Green composites from vanillin‐based benzoxazine: Modified almond shell particles, curing behavior, thermal stability, mechanical properties, and stress analysis
By adhering to green chemistry principles, unique and enhanced benzoxazine composite is made from renewable vanillin and furfuryl amine. The bio‐benzoxazine poly(V‐BZF) structure was confirmed by 1 H NMR and Fourier‐transform infrared spectroscopy spectroscopy. Enhanced composites were developed suc...
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| Published in | Journal of applied polymer science Vol. 140; no. 45 |
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| Main Authors | , , , , , , , |
| Format | Journal Article |
| Language | English |
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05.12.2023
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| Abstract | By adhering to green chemistry principles, unique and enhanced benzoxazine composite is made from renewable vanillin and furfuryl amine. The bio‐benzoxazine poly(V‐BZF) structure was confirmed by
1
H NMR and Fourier‐transform infrared spectroscopy spectroscopy. Enhanced composites were developed successfully by blending different chemical‐treated almond shell particles with poly(V‐BZF). Differential scanning calorimetry results reveal that novel benzoxazine's curing temperature was low and slightly reduced by incorporating chemically treated fillers. The lowest polymerizing temperature was recorded as 215°C for the blend of alkali‐treated particles. Thermogravimetric analysis demonstrates that composites exhibited superior thermal characteristics, and chemical treatment positively impacts filler material. The limiting oxygen index value classifies poly(V‐BZF) composites as flame‐retardant and extinguishing. Approximately a 47.56% increase in tensile strength and a 28.9% increase in modulus were recorded with the incorporation of silane‐treated filler. Flexural tests demonstrated that composites with silane‐treated particles showed maximum flexural strength of 101.5 MPa and a modulus of 4112.6 MPa. The impact strength of composites increased to 73.3%, expanding benzoxazine's manufacturing applications. In addition, the specimen was designed to have composite properties and stress analysis was performed in two Multiphysics software packages. In all, this work confirms that adopting environmentally‐friendly methodologies and surface modification of filler can yield superior composites. |
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| AbstractList | By adhering to green chemistry principles, unique and enhanced benzoxazine composite is made from renewable vanillin and furfuryl amine. The bio‐benzoxazine poly(V‐BZF) structure was confirmed by
1
H NMR and Fourier‐transform infrared spectroscopy spectroscopy. Enhanced composites were developed successfully by blending different chemical‐treated almond shell particles with poly(V‐BZF). Differential scanning calorimetry results reveal that novel benzoxazine's curing temperature was low and slightly reduced by incorporating chemically treated fillers. The lowest polymerizing temperature was recorded as 215°C for the blend of alkali‐treated particles. Thermogravimetric analysis demonstrates that composites exhibited superior thermal characteristics, and chemical treatment positively impacts filler material. The limiting oxygen index value classifies poly(V‐BZF) composites as flame‐retardant and extinguishing. Approximately a 47.56% increase in tensile strength and a 28.9% increase in modulus were recorded with the incorporation of silane‐treated filler. Flexural tests demonstrated that composites with silane‐treated particles showed maximum flexural strength of 101.5 MPa and a modulus of 4112.6 MPa. The impact strength of composites increased to 73.3%, expanding benzoxazine's manufacturing applications. In addition, the specimen was designed to have composite properties and stress analysis was performed in two Multiphysics software packages. In all, this work confirms that adopting environmentally‐friendly methodologies and surface modification of filler can yield superior composites. By adhering to green chemistry principles, unique and enhanced benzoxazine composite is made from renewable vanillin and furfuryl amine. The bio‐benzoxazine poly(V‐BZF) structure was confirmed by 1H NMR and Fourier‐transform infrared spectroscopy spectroscopy. Enhanced composites were developed successfully by blending different chemical‐treated almond shell particles with poly(V‐BZF). Differential scanning calorimetry results reveal that novel benzoxazine's curing temperature was low and slightly reduced by incorporating chemically treated fillers. The lowest polymerizing temperature was recorded as 215°C for the blend of alkali‐treated particles. Thermogravimetric analysis demonstrates that composites exhibited superior thermal characteristics, and chemical treatment positively impacts filler material. The limiting oxygen index value classifies poly(V‐BZF) composites as flame‐retardant and extinguishing. Approximately a 47.56% increase in tensile strength and a 28.9% increase in modulus were recorded with the incorporation of silane‐treated filler. Flexural tests demonstrated that composites with silane‐treated particles showed maximum flexural strength of 101.5 MPa and a modulus of 4112.6 MPa. The impact strength of composites increased to 73.3%, expanding benzoxazine's manufacturing applications. In addition, the specimen was designed to have composite properties and stress analysis was performed in two Multiphysics software packages. In all, this work confirms that adopting environmentally‐friendly methodologies and surface modification of filler can yield superior composites. |
| Author | Gorar, Athar Ali Khan Pan, Zhong‐cheng Daham, Abbas Zhiyi, Guo Liu, Wen‐Bin Wang, Jun Zhicheng, Wang Derradji, Mehdi |
| Author_xml | – sequence: 1 givenname: Athar Ali Khan orcidid: 0009-0000-8605-9609 surname: Gorar fullname: Gorar, Athar Ali Khan organization: College of Materials Science and Chemical Engineering Harbin Engineering University Harbin China, Department of Mechanical Engineering Quaid‐e‐Awam University of Engineering, Sciences & Technology Larkana Pakistan – sequence: 2 givenname: Guo surname: Zhiyi fullname: Zhiyi, Guo organization: College of Materials Science and Chemical Engineering Harbin Engineering University Harbin China – sequence: 3 givenname: Wang surname: Zhicheng fullname: Zhicheng, Wang organization: College of Materials Science and Chemical Engineering Harbin Engineering University Harbin China – sequence: 4 givenname: Abbas surname: Daham fullname: Daham, Abbas organization: College of Materials Science and Chemical Engineering Harbin Engineering University Harbin China – sequence: 5 givenname: Zhong‐cheng surname: Pan fullname: Pan, Zhong‐cheng organization: College of Materials Science and Chemical Engineering Harbin Engineering University Harbin China – sequence: 6 givenname: Jun surname: Wang fullname: Wang, Jun organization: College of Materials Science and Chemical Engineering Harbin Engineering University Harbin China – sequence: 7 givenname: Wen‐Bin orcidid: 0000-0003-0390-8455 surname: Liu fullname: Liu, Wen‐Bin organization: College of Materials Science and Chemical Engineering Harbin Engineering University Harbin China – sequence: 8 givenname: Mehdi surname: Derradji fullname: Derradji, Mehdi organization: UER Proced'es Energ'etiques Ecole Militaire Polytechnique Algiers Algeria |
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| Snippet | By adhering to green chemistry principles, unique and enhanced benzoxazine composite is made from renewable vanillin and furfuryl amine. The bio‐benzoxazine... |
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| SubjectTerms | Benzoxazines Chemical treatment Curing Fillers Flexural strength Fourier transforms Impact strength Infrared spectroscopy Materials science Mechanical properties NMR Nuclear magnetic resonance Particulate composites Polymers Silanes Stability analysis Stress analysis Tensile strength Thermal stability Thermogravimetric analysis Vanillin |
| Title | Green composites from vanillin‐based benzoxazine: Modified almond shell particles, curing behavior, thermal stability, mechanical properties, and stress analysis |
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