饱和重塑黄土在循环载荷作用下的动态特性

Yuting Fu, Yanbo Cao, Jiaxu Kong, Jia Zheng, Jiaqi Mu, Jie Wang, Jianqi Zhuang
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引用次数: 0

摘要

由于黄土的节理发育特征和大孔隙结构,在地震或人工振动作用下容易造成结构坍塌。由于黄土的复杂性,对其在地震作用下的灾害效应及其机理的研究尚不充分。因此,为了更准确地研究黄土的变形和力学性能,本文使用 GDS 动态三轴仪测试了饱和重塑黄土在循环动荷载作用下的动态特性。试验结果表明,应变和孔隙水压力随着振动的发展以不同的速率逐渐增大,两者的时程曲线均存在明显的拐点。当振动次数(N)超过该点时,应变迅速增加,孔隙水压力趋于稳定。在大振幅、低频率动荷载作用下,应变和孔隙水压力随着振动次数的减少而迅速增加,偏差应力(q)迅速减小,试样随着振幅的增加而加速破坏。在施加动荷载期间,有效应力(p)逐渐减小,其变化速度也减慢。最后,当饱和重塑黄土受到恒定振幅的动荷载时,大振幅和低频率的组合导致样品在最短时间内破坏。
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The dynamic characteristics of saturated remolded loess under cyclic load

Due to the joint development characteristic and macropore structure of loess, it is easy to cause structure collapse under earthquake or artificial vibration. The study on the loess disaster effect and its mechanism under earthquake action is insufficient due to its complexity. Hence, to study the deformation and mechanical properties more accurately, the dynamic characteristics of saturated remolded loess under cyclic dynamic load were tested using a GDS dynamic triaxial instrument in this paper. The test results show that strain and pore water pressure increase gradually at different rates with the development of vibration, and there is an obvious inflection point in the time-history curve of both. When the number of vibrations (N) exceeds this point, the strain increases rapidly, and pore water pressure tends to be stable. Under the action of large amplitude and low-frequency dynamic load, the strain and pore water pressure increase rapidly with fewer vibrations and the deviator stress (q) decreases rapidly, while the sample achieves damage faster with the increase of amplitude. During the application of a dynamic load, the effective stress (p) gradually decreases and its rate of change slows down. Finally, when the saturated remolded loess is subjected to a constant-amplitude dynamic load, the combination of large amplitude and low frequency leads to the failure of the sample in the shortest time.

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