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Parametric study of MHD mixed convection heat transfer in a trapezoidal cavity with NEPCM suspension and rotating star-shaped heat source

Aissa Abderrahmane, Houssem Laidoudi, Abdeldjalil Belazreg, Obai Younis, Hamoud A. Al-Nehari, Riadh Marzouki

2025Results in Physics7 citationsDOIOpen Access PDF

Abstract

• This study examines thermal performance of NEPCM in a chamber with a hot rotating star-shaped body. • Higher Re and Da increase Nu, while higher Ha decreases Nu. • Adding 8% NEPCM raises heat transfer by ~1.5% without affecting flow dynamics. • Higher Re and Da boost average Nu by up to 47% and 23%; 8% NEPCM adds ~2% due to viscosity. A comprehensive numerical investigation of two-dimensional, steady, laminar magneto–hydrodynamic (MHD) mixed convection in a trapezoidal cavity filled with a nano-encapsulated phase–change material (NEPCM) suspension is presented. A star‑shaped heat source located at the cavity centre rotates with a constant angular velocity, while a uniform transverse magnetic field acts on the flow. The physical model couples the energy equation with a temperature–dependent effective specific heat formulation to represent the phase transition of NEPCM particles. The dimensionless governing equations are solved using a Galerkin weighted residual finite‑element method. Detailed parametric studies are carried out for Reynolds number Re = 10–1000, Darcy number Da = 10 −6 –10 −2 , Hartmann number Ha = 0–100 and NEPCM volume fraction φ = 0–0.08. Grid independence and code verification against benchmark solutions are demonstrated. Results reveal that increasing Re and Da enhances the average Nusselt number by up to 47 % and 23 %, respectively, whereas an 8 % NEPCM loading yields a modest ≈2 % enhancement due to increased slurry viscosity. Lorentz forces progressively damp convective rolls, reducing heat transfer at Ha > 40. The unique combination of a rotating internal heater, complex cavity geometry, and phase‑change suspension provides new insights for the design of compact thermal energy‑storage and electronics‑cooling devices.

Topics & Concepts

MagnetohydrodynamicsMechanicsHeat transferPhysicsStar (game theory)Parametric statisticsCombined forced and natural convectionConvective heat transferConvectionNatural convectionMaterials scienceAstrophysicsMagnetic fieldMathematicsStatisticsQuantum mechanicsNanofluid Flow and Heat TransferHeat Transfer and OptimizationHeat Transfer and Boiling Studies
Parametric study of MHD mixed convection heat transfer in a trapezoidal cavity with NEPCM suspension and rotating star-shaped heat source | Litcius