阅读说明：本技术 中子束流装置及中子照射装置 (Neutron beam device and neutron irradiation device ) 是由 彭旦 李义国 郝倩 洪景彦 于 2020-04-16 设计创作，主要内容包括：本发明的实施例提供了一种中子束流装置,中子束流装置用于对进入其中的中子束进行中子能谱调节,中子束的粒子包括快中子、超热中子、热中子、γ光子；中子束流装置包括：过滤部,用于过滤中子束中的快中子；调节部,用于调节中子束的中子能谱以获得超热中子束或热中子束；准直器,用于将调节后的中子束准直射出,其中,过滤部、调节部以及准直器在沿着中子束进入到中子束流装置到射出中子束流装置方向,在中子束流装置内依次设置。根据本发明实施例的中子束流装置,通过一条束流通道可提供两种中子束流：热中子或超热中子,即无需分别设置两条束流通道从而避免多个束流通道位置占用较大空间、以及增加建造成本。(The embodiment of the invention provides a neutron beam device, which is used for performing neutron energy spectrum adjustment on a neutron beam entering the neutron beam device, wherein particles of the neutron beam comprise fast neutrons, epithermal neutrons, thermal neutrons and gamma photons; the neutron beam device comprises: the filtering part is used for filtering fast neutrons in the neutron beam; a regulating part for regulating the neutron spectrum of the neutron beam to obtain a epithermal neutron beam or a thermal neutron beam; and the collimator is used for collimating and emitting the adjusted neutron beam, wherein the filtering part, the adjusting part and the collimator are sequentially arranged in the neutron beam device along the direction from the neutron beam entering the neutron beam device to the neutron beam emitting device. According to the neutron beam device provided by the embodiment of the invention, two neutron beams can be provided through one beam channel: thermal neutrons or epithermal neutrons, namely two beam channels do not need to be arranged respectively, so that the situation that a plurality of beam channels occupy larger space and the construction cost is increased is avoided.)

1. A neutron beam device (20), the neutron beam device (20) being adapted for neutron spectral modulation of a neutron beam entering it, the particles of the neutron beam comprising fast neutrons, epithermal neutrons, thermal neutrons, gamma photons;

the neutron beam device (20) comprises:

a filtering section (21) for filtering fast neutrons in the neutron beam;

a regulating section (22) for regulating the neutron spectrum of the neutron beam to obtain a hyperthermia or thermal neutron beam;

a collimator (23) for collimating the conditioned neutron beam, wherein,

the filtering part (21), the adjusting part (22) and the collimator (23) are arranged in the neutron beam device (20) in sequence along the direction from the neutron beam device (20) to the neutron beam device (20).

2. The neutron beam device (20) of claim 1,

the regulating portion (22) is provided with a housing configured to contain a liquid moderating material;

the thickness of the liquid moderator material is adjustable.

3. The neutron beam device (20) of claim 2,

the liquid moderating material is water or heavy water.

4. The neutron beam device (20) of claim 3,

the neutron beam enters and exits the neutron beam device (20) along the vertical direction.

5. The neutron beam device (20) according to claim 1, further comprising:

and a reflection unit (24) which is provided on the outer circumferential sides of the filter unit (21) and the adjustment unit (22) and reflects the scattered neutrons back to the emission direction.

6. The neutron beam device (20) according to claim 1, further comprising:

a gamma shielding part (25) disposed between the adjusting part (22) and the collimator (23) for shielding gamma photon contamination.

7. The neutron beam device (20) of claim 1,

the collimator (23) has a hollow cavity (231), the hollow cavity (231) providing an exit port for the hyperthermia neutron beam or the thermal neutron beam;

the cross section of the hollow cavity (231) is gradually reduced along the exit direction of neutrons.

8. The neutron beam device (20) of claim 7,

and a reflecting layer (232) and a shielding layer (233) are arranged on the outer wall of the collimator (23) and are respectively used for reflecting and shielding neutrons deviating from the emergent direction.

9. A neutron irradiation device (100), comprising:

a neutron source (10) and a neutron beam stream device (20), wherein,

the neutron source (10) is arranged to provide a neutron beam;

the neutron beam device (20) is arranged to perform neutron spectrum adjustment on the neutron beam entering the neutron beam device and emit the adjusted neutron beam for irradiation;

the neutron beam device (20) is as defined in any one of claims 1 to 8.

10. A neutron irradiation device (200), comprising:

a reactor (50) and a neutron flux device (60), wherein,

the reactor (50) is arranged to provide a neutron beam;

the neutron beam device (60) is arranged to perform neutron spectrum adjustment on the neutron beam entering the neutron beam device and emit the adjusted neutron beam for irradiation; wherein the content of the first and second substances,

the neutron beam enters and emits out of the neutron beam device (60) along the vertical direction;

the adjusted neutron beam is a super-thermal neutron beam or a thermal neutron beam.

11. The neutron irradiation device (200) of claim 10,

the reactor (50) is a micro neutron source reactor;

the reactor core of the reactor (50) is arranged in the reactor barrel, and the neutron beam device (60) is arranged close to the bottom of the outer side of the reactor barrel.

Technical Field

The invention relates to the technical field of neutron irradiation treatment, in particular to a neutron beam device and a neutron irradiation device.

Background

The neutron capture therapy is to inject drugs such as boron-containing compounds with affinity with cancer cells into tumors, and neutron irradiation with certain energy is adopted to lead boron atoms to be fissured so as to lead the cancer cells to die. The neutron beam used for irradiation therapy comprises a thermal neutron beam and a super-thermal neutron beam which are respectively used for irradiating superficial tumors on the body surface and deep tumors in the body.

Currently, a neutron irradiator for satisfying different irradiation requirements needs to provide different neutron beam flow channels, for example, two beam channels are provided to provide a thermal neutron beam and an epithermal neutron beam respectively, which has the following disadvantages: the arrangement of a plurality of beam channels increases the occupied space, which is not beneficial to the miniaturization of the whole device; the construction cost is high. In view of this, there is a need for an improved neutron irradiation device having the above-described problems.

Disclosure of Invention

The invention provides a neutron beam device and a neutron irradiation device, and solves the problem that a plurality of neutron beam flow channels are required to be arranged to provide a plurality of neutron beams in the related technology.

According to one aspect of the present invention, there is provided a neutron beam device for neutron spectrum modulation of a neutron beam entering the neutron beam device, the particles of the neutron beam comprising fast neutrons, epithermal neutrons, thermal neutrons, gamma photons; the neutron beam device comprises: the filtering part is used for filtering fast neutrons in the neutron beam; a regulating part for regulating the neutron spectrum of the neutron beam to obtain a epithermal neutron beam or a thermal neutron beam; and the collimator is used for collimating and emitting the adjusted neutron beam, wherein the filtering part, the adjusting part and the collimator are sequentially arranged in the neutron beam device along the direction from the neutron beam entering the neutron beam device to the neutron beam device.

Optionally, the conditioning portion provides a housing configured to contain a liquid moderating material; the thickness of the liquid moderator material is adjustable.

Optionally, the liquid moderator material is water or heavy water.

Optionally, the neutron beam enters and exits the neutron beam device along a vertical direction.

Optionally, the neutron beam device further includes: and the reflecting part is arranged on the circumferential outer sides of the filtering part and the adjusting part and used for reflecting the scattered neutrons back to the emergent direction.

Optionally, the neutron beam device further includes: and the gamma shielding part is arranged between the adjusting part and the collimator and is used for shielding gamma photon pollution.

Optionally, the collimator has a hollow cavity, the hollow cavity providing an exit port for the hyperthermia neutron beam or the thermal neutron beam; the cross section of the hollow cavity is gradually reduced along the exit direction of neutrons.

Optionally, a reflecting layer and a shielding layer are disposed on an outer wall of the collimator, and are respectively used for reflecting and shielding neutrons deviated from the emergent direction.

According to another aspect of the present invention, there is provided a neutron irradiation device including: a neutron source and a neutron beam flow device, wherein the neutron source is arranged to provide a neutron beam; the neutron beam device is arranged to perform neutron energy spectrum adjustment on the neutron beam entering the neutron beam device and emit the adjusted neutron beam for irradiation; the neutron beam device is the neutron beam device of the above embodiment.

According to another aspect of the present invention, there is also provided a neutron irradiation device including: a reactor and a neutron beam flow device, wherein the reactor is configured to provide a neutron beam; the neutron beam device is arranged to perform neutron energy spectrum adjustment on the neutron beam entering the neutron beam device and emit the adjusted neutron beam for irradiation; the neutron beam enters and emits out of the neutron beam device along the vertical direction; the adjusted neutron beam is a super-thermal neutron beam or a thermal neutron beam.

Optionally, the reactor is a micro neutron source reactor; the reactor core of the reactor is arranged in the reactor barrel, and the neutron beam device is arranged close to the bottom of the outer side of the reactor barrel.

The neutron beam device and the neutron irradiation device provided by the invention solve the problem that one neutron beam flow channel can only provide one neutron beam in the related technology, thereby reducing the number of the neutron beam flow channels, reducing the occupied space and lowering the construction cost.

Drawings

Other objects and advantages of the present invention will become apparent from the following description of the invention which refers to the accompanying drawings, and may assist in a comprehensive understanding of the invention.

The accompanying drawings, which are incorporated in and constitute a part of this application, illustrate embodiments of the invention and, together with the description, serve to explain the invention and not to limit the invention. In the drawings:

fig. 1 is a schematic structural diagram of a neutron beam device according to an embodiment of the invention;

fig. 2 is a schematic structural diagram of a neutron irradiation device according to an embodiment of the present invention.

It is noted that the drawings are not necessarily to scale and are merely illustrative in nature and not intended to obscure the reader.

Detailed Description

In order to make the technical solutions of the present invention better understood, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Unless defined otherwise, technical or scientific terms used herein shall have the ordinary meaning as understood by one of ordinary skill in the art to which this invention belongs.

Referring to fig. 1, according to a neutron beam device 20 of the embodiment of the present invention, the neutron beam device 20 is configured to perform neutron spectrum adjustment on a neutron beam entering the neutron beam device, where particles of the neutron beam include fast neutrons, epithermal neutrons, thermal neutrons, and gamma photons; the neutron beam device 20 includes: a filtering unit 21 for filtering fast neutrons in the neutron beam; a regulating section 22 for regulating a neutron spectrum of the neutron beam to obtain a epithermal neutron beam or a thermal neutron beam; and a collimator 23 for collimating and emitting the adjusted neutron beam, wherein the filter unit 21, the adjusting unit 22, and the collimator 23 are sequentially disposed in the neutron beam device 20 along a direction from the neutron beam entering the neutron beam device 20 to the neutron beam emitting device 20.

In particular, the neutron beam device 20 is used to provide a neutron beam flow channel to obtain a thermal or hyperthermal neutron beam, for example for medical irradiation. To obtain a neutron beam, a corresponding neutron source is usually used to emit a neutron beam, which contains neutrons of different energy bands and some impurity particles, and in order to facilitate the target particles of desired energy to pass through the neutron beam flow channel, other particles need to be processed.

The neutron beam device 20 is sequentially provided with a filtering part 21, an adjusting part 22 and a collimator 23 along the direction that a neutron beam enters an emergent beam channel; wherein, the neutron beam emitted by the neutron source firstly passes through the filtering portion 21, and the filtering portion 21 filters fast neutrons (energy > 10keV) in the neutron beam, for example, the fast neutrons are absorbed or moderated; further, the neutron beam is emitted from the filtering portion 21 and enters the adjusting portion 22, and the adjusting portion 22 adjusts the neutron energy spectrum of the neutron beam, so that the neutron beam with required energy is obtained at the outlet of the neutron beam device; further, the neutron beam is emitted from the adjusting unit 22 and enters the collimator 23, and the collimator 23 is configured to confine the emitted neutrons to obtain a collimated neutron beam emitted in parallel.

According to the neutron beam device 20 of the embodiment of the invention, two neutron beams can be provided through one beam channel: thermal neutrons or epithermal neutrons; that is, two beam channels do not need to be respectively arranged, so that the positions of the plurality of beam channels do not occupy larger space and the construction cost is increased, and the neutron beam device 20 can simultaneously provide thermal neutron beams or super-thermal neutron beams to meet different irradiation requirements.

For any particle generating device, the neutron beam device 20 is arranged adjacent to the particle generating device, so that the neutron beam can move along a beam channel provided by the neutron beam device 20 and be emitted; the neutron beam device 20 can provide two kinds of neutron beams only by occupying one beam channel position, thereby optimizing the use performance of the neutron beam device.

Further, the regulating portion 22 is provided with a casing configured to contain the liquid-moderating material; the thickness of the liquid moderator material can be adjusted.

Specifically, the neutron beam reaching the adjusting unit 22 mainly contains an epithermal neutron and a thermal neutron, and the proportion of the two types of particles is adjusted, so that an epithermal neutron beam or a thermal neutron beam is expected to be obtained at the outlet of the neutron beam device 20.

The adjustment portion 22 is provided with a thickness, and the thickness is adjustable to provide continuous adjustment of the neutron spectrum. Simultaneously, for satisfying the staff and regulating and control the thickness of regulating part 22 at any time in the use, this regulating part 22 adopts liquid moderation material, realizes neutron energy spectrum continuous control through changing liquid layer thickness. For example, the regulating section 22 is provided with a housing in which the liquid-moderating material is contained, and a passage for the liquid to and from the housing is provided to replenish/discharge the liquid to change the liquid layer thickness.

The liquid moderating material is used to moderate epithermal neutrons to increase the thermal neutron fraction. The liquid moderating material, for example, has a small neutron absorption cross section to provide high neutron utilization. The liquid moderator material includes, for example, a hydrogen-containing compound.

Thus, the adjustment unit 22 is configured to make the neutron beam device 20 obtain a epithermal neutron beam or a thermal neutron beam, and when it is desired to obtain a thermal neutron beam, the thickness of the liquid moderating material is increased to thereby increase moderation of epithermal neutrons, so that the thermal neutron proportion is increased. Correspondingly, when it is desired to obtain a epithermal neutron beam, the moderating action of the adjusting section 22 is weakened to increase the epithermal neutron fraction.

Further, the liquid moderating material is water or heavy water.

The hydrogen-containing compound has a larger neutron scattering cross section, has more scattering centers in unit volume, and has good moderating effect on the epithermal neutrons (the epithermal neutrons are moderated into thermal neutrons through elastic scattering); for example, when water or heavy water is used as the material of the regulating portion 22, the thickness of the water or heavy water layer is changed to obtain a hyperthermo-neutron beam or a thermal neutron beam at the beam outlet.

Further, the neutron beam enters and exits the neutron beam device 20 in the vertical direction.

The particle generating device is disposed adjacent to the neutron beam device 20, and both are disposed, for example, in a horizontal direction or a vertical direction, depending on the beam direction to be actually obtained. In the present embodiment, the particle generating device and the neutron beam device 20 are arranged in a vertical direction, for example, the neutron beam device 20 is arranged below the particle generating device, and a neutron beam is emitted and enters the neutron beam device 20 so as to extract a vertically downward neutron beam.

In some embodiments, a neutron beam device 20 is disposed at a horizontal side of the particle generating device for emitting a neutron beam in a horizontal direction.

Further, in order to improve the neutron utilization rate, the neutron beam device 20 further includes: and a reflection unit 24 provided on the outer circumferential side of the filter unit 21 and the adjustment unit 22 and configured to reflect the scattered neutrons back to the emission direction.

In some embodiments, a reflector 24 is disposed around the entire neutron beam assembly 20 to reduce the number of neutrons lost and increase the exit neutron density.

Further, the neutron beam device 20 further includes: and a gamma shielding part 25 disposed between the adjusting part 22 and the collimator 23 for shielding gamma photon contamination.

In addition to the primary gamma rays originally included in the neutron beam, the secondary gamma rays generated during the moderation process, for example, when the neutron beam passes through the neutron beam device 20, affect the purity of the outlet neutron beam, and the primary and secondary gamma rays are absorbed by the gamma shielding part 25, so that impurity contamination can be reduced.

Further, the collimator 23 has a hollow cavity 231, and the hollow cavity 231 provides an exit port for the hyperthermia neutron beam or the thermal neutron beam; the hollow cavity 231 has a cross-sectional area gradually decreasing in a neutron emitting direction.

Specifically, the collimator 23 provides a collimation outlet for the neutron beam, the hollow cavity 231 includes, for example, a collimator inlet and an outlet, one end near the γ shielding portion 25 is the collimator inlet, and the hollow cavity 231 is the collimator inlet with a large diameter and a small diameter in the outlet direction, so that the number of neutrons entering the collimator can be increased, the number of neutrons deviating from the outlet direction can be decreased, and the outlet neutron density can be increased.

Further, in order to increase the outlet neutron density, the outer wall of the collimator 23 is provided with a reflecting layer 232 and a shielding layer 233, which are respectively used for reflecting and shielding neutrons deviated from the emergent direction.

Thus, the neutron beam enters the neutron beam device 20, passes through the filter unit 21, the adjustment unit 22, the reflection unit 24, the γ shielding unit 25, and the collimator 23 in this order, and is emitted from the outlet, thereby obtaining a hyperthermo-neutron beam or a thermal neutron beam.

The position, shape, size, material and the like of each component of the neutron beam device 20 are set according to actual needs.

The filter unit 21 is made of a material having a large fast neutron resonance absorption cross section, such as Al, F, or O, for example, to absorb or moderate fast neutrons; the adjusting part 22 is made of a material with a small neutron absorption cross section, and moderation of epithermal neutrons is realized; the reflecting part 24 is made of a material with a small neutron absorption section and a large scattering section so as to reflect scattered neutrons back to the beam current; the γ shielding portion 25 is made of, for example, lead, bismuth, or the like to absorb γ rays; the outer wall of the collimator 23 is, for example, a multi-layer structure, and a combination of a reflecting layer and a shielding layer is used to absorb gamma rays and reduce scattered neutrons, thereby increasing the neutron density at the outlet.

Referring to fig. 1, a neutron irradiation device 100 according to an embodiment of the present invention includes: a neutron source 10 and a neutron beam flow device 20, wherein the neutron source 10 is arranged to provide a neutron beam; the neutron beam device 20 is configured to perform neutron spectrum adjustment on a neutron beam entering the neutron beam device, and emit the adjusted neutron beam for irradiation; the neutron beam device 20 is the neutron beam device of the above embodiment.

Specifically, the neutron irradiation apparatus 100 is used for boron neutron capture therapy, for example, and includes a neutron source 10 for providing an initial neutron beam and a neutron beam current apparatus 20 for obtaining a epithermal neutron beam or a thermal neutron beam after performing energy spectrum adjustment on the initial neutron beam.

The neutron source 10 is, for example, a nuclear reactor or an accelerator to provide a neutron beam of a certain energy. The neutron source 10 and the neutron beam flow device 20 are adjacently arranged, for example, when the neutron source 10 and the neutron beam flow device 20 are arranged in the horizontal direction, a horizontally extracted neutron beam flow can be obtained from the neutron beam flow device 20; when the two are arranged along the vertical direction, vertically-extracted neutron beam current can be obtained from the neutron beam current device 20, so that the requirements of different irradiation positions are met.

Referring to fig. 2, a neutron irradiation device 200 according to another embodiment of the present invention includes: a reactor 50 and a neutron beam flow device 60, wherein the reactor 50 is arranged to provide a neutron beam; the neutron beam device 60 is configured to perform neutron spectrum adjustment on a neutron beam entering the neutron beam device, and to emit the adjusted neutron beam for irradiation; wherein, neutron beams enter and emit a neutron beam device 60 along the vertical direction; the adjusted neutron beam is a hyperthermia neutron beam or a thermal neutron beam.

Specifically, the nuclear fission reaction of the reactor 50 generates a neutron beam, and the particle types of the neutron beam include fast neutrons, epithermal neutrons, thermal neutrons and gamma photons; the neutron beam enters a neutron beam device 60, and the neutron beam device 60 can filter out fast neutrons and gamma photons, so that a super-thermal neutron beam or a thermal neutron beam is obtained at an outlet; further, the reactor 50 and the neutron beam current device 60 are disposed in a vertical direction, so that a neutron beam emitted from the reactor 50 enters the neutron beam current device 60 in the vertical direction and is emitted in the vertical direction.

Further, the neutron beam device 60 is provided with a filter 61, an adjusting part 62 and a collimator 63 in sequence, for example, along the vertical direction, the filter 61 is connected to one end of the reactor 50 emitting the neutron beam, so that the neutron beam enters the neutron beam device 60 from the end, and the collimator 63 provides a beam outlet, so that the adjusted neutron beam exits from the outlet.

Further, the reactor 50 is a micro neutron source reactor; the reactor core of the reactor 50 is arranged in the reactor barrel, and the neutron beam device 60 is arranged near the bottom of the outer side of the reactor barrel.

Specifically, the reactor 50 is of a tank-pool structure, with the reactor core disposed within a reactor barrel disposed in a reactor water pool. In general, a beryllium reflecting layer is arranged around the reactor core, the reflecting layer comprises an upper beryllium reflecting layer, a side beryllium reflecting layer and a lower beryllium reflecting layer, when the reactor is used as a neutron source, the lower beryllium reflecting layer can be removed, so that neutron beams generated by the reactor core are emitted from the lower part of the reactor barrel, and correspondingly, the neutron beam device 60 is arranged below the bottom of the reactor barrel, so that the neutron beams generated by the reactor core enter the neutron beam device 60.

The reactor with the miniature neutron source is used as the neutron source, has small volume, low radiation level and convenient operation, and is easy to popularize and popularize in hospitals or scientific research institutions.

According to the neutron irradiation device provided by the embodiment of the invention, a micro-reactor is adopted as a neutron source, and the neutron beam device can provide two types of neutron beams through one beam channel: thermal neutrons or epithermal neutrons; the neutron beam device can simultaneously meet the requirement of providing thermal neutron beams or super thermal neutron beams so as to meet different irradiation requirements.

In order that those skilled in the art will better understand the present invention, the following detailed description will proceed with reference being made to specific examples.

Referring to fig. 2, the neutron irradiation device 200 includes: the reactor 50 and the neutron beam device 60, wherein the neutron beam device 60 is arranged below the bottom of the reactor barrel of the reactor 50, the beryllium reflective layer is removed from the core 51 of the reactor 50, and the neutron beams generated by the core 51 are emitted from the bottom of the reactor barrel 53 after passing through the aluminum layer 52 and then enter the neutron beam device 60.

The neutron beam device 60 is sequentially provided with a filtering part 61, an adjusting part 62 and a collimator 63 along the moving direction of a neutron beam, the filtering part 61 filters fast neutrons, so that the main components in the neutron beam are epithermal neutrons and thermal neutrons, then the neutron beam enters the adjusting part 62, the adjusting part 62 can slow the epithermal neutrons, the proportion of the epithermal neutrons is changed, and finally, the adjusted neutron beam is emitted from the outlet of the collimator 63.

Further, in order to increase the density of outlet neutrons, a reflecting part 64 is arranged outside the filtering part 61 and the adjusting part 62 and used for reflecting scattered neutrons back to the beam; a gamma shielding part 65 is further provided between the adjusting part 62 and the collimator 63 for reducing gamma photon contamination.

Further, as the filter portion 61, for example, use is made of

AlF₃(69% M/M) + Al (30% M/M) + L iF (1% M/M) neutron moderating material, lead for example for the reflection section 64, and bismuth for example for the gamma shielding section 65.

The adjustment portion 62 is provided with, for example, a housing in which the liquid-slowing material is accommodated, and a passage for the liquid to enter and exit is provided in the housing.

The collimator 63 has a hollow cavity 631 with an upper end radius larger than a lower end neutron beam exit radius; for example, a graphite layer 632, a cadmium layer 633 and a lead boron polyethylene 634 are sequentially disposed on the outer wall of the hollow cavity 631 in a direction perpendicular thereto, wherein graphite is used for neutron reflection, and the cadmium and lead boron polyethylene can absorb neutrons deviated from the emitting direction, so as to reduce the influence of the neutrons on the outside.

Further, the outer layer of the neutron beam device 60 is made of stainless steel 66, so that isolation from the external environment is enhanced, and influence of particle radiation on the outside is reduced.

In this embodiment, the liquid moderator of the adjustment portion 62 is water or heavy water, and the neutron spectrum at the beam outlet is changed by changing the thickness of the water or heavy water layer. The neutron flux density at the beam exit is calculated, for example, using the MCNP program: when the thickness of the water layer is 0cm, the proportion of the epithermal neutrons at the beam outlet can account for more than 90 percent, so that the epithermal neutrons are used for medical irradiation of deep tumors; when the thickness of the water layer is increased, the thermal neutron share is gradually increased, and when the thickness of the water layer is 5cm, the thermal neutron share exceeds 50%, so that a thermal neutron beam is obtained for medical irradiation of a shallow tumor; similarly, when heavy water is used, when the thickness of the heavy water layer is 0cm, a hyperthermophile neutron beam can be obtained, and when the thickness of the heavy water layer reaches 10cm, a thermionic neutron beam can be obtained.

It is understood that the shape, material, size, etc. of each component of the neutron beam device may be set according to actual requirements, and is not limited to this embodiment.

It should also be noted that, in the case of the embodiments of the present invention, features of the embodiments and examples may be combined with each other to obtain a new embodiment without conflict.

The above description is only an embodiment of the present invention, but the scope of the present invention is not limited thereto, and the scope of the present invention is subject to the scope of the claims.