JP2021156838A - Target holder and target holder holding mechanism - Google Patents

Abstract

To provide a target holder loading a target disk and guaranteeing safety so as not to leak a radioactive material generated from the target disk to the outside, and a target holder holding mechanism for holding the target holder.SOLUTION: A target holder 1 includes a vessel main body 11, a lid body 12 and a loading member 13. The vessel main body 11 is provided as a vacuum chamber by a cylindrical part 112 forming a space part 111 for loading one or more target disks T having hole-like parts Ta to be held formed at two or more points, an opening 113 provided on the one end side of the cylindrical part 112 and a closure part 114 for blocking the other end side of the cylindrical part 112; the cylindrical part 112 has a shape formed in a polygonal tube shape; the lid body 12 opens and closes the opening 113; and the loading member 13 is a rod 13 inserted into the part Ta to be held of the target disk T.SELECTED DRAWING: Figure 3

Description

The present invention relates to a target holder for loading a target disk irradiated with radiation such as electron beam, X-ray, and gamma ray, and a target holder holding mechanism for holding the target holder.

Patent Document 1 describes an apparatus for producing molybdenum-99 ( ^{99 Mo) from a molybdenum-100 (100} Mo) target using high-energy radiation generated by a linear particle accelerator. This device includes a linear accelerator (linac), a bremsstrahlung converter station, a target holder, a vacuum chamber (target irradiation unit), a cooling system, and a target assembly unit.

The linear accelerator produces an electron beam (“electron beam” in Patent Document 1) having a power of at least 5 kW to about 100 kW. The bremsstrahlung transducer station includes a tantalum plate, receives an electron beam, and produces bremsstrahlung photons with a flux of at least 20 MeV to about 45 MeV. The target holder ^{accommodates a plurality of 100} Mo target disks and is housed in a vacuum chamber. The vacuum chamber incorporates a bremsstrahlung transducer station and accepts the target holder.

The cooling system circulates cooling water to cool the tantalum plate, the target holder, and the ^{100 Mo target disk.} The target assembly section is covered with a shield section, ^{and a target holder containing a plurality of 100} Mo target disks is attached inside, and the generated high-energy radiation is blocked by a water-cooled transducer.

^{A plurality of 100} Mo target disks housed in the target holder are irradiated with a photon flux of bremsstrahlung generated by the bremsstrahlung converter station. ^{The 100 Mo target produces 99} Mo by a photonuclear reaction. The large heat load caused by high-energy radiation is dissipated by the bremsstrahlung conversion station. ^{The 100} Mo target disk, which is irradiated with the photon flux of bremsstrahlung, has a reduced thermal load due to the cooling system.

Special Table 2016-520194

In the apparatus described in Patent Document 1, circulating cooling water ^{passes between tantalum plates and between 100} Mo target disks. This cooling water is the one in which radiolysis has occurred. The cooling water produced by radiolysis produces hydrogen gas that creates a risk of explosion, and also produces hydrogen peroxide that is corrosive to ^{99 Mo.} This greatly reduces the potentially achievable ^{99 Mo yield from the 100 Mo target disc.}

Further, in the device as described in Patent Document 1, in order to reduce the radioactive contamination range even in the unlikely event of leakage, the irradiation room itself in which the device is installed is also sealed, and radioactive substances are excluded from the ventilation facility. It is necessary to take measures such as adding a filter for this. Then, the target for shielding radiation is wide-ranging, and the installation cost and maintenance cost of the equipment become high.

Moreover, ⁹⁹ Mo cannot be easily removed from the device. In addition, if a substance containing radioactivity is generated, or if ⁹⁹ Mo is dissolved or scattered in an abnormal situation, the inside of the vacuum chamber is contaminated or damaged by radiation. Repairing such a vacuum chamber is also a safety concern.

The present invention provides a target holder for loading a target disk, a target holder for which safety is ensured by suppressing leakage of radioactive substances generated from the target disk to the outside, and a target holder holding mechanism for holding the target holder. That is the purpose.

The target holder according to the present invention is
A tubular portion forming a space for loading one or more target discs, an opening provided on one end side of the tubular portion, and the other end side of the tubular portion are closed to allow radiation into the space. A container body sealed by a closure having a passage through which,
A lid that opens and closes the opening,
A loading member that presses the target disk against the closure,
It has.

In the target holder according to the present invention.
The tubular portion is formed in a rectangular tubular shape having a polygonal outer shape.

In the target holder according to the present invention.
The loading member that presses the target disk having two or more hole-shaped or notched-shaped held portions against the closed portion is a rod that is engaged in the held portion.
The closed portion is provided with a thin-walled portion in which the passing portion is formed to be thin-walled and a thick-walled portion in which a connecting hole into which the tip end portion of the rod is inserted is formed.

In the target holder according to the present invention.
The rod is a bolt having a male screw formed on the tip end side and having a head portion at the base end portion where the target disk hits a surface facing the lid body.
A female screw into which the male screw of the rod is screwed is formed in the connecting hole.

In the target holder according to the present invention.
On the end face on one end side of the tubular portion, holes for fixing the lid body are formed at a plurality of places.
The lid body is a flange portion that is fitted into the opening and has a groove formed in the circumferential direction, and a flange portion that overlaps an end surface on one end side of the tubular portion, and communicates with the lid body fixing hole. It has a flange portion on which a screw hole is formed and a gasket fitted in the groove.

In the target holder according to the present invention.
The tubular portion includes a reduced diameter portion formed in an intermediate portion, an enlarged diameter portion formed on one end side, a stepped portion formed at a boundary portion between the reduced diameter portion and the enlarged diameter portion, and one end. It is provided with holes for fixing the lid body formed at a plurality of places on the end face on the side.
The lid body is a flange portion that overlaps with an fitting portion that is fitted into the enlarged diameter portion of the tubular portion and an end surface on one end side of the tubular portion, and has a screw hole that communicates with the lid body fixing hole. It has a formed flange portion and a gasket that is attached to the tip end surface of the fitting portion and is in close contact with the step portion.

In the target holder according to the present invention.
At least the container body is molded of aluminum or an aluminum alloy.

The target holder holding mechanism according to the present invention is
A pair of stages that approach the target holder according to the present invention so as to sandwich the tubular portion from both sides and separate the tubular portion from both sides.
With
The pair of stages has an inner surface portion formed in a groove shape along the outer surface of the tubular portion, and cools the target disk in the space portion via the tubular portion.

In the target holder holding mechanism according to the present invention
The target holder is in a horizontal position.
The pair of stages move up and down between a bottom stage on which the tubular portion is placed, a position lowered so as to hit the tubular portion mounted on the bottom stage, and a position above the tubular portion. It has a stage.

According to the present invention, in a target holder that holds a target disk, a target holder that suppresses leakage of radioactive substances generated from the target disk to the outside and ensures safety, and a target holder holding mechanism that holds the target holder are provided. Can be provided.

FIG. 5 is a cross-sectional perspective view showing an embodiment of a target holder and a target holder holding mechanism according to the present invention, and is a schematic cross-sectional perspective view showing a state during work. FIG. 5 is a cross-sectional perspective view showing an embodiment of a target holder and a target holder holding mechanism according to the present invention, and is a schematic cross-sectional perspective view showing a state before or after the work. It is sectional drawing which shows one Embodiment of the target holder which concerns on this invention. It is sectional drawing which shows one Embodiment of the container body provided in the target holder which concerns on this invention. It is a side view which shows one Embodiment of the container body provided in the target holder which concerns on this invention. It is a perspective view which shows one Embodiment in the state which the rod provided in the target holder which concerns on this invention is engaged with the target disk. It is a perspective view which shows one Embodiment of the lid provided in the target holder which concerns on this invention.

An embodiment of the target holder and the target holder holding mechanism according to the present invention will be described with reference to FIGS. 1 to 7. FIG. 1 is a cross-sectional perspective view showing an embodiment of a target holder and a target holder holding mechanism according to the present invention, and is a schematic cross-sectional perspective view showing a state during work. FIG. 2 is a cross-sectional perspective view showing an embodiment of the target holder and the target holder holding mechanism according to the present invention, and is a schematic cross-sectional perspective view showing a state before or after the work. FIG. 3 is a front sectional view showing an embodiment of the target holder according to the present invention. FIG. 4 is a cross-sectional perspective view showing an embodiment of a container body provided in the target holder according to the present invention. FIG. 5 is a side view showing an embodiment of a container body provided in the target holder according to the present invention. FIG. 6 is a perspective view showing an embodiment in which a rod provided in the target holder according to the present invention is engaged with a target disc. FIG. 7 is a perspective view showing an embodiment of a lid provided in the target holder according to the present invention.

The target holder 1 is a ^{closed container for loading (inserting) a molybdenum-100 (100} Mo) target disk (hereinafter, mainly referred to as “target”) T. The target holder 1 is formed of aluminum or an aluminum alloy to reduce activation due to electron beam radiation. As shown in FIG. 3, the target holder 1 includes a container main body 11, a lid body 12, and a loading member 13. The container body 11 has a tubular portion 112 forming a space portion 111 for loading one or more targets T, an opening 113 provided on one end side of the tubular portion 112, and the other end side of the tubular portion 112. It is provided like a vacuum chamber by a closing portion 114 that closes the door.

The target T has a disk shape, and a hole-shaped held portion Ta is formed at two or more places. The target T includes not only a thin type and a thick type as shown in the figure but also various thickness types (not shown). The held portion Ta is formed in a hole shape near both ends of the diameter. However, the held portion Ta may be formed in a notch shape such as an arc shape (not shown).

As shown in FIG. 6, a plurality of target Ts are stacked. In FIG. 6, thin targets T and thick targets T are alternately overlapped. However, a plurality of thin targets T may be stacked together, or a plurality of thick targets T may be stacked together. Further, a target T having an intermediate thickness may be sandwiched. Alternatively, the target T may be superposed on only the thin type, only the thick type, or only the medium thickness type. Alternatively, the number of targets T may be only one.

The plurality of targets T are superposed together by the loading member 13. Since the target T is formed with a hole-shaped or notched-shaped held portion Ta, a rod engaged with the held portion Ta is used as the loading member 13. Hereinafter, the loading member 13 will be mainly described as a rod 13. When the held portion Ta is formed in two places as shown in the figure, two rods 13 are provided. Although not shown, when the held portions Ta are formed at six positions, six rods 13 are provided. The rod 13 is a bolt, a male screw 131 is formed on the tip end side, and a head 132 is provided on the base end portion. Hexagonal hole processing is applied to the head 132. The seating surface of the head 132 hits the outermost surface of the target T loaded in the space 111, that is, the surface of the target T on the opening 113 side.

The tubular portion 112 of the container body 11 includes a diameter-reduced portion 112a formed in the inner or intermediate portion of the cylindrical space portion 111 for loading the target T, and a diameter-expanded portion 112b formed on one end side. A stepped portion 112c formed at a boundary between the reduced diameter portion 112a and the enlarged diameter portion 112b is provided. The enlarged diameter portion 112b has an inner diameter slightly larger than the outer diameter of the target T, and is formed longer than the lid body 12 (specifically, the fitting portion 121 described later). The enlarged diameter portion 112b has an inner diameter slightly larger than that of the reduced diameter portion. A plurality of lid fixing holes 112e (8 in the drawing) are formed on the end surface 112d on one end side of the tubular portion 112.

The tubular portion 112 is formed in a rectangular tubular shape having a polygonal outer shape (hereinafter, will be described as a regular octagon according to the drawings). The target holder 1 is used with the container body 11 in a horizontal posture. The outer surface of the container body 11 having a regular octagonal outer shape is formed by a horizontally oriented lower surface and an upper surface, a pair of vertically oriented side surfaces, a pair of lower lower slopes, and a pair of upper upper slopes in use. It has eight sides. The width of the tubular portion 112, such as the distance between the upper surface and the lower surface, is the same over the entire length.

The closed portion 114 of the container body 11 is provided with a passing portion 114a formed on the center side and a thick portion 114b formed on the peripheral side. The passing portion 114a is a thin-walled portion 114a formed to be thin enough to allow an electron beam to pass through the space portion 111. The thin-walled portion 114a is provided at the center of the closed portion 114 so that the inner surface on the other end side of the space portion 111 becomes flat. Therefore, a recessed portion 114d is formed on the outer end side of the closed portion 114.

The thick portion 114b is formed with a connecting hole 114c into which a male screw 131 on the tip end side of the rod 13 is inserted. By providing two rods 13, the connecting holes 114c need only be provided at at least two places. However, as shown in FIG. 5, the held portions Ta are formed at 6 places, and the connecting holes 114c are provided at 6 places so that the target T can be used even if the target T is locked by the 6 rods 13. Be done. The connecting hole 114c is formed with a female screw that is screwed into the male screw 131 of the rod 13.

The opening 113 provided on one end side of the container body 11 is opened and closed by the lid body 12. The lid body 12 has a fitting portion 121 that is fitted into the opening 113, and a flange portion 122 that overlaps the end surface 112d on one end side of the tubular portion 112. A screw hole 122d communicating with the lid fixing hole 112e is formed on the outer peripheral portion of the collar portion 122. The screw holes 122d are formed in the same number (8 places in the drawing) as the lid fixing holes 112e of the tubular portion 112. A recess is provided in the center of the collar 122.

A female screw such as a double-threaded screw (hereinafter, mainly referred to as a “female screw of the lid”) 123a is formed in the recessed portion. The tip of the transfer rod (not shown) is inserted into the female screw 123a of the lid. That is, the target holder 1 in a state where the lid 12 closes the opening 113 of the container body 11 is gripped by the tip of the transfer rod. A groove 121a is formed on the entire circumference in the middle of the fitting portion 121 in the length direction. A gasket 124 is fitted into the groove 121a. The gasket 124 is in close contact with the inner surface of the enlarged diameter portion 112b.

The target holder 1 is held by the target holder holding mechanism (hereinafter, mainly referred to as “holding mechanism”) 2. As shown in FIGS. 1 and 2, the holding mechanism 2 includes a pair of stages 21 and 22. The pair of stages 21 and 22 are a bottom stage 21 and a top stage 22. The bottom stage 21 carries the tubular portion 112 of the target holder 1 in a horizontal posture. The cylindrical portion 112 having an octagonal outer shape has a surface to be a lower surface and a surface to be an upper surface oriented horizontally.

The bottom stage 21 has an inner surface portion 211 formed in a groove shape along the lower outer surface of the tubular portion 112, and cools the target T loaded in the target holder 1. The inner surface portion 211 of the bottom stage 21 includes a lower horizontal portion whose inner surface hits the lower surface of the cylindrical portion 112 in a horizontal posture, a pair of lower slope portions whose inner surface hits a pair of lower slopes of the tubular portion 112, and a pair of lower slope portions. It is formed in an upwardly deformed U-shape by a pair of lower convex portions that sandwich the lower portion of a pair of side surfaces of the tubular portion 112. A hole 212 with a counterbore is formed in the lower horizontal portion of the bottom stage 21.

The bottom stage 21 is supported by a columnar lower rotating shaft 23 at the center of the lower surface of the lower horizontal portion. A female screw 231 communicating with the counterbore hole 212 of the bottom stage 21 is formed at the upper end of the lower rotating shaft 23. The bottom stage 21 and the lower rotating shaft 23 are integrated by tightening a bolt (not shown) from the counterbore hole of the bottom stage 21 to the female screw 231 of the lower rotating shaft 23. A double pipe 232 of an inner pipe and an outer pipe is provided on the inner central shaft of the lower rotating shaft 23. The inner pipe or outer pipe is the outward path of the cooling water, and the outer pipe or the inner pipe is the return path of the cooling water.

The top stage 22 has an inner surface portion 221 formed in a groove shape along the upper outer surface of the tubular portion 112, and cools the target T loaded in the target holder 1. The inner surface portion 221 of the top stage 22 includes an upper horizontal portion whose inner surface hits the upper surface of the tubular portion 112 in a horizontal posture, a pair of upper slope portions whose inner surface hits a pair of upper slopes of the tubular portion 112, and a tubular portion. It is formed in a downwardly deformed U-shape by an upper convex portion that sandwiches the upper part of a pair of side surfaces of the 112. A hole 222 with a counterbore is formed in the lower horizontal portion of the top stage 22.

The top stage 22 is supported by a columnar upper rotating shaft 24 at the center of the upper surface of the upper horizontal portion. A female screw 241 communicating with the counterbore hole 222 of the bottom stage 21 is formed at the upper end of the upper rotating shaft 24. The bottom stage 21 and the upper rotating shaft 24 are integrated by tightening a bolt (not shown) from the counterbore hole of the bottom stage 21 to the female screw 241 of the upper rotating shaft 24. A double pipe 242 of an inner pipe and an outer pipe is provided on the inner central shaft of the lower rotating shaft 23. The inner pipe or outer pipe is the outward path of the cooling water, and the outer pipe or the inner pipe is the return path of the cooling water. The upper rotating shaft 24 has a position where the top stage 22 is lowered so as to hit the cylindrical portion 112 mounted on the bottom stage 21 (see FIG. 1) and a position above the tubular portion 112 mounted on the bottom stage 21 (see FIG. 1). Move up and down between (see Fig. 2).

A linear accelerator (not shown) is provided adjacent to the holding mechanism 2 including the bottom stage 21 and the top stage 22. The linear accelerator is equipped with an electron beam source. The electron beam generation source is arranged so as to face the closed portion 114 of the container body 11 sandwiched between the bottom stage 21 and the top stage 22.

Here, a method for producing molybdenum-99 ( ^{99 Mo) from 100} Mo target T using the target holder 1 will be described.

As shown in FIG. 6, by engaging the rod 13 with the two hole-shaped held portions Ta formed on the target T, the plurality of target Ts are overlapped together by the rod 13. NS. The tip of the male screw 131 of the rod 13 projects from one surface of the superposed targets T.

At a predetermined location away from the holding mechanism 2, as shown in FIG. 3, a plurality of targets T are loaded into the space 111 of the cylindrical portion 112. One surface of the target T contacts the inner surface of the closure 114. The male screw 131 on the tip end side of the rod 13 is inserted into the connecting hole 114c formed in the closing portion 114 of the target holder 1. A hexagon wrench is inserted into the hexagonal hole of the head 132 of the rod 13, and the hexagon wrench is turned to tighten the male screw 131 formed on the tip side of the rod 13 to the female screw formed in the connecting hole 114c. Be done. The head 132 of the rod 13 pushes the other surface of the superposed targets T towards the closure 114. The plurality of targets T are fixed on the closed portion 114 side of the space portion 111. The surface of the target T on the innermost side (left side in FIG. 3) is in close contact with the inner surface of the closing portion 114.

The opening 113 of the tubular portion 112 is closed by the lid body 12. The outer peripheral edge of the end surface on one end side of the lid body 12 does not correspond to the stepped portion 112c formed in the space portion 111 of the tubular portion 112. The flange portion 122 of the lid body 12 overlaps the end surface 112d on one end side of the tubular portion 112. The screw hole 122d formed in the flange portion 122 of the lid portion and the lid body fixing hole 112e formed in the end surface 112d on one end side of the tubular portion 112 communicate with each other, and the screw 14 is screwed from the lid body fixing hole 112e. By passing through the hole 122d, the lid body 12 is integrated with the tubular portion 112. Since the gasket 124 is fitted in the groove 121a formed in the fitting portion 121 of the lid body 12, the gasket 124 comes into close contact with the inner surface of the enlarged diameter portion 112b of the container body 11. Therefore, the space portion 111 formed in the container body 11 is sealed by the closed lid body 12.

In the tubular portion 112 in which a plurality of targets T are loaded in the space portion 111 in this way, the tip portion of the transfer rod is inserted into the female screw 123a of the lid, and the transfer rod is operated to determine a predetermined value. Set to position. It is placed on the bottom stage 21. As shown in FIG. 2, the pair of lower slopes of the tubular portion 112 hits the pair of lower slope portions of the bottom stage 21, and the lower part of the pair of side surfaces of the tubular portion 112 is the pair of lower convex portions of the bottom stage 21. It will be sandwiched between the strips.

On the other hand, as shown in FIG. 1, the top stage 22 that has been waiting at the upper position descends, and the inner surface portion 221 hits the cylindrical portion 112 on the bottom stage 21. That is, the upper slope portion of the top stage 22 hits the pair of upper slopes of the tubular portion 112. The upper convex portion of the top stage 22 sandwiches the upper portion of the pair of side surfaces of the tubular portion 112. The lower ridge portion of the bottom stage 21 and the upper ridge portion of the top stage 22 are separated from each other. By doing so, the bottom stage 21 and the top stage 22 sandwich the tubular portion 112 substantially all around.

By flowing the cooling water in the double pipe of the lower rotating shaft 23 and the double pipe of the upper rotating shaft 24, the bottom stage 21 and the top stage 22 are cooled, and almost the entire surface of the tubular portion 112 is cooled. By doing so, the inside of the space 111 is cooled.

The closed portion 114 of the container body 11 faces the electron beam source of the linear accelerator. The electron beam emitted from the electron beam generation source passes through the thin-walled portion 114a of the closed portion 114 of the container body 11 and irradiates the target T in the space portion 111. As a result, gamma rays are generated. The target T produces ¹⁰⁰ Mo to ⁹⁹ Mo by a photonuclear reaction.

At this time, the target T generates heat. However, since the surface of the innermost target T is in close contact with the inner surface of the closed portion 114 of the container body 11, the heat of the target T is transferred from the closed portion 114 to the tubular portion 112. The heat generated in the target T is absorbed from the closed portion 114 to the bottom stage 21 and the top stage 22 in contact with the tubular portion 112 via the tubular portion 112 of the container body 11.

^{After 99} Mo is manufactured, the irradiation of the electron beam from the electron beam source is stopped. Then, the top stage 22 rises and the target holder 1 is taken out from the holding mechanism 2. That is, when the tip of the transfer rod grips the female screw 123a of the lid, the target holder 1 is discharged from the holding mechanism 2. The target holder 1 is carried to a predetermined transport unit where the radiation leakage is allowed via the intermediate route in a state where the radiation leakage from the target T is suppressed. In the transport section, the lid 12 of the target holder 1 is removed from the opening 113 of the tubular portion 112, and the target T is taken out from the inside of the tubular portion 112 without worrying about radiation leakage.

Although the embodiment of the present invention has been described above, the present invention is not limited to the configuration described in the embodiment, and can be considered within the scope of the claims. It also includes embodiments and modifications of the above. Further, various changes and combinations of the above-described embodiments may be made as long as the gist of the present invention is not deviated.

In the above embodiment, the target holder 1 ^{irradiates the 100} Mo target T with an electron beam in order to produce ¹⁰⁰ Mo to ^{99 Mo.} However, the target holder 1 ^{loads a target T other than the 100} Mo target T into the container body 11 so that radiation such as X-rays and gamma rays penetrates the thin portion 114a of the container body 11 according to the type of atom. You may. The thin portion 114a of the container body 11 is formed to be thin enough to allow radiation such as electron beam, X-ray, and gamma ray to pass through. Further, the target holder 1 can be loaded with a chemical substance, a biological sample such as a virus or a bacterium, or the like instead of the ^{100 Mo target T.}

Further, in the above-described embodiment, the tubular portion 112 is formed to have a polygonal outer diameter. However, the tubular portion 112 may be formed in a cylindrical shape or a spherical shape. In this case, the bottom stage 21 and the inner surface portions 211 and 221 of the top stage 22 are formed in a curved surface shape.

Further, in the above-described embodiment, a groove 121a is formed in the middle of the fitting portion 121 of the lid body 12, and the gasket 124 is fitted in the groove 121a to ensure airtightness. However, although not shown, a groove 121a is not formed in the middle of the fitting portion 121 of the lid body 12, and a ring-shaped aluminum gasket such as a ring-shaped aluminum gasket is formed between the tip surface of the fitting portion 121 and the stepped portion 112c of the tubular portion 112. Radiation resistance may be improved by interposing a metal gasket or a disk-shaped metal gasket. In this case, the step portion 112c is preferably wider than the step portion 113c shown in FIG. 3, and the diameter-reduced portion 112a of the container body 11 is made smaller than the diameter-reduced portion 112a shown in FIG. NS. Also. The inner diameter of the ring-shaped gasket is the same as that of the reduced diameter portion 112a of the container body 11. Further, a step is provided on the outer periphery of the tip surface of the lid 12 to fit the outer periphery of the ring-shaped gasket or the disk-shaped gasket.

Further, in the above-described embodiment, the cylindrical portion 112 includes a diameter-expanded portion 112b, a diameter-reduced portion 112a, and a stepped portion 112c. However, the tubular portion 112 may be formed to have the same inner diameter over the entire length. Further, a female screw may be formed in the opening 113, and a male screw may be formed in the fitting portion 121 of the lid body 12.

Further, the target T does not have to have a hole-shaped or notched-shaped held portion Ta. In this case, the loading member 13 uses an urging member such as a compression spring instead of the rod 13. The urging member is interposed between the lid 12 and the outermost target T, and presses the target T against the closing portion 114 of the container body 11. In this case, since the rod 13 is not used, the closing portion 114 does not need to be provided with the thick portion 114b having the connecting hole 114c formed therein. Therefore, the entire surface of the closed portion 114 is a thin-walled portion 114a, in other words, a passing portion 114a. Even when a compression member is used as the loading member 13, a target T having a hole-shaped or notched-shaped held portion Ta may be loaded.

Further, in the above-described embodiment, the rod 13 is a bolt, and the head 132 is hexagonally holed. However, the head 132 of the rod 13 may be formed with a groove such as a Phillips screw or a minus screw. Further, the rod 13 may be a simple shaft in which a male screw 131 is not formed at the tip portion. In this case, the connecting hole 114c formed in the closing portion 114 is a smooth surface on which the tip end portion of the rod 13 on which the female screw is not formed is simply inserted.

Further, in the above embodiment, it is assumed that the target holder 1 is formed of aluminum or an aluminum alloy. However, the target holder 1 may use copper, a copper alloy, or the like.

Further, in the above-described embodiment, the target holder holding mechanism 2 includes a bottom stage 21 and a top stage 22 for holding the target holder 1 in a horizontal posture. However, the target holder holding mechanism 2 may include a pair of stages 21 and 22 that hold the target holder 1 in a vertical posture or an inclined posture. The pair of stages 21 and 22 approach each other so as to sandwich the tubular portion 112 from both sides, and separate from both sides of the tubular portion 112. The pair of stages 21 and 22 also have an inner surface portion 221 formed in a groove shape along the outer surface of the tubular portion 112, and the target disk in the space portion 111 via the tubular portion 112. Cool T.

In summary, the target holder 1 and the target holder holding mechanism 2 to which the present invention is applied need only have the following configurations, and various embodiments can be taken.

That is, the target holder 1
The tubular portion 112 forming the space portion 111 for loading one or more target disks T, the opening 113 provided on one end side of the tubular portion 112, and the other end side of the tubular portion 112 are closed. A container body 11 sealed by a closing portion 114 having a passing portion 114a for passing radiation into the space portion 111.
A lid 12 that opens and closes the opening 113,
A loading member 13 that presses the target disk T against the closing portion 114, and
It has.

The target holder 1 is arranged so that the thin portion 114a of the closed portion 114 faces the linear accelerator, so that the radiation emitted from the linear accelerator passes through the passing portion 114a of the closed portion 114. The target disk T is loaded into the space portion 111 so as not to move by being pressed against the closing portion 114 by the loading member 13. The target disk T is irradiated with radiation emitted from the linear accelerator. The target holder 1 can produce a radioactive isotope from the loaded target disk T.

In the target holder 1 according to the present invention.
The tubular portion 112 is formed in a rectangular tubular shape having a polygonal outer shape.

Since the outer shape of the tubular portion 112 of the target holder 1 is a polygonal square cylinder, the wall thickness between the outer surface of the tubular portion 112 and the inner surface of the tubular portion 112 does not become thick, and the tubular portion does not become thick. The cold heat from the bottom stage 21 and the top stage 22 surrounding the 112 is easily transmitted to the space portion 111 in the cylindrical portion 112, and the heat of the target disk T is easily released to the bottom stage 21 and the top stage 22. Can be done. Further, since the square cylindrical portion 112 does not roll, it is stably sandwiched between the bottom stage 21 and the top stage 22.

In the target holder 1 according to the present invention.
The loading member 13 that presses the target disk T having two or more hole-shaped or notched-shaped held portions Ta against the closed portion 114 is a rod 13 that is engaged with the held portion Ta.
The closed portion 114 is provided with a thin-walled portion 114a in which the passing portion 114a is formed to be thin-walled, and a thick-walled portion 114b in which a connecting hole 114c into which the tip end portion of the rod 13 is inserted is formed.

In the target disk T, the rod 13 which is the loading member 13 is engaged with the held portion Ta having a hole shape or a notch shape formed at two or more places, and the tip portion of the rod 13 is a thick portion of the closing portion 114. By being inserted into the connecting hole 114c formed in 114b, 113 is loaded into the space so as not to move.

In the target holder 1 according to the present invention.
The rod 13 is a bolt having a male screw 131 formed on the tip end side and having a head 132 at the base end where the target disk T hits a surface facing the lid 12.
A female screw into which the male screw 131 of the rod 13 is screwed is formed in the connecting hole 114c.

In the target holder 1, the male screw 131 formed on the rod 13 is screwed into the female screw formed in the connecting hole 114c, and the target disk T is loaded into the space 111 of the tubular portion 112. When the rod 13 is tightened, the head 132 of the rod 13 presses the target disk T against the inner surface of the closed portion 114 of the tubular portion 112. When the target disk T is in close contact with the inner surface of the closed portion 114, the target holder 1 can absorb heat generated by the target disk T.

In the target holder 1 according to the present invention.
A lid fixing hole 112e is formed at a plurality of places on the end surface 112d on one end side of the tubular portion 112.
The lid 12 is a fitting portion 121 that is fitted into the opening 113 and has a groove 121a in the circumferential direction, and a flange portion 122 that overlaps an end surface 112d on one end side of the tubular portion 112. It has a flange portion 122 formed with a screw hole 122d communicating with the lid fixing hole 112e, and a gasket 124 fitted in the groove 121a.

In the target holder 1, the fitting portion 121 of the lid body 12 is fitted into the opening 113 of the tubular portion 112, and the flange portion 122 of the lid body 12 overlaps the end surface 112d on one end side of the tubular portion 112, and the collar portion By tightening the screw 14 from the screw hole 122d formed in 122 to the lid fixing hole 112e formed in the end surface 112d on one end side of the tubular portion 112, the lid 12 is prevented from coming off from the tubular portion 112. Can be. The gasket 124 formed in the groove 121a of the lid 12 is in close contact with the inner surface of the opening 113 of the tubular portion 112, so that the airtightness of the space portion 111 can be ensured.

In the target holder 1 according to the present invention.
The tubular portion 112 is formed at a boundary portion between the reduced diameter portion 112a formed in the intermediate portion, the enlarged diameter portion 112b formed on one end side, and the reduced diameter portion 112a and the enlarged diameter portion 112b. It is provided with a stepped portion 112c and lid fixing holes 112e formed at a plurality of locations on the end surface on one end side.
The lid 12 is a fitting portion 121 fitted into the enlarged diameter portion 112b of the tubular portion 112 and a flange portion 122 overlapping the end surface on one end side of the tubular portion 112 for fixing the lid body. It may have a flange portion 122 formed with a screw hole 122d communicating with the hole 112e, and a gasket attached to the tip surface of the fitting portion 121 and in close contact with the stepped portion 112c.

In the target holder 1, the gasket provided in the lid 12 is brought into close contact with the stepped portion 112c formed at the boundary between the diameter-reduced portion 112a and the diameter-expanded portion 112b of the tubular portion, so that the space portion 111 is airtight. Sex can be ensured.

In the target holder 1 according to the present invention.
At least the container body 11 is molded of aluminum or an aluminum alloy.

Since the container body 11 of the target holder 1 is made of aluminum or an aluminum alloy, activation due to irradiation can be reduced.

The target holder holding mechanism 2 according to the present invention is
A pair of stages 21 and 22 that approach the target holder 1 according to the present invention so as to sandwich the tubular portion 112 from both sides and separate from both sides of the tubular portion.
With
The pair of stages 21 and 22 have inner surface portions 211 and 221 formed in a groove shape along the outer surface of the tubular portion 112, and the target in the space 111 portion via the cylindrical portion 112. Cool the disk T.

The target holder holding mechanism 2 is held in a state where the target holder 1 is sandwiched between a pair of stages 21 and 22. The pair of stages 21 and 22 cool the target disk T via the cylindrical portion 112, so that the heat generation temperature of the target disk T in the space portion 111 is lowered.

In the target holder holding mechanism 2 according to the present invention,
The target holder 1 is in a horizontal posture.
The pair of stages 21 and 22 have a bottom stage 21 on which the tubular portion 112 is placed, a position lowered so as to hit the tubular portion 112 mounted on the bottom stage 21, and a position above the tubular portion 112. It is provided with a top stage 22 that moves up and down between the positions.

In this target holder holding mechanism, the lower side of the target holder 1 in the horizontal posture is fitted into the groove-shaped inner surface portion 211 of the bottom stage 21, and the upper side of the target holder 1 in the horizontal posture is the top stage. It fits into the inner surface portion 221 formed in the shape of a groove of 22. That is, the target holder 1 is held in a state of being sandwiched between the bottom stage 21 and the top stage 22.

1 ... Target holder 11 ... Container body 111 ... Space part 112 ... Cylindrical part 112a ... Reduced diameter part 112b ... Expanded diameter part 112c ... Step portion 112d ・ ・ ・ End face 112e ・ ・ ・ Hole for fixing the lid 113 ・ ・ ・ ・ Opening 114 ・ ・ ・ ・ Closed part 114a ・ ・ ・ Passing part (thin wall part)
114b ・ ・ ・ Thick part 114c ・ ・ ・ Connection hole 12 ・ ・ ・ ・ ・ Lid body 121 ・ ・ ・ ・ Fitting part 121a ・ ・ ・ Groove 122 ・ ・ ・ ・ Flange part 122a ・ ・ ・ Screw hole 124 ・ ・ ・・ ・ Gasket 13 ・ ・ ・ ・ ・ Loading member (rod)
131 ... Male screw 132 ... Head 2 ... Gasket holding mechanism (holding mechanism)
21 ... Stage (bottom stage)
211 ... Inner surface 22 ... Stage (top stage)
221 ... Inner surface T ... Target disk (target)
Ta: Held part

Claims (9)

A tubular portion forming a space for loading one or more target discs, an opening provided on one end side of the tubular portion, and the other end side of the tubular portion are closed to allow radiation into the space. A container body sealed by a closure having a passage through which,
A lid that opens and closes the opening,
A loading member that presses the target disk against the closure,
Is equipped with
Target holder. The tubular portion is formed in a polygonal square tubular shape.
The target holder according to claim 1. The loading member that presses the target disk having two or more hole-shaped or notched-shaped held portions against the closed portion is a rod that is engaged in the held portion.
The closed portion is provided with a thin-walled portion in which the passing portion is formed to be thin-walled and a thick-walled portion in which a connecting hole into which the tip end portion of the rod is inserted is formed.
The target holder according to claim 1 or 2. The rod is a bolt having a male screw formed on the tip end side and having a head portion at the base end portion where the target disk hits a surface facing the lid body.
A female screw into which the male screw of the rod is screwed is formed in the connecting hole.
The target holder according to claim 3. On the end face on one end side of the tubular portion, holes for fixing the lid body are formed at a plurality of places.
The lid body is a flange portion that is fitted into the opening and has a groove formed in the circumferential direction, and a flange portion that overlaps an end surface on one end side of the tubular portion, and communicates with the lid body fixing hole. It has a flange portion on which a screw hole is formed and a gasket fitted in the groove.
The target holder according to any one of claims 1 to 4. The tubular portion includes a reduced diameter portion formed in an intermediate portion, an enlarged diameter portion formed on one end side, a stepped portion formed at a boundary portion between the reduced diameter portion and the enlarged diameter portion, and one end. It is provided with holes for fixing the lid body formed at a plurality of places on the end face on the side.
The lid body is a flange portion that overlaps with an fitting portion that is fitted into the enlarged diameter portion of the tubular portion and an end surface on one end side of the tubular portion, and has a screw hole that communicates with the lid body fixing hole. It has a formed flange portion and a gasket that is attached to the tip surface of the fitting portion and is in close contact with the step portion.
The target holder according to any one of claims 1 to 4. At least the container body is molded of aluminum or an aluminum alloy.
The target holder according to any one of claims 1 to 6. A pair of stages that approach the target holder according to any one of claims 1 to 7 so as to sandwich the tubular portion from both sides and separate the tubular portions from both sides.
With
The pair of stages has an inner surface portion formed in a groove shape along the outer surface of the tubular portion, and cools the target disk in the space portion via the tubular portion.
Target holder holding mechanism. The target holder is in a horizontal position.
The pair of stages move up and down between a bottom stage on which the tubular portion is placed, a position lowered so as to hit the tubular portion mounted on the bottom stage, and a position above the tubular portion. It has a stage,
The target holder holding mechanism according to claim 8.

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