RU2612304C1 - Thermal protection material - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: invention relates to thermal protection materials, based on ethylene-propylene-diene elastomers, intended for use in aircraft and spacecraft engineering. The thermal protection material on the basis of ethylene-propylene-diene elastomer comprises sulphur, zinc oxide, stearine, carbon black, tetramethylthiuram disulphide, 2-mercaptobenzothiazole, pine rosin, white carbon and phosphorus-boron-nitrogen-bearing oligomer; the material also contains cenospheres, pretreated with a phosphorus-boron-nitrogen-bearing oligomer at 80°C, wherein the components ratio is as follows, pts.wt.: ethylene-propylene-diene elastomer-40 100,0, sulphur 2.0, tetramethylthiuram disulphide 0.75, 2-mercaptobenzothiazole 1.5, zinc oxide 5.0, stearine 1.0, carbon black "П-324" 2.0, pine rosin 3.0, white carbon "БC-120" 30.0, cenospheres 5.0, phosphorus-boron-nitrogen-bearing oligomer 1.0-3.0.

EFFECT: thermal protection material with a reduced warming-up rate.

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Description

The invention relates to heat-protective materials based on ethylene propylene diene rubbers that can be used in aircraft and rocket science.

Known heat-protective material AR-998 (TU 38.1051211-83), which is a composition comprising a reinforcing heat-resistant filler of asbestos fabric with a double-sided lining with a rubber mixture based on synthetic ethylene propylene diene rubber.

A significant drawback of this material is that asbestos fabric has a higher coefficient of thermal conductivity than the rubber compound, which in turn leads to an increase in the heating rate of the heat-shielding material and, as a consequence, to a decrease in its heat-shielding characteristics.

Known heat-shielding material (Pat. RU 2404209, IPC C08L 23/16, B32B 25/10, F16L 59/00, F02K 9/34, 11/20/2010), made of a formed layer of aramid fiber non-woven structure, laid between two layers of rubber compound Grades 51-2110 (TU 38.10551177-88) based on ethylene propylene diene rubber with subsequent vulcanization as part of the product.

The disadvantage of this heat-shielding material is that during its operation, the rubber layer is destroyed and the substance is carried away from the surface of the heat-shielding material, which, in turn, leads to an increase in the heating rate of the heat-shielding material, a decrease in its heat-shielding characteristics, and a decrease in the service life of the product or unit in whole.

Known heat-protective material based on ethylene propylene diene rubber (Pat. RU 2486215, IPC C08L 23/16, 06/27/2013), including a vulcanizing group, a filler and processing aids, additionally contains a modifying additive polyvinylidene chloride or adamantane.

The disadvantage of this heat-shielding material is that it does not provide a decrease in the heating rate of the heat-shielding material based on ethylene propylene diene rubber.

Known heat-shielding composition (RU 2400506, IPC C09D 1/00, C08K 7/22, publ. 09/27/2010) containing aluminosilicon (30-77 parts by weight), an aqueous dispersion of vinyl acetate (6-50 parts by weight), hollow glass microspheres (12-30 parts by weight), auxiliary components in the form of coloring pigments, ammonium polyphosphate and hydrosil (5-20 parts by weight) and titanium dioxide (0-3 parts by weight).

A disadvantage of the known composition is that it is able to catch fire when exposed to an open flame.

The closest is the composition described in the method for producing a rubber mixture based on ethylene propylene diene rubber, including 100.0 wt.h. ethylene propylene diene rubber, 2.0 parts by weight sulfur, 5.0 parts by weight zinc oxide, 1.0 wt.h. stearic acid, 2.0 wt.h. carbon black, 0.75 parts by weight tetramethylthiuram disulfide, 1.5 parts by weight mercaptobenzthiazole, 2.0 parts by weight dithiomorpholine, 3.0 wt.h. pine rosin, 30.0 parts by weight soot and 5 parts by weight phosphorus-borazo-containing oligomer (Pat. RU 2563016, IPC C08J 3/28, 09/10/2015).

The disadvantage of this composition is its high heating rate and the rapid achievement of 100 ° C on an unheated surface, which limits its use.

The task of the invention is to obtain materials with high thermal characteristics.

The technical result of the claimed invention is to reduce the heating rate of the heat-shielding material.

The technical result is achieved in that the heat-protective material based on ethylene-propylene diene rubber contains sulfur, zinc oxide, stearin, carbon black, tetramethylthiuramdisulfide, 2-mercaptobenzthiazole, pine rosin, white soot and phosphorus-boron-containing oligomer, the phosphorus-containing materials additionally contain oligomer at 80 ° C, in the following ratio, wt.h .: ethylene propylene diene rubber SKEPT-40 100.0, sulfur 2.0, tetramethyl yuramdisulfide 0.75, 2-mercaptobenzthiazole 1.5, zinc oxide 5.0, stearin 1.0, carbon black P-324 2.0, pine rosin 3.0, white carbon black BS-120 30.0, aluminosilicate hollow microspheres 1.0, phosphorus-borazo-containing oligomer 1.0-3.0.

In the proposed heat-shielding material, the following components are used.

SKEPT-40 ethylene propylene diene rubber containing dicyclopentadiene as the diene copolymer (TU 2294-087-05766563-2010).

Vulcanizing group, including:

vulcanizing agents - sulfur (GOST 127-76), tetramethylthiuram disulfide (thiuram D) (TU 6-14-943-79);

vulcanization accelerator - 2-mercaptobenzothiazole (captax) (TU 113-00-05761631-23-91);

vulcanization activators - zinc oxide (GOST 202-84), stearin (GOST 6484-96).

Filler - white soot BS-120 (GOST 18307-78).

Pine rosin (GOST 19113-84) and P-324 carbon black (GOST 7885-86) are used as technological additives.

As modifying additives, a phosphorus-borazo-containing oligomer FEDA and aluminosilicate hollow microspheres (TU 21-22-37-94) are used. Moreover, FEDA increases the fire resistance of polymer coatings, as contains oxidation and combustion inhibitors - phosphorus, boron and nitrogen (Pat. RU 2526980, IPC C09D 127/24, C09D 5/18, 07/28/2014).

First, the aluminosilicate hollow microspheres are treated with a phosphorus-boron-containing oligomer at 80 ° C. Then the pre-treated microspheres are introduced into the mixture.

It is known to use aluminosilicate hollow microspheres as additives that increase the fire and heat-protective characteristics of coatings. However, when they are introduced into the composition of elastomeric compositions, they significantly lose their properties due to the destruction of the walls. Pretreatment of the microspheres with a phosphorus-borazo-containing oligomer at 80 ° C avoids this, since FEDA creates a protective film on the surface of the microspheres. The increase in heat resistance is ensured by the fact that during the thermal destruction of the walls of the microspheres, the gases contained in them (CO ₂ and N ₂ ) escape, displacing oxygen from the pyrolysis region, and extinguish the extinguishing effect.

The claimed amount of modifying additives in combination with the vulcanization accelerators used and other components of the rubber composition allows to obtain a heat-shielding material with enhanced heat-shielding characteristics.

The rubber mixture is prepared in a rubber mixer at a temperature of 40-75 ° C.

The mixing time is 15 minutes. Then the vulcanization of the rubber mixture is carried out at a temperature of 165 ° C for 45 minutes. Then, the obtained samples are subjected to the necessary tests.

The compositions of the prepared mixtures and prototype are shown in table 1.

The rate of heating of the heat-shielding material during high-temperature heating (heat resistance) was estimated as follows: the time of heating the reverse side of the sample made in the form of a washer with a diameter of 30 mm and a thickness of 6 mm to a temperature of 100 ° C was determined.

The sample was heated by an open flame of a plasma torch (a temperature of 2000 ° C was created on the surface). The sample was mounted in a tripod at an angle of 45 ° to the burner flame. To reduce the heat sink and reduce the experimental error, the sample was insulated with asbestos along the edge.

To measure the temperature on the unheated surface of the sample, a S-300.3 Photon pyrometer was used (GOST 28243-96 Pyrometers. General Specifications). The principle of operation of the pyrometer is based on measuring the thermal radiation power of the measurement object mainly in the ranges of infrared radiation and visible light; and contact chromel-kopel thermocouple of the Aries regulator TRM-1.

The results of tests of the heat-shielding properties of the proposed heat-shielding material are shown in table 2.

As can be seen from the data presented, the proposed heat-shielding materials in comparison with the prototype have higher heat-shielding properties.

Thus, a heat-protective material based on ethylene-propylene diene rubber, containing aluminosilicate hollow microspheres as an additional modifying additive, pre-treated with a phosphorus-boron-containing oligomer at 80 ° C, at given ratios of the components of the mixture, ensures a decrease in the heating rate of the heat-protective material, which makes it possible to increase its heat-protective properties.

Claims (2)

Ethylene propylene diene rubber-based heat-shielding material containing sulfur, zinc oxide, stearin, carbon black, tetramethylthiuramdisulfide, 2-mercaptobenzthiazole, pine rosin, white soot and phosphorus-borazo-containing oligomer, characterized in that the material is additionally polysilane ° C, in the following ratio, wt.h .: Ethylene propylene diene rubber SKEPT-40 100.0 Sulfur 2.0 Tetramethylthiuram disulfide 0.75 2-mercaptobenzthiazole 1,5 Zinc oxide 5,0 Stearin 1,0 Carbon black P-324 2.0 Pine Rosin 3.0 White soot BS-120 30,0 Aluminosilicate Hollow Microspheres 5,0 Phosphorus borazo-containing oligomer 1.0-3.0