JP2018179677A - Resin laminate having radiation shield properties - Google Patents

Abstract

PROBLEM TO BE SOLVED: To effectively suppress a reduction in intensity caused by an increase of a mixing amount of a radiation shielding material.SOLUTION: A resin laminate includes: a radiation shielding layer 2 formed of a resin composition containing a metal compound with a density of 4.6 g/cmor larger in the concentration of 60% by volume or larger; and a reinforced resin layer 3 formed of a resin composition containing no metal compound or containing a metal compound in the concentration of 40% by volume or less.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a resin laminate having a radiation shielding property.

  Radiation shielding materials having the function of shielding radiation from radioactive materials that generate radiation are incorporated into easy-to-mold resins, and various structures in which radioactive materials are accommodated, such as containers, pipes, armor, syringes, wall materials There are many cases where it is used after being formed into an etc.

  As a radiation shielding material, lead and lead glass are representative, but in addition to this, metals such as tungsten, barium sulfate and the like are also known, and further, Patent Document 1 proposed by the present applicant It is disclosed that fluorides such as barium fluoride and the like have excellent radiation shielding properties.

  By the way, in the resin molded product in which the radiation shielding material is blended, as a matter of course, the radiation shielding properties improve as the blending ratio increases, but the strength decreases as the radiation shielding properties improve. There has been a problem that the blending amount of the radiation shielding material is limited. In particular, the radiation shielding material disclosed in Patent Document 1 can obtain radiation shielding properties comparable to lead glass when the compounding amount is increased, but there is a problem of strength reduction, so its excellent There have been cases where it has been difficult to use for applications that make full use of the radiation shielding properties.

WO 2016/098725

  Therefore, an object of the present invention is to effectively suppress a decrease in strength due to an increase in the amount of the radiation shielding material even when the radiation shielding material is blended in a large amount.

According to the present invention, a radiation shielding layer formed of a resin composition containing 60% by volume or more of a metal compound having a density of 4.6 g / cm ³ or more, and the metal compound not contained or 40 There is provided a resin laminate including a reinforcing resin layer formed of a resin composition containing in an amount of% by volume or less.

In the resin laminate of the present invention,
(1) A reinforced resin layer is laminated on both sides of the radiation shielding layer,
(2) the radiation shielding layer contains the metal compound in an amount of more than 80% by volume;
(3) The difference between the refractive index of the resin forming the radiation shielding layer and the resin forming the reinforcing resin layer is within 0.1,
(4) The thickness (t ₁ ) of the radiation shielding layer is 0.2 to 20 mm, and the ratio (t ₂ / t ₁ ) of the thickness (t ₂ ) of the reinforcing resin layer to the thickness (t ₁ ) of the radiation shielding layer is , 0.1 to 1, preferably 0.2 to 0.5,
(5) Having a lead equivalent of 0.5 mm Pb or more and a total light transmittance (@ 500 nm) of 85% or more,
Is preferred.

The resin laminate of the present invention has a radiation shielding layer in which a metal compound having a density of 4.6 g / cm ³ or more is compounded as a radiation shielding material in a high filling amount with a resin. At the same time, a reinforcing resin layer is provided which is made of a resin which contains or does not contain a small amount of radiation shielding material which does not adversely affect the strength of the resin. That is, although the radiation shielding property is improved as the amount of the metal compound in the radiation shielding layer is increased, the resin property is deteriorated, and thus the strength characteristic is deteriorated. However, in the present invention, since the reinforcing resin layer is provided, even when the radiation shielding property is improved by increasing the compounding amount of the metal compound which is the radiation shielding material, the inconvenience due to the strength reduction is effectively avoided. can do.

  Thus, the resin laminate of the present invention has the advantage of being able to enhance the radiation shielding properties by increasing the compounding amount of the metal compound, but the greatest advantage is that it is free with respect to the compounding amount of the metal compound Because of the high degree of freedom, the range of choices for radiation shielding properties and transparency is broadened by appropriately selecting the type of resin used to form the radiation shielding layer and the reinforcing resin layer, as well as the type of metal compound. That's what it means.

For example, the amount of the metal compound in the radiation shielding layer is set to 60% by volume or more in order to obtain a radiation shielding property with a lead equivalent of 0.5 mmPb or more at a practical thickness described later. By using a metal compound having a refractive index close to that of the resin that forms the radiation shielding layer, and by selecting the refractive index of the resin used to form the reinforcing resin layer also close to the refractive index of the resin of the radiation shielding layer, Transparency can also be ensured, and a total light transmittance of 85% or more can be obtained for visible light with a wavelength of 500 nm.
In addition, about a certain radiation shielding material, a lead equivalent means the thickness of the lead which provides the shielding ability equivalent to this, and it is excellent in radiation shielding property, so that a lead equivalent is high. For example, a radiation shielding material having a lead equivalent of 1 mmPb has a radiation shielding property equivalent to a lead plate having a thickness of 1 mm.

  Furthermore, when the amount of the metal compound in the radiation shielding layer is set to an amount exceeding 80% by volume, the transparency of this resin laminate tends to decrease, but on the other hand, the radiation shielding property is greatly improved, lead glass and It is possible to obtain the same or more radiation shielding properties.

BRIEF DESCRIPTION OF THE DRAWINGS The schematic sectional drawing which shows the basic layer structure of the resin laminated body of this invention.

  Referring to FIG. 1, the basic layer structure of resin laminate 1 of the present invention has a radiation shielding layer 2 and a high strength layer 3.

<Radiation shielding layer 2>
The radiation shielding layer 2 contains a metal compound as a radiation shielding material, and the density of such a metal compound is 4.6 g / cm ³ or more, particularly 4.8 g / cm ³ or more, and most preferably 5.0 g / cm ^3. It is in the range of ³ cm or more. That is, when a metal compound whose density is smaller than the above range is used, the limit of radiation blocking properties due to high filling is reduced, and a radiation blocking layer having both high radiation blocking properties and translucency, which has not been realized conventionally. It will be difficult to realize.

The above-mentioned metal compound used in the present invention has an arbitrary molecular structure such as an oxide, carbonate, sulfate, fluoride, etc. containing a single metal or two or more metals, as long as the density is in the above range. In particular, those having a refractive index close to that of the resin (for example, 1.4 to 1.7) are preferable in terms of securing light transmittance. Examples of metal compounds having such a density and refractive index include fluorides, particularly fluorides of alkaline earth metals and fluorides of rare earth metals.
The specific example is as follows.
BaF ₂ (density 4.8, refractive index 1.48)
BaY ₂ F ₈ (complex fluoride, density 5.0, refractive index 1.52)
BaLiF ₃ (complex fluoride, density 5.2, refractive index 1.54)
LaF ₃ (density 5.9, refractive index 1.60)
CeF ₃ (density 6.2, refractive index 1.61)
SmF ₃ (density 6.6, refractive index 1.62)
YbF ₃ (density 8.2, refractive index 1.60)

  The above metal compounds are usually used alone, but may be used as a mixture of two or more for adjusting the refractive index, or may be a solid solution of two or more compounds, and particularly transparent In applications where the property is required, materials close to the refractive index of the resin used to form the radiation shielding layer 2 (for example, the difference in refractive index with the resin is within ± 0.05) are preferably used.

  In the present invention, such a metal compound is preferably blended with the resin after adjusting the particle size of the single crystal to a particle size of 1000 μm or less, particularly about 10 to 500 μm, by grinding or the like. If the particle size is too large, the transparency may be impaired, and if too small, aggregation of the particles may make it difficult to uniformly disperse the resin, or may make it difficult to handle the resin. Depending on the type of resin, there is a possibility that the moldability of the resin may be impaired due to thickening or the like. In addition, in the range which does not produce this fear, when aiming at obtaining especially high transparency, you may use the metal compound of the particle size of about 100 nm or less.

  Also, as the resin used to form the radiation shielding layer 2, that is, the matrix resin in which the above-mentioned metal compound is dispersed, a resin known per se can be used as long as it has a predetermined formability, for example , Low density polyethylene, high density polyethylene, polypropylene, poly 1-butene, poly 4-methyl-1-pentene or random or block of α-olefins such as ethylene, propylene, 1-butene, 4-methyl-1-pentene, etc. Copolymers, olefin-based resins such as cyclic olefin copolymers; ethylene-vinyl acetate copolymers, ethylene-vinyl alcohol copolymers, ethylene-vinyl copolymers such as ethylene-vinyl chloride copolymers; polystyrene, Acrylonitrile, styrene copolymer, ABS, α-methylstyrene, styrene copolymer, etc. Tyrene resins; polyvinyl resins such as polyvinyl chloride, polyvinylidene chloride, vinyl chloride / vinylidene chloride copolymer, polymethyl methacrylate, polymethyl methacrylate etc .; nylon 6, nylon 6-6, nylon 6-10, nylon 11, polyamide resins such as nylon 12; polyester resins such as polyethylene terephthalate, polybutylene terephthalate, polyethylene naphthalate, and copolyesters thereof; polycarbonate resins; polyphenylene oxide resins; biodegradable resins such as polylactic acid; polyvinyl acetate Acetate resins such as; silicone resins; epoxy resins; phenol resins; urethane resins;

  In the case of a thermoplastic resin, the compounding of the metal compound to the resin is generally carried out by melt-kneading using an extruder or the like, but in the case of a thermosetting resin for curing a liquid monomer, a ball mill Alternatively, the metal compound powder may be dispersed in the resin by blending a powder of the metal compound whose particle size is adjusted to the liquid monomer using a Banbury mixer or the like, and then polymerizing.

In the radiation shielding layer 2 formed of the metal compound and the resin described above, the compounding amount of the metal compound is set to such an amount that at least high radiation shielding properties can be obtained, for example, 0.5 mm Pb or more in practical thickness It is preferable that the metal compound is blended in an amount of 60% by volume or more to secure a lead equivalent of
Furthermore, in the radiation shielding layer 2, metal compounds can be blended in an amount of more than 80% by volume, whereby radiation shielding properties comparable to or more than lead glass can be obtained. However, in this case, the reduction in strength is further increased, and the formability may also be impaired. Therefore, the blending amount of the metal compound is preferably suppressed to 95% by volume or less.

  Although the radiation shielding layer 2 mentioned above changes with applications, it is practically set to the thickness of about 200 micrometers-20 mm in the use mentioned later.

<High-strength layer 3>
In the present invention, the reinforcing resin layer 3 is a layer for supplementing the strength of the radiation shielding layer which has become brittle due to the high loading of the metal compound, and the resin constituting such layer significantly reduces the intrinsic characteristics of the resin used. The resin which contains the metal compound in the range which is not included or does not contain this is used. By using the above-mentioned resin, the strength characteristics or flexibility inherent to the resin can be exhibited by the reinforcing resin layer. That is, by providing such a reinforcing resin layer 3, it is possible to effectively avoid the problem when a large amount of metal compound is blended in the above-mentioned radiation shielding layer 2 to express high radiation shielding properties.

As resin used for formation of such a reinforcement resin layer 3, resin similar to what is used for formation of the radiation shielding layer 2 mentioned above can be illustrated.
In addition, when transparency is particularly required, it is preferable to use a resin having a difference in refractive index of 0.07 or less from the resin used to form the radiation shielding layer 2, and it is optimal to use the same resin. is there.

Such a reinforcing resin layer 3 has a ratio (t ₂ / t ₁ ) of the thickness (t ₂ ) of the reinforcing resin layer to the thickness (t ₁ ) of the radiation shielding layer of 0.1 to 1, preferably 0. It is preferable to provide so as to be from 2 to 0.5.
Since the reinforcing resin layer provided on the surface layer of the radiation shielding layer exerts a sufficient reinforcing effect even if it is relatively thin as described above, in the range in which the entire thickness of the resin laminate is not abnormally thickened, more than the conventional shielding material Can realize a high shielding effect.
In particular, in the case where reinforcing resin layers are provided on both sides of the radiation shielding layer, reinforcing and curing by the reinforcing resin layer can be further enhanced, which is preferable.

  In the present invention, in the radiation shielding layer 2 and the reinforcing resin layer 3 described above, a resin compounding agent known per se, such as an antioxidant, ultraviolet light, as long as the properties required for these layers are not impaired. Absorbents, surfactants, fillers, plasticizers, antistatic agents, color pigments and the like may be blended.

<Layer structure and manufacture of resin laminate>
The resin laminate of the present invention has a basic layer structure including the above-described radiation shielding layer 2 and the reinforcing resin layer 3, but as long as it has such a basic layer structure, depending on the application. , And may have other layers.
For example, although the two-layer structure of the radiation shielding layer 2 and the reinforcing resin layer 3 is shown in the example of FIG. 1, it is also possible to have a multilayer structure having a plurality of the radiation shielding layer 2 and the reinforcing resin layer 3 respectively. It is possible. However, in the case where a plurality of radiation shielding layers 3 are formed, it is preferable that the reinforcing resin layer 3 be present at least at positions adjacent to the respective radiation shielding layers 2.
When the adhesion between the radiation shielding layer 2 and the reinforcing resin layer 3 is low, an adhesive resin layer (for example, a layer of a maleic anhydride-modified olefin resin) or a dry laminating adhesive (for example, between the two layers) A layer of polyurethane) may be interposed. Furthermore, when the resin laminate is used for an optical system application, an antireflective film, a hard coat layer, etc. may be formed by coating or vapor deposition, and when used for applications such as containers, gas barrier properties Resin layer (for example, ethylene / vinyl alcohol copolymer layer or aromatic polyamide resin layer), and an oxygen absorbing layer having an oxidizable polymer (polybutadiene etc.) are appropriately provided via an adhesive layer. May be

The resin laminate of the present invention having such a layer structure can be produced by a known molding method such as coextrusion or coinjection, and each resin layer is molded by extrusion molding, cast polymerization or the like. Alternatively, it can be manufactured by dry lamination or the like.
In addition, as another method for producing the resin laminate of the present invention having the above-mentioned layer structure, the metal compound is added to and dispersed in a liquid resin having a low viscosity, specifically, a viscosity of 3000 mPa · S or less at 25 ° C. Then, it is poured into a mold, and the metal compound is allowed to settle to form a high concentration layer and a supernatant layer, which is then cured to simultaneously form a radiation shielding layer and a reinforcing resin layer. it can. Of course, it is also possible to form a reinforcing resin layer on the other side of the radiation shielding layer in the same manner as the above method.

The resin laminate of the present invention thus obtained has a radiation shielding property with a lead equivalent of, for example, 0.5 mm Pb or more, by being provided with the above-described radiation shielding layer 2 having a high radiation shielding effect. Furthermore, by selecting various materials, it is possible to secure a total light transmittance (@ 500 nm) of 85% or more.
Moreover, in spite of having the above high radiation shielding properties, since the reinforcement resin layer 3 is provided, the strength reduction can be effectively avoided.
Furthermore, by providing the reinforcing resin layer 3, the radiation shielding property of the radiation shielding layer 2 can be enhanced to a region close to the limit, and in the case of use for a window for daylighting where transparency is not required so much, lead glass Or it exhibits more radiation shielding properties.

The resin laminate of the present invention can be applied to various applications by taking advantage of its high radiation shielding properties and strength characteristics, and it can be used as protective glasses, glass for windows, windows for daylighting, other containers for containing radiation materials, etc. It is preferably used.
According to the metal light-transmissive member of the present invention manufactured in this manner, it is possible to effectively block the penetration of radiation from the light-transmitting gap while securing a certain light-transmitting property. Health hazards from radiation can also be effectively prevented.

The invention is illustrated by the following experimental example.
(Example)
A BaLiF ₃ single crystal was produced using the same method as that described in Example 1 of JP-A-2008-201644. The refractive index of the obtained BaLiF ₃ single crystal was 1.53 and the specific gravity was 5.2.
The resultant was finely pulverized using a pulverizer, passed through a 200 μm mesh sieve, and the lower part of the sieve was collected to obtain BaF powder 1. The average particle size of BaF powder 1 was 120 μm.

  A mixture of 4000 g of BaF powder 1 with 200 g of polyvinyl chloride resin having a refractive index of 1.54 and a specific gravity of 1.4 was kneaded using a Banbury mixer, and the obtained molten mixture was used to press the press to a thickness of 5 mm. A 100 mm × 100 mm radiation shielding plate 1 having a length was manufactured. The BaF powder 1 is contained at 84.3% by volume in the radiation shielding plate. The obtained radiation shielding plate was transparent, and its total light transmittance was 86%.

  Next, 200 g of BaF powder 1 is mixed with 100 g of the polyvinyl chloride resin, and the mixture is kneaded using a Banbury mixer, and a portion of the obtained molten mixture is used to obtain a 100 mm thickness of 0.5 mm with a pressure press. Two X 100 mm radiation shielding plates 2 were produced. The BaF powder 1 is contained 35% by volume in the radiation shielding plate 2.

  Next, the radiation shielding plate 2 was bonded on both surfaces of the radiation shielding plate 1, and the radiation shielding plate 3 with a thickness of 5 mm was obtained by a heating press. When the cross section of the radiation shield 3 was observed using an optical microscope, the layer derived from the radiation shield 1 was 4.2 mm, and the layer derived from the radiation shield 2 was 0.4 mm.

Next, the radiation transmittance of the radiation shielding plate produced by the following method was measured.
The gamma ray source of 611 eV of 1 Cs 137 and the NaI-R 6249 gamma ray detector are made to face each other at a distance of 30 cm, and the gamma ray intensity C 0 is obtained with no shield placed therebetween. Next, the gamma ray intensity C1 in a state where the prepared sheet is placed 3 cm before the detector between the gamma ray source and the gamma ray detector is obtained. The radiation transmittance was determined by the following equation.
Radiation transmittance (%) = C1 / C0 × 100

When the radiation shielding board 3 produced in the present Example was evaluated by said method, the radiation transmittance was 85% (0.7 mm Pb equivalent).
Next, the falling ball impact strength of the obtained radioactive shielding plate was evaluated. When the radiation shielding plate 1 was placed horizontally and a hard ball of 500 g was dropped from above while changing the height, cracks occurred on the surface at a drop height of 20 cm.
Next, when the same test was conducted on the radioactive shielding plate 2, cracking occurred at 100 cm.

1: Resin laminate 2: Radiation shielding layer 3: Reinforcing resin layer

Claims (6)

A radiation shielding layer formed of a resin composition containing 60% by volume or more of a metal compound having a density of 4.6 g / cm ³ or more; and an amount of 40% by volume or less containing no such metal compound The resin laminated body containing the reinforcement resin layer currently formed from the resin composition containing.   The resin laminate according to claim 1, wherein a reinforcing resin layer is laminated on both sides of the radiation shielding layer.   The resin laminate according to claim 1 or 2, wherein the metal compound is contained in the radiation shielding layer in an amount of more than 80% by volume.   The resin according to any one of claims 1 to 3, wherein the difference between the refractive index of the resin forming the radiation shielding layer and the resin forming the reinforcing resin layer is within 0.1. Stack. The thickness (t ₁ ) of the radiation shielding layer is 0.2 to 20 mm, and the ratio (t ₂ / t ₁ ) of the thickness (t ₂ ) of the reinforcing resin layer to the thickness (t ₁ ) of the radiation shielding layer is 0. The resin laminate according to any one of claims 1 to 4, which is 1 to 1.   The resin laminate according to any one of claims 1 to 5, which has a lead equivalent of 0.5 mm Pb or more and a total light transmittance (@ 500 nm) of 70% or more.