实验室规模的二氧化碳捕集真空变压吸附试验:MIL-160(Al)与沸石 13X

A. Henrotin , N. Heymans , M.E. Duprez , G. Mouchaham , C. Serre , D. Wong , R. Robinson , D. Mulrooney , J. Casaban , G. De Weireld
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引用次数: 0

摘要

碳捕集是到 2050 年将人为二氧化碳排放量迅速减少到净零排放的关键技术之一。在各种分离技术中,吸附技术是最有前途的技术之一。已经开发并测试了几种主要使用沸石 13X 进行二氧化碳捕集的真空和/或变压吸附循环。金属有机框架因其特殊的可调性,可以提高吸附过程的性能。然而,目前还缺乏针对这些材料的中试规模实验结果。为了填补这一空白,我们开发了一种多功能 VPSA 实验室规模的中试装置(3 个 1.1 升的柱子),用于评估吸附剂在各种吸附工艺配置中的二氧化碳捕集能力。在此装置上还研究了以 60 公斤为单位合成和成型的金属有机框架 MIL 160(Al),并将其与沸石 13X 进行了比较,后者采用 3 床 6 步 VPSA 循环,在 0.1 至 2 巴之间分离 15/85%vol 的 CO2/N2 混合物。结果显示,MIL-160(Al) 的纯度为 90%,回收率为 92.7%,而沸石 13X 的纯度仅为 79.7%,回收率为 85%,证明了这种材料在二氧化碳捕获方面的效率。这些结果与传统指标相矛盾,证明了在 VPSA 循环中对材料进行公斤级测试以全面评估其性能的重要性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Lab-scale pilot for CO2 capture vacuum pressure swing adsorption: MIL-160(Al) vs zeolite 13X

Lab-scale pilot for CO2 capture vacuum pressure swing adsorption: MIL-160(Al) vs zeolite 13X

Carbon capture is among the key technologies to quickly reduce anthropogenic CO2 emissions to a net zero emission by 2050. Among the different separation technologies, adsorption is one of the most promising. Several Vacuum and/or Pressure Swing Adsorption cycles have been developed and tested for CO2 capture using mainly zeolite 13X. Metal organic frameworks, due to their exceptional tunability, can improve the performance of adsorption processes. Nevertheless, there is a lack of experimental results for these materials at pilot scale. To address this gap, a versatile VPSA lab-scale pilot (3 columns of 1.1 L) has been developed to evaluate adsorbents at kilogram scale for CO2 capture in various adsorption process configurations. The metal organic framework MIL 160(Al), synthesized and shaped at 60 kg, was also studied on this installation and compared to zeolite 13X with a 3-bed 6-step VPSA cycle for the separation of a 15/85 %vol of CO2/N2 mixture between 0.1 and 2 bar. Results obtained reveal purity of 90 % and recovery of 92.7 % for the MIL-160(Al) while zeolite 13X only reaches 79.7 % of purity and 85 % of recovery, proving the efficiency of this material for CO2 capture. These results contradict conventional indicators and demonstrate the importance of testing a material in VPSA cycle at kg scale to fully assess its performance.

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