DE1936237A1 - Large area surface heater - Google Patents

Abstract

An electrically conductive layer between two layers of insulation is composed of a binder which is applied as a liquid and then hardened loaded with electrically conductive powder. The binder may be synthetic resin, plastic, dyestuff, varnish, tar or bitumen, or of resins or oils which are cured by polymerisation or polyaddition. A carrier of woven or unwoven fibre material may be included in the conductive layer. The outer insulated layers may both be of a plastic or resin applied in liquid form and then cured by polymerisation or polyaddition or of thermoplastic resin applied in molten form and allowed to harden.

Description

Large area heating The invention relates to electrical large area heating with an electrically conductive layer arranged between two insulating layers. The electrically conductive layer represents a resistance layer that is heated when current passes through.

The electrically conductive powder can for example be carbon powder or metal powder. Synthetic resins, plastics and commercially available binders are used as binders Paints and laoke, tar and bitumen as well as solo resins and oils in question, which by Polymerization or polyaddition are curable. It is important that the binder in the non-hardened state has a consistency that makes it pasty electrically conductive powder to a paintable or pourable wet permitted. Thermoplastics too can be used as binders; they are heated with the electric conductive powder mixed, applied and hardened by cooling. Of course you have to ensured be that the highest temperatures occurring the heating are below the melting temperature of the thermoplastic binder.

The electrically conductive powder can be coated with a dielectric material are mixed, you are also in powder form. By adding powdered egg, dielectric material can be the resistivity of the electrically conductive Layer can be changed. Because greater layer thicknesses are easier with a certain percentage accuracy can be applied as thin layers, it will be in different Use cases be appropriate, large layer thicknesses of the electrically conductive Apply layer.

In doing so, you can set a given resistance Add correspondingly larger amounts of powdery dielectric material.

The electrically conductive layer can also be used in a simple manner can be produced that a woven or non-woven fiber layer as the carrier layer used and this with the electrically conductive mass, consisting of electrically conductive powder, binder and, if necessary, dielectric fillers will. In some cases, fiber mats can be used. The absorption capacity the fiber bashn is limited and ensures that over the entire surface of the Railway approximately the same content of electrically conductive mass is guaranteed.

When impregnating a fibrous web, for example, you can proceed as follows: that the fibrous web is passed through the liquid, electrically conductive mass and then run through a pair of nip rollers, in which the content of liquid, electrically conductive mass reduced and standardized through the squeeze will.

The first and second insulating layers can be formed from one by polymerization or polyaddition curable plastic or synthetic resin.

In addition, thermoplastics can also be used here. Particularly Curable compositions based on polyurethane have proven suitable.

Basically there is the possibility of the electrically conductive layer on a first insulating layer, which in turn on a first stationary underlay is laid and over the electrically conductive layer a to lay a second layer of insulation.

If you lay directly on a stationary surface, and this stationary base for the coating that forms the electrically conductive layer or pourable mass is absorbent, the first insulating layer must be used in any case be dimensioned so that it cancels the absorbency of the pad, so that the electrically conductive layer is not random in its composition and strength Fluctuations in the absorbency of the pad is dependent.

The production of large-area heatings according to the invention is preferred in the form of prefabricated mats. These mats can be flexible, whatever both the adaptability to uneven surfaces as well as the transport of the mats relieved. The large-area heating systems according to the invention produced in the form of mats can be glued to the base. Gluing is particularly useful the so-called two-component adhesives, which do not develop solvent vapors and water can be hardened.

Regardless of whether the mats are glued to the base or not, you can embed them in an embedding layer that is directly connected to the base connected is. With this embedding layer, joints can be made between adjacent mats fill in, but also form a cover for the mats. For the production of the embedding layer come in turn in particular those curable by polymerization or polyaddition Plastics into consideration. Curable compositions based on polyurethane are particularly suitable. The embedding layers can, however, also consist of thermoplastics.

When the direct connection between the embedding layer and the substrate ii The area of the joints between successive mats is insufficient, so may an additional one through recesses in the mats link the investment can be made with the base.

Power supply connections can be made in the electrically conductive layer be embedded, for example in the form of wires on at least one Part of their length are laid in the electrically conductive layer.

A constant flow of current over a larger area and thus A uniform heating in this area can be ensured, one can dio the area divide them into individual fields, which are arranged next to one another and one behind the other together result in a flat band, one each along the longitudinal edges of the flat band Lay the power supply line and each end of a group from across fields lying next to one another to the longitudinal direction of the tape with one power supply line and the other ends of the fields of this group with the other power supply line associate. This principle is applicable both when the electrical large area heating is laid stationary in large areas as well as when the heating is in shape is made up of mats lying next to and behind one another.

In the latter case, the joints between adjacent ones offer themselves Mats for holding power supply connection wires, especially for Connection of the adjacent mats associated wires.

You can, for example, the power supply connections from across the In the longitudinal direction of the flat belt, connect the mats lying immersed to one another.

In the case of a stationary arrangement, one can use the electrically conductive Layer a mesh across the length of the ribbon Lay connecting wires that alternate with the power supply line on one Longitudinal edge and with the power supply line on the other longitudinal edge of the ribbon are connected.

The second insulating layer and / or the embedding layer can be used as a carrier serve for a surface overlay, for example for a surface overlay granular material.

Even in the case of stationary large area heating you can make a subdivision into individual fields, which are separated by joints are separated.

The large area heating according to the invention is suitable for heating of roads, bridge surfaces, airport runways, industrial yards, roofs, in particular Flat roofs, terraces, roof terraces, house entrances, containers, rail switches, but also for wall and floor heating in apartments; in the case of the last specified Applications can be a heating point or heating wallpaper, on the inventive Building on the principle, apply it.

The accompanying figures explain the invention on the basis of exemplary embodiments. The figures show: Fig. 1 a section through a built-up from individual mats, large-area heating of a road surface according to the invention, Fig. 2 shows a plan view of the arrangement according to FIG. 3 shows a section through a large-area heating system according to the invention installed in a stationary manner and FIG. 4 shows a plan view of the arrangement according to FIG. 3, in the plan view In itself invisible power supply wires and joints are made visible.

In the embodiment according to FIG. 1, an underlay is made of asphalt or concrete denoted by 10, this base is followed by an adhesive layer 12 the adhesive layer 12 a lower insulating layer 14, on the lower insulating layer 14 the electrically conductive layer 1%. on the electrically conductive layer 16 the second insulating layer 18 and on the second insulating layer 18 an embedding layer 20. The three-layer bond - lower insulating layer, electrically conductive layer, upper insulating layer - is in the form of mats. The mats are through butt joints 22 separated from each other. to embedding layer 20 fills the 8toßfugen 22 and has Direct connection to the adhesive layer via the butt joints 22 and slots 24 of the mats 12 or, if the adhesive layer is cut out at these points, with the base 10.

In Fig. 2 you can see individual mats 26, which are in rows next to each other and are arranged one behind the other and an elongated band, for example as Form heating for a road surface. You can see there power connection wires 28, 30, which, as FIG. 1 shows, into the electrically conductive layer 16 are embedded. The stringer base wires 28 are connected to one another in the joints 22 and connected to a power supply line 32, while the connecting wires 30 are connected to a power supply line 34.

Figure 3 shows an asphalt road end 36. On this asphalt road surface a first insulating layer 38 is laid stationary; this is followed by the electric conductive layer 40 and then the second insulating layer 42.

Grit grains 44 are embedded in the second insulating layer 42. Connection wires 46, 48 are laid in the electrically conductive layer 40. The connecting wires 46 are connected to a power supply line 50, the connecting wires 48 to a power supply line 52. The connecting wires 46, 48 traverse separating lines 54.

To give an idea of the geometrical orders of magnitude, it should also be mentioned that the lower insulating layer 58 has a thickness of about 2 mm, the electrically conductive layer a thickness of approx. 2 mm and the upper insulating layer 42 has a thickness of about 4 to 5 µm.

Claims (23)

P A T E N T A N S P R Ü C H E 1. Electric large area heating with an insulating layer between two arranged electrically conductive layer, characterized in that the electrically conductive layer (16) is composed of an electrically conductive powder and a this electrically conductive powder containing, liquid applicable and curable Binder. 2. Electric large area heating according to claim 1, characterized in that that as binders synthetic resins, plastics, paints, lacquer Iner, bitumen or by Polyjerisation or polyaddition curable resins or oils are used. 3. Electric large area heating according to one of claims 1 and 2, characterized in that the electrically conductive powder with a powdery, dielectric material mixed iat. 4. Electric large area heating according to one of claims 1 to 3, characterized in that the electrically conductive layer is used as a substrate contains a woven or non-woven sheet of fibrous material. 5. Electric large area heating according to one of claims 1 to 4, characterized in that the first (14) and / or the second insulating layer (18) from a cured by polymerization or polyaddition, in liquid State of applied plastic or resin. 6. Electric large area heating according to one of claims 1 to 4, characterized in that the first (14) and / or the second Insulating layer (18) made of a layer applied in the melted state and heated through hardened thermoplastics. 7. Electric large area heating according to one of claims 1 to 6, characterized in that the first (14) and / or the second insulating layer (18) a textile reinforcement insert, e.g. B. in the form of fiberglass or fiberglass fabric, contains. 8. Electric large area heating according to one of claims 1 to 7, characterized in that the electrically conductive layer (40) on a first The insulating layer (38) is laid, which in turn is on a stationary base (36) is laid and that over the electrically conductive layer (40) a second The insulating layer (42) is laid in a stationary manner. 9. Electric large area heating according to one of claims 1 to 7, characterized in that it is in the form of a mat (26). 10. Electric large area heating according to claim 9, characterized in that that the mat (26) is flexible. 11. Electric large area heating according to one of claims 9 and 10, characterized in that the mat (26) is glued to the base (10). 12. Electric large area heating according to one of claims 9 to 11, characterized in that the mat (26) in one with the base (10) directly connected Embedding layer (20) is embedded. 13. Electric large area heating according to claim 12, characterized in that that the embedding layer (20) consists of a hardenable material by polymerization or polyaddition Made of plastic. 14. Sheet metal large-area heating according to claim 12, characterized in that that the embedding layer (20) consists of a thermoplastic. 15. Electric large area heating according to one of the speech 12 to 14, characterized in that the embedding layer (20) in the area of the joints (22) between successive mats (26) and / or through recesses (24) in the Mats (26) is directly connected through to the base (10). 16. Electric large area heating according to one of claims 1 to 15, characterized in that power supply connections (28, 30) in the electrical conductive layer (16) are embedded. 17. Electric large-area heating according to claim 16, characterized in that that the electrical power supply connections (28, 30) of at least one Part of their long formed in the electrically conductive layer (163-laid wires oind. 18. Electric large area heating according to one of claims 16 and 17, characterized in that it is divided into individual rectangular fields (26) is which by side by side and one behind the other a Flat band show that the length of the longitudinal edges of the flat band each have a power supply line (32, 34) is laid and that each end of a group is transverse to the longitudinal direction of the tape adjacent fields (26) with one power supply line (32) and the other ends of the fields of this group with the other power supply line (34) are connected. 19. Electrical large area heating system according to claim 18, characterized in that that in the case of the formation of the fields (26) in the form of individual mats, the Stroizuftihrverbinddräires (28, 3o) of mats lying next to one another transversely to the longitudinal direction of the flat strip are connected to each other. 20. Electric large area heating according to claim 18, characterized in that that in the case of a stationary arrangement in the electrically conductive layer (40) a network of connecting wires running transversely to the longitudinal direction of the ribbon (46, 48) is laid, which alternate with the power supply line (50) to a Edge and connected to the power supply line (52) at the other edge of the ribbon are. 21. Electric large-area heating according to one of claims 1 to 20, characterized in that the wide insulating layer (42) and / or the embedding layer serve as a carrier for a surface support (44). 22. Electric large area heating according to claim 20, characterized in that that the surface layer is formed from a granular material. 23. A method for producing a large area heating system according to a of claims 1 to 22, characterized in that at least one of the layers is generated by means of a slot die, which is preceded by an extruder.