Electrical treeing characteristics of alumina‐, zinc oxide‐, and organoclay‐nanoparticle‐filled<scp>XLPE</scp>nanocomposites

Hamzah, Muhammad Safwan; Jaafar, Mariatti; Ismail, Hanafi; Jamil, Mohamad Kamarol Mohd

doi:10.1002/pen.25883

Cited by 2 publications

References 24 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

Study on the Inhibition Characteristics of Electrical Trees by the Synergistic Effect of Layered MMT and Spherical SiO₂ in PE

Wang,

Liu,

et al. 2024

Polymers for Advanced Techs

View full text Add to dashboard Cite

In power equipment insulations subjected to prolonged high‐field conditions, the formation of electrical trees is a common occurrence, significantly impacting the service life and operational reliability of the equipment. In this paper, PE composites were prepared by melt blending method using layered nano‐MMT and spherical nano‐SiO2 as fillers to enhance the suppression of electrical trees. The microscopic properties of PE composites were characterized by scanning electron microscopy (SEM), polarizing microscopy (PLM), (DSC). The electrical tree of composites was conducted by the electrical tree test system. Subsequently, the synergistic inhibition of PE by nanoparticles with different morphologies was investigated. Key insights derived from the experimental findings are as follows: first, when MMT is doped with PE, due to the layered structure characteristics, the electro‐acoustic coupling effect, and the coulomb blockade effect, the complexity and complicacy of electron motion trajectory are increased, then the breakdown field strength EB of MMT/PE is increased by 5.74% compared with PE. Thus, the length of electrical trees at the retardation stage decreased by 175 μm, and their morphology changed from branch to bushy branch. Second, when layered MMT and spherical SiO2 are doped in PE simultaneously, the electron travel becomes more complex and tortuous due to the synergistic effect of nanoparticles. Compared with PE, EB of MMT/SiO2/PE is increased by 9.95%, the length entering the retardation stage of electrical trees decreases by 240 μm, and their morphology changes from branch to cluster like. Finally, microscopic and macroscopic results reveal that the combination of layered MMT and spherical SiO2 can effectively suppress the electrical tree growth in PE. These findings underscore the potential of utilizing nanostructured fillers to mitigate the development and expansion of electrical trees in polyethylene insulations, thereby enhancing the overall performance and reliability of power equipment.

show abstract

Study on the Inhibition Characteristics of Electrical Trees by the Synergistic Effect of Layered MMT and Spherical SiO₂ in PE

Wang,

Liu,

et al. 2024

Polymers for Advanced Techs

View full text Add to dashboard Cite

show abstract

Modelling the Electric Field Distribution in Polyethylene Nano-Composite to Investigate Electrical Treeing Initiation Using Finite Element Method

Azhar¹,

Amin²

2022

The 7th International Electrical Engineering Conference

View full text Add to dashboard Cite

Electrical treeing characteristics of alumina‐, zinc oxide‐, and organoclay‐nanoparticle‐filledXLPEnanocomposites

Cited by 2 publications

References 24 publications

Study on the Inhibition Characteristics of Electrical Trees by the Synergistic Effect of Layered MMT and Spherical SiO₂ in PE

Study on the Inhibition Characteristics of Electrical Trees by the Synergistic Effect of Layered MMT and Spherical SiO₂ in PE

Modelling the Electric Field Distribution in Polyethylene Nano-Composite to Investigate Electrical Treeing Initiation Using Finite Element Method

Contact Info

Product

Resources

About

Electrical treeing characteristics of alumina‐, zinc oxide‐, and organoclay‐nanoparticle‐filledXLPEnanocomposites

Cited by 2 publications

References 24 publications

Study on the Inhibition Characteristics of Electrical Trees by the Synergistic Effect of Layered MMT and Spherical SiO2 in PE

Study on the Inhibition Characteristics of Electrical Trees by the Synergistic Effect of Layered MMT and Spherical SiO2 in PE

Modelling the Electric Field Distribution in Polyethylene Nano-Composite to Investigate Electrical Treeing Initiation Using Finite Element Method

Contact Info

Product

Resources

About

Study on the Inhibition Characteristics of Electrical Trees by the Synergistic Effect of Layered MMT and Spherical SiO₂ in PE

Study on the Inhibition Characteristics of Electrical Trees by the Synergistic Effect of Layered MMT and Spherical SiO₂ in PE