Study on influencing factors of controllable mechanical behavior of rock-like porous materials.

IF 2.6 4区 综合性期刊 Q2 MULTIDISCIPLINARY SCIENCES Science Progress Pub Date : 2024-10-01 DOI:10.1177/00368504241291395
Xiaojing Zhu, Qingxin Qi, Yonghui Xiao, Haitao Li
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Abstract

Due to the discrete and non-homogeneous of similar materials and the inability to realize large-size and original scale modeling, it is difficult to restore the structure and stress state of underground coal and rock mass in similar simulation tests. To solve this problem, a lightweight and suitable for large-scale modeling similar material, rock-like porous material has been developed. The quasi-static uniaxial compression experiment was carried out by using the large tonnage multi-module electronic control test system. And the influencing factors of controllable mechanical behavior of rock-like porous materials were studied. The results showed that, under uniaxial compression conditions, the material stress-strain curve exhibits three phases: elastic stage, failure stage, and platform stage. The uniaxial compressive strength, elasticity modulus, stress drop, and softening modulus of rock-like porous materials basically increase with the increase of density. The stress after peak strength changes from a slow decrease to a "stepped" or even "cliff like" downward trend. Polypropylene fibers have the effect of enhancing the uniaxial compressive strength, elasticity modulus, stress drop, softening modulus, shear deformation, and residual strength stability of rock-like porous materials. The rock-like porous material has a critical loading velocity, and it increases with density. At the critical loading velocity, the material shows obvious shear failure, and the shear inclination angle is the largest, and so is the uniaxial compressive strength. Through the experimental research, the influence laws of density, polypropylene fiber, and loading velocity on the failure mode, mechanical parameters, and mechanical behavior of the material are clarified, and the quantitative relationship between density and each mechanical parameter is obtained. The research is helpful to realize the accurate control of mechanical behavior of rock-like porous materials and further inverts the deformation and failure mechanism of underground coal and rock structures through indoor similar simulation tests.

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类岩石多孔材料可控力学行为影响因素研究
由于类似材料的离散性和非均质性,以及无法实现大尺度、原尺度建模,在类似模拟试验中很难还原地下煤岩体的结构和应力状态。为解决这一问题,一种轻便且适合大规模建模的类似材料--类岩石多孔材料应运而生。利用大吨位多模块电子控制试验系统进行了准静态单轴压缩试验。并研究了类岩石多孔材料可控力学行为的影响因素。结果表明,在单轴压缩条件下,材料的应力-应变曲线呈现三个阶段:弹性阶段、破坏阶段和平台阶段。类岩石多孔材料的单轴压缩强度、弹性模量、应力降和软化模量基本上随密度的增加而增加。峰值强度后的应力由缓慢下降变为 "阶梯式 "甚至 "悬崖式 "下降趋势。聚丙烯纤维具有提高类岩石多孔材料的单轴抗压强度、弹性模量、应力下降、软化模量、剪切变形和残余强度稳定性的作用。类岩石多孔材料有一个临界加载速度,它随密度的增加而增加。在临界加载速度下,材料出现明显的剪切破坏,剪切倾角最大,单轴抗压强度也最大。通过实验研究,阐明了密度、聚丙烯纤维和加载速度对材料失效模式、力学参数和力学行为的影响规律,并得出了密度与各力学参数之间的定量关系。该研究有助于实现对类岩石多孔材料力学行为的精确控制,并通过室内类似模拟试验进一步反演地下煤岩结构的变形与破坏机理。
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来源期刊
Science Progress
Science Progress Multidisciplinary-Multidisciplinary
CiteScore
3.80
自引率
0.00%
发文量
119
期刊介绍: Science Progress has for over 100 years been a highly regarded review publication in science, technology and medicine. Its objective is to excite the readers'' interest in areas with which they may not be fully familiar but which could facilitate their interest, or even activity, in a cognate field.
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