Evaluation of Microstructure, Phases, and Mechanical Properties of Aged Porcelain Insulator

Jun-Young Cho; Woo-Chan Jin; Sung-Hwan Bae; Chan Park

Korean Journal of Materials Research, Vol.29, No.3, 137-142, March, 2019

DOI10.3740/MRSK.2019.29.3.137 Export Citation

Evaluation of Microstructure, Phases, and Mechanical Properties of Aged Porcelain Insulator

Jun-Young Cho, Woo-Chan Jin, Sung-Hwan Bae¹, and Chan Park^†

Department of Materials Science and Engineering, Seoul National University, Seoul 08826, Republic of Korea
¹Nano Materials Science and Engineering, Kyungnam University, Changwon 51767, Republic of Korea

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The microstructure, phase, and mechanical properties of three aged porcelain insulators which were manufactured in different years (1973, 1995 and 2008) and which were used in the field for different amounts of time, were investigated. With X-ray 3D computed tomography (CT), defects with ~mm size can be detected without destroying the aged insulators. Defects of small specimens, which are cut from the aged insulators and polished, are analyzed with optical and scanning electron microscopy (OM and SEM), and defects of um size are detected by OM and SEM. The number and size of defects in all the aged insulators are similar. Porcelain insulators manufactured in 1973 contain more SiO2 (quartz and cristobalite) than those manufactured in 2008. Those manufactured in 2008 contain more Al2O3 than those manufactured earlier. The Vickers hardness of the insulator manufactured in 1973 has the lowest value. The formation of the cristobalite (SiO2) in the insulator manufactured in 1973 which can come from the phase transformation of quartz can cause stress in the insulator by formation of microcracks, which can lead to the low hardness of the insulator.

Keywords:aged porcelain insulator;microstructure;X-ray CT;mechanical property

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[2] Vaillancourt G, Bellerive J, St-Jean M, Jean C, IEEE Trans. Power Delivery, 9, 208 (1994)

[3] Wang X, Kumagai S, Kobayashi K, Yoshimura N, IEEJ Trans. Fund. Mater, 118, 502 (1998)

[4] Schneider HM, Hall JF, Karady G, Renowden J, IEEE Trans. Power Deliv., 4, 2214 (1989)

[5] Lambeth P, Proc. Inst. Electr. Eng., 118, 1107 (1971)

[6] Schneider H, Guidi W, Burnham J, Gorur R, Hall J, IEEE Trans. Power Deliv., 8, 325 (1993)

[7] Karady GG, Shah M, Brown R, IEEE Trans. Power Deliv., 10, 1965 (1995)

[8] Cherney E, IEEE PAS., 102, 2765 (1983)

[9] Cherney E, Hooton R, IEEE Trans. Power Deliv., 2, 249 (1987)

[10] Chandrasekar S, Kalaivanan C, Cavallini A, Montanari GC, IEEE Trans. Dielectr. Electr. Insul., 16, 574 (2009)

[11] Reynders J, Jandrell I, Reynders S, IEEE Trans. Dielectr. Electr. Insul., 6, 620 (1999)

[12] Pohlman JC, Davis CR, in 7th Int'l. Conf. Transmission and Distribution Construction and Live Line Maintenance (ESMO-95), p.149, Columbus, OH, USA (1995).

[13] Mishra A, Gorur R, Venkataraman S, IEEE Trans. Dielectr. Electr. Insul., 15, 467 (2008)

[14] Nyamupangedengu C, Luhlanga L, Letlape T, in IEEE Conf. Power Eng. Soc. Exposition., South Africa (2007).

[15] Ha H, Han S, Lee J, IEEE Trans. Instrum. Meas., 61, 267 (2012)

[16] Cheng Y, Li C, Liu B, Proc. IEEE 8th Int. Conf. on Properties and Applications of Dielectric Materials., p.615, Bali, Indonesia (2006).

[17] Cherney E, Baker A, Kuffel J, Lodi Z, Phillips A, Powell D, Stewart G, IEEE Trans. Power Deliv., 29, 275 (2014)

[18] Rawat A, Gorur R, IEEE Trans. Dielectr. Electr. Insul., 16, 107 (2009)

[19] Liebermann J, Am. Ceram. Soc. Bull., 82, 39 (2003)

[20] Silva PP, Shinohara AH, Pacheco AP, Filho ZPC, Monteiro SL, Mater. Trans., 53, 617 (2012)

[21] Carbajal L, Rubio-Marcos F, Bengochea M, Fernandez J, J. Eur. Ceram. Soc., 27, 4065 (2007)

[22] Carty WM, Pinto BM, Ceram. Eng. Sci. Proc., 23, 95 (2002)

[23] Islam RA, Chan YC, Islam MF, Mater. Sci. Eng. B-Solid State Mater. Adv. Technol., 106, 132 (2004)