Tytuł artykułu
Autorzy
Wybrane pełne teksty z tego czasopisma
Identyfikatory
Warianty tytułu
Power electronic supplies for atmospheric pressure, non-thermal plasma technology
Języki publikacji
Abstrakty
Artykuł przedstawia podstawowe właściwości systemów opartych o reaktory atmosferycznej plazmy nietermicznej (AP-NTP). Kolejno scharakteryzowano sposoby zasilania oraz konstrukcje reaktorów, podstawowe cechy źródeł zasilających oraz podstawy technik pomiarowych. W ostatniej części podsumowano doświadczenia zebrane podczas konstrukcji energoelektronicznych źródeł zasilających różnych topologii oraz ich podstawowe właściwości użytkowe.
Presented paper discusses basic properties of atmospheric pressure, non-thermal plasma reactor based systems. Typical supply system properties as well as reactor construction outline is described. Concluding part summarizes experiences gained while constructing various power electronic supply systems with their basic properties.
Wydawca
Czasopismo
Rocznik
Tom
Strony
199--206
Opis fizyczny
Bibliogr. 38 poz., il., rys., wykr.
Twórcy
Bibliografia
- [1] M. Moreau, N. Orange, M.G.J. Feuilloley, “Nonthermal plasma technologies: New tools for biodecontamination”, Biotechnology Advances 26 (2008) 610–617
- [2] M. Wroński, I. Pollo: „Koncepcja wykorzystania impulsowych wyładowań koronowych do usuwania zanieczyszczeń gazowych emitowanych przez elektrownie”, Ograniczenie zanieczyszczeń z urządzeń energetycznych, Cz. 2: Techniczno-ekonomiczne aspekty ochrony powietrza, Poznań, (1995), 29-48
- [3] J. Reece Roth, Jozef Rahel, Xin Dai, and Daniel M. Sherman, “The physics and phenomenology of One Atmosphere Uniform Glow Discharge Plasma (OAUGDP™) reactors for surface treatment applications,” Journal of Physics D: App. Physics, vol. 38, (2005), 555-567
- [4] Jaeyoung Park, I . Henins, H. W. Herrmann, G. S. Selwyn R. F. Hicks: “Discharge phenomena of an atmospheric pressure radio-frequency capacitive plasma source”, Journal of Applied Physics, Volume 89, Number 1, 1 Jan. (2001)
- [5] Y. Kim, M. S. Cha, W.-H. Shin, and Y.-H. Song: “Characteristics of Dielectric Barrier Glow Discharges with a Low-Frequency Generator in Nitrogen”, Journal of the Korean Physical Society, Vol. 43, No. 5, November (2003), 732-737
- [6] K Matyash, R Schneider, K Dittmann, J Meichsner, F X Bronold and D Tskhakaya: “Radiofrequency discharges in oxygen: III. Comparison of modelling and experiment”, Journal of Physics, D: App. Physics. Vol. 40 (2007) 6601–6607
- [7] A. Mizuno, Y. Yamazaki, S. Obama, E. Suzuk i , K. Okazaki : „Effect of Voltage Waveform on Partial Discharge in Ferroelectric Pellet Layer for Gas Cleaning”, IEEE Transactions on Industry Applications, Vol. 29, No 2, March/April (1993)
- [8] K. Minami, M. Akiyama, A. Okino, M. Watanabe, E. Hotta: „De-Nox characteristics of bidirectional pulse corona discharge”, Papers of Technical Meeting on Plasma Science and Technology, IEE Japan, Vol. PST-01, No. 1-21, (2001), 67-72
- [9] R. H. Conrad: “Method of powering corona discharge in ozone generators with bipolar pulses and a precharge pulse“, United States Patent number 5 269 893, December (1993)
- [10] H.-E. Wagner , R. Brandenburg, K.V. Kozlov, A. Sonnenfeld, P. Michel , J.F. Behnke: “ The barrier discharge: basic properties and applications to surface treatment“, Vacuum 71 (2003) 417–436
- [11] S. Masuda: “Pulse corona induced plasma chemical process: a horizon of new plasma chemical technologies”, Pure & Applied Chemistry, Vol. 60, No. 5 (1988), 727-731
- [12] Y. Nomoto, T. Ohkubo, S. Kazanawa, T. Adachi : „Improvement of Ozone Yield by a Silent-Surface Hybrid Discharge Ozonizer”, IEEE Transactions on Industry Applications, Vol. 31, No 6, November/December (1995)
- [13] T. Yamamoto, K. Mizuno, I . Tamori, A. Ogata, M. Nifuku, M. Michalska, G. Prieto: „Catalysis-Assisted Plasma Technology for Carbon Tetrachloride Destruction”, IEEE Transactions on Industry Applications, Vol. 32, No 1, January/February (1996)
- [14] M.H. Cho, K. B. Ko, Y. C. Byun, D.N. Shin, D. J. Koh: “Environmental Applications of Plasmas”, 8th APCPST at Cairns, Australia, July 3, (2006)
- [15] M. Rea, K. Yan: “Evaluation of Pulse Voltage Generators”, IEEE Transactions on Industry Applications, Vol. 31, No 3, May/June (1995)
- [16] U. Kogels chat z : „Dielectric-barrier Discharges: Their History, Discharge Physics, and Industrial Applications”, Plasma Chemistry and Plasma Processing, Vol. 23, No. 1, March (2003)
- [17] Y. Yoshioka: “Recent Developments in Plasma De-NOx and PM (Particulate Matter) Removal Technologies from Diesel Exhaust Gases”, Int. Journal of Plasma Environmental Science & Technology Vol.1, No.2, September (2007)
- [18] U. Kogels chat z : “Filamentary, patterned and diffuse barrier discharges”, IEEE Transactions on Plasma Science 30 1400 - 1408 (2002)
- [19] G.-H. Kim, S.-Y. Jeong, H.-C. Kwon, S.-H. Song: „Capacitance between an Atmospheric Discharge Plasma and the Dielectric Electrode in the Parallel Cell Reactor”, Journal of the Korean Physical Society, Vol. 49, No. 3, Sept. (2006), 1307 - 1311
- [20] B. G. Rodríguez-Méndez, López-Callejas, R. Peña-Eguiluz, A. Mercado-Cabrera, R. Valencia- Alvarado, S. R. Barocio, A. de la Piedad- Benei t ez, J. S. Benítez-Read,* and J. O. Pacheco-Sotelo: „A model of plasma discharges in prearcing regime for water treatment”, proceeding of the 25th IASTED Modelling, Identification and Control, February 6-8, (2006), Canary Islands, Lanzarote, Spain
- [21] E. Panousis, L. Papageorghiou, N. Spyrou, J.-F. Loiseau, B. Held, F. Clement : “Comparison between experimental and modelling results of an atmospheric pressure N2 DBD discharge under 130kHz sinusoidal excitation”, proceedings of 28th ICPIG, Prague, Czech Republic, June 15 – 20, (2007)
- [22] Z. Chen: „PSpice simulation of one atmosphere uniform, glow discharge plasma (OAUGDP) reactor systems”, IEEE Transactions on Plasma Science, vol. 31 511–520, (2003)
- [23] J. M. Alonso, J. Cardesin, E. L. Corominas, M. Ri co-Secades , J. Garc ia: “Low-Power High-Voltage High-Frequency Power Supply for Ozone Generation”, IEEE Transactions on Industry Applications, Vol. 40, No 2, March/April (2004)
- [24] T. C. Manley: “The electric characteristics of the ozonator discharge”, Transactions of Electrochemical Society 84, 83 (1943)
- [25] J. M. Meek, and J. D. Craggs, ‘‘Breakdown voltage characteristics”, Electrical breakdown of gases, Wiley–Interscience, New York, 533–545 (1953)
- [26] H. D. Stryczewska: “Analiza zintegrowanych zasilaczy elektromagnetycznych w urządzeniach wyładowczych”, Wydawnictwa uczelniane Politechniki Lubelskiej, (1996)
- [27] K.-P. Francke, R. Rudolph, H. Miessner: „Design and Operating Characteristics of a Simple and Reliable DBD Reactor for Use with Atmospheric Air“, Plasma Chemistry and Plasma Processing, Vol. 23, No. 1, 47 – 57, (2003)
- [28] J. Grundmann, S. Müller and R.-J. Zahn: „Treatment of Soot by Dielectric Barrier Discharges and Ozone“, Plasma Chemistry and Plasma Processing, Vol. 25, No. 5, October (2005)
- [29] R. Casanueva, F. J. Azcondo, S. Bracho: “Series– parallel resonant converter for an EDM power supply”, Journal of Materials Processing Technology 149 (2004), 172 – 177
- [30] M. Teschke, D. Korzec, E.G. Finantu-Dinu, J. Engemann, R. Kennel : „Resonant, high voltage, high power supply for atmospheric pressure plasma sources”, Power Electronics Specialists Conference PESC 04, 20-25 June, Volume: 1, 835- 839 (2004)
- [31] H. Fujita, H. Akagi : „Control and performance of a pulsedensity- modulated series-resonant inverter for corona discharge processes”, Industry Applications Conference, 33 IAS Annual Meeting, 12-15 Oct (1998), Volume: 2, 1320-1325
- [32] S. Kalisiak, M. Hołub and T. Jakubowski: „Resonant inverter with output voltage pulse-phase-shift control for DBD plasma reactor supply”, materiały konferencji EPE 2009, the 13th Int. European Power Electronics Conference and Exhibition, wrzesień (2009)
- [33] Erwin Marx: “Verfahren zur Schlagpruefung von Isolatoren und anderen elektrischen Vorrichtungen“, Patentschrift nr. 455933, 13 February (1928)
- [34] Richard Anthony Fitch et al.: ”Electrical Pulse Generators”, US Patent nr 3,366,799, 30 January (1968)
- [35] G. Dinelli, L. Civitano, M. Rea: “Industrial Experiments on Pulse Corona Simultaneous Removal of NOx and SO2 from flue gas”, IEEE Transactions on Industry Applications, Vol. 26, No 3, May/June (1990)
- [36] T. Oda: “Atmospheric Pressure nonthermal plasma decomposition of gaseous air contaminants and that diagnosis”, proceedings of the Xth ICESP Conference, Australia, (2006)
- [37] S.-D. Jang, Y. -G. Son, J.-S. Oh and M.-H. Cho, D. - J . Koh: “Pulsed Plasma Process for Flue Gas Removal from an Industrial Incinerator by Using a Peak 200-kV, 10-kA Pulse Modulator”, Journal of the Korean Physical Society, Vol. 44, No. 5, May (2004), 1157-1162
- [38] S. Kalisiak, M. Hołub: „Modified Fitch generator topology for non-thermal plasma applications”, Przegląd Elektrotechniczny, R. 85, nr 7 (2009), 134 - 137
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-article-BPOB-0026-0015