Abstract
Collapsible loess is generally characterized by a sudden and substantial decrease in volume that occurs when is applied under constant stress. To evaluate the loess collapse potential, the self-weight collapse and collapse coefficients have been defined by the code for building construction in collapsible loess regions. However, the method in the code does not account for the vertical stress variation. The loess collapse process commonly occurs with stress variation in practice. This paper documents a low-cost, quantitative evaluation scheme using regression analysis to evaluate the loess collapse potential by varying the unloading levels. The results show that the factors that prominently account for loess collapse deformation are the initial pressure, unloading ratio, and collapse completed-ratio. At a constant collapse-completed ratio, the remnant collapse coefficient significantly decreases with the decreasing unloading ratio; at a constant unloading ratio, the remnant collapse coefficient increases with a decreasing collapse-completed ratio. Decreasing unloading and collapse-completed ratios decreased the loess collapse potential with an initial pressure that exceeds the threshold value. Finally, an unloading collapse deformation calculation of loess was prepared to analyze practical project problems of loess based on the unloading collapse test.
Highlights
Loess is an aeolian deposit of yellowish dust mostly formed during the Quaternary period [1,2,3]
Because of its collapse behavior and other associated geotechnical engineering issues, such as landslides, hydro-consolidation, and wetting-induced collapse, loess belongs to problematic soils and has been the subject of geotechnical research and practice since the 1960s [4,5,6,7,8,9,10,11,12,13,14]
In order to express the value of uncompleted collapse of intact loess under the effect of unloading, the ratio of uncompleted collapse Sr to initial height h0 is defined as the coefficient of collapse reduced by unloading. e remnant collapse characteristic is represented by the remnant collapse coefficient δr, which is calculated using δr
Summary
Loess is an aeolian deposit of yellowish dust mostly formed during the Quaternary period [1,2,3]. There are two ways to study the collapse of loess under constant load: one is the combination of the laboratory test and numerical calculation method; the other is the field immersion test. Li et al [20] investigated the functional mechanism of loess collapse for a tunnel structure by conducting a large-field water immersion test on the ground surface above an existing loess tunnel. Shao et al [22,23,24] based on the triaxial test of Q3 loess, the initial tangent modulus of loess with different water content under the given confining pressure under axial loading is measured, and the damage evolution characteristics of the loess structure during humidification are investigated according to the variety of modulus. E research work is significant to supplement and improve the evaluation method of loess collapse and to promote a scientific design method of bored concrete-pile composite foundation in the self-weight collapsible loess site by considering the loess unloading effect
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