Thermal and mechanical properties of high-performance polyester nanobiocomposites reinforced with pre-treated sunn hemp fiber for automotive applications

The objective of this study is to create high-performance nano biocomposites by utilizing unsaturated polyester resin (PE) reinforced with pre-treated short (2 cm) lengthened sunn hemp (SH) fibers and by incorporating 5 % nanoclay (hydrophilic bentonite) through the compression molding technique. Th...

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Veröffentlicht in:	International journal of biological macromolecules 2024-11, Vol.280 (Pt 2), p.135591, Article 135591
Hauptverfasser:	Arumugam, Gandarvakottai Senthilkumar, Arumugam, Chinnappa, Damodharan, Kannan, Sathish Kumar, R., Gummadi, Sathyanarayana N., Muthusamy, Sarojadevi
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Sprache:	eng
Schlagworte:	Automobiles bentonite Biocomposites Cannabis - chemistry Chemical treatment Clay - chemistry Compression molding Crotalaria juncea hydrophilicity industry Mechanical Phenomena modulus of rupture Nanoclay nanoclays Nanocomposites - chemistry polyesters Polyesters - chemistry separation Sunn hemp fiber Temperature Tensile Strength Unsaturated polyester water uptake
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container_issue	Pt 2
container_start_page	135591
container_title	International journal of biological macromolecules
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creator	Arumugam, Gandarvakottai Senthilkumar Arumugam, Chinnappa Damodharan, Kannan Sathish Kumar, R. Gummadi, Sathyanarayana N. Muthusamy, Sarojadevi
description	The objective of this study is to create high-performance nano biocomposites by utilizing unsaturated polyester resin (PE) reinforced with pre-treated short (2 cm) lengthened sunn hemp (SH) fibers and by incorporating 5 % nanoclay (hydrophilic bentonite) through the compression molding technique. The addition of 5 % nanoclay to the biocomposite significantly increased the flexural strength by approximately 165 % for H2O2-treated SH fiber and 148 % for KMnO4-treated SH fiber, when compared to untreated fibers. This enhancement was achieved through phase separation, intercalation, and exfoliation between the SH fibers, polyester resin (PE), and 5 % nanoclay. In particular, the H2O2-treated SH fiber nanobiocomposite exhibited a 43 % higher flexural strength compared to its corresponding biocomposite. The incorporation of nanoclay significantly decreased the water absorption of the bio-composites from 11.86 % in the untreated samples to a minimum of 2.76 % in the H2O2-treated SH/PE nanobiocomposite. The study suggests that short SH fiber/PE/nanoclay nanobiocomposites could be used as effective alternatives to synthetic composites in various applications, including the aerospace industry, household products, and automotive interior components such as side panels, seat frames, and central consoles. Additionally, they could be utilized in exterior parts like door panels and dashboards. [Display omitted]
doi_str_mv	10.1016/j.ijbiomac.2024.135591
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The addition of 5 % nanoclay to the biocomposite significantly increased the flexural strength by approximately 165 % for H2O2-treated SH fiber and 148 % for KMnO4-treated SH fiber, when compared to untreated fibers. This enhancement was achieved through phase separation, intercalation, and exfoliation between the SH fibers, polyester resin (PE), and 5 % nanoclay. In particular, the H2O2-treated SH fiber nanobiocomposite exhibited a 43 % higher flexural strength compared to its corresponding biocomposite. The incorporation of nanoclay significantly decreased the water absorption of the bio-composites from 11.86 % in the untreated samples to a minimum of 2.76 % in the H2O2-treated SH/PE nanobiocomposite. The study suggests that short SH fiber/PE/nanoclay nanobiocomposites could be used as effective alternatives to synthetic composites in various applications, including the aerospace industry, household products, and automotive interior components such as side panels, seat frames, and central consoles. Additionally, they could be utilized in exterior parts like door panels and dashboards. [Display omitted]</description><identifier>ISSN: 0141-8130</identifier><identifier>ISSN: 1879-0003</identifier><identifier>EISSN: 1879-0003</identifier><identifier>DOI: 10.1016/j.ijbiomac.2024.135591</identifier><identifier>PMID: 39304055</identifier><language>eng</language><publisher>Netherlands: Elsevier B.V</publisher><subject>Automobiles ; bentonite ; Biocomposites ; Cannabis - chemistry ; Chemical treatment ; Clay - chemistry ; Compression molding ; Crotalaria juncea ; hydrophilicity ; industry ; Mechanical Phenomena ; modulus of rupture ; Nanoclay ; nanoclays ; Nanocomposites - chemistry ; polyesters ; Polyesters - chemistry ; separation ; Sunn hemp fiber ; Temperature ; Tensile Strength ; Unsaturated polyester ; water uptake</subject><ispartof>International journal of biological macromolecules, 2024-11, Vol.280 (Pt 2), p.135591, Article 135591</ispartof><rights>2024 Elsevier B.V.</rights><rights>Copyright © 2024 Elsevier B.V. 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The addition of 5 % nanoclay to the biocomposite significantly increased the flexural strength by approximately 165 % for H2O2-treated SH fiber and 148 % for KMnO4-treated SH fiber, when compared to untreated fibers. This enhancement was achieved through phase separation, intercalation, and exfoliation between the SH fibers, polyester resin (PE), and 5 % nanoclay. In particular, the H2O2-treated SH fiber nanobiocomposite exhibited a 43 % higher flexural strength compared to its corresponding biocomposite. The incorporation of nanoclay significantly decreased the water absorption of the bio-composites from 11.86 % in the untreated samples to a minimum of 2.76 % in the H2O2-treated SH/PE nanobiocomposite. The study suggests that short SH fiber/PE/nanoclay nanobiocomposites could be used as effective alternatives to synthetic composites in various applications, including the aerospace industry, household products, and automotive interior components such as side panels, seat frames, and central consoles. Additionally, they could be utilized in exterior parts like door panels and dashboards. [Display omitted]</description><subject>Automobiles</subject><subject>bentonite</subject><subject>Biocomposites</subject><subject>Cannabis - chemistry</subject><subject>Chemical treatment</subject><subject>Clay - chemistry</subject><subject>Compression molding</subject><subject>Crotalaria juncea</subject><subject>hydrophilicity</subject><subject>industry</subject><subject>Mechanical Phenomena</subject><subject>modulus of rupture</subject><subject>Nanoclay</subject><subject>nanoclays</subject><subject>Nanocomposites - chemistry</subject><subject>polyesters</subject><subject>Polyesters - chemistry</subject><subject>separation</subject><subject>Sunn hemp fiber</subject><subject>Temperature</subject><subject>Tensile Strength</subject><subject>Unsaturated polyester</subject><subject>water uptake</subject><issn>0141-8130</issn><issn>1879-0003</issn><issn>1879-0003</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2024</creationdate><recordtype>article</recordtype><sourceid>EIF</sourceid><recordid>eNqNkcFu3CAQhlHUKtmkeYWIYy_egjE2vrWKmrZSpF72jjCMY1Y2uIBT5VH6tp1ok16bE5rR988_w0_IDWd7znj76bj3x8HHxdh9zepmz4WUPT8jO666vmKMiXdkx3jDK8UFuyCXOR-x20quzsmF6AVrmJQ78ucwQVrMTE1wdAE7meAtlmuKK6TiIdM40sk_TBXWY0Q2WKBrnJ8gF0g0mBBxERuXNWZfkE_gA4IWHP3ty4SjoCoJTMFG3kKgEywrHf2AauSo2UpcYvGPQM26zmhffAz5A3k_mjnD9ct7RQ53Xw-336v7n99-3H65r2zdqVJxy1pnxQC16-qxUbyv5SDqth2MMKypnTVKyI6B5Axsb0GNRjjeGuVsN3BxRT6exuLFvza8SS8-W5hnEyBuWQsuGy6Vavo3oKyTrKulQLQ9oTbFnBOMek1-MelJc6afA9RH_Rqgfg5QnwJE4c2LxzYs4P7JXhND4PMJAPyTRw9JZ-sBM3E-gS3aRf8_j7__MLQn</recordid><startdate>202411</startdate><enddate>202411</enddate><creator>Arumugam, Gandarvakottai Senthilkumar</creator><creator>Arumugam, Chinnappa</creator><creator>Damodharan, Kannan</creator><creator>Sathish Kumar, R.</creator><creator>Gummadi, Sathyanarayana N.</creator><creator>Muthusamy, Sarojadevi</creator><general>Elsevier B.V</general><scope>CGR</scope><scope>CUY</scope><scope>CVF</scope><scope>ECM</scope><scope>EIF</scope><scope>NPM</scope><scope>AAYXX</scope><scope>CITATION</scope><scope>7X8</scope><scope>7S9</scope><scope>L.6</scope></search><sort><creationdate>202411</creationdate><title>Thermal and mechanical properties of high-performance polyester nanobiocomposites reinforced with pre-treated sunn hemp fiber for automotive applications</title><author>Arumugam, Gandarvakottai Senthilkumar ; 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The addition of 5 % nanoclay to the biocomposite significantly increased the flexural strength by approximately 165 % for H2O2-treated SH fiber and 148 % for KMnO4-treated SH fiber, when compared to untreated fibers. This enhancement was achieved through phase separation, intercalation, and exfoliation between the SH fibers, polyester resin (PE), and 5 % nanoclay. In particular, the H2O2-treated SH fiber nanobiocomposite exhibited a 43 % higher flexural strength compared to its corresponding biocomposite. The incorporation of nanoclay significantly decreased the water absorption of the bio-composites from 11.86 % in the untreated samples to a minimum of 2.76 % in the H2O2-treated SH/PE nanobiocomposite. The study suggests that short SH fiber/PE/nanoclay nanobiocomposites could be used as effective alternatives to synthetic composites in various applications, including the aerospace industry, household products, and automotive interior components such as side panels, seat frames, and central consoles. Additionally, they could be utilized in exterior parts like door panels and dashboards. [Display omitted]</abstract><cop>Netherlands</cop><pub>Elsevier B.V</pub><pmid>39304055</pmid><doi>10.1016/j.ijbiomac.2024.135591</doi></addata></record>
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subjects	Automobiles bentonite Biocomposites Cannabis - chemistry Chemical treatment Clay - chemistry Compression molding Crotalaria juncea hydrophilicity industry Mechanical Phenomena modulus of rupture Nanoclay nanoclays Nanocomposites - chemistry polyesters Polyesters - chemistry separation Sunn hemp fiber Temperature Tensile Strength Unsaturated polyester water uptake
title	Thermal and mechanical properties of high-performance polyester nanobiocomposites reinforced with pre-treated sunn hemp fiber for automotive applications
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