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Stirred tank design

A basic stirred tank design is shown in Fig. 23-30. Height to diameter ratio is H/D = 2 to 3. Heat transfer may be provided through a jacket or internal coils. Baffles prevent movement of the mass as a whole. A draft tube enhances vertical circulation. The vapor space is about 20 percent of the total volume. A hollow shaft and impeller increase gas circulation (as in Fig. 23-31). A splasher can be attached to the shaft at the hquid surface to improve entrainment of gas. A variety of impellers is in use. The pitched propeller moves the liquid axially, the flat blade moves it radially, and inclined blades move it both axially and radially. The anchor and some other designs are suited to viscous hquids. [Pg.2111]

FIG. 23-30a A basic stirred tank design, not to scale, showing a lower radial impeller and an upper axial impeller boused in a draft tube. Four equally spaced baffles are standard. H = beigbt of liquid level, Dj = tank diameter, d = impeller diameter. For radial impellers, 0.3 < d/Dt < 0.6. [Pg.2112]

FIG. 23-30 Basic stirred tank design and selected lands of impellers, (h) Propeller, (c) Turbine, (d) Hollow, (e) Anchor,... [Pg.2113]

The hydrodynamic parameters that are required for stirred tank design and analysis include phase holdups (gas, liquid, and solid) volumetric gas-liquid mass-transfer coefficient liquid-solid mass-transfer coefficient liquid, gas, and solid mixing and heat-transfer coefficients. The hydrodynamics are driven primarily by the stirrer power input and the stirrer geometry/type, and not by the gas flow. Hence, additional parameters include the power input of the stirrer and the pumping flow rate of the stirrer. [Pg.53]

Stirred tank design, 287,288 baffles, 287 draft tubes, 287... [Pg.754]

The optimal stirred tank design is identified through iterating until both geometric and mass transfer requirements are simultaneously satisfied. [Pg.1128]

Figure 5-12. Typical proportion of stirred tank design with radial and axial impellers and baffles. The upper axial impeller is housed in a draft tube. For radial impellers,. 3 < d/Dt <. 6... Figure 5-12. Typical proportion of stirred tank design with radial and axial impellers and baffles. The upper axial impeller is housed in a draft tube. For radial impellers,. 3 < d/Dt <. 6...
See other pages where Stirred tank design is mentioned: [Pg.69]    [Pg.145]    [Pg.287]    [Pg.44]    [Pg.503]    [Pg.287]    [Pg.277]    [Pg.287]    [Pg.287]    [Pg.769]    [Pg.2134]    [Pg.1127]    [Pg.243]    [Pg.2120]    [Pg.104]   
See also in sourсe #XX -- [ Pg.287 , Pg.288 ]

See also in sourсe #XX -- [ Pg.277 , Pg.278 ]

See also in sourсe #XX -- [ Pg.287 , Pg.288 ]

See also in sourсe #XX -- [ Pg.287 , Pg.288 ]

See also in sourсe #XX -- [ Pg.287 , Pg.288 ]



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