Current interruption performance of ultrahigh-pressure nitrogen arc

Abid, Fahim; Niayesh, Kaveh; Espedal, Camilla; Støa-Aanensen, Nina Sasaki

doi:10.1088/1361-6463/ab7352

Cited by 8 publications

(10 citation statements)

References 34 publications

(45 reference statements)

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“…For instance, the current interruption performance at 20 bar for the tube constricted arrangements with 4 mm inner diameter, is observed to be worse than that at 1 bar, whereas 40 bar shows the best performance in the proposed N 2 CB model [50]. Compared with FB arcs, at higher pressures (5-30 bar), 3 cm nozzle length with 2 mm inner diameter in thc tot increases with p after 13 000 K, while decreases for temperatures less than 8 000 K in both 20 and 40 bar cases.…”

Section: Interruption Performance; Nozzle-pressure Effectsmentioning

confidence: 90%

“…Figure 21 depicts the measured values of V, P (voltage multiplied by current), and R (voltage divided by current) for 20 µm EEW with a sampling rate of 1.25 Msamples per second, 40 µm and 100 µm EEW with a sampling rate of 500 Msamples per second in the logarithmic scale. In contrast to the well-known pulse with dwell (current pause), a single electrical pulse is produced [48], which is usual for relatively low resistive metals like copper [49] although it is also possible to have a current pause with 25 µm EEW, (for instance see figure 4 in [50]). The heating process changes to an explosion after 76, 116, and 529 µs from the current injection corresponding to 25, 40, and 100 µm, respectively, which results in the change of the voltage slope.…”

Section: The Arc Metal Content For Different Wire Sizesmentioning

confidence: 99%

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Metal vapor content of an electric arc initiated by exploding wire in a model N₂ circuit breaker: simulation and experiment

Kadivar

Niayesh

Støa-Aanensen

et al. 2020

J. Phys. D: Appl. Phys.

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A conductive wire can explode by rapidly heating it to vaporization temperature by flowing a current through it. This process is utilized to generate high-temperature high-density plasmas. The temperature and pressure distributions at the time of the explosion are not easily measured. Moreover, the amount of metal vapor from the wire that remains within the arcing area is unknown. This work presents the whole-process model of a single-wire electrical explosion from solid-state to plasma formation. For this purpose, the voltage drop and resistance of the exploding copper wire in solid-state are simulated through a zero-dimensional thermo-electrical model. Then, compressible Euler equations are implemented with nodal discontinuous Lagrange shape functions in a one-dimensional model to compute the flow of the generated copper vapor (due to the wire explosion) in surrounding nitrogen gas. The aim is to calculate the distributions of pressure, density, velocity, temperature, and mass flow along the cylindrical shock waves to estimate the arc’s copper/nitrogen mixture ratio in free burning and nozzle constricted arcs. This mixture ratio is used to calculate the precise percentage of the metal vapor in the arcing area and to calculate Townsend growth coefficients utilizing to estimate the streamer breakdown of the mixture. The simulation results show good agreement with the experimental results in terms of the temporal evolution of the plasma channel boundary, the shock front speed estimation as well as the arc voltage magnitude numerically calculated deploying the extracted mixture percentage from this study, manifesting the validity of the model. It shows that despite the low-pressure studies, the exploding wire method is not suitable for circuit breakers employing supercritical fluids as the insulation.

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Section: Interruption Performance; Nozzle-pressure Effectsmentioning

confidence: 90%

Section: The Arc Metal Content For Different Wire Sizesmentioning

confidence: 99%

Metal vapor content of an electric arc initiated by exploding wire in a model N₂ circuit breaker: simulation and experiment

Kadivar

Niayesh

Støa-Aanensen

et al. 2020

J. Phys. D: Appl. Phys.

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“…Accelerating the arc towards to the steel plates and forcing the arc evenly being cut and split can help to fulfill the efficient power interruption. Some techniques like imposing a gas flow [33] from the polymer dielectric polymer to interact with the thermal arc are proposed to expedite the power interruption.…”

Section: Arc Splitting Phenomenonmentioning

confidence: 99%

Rapid and Safe Arc Quench by Using External Magnetic Coil in Power Interruption

Wang¹,

Liang²,

Zhou³

2022

AJST

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Low-voltage arc quench is one of the most processes for a successful power interruption in circuit breakers. Typical circuit breakers are designed to switch off the fault current within half a cycle, less than 10 milliseconds, which requires an efficient arc quench and thus poses great challenges in power interruption. Apart from using power electronics, which is very expensive and of low capacity, the classical circuit breakers that uses a stack of steel plates to split the fault-current arc into many sub-arcs are still dominant for both industry and residential installations. Due to the high current, the self-induced magnetic field will drive the arc towards to the steel plates and force the arc being spitted into many sub-arcs, from which the arc-steel plate interfaces generates multiple voltage drops. Once the sum of all voltage drops increases and exceeds the source voltage, the arc will extinguish and quench. Due to the ferromagnetic effect, the magnetic field increases dramatically during arc splitting by steel plates. However, the self-induced magnetic field have reversed direction on both sides of the steel plates which pushes the sub-arcs to opposite directions and prevents concurrent and even arc splitting. In this report, we report a new technique to compensate the self-induced the magnetic field by using a background magnetic coil, thus, to give an even and simultaneous arc splitting and guarantee the power interruption.

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“…The results showed that increasing the nitrogen filling pressure from 1 to 40 bar abs caused an almost threefold increase of the arc voltage. The arc-voltage characteristics for wall-restricted arcs, both thermal interruption capability and dielectric recovery rates in the contact gap after short (0.5-2.6 ms) current half-cycles, have also been published [4][5][6][7][8][9]. Moreover, dielectric recovery and arc characteristics in high-pressure (supercritical) CO 2 have been studied [10].…”

Section: Introductionmentioning

confidence: 99%

“…This paper reports on current-interruption experiments with a puffer-like contact configuration and nitrogen as the current interruption medium. In contrast to previous work [3][4][5][6][7][8], an upgraded test circuit with a current waveform close to 50 Hz is used. The current interruption capabilities at nitrogen filling pressures of 1, 10, 20 (subcritical) and 40 bar abs (supercritical state) were compared, using the same contact configuration and puffer design.…”

Section: Introductionmentioning

confidence: 99%

Arc extinction with nitrogen at 1-40 bar in a puffer-like contact configuration

Støa-Aanensen

Espedal

Rokseth

et al. 2021

PPT

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To develop cost-eﬃcient subsea switchgear for large sea depths, the extinction of arcs under high ﬁlling pressures must be understood. In this work, arc-extinction experiments have been performed with a puﬀer-like contact conﬁguration using nitrogen at diﬀerent ﬁlling pressures as the current interruption medium. The main ﬁnding is that, for the given contact conﬁguration, the currentinterruption capability was lower at 20 and 40 barabs than at 1 and 10 barabs. While higher pressures result in higher cooling ﬂow rates and longer ﬂow times given the same puﬀer volume, compression spring and nozzle geometry; it does not necessarily improve the arc-extinction capability. This is probably because higher ﬁlling pressures increase the arc voltage and total energy dissipated in the arcing zone. Because the ﬁlling pressure greatly inﬂuences the ﬂow characteristics, the puﬀer design should be optimized for each pressure level.

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Current interruption performance of ultrahigh-pressure nitrogen arc

Cited by 8 publications

References 34 publications

Metal vapor content of an electric arc initiated by exploding wire in a model N₂ circuit breaker: simulation and experiment

Metal vapor content of an electric arc initiated by exploding wire in a model N₂ circuit breaker: simulation and experiment

Rapid and Safe Arc Quench by Using External Magnetic Coil in Power Interruption

Arc extinction with nitrogen at 1-40 bar in a puffer-like contact configuration

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Current interruption performance of ultrahigh-pressure nitrogen arc

Cited by 8 publications

References 34 publications

Metal vapor content of an electric arc initiated by exploding wire in a model N2 circuit breaker: simulation and experiment

Metal vapor content of an electric arc initiated by exploding wire in a model N2 circuit breaker: simulation and experiment

Rapid and Safe Arc Quench by Using External Magnetic Coil in Power Interruption

Arc extinction with nitrogen at 1-40 bar in a puffer-like contact configuration

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Product

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Metal vapor content of an electric arc initiated by exploding wire in a model N₂ circuit breaker: simulation and experiment

Metal vapor content of an electric arc initiated by exploding wire in a model N₂ circuit breaker: simulation and experiment