Hygrothermal Aging of Pultruded Fiber-Polymer Composite with Predictions for Design Service Lives

Behrouz Zafari, Toby Mottram, Phil Purnell, Sotirios Grammatikos, Mark Evernden

Research output: Contribution to journalArticlepeer-review

Abstract

This study presents the findings from an in-depth study into the influence of hygrothermal aging on the material properties of a pultruded flat sheet composite composed of electrical-corrosion resistant (E-CR) glass fibers and an unsaturated polyester-based matrix. By discussing the impact of hygrothermal aging across 10 material properties, assessing the suitability of test procedures, and presenting a framework, this study evaluates the suitability of the experimental test results for use with two service life models. This study offers an open and critical evaluation of the currently accepted methods. Across 102 batches, which consist of 476 coupons, immersed in distilled water at 25°C, 40°C, 60°C, and 80°C, with exposure times of 28, 56, 112 and 224 days, the changes in tensile, compressive, in-plane shear, and pin-bearing properties are evaluated alongside mass changes. An understanding is discussed of the relationships that were obtained for moisture uptake and for material property retentions over time, which identified evidence termed nonconsistent fluctuating trends. This study highlights the possibility of misleading results that arise from the impact of the forced drying of coupons before coupon testing. For longitudinal tensile properties, a direct comparison is made between coupons termed Dried and Wet (to represent field conditions) coupons, which indicates the need for careful consideration in characterization work for the determination of the long-term material properties of composites. With the development of a framework for the evaluation of two service life prediction models, the quality of 11 sets of experimental results is evaluated. Using the four most reliable sets of predictions, the acceleration factors and service lifetimes are reported. From the evaluation of the experimental findings, testing methodologies, and the application of service life prediction techniques, this study puts forward an understanding of how to execute experimental programs with accelerated aging with the aim of obtaining meaningful test results for the long-term material properties of fiber–polymer composites.
Original languageEnglish
Article number04024088
JournalJournal of Composites for Construction
Volume29
Issue number1
Early online date20 Nov 2024
DOIs
Publication statusE-pub ahead of print - 20 Nov 2024

Data Availability Statement

All data, models, and codes generated or used during the study appear in the published article.

Funding

This work was conducted as part of the research program with the EPSRC-funded project DURACOMP (EP/K026925/1). The authors acknowledge that the test results presented could not have been generated without professional service support from the engineering technicians within the School of Engineering, The University of Warwick.

FundersFunder number
University of Warwick
EPSRC-fundedEP/K026925/1

    Keywords

    • Arrhenius relationship
    • Hygrothermal aging
    • Material properties
    • Moisture kinetics
    • Pultruded fiber-polymer composites
    • Service life prediction

    ASJC Scopus subject areas

    • Ceramics and Composites
    • Civil and Structural Engineering
    • Building and Construction
    • Mechanics of Materials
    • Mechanical Engineering

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