Magnetic field influence on heat transfer of NEPCM in a porous triangular cavity with a cold fin and partial heat sources: AI analysis combined with ISPH method

Magnetic field influence on heat transfer of NEPCM in a porous triangular cavity with a cold fin and partial heat sources: AI analysis combined with ISPH method

This study employs the Incompressible Smoothed Particle Hydrodynamics (ISPH) method and an Artificial Neural Network (ANN) model to examine the thermal and fluid dynamics behavior of nano-enhanced phase change material (NEPCM) within a triangular cavity containing a fin. The research investigates ho...

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Bibliographic Details
Main Authors: Munirah Aali Alotaibi, Weaam Alhejaili, Abdelraheem M. Aly, Samiyah Almalki
Format: Article
Language:English
Published: Elsevier 2025-04-01
Series:Alexandria Engineering Journal
Subjects:
Artificial intelligence
ISPH method
Magnetic field
Tringle cavity
Porous media
Online Access:http://www.sciencedirect.com/science/article/pii/S1110016825001061
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Summary:This study employs the Incompressible Smoothed Particle Hydrodynamics (ISPH) method and an Artificial Neural Network (ANN) model to examine the thermal and fluid dynamics behavior of nano-enhanced phase change material (NEPCM) within a triangular cavity containing a fin. The research investigates how varying physical parameters optimize heat transfer efficiency. The analysis spans partial heat source length LB:0.2 to 0.9, Darcy number Da:10−2 to 10−5, Hartmann number Ha:0 to 50, Cattaneo-Christov heat fluxes δHt:0 to 0.1, fusion temperature θf:0.25 to 0.95, and nanoparticle concentration ϕ:0 to 0.06. Key findings demonstrate that increasing LB by 350 % enhances temperature distribution and nanofluid velocities, reducing the heat capacity ratio Cr by approximately 20 %. The addition of cooling fins decreases peak temperatures by around 15 %. Higher Darcy numbers improve circulation and convection by up to 30 %, creating more uniform thermal distributions, whereas lower Da values restrict fluid motion, intensifying temperature gradients. Increasing the Hartmann number reduces flow and heat transfer efficiency by 40 %, causing sharper temperature gradients, while lower Ha values promote natural convection and more uniform temperature distributions. The fusion temperature θf stabilizes thermal profiles through latent heat absorption, adjusting Cr by 25 %. A higher nanoparticle concentration boosts the average Nusselt number Nu̅ by 10 %, improving overall heat transfer efficiency. The ANN model’s training, reflected in a decreasing mean squared error (MSE), demonstrates prediction accuracy, and regression analysis reveals high model reliability, with predictions closely aligning with theoretical Nu̅ values.
ISSN:1110-0168

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