单向水平循环荷载作用下高刚度大直径钢管桩的物理建模

IF 2.2 4区工程技术 Q3 ENGINEERING, GEOLOGICAL Environmental geotechnics Pub Date : 2023-06-11 DOI:10.3390/geotechnics3020028

S. Shafi, J. Takemura, V. Kunasegaram

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引用次数: 0

摘要

进行了2次离心模型试验，每次试验安装3根大直径钢管桩，条件相似，即直径(Φ) = 2 m;厚度(t) = 25mm;在原型尺度下，岩石嵌套深度(dr)分别为2 m、3 m和4 m，加载高度(HL)为6.5 m。使用相同的模型桩和地基进行了另外两次1 g模型试验。结果表明:在1 g和50 g模型中，桩侧阻力随嵌岩深度直径比(dr/Φ)的增加而增加;然而，随着施加位移的增加，两种重力加速度水平之间的差异在非线性行为中变得明显。具体来说，1g模型在再加载时比50g模型显示出更大的残余位移和更小的刚度，特别是在循环加载下。观察到两种类型的极限破坏模式，即岩石破坏和桩结构破坏，岩石表面以上局部屈曲。模型所采用的试验条件中，只有在50g模型中dr/Φ = 2的桩基出现后一种破坏模式，而在1g模型中没有出现后一种破坏模式。

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Physical Modelling of High Stiffness Large Diameter Steel Tubular Pile Subjected to One-Way Horizontal Cyclic Loading

Two centrifuge model tests were conducted, each with three large diameter steel tubular piles installed under similar conditions, i.e., diameter (Φ) = 2 m; thickness (t) = 25 mm; loading height from the rock surface (HL) = 6.5 m, but different rock socketing depths (dr), i.e., 2 m, 3 m, and 4 m, respectively, in prototype scale. Two additional 1 g model tests were conducted using the same model pile and ground. The results indicate that the pile lateral resistance increased with an increase in the rock socketing depth to diameter ratio (dr/Φ) in both 1 g and 50 g models. However, the difference between the two gravitational acceleration levels became visible in the non-linear behaviour as the imposed displacement increased. Specifically, the 1 g models showed larger residual displacement and less stiffness in reloading than the 50 g models, particularly under cyclic loading. Two types of ultimate failure modes were observed, i.e., rock failure and pile structural failure with local buckling just above the rock surface. The latter failure mode was only attained in the pile with a dr/Φ ratio of 2 in a 50 g models among the test conditions adopted in the models, but not in the 1 g model.

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来源期刊

Environmental geotechnics Environmental Science-Water Science and Technology

CiteScore

6.20

自引率

18.20%

发文量

期刊介绍： In 21st century living, engineers and researchers need to deal with growing problems related to climate change, oil and water storage, handling, storage and disposal of toxic and hazardous wastes, remediation of contaminated sites, sustainable development and energy derived from the ground. Environmental Geotechnics aims to disseminate knowledge and provides a fresh perspective regarding the basic concepts, theory, techniques and field applicability of innovative testing and analysis methodologies and engineering practices in geoenvironmental engineering. The journal''s Editor in Chief is a Member of the Committee on Publication Ethics. All relevant papers are carefully considered, vetted by a distinguished team of international experts and rapidly published. Full research papers, short communications and comprehensive review articles are published under the following broad subject categories: geochemistry and geohydrology, soil and rock physics, biological processes in soil, soil-atmosphere interaction, electrical, electromagnetic and thermal characteristics of porous media, waste management, utilization of wastes, multiphase science, landslide wasting, soil and water conservation, sensor development and applications, the impact of climatic changes on geoenvironmental, geothermal/ground-source energy, carbon sequestration, oil and gas extraction techniques, uncertainty, reliability and risk, monitoring and forensic geotechnics.