Decomposition of indoor VOC pollutants using non-thermal plasma with gas recycling

Christian Ariane Santos; Nguyen Hoang Phuong; Mi Jeong Park; Sang Bum Kim; Young Min Jo

Korean Journal of Chemical Engineering, Vol.37, No.1, 120-129, January, 2020

DOI10.1007/s11814-019-0406-8 Export Citation

Decomposition of indoor VOC pollutants using non-thermal plasma with gas recycling

Christian Ariane Santos, Nguyen Hoang Phuong, Mi Jeong Park, Sang Bum Kim¹, and Young Min Jo^†

Department of Environmental Science & Environmental Engineering, Kyung Hee University, Yongin-City, Gyeonggi-do 17104, Korea
¹Green Process and Material R&D Group, KITECH, 31056, Korea

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Volatile organic compounds in the indoor environment of small businesses (painting workshops, hair salons, nail shops, printing shops, laundries etc.) may result in adverse health effects for both workers and customers. Similarly, VOCs identified in these small businesses are included in the list of ozone precursors that harm the environment. We used a non-thermal plasma reactor with gas recycling to study the decomposition of dilute concentrations of VOCs in air. The non-thermal plasma reactor was a surface dielectric barrier discharge (surface DBD) type, and the target gases were methyl ethyl ketone, toluene and n-hexane at concentrations of 20, 50 and 100 ppmv. Highest decomposition efficiency (97%) was achieved by treating n-hexane at 20 ppmv. Gas recycling had an almost negligible effect during pollutant treatment at varying recycling rates (0-50%). Increasing the input energy resulted in higher decomposition efficiency, but had an inverse effect on the energy yield of the system. Concentrations of CO2 and ozone increased linearly with the increase of energy input in the system. Consumption of ozone for other applications, such as water treatment or coupling the DBD system with an appropriate catalyst, may address this concern.

Keywords:Volatile Organic Compounds;Surface DBD;Gas Recycling;Toluene;MEK;n-Hexane;Indoor Air Pollution;Non-thermal Plasma

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[Referenced By]

[1] Odeh I, Hussein T, Int. J. Environ. Res. Public Health, 13, 960 (2016)

[2] Tham KW, Energy Build., 130, 637 (2016)

[3] Jenkin ME, Derwent RG, Wallington TJ, Atmos. Environ., 163, 128 (2017)

[4] Wu W, Zhao B, Wang S, Hao J, J. Environ. Sci., 53, 224 (2017)

[5] Vandenbroucke AM, Morent R, De Geyter N, Leys C, J. Hazard. Mater., 1195, 30 (2011)

[6] Ondarts M, Hajji W, Outin J, Bejat T, Gonze E, Chem. Eng. Res. Des., 118, 194 (2017)

[7] Liang P, Jiang WM, Zhang L, Wu JF, Zhang JS, Yang DJ, Process Saf. Environ. Protect., 94, 380 (2015)

[8] Bahri Mitra, Haghighat Fariborz, Rohani Sohrab, Kazemian Hossein, Chem. Eng. J., 302, 204 (2016)

[9] Zhang HB, Li K, Shu CH, Lou ZY, Sun TH, Jia JP, Chem. Eng. J., 256, 107 (2014)

[10] Brandenburg R, Plasma Sources Sci. Technol., 27, 1 (2018)

[11] Nguyen HP, Park MJ, Kim SB, Kim HJ, Baik LJ, Jo YM, J. Clean Prod., 198, 1232 (2018)

[12] Guo YF, Ye DQ, Chen KF, Tian YF, Plasma Chem. Plasma Process., 26(3), 237 (2006)

[13] Van Durme J, Dewulf J, Sysmans W, Leys C, Van Langenhovegenhove H, Chemosphere, 68, 1821 (2007)

[14] Gupta AK, Modi B, J. Inst. Eng. India, Ser. A, 99, 565 (2018)

[15] Chang CJ, Cheng SF, Chang PT, Tsai SW, Indoor Air, 28, 173 (2018)

[16] Ebrahemzadih M, Sadeghi S, Mozaffari P, Salehzadeh H, J. Adv. Environ. Health Res., 6, 67 (2018)

[17] Yoon MS, Choi YJ, Ryu HW, J. of Odor and Indoor Environment, 15, 319 (2016).

[18] Park OH, Lee KS, Min KW, Cho GW, Yoon KJ, Jeong WS, Cho YG, Kim ES, Yang JS, J. of Korean Society of Occupational and Environmental Hygiene, 26, 159 (2016).

[19] Zheng J, Yu Y, Mo Z, Zhang Z, Wang X, Yin S, Peng K, Yang Y, Feng X, Cai H, Sci. Total Environ., 456-457, 127 (2013)

[20] Baek SO, Narayana L, Seo YK, Sensors, 15, 19102 (2015)

[21] Baik LJ, Plasma Generating Apparatus for Air Cleaning and Sterilizing. KR Patent, 1010037290000 (2010).

[22] McNair HM, Miller JM, Show NH, Basic Gas Chromatography, Wiley, New Jersey (2019).

[23] Manley TC, J. Electrochem. Soc., 84(1), 83 (1943)

[24] Huang H, Ye D, Leung DY, Feng F, Guan X, J. Mol. Catal. A-Chem., 336, 87 (2015)

[25] Xiao G, Xu WP, Wu RB, Ni MJ, Du CM, Gao X, Luo ZY, Cen KF, Plasma Chem. Plasma Process., 34(5), 1033 (2014)

[26] Urashima K, Chang J, IEE Transactions on Dielectrics and Electrical Insulation, 7, 602 (2000).

[27] Karatum O, Deshusses MA, Chem. Eng. J., 294, 308 (2016)

[28] Jin Q, Jiang BQ, Han JY, Yao SL, Chem. Eng. J., 286, 300 (2016)

[29] Holzer F, Kopinke FD, Roland U, Chem. Eng. J., 334, 1988 (2018)

[30] Rostami R, Moussavi G, Darbari S, Jafari AJ, Plasma Sci. Technol., 21, 095501 (2019)

[31] Aghbolaghy M, Soltan J, Sutarto R, Chem. Eng. Res. Des., 128, 73 (2017)

[32] Jiang L, Nie G, Zhu R, Wang J, Chen J, Mao Y, Cheng Z, Anderson WA, J. Environ. Sci., 55, 266 (2016)

[33] Zhang Z, Jiang Z, Shangguan W, Catalysis Today, 264, 270 (2016)

[34] Son YS, Chem. Eng. J., 316, 60 (2017)

[35] Mustafa MF, Fu XD, Liu YJ, Abbas Y, Wang HT, Lu WJ, J. Hazard. Mater., 347, 317 (2018)

[36] Zhang X, Lee BJ, Im H, Cha MS, IEEE Trans. Plasma Sci., 44, 2288 (2016)