DE8803095U1 - Device for contacting immiscible or partially miscible fluids - Google Patents

Description

&iacgr; :.". . 1 : '. . «uWijied Kingdom Atomic...

Description Title &igr; Device 2um Contacting

immiscible or partially miscible fluids

The invention relates to a device for contacting immiscible or partially miscible fluids and is used, for example, in solvent extraction.

According to the invention, such a device is characterized by a mixing device for mixing the fluids due to the initial kinetic energy of at least one of the fluids to produce a dispersion, further by a cyclone device for separating the fluid components of the dispersion from one another and by a contacting section for conducting the dispersion from the mixing device to the cyclone device, wherein the contacting section contains means for repeatedly or continuously changing the flow direction of the dispersion on its way from the mixing device to the cyclone device.

According to the invention, the mixing device, cyclone device and the contacting section do not require any moving parts to bring the fluids into intimate contact with one another, to stir them or to separate them, i.e. no mechanical energy is required other than that which is imposed on at least one of the fluids before it enters the mixing device. *

The mixing device may comprise a fluidic injector.

The contacting section is preferably designed so that turbulence is imposed on the dispersion and can contain turbulence-promoting elements.

The turbulence-promoting elements can be, for example, internal impact or guide bodies and/or randomly or regularly arranged packing elements within the contact section.

Preferably, the residence time of the dispersion within the contacting section is significantly longer (preferably at least one order of magnitude) than in the mixing device and/or the cyclone device.

The flow path determined by the contact section can be designed in a meandering or labyrinthine manner in order to achieve a relatively long residence time within a compact construction / during which the fluids are in intimate contact with each other.

An advantageous feature of the invention is that the residence time for intimate contact between the fluids is provided primarily by the contacting section. This provides the ability to feed the fluids into the cyclone device at a relatively high rate as desired for effective separation of the fluid components. Heretofore it has been common to feed the dispersion directly into the cyclone device with the result that the time available for intimate contact between the fluids is dictated by the feed rate into the cyclone device. Thus, attempts to ensure relatively extended residence times have resulted in reduced feed rates and hence less efficient separation, i.e. increased residence time leads to reduced separation efficiency and vice versa.

Examples of the invention are shown in the drawing.

Fig. 1 is a schematic view of the device according to the invention,

Fig. 2 a modified form of the separating section of the Fig. 3 shows another embodiment of the device,

Fig. 4 shows another embodiment of the device,

Fig. 5 is a section along the line 5-5 in Fig. 4, Fig. 6 is a schematic view of a modified Design of the contact section,

Fig. 7 is a plan view of the mixing section according to Fig. 6 and the

Figs. 8 and 9 schematic views of further Modifications of the contact section.

According to Fig. 1, two fluids, e.g. a solvent such as tributyl phosphate in an odorless kerosene dilution and an aqueous solution derived from nitric acid treatment of irradiated nuclear fuel, are mixed to effect solvent extraction of plutonium and/or uranium from the aqueous solution. One fluid is pumped via an inlet nozzle 12 so that it flows through nozzles 16 and into a nozzle 13. The fluid velocity is at a maximum in the region of the gap between the nozzles 16/13 and thus the pressure is at a minimum, whereby the second fluid is introduced into an injector 14 via an inlet 10, thus creating a dispersion of the two fluids within the injector.

The two-phase dispersion then enters the contacting section 20 which is designed to provide the necessary holding time for the extraction to proceed as far as required. If the volume of the section 20 is V cubic meters, then the holding time t is given by:

t · v/ Cf ₁ + f ₂ >,

(where f ₁ and f ₂ are volumetric flow rates (cubic meters/second) of the two phases.

ß '-' In the embodiment according to Fig. 1, the

Contacting section has an elongated chamber which contains a series of flow direction changing elements 22 which have the shape of spiral bond-like guide surfaces

' which sit on a central rod 24 so that

adjacent spiral vane sets are spiraled in opposite directions so that the dispersion periodically changes direction as it passes through the contacting chamber. Intensive mixing occurs at any point where the spiral direction changes and the contacting chamber is provided with a sufficient number of spiral vanes to maintain a high level of turbulence in the mixed phases.

After leaving the contacting chamber, the mixed phases enter a hydrocyclone 26 in a generally tangential direction to form a vortex, the cyclone 26 containing a correspondingly shaped vortex 28 which acts as a vortex finder. The swirl imposed on the fluids in the cyclone results in centrifugal separation of the two phases, one phase leaving the cyclone via an outlet 30 and the other phase via the vortex finder 28.

Since the holding time required to effect the desired degree of intimate contact between the phases is primarily determined by the contacting section 20, it will be understood that the flow velocity of the dispersion upon entering the cyclone 26 may be relatively high, thereby promoting effective separation of the phases.

Fig. 2 shows an alternative cyclone arrangement in which the cyclone is disposed generally coaxially within the contacting chamber 20 to create an in-line geometry. The mixed phases enter the cyclone 26 via a tangentially extending inlet opening 32. One phase exits the assembly via the discharge pipe 26 while the other phase exits via the vortex finder 34. In this embodiment, the spiral vane sets 22 are arranged such that the last set, ie the set closest to the cyclone 26, imparts a swirl to the mixed phases in a direction consistent with the tangential inlet opening 32 so that the fluids naturally spiral into the opening 32 and thence into the cyclone 26.

Fig. 3 shows a further modification in which the injector 14 is arranged transversely to the contact chamber 20 so that one phase can leave the cyclone 26 via an extension which extends longitudinally through the contact chamber 20 and serves to carry the spiral guide surfaces 22.

Figures 4 and 5 show an alternative embodiment of a contacting section 40 which connects the injector 14 and the cyclone 26. In this embodiment, the contacting section provides a flow path (see arrows) which runs spirally around the cyclone 26, so that a compact construction is created, the flow path being defined by a spiral guide surface.

■ &igr; 11 Il III« ·· · · »·'< ■ Il Il · <· · · « ·

ti Il I · < · Il · · ··

&bull; Il Il I fl 1**4 *

I ··«··· ill « I

&bull;I I* I* I· I* I* ·*·

·« »t tt IMI »· ··

42. At the innermost end of the spiral flow path, the mixed fluids enter the cyclone tangentially through an inlet opening 44, with one phase exiting through the vortex finder 28 and the other through an outlet 30. If desired, the arrangement can also be made so that the mixed fluids enter from the injector in the center of the spiral and exit at its periphery to enter the cyclone tangentially (see Fig. 9).

6 and 7, the contacting section 60 is in the form of a drum, the injector 14 being arranged to introduce the dispersion into the central region of the drum, the interior of the drum being provided with generally radial baffles 62, 64, the outer ends and inner ends of which terminate just before the inner wall 66 and the outer wall 68 of the drum, respectively, to create a labyrinthine flow channel (as indicated by arrows in Fig. 6) extending from an inlet opening 70 to an outlet 72, the outlet being connected to the cyclone (not shown). Such a baffle arrangement defines a radially undulating flow path and indicates that a high degree of turbulence is present each time

v change in flow direction is generated, this serves to maintain the dispersion of one phase with the other. According to Figs. 6 and 7, the injector is connected to the central region of the contacting section, while the cyclone is connected to its peripheral region; the arrangement can also be reversed, i.e. the injector at the periphery and the cyclone in the middle.

Fig. 8 shows a further modification of a contact section 80 in which inner guide surfaces 82 form a labyrinthine form of the dispersion flow. The guide surfaces 82 are arranged in such a way that they form a series of annular flow channels which are connected to one another via openings 84 which are circumferentially separated by a

annular channel are arranged offset from the next, the fluids entering each annular channel being forced to flow in both directions over an angle of the order of 90° before they have a chance to enter the next annular channel. Again, the injector and the cyclone can each be arranged in the middle or at the periphery of the contacting section, as shown in Fig., or vice versa.

In any of the described embodiments, the contacting section may additionally contain randomly poured or ordered packing materials in the flow path of a dispersion through the contacting section.

Claims (12)

f ' : ir": * &Igr;&Ggr;. ': * furtitjed Kingdom Atomic Protection Claims 1. Device for contacting immiscible or partially miscible fluids, characterized by a mixing device C14) for mixing the fluids due to the initial kinetic energy of at least one of the fluids to produce a dispersion, by a cyclone device (26) for separating the fluid components of the dispersion from one another and by a contacting section (20) for conducting the &Ggr;\ Dispersion from the mixing device (14) to the cyclone device (26), wherein the contacting section (20) contains means for repeatedly or continuously changing the flow direction of the dispersion on its way from the mixing device (14) to the cyclone device (26). 2. Device according to claim 1, characterized in that the flow path of the dispersion through the contacting section (20) is designed such that the residence time of the dispersion within the contacting section (20) is longer than in the mixing device (14) and/or cyclone device (26). V' 3. Device according to claim 2, characterized in that the residence time within the contacting section (20) is at least one order of magnitude longer than in the mixing and/or cyclone device (14 or 26). 4. Device according to one of claims 1 to 3, characterized in that the flow path through the contacting section (20) is designed in a meandering or labyrinthine shape. 5. Device according to one of claims 1 to 4 / characterized in that the contacting section (20) contains irregularly or regularly arranged packing elements or materials 1m along the flow path of the dispersion. 6. Device according to one of claims 1 to 5, characterized in that the cyclone device (26) extends at least partially into the contacting section (20). 7. Device according to claim 6, characterized in that the flow path of the dispersion in the Contact section at least partially around the Cyclone device (26) extends around. 8. Device according to claim 6 or 7, characterized in that the axis of the vortex generated by the cyclone device (26) extends generally in the longitudinal direction of the flow path determined by the contacting section (20). 9. Device according to one of claims 1 to 5, characterized in that the contacting section (60) contains means for forcing the dispersion to flow in a path encircling the axis of the cyclone device or the niche device. ~) 10. Device according to claim 9, characterized in that the flow path extends spirally. r 11. Device according to claim 9, characterized in that the flow path extends in a helical shape. ( 12. Device according to claim 9, characterized in that the flow path extends radially in a wave-like manner.