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采用双层衬砌设计的高填方明挖隧道土压力和内力研究:基于光纤布拉格光栅自动数据采集系统的现场测试。

Research on the Earth Pressure and Internal Force of a High-Fill Open-Cut Tunnel Using a Bilayer Lining Design: A Field Test Using an FBG Automatic Data Acquisition System.

机构信息

Key Laboratory of Transportation Tunnel Engineering, Ministry of Education, Southwest Jiaotong University, Chengdu 610031, Sichuan, China.

出版信息

Sensors (Basel). 2019 Mar 27;19(7):1487. doi: 10.3390/s19071487.

DOI:10.3390/s19071487
PMID:30934699
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6480922/
Abstract

When there are railway tunnels on both sides of a valley, a bridge is usually built to let trains pass. However, if the valley is very close to an urban area, building an open-cut tunnel at the portal and then backfilling it to create available land resources for the city and to prevent excavation slag from polluting the environment would be a wise choice. This has led to the emergence of a new type of structure, namely, the high-fill open-cut tunnel. In this paper, by performing an automatic long-term field test on the first high-fill open-cut tunnel using a bilayer design in China, the variations of earth pressure and structural internal force during the backfilling process were obtained, and different tunnel foundation types were studied. The results showed that the earth pressure significantly exceeded the soil column weight, with a maximum earth pressure coefficient between 1.341 and 2.278. During the backfilling process, the earth pressure coefficient increased at first and then decreased slowly to a relatively stable value, and a stiffer foundation would make the structure bear higher earth pressure (1.69 times the normal one observed during monitoring). The change of internal force had two stages during backfilling: before the backfill soil reached the arch crown, the internal force of the lining changed slowly and then grew linearly as the backfill process continued. Moreover, the axial force ratio of the inner and outer linings was close to their thickness proportion, and the interaction mode between the two layers was very similar to the composite beam.

摘要

当山谷两侧都有铁路隧道时,通常会建造一座桥梁让火车通过。然而,如果山谷非常靠近城区,在洞口处修建明洞并回填,以创造城市可用的土地资源,防止挖掘渣污染环境,将是一个明智的选择。这导致了一种新型结构的出现,即高填明洞。本文通过对中国首例采用双层设计的高填明洞进行自动长期现场测试,获得了回填过程中土压力和结构内力的变化,并研究了不同的隧道基础类型。结果表明,土压力显著超过土柱重量,最大土压力系数在 1.341 到 2.278 之间。在回填过程中,土压力系数先增大后缓慢减小至相对稳定值,较硬的基础会使结构承受更高的土压力(比监测中观察到的正常土压力高 1.69 倍)。回填过程中,内力的变化有两个阶段:在回填土到达拱顶之前,衬砌内力变化缓慢,然后随着回填过程的继续线性增长。此外,内外衬砌的轴力比接近其厚度比例,两层之间的相互作用模式与组合梁非常相似。

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