RU2111558C1 - Pasty material for shielding against radioactive radiation - Google Patents

Abstract

FIELD: radiation shielding. SUBSTANCE: material has plastic synthetic mass, filler, plasticizer, and surface-active agents. Used as plasticizer is butadiene or butadiene-nitrile, or butyl-nitrile rubbers, or butyl rubber. Used as filler is lead oxide or lithium-6 fluoride, or boron, or boron compounds, or titanium hydride, or powdered lead, or bismuth oxide, or uranium dioxide, or thorium dioxide, or tungsten, or tungsten trioxide, or oxides of rare-earth elements. Used as plasticizer may be also dibutyl phthalate or transformer oil, or industrial oil, or dibutyl sebacinate, or dioctyl sebacinate. Used as surface-active agents are cation-exchange resin 7 and lecithin. EFFECT: provision for shielding against various kinds of radiation with desired degree of filling with target component.

Description

 Usage: in nuclear technology, in particular in the development of materials for protection against various types of radiation. The paste-like material for protection against radioactive radiation allows you to fill various products of any geometric shape, cable shafts, etc. Since the paste-like material does not cure in time, it can be repeatedly used for protection elements.

 Known elastic material for protection against x-ray and gamma radiation based on a polymer matrix [1].

 The disadvantage of these materials is the inability to use them for products of complex configuration, since they are thermoplastics and are available in the form of sheets or profiles.

 The closest technical solution is plastic masses for shielding radioactive radiation [2].

 The protective material contains lead oxide as a filler and a plastic synthetic material. The disadvantages of this material are the low filler content, which reduces the protective properties and the limited type of protection (x-ray and gamma radiation), which narrows the scope of the material.

 The aim of the invention is the creation of pasty materials from various types of radiation (x-ray, gamma, neutron) with a given degree of filling of the target component, including up to 96 wt.%.

 The goal is achieved by introducing new components, changing the ratio of components and temperature regimes of mixing materials.

The essence of the proposed technical solution lies in the fact that as a polymeric binder for a paste-like protective material from radioactive radiation, butadiene or butadiene-nitrile or butyl rubber or butyl nitrile or divinyl styrene rubbers, plasticized with plasticizers (dibutyl phthalate or dibutyl-butyl butenocinate or and as a surface-active substance (surfactant) - lecithin or cationate-7 in the following ratio of compo entov, wt.%
Plastic synthetic mass mixed with a plasticizer with a rubber ratio of 8-20%, a plasticizer of 80-92% - 4 - 40
Surfactant - 0.1 - 0.5 - Over 100
The introduction of a polymer base consisting of rubber plasticized with a plasticizer in a certain ratio into the material for radiation protection allows to improve the wetting and enveloping of the filler particles, the degree of homogeneity of the mixture and to obtain the optimal viscosity for the composition of materials of a given degree of filling.

 Introduction to the composition of the material for protection against radiation of a surface-active substance (SAS) also improves the process of wetting the particles of the target filler, which allows to maximize the degree of filling (for example, for tungsten up to 95 - 96 wt.%.

 The introduction of fillers to protect against radiation (lithium-6 fluoride, boron and its compounds, titanium hydride, powdered lead, bismuth oxide, uranium dioxide and thorium dioxide, rare earth oxides, tungsten and its trioxide) provides it in each case efficiency from various types of ionizing radiation.

 The ratio of the components of the polymer base and filler allows you to get pasty materials with the desired viscosity and flowability.

 The essence of the proposed technical solution is illustrated by examples of the preparation of compositions.

 Example 1. Preparation of a paste containing 90% bismuth oxide.

Take 9.2 g of dibutyl phthalate, add 0.8 g of nitrile butadiene rubber (SKN-26), 0.1 g of lecithin. Mix the mass in a paddle mixer at a temperature of 80 - 100 ^o C to obtain a homogeneous mass; add 90 g of bismuth oxide and mix until a homogeneous mass. Then the resulting paste-like material is discharged. A paste is obtained with an attenuation coefficient of 0.30 at a radiation energy (E _γ ) of 1 MeV, a density of ~ 5140 kg / m ³ , a viscosity at 20 ^o C of ~ 85000 pz, and a spreadability (Δ) of 0.8 - 0.9.)
Example 2. The preparation of a paste containing 65% amorphous boron.

Take 32.2 g of dibutyl phthalate, add 2.8 g of nitrile butadiene rubber (SKN-26), 0.1 lecithin. Mix the mass in a paddle mixer at 80 - 100 ^o C to obtain a homogeneous mass; 65 g of amorphous boron are added and mixed until a homogeneous mass is obtained. Then the resulting paste-like material is discharged. Get a paste with an absorption cross section of 44.63 cm ^-1 , a density of ~ 5140 kg / m ³ , a viscosity at 20 ^° C of 90,000 pz, a spreadability of 0.8 - 0.9.

 Example 3. Preparation of a paste containing 68% lithium fluoride.

Take 29.44 g of dibutyl phthalate, add 3.56 g of nitrile butadiene rubber (SKN-26), 0.1 lecithin. Mix the mass in a paddle mixer at 80 - 100 ^o C to obtain a homogeneous mass; add 68 g of lithium fluoride and mix until smooth. Then the resulting paste-like material is discharged. Get a paste with a cross section of 2.72 cm ^-1 , a density of ~ 5140 kg / m ³ , a viscosity at 20 ^o C ~ 90,000 pz, a spreadability of 0.8 - 0.9.

 The proposed technical solution allows you to get pasty protective materials from various types of ionizing radiation with the necessary viscosity and spreadability, which are required to solve specific problems.

Claims (1)

A paste-like material for protection against radioactive radiation, including a plastic synthetic mass and a filler, characterized in that butadiene, or nitrile butadiene, or nitrile butyl rubber, or styrene butadiene rubber, or styrene rubber are used as filler, and oxide is used as filler lead, or lithium-6 fluoride, or boron, or boron compounds, or titanium hydride, or powdered lead, or bismuth oxide, or uranium dioxide, or thorium dioxide, or tungsten, or trioxide tungsten, or oxides of rare earth elements, wherein the program further includes dibutyl phthalate or transformer oil or industrial oil or dibutyl sebacate, or dioctyl sebacate as a plasticizer and kationat-7 or lecithin as surface-active substances in the following ratio, wt.%:
Plastic synthetic mass mixed with a plasticizer at a ratio of 8 - 20% rubber / 92 - 80% plasticizer - 4 - 40
Filler - 60 - 96
Surfactant - 0.1 - 0.5 - Over 100% n