# A Discrete Macro-Element Method (DMEM) for the nonlinear structural   assessment of masonry arches

**Authors:** F. Cannizzaro, B. Pant\`o, S. Caddemi, I. Cali\`o

arXiv: 1907.11759 · 2019-07-30

## TL;DR

This paper introduces a novel Discrete Macro-Element Method (DMEM) for accurately predicting the nonlinear structural response of masonry arches, capturing key mechanisms like rocking and sliding that traditional models often miss.

## Contribution

The paper presents a new macro-element based approach that models masonry arches with a single degree of freedom per element, improving nonlinear response predictions.

## Key findings

- Successfully predicts nonlinear behavior of masonry arches
- Validates the method with experimental and numerical results
- Captures collapse mechanisms like rocking and sliding

## Abstract

The structural response of masonry arches is strongly dominated by the arch geometry, the stone block dimensions and the interaction with backfill material or surrounding walls. Due to their intrinsic discontinuous nature, the nonlinear structural response of these key historical structures can be efficiently modelled in the context of discrete element approaches. Smeared crack finite elements models, based on the assumption of homogenised media and spread plasticity, fail to rigorously predict the actual collapse behaviour of such structures, that are generally governed by rocking and sliding mechanisms along mortar joints between stone blocks. In this paper a new Discrete Macro-Element Method (DMEM) for predicting the nonlinear structural behaviour of masonry arches is proposed. The method is based on a macro-element discretization in which each plane element interacts with the adjacent elements through zero-thickness interfaces and whose internal deformability is related to a single degree of freedom only. Both experimental and numerical validations show the capability of the proposed approach to be applied for the prediction of the non-linear response of masonry arch structures under different loading conditions.

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Source: https://tomesphere.com/paper/1907.11759