도시지역은 인구가 집중되어 토지이용이 집약적이며 불투수면의 비율이 높아 강우시 비점오염에 의한 영향이 높은 지역이다. 비점오염원은 강우시 다양한 토지이용으로부터 발생되며 수계에 직접적인 영향을 미치고 오염물질의 종류와 양에 따라 불확실성이 높은 오염원이므로 점오염원과 함께 관리가 필요하다. 이러한 비점오염원을 관리하기 위한 방안으로 국내 외에서는 자연적인 기작을 이용한 비점오염원 관리기법인 저영향개발기법 (Low impact development, LID)을 도입하였으며 침투도랑, 식생체류지, 인공습지 등 다양한 요소기술이 포함된다. 이중 인공습지는 수질정화 (비점오염물질 저감)와 더불어 물을 저류하는 기능을 가진 친환경적인 시설로 잘 알려져 있다. 본 연구는 비점오염원 관리를 위한 LID 기술의 효과를 알아보기 위하여 수행되었으며 도시지역에 조성된 두 종류의 인공습지를 운영한 결과를 분석하고 평가하고자 한다. 연구대상 인공습지는 HSSF형과 Hybrid형으로 두 시설 모두2010년에 조성되어 현재까지 운영 중에 있으며 본 논문에서는 2010년부터 2015년까지의 총 42회의 모니터링 결과를 이용하였다. 분석결과, 두 인공습지를 통해 강우유출유출량을 평균 37~41% 범위로 저감되였으며 오염물질별 저감효율의 경우 TSS는 63~79%, TN은 38~54%, TP는 54%, 중금속은 32~81% 범위로 나타나 도시지역내 인공습지 적용시 비점오염원 저감에 도움이 될 수 있을 것으로 판단된다.
도시지역은 인구가 집중되어 토지이용이 집약적이며 불투수면의 비율이 높아 강우시 비점오염에 의한 영향이 높은 지역이다. 비점오염원은 강우시 다양한 토지이용으로부터 발생되며 수계에 직접적인 영향을 미치고 오염물질의 종류와 양에 따라 불확실성이 높은 오염원이므로 점오염원과 함께 관리가 필요하다. 이러한 비점오염원을 관리하기 위한 방안으로 국내 외에서는 자연적인 기작을 이용한 비점오염원 관리기법인 저영향개발기법 (Low impact development, LID)을 도입하였으며 침투도랑, 식생체류지, 인공습지 등 다양한 요소기술이 포함된다. 이중 인공습지는 수질정화 (비점오염물질 저감)와 더불어 물을 저류하는 기능을 가진 친환경적인 시설로 잘 알려져 있다. 본 연구는 비점오염원 관리를 위한 LID 기술의 효과를 알아보기 위하여 수행되었으며 도시지역에 조성된 두 종류의 인공습지를 운영한 결과를 분석하고 평가하고자 한다. 연구대상 인공습지는 HSSF형과 Hybrid형으로 두 시설 모두2010년에 조성되어 현재까지 운영 중에 있으며 본 논문에서는 2010년부터 2015년까지의 총 42회의 모니터링 결과를 이용하였다. 분석결과, 두 인공습지를 통해 강우유출유출량을 평균 37~41% 범위로 저감되였으며 오염물질별 저감효율의 경우 TSS는 63~79%, TN은 38~54%, TP는 54%, 중금속은 32~81% 범위로 나타나 도시지역내 인공습지 적용시 비점오염원 저감에 도움이 될 수 있을 것으로 판단된다.
Nonpoint source (NPS) pollution continues to degrade the water quality. NPS pollutants signals high concerns against a sustainable environment. Low impact development (LID) is the leading management practice which regulates and treats stormwater runoff especially in highly impervious urban areas. Co...
Nonpoint source (NPS) pollution continues to degrade the water quality. NPS pollutants signals high concerns against a sustainable environment. Low impact development (LID) is the leading management practice which regulates and treats stormwater runoff especially in highly impervious urban areas. Constructed wetlands are known to have efficient removal capability of NPS pollutants. Likewise, these LID facilities were intended to maintain the predeveloped hydrologic regime through series of mechanisms such as particle settling, filtration, plant uptake, and etc. In this study, the objective was to investigate the characteristics, fate and treatment performance of the two in-campus constructed wetlands (SW1 and SW2) which were installed adjacent to impervious roads and parking lots to treat stormwater runoff. A total of 42 storm events were monitored starting from July 2010 until November 2015. Manual grab sampling was utilized at the inlet and outlet units of each LID facilities. Based on the results, the wetlands were found to be effective in reducing 37% and 41% of the total runoff volume and peak flows, respectively. Aside from this, outflow EMCs were generally lower than the inflow EMCs in most events suggesting that the two wetlands improved the water quality of stormwater runoff. The average removal efficiency of pollutants in facilities were 63~79% in TSS, 38~54% in TN, 54% in TP and 32%~81% in metals. The results of this study recommend the use of constructed wetlands as efficient treatment facility for urban areas for its satisfactory performance in runoff and pollutant reduction.
Nonpoint source (NPS) pollution continues to degrade the water quality. NPS pollutants signals high concerns against a sustainable environment. Low impact development (LID) is the leading management practice which regulates and treats stormwater runoff especially in highly impervious urban areas. Constructed wetlands are known to have efficient removal capability of NPS pollutants. Likewise, these LID facilities were intended to maintain the predeveloped hydrologic regime through series of mechanisms such as particle settling, filtration, plant uptake, and etc. In this study, the objective was to investigate the characteristics, fate and treatment performance of the two in-campus constructed wetlands (SW1 and SW2) which were installed adjacent to impervious roads and parking lots to treat stormwater runoff. A total of 42 storm events were monitored starting from July 2010 until November 2015. Manual grab sampling was utilized at the inlet and outlet units of each LID facilities. Based on the results, the wetlands were found to be effective in reducing 37% and 41% of the total runoff volume and peak flows, respectively. Aside from this, outflow EMCs were generally lower than the inflow EMCs in most events suggesting that the two wetlands improved the water quality of stormwater runoff. The average removal efficiency of pollutants in facilities were 63~79% in TSS, 38~54% in TN, 54% in TP and 32%~81% in metals. The results of this study recommend the use of constructed wetlands as efficient treatment facility for urban areas for its satisfactory performance in runoff and pollutant reduction.
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문제 정의
A constructed wetland is an applicable technique for stormwater management and protection of water quality and associated aquatic habitat. Therefore, this study aimed to investigate the characteristics and treatment performance of the two small constructed wetlands installed in an urbanized campus. Specifically, the study was conducted to determine the hydraulic, hydrologic, and water quality characteristics of stormwater runoff and pollutants conveyed from roads and parking lots entering the constructed wetlands.
Specifically, the study was conducted to determine the hydraulic, hydrologic, and water quality characteristics of stormwater runoff and pollutants conveyed from roads and parking lots entering the constructed wetlands. In addition, another goal of the study was to predict the runoff treatment efficiency of the wetlands from values obtained from storm events.
제안 방법
Therefore, this study aimed to investigate the characteristics and treatment performance of the two small constructed wetlands installed in an urbanized campus. Specifically, the study was conducted to determine the hydraulic, hydrologic, and water quality characteristics of stormwater runoff and pollutants conveyed from roads and parking lots entering the constructed wetlands. In addition, another goal of the study was to predict the runoff treatment efficiency of the wetlands from values obtained from storm events.
In this study, the behavior, relationship, characteristics and fate of pollutants in the runoff were described and their correlation with respect to the hydrologic-hydraulic characteristics was also determined. The study concluded that runoff volume and peak flow reductions can be fairly performed by the wetlands even without infiltration capabilities.
대상 데이터
Two constructed wetlands were utilized in the study namely, the Small Hybrid Wetland (SW1) and Small HSSF Wetland (SW2). The facilities are located in Kongju National University in Cheonan City, South Chungcheong Province, South Korea.
Two constructed wetlands were utilized in the study namely, the Small Hybrid Wetland (SW1) and Small HSSF Wetland (SW2). The facilities are located in Kongju National University in Cheonan City, South Chungcheong Province, South Korea. Fig.
성능/효과
05). According to overall values of inflow and outflow EMCs, the inflow EMCs were higher the outflow EMCs indicating that the constructed wetlands were capable of efficiently improving the water quality of runoff.
In this study, the behavior, relationship, characteristics and fate of pollutants in the runoff were described and their correlation with respect to the hydrologic-hydraulic characteristics was also determined. The study concluded that runoff volume and peak flow reductions can be fairly performed by the wetlands even without infiltration capabilities. Inflow EMCs were significantly higher than outflow EMCs which indicates the constructed wetlands were capable of efficiently improving the water quality of the inflow.
Despite the long term monitoring, it was suggested that the constructed wetlands have varying performances but mostly effective in treating stormwater runoff. The results of this study recommend the use of constructed wetlands as efficient treatment facility for impervious areas for its satisfactory performance in runoff and pollutant reduction.
참고문헌 (24)
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