理评估桥桩施工影响下隧道结构的健康状态和长期服役性能,有必要对隧道管片横向受力与变形特征进行深入研究。根据桥桩施工附加应力结果,首先,提出一种考虑既有隧道刚度的附加围压计算公式,获得桥桩钢套管施工过程的隧道附加围压分布;其次,基于壳—弹簧模型建立管片三维数值模拟,探讨隧道管片横向变形与内力的变化规律;最后,定义一种识别隧道旋转行为,提出管片局部偏转的性能指标。结果表明:计算结果与实测数据对比验证较为吻合;随着桥桩钢套管施工深度的增加,隧道先发生小幅度左移后发生倾斜右移,隧道整体产生沉降及“竖椭圆”变形;桥桩施工至隧道轴线埋深之后,隧道收敛急剧变化,进入隧道横向变形发展的不易控制阶段;管片弯矩零点、剪力最值大多位于相邻块拼接处,故接缝处受剪力较大更易发生张开错台、渗漏水等病害;桥桩钢套管施工过程中隧道管片经历了从顺时针旋转到逆时针旋转的转变,其临界点位于隧道轴线埋深下方0.85D范围。

     

    Abstract: In order to reasonably evaluate the health status and long-term service performance of tunnel structures under the construction influences of bridge piles, it is necessary to conduct an in-depth study on the transverse force and deformation characteristics of the tunnel segments. Based on the results of the additional stress under construction of a bridge pile, firstly a formula for calculating the additional confining pressure considering the stiffness of the existing tunnel is proposed, and the additional confining pressure distribution of the tunnel is obtained during the construction of the steel casing of the bridge pile. Then, based on the shell-spring model, a three-dimensional numerical simulation of the segment is established, and the laws of the transverse deformation and internal force of the tunnel segments are discussed. Finally, a method for identifying the rotation behavior of the tunnel is defined, and the performance index of the local deflection of the segment is proposed. The results show the calculated results are more consistent with the measured data. As the construction depth of the steel casing of the bridge pile increases, the tunnel moves to the left firstly and then tilts to the right, which eventually leads to the overall settlement and the "vertical ellipse" deformation of the tunnel as a whole. After the bridge pile is constructed to the depth of the tunnel axis, the tunnel convergence changes drastically and enters the difficult-to-control phase of the development of the lateral deformation of the tunnel. The zero value of bending moment and the maximum value of shear force are mostly located at the joints of the adjacent segments, so the joints with larger shear force are more prone to diseases such as misalignment, water leakage, etc. During the construction of the steel casing of the bridge pile, the tunnel segments have undergone a transition from clockwise rotation to counterclockwise one, and the critical point is in the range of 0.85D below the buried depth of the tunnel axis.

     

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