• Title/Summary/Keyword: 분말활성탄 접촉조

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Application of CFD Program for Analyzing the Hydrodynamic Characteristics of Baffled PAC Contactor (격벽식 분말활성탄 접촉조의 흐름해석을 위한 전산유체역학 프로그램의 적용)

  • Ahn, Chang-Jin;Ahn, Sang-Jin
    • Journal of Korea Water Resources Association
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    • v.35 no.2
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    • pp.221-229
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    • 2002
  • For the efficient design of baffled Powdered activated carbon(PAC) contractor, which has been widely used in water treatment plant(WTP) against the algae-related odor problems, a CFD(computational fluid dynamics) program was applied. In order to verify the performance of FLOW-3D program, the previously reported results of tracer tests from a pilot-scale PAC contractor(working volume of 288 liters) were compared to those from FLOW 3D. The results of FLOW-3D simulation were very similar to those from tracer tests conducted with the Pilot-scale PAC contactor. On the other hand, the hydrodynamic characteristics of baffled contractor in the P-WTP were simulated by using FLOW-3D. Simulation results on the distribution of PAC particles showed that there are some stagnant parts in the back side of baffles in which PAC Particles are not present. These stagnant parts might decrease the adsorption capacity of PAC particles. When the baffles were changed to maze-type intra-basin baffling, PAC particles were evenly distributed and the amount of stagnant parts reduced. In conclusion, it is anticipated that FLOW-3D simulation could be a viab1e tool for analyzing the hydrodynamic characteristics of structures used in drinking water treatment plant.

Evaluation on the Locations of Powdered Activated Carbon Addition for Improvement of Taste and Odor Removal in Drinking Water Supplies (상수원수 내 이취미 제거효율 향상을 위한 분말활성탄 투입지점의 평가)

  • Kim, Young-Il;Lee, Sang-Jin;Bae, Byung-Uk
    • Journal of Korean Society of Water and Wastewater
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    • v.21 no.3
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    • pp.341-348
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    • 2007
  • The efficiency of powdered activated carbon (PAC) for removing taste and odor (T&O) in drinking water supplies is dependent on the contact time, quality of mixing, and the presence of competing compounds. All of these are strongly influenced by the stage in the treatment process at which the PAC is added. In conventional water treatment plants (WTPs), PAC is commonly added into the rapid mixing basin where chemicals such as coagulants, alkaline chemicals, and chlorine, are simultaneously applied. In order to prevent interference between PAC and other water treatment chemicals, alternative locations for addition of PAC, such as at transmission pipe in the water intake tower or into a separated PAC contactor, were investigated. Whatever the location, addition of PAC apart from other water treatment chemicals was more effective for geosmin removal than simultaneous addition. Among several combinations, the sequence 'chlorine-PAC-coagulant' produced the best result with respect to geosmin removal efficiency. Consequently, when PAC has to be applied to cope with T&O problems in conventional WTPs, it is very important to prevent interference with other water treatment chemicals, such as chlorine and coagulant. Adequate contact time should also be given for adsorption of the T&O compounds onto the PAC. To satisfy these conditions, installation of a separated PAC contactor would be the superior alternative if there is space available in the WTP. If necessary, PAC could be added at transmission pipe in the water intake tower and still provide some benefit for T&O treatment.

Study on Removal of Artificial Radionuclide (I-131) in Water (물속의 인공방사성핵종(I-131) 제거율 연구)

  • Jeong, Gwanjo;Lee, Kyungwoo;Kim, Bogsoon;Lee, Suwon;Lee, Jonggyu;Koo, Ami
    • Journal of Korean Society of Environmental Engineers
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    • v.36 no.11
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    • pp.747-752
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    • 2014
  • Iodine-131, an artificial radionuclide, mostly exists as iodide ion ($^{131}I^-$) and iodate ion ($^{131}IO_3{^-}$) in the water, and When a short time contacted, it could not be removed by poly aluminum chloride (PACl) and powdered activated carbon (PAC). Although the removal rate of iodine-131 was not related with turbidity of raw water, it showed linear relationship with contact time with PAC. With the mixture of PACl (24 mg/L or more) and PAC (40 mg/L or more), about 40% of iodine-131 could be removed. Iodine-131 could be removed little by sand filtration, but approximately 100% by granular activated carbon (GAC), both virgin-GAC and spent-GAC. Microfiltration process could remove little iodine-131 while reverse osmosis process could remove about 92% of iodine-131.

Performance Evaluation of Powdered Activated Carbon (PAC) Contactor for the Removal of Organics and Taste and Odor (분말활성탄 접촉조의 맛·냄새 및 유기물 제거 효율 평가)

  • Bae, Byung-Uk;Lim, Mun-Gu
    • Journal of Korean Society on Water Environment
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    • v.26 no.4
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    • pp.585-589
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    • 2010
  • In order to evaluate the performance of a powdered activated carbon (PAC) contactor, two water treatment plants (WTP) were selected as target sites. The result of tracer tests showed that the plug flow portion of a bisymmetry-type contactor (H WTP) was more than 70%. A maze-type contactor (C WTP) also had more than 70% of plug flow portion after intra-basin baffles were installed. According to the operating data of the target WTPs, there was no clear evidence that the addition of PAC contributed to the removal of organics. However, the results of jar tests, conducted with the raw water taken from the H WTP, proved that PAC could remove dissolved organic carbon (DOC) to some extent when the proper velocity gradient was maintained. It was estimated that the production rate, defined as the ratio of the operating flowrate to the design flowrate, of the C and H WTPs was only 27 and 50%, respectively. Because of these lower production rates, the mixing intensity in the contactor was much less than the designed value and, finally, the performance of the PAC contactor was much lower than what was expected.

Development of a New Advanced Water Treatment Process (PMR) and Assessment of Its Treatment Efficiency (고도정수처리 신(新) 공정(PMR)개발 및 처리효율 평가)

  • Ahn, Hyo-Won;Noh, Soo-Hong;Kwon, Oh-Sung;Park, Yong-Hyo;Wang, Chang-Keun
    • Membrane Journal
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    • v.18 no.2
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    • pp.157-167
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    • 2008
  • Removal of organic substances and taste/odor control are ones of the main issues in water supply, resulting in introduction of advanced processes such as ozon/GAC, or PAC. However, raw water quality deteriorates, new pollutants advent, so water quality is not acceptable enough even with those existing advanced processes. In this paper, a new advanced water treatment process using PAC slurry blanket, where PAC particles stay in the basin as slurry blanket, coupled with submerged membranes is introduced. A pilot plant $(80m^3/day)$ was installed to assess the performance of this new process using actual raw water, and DOC was removed higher than 90% in the beginning and $70{\sim}80%$ afterwards, while 2-MIB and geosmin were removed completely. This new process still requires future study on process optimization and long-term assessment, however it seems highly possible to countermeasure as a new advanced process with high removal efficiency.

Study on Removal of Cesium in Water Treatment System (물속의 방사성핵종(세슘) 제거율 연구)

  • Jeong, Gwanjo;Son, Boyoung;Ahn, Chihwa;Lee, Suwon;Ahn, Jaechan;Kim, Bogsoon;Chung, Deukmo
    • Journal of Korean Society of Environmental Engineers
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    • v.38 no.1
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    • pp.8-13
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    • 2016
  • This study investigated the removal of a radioactive cesium ($Cs^+$) in the water at the water treatment processes. Since cesium is mostly present as the $Cs^+$ ion state in water, it is not removed by sand filtration, and coagulation with polyaluminum chloride (PACl), powdered activated carbon (PAC) and mixture of PACl and PAC. However, it is known that the removal rate of cesium increases as the turbidity increases in raw water. As the turbidity was adjusted by 74 NTU and 103 NTU using the surrounding solids near G-water intake and yellow soils, removal rate of cesium was about 56% and 51%, respectively. In case of a GAC filtration with supernatants after jar-mixing/setting was conducted, 80% of cesium is approximately eliminated. The experimental results show that it is efficient to get rid of cesium when the turbidity of the raw water is more than 80 NTU. In case of a GAC filtration, about 60% of cesium is removed and it is considered by the effect of adsorption. Cesium is not eliminated by microfiltration membrane while about 75% of cesium is removed by reverse osmosis.