RU84731U1 - CENTRIFUGAL EXTRACTOR - Google Patents

Abstract

A centrifugal extractor comprising a drive, a bearing support, a housing with a mixing chamber and phase output chambers, a rotor with a separation chamber, a conveying device, a water seal, and tubes for outputting a light phase, characterized in that the extractor is equipped with a magnetic coupling, the driving coupling of which is fixed to the drive shaft , the driven half-coupling is rigidly connected to the rotor, and between the half-couplings there is a sealing screen partition connected to the housing rigidly, and with the rotor through one of the plain bearings, the bearing howl bearing, the second bearing support bearing coupled to the rotor bottom, and the water seal chamber communicates with a gap between the sealing baffle screen and the driven half coupling.

Description

The utility model relates to designs of centrifugal extractors for a liquid-liquid system, for use mainly in radiochemical industries, but can be successfully used in chemical, petrochemical, hydrometallurgical, pharmaceutical and other industries for the purification and separation of radioactive, aggressive, toxic, explosive , fire hazardous and other liquids harmful to human health and the environment.

It is known that it is most advantageous and advisable to use centrifugal extractors where they have decisive advantages over other extraction devices, that is:

- for processes requiring a short phase contact time due to the destructive effect of radioactivity on the extractant or changes in the properties of solutions over time;

- for processes requiring limitation of the volume of liquids, for example, due to the nuclear and toxic hazards of liquid media, explosion and fire hazard of the extractant;

- for processes in which viscous and slightly different in density liquids are used, prone to the formation of stable emulsions;

- for processes in which it is necessary to realize the difference in the speed of extraction of elements to increase their separation coefficients.

However, when using centrifugal extractors in working with radioactive, aggressive, toxic and other hazardous liquids, the problem arises of ensuring the tightness of extractors, namely their bodies, where the mass transfer process itself takes place. The implementation of a highly efficient mass transfer process for the separation of contacting phases in a centrifugal field requires the supply of external energy to the interacting liquids. To do this, it is necessary to equip the centrifugal extractor with an electric motor, which rotates the rotor located in the extractor housing and ensures the separation of liquids. And if the liquids being separated are radioactive, aggressive, toxic, explosive, etc., then remote maintenance of the extractors is required, for example, using various manipulators or robots and chemically and radiation-resistant electric motors, or using a protective plug in which the standard electric motor. However, in this case, not only complex seals of the bearing assembly are necessary, but also ensuring constant tightness at the junction of the electric motor (or drive shaft) with the extractor rotor.

Currently, this problem has not been solved. When conducting patent research, the applicant did not find technical solutions known from the prior art that would ensure the absolute tightness of centrifugal extractors designed for cleaning and separating liquid media, the exit of which from the apparatus into the surrounding space is unacceptable.

From the above it follows that the solution of this problem is of great importance. The need to solve the problem is also important because large-scale research work is underway to improve the technology for processing irradiated uranium-plutonium fuel with the aim of regenerating it and preparing MOX fuel for further use in nuclear reactors. This technology also provides for the extraction redistribution. But since irradiated plutonium is not only highly active, but also highly toxic, the question of creating special sealed centrifugal extractors is very relevant.

Specialists of SverdNIIkhimmash OJSC created such an extractor and is the subject of patent protection for this application.

But first, consider and analyze the analogues of the inventive centrifugal extractor.

Known centrifugal extractor (see ed. Certificate. USSR No. 1546096, class B01D 11/04, 1987), comprising a drive, a support (bearing support with rolling bearings, provided with a seal), a shaft connected to the drive shaft, a housing with a mixing chamber and phase output chambers, a conical rotor with a separation chamber, a conveying device, a water seal, tubes for outputting a light phase and a cover, the water seal being made in the form of a ring and a shell rigidly mounted, respectively, on the shaft and the support, and the shell is located between the ring and cap ro Torah. The well-known extractor "can find application in the hydrometallurgical, ... food and other industries for clarification of suspensions." Moreover, the design of this extractor really "avoids the accumulation of sediment in the rotor by carefully maintaining the flow rate of the heavy phase at a given level and to increase the productivity of the apparatus."

However, such a reactor cannot be applicable in the radiochemical industry, since using this extractor it will not be possible to solve the problem of ensuring the tightness of the apparatus body and eliminating leakage of liquid radioactive, toxic, aggressive and other harmful liquid media from the rotor, since there are no elements in its design preventing these leaks. The seal material is rapidly destroyed under the influence of liquid radioactive media, and, especially, at high rotational speeds of the rotor of the centrifugal extractor, so necessary for the implementation of a highly efficient mass transfer process. As a result, the heavy phase entering the water trap is poured not only into the chamber 3 for collecting the heavy phase, but also through the destroyed seal flows into the space surrounding the centrifugal extractor, which does not meet the radiation safety requirements and is unacceptable in real production conditions.

The closest in technical essence to the claimed one is the well-known centrifugal extractor (see book. Kuznetsova G.I., Pushkova A.A., Kosogorova A.V. "Centrifugal extractors TSENTREK", RCTU named after D.I. Mendeleev. - M ., 2000, p. 47, Fig.1.29.), Adopted as a prototype. The extractor contains a drive, a support (bearing support with rolling bearings, equipped with a seal), a housing with a mixing chamber and phase output chambers, a conical rotor with a separation chamber, a conveying device, a water seal, light phase outlet tubes and a cover.

This known apparatus has the same drawbacks as the previous one, since their designs are identical. The only difference is that the surface of the extractor water seal according to ed. testimonial. USSR No. 1546096 made conical, and in the technical solution adopted for the prototype, similar surfaces are located horizontally. And also, as in the previously described known solution, the seal at the junction of the rotor cover through the rolling bearings with the drive shaft will be destroyed under the influence of radioactive, aggressive or toxic liquids and high rotor speeds of the extractor rotor, which will cause dangerous space to leak through the destroyed seal into the centrifugal extractor surrounding substances, which is unacceptable under operating conditions.

These disadvantages of the known centrifugal extractors are absent in the inventive centrifugal extractor, the design of which provides absolute tightness, which, of course, eliminates leakage from the apparatus of liquids hazardous to humans and the environment.

The inventive centrifugal extractor, like the prototype, contains a drive, a bearing support, a housing with a mixing chamber and phase output chambers, a rotor with a separation chamber, a conveying device, a water seal, and tubes for outputting the light phase.

The centrifugal extractor is characterized in that it is equipped with a magnetic coupling, the leading coupling half of which is fixed to the drive shaft, the driven coupling half is rigidly connected to the rotor, and between the coupling halves there is a sealing screen-shield connected rigidly to the housing, and with the rotor through one of the bearing sliding bearings bearings, while the second bearing of the bearing support is mated to the bottom of the rotor, and the cavity of the valve is in communication with the gap between the sealing baffle-screen and the driven coupling half.

The claimed utility model meets all patentability criteria.

It is new, as it is unknown from the prior art (see analogues described above).

The utility model is industrially applicable, as it can be used in industry. The inventive utility model is characterized by specific design features, each of which is reproducible and does not contradict the use of a centrifugal extractor in an industrial environment. The entire set of essential features of the utility model and each feature individually is aimed at achieving the expected technical result - the absolute tightness of the extractor, eliminating the leakage of hazardous liquids involved in the extraction process.

In the presented drawing is an illustration of a specific design of the claimed utility model.

The centrifugal extractor comprises a drive 1, a bearing support with sliding bearings 2 and 3, a housing 4 with a mixing chamber 5 and chambers 6 and 7 of the output, respectively, light and heavy phases, a rotor 8 with a separation chamber 9, tubes 10 for outputting the light phase, transporting device 11, for example, with a screw, and with a water seal formed by the cover 12 of the rotor 8 and a disk 13 with holes 14. An activator 15 is placed in the cavity of the water seal. The inner surfaces of the cover 12 are equipped with scrapers 16 and 17, and the disk 13 is equipped with a scraper 18.

The extractor is equipped with a magnetic coupling, the leading coupling half 19 of which is mounted on the drive shaft 1, the driven coupling half 20 is rigidly connected to the rotor 8 through its cover 12, and between the coupling halves 19 and 20 there is a sealing screen-screen consisting of a flange 21, a thin-walled shell 22 and the bottom 23. The sealing baffle-screen is rigidly connected to the housing 4 due to the connection of the flange 21 to the flange 24 of the housing 4. The sealing baffle-screen is also connected to the rotor 8 through a sliding bearing 2, the movable sleeve 25 of which is coupled to the cover 12, and not the movable sleeve 26 is coupled to the bottom 23 of the partition screen. The second sliding bearing 3 through its movable sleeve 27 is connected with the bottom of the rotor 8, and through the stationary sleeve 28 with ribs 29 located on the wall of the mixing chamber 5. In the rotor 8 there is a crosspiece 30. The cavity of the water seal is connected with a gap 31 between the thin-walled shell 22 of the sealing screen partitions.

A mixing chamber 5 with a mixer 32 is located in the lower part of the housing 4 in the immediate vicinity of the inlet fluids 33 and 34. To output the resulting from the extraction of light and heavy phases from chambers 6 and 7, pipes 35 and 36 are used.

The operation of the inventive centrifugal extractor is as follows.

A motor is connected to the mains supply, the drive shaft begins to rotate, driving the driving coupling half 19, transmitting the rotation moment of the driven coupling half 20 through the thin-walled shell 22. The rotor 8 begins to rotate, since it is rigidly connected to the driven coupling half 20 through the cover 12.

After the rotor 8 has set a predetermined number of revolutions, the initial processed solution is through the pipe 33, and the extractant is supplied through the pipe 34 to the mixing chamber 5, where they are mixed with a mixer 32 connected to the bottom of the rotor 8

The ribs 29 located in the chamber 5 prevent the twisting of liquids in the central part of the chamber 5 during the mixing process. The emulsion formed by mixing with the screw 11 is transported to the rotor 8. Under the action of centrifugal force in the rotor 8, the emulsion is stratified in the crosspiece 30 into light and heavy phases. The light phase moves upward in the central part of the rotor 8 while the heavy phase, discarded by centrifugal force, moves upward along the inner wall of the rotor 8. The light phase reaches the level of the tubes 10 along the height of the apparatus, and since their inlet holes are in the zone of movement of the light phase in the center of the rotor 8, it, overflowing into the tubes 10, is discharged from the rotor 8 into the chamber 6, from where the light phase is removed through the pipe 35 from a centrifugal extractor. At the same time, the heavy phase, moving along the inner wall of the rotor 8, reaches the disk 13 and through the holes 14 in it enters the cavity of the hydraulic lock. Under the influence of the activator 15, the heavy phase moves to the overflow 37 and further, passing through the gaps 38, the grooves 39 in the bearing 2 and the gap 40, enters the gap 31 between the thin-walled shell 22 of the sealing screen and the driven coupling half 20. D Further heavy movement the upward phase is prevented by the flange 21 of the sealing baffle-screen, and it, forced to change direction is opposite, is poured into the chamber 7 of the output of the heavy phase, from where it is removed from the centrifugal extractor through the pipe 36. The exclusion of heavy phase clogging of the space in the upper part of the rotor 8 is carried out using scrapers 16, 17 and 18.

From the above description of the utility model in statics (see drawing) and in the work, it follows that in the inventive centrifugal extractor there is not even the slightest possibility of leaks. The sealing baffle screen prevents the penetration of liquids from the housing to the seal of the connection of the magnetic coupling to the drive shaft. The magnetic coupling that seals the baffle - the screen and sliding bearings 2 and 3 spaced apart in certain places, as well as the relationships of the listed features with the features from the restrictive part of the utility model formula, perform not only their inherent functions of ensuring rotation and the extraction process, but also create absolute tightness in the device.

In addition, the lubrication and cooling of them is necessary for the normal operation of the plain bearings. In the claimed extractor, this problem is solved: a heavy phase flow is used for the upper sliding bearing, and the emulsion formed during mixing is used for the lower sliding bearing. Thus, in the design of the claimed apparatus, everything is provided so that when used in industrial production to achieve the desired result - its absolute tightness, which eliminates leakage of the liquids involved in the process from the extractor into the environment, as well as the ingress of impurities from the outside when working with very clean liquids.

Claims (1)

A centrifugal extractor comprising a drive, a bearing support, a housing with a mixing chamber and phase output chambers, a rotor with a separation chamber, a conveying device, a water seal, and tubes for outputting a light phase, characterized in that the extractor is equipped with a magnetic coupling, the driving coupling of which is fixed to the drive shaft , the driven half-coupling is rigidly connected to the rotor, and between the half-couplings there is a sealing screen partition connected to the housing rigidly, and with the rotor through one of the plain bearings, the bearing howl bearing, the second bearing support bearing coupled to the rotor bottom, and the water seal chamber communicates with a gap between the sealing baffle screen and the driven half coupling.