Mechanical Uniaxial Tensile Performance of Hybrid Glass/Carbon Woven Composites

Carbon fibres are widely recognized for their remarkable strength-to- weight ratio, but their high cost and limited lifespan have prompted researchers to explore alternative materials. One promising solution is the use of hybrid composites, which combine carbon fibres with other fibre types, to main...

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Published in:INTERNATIONAL JOURNAL OF INTEGRATED ENGINEERING
Main Authors: Zulkifli, Muhammad Nasrun Faris Mohd; Yahya, Mohamad Faizul
Format: Article
Language:English
Published: UNIV TUN HUSSEIN ONN MALAYSIA 2024
Subjects:
Online Access:https://www-webofscience-com.uitm.idm.oclc.org/wos/woscc/full-record/WOS:001354562500001
author Zulkifli
Muhammad Nasrun Faris Mohd; Yahya
Mohamad Faizul
spellingShingle Zulkifli
Muhammad Nasrun Faris Mohd; Yahya
Mohamad Faizul
Mechanical Uniaxial Tensile Performance of Hybrid Glass/Carbon Woven Composites
Engineering
author_facet Zulkifli
Muhammad Nasrun Faris Mohd; Yahya
Mohamad Faizul
author_sort Zulkifli
spelling Zulkifli, Muhammad Nasrun Faris Mohd; Yahya, Mohamad Faizul
Mechanical Uniaxial Tensile Performance of Hybrid Glass/Carbon Woven Composites
INTERNATIONAL JOURNAL OF INTEGRATED ENGINEERING
English
Article
Carbon fibres are widely recognized for their remarkable strength-to- weight ratio, but their high cost and limited lifespan have prompted researchers to explore alternative materials. One promising solution is the use of hybrid composites, which combine carbon fibres with other fibre types, to maintain mechanical strength at optimal levels while reducing costs. A scientific study was conducted to investigate the impact of stacking configuration on hybrid glass/carbon woven composites. The study established eight stacking configurations based on the incorporation of identical and non-identical weave structures at the outermost layers. The hybrid glass/carbon woven composites were fabricated using the hand lay-up approach, with epoxy resin used as the polymer matrix. The results of the study showed that the hybrid B configuration yielded the highest tensile strength at 322.75 MPa, while the hybrid F sequence generated the lowest tensile strength at 169.00 MPa. The findings from this study indicated that the incorporation of weave structures with longer yarn floats in a non-identical arrangement at the outermost layer resulted in improved uniaxial tensile strength performance.
UNIV TUN HUSSEIN ONN MALAYSIA
2229-838X

2024
16
6
10.30880/ijie.2024.16.06.011
Engineering

WOS:001354562500001
https://www-webofscience-com.uitm.idm.oclc.org/wos/woscc/full-record/WOS:001354562500001
title Mechanical Uniaxial Tensile Performance of Hybrid Glass/Carbon Woven Composites
title_short Mechanical Uniaxial Tensile Performance of Hybrid Glass/Carbon Woven Composites
title_full Mechanical Uniaxial Tensile Performance of Hybrid Glass/Carbon Woven Composites
title_fullStr Mechanical Uniaxial Tensile Performance of Hybrid Glass/Carbon Woven Composites
title_full_unstemmed Mechanical Uniaxial Tensile Performance of Hybrid Glass/Carbon Woven Composites
title_sort Mechanical Uniaxial Tensile Performance of Hybrid Glass/Carbon Woven Composites
container_title INTERNATIONAL JOURNAL OF INTEGRATED ENGINEERING
language English
format Article
description Carbon fibres are widely recognized for their remarkable strength-to- weight ratio, but their high cost and limited lifespan have prompted researchers to explore alternative materials. One promising solution is the use of hybrid composites, which combine carbon fibres with other fibre types, to maintain mechanical strength at optimal levels while reducing costs. A scientific study was conducted to investigate the impact of stacking configuration on hybrid glass/carbon woven composites. The study established eight stacking configurations based on the incorporation of identical and non-identical weave structures at the outermost layers. The hybrid glass/carbon woven composites were fabricated using the hand lay-up approach, with epoxy resin used as the polymer matrix. The results of the study showed that the hybrid B configuration yielded the highest tensile strength at 322.75 MPa, while the hybrid F sequence generated the lowest tensile strength at 169.00 MPa. The findings from this study indicated that the incorporation of weave structures with longer yarn floats in a non-identical arrangement at the outermost layer resulted in improved uniaxial tensile strength performance.
publisher UNIV TUN HUSSEIN ONN MALAYSIA
issn 2229-838X

publishDate 2024
container_volume 16
container_issue 6
doi_str_mv 10.30880/ijie.2024.16.06.011
topic Engineering
topic_facet Engineering
accesstype
id WOS:001354562500001
url https://www-webofscience-com.uitm.idm.oclc.org/wos/woscc/full-record/WOS:001354562500001
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