RU98825U1 - RADIATION DETECTION BLOCK - Google Patents

Abstract

 1. The radiation detection unit containing a detector located in a sealed enclosure and at least one sealed cable communication line with an electrical connector, characterized in that the cable communication line is made of metal thermo-radiation-resistant cable with a sealed sheath, an internal electromagnetic shield and mineral insulation while the internal volume of the cable communication line is separated from the internal volume of the electrical connector by means of vacuum-tight insulating fittings. ! 2. The radiation detection unit according to claim 1, characterized in that the internal volume of the sealed cable communication line is separated from the sealed volume of the casing of the detection unit by means of vacuum tight insulating fittings. ! 3. The radiation detection unit according to claim 1 or 2, characterized in that the vacuum-tight insulating reinforcement comprises hollow ceramic-metal insulators, one of which is installed between the sheath and the internal electromagnetic screen, and the other between the internal electromagnetic screen and the current-carrying residential cable. ! 4. The radiation detection unit according to claim 3, characterized in that the ceramic-metal insulators are connected to the sheath, the internal electromagnetic shield and the current-carrying residential cable by means of intermediate metal bushings, while in the bushings connecting the insulator to the electromagnetic screen and the current-carrying residential cable, side channels for evacuating the cable and filling it with inert gas or a mixture thereof. ! 5. The radiation detection unit according to claim 3, characterized in that each ceramic-metal insulator for sealing

Description

The utility model relates to the field of measurement technology, and more specifically to devices for recording high flux densities of ionizing radiation from nuclear reactors or nuclear facilities of research scientific centers, and can be used to measure the flux density of neutron radiation generated by the source. The utility model can be applied in equipment for the protection and control of nuclear reactors at stationary nuclear power plants.

A known detection unit containing a radiation detector galvanically separated from the casing of the detection unit using insulators (see USSR copyright certificate "Block detection of radiation" No. 555718 of January 7, 1976). A disadvantage of the known detection unit is leakage and low radiation resistance of the cable communication line.

Closest to the proposed technical solution is a detection unit containing a radiation detector galvanically separated from the housing of the detection unit, in which the cable lines are made of a sealed metal thermo-radiation-resistant cable with mineral insulation (see patent JP 54-139781 of October 30, 1979) A disadvantage of the known detection unit is the low noise immunity from sources of electromagnetic interference, since the body of the electrical connector is installed directly o on the outer metal sheath of the cable. A disadvantage of the known detection unit is also the high cost of vacuum-tight electrical connectors, while the connectors together with the cable form a sealed non-separable structure fixed to the cable by welding or soldering. The nomenclature of the manufactured connectors has a very limited range of sizes and, as a rule, has only a straight type of connector housing, coaxial with the cable, which limits the possibility of using the known detection unit and creates inconvenience when connected to measuring equipment with a lateral arrangement of input connectors, since the metal cable with mineral insulation allows a very small amount of kinks during installation. In case of failure of the electrical connector, for example, due to damage to the threaded part of the connector, the entire detection unit becomes unusable, since the sealed electrical connector forms a non-repairable construction together with the cable.

The objective of the utility model to be solved is to increase the noise immunity in severe electromagnetic conditions when working in the environment of industrial sources of electromagnetic interference, expand the range of used electrical connectors, simplify the assembly process, increase the reliability and service life of the detection unit in case of failure of the electrical connector.

The technical result from the use of the utility model is to unify the design of the detection unit for connection to various measuring equipment, increase the sensitivity of radiation detectors, increase the reliability and ease of use, expand the applicability, improve maintainability, reduce the requirements for compliance with the production of vacuum hygiene rules and the quality of intermediate operations , decrease in marriage, decrease in cost. Such a detection unit can be used in conditions of high humidity, pressure, temperature and mechanical stresses under the influence of a high flux density of ionizing radiation of a nuclear reactor.

The specified technical result is achieved in that the detecting unit comprises a detector located in a sealed enclosure and at least one sealed cable communication line with an electrical connector. The cable communication line is made of metal thermo-radiation-resistant cable with a sealed sheath, an internal electromagnetic shield and mineral insulation. The internal volume of the cable communication line is separated from the internal volume of the electrical connector by means of vacuum-tight insulating fittings.

The internal volume of the sealed cable communication lines is separated from the sealed volume of the casing of the detection unit by means of vacuum-tight insulating fittings.

Vacuum-tight insulating fittings contain hollow cermet insulators, one of which is installed between the sheath and the internal electromagnetic shield, and the other between the internal electromagnetic shield and the current-carrying residential cable.

Ceramic-metal insulators are connected to the sheath, the internal electromagnetic shield and the current-carrying residential cable by means of intermediate metal bushings, while in the bushings connecting the insulator to the electromagnetic screen and the current-carrying residential cable, side channels are made for evacuating the cable and filling it with an inert gas or a mixture thereof.

Each ceramic-metal insulator for sealing cables contains a ceramic sleeve connected to conical sleeves from Kovar through a sealed ceramic-metal junction.

The outer surface of the insulators for cable sealing is made wavy to reduce leakage currents.

All insulators of cable communication lines are made the same.

The input of cable communication lines into the sealed casing of the detection unit is made through transitional metal bushings.

The vacuum-tight insulating reinforcement of the cable communication line from the side of the electrical connector is equipped with a protective casing isolated from the cable sheath.

Radial grooves are made in the casing of the vacuum-tight insulating fittings, while the electrical connector is provided with a sleeve with protrusions corresponding to the said grooves.

The utility model is illustrated by drawings.

Figure 1 shows the detection unit.

Figure 2 shows a cable communication line from the side of the connector.

Figure 3 shows a cable line with a corner connector.

Figure 4 shows a section aa in figure 2 and figure 3.

A utility model can be implemented as follows. The radiation detector 1, which can be used as an ionization chamber, is placed in a sealed casing 2 of aluminum or stainless steel. The casing 2 is provided with a flange 3, through which the cable lines are inserted into the sealed casing 2 and filled through an inert gas 4 or an inert gas mixture or mixture thereof, in particular nitrogen. The radiation detector 1 is galvanically separated from the casing of the detection unit 2 by means of a ceramic insulator 5.

Cable communication lines (one or several) are made of a heat-radiation-resistant cable with a sealed metal sheath 6, an internal electromagnetic shield 7 and mineral insulation, for example, KNMS2S or KNMMS brands. To ensure constant insulation resistance, the internal volume of the cable communication line is separated from the internal volume of the electrical connector 8 by means of vacuum-tight insulating fittings. Also in the described embodiment, the internal volume of the sealed cable communication lines is separated from the sealed volume of the casing 2 by means of identical vacuum-tight insulating fittings. The cable communication line is filled through the pumping tubes 9 with an inert gas or a mixture thereof, in particular nitrogen.

Vacuum tight insulating fittings contain hollow cermet insulators, one of which is installed between the sheath 6 and the shield 7, and the other between the shield 7 and the current-carrying core 10 of the cable and connected to the sheath 6, the shield 7 and the core 10 through intermediate metal bushings 11. In the bushings connecting an insulator with a screen 7 and a current-carrying core 10, side channels are made for evacuating the cable and filling it with inert gas or a mixture thereof.

The ceramic-metal insulator for sealing the cable communication line contains a ceramic sleeve 12 made of a vacuum-tight material that is resistant to a large integral neutron flux and gamma radiation, for example, ceramic with a high content of aluminum oxide, connected to conical sleeves 13 from a carpet using a sealed ceramic-metal junction. To reduce leakage currents on a contaminated or wet surface, the insulators are wavy on the outside.

In order to increase the manufacturability of the design, all ceramic-metal insulators have the same shape, which allows vacuum soldering of the entire assembly of vacuum-tight insulating fittings as one typical technological operation. To minimize the gap between ceramics and metal, ceramic sleeves 12 have a conical self-centering junction surface with sleeves 13.

The ends of the sleeves 13 by welding or soldering with high-temperature solder are connected to the intermediate sleeves 11 of stainless steel.

The input of the cable communication lines into the sealed casing of the detection unit is made through transition metal sleeves 14 of the flange 3 by welding or soldering, which simplifies assembly and divides it into typical technological operations of sealing each cable and the detection unit as a whole.

In order to mechanically protect the insulating fittings, as well as to increase the noise immunity and sensitivity of the detector 1, the vacuum-tight insulating fittings of the cable line from the side of the electrical connector 8 is provided with a protective casing 15, insulated from the cable sheath 6 by means of a dielectric washer 16. In the casing 15, radial grooves are made, when this connector 8 is provided with a sleeve 17 with protrusions corresponding to the said grooves. The combination of grooves with protrusions provides a choice of the angular position of the connector relative to the fixed cable, which significantly increases the ease of use. The grooves made on the casing 15 allow you to arbitrarily change the type of electrical connector 8 (plug or socket), the shape of its body (straight or angular) and its connecting dimensions, which allows you to quickly and reliably connect the detection unit with various measuring equipment depending on operating conditions. Moreover, in case of failure of the electrical connector 8, it can be easily replaced by a working one, which extends the life of the detection unit as a whole, increases the reliability of the control equipment and reduces operating costs.

The proposed detection unit based on an ionization chamber was tested as part of a suspension of radiation detectors of the VVER-1000 reactor to control the relative physical power and period of the reactor by the value of the thermal neutron flux density and showed high reliability in combination with the technological design. An increase in the reliability and convenience of operation, an increase in the possibility of application was established, the possibility of using such a detection unit under conditions of high humidity, pressure, temperature and mechanical stresses under the influence of a high flux of ionizing radiation from a nuclear reactor was confirmed.

Claims (10)

1. The radiation detection unit containing a detector located in a sealed enclosure and at least one sealed cable communication line with an electrical connector, characterized in that the cable communication line is made of metal thermo-radiation-resistant cable with a sealed sheath, an internal electromagnetic shield and mineral insulation while the internal volume of the cable communication line is separated from the internal volume of the electrical connector by means of vacuum-tight insulating fittings. 2. The radiation detection unit according to claim 1, characterized in that the internal volume of the sealed cable communication line is separated from the sealed volume of the casing of the detection unit by means of vacuum-tight insulating fittings. 3. The radiation detection unit according to claim 1 or 2, characterized in that the vacuum-tight insulating reinforcement comprises hollow ceramic-metal insulators, one of which is installed between the sheath and the internal electromagnetic screen, and the other between the internal electromagnetic screen and the current-carrying residential cable. 4. The radiation detection unit according to claim 3, characterized in that the ceramic-metal insulators are connected to the sheath, the internal electromagnetic shield and the current-carrying residential cable by means of intermediate metal sleeves, while the bushings connecting the insulator to the electromagnetic screen and the current-carrying residential cable have side channels for evacuating the cable and filling it with inert gas or a mixture thereof. 5. The radiation detection unit according to claim 3, characterized in that each ceramic-metal insulator for sealing cables contains a ceramic sleeve connected to conical sleeves from Kovar through a sealed ceramic-metal junction. 6. The radiation detection unit according to claim 3, characterized in that the outer surface of the insulators for cable sealing is made wavy to reduce leakage currents. 7. The radiation detection unit according to claim 3, characterized in that all the insulators of the cable communication lines are made the same. 8. The radiation detection unit according to claim 3, characterized in that the cable communication lines are inserted into the airtight casing of the detection unit through transition metal sleeves. 9. The radiation detection unit according to claim 3, characterized in that the vacuum-tight insulating reinforcement of the cable communication line from the side of the electrical connector is equipped with a protective casing isolated from the cable sheath. 10. The radiation detection unit according to claim 9, characterized in that radial grooves are made in the casing of the vacuum-tight insulating reinforcement, while the electrical connector is provided with a sleeve with protrusions corresponding to the said grooves.