NU_WAKAO_KAGEI
This function estimates packed-bed convective heat transfer with the Wakao-Kagei correlation. The relationship depends on Reynolds and Prandtl numbers and provides a practical estimate when a simple, widely used packed-bed correlation is needed.
The correlation is:
Nu = 2 + 1.1Pr^{1/3}Re^{0.6}
where Re is the particle Reynolds number and Pr is the Prandtl number of the fluid.
Excel Usage
=NU_WAKAO_KAGEI(Re, Pr)Re(float, required): Reynolds number using particle diameter as length scale (-).Pr(float, required): Prandtl number of the fluid (-).
Returns (float): Nusselt number for heat transfer to the packed bed.
Example 1: Example Reynolds and Prandtl values
Inputs:
| Re | Pr |
|---|---|
| 2000 | 0.7 |
Excel formula:
=NU_WAKAO_KAGEI(2000, 0.7)Expected output:
95.4064
Example 2: Lower Reynolds number case
Inputs:
| Re | Pr |
|---|---|
| 50 | 1.2 |
Excel formula:
=NU_WAKAO_KAGEI(50, 1.2)Expected output:
14.2227
Example 3: Mid range Reynolds number
Inputs:
| Re | Pr |
|---|---|
| 12000 | 0.9 |
Excel formula:
=NU_WAKAO_KAGEI(12000, 0.9)Expected output:
299.611
Example 4: Higher Prandtl number case
Inputs:
| Re | Pr |
|---|---|
| 1500 | 5 |
Excel formula:
=NU_WAKAO_KAGEI(1500, 5)Expected output:
153.369
Python Code
Show Code
from ht.conv_packed_bed import Nu_Wakao_Kagei as ht_Nu_Wakao_Kagei
def Nu_Wakao_Kagei(Re, Pr):
"""
Calculate Nusselt number for a packed bed using the Wakao-Kagei correlation.
See: https://ht.readthedocs.io/en/latest/ht.conv_packed_bed.html
This example function is provided as-is without any representation of accuracy.
Args:
Re (float): Reynolds number using particle diameter as length scale (-).
Pr (float): Prandtl number of the fluid (-).
Returns:
float: Nusselt number for heat transfer to the packed bed.
"""
try:
Re = float(Re)
Pr = float(Pr)
return ht_Nu_Wakao_Kagei(Re=Re, Pr=Pr)
except Exception as e:
return f"Error: {str(e)}"Online Calculator
Reynolds number using particle diameter as length scale (-).
Prandtl number of the fluid (-).