Your search keyword '"TOBITA, Tetsuo"' showing total 4 results

1. Verification of Liquefaction Potential during the Strong Earthquake at the Border of Thailand-Myanmar.

Author

Mase, Lindung Zalbuin, Likitlersuang, Suched, and Tobita, Tetsuo

Subjects

SEISMIC response, EARTHQUAKES, SOIL liquefaction, FRICTION velocity, SHEAR waves, DEPTH profiling

Abstract

The study presents a liquefaction potential analysis for the Thailand-Myanmar border area due to the earthquake. Three sites reported liquefaction during Tarlay earthquake in 2011 were investigated including a microtremor to obtain the shear wave velocity profile and depth of engineering bedrock. Next-generation attenuation model was used to estimate the peak ground acceleration at the liquefied sites. A seismic ground response analysis was then conducted, and the result revealed that the shallow sand layers were very vulnerable to undergo liquefaction. The results also showed a similar tendency to the predictions based on the empirical methods. [ABSTRACT FROM AUTHOR]

Published

2022

2. Local Site Investigation of Liquefied Soils Caused by Earthquake in Northern Thailand.

Author

Mase, Lindung Zalbuin, Likitlersuang, Suched, Tobita, Tetsuo, Chaiprakaikeow, Susit, and Soralump, Suttisak

Subjects

EARTHQUAKES, FRICTION velocity, SOILS, SHEAR waves, NOISE measurement

Abstract

Ambient noise measurements and spectral analysis of surface waves were performed in Mae Lao to investigate the local site effects of the May 5, 2014 Mae Lao earthquake in Northern Thailand. Site investigations were conducted to determine horizontal to vertical spectral ratio, predominant frequency, and shear wave velocity profile. The results showed that the liquefied locations were classified as Site Class D. The low Vs profile at the shallow depth confirmed evidences of liquefaction in this area. The results could bring an understanding of site response and dynamic behavior of soils during earthquake in the Northern Thailand. [ABSTRACT FROM AUTHOR]

Published

2020

3. Cyclic behaviour and liquefaction resistance of Izumio sands in Osaka, Japan.

Author

Mase, Lindung Zalbuin, Likitlersuang, Suched, and Tobita, Tetsuo

Subjects

SOIL liquefaction, SANDY soils, R-curves, SAND, CYCLIC loads, HYSTERESIS loop, BEHAVIOR

Abstract

This article presents a study of liquefaction resistance behaviour of sand using a cyclic triaxial test. The site investigation was performed, and frozen undisturbed specimens were taken from the Izumio site in Osaka, Japan. According to the evidence in 1995 Kobe Earthquake, the first two sand layers are vulnerable to undergo liquefaction. The effect of deviatoric stress on liquefaction resistance was focused on in this study. The excess pore pressure ratio, hysteresis loop, and effective stress path from the cyclic triaxial tests were reported. A multispring element model was employed to simulate the soil behaviour under cyclic loading. The results showed that applied deviatoric stress could influence the liquefaction resistance of sandy soil samples. The plots of the cyclic stress ratio versus the number of cycles to generate liquefaction known as a liquefaction resistance curve can be then constructed and compared with other sands. [ABSTRACT FROM AUTHOR]

Published

2019

4. Vertical loads effect on the lateral pile group resistance in sand.

Author

Hussien, Mahmoud N., Tobita, Tetsuo, Iai, Susumu, and Rollins, Kyle M.

Subjects

*PILES & pile driving, *SAND, *MECHANICAL loads, *FINITE element method, *SOILS, *NONLINEAR analysis, *PRESSURE

Abstract

Vertical loads effect on the lateral response of a 3×5 pile group embedded in sand is studied through a two-dimensional finite element analysis. The soil-pile interaction in three-dimensional type is idealized in the two-dimensional analysis using soil-pile interaction springs with a hysteretic nonlinear load displacement relationship. Vertical loads inducing a vertical pile head displacement of 0.1-pile diameter increase the lateral resistance of the single pile at a 60 mm lateral deflection by 8%. Vertical loads inducing the same vertical displacement applied to a pile group spaced at 3.92-pile diameter increase the overall lateral resistance by 9%. The effect on individual piles, however, depends on the pile position. The vertical load decreases the lateral resistance of the leading pile (pile 1) by 10% and increases the lateral resistances of piles 2, 3, 4, and 5 by 9%, 14%, 17%, and 35%, respectively. Vertical loads applied to the pile group increase the confining pressures in the sand deposit confined by the piles but the rate of increase in those outside the group is relatively small, resulting in the difference in a balance of lateral soil pressures acting at the back of and in front of the individual pile. [ABSTRACT FROM PUBLISHER]

Published

2012