Shan Renliang, Song Wei, Zhang Shupeng, Tong Xiao, Liang Junqi
School of Mechanics and Civil Engineering, China University of Mining and Technology (Beijing), Beijing, 100083, China.
North Blasting Technology Co., Ltd., Beijing, 100097, China.
Sci Rep. 2024 Oct 2;14(1):22903. doi: 10.1038/s41598-024-73905-8.
To prevent the early breakage of anchor cables under shear loads in support engineering, a combined structure of Anchor Cable with C-shaped Tube (ACC) has been proposed. The shear resistance enhancement mechanism of this structure and the mechanisms of various influencing factors have yet to be fully revealed. A refined nonlinear finite element model of ACC was original established using ABAQUS software, taking into account the actual structure of the steel strands and the interactions, such as contact and failure between the various components. Various anchor cable pretension forces and block strengths were set to investigate their effects on the shear mechanical response of ACC. The results successfully demonstrated a high correlation between peak shear load and pretension force. The results demonstrate that an increase in pretension force reduces the ACC's peak shear load and break displacement. Additionally, the structure exhibited higher flexural stiffness, the block strength was mobilized earlier, and the block failed locally more quickly. Under high pretension forces, the system exhibited higher shear stiffness in the early stages of shearing due to the influence of the axial force component. With low pretension forces, the ACC exhibited a larger break displacement due to the minor tensile deformation at the shear plane position for the same shear displacement. At low pretension forces, the structure's bending angle increased more rapidly during the middle and later stages of shearing, accompanied by a larger break displacement. Both of these factors led to a greater bending angle at the shear plane position at the point of failure. The results reveal the characteristic of the peak shear load initially increasing and then decreasing with the increase in test block strength, along with its underlying mechanism. As the block strength increased, the bending angle of the structure at the shear plane position increased more rapidly, resulting in higher shear stiffness. With high block strength, the combination of smaller break displacement and greater shear stiffness led to an initial increase followed by a decrease in peak shear load. A comprehensive RSSB (Relative Stiffness between Structure and Test Block) that considers both structural and test block stiffness was proposed. The deformation pattern of the structure was controlled by the RSSB. The higher the RSSB, the wider the plastic hinge extension range for the same shear displacement, the smaller the bending angle at the shear plane position, and the smaller the maximum curvature of the structure. The contact force of the C-shaped tube generally exhibited a "single peak" distribution. As the shear displacement increased, the peak position of the contact force moved away from the shear plane, and the maximum contact force increased rapidly and remained relatively stable. At the end of the shearing process, the contact force of the C-shaped tube exhibited a "double peak" distribution.
为防止支护工程中锚索在剪切荷载作用下过早断裂,提出了一种锚索与C形管组合结构(ACC)。该结构的抗剪增强机理及各种影响因素的作用机制尚未完全揭示。利用ABAQUS软件初步建立了ACC的精细化非线性有限元模型,考虑了钢绞线的实际结构以及各部件之间的接触和破坏等相互作用。设置了不同的锚索预紧力和块体强度,研究它们对ACC剪切力学响应的影响。结果成功表明峰值剪切荷载与预紧力之间具有高度相关性。结果表明,预紧力的增加会降低ACC的峰值剪切荷载和破坏位移。此外,该结构表现出较高的抗弯刚度,块体强度更早发挥作用,块体局部破坏更快。在高预紧力作用下,由于轴向力分量的影响,系统在剪切初期表现出较高的剪切刚度。在低预紧力作用下,对于相同的剪切位移,由于剪切面位置的拉伸变形较小,ACC表现出较大的破坏位移。在低预紧力作用下,结构在剪切中后期的弯曲角度增加更快,同时破坏位移也更大。这两个因素导致破坏时剪切面位置的弯曲角度更大。结果揭示了峰值剪切荷载随试验块体强度增加先增大后减小的特性及其潜在机制。随着块体强度的增加,结构在剪切面位置的弯曲角度增加更快,从而导致更高的剪切刚度。在高块体强度下,较小的破坏位移和较大的剪切刚度共同作用导致峰值剪切荷载先增大后减小。提出了一种综合考虑结构和试验块体刚度的相对刚度比(RSSB)。结构的变形模式由RSSB控制。RSSB越高,对于相同的剪切位移,塑性铰扩展范围越宽,剪切面位置的弯曲角度越小,结构的最大曲率越小。C形管的接触力一般呈“单峰”分布。随着剪切位移的增加,接触力的峰值位置远离剪切面,最大接触力迅速增加并保持相对稳定。在剪切过程结束时,C形管的接触力呈“双峰”分布。
