具有热调节门控效应的超微孔氢键有机骨架材料，用于创纪录的丙烯分离。

Ultramicroporous Hydrogen-Bonded Organic Framework Material with a Thermoregulatory Gating Effect for Record Propylene Separation.

机构信息

College of Chemical Engineering and Technology, Shanxi Key Laboratory of Gas Energy Efficient and Clean Utilization, Taiyuan University of Technology, Taiyuan, Shanxi 030024, China.

Fujian Provincial Key Laboratory of Polymer Materials, College of Materials Science and Engineering, Fujian Normal University, Fuzhou, Fujian 350007, China.

出版信息

J Am Chem Soc. 2022 Sep 21;144(37):17033-17040. doi: 10.1021/jacs.2c06585. Epub 2022 Sep 7.

DOI:10.1021/jacs.2c06585

PMID:36069372

Abstract

Propane/propylene separation is one of the most challenging and energy-consuming but most important tasks in the petrochemical industry. Herein, a stable hydrogen-bonded organic framework (HOF-FJU-1) was tailor-made for highly efficient propylene separation from binary CH/CH and even seven component CH/CH/CH/CH/CH/CO/H mixtures. The temperature-controllable diffusion channels in HOF-FJU-1 have enabled the porous material to completely exclude propane to reach high-performance propylene purification under energy-efficient operation conditions. Single-crystal structural analysis revealed that the well-matched pore aperture of HOF-FJU-1 can exactly accommodate propylene molecules via multiple intermolecular interactions, exhibiting a very high propylene/propane selectivity of 616 at 333 K. The propylene purity and productivity are over 99.5% and 30.2 L kg from the binary CH/CH (50/50) mixture at 333 K. Through a follow-up column separation of CH/CH at 353 K, not only high-purity propylene (99.5%) but also ethylene (98.3%) can be readily collected from the seven component CH/CH/CH/CH/CH/CO/H (31/10/25/10/10/1/13) cracking gas mixtures. The great potential of HOF-FJU-1 for the industrial propylene separation process has been further supported by the high stability of this porous material under different environments and straightforward processibility and regeneration feasibility.

摘要

丙烷/丙烯分离是石油化工行业中最具挑战性和能耗最高但也是最重要的任务之一。在此，我们专门设计了一种稳定的氢键有机框架（HOF-FJU-1），用于从二元 CH/CH 混合物甚至是七个组分的 CH/CH/CH/CH/CH/CO/H 混合物中高效分离丙烯。HOF-FJU-1 中温度可控的扩散通道使该多孔材料能够完全排斥丙烷，从而在节能操作条件下实现高性能丙烯纯化。单晶结构分析表明，HOF-FJU-1 的匹配良好的孔径可以通过多种分子间相互作用精确容纳丙烯分子，在 333 K 下表现出非常高的丙烯/丙烷选择性，为 616。从二元 CH/CH（50/50）混合物在 333 K 下，丙烯的纯度和产率超过 99.5%和 30.2 L kg-1。通过在 353 K 下对 CH/CH 进行后续柱分离，不仅可以从七个组分的 CH/CH/CH/CH/CH/CO/H（31/10/25/10/10/1/13）裂解气混合物中轻易地收集到高纯度的丙烯（99.5%），还可以收集到乙烯（98.3%）。该多孔材料在不同环境下的高稳定性、简单的加工性和可重复使用性进一步证明了 HOF-FJU-1 在工业丙烯分离过程中的巨大潜力。

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具有热调节门控效应的超微孔氢键有机骨架材料，用于创纪录的丙烯分离。

Ultramicroporous Hydrogen-Bonded Organic Framework Material with a Thermoregulatory Gating Effect for Record Propylene Separation.

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