Ergun equation

The Ergun equation, derived by the Turkish chemical engineer Sabri Ergun in 1952, expresses the friction factor in a packed column as a function of the modified Reynolds number.

Equation


f_p = \frac {150}{Gr_p} + 1.75

where f_p and Gr_p are defined as

f_p = \frac{\Delta p}{L} \frac{D_p}{\rho v_s^2} \left(\frac{\epsilon^3}{1-\epsilon}\right) and Gr_p = \frac{\rho v_s D_p}{(1-\epsilon)\mu}

where: Gr_p is the modified Reynolds number,
\Delta p is the pressure drop across the bed,
L is the length of the bed (not the column),
D_p is the equivalent spherical diameter of the packing,
\rho is the density of fluid,
\mu is the dynamic viscosity of the fluid,
v_s is the superficial velocity (i.e. the velocity that the fluid would have through the empty tube at the same volumetric flow rate), and
\epsilon is the void fraction of the bed (bed porosity at any time).

Extension

The extension of the Ergun equation to fluidized beds is discussed by Akgiray and Saatçı (2001). To calculate the pressure drop in a given reactor, the following equation may be deduced

\Delta p=\frac{150\mu ~L}{D_p^2} ~\frac{(1-\epsilon)^2}{\epsilon^3}v_s + \frac{1.75~L~\rho}{D_p}~ \frac{(1-\epsilon)}{\epsilon^3}v_s|v_s|

This arrangement of the Ergun equation makes clear its close relationship to the simpler Kozeny-Carman equation which describes laminar flow of fluids across packed beds.

See also

References

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