Design and optimization of the efficient extractive distillation process for separating the binary azeotropic mixture methanol-acetone based on the quantum chemistry and conceptual design

[Display omitted] •A systematic method screening ILs entrainers has been developed.•σ-profiles of widely used five cations and eight anions are first studied.•The selected ILs are further studied by the thermodynamic topological analysis.•Design and optimization of extractive distillation with the I...

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Bibliographic Details
Published in:Separation and purification technology 2020-07, Vol.242, p.116829, Article 116829
Main Authors: Hu, Yanjie, Li, Fuhua, Wei, Shunan, Jin, Saimeng, Shen, Weifeng
Format: Article
Language:English
Subjects:
Entrainer screening
Extractive distillation
Ionic liquids
Quantum chemistry
Residue curve maps
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Summary:[Display omitted] •A systematic method screening ILs entrainers has been developed.•σ-profiles of widely used five cations and eight anions are first studied.•The selected ILs are further studied by the thermodynamic topological analysis.•Design and optimization of extractive distillation with the ILs are conducted. The contribution of this work is proposing a systematic approach to design an efficient extractive distillation (ED) process for separating binary azeotropic mixture, which including the study of σ-profiles, the analysis of thermodynamic topology, and the investigation of economic validation. The separation of methanol-acetone azeotrope serves as the case study to demonstrate the effectiveness of the proposed method. Firstly, the σ-profiles is employed to select appropriate candidates of ILs via the analysis of interaction between five cations and eight anions. Then, the feasibilities of two candidates ILs (i.e., 1-Methylimidazolium acetate ([MIM][OAc]) and 1-methylimidazolium 2-hydroxypropionate ([MIM][Hpr])) and DMSO are further studied by the thermodynamic topological analysis with residue curve maps and univolatility lines. Finally, the design and optimization of ED with the three potential entrainers are conducted to prove the validity of the proposed method. The results demonstrated that the ED process with [MIM][Hpr] is the most economical process compared with [MIM][OAc] and DMSO indicating that the proposed approach is appropriate for screening entrainer to separate such mixture. Moreover, the proposed comprehensive methodology in this work is a valuable protocol, which could be extended to separate other azeotropic systems by using an energy-saving ED process.
ISSN:1383-5866
1873-3794
DOI:10.1016/j.seppur.2020.116829