• Proceedings of the Korea Technical Association of the Pulp and Paper Industry Conference
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• 2000.11a
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• pp.41-41
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• 2000

부유부상 공정은 현재 신문고지와 사무용 고지의 탈묵을 통한 신문용지 및 화장지 제조 에 널리 사용되고 있는 고지재활용을 위한 핵심공정이다. 하지만 이들 공정은 갈수록 열악 해지는 국내 고지원료의 품질변화에 따라서 잉크 및 토너의 분리효율이 저하되고 있어 생산 되는 탈묵 펄프의 품질저하, 리젝트 발생량의 증대, 폐수 처리공정의 부하 증가 등 다양한 문제점을 발생시키고 있어 이에 대한 대책의 수립이 시급히 요청되고 있다. 현재와 같이 다양한 형태의 잉크 및 인쇄방식으로 인쇄된 많은 종류의 재활용지가 원료 로 투입되고 있는 경우 탈묵공정의 효율 향상을 위해서는 부유부상 공정에 대한 좀 더 체계 적이고 논리적인 접근이 필요하다. 이러한 문제점을 극복하기 위해 먼저 고지 재활용 공정 의 핵심 단위공정인 부유부상 공정에 관련된 복잡한 문제점을 단순화하여 고상 및 액상의 표면화학적 특성을 평가하고, 이에 따른 부유부상 공정의 효율을 분석하였다. 본 연구에서는 부유부상 공정을 기초과학적 측면에서 구명하기 위해 마이크로 크리스탈린 셀룰로오스(Microcrystalline cellulose: MCC)를 모델 물질로 사용하였고, 친수성 의 표면 특 성을 나타내는 MCC의 표면 특성을 바꾸기 위하여 AKD(alkyl ketene dimer)로 처리비율을 달리하여 사이징 처리하였다. 부유부상 실험에 사용된 MCC는 친수성을 띠는 것과 소수성 을 부여한 것을 구별하고 그 비율을 백색도를 통해 측정하기 위하여 자체적으로 친수성을 가지는 MCC는 세척 견뢰도가 높은 검은색 염료로 염색하였다. 준비된 친수성과 소수성 M MCC의 혼합비율 별로 패드를 작성하여 백색도를 측정함으로써 검량선을 작성하였다. 또한 부유부상 시간에 따른 제거효율을 알아보기 위하여 부유부상 시간별로 각각의 리젝트율과 수율올 측정하고, 리젝트 시료로부터 패드를 제조하여 백색도를 측정하였다. 실험 결과 소수성 MCC의 소수화 정도에 따라서 리젝트율이 증가하였으며, 이를 통해 표 면에 소수성을 띠는 입자는 소수성이 강할수록 부유부상공정에서 제거율이 증가한다는 것을 확인하였다. 부유부상 처리한 MCC로 패드를 제조한 뒤 백색도를 비교한 결과에서도 이를 확인하였다. 한편 리젝트로 함께 제거된 MCC 내에 존재하는 친수성 MCC의 양은 극히 미 세하였다. 또한 부유부상를 실시하는 초기에 상당량의 리젝트가 발생함을 확인하였는데, 이 는 전체 부유부상을 통해 제거되는 양의 45-68%였다. 한편 부유부상이 진행됨에 따라서 리젝트 양의 증가폭이 둔화되는 경향을 나타내었다. 이러한 경향은 MCC의 소수성이 강할 수록 더욱 뚜렷하게 나타났다. 이를 통해 계 내로부터 소수성인 물질이 급속하게 제거됨을 알 수 있었으며 필요 이상의 부유부상 처리는 잉크제거 효율을 높일 수는 있으나 소모되는 시간에 비하여 비효과적임을 알 수 있었다.

• Journal of Environmental Health Sciences
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• v.26 no.4
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• pp.29-37
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• 2000

Fenton’s oxidation process is one of the most commonly applied processes to the wastewater which cannot be treated by conventional biological treatment processes. However, it is necessary to minimize the cost of Fenton’s oxidation treatment by modifying the treatment processes or other means of chemical treatment. So, as a method for the chemical oxidation of biorefractory or nonbiodegradable organic pollutants, the Photo-Fenton-Reaction which utilizes iron(11)salt. $H_2O$$_2$ and UV-light simultaneously has been proprosed. Therfore, the purpose of this study is to test a removal efficiency of dye-wastewater and treatment cost with Fenton’s and Photo-Fenton’s oxidation process. The Fe(11)/$H_2O$$_2$ reagent is referred to as the fenton’s reagent. which produces hydroxy radicals by the interaction of Fe(11) with $H_2O$$_2$. In this exoeriment, the main results are as followed; 1. The Fenton oxidation was most efficient in the pH range of 3-5. The optimal condition for initial reaction pH was 3.5 for the high CO $D_{Cr}$ & TOC-removal efficiency. 2. The removal efficiency of TOC and CO $D_{Cr}$ increased up to the molar ration between ferrate and hydrogen peroxide 0.2:1, but above that ratio removal efficiency hardly increased. 3. The highest removal efficiency of TOC and CO $D_{Cr}$ were showed when the mole ration of ferrate to hydrogen peroxide was 0.2:3.4. 4. Without pretreatment process, photo-fenton oxidation which was not absorbed UV light was not different to fenton oxidation. 5. And Fenton oxidtion with pretreatment process was similar to Fenton oxidation in the absence of coagulation, the proper dosage of F $e^{2+}$: $H_2O$$_2$ was 0.2:1 for the optimal removal efficiency of TOC or CO $D_{Cr}$ .6. Also, TOC & CO $D_{Cr}$ removal efficiency in the photo-fenton oxidation with pretreatment was increased when UV light intensity enhanced.7. Optimum light intensity in the range from 0 to 1200 W/$m^2$ showed that UV-intensity with 1200W/$m^2$ was the optimum condition, when F $e_{2+}$:$H_2O$$_2$ ratio for the highest decomposition was 0.2:2.5.EX>$_2$ ratio for the highest decomposition was 0.2:2.5.

• Economic and Environmental Geology
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• v.42 no.6
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• pp.527-539
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• 2009

The Kumho River flows through volcanic and sedimentary rocks at upstream and downstream regions and also through industrial district including dyeing complex before it meets the Nakdong River, and as a result, many factors can influence the geochemistry of river water. The concentrations of dissolved ions generally increased as it flows downstream. The concentrations of cations are in the order of Ca>Na>Mg>K, and those of anions are $HCO_3$>$SO_4$>Cl>$NO_3$. These results show that the weathering of sandstone and shale containing carbonate including calcite caused the enrichment of Ca and $HCO_3$. At first 4 sampling sites, Si contents are relatively high mainly due to the weathering of silicate minerals of volcanic rocks. However, Na and $SO_4$ contents are higher at downstream sites due to the industrial and municipal sewage. Piper diagram also shows that the geochemical patterns changed from Ca-$HCO_3$ to Ca-Cl/Ca-$SO_4$ and Na-Cl/Na-$SO_4$ type. When comparing the samples collected in May and July, the concentrations of dissolved ions in July are generally lower than those in May, which indicates that dilution by precipitation played an important role. In July the relative concentration of Ca increased, indicating that Ca in soils probably from fertilizer were mixed into the river water by precipitation. The river waters are mainly from precipitation. The dissolved ions are mainly from weathering of carbonate minerals and pollutants from municipal sewage and discharged water from industrial complex. The composition of oxygen and deutrium isotope in July showed higher values, which is contrary to the amount effect, maybe due to Youngchon Dam. The nitrogen isotope showed lower values in July than those in May, which can be interpreted to indicate mixing of nitrate from soils and fertilizer in the cultivated land by the heavy rain. The isotope composition of nitrate increased downstream, indicating that the influence of sewage and animal manure also increased downstream.

• Journal of Korean Society of Environmental Engineers
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• v.27 no.8
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• pp.870-876
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• 2005

The multiple regression models which have two factors(population and commercial area) have been used to forecast the water demand in the future. But, the coefficient of population had a negative value because proper regional classification wasn't performed, and it is not reasonable because the population must be a positive factor. So, the regional classification was performed by principal component and cluster analysis to solve the problem. 6 regional characters were transformed into 4 principal components, and the areas were divided into two groups according to cluster analysis which had 4 principal components. The new regression models were made by each group, and the problem was solved. And, the future water demands were estimated by three scenarios(Active, moderate, and passive one). The increase of water demand ore $89.034\;m^3/day$ in active plat $49,077\;m^3/day$ in moderate plan, and $19,996\;m^3/day$ in passive plan. The water supply ability as scenarios is enough in water treatment plant, however, 2 reservoirs among 4 reservoirs don't have enough retention time in all scenarios.