In this study, the vertical and horizontal flow wetlands were combined in series to create conditions for flow in the exhalation and anaerobic state with the aim of monitoring the variability and reduction of dissolved organic matter in the bio-reactive artificial wetlands, and the performance assessment was conducted as acrylic reaction groups by designing artificial wetlands that filled the functional residuals. In case of artificial wetlands in vertical and horizontal planes, the concentration of dissolved oxygen (DO) in the reaction tank was measured as 2.7 mg/L in the vertical flow wetlands under exhalation, and N.D. in the horizontal flow artificial wetlands under anaerobic conditions. The test was carried out by changing the operation time to 140 min, 80 min, and 60 min.
The test was conducted with the same natural operation time of 20 min depending on the operation time. All hours of operation were shown to be due to microbial activity. In 3D-EEM, it was found that the longer the driving time was taken, the more reduction the organic compounds in the areas of insoluble human resources, III and V. Further research on the mechanism analysis of future reduction effects is expected to be carried out, but the findings are expected to contribute to the development of technologies for reducing obfuscated substances using artificial wetlands in the future.

본 연구에서는 생물반응 인공습지 내 용존유기물질의 변동 및 저감특성을 모니터링할 목적으로 수직·수평 흐름 습지를 직렬로 복합 적용하여 호기, 혐기상태의 흐름조건을 만들어 주었고 기능성 여재를 충진한 인공습지를 고안하여 아크릴 반응조로 제작 후 성능평가를 진행하였다. 수직·수평의 인공습지의 경우 호기 및 혐기조건을 평가하기 위해 반응조 내 용존산소(DO) 농도를 측정해본 결과 호기상태의 수직흐름인공습지에서는 2.7 mg/L, 혐기상태의 수평 흐름인공습지에서는 N.D.로 측정되어 운전조건에 부합하였다. 운전시간은 140 min, 80 min, 60 min으로 변경하며 실험을 진행을 하였으며, 운전시간에 따른 자연폭기시간 20 min을 동일하게 설정해 주고 실험을 진행하였다. 운전시간 모두 미생물의 활동으로 인한결과를 보였으며, 3D-EEM에서는 운전시간을 길게 가져갈수록 난분해성 휴믹계물질구역인 III, V구역의유기물에서 높은 저감효과를 보이는 것으로 확인되었다. 향후 저감효과에 대한 메커니즘 분석에 대한 연구는 추가로 진행될 필요가 있을 것으로 사료되지만, 본 연구결과는 향후 인공습지를 활용한 난분해성 물질의 저감을 위한 기술발전에 기여할 수 있을 것으로 기대된다.

1 허진, "하천 및 호소 수질관리를 위한 용존 자연유기물질 형광특성 분석" 대한환경공학회 28 (28): 2006

2 최돈혁, "인공습지의 수질정화메카니즘 및 기능향상 연구" 충남대학교 대학원 2010

3 심재훈, "인 제거를 위한 응집제로서 마그네타이트-황토 복합체의 특성" 한국수처리학회 24 (24): 39-48, 2016

4 이선경, "생활하수내 인 제거를 위한 화학적 침전의 최적화" 대한상하수도학회 30 (30): 663-671, 2016

5 Stedmon CA, "Tracing dissolved organic matter in aquatic environments using a new approach to fluorescence spectroscopy" 82 (82): 239-254, 2003

6 National Institute of Environmental Research(NIEF), "The increasing treand of regratory organic matters and the management plans for the han river basin" Hangang Sugye Gwanri Wiwonhoe 2010

7 Park YH, "Study on the characterization of dissolved organic matter in groundwater and surfacewater with fluorescence analysis" Kangwon National University 2017

8 McKnight DM, "Spectrofluorometric characterization of dissolved organic matter for indication precursor organic material and aromaticity" 46 : 38-48, 2001

9 Huguet A, "Properties of fluorescent dissolved organic matter in the Gironde Estuary" 40 : 706-719, 2009

10 Lakowicz JR, "Principles of fluorescence spectroscopy" Springer Science & Business Media 2013

11 Lee DH, "Molecular structural characteristics of soil and sediment humic substances and correlation with phenanthrene sorption parameters" Seoul National University of Science and Technology 2016

12 Wetzel RG, "Limnology, Lake and River Ecosystems" Elsevier academic press 2001

13 Steinberg G, "Humic Substances in soil, sediment, and water, Geochemistry, Isolation, and Characterization" John Wiley and sons 1985

14 Malcolm RL, "Humic Substances in soil, sediment, and water, Geochemistry, Isolation, and Characterization" John Wiley and sons 1985

15 Ministry of Environment, "Future bureau of Creativity" Ministry of land, Infrastructure and Transport 2014

16 Lee KC, "Formation Characteristics and Controls of Disinfection By-products in G Drinking Water Treatment Processes" Seoul Metropolitan Government Institute of Health and Environment 148-172, 2014

17 Chen W, "Fluorescence excitation-emission matrix regional integration to quantify spectra for dissolved organic matter" 37 (37): 5701-5710, 2003

18 Baker A, "Fluorescence excitation-emission matrix characterization of some sewageimpacted rivers" 35 (35): 948-953, 2001

19 Hudson N, "Fluorescence analysis of dissolved organic matter in natural waste and polluted waters-a review" 23 (23): 631-649, 2007

20 Wen C, "Fluorescence Excitation-Emission Matrix Regional Integration to Quantify Spectra for Dissolved Organic Matter" 37 (37): 5701-5710, 2003

21 United Sates Environmental Protection Agency, "Environmental Regulation and Technology, Autothermal Themophilic Aerobic Digestion of Municipal Wastewater Sludge" 1990

22 Zsolnay A, "Differentiating with fluorescence spectroscopy the sources of dissolved organic matter in soil subjected to drying" 38 : 45-50, 1999

23 Lee EJ, "Comparison of UV-VIS and FDOM sensors for in situ monitoring of stream DOC concentrations" 12 (12): 3109-3118, 2015

24 Chen Z, "Colored dissolved organic matter in Tampa Bay, Florida" 104 : 98-109, 2007

25 Coble PG, "Characterization of marine and terrestrial DOM in seawater using excitation-emission matrix spectroscopy" 51 (51): 325-346, 1996

26 Hunt JF, "Characterization of fresh and decomposed dissolved organic matter using excitation-emission matrix fluorescence spectroscopy an multiway analysis" 55 : 2121-2128, 2007

27 Birdwell JE, "Characterization of dissolved organic matter in fogwater by excitation-emission matrix fluorescence spectroscopy" 44 : 3246-3253, 2010