Hybrid nanofluid flow around a triangular-shaped obstacle inside a split lid-driven trapezoidal cavity

Numerical simulation analyzes the mixed convection flow of Al2O3-Cu-H2O (aluminium oxide-copper-water) hybrid nanofluid inside a split lid-driven trapezoidal cavity. A triangular-shaped cold obstacle is placed inside the cavity. The horizontal base of the cavity is kept cold, whereas the side walls are chosen adiabatic. The thermally active upper wall maintained at a constant temperature is split into halves, and each half moves opposite to the other with constant velocity. Modeled equations are converted into a nonlinear system of partial differential equations. This system, along with incorporated physical boundary constraints, is solved numerically via Galerkin finite-element method. Attained results are also compared with the earlier publications to ensure validation and accuracy. To examine the effects of various pertinent parameters, various flow and heat transfer attributes like dimensionless velocity, stream contours, temperature, and isotherms, and local and average Nusselt numbers are critically analyzed. The outcomes of this examination will provide qualitative suggestions to improve the cooling mechanism of several electronic gadgets and thermal devices.

Automated summary

The mixed convection flow of Al2O3-Cu-H2O hybrid nanofluid inside a split lid-driven trapezoidal cavity was studied using numerical simulation. Various flow and heat transfer attributes were analyzed to provide suggestions for improving the cooling mechanism of electronic gadgets and thermal devices.