KR20040048589A - Radation shielding body and method for producing the same - Google Patents

Abstract

PURPOSE: A radiation shielding body and a method for producing the same are provided to achieve improved radiation shielding performance by preventing perforation of pin holes. CONSTITUTION: A radiation shielding body(10) comprises a plurality of resin sheets(10a) made of powder or compound powder consisting of an element having an atomic number 40 or higher as a main body. A method for producing a radiation shielding body comprises a step of producing resin sheets by mixing a resin material and powder consisting of an element having an atomic number 40 or higher and performing an extrusion molding process, a calendar processing, a coating process, or a molding process to the mixture; and a step of laminating the resin sheets.

Description

Radiation shielding body and method for producing the same

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a radiation shielding body and a method for manufacturing the same. More specifically, the present invention relates to X-ray generators, nuclear power equipment, radioactive material containers, radioactive waste containers, and the like. X-ray technicians, doctors, researchers, non-destructive inspectors, patients undergoing X-ray diagnostics or radiation therapy, workers handling and treating radioactive material or radioactive waste, and accident handling personnel of nuclear-related equipment, such as The present invention relates to a radiation shield used for preventing exposure to radiation such as alpha rays (α), beta rays (β), and gamma rays (γ).

Fig. 3 is a cross-sectional view schematically showing this type of radiation shielding sheet of the related art, and in Fig. 31, a thermoplastic resin such as vinyl chloride is shown. The thermoplastic resin 31 is formed in a sheet shape having a thickness (t), and a predetermined amount of Pb (lead) powder 32 is blended and dispersed in the thermoplastic resin 31. The radiation shielding sheet 30 is composed of these thermoplastic resins 31, Pb powder 32, and the like.

Although not shown, the radiation shielding sheet 30 is cut to a predetermined size and wrapped in a cloth or the like, and then sewn into a predetermined shape by sandwiching the cloth or the like, and the jacket, pants, apron, coat, hat, It is formed and worn with protective gloves such as gloves. Alternatively, the cover or curtain may be used to be in close contact with the radiation source or to cover the radiation source indirectly.

In addition, although not shown, in the X-ray generator, nuclear power equipment, radioactive material container, radioactive waste container and the like, a radiation shield in which Pb powder is mixed and dispersed in a thermosetting resin plate is used as a structural member.

In the above-described conventional radiation shielding sheet 30 or radiation shielding plate, since the thickness of the radiation shielding sheet 30 or radiation shielding plate is thin, no matter how many pinholes (not shown) generated in the manufacturing process are radiation shielded. There existed a problem that it was easy to penetrate into the sheet | seat 30 and a radiation shielding plate, and radiation may permeate | transmit through this pinhole.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and an object of the present invention is to provide a radiation shielding body and a manufacturing method thereof capable of preventing penetration by pinholes and improving radiation shielding performance.

BRIEF DESCRIPTION OF THE DRAWINGS It is sectional drawing which shows typically the Example of the radiation shielding body which concerns on this invention.

2 is a cross-sectional view schematically showing the method for manufacturing a radiation shield according to the embodiment.

3 is a cross-sectional view schematically showing a conventional radiation shield.

<Description of the code | symbol about the principal part of drawing>

10: radiation shielding sheet

10a: Resin Sheet

11a: Pb powder

In order to achieve the above object, in the radiation shielding body of the present invention, a resin sheet formed by blending and dispersing a powder or compound powder mainly composed of an element having an atomic number of 40 or more is laminated. It is characterized by that).

According to the above-mentioned radiation shielding body, since the powder or the compound powder mainly containing the atomic number 40 or more of which is mix | blended and dispersed easily shields radiation, transmission of radiation can be suppressed. In addition, since a plurality of the resin sheets are laminated, it is possible to greatly reduce the pinholes from passing through the resin sheets. Further, pinholes generated in the lamination step of the sheet can be collapsed and removed. As a result, the radiation can be prevented from penetrating through the pinhole and the radiation can be reliably shielded.

In addition, in the method for producing a radiation shielding body according to the present invention, a resin sheet is prepared by extrusion, calendering, coating, or mold molding by mixing powder or compound powder mainly composed of an element having an atomic number of 40 or more in a water support material. After the production, a plurality of resin sheets are laminated and laminated.

According to the method for producing a radiation shielding body, the resin sheet can be produced by the extrusion molding, calendering, coating, or mold molding, and in the lamination processing step, Since the generated pinhole can be removed and the pinhole can penetrate through the resin sheet, it is possible to reliably produce a radiation shield excellent in radiation shielding ability.

<Example>

EMBODIMENT OF THE INVENTION Hereinafter, the Example of the radiation shielding body which concerns on this invention is described based on drawing. Moreover, the same reference numerals will be given to the components having the same function as the conventional example.

Fig. 1 is a sectional view schematically showing a radiation shielding body according to an embodiment, and in Fig. 1, 10a shows a resin sheet such as vinyl chloride resin. The thickness of the resin sheet 10a is set to about (t / 2) when the thickness of the sheet as a final product is set to (t). In this resin sheet 10a, Pb powder 11a having an atomic number 82 is blended and dispersed in a predetermined amount.

Two resin sheets 10a and 10a are laminated, and the radiation shielding sheet 10 having a thickness (t) is formed including these resin sheets 10a and 10a.

When manufacturing the resin sheet 10a comprised in this way, a predetermined amount of thermoplastic water support material, Pb powder, a plasticizer, an adhesive component, etc. are mixed using a mixer. Subsequently, these mixtures are molded by extrusion molding, calendering, coating, or mold molding to prepare a resin sheet 10a having a thickness of about (t / 2).

Fig. 2 is a cross-sectional view schematically showing a press working machine for explaining the method of manufacturing a radiation shielding sheet according to the embodiment, and in Fig. 21, a bed is shown. The drive ram 22 is arrange | positioned in the upper part of the bed 21 so that driving to the arrow A-B direction is possible in the figure. The press machine main body 20a is comprised including these beds 21, the drive ram 22, etc. On the other hand, between the bed 21 and the drive ram 22, the board | substrates 23-25 which have substantially rectangular parallelepiped shape are attached and arrange | positioned, and the board | substrates 23- ( 25 is equipped with heating means (not shown). A plurality of sets of resin sheets 10a and 10a are laminated between the substrates 23 to 25, and each of the sets of resin sheets 10a and 10a is a separate plate made of stainless steel. It is pinched by 26a and 26a. The jig 20b is comprised including these board | substrates 23-25, the separator 26a, etc.

When manufacturing the radiation shielding sheet 10 using the resin sheet (10a), (10a) using the press working machine, first, the substrate (23), (under the bed 21 and the drive ram 22) 24) Fit. Subsequently, after laminating the resin sheets 10a and 10a sandwiched between the separators 26a and 26a and disposing the substrate 25 at a predetermined position, the separators 26a and 26a are further sandwiched. The resin sheets 10a and 10a were laminated. Thereafter, the heating means is operated to raise the resin sheets 10a and 10a to a predetermined temperature via the substrates 23 to 25 and the separation plates 26a and 26a, and then the drive ram 22 Is driven in the direction of arrow B in the figure, and a predetermined pressure is applied to the resin sheets 10a and 10a. Thereafter, by cooling, the resin sheets 10a and 10a are integrated to produce a radiation shielding sheet 10 having a thickness (t).

In the radiation shielding sheet 10 according to the embodiment, since the powder mainly composed of Pb of atomic number 40 or more that is blended and dispersed easily shields the radiation, the transmission of the radiation can be suppressed. In addition, since two resin sheets 10a and 10a are laminated, it is possible to drastically reduce the penetration of the pinholes and penetrating into the resin sheets 10a and 10a. In addition, pinholes generated in the manufacturing steps of the resin sheets 10a and 10a can be collapsed and removed in the lamination step. As a result, radiation can be prevented from penetrating through the pinhole and the radiation can be reliably shielded.

In addition, by extrusion molding, calendering, coating, or mold molding, the resin sheet 10a having a uniform thickness can be produced while suppressing the occurrence of pinholes.

Moreover, in the radiation shielding sheet 10 and the manufacturing method thereof according to the embodiment, the case where the two resin sheets 10a and 10a are laminated is explained, but the present invention is not limited to only two sheets, but other implementations. In the example, three or four,... … It may be. The larger the number of sheets to be laminated, the lower the probability of sheet penetration due to pinholes, but the production becomes difficult little by little.

In addition, in the manufacturing method of the radiation shielding sheet 10 which concerns on an Example, the case where press processing is performed by laminating processing was demonstrated, In another Example, the adhesive rolling process using the roll rolling method including a heating process, or an adhesive agent is performed. You may carry out.

In addition, in the radiation shielding sheet 10 according to the embodiment, the case where the Pb powder 11a made of a metal is used has been described. In another embodiment, the compound powder such as an oxide or an alloy of Pb is used. It may be.

In addition, although the case where Pb powder was used was demonstrated in the radiation shielding sheet 10 which concerns on an Example, it is not limited only to this, The atomic number should just be an element of 40 or more, for example, Zr, Mo, Te , Ba and these compounds, or these may be used in combination.

In the radiation shielding sheet 10 according to the embodiment, the case where the resin sheet 10a is made of thermoplastic vinyl chloride resin has been described. In another embodiment, the resin sheet 10a is thermoplastic. It may be comprised from vinyl resin, polyurethane resin, polyethylene resin, or the like.

In addition, although the radiation shielding sheet 10 which concerns on an Example demonstrated the case where the resin sheet 10a was comprised with the thermoplastic vinyl chloride resin, in another Example, the resin sheet 10a is a thermosetting epoxy type system. It may be comprised with resin, phenol resin, silicone resin, etc.

According to the following conditions, the radiation shielding body according to the Example and the comparative example was manufactured, and the lead equivalent, Tensile stress, and tear strength in 1 mm thickness of the shielding body under the following experimental conditions. The results of the investigation of the strength, the flexibility in the product thickness (0.5 mm) of the shield, and the occurrence of pinholes will be described.

The production method is carried out by mixing and mixing the vinyl chloride resin, Pb powder and a predetermined amount of plasticizer, adhesive components and the like shown in the first table as follows using a mixer to produce a sheet having a predetermined thickness by extrusion. In Example (1), two sheets were stacked and laminated with a press. Heating temperature was 180 degreeC, and press pressure was set to 60 Kgf / cm <2>. Comparative example (1) was made into the sheet | seat 1 sheet | seat (not laminating process). Measurement of lead equivalent weight, tensile strength, tear strength, and cut resistance was performed in accordance with JIS-Z4801 (1991), and the evaluation of pinhole occurrence was performed in accordance with JIS-Z4501 2 (film size 25.4 cm x 0.5 cm). .

The measurement results of the compounding ratio, the number of laminated sheets, the lead equivalent weight per 1 mm of the shield, the tensile strength, the tear strength, the cut resistance at the product thickness of 0.5 mm, and the occurrence of pinholes are shown in the following table.

Suzy Pb Stacked Number Lead equivalent The tensile strength Tear strength Resistance Pinhole occurrence unit % % buying MmPb MPa N / m cycle dog First embodiment 20 80 2 0.26 5.5 18,000 82,000 0 Comparative Example 1 20 80 One 0.26 5.5 18,000 80,000 1 to 2

(1) As shown in Table 1, the generation of pinholes was reduced in Example (1) as compared with Comparative Example (1).

(2) About lead equivalent weight per 1mm of thickness, both Comparative Example (1) and Example (1) are 0.26 mmPb, and the standard value in protective apron, protective coat, thyroid protective tool, protective gloves, etc. (JIS-Z4831 ) 0.25 mmPb.

(3) In terms of tensile strength, tear strength and cut resistance, both of Example (1) and Comparative Example (1) exceeded the standard value.

According to the present invention, since the powder or compound powder mainly composed of elements having atomic number of 40 or more, which is blended and dispersed, easily shields the radiation, the transmission of the radiation can be suppressed. In addition, since a plurality of the resin sheets are laminated, it is possible to greatly reduce the pinholes from passing through the resin sheets. Further, in the lamination step of the sheet, pinholes generated can be collapsed and removed. As a result, the radiation can be prevented from penetrating through the pinhole and the radiation can be reliably shielded.

Further, according to the present invention, the resin sheet can be produced by the extrusion molding, calendering, coating, or mold molding, and at the same time, the pinholes generated during the manufacturing process of the resin sheet in the laminating processing step. Since it is possible to reduce the penetration of the pinhole through the sheet, it is possible to reliably produce a radiation shield having excellent radiation shielding ability.

Claims (2)

A radiation shielding body characterized in that a plurality of resin sheets formed by mixing and dispersing powder or compound powder mainly composed of elements having an atomic number of 40 or more are laminated. A resin sheet is prepared by extrusion, calendering, coating, or mold molding by mixing powder or compound powder mainly composed of an element having an atomic number of 40 or more in the water support material, and laminating a plurality of resin sheets by lamination. A method of manufacturing a radiation shield, characterized in that the processing.