Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Model testing of the response of stabilizing piles in landslides with upper hard and lower weak bedrock
Abstract The behavior of stabilizing piles with different embedded lengths in bedrock with a hard upper layer and a weak lower layer is examined using physical model tests. Based on the geological model of the landslide with bedrock with a hard upper layer and a weak lower layer, the pile–landslide physical model is developed and includes the data collection system, the pile–landslide model and the loading system. The real-time deformation and moment of the stabilizing pile is obtained in the process of loading at the trailing edge of the landslide for different percentages of hard bedrock. The test results indicate that the percentage of hard bedrock has a strong influence on the deformation and moment of the stabilizing pile embedded in bedrock with a hard upper layer and a weak lower layer. A higher percentage of hard bedrock can result in a greater maximum bending moment of the stabilizing pile and a smaller displacement at the stabilizing pile head, and vice versa. The results also show that 40% of hard bedrock can be considered the critical condition in bedrock with a hard upper layer and a weak lower layer. The percentage of hard bedrock has a limited influence on the deformation of the stabilizing pile when the percentage is greater than 40%. Moreover, four tests with stabilizing piles with different embedded lengths are conducted to investigate the most suitable embedded length in the bedrock with a hard upper layer and a weak lower layer. The results indicate that 28.5cm is a reasonable embedded length for the stabilizing pile in the two-layered bedrock with a hard rock percentage of 20%.
Highlights Physical model was developed to simulate pile embedded in upper hard and lower weak bedrock. Pile deformation was obtained under different percentages of hard bedrock and embedded lengths. Relation between the displacement of pile head and the percentage of hard bedrock was examined. Reasonable embedded length of the stabilizing pile in upper hard and lower weak bedrock was proposed. The merit of the tilted loading system over the horizontal loading was proved.
Model testing of the response of stabilizing piles in landslides with upper hard and lower weak bedrock
Abstract The behavior of stabilizing piles with different embedded lengths in bedrock with a hard upper layer and a weak lower layer is examined using physical model tests. Based on the geological model of the landslide with bedrock with a hard upper layer and a weak lower layer, the pile–landslide physical model is developed and includes the data collection system, the pile–landslide model and the loading system. The real-time deformation and moment of the stabilizing pile is obtained in the process of loading at the trailing edge of the landslide for different percentages of hard bedrock. The test results indicate that the percentage of hard bedrock has a strong influence on the deformation and moment of the stabilizing pile embedded in bedrock with a hard upper layer and a weak lower layer. A higher percentage of hard bedrock can result in a greater maximum bending moment of the stabilizing pile and a smaller displacement at the stabilizing pile head, and vice versa. The results also show that 40% of hard bedrock can be considered the critical condition in bedrock with a hard upper layer and a weak lower layer. The percentage of hard bedrock has a limited influence on the deformation of the stabilizing pile when the percentage is greater than 40%. Moreover, four tests with stabilizing piles with different embedded lengths are conducted to investigate the most suitable embedded length in the bedrock with a hard upper layer and a weak lower layer. The results indicate that 28.5cm is a reasonable embedded length for the stabilizing pile in the two-layered bedrock with a hard rock percentage of 20%.
Highlights Physical model was developed to simulate pile embedded in upper hard and lower weak bedrock. Pile deformation was obtained under different percentages of hard bedrock and embedded lengths. Relation between the displacement of pile head and the percentage of hard bedrock was examined. Reasonable embedded length of the stabilizing pile in upper hard and lower weak bedrock was proposed. The merit of the tilted loading system over the horizontal loading was proved.
Model testing of the response of stabilizing piles in landslides with upper hard and lower weak bedrock
Li, Changdong (Autor:in) / Wu, Junjie (Autor:in) / Tang, Huiming (Autor:in) / Hu, Xinli (Autor:in) / Liu, Xinwang (Autor:in) / Wang, Chenqi (Autor:in) / Liu, Tao (Autor:in) / Zhang, Yongquan (Autor:in)
Engineering Geology ; 204 ; 65-76
04.02.2016
12 pages
Aufsatz (Zeitschrift)
Elektronische Ressource
Englisch
| British Library Online Contents | 2016