Oxygen transport membrane technology, under development at Eltron Research Inc., facilitates the exclusive mediation of oxygen from the atmosphere to a desired reaction site. As a consequence, these membranes can be incorporated into Catalytic Membrane Reactors (CMRs) where exothermic hydrocarbon partial oxidation chemistries can proceed while at the same time eliminating the need for a separate oxygen plant - a significant reduction in overall production costs compared to currently available technology. An additional feature is that in such chemical processing NO_x emissions are eliminated since N_2 in the air is separated from O_2 via the membrane. In particular, the above technology can be used for the spontaneous reforming of, respectively, natural gas, biomass, and coal into synthesis gas, an equilibrium mixture of hydrogen and carbon monoxide. Application of water-gas shift chemistry leads to an increase in hydrogen fraction. We are also developing low cost hydrogen transport membranes compatible with the efficient separation of hydrogen from hydrogen containing feedstreams discussed above. Hydrogen separation rates have been found approximately an order of magnitude higher than for palladium membranes. Hence by employing these two membrane technologies in concert, a low energy pathway for the decarbonization of gas fed feedstocks to supply a pure hydrogen feedstream in support of the future hydrogen economy may exist. The by-product concentrated carbon dioxide feedstream would provide the opportunity for subsequent convenient sequestration.
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机译:在Eltron Research Inc的开发下,氧气运输膜技术有助于将氧的独家调解从大气中的氧气中的含量分配到所需的反应部位。因此,这些膜可以掺入催化膜反应器(CMR)中,其中可以进行放热的烃部分氧化化学品,同时消除对单独的氧气植物的需要 - 与目前可用技术相比,整体生产成本显着降低。另外的特征是在这种化学处理中,由于空气中的N_2通过膜与O_2分离出来,因此消除了NO_X排放。特别地,上述技术可用于分别,分别,天然气,生物质和煤的自发重整为合成气,氢气和一氧化碳的平衡混合物。水 - 气体移位化学的应用导致氢馏分的增加。我们还在开发低成本的氢气转运膜,与上面讨论的含氢的氢气进料流的有效分离相容。已经发现氢分离率大约比钯膜高的数量级。因此,通过在音乐会中采用这两个膜技术,存在用于供应未来氢气经济的烃进料器的脱碳的低能量通路以供应纯氢气进料流。副产品浓缩二氧化碳进料流将为随后的方便螯合提供机会。
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