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Dynamic response of rocking cracked masonry walls

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Abstract

The behaviour of masonry constructions results to be very far from the one characterizing ductile structures. In masonry constructions, the seismic action activates a rocking motion rather than a dissipating mechanism. A strength resource of masonry structures, properly reinforced in order to avoid early local failures, consists in exhibiting rocking behaviour, until a failure condition is attained. Aim of the paper is to investigate the dynamic behaviour of masonry single storey walls, according to Housner’s studies and innovatively introducing the effect of diagonal cracks developing from the toes of the piers and shown by typical post-earthquake cracking patterns. The proposed procedure can be easily applied to the case of multi-storey regular masonry walls with openings representing the main resistant structural components of a masonry building. Starting from the evaluation of the incipient rocking acceleration of the system, the free and forced motions of the wall are examined. In the paper, according to the classical Housner’s approach, the energy dissipation occurring during the impact is modelled. Finally, a numerical application, considering a simple constant horizontal acceleration impulse of given duration has been carried out.

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Authors and Affiliations

  1. Department of Civil Engineering and Computer Science Engineering (DICII), University of Rome Tor Vergata, Via del Politecnico 1, 00133, Rome, Italy

    Mario Como, Fabio Di Carlo & Simona Coccia

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  1. Mario Como
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  2. Fabio Di Carlo
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  3. Simona Coccia
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Correspondence to Simona Coccia.

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Como, M., Di Carlo, F. & Coccia, S. Dynamic response of rocking cracked masonry walls. Meccanica 54, 381–398 (2019). https://doi.org/10.1007/s11012-019-00949-w

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