Abstract
For many decades, researchers have been working on finding innovative and sustainable solutions to address the enormous quantities of plastic waste that are produced every year which, after being collected, are transformed into energy, recycled, or sent to landfills. Giving a second life to plastic waste as a material to be incorporated, in the form of macro-fibres, into concrete, could be one such solution. The purpose of this study was to analyse the mechanical and physical behaviour of the hardened concrete reinforced with macro plastic fibres (RPFs) obtained from food packaging waste (FPW) discarded during the packaging phase. By varying the quantity of macro-fibres used, physical and mechanical properties such as compressive strength, modulus of elasticity, flexural strength, and toughness were evaluated. It was observed that, although the presence of macro plastic fibres reduced the mechanical resistance capacity compared to that of traditional concrete, their contribution proved to be of some importance in terms of toughness, bringing an improvement in the post-crack resistance of the composite material. This innovative mixture provides a further impulse to the circular economy.
Highlights
IntroductionPublisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations
This study addressed the use of fibre from multilayer recycled plastic from food packaging plastic waste for reinforcement in concrete
The presence of plastic fibres inside the matrix increased both the ability of the concrete to resist the advancement of cracks, and its ability to deform plastically before breaking, giving the concrete matrix a certain residual tensile strength during the post-crack phase; The increase in toughness index with an increase in the percentage of recycled plastic fibres confirmed their stitching action inside the cement matrix, which is fundamentally dependent on the type of fibre and its quantity; The toughness index presented by the concrete with commercial fibres was greater than that with the same dosage of reinforced with macro plastic fibres (RPFs), due to its rougher surface and greater adherence to the cementitious matrix
Summary
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. Concrete is a widely used construction material worldwide due to its great availability of raw materials and low cost [1]. Concrete has good compressive behaviour, it does not respond adequately under high tensile stresses. Steel reinforcements have usually been used to improve its tensile and flexural strengths [2,3,4]. In recent years, natural (mainly vegetable), steel, glass, and synthetic fibres have been used [1]. Synthetic fibres help to prevent plastic shrinkage cracks in fresh concrete [5], and improve concrete performance after cracking [6]
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