RU167810U1 - Stand for the study of radiation-protective properties of materials - Google Patents

Abstract

The utility model relates to the field of non-destructive testing and quantification. The stand contains a bed with parallel vertical racks and a horizontal base, an ionizing radiation source located on the same optical axis, installed in a housing with radiation protection and a collimator, a detector of ionizing radiation passing through a sample installed in a housing with radiation protection and a collimator, as well as a programmable digital computer controlled signal processor. The base of the bed is made in the form of parallel beams, the legs of the bed are fixedly connected to the beams of the base, and horizontal rails are fixed between the racks and between the beams of the base of the bed, on which the movable carriages are placed. At the same time, a source is placed on the carriage guiding between the base beams, and a detector with the possibility of vertical movement is placed on the carriage guiding between the racks. All carriages are movable along respective guides and with computer-controlled drives. Horizontal movements of the source and detector are carried out synchronously, coaxially and parallel to each other. The radiation source is at least one radioactive isotope emitting gamma and / or beta radiation, and the detector of ionizing radiation is, respectively, a gamma or beta radiation detector. The technical result is the ability to study and control the spatial distribution of the composition of the sample, including made in the form of a sheet or tape. 4 s.p. f-ly, 5 ill.

Description

The utility model relates to the field of non-destructive testing and quantitative composition determination, and more particularly, to instrumentation for studying the radiation-protective properties of materials, including in the form of a tape or sheet, and can be used to control the composition and quality of the material in the process production or manufacture of protective equipment from it.

The operation of the device is based on determining the change in the intensity of the flow of ionizing radiation after its interaction with the test substance (see, for example, [Rumyantsev S.V., Shtan A.S., Goltsev V.A. Handbook of radiation non-destructive testing methods / Ed. S.V. Rumyantseva - M .: Energoizdat, 1982. 240 p.], [G. Nelson, D. Reilly "Gamma-Ray Interactions with Matter", in Passive Nondestructive Analysis of Nuclear Materials, Los Alamos National Laboratory. 1991. PP. 27-42. - http://www.lanl.gov/orgs/n/n1/panda/00326397.pdf]).

Laboratory stands and installations are known from the prior art for studying the absorption and, accordingly, protective characteristics of various materials (see, for example, [S. El-Fiki et al. / Influence of Bismuth Contents on Mechanical and Gamma Ray Attenuation Properties of Silicone Rubber Composite // International Journal of Advanced Research (2015). Volume 3. Issue 6. PP. 1035-1039], [KANG Kedzhun et al. Method for testing an object using multi-energy radiation and installation for its implementation. RF patent №2 351 921 , G01N 23/083, 2006]), which contain a source of ionizing radiation, an investigated sample of material, det vector of ionizing radiation passing through the sample, a system for recording and processing signals from the detector. Such devices are used to study the absorption characteristics in local areas of the samples and do not provide the ability to study and control the spatial distribution of their composition. Therefore, these devices have limited functionality.

Also known is a bench for studying the radiation-protective properties of materials, containing a bed with parallel vertical struts and a horizontal base, an ionizing radiation source located on the same optical axis, mounted in a housing with radiation protection, a source collimator, an ionizing radiation detector passed through a sample installed in case with radiation protection, and the collimator of the detector, as well as a system for recording and processing signals from the detector [Siqi Xu. A Novel Ultra-light Structure for Radiation Shielding / A thesis submitted to the Graduate Faculty of North Carolina State University in partial fulfillment of the requirements for the Degree of Master of Science (Under the direction of Mohamed A. Bourham and Afsaneh Rabiei) // Nuclear Engineering, Raleigh, North Carolina. 2008. - http://repository.lib.ncsu.edu/ir/bitstream/1840.16/606/1/etd.pdf].

The known solution is intended to study the radiation-protective properties of materials and provides a measurement of changes in the intensity of the flow of ionizing radiation after its interaction with the test substance, but does not provide, for example, the ability to study and control the spatial distribution of the composition of the sample.

Thus, well-known technical solutions have limited functionality.

The objective of the claimed utility model is to expand the functionality of the stand for the study of radiation-protective properties of materials.

The technical result that allows us to solve this problem is the ability to study and control the spatial distribution of the composition of the sample, including those made in the form of a sheet or tape.

This result is achieved by the fact that in the test bench for studying the radiation-protective properties of materials containing a bed with parallel vertical columns and a horizontal base, an ionizing radiation source located in the same optical axis, mounted in a housing with radiation protection, a source collimator, an ionizing radiation detector that has passed through a sample installed in a case with radiation protection, and a collimator of the detector, as well as a system for recording and processing signals from the detector, the basics of the frame is in the form of parallel beams, racks secured to the frame beams of a base or mounted on them, and between the uprights and the base of the frame between the beams are fixed horizontal guide, which are arranged movable carriage. The distances between the uprights and the frame beams and the lengths of the horizontal guides are chosen larger than the width of the material sample to be studied, which can be sheet or made in the form of a tape stretched between the uprights. In this case, the source is placed on the guide carriage between the base beams, and the guide carriage between the racks is made with a vertical guide with a movable carriage on which the detector is placed. All carriages are movable along respective guides and with computer-controlled drives. Horizontal movements of the source and detector are carried out synchronously, coaxially and parallel to each other. Along the sides of the horizontal source guide, rotating rolls are installed in parallel at a level above the source collimator. The radiation source is at least one radioactive isotope emitting gamma and / or beta radiation, and the detector of ionizing radiation is, respectively, a gamma or beta radiation detector. As a system for recording and processing signals from the detector, a programmable digital signal processor controlled by a computer is used.

The essence of the utility model is illustrated by drawings.

In FIG. 1 shows a diagram of a stand for the study of radiation-protective properties of materials, where:

1 - source of ionizing radiation,

2 - source housing with radiation protection,

3 - source collimator,

4 - test sample of material,

5 - ionizing radiation detector,

6 - detector housing with radiation protection,

7 - collimator of the detector,

8 - programmable digital signal processor,

9 - personal computer.

In FIG. 2 shows a diagram of the stationary elements of the stand, where:

10 - bed

11 - horizontal base of the bed,

12 - stand racks,

13 - beam base frame

14, 15 - horizontal guides,

16 - rotating rolls.

In FIG. 3 shows a diagram of the movable elements of the stand, where:

1 - source of ionizing radiation (case with radiation protection is not shown),

5 - ionizing radiation detector (case with radiation protection is not shown),

14, 15 - horizontal guides,

17, 18, 19 - movable carriages,

20 - computer-controlled drive.

In FIG. 4 shows the assembly diagram of the stand, where:

1 - source of ionizing radiation (case with radiation protection is not shown),

5 - ionizing radiation detector (case with radiation protection is not shown),

12 - stand racks,

13 - beam base frame

14, 15 - horizontal guides,

16 - rotating rolls,

17, 18, 19 - movable carriages.

In FIG. Figure 5 shows the amplitude spectra from the detector obtained by irradiating the sample with γ-radiation from a ¹⁵² Eu source.

A stand for studying the radiation-protective properties of materials includes a frame 10 with parallel vertical struts 12 and a horizontal base 11 located on the same optical axis, an ionizing radiation source 1 installed in a housing 2 with radiation protection and a collimator 3, a material sample 4, a detector 5 ionizing radiation passing through a sample installed in a housing 6 with radiation protection and a collimator 7, as well as a programmable digital signal processor 8, controlled by a computer 9. OS The novelty 11 of the frame 10 is made in the form of parallel beams 13. The stands 12 of the frame 10 are motionlessly connected to the beams 13 of the base 11 or are installed on them. Between the uprights 12 and between the beams 13 of the base 11 of the bed 10, horizontal guides 14 and 15 are fixedly fixed, on which the movable carriages 17 and 18 are placed. The distances between the uprights 12 and the beams 13 of the bed 10 and the lengths of the horizontal rails 14 and 15 are chosen larger than the width of the test sample 4 of material, which can be sheet or made in the form of a tape stretched between the uprights 12. In this case, the source 1 is placed on the carriage 18 of the guide 15 of the horizontal base 11, and the carriage 17 of the guide 14 is made with a vertical direction -governing the movable carriage 19 on which is placed a detector 5. The carriages 17, 18 and 19 are movable along the respective guide with computer-controlled actuators 9 20. Horizontal movement of the source 1 and detector 5 are performed synchronously, coaxially and parallel to each other. To support the material sample 4 under study along the sides of the horizontal guide 15 of the source 1, rotating rolls 16 are installed in parallel at a level above the collimator 3 of the source 1. The radiation source is at least one radioactive isotope emitting gamma and / or beta radiation, and an ionizing radiation detector is, respectively, a gamma or beta radiation detector.

The device operates as follows.

The studied samples of materials are irradiated with a narrow collimated gamma-ray beam of an isotope source, which is used as standard OSGI gamma sources ( ¹³⁷ Cs Еγ = 662 keV, ⁵⁷ Co Eγ = 122 keV, etc.) and sources activated on neutron source IN-LUE of the Institute for Nuclear Research ( ¹⁵² Eu (Еγ = 122 and 344 keV), ¹⁸⁶ Re (Еγ = 137 keV), etc.). Using a wide range of source energies makes it possible to determine the linear attenuation coefficient and the content of heavy elements in the material with good accuracy. Gamma radiation transmitted through the sample is measured with a scintillation detector based on a 5 × 5 cm NaI (Tl) crystal and PMT-143. Measurements are carried out in the presence and absence of a sample. Separately, the background is measured in the absence of a source (see Fig. 5). In this case, the signals directly from the PMT of the detector in the form of waveforms are digitized by a digital signal processor type CAEN DT 5720 and recorded on a computer. Further processing is carried out off-line. Recording information in the form of waveforms allows you to take into account changes in the waveform (for example, the baseline, etc.) at large and small detector loads (associated with a rapid change in the intensity of short-lived sources) during measurement without involving additional equipment. A change in the waveform also leads to errors in the calculation of the peak areas, especially those closely spaced. When processing take into account the change in the spectrum of short-lived sources. The design of the stand allows the transverse movement of the source-detector pair (scanning) during longitudinal movement of the sample between the racks to study the uniformity of extended samples of materials.

Thus, the use of this technical solution significantly expands the functionality of the stands for the study of radiation-protective properties of materials. The inventive stand can be widely used in industry as control and measuring equipment for studying the radiation-protective properties of materials, including in the form of tape or sheet materials, and can be used to control the composition and quality of the material during the production or manufacture of protective materials from it funds.

Claims (5)

1. A stand for studying the radiation-protective properties of materials, containing a bed with parallel vertical struts and a horizontal base, an ionizing radiation source located on the same optical axis, installed in a housing with radiation protection, a source collimator, an ionizing radiation detector passing through a sample installed in case with radiation protection, and the collimator of the detector, as well as a system for recording and processing signals from the detector, characterized in that the base of the bed, made but in the form of parallel beams, the bed racks are motionlessly connected to the base beams, and horizontal rails are fixed between the racks and between the bed base beams, on which movable carriages are placed with the possibility of moving along the rails, while the source is placed on the rail carriage between the base rails, and the guide carriage between the racks is made with a vertical guide with a movable carriage on which the detector is placed, while all the carriages are movable s respective guides, and the horizontal movement of the source and detector synchronously performed coaxially and parallel to each other, wherein as a system for registering and processing of signals from the detector is used a programmable digital signal processor controlled by a computer. 2. A stand for studying the radiation-protective properties of materials according to claim 1, characterized in that all the carriages are made with computer-controlled drives. 3. A stand for studying the radiation-protective properties of materials according to claim 1, characterized in that the bed stands are mounted motionless on the beams of the bed base. 4. A bench for studying the radiation-protective properties of materials according to claim 1, characterized in that along the sides of the horizontal source guide, rotating rolls are installed in parallel at a level above the source collimator. 5. A bench for studying the radiation-protective properties of materials according to claim 1, characterized in that the radiation source is at least one radioactive isotope emitting gamma and / or beta radiation, and the gamma detector is, respectively, a detector of ionizing radiation or beta radiation.

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