Shrinkage Module of Soil Samples with Different Cement Content

Mohannad Sabry, M. A. Mandalawi, Mays Sabry
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引用次数: 1

Abstract

The differences in soil's body mass during shrinkage over time have changes in soil physical properties which provide an important reason to check the design of underground foundations in expansive soils. In this paper, a state-of-art of the soil heat stress-strain relationship prediction methods is checked using soil engineering laboratory experiments and Matlab R2013b numerical modelling. The shrinkage of soils with different cement content of (0%, 2%, 4%, 6% and 8%) with the same water content of 20 percent in room temperature for 24 hours, are critically reviewed in terms of their predictive shrinkage along with their strengths and flexural behaviour. The review highlights the prediction methods present to determine the effect of heat stress on the shrinkage of soil samples with different cement content after classifying the soils into clay, silt and sand depending on their particle size using sieve and hydrometer experiments. The results of the soil engineering laboratory experiments showed that as the cement content increases, the shrinkage of soil decreases as a result of increased elasticity in soil. The numerical analysis using finite element method in Matlab R2013b shows that as the cement content increases the displacement in the soil sample decreases and that the soil sample with 8% cement content has more resistance to shrinkage and less displacement than the soil with 6% cement, which has less resistance to heat stresses and more displacement.
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不同水泥掺量土样的收缩模量
随着时间的推移,收缩过程中土体质量的差异导致了土体物理性质的变化,这是检验膨胀土地下基础设计的重要依据。本文通过土壤工程室内实验和Matlab R2013b数值模拟,对一种目前最先进的土壤热应力-应变关系预测方法进行校核。不同水泥含量(0%、2%、4%、6%和8%)、相同含水量为20%的土壤在室温下24小时的收缩,根据其预测收缩以及强度和弯曲行为进行了严格的审查。本文重点介绍了利用筛分试验和比重计试验,将不同水泥含量的土按粒径分为粘土、粉土和砂土后,热应力对不同水泥含量土试样收缩影响的预测方法。土工程室内试验结果表明,随着水泥掺量的增加,土的收缩率减小,这是由于土的弹性增加。在Matlab R2013b中采用有限元方法进行数值分析表明,随着水泥掺量的增加,土样中的位移减小,水泥掺量为8%的土样比水泥掺量为6%的土样具有更强的抗收缩性和更小的位移性,后者对热应力的阻力更小,位移更大。
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