Prediction of masonry compressive behaviour using a damage mechanics inspired modelling method

•Analytical model requires only constituents properties as input.•Time and cost effective computational model to predict the masonry strength.•Prediction of strength close to experimental data conservatively.•Good comparison with National Masonry Standards (AS3700-2011 and Eurocode 6).•Sensitive to...

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Bibliographic Details
Published in:Construction & building materials 2016-04, Vol.109, p.128-138
Main Authors: Zahra, Tatheer, Dhanasekar, Manicka
Format: Article
Language:English
Subjects:
Analytical modelling
Damage
Limiting surfaces
Masonry compressive strength
Progressive stiffening characteristics
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Summary:•Analytical model requires only constituents properties as input.•Time and cost effective computational model to predict the masonry strength.•Prediction of strength close to experimental data conservatively.•Good comparison with National Masonry Standards (AS3700-2011 and Eurocode 6).•Sensitive to unit strength, mortar strength and mortar joint thickness. Masonry under compression is affected by the properties of its constituents and their interfaces. In spite of extensive investigations of the behaviour of masonry under compression, the information in the literature cannot be regarded as comprehensive due to ongoing inventions of new generation products – for example, polymer modified thin layer mortared masonry and drystack masonry. As comprehensive experimental studies are very expensive, an analytical model inspired by damage mechanics is developed and applied to the prediction of the compressive behaviour of masonry in this paper. The model incorporates a parabolic progressively softening stress–strain curve for the units and a progressively stiffening stress–strain curve until a threshold strain for the combined mortar and the unit-mortar interfaces is reached. The model simulates the mutual constraints imposed by each of these constituents through their respective tensile and compressive behaviour and volumetric changes. The advantage of the model is that it requires only the properties of the constituents and considers masonry as a continuum and computes the average properties of the composite masonry prisms/wallettes; it does not require discretisation of prism or wallette similar to the finite element methods. The capability of the model in capturing the phenomenological behaviour of masonry with appropriate elastic response, stiffness degradation and post peak softening is presented through numerical examples. The fitting of the experimental data to the model parameters is demonstrated through calibration of some selected test data on units and mortar from the literature; the calibrated model is shown to predict the responses of the experimentally determined masonry built using the corresponding units and mortar quite well. Through a series of sensitivity studies, the model is also shown to predict the masonry strength appropriately for changes to the properties of the units and mortar, the mortar joint thickness and the ratio of the height of unit to mortar joint thickness. The unit strength is shown to affect the masonry strength significantl
ISSN:0950-0618
1879-0526
DOI:10.1016/j.conbuildmat.2016.01.048