Combined biologic aerated filter and sulfur/ceramisite autotrophic denitrification for advanced wastewater nitrogen removal at low temperatures

Tian WAN , Guangming ZHANG , Fengwei DU , Junguo HE , Pan WU

Front. Environ. Sci. Eng. ›› 2014, Vol. 8 ›› Issue (6) : 967 -972.

PDF (156KB)
Front. Environ. Sci. Eng. ›› 2014, Vol. 8 ›› Issue (6) : 967 -972. DOI: 10.1007/s11783-014-0690-9
RESEARCH ARTICLE
RESEARCH ARTICLE

Combined biologic aerated filter and sulfur/ceramisite autotrophic denitrification for advanced wastewater nitrogen removal at low temperatures

Author information +
History +
PDF (156KB)

Abstract

An innovative advanced wastewater treatment process combining biologic aerated filter (BAF) and sulfur/ceramisite-based autotrophic denitrification (SCAD) for reliable removal of nitrogen was proposed in this paper. In SCAD reactor, ceramisite was used as filter and Ca(HCO3)2 was used for supplying alkalinity and carbon source. The BAF-SCAD was used to treat the secondary treatment effluent. The performance of this process was investigated, and the impact of temperature on nitrogen removal was studied. Results showed that the combined system was effective in nitrogen removal even at low temperatures (8 °C). Removal of total nitrogen (TN), NH4+-N, NO3-_N reached above 90% at room temperature. Nitrification was affected by the temperature and nitrification at low temperature (8 °C) was a limiting factor for TN removal. However, denitrification was not impacted by the temperature and the removal of NO3--N maintained 98% during the experimental period. The reason of effective denitrification at low temperature might be the use of easily dissolved Ca(HCO3)2 and high-flux ceramisite, which solved the problem of low mass transfer efficiency at low temperatures. Besides, vast surface area of sulfur with diameter of 2–6 mm enhanced the rate of microbial utilization. The removal of nitrate companied with the production of SO42-, and the average concentration of SO42- was about 240 mg·L-1. These findings would be beneficial for the application of this process to nitrogen removal especially in the winter and cold regions.

Keywords

autotrophic denitrification / biologic aerated filter (BAF) / sulfur/ceramisite-based autotrophic denitrification (SCAD) / advanced nitrogen removal

Cite this article

Download citation ▾
Tian WAN, Guangming ZHANG, Fengwei DU, Junguo HE, Pan WU. Combined biologic aerated filter and sulfur/ceramisite autotrophic denitrification for advanced wastewater nitrogen removal at low temperatures. Front. Environ. Sci. Eng., 2014, 8(6): 967-972 DOI:10.1007/s11783-014-0690-9

登录浏览全文

4963

注册一个新账户 忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Loucks D P, Jia H. Managing water for life. Frontiers of Environmental Science & Engineering, 2012, 6(2): 255–264
[2]

Carey R O, Migliaccio K W. Contribution of wastewater treatment plant effluents to nutrient dynamics in aquatic systems: a review. Environmental Management, 2009, 44(2): 205–217
[3]

Soares M I M. Biological denitrification of groundwater. Water, Air, and Soil Pollution, 2000, 123(1-4): 183–193
[4]

Mirvish S S. N-nitroso compounds: Their chemical and in vivo formation and possible importance as environmental.Journal of Toxicology and Environmental Health, 1977, 2(6): 1267–1277
[5]

Kalkan Ç, Yapsakli K, Mertoglu B, Tufan D, Saatci A. Evaluation of biological activated carbon (BAC) process in wastewater treatment secondary effluent for reclamation purposes. Desalination, 2011, 265(1-3): 266–273
[6]

Garron A, Epron F. Use of formic acid as reducing agent for application in catalytic reduction of nitrate in water. Water Research, 2005, 39(13): 3073–3081
[7]

Rezania B, Oleszkiewicz J A, Cicek N. Hydrogen-dependent denitrification of water in an anaerobic submerged membrane bioreactor coupled with a novel hydrogen delivery system. Water Research, 2007, 41(5): 1074–1080
[8]

Wang S, Ma J, Liu B, Jiang Y, Zhang H. Degradation characteristics of secondary effluent of domestic wastewater by combined process of ozonation and biofiltration. Journal of Hazardous Materials, 2008, 150(1): 109–114
[9]

Helmer C, Kunst S, Juretschko S, Schmid M C, Schleifer K H, Wagner M. Nitrogen loss in a nitrifying biofilm system. Water Science and Technology, 1999, 39(7): 13–21
[10]

Seca I, Torres R, Val del Río A, Mosquera-Corral A, Campos J L, Méndez R. Application of biofilm reactors to improve ammonia oxidation in low nitrogen loaded wastewater. Water Science and Technology, 2011, 63(9): 1880–1886
[11]

Liu H J, Jiang W, Wan D J, Qu J H. Study of a combined heterotrophic and sulfur autotrophic denitrification technology for removal of nitrate in water. Journal of Hazardous Materials, 2009, 169(1-3): 23–28
[12]

Kimura K, Nakamura M, Watanabe Y. Nitrate removal by a combination of elemental sulfur-based denitrification and membrane filtration. Water Research, 2002, 36(7): 1758–1766
[13]

Dong Y M, Zhang Z J, Jin Y W, Li Z R, Lu J. Nitrification performance of nitrifying bacteria immobilized in waterborne polyurethane at low ammonia nitrogen concentrations. Journal of Environmental Sciences-China, 2011, 23(3): 366–371
[14]

Chen Q, Qu L, Tong G, Ni J. Simultaneous nutrients and carbon removal from low-strength domestic wastewater with an immobilised-microorganism biological aerated filter. Water Science and Technology, 2011, 63(5): 885–890
[15]

Ryu H, Kim D, Lim H H, Lee S. Nitrogen removal from low carbon-to-nitrogen wastewater in four-stage biological aerated filter system. Process Biochemistry, 2008, 43(7): 729–735
[16]

Komorowska K M, Majcherek H, Klaczynski E. Factors affecting the biological nitrogen removal from wastewater. Process Biochemistry, 2006, 41(5): 1015–1021
[17]

Koenig A, Liu L H. Autotrophic denitrification of high-salinity wastewater using elemental sulfur: batch tests. Water Environment Research, 2004, 76(1): 37–46
[18]

Moon H S, Nam K, Kim J Y. Initial alkalinity requirement and effect of alkalinity sources in sulfur-based autotrophic denitrification barrier system. Journal of Environmental Engineering, 2006, 132(9): 971–975
[19]

Albuquerque A, Makinia J, Pagilla K. Impact of aeration conditions on the removal of low concentrations of nitrogen in a tertiary partially aerated biological filter. Ecological Engineering, 2012, 44: 44–52
[20]

Kim J H, Guo X J, Park H S. Comparison study of the effects of temperature and free ammonia concentration on nitrification and nitrite accumulation. Process Biochemistry, 2008, 43(2): 154–160
[21]

American Public Health Association (APHA), American Water Works Association (AWWA), Water Environment Federation (WEF). Standard Methods for the Examination of Water and Wastewater. 20th ed. Washington, D C, USA: APHA, AWWA, WEF, 1999
[22]

Zhu S M, Chen S L. The impact of temperature on nitrification rate in fixed film biofilters. Aquacultural Engineering, 2002, 26(4): 221–237
[23]

Koenig A, Liu L H. Kinetic model of autotrophic denitrification in sulphur packed-bed reactors. Water Research, 2001, 35(8): 1969–1978
[24]

Trouve C, Chazal P M, Gueroux B, Sauvaitren N. Denitrification by new strains of Thiobacillus denitrificans under non-standard physicochemical conditions: Effect of temperature, pH and sulphur source. Environmental Technology, 1998, 19(6): 601–610
[25]

Zhang T C, Lampe D G. Sulfur limestone autotrophic denitrification processes for treatment of nitrate contaminated water: batch experiments. Water Research, 1999, 33(3): 599–608

RIGHTS & PERMISSIONS

Higher Education Press and Springer-Verlag Berlin Heidelberg

AI Summary AI Mindmap
PDF (156KB)

2896

Accesses

0

Citation

Detail
Sections
Recommended

AI思维导图

/