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황승진(S.J Hwang),박성호(S.H. Park),한수민(S.M. Han),김정식(J.S. Kim),장성철(S.C. Jang) 대한기계학회 2013 대한기계학회 춘추학술대회 Vol.2013 No.12
Eeplosion fan is abbreviation for inert gas generator high temperature in cargo tank it desulfurize, exhaust and froze the gas that combined brimstone element and soot, then supply inert gas by blower and mack tank inside incombustible range this is equipment that nip in the bud the explosion. The blower for suppling inactivated gas has big impeller with heavy weight to achieve the high pressure, it causes a delay for first operation time and too much load is delivered to motor, total destruction by fire of motor is happen frequently. On this research, we will reduce the size and weight of impeller and install it with several stage, it makes an effect for reducing the first operation time. We also intend to contribute to efficient I.G.G. blower design by research a flow rate and pressure specialty from the diameter of impeller number of blades and size of casing.
혼합소스 HVPE에 의해 성장된 In(Al)GaN 층의 특성
황선령,김경화,장근숙,전헌수,최원진,장지호,김홍승,양민,안형수,배종성,김석환,Hwang, S.L.,Kim, K.H.,Jang, K.S.,Jeon, H.S.,Choi, W.J.,Chang, J.H.,Kim, H.S.,Yang, M.,Ahn, H.S.,Bae, J.S.,Kim, S.W. 한국결정성장학회 2006 한국결정성장학회지 Vol.16 No.4
혼합소스 HVPE(hydride vapor phase epitaxy) 방법을 이용하여 InGaN 층을 GaN 층이 성장된 사파이어 (0001) 기판 위에 성장하였다. InGaN 층을 성장하기 위해 금속 In에 Ga을 혼합하여 III족 소스로 이용하였으며 V족 소스로는 $NH_3$를 이용하였다. InGaN층은 금속 In에 Ga을 혼합한 소스와 HCl을 흘려 반응한 In-Ga 염화물이 다시 $NH_3$와 반응하도록 하여 성장하였다. XPS 측정을 통해 혼합소스 HVPE 방법으로 성장한 층이 InGaN 층임을 확인할 수 있었다. 선택 성장된 InGaN 층의 In 조성비는 PL과 CL을 통해서 분석하였다. 그 결과 In 조성비는 약 3%로 평가되었다. 또한, 4원 화합물인 InAlGaN 층을 성장하기 위해 In 금속에 Ga과 Al을 혼합하여 III족 소스로 사용하였다. 본 논문에서는 혼합소스 HVPE 방법에 의해 III족 소스물질로 금속 In에 Ga(Al)을 혼합한 소스를 이용하여 In(Al)GaN층을 성장할 수 있음을 확인할 수 있었다. InGaN layers on GaN templated sapphire (0001) substrates were grown by mixed-source hydride vapor phase epitaxy (HVPE) method. In order to get InGaN layers, Ga-mixed In metal and $NH_3$ gas were used as group III and group V source materials, respectively. The InGaN material was compounded from chemical reaction between $NH_3$ and indium-gallium chloride farmed by HCl flowed over metallic In mixed with Ga. The grown layers were confirmed to be InGaN ternary crystal alloys by X-ray photoelectron spectroscopy (XPS). In concentration of the InGaN layers grown by selective area growth (SAG) method was investigated by the photoluminescence (PL) and cathodoluminescence (CL) measurements. Indium concentration was estimated to be in the range 3 %. Moreover, as a new attempt in obtaining InAlGaN layers, the growth of the thick InAlGaN layers was performed by putting small amount of Ga and Al into the In source. We found the new results that the metallic In mixed with Ga (and Al) as a group III source material could be used in the growth process of the In(Al)GaN layers by the mixed-source HVPE method.