Litcius/Paper detail

Magneto-nanofluidic thermal transport and irreversibility in semicircular systems with heated wavy bottom under constant fluid volume and cooling surface constraints

Nirmalendu Biswas, Deep Chatterjee, Sandip Sarkar, Nirmal K. Manna

2024International Journal of Numerical Methods for Heat &amp Fluid Flow49 citationsDOI

Abstract

Purpose This study aims to investigate the influence of wall curvature in a semicircular thermal annular system on magneto-nanofluidic flow, heat transfer and entropy generation. The analysis is conducted under constant cooling surface and fluid volume constraints. Design/methodology/approach The mathematical equations describing the thermo-fluid flow in the semicircular system are solved using the finite element technique. Four different heating wall configurations are considered, varying the undulation numbers of the heated wall. Parametric variations of bottom wall undulation ( f ), buoyancy force characterized by the Rayleigh number (Ra), magnetic field strength represented by the Hartmann number (Ha) and inclination of the magnetic field ( γ ) on the overall thermal performance are studied extensively. Findings This study reveals that the fluid circulation strength is maximum in the case of a flat bottom wall. The analysis shows that the bottom wall contour and other control parameters significantly influence fluid flow, entropy production and heat transfer. The modified heated wall with a single undulation exhibits the highest entropy production and thermal convection, leading to a heat transfer enhancement of up to 21.85% compared to a flat bottom. The magnetic field intensity and orientation have a significant effect on heat transfer and irreversibility production. Research limitations/implications Further research can explore a wider range of parameter values, alternative heating wall profiles and boundary conditions to expand the understanding of magneto-nanofluidic flow in semicircular thermal systems. Originality/value This study introduces a constraint-based analysis of magneto-nanofluidic thermal behavior in a complex semicircular thermal system, providing insights into the impact of wall curvature on heat transfer performance. The findings contribute to the design and optimization of thermal systems in various applications.

Topics & Concepts

Heat transferMechanicsHartmann numberMaterials scienceThermalFluid dynamicsHeat transfer enhancementMagnetic fieldNusselt numberThermodynamicsHeat transfer coefficientPhysicsTurbulenceReynolds numberQuantum mechanicsNanofluid Flow and Heat TransferHeat Transfer MechanismsHeat Transfer and Optimization