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Hauptverfasser: Amino, Hector, Porcheron, Lynda, Daubech, Jérôme, Ricrot, Emilie, Brisse, Annabelle, Leprette, Emmanuel, Hurisse, Olivier
Format: Preprint
Veröffentlicht: 2026
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Online-Zugang:https://arxiv.org/abs/2601.04970
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author Amino, Hector
Porcheron, Lynda
Daubech, Jérôme
Ricrot, Emilie
Brisse, Annabelle
Leprette, Emmanuel
Hurisse, Olivier
author_facet Amino, Hector
Porcheron, Lynda
Daubech, Jérôme
Ricrot, Emilie
Brisse, Annabelle
Leprette, Emmanuel
Hurisse, Olivier
contents Hydrogen plays an important role in driving decarbonization within the current global energy landscape. As hydrogen infrastructures rapidly expand beyond their traditional applications, there is a need for comprehensive safety practices, solutions, and regulations. Within this framework, the dispersion of hydrogen in enclosed facilities presents a significant safety concern due to its potential for explosive accidents. In this study, hydrogen dispersion in a confined and congested environment (37 m${}^3$ container) is studied using computational fluid dynamics simulations. The experimental setup mirrors previous INERIS investigations, featuring a centrally located hydrogen injection point on the floor with a 20 mm diameter injector and a release rate of 35 g/s, resulting in a Froude number of 650. This yields an inertial jet and a challenging dispersion scenario for numerical prediction. Concentration mapping is carried out by 3 oxygen analyzers distributed throughout the 37 m3 chamber. Comparisons are made between the measured and numerical data to validate the solver used under such conditions. Best practice guidelines are followed, and sensitivity studies involving grid refinement and boundary conditions are conducted to ensure robust simulation results. The findings highlight the model's ability to reproduce the hydrogen concentration distribution for both empty and congested containers and underline the role of accounting for leakages in such scenarios.
format Preprint
id arxiv_https___arxiv_org_abs_2601_04970
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle CFD modeling of hydrogen release and dispersion in a congested container
Amino, Hector
Porcheron, Lynda
Daubech, Jérôme
Ricrot, Emilie
Brisse, Annabelle
Leprette, Emmanuel
Hurisse, Olivier
Classical Physics
Hydrogen plays an important role in driving decarbonization within the current global energy landscape. As hydrogen infrastructures rapidly expand beyond their traditional applications, there is a need for comprehensive safety practices, solutions, and regulations. Within this framework, the dispersion of hydrogen in enclosed facilities presents a significant safety concern due to its potential for explosive accidents. In this study, hydrogen dispersion in a confined and congested environment (37 m${}^3$ container) is studied using computational fluid dynamics simulations. The experimental setup mirrors previous INERIS investigations, featuring a centrally located hydrogen injection point on the floor with a 20 mm diameter injector and a release rate of 35 g/s, resulting in a Froude number of 650. This yields an inertial jet and a challenging dispersion scenario for numerical prediction. Concentration mapping is carried out by 3 oxygen analyzers distributed throughout the 37 m3 chamber. Comparisons are made between the measured and numerical data to validate the solver used under such conditions. Best practice guidelines are followed, and sensitivity studies involving grid refinement and boundary conditions are conducted to ensure robust simulation results. The findings highlight the model's ability to reproduce the hydrogen concentration distribution for both empty and congested containers and underline the role of accounting for leakages in such scenarios.
title CFD modeling of hydrogen release and dispersion in a congested container
topic Classical Physics
url https://arxiv.org/abs/2601.04970