RU46108U1 - IONIZATION DIVISION CAMERA - Google Patents

Abstract

A useful model — the ionization fission chamber, hereinafter referred to as ICD — relates to the technique of measuring ionizing radiation, in particular, to the equipment of control and protection systems for nuclear reactors and is used as a primary converter of the in-reactor channel for controlling neutron flux density. The essence of the utility model lies in the fact that the ICD contains a cylindrical body made in the form of a multi-section one-piece assembly, with the inner electrode coaxially located inside it, coated with fissile material deposited on the inner surface of the cylindrical body and the outer surface of the inner electrode, spacer cylindrical insulators, a ceramic-metal assembly and a plug, and a tight connection of sections in order to increase the reliability of the ICD is carried out by bushings that overlap the outer Ortsevo sample spacing of adjacent sections and isolators. The proposed design of the ICD is characterized by a small diameter, reduced length compared to the analogue, high sensitivity and reliability, which makes it possible to measure the neutron flux and its spatial distribution directly in the active zone of an energy reactor. 1 illustration.

Description

The technical field to which the utility model belongs (ionization fission chamber, hereinafter referred to as ICD) is the measurement of ionizing radiation, in particular, to the equipment of control systems and protection of nuclear reactors and is used as a primary converter of an intra-reactor channel for monitoring neutron flux density.

The main requirements for ICD 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 channels, the ionization chamber is structurally combined with communication lines, shielding elements and an external casing into one device, called the suspension of the ionization chamber.

When creating suspensions and ICDs for intra-reactor channels for monitoring neutron flux density, limiting the diameter of ICDs is one of the critical parameters. For example, the diameter of the channel inside the active zone of the energy reactor, into which the suspension of the ionization chamber can be placed, as a rule, does not exceed 6 mm.

Known ionization fission chamber, including a cylindrical body, in which the inner electrode is coaxially located, separated with the housing by distance insulators, a ceramic-metal assembly and a plug (V.I. Alekseev, I.Ya. Emelyanov, V.M. Ivanov, etc. A.s. USSR No. 482704 IPC ³ G 01 T 3/00, decl. 08/03/1973, publ. 08/05/1976, bull. No. 29). In addition, an outer collecting and intermediate guard coaxial electrodes are installed in the housing along the length of the chamber. Intermediate guard electrode separated

external distance insulators from the housing and internal insulators from the internal electrode, to which the external collecting electrode is connected by insulated conductive jumpers divided in length into sections located with a gap between the external distance isolating insulators, which are separated by insulators from the intermediate guard electrode, and from the tubular chamber body - a gas-filled gap moreover, a coating of fissile material is applied to the outer surface of the collecting electrode.

The considered design of the ionization chamber has found wide application in monitoring the neutron flux in the active zone of a nuclear reactor when installing the suspension of the ionization chamber outside the active zone.

The disadvantage of this design is the use of numerous elements, which leads to complexity of the design and, most importantly, to increase the diameter of the chamber, which does not allow its use in the suspension, designed to measure the neutron flux density directly inside the active zone of a nuclear reactor.

Known ionization fission chamber, comprising a cylindrical body with an internal electrode located in it, which is coated with fissile material, and spacer insulators, cermet unit and plug. (Malyshev E.K., Stabrovsky S.A. Small-sized ionization chambers and their use in nuclear reactors. - Nuclear technology abroad, 1983, No. 12, pp. 10-17).

The indicated design of the ICD is characterized by a small diameter, is small-sized, which allows it to be used in the suspension of an ionization chamber designed to measure the neutron flux density directly inside the core of a nuclear reactor. However, its significant drawback is its low sensitivity due to the small coating area of fissile material, which does not allow for control of the flux density

neutron nuclear reactor in the muffled state and when it is brought to the rated power level.

The closest technical solution to the claimed is an ionization fission chamber, including a cylindrical body coated internally with fissile material, spacer insulators inserted into the end samples in each section, a ceramic-metal assembly and a ram, the cylindrical body made in the form of a multi-section assembly, and the sections are connected by ring junctions . (Alekseev S.V., Shkolyarenko V.V., Kirichenko G.P. Certificate of the Russian Federation for utility model No. 29382 IPC ⁷ G 01 T 3/00 Declaration. 08/14/02. Publish. 05/10/03. Bull. No. 13)

The indicated ICD design is characterized by a small diameter and can be used in the suspension of an ionization chamber designed to measure the neutron flux density directly inside the core of a nuclear reactor. However, its significant disadvantages include the fact that in order to achieve the required sensitivity, it is necessary to use such a number of sections in the design that leads to a large chamber length, inaccurate positioning of the internal ICD electrode in insulators relative to the cylindrical body, as well as low mechanical strength of end junctions, and leakage which leads to the failure of the ICD.

The author of the utility model was faced with the task of increasing the sensitivity of the ICD to the neutron flux while reducing the length of the ICD, eliminating the inaccuracy of the positioning of the internal electrode relative to the cylindrical body, and also increasing the mechanical strength of the ICD.

The problem is solved in that in the ionization chamber of fission, including a cylindrical body, made in the form of a multi-section one-piece assembly, with the inner electrode coaxially located in it, a coating of fissile material deposited on the inner surface of the cylindrical body and the outer surface of the inner

electrodes, spacer cylindrical insulators, ceramic-metal assembly and plug, end samples are made on the outer surface of each section of the cylindrical body, distant cylindrical insulators are installed flush with the surface of the samples between the end surfaces of each section, and the sections are permanently sealed by cylindrical bushings mounted on the end samples with overlapping samples of adjacent sections and distance insulators and connected to sections and ring welds.

The application of fissile material to the outer surface of the inner electrode increases the coating area, which leads to an increase in the sensitivity of the ICD per unit length of the ICD.

The presence of end samples on the outer surface of each section allows you to perform the diameter and length of the samples with the required tolerances, which ensures the necessary accuracy of the assembly.

The placement of the spacer insulators between the end surfaces of the sections flush with the surface of the samples eliminates the possibility of their movement and, therefore, improves the reliability of the ICD by eliminating the possibility of moving the internal electrode.

The use of cylindrical bushings for connecting the sections provides, firstly, a reliable fixation of the distance insulators and the inner electrode relative to the cylindrical body due to the exact adjustment of the length and diameter of the sleeve, and, secondly, eliminates the possibility of damage to the weld between the sections in case of accidental bending and, therefore eliminates the possibility of violation of the tightness of the ICD and its failure. All this together increases the reliability of the ICD.

The specified set of distinctive features indicates compliance of the claimed ICD with the criterion of "novelty."

The essence of the utility model is illustrated by figure 1, which schematically depicts the claimed ionization fission chamber.

The ionization division chamber consists of a cylindrical body composed of sections 1. In the housing, an internal electrode 2 is coaxially located, having a coating of fissile material 6, as well as distance insulators 3. The cylindrical body is made in the form of an integral multi-section assembly. The sections 1 of the multisectional cylindrical body are connected by bushings 4, made so that their inner diameter is equal to the outer diameter of the spacer insulators 3, the diameter of the end samples of the sections 1 of the ionization chamber body, and the length of the bushings is equal to the total length of the end samples of two adjacent sections 1 and the distance insulator 3 .

On the inner surface of each section 1 is coated with fissile material 5.

To ensure electrical isolation between the inner electrode and the cylindrical body, a ceramic-metal assembly 7 is used.

To degass the internal cavity of the ionization fission chamber, a plug 8 is used. One-piece connection of sections 1, bushings 4, cermet unit 7 and plug 8 is made by laser ring seams.

The number of sections 1 in the ionization division chamber is determined by the required sensitivity of the chamber.

For reliable control of the density of neutron fluxes during fuel overload, measurements of the physical parameters of the elements of the control system and reactor protection after shutdowns and repairs of power reactors, for example, RBMK-1000, it is necessary that the sensitivity of the ICD be at least 5 · 10 ^-3 pulse · cm ² /neutron. In this case, to obtain

the most reliable results on estimating the distribution of the neutron flux density over the height of the reactor core, it is necessary to reduce the length of the ICD if possible.

The cylindrical housing 1 of the ionization chamber is made of tubes of steel 12X18H10T with a diameter of 3 mm with a wall thickness of 0.5 mm and a length of 70 mm. Due to the fact that a coating of fissile material 5 and 6 (uranium with ²³⁵ U isotope enrichment up to 95%) is applied to the inner surface of the cylindrical body 1 and the outer surface of the inner electrode 2, the total coating area is approximately doubled compared to ICD, in which a coating of fissile material is applied only to the inner surface of the cylindrical body. Therefore, to obtain the necessary sensitivity, the length of the ICD is significantly reduced. The surface density of the coating is 1 mg / cm ² (the value is selected experimentally and is consistent with literature data).

The spacer insulators 3 are made of ceramics consisting of 99% aluminum oxide (Al ₂ O ₃ ) in the form of cylinders with an external diameter of 2.5 mm and a length of 3 mm and an opening diameter of 0.85 mm.

End samples at the ends of sections 1 are made to a length of 3 mm to a diameter of 2.5 mm, and the diameter of the samples corresponds to the outer diameter of the spacer insulators 3.

The bushings 4 are made of tubes made of steel 12X18H10T, and their diameter corresponds to the outer diameter of the insulators 3 and end samples of sections 1, and the length is adjusted according to the total length of end samples of two adjacent sections 1 and insulator 3.

The output of the internal electrode 2 and its electrical connection with the measuring equipment is carried out through a sealed ceramic-metal insulator 7

Pumping, checking for leaks and filling the ICD with the working gas mixture is carried out through the plug 8, which, after refueling the ICD with the working gas mixture, is pressed and welded.

The assembly of the iopization fission chamber consists in joining the sections 1 (coated with fissile material 5), the spacer insulators 3 and the bushings 4, laser welding of the circumferential welds (in the figure, the welding is indicated by the welding symbol in accordance with the requirements of ESKD), installation in the remote insulators of the internal electrode 2 with a coating 6 of fissile material, installation and welding of a ceramic-metal insulator 7 with a section of the housing 1 and the internal electrode 2, installation and welding of the plug 8.

During the assembly of the ICD, an intermediate technological control of the insulation resistance between the cylindrical body and the inner electrode is performed, as well as the electrical breakdown of the interelectrode gap.

After assembling the ICD and monitoring the insulation resistance between the cylindrical body and the inner electrode, as well as electrical breakdown of the interelectrode gap, the ICD is installed on a vacuum stand to check for leaks using the mass spectrometric method, pumping and refueling with the working gas mixture.

The ICD is connected to electronic recording equipment by a radiation and heat-resistant cable.

ICD works as follows. When the ICD is irradiated with a neutron flux, fission nuclei of the coating are made of fissile material, fission fragments ionize the atoms of the working gas mixture, the resulting space charge creates a current pulse recorded by electronic equipment.

The inventive ICD has the following technical characteristics: the sensitivity of the ICD, consisting of 4 sections, is at least 1 · 10 ^-2 pulse · cm ² / neutron, diameter 3 mm, length 350 mm

These technical characteristics make it possible to ensure reliable control of the neutron flux and its spatial distribution directly in the active zone of the RBMK-1000 nuclear power reactor in all modes of its operation, including the muffled state and fuel overload.

Claims (1)

Ionization fission chamber, including a cylindrical body made in the form of a multi-section one-piece assembly, with an internal electrode coaxially located in it, a coating of fissile material deposited on the inner surface of the cylindrical body, spacer cylindrical insulators, ceramic-metal assembly and plug, characterized in that on the outer end surfaces of each section of the cylindrical body are made, distance between end surfaces of each section is set iruyuschie cylindrical insulators flush with the surface of the samples, one-piece sealed connection sections is carried out by cylindrical bushings, each sampling overlapping end sections, and a spacer insulator disposed therebetween, and the outer surface of the inner electrode coated with fissile material.