| Abstract |
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Insulators are required in a power system network to provide ground isolation and mechanical support for line conductors. Different kinds of insulators are being utilized in transmission lines and substations. Many power utilities are now using non-ceramic insulators like Cross-Linked Polyethylene (XLPE) composite insulators. This research aims to develop XLPE nanocomposites for use as power cable insulation in industrial applications. To attain this, XLPE nanocomposites were made with five different loadings of Titanium Dioxide (TiO2) nanoparticles: 0, 1, 3, 5 and 7 weight (wt)% in the presence of a Dicymul Peroxide agent, which is used to minimize nanoparticle agglomeration and enhance compatibility within the polymer matrix. A Scanning Electron Microscope (SEM) was utilized to investigate the structure and distribution of nanoparticles inside the XLPE. The dielectric properties of these developed XLPE/TiO2 nanocomposites were studied by measuring the AC dielectric strength with a regulated high voltage testing transformer (50Hz). The mechanical properties such as tensile strength and elongation at break were also assessed. The thermal properties of nanocomposites were examined using Thermo Gravimetric Analysis (TGA). When TiO2 nanoparticles are included in the XLPE matrix, the dielectric strength of XLPE/TiO2 is shown to be higher than pure XLPE. This indicates that XLPE/TiO2 nanocomposites have higher dielectric characteristics, with a TiO2 filler loading of 5 wt% being the best. This might be because TiO2 nanoparticles have a low surface energy, which prevents them from clustering together. Also, the addition of nano TiO2 improves the mechanical and thermal characteristics of XLPE nanocomposites. XLPE with 5 wt% nano TiO2 showed the best improvement in different properties. |
| References |
: |
|
[1]Huang X, Ma Z, Jiang P, Kim C, Liu F, Wang G, et al. Influence of silica nanoparticle surface treatments on the water treeing characteristics of low density polyethylene. In 9th international conference on the properties and applications of dielectric materials 2009 (pp. 757-60). IEEE.
|
| [Crossref] |
[Google Scholar] |
|
[2]Li X, Liu X, Xu M, Xie D, Cao X, Wang X, et al. Influence of compatibilizers on the water-tree property of montmorillonite/cross-linked polyethylene nanocomposites. In international conference on the properties and applications of dielectric materials 2012 (pp. 1-4). IEEE.
|
| [Crossref] |
[Google Scholar] |
|
[3]Li X, Xu M, Xin L, Xie D, Cao X. Study of montmorillonite on morphology and water treeing behavior in crosslinking polyethylene. In proceedings of international symposium on electrical insulating materials 2011(pp. 205-8). IEEE.
|
| [Crossref] |
[Google Scholar] |
|
[4]Matthews FL, Rawlings RD. Composite materials: engineering and science. Elsevier; 1999.
|
| [Google Scholar] |
|
[5]https://en.wikipedia.org/wiki/Nanocomposite. Accessed 9 December 2015.
|
|
[6]Tanaka T, Montanari GC, Mulhaupt R. Polymer nanocomposites as dielectrics and electrical insulation-perspectives for processing technologies, material characterization and future applications. IEEE Transactions on Dielectrics and Electrical Insulation. 2004; 11(5):763-84.
|
| [Crossref] |
[Google Scholar] |
|
[7]Camargo PH, Satyanarayana KG, Wypych F. Nanocomposites: synthesis, structure, properties and new application opportunities. Materials Research. 2009; 12(1):1-39.
|
| [Crossref] |
[Google Scholar] |
|
[8]Lewis TJ. Nanometric dielectrics. IEEE Transactions on Dielectrics and Electrical Insulation. 1994; 1(5):812-25.
|
| [Crossref] |
[Google Scholar] |
|
[9]Frechette MF, Trudeau ML, Alamdar HD, Boily S. Introductory remarks on nanodielectrics. IEEE Transactions on Dielectrics and Electrical Insulation. 2004; 11(5):808-18.
|
| [Crossref] |
[Google Scholar] |
|
[10]Cao Y, Irwin PC, Younsi K. The future of nanodielectrics in the electrical power industry. IEEE Transactions on Dielectrics and Electrical Insulation. 2004; 11(5):797-807.
|
| [Crossref] |
[Google Scholar] |
|
[11]Guastavino F, Briano L, Gallesi F, Torello E. Corona resistant insulating systems characterization for low voltage rotating machine. In conference on electrical insulation and dielectric phenomena 2019 (pp. 694-7). IEEE.
|
| [Crossref] |
[Google Scholar] |
|
[12]Henk PO, Kortsen TW, Kvarts T. Increasing the electrical discharge endurance of acid anhydride cured DGEBA epoxy resin by dispersion of nanoparticle silica. High Performance Polymers. 1999; 11(3):281-96.
|
| [Google Scholar] |
|
[13]Singha S, Thomas MJ. Dielectric properties of epoxy nanocomposites. IEEE Transactions on Dielectrics and Electrical Insulation. 2008; 15(1):12-23.
|
| [Crossref] |
[Google Scholar] |
|
[14]Nelson JK, Fothergill JC. Internal charge behaviour of nanocomposites. Nanotechnology. 2004; 15(5).
|
| [Crossref] |
[Google Scholar] |
|
[15]Nelson JK, Fothergill JC, Dissado LA, Peasgood W. Towards an understanding of nanometric dielectrics. In annual report conference on electrical insulation and dielectric phenomena 2002 (pp. 295-8). IEEE.
|
| [Crossref] |
[Google Scholar] |
|
[16]Bréchet Y, Cavaillé JY, Chabert E, Chazeau L, Dendievel R, Flandin L, et al. Polymer based nanocomposites: effect of filler‐filler and filler‐matrix interactions. Advanced Engineering Materials. 2001; 3(8):571-7.
|
| [Google Scholar] |
|
[17]Šupová M, Martynková GS, Barabaszová K. Effect of nanofillers dispersion in polymer matrices: a review. Science of Advanced Materials. 2011; 3(1):1-25.
|
| [Crossref] |
[Google Scholar] |
|
[18]Mansor NS, Nazar NS, Fairus M, Ishak D, Mariatti M, Halim HS, et al. Electrical treeing characteristics of XLPE material containing treated ZnO nano-filler. In international conference on robotics, vision, signal processing and power applications 2019 (pp. 305-11). Springer, Singapore.
|
| [Google Scholar] |
|
[19]Daskalopoulos K, Verginadis D, Yin Y, Danikas MG, Sarathi R. Surface discharges and flashover voltages: investigation of XLPE samples with SiO2 and Al2O3 nanoparticles. In international symposium on electrical insulating materials (ISEIM) 2020 (pp. 237-40). IEEE.
|
| [Google Scholar] |
|
[20]Wang S, Yu S, Xiang J, Li J, Li S. DC breakdown strength of crosslinked polyethylene based nanocomposites at different temperatures. IEEE Transactions on Dielectrics and Electrical Insulation. 2020; 27(2):482-8.
|
| [Crossref] |
[Google Scholar] |
|
[21]Abd RAB, Abd RMS, Ariffin AM, Ali NN, Abd GAB, Lau KY, et al. Influence of SiO2 and ZrO2 nanocomposite on the AC breakdown strength of cross-linked polyethylene (XLPE). In international conference on the properties and applications of dielectric materials (ICPADM) 2021(pp. 378-81). IEEE.
|
| [Crossref] |
[Google Scholar] |
|
[22]Thabet A, Mubarak YA, Bakry MJ. A review of nano-fillers effects on industrial polymers and their characteristics. International Journal of Engineering Science. 2011; 39:377-403.
|
| [Google Scholar] |
|
[23]Kołodziejczak-radzimska A, Jesionowski T. Zinc oxide—from synthesis to application: a review. Materials. 2014; 7(4):2833-81.
|
| [Crossref] |
[Google Scholar] |
|
[24]Chavali MS, Nikolova MP. Metal oxide nanoparticles and their applications in nanotechnology. SN Applied Sciences. 2019; 1(6):1-30.
|
| [Crossref] |
[Google Scholar] |
|
[25]Mohan AC, Renjanadevi B. Preparation of zinc oxide nanoparticles and its characterization using scanning electron microscopy (SEM) and X-ray diffraction (XRD). Procedia Technology. 2016; 24:761-6.
|
| [Crossref] |
[Google Scholar] |
|
[26]Siddiqi KS, Rahman AU, Husen A. Properties of zinc oxide nanoparticles and their activity against microbes. Nanoscale Research Letters. 2018; 13(1):1-3.
|
| [Crossref] |
[Google Scholar] |
|
[27]Abd RAB, Abd RMS, Ariffin AM, Ali NN, Abd GAB, Lau KY, et al. Investigation of BaTiO3 and TiO2 based nano-fillers on the space charge and electrical strength of cross-linked polyethylene (XLPE). In international conference on the properties and applications of dielectric materials 2021 (pp. 374-7). IEEE.
|
| [Crossref] |
[Google Scholar] |
|
[28]Eldesoky E, Said A, Nawar A, Abdallah M, Kamel S. High voltage cross-linked polyethylene insulator characteristics improvement using functionalized ZnO nanoparticles. Egyptian Journal of Chemistry. 2020; 63(12):4929-39.
|
| [Crossref] |
[Google Scholar] |
|
[29]Yu Q, Selvadurai AP. Mechanical behaviour of a plasticized PVC subjected to ethanol exposure. Polymer Degradation and Stability. 2005; 89(1):109-24.
|
| [Crossref] |
[Google Scholar] |
|
[30]Juliana NC, Chibuike NA, Josiah E. Evaluation of the thermal stability of poly (O–phenylenediamine)(PoPD) by thermogravimetric analysis (TGA). American Journal of Nanosciences. 2019; 5:18-22.
|
| [Google Scholar] |
|
[31]El-sayed NS, El-sakhawy M, Hesemann P, Brun N, Kamel S. Rational design of novel water-soluble ampholytic cellulose derivatives. International Journal of Biological Macromolecules. 2018; 114:363-72.
|
| [Crossref] |
[Google Scholar] |
|
[32]Huang C, Qian X, Yang R. Thermal conductivity of polymers and polymer nanocomposites. Materials Science and Engineering: R: Reports. 2018; 132:1-22.
|
| [Crossref] |
[Google Scholar] |
|
[33]Khan H, Amin M, Ali M, Iqbal M, Yasin M. Effect of micro/nano-SiO $ _ {2} $ on mechanical, thermal, and electrical properties of silicone rubber, epoxy, and EPDM composites for outdoor electrical insulations. Turkish Journal of Electrical Engineering & Computer Sciences. 2017; 25(2):1426-35.
|
| [Crossref] |
[Google Scholar] |
|
[34]Corcione CE, Frigione M. Characterization of nanocomposites by thermal analysis. Materials. 2012; 5(12):2960-80.
|
| [Crossref] |
[Google Scholar] |
|
[35]Nabinejad O, Sujan D, Rahman ME, Davies IJ. Determination of filler content for natural filler polymer composite by thermogravimetric analysis. Journal of Thermal Analysis and Calorimetry. 2015; 122(1):227-33.
|
| [Crossref] |
[Google Scholar] |
|
[36]Gao JG, Li X, Yang WH, Zhang XH. Space charge characteristics and electrical properties of micro-nano ZnO/LDPE composites. Crystals. 2019; 9(9):1-13.
|
| [Crossref] |
[Google Scholar] |
|
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