The Reduction Factor of Pultrude Glass Fibre-Reinforced Polyester Composite Cross-Arm: A Comparative Study on Mathematical Modelling for Life-Span Prediction

This paper presents an experimental and numerical investigation of pultruded composite glass fibre-reinforced polymer (pGFRP) cross-arms subjected to flexural creep behaviour to assess their performance and sustainability in composite cross-arm structure applications. The primary objective of this s...

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Main Authors: Abu Bakar M.S., Syamsir A., Alhayek A., Asyraf M.R.M., Itam Z., Shaik S.M.M., Abd Aziz N., Jamal T., Mohd Mansor S.A.
Other Authors: 57202962691
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Published: Multidisciplinary Digital Publishing Institute (MDPI) 2024
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spelling my.uniten.dspace-341072024-10-14T11:17:59Z The Reduction Factor of Pultrude Glass Fibre-Reinforced Polyester Composite Cross-Arm: A Comparative Study on Mathematical Modelling for Life-Span Prediction Abu Bakar M.S. Syamsir A. Alhayek A. Asyraf M.R.M. Itam Z. Shaik S.M.M. Abd Aziz N. Jamal T. Mohd Mansor S.A. 57202962691 57195320482 57221437286 57205295733 55102723400 58534588300 57201665672 57225150163 58535131600 energy life-span prediction mathematical model pultrude glass fibre-reinforced polyester composite reduction factor Creep Electric power transmission Fiber reinforced plastics Forecasting Glass fibers Overhead lines Sustainable development Composite glass Cross arm Energy Glass fiber-reinforced polyesters Life-span prediction Lifespans Polyester composites Pultrude glass fiber-reinforced polyester composite Pultruded composites Reduction factor Strain rate This paper presents an experimental and numerical investigation of pultruded composite glass fibre-reinforced polymer (pGFRP) cross-arms subjected to flexural creep behaviour to assess their performance and sustainability in composite cross-arm structure applications. The primary objective of this study was to investigate the failure creep behaviour of pGFRP cross-arms with different stacking sequences. Specifically, the study aimed to understand the variations in strain rate exhibited during different stages of the creep process. Therefore, this study emphasizes a simplified approach within the experiment, numerical analysis, and mathematical modelling of three different pGFRP composites to estimate the stiffness reduction factors that determine the prediction of failure. The findings show that Findley�s power law and the Burger model projected very different strains and diverged noticeably outside the testing period. Findley�s model estimated a minimal increase in total strain over 50 years, while the Burger model anticipated PS-1 and PS-2 composites would fail within about 11 and 33 years, respectively. The Burger model�s forecasts might be more reasonable due to the harsh environment the cross-arms are expected to withstand. The endurance and long-term performance of composite materials used in overhead power transmission lines may be predicted mathematically, and this insight into material property factors can help with design and maintenance. � 2023 by the authors. Final 2024-10-14T03:17:59Z 2024-10-14T03:17:59Z 2023 Article 10.3390/ma16155328 2-s2.0-85167810060 https://www.scopus.com/inward/record.uri?eid=2-s2.0-85167810060&doi=10.3390%2fma16155328&partnerID=40&md5=985d10e13b2f8df5df70a29bddc92949 https://irepository.uniten.edu.my/handle/123456789/34107 16 15 5328 All Open Access Gold Open Access Multidisciplinary Digital Publishing Institute (MDPI) Scopus
institution Universiti Tenaga Nasional
building UNITEN Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Tenaga Nasional
content_source UNITEN Institutional Repository
url_provider http://dspace.uniten.edu.my/
topic energy
life-span prediction
mathematical model
pultrude glass fibre-reinforced polyester composite
reduction factor
Creep
Electric power transmission
Fiber reinforced plastics
Forecasting
Glass fibers
Overhead lines
Sustainable development
Composite glass
Cross arm
Energy
Glass fiber-reinforced polyesters
Life-span prediction
Lifespans
Polyester composites
Pultrude glass fiber-reinforced polyester composite
Pultruded composites
Reduction factor
Strain rate
spellingShingle energy
life-span prediction
mathematical model
pultrude glass fibre-reinforced polyester composite
reduction factor
Creep
Electric power transmission
Fiber reinforced plastics
Forecasting
Glass fibers
Overhead lines
Sustainable development
Composite glass
Cross arm
Energy
Glass fiber-reinforced polyesters
Life-span prediction
Lifespans
Polyester composites
Pultrude glass fiber-reinforced polyester composite
Pultruded composites
Reduction factor
Strain rate
Abu Bakar M.S.
Syamsir A.
Alhayek A.
Asyraf M.R.M.
Itam Z.
Shaik S.M.M.
Abd Aziz N.
Jamal T.
Mohd Mansor S.A.
The Reduction Factor of Pultrude Glass Fibre-Reinforced Polyester Composite Cross-Arm: A Comparative Study on Mathematical Modelling for Life-Span Prediction
description This paper presents an experimental and numerical investigation of pultruded composite glass fibre-reinforced polymer (pGFRP) cross-arms subjected to flexural creep behaviour to assess their performance and sustainability in composite cross-arm structure applications. The primary objective of this study was to investigate the failure creep behaviour of pGFRP cross-arms with different stacking sequences. Specifically, the study aimed to understand the variations in strain rate exhibited during different stages of the creep process. Therefore, this study emphasizes a simplified approach within the experiment, numerical analysis, and mathematical modelling of three different pGFRP composites to estimate the stiffness reduction factors that determine the prediction of failure. The findings show that Findley�s power law and the Burger model projected very different strains and diverged noticeably outside the testing period. Findley�s model estimated a minimal increase in total strain over 50 years, while the Burger model anticipated PS-1 and PS-2 composites would fail within about 11 and 33 years, respectively. The Burger model�s forecasts might be more reasonable due to the harsh environment the cross-arms are expected to withstand. The endurance and long-term performance of composite materials used in overhead power transmission lines may be predicted mathematically, and this insight into material property factors can help with design and maintenance. � 2023 by the authors.
author2 57202962691
author_facet 57202962691
Abu Bakar M.S.
Syamsir A.
Alhayek A.
Asyraf M.R.M.
Itam Z.
Shaik S.M.M.
Abd Aziz N.
Jamal T.
Mohd Mansor S.A.
format Article
author Abu Bakar M.S.
Syamsir A.
Alhayek A.
Asyraf M.R.M.
Itam Z.
Shaik S.M.M.
Abd Aziz N.
Jamal T.
Mohd Mansor S.A.
author_sort Abu Bakar M.S.
title The Reduction Factor of Pultrude Glass Fibre-Reinforced Polyester Composite Cross-Arm: A Comparative Study on Mathematical Modelling for Life-Span Prediction
title_short The Reduction Factor of Pultrude Glass Fibre-Reinforced Polyester Composite Cross-Arm: A Comparative Study on Mathematical Modelling for Life-Span Prediction
title_full The Reduction Factor of Pultrude Glass Fibre-Reinforced Polyester Composite Cross-Arm: A Comparative Study on Mathematical Modelling for Life-Span Prediction
title_fullStr The Reduction Factor of Pultrude Glass Fibre-Reinforced Polyester Composite Cross-Arm: A Comparative Study on Mathematical Modelling for Life-Span Prediction
title_full_unstemmed The Reduction Factor of Pultrude Glass Fibre-Reinforced Polyester Composite Cross-Arm: A Comparative Study on Mathematical Modelling for Life-Span Prediction
title_sort reduction factor of pultrude glass fibre-reinforced polyester composite cross-arm: a comparative study on mathematical modelling for life-span prediction
publisher Multidisciplinary Digital Publishing Institute (MDPI)
publishDate 2024
_version_ 1814060059415543808
score 13.214268