Fiber Reinforced Polymers in Civil Engineering: Durability Issues

Mariaenrica Frigione

doi:10.4028/www.scientific.net/AMR.1129.283

Paper Titles

Improvement of the Adhesion between Epoxy-Based Surface Coating and Hydrophobic Impregnated Concrete
p.256

Influence of Acrylic Emulsion on Polymer-Cement Waterproof Coating
p.263

Influence of Film Thickness and Ambient Temperature to the Protective Performance of Surface Coating Material
p.270

New Applications for Polymer Overlays
p.277

Fiber Reinforced Polymers in Civil Engineering: Durability Issues
p.283

Advanced Active Prestressed CFRP in RCC Structures
p.290

Serviceability Behavior of Reinforcement Concrete Beams with Polypropylene and Steel Fibers
p.298

Apparent vs. True Bond Strength of Steel and PC with Nanoalumina
p.307

Comparison of Ordinary Pores with Internal Cured Pores Produced by Superabsorbent Polymers
p.315

HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 1129Fiber Reinforced Polymers in Civil Engineering:...

Fiber Reinforced Polymers in Civil Engineering: Durability Issues

Abstract:

In the last decades, the use of fiber reinforced polymers (FRP) composites to repair and/or upgrade existing buildings or infrastructure systems proved to be an effective solution, being able to overcome some of the drawbacks experienced with traditional interventions. The knowledge of durability behavior of polymer composite materials in terms of their degradation/aging causes and mechanisms is a critical issue for a safe and advantageous implementation of FRP. The durability of FRP employed in civil infrastructure applications mainly depends on the durability of any single component and on the environment (service conditions) in which the system operates. The components of FRP are: polymeric resins (more frequently thermosetting resins cured in service, i.e. at ambient temperature), fibers and the interface between them. Referring to the resins, heavy concerns arise from the behavior of “Cold-cured” thermosetting resins, often epoxy, used as matrices to manufacture (through wet layup technique) and adhesives to apply, also precured, FRP. The experimental studies present in current literature on the effect of environmental agents on the properties of FRP highlight the crucial role of the adhesive/matrix on the behavior of the whole system. Many other parameters (i.e. direction and disposition of fibers, direction of load application) are involved in the assessment of the durability of FRP. However, in the durability studies of FRP and their components, a lack of specific standards for such materials is recognized. In addition, the results of durability studies do not always agree, possibly due to different curing/conditioning conditions employed. The aim of this work is to critically illustrate the durability studies carried out on FRP for civil engineering applications and appeared in current literature, highlighting the issues that are not yet assessed and addressed.

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Periodical:

Advanced Materials Research (Volume 1129)

Pages:

283-289

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.1129.283

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Online since:

November 2015

Authors:

Mariaenrica Frigione*

Keywords:

Cold-Curing Epoxy, Durability, Long-Term Performance, Water Effects

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