AT13921U1 - Infrared surface heating element - Google Patents

Abstract

An infrared surface heating element has a glass plate (1) on the front side and a rear wall (3) and an electrically conductive layer (4) arranged therebetween. The electrically conductive layer (4) is a coating applied to the glass plate (1). Between the electrically conductive layer (4) and the rear wall (3), an insulating layer (2) is arranged and on the front side of the electrically conductive layer (4) is arranged a non-transparent layer.

Description

Austrian Patent Office AT 13 921 U1 2014-12-15

Description: The invention relates to an infrared surface heating element with a glass plate on the front side and a rear wall and an electrically conductive layer arranged therebetween.

Radiant heaters generally act differently than convection heaters, since not the air serves as a carrier medium for heat, but the radiation acts directly on the body located in the room. Only then does the air warm up. In buildings with radiant heaters, the room temperature can be lowered by 1-2 ^ 0 with the same sense of well-being, which leads to further energy savings.

Infrared radiation heaters are known for example from AT 509 565 A. The cover plates on the front often consist of laminates, sheet metal or the like, which may also be coated if necessary in order to improve the radiation properties. Nevertheless, the radiation properties are often unsatisfactory and the surface heating elements often thick and heavy due to the complex structure.

Furthermore, e.g. from EP 2 431 669 A laminated glass panes for heating purposes, in which the inside of a disc is provided with an electrically conductive coating. However, these are often unsatisfactory both in terms of their radiation behavior or their weight and the heating time as well as aesthetically.

The invention is therefore an object of the invention to provide an infrared surface heating, which has good radiation properties and the thinnest possible and light construction.

This object is achieved with an infrared surface heating element with the features of claim 1.

Since the electrically conductive layer is a coating applied to the glass plate, a lossy contact heat transfer is avoided, whereby a very rapid and good radiation and thus high efficiency is achieved. If a tempered safety glass is preferably used, it can be very thin, preferably between 2 and 3 mm, but also less, which has a positive effect both on a very good or rapid emission and on the weight and a slim design of the infrared surface heating element. The thin glass ensures a minimal heat-up time, so that the full heat radiation is released within a few minutes. Especially in temporarily inhabited rooms (eg: bathroom, toilet) this is a great energetic advantage, as only during their often short-term use of heat is needed.

Since the coating is possibly aesthetically not very appealing, the non-transparent layer is provided, which can either be arranged between the electrically conductive layer and the transparent pane or applied on the outside of the transparent pane as a color layer, image or the like. Alternatively or additionally, the nontransparent layer can also be formed from the glass plate made of colored glass, which is not transparent due to the coloration in any desired color, possibly in combination with an additional nontransparent layer, in that the electrically conductive coating can not be seen.

It can also be arranged between the non-transparent layer on the inside of the transparent pane and the transparent pane, a color layer, an image or the like.

By the non-transparent layer and / or the color layer, the image or the like, both the aesthetic appearance of the infrared Flächenheizelementes invention and under certain circumstances, the radiation behavior can be improved.

The insulating layer ensures thermal insulation to minimize heat loss to the rear. This ensures that a high proportion of the absorbed power is converted into efficient heat radiation and not into convective heat. [0012] According to the invention, the insulating layer used is preferably a glass fiber mat or even better an airgel, in particular a flexible nonwoven fabric substrate containing amorphous silica gel, since these materials have very good insulating properties and are therefore too contribute to a slim design of the infrared surface heating element according to the invention.

Further features and advantages of the invention will become apparent from the following description of a preferred embodiment of the invention with reference to the accompanying drawings. 1 shows an exploded view of an embodiment of an infrared surface heating element according to the invention, FIG. 2 shows a side view of the infrared surface heating element according to the invention in the assembled state, and [0016] FIG. 3 shows a perspective view of the back side of FIG according to the invention

Surface heating element in the assembled state The infrared surface heating element according to the invention has in the illustrated embodiment, an approximately 2.1 mm thick glass plate 1 teilvorgespanntem glass with ESG properties (ESG = tempered safety glass) on the front, which has a thermal Insulating layer 2 is attached to a rear wall 3. The insulating layer 2 has, for example, a thickness of 2 to 8 mm and is preferably made of a glass fiber mat or an airgel, e.g. a flexible nonwoven fabric substrate containing an amorphous silica gel. Other insulating materials and combinations of these or other insulating materials are also conceivable according to the invention. These also preferably have electrically insulating properties, since in this way additional insulation of the electrically conductive layer 4 applied to the glass plate 1 can be dispensed with. If electrically insulating properties of the insulating layer 2 are not or not sufficiently present, as shown in FIG. 1, an additional electrically insulating layer or film 17 may be arranged between the insulating layer 2 and the electrically conductive layer 4.

The electrically conductive layer 4 is a surface homogeneously applied heating layer, e.g. at a supply voltage of 230VAC across the entire heating surface evenly with 80-90 ° C surface temperature long-wave IR radiation emits. Such layers having a layer thickness of up to 50μ, preferably < 20μ, are well known in the art and are therefore not described here in detail. By way of example only, an aqueous acrylate-based dispersion having electrically conductive particles, e.g. Carbon nanoparticles, called a suitable layer. An adhered heating foil could also be used.

The electrically conductive layer 4 is either directly applied homogeneously and flat on the inside of the glass plate 1 or an intransparente intermediate layer, which prevents the electrically conductive layer 4 is visually visible through the glass plate 1. The nontransparent layer can be dyed in one color according to the customer's request and / or possibly reproduce an image or the like. The non-transparent layer, color layer, the image or the like may also be mounted on the outside of the glass plate 1. It is also possible to use a combination of an opaque layer with an additional color layer, an image or the like.

At opposite edges of the electrically conductive layer 4, two conductor tracks 5 are provided for contacting the heating layer 4, which are connected via electrical conductors 6 with terminal blocks 7. The interconnects 5 are made of very good conductive material, such as silver, which can also connect well with the electrically conductive layer 4.

As protection against harmful or dangerous excess temperatures, two temperature sensors or temperature limiters 8, which are set to, for example, 110 ° C., are connected to a control board 10 at the rear side of the electrically conductive layer 4 13 921 U1 2014-12-15 assembled state in a junction box 9 is included. The temperature limiter 8 are mounted through recesses 18 in the insulating layer 2 to the additional, electrically insulating layer or foil 17 or directly to the electrically conductive layer 4. The junction box 9 is screwed by means of screws 11 to the rear wall 3.

Since the infrared surface heating element according to the invention in the illustrated embodiment via the junction box 9 and a mounting plate 12 disposed thereon can be attached to a wall or the like, is for stiffening the rear wall 3 on the inside of an aluminum plate 13 is still arranged with the the junction box 9 is screwed through the screws 11 through the rear wall 3 therethrough.

The rear wall may be made of any mechanically stable enough material, such as wood, wood materials such as MDF boards or composites or laminates. It is advantageous if the rear wall 3 has good heat insulating properties. Preferably, the rear wall 3 on projecting edges, so that the individual components of the infrared surface heating element according to the invention can be accommodated in the interior of the rear wall 3. The transparent pane 1 can also be received flush within the edges of the rear wall or placed on the edges and thus flush with the outer periphery of the rear wall 3. In this way, a very thin or slender and aesthetically beautiful overall structure can be realized.

In order to connect the infrared surface heating element according to the invention with the power supply, a connector 14 is provided, which has not only an input but also one, two or more outputs to connect further infrared surface heating elements according to the invention can, either each infrared Surface heating can be switched separately or via a master-slave circuit. For example, if two or more infrared panel heaters are used, they may be attached to a swing arm system that allows, e.g. to swing two lateral elements at an angle of up to 45 ° to the front. Thereby, the infrared surface heating elements can be used e.g. be used as a compact infrared cabin.

For switching on and off of the infrared Flächenheizelementes a switch 15 may be mounted on one edge thereof, either on the front or on the back, which is also connected via an electrical line 16 to the control board 10. The switch 15 may, for example, be a simple mechanical-electrical switch or a switch which can be actuated capacitively by simple contact. 3.6

Claims (15)

Austrian patent office AT 13 921 U1 2014-12-15 Claims 1. Infrared surface heating element with a glass plate (1) on the front and a rear wall (3) and an electrically conductive layer (4) arranged therebetween, characterized in that the electrically conductive Layer (4) on the glass plate (1) attached coating is that between the electrically conductive layer (4) and the rear wall (3) an insulating layer (2) is arranged and that at the front of the electrically conductive layer (4) has a non-transparent layer is arranged. 2. Infrared surface heating element according to claim 1, characterized in that the non-transparent layer between the electrically conductive layer (4) and the glass plate (1) is arranged. 3. Infrared surface heating element according to claim 1, characterized in that as a non-transparent layer on the outside of the glass plate (1) a color layer or an image is applied. 4. infrared surface heating element according to claim 2, characterized in that between the non-transparent layer and the glass plate (1) a color layer or an image is arranged. 5. Infrared surface heating element according to one of claims 1 to 4, characterized in that the non-transparent layer on the outside of the glass plate (1) is applied. 6. infrared surface heating element according to claim 5, characterized in that on the outside of the non-transparent layer, a color layer or an image is applied. 7. Infrared surface heating element according to one of claims 1 to 6, characterized in that the non-transparent layer of the glass plate (1) is formed from colored glass. 8. Infrared surface heating element according to one of claims 1 to 7, characterized in that the glass plate (1) is a prestressed or teilvorgespanntes safety glass with a thickness of preferably 2 to 3 mm or less. 9. infrared surface heating element according to one of claims 1 to 8, characterized in that the insulating layer (2) comprises an airgel, in particular a flexible nonwoven fabric substrate containing amorphous silica gel. 10. Infrared surface heating element according to one of claims 1 to 9, characterized in that the insulating layer (2) comprises a glass fiber mat. 11. Infrared surface heating element according to one of claims 1 to 10, characterized in that the rear wall (3) consists of a wood material. 12. Infrared surface heating element according to one of claims 1 to 11, characterized in that the electrically conductive layer (4) is a flat homogeneously applied heating layer, preferably at a Vesorgungsspannung of 230VAC over the entire heating surface uniformly with 80-90 * 0 surface temperature emits long-wave IR radiation. 13. Infrared surface heating element according to one of claims 1 to 12, characterized in that at the back of the electrically conductive layer (4) two, preferably set to 1100, temperature sensors or temperature limiter (8), which are connected to a control board (10) , are arranged. 14. Infrared surface heating element according to one of claims 1 to 13, characterized in that it comprises a connector (14) having an input and one or more outputs to connect a plurality of infrared surface heating elements can. 15. Infrared surface heating element according to claim 14, characterized in that each infrared surface heating element can be switched on separately or via a master salvo circuit. For this 2 sheets of drawings 4/6