Todor Ganev scite author profile

Earthquake Engng. Struct. Dyn.

Ishizaki³

et al. 1998

SUMMARYThis paper presents results of observation and analysis of the response of one of the longest cable-stayed bridges in the world to the Hyogoken-Nanbu (Kobe) Earthquake of 17 January 1995. It is determined that interaction of the foundations of the bridge towers with the supporting soil plays a decisive role in the overall structural behaviour. The key factor governing the changes of the soil properties at this site is pore-water pressure buildup, which results in liquefaction of the saturated surface soil layers under large dynamic loads. Models of the soil and structure are created and initially validated by accurately simulating the system response to a small earthquake. Soil parameters reflecting the pore-water pressure buildup in the strong earthquake are determined by an advanced non-linear effective stress analysis, combining the Ramberg-Osgood model of stress-strain dependence with a pore pressure model based on shear work concept. They are utilized to investigate and simulate the interaction of the foundation and the supporting soil using the program SASSI with the flexible volume substructuring approach. The results show a good agreement with the observations and have useful implications to the scientific and engineering practice.

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Observation and numerical analysis of soil‐structure interaction of a reinforced concrete tower

Earthq Engng Struct Dyn

Katayama

1995

SUMMARYA vast amount of earthquake response records of an observation tower are used together with microtremor data to investigate various aspects of the dynamic behaviour of the soil-structure system. It is found that separation of the soil from the structure occurs under large dynamic loads, leading to changes in the predominant frequency of the system. As a result of the decreasing of the soil support at the side walls of the foundation, the stress caused by the structural weight on the bottom soil increases during earthquakes. With regard to its practical applicability, a linear sway-rocking model is applied for numerical modelling of the soil-structure system. Alterations in the soil support as a result of soil non-linearity and separation of the structure from the soil are investigated by comparing recorded and simulated structural response. The influence of each of these factors on the softening of the soil support is distinctly assessed. An empirical relationship between the peak ground velocity and the soil constants for earthquake excitations of different magnitude is presented.

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Soil-structure interaction analysis of the Hualien containment model

Soil Dynamics and Earthquake Engineering

Katayama

et al. 1997

Observation of Soil-Structure Interaction Effects Based on Earthquake and Microtremor Records of a Reinforced Concrete Tower

PROCEEDINGS OF THE JSCE EARTHQUAKE ENGINEERING SYMPOSIUM

Nagata

et al. 1993

Soil-Structure Interaction of a Containment Model in Hualien, Taiwan

PROCEEDINGS OF THE JSCE EARTHQUAKE ENGINEERING SYMPOSIUM

Katayama

et al. 1995