Pure hydrogen production in a membrane reformer: Demonstration, macro-scale and atomic scale modeling

TY - JOUR

T1 - Pure hydrogen production in a membrane reformer

T2 - Demonstration, macro-scale and atomic scale modeling

AU - Sheintuch, Moshe

N1 - Publisher Copyright: © 2014 Elsevier B.V. All rights reserved.

PY - 2015/7/28

Y1 - 2015/7/28

N2 - We discuss various designs for scaled down membrane steam reformer for generating pure hydrogen onboard or in a hydrogen fuel station, motivated by the expectation of using hydrogen as an energy carrier, mainly to power the energy efficient and environmentally friendly Proton Exchange Membrane Fuel Cells (PEMFC). Pure H2 separation is achieved by Pd or Pd/Ag membranes. A novel concept for hydrogen generation by auto-thermal methane steam reforming (MSR) was experimentally demonstrated by our group. The reactor, built from three concentric compartments, indirectly couples the endothermic methane steam reforming (catalyzed by Ni/Al2O3) with the exothermic methane oxidation, while hydrogen is separated by a permselective Pd/Ag membrane. The MSR conversion is mainly determined by the membrane hydrogen flux. The system is optimized using an appropriate model, validated with experimental data using parameters from literature. The optimized reformer, is predicted to achieve a methane-to-hydrogen conversion efficiency of up to 0.8. In a second concept, solar energy circulated by means of molten salts is used to heat the membrane reformer in a hydrogen fuel station. Laboratory scaled membrane reformer, packed with a foam washcoated with Ni-Pt catalyst and heated externally, demonstrated the concept feasibility. Modeling this reactor suggests about 80% reduction in permeance, compared to a value measured in pure hydrogen. We describe 1-D mathematical model that were successfully used to predict the experimental results and ask whether 2-D models are necessary. By deriving an appropriate criteria we show that concentration polarization cannot account for the large observed permeance inhibition. To understand this phenomenon we resort to DFT-calculated adsorption energies to estimate the inhibition due to surface adsorption of possible co-adsorbates like methane, CO and water. While CO adsorption is strong, CO concentration is small, and this effect is too small to account for observations, suggesting that surface reaction on the Pd membrane should be considered to estimate coverages by C, O and other intermediates.

AB - We discuss various designs for scaled down membrane steam reformer for generating pure hydrogen onboard or in a hydrogen fuel station, motivated by the expectation of using hydrogen as an energy carrier, mainly to power the energy efficient and environmentally friendly Proton Exchange Membrane Fuel Cells (PEMFC). Pure H2 separation is achieved by Pd or Pd/Ag membranes. A novel concept for hydrogen generation by auto-thermal methane steam reforming (MSR) was experimentally demonstrated by our group. The reactor, built from three concentric compartments, indirectly couples the endothermic methane steam reforming (catalyzed by Ni/Al2O3) with the exothermic methane oxidation, while hydrogen is separated by a permselective Pd/Ag membrane. The MSR conversion is mainly determined by the membrane hydrogen flux. The system is optimized using an appropriate model, validated with experimental data using parameters from literature. The optimized reformer, is predicted to achieve a methane-to-hydrogen conversion efficiency of up to 0.8. In a second concept, solar energy circulated by means of molten salts is used to heat the membrane reformer in a hydrogen fuel station. Laboratory scaled membrane reformer, packed with a foam washcoated with Ni-Pt catalyst and heated externally, demonstrated the concept feasibility. Modeling this reactor suggests about 80% reduction in permeance, compared to a value measured in pure hydrogen. We describe 1-D mathematical model that were successfully used to predict the experimental results and ask whether 2-D models are necessary. By deriving an appropriate criteria we show that concentration polarization cannot account for the large observed permeance inhibition. To understand this phenomenon we resort to DFT-calculated adsorption energies to estimate the inhibition due to surface adsorption of possible co-adsorbates like methane, CO and water. While CO adsorption is strong, CO concentration is small, and this effect is too small to account for observations, suggesting that surface reaction on the Pd membrane should be considered to estimate coverages by C, O and other intermediates.

KW - Autothermal reformer

KW - Fuel cells

KW - Hydrogen

KW - Membrane reactor

KW - Methane steam reforming

KW - Model-based optimization

UR - http://www.scopus.com/inward/record.url?scp=84939794266&partnerID=8YFLogxK

U2 - 10.1016/j.cej.2014.11.100

DO - 10.1016/j.cej.2014.11.100

M3 - 文章

AN - SCOPUS:84939794266

SN - 1385-8947

VL - 278

SP - 363

EP - 373

JO - Chemical Engineering Journal

JF - Chemical Engineering Journal

ER -