控制颗粒材料体积特性的微观尺度措施与加载有关:应力-力-织物关系的实验测试

Carmen L. Lee, Ephraim Bililign, Emilien Azéma, Karen E. Daniels
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引用次数: 0

摘要

颗粒材料的大体积行为与其中观尺度和颗粒尺度特征息息相关:强度特性源于颗粒尺度上由颗粒连通性(结构)、力传递和摩擦动员引起的各种各向异性结构的积累。从根本上说,这些各向异性结构共同决定了宏观尺度上的体积摩擦系数和应力张量等特征,并可通过源于微观尺度的应力-力-织构(SFF)关系加以解释。尽管 SFF 关系已通过离散数值模拟得到了广泛验证,但由于同时测量法向力和摩擦接触力的挑战,实验室实现 SFF 关系仍然遥遥无期。在本研究中,我们分析了在四种不同加载条件下对光弹性颗粒系统进行的实验:单轴压缩、各向同性压缩、纯剪切和环形剪切。在这些实验中,我们记录了颗粒的位置、接触、法向力和摩擦力矢量,以测量颗粒尺度对应变的响应。我们跟踪微观尺度的测量值,如堆积分数、平均配位数和平均法向力,以及接触和力的各向异性分布。我们使用 SFF 关系将粒子尺度的各向异性与大体相匹配,该关系建立在两个关键原则之上,即描述应力张量的 "应力规则 "和描述大体摩擦系数的 "总和规则";我们发现,"总和规则 "和 "应力规则 "准确地描述了大体测量结果。此外,我们还测试了 "结构和力在粒状材料中的传递载荷是相等的 "这一假设,结果表明在大应变值下这一假设是充分的,并可应用于无法获得力信息的岩石力学、软胶体或纤维组织等领域。
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Loading-dependent microscale measures control bulk properties in granular material: an experimental test of the Stress-Force-Fabric relation
The bulk behaviour of granular materials is tied to its mesoscale and particle-scale features: strength properties arise from the buildup of various anisotropic structures at the particle-scale induced by grain connectivity (fabric), force transmission, and frictional mobilization. More fundamentally, these anisotropic structures work collectively to define features like the bulk friction coefficient and the stress tensor at the macroscale and can be explained by the Stress-Force-Fabric (SFF) relationship stemming from the microscale. Although the SFF relation has been extensively verified by discrete numerical simulations, a laboratory realization has remained elusive due to the challenge of measuring both normal and frictional contact forces. In this study, we analyze experiments performed on a photoelastic granular system under four different loading conditions: uniaxial compression, isotropic compression, pure shear, and annular shear. During these experiments, we record particle locations, contacts, and normal and frictional forces vectors to measure the particle-scale response to progressing strain. We track microscale measures like the packing fraction, average coordination number and average normal force along with anisotropic distributions of contacts and forces. We match the particle-scale anisotropy to the bulk using the SFF relation, which is founded on two key principles, a Stress Rule to describe the stress tensor and a Sum Rule to describe the bulk friction coefficient; we find that the Sum and Stress Rules accurately describe bulk measurements. Additionally, we test the assumption that fabric and forces transmit load equally through our granular packings and show that this assumption is sufficient at large strain values, and can be applied to areas like rock mechanics, soft colloids, or cellular tissue where force information is inaccessible.
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