RU144823U1 - FILTER MECHANICAL HIGH-TEMPERATURE AFMVT-1.0-16.0 (OPTIONS) - Google Patents

Abstract

1. High-temperature mechanical filter for removing radioactive corrosion products from an uncooled coolant in the primary reactor of a nuclear power plant, comprising a housing with a filtering unit located inside the housing and with a manhole hole located in the upper part of the body, a manhole door with a nozzle mounted on it for unloading the sorbent, a nozzle cover for unloading the sorbent, means for attaching the covers to the flanges of the nozzles and means for sealing the mating surfaces of the covers and flanges bkov, characterized in that the sealing means covers mating surfaces of the pipes and flanges are in the form of rectangular annular recesses in the flanges and the pipes installed therein gaskets from expanded grafita.2. The mechanical high-temperature filter according to claim 1, characterized in that the gaskets of thermally expanded graphite are made of graphite foil. The high-temperature mechanical filter according to claim 1, characterized in that the means for sealing the mating surfaces of the caps and flanges of the nozzles are made in the form of two concentric annular rectangular recesses on each of the flanges of the nozzles and the gaskets installed in them from thermally expanded graphite, and on the flange of the nozzle of the manhole two gaskets made of graphite foil; two gaskets made of graphite foil are installed on the flange of the nozzle for unloading the sorbent. 4. The mechanical high-temperature filter according to claim 1, characterized in that the means for attaching the caps to the flanges of the nozzles are made in the form of studs with nuts with the possibility of determining the tightening forces of the studs according to the relative

Description

Technical field

The utility model relates to the field of nuclear energy, to the technique of cleaning uncooled water coolants of the primary circuit of a reactor of a nuclear power plant, namely to devices of high-temperature mechanical filters of the coolant of the primary circuit of a nuclear power plant, for example, high-temperature mechanical filters AFMVT-1,0-16,0, designed to remove radioactive corrosion products from an uncooled coolant in the first reactor loop of a nuclear power plant.

State of the art

A known filter for liquid, mainly water of the primary circuit of nuclear power plants, including a housing with a bottom and a lid, filled with a sorbent, a loading hatch and a sorbent discharge device, characterized in that, in order to increase the efficiency of unloading a heavy sorbent, the sorbent discharge device is made in the form of a centrally installed in the lid with the possibility of vertical movement of the pipe with peripheral collecting tubes connected to its lower end by flexible cuffs. In this case, a centrally installed pipe of the sorbent discharge device is placed in the loading hatch [1].

It is known to use sponge titanium as a sorbent of radioactive corrosion products in the aqueous coolant of nuclear power plants [2].

A known installation for the treatment of radioactive waste, which to reduce the amount of radioactive waste and increase the reliability of the operation contains a continuous filter, including a housing with a bottom, a conical drainage grid, fixed with a large base on the lower part of the housing and facing a smaller base to the bottom, a node for removing the spent sorbent layer , a container for collecting the spent sorbent layer and a circulation pump. The node for removing the spent layer of the sorbent is made in the form of a cone-shaped nozzle with radial nozzles connected with a circulation pump and installed under the drainage grate and a perforated disk placed under them. The container has a drainage grid and is connected by the upper part to the body, and the lower part to the pump. The invention allows to reduce the amount of radioactive waste and increase the reliability of the installation [3].

A device for remote unloading of radioactive sorbents from high-temperature filters of the coolant of the primary circuit of a nuclear power plant, which to increase the safety and reliability of the remote discharge of radioactive sorbent from the filter into the container contains an exhaust pipe with two flanges, one of which is designed to connect it to the flange of a vertical pipe, and the second is for connecting to the flange of the conveying pipeline. The vertical pipe by means of a flange is fixedly mounted in the nozzle of the hydraulic discharge of the filter, inside it, coaxially to it, is a vertically moving inner pipe, at the end of which a collecting body is mounted, made in the form of a perforated nozzle. An annular plate is mounted on the lower end of the fixed outer tube, which forms an inner collar that prevents particles of sorbent from entering the space between the outer and inner pipes, and an annular plate is formed on the upper end of the inner tube [4].

A device is known for unloading a radioactive sorbent from a filter for cleaning water heat carriers into a container, which consists of a housing, a drive, a movable rod, a flange, a vertical movable pipe, and collecting tubes to increase safety. At the ends of the housing there are seals, and on the side surface there is a vertical slot through which a bent upper section of the movable pipe is passed, and a flange connection. By means of a flange connection, a removable box having a drain hole and a drain pipe at the bottom is hermetically attached to the housing. Inside the box is a flexible hose attached to the upper portion of the movable pipe and the inlet pipe. The inlet pipe is in communication with the drainage pipe and connected to a discharge pipe through which the sorbent enters the container [5].

A device is known for unloading a radioactive sorbent from a filter into a container, in which to increase the reliability of the device and simplify the design containing a pipe with flanges at the ends for connecting to the container flange and the sleeve flange mounted on the filter flange, a flexible hose, one end of which is connected to the end of the pipe, and the collector for collecting the radioactive sorbent from the filter, the collector for collecting the radioactive sorbent from the filter is made in the form of a concave star, the rays of which are rotary tubes and. In the center of the star, on the concavity side, a hollow cylinder is mounted symmetrically, in which a spring-loaded rod with a counterweight is installed, and the second end of the flexible hose is connected to the concave star using a flexible connection [6].

The closest in technical essence and the result achieved when using it is a high-temperature mechanical filter AFMVT-1.0-16.0, manufactured according to TU 108-11-624, where A is an apparatus for a nuclear power plant (NPP), F is a filter, M is mechanical, VT - high temperature, 1.0 - diameter of the apparatus in meters, 16.0 - working pressure in MPa [7 (prototype), 8]

The high-temperature mechanical filter AFMVT-1.0-16.0, then the AFMVT-1.0-16.0 filter, is part of the equipment of the bypass purification unit for the coolant of the primary circuit of the VVER-1000 nuclear reactor and is intended for high-temperature continuous mechanical and sorption cleaning coolant from radioactive corrosion products of structural materials of the circuit in order to reduce deposits of these products in the coolant path and reduce radiation exposure to maintenance personnel.

Structurally, the AFMVT-1.0-16.0 filter according to TU 108-11-624 consists of a cylindrical body with elliptical bottoms, lower and upper assembly-distribution devices and supports.

A hatch-manhole pipe with a removable cover is welded to the upper bottom, to which, in turn, a fitting is connected for supplying the treated water.

Pipes are welded to the bottom of the pipe to drain the coolant filtrate and drain the filter.

The upper switchgear of the “baffle plate” type serves to dampen the flow when water is supplied to the filter.

The lower collection and distribution device (filter unit) is designed to ensure uniform collection of treated water and uniform distribution of the wash water filter over the cross section. It consists of a vertical collector to which horizontal bends are attached, at the ends of which plates with slotted filter caps from a set of plates with spacer protrusions are screwed onto a threaded connection.

A nozzle for unloading the sorbent is attached to the cover of the manhole hole of the AFMVT-1.0-16.0 mechanical high-temperature filter in accordance with TU 108-11-624, which, when the AFMVT-1.0-16.0 filter is in operation, is closed by the cover of the nozzle for unloading the sorbent and in which, when replacing the sorbent, a sorbent discharge device is installed.

The manhole cover nozzle cover with a nozzle for unloading the sorbent in the AFMVT-1.0-16.0 filter according to TU 108-11-624 is attached to the manhole manhole flange with 14 studs 560 mm long, neck diameter 54 mm, thread length M72 100 mm and thread length M64 170 mm with a tightening force of 11,000 Nm.

The nozzle cover for unloading the sorbent in the AFMVT-1.0-16.0 filter according to TU 108-11-624 is attached to the flange of the nozzle for unloading the sorbent with 10 studs 258 mm long, with a neck diameter of 30 mm, M36 thread lengths of 50 mm and 84 mm with a tightening force of 1440 Nm.

When installing in the AFMVT-1.0-16.0 filter in accordance with TU 108-11-624 plates of the filter block, one of the 6 holes at the edges of the plates is used to fix them relative to each other, which allows you to wrap the filter plates in steps of 60 °.

In AFMVT-1.0-16.0 filters according to TU 108-11-624, sealing gaskets in the form of round NP-2 nickel wire in accordance with GOST 2179-75 are used to seal the connectors of the nozzles and caps.

O-rings made of nickel wire of round cross-section are laid in annular conical grooves on the flanges of nozzles with a depth of about half the diameter of the nickel-shaped wire of round cross-section and clamped with lids using studs with the required seal with a tightening force for the cover of the manhole cover - 11,000 Nm, for the cover of the nozzle for unloading sorbent - 1440 Nm.

The disadvantages of conical sealing grooves on the flanges of the nozzles and gaskets in the form of a round nickel wire are the point contact in the places of their contact, which requires significant clamping forces of the covers to ensure reliable sealing (11000 Nm for the manhole cover and 1440 Nm for the unloading nozzle cover sorbent), which deform the round nickel sealing wire and make it unsuitable for reuse.

In the manufacture of sealing gaskets in the form of a round nickel wire, increased requirements are also imposed on the quality of the metal of the nickel wire and the absence of foreign inclusions in it. Uneven mechanical properties of the metal in different parts of the nickel wire gasket lead to misalignment of the sealing surfaces, insufficient density of the joints of the detachable parts and, as a result, to undesirable leakage of the radioactive coolant.

The use of nickel gaskets is also demanding on manufacturing accuracy and the location of flange connectors.

After tightening the tie rods with the nuts with the necessary efforts and achieving a certain deformation, the metal is hardened and the sealing force increases sharply. Some time after the seal of the joint, metal relaxation occurs, the seal weakens, and tightening of the tie rods and bolts becomes necessary.

From the operating experience of the AFMVT-1.0-16.0 filter according to TU 108-11-624 it is also known that sealing with nickel gaskets worsens its sealing properties during cyclic temperature changes.

When decompressing the lid fasteners, a complex and laborious extraction of deformed nickel gaskets is required with the risk of damage to the sealing surfaces.

At the same time, it is important to ensure the reliability of the seals of the joints of the detachable parts of the mechanical high-temperature filter to remove radioactive corrosion products from the uncooled coolant in the primary reactor of a nuclear power plant, since it is used to clean the radioactive coolant. In particular, the failure criteria of the AFMVT-1.0-16.0 filter are considered to be a violation of the tightness of the housing, flange connections, connections of caps and nozzles, which led to the exit of the coolant into the surrounding space.

It is also known to use thermally expanded graphite for flange gaskets in reinforcing equipment, including for connecting parts of pipelines, however, examples of using thermally expanded graphite to seal detachable joints of high-temperature mechanical filters operating in radiation conditions at high temperatures and high coolant pressures do not detected.

Task and technical result

The objective of the patented utility model and the technical result obtained from the use of the patented utility model is to increase the manufacturability and assembly / disassembly of a high-temperature mechanical filter to remove radioactive corrosion products from uncooled coolant in the primary reactor of a nuclear power plant, reduce the material consumption of the structure and increase the reliability of its operation.

Utility Model Essence

A characteristic distinguishing feature of the patented utility model is the use of the following previously unknown design solutions of a mechanical high-temperature filter to remove radioactive corrosion products from an uncooled coolant in the primary reactor of a nuclear power plant, ensuring the achievement of the required technical result:

Two concentric rectangular annular recesses are made on the flanges of the manhole manhole and the nozzle for unloading the sorbent, in which sealing gaskets are made of thermally expanded graphite, for example, graphite foil “Graflex” type PGF-D-V according to TU 5728-016-50187417-99 .

At the same time, two gaskets made of graphite foil are installed on the flange of the manhole hatch, for example, graphite foil “Graflex” of the type PGF-D-8-18-06-524 × 512 × 10 and PGF-D-V-28,6-06- 476 × 464 × 10 according to TU 5728-016-50187417-99, and two gaskets made of graphite foil are installed on the flange of the nozzle for unloading the sorbent, for example, graphite foil “Graflex” type PGF-D-V-18-06-198 × 186 × 10 and PGF-D-V-28.6-06-150 × 138 × 10 according to TU 5728-016-50187417-99 ..

Means of fastening the caps to the flanges of the nozzles are made in the form of studs with nuts with the possibility of determining the tightening forces of the studs by the value of the relative elongation of the studs when tightening with the ability to control the efforts of the studs to tighten the studs with nuts by measuring the elongation of the body of the studs relative to the inner rod by measuring and comparing the distances from the upper parts located the studs of the fixed rods and the upper parts of the studs before tightening the studs and in the process of tightening the studs.

The cover with the sorbent discharge nozzle was secured to the manhole door by means of 14 M72 threaded holes with a depth of 125 mm on the manhole manhole flange and 14 studs 562 mm long, with a neck diameter of 56 mm, M72 thread length 116 mm and length M64 threads 116 mm, with a controlled torque of 8000 Nm.

The nozzle cover for unloading the sorbent to the flange of the nozzle for unloading the sorbent was fastened by means of 10 threaded holes M32 and 10 threaded rods 264 mm long, neck diameter 31 mm, lengths of M36 threads 62 mm and 78 mm, with a controlled tightening force of 980 Nm.

The filter block of a mechanical high-temperature filter for removing radioactive corrosion products from an uncooled coolant in the primary reactor of a nuclear power plant is made up of a set of seven plates, each of which has seven filter caps with slotted holes and which are fixed relative to each other by twenty-four evenly spaced plates of holes and fixing brackets with the ability to rotate the plates relative to each other in increments of 15 ° for larger its full use of the connecting thread and more reliable fixation of the plates in the filter unit.

The filter caps with slotted holes located on the plates of the filtering unit are made in the form of a set of 5 disks with spacing protrusions and a cover forming 6 annular gaps between them with slit widths of 0.3 mm for the heat carrier outlet.

These new structural solutions provide the opportunity to achieve a technical result when implementing a utility model, namely, they increase the manufacturability and manufacturing / assembly / disassembly of a mechanical high-temperature filter to remove radioactive corrosion products from uncooled coolant in the primary reactor of a nuclear power plant, reduce the material consumption of the structure and increase the reliability of its operation .

Brief Description of the Drawings

A mechanical high-temperature mechanical filter that is patented as a utility model is a mechanical high-temperature filter for removing radioactive corrosion products from uncooled coolant in the primary reactor of a nuclear power plant, hereinafter the filter is illustrated by drawings.

Figure 1 shows a section through a filter, which shows: a housing 1 with a manhole hole 2 nozzle, to the flange of which a manhole manhole cover 3 is attached by means of studs 6, to which a nozzle for unloading the sorbent 5 is attached, to the flange of which a nozzle cover is attached unloading the sorbent 5 by means of pins 7, a nozzle for supplying a coolant 8, a nozzle for removing a filtrate of a coolant 9, a drain pipe of a filter 10, a filter unit 11, plates of a filter unit 12 with filter caps 13.

Figure 2 shows a view BB of the filter along the line BB, which shows the cross section of the housing 1 and the location of the seven plates of the filter unit 12 with seven filter caps 13 on each of the plates, and also shows a diagram of the fixing of the plates of the filter unit relative to each other each other through one of twenty-four holes along the edges of the plates and fixing brackets.

Figure 3 shows a cross-section of the G-D filter along the G-G line, which shows the design of the filter unit 11, with the plates of the filter unit 12 screwed onto the horizontal bends of the vertical collector with filter caps 13, and also shows a diagram of the fixing of the plates of the filter unit relative to each other each other through one of twenty-four holes along the edges of the plates and fixing brackets.

Figure 4 shows the cross section A of the filter at location A, where the seal design of the junction of the manhole-3 nozzle and the manhole-manhole nozzle cover 3 is shown, and also the location of the O-rings made of thermally expanded graphite 14 on the flange of the manhole-manhole nozzle 2 and the fitting seal tightness control 15.

Figure 5 shows a section B of filter 0 at location B, which shows the seal design of the junction of the nozzle for unloading the sorbent 4 and the cover of the nozzle for unloading the sorbent, and also shows the location of the O-rings from thermally expanded graphite 14 on the flange of the nozzle for unloading the sorbent and the control fitting tightness of seal 15.

Figure 6 shows a cross section of a gasket made of thermally expanded graphite 14 and its location in a rectangular recess on the flange of the manhole hole pipe and on the flange of the pipe for unloading the sorbent.

Figures 7 and 8 show the design of the studs 6 for attaching the manhole cover of the manhole to the flange of the manhole manhole nozzle (Figs. 1, 7) and the studs 7 for attaching the manhole cover for unloading the sorbent to the nozzle flange for unloading the sorbent (Fig. 1, 8), made with the possibility of controlling the tightening forces not by the magnitude of the effort of tightening the nuts on the studs, but by the magnitude of the relative elongation of the studs after tightening and structurally made hollow with through centrally located holes, inside of which are installed the inner rods 16 of the weld nye lower ends to the lower ends of the pins.

Utility Model Implementation

The patented mechanical high-temperature filter, hereinafter referred to as the filter, is a vertical pressure vessel in the form of a cylindrical body 1 with elliptical bottoms, partially filled with a filtering sorbent - titanium sponge crumbs with a fraction of 2 ^+0.63 mm.

The source fluid through the inlet of the coolant 8 under pressure up to 16.0 MPa enters the filter and passes through a layer of granular filter material (high-temperature sorbent in the form of crushed sponge titanium) from top to bottom.

The mechanical impurities are retained by the sorbent, and the clarified heat carrier is collected by the lower collection and distribution system and, through the filter caps 13 on the plates of the filter unit 12, is discharged from the filter through the outlet of the coolant filtrate discharge 9.

The filtering work cycle ends when one of the indicators is achieved: the pressure drop across the filter or the amount of processed coolant.

At the end of the filter cycle, the sorbent is loosened and washed with a reverse flow of water.

The filter material (a high-temperature sorbent in the form of sponge titanium chips) that has exhausted its life is removed from the filter by periodically removing the nozzle cover for unloading the sorbent, replacing the sorbent (sponge titanium chips), and then tightly fastening the nozzle cover for unloading the sorbent in its working position on the nozzle for unloading the sorbent.

The filter is mounted on the foundation using a cylindrical support, including a cylindrical shell and a support ring, welded together and welded to the bottom.

A hatch-manhole pipe 2 with a flange with an inner diameter of 450 mm, which is a manhole, and allows access to internal devices after unloading the sorbent and dismantling the corresponding flange connector, is welded on top of the housing 1.

On the side wall of the hatch-manhole pipe 2 is a coolant supply pipe 8.

On the flange of the hatch-manhole nozzle 2, a flat cover of the manhole-manhole nozzle 3 is installed, into which a pipe with an inner diameter of 123 mm is welded with a pipe protruding upward for unloading the sorbent 4, the flange of which is closed by a flat cover of the nozzle for unloading the sorbent 5.

The pipe for unloading the sorbent 4 is intended for installation of a device for unloading the sorbent when it is replaced.

Each flange connector is sealed with two gaskets made of thermally expanded graphite with the formation of a control cavity between them, from which an outlet to the leakage control system is organized. An air vent is placed on the upper flange.

Thermally expanded graphite is characterized by resistance to corrosion even at high temperatures, has high elastic properties, and provides reliable sealing for a long time.

Graphite gaskets are less demanding on the parallelism and surface of the flanges, they are very easy to mount and dismount.

The use of graphite gaskets allows for a more reliable seal, with the possibility of multiple decompression without damage to the seating surfaces.

In the proposed filter design, graphite gaskets are installed in deep rectangular grooves with a torque of 8000 Nm for the neck flange and 980 Nm for the sorbent discharge pipe

On the lower bottom, there is a pipe for removing the coolant from the filter and a drainage fitting, inside there is a drainage device consisting of a collector with seven plates fixed to it with seven drainage caps on each.

Each drainage cap is composed of 5 disks and a cover, forming 6 annular gaps between them for the output of the coolant.

A high-temperature mechanical filter is an element of a normal operation system that is important for safety and must comply with the requirements for equipment of safety class 2 according to NP-001-97 (PNAEG-01-011-97), qualification designation 2H, group C according to PNAEG-7 -008-89 and I category of earthquake resistance according to PN-031-01.

The materials used in the design of the filter must be corrosion resistant to process media, the environment and decontamination solutions. The main filter material is stainless steel 08X18H10T. The material of the case and internals should be resistant to MKK.

Studs 6 for securing the cover of the manhole cover nozzle and studs 7 for securing the cap of the nozzle port for unloading the sorbent to the corresponding flanges of the manhole port and the nozzle for unloading the sorbent (Figs. 7, 8) are configured to control the tightening forces not by the magnitude of the nut tightening force on the studs, and in terms of the relative elongation of the studs after tightening, they are structurally hollow with through centrally located holes, inside of which the inner rods 16 are welded with the lower ends to the lower ends studs.

The efforts during the tightening of the studs 6 and 7 are controlled by measuring the elongation of the body of the studs relative to the inner rod 16 by measuring the distances from the upper parts of the fixed inner rods 16 and the upper parts of the studs located inside the studs, moving as a result of the stretching of the studs under the influence of tensile forces.

Before tightening the studs, the distances from the upper ends of the rods in the studs to the upper ends of the studs are measured.

When the studs are loaded by the tightening forces, deformation (drawing) of the “working medium” of the studs and the corresponding movement of the upper ends of the studs occurs.

By changing the distances from the ends of the fixed rods in the studs to the upper ends of the studs, the loads on the studs and their tightening forces are determined.

The material of the stud connectors is steel 10X11N20TZR, the gasket material is Graphite graphite foil, the type of gaskets is PGF-D-V according to TU 5728-016-50187417-99.

As options for the design of individual parts, nodes Filter AFMVT-1.0-16.0 can be used known and suitable for use in this technology, materials and design solutions commonly used in the art to perform similar functions.

To fix the filter blocks together, additional holes with a diameter of 5 mm are made in the plates (24 holes in total), which are more precisely aligned when the filter blocks are twisted on the distribution head

Thus, given the novelty of the set of essential features, the technical solution of the problem, the materiality of all general and particular features of the utility model displayed in the formula shown in the sections "prior art", "Disclosure of a utility model" and "Implementation of a utility model", a detailed technical feasibility and industrial applicability of the utility model, the solution of the inventive task and the confident achievement of the required technical result in the implementation and use of useful th model, the claimed group of utility models meets all the requirements for the protection of utility models.

A detailed disclosure of the design and functioning features also shows that all the general and particular features of the utility model are essential, since each of them is necessary, and together they are not only sufficient to achieve the goal of the utility model and are in a causal relationship with the technical result, but also allow you to implement a useful model in an industrial way.

INFORMATION SOURCES

1.SU 713006 B01D 24/44 03/20/2000

2. SU 824796 Application 2878840/25, 02/05/1980 G21F 9/12 Publ. 01/20/2000

3. RU 1537046 G21F 9/12 Publ. 10/27/1995

4. RU 2341835 G21F 9/28 B01D 35/16 Publ. 12/20/2008

5. RU 2216060 G21F 9/00, B01D 35/16 Publ. 11/10/2003

6. RU 2289863 G21F 9/28 B01D 35/16 Publ. 12/20/2006

7. TU 108-11-624 (prototype)

8.http: //vpolesye.ru/katalog_n/filtry/filtr_mehanicheskij_vysokotemperaturnyj_afmvt10160

Claims (21)

1. High-temperature mechanical filter for removing radioactive corrosion products from an uncooled coolant in the primary reactor of a nuclear power plant, comprising a housing with a filtering unit located inside the housing and with a manhole hole located in the upper part of the body, a manhole door with a nozzle mounted on it for unloading the sorbent, a nozzle cover for unloading the sorbent, means for attaching the covers to the flanges of the nozzles and means for sealing the mating surfaces of the covers and flanges bkov, characterized in that the sealing means covers mating surfaces of the pipes and flanges are in the form of rectangular annular recesses in the flanges and the pipes installed therein gaskets from expanded graphite. 2. The mechanical high-temperature filter according to claim 1, characterized in that the gaskets of thermally expanded graphite are made of graphite foil. 3. The mechanical high-temperature filter according to claim 1, characterized in that the means of sealing the mating surfaces of the caps and flanges of the nozzles are made in the form of two concentric annular rectangular recesses on each of the flanges of the nozzles and gaskets installed in them from thermally expanded graphite, and on the flange of the hatch manhole installed two gaskets made of graphite foil, on the flange of the nozzle for unloading the sorbent installed two gaskets made of graphite foil. 4. The high-temperature mechanical filter according to claim 1, characterized in that the means for attaching the covers to the flanges of the nozzles are made in the form of studs with nuts with the possibility of determining the tightening forces of the studs by the value of the relative elongation of the studs when tightening with the ability to control the efforts of the studs to tighten the nuts with nuts by measuring the elongation of the body the studs relative to the inner rod by measuring and comparing the distances from the upper parts of the fixed rods and the upper parts of the studs located inside the studs to tightening the studs lek and in the process of tightening the studs. 5. The high-temperature mechanical filter according to claim 1, characterized in that the filter unit is made up of a set of seven plates, on each of which there are seven filter caps with slotted holes and which are fixed relative to each other by twenty-four holes equally spaced along the edges of the plates and fixing brackets with the ability to rotate the plates relative to each other with a step of 15 ° for more complete use of the connecting thread and more reliable fixation of the plates in the filter unit, and the filter caps with slotted holes located on the plates of the filtering unit are made in the form of a set of 5 disks with spacing protrusions and a cover forming 6 annular gaps between them with slit widths of 0.3 mm for conveying the coolant. 6. High-temperature mechanical filter for removing radioactive corrosion products from an uncooled coolant in the primary reactor of a nuclear power plant, comprising a housing with a filtering unit located inside the housing and with a manhole hole located in the upper part of the housing, a manhole door with a nozzle mounted on it for unloading the sorbent, a nozzle cover for unloading the sorbent, means for attaching the covers to the flanges of the nozzles and means for sealing the mating surfaces of the covers and flanges flanges, characterized in that the means for attaching the caps to the flanges of the nozzles are made in the form of studs with nuts with the possibility of determining the tightening forces of the studs by the value of the relative elongation of the studs when tightening, and the means of sealing the mating surfaces of the caps and flanges of the nozzles are made in the form of rectangular rectangular recesses on the flanges of the nozzles and gaskets made of thermally expanded graphite installed in them. 7. The high-temperature mechanical filter according to claim 6, characterized in that the studs are hollow with a through centrally located hole, inside which are installed rods that are welded with their lower ends to the lower ends of the studs and remain stationary when the studs are extended when they are tightened with the nuts. 8. The mechanical high-temperature filter according to claim 7, characterized in that the studs are configured to control the efforts of tightening the studs with nuts by measuring the elongation of the body of the studs relative to the inner rod by measuring and comparing the distances from the upper parts of the fixed rods located inside the studs and the upper parts of the studs to tightening studs and in the process of tightening the studs. 9. The high-temperature mechanical filter according to claim 7, characterized in that the studs for attaching the manhole cover to the flange of the manhole cover are 562 mm long, with a neck diameter of 56 mm, a M72 thread length of 116 mm and a M64 thread length of 116 mm , with a controlled stud tightening force of 8000 Nm, and studs for attaching a nozzle cover for unloading a sorbent to a nozzle unloading flange for a sorbent are made with a length of 264 mm, a neck diameter of 31 mm, M36 thread lengths of 62 mm and 78 mm, with a controlled stud tightening force of 980 Nm . 10. The high-temperature mechanical filter according to claim 6, characterized in that the means for sealing the mating surfaces of the caps and flanges of the nozzles are made in the form of two concentric annular rectangular recesses on each of the flanges of the nozzles and gaskets installed in them from thermally expanded graphite in the form of graphite foil, and there are two graphite foil gaskets installed on the manhole flange of the manhole, and two graphite foil gaskets are installed on the flange of the nozzle for unloading the sorbent. 11. The high-temperature mechanical filter according to claim 6, characterized in that the filtering unit is made up of a set of seven plates, each of which has seven filter caps with slotted holes and which are fixed relative to each other by one of twenty-four evenly spaced along the edges of the plates holes and fixing brackets with the ability to rotate the plates relative to each other in increments of 15 ° for more complete use of the connecting thread and more reliable fixation of the plates in the filter m block, and the filter caps located on the plates of the filter block with slotted holes are made in the form of a set of 5 disks with spacing protrusions and a cover forming 6 annular gaps between them with slit widths of 0.3 mm for the heat carrier outlet. 12. A high-temperature mechanical filter for removing radioactive corrosion products from an uncooled coolant in the primary reactor of a nuclear power plant, comprising a housing with a filtering unit located inside the housing and with a manhole hole located in the upper part of the body, a manhole door with a nozzle mounted on it for unloading the sorbent, a nozzle cover for unloading the sorbent, means for attaching the covers to the flanges of the nozzles and means for sealing the mating surfaces of the covers and flanges ubkov, characterized in that the filter unit is made up of a set of seven plates, on each of which there are seven filter caps with slotted holes and which are fixed relative to each other by means of twenty-four holes evenly arranged along the edges of the plates and fixing brackets. 13. The high-temperature mechanical filter according to claim 11, characterized in that the filtering unit is made up of a set of seven plates, each of which has seven filter caps with slotted holes and which are fixed relative to each other by one of twenty-four evenly spaced along the edges of the plates holes and fixing brackets with the ability to rotate the plates relative to each other in increments of 15 ° for more complete use of the connecting thread and more reliable fixation of the plates in the filter m block. 14. The mechanical high-temperature filter according to claim 11, characterized in that the filter caps with slotted holes located on the plates of the filtering unit are made in the form of a set of 5 disks with spacing protrusions and a cover forming 6 annular gaps between them with a slit width of 0.3 mm for a conclusion of the heat carrier. 15. The mechanical high-temperature filter according to claim 11, characterized in that the means for sealing the mating surfaces of the caps and flanges of the nozzles are made in the form of two concentric annular rectangular recesses on each of the flanges of the nozzles and the gaskets made of thermally expanded graphite in the form of graphite foil installed in them, and there are two graphite foil gaskets installed on the flange of the manhole hatch, and two graphite foil gaskets are installed on the flange of the nozzle for unloading the sorbent. 16. The high-temperature mechanical filter according to claim 11, characterized in that the means for attaching the covers to the flanges of the nozzles are made in the form of studs with nuts with the possibility of determining the tightening forces of the studs by the value of the relative elongation of the studs when tightening, with the ability to control the tightening forces of the studs with nuts by measuring the elongation of the body the studs relative to the inner rod by measuring and comparing the distances from the upper parts of the fixed rods and the upper parts of the studs located inside the studs to tightening the bolts he got it in the process of tightening the studs, moreover, the studs for attaching the cover of the manhole cover to the flange of the manhole cover are 562 mm long, with a neck diameter of 56 mm, a M72 thread length of 116 mm and a M64 thread length of 116 mm, with a controlled stud tightening force 8000 Nm, and the studs for attaching the nozzle cover for unloading the sorbent to the flange of the nozzle for unloading the sorbent are 264 mm long, neck diameter 31 mm, M36 threads lengths 62 mm and 78 mm, with a controlled torque of 980 Nm. 17. High-temperature mechanical filter for removing radioactive corrosion products from an uncooled coolant in the primary reactor of a nuclear power plant, comprising a housing with a filtering unit located inside the housing and with a manhole hole located in the upper part of the body, a manhole door with a nozzle mounted on it for unloading the sorbent, a nozzle cover for unloading the sorbent, means for attaching the covers to the flanges of the nozzles and means for sealing the mating surfaces of the covers and flanges ubkov, characterized in that the means of fastening the caps to the flanges of the nozzles are made in the form of studs with nuts with the possibility of determining the tightening forces of the studs by the value of the relative elongation of the studs when tightening, the means of sealing the mating surfaces of the caps and flanges of the nozzles are made in the form of rectangular rectangular recesses on the flanges of the nozzles and gaskets made of thermally expanded graphite installed in them, and the filter unit is made of a set of seven plates, each of which has seven filter caps with a slot bubbled holes and which are fixed relative to one another by twenty-four evenly spaced holes along the edges of plates and fixing brackets. 18. The high-temperature mechanical filter according to clause 16, characterized in that the means of sealing the mating surfaces of the caps and flanges of the pipes are made in the form of two concentric annular rectangular recesses on each of the flanges of the pipes and gaskets installed in them from thermally expanded graphite in the form of graphite foil, and two gaskets made of graphite foil are installed on the flange of the manhole door; two gaskets made of graphite foil are installed on the flange of the pipe for unloading the sorbent. 19. The high-temperature mechanical filter according to clause 16, characterized in that the means for attaching the covers to the flanges of the nozzles are made in the form of studs with nuts with the possibility of determining the tightening forces of the studs by the value of the relative elongation of the studs when tightening with the ability to control the efforts of the studs to tighten the nuts with nuts by measuring the elongation of the body the studs relative to the inner rod by measuring and comparing the distances from the upper parts of the fixed rods and the upper parts of the studs located inside the studs to tightening the bolts Ilek and in the process of tightening the studs. 20. The high-temperature mechanical filter according to clause 16, characterized in that the studs for attaching the manhole cover to the flange of the manhole cover are 562 mm long, with a neck diameter of 56 mm, a M72 thread length of 116 mm and a M64 thread length of 116 mm , with a controlled stud tightening force of 8000 Nm, and studs for attaching a nozzle cover for unloading a sorbent to a nozzle unloading flange for a sorbent are made with a length of 264 mm, a neck diameter of 31 mm, M36 thread lengths of 62 mm and 78 mm, with a controlled stud tightening force of 980 Nm . 21. The high-temperature mechanical filter according to clause 16, wherein the filter unit is made up of a set of seven plates, each of which has seven filter caps with slotted holes and which are fixed relative to each other by one of twenty-four evenly spaced along the edges of the plates holes and fixing brackets with the ability to rotate the plates relative to each other in increments of 15 ° for more complete use of the connecting thread and more reliable fixation of the plates in the filter m block, and a filtering unit disposed on dishes with filter caps slotted holes made in the form of a set of five disks with spacing projections and the cover forming the annular gap 6 between them with a width of 0.3 mm slots to output the coolant.