Abstract
A two-step strategy for the mechanical analysis of unreinforced masonry (URM) structures, subjected to either in-or out-of-plane loading, is presented. At a first step, a semi-automatic digital tool allows the parametric modeling of the structure that, together with an upper bound limit analysis tool and a heuristic optimization solver, enables tracking the most prone failure mechanism. At a second step, a coupled concurrent FE model with micro-and macroscales is assumed. A micromodeling description of the masonry is allocated to regions within the failure mechanism found in the former step. In converse, the other domain regions are modeled via a macroscale approach, whose constitutive response is elastic and orthotropic and formulated through closed-form homogenized-based solutions. The application of the framework is based on nonlinear static (pushover) analysis and conducted on three benchmarks: (i) an in-plane loaded URM shear wall; (ii) a U-shaped URM structure; and (iii) a URM church. Results are given in terms of load capacity curves, total displacement fields, and computational running time; and compared against those found with an FE microscopic model and with a limit analysis tool. Lastly, conclusions on the potential of the framework and future research streams are addressed.
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Funari, M. F., Silva, L. C., Savalle, N., & Lourenço, P. B. (2022). A CONCURRENT MICRO/MACRO FE-MODEL OPTIMIZED WITH A LIMIT ANALYSIS TOOL FOR THE ASSESSMENT OF DRY-JOINT MASONRY STRUCTURES. International Journal for Multiscale Computational Engineering, 20(5), 65–85. https://doi.org/10.1615/IntJMultCompEng.2021040212
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