Transient spark: a dc-driven repetitively pulsed discharge and its control by electric circuit parameters

Janda, M.; Martišovitš, V.; Machala, Zdenko

doi:10.1088/0963-0252/20/3/035015

Cited by 79 publications

(100 citation statements)

References 34 publications

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“…In general, the sparks are visible to the naked eye but they can also be recorded as short and strong current pulses, in the order of 1A and more. The power supply can not afford a permanent transition to the arc regime, so that this phenomenon can be described as a 'transient spark' [8], sustained only by the occasional complete discharge of the circuit capacity. The stability of a corona under steady working conditions can be quantified by reporting the time Δt between consecutive transient sparks as in figure 4: this figure is obtained from the histograms of the Δt measured along tests including hundredth of events for a set of actuators of sharpness growing from r = 0 to 4, namely C1,4,5,9,11 and 12.…”

Section: Xquhvwulfwhg Xvhmentioning

confidence: 99%

Ionic wind measurements on multi-tip plasma actuators

Messanelli

Belan

2016

EPJ Web of Conferences

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Abstract. This work presents an experimental investigation about the effects of triangular tips on the active electrodes of plasma actuators. The tests are performed on two sets of actuators, corona and DBD, parameterized by means of the tip sharpness and the tips number per unit length. A total number of 30 actuators is considered. The devices are evaluated on the basis of the far field ionic wind velocity, that has been chosen as a representative test common to both kinds of actuator. The dataset includes velocity profiles and maps, that can be integrated to give mass flows and electromechanical efficiencies. Some results are also presented in the parameter space defined by tip sharpness and tips number per unit length: this gives the chance of defining optimal electrode shapes within each set. In general, the longitudinal velocity of the gas increases downstream of the tips in all the actuators tested, but the velocity field is modified to different extents in the two kinds of actuators, and is more complicated for the DBDs than for the coronas. The tips also increase the efficiency of all the actuators, particularly for the corona set, where even the stability is remarkably improved.

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Section: Xquhvwulfwhg Xvhmentioning

confidence: 99%

Ionic wind measurements on multi-tip plasma actuators

Messanelli

Belan

2016

EPJ Web of Conferences

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“…However, this capacitance is inevitably available in the electric circuit (even in the absence of the connecting cable, this is a stray capacitance of the gap and of the connecting wires). In the transient processes, the capacitance C starts playing an essential role [27]- [29], [31], [34], [35]. For example, in the course of accident transition from glow to spark [27] or from corona to spark [31], [34], [35], just the energy stored in the capacitance is expended for formation of spark channel.…”

Section: Experimental Arrangementmentioning

confidence: 99%

“…In the transient processes, the capacitance C starts playing an essential role [27]- [29], [31], [34], [35]. For example, in the course of accident transition from glow to spark [27] or from corona to spark [31], [34], [35], just the energy stored in the capacitance is expended for formation of spark channel. Similarly, the capacitance C determines a process of the very first breakdown in the gap and subsequent discharge behavior [27]- [29].…”

Section: Experimental Arrangementmentioning

confidence: 99%

“…This effect typically appears at a time scale of 100 µs [27]- [29]. 0093-3813/$31.00 © 2012 IEEE However, the aforementioned applications often use the discharge regimes when, due to the glow-to-spark transitions, the short current pulses with a duration of about 100 ns are superimposed on a steady-state glow-type discharge plasma [20], [24]- [31]. In some cases, the so-called plasma bullets of short duration can propagate over the plasma plume [12], [32], [33].…”

Section: Introductionmentioning

confidence: 99%

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Transient Processes During Formation of a Steady-State Glow Discharge in Air

Korolev

Франц

Geyman

et al. 2012

IEEE Trans. Plasma Sci.

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This paper describes the investigation of an atmospheric-pressure glow discharge in air at a current of 0.05-0.3 A. Before the glow discharge is established, a preliminary nonsteady temporal stage is available in the gap. The principal process, which governs with the nonsteady-state discharge behavior, is the glow-to-spark transition phenomenon. The transition is initiated due to the explosive emission instability in the near-cathode layer of glow-type discharge that results in a microexplosion of the cathode surface and appearing of a spark cathode spot. At a low current, the spot is extinguished, so that the discharge starts burning again in one of the glow modes. After that, a new act of transition occurs and so on. The preliminary nonsteady-state stage ensures two prerequisites. First, an effective gas pressure decreases to a low value. Second, due to microexplosions, conditioning of the cathode surface is provided. Both factors facilitate establishing the normal glow discharge.Index Terms-Atmospheric-pressure plasma jets, glow-to-spark transition, high-pressure glow discharge.

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“…For instance, a corona discharge can be accompanied by the short current pulses or can be transformed into glow discharge [7]- [11]. A characteristic property of the glow discharge at a high pressure is the socalled glow-to-spark transition [9]- [14]. This means that the discharge burns in a glow regime only during a limited time, after which an accident transition to spark can occur.…”

mentioning

confidence: 99%

Low-Current Plasmatron as a Source of Nitrogen Oxide Molecules

Korolev

Франц

Landl

et al. 2012

IEEE Trans. Plasma Sci.

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This paper describes a usage of a low-current coaxial plasmatron for generation of nitrogen oxide molecules. Glow-type discharge in vortex air flow is sustained at an average current from 0.05 to 0.2 A that corresponds to an average discharge power from 65 to 160 W. The diameter of an exit nozzle of the plasmatron is of 0.5 cm, and the air flow is varied from 0.2 to 1.5 g/s. In such conditions, the discharge burns in nonsteady-state regime, when a sustainment of a plasma jet/plume and a plasma column in the plasmatron nozzle is accompanied by the spontaneous glow-tospark transitions. Due to the special design of the anode nozzle, an efficient interaction of the air flow with the plasma plume and plasma column is provided. Typical contents of nitric monoxide in the output gas are of about several grams per cubic meter, and the cost for formation of one molecule is from 50 to 35 eV.

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Transient spark: a dc-driven repetitively pulsed discharge and its control by electric circuit parameters

Cited by 79 publications

References 34 publications

Ionic wind measurements on multi-tip plasma actuators

Ionic wind measurements on multi-tip plasma actuators

Transient Processes During Formation of a Steady-State Glow Discharge in Air

Low-Current Plasmatron as a Source of Nitrogen Oxide Molecules

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