Numerical investigation of the effect of baffle inclination angle on nanofluid natural convection heat transfer in a square enclosure

Abstract EN

The characteristics of the conjugate natural convection of (Al2O3-water) nanofluid inside differentially heated enclosure are numerically analyzed using COMSOL Multiphysics (5.3a).

The enclosure consists of two vertical walls, the left wall has a thickness and maintain at a uniform hot temperature, while the opposite wall at cold temperature and the horizontal walls are isolated.

A high thermal conductivity thin baffle has been added on the insulated bottom wall at a different inclination angles.

The effect of the volume fractions of nanoparticles (), Rayleigh number (Ra), solid wall thermal conductivity ratio (Kr), baffle incline angles (Ø) and the thickness of solid wall (D) on the isothermal lines, fluid flow patterns and the average Nusselt number (Nu) has been investigated.

At low Rayleigh number (Ra=103 to 104) the Isothermal lines are parallel with the vertical wall which is characteristic of conduction heat transfer.

On the other hand, when Rayleigh number increase to (Ra=106), the isotherms lines distribution in the inner fluid become parallel curves with the adiabatic horizontal walls of the enclosure and smooth so convection heat transfer becomes dominant.

As the Rayleigh number further increases, the average Nusselt number enhance because of buoyancy force become stronger.

In addition, the fluid flow within the space is affected by the presence of baffle, its causes blockage and obstruction of flow near the hot wall.

The maximum value of the stream function can be noticed in case of nanofluid when the angle is in rang (30<Ø≤60), therefore, the maximum value of (Nu) find in this range whereas they decrease when the angle is in rang (60> Ø ≥90) where the baffle obstruction causing decreases in flow movement.

As a result, the left region temperature increase and accompanied with a minimum (Nu), This is an indication of reduction in the heat transfer.

In addition, when the inclination angle increases (Ø >90), the baffle obstruction on flow and fluid resistance becomes smaller and the buoyancy strength increase, as a result, the heat transfer is increasing again in this case.

The results shown, the improvement rate in the (Nu) between the highest obstruction occurs at the angle (Ø = 90) and the least obstruction at (Ø = 30) is about (7% ).

The increasing of wall thickness from (D=0.1 to 0.4) leads to reduce the intensive heating through the solid wall as well as small heat transferred to the inner The characteristics of the conjugate natural convection of (Al2O3-water) nanofluid inside differentially heated enclosure are numerically analyzed using COMSOL Multiphysics (5.3a).

The enclosure consists of two vertical walls, the left wall has a thickness and maintain at a uniform hot temperature, while the opposite wall at cold temperature and the horizontal walls are isolated.

A high thermal conductivity thin baffle has been added on the insulated bottom wall at a different inclination angles.

The effect of the volume fractions of nanoparticles (), Rayleigh number (Ra), solid wall thermal conductivity ratio (Kr), baffle incline angles (Ø) and the thickness of solid wall (D) on the isothermal lines, fluid flow patterns and the average Nusselt number (Nu) has been investigated.

At low Rayleigh number (Ra=103 to 104) the Isothermal lines are parallel with the vertical wall which is characteristic of conduction heat transfer.

On the other hand, when Rayleigh number increase to (Ra=106), the isotherms lines distribution in the inner fluid become parallel curves with the adiabatic horizontal walls of the enclosure and smooth so convection heat transfer becomes dominant.

As the Rayleigh number further increases, the average Nusselt number enhance because of buoyancy force become stronger.

In addition, the fluid flow within the space is affected by the presence of baffle, its causes blockage and obstruction of flow near the hot wall.

The maximum value of the stream function can be noticed in case of nanofluid when the angle is in rang (30<Ø≤60), therefore, the maximum value of (Nu) find in this range whereas they decrease when the angle is in rang (60> Ø ≥90) where the baffle obstruction causing decreases in flow movement.

As a result, the left region temperature increase and accompanied with a minimum (Nu), This is an indication of reduction in the heat transfer.

In addition, when the inclination angle increases (Ø >90), the baffle obstruction on flow and fluid resistance becomes smaller and the buoyancy strength increase, as a result, the heat transfer is increasing again in this case.

The results shown, the improvement rate in the (Nu) between the highest obstruction occurs at the angle (Ø = 90) and the least obstruction at (Ø = 30) is about (7% ).

The increasing of wall thickness from (D=0.1 to 0.4) leads to reduce the intensive heating through the solid wall as well as small heat transferred to the inner fluid.