EA001762B1 - Oil-water filtering separator with electrostatic and magnetic water filtration - Google Patents

Abstract

1. An oil-water filtering separator, comprising body with outer and inner shells, a heater in the form of steam- water coil disposed in a gap between the shells, filtering granulated filler in the form of thermally-tempered balls arranged in the internal space of the inner shell in its bottom part, gravity oil settler and a tank for purified water, a branch pipe for feeding cleaning water, a branch pipe removing mud and sludge, branch pipe for removing oil products, a branch pipe for removing purified water, branch pipes for feeding heat carrier and removing condensate, air and safety valves, a heat-sensing device, characterized in that the separator includes an extractor and a recuperator, the body is provided with a cover and a bottom, where arranged correspondingly gravity oil settler and a collector of purified water with tangential branch pipes for feeding cleaning water connected with the outer shell moving tangentially to the circumference, branch pipes for feeding washing water and blowoff air, the cover is provided with a branch pipe for removing oil products, an air valve, wherein the extractor designed in the form of electrically-insulated cylindrical cassette, the inner space of which granulated thermally-stressed coarse filler retained from washing out by a disk perforated with longitudinal slots and arranged atop and from the bottom is retained by at least one filter of disk and edge type, a recuperator consisting of at least one electrically-insulated conic edge filter, which is under the positive potential, and toroidal magnets (constant or electric), creating magnetic field, the field vector of which is directed opposing velocity vector of the laminar stream of cleaning water, and in the bottom part of the internal space of the inner shell a granulated thermally-stressed small-sized filler is arranged, wherein at least on 1, 5?3 lower turns of the steam-water coil of the heater horizontal ribs are provided in one plane, at the end of the vertical pipe of purified water removal, arranged in the collector of purified water, a cone is provided, and in the bottom part of the internal space of the inner shell a filter of a cap and edge type is provided, radial ribs of constant heat resistance are arranged along the whole height of the inner shell from the recuperator to the filter of cap and edge type. 2. The separator as claimed in claim 1, characterized in that the filter of disk-edge type is designed in the form of perforated disks with holes displaced relative to each other to a space equal 4/5?5/6 of the filler ball diameter, the displacement is provided by distance washers enabling to close the holes. 3. The separator as claimed in claims 1 to 2, characterized in that the filter of cone and edge type is designed in the form of a perforated disk with holes, above each a cone is fastened with slots and stiffening ribs. 4. The separator as claimed in claims 1 to 3, characterized in that the filter of cap and edge type is designed in the form of a perforated disk with holes, above each a cap is fastened with slots on the cylindrical part and partially on the bottom. 5. The separator as claimed in claims 1 to 4, characterized in that the balls of the filtering filler are made of metal, glass or ceramics.

Description

The invention relates to mechanical engineering and is intended for the purification of oily waters of industrial enterprises, treatment plants, as well as bilge ship (batch) and ballast water.

Known pressure separator containing a housing with a heater placed in it, filtering with granular filler, upper and lower gravity sedimentation tanks, nozzle for supplying purified water, oil outlet pipe, purified water outlet pipe (USSR, AS No. 1526735, 1989, V 0P 17/022).

This design does not provide a sufficient depth of extraction of dispersed oil products from the volume of treated water, which makes it possible to solve the problem of environmental protection in the face of an increase in the volume of effluents discharged into industrial waters, bilge (sub-batch) and ballast water, and oil fields.

Close to the proposed device is an oil-water filter separator containing a housing with an outer and inner shells, a heater in the form of a steam-water coil placed in the gap between the inner and outer shells of the housing, a filter granular filler in the form of thermally hardened balls placed in the inner volume of the inner shell, upper and lower gravity sedimentation tanks-oil collectors, a cassette installed in the upper part of the inner shell, the outlet pipe for purified water, nozzles for supplying coolant and condensate drain, removal of separated oil products (RF patent No. 2089261 from 10.9.97)

This design does not provide a large depth of extraction of dispersed oil products from the volume of treated water, and in the case of separators on ships, during roll and keel rolling, the granular filler will move, which will lead to a deterioration in the purification ability of the separator.

The aim of the present invention is to increase the cleaning ability of the separators, providing the discharge of purified water into the waters of ports and territorial waters, rivers and lakes without the use of after-treatment devices with water purification from metals.

This goal is achieved by the fact that in the device of an oil-water filter separator containing a housing with outer and inner shells, a heater in the form of a steam-water coil placed in the gap between the shells, a filter granular filler, in the form of thermally hardened balls, placed in the inner volume of the inner shell, below is a gravity sump-oil collector and a collection of purified water, a branch pipe for supplying purified water, a deckhouse for removing dirt and sludge, a branch pipe for the withdrawal of oil products, a cartridge side of the outlet for purified water, nozzles for supplying coolant and condensate drain, air and safety valves, a temperature sensor, an extractor and a recuperator are introduced into it, the housing is equipped with a cover and a bottom, in which a gravity sump-oil collector and a reservoir for purified water with tangential nozzles for supplying purified water are placed connected to the outer shell of the casing tangentially to the circumference, the flushing water and purge air supply pipes, the oil removal pipe is installed in the lid com, an air valve, a temperature sensor, the extractor is made in the form of an electrically insulated cylindrical cartridge, the inner volume of which is filled with a granular thermally stressed filler of a large fraction, kept from being washed out from above by a disk perforated by longitudinal slots, and from below by at least one disk-gap filter, a recuperator, consisting of an electrically insulated at least one cone-slot filter under positive potential and teridal magnets (permanent or electric e) creating a magnetic field, the intensity vector of which is directed opposite to the velocity vector of the laminar flow of the water being purified, and in the lower part of the internal volume of the inner shell there is a granular thermally stressed filler of a fine fraction, moreover, at least 1.5-3 lower turns of the steam-water coil of the heater in one plane, horizontal ribs are made, a cone is mounted at the end of the vertical outlet pipe of purified water located in the collector-bottom of the purified water, and in the lower part of the inner the inner volume of the sleeve is mounted, at least one cap-gap filter, the entire height of the inner shell of the recuperator to the cap-gap filter provided with radial ribs constant heat resistance. In addition, the disk-slot filter of the separator is made in the form of perforated disks with holes installed with a shift relative to each other at a distance equal to 4/5 - 5/6 of the diameter of the filler ball by means of distance washers to ensure overlapping holes, and the cone-slot filter is made in the form of a perforated disk with holes, over each of which a cone with slots and stiffeners is fixed, while the cap-slotted filter is made in the form of a perforated disk with holes, over each of which is fixed to a cap with slots on a cylindrical surface and partially on the bottom, the balls of the filtering filler are made of metal, glass or ceramic.

The essence of the invention lies in the fact that in a device for purifying water from liquid petroleum products and metals, including the creation of centrifugal forces, heating the treated water with sludge in the field of gravitational forces and filtering it through granules of the extractor, which are at a negative potential with respect to the recuperator, laminar flow of water between the extractor and the recuperator in the electrostatic field and the magnetic field of torroidal magnets, the magnetic field vector of which is directed opposite to the velocity vector, we clear water through the slots of the cone-slot filter of the recuperator, which is under the positive potential of the same direct current source as the extractor, followed by filtering the water through granules of oleophilic material, heating is carried out in a centrifugal field with a constant temperature gradient in the counterflow mode when the water moves from below -up between the turns of a coil-type steam-water heater, located in the annular gap formed by the outer and inner shells of the housing, and cleaning in the electrostatic and m magnetic fields with filtration in a granular filler of the inner shell are produced from top to bottom in a well-laminated regime for the flow of treated water through the pore channels between the negatively charged individual granules of the extractor and the granules of the filter material of the inner shell, which is thermally hardened balls of metal, glass or ceramic, in electrostatic and magnetic fields in the space between the extractor and recuperator of the inner shell, with simultaneous tap epla metal through a purified water collection area and partially cleaned water into the bottom of the separator.

In the presence of surfactants, for example, synthetic substances or deactivators, a coagulant, for example, aluminum sulfate, is introduced into the water to be purified.

The invention also consists in the fact that in a device for purifying water from liquid petroleum products, comprising a housing with a heater, extract and recuperator in the inner shell, a granular filtering filler, a lid with a gravity settler, an oil collector, tangential nozzles for supplying purified water, specifying rotational movement water around the inner shell along the heater coil, oil product outlet pipe from the gravity sedimentation tank-oil collector, con In order to withdraw purified water from the treated water collector, the heater is made in the form of a steam-water coil, the first 1.5 - 3 turns from the bottom of which have two horizontal ribs located in the same plane to provide rotational movement of water and increase the heat exchange surface, with a lower condensate drain fitting and placed vertically in the annular gap formed by the outer and inner shells, with glands-insulators of current-carrying terminals in the outer and inner shells for supplying DC voltage to the extractor ru and the recuperator, in the upper part of the inner shell, at a predetermined distance from the upper edge, is placed, electrically insulated from the shell of the inner shell, an extractor in the form of a cylindrical cartridge with thermally quenched granular filler, the lower part of which is a disk-slot filter, and the upper part is a disk perforated with slots 4/5 - 5/6 wide of the diameter of the granule and a length ensuring the strength of the perforated disk during water recirculation to the extractor through an electrically insulated terminal mounted in the glands-insulators, a negative low voltage is supplied from the DC source, and the positive potential of the same current source is supplied through an electrically insulated terminal and glands-insulators to the cone-slot filter of the recuperator, which also prevents the granular filler from being washed out of the fine fraction during water recirculation in the separator and returns to the extractor under the influence of an electrostatic field positively charged micro- and miles-balls of oil-water emulsion, molecules and metal particles, after the extractor, one or more toroidal magnets are placed together with a cone slit filter together with a cone-slit filter, forming the cassette of the recuperator, the lower part of the inner shell is connected to the cap-slot filter to prevent the granular filler from being washed out and filled to a height of 0.75-0.85 internal volume of a small fraction of thermally quenched metal, glass or ceramic balls, the entire volume of the filter media from the recuperator to the cap-slot of the filter is divided into several volumes by vertical ribs of constant thermal resistance, excluding the movement of granular filler when the ship is rolling and transferring heat to the metal structures of the treated water collector, the ribs of constant thermal resistance are connected by welding with a perforated disk of a cap-slot filter and an inner shell, with tangential nozzles the input of the water to be cleaned is installed tangentially to the circumference of the outer shell in its lowest part, and the nozzle ud lines from the condensate heater coil are 100-250 mm higher than the tangential inlets, after 10-20 degrees against the circulation of the water being cleaned from the potential inlets in the outer shell in its lowermost part, mud and sludge removal nozzles are welded, purge nipples are connected to the outlet of the purified water air and rinsing water, and a nozzle of rinsing water for removing dirt and sludge from the annular gap formed by the outer and inner shells is connected to the inlet of the purified water.

Water heating, carried out in the field of centrifugal forces, in which the dispersion medium (water) is pushed to the outside, and the dispersed medium (oil) to the inner shells of the annular gap in conditions of countercurrent heat transfer (the coolant is supplied from top to bottom when the treated water moves from top to bottom in a spiral between turns of the steam-water coil of the heater), ensures the preservation of constant thermal resistance between the heating and the heated media, the specified temperature gradient in height, which eliminates the need for Itie annular gap convectively eddy currents and realize shared media height steam coil heater aggregate surfacing effect (deposition) providing increased depth of the extraction volume of treated water dispersed oil.

The electrostatic field created between the extractor and the recuperator attracts positively charged micro- and milli-balls of the oil product, molecules and metal particles contained in the treated water to the extractor, and the field created by toroidal magnets, the magnetic field of which is directed opposite to the outflow velocity vector of the treated water, pushes metals and milliparticles of oil from the stream, metals in the direction of the extractor, enhancing the extracting effect and thereby increasing the cleaning ability separator.

The use of thermally hardened metal, glass or ceramic balls with high oleophilic properties as filter fillers placed in the volume of the inner shell of the housing up to 0.75-0.85 of its height from the cap-slot filter to the recuperator and extractor allows the processes of orthokinetic coagulation, coalescence of individual particles of petroleum products and eliminates the need for periodic replacement of the filter material, providing a stable cleaning over time and the possibility of periodic minutes filler purification from mechanical suspensions and its volume metallochastits purge air in an upward direction, followed by additional purification with pure water in the same direction while changing the polarity opposite to the extractor or an extractor for supplying an AC high voltage.

Placing radial ribs of constant thermal resistance in the inner shell allows reducing secondary emulsification of the separated oil products by lowering the temperature of the filtering medium (oil-water) and, as a result, reducing the hydraulic resistance and increasing the cleaning ability, and also eliminates the influence of the separator tilt in any the plane to the thickness of the layer of granular filter media through which the treated water is bubbled, which ensures t stability of the cleaning ability of the separator.

The inventive design features of the separator in their totality provide the minimum weight and size characteristics of the device and almost complete purification of water from both petroleum products and metals.

Purified water, having entered the annular gap formed by the outer and inner shells of the housing, through tangential nozzles tangential to the circumference of the outer shell, having received a rotational movement, is pumped between the turns of the steam coil heater, the lower 1.5 - 3 turns of which have two horizontal ribs providing rotational movement of water around the inner shell of the separator housing and improving heat transfer. When the purified water moves from the bottom up, the coolant is supplied to the steam coil heater from top to bottom, as a result of the gradual heating of the purified water, carried out in the field of centrifugal forces while maintaining constant thermal resistance between the heating and the heated media, ensuring a given temperature gradient along the height of the steam-water coil, is realized the effect of cumulative ascent (deposition), in which large particles of the dispersion phase, together with the attached mass of the dispersed medium, entrain m lkodispersnye particles, increase the probability of their colliding with subsequent mutual fusion to a size that allow their separation from the water volume density difference under the action of shared media. Under the influence of centrifugal forces and the temperature effect, large particles of oil float along the surface from the inner shell and fall into the gravity sump-oil collector.

Heated and pre-separated water enters the gravity sump-oil collector, in the volume of which the particles of oil coagulate and are removed as they accumulate.

The post-treatment of water from the finely dispersed phase of oil products and metal is carried out in the process of filtering it through the pore channels between the granules of the filter material, which is thermally hardened balls of metal, glass, ceramics, which are at a negative potential in the extractor, and in the lower part of the inner shell with induced oleophilic properties due to thermal overvoltage of their surface, first in the extractor cassette, and then in the field of electrostatic and magnetic fields in the space between the extractor and the recuperator, and finally in the volume of the inner shell with granules of the filler of the fine fraction.

When filtering fresh water through the pore channels between the granules of the extractor filler, which are at a negative potential, at velocities corresponding to a strictly laminated flow regime, when the ascent rate of the oil particles is higher than the flow rate of water, the dispersed particles of oil products and metal, moving into successively located pores, are attracted to the surface of the balls, moisten them, and then spread on their surface with an increase in the film to a certain size. Overlapping of the pore channels with oil products prevents the solid connection of molecules and finely dispersed metal particles with filler granules and provides bubbling of the purified water through a filter layer, which is naturally supported phases: filler granules - oil product with metals.

If the saturation of the pore channels with oil products is exceeded, its excess mass due to an increase in the pressure drop and the ascent forces from the surface of the granules in the form of separate pear-shaped drops, which merge with each other during coalescence, are removed from the granular filler volume with their subsequent isolation from the volume of the treated water in the gravity settler under the influence of the forces of Archimedes (due to the difference in the densities of the separated media).

Part of the oil product droplets carried out by the flow of water from the extractor, falling into the field of action of the electrostatic and magnetic fields of the recuperator, are pushed out of the water volume into the extractor, where they are attracted to the metal structure, filler granules and discharged, as previously described, into the oil reservoir. At the final stage, the remaining finely divided part of the oil product in the treated water, flowing with a stream of water through the cone-slit filter of the recuperator, which is under the positive potential and through the toroidal magnets, after receiving a positive charge, is filtered in a granular filler of a fine fraction of the lower part of the inner shell, attracted to the surface of the balls, it flanks them in the pore channels, increases to a certain size and pops up, falling into the extractor, and then into the oil reservoir.

The cap-slot filter, acting as the bottom of the inner shell, provides not only retention of the granular filler from leaching, but also acts as a gravitational settler-accumulator of petroleum products by the internal volumes of the caps.

The water purified from oil products, dropping down the sump-collector of purified water, through a cone-shaped receiver is removed from the separator through a pipe.

The use of a cone-shaped water receiver provides a smooth increase in the flow rate.

In order to avoid secondary emulsification of already separated oil products, filtration in the lower part of the inner shell is carried out with heat removal from the filtered medium through radial fins of constant thermal resistance to the purified water and the metal structure of the purified water collector - the bottom of the separator, for which the condensate drain pipe is separated from the tangential inlets of the purified water 100 - 250 mm higher.

When the separator case is filled with purified water and if air enters the case during operation, it is removed through an automatic air valve located in the separator cover.

To prevent rupture of the separator housing, when the set pressure limit of the pump unit is exceeded, a safety valve is installed in the lower part of the outer shell of the housing.

The presence of synthetic natural surfactants or deactivators to prevent emulsification of the dispersed phase of petroleum products into the volume of the source water, the coagulant is dosed with a concentration of up to 100 mg / l.

In FIG. 1 shows a general view of a separator device; FIG. 2- section AA of FIG. 1 top view; in FIG. 3-section BB of FIG. 1 top view and a fragment of a side view; in FIG. 4- section BB of FIG. 1 top view and a fragment of a side view; in FIG. 5- section DD of FIG. 1 top view; in FIG. 6 section EE of FIG. 1 top view; in FIG. 7 section CC of FIG. 1 top view and a fragment of a side view.

The device comprises a housing having an outer 1 and an inner 2 shells forming an annular gap 3, in which a steam coil heater 4 is vertically placed, the first 1.5 - 3 turns of which have two horizontal ribs 28 from the bottom, and an extractor 6 in the form of a cylindrical cartridge with a large granular thermally stressed filler 7, located in the upper part of the inner shell 2, provided in the upper part with a perforated, longitudinal slots disk 8 (Fig. 1, 2), and in the lower part with a disk-slot filter 9 (Fig. 1, 3), made in parallel perforated disks 10 with holes mounted relative to each other at a distance of the distance washers 11 by arranging the holes of the upper and lower disks in a checkerboard pattern relative to each other, electrically insulated from the casing of the inner shell 2 by a dielectric spacer 12 and located at a negative potential of a small DC voltage supplied to the extractor through terminal 13 with the gland-insulator 14, the recuperator 15, consisting of a cone-slot filter 16, insulated from the housing filled in the form of a disk 17 with holes of large diameter, over which cones with slots 18 and stiffeners are fixed, which is under the positive potential of a small DC voltage supplied through terminal 19 with the gland-insulator 20, dielectric gasket 21, torroidal magnets 22, voltage k which is supplied through terminals 23 with gaskets-insulators.

A fine fraction of granular filler 24 is placed in the volume of the inner shell 2 to 0.75 - 0.85 of its height from the cap of the slot filter 25 (Fig. 1, 6), which is a disk 26 (Fig.6), perforated with holes of large diameter 27, above with which caps 28 are fixed with slots 29 along the entire cylindrical part of the cap and partially on its bottom, to the recuperator.

The device has a nozzle 30 for supplying coolant, a nozzle 31 for condensate drain, radial ribs 32 (FIGS. 5, 6) of constant resistance, a nozzle 33 for output of oil products and regeneration products from a gravity sump-oil collector 34, a collection of purified water 35 with a nozzle 36 for output of purified water, one end of which, placed in the collection, is equipped with a cone 37.

The device also has nozzles 38 for removing dirt and sludge, a nozzle for connecting a safety valve 39, a nozzle 40 for supplying flushing water, nozzles 41 for supplying purge air and flushing water, and tangential nozzles 42 (FIGS. 1, 5) for supplying purified water connected to the outer shell 1 housing tangent to a circle (Fig. 5), creating a rotational movement of water around the vertical axis of the separator along the coil, the air valve 43 to remove air into the atmosphere, the neck 44 for fixing the sensors products is envisaged, the upper and lower water levels, the fitting 45 for fixing the temperature sensor.

The device operates as follows.

Purified water is supplied by a low emulsification pump through tangential nozzles 42 (Figs. 1, 5) into the annular gap 3 formed by the outer 1 and inner 2 shell edges of the housing, and spiraling along the finned tubes of the coil 4 heats up, pumping from bottom to top, while the air from the inner cavity of the separator is automatically removed through the air valve 43 into the atmosphere.

The coolant is supplied to the coil heater 4 through the upper pipe 30, and condensate is removed through the lower pipe 31.

Heated and pre-separated from large particles of oil products, the water enters the gravity sump tank, in the volume of which the coarse particles of oil are coagulated and, as they accumulate, are discharged through pipe 33.

Partially purified water from petroleum products, containing positively charged micro and millichalas of the oil emulsion, through the cartridge of the extractor 6 with a perforated longitudinal slit disk 8 (Figs. 1, 2) at the top and a disco-slit filter 9 at the bottom with a thermally strained granular filler of a large fraction between them, located at a negative potential, flows from top to bottom through the electrostatic and magnetic fields formed by the extractor 6 and recuperator 15, the cone-slot filter of the recuperator 16, located under potential, and torroidal magnets 22 in the volume of the granular filler 24 of the fine fraction, while it is filtered through the pore channels between the individual granules in a strictly laminated stream.

The vectors of the magnetic field and electrostatic field are directed opposite to the flow velocity vector of the laminar flowing water downward, which leads to the expulsion of positively charged micro- and milli-balls of the oil emulsion, molecules and metal particles.

When filtering fresh water through the pore channels between the granules of the extractor filler under negative potential, metal particles and dispersed positively charged particles of oil products are attracted to the surface of the balls, moisten them, spread over their surface with an increase in the film to a certain size and sparge.

After the saturation of the pore channel with oil products is exceeded, its excess mass, due to the forces of ascent and an increase in the pressure drop, breaks off the surface of the granules in the form of separate pear-shaped drops, which merge with each other during coalescence and are removed from the granular filler volume with their subsequent separation from the volume of the refined water into the gravity sump-oil collector.

In the event that some of the micro- and milli-balls of the oil emulsion slip through the granules of the extractor, the magnetic and electrostatic fields, then passing with a stream of purified water through the cone-slot filter 16 of the recuperator, and receiving an additional positive charge, they are filtered through the pore channels between the individual granules fine fractions of the filler of the inner shell in a strictly laminated flow with the process described above.

In order to avoid secondary emulsification of the separated oil products, heat removal from the filtered water is provided by radial ribs 32 (Fig. 5, 6) of constant thermal resistance through the metal structures of the purified water collector 35 and the purified water in the lower part of the housing.

Being freed from petroleum products in an extractor, a granular filler of a fine fraction, an internal shell, water enters the collection of purified water 35 and is removed from it through a cone 37 and a pipe 36.

The invention provides a residual concentration of petroleum products in purified water up to 0.05 million ^-1 with an acceptable value of 15.0 million ^-1 , which is significantly less than the requirements of MERS 60/33 IMO, allows the discharge of purified water in the ports, territorial waters, rivers and lakes.

Claims (5)

CLAIM 1. Oil-water filter separator containing a housing with outer and inner shells, a heater in the form of a steam-water coil placed in the gap between the shells, filter granular filler, in the form of thermally hardened balls placed in the inner volume of the inner shell below, a gravity sump tank and purified water collector , a branch pipe for supplying purified water, a branch pipe for removing dirt and sludge, a branch pipe for withdrawing oil products, a branch pipe for removing purified water, a branch pipe for supplying coolant For condensate discharge and drainage, air and safety valves, a temperature sensor, characterized in that an extractor and a recuperator are introduced into it, the housing is equipped with a cover and a bottom, in which respectively a gravity sump-oil collector and a purified water collector are located with tangential pipes for supplying purified water connected to the outer shell of the housing in a tangent to the circumference, the nozzles for supplying washing water and purge air, the nozzle for removing petroleum products, an air valve, a temperature sensor, the extractor is made in the form of an electrically insulated cylindrical cartridge, the inner volume of which is filled with a granular thermally stressed filler of a large fraction, kept from being washed out from above by a disk, perforated by longitudinal slots, and from below by at least one disk-slot filter, the recuperator consists of an electrically insulated, per at least one cone-slit filter under positive potential, and torroidal magnets (permanent or electric) that create a magnetic field, the tension vector of which is directed opposite to the velocity vector of the laminar flow of purified water, and in the lower part of the internal volume of the inner shell there is a granular thermally stressed filler of a fine fraction, moreover, at least 1.5 ... 3 lower turns of the steam-water heater coil in one plane are made horizontal ribs, a cone is mounted at the end of a vertical outlet pipe of purified water, placed in the collector-bottom of the purified water, and one in the lower part of the internal volume of the inner shell cap-slot filter, along the entire height of the inner shell from the recuperator to the cap-slot filter, radial ribs of constant thermal resistance are made. 2. The separator according to claim 1, characterized in that the disco-slotted filter is made in the form of perforated disks with holes installed with a shift relative to each other at a distance equal to 4/5 - 5/6 of the diameter of the filler ball by means of distance washers with overlapping holes. 3. The separator according to claims 1 to 2, characterized in that the cone-slot filter is made in the form of a perforated disk with holes, over each of which a cone with slots and stiffeners is fixed. 4. The device according to claims 1 to 3, characterized in that the cap-slotted filter is made in the form of a perforated disk with holes, over each of which a cap with slots is fixed on a cylindrical surface and partially on the bottom. 5. The device according to claims 1 to 4, characterized in that the balls of the filtering filler are made of metal, glass or ceramic.