Physical modelling of lime stabilisation in soft soils around deep excavations

DFI Journal - The Journal of the Deep Foundations Institute Pub Date : 2017-04-06 DOI:10.1080/19375247.2018.1436254

J. Panchal, A. McNamara, S. E. Stallebrass

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引用次数: 1

Abstract

The availability of space above ground decreases as cities expand, causing a demand for very deep underground structures so developments must mitigate the risk of damaging adjacent buildings. This is especially critical in soft clays where ground movements are considerable and can extend far beyond the excavation site. This paper investigates the efficacy of a shallow lime stabilised clay layer on reducing heave and the settlement profile behind an embedded retaining wall. Centrifuge modelling at 160 g was used to observe surface and subsurface soil movements of a 12 m deep excavation (H) supported by a retaining wall of 8.8 m embedment at prototype scale. Since this research focussed on measures used to minimise heave the model comprised a high stiffness, fully supported ‘rigid wall’ to eliminate ground movements attributed to wall deformation. A direct comparison between a reference test, with no improvements and a test comprising H/2 thick 5% lime stabilised layer indicated that the lime treatment increased the excavation stability by a factor of three.

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深基坑周围软土石灰稳定的物理模拟

随着城市的扩张，地面上的可用空间减少，导致对非常深的地下结构的需求，因此开发必须降低破坏相邻建筑的风险。这在软粘土中尤其重要，因为那里的地面运动相当大，并且可以远远超出挖掘地点。本文研究了浅石灰稳定粘土层对嵌入式挡土墙后的减胀效果和沉降剖面。采用160 g离心模拟，以原型规模观察8.8 m埋置挡墙支撑的12 m深基坑(H)的地表和地下土壤运动。由于这项研究的重点是用于最小化隆起的措施，该模型包括高刚度，完全支持的“刚性墙”，以消除由于墙壁变形引起的地面运动。没有任何改进的参考试验与含有H/2厚5%石灰稳定层的试验之间的直接比较表明，石灰处理将开挖稳定性提高了三倍。

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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DFI Journal - The Journal of the Deep Foundations Institute

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