爆破地震波作用下城市隧道结构动力响应的敏感性

路亮; 龙源; 郭涛; 谢全民; 赵长啸; 高福银

doi:10.11883/1001-1455(2014)06-0701-08

爆破地震波作用下城市隧道结构动力响应的敏感性

doi: 10.11883/1001-1455(2014)06-0701-08

路亮^{1, 2, ,},
龙源¹,
郭涛¹,
谢全民^{1, 3},
赵长啸^{1, 3},
高福银¹

1.
解放军理工大学野战工程学院，江苏南京210007
2.
中国人民解放军72351部队，山东莱芜271109
3.
武汉军械士官学校，湖北武汉430075

基金项目: 国家自然科学基金项目（51178460，51204071）

详细信息

作者简介:
路亮(1983—), 男, 博士研究生

中图分类号: O384; TD235.1
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- 被引次数: 0
出版历程
- 收稿日期: 2013-04-03
- 修回日期: 2013-06-08
- 刊出日期: 2014-11-25

Dynamic response sensitivity of urban tunnel structures under blasting seismic waves to parameters

Lu Liang^{1, 2
, ,},
Long Yuan¹,
Guo Tao¹,
Xie Quan-min^{1, 3},
Zhao Chang-xiao^{1, 3},
Gao Fu-yin¹

1.
College of Field Engineering, University of Science and Technology of PLA, Nanjing 210007, Jiangsu, China
2.
72351 Unit, Laiwu 271109, Shandong, China
3.
Wuhan Ordnance N.C.O Academy, Wuhan 430075, Hubei, China

Funds: Supported bythe National Natural Science Foundationof China (51178460, 51204071)

More Information

Corresponding author: Lu Liang, jzd04-20087@163.com

摘要

摘要: 选取纵波作为研究对象，采用波函数展开法，推导了无限弹性介质中复合衬砌结构隧道在爆破地震波作用下动力响应问题的解析解，结合南京红山南路隧道群开挖工程开展了隧道结构动应力集中因数的敏感性分析，并通过曲线拟合分别得到了隧道围岩及内衬环向动应力集中因数随隧道结构动力学及几何参数变化的回归方程。分析结果表明：隧道围岩和二次衬砌层的弹性模量及围岩泊松比对考察点处环向动应力的影响较大，而初期支护层弹性模量的影响几乎可以忽略不计；衬砌层厚度变化对围岩环向动应力的影响要远大于内衬，在隧道施工设计时可以通过增加衬砌层的厚度平衡隧道结构的受力状态，但增加初期支护层的效果不如二次衬砌层。
- 爆炸力学 /
- 动力响应 /
- 解析解 /
- 隧道结构 /
- 爆破地震波
Abstract: Primary waves were chosen as the study object, then an analytical solution for the dynamic response of tunnels with composite lining in infinite media under blasting seismic waves was deduced based on the wave function expansion method.According to the solution, the sensitivity of dynamic stress concentration factors to parameters was analyzed with the tunnel group excavation at Nanjing Hongshan South Road.By curve fitting, the regression equations were obtained for the hoop dynamic stress concentration factors of the surrounding rock and inner lining varied with the kinetic and geometrical parameters, respectively.The analysis result show that the elastic moduli of the surrounding rock and secondary lining and the Poisson's ratio of the surrounding rock have more impact on the hoop dynamic stress at the observation points and the effect of the elastic modulus of the primary lining is negligible.The lining thickness change has greater influence on the hoop dynamic stress of the surrounding rock than on the inner lining.Increasing the lining thickness can balance the stress states of the tunnel structures in designs and constructions, but the effect by the thicker inner lining is not as well as that by the thicker secondary lining.
- mechanics of explosion /
- dynamic response /
- analytical solution /
- tunnel structures /
- blasting seismic waves

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图 1 爆破地震波衍射问题计算模型

Figure 1. Acalculation model for the diffraction problem of blasting seismic waves

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图 2 实测爆破振动信号时程曲线及功率谱密度

Figure 2. Time history and power spectrum density of measurement signal

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图 3 复合衬砌和单层衬砌条件下动应力集中因数对比

Figure 3. Comparison of dynamic stress concentration factors between composite－lining and single－lining tunnels

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图 4 K_A、K_B随围岩弹性模量的变化

Figure 4. K_Aand K_Bvaried with elastic modulus of surrounding rock

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图 5 K_A、K_B随初期支护层弹性模量的变化

Figure 5. K_Aand K_Bvaried with elastic modulus of primary lining

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图 6 K_A、K_B随二次衬砌层弹性模量的变化

Figure 6. K_Aand K_Bvaried with elastic modulus of secondary lining

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图 7 K_A、K_B随围岩泊松比的变化

Figure 7. K_Aand K_Bvaried with Poisson's ratio of surrounding rock

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图 8 K_A、K_B随二次衬砌层厚度的变化

Figure 8. K_Aand K_Bvaried with secondary lining thickness

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图 9 K_A、K_B随初期支护层厚度的变化

Figure 9. K_Aand K_Bvaried with primary lining thickness

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表 1 敏感性分析所用的材料参数

Table 1. Materials parameters for sensitivity analysis

介质	E/GPa	ρ/(g·cm^-3)	υ	d/m
围岩(Ⅰ)	50(40~95)	2.60	0.26(0.20~0.40)
C20砼(Ⅱ)	25(20~30)	2.50	0.25	0.15(0.10~0.30)
C30砼(Ⅲ)	32(20~36)	2.50	0.30	0.45(0.25~0.60)

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表 2 动应力集中因数随隧道物理力学参数变化关系的回归方程

Table 2. Regression equations for relations between dynamic stress concentration factors and physico－mechanical parameters of tunnel

回归方程	R²	S_rs
K_A=-0.230+0.019E₁-1.818×10^-4E₁²+6.608×10^-7E₁³	0.999	2.996×10^-4
K_B=5.183-0.012E₁+1.100×10^-3E₁²-4.032×10^-6E₁³	0.999	7.920×10^-3
K_A=0.345+2.512×10^-4E₂-2.697×10^-5E₂²	0.978	3.875×10^-4
K_B=2.012-1.037×10^-2E₂+9.276×10^-5E₂²	0.997	1.713×10^-4
K_A=0.601-8.320×10^-3E₃	0.999	3.171×10^-4
K_B=0.047+5.501×10^-2E₃	0.999	1.390×10^-3
K_A=0.479-1.763×10^-2υ-2.075υ²	0.999	1.098×10^-4
K_B=2.221-0.743υ-3.213υ²	0.999	1.132×10^-4

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表 3 动应力集中因数随隧道几何尺寸变化关系的回归方程

Table 3. Regression equations for variations of dynamic stress concentration factors with geometrical dimensions of tunnel

回归方程	R²	S_rs
K_A=0.585-0.619d₁+0.135d₁²	0.989	5.160×10^-3
K_B=1.710+0.275d₁-0.115d₁²	0.996	7.783×10^-4
K_A=0.427-0.369d₂	0.964	7.918×10^-4
K_B=1.764+0.186d₂	0.992	3.761×10^-4

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