结构面对隧道钻爆围岩损伤影响的数值试验研究

doi:10.19952/j.cnki.2096-5052.2026.01.01

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摘要为揭示结构面几何参数对隧道爆破开挖围岩损伤演化与断面成型质量的影响机理,以厦门海沧疏港通道隧道工程为原型,采用LS-DYNA建立三维数值模型开展数值试验,研究不同结构面倾角、宽度和间距对隧道钻爆围岩损伤分布的影响。结果表明:结构面对围岩爆破损伤具有显著的方向性控制作用,损伤沿结构面倾向优先延伸,而在法向上受到明显限制;结构面倾角由0°增加至90°,断面损伤由近似对称逐步转为定向导向控制的非对称扩展,受分割阻隔作用主导而呈局部化与离散化特征;结构面宽度由0.1 m增加至0.7 m,显著强化了界面弱化效应与应力波场散射耗能,超挖面积与最大超挖显著增加;结构面间距由0.6 m增加至2.4 m,超挖减小、轮廓平整性增加。研究成果可为揭示隧道爆破的能量控制、参数优化与成型质量提升提供依据。

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	王建秀
	曹安生
	高元博
	刘鹏飞
	严龙
	林路宇

关键词: 结构面隧道钻爆数值试验围岩损伤超欠挖

Abstract: To reveal the influence mechanism of geometric parameters of structural planes on the damage evolution of surrounding rock and the quality of section formation during tunnel blasting excavation, taking the Xiamen Haicang Expressway Tunnel project as a prototype, a three-dimensional numerical model was established using LS-DYNA to conduct numerical experiments. The influence of different structural plane dip angles, widths, and spacing on the distribution of blasting-induced damage in the tunnel surrounding rock was investigated. The results indicated that structural planes exerted a pronounced directional control effect on blasting damage. Damage preferentially extended along the dip direction of the structural planes, while being significantly constrained in the normal direction. As the dip angle increased from 0° to 90°, the cross-sectional damage pattern transitioned from approximately symmetrical to an asymmetrical expansion dominated by directional guidance, exhibiting localized and discrete characteristics due to segmentation and blocking effects. When the structural plane width increased from 0.1 m to 0.7 m, the interface weakening effect and stress wave scattering energy dissipation were significantly enhanced, leading to a notable increase in overbreak area and maximum overbreak. Conversely, as the structural plane spacing increased from 0.6 m to 2.4 m, overbreak decreased and contour smoothness improved. The research findings provided a basis for understanding energy control, parameter optimization, and the improvement of formation quality in tunnel blasting.

Key words: structural plane tunnel drilling and blasting numerical experimentation surrounding rock damage overbreak and underbreak

发布日期: 2026-03-23

中图分类号:	U45
	TU452

基金资助: 上海市住建委重点资助项目(沪建科2024-Z02-007);中国水利水电第十一工程局有限公司资助项目(kh0023020232375,kh0023020250483);厦门路桥建设集团有限公司科技资助项目(2024137)

作者简介: 王建秀(1971— ),男,吉林长春人,教授,博士生导师,博士,主要研究方向为岩石动力学与工程、工程地下水与环境控制. E-mail:wang_jianxiu@163.com

引用本文:

王建秀, 曹安生, 高元博, 刘鹏飞, 严龙, 林路宇. 结构面对隧道钻爆围岩损伤影响的数值试验研究[J]. 隧道与地下工程灾害防治, 2026, 8(1): 1-12.
WANG Jianxiu, CAO Ansheng, GAO Yuanbo, LIU Pengfei, YAN Long, LIN Luyu. Numerical experimental study on the influence of structure plane on the damage of surrounding rock in tunnel drilling and blasting. Hazard Control in Tunnelling and Underground Engineering, 2026, 8(1): 1-12.

链接本文:

http://tunnel.sdujournals.com/CN/Y2026/V8/I1/1

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