RU2138865C1 - X-radiation protective compound - Google Patents

Abstract

FIELD: radiation-shielding polymeric materials; protection of personnel operating X-ray units. SUBSTANCE: 19-28 mole percent of dimethyl siloxane of molecular mass 15•10³-70•10³, 0.8-1.25 mass percent of catalyst (tin diethyl dicaprylate IV dissolved in tetraethoxysilane), ), and filler composed of mixture of rare- earth elements, antimony (III) and yttrium with mass proportion of oxides of rare-earth elements and amount of antimony (III) and yttrium being 1:(1.15-1.59) and mass proportion of antimony (III) oxide and yttrium oxide being 1:(0.016-0.088) are mixed up on rolls for 10-30 minutes at room temperature and polymerized under cold curing conditions; filler has in its composition 9.0-16.0 mass percent of oxides of light elements (lactan, cerium, neodymium), 7.0-20.0 mass percent of oxides of medium elements (samarium, europium, gadolinium, terbium), 7.0-23.0 mass percent of oxides of heavy elements (dysprosium, holmium, erbium, thulium), 53.1-57.3 mass percent of antimony oxide, and yttrium oxide - the rest. Polymeric compound is noted for low content of toxic materials, mechanical strength of about 3.0 MPa, effective reduction of X-radiation with boundary energy up to 80 keV characterized by lead equivalent of 0.57 mm of lead at material specimen thickness of 2 mm; it may be found useful for manufacturing protective clothing. EFFECT: improved physical and mechanical characteristics of compound. 2 cl, 1 tbl

Description

 The alleged invention relates to polymeric materials for protection against radiation and can be used in various fields of science and technology, as well as in medicine to protect personnel of x-ray units.

 Known x-ray composition / application of Great Britain N 2118410, publ. 10.26.83 / containing a polymer binder, a powdery filler, which contains lead.

 The disadvantages of the known composition include the high mass and toxicity of the filler, which reduces the quality and does not provide the ability to manufacture protective clothing.

 Known closest in technical essence to the proposed composition for radiation protection, including a polymer silicon-containing binder, a cold curing catalyst and a powdery filler / US patent N 4176093, MKI G 21 F 1/12 /, which contains boron and / or its connections.

 The disadvantages of the known composition include low physical and mechanical properties (elasticity, mechanical strength) of the material obtained from it, low efficiency of protection against x-ray radiation (RI) due to the chemical nature of the filler, which reduces the quality and makes it unsuitable for the manufacture of protective clothing.

 The task of the authors of the invention is to develop a composition of a highly effective X-ray protective composition, characterized by a sufficiently high X-ray protection efficiency with a radiation spectrum of known X-ray installations operating at ≈ 100 keV at the anode (a spectrum close to Planck's), and the operational characteristics of the material based on this composition, corresponding to the climatic conditions of the middle band and the conditions of exposure to repeated bending and other mechanical influences, as well as one for the manufacture of protective clothing.

 A new technical result achieved by using the proposed composition for the manufacture of X-ray protective material, compared with the prototype, is to provide sufficient efficiency of attenuation of radiation and increase physical and mechanical properties, increase manufacturability and the possibility of manufacturing X-ray protective clothing.

The task and a new technical result are ensured by the fact that in the known composition, including a polymer silicon-containing binder, a powdered shielding filler, a cold curing catalyst, according to the proposed composition contains dimethylsiloxane rubber with a molecular weight of 15 • 10 ³ - 70 • 10 ³ , tin diethyl dicaprylate ( IV) in a solution of tetraethoxysilane as a catalyst, rare earth oxides (REE), antimony (III) and yttrium oxides as a powdery filler, with mass the ratio of the number of REE oxides to the amount of antimony (III) and yttrium 1 oxides: (1.15-1.59) and the mass ratio of the amount of antimony (III) oxide and the amount of yttrium oxide 1: (0.016-0.088), with the following composition components , wt%:
Dimethylsiloxane rubber - 19.0-28.0
Tin (IV) diethyl dicaprylate in a tetraethoxysilane solution - 0.8-1.25
Filler containing a mixture of REE oxides and antimony (III) and yttrium oxides - Else
In addition, the filler of the proposed composition contains light REE oxides - lanthanum, cerium, neodymium, praseodymium, medium rare earth oxides - samarium, europium, gadolinium, terbium and heavy REE oxides - dysprosium, holmium, erbium, thulium, ytterbium and antimony oxides ( III) and yttrium in the following ratio of ingredients, wt.%:
REE light oxides - 9.0-16.0
oxides of medium REE - 7.0-20.0
heavy REE oxides - 7.0-23.0
antimony (III) oxide - 53.1-57.3
yttrium oxide - The rest
An additional technical result is to increase the efficiency of attenuation of X-ray, due to the effective absorption of energy of adjacent sections of the X-ray spectrum by each component of the filler, which is determined by the structural features of the atoms of REE, antimony and yttrium, which are part of these oxides.

 The proposed composition is prepared by mixing polymerizable at room temperature dimethylsiloxane rubber with components of a powdery filler and a catalyst in the claimed concentration range. It is possible to pre-mix the components of the filler by known methods, for example, in a ball mill.

 The boundary values of the filler content were determined experimentally, which are necessary to simultaneously provide the required effectiveness of attenuation of radiation, high mechanical strength and elasticity, acceptable toxicity and weight. Moreover, it was found that when the content of tin (IV) diethyl dicaprylate was exceeded, a sharp decrease in elasticity and mechanical strength, manufacturability in the manufacture of protective clothing based on the composition was observed. When you go beyond the specified lower limit of the catalyst content, the advantages of the proposed composition are lost, because in this case, product design was not observed, which led to inoperability of the material.

 A decrease in the content of powdered filler containing REE, antimony and yttrium oxides that absorb RI energy reduced the efficiency of RI attenuation, and exceeding their content over the proposed range of values (mainly relative to the antimony (III) oxide content leads to a decrease in mechanical strength and elasticity, while antimony oxide is likely to exhibit modifier properties.

 In the case of using a composition containing all components within the claimed range of ratios, a mechanical strength of 2.9-3.6 MPa is realized, a sufficiently high RI attenuation efficiency (the lead equivalent of the RI attenuation generated by the tube of an RUM-20 x-ray unit at an anode voltage of 80- 100 kV according to the methodology of IEC PK-62B is 0.57 mm of lead with a thickness of the investigated material sample of 2 mm).

 In addition, it was confirmed that the presence of REE oxides, antimony (III) oxides, and yttrium in the composition provides an increase in the attenuation of RI due to an increase in the number of sections of the RI spectrum and their overlap with the most complete and effective absorption of each filler component. The optimal ratios between the groups of REE oxides and antimony (III) oxides, which are characterized by the corresponding cross sections for the absorption of RI energy, were established. In this case, antimony and yttrium most effectively absorb the “soft” part of the X-ray tube X-ray spectrum. The total energy absorption of radiation significantly exceeds the capabilities of the prototype and other X-ray protective materials, which include individual representatives of REE oxides from those proposed in this composition. This allows you to significantly expand the scope of the invention.

 In the process of manufacturing samples for measuring the physicomechanical characteristics, the finished composition was applied to the layers of cotton fabric, while the manufacturability of the composition, the necessary pot life, was ensured by a sufficient amount of dimethylsiloxane rubber, a catalyst, and, as experiments showed, the amount of antimony (III) oxide, based This fact specified the ranges of their ratios.

 Samples of the material were tested for X-ray and toxicity. Tests for the toxicity of the composition were carried out in VNIIIMT, Moscow (test report dated 13.12.93). The test results indicated the absence of toxicity in the X-ray protective material.

 The possibility of industrial implementation of the invention is confirmed by the following specific examples of implementation.

Example 1. To obtain a composition, a mixture of a powdered filler in the claimed proportions was first prepared, mixed with a polymerizable base - dimethylsiloxane rubber and a catalyst. In the conditions of this example, synthetic molecular weight SKTN grade G, molecular weight 15 • 10 ³ - 70 • 10 ³ in the amount of 19 wt.% (In the composition) was used.

An organometallic compound m. N 18, which is a solution of tin (IV) diethyl dicaprylate in a solution of tetraethoxysilane (trade name ethyl silicate-32) (TU 6-02-805-78) in the amount of 1.25 wt.%, Was chosen as a cold cure catalyst.
A separately prepared mixture of powdered filler was taken in an amount of 79.75 wt.%, While yttrium oxide is a natural impurity in the heavy group of rare-earth oxides.

 All components of the composition were mixed and the mixture was rolled on rollers for 10-20 minutes at room temperature. For the manufacture of prototypes, the composition was applied to a woven base (voile GOST 12239-79).

 Further, in examples 2-6, under the conditions of example 1, compositions were prepared using other specific ratios of components from the claimed range of values. Data on the compositions and their properties are summarized in table.

 The table shows that the use of the composition of the proposed composition of all these components in the claimed ranges of their content provides a material with high attenuation of radiation, physical and mechanical properties, manufacturability, which allows it to be used in the manufacture of protective clothing.

Claims (1)

1. X-ray protective composition comprising a polymer silicon-containing binder, a cold curing catalyst, a powdery filler, characterized in that it contains dimethylsiloxane rubber with a mol.m. 15 • 10 ³ - 70 • 10 ³ as a binder, the organometallic compound is tin IV diethyl dicaprylate in the form of its solution in tetraethoxysilane as a catalyst, and the filler contains a mixture of rare-earth oxides and antimony (III) and yttrium oxides with a mass ratio of rare-earth oxides elements to the amount of antimony (III) and yttrium oxides 1: (1.15-1.59) and the mass ratio of the amount of antimony (III) oxide and the amount of yttrium oxide 1: (0.016 - 0.088) in the following components, wt.%:
Dimethylsiloxane rubber - 19.0 - 28.0
Tin (IV) diethyl dicaprylate in tetraethoxysilane solution - 0.8 - 1.25
Filler containing a mixture of rare earth oxides and antimony (III) and yttrium oxides - Else
2. The x-ray protective composition according to claim 1, characterized in that it contains oxides of light rare-earth elements — lanthanum, cerium, neodymium, praseodymium, oxides of medium rare-earth elements — samarium, europium, gadolinium, terbium, oxides of heavy rare-earth elements — dysprosium , holmium, erbium, thulium, ytterbium, as well as antimony (III) and yttrium oxides in the following ratio of ingredients, wt.%:
Oxides of light rare earths - 9.0-16.0
Oxides of medium rare earths - 7.0-20.0
Heavy rare earth oxides - 7.0-23.0
Antimony (III) oxide - 53.1-57.3
Yttrium Oxide - Else

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