Growing Science » Current Chemistry Letters » A study to use activated sludge anaerobic combining aerobic for treatment of high salt seafood processing wastewater

Journals


CCL Volumes


Current Chemistry Letters

ISSN 1927-730x (Online) - ISSN 1927-7296 (Print)
Quarterly Publication
Volume 9 Issue 2 pp. 79-88 , 2020

A study to use activated sludge anaerobic combining aerobic for treatment of high salt seafood processing wastewater Pages 79-88 Right click to download the paper Download PDF

Authors: Thi Thu Hoai Pham, Thi Mai Huong Nguyen

DOI: 10.5267/j.ccl.2019.8.002

Keywords: Seafood processing wastewater, Salt concentration, Activated sludge, Anaerobic, Aerobic

Abstract: Seafood processing operations generate a high strength wastewater, which contain organic pollutants in soluble, colloidal, particulate form and salt content, up to 30g NaCl/L. This research aimed to study the effect of salt (NaCl) concentration on the treatment efficiency of seafood processing wastewater by the use of a laboratory-scale bioreactor, which is operated in anaerobic combining aerobic system with concentration salt different from 0- 5%. The results showed that the wastewater from seafood processing with the chemical input parameters of pH = 7 - 8.5, COD = 2000 mg / L, total nitrate nitrogen = 150 mg / L, NH4+ = 90 mg / L, total phosphorus = 50 mg / L, salt content 3% was treated with anaerobic activated sludge content of 8000mg/l, 16HRT and combining an aerobic activated sludge content of 6000mg/l, 6HRT, DO=2-4mgO2/l with the acclimatization of 7% bacteria Bacillus velezensis at high salinity The parameters output wastewater was treated according to standards QCVN 11-MT:2015/BTNMT (column B).

How to cite this paper
Pham, T & Nguyen, T. (2020). A study to use activated sludge anaerobic combining aerobic for treatment of high salt seafood processing wastewater.Current Chemistry Letters, 9(2), 79-88.

Refrences
4
1. Lefebvre, O., & Moletta, R. (2006). Treatment of organic pollution in industrial saline wastewater: a literature review. Water Res., 40(20), 3671-3682.
2. Li, A., & Guowei, G. (1993). The treatment of saline wastewater using a two-stage contact oxidation method. Water Sci. and Technol., 28(7), 31-37.
3. Omil, F., Méndez, R. J., & Lema, J. M. (1995). Characterization of biomass from a pilot plant digester treating saline wastewater. J. Chem. Technol. Biot.: Int. Res. Proc., Environ. Clean Technol., 63(4), 384-392.
4. Hamoda, M. F., & Al-Attar, I. M. S. (1995). Effects of high sodium chloride concentrations on activated sludge treatment. Water Sci. and Technol., 31(9), 61-72.
5. Kargi, F., & Uygur, A. (1996). Biological treatment of saline wastewater in an aerated percolator unit utilizing halophilic bacteria. Environ. Technol., 17(3), 325-330.
6. Intrasungkha, N., Keller, J., & Blackall, L. L. (1999). Biological nutrient removal efficiency in treatment of saline wastewater. Water Sci. and Technol., 39(6), 183-190.
7. Henry, J.G., & Heinke, G.W. (1996). Environmental Science and Engineering. 2nd Ed.; Prentice-Hall, Inc.: Upper Saddle River, NJ, 445–447.
8. Sherly, T. M. V., Harindranathan, N., & Bright, S. I. S. (2015). Physicochemical analysis of seafood processing effluents in Aroor Gramapanchayath, Kerala. IOSR J. Environ. Sci. Toxicol. Food Technol, 9, 38-44.
9. Carawan, R.E., Chambers, J.V., & Zall, R.R. (1979). Seafood Water and Wastewater Management, The North Carolina, Agricultural Extension Service. U.S.A.
10. Mosquera-Corral, A., Campos, J. L., Sánchez, M., Méndez, R., & Lema, J. M. (2003). Combined system for biological removal of nitrogen and carbon from a fish cannery wastewater. J. Environ. Eng., 129(9), 826-833.
11. Hall, G. M., & Ahmad, N. H. (1997). Surimi and fish-mince products. In Fish processing technology (pp. 74-92). Springer, Boston, MA.
12. COWI. (1999). Industrial Sector Guide. Cleaner Production Assessment in Fish Processing Industry; UNEP DTIE: Paris, France; Danish Environmental Protection Agency: Copenhagen, Denmark, 1999.
13. Méndez, R., Omil, F., Soto, M., & Lema, J. M. (1992). Pilot plant studies on the anaerobic treatment of different wastewaters from a fish-canning factory. Water Sci. and Technol., 25(1), 37-44.
14. Cui, Y. W., Zhang, H. Y., Ding, J. R., & Peng, Y. Z. (2016). The effects of salinity on nitrification using halophilic nitrifiers in a Sequencing Batch Reactor treating hypersaline wastewater. Sci. Rep., 6, 24825.
15. Sherly, T. M. V., Harindranathan, N., & Bright, S. I. S. (2015). Physicochemical analysis of seafood processing effluents in Aroor Gramapanchayath, Kerala. IOSR J. Environ. Sci. Toxicol. Food Technol, 9, 38-44.
16. Woolard, C. R., & Irvine, R. L. (1995). Response of a periodically operated halophilic biofilm reactor to changes in salt concentration. Water Sci. and Technol., 31(1), 41-50.
17. Stewart, M. J., Ludwig, H. F., & Kearns, W. H. (1962). Effects of varying salinity on the extended aeration process. J. Water Pollut. Control Fed., 1161-1177.
18. Campos, J. L., Mosquera-Corral, A., Sanchez, M., Méndez, R., & Lema, J. M. (2002). Nitrification in saline wastewater with high ammonia concentration in an activated sludge unit. Water Res., 36(10), 2555-2560.
19. Rene, E. R., Kim, S. J., & Park, H. S. (2008). Effect of COD/N ratio and salinity on the performance of sequencing batch reactors. Bioresour. Technol., 99(4), 839-846.
20. Tchobanoglous, G., & Burton, F. L. (1991). Wastewater engineering treatment, disposal and reuse. McGraw-Hill, Inc.
21. Grady Jr, C. L., Daigger, G. T., Love, N. G., & Filipe, C. D. (2011). Biological wastewater treatment. CRC press.
22. Burnett, W. E. (1974). The effect of salinity variations on the activated sludge process. Water Sew. Works, 121, 37-38.
23. Oren, A., Gurevich, P., Azachi, M., & Henis, Y. (1992). Microbial degradation of pollutants at high salt concentrations. Biodegradation, 3(2-3), 387-398.
24. Kim, J. K., Kim, J. B., Cho, K. S., & Hong, Y. K. (2007). Isolation and identification of microorganisms and their aerobic biodegradation of fish-meal wastewater for liquid-fertilization. Int. Biodeterior. Biodegrad., 59(2), 156-165.
25. Hamoda, M. F., & Al-Attar, I. M. S. (1995). Effects of high sodium chloride concentrations on activated sludge treatment. Water Sci. Technol., 31(9), 61-72.
26. Dincer, A. R., & Kargi, F. (1999). Salt inhibition of nitrification and denitrification in saline wastewater. Environ.Technol., 20(11), 1147-1153.
27. Jean, D. S., & Lee, D. J. (1999). Effects of salinity on expression dewatering of waste activated sludge. J. Colloid Interf. Sci., 215(2), 443-445.
28. APHA; AWWA (2005). Standard Methods for Water and Wastewater Examinations, 21st ed.; American Public Health Association (APHA); American Water Works Association (AWWA): Washington, DC, USA.
29. APHA; AWWA. (1995). Standard Methods for the Examination of Water and Wastewater, 19th ed.; American Public Health Association (APHA); American Water Works Association (AWWA); Water Pollution Control Federation (WPCF):Washington, DC, USA.

Journal: Current Chemistry Letters | Year: 2020 | Volume: 9 | Issue: 2 | Views: 1974 | Reviews: 0

Related Articles:

Add Reviews

Name:*
E-Mail:
Review:
Bold Italic Underline Strike | Align left Center Align right | Insert smilies Insert link URLInsert protected URL Select color | Add Hidden Text Insert Quote Convert selected text from selection to Cyrillic (Russian) alphabet Insert spoiler
Security Code: *

® 2010-2026 GrowingScience.Com