变坡条件下浅埋偏压隧道围岩压力解析法

doi:10.3969/j.issn.0258-2724.20180825

基金项目:国家自然科学基金（51508475）；四川省科技厅科技创新创业项目（2018RZ0109）；中央高校基本科研业务费理工类科技创新项目（2682016CX017）；教育部“春晖计划”科研项目（Z2016168）；高层次人才队伍建设科研支持项目（10101X10096078）

详细信息

作者简介:
严涛（1982—），男，讲师，研究方向为隧道及地下工程，电话：13808197336，E-mail：yantao228@163.com

中图分类号:V221.3
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出版历程
- 收稿日期:2018-09-18
- 修回日期:2018-11-19
- 网络出版日期:2018-04-04
- 刊出日期:2020-06-01

Analytical Method for Calculation of Surrounding Rock Pressure of Shallow-Buried and Unsymmetrically Loaded Tunnel Adjacent to Variable Slope

摘要

摘要:目前浅埋偏压隧道围岩压力主要采用隧规计算方法，而对于左右洞隧道洞门不在同一里程，一侧需要开挖路基边坡，使隧道从自然放坡状态转为邻路基变坡状态的工况，隧规不适用于计算其围岩压力. 依托安徽某高速公路，运用极限平衡原理推导了邻路基变坡条件下浅埋偏压隧道围岩压力解析解. 计算结果表明：由于变坡的存在，深埋侧修正算法计算竖向围岩压力小于规范法，相对误差为15.98%，水平围岩压力保持不变；浅埋侧修正算法计算竖向围岩压力及水平压力均小于规范法，其竖向压力相对误差为24.93%，水平压力相对误差为5.50%，变坡的存在对浅埋侧影响较大；对比围岩竖向及水平偏压率，有变坡围岩偏压率更大；围岩位移、应力及等效应力，有变坡约为无变坡的1～5倍，围岩及结构更加偏于不安全.
- 浅埋偏压隧道/
- 变坡/
- 围岩压力/
- 解析法
Abstract:At present the surrounding rock pressure of shallow-buried and unsymmetrical loading tunnels is generally calculated by code for design of road tunnel. However, when the two portal parts of twin tunnels are not located at the same mileage, one of them will be constructed adjacent to the excavated subgrade slope, rather than under a natural mountain slope. In this case, the code is not applicable to the calculation of surrounding rock pressure of the tunnel. To solve this problem, an analytical solution for calculating the surrounding rock pressure of the shallow-buried and unsymmetrically loaded tunnel adjacent to variable slope is proposed using the limited equilibrium theory, taking a highway tunnel in Anhui province as a prototype. The results indicate that due to the variable slope, the vertical pressure in the surrounding rock of deep-buried side calculated by the modified algorithm is smaller than that calculated by the code with a relative error of 15.98%, while values of horizontal pressure in the deep-buried rock remain unchanged. However, in the surrounding rock of shallow-buried side, both vertical and horizontal rock pressures calculated by the modified algorithm are smaller than that by the code, with relative errors being 24.93% and 5.50% for vertical and horizontal pressures, respectively. Therefore, the variable slope has a greater influence on the shallow side. In addition, the surrounding rock with variable slope has a larger bias rate than that with a natural slope. Values of stress, equivalent stress and rock displacement of the former are approximately 1–5 times larger than those of the latter, indicating that the tunnel with variable slope is more unsafe.
- shallow-buried and unsymmetrically loaded tunnel/
- variable slope/
- surrounding rock pressure/
- analytical method

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图 1坡度变化示意

Figure 1.Change of slope

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图 2变坡条件下浅埋偏压隧道滑动体受力

Figure 2.Force analysis of the shallow-buried and unsymmetrically loaded tunnel with variable slope

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图 3块体CHFD受力

Figure 3.Force analysis of blockCHFD

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图 4块体CHED受力

Figure 4.Force analysis of blockCHED

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图 5块体HEF受力

Figure 5.Force analysis of blockHEF

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图 6块体CHED受力矢量图

Figure 6.Force vector diagram of blockCHED

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图 7浅埋偏压隧道受竖直围岩压力示意

Figure 7.Vertical pressure analysis of the shallow-buried and unsymmetrically loaded tunnel

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图 8浅埋偏压隧道围岩压力示意

Figure 8.Surrounding rock pressure analysis of the shallow-buried and unsymmetrically loaded tunnel

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图 9计算模型（单位：m）

Figure 9.Calculation model (unit: m)

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表 1围岩压力对比

Table 1.Comparison of surrounding rock pressures kPa

变量	深埋侧			浅埋侧
变量	规范法	修正算法	相对误差/%	规范法	修正算法	相对误差/%
q₁	104.42	90.03	15.98	72.06	57.68	24.93
e₁	21.85	21.85	0	13.61	12.90	5.50
e₂	51.37	51.37	0	41.48	39.32	5.49

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表 2计算结果对比

Table 2.Comparison of calculation results

压力类型	位置	压力（规范法）/kPa		偏压率	压力（修正算法）/kPa		偏压率
压力类型	位置	内侧	外侧	偏压率	内侧	外侧	偏压率
竖直压力	拱腰	104.42	72.06	1.45	90.03	57.68	1.56
水平压力	拱腰	41.13	31.20	1.32	41.13	29.57	1.39
水平压力	拱底	51.37	41.48	1.24	51.37	39.32	1.31

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表 3计算参数

Table 3.Calculation parameters

类别	$\gamma $/ （kN•m^–1）	弹性模量 E/GPa	泊松比$\mu $	粘聚力C/MPa	${\varphi _{\rm{c}}}$/ （°）
Ⅴ级围岩	1 800	2.5	0.40	0.5	35
加固圈	2 100	6.0	0.35	0.7	39
初期支护	2 300	29.5	0.20

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表 4围岩变形及应力对比

Table 4.Comparison of surrounding rock deformation and stress

项目	有变坡	无变坡	比值
围岩最大x向移位/mm	1.132	0.861	1.31
围岩最大y向移位/mm	2.433	2.264	1.05
围岩最大x向应力/MPa	0.667	0.540	1.24
围岩最大y向应力/MPa	0.723	0.615	1.18
围岩第 1 主应力/MPa	0.121	0.021	5.76
围岩第 3 主应力/MPa	–0.796	–0.702	1.13
等效应力/MPa	0.490	0.410	1.20

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