Fahim Abid scite author profile

When the pressure and temperature of a fluid exceed a critical point, the fluid enters into the supercritical region. In this region, the physical properties are believed to be in favor of a good current interruption medium. This study focuses on the arc voltage characteristics of nitrogen arcs burning inside cylindrical tubes at different filling pressures: 1 bar, 20 bar, 40 bar, and 80 bar, thus covering the supercritical region. Two different tube materials have been used in the experiments; alumina and PTFE. Arc voltages are measured for arcs burning inside tubes of 2, 4, 8, and 15 mm inner diameters. In addition, free-burning arcs have been investigated at the same filling pressures. The arc current was 150 A at 350 Hz throughout the study. The arc voltage is found to increase with decreasing inner diameter of the tube at atmospheric pressure. At higher filling pressures (i.e., 20 bar, 40 bar, 80 bar), however, such a simple relationship is not observed. The arc temperature and radius have been calculated based on the 'simple theory of free-burning arcs' and the 'two-zone ablation arc model'. The calculated arc radius decreases with increasing gas pressure. Furthermore, due to increased absorption of radiation at high filling pressures, ablation is found less significant for ultrahigh-pressure nitrogen arcs compared to atmospheric pressure arcs. This is in line with the observations from optical micrographs of the inner surfaces of the tubes exposed to arcs at different filling pressures.

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Interaction between grid-connected PV systems and LED lamps: Directions for further research on harmonics and supraharmonics

Busatto

Abid

Larsson

et al. 2016

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Effect of heat-treatment and sample preparation on physical properties of XLPE DC cable insulation material

Ghorbani¹,

Saltzer²,

Abid

et al. 2016

IEEE Trans. Dielect. Electr. Insul.

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Current interruption performance of ultrahigh-pressure nitrogen arc

Abid

Niayesh

Espedal

et al. 2020

J. Phys. D: Appl. Phys.

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In this paper, the influence of gas filling pressure on the current interruption performance of different switch configurations with electric arcs burning in nitrogen has been experimentally investigated. A synthetic circuit generating a current of 130 A at 190 Hz is used and the initial rate of rise of recovery voltage just after current zero is varied from 9.8 V/µs to 84.9 V/µs. To evaluate the effect of forced gas flow on current interruption performance, three different test arrangements are investigated: a simple contact configuration with a free-burning arc, a contact and a cylindrical nozzle setup (tube-constricted arc), and finally a self-blast arrangement where the arc is cooled by a gas flow near current zero. In each arrangement, three different filling pressures are mainly studied: 1, 20, and 40 bar, the latter being in the supercritical region. In all cases, the interelectrode gap is fixed at 50 mm. It is observed that the interruption performance deteriorates with increased filling pressure in the absence of forced gas flow. A higher post-arc current is observed for the arcs burning at high filling pressures (i.e. 20 and 40 bar) compared to at atmospheric pressure in cases with no or little forced cooling. On the other hand, a forced gas flow near the current zero reduces the post-arc current and improves the interruption performance also at high filling pressures. Little effect of the supercritical state on the interruption performance of nitrogen is observed. Under the above-mentioned test conditions, the majority of the failures at high filling pressure are observed to be of thermal re-ignition type.

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Fahim Abid

Arc Voltage Characteristics in Ultrahigh-Pressure Nitrogen Including Supercritical Region

Ultrahigh-Pressure Nitrogen Arcs Burning Inside Cylindrical Tubes

Interaction between grid-connected PV systems and LED lamps: Directions for further research on harmonics and supraharmonics

Effect of heat-treatment and sample preparation on physical properties of XLPE DC cable insulation material

Current interruption performance of ultrahigh-pressure nitrogen arc

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