Production of high pressure pure H2 by pressure swing sorption enhanced steam reforming (PS-SESR) of byproducts in biorefinery

[Display omitted] •High pressure sorption enhanced steam reforming for H2 production for biorefinery.•Byproducts from the FHP/HDO process are successfully used to obtain H2.•High pressure produces higher H2 purity at temperatures of 600 °C or higher.•H2 purity of 99.0 vol% is obtained at 600 °C and...

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Bibliographic Details
Published in:Applied energy 2018-07, Vol.222, p.595-607
Main Authors: Gil, María V., Rout, Kumar R., Chen, De
Format: Article
Language:English
Subjects:
Bio-oil
Biomass
High-pressure sorption enhanced steam reforming
Hydrogen
Pressure swing decarbonation
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Summary:[Display omitted] •High pressure sorption enhanced steam reforming for H2 production for biorefinery.•Byproducts from the FHP/HDO process are successfully used to obtain H2.•High pressure produces higher H2 purity at temperatures of 600 °C or higher.•H2 purity of 99.0 vol% is obtained at 600 °C and 5 bar, with H2 yield of 92.6%.•A pressure swing process for regeneration of the sorbent is proposed. Hydrogen is highly demanded in biorefinery, and hydrogen production from renewable sources is essential to produce truly green transportation fuels from biomass. The present work demonstrates experimentally the production of high pressure H2 with high purity by pressure swing sorption enhanced steam reforming (PS-SESR) of the byproducts from biorefinery. Pure hydrogen was produced by one-pot high pressure sorption enhanced reforming of a mixture of acetic acid (AA), glycolaldehyde (Gl) and hydroxyacetone (Hy), as model of the byproducts obtained from biomass fast-hydropyrolysis, which is integrated in the H2Bioil process, aimed at producing liquid transportations fuels. SESR was performed using Pd/Ni-Co derived from a hydrotalcite-like material as catalyst and dolomite as CO2 acceptor. Both thermodynamic analysis and experimental study revealed enhanced hydrogen purity but lower hydrogen yield at high pressure compared to atmospheric pressure. Moreover, a compromise between pressure and temperature is needed to get high purity and yield of hydrogen. A H2 purity as high as 99.6 vol% can be obtained at atmospheric pressure and 550 °C, while a H2 purity of 99.0 vol% can be reached at 5 bar and 600 °C. Under these conditions, the H2 yield is of 92.3% at 1 bar and 92.6% at 5 bar. These results show that the SESR of the biomass-derived compounds is an efficient method for the production of highly pure, hot and high pressure hydrogen, which is required for the overall process studied. According to the thermodynamic analysis, and given that the process is performed at high pressure, a pressure swing decarbonation process is suggested for the sorbent regeneration.
ISSN:0306-2619
1872-9118
DOI:10.1016/j.apenergy.2018.03.181