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박태성,홍성창 ( Tae Sung Park,Sung Chang Hong ) 한국공업화학회 1998 공업화학 Vol.9 No.2
배출가스중의 SO₂제거를 위하여 다양한 금속산화물로 구성된 천연망간광석, 철광석, CuO/γ-Al₂O₃등을 흡착제로 사용하여 고정층반응기에서 흡착용량실험을 하였다. 또한 흡착제중 흡착용량이 떨어지는 철광석을 제외한 두 가지 흡착제를 이용하여 유동층반응기에서 유속, 온도, 입자크기 등의 조업조건에 따른 SO₂ 흡착실험을 수행하였다. 모든 흡착제에서 온도가 증가할수록 흡착량이 증가하는 화학흡착반응을 보였고 유동층반응기에서 U_0/U_mf및 U_0-U_mf와 같은 유속조건에 따라 입자 크기에 따른 흡착량의 변화가 다르게 나타났으며 유동층반응기 성능식으로부터 반응속도상수를 얻었다. 이 실험을 통하여 천연망간광석이 유동층반응기에서 SO₂ 흡착제로의 사용가능성을 확인할 수 있었다. In a fixed bed reactor, adsorption capacity of SO₂in simulated flue gases was investigated with NMO(natural manganese ore), composed of various metal oxides, iron ore and CuO/ γ-Al₂O₃ as adsorbents. The experiment carried out in a fluidized bed reactor with variables such as gas velocity, temperature and particle size. Iron ore was excluded in the fluidized bed reactor experiment for the lower adsorption capacity. The adsorption of SO₂ in metal oxide is a typical chemisorption because the adsorption capacity of all adsorbents increased with temperature. The effect of particle size on the adsorption capacity was varied with the ratio, U_0/U_mf and the difference of U_0- U_mf. U_0 is the gas velocity, U_mf is the minimum fluidization gas velocity. U_0/U_mf and U_0/U_mf explain the behavior of the gas and solids in the fluidized bed reactor. From the performance equation of the fluidized bed reactor, kinetic reaction rate constants were obtained by the non-linear least square method. The adsorption capacity of NMO proved the potential use of SO₂ adsorbents.
대장 종양의 진단에서 F18-FDG PET/CT의 유용성
강민경 ( Min Kyung Kang ),홍성표 ( Sung Pyo Hong ),이지은 ( Ji Eun Lee ),전태주 ( Tae Joo Jeon ),김종우 ( Jong Woo Kim ),권창일 ( Chang Il Kwon ),고광현 ( Kwang Hyun Ko ),황성규 ( Seong Gyu Hwang ),박필원 ( Pil Won Park ),임규성 ( 대한장연구학회 2010 Intestinal Research Vol.8 No.1
Background/Aims: The diagnostic value of 2-18F-fluoro-2-deoxy-D-glucose positron emission tomography (FDG PET)/CT in the detection of colon carcinoma and adenoma was evaluated retrospectively. Methods: Between May 2007 and June 2008, 102 patients (42 males and 60 females: age range, 28-89 years) underwent both FDG PET/CT and colonoscopy in < a 3 month interval. FDG uptake on PET/CT was divided into physiologic and pathologic uptake by a nuclear medicine specialist. Pathologic confirmation was obtained in all patients. Results: Forty-three patients had no abnormal findings on both FDG PET/CT and colonoscopy. One hundred five and 59 colonic lesions were detected on FDG PET/CT and colonoscopy, respectively. Eleven of 24 lesions with pathologic FDG uptake were histologically-confirmed to be malignancies. Among 18 lesions with physiologic FDG uptake, 1 carcinoma and 1 adenoma were revealed. One carcinoma, 25 adenomas, and 11 hyperplastic polyps did not reveal FDG uptake. Interpretation of pathologic FDG uptake in the colon had a sensitivity of 84.6% and 28.2%, a specificity of 90.4% and 88.1%, a positive predictive value of 45.8% and 45.8%, and a negative predictive value of 98.4% and 77.8% for carcinomas and adenomas, respectively. Conclusions: FDG PET/CT is a very useful diagnostic method for the detection of colon cancer, but the sensitivity is low for adenomas, which may need further evaluation, such as a screening endoscopy. (Intest Res 2010;8:18-23)
유동층반응기에서 MeO/NMD를 이용한 저농도 연소가능 오염물의 제거
박태성,정순관,윤재성,홍성창,도동섭 ( Tae Sung Park,Soon Kwan Jeong,Jae Sung Yun,Sung Chang Hong,Dong Sup Doh ) 한국화학공학회 1998 Korean Chemical Engineering Research(HWAHAK KONGHA Vol.36 No.5
For the removal of combustible pollutant gas at low concentration, the experiment about oxidation of CH₄, C_6H_6, C₂H_5OH, CO, was carried out using platinum, paladium-impregnated NMD(Natural Manganese Dioxide) in the fluidized bed reactor for several variables. At the same flow velocity the effect of particle size on conversion appeared most efficient in the size of 0.359 ㎜. The oxidation was excellent at low flow velocity and large aspect ratio because of the effect of residence time of reactant. Also the, noble metal-impregnated catalyst oxidated VOCs at more low temperature than catalyst without impregnation. For methane oxidation ability of PdO/NMD decreased in the reason that experimental temperature was so high that the structural transformation was caused.