• Title/Summary/Keyword: Catalytic Combustion of Methane

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Catalytic Combustion of Methane over Perovskite-Type Oxides

  • Hong, Seong-Soo;Sun, Chang-Bong;Lee, Gun-Dae;Ju, Chang-Sik;Lee, Min-Gyu
    • Environmental Sciences Bulletin of The Korean Environmental Sciences Society
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    • v.4 no.2
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    • pp.95-102
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    • 2000
  • Methane combustion over perovskite-type oxides prepared using the malic acid method was investigated. To enhance the catalytic activity, the perovskite oxides were modified by the substitution of metal into their A or B site. In addition, the reaction conditions, such as the temperature, space velocity, and partial pressure of the methane were varied to understand their effect on the catalytic performance. With the LaCoO3-type catalyst, the partial substitution of Sr or Ba into site A enhanced the catalytic activity in the methane combustion. With the LaBO3(B=Co, Fe, Mn, Cu)-type catalyst, the catalytic activities were exhibited in the order of Co>Fe Mn>Cu. Futhermore, the partial substitution of Co into site B enhanced the catalytic activity, whereas an excess amount of Co decreased the activity. The surface area and catalytic activity of the perovskite catalysts prepared using the malic acid method showed higher values than those prepared using the solid reaction method. The catalytic activity was enhanced with decreased methane concentration and with a decrease in the space velocity.

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Catalytic Activity of Commercial Metal Catalysts on the Combustion of Low-concentration Methane (저농도 메탄 연소에서 상용 금속촉매의 활성)

  • Lee Kyong-Hwan;Park Jae-Hyun;Song Kwang-Sup
    • Journal of Korean Society for Atmospheric Environment
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    • v.21 no.6
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    • pp.625-630
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    • 2005
  • This study was focused on the catalytic activity for the combustion of low-concentration methane using various commerical catalysts (six transition metal catalysts in Russia and one rare earth metal (Honeycomb) catalyst in Korea). Catalytic activity was strongly influenced by the type and loading content of metal supported in catalyst. Catalytic performance showed the highest activity in Honeycomb catalyst including rare earth metal, which was the most expensive catalyst, while the next was the catalyst supported Cu with high content (AOK-78-52) and also that supported Cr and Co (AOK-78-56). However, both AOK-78-52 and AOK-78-56 catalysts that were very cheap had lower activation energy than Honeycomb catalyst. In the economical field, both AOK-78-52 and AOK-78-56 catalysts with transition metals showed a good alternative catalyst on the combustion of methane.

Numerical Study on the Application of High Temperature Catalytic Combustion to a Gas Turbine (고온촉매연소의 가스터빈 적용에 관한 수치적 연구)

  • Kim, Hyung-Man;Jeun, Ho-Sig;Jang, Seok-Yong
    • Proceedings of the KSME Conference
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    • 2001.06d
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    • pp.989-994
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    • 2001
  • Numerical simulations of high temperature catalytic combustion have been performed for the application to a gas turbine combustor. Dependences of inlet temperature and pressure on the distributions of temperature and species concentrations were investigated using plug flow model with detailed homogeneous and heterogeneous chemistries of methane-air mixtures. Honeycomb typecombustor deposited with Pt catalyst of 100mm in length and 26mm in diameter is used. The results show that rapid increase of temperature profile occurs earlier with the increase of inlet temperature and the decrease of inlet pressure. The condition which catalytic combustion is stabilized exists at certain range of inlet temperature and pressure. The state of catalytic combustion is also confirmed by the distributions of species concentration.

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Numerical Studies on Combustion Characteristics of a Hybrid Catalytic Combustor (하이브리드 촉매 연소기의 연소특성에 관한 수치적 연구)

  • Hwang, Chul-Hong;Jeong, Young-Sik;Lee, Chang-Eon
    • Proceedings of the KSME Conference
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    • 2000.11b
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    • pp.328-334
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    • 2000
  • The hybrid catalytic(catalytic+thermal) combustor of a lean methane-air mixture on platinum catalyst was investigated numerically using a 2-D boundary layer model with detailed homogeneous and heterogeneous chemistries. For the more accurate calculations, the actual surface site density of monolith coated with platinum was decided by the comparison with experimental data. It was found that the homogeneous reactions in the monolith had little effect on the change of temperature profile, methane conversion rate and light off location. However, the radicals such as OH and CO were produced rapidly at exit by homogeneous reactions. Thus the homogeneous reactions were important to predict the productions of CO and NOx exactly. In thermal combustor, the production of $N_2O$ was more dominant than that of NO due to the relative important of the reaction $N_2+O(+M){\to}N_2O(+M)$. Finally the production of CO and NOx by amount of methane addition were studied.

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Numerical Studies on Combustion Characteristics of a Hybrid Catalytic Combustor (하이브리드 촉매 연소기의 연소특성에 관한 수치적 연구)

  • Hwang, Cheol-Hong;Jeong, Yeong-Sik;Lee, Chang-Eon
    • Transactions of the Korean Society of Mechanical Engineers B
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    • v.25 no.4
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    • pp.583-592
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    • 2001
  • The combustion characteristics of the hybrid catalytic(catalytic+thermal) combustor with a lean methane-air mixture on platinum catalyst were investigated numerically using a 2-D boundary layer model with detailed homogeneous and heterogeneous chemistries. for the more accurate calculations, the actual surface site density of monolith coated with platinum was decided by the comparison with experimental data. It was found that the homogeneous reactions in the monolith had little effect on the change of temperature profile, methane conversion rate and light off location. However, the radicals such as OH and CO were produced rapidly at exit by homogeneous reactions. The effect of operation conditions such as equivalence ratio, temperature, velocity, pressure and diameter of the monolith channel at the entrance were studied. In thermal combustor, the production of N$_2$O was more dominant than that of NO due to the relative importance of the reaction N$_2$+O(+M)→N$_2$O(+M). Finally the productions of CO and NOx by amount of methane addition were studied.

Effects of Catalytic Reaction and Natural Convection on the Hot Surface Ignition of Methane-Air Mixtures (메탄-공기 예혼합기의 열면점화에 미치는 촉매반응 및 자연대류의 영향)

  • Kim, H.M.;Jurng, J.S.
    • Journal of the Korean Society of Combustion
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    • v.2 no.1
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    • pp.29-38
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    • 1997
  • In this study, the experimental and numerical investigations of the ignition of methane-air mixtures by a electrically heated wire have been carried out. In order to define the initial condition and make the analysis simple, the following control unit was developed; which heats the wire to the setting temperature in a very short time, and maintains the wire temperature constant until ignition. Experiments with the feedback control have been performed using nickel and platinum wires in normal gravity and microgravity. From experimental results, ignition temperatures in normal gravity are higher than those in microgravity, however, the dependences of ignition temperature on equivalence ratio are not affected by natural convection. Numerical calculations, including catalytic reaction for platinum, have been performed to analyze the experimental results in microgravity. Numerical results show that reactants near platinum wire are consumed by catalytic reaction, therefore, the higher temperature is needed to ignite the mixture with platinum wire.

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Effect of Bimetallic Pt-Rh and Trimetallic Pt-Pd-Rh Catalysts for Low Temperature Catalytic Combustion of Methane

  • Bhagiyalakshmi, Margandan;Anuradha, Ramani;Park, Sang-Do;Park, Tae-Sung;Cha, Wang-Seog;Jang, Hyun-Tae
    • Bulletin of the Korean Chemical Society
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    • v.31 no.1
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    • pp.120-124
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    • 2010
  • Monometallic, bimetallic and trimetallic particles consisting of different weight compositions of Pt-Pd-Rh over pure alumina wash coats have been synthesized and their catalytic performance on methane conversion was studied from 150 to $600^{\circ}C$. Different catalyst formulations with variable Pt, Pd and Rh contents for bimetallic and trimetallic systems were tried and $Pt_{(1.5)}Rh_{(0.3)}/Al_2O_3$ and $Pt_{(1.0)}Pd_{(1.0)}Rh_{(0.3)}/Al_2O_3$ shows low $T_{50}$ and $T_{90}$ temperatures. Bimetallic and trimetallic particle synergism acts as three way catalysts and therefore, all the catalysts show 100% methane conversion. The effect of supports such as $ZrO_2$ and $TiO_2$ on methane combustion was investigated; from $T_{50}$ and $T_{90}$ results both $Al_2O_3$ and $ZrO_2$ are suitable supports for low temperature methane combustion.

Catalytic Activity Change of Perovskite Catalysts with A-Site Substitution (페로브스카이트 촉매에서 A-Site 치환에 따른 촉매활성 변화)

  • Hahm, Hyun-Sik;Kim, Kyu-Sung;Ahn, Sung-Hwan;Shin, Ki-Seok;Kim, Song-Hyoung;Park, Hong-Soo
    • Journal of the Korean Applied Science and Technology
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    • v.24 no.3
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    • pp.272-277
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    • 2007
  • Catalytic activity changes of perovskite catalysts were examined with their A-site substitution. For the preparation of catalysts, Mn was used for B-site component and La, Ce, Sr, Ba, Ca, Ag were used for A-site component of the perovskite $catalysts(ABO_3)$ The effect of calcination temperature on methane combustion and perovskite structure was also investigated. The surface area and adsorbed oxygen species were tested with BET apparatus and $O_2-TPD$, respectively. Perovskite catalysts whose A-site was partially substituted needed higher calcination temperature than un-substituted one to form the perovskite structure. From $O_2-TPD$ experiment, it was found that methane combustion activity was directly related to the oxygen desorbing ability of the catalysts. The prepared catalyst(LM-7) was stable at $600^{\circ}C$ for 72 hours of reaction.

Performance Analysis of Off-Gas/Syngas Combustor for Thermal Management of High Temperature Fuel Cell System (고온형 연료전지 열관리를 위한 배기가스 연소기 성능시험)

  • Lee, Sang-Min;Lee, Youn-Hwa;Ahn, Kook-Young;Yu, Sang-Seok
    • Journal of Hydrogen and New Energy
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    • v.21 no.3
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    • pp.193-200
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    • 2010
  • Anode off-gas of high temperature fuel cell still contains combustible components such as hydrogen, carbon monoxide and hydrocarbon. In this study, a catalytic combustor has been applied to the high temperature fuel cell so that the combustion of anode-off gas can be boosted up. Since the performance of catalytic combustor directly depends on the combustion catalyst, this study is designed to perform the experimental investigation on the combustion characteristics of the three commercial catalysts with a different composition. Screening tests with three catalysts are preceded before the performance examination since it is necessary to determine the most suitable catalyst for design configuration of the catalytic combustor. The performance analysis shows that methane conversion rate strongly depends on gas hourly space velocity (GHSV) as well as inlet gas temperature. Additionally, the GSHV optimization results show that the optimum GHSV will be in the range between 18,000 $hr^{-1}$ and 36,000 $hr^{-1}$. It is also shown that the minimum inlet temperature of catalytic reaction of methane is from $100^{\circ}C$ to $150^{\circ}C$.

An Experimental Study on the Reaction Characteristics of Anode offgas Catalytic Combustor for 25kW MCFC Systems (25 kW급 MCFC 배가스 촉매연소기의 실험적 연소특성)

  • Lee, Sang Min;Woo, Hyuntack;Ahn, Kook Young
    • 한국신재생에너지학회:학술대회논문집
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    • 2011.11a
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    • pp.92.1-92.1
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    • 2011
  • Anode off-gas of high temperature fuel cells such as MCFC contains a significant amount of combustible components like hydrogen, carbon monoxide and methane according to fuel utilization ratio of the fuel cell stack. Thus, it is important to fully burn anode off-gas and utilize the generated heat in order to increase system efficiency and reduce emissions as well. In the present study, 25 kW catalytic combustor has been developed for the application to a load-following 300kW MCFC system. Mixing and combustion characteristics have been experimentally investigated with the catalytic combustor. Since the performance of catalytic combustor directly depends on the combustion catalyst, this study has been focused on the experimental investigation on the combustion characteristics of multiple catalysts having different structures and compositions. Results show that the exhaust emissions are highly dependent on the catalyst loading and the ratio of catalytic components. Test results at load-following conditions are also shown in the present study.

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