• 한국세라믹학회지
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• 제42권6호
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• pp.425-431
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• 2005

Line Shaped Solid Oxide Fuel Cell (SOFC) with multilayered structure has been fabricated via direct-writing process. The cell is electrolyte of Ni-YSZ cermet anode, YSZ electrolyte and LSM cathode. They were processed into pastes for the direct writing process. Syringe filled with each electrode and electrolyte paste was loaded into the computer-controlled robe-dispensing machine and the paste was dispensed through cylindrical nozzle of 0.21 mm in diameter under the air pressure of 0.1 tow onto a moving plate with 1.22 mm/s. First of all, the anode paste was dispensed on the PSZ porous substrate, and then the electrolyte paste was dispensed. The anode/electrolyte and the PSZ substrate were co-fired at $1350^{\circ}C$ in air atmosphere for 3 h. The cathode layer was similarly dispensed and sintered at $1200^{\circ}C$ for 1 h. All the electrode/electrolyte lines were visually aligned during the direct writing process. The effective reaction area of fabricated SOFC was $0.03 cm^2$, and the thickness of anode, electrolyte and cathode was 20 $\mu$m, 15 $\mu$m, and 10 $\mu$m, respectively. The single line-shaped SOFC fabricated by direct-writing process exhibited OCV of 0.95 V and maximum power density of $0.35W/cm^2$ at $810^{\circ}C$.

• KSBB Journal
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• 제25권4호
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• pp.379-386
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• 2010

본 연구에서는 coriander 정유의 안정성 향상을 위해 초임계 PGSS 공정을 이용하여 coriander 정유가 봉입된 PEG 미세입자를 제조하였으며 공정 온도와 압력, 노즐 크기가 미세입자의 크기, 형태 및 정유의 봉입률에 미치는 영향에 대하여 조사하였다. $100\;{\mu}m$ 노즐을 사용하여 얻어진 미세입자의 형상을 분석한 결과 $1-10\;{\mu}m$ 크기의 구형 입자 형태를 나타내었으나 노즐의 크기가 증가한 경우에는 덩어리진 입자가 얻어짐을 확인하였다. 온도, 압력 변화에 따라 얻어진 미세입자의 경우 일정 압력 조건에서 공정 온도가 높아짐에 따라, 일정 온도 조건에서 공정 압력이 낮아짐에 따라 구형입자 비율이 증가함을 보였으며, 일정 온도 조건에서는 공정 압력이 높아짐에 따라 더 많은 기공을 가지는 입자가 생성됨을 확인하였다. 제조된 PEG 미세입자 내 coriander 정유의 봉입률은 모든 온도 조건에서 가장 낮은 압력인 75 bar일 때 가장 높은 값을 보였다.

• 에너지공학
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• 제14권4호
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• pp.268-276
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• 2005

액체연료(중유)공급량 기준 20kg/hr규모의 반응로에서 증기분무 내부 혼합식 노즐을 이용하여 잔사유의 연소실험을 수행하였다. 본 실험에서 사용한 감압 잔사유는 점도가 높고 황함량, 잔류탄소와 금속성분의 함량도 높았다. 잔사유의 착화를 위해서는 반응로를 일정온도까지 예열하여야 했으며 이는 LPG를 이용하였다. 잔사유 공급량을 변화시키면서 축방향 및 반경방향의 로내 가스 온도, 주요 가스농도 및 채집된 고체 입자를 분석하였다. 잔사유의 주반응영역은 버너 팁으로부터 약 1 m 근방에서 형성되었으며 이는 축방향 가스 온도, 농도 분포 및 입자의 크기로부터 확인할 수 있었고, 반응로의 하류에서는 완전 확립된 온도분포를 보여주고 있었다. 고체 입자의 SEM 분석으로부터 잔류 탄소입자는 기공이 많은 형태를 띠고 있었다.

• 대한기계학회논문집B
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• 제31권9호
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• pp.790-798
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• 2007

An experimental study was performed to investigate the effects of mixing quality, inlet pressure, nozzle diameter on CO, NO emission and radiation characteristics in porous ceramic fiber radiant burners. Observations of combustion characteristics occurring inside the burner system which was insulated fiber mat, were investigated by measuring emission and radiation characteristics. Combustion was achieved at the firing rate of $88{\sim}99\;kcal/hr$, inlet pressure of $100{\sim}250mmH_2O$. The fiber burner exhibit significant both spectral intensity peaks in the bands at $2.5{\mu}m\;and\;4.0{\mu}m$ relatively. There is a small difference in the variable mixing tube. However spectral intensity increased with the firing rate. CO emissions were found to be strongly dependent on the operating conditions. There was a tendency that CO concentration increased as the firing rate increases. the reason for rise of CO concentration is that is becomes it the relatively rich condition. Relatively low NO emission was observed for the whole operating range. The NO concentration is maximal at the firing rate of approximately 2850 kcal/hr and an air ratio of about 1.

• 한국결정성장학회지
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• 제10권3호
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• pp.226-232
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• 2000

침지노즐(SEN)의 재료로 사용되는 지르코니아/흑연 재질에서 용강 및 슬래그에 의한 침식의 형태를 살펴본 결과, 침식의 첫번째 기구는 부분안정화 지르코니아 내 안정화제인 CaO가 용강 및 슬래그에 의해 용해되면서 입방정 안정화 지르코니아가 단사정상으로 상전이하여 일어났는데, 상전이 시 부피팽창에 의한 균열이 발생하고 파괴가 진행되었고, 이로 인하여 미세 $ZrO_2$입자의 용해 및 탈락이 촉진되었다. 침식의 두 번째 기구는 슬래그가 큰 c-$ZrO_2$입자의 입계를 따라 침투하여 작은 입자들로 분리시키고, 작은 입자들이 용강과 슬래그에 탈락되어 진행되었다. 마지막 기구로는 입방정 지르코니아와 흑연이 반응하여 다공질의 미세한 ZrC 상을 형성하고, 이들이 slag에 용해되면서 침식이 진행되었다.

• 한국재료학회:학술대회논문집
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• 한국재료학회 2012년도 춘계학술발표대회
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• pp.58.2-58.2
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• 2012

Heavy hydrocarbon reforming is a core technology for "Dirty energy smart". Heavy hydrocarbons are components of fossil fuels, biomass, coke oven gas and etc. Heavy hydrocarbon reforming converts the fuels into $H_2$-rich syngas. And then $H_2$-rich syngas is used for the production of electricity, synthetic fuels and petrochemicals. Energy can be used efficiently and obtained from various sources by using $H_2$-rich syngas from heavy hydrocarbon reforming. Especially, the key point of "Dirty energy smart" is using "dirty fuel" which is wasted in an inefficient way. New energy conversion laboratory of KAIST has been researched diesel reforming for solid oxide fuel cell (SOFC) as a part of "Dirty energy smart". Diesel is heavy hydrocarbon fuels which has higher carbon number than natural gas, kerosene and gasoline. Diesel reforming has difficulties due to the evaporation of fuels and coke formation. Nevertheless, diesel reforming technology is directly applied to "Dirty fuel" because diesel has the similar chemical properties with "Dirty fuel". On the other hand, SOFC has advantages on high efficiency and wasted heat recovery. Nippon oil Co. of Japan recently commercializes 700We class SOFC system using city gas. Considering the market situation, the development of diesel reformer has a great ripple effect. SOFC system can be applied to auxiliary power unit and distributed power generation. In addition, "Dirty energy smart" can be realized by applying diesel reforming technology to "Dirty fuel". As well as material developments, multidirectional approaches are required to reform heavy hydrocarbon fuels and use $H_2$-rich gas in SOFC. Gd doped ceria (CGO, $Ce_{1-x}Gd_xO_{2-y}$) has been researched for not only electrolyte materials but also catalysts supports. In addition, catalysts infiltrated electrode over porous $La_{0.8}Sr_{0.2}Ga_{0.8}Mg_{0.2}O_3-{\delta}$ and catalyst deposition at three phase boundary are being investigated to improve the performance of SOFC. On the other hand, nozzle for diesel atomization and post-reforming for light-hydrocarbons removal are examples of solving material problems in multidirectional approaches. Likewise, multidirectional approaches are necessary to realize "Dirty energy smart" like reforming "Dirty fuel" for SOFC.