Atmospheric Turbulent Dispersion Modeling Methods using Machine learning Tools

Atmospheric Turbulent Dispersion Modeling Methods using Machine learning Tools

Assessment of likely consequences of a potential accident is a major concern for loss prevention and safety promotion in process industry. Loss of confinement on a storage tank, vessel or piping on industrial sites could imply atmospheric dispersion of toxic or flammable gases. Gas dispersion foreca...

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Main Authors: P. Lauret, F. Heymes, L. Aprin, A. Johannet, G. Dusserre, E. Lapebie, A. Osmont
Format: Article
Language:English
Published: AIDIC Servizi S.r.l. 2014-04-01
Series:Chemical Engineering Transactions
Online Access:https://www.cetjournal.it/index.php/cet/article/view/5930
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spelling doaj-e940d69991ce4d7e89d5724e79bcbb822021-02-21T21:01:37ZengAIDIC Servizi S.r.l.Chemical Engineering Transactions2283-92162014-04-013610.3303/CET1436087Atmospheric Turbulent Dispersion Modeling Methods using Machine learning ToolsP. LauretF. HeymesL. AprinA. JohannetG. DusserreE. LapebieA. OsmontAssessment of likely consequences of a potential accident is a major concern for loss prevention and safety promotion in process industry. Loss of confinement on a storage tank, vessel or piping on industrial sites could imply atmospheric dispersion of toxic or flammable gases. Gas dispersion forecasting is a difficult task since turbulence modeling at large scale involves expensive calculations. Therefore simpler models are used but remain inaccurate especially when turbulence is heterogeneous. The present work aims to study if Artificial Neural Networks coupled with Cellular Automata could be relevant to overcome these gaps. Two methods are reviewed and compared. An example database was designed from RANS k- e CFD model. Both methods were then applied. Their efficiencies are compared and discussed in terms of quality, real-time applicability and real-life plausibility.https://www.cetjournal.it/index.php/cet/article/view/5930
collection DOAJ
language English
format Article
sources DOAJ
author P. Lauret
F. Heymes
L. Aprin
A. Johannet
G. Dusserre
E. Lapebie
A. Osmont
spellingShingle P. Lauret
F. Heymes
L. Aprin
A. Johannet
G. Dusserre
E. Lapebie
A. Osmont
Atmospheric Turbulent Dispersion Modeling Methods using Machine learning Tools
Chemical Engineering Transactions
author_facet P. Lauret
F. Heymes
L. Aprin
A. Johannet
G. Dusserre
E. Lapebie
A. Osmont
author_sort P. Lauret
title Atmospheric Turbulent Dispersion Modeling Methods using Machine learning Tools
title_short Atmospheric Turbulent Dispersion Modeling Methods using Machine learning Tools
title_full Atmospheric Turbulent Dispersion Modeling Methods using Machine learning Tools
title_fullStr Atmospheric Turbulent Dispersion Modeling Methods using Machine learning Tools
title_full_unstemmed Atmospheric Turbulent Dispersion Modeling Methods using Machine learning Tools
title_sort atmospheric turbulent dispersion modeling methods using machine learning tools
publisher AIDIC Servizi S.r.l.
series Chemical Engineering Transactions
issn 2283-9216
publishDate 2014-04-01
description Assessment of likely consequences of a potential accident is a major concern for loss prevention and safety promotion in process industry. Loss of confinement on a storage tank, vessel or piping on industrial sites could imply atmospheric dispersion of toxic or flammable gases. Gas dispersion forecasting is a difficult task since turbulence modeling at large scale involves expensive calculations. Therefore simpler models are used but remain inaccurate especially when turbulence is heterogeneous. The present work aims to study if Artificial Neural Networks coupled with Cellular Automata could be relevant to overcome these gaps. Two methods are reviewed and compared. An example database was designed from RANS k- e CFD model. Both methods were then applied. Their efficiencies are compared and discussed in terms of quality, real-time applicability and real-life plausibility.
url https://www.cetjournal.it/index.php/cet/article/view/5930
work_keys_str_mv AT plauret atmosphericturbulentdispersionmodelingmethodsusingmachinelearningtools
AT fheymes atmosphericturbulentdispersionmodelingmethodsusingmachinelearningtools
AT laprin atmosphericturbulentdispersionmodelingmethodsusingmachinelearningtools
AT ajohannet atmosphericturbulentdispersionmodelingmethodsusingmachinelearningtools
AT gdusserre atmosphericturbulentdispersionmodelingmethodsusingmachinelearningtools
AT elapebie atmosphericturbulentdispersionmodelingmethodsusingmachinelearningtools
AT aosmont atmosphericturbulentdispersionmodelingmethodsusingmachinelearningtools
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