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암모니아수용액을 이용한 SO<sub>X</sub>-NO<sub>X</sub> 동시 흡수에 관한 연구
김재강,이주열,박병현,최진식,Kim, Jae-Gang,Lee, Ju-Yeol,Park, Byung-Hyun,Choi, Jin-Sik 한국응용과학기술학회 2015 한국응용과학기술학회지 Vol.32 No.3
The experiment was performed using the cleaning precipitator To investigate the absorption efficiency of the $SO_X/NO_X$ of the aqueous ammonia solution. Concentration of the cleaning liquid is 0.1, 0.5, and 1.0% with increasing absorption efficiency has improved. However, the reaction shown only a difference in time. Absorption efficiency has improved in accordance with the gas residence time. When the direction of the same gas and the cleaning liquid is determined that there is the effect of increasing the residence time. The relative impact of $SO_X$ and $NO_X$ is this likely to react slower than $SO_X/NO_X$. The yield is determined to require adjustment of the cleaning dust collector according to the concentration of the next gas.
암모니아수용액을 이용한 SOx-NOx 동시 흡수에 관한 연구
김재강(Jae-Gang Kim),이주열(Ju-Yeol Lee),박병현(Byung-Hyun Park),최진식(Jin-Sik Choi) 한국유화학회 2015 한국응용과학기술학회지 Vol.32 No.3
The experiment was performed using the cleaning precipitator To investigate the absorption efficiency of the SOX/NOX of the aqueous ammonia solution. Concentration of the cleaning liquid is 0.1, 0.5, and 1.0% with increasing absorption efficiency has improved. However, the reaction shown only a difference in time. Absorption efficiency has improved in accordance with the gas residence time. When the direction of the same gas and the cleaning liquid is determined that there is the effect of increasing the residence time. The relative impact of SOX and NOX is this likely to react slower than SOX/NOX. The yield is determined to require adjustment of the cleaning dust collector according to the concentration of the next gas.
Post Normal Shock Flow Analysis of Nitrogen
Jae Gang Kim(김재강) 한국항공우주학회 2015 한국항공우주학회 학술발표회 논문집 Vol.2015 No.11
One dimensional post-normal shock flow calculations are carried out using state-of-the-art thermochemical nonequilibrium models. Two-temperature, four-temperature, and electronic master equation coupling models are adopted in the present work. In the four-temperature model, the rotational nonequilibrium is described by Parker and modified Park models. In the electronic master equation coupling model, recently evaluated electron and heavy-particle impacts and radiative transition cross sections are employed in constructing the system of electronic master equations. In analyzing the shock-tube experiments, the results calculated by the state-of-the-art thermochemical nonequilibrium models are compared with existing shock-tube experimental data. The four-temperature and electronic master equation coupling models with rotational nonequilibrium accurately reproduce the measured nonequilibrium temperatures.