T. Kokusho, H. Hazarika, T. Ishizawa, S. Ishibashi, Katsuya Ogo
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引用次数: 0
摘要
在日本北海道最近发生的两次地震中,液化的沙子异常地在非常平缓的人造填充物斜坡上流入地下,造成了大面积的地表凹陷。在这两种情况下,松散的细砂中都存在大量的非塑性细粒。在不排水的三轴试验中,这些砂比相同密度的无细粒砂更容易收缩和流动。这强烈表明,高细粒含量是导致奇怪的流动破坏的主要原因,因为它使砂在稳态线的收缩侧可流动。另一系列初始剪应力作用下含细粒收缩砂的循环扭转单剪试验表明,即使在缓坡中也可能发生流动破坏。这是当有效应力路径遇到一条从τ−σ c '图上的原点绘制的直线屈服线时,而不考虑应力路径。根据观察结果,开发了一个模拟异常流动故障的场景。
Understanding Liquefaction Flow of Gentle Slopes Containing Non-Plastic Fines
In two recent earthquakes in Hokkaido, Japan, liquefied sand unusually flowed underground in very gentle man-made fill slopes, creating large ground surface depressions. In both cases, a significant amount of non-plastic fines was present in the loose fine sands. When tested in undrained triaxial tests, these sands were found far more contractive and easier to flow than sand of the same density without fines. This strongly suggested that the high fines content was the major cause of the strange flow failures because it made the sand flowable on the contractive side of the steady state line. Another series of cyclic torsional simple shear tests on contractive sands with fines under initial shear stress indicated that the flow failure can initiate even in a gentle slope. This is when the effective stress path comes across a straight yield line drawn from the origin on τ−σ c ’ diagram uniquely defined irrespective of stress paths. A scenario to replicate the unusual flow failures was developed based on the observations.