Optimizing hydrogen production and efficiency in biomass gasification through advanced CFD modeling

Rafael D. Gomez Vásquez; Jesús D. Rhenals-Julio; Jorge M. Mendoza; Juan Acevedo; Antonio José Bula Silvera

doi:10.1016/j.applthermaleng.2025.126454

Optimizing hydrogen production and efficiency in biomass gasification through advanced CFD modeling

Rafael D. Gomez Vásquez, Jesús D. Rhenals-Julio, Jorge M. Mendoza, Juan Acevedo, Antonio José Bula Silvera

Producción científica: Contribución a una revista › Artículo en revista científica indexada › revisión exhaustiva

Resumen

Gasification is a thermochemical process that converts biomass into biochar, bio-oil, and syngas. This study applies Computational Fluid Dynamics (CFD) to predict Cold Gas Efficiency (CGE) and hydrogen yield (yH₂), integrating a pyrolysis submodel and an average intrinsic reactivity approach for solid–gas reactions to assess the influence of temperature on gas composition and reaction kinetics. A two-dimensional downdraft gasifier model was developed to simulate species transport and reaction mechanisms under four experimental treatments: gasification with air (B), with CaCO₃ as a catalyst (BC), with steam addition (BS), and with both steam and CaCO₃ (BCS). Model validation demonstrated that CFD accurately captured the effects observed experimentally, predicting syngas composition with a global error of 7.71 %. The highest CGE achieved was 61.6 %, and the maximum yH₂ reached 308 ml H₂/g biomass under the BCS condition, where the combination of steam and CaCO₃ enhanced hydrogen production by promoting tar reforming and CO₂ capture. The results confirm that steam and CaCO₃ improve cold gas efficiency and hydrogen yield, aligning with experimental observations. This study highlights CFD as a reliable tool for predicting biomass gasification performance, particularly for hydrogen-rich syngas production.

Idioma original	Inglés
Número de artículo	126454
Publicación	Applied Thermal Engineering
Volumen	272
DOI	https://doi.org/10.1016/j.applthermaleng.2025.126454
Estado	Publicada - 1 ago. 2025

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@article{fd2b4b2019e6460d94f804dcf804aef8,

title = "Optimizing hydrogen production and efficiency in biomass gasification through advanced CFD modeling",

abstract = "Gasification is a thermochemical process that converts biomass into biochar, bio-oil, and syngas. This study applies Computational Fluid Dynamics (CFD) to predict Cold Gas Efficiency (CGE) and hydrogen yield (yH2), integrating a pyrolysis submodel and an average intrinsic reactivity approach for solid–gas reactions to assess the influence of temperature on gas composition and reaction kinetics. A two-dimensional downdraft gasifier model was developed to simulate species transport and reaction mechanisms under four experimental treatments: gasification with air (B), with CaCO3 as a catalyst (BC), with steam addition (BS), and with both steam and CaCO3 (BCS). Model validation demonstrated that CFD accurately captured the effects observed experimentally, predicting syngas composition with a global error of 7.71 %. The highest CGE achieved was 61.6 %, and the maximum yH2 reached 308 ml H2/g biomass under the BCS condition, where the combination of steam and CaCO3 enhanced hydrogen production by promoting tar reforming and CO2 capture. The results confirm that steam and CaCO3 improve cold gas efficiency and hydrogen yield, aligning with experimental observations. This study highlights CFD as a reliable tool for predicting biomass gasification performance, particularly for hydrogen-rich syngas production.",

keywords = "Biomass gasification, Catalysts (CaO), Cold gas efficiency, Computational fluid dynamics (CFD), Hydrogen production",

author = "{Gomez V{\'a}squez}, {Rafael D.} and Rhenals-Julio, {Jes{\'u}s D.} and Mendoza, {Jorge M.} and Juan Acevedo and {Bula Silvera}, {Antonio Jos{\'e}}",

note = "Publisher Copyright: {\textcopyright} 2025 The Author(s)",

year = "2025",

month = aug,

day = "1",

doi = "10.1016/j.applthermaleng.2025.126454",

language = "Ingl{\'e}s",

volume = "272",

journal = "Applied Thermal Engineering",

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TY - JOUR

T1 - Optimizing hydrogen production and efficiency in biomass gasification through advanced CFD modeling

AU - Gomez Vásquez, Rafael D.

AU - Rhenals-Julio, Jesús D.

AU - Mendoza, Jorge M.

AU - Acevedo, Juan

AU - Bula Silvera, Antonio José

PY - 2025/8/1

Y1 - 2025/8/1

N2 - Gasification is a thermochemical process that converts biomass into biochar, bio-oil, and syngas. This study applies Computational Fluid Dynamics (CFD) to predict Cold Gas Efficiency (CGE) and hydrogen yield (yH2), integrating a pyrolysis submodel and an average intrinsic reactivity approach for solid–gas reactions to assess the influence of temperature on gas composition and reaction kinetics. A two-dimensional downdraft gasifier model was developed to simulate species transport and reaction mechanisms under four experimental treatments: gasification with air (B), with CaCO3 as a catalyst (BC), with steam addition (BS), and with both steam and CaCO3 (BCS). Model validation demonstrated that CFD accurately captured the effects observed experimentally, predicting syngas composition with a global error of 7.71 %. The highest CGE achieved was 61.6 %, and the maximum yH2 reached 308 ml H2/g biomass under the BCS condition, where the combination of steam and CaCO3 enhanced hydrogen production by promoting tar reforming and CO2 capture. The results confirm that steam and CaCO3 improve cold gas efficiency and hydrogen yield, aligning with experimental observations. This study highlights CFD as a reliable tool for predicting biomass gasification performance, particularly for hydrogen-rich syngas production.

AB - Gasification is a thermochemical process that converts biomass into biochar, bio-oil, and syngas. This study applies Computational Fluid Dynamics (CFD) to predict Cold Gas Efficiency (CGE) and hydrogen yield (yH2), integrating a pyrolysis submodel and an average intrinsic reactivity approach for solid–gas reactions to assess the influence of temperature on gas composition and reaction kinetics. A two-dimensional downdraft gasifier model was developed to simulate species transport and reaction mechanisms under four experimental treatments: gasification with air (B), with CaCO3 as a catalyst (BC), with steam addition (BS), and with both steam and CaCO3 (BCS). Model validation demonstrated that CFD accurately captured the effects observed experimentally, predicting syngas composition with a global error of 7.71 %. The highest CGE achieved was 61.6 %, and the maximum yH2 reached 308 ml H2/g biomass under the BCS condition, where the combination of steam and CaCO3 enhanced hydrogen production by promoting tar reforming and CO2 capture. The results confirm that steam and CaCO3 improve cold gas efficiency and hydrogen yield, aligning with experimental observations. This study highlights CFD as a reliable tool for predicting biomass gasification performance, particularly for hydrogen-rich syngas production.

KW - Biomass gasification

KW - Catalysts (CaO)

KW - Cold gas efficiency

KW - Computational fluid dynamics (CFD)

KW - Hydrogen production

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U2 - 10.1016/j.applthermaleng.2025.126454

DO - 10.1016/j.applthermaleng.2025.126454

M3 - Artículo en revista científica indexada

AN - SCOPUS:105002374176

SN - 1359-4311

VL - 272

JO - Applied Thermal Engineering

JF - Applied Thermal Engineering

M1 - 126454

ER -

Optimizing hydrogen production and efficiency in biomass gasification through advanced CFD modeling

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