Influence of principal stress rotation of unequal tensile and compressive stress amplitudes on characteristics of soft clay

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• 作者：Yang Shen ; Xin Wang ; Han-long Liu ; Wen-han Du…
• 关键词：Complex stress path ; Principal stress rotation ; Train loads ; Amplitude ratio ; Cyclic dynamic stress ratio ; Failure criterion
• 刊名：Journal of Mountain Science
• 出版年：2017
• 出版时间：February 2017
• 年：2017
• 卷：14
• 期：2
• 页码：369-381
• 全文大小：
• 刊物主题：Earth Sciences, general; Geography, general; Environment, general; Ecology;
• 出版者：Science Press
• ISSN：1993-0321
• 卷排序：14

文摘

Soil behavior can reflect the characteristics of principal stress rotation under dynamic wave and traffic loads. Unequal amplitudes of tensile and compressive stresses applied to soils have complex effects on foundation soils in comparison with the pure principal stress rotation path. A series of undrained cyclic hollow torsional shear tests were performed on typical remolded soft clay from the Ilexi area of Nanjing, China. The main control parameters were the tensile and compressive stress amplitude ratio (α) and the cyclic dynamic stress ratio (η). It was found that the critical η tended to remain constant at 0.13, when the value of the compressive stress amplitude was higher than the tensile stress amplitude. However, the influence of the tensile stress was limited by the dynamic stress level when α= 1. For obvious structural change in the soil, the corresponding numbers of cyclic vibration cycles were found to be independent of α at low stress levels and were only related to η. Finally, a new method for evaluating the failure of remolded soft clay was presented. It considers the influence of the tensile and compressive stresses which caused by complex paths of the principal stress rotation. This criterion can distinguish stable, critical, and destructive states based on the pore-water-pressure-strain coupling curve while also providing a range of failure strain and vibration cycles. These results provide the theoretical support for systematic studies of principal stress rotation using constitu tive models.