JP4886729B2 - Radiation detector - Google Patents

Description

  The present invention relates to a radiation detector, and more particularly to a light shielding structure in a radiation detector used in a radiation measuring apparatus.

  As radiation measuring apparatuses, monitoring posts, body surface monitors, survey meters, and the like are known. Such a radiation measuring apparatus has a radiation detector for detecting radiation. For example, the survey meter includes a measurement unit and a radiation detector, and the measurement unit is provided with an arithmetic circuit, a display, an input unit, and the like. The radiation detector is provided with a scintillator member, a photomultiplier tube, and the like. As is well known, the scintillator member generates light by the incidence of radiation such as X-rays and β-rays, and the light is detected by a photomultiplier tube. In order to detect weak light, the space on the light emission side of the scintillator member in the radiation detector is a dark room. The radiation detector is provided with various light shielding structures so that extraneous light does not enter the space. Since the scintillator material is a transparent member, it is necessary to first prevent external light from entering through the scintillator member.

  Generally, in a radiation detector that detects β-rays or α-rays, one or a plurality of extremely thin light-shielding films are stretched away from the radiation incident surface of the scintillator member. However, since the light-shielding film is very thin and brittle because it needs to transmit β rays or the like, it is very difficult to stretch the light-shielding film without damaging it, and the work load is large. Therefore, Patent Document 1 proposes a method of forming a light shielding film on a scintillator plate using a transfer technique. Before the transfer, the light shielding film is stuck on the base film, so that it is physically strong. After the transfer, the scintillator itself functions as a back substrate, so that the light shielding film is physically strong. . In addition, since the transfer is used, there is an advantage that the light shielding film can be formed quickly and easily. Patent Document 2 also discloses a scintillator member having a light shielding film formed by transfer.

JP 2007-147581 A JP 2007-240495 A

  By the way, in the case where a radiation detector is configured using a scintillator member having a light shielding film formed by some technique, light passing through the scintillator member itself can be sufficiently blocked, but the problem here is that the surroundings of the scintillator member It is how to sufficiently shield the external light that enters from and enters. Generally, it is conceivable to use a flat packing having a frame shape that is in close contact with the surrounding area of the radiation incident surface of the scintillator member, but simple surface bonding between the flat packing and the scintillator member, or In the simple surface joining of the flat packing and the frame material, there is a possibility that the extraneous light cannot always be sufficiently blocked. Even a small gap that cannot be seen by the eyes can enter the light, so it is necessary to prevent it with a simple structure.

  An object of the present invention is to reliably prevent entry of external light in a radiation detector using a scintillator member with a light shielding film.

  The present invention comprises a scintillator member that includes a light-shielding film on an incident surface on which radiation is incident, and that emits light by incident radiation from the outside, and light generated thereby is emitted from the light emitting surface, and a peripheral portion of the scintillator member. A hollow main body case having a first pedestal structure for receiving, a second pedestal structure for receiving a peripheral portion of the scintillator member, a cover for sandwiching the scintillator member together with the main body case, and a second pedestal structure. And a light-shielding packing that has a bent shape that wraps around from the incident surface side to the side surface side of the scintillator member and performs light shielding on the incident surface side and light shielding on the side surface side of the scintillator member. It relates to a radiation detector.

  According to the said structure, a holding means is comprised by the combination of a 1st base structure and a 2nd base structure, and, thereby, the peripheral part of a scintillator member is hold | maintained. Since the second pedestal structure (or from the second pedestal structure to the first pedestal structure) is provided with a light shielding packing, it has a bent shape that wraps around from the incident surface (for example, the lower surface) of the scintillator member, It is possible to simultaneously perform light shielding in the peripheral region on the incident surface of the scintillator member and light shielding on the side surface side of the scintillator member. In an embodiment described later, the first pedestal structure is a first step structure having at least one step, and the second pedestal structure is a second step structure having at least one step.

  Preferably, the light-shielding packing includes a horizontal spacer portion provided between an incident surface of the scintillator member and a pedestal surface included in the second pedestal structure as a surface facing the incident surface, and a portion connected to the horizontal spacer portion. The scintillator member has a side surface, and a regulation surface that is formed on one of the first pedestal structure and the second pedestal structure, or is formed across both, and faces the side surface of the scintillator member. , And a vertical spacer portion provided between the two.

  Preferably, the horizontal spacer portion has a horizontal seal surface as a surface facing a peripheral region of the incident surface of the scintillator member, and the horizontal seal surface has at least one protruding toward the incident surface side of the scintillator member. Two protruding frames are provided. According to this configuration, not the surface bonding but the point bonding (generally, the line bonding), the apex portion of the projecting frame is surely pressed against the incident surface (that is, the light shielding film), and reliable light shielding is performed there. Yes. The protruding frame has a shape that matches the shape of the scintillator member. If the scintillator member is rectangular, the protruding frame is generally rectangular. If the scintillator member is circular, the protruding frame is generally circular.

  Preferably, the horizontal sealing surface is provided with a double protruding frame protruding toward the incident surface side of the scintillator member. According to this configuration, it is possible to more reliably shield light on the incident surface side. Although triple protrusion frames may be provided, it is considered most reasonable to provide double protrusion frames from the standpoint of reliable light shielding because if too many protrusion frames are provided, it will approach surface bonding. It is.

  Preferably, the first pedestal structure has a slope that obliquely crushes a corner portion of the vertical spacer portion toward a side surface of the scintillator member in a coupled state of the first pedestal structure and the second pedestal structure. . According to this configuration, since the inclined surface comes into pressure contact with the sharp corner, the same effect as the above-described protruding frame can be obtained. That is, it is possible to reliably prevent light from entering from the outside of the vertical spacer portion.

  Further, the present invention is a radiation detector having a plurality of detection units arranged one-dimensionally or two-dimensionally, each detection unit including a light-shielding film on an incident surface on which radiation is incident, and radiation from the outside The scintillator member that emits light by the incident light, and the light generated thereby is emitted from the light emitting surface, the opening having the first base structure that receives the peripheral portion of the scintillator member, and the first portion that receives the peripheral portion of the scintillator member. It has a two pedestal structure, a frame body that sandwiches the scintillator member together with the opening, and a bent shape that is disposed in the second pedestal structure and wraps around from the incident surface side to the side surface side of the scintillator member, The present invention relates to a radiation detector comprising: a light shielding packing that performs light shielding on an incident surface side and light shielding on a side surface side of the scintillator member.

  According to the said structure, a large area type radiation detector is comprised by the some detection unit. Moreover, since each detection unit has a packing having a bent shape sandwiched between the first pedestal structure and the second pedestal structure, light can be shielded in units of detection units.

  Preferably, the plurality of openings of the plurality of detection units are configured as a lattice plate of a main body frame on which the plurality of detection units are mounted, and a plurality of frame bodies separated for each of the detection units are provided. The plurality of scintillator members and the plurality of light shielding packings included in the plurality of detection units are sandwiched between the lattice plate and the plurality of separated frames. According to this configuration, since the frame is provided for each detection unit, it is easy to replace the packing in units of detection units. Further, since the packing can be surely pressed for each detection unit, the light shielding property is improved.

  Preferably, the plurality of detection units are two-dimensionally arranged, and a large sensitive surface is formed by denseness of the scintillator member surfaces. Preferably, the large sensitive surface has a planar form. Preferably, the large sensitive surface has a curved shape. If the sensitive surface is configured as a shape corresponding to the shape of the object, the detection efficiency can be increased.

  As described above, according to the present invention, the entry of external light can be reliably prevented in a radiation detector using a scintillator member with a light shielding film.

  DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, preferred embodiments of the invention will be described with reference to the drawings.

  FIG. 1 shows a preferred embodiment of a radiation detector according to the present invention, and FIG. 1 is a partial sectional view of the radiation detector. This radiation detector constitutes a part of a radiation measurement device, and is electrically connected to a measurement unit (not shown) via a cable. The radiation measuring apparatus is a survey meter in this embodiment.

  The radiation detector has a main body case 10 and a protective cover 12. The main body case 10 is roughly divided into a lower part 10A and an upper part 10B. The inside of the main body case 10 is a cavity 14, and the cavity 14 constitutes a dark room. A photomultiplier tube (PMT) 17 is provided in the upper part 10B, and the light receiving surface of the photomultiplier tube 17 faces the cavity. The photomultiplier tube 17 is actually built in the handle, but the handle case and the like are not shown. Incidentally, the radiation detector is held by a hand, that is, forms a portable unit.

  The lower portion 10A has a square shape when viewed from above, and a rectangular protective cover 12 is provided correspondingly. Specifically, the protective cover 12 is coupled to the main body case 10 by screws or the like not shown. In the coupled state of the main body case 10 and the protective cover 12, the scintillator member 16 provided therein is held and fixed.

  The scintillator member 16 has a structure described in Patent Document 1 above, that is, has a scintillator plate 18 and a light shielding film 20. The scintillator plate 18 has a flat plate shape. When the radiation 22 enters, light is generated there, and the light is guided into the cavity 14 as indicated by reference numeral 24. The light is detected by the photomultiplier tube 16. In the state shown in FIG. 1, the lower surface 16B of the scintillator member 16 is a radiation incident surface, and the upper surface 16A is a light emitting surface. 3 and 5 described later, the upper surface of the scintillator member is an incident surface, and the lower surface is a light emitting surface. As described above, the light shielding film 20 as a film is formed on the lower surface 16B. The light shielding film 20 is composed of an adhesive layer, an aluminum vapor deposition layer (light shielding layer), and a protective layer when viewed from the scintillator plate 18 side. The A plurality of light shielding films 20 may be formed on the lower surface 16B. The light shielding film 20 is formed by the thermal transfer method in this embodiment, but the light shielding film 20 can be formed by various manufacturing techniques.

  The main body case 10 is provided with a step structure 26 as a first pedestal structure. On the other hand, the protective cover 12 is provided with a step structure 28 as a second pedestal structure. The step structure 26 and the step structure 28 function as a holding portion for the scintillator member 16 as a whole. That is, the step structure 26 has a structure for receiving the peripheral edge portion of the scintillator member 16, and similarly, the step structure 28 has a structure for receiving the peripheral edge portion of the scintillator member 16. However, the step structure 26 is a downward structure in FIG. 1, and the step structure 28 is an upward structure in FIG. The step structure 26 and the step structure 28 are formed over the entire circumference of the scintillator member 16.

  The step structure 28 is provided with a packing 30 as shown. The packing 30 is a light shielding member, which is provided over the entire periphery of the scintillator member 16, that is, the packing 30 has a frame shape. The packing 30 is preferably composed of an elastic member such as rubber. The cross section of the packing 30 has a bent shape or an L-shape as shown in FIG. Although the structure of the packing 30 will be described in detail later, the packing 30 realizes light shielding in the peripheral region on the lower surface 16B of the scintillator member 16, and also realizes light shielding on the side surface of the scintillator member 16. Incidentally, the protective cover 12 is an eye plate or a lattice member, and exhibits an effect of protecting the scintillator member 16. The scintillator member 16 may be configured in a circular shape. In that case, the shape of the step structures 26 and 28 and the packing 30 is determined to be circular according to the shape of the scintillator member 16.

  FIG. 2 shows a partially enlarged view of the radiation detector shown in FIG. In particular, an enlarged view of the vicinity of the peripheral edge of the scintillator member 16 is shown. As described above, the step structure 26 has a step for receiving the peripheral portion of the scintillator member 16, and specifically, a ceiling surface (pedestal surface) 26A joined to the upper surface 16A, a vertical surface 26B facing the side surface 16C, An intermediate horizontal surface 26C extending in the horizontal direction from the lower end of the vertical surface 26B, and a slope 26D extending downward from the intermediate horizontal surface 26C. Incidentally, FIG. 2 shows a state in which the main body case 10 is slightly lifted upward with respect to the protective cover 12, but this is for the purpose of explanation of the structure. 10 are connected in close contact.

  On the other hand, the step structure 28 has a pedestal surface 28A as a horizontal plane, a jetty 28B protruding slightly upward therefrom, and a vertical surface 28C. The base surface 28 </ b> A functions as a base for the packing 30. When the step structure 26 receives the peripheral edge of the scintillator member 16, a side space 32 is formed in the step structure 26. Similarly, when the step structure 28 receives the peripheral edge of the scintillator member 16, there is a lower space there. A (gap space) 34 is formed. However, the above-described packings 30 are accommodated in the spaces 32 and 34, and the packing 30 shields light from the lower surface side to the side surface side of the scintillator member 16.

  The packing 30 is composed of a horizontal seal portion 36 and a vertical seal portion 38 standing from one end thereof. When the vertical cross section of the packing 30 is viewed, it has a bent shape or an L-shape. The horizontal seal portion 36 has a lower surface (one joint surface) joined to the pedestal surface 28A and an upper surface (the other joint surface) 36A on the opposite side, and the upper surface (the other joint surface) 36A has a double protrusion. A frame, that is, a first projecting frame 40A and a second projecting frame 40B are provided apart from each other.

  Each protruding frame 40A, 40B has a form protruding from the upper surface 36A toward the lower surface (radiation incident surface) 16B side of the scintillator member 16, and each cross section has a mountain shape or a dome shape. Each protruding frame 40A, 40B has a rectangular shape, that is, a rectangular shape as a whole. Since the double protruding frames 40A and 40B are provided, as shown at 104, even when extraneous light enters, reliable light shielding can be performed. That is, if the upper surface 36A and the lower surface 16B are simply joined, it can be said that a slight gap is inevitably generated. However, according to each of the protruding frames 40A and 40B, the gap between the members by point contact (actually line contact). Can be reliably closed, so that the entry of extraneous light can be effectively prevented. In particular, in the present embodiment, since the double projecting frames 40A and 40B are provided, even if there is an insufficient surface for the function of the first projecting frame 40A, light leakage is caused by the next projecting frame 40B. It becomes possible to prevent it reliably. Since the light shielding film 20 is provided on the lower surface 16B of the scintillator member as described above, extraneous light does not pass through the scintillator member 16 itself. That is, it can be said that each of the projecting frames 40 </ b> A and 40 </ b> B is a light shielding member connected to the light shielding film 20.

  On the other hand, the vertical seal portion 38 has an inner surface 38A and an outer surface 38B. The vertical seal portion 38 has a rectangular shape in its original state, that is, in the original shape, a corner portion is formed on the side opposite to the scintillator member 16 as indicated by reference numeral 38a. When the main body case 10 is pressed against the protective cover 12 as indicated by reference numeral 100, the corner portion is obliquely crushed toward the side surface 16C, thereby causing a deformed state as shown in FIG. In FIG. 2, reference numeral 102 represents an oblique crushing action.

  In this manner, the protruding portion as in the projecting frames 40A and 40B is naturally crushed by the inclined surface 26D, so that a state similar to a point joining (line joining) is generated there, and an external part as indicated by reference numeral 106 is generated. It is possible to reliably prevent light from entering. In addition, since the entire periphery of the scintillator member 16 is elastically held by the packing 30 by such crushing, there is an advantage that wobbling of the scintillator member 16 can be prevented.

  Reference numeral 110 denotes a gap 110 formed between the main body case 10 and the protective cover 12, and the gap 110 is hardly formed when the two are joined together, but if a slight gap is generated, the light 110 Therefore, such light is reliably blocked by the action of the packing 30 described above. The inclined surface 26D and the vertical surface 28C are surfaces facing the side surface 16C, and they function as regulating surfaces. That is, the vertical seal portion 38 is provided between the regulation surface composed of these surfaces and the side surface 16C. It is also possible to provide a structure similar to the above-described protruding frames 40A and 40B on the outer side surface 38B and the inner side surface 38A.

  According to the above embodiment, when the main body case 10 and the protective cover 12 are joined, the scintillator member 16 is securely held by the action of the packing 30, and in this state, light from the lower surface 16 </ b> B side of the scintillator member 16 is transmitted. The entry is reliably prevented, and at the same time, the entry of light on the side surface side of the scintillator member 16, specifically, the entry of light through the gap 110 is reliably prevented. This has the advantage that the operating state of the radiation detector can be maintained properly.

  Next, another embodiment will be described with reference to FIGS. The radiation detector shown in FIG. 3 is a large-area type radiation detector, and is used, for example, for a body surface monitor. A plurality of openings are formed in the hollow main body case 200 that forms a dark room, and a plurality of detection units 202 are disposed in the plurality of openings. Each opening can be regarded as a part of each detection unit. In the example shown in FIG. 3, 3 × 3 detection units are closely packed together to form a two-dimensional unit array. As a result, the effective area exhibiting sensitivity to radiation is expanded. The sensitive surface forms a plane in the example shown in FIG. Each detection unit has basically the same structure as that of the embodiment shown in FIG. 1, that is, has a rectangular light-shielding packing having a bent shape.

  The front plate of the main body case 200 is configured as a lattice member having a plurality of openings. Each packing is held between each opening and each frame 206, and light leakage around each scintillator member is reliably prevented. The inside of the main body case 200 is a single dark room, and the light receiving surfaces of the four photomultiplier tubes 204A to 204D face it. A plurality of screws 208 are used to fix the plurality of frames 206 to the front plate. A screw 208 provided between two adjacent detection units is inserted into a boundary portion between the two frames and exerts an action of fixing them simultaneously.

  FIG. 4 shows a partial cross section of the radiation detector shown in FIG. The basic structure for shading is the same as that shown in FIGS. 1 and 2, and the same elements as those shown in FIGS. 1 and 2 are denoted by the same reference numerals. The same applies to the embodiments shown in FIGS. 5 and 6 described later.

  In FIG. 4, the front plate 210 on the radiation incident side in the main body case has a plurality of openings corresponding to the plurality of detection units 202, and the front plate 210 has a lattice-like form. Reference numeral 210A denotes an aperture through which light passes. Each opening in the front plate 210 is formed with a rectangular step structure 26 as viewed from above, which receives and positions the periphery of the scintillator member 16. The step structure 26 may be configured as a combined body of a plurality of members. If the scintillator member 16 can be initially positioned by means other than the step structure 26, a front plate having a uniform thickness may be used instead of the step structure 26, that is, a pedestal structure having a flat surface may be adopted. Good. The frame 206 has a rectangular shape when viewed from above, and its vertical cross section is L-shaped. On the other hand, the frame 206 has a step structure 28 that receives and positions the packing 30. The peripheral portion of the scintillator member 16 is held by the frame 206 and the front plate 210 via the packing 30 which is an elastic member, and at the same time, light shielding there is realized. The scintillator member 16 includes a scintillator 18 and a film (light shielding film) 20. Reference numeral 220 indicates radiation (for example, β-rays), and when it reaches the scintillator 18 through the coating 20, light emission occurs there. Reference numeral 222 indicates light generated thereby. The light 222 exits to the dark room side and further reaches the light receiving surface of the photomultiplier tube. Reference numeral 206A denotes an opening of the frame body 206.

  The packing 30 has a bent shape or an L-shape around the scintillator member 16 from the incident surface (upper surface) side to the side surface side, and the above-described two protruding frames are formed thereon. Therefore, light leakage around the scintillator member 16 can be reliably prevented. This is the same as the embodiment shown in FIGS. In the embodiment shown in FIGS. 3 and 4, a slope (see reference numeral 26D in FIG. 2) for obliquely crushing the corner of the packing 30 is not formed, but such a slope is further provided on the front plate or the like. You may do it. The frame body 206 may be composed of a plurality of members. For example, the frame body 206 may be configured by a horizontal flat plate and a vertical flat plate. Since the packing 30 has a bent shape and wraps the incident side corner portion at the end of the scintillator member 16, even if the frame body 206 is constituted by a plurality of members, reliable light shielding can be performed.

  Still another embodiment is shown in FIGS. The configuration shown in FIG. 5 is basically the same as the configuration shown in FIG. 3, but in the configuration shown in FIG. 5, the sensitive surface is curved in a concave shape. That is, the radiation detector shown in FIG. 5 has a plurality of detection units 302 fixed to the main body case 300, and in the illustrated example, 3 × 3 detection units 302 are two-dimensionally arranged. Among them, the unit group indicated by B faces the front, whereas the unit group indicated by A and C has a direction inclined toward the B side. According to such a curved form, when the object is rounded, the sensitive surface can be brought close to the surface, so that the detection sensitivity is increased.

  FIG. 6 shows a partial cross section between adjacent units. The front plate 310 of the main body case has a plurality of openings, which have a lattice shape. Reference numeral 310A denotes an opening. In order to incline the directions of the A group and the C group, the front plate 310 is slightly bent between the groups. Other structures are the same as those shown in FIG. That is, the front plate 310 is provided with a step structure 26 for each opening, while each frame body 206 is provided with a step structure 28. The peripheral part of each scintillator member 16 is held between the front plate 310 and each frame 206 via each packing 30, and light shielding is realized there. When the radiation 200 reaches the scintillator, light 222 is generated. Light 226 going out from the dark room side is reflected by the film (light-shielding film), and the entrance of light 224 from the outside is blocked by the film (light-shielding film).

  Also in this embodiment, since the packing 30 has a bent shape and has two projecting frames that come into contact with the film, it is possible to realize reliable light shielding. Also in this embodiment, the above-described slope (see reference numeral 26D in FIG. 2) may be provided. The large area type radiation detector shown in FIGS. 3 to 6 is preferably mounted on a body surface monitor, an article monitor, or the like, but can also be mounted on other radiation measuring apparatuses.

It is a partial sectional view showing an embodiment of a radiation detector concerning the present invention. It is a partial enlarged view of the radiation detector shown in FIG. It is a perspective view which shows the radiation detector which concerns on other embodiment. It is a fragmentary sectional view of the radiation detector shown in FIG. It is a perspective view which shows the radiation detector which concerns on other embodiment. It is a fragmentary sectional view of the radiation detector shown in FIG.

Explanation of symbols

  10 body case, 12 protective cover, 14 cavity (dark room), 16 scintillator member, 20 light shielding film, 26 step structure, 28 step structure, 30 packing.

Claims (11)

A scintillator member provided with a light-shielding film on the incident surface on which the radiation is incident, causing light emission by the incidence of radiation from the outside, and light generated thereby being emitted from the light emitting surface;
A hollow body case having a first pedestal structure for receiving a peripheral edge of the scintillator member;
A cover having a second pedestal structure for receiving a peripheral portion of the scintillator member, and sandwiching the scintillator member together with the main body case;
A light-shielding packing disposed on the second pedestal structure, having a bent shape that wraps around from the incident surface side to the side surface side of the scintillator member, and performs light shielding on the incident surface side and light shielding on the side surface side of the scintillator member; ,
Only including,
The shading packing is
A horizontal spacer portion provided between the incident surface of the scintillator member and the pedestal surface of the second pedestal structure as the surface facing the incident surface;
A portion that is continuous with the horizontal spacer portion, is a surface that is formed on one side of the scintillator member and one of the first pedestal structure and the second pedestal structure, or is formed across both of the scintillator members. A vertical spacer portion provided between a regulating surface facing the side surface;
A radiation detector characterized in that it comprises a. The radiation detector according to claim 1.
2. The radiation detector according to claim 1, wherein the light shielding packing is made of an elastic member . The radiation detector according to claim 1 .
The horizontal spacer portion has a horizontal seal surface as a surface facing a peripheral region in the incident surface of the scintillator member,
The radiation detector according to claim 1, wherein the horizontal sealing surface is provided with at least one protruding frame protruding toward the incident surface side of the scintillator member. The radiation detector according to claim 3.
The radiation detector according to claim 1, wherein the horizontal sealing surface is provided with a double projecting frame projecting toward the incident surface side of the scintillator member. The radiation detector according to claim 1 .
The first pedestal structure has a slope that obliquely crushes a corner portion of the vertical spacer portion toward a side surface of the scintillator member in a coupled state of the first pedestal structure and the second pedestal structure. Characteristic radiation detector. The radiation detector according to any one of claims 1 to 5,
The first pedestal structure is a first step structure having at least one step,
The second pedestal structure is a second step structure having at least one step,
A radiation detector characterized by that. A radiation detector having a plurality of detection units arranged in one or two dimensions,
Each of the detection units is
A scintillator member provided with a light-shielding film on the incident surface on which the radiation is incident, causing light emission by the incidence of radiation from the outside, and light generated thereby being emitted from the light emitting surface;
An opening having a first pedestal structure for receiving a peripheral portion of the scintillator member;
A frame having a second pedestal structure for receiving a peripheral portion of the scintillator member, and sandwiching the scintillator member together with the opening;
A light-shielding packing disposed on the second pedestal structure, having a bent shape that wraps around from the incident surface side to the side surface side of the scintillator member, and performs light shielding on the incident surface side and light shielding on the side surface side of the scintillator member; ,
Only including,
The shading packing is
A horizontal spacer portion provided between the incident surface of the scintillator member and the pedestal surface of the second pedestal structure as the surface facing the incident surface;
A portion that is continuous with the horizontal spacer portion, is a surface that is formed on one side of the scintillator member and one of the first pedestal structure and the second pedestal structure, or is formed across both of the scintillator members. A vertical spacer portion provided between a regulating surface facing the side surface;
A radiation detector characterized in that it comprises a. The radiation detector according to claim 7.
The plurality of openings of the plurality of detection units are configured as a lattice plate of a main body frame on which the plurality of detection units are mounted,
A plurality of separate frames are provided for each of the detection units,
The plurality of scintillator members and the plurality of light shielding packings included in the plurality of detection units are sandwiched by the lattice plate and the plurality of separated frames.
A radiation detector characterized by that. The radiation detector according to claim 7.
The radiation detector according to claim 1, wherein the plurality of detection units are two-dimensionally arranged, and a large sensitive surface is formed by a dense surface of the scintillator members. The radiation detector according to claim 9.
The radiation detector according to claim 1, wherein the large sensitive surface has a planar form. The radiation detector according to claim 9.
The radiation detector, wherein the large sensitive surface has a curved shape.

Images