Swinburne
Browse
- No file added yet -

Thermo-mechanical characterization of VGCF- modified adhesive for bond between CFRP and concrete subjected to combined effect of temperature and humidity

Download (332 kB)
conference contribution
posted on 2024-07-26, 14:54 authored by Rawaa Al-Safy, Riadh Al-MahaidiRiadh Al-Mahaidi, George P. Simon, Jana Habsuda
Adhesives are employed in external strengthening of bond concrete structures by CFRP composite elements. Carbon-based composites are currently the most common type used to increase the strength of concrete members. The application of CF fabric to concrete members involves the use of a compatible bonding agent, and it is the modification of such bonding agents that is investigated in this paper. The investigation involves examining the effects of adding different concentrations of vapour-grown carbon nanofibres (VGCF) (0.5 wt%, 1 wt%, 1.5 wt% and 2 wt%) on the thermal and mechanical properties of the bonding agent. The effect of modification on the glass transition temperature and heat flow of the modified adhesive was explored using DSC technique. It was found that Tg reduces slightly or remains the same with the addition of VGCF to Part A of the adhesive and the highest reduction in Tg was found when Part A was reinforced with 2 wt % VGCF. Agglomaration of the fibres was observed when VGCF was introduced into MBrace® Saturant epoxy adhesive using the speed mixer and a random orientation for the fibres was noted within the epoxy matrix. Peeling-off of CF fabric was the common failure mode as the loaded CFRP/concrete system was subjected to the combined effect of temperature and humidity after short periods of exposure to such severe conditions.

History

Available versions

PDF (Published version)

ISBN

9780987593016

ISSN

1369-4332

Journal title

4th Asia-Pacific Conference on FRP in Structures (APFIS 2013), Melbourne, Australia, 11-13 December 2013

Conference name

4th Asia-Pacific Conference on FRP in Structures APFIS 2013, Melbourne, Australia, 11-13 December 2013

Volume

17

Issue

12

Pagination

1817-1823

Publisher

Swinburne University of Technology

Copyright statement

Copyright © 2013 International Institute for FRP in Construction. The published version is reproduced with the permission of the copyright owner.

Language

eng

Usage metrics

    Publications

    Categories

    No categories selected

    Keywords

    Exports

    RefWorks
    BibTeX
    Ref. manager
    Endnote
    DataCite
    NLM
    DC