Nusselt number

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The Nusselt number is a dimensionless number that measures the enhancement of heat transfer from a surface that occurs in a 'real' situation, compared to the heat transferred if just conduction occurred. Typically it is used to measure the enhancement of heat transfer when convection takes place.

\mathit{Nu}_L = \frac{hL}{k_f} = \frac{\mbox{Convective heat transfer}}{\mbox{Conductive heat transfer}} in perpendicular to the flow direction

where

Selection of the significant length scale should be in the direction of growth of the boundary layer. A salient example in introductory engineering study of heat transfer would be that of a horizontal cylinder versus a vertical cylinder in free convection.

Several empirical correlations are available that are expressed in terms of Nusselt number in the elementary analysis of flow over a flat plate etc. Sieder-Tate, Colburn and many others have provided such correlations.

For a local Nusselt number, one may evaluate the significant length scale at the point of interest. To obtain an average Nusselt number analytically one must integrate over the characteristic length. More commonly the average Nusselt number is obtained by the pertinent correlation equation, often of the form Nu = Nu(Ra, Pr).

The Nusselt number can also be viewed as being a dimensionless temperature gradient at the surface.

The mass transfer analog of the Nusselt number is the Sherwood number.

Contents

[edit] Empirical calculations

[edit] Free convection at a vertical wall

Cited as coming from Churchill and Chu[1]

\overline{Nu}_L \ = 0.68 + \frac{0.67Ra_L^{1/4} \,}{\left[1 + (0.492/Pr)^{9/16} \, \right]^{4/9} \,} \quad Ra_L \le 10^9

[edit] Free convection from horizontal plates

For the top surface of a hot object in a colder environment or bottom surface of a cold object in a hotter environment[1]

\overline{Nu}_L \ = 0.54 Ra_L^{1/4} \, \quad 10^4 \le Ra_L \le 10^7

\overline{Nu}_L \ = 0.15 Ra_L^{1/3} \, \quad 10^7 \le Ra_L \le 10^{11}

For the bottom surface of a hot object in a colder environment or top surface of a cold object in a hotter environment[1]

\overline{Nu}_L \ = 0.27 Ra_L^{1/4} \, \quad 10^5 \le Ra_L \le 10^{10}

[edit] Forced convection in pipe flow

The Dittus-Boelter equation (for turbulent flow), with n=0.4 for heating of the fluid, and n=0.3 for cooling of the fluid[1]:

Nu_D = 0.023 Re_D^{4/5} Pr^{n}

[edit] References

  1. ^ a b c d Incropera & DeWitt, Fundamentals of Heat and Mass Transfer, 4th Ed, p 493
 v  d  e Dimensionless numbers in fluid dynamics
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