TY - GEN
T1 - Critical aspects of finite element modeling of RC structures for seismic performance assessment
AU - Yazgan, Ufuk
AU - Dazio, Alessandro
PY - 2010
Y1 - 2010
N2 - Finite-element modeling of RC structures involves making a series of assumptions related to the distribution of forces and deformations within the structure. In an extensive variety of possible modeling strategies, the engineer is challenged to build an effective numerical model which can be used to quantify the performance of the structure in an efficient manner. In this study a fundamental component of the FE modeling which is the discretization of the model is discussed. The influence of the adopted discretization scheme on the simulated response is presented for a set of representative RC components. Both displacement-based and force-based beam-column finite-elements with two nodes are considered in the analysis. The results obtained using alternative meshing schemes are compared to estimates obtained using the empirical approach of the equivalent plastic hinge length method, as well as against experimental evidence. Additionally, the impact of the adopted meshing scheme on the predicted dynamic response of structures is investigated. The response of a series of RC columns and walls tested on shaking table are considered for this purpose. The simulated maximum and residual displacements are compared to the measured values. Based on the obtained results, preliminary recommendations are developed for the identification of appropriate meshing schemes.
AB - Finite-element modeling of RC structures involves making a series of assumptions related to the distribution of forces and deformations within the structure. In an extensive variety of possible modeling strategies, the engineer is challenged to build an effective numerical model which can be used to quantify the performance of the structure in an efficient manner. In this study a fundamental component of the FE modeling which is the discretization of the model is discussed. The influence of the adopted discretization scheme on the simulated response is presented for a set of representative RC components. Both displacement-based and force-based beam-column finite-elements with two nodes are considered in the analysis. The results obtained using alternative meshing schemes are compared to estimates obtained using the empirical approach of the equivalent plastic hinge length method, as well as against experimental evidence. Additionally, the impact of the adopted meshing scheme on the predicted dynamic response of structures is investigated. The response of a series of RC columns and walls tested on shaking table are considered for this purpose. The simulated maximum and residual displacements are compared to the measured values. Based on the obtained results, preliminary recommendations are developed for the identification of appropriate meshing schemes.
UR - http://www.scopus.com/inward/record.url?scp=84867169147&partnerID=8YFLogxK
M3 - Conference contribution
AN - SCOPUS:84867169147
SN - 9781617388446
T3 - 9th US National and 10th Canadian Conference on Earthquake Engineering 2010, Including Papers from the 4th International Tsunami Symposium
SP - 5835
EP - 5844
BT - 9th US National and 10th Canadian Conference on Earthquake Engineering 2010, Including Papers from the 4th International Tsunami Symposium
T2 - 9th US National and 10th Canadian Conference on Earthquake Engineering 2010, Including Papers from the 4th International Tsunami Symposium
Y2 - 25 July 2010 through 29 July 2010
ER -