JP2017040494A - Radiation detector, radiation detection device, and method of inspecting radiation detector - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method of inspecting health of a radiation detector using a simple and inexpensive configuration.SOLUTION: A radiation detector (5) is configured to be installed in an installation hole (19) provided in a shield case (3), and includes a detection element (35) which is inserted through the installation hole to be disposed at the end thereof, a radiation source holding member disposed behind the detection element and configured to be capable of holding a radiation check source (75), and a lead block (51) disposed behind the radiation source holding member in the installation hole.SELECTED DRAWING: Figure 6

Description

  The present invention relates to a radiation detector and a radiation detection device that detect radiation (environmental radiation) or the like in wastewater from waste-related facilities or exhaust gas, and an inspection method for the radiation detector.

  2. Description of the Related Art Conventionally, a radiation detection apparatus in which a radiation detector is attached to a container connected to a piping of a radiation-related facility is known (for example, see Patent Document 1). The radiation detection apparatus described in Patent Literature 1 takes a part of drainage from a radiation-related facility into a container, and detects radiation in the drainage with a detection element of a radiation detector protruding into the container. By the way, the soundness of the radiation detector is inspected using a check radiation source before product shipment or during regular maintenance. For example, in the above-described radiation detection apparatus, the entire container is covered with a lead shielding case, and the radiation detector is inspected by attaching a check line source to the wall surface of the shielding case.

Japanese Patent Laying-Open No. 2015-99028

  However, in the inspection of the radiation detector described above, in order to attach and detach the check radiation source to the shielding case, it is necessary to perform inspection processing such as holes and closing plugs and install parts on the wall surface of the shielding case. There were problems that caused an increase in processes and complicated equipment.

  The present invention has been made in view of the above points, and an object thereof is to provide a radiation detector and a radiation detection apparatus that can perform an inspection with a simple and inexpensive configuration, and an inspection method for the radiation detector. .

  The radiation detector of the present invention is a radiation detector that is attached to an attachment hole provided in a shielding wall, and includes a detection element that is inserted through the attachment hole and disposed in the back, and a check line behind the detection element. A radiation source holding member capable of holding a source, and a shielding member installed in the mounting hole behind the radiation source holding member.

  According to this configuration, in the radiation detector attached to the shielding wall via the attachment hole, the radiation source holding member is positioned behind the detection element. Therefore, the radiation from the check radiation source is detected by the detection element by holding the check radiation source on the radiation source retaining member. A shielding member is installed in the mounting hole. Thus, since the check line source is held in the radiation detector itself, the inspection of the radiation detector can be performed without requiring inspection processing or installation of parts on the wall surface of the shielding wall.

  Another radiation detector of the present invention includes a detection unit having a radiation detection element, a radiation source unit that can hold a check radiation source, and a unit case that houses the detection unit and the radiation source unit. It is characterized by.

  According to this configuration, the detection unit and the radiation source unit are accommodated in the unit case. And radiation is detected by the detection element of a detection unit by making a radiation source unit hold | maintain a check radiation source. Thus, since the check line source is held in the radiation detector itself, the inspection of the radiation detector can be performed without requiring inspection processing or installation of parts on the wall surface of the shielding wall.

  An inspection method for a radiation detector according to the present invention is an inspection method for a radiation detector attached to an attachment hole provided in a shielding wall, and is provided behind the detection element of the radiation detector via the attachment hole side. Arranging a radiation source holding member for holding a check radiation source, installing a shielding member in the mounting hole, and causing the detection element to detect radiation from the check radiation source in the radiation source holding member; It is characterized by having.

  According to this configuration, the radiation source holding member is arranged behind the detection element, and the shielding member is installed in the mounting hole. Then, the radiation from the check line source is detected by the detection element. Since the check radiation source is held by the radiation detector itself, inspection of the radiation detector can be performed without requiring inspection processing or installation of parts on the wall surface of the shielding wall.

  According to the present invention, the check line source is held in the radiation detector itself, so that a dedicated facility for holding the check line source is not required, and the radiation detector can be inspected with a simple and inexpensive configuration. .

It is a perspective view of the radiation detection apparatus which concerns on this Embodiment. It is a disassembled perspective view of the radiation detector which concerns on this Embodiment. It is sectional drawing of the radiation detector which concerns on this Embodiment. It is a disassembled perspective view of the radiation source unit which concerns on this Embodiment. It is a usage pattern figure of the radiation detection apparatus which concerns on this Embodiment. It is explanatory drawing at the time of the test | inspection of the radiation detection apparatus which concerns on this Embodiment.

  Hereinafter, a radiation detection apparatus will be described with reference to the accompanying drawings. FIG. 1 is a perspective view of a radiation detection apparatus 1 according to the present embodiment. In addition, the radiation detection apparatus 1 is not limited to the structure shown in FIG. The radiation detection apparatus 1 shown in FIG. 1 is only an example, and can be changed as appropriate.

  As shown in FIG. 1, the radiation detection apparatus 1 is a so-called water monitor, which takes in a part of drainage from a radiation-related facility into a pipe 4 and emits radiation in the drainage with a radiation detector 5 protruding into the pipe 4. Are continuously detected. On the frame 2 of the radiation detector 1, a lead shielding case 3 that supports the radiation detector 5 together with the pipe 4 is installed. The shielding case 3 is formed in a T shape in a top view by a box-shaped pipe support part 11 that shields the periphery of the pipe 4 and a columnar detector support part 12 that shields the periphery of the radiation detector 5. . The shielding case 3 forms a radiation detection space in the radiation detection apparatus 1.

  In the present embodiment, the shielding case 3 is exemplified as a shielding wall that shields radiation emitted from the radiation detection space and prevents scattering to the outside. There is no limit.

  The pipe 4 is supported on the pipe support portion 11 with both ends of the pipe 4 protruding. One end of the pipe 4 is provided with an inlet joint 15 connected to the upstream pipe of the sampling channel (not shown), and the other end of the pipe 4 is an outlet joint connected to the downstream pipe of the sampling channel. 16 is provided. The radiation detector 5 is supported by the detector support 12 so as to be orthogonal to the pipe 4. A detector mounting portion 17 (see FIGS. 5 and 6), which is an opening for mounting the detector, is formed at an intermediate portion in the extending direction of the pipe 4, and the radiation detector 5 is passed through the detector mounting portion 17. The detection element at the tip of the projection protrudes into the pipe 4.

  A supply pipe 18 for supplying cleaning water enters the hole 13 at the top of the shielding case 3, and an outlet of the supply pipe 18 is connected to the pipe 4. Further, a drain pipe (not shown) is connected to the lower part of the pipe 4 to drain the drainage in the pipe. In the radiation detection apparatus 1 configured as described above, the radiation in the waste water flowing in the pipe 4 is detected by the radiation detector 5 and output to the preamplifier 7 as a pulse signal.

  By the way, the soundness of the radiation detector 5 is periodically inspected with respect to the radiation detection apparatus 1 installed at the site using a check radiation source. In a normal inspection of the radiation detector 5, a check radiation source is attached to the shielding case 3, but in order to attach and detach the check radiation source, a hole or a closing plug must be provided on the wall surface of the shielding case 3, The configuration of the detection device 1 was complicated. Therefore, in this embodiment, the radiation detector 5 itself holds the check radiation source so that the inspection can be easily performed.

  FIG. 2 is an exploded perspective view of the radiation detector 5 according to the present embodiment. As shown in FIG. 2, the radiation detector 5 can accommodate the detection unit 30 for detecting radiation and the radiation source unit 60 (radiation source holding member) capable of holding the check radiation source 75 in the unit case 20. Composed. The unit case 20 is formed in a bottomed cylindrical shape having an open end so as to accommodate the members arranged in a row in the detection unit 30. The detection unit 30 includes a scintillator 35 as a detection element, a housing 41, a spring 46, a lead block 51, and the like.

  FIG. 3 is a cross-sectional view of the radiation detector 5 according to the present embodiment. As shown in FIG. 3, a photomultiplier tube 39 is disposed inside the housing 41. A plurality of members such as the scintillator 35, the photomultiplier tube 39, the spring 46, and the lead block 51 are arranged coaxially and integrated, and the scintillator 35, the photomultiplier tube 39 side is the inner bottom surface of the front end side of the unit case 20 To be accommodated in the unit case 20.

  The lead block 51 of the detection unit 30 is fixed to the flange 31 of the detection unit 30. The flange 31 of the detection unit 30 is abutted against the flange 21 of the unit case 20 and is fixed to the shielding case 3 by fixing bolts 25 inserted into the through holes 24 and 34 of the flanges 21 and 31. In this case, the lead block 51 is positioned in the vicinity of the opening of the unit case 20 by the biasing force of the spring 46, and the scintillator 35 and the photomultiplier tube 39 are pressed against the front end side of the unit case 20. Thereby, the scintillator 35, the photomultiplier tube 39, and the lead block 51 are positioned at predetermined positions of the unit case 20.

  Refer to FIG. 2 again. An opening is formed on the inner side (center) of the lead block 51 and the flange 31. Such an opening serves as an insertion space of the radiation source unit 60, that is, an accommodation space in which the radiation source unit 60 is accommodated. Therefore, in the following, this opening is referred to as a radiation source housing portion 33. As shown in FIG. 3, the radiation source housing portion 33 is divided into a small-diameter space 53 and a large-diameter space 54 by a step 52 provided on the inner peripheral surface of the lead block 51. Since the opening of the lead block 51 and the opening of the flange 31 are flush with each other, the opening of the flange 31 is also a large-diameter space 54.

  As shown in FIG. 2, the radiation source unit 60 is configured to hold a disk-shaped check radiation source 75 with a radiation source case 62 provided at the tip of a lead mounting rod 61.

  FIG. 4 is an exploded perspective view of the radiation source unit 60 according to the present embodiment. As shown in FIG. 4, a rectangular attachment plate 63 detachably attached to the flange 31 of the detection unit 30 is fixed to the attachment rod 61 of the radiation source unit 60. The attachment plate 63 is attached to the flange 31 in a state where the radiation source unit 60 is inserted into the radiation source accommodating portion 33. With such a configuration, the radiation source unit 60 is detachably attached to the detection unit 30 with the check radiation source 75 positioned in the unit case 20. This will be described in more detail below.

  The mounting rod 61 of the radiation source unit 60 is a lead cylinder, and the radiation source case 62 is fixed to the distal end, and the mounting plate 63 is fixed to the proximal end. The mounting rod 61 is divided into a small diameter portion 65 on the radiation source case 62 side and a large diameter portion 66 on the mounting plate 63 side by a step 64 provided on the outer peripheral surface. The radiation source case 62 includes a case main body 71 having an open front surface and a lid member 72 that covers the front surface of the case main body 71. The case main body 71 and the lid member 72 hold a check line source 75. A check line source 75 is placed on the bottom surface of the case main body 71 via a cushion member 73, and an opening 74 is formed in the lid member 72 to partially expose the check line source 75 to the outside.

  As shown in FIG. 3, the outer diameter of the small diameter portion 65 of the mounting rod 61 corresponds to the inner diameter of the small diameter space 53 of the radiation source accommodating portion 33, and the outer diameter of the large diameter portion 66 of the mounting rod 61 is the radiation source accommodating portion 33. This corresponds to the inner diameter of the large-diameter space 54. Therefore, the mounting rod 61 is positioned with respect to the lead block 51 by the step 64 on the outer peripheral surface of the mounting rod 61 abutting against the step 52 on the inner peripheral surface of the radiation source housing portion 33. With the mounting rod 61 positioned with respect to the lead block 51, the mounting plate 63 is screwed to the flange 31 of the detection unit 30 by a bolt 26 in consideration of the work efficiency of the operator (see FIG. 5). 4).

  Thus, the radiation source unit 60 is attached to the detection unit 30 so that the check radiation source 75 is positioned at a position away from the scintillator 35 within the unit case 20 by a certain distance. Since the distance from the scintillator 35 to the check line source 75 is constant, an error in detection sensitivity due to the distance can be eliminated.

  In the radiation detector 5 configured as described above, the scintillator 35 emits light according to the radiation from the check line source 75, and a pulse signal is output from the photomultiplier tube 39 according to the light emission of the scintillator 35. The soundness of the radiation detector 5 is inspected according to the output from the photomultiplier tube 39. For example, the radiation standard gamma ray source 402 type is used as the check radiation source 75, but the type is not limited to this type, and 401 type, 403-405 type may be appropriately used according to the type of the scintillator 35. Is possible. The check line source 75 is configured to be detachable from the opening side of the mounting hole 19.

  Further, the lead block 51 and the mounting rod 61 as the shielding member shield the opening of the unit case 20 and the mounting hole 19 of the shielding case 3. Therefore, leakage of radiation from these can be suppressed. In addition, about the opening of the unit case 20, and the attachment hole 19, the location where members, such as lead with high shielding capability, such as the path of wiring and the thickness of the unit case 20, are not arrange | positioned may arise in part. That is, as long as the shielding effect by the shielding member is exhibited, it is not necessary to completely close the opening and the mounting hole. In this embodiment, the lead block and the mounting rod are exemplified as the shielding member. However, the present invention is not limited to this configuration. For example, the mounting hole 19 of the shielding case 3 may be shielded by a single shielding member. Good.

  The above-described radiation source unit 60 is attached to the radiation detector 5 when the radiation detector 5 is inspected.

  FIG. 5 is a usage diagram of the radiation detection apparatus 1 according to the present embodiment. That is, FIG. 5 shows an aspect during normal use, that is, when the radiation detector 5 is not inspected. As shown in FIG. 5, in the radiation detector 5, a plug unit 80 is attached to seal the radiation source housing portion 33 that is an opening inside the lead block 51 and the flange 31 in place of the radiation source unit 60 during normal use. It is done. Unlike the radiation source unit 60, the plug unit 80 is screwed to the flange 31 at a plurality of locations on the mounting plate 82.

  More specifically, a step 85 is formed on the outer peripheral surface of the mounting rod 81 of the plug unit 80 by a small diameter portion 83 on the distal end side and a large diameter portion 84 on the proximal end side, similarly to the mounting rod 61 of the radiation source unit 60. Is formed. Therefore, when the mounting rod 81 of the plug unit 80 is inserted inside the lead block 51, the step 85 on the outer peripheral surface of the mounting rod 81 hits the step 52 on the inner peripheral surface of the lead block 51, and The mounting rod 81 is positioned. The mounting plate 82 is screwed to the flange 31 with the mounting rod 81 positioned relative to the lead block 51.

  As a result, the radiation detector 5 is attached to the attachment hole 19 of the shielding case 3, so that the attachment hole 19 is shielded by the attachment rod 81 and the lead block 51 installed in the attachment hole 19. As described above, the shielding case 3 is made of lead, and the mounting hole 19 of the shielding case 3 is also closed with lead, so that leakage of radiation from the inside of the shielding case 3 to the outside is effectively suppressed.

  When the radiation detector 5 is attached to the shielding case 3, the scintillator 35 at the tip of the radiation detector 5 protrudes into the pipe 4 through the mounting well 87 installed in the detector attachment portion 17. In this way, when the radiation detector 5 is normally used, the radiation in the waste water flowing through the pipe 4 is detected.

  FIG. 6 is an explanatory diagram at the time of inspection of the radiation detection apparatus 1 according to the present embodiment. As shown in FIG. 6, when the radiation detector 5 is inspected, the plug unit 80 is removed from the flange 31 of the detection unit 30 and the radiation source unit 60 is attached. At this time, the plug unit 80 and the radiation source unit 60 are attached / detached at a location where the detection unit 30 is exposed from the opening of the unit case 20, that is, at the flange 31. Since the plug unit 80 and the radiation source unit 60 can be attached to and detached from the detection unit 30 in a state where the radiation detector 5 is fixed to the shielding case 3, the work load on the operator is reduced. Thus, the radiation detector 5 can be inspected simply by replacing the plug unit 80 and the radiation source unit 60.

  When the radiation source unit 60 is attached to the detection unit 30, the check radiation source 75 at the tip of the attachment rod 61 is positioned in the unit case 20. Accordingly, since the check radiation source 75 is held in the radiation detector 5 itself, it is not necessary to provide a facility for the check radiation source 75 in the shielding case 3. Similarly to the plug unit 80, the mounting rod 61 of the radiation source unit 60 is inserted inside the lead block 51 of the detection unit 30, so that the mounting hole 19 of the lead shielding case 3 becomes the mounting rod 61 and the lead block. Closed with 51 lead. Therefore, radiation from the check line source 75 is shielded by lead, and leakage of radiation from the inside of the shielding case 3 to the outside is effectively suppressed.

  Further, as described above, the check line source 75 is positioned at the tip of the mounting rod 61 in the unit case 20. Therefore, regardless of the assembly error of the detection unit 30, the radiation from the check line source 75 can be detected by the scintillator 35 with a constant detection sensitivity. In this way, when the radiation detector 5 is inspected, radiation from the check line source 75 in the unit case 20 is detected.

  As described above, in the radiation detector 5 according to the present exemplary embodiment, the check radiation source 75 is positioned in the unit case 20, and the radiation from the check radiation source 75 is detected by the scintillator 35. Since the radiation detector 5 itself holds the check radiation source 75, the shielding case 3 does not require the equipment for the check radiation source 75, and the radiation detector 5 can be inspected even when the shielding case 3 has no dedicated equipment. Can be implemented. In this case, since it is only necessary to attach the radiation source unit 60 to the detection unit 30, the work burden on the worker is not increased. Therefore, the radiation detector can be inspected with a simple and inexpensive configuration.

  In addition, this invention is not limited to the said embodiment, It can change and implement variously. In the above-described embodiment, the size, shape, and the like illustrated in the accompanying drawings are not limited to this, and can be appropriately changed within a range in which the effect of the present invention is exhibited. In addition, various modifications can be made without departing from the scope of the object of the present invention.

  For example, in the present embodiment, a water monitor has been exemplified and described as the radiation detection apparatus 1, but the present invention is not limited to this configuration. The radiation detection apparatus 1 may be anything provided with the radiation detector 5 capable of holding the check line source 75, and may be a gas monitor, for example.

  In the present embodiment, the configuration in which the radiation detector 5 is inspected with the radiation detector 5 attached to the radiation detection device 1 has been described. However, the configuration is not limited to this configuration. The radiation detector 5 can be inspected by another equipment without being attached to the radiation detection apparatus 1.

Moreover, in this Embodiment, the radiation detector 5 may detect radiations, such as not only a gamma ray energy but a beta ray, an X ray, a neutron ray. Therefore, the detection element of the radiation detector 5 includes NaI (Tl) scintillator, CsI (Tl) scintillator, LaBr ₃ (Ce) scintillator, CeBr ₃ scintillator, BGO scintillator, YAP (Ce) scintillator, CdTe semiconductor, CdZnTe semiconductor, Ge A semiconductor, Si semiconductor, ³ He scintillator, ⁶ Li scintillator, ⁷ Li scintillator, or plastic scintillator may be used.

  Moreover, in this Embodiment, although the detection unit 30 was comprised by several members, such as the scintillator 35, the photomultiplier tube 39, the spring 46, and the lead block 51, it is not limited to this structure. The detection unit 30 only needs to be configured to detect radiation.

  In the present embodiment, the radiation source unit 60 as the radiation source holding member is composed of a plurality of members such as the mounting rod 61 and the radiation source case 62, but is not limited to this configuration. Further, the radiation source holding member is not limited to the radiation source unit 60.

  For example, the radiation source holding member may be like the radiation source case 62, or may hold the check radiation source 75 with a fitting portion or the like. That is, the radiation source holding member only needs to be able to hold the check radiation source behind the detection element, and it is more preferable that the single body or the composite body is detachable or replaceable.

  In the present embodiment, the unit case 20 is formed in a bottomed cylindrical shape, but is not limited to this configuration. The unit case 20 only needs to be configured to accommodate the detection unit 30 and the radiation source unit 60. For example, the unit case 20 may be formed in a box shape with one end opened.

  In the present embodiment, the check line source 75 is positioned in the unit case 20 by the step 64 on the outer peripheral surface of the mounting rod 61 abutting against the step 52 on the inner peripheral surface of the lead block 51. It is not limited to this configuration. The check line source 75 may be positioned in any way as long as it is positioned at a position away from the scintillator 35 by a certain distance.

The feature points in the various embodiments described above are organized below.
In the radiation detector described in the above embodiment, the radiation source holding member is detachable or replaceable. According to this structure, the structure at the time of normal use and the time of a test | inspection can be used properly by attaching or detaching or replacing | exchanging a radiation source holding member from a radiation detector. Further, the check radiation source in the radiation source holding member can be replaced or removed along with the attachment or detachment or replacement of the radiation source holding member.

  In the radiation detector according to the above embodiment, the radiation source unit is positioned with respect to the detection unit so as to position the check radiation source at a position away from the detection element by a certain distance within the unit case. Removably attached. According to this configuration, since the distance from the detection element to the check line source is constant, an error in detection sensitivity due to the distance can be eliminated.

  In the radiation detector according to the above embodiment, the unit case is formed in a bottomed cylindrical shape with one end opened, and the radiation source unit is located at a position where the detection unit is exposed from the opening of the unit case. Detachable. According to this configuration, since the radiation source unit can be attached to and detached from the detection unit in a state where the detection unit is accommodated in the unit case, the burden on the operator can be reduced.

  In the radiation detector according to the above embodiment, the radiation source unit has a lead mounting rod that holds the check radiation source at the tip, and the detection unit is a lead into which the mounting rod is inserted from the tip. A cylindrical block made of metal, and the opening of the unit case is shielded by lead of the mounting rod and the cylindrical block. According to this configuration, it is possible to radiate radiation toward the detection element with the check line source while suppressing leakage of radiation from the opening of the unit case.

  The radiation detection apparatus according to the embodiment includes the radiation detector described above and a lead shielding wall that forms a radiation detection space, and is attached to the shielding wall for attaching the radiation detector. A hole is formed, and the mounting hole is shielded by lead of the mounting rod and the cylindrical block. According to this configuration, since the mounting hole of the shielding wall is closed with lead, the radiation detection space can be shielded with lead, and radiation leakage from the detection space can be suppressed.

  As described above, the present invention has an effect that inspection can be performed with a simple and inexpensive configuration, and in particular, a radiation detector for detecting radiation in waste water from waste-related facilities and exhaust gas, and It is useful for the radiation detection apparatus and the inspection method of the radiation detector.

1 radiation detector 3 shielding case (shielding wall)
5 Radiation detector 19 Mounting hole 20 Unit case 30 Detection unit 35 Scintillator (detection element)
39 Photomultiplier tube 51 Lead block (shielding member, cylindrical block)
60 radiation source unit (radiation source holding member)
61 Mounting rod (shielding member)
62 Radiation source case (radiation source holding member)
63 Mounting plate 75 Check source

Claims (8)

A radiation detector attached to a mounting hole provided in the shielding wall,
A detecting element inserted from the mounting hole and disposed in the back;
A radiation source holding member capable of holding a check radiation source behind the detection element;
A shielding member installed in the mounting hole behind the radiation source holding member;
A radiation detector comprising:   The radiation detector according to claim 1, wherein the radiation source holding member is detachable or replaceable. A detection unit having a radiation detection element;
A radiation source unit capable of holding a check radiation source;
A unit case for housing the detection unit and the radiation source unit;
A radiation detector comprising:   The said radiation source unit is detachably attached to the detection unit so as to position the check radiation source at a position away from the detection element by a certain distance in the unit case. 3. The radiation detector according to 3. The unit case is formed in a bottomed cylindrical shape with one end opened,
The radiation detector according to claim 4, wherein the radiation source unit is detachable at a position where the detection unit is exposed from the opening of the unit case. The radiation source unit has a lead mounting rod that holds the check radiation source at the tip,
The detection unit has a lead cylindrical block into which the mounting rod is inserted from the tip,
The radiation detector according to claim 5, wherein an opening of the unit case is shielded by lead of the mounting rod and the cylindrical block. The radiation detector according to claim 6, and a lead shielding wall that forms a radiation detection space,
An attachment hole is formed in the shielding wall for attaching the radiation detector, and the attachment hole is shielded by lead of the attachment rod and the cylindrical block. A method for inspecting a radiation detector attached to an attachment hole provided in a shielding wall,
Arranging a radiation source holding member for holding a check radiation source behind the detection element of the radiation detector via the attachment hole side, and installing a shielding member in the attachment hole;
Detecting radiation from the check radiation source in the radiation source holding member with the detection element;
A method of inspecting a radiation detector, comprising:

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