convective heat transfer

The most used method is based on the convective heat transfer.

The main mechanism for water cooling is convective heat transfer.

However the distinction between natural and forced convection is particularly important for convective heat transfer.

Reducing airflow from inside to outside can help to reduce convective heat transfer significantly.

Gas convective heat transfer is a function of viscosity and specific heat.

Two types of convective heat transfer may be distinguished:

A vacuum chamber surrounding the cold components to eliminate convective heat transfer by gases.

Convective heat transfer can be beneficial or detrimental.

Deactivation typically occurs by free convective heat transfer to the ambient environment.

In engineering, the term convective heat transfer is used to describe the combined effects of conduction and fluid flow.

Convective heat transfer is cooling the shoe.

There is a linear relationship between temperature differential and conductive / convective heat transfer rate.

They exhibit enhanced thermal conductivity and the convective heat transfer coefficient compared to the base fluid.

The equation yields the surface averaged Nusselt number, which is used to determine the average convective heat transfer coefficient.

It turns out that as the drop cools, convective heat transfer begins to occur between the warmer air and the colder water.

The rate of convective heat transfer may be improved by the use of a heat sink, often in conjunction with a fan.

Additionally, the temperature of the surroundings and the convective heat transfer coefficient must remain constant and uniform.

Convective heat transfer with underfloor systems is much greater when the system is operating in a heating rather than cooling mode.

Ensuring low convective heat transfer also requires attention to building construction (weatherization) and the correct installation of insulative materials.

The amount of heat exchanged from or to an underfloor system is based on the combined radiant and convective heat transfer coefficients.

They developed relationships between the turbulent and moleculer Prandtl number that can be employed in convective heat transfer calculations.

Air infiltration can allow convective heat transfer or condensation formation, both of which may degrade the performance of an insulation.

An understanding of convection boundary layers is necessary to understanding convective heat transfer between a surface and a fluid flowing past it.

Investigation of microscale thermal devices is motivated by the single phase internal flow correlation for convective heat transfer:

In contrast, the fans in convection ovens allow more heat to be transferred via convective heat transfer.