Erodibility of Granular Materials Models

Journal of Advanced Civil and Environmental Engineering Pub Date : 2018-10-31 DOI:10.30659/JACEE.1.2.49-56

A. Sentani, D. Marot, F. Bendahmane

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Abstract

Abstract: Two means physical processes are involved in failure of a dams structure: either a mechanical failure by sliding, or a hydraulic failure by erosion. The causes of failures are internal erosion (23 cases between 44), or external erosion (20 cases of overtopping) and 1 case of sliding. In consequence, internal erosion is the most frequent cause for all the water retaining structures. A series of test are needed to develop models that can describe the internal erosion. This research uses two kinds of tests. They are The Consodilated Drained (CD) Triaxial test and The Erodibility test with triaxial erodimetre. These two tests uses mixture between Kaolinite Proclay (25%) and Fontainebleau Sand (75%) with 9% of water content. The result shows that confinement pressure increase, time for obtained maximal deviatoric also increase. When deviatoric stress is increase, percentage of deformation is also increase. And also the volume variation of specimen is decrease in function of deformation. For the second test, the result shows after the loss of fine particles in the soil, the original dilative stress-strain behavior changes to be contractive and the peak stress is decreases. Comparing the results of Chang & Zhang in 2011, the curves rank in a coherent way for the stress-strain curve although it used different speciments.

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颗粒材料可蚀性模型

摘要:大坝结构破坏涉及两种物理过程:由滑动引起的机械破坏或由侵蚀引起的水力破坏。破坏的原因是内部侵蚀(23例44)，或外部侵蚀(20例溢顶)和1例滑动。因此，内部侵蚀是所有挡水结构最常见的原因。为了建立能够描述内部侵蚀的模型，需要进行一系列的试验。本研究使用了两种测试。它们是固结排水(CD)三轴试验和用三轴侵蚀计进行的可蚀性试验。这两个试验使用高岭石Proclay(25%)和枫丹白露砂(75%)的混合物，含水量为9%。结果表明，约束压力增大，得到最大偏差的时间也增大。当偏应力增大时，变形率也随之增大。试件体积随变形量的变化呈减小趋势。第二次试验结果表明，细颗粒失失后，土中原有的扩张应力-应变行为由收缩变为收缩，峰值应力减小。对比Chang & Zhang(2011)的结果，尽管采用了不同的试样，但应力-应变曲线的曲线排列一致。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Journal of Advanced Civil and Environmental Engineering

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