Process Simulation and Optimization on Ionic Liquids

Ionic liquids (ILs) are promising alternative compounds that enable the development of technologies based on their unique properties as solvents or catalysts. These technologies require integrated product and process designs to select ILs with optimal process performances at an industrial scale to promote cost-effective and sustainable technologies. The digital era and multiscale research methodologies have changed the paradigm from experiment-oriented to hybrid experimental–computational developments guided by process engineering. This Review summarizes the relevant contributions (>300 research papers) of process simulations to advance IL-based technology developments by guiding experimental research efforts and enhancing industrial transferability. Robust simulation methodologies, mostly based on predictive COSMO-SAC/RS and UNIFAC models in Aspen Plus software, were applied to analyze key IL applications: physical and chemical CO2 capture, CO2 conversion, gas separation, liquid–liquid extraction, extractive distillation, refrigeration cycles, and biorefinery. The contributions concern the IL selection criteria, operational unit design, equipment sizing, technoeconomic and environmental analyses, and process optimization to promote the competitiveness of the proposed IL-based technologies. Process simulation revealed that multiscale research strategies enable advancement in the technological development of IL applications by focusing research efforts to overcome the limitations and exploit the excellent properties of ILs.

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[142]  J. Bedia,et al.  Acetylene absorption by ionic liquids: A multiscale analysis based on molecular and process simulation , 2018, Separation and Purification Technology.

[143]  A. A. Kiss,et al.  Novel pressure and temperature swing processes for CO2 capture using low viscosity ionic liquids , 2018, Separation and Purification Technology.

[144]  Meng Wang,et al.  Ammonia/ionic liquid based double-effect vapor absorption refrigeration cycles driven by waste heat for cooling in fishing vessels , 2018, Energy Conversion and Management.

[145]  J. J. Rodríguez,et al.  From kinetics to equilibrium control in CO2 capture columns using Encapsulated Ionic Liquids (ENILs) , 2018, Chemical Engineering Journal.

[146]  Julián García,et al.  Experimental screening towards developing ionic liquid-based extractive distillation in the dearomatization of refinery streams , 2018, Separation and Purification Technology.

[147]  Yixin Ma,et al.  Ionic liquid-based CO2 capture in power plants for low carbon emissions , 2018, International Journal of Greenhouse Gas Control.

[148]  Zhigang Lei,et al.  CO2 capture by methanol, ionic liquid, and their binary mixtures: Experiments, modeling, and process simulation , 2018 .

[149]  F. Graf,et al.  Characterization of functionalized ionic liquids for a new quasi-isothermal chemical biogas upgrading process , 2018 .

[150]  Julián García,et al.  Novel process to reduce benzene, thiophene, and pyrrole in gasoline based on [4bmpy][TCM] Ionic Liquid , 2018 .

[151]  Zhigang Lei,et al.  Extractive distillation of methylal/methanol mixture using the mixture of dimethylformamide (DMF) and ionic liquid as entrainers , 2018 .

[152]  M. Jobson,et al.  Flowsheet Simulation of Cobalt–Nickel Separation by Solvent Extraction with Trihexyl(tetradecyl)phosphonium Chloride , 2018 .

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[173]  Julián García,et al.  Design of the recovery section of the extracted aromatics in the separation of BTEX from naphtha feed to ethylene crackers using [4empy][Tf2N] and [emim][DCA] mixed ionic liquids as solvent , 2017 .

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