What question did this study set out to answer?

The aim is to optimize a membrane process for recovering hydrogen from CO2-rich mixtures using various polymer membranes.

March 25, 2026

Beyond Pure-Gas Permeation: Designing an Efficient Two-Stage Membrane Process for Hydrogen Recovery from Reformate Mixtures

Key Points

The aim is to optimize a membrane process for recovering hydrogen from CO2-rich mixtures using various polymer membranes.
Evaluated gas transport properties of several polymer membranes.
Developed a two-stage membrane process with recirculation using Aspen Plus simulation.
Conducted a techno-economic assessment of the hydrogen production process.
PEI membrane showed optimal selectivity of H2/CO2 at 5.07.
Achieved hydrogen purity of 95 mol % with 90% recovery.
Lower hydrogen production cost compared to traditional methods confirmed through economic assessment.

Abstract

This work presents a comprehensive study on hydrogen recovery from a CO2-containing mixture (75/25 mol %) using commercial polymer membranes. The gas transport properties of polyimide (PI), polysulfone (PSF), polyphenylene oxide (PPO), polyetherimide (PEI), and a PEI + PI composite were evaluated. A significant discrepancy was found between single-gas and mixture permeation data, highlighting the necessity of using mixture-based permeance for accurate process design. The PEI membrane demonstrated the optimal combination of H2/CO2 selectivity (5.07) and permeance. An optimized two-stage membrane process with recirculation was developed using Aspen Plus simulation, achieving a hydrogen purity of 95 mol % with 90% recovery. The techno-economic assessment confirmed the process feasibility, demonstrating a lower cost of hydrogen production compared to traditional methods.

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Beyond Pure-Gas Permeation: Designing an Efficient Two-Stage Membrane Process for Hydrogen Recovery from Reformate Mixtures

Key Points

Abstract

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