NU_HORZ_TURB_SCHL
This function computes the turbulent flat-plate Nusselt number for an isothermal plate using the Schlichting formulation, which includes a denominator correction term as a function of Reynolds and Prandtl numbers.
Nu_L = \frac{0.037Re_L^{0.8}Pr}{1 + 2.443Re_L^{-0.1}(Pr^{2/3} - 1)}
Excel Usage
=NU_HORZ_TURB_SCHL(Re, Pr)Re(float, required): Reynolds number with respect to plate length (-).Pr(float, required): Prandtl number at bulk temperature (-).
Returns (float): Nusselt number with respect to plate length (-).
Example 1: Schlichting example case
Inputs:
| Re | Pr |
|---|---|
| 100000 | 0.7 |
Excel formula:
=NU_HORZ_TURB_SCHL(100000, 0.7)Expected output:
309.62
Example 2: Schlichting at mid Reynolds
Inputs:
| Re | Pr |
|---|---|
| 400000 | 0.9 |
Excel formula:
=NU_HORZ_TURB_SCHL(400000, 0.9)Expected output:
1057.72
Example 3: Schlichting at high Prandtl
Inputs:
| Re | Pr |
|---|---|
| 900000 | 8 |
Excel formula:
=NU_HORZ_TURB_SCHL(900000, 8)Expected output:
6001.36
Example 4: Schlichting at high Reynolds
Inputs:
| Re | Pr |
|---|---|
| 2000000 | 1.1 |
Excel formula:
=NU_HORZ_TURB_SCHL(2000000, 1.1)Expected output:
4309.28
Python Code
Show Code
from ht.conv_external import Nu_horizontal_plate_turbulent_Schlichting as ht_Nu_horizontal_plate_turbulent_Schlichting
def Nu_horz_turb_Schl(Re, Pr):
"""
Calculate the Nusselt number for turbulent flow across an isothermal flat plate using the Schlichting correlation.
See: https://ht.readthedocs.io/en/latest/ht.conv_external.html
This example function is provided as-is without any representation of accuracy.
Args:
Re (float): Reynolds number with respect to plate length (-).
Pr (float): Prandtl number at bulk temperature (-).
Returns:
float: Nusselt number with respect to plate length (-).
"""
try:
return ht_Nu_horizontal_plate_turbulent_Schlichting(Re=Re, Pr=Pr)
except Exception as e:
return f"Error: {str(e)}"Online Calculator
Reynolds number with respect to plate length (-).
Prandtl number at bulk temperature (-).