• Journal of Energy Engineering
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• v.9 no.4
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• pp.319-327
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• 2000

산업분야의 여러공정에서 배출되는 휘발성 유기화합물은 1차적인 작업자에 대한 유해성뿐만이 아니라 대기중에 배출시의 제 2차 오염물질의 생성 때문에 최근 들어 이러한 물질의 처리에 큰 관심이 집중되고 있다. 본 연구에서는 휘발성 유기화합물로서 프로판을 사용하여 이러한 초 희박 혼합기의 제거를 위해 재생열산화법이 제안되었다. 실험장치에는 중앙에 연소실과 전기적 열량공급장치를 장착하였다. 초 희박 혼합기의 연소실에서의 산화과정과 열사화 장치의 폐열회수 특성을 연구하기 위하여 혼합기의 농도, 유속 및 연소실 최대온도와 같은 다양한 작동조건을 고려하였다. 그 결과. 재생열산화장치가 초 희박 혼합기의 산화에 적절하게 사용될 수 있음을 알았으며 최대 96%의 제거효율 얻을 수 있었다. 산화과정중에 발생하여 배출되는 CO는 운전조건을 변화시킴으로써 그 농도를 낮출 수 있었으며 열적 NOx는 배출되지 않았다. 페열회수효율은 전 운전영역에서 높게 나타났으며 그 값이 최대 98%에 이르렀다.

• Transactions of the Korean Society of Mechanical Engineers B
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• v.39 no.9
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• pp.727-734
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• 2015

Recently, because of the increased oil prices globally, there have been studies investigating the improvement of fuel-conversion efficiency in internal combustion engines. The improvements realized in thermal efficiency using lean combustion are essential because they enable us to realize higher thermal efficiency in gasoline engines because lean combustion leads to an increase in the heat-capacity ratio and a reduction of the combustion temperature. Gasoline direct injection (GDI) engines enable lean combustion by injecting fuel directly into the cylinder and controlling the combustion parameters precisely. However, the extension of the flammability limit and the stabilization of lean combustion are required for the commercialization of GDI engines. The reduction characteristics of three-way catalysts (TWC) for lean combustion engines are somewhat limited owing to the high excess air ratio and low exhaust gas temperature. Therefore, in the present study, we assess the reaction of exhaust gases and their production in terms of the development of efficient TWCs for lean-burn GDI engines at 2000 rpm / BMEP 2 bar operating conditions, which are frequently used when evaluating the fuel consumption in passenger vehicles. At the lean-combustion operating point, $NO_2$ was produced during combustion and the ratio of $NO_2$ increased, while that of $N_2O$ decreased as the excess air ratio increased.

• Transactions of the Korean hydrogen and new energy society
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• v.15 no.2
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• pp.89-97
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• 2004

A heavy duty hydrogen enriched CNG engine has the possibility to obtain stable operation at ultra lean condition and to reduce emission extremely. And it can also serve as a so called bridge technology between the current fossil fueled engine and the future hydrogen power system. The emission, torque and brake thermal efficiency characteristics of a heavy-duty hydrogen-CNG engine were investigated to determine the proper mixing rate of hydrogen and CNG. It was found that the proper mixing rates at ${\lambda}=1.4$ and ${\lambda}=1.6$ were around 20% and 30% for hydrogen addition rate respectively.

• Transactions of the Korean hydrogen and new energy society
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• v.16 no.2
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• pp.191-198
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• 2005

Adding hydrogen gas in natural gas leads to stable combustion in internal combustion engine and its performances rely on compression ratio. To analyze the effects of compression ratio and rate of hydrogen addition on the engine performance, the characteristics of overall engine performance including emission were investigated by using the medium duty natural gas fueled engine. As results, it was found that compression ratio occurred knock was nearby compression ratio, $\varepsilon$=14 for the case that hydrogen was enriched in the natural gas fueled engine. But slight knock was occurred at $\varepsilon$=14.7 in the case of neat natural gas. Also HC and $CO_2$ were reduced around 80% and 20% respectively when the rate of hydrogen addition was increased to 50% and compression ratio from $\varepsilon$=13 to $\varepsilon$=14.7.

• Transactions of the Korean Society of Automotive Engineers
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• v.14 no.2
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• pp.84-91
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• 2006

A heavy duty hydrogen-natural gas fueled engine can obtain stable operation at ultra lean conditions and reduce emissions extremely. Reduction of $CO_2$ in its engine is one of the most benefit. In this study, rate of hydrogen addition($R_{dH2}$) and compression ratio($\varepsilon$) were investigated including performance of this engine. As results, it was found that phenomenon of pressure oscillation when increasing $R_{dH2}$ and $\varepsilon$, it means occurring knock. It consider that pressure oscillation was increased due to fast burning speed of hydrogen. Even if same compression ratio, pressure oscillation was remarkable increased according to increasing $R_{dH2}$. Therefore, limit compression ratio of knock occurring was reduced by increasing $R_{dH2}$.