Журнал Геоэкология

ГЕОЭКОЛОГИЯ

ИНЖЕНЕРНАЯ ГЕОЛОГИЯ. ГИДРОГЕОЛОГИЯ. ГЕОКРИОЛОГИЯ

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0869-7809 (Print)
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Вознесенский Евгений Арнольдович
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Geoekologiya, 2019, Vol. 5, P. 48-60

PHYSICO-CHEMICAL NATURE OF CLAYEY SOILS STRENGTH

© 2019 F. S. Karpenko
Sergeev Institute of Environmental Geoscience, Russian Academy of Sciences,
Ulanskii per. 13, bld. 2, Moscow, 101000 Russia
E-mail: kafs08@bk.ru

The principles of soil mechanics based on Mohr—Coulomb strength theory and Terzaghi effective stresses theory give us the idea about the nature of clay strength. However, these theories consider the clay as a solid body and do not take into account their internal structure. In the present paper, the problems in determining the strength of clayey soils are considered from the standpoint of the physicochemical theory of effective stresses. This theory is based on the ideas of the internal structure of clays. The main idea implies that the structure of clays depends on the contacts formed between mineral particles, where the external stresses transmitted to the soil are concentrating. Water in clayey soils not only fills the pore space but also interacts with the mineral particles forming hydrate films around them. The prevailing type of structural contacts in clays determines the properties of latter. Strength is an intrinsic property of soil determined by its composition and internal structure, independent of the conditions of load application to it and characterized by the actual effective strength value. The value of actual effective strength in clays is determined by the total strength of individual contacts. This is the maximal stress transferred to the soil contacts, the structure being ruined upon exceeding this value. The actual effective strength in soils with the same predominant type of contacts depends on the number of contacts. The numerical strength characteristics of contact types are determined for different clay soil varieties to characterize the actual effective strength. The parameters of relationship between the actual effective strength in clays and their strength characteristics are obtained from the soil testing by standard methods.

Keywords: strength, structural contacts, contact type, number of contacts, hydrate films, actual effective stresses, actual effective strength.

DOI: https://doi.org/10.31857/S0869-78092019548-60

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