KR101892569B1 - A movable radiation shielding device for nuclide analysis of radioactive materials - Google Patents

Abstract

The present invention relates to a mobile radiation shielding device for nuclide analysis, capable of remarkably improving the reliability of measurement, which comprises: a sample analysis enclosure; a shielding body accommodating enclosure; a plurality of shielding bodies for shielding radiation; a shielding body transfer unit; a radiation dose rate measuring device for measuring a radiation dose rate and transmitting a measurement value thereof; a high-purity germanium detector for measuring a radioactivity value; and a control unit for controlling an operation of a plurality of solenoids and a transfer plate driving motor of the shielding body transfer unit.

Description

Technical Field [0001] The present invention relates to a radioactive shielding device for nuclide analysis,

The present invention relates to a movable type radiation shielding apparatus for nuclide analysis, which can be used in the field, and more particularly, to a mobile radiation shielding apparatus for nuclide analysis, which is capable of analyzing a nuclide of a radioactive material, ≪ / RTI >

Generally, a nuclide analyzer combining a high purity germanium (HPGe) detector and a multi channel analyzer (MCA) is used to determine the nuclide of the radioactive substance emitting the radiation. In order to minimize the influence of radiation, a nuclide analysis is performed by inserting a sample to be measured in a fixed lead shield. The apparatus for analyzing nuclides of the conventional sample is used for measuring a sample having a low radiation dose.

These contents are published in Korean Registered Utility Model No. 20-0288517 (registered Aug. 28, 2002).

However, recently, it is required to use a mobile nuclide analyzer for the measurement of a sample having a high radioactivity value or a sample having a high radioactivity value when the nuclear power plant is dismantled, but it is not suitable for nuclide analysis for a sample having a high radioactivity value of the lead shield .

In the operation of the conventional nuclide analyzer, when the nuclide is analyzed for a sample having a high radioactivity value, the dead time (Dead Time, even if the next radiation is input by the pulse generated by the previous radiation, Is not counted due to the absence of start-up), the lifetime of expensive high-purity germanium detectors exposed to high radiation dose rates is shortened, and in sample analysis, due to increase in dead time, There is a problem that the reliability of the analysis result is remarkably deteriorated.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and it is an object of the present invention to provide a high purity germanium detector capable of obtaining radionuclides and radioactivity values with high radiation dose rates at the dismantling site of a nuclear power plant, The present invention is to provide a mobile radiation shielding apparatus for nuclide analysis which can securely extend the service life and sufficiently improve the reliability of measurement.

It is an object of the present invention to provide a radiation shielding apparatus for analyzing a nuclide in which a sample taken for nuclide analysis of a sample of a radioactive material is accommodated and the radioactivity value of the corresponding sample is measured, An opening and closing door which is mounted on the sample receiving opening and opens and closes the sample receiving opening, a shield operating hole formed on one side of the other side of the opening, A plurality of shielding guide protrusions protruding downward in parallel with each other in the direction of the shielding operation hole at regular intervals in front of the shielding body to guide the shielding body to be transported during transportation of the shielding body; A plurality of shielding conveying rails protruding from each other in parallel with each other, A detector assembly assembly which is formed to penetrate through a central portion of the sidewall of the sidewall of the sidewall of the body, a radiation dose rate measuring instrument mounting hole formed on one side of the sidewall of the sidewall of the sidewall of the sidewall, A sample analyzing body having a plurality of shielding conveying rails protruding from the sample analyzing body; And a plurality of shielding members formed on the bottom surface and protruding from the bottom surface of the shielding member in parallel to each other so as to be opposed to the shielding member, A guiding groove which is mutually opposed along an inward side surface portion of a protruding portion protruding upward at both opposite ends of the upper surface of the shield housing body and which is symmetrically and concave in parallel to the shield conveying hole; A shield housing body which is protruded downward in parallel with the shield conveying hole and assembled with an upper end portion of the shield body to have a guide protrusion for guiding the shield when the shield is transported and the opening portion is engaged with the shield operating hole of the sample analyzing housing; And a shielding body which is mounted on the shielding body transferring rail of the shielding body housing body and accommodated in the shielding body housing body and selectively transferred into the sample analyzing body to be radiated from the sample, A plurality of shields for shielding radiation; A plurality of operating holes formed in a plate shape so as to pass through the front end portion at predetermined intervals and a rack extending outwardly from the rear end middle portion, both end portions being assembled so as to be slidably engaged with the guide recesses of the shield housing housing body, A plurality of solenoids vertically mounted on each of the actuating balls so as to be downwardly operated through the actuating balls of the shielding plate so as to be removably assembled to the engaging holes of the shielding body, And a conveyance plate drive motor having a pinion which is engaged with a rack of the shielding plate on a rotating shaft, and which is mounted on the sample analyzing body and reciprocates the shielding plate. A radiation dose rate measuring device mounted on a mounting hole of the radiation analyzer of the sample analyzing body to measure a radiation dose rate radiated from the sample and transmit the measured value; A high purity germanium detector detachably assembled to a detector assembler of the sample analyzing body and connected to the multi-peak analyzer to measure a nuclear type radioactivity value of the sample; A plurality of solenoids of the shield conveying unit, a plurality of solenoids of the shield conveying unit, a conveying plate driving motor, and a radiation dose rate measuring unit, And a control unit for controlling the operation of the motor. The present invention can be achieved by a mobile radiation shielding apparatus for nuclide analysis.

The mobile radiation shielding apparatus for nuclear radionuclid analysis according to the present invention is characterized in that when a nuclide is analyzed for a radioactive material sample having a high radiation dose rate from disassembled waste at the dismantling site of a nuclear power facility, And when the measured radiation dose rate is above the allowable value of the high purity germanium detector, the space between the sample and the high purity germanium detector is adjusted so that the radiation dose rate irradiated by the high purity germanium detector is less than the permissible value of the high purity germanium detector The high purity germanium detector can be set to the detection position only when the radiation dose rate irradiated by the high purity germanium detector becomes less than the allowable value so that the radionuclide analysis can be performed so that the radionuclide radionuclide having the high radiation dose rate is obtained Highly affordable Not only to reliably protect the high purity germanium detector from a high radiation dose rate can substantially increase the service life, as well has an effect capable of remarkably improving the reliability of the measurement.

1 is a perspective view showing a mobile radiation shielding apparatus for nuclide analysis according to the present invention,
FIG. 2 and FIG. 3 are plan views showing the operation state of the mobile radiation shielding apparatus for nuclide analysis according to the present invention,
FIG. 4 is a perspective view illustrating a specimen analysis enclosure of a mobile radiological shielding apparatus for nuclide analysis according to the present invention,
FIG. 5 is a perspective view illustrating the configuration of a shielding body transferring unit for transferring a shielding body among mobile radiation shielding apparatuses for nuclide analysis according to the present invention,
6 to 8 are operational sectional views showing an operating state of a solenoid, a sample transfer tray unit, and a detector lifting unit of a shielding unit transferring unit among the movable type radiation shielding apparatuses for nuclide analysis according to the present invention,
FIGS. 9 to 11 are views for explaining the operation state of the shielding plate of the shielding unit transferring unit and the operation of the shielding unit transferring unit for shielding the shielding body, Fig. 3 is a cross-sectional view of the operating state,
FIG. 12 is a perspective view illustrating a configuration of a shielding body and a disposition state of the shielding unit in a mobile radiation shielding apparatus for nuclide analysis according to the present invention,
FIG. 13 is a block diagram illustrating mutual organic correlations among components connected to a control unit and a control unit of a mobile radiation shielding apparatus for nuclide analysis according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

Prior to this, terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms, and the inventor should appropriately interpret the concepts of the terms appropriately It should be interpreted in accordance with the meaning and concept consistent with the technical idea of the present invention based on the principle that it can be defined.

Therefore, the embodiments described in the present specification and the configurations shown in the drawings are only the most preferred embodiments of the present invention, and not all of the technical ideas of the present invention are described. Therefore, It should be understood that various equivalents and modifications may be present.

The movable type radiation shielding apparatus 10 for nuclide analysis according to the present invention will be described with reference to FIGS. 1 to 5, 12, and 13 attached hereto.

A portable radiation shielding apparatus 10 for nuclide analysis according to the present invention includes a sample analyzing housing 20, a shield housing 30, a plurality of shielding bodies 40, a shielding body transferring unit 50, Unit 60, a high purity germanium detector 80, a detector lifting unit 90, and a control unit 100. [

The sample analyzing housing 20 is a housing having a sample receiving opening 21 formed at one end side of an upper surface thereof and includes an opening / closing door 22, a shielding body operating hole 23, a plurality of shielding body guiding projections 24, A plurality of shielding conveying rails 25, a sample conveying rail 26, a sample conveying rack 27, a detector assembler 28, a radiation dose rate measuring instrument mounting hole 29 and a plurality of shielding conveying rails 25 .

The opening / closing door 22 is hingedly mounted on the sample receiving opening 21 so as to be vertically rotatable, thereby opening / closing the sample receiving opening 21.

The shielding operation hole 23 is formed on the other side of one side of the sample analyzing housing 20.

The plurality of shield guiding protrusions 24 protrude downward in parallel with each other in the direction of the shielding operation hole 23 at regular intervals on the inner ceiling surface of the section where the shielding operation holes 23 are formed, To guide the shield 40 to be transported.

The plurality of shield conveying rails 25 protrude from the bottom surface of the section where the shielding operation hole 23 of the sample analyzing body 20 is formed so as to be opposed to the shielding guide protrusion 24 and parallel to each other.

The sample transfer rail 26 is protruded along the longitudinal direction in the middle portion of the inner bottom surface of the sample analyzing housing 20.

The sample transfer rack 27 is formed to protrude in parallel between the sample transfer rails 26.

The detector assembler 28 is formed to pass through the central portion of the end surface of the sample analyzing housing 20 on the side of the shield operating hole 23.

The radiation dose rate measuring instrument mounting hole 29 is formed through one side of the end surface of the shielding member operating hole 23 of the sample analyzing body 20.

The plurality of shield conveying rails 25 are protrudingly formed on the inner bottom surface of the sample analyzing housing 20 on the side of the shielding operation hole 23 at regular intervals in the horizontal direction.

The shield housing housing body 30 is an enclosure having one side opened and has a plurality of shielding body transporting holes 31, a plurality of shielding body transporting rails 32, guide grooves 33 and a guide protrusion 34 A plurality of the shielding bodies 40 housed in the inside of the shielding body 30 and the shielding body 30 are inserted into the inner space of the sample analyzing housing 20 and the shielding housing body 30 through the opening portion and the shielding operation hole 23 of the sample analyzing housing 20 The open portion is engaged with the shield operating hole 23 of the sample analyzing housing 20 so as to be reciprocally transported.

The plurality of shielding body transporting holes 31 are formed in the upper surface of the shielding housing body 30 and extend in parallel to each other in the direction of the shielding operation hole 23 with a predetermined width.

The plurality of shield conveying rails 32 are formed on the bottom surface of the shield housing body 30 so as to protrude in parallel to each other so as to face the shield body transfer hole 31.

The guide grooves 33 are formed symmetrically and concave in parallel with the shield conveying holes 31 along opposite inward side portions of protrusions protruding upward from opposite ends of the upper surface of the shield housing body 30.

The guide protrusion 34 protrudes downward in parallel with the shield conveying hole 31 on the inner ceiling surface of the shield housing body 30 and is assembled with the upper end of the shield body to guide the shield body at the time of conveyance of the shield body. (34)

6 and 10 to 12, the plurality of shielding bodies 40 are plate-shaped and have a latching hole 41 formed at one end of the upper end surface of the shielding body 40 so as to be concave, and the sample analyzing body 20 and the shielding housing body And a rail wheel member 40a mounted in a rolling manner on the shield conveying rails 25 and 32 of the shielding body housing body 30 and selectively transported into the sample analyzing housing 20 Thereby shielding radiation emitted from the sample.

The shield 40 includes a plurality of gamma ray shielding plates 42 and 43 including a plate-like betaine shielding plate 44, a plurality of iron plate shielding plates 42 and a plurality of lead shielding plates 43 And shielding plates 42b and 43b having through holes 42c and 43c are alternately disposed at the central portion of the iron shielding plate 42 and the lead shielding plate 43. [

The thicknesses of the iron shielding plate 41 and the solder shielding plate 42 are different from each other and the diameters of the through holes 41c and 42c are set so as to become smaller toward the high purity germanium detector 80 side.

The shielding conveying unit 50 includes a shielding plate 51, a plurality of solenoids 52 and a conveying plate driving motor 53. The shielding conveying unit 50 is provided on the upper surface of the sample analyzing housing 20 and the shielding housing body 30, Respectively.

The shield plate 51 is formed in a plate shape and has a plurality of operation holes 51a formed at predetermined intervals along the front end portion and a rack 51b extending outwardly in the rear end middle portion, (30) so that the shield (40) can be slidably engaged with the guide groove (33) of the shield body housing body (30).

The plurality of solenoids 52 are operated downward through the operating holes 51a of the shield plate 51 so that the actuating shafts can be detachably attached to the engaging holes 41 of the shield 40. [ And is vertically mounted on the hole 51a.

The conveyance plate driving motor 53 has a pinion 53a which engages with a rack 51b of the shield plate 51 on the rotating shaft and is mounted on the sample analyzing housing 20 to guide the shield plate 51 So that the shielding body 40 is selectively reciprocated so that one or more shielding bodies 40 housed inside the shielding body housing body 30 are selected and transferred to the inside of the sample analysis housing body 20, The shielding body 40 transferred to the inside of the sample analyzing housing 20 is returned to the inside of the shielding housing body 30 again.

2, 3, 5, 6, and 9 to 11, the shield conveying unit 50 having such a configuration is mounted on a plurality of operation holes 51a formed through the front end portion, respectively The solenoid 52 is controlled to be operated downward under the control of the control unit 100 so that the operating shaft passes through the operating hole 51a and the shielding hole 31 to be engaged with the engaging hole 41 The shield plate 51 is housed in the shield housing 52 in accordance with the forward and backward rotation of the drive plate drive motor 53 in which the pinion 53a of the rotary shaft is engaged with the rack 51b of the shield plate 51, The shielding body 40 in which the actuating shaft of the solenoid 52 and the engaging hole 41 are assembled is guided by the shield plate 51, The shielding body transporting rails 25 and 32 of the sample analyzing housing 20 and the shielding housing body 30 are connected to the sample analyzing housing 20, La samples enclosure 20 and operates in the transfer area of the inner shield holder body 30.

6 to 9, the sample transfer tray unit 60 includes a tray 61 for mounting the sample 200, a rail wheel member 61a, a sample transfer drive motor 62 And a sample transporting rail (not shown) in the sample analyzing housing 20 is provided with a sample to be measured mounted on the upper side of the tray 61 from the inside of the sample analyzing housing 20 along the sample transporting rail 26 26). ≪ / RTI >

The tray 61 is mounted in parallel on both sides of the lower surface of the tray 61 and the sample transport driving motor 62 is mounted on the rotating shaft And is mounted between the rail wheel members 61a so that the sample transfer tray unit 60 is transferred along the sample transferring rail 26 in accordance with normal and reverse rotations and has a pinion 62a engaged with the sample transfer rack 27. [

The sample transfer tray unit 60 having such a configuration is rotatably mounted on a sample transferring rail 26 of the sample analyzing housing 20 and is rotatably mounted on a rotating shaft of a sample transfer tray 27 Purity germanium detector 80 while being driven to move along the sample transporting rail 26 in accordance with the forward and reverse rotation of the sample transporting drive motor 62 having the tray 61 And adjusts the radiation dose rate radiated from the sample (200) mounted on the sample (200).

The radiation dose rate measuring instrument 70 is mounted on the radiation dose rate measuring instrument mounting hole 29 of the sample analyzing housing 20 to measure a radiation dose rate radiated from the sample 200 and transmit the measured value.

The high purity germanium detector 80 is detachably assembled to the detector assembler 28 of the sample analyzing body 20 and connected to the multi-peak analyzer to detect the nuclear type radioactivity value of the sample.

1 to 3 and 6 to 8, the detector lifting unit 90 includes a plurality of horizontal support rods 91, a transfer plate 92, a detector support 93, a first solenoid 94 and a second solenoid 95 and is disposed outside the detector assembler 28 of the sample analyzer 20 to remove the high purity germanium detector 80 from the detector assembler 28, And assembled into the detector assembler 28.

The plurality of horizontal support rods 91 are arranged parallel to each other.

The transfer plate 92 is assembled with the horizontal support rods 91 so as to reciprocate along the horizontal support rods 91.

The detector support 93 has a detector mounting portion 93a at its upper end and a lower end hinged on the conveying plate 92 so as to be rotatable.

The first solenoid 94 is mounted on the horizontal support rod 91 to reciprocate the conveyance plate 92 along the horizontal support rod 91.

The second solenoid 95 is mounted on the conveying plate 92 to rotate the detector support 93.

The detector lifting unit 90 having such a configuration can be damaged if exposure of the high purity germanium detector 80 to radiation in a state where the radiation dose rate radiated from the sample 200 is not adjusted below the allowable use level , It is assembled to the detector assembler 28 of the sample analyzing body 20 only when the radiation dose rate measured by the radiation dose rate measuring device 70 is less than the allowable value of the high purity germanium detector 80, The high purity germanium detector 80 is removed from the detector assembler 28 of the sample analyzing body 20 so as not to be exposed to an excessive radiation dose rate.

13, the control unit 100 includes a plurality of solenoids 52 and a conveyance plate driving motor 53 of the shield conveyance unit 50, a sample conveyance drive motor 62 of the sample conveyance tray unit 60, ), A radiation dose rate measuring device (70), and a first and a second solenoid (94, 95) of the detector lifting unit (90) A plurality of solenoids 52 of the shielding conveying unit 50, a conveying plate driving motor 53, a sample conveying drive motor 62 of the sample conveying tray unit 60, And controls the operation of the first and second solenoids 94 and 95.

The mobile radiation shielding apparatus 10 for nuclide analysis according to the present invention having the above-described structure may be configured such that the high-purity germanium detector 80 detects the nuclide of the sample analyzing body 20 are removed from the detector assemblies 28 of the detector.

In order to perform nuclide analysis on the sample 200 collected using the portable radiation shielding apparatus 10 for nuclide analysis according to the present invention, the opening / closing door 22 is opened to set the sample 200 Is placed on a tray (61) of a sample transfer tray unit (60) disposed inside the sample analysis housing (20), and the opening / closing door (22) is closed.

When the sample 200 is disposed as described above, the radiation dose rate value radiated from the sample 200 by the radiation dose rate measuring instrument 70 is measured. As a result of the measurement, if the measured value is less than the set allowable value of the high purity germanium detector 80, the control unit 100 immediately controls the operation of the detector lifting unit 90 to detect the high purity germanium detector 80 The high purity germanium detector 80 assembled in the detector assembler 28 of the sample analyzing body 20 measures the nuclear type radioactivity value of the sample 200.

If the radiation dose rate of the sample is measured by the radiation dose rate measurer 70 and the measured value is equal to or greater than the allowable use limit value set by the high purity germanium detector 80, the controller 100 sets the radiation dose rate of the measured sample Purity germanium detector 80 to determine the type and number of the shielding body 40 and the distance between the sample and the high purity germanium detector 80 for adjusting the radiation dose rate to an appropriate radiation dose rate, The solenoid 52 of the shielding body transfer unit 50 corresponding to the shielding body 40 is operated to operate the operation shaft of the corresponding solenoid 52 downward to assemble with the locking hole 41 of the shielding body 40, The board drive motor 53 is driven to transfer the shielding body 40 in the shield housing body 30 to the inner space of the sample analysis housing 20 to shield the sample, Control the operation of the sample transfer tray unit 60 to transfer the sample 200 to the determined position and then control the operation of the detector lifting unit 90 to transfer the high purity germanium detector 80 to the sample analysis tray (28) of the detector (20) to measure the nuclear type radioactivity value of the sample.

By performing nuclide analysis on the sample 200 collected according to the above operation, the mobile radiation shielding apparatus 10 for analyzing nuclides according to the present invention can detect a radioactive material having a high radiation dose rate even when a high purity germanium detector 80) and the nuclide analysis for the sample 200 without excessive dead time can be performed quickly and accurately.

As described above, the present invention has been described with reference to particular embodiments, such as specific elements, and specific embodiments and drawings. However, it should be understood that the present invention is not limited to the above- And various modifications and changes may be made thereto by those skilled in the art to which the present invention pertains.

Accordingly, the spirit of the present invention should not be construed as being limited to the embodiments described, and all of the equivalents or equivalents of the claims, as well as the following claims, belong to the scope of the present invention .

10: Mobile Radiation Shielding Device for Nuclide Analysis
20: sample analysis housing 30: shield housing housing body
40: Shielding unit 50: Shielding unit
60: sample transfer tray unit 70: radiation dose rate measuring instrument
80: High purity germanium detector 90: Detector lifting unit
100: control unit 200:

Claims (5)

A radioactive ray shielding apparatus for analyzing a nuclide for storing a sample collected for nuclide analysis of a sample of a radioactive substance and measuring the radioactivity value of the nuclear sample of the sample,
The radiation shielding apparatus (10)
(22) that is mounted on the sample receiving port (21) and opens and closes the sample receiving port (21), and a through hole (22) formed on the other side of the sample through hole And a shielding member 23 which is formed to protrude downward and parallel to the shielding member operating hole 23 at predetermined intervals on the inner ceiling surface of the shielding member operating hole 23, A plurality of shielding guide protrusions 24 for guiding the shielding body 40 to be transported during the transportation of the shielding body 40 and a plurality of shielding protrusions 24 protruding in parallel to the shielding guide protrusions 24 on the bottom surface of the section in which the shielding operation holes 23 are formed A detector assembler 28 penetratingly formed at a central portion of the end surface of the shielding member operation hole 23 and a radiation dose rate measuring instrument mounting hole 28 penetratingly formed on one side of the end surface of the shielding member operating hole 23, (29), a shielding member Ball 23 samples housing 20 having a plurality of shield transfer rail 25 that certain side in the lateral direction interval on the inner bottom surface jyeosyeo protrusion formed in equilibrium with each other;
A plurality of shielding member transfer holes 31 formed in the upper surface in a direction parallel to each other and extending in the direction of the shielding member operating hole 23; A plurality of shielding conveying rails 32 protruding in parallel to each other and a plurality of shielding conveying rails 32 facing each other along inward side portions of protrusions formed upwardly at opposite ends of the upper surface of the shield housing body 30, 31), a guide groove (33) formed concavely and symmetrically in parallel to the shielding member (31), and a guide groove (33) projecting downwardly in parallel with the shielding member transfer hole (31) on the inner ceiling surface and assembled with the upper end of the shielding member A shield housing body 30 having an opening portion that is engaged with the shield operating hole 23 of the sample analyzing housing 20;
And is mounted on the shielding conveying rails 25 and 32 of the sample analyzing housing 20 and the shielding housing housing body 30 so that the shielding housing housing body A plurality of shields (40) housed in the sample analyzing chamber (30) and selectively shielding the radiation emitted from the sample by being transferred into the sample analyzing enclosure (20);
And a rack 51b extending outwardly in the middle of the rear end portion. The both ends of the operating hole 51a are formed in the guide groove 51a of the shield housing body 30, A shield plate 51 which is assembled so as to be slidably engaged with the shield plate housing member 33 and which transports the shield plate 40 in the shield housing body 30 and a lower shield plate 51 which is operated downward through an operation hole 51a of the shield plate 51 A plurality of solenoids 52 vertically mounted on each of the actuating holes 51a so that the actuating shaft is removably assembled to the engaging hole 41 of the shielding body 40, And a conveyance plate driving motor 53 having a pinion 53a which is engaged with the rack 51b of the rack 51b and which is mounted on the sample analyzing housing 20 and reciprocates the shield plate 51. [ )and;
A radiation dose rate measuring instrument 70 mounted on the radiation dose rate measuring instrument mounting hole 29 of the sample analyzing body 20 to measure the radiation dose rate radiated from the sample and transmit the measured value;
A high purity germanium detector 80 detachably assembled to the detector assembler 28 of the sample analyzing body 20 and connected to the multi-peak analyzer to measure the nuclear radioactivity value of the sample;
A radiation dose rate meter 70 electrically connected to the plurality of solenoids 52 of the shielding unit transfer unit 50 and the conveyance plate driving motor 53 and the radiation dose rate meter 70, And a control unit (100) for controlling the operation of the plurality of solenoids (52) and the conveyance plate driving motor (53) of the shielding conveyance unit (50)
The method according to claim 1,
The shield (40)
A plate-shaped beta ray shielding plate 44;
A plurality of gamma ray shielding plates 42 and 43 including a plurality of iron shielding plates 42 and a plurality of solder shielding plates 43;
Shielding plates 42b and 43b having through holes 42c and 43c are alternately disposed at the central portion of the iron shielding plate 42 and the lead shielding plate 43;
Wherein the thicknesses of the iron shielding plate and the lead shielding plate are different and the diameters of the through holes are smaller toward the high purity germanium detector. Radiation shielding device.
The method according to claim 1,
The sample analyzing body (20)
A sample transferring rail (26) protruding along the longitudinal direction at an intermediate portion of the bottom surface of the inner space in which the sample is stored;
A sample transporting rack 27 protruding in parallel between the sample transporting rails 26;
A tray 61 on which a sample to be measured is mounted on an upper surface thereof and a rail wheel 61 mounted parallel to both sides of the lower surface of the tray 61 and rolling on the sample transporting rail 26, And a sample transport driving motor 62 having a pinion 62a engaged with the sample transporting rack 27 on the rotating shaft and mounted between the rail wheel members 61a on the lower surface of the tray 61 And a sample conveyance tray unit 60 for conveying the sample 200 along the sample conveyance rail 26 in the sample analyzing body 20 while the sample to be measured is mounted on the upper surface of the tray 61 ;
The control unit (100)
And the operation of the sample transport driving motor (62) is controlled by being electrically connected to the sample transport driving motor (62) of the sample transport tray unit (60).
The method of claim 1,
The plurality of shields (40)
The shielding body 20 abuts against the shield conveying rails 25 and 32 on the lower end surfaces thereof so that the sample analyzing housing 20 and the shield housing body 30 can be smoothly conveyed on the shield conveying rails 25 and 32, And an operating rail wheel member (40a) for operating the radionuclide.
The method according to claim 1,
The radiation shielding apparatus (10)
A transfer plate 92 reciprocating along the horizontal support rod 91 and a detector mounting portion 93a at an upper end thereof and a lower end mounted on the transfer plate 92 A first solenoid 94 mounted on the side of the horizontal support rod 91 to reciprocate the conveyance plate 92 along the horizontal support rod 91, And a second solenoid 95 mounted on the plate 92 for pivotally operating the detector support 93. The second solenoid 95 is disposed outside the detector assembler 28 of the sample analyzer 20 and has a high purity germanium detector 80 A detector lifting unit (90) that removes or assembles the detector assembly (28) from the detector assembler (28);
The control unit (100)
Characterized in that the operation of the first and second solenoids (94, 95) is electrically connected to the first and second solenoids (94, 95) of the detector lifting unit (90) Movable type radiation shielding device.

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