RU2679530C1 - Multifunctional combined heat-insulation system - Google Patents

Abstract

FIELD: protective devices.

SUBSTANCE: claimed solution relates to the construction of universal protective coatings, in particular the heat-insulating coating for applying to various types of surfaces. Claimed result is achieved due to the multi-layer thermal insulation coating based on VLHI (vacuumed liquid heat insulator) made from the composition, consisting of a binder base, in which ceramic and polymeric (based on thermoplastics) hollow and evacuated microspheres ranging in size from 0.01 to 250 microns are dispersed, as well as functional additives, wherein the coating contains a substrate on which a primer layer and a heat-insulating layer are successively applied, the heat-insulating layer being made on the basis of a VLHI with a content of microspheres in the amount of 50–87 %.

EFFECT: technical result is an increase in the service life of structures, improved thermal insulation characteristics and increased resistance to the effects of aggressive environmental factors through the use of evacuated microspheres as part of a coating system.

13 cl, 5 dwg

Description

FIELD OF TECHNOLOGY

The claimed solution relates to the construction of universal protective coatings, in particular a heat-insulating coating for application to various types of surfaces.

BACKGROUND

A heat-insulating coating is known (RU 102021 U1, 02/10/2011) containing microspheres and a binder based on acrylic latex, and it contains a layer of hollow microspheres coated with metal. The disadvantage of this solution is the lack of insulating ability.

Known heat-insulating material RE-THERM (RU 141763 U1, 06/10/2014). This material contains glass hollow microspheres, which are distributed in a latex dispersion, and as a latex dispersion, a dispersion of a copolymer of methacrylic acid and butyl ether of methacrylic acid of the following composition, wt. %:

Dispersion of a copolymer of methacrylic acid and methacrylic acid butyl ether 10-86

Glass microsphere 10-86 Suspension Agent 1-3 Titanium dioxide 2-4 Thixotropic supplement 1-2.

Since hollow microspheres are the main heat-insulating component in the composition of the material (other components of the material slightly affect the thermal insulation characteristics), and their concentration is lower than in the framework of the proposed solution, the thermal insulation efficiency of the analog is inferior.

A heat-insulating coating is known (RU 2478866 C1, 04/10/2016). The invention relates to the field of power engineering, in particular to thermal insulation of pipelines, and can be used in heating systems and hot water supply.

The heat-insulated pipe contains a layer of hollow microspheres, which, using a shell of heat-shrink material, presses a layer of microspheres to the surface of the pipe. On the outer surface of the insulated pipe, an anti-corrosion coating can be additionally located.

The disadvantage of this solution is the use of hollow, non-evacuated microspheres, which have a lower thermal insulation effect, the absence of an additional thermal insulation layer, the need for heat-shrinkable materials

A common drawback of existing solutions is the lack of application of vacuum microspheres in the coating system, which increase the efficiency of the insulating layer.

SUMMARY OF THE INVENTION

The technical problem to be solved by the claimed coating is the creation of an effective high-tech coating for thermal insulation, sound insulation and corrosion protection of structures for various purposes with high surface temperatures in all climatic regions.

The technical result is to increase the service life of structures, improve thermal insulation characteristics through the use of evacuated microspheres in the coating system and increase resistance to aggressive environmental factors.

An additional result from the use of the coating is also the effective reflection of solar radiation.

The claimed result is achieved due to the multilayer heat-insulating coating based on VZhT (evacuated liquid heat insulator), which is made of a composition consisting of a bonding base in which ceramic and polymer (based on thermoplastics) are hollow, and evacuated microspheres ranging in size from 0.01 to 250 μm, as well as functional additives, and the coating contains a substrate on which a primer layer and a heat-insulating layer are sequentially applied, and the heat-insulating layer is made on the basis of VZhT with the content of microspheres in the amount of 50-87%.

In one example of implementation, a surface made of a system of paint coatings (hereinafter - LCP), metal, polymer material, mineral material, concrete or foam glass is used as a substrate.

In one embodiment, the heat-insulating layer further comprises a heat-blocking layer based on VZhT with the content of microspheres in the amount of more than 87%.

In one example of implementation, an LKP layer is additionally applied over the insulating layer.

In one embodiment, an LPC layer is additionally applied over the fuser layer.

In one embodiment, an applied layer is additionally applied to the heat-insulating layer based on concrete, polyurethane foam, foamed rubber, foamed polypropylene or mineral wool.

In one embodiment, the application layer is attached using fixing or reinforcing elements, or applied by extrusion, spraying, spraying, shotcrete, or using adhesive formulations.

In one embodiment, the implementation further comprises a steel, polymer or metal-polymer shell.

In one embodiment, the sheath is attached to a heat insulating layer over the applied layer.

In one example of implementation, centering or reinforcing elements are installed between the insulating layer and the shell, and concrete or polyurethane foam is pumped into the created cavity under pressure.

In one example of implementation, the primer layer is based on VZhT with the content of microspheres in the amount of 10-70%.

In one example of implementation, the primer layer is based on paints and varnishes selected from the group: acrylic, urethane, organosilicate, organosilicon or epoxy.

In one example of the implementation of the paintwork is made of flame retardant material.

BRIEF DESCRIPTION OF THE DRAWINGS

In FIG. 1 shows a General view of the claimed coating.

In FIG. 2 and FIG. 3 presents thermograms with a coating based on VZhT.

In Fig 4 and Fig 5 presents an example of finished products created on the basis of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

As shown in FIG. 1, the design of the claimed coating consists of several layers deposited on a substrate (1). The coating is performed consisting of at least two layers (2A, 2B) applied to the substrate (1).

VLT is based on a composition consisting of a binder base in which ceramic and silicone hollow and evacuated microspheres are sized from 0.01 to 250 microns. VZhT also contains functional additives (titanium, calcium, zinc oxides, corrosion converters, antifungal, etc.).

The bonding base can be acrylic, rubber, latex, alkyd-urethane, organosilicate, organosilicon, polysiloxane, polyurethane, epoxy, epoxy rubber, chlorosulfonated, etc. The bonding base provides uniform distribution of the microsphere and adhesion to the surface on which the coating is formed

The substrate (1) can be made of various materials that provide adhesion with VZhT. The substrate (1) may be a paintwork system, metal, polymeric material, mineral material or wood. Facades of buildings, walls of premises, metal and non-metal pipes, etc. can serve as a substrate.

A primer layer (2A) is applied to the substrate (1). The primer layer (2A) can be made, for example, of paints and varnishes (acrylic, urethane, organosilicate, organosilicon, epoxy, etc.), or can be made on the basis of VZhT with the content of microspheres in the amount of 10-70%.

On top of the primer layer (2A), a thermal insulation layer (2B) is applied, which is based on VZhT with the content of microspheres in the amount of 50-85%.

This coating design is effective as a heat-insulating layer in the production of internal and external finishing work, for insulation, waterproofing and corrosion protection of various surfaces.

Due to the application of a coating system of layers 2A and 2B, a vacuum layer is formed on the surface of the substrate, which has an extremely low thermal conductivity. The higher the concentration of the vacuum spheres in the layer, the higher the heat-insulating effect. Additionally, it is worth noting that existing analogues with hollow or gas-filled spheres often do not have a tangible effect.

A heat-blocking layer (2C) based on VZhT with a content of microspheres in the amount of more than 80% can be additionally applied to the heat-insulating layer (2B). An additional advantage of the use of the layer (2C) is due to the application of the coating structure to a surface with a temperature above 100 ° C, in particular, to elements located in enclosed spaces.

To provide additional protection on the layer (2C) can be applied layer of paintwork (2D). LCP (2D) is based on paints and varnishes, for example, alkyd-urethane, organosilicate, organosilicon, rubber, polysiloxane, polyurethane, epoxy, epoxy-rubber, chlorosulfonated, water-dispersed, and others. LCP (2D) can also be applied to the heat-insulating layer (2 )

The layer (2D) is used when operating the coating under the risk of mechanical damage to the heat-insulating layer, and also provides imparting decorative properties. The layer (2D) can be made of flame retardant materials.

Also, an applied layer (3) made on the basis of concrete, polyurethane foam, foamed rubber, foam glass, mineral wool or other material suitable for forming this layer can be additionally applied to the heat-insulating layer (2B) applied to the substrate (1). The application layer (3) can be fastened with fixing or reinforcing elements, for example, clamps for cylindrical surfaces (pipes) or spacers for horizontal and vertical surfaces. The layer (3) can also be applied by extrusion, spraying, spraying, gunning or gluing.

The applied layer (3), as a rule, can be used in the construction of pipelines, in particular, steam, water, main, field and other. The applied layer (3) additionally provides sound insulation, protection against physical and mechanical effects, radio frequency protection.

On the applied layer (3) can also be installed shell (4), which may be a steel, polymer or metal-polymer shell. The shell (4) can be mounted on a heat insulating layer (2B) over the applied layer (3).

Also, between the layer (2), with the applied layer (2B), and the sheath (4), centering or reinforcing elements can be installed, and concrete or polyurethane foam or other applied material is pumped into the created cavity under pressure (pipe-to-pipe technology). This allows reducing the thickness of the heat-insulating layer (2 V) or the applied heat-insulating layer (3) while maintaining the heat-insulating characteristics. Additionally, when pumping concrete into the cavity, it performs a protective and weighting function.

In FIG. 2 and FIG. 3 is a thermogram depicting a thermal survey of the walls of two houses before and after the application of the VZhT layer. As you can see, the surface temperature of the house, not treated with VHT, is higher than processed, which is to say about heat loss. The application of the invention in this case has reduced the total amount of heat loss from heating to the environment.

In FIG. 4 presents an example of the invention with an applied layer and a sheath (using pipe-in-pipe technology), where 1 is a pipe (substrate); 2 - heat-insulating layer based on VZhT (2A + 2B), 3 - an applied layer of polyurethane foam; 4 - polymer shell.

In FIG. 5 shows an example of a heat-insulating structure, where 2 is a heat-insulating layer based on VZhT (2A + 2B); 3 - basalt wool (non-combustible thermal insulation); 4 - metal foil. This product allows for a long time to protect the structure, which acts as a substrate (1), on which it is fixed, from direct fire and fire due to the presence of a foil shell and non-combustible basalt wool, and also reduces heat loss due to the VZhT layer.

Claims (13)

1. A multilayer heat-insulating coating based on VZhT (evacuated liquid heat insulator) made of a composition consisting of a bonding base in which ceramic and polymeric (based on thermoplastics) hollow and evacuated microspheres ranging in size from 0.01 to 250 microns, as well as functional additives, and the coating contains successively applied primer layer and a heat-insulating layer, which is made on the basis of VZhT with the content of microspheres in the amount of 50-87%. 2. The coating according to claim 1, characterized in that the heat-insulating layer further comprises a heat-blocking layer based on VZhT with a content of microspheres in the amount of more than 87%. 3. The coating according to claim 1, characterized in that an LKP layer is additionally applied over the heat-insulating layer. 4. The coating according to claim 2, characterized in that an LKP layer is additionally applied on top of the thermal blocking layer. 5. The coating according to claim 1, characterized in that the applied layer made on the basis of concrete, polyurethane foam, foamed rubber, foamed polypropylene or mineral wool is additionally applied to the heat-insulating layer. 6. The coating according to claim 5, characterized in that the applied layer is attached using fixing or reinforcing elements or is applied using extrusion, spraying, spraying, gunning or with adhesive compositions. 7. The coating according to claim 5, characterized in that it further comprises a steel, polymer or metal-polymer shell. 8. The coating according to claim 7, characterized in that the shell is attached to a heat insulating layer over the applied layer. 9. The coating according to claim 1, characterized in that centering or reinforcing elements are installed between the insulating layer and the shell, and concrete or polyurethane foam is pumped into the created cavity under pressure. 10. The coating according to claim 1, characterized in that the primer layer is based on VZhT with the content of microspheres in the amount of 10-70%. 11. The coating according to claim 1, characterized in that the primer layer is based on paints and varnishes. 12. The coating according to claim 11, characterized in that the coatings are acrylic, urethane, organosilicate, organosilicon or epoxy. 13. The coating according to any one of paragraphs. 3 or 4, characterized in that the paintwork is made of flame retardant material.

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