SU897016A1 - Scintillation spectrometer of photons - Google Patents

Abstract

In the United States, the PhDs are equipped with a mainstream and a living app. Detection and passive protection objects; and can be used, in particular, for measuring the characteristics of photons in cosmic space. So far, in order to increase sensitivity, accuracy and decrease memory in gasha-astronon and / oa xvkl the need to create scattering spectrometers of photons with a cryptographic dimension, the methods of measuring them when there are sufficiently large flows of background particles. I 1SEH; (I. L; ;;:, -.: / I;, -, v5.:H0:r:-. A multiplier, and the protective one is a protective scintillator, produced in the form of a container with a lid and, at least At least two photomultiplier tubes, characterized in that, in order to simplify the construction, the detection units are installed on a common base, and the inorganic crystal is installed inside the protective scintillator in such a way that its optical contact with its photomultiplier14 occurs only through the container lid, and the rest of the specified container is wholesale Combined with a photoelectron multiplier of the protective unit 2. The spectrometer according to claim I, distinguished by the fact that the scintillator's roof {is mechanically connected tightly to the indicated body and optically with the crystal itself. 00 0 center 1 The scintillating spectrometer is known for investigating the gamma , radiation of radiation in space. A well-known spectrometer is structurally complete from two blocks; a detection unit and an electronics unit. Children, the photon kitting on the background of the charged particles is carried out by a main crystal with a diameter of 39 mm and a thickness of 8 m, placed in a container made of protective plastic scintillator and optically connected with it. The design of the known scintillator allows to obtain small sizes.

Description

devices and registering light flashes from the main and protective scintillator with one PMT.

However, the use of such an arrangement for detecting photons has several disadvantages:

the difficulty of creating reliable optical control between the surfaces of the main and protective scintillators for large sizes of the main crystal;

Due to the fact that the protective and main scintillators have different temperature expansion coefficients, thermal stresses and deformations occur in the scintillators, which can lead to their damage. The presence of thermal gaps between the main and protective scintillator does not ensure the resistance of the structure to the effects of vibration and shock loads;

the weakening of the scintillation in the protective scintillator from the top and side surfaces;

reduction in detection efficiency due to registration of the fast signal component.

Closest to the invention is a spectrometer comprising a main and detection units and passive protection, with the main detection unit containing an inorganic crystal in a light and moisture protective case and a photomultiplier. The optical contact of the crystal with the PMT of the prog proceeds through the window of the package body covered with glass. The main detection unit is fully positioned inside the three protective scintillators. The cyclic detection unit contains a protective scintillator made in the form of a container that has a cartridge and at least two photomultipliers. The detection of photons with such a constructive implementation of the spectrometer is carried out by the main detection unit, and the detection of background charged particles is carried out by a protective detection unit. The known spectrometer makes it possible to get rid of the drawbacks inherent in the construction of the spectrometer described above. However, the use of a known construction using a large inorganic crystal leads to a constructive complication of the spectrometer,

For example, when using a Csl crystal (T1) with dimensions of 160x100 mm with a PMT-49, the dimensions of the protective scintillator are 450x250x220 mm. The manufacture of a closed scintillation container (for example, a cylindrical shape of 250 mm, n 450 mm) is associated with the use of complex and expensive technological processes to ensure a homogeneous transparent medium. In addition, the mechanical mounting of the main detection unit inside the protective scintillator, taking into account the vibration resistance and impact resistance of the structure, is more complex and requires an increase in the mass of the structure. The manufacture of a closed scintillator container from separate scintillating plates is also associated with the use of complex technological processes to provide reflective surfaces, to mechanically connect both the individual plates to each other, and the main detection unit. The light collection from the protective scintillator in this device must be performed from each plate separately by one nln to two PMTs.

Thus, the use of a known construction is associated with the use of a complex and expensive manufacturing technology, an increase in the mass of the spectrometer and the number of security PMTs, the complexity of creating a vibration-shock-resistant spectrometer design.

The purpose of the invention is to simplify the design of the spectrometer.

The goal is achieved by the fact that in a photon scintillation spectrometer containing the main and protective detection units and passive protection, the main unit contains an inorganic crystal in a light- and moisture-proof case and a photomultiplier, and a protective scintillator made in the form of a closed kintener having the detector, and at least two photomultiplier tubes, the detection units are installed and fixed on a common basis, and the specified inorganic cristae are installed inside the three protective scintillators such that its optical contact with its photoelectric multiplier occurs only through the container, and the rest of the specified container is optically connected with

Claims (2)

<claim-text> 1. SSh1NTILPYATNAYA PHOTON SPECTROMETER "containing the main and protective detection units and passive protection, the main unit contains an inorganic crystal in a light and moisture protective case and photo - </ claim-text> </ li> </ ul> <claim-text> The present invention relates to the field of measuring nuclear radiation. and can be used, in particular, to measure the characteristics of photons in outer space. </ claim-text> <claim-text> At present, the day of increase in sensitivity, accuracy, and reduction of measurement time in gamma astronomy, it has become necessary to create scintillation spectrometers of photons with large crystals capable of measuring when there are sufficiently large fluxes of background charged particles. </ claim-text> 2 multiplier, and protective - protective: scintillator, made in the form of a container with a lid and at least two photomultiplier tubes, characterized in that, in order to simplify the design, the detection units are installed on a common base, and the specified scintillator is installed inside the protective scintillator the inorganic crystal is such that its optical contact with its photomultiplier tube occurs only through the lid of the container, and the rest of the specified container is optically connected to the photomultiplier elem protective unit.

• 2. Spectrometer on π. I, characterized in that the cover of the protective scintillator is mechanically connected tightly with the specified case and optically with the crystal itself.

8TS "897016