JP2019009122A - Radiation tube, radiation source, and radiation inspection device - Google Patents

Abstract

To provide a radiation tube which emits radiation as a fan beam suitable for application to an inspection device with a simple configuration.SOLUTION: A radiation tube includes: an envelope having an opening part; and an electron source provided inside the envelope; a target part 12 for generating radiation by irradiation of electrons emitted from the electron source. The radiation tube includes a front shield 21 which is installed at an opening part and which is joined to the target part 12. The front shield 21 includes a slit-like opening 25 for interrupting a part of the radiation emitted from the target part 12. Opening width of the opening 25 in a lateral direction in a side of the target part 12 is equal to a diameter of a target layer 19 or less, and opening width of the opening in a longitudinal direction is larger than the opening width of the target layer 19.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a non-destructive X-ray inspection apparatus in the industrial equipment field, a radiation tube applicable to diagnostic applications in the medical equipment field, and a radiation inspection apparatus using the same.

  The radiation tube generates radiation such as X-rays by applying a high voltage between a cathode and an anode and irradiating a target with electrons emitted from an electron source. The radiation tube is applied, for example, as an X-ray source to an inspection apparatus that inspects foreign objects in an article.

  Patent Document 1 discloses an X-ray inspection apparatus including an X-ray source that irradiates an article with X-rays, a slit forming member that adjusts an X-ray irradiation range, and a conveyance unit that conveys the article.

JP2013-88199A

  The configuration of a conventional X-ray inspection apparatus 301 is shown in FIG. While the article to be inspected 307 is conveyed by the conveying device 304, the X-ray tube 306 irradiates the article 307 with X-rays, and the X-ray line sensor 305 detects X-rays transmitted through the article 307. The irradiation range of the cone beam-shaped X-ray 308 emitted from the X-ray tube 302 is adjusted by a slit forming member 306 having a slit extending in a direction orthogonal to the conveyance direction of the article 307. Broken line arrows indicate X-rays scattered from the slit forming member 306. An X-ray shielding wall 309 is provided to shield X-rays outside these inspection spaces.

  However, since the X-ray focal point position (target) and the slit position are separated, X-ray scattering between the target and the slit occurs in a wide range. For this reason, there is a problem in that the entire apparatus is increased in size by providing a wide range of the X-ray shielding wall.

The radiation tube of the present invention includes a cathode having an electron source that emits electrons, an anode having a target part that generates radiation by electron irradiation, and a tubular front shield that holds the target part, and a tube axis direction A radiation tube having a cathode and an insulating tube connected to the anode at each of both ends,
The target unit includes a target layer and a base material that supports the target layer, and the front shield receives a part of radiation emitted from a surface of the target unit opposite to the electron source. It has a slit-shaped opening for passing the radiation into a fan beam, and the opening width in the short direction on the target portion side of the opening is equal to or smaller than the diameter of the target layer, and the opening width in the longitudinal direction is the target. It is characterized by being larger than the diameter of the layer.

  According to the present invention, radiation is emitted as a fan beam suitable for application to an inspection apparatus with a simplified configuration by using a radiation tube in which a front shield having a slit-like opening is formed. . Moreover, since unnecessary radiation in the vicinity of the target portion can be effectively shielded, scattering of radiation between the target portion and the slit portion can be suppressed. As a result, scattering of radiation outside the examination space is suppressed, and a safe and miniaturized radiation examination apparatus is provided.

It is a schematic diagram which shows the radiation source which concerns on 1st Embodiment. It is a schematic diagram which shows the front shield and target part which concern on 1st Embodiment. It is a schematic diagram which shows the front shielding body which concerns on 2nd Embodiment. It is a schematic diagram for demonstrating opening of the back shield which concerns on 1st Embodiment. It is a schematic diagram which shows the radiation source which concerns on 3rd Embodiment. It is a schematic diagram which shows the back shield which concerns on 3rd Embodiment. It is a block diagram of the radiation inspection apparatus which concerns on 4th Embodiment. 6 is a schematic diagram illustrating a radiation inspection apparatus according to Embodiment 2. FIG. FIG. 6 is a schematic diagram illustrating a radiation inspection apparatus according to a third embodiment. It is a schematic diagram which shows the conventional radiation inspection apparatus.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. X-rays are preferable as the radiation used in the present invention, but radiation such as neutrons and protons can also be applied.

[First Embodiment]
FIG. 1 is a schematic diagram of a radiation source according to the present embodiment. The radiation source 81 includes a radiation tube 88 and a high-pressure generator 82 arranged in the storage container, and the extra space in the storage container is filled with insulating oil 87. The radiation tube 88 has an envelope in which one end of a cylindrical insulating tube 83 and a cathode 84 are joined, and the other end and an anode 85 are joined. The high voltage generator 82 applies a desired voltage to the cathode 84 and the anode 85. Electrons emitted from the electron source 86 constituting the cathode 84 are accelerated by an acceleration voltage (cathode / anode voltage) and collide with the target unit 12. Of the radiation generated by the collision of electrons, the radiation emitted from the side of the target portion 12 facing the surface where the electrons collide is emitted to the outside of the envelope. That is, the radiation tube 88 used in this embodiment is a transmission type.

  The front shield 21 is connected to the opening of the envelope (anode flange portion) and shields a part of the radiation emitted from the target unit 12. That is, the radiation generated from the radiation tube 88 is emitted as a fan beam whose irradiation area is limited to a fan shape by the front shield 21 having the slit-shaped (rectangular) opening 25 connected to the target unit 12.

  For the insulating tube 83, a ceramic material such as alumina or an electrically insulating material such as glass is used. The cathode 84 and the flange portion of the anode 85 are made of Monel (US registered trademark: MONEL, Ni-Cu alloy), Inconel (US registered trademark: INCONEL, Ni-based superalloy), Kovar (US registered trademark: KOVAR, Fe). It is made of a low linear expansion coefficient alloy such as (Ni—Co alloy) or a metal such as stainless steel.

  The electron source 86 is disposed inside the envelope so as to face the target portion 12 constituting the anode 85. The electron source 86 includes a tungsten filament, a hot cathode such as an impregnated cathode, or a cold cathode such as a carbon nanotube. The electron source 86 is provided with an extraction electrode and a lens electrode for controlling the electrons to reach a desired position and range of the target unit 12.

  FIG. 2A is a schematic diagram of the front shield 21, which is a front view, a cross-sectional view taken along A-A ′, and a cross-sectional view taken along B-B ′. The front shield 21 has a slit-shaped opening (radiation passage hole) 25, and the ratio of the longitudinal width (L1) to the short width (L2) of the opening 25 is about 2: 1 to 50: 1. Preferably, it is about 4: 1 to 20: 1.

  The target portion 12 shown in FIG. 2B is formed in a circular shape on the surface of the disk-shaped base material 18 and the electron source side of the base material 18 (the side opposite to the connection surface with the front shield 21). It consists of a target film 19. The base material 18 preferably supports the target film 19 and has a strength capable of maintaining the vacuum in the envelope. Further, it is preferable to have a high thermal conductivity so that the radiation generated in the target film 19 is less absorbed and the heat generated in the target film 19 can be quickly dissipated. For example, diamond, silicon carbide, aluminum nitride, or the like can be used.

  The material constituting the target film 19 preferably has a high melting point and high radiation generation efficiency. For example, tungsten, tantalum, molybdenum, or the like can be used. In order to reduce absorption generated when the generated radiation passes through the target film 19, the thickness of the target film 19 is preferably about 1 μm to 100 μm. Similarly, the thickness of the substrate 18 is preferably 500 μm to 5 mm.

  The front shield 21 has a high radiation shielding capability and preferably has a high thermal conductivity so that heat generated in the target portion 12 can be dissipated to the outside, such as a metal such as copper, iron, nickel, tungsten, lead, , Alloys containing them as main components, and composite materials thereof. Further, since a part of the front shield 21 is disposed so as to protrude outside the envelope, the heat generated in the target portion 12 is quickly radiated to the outside via the front shield 21.

  FIG. 4A is a schematic diagram showing an arrangement relationship between the slit-like opening 25 of the front shield 21 and the diameter of the electron beam irradiated on the target film 19, that is, the focal point 23. The focal diameter d1, the diameter D1 of the target film 19, and the short width L2 of the opening 25 satisfy d1 <L2 ≦ D1 (the short width is larger than the focal diameter and equal to or smaller than the diameter of the target film). With such a relationship, the radiation radiated in a cone beam shape at the focal point 23 can be effectively shaped into a fan beam radiation, and radiation in an unnecessary direction can be efficiently shielded.

[Second Embodiment]
Drawing 3 is a mimetic diagram of front shield 21 of this embodiment, and is a front view, an AA 'sectional view, and a BB' sectional view. The slit-shaped opening 25 is tapered such that the longitudinal width becomes wider from the target portion side toward the outside side. By increasing the thickness in the vicinity of the target portion with a large amount of radiation to be shielded, the size of the front shield 21 necessary for shielding unnecessary radiation can be reduced. Further, if the target portion side is narrower than the radiation side in the longitudinal direction of the opening 25, the taper need not be a linear taper, or may be a stepped structure. The longitudinal width of the end portion on the target portion side is preferably larger than the focal diameter, and is the same as the opening diameter of the rear shield 64 described later, and the square is equal in length and width (L3 = L2). Become.

  FIG. 4B is a schematic diagram illustrating an arrangement relationship between the opening 25 of the front shield 21 and the focal point 23. The focal diameter d1, the diameter D1 of the target film 19, and the short width L2 of the opening 25 satisfy d1 <L2 ≦ D1. With such a relationship, the radiation radiated in a cone beam shape at the focal point 23 can be more effectively shaped into a fan beam radiation, and radiation in an unnecessary direction can be effectively shielded.

[Third Embodiment]
FIG. 5 is a schematic diagram of a radiation source according to the present embodiment. The configuration other than the arrangement of the rear shield 64 is the same as that of the first embodiment or the second embodiment.

  Radiation and reflected electrons generated on the cathode side from the target unit 12 are shielded by the rear shield 64. The rear shield 64 is made of the same material as the front shield 21. Further, the front shield 21 and the rear shield 64 may have a two-layer configuration in which a material having a high shielding effect (for example, tungsten) is disposed on the inside and a material having a high thermal conductivity (for example, copper) is disposed on the outside. Good.

  FIG. 6 is a schematic view of the rear shield 64, which is a front view, a cross-sectional view taken along line A-A ′, and a cross-sectional view taken along line B-B ′. As shown in FIG. 6A, the rear shield 64 has a cylindrical opening (electron passage hole) 66 and is connected to the target unit 12. The target unit 12 is accommodated in and joined to a notch formed at the end of the rear shield 64. The front shield 21, the target portion 12, and the rear shield 64 are integrally joined to the opening of the anode flange portion.

  Further, as shown in FIG. 6B, the opening 66 may be tapered. With this structure, shielding is efficiently performed in the vicinity of the target portion with a large amount of unnecessary radiation, and unnecessary radiation is prevented from being generated by collision of electrons with the cathode side surface of the rear shielding body. If the target portion side of the opening 66 of the rear shield is narrower than the cathode side, the taper need not be a linear taper, or may be a stepped structure.

[Fourth Embodiment]
Next, the radiation inspection apparatus of this embodiment will be described with reference to FIG. The system control unit 502 controls the radiation tube 88, the radiation detection unit 501, and the transport driving unit 505 in a coordinated manner. As the radiation tube 88, the one described in the first to third embodiments is used. The radiation tube control unit 504 outputs various control signals to the radiation source 81 under the control of the system control unit 502. The emission state of the radiation emitted from the radiation tube 88 is controlled by the control signal. The conveyance drive unit 505 drives the article placement unit 506 so that the article to be inspected 509 passes through between the radiation tube 88 and the detector 507. The radiation emitted from the radiation tube 88 passes through the article 509 and is detected by the detector 507. The detector 507 converts the detected radiation into an electrical signal and outputs it to the signal processing circuit 508. The signal processing circuit 508 performs predetermined signal processing on the electrical signal under the control of the system control unit 502, and outputs the processed electrical signal to the system control unit 502. The system control unit 502 generates an image signal based on the processed processing signal, and causes the display unit 503 to display an image inside the article based on the image signal. Further, the system control unit 502 determines the presence / absence of a foreign substance contained in the article based on the video information. The determination result is displayed on the display device 503. The article 509 that has been inspected is conveyed to a predetermined place that differs depending on the determination result by the article arrangement unit 506 that is driven by the conveyance driving device 505. The article 509 is continuously conveyed at a predetermined interval, and radiation is emitted from the radiation tube 88 in synchronization with the timing when the article 509 enters and exits the irradiation range of the radiation tube 88.

Example 1
An embodiment of the radiation tube of the present invention will be described with reference to FIGS. 4, 5, and 6. In the radiation tube 88, a cathode 84 is joined to one end of an insulating tube 83 made of alumina, and an anode 85 is joined to the other end to constitute an envelope. The material of the cathode and the flange portion of the anode is Kovar. The anode 85 includes the target unit 12, the front shield 21, and the rear shield 64. In the target portion 12, tungsten is formed in a diameter of φ3 mm × t5 μm on the cathode side of a diamond substrate of φ5 mm × t2 mm. The front shield 21 is made of copper and has a substantially cylindrical shape of φ20 mm × t10 mm. The slit-shaped opening 25 has a tapered shape in which the radiation side longitudinal width L1 is 10 mm, the target portion side longitudinal width L3 is 2.5 mm, and the lateral width L2 is 2.5 mm. Further, the target diameter D1 is 3 mm, the focal diameter d1 is 2 mm, and d1 <L2 ≦ D1 is satisfied. The rear shield 64 is made of copper, and includes a cylindrical opening 66 of φ2 mm in a substantially cylindrical shape of φ20 mm × t10 mm. A digging of approximately the same size as the target portion 12 is created in the rear shield 64, and the target portion 12 is fitted therein and brazed with silver solder. Further, the side where the opening 25 of the front shield 21 is small is brazed to the connection surface of the rear shield 64 with silver solder.

  The high voltage generator 82 includes a cockcroft circuit and applies a voltage of approximately 40 kV to 120 kV depending on the intended use of radiation. The electron source 86 is an impregnated cathode. The generated radiation was converted into a fan beam having an appropriate shape by the front shield 21 and emitted to the outside. Further, the radiation generated on the cathode side was effectively shielded by the rear shield 64.

(Example 2)
An embodiment of the radiation inspection apparatus of the present invention will be described. FIG. 8 is a front view and a side view of a schematic cross-sectional view showing the configuration of the radiation inspection apparatus of the present embodiment. The radiation inspection apparatus 101 performs foreign object inspection using the radiation irradiated from the radiation tube 88 while the article 107 is transported by the transport unit 104. The conveyance unit 104 is a belt conveyor and conveys the article 107 in the left-right direction by drive motors at both ends. The opening 25 of the front shield 21 is formed in a direction in which the longitudinal direction intersects the conveying direction of the conveying device 104, preferably in a direction orthogonal thereto. As a result, the radiation emitted from the radiation tube 88 has a fan angle that is an irradiation range larger than the size of the article 107 in the direction orthogonal to the conveyance direction, and an irradiation range that is sufficiently smaller than the size of the article in the conveyance direction. A fan beam having a radiation angle of The radiation that has passed through the article 107 is detected by a line sensor 105 that is a detector.

  Since the radiation inspection apparatus 101 of the present embodiment shields unnecessary radiation with the front shield 21, there is no scattered radiation from the slit forming member 306 as shown in the conventional example of FIG. Therefore, even if the radiation shielding wall 109 is simplified, the scattered radiation can be sufficiently shielded.

(Example 3)
Another embodiment of the radiation inspection apparatus of the present invention will be described. FIG. 9 is a front view and a side view of a schematic cross-sectional view showing the configuration of the radiation inspection apparatus of the present embodiment. Example 2 is the same as Example 2 except that the slit portion 206 is disposed between the front shield 21 and the article 107. The slit portion 206 is made of tungsten, and a slit-shaped opening (slit) is formed in a direction orthogonal to the conveyance direction of the conveyance unit 104. The longitudinal direction of the slit coincides with the longitudinal direction of the opening 25 of the front shield 21.

  The fan beam radiation radiated from the radiation tube 88 passes through the slit portion 206 so that the irradiation range is maintained in the direction orthogonal to the conveyance direction, and the irradiation range is further reduced in the conveyance direction. It becomes.

  According to the present embodiment, since the resolution in the transport direction is increased, more accurate inspection can be performed. Further, since the amount of radiation scattered by the slit portion 206 is very small compared to the conventional radiation inspection apparatus, the radiation shielding wall 109 is simplified and the entire apparatus is downsized.

86 Electron source 12 Target portion 21 Front shield 25 Slit-shaped opening 18 Base material 19 Target film 23 Focus

The radiation tube of the present invention includes a cathode having an electron source that emits electrons, an anode having a target part that generates radiation by electron irradiation, and a tubular front shield that holds the target part, and a tube axis direction an insulating tube which is connected to said anode and Oite the cathode at both ends, a radiation tube having,
The target unit includes a target layer and a base material that supports the target layer, and the front shield receives a part of radiation emitted from a surface of the target unit opposite to the electron source. slit-like opening for forming the radiation fan beam is passed is provided, wherein the short side direction of the opening width of the side of the target portion of the front shield Ri der less in diameter before Symbol target layer, the front shielding The opening width in the longitudinal direction on the side of the target portion of the body is larger than the diameter of the target layer.

Claims (13)

A cathode having an electron source that emits electrons; an anode having a target portion that generates radiation by electron irradiation; and a tubular front shield that holds the target portion; and the cathode at each of both ends in the tube axis direction; A radiation tube having an insulating tube connected to the anode,
The target unit includes a target layer and a base material that supports the target layer, and the front shield receives a part of radiation emitted from a surface of the target unit opposite to the electron source. It has a slit-shaped opening for passing the radiation into a fan beam, and the opening width in the short direction on the target portion side of the opening is equal to or smaller than the diameter of the target layer, and the opening width in the longitudinal direction is the target. A radiation tube characterized by being larger than the diameter of the layer.   2. The radiation tube according to claim 1, wherein an opening width in a lateral direction on the target portion side is larger than a diameter of a focal point of radiation formed in the target layer.   The radiation tube according to claim 1, wherein an opening width in a longitudinal direction on the side of the target portion is larger than a diameter of a focal point of radiation formed in the target layer.   The opening has an opening width in a longitudinal direction that defines a fan angle, and an opening width in the short-side direction that defines a radiation angle that is smaller than the opening width in the longitudinal direction. The radiation tube according to any one of claims 1 to 3.   The anode has a flange-shaped anode member connected to the insulating tube and to which the front shield is connected, and at least a part of the front shield projects outward from the anode member. The radiation tube according to any one of claims 1 to 4, wherein the radiation tube is provided.   The radiation tube according to any one of claims 1 to 5, wherein the opening has a tapered shape in which an opening width in a longitudinal direction becomes wider from a target portion side toward an outside side. A back shield disposed on the opposite side of the front shield with respect to the target portion;
The radiation tube according to claim 1, wherein the rear shield has an electron passage hole through which electrons emitted from the electron source pass.   The radiation tube according to claim 1, wherein the opening has an aspect ratio of 2 or more and 50 or less.   The radiation tube according to claim 8, wherein the opening has an aspect ratio of 4 or more and 20 or less. Insulating oil and the radiation tube according to any one of claims 1 to 9,
An acceleration voltage circuit for applying an acceleration voltage between the cathode and the anode,
The radiation source, wherein the acceleration voltage is 40 kV or more and 120 kV or less. Storing the radiation tube, and having a storage container provided with an opening;
The radiation source according to claim 10, wherein the front shield projects outside the storage container from the opening. A radiation source according to claim 10 or 11,
A transport unit that transports an article in a direction that intersects the longitudinal direction of the opening; a detection unit that detects radiation emitted from the radiation tube and transmitted through the article;
A radiation inspection apparatus comprising: A slit part disposed between the front shield and the article;
The radiographic examination apparatus according to claim 12, wherein a longitudinal direction of the slit formed in the slit portion coincides with a longitudinal direction of the opening.

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