The Nusselt Number

For forced convection of a single-phase fluid with moderate temperature differences, the heat flux per unit area tex2html_wrap_inline12 is nearly proportional to the temperature difference tex2html_wrap_inline14 . This was discovered by Newton who then inferred that tex2html_wrap_inline16 . Thus we arrive at Newton's law of cooling:

displaymath18

where h is called the heat transfer coefficient, with units of tex2html_wrap_inline22 or tex2html_wrap_inline24 .

But h is dimensional and thus its value depends on the units used. The traditional dimensionless from of h is the Nusselt number Nu, which may be defined as the ratio of convection heat transfer to fluid conduction heat transfer under the same conditions. Consider a layer of fluid of width L and temperature difference tex2html_wrap_inline32 . Assuming that the layer is moving so that convection occurs, the heat flux would be,

displaymath34

If, on the other hand, the layer were stagnant, the heat flux would be entirely due to fluid conduction through the layer:

displaymath36

We define the Nusselt number as the ratio of these two:

displaymath38

A Nusselt number of order unity would indicate a sluggish motion little more effective than pure fluid conduction: for example, laminar flow in a long pipe. A large Nusselt number means very efficient convection: For example, turbulent pipe flow yields Nu of order 100 to 1000.

(From Frank M. White, Heat Transfer)