RU57138U1 - FLOATING EQUIPMENT FOR RADIOACTIVE SOLUTIONS - Google Patents

Abstract

Usage: for deep concentration of radioactive solutions to be disposed of. The essence of the utility model:

The evaporator for radioactive solutions contains a housing with a mortar chamber and a steam chamber located above it, as well as with a bottom and an upper removable cover, a heating chamber placed in a mortar chamber with an annular gap and mounted on the lid, a circulation pipe mounted on the lid of the housing a circulation pump with an impeller on the lower end of the shaft, nozzles for supplying steam and condensate, mounted on the housing cover and connected to the heating chamber by pipes, nozzles for supplying the initial solution and twater vapor, and draining the evaporated solution.

What is new in the evaporator is that the heating chamber is installed with a gap to the bottom, made circular and covering the circulation pipe fixed to the lid, in which the pump impeller is located.

In addition, the heating chamber and the circulation pipe are fixed to the lid by means of an installation pipe in which at least one hole is made. The solution chamber may be provided with a steam jacket with nozzles for supplying steam and condensate.

The shaft of the vertical pump is equipped with an additional bearing mounted on the wall of the circulation pipe and protected by a casing. The evaporator also differs in that. that the pipe for the removal of the secondary steam is placed on the wall of the steam chamber under the removable cover, and the pipe for the removal of one stripped off solution is placed on the wall of the housing above the heating chamber. The pipe for emptying can be placed on the wall of the housing above the pipe for the removal of one stripped off solution and is equipped with a pipe, the lower beveled end of which is lowered into a recess made in the lower bottom of the housing. The nozzles for supplying steam and condensate drain are each made in the form of a bend with a flange, the connecting surface of which is placed in one vertical plane with the edge of the apparatus body.

The lower end of the condensate drain pipe from the heating chamber is beveled and lowered to the bottom of the heating chamber. The steam chamber may be provided with a nozzle for supplying compressed air or steam. It is better to place the pipe for supplying the initial solution above the pipe for the removal of one stripped off solution.

Description

The utility model relates to evaporation equipment used for deep evaporation of solutions, in particular, to evaporation apparatus for concentrating radioactive wastes to be disposed of in nuclear power plants.

In the processing of radioactive materials, all basic technological equipment is located in concrete chambers or boxes equipped with appropriate protection, accessed from above through a minimum number of openings covered with slabs. To ensure the radiation safety of the operating personnel, the service time of the devices should be extremely minimal, and the main repair and cleaning work on the units of the devices should be carried out outside the camera in specially designated places. This circumstance makes special demands on the design of the apparatus: the possibility and convenience of dismantling the units subject to periodic maintenance. For evaporators, in addition, complete emptying of the processed solution (absence of stagnant zones), good washing of all internal surfaces, providing conditions for the complete mechanical cleaning of internal surfaces from deposits that occur during operation are necessary.

In the chemical and other industries for deep concentration of solutions, the evaporator with forced circulation of the solution is widely and successfully used (Chernobyl II, Machines and devices of chemical production. M; Mashinostroyenie, 1975, p. 205, Fig. 57). The apparatus comprises a heating chamber with heat exchange tubes, a separator and a circulation pump. The evaporated solution is pumped at high speed through the heat exchange tubes by the pump, which significantly reduces the formation of scale and inlays on the heat exchange and other internal surfaces, and also increases the heat transfer rate and the productivity of the apparatus through the evaporated water. The main disadvantages of this apparatus are that the circulation pump is below the level of the solution in the apparatus, and the pump shaft has a sealing device that prevents leakage of the solution through the shaft, which requires constant monitoring and maintenance. The pump and the heating chamber are installed stationary and cannot be removed to a special place for maintenance and cleaning. These shortcomings indicate that

that the device is not suitable for working with radioactive solutions and is practically not suitable for radiochemical industries.

Known evaporator with forced circulation, designed to evaporate the radioactive effluents of nuclear power plants (see US patent No. 3933576, IPC B 01 D 1/26, 1976). The description of the invention includes three versions of the apparatus, shown in figures 3, 5 and 6. All options contain the main components: a heating chamber with heat exchange tubes, an evaporator (separator body) with a solution chamber and a steam chamber located above it, as well as with a bottom and with top removable cover, circulation pipe and vertical circulation pump. In the first embodiment of the apparatus, shown in figure 3 of the US patent, all the main nodes are placed separately and interconnected by pipes with detachable elements. The heating chamber contains a bundle of heat exchange tubes fixed in tube sheets and enclosed in a casing with a removable cover, on which pipes for supplying steam, condensate and non-condensing gases are placed, passing through the upper tube sheet and bonded to it. This allows, together with the lid, to remove the entire tube bundle assembly from the apparatus for inspection and, if necessary, for cleaning and repairing the tubes. The electric motor and gearbox of the vertical pump are mounted on the upper removable cover of the pumping cylindrical mortar chamber with a narrowed lower part, in which there is an impeller (propeller) mounted on the lower end of the vertical pump shaft. The upper end of the shaft is fixed in the gearbox. Between the casing of the heating chamber and the pump chamber is located the body of the evaporator (separator or evaporator), the lower part of which is occupied by the mortar chamber, and the upper one is the vapor chamber. The solution chamber is connected to the upper part of the heating chamber. The top cover of the evaporator casing is removable and serves as a mounting point for the drip eliminator. The discharge pipe of the circulation pump is in communication with the lower solution part of the heating chamber by a circulation pipe with a detachable element. On the removable lid of the evaporator body there is a nozzle for withdrawing secondary steam, and in the solution chamber below the working level of the solution, one or more nozzles for supplying the initial solution. In the bottom of the heating chamber, a pipe is provided for the removal of one stripped off solution and drainage.

The advantage of this embodiment of the apparatus is the ability to disassemble and remove from the protective chamber or box each of the main components of the device, independently of other nodes. The disadvantages of this known design are

the need for a significant area of the protective chamber to accommodate and the presence of a large number of connectors requiring maintenance.

More perfect and compact is another embodiment of the evaporator according to US patent No. 3933576, IPC B 01 D 1/26, 1976, shown in Fig.6 of the description of the invention to the patent. This design is the closest to the claimed and adopted as a prototype.

In the evaporator apparatus of the prototype, the heating chamber and the circulation pump are located directly in the body of the evaporator (separator). The casing of the tubular heating chamber is introduced through the lower bottom of the evaporator casing into the solution chamber of the latter below the working level of the solution in it. The motor and gear of the circulation pump are mounted on a removable top cover of the evaporator so that the impeller (propeller) mounted on the lower end of the vertical shaft is placed in the discharge pipe integrated in the bottom of the evaporator. A bundle of heat transfer tubes fixed in the upper and lower tube sheets and enclosed in a casing, by means of pipes for supplying steam to the heating chamber, condensate and non-condensable gases, is attached to the removable top cover using a flange connector. This makes it easy to remove the heating chamber from the evaporator body. Pipes for supplying steam, condensate and gas drain end above the top cover with horizontally arranged flanges for connection to external communications pipes. In the upper lid of the evaporator housing there is also a pipe for outputting the secondary steam. The pressure port of the circulation pump is connected to the bottom of the heating chamber by means of a circulation pipe with a connector. A nozzle for supplying the initial solution is located on the wall of the evaporator body below the working level of the solution, and a nozzle for removing the evaporated solution and emptying is located in the lower part of the circulation pipe.

Although the prototype apparatus is more compact than other known designs, nevertheless, in terms of compactness and other important parameters of evaporation equipment for radioactive solutions, it is far from perfect and requires a significant amount of a protective chamber to be placed, as well as time and costs for maintenance and repair. The main disadvantages of the prototype are as follows.

The heat transfer surface in the heating chamber made of heat transfer tubes is inconvenient for periodically mechanical cleaning and washing even when carrying out these operations outside the protective chamber or box. The cleaning element (brush) has to be introduced sequentially into each tube, which requires a different time for cleaning. It is difficult to control the quality of cleaning.

During deep evaporation, suspended solids inevitably form in solution (in particular, crystals of dissolved substances, scale particles), which are deposited on horizontal and inclined surfaces inside the apparatus and on the circulation pipes. When emptying, deposits remain on the bottoms of the evaporator and the heating chamber, on the circulation pipelines, on the upper tube sheet. Additional cleaning and flushing of the apparatus is required to remove these deposits. The pipe for the removal of one stripped off solution and for drainage during operation of the apparatus, especially during its periodic operation, will be filled and clogged with suspended solids, causing unstable operation and frequent unplanned shutdowns of the apparatus. Due to the predisposition to blockage of drainage communications, the solution provided for in the prototype to remove the solution during stops by free draining will not provide a reliable and efficient emptying of the apparatus.

The placement of the secondary steam outlet pipe on the cover of the evaporator case complicates the removal of the cover for simultaneous removal of the heating chamber and the circulation pump, since it is necessary to release the flange connector not only on the cover, but also the flange connector of this pipe, as well as to dismantle the adjacent portion of the external output communication pipe secondary steam. Similarly, the operation of extracting the tube bundle of the heating chamber is complicated due to the need to free the pipe connectors from the flanges of the apparatus from the bolts and to dismantle the sections of external communication pipes adjacent to these flanges and hanging from above. Practice shows that during the operation of propeller pumps, in which the propeller is mounted on the end of a long shaft, pumping a viscous liquid or a solution with a high content of suspended solid phase, there are radial vibrations of the shaft. In the evaporator apparatus of the prototype due to fluctuations in the density of the pumped solution, this phenomenon will be observed. In this case, the impeller with the edges of the blades will touch the walls of the apparatus, as a result of which the impeller blades may be destroyed.

The disadvantage of the apparatus of the prototype is also the location of the supply pipe of the initial solution on the evaporator body below the working level of the solution. If the supply of the initial solution to the apparatus is stopped for any reason (failure of the feed pump, violation of the tightness of the external supply lines, etc.), the device spontaneously empties through the supply line, which can lead to an emergency.

The proposed technical solution is aimed at eliminating the above disadvantages. The study of the characteristics of radiochemical industries, patterns

deep concentration by evaporation of radioactive wastewater, operating experience and maintenance procedures for similar equipment allowed the authors to realize the goal of the utility model - to create a highly efficient evaporator of a new design: more compact, simple and reliable, as well as high-performance by reducing the number of connectors and thereby reducing shutdown time and cleaning the unit, increasing the inter-flushing period and preventing situations requiring unplanned stops. The new device can be quickly mounted, easily put into operation, quickly remove individual components and troubleshoot in comfortable conditions, reducing the duration of the shutdown.

The inventive evaporator, as well as the prototype, contains a housing with a mortar chamber and a steam chamber located above it, as well as with a bottom and an upper removable cover, a heating chamber placed in a mortar chamber with an annular gap and fixed to the lid, a circulation pipe mounted on circulating pump with an impeller on the lower end of the shaft, nozzles for supplying steam and condensate, installed on the housing cover and connected to the heating chamber with pipes, pipes for supplying the initial solution and outlet and vapor, and draining the evaporated solution.

A new technical result is achieved due to the fact that the heating chamber is installed with a gap to the bottom, made circular and covering the circulation pipe mounted on the lid, in which the pump impeller is located.

In addition, the inventive apparatus differs from the prototype in that the heating chamber and the circulation pipe can be fixed to the cover by means of an installation pipe in which at least one hole is made. The solution chamber may be provided with a steam jacket with nozzles for supplying steam and condensate. The pump shaft is equipped with an additional bearing mounted on the wall of the circulation pipe and protected by a casing. A pipe for the removal of secondary steam is placed on the wall of the steam chamber under a removable cover. The pipe for the removal of one stripped off solution is placed in the wall of the housing above the heating chamber.

The discharge pipe is placed on the wall of the housing above the pipe for the removal of one stripped off solution and is equipped with a pipe, the lower beveled end of which is lowered into a recess made in the lower bottom of the housing. The nozzles for supplying steam and condensate drain are each made in the form of a bend with a flange, the connecting surface of which is placed in one vertical plane with

the edge of the apparatus. The lower end of the condensate drain pipe from the heating chamber is beveled and lowered to the bottom of the heating chamber. The steam chamber is equipped with a nozzle for supplying compressed air or steam. A nozzle for supplying the initial solution is located above the nozzle for the removal of one stripped off solution.

The inventive utility model meets the criteria of patentability.

It has novelty, as from the prior art the applicants have not identified a technical solution characterized by the same set of essential features.

The utility model is industrially applicable, since the evaporator and all its signs are feasible and reproducible; nothing in the proposed technical solution does not contradict and does not interfere with their use in industrial production with the achievement of the expected technical result.

Proof of this - the following description of the design of the evaporator and its operation.

The attached to the description of the invention, the figure shows an embodiment of the claimed technical solution.

The evaporator for radioactive solutions contains a housing 1 with a solution chamber 2 and a steam chamber 3 placed above it, as well as with a lower elliptical bottom 4 and with an upper removable cover 5. The diameter of the solution chamber 2 may be less than the diameter of the steam chamber 3. The cover 5 may be made flat and mounted using a flange connector on the housing 1. To do this, on the upper end of the housing 1, a mounting ring is welded. Inside the mortar chamber 2 with an annular gap 7 to its wall and with a gap to the lower bottom 4 there is an annular heating chamber 6. It can be made, for example, of two coaxially located thin-walled cylinders (shells or pipes). The outer cylinder is hermetically attached to the inner annular bottoms. In this case, the inner cylinder (shell or pipe) may be slightly higher than the outer, protrudes above the upper bottom and forms a circulation pipe 8.

Thus, the annular heating chamber 6 is placed around the circulation pipe 8, covering it. The circulation pipe 8 can be installed in the center (axis) of the housing 1. The heating chamber 6 is mounted on the cover 5, for example, by means of an installation (support) pipe 9, which is a continuation of the circulation pipe 8 and rigidly connected with the top edge to the cover 5. B in this case, the circulation pipe 8 and the installation pipe 9 are a single unit. At the same time, holes 10 are made in the wall of this whole pipe. The fastening of the circulation pipe 8 can

to be different. For example, instead of the installation pipe 9, rods, rolling profiles, and the like can be used.

A circulating pump is installed on the cover 5, containing an electric motor 11, a vertical shaft 12, at the lower end of which an impeller (propeller) 13 is fixed, which is placed in the circulation pipe 8. The position of the lower end of the shaft 12 is fixed by a bearing 14 mounted on the inner wall of the circulation pipe 8. The bearing 14 and the pump shaft 12 are protected by a pipe - casing 15. The circulation pump is mounted on the cover 5 by means of a support ring 16 through a flange connector.

The solution chamber 2 can be equipped with a steam jacket 17 with nozzles 18 for supplying steam and 19 for draining condensate. On the side wall of the housing 1 above the heating chamber 6, at the level of the upper edge of the circulation pipe 8, a nozzle 20 is located for withdrawing one stripped off solution. The holes 10 in the wall of the installation pipe 9 are made at the level of the nozzle 20. For supplying heating steam 6 to the heating chamber 6, a nozzle 21 is provided on the cover 5 and a pipe 22 which is hermetically passed through the upper annular bottom of the heating chamber 6 and a removable cover 5. For removal condensate from the heating chamber 6 is the pipe 23 mounted on the cover 5, and the pipe 24, passed through the cover 5 and the upper annular bottom of the chamber 6. The lower end of the pipe 24 is lowered to the bottom of the heating chamber 6 and beveled at an angle to the bottom. The nozzles 21 and 23 are each made in the form of a bend with a flange, the connecting surface of which is placed in one vertical plane with the edge of the apparatus body. It is advisable to place the pipes 22 and 24 diametrically opposite.

On the wall of the housing 1 under the cover 5, nozzles 25 are provided for outputting the secondary steam, 26 for supplying compressed air or steam, 27 for supplying the initial solution. Also on the side wall of the housing 1 above the pipe 20 for the output of one stripped off solution is a pipe 28 for emptying the apparatus. The pipe 28 is equipped with a pipe 29, the lower end of which is lowered to the bottom 4. A recess 30 is provided in the bottom 4. If the end of the pipe 29 is angled beveled and lowered into the recess 30, then the emptying of the apparatus will be more complete.

The inventive evaporator operates as follows.

Through the nozzle 27, the solution chamber 2 is filled with the initial solution to the working level determined by the nozzle 20 for withdrawing one stripped off solution, and the circulation pump is turned on. Through the pipe 21 in the heating chamber 6 serves heating steam and create working pressure in it. On external communications, shut-off devices are opened: on the condensate drain pipe from the heating chamber 6, connected to

the pipe 23, as well as on the secondary steam discharge pipe in communication with the pipe 25. As the solution level decreases in the chamber 2, the initial solution is added. Under the influence of the rotating impeller 13 of the circulation pump, the evaporated solution from the circulation pipe 8 is pumped down under the heating chamber 6, from where the solution moves upward in the annular gap 7 between the heated walls of the heating 6 and the solution 2 of the chambers. Moving upward, the solution heats up and slightly overheats with the heat of steam condensing in the heating chamber 6 and in the steam jacket 17. Leaving the gap 7, the superheated solution boils. The resulting steam rises up into the steam chamber 3 and is discharged from the apparatus through the nozzle 25, and the boiled solution flows through the openings 10 into the circulation pipe 8, where it is also heated by the steam of the heating chamber 6, covering the pipe 8. Then the solution is again pumped into the annular gap by the pump 7. Upon reaching a predetermined concentration of dissolved substances in the evaporated solution, the supply of the initial solution is controlled so that part of the evaporated solution is discharged from the apparatus through the pipe 20. Heating steam condenses I am on the outer and inner walls of the heating chamber 6, condensate flows down and through the pipe 24 through the pipe 23 is discharged from the apparatus. Non-condensing gases are discharged from the heating chamber along the same pipe along with condensate.

Distinctive features of the proposed technical solution provide the evaporation apparatus with significant advantages compared with the known ones, including the prototype apparatus.

In the annular heating chamber 6 of the "pipe in pipe" type, there is less hydraulic resistance to the movement of the evaporated solution created by the circulation pump. Therefore, ceteris paribus, the speed of movement of the solution along the heat transfer surface in the inventive apparatus is greater than in pipe heat exchangers, which provides a higher intensity of heat transfer and reduces the rate of scale formation. In addition, this surface shape is much more convenient for mechanical descaling. The presence of a steam jacket 17 increases the heat transfer surface and helps to increase the productivity and efficiency of the apparatus. The supply of the apparatus with the installation pipe 9 increases the stability of the position of the heating chamber 6 and the circulation pump, since it firmly combines them into a single unit in which a long vertical shaft 12 with a rotating impeller 13 is fixed at the end at the end. This prevents radial runout of the shaft 12 during pump operation. The fastening of the heating chamber 6 and the circulation pump together on the removable cover 5 allows you to quickly, having disconnected only one flange connection of the cover 5, remove both nodes from the apparatus

at the same time as a single unit and, if necessary, carry out their subsequent disassembly outside the protective chamber in a suitable place for this. This speeds up dismantling and reduces machine downtime.

The proposed design of the nozzles 21 for supplying steam to the heating chamber and 23 for condensate drainage also facilitates and accelerates dismantling. The shape of the elbow and the placement of the connecting surfaces of the flanges in the same vertical plane with the wall of the apparatus body allow placing inlet pipelines not from above, but from the side of the apparatus. After separation of the flange connections, the pipelines do not interfere with the upward removal of the removable cover 5 together with the assemblies fastened to it. The absence of pipelines from above allows you to remove the entire housing 1 of the device from the protective chamber if necessary. The same technical result is facilitated by the placement of the pipe 25 for the removal of secondary steam on the wall of the housing, and not on the lid, as in the prototype. When removing the cover 5, there is no need to release the flange connector of the nozzle 25, and when removing the housing 1, only this one flange connector must be disconnected. In this case, the discharge pipe (not shown in the figure) will not interfere with the removal of the housing 1, which was the case in the prototype.

The placement of the pipe 20 to output one stripped off solution on the side eliminates its rapid overgrowth of sedimentary suspensions, as was the case in the apparatus of the prototype. One stripped off solution removed from the proposed apparatus contains only the average concentration of suspended particles, characteristic of the circulating stream, and not for the settled. This provides a longer non-stop operation of the device.

The position and design of the pipe 28 with the pipe 29 also prevent clogging them with settled sediment. Drain pipe 29 during operation of the apparatus is only partially filled, corresponding to the working level of the solution, determined by the position of the nozzle 20. Therefore, suspensions from the circulating solution do not get into it. The flow created by the circulation pump and directed downward, reaching the bottom 4, acts on its surface and on a recess 30 in it, into which the lower end of the pipe 29 is lowered, preventing the formation of deposits on the bottom and directly at the open lower end of the pipe 29. Angled ends pipes 29 and 24 allow you to completely empty the mortar 2 and heating 6 chambers.

At the end of the working cycle, the apparatus is stopped for inspection. If necessary, clean the heating surface and carry out other types of maintenance. The device can be stopped at any time for commissioning or in emergency situations. When stopped, the solution is removed from the apparatus, flushing is performed, and then flange connections are freed from the bolts and the internal components are removed. Wherein

the fastening of the removable cover 5 and the support ring 16 enables the dismantling of the heating chamber 6 and the pump at the same time, or the dismantling of one circulation pump. To stop the apparatus, the steam supply to the heating chamber 6 is shut off, the circulation pump is turned off and the feed solution is stopped. Before dismantling the main components, the apparatus is emptied, for which use compressed air or high-pressure steam. Having closed the locking devices on external communications (not shown in the figure) connected to the nozzles 27 for supplying the initial solution and 25 for the output of the secondary steam, as well as opening the locking device on the pipe to the nozzle 28, they begin supplying compressed air or steam through the nozzle 26, creating in case 1 overpressure. Under the action of a pressure differential in the housing 1 and in the external communication pipe, the solution is squeezed out through the pipe 29 and the pipe 28 until the bottom 4 is completely emptied. After that, the shut-off device to the compressed air supply pipe 26 is closed, the shut-off device on the drain pipe with the pipe 28 is closed and the shut-off device is opened a device in the pipeline to the pipe 25 for outputting the secondary steam. Similarly empty the housing 1 from the wash water.

Placing the nozzle 27 for supplying the initial solution above the level of the solution to be evaporated in the apparatus is intended to prevent the solution from entering the solution chamber 2 into external communications, tanks and the pump when the feed pump is suddenly stopped or the supply lines are not tight. This will not aggravate the emergency situation by spilling hot solution from the apparatus and prevent exposure of the heated surface of the heating chamber 6, usually accompanied by intense carbon formation.

From the foregoing, it follows that the claimed evaporator has significant advantages over known devices. Its advantages are greater compactness of the location of the main components, smaller dimensions, the absence of stagnant zones, the possibility of quick dismantling for inspection, cleaning and repair, as well as the perfect design of components and parts, which ensures a long, reliable and convenient operation of the device.

Claims (11)

1. An evaporator for radioactive solutions, comprising a housing with a solution chamber and a steam chamber placed above it, as well as with a bottom and an upper removable cover, a heating chamber placed in a solution chamber with an annular gap and fixed to the cover, a circulation pipe installed on the housing cover, a circulation pump with an impeller on the lower end of the shaft, nozzles for supplying steam and condensate drain, installed on the housing cover and communicated with pipes heating the chamber, nozzles for supplying the initial solution and a vapor outlet, and discharge the evaporated solution, characterized in that the heating chamber is installed with a gap to the lower bottom, is annular and mounted on the lid covering the downcomer, wherein the pump impeller taken. 2. The evaporator apparatus according to claim 1, characterized in that the heating chamber and the circulation pipe are fixed to the lid by means of an installation pipe in which at least one hole is made. 3. The evaporator apparatus according to claim 1, characterized in that the mortar chamber is equipped with a steam jacket with nozzles for supplying steam and condensate. 4. The evaporator apparatus according to claim 1, characterized in that the pump shaft is provided with an additional bearing mounted on the wall of the circulation pipe and protected by a casing. 5. The evaporator apparatus according to claim 1, characterized in that the pipe for removing the secondary steam is placed on the wall of the steam chamber under a removable cover. 6. The evaporator apparatus according to claim 1, characterized in that the pipe for the removal of one stripped off solution is placed on the wall of the housing above the heating chamber. 7. Evaporator according to claims 1 and 6, characterized in that the discharge pipe is placed on the wall of the housing above the pipe to drain one stripped off solution and is equipped with a pipe, the lower beveled end of which is lowered into a recess made in the lower bottom of the housing. 8. The evaporator apparatus according to claim 1, characterized in that the nozzles for supplying steam and condensate drain are each made in the form of an elbow with a flange, the connecting surface of which is placed in one vertical plane with the edge of the apparatus body. 9. The evaporator apparatus according to claim 1, characterized in that the lower end of the pipe for draining condensate from the heating chamber is beveled and lowered to the bottom of the heating chamber. 10. The evaporator according to claim 1, characterized in that the steam chamber is equipped with a pipe for supplying compressed air or steam. 11. The evaporator apparatus according to claim 1, characterized in that the pipe for supplying the initial solution is located above the pipe for removing one stripped off solution.