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Evaluation of Swine Wastewater Pretreatment Using Anaerobic Filter
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 Title & Authors
Evaluation of Swine Wastewater Pretreatment Using Anaerobic Filter
Kang, Ho; Moon, Seo-yeon;
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 Abstract
Anaerobic Filters (AF) packed with porous ceramic floating media were operated at different operational conditions to identify the feasibility of the renewable bioenergy, methane production from swine wastewater and to verify the suitability of effluent from anaerobic filters for the subsequent biological nitrogen and phosphorus removal. Stepwise increase in organic loading rates (OLRs) or decrease in hydraulic retention times (HRTs) with influent TCOD concentration of 14,000 mg/L were utilized at mesophilic temperature. The maximum methane productivity of 1.74 volume of per volume of reactor per day (v/v-d) was achieved at an hydraulic retention time (HRT) of 0.5 day (OLR 28 g TVS/L-d). Based on the biogas production, the highest total volatile solids (TVS) removal efficiency of 63% was obtained at an HRT of 3 days (OLR 4.67 g TVS/L-d), however based on the result from the effluent total chemical oxygen demand (TCOD) analysis, the highest TCOD removal efficiency of 75% was achieved. The effluent alkalinity concentration over the range of 2,050~2,980 mg/L as at all operational conditions, could compensate the alkalinity destruction caused by nitrification. The effluent from the anaerobic filter operated under the HRT of 2 days showed the COD/TKN ratio of 15~35 and COD/TP ratio of 38~56. Therefore effluent C/N/P ratio is able to satisfy the optimum COD/TKN ratio of greater than 8.0 and COD/TP ratio of 33 for the subsequent biological nutrient removal.
 Keywords
Anaerobic Filter;Biogas;Swine Wastewater;OLR/HRT;C/N/P Ratio;
 Language
Korean
 Cited by
1.
Evaluation of the Performance Parameters with a Semi-Continuously Fed and Mixed Anaerobic Reactor using Food Waste, New & Renewable Energy, 2016, 12, 4, 88  crossref(new windwow)
 References
1.
Ministry of Environment (ME), "Guideline for Operation Maintenance and Installment of Livestock Manure Treatment Facility," ME, Korea(2013).

2.
Kang, H., "Optimization of Maximum Biogas Production from Anaerobic Digestion of Dairy Cow Manure using Semi- Continuously Fed and Mixed Reactor (SCFMR)," Rural Res. Ins., Korea(2014).

3.
Ahn, J. W. and Lee, H. D., "A Study on Optimum Management of Livestock Wastewater," J. Korean Soc. Water Qual., 16(2), 255-264(2000).

4.
Teodorita, A. S. and Clare, L., Quality Management of Digestate from Biogas Plants Used as Fertiliser, IEA Bioenergy, pp. 4-38(2012).

5.
Won, C. H., Kwon, J. H. and Rim, J. M., "Effect of Ammonia Nitrogen Loading Rate on Anaerobic Digestion of Slurry-typed Swine Wastewater," J. Korean Organic. Resour. Recycling Assoc., 17(1) 49-57(2009).

6.
Clare, T. L., Peter, F. and Teodorita, A. S., Utilisation of Digestate from Biogas Plants as Biofertiliser," IEA Bioenergy, pp. 4-22(2010).

7.
Kim, J. S. and Seo, J. W., "Treatment of Swine Wastewater by Anaerobic Filter Bioreactors," Appl. Chem., 3(1), 189-192(1999).

8.
Kang, H., Shin, K. S., and Richards, B., "Determination of Ultimate Biodegradability and Multiple Decay Rate Coefficients in Anaerobic Batch Degradation of Organic Wastes," J. Korean Soc. Environ. Eng., 27(5), 555-601(2005).

9.
Kang, H., Jeong, K. H., Jeong, J. H., Kim, S. W. and Ahn, H. K., "Anaerobic Ultimate Biodegradability and Multiple Decay Rates of Dairy Cow Manure," J. Korean Soc. Waste Manage., 31(8), 833-842(2014). crossref(new window)

10.
Jeong, K. H., Kang, H., Jeong, J. H., Kim, S. W. and Ahn, H. K., "Biogas Production from Dairy Cow Manure using Semi-Continuously Fed and Mixed Reactor (SCFMR)," J. Korean Soc. Waste Manage., 31(8), 843-853(2014). crossref(new window)

11.
Eugene, W. R., Rodger, B. B., Andrew, D. E., and Lenore, S. C., Standard Methods For the Examination of Water and $wastewater^{TM}$, 22nd Ed., APHA (with AWWA and Water Environ. Fed.), Hanover, pp. 4-1496(2012).

12.
McCarty, P. L., "Anaerobic Waste Treatment Fundamentals," Public Works, 95(1964).

13.
Eom, T. K. and Lim, J. W., "Effect of ammonium nitrogen in anaerobic biofilter using livestock wastewater," J. Korean Soc. Water and Wastewater, 11(4), 43-53(1997).

14.
Park, W. K., Jun, H. B., Park, N. B., Kwon, S. I., Shin, J. D. and Hong, S. K., "Performance Evaluation and Characteristic Study of the Single Anaerobic Digestion from Piggery Slurry," Korean J. Environ. Agri., 30(1), 31-36(2011). crossref(new window)

15.
Hill, D. T., Cobb, S. A. and Bolte, J. P., "Using Volatile Fatty Acid Relationships to Predict Anaerobic Digester Failure," Trans. ASAE, 30(2), 496-501(1987). crossref(new window)

16.
Sanchez, E., Borja, R., Travieso, L., Colmenarejo, M. F., Chica, A. and Martin, A., "Treatment of settled piggery waste by a down-flow anaerobic fixed bed reactor," J. Chem. Technol. and Biotechnol., 79, 851-862(2004). crossref(new window)

17.
ATV Report, ATV Fachausschuss 2.6 and 2.8, Korrespondenz Abwasser, 34, 77, Germany(1987).

18.
Clifford, W. R., Barnard, J. L. and Stensel, H. D., "Volume 5/ Design and Retrofit of Wastewater Treatment Plants for Biological Nutrient Removal," Water Quality Management Library, Technomic Publishing Co, Inc., Lancaster, pp. 1-431(1992).