Agitator Design Calculation Xls -

Rei=N⋅D2⋅ρμcap R e sub i equals the fraction with numerator cap N center dot cap D squared center dot rho and denominator mu end-fraction : Laminar flow. : Transition flow. : Turbulent flow. B. Power Calculation (The Core Formula) The power required by the impeller (P) is calculated as:

| Parameter | Value | Unit | | --- | --- | --- | | Tank Diameter | | m | | Tank Height | | m | | Material Density | | kg/m³ | | Material Viscosity | | Pa·s | | Mixing Time | | min | | Mixing Intensity | | W/kg | | Agitator Type | | | | Impeller Diameter | | m | | Impeller Shape | | | | Shaft Length | | m | | Shaft Diameter | | m | | Motor Power | | kW |

, which tells you if the flow is laminar (honey-like) or turbulent (water-like). 2. Impeller Selection and Power Number The "heart" of the agitator is the Hydrofoils are used for high flow with low shear. Rushton turbines are the go-to for gas dispersion. Pitched blades provide a mix of radial and axial flow. Each impeller has a unique Power Number ( cap N sub p agitator design calculation xls

Change RPM, impeller size, or fluid viscosity to see immediate effects on power consumption.

Note: This formula strictly applies to fully turbulent regimes ( Rei=N⋅D2⋅ρμcap R e sub i equals the fraction

Whether your application involves ? I can provide the exact dimensionless constants ( Npcap N sub p Nqcap N sub q ) or specialized scaling formulas for your sheet. Share public link

Create a standardized company template for agitator sizing. Impeller Selection and Power Number The "heart" of

=Np_Cell * Density_Cell * (Speed_Cell^3) * (Impeller_Dia_Cell^5)