Reversible and irreversible effects on the epoxy GFRP fiber-matrix interphase due to hydrothermal aging

IF 5.3 Q2 MATERIALS SCIENCE, COMPOSITES

Composites Part C Open Access Pub Date : 2023-10-01 DOI:10.1016/j.jcomc.2023.100395

Andrey E. Krauklis , Olesja Starkova , Dennis Gibhardt , Gerhard Kalinka , Hani Amir Aouissi , Juris Burlakovs , Alisa Sabalina , Bodo Fiedler

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引用次数: 1

Abstract

Epoxy R-Glass Fiber-Reinforced Polymer (GFRP) composite plates were hydrothermally aged at 60 °C for 23, 75, and 133 days. The water content reached 0.97 wt%, 1.45 wt% and 1.63 wt%, respectively. The studied GFRP matrix was inert to hydrolysis or chain scission, allowing for investigation of irreversible changes in the fiber-matrix interphase due to hydrothermal aging upon re-drying. During each period, a subset of the specimens was removed from the water bath and dried in a chamber. The weight loss upon drying was explained with epoxy leaching (impurities), sizing-rich interphase hydrolysis, glass fiber surface hydrolysis, accumulated degradation products escaping, and water changing state from bound to free. The influence of hydrothermal aging on the fiber-matrix interfacial properties was investigated. Lower interfacial strength of hydrothermally aged (wet) samples was attributed to plasticization of the epoxy, plasticization and degradation of the sizing-rich interphase (including formation of hydrolytic flaws), and hydrolytic degradation of the glass fiber surface. The kinetics of epoxy-compatible epoxysilane W2020 sizing-rich interphase hydrolysis provided an estimate of ca. 1.49%, 4.80%, and 8.49% of the total composite interphase degraded after 23, 75, and 133 days, respectively. At these conditions, the interface lost 39%, 48%, and 51% of its strength. Upon re-drying the specimens, a significant part of the interfacial strength was regained. Furthermore, an upward trend was observed, being 13%, 10% and 3% strength, respectively; thus, indicating a possibility of partial recovery of properties.

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水热老化对环氧GFRP纤维基体界面的可逆和不可逆影响

环氧r-玻璃纤维增强聚合物(GFRP)复合板在60°C下水热老化23、75和133天。其含水量分别达到0.97 wt%、1.45 wt%和1.63 wt%。所研究的GFRP基体对水解或断链是惰性的，允许研究由于水热老化在再干燥时纤维-基体界面相的不可逆变化。在每一阶段，一部分标本从水浴中取出并在室内干燥。从环氧树脂浸出(杂质)、富施胶界面水解、玻璃纤维表面水解、累积降解产物逸出、水由结合状态变为游离状态等方面解释了干燥失重的原因。研究了水热老化对纤维-基体界面性能的影响。水热老化(湿)样品较低的界面强度归因于环氧树脂的塑化、富施胶界面的塑化和降解(包括水解缺陷的形成)以及玻璃纤维表面的水解降解。在23、75和133天后，富含施胶剂的环氧基硅烷W2020互相水解的动力学估计分别为1.49%、4.80%和8.49%的复合互相降解。在这些条件下，界面强度分别下降39%、48%和51%。再干燥后，界面强度恢复了很大一部分。此外，还观察到上升趋势，强度分别为13%、10%和3%;因此，表明有可能部分恢复财产。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Composites Part C Open Access Engineering-Mechanical Engineering

CiteScore

8.60

自引率

2.40%

发文量

审稿时长

55 days