Mitigation of Disasters by Earthquakes, Tsunamis, and Rains by Means of Geosynthetic-Reinforced Soil Retaining Walls and Embankments

Koseki, Junichi; Shibuya, Satoru

doi:10.1007/s40515-014-0009-0

Cited by 12 publications

(2 citation statements)

References 13 publications

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“…The damages level variation is varied such as exposure of the buildings and the foundations, peak ground acceleration variation of seeming by different local soil profile, and structures which might involve soil settlement or resonance induced foundation failures. Besides huge seismic loads, excessive of groundwater and inadequate strength of soil should also be considered [5]. Furthermore, local geological and geotechnical histories should also be a part of further measurements [6].…”

Section: B Geotechnical Failures Due To Earthquakementioning

confidence: 99%

Geotechnical Engineering Aspect Related to Pidie Jaya–Aceh Earthquake Disaster and Mitigation

Munirwansyah¹,

Munirwan²,

Yunita³

2018

International Journal on Advanced Science, Engineering and Information Technology

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Earthquake catastrophe in Pidie Jaya has caused damages to the city of Meureudu, Aceh-Sumatra Indonesia. Based on preliminary study for buildings and infrastructures, the geotechnical engineering aspects damages-related are presented. Seismic motion effect damage of earthquakes such as liquefaction of soil, lateral spreads, and ground failure were the majority effect for infrastructures and buildings. Moreover, failures of almost of multi-storey buildings and mosques along the national road lines are because the effect of peak surface accelerations and earthquake wave propagation forces which are very close with epicenter coordinates 5.308°N / 96.269°E in 4km radius. Seismic back investigates of the Aceh's fault seismic source as well as initial probabilistic seismic hazard analysis post-Pidie Jaya earthquake for city of Mereudu is offered. Liquefaction potential analysis from the estimation of peak ground acceleration was conducted. Geotechnical aspect and substructure failure characteristics to infrastructure and housing damages due earthquake are also reported. The earthquake has caused 104 people deaths, 2.474 unit houses in total need to be rehabilitated and rebuilt, almost 10 km of roads and 50 bridges need to be reconstructed. Some descriptive countermeasures for reconstructions of geotechnical engineering aspects and mitigation are also provided.

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Section: B Geotechnical Failures Due To Earthquakementioning

confidence: 99%

Geotechnical Engineering Aspect Related to Pidie Jaya–Aceh Earthquake Disaster and Mitigation

Munirwansyah¹,

Munirwan²,

Yunita³

2018

International Journal on Advanced Science, Engineering and Information Technology

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“…Several researchers had used geogrid to solve numerous embankment stability related problems. Koseki and Shibuya [15] evaluated performance of geogrid reinforced embankments against large earthquake and heavy rainfall. Naggar et al [16] introduced geogrid reinforced bridge platform to reduce additional earth pressure caused by buried utility pipes in the road embankment.…”

Section: Literature Reviewmentioning

confidence: 99%

Effectiveness of Geogrid for Protecting Polder in Sundarban Coastal Region

Chy

Barua

Ansary

2018

AEF

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Numbers of large scale polders are constructed to protect low-lying coastal area of Sundarban in Bangladesh during 1960s. At present, there are number of polders occupying an area of about 1.2 million hectares, which are vulnerable to breach and cause immense misery to millions of people every year. The purpose of this study is to assess the safety factors (FoS) of those Polder embankments during diurnal tidal cycle in coastal area and provide solution to improve the stability of embankment through installation of geogrid layers. To investigate vulnerability of the embankment failure, soil samples are collected from several borehole locations in Satkhira, a coastal site of Sundarban area. Field test—SPT and several Laboratory tests—direct shear test and Sieve analysis test have been carried out to determine shear strength, angle of internal frictions and grain size distribution. Slope stability analysis are performed using Geo5 software under several conditions—high water table (HWT), low water table (LWT) and rapid drawdown (RD) with side slope are 1:1, 1:1.5 and 1:2 and embankment height are 5m, 7.5m and 10m. The safety factor has been found lowest at rapid drawdown condition because of rapid recession of external water level. The lower FoS have been found 0.68, 0.89 and 0.92 which can be improved to 1.23, 1.34 and 1.24 respectively by installing several geogrid layers. Simplified Bishop Method have been used in Geo5 to perform the stability analysis under various conditions. In our investigation, HDPE biaxial geogrid have been taken to strengthen of polder embankments, which are timesaving, cost effective and efficient, side by side suitable for Sundarban area. The findings and solutions proposed by the study will help geotechnical engineers to reduce the vulnerability of Polder embankment under similar coastal conditions.

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Analysis of the stability and seismic behavior of the geosynthetic-reinforced embankments under earthquake

Zhu

Yao

2020

J. Mt. Sci.

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Mitigation of Disasters by Earthquakes, Tsunamis, and Rains by Means of Geosynthetic-Reinforced Soil Retaining Walls and Embankments

Cited by 12 publications

References 13 publications

Geotechnical Engineering Aspect Related to Pidie Jaya–Aceh Earthquake Disaster and Mitigation

Geotechnical Engineering Aspect Related to Pidie Jaya–Aceh Earthquake Disaster and Mitigation

Effectiveness of Geogrid for Protecting Polder in Sundarban Coastal Region

Analysis of the stability and seismic behavior of the geosynthetic-reinforced embankments under earthquake

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