• Title/Summary/Keyword: Steam-Carbon Ratio

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Biomass and PE Gasification with High Temperature Steam of Brown Gas (브라운 가스 고온(高溫) 수증기(水蒸氣)를 이용한 바이오매스 및 PE 가스화)

  • Roh, Seon-Ah;Yun, Jin-Han;Kim, Woo-Hyun;Keel, Sang-In;Min, Tai-Jin
    • Resources Recycling
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    • v.18 no.2
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    • pp.51-55
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    • 2009
  • Sawdust and sewage sludge and PE gasification by high temperature steam of Brown gas have been performed in this study. Steam/carbon ratio has been changed from 1 to 5 and the effect of steam/carbon ratio on the produced gas concentrations, gasification rate and tar generation has been determined. Also, the temperature distribution in the gasification reactor has been studied. Highest combustible content in the produced gas is around 70vol% and $H_2$ shows highest content among the combustible compounds. However, the heating value of the produced gas and tar content have been reduced with increasing steam/carbon ratio.

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

  • Roh, Seon Ah
    • Resources Recycling
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    • v.30 no.6
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    • pp.12-18
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    • 2021
  • The water-gas shift reaction is the subsequent step using steam for hydrogen enrichment and H2/CO ratio-controlled syngas from gasification. In this study, a water-gas shift reaction was performed using syngas from an RPF gasification system. The water-gas shift using a catalyst was performed in a laboratory-scale tube reactor with a high temperature shift (HTS) and a low temperature shift (LTS). The effects of the reaction temperature, steam/carbon ratio, and flow rate on H2 production and CO conversion were investigated. The operating temperature was 250-400℃ for the HTS system and 190-220℃ for the LTS system. Steam/carbon ratios were between 1.5 and 3.5, and the composition of reactant was CO : 40 vol%, H2 : 25 vol%, and CO2 : 25 vol%. The CO conversion and H2 production increased as the reaction temperature and steam/carbon ratio increased. The CO conversion and H2 production decreased as the flow rate increased due to reduced retention time in the catalyst bed.

Thermodynamic Analysis of DME Steam Reforming for Hydrogen Production (수소제조를 위한 DME 수증기 개질반응의 열역학적 특성)

  • Park, Chan-Hyun;Kim, Kyoung-Suk;Jun, Jin-Woo;Cho, Sung-Yul;Lee, Yong-Kul
    • Applied Chemistry for Engineering
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    • v.20 no.2
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    • pp.186-190
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    • 2009
  • This study is purposed to analyze thermodynamic properties on the hydrogen production by dimethyl ether steam reforming. Various reaction conditions of temperatures (300~1500 K), feed compositions (steam/carbon = 1~7), and pressures (1, 5, 10 atm) were applied to investigate the effects of the reaction conditions on the thermodynamic properties of dimethyl ether steam reforming. An endothermic steam reforming competed with an exothermic water gas shift reaction and an exothermic methanation within the applied reaction condition. Hydrogen production was initiated at the temperature of 400 K and the production rate was promoted at temperatures exceeding 550 K. An increase of steam to carbon ratio (S/C) in feed mixture over 1.5 resulted in the increase of the water gas shift reaction, which lowered the formation of carbon monoxide. The maximum hydrogen yield with minimizing loss of thermodynamic conversion efficiency was achieved at the reaction conditions of a temperature of 900 K and a steam to carbon ratio of 3.0.

The Effects of Combustion Parameters on the Characteristics of a Steam-Methane Reformer (연소 변수가 수증기-메탄 개질기의 특성에 미치는 영향)

  • Lee, Jae-Seong;Kim, Ho-Young
    • 한국연소학회:학술대회논문집
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    • 2012.04a
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    • pp.29-31
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    • 2012
  • The effects of combustion parameters on the characteristics of a steam-methane reformer. The reformer system was numerically simulated using a simplified two-dimensional axisymmetric model domain with an appropriate user-defined function. The fuel ratio, defined as the ratio of methane flow rate in the combustor to that in the reactor, was varied from 20 to 80%. The equivalence ratio was changed from 0.5 to 1.0. The results indicated that as the fuel ratio increased, the production rates of hydrogen and carbon monoxide increased, although their rates of increase diminished. In fact, at the highest heat supply rates, hydrogen production was actually slightly decreased. Simulations showed that equivalence ratio of 0.7 yielded the highest steam-methane mixture temperature despite a 43% higher air flow rate than the stoichiometric flow rate. This means that the production of hydrogen and carbon monoxide can be increased by adjusting the equivalence ratio, especially when the heat supply is insufficient.

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Study on the Characteristics of Methanol Steam Reformer Using Latent Heat of Steam (수증기의 잠열을 이용한 메탄올 수증기 개질기의 특성 연구)

  • CHEON, UKRAE;AHN, KANGSUB;SHIN, HYUNKHIL
    • Journal of Hydrogen and New Energy
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    • v.29 no.1
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    • pp.19-24
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    • 2018
  • Fuel cells are used to generate electricity with a reformer. In particular, methanol has various advantages among the fuels for reformer. Methanol steam reformer devices can efficiently supply hydrogen to PEM fuel cell. This study investigated the optimal operation conditions of a methanol steam reforming process. For this purpose, aspen HYSYS was used for the optimization of reforming process. The optimal operating condition could be designed by setting independent variables such as temperature, pressure and steam to carbon ratio (SCR). The optimal temperature and steam to carbon ratio were $250-270^{\circ}C$ and 1.3-1.5, respectively. It is advantageous to operate at a pressure of 15-20 barg, considering the performance of the hydrogen purifier. In addition, a heat exchange network was designed to supply heat constantly to reformer through the latent heat of steam.

A Simulation Study on SCR(Steam Carbon Dioxide Reforming) Process Optimization for Fischer-Tropsch Synthesis (Fischer-Tropsch 합성용 SCR(Steam Carbon Dioxide Reforming) 공정 최적화 연구)

  • Kim, Yong Heon;Koo, Kee Young;Song, In Kyu
    • Korean Chemical Engineering Research
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    • v.47 no.6
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    • pp.700-704
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    • 2009
  • A simulation study on SCR(steam carbon dioxide reforming) in gas-to-liquid(natural gas to Fischer-Tropsch synthetic fuel) process was carried out in order to find optimum reaction conditions for SCR experiment. Optimum operating conditions for SCR process were determined by changing reaction variables such as temperature and $CH_4/steam/CO_2$ feed ratio. Simulation was carried out by Aspen Plus. During the simulation, overall 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. Optimum simulation variables such as temperature and feed ratio were determined by considering $H_2/CO$ ratio for FTS(Fischer-Tropsch synthesis), $CH_4$ conversion, and $CO_2$ conversion. Simulation results showed that optimum reaction temperature and $CH_4/steam/CO_2$ feed ratio in SCR process were $850^{\circ}C$ and 1.0/1.6/0.7, respectively. Under optimum temperature of $850^{\circ}C$, $CH_4$ conversion and $CO_2$ conversion were found to be 99% and 49%, respectively.

The Study of Steam Reforming for Model Bioigas using 3D-IR Matrix Burner Reformer (3D-IR Matrix 버너 개질기를 활용한 모사 바이오가스 수증기 개질 연구)

  • Lim, Mun-Sup;Chun, Young-Nam
    • Journal of Hydrogen and New Energy
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    • v.22 no.1
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    • pp.100-108
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    • 2011
  • The use of biogas as an energy source reduces the chance of possible emission of two greenhouse gases, $CH_4$ and $CO_2$, into the atmosphere at the same time. Its nature of being a reproducible energy source makes its use even more attractive. This research if for the hydrogen production through the steam reforming of the biogas. The biogas utilized 3D-IR matrix burner in which the surface combustion is applied. The nickel catalyst was used inside a reformer. Parametric screening studies were achieved as Steam/Carbon ratio, biogas component ratio, Space velocity and Reformer temperature. When the condition of Steam/Carbon ratio, $CH_4/CO_2$ ratio, Space velocity and Refomer temperature were 3.25, 60%:40%, 19.32L/$g{\cdot}hr$ and $700^{\circ}C$ respectively, the hydrogen concentration and methane conversion rate were showed maximum values. Under the condition mentioned above, $H_2$ concentration was 73.9% and methane conversion rate was 98.9%.

Thermodynamic Equilibrium and Efficiency of Ethylene Glycol Steam Reforming for Hydrogen Production (에틸렌글리콜의 수증기 개질반응을 이용한 수소제조에 대한 열역학적 평형 및 효율 분석)

  • Kim, Kyoung-Suk;Park, Chan-Hyun;Jun, Jin-Woo;Cho, Sung-Yul;Lee, Yong-Kul
    • Korean Chemical Engineering Research
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    • v.47 no.2
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    • pp.243-247
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    • 2009
  • This study is purposed to analyze thermodynamic properties on the hydrogen production by ethylene glycol steam reforming. Various reaction conditions of temperatures(300~1,600 K), feed compositions(steam/carbon= 0.5~4.5), and pressures(1~30 atm) were applied to investigate the effects of the reaction conditions on the thermodynamic properties of dimethyl ether steam reforming. An endothermic steam reforming competed with an exothermic water gas shift reaction and an exothermic methanation within the applied reaction condition. Hydrogen production was initiated at the temperature of 400 K and the production rate was promoted at temperatures exceeding 500 K. An increase of steam to carbon ratio(S/C) in feed mixture over 1.0 resulted in the increase of the water gas shift reaction, which lowered the formation of carbon monoxide. The maximum hydrogen yield with minimizing loss of thermodynamic conversion efficiency was achieved at the reaction conditions of a temperature of 900 K and a steam to carbon ratio of 3.0.

Coal gasification with High Temperature Steam (고온(高溫) 수증기(水蒸氣)를 이용한 석탄(石炭) 가스화)

  • Yun, Jin-Han;Kim, Woo-Hyun;Keel, Sang-In;Min, Tai-Jin;Roh, Seon-Ah
    • Resources Recycling
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    • v.16 no.6
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    • pp.28-33
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    • 2007
  • Coal is the most abundant energy source and deposited in every area of world. Combustion process with lower efficiency has been mainly used. Therefore, implementation of more efficient technologies, involving gasification, combined cycles and fuel cells, would be a key issue in the plans for more efficient power generation. In these technologies, gasification has been studied for decades. However, coal gasification to high value combustible gas such as hydrogen and carbon monoxide is focused again due to high oil price. The gaseous product, called syngas, can be effectively utilized in a variety of ways ranging from electricity production to chemical industry (as feedstock). In this study, coal gasification with ultra high temperature steam has been performed. The effect of steam/carbon ratio on the produced gas concentrations, gasification rate and additional products like tar, ammonia and cyan compounds has been determined.

Experimental study on operation of diesel autothermal reformer for SOFC system (SOFC 시스템용 디젤 자열개질기 운전을 위한 기초 연구)

  • Yoon, Sang-Ho;Kang, In-Yong;Bae, Joong-Myeon
    • Proceedings of the KSME Conference
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    • 2007.05b
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    • pp.2015-2020
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    • 2007
  • Diesel is an excellent candidate fuel for fuel cell applications due to its high hydrogen density and well-established infrastructure. But, it is hard to guarantee desirable performance of diesel reformer because diesel reforming has several problems such as sulfur poisoning of catalyst and carbon deposition. We have been focusing on diesel autothermal reforming(ATR) for substantial period. It is reported that ATR of diesel has several technical advantages such as relatively high efficiency and fuel conversion compared to steam reforming(SR) and partial oxidation(POX). In this paper, we investigate characteristics of diesel reforming under various ratios of reactants(oxygen to carbon ratio, steam to carbon ratio) for improvement of reforming performances(high reforming efficiency, high fuel conversion, low carbon deposition). We also exhibit calculated heat balance of autothermal reformer at each condition to help thermal management of SOFC system.

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