Comparative Study on the Reinforced Sand-Bed and the Stone Column in Improving the Clay Deposit Supporting Isolated Footing

IF 1.5 4区 工程技术 Q3 CONSTRUCTION & BUILDING TECHNOLOGY Advances in Civil Engineering Pub Date : 2024-01-31 DOI:10.1155/2024/8836116
Premalatha Krishnamurthy, Priyadharshini Maniam Rajan
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Abstract

The working mechanism of a geotechnical structure can be understood from the deformations and the vertical stresses in the soil media. This article attempts to study the deformation, vertical stress development, and distribution of improved clay deposits carrying a single isolated footing. Through PLAXIS 3D software, numerical analyses were conducted for the ground improvement methods, such as the geogrid reinforced sand-bed (GRSB) and ordinary and geogrid encased stone column installation (OSC and GESC). In GRSB, the results show that the stresses were maximum at the sand–clay interface at a depth of 0.67 B (B—footing width). It is proposed to place an additional layer of geogrid at the interface, and it must be within the critical depth, i.e., the width of the footing. Furthermore, for the current study, the stiffness of the geogrid in the sand layer greater than 500 kN/m was insignificant in soil improvement, whereas the optimum axial stiffness of the stone column encasement was 1,000 kN/m based on the stress concentration factor. The stone column installation improved the clay layer even below the depth of 0.67 B, improving the capacity of clay to carry higher vertical stresses on par with the stone columns. The GRSB carried higher vertical stresses than the unimproved ground. However, the OSC and GESC could carry vertical stresses higher than the GRSB. This knowledge can allow the practitioners to decide the depth of placement of the reinforcement and also to choose an alternate if one method is not feasible for the site.
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加固砂基和石柱在改善粘土沉积物支撑孤立基底中的比较研究
岩土结构的工作机制可以从土壤介质的变形和垂直应力中了解。本文试图研究承载单个孤立基脚的改良粘土沉积的变形、垂直应力发展和分布。通过 PLAXIS 3D 软件,对土工格栅加固砂床(GRSB)和普通及土工格栅包裹石柱安装(OSC 和 GESC)等地基改良方法进行了数值分析。结果表明,在土工格栅加固砂床中,砂粘土界面处的应力最大,深度为 0.67 B(B 基底宽度)。建议在界面处多铺一层土工格栅,且必须在临界深度(即基脚宽度)范围内。此外,在本次研究中,砂层中土工格栅的刚度大于 500 kN/m 对土壤改良作用不大,而根据应力集中系数,石柱围护结构的最佳轴向刚度为 1 000 kN/m。石柱的安装甚至改善了 0.67 B 深度以下的粘土层,提高了粘土承受更大垂直应力的能力,与石柱相当。与未经改良的地层相比,地下连续墙承受了更高的垂直应力。然而,奥氏体层和普通砂浆沉积层承受的垂直应力高于普通砂浆砌块。这些知识可以帮助施工人员决定加固的深度,如果一种方法在施工现场不可行,还可以选择另一种方法。
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来源期刊
Advances in Civil Engineering
Advances in Civil Engineering Engineering-Civil and Structural Engineering
CiteScore
4.00
自引率
5.60%
发文量
612
审稿时长
15 weeks
期刊介绍: Advances in Civil Engineering publishes papers in all areas of civil engineering. The journal welcomes submissions across a range of disciplines, and publishes both theoretical and practical studies. Contributions from academia and from industry are equally encouraged. Subject areas include (but are by no means limited to): -Structural mechanics and engineering- Structural design and construction management- Structural analysis and computational mechanics- Construction technology and implementation- Construction materials design and engineering- Highway and transport engineering- Bridge and tunnel engineering- Municipal and urban engineering- Coastal, harbour and offshore engineering-- Geotechnical and earthquake engineering Engineering for water, waste, energy, and environmental applications- Hydraulic engineering and fluid mechanics- Surveying, monitoring, and control systems in construction- Health and safety in a civil engineering setting. Advances in Civil Engineering also publishes focused review articles that examine the state of the art, identify emerging trends, and suggest future directions for developing fields.
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