• 제목/요약/키워드: Reaction gas ratio

검색결과 557건 처리시간 0.025초

폐플라스틱 가스화에 의한 가스로부터 상용 촉매 펠릿을 이용한 수성가스 전환 반응 (Water Gas Shift Reaction Using the Commercial Catalyst Pellets from the Gases by Waste Plastic Gasification)

  • 윤지민;최영섭;김진배;김진배;황갑진
    • 한국수소및신에너지학회논문집
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    • 제34권4호
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    • pp.327-333
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    • 2023
  • The water gas shift reaction was carried out using the commercial catalyst pellet and the simulated gases expected to occur from waste plastic gasification. In the water gas shift reaction, the high temperature shift reaction and the low temperature shift reaction were continuously performed with CO:H2O ratio of 1:2, 1:2.5, and 1:3, and the CO conversion and H2 increase rate were evaluated. The H2 increase rate increased in order to CO:H2O ratio of 1:3 > CO:H2O ratio of 1:2.5 > CO:H2O ratio of 1:2. The CO conversion showed a high value of more than 97% at each CO:H2O ratio. The water gas shift reaction at a CO:H2O ratio of 1:3 showed the highest H2 increase rate and CO conversion.

기상반응에 의한 $Si_3N_4$ 미세분말의 합성 (Synthesis of Ultrafine Silicon Nitride Powders by the Vapor Phase Reaction)

  • 유용호;어경훈;소명기
    • 한국세라믹학회지
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    • 제37권1호
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    • pp.44-49
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    • 2000
  • Silicon nitride powders, were synthesized by the vapor phase reaction using SiH4-NH3 gaseous mixture. The reaction temperature, ratio of NH3 to SiH4 gas and the overall gas quantity were varied. The synthesized powders were characterized using X-ray, TEM, FT-IR and EA. The synthesized silicon nitride powders were in amorphous state, and the average particle size was about 100nm. TEM analysis revealed that the particle size decreased with increasing reaction temperature and gas flow quantity. As-received amorphous powders were annealed in nitrogen atmosphere at 140$0^{\circ}C$ for 2h, then the powders were completely crystallized at 0.2 ratio of NH3 to SiH4.

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Mo Powders Fabricated from MoO3 by Reduction in Hydrogen Gas

  • Hong, Seonghoon;Lee, Changsup;Oh, Changsup;Kil, Sangcheol;Kim, Yongha
    • 대한금속재료학회지
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    • 제50권6호
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    • pp.445-448
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    • 2012
  • We studied the effect of temperature and reaction time by investigating the various temperatures and reaction times in the reduction of molybdenum oxide ($MoO_3$) to molybdenum (Mo) powder in hydrogen gas. We also studied the effect of the reaction of reduction according to the various hydrogen gas flow rates. We surveyed the reduction from molybdenum oxide to molybdenum powder in hydrogen gas and checked two temperature ranges, one from $400^{\circ}C$ to $600^{\circ}C$ and the other from $700^{\circ}C$ to $900^{\circ}C$. We found that the reaction ratio of molybdenum oxide increased with an increasing temperature and also increased with an increasing reaction time, but hydrogen gas did not influence the reduction ratio of molybdenum oxide. We examined molybdenum powders fabricated by ball milling for two hours, using with X-ray diffraction (XRD) and a scanning electron microscopy (SEM).

회분식 유동층 반응기에서 촉매함량 변화에 따른 WGS 촉매의 반응특성 (Reaction Characteristics of WGS Catalyst with Fraction of Catalyst in a Batch Type Fluidized Bed Reactor)

  • 류호정;현주수;김하나;황택성
    • 한국수소및신에너지학회논문집
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    • 제22권4호
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    • pp.465-473
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    • 2011
  • To find the optimum mixing ratio of WGS catalyst with $CO_2$ absorbent for SEWGS process, water gas shift reaction tests were carried out in a fluidized bed reactor using commercial WGS catalyst and sand (as a substitute for $CO_2$ absorbent). WGS catalyst content, gas velocity, and steam/CO ratio were considered as experimental variables. CO conversion increased as the catalyst content increased during water gas shift reaction. Variations of the CO conversion with the catalyst content were small at low gas velocity. However, those variations increased at higher gas velocity. Within experimental range of this study, the optimum operating condition(steam/CO ratio=3, gas velocity = 0.03 m/s, catalyst content=10 wt.%) to get high CO conversion and $CO_2$ capture efficiency was confirmed. Moreover, long time water gas shift reaction tests up to 20 hours were carried out for two cases (catalyst content = 10 and 20 wt.%) and we could conclude that the WGS reactivity at those conditions was maintained up to 20 hours.

수소 수율 증가를 위한 합성가스의 수성가스전환 반응 연구 (Water Gas Shift Reaction Research of the Synthesis Gas for a Hydrogen Yield Increase)

  • 김민경;김재호;김우현;이시훈
    • 신재생에너지
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    • 제5권2호
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    • pp.9-14
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    • 2009
  • Automobile Shredder Residue (ASR) is very appropriate in a gasification melting system. Gasification melting system, because of high reaction temperature over than $1,350^{\circ}C$, can reduce harmful materials. To use the gasification processes for hydrogen production, the high concentration of CO in syngas must be converted into hydrogen gas by using water gas shift reaction. In this study, the characteristics of shift reaction of the high temperature catalyst (KATALCO 71-5M) and the low temperature catalyst (KATALCO 83-3X) in the fixed - bed reactor has been determined by using simulation gas which is equal with the syngas composition of gasification melting process. The carbon monoxide composition has been decreased as the WGS reaction temperature has increased. And the occurrence quantity of the hydrogen and the carbon dioxide increased. When using the high temperature catalyst, the carbon monoxide conversion ratio ($1-CO_{out}/CO_{in}$) rose up to 95.8 from 55.6. Compared with average conversion ratio from the identical synthesis gas composition, the low temperature catalyst was better than the high temperature catalyst.

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RPF(Refuse plastic fuel) 합성가스의 수성가스 전환 반응 연구 (A Study on the Water Gas Shift Reaction of RPF Syngas)

  • 노선아
    • 자원리싸이클링
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    • 제30권6호
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    • pp.12-18
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    • 2021
  • 수성가스 전환 반응은 가스화로 생성된 합성 가스에 수소 생산 증가와 H2/CO 비율 제어를 위해 수증기를 첨가하는 가스화 후속 공정이다. 본 연구에서는 RPF(Refuse plastic fuel) 가스화 시스템의 합성가스를 대상으로 수성가스 전환 반응을 연구하였다. 수성가스 전환 반응은 촉매를 이용하여 high temperature shift(HTS) 와 low temperature shift(LTS) 반응에 대하여 lab scale 관형 반응기를 이용하여 반응 온도, steam/carbon ratio, 유량의 변화가 H2 생성과 CO 전환율에 미치는 영향을 조사하였다. 운전 온도는 HTS 시스템이 250-400℃, LTS 시스템이 190-220℃이며 steam/carbon ratio는 1.5-3.5로 변화시켰다. 반응 모의 가스의 농도는 RPF 합성가스의 농도를 기준으로 CO, 40vol%, H2, 25vol%, CO2, 25vol%이다. 반응 온도와 steam/carbon ratio가 증가함에 따라 CO 전환율 및 H2 생성량이 증가하고, 유량이 증가하면 촉매층의 체류시간 단축으로 CO 전환율과 H2 생성량이 감소하였다.

디메틸에테르의 직접반응 속도론 (Kinetics on Direct Synthesis Dimethyl Ether)

  • 조원일;최창우;백영순;노경호
    • 한국가스학회:학술대회논문집
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    • 한국가스학회 2005년도 추계학술발표회 논문집
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    • pp.83-87
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    • 2005
  • The kinetics of the direct synthesis of DME was studied under different conditions over a temperature range of $220\~280^{\circ}C$, syngas ratio $1.2\~ 3.0$ All experiment were carried out over hybrid catalyst, composed to a methanol synthesis catalyst (Cu/ZnO/$Al_2O_3$) and a dehydration Catalyst ($\gamma$-Al_2O_3$) The observed reaction rate qualitatively follows a Langmiur-Hinshellwood type of reaction mechanism. Such a mechanism is considered with three reaction, methanol synthesis, methanol dehydration and water gas shift reaction. From a surface reaction with dissociative adsorption of hydrogen, methanol and water, individual reaction rate was determined

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천연가스를 이용한 자열개질기의 운영조건에 대한 수치해석 연구 (Numerical Study on operating conditions of Autothermal Reformer using natural gas)

  • 김진욱;김상우;박달영;전상희;이도형
    • 한국신재생에너지학회:학술대회논문집
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    • 한국신재생에너지학회 2010년도 추계학술대회 초록집
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    • pp.91.1-91.1
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    • 2010
  • The Reforming system is an effective method to generate hydrogen which uses for fuel cell system. The purpose of this study is to present characteristics of an autothermal reformer at various operating conditions and to investigate ideal conditions for reforming efficiency. Dominant chemical reactions are Full Combustion, Steam Reforming reaction, Water-Gas Shift reaction and Direct Steam Reforming reaction. Operating parameters of the autothermal reformer are inlet temperature, Oxygen to Carbon Ratio, Steam to Carbon Ratio and Gas Hourly Space Velocity. Autothermal reformer is filled with catalysis of a packbed-bed type. Using numerical approach, we have investigated on various reaction conditions.

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FT(Fischer-Tropsh) 합성유 제조를 위한 합성가스 공정 최적화 연구 (A simulation study on synthesis gas process optimization for FT(Fischer-Tropsh) synthesis)

  • 김용헌;이원수;이흥연;구기영;송인규
    • 한국신재생에너지학회:학술대회논문집
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    • 한국신재생에너지학회 2009년도 춘계학술대회 논문집
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    • pp.888-888
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    • 2009
  • A simulation study on SCR (Steam Carbon dioxide Reforming) process in gas-to-liquid (natural gas to Fischer-Tropsch synthetic fuel) process was carried out in order to find optimum reaction conditions for GTL (gas-to-liquid) process reaction. Optimum SCR operating conditions for synthesis gas to FT (Fischer-Tropsch) process were determined by changing reaction variables such as feed temperature and pressure. During the simulation, overall synthesis process was assumed to proceed under steady-state conditions. It was also assumed that physical properties of reaction medium were governed by RKS (Redlich-Kwong-Soave) equation. SCR process was considered as reaction models for synthesis gas in GTL proess. The effect of temperature and pressure on SCR process $H_2$/CO ratio and the effect of reaction pressure on SCR reaction were mainly examined. Simulation results were also compared to experimental results to confirm the reliability of simulation model. Simulation results were reasonably well matched with experimental results.

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CNT-confined reaction에 의한 탄화규소 나노튜브의 합성 (Synthesis of SiC Nanotube by CNT-confined Reaction)

  • 노대호;김재수;변동진;양재웅;김나리
    • 한국재료학회지
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    • 제14권3호
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    • pp.175-180
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    • 2004
  • SiC nanotubes were synthesized by CNT-confined reaction. Evaporated SiO gas reacted with carbon nanotubes by VS growth mechanism. By confineded reaction, carbon nanotube was changed to SiC nanotube, and synthesized SiC nanotube was filled partly by the gas reaction in the nanotubes. SiC nanotube's mean diameters were not changed than carbon nanotubes because of means ratio of $CO_2$ and SiO gas was maintained evenly during the process. This result was same of data of simulation. By TEM observastion, SiC nanotube was filled by reaction of inner wall of CNT and SiO gas through the VS reactions. Converted SiC nanotube's compositions were revealed Si and C of 1: 1 ratios at all sites of nanotube by EDS.