Estimation of Benzene from Storage Tanks and Determination of the Permissible Distance from Gas Stations

Chehrehei, Maryam; Mirzahosseini, Seyed Alireza; Mansouri, Nabiollah; Behzadi, Mohammad Hassan; Rashidi, Yousef

doi:10.22059/poll.2022.350101.1669

Estimation of Benzene from Storage Tanks and Determination of the Permissible Distance from Gas Stations

Document Type : Original Research Paper

Authors

¹ Faculty of Natural Resources and Environment, Science and Research Branch, Islamic Azad University, Tehran, Iran

² Faculty of Basic Sciences, Science and Research Branch, Islamic Azad University, Tehran, Iran

³ Institute of Environmental Sciences, Shahid Beheshti University, Tehran, Iran

10.22059/poll.2022.350101.1669

Abstract

Benzene is considered a toxic and hazardous pollutant in Tehran metropolis. The storage tanks of petroleum products and refueling in gas stations are among the main sources of benzene emissions. Using the software AERMOD and reviewing the benzene dispersion maps at different distances from 412 storage tanks at 148 gas stations, it was found the permissible distance of the emission source is dependent on various variables such as the number of loading times and the storage capacity. When, storage capacity in the range of 60,000 L to 96,000 L and the number of loading is in the range of 675 to 1328 times a year, the concentration of benzene at a distance of 30 m of the emission source reaches the annual standard of 5 μg/ m3. While, storage capacity in the range of 80,000 L to 128,000 L and the number of loading is in the range of 1329 to 1834 times a year, the concentration of benzene at a distance of 40 m of the emission source reaches the annual standard of 5 μg/ m3. Also, based on the analysis of data and the linear regression equation, the permissible distance of the emission source can be predicted.

Keywords

References

Atabi, F., Moattar, F., Mansouri, N., Alesheikh, A.A. and Mirzahosseini, S.A.H. (2013), Assessment of variations in benzene concentration produced from vehicles and gas stations in Tehran using GIS. IJEST . 10,283–294.
Burghardt, TE., Pashkevich, A. and Żakowska L. (2016). Influence of Volatile Organic Compounds Emissions from Road Marking Paints on Ground-level Ozone Formation: Case Study of Krakow, Poland. Transportation. Research Procedia., 14, 714-723.
Correa, S.M., Arbilla, G., Marques, M.R.C. and Oliveira M.P.G. (2012). The impact of BTEX emissions from gas stations into the atmosphere. APR., 3(2); 163-169.
Dos Santos Cerqueira, J., De Albuquerque, H.N., De Assis Salviano, F. (2019). Atmospheric pollutants: modeling with Aermod software. Air Qual Atmos Health., 12, 21–32.
Fontes, T., Barros, N. and Manso, MC. (2016 June). Human health risk for the population living in the vicinity of urban petrol stations. (Paper presented at the: International Conference on Urban Risks, CaixaGest, Lisboa)
Gurjar, BR., Molina, LT. and Ojha, CSP. (Eds)(2010). Air Pollution: Health &Environmental impacts. (CRC Press)
Hajizadeh, Y., Mokhtari, M., Faraji, M., Mohammadi, A., Nemati, S., Ghanbari, R., Abdolahnejad, A., FouladiFard, R., Nikoonahad, A., Jafari, N. and Miri, M. (2018). Trends of BTEX in the central urban area of Iran: A preliminary study of photochemical ozone pollution and health risk assessment. APR 9(2); 220-229.
Hanna, SR., Paine, R., Heinold, D., Kintigh, E. and Baker, D. (2007). Uncertainties in air toxics calculated by the dispersion models AERMOD and ISCST3 in the Houston ship channel area. JAMC 46(9); 1372-1382.
Heibati, B., Pollitt KJG., Karimi A., Yazdani Charati J., Ducatman A., Shokrzadeh M. and Mohammadyan M. (2017). BTEX exposure assessment and quantitative risk assessment among petroleum product distributors. Ecotoxicology and environmental safety. 144,445-449.
Hilpert, M, Rule, AM, Adria-Mora, B. and Tiberi, T. (2019). Vent pipe emissions from storage tanks at gas stations: Implications for setback distances. Science of the Total Environment, 650(2); 2239-2250.
Khosravi, H. and Talaei Khozani, A.R. (2019). Evaluation of emissions of volatile organic compounds from gasoline storage tanks in Isfahan. Journal of Air Pollution Health. 3(2); 95-105
Lan, Q., Zhang, L., Li, G., Vermeulen, R., Weinberg, R.S., Dosemeci, M. et al. (2004). Hematotoxicity in workers exposed to low levels of benzene. Science, 306(5702); 1774-1776.
Macêdo, M.F.M. and Ramos, A.L.D. (2020). Vehicle atmospheric pollution evaluation using AERMOD model at avenue in a Brazilian capital city. Air Qual Atmos Health., 13,309–320.
Mcgaughey, G., Mcdonald-Buller, E., Kimura, Y. and Kim, H.S. (2009 October). Modeling and ambient monitoring of air toxics in Corpus Christi, Texas. (Paper presented at the 8th Annual CMAS Conference, Chapel Hill, NC)
Merchant-Borna, K., Rodrigues, EG., Smith, KW., Proctor, S.P. and McClean, M.D. (2012). Characterization of inhalation exposure to jet fuel among US Air Force personnel. Annals of occupational hygiene, 56(6); 736-745.
Mohammed, M.U., Musa, I.J. and Jeb, D.N. (2014). GIS-Based Analysis of the Location of Filling Stations in Metropolitan Kano against the Physical Planning Standards. IJER. 3(9); 147-158.
Monod, A., Sive, B.C., Avino, P., Chen, T., Blake, D.R. and Rowland, F.S. (2001). Mono aromatic compounds in ambient air of various cities: a focus on correlations between the xylenes and ethyl benzene. Atmospheric Environment. 35(1); 135-149.
Neghab, M., Hosseinzadeh, K. and Hassanzadeh, J. (2015). Early Liver and Kidney Dysfunction Associated with Occupational Exposure to Sub-Threshold Limit Value Levels of Benzene, Toluene, and Xylenes in Unleaded Petrol, Saf Health Work, 6(4); 312-316.
NIU, He., MO, Ziwei., SHAO, Min., LU, Sihua and XIE, Shaodong. (2016). Screening the emission sources of volatile organic compounds (VOCs) in China by multi-effects evaluation. Front.Environ.Sci.Eng 10, 1.
Okonkwo, U.C., Orgi, I.N. and Onwuamaeze, I (2014). Environmental impact assessment of petrol and gas filling station on air quality in Umuahia, Nigeria. Global journal of engineering research. 13(1); 11-20.
Okonkwo, C., Ehileboh, A.D., Nwobodo, E. and Dike, C. (2016). The effects of acute gasoline vapor inhalation on some hematological indices of albino Wistar rats. JAD. 5(2); 123-125.
Owagboriaye, F.O, Dedeke, G.A, Ashidi, J.S., Aladesida, A. and Olooto, W.E. (2017). Hepatotoxicity and genotoxicity of gasoline fumes in albino rats, Beni-Suef University Journal of Basic and Applied Sciences, 6(3); 253-259.
Pandey, G. and Sharan, M. (2019). Accountability of wind variability in AERMOD for computing concentrations in low wind conditions. Atmospheric Environment, 202,105–116.
Ramavandi, B., Ahmadimoghadam, M., SHahheidar, N. and Bighami, M. (2016). Estimation of volatile organic compounds emissions from the fuel storage tanks using tanks model and its distribution modeling by Aermod model. Journal of sabzevar university of medical sciences, 23(2); 253-261.
Srivastava, A., Joseph, A.E., More, A. and Patil, S. (2005). Emissions of VOCs at urban petrol retail distribution centres in India (Delhi and Mumbai). Environ Monit Assess, 109, 227–242.
Srivastava, A., Joseph, A.E. and Devotta, S. (2006). Volatile organic compounds in ambient air of Mumbai–India. Atmospheric Environment, 40(5); 892-903.
Thepanondh, S., Thanatrakolsri, P.O. and Saikomol, S. (2016). Evaluation of dispersion model performance in predicting SO2 concentrations from petroleum refinery complex, International Journal of GEOMATE, 11(23); 2129-2135.
Tohid, L., Sabeti, Z., Sarbakhsh, P., Zoroufchi, KH., Shakerkhatibi, M., Rasoulzadeh, Y., Rahimian, R. and Darvishali, S. (2019). Spatiotemporal variation, ozone formation potential and health risk assessment of ambient air VOCs in an industrialized city in Iran. APR, 10(2); 556-563.
Truong, S.C.H., Lee, M.I., Kim, G. and Kim, D. (2016). Accidental benzene release risk assessment in an urban area using an atmospheric dispersion model. Atmospheric Environment. 144,146-159.
Tsai, W T. (2016). Toxic Volatile Organic Compounds (VOCs) in the Atmospheric Environment: Regulatory Aspects and Monitoring in Japan and Korea. Environments, 3(3); 23.
USEPA (1999). “User’s Guide to TANKS, Storage Tank Emissions Calculation Software Version 4.0” Emission Factor and Inventory Group Emissions, Monitoring, and Analysis Division Office of Air Quality Planning and Standards. https://www3.epa.gov/ttnchie1/software/tanks/tank4man.pdf.
USEPA (2018). “User’s Guide for the AMS/EPA Regulatory Model-AERMOD”. Office of Air Quality Planning and Standards Air Quality Assessment Division Air Quality Modeling Group Research Triangle Park, North Carolina, EPA-454/B-18-001. https://gaftp.epa.gov/Air/aqmg/SCRAM/models/preferred/aermod /user guide.
Xu, Z., Huang, X., Nie, W., Chi, X., XU, Z., Zheng, L., Sun P. and Ding, A. (2017). Influence of synoptic condition and holiday effects on VOCs and ozone production in the Yangtze River Delta region, China. Atmospheric Environment, 168,112-124.

Article View: 257
PDF Download: 867

Estimation of Benzene from Storage Tanks and Determination of the Permissible Distance from Gas Stations

References

Volume 9, Issue 2
April 2023
Pages 745-755

Files

Share

How to cite

Statistics

Estimation of Benzene from Storage Tanks and Determination of the Permissible Distance from Gas Stations

References

Volume 9, Issue 2April 2023Pages 745-755

Files

Share

How to cite

Statistics

Volume 9, Issue 2
April 2023
Pages 745-755