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3rd International Workshop and Exhibition on Plasma Assisted Combustion

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Thermophysics and Aeromechanics Aims and scope

Abstract

This paper reviews the works of the 3rd International Workshop and Exhibition on Plasma Assisted Combustion, which dealt with the last achievements in the following scientific fields: fuel conversion and activation, plasma ignition of fuels and flame control, plasma generation and modelling, waste treatment and utilization, and promising industrial technologies.

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References

  1. Proceedings of the 3rd Int. Workshop and Exhibition on Plasma Assisted Combustion (IWEPAC), September 18–21, 2007, Best Western Falls Church Inn, Virginia, USA.

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  12. I. Matveev and S. Serbin, Thermal efficiency of a hybrid type plasma reformation system., Ibid. P. 27–29.

  13. V.Ya. Chernyak, V.V. Yukhymenko, Yu.U. Solonenko, et al., Plasma production of hydrogen-enriched gases from ethanol, Ibid., P. 33–36.

  14. V.V. Galvita, V.E. Messerle, and A.B. Ustimenko, COx-free hydrogen production by combination of plasma reforming and cyclic water gas shift technologies for the fuel cells application, Ibid., P. 37–38.

  15. M. Kim, S. Park, and J. Eden, Fuel reforming using dielectric barrier discharge and micro-cavity plasma array and reformed fuel effects on BUNSEN flame, Proc. 3rd Int. Workshop and Exhibition on Plasma Assisted Combust. (IWEPAC), September 18–21, 2007, Best Western Falls Church Inn, Virginia, USA, P. 39–41.

  16. L. Rosocha and Yo. Kim, Decomposition of ethane in atmospheric-pressure dielectric barrier discharges: Model, Ibid., P. 42–43.

  17. R. Renneke, L. Rosocha, and Yo. Kim, temperature effects on gaseous fuel cracking studies using a dielectric barrier discharge, Ibid., P. 44.

  18. Yo. Kim, S. Brannon, H. Ziock, and L. Rosocha, Carbon gasification in hydrogen dielectric barrier plasmas, Ibid., P. 45.

  19. L. Lenarduzzi, Plasma ignition system for internal combustion engines “Plasma Drive” Ibid., P. 46.

  20. S. Memarzadeh, J. Colgrove, and P.D. Ronney, Transient plasma discharge ignition for internal combustion engines, Ibid., P. 47.

  21. I.I. Esakov, L.P. Grachev, K.V. Khodataev, and V.L. Bychkov, Combustion of lean gaseous fuel mixture stimulated by microwave discharge, Ibid., P. 48–50.

  22. C. Carter and S. Leonov, Plasma-assisted combustion and flameholding in high-speed flow, Ibid., P. 51–53.

  23. I. Matveev and S. Leonov, First test results of the transient arc plasma igniter in a supersonic flow, Ibid., P. 54–57.

  24. I. Matveev, S. Matveev, and S. Serbin, Triple vortex plasma assisted combustion, Ibid., P. 58–61.

  25. V.I. Golish, E.I. Karpenko, V.G. Lukyashchenko, V.E. Messerle, V.Zh. Ushanov, and A.B. Ustimenko, Plasmatorch with regenerable carbon nanostructured electrodes, Ibid., P. 62–63.

  26. Yu.D. Korolev, O.B. Frants, N.V. Landl, and I. Matveev, Investigation of a non-steady state discharge in a pilot for ignition and flame control, Ibid., P. 64–66.

  27. A.A. Tropina, Three-temperature model of nonequilibrium Air Plasma, Ibid., P. 67–69.

  28. I. Matveev, S. Serhiy, and A. Mostipanenko, CFD calculations of reverse vortex reactive flows, Ibid., P. 70–72.

  29. J. Amouroux, S. Dresvin, and D. Ivanov, Mathematical modelling of argon plasma in ICP torch by non-equilibrium model, Ibid., P. 73–75.

  30. J. Amouroux, S. Dresvin, and D. Ivanov, Chemical reactions in heat and mass transfer between small particles and plasma, Ibid., P. 76–78.

  31. D.M. Voytovych, Numerical analysis of high-speed flows with combustion of fuel ignited by a plasmatorch, Ibid., P. 79–80.

  32. V.L. Bychkov, V.A. Chernikov, A.A. Kostiuk, and V.Yu. Sergienko, Application of erosive plasma generator over flammable liquids, Ibid., P. 81–82.

  33. E.I. Karpenko, V.E. Messerle, and A.B. Ustimenko, New plasma technologies for fuels utilization, Ibid., P. 83–85.

  34. K. Zhang, D. Glover, A. Harling, and J.C. Whitehead, Plasma clean — a non-thermal plasma approach to air quality improvement, Ibid., P. 86–87.

  35. B. Piwczyk, New solar cell manufacturing processes and equipment using atmospheric plasma technology, Ibid., P. 88–89.

  36. A.G. Karengin and Yu.D. Korolev, Plasma catalytic module for utilization of oil residuals based on high-frequency discharge, Ibid., P. 12–13.

  37. E. Leal-Quiros, Hydrogen Production using plasma torches and plasmatorch for plasma gasification and plasma magmavication of organic and inorganic materials, Ibid., P. 14–15.

  38. P. Carabin, Energy from waste using the plasma resource recovery system (PRRS), Ibid., P. 22–23.

  39. L. Rosocha, M. Zollinger, M. Elliott, and I. Matveev, Plasma applications to utilization of municipal solid waste for energy: pollution control and fuel conversion, Ibid., P. 24.

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Authors and Affiliations

  1. Ulan-Ude Division of Kutateladze Institute of Thermophysics SB RAS, Ulan-Ude, Russia

    V. E. Messerle

  2. NTO Plasmotekhnika, Almaty, Kazakhstan

    A. B. Ustimenko

Authors
  1. V. E. Messerle
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  2. A. B. Ustimenko
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Messerle, V.E., Ustimenko, A.B. 3rd International Workshop and Exhibition on Plasma Assisted Combustion. Thermophys. Aeromech. 15, 351–358 (2008). https://doi.org/10.1134/S0869864308020182

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