Artificial Ageing of Mortar Prisms Reinforced through Steel, Glass and Organic Fibres

Daniela Sinicropi; Elena Perria; Stefano Galassi; Michele Paradiso; Antonio Borri

doi:10.4028/www.scientific.net/KEM.624.542

Paper Titles

Laboratory Tests on Masonry Vaults with Backfill Strengthened at the Extrados
p.510

Is it Possible to Repair Detached Composites Effectively after Failure of Masonry Strengthening
p.518

Effect of the Presence of Mortar Joints in the Bond Behaviour of Tuff Masonry Elements
p.526

Application of Acoustic Emission Technique for Bond Characterization in FRP-Masonry Systems
p.534

Artificial Ageing of Mortar Prisms Reinforced through Steel, Glass and Organic Fibres
p.542

Confinement Effectiveness in Eccentrically Loaded Masonry Columns Strengthened by Fiber Reinforced Cementitious Matrix (FRCM) Jackets
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Experimental Study on Masonry Panels Strengthened by GFRP: The Role of Inclination between Mortar Joints and GFRP Sheets
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Analytical Modeling of Composite-to-Masonry Prisms Bond
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The Effects of Mortar Joints on the Efficiency of Anchored CFRP Sheets Reinforcements of Brick-Masonry
p.575

HomeKey Engineering MaterialsKey Engineering Materials Vol. 624Artificial Ageing of Mortar Prisms Reinforced...

Artificial Ageing of Mortar Prisms Reinforced through Steel, Glass and Organic Fibres

Abstract:

The process of ageing in construction materials is natural and expected, and the technologies to contrast and reverse any damage due to the passing of time are well known in the field of civil engineering. This is true for structures themselves as well as the reinforcement technologies such as, for example, fiber reinforcements (FRP or FRCM). In fact, studies [1,5] have brought attention early on to severe mechanical characteristic reduction caused by the ageing process of specific resin matrices used in composite reinforcement materials, or, even more perilous, their exposure to extreme conditions of temperature. In this project, the authors have set up an experimental campaign on mortar prisms reinforced with different types of fibers and subjected to cycles of ageing through heat exposure. This paper presents the results obtained by three point flexural testing performed at the Testing Laboratory of the University of Florence, comparing the results of the reinforced and aged prisms with those of the non-aged and non reinforced prisms, providing a precedent on how ageing influences the structural behavior of fibers and mortar.

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Periodical:

Key Engineering Materials (Volume 624)

Pages:

542-550

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.624.542

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Online since:

September 2014

Authors:

Daniela Sinicropi*, Elena Perria, Stefano Galassi, Michele Paradiso, Antonio Borri

Keywords:

Artificial Ageing, Experimental Testing, Mortar Prisms

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