碳化作用
钙环
集中太阳能
材料科学
储能
化学工程
氧化钙
针状的
烧结
太阳能
工艺工程
化学
煅烧
催化作用
冶金
复合材料
有机化学
功率(物理)
工程类
物理
微观结构
生物
量子力学
生态学
作者
Pedro E. Sánchez‐Jiménez,Antonio Perejón,Mónica Benítez‐Guerrero,José Manuel Valverde,C. Ortiz,Luis A. Pérez‐Maqueda
出处
期刊:Applied Energy
[Elsevier]
日期:2018-11-10
卷期号:235: 543-552
被引量:136
标识
DOI:10.1016/j.apenergy.2018.10.131
摘要
High energy density, cycling stability, low cost and scalability are the main features required for thermochemical energy storage systems to achieve a feasible integration in Concentrating Solar Power plants (CSP). While no system has been found to fully satisfy all these requirements, the reversible CaO/CaCO3 carbonation reaction (CaL) is one of the most promising since CaO natural precursors are affordable and earth-abundant. However, CaO particles progressively deactivate due to sintering-induced morphological changes during repeated carbonation and calcinations cycles. In this work, we have prepared acicular calcium and magnesium acetate precursors using a simple, cost-effective and easily scalable technique that requires just the natural minerals and acetic acid, thereby avoiding expensive reactants and environmentally unfriendly solvents. Upon thermal decomposition, these precursors yield a stable porous structure comprised of well dispersed MgO nanoparticles coating the CaO/CaCO3 grains that is resistant to pore-plugging and sintering while at the same time exhibits high long term effective conversion. Process simulations show that the employment of these materials could significantly improve the overall CSP-CaL efficiency at the industrial level.
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