• 상하수도학회지
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• 제23권4호
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• pp.439-446
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• 2009

This study was performed to evaluate SND(simultaneous nitrification and denitrification)efficiency, nitrogen removal efficiency and filtration function of non-woven fabric by using submerging MBR packed with granular sulfur covered with non-woven fabric filter. Synthetic wastewater was used as influent wastewater. Concentration of $NH_4{^+}-N$ in influent was maintained about 40 mg/L and the experiment was performed in four phases according to the flow rate. Nitrogen loading rate divided four phases ranging from $0.04 kg\;NH_4{^+}-N/m^3-day$ to $0.16 kg\;NH_4{^+}-N/m^3-day$. As a result, the maximum $NH_4{^+}-N$ removal rate was accomplished at $0.142 kg\;NH_4{^+}-N/m^3-day$ in nitrogen loading of $0.147 kg\;NH_4{^+}-N/m^3-day$. Nitrification efficiency was higher than 95% in all phases. $NO_3{^-}-N$ loading rate was adjusted ranging from $0.22 kg\;NO_3{^-}-N/m^3-day$ to $0.89 kg\;NO_3{^-}-N/m^3-day$. The maximum $NO_3{^-}-N$ removal rate was accomplished up to $0.71 kg\;NO_3{^-}-N/m^3-day$ in $NO_3{^-}-N$ loading of $0.89 kg\;NO_3{^-}-N/m^3-day$. The maximum $NO_3{^-}-N$ removal efficiency was 95% in $NO_3{^-}-N$ loading of $0.22 kg\;NO_3{^-}-N/m^3-day$. T-N removal rate was 90% and concentration of T-N in effluent was 3.7 mg/L in T-N loading rate of $0.039 kg\;NO_3{^-}-N/m^3-day$. In this study, TMP in reactor with and without non-woven fabric filter were observed to define fouling of hollow-fiber membrane module. Reaching time to standard washing pressure(22 cm Hg) of two reactors were 29 days with non-woven fabric But the reactor without non-woven fabric reached standard washing pressure only after 4 days. Accordingly, non-woven fabric was demonstrated the superiority as a filtration ability. With high nitrogen removal rate and decreasing of fouling of membrane, MBR packed with granular sulfur covered with non-woven fabric filter submerging in activated sludge aeration tank can be used as an advanced treatment process.

• 한국생물공학회:학술대회논문집
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• 한국생물공학회 2005년도 생물공학의 동향(XVII)
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• pp.434-438
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• 2005

생물반응기의 운전 특성과 성능은 온도나 pH, 용존산소 등의 물리화학적 조건 외에 미생물의 종류와 분포비율, 미생물의 대사상태에 따라서도 매우 다양한 특성을 보인다. 질산화 미생물 코팅 담체를 투입한 반응조에서는 담체가 없는 반응조에 비해 질산화 미생물의 양이 증가하였고, 또한 질산화 미생물이 코팅된 담체를 사용한 반응기는 코팅되지 않은 담체를 투입한 반응조에 비해 질산화 미생물 양의 상승효과가 있었다. 질산화 미생물의 양은 운전 기간과 수온의 상승에 따라 증가하는 것으로 나타났다.

• 상하수도학회지
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• 제24권1호
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• pp.51-62
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• 2010

The high concentration of N in the wastewater from livestock farming generally renders the efficiency of the wastewater treatment. Therefore, removal of N in livestock wastewater is crucial for successful treatment. The current study was conducted to investigate the optimum conditions for partial nitrification under anaerobic condition following nitritation in TPAD-BNR(two-phase anaerobic digestion-biological nitrogen removal) operating system. Sequential operating test to stimulate partial nitrification in reactor showed that partial nitrification occurred at a ratio of 1.24 in $NO_2{^-}$-N:$NH_4{^+}$-N. With this result, a wide range of factors affecting stable nitritation were examined through regression analysis. In the livestock wastewater treatment procedure, the hydraulic retention time (HRT) and pH range for optimum nitrite accumulation in the reactor were 1-1.5 days and 7-8, respectively. It was appeared that accumulation of $NO_2{^-}$-N in the reactor is due to inhibition of the $NO_2{^-}$-N oxidizer by free ammonia (FA) while the effect of free nitrous acid was minimal. Nitrification was not influenced by DO concentration at a range of 2.0-3.0 mg/L and the difference in the growth rate between $NH_4{^+}$-N oxidizer and $NO_2{^-}$-N oxidizer was dependent on the temperature in the reactor.

• 한국미생물·생명공학회지
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• 제34권3호
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• pp.257-264
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• 2006

침지형 막/생물반응기에 암모니움 합성폐수를 공급하여 약 350일 동안 운전하면서 질산화 특성 및 미생물의 분포 변화를 살펴보았다. 원수의 암모니움 농도는 500-1000 $mgNH_4-N/L$, 질소 부하는 $1-2\;kgN/m^3{\cdot}d$로 공급하였고, 용존산소(DO)농도, 슬러지 체류시간(SRT), 온도 변화에 따른 질산화 효율, 아질산성 질소의 비율, 슬러지 농도, sludge volume index(SVI)변화를 모니터링 하였다. DO 농도, 온도, SRT 증가에 따라 암모니움 산화율은 증가하였으며, 이와 같은 암모니움 산화율의 감소로 MBR 내에서 free ammonia($NH_3-N$)농도가 증가할 경우 처리수에서 아질산성 질소의 비율이 높아졌다. 운전 기간 중 원인이 뚜렷하지 않은 질산화 효율의 급격한 감소가 관찰되었는데, 이때 슬러지 벌킹 및 SVI 값의 증가가 동시에 수반되었다. 운전 후반부에 질산화균이 우점된 MBR에 추가로 유기물을 공급하면, SVI 값이 2배로 증가하였고 암모니움 산화율은 감소하였다. FISH 분석에서 나타난 MBR내의 미생물 분포는 암모니아 산화균의 경우 Nitrosomonas가 우점하였으나 운전 후반부로 갈수록 Nitrosospira의 비율이 Nitrosomonas와 비슷할 정도로 증가하였다. 아질산 산화균은 Nitrospira가 우점하였지만 Nitrobacter 역시 운전기간 내내 관찰되었는데, 이는 MBR 내에서 높게 유지된 아질산성 질소가 Nitrobacter의 성장에 도움을 준 것으로 보인다.

• 한국물환경학회지
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• 제24권3호
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• pp.383-390
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• 2008

Recently, the interests on economical nitrogen removal from wastewater are growing. As a method of the novel nitrogen removal technology, nitrogen removal via nitrite pathway by selective inhibition of free ammonia and free nitrous acid on nitrite oxidizing bacteria have been intensively studied. The inhibition effects of free ammonia and free nitrous acid are low when domestic wastewater is used, however, because of its relatively lower nitrogen concentration than the wastewater from industry and landfill, etc. In this study, a sequencing batch reactor (SBR) is proposed for nitrogen removal to investigate the effect of the low nitrogen concentration on nitrite accumulation. Nitrification efficiency reached almost 100% during the aerobic cycle and the maximum specific nitrification rate ($V_{max,nit}$) reached $17.8mg\;NH_4{^+}-N/g\;MLVSS{\bullet}h$. During the anoxic cycle, average denitrification efficiency reached 87% and the maximum specific denitrification rate ($V_{max,den}$) reached $9.8mg\;NO_3{^-}-N/g\;MLVSS{\bullet}h$. From the analysis the main reason of nitrite accumulation in the SBR was free nitrous acid rather than free ammonia. Nitrite accumulation increased with the decrease of organic content in the wastewater and the mechanism is not well understood yet. From the result of fluorescent in situ hybridization, the distribution of nitrite oxidizing bacteria was in equilibrium with ammonium oxidizing bacteria when nitrite accumulation did not occur.

• 대한환경공학회지
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• 제27권5호
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• pp.542-548
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• 2005

부착 미생물을 이용한 다공성 담체 유동상 반응기는 하폐수중의 유기물 및 질소제거에 많이 적용되어져 왔다. 특히 생물막이 형성된 담체에서는 호기, 무산소 그리고 혐기영역이 공존하여 동시적 질산화/탈질 반응에 의한 질소제거에 유리한 환경이 제공된다고 알려져 있다. 이러한 반응을 활성화시키기 위해서는 담체표면과 내부에서 산소와 유기물등의 적절한 기질확산이 이루어져야 한다. 그러나 하폐수중의 유기물농도나 생물막의 마찰조건등 운전조건에 따라서는 표면에서의 종속영양균의 과잉성장에 의해 질소 제거 반응이 저해되기도 한다. 다공성 담체 유동상 반응기에 막모듈을 결합시킨 하이브리드 반응기는 단일조내에서 활성화된 동시적 질산화/탈질 반응으로 종래의 유동상 반응기에 비해 30% 이상 질소제거 효율이 증가하였다. 미소전극 연구를 통해 담체내부의 탈질율을 조사할 수 있으며 유동상 반응기에 비하여 하이브리드 반응기내 담체내부에서는 탈질반응에 대한 유기물의 확산에 대한 제한인자가 작으며 따라서 보다 높은 탈질율을 유지할 수 있음을 보였다.

• 한국농림기상학회:학술대회논문집
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• 한국농림기상학회 2005년도 추계 학술발표논문집
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• pp.164-167
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• 2005

• KSBB Journal
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• 제16권6호
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• pp.573-578
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• 2001

직경 0.613mm 활성탄 입자를 생물입자 담체로 사용한 공기리프트 생물막 반응기를 폐수 질화에 적용하여 생물막을 형성시켰다. 공기유속과 암모니움 부하속도(유입수 유량)를 순차적으로 증가시키어 반응기 운전 약 130일 만에 140um 두께의 생물막을 형성시켰다. 온도 3$0^{\circ}C$ 및 상승관 공기유속 6.3cm/s에서 5.0 kg N/㎥.d의 암모니움 산화속도를 얻었다. 생물막 형성 초기에는 암모니움 산화 균주가 주로 형성되어 아질산 축적이 발생하였으며 아질산 완전 산화되었다. 유기물 부하율을 증가시킴에 따라 COD 제거속도는 증가하여 26.6 kg COD/㎥.d의 부하율에서 25.0 kg COD/㎥.d의 제거속도를 보여 94%의 제거효율을 보였다. 반면에 COD 제거속도가 증가함에 따라 암모니움 및 아질산 산화속도는 감소하였다. 특히 약 11 kg/㎥.d 이상의 COD 제거속도에서 많은 종속영양균주 과잉 슬러지가 반응기 액상에서 관찰되었으며 암모니움 및 아질산 산화속도는 COD 제거속도가 증가함에 따라 급격히 감소하였다. 용존산소가 물질확산 저항을 적게 받는 반응기 액상 부유 유기물 산화 균체에 의해 우선적으로 이용되어 반응기 액상 농도가 낮은 값을 보여서 물질확산 저항이 크게 작용하는 생물막에 주로 존재하는 질화균체에 의해 적게 사용된 것으로 생각된다. 이러한 결과는 종속영양균주의 반응기 액상 부유 생장이 생물입자 생물막에서의 독립영양균주 생장에 의한 질화에 유리하다는 제안과 일치하지 않는다. 용존산소 농도를 증가시킴에 따라 순수질화에서 암모니움 및 아질산 산화속도는 증가하였으며, 순산소를 사용할 경우 공기를 사용한 경우에 비하여 약 5배의 높은 암모니움 산화속도를 보였다.

• 한국환경복원기술학회지
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• 제5권6호
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• pp.24-29
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• 2002

Nitrate removal rate in three cattail wetland cells was investigated. They were a part of a pond-wetland system for stream water treatment demonstration. The system was composed of two ponds and six wetland cells. The acreage of each cell was approximately $150m^2$. The earth works for the system were finished from April 2000 to May 2000 and cattails were planted in the three cells in June 2000. Waters of Sinyang Stream flowing into Kohung Estuarine Lake were pumped into a primary pond, whose effluent was discharged into a secondary pond. The reservoir was formed by a tidal marsh reclamation project and located in southern coastal area of Korean Peninsula. Effluents from the secondary pond were funneled into the three cells. Volumes and water quality of inflow and outflow were analyzed from July 2000 through January 2001. Inflow and outflow averaged $20.2m^3/day$ and $19.8m^3/day$, respectively. Hydraulic retention time was about 1.6 days. Average influent and effluent nitrate concentration was $1.98mg/{\ell}$, $1.38mg/{\ell}$, respectively. Nitrate removal rate averaged $82.6mg\;m^{-2}\;day^{-1}$. Seasonal changes of nitrate retention rates were closely related to those of wetland cell temperatures. The average nitrate removal rate in the cells was a little lower, compared with that of $125.0mg\;m^{-2}\;day^{-1}$ for the wetlands operating in North America. This could be attributed to the initial stage of the cells and inclusion of three cold months into the seven-month study period. Root rhizosphere in wetland soils and litter-soil layers on cell bottoms could not developed. Increase of standing density of cattails within a few years will establish both root zones suitable for the nitrification of ammonia to nitrates and substrates beneficial to the denitrification of nitrates into nitrogen gases, which may lead to increase of the nitrate retention rate.

• 한국환경보건학회지
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• 제27권1호
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• pp.112-118
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• 2001

The aim of this study was to evaluate on the removal effect of total nitrogen and phosphorus in municipal wastewater with temperature change from 1$0^{\circ}C$ to 24$^{\circ}C$ in CNR(Cilia Nutrient Removal) process. CNR process is the process combining $A^2$/O process with cilium media of H2L company. The removal efficiencies for T-N were found to be 57.9% at 1$0^{\circ}C$ below, 53.7% at 10-2$0^{\circ}C$, 52.2%at 20-24$^{\circ}C$ and 44.4% over 24$^{\circ}C$ respectively. The removal efficiencies for T-P were 53.3% at 1$0^{\circ}C$ below, 59.1% at 10-2$0^{\circ}C$, 72.4% at 20-24$^{\circ}C$ and 50.0% over 24$^{\circ}C$ respectively. The specific nitrification rate (kg NH$_3$-N/kg MLSS.d) of Oxic basin was 0.088 and 0.053 at 1$0^{\circ}C$ below, 0.077 at 10-2$0^{\circ}C$, 0.097 at 20-24$^{\circ}C$ and 0.088 over 24$^{\circ}C$ respectively. The specific denitrification rate (kg NH$_3$-N/kg MLSS.d) in anaerobic and anoxic was 0.013, 0.008 respectively.