拱部为干燥粉细砂层之大断面隧道施工技术

›› 2014, Vol. 28 ›› Issue (2): 34-38.

拱部为干燥粉细砂层之大断面隧道施工技术

侯刚

(中铁十二局集团公司第三工程公司，太原 100037)

收稿日期:2013-09-11 出版日期:2014-04-21 发布日期:2014-04-25
作者简介:侯刚(1970-)，男，山西平遥人，1996年7月毕业于苏州城建环保学院，高级工程师，研究方向为岩土工程。

Construction Techniques of Dry Silty Sand Soils at theArch of a Large Section Tunnel

HOU Gang

（The 3rd Engineering Co., Ltd., China Railway 12th Bureau Group, Taiyuan, 100037）

Received:2013-09-11 Online:2014-04-21 Published:2014-04-25

摘要/Abstract

摘要： 大西客专上白隧道出口工区隧道拱部为干燥粉细砂地层，下部为黄土地层。粉细砂层含水量小、粒径均匀，自稳性能极差，若采用普通注浆方式固结砂层其效果差，施工过程中经常出现流沙涌砂情况，无法保证隧道施工安全。经过对多种预支护技术的对比分析，决定采用水平旋喷预支护后再采用三台阶法开挖，并用三维数值方法分析隧道施工过程的力学特性，现场监测结果和施工效果表明，所采用施工方案能有效保证隧道施工安全。

关键词: 干燥粉细砂, 大断面隧道, 水平旋喷预支护, 三维有限元, 三台阶法

Abstract: Two different soil layers are deposited at a tunnel of Shangbai Passenger Rail for DatongXian Line. The upper dry silty fine sand soil is at the arch portion of the tunnel, and the underlying soil is classified as loess. The silty fine sand soil is characterized as low moisture content, uniform in grain size and it has a poor selfstability. The conventional permeating grout often results in a poor cementation outcome. Further, the grouting operation can often lead to the sand flow and even collapse incidents and a safe construction of the tunnel is jeopardized. After feasibility studies of several prelining mitigation methods, the horizontal jet grout methods followed by the threebench excavation were selected. The tunnel excavation process was also simulated with the three dimensional numerical method. Both the construction monitoring and the simulation results indicated that the adopted mitigation method of horizontal jet grout is a viable solution.

Key words: Dry Silty Fine Sand, Large Section Tunnels, Horizontal Jet Grout Prelining, 3D Finite Element Methods, ThreeBench Excavation Method

侯刚. 拱部为干燥粉细砂层之大断面隧道施工技术[J]. , 2014, 28(2): 34-38.

HOU Gang. Construction Techniques of Dry Silty Sand Soils at theArch of a Large Section Tunnel[J]. , 2014, 28(2): 34-38.

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