Abstract
This paper presents a framework for the three-dimensional structural analysis of full-scale, geometrically irregular discontinuum structures such as rubble masonry, directly from geospatial data. A convex decomposition algorithm is adopted, whereby a watertight mesh is subdivided into so-called voronoi blocks which approximate the anisotropic nature of the rubble masonry for structural analysis. The proposed “Voronoi4DEM” framework was implemented to assess the structural stability of the southwest leaning tower of Caerphilly Castle in Wales, UK. Simulations were performed with the three-dimensional computational software 3DEC, based on the Discrete Element Method (DEM) of analysis whilst each voronoi block of the rubble masonry was represented as a rigid, distinct block while mortar joints were modelled as zero thickness interfaces which can open and close depending on the magnitude and direction of the stresses applied to them. The innovation of this framework lies in the specific geometric strategy which approximates the random nature of discontinuous materials at a block-based level (such as rubble) with sufficient accuracy, whilst vastly reducing computational times. Consequently, the approach can simulate the highly complex behaviour of rubble masonry structures with a high degree of efficiency, geometric accuracy, and automation. It is anticipated that the methodology proposed here to enable unprecedented high-level numerical modelling (block-based numerical modelling) of full-scale rubble masonry structures with, until now, unemployed techniques such as the DEM.
Original language | English |
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Journal | COMPDYN Proceedings |
Publication status | Published - 2023 |
Event | 9th ECCOMAS Thematic Conference on Computational Methods in Structural Dynamics and Earthquake Engineering, COMPDYN 2023 - Athens, Greece Duration: 12 Jun 2023 → 14 Jun 2023 |
ASJC Scopus subject areas
- Computers in Earth Sciences
- Geotechnical Engineering and Engineering Geology
- Computational Mathematics
- Civil and Structural Engineering
Keywords
- block-based numerical modelling
- Discrete Element Method (DEM)
- mesh
- Point cloud
- rubble masonry
- structure-from-motion photogrammetry
- terrestrial laser scanning