Abstract
This paper leads to synthesize new electrical insulating polyvinyl chloride nanocomposites to achieve more cost-effective, energy-effective and hence innovate better environmental materials using nanotechnology techniques. It has been investigated simulations and experimental work for studying the effect of cost-fewer nanoparticles on electric properties (resistance and susceptance) of the new resin system nanocomposites. Cambridge Engineering Selector program was carried out the electrical/mechanical predictable models for the suggested materials. In addition, it has been compared between electrical, thermal and mechanical characterization of new polyvinyl chloride nanocomposites with the same unfilled industrial materials within variant frequencies up to 1 kHz.
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Hosier IL, Vaughan AS, Swingler SG (2002) The Effects of measuring technique and sample preparation on the breakdown strength of polyethlyene. IEEE Trans Diekctrics Electr Insul 9(3):353–361
Zhang Chao, Mori Tatsuo, Mizutani Teruyoshi, lshioka MitSUgU (2003) Effects of manufacturing; technolon on electrical breakdown and morpholoiof thin flms of low density polyethylene blended with polypropylene copolymer. IEEE Trans Diekctrics Electr Insul 10(3):435–443
Dang Zhimin, Shen Yang, Fan Lizhen, Cai Ning, Nan Cewen, Zhao Shujin (2003) Dielectric properties of carbon fiber filled low-density polyethylene. J Appl Phys 93(9):5543–5545
Hong JI, Schadler LS, Siegel RW, Martensson E (2003) Rescaled electrical properties of ZnO/low density polyethylene nanocomposites. Appl Phys Lett 82(12):1956–1958
Aman A, Yaacob MM, Alsaedi MA, Ibrahim KhA (2013) Polymeric composite based on waste material for high voltage outdoor application. Int J Electr Power Energy Syst 45(1):346–352
Sarathi R, Umamaheswari R (2013) Understanding the partial discharge activity generated due to particle movement in a composite insulation under AC voltages. Int J Electr Power Energy Syst 48:1–9
Mobarak Youssef A, Bassyouni M, Almatawa M (2013) Materials selection, synthesis, and dielectrical properties of pvc nanocomposites. Adv Mater Sci Eng 2013:1–6
McCalley JD, Krishnan V (2014) A survey of transmission technologies for planning long distance bulk transmission overlay in US. Int J Electr Power Energy Syst 54:559–568
da Silva DA et al (2013) Reliability of directly-molded polymer surge arresters: degradation by immersion test versus electrical performance. Int J Electr Power Energy Syst 53:488–498
Tanaka T, Montanari GC, Mülhaupt R (2004) Polymer nanocomposites as dielectrics and electrical insulation-perspectives for processing technologies, material characterization and future applications. IEEE Trans Dielectr Electr Insul 11:763–784
Montanari GC, Fabiani D, Palmieri F, Kaempfer D, Thomann R, Mülhaupt R (2004) Modification of electrical properties and performance of eva and pp insulation through nanostructure by organophilic silicates. IEEE Trans Dielectr Electr Insul 11:754–762
Yamamoto Yoshimi, Ikeda Masaaki, Tanaka Yasuhiro (2004) Electrical properties and morphology of polyethylene produced with a novel catalyst. IEEE Trans Dielectr Electr Insul 11(5):881–890
Chao Z, Ralf M, Stevens Gary C (2005) Dielectric properties of epoxy and polyethylene nanocomposites. In: IEEE, proceedings of international symposium on electrical insulating materials, June 5–9, Kitakyushu, Japan
Dong X, Yin Y, Li Z, Jiang X (2006) Low frequency polarization behavior of nano-Ag/low-density polyethylene composite. In: IEEE, international conference on properties and applications of dielectric materials
Ulzutuev AN, Ushakov NM (2008) Investigation of the charge localization processes in the metal polymeric materials based on the low density polyethylene matrix with stabilized nanoparticles. In: IEEE, international conference on advanced optoelectronics and lasers, CAOL, 435–437
Hinata K, Fujita A, Tohyama K, Murata Y (2006) Dielectric properties of LDPE/MgO nanocomposite material under AC high field. In: IEEE, annual report conference on electrical insulation and dielectric phenomena, 313–316
Thabet A, Mobarak YA (2012) A model for dielectric characterization of nanocomposite polymeric industrial materials. J Eng Sci 40(5):1375–1388
Thabet A, Mobarak Youssef A (2012) Experimental study for dielectric strength of new nanocomposite polyethylene industrial materials. Int J Electr Eng Tech (IJEET) 3(1):553–564 (Jan–June 2012)
Thabet A, Mobarak YA (2010) Dielectric characteristics of new nano-composite industrial materials. In: Proceedings of the 2010 international conference on high voltage engineering and application (ICHVE), New Orleans, LA, 11–14 Oct 2010. IEEE, pp 568–571. doi:10.1109/ICHVE.2010.5640767
Thabet A (2013) Experimental investigation on thermal electric and dielectric characterization for polypropylene nanocomposites using cost-fewer nanoparticles. Int J Electr Eng Technol (IJEET) 4(2):1–12 (IAEMEMarch–April 2013)
Gouda O, Thabet A, Mubarak YA, Samir M (2014) Nanotechnology effects on space charge relaxation measurements for polyvinyl chloride thin films. Int J Electr Eng Inf (IJEEI) Eng Technol 6(1):1–12 (March, 2014)
Wang X, He HQ, Tu DM, Lei C, Du QG (2008) Dielectric properties and crystalline morphology of low density polyethylene blended with metallocene catalyzed polyethylene. IEEE Trans Dielectr Electr Insul 15(2):319–326
Ishimotol K, Tanaka2 T, Ohki 1 Y, Sekiguchi Y, Murata Y, Gosyowaki M (2008) Comparison of dielectric properties of low-density polyethylene/MgO composites with different size fillers. In: IEEE Annual Report Conference on Electrical Insulation Dielectric Phenomena, pp. 208–211
Kuznetsova IE, Zaitsev BD, Shikhabudinov AM (2010) Elastic and viscous properties of nanocomposite films based on low-density polyethylene. IEEE Trans Ultrason Ferroelectr Freq Control 57(9):2099–2102
Shengtao L, Guilai Y, Fengyan N, Suna B, Jianying L, Tuo Z (2010) Investigation on the dielectric properties of nanotitanium dioxide—low density polyethylene composites. In: IEEE, international conference on solid dielectrics, Potsdam, Germany, July 4–9, pp 1-4
Ciuprina F, Plesa I, Notingher PV, Rain P, Zaharescu T, Panaitescu D (2010) Dielectric properties of LDPE-SiO2 nanocomposites. In: IEEE, international conference on solid dielectrics, Potsdam, Germany, July 4–9, 1–4
Fang P, Qiu X, Wirges W, Gerhard R (2010) Polyethylene-naphthalate (PEN) ferroelectrets: cellular structure, piezoelectricity and thermal stability. IEEE Trans Dielectr Electr Insul 17(4):1079–1087
Thabet A, Mobarak YA (2012) Experimental study for dielectric strength of new nanocomposite polyethylene industrial materials. Int J Electr Eng Technol (IJEET) 3(1):353–364
Thabet A (2014) Experimental investigation on thermal dielectric characterization for new PMMA nanocomposites. Int J Electr Eng Inf (IJEEI) 6(4):631–643
Thabet A (2015) Experimental enhancement for dielectric strength of polyethylene insulation materials using cost-fewer nanoparticles. Int J Electr Power Energy Syst (IJEPES) 64:469–475
Thabet A (2015) Experimental verification for improving dielectric strength of polymers by using clay nanoparticles. Adv Electr Electron Eng J 13(2):182–190
Thabet A (2016) Thermal experimental verification on effects of nanoparticles for enhancing electric and dielectric performance of polyvinyl chloride. J Int Meas Confed (IMEKO) 89:28–33
Thabet A (2016) Theoretical analysis for effects of nanoparticles on dielectric characterization of electrical industrial materials. Electr Eng 1–7. doi:10.1007/s00202-016-0375-4
Acknowledgments
The present work was supported by Nanotechnology Research Center in Aswan University; this center is established under supervision of the Science and Technology Development Fund (STDF), Egypt, Grant No: Project ID 505, 2009-2011.
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Thabet, A., Mobarak, Y. The effect of cost-fewer nanoparticles on the electrical properties of polyvinyl chloride. Electr Eng 99, 625–631 (2017). https://doi.org/10.1007/s00202-016-0392-3
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DOI: https://doi.org/10.1007/s00202-016-0392-3