Programs for using Newmark's method to model slope performance during earthquakes

Rainfall-induced landslides occur in many parts of the world and causing a lot of the damages. For effective prediction of rainfall-induced landslides the comprehensive understanding of the failure process is necessary. Under different soil and hydrological conditions experiments were conducted to investigate and clarify the mechanism of slope failure. The failure in model slope was induced by sprinkling the rainfall on slope composed of sandy soil in small flume. Series of tests were conducted in small scale flume to better understand the failure process in sandy slopes. The moisture content was measured with advanced Imko TDR (Time Domain Reflectrometry) moisture sensors in addition to measurements of pore pressure with piezometers. The moisture content increase rapidly to reach the maximum possible water content in case of higher intensity of rainfall, and higher intensity of the rainfall causes higher erosion as compared to smaller intensity of the rainfall. The controlling factor for rainfall-induced flowslides was density of the slope, rather than intensity of the rainfall and during the flowslide the sudden increase in pore pressure was observed. Higher pore pressure was observed at the toe of the slope as compared to upper part of the slope.

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Monitoring of model slope failure tests using Amplitude Domain Reflectometry and Tensiometer methods

Prediction and Simulation Methods for Geohazard Mitigation ◽

10.1201/noe0415804820.ch72 ◽

2009 ◽

Author(s):

S Shimobe ◽

N Ujihira

Keyword(s):

Slope Failure ◽

Model Slope

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Time prediction of an onset of failure in a sandy model slope based on the monitoring of the groundwater level and the surface displacement at different locations

Landslides and Engineered Slopes. Experience, Theory and Practice ◽

10.1201/9781315375007-212 ◽

2018 ◽

pp. 1791-1798

Author(s):

K. Sasahara ◽

T. Ishizawa

Keyword(s):

Groundwater Level ◽

Surface Displacement ◽

Time Prediction ◽

Model Slope

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Bench-Scale Experiments on Effects of Pipe Flow and Entrapped Air in Soil Layer on Hillslope Landslides

Geosciences ◽

10.3390/geosciences9030138 ◽

2019 ◽

Vol 9 (3) ◽

pp. 138 ◽

Cited By ~ 2

Author(s):

Yasutaka Tanaka ◽

Taro Uchida ◽

Hitoshi Nagai ◽

Hikaru Todate

Keyword(s):

Water Supply ◽

Pore Water ◽

Pore Water Pressure ◽

Water Pressure ◽

Soil Layer ◽

Silica Sand ◽

Bench Scale ◽

Drainage Capacity ◽

Entrapped Air ◽

Model Slope

Soil pipes are commonly found in landslide scarps, and it has been suggested that build-up of pore water pressure due to clogged soil pipes influences landslide initiation. Several researchers have also suggested that entrapped air in the soil layer increases the pore water pressure. We carried out bench-scale model experiments to investigate the influence of soil pipes and entrapped air on the build-up of pore water pressure. We installed a water supply system consisting of an artificial rainfall simulator, and used a water supply tank to supply water to the model slope and artificial pipe. We used two types of artificial pipe: A straight pipe, and a confluence of three pipes. Furthermore, we placed a layer of silica sand on top of the model slope to investigate the effect of entrapped air in the soil layer on the build-up of pore water pressure. Silica sand is finer than the sand that we used for the bulk of the model slope. Our results indicate that, although artificial pipes decrease the pore water pressure when the amount of water supplied was smaller than the pipe drainage capacity, the pore water pressure increased when the water supply was too large for the artificial pipe to drain. In particular, the confluence of pipes increased the pore water pressure because the water supply exceeded the drainage capacity. The results also indicate that entrapped air increases the pore water pressure in the area with relatively low drainage capacity, too. Based on these results, we found that although soil pipes can drain a certain amount of water from a soil layer, they can also increase the pore water pressure, and destabilize slopes. Furthermore, entrapped air enhances the trend that the pore water pressure can increase in the area with relatively low drainage capacity, as pore water pressure increases when too much water is supplied, and the artificial pipe cannot drain all of it.

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The discretization error of Newmark's method for numerical integration in structural dynamics

Computer-Aided Design ◽

10.1016/0010-4485(85)90218-0 ◽

1985 ◽

Vol 17 (4) ◽

pp. 200

Author(s):

S. Sutharshana

Keyword(s):

Numerical Integration ◽

Structural Dynamics ◽

Discretization Error ◽

Newmark’S Method

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Time-prediction of an onset of failure in full-scale model slope due to multi-step excavations based on Fukuzono formula

Japanese Geotechnical Journal ◽

10.3208/jgs.13.13 ◽

2018 ◽

Vol 13 (1) ◽

pp. 13-25

Author(s):

Katsuo SASAHARA ◽

Naoki IWATA ◽

Naotaka KIKKAWA ◽

Nobutaka HIRAOKA ◽

Kazuya ITOH

Keyword(s):

Full Scale ◽

Scale Model ◽

Time Prediction ◽

Model Slope

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Application of Distributed Fiber Optic Sensing Technique to Monitor Stability of a Geogrid-Reinforced Model Slope

International Journal of Geosynthetics and Ground Engineering ◽

10.1007/s40891-020-00209-y ◽

2020 ◽

Vol 6 (2) ◽

Cited By ~ 1

Author(s):

Yijie Sun ◽

Suqian Cao ◽

Hongzhong Xu ◽

Xiaoxian Zhou

Keyword(s):

Fiber Optic ◽

Fiber Optic Sensing ◽

Model Slope

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Initiation and displacement of landslide induced by earthquake — a study of shaking table model slope test

Engineering Geology ◽

10.1016/j.enggeo.2011.04.008 ◽

2011 ◽

Vol 122 (1-2) ◽

pp. 106-114 ◽

Cited By ~ 55

Author(s):

Kuo-Lung Wang ◽

Meei-Ling Lin

Keyword(s):

Shaking Table ◽

Slope Test ◽

Table Model ◽

Model Slope

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