Analysis of Last Development Results for High Voltage Circuit-breakers Using New G3 Gas

Robin-Jouan, P.; Bousoltane, K.; Kieffel, Yannick; Trépanier, Jean‐Yves; Camarero, R.; Arabi, Sina; Pernaudat, Guillaume

doi:10.14311/ppt.2017.2.157

Cited by 4 publications

(2 citation statements)

References 2 publications

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“…However, only a limited selection remains in the actual investigations. Gas mixtures containing fluoro-nitriles (C 4 F 7 N) or fluoro-ketones (C 5 F 10 O) as minority components (<20 %) have been identified as most promising alternatives to SF in high-voltage gas-insulated switchgear applications, because of their low global warming potential together with their dielectric strength values being comparable to SF 6 [5][6][7]. Due to high boiling points (at 1 bar) of the fluoro-ketones (27 • C) and fluoro-nitriles (-4.7 • C), gas mixtures with carbon dioxide CO 2 as buffer gas prevent liquefaction at temperatures below -30 • C. One of the most promising alternatives that has less limitations concerning temperature range and greenhouse effect but reasonable electrical insulation is CO 2 [8][9][10].…”

Section: Introductionmentioning

confidence: 99%

Ablation-Dominated Arcs in CO2 Atmosphere - Part I: Temperature Determination near Current Zero

Methling¹,

Khakpour²,

Götte³

et al. 2020

Preprint

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Wall–stabilized arcs dominated by nozzle–ablation are key elements of self–blast circuit breakers. In the present study, high–current arcs were investigated using a model circuit breaker (MCB) in CO2 as gas alternative to SF6 and in addition a long polytetrafluoroethylene nozzle under ambient conditions for stronger ablation. The assets of different methods for optical investigation were demonstrated, e.g. high-speed imaging with channel filters and optical emission spectroscopy. Particularly the phase near current zero (CZ) crossing was studied in two steps. In the first step using high-speed cameras, radial temperature profiles have been determined until 0.4 ms before CZ in the nozzle. Broad temperature profiles with a maximum of 9400 K have been obtained from analysis of fluorine lines. In the second step, the spectroscopic sensitivity was increased using an intensified CCD camera, allowing single-shot measurements until few microseconds before CZ in the MCB. Ionic carbon and atomic oxygen emission were analyzed using absolute intensities and normal maximum. The arc was constricted and the maximum temperature decreased from &gt;18000 K at 0.3 ms to about 11000 K at 0.010 ms before CZ. The arc plasma needs about 0.5-1.0 ms after both the ignition phase and the current zero crossing to be completely dominated by the ablated wall material.

show abstract

Section: Introductionmentioning

confidence: 99%

Ablation-Dominated Arcs in CO2 Atmosphere - Part I: Temperature Determination near Current Zero

Methling¹,

Khakpour²,

Götte³

et al. 2020

Preprint

View full text Add to dashboard Cite

show abstract

“…However, only a limited selection remains in the actual investigations. Gas mixtures containing fluoro-nitriles (C 4 F 7 N) or fluoro-ketones (C 5 F 10 O) as minority components (<20%) have been identified as the most promising alternatives to SF 6 in high-voltage gas-insulated switchgear applications because of their low global warming potential together with their dielectric strength values being comparable to SF 6 [5][6][7]. Due to high boiling points (at 1 bar) of the fluoro-ketones (27 • C) and fluoro-nitriles (−4.7 • C), gas mixtures with carbon dioxide CO 2 as buffer gas prevent liquefaction at temperatures below −30 • C. One of the most promising alternatives that has less limitations concerning temperature range and greenhouse effect but reasonable electrical insulation is CO 2 [8][9][10].…”

Section: Introductionmentioning

confidence: 99%

Ablation-Dominated Arcs in CO2 Atmosphere—Part I: Temperature Determination near Current Zero

et al. 2020

View full text Add to dashboard Cite

Wall-stabilized arcs dominated by nozzle–ablation are key elements of self-blast circuit breakers. In the present study, high-current arcs were investigated using a model circuit breaker (MCB) in CO2 as a gas alternative to SF6 (gas sulfur hexafluoride) and in addition a long polytetrafluoroethylene nozzle under ambient conditions for stronger ablation. The assets of different methods for optical investigation were demonstrated, e.g., high-speed imaging with channel filters and optical emission spectroscopy. Particularly the phase near current zero (CZ) crossing was studied in two steps. In the first step using high-speed cameras, radial temperature profiles have been determined until 0.4 ms before CZ in the nozzle. Broad temperature profiles with a maximum of 9400 K have been obtained from analysis of fluorine lines. In the second step, the spectroscopic sensitivity was increased using an intensified CCD camera, allowing single-shot measurements until few microseconds before CZ in the MCB. Ionic carbon and atomic oxygen emission were analyzed using absolute intensities and normal maximum. The arc was constricted and the maximum temperature decreased from >18,000 K at 0.3 ms to about 11,000 K at 0.010 ms before CZ. The arc plasma needs about 0.5–1.0 ms after both the ignition phase and the current zero crossing to be completely dominated by the ablated wall material.

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Production of Graphite During the Extinguishing Arc with New SF6 Alternative Gases

André-Maouhoub¹,

André²,

Makhlouf³

et al. 2020

Plasma Chem Plasma Process

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Analysis of Last Development Results for High Voltage Circuit-breakers Using New G3 Gas

Cited by 4 publications

References 2 publications

Ablation-Dominated Arcs in CO2 Atmosphere - Part I: Temperature Determination near Current Zero

Ablation-Dominated Arcs in CO2 Atmosphere - Part I: Temperature Determination near Current Zero

Ablation-Dominated Arcs in CO2 Atmosphere—Part I: Temperature Determination near Current Zero

Production of Graphite During the Extinguishing Arc with New SF6 Alternative Gases

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