A High-Power Pulsed Corona Source for Pollution Control Applications

Pokryvailo, A.; Yankelevich, Y.; Wolf, M.; Abramzon, E.; Wald, S.; Welleman, A.

doi:10.1109/tps.2004.835952

Cited by 49 publications

(24 citation statements)

References 18 publications

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“…For the 120 kW average power modulator described in [14], the efficiency is about 50%. The 40-kW average power modulator described in [13] has a efficiency of less then 76%; and for the system described in [22], it is less then 50% for 1-2 kW average power. All systems have considerably lower energy transfer efficiency than the presented one.…”

Section: Resultsmentioning

confidence: 99%

An Industrial Streamer Corona Plasma System for Gas Cleaning

Winands

Yan

Pemen

et al. 2006

IEEE Trans. Plasma Sci.

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Abstract-For pulsed corona plasma applications, it becomes important to develop pilot systems with large average power and high-energy conversion efficiency. Since the beginning of 2000, we have been working on an industrial corona plasma system with tasks of 10-30 kW in average power and higher than 90% of total energy conversion efficiency. The pulsed-power source should have the following specifications: rise time of 10-25 ns, pulsewidth of 50-150 ns, pulse repetition rate of up to 1000 pulses per second, peak voltage pulse of 70 kV, peak current of 3.5 kA, dc bias voltage of 10-35 kV, and energy per pulse of up to 30 J. Sixteen parallel wire cylinder reactors are used to match the source. Gas and reactor temperatures can be controlled individually with water flow around the outside of those cylinders. The system is designed for gaseous oxidation and electrostatic dust precipitation. The system has been used for up to 17 kW in average power. This paper reports the system in detail, discusses issues related to the matching between the source and the reactor, and presents an example of industrial demonstrations on odor abatement at 1000 m 3 /h. Finally, this paper also gives a general guideline for design of corona plasma systems.

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Section: Resultsmentioning

confidence: 99%

An Industrial Streamer Corona Plasma System for Gas Cleaning

Winands

Yan

Pemen

et al. 2006

IEEE Trans. Plasma Sci.

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“…2) using Eqs. (1) and (2). From the hysteresis loops, it can be seen that (a) the ratio of remnant flux density to saturation magnetic flux density (B r /B s ) is close to 1, and the maximum flux swing over 2.2 T is obtained, which means that this core can withstand larger pulse energy compared to those ferrite cores [4], (b) low core loss under µs level pulse excitation is expected from the narrow area of the hysteresis loop, so it is quite suitable for using in preceding stage saturable transformer, and (c) the eddy current loss, the dissipated energy as well as the leakage current are in direct proportion to dB/dt, therefore the switching performance of this core is poor when it is used in final stage magnetic switch.…”

Section: Dd Zhang Et Almentioning

confidence: 99%

“…Magnetic switch (MS) [1] used in pulsed-power applications is superior in its high stability, high repetition rate, and long lifetime to electrical discharge switches which have unstable switching and short lifetimes due to electrode deterioration [2]. Recent pulse generators based on the new magnetic pulse compression (MPC) algorithm [2][3][4] have allowed high repetitive operation of MSs with very low losses, and made it possible to use repetitive pulsed power generated by magnetic pulse compressors in practical industrial applications such as water treatment, laser exciters, removal of volatile toxic compounds and decomposition of hazardous gases [2].…”

Section: Introductionmentioning

confidence: 99%

“…Recent pulse generators based on the new magnetic pulse compression (MPC) algorithm [2][3][4] have allowed high repetitive operation of MSs with very low losses, and made it possible to use repetitive pulsed power generated by magnetic pulse compressors in practical industrial applications such as water treatment, laser exciters, removal of volatile toxic compounds and decomposition of hazardous gases [2]. As the use of magnetic cores has become popular in pulsed power applications, there have been several studies on the pulse magnetic characteristics that are critical for a MPC system [1][2][3][4]. As the pulse width of excitation pulse stages in an MPC becomes shorter, the switching performance of the magnetic switch which is one of the dominant measures for overall performance becomes poor.…”

Section: Introductionmentioning

confidence: 99%

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Characteristics of Magnetic Core in Magnetic Pulse Compression System

et al. 2009

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In order to obtain the characteristics of magnetic core under ≈ 0.5-5 µs saturation time, a one-stage magnetic pulse compression circuit without external demagnetization circuits which are commonly used in magnetic compressors is designed. The current through the core is calculated by voltage across the resistive load, and the loop voltage is picked up with a single wire loop and integrated by software. B-H curves are derived from the measured voltage and current wave forms. B-H curves show that the core loss is in inverse proportion to the time to saturation, whereas the percentile core loss decreases as the charging energy increases. While the eddy current loss and dissipated energy are in direct proportion to dB/dt. The low inductance of magnetic switch indicates that the core is saturated and behaves as an air core. By applying custom characteristics to each stage in Pspice simulation, more practical energy transfer in magnetic pulse compression and the effects of leakage current are presented.

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“…Unfortunately, the lack of costeffective corona-plasma generation and processing techniques discouraged industries. Nevertheless, three industrial coronaplasma demonstration systems with up to 40-120 kW in average power were recently reported in Japan, Korea, and China [4]- [6]. These systems are based on magnetic compression techniques with pulse duration of 200-500 ns.…”

Section: Introductionmentioning

confidence: 99%

AC/DC/Pulsed-Power Modulator for Corona-Plasma Generation

Ariaans

Pemen

Winands³

et al. 2009

IEEE Trans. Plasma Sci.

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Abstract-Gas-cleaning techniques using nonthermal plasma are slowly introduced into industry nowadays. In this paper, we present a novel power modulator for the efficient generation of large-volume corona plasma. No expensive high-voltage components are required. Switching is done at an intermediate voltage level of 1 kV with standard thyristors. Detailed investigations on the modulator and a wire-plate corona reactor will be presented. In a systematic way, modulator parameters have been varied. Furthermore, reactor parameters, such as the number of electrodes and the electrode-plate distance, have been varied systematically. The yield of O radicals was determined from the measured ozone concentrations at the exhaust of the reactor.

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A High-Power Pulsed Corona Source for Pollution Control Applications

Cited by 49 publications

References 18 publications

An Industrial Streamer Corona Plasma System for Gas Cleaning

An Industrial Streamer Corona Plasma System for Gas Cleaning

Characteristics of Magnetic Core in Magnetic Pulse Compression System

AC/DC/Pulsed-Power Modulator for Corona-Plasma Generation

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