The odors emitted from wastewater treatment plants are not only a health and hygiene problem, but can also lead to complaints from residents and have wider social ramifications such as bringing about falling property values in the surrounding area. In this paper, based on the data measured at domestic and overseas wastewater treatment facilities, the concentrations of complex odors and odorous compounds were compared for each treatment/process: primary treatment, secondary treatment, and sludge treatment processes. Odor compounds that contribute greatly to complex odors were summarized for each process. In addition, the characteristics of odor wheels for each wastewater treatment process, which provide both chemical and olfactory information regarding odors, were reviewed. For domestic wastewater treatment facilities, the complex odor concentrations (unit, dilution factor) of the primary and secondary treatment processes were 4.5-100,000 (median, 32.1) and 2.5-30,000 (median, 10.7), respectively. However, the complex odor concentrations in the sludge treatment process were 3.0-100,000 (median, 118.7), which was more than three times higher than that in the wastewater treatment process. In the wastewater treatment process, those odor compounds making the greatest contributions to complex odors were sulfur-containing compounds such as hydrogen sulfide, dimethyl sulfide, and dimethyl disulfide DMS. In order to properly manage odors from wastewater treatment plants and minimize their impact, it is important to understand the status of odor emissions. Therefore, the compositions and concentrations of odors from wastewater treatment processes and odor wheel information, which are reviewed in this paper, are used to evaluate the potential risk of odor from wastewater treatment facilities in order to derive strategies to minimize odor emissions. Moreover, the information can be usefully used to introduce the best available technology to reduce odors emitted from wastewater treatment facilities.

The removal of organic carbon and nutrients (i.e. N and P) from wastewater is essential for the protection of the water environment. Especially, nitrogen compounds cause eutrophication in the water environment, resulting in bad water quality. Conventional nitrogen removal systems require high aeration costs and additional organic carbon. Microbial electrochemical system (MES) is a sustainable environmental system that treats wastewater and produces energy or valuable chemicals by using microbial electrochemical reaction. Innovative and cost-effective nitrogen removal is feasible by using MESs and increasing attention has been given to the MES development. In this review, recent trends of MESs for nitrogen removal and their mechanism were conclusively reviewed and future research outlooks were also introduced.

혐기성 MBR은 에너지 소비가 높은 기존 호기성 처리를 대체할 수 있는 에너지 중립형 기술로서 최근 하폐수 처리의 차세대 기술로 주목받고 있다. 혐기성 MBR은 다양한 장점을 가지고 있지만, 분리막 파울링은 해결해야하는 과제이다. 따라서 본 연구에서는 막 파울링 억제를 위하여 섬유볼 미디어와 회전판을 이 용하여 혐기성 MBR의 막 파울링을 제어하였다. 혐기성 MBR을 이용하여 저농 도의 유기물 부하 조건에서 안정적인 처리수질을 보였으며, 유기물 부하가 높을 수록 높은 메탄가스 생산량을 보였다. 이를 토대로 혐기성 MBR의 적용에 효율적일 것으로 보이는 고농도 폐수의 처리 가능성 확인하기 위하여 음폐수를 대상으로 혐기성 MBR의 처리 특성을 살펴보고 고효율 혐기성 MBR 기술의 에너지 자립의 가능성을 평가하였다.

급격한 산업화 및 인구증가로 물부족 문제가 가속화됨에 따라 최근 수처리 공정은 방류수 수질기준을 준수하여 방류하는 단순한 수준을 넘어서 보다 엄격한 수질을 만족시켜야하는 방향으로 발전하고 있는 추세이다. 이러한 노력의 일환으로 많은 하⋅폐수 처리장에서 생물학적 처리와 멤브레 인이 결합된 MBR 공정을 적용하고 있으나, 적용 현장별 특징을 충분히 반영하지 못한 설계로 MBR 공정의 우수한 처리성능을 제대로 활용하지 못하고 있는 실정이다. 이에, 본 연구에서는 산업단지 내에 설치되는 폐수처리시설의 입지여건과 특성을 반영하여 저유량 및 수질의 불균질화 문제를 해결하기 위한 설계사례 등 을 제시하고자 하였다.

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.