层状砂土上内埋和围边e型基础承载力研究

S. Nazeer, R. Dutta
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The various parameters varied were the friction angle of the upper (30° to 34°) and lower (42° to 46°) layer of sand, the skirt depth (0B, 0.25B, 0.5B and 1B), the embedment depth (0B, 0.25B, 0.5B and 1B) and the thickness (0.5B, 2B and 4B) of the upper sand layer, where B is the width of the square footing. \nFindings: The ultimate bearing capacity was higher for the skirted E-shaped footing followed by embedded E-shaped footing and unskirted E-shaped footing in this order for all combinations of variables studied. The improvement in the ultimate bearing capacity for the skirted E-shaped footing in comparison to the embedded E-shaped footing was in the range of 0.31 % to 61.13 %, 30.5 % to 146.31 % and 73.26 % to 282.38% corresponding to H/B ratios of 0.5, 2.0 and 4.0 respectively. 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引用次数: 2

摘要

目的:采用有限元法研究两层砂基础上e型基础的极限承载力。采用ABACUS软件进行分析。设计/方法/途径:采用有限元分析方法对层状砂土上嵌入和围接的e型基础在竖向荷载作用下的极限承载力进行了数值研究。层状砂的上层为厚度为H的松散砂,下层为无限深度的致密砂。各参数分别为上砂层(30°~ 34°)和下砂层(42°~ 46°)的摩擦角、裙边深度(0B、0.25B、0.5B、1B)、埋置深度(0B、0.25B、0.5B、1B)和上砂层厚度(0.5B、2B、4B),其中B为方基宽度。研究发现:在所有研究变量的组合中,有裙边的e型基础的极限承载力较高,其次是嵌入式e型基础和无裙边的e型基础。当H/B比分别为0.5、2.0和4.0时,裙边型e型基础的极限承载力比预埋型e型基础提高了0.31% ~ 61.13%,30.5% ~ 146.31%和73.26% ~ 282.38%。当H/B和d /B比分别为4.0和1.0时,φ1 =30°和φ2 =46°的增幅最大(283.38%);当H/B比为0.5和d /B比为0.5时,φ1 =34°和φ2 =46°的增幅最小(0.31%)。裙边型e型基础的横向扩展大于内嵌型e型基础。裙边基础承载力等于裙边基础承载力、裙边周围形成的表皮阻力和裙边尖端阻力之和,决定系数为0.8739。无裙边e型基础和预埋e型基础下部位移最大,裙边e型基础顶部位移最大。此外,生成的位移等高线支持了关于层状砂的极限承载力的多边嵌入式和围脚基础的观察结果。研究局限/启示:本文中提出的结果是基于对尺寸为1.5 m x 1.5 m的方形基础制成的E形基础进行的数值研究。但是,建议通过类似尺寸的E型基础的试验研究来进一步验证本文的结果。实际意义:所提出的数值研究可以为建筑师设计类似类型的需要类似形状基础的上层结构提供优势。独创性/价值:目前还没有对层状砂土(松散大于致密)上嵌套和围边的E形基础进行数值研究。因此,本文试图估算相同基础的承载力。
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Bearing capacity of embedded and skirted E-shaped footing on layered sand
Purpose: The purpose of this study is to investigate the ultimate bearing capacity of the embedded and skirted E-shaped footing resting on two layered sand using finite element method. The analysis was carried out by using ABACUS software. Design/methodology/approach: The numerical study of the ultimate bearing capacity of the embedded and skirted E-shaped footing resting on layered sand and subjected to vertical load was carried out using finite element analysis. The layered sand was having an upper layer of loose sand of thickness H and lower layer was considered as dense sand of infinite depth. The various parameters varied were the friction angle of the upper (30° to 34°) and lower (42° to 46°) layer of sand, the skirt depth (0B, 0.25B, 0.5B and 1B), the embedment depth (0B, 0.25B, 0.5B and 1B) and the thickness (0.5B, 2B and 4B) of the upper sand layer, where B is the width of the square footing. Findings: The ultimate bearing capacity was higher for the skirted E-shaped footing followed by embedded E-shaped footing and unskirted E-shaped footing in this order for all combinations of variables studied. The improvement in the ultimate bearing capacity for the skirted E-shaped footing in comparison to the embedded E-shaped footing was in the range of 0.31 % to 61.13 %, 30.5 % to 146.31 % and 73.26 % to 282.38% corresponding to H/B ratios of 0.5, 2.0 and 4.0 respectively. The highest increase (283.38 %) was observed at φ1 =30° and φ2 =46° corresponding to H/B and Ds/B ratio of 4.0 and 1.0 respectively while the increase was lowest (0.31 %) at φ1 =34° and φ2 =46° at H/B ratio of 0.5 and Ds/B ratio of 0.5. For the skirted E-shaped footing, the lateral spread was more as in comparison to the embedded E-shaped footing. The bearing capacity of the skirted footing was equal the sum of bearing capacity of the surface footing, the skin resistance developed around the skirt surfaces and tip resistance of the skirt with coefficient of determination as 0.8739. The highest displacement was found below the unskirted and embedded E-shaped footing, and at the skirt tip in the case of the skirted E-shaped footing. Further, the displacement contours generated supports the observations of the multi-edge embedded and skirted footings regarding the ultimate bearing capacity on layered sands. Research limitations/implications: The results presented in this paper were based on the numerical study conducted on E shaped footing made from a square footing of size 1.5 m x 1.5 m. However, further validation of the results presented in this paper, is recommended using experimental study conducted on similar size E shaped footing. Practical implications: The proposed numerical study can be an advantage for the architects designing similar types of super structures requiring similar shaped footings. Originality/value: No numerical study on embedded and skirted E shaped footing resting on layered sand (loose over dense) were conducted so far. Hence, an attempt was made in this article to estimate the bearing capacity of the same footings.
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来源期刊
Journal of Achievements in Materials and Manufacturing Engineering
Journal of Achievements in Materials and Manufacturing Engineering Engineering-Industrial and Manufacturing Engineering
CiteScore
2.10
自引率
0.00%
发文量
15
期刊介绍: The Journal of Achievements in Materials and Manufacturing Engineering has been published by the Association for Computational Materials Science and Surface Engineering in collaboration with the World Academy of Materials and Manufacturing Engineering WAMME and the Section Metallic Materials of the Committee of Materials Science of the Polish Academy of Sciences as a monthly. It has 12 points which was received during the evaluation by the Ministry of Science and Higher Education journals and ICV 2017:100 on the ICI Journals Master list announced by the Index Copernicus. It is a continuation of "Proceedings on Achievements in Mechanical and Materials Engineering" published in 1992-2005. Scope: Materials[...] Properties[...] Methodology of Research[...] Analysis and Modelling[...] Manufacturing and Processingv Biomedical and Dental Engineering and Materials[...] Cleaner Production[...] Industrial Mangement and Organisation [...] Education and Research Trends[...]
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