Your search keyword '"Barbosa, Andre R."' showing total 5 results

1. Analytical and Numerical Models for Wind and Seismic Design and Assessment of Mass Timber Diaphragms.

Author

Rodrigues, Leonardo G., Barbosa, Andre R., Sinha, Arijit, Higgins, Christopher, Breneman, Scott, Zimmerman, Reid B., Pei, Shiling, van de Lindt, John W., Berman, Jeffrey W., Branco, Jorge M., and Neves, Luís C.

Subjects

*EARTHQUAKE resistant design, *STRUCTURAL panels, *TIMBER, *BUILDING design & construction, *EARTHQUAKES

Abstract

While the use of cross-laminated timber (CLT) panels for building construction has increased over the last several decades, current standards and existing literature provide limited information regarding the design of CLT diaphragms or the prediction of their deflections when subjected to wind and strong earthquake motions. This paper presents the design and assessment of a CLT diaphragm that was part of a full-scale two-story structure subjected to shake-table testing. An analytical model is proposed for diaphragm deflection accounting for in-plane shear and bending stiffness, as well as the stiffness of various connections. Moreover, a refined numerical modeling strategy is proposed in order to consider phenomena such as panel-to-panel gap closure. Results indicate that the analytical model yields conservative results both in terms of deflections and forces when compared to the numerical model that simulates similar sources of strength and stiffness. The analytical model is suitable for the design of symmetric diaphragms with regular shapes, whereas the numerical model can also be used to model asymmetric diaphragms with irregular shapes. [ABSTRACT FROM AUTHOR]

Published

2024

2. System Identification of UCSD-NHERI Shake-Table Test of Two-Story Structure with Cross-Laminated Timber Rocking Walls.

Author

Mugabo, Ignace, Barbosa, Andre R., Sinha, Arijit, Higgins, Christopher, Riggio, Mariapaola, Pei, Shiling, van de Lindt, John W., and Berman, Jeffrey W.

Subjects

*SYSTEM identification, *WOODEN beams, *EARTHQUAKE resistant design, *EFFECT of earthquakes on buildings, *EARTHQUAKE intensity, *MODE shapes, *TIMBER, *WHITE noise

Abstract

A full-scale 2-story mass timber building was tested on the University of California San Diego Natural Hazards Engineering Research Infrastructure (UCSD-NHERI) uniaxial shake table during the period from June 2017 to September 2017. The main objective of the experimental program was to test the performance of mass timber building designs with different seismic lateral force–resisting systems. The focus of this study is on a building configuration designed using self-centering post-tensioned cross-laminated timber (CLT) rocking walls with U-shaped steel flexural plate energy dissipators. The shake-table tests were designed to subject the building to a series of earthquake ground motions of increasing intensity, ranging from a service-level earthquake to 1.20 times the maximum considered earthquake intensity. Between each ground motion, low-amplitude white-noise excitations were applied to the building, which responded as a quasilinear system. In this paper, two output-only operational modal analysis methods are used to estimate the modal parameters (frequency, damping, and mode shapes) based on acceleration data collected during the white-noise shake-table tests. The correlations of observed damage and repairs performed during the experimental program with changes in estimated modal features are reported. The modal parameters estimated from the testing program are also compared with a linear finite-element model that is used to validate the modal identification results and study the performance of the two system identification methods for CLT rocking structures. [ABSTRACT FROM AUTHOR]

Published

2021

3. Implementation and Calibration of Finite-Length Plastic Hinge Elements for Use in Seismic Structural Collapse Analysis.

Author

Ribeiro, Filipe L. A., Neves, Luis A. C., and Barbosa, Andre R.

Subjects

EARTHQUAKE resistant design, MATERIAL plasticity, PHENOMENOLOGICAL theory (Physics), ERROR analysis in mathematics, EMPIRICAL research

Abstract

Finite-length plastic hinge (FLPH) models have shown advantages over the concentrated plasticity hinge (CPH) models. However, empirical phenomenological relationships, such as Modified Ibarra–Medina–Krawinkler (ModIMK) deterioration model, were mainly calibrated for use in CPH models. ModIMK relationships are versatile and have been applied to steel, reinforced concrete, and timber structures. Herein, a calibration procedure of FLPH models and a unified algorithm for use of ModIMK relationships in CPH and FLPH models are presented. Results from included examples validate the proposed algorithms, which were implemented in OpenSees. Additionally, results highlight that FPLH models avoid errors and convergence pitfalls of CPH models. [ABSTRACT FROM PUBLISHER]

Published

2017

4. Influence of earthquake ground-motion duration on damage estimation: application to steel moment resisting frames.

Author

Barbosa, Andre R., Ribeiro, Filipe L. A., and Neves, Luis A. C.

Subjects

BUILDING design & construction, EARTHQUAKE resistant design, STEEL framing, DUCTILITY, FINITE element method

Abstract

This paper presents an analytical study evaluating the influence of ground motion duration on structural damage of 3-story, 9-story, and 20-story SAC steel moment resisting frame buildings designed for downtown Seattle, WA, USA, using pre-Northridge codes. Two-dimensional nonlinear finite element models of the buildings are used to estimate the damage induced by the ground motions. A set of 44 ground motions is used to study the combined effect of spectral acceleration and ground motion significant duration on drift and damage measures. In addition, 10 spectrally equivalent short-duration shallow crustal ground motions and long-duration subduction zone records are selected to isolate duration effect and assess its effect on the response. For each ground motion pair, incremental dynamic analyses are performed at at least 20 intensity levels and response measures such as peak interstory drift ratio and energy dissipated are tracked. These response measures are combined into two damage metrics that account for the ductility and energy dissipation. Results indicate that the duration of the ground motion influences, above all, the combined damage measures, although some effect on drift-based response measures is also observed for larger levels of drift. These results indicate that because the current assessment methodologies do not capture the effects of ground motion duration, both performance-based and code-based assessment methodologies should be revised to consider damage measures that are sensitive to duration. Copyright © 2016 John Wiley & Sons, Ltd [ABSTRACT FROM AUTHOR]

Published

2017

5. Deterioration Modeling of Steel Moment Resisting Frames Using Finite-Length Plastic Hinge Force-Based Beam-Column Elements.

Author

Ribeiro, Filipe L. A., Barbosa, Andre R., Scott, Michael H., and Neves, Luis C.

Subjects

*STEEL framing, *EARTHQUAKE resistant design, *MATERIAL plasticity, *FINITE element method, *STIFFNESS (Engineering)

Abstract

The use of empirically calibrated moment-rotation models that account for strength and stiffness deterioration of steel frame members is paramount in evaluating the performance of steel structures prone to collapse under seismic loading. These deterioration models are typically used as zero-length springs in a concentrated plasticity formulation; however, a calibration procedure is required when they are used to represent the moment-curvature behavior in distributed plasticity formulations because the resulting moment-rotation response depends on the element integration method. A plastic hinge integration method for using deterioration models in force-based elements is developed and validated using flexural stiffness modifications parameters to recover the exact solution for linear problems while ensuring objective softening response. To guarantee accurate results in both the linear and nonlinear range of response, the flexural stiffness modification parameters are computed at the beginning of the analysis as a function of the user-specified plastic hinge length. With this approach, moment-rotation models that account for strength and stiffness deterioration can be applied in conjunction with force-based plastic hinge beam-column elements to support collapse prediction without increased modeling complexity. [ABSTRACT FROM AUTHOR]

Published

2015