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Study of the working of a new multicell scrubber applied in the fight against air pollution
The Science o f the Total Environment, 23 (1982) 215--224 Elsevier Scientific Publishing Company, Amsterdam -- Printed in The Netherlands
STUDY OF THE WORKING OF A NEW MULTICELL
SCRUBBER APPLIED
215
IN THE FIGHT AGAINST AIR
POLLUTION L. PERDREAU (*)
(*), S. DJERID
Laboratoire
54042 Nancy Cedex (**) Europoll,
(*), C. BELIN
des Sciences
(**), A. LAURENT
du GEnie Chimique,
(*) and J.C. CHARPENTIER
CNRS-ENSIC,
(*)
l, rue Grandville,
(France)
2 rue Amorteaux,
78730 Saint Arnoult en Yvelines
(France)
ABSTRACT The EUROPOLL multicell for the fight against This contactor
contactor
of which constitutes
that may be use
patterns
called cells
to transfer mass and/or heat between the gas and liquid
Indeed each cell comprises
a convergent
and a divergent
the intersection
the throat and thus leads to a good contact between the phases.
From the hydrodynamic of pressure
is a new gas-liquid
and dust pollution of air.
involves a regular package of elementary
in which it is possible phases.
scrubber
the chemical
point of view,
the scrubber
is characterized
by graphs
losses and liquid holdup and by the domain of the flowrates
to the working
in satisfactory
leading
conditions.
The capacity of the mass transfer of the contactor quid side and gas side mass transfer
coefficients
is presented
in terms of li-
and of gas-liquid
interfacial
area. Finally classical
the performances contactors
of the scrubber are compared with those of the other
employed
use of a diagram plotting
to fight the air pollution.
the mass transfer parameters
This is made with the
versus
the spent energy.
INTRODUCTION The main classical columns,
absorbers
spray columns,
ejector reactors.
and gas-liquid
bubble columns, mechanically
Generally
for the treatment
of operation
are well adapted
is to present
(ref.
reaction.
the new EUROPOLL multicell
its appli-
I). For example,
packed
free of dust par-
Moreover
turbulent solid par-
reactions. The aim of the present paper
scrubber,
then to precise
and its mass transfer performances
limits of its potential
plate
tanks, venturi and as concerns
for the washing of hot gases containing
ticles together with very rapid gas-liquid
mical characteristics
stirred
of the gaseous effluents
ticles during an absorption with a rapid chemical jet reactors
are packed columns,
each one has its own specificity
cation field and has its own flexibility columns are employed
reactors
its hydrodyna-
and finally to define the
use when compared with the other types of absorbers.
0048-9697/82/0000--0000/$02.75 © 1982 Elsevier Scientific Publishing Company
216 DESCRIPTION
OF THE EQUIPMENT AND EXPERIMENTAL
Description
of the multicell
The multicell
scrubber
- an inferior hopper - a modular
contactor
involves three main parts
for the gas entrance
:
and the recovering
of the washing liquid,
shell for gas washing the length and/or the height of which are variable
by placing side to side and/or by packing
identical
elementary
- a cap for the gas exit and the entrance and distribution A classical
ID
convergent
,
/
section, throat
elementary
the intersection (Fig,
(Fig.
of rectangular of which forms the
]b). The elementary
(80 rmn), the length WIDTH ~
(= 20 degrees)
(= 20 degrees),
ness of the throat
p
(I0 mm),
la. Multicell scrubber
Fig.
the wideness
(200 rr~).
/~
constituted by a vertical
lb. Elementary cell
study is
package of elemen-
tary cells the number of which is comprised between
Experimental
the thick-
(80 mm) and the height
The contactor of the present Fig.
cell inves-
study is defined by
the angles of the convergent and the divergent
5;
la),
cell involves a
and a divergent
tigated in the present
,/
cells
of the liquid.
I and 8.
apparatus
A schematic
description
of the experimental
The gas and the liquid phases with an initial trickling the gas phase.
apparatus
flow counter-currently
is presented
in figure 2.
inside the absorber either
flow of the liquid phase or with an initial bubble
The liquid is distributed
flow of
at the top of the package by a distributor
having the shape of a cross and containing many holes. The gas is injected at the bottom of the apparatus by a fritted distributor. The range of the liquid and gas flowrates L and G are respectively 4×]0 -5 m3.s-I
and 0 to 0.01 m 3.s-I. The scrubber
prised between The pressure trickling
apparatus
0.8×10 -5 to
at range L/G com-
0.8 and 4 m 3 of liquid per 1000 m 3 of gas to be washed. loss in the equipment
flow operations
(also sometimes
is thus operating
is measured with a U-tube water manometer
and with two piezometric
called at flooded flow conditions).
is measured by weighting
in the equipment
lysis of the gas solute concentration the mass transfer
study.
at bubble
flow operation
The amount of liquid held in the
the liquid that leaves the apparatus
shut of the flows of the phases at the entrance both phases before the entrance
manometers
at
after a rapid
and at the exit. Samples gathered
in
and after the exit allow for the ana-
and of the liquid reactant
concentration
during
217
®
®
®
® ®
I Fig. 2. Experimental apparatus. I. Liquid storage tank 6. 2. Centrifugal pump 7. 3. Liquid rotameter 8. 4. Multicell scrubber 9. 5. Gas-liquid demister I0.
Bottom of the scrubber Liquid rotameter Air compressor Air rotameter Gas solute rotameter
II. 12. 13. 14. 15.
Washing column Gas sampling (in) Gas sampling (out) Liquid sampling (in) Liquid sampling (out)
HYDRODYNAMIC S Operating
zones
I02G (Nm3.s-I)
When the equipment •
\
REGIME o B~BLINGRE~E
•
T
~
is initially working at
trickle flow (trickling and Djerid
regime),
Boldo
(ref. 3) have described
(ref. 2)
the different
flow regimes visually observed and have shown the existence between /
of a discontinuity
for the operation
the zones corresponding
to a trickle flow
or a surging flow of the liquid on the walls of
(17
the cells and the zone corresponding
m~ 05
0.25
operation with a good mixture of both phases.
SURGING FLOW
last zone is limited between
an TRICKLINGFLOW
curves and the "flooding"
BUBBLINGFLOW
plot.
AIR_WATERSYSTEM n.5 IOsL (m3.s-9
When the equipment
curves
in a L versus C
is initially working at bub-
ble flow (bubbling regime), not observed
Thi~
the "picking-up"
Perdreau
the discontinuous
non and led to the conclusion Fig. 3. Operating zones of the multicell scrubber.
to a correct
(ref. 4) did
picking-up
phenome-
that the operating
zone was only limited by the flooding
curve.
218
The operating
zones of the scrubber working
bubbling regime are presented corresponding
to a correct operation
ting zone at bubbling operating
regimes,
contactors Pressure
regime.
either at trickling regime or at
in figure 3. It has to be underlined at trickling
Besides,
regime
and bubbling
concerning
the
5-6).
of the pressure
flow regimes
and liquid flowrates an approximatively At trickling
drop per unit length AP/Z measured
pressure
It should be noted that the flooding occurs for drop as in the case of packed columns
for a given liquid flowrate
the pressure
slowly for the low gas flowrates
(before the picking-up
the picking-up
increases
point and finally
gas flowrate
On the contrary,
rate first very quickly,
regime,
(ref.
7).
drop first increases then present a jump at
quickly up to the flooding point. For a is high.
the pressure drop decreases with the gas flow-
then more slowly up to the flooding.
is all the more weak that the liquid flowrate
-2&P/Z(mbar.m ')
point),
is all the more high that the liquid flowrate
at bubbling
are presented
the location of the flooding zone for the same gas
at both regimes.
constant
regime,
for trickling
in function of the gas and liquid flowrates
in figure 4a. This plot confirms
ll
in the opera-
drop
The variations
constant
is included
the flooding curve, which is common for both
may be predicted by a more general correlation
of tubular type (ref.
that the zone
Also the pressure drop
is high.
~(m
AH/n (m w,ter/cell)
,100 AIR.WATER SYSTEM
020'
60•m 0
AIR_WATER SYSTEM 0.15'
•40
\%---.... )
REGIME
m 3. s -~
F~CKLb'~C;I~I~_ING
0
x
+
0.833
•
o
2.5
•
"
3.333
•
a
0.10"
n=5
"
105 L
II
n. 5
~ +
•20 (b) ~
o
•
0
025
Fig. 4a.-4b.
05
Q75
f lo'G
0
Q25
Q50
(175
Variations of the pressure drop (4a) and of the liquid holdup sus gas and liquid flowrates.
1 (4b) ver-
219 Liquid holdup The variations of the total liquid holdup reported to the total empty volume of the scrubber in function of the gas and liquid flowrates are reported in figure 4b. The general trend observed in this graph is identical to that concerning the pressure drop. At trickling regime, the evolution of the liquid holdup also presents a discontinuity at the level of the picking-up point. The order of magnitude of the liquid holdup is the same at that in a packed column. At bubbling regime, the liquid holdup is greatly superior as compared with the values obtained at trickling regime. Generally the liquid holdup decreases when the gas flowrate increases and the influence of the liquid flowrate is all the more marked that this liquid flowrate is high and is located near the flooding of the scrubber. MASS TRANSFER The chemical techniques for the experimental determination of the mass transfer coefficients kLS (liquid film) and kGS (gas film) and of the interfacial area S (gasliquid) for a gas-liquid reactor by absorption with chemical reaction have been reported in the literature (ref. |). A slow irreversible reaction is used for the measurement of kLS , a fast pseudo m-th order reaction for S and an instantaneous surface reaction for the determination of kGS. The kinetics of each reaction employed has been previously studied in a laboratory model of known interfacial area and contact time (cylindrical wetted wall column). These techniques have been applied in the present equipment. Liquid phase coefficient The liquid mass transfer coefficient kLS was determined by the absorption of dilute carbon dioxyde (2 %) in air into aqueous potassium carbonate and bicarbonate buffer solutions
(0.6 M K2CO 3 + 0.2 M HKC03) in the conditions of a slow reaction totally
controlled by the mass transfer resistance in the liquid phase. The variations of the kLS values in function of the gas flowrates for different given liquid flowrates are presented in figure 5. At trickling regime, kLS is simultaneously influenced both by L and G. At bubbling regime, kLS increases with the gas flowrate and is independent of the liquid flowrate if the accuracy of the measurements
(within + ]0 %) is taken into account. It has to be noted that the values
determined with the bubbling regime are greatly superior. Gas phase coefficient The gas mass transfer coefficient kGS was determined by absorption of dilute sulphur dioxyde
(2 %) in air into aqueous solution of sodium hydroxyde
(IN) in the con-
ditions of an instantaneous surface and irreversible reaction totally controlled by the resistance in the gas phase.
220
103koS(kmol.s-LI~-') I0' WLS(m3.SJ)
ll~i~l o I " I " I bo'u~.~-')lo~31 ~ 13.3331 o/
~o
~/yD
°lol
BUBBLING o lOSL(m3.d) 0833 25 3.333
TRICKUNG
•
•
•
J
I
/
n=3
f
/
I
,,"
-"
i_,,,, '..,.-" I ivilrt
0.5
T~Ki_l,~l
•
I v l •
I
~o~u,,.,-,ilof~ol~63s12~s2sl 102 G (NmS.s -1)
o.~s
o'.s
o.~,s
i
Fig. 5. Liquid-side mass transfer the multicell scrubber
o:~s
--
in
102G(Nms.s-9 075 1' -'
ds
Fig. 6. Gas-side mass transfer in the multicell scrubber
S (m2) 1.2'
The variation
IBUBBLI~I ° ] ~ ] D [
of the kGS values
for different
constant
are reported
liquid flowrates
figure 6. At trickling
10 ,
/I
,,
oi..---o-i'
+
!/
a
independent
of the liquid flowrate.
Interfacial
area
The interfacial
area S was determined by
the absorption with the rapid irreversible
"1
fast pseudo first order reaction of dilute
/'
carbon dioxyde
OA 10SL('%O06801t633 2~51
o~o
o~s
(2 %) in air into aqueous
solution of sodium hydroxyde
102G(Nm 3 . s -~) o~s
regime,
linear function of the gas flowrate and is
n.5
TR~Lm "/" o
in
kGS increa-
in the studied zone, kGS is practically
"i,,',,,:./ I
regime,
ses with both L and G. At bubbling
'
0.6 #
in func-
tion of the gas flowrates
The variations
i~
of the S values
tion of L and G are reported Fig. 7. InterfacJal scrubber
(0.2N). in func-
in figure 7.
area in the multicell It is observed
that S increases with both
L and G in the trickling and bubbling flows. However at bubbling
regime,
liquid flowrate when L is higher
the interfacial
area becomes
independent
of the
than 2.5×I0 -5 m 3os -!. The area obtained with this
regime is also bigger than with the trickling
regime.
221 COMPARISON OF THE PERFORMANCES To tempt an exhaustive pes of gas-liquid rature results, necessary
confrontation
absorbers
of the various
scrubber
SCRUBBER WITH OTHER ABSORBERS
between
the performances
is very often a challenge
for this comparison.
the EUROPOLL
OF THE MULTICELL
conditions
of the different
ty-
due to the scatter of the lite-
of the tests and/or of the lack of the data
We are going to try to present now the performances
in a diagram with the plot - mass transfer
spent energy - in both trickling
and flooding
parameter versus
regimes and then to confront
formances with those of other contactors when the literature
of
these per-
data are available.
kLS parameter
k.{~L ~4./3 L"~-~L~2)
Perdreau determined powers
10-;
®/
in the EUROPOLL
the values of the scrubber necessary
to obtain the values of the liquid side mass transfer kLS reported
in figure 5.
These are comprised between
I to 2 watts
for each cell in the trickling regime and between
1.5 and 4 watts
the bubbling
regime
for each cell in
(ref. 4). It was also
shown that for a constant
dissipated
power
in each cell, the kLS value at bubbling
N
gime is thrice as high as at trickling
reregi-
me together with a liquid holdup ratio of ten. This leads to suggest the potential of the EUROPOLL
10_10_,6
10°
101
gas-liquid
10"
chemical
2 ,,,-',~ 7[P(~I L p~9~)
absorptions
employed
for oxidation
can be seen that the EUROPOLL stirred vessel and the stirred
processes
such as those of effluents or in aero-
bic fermentations. Figure 8 presents form the volumetric
in a dimensionless mass transfer
coeffi-
cient kLa as a function of the specific power requirement of the EUROPOLL
tional reactors
followed by a'slow
in the treatment
with slow kinetics
use
in the cases of
reaction processes
encountered
Fig. 8. Dimensionless form of the volumetric liquid mass transfer coefficient for various contactors I. Stirred loop reactor 2. Stirred vessel (coalescing) 3. Stirred vessel (hollow stirrer) 4. Injector 5. Stirred vessel (non coalescing) 6. Multicell scrubber
scrubber
(ref. 8). Comparing
scrubber achieves loop reactor.
and gives the location
scrubber among the convenregions
I, 5 and 6, it
same mass transfer
rates than the
222 kGS parameter The comparison of the k~S values
NG
EUROPOLL
9 8
BUBBLING
scrubber
in the
shows that the operation
at the bubbling regime results
in gas phase
efficiencies
99.6 % and
(a.3)
7
comprised
between
99.97 % while the operation ling regime results
at the trick-
in gas phase efficien-
cies comprised between 83 and 93 %. The Number of Transfer phase is plotted against
DUALFLOWTRAY
Units
in the gas
the energy dissipa-
ted per unit volume of treated gas in figure 9. It is seen that the performances the absorber
of
strictly vary with the dissipa-
ted energy for the studied gas-liquid and whatever
~ I
I
I
0.1
I
I I i i I
05
I
I
I
I
1
the flow regime. For a compari-
son with other absorbers,
(kJ. m-3)
regroups
---
5
the same diagram
the data obtained with the same
gas-liquid
system in a plate column invol-
ving 4 dual flow trays
Fig. 9. Comparison between the attainable number of gas mass transfer units for dual flow tray, packed column and multicell scrubber,
and distance between in a packed column
(diameter
the trays
(height
: 0.5 m
: 0.4 m) and
: I m, packings
are I inch and 2 inches polypropylen rings),
(ref. 9). This confrontation
for the treatment
at trickling
system
shows the potential
Pall
use of the EUROPOLL scrubber
flow regime of the gaseous effluents when an absorp-
tion with a rapid and/or instantaneous
reaction
is required.
S parameter The comparison of the dissipated
of the interfacial
(ref. 4). It was observed
that at the trickling
a = 100-200 m2.m -3 for a dissipated at the bubbling
regime,
m2.m -3 for a dissipated Moreover Nagel et al. characteristic flowrate
area in the EUROPOLL equipment
the interfacial
1 and 1.5 kW.m -3 while
the interfacial
to define a criterion
for the confrontation
bers. Using such a plot,
figure
of the EUROPOLL
shows that the EUROPOLL
10 allows
the use of another
interesting
area created per unit volumetric
and the selection
for a comparison
scrubber and other contactors.
scrubber
100 and 200
2 and 3.6 kW.m -3.
10) have proposed
diagram plotting
the order of magnitude was
area was comprised between
power comprised between (ref.
regime,
power comprised between
in function of the energy supplied per unit volumetric
performances
in function
energy per unit volume of scrubber has been made by Perdreau
is only suitable
of gas-liquid
gas
in order
absor-
to be made between
the
This working diagram
for production
transfer areas, but a such diagram is only qualitatively ted chemical system.
gas flowrate,
of average mass
valid for the investiga-
223
$/G (m~. S. m-z')
CONCLUSION
EAT cotuMN
I I
The present study shows that the
B. RPE FLOW C. COUNTERCURRENTPACKEDCOLUMN
EUROPOLL scrubber may be employed at trickling regime for the treatment of gaseous effluents containing eventually particles or dust in suspension and when a gas-liquid absorption accompanied
103
by a rapid or an instantaneous chemical reaction occurs (abatement of S02, H2S, NH3, acidic aerosols...).
I02!~ /~
It seems also
that this equipment could be employed at bubbling regime for the treatment of gas effluents by liquids where a slow chemical reaction happens (absorption of Nitrogene oxides or oxygenation of loa-
(BUBBLI~) E CELLULARSCRUBBER(TRICKLNG)
I
1010! DO _
I
P/G(kJ'm-3)
ded liquids) in trying in future to compare its performances with those of bubble columns.
10
Fig. 10. Comparison of interfacial transfer areas and specific power dissipations for any gas-liquid reactors.
Summarizing due to its flexibility depending its operating regime encountered, this new type of multicell contactor should allow to propose solutions adapted to the problems of the fight against the air pollution.
NOTATIONS a e g G kG
kL L n
NG P S V Z B PL
hL AP
interfacial area per unit volume of reactor thickness of the throat gravitational acceleration volumetric gas flowrate gas mass transfer coefficient liquid mass transfer coefficient volumetric liquid flowrate number of elementary cells number of gas mass transfer units dissipated power total interfacial area total volume of reactor height of column total liquid holdup liquid density dynamic viscosity of liquid gas pressure drop
REFERENCES 1 .
J.C. Charpentier, Mass transfer rates in gas-liquid absorbers and reactors, in Adv. Chem. Engng., Ed. T.B. Drew and T. Vermeulen, Vol. 11, Academic Press,
1981,
1-133.
224
2. 3. 4. 5. 6. 7. 8. 9. 10.
P. Boldo, A. Laurent, C. Belin and J.C° Charpentier, La Houille Blanche, 6/7 (1979) 435. S. Djerid, DEA, Nancy (1980). L. Perdreau, Th~se INPL, ENSIC, Nancy (1981). T. Takahashi, Y. Akagi and K. Fujita, J. Chem. Eng. Japan, ! (1973), 97. T. Takahashi, Y. Akagi, K. Fujita and T. Kishimoto, J. Chem. Eng. Japan, 3 (1974) 223. L. Musil, C. Prost and P. Le Goff, Chem. Ind. Ggnie Chimique, 5 (1968) 674. G. Keitel and U. Onken, Ger. Chem. Eng. 4 (1981) 250. P. Krotzsch and M. Molzahn, Ger. Chem. Eng. 3 (1980) 257. O. Nagel, B. Hegner and H. K~rten, Chem. Ing. Techn. 50 (1978), 934.
STUDY OF THE WORKING OF A NEW MULTICELL
SCRUBBER APPLIED
215
IN THE FIGHT AGAINST AIR
POLLUTION L. PERDREAU (*)
(*), S. DJERID
Laboratoire
54042 Nancy Cedex (**) Europoll,
(*), C. BELIN
des Sciences
(**), A. LAURENT
du GEnie Chimique,
(*) and J.C. CHARPENTIER
CNRS-ENSIC,
(*)
l, rue Grandville,
(France)
2 rue Amorteaux,
78730 Saint Arnoult en Yvelines
(France)
ABSTRACT The EUROPOLL multicell for the fight against This contactor
contactor
of which constitutes
that may be use
patterns
called cells
to transfer mass and/or heat between the gas and liquid
Indeed each cell comprises
a convergent
and a divergent
the intersection
the throat and thus leads to a good contact between the phases.
From the hydrodynamic of pressure
is a new gas-liquid
and dust pollution of air.
involves a regular package of elementary
in which it is possible phases.
scrubber
the chemical
point of view,
the scrubber
is characterized
by graphs
losses and liquid holdup and by the domain of the flowrates
to the working
in satisfactory
leading
conditions.
The capacity of the mass transfer of the contactor quid side and gas side mass transfer
coefficients
is presented
in terms of li-
and of gas-liquid
interfacial
area. Finally classical
the performances contactors
of the scrubber are compared with those of the other
employed
use of a diagram plotting
to fight the air pollution.
the mass transfer parameters
This is made with the
versus
the spent energy.
INTRODUCTION The main classical columns,
absorbers
spray columns,
ejector reactors.
and gas-liquid
bubble columns, mechanically
Generally
for the treatment
of operation
are well adapted
is to present
(ref.
reaction.
the new EUROPOLL multicell
its appli-
I). For example,
packed
free of dust par-
Moreover
turbulent solid par-
reactions. The aim of the present paper
scrubber,
then to precise
and its mass transfer performances
limits of its potential
plate
tanks, venturi and as concerns
for the washing of hot gases containing
ticles together with very rapid gas-liquid
mical characteristics
stirred
of the gaseous effluents
ticles during an absorption with a rapid chemical jet reactors
are packed columns,
each one has its own specificity
cation field and has its own flexibility columns are employed
reactors
its hydrodyna-
and finally to define the
use when compared with the other types of absorbers.
0048-9697/82/0000--0000/$02.75 © 1982 Elsevier Scientific Publishing Company
216 DESCRIPTION
OF THE EQUIPMENT AND EXPERIMENTAL
Description
of the multicell
The multicell
scrubber
- an inferior hopper - a modular
contactor
involves three main parts
for the gas entrance
:
and the recovering
of the washing liquid,
shell for gas washing the length and/or the height of which are variable
by placing side to side and/or by packing
identical
elementary
- a cap for the gas exit and the entrance and distribution A classical
ID
convergent
,
/
section, throat
elementary
the intersection (Fig,
(Fig.
of rectangular of which forms the
]b). The elementary
(80 rmn), the length WIDTH ~
(= 20 degrees)
(= 20 degrees),
ness of the throat
p
(I0 mm),
la. Multicell scrubber
Fig.
the wideness
(200 rr~).
/~
constituted by a vertical
lb. Elementary cell
study is
package of elemen-
tary cells the number of which is comprised between
Experimental
the thick-
(80 mm) and the height
The contactor of the present Fig.
cell inves-
study is defined by
the angles of the convergent and the divergent
5;
la),
cell involves a
and a divergent
tigated in the present
,/
cells
of the liquid.
I and 8.
apparatus
A schematic
description
of the experimental
The gas and the liquid phases with an initial trickling the gas phase.
apparatus
flow counter-currently
is presented
in figure 2.
inside the absorber either
flow of the liquid phase or with an initial bubble
The liquid is distributed
flow of
at the top of the package by a distributor
having the shape of a cross and containing many holes. The gas is injected at the bottom of the apparatus by a fritted distributor. The range of the liquid and gas flowrates L and G are respectively 4×]0 -5 m3.s-I
and 0 to 0.01 m 3.s-I. The scrubber
prised between The pressure trickling
apparatus
0.8×10 -5 to
at range L/G com-
0.8 and 4 m 3 of liquid per 1000 m 3 of gas to be washed. loss in the equipment
flow operations
(also sometimes
is thus operating
is measured with a U-tube water manometer
and with two piezometric
called at flooded flow conditions).
is measured by weighting
in the equipment
lysis of the gas solute concentration the mass transfer
study.
at bubble
flow operation
The amount of liquid held in the
the liquid that leaves the apparatus
shut of the flows of the phases at the entrance both phases before the entrance
manometers
at
after a rapid
and at the exit. Samples gathered
in
and after the exit allow for the ana-
and of the liquid reactant
concentration
during
217
®
®
®
® ®
I Fig. 2. Experimental apparatus. I. Liquid storage tank 6. 2. Centrifugal pump 7. 3. Liquid rotameter 8. 4. Multicell scrubber 9. 5. Gas-liquid demister I0.
Bottom of the scrubber Liquid rotameter Air compressor Air rotameter Gas solute rotameter
II. 12. 13. 14. 15.
Washing column Gas sampling (in) Gas sampling (out) Liquid sampling (in) Liquid sampling (out)
HYDRODYNAMIC S Operating
zones
I02G (Nm3.s-I)
When the equipment •
\
REGIME o B~BLINGRE~E
•
T
~
is initially working at
trickle flow (trickling and Djerid
regime),
Boldo
(ref. 3) have described
(ref. 2)
the different
flow regimes visually observed and have shown the existence between /
of a discontinuity
for the operation
the zones corresponding
to a trickle flow
or a surging flow of the liquid on the walls of
(17
the cells and the zone corresponding
m~ 05
0.25
operation with a good mixture of both phases.
SURGING FLOW
last zone is limited between
an TRICKLINGFLOW
curves and the "flooding"
BUBBLINGFLOW
plot.
AIR_WATERSYSTEM n.5 IOsL (m3.s-9
When the equipment
curves
in a L versus C
is initially working at bub-
ble flow (bubbling regime), not observed
Thi~
the "picking-up"
Perdreau
the discontinuous
non and led to the conclusion Fig. 3. Operating zones of the multicell scrubber.
to a correct
(ref. 4) did
picking-up
phenome-
that the operating
zone was only limited by the flooding
curve.
218
The operating
zones of the scrubber working
bubbling regime are presented corresponding
to a correct operation
ting zone at bubbling operating
regimes,
contactors Pressure
regime.
either at trickling regime or at
in figure 3. It has to be underlined at trickling
Besides,
regime
and bubbling
concerning
the
5-6).
of the pressure
flow regimes
and liquid flowrates an approximatively At trickling
drop per unit length AP/Z measured
pressure
It should be noted that the flooding occurs for drop as in the case of packed columns
for a given liquid flowrate
the pressure
slowly for the low gas flowrates
(before the picking-up
the picking-up
increases
point and finally
gas flowrate
On the contrary,
rate first very quickly,
regime,
(ref.
7).
drop first increases then present a jump at
quickly up to the flooding point. For a is high.
the pressure drop decreases with the gas flow-
then more slowly up to the flooding.
is all the more weak that the liquid flowrate
-2&P/Z(mbar.m ')
point),
is all the more high that the liquid flowrate
at bubbling
are presented
the location of the flooding zone for the same gas
at both regimes.
constant
regime,
for trickling
in function of the gas and liquid flowrates
in figure 4a. This plot confirms
ll
in the opera-
drop
The variations
constant
is included
the flooding curve, which is common for both
may be predicted by a more general correlation
of tubular type (ref.
that the zone
Also the pressure drop
is high.
~(m
AH/n (m w,ter/cell)
,100 AIR.WATER SYSTEM
020'
60•m 0
AIR_WATER SYSTEM 0.15'
•40
\%---.... )
REGIME
m 3. s -~
F~CKLb'~C;I~I~_ING
0
x
+
0.833
•
o
2.5
•
"
3.333
•
a
0.10"
n=5
"
105 L
II
n. 5
~ +
•20 (b) ~
o
•
0
025
Fig. 4a.-4b.
05
Q75
f lo'G
0
Q25
Q50
(175
Variations of the pressure drop (4a) and of the liquid holdup sus gas and liquid flowrates.
1 (4b) ver-
219 Liquid holdup The variations of the total liquid holdup reported to the total empty volume of the scrubber in function of the gas and liquid flowrates are reported in figure 4b. The general trend observed in this graph is identical to that concerning the pressure drop. At trickling regime, the evolution of the liquid holdup also presents a discontinuity at the level of the picking-up point. The order of magnitude of the liquid holdup is the same at that in a packed column. At bubbling regime, the liquid holdup is greatly superior as compared with the values obtained at trickling regime. Generally the liquid holdup decreases when the gas flowrate increases and the influence of the liquid flowrate is all the more marked that this liquid flowrate is high and is located near the flooding of the scrubber. MASS TRANSFER The chemical techniques for the experimental determination of the mass transfer coefficients kLS (liquid film) and kGS (gas film) and of the interfacial area S (gasliquid) for a gas-liquid reactor by absorption with chemical reaction have been reported in the literature (ref. |). A slow irreversible reaction is used for the measurement of kLS , a fast pseudo m-th order reaction for S and an instantaneous surface reaction for the determination of kGS. The kinetics of each reaction employed has been previously studied in a laboratory model of known interfacial area and contact time (cylindrical wetted wall column). These techniques have been applied in the present equipment. Liquid phase coefficient The liquid mass transfer coefficient kLS was determined by the absorption of dilute carbon dioxyde (2 %) in air into aqueous potassium carbonate and bicarbonate buffer solutions
(0.6 M K2CO 3 + 0.2 M HKC03) in the conditions of a slow reaction totally
controlled by the mass transfer resistance in the liquid phase. The variations of the kLS values in function of the gas flowrates for different given liquid flowrates are presented in figure 5. At trickling regime, kLS is simultaneously influenced both by L and G. At bubbling regime, kLS increases with the gas flowrate and is independent of the liquid flowrate if the accuracy of the measurements
(within + ]0 %) is taken into account. It has to be noted that the values
determined with the bubbling regime are greatly superior. Gas phase coefficient The gas mass transfer coefficient kGS was determined by absorption of dilute sulphur dioxyde
(2 %) in air into aqueous solution of sodium hydroxyde
(IN) in the con-
ditions of an instantaneous surface and irreversible reaction totally controlled by the resistance in the gas phase.
220
103koS(kmol.s-LI~-') I0' WLS(m3.SJ)
ll~i~l o I " I " I bo'u~.~-')lo~31 ~ 13.3331 o/
~o
~/yD
°lol
BUBBLING o lOSL(m3.d) 0833 25 3.333
TRICKUNG
•
•
•
J
I
/
n=3
f
/
I
,,"
-"
i_,,,, '..,.-" I ivilrt
0.5
T~Ki_l,~l
•
I v l •
I
~o~u,,.,-,ilof~ol~63s12~s2sl 102 G (NmS.s -1)
o.~s
o'.s
o.~,s
i
Fig. 5. Liquid-side mass transfer the multicell scrubber
o:~s
--
in
102G(Nms.s-9 075 1' -'
ds
Fig. 6. Gas-side mass transfer in the multicell scrubber
S (m2) 1.2'
The variation
IBUBBLI~I ° ] ~ ] D [
of the kGS values
for different
constant
are reported
liquid flowrates
figure 6. At trickling
10 ,
/I
,,
oi..---o-i'
+
!/
a
independent
of the liquid flowrate.
Interfacial
area
The interfacial
area S was determined by
the absorption with the rapid irreversible
"1
fast pseudo first order reaction of dilute
/'
carbon dioxyde
OA 10SL('%O06801t633 2~51
o~o
o~s
(2 %) in air into aqueous
solution of sodium hydroxyde
102G(Nm 3 . s -~) o~s
regime,
linear function of the gas flowrate and is
n.5
TR~Lm "/" o
in
kGS increa-
in the studied zone, kGS is practically
"i,,',,,:./ I
regime,
ses with both L and G. At bubbling
'
0.6 #
in func-
tion of the gas flowrates
The variations
i~
of the S values
tion of L and G are reported Fig. 7. InterfacJal scrubber
(0.2N). in func-
in figure 7.
area in the multicell It is observed
that S increases with both
L and G in the trickling and bubbling flows. However at bubbling
regime,
liquid flowrate when L is higher
the interfacial
area becomes
independent
of the
than 2.5×I0 -5 m 3os -!. The area obtained with this
regime is also bigger than with the trickling
regime.
221 COMPARISON OF THE PERFORMANCES To tempt an exhaustive pes of gas-liquid rature results, necessary
confrontation
absorbers
of the various
scrubber
SCRUBBER WITH OTHER ABSORBERS
between
the performances
is very often a challenge
for this comparison.
the EUROPOLL
OF THE MULTICELL
conditions
of the different
ty-
due to the scatter of the lite-
of the tests and/or of the lack of the data
We are going to try to present now the performances
in a diagram with the plot - mass transfer
spent energy - in both trickling
and flooding
parameter versus
regimes and then to confront
formances with those of other contactors when the literature
of
these per-
data are available.
kLS parameter
k.{~L ~4./3 L"~-~L~2)
Perdreau determined powers
10-;
®/
in the EUROPOLL
the values of the scrubber necessary
to obtain the values of the liquid side mass transfer kLS reported
in figure 5.
These are comprised between
I to 2 watts
for each cell in the trickling regime and between
1.5 and 4 watts
the bubbling
regime
for each cell in
(ref. 4). It was also
shown that for a constant
dissipated
power
in each cell, the kLS value at bubbling
N
gime is thrice as high as at trickling
reregi-
me together with a liquid holdup ratio of ten. This leads to suggest the potential of the EUROPOLL
10_10_,6
10°
101
gas-liquid
10"
chemical
2 ,,,-',~ 7[P(~I L p~9~)
absorptions
employed
for oxidation
can be seen that the EUROPOLL stirred vessel and the stirred
processes
such as those of effluents or in aero-
bic fermentations. Figure 8 presents form the volumetric
in a dimensionless mass transfer
coeffi-
cient kLa as a function of the specific power requirement of the EUROPOLL
tional reactors
followed by a'slow
in the treatment
with slow kinetics
use
in the cases of
reaction processes
encountered
Fig. 8. Dimensionless form of the volumetric liquid mass transfer coefficient for various contactors I. Stirred loop reactor 2. Stirred vessel (coalescing) 3. Stirred vessel (hollow stirrer) 4. Injector 5. Stirred vessel (non coalescing) 6. Multicell scrubber
scrubber
(ref. 8). Comparing
scrubber achieves loop reactor.
and gives the location
scrubber among the convenregions
I, 5 and 6, it
same mass transfer
rates than the
222 kGS parameter The comparison of the k~S values
NG
EUROPOLL
9 8
BUBBLING
scrubber
in the
shows that the operation
at the bubbling regime results
in gas phase
efficiencies
99.6 % and
(a.3)
7
comprised
between
99.97 % while the operation ling regime results
at the trick-
in gas phase efficien-
cies comprised between 83 and 93 %. The Number of Transfer phase is plotted against
DUALFLOWTRAY
Units
in the gas
the energy dissipa-
ted per unit volume of treated gas in figure 9. It is seen that the performances the absorber
of
strictly vary with the dissipa-
ted energy for the studied gas-liquid and whatever
~ I
I
I
0.1
I
I I i i I
05
I
I
I
I
1
the flow regime. For a compari-
son with other absorbers,
(kJ. m-3)
regroups
---
5
the same diagram
the data obtained with the same
gas-liquid
system in a plate column invol-
ving 4 dual flow trays
Fig. 9. Comparison between the attainable number of gas mass transfer units for dual flow tray, packed column and multicell scrubber,
and distance between in a packed column
(diameter
the trays
(height
: 0.5 m
: 0.4 m) and
: I m, packings
are I inch and 2 inches polypropylen rings),
(ref. 9). This confrontation
for the treatment
at trickling
system
shows the potential
Pall
use of the EUROPOLL scrubber
flow regime of the gaseous effluents when an absorp-
tion with a rapid and/or instantaneous
reaction
is required.
S parameter The comparison of the dissipated
of the interfacial
(ref. 4). It was observed
that at the trickling
a = 100-200 m2.m -3 for a dissipated at the bubbling
regime,
m2.m -3 for a dissipated Moreover Nagel et al. characteristic flowrate
area in the EUROPOLL equipment
the interfacial
1 and 1.5 kW.m -3 while
the interfacial
to define a criterion
for the confrontation
bers. Using such a plot,
figure
of the EUROPOLL
shows that the EUROPOLL
10 allows
the use of another
interesting
area created per unit volumetric
and the selection
for a comparison
scrubber and other contactors.
scrubber
100 and 200
2 and 3.6 kW.m -3.
10) have proposed
diagram plotting
the order of magnitude was
area was comprised between
power comprised between (ref.
regime,
power comprised between
in function of the energy supplied per unit volumetric
performances
in function
energy per unit volume of scrubber has been made by Perdreau
is only suitable
of gas-liquid
gas
in order
absor-
to be made between
the
This working diagram
for production
transfer areas, but a such diagram is only qualitatively ted chemical system.
gas flowrate,
of average mass
valid for the investiga-
223
$/G (m~. S. m-z')
CONCLUSION
EAT cotuMN
I I
The present study shows that the
B. RPE FLOW C. COUNTERCURRENTPACKEDCOLUMN
EUROPOLL scrubber may be employed at trickling regime for the treatment of gaseous effluents containing eventually particles or dust in suspension and when a gas-liquid absorption accompanied
103
by a rapid or an instantaneous chemical reaction occurs (abatement of S02, H2S, NH3, acidic aerosols...).
I02!~ /~
It seems also
that this equipment could be employed at bubbling regime for the treatment of gas effluents by liquids where a slow chemical reaction happens (absorption of Nitrogene oxides or oxygenation of loa-
(BUBBLI~) E CELLULARSCRUBBER(TRICKLNG)
I
1010! DO _
I
P/G(kJ'm-3)
ded liquids) in trying in future to compare its performances with those of bubble columns.
10
Fig. 10. Comparison of interfacial transfer areas and specific power dissipations for any gas-liquid reactors.
Summarizing due to its flexibility depending its operating regime encountered, this new type of multicell contactor should allow to propose solutions adapted to the problems of the fight against the air pollution.
NOTATIONS a e g G kG
kL L n
NG P S V Z B PL
hL AP
interfacial area per unit volume of reactor thickness of the throat gravitational acceleration volumetric gas flowrate gas mass transfer coefficient liquid mass transfer coefficient volumetric liquid flowrate number of elementary cells number of gas mass transfer units dissipated power total interfacial area total volume of reactor height of column total liquid holdup liquid density dynamic viscosity of liquid gas pressure drop
REFERENCES 1 .
J.C. Charpentier, Mass transfer rates in gas-liquid absorbers and reactors, in Adv. Chem. Engng., Ed. T.B. Drew and T. Vermeulen, Vol. 11, Academic Press,
1981,
1-133.
224
2. 3. 4. 5. 6. 7. 8. 9. 10.
P. Boldo, A. Laurent, C. Belin and J.C° Charpentier, La Houille Blanche, 6/7 (1979) 435. S. Djerid, DEA, Nancy (1980). L. Perdreau, Th~se INPL, ENSIC, Nancy (1981). T. Takahashi, Y. Akagi and K. Fujita, J. Chem. Eng. Japan, ! (1973), 97. T. Takahashi, Y. Akagi, K. Fujita and T. Kishimoto, J. Chem. Eng. Japan, 3 (1974) 223. L. Musil, C. Prost and P. Le Goff, Chem. Ind. Ggnie Chimique, 5 (1968) 674. G. Keitel and U. Onken, Ger. Chem. Eng. 4 (1981) 250. P. Krotzsch and M. Molzahn, Ger. Chem. Eng. 3 (1980) 257. O. Nagel, B. Hegner and H. K~rten, Chem. Ing. Techn. 50 (1978), 934.