Journal of Korean Society on Water Environment (한국물환경학회지)

Korean Society on Water Environment (한국물환경학회)
권호 표지
DOI QR코드

DOI QR Code

Bio-regeneration of Ion-exchange Resin for Treating Reverse Osmosis Concentrate

RO 농축폐액의 처리를 위한 이온교환수지의 생물재생

  • Bae, Byung-Uk (Department of Environment Engineering, Daejeon University) ;
  • Nam, Youn-Woo (Department of Environment Engineering, Daejeon University)
  • Received : 2014.05.12
  • Accepted : 2014.09.04
  • Published : 2014.09.30
Download PDF
⟨ Previous Next ⟩

Abstract

In order to remove both nitrate and sulfate present in the concentrate of RO(reverse osmosis) process, a combined bio-regeneration and ion-exchange(IX) system was studied. For this purpose, both denitrifying bacteria(DNB) and sulfate reducing bacteria(SRB) were simultaneously cultivated in a bio-reactor under anaerobic conditions. When the IX column containing a nitrate-selective A520E resin was fully exhausted by nitrate and sulfate, the IX column was bio-regenerated by pumping the supernatant of the bio-reactor, which contains MLSS concentration of $125{\pm}25mg/L$, at the flowrate of 360 BV/hr. Even though the nitrate-selective A520E resin was used, the breakthrough curves of ionic species showed that sulfate was exhausted earlier than nitrate. The reason for this result is due to the fact that the concentration of sulfate in RO concentrate was 36 to 48 times higher than nitrate. The bio-reactor was successfully operated at a volumetric loading rate of 0.6 g $COD/l{\cdot}d$, nitrate-N loading rate of 0.13 g $NO_3{^-}-N/l{\cdot}d$, and sulfate loading rate of 0.08 g $SO_4{^{2-}}/l{\cdot}d$. The removal rate of SCOD, nitrate-N, sulfate was 90, 100, and 85%, respectively. When the virgin resin was fully exhausted and consecutively bio-regenerated for 2 days, 81% of nitrate and 93% of sulfate were reduced. When the virgin resin was repeatedly used up to 4 cycles of service and bio-regeneration, the ion-exchange capacity of bio-regenerated resin decreased to 95, 91, 88, and 81% of virgin resin.

Keywords

References

  1. Bae, B. U., Kim, C. H., and Kim, Y. I. (2004). Treatment of Spent Brine from a Nitrate Exchange Process Using Combined Biological Denitrification and Sulfate Precipitation, Water Science and Technology, 49(5-6), pp. 413-419.
  2. Clifford, D. A. and Liu, X. (1993). Ion Exchange for Nitrate Removal, American Water Works Association, 85(4), pp. 135-143.
  3. Cornelissen, E. R., Moreau, N., Siegers, W. G., Abrahamse, A. J., Rietveld, L. C., Grefte, A., Dignum, M., Amy, G., and Wessels, L. P. (2008). Selection of Anionic Exchange Resins for Removal of Natural Organic Matter (NOM) Fractions, Water Research, 42(1-2), pp. 413-423. https://doi.org/10.1016/j.watres.2007.07.033
  4. Kim, Y. K. and Kang, S. H. (2012). Evaluation of the Effect of High Salinity RO Concentrate on the Microbial Acclimation/Cultivation Characteristics in Biological Wastewater Treatment Process, Journal of Environmental Impact Assessment, 21(5), pp. 707-713. [Korean Literature]
  5. Nam, Y. W. and Bae, B. U. (2013). Direct Bio-regeneration of Nitrate-laden Ion-exchange Resin, Journal of Korean Society on Water Environment, 29(6), pp. 777-781. [Korean Literature]
  6. Samatya, S., Kabay, N., Yuksel, U., Arda, M., and Yuksel, M. (2006). Removal of Nitrate Removal from Aqueous Solution by Nitrate Selective Ion Exchange Resins, Reactive and Functional Polymers, 66(11), pp. 1206-1214. https://doi.org/10.1016/j.reactfunctpolym.2006.03.009
  7. Shelton, D. R. and Tiedje, J. M. (1984). General method for determining anaerobic biodegradation potential, Applied and Environmental Microbiology, 47(4), pp. 850-857.
  8. Van der Hoek, J. P. and Klapwijk, A. (1987). Nitrate Removal from Ground Water, Water Research, 21(8), pp. 989-997. https://doi.org/10.1016/S0043-1354(87)80018-0