Utilization of Bracing Arms as Additional Reinforcement in Pultruded Glass Fiber-Reinforced Polymer Composite Cross-Arms: Creep Experimental and Numerical Analyses.

Muhammad Rizal Muhammad Asyraf,Noorfaizal Yidris,Salit Mohd Sapuan,Mohamad Ridzwan Ishak

doi:10.3390/polym13040620

Muhammad Rizal Muhammad Asyraf, Noorfaizal Yidris + Show 2 more

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https://doi.org/10.3390/polym13040620

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Journal: Polymers	Publication Date: Feb 19, 2021
Citations: 42	License type: CC BY 4.0

Affiliation: Universiti Putra Malaysia

Abstract

The application of pultruded glass fiber-reinforced polymer composites (PGFRPCs) as a replacement for conventional wooden cross-arms in transmission towers is relatively new. Although numerous studies have conducted creep tests on coupon-scale PGFRPC cross-arms, none had performed creep analyses on full-scale PGFRPC cross-arms under actual working load conditions. Thus, this work proposed to study the influence of an additional bracing system on the creep responses of PGFRPC cross-arms in a 132 kV transmission tower. The creep behaviors and responses of the main members in current and braced PGFRPC cross-arm designs were compared and evaluated in a transmission tower under actual working conditions. These PGFRPC cross-arms were subjected to actual working loads mimicking the actual weight of electrical cables and insulators for a duration of 1000 h. The cross-arms were installed on a custom test rig in an open area to simulate the actual environment of tropical climate conditions. Further creep analysis was performed by using Findley and Burger models on the basis of experimental data to link instantaneous and extended (transient and viscoelastic) creep strains. The addition of braced arms to the structure reduced the total strain of a cross-arm’s main member beams and improved elastic and viscous moduli. The addition of bracing arms improved the structural integrity and stiffness of the cross-arm structure. The findings of this study suggested that the use of a bracing system in cross-arm structures could prolong the structures’ service life and subsequently reduce maintenance effort and cost for long-term applications in transmission towers.

Highlights

In electrical power grid systems, transmission towers are implemented to grasp and hold conductor cables from power generators to substations in continuous line connections
The time-dependent creep behavior of pultruded glass fiber-reinforced polymer composites (PGFRPCs) cross-arms implemented with bracing systems was reduced compared with that of the existing PGFRPC cross-arm design
Previous works have investigated the creep behaviors of coupon-scale PGFRPC cross-arms in the laboratory environment

Summary

Introduction

In electrical power grid systems, transmission towers are implemented to grasp and hold conductor cables from power generators to substations in continuous line connections. Transmission towers are divided and grouped into two major types, namely, latticed steel towers and monopole steel tubes. Latticed steel towers have been installed throughout Peninsular Malaysia since 1929 [1]. This type of transmission tower has remained in service for the transmission of electrical power to housing and industrial areas. Latticed steel transmission towers are composed of a peak, cross-arm, tower body, boom and cage. Crossarms are installed and used to secure utility wires with their insulators, which hold lines directly, to maintain power cables above ground [2,3]

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