C型管嵌入深度与结构面压力对ACC加固作用影响试验研究

doi:10. 11799/ ce202509022

摘要/Abstract

摘要：

管索组合结构（ACC）作为一种新型支护结构已应用于多个井巷工程。为了解决工程应用中对C型管嵌入岩壁深度与结构面压力对ACC加固作用影响尚不清晰的问题，采用自主研发的管索拉剪试验系统，分别测试了5种不同C型管嵌入岩壁深度以及3种不同初始预紧力条件下ACC的剪切力学性能，获取了ACC的剪切荷载-剪切位移曲线及其剪切变形量, 研究了不同C型管嵌入岩壁深度下ACC的力学性能表现。试验结果表明，嵌入深度大的C型管会增加ACC的剪切荷载及剪切变形量，与嵌入深度0mm相比，嵌入深度为50、100、150及300mm时，峰值剪切荷载分别增加20.7%、43.1%、50.4%和54.6%，合理的C 型管嵌入深度能够有效提高ACC的加固效果；与结构面无正压力比较，初始预紧力提供给结构面的正压力配合ACC高抗剪性能可以进一步提高整个支护系统的峰值剪切荷载；不同初始预紧力下ACC峰值剪切荷载和剪切变形量明显不同，其峰值剪切荷载和剪切变形量通过增加初始预应荷载而减小；ACC在剪切方向上的延展性远远大于锚索，有效解决了在施加高预紧力后，锚索的剪切位移显著减少的问题。基于试验结果提出了C型管参数设计方法, 并详细介绍了ACC施工工艺，研究结果可为ACC在煤巷工程中的应用设计提供参考。

关键词:

管索组合结构 , 锚索 , 剪切试验 , 剪切荷载 , 剪切位移

Abstract:

As a new type of support structure, ACC has been gradually applied in many coal mine projects. However, in engineering application, the influence of c-shaped tube insertion depth and structural surface pressure on the reinforcement of ACC is still unclear. In this paper, the laboratory test method was used to establish a tensile and shear test system of the tube cable, and the shear mechanical properties of the ACC under 5 different c-shaped tube insertion depths and 3 different initial preload conditions were tested respectively. The shear load-shear displacement curve of ACC and its shear deformation are obtained. The mechanical properties of the ACC under different c-shaped tube insertion depths on the structural plane were studied, and the effects of the structural plane with and without normal pressure and different preload loads on the shear performance of the ACC were compared and analyzed. The test results show that the insertion depth of the c-shaped tube and the positive pressure of the structural surface have a certain influence on the reinforcement of the ACC under shearing action. The c-shaped tube with a large insertion depth will increase the shear load and shear deformation of the ACC. Compared with the insertion depth of 0mm, when the insertion depth is 50mm, 100mm, 150mm and 300mm, the peak shear load increases by 20.7%, 43.1%, 50.4% and 54.6%, respectively. The greater the insertion depth of the c-shaped tube, the higher the shear resistance of the ACC The better the performance, the reasonable c-shaped tube insertion depth can effectively improve the reinforcement effect of the ACC. Compared with no positive pressure on the structural surface, the positive pressure provided by the initial preload load to the structural surface combined with the high shear performance of ACC can further improve the peak shear load of the entire support system. The peak shear load and shear deformation of ACC under different initial preload loads are significantly different, and the peak shear load and shear deformation of ACC decrease by increasing the initial preload load. The breaking of ACC is mainly due to the combination of tension and shear, and compared with pure anchor cables, ACC has a good ability to enhance the shear strength of rock mass and resist shear deformation. The results of this study can provide reference for the further application design of ACC in coal roadway engineering.

中图分类号:

"> TD353

仝潇, 刘楠, 单仁亮, 李兆龙, 赵岩, 刘冬, 代卫林.

C型管嵌入深度与结构面压力对ACC加固作用影响试验研究 [J]. 煤炭工程, 2025, 57(9): 165-174.

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