A study of the shear strength properties of expansive soil treated with fly ash admixture

Q2 Materials Science

Engineering Solid Mechanics Pub Date : 2023-01-01 DOI:10.5267/j.esm.2023.7.003

J. K. Naik, D. Bagal, P. K. Muduli

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Abstract

The behavior of clay minerals in expansive soils causes them to exhibit shrink-swell characteristics, making them unsuitable for engineering purposes in their natural state. To address this problem, researchers conducted direct shear experiments using fly ash as an admixture and black cotton soil as an expanding soil to explore the strength parameter. The experiments were conducted with varying amounts of fly ash ranging from 2% to 20%. Two arrangements of test series were made, and in the principal series, tests were made utilizing five unique densities and comparing dampness contents. The outcomes showed that the point of inside grating and union expanded directly up to the ideal dampness content and most significant dry thickness before diminishing. The subsequent series showed that the end of inward rubbing grew straightly with the expansion of fly debris admixture, yet attachment reduced after 10% admixture. The decrease in shear strength was because of the diminished passion, as the fly debris' cohesionless attributes took over as the admixture rate increased above 10%. Based on these findings, adding fly ash in small quantities to black cotton soil is recommended to avoid weakening it.

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粉煤灰掺合料处理膨胀土抗剪强度特性研究

膨胀土中粘土矿物的性质使其表现出收缩膨胀特性，使其在自然状态下不适合工程用途。针对这一问题，研究人员以粉煤灰为外加剂，黑棉土为膨胀土进行直剪试验，探索其强度参数。试验采用了2%至20%不等的粉煤灰。试验系列有两种安排，在主系列中，利用五种独特的密度进行试验，并比较湿度含量。结果表明，内格栅和结合点在减小之前，直接膨胀到理想的湿含量和最显著的干厚度。随后的系列分析表明，随着掺量的增加，向内摩擦的末端呈直线增长，掺量达到10%后，附着量减小。抗剪强度的下降是由于掺量超过10%后，蝇屑的无黏结性取代了抗剪强度的降低。在此基础上，建议在黑棉土中添加少量粉煤灰，以避免黑棉土变弱。

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来源期刊

Engineering Solid Mechanics Materials Science-Metals and Alloys

CiteScore

3.00

自引率

0.00%

发文量

期刊介绍： Engineering Solid Mechanics (ESM) is an online international journal for publishing high quality peer reviewed papers in the field of theoretical and applied solid mechanics. The primary focus is to exchange ideas about investigating behavior and properties of engineering materials (such as metals, composites, ceramics, polymers, FGMs, rocks and concretes, asphalt mixtures, bio and nano materials) and their mechanical characterization (including strength and deformation behavior, fatigue and fracture, stress measurements, etc.) through experimental, theoretical and numerical research studies. Researchers and practitioners (from deferent areas such as mechanical and manufacturing, aerospace, railway, bio-mechanics, civil and mining, materials and metallurgy, oil, gas and petroleum industries, pipeline, marine and offshore sectors) are encouraged to submit their original, unpublished contributions.