RU2781678C1 - Apparatus for assembling spent graphite sealing ring of the step-position sensor of the control rod of a nuclear reactor and method for operation of said apparatus - Google Patents

Abstract

FIELD: nuclear technology.

SUBSTANCE: group of inventions relates to an apparatus and a method for assembling a graphite sealing ring of a step-position sensor of the control rod of a nuclear reactor. Apparatus comprises fasteners (1), an upper sector block (2), a semi-ring washer of the lower sector block (3), a lower sector block (4) located rotatably relative to the upper sector block (2), a clamp of the upper sector block (5), a torsion spring (6), a clamping shaft (7), a clamp of the lower sector block (8), a semiannular washer of the upper sector block (9), thrust plates (11), a semiannular stepped sleeve of the upper sector block (12), and a peripheral closed plate of the upper sector block (15). In the method, the step-position sensor is placed in the centre of the apparatus, the upper sector block (2) is rotated clockwise, the apparatus is clamped on the sensor, the upper sector block (2) is rotated counterclockwise, and the apparatus is separated from the step-position sensor.

EFFECT: prevented entry of foreign elements into process systems; reduced risk of mechanical damage to the working personnel.

20 cl, 11 dwg

Description

Technical field

The claimed technical solution relates to the repair of a reactor at a nuclear power plant (NPP), in particular, to a device for assembling a used graphite sealing ring of a step sensor for the position of a nuclear reactor control rod and the method of operation of the device.

State of the art

The control rod drive mechanism, which is located at the top of the nuclear reactor, installs the control rod assembly into the fuel assembly (FA) or removes the control rod assembly from the fuel assembly to implement the start, power control and shutdown of the nuclear reactor.

The stepper encoder is an important part of the control rod drive mechanism, used to measure and display the height position of the control rod in a nuclear reactor, and is also the pressure boundary of the primary circuit system (tightness is ensured by a graphite o-ring and fastener).

A graphite o-ring is installed at the location of the flange boss of the stepper encoder. In this case, the tightness between the stepper position sensor and the pressure-resistant shell is realized by a graphite sealing ring compressed by two thrust blocks, one thrust ring and six bolts.

The graphite sealing ring has an annular configuration, its upper and lower ends are covered with stainless steel. The middle part of the ring is graphite, a stainless steel wire is placed between the graphite and the stainless steel coating to increase strength.

After prolonged compression, the graphite o-ring is tightly connected to the flange of the stepper position sensor. During the dismantling of the stepper position sensor, a graphite o-ring is usually attached to its flange.

For a nuclear power unit, as a rule, a fuel cycle is taken with a duration of 12-18 months, after the completion of each fuel cycle, scheduled preventive maintenance (SPM) and fuel refueling are carried out.

During each shutdown, the control rod drive mechanism is partially disassembled and the following repair work is performed to maintain the stepper position sensor: the stepper position sensor is removed from the upper part of the reactor, it is lifted and installed on a storage rack at the edge of the revision shaft of the internal devices (VCU), removed graphite sealing ring, clean it, check the sealing surface, install a new graphite sealing ring, return the stepper position sensor.

In the current state of the art, the graphite o-ring is removed as follows: raise the stepper position sensor to a suitable height (maintaining the suspended position), use a flat screwdriver to separate the o-ring from the flange of the stepper position sensor, cut off the o-ring with a side cutter and then remove it.

The problems of the current state of the art are as follows:

- after prolonged compression, the graphite sealing ring and the flange of the stepper position sensor are firmly connected;

- it is difficult to separate them using a flat screwdriver;

- extraction of each sealing ring takes 5-10 minutes;

- when removing the graphite sealing ring is damaged, it is difficult to control the graphite fragments;

- the stepper position sensor is a stick-shaped cylinder that cannot be assembled in all directions around a 360° circumference;

- in the process of separating the graphite sealing ring from the flange of the stepper encoder and cutting the sealing ring with a side cutter, graphite easily crumbles, while the metal ring of the side cutter has the risk of falling;

- the site of the operation is located in the area adjacent to and connected to the inspection shaft of the VCU and the system of the primary circuit of the reactor. In this case, the falling object enters the mentioned system and forms extraneous processes, which leads to a hidden threat to the safe operation of the power unit.

As a prototype for the claimed device, a bearing seal remover (US3264722 "Main bearing seal remover", POTTER ROBERT E, 08/09/1966) is adopted, containing an arcuate body element with a semicircular cross-sectional configuration and an offset lever held by the specified arcuate body of the seal remover. In said lever, means are provided for receiving the seal guide in the form of grooves. A plurality of seal remover bolts secure the seal remover to the seal guide.

From the description of the prototype known method of removing the seal, in which the crankshaft of the engine is weakened and lowered. The bearing seal remover is positioned so that the seal guide enters one of the slots, and then the bolts are tightened to secure the bearing seal. The mechanic inserts a screwdriver into the teeth of the engine flywheel and rotates the engine, while the bearing seal remover pushes the old seal out.

The disadvantage of the prototype is the failure of the stuffing box when it is tightened with bolts and turning the engine.

The purpose of the present invention is to propose a device and a method for collecting a spent graphite sealing ring of a nuclear reactor control rod position stepper sensor, which reduce the risk of mechanical damage to workers and significantly reduce the requirements for their skill level during the method.

Disclosure of the proposed technical solution

The technical result provided by the claimed technical solutions is to increase the efficiency of the device and method. It takes 2-3 minutes to remove each O-ring, and the working efficiency is increased by 3-4 times.

Other technical results are:

- the present invention makes it possible to carry out 100% collection of used graphite sealing rings and eliminate the risk of foreign elements getting into technological systems;

- in the present invention, the use of a device for collecting a spent graphite sealing ring reduces the amount of radioactive waste that is generated during the extraction of a graphite sealing ring;

- the present invention reduces the risk of mechanical damage to personnel during the method;

- the present invention has a simple operation of the device for collecting the spent graphite sealing ring, which greatly reduces the requirements for the skill level of the operating personnel to perform this operation.

The essence of the claimed device is that a device for collecting a used graphite sealing ring of a step sensor for the position of a nuclear reactor control rod, characterized in that it contains fasteners, an upper sector block, a half-ring washer of the lower sector block, a lower sector block, a clamp of the upper sector block, a spring torsion shaft, clamp shaft, clamp of the lower sector block, half-ring washer of the upper sector block, while the upper sector block is located on the lower sector block, and the upper edge of the upper sector block is flush with the upper edge of the lower sector block, while both of them are connected by fasteners, in addition, the lower sector block is located with the possibility of rotation relative to the upper sector block, while the clamp in the lower part of the device contains the clamp of the upper sector block, the clamp of the lower sector block, the torsion spring and the clamp shaft, while the clamp of the upper sector block a, the clamp of the lower sector block and the torsion spring are connected to the clamp shaft, in addition, the clamp of the lower sector block is glued and fixed in the lower part of the lower sector block, while the upper sector block contains thrust plates, a semi-annular stepped bushing of the upper sector block and a peripheral closed plate of the upper sector block.

In special cases, it is permissible to carry out the technical solution as follows.

Fasteners are arcuate and U-shaped elements.

The device contains four fasteners, two of them are respectively flush with the side surface of the lower sector block, the angle between the said side surface and the other two fasteners is 30°.

The lower part of the upper sector block is a sector with an angle of 240°, while thrust plates are fixed on its edges, in addition, a peripheral closed plate of the upper sector block is installed on the upper edge of the lower part of the upper sector block.

The step position sensor is in contact with the semi-annular stepped bushing of the upper sector block in the center of the peripheral closed plate of the upper sector block, while the arc angle of the semi-annular stepped bushing of the upper sector block is 180°.

The semi-annular stepped bushing of the upper sector block contains the upper part of the semi-annular stepped bushing of the upper sector block and the lower part of the semi-annular stepped bushing of the upper sector block, which are firmly connected to each other.

Notches are made on the border of the thrust plates through which the fasteners pass during the rotation of the upper sector block.

Recesses, thrust plates, semi-annular stepped bushing of the upper sector block and peripheral closed plate of the upper sector block are made of sheet metal.

The lower part of the lower sector block is a sector structure with an angle of 180°, in the upper part of which a peripheral closed plate of the lower sector block is installed.

The upper end of the peripheral closed plate of the upper sector block is flush with the upper end of the peripheral closed plate of the lower sector block, which are connected by fasteners.

The lower sector block contains a peripheral closed plate of the lower sector block and guard plates, which are made of sheet metal and are firmly connected.

The step position sensor is in contact with the upper part of the semi-annular stepped bushing of the upper sector block and the lower part of the semi-annular stepped bushing of the upper sector block in the center of the peripheral closed plate of the lower sector block, while the arc angles of the semi-annular stepped bushing of the upper sector block and the arc of the lower part of the semi-annular stepped bushing of the upper sector block blocks are 180°.

Inside the lower sector block, nine guard plates are evenly spaced, which make up the lattice zone, while a chamfer is made in the upper part of each guard plate to prevent foreign fragments from falling onto the side surface.

The upper sector block and the lower sector block are located coaxially on each other, while the upper sector block is located above the lattice area of the lower sector block, the lattice zone is not only a container for collecting foreign elements, but also supports the upper sector block during its rotation.

The clamp shaft is made hollow, while during installation, both ends of the clamp shaft expand and are retracted outward to prevent axial displacement of the clamp shaft.

In the normal state, the torsion spring is open, under the force of the torsion spring, the clamp of the upper sector block and the clamp of the lower sector block are closed together.

The clamp of the upper sector block is a stepped semi-ring, in working condition the force of the torsion spring through the large end of the clamp of the upper sector block and the lower end of the semi-annular stepped bushing of the upper sector block is transmitted to the stepper position sensor, after which a friction force arises, the small end of the clamp of the upper sector block block is in contact with the stepper position sensor and then creates a friction force.

The clamp of the lower sector block is a semi-circular structure, glued and fixed in the lower part of the semi-circular stepped bushing of the lower sector block, while the force of the torsion spring through the lower sector block, the semi-circular washer of the lower sector block is transmitted to the stepper position sensor, after which a friction force arises.

The essence of the claimed method is that:

- at the first stage, the clamp of the lower sector block is opened, the upper sector block is rotated counterclockwise so that its span is sufficient for the stepper position sensor to enter the center of the device for collecting the spent graphite sealing ring;

- at the second stage, a device for collecting the spent graphite sealing ring is placed next to the stepper position sensor so that the stepper position sensor enters the center of the device;

- at the third stage, the upper sector block is rotated clockwise, a closed area is formed between the upper sector block and the lower sector block;

- at the fourth stage, the clamp of the lower sector block is released so that, under the force of the torsion spring, the device for collecting the graphite sealing ring is clamped on the stepper position sensor, check the clamping of the device for collecting the spent graphite sealing ring;

- at the fifth stage, the clamp of the lower sector block is opened, the upper sector block is rotated counterclockwise so that its span is sufficient for the stepper position sensor to separate from the center of the device for collecting the used graphite sealing ring;

- at the sixth stage, the device for collecting the spent graphite sealing ring is separated from the stepper position sensor, the upper sector block is rotated clockwise, a closed area is formed between the upper sector block and the lower sector block;

- at the seventh stage, the clamp of the lower sector block is released, foreign elements that have fallen on the upper sector block and the lattice zone of the lower sector block are removed.

Brief description of the drawings

In FIG. 1 shows an axonometric diagram of the upper part of a device for collecting a used graphite sealing ring of a stepper control rod position sensor of a nuclear reactor; in fig. 2 is an axonometric diagram of the lower part of the device for collecting the spent graphite sealing ring of a stepper sensor for the position of a nuclear reactor control rod; in fig. 3 is a top view of a device for collecting a spent graphite sealing ring of a stepper control rod position sensor of a nuclear reactor; in fig. 4 is a plan view of the clamp at the bottom of the device for collecting the spent graphite O-ring of a nuclear reactor control rod position stepper; in fig. 5 is a section B-B of FIG. four; in fig. 6 is a section C-C of FIG. four; in fig. 7 - top view of the upper sector block; in fig. 8 is a section D-D of FIG. 7; in fig. 9 is a side view of the upper sector block; in fig. 10 - diagram of the lower sector block; in fig. 11 is a top view of the lower sector block.

List of reference designations: 1 - fasteners; 2 - upper sector block; 3 - semi-annular washer of the lower sector block; 4 - lower sector block; 5 - clamp of the upper sector block; 6 - torsion spring; 7 - clamp shaft; 8 - clamp of the lower sector block; 9 - semi-annular washer of the upper sector block; 10 - notches; 11 - thrust plate; 12 - semi-annular stepped bushing of the upper sector block; 13 - the upper part of the semi-annular stepped bushing of the upper sector block; 14 - the lower part of the semi-annular stepped bushing of the upper sector block; 15 - peripheral closed plate of the upper sector block; 16 - peripheral closed plate of the lower sector block; 17 - fencing plates; 18 - the upper part of the semi-annular stepped bushing of the lower sector block; 19 - the lower part of the semi-annular stepped bushing of the lower sector block; 20 - lattice zone.

Device implementation

For a better understanding by a person skilled in the art of the essence of the claimed invention, the following is a clear and complete description of the technical solution, an example of the implementation of this invention, taking into account the attached figures. Obviously, the following implementation example is a special case of the invention. Based on the embodiment set forth in this invention, other embodiments obtained by a person skilled in the art without creative work will be within the protection scope of the present invention.

As shown in FIG. 1, 2 and 3, the present invention provides a device for collecting a spent graphite sealing ring of a nuclear reactor control rod stepper sensor, which includes an upper sector block (2), a half-ring washer of a lower sector block (3), a lower sector block (4), clamp of the upper sector block (5), torsion spring (6), clamp shaft (7), clamp of the lower sector block (8), half ring washer of the upper sector block (9).

The upper sector block (2) is located on the lower sector block (4). The upper edge of the upper sector block (2) is flush with the upper edge of the lower sector block (4), while both of them are connected by fasteners (1). In particular, fasteners (1) are evenly distributed along the outer wall of the upper part of the upper sector block (2) and are glued to it.

The lower sector block (4) is rotatably positioned relative to the upper sector block (2). The half-ring washer of the lower sector block (3) is installed and fixed in the lower sector block (4).

The clamp of the upper sector block (5), the clamp of the lower sector block (8), the torsion spring (6) are connected to the clamp shaft (7) to realize the pressing function. The clamp shaft (7) passes through the torsion spring (6). The semi-annular washer of the upper sector block (9) is fixedly connected to the inner side of the upper sector block (2). The clamp of the lower sector block (8) is firmly connected to the outer side of the lower sector block (4) by gluing.

The claimed device has a vertical two-layer structure and is divided into two parts - upper and lower. They rotate together for opening and closing (see Fig. 1, 2, 3). The lower part of the upper sector block (2) is a sector with an angle of 240° (see Fig. 7, 8, 9), the outer circle of which is closed. The upper sector block (2) includes recesses (10), thrust plates (11), a semi-annular stepped bushing of the upper sector block (12) and a peripheral closed plate of the upper sector block (15). All of the above parts are made of sheet metal and connected to each other by welding, but can also be made by injection molding.

The stepper position sensor is in contact with the semi-annular stepped bushing of the upper sector block (12) in the center of the peripheral closed plate of the upper sector block (15). In this case, the arc angle of the semi-annular stepped bushing of the upper sector block (12) is 180°. The upper part of the semi-annular stepped bushing of the upper sector block (12) and the lower part of the semi-annular stepped bushing of the upper sector block (14) are sheet metal parts that are connected by welding, but can also be made as one piece by injection molding. On the edge of each thrust plate (11), a notch (10) is made, which is not open until the lower end of the plate (11). Fasteners (1) pass through the recesses (10) during the rotation of the upper sector block (2).

The lower part of the lower sector block (4) is a sector with an angle of 180° (see Fig.10, 11), having a closed circumference of the periphery. The lower sector block (4) contains a peripheral closed plate of the lower sector block (16) and fence plates (17), which are sheet metal parts and are welded to each other.

The step position sensor is in contact with the upper part of the semi-annular stepped bushing of the upper sector block (13) and the lower part of the semi-annular stepped bushing of the upper sector block (14) in the center of the peripheral closed plate of the lower sector block (16). In this case, the arc angles of the semi-annular stepped bushing of the upper sector block (13) and the arc of the lower part of the semi-annular stepped bushing of the upper sector block (14) are 180°.

Inside the lower sector block (4), nine fence plates (17) are uniformly located, which make up the lattice zone (20). A chamfer is made in the upper part of each guard plate (17) to prevent foreign fragments from falling onto the side surface.

The lattice zone (20) is not only a container for collecting foreign elements, but also supports the upper sector block (2) during its rotation.

The clamp in the lower part of the device contains a clamp of the upper sector block (5), a clamp of the lower sector block (8), a torsion spring (6) and a clamp shaft (7) (see Fig. 4, 5, 6). Upper sector block clamp (5), lower sector block clamp (8) and torsion spring (6) are connected to clamp shaft (7). The clamp shaft (7) is hollow. During assembly, both ends of the clamp shaft (7) expand and retract outwards to prevent axial movement of the clamp shaft (7). In the normal state, the torsion spring (6) is open. Under the force of the torsion spring (6), the clamp of the upper sector block (5) and the clamp of the lower sector block (8) close together.

The clamp of the upper sector block (5) is a stepped half ring. In working condition, the force of the torsion spring (6) through the end of the large clamp of the upper sector block (5) and the lower end of the semi-annular stepped bushing of the upper sector block (12) is transmitted to the stepper position sensor, after which a friction force arises. The small end of the clamp of the upper sector block (5) is in contact with the stepper position sensor and then creates a friction force.

The clamp of the lower sector block (8) is a semi-annular structure, glued and fixed in the lower part of the semi-annular stepped bushing of the lower sector block (19). The force of the torsion spring (6) through the lower sector block (4), the half-ring washer of the lower sector block (3) is transmitted to the stepper position sensor, after which a friction force arises.

The upper sector block (2) and the lower sector block (4) are located coaxially on top of each other. The upper sector block (2) is located above the lattice zone (20) of the lower sector block (4). The lower sector block (4) supports the upper sector block (2). The upper end of the peripheral closed plate of the upper sector block (15) is flush and connected by fasteners (1) to the upper end of the peripheral closed plate of the lower sector block (16). Fastening elements (1) are arcuate and U-shaped elements. The inner side of the long end of the fastener (1) is glued and fixed on the peripheral closed plate of the lower sector block (16). The device contains four fasteners (1), two of them are respectively flush with the side surface of the lower sector block (4), the angle between the said side surface and the other two fasteners is 30°. This arrangement secures the two fasteners (1) when the upper sector block (2) rotates coaxially over the lower sector block (4).

Description of the device

Open the clamp of the lower sector block (8), rotate the upper sector block (2) counterclockwise so that its span is sufficient for the stepper position sensor to enter the center of the device for collecting the spent graphite sealing ring. Then place the device for collecting the spent graphite O-ring next to the stepper position sensor so that the stepper position sensor enters the center of the device. After that, the upper sector block (2) is rotated clockwise, a closed area is formed between the upper sector block (2) and the lower sector block (4). Then release the clamp of the lower sector block (8) so that under the force of the torsion spring (6) the device for collecting the graphite sealing ring is clamped on the stepper position sensor, check the clamping of the device for collecting the spent graphite sealing ring. Open the clamp of the lower sector block (8), rotate the upper sector block (2) counterclockwise so that its span is sufficient for the stepper position sensor to separate from the center of the device for collecting the spent graphite sealing ring. The device for collecting the used graphite sealing ring is separated from the stepper position sensor, the upper sector block (2) is rotated clockwise, a closed area is formed between the upper sector block (2) and the lower sector block (4). Then the clamp of the lower sector block (8) is released, foreign elements that have fallen on the upper sector block (2) and the lattice zone (20) of the lower sector block (4) are removed.

Implementation of the method

The present invention also provides a method for collecting a spent graphite O-ring of a stepper control rod position sensor of a nuclear reactor, and the method includes the following steps:

- at the first stage open the clamp of the lower sector block (8), rotate the upper sector block (2) counterclockwise so that its span is sufficient for the stepper position sensor to enter the center of the device for collecting the spent graphite sealing ring;

- at the second stage, a device for collecting the spent graphite sealing ring is placed next to the stepper position sensor so that the stepper position sensor enters the center of the device;

- at the third stage, the upper sector block (2) is rotated clockwise, a closed area is formed between the upper sector block (2) and the lower sector block (4);

- at the fourth stage, the clamp of the lower sector block (8) is released so that under the force of the action of the torsion spring (6) the device for collecting the graphite sealing ring is clamped on the stepper position sensor, check the clamping of the device for collecting the spent graphite sealing ring;

- at the fifth stage, the clamp of the lower sector block (8) is opened, the upper sector block (2) is rotated counterclockwise so that its span is sufficient for the stepper position sensor to separate from the center of the device for collecting the spent graphite sealing ring;

- separating the device for collecting the spent graphite sealing ring from the stepper position sensor, rotating the upper sector block (2) clockwise, forming a closed area between the upper sector block (2) and the lower sector block (4);

- release the clamp of the lower sector block (8), remove foreign elements that have fallen on the upper sector block (2) and the lattice area (20) of the lower sector block (4).

The proposed invention has been described in detail above with reference to the drawings and exemplary embodiments. However, the present invention is not limited to the above examples. Various modifications can be made within the scope of the knowledge of those skilled in the art. Changes can be made without deviating from the purpose of the present invention. Information not described in detail in the present invention may include existing technology data.

Claims (26)

1. A device for collecting a spent graphite sealing ring of a nuclear reactor control rod stepper position sensor, characterized in that it contains fasteners (1), an upper sector block (2), a half-ring washer of the lower sector block (3), a lower sector block (4) , clamp of the upper sector block (5), torsion spring (6), clamp shaft (7), clamp of the lower sector block (8), half ring washer of the upper sector block (9), while the upper sector block (2) is located on the lower sector block block (4), moreover, the upper edge of the upper sector block (2) is flush with the upper edge of the lower sector block (4), while both of them are connected by fasteners (1), in addition, the lower sector block (4) is located with the possibility of rotation relative to of the upper sector block (2), in addition, the clamp in the lower part of the device contains the clamp of the upper sector block (5), the clamp of the lower sector block (8), the torsion spring (6) and the clamp shaft (7), with In this case, the clamp of the upper sector block (5), the clamp of the lower sector block (8) and the torsion spring (6) are connected to the clamp shaft (7), and the clamp of the lower sector block (8) is fixed in the lower part of the lower sector block (4), with In this case, the upper sector block (2) contains thrust plates (11), a semi-annular stepped bushing of the upper sector block (12) and a peripheral closed plate of the upper sector block (15). 2. The device according to claim 1, characterized in that the fasteners (1) are arcuate and U-shaped elements. 3. The device according to claim 1, characterized in that it contains four fasteners (1), two of them, respectively, are flush with the side surface of the lower sector block (4), the angle between the said side surface and the other two fasteners is 30°. 4. The device according to claim 1, characterized in that the lower part of the upper sector block (2) is a sector with an angle of 240 °, while thrust plates (11) are fixed on its edges, in addition, on the upper edge of the lower part of the upper sector block (2) a peripheral closed plate of the upper sector block (15) is installed. 5. The device according to claim 1, characterized in that the stepper position sensor is in contact with the semi-annular stepped bushing of the upper sector block (12) in the center of the peripheral closed plate of the upper sector block (15), while the arc angle of the semi-annular stepped bushing of the upper sector block (12 ) is 180°. 6. The device according to claim 5, characterized in that the semi-annular stepped bushing of the upper sector block (12) contains the upper part of the semi-annular stepped bushing of the upper sector block (13) and the lower part of the semi-annular stepped bushing of the upper sector block (14), which are firmly connected between yourself. 7. The device according to claim 1, characterized in that recesses (10) are made on the border of the thrust plates (11), through which the fasteners (1) pass during the rotation of the upper sector block (2). 8. The device according to claim 5, characterized in that the recesses (10), thrust plates (11), the semi-annular stepped bushing of the upper sector block (12) and the peripheral closed plate of the upper sector block (15) are made of sheet metal. 9. The device according to claim 1, characterized in that the lower part of the lower sector block (4) is a sector structure with an angle of 180°, in the upper part of which a peripheral closed plate of the lower sector block (16) is installed. 10. The device according to claim 1, characterized in that the upper end of the peripheral closed plate of the upper sector block (15) is flush with the upper end of the peripheral closed plate of the lower sector block (16), which are connected by fasteners (1). 11. The device according to claim 1, characterized in that the lower sector block (4) contains a peripheral closed plate of the lower sector block (16) and fence plates (17), which are made of sheet metal and are firmly connected. 12. The device according to claim 1, characterized in that the stepper position sensor is in contact with the upper part of the semi-annular stepped bushing of the upper sector block (13) and the lower part of the semi-annular stepped bushing of the upper sector block (14) in the center of the peripheral closed plate of the lower sector block (16 ), while the arc angles of the semi-annular stepped bushing of the upper sector block (13) and the arc of the lower part of the semi-annular stepped bushing of the upper sector block (14) are 180°. 13. The device according to claim 1, characterized in that nine fencing plates (17) are evenly located inside the lower sector block (4), which make up the lattice zone (20), while a chamfer is made in the upper part of each fence plate (17) to prevent foreign fragments from falling onto the side surface. 14. The device according to claim 1, characterized in that the upper sector block (2) and the lower sector block (4) are located coaxially on top of each other, while the upper sector block (2) is located above the lattice zone (20) of the lower sector block ( 4), the lattice zone (20) is not only a container for collecting foreign elements, but also supports the upper sector block (2) during its rotation. 15. The device according to claim 1, characterized in that the clamp shaft (7) is made hollow, while during installation both ends of the clamp shaft (7) expand and retract outward to prevent axial displacement of the clamp shaft (7). 16. The device according to claim 1, characterized in that in the normal state the torsion spring (6) is open, while under the force of the torsion spring (6) the clamp of the upper sector block (5) and the clamp of the lower sector block (8) close together. 17. The device according to claim 1, characterized in that the clamp of the upper sector block (5) is a stepped semi-ring, in working condition the force of the torsion spring (6) through the large end of the clamp of the upper sector block (5) and the lower end of the semi-annular stepped sleeve of the upper sector block (12) is transferred to the step position sensor, after which a friction force arises, while the small end of the clamp of the upper sector block (5) comes into contact with the step position sensor and then creates a friction force. 18. The device according to claim 1, characterized in that the clamp of the lower sector block (8) is a semi-circular structure, glued and fixed in the lower part of the semi-annular stepped bushing of the lower sector block (19), while the force of the torsion spring (6) through the lower sector block (4), the half-ring washer of the lower sector block (3) is transferred to the stepper position sensor, after which a friction force arises. 19. The method of operation of the device for collecting the spent graphite sealing ring of the stepper position sensor of the control rod of a nuclear reactor, characterized in that - at the first stage, the clamp of the lower sector block (8) is opened, the upper sector block (2) is rotated counterclockwise so that its span is sufficient for the stepper position sensor to enter the center of the device for collecting the spent graphite sealing ring; - at the second stage, a device for collecting the spent graphite sealing ring is placed next to the stepper position sensor so that the stepper position sensor enters the center of the device; - at the third stage, the upper sector block (2) is rotated clockwise, a closed area is formed between the upper sector block (2) and the lower sector block (4); - at the fourth stage, the clamp of the lower sector block (8) is released so that under the force of the action of the torsion spring (6) the device for collecting the graphite sealing ring is clamped on the stepper position sensor, check the clamping of the device for collecting the spent graphite sealing ring; - at the fifth stage, the clamp of the lower sector block (8) is opened, the upper sector block (2) is rotated counterclockwise so that its span is sufficient for the stepper position sensor to separate from the center of the device for collecting the spent graphite sealing ring; - at the sixth stage, the device for collecting the spent graphite sealing ring is separated from the stepper position sensor, the upper sector block (2) is rotated clockwise, a closed area is formed between the upper sector block (2) and the lower sector block (4); - at the seventh stage, the clamp of the lower sector block (8) is released, foreign elements that have fallen on the upper sector block (2) and the lattice zone (20) of the lower sector block (4) are removed.

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