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Modelling Study of Palladium Membrane Reactor Performance during Methan Steam Reforming using CFD Method

  • Kamran Ghasemzadeh EMAIL logo , Ehsan Andalib and Angelo Basile
Published/Copyright: January 8, 2016
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Chemical Product and Process Modeling
From the journal Chemical Product and Process Modeling Volume 11 Issue 1

Abstract

The main aim of this study is the investigation of dense palladium membrane reactor (MR) performance during methane steam reforming (MSR) reaction using computational fluid dynamic (CFD). To this purpose, a two-dimensional isothermal CFD model was developed and its validation was realized by comparing the theoretical results with our experimental data achieved in ITM of Italy. In this work, the CFD model was presented by COMSOL- Multiphysics software version 5. The reaction rate expressions and kinetics parameters were used from literatures. According to validation results, a good agreement between modeling results and experimental data was found. After model validation, the effect of the some important operating parameters (temperature and pressure) on the performance of palladium MR was studied in terms of methane conversion and hydrogen recovery. The CFD model presented velocity and pressure profiles in both side of MR and also molar fraction of different species in permeate and retentate streams. The modeling results showed that the palladium MR presents comparable performance with respect to traditional reactor (TR) in terms of the methane conversion, especially, at lower temperatures and higher pressures. In fact, CFD results indicated that palladium MR performance was improved by increasing the reaction pressure, while this parameter had negative effect on the TR performance. This result related to increasing the hydrogen permeance through the palladium membrane by enhancement of pressure gradient. Indeed, this shift effect can provide a higher methane conversion in lower temperatures in the palladium MR. In particular, 99% methane conversion and 43% hydrogen recovery was achieved at 500°C and 1.5 atm.

Keywords: Membrane process; Pd-based membrane reactor; Modeling; CFD

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Received: 2015-12-2
Accepted: 2015-12-5
Published Online: 2016-1-8
Published in Print: 2016-3-1

©2016 by De Gruyter

Articles in the same Issue

  1. Frontmatter
  2. Editorial Note
  3. Editorial Special Issue: Selected Extended Papers from the 12th International Conference on Membrane Science and Technology (MST2015) Symposium on Modeling and Simulation
  4. Research Articles
  5. Molecular Perspective of Radionuclides Separation by Nanoporous Graphene Oxide Membrane
  6. Mathematical Modeling and Investigation on the Temperature and Pressure Dependency of Permeation and Membrane Separation Performance for Natural gas Treatment
  7. Mathematical Modeling of Natural Gas Separation Using Hollow Fiber Membrane Modules by Application of Finite Element Method through Statistical Analysis
  8. Modelling Study of Palladium Membrane Reactor Performance during Methan Steam Reforming using CFD Method
  9. Performance Investigation of Membrane Process in Natural Gas sweeting by Membrane Process: Modeling Study
  10. Gas Separation in Nanoporous Graphene from Molecular Dynamics Simulation
  11. The Effect of Module Geometry on Heat and Mass Transfer in Membrane Distillation
  12. Experimental Study and Numerical Simulation of the Air Gap Membrane Distillation (AGMD) Process
  13. Multi-objective Optimization of Preparation Conditions of Asymmetric Polyetherimide Membrane for Prevaporation of Isopropanol
  14. Investigation of Palladium Membrane Reactor Performance during Ethanol Steam Reforming using CFD Method
  15. Designing Better Membrane Modules Using CFD
  16. Simulation of Membrane Gas Separation Process Using Aspen Plus® V8.6
  17. Numerical Simulation of Salt Water Passing Mechanism Through Nanoporous Single-Layer Graphene Membrane
  18. Facilitated Transport of Propylene Through Composite Polymer-Ionic Liquid Membranes. Mass Transfer Analysis
  19. CFD Simulation of Hydrogen Separation in Pd Hollow Fiber Membrane
  20. Numerical Study on Concentration Polarization for H2-N2 Separation through a Thin Pd Membrane by Using Computational Fluid Dynamics
https://doi.org/10.1515/cppm-2015-0055
Keywords for this article
Membrane process; Pd-based membrane reactor; Modeling; CFD

Articles in the same Issue

  1. Frontmatter
  2. Editorial Note
  3. Editorial Special Issue: Selected Extended Papers from the 12th International Conference on Membrane Science and Technology (MST2015) Symposium on Modeling and Simulation
  4. Research Articles
  5. Molecular Perspective of Radionuclides Separation by Nanoporous Graphene Oxide Membrane
  6. Mathematical Modeling and Investigation on the Temperature and Pressure Dependency of Permeation and Membrane Separation Performance for Natural gas Treatment
  7. Mathematical Modeling of Natural Gas Separation Using Hollow Fiber Membrane Modules by Application of Finite Element Method through Statistical Analysis
  8. Modelling Study of Palladium Membrane Reactor Performance during Methan Steam Reforming using CFD Method
  9. Performance Investigation of Membrane Process in Natural Gas sweeting by Membrane Process: Modeling Study
  10. Gas Separation in Nanoporous Graphene from Molecular Dynamics Simulation
  11. The Effect of Module Geometry on Heat and Mass Transfer in Membrane Distillation
  12. Experimental Study and Numerical Simulation of the Air Gap Membrane Distillation (AGMD) Process
  13. Multi-objective Optimization of Preparation Conditions of Asymmetric Polyetherimide Membrane for Prevaporation of Isopropanol
  14. Investigation of Palladium Membrane Reactor Performance during Ethanol Steam Reforming using CFD Method
  15. Designing Better Membrane Modules Using CFD
  16. Simulation of Membrane Gas Separation Process Using Aspen Plus® V8.6
  17. Numerical Simulation of Salt Water Passing Mechanism Through Nanoporous Single-Layer Graphene Membrane
  18. Facilitated Transport of Propylene Through Composite Polymer-Ionic Liquid Membranes. Mass Transfer Analysis
  19. CFD Simulation of Hydrogen Separation in Pd Hollow Fiber Membrane
  20. Numerical Study on Concentration Polarization for H2-N2 Separation through a Thin Pd Membrane by Using Computational Fluid Dynamics
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