Thermodynamic assessment of the oxidative steam reforming of biomass fast pyrolysis volatiles

[EN] The joint process of pyrolysis-steam reforming is a novel and promising strategy for hydrogen production from biomass; however, it is conditioned by the endothermicity of the reforming reaction and the fast catalyst deactivation. Oxygen addition may potentially overcome these limitations. A the...

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Bibliographic Details
Authors: López Zabalbeitia, Gartzen, García González, Irati, Arregi Joaristi, Aitor, Santamaría Moreno, Laura, Amutio Izaguirre, Maider, Artetxe Uria, Maite, Bilbao Elorriaga, Javier, Olazar Aurrecoechea, Martin
Format: article
Publication Date:2020
Country:España
Institution:Universidad del País Vasco
Repository:Addi. Archivo Digital para la Docencia y la Investigación
OAI Identifier:oai:addi.ehu.eus:10810/46387
Online Access:http://hdl.handle.net/10810/46387
Access Level:Open access
Keyword:hydrogen
bomass
oxidative reforming
thermodynamic study
Gibbs simulation
pyrolysis
oxygenates reforming
Description
Summary:[EN] The joint process of pyrolysis-steam reforming is a novel and promising strategy for hydrogen production from biomass; however, it is conditioned by the endothermicity of the reforming reaction and the fast catalyst deactivation. Oxygen addition may potentially overcome these limitations. A thermodynamic equilibrium approach using Gibbs free energy minimization method has been assumed for the evaluation of suitable conditions for the oxidative steam reforming (OSR) of biomass fast pyrolysis volatiles. The simulation has been carried out contemplating a wide range of reforming operating conditions, i.e., temperature (500–800 °C), steam/biomass (S/B) ratio (0–4) and equivalence ratio (ER) (0–0.2). It is to note that the simulation results under steam reforming (SR) conditions are consistent with those obtained by experiments. Temperatures between 600 and 700 °C, S/B ratios in the 2–3 range and ER values of around 0.12 are the optimum conditions for the OSR under autothermal reforming (ATR) conditions, as they allow attaining high hydrogen yields (10 wt% by mass unit of the biomass in the feed), which are only 12–15% lower than those obtained under SR conditions.