吸附剂
空气分离
填充床
变压吸附
材料科学
蒸馏
气流
解吸
工艺工程
体积流量
化学工程
分析化学(期刊)
吸附
核工程
化学
色谱法
机械工程
热力学
工程类
有机化学
物理
氧气
作者
Runxia Cai,Henri Dou,Emily Krzystowczyk,Anthony Richard,Fanxing Li
标识
DOI:10.1016/j.cej.2021.132370
摘要
• Chemical looping air separation with a perovskite sorbent in packed beds was studied. • A bench-scale testbed was used to demonstrate the sorbent performance. • A one-dimensional packed bed model matched experimental data well. • Parametric analysis and multi-objective optimization were conducted. • A 5-step configuration consumes as low as 118 kW·h to produce 1 ton of 95% pure O 2. Chemical looping air separation (CLAS) represents a promising approach for efficient O 2 production from the air. The present study aims at optimizing the absorber/desorber operations and the separation process with extensive experimental validation. Specifically, a one-dimensional packed bed model was developed to investigate the CLAS operation with a Sr 0.8 Ca 0.2 Fe 0.9 Co 0.1 O 3-δ perovskite sorbent. The redox thermodynamics of perovskite sorbent was measured by TGA and then incorporated into a linear driving force model to describe the O 2 absorption and desorption rates. Both 4-step and 5-step air separation cycle configurations, with various cyclic structures, were performed in a subpilot-scale packed bed. The model predicted O 2 purity and productivity were consistent with experimental results, supporting its accuracy and applicability. Parametric analysis and multi-objective optimization were further carried out to assess the performance of CLAS. Both O 2 purity and recovery increased monotonically with the cycle time, airflow rate, steam flow rate, and absorption pressure. Meanwhile, optimal O 2 productivity and power consumption can only be achieved by specific combinations of these parameters. The optimized results showed that CLAS can be highly competitive when compared to conventional pressure swing adsorption (PSA) or cryogenic distillation. The 5-step cycle configuration achieved a minimum power consumption of 118 kW·h for producing 1 ton O 2 with ≥ 95% purity. The maximum O 2 productivity reached 0.0932 g O2 /(g sorbent ·h) with 390 kW·h/ton O 2 of energy consumption (95% pure). The optimization results also indicate that CLAS can potentially be more efficient than cryogenic distillation even when the required O 2 purity is above 99%.
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