Enhancing mechanical properties of natural waste‐based composites for automobile and plastic industry

Motaleb, K. Z. M. Abdul; Repon, Md. Reazuddin; Pranta, Arnob Dhar; Milašius, Rimvydas

doi:10.1002/pc.28690

Polymer Composites

2024

DOI: 10.1002/pc.28690

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Enhancing mechanical properties of natural waste‐based composites for automobile and plastic industry

K. Z. M. Abdul Motaleb,

Md. Reazuddin Repon,

Arnob Dhar Pranta

et al.

Abstract: Natural fiber composites are a renewable and environmentally friendly alternative to conventional synthetic materials that combine the biodegradability and essential durability of natural fibers with adaptability. Improved adhesion between fibers and matrix can be accomplished by comparing surface treatments applied to sugarcane, water hyacinth, and banana plant wastes. This will allow us to produce composite materials that are more durable and sustainable. To study the mechanical and morphological characteris… Show more

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Cited by 7 publications

References 49 publications

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Eco‐sustainable printing of cellulosic polymeric material using bio‐colorants and bio‐crosslinkers

Ahmed,

Repon,

Pranta

et al. 2024

SPE Polymers

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A sustainable solution to lessen environmental damage, improve health and fulfill the increasing need for environmentally conscious goods might be for the textile industry to use eco‐friendly printing techniques and natural colors. Without the use of toxic metal‐based mordants, this research work set out to examine how natural thickeners, biomordants, and dyes interacted when printed on cotton knit fabric. Two natural dyes from natural resources leaves Jujube leaves (JL) and Eucalyptus bark (EB) were extracted in an aqueous medium. A printing paste was produced using different proportions of two bio‐mordants. For an eco‐friendly printing process, tamarind seeds, and Indian gooseberries were used that have been extracted using a Soxhlet apparatus at 80°C for 8 h. All but a handful of samples using natural binders showed outstanding fastness in the printed sample which was graded 4 or 5. The development of the dye‐fiber bond was indicated by the presence of an intense covalent bond between the dye and fiber molecules as indicated by FTIR. The CMC lab data and K/S value of the printed samples were also obtained satisfactorily with maximum RFL value 77.319 and K/s value 1.659. This method not only lessens the environmental impact of the sector but also supports a better and more ecologically sensitive manufacturing technique. Moreover, sustainable apparel, household textiles, technical fabrics, and environmentally friendly packaging can all benefit from eco‐friendly printing using bio‐colorants and bio‐crosslinkers.Highlights Eco‐friendly printing on cotton using jujube and eucalyptus dyes reduces environmental harm. Bio‐mordants from tamarind seeds and gooseberry effectively replace harmful metal‐based mordants. Printed samples show excellent fastness ratings of 4–5, proving the quality of eco‐friendly printing. FTIR analysis confirms strong covalent bonds between dye and fiber molecules. This method supports sustainability by using renewable, biodegradable resources in textile production.

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Eco‐sustainable printing of cellulosic polymeric material using bio‐colorants and bio‐crosslinkers

Ahmed,

Repon,

Pranta

et al. 2024

SPE Polymers

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Antimicrobial and antioxidant functionalization of cellulosic fabric via mushroom and neem oil treatment: A step toward sustainable textiles

Saha,

Ara,

Pranta

et al. 2024

Vinyl Additive Technology

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Nowadays, the demand for protective clothing for specific activities has been fueled by consumer's attitudes toward hygiene and their active lifestyles. The aim of the present work is focused on creating protective textiles that are safe for the environment. This study uses mushroom–neem oil and neem oil to test their antioxidant properties to make cotton fabric that resists bacterial growth. Pad dry cure is used to create antimicrobial fabric with mushroom–neem oil and neem oil with citric acid (1%) as a cross‐linking agent. The antibacterial activity against Escherichia coli and antioxidant activity by DPPH assay were assessed by applying mushroom–neem oil and neem oil separately to cotton knitted fabric at 120, 130, 140, and 150°C. FTIR and EDS were used to study the incorporation of mushroom–neem oil and neem oil on cotton fabric surfaces. Both the treated and untreated fabric surface morphology were examined using scanning electron microscopy. An increase in curing temperature was found to change the comfort characteristics of the treated fabric. The analysis also found that antimicrobials reduced thermal conductivity. Most importantly, increasing the curing temperature improved all comfort properties. Notably, fabric treated with mushroom neem oil is more comfortable than fabric treated with neem oil.Highlights Cotton fabrics with mushroom–neem and neem oil showed antibacterial activity. Neem oil‐treated fabrics had better antioxidant properties than mushroom–neem oil. Higher curing temperatures reduced thermal conductivity and improved comfort. Mushroom–neem oil samples have superior physical properties. Bioactive material treatments can reduce chemical and environmental impact.

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Addition of ammonium polyphosphate for simultaneous enhancement of flame retardancy, mechanical, and viscoelastic properties of PALF‐reinforced bio‐HDPE composite

Singh,

Rangappa

et al. 2024

Vinyl Additive Technology

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This work is focused on reducing the flammability of 25 wt.% pineapple leaf fiber (PALF)‐reinforced bio‐based high‐density polyethylene (bio‐HDPE) composites. Varying contents of ammonium polyphosphate (APP) up to 10 wt.%, have been incorporated as a flame retardant while its effects on mechanical and viscoelastic properties are also evaluated. The linear burning rate is reduced by up to 26% for 10% APP content in the horizontal burn test. The incorporation of APP also proved beneficial in arresting the dripping of the polymer matrix during the vertical burn test. Thermal analysis showed that the interaction between APP and natural fibers enhanced the residual char content by up to 9%. Furthermore, dynamic mechanical analysis revealed an increase in the damping factor (loss tangent) with APP addition. The findings recommend incorporating up to 5% APP in PALF/Bio‐HDPE composites as optimum. PALF‐reinforced Bio‐HDPE composite with improved flame retardancy, mechanical, and damping properties is achieved, offering an alternative to conventional composites used in automobile and construction industries.Highlights Flame‐retardant composites made from 25% PALF and 10% APP. 10% APP base composite showed a 26% reduced UL 94 horizontal burning rate. APP incorporation increases residual char content and prevents dripping also. APP enhances both the mechanical properties and damping factor of composites.

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Enhancing mechanical properties of natural waste‐based composites for automobile and plastic industry

Cited by 7 publications

References 49 publications

Eco‐sustainable printing of cellulosic polymeric material using bio‐colorants and bio‐crosslinkers

Eco‐sustainable printing of cellulosic polymeric material using bio‐colorants and bio‐crosslinkers

Antimicrobial and antioxidant functionalization of cellulosic fabric via mushroom and neem oil treatment: A step toward sustainable textiles

Addition of ammonium polyphosphate for simultaneous enhancement of flame retardancy, mechanical, and viscoelastic properties of PALF‐reinforced bio‐HDPE composite

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