Effects of physical properties and undrained cyclic shear conditions on the pore water pressure responses of saturated sands and clays

IF 2.4 Q2 GEOSCIENCES, MULTIDISCIPLINARY
Nhan Tran Thanh, H. Matsuda, An Tran Thi Phuong, Nhan Nguyen Thi Thanh, Tien Pham Van, Thien Do Quang
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引用次数: 1

Abstract

For clarifying the effects of relative density (Dr) and Atterberg’s limits on the cyclic shear-induced pore water pressure properties of soils, sandy soils with similar index properties and clayey soils with different Atteberg’s limits were collected from Vietnam and Japan and used for this study. Specimens at Dr = 50% of Nam O sand and Dr = 70% of Toyoura sand, and those of Hue clay and Japanese Kaolin clay were consolidated under the vertical stress of σvo = 49 kPa. They were then subjected to undrained cyclic shear for various cyclic shear directions and wide ranges of the number of cycles and shear strain amplitudes. Under the same cyclic shearing conditions, specimens of sand at higher Dr (Toyoura sand) and clay with higher Atterberg’s limits (Kaolin) show a lower pore water pressure ratio. The number of cycles and the cumulative shear strain at the starting point of pore water pressure generation were observed for different soils and testing conditions. In addition, using the cumulative shear strain, a new strain path parameter, the effects of shear strain amplitude and cyclic shear direction can be captured, resulting in a unique uacc/σ’vo - G*  relation on each soil. Based on this, fitting lines can be drawn and referred to promote a prediction of the cyclic shear-induced pore water pressure accumulation for the used soils under different cyclic shear conditions.
物性和不排水循环剪切条件对饱和砂和粘土孔隙水压力响应的影响
为了阐明相对密度(Dr)和阿氏极限对土壤循环剪切引起的孔隙水压力特性的影响,从越南和日本收集了具有相似指数特性的砂土和具有不同阿氏极限的粘性土,并将其用于本研究。在σvo=49kPa的垂直应力下,对Dr=50%的Nam O砂和Dr=70%的Toyura砂以及Hue粘土和日本高岭土的试样进行固结。然后,对它们进行不同循环剪切方向和宽范围的循环次数和剪切应变振幅的不排水循环剪切。在相同的循环剪切条件下,Dr较高的砂(Toyura砂)和Atterberg极限较高的粘土(高岭土)试样的孔隙水压力比较低。在不同的土壤和试验条件下,观察了孔隙水压力产生起始点的循环次数和累积剪切应变。此外,使用累积剪切应变这一新的应变路径参数,可以捕捉剪切应变幅度和循环剪切方向的影响,从而在每种土壤上产生独特的uacc/σ'vo-G*关系。基于此,可以绘制和参考拟合线,以促进对不同循环剪切条件下所用土壤的循环剪切引起的孔隙水压力累积的预测。
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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来源期刊
VIETNAM JOURNAL OF EARTH SCIENCES
VIETNAM JOURNAL OF EARTH SCIENCES GEOSCIENCES, MULTIDISCIPLINARY-
CiteScore
3.60
自引率
20.00%
发文量
0
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