A study on the denitrification of reverse osmosis(RO) concentrated wastewater from sewage reuse treatment plant in P city was conducted using waste desulfurization agent obtained from desulfurization process. Sulfur-based autotrophic denitrifying carrier comprises the predetermined amount of waste iron sulfide (FeS, Fe2S3), mine drainage sludge and elemental sulfur showing mesoporisity with 9.9 nm (99 Å) of average pore size. Sulfur denitrifying bacteria and sulfur reducing bacteria were implanted into the pores of sulfur denitrifying carrier. Nitrate was not affected by empty bed contact time (EBCT). It is probably due to larger reducing capacity of the carrier than the concentration of nitrate in RO concentrated wastewater. Total nitrogen (T-N) removal efficiency exhibited about 90% after 4 days. Sulfate ion was surprisingly decreased with sulfur autotropic process due to the reduction of sulfate ion to HS- and S2- by sulfur reducing bacteria. Sulfide and hydrogen sulfide ions were then taken by Fe(OH)3, main component of mine drainage sludge, releasing OH-. Alkalinity was therefore maintained between 7.5 and 8.5 in pH by the released OH-. Also, it had the effect of suppressing the production of H2S, which causes bad odor.

The object of this study is to feasibility assesment for co-digestion efficiency of food waste recycling wastewater(FWR) with thermal hydrolysis process dehydration cake (THP Sludge). As a result of THP pre-treatment experimental conditions to 160oC and 30 minutes, the solubility rate(conversion rate of TCOD to SCOD) of the THP sludge increased by 34%. And the bio-methane potential in the THP sludge increased by about 1.42 times from 0.230 to 0.328 m3 CH4/kg VS compared to the non-pre-treatment. The substrates of the co-digestion reactor were FWR and THP sludge at a 1:1 ratio. Whereas, only FWR was used as a substrate in the digestion reactor as a control group. The experimental conditions are 28.5 days of hydraulic retention time(HRT) and 3.5 kg VS/m3-day of organic loading rate(OLR). During the 120 days operation period, the co-digestion reactor was able to operate stably in terms of water quality and methane production, but the FWR digestion reactor deteriorated after 90 days, and methane production decreased to 0.233 m3 CH4/kg VS, which is 67% of normal condition. After 120 days of the experiment, organic loading rate(OLR) of co-digestion reactor was gradually increased to 4.5 kg VS/m3-day and operated for 80 days. Methane production during 80 days was evaluated to be good at the level of 0.349 m3 CH4/kg VS. As a result of evaluating the dehydration efficiency of the sludge before/after 150-180oC THP using a filter press, it was confirmed that the moisture content of the sludge treated before THP at 180oC was 75% and improved by 8% from 83-85% level. Therefore, it is expected that the co-digestion reactor of FWR and THP sludge will ensure stable treatment water quality and increase bio-methane production and reduction effect of dehydration sludge volume.

Sulfide dissolved in wastewater is a potential source of hydrogen sulfide. Hydrogen sulfide is an odorous substance that causes civil complaints and is a dangerous substance that threatens the corrosion of structures and the safety and health of workers. The removal efficiencies of the chemical oxidant and the coagulants were compared to evaluate the removal of dissolved sulfide. Since the effectiveness may vary depending on the characteristics of the wastewater, water was used as a control, and 5 mg/L of dissolved sulfide was dissolved in water and sewage wastewater. When oxidant was used, the results showed a high sulfide removal rate in sewage wastewater than water, and the removal efficiency was enhanced with increasing oxidant concentration. Sulfide removal efficiencies after one hour after injecting oxidants H2O2, NaOCl, NaClO2 to sewage wastewater were 70%, 90%, and 100%, respectively. After the oxidants were administered four times, the removal was 90%, 100%, and 100%, respectively. In the case of sulfide removal with the oxidizing agent, the removal efficiency was NaClO2, NaOCl, H2O2 (highest - lowest). NaClO2 showed 100% removal efficiency within 10 minutes under all conditions (A condition, B condition), making it the most sewage effective agent in this study. In the case of the coagulants, 100% of the sulfides dissolved in water were removed in the first 10 minutes under all conditions. In sewage wastewater, FeCl2 and FeSO4 also showed 100% removal efficiency under all conditions after one hour, and FeCl3 showed 90% and 99% removal rates under A and B conditions, respectively. That is, the monovalent iron coagulants (FeCl2, FeSO4) were found to be somewhat more effective in the removal of sulfides in sewage wastewater than the divalent iron (FeCl3) coagulants. When the sulfides were removed with coagulants, FeCl2 had the highest removal efficiency followed by FeSO4 and FeCl3. Moreover, it was found that NaClO2 has the best reaction efficiency at the minimum reaction time and the reaction concentration.

The sewage and wastewater (SAW) are a well-known major source of eutrophication and greentide in freshwaters and also a potential source of thermal pollution; however, there were few approaches to thermal effluent of SAW in Korea. This study was performed to understand the behavioral dynamics of the thermal effluents and their effects on the water quality of the connected streams during winter season, considering domestic sewage, industrial wastewater and hot spring wastewater from December 2015 to February 2016. Sampling stations were selected the upstream, the outlet of SAW, and the downstream in each connected stream, and the water temperature change was monitored toward the downstream from the discharging point of SAW. The temperature effect and its range of SAW on the stream were dependent not only on the effluent temperature and quantity but also on the local air temperature, water temperature and stream discharge. The SAW effects on the stream water temperature were observed with temperature increase by 2.1~5.8℃ in the range of 1.0 to 5.5 km downstream. Temperature effect was the greatest in the hot spring wastewater despite of small amount of effluent. The SAW was not only related to temperature but also to the increase of organic matter and nutrients in the connected stream. The industrial wastewater effluent was discharged with high concentration of nitrogen, while the hot spring wastewater was high in both phosphorus and nitrogen. The difference between these cases was due to with and without chemical T-P treatment in the industrial and the hot spring wastewater, respectively. The chlorophyll-a content of the attached algae was high at the outlet of SAW and the downstream reach, mostly in eutrophic level. These ecological results were presumably due to the high water temperature and phosphorus concentration in the stream brought by the thermal effluents of SAW. These results suggest that high temperature of the SAW needs to be emphasized when evaluating its effects on the stream water quality (water temperature, fertility) through a systematized spatial and temporal investigation.

This study was intended to evaluate the removal efficiency of nutrients in effluents of wastewater using microalgae. Microalgae used in the culture experiment collected in stream and reservoir located in Gyeongsangbuk-do. Dominant species in prior-culture tank were Monoraphidium contortum, Scenedesmus acutus, Coelastrum microporum and Chlorella sp. Dominant species in synthetic wastewater culture under the 4000 Lux and 8000 Lux were Chlorella sp. and Scenedesmus obliquus. The removal efficiency of NO3-N under the 4000 Lux and 8000 Lux were 27.2%~88.1% and 63.0%~83.6% respectively. The removal efficiency of PO4-P under the 4000 Lux and 8000 Lux showed above 93%. Removal efficiency of nutrients of 1.0×106 cells mL-1 inoculation concentration was more higher than that of nutrients of 1.0×105 cells mL-1 and 1.0×107 cells mL-1 inoculation concentration. Microalgae cultured in synthetic wastewater removed 94.9% of TN and 90.0% of TP. The removal rate of TN and TP in synthetic wastewater were 1.961 mg L-1 day-1 and 0.200 mg L-1 day-1 respectively. Nutrient removal efficiency of microalgae according to kinds of wastewater showed the highest in the private sewage.

In this study, we investigated influent and effluent water pollutants in 53 Public Sewage Treatment Works (PSTWs) where industrial wastewater or landfill leachate is combined four times for two years from 2014 to 2015. Also, we analyzed the characteristics of heavy metals and volatile organic carbons at influent and effluent of these PSTWs caused by sewage treatment combined with industrial wastewater or landfill leachate. As a result, six heavy metals such as barium, copper, iron, manganese, nickel and zinc, and four volatile organic carbons (VOCs) including phenols, di(2-)ethylhexyl phthalate (DEHP), formaldehyde and toluene were observed above detection limits in most of PSTWs. Also, it was revealed that six heavy metals such as hexavalent chromium, mercury, cadmium, chromium, nickel and selenium, and four VOCs including 1,1-dichloroethylene, vinyl chloride, naphthalene, and epichlorohydrin were observed more frequently according to precipitation. As a result of reviewing the monitoring data on “Water Quality Monitoring Networks” in lower watersheds of PSTWs, both heavy metals and VOCs were below detection limits, indicating that the effluent water had little influence on the watershed. Nevertheless for the better management of influent and effluent pollutants in PSTWs, it is necessary to establish the advanced management plans for water pollutants in PSTWs, which include a list of priority substances management, monitoring plans, and guidelines for industrial wastewater and landfill leachate combined in PSTWs.

The economic effects of sewage and wastewater treatment service (SWTS) sector on other sectors have been rarely investigated in the literature. This paper attempts to apply an inter-industry analysis to looking into the economic effects of the SWTS sector. To this end, the most recently published 2012 input-output table is used here. In particular, the SWTS sector is specified as exogeneous to identify the economic effects of the SWTS sector on other sectors. Production-inducing effect, value-added creation effect, and employment-inducing effect are quantified based on demand-driven model. Supply shortage effect and price pervasive effect are also analyzed employing supply-driven model and Leontief price model, respectively. The results show that production-inducing effect and value-added creation effect of a unit of investment or production in SWTS sector are estimated to be 1.7076 and 0.7392, respectively. The employment-inducing effect of one billion of investment or production in the SWTS sector is computed to be 11.0498 persons. The shortage effect of the SWTS sector amounts to 0.8417 won. The overall price effect of the 10% increase in the price of SWTS sector is calculated to be 0.0115%. This quantitative information can be utilized in predicting the economic effects of the SWTS sector-related activities or policy-making.

본 연구에서는 생활오수, 산업폐수, 축산폐수 등에서 발생하는 질산성화합물 및 난분해성 화합물을 효과적으로 처리하기 위해 막분리법과 다공 전극형 전기분해법을 조합한 하 폐수의 고도처리 기술을 제안하였고 제안 시스템의 효율성을 검토하였다. 제안하는 시스템은 활성슬러지 공정, 막분리 공정, 다공 전극형 전기분해공정의 3단계로 구성하였다. 본 연구에서 구성되는 막분리 공정은 부유물질을 제거해줌으로써 전기분해공정의 부하를 최소화할 수 있는 역할을 담당할 수 있게 하여 시스템을 안정하게 운전할 수 있도록 하였다. 전기분해 하이브리드 공정에 있어서는 다공성 전극으로 구성함으로써 비표면적의 확대로 인한 전극의 효율성을 높였다. 아울러 외부전압을 인가함에 따라 처리제의 공급 없이 장치에 유입된 물을 분해시킴으로써 산화 환원 반응을 유도하였다. 즉 중간체로서 수소 자유전자 라디칼과 산소원자 라디칼이 발생되어 난분해성 유기물을 산화 분해하는 역할을 담당하도록 하였다. 이는 전극 내에서 발생하는 중간체를 폐용질의 분해에 사용하기 때문에 친환경적 처리공법이었다. 실험결과들은 제안공정이 활성슬러지공법에 비하여 우수한 공정임을 보여 주었다. SS제거율은 제안공정, 막분리공정, 활성슬러지 단독공정에서 각각 약 100%, 약 100%, 약 90%였고 COD 제거효율은 제안공정 약 92%, 막분리공정 약 84%, 활성슬러지 단독공정 약 75%였으며 T-N의 제거효율은 제안공정 약 88%, 막분리공정 약 67% 활성슬러지 단독공정 약 58%였다. 이결과는 SS의 제거에 있어서 막분리 하이브리드 공정만으로도 부유물질이 충분히 제거됨을 나타내고 있었다. COD의 제거에 있어서 막분리 하이브리드 공정은 SS분의 제거를 통한 COD와 SS이외의 유기물질이 소량제거 되었음을 보였고 전기분해 하이브리드 공정에 있어서는 유기물질의 산화반응을 통한 분해로 높은 제거효율을 보였다. T-N의 제거에 있어서는 막분리 하이브리드 공정은 SS분에 포함된 부분과 소량의 유기물에 포함된 부분이 제거되고 있는 반면 전기분해 공정에 있어서는 유기물질의 산화분해반응으로 인한 높은 제거효율을 나타내고 있었다.

Based on the experiment results of laboratory scale modified anoxic-oxic process for leachate treatment, biological nitrogen removal program was verified in terms of SS, COD, and TN concentration. These measured water qualities concentration could be predicted by biological nitrogen removal program with R2 of 0.994, 0.987, 0.990, respectively. No error was occurred between water qualities concentration and quite wide range of water qualities concentration (i.e., 50-4200 mg/L) during the modelling. Each unit and final effluent of simulated concentration was kept good relationship with that of measured concentration therefore this biological nitrogen removal program for sewage or wastewater treatment plants has good reliance.

우리나라는 런던협약 이행을 위하여 2012년부터 하수슬러지의 해양투기를 금지하고, 매립용 복토재, 발전소 보조연료, 바이오가스 생산 원료 등 하수슬러지를 다양한 재활용 물질로써 활용하기 위한 방법을 모색하여왔다. 이중 수열탄화(Hydrothermal carbonization)방법은 닫힌계에서 180℃~250℃온도조건과 이때 생성되는 반응기내 압력으로 운영되는 기술로, 기존 건조기술대비 에너지소비가 적은 연료화 기술이나 수열탄화 공정이후 다량으로 발생하는 탈리액의 처리가 필요하다. 이처럼 수열탄화 공정이후 고액분리된 액체생성물을 효과적으로 처리·활용하고자 본 연구는 하수슬러지 수열탄화 액체생성물의 단독 혐기소화 및 음폐수와의 혼합소화실험을 통하여 바이오가스 생산추이를 비롯한 혐기소화 특성변화를 관찰하였다. 실험은 유효용적 5L 규모의 혐기성소화조를 이용하였고, 35℃ 항온조건을 유지하기 위하여 water jacket형태로 반응기를 구성하였으며, 반응기 내부 균질화를 위하여 80rpm속도로 기계적 교반을 진행하였다. 유기물부하율(OLR)은 1g VS/L-day로 운영후 1.5g VS/L-day까지 증대시켰다. 실험 결과, OLR 1g VS/L-day 조건에서 하수슬러지 수열탄화 액체생성물의 경우 0.17L/g COD의 메탄전환율을 보였고, 음폐수혼합액의 경우 메탄전환율은 0.30L/g COD로 수열탄화 액체생성물 단독소화일 때 보다 높은 값을 보였다. OLR 1.5g VS/L-day 조건에서는 수열탄화액 액체생성물 단독처리시 OLR 1g VS/L-day 조건보다 메탄전환율이 크게 감소하는 경향을 보였고, 음폐수 혼합액은 OLR 1g VS/L-day 조건과 유사한 메탄전환율을 나타냈다.

최근 산업발전에 따른 폐기물의 발생량과 재활용되지 못하고 매립되는 폐기물이 증가하고 있다. 우리나라는 국토환경의 제약에 따라 매년 증가하는 폐기물에 대해 “미처리폐기물의 매립제로화”를 주요과제로 추진하고 있다. 또한 2035년 까지 재활용가능 폐기물의 직매립을 금지하고, 매립처리비율 1% 이하로 달성하고자 한다. 따라서 2015년도 “폐기물 발생 및 처리현황(2015)” 에서 매립처리가 23,577 톤/일로 가장 많은 사업장배출시설계 폐기물을 분석하였다. 그중 오니류 폐기물의 매립처리가 8,926 톤/일로 사업장배출시설계폐기물의 매립처리량대비 약 38 %의 비율을 차지하고 있다. 오니류의 경우 유기성과 무기성으로 구분되어지고 하수처리오니, 폐수처리오니 등으로 구분되어진다. 특히 폐수처리오니의 경우 사업장 별 업종이 무수히 다양하기 때문에 매립억제를 위한 특성조사는 한국표준산업분류코드를 이용하여 구분하였다. 본 연구는 매립되는 하･폐수처리오니를 유･무기성으로 분류하고 배출사업장 업종별로 구분한 처리현황과 매립되고 있는 오니류의 에너지회수 대상으로서 가능성을 보기위한 삼성분, 발열량 및 원소분석의 특성을 고찰하였다. 전체 업종의 유기성오니류 평균은 수분함량 71.7 %, VS의 함량은 60.6 %, FS의 함량은 39.4 %이며, 발열량은 2,948 kcal/kg로 나타났다. 무기성오니류의 수분함량은 65.8 %, VS의 함량은 27.1 %, FS의 함량은 72.9 %이며, 발열량은 1,096 kcal/kg로 나타났다. 따라서 유기성오니류의 에너지회수 가능성을 확인하였고 이를 통한 사업장배출시설계폐기물의 매립저감이 예상된다.

Water samples from several wastewater treatment plants and two industry drains in Gyeongsangbukdo were investigated for concentration levels of micropollutants. Samples were taken totally four times from May to November of 2008 and tested for seven factors including pesticide, 1,4-Dioxane and Perchlorate which had been big issues for Nakdong river because of their contaminations. As results, 2,4-D, Alachlor, and BEHA were not detected while BEHP was detected at some sampling sites. 1,4-Dioxane and Perchlorate were also detected in wide ranges from several sampling sites. Therefore, continuous supervising and monitoring systems needed to be invested for proper management for micropollutants since those micropollutants could affect human health and aquatic system with low concentration levels.

Currently, the application of TiO2 photocatalyst has been focused on purification and treatment of wastewater. However, the use of conventional TiO2 slurry photocatalyst results in disadvantage of stirring during the reaction and of separation after the reaction. And the usage of artificial UV lamp has made the cost of photocatalyst treatment system high. Consequently, we studied that solar light/TiO2 film system was designed and developed in order to examine disinfection characteristics of sewage wastewater treatment. The optimum conditions for disinfection such as solar light intensity, characteristic of sewage wastewater, amounts of TiO2 and comparison of solar ligth/TiO2 systems with UV light/TiO2 system was examined. The results are as follows: (1) photocatalytic disinfection process with solar light in the presence of TiO2 film more effectively killed total coliform (TC) than solar light or TiO2 film absorption only. (2) The survival ratio of TC and residual ratio of organic material (BOD, CODcr) decreased with remain resistant material. (3) The survival ratio of TC and residual ratio of organic material (BOD, CODcr) decreased with the increase of amounts of TiO2. (4) TC survival ratio decreased linearly with increasing UV light intensity. (5) The disinfection effect of solar light/TiO2 slurry system decreased more than UV light/TiO2 film systems. (6) The disinfection reaction followed first-order kinetics. We suggest that solar light instead of using artificial UV light was conducted to investigate the applicability of alternative energy source in the disinfection of TC and the degradation of organic material.

선박에서 발생하는 오·폐수를 처리하기 위하여 생물학적 질소 및 인의 제거공정으로 사용되고 있는 연속 회분식 공정을 이용하여 유기물의 제거 특성과 산소 소모량, 반응조내에서 우점하고 있는 Bacillus sp.균주의 상태를 알아보기 위하여 Lab-sacle로 수행하였다. 반응조에서 COD의 제거효율은 92.0%, 암모니아성질소는 90.0%, 총질소의 제거효율은 84.0%, 인의 제거효율은 93.0%로 나타났다. Bacillus sp.를 이용한 SBR를 사용한 선박폐수의 처리효율은 안정적이었다. 포기시에 SBR 내의 pH는 초기의 8.1에서 30분동안에 pH는 7.0으로 감소하였다. 무산소 단계인 3단계와 4단계에서 pH는 증가하기 시작하여 최종적으로 pH는 7.3으로 유지되었다. TOC제거량에 대한 슬러지 생성량은 약0.36kg·MLSS/kg·TOC으로 나타났으며 낮은 슬러지 발생율과 높은 슬러지 침강성을 나타내었다. 반응조에서 바실러스균의 평균 우점율은 24.2%로 나타났고 각 반응단계에서 안정적인 처리효율을 얻을 수 있어 충분히 우점화 되었다고 판단할 수 있었다.

This study was carried out to obtain the optimal operating parameter on organic matters and nutrient removal of mixed wastewater which was composed of sewage and stable wastewater using SBR. A laboratory scale SBR was operated with An/Ae(Anaerobic/ Aerobic) ratio of 3/3, 2/4 and 4/2(3.5/2.5) at organic loading rate of 0.14 to 0.27 ㎏BOD/㎥/d. TCOD/SCOD ratio of mixed wastewater was 3, so the important operating factor depended upon the resolving the particulate parts of wastewater. Conclusions of this study were as follows: 1) For mixed wastewater, BOD and COD removal efficiencies were 93-96% and 85-89%, respectively. It was not related to each organic loading rate, whereas depended on An/Ae ratio. During Anaerobic period, the amount of SCOD consumption was very little, because ICOD in influent was converted to SCOD by hydrolysis of insoluble matter. 2) T-N removal efficiencies of mixed wastewater were 55-62% for Exp. 1, 66-76% for Exp. 2, and 67-81% for Exp. 3, respectively. It was found that nitrification rate was increased according to organic concentration in influent increased. Therefore, the nitrification rate seemed to be achieved by heterotrophs. During anoxic period, denitrification rate depended on SCOD concentration in aerobic period and thus, was not resulted by endogenous denitrification. However, the amount of denitrification during anaerobic period were 3.5-14.1㎎/cycle, and that of BOD consumed were 10-40㎎/cycle. 3) For P removal of mixed wastewater, EBPR appeared only Mode 3(3*). It was found that the time in which ICOD was converted to VFA should be sufficient. For mode 3 in each Exp., P removal efficiencies were 74, 87, and 81%, respectively. But for 45-48 of COD/TP ratio in influent, P concentration in effluent was over 1 ㎎/L. It was caused to a large amount of ICOD in influent. However, as P concentration in influent was increased, the amounts of P release and uptake were increased linearly.