Prediction of velocity profile of water based copper nanofluid in a heated porous tube using CFD and genetic algorithm

Prediction of velocity profile of water based copper nanofluid in a heated porous tube using CFD and genetic algorithm

Abstract The heat transfer improvements by simultaneous usage of the nanofluids and metallic porous foams are still an attractive research area. The Computational fluid dynamics (CFD) methods are widely used for thermal and hydrodynamic investigations of the nanofluids flow inside the porous media....

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Main Authors: Tiziana Ciano, Massimiliano Ferrara, Meisam Babanezhad, Afrasyab Khan, Azam Marjani
Format: Article
Language:English
Published: Nature Publishing Group 2021-05-01
Series:Scientific Reports
Online Access:https://doi.org/10.1038/s41598-021-90201-x
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spelling doaj-64e7da7f2de447f4b2337f1bda2bca3e2021-05-23T11:33:31ZengNature Publishing GroupScientific Reports2045-23222021-05-0111111210.1038/s41598-021-90201-xPrediction of velocity profile of water based copper nanofluid in a heated porous tube using CFD and genetic algorithmTiziana Ciano0Massimiliano Ferrara1Meisam Babanezhad2Afrasyab Khan3Azam Marjani4Department of Law, Economics and Human Sciences & Decisions Lab, Mediterranea University of Reggio CalabriaDepartment of Law, Economics and Human Sciences & Decisions Lab, Mediterranea University of Reggio CalabriaInstitute of Research and Development, Duy Tan UniversityInstitute of Engineering and Technology, Department of Hydraulics and Hydraulic and Pneumatic Systems, South Ural State UniversityDepartment of Chemistry, Islamic Azad UniversityAbstract The heat transfer improvements by simultaneous usage of the nanofluids and metallic porous foams are still an attractive research area. The Computational fluid dynamics (CFD) methods are widely used for thermal and hydrodynamic investigations of the nanofluids flow inside the porous media. Almost all studies dedicated to the accurate prediction of the CFD approach. However, there are not sufficient investigations on the CFD approach optimization. The mesh increment in the CFD approach is one of the challenging concepts especially in turbulent flows and complex geometries. This study, for the first time, introduces a type of artificial intelligence algorithm (AIA) as a supplementary tool for helping the CFD. According to the idea of this study, the CFD simulation is done for a case with low mesh density. The artificial intelligence algorithm uses learns the CFD driven data. After the intelligence achievement, the AIA could predict the fluid parameters for the infinite number of nodes or dense mesh without any limitations. So, there is no need to solve the CFD models for further nodes. This study is specifically focused on the genetic algorithm-based fuzzy inference system (GAFIS) to predict the velocity profile of the water-based copper nanofluid turbulent flow in a porous tube. The most intelligent GAFIS could perform the most accurate prediction of the velocity. Hence, the intelligence of GAFIS is tested for different values of cluster influence range (CIR), squash factor(SF), accept ratio (AR) and reject ratio (RR), the population size (PS), and the percentage of crossover (PC). The maximum coefficient of determination (~ 0.97) was related to the PS of 30, the AR of 0.6, the PC of 0.4, CIR of 0.15, the SF 1.15, and the RR of 0.05. The GAFIS prediction of the fluid velocity was in great agreement with the CFD. In the most intelligent condition, the velocity profile predicted by GAFIS was similar to the CFD. The nodes increment from 537 to 7671 was made by the GAFIS. The new predictions of the GAFIS covered all CFD results.https://doi.org/10.1038/s41598-021-90201-x
collection DOAJ
language English
format Article
sources DOAJ
author Tiziana Ciano
Massimiliano Ferrara
Meisam Babanezhad
Afrasyab Khan
Azam Marjani
spellingShingle Tiziana Ciano
Massimiliano Ferrara
Meisam Babanezhad
Afrasyab Khan
Azam Marjani
Prediction of velocity profile of water based copper nanofluid in a heated porous tube using CFD and genetic algorithm
Scientific Reports
author_facet Tiziana Ciano
Massimiliano Ferrara
Meisam Babanezhad
Afrasyab Khan
Azam Marjani
author_sort Tiziana Ciano
title Prediction of velocity profile of water based copper nanofluid in a heated porous tube using CFD and genetic algorithm
title_short Prediction of velocity profile of water based copper nanofluid in a heated porous tube using CFD and genetic algorithm
title_full Prediction of velocity profile of water based copper nanofluid in a heated porous tube using CFD and genetic algorithm
title_fullStr Prediction of velocity profile of water based copper nanofluid in a heated porous tube using CFD and genetic algorithm
title_full_unstemmed Prediction of velocity profile of water based copper nanofluid in a heated porous tube using CFD and genetic algorithm
title_sort prediction of velocity profile of water based copper nanofluid in a heated porous tube using cfd and genetic algorithm
publisher Nature Publishing Group
series Scientific Reports
issn 2045-2322
publishDate 2021-05-01
description Abstract The heat transfer improvements by simultaneous usage of the nanofluids and metallic porous foams are still an attractive research area. The Computational fluid dynamics (CFD) methods are widely used for thermal and hydrodynamic investigations of the nanofluids flow inside the porous media. Almost all studies dedicated to the accurate prediction of the CFD approach. However, there are not sufficient investigations on the CFD approach optimization. The mesh increment in the CFD approach is one of the challenging concepts especially in turbulent flows and complex geometries. This study, for the first time, introduces a type of artificial intelligence algorithm (AIA) as a supplementary tool for helping the CFD. According to the idea of this study, the CFD simulation is done for a case with low mesh density. The artificial intelligence algorithm uses learns the CFD driven data. After the intelligence achievement, the AIA could predict the fluid parameters for the infinite number of nodes or dense mesh without any limitations. So, there is no need to solve the CFD models for further nodes. This study is specifically focused on the genetic algorithm-based fuzzy inference system (GAFIS) to predict the velocity profile of the water-based copper nanofluid turbulent flow in a porous tube. The most intelligent GAFIS could perform the most accurate prediction of the velocity. Hence, the intelligence of GAFIS is tested for different values of cluster influence range (CIR), squash factor(SF), accept ratio (AR) and reject ratio (RR), the population size (PS), and the percentage of crossover (PC). The maximum coefficient of determination (~ 0.97) was related to the PS of 30, the AR of 0.6, the PC of 0.4, CIR of 0.15, the SF 1.15, and the RR of 0.05. The GAFIS prediction of the fluid velocity was in great agreement with the CFD. In the most intelligent condition, the velocity profile predicted by GAFIS was similar to the CFD. The nodes increment from 537 to 7671 was made by the GAFIS. The new predictions of the GAFIS covered all CFD results.
url https://doi.org/10.1038/s41598-021-90201-x
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