Ozonized water generator based on coaxial dielectric-barrier-discharge in air

A coaxial dielectric-barrier-discharge (DBD) as an ozonized water reactor system has been developed and described. It operates in the air at an atmospheric pressure. In the reactor one of the dielectric layers is flowing water. Ozone and ozonized water are generated in the same volume of the dischar...

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Published in:	Vacuum Vol. 73; no. 3; pp. 705 - 708
Main Authors:	Kuraica, Milorad M., Obradović, Bratislav M., Manojlović, Dragan, Ostojić, Daliborka R., Purić, Jagoš
Format:	Journal Article
Language:	English
Published:	Elsevier Ltd 19-04-2004
Subjects:	Atmospheric pressure discharge Dielectric barrier discharge Ozonizer Atmospheric pressure discharge Dielectric barrier discharge Ozonizer
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Abstract	A coaxial dielectric-barrier-discharge (DBD) as an ozonized water reactor system has been developed and described. It operates in the air at an atmospheric pressure. In the reactor one of the dielectric layers is flowing water. Ozone and ozonized water are generated in the same volume of the discharge. The ozone production and its dissolution in the water simultaneously occur leading to increases of the reactor efficiency. Filamentary 50 Hz DBD has been performed using up to 20 kV applied voltage. The obtained ozone concentrations correspond to the values typically suggested for the treatment of potable and wastewater. The efficiency can be further increased by addition of small amount of the oxygen in the DBD device. The periodical time dependence of the dissolved ozone concentration in Danube water is found and discussed.
AbstractList	A coaxial dielectric-barrier-discharge (DBD) as an ozonized water reactor system has been developed and described. It operates in the air at an atmospheric pressure. In the reactor one of the dielectric layers is flowing water. Ozone and ozonized water are generated in the same volume of the discharge. The ozone production and its dissolution in the water simultaneously occur leading to increases of the reactor efficiency. Filamentary 50 Hz DBD has been performed using up to 20 kV applied voltage. The obtained ozone concentrations correspond to the values typically suggested for the treatment of potable and wastewater. The efficiency can be further increased by addition of small amount of the oxygen in the DBD device. The periodical time dependence of the dissolved ozone concentration in Danube water is found and discussed.
Author	Purić, Jagoš Manojlović, Dragan Obradović, Bratislav M. Kuraica, Milorad M. Ostojić, Daliborka R.
Author_xml	– sequence: 1 givenname: Milorad M. surname: Kuraica fullname: Kuraica, Milorad M. email: kuki@ff.bg.ac.yu organization: Faculty of Physics, University of Belgrade, PO Box 368, Belgrade 11001, Serbia and Montenegro – sequence: 2 givenname: Bratislav M. surname: Obradović fullname: Obradović, Bratislav M. organization: Faculty of Physics, University of Belgrade, PO Box 368, Belgrade 11001, Serbia and Montenegro – sequence: 3 givenname: Dragan surname: Manojlović fullname: Manojlović, Dragan organization: Faculty of Chemistry, University of Belgrade, PO Box 158, Belgrade 11001, Serbia and Montenegro – sequence: 4 givenname: Daliborka R. surname: Ostojić fullname: Ostojić, Daliborka R. organization: Faculty of Chemistry, University of Belgrade, PO Box 158, Belgrade 11001, Serbia and Montenegro – sequence: 5 givenname: Jagoš surname: Purić fullname: Purić, Jagoš organization: Faculty of Physics, University of Belgrade, PO Box 368, Belgrade 11001, Serbia and Montenegro
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References	Gottschalk C, Libra JA, Saupe A. Ozonization of drinking water and of wastewater, 1st ed. New York: Wiley; 2000. Methods 2-41, 2-42 and 4-104, in Standard Methods for the Examination of Water and Wastewater, Eds. Andrew D. Eaton, Leonore C. Clesceri, Arnold E. Greenberg and Mary Ann H. Franson, American Public Health Association, Washington, 1995. Tajima R, Ehara Y, Kishida H, Ito T. Proceedings of the Hakone VII, Germany: Greifswald; 2001; 2: p. 412–6. Watanabe T, et al. Proceeding of the Seventh Ozone Science and Technology in Japan 1998. Kyoto, Japan p. 157–60. 10.1016/j.vacuum.2003.12.093_BIB1 10.1016/j.vacuum.2003.12.093_BIB2 10.1016/j.vacuum.2003.12.093_BIB3 10.1016/j.vacuum.2003.12.093_BIB4
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Title	Ozonized water generator based on coaxial dielectric-barrier-discharge in air
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