본 연구는 경상북도 지역에서 호소수를 원수로 사용하는 한 정수장의 원수 및 공정별 처리수의 자연유기물질(NOM) 및 소독부산물(DBPs) 생성특성을 조사하고 정수공정내 DBPs 제어방안을 제시하였다. Fluorescence excitation-emission matrix(FEEM) 분석결과 원수의 NOM은 토양과 미생물의 복합기원에 의한 것으로 밝혀졌다. NOM의 분자량크기 및 분획제거 특성은 liquid chromatography-organic carbon detector (LC-OCD)를 이용하여 분석하였다. 대체로 휴믹물질과 저분자량 유기물질 분획이 많았고, 고분자량물질은 저분자량물질보다 응집·침전공정에서 제거가 용이한 것으로 나타났다. 전염소주입 후 정수공정별로 진행될수록 반응시간이 길어져 DBPs 농도가 증가하였으며 생성된 DBPs는 일반적인 정수처리로 제거되지 않았다. THMs은 chloroform이 74%로 주종을 이루었으며 bromodichloromethane (22%)와 dibromochloromethane (4%)도 발생했다. HAAs는 dichloroacetic acid (50%)와 trichloroacetic acid (48%)가 주종을 이루었고 dibromoacetic acid (2%) 등 브롬계열은 농도가 낮거나 발생되지 않았다. HANs은 dichloroacetonitrile (60%), bromochloroacetonitrile (30%), dibromoacetonitrile (10%)이 발생되었다. 실험기간 동안 해당 정수장에서 DBPs 발생은 용존유기물농도와 수온보다 전염소주입농도에 큰 영향을 받은 것으로 나타났고, 염소주입농도의 조절로 DBPs 생성농도를 이전에 비해 16~44% 감소시킬 수 있었다.

This study investigated the influence of characteristics of natural organic matter (NOM) on the formation of disinfection by-products (DBPs), and proposed the control strategies of DBPs formation in a drinking water treatment plant using lake water in Gyeongsangbuk-do. The fluorescence excitation-emission matrix analysis results revealed that the origins of NOM in raw waters to the plant were a mixture of terrestrial and microbial sources. Molecular size distributions and removals of NOM fractions were evaluated with a liquid chromatography-organic carbon detector (LC-OCD) analysis. Humic substances and low molecular weight organics were dominant fractions of NOM in the raw water. High molecular weight organics were relatively easier to remove through coagulation/precipitation than low molecular weight organics. The concentrations of DBPs formed by pre-chlorination increased through the treatment processes in regular sequence due to longer reaction time. Chloroform (74%) accounts for the largest part of trihalomethanes, followed by bromodichloromethane (22%) and dibromochloromethane (4%). Dichloroacetic acid (50%) and trichloroacetic acid (48%) were dominant species of haloacetic acids, and brominated species such as dibromoacetic acid (2%) were minimal or none. Dichloroacetonitrile (60%) accounts for the largest part of haloacetonitriles, followed by bromochloroacetonitrile (30%) and dibromoacetonitrile (10%). The formation of DBPs were reduced by 16~44% as dosages of pre-chlorine decreased. Dosages of pre-chlorine was more contributing to DBPs formation than variations of dissolved organic contents or water temperature.

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