1. Data Base Expansion for Bubble Column Flows reported for DOE in period from 1995 to 2001 & summarized by Peter Spicka

2. Goals Outline Contract DE-FC 22-95 PC 95051
Development of reliable data base for evaluation of parameters in CFD based models
Development of improved engineering models for flow mixing and mass transfer in bubble columns
Outline
Topical review of the data reported for DOE since 1995
Gas Holdup and Liquid Recirculation
Solid Loadings and Sparger Effect
Scale-Up of Bubble Columns
Eddy Diffusivities
Summary

3. Gas holdup and Liquid Recirculation
Main aspects of multiphase flow
Hydrodynamics is driven by:
buoyancy, drag, inertia, pressure, viscous, interface forces…
strong coupling between the forces
many different scales
Commonly used correlations
Reference
Axial Liquid Velocity
Overall gas holdup
Reilly et al. (1986)
Hammer et al. (1984)
Gas holdup radial profile
Luo & Svendsen (1991)
Centerline axial liquid velocity
Joshi & Sharma (1979)
Zehner (1982b)
Axial liquid velocity profile
Garcia-Calvo et al. (1994)
The scale-up is tricky and only very sophisticated CFD simulations can resolve all the aspects - feasible in future ?
Simplifications:
Steady–state one-dimensional flow
Only gas holdup, liquid velocity and turbulence radial profiles are determining factors

4. Gas Holdup & Liquid Recirculation I
Gas Holdup & Liquid Recirculation I. Effect of Ug and Liquid Properties (DOE Quarterly Reports 7-11, 1996)
Gas holdup profiles
Axial velocity profiles
air-water
air-Drakeoil
air-water air-water vs. air-Drakeoil
Air-water air-Drakeoil
Observations:
Increased Ug results in higher holdup and less uniform holdup profile
Gas holdup is lower in air-Drakeoil system due to higher liquid viscosity (20 cP)
The higher holdup in air-water system results in higher recirculation rate

5. with and without internals
Gas Holdup & Liquid Recirculation II. Effect of Column Diameter & Internals (DOE Quarterly Reports 8 & 9, 1996)
Overall gas holdup in 6”, 8” and 18” columns
Axial velocity profiles
18” 8” 6”
Internals layout
6”& 8” columns
with and without internals
in 18” columns
Observations:
Overall gas holdup and liquid recirculation increases with column diameter
Effect of internals on axial velocity is less pronounced
Internals reduce radial eddy diffusivity ( Chen et al., 1999)

6. Equilateral triangle 1 cm apart Circular rings 1.5 cm apart
Gas Holdup & Liquid Recirculation III. Gas Distributor Effect (DOE Quarterly Report 18, 1999)
Ug = 14 cm/s
Ug = 30 cm/s Z+ Z-
Gas distributors: D1
Porosity = 0.1 %
163 holes of 0.4 mm ID
Equilateral triangle 1 cm apart D2
4 holes of 2.6 mm ID
Distributed on a cross
Single hole of 5.1 mm ID
Located in the center D3 D4
Porosity = 0.15 %
163 holes of 0.5 mm ID
Porosity = 0.04 %
61 holes of 0.4 mm ID
Circular rings 1.5 cm apart D5 D6
Porosity = 1.0 %
163 holes of 1.25 mm ID
Observations:
Gas distributor effect is visible only at low Ug (14 cm/s) and near the column bottom
Flow stabilizes faster when single nozzle distributors are used
At Ug of 30 cm/s, the gas distributor effect is negligible

7. Gas Holdup & Liquid Recirculation III
Gas Holdup & Liquid Recirculation III. Gas Distributor Effect (DOE Quarterly Report 14, 1996; Degaleesan et al., 1997)
Turbulent kinetic energy profile
Liquid Velocity profile
8” column, Ug=12.0 cm/s. Distributors are: Cone (8C), Bubble Cap (8B), and Perforated Plate (8A)
Observations:
Single nozzle distributors
produce larger bubbles flow is less organized with large spiraling structures
suppressed recirculation and higher turbulent kinetic energy (about 40% higher compared to multiple nozzles distributors)
Multiple holes distributors
Smaller bubbles, less violent flow and enhanced recirculation

8. Gas Holdup & Liquid Recirculation IV
Gas Holdup & Liquid Recirculation IV. Pressure Effect (DOE Quarterly Report 22, 2000; Kemoun et al., 2001) 14
Ug cm/s 8 2
6.4” column
Findings
Almost uniform gas holdup profiles, which are not pressure dependent were observed at lower Ug. This finding is in good agreement with Letzel (1997)
In churn-turbulent regime, gas holdup increases with pressure (in the interval from 1 to10 bars) as well as the steepness of the profile
Single hole distributor D3 provides visibly higher gas holdup than perforated plate distributors at 4 bars and Ug of 30 cm/s due to increased dispersion and break up of the gas jet produced by the single nozzle (Kling, 1962; Nauze et al., 1974)
6.4” column, 4 bars, Ug= 30 cm/s
6.4” column, axial level z/D = 5.5, distributor D4

9. Gas Holdup & Liquid Recirculation V
Gas Holdup & Liquid Recirculation V. Effect of Solids Loading (DOE Quarterly Report 12, 1998)
G-L system
G-L-S system
Dc inch(cm)
4 (10.2)
6 (14)
Composition
air - 50%
iso-propanol
air - water
air - 50% iso-propanol - alumina
air - water - glass beads
Ug [cm/s]
4-12
2.4-12
2-8
2-14
Solids [wt. %] ‑
10 
7, 14 and 20
Particle size [mm] -   -
40-106
Sparger
perf.plate,
bubble cap
perf. plate
sintered plate
perforated plate
Comparison of G-L and G-L-S systems
Ug has smaller effect on axial velocity profiles in slurries and its effect decreases with increased concentration of slurries
All observed differences can be attributed to altered viscosity and density of the pseudo slurry phase
Influence of Solids Loading Axial Distance

10. Eddy Diffusivities Effect of Ug, solids loading (DOE Quarterly Reports 13 & 14, 1998)
Eddy diffusivity
Flow in bubble columns is of transient nature
Fluctuating character of flow and backmixing can by captured by eddy diffusivity, defined in Langrangian framework as:
Findings of the study
With increased Ug, the axial eddy diffusivity increases
Maximum Dzz occurs at r/R = 0.75
Solids loading does not affect the axial eddy diffusivity profiles significantly
Effect of Ug
Effect of solids loading
6” column , GLS system, glass particles of 150 mm

11. Eddy Diffusivities Effect of Ug and Dc – correlations (DOE Quarterly Report 13, 1998)
These correlation are valid for air-water systems in large columns size (Dc> 10 cm) and churn-turbulent regime ( Ug > 5 cm/s)

12. Scale–Up Issues I. (DOE Quarterly Report 13, 1998)
CREL contribution II
In a separated effort ( not directly funded by DOE), new correlations for radial gas holdup and axial liquid velocity were proposed
Chronology:
Energy balance models:
Whalley & Daviddson (1974)
extended by Joshi & Sharma (1979) who proposed circulation structures
Momentum balance models:
Rietema & Ottengraf (1970)
Zehner (1980)
Implementation of turbulence:
universal mixing length by Ueyama & Miyauchi (1979)
Anderson and Rice (1989) proposed a‘three zones’ concept
Geary and Rice (1992) proposed model which depends on bubble size
CREL contribution I
based on CARPT/CT, a new correlation for centerline axial velocity was developed:
Wu et al. (2001b)
Wu et al. (2001a)

13. Scale –Up Issues II. (DOE Quarterly Report 13, 1998: Degaleesan, 1997)
CREL contribution III
Correlations for radial profiles of axial and radial eddy diffusivities were proposed
(Valid for churn-turbulent regime and Dc> 10 cm)

14. Summary I.
Extensive data base has been created which encompass broad range of operating conditions:
Column diameters: 4, 6, 8 and 18 inch column
Range of UG : from 2 to 30 cm/s
Range of pressure: 1, 4, and 10 bars for 6.4” column
Distributors: perfor. plate (various porosities), sintered plate,cross sparger, cone, buble cap
Liquids : water, Drakeoil, 50% isopropanol in water
Internals in 18”column)

15. Summary II.
Gas holdup and liquid recirculation is affected primarily by superficial gas velocity
Secondary effects are due to: liquid physical properties; column diameter and; solids concentration
Heat exchange tubes do not affect significantly gas holdup and liquid recirculation profiles
Gas distributor does has minimum effect gas holdup and liquid velocity in fully developed region
Gas holdup is not affected by pressure in bubbly regime but it rises with pressure in churn-turbulent regime and becomes increasing parabolic
Correlations have been developed for the gas holdup, liquid velocity and eddy diffusivity radial profiles
Future work
Data base extension to higher pressure and temperature
Experiments at low H/Dc to identify sparger with most desirable properties
New models need to be proposed as to which variable is dominant one that governs the establishment of gas holdup and liquid velocity profile