Research progress of carbon deposition resistance of catalyst for dry reforming of methane to hydrogen
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摘要: 现代工业制氢技术中,甲烷重整制氢具有反应物丰富、可利用性高等独特优势,尤其甲烷干重整(Dry Reforming of Methane, DRM)技术,以甲烷和二氧化碳为原料,兼具环境和经济效益,而催化剂积碳是影响DRM技术发展的主要问题之一. 从催化剂活性组分、载体和助剂方面,详细阐述催化剂组分相互作用、活性金属粒径、碱度、储氧能力和积碳类型对DRM催化剂抗积碳性能的影响. 分析发现活性金属和载体的强相互作用、双金属的协同作用以及较小的活性金属颗粒均有助于减少积碳和提高催化剂活性,提高催化剂的储氧能力能促进碳脱除,积碳类型及数量与载体密切相关,载体碱度适中有助于增强CO2的活化,提高催化剂抗积碳能力. 研究结果为甲烷干重整制氢催化剂的设计和优化提供参考.Abstract: Among modern industrial hydrogen production technologies, methane reforming for hydrogen production has unique advantages in rich reactant sources and high availability, especially dry reforming of methane (DRM) technology, which uses methane and carbon dioxide as raw materials and has both environmental and economic benefits. Carbon deposition on catalyst is one of the main problems affecting the development of DRM technology. To design high-performance catalysts, current research mainly focuses on the active components, supports, and promoters. This article discusses in detail the effects of interaction between active components and supports, active metal particle size, basicity, oxygen storage capacity, and carbon deposition type on the carbon deposition resistance of DRM catalysts. The results indicate that strong interactions between active metals and supports, synergistic effects of bimetallic catalysts, and smaller active metal particles can reduce carbon deposition and improve catalyst activity. Increasing oxygen storage capacity can promote carbon removal. The type and amount of carbon deposition are closely related to the support material, and moderate support basicity can promote CO2 activation, thereby improving the carbon deposition resistance of the catalyst. This article provides a reference for the design and optimization of DRM catalysts.
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