Hydrostatic Pressure Analysis of Yarn Composites Patch for PVC Pipes

Hydrostatic Pressure Analysis of Yarn Composites Patch for PVC Pipes

The globally high-demand pipeline is prone to operational issues that can be mitigated using composite materials. Damage and cracks in the pipe can lead to structural weakening, leaks, and reduced functionality. This research aims to determine the adhesion strength of polyvinyl (PV) resin through la...

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Published in:Journal of Mechanical Engineering
Main Author: Said J.M.; Rahman N.L.A.; Jumahat A.; Zahib Z.M.; Mahadzir M.Z.I.
Format: Article
Language:English
Published: UiTM Press 2025
Online Access:https://www.scopus.com/inward/record.uri?eid=2-s2.0-85215676610&doi=10.24191%2fjmeche.v22i1.2921&partnerID=40&md5=0d8cc832929d89f85bed690d58495554
id 2-s2.0-85215676610
spelling 2-s2.0-85215676610
Said J.M.; Rahman N.L.A.; Jumahat A.; Zahib Z.M.; Mahadzir M.Z.I.
Hydrostatic Pressure Analysis of Yarn Composites Patch for PVC Pipes
2025
Journal of Mechanical Engineering
22
1
10.24191/jmeche.v22i1.2921
https://www.scopus.com/inward/record.uri?eid=2-s2.0-85215676610&doi=10.24191%2fjmeche.v22i1.2921&partnerID=40&md5=0d8cc832929d89f85bed690d58495554
The globally high-demand pipeline is prone to operational issues that can be mitigated using composite materials. Damage and cracks in the pipe can lead to structural weakening, leaks, and reduced functionality. This research aims to determine the adhesion strength of polyvinyl (PV) resin through lap joint testing, assess the burst pressure of polyvinyl chloride (PVC) pipes via hydrostatic pressure testing, and evaluate the impact of various wrapping materials on the maximum hydrostatic pressure of damaged PVC pipes. The PVC pipe was introduced to a 20 mm hole diameter as a defect and then patched with woven basalt fiber. The yarn-commingled fiber mat was wrapped onto the PVC pipe surface using the hand lay-up and vacuum bagging methods. Various materials with the same stacking lay-up layer and different fiber orientations were used in this study. Hydrostatic pressure testing on the PVC pipe showed that the bare pipe (unwrapped) can withstand up to 1.5 MPa before failing. For reference materials in the woven fiber type, the highest maximum pressure achieved was approximately 2.03 MPa using the glass chopped strain mat (CSM) and woven fiber for the wrapping system. Among the commingled fiber systems, the basalt (B/B) commingled fiber demonstrated the highest maximum hydrostatic pressure of about 1.86 MPa, with a maximum hoop stress of 26.5 MPa and a strain of 1.37%. This research demonstrates that using composite materials, particularly glass chopped strain mat (CSM), woven fibers, and basalt commingled fibers, significantly enhances the structural performance of damaged PVC pipelines compared to untreated pipes. These findings provide valuable insights into the effective design and selection of fiber composite materials for pipeline repairs, offering durable and innovative solutions to mitigate operational issues in high-demand pipeline systems. © Jamaliah Md Said et al., 2025
UiTM Press
18235514
English
Article
author Said J.M.; Rahman N.L.A.; Jumahat A.; Zahib Z.M.; Mahadzir M.Z.I.
spellingShingle Said J.M.; Rahman N.L.A.; Jumahat A.; Zahib Z.M.; Mahadzir M.Z.I.
Hydrostatic Pressure Analysis of Yarn Composites Patch for PVC Pipes
author_facet Said J.M.; Rahman N.L.A.; Jumahat A.; Zahib Z.M.; Mahadzir M.Z.I.
author_sort Said J.M.; Rahman N.L.A.; Jumahat A.; Zahib Z.M.; Mahadzir M.Z.I.
title Hydrostatic Pressure Analysis of Yarn Composites Patch for PVC Pipes
title_short Hydrostatic Pressure Analysis of Yarn Composites Patch for PVC Pipes
title_full Hydrostatic Pressure Analysis of Yarn Composites Patch for PVC Pipes
title_fullStr Hydrostatic Pressure Analysis of Yarn Composites Patch for PVC Pipes
title_full_unstemmed Hydrostatic Pressure Analysis of Yarn Composites Patch for PVC Pipes
title_sort Hydrostatic Pressure Analysis of Yarn Composites Patch for PVC Pipes
publishDate 2025
container_title Journal of Mechanical Engineering
container_volume 22
container_issue 1
doi_str_mv 10.24191/jmeche.v22i1.2921
url https://www.scopus.com/inward/record.uri?eid=2-s2.0-85215676610&doi=10.24191%2fjmeche.v22i1.2921&partnerID=40&md5=0d8cc832929d89f85bed690d58495554
description The globally high-demand pipeline is prone to operational issues that can be mitigated using composite materials. Damage and cracks in the pipe can lead to structural weakening, leaks, and reduced functionality. This research aims to determine the adhesion strength of polyvinyl (PV) resin through lap joint testing, assess the burst pressure of polyvinyl chloride (PVC) pipes via hydrostatic pressure testing, and evaluate the impact of various wrapping materials on the maximum hydrostatic pressure of damaged PVC pipes. The PVC pipe was introduced to a 20 mm hole diameter as a defect and then patched with woven basalt fiber. The yarn-commingled fiber mat was wrapped onto the PVC pipe surface using the hand lay-up and vacuum bagging methods. Various materials with the same stacking lay-up layer and different fiber orientations were used in this study. Hydrostatic pressure testing on the PVC pipe showed that the bare pipe (unwrapped) can withstand up to 1.5 MPa before failing. For reference materials in the woven fiber type, the highest maximum pressure achieved was approximately 2.03 MPa using the glass chopped strain mat (CSM) and woven fiber for the wrapping system. Among the commingled fiber systems, the basalt (B/B) commingled fiber demonstrated the highest maximum hydrostatic pressure of about 1.86 MPa, with a maximum hoop stress of 26.5 MPa and a strain of 1.37%. This research demonstrates that using composite materials, particularly glass chopped strain mat (CSM), woven fibers, and basalt commingled fibers, significantly enhances the structural performance of damaged PVC pipelines compared to untreated pipes. These findings provide valuable insights into the effective design and selection of fiber composite materials for pipeline repairs, offering durable and innovative solutions to mitigate operational issues in high-demand pipeline systems. © Jamaliah Md Said et al., 2025
publisher UiTM Press
issn 18235514
language English
format Article
accesstype
record_format scopus
collection Scopus
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