流化床与固定床中甲烷裂解制氢过程的比较被引量：3

Comparison of fluidized and fixed bed operations for hydrogen production from methane decomposition

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摘要 The effect of reaction modes,i.e.fluidized bed and fixed bed operations,on catalyst life for hydrogen production from methane decomposition was investigated over a 75Ni15Cu10Al catalyst and a 2Co1Al catalyst.Pure methane was used as the feed.The results showed that the apparent reaction rate in the fluidized bed was much higher than that in the fixed bed,indicating that in the fixed bed the reaction was transport-controlled.The carbon formed was characterized with TEM technique,and the results showed that the size of metal particles increased with rising reaction temperature,and at the same reaction temperature the size of metal particles on the catalyst in the fixed bed was larger than that on the catalyst in the fluidized bed,signifying that fluidized bed reactor is beneficial to preventing the sintering of active metals. The effect of reaction modes, i. e. fluidized bed and fixed bed operations, on catalyst life for hydrogen production from methane decomposition was investigated over a 75NilSCu10Al catalyst and a 2ColAl catalyst. Pure methane was used as the feed. The results showed that the apparent reaction rate in the fluidized bed was much higher than that in the fixed bed, indicating that in the fixed bed the reaction was transport-controlled. The carbon formed was characterized with TEM technique, and the results showed that the size of metal particles increased with rising reaction temperature, and at the same reaction temperature the size of metal particles on the catalyst in the fixed bed was larger than that on the catalyst in the fluidized bed, signifying that fluidized bed reactor is beneficial to preventing the sintering of active metals.

作者刘少文李永丹

机构地区天津市应用催化科学与工程重点实验室天津大学化工学院

出处《化工学报》 EI CAS CSCD 北大核心 2007年第1期102-107,共6页 CIESC Journal

基金国家自然科学基金项目(20425619)~~

关键词甲烷裂解制氢反应器流态化碳生长 methane decomposition hydrogen production reactor fluidization carbon growth

分类号 TQ032.4 [化学工程]

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参考文献21

1Armor J N.The multiple roles for catalysis in the production of H2.Appl.Catal.A:Gen.,1999,176(2):159-176
2Appleby A J,Foulkes F R.Fuel Cell Handbook.New York:Nostrand Reinhold(Van),1989
3Zhang T,Amiridis M D.Hydrogen production via the direct cracking of methane over silica-supported nickel catalysts.Appl.Catal.A:Gen.,1998,167(2):161-172
4Choudhary T V,Goodman D W.CO-free production of hydrogen via stepwise steam reforming of methane.J.Catal.,2000,192(2):316-321
5Choudhary V R,Banerjee S,Rajput A M.Continuous production of H2 at low temperature from methane decomposition over Ni-containing catalyst followed by gasification by steam of the carbon on the catalyst in two parallel reactors operated in cyclic manner.J.Catal.,2001,198(1):136-141
6Avdeeva L B,Kochubey D I,Shaikhutdinov Sh K.Cobalt catalysts of methane decomposition:accumulation of the filamentous carbon.Appl.Catal.A:Gen.,1999,177(1):43-51
7Steinberg M,Cheng H C.Modern and prospective technologies for hydrogen production from fossil fuels.Int.J.Hydrogen Energy,1989,14(11):797-820
8Muradov N Z.How to produce hydrogen from fossil fuels without CO2 emission.Int.J.Hydrogen Energy,1993,18(3):211-215
9Tibbetts G,Meisner G P,Olk Ch H.Hydrogen storage capacity of carbon nanotubes,filaments,and vapor-grown fibers.Carbon,2001,39(15):2291-2301
10Alstrup I.A new model explaining carbon filament growth on nickel,iron,and Ni-Cu alloy catalysts.J.Catal.,1988,109(2):241-251

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流化床与固定床中甲烷裂解制氢过程的比较被引量：3

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流化床与固定床中甲烷裂解制氢过程的比较被引量：3