4.7 Article

Effect of Thermal Exposure on Residual Properties of Wet Layup Carbon Fiber Reinforced Epoxy Composites

Journal

POLYMERS
Volume 14, Issue 14, Pages -

Publisher

MDPI
DOI: 10.3390/polym14142957

Keywords

polymer matrix composites; thermal exposure; residual characteristics; mechanical properties; deterioration

Funding

  1. Republic of South Korea and Naval Academy

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This paper investigates the residual mechanical properties and damage states of ambient cured wet layup carbon fiber reinforced epoxy composites exposed to elevated temperature regimes. The results show that high temperature conditions lead to the deterioration of resin characteristics and the bond between fibers and resin. This is a weakness in layered composites formed from unidirectional fabric architectures. Changes in failure modes are correlated through microscopy to damage progression at the fiber-matrix interface and resin levels. Differential scanning calorimetry is used to determine transitions in glass transition temperature, which indicate changes in damage mechanisms.
Ambient cured wet layup carbon fiber reinforced epoxy composites used extensively in the rehabilitation of infrastructure and in structural components can be exposed to elevated temperature regimes for extended periods of time of hours to a few days due to thermal excursions. These may be severe enough to cause a significant temperature rise without deep charring as through fires at a small distance and even high-temperature industrial processes. In such cases, it is critical to have information related to the post-event residual mechanical properties and damage states. In this paper, composites are subjected to a range of elevated temperatures up to 260 degrees C over periods of time up to 72 h. Exposure to elevated temperature regimes is noted to result in a competition between the mechanisms of post-cure that can increase the levels of mechanical characteristics, and the deterioration of the resin and the bond between the fibers and resin that can reduce them. Mechanical tests indicate that tensile and short beam shear properties are not affected negatively until the highest temperatures of exposure considered in this investigation. In contrast, all elevated temperature conditions cause deterioration in resin-dominated characteristics such as shear and flexure, emphasizing the weakness of this mode in layered composites formed from unidirectional fabric architectures due to resin deterioration. Transitions in failure modes are correlated through microscopy to damage progression both at the level of fiber-matrix interface integrity and through the bulk resin, especially at the inter-layer level. The changes in glass transition temperature determined through differential scanning calorimetry can be related to thresholds that indicate changes in the mechanisms of damage.

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