Journals Information
Civil Engineering and Architecture Vol. 8(4), pp. 721 - 733
DOI: 10.13189/cea.2020.080434
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Swelling Stress and Suction Correlation of Compacted, Heaving Soils
Armand A. Fondjo 1, Thywill C. Dzogbewu 2,*
1 Department of Civil Engineering, Central University of Technology, Free State, South Africa
2 Department of Mechanical Engineering, Central University of Technology, Free State, South Africa
ABSTRACT
The behaviour of unsaturated soils is mainly influenced by suction. When unsaturated soils display swelling properties, it becomes fundamental to investigate the impact of soil suction on the swelling stress. A survey was done across Free State province in South Africa and samples were obtained from Bloemfontein, Winburg, and Welkom. Geotechnical studies were performed on particle size definition, free swell ratio, free swell index, Atterberg limits, X-ray diffraction, proctor compaction test, soil suction measurement, and constant volume swelling tests to determine the physical and hydro-mechanical properties of the soil samples. According to the findings, at the optimum water content, the swelling stress values are in the range of 177 kPa to 326 kPa which is more than the bearing limit (~ 40 kPa) applied for most lightweight footing. Smectite is identified as the predominant clay mineral in the study areas and has a key influence on the swelling properties. A solid relation is observed between the swelling stress and the soil suctions, with a correlation coefficient value greater than 80 %.
KEYWORDS
Swelling Stress, Suction, Compaction, Heaving Soil, X-ray Diffraction, Optimum Water Content
Cite This Paper in IEEE or APA Citation Styles
(a). IEEE Format:
[1] Armand A. Fondjo , Thywill C. Dzogbewu , "Swelling Stress and Suction Correlation of Compacted, Heaving Soils," Civil Engineering and Architecture, Vol. 8, No. 4, pp. 721 - 733, 2020. DOI: 10.13189/cea.2020.080434.
(b). APA Format:
Armand A. Fondjo , Thywill C. Dzogbewu (2020). Swelling Stress and Suction Correlation of Compacted, Heaving Soils. Civil Engineering and Architecture, 8(4), 721 - 733. DOI: 10.13189/cea.2020.080434.