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Fabrication of waste bagasse fiber‐reinforced epoxy composites: Study of physical, mechanical, and erosion properties

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Bibliographische Detailangaben
Zeitschriftentitel: Polymer Composites
Personen und Körperschaften: Singh, Tej, Tejyan, Sachin, Patnaik, Amar, Singh, Vedant, Zsoldos, Ibolya, Fekete, Gusztáv
In: Polymer Composites, 40, 2019, 9, S. 3777-3786
Format: E-Article
Sprache: Englisch
veröffentlicht:
Wiley
Schlagwörter:
Materials Chemistry
Polymers and Plastics
General Chemistry
Ceramics and Composites
author_facet Singh, Tej
Tejyan, Sachin
Patnaik, Amar
Singh, Vedant
Zsoldos, Ibolya
Fekete, Gusztáv
Singh, Tej
Tejyan, Sachin
Patnaik, Amar
Singh, Vedant
Zsoldos, Ibolya
Fekete, Gusztáv
author Singh, Tej
Tejyan, Sachin
Patnaik, Amar
Singh, Vedant
Zsoldos, Ibolya
Fekete, Gusztáv
spellingShingle Singh, Tej
Tejyan, Sachin
Patnaik, Amar
Singh, Vedant
Zsoldos, Ibolya
Fekete, Gusztáv
Polymer Composites
Fabrication of waste bagasse fiber‐reinforced epoxy composites: Study of physical, mechanical, and erosion properties
Materials Chemistry
Polymers and Plastics
General Chemistry
Ceramics and Composites
author_sort singh, tej
spelling Singh, Tej Tejyan, Sachin Patnaik, Amar Singh, Vedant Zsoldos, Ibolya Fekete, Gusztáv 0272-8397 1548-0569 Wiley Materials Chemistry Polymers and Plastics General Chemistry Ceramics and Composites http://dx.doi.org/10.1002/pc.25239 <jats:p>The aim of the research work is to study the physical, mechanical, and erosive wear properties of sugarcane bagasse fiber‐reinforced epoxy composites. The physical (density, void content) and the mechanical (hardness, tensile strength, impact energy, flexural strength) properties of the composites were found to increase with the content of bagasse fiber. For erosive wear analysis, the experiments were carried out with the help of erosion test machine. To minimize the erosive wear rate, Taguchi technique is executed to explore the influence of five control factors including fiber content, impact velocity, impingement, stand‐off distance, and erodent size at three levels. Using Taguchi (<jats:italic>L</jats:italic><jats:sub>27</jats:sub>) orthogonal array, the optimal combination of control factors, which yielded minimum erosive wear rate, was statistically predicted and experimentally verified. The fiber content and impact velocity were the two most contributing control factors for the minimization of erosive wear rate. The important sequence of the parameters is fiber content &gt; impact velocity &gt; impingement angle &gt; erodent size &gt; stand‐off distance. The optimal combination of control factors was obtained at 10 wt% of fiber content, 30 m/s of impact velocity, 30° of impingement angle, 85 mm of stand‐off distance, and 250 μm of erodent size. Finally, composites worn surfaces were examined with scanning electron microscope to study the possible erosive wear mechanism. POLYM. COMPOS., 40:3777–3786, 2019. © 2019 Society of Plastics Engineers</jats:p> Fabrication of waste bagasse fiber‐reinforced epoxy composites: Study of physical, mechanical, and erosion properties Polymer Composites
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title Fabrication of waste bagasse fiber‐reinforced epoxy composites: Study of physical, mechanical, and erosion properties
title_unstemmed Fabrication of waste bagasse fiber‐reinforced epoxy composites: Study of physical, mechanical, and erosion properties
title_full Fabrication of waste bagasse fiber‐reinforced epoxy composites: Study of physical, mechanical, and erosion properties
title_fullStr Fabrication of waste bagasse fiber‐reinforced epoxy composites: Study of physical, mechanical, and erosion properties
title_full_unstemmed Fabrication of waste bagasse fiber‐reinforced epoxy composites: Study of physical, mechanical, and erosion properties
title_short Fabrication of waste bagasse fiber‐reinforced epoxy composites: Study of physical, mechanical, and erosion properties
title_sort fabrication of waste bagasse fiber‐reinforced epoxy composites: study of physical, mechanical, and erosion properties
topic Materials Chemistry
Polymers and Plastics
General Chemistry
Ceramics and Composites
url http://dx.doi.org/10.1002/pc.25239
publishDate 2019
physical 3777-3786
description <jats:p>The aim of the research work is to study the physical, mechanical, and erosive wear properties of sugarcane bagasse fiber‐reinforced epoxy composites. The physical (density, void content) and the mechanical (hardness, tensile strength, impact energy, flexural strength) properties of the composites were found to increase with the content of bagasse fiber. For erosive wear analysis, the experiments were carried out with the help of erosion test machine. To minimize the erosive wear rate, Taguchi technique is executed to explore the influence of five control factors including fiber content, impact velocity, impingement, stand‐off distance, and erodent size at three levels. Using Taguchi (<jats:italic>L</jats:italic><jats:sub>27</jats:sub>) orthogonal array, the optimal combination of control factors, which yielded minimum erosive wear rate, was statistically predicted and experimentally verified. The fiber content and impact velocity were the two most contributing control factors for the minimization of erosive wear rate. The important sequence of the parameters is fiber content &gt; impact velocity &gt; impingement angle &gt; erodent size &gt; stand‐off distance. The optimal combination of control factors was obtained at 10 wt% of fiber content, 30 m/s of impact velocity, 30° of impingement angle, 85 mm of stand‐off distance, and 250 μm of erodent size. Finally, composites worn surfaces were examined with scanning electron microscope to study the possible erosive wear mechanism. POLYM. COMPOS., 40:3777–3786, 2019. © 2019 Society of Plastics Engineers</jats:p>
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author Singh, Tej, Tejyan, Sachin, Patnaik, Amar, Singh, Vedant, Zsoldos, Ibolya, Fekete, Gusztáv
author_facet Singh, Tej, Tejyan, Sachin, Patnaik, Amar, Singh, Vedant, Zsoldos, Ibolya, Fekete, Gusztáv, Singh, Tej, Tejyan, Sachin, Patnaik, Amar, Singh, Vedant, Zsoldos, Ibolya, Fekete, Gusztáv
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description <jats:p>The aim of the research work is to study the physical, mechanical, and erosive wear properties of sugarcane bagasse fiber‐reinforced epoxy composites. The physical (density, void content) and the mechanical (hardness, tensile strength, impact energy, flexural strength) properties of the composites were found to increase with the content of bagasse fiber. For erosive wear analysis, the experiments were carried out with the help of erosion test machine. To minimize the erosive wear rate, Taguchi technique is executed to explore the influence of five control factors including fiber content, impact velocity, impingement, stand‐off distance, and erodent size at three levels. Using Taguchi (<jats:italic>L</jats:italic><jats:sub>27</jats:sub>) orthogonal array, the optimal combination of control factors, which yielded minimum erosive wear rate, was statistically predicted and experimentally verified. The fiber content and impact velocity were the two most contributing control factors for the minimization of erosive wear rate. The important sequence of the parameters is fiber content &gt; impact velocity &gt; impingement angle &gt; erodent size &gt; stand‐off distance. The optimal combination of control factors was obtained at 10 wt% of fiber content, 30 m/s of impact velocity, 30° of impingement angle, 85 mm of stand‐off distance, and 250 μm of erodent size. Finally, composites worn surfaces were examined with scanning electron microscope to study the possible erosive wear mechanism. POLYM. COMPOS., 40:3777–3786, 2019. © 2019 Society of Plastics Engineers</jats:p>
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spelling Singh, Tej Tejyan, Sachin Patnaik, Amar Singh, Vedant Zsoldos, Ibolya Fekete, Gusztáv 0272-8397 1548-0569 Wiley Materials Chemistry Polymers and Plastics General Chemistry Ceramics and Composites http://dx.doi.org/10.1002/pc.25239 <jats:p>The aim of the research work is to study the physical, mechanical, and erosive wear properties of sugarcane bagasse fiber‐reinforced epoxy composites. The physical (density, void content) and the mechanical (hardness, tensile strength, impact energy, flexural strength) properties of the composites were found to increase with the content of bagasse fiber. For erosive wear analysis, the experiments were carried out with the help of erosion test machine. To minimize the erosive wear rate, Taguchi technique is executed to explore the influence of five control factors including fiber content, impact velocity, impingement, stand‐off distance, and erodent size at three levels. Using Taguchi (<jats:italic>L</jats:italic><jats:sub>27</jats:sub>) orthogonal array, the optimal combination of control factors, which yielded minimum erosive wear rate, was statistically predicted and experimentally verified. The fiber content and impact velocity were the two most contributing control factors for the minimization of erosive wear rate. The important sequence of the parameters is fiber content &gt; impact velocity &gt; impingement angle &gt; erodent size &gt; stand‐off distance. The optimal combination of control factors was obtained at 10 wt% of fiber content, 30 m/s of impact velocity, 30° of impingement angle, 85 mm of stand‐off distance, and 250 μm of erodent size. Finally, composites worn surfaces were examined with scanning electron microscope to study the possible erosive wear mechanism. POLYM. COMPOS., 40:3777–3786, 2019. © 2019 Society of Plastics Engineers</jats:p> Fabrication of waste bagasse fiber‐reinforced epoxy composites: Study of physical, mechanical, and erosion properties Polymer Composites
spellingShingle Singh, Tej, Tejyan, Sachin, Patnaik, Amar, Singh, Vedant, Zsoldos, Ibolya, Fekete, Gusztáv, Polymer Composites, Fabrication of waste bagasse fiber‐reinforced epoxy composites: Study of physical, mechanical, and erosion properties, Materials Chemistry, Polymers and Plastics, General Chemistry, Ceramics and Composites
title Fabrication of waste bagasse fiber‐reinforced epoxy composites: Study of physical, mechanical, and erosion properties
title_full Fabrication of waste bagasse fiber‐reinforced epoxy composites: Study of physical, mechanical, and erosion properties
title_fullStr Fabrication of waste bagasse fiber‐reinforced epoxy composites: Study of physical, mechanical, and erosion properties
title_full_unstemmed Fabrication of waste bagasse fiber‐reinforced epoxy composites: Study of physical, mechanical, and erosion properties
title_short Fabrication of waste bagasse fiber‐reinforced epoxy composites: Study of physical, mechanical, and erosion properties
title_sort fabrication of waste bagasse fiber‐reinforced epoxy composites: study of physical, mechanical, and erosion properties
title_unstemmed Fabrication of waste bagasse fiber‐reinforced epoxy composites: Study of physical, mechanical, and erosion properties
topic Materials Chemistry, Polymers and Plastics, General Chemistry, Ceramics and Composites
url http://dx.doi.org/10.1002/pc.25239