Archimedes number

In viscous fluid dynamics, the Archimedes number (Ar) (not to be confused with Archimedes' constant, π), named after the ancient Greek scientist Archimedes is used to determine the motion of fluids due to density differences. It is a dimensionless number, the ratio of gravitational forces to viscous forces[1] and has the form:[2]

\mathrm {Ar} ={\frac {gL^{3}\rho _{\ell }(\rho -\rho _{\ell })}{\mu ^{2}}}

where:

$g$ is the local external field (for example gravitational acceleration), $m/s 2$ ,
$\rho _{\ell }$ is the density of the fluid, $kg/m 3$ ,
$\rho$ is the density of the body, $kg/m 3$ ,
$\mu$ is the dynamic viscosity, $kg/ms$ ,
$L$ is the characteristic length of body, $m$ .

Uses

The Archimedes number is generally used in design of tubular chemical process reactors. The following are non-exhaustive examples of using the Archimedes number in reactor design.

Packed Bed Fluidization Design

The Archimedes number is applied often in the engineering of packed beds, which are very common in the chemical processing industry.[3] A packed bed reactor, which is similar to the ideal plug flow reactor model, involves packing a tubular reactor with a solid catalyst, then passing incompressible or compressible fluids through the solid bed.[3] When the solid particles are small, they may be "fluidized", so that they act as if they were a fluid. When fluidizing a packed bed, the pressure of the working fluid is increased until the pressure drop between the bottom of the bed (where fluid enters) and the top of the bed (where fluid leaves) is equal to the weight of the packed solids. At this point, the velocity of the fluid is just not enough to achieve fluidization, and extra pressure is required to overcome the friction of particles with each other and the wall of the reactor, allowing fluidization to occur. This gives a minimum fluidization velocity, $u_{mf}$ , that may be estimated by:[2][4]

$u_{mf}={\frac {\mu }{\rho _{l}d_{v}}}(33.7^{2}+0.0408{\text{Ar}})^{\frac {1}{2}}-33.7$

where:

$d_{v}$ is the diameter of sphere with the same volume as the solid particle and can often be estimated by:[2]

$d_{v}\approx 1.13d_{p}$

where:

$d_{p}$ is the diameter of the particle.

Bubble Column Design

Another use is in the estimation of gas holdup in a bubble column. In a bubble column, the gas holdup (fraction of a bubble column that is gas at a given time) can be estimated by:[5]

$\varepsilon _{g}=b_{1}\left[{\text{Eo}}^{b2}{\text{Ar}}^{b3}{\text{Fr}}^{b4}\left({\frac {d_{r}}{D}}\right)^{b5}\right]^{b6}$

Where:

$\varepsilon _{g}$ is the gas holdup fraction
${\text{Eo}}$ is the Eötvos number
${\text{Fr}}$ is the Froude number
$d_{r}$ is the diameter of holes in the column's spargers (holed discs that emit bubbles)
$D$ is the column diameter
Parameters $b1$ to $b6$ are found empirically

Spouted Bed Minimum Spouting Velocity Design

A spouted bed is used in drying and coating. It involves spraying a liquid into a bed packed with the solid to be coated. A fluidizing gas fed from the bottom of the bed causes a spout, which causes the solids to circle linearly around the liquid.[6] Work has been undertaken to model the minimum velocity of gas required for spouting in a spouted bed, including the use of artificial neural networks. Testing with such models found that Archimedes number is a parameter that has a very large effect on the minimum spouting velocity.[7]

References

Wypych, George (2014). Handbook of Solvents, Volume 2 - Use, Health, and Environment (2nd ed.). ChemTec Publishing. p. 657.
Harnby, N; Edwards, MF; Nienow, AW (1992). Mixing in the Process Industries (2nd ed.). Elsevier. p. 64.
Nauman, E. Bruce (2008). Chemical Reactor Design, Optimization, and Scaleup (2nd ed.). John Wiley & Sons. p. 324.
Önsan, Zeynep Ilsen; Avci, Ahmet Kerim (2016). Multiphase Catalytic Reactors - Theory, Design, Manufacturing, and Applications. John Wiley & Sons. p. 83.
Feng, Dan; Ferrasse, Jean-Henry; Soric, Audrey; Boutin, Olivier (April 2019). "Bubble characterization and gas–liquid interfacial area in two phase gas–liquid system in bubble column at low Reynolds number and high temperature and pressure". Chem Eng Res Des. 144: 95–106.
Yang, W-C (1998). Fluidization, Solids Handling, and Processing - Industrial Applications. William Andrew Publishing/Noyes. p. 335.
Hosseini, SH; Rezaei, MJ; Bag-Mohammadi, M; Altzibar, H; Olazar, M (October 2018). "Smart models to predict the minimum spouting velocity of conical spouted beds with non-porous draft tube". Chem Eng Res Des. 138: 331–340.

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[1] Wypych, George (2014). Handbook of Solvents, Volume 2 - Use, Health, and Environment (2nd ed.). ChemTec Publishing. p. 657.

[:1-2] Harnby, N; Edwards, MF; Nienow, AW (1992). Mixing in the Process Industries (2nd ed.). Elsevier. p. 64.

[:0-3] Nauman, E. Bruce (2008). Chemical Reactor Design, Optimization, and Scaleup (2nd ed.). John Wiley & Sons. p. 324.

[4] Önsan, Zeynep Ilsen; Avci, Ahmet Kerim (2016). Multiphase Catalytic Reactors - Theory, Design, Manufacturing, and Applications. John Wiley & Sons. p. 83.

[5] Feng, Dan; Ferrasse, Jean-Henry; Soric, Audrey; Boutin, Olivier (April 2019). "Bubble characterization and gas–liquid interfacial area in two phase gas–liquid system in bubble column at low Reynolds number and high temperature and pressure". Chem Eng Res Des. 144: 95–106.

[6] Yang, W-C (1998). Fluidization, Solids Handling, and Processing - Industrial Applications. William Andrew Publishing/Noyes. p. 335.

[7] Hosseini, SH; Rezaei, MJ; Bag-Mohammadi, M; Altzibar, H; Olazar, M (October 2018). "Smart models to predict the minimum spouting velocity of conical spouted beds with non-porous draft tube". Chem Eng Res Des. 138: 331–340.

Archimedes number

Uses

Packed Bed Fluidization Design

Bubble Column Design

Spouted Bed Minimum Spouting Velocity Design

See also

References