The Stanton number, ''St'', is a dimensionless number that measures the ratio of heat transferred into a fluid to the thermal capacity of fluid. The Stanton number is named after

Thomas Stanton (engineer) Sir Thomas Ernest Stanton (12 December 1865 - 30 August 1931) was a British mechanical engineer and a specialist in fluid dynamics and tribology. He was the first to construct a supersonic wind tunnel in 1921. The eponymous Stanton number is based ...

(1865–1931). It is used to characterize heat transfer in forced convection flows.

Formula

St = \frac = \frac

where *''h'' = convection heat transfer coefficient * ''ρ'' = density of the fluid *''c_p'' = specific heat of the fluid *''u'' = velocity of the fluid It can also be represented in terms of the fluid's Nusselt, Reynolds, and Prandtl numbers: :

\mathrm = \frac

where * Nu is the Nusselt number; * Re is the

Reynolds number In fluid mechanics, the Reynolds number () is a dimensionless quantity that helps predict fluid flow patterns in different situations by measuring the ratio between inertial and viscous forces. At low Reynolds numbers, flows tend to be do ...

; * Pr is the

Prandtl number The Prandtl number (Pr) or Prandtl group is a dimensionless number, named after the German physicist Ludwig Prandtl, defined as the ratio of momentum diffusivity to thermal diffusivity. The Prandtl number is given as: : \mathrm = \frac = \frac ...

. The Stanton number arises in the consideration of the geometric similarity of the momentum boundary layer and the thermal boundary layer, where it can be used to express a relationship between the

shear force In solid mechanics, shearing forces are unaligned forces acting on one part of a body in a specific direction, and another part of the body in the opposite direction. When the forces are collinear (aligned with each other), they are called ...

at the wall (due to viscous drag) and the total heat transfer at the wall (due to thermal diffusivity).

Mass transfer

Using the heat-mass transfer analogy, a mass transfer St equivalent can be found using the Sherwood number and Schmidt number in place of the Nusselt number and Prandtl number, respectively.

\mathrm_m = \frac

\mathrm_m = \frac

where *

St_m

is the mass Stanton number; *

Sh_L

is the Sherwood number based on length; *

Re_L

is the Reynolds number based on length; *

Sc

is the Schmidt number; *

h_m

is defined based on a concentration difference (kg s⁻¹ m⁻²); *

u

is the velocity of the fluid

Boundary layer flow

The Stanton number is a useful measure of the rate of change of the thermal energy deficit (or excess) in the boundary layer due to heat transfer from a planar surface. If the enthalpy thickness is defined as:

\Delta_2 = \int_0^\infty \frac \frac d y

Then the Stanton number is equivalent to

\mathrm = \frac

for boundary layer flow over a flat plate with a constant surface temperature and properties.

Correlations using Reynolds-Colburn analogy

Using the Reynolds-Colburn analogy for turbulent flow with a thermal log and viscous sub layer model, the following correlation for turbulent heat transfer for is applicable

\mathrm = \frac

where

C_f = \frac

References

{{DEFAULTSORT:Stanton Number Dimensionless numbers of fluid mechanics Dimensionless numbers of thermodynamics Fluid dynamics

Formula

Mass transfer

Boundary layer flow

Correlations using Reynolds-Colburn analogy

See also

References