JP2014228293A - Radiation shield panel mounting jig and radiation shield panel mounting method using radiation shield panel mounting jig - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a radiation shield panel mounting jig and a radiation shield panel mounting method using the same capable of preventing a radiation from leaking from a radiation generating source and setting a radiation shield panel forming a radiation shield wall flush with each other.SOLUTION: A radiation shield panel mounting jig 10 is constituted of a first joint corresponding plate 12, a second joint corresponding plate 14, and a corner part corresponding plate 16. Both end parts of the first joint corresponding plate 12 are formed with corner corresponding plate first housing parts 24, and both end parts of the second joint corresponding plate are formed with corner part corresponding plate second housing parts 30. A corner part corresponding plate housing part 32 formed by fixing the first joint corresponding plate 12 and the second joint corresponding plate 14 in a lattice-shape is disposed with the corner part corresponding plate 16.

Description

  The present invention provides a radiation shielding panel mounting tool and a radiation shielding panel mounting tool for mounting the radiation shielding panel in the case of providing a radiation shielding wall comprising a radiation shielding panel installed inside a wall or ceiling surrounding a radiation generation source. The present invention relates to a radiation shielding panel mounting method used.

Radiation shielding walls are provided inside walls and ceilings surrounding radiation sources such as radiation rooms of hospitals where X-ray equipment and CT equipment are installed to prevent leakage of radiation to the outside. (Patent Document 1).
Although there are various types of structures of the radiation shielding wall, there is a radiation shielding wall formed by fixing the radiation shielding panel 1 in a planar shape as shown in FIG.
The radiation shielding panel 1 is formed by fixing a rectangular lead plate 1B having the same area as the veneer plate 1A to a back surface of the rectangular veneer plate 1A by an appropriate fixing means such as an adhesive.
As shown in FIG. 8, when the radiation shielding wall 2 is formed using the radiation shielding panel 1, the radiation shielding panel adjacent to the radiation shielding panel mounting plate 3 as the radiation shielding panel mounting portion already formed. 1st end surface 1C of 1 and 1st end surface 1C of the radiation shielding panel 1, 2nd end surface 1D of the adjacent radiation shielding panel 1, and 2nd end surface 1D of the radiation shielding panel 1 are contact | abutted, and many radiation shielding panels 1 are contact | abutted. Is fixed to the radiation shielding panel mounting plate 3 in a planar shape to form the radiation shielding wall 2.
However, even if the first end face 1C of the radiation shielding panel 1 and the first end face 1C of the radiation shielding panel 1 and the second end face 1D of the radiation shielding panel 1 and the second end face 1D of the radiation shielding panel 1 are brought into close contact with each other, the joint portion 4 leaks radiation.
Therefore, in order to prevent leakage of the radiation, a strip-shaped lead plate 5 is fixed in a lattice shape to the radiation shielding panel mounting plate 3 corresponding to the joint portion 4 of the radiation shielding panel 1, and then the radiation shielding panel 1 is used. Are continuously fixed to the radiation shielding panel mounting plate 3 to prevent radiation from leaking to the outside from the joint portion 4 of the radiation shielding panel 1.
However, since the lead plate 5 and the lead plate 5 overlap each other at the lead plate intersection 6 where the lead plate 5 and the lead plate 5 intersect, the lead plate intersection 6 is raised.
As a result, when the radiation shielding panel 1 is fixed to the radiation shielding panel mounting plate 3 by appropriate fixing means, the portion of the radiation shielding panel 1 corresponding to the lead plate intersection 6 is raised, and the surface of the radiation shielding panel 1 is fixed flush. There is a problem that the interior work of the radiation shielding wall 2 performed after fixing the radiation shielding panel 1 is hindered or the appearance quality is deteriorated.

JP-A-6-294895

  An object of the present invention is to provide a radiation shielding panel fixture capable of preventing radiation from leaking from a wall or ceiling surrounding a radiation generation source and fixing the radiation shielding panel forming the radiation shielding wall to be flush with each other. A radiation shielding panel mounting method using a shielding panel mounting tool is provided.

The invention of claim 1 is a radiation shielding panel fixture comprising a first joint correspondence plate, a second joint correspondence plate, and a corner portion correspondence plate,
A first joint-corresponding plate formed in a strip shape with a radiation shielding material, a corner-corresponding plate first accommodating portion formed on each end of the first joint-corresponding plate, and a first strip formed in a strip shape with a radiation shielding material A second joint correspondence plate, a corner correspondence plate second accommodation portion formed at each end of the second joint correspondence plate, the corner correspondence plate first accommodation portion, and the corner correspondence plate second accommodation portion; The corner-corresponding plate accommodating portion is formed, and the corner-corresponding plate is accommodated in the corner-corresponding plate accommodating portion and is formed of a radiation shielding material.
The invention of claim 2 is a radiation shielding panel mounting tool comprising a first joint corresponding plate, a second joint corresponding plate, and a corner portion corresponding plate,
A first shielding plate body formed in a strip shape with a radiation shielding material constituting the first joint corresponding plate, and the first shielding plate body and the first joint correspondence plate are configured and mounted on the first shielding plate body. A belt-shaped first plate body fixed and fixed, a corner-corresponding plate first accommodating portion formed at each end of the first joint-corresponding plate, and a radiation shielding material constituting the second joint-corresponding plate A second shielding plate body formed on the second shielding plate body, a belt-like second plate body that constitutes the second shielding plate body and the second joint plate, and is placed and fixed on the second shielding plate body, Formed by a corner-corresponding plate second accommodating portion formed at both ends of the joint joint corresponding plate, the corner-corresponding plate first accommodating portion, and the corner-corresponding plate second accommodating portion. And the corner portion corresponding plate accommodating part which is characterized with corner corresponding plate made of a radiation shielding material, to become a while being accommodated in the corner corresponding the plate accommodating section.
The invention of claim 3 is a radiation shielding panel mounting method using a radiation shielding panel mounting tool comprising a first joint corresponding plate, a second joint corresponding plate, and a corner portion corresponding plate,
Radiation shielding is performed by continuously connecting the first joint-corresponding plates in a straight line so that the end faces of the adjacent first joint-corresponding plates abut on the first joint-corresponding plates having the corner-corresponding plate first accommodating portions formed at both ends. A first step of fixing to the panel mounting portion;
The end face of the second joint corresponding plate having the corner corresponding plate second accommodating portions formed at both ends is brought into contact with the corner corresponding plate first accommodating portion of the first joint corresponding plate, and the first joint corresponding plate A second step of fixing the second joint corresponding plate to the radiation shielding panel mounting portion in a grid with the first joint corresponding plate fixed to the radiation shielding panel mounting portion so as to be orthogonal;
A third step of accommodating a corner-corresponding plate formed of a radiation shielding material in a corner-corresponding plate container formed by the corner-corresponding plate first container and the corner-corresponding plate second container;
The radiation shielding panel is appropriately fixed by a fixing means with the first end face of the radiation shielding panel corresponding to the first joint correspondence plate and the second end face of the radiation shielding panel corresponding to the second joint correspondence plate. And a process.
The invention of claim 4 is a radiation shielding panel mounting method using a radiation shielding panel fixture comprising a first joint corresponding plate, a second joint corresponding plate, and a corner portion corresponding plate,
Radiation shielding is performed by continuously connecting the first joint-corresponding plates in a straight line so that the end faces of the adjacent first joint-corresponding plates abut on the first joint-corresponding plates having the corner-corresponding plate first accommodating portions formed at both ends. A first step of fixing to the panel mounting portion;
The end face of the second joint corresponding plate having the corner corresponding plate second accommodating portions formed at both ends is brought into contact with the corner corresponding plate first accommodating portion of the first joint corresponding plate, and the first joint corresponding plate A second step of fixing the second joint corresponding plate to the radiation shielding panel mounting portion in a grid with the first joint corresponding plate fixed to the radiation shielding panel mounting portion so as to be orthogonal;
The radiation shielding panel is appropriately fixed by a fixing means with the first end face of the radiation shielding panel corresponding to the first joint correspondence plate and the second end face of the radiation shielding panel corresponding to the second joint correspondence plate. Process,
A fourth step of accommodating a corner-corresponding plate formed of a radiation shielding material in a corner-corresponding plate container formed by the corner-corresponding plate first container and the corner-corresponding plate second container;
It is characterized by consisting of.
The invention according to claim 5 is characterized in that at least the first shielding plate body and the second shielding plate body have the same thickness.

The radiation shielding panel fixture of this invention has the outstanding effect that a radiation shielding panel can be attached flush.
The attachment method of the radiation shielding panel using the radiation shielding panel attachment of the present invention has an excellent effect that the radiation shielding panel can be easily attached to the radiation shielding panel attachment portion.

It is a whole perspective view of a radiation shielding panel fixture. It is the front view which fixed the 1st joint corresponding | compatible plate and the 2nd joint corresponding | compatible plate of the radiation shielding panel fixture in the grid | lattice form. It is the front view which fixed the 1st joint corresponding | compatible plate, the 2nd joint corresponding | compatible plate, and the corner | angular part shielding plate of the radiation shielding panel fixture. It is a front view of the state which attached the radiation shielding panel to a part of fixed radiation shielding panel fixture. It is a front view of the state which attached many radiation shielding panels to the fixed radiation shielding panel fixture. It is the front view which fixed the radiation shielding panel to the 1st joint corresponding | compatible plate and 2nd joint corresponding | compatible plate of a radiation shielding panel fixture. It is a perspective view of a radiation shielding panel. It is a front view of the state which attached the radiation shielding panel in the prior art example.

  Examples of the best mode for carrying out the invention are shown below.

Hereinafter, an embodiment of the radiation shielding panel fixture of the present invention will be described.
As shown in FIG. 1, the radiation shielding panel fixture 10 of the present invention includes a first joint correspondence plate 12, a second joint correspondence plate 14, and a corner portion correspondence plate 16.
The first joint corresponding plate 12 is formed by adhering a first plate body 22 formed of a band-like plywood plate on an adhesive layer on a first shielding plate body 20 formed of a lead as a radiation shielding material. Has been. The length dimension L1 of the first shielding plate body 20 is longer than the length dimension L2 of the first plate body 22. Thus, corner corresponding plate first accommodating portions 24 and 24 are formed at both ends of the first joint corresponding plate 12. The length dimension L3 of these corner | angular part corresponding | compatible plate 1st accommodating parts 24 and 24 is set to the same length dimension. The width dimension W1 of the first shielding plate body 20 and the width dimension W2 of the first plate body 22 are set to the same width dimension.
Further, the thickness dimension T1 of the first shielding plate body 20 and the thickness dimension T2 of the first plate body 22 are set to the same thickness dimension.
The second joint plate 14 is formed by adhering a second plate body 28 formed of a belt-like plywood plate onto a second shielding plate body 26 formed of lead as a radiation shielding material. Has been. The length dimension L4 of the second shielding plate body 26 is longer than the length dimension L5 of the second plate body 28. Thus, corner corresponding plate second accommodating portions 30 and 30 are formed at both ends of the second joint corresponding plate 14. The length dimension L6 of these corner | angular part corresponding plate 2nd accommodating parts 30 and 30 is set to the same length dimension. The width dimension W3 of the second shielding plate body 26 and the width dimension W4 of the second plate body 28 are set to the same width dimension. Further, the width dimension W3 of the second shielding plate body 26 is set to a dimension twice as long as the length dimension L3 of the corner-corresponding plate first accommodating part 24.
The wall thickness T3 of the second shielding plate body 26 and the wall thickness T4 of the second plate body 28 are formed to have the same wall thickness.
The thickness T1 of the first shielding plate body 20, the thickness T2 of the first plate body 22, the thickness T3 of the second shielding plate body 26, and the thickness dimension of the second plate body 28. T4 is set to the same wall thickness.
The corner-corresponding plate 16 is formed in a rectangular shape of lead as a radiation shielding material. The length L7 of the corner corresponding plate 16 is a dimension obtained by adding the width dimension W1 of the first shielding plate body 20 and a length dimension twice as long as the length L6 of the corner corresponding plate second accommodating portion 30. Is set to Further, the width dimension W5 of the corner corresponding plate 16 is set to the same width dimension as the width dimension W3 of the second shielding plate body 26. The thickness T5 of the corner corresponding plate 16 is set to the same thickness as the thickness T2 of the first plate body 22 and the thickness T4 of the second plate body 28.
The first joint corresponding plate 12 is disposed along the first end face 1C of the radiation shielding panel 1, and the second joint corresponding plate 14 is disposed along the second end face 1D of the radiation shielding panel 1. It is like that. The corner corresponding plate 16 is arranged at the corner of the radiation shielding panel 1.
As shown in FIG. 2, the first joint corresponding plate 12 is continuously arranged in the left-right direction of FIG. 2, and is fixed to the radiation shielding panel mounting plate 3 as the radiation shielding panel mounting portion through appropriate fixing means. Further, the second joint corresponding plate 14 is continuously arranged in the vertical direction of FIG. 2 and is fixed to the radiation shielding panel mounting plate 3 through fixing means as appropriate.
The first joint correspondence plate 12 and the second joint correspondence plate 14 are continuously arranged and fixed to the radiation shielding panel mounting plate 3 in a lattice shape to thereby provide a corner correspondence plate first housing portion of the first joint correspondence plate 12. 24 and the corner corresponding plate second accommodating portion 30 of the second joint corresponding plate 14 form a corner corresponding plate accommodating portion 32.
As a result, as shown in FIG. 3, the corner corresponding plate 16 can be accommodated and disposed in the corner corresponding plate accommodating portion 32.
Accordingly, the contact surface between the first joint correspondence plate 12 and the first joint correspondence plate 12 and the contact surface between the second joint correspondence plate 14 and the second joint correspondence plate 14 are the corner correspondence plate 16. Is shielded by.
Accordingly, as shown in FIG. 5, the first end face 1 </ b> C of the radiation shielding panel 1 and the joint 4 of the first end face 1 </ b> C of the radiation shielding panel 1, the second end face 1 </ b> D of the radiation shielding panel 1, and the second end face of the radiation shielding panel 1. Since the 1D joint 4 is shielded by the first joint corresponding plate 12, the second joint corresponding plate 14, and the corner corresponding plate 16, leakage of radiation can be prevented.
As shown in FIG. 1, the wall thickness dimension T <b> 1 of the first shielding plate body 20 and the wall thickness dimension T <b> 3 of the second shielding plate body 26 are the same, and therefore the bottom surface of the corner corresponding plate receiving portion 32. Will be the same.
Further, the thickness dimension T2 of the first plate body 22, the thickness dimension T4 of the second plate body 28, and the thickness dimension T5 of the corner portion corresponding plate 16 are the same.
Accordingly, when the corner corresponding plate 16 is accommodated in the corner corresponding plate accommodating portion 32, the surface of the first plate body 22, the surface of the second plate body 28, and the surface of the corner corresponding plate 16 are flush with each other. Become.
As a result, when a large number of radiation shielding panels 1 are appropriately attached to the surfaces of the first joint correspondence plate 12, the second joint correspondence plate 14, and the corner portion correspondence plate 16 by fixing means, Since the radiation shielding wall 2 can be provided with the surface flush, the interior work of the radiation shielding wall 2 can be performed smoothly and the appearance quality of the radiation shielding wall 2 can be maintained.

Next, an embodiment of a radiation shielding panel mounting method using the first joint corresponding plate 12, the second joint corresponding plate 14, and the corner corresponding plate 16 which are radiation shielding panel mounting tools is shown. The case where the radiation shielding wall 2 is provided on the inner side will be described as an example.
As shown in FIG. 2, the first joint corresponding plate 12 is fixed to the inner side surface of the radiation shielding panel mounting plate 3 as the already provided radiation shielding panel mounting portion in the left-right direction of FIG. 2 by appropriate means such as screws. To do. At this time, the end surface of the corner corresponding plate first accommodating portion 24 of the first joint corresponding plate 12 adjacent to the end surface of the corner corresponding plate first accommodating portion 24 of the first joint corresponding plate 12 is brought into close contact with the first end corresponding plate. The joint corresponding plate 12 is continuously fixed by appropriate fixing means such as screws.
On the other hand, the second joint corresponding plate 14 is fixed to the inner side surface of the radiation shielding panel mounting plate 3 in the vertical direction of FIG. 2 by appropriate fixing means such as screws.
At this time, the end face of the corner corresponding plate second accommodating portion 30 of the second joint corresponding plate 14 is brought into close contact with the corner corresponding plate first accommodating portion 24 of the first joint corresponding plate 12 so as to contact the second joint corresponding plate. 14 is continuously fixed.
As a result, the first joint correspondence plate 12 and the second joint correspondence plate 14 are fixed to the inner surface of the radiation shielding panel mounting plate 3 in a lattice shape (see FIG. 2).
Further, by fixing the first joint corresponding plate 12 and the second joint corresponding plate 14 in a lattice shape by the above method, the corner corresponding plate first accommodating portions 24, 24 and the corner corresponding plate second accommodating portion 30 are fixed. , 30 form a corner corresponding plate receiving portion 32.
Next, the corner corresponding plate 16 is accommodated and attached to the corner corresponding plate accommodating portion 32 as shown in FIG.
As shown in FIG. 4, the first end face 1 </ b> C of the radiation shielding panel 1 is made to correspond to the first joint on the surfaces of the first joint correspondence plate 12, the second joint correspondence plate 14, and the corner portion correspondence plate 16. Corresponding to the plate 12, the radiation shielding panel 1 is fixed by appropriate fixing means such as screws, with the second end face 1D of the radiation shielding panel 1 corresponding to the second joint corresponding plate 14.
Similarly, the radiation shielding panel 1 is continuously fixed, and the radiation shielding panel 1 is fixed in a plane shape as shown in FIG.
Therefore, even if radiation leaks from the joint portion 4 of the first end face 1C of the radiation shielding panel 1 adjacent to the first end face 1C of the radiation shielding panel 1, the leakage is shielded by the first joint corresponding plate 12, and the radiation shielding panel. Even if radiation leaks from the joint portion 4 of the second end face 1D of the radiation shielding panel 1 adjacent to the first second end face 1D, the leakage is shielded by the second joint corresponding plate 14.
Further, even if radiation leaks from the joint 4 at the corner of the radiation shielding panel 1, it is shielded by the corner corresponding plate 16.
Since the surface of the corner corresponding plate 16 is flush with the surfaces of the first joint corresponding plate 12 and the second joint corresponding plate 14, the radiation shielding wall 2 is provided with the surface of the radiation shielding panel 1 being flush. Therefore, the interior work of the radiation shielding wall 2 can be performed smoothly and the appearance quality of the interior of the radiation shielding wall 2 can be prevented from being deteriorated.

The radiation shielding panel mounting method using the first joint corresponding plate 12, the second joint corresponding plate 14, and the corner corresponding plate 16 which are radiation shielding panel mounting tools is not limited to the above-described embodiment. Absent.
For example, the first joint correspondence plate 12 and the second joint correspondence plate 14 are fixed to the inner surface of the radiation shielding panel mounting plate 3 in the same manner as in the first embodiment (see FIG. 2). .
Next, as shown in FIG. 6, the first end face 1 </ b> C of the radiation shielding panel 1 is placed on the surface of the first joint correspondence plate 12, the second joint correspondence plate 14, and the corner portion correspondence plate 16. Corresponding to the corresponding plate 12, the radiation shielding panel 1 is fixed by appropriate fixing means such as a screw with the second end face 1D of the radiation shielding panel 1 corresponding to the second joint corresponding plate 14.
Next, the corner corresponding plate 16 is slid obliquely from the exposed portion of the corner corresponding plate accommodating portion 32 and accommodated in the corner corresponding plate accommodating portion 32 to obtain the state shown in FIG. Also good.
Similarly, the radiation shielding panel 1 is fixed and the corner corresponding plate 16 is slid obliquely from the exposed portion of the corner corresponding plate receiving portion 32 to the corner corresponding plate receiving portion 32. It may be accommodated and the radiation shielding wall 2 may be provided.
In this method, the corner portion corresponding plate 16 is accommodated by sliding the corner portion corresponding plate 16 from the exposed portion of the corner portion corresponding plate accommodating portion 32 in an oblique lateral direction. Is partly supported by the radiation shielding panel 1, so that the corner correspondence plate 16 is easily dropped from the corner correspondence plate housing portion 32, such as when the radiation shielding wall 2 is provided inside the ceiling. There is an advantage that 16 can be prevented from falling.

In the embodiment, the thickness T 1 of the first shielding plate body 20, the thickness T 2 of the first plate body 22, the thickness T 3 of the second shielding plate body 26, and the second plate body 28. Although the wall thickness T4 is set to the same wall thickness, the wall thickness T1 of the first shielding plate body 20, the wall thickness T2 of the first plate body 22, and the wall thickness of the second shielding plate body 26 are not necessarily limited. Even if the dimension T3 and the thickness dimension T4 of the second plate body 28 are not the same thickness dimension, the thickness dimension T1 of the first shielding plate body 20 and the thickness dimension T3 of the second shielding plate body 26 are the same. As long as the thickness dimension T2 of the first plate body 22 and the thickness dimension T4 of the second plate body 28 are the same, the thickness dimension may be the same.
Moreover, although lead was shown as a radiation shielding material in the Example, as long as it is a material which can shield a radiation, it is not restricted to lead, Of course, materials other than lead may be used.
In the embodiment, the first plate body 22 and the second plate body 28 are formed of veneer plates. However, the first plate body 22 and the second plate body 28 may be formed of a material other than the veneer plate. Of course.

  As long as the radiation shielding panel attachment method and the radiation shielding panel attachment method using the radiation shielding panel attachment of the present invention are portions surrounding the radiation generation source, they can be used other than the walls and ceilings of the radiation chamber.

DESCRIPTION OF SYMBOLS 1 Radiation shielding panel 1A Veneer board 1B Lead board 1C 1st end surface 1D 2nd end surface 2 Radiation shielding wall 3 Radiation shielding panel mounting plate 4 Joint part 5 Lead plate 6 Lead plate crossing part 10 Radiation shielding panel attachment tool 12 1st joint corresponding plate 14 Second Joint Corresponding Plate 16 Corner Corresponding Plate 20 First Shielding Plate Body 22 First Plate Body 24 Corner Part Corresponding Plate First Storage Unit 26 Second Shielding Plate Body 28 Second Plate Body 30 Corner Part Corresponding Plate Second Housing Part 32 Corner plate support part

Claims (5)

A radiation shielding panel fixture comprising a first joint correspondence plate, a second joint correspondence plate, and a corner correspondence plate,
A first joint-corresponding plate formed in a strip shape with a radiation shielding material, a corner-corresponding plate first accommodating portion formed on each end of the first joint-corresponding plate, and a first strip formed in a strip shape with a radiation shielding material A second joint correspondence plate, a corner correspondence plate second accommodation portion formed at each end of the second joint correspondence plate, the corner correspondence plate first accommodation portion, and the corner correspondence plate second accommodation portion; A radiation shielding panel mounting comprising: a formed corner corresponding plate accommodating portion; and a corner corresponding plate formed of a radiation shielding material while being accommodated in the corner corresponding plate accommodating portion. Ingredients. A radiation shielding panel fixture comprising a first joint correspondence plate, a second joint correspondence plate, and a corner correspondence plate,
A first shielding plate body formed in a strip shape with a radiation shielding material constituting the first joint corresponding plate, and the first shielding plate body and the first joint correspondence plate are configured and mounted on the first shielding plate body. A belt-shaped first plate body fixed and fixed, a corner-corresponding plate first accommodating portion formed at each end of the first joint-corresponding plate, and a radiation shielding material constituting the second joint-corresponding plate A second shielding plate body formed on the second shielding plate body, a belt-like second plate body that constitutes the second shielding plate body and the second joint plate, and is placed and fixed on the second shielding plate body, Formed by a corner-corresponding plate second accommodating portion formed at both ends of the joint joint corresponding plate, the corner-corresponding plate first accommodating portion, and the corner-corresponding plate second accommodating portion. A radiation shielding panel fixture, comprising: a corner corresponding plate receiving portion; and a corner corresponding plate which is received in the corner corresponding plate receiving portion and formed of a radiation shielding material. . A radiation shielding panel mounting method using a radiation shielding panel mounting tool composed of a first joint corresponding plate, a second joint corresponding plate, and a corner portion corresponding plate,
Radiation shielding is performed by continuously connecting the first joint-corresponding plates in a straight line so that the end faces of the adjacent first joint-corresponding plates abut on the first joint-corresponding plates having the corner-corresponding plate first accommodating portions formed at both ends. A first step of fixing to the panel mounting portion;
The end face of the second joint corresponding plate having the corner corresponding plate second accommodating portions formed at both ends is brought into contact with the corner corresponding plate first accommodating portion of the first joint corresponding plate, and the first joint corresponding plate A second step of fixing the second joint corresponding plate to the radiation shielding panel mounting portion in a grid with the first joint corresponding plate fixed to the radiation shielding panel mounting portion so as to be orthogonal;
A third step of accommodating a corner-corresponding plate formed of a radiation shielding material in a corner-corresponding plate container formed by the corner-corresponding plate first container and the corner-corresponding plate second container;
The radiation shielding panel is appropriately fixed by a fixing means with the first end face of the radiation shielding panel corresponding to the first joint correspondence plate and the second end face of the radiation shielding panel corresponding to the second joint correspondence plate. And a radiation shielding panel mounting method using the radiation shielding panel mounting tool. A radiation shielding panel mounting method using a radiation shielding panel mounting tool composed of a first joint corresponding plate, a second joint corresponding plate, and a corner portion corresponding plate,
Radiation shielding is performed by continuously connecting the first joint-corresponding plates in a straight line so that the end faces of the adjacent first joint-corresponding plates abut on the first joint-corresponding plates having the corner-corresponding plate first accommodating portions formed at both ends. A first step of fixing to the panel mounting portion;
The end face of the second joint corresponding plate having the corner corresponding plate second accommodating portions formed at both ends is brought into contact with the corner corresponding plate first accommodating portion of the first joint corresponding plate, and the first joint corresponding plate A second step of fixing the second joint corresponding plate to the radiation shielding panel mounting portion in a grid with the first joint corresponding plate fixed to the radiation shielding panel mounting portion so as to be orthogonal;
The radiation shielding panel is appropriately fixed by a fixing means with the first end face of the radiation shielding panel corresponding to the first joint correspondence plate and the second end face of the radiation shielding panel corresponding to the second joint correspondence plate. Process,
A fourth step of accommodating a corner-corresponding plate formed of a radiation shielding material in a corner-corresponding plate container formed by the corner-corresponding plate first container and the corner-corresponding plate second container;
The radiation shielding panel attachment method using the radiation shielding panel attachment characterized by comprising.   The radiation shielding panel fixture according to claim 2, wherein at least the first shielding plate body and the second shielding plate body have the same thickness.

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