RU2161174C2 - Heat-accumulating material - Google Patents

Abstract

FIELD: chemical industry. SUBSTANCE: described is heat-accumulating material composed of polymeric binder and heat-accumulating agent. Polymeric binder is composition based on hydroxyl-containing oligodiene, polyisocyanate, glycerol and urethane-formation catalyst, and heat-accumulating agent is crystallohydrate of inorganic salt that affords crystallization water content of at least 17% in heat-accumulating material, ratio of components is as follows, wt.%: hydroxyl-containing oligodiene, 100; polyisocyanate, 20-38; glycerol, 1-5; urethane formation catalyst, 0.01-3.0; crystallohydrate of inorganic salt that affords crystallization water content of at least 17%, 50-200. EFFECT: coatings resistant to high-temperature load effects that develop during fires. 2 cl, 1 tbl

Description

 The invention relates to elastic materials, the purpose of which is to protect components and structures from high-temperature heat fluxes and fields, can be used in instrument and mechanical engineering, construction.

Known heat storage composition based on (NH ₄ ) ₂ CO ₃ , which includes Ba (OH) ₂ • 8H ₂ O, containing crystallization water.

 (A.S. 1214707, C 09 K 5/02, 1986).

However, the temperature range of this composition is in the range of 29.0-147.5 ^o C, which limits the scope of its application when exposed to high temperatures to 150 ^o C.

 Heat storage compositions based on crystalline hydrates of various nature are known.

 (Heat and cold storage materials / V.N. Danilin, L.V. Borovskaya, A.G. Dolesov et al. - Krasnodar: KPI, 1981, p. 36-53).

However, the temperature range of their operation lies in the range of 17-75 ^o C, and they are highly filled inelastic compositions.

 The closest are heat-accumulating materials of a single action, which are compositions based on a polymeric binder (epoxy resin or a mixture based on two types of silicone rubber) and heat-accumulating substance (α-polyformaldehyde or polyoxymethylene). The thermal effect of the phase transition of polyoxymethylene is 170 kJ / kg, decomposition is 1500 kJ / kg. The thermal effect of the decomposition of α-polyformaldehyde is 2700 kJ / kg.

 (Heat and cold storage materials / V.N. Danilin, L.V. Borovskaya, A.G. Dolesov et al. - Krasnodar: KPI, 1981, pp. 75-76).

However, these materials have the following disadvantage: in the temperature range 105-360 ^o C they decompose with the formation of highly flammable products, which limits the scope of their application.

The objective of the invention is:
- the ability to develop flexible heat-resistant coatings, namely the development of the composition of the heat-accumulating material, which allows to obtain coatings that are resistant to high-temperature loads arising from a fire.

When carrying out the invention, the following technical result is obtained: the resistance of the heat storage material to the action of high temperature thermal fields in the temperature range of 100-600 ^o C in contact with air is increased.

 The specified technical result is achieved in that the heat-storage material, consisting of a polymer binder and heat-storage substance, contains as a polymer binder a composition based on hydroxyl-containing oligodiene SKDP-N, which is a copolymer of butadiene with piperylene, polyisocyanate, glycerol and a urethane formation catalyst, and as heat transfer agent substances - crystalline hydrate of inorganic salt, providing the content of crystallization water, not less than 17% in the heat storage As a crystalline hydrate of an inorganic salt, it contains aluminum nitrate nonahydrate, nickel chloride hexahydrate, magnesium sulfate heptahydrate or potassium fluoride dihydrate, in the following ratio of components, wt. h .: hydroxyl-containing oligodien SKDP-N, which is a copolymer of butadiene with piperylene, 100, polyisocyanate 20-38, glycerin 1-5, urethane formation catalyst 0.01-3.0, crystalline hydrate of an inorganic salt, providing a crystallization water content in the material of at least 17%, 50-200.

The essence of the invention lies in the fact that under the action of a high-temperature thermal field, crystalline hydrate undergoes a number of physicochemical transformations accompanied by endothermic effects. Moreover, the greatest contribution comes from the loss of water of crystallization enthalpy (Δ H _dehydro.), Bound water heating enthalpy (ΔH _heating and evaporation enthalpy (Δ H _es), thus they can be _rank..:
Δ H _isp. > Δ H _dehydr. > Δ H _loading
During these transformations, crystallization water accumulates heat and thereby protects the polymer matrix from heat load.

 Thus, the use of crystalline hydrates of inorganic salts allows one to obtain effective heat-storage materials that are resistant to high-temperature action.

 The analysis of the technology cited by the applicant, including a search by patent and scientific and technical sources of information and identification of sources containing information about analogues of the claimed invention, allowed to establish that the applicant did not find an analogue characterized by features identical to all the essential features of the claimed invention, but determined from the list of identified analogues the prototype, as the closest in the totality of the characteristics of the analogue, allowed to identify the set of essential in relation to the perceived Applicant technical result in the distinguishing features of the claimed subject set out in the claims.

 Therefore, the claimed invention meets the requirement of "novelty" under applicable law.

 To verify the conformity of the claimed invention to the requirements of the inventive step, the applicant searched for known solutions in order to identify features that match the distinctive features of the claimed invention, the results of which show that the claimed invention does not explicitly follow from the prior art, as the prior art defined by the applicant, the effect of the transformations provided for by the essential features of the claimed invention on the achievement of s technical result.

 Therefore, the claimed invention meets the requirement of "inventive step" under applicable law.

 To obtain the proposed heat-accumulating material, compositions with different contents of crystalline hydrate are prepared. The composition is made on the basis of SKDP-N hydroxyl-containing oligodiene (TU 38.303-01-29-90), polyisocyanate (TU 6-03-375-75), glycerol (GOST 6259-75) and a urethane formation catalyst, a tertiary amine.

As a polymeric binder, use is made of a composition based on hydroxyl-containing oligodien SKDP-N, which is a copolymer of butadiene with piperylene (A. p. 1229214. Composition for coatings / VP Medvedev, AM Ogrel, EZ Krasnov):
Hydroxyl-containing oligodien SKDP-N, which is a copolymer of butadiene with piperylene - 100
Polyisocyanate - 24
Glycerin - 3
Tertiary amine - 0.6
The preparation of the proposed heat storage material is carried out in a paddle mixer, providing thorough mixing of the ingredients of the mixture. The mixture is poured into a mold and kept at room temperature (17-25 ^o C) for 3 days. Then, samples are removed from the mold using a knife, which are subsequently tested. The dimensions of the mold should ensure the receipt of samples corresponding to the requirements of GOST 21207-81. Since at the moment of high-temperature heat exposure (up to 600 ^o C) under conditions of contact with air, the heat-accumulating material begins to degrade and burn, a linear characteristic (V _g ) is a convenient characteristic for analyzing the performance of a single-action heat-accumulating material. The linear burning rate and the length of the charred part of the sample (L) are determined in accordance with GOST 21207-81. If the sample self-extinguished before reaching the mark on the sample, then the time at the time of its attenuation was taken as the self-extinguishing time (t _s ).

The invention is illustrated by the following examples:
Example 1. In a paddle stirrer placed 100 g of hydroxyl-containing oligodiene CKDP-N, 24 g of polyisocyanate, 3 g of glycerol, 0.6 g of tertiary amine and 100 g of aluminum nitrate nonahydrate. The mixture is thoroughly mixed for 30 minutes. Then it is poured into a mold and kept at room temperature (17-25 ^o C) for 3 days. Finished samples are removed from the mold with a knife.

 The composition and properties of the heat storage material of example 1 are shown in the table (composition 1).

 Example 2. According to the technology indicated in example 1, heat storage materials are prepared, the composition of which is given in the table.

 As can be seen from the table, the use of crystalline hydrates of inorganic salts allows you to get effective heat-storage materials. Moreover, with an increase in the amount of crystallization water in the material (compositions 1-6, see table), the resistance of the material to high-temperature effects increases. This is due to the endothermic effect of physicochemical processes occurring in crystalline hydrate and associated with the water that it contains. During such transformations, water accumulates heat and thereby protects the polymer binder from heat load.

 The selected composition of the polymer binder is associated with the need to obtain a heat-storage material with the necessary set of properties. The inventive dosage of the ingredients included in the polymer binder, due to technological factors in the production of heat-accumulating material.

 The use of other types of crystalline hydrates of inorganic salts (compositions 7-13) does not allow to obtain effective heat storage materials. As can be seen from the table, they are ignited and burned during exposure to a high-temperature heat flux. In addition, dropping is observed for them, which is undesirable from the point of view of maintaining the shape and design of the product.

 As can be seen from the data in the table, to obtain more efficient heat-storage materials, it is necessary to use crystalline hydrates of inorganic salts selected from the group of aluminum nitrate nonahydrate, nickel chloride hexahydrate, magnesium sulfate heptahydrate, potassium fluoride dihydrate.

 The use of these crystalline hydrates eliminates dropping, which is undesirable from the point of view of maintaining the shape and design of the product.

Increasing the dosage of crystalline hydrate to 200 parts by weight (composition 5) allows to obtain a material with L = 0 mm and t _s = 0 sec, while there is no dropping. However, with an increase in the dosage of crystalline hydrate more than 200 parts by weight the technological properties of the composition are deteriorating.

 The decrease in the content of crystalline hydrate to 50 wt.h. (composition 6) leads to a decrease in the content of crystallization water in the composition, this leads to dropping, which in some cases is acceptable and does not affect the achievement of the technical result.

 The table shows that the crystalline hydrates of inorganic salts, providing a content of crystallization water in the material in an amount of at least 17% (formulations 1-6), make it possible to obtain effective heat storage materials with a total endothermic effect of 512-2138 kJ / kg, which allows to achieve the claimed technical result .

Thus, the above information indicates the fulfillment of the following set of conditions when using the claimed invention:
- the claimed invention allows the development of elastic heat-resistant coatings;
- for the claimed invention in the form as described in the independent clause of the claims below, the possibility of its implementation using the means and methods described above or known prior to the priority date is confirmed;
- a tool embodying the claimed invention in its implementation, is able to ensure the achievement of the perceived by the applicant technical result.

 Therefore, the claimed invention meets the requirement of "industrial applicability" under applicable law.

Claims (1)

1. Heat storage material, consisting of a polymeric binder and heat storage substance, characterized in that as a polymer binder it contains a composition comprising hydroxyl-containing oligodien SKDP-N, which is a copolymer of butadiene with piperylene, polyisocyanate, glycerin and a urethane formation catalyst, and substances - inorganic salt crystallohydrate, providing a content of crystallization water of at least 17% in the heat-accumulating material, in the following the ratio of components, parts by weight:
Hydroxyl-containing oligodien SKDP-N, which is a copolymer of butadiene with piperylene - 100
Polyisocyanate - 20 - 38
Glycerin - 1 - 5
Urethane catalyst - 0.01 - 3.0
Inorganic salt crystalline hydrate providing a content of crystallization water in the material of at least 17% - 50 - 200
2. The heat storage material according to claim 1, characterized in that it contains aluminum nitrate nonahydrate, nickel chloride hexahydrate, magnesium sulfate heptahydrate or potassium fluoride dihydrate as the crystalline hydrate of the inorganic salt.

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