WO2005049713A1 - Radiation shielding material for protective clothing, such as aprons or the like - Google Patents

Abstract

The invention relates to a lead-free radiation shielding material, for aprons or the like, wherein a radiation absorption material based on elements having an atomic number higher than 50 is integrated into an elastomer or a plastomer. The aim of the invention is to improve one such radiation shielding material such that it can be stretched to form a film, that the production thereof is technically possible and cost-effective, and that the lead equivalent characterising the absorption capacity remains constant over the energy range of the radiation between 40 kV and approximately 120 kV. To this end, the elastomer or plastomer of the radiation shielding material to be processed into a film, for radiation absorption, contains metallic bismuth or bismuth compounds as the only additive.

Description

 Radiation protection material for protective clothing such as aprons and. the like

The invention relates to a lead-free radiation protection material for protective clothing, such as aprons and. Like., In which metallic or oxidic radiation absorption material is incorporated into an elastomer.

So far, radiation protection materials based on lead have been used for the production of protective clothing. In recent years, because of its properties as a heavy metal, this lead has been replaced by various other absorber materials for X-rays, combinations of different elements with an atomic number greater than 50 being used. DE 19955192 A1 discloses a process for producing a lead-free radiation protection material from a polymer, the polymer being a synthetic, thermoplastic, vulcanizable elastomer, into which a powder of a high atomic number metal or its compounds is incorporated as the radiation-absorbing material , The polymer being natural rubber (NR) and / or polychloroprene (CR) and / or nitrile butadiene (NBR) and / or styrene butadiene rubber (SBR) and / or butadiene rubber (BR) and / or ethylene-propylene terpolymer (EPDM) and / or ethylene-propylene copolymer (EPM) and / or polyurethane (PUR) and / or isobutylene-isoprene rubber (CSM) and / or silicone rubber (VMQ and MQ) and / or ethylene-vinyl acetate rubber (EVA) and / or their blends or non-vulcanizable elastomers such as polypropylene (PP / EPDM) and / or styrene-ethylene-butylene-styrene (SEBS) and / or polyvinylchloride-nitπlbutadiene (NBR / PVC) and / or ethylene-propylene copolymer (EPM) and / or their blends is

According to this patent, the radiation-absorbing material is a metal with atomic numbers greater than 50 or its compounds, for example zinc, antimony, elements of the lathanoid series or elements of the actinoid series or their mixtures with a particle size distribution of 20 μm to 120 μm Additions to achieve a homogeneous distribution while avoiding agglomerations are further additions in the form of powdery additives, for example in the form of silicates. Sulphides or stereates, necessary. These additives act as fillers which reduce the flexibility of the elastomer and which limit the addition of the radiation-absorbing material. The problem with such lead-free materials to date has been that their radiation absorption capacity, determined as lead equivalent at X-ray tube tension greater than 100 kV, decrease significantly, the same applies to X-ray tube voltage in the range of 30 to 60 kV. In addition, these materials can also have absorption gaps. Both limit the use of such materials as radiation protection material

It is therefore the task of specifying a lead-free radiation protection material which can be drawn into the film and whose production is technically possible and economically feasible, the lead equivalent characterizing the absorption capacity being intended to remain constant over the energy range of the radiation from approximately 40 kV to approximately 120 kV

This task is solved according to this invention by the features of the independent claim, advantageous further developments and preferred embodiments describe the subclaims

It has been shown that bismuth has such absorption properties. If metallic bismuth or a bismuth compound, such as bismuth oxide, is added in powder form to an elastomer or a plastomer alone and a flexible film is drawn therefrom as the starting material for radiation protection clothing, this has a through the lead Equally characterized absorption capacity for X-rays of an energy in the range from 30 kV to 150 kV, which is almost constant in this range. The addition of powdered bismuth / bismuth oxide is based on metallic bismuth - At about 70 to 90 percent by weight, the addition is advantageously in the range of 75 to 85 percent by weight, the rest being exclusively the elastomer or plastomer as material.

The powder form of the additional material is advantageously set such that its grain size distribution is essentially below 10 μm. It is advantageous if the grain size spectrum is such that approximately 70 percent by weight of the particles are smaller than 5 μm. With this grain size spectrum, which is significantly shifted towards smaller grain sizes compared to the known grain size distribution, the production of a homogeneous distribution is possible without further additives. Since neither powdered bismuth nor powdered bismuth oxide tends to agglomerate, no agglomeration-preventing additives are required. It has been shown that coarser particles emerge from the surface when the film is pulled and cause surface disturbances which are noticeable during further processing. With the same additives, their distribution in the elastomer can also have gaps which cause undesired X-ray radiation - enable gear

Finally, it has surprisingly been shown that bismuth and also bismuth oxide require crosslinking. This is shown by an improvement in the aging resistance of the film, since the elastomer is less prone to brittle. This property is a consequence of the fact that fewer sulfur bridges are formed during vulcanization and thus the elastic structure of the elastoeren material is increased

When using chlorinated elastomers, such as, for example, polychloroprene (CR) or polyvinylchloride-nitπlbutadiene (NBR / PVC), it has been found to be useful if no metallic bismuth is used, but bismuth oxide or other bismuth compounds which are resistant to halogens

In one embodiment of the invention, a structure has been retained in which bismuth / bismuth oxide 70-90 percent by weight Bi elastomer as matrix 30-10 percent by weight are used

In an advantageous development, the one described below has been developed

Structure preserved - bismuth / bismuth oxide 80 - 90 percent by weight Bi elastomer as a matrix 20 - 10 percent by weight In a preferred embodiment of the invention, the structure described below has proven itself: bismuth / bismuth oxide 85-90% by weight Bi elastomer as a matrix 15-10% by weight This is used in the range of tube voltages from 30 to 150 kV, depending on the thickness of the film Lead equivalent of 0.1 to 1.0 mm Pb reached.

Claims

claims 1. Lead-free radiation protection material for protective clothing, such as aprons and the like, in which radiation absorption material is incorporated into an elastomer or a plastomer on the basis of elements with an atomic number greater than 50, characterized in that the elastomer or the plastomer continues to form the film processing radiation protection material as the only additive contains metallic bismuth or bismuth compounds 2 radiation protection material according to claim 1, in particular when using halogenated elastomers or plastomers as Matπxmateπal, characterized in that bismuth oxide is provided as bismuth compound. 3 radiation protection material according to claim 1 or 2, characterized by a proportion of 70 Gewft to 90 Gewü! Bismuth in 30 Gew2 to 10 Gew ^ elastomeres or plastomeres Matπxmateπal. 4 radiation protection material according to claim 3, characterized by a proportion of 75 to 85% by weight of bismuth in 25% by weight to 15% by weight of elastomeric or plastomeric material, preferably 80 to 85% by weight of bismuth in 20% by weight of 15% by weight of elastomeric or plastomeric material. 5. Radiation protection material according to one of claims 1 to 4, characterized in that the powdered bismuth or bismuth oxide used has a grain size spectrum, with at least a proportion of 70 pounds of particles with a grain size <8 microns. preferably <4 μm. 6 radiation protection material according to one of claims 1 to 5, characterized in that as Matπxmateπal thermoplastic elastomers or plastomers, such as natural rubber (NR) and / or styrene-butadiene rubber (SBR) and / or nitπlbutadiene rubber (NBR) and / or butadiene rubber (BR) and / or ethylene / propylene terpolym (EPDM) and / or ethylene-propylene copolyer (EPM) and / or polyurethane (PUR) and / or polyisoprene rubber (IR) and / or isobutylene-isoprene rubber (IIR) and / or silicone Rubber (VMQ and MQ) and / or ethylene vinyllace tat (EVA) and / or their blends and / or a non-vulcanizable elastomer such as PP / EPDM and / or SEBS and / or NBR and / or their blends are provided. 7. Radiation protection material according to one of claims 1 to 5, characterized in that the matrix material made of halogen-containing, thermoplastic elastomers or plastomers, such as polychloroprene (CR) and / or and / or chlorosulforated polyethylene (CSM) and / or their blends and / or consists of a non-vulcanizable elastomer PVC and / or their blends. 8. Radiation protection film made of the radiation protection material according to one of claims 1 to 7, characterized in that a further film made of a (known lead-free) radiation protection material with a combination of some elements of atomic number greater than 50 is attached to the radiation drawn from this radiation protection material ,