RU2715999C1 - Infrared heater - Google Patents

Abstract

FIELD: electrical engineering.SUBSTANCE: present invention relates to electrical engineering, in particular to electric infrared heaters, and is intended for warming and heating of residential or other premises and buildings. In the infrared heater, having a heating panel consisting of at least two glass plates fixed at a certain distance from each other, on the inner surface of one of the glass plates a current-conducting heated coating is made, wherein heater comprises housing, in which heating panel is fixed, and outer glass plates of heating panel are made of at least one tempered glass, and on the inner surface of the second outer hardened glass plate of the heating panel there is a selective heat-reflecting coating.EFFECT: technical result is increase in durability and reliability of heater operation.19 cl, 6 dwg

Description

The present invention relates to the field of electrical engineering, in particular to electric infrared heaters, and is intended for heating and heating of residential or other premises, buildings.

Currently, various types of infrared heaters are used for space heating.

Known infrared heater according to the patent of the Russian Federation on PM No. 178637, IPC Н05В 3/20, comprising a housing, with infrared radiation elements fixed in it, made in the form of at least two rectangular radiating plates with electric radiating elements, each of which is located in the middle of the radiating plates as well as reflector. Moreover, each of the radiating plates is made of sheet metal.

This heater has a housing with heating elements and radiating plates placed in it, which ensures its sufficiently high reliability and operational safety, but at the same time it has a rather complicated design and also quite low heat efficiency.

Also known is an electric heater containing a casing, film heaters located parallel to the front and rear walls of the casing, while the front wall of the casing is made of material with high thermophysical properties, in particular tempered glass or ceramic (Russian patent for PM No. 181313, IPC Н05В 3 / 00).

This heater provides a sufficiently high heat efficiency, but it does not have the necessary reliability and safety of operation, since it does not provide a housing that reliably protects this heater from external influences, as well as protecting the installation site of the heater from direct heat exposure from local heating.

Closest to the proposed invention is a flat electric heater according to the Russian patent for PM No. 6489, IPC Н05В 3/26, containing two glass and electrically insulated at the ends along the contour of the silicate glass plate mounted parallel to each other, while on the inner surface of the first of the glass a conductive heated coating is made on the plates, on which low-impedance current-carrying paths are formed with power supply pads installed on them, which are connected by electric wires Ania with the power supply.

This flat electric heater is selected as a prototype.

This flat electric heater has a sufficiently high heat efficiency, but it does not have the necessary reliability and safety of operation, since it uses ordinary silicate glass plates that do not have sufficient strength, and also does not provide a housing that reliably protects this heater from external impacts, as well as protecting the installation site of the heater from local heating from direct heat exposure.

The objective of the invention is the creation of an infrared heater with increased strength and reliability of its operation, while ensuring its high heat efficiency.

The technical result of the proposed invention is to increase the strength and reliability of the heater.

The technical result is achieved due to the fact that in an infrared heater containing a heating panel with an infrared radiation spectrum, consisting of at least two glass plates fixed at a certain distance from each other using distance frames that serve to control the distance between the glass plates, and seals in the form of layers of sealant, which serves to seal the cavities between the glass plates from environmental influences, while on the inner surface one of the glass plates has a conductive heated coating on which low-impedance current-carrying tracks are formed, with power supply pads installed on them, which are connected by power wires to a power source, and also containing a housing in which a heating panel is fixed, in which the first outer glass plate is made laminated, and contains at least one outer tempered glass and one inner non-tempered glass, which are glued together adhesive a layer, while on the inner surface of the outer tempered glass of the first laminated outer glass plate, a conductive heated coating is applied, and the second outer glass plate is made of tempered glass, on the inner surface of which a selective heat-reflecting coating is applied, capable of reflecting thermal radiation from the inner surface of the second outer tempered glass plate toward the first outer laminated tempered glass plate.

Preferably, in the infrared heater, the second outer tempered glass plate is laminated and contains at least one outer tempered glass and one inner non-tempered glass that are glued together by an adhesive layer.

In an infrared heater, it is desirable that a selective heat-reflecting coating is applied to the inner surface of the inner, non-tempered glass, second laminated tempered outer glass plate, capable of reflecting heat radiation from the inner surface of the second outer tempered laminated glass plate to the side of the first outer laminated tempered glass .

It is advisable that in the infrared heater on the inner surface of the outer tempered glass of the second tempered laminated outer glass plate, a conductive heated coating is formed on which low-impedance current-carrying tracks are formed, with power supply contact pads installed on them.

Preferably, in the infrared heater, the bonding layer was a cured bonding layer of a solution of a high molecular weight polyester oligomer in methyl methacrylate in the form of a photocurable composition.

Advantageously, in the infrared heater, the bonding layer was a polyvinyl butyral film.

Advantageously, in the infrared heater, the bonding layer was an ethyl vinyl acetate film.

Preferably, in the infrared heater, low-resistance current paths are formed on the surface of the conductive heated coating by applying tin or silver oxide-based alloy to the coating surface.

It is advisable that in the infrared heater, the distance frames were made of dielectric material.

It is desirable that in the infrared heater the sealant was made on the basis of silicon-containing polymers.

Preferably, in the infrared heater, the selective heat-reflecting coating was made of a material selected from the group consisting of cobalt oxide, tin oxide, copper oxide.

It is desirable that in the infrared heater the heater case be made in the form of a horizontally oriented triangular prism with a cut upper base, along the entire length of which there is a guide for placing and fixing the heating panel in it, and the lower base is made concave inward, with the formation of two extended along the entire length of the prism of the supports.

It is advisable that in the infrared heater, the heater body was made in the form of a frame into which the heating panel was installed.

It is advisable that the infrared heater contains at least one temperature sensor and an electronic control system for the heating mode, which was connected with the contact pads of the power supply and temperature sensors, while the electronic control system of the heating mode, temperature sensors and power wires were placed in the heater body .

It is desirable that the conductive heated coating in the infrared heater contain at least one layer made of a material selected from the group consisting of silver, tin, copper, nickel, aluminum, magnesium, silicon, as well as various compounds of these metals with other substances.

Preferably, in the infrared heater, the outer laminated glass plates of the heating panel are made of tempered glass with a thickness of 5-10 mm.

It is desirable that in an infrared heater a conductive heated coating was applied to tempered glass by a vacuum method with removal along its entire perimeter at a distance of 1-5 mm from the edge of this tempered glass.

It is advisable that in the infrared heater tempered glass have a chamfer made on their edges around their entire perimeter.

Preferably, in the infrared heater, a decorative coating is applied to the outer laminated glass plates of the heating panel.

For a more complete disclosure of the invention, the following is a description of specific possible options for its execution, which are illustrated by the corresponding drawings.

FIG. 1 - appearance of a floor infrared heater.

FIG. 2 - appearance of a wall or ceiling infrared heater.

FIG. 3 is a cross-sectional view of a heating panel with two external tempered glass plates with a conductive heated coating on one plate and a selective heat-reflecting coating on the other.

FIG. 4 is a cross-sectional view of a heating panel with a first external tempered glass plate in the form of a laminated glass.

FIG. 5 is a cross-sectional view of a heating panel with two external tempered glass plates with a conductive heated coating on each of the plates.

FIG. 6 is a cross-sectional view of a heating panel with a second outer tempered glass plate in the form of a laminated glass with a selective heat-reflecting coating on the inner surface of the inner tempered glass.

In a preferred embodiment, the infrared heater comprises a heating panel 1 mounted in the heater body 2 (Fig. 1-2).

In this case, the housing 2 of the floor heater variant is preferably made in the form of a horizontally oriented triangular prism with a cut off upper base 3, along the entire length of which there is a guide for placing and fixing the heating panel 1 in it, and the lower base 4 is made concave inward, with the formation of two the entire length of the prism of the supports (Fig. 1).

The housing 2 of the wall or ceiling version of the heater is preferably made in the form of a frame 5, in which a heating panel 1 is installed (Fig. 2). At the same time, elements 6 can be made on the frame 5 for attaching it to the ceiling or wall in the form of brackets, rails, chains, or other similar devices.

The heating panel 1 of the infrared heater, in a preferred embodiment, contains at least two outer glass plates 7, each of which is laminated, consisting of tempered glass 8 and non-tempered glass, while conductive conductive glass can be made on the inner surfaces of each tempered glass 8 heated coating 9, on which low-resistance current-carrying tracks 10 are formed, with power supply pads 11 mounted on them, which are connected by power supply wires Nia 12 to the power supply. The glass plates 7 are mounted parallel to each other at a certain distance from each other using distance frames 13, which serve to control the distance between the glass plates 7, which are fastened with a sealant 14, which also serves to seal the cavities between the glass plates 7 from the influence of the environment (Fig. 3 -6).

The heater may also contain at least one temperature sensor 15 and an electronic control system 16 for the heating mode, which is connected to the contact pads of the power supply 11 and temperature sensors 15. Moreover, the temperature sensors 15 and the electronic control system 16 for the heating mode are located in the housing 2 of the heater .

Glass plates 7 of tempered glass 8 may have a chamfer 17 (usually 1 × 45 °), made at their edges around the entire perimeter of these glass plates 7, which provides increased strength. This is done in order to remove stress concentrators before tempering each silicate glass.

On the inner surface of the second glass plate 7 of tempered glass 8, a selective heat-reflecting coating 18 can be placed made of a material selected from the group consisting of cobalt oxide, tin oxide, copper oxide (Figs. 3, 4, 6).

The use of selective heat-reflecting coating 18 allows to increase the degree of reflection of thermal radiation from the inner surface of the second glass plate 7 and direct it towards the first glass plate 7.

This is especially advisable for wall and ceiling heaters, where it is necessary to direct thermal radiation towards the conductive heated coating 9, so as not to heat the surface of the wall or ceiling.

In addition, the first outer glass plate 7 of the heating panel 1 is laminated, in addition to the external tempered glass 8, it contains an inner non-tempered glass 19, which are interconnected by an adhesive layer 20 (Fig. 4).

The second outer glass plate 7 of the heating panel 1 can also be laminated, in addition to the external tempered glass 8, it contains an inner, not tempered glass 19, which are interconnected by an adhesive layer 20. Moreover, on the inner surface of the inner tempered glass 19 can be placed selective heat-reflecting coating 18. (Fig. 6).

This is especially suitable for wall and ceiling infrared heaters, where it is necessary to direct thermal radiation to one side of the conductive heated coating 9, so as not to heat the surface of the ceiling or wall.

The implementation of the heating panel 1 of the laminated first glass plate 7, and the second laminated glass plate 7, provides not only high strength of the heating panel 1, but also the safety of its use when it is destroyed, since when the tempered glass 8 is destroyed, they break into glass fragments with blunt edges.

The process of obtaining tempered glass 8 of silicate glass consists in the tempering of silicate glass by heating it to a temperature of 650-680 ° C followed by its rapid cooling with air.

As a result of this process, an uneven temperature distribution occurs over the thickness of the glass plates 7 of tempered glass 8, and residual surface compressive stresses are formed in them, which provide increased mechanical strength and heat resistance, which are especially necessary when using this design as a heating panel 1 of an infrared heater.

Conductive heated coating 9 on the inner surface of the first outer glass plate 7 can be made in the form of a translucent coating with a thickness of 3-400 nm, and contains at least one layer made of a material selected from the group consisting of silver, tin, copper, nickel, aluminum, magnesium, silicon, as well as from various compounds of these metals with other substances.

And the bonding layer 20 may be a cured bonding layer of a solution of a high molecular weight polyester oligomer in methyl methacrylate in the form of a photocurable composition, or a polyvinyl butyral film, or an ethyl vinyl acetate film.

Low resistance current paths 10 can be made of dielectric material and formed on the surface of a conductive heated coating 9 by applying an alloy based on tin or silver to the coating surface.

In one embodiment of the heating panel 1 (Fig. 5), an additional conductive heated coating 9 can be placed on the inner surface of the second outer glass plate 7 of laminated glass, on which low-resistance current-carrying tracks 10 are formed with power supply pads 11 installed on them, which connected by power wires 12 to a power source.

This is especially suitable for floor-mounted infrared heaters, where it is necessary to direct thermal radiation to both sides of the conductive heated coating 9 in order to warm the space on both sides of the heater.

In the infrared heater, the outer glass plates 7 of the heating panel 1 can be made of tempered glass 8 with a thickness of 2-10 mm, and the conductive heated coating 9 is applied to the tempered glass 8 by a vacuum method, removing 1-5 mm from its edge around its entire perimeter tempered glass 8.

Also in the infrared heater, the tempered glass 8 may have a chamfer 17, made on their edges around their perimeter.

Also in the infrared heater, the heating panel can be made with a decorative coating on the outer glass plates in the form of a pattern or tinting.

The infrared heater works as follows.

When this infrared heater is connected to the electric network, the conductive heated coating 9 begins to actively radiate thermal infrared radiation, heating the surfaces of the outer glass panels 7, which retain and dissipate heat for a long time in the room in which the heater is installed.

Thus, in the presented infrared heater, it was possible to significantly increase its strength by making its heating panel 1 of two outer glass plates 7 in the form of laminated glass consisting of tempered glass 8 and non-tempered glass 19, as a result of their joining by means of an adhesive layer 20.

Also, due to the presence in the infrared heater of the case 2, it was possible to significantly increase the reliability of operation of the heater, since this case 2 protects the surface of the heating panel 1 from various contaminants, ensures the safety of the operation of the heating panel 1 and the increased duration of its operation.

In addition, the presence in this infrared heater of the housing 2 provides a reliable installation of the heater on the floor, as well as its mounting on the wall and ceiling by placing on this housing 2 various devices for its mounting.

Also, by using a selective heat-reflecting coating 18 in the infrared heater on the inner surface of the second outer glass plate 7, it was possible to reflect heat radiation from the surface of the second outer glass plate 7 towards the first outer glass plate 7, which allowed to solve the problem of local heating of the wall or ceiling during operation a heater.

As is apparent to those skilled in the art, the invention is readily developed in other specific forms without departing from the spirit of the invention.

Moreover, the present embodiments should be considered merely illustrative, and not limiting, the scope of the invention represented by its formula, and it is assumed that it includes all possible changes and the scope of equivalence to the claims of this invention.

Claims (19)

1. An infrared heater comprising a heating panel with an infrared radiation spectrum, consisting of at least two glass plates fixed at a certain distance from each other using distance frames used to control the distance between the glass plates, and a seal in the form of sealant layers , which serves to seal the cavities between the glass plates from the influence of the environment, while on the inner surface of one of the glass plates made conductive heated a coating on which low-resistance current paths are formed with power supply pads installed on them, which are connected by power wires to a power source, characterized in that it comprises a housing in which a heating panel is fixed, in which the first outer glass plate is laminated and contains at least at least one external tempered glass and one internal non-tempered glass, which are glued together by an adhesive layer, while on the inner surface of the outer a conductive heated coating is applied to the glass of the first laminated outer glass plate, and the second outer glass plate is made of tempered glass, a selective heat-reflecting coating is applied to its inner surface, which is capable of reflecting heat radiation from the inner surface of the second outer tempered glass plate to the side of the first outer laminated tempered glass plate. 2. The infrared heater according to claim 1, characterized in that the second external tempered glass plate is laminated and contains at least one external tempered glass and one internal non-tempered glass, which are glued together by an adhesive layer. 3. The infrared heater according to claim 2, characterized in that a selective heat-reflecting coating is applied to the inner surface of the inner non-tempered glass of the second laminated tempered outer glass plate, which is configured to reflect heat radiation from the inner surface of the second outer tempered laminated glass plate to the side of the first outer laminated tempered glass plate. 4. The infrared heater according to claim 2, characterized in that a conductive heated coating is formed on the inner surface of the outer tempered glass of the second tempered laminated outer glass plate, on which low-impedance current-carrying tracks with power supply contact pads installed on them are formed. 5. The infrared heater according to claim 1, characterized in that the bonding layer is a cured bonding layer of a solution of a high molecular weight polyester oligomer in methyl methacrylate in the form of a photocurable composition. 6. The infrared heater according to claim 1, characterized in that the bonding layer is a polyvinyl butyral film. 7. The infrared heater according to claim 1, characterized in that the bonding layer is an ethyl vinyl acetate film. 8. The infrared heater according to claim 1, characterized in that the low-impedance current-carrying paths are formed on the surface of the conductive heated coating by applying tin or silver oxide-based alloy to the coating surface. 9. The infrared heater according to claim 1, characterized in that the distance frames are made of dielectric material. 10. The infrared heater according to claim 1, characterized in that the sealant is made on the basis of silicon-containing polymers. 11. The infrared heater according to claim 1, characterized in that the selective heat-reflecting coating is made of a material selected from the group consisting of cobalt oxide, tin oxide, copper oxide. 12. The infrared heater according to claim 1, characterized in that the heater body is made in the form of a horizontally oriented triangular prism with a cut off upper base, along the entire length of which there is a guide for placing and fixing the heating panel in it, and the lower base is made concave inward, with the formation of two long supports along the entire length of the prism. 13. The infrared heater according to claim 1, characterized in that the heater body is made in the form of a frame into which the heating panel is installed. 14. The infrared heater according to claim 1, characterized in that it comprises at least one temperature sensor and an electronic control system for the heating mode, which is connected to the contact pads of the power supply and temperature sensors, while the electronic control system for the heating mode, temperature sensors and power wires are located in the heater body. 15. The infrared heater according to claim 1, characterized in that the conductive heated coating contains at least one layer made of a material selected from the group consisting of silver, tin, copper, nickel, aluminum, magnesium, silicon, and from all kinds of compounds of these metals with other substances. 16. The infrared heater according to claim 1, characterized in that the outer glass laminated plates of the heating panel are made of tempered glass 5-10 mm thick. 17. The infrared heater according to claim 1, characterized in that the conductive heated coating is applied to tempered glass by a vacuum method with removal along its entire perimeter at a distance of 1-5 mm from the edge of this tempered glass. 18. The infrared heater according to claim 1, characterized in that the tempered glass has a chamfer made on their edges around their perimeter. 19. The infrared heater according to claim 1, characterized in that a decorative coating is applied to the outer laminated glass plates of the heating panel.

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