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Temperature measurement and arc rotation observation of spiral-type contact

In this paper, the authors report the relation between the arc rotation and the temperature of contact surface. The interruption tests were performed with the vacuum chamber equipped with spiral-type contacts. The rotation of vacuum arc was observed with high speed cameras from two different directi...

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Main Authors: Donen, Taiki, Abe, Junichi, Tsukima, Mitsuru, Takai, Yuichi, Miki, Shinichi, Ochi, Satoshi
Format: Conference Proceeding
Language:English
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Abe, Junichi
Tsukima, Mitsuru
Takai, Yuichi
Miki, Shinichi
Ochi, Satoshi
description In this paper, the authors report the relation between the arc rotation and the temperature of contact surface. The interruption tests were performed with the vacuum chamber equipped with spiral-type contacts. The rotation of vacuum arc was observed with high speed cameras from two different directions. The temperature of the contact surface was estimated from emission intensity measured by high speed camera with the infrared band-pass filter. Local surface overheating occurs with slow-speed arc rotation, whereas surface temperature rises homogeneously with high-speed arc rotation. In addition, differences of arc behavior certainly effects on the interrupting performance.
doi_str_mv 10.1109/DEIV.2016.7748725
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identifier EISSN: 1093-2941
ispartof 2016 27th International Symposium on Discharges and Electrical Insulation in Vacuum (ISDEIV), 2016, Vol.1, p.1-4
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language eng
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source IEEE Xplore All Conference Series
subjects Anodes
Cameras
Ignition
Interrupters
Temperature distribution
Temperature measurement
Vacuum arcs
title Temperature measurement and arc rotation observation of spiral-type contact
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