Abstract

This work shows the application of a validated mathematical model for gas permeation at high temperatures focusing on demonstrated scale-up design for H2 processing. The model considered the driving force variation with spatial coordinates and the mass transfer across the molecular sieve cobalt oxide silica membrane to predict the separation performance. The model was used to study the process of H2 separation at 500 °C in single and multi-tube membrane modules. Parameters of interest included the H2 purity in the permeate stream, H2 recovery and H2 yield as a function of the membrane length, number of tubes in a membrane module, space velocity and H2 feed molar fraction. For a single tubular membrane, increasing the length of a membrane tube led to higher H2 yield and H2 recovery, owing to the increase of the membrane area. However, the H2 purity decreased as H2 fraction was depleted, thus reducing the driving force for H2 permeation. By keeping the membrane length constant in a multi-tube arrangement, the H2 yield and H2 recovery increase was attributed to the higher membrane area, but the H2 purity was again compromised. Increasing the space velocity avoided the reduction of H2 purity and still delivered higher H2 yield and H2 recovery than in a single membrane arrangement. Essentially, if the membrane surface is too large, the driving force becomes lower at the expense of H2 purity. In this case, the membrane module is over designed. Hence, maintaining a driving force is of utmost importance to deliver the functionality of process separation.

Highlights

  • Global climate change is closely associated with energy production, CO2 emissions from power generation and transportation using fossil fuels

  • The simulation shows that by increasing the membrane length, it benefited H2 yield and H2 recovery, though it was detrimental to H2 purity

  • This study presents a model to simulate the membrane separation performance in a scale-up single and multi-tube membrane module arrangement

Read more

Summary

Introduction

Global climate change is closely associated with energy production, CO2 emissions from power generation and transportation using fossil fuels. Conventional industrial processes for gas separation include amine absorption strippers and pressure swing adsorption These processes are energy intensive, because the gases produced at high temperatures (>800 °C) needed to be cooled down to meet the temperature requirements for these technologies in order to operate effectively at lower temperatures (

The Mathematical Modelling Details
Mass Transfer in Gas Phase
Mass Transfer across Membrane
Experiment and Model Validation
Numerical Technique
Process Parameters of Interest
Effect of Membrane Length on Process Performance
Effect of Multi-Tube Membranes on Process Performance
Effect of Space Velocity on Process Performance
Effect of H2 Feed Molar Fraction on Process Performance
Conclusions

Talk to us

Join us for a 30 min session where you can share your feedback and ask us any queries you have

Schedule a call

Disclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.