Iranian Journal of Health, Safety and Environment

ABSTRACT
Environmental impacts and health concerns of BTEX compounds have been pointed in many studies. The agencies responsible for health and environment have delivered standard and guideline for BTEX concentrations. Because of the extensive use in industries and the presence of these compounds in fossil fuels, their emission resources are very divers. Today's, Control of air pollution caused by these compounds is one of the air qualities controlling challenges. "Thermal catalyzed" process is one of the technologies to control this kind of air pollution and consistent with using nanoparticles as a catalyst, this process is further considered now. So, we conducted this study to survey elimination of the BTEX, form polluted air flow, by this process. In this study, removal of the BTEX from polluted air by a thermal catalyzed process in the presence of zero-valent iron and copper oxide nanoparticles was investigated and the effect of changes in pollution load and flow rate was surveyed on removal efficiency and the decomposition of the pollutants. Fe0 and Cu2O nanoparticles were coated on a bed of natural zeolite (Clinoptilolite) with a zeolite grains size of 1-2 mm. The thermal catalyst process was conducted at 350°C and different pollution loading and air flow rate. 96.18% and 78.42% of removal efficiency achieved with the retention times of 14.1s and 7.05s. Increasing the pollution load reduced removal efficiency and pollutants' mineralization. By doubling the pollution load, the removal efficiency declined as much as 14.5 %. According to the results, increasing of the flow rate has a greater effect than the pollution load on the complete decomposition. Also this process showed a good efficiency for BTEX removal under high pollution loading and flow rates.

Aromatic organics, Air pollution, Chemical process, Nanoparticles, Zeolite

Guo H, Lee S, Li W, Cao J. Source characterization of BTEX in indoor micro- environments in Hong Kong. Atmos Environ. 2003;37(1):73-82.

Hinwood AL, Rodriguez C, Runnion T, Farrar D, Murray F, Horton A, et al. Risk factors for increased BTEX exposure in four Australian cities. Chemosphere. 2007;66(3):533-41.

Grassian VH. Environmental Catalysis: CRC Press, Taylor & Francis Group: Florida; 2005.

Hong S-S, Lee G-H, Lee G-D. Catalytic combustion of benzene over supported metal oxides catalysts. Korean J chem eng. 2003;20(3):440-4.

Garcia T, Solsona B, Taylor SH. Naphthalene total oxidation over metal oxide catalysts. Appl catal B-Environ. 2006;66(1-2):92-9.

Li P, Miser DE, Rabiei S, Yadav RT, Hajaligol MR. The removal of carbon monoxide by iron oxide nanoparticles. Appl catal B-Environ. 2003;43(2):151-62.

Fan B, Li H, Fan W, Jin C, Li R. Oxidation of cyclohexane over iron and copper salen complexes simultaneously encapsulated in zeolite Y. Appl Catal A-Gen. 2008;340(1):67-75.

Hernandez M, Corona L, Gonzalez A, Rojas F, Lara V, Silva F. Quantitative study of the adsorption of aromatic hydrocarbons (benzene, toluene, and p-Xylene) on dealuminated clinoptilolites. Ind Eng Chem Res. 2005;44(9):2908-16.

Rostami R, Jonidi Jafari A, Rezaei Kalantari R, Gholami M, Esrafili A. Benzene-Toluene-Xylene (BTX) Removal from Polluted Air flow by Combined Filter of Zero Valence Iron and Copper oxide Nanoparticles on Iranian Amended Clinoptilolite Bed. J Babol Univ Med Sci. 2012;14 (Suppl. 1):23-9.

Rostami R, Jafari AJ, Kalantari RR, Gholami M. Survey of Modified Clinoptilolite Zeolite and Cooper Oxide Nanoparticles-Containing Modified Clinoptilolite Efficiency for Polluted Air BTX Removal. Iran. J. Health & Environ. 2012;5(1):1-8

Wang JB, Li CH, Huang TJ. Study of partial oxidative steam reforming of methanol over Cu–ZnO/samaria-doped ceria catalyst. Catal Lett. 2005;103(3):239-47.

McDermott HJ, Ness SA. Sample collection device methods for gases and vapors. Air monitoring for toxic exposures. 2nd ed. Hoboken, New Jersey: John Wiley and Sons; 2004: 161-208.

McDermott HJ, Ness SA. Gas and vapor calibration. Air monitoring for toxic exposures. 2nd ed. Hoboken, New Jersey: John Wiley and Sons; 2004: 637-50.

Keshavarzi H, Halak FS, Mirmohamadi M. Survey and measurement of VOCs in closed domestic ambient and public places. Environ St. 2003;29 (32): 41-6.

NIOSH. NIOSH Manual of Analytical Methods. Atlanta; 2003. Report No.: Method 1501.

Das BM. Soil Mechanics Laboratory Manual. 6 ed: Oxford University Press, USA, 2001.

ASTM. Standard Test Method for Volume Weights, Water-Holding Capacity, and Air Capacity of Water-Saturated Peat Materials. West Conshohocken, PA: ASTM International, 2010.

Zou L, Luo Y, Hooper M, Hu E. Removal of VOCs by photocatalysis process using adsorption enhanced TiO2-SiO2 catalyst. Chem Eng Process. 2006;45(11):959-64.

Dinaro JL, Howard JB, Green WH, Tester JW, Bozzelli JW. Analysis of an elementary reaction mechanism for benzene oxidation in supercritical water. P Combust Inst. 2000;28(2):1529-36.

Li J, Bai SP, Shi XC, Han SL, Zhu XM, Chen WC, et al. Effects of temperature on benzene oxidation in dielectric barrier discharges. Plasma Chem Plasma P. 2008;28(1):39-48.

Beauchet R, Magnoux P, Mijoin J. Catalytic oxidation of volatile organic compounds (VOCs) mixture (isopropanol/o-xylene) on zeolite catalysts. Catal Today. 2007;124(3-4):118-23.

Van Durme J, Dewulf J, Sysmans W, Leys C, Van Langenhove H. Abatement and degradation pathways of toluene in indoor air by positive corona discharge. Chemosphere. 2007; 68(10): 1821-9.

Abumaizar RJ, Kocher W, Smith EH. Biofiltration of BTEX contaminated air streams using compost-activated carbon filter media. J Hazard Mater. 1998;60(2):111-26.

Lu C, Chu W, Lin M-R. Removal of BTEX Vapor from Waste Gases by a Trickle Bed Biofilter. JAPCA J Air Waste MA. 2000 2000/03/01;50(3):411-7.

Sleiman M, Conchon P, Ferronato C, Chovelon J-M. Photocatalytic oxidation of toluene at indoor air levels (ppbv): Towards a better assessment of conversion, reaction intermediates and mineralization. Appl catal B-Environ. 2009;86(3–4):159-65.

Demeestere K, Dewulf J, De Witte B, Beeldens A, Van Langenhove H. Heterogeneous photocatalytic removal of toluene from air on building materials enriched with TiO2. Build Environ. 2008;43(4):406-14.

Ramirez AM, Demeestere K, De Belie N, Mäntylä T, Levänen E. Titanium dioxide coated cementitious materials for air purifying purposes: Preparation, characterization and toluene removal potential. Build Environ. 2010;45(4):832-8.

Chen J, Li G, He Z, A T. Adsorption and degradation of model volatile organic compounds by a combined titania-montmorillonite-silica photocatalyst. J Hazard Mater. 2011;190(1-3):416-23

Schmid S, Jecklin MC, Zenobi R. Degradation of volatile organic compounds in a non-thermal plasma air purifier. Chemosphere. 2010;79(2):124-30.

Wu H, Wang L, Zhang J, Shen Z, Zhao J. Catalytic oxidation of benzene, toluene and p-xylene over colloidal gold supported on zinc oxide catalyst. Catal Commun. 2011;12(10):859-65.