围压作用下锚杆锚固结构动态拉拔数值试验研究

doi:10.19952/j.cnki.2096-5052.2025.04.04

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摘要为探究围压作用下锚杆锚固结构的动态响应,分析锚固界面载荷传递特征及损伤机理,阐明围压对锚杆动态黏结强度增强效应的影响规律,开展了不同围压、加载速率条件下锚杆锚固结构拉拔数值试验研究。结果表明:围压作用下随着加载速率的增大,锚杆最大拔出载荷增大,锚固界面表现出明显的加载速率依赖性和剪切增强特性。高加载速率时,锚固界面在软化阶段局部应变增大,动态剪应力出现波动,围压的止裂效应使波动凹点靠近加载端,由于锚固体承载力增加,造成波动幅值随着围压的增大而增大。相对黏结强度与对数速率比呈正相关,围压越大,锚杆黏结性能对加载速率越敏感。而锚杆发生屈服后,围压从0.5 MPa增至1.0 MPa时,两者关系曲线的斜率仅提高11.96%,围压对锚杆动态黏结强度的增强效应趋于饱和。随着围压增大,锚杆动态峰值滑移量呈现先增大后减小的趋势,锚固结构局部逐渐发生破坏,失效面积向混凝土表面扩展。

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	于水生
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	陆书灿

关键词: 锚杆锚固结构黏结性能围压加载速率数值试验

Abstract: To investigate the dynamic mechanical response of rockbolt grouted structures under confining pressure, the load transfer characteristics and damage mechanisms were analyzed, and the influence of confining pressure on the dynamic bond strength enhancement effect of rockbolts was elucidated. Numerical and experimental studies on the pullout behavior of rockbolt grouted structures under various confining pressures and loading rates were conducted.The results showed that under confining pressure, the maximum pullout load of the rockbolt increased with the loading rate, and the bonding interface exhibited significant loading rate dependence and shear enhancement characteristics.At high loading rates, the local strain at the bond interface was increased during the softening phase, while the dynamic shear stress was found to fluctuate, with the fluctuating concave point shifting closer to the loading end due to the restraining effect of the confining pressure. The fluctuation amplitude was enhanced with increasing confining pressure, attributed to the improved bearing capacity of the grouted body.A positive correlation was identified between the relative bond strength and the logarithmic rate ratio, and the bond performance of the rockbolt was found to be more sensitive to the loading rate under higher confining pressure. After yielding, the slope of the relationship curve was increased by only 11.96% when the confining pressure was raised from 0.5 MPa to 1.0 MPa, indicating that the enhancement effect of confining pressure on the dynamic bond strength of the rockbolt tended toward saturation. The dynamic peak slip of the rockbolt initially increased and subsequently decreased as the confining pressure was elevated. Localized damage to the grouted body was progressively generated, and the failure zone was observed to extend toward the concrete surface.

Key words: rockbolt grouted structures bond performance confining pressure loading velocity numerical test

发布日期: 2025-12-29

中图分类号:	TD353
	TU476

基金资助: 国家自然科学基金资助项目(52104157);中原工学院“青年骨干教师培养计划”资助项目(2023XQG13);中原工学院“学科青年硕导培育计划”资助项目(SD202424)

作者简介: 于水生(1988— ),男,河南周口人,副教授,硕士生导师,博士,主要研究方向为锚杆支护、材料动力学响应. E-mail:yuss.1987@163.com

引用本文:

于水生, 张鸿森, 孙玉周, 赵毅, 陆书灿. 围压作用下锚杆锚固结构动态拉拔数值试验研究[J]. 隧道与地下工程灾害防治, 2025, 7(4): 43-52.
YU Shuisheng, ZHANG Hongsen, SUN Yuzhou, ZHAO Yi, LU Shucan. Numerical experimental study on dynamic pullout of rockbolt grouted structures under confining pressure. Hazard Control in Tunnelling and Underground Engineering, 2025, 7(4): 43-52.

链接本文:

http://tunnel.sdujournals.com/CN/Y2025/V7/I4/43

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