Moisture Absorption Characteristics and Subsequent Mechanical Property Loss of Enset–PLA Composites

Abdela, Abebayehu; Vandaele, Maxim; Haenen, Sam; Buffel, Bart; Sirahbizu, Belete; Desplentere, Frederik

doi:10.3390/jcs7090382

J. Compos. Sci.

2023

DOI: 10.3390/jcs7090382

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Moisture Absorption Characteristics and Subsequent Mechanical Property Loss of Enset–PLA Composites

Abebayehu Abdela,

Maxim Vandaele,

Sam Haenen

et al.

Abstract: One of the drawbacks of natural fibers and their composites is their inherent hydrophilic nature. The effect of moisture on the mechanical properties of composites is irrefutable. This study deals with the hygroscopic characteristics of enset–PLA composites and their effect on the mechanical properties of the composites. To do this, injection-molded composite specimens with different fiber volume fractions, plasticizer ratios, fiber lengths, and fiber ages were considered. The specimens were exposed to distill… Show more

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2024

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Cited by 8 publications

References 41 publications

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The influence of water absorption on the mechanical performance of 3D‐printed sandwich composite structures made from PLA‐based materials under quasi‐static loading conditions

Ainin,

Azaman,

Abdul Majid

et al. 2024

Polymer Composites

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Abstract3D printing technology has transformed the production of complex sandwich composite structures and offers exceptional control over material selection. PLA‐based composites are favored for load‐bearing applications due to their renewability and durable mechanical properties. However, their interaction with water poses a major challenge as moisture can severely affect their performance. This study investigates the effects of water absorption on the mechanical properties, energy absorption, and failure modes of 3D‐printed sandwich composite structures made of PLA‐based materials (PLA, PLA–Carbon, and PLA–Wood) under quasi‐static loads such as flatwise, in‐plane, and flexural tests. The results show that PLA–Wood has the highest water absorption among the composites due to its hydrophilicity, resulting in a significant reduction in compressive strength and Young's modulus by 19 and 9%, respectively, in flatwise tests, due to severe degradation. In contrast, PLA–Carbon shows superior energy absorption with values of 277.91, 10.74, and 1.73 J in flatwise, in‐plane and flexural tests, respectively, compared to 163.83, 2.47, and 1.17 J for PLA–Wood. This difference results from the ability of PLA–Carbon to deform in a controlled deformation, whereas PLA–Wood is susceptible to severe structural deformation. These results emphasize the durability of PLA‐based composites for load‐bearing applications, especially in moisture‐prone environments.Highlights Quasi‐static response on 3D‐printed PLA composites under water exposure. PLA–Wood has a higher water absorption because of its hydrophilic nature. The hydrophobicity of PLA–Carbon leads to remarkable strength and stiffness. PLA–Carbon has great energy absorption, which enhances its retained ductility. The failure modes are dependent on the PLA composite materials against water.

show abstract

The influence of water absorption on the mechanical performance of 3D‐printed sandwich composite structures made from PLA‐based materials under quasi‐static loading conditions

Ainin,

Azaman,

Abdul Majid

et al. 2024

Polymer Composites

View full text Add to dashboard Cite

show abstract

Development and optimization of sustainable and functional food packaging using false banana (Enset) fiber and zinc-oxide (ZnO) nanoparticle-reinforced polylactic acid (PLA) biocomposites: A case of Injera preservation

Dejene,

Gudayu,

Abtew

2024

International Journal of Biological Macromolecules

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Empirical and statistical investigation of injection molded Enset–PLA biocomposites’ characteristics in response to impact loading

Gelgelu,

Buffel,

Sirahbizu

et al. 2024

Results in Engineering

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Moisture Absorption Characteristics and Subsequent Mechanical Property Loss of Enset–PLA Composites

Cited by 8 publications

References 41 publications

The influence of water absorption on the mechanical performance of 3D‐printed sandwich composite structures made from PLA‐based materials under quasi‐static loading conditions

The influence of water absorption on the mechanical performance of 3D‐printed sandwich composite structures made from PLA‐based materials under quasi‐static loading conditions

Development and optimization of sustainable and functional food packaging using false banana (Enset) fiber and zinc-oxide (ZnO) nanoparticle-reinforced polylactic acid (PLA) biocomposites: A case of Injera preservation

Empirical and statistical investigation of injection molded Enset–PLA biocomposites’ characteristics in response to impact loading

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