SU815795A2 - Ionization chamber - Google Patents

Abstract

<P> The invention relates to an ionization chamber. </ P> <P> This chamber comprises a guard electrode 12 in which are placed the rods 18 of four collecting electrodes 13 to 16. Each rod 18 is connected to a corresponding section of tube 19 surrounding the electrode 12. These sections are separated from each other and spaced from the electrode 12. Their surface constitutes the active surface of the corresponding collecting electrode </ P> <P> Application: Intrazonal control of nuclear reactors. </ P>

Description

one

The invention relates to an ionization chamber for measuring high-intensity neutron n gamma radiation at high temperatures and can be used to measure the distribution of neutron and gamma radiation in the core of nuclear reactors.

It is known to use ionization chambers to measure the distribution of neutron and gamma radiation over the height of the reactor channel, for which beams with independent, isolated from each other chambers 1 are placed in channels of a nuclear reactor.

The disadvantages of such devices are their large size and a large amount of metal, the introduction of which in the core of a nuclear reactor leads to a deterioration of its physical characteristics.

According to the main author. St. 482704 a ionization chamber is known, provided with a communication line from a triaxial cable, hermetically inserted into the camera body. The communication line consists of a central current-carrying metal conductor, a metal outer sheath, and an intermediate metal coaxial sheath, separated by isolation from the center conductor and the outer sheath of the cable.

In the gas-filled housing along the length of the chamber there are three coaxial electrodes: an outer collecting, intermediate guarding and central one, which is connected to the central current-carrying residential triax cable of the communication line. The intermediate security electrode of the chamber is connected to the intermediate sheath of the triaxial cable of the communication line, is isolated from the central electrode of the chamber, and is separated from the camera body by discretely placed distance-insulators. The outer collecting electrode consists of sections located with a gap between the outer distance isolators and separated by isolation from the intermediate guard electrode and the gas gap from the camera body. The outer electrode sections are electrically connected by insulated jumpers to the central electrode of the chamber and the cable. The communication lines and working electrodes of the chamber can be made on the basis of a single triaxial cable. With this arrangement, the central and intermediate electrodes of the chamber serve as continuations of the central core and intermediate sheath of the triaxial cable of the communication line.

The sections of the collecting electrode and the outer IOLYATO1Zh1 of the intermediate electrode are the segments of the outer sheath and the ISOLATION of the cable located between the outer and intermediate electrodes. The end surfaces of downstream insulators and insulators between the outer and intermediate shells of the triax cable of the communication line in the chamber volume are sealed with a coating of radiation-resistant metal ceramics.

To register neutrons, the outer surface of the collecting electrode is coated with a neutron sensitive substance, for example, a fissionable substance 2.

However, the camera allows to measure only the value of the integral radiation flux using; the camera cannot measure the distribution of neutron and gamma radiation along its length. The camera also does not allow simultaneous acquisition of separate measurements of neutron and gamma fluxes.

The purpose of the invention is to expand the functions of the ionization chamber by allowing the measurement of the distributions of the neutron and gamma-rays along its length, as well as the possibility of separately recording the neutron and gamma streams.

This goal is achieved by the fact that the central electrode is made in the form of several, at least two central cores located inside the guard electrode and isolated from each other and from the guard electrode. Kazkda central core is connected to a conductive jumper with at least one section of the outer collecting electrode. The number of central cores in the triaxial cable is equal to the number of cores of the chamber electrode.

In addition, in the case of simultaneous registration of neutron and gamma-ray. the uncoated collecting electrode section radiation sections and sections equipped with a neutron sensitive material coating are arranged alternately.

FIG. 1- shows a small ionization chamber, longitudinal section; in fig. 2 shows the node B in FIG. 1, in the place where the communication line crosses into the internal structure of the chamber, a longitudinal section; in fig. 3 shows section A-A in FIG. one.

The compact ionization chamber includes a sealed cylindrical body 1 of heat-resistant and radiation-resistant conductive material, welded to adapter 2, which in turn is welded to the outer shell 3 of the communication line. The adapter 2 is the entry point of the communication line into the housing 1. In the communication line, the central current-carrying wires in an amount of, for example, four 4-7, intermediate shell 8 and outer shell 3, are made

made of corrosion-resistant steel, insulated from each other by compressed powdered magnesium oxide 9 and 1

In the housing 1, a cylindrical tube made of an electrically conductive material with holes, which is a guard electrode, is laid coaxially along its length. The guard electrode 11 is isolated from the case 1 by spaced spacing insulators 12 and is connected to the intermediate shell of the communication line 8 by a metal adapter 13.

Inside the guard electrode 11, central current-carrying conductors 14-17 are placed, insulated from each other and the guard electrode by tubular insulators 18, for example, of alundum. Each of the central current-carrying veins of 14-17 is connected to one of the central current-carrying veins of 4-7 communication lines ..

In the intervals between the spacing insulators 12 on the guard electrode 11, pipe sections 19-22 are fixed, which are sections of the collecting electrode, which are isolated from the protective electrode 11. The insulation 23 between the protective electrode 11 and the sections of the collecting electrode 19-22 is separated by an outer surface guard electrode from spacer insulators 12. Each section of collecting electrode 19 is electrically connected by an insulated jumper 24 to one of the central current-carrying veins 14-17 of the chamber. Jumpers 24 are laid through holes in the guard electrode 11.

Thus, inside the housing 1, several, for example, four independent recording volumes are actually formed, arranged along the axis one after the other with collecting electrodes 19-22. The number of independent registration volumes corresponds to the number of central veins in the housing.

The outer surface of some sections, such as 19 and 21, of the collecting electrode for detecting neutron radiation, is covered with a layer of fissile material.

The outer surface of the sections of the electrodes 20 and 22, intended for the detection of gamma radiation, does not have a dividing coating.

The housing 1 is filled with an inert gas through the pingels 25, welded to the end cap 26 and closed with a lid 27. In the lower part of the housing 1 there is a volume 28 free from electrodes, which is the ballast volume.

Sealants-29 are installed in the communication line above adapter 2 at a distance chosen depending on the operating conditions of the chamber. They are enclosed in a sealed cylindrical body 30 welded to adapters 3-. These adapters are welded to the outer shell of the communication line by high-temperature fast ice. The free end of the communication line is sealed with insulators 32. Power supply 33 is connected between the outer and intermediate cable sheaths. The central cores are connected to the guard electrode through low-resistance current meters 34-37.

The lines of communication, entry into the chamber and working electrodes of the chamber can be made on the basis of a single stranded triax cable. In this case, the central current-carrying wires 14-17 of the camera and the guard electrode 11 are a continuation, respectively, of the central current-carrying wires 4-7 triaxial cable communication lines and intermediate cable jacket 8. As in the communication line, the central cores 14-17 of the chamber and the electrode 11 are un-insulated from each other by compressed magnesium oxide. Along the length of the outer sheath of a stranded triaxial cable enclosed in the housing 1, the outer sheath of the cable is cut and isolated from the intermediate sheath. A portion of the remaining sections of the outer sheath of the cable 38 and the insulation of the cable, together with the spacer rings 39 welded to them, form the spacer insulators 12 separating the intermediate sheath — the guard electrode 11 from the camera body 1.

Alternating with spacer insulators, 12 areas of outer shell 19-22 serve as sections of a collecting electrode. They are electrically connected by bridges 24 to the central conductors of the triaxial cable, which are the central current conductors of the 14-17 chambers. The surface sections of the outer sheath of cable 19 and 21 are covered with a layer of a material that is sharing. The surface of the outer shell sections 20 and 22 does not have a coherent coating. Jumpers 24 of stainless steel are located behind the holes made in the outer and intermediate electrodes of the cable. Each re, sliver 24 is welded at one end to one of the central electrodes 14-17, and the other to the profiled

covers 40 of the same material, Kryiki 40 are welded to the collecting electrodes in such a way that the latter retains its outer geometry, which occurred before the trick — the hole. The bridges 24 are insulated from the intermediate guard electrode 11 with magnesium oxide.

The camera works as follows.

Q The power supply 33 supplies a voltage between the camera body 1 and the collecting electrodes 19-22 through low-impedance meters 34-37. At the same time, the voltage of the power supply 33 is supplied between the housing 1 and the guard electrode 11.

When placed - the camera in the mixed field of neutron and gamma radiation in the gaps between the housing 1. and the collecting electrodes 19-22 occurs

0 ionization of the gas filling the chamber.

The current arising between the housing 1 and the collecting electrodes 20 and 22 is proportional to the level of gamma radiation in the region where these electrodes are located.

. The current arising between case 1 and collecting electrodes 1.9 and 21 is proportional to the total ionization effected in an insignificant degree of rai / iMa radiation and, mainly / by fission fragments, flying off with-. the surfaces of collecting electrodes 19 and 21 due to the interaction of neutrons with the material of the coating being divided.

Thus, the camera measures the level of the neutrino flux at the locations of the electrodes 19 and 21 and the level of gamma radiation at the locations of the electrodes 20 and 22.

When heating the chamber in the reactor

0, the pressure of the gas in the volume of housing 1 occurs and the resulting redistribution of gas between the total volume of pores in the magnesian isolation of the communication line and the volume of the body

5 A change in the density of a gas in a chamber leads to a change in the sensitivity of individual detection volumes to neutron and gamma radiation. This effect is largely

0 is compensated by the gas in the ballast volume of the chamber, since, with an appropriate choice of the size of the ballast volume, the amount of gas in this volume must

c cjiiiecTBeHHo to exceed the amount of gas in the pores of the magnesian isolation of the communication line.

When reducing the insulation resistance between the housing 1 and the guard electrode 11, the resulting

Claims (2)

0 Leakage currents only load the power supply and do not affect the currents flowing through the low-resistance 34-37 current meters. A decrease in the insulation resistance between the collecting electrodes 19-22 and the guard electrode 11 can only affect if these incidences are measurable with the resistance of low-resistance 34-37 current meters. The main advantage of the camera is the expansion of its functions. Due to the introduction of additional elements, it is possible to measure the distribution of the neutron and gamma streams along the length of the chamber. This makes it possible to increase the accuracy and reliability of the control reactor by increasing the control points in the active zone and simultaneously measuring the neutron and gamma fluxes simultaneously, which makes it possible to refine the ratio between the neutron flux and the energy release, which in stationary modes is more accurately controlled by gamma radiation. Claim 1. Ionization camera on aut. St. 482704, characterized in that, in order to expand its functionality by separately registering neutron and GS1mma-streams and measuring their distribution along the chamber height, the central electrode of the chamber is made in the form of at least two central wires located inside the guard electrode and insulated from it and from each other, each central core being connected to at least one section of the outer collecting electrode, and the number of central cores in the triaxial cable of the communication line corresponds to the number of cores tral chamber electrode. 2. The camera according to claim l, except that the collecting electrode sections are coated with ne-. The sensitive substance and without it are alternated. Sources of information taken into account when examining 1. US Patent 3,043,954, cl. 250-83.1, publ. 1958. 2. Authors certificate of the USSR 482704, cl. G 01 T 3/00, 08/03/73 (prototype). 3