Rancang Bangun Peralatan Sterilisasi dan Disinfeksi Virus Covid-19 Menggunakan Plasma Tegangan 2 kV

Ri Munarto, Muhamad Otong

Abstract


Atmosferic pressure plasma can sterilize Escherichia coli bacteria because many ions and reactice species, such as oxygen and ozon atoms are generated during discharge using emission epectroscopy and the observed emission spectrum is atomic oxygen 394.2 and 436.8 nm and the second positive system nitrogen 337.1 nm.

The experiment results showed that DBD treatment for 70 seconds of sterilized Escherichia coli was 99.99% effective and ozone molecules were were dominat bacterial species. From these result it can be concluded that the pulsed DBD system is very effective for sterilization.

The result of designing medical equipment for sterilization and disinfection viruces are suitable and can be used to kill echerichia coli bacteria from the result of experiment conducted.

Keywords : atmospheric microplasma, virus sterilization and disinfection, airbone viruces, surfave colonized viruces.


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References


Kitler ME, Gavinio P, Lavanchy D, Influenza and the work of the World Health Organization, Vaccine 20: S5-S14, 2002

Cowled B, Ward MP, Hamilton S, Garner G, The equine influenza epidemic in Australia. Spatial and temporal descriptive analysis of a large propagating epidemic. Prev Vet Med 92: 60-70, 2009.

Spira AM, Preparing the traveler, Lancet 361: 1368-1381, 2003

Pontoriero AV, Baumester EG, Campos AM, Savy VL, Lin YP, et. Al, Antigenic and genomic relation between human influenza viruse that circulated in Argentina in the period 1995/1999 and the corresponding vaccine component. J Clin Virol 28: 130-140, 2003

Larousi M, Sayler GS, Glascock BB, McCurdy B, Pearce ME, et.al, Image of Biological Samples Undergoing Sterilization by a Glow Disvharge at Atmospheric Pressure. IEEE Transactions on plasma science 27: 34-35, 2004.

Singh MK, Ogino A, Nagatsu M., Inactivation factors of spore-forming bacteria using low-pressure microwave plasmas in aN2 and O2 gas mixture. New J Phys 11: 115027, 2009

Shintani H, Sakudo A, Burke P, McDonneli G., Gas plasma sterilization of microorganism and mechanism of action (Review). Exp Therapeutic Med 1: 731-738, 2009

Shimizu K, Sugiyama T, Manisha Nishamani LS,, Application of microplasma for ozone generation and environtmental protection. Int J Plasma Environtmental Science and Technology 2: 38-43, 2008

Shimizu K, Yamada M, Kanamori M, Blajan, Basic Study of Bacteria Inactivation at Low Discharge Voltage by Using Microplasma. IEEE Trans on IAS 46: 641-649, 2010

Shimizu K, Kanamori M, Blajan M, Appliction of Atmospheric Microplasma for Indoor Indoor Air Treatment. Int J Plasma Environtmental Science and Technology 4: 45-51, 2010.

Shimizu K, Blajan M, Kuwabara T, Removal of Indoor Air Contaminant by Atmospheric Microplasma. IEEE Trans on IAS Digital Object Identifier:10.1109/TIA.2011.2168509, 2011.

Shimizu K, Umeda A, Blajan M., Surface Treatment of Polymer Film by Atmospheric Pulsed Microplasma: Study on Gas Humidity Effect for Improving the Hydrophilic Property. Jpn J Appl Phys 60: 08KA3, 2011.

Blajan M, Umeda A, Muramatsu S, Shimizu K., Emission Spectroscopy of Pulsed Powered Microplasma for Surface Treatment of PEN Film. IEEE Trans on IAS 47: 1100-1108, 2011.

Barsoum, G.I, Stanley, Design of High Voltage Devices Low Power Supply, Univ. Electron Eng., vol. 3 pp. 6-12, 2015

Deenicolai T.M., Tesla Transformer for Experimentation and Research, Tesla Transformer, vol 1-3, May, pp 16-17, 2012




DOI: http://dx.doi.org/10.36055/setrum.v9i2.9674

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