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"Volume resistivity"

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"Volume resistivity"

Effect of Temperature on Current Density of Nano Composite XLPE Material
Hyun-jung Jung, Yi-seul Yang, Jin-ho Nam, Gi-joon Nam, Dong-wook Kim
J Electr Electron Mater 2019;32(5):413-417.   Published online September 1, 2019
In this study, the volume resistivity of XLPE materials with various voltage ratings was discussed. The volume resistivity of the developed XPLE nanocomposite was measured, and the conductivity mechanism of the material was also examined. The ASTM D 257 and IEC 60093 measurement methods were used for these tests. The equipment was designed to measure up to a temperature of 200℃, and the electrode structure was designed to maintain the thickness and temperature uniformity of the sample. The conductivity of the sample decreased with temperature, and the samples reached saturation within 500s, after which the conductivity leveled off. By analyzing the current density and the electric field, we can well explain the electric conductivity behavior of our sample with the Schottky mechanism.
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Insulation Materials : Electrical and Mechanical Properties of Semiconductive Composites for DC Power Cable
Ki Joung Lee, Bum Sik Seo, Jong Seok Yang, Baeg Yong Seong, Dae Hee Park
J Electr Electron Mater 2013;26(2):119-125.   Published online February 1, 2013
In this paper, semiconducting shield specimens for a DC cable is fabricated and characterized by measurement of volume resistance, tensile strength, and the coefficient of expansion to show the electrical and mechanical characteristics of the semiconducting shield. Due to the PTC phenomenon, the volume resistance at 25℃ increases rapidly in comparison to the volume resistance at 90℃. Since the compounding ratio of carbon black is low, the tensile strength and density become lower and the coefficient of expansion is increased. As the general specification of the tensile strength and density is 0.8 kgf/㎟ and 150%, respectively, the fabricated specimen in this paper has excellent mechanical characteristic.
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High Voltage and Discharge Engineering : Temperature Dependence of Volume Resistivity on Epoxy Nano-composites
Chang Hoon Kim, Young Sang Lee, Yong Gil Kang, Hee Doo Park, Jong Yeol Shin, Jin Woong Hong
J Electr Electron Mater 2011;24(10):834-838.   Published online October 1, 2011
This research shows the electrical characteristic using excellent epoxy nano-composite of MgO 5.0 wt% and SiO2 0.4 wt% in mechanical strength test depending on nano-additive. First of all, volume resistance depending on nano-additive and temperature using high resistance meter (HP. 4329A) by increasing 10, 100, 1,000 V of applying voltage was measured. Moreover, temperature range of 25~120℃ with virgin sample was tested using TO-9B oven by Ando Company. The result showed that virgin and the samples added with MgO and SiO2 had similar value of volume resistance in low temperature and low electric field region and reduced with slow slope. The nano-composite`s volume resistance of sample added with MgO and SiO2 had higher value than virgin sample`s volume resistance in high temperature region more than 80℃. Moreover, the slope has steeply reduced. The volume resistance of sample added with MgO 5.0 wt% was 8.38×10(13) Ω·cm and it was 6.8 times more than virgin sample in high temperature at 120℃. The insulation characteristics were constant although filler has changed in low temperature region. But, in high temperature region, the value of volume resistance of sample with MgO 5.0 wt% was 7.6 times more than the virgin sample`s volume resistance.
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Analysis of Electric Field Distribution and Characteristics of Volume Resistivity in HDPE/EVA Film for Recycling
Hung Kyu Lee, Kee Joe Lim, Yong Joo Kim
J Electr Electron Mater 2008;21(9):801-807.   Published online September 1, 2008
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