Your search keyword '"*EARTHQUAKE hazard analysis"' showing total 12 results

1. Foreword to the Special Issue for the 2019-2021 RINTC (The Implicit Seismic Risk of Existing Structures) Project.

Author

Iervolino, Iunio

Subjects

*SEISMIC response, *EARTHQUAKE hazard analysis, *EARTHQUAKE engineering, *EARTHQUAKE resistant design, *BUILDING sites, *STRUCTURAL reliability

Published

2024

2. Effect of Multi-Components Strong Motion Duration on Seismic Performance of High CFRDs Based on Fragility Analysis.

Author

Xu, Bin, Wang, Xingliang, Pang, Rui, and Zhou, Yang

Subjects

*EARTH dams, *GROUND motion, *EARTHQUAKE resistant design, *SEISMIC response, *FINITE element method, *DAMS, *EARTHQUAKE hazard analysis, *EARTHQUAKES

Abstract

This paper investigates the influence of multi-components strong motion duration on seismic performance of high concrete-faced rockfill dams (CFRDs) by fragility analysis based on the method of incremental dynamic analysis (IDA). The contributions of all compositions of earthquake excitations are considered by the definition of integrated duration based on the concept of significant duration. The nonlinear finite element model of a 2D 200-m-high CFRD is established as a case study and the vertical and horizontal displacements are selected as damage measures. Fragility curves and probabilities of two sets of 23 and 25 spectrally equivalent as-recorded bi-directional long-duration and short-duration motions are determined under different failure grades and intensities. The results show that the duration of vertical component has a certain effect on correction between strong motion duration and deformation of the dam and fragility analysis indicates that the ground motions with long duration can make more risk of failure of high CFRDs than short duration motions. Therefore, the seismic performance of high CFRDs will be reformed by taking the effect of ground motion duration into seismic design and risk assessment consideration. [ABSTRACT FROM AUTHOR]

Published

2023

3. Seismic response of randomly infilled reinforced concrete frames with soft ground storey.

Author

Alam, Taskin and Amanat, Khan Mahmud

Subjects

*SEISMIC response, *BUILDING failures, *REINFORCED concrete, *CONCRETE masonry, *EARTHQUAKE hazard analysis, *MASONRY, *EARTHQUAKE resistant design, *EARTHQUAKES

Abstract

Multistoried masonry infilled concrete (RC) frame with open ground storey has been recognized as a serious stiffness irregularity that has led to typical soft storey collapse of many buildings in past seismic events. Present study represents extensive static and dynamic analyses to investigate the seismic behavior of masonry infilled soft storied RC buildings. Several soft storied 2D frames with variation in number of storeys, number of spans, percentage of infilled frame panels, height to horizontal extent ratio as well as randomness of infill positions have been analyzed and the behavior of frames is investigated. Effect of variation of these parameters on base shear, natural period of vibration, storey drift etc. are studied. Results show that the base shear is significantly increased in presence of structurally active infill panels as compared to static analysis while randomness in the distribution of infill shows no appreciable influence. The findings show that seismic forces obtained from static analysis leads to significantly under-designed ground storey columns in soft storey buildings and are vulnerable during earthquake. Magnification of base shear as a function of amount of infill number of storeys are presented which may act as a guideline for the engineers towards safer design of columns and other elements of buildings with open and soft ground storey in a rational manner. [ABSTRACT FROM AUTHOR]

Published

2020

4. Seismic Retrofitting of Non-Seismically Designed RC Beam-Column Joints using Buckling-Restrained Haunches: Design and Analysis.

Author

Bin Wang, Songye Zhu, You-Lin Xu, and Huanjun Jiang

Subjects

*SEISMIC response, *EARTHQUAKE resistant design, *EARTHQUAKE hazard analysis, *RETROFITTING of buildings, *EFFECT of earthquakes on buildings, *REINFORCED concrete

Abstract

Many existing reinforced concrete (RC) structures around the world have been designed to sustain gravity and wind loads only. Past earthquake reconnaissance showed that strong earthquakes can lead to substantial damage to non-seismically designed RC buildings, particularly to their beam-column joints. This paper presents a novel retrofit method using buckling-restrained haunches (BRHs) to improve the seismic performance of such joints. A numerical model for RC joints is introduced and validated. Subsequently, a new seismic retrofit strategy using BRHs is proposed, aimed at relocating plastic hinges and increasing energy dissipation. The results indicate the retrofit method can effectively meet the performance objectives. [ABSTRACT FROM AUTHOR]

Published

2018

5. Long-Period Ground Motion Simulation and its Impact on Seismic Response of High-Rise Buildings.

Author

Hu, R. P., Xu, Y. L., and Zhao, X.

Subjects

*SEISMIC response, *SKYSCRAPER design & construction, *EFFECT of earthquakes on buildings, *EARTHQUAKE resistant design, *EARTHQUAKE hazard analysis

Abstract

This paper first critically reviews a seismological model and then a three-segment curve model (in log-log space) to model the Q-f relationship is proposed to overcome the potential biased estimation in the long-period range by the "coda wave" method. The optimal curve-fitting process is performed to determine the Q-f relationship for the Hong Kong region. The calibrated seismological factors are incorporated with the stochastic simulation procedure to generate synthetic ground motions, which are validated through comparison with seismic records. The impact of long-period ground motions on the seismic response of high-rise buildings is finally manifested through a numerical study. [ABSTRACT FROM AUTHOR]

Published

2018

6. Probabilistic seismic damage assessment of reinforced concrete buildings considering directionality effects.

Author

Vargas Alzate, Yeudy F., Pujades Beneit, Lluis G., Barbat, Alex H., Hurtado Gomez, Jorge E., Diaz Alvarado, Sergio A., and Hidalgo Leiva, Diego A.

Subjects

*EARTHQUAKE hazard analysis, *REINFORCED concrete, *EARTHQUAKE resistant design, *STRUCTURAL design, *SEISMIC response

Abstract

Most of buildings and structures are usually projected according to two main axes. However, the geographical position of these buildings varies randomly. Such random distributions of the azimuthal positions of structures, in most of the cities, generally, are not accounted for when assessing their seismic risk; certainly, the direction of the seismic loads is another highly random variable. Moreover, an additional important source of uncertainty is related to the structural response, mainly due to the random character of the mechanical properties. There is a consensus that uncertainties must be considered for adequately assessing the seismic risk of structures, but these directionality effects have not been deeply explored so far. In this article, the influence of the high uncertainty involved in these input variables on the expected seismic damage is analysed. Thus, an actual earthquake, which affected the southern part of Spain, is studied. Notably, damages on a group of affected buildings, located close to the epicentre, are analysed and discussed in detail. The results show that the influence of the random azimuthal position of structures is an important source of uncertainty and that it should be taken into account when estimating the expected seismic risk in urban areas. [ABSTRACT FROM AUTHOR]

Published

2018

7. Modeling and Seismic Response Analysis of Italian Code-Conforming Reinforced Concrete Buildings.

Author

Ricci, Paolo, Manfredi, Vincenzo, Noto, Fabrizio, Terrenzi, Marco, Petrone, Crescenzo, Celano, Francesca, De Risi, Maria Teresa, Camata, Guido, Franchin, Paolo, Magliulo, Gennaro, Masi, Angelo, Mollaioli, Fabrizio, Spacone, Enrico, and Verderame, Gerardo M.

Subjects

*SEISMIC response, *EARTHQUAKE hazard analysis, *REINFORCED concrete, *EARTHQUAKE engineering, *EARTHQUAKE resistant design

Abstract

This study investigates the seismic response of reinforced concrete buildings designed according to the current Italian building code. Number of stories, site hazard, presence and distribution of masonry infill panels, and type of lateral resisting system are the key investigated parameters. The main issues related to design and modeling are discussed. Two Limit States are considered, namely Global Collapse and Usability-Preventing Damage. The main aim of the study is a comparison between the seismic response of the buildings, investigated through nonlinear static and dynamic analyses. Irregularity in the distribution of infill panels and site hazard emerge as the most influential parameters. [ABSTRACT FROM AUTHOR]

Published

2018

8. Modelling and Seismic Response Analysis of Italian Code-Conforming Base-Isolated Buildings.

Author

Ragni, L., Cardone, D., Conte, N., Dall'Asta, A., Di Cesare, A., Flora, A., Leccese, G., Micozzi, F., and Ponzo, C.

Subjects

*EARTHQUAKE resistant design, *EARTHQUAKE hazard analysis, *SEISMIC response, *RUBBER bearings, *EARTHQUAKE engineering

Abstract

This paper reports on results of nonlinear analyses performed within the RINTC project on an RC building isolated with different systems (High Damping Rubber Bearings, High Damping Rubber Bearings and Flat Sliding Bearings, Friction Pendulum System) and designed according to the Italian design code. The seismic response has been evaluated under different seismic input levels of two sites with different hazard and by considering two Limit States: Global Collapse and Usability-Preventing Damage. The influence of seismic stoppers and modelling uncertainties is also evaluated. Results permit to compute the implicit collapse risk and to identify critical aspects of current design procedures. [ABSTRACT FROM AUTHOR]

Published

2018

9. Modeling and Seismic Response Analysis of RC Precast Italian Code-Conforming Buildings.

Author

Magliulo, Gennaro, Bellotti, Davide, Cimmino, Maddalena, and Nascimbene, Roberto

Subjects

*SEISMIC response, *EARTHQUAKE engineering, *EARTHQUAKE hazard analysis, *EARTHQUAKE resistant design, *EFFECT of earthquakes on buildings

Abstract

In this study, industrial single-story RC precast buildings are investigated. Twenty-four case studies have been considered, in which the column height, the beam spans and the seismic hazard level are varied. The seismic design of the selected case studies is performed according to the Italian building code and additional technical documentation. Three-dimensional nonlinear models are defined to perform static and dynamic analyses for the seismic assessment of the selected case studies. Demand/capacity ratios in terms of the selected engineering demand parameters are computed for ten increasing values of the seismic input return period. [ABSTRACT FROM AUTHOR]

Published

2018

10. Modeling and Seismic Response Analysis of Italian Code-Conforming Single-Storey Steel Buildings.

Author

Scozzese, Fabrizio, Terracciano, Giusy, Zona, Alessandro, Corte, Gaetano Della, Dall'Asta, Andrea, and Landolfo, Raffaele

Subjects

*EARTHQUAKE engineering, *EARTHQUAKE hazard analysis, *EARTHQUAKE resistant design, *SEISMIC response

Abstract

This article describes the structural design, nonlinear modeling, and seismic analysis of prototype single-storey non-residential steel buildings made of moment-resisting portal frames in the transverse direction and concentric braces in the longitudinal direction. Various design parameters (building geometry, seismic hazard, foundation soil category) and different modeling assumptions (bare frame model, model including cladding elements, ground motions including vertical accelerations, and modeling uncertainties) were considered to investigate their effects on the simulated seismic performance. [ABSTRACT FROM AUTHOR]

Published

2018

11. Fragility of skewed bridges under orthogonal seismic ground motions.

Author

Bhatnagar, Unmukt R. and Banerjee, Swagata

Subjects

*EFFECT of earthquakes on bridges, *EARTHQUAKE hazard analysis, *ANGLE sections (Structural engineering), *SEISMIC response, *EARTHQUAKE resistant design, *ORTHOGONAL arrays

Abstract

The paper evaluates seismic fragility characteristics of skewed bridges under simultaneous action of orthogonal ground motion components. The effect of skew angle on bridge seismic fragility characteristics is investigated through nonlinear time-history analyses of Painter Street Overpass, a 38.5° skewed bridge located in Rio Dell, CA, and six representative bridges with skew angles varying between 0° and 50°. Ground motion incident angle is varied from 0° to 180° to investigate the effect of the direction of ground motion incidence on bridge seismic performance. Bridge seismic response is used to generate fragility curves and contours plots that quantify the sensitivity of bridge fragility characteristics on skew angle and incident angle. For any value of incident angle, bridge seismic vulnerability increases with an increase in skew angle; however, no such general trend is found to describe the effect of incident angle on bridge fragility characteristics. Results show that the variation of maximum rotation of bridge columns for an earthquake does not follow any particular trend with the change in skew angle and incident angle. Analysis-based fragility curves are further compared with empirical fragility curves generated using real-life seismic damage data of skewed bridges and a reasonable agreement is observed between these two. [ABSTRACT FROM AUTHOR]

Published

2015

12. Earthquake Stability of Columns and Statues.

Author

Ambraseys, Nicholas and Psycharis, Ioannis N.

Subjects

*EARTHQUAKES, *COLUMNS, *STATUES, *EARTHQUAKE hazard analysis, *EARTHQUAKE resistant design, *SEISMIC waves

Abstract

The seismic vulnerability of statues mounted on monolithic or multidrum columns is presented in this article. Emphasis is given to the procedure that should be followed for the assessment of the stability to future earthquakes, which is presented through the case study of the statue of Apollo at the Academy of Athens. The earthquake of 1999 (MW = 5.9), at a source distance of about 10 km, caused the base of the statue to slide on the column capital and rotate, with no evidence of any damage having been done to the column or to the Academy Building proper. Earthquake damage of monuments of this type is rarely noticed and, even if observed, is not reported in any detail. This particular case, therefore, offered the opportunity to investigate the stability of statues mounted on multi-drum columns, and also to present critical issues related to the assessment of their vulnerability, as the selection of the ground motions that should be used in the analysis, the determination of the parameters of the numerical models and the correct interpretation of the numerical results. Comments on the validity of the various methods currently in use by practicing engineers are also presented. [ABSTRACT FROM AUTHOR]

Published

2011