RU56003U1 - DETECTOR OF NEUTRONS AND GAMMA QUANTUM - Google Patents

Abstract

Usage: detection and identification of radiation sources. Purpose: improving the reliability of detection of radiation sources of various sizes and shapes. The inventive detector consists of alternating layers: a neutron moderator layer, a converting layer of high-density material, in which the γ-radiation is transformed into a stream of electrons and positrons, and an adjacent detection layer of a lithium-containing scintillating optical fiber. Optical fiber converts the energy of charged particles into light scintillations. Each layer of scintillating optical fiber is connected by means of a PMT to an information processing system. 1 ill.

Description

The utility model relates to radiation detectors and can be used to detect and identify isotopic sources, as well as to measure the energy and time parameters of the radiation of pulsed installations (devices).

Known ionization and scintillation radiation detectors based on the conversion of ionizing radiation energy into an electrical signal (Albikov Z.A., Veretennikov A.I., Kozlov O.V. Detectors of pulsed ionizing radiation. - M.: Energoatomizdat, 1978; Horn L.S., Khazanov, B.I., Modern Instruments for Measuring Ionizing Radiations (Moscow: Energoatomizdat, 1989).

Each type of detector has a limited scope and is focused on the use in measurements related to specific requirements for efficiency, spectral characteristics, radiation sensitivity, time resolution, current sensitivity, the ability to measure single pulses of ionizing radiation, the limits of flux density measurement, and various operational characteristics.

Portal monitors are known (patent of the Russian Federation No. 2129289, G 01 T 1/167, publ. 04/20/1999), in which plastic scintillators of a large area are widely used for registration of γ-radiation, and helium gas-discharge neutron detectors for registration of neutrons.

A disadvantage of a plastic scintillator is a weak spectral sensitivity to γ-radiation, and a disadvantage of neutron counters is a lack of spectral sensitivity and a limited aperture.

Known (RSSeymour, RACraig, M. Bliss et al. Performance of a Neutron-Sensitive Scintillating Glass-Fiber Panel for Portal, Freight and Vehicle Monitoring. Proceeding of SPIE, v. 3536. Nuclear Waste Engineering Section, p.148- 155, 1998) portal neutron radiation monitors based on a PUMA lithium-containing scintillating optical fiber (US Pat. No. 5,680,423, G 01 T 3/06, 10/21/1997), in which inorganic crystals (NaI ( Tl), BGO).

The disadvantages include: the lack of spectral sensitivity to neutrons, the limited aperture of registration of γ-radiation, the inability to provide spectral γ-measurements in the current mode, the high cost of large inorganic crystals.

The closest technical solution, selected as a prototype, is a device for recording neutron fluxes described in the patent of the Russian Federation No. 2102775, G 01 T 3/00, publ. 01/20/1998, the Device consists of alternating layers of thermal and slow neutrons (registrars) that slow down and absorb neutrons. Each layer of registrars is connected to the corresponding counter of electric impulses (information processing system).

The disadvantage of such a device is that the device does not register γ-radiation of sources associated with neutrons, which does not allow to fully measure the characteristics of radiation sources and, thus, to identify it. The disadvantage is that it has a limited flat aperture associated with the shape and size of gas discharge neutron counters, which must be used in the device.

The problem solved by the proposed utility model is to create an energy-sensitive, highly efficient detector of neutrons and γ-quanta, which has a large aperture and allows reliable detection

and identify radiation sources of various sizes and shapes.

The technical result is to provide high spectral sensitivity of the detector to neutrons and γ-quanta.

To obtain such a technical result, the proposed detector, consisting of alternating neutron-moderating and radiation-detecting layers, in which each of the detecting layers is connected to an information processing system, according to the claimed utility model, it is equipped with high-density material converting γ-radiation installed in front of scintillating optical fibers detecting radiation.

This leads to the fact that, thanks to the converting layers, spectral sensitivity to γ radiation is realized, the use of scintillation optical fibers allows the creation of highly sensitive radiation detectors of various shapes, large apertures - with an input window area larger than the size of the plastic scintillators of the portal monitors.

As a result of the applicant's analysis of the prior art, including a search by patent and scientific and technical sources of information and identification of sources containing information about analogues of the claimed utility model, no analogue was found that is characterized by features identical to all the essential features of the claimed utility model, and the definition is from the list of identified analogues of the prototype, as the closest in the totality of the features of the analogue, allowed to identify the set of essential in relation to the perceived by the applicant the technical result of the distinguishing features in the claimed object, set out in the formula for a utility model.

Therefore, the claimed utility model meets the condition of patentability “novelty”.

The utility model is illustrated in the drawing.

The figure shows a detector containing the i-oe number of alternating layers: a moderating material (1), a converting material (2) and adjacent detection layers (3) of a scintillating optical fiber (scintillator). The longitudinal axis of the detector is oriented along the direction of radiation propagation.

The device operates as follows.

Detection and identification of neutron sources is carried out by recording thermal neutrons in the detecting layers (3) after the neutrons pass through the slowing layers (1). When using an organic scintillator as a moderator to isolate the fraction of fast neutrons against the background of slow ones, the coincidence of the momentum from the fast neutron in the organic scintillator and the momentum in the lithium scintillating fiber from the absorption of a thermal neutron is analyzed within the information processing unit (not shown) within the neutron deceleration time after it slows down.

The operation of the detector for recording γ quanta is based on the following algorithm. Registered γ-quanta with energy E propagating in the Z direction fall on the front surface of the converting layers (2) and, interacting with them, create a flow of electrons and positrons, which, depending on their energy and range in the layers (2), reach the corresponding detecting layer (3) of the scintillator, which converts the energy of charged particles into light scintillations - readings (N _i ) recorded by the PMT.

Each γ-ray energy E and a converting layer (2) of a fixed thickness will correspond to its own characteristic set of samples N _i .

The thickness of the conversion layers (Δ _k ) in the detector is selected from the condition

where R _e is the average path length of the charged particles formed in them. The number of converting (2) and detecting (3) layers in the detector is chosen so that its thickness is approximately equal to or slightly larger than the mean free path of γ quanta with energy E

where d is the thickness of the layer;

l _γ (E) is the mean free path of γ-quanta with energy E.

The fulfillment of these conditions is aimed at achieving high efficiency and selectivity of the detector. This is also facilitated by the fact that the design of the proposed detector allows the use of various materials for the manufacture of the converting layers and makes it possible to measure the energy spectrum of the registered γ-radiation by the “filter method” using the proposed detector, provided that the signal from it is recorded separately from each detecting layer.

By choosing the material and thickness of the conversion layers, as well as their number (n), it is possible to purposefully change the energy dependence of the detector sensitivity (selectivity).

The detector conversion layers are made of materials with a high atomic number and high density (for example, lead), which makes it possible to create high-efficiency scintillation detectors for high-energy γ-quanta: the calculations performed for the detector model with conversion layers of Pb with a thickness of Δ _k = 0.15 cm and detection layers with a thickness of Δ _c = 0.07 cm at n = 10 showed that the expected detection efficiency of γ-quanta with an energy of E = 10 MeV will be ≅47%, which

comparable with the corresponding value for large NaI detectors (⌀15 × 10 cm).

The small thickness of the detector with its large area of ≥ (30 × 40) cm ² causes a new additional, valuable quality — the sensitivity anisotropy with respect to the direction of incident radiation, which makes it possible to determine the location of the radiation source.

Thus, the above information indicates the fulfillment of the following set of conditions when using the claimed utility model:

a device embodying the claimed utility model, when implemented, is intended to detect and identify isotopic sources;

for the claimed detector in the form described in the formula for a utility model, the possibility of its implementation using the means and methods described in the application and known prior to the priority date has been confirmed;

the neutron and γ-quantum detector embodied in the claimed utility model, when implemented, is capable of achieving the achievement of the technical result perceived by the applicant.

Therefore, the claimed utility model meets the condition of "industrial applicability".

Claims (1)

A neutron and γ-quantum detector, consisting of alternating neutron-moderating and radiation-detecting layers, in which each of the detecting layers is connected to an information processing system, characterized in that it is equipped with high-density material converting γ-radiation installed in front of scintillating optical fibers that detect radiation.