Shear strength characteristics of weathered jointed Kenny Hill interbedded formation for cylindrical specimen under direct shear test

Q3 Chemical Engineering

International Journal of Applied Mechanics and Engineering Pub Date : 2023-06-28 DOI:10.59441/ijame/168938

H. Abbas, Z. Mohamed, Muntadher J. Taher, S. A. Kudus, Manaf Raid Salman, Hasanain M. Ghaltan

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引用次数: 0

Abstract

The sliding failures commonly occur in interbedded formations along the weakness plane of the bedding plane a sedimentary rock or the joint interface. Therefore, studying the shear strength characteristics at the bedding plane or interface is crucial for evaluating the expected failure plane. In this study, the shear strength characteristics of planar jointed Kenny Hill shale, sandstone, and shale-sandstone specimens were investigated using the direct shear box method. The results reveal that the friction angle values for the planar sandstone, shale-sandstone, and shale are 31.28°, 21.1°, and 19.34°, respectively. These findings, combined with the shear stress-strain behavior, suggest that the interface (shale-sandstone) is primarily influenced by the shale characteristics rather than the sandstone characteristics. Hence, it is important to consider failure along the interface when analyzing critical conditions, particularly in slope failure scenarios.

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直剪试验下肯尼山风化节理夹层柱状试样抗剪强度特征

滑动破坏一般发生在顺层面软弱面、沉积岩或节理界面的互层地层中。因此，研究层理面或界面处的抗剪强度特征对于评估预期破坏面至关重要。本研究采用直接剪切箱法对肯尼山平面节理页岩、砂岩及页岩-砂岩试样的抗剪强度特征进行了研究。结果表明:平面砂岩、页岩-砂岩和页岩的摩擦角值分别为31.28°、21.1°和19.34°;这些发现，结合剪切应力-应变行为，表明界面(页岩-砂岩)主要受页岩特征而不是砂岩特征的影响。因此，在分析临界条件时，特别是在边坡破坏情况下，考虑沿界面破坏是很重要的。

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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来源期刊

International Journal of Applied Mechanics and Engineering Engineering-Civil and Structural Engineering

CiteScore

1.50

自引率

0.00%

发文量

审稿时长

35 weeks

期刊介绍： INTERNATIONAL JOURNAL OF APPLIED MECHANICS AND ENGINEERING is an archival journal which aims to publish high quality original papers. These should encompass the best fundamental and applied science with an emphasis on their application to the highest engineering practice. The scope includes all aspects of science and engineering which have relevance to: biomechanics, elasticity, plasticity, vibrations, mechanics of structures, mechatronics, plates & shells, magnetohydrodynamics, rheology, thermodynamics, tribology, fluid dynamics.