RU53456U1 - DIRECT CHARGE NEUTRON DETECTOR - Google Patents

Abstract

The direct charge neutron detector (hereinafter referred to as the SCD) belongs to the field of technology related to the measurement of ionizing radiation, in particular, to the equipment of control systems and protection of nuclear reactors. DPS is used as a primary converter of intra-reactor channels for monitoring neutron flux density.

DPZ contains a collector, an emitter made in the form of a piece of wire made of rhodium, silver, vanadium (or a capillary tube filled with hafnium oxide), an insulator located between the emitter and the collector, and a communication line made of a cable with mineral insulation designed to transmit electrical signal from the emitter to electronic equipment. The cable contains an element for monitoring the background current in the form of an auxiliary current-carrying cable core located along the main current-carrying cable core with mineral insulation and isolated from it. A cable gland is installed at the end of the cable, to which the main and auxiliary cores of the cable are connected. The Germanovod is made in the form of an element consisting of a glass with two flanges, one of which is hermetically connected to the cable sheath, and ceramic-metal insulators are placed on the other flange, one of which is designed for hermetically welded connection of the main current-carrying core of the cable, and the other for auxiliary current-carrying veins. A plug designed to provide vacuum drying of the cable insulation is hermetically connected to each ceramic-metal insulator.

Description

The technical field to which the utility model belongs (direct charge neutron detector, hereinafter referred to as DPS) is the measurement of ionizing radiation, in particular, to the equipment of control and protection systems for nuclear reactors and is used as a primary converter of intra-reactor channels for monitoring neutron flux density.

The main requirements for SCD for in-reactor channels for controlling neutron flux density include high reliability and sensitivity with minimal transverse dimensions.

To ensure the reliability and noise immunity of the intra-reactor channels for monitoring the neutron flux density, the SCD is structurally combined with shielding elements, electrical connectors, and an external casing in one device.

When creating a DPS for intra-reactor channels for monitoring neutron flux density, the requirement for reliability and stability of parameters is one of the critical parameters. So, for example, in the system of in-reactor control of energy release of a nuclear power reactor, up to 80 control channels are used with the use of DPS and their failure during the campaign is allowed to be no more than 10% of the DPS.

A direct charge neutron sensor is known, including a cylindrical body, which is a collector in which an emitter of rhodium wire is coaxially located, an insulating element made in the form of an electrical insulating tube, the walls of which are located between the emitter and the collector, a cable, one core of which is connected to the emitter, and the second is auxiliary and serves to

control of the background current, the cable sheath on the opposite end from the emitter is hermetically connected to a pressure lead, which is used as a metal sleeve filled with an epoxy compound (Mittelman MG et al. “Detectors for in-reactor measurements of energy release”, M., Atomizdat, 1997 .). The disadvantage of the described detector is its insufficient reliability of the pressure seal using an epoxy compound, due to the depressurization of the pressure seal during operation, the insulation resistance of the DPZ decreases below the permissible limit due to sorption of atmospheric moisture and the DPZ fails.

There is also a known design of a surge protection circuit in which the insulator between the emitter and the collector is made in the form of a dense packing of magnesium oxide or aluminum powder (Autushenko A.F. et al., RF Certificate for Utility Model No. 29380 IPC ⁷ G 01 T 3/00 Claims 08/14/02. Publish. 05/10/03. Bull. No. 13) The disadvantage of this design is that a metal sleeve filled with an epoxy compound is used as a pressure seal.

The closest technical solution to the claimed one is a direct charge neutron sensor, including a collector made of a material with a small cross section for interaction with neutrons, an emitter made in the form of a piece of wire made of rhodium, silver, vanadium or a capillary tube filled with hafnium oxide, an electrically insulated tube made of pressed a powder of magnesium oxide or aluminum oxide located between the emitter and the collector, a cable with mineral insulation, designed to transmit an electrical signal from the emitter to electronic equipment, an element of background current control in the form of an auxiliary current-carrying cable core, located along the main current-carrying cable core with mineral insulation and isolated from it, a cable gland installed on the cable end to which are connected

the main and auxiliary cable veins (Mittelman MG et al., RF Patent No. 2138833 IPC ⁶ G 01 T 3/00, H 01 J 47/12 decl. 08.02.99, publ. 27.09.99).

The specified design is characterized by good metrological properties and does not require individual calibration of the DPZ before installation in the reactor.

However, in this design, the sealing of the leads of the signal and background cores is carried out using a block in which the leads of both cores are passed through metal tubes and connected to them by soldering or welding. The tubes, in turn, are simultaneously hermetically soldered into the insulating glass part of the metal-glass block. The shell of the glass-metal block is hermetically welded to the cable sheath.

A significant drawback of such a technical solution is the low reliability of the sealing metal-glass block due to the difficulty of ensuring the tightness of the block while soldering two tubes with a small diameter of the block, as well as the low manufacturability and non-repairability of the specified connection. In addition, it is impossible to connect a DPZ with the specified design of the pressure seal to the vacuum system to ensure high-quality drying of the insulation of the DPZ.

The authors of the utility model were faced with the task of improving the reliability and manufacturability of the sealing unit, as well as providing the possibility of operational control of tightness and eliminating welding defects during the manufacturing process of DPD and eliminating adhesive joints, as well as providing the possibility of connecting the DPZ to the vacuum system to ensure drying of the DPZ insulation.

The problem is solved in that a DPZ containing a collector made of a material with a small cross section for interaction with neutrons, an emitter made in the form of a piece of wire made of rhodium, silver, vanadium or a capillary tube filled with hafnium oxide, an insulating tube made of pressed powder of magnesium oxide or oxide aluminum located between the emitter and the collector, cable with

mineral insulation, designed to transmit an electrical signal from the emitter to electronic equipment, a background current control element in the form of an auxiliary current-carrying cable core, located along the main current-carrying cable core with mineral insulation and isolated from it, a cable gland installed on the cable end to which the main and auxiliary cable conductors.

In the claimed design, the pressure seal is made in the form of an element consisting of a glass with two flanges, one of which is hermetically connected to the cable sheath, and ceramic-metal insulators are placed on the other flange, one of which is designed for hermetically welded connection of the main current-carrying core of the cable, and the other for auxiliary live conductor. This design of the hermetic lead-in allows for a site-by-site check of the tightness of this DPZ element and, if necessary, elimination of welding defects, and also eliminates the use of adhesive joints. In addition, plugs are connected to the ceramic-metal insulators by welding, which allow connecting the DPZ to the vacuum system for high-quality drying of the DPZ insulation. At the same time, the reliability of the DPZ as a whole increases.

The specified set of distinctive features indicates the conformity of the claimed DPS to the criterion of "novelty."

The essence of the utility model is illustrated by figure 1, which schematically depicts the claimed design of the DPS.

DPS contains a collector 1 (see Fig. 1) made of an electrically conductive material with a small interaction cross section with neutrons, in which an emitter 2 is placed, made of a material with a high interaction cross section with thermal neutrons and emitting electrons as a result, an insulating element 3 located between the emitter and the collector and made of a material with a small cross section for interaction with neutrons, cable 4, current-carrying core 5

which is connected by welding or soldering to the emitter, and the sheath 6 is hermetically welded or soldering connected around the perimeter to the collector.

The insulating element 3 is made in the form of a dense packing, for example, of aluminum oxide or magnesium oxide powder, and the collector 1 is made of stainless steel.

The collector ends with a plug 7, designed to connect DPZ to the vacuum system to ensure high-quality drying of the insulating element 3.

At the opposite end of the cable 4 to the emitter, a pressure seal is connected hermetically by welding or soldering to its sheath 6, consisting of a flange 9, a cup 10 and a flange 11, to which metal-ceramic insulators 12 are tightly connected, to which, in turn, a current 5 is connected by welding or soldering and background 8 cores of cable 4. Metal-ceramic insulators 13 are equipped with plugs 13 designed to connect the DPZ to the vacuum system for high-quality drying of its insulation. To connect the DPZ to the system with electrical connectors of the internal reactor control system, the plugs are equipped with flexible conductors 14.

DPZ is made as follows.

The collector 1 is made of a tube of steel 12X18H10T with an external diameter of 2 to 3 mm and a length of 120 to 7000 mm. The emitter 2 is located in the collector, which is either a wire of rhodium or silver, or a capillary tube filled with hafnium oxide. These materials have a high cross section for interaction with thermal neutrons. The insulating element 3 is located between the emitter 2 and the collector 1 and is a dense packing of fine powder of aluminum oxide or magnesium oxide.

As the communication line of the DPZ with the electronic equipment of the internal reactor control system (not shown in FIGS. 1 and 2), a two-core cable with mineral insulation and a conductive sheath is used,

for example, CNMS with a diameter of 1 to 1.5 mm. The current-carrying core 5 of the cable is connected to the emitter 2, for example, by laser welding, and its sheath 6 is hermetically connected to the collector 4 around the perimeter, for example, by laser welding.

To the cable 4 around the perimeter of the sheath 6 a hermetic inlet is connected hermetically (for example, by laser welding), consisting of a flange 9, a cup 10 and a flange 11 with ceramic-metal insulators 12. The hermetic inlet is assembled separately from the DPZ, it is checked for leaks by a mass spectrometric method, and then attached to cable sheath 6 4.

After connecting the cable gland to cable 4, the current-carrying core 5 and background core 8 of the cable are laser-welded to the ceramic-metal insulators 2. Then, the metal-ceramic insulators 12 are hermetically laser-welded by means of plugs 13, which are tubes 2 × 0.2 in diameter made of 12X18H10T steel, designed for connecting DPZ to the technological vacuum system in the process of vacuum drying the porous insulation of the cable 4.

The collector 1 is equipped with a plug 7, designed to connect DPZ to the technological vacuum system during the vacuum drying of the insulating element 3.

The shtangels 7 and 13 are connected to the technological vacuum system, the tightness of the welded joints of the DPZ is checked by the mass spectrometric method, if necessary, the defects of the welded joints are corrected and the tightness checked again.

After obtaining satisfactory leakage control results, the plugs 7 and 13 are connected to the technological vacuum system and vacuum insulation of the DPZ elements is vacuum dried at a temperature of at least 150 ° C.

The drying quality of the insulation of the elements of the DPZ is controlled by the insulation resistance between the terminals of the current and background conductors and

DPZ case, which is the main technological parameter that determines the quality of DPZ.

DPZ works as follows. In the reactor core, after the neutron flux is exposed to emitter 2, it becomes radioactive and the final result of radioactive decay is the electrons that pass through the insulating element 3 and reach collector 1. In this case, a current occurs that is proportional to the neutron flux at the location of the SCR. The neutron flux, in turn, is proportional to the energy release in the nearest fuel element of the fuel cartridge.

In comparison with the known, the claimed DPS is characterized by increased manufacturability and maintainability, as well as the ability to control parameters at all stages of the manufacturing process.

Claims (1)

Direct charge neutron detector, comprising a collector made of a material with a small cross section for interaction with neutrons, an emitter made in the form of a piece of wire made of rhodium, silver, vanadium or a capillary tube filled with hafnium oxide, an electrical insulating tube made of pressed powder of magnesium oxide or aluminum oxide, located between the emitter and the collector, a cable with mineral insulation, designed to transmit an electrical signal from the emitter to electronic equipment, an element for monitoring the background current in The idea of an auxiliary current-carrying cable core, located along the main current-carrying cable core with mineral insulation and isolated from it, is a cable gland installed on the cable end to which the main and auxiliary cable cores are connected, characterized in that the cable gland is made in the form of an element consisting of a glass with two flanges, one of which is hermetically connected to the cable sheath, and ceramic-metal insulators are placed on the other flange, one of which is designed for tight welded backing connections of the main current-carrying core of the cable, and the other for the auxiliary current-carrying core, with a plug designed for vacuum drying of the cable insulation tightly connected to each ceramic-metal insulator.