Improvement of the Geotechnical Properties of the Soil of Lime-Treated Cubitermes Mound Soil

Open Journal of Civil Engineering Pub Date : 2020-01-13 DOI:10.4236/ojce.2020.101003

Séverin Jean Maixent Loubouth, L. Ahouet, R. Elenga, Sylvain Ndinga Okina, Paul Louzolo Kimbembe

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引用次数: 5

Abstract

This work consisted in determining the geotechnical properties of the soil of the Cubitermes termite mound soil treated with lime for use in road construction in accordance with the relevant standards. The raw soil is composed of 29.45% clay, 45.12% silt and 25.43% sand, and its granulometric curve is above the relevant standard curve. The addition of lime up to 9% decreases the fine fraction content from 75% to 60%, and the maximum dry density from 1.62 t/m3 to 1.36 t/m3. The reduction of the fine fraction should reduce the soil sensitivity to water, and the emission of dust from the road. The compressive strength of the raw soil (3.89 MPa) is higher than that of most cohesive soil, and is probably one the causes of the longevity of the rural road paved with this soil. Treated soil with 6% in lime content has the highest compressive strength (5.95 MPa), and the lowest deformation at failure. Until 28 days, the improvement of the compressive upon the curing time is almost the same for untreated and treated termite mound soils. Thus, this improvement could be mostly attributed to the drying of the samples instead to the pozzolanic reactions. Besides, adding lime also enhances the shear strength of soil. Therefore, adding lime up to 6% in content to the termite mound soil should improve its behavior as surface roads.

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石灰处理立柱土土工性能的改善

本工作是根据有关标准测定石灰处理后的Cubitermes白蚁丘土的土工性能。原土由29.45%的粘土、45.12%的粉土和25.43%的砂土组成，其粒度曲线高于相关标准曲线。石灰添加量达到9%时，细粒含量由75%降至60%，最大干密度由1.62 t/m3降至1.36 t/m3。细颗粒的减少应该会降低土壤对水的敏感性，以及道路粉尘的排放。生土的抗压强度(3.89 MPa)高于大多数粘性土，这可能是用这种土铺设的乡村道路寿命长的原因之一。石灰含量为6%的处理土抗压强度最高(5.95 MPa)，破坏变形最小。直到28天，未处理和处理过的白蚁丘土的抗压强度随养护时间的增加几乎相同。因此，这种改进可能主要归功于样品的干燥，而不是火山灰反应。此外，石灰的加入也提高了土的抗剪强度。因此，在白蚁丘土中添加含量为6%的石灰，可以改善其作为路面路面的性能。

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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Open Journal of Civil Engineering

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