EP4250871A1 - Surface coating and method for the production of such - Google Patents

Abstract

The invention relates to a surface covering and a method for producing the same, the surface covering having a heating device enclosed in a material which has a base layer on which the heating device is arranged. The object that the invention described here sets itself is that Providing a heatable surface covering that can be easily integrated into an existing component or applied to an existing component and can also be flexibly adapted to the structural conditions. This object is achieved with the surface covering according to the invention in that the heating device is at least one heating foil, which can be connected to the base layer by means of an adhesive layer and can be enclosed on the base layer by means of a sealing layer, a wear layer being applied to the sealing layer, so that the sealing layer enclosing the heating foil and the heating foil itself are protected from any environmental influences.

Description

The invention relates to a surface covering with a heating device enclosed in a material, which has a base layer on which the heating device is arranged. The invention further relates to a method for producing such a surface covering and the use of such a surface covering.

Various devices for temperature control of ramps, driveways, roofs, etc. are known from the prior art.

The US patent application US 2004/0245234 A1 discloses a heating mat for outdoor use, which is characterized in that it has a structural layer, a heating element and a plurality of intermediate layers and at least one cable with a plug.

The first and second structural layers are both durable and insulating. The first of such a shift is here assigned a plurality of first layer edges, the heating element being arranged above the first structural layer. The plurality of intermediate layers are also attached to the first structural layer and are arranged in the vicinity of at least one of the first layers and the heating element. The second structural layer is ultimately attached to the plurality of intermediate layers opposite the first structural layer. Like from the Figures 1 to 3 of the patent application, this heating mat can be used for the entrance to a garage as well as for stairs, especially for basement stairs.

Unlike the invention described here, the one described in the patent application US 204/0245234 A1 However, the heating mat presented is not connected to the component, for example the garage entrance or the stairs, but is simply placed on the respective component. However, this also leads to a corresponding loss of heat, which is released into the environment without it being able to penetrate into the component that is actually being heated.

Furthermore, it is from the European patent EP 0 358 670 B1 discloses a surface covering, which consists of a heating cable enclosed by a plastic mass or a similar thread-like heating element that has an electrically insulated base layer applied to a flat structure and consisting of a flowable plastic that can be polymerized in place, as well as a heating cable arranged on the base layer has, wherein the heating cable is enclosed by means of a flowable, in-situ polymerizable plastic and containing particles of high thermal conductivity. This surface is characterized in that in order to reduce the maximum of the surface temperature to a minimum temperature in order to maintain the required working conditions and to increase the durability of the surface covering, a top layer acting as a heat compensation layer made of a material with significantly low thermal conductivity is applied to this heat-bearing layer.

The surface can also be provided with grained quartz, in particular to improve tread resistance and increase the coefficient of friction. The polymerizable plastics can be resins, in particular acrylic resins.

Based on this prior art, the object of the invention is to provide a heatable surface covering that can be easily integrated into an existing component or applied to an existing component and can also be flexibly adapted to the structural conditions.

This task is achieved with a surface covering according to current claim 1. Furthermore, this task is solved by means of the independent method claim 9 and the independent usage claim 13. Advantageous embodiments of the invention can be found in the dependent claims.

In a first aspect, the invention is a surface covering with a heating device enclosed in a material. The surface covering has a base layer on which the heating device is arranged. The surface covering according to the invention is characterized in that the heating device is initially at least one heating foil. The advantage of using a heating foil is that it can be easily laid on the base layer and easily adapted to the structural conditions prevailing on site. In addition, heating foils can withstand heavy loads, exhibit high resistance to mechanical and chemical influences and are also relatively insensitive to temperature.

So that the at least one heating foil arranged on the base layer remains in its desired position, the invention further provides for the surface covering that the heating foil is connected to the base layer by an adhesive layer. This adhesive layer can be arranged below the heating foil. But it is also conceivable that the adhesive layer partially covers the heating foil or completely encloses. According to the invention, a further layer is applied to the heating foil connected to the base layer by means of the adhesive layer, namely a sealing layer. This sealing layer serves to protect the heating foil and is intended to prevent environmental influences, such as rainwater, leaking chemicals or high heat (fire), from penetrating the heating foil so that it is not damaged. The sealing layer also serves to compensate for any unevenness in order to guarantee an even layer height.

In order to further reduce the risk of possible environmental influences penetrating and at the same time further increase the mechanical and chemical resistance, a wear layer is applied to the sealing layer.

In a further advantageous embodiment, a sealing layer is applied to the wear layer. This seals the wear layer so that the risk of any environmental influences penetrating the deeper layers of the surface covering is further minimized.

In order to be able to optimally adapt the surface covering to the conditions prevailing on site, the invention provides in an advantageous embodiment that the respective layers consist of a plastic mass. The plastic mass is particularly preferably a polymerizable and flowable resin. Particularly preferably a two-component resin, for example based on a polymethyl methacrylate resin.

So that the surface covering is also suitable for vehicles of the common type, for example cars, trucks and bicycles, the invention provides for the surface covering in a further advantageous embodiment that the wear layer has a durable material to increase the closing resistance of the wear layer. A durable material can be quartz, quartz sand, granite, or another good that increases wear resistance and can be sprinkled into the wear layer. Also will through The durable material increases the surface roughness, which in turn has a positive effect on the coefficient of adhesion and friction.

The wear layer particularly preferably has pigmentation. It is also conceivable that the durable material has pigmentation. The color of the surface covering can be individually adapted to the visual conditions on site or to the respective wishes, both in relation to the wear layer and the durable material that may be present in the wear layer.

In order to be able to ensure automated heating of the heatable surface covering by means of the heating foil integrated into the surface covering, the invention provides for the surface covering to have a sensor element for detecting the temperature and/or the moisture of the surface covering. The sensor element is preferably integrated into the wear layer. The sensor element can therefore be used to determine the temperature and/or moisture prevailing within the surface covering or on the surface of the surface covering at any time. If, for example, the temperature falls below a certain threshold value at which there is a risk that the water that may be on the surface will freeze, and the presence of any water can be determined by measuring the moisture, the heating foil can, for example, be automatically switched on to heat the surface covering. It is also conceivable that only a message about the falling below a threshold value is issued, which means that manual intervention or switching on is also conceivable.

A second aspect of the invention is a method of producing a surface covering with a heater enclosed in a material on a base layer. The method is characterized in that the at least one heating foil is connected to the base layer by means of an adhesive layer and enclosed on the base layer by means of a sealing layer. Then click on the A wear layer is applied to the sealing layer, which protects the heating foil and the sealing layer enveloping the heating foil from any environmental influences.

To increase the wear resistance of the wear layer, a durable material is advantageously added to the wear layer before it is applied to the sealing layer.

In an advantageous embodiment, the method according to the invention also provides for pigmentation to be added to the wear layer. It is conceivable to add a pigment to color the wear layer or add another colored material.

Furthermore, the method according to the invention provides in an advantageous embodiment that a sensor element for determining the temperature and/or the moisture of the surface covering is embedded in the surface covering. The sensor element is preferably embedded in the wear layer.

In a third aspect, the invention provides for the use of a surface covering according to the invention or a surface covering produced from the method according to the invention for flat structures, in particular for driveways or ramps, to prevent icing or for de-icing.

The invention is then explained in more detail using an exemplary embodiment.

Fig. 1

eine schematische Darstellung eines Ausführungsbeispiels eines erfindungsgemäßen Oberflächenbelags,

Fig. 2

ein Diagramm über den zeitlichen Verlauf der Aufheizung eines erfindungsgemäßen Oberflächenmaterials.

It shows:

Fig. 1

a schematic representation of an exemplary embodiment of a surface covering according to the invention,

Fig. 2

a diagram showing the time course of the heating of a surface material according to the invention.

Figure 1 show a schematic representation of an exemplary embodiment of a surface covering 1 according to the invention. This is made up of a base layer 2, an adhesive layer 3, a heating foil 4, a sealing layer 5, a wear layer 6 and a sealing layer 7.

The heating foil 4, which in this exemplary embodiment has a height of 0.6 mm, is connected to the base layer 2 by means of an adhesive layer 3, which can be arranged on the underside of the heating foil 4, but can also partially or completely surround the heating foil 4 . The base layer 2 is applied thinly here and has a layer height of 0.5 mm. The adhesive layer 3, on the other hand, can have a height of up to 1 mm and serves to attach the heating foil 4 to the base layer 2, so that when the sealing layer 5 is applied, the position of the heating foil 4 on the base layer 2 no longer changes. Because without the adhesive layer 3, the heating foil 4 previously arranged on the base layer 2 could shift when the sealing layer 5 is applied, which would result in an uneven temperature distribution when the surface material 1 is heated.

The heating foil 4 arranged by means of the adhesive layer 3 on the thinly applied base layer 2 here and the adhesive layer 3 itself are here enclosed by a sealing layer 5. The sealing layer 5 also serves, among other things, to level out any unevenness and in this exemplary embodiment has a layer thickness of up to 2.5 mm or a material quantity of up to 3.5 kg/m ² . The sealing layer 5 also serves to protect the heating foil 4 and the adhesive layer 3 from any environmental influences.

Furthermore, there is a wear layer 6 on the sealing layer 5. The wear layer 6 has a granite scattering, with which a high Surface roughness or a high coefficient of friction is achieved, making the surface covering particularly suitable for driving on cars and trucks. Furthermore, the wear layer 6 is colored with dark pigments, so that the surface covering 1 visually resembles an asphalt road. The wear layer 6 represents the largest layer of the surface covering compared to the remaining layers, with a layer height of up to 4 mm.

Furthermore, the surface covering 1 is provided with a sealing layer 7, with which, on the one hand, any pores within the wear layer 6 can be closed. On the other hand, the sealing layer serves as protection against the penetration of, for example, UV radiation, rainwater, etc. As a result, the longevity of the wear layer 6 can be increased with the sealing layer 7. The sealing layer 7 here has a layer height of 0.5 to 0.8 mm.

The surface covering 1 constructed in this way is arranged in a flat structure 8, for example an underground car park entrance, and only has a total height of 8 to 9 mm. Furthermore, the surface covering 1 has a sensor element (not shown) with which the temperature and/or moisture of the surface covering 1, in particular the temperature and/or moisture of the wear layer 6, can be detected. Should the temperature of the surface covering 1 fall below a certain threshold value, the heating foil 4 can be supplied with energy, with which the surface covering 1 can be heated. As soon as a certain temperature is reached, the heating foil can be switched off. This heating process can take place completely automatically and depending on threshold values to be specified.

Such a heating process is in Figure 2 shown. At the time the heating foil was switched on, the outside temperature was 1.5 °C. It can be seen here that after a very short time, i.e. within a few minutes after switching on the at least one heating foil 4 in the surface covering 1 and on it Surface, a temperature is reached that leads to the defrosting of any ice layer that may be present. This is clear from the temperature profile of the surface of the surface covering 9 and from the temperature profile within the surface covering 10. It can also be seen that the temperature within the surface covering is higher than on the surface of the surface covering, whereby this is due, among other things, to the fact that the heat on the surface is lost through the melting of any ice or to the surroundings, in particular the air is released. The use of a heating foil can also ensure even heat distribution within the surface covering. As a result, an ice-free surface can always be guaranteed with the surface covering 1 described here.

Thus, a heatable surface covering is disclosed here, which can be easily integrated into an existing component or applied to an existing component and can also be flexibly adapted to the structural conditions.

REFERENCE SYMBOL LIST

1

surface covering

2

base layer

3

adhesive layer

4

Heating foil

5

waterproofing layer

6

wear layer

7

sealing layer

8th

structure

9

Temperature profile on the surface of the surface covering

10

Temperature progression within the surface covering

Claims (13)

Surface covering (1) with a heating device enclosed in a material, which has a base layer (2) on which the heating device is arranged,
characterized in that the heating device is at least one heating foil (4), which can be connected to the base layer (2) by means of an adhesive layer (3) and can be enclosed on the base layer (2) by means of a sealing layer (5), the sealing layer (5 ) a wear layer (6) is applied so that the sealing layer (5) enclosing the heating foil (4) and the heating foil (4) itself are protected from any environmental influences. Surface covering according to claim 1, characterized in that a sealing layer (7) is applied to the wear layer (6) for sealing and increasing the mechanical and chemical resistance of the wear layer. Surface covering according to claim 1 or 2, characterized in that the respective layer consists of a plastic mass. Surface covering according to claim 3, characterized in that the plastic mass is a polymerizable and flowable resin. Surface covering according to claim 4, characterized in that the polymerizable and flowable resin is a two-component resin. Surface covering according to at least one of the preceding claims, characterized in that the wear layer (6). has durable material to increase the wear resistance of the wear layer (6). Surface covering according to at least one of the preceding claims, characterized in that the wear coating (6) has pigmentation. Surface covering according to at least one of the preceding claims, characterized in that the surface covering (1) has a sensor element for detecting the temperature and/or moisture of the surface covering (1) and/or a part or region of the surface covering (1). Method for producing a surface covering (1) according to at least one of the preceding claims 1 to 8, wherein a heating device with a material is enclosed on a base layer (2),
characterized in that at least one heating foil (4) is connected to the base layer (2) by means of an adhesive layer (3) and enclosed on the base layer (2) by means of a sealing layer (5), with a wear layer (6) being placed on the sealing layer (5). ) is applied so that the sealing layer (5) enclosing the heating foil (4) and the heating foil (4) itself are protected from any environmental influences. Method according to claim 9, characterized in that a durable material is added to the wear layer (6) to increase the wear resistance. Method according to claim 9 or 10, characterized in that a pigmentation is added to the wear layer (6) to color the wear layer (6). Method according to at least one of the preceding claims, characterized in that a sensor element for determining the temperature and/or moisture of the surface covering and/or a part or a region of the surface covering (1) is embedded in the surface covering (1). Use of a surface covering (1) according to one of claims 1 to 8 or a surface covering (1) produced according to claims 9 to 12 on a flat structure (8), in particular an entrance or a ramp, to prevent icing or to de-ice the flat structure (8).

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