JP5213787B2 - Radiation measurement device mockup and mockup system - Google Patents

Description

  The present invention relates to a mock-up and a mock-up system for a radiation measurement apparatus that can ascertain whether or not internal components are healthy without unsealing the radiation measurement apparatus.

  As shown in FIG. 3, the radiation measuring apparatus 20, which is a device that measures radiation, includes various parts of the radioactive material management facility 100 (for example, the radioactive material management facility 100) having a management area that handles radioactive materials such as a nuclear power plant. It arrange | positions at the storage box 110 provided in the wall (refer nonpatent literature 1, 2, 3).

  Among the radiation measuring devices, radiation is detected, and the detection result is output with a very small current such as μA or pA, or a very small current such as a preamplifier 24 that amplifies the very small current output from the detector 22. The radiation measuring apparatus 20 that operates is provided with an electronic circuit that operates with a very small current inside the radiation measuring apparatus 20.

  The detector 22 has one internal space that accommodates components necessary for the operation of the detector 22. In general, the detector 22 is installed at a position where the inspector can visually recognize in a normal posture, and is slightly above the inspector's line of sight (for example, a height in the range of about 1.8 m to 2 m from the floor). Is installed. The detector 22 is installed so as to be perpendicular to the wall. For example, some detectors are installed at the front end of a frame extending downward from the ceiling. Thus, the detector 22 is generally installed at a position where radiation can be easily measured, and is often not installed at a position suitable for opening the inside of the detector 22. In addition, the detector 22 is installed in a direction perpendicular to the pipe or installed in a manner along the pipe so that the detector 22 measures the radiation in the vicinity of the pipe.

  Since the detector 22 handles particularly minute currents such as μA and pA, the preamplifier 24 is installed near the detector 22 where the divided voltage effect is hardly affected. The size of the preamplifier 24 is, for example, about 30 cm in length, about 15 cm to 20 cm in width, and about 15 cm in thickness.

  The electronic circuit of the detector 22 and the preamplifier 24 has a structure that handles a very small current such as μA or pA. Therefore, when rust due to moisture occurs in the electronic circuit, the electrical resistance of the electronic circuit changes, and consequently the electronic circuit The flowing very small current changes greatly, and the radiation measuring apparatus cannot perform accurate radiation measurement. The preamplifier 24 is firmly assembled by a mounting means such as a bolt in a dedicated box (not shown). The dedicated box is also firmly fixed to the wall or the like by attachment means such as bolts.

  Therefore, the radiation measurement device is formed with a rigid frame so that the inside of the radiation measurement device has a sealed structure, a hygroscopic agent such as silica gel is installed inside the radiation measurement device, and the inside of the radiation measurement device is dried. Maintained in a state. Moreover, the lid | cover for putting a hygroscopic agent in the inside of a radiation measuring device is attached to the flame | frame via packing.

  Since the hygroscopic agent and packing installed inside the radiation measuring device deteriorate over time, the inspector who checks the radiation measuring device in order to stably maintain the inside of the radiation measuring device is an electronic circuit, a hygroscopic agent. It is necessary to periodically replace internal parts such as packing.

  Since the radiation measuring apparatus is formed of a solid frame, generally, the inside of the radiation measuring apparatus cannot be visually recognized. Therefore, the inspector must unravel the sealed state of the radiation measuring apparatus, take out the parts inside the radiation measuring apparatus, and then determine whether or not replacement of the parts inside the radiation measuring apparatus is necessary.

  Since the inspector cannot visually check the state of the internal components of the radiation measuring apparatus from the outside of the radiation measuring apparatus, the inspector cannot check the state of the radiation measuring apparatus even if the state of the internal parts of the radiation measuring apparatus is healthy. According to the replacement cycle, the radiation measurement device is forcibly released from the sealed state and the internal components are taken out.

  When the inspector takes out the internal components of the radiation measurement device, it is inadvertently prepared for the components that were in a healthy state by forcibly releasing the sealed state of the radiation measurement device even though it was a healthy component. May attach to excessive moisture, or may inadvertently damage or accelerate deterioration of other internal components and circuits. In particular, since the inside of radioactive material management facilities often has high humidity, in such a situation, forcibly releasing the sealed state of the radiation measurement device is a hygroscopic agent installed inside the radiation measurement device. However, it absorbs moisture inside the radioactive substance management facility, and its utility runs out earlier than the original action period of the hygroscopic agent.

http: // www. fesys. co. jp / sougou / seihin / p09 / rad. html http: // www. fesys. co. jp / sougou / seihin / p09 / pdf / CNO2100-1b. pdf http: // www. jaea. go. jp / 04 / turuga / jturuga / realtime / unchange_file / expln_1. html

  An object of the present invention is to provide a mock-up and a mock-up system for a radiation measurement apparatus that can infer whether internal components are healthy without unsealing the radiation measurement apparatus.

  The mockup of the radiation measurement apparatus according to the present invention is a mockup of the radiation measurement apparatus for inferring whether the internal components arranged in an airtight state in the internal space of the radiation measurement apparatus are healthy. The mockup of the radiation measuring apparatus has the same size as the internal space, and is continuous with the mockup internal space in which mockup components equivalent to the internal components can be arranged, and the mockup internal space. A housing portion having an opening portion, a visible window portion provided in at least a part of the housing portion, and a lid portion that is airtightly assembled to the opening portion.

  The mock-up of the radiation measuring apparatus according to the present invention may include an attaching means for attaching the lid to the opening so that the mock-up internal space is in the same state as the airtight state of the internal space.

  A mockup system for a radiation measurement apparatus according to the present invention includes a radiation measurement apparatus according to claim 1 or 2 and a mockup for the radiation measurement apparatus according to claim 1 or 2 disposed in the vicinity of the radiation measurement apparatus. And comprising.

  According to the present invention, since the mockup of the radiation measurement apparatus includes a visible window portion, the mockup arranged in the mockup internal space in a state where the inside of the mockup of the radiation measurement apparatus is maintained in a sealed state. The aging deterioration state of the parts for use can be confirmed through the window.

  Furthermore, since the mock-up internal space is provided with attachment means for attaching the lid to the opening so that the internal space for the mock-up is in the same state as the airtight state of the internal space, the internal space for mockup is substantially the same as the airtight state of the internal space Thus, the aging deterioration state of the internal parts arranged in the internal space of the radiation measuring apparatus can be estimated from the aging deterioration state of the mock-up parts.

  Furthermore, since the mockup of the radiation measurement apparatus is disposed in the vicinity of the radiation measurement apparatus, the state where the mockup of the radiation measurement apparatus is placed is close to the state where the radiation measurement apparatus is placed. Therefore, the degree of aging deterioration inside the radiation measuring apparatus can be known more accurately.

It is a schematic diagram which shows the outline | summary of the mockup and mockup system of the radiation measuring device which concern on this invention. It is a perspective view of the mockup of the radiation measuring device shown in FIG. It is a perspective view which shows the conventional radiation measuring device.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

  Referring to FIGS. 1 and 2, the mock-up system and mock-up of the radiation measuring apparatus according to the present invention according to the present invention are respectively indicated by reference numerals 10 and 30 as a whole.

  A mock-up system 10 for a radiation measurement apparatus includes a radiation measurement apparatus 20 that is a device for measuring radiation, and a radiation measurement apparatus mock-up 30 that is disposed in the vicinity of the radiation measurement apparatus 20. Is provided. The radiation measuring apparatus 20 as the present article includes a detector 22 that detects radiation and a preamplifier 24 that amplifies a very small current output from the detector 22. The preamplifier 24 of the radiation measuring apparatus 20 amplifies the very small current output from the detector 22, and the amplified current is indicated via the cable 26 in the central control room 40 installed outside the management area. Output to 42. A monitor who monitors the radioactive substance management facility 100 in the management area monitors whether the radiation amount inside the radioactive substance management facility 100 is abnormal by displaying on the indicator 42.

  Each of the detector 22 and the preamplifier 24 has an internal space of a predetermined size, and has a housing portion having an opening continuous with the internal space, and an airtight seal through the packing of the opening of the housing portion. And a lid portion to be assembled to the housing. In the internal space of the detector 22 and the internal space of the preamplifier 24, a plurality of internal parts such as an electronic circuit and a hygroscopic agent such as silica gel are accommodated.

  The mockup 30 of the radiation measuring apparatus includes a mockup detector 32 and a mockup preamplifier 34. The mockup detector 32 is a mockup of the detector 22, and the internal space of the mockup detector 32 is formed to have approximately the same size as the internal space of the detector 22. The mockup preamplifier 34 is a mockup of the preamplifier 24, and the internal space of the mockup preamplifier 34 is formed to be approximately the same size as the internal space of the preamplifier 24.

  As shown in FIG. 2, the mockup detector 32 has the same size as the internal space of the detector 22, and can mockup a mockup component 60 equivalent to the internal component of the detector 22. Internal space 50a, a housing part 50 having an opening 54 continuous with the mock-up internal space 50a, a visible window part 52 provided in at least a part of the housing part 50, and an opening part 54 and a lid portion 56 that is assembled in an airtight manner.

  The casing 50 is preferably made of the same material as that of the detector 22, but may be made of a metal such as iron or stainless steel, or a material that can be visually recognized, for example, acrylic. May be. The casing 50 has, for example, a rectangular parallelepiped shape with a hollow inside. The mockup internal space 50a preferably has substantially the same volume as the internal space of the detector 22. The mockup internal space 50a preferably has substantially the same shape as the internal space of the detector 22.

  In the illustrated example, the window 52 is provided on the side surface on the near side of the drawing. The window 52 is made of a visible material such as acrylic. The window portion 52 is a shield material such as packing and is airtightly attached to the window opening 53. The size of the window 52 is not particularly limited as long as the size of the mock-up component 60 arranged in the mock-up internal space 50a is visible.

  The opening 54 is provided in a portion corresponding to the right side surface of the casing 50 in the illustrated example.

  The lid 56 is airtightly attached to the opening 54 via the packing 58. More specifically, a housing side flange portion 51 is formed integrally with the housing portion 50 around the opening 54, and the housing side flange portion 51 has a plurality of through holes. In addition, the packing 58 has substantially the same shape as the housing-side flange portion 51, and the packing 58 has a plurality of holes at the same positions as the plurality of through holes formed in the housing-side flange portion 51. A through hole is formed. The packing 58 is preferably of the same material and shape as the packing used in the detector 22 so that the progress of the aging of the packing 58 is substantially the same as the progress of the aging of the packing of the detector 22.

  The lid portion 56 has a concave cross-sectional shape, and a lid-side flange portion 57 is formed around the concave opening. The lid side flange portion 57 has substantially the same shape as the housing side flange portion 51. A plurality of through holes are formed in the lid side flange portion 57 so as to correspond to the plurality of through holes formed in the housing side flange portion 51, respectively. In the illustrated example, the number of through holes formed in the housing side flange portion 51, the lid side flange portion 57, and the packing 58 is four so as to correspond to these four corners.

  In the illustrated example, the lid portion 56 is securely assembled by a bolt / nut 62 that penetrates the through-holes of the lid-side flange portion 57, the packing 58, and the housing-side flange portion 51. The lid portion 56 is preferably assembled to the housing unit 50 with the same structure as that of the lid portion that forms the sealed internal space of the detector 22. Since the packing 58 is sandwiched between the housing side flange portion 51 and the lid side flange portion 57, the lid portion 56 and the housing portion 50 are assembled in an airtight manner, that is, in a sealed state. The bolts and nuts 62 act as attachment means for attaching the lid portion 56 to the opening portion 54 so that the mock-up inner space 50a is in the same state as the airtight state of the inner space of the detector 22.

  Although the mockup detector 32 has been described with reference to FIG. 2, the mockup preamplifier 34 has the same structure as the mockup detector 32.

  These mockup detectors 32 prepare for mockup as follows. The mockup preparation of the mockup preamplifier 34 is the same.

  First, outside the management area, the inspector completely loosens the bolt 62, unscrews the bolt and nut, and opens the lid portion 56 of the mockup detector 32.

  Next, the inspector puts a mock-up part 60 in which the aged deterioration state is to be estimated among the parts used in the detector 22 into the mock-up internal space 50a. Examples of the mock-up component 60 include silica gel and electronic components inside the detector 22. At this time, it is preferable to arrange the mockup component 60 at a position where it can be seen from the window 52 of the mockup detector 32. Also, the mock-up component 60 is preferably the same size as the corresponding internal component of the detector 22 so that it will degrade to the same extent as the internal component of the detector 22.

  Next, the packing 58 is disposed again on the housing side flange portion 51, and the lid side flange portion 57 is further disposed on the packing 58, and the bolts and nuts 62 are securely attached so as to be in an airtight state. The bolt / nut 62 is preferably attached to the opening 54 so that the mock-up inner space 50 a is in the same state as the airtight state of the inner space of the detector 22. That is, the flange shape of the casing side flange portion 51 and the lid side flange portion 57, the material and shape of the packing 58 to be used, the number of bolts for tightening the flange, the shape, the tightening torque, and the like may be the same as those of the detector 22. preferable.

  Then, the inspector installs the mock-up detector 32 in the vicinity of the detector 22 in which the aging degradation in the management area is desired.

  As a result, the mockup detector 32 is installed in the radioactive substance management facility 100 under the same conditions as the detector 22, so the mockup arranged in the mockup internal space 50 a of the mockup detector 32. The part 60 for use deteriorates with age almost the same as the part arranged in the internal space of the detector 22. Therefore, the inspector can recognize the aged deterioration state by visually recognizing the mockup component 60 of the mockup detector 32 without touching the detector 22.

  When the mock-up component 60 is silica gel as a hygroscopic agent, the silica gel changes color when the silica gel absorbs moisture, so if the inspector sees the change in the color of the silica gel, how much has it deteriorated over time? Can be easily grasped.

  Further, since the packing 58 is sandwiched between the housing side flange portion 51 and the lid side flange portion 57, even if the aging of the packing 58 proceeds to some extent, it is difficult for the inspector to visually recognize the packing 58. However, since the performance required for the packing 58 is sealability, the inspector has completely lost its sealability, or the sealability has been impaired within the visible range. Since it is only necessary to determine whether or not the packing 58 is in progress, it may not be possible to grasp the progress of the aging of the packing 58 to some extent.

  Thus, since the mock-up 30 of the radiation measuring apparatus is provided with the visually recognizable window portion 52, the progress of the aging deterioration of the mock-up component 60 can be visually recognized through the window portion 52 visible to the inspector. It can be confirmed, the degree of aging of the corresponding internal part of the detector 22 can be inferred, and as a result, the replacement time of the internal part can be predicted.

  In addition, the inspector prepares a mockup detector 32 in which the portions other than the window portion 52 are in the same state as the detector 22, and the mockup detector 32 is placed at or near the same location as the detector 22. By installing it, the evaluation time of the detector 22 can be determined by confirming the progress of aged deterioration of the mockup component 60 of the mockup detector 32.

  In addition, although the mockup system 10 of the radiation measuring device was demonstrated as having been formed with the mockup 30 of one radiation measuring device, it is not limited to this. For example, a mock-up system for a radiation measurement apparatus has the same configuration as a radiation measurement apparatus including a detector and a preamplifier arranged at a predetermined location, and a detector of the radiation measurement apparatus arranged near the detector of the radiation measurement apparatus. A first mockup provided, and a second mockup having the same configuration as the preamplifier of the radiation measurement apparatus, and in the second mockup, members similar to the preamplifier of the radiation measurement apparatus May be arranged. As a result, the mock-up system of the radiation measurement apparatus has two mock-ups, so that it is not necessary to periodically release the sealed state of the first and second mock-ups, and the total lifetime of the radiation measurement apparatus is measured. Can do.

DESCRIPTION OF SYMBOLS 10 Radiation measuring device mockup system 20 Radiation measuring device 22 Detector 24 Preamplifier 26 Cable 30 Radiation measuring device mockup 32 Mockup detector 34 Mockup preamplifier 40 Central control room 42 Indicator 50 Mock-up part 50a Mock UP internal space 51 Housing side flange 52 Window 54 Opening 56 Lid 57 Lid flange 58 Packing 60 Mock-up parts 62 Bolt / Nut 100 Radioactive material management facility 110 Storage box

Claims (3)

A mockup of the radiation measurement device for confirming whether the internal components arranged in an airtight state in the internal space of the radiation measurement device are healthy,
A mock-up internal space having a size equivalent to the internal space and capable of arranging mock-up parts equivalent to the internal parts, and a housing part having an opening continuous to the mock-up internal space; ,
A visible window provided in at least a part of the housing;
A lid portion hermetically assembled to the opening ,
The internal components and the mock-up parts, mockups of radiation measurement device Ru silica gel der discolored by absorbing moisture.   The mockup of a radiation measurement apparatus according to claim 1, further comprising attachment means for attaching the lid portion to the opening so that the mockup internal space is in the same state as an airtight state of the internal space. The radiation measurement apparatus according to claim 1 or 2,
A mockup system for a radiation measurement apparatus, comprising: a mockup for the radiation measurement apparatus according to claim 1, which is disposed in the vicinity of the radiation measurement apparatus.

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