RU2634330C1 - Photoneutron source - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: photoneutron source includes a channel for introducing an electron beam irradiated by an electron beam with an energy of 6-8 MeV, e-γ-converter of tungsten with a thickness of 0.1 cm, two photoneutron targets from beryllium, a cavity for sample irradiation, a fast neutron retarder from polyethylene, and biological protection from borated polyethylene to absorb thermal and slow and absorb fast neutrons emitted from the source. In biological protection, a cavity filled with a moderator is made. In the centre of the moderator, a cavity is also made, in which the first and the second photoneutron targets are symmetrically positioned relative to its centre. The space between the targets serves as a cavity for irradiating the samples. On the outer surface of the first photoneutron target, an e-γ-converter is located, which is coupled with a channel for the input of an electron beam. On the sides of the cavity, side photoneutron targets of beryllium with a thickness of, at least, 1 cm can be additionally located. The photoneutron source further comprises a channel for placing the samples inside the cavity to irradiate the samples and a channel for withdrawing neutrons from the centre of the source, wherein the first and the second photoneutron targets are movable with the ability to move to the centre of the source.

EFFECT: simplification of the design and technology of manufacturing a photoneutron source, increasing the efficiency and reliability of its operation, increasing the protection against neutron irradiation during operation.

16 cl, 7 dwg, 3 ex

Description

The invention relates to neutron technology and, in particular, to photoneutron sources and means of forming neutron fluxes and can be used in experimental neutron physics, nuclear geophysics, in the analysis of materials, including neutron activation analysis, and in other areas of nuclear engineering and technology .

Various photoneutron neutron sources are known in the art. Such sources are called sources in which the formation of neutrons occurs under the action of photons (gamma rays) in the reactions (γ, n) that go to the nuclei at relatively small reaction thresholds.

Isotopic photoneutron sources are known where gamma rays are emitted by isotopic sources, and neutrons are formed in the reaction (γ, n) on deuterium or beryllium nuclei. Usually use the reaction ⁹ Be (γ, n) ⁸ Be (see, for example, [Rusanov A.E. et al. Working source of neutrons. Patent WO 2016099333 (2014); Britvich G.I. et al. Monoenergetic source of neutrons. RF patent 1762667 (1994)]). A source, for example, of ¹²⁴ Sb is surrounded by a beryllium target. Isotopic photoneutron sources are rarely used due to the low neutron yield and the need for radiation protection measures.

Also known are photoneutron neutron sources in which beams of charged accelerator particles are used to form gamma rays. The most economical is the use of low energy electron accelerators. Materials with a large atomic number, such as tantalum or tungsten, are used as the material of the e-γ converter, and heavy water is used as the material of the photoneutron target (D ₂ O, threshold D (γ, n) Н of the reaction = 2.23 MeV) or beryllium (threshold ⁹ Be (γ, n) ⁸ Be reactions = 1.66 MeV).

Thus, a photoneutron neutron source based on an electron accelerator is known [John M. Gahl and Gregory E. Dale. Method and apparatus for generating thermal neutrons using an electron accelerator. US Patent 8666015 (2002)], containing an e-γ converter irradiated by an electron beam, a photoneutron target and a moderator, with tantalum or tungsten used as the converter material, heavy water (D ₂ O) used as the material of the photoneutron target, which also acts as a moderator material. The disadvantages of such sources include the large size of the container for the photoneutron target and moderator, as well as the even larger size of radiation protection.

One of the best options for photoneutron neutron sources based on an electron accelerator are sources in which beryllium is used as the material of the photoneutron target. This makes the installation more compact and cost-effective.

The closest technical solution is a photoneutron neutron source based on an electron accelerator [L. Auditore et al. Study of a 5 MeV electron linac based neutron siurce. Nuclear Instruments and Methods in Physics Research B 229 (2005) 137-143 (fig. 3)], including an electron beam irradiated e-γ converter, a photoneutron target and a fast neutron moderator. Moreover, the e-γ converter is made of tungsten, the photoneutron target is made of beryllium, and the moderator is made of polyethylene.

The disadvantage of this technical solution is the design complexity, large size and the need to ensure radiation protection.

The technical result of the invention is to simplify the design and manufacturing technology of the source, increase the efficiency and reliability of its operation, increase protection against neutron radiation.

The technical result is achieved by the fact that a photoneutron source containing an e-γ converter from tungsten irradiated by an electron beam, a beryllium photoneutron target and a polyethylene fast neutron moderator, additionally contains an electron beam input channel, a second photoneutron target, a sample cavity and a biological protection to absorb thermal and to slow down and absorb fast neutrons flying out from the source. In this case, the biological protection is performed with a cavity filled with a moderator. A cavity is also made in the center of the moderator, in which the first and second photoneutron targets are mounted symmetrically with respect to its center. The space between the targets serves as a cavity for irradiating samples bounded from the ends by the inner ends of the photoneutron targets, and on the other sides by the surface of the moderator cavity. An e-γ converter is placed on the outer surface of the first photoneutron target, which is coupled to an electron beam input channel, the axis of which passes through the centers of the e-γ converter, the first photoneutron target, the cavity for irradiating the samples, and the second photoneutron target. In this case, the e-γ converter is irradiated with an electron beam with an energy of 6-8 MeV and is made of tungsten 0.05-0.15 cm thick. Biological protection, the cavity inside the biological protection and the moderator can be made in the form of a parallelepiped, a cube or a body of revolution . The cavity for irradiating the samples may have a cubic shape, and the dimensions of the cavity may coincide with the dimensions of the photoneutron target. In this case, the second photoneutron target can be made of beryllium, the moderator can be made of polyethylene, and biological protection can be made of borated polyethylene with the addition of boron compounds with a total content of at least 3%. Moreover, the moderator thickness is at least 24 cm, and the biological protection is at least 16 cm. The first and second photoneutron targets can be of the same size and can be made, for example, in the form of cubes with sides of 10 cm. Additionally, on the sides of the cavity for irradiating samples, lateral photoneutron targets can be placed, which can be made of beryllium with a thickness of at least 1 cm. The photoneutron source additionally contains a channel for placing the samples inside the cavity for irradiating the samples and an insert for closing this th channel, wherein the liner structure and composition of the materials from which it is made, repeated structure and composition of the source materials. The photoneutron source also additionally contains a channel for removing neutrons from the center of the source, an insert for closing this channel, and filters from various materials, for example Cd, B ₄ C, ⁶ Li ₂ CO ₃ , inside the channel to reduce the fraction of thermal neutrons in the neutron spectrum at the exit from source. The first and second photoneutron targets are movable with the possibility of moving to the center of the source to increase the flux of neutrons leaving the channel. The structure of the liner and the composition of the materials from which it is made, repeat the structure and composition of the source materials.

The invention is illustrated by the accompanying drawings.

In FIG. 1 shows a diagram of a photoneutron source, where:

1 - channel for inputting an electron beam,

2 - e-γ converter

3 - the first photoneutron target,

4 - the second photoneutron target,

5 - cavity for irradiation of samples,

6 - moderator of fast neutrons,

7 - biological protection for thermal absorption and moderation and absorption of fast neutrons,

8 - side photoneutron targets,

9 - channel for neutron output.

In FIG. Figure 2 shows the results of modeling the interaction of electrons with an energy of 8 MeV with an e-γ converter: the dependence of the number of photons (photon / sr / e) from a tungsten e-γ converter on the thickness of the e-γ converter.

In FIG. Figure 3 shows the results of modeling the interaction of gamma rays with the first photoneutron target: the dependence of the neutron flux (neutron / s / μA) from the beryllium photoneutron target on the thickness of the first photoneutron target.

In FIG. Figure 4 shows the results of modeling the interaction of neutrons with a moderator of polyethylene: the dependence of the neutron flux density (neutron / cm ² s) in the center of the cavity for irradiating samples on the thickness of the moderator.

In FIG. Figure 5 shows the results of modeling the interaction of neutrons with biological protection from boron polyethylene: the dependence of the neutron flux density (neutron / cm ² s) at a distance of 400 cm from the source on the thickness of biological protection from boron polyethylene.

In FIG. Figure 6 shows the results of modeling the interaction of gamma rays and neutrons with lateral photoneutron targets from beryllium: the dependence of the neutron flux density in the center of the cavity for irradiating samples on the thickness of lateral photoneutron targets from beryllium.

In FIG. 7 shows a photoneutron source.

The implementation of the claimed photoneutron source is confirmed by the following explanations and examples.

The photoneutron source (Fig. 1) contains a channel 1 for introducing an electron beam of an electron accelerator, an electron beam irradiated by an e-γ converter 2 from tungsten, the first (3) and second (4) photoneutron targets from beryllium, a cavity 5 for irradiating samples, a moderator 6 fast neutrons from polyethylene and biological protection 7 to absorb thermal and slow down and absorb fast neutrons flying out from the source. Moreover, the biological protection 7 is made with a cavity filled with a moderator 6. In the center of the moderator 6 there is also a cavity in which the first (3) and second (4) photoneutron targets are mounted symmetrically relative to its center. The space between the targets serves as a cavity 5 for irradiating samples bounded at the ends by the inner ends of the photoneutron targets 3 and 4, and on the other sides by the surface of the moderator cavity 6. On the outer surface of the first photoneutron target 3, an e-γ converter 2 is placed that is coupled to the channel 1 for introducing an electron beam whose axis passes through the centers of the e-γ converter 2, the first photoneutron target 3, cavity 5 for irradiating the samples and the second photoneutron target 4. In this case, the e-γ converter 2 is irradiated with an electron beam with energy s 6-8 MeV and thick made of tungsten 0.05 -. 0.15 cm Biological Protection 7, the cavity inside the biological protection, and the retarder 6 may be shaped as a parallelepiped, a cube or a body of revolution. The cavity 5 for irradiating the samples may have a cubic shape, and the dimensions of the cavity 5 may coincide with the dimensions of the first photoneutron target 3. The second photoneutron target 4 may be made of beryllium, moderator 6 of polyethylene, and biological protection 7 of boron polyethylene with the addition of boron compounds with a total content of at least 3%. Moreover, the thickness of the moderator 6 is at least 24 cm, and the biological protection 7 is at least 16 cm. The first and second photoneutron targets 3 and 4 can have the same dimensions and can be made, for example, in the form of cubes with a side of 10 cm. On the sides of the cavity 5, for the irradiation of samples, lateral photoneutron targets 8 can be placed, which can be made of beryllium with a thickness of at least 1 cm. The photoneutron source additionally contains a channel for placing the samples inside the cavity for irradiating the samples and an insert for closing ment of the channel, wherein the liner structure and composition of the materials from which it is made, repeated structure and composition of the source materials. The photoneutron source also additionally contains a channel 9 for removing neutrons from the center of the source and an insert to close this channel, while the structure of the insert and the composition of the materials from which it is made, repeat the structure and composition of the source materials. In this case, the first and second photoneutron targets 3 and 4 are made movable with the possibility of moving to the center of the source.

A photoneutron source operates as follows.

Electrons (Fig. 1) with an energy, for example, 8 MeV, pass through channel 1 to enter an electron beam to a tungsten e-γ-converter 2 and form in it a flux of inhibitory gamma rays with a limiting energy of 8 MeV. Brake gamma rays, incident on the first beryllium photoneutron target 3 (material with a low threshold for the formation of photoneutrons), give rise to fast neutrons (average neutron energy ~ 2 MeV). These neutrons, as well as gamma rays from the first photoneutron target 3, interact with the second beryllium photoneutron target 4 and side photoneutron targets 8 located on the sides of the cavity 5 for irradiating the samples. This increases the neutron flux in cavity 5 between the photoneutron targets 3 and 4. Due to the photoneutron reaction and the reaction (n, 2n) in beryllium (the reaction threshold is 1.9 MeV, i.e., due to fast neutrons), the fraction of neutrons returning to the cavity 5 is increasing. Further, the neutrons in the polyethylene moderator 6 experience collisions with hydrogen nuclei, as a result of which they slow down to an energy of 0.07 eV, which is close to the energy of thermal neutrons. Thermal neutrons from the polyethylene moderator 6 fall into the cavity 5, in which the irradiated samples are located. The size of the cavity 5 depends on the size of the cavity in the moderator and the sizes bounding the cavity 5 of the photoneutron targets 3 and 4. The input and output of samples for irradiation is carried out through the channel for placing the samples inside the cavity for irradiating the samples (not shown in Fig. 1). During irradiation, the channel is closed by a liner, the structure and composition of the materials from which it is made, repeat the structure and composition of the source materials. The biological defense layer 7 of boron polyethylene with the addition of boron compounds with a total content of at least 3% slows down fast neutrons emerging from the moderator 6 to the outside of the source and absorbs slow and thermal neutrons. The output from the source of neutrons for neutron research is carried out through channel 9 to output neutrons from the center of the source. During the irradiation of samples in the cavity 5, the channel 9 is closed by a liner, the structure and composition of the materials from which it is made, repeat the structure and composition of the source materials. To increase the flux of neutrons emerging through channel 9 from a photoneutron source, the first and second photoneutron targets 3 and 4 are made movable with the possibility of moving to the center of the source. At the same time, filters of various materials, for example Cd, B ₄ C, ⁶ Li ₂ CO ₃ , can be placed inside the channel 9 to reduce the fraction of thermal neutrons in the neutron spectrum at the source exit if fast neutrons are needed.

Example 1

A computer model of the photoneutron source is constructed according to the circuit in FIG. 1 and numerically simulated the properties of a photoneutron source. When modeling a tungsten e-γ converter, the energy and angular distributions of gamma rays emitted from tungsten plates of various thicknesses were calculated when they were irradiated with a point electron beam with an energy of 8 MeV. When simulating a photoneutron beryllium target, the energy and angular distributions of neutrons and gamma quanta emitted from beryllium layers of various thicknesses were obtained upon irradiation with a point beam of gamma quanta. As a result of the simulation, the optimal parameters of the moderator and protection were obtained. The simulation results are shown in FIG. 2-6. The calculations showed the possibility of obtaining a thermal neutron flux density in the cavity for irradiating samples of ~ 10 ⁸ -10 ⁹ neutrons / s⋅cm ² when leaving the first fast neutron photoneutron target ~ 1-5⋅10 ¹⁰ neutrons / s at an electron beam current of ~ 30 μA .

Example 2

According to the simulation results, a photoneutron source was created and installed on an electron beam of an industrial linear accelerator LUE-8-5 (Fig. 7). In the source, the e-γ converter is made of 0.1 cm thick tungsten, and two photoneutron targets are made of beryllium in the form of cubes with sides of 10 cm. The moderator and biological protection were drawn, respectively, from standard figured blocks C0 (from pure polyethylene) and C3 (from boron polyethylene with the addition of boron compounds with a total content of at least 3%) with dimensions of 250 × 120 × 60 mm. The thickness of the biological protection and moderator in this case was at least 16 and 24 cm, respectively. This provided the required level of neutron flux outside the source as required by sanitary standards. The neutron flux density inside the source was measured using (n, γ) reactions using the neutron activation analysis. Samples of ⁶³ Cu, ⁵⁵ Mn, ¹¹⁵ In, ⁴⁵ Sc were used as monitors of the neutron flux density in these measurements. The experimentally measured thermal neutron flux density in the cavity for irradiating the samples was ~ 10 ⁷ -10 ⁸ neutrons / s⋅cm ² at a beam current of ~ 40 μA and a frequency of 50 Hz, which can be increased with a corresponding increase in the current and beam frequency.

Example 3

The neutron flux density at the output of channel 9 for neutron output from the center of the source was measured in the same way as in Example 2. In this case, the first and second photoneutron targets were shifted to the center of the source to increase the flux of neutrons leaving the channel. The experimentally measured neutron flux density at the output of channel 9 was ~ 10 ⁴ -10 ⁵ neutron / s⋅cm ² . To reduce the fraction of thermal neutrons in the neutron spectrum at the source exit, filters of Cd, B ₄ C, ⁶ Li ₂ CO ₃ , respectively, with a thickness of 2 mm, 1 and 4 cm were used. This ensured the ratio of thermal to fast neutrons, respectively, ~ 10 ^-2 , 10 ^-5 and 10 ^-3 .

Thus, the use of this technical solution simplifies the design and manufacturing technology of the photoneutron source, increases the efficiency and reliability of its operation, increases protection against neutron irradiation during operation.

Claims (16)

1. A photoneutron source containing an e-γ converter irradiated by an electron beam, a photoneutron target and a fast neutron moderator, the e-γ converter made of tungsten, the photoneutron target made of beryllium, and the moderator made of polyethylene, characterized in that the source additionally contains a channel for introducing an electron beam, a second photoneutron target, a cavity for irradiating the samples, and biological protection for absorbing thermal and slowing down and absorbing fast neutrons flying outside the source, while each protection is performed with a cavity filled with a moderator, in the center of which there is a cavity in which the first and second photoneutron targets are mounted symmetrically relative to its center, the space between which serves as a cavity for irradiating samples, limited from the ends of the inner ends of the photoneutron targets, and on the other sides, the surface of the cavity of the moderator, while on the outer surface of the first photoneutron target an e-γ converter is placed, which is interfaced with a channel for introducing an electron beam, the axis of which Odita through the centers of e-γ-converter photoneutron first target, the irradiation cavity and a second sample photoneutron target. 2. A photoneutron source according to claim 1, characterized in that the biological protection can be made in the form of a parallelepiped, a cube or a body of revolution. 3. A photoneutron source according to claim 1, characterized in that the cavity inside the biological protection and the moderator can be made in the form of a parallelepiped, cube or body of revolution. 4. A photoneutron source according to claim 1, characterized in that the e-γ converter is irradiated with an electron beam with an energy of 6-8 MeV. 5. The photoneutron source according to claim 1, characterized in that the e-γ converter is made of tungsten 0.05-0.15 cm thick. 6. A photoneutron source according to claim 1, characterized in that the second photoneutron target is made of beryllium. 7. A photoneutron source according to claim 1, characterized in that the moderator is made of polyethylene, and the thickness of the moderator is at least 24 cm. 8. A photoneutron source according to claim 1, characterized in that the biological protection is made of borated polyethylene with the addition of boron compounds with a total content of at least 3%, and the thickness of the biological protection is at least 16 cm. 9. A photoneutron source according to claim 1, characterized in that the first and second photoneutron targets are made in the form of cubes. 10. A photoneutron source according to claim 1, characterized in that the first and second photoneutron targets are made in the form of cubes of the same size. 11. A photoneutron source according to claim 1, characterized in that the first and second photoneutron targets are made of beryllium in the form of cubes with sides of 10 cm. 12. A photoneutron source according to claim 1, characterized in that the cavity for irradiating the samples has a cubic shape, and the dimensions of the cavity coincide with the dimensions of the first photoneutron target. 13. A photoneutron source according to claim 1, characterized in that lateral photoneutron targets can be additionally placed on the sides of the cavity for irradiating the samples. 14. A photoneutron source according to claim 13, characterized in that the lateral photoneutron target is made of beryllium at least 1 cm thick. 15. A photoneutron source according to claim 1, characterized in that the source further comprises a channel for placing samples inside the cavity for irradiating samples and an insert for closing this channel, wherein the structure of the insert and the composition of the materials from which it is made repeat the structure and composition of materials source. 16. A photoneutron source according to claim 1, characterized in that the source further comprises a channel for removing neutrons from the center of the source, an insert for closing this channel, filters from various materials, for example Cd, B ₄ C, ⁶ Li ₂ CO ₃ , inside the channel to reduce the fraction of thermal neutrons in the neutron spectrum at the exit from the source, and the first and second photoneutron targets are movable with the ability to move to the center of the source, while the structure of the liner and the composition of the materials from which it is made, repeat the structure and composition of the material a source.

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