Browse > Article
http://dx.doi.org/10.12652/Ksce.2021.41.4.0399

Selective Nitrate Removal Performance Analysis of Ion Exchange Resin in Shipboard Waste Washwater by Air Pollution Prevention Facility  

Kim, Bong-Chul (Korea Testing Laboratory)
Yeo, In-Seol (Korea Testing Laboratory)
Park, Chan-Gyu (Korea Testing Laboratory)
Publication Information
KSCE Journal of Civil and Environmental Engineering Research / v.41, no.4, 2021 , pp. 399-404 More about this Journal
Abstract
From 1 January 2020, the limit for Sulphur in fuel oil used on board ships operating outside designated emission control areas will be reduced to 0.5 %. This regulation by international maritime organization (IMO) is able to significantly reduce the amount of Sulphur oxides (SOx) discharging from ships and should have environmental advantages and health for all over the world. To meet the regulation, in these days, wet scrubber system is being actively developed. However, this process leads to make washing wastewater. In this study, we evaluated ion exchange resin system in accordance with scrubber wastewater discharge regulation by IMO. Theoretical wastewater used as feed solution of lab scale water treatment systems. The results revealed that nitrate ion was removed selectively in spite of high TDS wash wastewater solution depending on ion exchange resin property. Moreover, it was possible to improve efficiency of the system by optimizing operating conditions.
Keywords
Ion exchange resin; Nitrate; Operating condition; Selective removal; Wastewater treatment;
Citations & Related Records
연도 인용수 순위
  • Reference
1 Ammar, N. R. and Seddiek, I. S. (2020). "An environmental and economic analysis of emission reduction strategies for container ships with emphasis on the improved energy efficiency indexes." Environmental Science and Pollution Research, Vol. 27, pp. 23342-23355.   DOI
2 Amoatey, P., Omidvarborna, H., Baawain, M. S. and Al-Mamun, A. (2019). "Emissions and exposure assessments of SOX, NOX, PM10/2.5 and trace metals from oil industries: A review study (2000-2018)." Process Safety and Environmental Protection, Vol. 123, pp. 215-228.   DOI
3 Bernard, S. M., Samet, J. M., Grambsch, A., Ebi, K. L. and Romieu, I. (2001). "The potential impacts of climate variability and change on air pollution-related health effects in the United States." Environmental Health Perspectives, Vol. 109, No. 2, pp. 199-209.   DOI
4 Kontovas, C. A. (2020). "Integration of air quality and climate change policies in shipping: The case of sulphur emissions regulation." Marine Policy, Vol. 113, pp. 103815.   DOI
5 Praetorius, B. and Schumacher, K. (2009). "Greenhouse gas mitigation in a carbon constrained world: The role of carbon capture and storage." Energy Policy, Vol. 37, No. 12, pp. 5081-5093.   DOI
6 Shimaoka, T., Miyawaki, K., Hanashima, M., Yoshida, T. and Uchida, T. (2000). "Heavy metal elution characteristics from municipal solid waste scrubber residue by a centrifugation method." Waste Management Series, Vol. 1, pp. 595-603.   DOI
7 Rabah, M. A. (2013). "Cleaning wastewater of wet scrubber in secondary lead smelters using cationic polyacrylamide." Journal of Environmental Chemistry and Ecotoxicology, Vol. 5, No. 10, pp. 250-264.
8 Du, X., Ye, S. and Dong, D. (2019). "Rapid determination of nitrate in drinking water using ion-exchange-enhanced infrared spectroscopy." Journal of Food Process Engineering, Vol. 42, No. 6, pp. 13164.
9 Li, L., Gao, S., Yang, W. and Xiong, X. (2020). "Ship's response strategy to emission control areas: From the perspective of sailing pattern optimization and evasion strategy selection." Transportation Research Part E: Logistics and Transportation Review, Vol. 133, pp. 101835.   DOI
10 Han, Z., Liu, B., Yang, S., Pan, X., and Yan, Z., (2017). "NOX Removal from Simulated Marine Exhaust Gas by Wet Scrubbing Using NaClO Solution." Journal of Chemistry, Vol. 2017 pp. 9340856.
11 Jiang, K., Yu, H., Chen, L., Fang, M., Azzi, M., Cottrell, A. and Li, K. (2020). "An advanced, ammonia-based combined NOX/SOX/CO2 emission control process towards a low-cost, clean coal technology." Applied Energy, Vol. 260, pp. 114316.   DOI
12 Rokicki, C. A. and Boyer, T. H. (2011). "Bicarbonate-form anion exchange: Affinity, regeneration, and stoichiometry." Water Research, Vol. 45, No. 3, pp. 1329-1337.   DOI
13 Teuchies, J., Cox, T. J. S., Van Itterbeeck, K., Meysman, F. J. R. and Blust, R. (2020). "The impact of scrubber discharge on the water quality in estuaries and ports." Environmental Sciences Europe, Vol. 32, No. 1, pp. 103.   DOI
14 Endres, S., Maes, F., Hopkins, F., Houghton, K., Martensson, E. M., Oeffner, J., Quack, B., Singh, P. and Turner, D. (2018). "A new perspective at the ship-air-sea-interface: The environmental impacts of exhaust gas scrubber discharge." Frontiers in Marine Science, Vol. 5, pp, 139.   DOI
15 Kennedy, C., Steinberger, J., Gasson, B., Hansen, Y., Hillman, T., Havranek, M., Pataki, D., Phdungsilp, A., Ramaswami, A. and Mendez, G. V. (2009). "Greenhouse gas emissions from global cities." Environmental Science and Technology, Vol. 43, No. 19, pp. 7297-7302.   DOI
16 Liu, L., Huang, G., Baetz, B. and Zhang, K. (2018). "Environmentally-extended input-output simulation for analyzing production-based and consumption-based industrial greenhouse gas mitigation policies." Applied Energy, Vol. 232, pp. 69-78.   DOI
17 Zhou, J. and Wang, H. (2020). "Study on efficient removal of SOx and NOx from marine exhaust gas by wet scrubbing method using urea peroxide solution." Chemical Engineering Journal, Vol. 390, pp. 124567.   DOI