砂-橡胶混合物中粒子尺度的相互作用和能量耗散机制

IF 1.5 4区工程技术 Q3 ENGINEERING, GEOLOGICAL

Geotechnique Letters Pub Date : 2019-04-30 DOI:10.1680/JGELE.18.00221

J. Fonseca, A. Riaz, J. Bernal-Sanchez, D. Barreto, J. McDougall, M. Miranda-Manzanares, A. Marinelli, V. Dimitriadi

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引用次数: 14

摘要

砂-橡胶混合料(SRm)的性能受橡胶含量(RC)的影响，而砂中的耗散是由颗粒间滑动引起的。沙土的耗散与沙土相同，甚至更显著。然而，SRm的耗散机制尚不清楚。本研究在标准测压仪上对质量比RC分别为0、15、30、45和100%的砂样进行了一维压缩试验。此外，在放置在x射线扫描仪内的微型测径仪上测试了RC为30%的SRm，并在加载和卸载的三个阶段获得了材料内部结构的三维图像。利用图像分析来推断颗粒尺度的测量结果，并提供实验证据来帮助解释SRm的能量耗散机制。在加载初始阶段，这些混合材料中的能量耗散主要是由颗粒间滑动主导的，但一旦橡胶颗粒填充了砂之间的空隙，变形和耗散机制就由橡胶颗粒的变形主导。

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Particle–scale interactions and energy dissipation mechanisms in sand–rubber mixtures

Sand−rubber mixture (SRm) behaviour is affected by rubber content (RC) while dissipation in sands is caused by inter-particle sliding. Dissipation in SRm is as, or more significant than in sands. However, the mechanisms of dissipation in SRm are not well understood. In this study, one-dimensional compression tests on sand samples with RC of 0, 15, 30, 45 and 100% by mass were performed on a standard oedometer. In addition, a SRm with RC of 30% was tested on a mini-oedometer placed inside an X-ray scanner and three-dimensional images of the internal structure of the material were acquired at three stages during loading and unloading. Image analysis was used to infer particle-scale measurements and provide experimental evidence to help explaining the energy dissipation mechanisms for SRm. It is postulated here that energy dissipation in these mixtures is dominated by inter-particle sliding at initial stages of loading, but once rubber particles fill the void spaces between the sand, deformation and dissipation mechanisms are dominated by the deformation of the rubber particles.

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来源期刊

Geotechnique Letters ENGINEERING, GEOLOGICAL-

CiteScore

4.20

自引率

0.00%

发文量

期刊介绍： Géotechnique Letters provides a vehicle for the rapid international dissemination of the latest and most innovative geotechnical research and practice. As an online journal, it is aimed at publishing short papers, intending to foster the quick exchange of the latest advances and most current ideas without the delays imposed by printed journals, whilst still maintaining rigorous peer reviewing standards.