RU2294030C2 - X-ray protection composition - Google Patents

Abstract

FIELD: ionizing emission protection materials.

SUBSTANCE: composition contains polymeric binder, shielding powdered filler based on rare-earth element compounds, and curing agent. Polymeric binder is oligourethane prepolymer, curing agent is a substance selected from amino compounds, and shielding filler is a mixture of fluorinated rare-earth element oxides selected only from light-weight group. Composition further contains tungsten carbide as modifying additive. Following proportions of ingredients are used, wt %: oligourethane prepolymer 9.10-13.50, amine curing agent 2.90-4.30, mixture of fluorinated rare-earth element oxides 29.00-49.30, tungsten carbide 32.90-59.00.

EFFECT: enhanced x-ray shielding efficiency.

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Description

The invention relates to compositions of X-ray protective materials and can be used for the manufacture of a polymer X-ray protective composition, on the basis of which X-ray protective materials are obtained as part of X-ray protective clothing, screens, floor coverings in medical rooms.

Known X-ray protective composition containing carbochain rubber as a polymeric binder (RF application No. 92003093, IPC G 21 F 1/10, publ. BI No. 13/96 of 05/10/96), a shielding filler in the form of compounds of rare-earth elements (REE) (from the group of lanthanides), and tungsten or lead oxides.

The disadvantages of the analogue are the insufficiently high efficiency of protection against x-ray radiation (RI) at a voltage on the anode of the x-ray tube of more than 100 kV due to the low content of shielding filler in the composition.

Known as the closest in technical essence and technical result to the proposed X-ray protective composition, containing as a polymer binder silicon-containing rubber, hardener, as a shielding filler, a mixture of REE oxides (RF patent No. 2138865, IPC G 21 F 1/10, publ. BI No. 27/99 of September 27, 1999).

The disadvantages of the prototype are not sufficiently high shielding efficiency from x-ray radiation at a voltage of 120 kV on the anode of the x-ray tube.

The objective of the proposed x-ray protective composition is to improve the composition of the latter in the direction of increasing the effectiveness of protection against x-ray radiation, especially in hard parts of the x-ray spectrum (RI), with a voltage of 120 kV on the anode of the x-ray tube.

A new technical result achieved by using the proposed X-ray protective composition is to simplify the composition, increase the efficiency of attenuation of X-ray radiation at a voltage of 120 kV on the anode of the X-ray tube by increasing the degree of filling of the composition, and improve physicomechanical, economic, and other performance indicators.

These tasks and a new technical result are achieved in that in the known X-ray protective composition containing a polymeric binder, a shielding powder filler based on compounds of rare-earth elements and a hardener, in accordance with the proposed X-ray protective composition as a polymeric binder, it contains an oligourethane prepolymer, as a hardener - a substance from the group of amine-containing compounds, and a mixture of fluorinated oxides is rare earth as a shielding filler elements (RE) only light group and additionally tungsten carbide as a modifying additive, with the following contents of ingredients, wt.%:

oligourethane prepolymer 9.10-13.50 amine hardener 2.90-4.30 a mixture of fluorinated rare earth oxides elements 29.00-49.30 Wolfram carbide 32.90-59.00

The essence of the proposed composition is illustrated as follows.

Initially, a polymer binder is prepared, for which a compound from the group of oligodien-urethane prepolymers is used.

Then, a mixture of powdered fluorinated REE oxides and tungsten carbide is simultaneously prepared using fluorinated oxides from only the light group of lanthanides, which simplifies the composition of the shielding filler and increases the efficiency of shielding of X-ray radiation (RI) of the X-ray protective composition in comparison with the prototype.

It can be assumed that the use of fluorinated rare-earth oxides in the composition of the X-ray protective composition in combination with tungsten carbide as compared to the prototype leads to an increase in the shielding efficiency on the hard part of the X-ray spectrum at a voltage of 120 kV on the anode of the x-ray tube due to more complete absorption of the energy of the hard part of the spectrum RI (> 69.5 keV).

The additional introduction of fluorinated REE oxides into the mixture in the composition of the shielding filler of tungsten carbide, as was shown in the course of experimental studies, contributes to the realization of a high degree of filling (up to 88 wt.%) Of the composition with shielding filler, due to which an increase in the effectiveness of X-ray protection is ensured, namely hard part of the spectrum of RI.

The resulting powdery mixture of filler components is introduced into the binder within the claimed values of the ratios of these components.

Next, the resulting composition is thoroughly mixed until the desired degree of homogeneity is achieved and combined with a hardener. A compound from the group of amine-containing compounds was selected as a hardener, since when it is used, the optimum speed and conditions of curing of the prepolymer, as well as the calculated value of viability, are achieved, which leads to the achievement of high physical and mechanical properties of the X-ray protective composition. Due to the increase in the mechanical strength of the X-ray protective material, there is no need to use fabric material used for reinforcing such products.

The use of a binder and a hardener within the claimed range of ratios ensures the required component compatibility and uniformity of the finished material, as a result of which the claimed level of shielding efficiency from radiation sources at a voltage of 120 kV on the anode of the x-ray tube is achieved.

The use of these reagents outside the claimed limits of the ratios leads to a decrease in the physicomechanical parameters of the composition due to underestimation of the finished product (in the case of insufficient binder or hardener) or its premature curing (in the case of an excessive amount of hardener, filler and lack of binder).

The resulting composition is loaded into a press and molding is performed at the design pressure and temperature. Finished samples are subjected to control tests.

It is experimentally shown that when using all of these components in the claimed range of ratios, an increase in the efficiency of attenuation of x-ray radiation at a voltage of 120 kV on the anode of the x-ray tube is provided, and physical and mechanical properties are improved. In addition, the exclusion from the composition of the composition of a significant amount of REE oxides and their replacement with other REE compounds in combination with tungsten carbide helps to simplify the composition and increase the warranty period of storage of products based on them and significantly reduce their cost.

Thus, the use of the proposed X-ray protective composition for the manufacture of X-ray protective material provides an increase in the attenuation of X-ray radiation at a voltage of 120 kV on the anode of the X-ray tube, and an improvement in physical, mechanical, economic, and other performance indicators.

The possibility of industrial implementation of the proposed x-ray protective composition is confirmed by the following implementation examples.

Example 1. In laboratory conditions, the implementation of the composition of the proposed x-ray protective composition was carried out using a grinding machine such as a paddle (or other mechanical machine) mixer, the working capacity of which was filled with the prepared composition.

The preparation of the X-ray protective composition was carried out by sequential dosing of a binder, then a mixture of powdered fillers in the form of fluorinated oxides of a light REE group (La, Ce, Pr, Nd) and tungsten carbide, and then a hardener. Before introducing into the binder, the filler was dried at a temperature of 150 ° C for 2 hours with constant stirring. The control of the degree of homogeneity and the consistency of the paste was measured according to GOST 6589-90. Homogeneity was considered achieved if the relative errors in determining the pycnometric density of the mixture and the starting components were of the same order. It is shown that the filler is chemically bonded to the polymer.

Under the conditions of this example, an oligourethane prepolymer was used as a polymer binder, an amine compound as a hardener, and only light group fluorinated rare-earth oxides as additional hardener compounds and, additionally, tungsten carbide.

As the fluorinated oxides of the light group under the conditions of this example, a mixture of the following compounds was used (empirical formulas of a general form are given):

(La ₂ O ₃ ) _{mF n} ; (CeO ₂ ) _{mF n} ; (Pr ₆ O ₁₁ ) _m · F _n ; (Nd ₂ O ₃ ) _m · F _n .

Mass ratios between these components lie in the following ranges, wt.%, Respectively 7: 16: 1: 4.

All components were mixed in a grinder.

Then the resulting composition is placed in the molding cavity of the press and subjected to molding under pressure ≈6.0 MPa, at temperatures from + 15 ° C to + 30 ° C for 24 hours. Obtained on the basis of the proposed x-ray protective composition, the samples were subjected to control tests. Determination of X-ray protective properties of the material in accordance with GOST R51532-99.

The test results are summarized in the table, which shows the data in the conditions of examples 1-7 specific implementation of the proposed composition.

As can be seen from the table, when using the proposed composition in the composition of the X-ray protective material provides a simplification of the composition, higher x-ray economic and physico-mechanical indicators than is achieved in the prototype, namely, the increased efficiency of the shielding of the radiation spectrum with a voltage on the anode of the x-ray tube of at least 120 kV, mechanical strength up to 5.8 MPa, simplified composition and reduced cost, maximum elasticity, elongation of 1.5 times, higher adaptability in the manufacture, the tensile strength is 5.81-4.3 MPa, the elongation in tension is 43.8-77.5%, the degree of filling is up to 88 wt.%.

Table Name and composition of components, wt.%, Physo-fur. indicators Implementation examples one 2 3 four 5 6 7 1. Oligodiurethane prepolymer, wt.% 9.10 13.50 11.2 10.30 10.70 13.00 12.00 2. Amine hardener, wt.% 2.9 4.30 3.6 3.30 3,50 4.10 3.8 3. A mixture of REE fluorinated oxides, wt.% 29.00 49.30 44,4 34.60 38.60 43.20 37.90 4. Tungsten carbide, wt.% 59.00 32.90 40.8 51.80 47.20 39.70 46.3 5. Density, g / cm ³ 5.00 3.68 4.13 4.66 4.41 3.86 4.13 6. Lead equivalent with a sample thickness of 1.1 mm * - - 0.4 - - - - 7. Mechanical strength, MPa - 4.3 5.5 5.2 5.8 5.35 5.8 8. The relative elongation in tension,% - 77.5 41,4 77.5 43.8 71.6 61.7 9. The degree of filling,% 88.0 82,2 85,2 86.4 85.8 82.90 84.2 * The lead equivalent of the prototype is 0.35 mm Pb with a thickness of 1.8 mm

Claims (1)

X-ray protective composition containing a polymeric binder, a shielding powder filler based on compounds of rare-earth elements and a hardener, characterized in that it contains an oligourethane prepolymer as a polymeric binder, a substance from the group of amine-containing compounds as a hardener, and a mixture of fluorinated oxides as a shielding filler rare earth elements only light group and additionally tungsten carbide as a modifying additive in the following soda Zhaniya ingredients, wt.%: Oligourethane prepolymer 9.10-13.50 Amine hardener 2.90-4.30 A mixture of fluorinated rare earth oxides elements 29.00-49.30 Wolfram carbide 32.90-59.00