Mechanical and Mineralogical Characterization of Mortar in Masonry Buildings Damaged by the 20-29th May Earthquake in Emilia

Elisa Galli; Marco Savoia; Camilla Colla; Daniele Ferretti

doi:10.4028/www.scientific.net/KEM.624.379

Paper Titles

Tensile Behaviour and Durability of Mortar-Based Strengthening Systems with Glass-Aramid Textiles
p.346

Conservation of the Structure and Materials of Historic Masonry Walls
p.354

Diagonal Tensile Strength of AAC Blocks Masonry with Thin Joints Superficially Strengthened by Reinforced Using GFRP Net Plastering
p.363

Experimental Analysis of the Bond Behavior of Glass, Carbon, and Steel FRCM Composites
p.371

Mechanical and Mineralogical Characterization of Mortar in Masonry Buildings Damaged by the 20-29^th May Earthquake in Emilia
p.379

Recent Developments in F.E. Analysis of FRP Reinforced Masonry Vaults: Case Studies in Italy
p.389

Experimental Study of Brick Masonry Walls Strengthened with Textile Reinforced Mortar
p.397

A Force-Based Equivalent Frame Element for Push-Over Analysis of Masonry Structures
p.405

Ageing Problems of GFRP Grids Used for Masonry Reinforcement
p.413

HomeKey Engineering MaterialsKey Engineering Materials Vol. 624Mechanical and Mineralogical Characterization of...

Mechanical and Mineralogical Characterization of Mortar in Masonry Buildings Damaged by the 20-29^th May Earthquake in Emilia

Abstract:

The aim of the work is to characterize mechanical and chemical properties of the mortar, and thus the masonry, of historical buildings damaged by the Emilia May 20-29^th 2012 earthquakes. The attention was focused on historical strategic buildings, located in Modena district. The experimental campaign here reported was carried out for each building through four steps: first, a mechanical characterization of masonry was performed in situ using non-destructive and semi-destructive methods (step 1); then, some materials were collected in order to obtain standard specimens of mortar joint and brick (step 2). In laboratory, those samples were properly prepared for testing (step 3) with compression and flexural test setups; finally, a limited number of those mortar samples were tested in order to obtain their chemical properties (step 4). The in-situ and laboratory test results were separately elaborated for mortar and brick, to characterize the single masonry components. The results were then used to estimate the characteristic masonry parameters. Criteria to obtain the masonry behavior were reviewed in order to give the average masonry parameters. The characteristic and average values of compression strength were compared with ranges provided in the codes for the same masonry typology.

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Periodical:

Key Engineering Materials (Volume 624)

Pages:

379-386

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.624.379

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Online since:

September 2014

Authors:

Elisa Galli*, Marco Savoia, Camilla Colla, Daniele Ferretti

Keywords:

Characterization, Earthquake, Experimental Testing, Masonry, Mortar, Strength

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References

[1] E. Sassoni, C. Mazzotti, The use of small diameter cores for assessing the compressive strength of clay brick masonries, Journal of Cultural Heritage 14S (2013) e95-e101.