Sensitivity analysis of heat transfers in an asymmetrically heated turbulent channel flow

A sensitivity analysis of heat transfers in an asymmetrically heated turbulent channel flow is performed using a dedicated heat transfer correlation. The investigated correlation is developed to study the heat transfers between the fluid and the wall in gas-pressurized solar receivers of concentrate...

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Autores principales: David Martin, Toutant Adrien, Bataille Françoise
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FR
Publicado: EDP Sciences 2021
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Acceso en línea:https://doaj.org/article/b07ba7da62e54241858fc5c17189a7b2
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spelling oai:doaj.org-article:b07ba7da62e54241858fc5c17189a7b22021-11-12T11:44:34ZSensitivity analysis of heat transfers in an asymmetrically heated turbulent channel flow2267-124210.1051/e3sconf/202132103001https://doaj.org/article/b07ba7da62e54241858fc5c17189a7b22021-01-01T00:00:00Zhttps://www.e3s-conferences.org/articles/e3sconf/pdf/2021/97/e3sconf_icchmt2021_03001.pdfhttps://doaj.org/toc/2267-1242A sensitivity analysis of heat transfers in an asymmetrically heated turbulent channel flow is performed using a dedicated heat transfer correlation. The investigated correlation is developed to study the heat transfers between the fluid and the wall in gas-pressurized solar receivers of concentrated solar power tower. The working conditions correspond to high-temperature levels and high heat fluxes. The correlation of the Nusselt number depends on five parameters: the Reynolds number, the Prandtl number, the fluid temperature, the hot and cold wall temperatures. We investigate the sensitivity of the heat flux to the wall and fluid temperatures. The results obtained with the global uncertainty management are compared to direct computations of the errors of measurement. In the global uncertainty management, the heat flux sensitivity is studied with the Taylor expansion of the function. This method assumes the quasilinearity and the quasi-normality of the function; therefore, only small variations of parameters are computed. The study points out the importance of the temperature measurement accuracy for the heat flux evaluation in asymmetrically heated turbulent channel flow. In particular, the results show that the cold wall heat flux is very sensitive to the variations of the cold wall temperature and the bulk temperature of the fluid. The hot wall is less influenced by the temperature variations than the cold wall. The global uncertainty management produces satisfying results on the prediction of the error linked to the uncertainties on bulk temperature. Nevertheless, the hot and cold wall temperature uncertainty propagation are poorly estimated by the method.David MartinToutant AdrienBataille FrançoiseEDP SciencesarticleEnvironmental sciencesGE1-350ENFRE3S Web of Conferences, Vol 321, p 03001 (2021)
institution DOAJ
collection DOAJ
language EN
FR
topic Environmental sciences
GE1-350
spellingShingle Environmental sciences
GE1-350
David Martin
Toutant Adrien
Bataille Françoise
Sensitivity analysis of heat transfers in an asymmetrically heated turbulent channel flow
description A sensitivity analysis of heat transfers in an asymmetrically heated turbulent channel flow is performed using a dedicated heat transfer correlation. The investigated correlation is developed to study the heat transfers between the fluid and the wall in gas-pressurized solar receivers of concentrated solar power tower. The working conditions correspond to high-temperature levels and high heat fluxes. The correlation of the Nusselt number depends on five parameters: the Reynolds number, the Prandtl number, the fluid temperature, the hot and cold wall temperatures. We investigate the sensitivity of the heat flux to the wall and fluid temperatures. The results obtained with the global uncertainty management are compared to direct computations of the errors of measurement. In the global uncertainty management, the heat flux sensitivity is studied with the Taylor expansion of the function. This method assumes the quasilinearity and the quasi-normality of the function; therefore, only small variations of parameters are computed. The study points out the importance of the temperature measurement accuracy for the heat flux evaluation in asymmetrically heated turbulent channel flow. In particular, the results show that the cold wall heat flux is very sensitive to the variations of the cold wall temperature and the bulk temperature of the fluid. The hot wall is less influenced by the temperature variations than the cold wall. The global uncertainty management produces satisfying results on the prediction of the error linked to the uncertainties on bulk temperature. Nevertheless, the hot and cold wall temperature uncertainty propagation are poorly estimated by the method.
format article
author David Martin
Toutant Adrien
Bataille Françoise
author_facet David Martin
Toutant Adrien
Bataille Françoise
author_sort David Martin
title Sensitivity analysis of heat transfers in an asymmetrically heated turbulent channel flow
title_short Sensitivity analysis of heat transfers in an asymmetrically heated turbulent channel flow
title_full Sensitivity analysis of heat transfers in an asymmetrically heated turbulent channel flow
title_fullStr Sensitivity analysis of heat transfers in an asymmetrically heated turbulent channel flow
title_full_unstemmed Sensitivity analysis of heat transfers in an asymmetrically heated turbulent channel flow
title_sort sensitivity analysis of heat transfers in an asymmetrically heated turbulent channel flow
publisher EDP Sciences
publishDate 2021
url https://doaj.org/article/b07ba7da62e54241858fc5c17189a7b2
work_keys_str_mv AT davidmartin sensitivityanalysisofheattransfersinanasymmetricallyheatedturbulentchannelflow
AT toutantadrien sensitivityanalysisofheattransfersinanasymmetricallyheatedturbulentchannelflow
AT bataillefrancoise sensitivityanalysisofheattransfersinanasymmetricallyheatedturbulentchannelflow
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