Detection and numerical simulation of blasting-induced damage in shallow-buried twin tunnels with small spacing

被引：0

作者：

Liu M. ^{[1
]}

Chen S. ^{[1
]}

Sun J. ^{[2
]}

He F. ^{[3
]}

Jie H. ^{[3
]}

机构：

[1] College of Civil Engineering, Huaqiao University, Xiamen

[2] Jinan Urban Construction Group Co. Ltd., Jinan

[3] Fujian Railway Construction Co. Ltd., China Railway 24th Bureau Group Co., Ltd., Fuzhou

来源：

Chen, Shihai (cshblast@163.com) | 1600年 / Explosion and Shock Waves卷 / 41期

关键词：

Acoustic detection; Blasting excavation; Damage constitutive model; Shallow-buried; Small spacing tunnel;

D O I：

10.11883/bzycj-2020-0378

中图分类号：

学科分类号：

摘要：

In order to study the damage effect of blasting load on the surrounding rock of shallow-buried small spacing twin tunnels, the shallow-buried tunneling section of the south extension project of Shunhe Expressway is taken as the engineering background. Firstly, based on the dynamic damage evolution and Hoffman failure criterion, an anisotropic dynamic damage constitutive model for rock materials is established. Then, by using the secondary development function of the LSDYNA software, the constitutive model is applied to the numerical simulation of the tunnel blasting damage. Finally, based on the acoustic wave measurement theory, the wave velocities in the surrounding rock of the shallow-buried small spacing twin tunnels before and after blasting were measured by using non-metallic ultrasonic detectors, and the damage of the surrounding rock is evaluated from changes in wave velocity. The applicability of the anisotropic dynamic damage constitutive model and the accuracy of the numerical results are verified by comparing the numerical simulation results with the field test results. The numerical simulation results show that the maximum damage radius of single-hole blasting is 0.58 m, and the maximum damage depth is 1.88 m. According to the failure threshold of the rock mass, the horizontal failure range of the rock mass can reach 0.14 m, and the failure depth is 1.70 m. According to the field test, the damage degree of the middle intercalated rock is higher than that of the other parts of the surrounding rock in the alternate blasting excavation of the double track tunnel. The damage range of the surrounding rock caused by blasting excavation is about 0.50 m, which is close to the simulation results, and verifying the accuracy of the anisotropic dynamic damage constitutive model. The research results have a certain guiding role on the blasting excavation and damage control of shallow-buried twin tunnels with small spacing.. © 2021, Editorial Staff of EXPLOSION AND SHOCK WAVES. All right reserved.

引用

共 20 条

[1] YU L Y, LI S C, XU B S., Study on the effect of blasting vibration for Qingdao twin subsea tunnels, China Civil Engineering Journal, 43, 8, pp. 100-108, (2010)
[2] GRADY D E, KIPP M E., Continuum modelling of explosive fracture in oil shale, International Journal of Rock Mechanics and Mining Sciences & Geomechanics Abstracts, 17, 3, pp. 147-157, (1980)
[3] TAYLOR L M, CHEN E P, KUSZMAUL J S., Microcrack-induced damage accumulation in brittle rock under dynamic loading, Computer Methods in Applied Mechanics and Engineering, 55, 3, pp. 301-320, (1986)
[4] CHEN J H, ZHANG J S, LI X P., Model of rock blasting-induced damage considering integrity of rock mass and its application, Chinese Journal of Geotechnical Engineering, 38, 5, pp. 857-866, (2016)
[5] WANG J, SONG W D, FU J X., A damage constitutive model and strength criterion of rock mass considering the dip angle of joints, Chinese Journal of Rock Mechanics and Engineering, 37, 10, pp. 2253-2263, (2018)
[6] OU X F, ZHANG X M, ZHANG C, Et al., Study on bedding effect and damage constitutive model of slate under compressive dynamic loading, Chinese Journal of Rock Mechanics and Engineering, 38, S2, pp. 3503-3511, (2019)
[7] MENG F B, LIN C M, CAI L G, Et al., Cumulative damage evaluation of clip rock in small-distance tunnels caused by blasting excavation and its application, Rock and Soil Mechanics, 32, 5, pp. 1491-1494, (2011)
[8] WANG Z D, XIA Y Y, ZHOU X, Et al., Blasting vibration control and damage characteristics of bedding rock slopes [J], Explosion and Shock Waves, 37, 1, pp. 27-36, (2017)
[9] TANG C M., Numerical simulation of progressive rock failure and associated seismicity, International Journal of Rock Mechanics and Mining Sciences, 34, 2, pp. 249-261, (1997)
[10] MA G W, AN X M., Numerical simulation of blasting-induced rock fractures, International Journal of Rock Mechanics and Mining Sciences, 45, 6, pp. 966-975, (2008)

← 1 2 →