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고정층 흡착탑에서 다성분 휘발성 유기화합물의 활성탄 흡착 특성
조종훈 ( Jong Hoon Cho ),이시훈 ( Sihyun Lee ),이영우 ( Young Woo Rhee ) 한국화학공학회 2016 Korean Chemical Engineering Research(HWAHAK KONGHA Vol.54 No.2
본 연구에서는 상용활성탄 4가지를 사용하여 산업공정에서 사용빈도가 높은 톨루엔, isopropyl alcohol (IPA), ethyl acetate (EA), 3성분계를 대상으로 흡착특성을 고찰하였다. 고찰결과 3가지 휘발성 유기화합물 중 활성탄과 가장 친화력이 낮은 IPA의 파과점이 가장 짧았으며 다음으로 EA, 톨루엔 순으로 파과점이 길어지는 것을 알 수 있었다. 가장 파과점이 짧은 IPA를 기준으로 단일성분, 2성분, 3성분계의 파과점 변화를 고찰한 결과 성분 수가 많아질수록 파과점이 낮아지는 것을 알 수 있었으며 이는 친화력이 낮은 물질이 친화력이 높은 물질에 의해 치환되는 경쟁흡착에 의한것을 알 수 있었다. 따라서 톨루엔-IPA-EA 3성분계 흡착에서는 IPA의 파과를 기준으로 흡착탑을 설계하여야 하며 실제 산업체에서 흡착탑을 설계하는 기준도 가장 친화력이 낮은 물질을 기준으로 하여야 함을 알 수 있었다. This study aims to examine absorption characteristics of toluene, isopropyl alcohol (IPA), ethyl acetate (EA), and ternary-compounds, all of which are widely used in industrial processes, by means of four types of commercial activated carbon substances. It turned out that among the three types of volatile organic compounds, the breakthrough point of activated carbon and that of IPA, whose affinity was the lowest, were the lowest, and then that of EA and that of toluene in the order. With the breakthrough point of IPA, which was the shortest, as the standard, changes in the breakthrough points of unary-compounds, binary-compounds, and ternary-compounds were examined. As a result, it turned out that the larger the number of elements, the lower the breakthrough point. This resulted from competitive adsorption, that is, substitution of substances with a low level of affinity with those with a high level of affinity. Hence, the adsorption of toluene-IPA-EA and ternary-compounds require a design of the activated carbon bed based on the breakthrough of IPA, and in the design of activated carbon beds in actual industries as well, a substance whose level of affinity is the lowest needs to be the standard.
열분해유 유래 피치로부터 이방성 미세구조 코크스 제조 및 특성 평가
조종훈 ( Jong Hoon Cho ),김지홍 ( Ji Hong Kim ),이영석 ( Young-seak Lee ),임지선 ( Ji Sun Im ),강석창 ( Seok Chang Kang ) 한국공업화학회 2021 공업화학 Vol.32 No.6
본 연구에서는 열분해유 유래 피치 합성 및 합성 피치로부터 이방성 미세구조를 갖는 코크스를 제조하고 그 특성을 평가하였다. 열분해유는 주로 방향족 고리가 2~3개로 구성된 분자로 이루어져 있어, 400 °C 이상의 온도에서 흡열반응인 축합중합으로 피치가 제조되었다. 코크스 반응기는 피치를 유동화 시키는 전처리 반응기, 코킹화 열에너지를 가해주는 preheater 및 코크스의 미세구조를 유도하는 코크스 드럼으로 구성되었으며, preheater의 온도를 400~490 °C로 조절하여 제조된 피치로부터 코크스를 제조하고 편광현미경, XRD 및 Raman spectroscopy로 특성을 평가하였다. Preheater의 온도가 460 °C에서 제조된 코크스는 이방성 미세조직이 flow 형태로 나타났으며, 높은 결정성으로 전기전도성이 72.0 S/cm이였다. 그리고 전도성 탄소 재료인 Super-P보다 대략 2.2배 높은 전기전도성을 나타냈다. In this study, pitch was synthesized using pyrolysis fuel oil (PFO). Coke with mesophase microstructure was then prepared from the synthesized pitch and its properties were evaluated. Pitch was synthesized by poly-condensation reaction, which is an endothermic reaction at a temperature above 400 °C because the PFO was mainly composed of molecules with two to three aromatic rings. The Coke reactor was composed of the pretreatment reactor, preheater for applying heat energy, and coke drum for inducing microstructure of coke. Coke was prepared from synthesized pitch by controlling the temperature of the preheater to 400~490 °C, and properties were evaluated by polarization microscope, XRD and Raman spectroscopy. The coke prepared at a preheater temperature of 460 °C identified flow anisotropic microstructure, and the electrical conductivity was 72.0 S/cm due to high crystallinity. And the flow anisotropic coke showed approximately 2.2 times higher electrical conductivity than that of Super-P, a conductive carbon material.
고밀도화 탄소 블록 제조 시 콜타르계 피치의 점도가 함침에 미치는 영향
조종훈 ( Jong Hoon Cho ),황혜인 ( Hye In Hwang ),김지홍 ( Ji Hong Kim ),이영석 ( Young-seak Lee ),임지선 ( Ji Sun Im ),강석창 ( Seok Chang Kang ) 한국공업화학회 2021 공업화학 Vol.32 No.5
본 연구에서는 코크스, 바인더 피치 및 함침 피치를 사용하여 고밀도 탄소 블록을 제조하고, 함침 공정 시 피치의 유동성이 탄소 블록의 고밀도화에 미치는 영향을 고찰하였다. 코크스와 바인더 피치의 고압 성형을 통해 그린블록을 제조하고 열처리 공정을 통하여 탄소 블록을 얻었다. 열처리 공정 시 바인더 피치의 휘발에 의해 생성된 기공을 제거하고자 함침 공정을 진행하였다. 함침 공정은 함침 피치를 용융하는 전처리 단계와 피치를 탄소 블록에 함침하는 고압 반응 단계로 나누어 진행하였다. 함침 피치의 용융은 140~200 ℃에서 진행하였으며, 열처리 온도가 증가할수록 함침 피치의 점도가 감소하였다. 함침 피치의 점도 감소는 유동성을 향상시켜 탄소 블록 내부 기공을 효율적으로 함침하여 탄소 블록의 기공률을 83% 감소시켰고 겉보기 밀도를 5% 상승시켰다. In this study, high-density carbon blocks were manufactured using coke, binder pitch, and impregnated pitch, then the effect of pitch fluidity on the densification of carbon blocks during the impregnation process was investigated. A green block was manufactured through high-pressure figuration of coke and binder pitch, and a carbon block was obtained through a heat treatment process. An impregnation process was performed to remove pores generated by volatilization of the binder pitch during the heat treatment process. The impregnation process was carried out the high-pressure reaction step of impregnating the pitch into the carbon block followed by the pretreatment step of melting the impregnation pitch. Melting of the impregnation pitch was carried out at 140~200 ℃, and the viscosity of the impregnation pitch decreased as the heat treatment temperature increased. The decrease in the viscosity of the impregnation pitch improved the fluidity and effectively impregnated the pores inside the carbon block, reducing the porosity of the carbon block by 83% and increasing the apparent density by 5%.
이성분 휘발성유기화합물(Toluene-MEK)의 활성탄 흡착 및 탈착 특성
유선아(Seon A Yu),조종훈(Jong Hoon Cho),박지윤(Ji Yun Park),이영우(Young Woo Rhee) 한국청정기술학회 2017 청정기술 Vol.23 No.4
본 연구는 상용활성탄을 사용하여 산업공정에서 많이 사용되는 휘발성 유기화합물 중 톨루엔, 메틸에틸케톤(MEK), 이성분계(톨루엔-MEK)를 대상으로 흡착 및 탈착특성을 고찰하였다. 최적탈착온도를 설정하기 위해 온도별 탈착특성을 고찰하였고, 활성탄의 특성을 파악하기 위해 BET분석을 하였다. 상온에서 흡착실험을 진행하였고, 120 ℃까지 승온하여 탈착실험을 진행하였다. 이 실험을 10회 반복해서 진행하였다. 이를 통해 단일성분에서는 반복횟수가 많아질수록 흡착 및 탈착능이 줄어들며 활성탄과 상대적으로 친화력이 적은 MEK의 경우 톨루엔보다 낮은 흡착 및 탈착능을 보였다. 이성분계의 흡착 및 탈착 반복시험에서 친화력이 낮은 MEK가 먼저 파과되고 결과적으로 주입 농도보다 높은 농도로 탈착되었다. In this study, we have investigated the characteristics of adsorption and desorption of toluene, methyl ethyl ketone (MEK) and their binary component using activated carbon. The BET analysis was performed to identify the characteristics of the activated carbon, and the desorption characteristics with temperature were examined to find out an optimum desorption temperature. Ten cyclic experiments of adsorption-desorption were performed, where each adsorption temperature was maintained at room temperature and desorption temperature at upto 120 ℃. In case of single component cyclic test, the efficiencies of adsorption and desorption decreased as the cycle increased. MEK which has lower affinity with activated carbon than toluene showed lower efficiencies of adsorption and desorption. In case of binary component cyclic test, a typical roll-up phenomenon was observed during adsorption process, where MEK reaches at breakpoint first and then was swept out by toluene.
정덕환,한정수,김진원,안옥균,조종훈,Chung, Duke-Whan,Han, Chung-Soo,Kim, Jin-Won,Ahn, Ok-Kyun,Cho, Jong-Hoon 대한미세수술학회 1993 Archives of reconstructive microsurgery Vol.2 No.1
The authors analyzed the clinical results of the reconstructive surgery for injured hands and feet due to frostbites and electrical burn with microsurgery in 7 patients, 12 cases at the department of orthopaedic surgery, school of medicine, Kyung Hee university from Jan. 1989 to Jul. 1992, and the results were as foollowings. 1. The age at the time of injury was av 24.6 yrs ranging from 4 to 35 yrs, and all cases were male. 2. The follow up period was av. 24.4 Mo ranging from 12 Mo. to 56 Mo. 3. The causes of injury were frostbite in 9 cases, electrical burn in 2 cases. 4. Initial operative treatment was performed av. 69.3 days ranging from 2 to 210 days. 5. For the reconstructive procedure, scapular free flap was applied in 6 cases, radial forearm flap in 4, dorsalis pedis 1ffap in 1, neurovascular island flap in 1. 6. Among total 12 cases, there were 5 cases(41.7%) of wound infection and 3 cases (25.0%) of partial necrosis of donor flap. 7. In 11 cases(90.1%), the end result was satisfactory. In the analysis of above results the reconstruction with microsurgery is effective procedure for reconstruction of Injured hand and foot due to frostbite and electrical burn.