HU197114B - Protective wall for screening x-ray and gamma radiation - Google Patents

Abstract

An X-ray and gamma radiation shielding structure comprises a laminated construction with n layers of different materials, each of the first n-1 layers comprising an element which converts (part of) the radiation to be shielded or the sec. radiation emitted by the preceeding preceding layer into radiation of energy above the energy level defined by the K edge of the next layer.

Description

BACKGROUND OF THE INVENTION The present invention relates to a protective wall for the screening of X-ray and / or gamma radiation.

For shielding X-rays or gamma rays, a protective wall made of metal, particularly lead, of suitable absorbency is used, the thickness of which is selected according to the desired radiation attenuation.

The walls are often made of bricks. In order to increase the mechanical strength of the barrier walls, AT-A-200 234 has already proposed a structure in which one or more lead sheets are inserted between non-metallic fibrous sheets and glued together. GB 2117 964 also discloses bricks for radiation shielding walls in which a radiation absorbing metal, e.g. a layer of lead material is sandwiched between two layers of plastic.

BACKGROUND OF THE INVENTION The present invention relates to a protective wall in which different radiation absorbing materials are combined in a layered structure.

The invention thus provides a screen for shielding X-ray and / or gamma radiation, which comprises a layered structure and according to the invention comprises at least n different layers of radiation absorbing material, where n is greater than or equal to two and the first η-1 each layer comprising an element transposing at least a portion of the X-ray or gamma radiation to be shielded or the secondary radiation emitted by the previous layer into an energy range above the energy level defined by the edge K of the element in the next layer.

According to the invention, it is expedient to choose the element of the first layer so that its K edge is less than the maximum energy of the X-ray or gamma radiation to be shielded, while the second layer - and optionally the elements of the further layers. so that its K edge is between the K edge and the Li edge of the element in the previous layer, preferably L1 near the edge.

Advantageously, the invention can be made so that the number of layers of different materials is two or three. The first layer may contain uranium, lead, gold, platinum, iridium, osmium, rhenium, tungsten and / or tantalum. The second layer may contain tin, myals, cadmium, silver, palladium, radium, molybdenum and / or niobium. If there is a third layer, it may contain zinc, copper, nickel, cobalt, iron, manganese, chromium, vanadium and / or titanium.

It is advantageous for practical implementation. a triple layer combination wherein the first layer contains lead or tungsten, the second layer tin, cadmium or molybdenum, and the third layer zinc, copper, nickel, iron or chromium. It is particularly advantageous if the first layer contains lead, the second layer tin and the third layer copper.

In many cases, a dual layer combination in which the first layer contains lead and the second layer contains tin, cadmium or molybdenum may be sufficient. For lower energy radiation, a combination of two layers where the first layer contains tin and the second layer contains copper may be appropriate.

It is very advantageous if the protective wall according to the invention is constructed of thin layers in order to increase the absorption effect. This may be done by one or more layers of thin layers of the same material with separating layers between them. The separating layers may be oxide or aluminum of adjacent thin layers, which improves the absorption properties of the barrier wall as an X-ray or gamma-scattering layer. The thin-layered structure according to the present invention may also be implemented in that the protective wall comprises a plurality of layers of layers, each consisting of n thin layers of different materials. In this case, there is no need for separate separating layers, however, aluminum thin scattering X-ray or gamma radiation is preferred here, e.g. it can be placed in layers or in a few layers.

The protective wall according to the invention, at least partly made of thin layers, has a thickness of less than 150 µm, preferably less than 50 µm. With a given barrier wall thickness, the absorbency increases with decreasing the thickness of the thin layers, i.e. increasing the number of thin layers, so a 0.1 to 20 µm layer thickness is particularly preferred. The thin layers in the barrier wall of the present invention need not be uniform in thickness. The beneficial effect of thin films on the barrier wall of the present invention is believed to be based on the fact that the potential barrier at the interfaces of the thin layer is much higher than the potential barrier inside the thin layer and therefore acts as an interface for moving charges. Thus, the thin layer inhibits the electrons generated by both the Compton effect and the photo effect.

In the protective wall of the present invention, the thin layers may be applied to one side of a copper or chromium steel sheet on a substrate, preferably on the radiation side to be shielded. However, thin layers can be placed between two substrates. For example, thin layers made by rolling can be bonded or pressed to each other and to one or two substrates. The thin layers on the substrate can also be produced by vacuum evaporation.

An advantage of the protective wall according to the invention is that a particular radiation protection task can be accomplished with less weight and thickness. The protective wall can be used in any area of radiation protection. It can be used, for example, as a cover for X-ray tubes, as a radiation shield or as clothing, for radiation shielding of instruments or experimental equipment. It can be manufactured in a rigid or flexible design.

The invention will now be described with reference to the embodiments illustrated in the drawings, wherein:

Figure 1 is a schematic view of a protective wall according to the invention, a

Figures 2 and 3 are schematic views of one embodiment of a protective wall according to the invention made of thin layers, and

Fig. 4 is a schematic view of an embodiment of a protective wall according to the invention partially constructed of thin layers.

In the figures, the same or the same. elements having the same function are denoted by the same reference number.

In Fig. 1, an X-ray or gamma-shielding wall from an arrow direction 7 comprises a protective layer 8 and layers 11, 12, ... In of different materials, where n is the number of layers.

The material of the first radiation-facing layer 11 should be selected in accordance with the maximum radiation energy, so that the element K of the layer 11 has a smaller edge K. Table 1 contains the elements from which in most practical cases this element can be selected. In the following, the item number is also indicated before the item mark. Table 1 gives the K-edge and L-edge of the element and the most likely energy levels al and a2 corresponding to the K-L transition of the excited element, all in keV. The most important elements for practical application are the 92U, 82Pb and 74W. The use of the 92U must also take into account its own radioactive radiation.

The element of the second layer 12 should be chosen such that its K edge is in the energy range between the K and L1 edge of the first layer 11 element, preferably as close as possible to the edge Li.

Table 1

Element Wakes al the 2 Find 92U 115.6 98.4 94.6 21.7 82Pb 88.0 75.0 72.8 15.9 79Au 80.7 68.8 67.0 14.3 78Pt 78.4 66.8 65.1 13.9 77Ir 76.1 64.9 63.3 13.4 76Os 73.9 63.0 61.5 13.0 75Re 71.7 61.1 59.7 12.5 74W 69.5 59.3 58.0 12.1 73Ta 67.4 57.5 56.3 11.6

Table 2 Element Wakes al the 2 Find 50Sn 29.2 25.3 25.0 4.4 49In 27.9 24.2 24.0 4.2 48Cd 26.7 23.2 23.0 4.0 47Ag 25.5 22.2 22.0 3.8 46Pd 24.3 21.2 21.0 3.6 45Rh 23.2 20.2 20.0 3.4 44Ru 22.1 19.3 19.1 3.2 42Mo 20.0 17.5 17.4 2.8 41Nb 19.0 16.6 16.5 2.7

Table 2 contains elements suitable for layer 12 when the layer 11 element is selected according to Table 1. It can be seen that in principle, any of the elements 50Sn ... 44Ru can be selected for the 92U element of the layer 11, since the latter have a K edge greater than the 92U L [edge]. In principle, for any element 82Pb ... 73Ta of layer 11, any element 50Sn ... 41Nb can be selected, since even the Li edge of 82Pb has a larger K edge of 41Nb.

The element of the third layer 13 should be selected so that its edge K is in the energy range between the edge K and Lj of the element of the second layer 12, preferably as close as possible to the edge Li. Table 3 gives the elements and their K edges that are suitable for the purpose of layer 13 when the element of layer 12 is selected according to Table 2.

Table 3

Element Wakes 30Zn 9.7 29Cu 9.0 28Ni 8.3 27Co 7.7 26Fe 7.1 25Mn 6.5 24Cr 6.0 23V 5.4 22Ti 5.0

It can be seen that for any element 50Sn ... 41Nb of layer 12, in principle, any element 30Zn ... 22Ti of Table 3 can be selected since even the edge L of 50Sn has a larger 22ΊΊ K edge.

For practical use, the triple layer combination of 82Pb-50Sn or 48Cd-29Cu or 28Ni and 74W-50Sn or 42Mo-30Zn or 24Cr is preferred. In many cases, the 82Pb-5 () Sn-29Cu triple layer combination is suitable and inexpensive.

It is not necessary for the protective wall according to the invention to have a third or further layer 13, ... In. For example, 82Pb-50Sn or 48Cd or 42Mo dual layer combination may be used.

For soft radiation (30-88 keV), a dual layer combination is preferred, wherein the first layer 11 element is 50Sn and the second layer 12 element is 29Cu.

Figure 2 shows an embodiment where each layer 11, 12, ... In is constructed of thin layers. Thus, layer 11 consists of thin layers 21, 22, ... 2k of uniform material, layer 12 consists of thin layers 31, 32, ... 3j of uniform material, and layer In consists of thin layers 41, 42, ... 4i of uniform material. which are on 5 media. The substrate 5 is on the radiation side and also serves as a protective layer. Thin layers of the same material include separating layers not shown, e.g. the oxide of the thin layer, or aluminum, which also increases the shielding effect of the protective wall as a thin layer that emits X-ray or gamma radiation. Fig. 2 is not to scale for illustration purposes, nor is Figures 3 and 4 similarly to scale.

In Figure 3, the material of the first thin layer 111, the second thin layer 121 and the third thin layer 131 is selected according to the configuration of Figure 1 and forms a group of layers. In the protective wall, m of these groups of layers are placed one after the other. A 111, 121, 131; 112, 122, 132; ... llm, 12m, 13m thin layers are sandwiched between two substrates 5 and 6. In this arrangement, there is no need for a separate separating layer between the thin layers, since the adjacent thin layers are each of different materials.

Figure 4 shows an embodiment where only the first layer 11 is made up of thin layers 21, 22, ... 2k and the other layers 12, 13, ... In are of the structure shown in Figure 1.

The protective wall according to the invention may be constructed differently than shown in the drawings. For example, it can be made in the form of a flexible sheet which can be made into protective clothing or which can also be formed as a non-planar protective cover.

Claims

Claims (25)

A shielding wall for X-ray and / or gamma radiation shielding, comprising at least n different layers (11, 12, ... In) of different absorbent material, wherein n is greater than or equal to two, and each of the first η-1 layers (eg 12) from the direction of radiation transmission is at least a portion of the x-ray or gamma radiation to be shielded, or at least part of the secondary radiation emitted by the previous layer (eg 13); element transposing an energy range above the energy level defined by its edge K. (Priority: October 22, 1985) The screen according to claim 1, characterized in that the first layer (11) comprises a K-edge element that is less than the maximum energy of the X-ray or gamma radiation to be shielded. (Priority: October 22, 1985) The barrier according to claim 1 or 2, characterized in that the second layer (12), and optionally each of the further layers (13, ... In), comprises an element having an edge K in the preceding layer (12). 11) the existing element is in the energy range between K edge and Lí edge. (Priority: April 30, 1986) The barrier according to claim 3, characterized in that the second layer (12), and optionally each of the further layers (13, ... In), comprises an element having an edge K in the previous layer (11). element is near edge of Lj. (Priority: April 30, 1986) 5. A barrier according to any one of claims 1 to 3, wherein n is three. (Priority: October 22, 1985) A barrier according to claim 5, characterized in that the first layer (11) comprises uranium, lead, gold, platinum, iridium, osmium, rhenium, tungsten and / or tantalum. (Priority: 4/30/1986) The barrier according to claim 6, characterized in that the second layer (12) comprises tin, indium, cadmium, silver, palladium, rhodium, ruthenium, molybdenum and / or niobium. (Priority: April 30, 1986) The barrier according to claim 7, characterized in that the third layer (13) comprises zinc, copper, nickel, cobalt, iron, manganese, chromium, vanadium and / or titanium. (Priority: April 30, 1986) The barrier according to claim 5, characterized in that the first layer (11) contains lead or tungsten, the second layer (12) contains tin, cadmium or molybdenum and the third layer (13) contains zinc, copper, iron or chromium. . (Priority: April 30, 1986) The barrier according to claim 5, characterized in that the first layer (11) comprises lead, the second layer (12) tin and the third layer (13) copper. (Priority: October 22, 1985) 11. A barrier according to any one of claims 1 to 3, characterized in that n is two and the first layer (11) contains lead and the second layer (12) contains tin, cadmium or molybdenum. (Priority: April 30, 1986) 12. A barrier according to any one of claims 1 to 3, characterized in that n is two and the first layer (11) contains tin and the second layer (12) contains copper. (Priority: April 30, 1986) 13. Figures 1-12. A barrier according to any one of claims 1 to 4, characterized in that it comprises a plurality of layers of layers, each of which consists of said n layers (111, 121, 131) of different material, each layer (111, 13m) being formed by a thin layer. (Priority: April 30, 1986) 14. Figures 1-12. Protective wall according to claims 1 to 3, characterized in that at least one layer (eg 11) consists of thin layers (eg 21, 22, ... 2k) of uniform material, between which there are separating layers. (Priority: October 22, 1985) A protective wall according to claim 14, characterized in that only the first layer (11) is made up of thin layers (21, 22, ... 2k). (Priority: April 30, 1986) The barrier according to claim 14, characterized in that each layer (11, 12, ... In) is made of thin layers (21, 22, ... 2k; 31, 32, ... 3j; 41, 42). , ... 4i) is built. (Priority: October 22, 1985) 17. A barrier according to any one of claims 1 to 3, characterized in that the separating layers are made of oxide or aluminum of the adjacent thin layer. (Priority: April 30, 1986) 18. A, 13-17. Protective wall according to any one of claims 1 to 4, characterized in that the thin layers (21, ... 2k; 31, ... 3j; 41, ... 4i; 111, 121, ... 13m) have a thickness of less than 150 µιη, preferably less than 50 μπι. (Priority: April 30, 1986) • 19. A 13-17. Protective wall according to any one of claims 1 to 3, characterized in that the thin layers (21, ... 2k; 31, ... 3j; 41, ... 4i; 111, 121, ... 13m) have a thickness of 0.1 to 20 μηι . (Priority: October 22, 1985) 20. A, 13-19. A process according to any one of claims 1 to 4 1971 i4 protective wall, characterized in that between the thin layers (21, ... 2k; 31, ... 3j; 41, ... 4i; 111, 121, ... 13m) there are also thin layers of radiation, preferably of aluminum. (Priority: October 22, 1985) 21, pp. 13-20. Protective wall according to any one of claims 1 to 4, characterized in that the thin layers (21, 22, ... 4i) are applied to one side of a substrate (5). (Priority: October 22, 1985) Shield according to claim 21, characterized in that the substrate (5) is a copper or chromium steel plate on the side to be shielded from the radiation side. (Priority; October 22, 1985) 23, pp. 13-20. Protective wall according to any one of claims 1 to 3, characterized in that the thin layers (111, 121, ... 13m) are disposed between two substrates (5, 6). (Priority: 30.4.1986) The protective wall according to claim 21, characterized in that the thin layers (21, 22, ... 4i), optionally the separating layers and the spray layers, are applied to the substrate (5) by vacuum evaporation. (Priority: April 30, 1986) 25, pp. 21-23. Protective wall according to any one of claims 1 to 4, characterized in that the thin layers (21, 22, ... 4i; 111, 112, ... 13M) are bonded or pressed to each other and to one or two substrates (5, 6). (Priority: April 30, 1986)