JP6170693B2 - Radiation dose measurement system - Google Patents

Description

  The present invention relates to a radiation dose measurement system.

  Radiation is used in various fields such as the medical field and nuclear power generation. In particular, in the medical field, radiation therapy is performed as a cancer treatment method, and treatment can be performed without cutting the cancer. Therefore, physical burden can be reduced and deterioration of life quality after surgery can be prevented. However, exposure to radiation exceeding a certain threshold value may affect the human body, so it is necessary to accurately measure the amount of radiation exposed.

  As a technique related to this, for example, Patent Document 1 discloses a technique in which a fluorescent glass element is used as a radiation dosimeter. The fluorescent glass element is made of phosphate glass containing silver ions, and the fluorescent glass element activated by irradiation with radiation is excited and emits fluorescence when irradiated with ultraviolet rays having a wavelength of 300 nm to 400 nm ( Radiophotoluminescence phenomenon). Since the intensity of the fluorescence emitted at this time is proportional to the irradiated radiation dose, the radiation dose can be measured by detecting the intensity of the fluorescence.

Japanese Patent Laid-Open No. 2003-75535

In the technique described in Patent Document 1, when placing a fluorescent glass element irradiated with radiation on a measurement magazine, an operator generally takes out the fluorescent glass element stored in the holder by tweezers and places it in the magazine. It is location. Therefore, there is a problem that it is difficult to move the fluorescent glass element and there is a possibility that the fluorescent glass element may be arranged at an incorrect position on the magazine.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a radiation dose measurement system that can easily move a glass element and prevent an error in the arrangement position of the glass element.

A radiation dose measuring system according to the present invention that achieves the above object includes a holder block that arranges a plurality of holders that respectively accommodate a plurality of glass elements irradiated with radiation, and a storage portion that stores the plurality of glass elements. A reading magazine placed in a measuring instrument that measures a radiation dose in a state where the containing unit contains a plurality of the glass elements, a plurality of the holders arranged in the holder block, and the reading magazine A radiation dose measuring system having a glass element transfer jig for transferring a plurality of the glass elements while maintaining the arrangement of the glass elements.

With the radiation dose measuring system configured as described above, the glass element can be transferred between the holder and the reading magazine while maintaining the arrangement of the glass elements by the glass element transfer jig. Therefore, it is possible to provide a radiation dose measurement system that can easily move the glass element and prevent an error in the arrangement position of the glass element.

It is the schematic which shows the radiation dose measuring system which concerns on embodiment of this invention. It is a perspective view which shows the glass element, holder, and cap which concern on this embodiment. FIG. 3A is a side view showing the holder block according to the present embodiment, and FIG. 3B is a cross-sectional view taken along line BB in FIG. It is sectional drawing which shows the state by which the glass element and the holder were hold | maintained at the holding hole of the holder block. It is a perspective view which shows the reading magazine which concerns on this embodiment. It is a top view which shows the glass element transfer jig which concerns on this embodiment. It is a front view which shows the glass element transfer jig which concerns on this embodiment. It is a perspective view which shows the measuring machine which concerns on this embodiment. It is a top view which shows the heat resistant metal tray which concerns on this embodiment. It is a top view which shows the state before and behind inserting a holder block in a holding | maintenance part. It is a top view which shows the state before and after the mounting part in which the reading magazine was mounted moves from a 2nd location to a 1st location. It is the schematic which shows a mode that a glass element slides down a 1st channel | path. It is the schematic which shows a mode that a shutter is moved only a half period, a glass element is dropped, and a glass element is accommodated in an accommodating part. It is the schematic which shows the state after the mounting part in which the reading magazine was mounted was moved from the 1st place to the 2nd place. It is a figure which shows an example of the table displayed on a display part. It is the schematic which shows a mode that a shutter is moved only a half period, a glass element is dropped, and a glass element is arrange | positioned at the obstruction | occlusion part. It is the schematic which shows a mode that a glass element slides down a 1st channel | path.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In addition, the dimension ratio of drawing is exaggerated on account of description, and may differ from an actual ratio.

  FIG. 1 is a schematic diagram showing a radiation dose measuring system 1 according to an embodiment of the present invention.

Briefly, the radiation dose measuring system 1 according to the present embodiment, as shown in FIG. 1, includes 20 holders 10 each storing a plurality of (for example, 20) glass elements G irradiated with radiation, A reading magazine 30 placed in a measuring instrument 50 for measuring a radiation dose in a state in which a containing portion 31 for containing 20 glass elements G is provided and 20 glass elements G are accommodated in the containing portion 31; Between the individual holders 10 and the reading magazine 30, a glass element transfer jig 40 for transferring the 20 glass elements G while maintaining the arrangement of the glass elements G is provided. Details will be described below.

As shown in FIG. 1, the radiation dose measurement system 1 includes 20 holders 10, a holder block 20, a reading magazine 30, a glass element transfer jig 40, a measuring device 50, a reading device 60, a control device 70, and an electric furnace 80. Have

FIG. 2 is a perspective view showing the glass element G, the holder 10 and the cap 90 according to the present embodiment.

  The glass element G is a detection element for measuring the irradiated radiation dose, and is made of phosphate glass containing silver ions. The glass element G activated by irradiation with radiation emits fluorescence when excited by irradiation with ultraviolet rays having a wavelength of 300 nm to 400 nm.

The holder 10 accommodates 20 glass elements G irradiated with radiation. As shown in FIG. 2, the holder 10 has an opening 11 formed at one end through which the glass element G can pass. Further, the other end side of the holder 10 has a D-shaped cross section by a predetermined distance, and the information M described later is attached to the first flat surface portion 13 having the D shape. In addition, a second flat surface portion 15 is provided on the other end side of the first flat surface portion 13 so as to be lowered by one step with respect to the first flat surface portion 13, and the second flat surface portion 15 includes 20 glasses. A two-dimensional code 12 in which information of serial numbers 1 to 20 corresponding to the element G is incorporated is attached. Specifically, the two-dimensional code 12 is a data matrix code or a QR code. According to this configuration, since the two-dimensional code 12 is provided on the second flat portion 15 formed one step down, it is possible to prevent the two-dimensional code 12 from being damaged. Further, the holder 10 has a pair of protrusions 14 on the outer periphery on one end side thereof, which are parallel to the first flat surface portion 13 and extend away from each other. In the present embodiment, the two-dimensional code 12 is attached to the holder 10, but the two-dimensional code 12 may be attached to the glass element G or the glass element G and the holder 10. The material of the holder 10 is, for example, a rubber material or a resin material.

The glass element G and the holder 10 are further assigned information M for associating the glass element G and the holder 10 with each other. The information M is, for example, an ID number in which serial numbers 1 to 20 are written. However, the information M is not limited to this, and may be dots or symbols having different numbers. By providing the information M, when the glass element G is dropped, the dropped glass element G can be stored in the corresponding holder 10.

The cap 90 includes a convex portion 91 that is inserted into the opening 11 of the holder 10 and a grip portion 92 that is gripped during insertion / removal. In a state in which the glass element G is housed in the holder 10, the convex portion 91 of the cap 90 by being inserted into the opening 11 of the holder 10, the glass element G is retained in the holder 10.

FIG. 3A is a side view showing the holder block 20 according to this embodiment, and FIG. 3B is a cross-sectional view taken along line BB in FIG. 3A. FIG. 4 is a cross-sectional view showing a state where the glass element G and the holder 10 are held in the holding holes 21 of the holder block 20.

The holder block 20 holds 20 holders 10. As shown in FIGS. 3 and 4, the holder block 20 includes 20 holding holes 21, a first path 22, a first grip portion 23, and a groove portion 24. The holder block 20 can be attached to and detached from the glass element transfer jig 40. The material of the holder block 20 is acrylic, for example.

The holder 10 is inserted into the holding hole 21 from the opening 11 side, and the glass element G and the holder 10 are held. For this reason, the inner diameter of the holding hole 21 is provided so that the holder 10 can slide. As shown in FIG. 3A, the holding holes 21 are arranged in a staggered manner so that the first paths 22 do not overlap each other when viewed from the direction intersecting the first path 22 in a plurality of stages (for example, two stages). ing. According to this configuration, when the holder block 20 has a certain length, the number of holder holders 20 holding the holder 10 can be earned. The holding holes 21 are provided at regular intervals of a period T in the vertical direction in FIG.

As shown in FIG. 4, the first path 22 communicates with the opening 11 of the holder 10, and the glass element G is transferred from the holder 10 to the glass element transfer jig 40 via the first path 22. The Therefore, the inner diameter of the first path 22 is provided so that the glass element G can pass therethrough. The first path 22 is provided substantially parallel to the direction in which the holder 10 is inserted into the holding hole 21.

The first grip portion 23 is gripped when the holder block 20 is attached to the glass element transfer jig 40.

A pair of projecting portions 14 is inserted into the groove portion 24. The grooves 24 are provided in two rows along the vertical direction in FIG. 3A, and the width of the grooves 24 in the horizontal direction in FIG. 3A is greater than the width of the protrusion 14 in the direction perpendicular to the first flat surface portion 13. The depth of the groove portion 24 is slightly larger than that of the holding hole 21. According to the groove portion 24 configured as described above, when the holder 10 is inserted into the holding hole 21, the insertion of the holder 10 is guided by inserting the pair of projecting portions 14 along the groove portion 24. After the insertion, since the two-dimensional code 12 provided on the second plane portion 15 faces the two-dimensional ID code reader 61 side described later, reading by the two-dimensional ID code reader 61 becomes easy.

  FIG. 5 is a perspective view showing the reading magazine 30 according to the present embodiment.

  The reading magazine 30 has a housing portion 31 that houses 20 glass elements, and is placed in a measuring instrument 50 that measures the radiation dose in a state where the housing portion 31 houses 20 glass elements G. The reading magazine 30 has a thin rectangular parallelepiped shape and can be attached to and detached from the glass element transfer jig 40. As shown in FIG. 5, the reading magazine 30 includes 20 accommodating portions 31 in which the glass elements G are accommodated and formed in parallel with the short sides, concave grooves 32 that hold both ends of the glass elements G, and the accommodating portions 31. An opening window 33 provided on the bottom surface so as to cross the central portion of the glass element G accommodated in the upper surface portion, and an upper surface portion 34 provided on the upper surface. The material of the reading magazine 30 is resin. In addition, it is not restricted to this, A heat resistant metal may be sufficient. If the material of the reading magazine 30 is a heat-resistant metal, the step of placing the heat-resistant metal tray 81 on the annealing process in the electric furnace 80 can be omitted.

  FIG. 6A is a top view showing the glass element transfer jig 40 according to this embodiment, and FIG. 6B is a front view showing the glass element transfer jig 40 according to this embodiment. .

The glass element transfer jig 40 transfers the 20 glass elements G between the 20 holders 10 and the reading magazine 30 while maintaining the arrangement of the glass elements G. As shown in FIGS. 6A and 6B, the glass element transfer jig 40 includes a holding portion 41 that holds the holder block 20 and a main body that is connected to the holding portion 41 and has a second path 421 therein. And a shutter 43 that transfers the glass element G to the housing part 31 by sliding while preventing the glass element G from falling. The glass element transfer jig 40 further includes a first portion 44 on which the reading magazine 30 is placed, and a receiving portion 31 of the reading magazine 30 placed on the placement portion 44 that can receive the glass element G. And a rail 45 that can move the mounting portion 44 from a location to a second location where the reading magazine 30 can be removed. 6A and 6B show a state in which the placement unit 44 is disposed at the second location. In FIG. 6B, the place where the placement portion 44 moves to the left along the rail 45 and the placement portion 44 contacts the first stationary portion 49 is the first place. The glass element transfer jig 40 further includes a rotating portion 46 that inclines the holding portion 41 and a base portion 47 that is connected to the holding portion 41 and the rail 45. According to this configuration, by rotating the rotation part 46, the holding part 41 is inclined, and accordingly, the main body part 42 and the shutter 43 connected to the holding part 41 are inclined. At the same time, the base portion 47 connected to the holding portion 41 is inclined, and the mounting portion 44 and the rail 45 are inclined accordingly. That is, by rotating the rotation part 46, the holding part 41, the main body part 42, the shutter 43, the mounting part 44, and the rail 45 are inclined. For this reason, the first path 22 and the second path 421 are inclined by rotating the rotation part 46 in a state where the holder block 20 is held by the holding part 41, and the 20 glass elements G are transferred. Is done by gravity. In addition, although the connection between each component of the glass element transfer jig 40 is performed by a bolt and a nut, for example, it is not limited thereto.

The holding part 41 holds the holder block 20. For this reason, the holding part 41 has a first groove 411 that is slightly larger in width and height than the holder block 20. The material of the holding part 41 is, for example, acrylic.

  The main body 42 is provided with a second path 421 therein, and the second path 421 communicates the glass element G transferred from the first path 22 with the through hole 431 of the shutter 43. The second path 421 intersects the first path 422, which is substantially parallel to the first path 22 and has a closed portion 424 having one end communicating with the first path 22 and closing the other end. The second passage 423 has one end communicating with the first passage 422 and the other end communicating with the shutter 43. The first passages 422 are provided at regular intervals of a period T in the vertical direction in FIG. The material of the main body 42 is acrylic, for example.

  The shutter 43 transfers the glass element G to the accommodating portion 31 by sliding while preventing the glass element G from falling. The shutter 43 is slid in the vertical direction in FIG. As shown in FIG. 6B, the shutter 43 is provided below the main body portion 42, and when the reading magazine 30 is set on the mounting portion 44 and the mounting portion 44 is disposed at the first location. , Provided above the accommodating portion 31. The shutter 43 has a through hole 431 formed with the same cycle T as the first passage 422. The shutter 43 is energized by a spring (not shown), and when the reading magazine 30 is set on the mounting portion 44 and the mounting portion 44 is disposed at the first place, and in a steady state, The through hole 431 is disposed at a position corresponding to the upper surface portion 34 of the reading magazine 30. At this time, the glass element G is disposed on the upper surface portion 34. In other words, the glass element G is prevented from falling. On the other hand, by sliding the shutter 43 by a half cycle T / 2, the glass element G arranged in the through-hole 431 is slid by a half cycle T / 2 and moved to a position corresponding to the accommodating portion 31 of the reading magazine 30. Therefore, the glass element G falls downward and is accommodated in the accommodating portion 31 of the reading magazine 30 (see FIG. 12). In addition, it is preferable to provide the 2nd stationary part (not shown) which makes a movement stop when the shutter 43 moves only by the half cycle T / 2. The material of the shutter 43 is, for example, acrylic.

  The placement unit 44 places the reading magazine 30 thereon. For this reason, the mounting portion 44 has a second groove 441 that is slightly larger in width and height than the reading magazine 30. The placement unit 44 includes a second grip 442 that is gripped when the placement unit 44 is moved between the first place and the second place along the rail 45. When the mounting portion 44 is disposed at the first location, the mounting portion 44 and the first stationary portion 49 are fixed by a magnet (not shown). For this reason, even when the mounting part 44 is inclined by the rotating part 46, the mounting part 44 is fixed to the first stationary part 49, and the first place can be maintained. The material of the mounting portion 44 is, for example, acrylic. The material of the rail 45 is aluminum, for example.

  The rotation unit 46 tilts the first path 22 and the second path 421. The rotation unit 46 is inserted into a through hole (not shown) provided inside the holding unit 41 and is rotated by the shaft unit 461 that rotates the holding unit 41 in synchronization with the rotation of the rotation unit 46. And a third grip 462 that is gripped to rotate the 461. In FIG. 6B, the third gripping portion 462 is omitted for clarity. The shaft portion 461 is rotatably supported by the two bearing portions 48. The material of the shaft portion 461 is, for example, iron. The material of the third grip 462 is, for example, plastic.

  The base portion 47 is connected to the holding portion 41 and the rail 45. The material of the base portion 47 is acrylic, for example.

  FIG. 7 is a perspective view showing the measuring instrument 50 according to the present embodiment.

  The measuring device 50 measures the radiation dose applied to the glass element G accommodated in the reading magazine 30. As shown in FIG. 7, the measuring device 50 includes a container 51, a reading magazine transport unit 52, an ultraviolet irradiation unit 53, and a fluorescence detection unit 54.

  The container 51 accommodates therein a reading magazine transport unit 52, an ultraviolet irradiation unit 53, and a fluorescence detection unit 54. The container 51 includes a case unit 511 in which a reading magazine transport unit 52, an ultraviolet irradiation unit 53, and a fluorescence detection unit 54 are arranged, and a cover unit 512 that covers the case unit 511. The cover unit 512 includes a first cover 513 and a second cover 514, and the inside of the first cover 513 is a dark box that covers the reading magazine transport unit 52 and the fluorescence detection unit 54. The first cover 513 is provided with an opening / closing cover 515 above the fluorescence detection unit 54.

  The reading magazine transport unit 52 transports the reading magazine 30 to the measurement position. The reading magazine transport unit 52 includes a magazine table 521 on which the reading magazine 30 is placed and a linear motion unit 522 that horizontally moves the magazine table 521. The magazine table 521 is provided with a holding member 523 for holding the reading magazine 30 and a calibration glass 524 which is a standard glass for detecting sensitivity calibration.

  The ultraviolet irradiation unit 53 irradiates the glass element G stored in the storage unit 31 of the reading magazine 30 placed on the magazine table 521 with ultraviolet light to bring the glass element G into an excited state. The ultraviolet irradiation unit 53 is disposed above the case unit 511, and a laser oscillator 531 that oscillates an ultraviolet laser. And. The laser oscillator 531 is, for example, a nitrogen gas laser that oscillates an ultraviolet laser having a wavelength of about 300 nm to 400 nm.

  The fluorescence detection unit 54 detects fluorescence generated from the glass element G when the laser oscillator 531 is irradiated with ultraviolet rays. The fluorescence detection unit 54 multiplies the fluorescence generated from the glass element G into an electrical signal and converts the photomultiplier tube 541 and the lens that collects the fluorescence generated from the glass element G and enters the photomultiplier tube 541. (Not shown).

The reading device 60 reads the two-dimensional code 12 attached to the holder 10. As shown in FIG. 1, the reading device 60 includes a two-dimensional ID code reader 61 and an LED irradiation unit 62 that irradiates the two-dimensional code 12 with LEDs. The two-dimensional ID code reader 61 is, for example, SR-D100 manufactured by Keyence Corporation.

  The control device 70 creates a table T including serial numbers obtained by reading the two-dimensional code 12 by the reading device 60. The measuring device 50 sequentially writes the measured radiation dose data in association with the serial number in the table T, and stores the table T in which the radiation dose data is written in the control device 70 as data. Then, the table T is displayed on the display unit 71 of the control device 70 by accessing the data. The display unit 71 is a display, for example.

  The electric furnace 80 removes the radiation stored in the glass element G by heating the glass element G irradiated with radiation at a predetermined temperature for a predetermined time. This process is generally referred to as an annealing process. When the annealing process is performed, the reading magazine 30 is made of resin and cannot withstand the processing temperature of the annealing process. Therefore, it is necessary to transfer the glass element G from the reading magazine 30 to the heat-resistant metal tray 81. FIG. 8 is a top view showing a heat-resistant metal tray 81. As shown in FIG. 8, the heat-resistant metal tray 81 includes a storage portion 811 for storing the glass element G, a mounting groove 812 that fits in the reading magazine 30, and a movement of the glass element G from the reading magazine 30. And a fourth gripping portion 813 for gripping. The storage portion 811 is provided so as to coincide with the storage portion 31 of the reading magazine 30 when the reading magazine 30 is fitted in the mounting groove 812.

Next, referring to FIGS. 2 and 9 to 16, 20 glass elements G irradiated with radiation after annealing are transferred from the holder 10 to the reading magazine 30 by the radiation dose measuring system 1 configured as described above. Next, a method of measuring the radiation dose applied to the glass element G, annealing the glass element G, and transferring the glass element G from the reading magazine 30 to the 20 holders 10 will be described. In FIG. 11, FIG. 12, FIG. 13, FIG. 15, and FIG. 16, for clarity, the bearing portion 48 and the third gripping portion 462 are omitted, and the glass element G is indicated by a solid line.

  First, the 20 glass elements G are heated in the electric furnace 80 for a predetermined time at a predetermined temperature and annealed. A processing time and a processing temperature when the annealing process is performed by the electric furnace 80 are, for example, 20 minutes and 400 ° C. And after measuring the radiation dose which the glass element G has potentially with the measuring device 50, the glass element G is appropriately irradiated with radiation.

Next, as shown in FIG. 2, the cap 90 is removed from the 20 holders 10 each storing the 20 glass elements G irradiated with radiation, and the holding holes of the holder block 20 are opened from the opening 11 side. 21 is inserted and held.

FIG. 9 is a top view showing a state before and after inserting the holder block 20 into the holding portion 41.

As shown in FIG. 9, the holder block 20 holding the 20 holders 10 is inserted into the first groove 411 of the glass element transfer jig 40 from the first path 22 side. After the insertion, the first path 422 of the first path 22 and the second path 421 communicate with each other. At this time, the first path 22 and the first passage 422 are substantially horizontal, and the posture of the glass element transfer jig 40 at this time is the first posture.

  FIG. 10 is a top view showing a state before and after the placement unit 44 on which the reading magazine 30 is placed moves from the second place to the first place.

  As shown in FIG. 10, the reading magazine 30 is placed on the placement portion 44 of the glass element transfer jig 40, the second gripping portion 442 is gripped, and the placement portion 44 is moved along the rail 45, as shown in FIG. It moves to the left from the second place to the first place until it hits the first stationary part 49.

  FIG. 11 is a schematic view showing a state in which the glass element G slides down the first passage 422.

As shown in FIG. 11, the 3rd holding part 462 is rotated 45 degree | times clockwise from a 1st attitude | position, and the glass element transfer jig 40 is inclined. Let the attitude | position of the glass element transfer jig 40 after an inclination be a 2nd attitude | position. At this time, 20 of the holder 10 in the 20 glass element G of which is housed respectively, from the holder 10 inside by gravity, through the first path 22, is transferred to the closed portion 424 of the first passage 422 The In addition, the angle to rotate is not restricted to 45 degree | times, The glass element G should just be transferred to the obstruction | occlusion part 424 of the 1st channel | path 422. FIG. The glass element transfer jig 40 is preferably provided with a lock mechanism so as to maintain the second posture.

  FIG. 12 is a schematic view showing a state in which the shutter 43 is moved in a direction orthogonal to the paper surface by a half cycle T / 2, the glass element G is dropped, and the glass element G is accommodated in the accommodating portion 31.

  As shown in FIG. 12, the third gripping portion 462 is rotated 45 degrees counterclockwise from the second posture, and the glass element transfer jig 40 is returned to the first posture. At this time, the glass element G disposed in the vicinity of the closing portion 424 falls through the second passage 423 and is disposed inside the through hole 431 of the shutter 43 and on the upper surface portion 34 of the reading magazine 30. . Then, the shutter 43 is moved by a half cycle T / 2 in the front direction of the drawing in FIG. As a result, the 20 glass elements G arranged on the upper surface portion 34 of the reading magazine 30 fall and are accommodated in the accommodating portion 31 of the reading magazine 30.

  FIG. 13 is a schematic diagram illustrating a state after the placement unit 44 on which the reading magazine 30 is placed is moved from the first place to the second place.

  As shown in FIG. 13, the mounting portion 44 on which the reading magazine 30 is mounted by gripping the second gripping portion 442 is moved along the rail 45 in the right direction in FIG. 9 from the first location to the second location. Move up.

  Next, the reading magazine 30 is taken out from the placement unit 44, and the reading magazine 30 is placed on the magazine table 521 of the measuring device 50. Then, the radiation dose irradiated to the glass element G is measured by the measuring device 50. Since a specific measuring method is a known technique, it is omitted here.

Next, the LED irradiation unit 62 irradiates the LED to the two-dimensional code 12 attached to the holder 10 as necessary, and the two-dimensional ID code reader 61 reads the two-dimensional code 12. Then, the control device 70 creates a table T including serial numbers obtained by reading the two-dimensional code 12 with the reading device 60. Then, the measuring device 50 sequentially writes the measured radiation dose data in association with the serial number in the table T, and stores the table T in which the radiation dose data has been written in the control device 70 as data. Then, the table T is displayed on the display unit 71 by accessing the data. FIG. 14 is a diagram illustrating an example of the table T displayed on the display unit 71. As shown in FIG. 14, the table T displays a first box B1 in which a serial number obtained by reading the two-dimensional code 12 by the two-dimensional ID code reader 61 is displayed, and radiation dose data measured by the measuring device 50. Second box B2. As shown in FIG. 14, the measurement result for 10 times, the average value (AVG), the standard deviation (SD), and the coefficient of variation (CV) for 10 times are displayed in the table T, respectively.

  Next, a metal tray 81 is disposed from the placement groove 812 side so as to cover the reading magazine 30 in which the glass element G is accommodated, and a fourth gripping unit is provided so as not to drop the integrated body of the reading magazine 30 and the metal tray 81. The glass element G accommodated in the accommodating portion 31 of the reading magazine 30 is moved to the accommodating portion 811 of the metal tray 81 by gripping and turning over 813. Then, the metal tray 81 in which the glass element G is accommodated is placed in the electric furnace 80. Then, the glass element G is heated in the electric furnace 80 for a predetermined time at a predetermined temperature and annealed. The processing time and processing temperature when performing the annealing process by the electric furnace 80 are, for example, 20 minutes and 400 ° C. In addition, the processing time when the radiation dose irradiated to the glass element G exceeds 1 Gy (gray) is preferably 1 hour.

  Next, the annealed glass element G is returned from the metal tray 81 to the reading magazine 30, and the reading magazine 30 is placed on the placement portion 44 arranged at the second location (the state shown in FIG. 13). ), The mounting portion 44 is moved to the first place along the rail 45 (state shown in FIG. 12).

  FIG. 15 is a schematic diagram showing a state in which the shutter 43 is moved by a half cycle T / 2 in a direction orthogonal to the paper surface, the glass element G is dropped, and the glass element G is accommodated in the closing portion 424.

  As shown in FIG. 15, the third grip 462 is rotated 180 degrees counterclockwise from the first posture, and the glass element transfer jig 40 is inverted from the first posture. Let the attitude | position of the glass element transfer jig 40 after inversion be a 3rd attitude | position. At this time, the glass element G is disposed inside the through hole 431 of the shutter 43 and on the main body 42. Then, the shutter 43 is moved by a half cycle T / 2 in the forward direction of the drawing in FIG. As a result, the 20 glass elements G arranged on the main body 42 fall through the second passage 423 and are arranged in the closing portion 424 of the first passage 422. The glass element transfer jig 40 is preferably provided with a lock mechanism so that the third posture can be maintained.

  FIG. 16 is a schematic diagram illustrating a state where the glass element G slides down the first passage 422 toward the holding portion 41.

As shown in FIG. 16, the third grip 462 is rotated 45 degrees clockwise from the third posture, and the glass element transfer jig 40 is tilted. The posture of the glass element transfer jig 40 at this time is defined as a fourth posture. At this time, the 20 glass elements G arranged in the closed portion 424 of the first passage 422 are separated from the closed portion 424 of the first passage 422 by gravity through the first passage 422 and the first route 22. It is stored in 20 holders 10. Note that the turning angle is not limited to 45 degrees. The glass element transfer jig 40 is preferably provided with a lock mechanism so that the fourth posture can be maintained.

  Next, the third grip 462 is rotated 135 degrees clockwise to return the glass element transfer jig 40 to the first posture.

Through the above steps, transfer from the holder 10 to the reading magazine 30, measurement of radiation dose, annealing treatment, and transfer from the reading magazine 30 to the holder 10 are sequentially performed.

As described above, the radiation dose measurement system 1 according to the present embodiment accommodates the 20 holders 10 each storing the 20 glass elements G irradiated with the radiation, and the 20 glass elements G. A reading magazine 30 placed in a measuring instrument 50 that measures the radiation dose in a state in which the containing portion 31 contains 20 glass elements G, and the 20 holders 10 and the reading magazine 30 And a glass element transfer jig 40 for transferring 20 glass elements G while maintaining the arrangement of the glass elements G. For this reason, it is possible to transfer the glass element G between the holder 10 and the reading magazine 30 while maintaining the arrangement of the glass elements G by the glass element transfer jig 40. Therefore, it is possible to provide the radiation dose measuring system 1 in which the movement of the glass element G is easy and an error in the arrangement position of the glass element G can be prevented.

Furthermore, the holder block 20 that holds the 20 holders 10 is further included. The holder block 20 and the reading magazine 30 can be attached to and detached from the glass element transfer jig 40, and the holder block 20 has one end of the holder 10. The glass element G is formed with a first path 22 that communicates with the opening 33 through which the glass element G can pass and can transfer the glass element G from the holder 10 to the glass element transfer jig 40. And a second path 421 for transferring the glass element G transferred from the first path 22 to the accommodating portion 31 of the reading magazine 30. Therefore, 20 glass elements G can be transferred via the first path 22 and the second path 421 with the holder block 20 and the reading magazine 30 attached to the glass element transfer jig 40. . Therefore, the movement of the glass element G becomes easier and an error in the arrangement position of the glass element G can be prevented more reliably.

  Further, the glass element transfer jig 40 further includes a rotating portion 46 for inclining the first path 22 and the second path 421, and the 20 glass elements G are transferred by gravity. For this reason, by rotating the rotation part 46, the 1st path | route 22 and the 2nd path | route 421 are inclined, and the glass element G is transferred. Therefore, the movement of the glass element G becomes easier.

  The second path 421 is substantially parallel to the first path 22 and has a first passage 422 having a closed portion 424 having one end communicating with the first path 22 and closing the other end. The glass element transfer jig 40 is provided between the second passage 423 and the accommodating portion 31. The second passage 423 has one end communicating with the first passage 422 and the other end communicating with the accommodating portion 31. The shutter 43 further transfers the glass element G to the accommodating portion 31 by being slid while preventing the glass element G from falling. For this reason, the movement of the glass element G becomes more accurate.

Further, the holder block 20 holds the 20 holders 10 alternately so that the first paths 22 do not overlap each other when viewed from the direction intersecting the first path 22 in two steps. For this reason, when the holder block 20 has a certain length, the number of holder blocks 20 that hold the holder 10 can be earned. In other words, when transferring the glass element G number which is determined, as compared with the case where the holder block 20 holds the holder 10 one step, it is possible to reduce the length of the holder block 20, by force the glass The size of the element transfer jig 40 can be reduced.

The holder 10 is provided with a two-dimensional code 12 in which information of serial numbers 1 to 20 corresponding to the number of 20 glass elements G is incorporated, and a reading device 60 that reads the two-dimensional code 12 and a reading device 60. Further includes a control device 70 that creates a table T including serial numbers obtained by reading the two-dimensional code 12, and the measuring device 50 associates the radiation dose data measured by the measuring device 50 with the serial numbers in the table T. Write sequentially. For this reason, it is possible to accurately associate the serial number with the radiation dose data.

The glass element G and the holder 10 are attached with information M for associating the glass element G and the holder 10 with each other. For this reason, even when the glass element G is dropped, the glass element G can be stored in the corresponding holder 10.

  Hereinafter, modifications of the above-described embodiment will be exemplified.

  The second path 421 according to the present embodiment has a first path 422 and a second path 423 that intersects the first path 422. However, the second path may be configured by a single through hole substantially parallel to the first path 22 having one end communicating with the first path 22 and the other end communicating with the accommodating portion 31. According to this configuration, the glass element G can be accommodated in the accommodating portion 31 by appropriately arranging the accommodating portion 31 so that the rotating portion 46 tilts the first path 22 and the second path. it can. Therefore, the shutter 43 can be omitted, and the movement of the glass element G becomes easier.

  Moreover, although the glass element transfer jig 40 which concerns on this embodiment transferred 20 glass elements G, it is not restricted to this, What is necessary is just to transfer 2 or more.

  Further, in the present embodiment, the first path 22 and the first path 422 are provided substantially horizontally, and the first path 22 and the first path 422 are inclined by rotating the rotating unit 46. The glass element G was transferred. However, the rotation part 46 may not be provided, and the first path and the first path may be provided to be inclined.

The glass element transfer jig 40 according to the present embodiment is provided with a first groove 411 into which the holder block 20 is inserted. However, the first groove 411 may not be provided, and a groove into which the holder 10 is directly inserted may be provided.

  Moreover, in this embodiment, the glass element G was transferred by gravity. However, it is not limited to this, and it may be transferred by electromagnetic force, elastic force, pneumatic pressure, or the like.

1 radiation dose measurement system,
10 holders ,
11 opening,
12 two-dimensional code,
20 holder blocks,
22 First route,
30 Reading magazine,
31 containment section,
40 Glass element transfer jig,
421 second route,
422 first passage,
423 second passage,
43 Shutter,
46 Rotating part,
50 measuring machine,
60 reader,
70 control device,
G glass element,
M information.

Claims (7)

A holder block for arranging a plurality of holders each storing a plurality of glass elements irradiated with radiation;
A reading magazine provided in a measuring machine for measuring a radiation dose in a state in which a plurality of glass elements are accommodated and a plurality of the glass elements are accommodated in the accommodating part;
A radiation dose measurement comprising: a glass element transfer jig for transferring the plurality of glass elements while maintaining the arrangement of the glass elements between the plurality of holders arranged in the holder block and the reading magazine. system. Before SL holder block and the reading magazine is detachable to the glass element transfer jig,
The holder block is in communication with an opening through which the glass element formed at one end of the holder can pass, and has a first path through which the glass element can be transferred from the holder to the glass element transfer jig,
2. The radiation dose measurement system according to claim 1, wherein the glass element transfer jig has a second path for transferring the glass element transferred from the first path to the housing portion of the reading magazine.   3. The radiation dose according to claim 2, wherein the glass element transfer jig further includes a rotating unit that inclines the first path and the second path, and the plurality of glass elements are transferred by gravity. Measuring system. The second path is substantially parallel to the first path, has a first passage having one end connected to the first path and a closed portion closed at the other end, and one end intersecting the first path. Has a second passage communicating with the first passage and the other end communicating with the accommodating portion,
The glass element transfer jig further includes a shutter that is provided between the second passage and the accommodating portion and that moves the glass element to the accommodating portion by sliding while preventing the glass element from dropping. The radiation dose measurement system according to claim 2 or 3.   5. The holder block according to claim 2, wherein the holder block holds a plurality of holders in a staggered manner so that the first paths do not overlap each other when viewed from a direction intersecting the first path. Radiation dose measuring system described in 1. At least one of the glass element and the holder is attached with a two-dimensional code in which serial number information corresponding to the number of the glass elements is incorporated,
A reading device that reads the two-dimensional code; and a control device that creates a table including the serial number obtained by reading the two-dimensional code by the reading device;
The radiation measuring system according to claim 1, wherein the measuring device sequentially writes radiation dose data measured by the measuring device into the table in association with the serial number.   The radiation dose measuring system according to claim 1, wherein information for associating the glass element and the holder is attached to the glass element and the holder.

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