试验研究了纤维和天然火山灰对水泥处理砂破坏特性的影响

IF 1.3 Q3 ENGINEERING, GEOLOGICAL

Proceedings of the Institution of Civil Engineers-Ground Improvement Pub Date : 2023-01-26 DOI:10.1680/jgrim.22.00024

Abouzar Esfandyaripour, S. H. Lajevardi, H. Molaabasi

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引用次数: 0

摘要

掺入沸石对水泥处理砂进行强化处理，除了环境效益和节省成本和时间外，还可以改善火山灰反应，从而改善随着时间的推移的失效机制。此外，用纤维增强这些样品可以进一步减轻脆性行为，同时增加基础土的强度特性。本研究的重点是研究有纤维和无纤维的沸石水泥处理砂在排水行为下的应力-应变(q -ε)关系和微观特征的变化。考虑到相对密度为50%，养护时间为56 d，水泥掺量为4%，沸石掺量为15%、30%、45%和60%(替代水泥)，纤维掺量为0.5%。进行了围压分别为50、100和200 kPa的固结排水(CD)三轴试验和扫描电镜(SEM)分析。从q -ε曲线中获得的关键岩土参数，如最大强度(qmax)，破坏应变(εf)，脆性指数(BI)，割线模量(E50)，黏聚力(C)和内摩擦角(φ)进行了评估。结果表明，纤维与沸石同时使用，显著改善了水泥处理砂的高脆性指数和低破坏应变。事实上，掺入沸石的混合物增强了峰后行为，而水泥处理砂的峰后应力急剧下降。此外，SEM显微观察分析证实，在最佳沸石含量下，孔隙基本被填满，纤维增强试样具有更强的抗拉性能。此外，沸石水泥处理过的样品中的纤维比水泥处理过的样品暴露在更小的张力下。沸石完全覆盖纤维，帮助它们提供更大的阻力，因此，防止完全失效，改善应变硬化特性。

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An experimental study to examine the effect of fiber and natural pozzolan on the failure characteristics of a cement-treated sand

Incorporating zeolite for the enhanced treatment of the cement-treated sands, apart from environmental benefits and saving cost and time, results in the improvement of pozzolanic reactions and hence, the failure mechanisms over time. Besides, reinforcing these samples with fibers can be a further contribution to mitigate the brittle behavior along with increasing the strength characteristics of the base soil. The main focus of the current study is to investigate the changes of the stress-strain (q–ε) relationships and the micro-character of the zeolite-cement treated sands with and without fibers subjected to the drained behavior. In this regard, the samples were prepared with cement content of 4%, zeolite contents of 15, 30, 45 and 60% (cement replacement) and fiber content of 0.5%, considering the relative density of 50% and 56 days of curing time. The consolidated drained (CD) triaxial tests with confining pressures of 50, 100 and 200 kPa and SEM analysis were performed. Crucial geotechnical parameters, obtained from the q–ε curves, like maximum strength (qmax), failure strain (εf), brittle index (BI), secant modulus (E50), cohesion (C) and internal friction angle (ϕ) were evaluated. The results indicated that concurrent use of fiber and zeolite substantially modified the high brittle index and low failure strain of the cement-treated sands. In fact, zeolite incorporation in the mixture enhanced the post-peak behavior while post-peak stresses in cement-treated sands experienced a dramatic drop. Besides, observational analysis from SEM micrographs confirmed that pores were roughly filled up in the optimum zeolite content and more tension resistance were witnessed in the fiber-reinforced samples. Furthermore, fibers in the zeolite-cement treated samples exposed to less tension rather than cement-treated ones. Zeolite fully covered the fibers and helped them to provide more resistance, hence, prevented the complete failure and improved the strain-hardening characteristics.

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来源期刊

Proceedings of the Institution of Civil Engineers-Ground Improvement ENGINEERING, GEOLOGICAL-

CiteScore

3.10

自引率

8.30%

发文量

期刊介绍： Ground Improvement provides a fast-track vehicle for the dissemination of news in technological developments, feasibility studies and innovative engineering applications for all aspects of ground improvement, ground reinforcement and grouting. The journal publishes high-quality, practical papers relevant to engineers, specialist contractors and academics involved in the development, design, construction, monitoring and quality control aspects of ground improvement. It covers a wide range of civil and environmental engineering applications, including analytical advances, performance evaluations, pilot and model studies, instrumented case-histories and innovative applications of existing technology.