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An Energy-Economic-Environment Tri-Objective Evaluation Method for Gas Membrane Separation Processes of H 2 /CO 2 .

Junjiang BaoShuai LiXiaopeng ZhangNing Zhang
Published in: Membranes (2023)
For pre-combustion carbon capture, the high syngas pressure provides a sufficient mass transfer driving force to make the gas membrane separation process an attractive option. Comparisons of combined different membrane materials (H 2 -selective and CO 2 -selective membranes) and membrane process layouts are very limited. Especially, the multi-objective optimization of such processes requires further investigation. Therefore, this paper proposes 16 two-stage combined membranes system for pre-combustion CO 2 capture, including 4 two-stage H 2 -selective membrane systems, 4 two-stage CO 2 -selective membrane systems, and 8 two-stage hybrid membrane systems. A tri-objective optimization method of energy, economy, and environment is proposed for comprehensive evaluation of the proposed systems. Results show that with the targets of 90% CO 2 purity and recovery, six gas membrane separation systems could be satisfied. After further multi-objective optimization and comparison, the C1H2-4 system (the hybrid system with H 2 -selective membranes and CO 2 -selective membranes) has the best performance. Feed composition and separation requirements also have an important influence on the multi-objective optimization results. The effects of selectivity and permeance of H 2 -selective and CO 2 -selective membranes on the performance of the C1H2-4 system are also significant.
Keyphrases
  • liquid chromatography
  • mass spectrometry