SU314180A1 - CONTROL AND CALIBRATION DEVICE NEUTRON ASSESSORS - Google Patents

Description

The invention relates to devices used to calibrate neutrinos to sensors, including a source of fast neutrols and a detector (or several detectors) of slow neutrons: non-neutron moisture meters, level meters, and geophysical logs of neutron probes.

The problem of calibrating neutrol sensors fills a central place, both in serial production of neutron moisture meters, Geophies 3H4eoKKx npHi6opOB, and in conducting scientific research by measuring neutron scoops to determine the distribution of the density of slow neutrons around a source in the medium (neutron moisture meter, and at least an electron source density in the medium under study (neutron moisture meter, and an element in the environment of neutron neutrons). composition, for example, the hydrogen content of rocks, etc.) or with a slit for measuring the intensity of the neutron flux (dosimetry).

A device for calibrating neutron sensors (moisture meters) is known, which contains a standard lock agent filled with a retarding medium (water, paraffin, plexiglas, plastic, etc.) and several standards (called moisture equivalents) with different slowness. The device also includes an accessory for lifting and lowering the zords and a transparent plastiglas protective screen filled with water. To protect against ga.makvantov use special advanced glass.

When calibrating neutron probes with the aid of the above device, it is necessary, after each measurement (count) of the density of slow neutrons in this standard, to replace the reference moderators. For this, the probe, together with the source of fast neutrons, is removed into a protective container, and after the next reference is set, the probe is again lowered into it. Obviously, the calibration performance suffers due to additional operations caused by the design flaws of the device itself.

The purpose of the invention is to simplify the calibration process and ensure high reproducibility of its results. FIG. 1 shows a general calibration scheme for neutron sensors; in fig. 2 moderator structure with an adjustable moderating ability; “And FIG. 3 dan incision retarder. In the figures, the following symbols are used: / - lifting and lowering device; 2 - retarder; 3-sensor containing a source of 4 fast neutrons and detectors 5 slow neutrons; 6 cable connecting sensor with radiometric equipment 7; 8-movable elements for regulator 2; P-slow environment; 10-cavity to accommodate the sensor 3 during the calibers to-and.

The main principle element in this co-control and calibration device (MCC) is moderator 2. It is a capacitor that is filled with a medium that is a strong moderator of fast neutrons. As it is known from the theory of neutron moderation, such media can be materials in which their composition includes the predominant amount of hydrogen nuclei. These include, for example, water, paraffin, plexiglass, plastics, etc. The container body should be made of corrosion-resistant materials that are not activated by thermal neutrons, for example, from duralumin. The container has a central cavity for accommodating the sensor 3.

A system of moving elements 8 is designed to change the retarding ability of the MCC according to a predetermined program. Changes in the modem power of the MCC can be achieved, for example, by adjusting the amount of moderator in capacitance or by shutting off the neutron flux with the aid of anomalously strong slow neutron absorbers. In the first case, the movable elements are made, for example, from hollow tubes (if liquid retarders are used), performing the role of hydraulic fluid pushers. The extruded amount of liquid is transferred to a special reservoir {not shown in the figures) or in the container itself (the level of the liquid changes with the introduction of basements).

When using a solid moderator, the movable (retractable) elements 8 can be made of the same material as the retarding medium 9.

If at the MCC, its moderating ability is adjusted according to the method of shutting off the neutron flux, the regulating elements should be made out of abnormally strong neutron absorbers, for example, from cadmium. You can also use some combinations when choosing a material for moving elements 8. There are options when a part of these elements is made of a moderator, and another part is made of an absorbent. The basic design of the MCC in this case does not change.

Calibration of neutron sensors is produced as follows. Sensor5 is lowered into the central cavity 10 of the moderator 2, radiometric equipment 7 is connected.

Measuring the counting rate (the density of slow neutrons) for various deceptive abilities creates a calibration curve or calibrates the instrument scale according to the resulting counting rate. The change in the counting rate of the apo is resolved with the aid of an appropriate system for regulating the retarding ability of the moderator. An important advantage of the proposed

The MCC is a high performance when calibrating neutron sensors, as well as using one moderator with an adjustable moderating ability, you can get all the necessary equivalent count rate values. This increases the performance (accuracy) of the results. In addition, the radiation hazard during calibration is reduced.

The above described MCC can be implemented, for example, in the series production of instruments including sensors with a fast source and a slow neutron detector. The proposed device is portable. And therefore it can also be used in field conditions.

Subject invention

Claims (4)

1. A control and calibration device for neutron sensors, which contains a tank with a retarding variable adjustable retarding ability, whose chemical composition includes substances with the predominant amount of nuclei hydrogen, and a central cavity for accommodating a sensor, characterized in that, in order to simplify the calibration process and ensure the reproducibility of its results, the retarding ability control system is made of a set of moving elements placed in the moderator evenly around its central cavity. 2. The control and calibration device according to claim 1, characterized by the TCLM, that the container is filled with a solid moderator, and the movable MieHTbi are made of the same material as the moderator. 3. Monitoring and calibration device according to claim 1, characterized in that the container is filled with a liquid moderator. 4. Control and calibration device for PP. 1-3, characterized in that the moving elements are made of a material that is an anomalously strong absorber of slow neutrons, for example, from cadmium. fus.7 -at