Your search keyword '"Itam, Zarina"' showing total 4 results

1. Effect of Stacking Sequence on Long-Term Creep Performance of Pultruded GFRP Composites.

Author

Asyraf, Muhammad Rizal Muhammad, Syamsir, Agusril, Zahari, Nazirul Mubin, Supian, Abu Bakar Mohd, Usman, Fathoni, and Itam, Zarina

Subjects

FIBER orientation, LIGHTWEIGHT materials, COMPOSITE materials, ELECTRIC insulators & insulation, FLEXURAL strength, CREEP (Materials), THERMAL insulation

Abstract

Pultruded glass-fibre reinforced polymer (pGFRP) composites are classified as lightweight material, which exhibit high strength-to-weight ratio for structural usage. This composite material has been applied as cross-arm members in transmission towers due to its ability in thermal and electrical insulation. However, the influence of the stacking sequence of pGFRP composite on its mechanical performance has not been fully covered in the literature to explain the long-term durability of the current cross-arm designs. The study expected to evaluate five fiber layers with various stacking sequences in terms of quasi-static and creep tests in a four-point bending mode. The creep test was performed for 1440 h (60 days). These composites were fabricated using the pultrusion process in the form of a square hollow structure. Later, it was cut into composite coupons with various sizes depending on the test conducted. The results showed that nine layers with 0°/45°/0°/−45°/0°/−45°/0°/45°/0° had the ultimate flexural strength. This stacking sequence configurations seemed to be optimally manufactured in continuous roving fibre by alternating between 0° and ±45° fiber orientations. Additionally, the S-9 pGFRP composite sample showed that it had a low-creep deflection with high elastic and apparent creep moduli in 1440 h. In terms of strength reduction factor, this configuration was recorded as the highest. The findings showed that the nine layers of pGFRP composites with alternation of 0° and ±45° fiber orientations were highly suitable for structural application at transmission towers for a long-term operation. [ABSTRACT FROM AUTHOR]

Published

2022

2. Flame Retardant Coatings: Additives, Binders, and Fillers.

Author

Mohd Sabee, Mohd Meer Saddiq, Itam, Zarina, Beddu, Salmia, Zahari, Nazirul Mubin, Mohd Kamal, Nur Liyana, Mohamad, Daud, Zulkepli, Norzeity Amalin, Shafiq, Mohamad Danial, and Abdul Hamid, Zuratul Ain

Subjects

*FIREPROOFING agents, *FLAME spread, *SURFACE coatings, *FLAMMABLE materials, *POLYMER degradation, *FLAME

Abstract

This review provides an intensive overview of flame retardant coating systems. The occurrence of flame due to thermal degradation of the polymer substrate as a result of overheating is one of the major concerns. Hence, coating is the best solution to this problem as it prevents the substrate from igniting the flame. In this review, the descriptions of several classifications of coating and their relation to thermal degradation and flammability were discussed. The details of flame retardants and flame retardant coatings in terms of principles, types, mechanisms, and properties were explained as well. This overview imparted the importance of intumescent flame retardant coatings in preventing the spread of flame via the formation of a multicellular charred layer. Thus, the intended intumescence can reduce the risk of flame from inherently flammable materials used to maintain a high standard of living. [ABSTRACT FROM AUTHOR]

Published

2022

3. Performance Analysis of Full Assembly Glass Fiber-Reinforced Polymer Composite Cross-Arm in Transmission Tower.

Author

Syamsir, Agusril, Nadhirah, Afiqah, Mohamad, Daud, Beddu, Salmia, Asyraf, Muhammad Rizal Muhammad, Itam, Zarina, and Anggraini, Vivi

Subjects

GLASS-reinforced plastics, WIRE, SAFETY factor in engineering, GLASS fibers, WIND pressure, QUALITY of service

Abstract

The usage of glass fiber reinforced polymer (GFRP) composite cross-arms in transmission towers is relatively new compared to wood timber cross-arms. In this case, many research works conducted experiments on composite cross-arms, either in coupon or full-scale size. However, none performed finite element (FE) analyses on full-scale composite cross-arms under actual working load and broken wire conditions. Thus, this work evaluates the performance of glass fiber reinforced polymer (GFRP) composite cross-arm tubes in 275 kV transmission towers using FE analysis. In this study, the performance analysis was run mimicking actual normal and broken wire conditions with five and three times more than working loads (WL). The full-scale assembly load test experiment outcomes were used to validate the FE analysis. Furthermore, the mechanical properties values of the GFRP composite were incorporated in simulation analysis based on the previous experimental work on coupons samples of GFRP tubes. Additionally, parametric studies were performed to determine the ultimate applied load and factor of safety for both normal and broken wire loading conditions. This research discovered that the GFRP composite cross-arm could withstand the applied load of five times and three times working load (WL) for normal and broken wire conditions, respectively. In addition, the factor of safety of tubes was 1.08 and 1.1 for normal and broken wire conditions, respectively, which can be considered safe to use. Hence, the composite cross-arms can sustain load two times more than the design requirement, which is two times the working load for normal conditions. In future studies, it is recommended to analyze the fatigue properties of the composite due to wind loading, which may induce failure in long-term service. [ABSTRACT FROM AUTHOR]

Published

2022

4. The Versatility of Polymeric Materials as Self-Healing Agents for Various Types of Applications: A Review.

Author

Nik Md Noordin Kahar, Nik Nur Farisha, Osman, Azlin Fazlina, Alosime, Eid, Arsat, Najihah, Mohammad Azman, Nurul Aida, Syamsir, Agusril, Itam, Zarina, and Abdul Hamid, Zuratul Ain

Subjects

SELF-healing materials, CARDIOVASCULAR system, MOLECULAR interactions, SELF-efficacy

Abstract

The versatility of polymeric materials as healing agents to prevent any structure failure and their ability to restore their initial mechanical properties has attracted interest from many researchers. Various applications of the self-healing polymeric materials are explored in this paper. The mechanism of self-healing, which includes the extrinsic and intrinsic approaches for each of the applications, is examined. The extrinsic mechanism involves the introduction of external healing agents such as microcapsules and vascular networks into the system. Meanwhile, the intrinsic mechanism refers to the inherent reversibility of the molecular interaction of the polymer matrix, which is triggered by the external stimuli. Both self-healing mechanisms have shown a significant impact on the cracked properties of the damaged sites. This paper also presents the different types of self-healing polymeric materials applied in various applications, which include electronics, coating, aerospace, medicals, and construction fields. It is expected that this review gives a significantly broader idea of self-healing polymeric materials and their healing mechanisms in various types of applications. [ABSTRACT FROM AUTHOR]

Published

2021