IL23539A - Liquid-liquid contactor - Google Patents

Liquid-liquid contactor

Info

Publication number
IL23539A
IL23539A IL23539A IL2353965A IL23539A IL 23539 A IL23539 A IL 23539A IL 23539 A IL23539 A IL 23539A IL 2353965 A IL2353965 A IL 2353965A IL 23539 A IL23539 A IL 23539A
Authority
IL
Israel
Prior art keywords
mixer
liquid
settler
vessel
compartment
Prior art date
Application number
IL23539A
Original Assignee
Israel Mining Ind Inst For Res
Meyer D
Baniel A
Gonen D
Blumberg R
Blumenthal R
El Roy M
Imray S
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Israel Mining Ind Inst For Res, Meyer D, Baniel A, Gonen D, Blumberg R, Blumenthal R, El Roy M, Imray S filed Critical Israel Mining Ind Inst For Res
Priority to IL23539A priority Critical patent/IL23539A/en
Priority to GB17364/66A priority patent/GB1117959A/en
Priority to US545365A priority patent/US3489526A/en
Priority to FR60976A priority patent/FR1483991A/en
Priority to NL6606628A priority patent/NL6606628A/xx
Priority to DE1557093A priority patent/DE1557093C3/en
Publication of IL23539A publication Critical patent/IL23539A/en

Links

Classifications

    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01DSEPARATION
    • B01D11/00Solvent extraction
    • B01D11/04Solvent extraction of solutions which are liquid
    • B01D11/0446Juxtaposition of mixers-settlers
    • B01D11/0457Juxtaposition of mixers-settlers comprising rotating mechanisms, e.g. mixers, mixing pumps
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01FMIXING, e.g. DISSOLVING, EMULSIFYING OR DISPERSING
    • B01F27/00Mixers with rotary stirring devices in fixed receptacles; Kneaders
    • B01F27/80Mixers with rotary stirring devices in fixed receptacles; Kneaders with stirrers rotating about a substantially vertical axis
    • B01F27/93Mixers with rotary stirring devices in fixed receptacles; Kneaders with stirrers rotating about a substantially vertical axis with rotary discs
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01FMIXING, e.g. DISSOLVING, EMULSIFYING OR DISPERSING
    • B01F27/00Mixers with rotary stirring devices in fixed receptacles; Kneaders
    • B01F27/05Stirrers
    • B01F27/11Stirrers characterised by the configuration of the stirrers
    • B01F27/19Stirrers with two or more mixing elements mounted in sequence on the same axis
    • B01F27/191Stirrers with two or more mixing elements mounted in sequence on the same axis with similar elements

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  • Chemical & Material Sciences (AREA)
  • Chemical Kinetics & Catalysis (AREA)
  • Extraction Or Liquid Replacement (AREA)
  • Structures Of Non-Positive Displacement Pumps (AREA)
  • Mixers Of The Rotary Stirring Type (AREA)

Description

A liquid-liquid contactor τοτο , »3¾na ni in ♦ mnaVi ipno C: 226J5 The present invention concerns liquid-liquid contactors of the mixer-settler type.
A large variety of mixer-settlers is described in literature. . As a rule a number of mixer-settler units consisting each of one mixer vessel and one settler vessel, are combined in series in a counter-current multistage manner to form a mixer-settler battery through which the liquids to be contacted proceed in counter-current flow.
The various mixer-settlers may be classified into three types according to the manner by which the flow of the liquid through the apparatus is brought about. In one type, generally referred to as the gravity flow type the driving force for the liquid flow is the head between the inlet and outlet. For the proper functioning of such a device the hydraulic communications between the vessels must be sufficiently large in order to minimize the flow resistance. However, by increasing the cross-sectional area of the apertures between the vessels the danger of back-mixing is equally increased. Consequently in designing a gravity flow type mixer-settler one is faced with two incompatible requirements of increasing on the one hand the cross-sectional area of the apertures between the vessels in order to reduce the flow resistance, and of decreasing on the other hand the same diameter in order to reduce the back-mixing. These incompatible requirements impose serious limitations on the design of apparatus of this type.
In another known type of mixer-settlers the flow of the liquid is brought about by pumping between stages. complicates the apparatus and renders it bulky. Moreover, the use of mechanical pumps for this purpose has the drawback of introducing additional moving parts which increases the power consumption and maintenance costs. In order to overcome this drawback it was suggested to use for the interstage pumping an airlift. This, however, has the disadvantage of causing volatilization of the solvents so that scrubbing of the air for the recovery of the solvents becomes necessary, both for reasons of economy and security. Also the introduction of air may cause undesired oxidation.
In a third type of mixer-settlers, generally referred to as the pump-mixing type, the pumping is combined with the mixing in the mixer. Here again it has been suggested to use an airlift by introducing air at the bottom of each mixer through a nozzle over which is placed a vertical lift tube. The disadvantages inherent in this method are the same as those mentioned above in connection with the use of an airlift for interstage pumping. In addition, the introduction of air during the mixing may cause the formation of fine emulsions which are difficult to separate.
Therefore, most commonly the pump-mixing in mixer-settlers of the pump-mix type is brought about mechanically in that the impeller of each mixer vessel acts as a pump for advancing the liquid to the associated settler vessel. The main disadvantage of this method is the complete coupling of the mixing and pumping functions. In conse uence the mixin has to have the same orientation as the pumping and it is, for example, impossible to combine an upward pumping with a downward thrust for mixing. Moreover, where in such an apparatus it is desired to vary the rate of flow the impeller speed has to be varied accordingly. This, however, affects the mixing. There thus exists a direct relationship between the rate of flow and the mixing which in many instances is highly inefficient since for efficient operation it may be necessary to increase the rate of flow and to decrease at the same time the mixing intensity or vice versa.
In all the three known types of mixer-settlers there exists a direct hydraulic communication between the mixer and settler vessels. In consequence the mixed liquid phase from each mixer vessel is introduced within the body of liquid present in the associated settler vessel. This in turn causes a turbulence inside the settler vessel that counteracts the phase separation in that vessel, which is manifested in an undesired increase of the turbid dispersed phase located between the clear upper and lower phases, with the result that special measures have to be taken in order to prevent the entrainment of one phase in the other. As a rule such measures consist in so dimensioning the settler vessel that each phase will always be of sufficient depth in order to prevent entrainment.
The above disadvantage inherent in hydraulio communication between mixer and settler vessels is overcome in a mixer-settler described in Ohem. and Prooess Engineering, January 1963 and November 1963. This mixer- mixer and settler vessels from each other so that the transfer of the mixed liquid phase from each mixer to the associated settler vessel is by gravity flow. This is achieved by providing on the top of each mixer vessel a tray communicating with the actual mixer chamber by a draught tube and by locating the mixer-pumping impeller inside this tube so that the mixed phase is drawn up onto the tray. Prom that tray the mixed phase is discharged by free gravity flow into the associated settler vessel from where the phases are withdrawn separately and fed to their respective mixers, again by gravity flow. While in this mixer-settler the desired hydraulic independence of mixer and settler is achieved there still remains the fundamental deficiency that the same impeller is used both for mixing and for pumping.
It is the object of the present invention to provide an improved liquid-liquid contactor of the mixer-settler type free of the disadvantages of the foregoing types.
In the following specification and claims the term "free flow" will be used for designating the discharge of liquid by gravity from one vessel into another without hydraulic communication between the liquid bodies in the two vessels.
The invention consists in a liquid-liquid contactor of the mixer-settler type including a mixer vessel comprising a lower compartment and an upper compartment separated from each other by a horizontal tube, at least one mixer impeller in the lower compartment in the region "below said draught tube, at least one pumping impeller within said draught tube adapted to lift a mixed liquid phase from the lower into the upper compartment, means for the free-flow discharge of the mixed liquid phase from the upper compartment and means for the separate introduction of two liquids into the lower compartment; a settler vessel comprising a diffuser chamber adapted to receive said mixed liquid phase arriving by free flow from the mixer vessel, a settler chamber surrounding the diffuser chamber, peripheral collector means in said settler chamber for the overflow of the light phase and means near the bottom of said settler chamber for the free-flow discharge of the heavy phase; and means leading from the upper compartment of the mixer vessel to the settler vessel adapted for the free-flow discharge of a mixed liquid phase from the former to the latter.
It is thus seen that in accordance with the invention the functions of mixing and pumping in the mixer vessel are performed separately. As a result of this functional separation it is possible to design the mixing impeller(s) for any desired mixing intensity and the pumping impeller(s) for any desired rate of flow. It is thus possible to combine a high mixing intensity with a low rate of flow or vice versa, a low mixing intensity with a high rate of fLow. It is furthermore possible to use a downthrust mixer impeller without interfering with the pumping efficiency. As mentioned before, this is impossible in cases where the same impeller is used for mixing and for pumping where the thrust is in the direction of the pumping.
The mixing and pumping impellers may be driven by the same or separate driving means. For example, the mixing impellers may be located on the bottom of the lower compartment and be driven mechanically or magnetically from below, while the shaft of the pumping impeller(s) may either depend into the draught tube from above or penetrate into it from below the mixer. Various modifications are possible in particular as regards the location and the driving of the mixing impeller(s). - In a preferred embodiment of the invention the mixer and pumping impellers are each keyed on a shaft depending from overhead driving means. In accordance with this preferred embodiment the shaft may either be common to both the mixer and pumping impellers or, alternatively, separate shafts may be provided. In the latter case the shaft for the pumping impeller(s) may be hollow and loosely envelope the shaft for the mixer impeller, possibly with interposition of suitable bearings. If desired the two shafts may be co-axial.
Where in accordance with the invention separate shafts are provided for the mixer and pumping impellers, different speeds of revolution may be applied which increases the versatility of the mixer. The two shafts may either be linked to different driving means or alternatively to the same driving means through the intermediary of separate . speed transformer means.
The upper chamber in a mixer of a liquid-liquid shallower than the lower one and may be of a tray-like design. In addition to its primary function of enabling the free flow of the liquid from the mixer to the associated settler, the upper chamber has the additional beneficiary effect of enabling a preliminary coalescence which may contribute towards simplification of design and reduction in size of the associated settler vessel.
The diffuser of the settler vessel is constituted by liquid-permeable partitions which may be perforated, porous, slotted or shutter-like and which divide the settler vessel into an inner diffuser chamber and an outer surrounding settler chamber. These partitions function as coalescence inducers. The use of such means for the induction of the coalescence is known from conventional settler vessels but in accordance with the invention the diffuser may as a rule be of simpler design than in conventional mixer-settlers because of the preliminary coalescence taking place in the upper compartment of the mixer. Any increase of the flow resistance due to the diffuser is of no consequence because of the hydraulic independence of the mixer and settler vessels.
The principle of free-flow of the mixed liquid phase from the mixer vessel to the settler vessel enables delivery of the mixed liquid phase at any desired point across the latter. For example it is possible to locate the diffuser chamber in the centre of the settler chamber and to deliver the mixed liquid phase into the centre of the former. Such an arrangement in combination with a occupies the entire settler circumference and possibly also a peripheral withdrawal of the heavy phase gives equal flow distribution throughout the settler and eliminates the turbulence due to directional flow. Peripheral overflow also reduces to a minimum the fluid velocity at the overflow point. The low fluid velocity and elimination of turbulence permit operation with a minimum depth of clear liquid; the "secondary break" i.e. coalescence of finely dispersed droplets, can take place unhindered by turbulence or high localized fluid velocities. Such a regime permits operation with a minimum depth of clear liquor i.e. the settler capacity is increased.
In liquid-liquid extraction there exists also the problem of operation at high phase ratios. Normally such operation is possible only with recycle of one phase in order to improve ooalescence. The reduction of fluid velocity and turbulence in the proposed contactor permits operation at any required ratio.
In a preferred embodiment of a liquid-liquid contactor according to the invention there is provided a by-pass connecting the lower compartment of a mixer vessel with the settler vessel below the liquid level in either vessel under normal operational conditions, which by-pass is fitted with pressure-sensitive control means adapted to close and remain closed when the hydrostatic pressure in the mixer vessel corresponds to operational conditions, and to open when the hydrostatic pressure in that vessel exceeds the value corresponding to normal operational conditions.
Owing to the provision of the above by-pass the flow of liquids through a particular contactor forming part of a battery may continue even if the pumping impeller of that unit breaks down. Upon such breakdown no liquid will be pumped up into the upper mixer compartment while the introduction of liquid into the lower compartment will continue. In consequence the hydrostatic pressure in the lower compartment will rise and eventually the control means of the by-pass will open and the excess liquid be discharged into the associated settler. When upon this discharge the liquid level in the mixer returns to normal the control means of the by-pass will close again. Where the breakdown of the pumping impeller is not accompanied by a breakdown of the mixer impeller the effect of the by-pass is that the particular contactor concerned is temporarily converted into a conventional gravity-flow unit with direct hydraulic communication between the mixer and settler vessels. Where, on the other hand, the breakdown of the pumping impeller is accompanied by a breakdown of the mixer impeller the effect of the by-pass is a temporary complete cut-out of the particular contactor concerned. In either case the remaining contactors of the battery will continue to function normally, the consequence being a temporary reduction of the total extraction efficiency of the battery which in many industrial operations is preferable to a total interruption of operation.
It follows from the above that a liquid-liquid contactor of the mixer-settler type according to the (a) Free flow from and into each mixer and settler vessel with no hydraulic communications between the vessels and equal flow distribution inside the settler vessel. There is thus no danger of back mixing and the turbulence in the settler vessels is greatly reduced. Consequently each phase may be shallow without danger of entrainment, which means that the size of the settler vessels may be considerably smaller than the size of a corresponding vessel in a conventional apparatus designed for the same through-flow. (b) The use of a pump-mix unit avoiding thereby the introduction of interstage vessels and/or pumps. (c) The separation of the mixing and pumping functions so that each may be performed independently according to its own requirements.
The free flow conditions obtaining in a liquid-liquid contactor acoording to the invention lead to a further great advantage in that they ensure a far-reaching similarity between model and prototype. Such a similarity is, as is well known, difficult if at all possible to achieve in conventional equipment of this kind. Consequently in the design of a liquid-liquid contactor according to the invention the upsealing does not constitute a serious problem as it does in conventional mixer-settlers.
The invention further provides for use in a liquid-liquid contactor as hereinbefore defined, a mixer vessel which oomprises a lower compartment and an upper comartment se arated from each other b a horizontal tube, · t · least one mixer impelle in the lower compartment in the .region .below said draught tube, at least one pumping impeller within said draught tube adapted to lift a mixed · liquid phase from the lower into the. upper compartment, means for .the free-flow discharge, of the mixed liquid, phase from ,' the. upper compartment and means for the separate introduction of two liquids into the lower' compartments. \. s- .'.The invention also "provides for .use in a liquid- liquid contactor as hereinbefore defined a- settler vessel .which comprises a 'diffuser chamber adapted to receive said mixed liquid phase arrivin ' by . free flow fro.m the- mixer vessel, a settler chamber surrounding the. diffuser chamber, peripheral collector means in said settle chamber for the overflo of the light phase and means near the bottom "of · said settler chamber- for the free^-flow discharge of the heavy phase. · ■ : .
' - Finally the invention, also provides liquid-liquid contactor batteries wherein a number of liquid-liquid ■ contactors .as hereinbefore defined are 'combined , in a multi- . stage : countercurrent manner with' free;-flow interstage . liquid-transfer. ■' . - . ';. .. ' "' ' ., . ■ ' . .The invention is illustrated, by. ay of example n3 in the accompanying' drawings in which:'' ·'. -Pig. 1 is a diagrammatic section .of a mixer for a liquid-liquid contactor according to the invention; ..Fig. 2 :is a diagrammatic section of one . embodiment Qf a liquid-liquid, contactor according to the invention; ' Fig. 3 is a plan view of. the contactor according to Fig. 2 with the cqver of the settler removed; Fig. 4 is a plan view of another embodiment of a ■ liquid-liquid contactor according to the invention;, and The mixer illustrated in Pig. 1 comprises a lower, mixing compartment 1 and an upper, substantially-flat compartment 2 separated from each other by a horizontal partition 3 which in its centre merges into a depending draught tube 4. The lower compartment 1 comprises ports 5 and 6 for the introduction of the two liquids to be contacted in the mixer. The level of the liquid body inside compartment 1 under normal operational conditions is indicated by the horizontal hyf& A shaft 8 connected to an overhead driving motor (not shown) extends through tube 4. On the lower end of shaft 8 outside of tube 4 is keyed a mixer impeller 11. Also keyed on the same shaft and located within tube 4 is a pumping impeller 12 situated between straightening vanes 9 and 0 forming an integral part of the pump.
During operation the two liquids that are to be contacted in the mixer are introduced into compartment 1 through ports 5 and 6 and are intimately mixed inside the compartment by means of the mixer impeller 11. Prom compartment 1 the mixed liquid phase is lifted by the submerged pumping impeller 12 to the upper chamber 2 from where it is discharged through port 7. The design of each of the impellers' 11 and 12 is such as to meet its requirements. Thus the mixer impeller 11 is designed for be exchangeable or adjustable in order to meet varying requirements. Likewise the pumping impeller 12 is designed to meet the desired flow requirements which may be selected in complete independence of the mixing requirements. Also in this case the impeller may be adjustable or exchangeable. It is thus possible to combine a high mixing intensity with a low rate of flow or vice versa.
In the embodiment of the mixer illustrated in Fig. 1 the mixer impeller 11 and the pumping impeller 12 are keyed on a common shaft. If desired, this design may be modified by having the impellers 11 and 12 keyed on separate shafts, the one for the pumping impeller 12 being hollow and loosely enveloping the one of the mixing impeller 1 , if desired with the interposition of suitable bearings. In this manner the two impellers may be revolved at different speeds which is a further contribution towards the versatility of the mixer according to the invention.
A further modification consists in using two or more pumping impellers located one above the other within the draught tube 4.
The liquid-liquid contactor according to the invention illustrated in Pig. 2 comprises a mixer 15 of the kind illustrated in Pig. 1 and a settler 16. The upper compartment 18 of the mixer is connected by a chute 19 to a collector tray 20 of the settler, which tray comprises a discharge opening 21 located above a diffuser 22. The latter is a chamber of upright prismatic shape by slotted partitions. The chamber may also be circular.
The lower portion of mixer compartment 17 communicates with the lower portion of settler 16 by means of a horizontal by-pass pipe 23 fitted at the end opening into the settler with a pressure sensitive shutting device 24 adapted to close and remain closed when the hydrostatic pressure in compartment 17 corresponds to operational conditions. If for some reason the liquid level inside compartment 17 rises so that the hydrostatic pressure exerted on the device 24 is increased, the latter will open and liquid will flow from compartment 17 into settler 16.
Settler 16 further comprises an upper peripheral duct 25 for the collection and free-flow discharge of the upper, lighter phase. Near its bottom the settler 16 comprises a luted port 26 for the discharge of the heavy phase. From above settler 16 is covered by a cover 27 inserted into a liquid seal 28. For operation a number of units according to Figs. 2 and 3 are combined into a multistage counter-current battery.
During operation the two liquids to be contacted are fed into each mixer at a properly selected rate. The mixed phase is pumped from each compartment 17 into the upper compartment 18 where a preliminary coalescence occurs and from where the liquid flows freely through chute 19 onto the collector plate 20 from where it is discharged by free fall through opening 21 into the diffuser 22. From the latter the liquid diffuses through the partitions into the surrounding main portion of the phases is induced. In the mai portion of the settler, ' vessel phase separation occurs and the upper phase overflows into duct '25 from where it is discharged while the lower phase is discharged from port '26. Each of the two phases is conducted by free flow into another coordinated mixe . in accordance with the counter-flow scheme.
If in operation the pumping impeller of the mixer ceases to operate, e.g. because of a breakdown of the driving motor, no .liquid will be lifted into the upper compartment 18.. Assumin , he remaining contactors of the 'same battery to- continue to operate, further quantities of liquid will be introduced into compartment !17. so that the , liquid level in that compartment will gradually rise.
Eventually the hydrostatic pressure exerted on the shutting device 24 will have increased to such an extent that this device will, open and some of the liquid inside mixer compartment 17 will be discharged .into settler 16 through by-pass 23. In this manner the flow of the liquid through the contactor unit is ensured and the battery as a whole may continue to operate. : - * The embodiment of a liquid-liquid contactor illustrated in Figs. 4 and 5 is basically similar to thai aocording to Figs. 2 and 3 and differs therefrom merely by the faot that the mixer, vesse is located''withi-ri the settler.
As shown the mixer vessel 30 is identical to the, one aooordin to Fig. 1 , comprising a mixing compartment 31. and an upper oompartment 32, which latter comprisee diecharge openings 33. Vessel 30 is located within diffuser 34. of settler vessel 35. Settler vessel 35 comprises a , peripheral duct 36 for the collection and free-flow discharge of the upper, lighter phase, and near its bottom a luted port 37 for the discharge of the heavy ' phase. . ·*· Ducts 38 and 39 lead into the mixing compartment 31. and serve for the introduction of the two phases to be contacted.
Vessel 30 comprises a spout 40 leading into . diffuser 34 and fitted with a pressure sensitive shutter 41.. The function of spout 40 and shutter 41 is completely analogous to by-pass pipe 23 and shutter 24 of the embodiment of Figs. 2 and 3.
The functioning of this device is fully ; identical to the functioning of the device according to Pigs. 2 and 3 and need therefore not be described.

Claims (14)

HAVING- NOW particularly described and ascertained the nature of our said invention and in what manner the same is to be performed, we declare that what we claim is:
1. A liquid-liquid contactor of the mixer-settler type including a mixer vessel comprising a lower compartment and an upper compartment separated from each other by a horizontal partition merging in its centre into a depending draught tube, at least one mixer impeller in the. lower compartment in the region below said draught tube, at least one pumping impeller within said draught tube adapted to lift the mixed liquid phase from the lower into the upper compartment, means for the free-flow discharge of the mixed phase from the upper compartment and means for the separate introduction of two liquids into the lower compartment; a settler vessel comprising a diffuser chamber adapted to receive said mixed liquid phase arriving by free flow from the mixer vessel, a settler chamber surrounding the diffuser chamber, peripheral collector means in said settler chamber in the overflow of the light phase and means near the bottom of said settler chamber for the free-flow discharge of the heavy phase; and means leading from the upper compartment of the mixer vessel to the settler vessel adapted for the free-flow discharge of a mixed liquid phase from the former to the latter.
2. A contactor according to Claim 1 , wherein the mixer and pumping impellers are each keyed on a shaft depending from overhead driving means.
3. A contactor accordin to Claim 2 wherein the
4. A contactor according to Claim 2, wherein the pumping and mixing impellers are keyed on separate shafts.
5. A contactor according to Claim 4, wherein the shaft of the pumping impellers is hollow and envelops loosely the shaft of the mixing impeller.
6. A contactor according to any one of the preceding claims, comprising a by-pass connecting the lower mixer compartment with the settler below the liquid level in either vessel under normal operational conditions, which by-pass is fitted with pressure-sensitive flow control means adapted to close and remain closed when the hydrostatic pressure in the mixer compartment corresponds to normal operational conditions, and to open when the hydrostatic pressure in the mixer compartment exceeds the value corresponding to normal operational conditions.
7. A liquid-liquid contactor according to Claim 1 , substantially as described.
8. For use in a liquid-liquid contactor according to Claim 1 , a mixer vessel comprising a lower compartment and an upper compartment separated from each other by a horizontal partition merging in its centre into a depending draught tube, at least one mixer impeller in the lower compartment in the region below said draught tube, at least one pumping impeller within said draught tube adapted to lift a mixed liquid phase from the lower into the upper compartment, means for the free-flow discharge of the mixed liquid phase from the upper
9. A mixer vessel according to Claim 8, wherein the mixer and pumping impellers are each keyed on a shaft depending from overhead driving means.
10.. A mixer vessel according to Glaim 9» wherein the pumping and mixing impellers are keyed on a common shaft.
11. A mixer vessel according to Claim 9» wherein the pumping and mixing impellers are keyed on separate shafts .
12. A mixer vessel according to Claim 11, wherein the shaft of the pumping impellers is hollow and envelops loosely the shaft of the mixing impeller.
13. 3. For use in a liquid-liquid contactor according to Claim 1 , a settler vessel comprising a diffuser chamber adapted to receive said mixed liquid phase arriving by free flow from the mixer vessel, a settler chamber surrounding the diffuser chamber, peripheral collector means in said settler chamber far the overflow of the light phase and mea/sn near the bottom of said settler chamber for the free-flow discharge of the heavy phase.
14. A liquid-liquid contactor apparatus comprising a battery of liquid-liquid contactors according to any one of Claims 1 to 7 in a multistage counterr-current manner with free-flow interstage liquid transfer. Dated this 13th day of May, 1965
IL23539A 1965-05-14 1965-05-14 Liquid-liquid contactor IL23539A (en)

Priority Applications (6)

Application Number Priority Date Filing Date Title
IL23539A IL23539A (en) 1965-05-14 1965-05-14 Liquid-liquid contactor
GB17364/66A GB1117959A (en) 1965-05-14 1966-04-20 A liquid-liquid contactor
US545365A US3489526A (en) 1965-05-14 1966-04-26 Liquid-liquid contactor
FR60976A FR1483991A (en) 1965-05-14 1966-05-10 Mixer-settling device for contacting two liquids
NL6606628A NL6606628A (en) 1965-05-14 1966-05-13
DE1557093A DE1557093C3 (en) 1965-05-14 1966-05-13 Mixing and settling device for liquids

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
IL23539A IL23539A (en) 1965-05-14 1965-05-14 Liquid-liquid contactor

Publications (1)

Publication Number Publication Date
IL23539A true IL23539A (en) 1968-12-26

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IL23539A IL23539A (en) 1965-05-14 1965-05-14 Liquid-liquid contactor

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US (1) US3489526A (en)
DE (1) DE1557093C3 (en)
GB (1) GB1117959A (en)
IL (1) IL23539A (en)
NL (1) NL6606628A (en)

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Also Published As

Publication number Publication date
US3489526A (en) 1970-01-13
DE1557093A1 (en) 1970-03-12
DE1557093B2 (en) 1974-05-30
DE1557093C3 (en) 1975-01-16
NL6606628A (en) 1966-11-15
GB1117959A (en) 1968-06-26

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