Comparing tensile, bending and interlaminar shear performance of GFRP composites fabricated using recovered and virgin glass fibers: Optimization of the microwave assisted chemical recycling technique

Abstract

AbstractGlobal glass fiber reinforced plastic (GFRP) recycling provides an effective solution to the end‐of‐life wastes and industrial scrap, by which we can construct a closed‐loop system that reduces environmental impact while increasing sustainability. This study reports the tensile, flexural and shear properties of GFRP composites fabricated from reclaimed fibers from the waste GFRP. A hybrid recycling technique that is, microwave assisted chemical recycling has been used for recovering the glass fiber fabrics. The quantity of solvents (a mixture of 30% H2O2 and CH3COOH in 1:1 ratio) required (in mL/g) for degrading the polymer is optimized with respect to the amount of microwave irradiation time. The microwave irradiation duration was varied at constant power of 900 W for optimizing the quantity of solvent used. SEM analysis of both virgin and reclaimed fiber surfaces indicate an almost complete degradation of polymer from the waste composites. RGFE laminates, fabricated from reclaimed glass fiber fabrics, exhibited marginally higher tensile strength (7%–8%) and significant lower tensile modulus (~29%). On the other hand, RGFE composites demonstrated a greater strain to failure of ~44% compared to VGFE composites during tensile testing, consequently leading to a subsequent increase in tensile toughness by ~28%. The ILSS values obtained from SBS tests and storage modulus and loss factor curves from DMA tests showed almost similar values. SEM studies revealed the probable causes of failures of the samples for tensile and flexural tests.Highlights Hybrid recycling technique using microwave irradiation is optimized. Amount of solvent used is optimized by varying the irradiation times. Tensile and flexural strengths exhibit a marginal increase of 7%–8%. Significant rise in strain at failure by 44% and tensile toughness by 28%. Fractography studies have been performed for analyzing failures.