JP5128453B2 - Self-shielded particle accelerator system - Google Patents

Description

  The present invention relates to a self-shielded particle accelerator system.

  Particle accelerators such as cyclotrons are used in the manufacture of radiopharmaceutical-labeled examination drugs used for positron emission tomography (PET) and radiotherapy. During operation of the particle accelerator, radiation such as neutrons and gamma rays is generated, so it is necessary to shield the radiation.

  Conventionally, radiation shielding has been performed by covering the building itself where the particle accelerator is installed with a radiation shielding medium. However, in recent years, the particle accelerator itself is shielded from radiation in order to reduce the weight and cost of the building. A so-called self-shielding particle accelerator system that is surrounded and shielded by a wall has been developed (see, for example, Patent Document 1).

  In such a self-shielding particle accelerator system, the radiation shielding wall body has an upper wall portion and a side wall portion, and the particle accelerator is accommodated in an internal space formed by the upper wall portion and the side wall portion. Yes. The upper wall part and side wall part which comprise a radiation shielding wall body are formed from concrete.

In such a conventional self-shielding particle accelerator system, the radiation shielding wall body is manufactured by pouring concrete into a mold and removing the mold after the concrete is solidified. The radiation shielding wall created in this way is provided with a mounting seat (attachment) for fixing peripheral devices such as a cabinet for housing sensors, a transport hole for transporting itself, and the like. .
JP 2000-105293 A

  In the production of a radiation shielding wall using a formwork, when the formwork is removed, a part of the concrete may be missing or cracked. Most of such cracks and cracks do not cause a problem in shielding the radiation. However, in the conventional self-shielding particle accelerator system, since the concrete of the radiation shielding wall body is exposed to the outside, it is necessary to correct all of these in appearance, which is very troublesome. In addition, due to deformation of the formwork, a precise mating surface may not be formed between each small block, and correction is troublesome.

  In addition, there may be cases where it is desired to change the mounting position of peripheral devices after manufacturing the radiation shielding wall, but it is difficult to provide a mounting seat on the concrete later because the concrete may be chipped. It was not possible to change the mounting position of peripheral devices.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a self-shielding particle accelerator system that can be easily manufactured and can change the mounting position of peripheral devices.

A self-shielding particle accelerator system according to the present invention includes a particle accelerator, and a wall for surrounding the particle accelerator itself and shielding radiation separately from a wall of a building in which the particle accelerator is installed . In this system, the wall body is composed of a concrete-filled frame body filled with concrete inside the frame body, and the wall body includes a fixed side block and a movable side block, and the fixed side block and the movable side block are included. Each block has concave portions facing each other in a plane cross section, and the fixed block and the movable block are joined to each other to form an interior constituted by the concave block of the fixed block and the concave block of the movable block. A radiation shield that accommodates the particle accelerator in the space is configured, and the movable block is moved away from the fixed block to enable maintenance of the particle accelerator accommodated inside the wall. A guide rail is provided to guide the movement of the movable side block away from the fixed side block.

  In this system, since the wall body is composed of a concrete-filled frame body, after the concrete body is filled with concrete and solidified, it can be used as it is as a member constituting the wall body. In this way, since the labor of removing the frame from the concrete can be saved, the manufacture becomes easy. In addition, chipping or cracking of concrete is hidden by the frame, so that it is not necessary to correct these problems and manufacturing is facilitated. Furthermore, since a mounting seat for attaching the peripheral device can be freely attached to the frame, the attachment position of the peripheral device can be changed.

  Further, since the guide rail for guiding the movement of the movable block away from the fixed block is provided, the movement of the movable block is facilitated, and maintenance is improved.

  In the self-shielding particle accelerator system according to the present invention, the fixed block and the movable block are preferably composed of a plurality of blocks. In this way, handling such as transportation and storage becomes easier as compared with the case where the wall body is formed as a single body.

  In the self-shielding particle accelerator system according to the present invention, it is preferable that stepped portions that fit each other are provided on the joint surfaces of adjacent blocks among the plurality of blocks. In this way, it is possible to reduce the risk of radiation leaking between adjacent blocks.

  In the self-shielding particle accelerator system according to the present invention, the plurality of blocks include a block constituting the upper wall and a block constituting the side wall, and on a joint surface between the block constituting the upper wall and the block constituting the side wall. May be characterized in that a fixing material is applied. If it does in this way, a possibility that radiation may leak from between the blocks joined up and down can be reduced.

  In the self-shielding particle accelerator system according to the present invention, the concrete filling frame constituting the wall may be provided with a passage communicating between the inside and the outside of the wall. If it does in this way, it will become possible to let the cable which supplies the power supply to a particle accelerator pass through the said channel | path, and to release the heat | fever emitted from a particle accelerator.

  According to the present invention, there is provided a self-shielding particle accelerator system that is easy to manufacture and can change the mounting position of peripheral devices.

  Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. In the description of the drawings, the same elements are denoted by the same reference numerals, and redundant description is omitted.

  FIG. 1 is an exploded perspective view showing a configuration of a radiation shield provided in a cyclotron system as a self-shielding particle accelerator system according to the present embodiment. The cyclotron system (1 in FIG. 6) includes a cyclotron (particle accelerator) (40 in FIG. 5) and a radiation shield (wall body) 10 surrounding the cyclotron 40 and shielding radiation. As shown in FIG. 1, the radiation shield 10 includes a rear wall body 12 and a front wall body 14.

  As shown in FIG. 2, the rear wall 12 includes a right upper wall (RRU: Rear Right Upper) block 16, a left upper wall (RLU: Rear Left Upper) block 18, and a right wall (RRS: Rear Right Side) block 20. And a left side wall (RLS: Rear Left Side) block 22. The RRS block 20 and the RLS block 22 are erected in the vertical direction and have a substantially L-shaped cross section. The RRU block 16 and the RLU block 18 extend in the horizontal direction and cover the upper portions of the RRS block 20 and the RLS block 22. These RRU block 16, RLU block 18, RRS block 20 and RLS block 22 are connected by tightening connecting portions C with bolts 24 and nuts 26 at a plurality of locations as shown in FIGS.

  As shown in FIG. 4, the front wall body 14 includes an upper right wall (FRU: Front Right Upper) block 28, an upper left wall (FLU: Front Left Upper) block 30, and a right side wall (FRS: Front Right Side) block 32. And a left side wall (FLS: Front Left Side) block 34. The FRS block 32 and the FLS block 34 are erected in the vertical direction and have a substantially L-shaped cross section. The FRU block 28 and the FLU block 30 extend in the horizontal direction and cover the upper portions of the FRS block 32 and the FLS block 34. The FRU block 28, FLU block 30, FRS block 32 and FLS block 34 are connected by tightening the connecting portions C with bolts 24 and nuts 26 at a plurality of locations, similarly to the rear wall body 12.

The radiation shield 10 is formed by joining the rear wall body 12 and the front wall body 14. This is formed by a radiation shield 10, the cyclotron 40 is accommodated in the internal space R (see FIG. 6) in that consists by a recess 14a having the recess 12a and a front wall 14 having the rear wall 12 in plan sectional, self A shielded cyclotron system 1 is configured. Thus, the “self-shielding type” is a type in which the particle accelerator is shielded by a wall provided to shield the particle accelerator itself, separately from the building wall where the particle accelerator such as a cyclotron is installed. Say. In that sense, it is different from a particle accelerator system in which a wall that shields the particle accelerator forms part of a building.

  As shown in FIG. 5, the cyclotron 40 is a so-called vertical cyclotron, and includes a pair of magnetic poles 42, a vacuum box 44, and an annular yoke 46 that surrounds the pair of magnetic poles 42 and the vacuum box 44. ing. A part of the pair of magnetic poles 42 is inserted into the vacuum box 44, and the upper surfaces of the pair of magnetic poles 42 face each other with a predetermined gap. In the gap between the pair of magnetic poles 42, particles such as protons and deuterons are multiply accelerated.

  FIG. 6 is a plan view showing a state in which the cyclotron 40 is accommodated in the radiation shield 10. In FIG. 6, for convenience of explanation, a state in which the RRU block 16, the RLU block 18, the FRU block 28, and the FLU block 30 are removed is shown.

  As shown in FIG. 6, the cyclotron 40 is disposed substantially at the center in the radiation shield 10. In the state in which the rear wall body 12 and the front wall body 14 are joined, the wall surfaces that define the space for accommodating the cyclotron 40 in this way are the inner front surface 48, the inner back surface 50, the inner side surfaces 52 and 54, and the inner wall surfaces, respectively. It is assumed to be called the upper surface (56 in FIG. 1). At this time, a lead (Pb) layer 58 and a polyethylene (PE) layer 60 are sequentially laminated on the inner front surface 48 except for the portion facing the yoke 46. A Pb layer 58 and a PE layer 60 are sequentially laminated on the inner side surfaces 52 and 54. Further, only the PE layer 60 is laminated on the inner back surface 50. Further, as shown in FIGS. 1, 2, and 4, a Pb layer 58 and a PE layer 60 are sequentially laminated on the inner upper surface 56 except for a portion facing the yoke 46.

  Next, the FRU block 28, the FLU block 30, the FRS block 32 and the FLS block 34 constituting the front wall body 14 will be described in more detail with reference to FIGS. 7 to 10, and FIGS. The RRU block 16, RLU block 18, RRS block 20 and RLS block 22 constituting the rear wall 12 will be described in more detail with reference to FIG.

  FIG. 7 is a perspective view showing a frame 70 constituting the FRU block 28. As shown in FIG. 7, the frame body 70 is configured as a box whose upper end is opened. The FRU block 28 is formed by filling the frame 70 with concrete. A concave stepped portion 72 is provided on the joint surface of the frame body 70 to be joined to the FLU block 30. A concave stepped portion 74 is provided on the joint surface of the frame body 70 to be joined to the RRU block 16. A concave stepped portion 76 is also provided on the bottom wall surface of the frame body 70. This stepped portion 76 is for avoiding interference with the yoke 46. In addition, ribs 78 are erected in the frame body 70 for reinforcement.

  Further, a hole 80 through which the bolt 24 is inserted is formed through the side wall joined to the FLU block 30 of the frame. A space for fastening the bolt 24 and the nut 26 is defined in the vicinity of the hole 80. In this way, the connecting portion C for connecting the FLU block 30 is constituted by the hole 80 and the space. Further, a hole 82 through which the bolt 24 is inserted is formed through the bottom wall of the frame body 70 joined to the FRS block 32. A space for fastening the bolt 24 and the nut 26 is defined in the vicinity of the hole 82. Thus, the connection part C for connecting with the FRS block 32 is comprised by the hole 82 and the space.

  Next, FIG. 8 is a perspective view showing a frame 90 constituting the FLU block 30. As shown in FIG. 8, the frame 90 is configured as a box whose upper end is opened. The FLU block 30 is formed by filling the frame 90 with concrete. A convex stepped portion 92 is provided on the joint surface of the frame 90 to be joined to the FRU block 28. The step 92 is fitted with the concave step 72 of the FRU block 28. A concave stepped portion 94 is provided on the joint surface of the frame body 90 to be joined to the RLU block 18. A concave stepped portion 96 is also provided on the bottom wall surface of the frame 90. The step 96 is for avoiding interference with the yoke 46. Further, ribs 98 are erected in the frame body 90 to reinforce.

  Further, a hole 100 through which the bolt 24 is inserted is formed through the side wall of the frame body 90 that is joined to the FRU block 28. A space for fastening the bolt 24 and the nut 26 is defined in the vicinity of the hole 100. In this way, the connecting portion C for connecting the FRU block 28 is constituted by the hole 100 and the space. Further, a hole 102 through which the bolt 24 is inserted is formed through the bottom wall of the frame body 90 joined to the FLS block 34. A space for fastening the bolt 24 and the nut 26 is defined in the vicinity of the hole 102. In this way, the connecting portion C for connecting the FLS block 34 is configured by the hole 102 and the space.

  Next, FIG. 9 is a perspective view showing the frame 110 constituting the FLS block 34. As shown in FIG. 9, the frame body 110 is configured as a box whose upper end is opened. The FLS block 34 is formed by filling the frame 110 with concrete. A convex stepped portion 112 is provided on the joint surface of the frame 110 to be joined to the FRS block 32. Further, a hole 114 through which the bolt 24 is inserted is formed through the side wall of the frame 110 that is joined to the FRS block 32. In the vicinity of the hole 114, a space (similar to that shown in FIG. 3) for fastening the bolt 24 and the nut 26 is defined. Thus, the connection part C for aiming the connection with the FRS block 32 is comprised by the hole 114 and the space. A concave stepped portion 116 is provided on the joint surface of the frame 110 to be joined to the RLS block 22. A concave step 118 is also provided on the inner surface of the frame 110. The step 118 is for avoiding interference with the yoke 46. In addition, ribs 120 are erected in the frame body 110 for reinforcement.

  In addition, an auxiliary plate 124 having a hole 122 through which the bolt 24 is inserted is attached to the upper opening of the frame 110 that is joined to the FLU block 30. In the vicinity of the hole 122, a space for performing the operation of inserting the bolt 24 is defined. In this way, the connecting portion C for connecting the FLU block 30 is constituted by the hole 122 and the space.

  Next, FIG. 10 is a perspective view showing the frame body 130 that constitutes the FRS block 32. As shown in FIG. 10, the frame body 130 is configured as a box whose upper end is opened. The FRS block 32 is formed by filling the frame 130 with concrete. A concave step portion 132 is provided on the joint surface of the frame body 130 to be joined to the FLS block 34. This stepped portion 132 fits with the convex stepped portion 112 of the FLS block 34. Further, a hole (not shown) for inserting the bolt 24 is formed through the side wall of the frame body 130 to be joined to the FLS block 34. A space (not shown) for fastening the bolt 24 and the nut 26 is defined in the vicinity of the hole. Thus, the connection part C for connecting with the FLS block 34 is comprised by the hole and the space. A concave stepped portion 136 is provided on the joint surface of the frame 130 to be joined to the RRS block 20. A concave step 138 is also provided on the inner surface of the frame 130. The step 138 is for avoiding interference with the yoke 46. In addition, ribs 140 are erected in the frame body 130 for reinforcement.

  Further, an auxiliary plate 144 having a hole 142 through which the bolt 24 is inserted is attached to the upper opening of the frame body 130 that is joined to the FRU block 28. In the vicinity of the hole 142, a space for performing the operation of inserting the bolt 24 is defined. Thus, the connection part C for connecting with the FRU block 28 is comprised by the hole 142 and the space.

  The FRS block 32 and the FLS block 34 described above are connected by tightening the connecting portions C with the bolts 24 and the nuts 26 in a state where the stepped portions 112 and 132 provided on the joint surfaces are fitted. Further, the FRU block 28 and the FLU block 30 are connected by tightening the connecting portions C with the bolts 24 and the nuts 26 in a state where the stepped portions 72 and 92 provided on the joint surfaces are fitted. Yes. And the front wall body 14 is comprised by fastening the connection parts C with the volt | bolt 24 and the nut 26 in the state which mounted the FRU block 28 and the FLU block 30 in the upper part of the FRS block 32 and the FLS block 34. ing.

  When the FRU block 28 and the FLU block 30 are placed on the FRS block 32 and the FLS block 34, it is preferable to apply a sticking agent such as mortar to the joint surfaces in advance. In this way, it is possible to reduce the possibility that a gap is generated between the concrete exposed at the upper openings of the FRS block 32 and the FLS block 34 and the lower surfaces of the FRU block 28 and the FLU block 30.

  Next, FIG. 11 is a perspective view showing the configuration of the frame 150 forming the RRU block 16. As shown in FIG. 11, the frame 150 is configured as a box having an open upper end. The RRU block 16 is formed by filling the frame 150 with concrete. A concave stepped portion 152 is provided on the joint surface of the frame 150 to be joined to the RLU block 18. A convex stepped portion 154 is provided on the joint surface of the frame 150 to be joined to the FRU block 28. This step 154 fits into the concave step (74 in FIG. 7) of the FRU block 28. A concave step 156 is also provided on the bottom wall surface of the frame 150. The step 156 is for avoiding interference with the yoke 46. In addition, ribs 158 are erected in the frame body 156 for reinforcement.

  Further, a hole 160 through which the bolt 24 is inserted is formed through the side wall of the frame body 150 joined to the RLU block 18. A space for fastening the bolt 24 and the nut 26 is defined in the vicinity of the hole 160. In this way, the connecting portion C for connecting the RLU block 18 is constituted by the hole 160 and the space. In addition, a hole 162 through which the bolt 24 is inserted is formed through the bottom wall of the frame 150 that is joined to the RRS block 20. A space for fastening the bolt 24 and the nut 26 is defined in the vicinity of the hole 162. Thus, the connection part C for connecting with the RRS block 20 is comprised by the hole 162 and the space. Furthermore, a through hole 164 is formed in the bottom wall of the frame 150. The through hole 164 is formed with a passage T penetrating the inside of the RRU block 16 in the vertical direction by inserting a pipe when filling with concrete as shown in FIG. The passage T is used for releasing heat generated from the cyclotron 40 or passing a cable for supplying power to the cyclotron 40. A plurality of such passages T may be formed as necessary. Further, a similar passage T may be formed in the RLU block 18, the FRU block 28, and the FLU block 30 as necessary.

  Next, FIG. 12 is a perspective view showing a frame 170 constituting the RLU block 18. As shown in FIG. 12, the frame 170 is configured as a box having an open upper end. The RLU block 18 is formed by filling the frame 170 with concrete. A convex stepped portion 172 is provided on the joint surface of the frame 170 to be joined to the RRU block 16. This stepped portion 172 fits into the recessed stepped portion 152 of the RRU block 16. A convex stepped portion 174 is provided on the joint surface of the frame 170 to be joined to the FLU block 30. The stepped portion 174 fits with the recessed stepped portion (94 in FIG. 8) of the FLU block 30. A concave step 176 is also provided on the bottom wall surface of the frame 170. The step 176 is for avoiding interference with the yoke 46. Further, ribs 178 are erected in the frame body 170 for reinforcement.

  Further, a hole 180 for inserting the bolt 24 is formed through the side wall of the frame 170 joined to the RRU block 16. A space for fastening the bolt 24 and the nut 26 is defined in the vicinity of the hole 180. Thus, the connection part C for connecting with the RRU block 16 is comprised by the hole 180 and the space. Further, a hole 182 for inserting the bolt 24 is formed through the bottom wall of the frame body 170 joined to the RLS block 22. A space for fastening the bolt 24 and the nut 26 is defined in the vicinity of the hole 182. Thus, the connection part C for connecting with the RLS block 22 is comprised by the hole 182 and the space.

  Next, FIG. 13 is a perspective view showing a frame 190 that constitutes the RLS block 22. As shown in FIG. 13, the frame 190 is configured as a box having an open upper end. The RLS block 22 is formed by filling the frame 190 with concrete. A concave step portion 192 is provided on the joint surface of the frame body 190 to be joined to the RRS block 20. Further, a hole 194 through which the bolt 24 is inserted is formed through the side wall of the frame body 190 joined to the RRS block 20. A space for fastening the bolt 24 and the nut 26 is defined in the vicinity of the hole 194. Thus, the connection part C for connecting with the RRS block 20 is comprised by the hole 194 and the space. A convex stepped portion 196 is provided on the joint surface of the frame 190 to be joined with the FLS block 34. The step 196 is fitted with the concave step (116 in FIG. 9) of the FLS block 34. A rib 198 is erected in the frame 190 for reinforcement.

  In addition, an auxiliary plate 202 having a hole 200 through which the bolt 24 is inserted is attached to an upper opening of the frame body 190 joined to the RLU block 18. In the vicinity of the hole 200, a space for performing an operation of inserting the bolt 24 is defined. In this way, the connecting portion C for connecting the RLU block 18 is constituted by the hole 200 and the space.

  Next, FIG. 14 is a perspective view showing a frame body 210 constituting the RRS block 20. As shown in FIG. 14, the frame body 210 is configured as a box whose upper end is opened. The RRS block 20 is formed by filling the frame 210 with concrete. A convex step 212 is provided on the joint surface of the frame 210 to be joined to the RLS block 22. The step 212 is fitted with the concave step 192 of the RLS block 22. In addition, a hole 214 for inserting the bolt 24 is formed through the side wall of the frame 210 that is joined to the RLS block 22. A space for fastening the bolt 24 and the nut 26 is defined in the vicinity of the hole 214. Thus, the connection part C for connecting with the RLS block 22 is comprised by the hole 214 and the space. Further, a convex stepped portion 216 is provided on a joint surface of the frame body 210 to be joined with the FRS block 32. This step 216 fits with the concave step (136 in FIG. 10) of the FRS block 32. A rib 218 is erected in the frame 210 for reinforcement.

  Further, an auxiliary plate 222 having a hole 220 through which the bolt 24 is inserted is attached to the upper opening of the frame 210 that is joined to the RRU block 16. In the vicinity of the hole 220, a space for performing the operation of inserting the bolt 24 is defined. Thus, the connection part C for connecting with the RRU block 16 is comprised by the hole 220 and the space.

  The RRS block 20 and the RLS block 22 described above are connected by tightening the connecting portions C with bolts 24 and nuts 26 in a state where the step portions 192 and 212 provided on the joint surfaces are fitted. Further, the RRU block 16 and the RLU block 18 described above are coupled by tightening the coupling portions C with bolts 24 and nuts 26 in a state where the stepped portions 152 and 172 provided on the joint surfaces are fitted. Yes. The rear wall 12 is configured by tightening the connecting portions C with bolts 24 and nuts 26 with the RRU block 16 and the RLU block 18 placed on top of the RRS block 20 and the RLS block 22. ing.

  Note that when the RRU block 16 and the RLU block 18 are placed on the RRS block 20 and the RLS block 22, it is preferable to apply a sticking agent such as mortar to the joint surfaces in advance. In this way, it is possible to reduce the possibility that a gap is generated between the concrete exposed at the upper openings of the RRS block 20 and the RLS block 22 and the lower surfaces of the RRU block 16 and the RLU block 18.

And as shown in FIG. 1, the radiation shield 10 is comprised by joining the front wall body 14 and the rear wall body 12. As shown in FIG. Note that no connection means as shown in FIG. 3 is provided between the front wall 14 and the rear wall 12. This allows maintenance of the cyclotron 40 accommodated in the interior by pulling the front wall body 14 forward while guiding it with the guide rail W, with the rear wall body 12 as the fixed side and the front wall body 14 as the movable side. This is because .

  As a material for forming the frame bodies 70, 90, 110, 130, 170, 150, 190, and 210 that constitute each block described above, a metal material such as iron, FRP, or the like can be used. However, iron is preferable from the viewpoint of cost and strength.

  Further, when the frames 70, 90, 110, 130, 170, 150, 190, 210 are made of iron, since iron has almost no radiation shielding ability, it is about 1.0 mm to 10.0 mm from the viewpoint of weight reduction. Is preferred.

  As the concrete filled in the frames 70, 90, 110, 130, 170, 150, 190, 210, concrete having a high specific gravity from the viewpoint of radiation shielding ability, for example, an aggregate having a high specific gravity such as magnetic steel. It is preferable to use the high density shielding concrete used.

  Further, when filling the frames 70, 90, 110, 130, 170, 150, 190, 210 with concrete, anchors G are inserted into the frames 70, 90, 110, 130, 170, 150, 190, 210, etc. It is preferable that the anchor G is partly fixed with concrete as shown in FIGS. If it does in this way, conveyance of a block will become possible by attaching detachable lifting tool J to this anchor G.

  As described above in detail, in the cyclotron system 1 according to the present embodiment, the radiation shield 10 surrounding the cyclotron 40 fills the frames 70, 90, 110, 130, 170, 150, 190, 210 with concrete. Since it is composed of a concrete-filled frame, after the concrete is filled and solidified in the frames 70, 90, 110, 130, 170, 150, 190, 210, this is used as a member constituting the radiation shield as it is. Can be used. As described above, since the labor of removing the frame body from the concrete can be saved, the radiation shield 10 can be easily manufactured, and the cyclotron system 1 can be easily manufactured. In addition, since concrete chips and cracks are hidden by the frames 70, 90, 110, 130, 170, 150, 190, and 210, it is not necessary to correct these problems, and manufacturing is facilitated. Furthermore, since a mounting seat for attaching a peripheral device can be freely attached to the frames 70, 90, 110, 130, 170, 150, 190, and 210, the attachment position of the peripheral device can be changed.

  In the cyclotron system 1 according to the present embodiment, the radiation shield 10 includes a plurality of blocks 16, 18, 20, 22, 28, 30, 32, and 34. In comparison, handling such as transportation and storage becomes easier.

  Furthermore, in the cyclotron system 1 according to the present embodiment, stepped portions (72 and 92, 112 and 132, 152 and 172, 192 and 212, 74 and 154, 94 and 174, 116 and 196 are formed on the joint surfaces of adjacent blocks. 136 and 216) are provided, and these are joined in a fitted state, so that the risk of radiation leaking between adjacent blocks can be reduced. Further, since a bonding agent such as mortar is applied to the joint surface between the upper block and the lower block where it is difficult to provide such a stepped portion, the risk of radiation leakage can be further reduced. Furthermore, if the frames 70, 90, 110, 130, 170, 150, 190, 210 are made of iron, the deformation of each block can be suppressed and the alignment accuracy at the joint surface can be improved, and radiation may leak. Can be further reduced.

  In addition, since the Pb layer 58 effective for shielding neutrons and the PE layer 60 effective for shielding gamma rays are appropriately laminated on the inner surface of the radiation shield 10, the shielding of these radiations by concrete is reinforced. Thus, the radiation shielding ability can be improved. It is preferable to design the thickness of the concrete, the Pb layer 58, and the PE layer 60 in consideration of the radiation attenuation characteristics and the volume / weight ratio.

  Further, since the RRU block 16 is provided with a passage T that communicates the inside and outside of the wall body, it is possible to pass a cable for supplying power to the cyclotron 40 and to release heat from the cyclotron. Become.

  Further, since the guide rail W for guiding the movement of the movable front wall body 14 is provided, the movement of the front wall body 14 is facilitated, and the maintenance performance is improved.

  The present invention is not limited to the above-described embodiment, and various modifications can be made. For example, in the above-described embodiment, the radiation shield 10 is configured from the eight blocks 16, 18, 20, 22, 28, 30, 32, and 34, but may be formed from other numbers of blocks.

  In the self-shielding particle accelerator system according to the present invention, a particle accelerator other than the cyclotron may be shielded by a radiation shield.

It is a disassembled perspective view which shows the structure of the radiation shield with which the cyclotron system which concerns on embodiment is provided. It is a disassembled perspective view which shows the structure of a rear wall body. It is a figure which shows the connection means for connecting the adjacent block. It is a disassembled perspective view which shows the structure of a front wall body. It is a perspective view which shows the structure of the cyclotron accommodated in a radiation shield. It is a top view which shows a mode that the cyclotron is accommodated in the radiation shield. FIG. 7A is a perspective view of the frame constituting the FRU block as viewed from above, and FIG. 7B is a perspective view of the frame as viewed from below. FIG. 8A is a perspective view of the frame constituting the FLU block as viewed from above, and FIG. 8B is a perspective view of the frame as viewed from below. It is a perspective view which shows the frame which comprises a FLS block. It is a perspective view which shows the frame which comprises a FRS block. FIG. 11A is a perspective view of the frame constituting the RRU block as viewed from above, and FIG. 11B is a perspective view of the frame as viewed from below. FIG. 12A is a perspective view of the frame constituting the RLU block as viewed from above, and FIG. 12B is a perspective view of the frame as viewed from below. It is a perspective view which shows the frame which comprises a RLS block. It is a perspective view which shows the frame which comprises a RRS block.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Cyclotron system, 10 ... Radiation shield, 16 ... RRU block, 18 ... RLU block, 20 ... RRS block, 22 ... RLS block, 28 ... FRU block, 30 ... FLU block, 32 ... FRS block, 34 ... FLS block, 40 ... cyclotron, 70, 90, 110, 130, 170, 150, 190, 210 ... frame, 72, 74, 92, 94, 112, 116, 132, 136, 152, 154, 172, 174, 192, 196 , 212, 216... Stepped portion, W... Guide rail, T.

Claims (5)

A self-shielding particle accelerator system comprising: a particle accelerator; and a wall for shielding the radiation surrounding the particle accelerator itself separately from a wall of a building in which the particle accelerator is installed ,
The wall body is composed of a concrete-filled frame body filled with concrete inside the frame body,
The wall includes a fixed side block and a movable side block, the fixed side block and the movable side block each having a recess facing each other in a plane cross section, and the fixed side block and the A radiation shield that accommodates the particle accelerator in an internal space constituted by the concave portion of the fixed side block and the concave portion of the movable side block by joining a movable side block; and Enabling the maintenance of the particle accelerator housed inside the wall by moving the movable block away from the fixed block forward;
A self-shielding particle accelerator system, characterized in that a guide rail is provided for guiding the movement of the movable block away from the fixed block.   The self-shielding particle accelerator system according to claim 1, wherein the fixed block and the movable block are composed of a plurality of blocks.   3. The self-shielding particle accelerator system according to claim 2, wherein stepped portions that are fitted to each other are provided on joint surfaces of adjacent blocks among the plurality of blocks. The plurality of blocks include a block constituting an upper wall and a block constituting a side wall, and a bonding material is applied to a joint surface between the block constituting the upper wall and the block constituting the side wall. The self-shielded particle accelerator system according to claim 2. 2. The self-shielding particle accelerator system according to claim 1, wherein the concrete filling frame constituting the wall is provided with a passage communicating between the inside and the outside of the wall.

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