RU142534U1 - HEATING UNIT - Google Patents

Abstract

1. The insulation block containing a material having a thermal conductivity of from 0.0001 to 0.3 W / (m · K) and made with the formation of a closed loop equipped with at least one cavity, and the total volume of the cavities is from 5 to 99% of total volume of the closed loop. 2. The block according to claim 1, in which the cavity is filled with gas. The block according to claim 2, in which the gas is air. The block according to claim 2, in which the gas is argon. The block according to claim 1, which contains at least one heat-reflecting element. The block according to claim 4, in which the heat-reflecting element contains at least one layer of foil. The block according to claim 1, in which the total volume of the cavities is more than 20% of the total volume of the closed loop. The block according to claim 1, in which it contains at least one soundproofing material. The block according to claim 1, in which the total volume of the closed loop cavity is at least 20% .10. The block according to claim 1, in which the material is a polystyrene foam. 11. The block according to claim 1, in which the material is polyurethane foam. Block according to any one of claims 1 to 9, in which the material is a mixture of expanded polystyrene and polyurethane foam. The insulation block containing at least two materials having a thermal conductivity of 0.0001 to 0.3 W / (m · K) and interconnected to form a closed loop provided with at least one cavity, the total volume of the cavities being from 5 to 99% of the total volume of the closed loop. 14. The block of claim 13, wherein the at least one material is a flat sheet, the second is a flat sheet provided with walls located at the edges of the sheet. The block according to claim 13, wherein at least one lane

Description

The technical field to which the utility model relates.

This utility model relates to the field of construction and building materials, namely: to insulation blocks for wall, ceiling and other surfaces.

State of the art

Insulation blocks are one of the main building materials that are used today in both civil and industrial construction. Almost all types of insulation are characterized by high porosity, which means that they also have low thermal conductivity. For this reason, they are widely used for thermal insulation of buildings and technical structures.

The prior art solution is known to RU 126724 (published on 04/10/2013). The solution describes a polymer heat-insulating panel containing parallel outer plates mounted across the heat flux, the space between them being filled with partitions. The structure of the partitions is designed so that a single air space between the outer layers is not created, i.e. formation of a cellular multilayer insulation structure. This solution is difficult to manufacture, has an increased mass due to the presence of a large number of layers, and has low flexural strength along the layers. In this solution, the value of the volume of cavities in the solution is not given in, which is an important heat-insulating property, so the presence of cavities is aimed at facilitating the construction, but the material itself is not the cavity, but the material itself.

A known solution from the prior art described in patent No. 114073 (published March 10, 2012). The solution describes a heat-insulating panel, including a layer of heat-insulating material and flat air cavities separated by jumpers, the latter are formed in the volume of the heat-insulating material parallel to the panel surfaces in at least two layers, and in different layers of the cavity can be staggered, the total area of the jumpers between adjacent cavities located in one layer is in the range from 15 to 20% of the total area of the panel, and in each air cavity parallel to the walls with the largest area One or more thermal reflectors are positioned with air gaps. The disadvantage of this solution is the difficulty of installing heat-reflecting elements. The cavities are made to accommodate heat-reflecting elements.

Cellular plastics, polystyrene foam and polyurethane foam are known, having heat-insulating characteristics of 0.025-0.04 W / (m * K), since a large amount of air is contained in the thickness of the material. Pores occupy 90-98% of the volume of the material (see http://pricep.centrttm.ru/st/st 3.html).

Known air-bubble film (http://www.polyairpack.ru/production/&id=5) laminated on both sides with a metallized polypropylene film, in which closed layers are formed between the layers of polyethylene, the volume of which is large in comparison with the total volume of the material, and thermal conductivity is low.

This utility model aims to solve the problems of the prior art and allows to solve the problems of the prior art.

Utility Model Disclosure

This utility model describes an insulation block containing a material having a thermal conductivity of from 0.0001 to 0.3 W / (m * K) and made with the formation of a closed loop provided with at least one cavity, and the total volume of the cavities is from 5 to 99 % of the total volume of the closed loop.

The cavity may be filled with gas.

The gas may be air.

In yet another embodiment, the gas may be argon.

The block may contain at least one heat-reflecting element.

The heat reflecting element in one of the embodiments may contain at least one layer of foil.

A block in which the total volume of the cavities can be more than 20% of the total volume of the closed loop.

The block may contain at least one soundproofing material.

The block may of the total volume of the closed loop cavity is at least 20%.

The material is selected from the group, may include: expanded polystyrene.

A material selected from the group may include: polyurethane foam.

Materials may include a mixture of polystyrene foam and polyurethane foam.

The insulation block may contain at least two materials having a thermal conductivity of 0.0001 to 0.3 W / (m * K) and interconnected to form a closed loop provided with at least one cavity, and the total volume of the cavities is from 5 to 99% of the total volume of the closed loop.

The block may include at least one material is a flat sheet, the second is a flat sheet provided with walls located at the edges of the sheet.

Stiffeners can be installed in at least one cavity.

The block may contain stiffeners perpendicular to at least one material.

The cavity may be filled with gas.

The gas may be air or argon.

The block may contain at least one heat-reflecting element.

The heat reflecting element in one of the embodiments may contain at least one layer of foil.

The technical result of this utility model is the production of heat-insulating panels having sufficient strength and rigidity, which allows to create heat-insulating structures, and having a thermal conductivity coefficient much lower, this utility model is also significantly lighter than its predecessors and thus requires less material to manufacture. The technical result is achieved by the fact that in the layer of heat-insulating material they form separated airborne partitions in no less than two layers forming space. In this case, partitions are used, which give rigidity to the material, thereby preventing the insulation block from bending. The cavity size used is more than 5% of the total volume. Grooves can be formed in the external and / or internal walls for inserting inserts (heat-reflecting elements, stiffeners and others) into them.

An additional equally important advantage of this solution is also high noise isolation. Sound vibrations are transmitted within the same material or through the air. In the present solution, the size of the cavity is large enough, which prevents the propagation of sound vibrations inside it, in fact, sound vibrations are transmitted from the air to the material, from the material to the cavity, from the cavity again to the material, from the material to air. In addition, the material itself can be porous, which makes it possible to disperse sound vibrations inside it in a chaotic manner, i.e. the vibrations cancel each other out.

Brief Description of the Drawings

The present utility model is illustrated by the following drawings:

Fig 1. presents the block in the section on the side.

A person skilled in the art, using the present description and drawings, may implement a utility model as claimed.

Utility Model Implementation

This utility model describes an insulation block containing a material having a thermal conductivity of from 0.0001 to 0.3 W / (m * K) and made with the formation of a closed loop provided with at least one cavity, and the total volume of the cavities is from 5 to 99 % of the total volume of the closed loop. In one embodiment of the present solution, the cavity size is more than 20% of the total product volume, preferably more than 40, 50, 60, 70, or even 80% or 90%. The implementation of the product containing the cavity with a volume of more than 95% is carried out in the preferred embodiment with the mandatory installation of stiffeners, because the side surfaces and the ribs themselves are thin, which can lead to low product strength.

The thermal conductivity table is compiled by sampling from SNiP II-3-79. The value of the thermal conductivity coefficient is taken from the column for the dry moisture zone (A) and the normal and wet zone (B) of the SNiP table.

Material Coeff. thermal conductivity W / (m · ° C) BUT B Expanded polystyrene (density 40 kg / m ³ ) 0,041 0.05 Expanded polystyrene (density 100 kg / m ³ ) 0,041 0,052 Expanded polystyrene (density 150 kg / m ³ ) 0,052 0.06

Polyfoam PHV-1 0.06 0,064 Gas and foam concrete, gas and foam silicate (density 1000 kg / m ³ ) 0.41 0.47 Gas and foam-ash concrete (density 1000 kg / m ³ ) 0.44 0.5 Gas and foam-ash concrete (density 1200 kg / m ³ ) 0.52 0.58 Ceramic hollow brick (density 1300 kg / m ³ ) 0.52 0.58 Ceramic brick (density 1400 kg / m ³ ) 0.58 0.64 Granulated blast furnace slag concrete (density 1800 kg / m ³ ) 0.7 0.81 Brickwork (clay brick, density 1800 kg / m ³ ) 0.7 0.81 Concrete on gravel or crushed stone from natural stone (density 2400 kg / m ³ ) 1.74 1.86 Reinforced concrete (density 2500 kg / m ³ ) 1.92 2.04

The insulation block in one embodiment is a material that is designed as a closed loop and contains cavities. The cavities can be filled with special gases having the necessary thermal conductivity, or with air. The increase in thermal conductivity of the product is achieved due to the presence in it of a large volume of a cavity or several cavities. The principle of operation of the product can be compared with the work of a window frame, which has two glasses and an air space between them. An important point of this solution is that the product is not subject to rot and the development of bacteria, like ordinary porous heaters. This is achieved due to the fact that the size of the cavities is significant, and the material of the product can contribute or, conversely, inhibit convection of air / gas.

In one of the embodiments of the present solution, the product is made of one, preferably flat or profiled sheet of insulation material, on which are installed along the edges of the wall, on which the second insulation material is supported. Thus, the product has the form of a closed loop in the form of, for example, a parallelepiped. The space inside the product can be partially filled with additional stiffeners and jumpers that reinforce the structure. The location of the stiffeners is preferably chosen so as to increase the resistance of the material to bending along at least one of the sides of the product (preferably along the longest). The ribs can be made of the same material as the insulation block itself. The connection of stiffeners and material between themselves can be carried out, for example, by means of adhesive bonding.

An additional important advantage of this solution is also its high sound insulation. Sound vibrations are transmitted within the same material or through the air. In the present solution, the size of the cavity is large enough, which prevents the propagation of sound vibrations inside it, in fact, sound vibrations are transmitted from the air to the material, from the material to the cavity, from the cavity again to the material, from the material to air. In addition, the material itself can be porous, which makes it possible to disperse sound vibrations inside it in a chaotic manner, i.e. the vibrations cancel each other out.

In accordance with the present description and the following formula of a utility model, a person skilled in the art can implement the present solution with all the indicated technical results achieved.

Claims (24)

1. The insulation block containing a material having a thermal conductivity of from 0.0001 to 0.3 W / (m · K) and made with the formation of a closed loop equipped with at least one cavity, and the total volume of the cavities is from 5 to 99% of total volume of the closed loop. 2. The block according to claim 1, in which the cavity is filled with gas. 3. The block according to claim 2, in which the gas is air. 4. The block according to claim 2, in which the gas is argon. 5. The block according to claim 1, which contains at least one heat-reflecting element. 6. The block according to claim 4, in which the heat-reflecting element contains at least one layer of foil. 7. The block according to claim 1, in which the total volume of the cavities is more than 20% of the total volume of the closed loop. 8. The block according to claim 1, in which it contains at least one soundproofing material. 9. The block according to claim 1, in which the total volume of the closed loop cavity is at least 20%. 10. The block according to claim 1, in which the material is a polystyrene foam. 11. The block according to claim 1, in which the material is a polyurethane foam. 12. The block according to any one of claims 1 to 9, in which the material is a mixture of expanded polystyrene and polyurethane foam. 13. The insulation block containing at least two materials having a thermal conductivity of from 0.0001 to 0.3 W / (m · K) and interconnected with the formation of a closed loop equipped with at least one cavity, the total volume of the cavities makes up from 5 to 99% of the total volume of the closed loop. 14. The block according to item 13, in which at least one material is a flat sheet, the second is a flat sheet provided with walls located at the edges of the sheet. 15. The block according to item 13, in which at least one cavity installed ribs. 16. The block according to clause 15, in which the ribs are perpendicular to at least one material. 17. The block according to item 13, in which at least one cavity is filled with gas. 18. The block of claim 17, wherein the gas is air or argon. 19. The block according to item 13, in which at least one cavity contains a heat-reflecting element. 20. The block according to claim 19, in which the heat-reflecting element contains at least one layer of foil. 21. The block according to item 13, in which the total volume of the cavities is more than 20% of the total volume of the closed loop. 22. The block according to item 13, in which at least one material is a polystyrene foam. 23. The block according to item 13, in which at least one material is polyurethane foam. 24. The block according to any one of paragraphs.13-21, in which at least one material is a mixture of expanded polystyrene and polyurethane foam.

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