EP3621409A1 - Heating film and heating plate - Google Patents

Abstract

A heating foil (1) for a heating plate (12), in particular for heating the interior of vehicles, buildings or containers on walls, ceilings and / or floors, is shown and described, with at least one conductor arrangement, the conductor arrangement comprising a plurality of current conductors (2 ) and a plurality of heating conductors (7) connectable to a voltage source (4) via the current conductors (2) for heating the heating plate (10). According to the invention, at least one heating conductor (7), preferably all heating conductors (7), has at least one heating section (10) and at least one safety section (9) for regulating the temperature of the heating conductor (7), the temperature dependence of the electrical resistance of the Heating conductor (7) in the area of the heating section (10) and the temperature dependence of the electrical resistance of the heating conductor (7) in the area of the safety section (9) are different.

Description

The invention relates to a heating film for a heating plate, in particular for heating the interior of vehicles, buildings or containers on walls, ceilings and / or on the floor, with at least one conductor arrangement, the conductor arrangement providing a plurality of current conductors and a plurality of conductors via the current conductors has a voltage source connectable heating conductors for heating the heating plate. Furthermore, the invention relates to a heating plate, in particular for heating the interior of vehicles, buildings or containers on walls, ceilings and / or on the floor.

Plate-like components for use as floor, wall and / or ceiling cladding for heating the interior of vehicles, buildings or containers are known. Such heating plates are used, for example, to uniformly heat the interiors of vehicles, in particular rail vehicles, buses and airplanes. For this purpose, heating plates on the floor, the walls and / or on the ceiling can be attached individually or across the board.

Common heating plates usually have two cover plates. The two cover plates can be connected to one another and spaced from one another, for example, via a wave-shaped intermediate plate. The undulating intermediate layer gives the heating plate a high level of rigidity and at the same time enables a high weight saving compared to a solid material. Heating cables can be laid in a meandering manner in the wave channels of the plate core. For easy installation, known heating plates generally have only one heating cable running through the heating plate in a meandering fashion. If the heating conductor is damaged at one point and the current flow is interrupted, the heating plate can no longer fulfill the heating function. In particular, the subsequent drilling of holes or fasteners in such heating plates is made considerably more difficult or impossible. Holes and fasteners can therefore only be made at certain points in the heating plate. Knowledge of the exact position and the course of the heating conductor is necessary for this. This increases the effort in connection with the laying of the heating plates.

Temperature sensors, which are part of a control system, are used to control and set the plate temperature of heating plates. If a threshold temperature of the heating plate is exceeded, the heating output of one Heating cable can be reduced via a controllable voltage or current source or the voltage source is switched off completely. If the temperature falls below a minimum, the heating output can be increased again or the voltage source can be switched on. In the simplest case, an on-off switching or regulation is implemented in this way.

Regulations of the aforementioned type are expensive, on the one hand, and thus increase the costs for producing the heating plate. On the other hand, a failure of the control system can lead to uncontrolled heating of the heating plate.

If the temperature of the heating plates is controlled via temperature sensors, these heating temperatures can only be recorded at certain points. If, for example, a thermal barrier is applied locally to the heating plate, for example by placing a case on the plate, this area heats up more when the plate is heated compared to the rest of the heating plate. If there is a temperature sensor in the area of the heat barrier, the sensor detects the higher temperature of the heating plate in this area and the heating of the plate is reduced overall. However, this leads to a greater temperature drop in areas outside the heat barrier, so that the hotplate temperature in these areas can drop below a predetermined target temperature. This can lead to excessive cooling of a heated interior. Conversely, when a heat barrier is applied, the heating plate can heat up in an impermissible manner at a distance from a temperature sensor and thus endanger the safe functioning of the heating plate.

The object of the present invention is to provide a heating film for a heating plate and a heating plate, in particular for heating the interiors of vehicles, buildings or containers on walls, ceilings and / or on the floor, which can be produced inexpensively and are easy to install and with little control effort Allow even heating even if local heat barriers occur.

The above object is achieved by a heating foil with the features of claim 1 and by a heating plate with the features of claim 10. The sub-claims reflect advantageous embodiments of the invention. According to the invention, at least one heating conductor, preferably all heating conductors, has at least one heating section for heating the film and at least one safety section for automatically regulating the temperature of the heating conductor when the heating film is energized, the temperature dependence of the electrical resistance of the heating conductor in the area of the heating section and the temperature dependence of the electrical resistance of the heating conductor in the area of the safety section are different. Due to the different temperature dependencies of the electrical resistance in the area of the heating section and of the safety section, the electrical resistance of the corresponding sections changes advantageously to a different degree when the temperature of the heating plate changes, in particular when a heat barrier is applied. If a heating conductor heats up, for example due to a heat barrier applied in the area of a heating conductor, the electrical resistance of the heating conductor increases more in the area of the safety section, which results in a reduced current flow through the heating conductor and a temperature reduction in the heating foil in the area of this heating conductor . The use of a temperature sensor and active regulation of the heating power of the heating foil can be dispensed with, the temperature of the heating conductor being regulated passively by the safety section. The accuracy of the passive temperature control of the heating conductors can correspond to a deviation of +/- 10 ° C, preferably +/- 5 ° C, more preferably +/- 3 ° C or less from a predetermined target temperature.

For the purposes of the invention, a positive temperature coefficient means that the specific electrical resistance increases with increasing temperature. As a result, the safety section conducts the electrical current better at low temperatures than at high temperatures. If the temperature of the heating conductor rises, the electrical resistance in the area of the safety section consequently increases more than in the area of the heating section. The safety section thus primarily serves to regulate the heating temperature of the heating conductor, while the heating section primarily serves for heating.

The current conductors of the heating foil according to the invention can be connected to a voltage or current source for energizing and thus heating the resistance of the heating conductors. The current conductors and the heating conductors can differ in particular by their electrical resistance and / or their geometry, the line cross section and / or by the conductor material. The electrical resistance determines what electric current flows through the heating conductor at a certain voltage. The electrical resistance of a conductor, also called ohmic resistance, results from the product of the specific electrical resistance of the conductor material and the conductor length divided by the cross-sectional area of the conductor. The specific electrical resistance is a temperature-dependent material constant.

The current conductor generally has a circular cross-sectional area, although other cross-sectional geometries are also not excluded. In contrast to this, in addition to a round cross-sectional shape, the heating conductor can, for example, also have a rectangular cross-sectional shape in order to increase the ratio of surface area to volume of the heating conductor. Current and heating conductors can advantageously be printed or glued onto a carrier material, in particular a film material, which results in a low height of the heating film according to the invention. Current and / or heating conductors are particularly preferably designed as flat conductor strips, which leads to a small thickness of the heating foil according to the invention.

The heating conductor can have a material with a higher positive temperature coefficient in the area of the safety section than in the area of the heating section and / or in the area of the safety section can consist of a material with a higher positive temperature coefficient than in the area of the heating section.

In a preferred embodiment, at least one safety conductor, which is electrically connected to at least one heating conductor, is provided for regulating the temperature of the heating conductor, the safety conductor having a temperature-dependent electrical resistance with a higher temperature coefficient than the heating conductor in the region of its heating section. The safety conductor and the heating conductor are preferably made of different materials. The safety conductor preferably has a PTC resistance behavior. An electrical conductor with a temperature-dependent resistance is referred to as a PTC resistor, PTC thermistor or PTC thermistor, the conductor conducting the electrical current better at low temperatures than at high temperatures. In the present case, PTC resistance behavior is not to be understood as the electrical resistance of pure metals, which increases linearly with the temperature. The PTC resistance method according to the invention is characterized in that that the resistance-temperature characteristic curve has a transition temperature, above which the resistance preferably increases essentially exponentially. This transition temperature is also called the Curie temperature.

If the transition temperature is exceeded, the resistance of the safety conductor can increase, for example by 20%, preferably by 30% or more, when the temperature rises by 1 ° C. With a constant voltage, an increase in resistance due to Ohm's law leads to a lower current. The range of the transition temperature therefore represents a threshold above which the current flow through the safety conductor is greatly reduced. The heating conductors electrically connected to the safety conductor are then energized with a lower current intensity, so that the heating power of the corresponding heating conductors is reduced. The heating power corresponds essentially to the electrical power, namely the product of the electrical voltage and the electrical current. In this way, a simple regulation of the heating conductor temperature to a certain temperature value is possible. The transition temperature can be set to a desired value by selecting the appropriate safety conductor.

The safety section of a heating conductor can be implemented by electrically connecting the heating conductor to the safety conductor. The heating conductor is electrically connected to the safety conductor in the area of the safety section. The total resistance of the heating conductor in the area of the safety section then results from the individual resistances of the heating conductor and the safety conductor, in the area of the safety section a parallel connection of the resistances of the heating conductor and the safety conductor in the direction of the current flow or in the direction of the heating conductor can be realized. When connected in parallel, the resulting total electrical resistance of the heating conductor in the area of the safety section corresponds to the product of the two individual resistances of the heating conductor and the safety conductor divided by their sum. By electrically connecting the safety conductor to the heating conductor, a self-temperature-regulating safety section of the heating conductor can be formed in a simple and inexpensive manner.

In an advantageous embodiment, at least one safety conductor is provided, which is electrically connected to a plurality of heating conductors, preferably to all heating conductors of a film web of the heating film according to the invention. To this The temperature of all the heating conductors that are electrically contacted with the safety conductor can be regulated in a simple manner with preferably only one safety conductor.

It is expedient if the heating foil is essentially in the form of a web or strip, at least one current conductor being arranged on each of the two longitudinal edges of the heating foil and, preferably, the current conductors being parallel to the longitudinal edges. The heating conductors can be electrically contacted at the ends with a current-carrying current conductor or a current-carrying current conductor. The two current conductors can be connected to a voltage or current source, a current-carrying and a current-carrying current conductor, viewed spatially, can run parallel to one another. In this way, the connection and energization of heating conductors can be ensured over the entire length of a film web. The safety conductor can preferably run essentially parallel to the current conductors.

A plurality, preferably all, of the heating conductors are preferably arranged in a parallel circuit, so that the same voltage is present across each heating conductor. The power supply takes place via at least one current-carrying current conductor and at least one current-carrying current conductor. The parallel connection of the heating conductors ensures that if the current flow through a heating conductor is interrupted, for example by drilling holes or mechanical fastening elements such as screws, into a heating conductor, the heating output of the other heating conductors is not impaired, and thus the heating function of the heating foil continues is guaranteed.

The heating conductors preferably have a linear course and are preferably also arranged parallel to one another. Heating conductors lying one behind the other in the longitudinal direction of the heating foil can have the same distance from one another. This applies particularly preferably over the entire length of a film web of the heating film. If the heating conductors are spaced from one another, for example in the range between 5 mm to 20 mm, preferably up to 10 mm, uniform heat emission can be achieved via the heating foil.

In an advantageous embodiment of the invention, the heating conductors preferably extend essentially over the entire film width of a film web heating foil according to the invention. In this way, uniform heat emission over the width of the film web is made possible.

A web-shaped heating foil according to the invention can have a conductor arrangement which is formed by two current conductors running spatially parallel to the longitudinal edges of the heating foil and a plurality of heating conductors arranged transversely to the longitudinal direction of the heating foil, the heating conductors being connectable to a voltage source via the current conductors. This conductor arrangement can extend over the entire length of the heating foil, wherein the heating conductors can extend essentially over the entire foil width. Preferably, only a single safety conductor is provided, the safety conductor electrically contacting a plurality of heating conductors, preferably all heating conductors, of the conductor arrangement, and the safety sections of the heating conductors being implemented in the contact points.

The heating conductors can extend transversely to the longitudinal direction of a film web of the heating film according to the invention and can be equally spaced from one another. However, it is also possible for heating conductors to be arranged in groups, a group being formed by a plurality of heating conductors with a certain equal distance from one another and with individual groups being spatially separated from one another by a greater distance in the longitudinal direction of the film web.

A film web of the heating film according to the invention can advantageously also have a plurality of conductor arrangements of the aforementioned type, which can be arranged next to one another in the longitudinal direction of the film web.

It is also possible for a film web of the heating film according to the invention to have a plurality of conductor arrangements, it being possible for each conductor arrangement to be connectable to its own voltage source or to a common voltage source. Several conductor arrangements can also be electrically connected to one another in a series connection. Each conductor arrangement can have a separate safety conductor. However, it is also possible for a safety conductor to be electrically connected to the heating conductors of several conductor arrangements.

The safety section can preferably be implemented in the region of half the length of the heating conductor. The safety conductor can do this in the middle of the heating conductor be connected to the heating conductors and / or be equally spaced from both current conductors.

With a film web of the heating film according to the invention, current conductors and safety conductors preferably also extend essentially over the entire film length. Current conductors and safety conductors are preferably designed as continuous conductor tracks that run in a straight line. A corresponding heating foil can easily be cut to a desired length.

The heating film preferably has at least one base film and at least one cover film, current conductors, heat conductors and preferably only one safety conductor being inserted between the films and fixed between the base film and cover film. The base film and the cover film can be glued together. Alternatively, however, it is also possible to use other joining methods for connecting the two foils. The base film and the cover film can consist of a plastic material. A crosslinked plastic, for example polyvinyl chloride (PVC), is preferably used.

Furthermore, the invention comprises a heating plate, in particular for heating the interior of vehicles, buildings or containers on walls, ceilings and / or on the floor, with at least one heating foil, in particular of the type described above. The heating plate can be a base plate, preferably made of a wood and / or composite material, and a cover plate, preferably also made of a wood and / or composite material. The insulation layer can consist of common insulation materials, such as polystyrene.

A cutout can be made in the base plate, into which a layer of insulation is made. The insulation layer can also be applied to a flat side of the base plate, preferably over the entire surface and on the inside. A heating foil can be provided on the insulation layer or arranged at a distance from the insulation layer. As a result, the heating foil is only insulated in the direction of the walls or the floor or the ceiling. In this way it can be ensured that the interior is heated as best as possible and at the same time as little heat as possible is conducted in the opposite direction to the walls or floor and ceiling.

The cover plate is preferably firmly connected to the base plate and can preferably also be in contact with the heating foil for good heat transfer. It is advantageous if the cover plate has the same base area and the same base area geometry as the base plate.

A decorative layer can be applied to an outside of the cover plate. The decorative layer can be common floor, wall or ceiling cladding, such as carpet, laminate or other decorative materials.

The base plate can have a thickness of, for example, between 5 and 50 mm, preferably between 10 and 40 mm, preferably of 15 mm. The base plate and the cover plate can each be formed from a wooden plate or a particle board. The cover plate can for example have a thickness between 1 mm and 10 mm, preferably between 2 and 8 mm, preferably 4 mm. The heating foil preferably has a thickness of less than 5 mm, preferably less than 2 mm, particularly preferably less than 1 mm.

A heating plate can have a single heating foil section or a plurality of heating foil sections arranged side by side and / or one above the other. If several heating foil sections are provided, each heating foil section can be connectable to a common voltage or current source. The heating foil sections can be connected to one another in an electrical series connection, for example.

The invention is not limited to the description of individual embodiments in paragraphs or to the following description of the figures, but also includes any combination of the forms and embodiments as well as their obvious and / or obvious further developments.

Fig. 1

eine schematische Darstellung eines Abschnitts einer bahnförmigen erfindungsgemäßen Heizfolie und

Fig. 2

eine schematische Querschnittsansicht einer erfindungsgemäßen Heizplatte.

Show in the drawings

Fig. 1

is a schematic representation of a portion of a web-shaped heating foil according to the invention and

Fig. 2

is a schematic cross-sectional view of a heating plate according to the invention.

In Fig. 1 A web-shaped heating foil 1 according to the invention is shown. The heating film 1 has a current conductor 2 on each of the two longitudinal edges, the current conductors 2 each running parallel to the longitudinal edge of the film 1. The current conductors 2 can be connected to a voltage source 4 with an anode 5 and a cathode 6 via current-conducting connecting cables 3.

The current conductors 2 are electrically connected to one another across the width of the heating foil 1 via a plurality of heating conductors 7. The heating conductors 7 are arranged in a parallel circuit and are connected at the ends to the current conductors 2. The voltage source 4 energizes the current conductors 2 and the heating conductors 7, as a result of which the heating conductors 7 heat up. A possible increase in temperature of the current conductors 2 is, however, preferably less in comparison to the heating conductors 7. By selecting the heating conductors 7, more precisely by the number of heating conductors 7, the heating conductor geometry and the heating conductor material, the heating foil 1 can be specifically adapted to a purpose, in particular the heat to be given off. The set voltage of the voltage source 4 is particularly important.

The heating conductors 7 are electrically contacted to one another in a central region, preferably in the region of half the length of the heating conductors 7, via a safety conductor 8. The safety conductor 8 preferably runs in the longitudinal direction parallel to the two current conductors 2.

The safety conductor 8 is placed on the heating conductors 7 running transversely thereto and electrically contacted at the crossing points. In the area of the electrical connection of a heating conductor 7 to the safety conductor 8, a safety section 9 of the heating conductor 7 is implemented. The total electrical resistance of the heating conductor 7 in the area of the safety section 9 then results from the individual resistors of the heating conductor 7 and the safety conductor 8 connected in parallel. Because of this parallel connection, the heating conductor 7 has a changed electrical resistance behavior in the area of the safety section 9.

The sections of the heating conductors 7 between the current conductors 2 and the safety section 9 are referred to below as heating sections 10, since these sections of the heating conductors 7 predominantly contribute to the heating of the heating foil 1. The safety conductor 8 preferably has a PTC resistance behavior. If the temperature of the heating film 1 increases in a film section, for example because a heat barrier, such as a suitcase or the like, has been placed on the heating film 1, the electrical resistance of the safety conductor 8 increases in this film section due to the PCT behavior of the safety conductor 8 and thus also the total electrical resistance of the heating conductor 7 in this section of film. In this way, the current flow through the heating conductors 7 in this film section can be reduced, which leads to a decrease in the temperature of the heating film 1. The current flow through each heating conductor 7 is thus independently reduced and passively regulated via the safety conductor 8 depending on the temperature.

In the Fig. 1 The heating film 1 shown has three heating areas 11, each heating area 11 having a plurality of heating conductors 7 which are equally spaced apart and run transversely to the longitudinal direction of the film web. A larger distance is provided between adjacent heating areas 11. Depending on the required length of a section of a film web of the heating film 1 according to the invention, the heating film 1 can be cut at any point between two heating conductors 7, preferably between two heating areas 11, parallel to the heating conductors 7. If the current conductors 2 of the separated section are then connected to a voltage source, this section can be used for heating in the manner described. The conductor arrangement shown, comprising current conductors 2 arranged in parallel and a safety conductor 8 and heating conductors 7 arranged transversely thereto in a parallel connection, thus opens up the possibility in a simple manner of separating film sections with lengths adapted to the application from the film web.

A plurality of heating foils 1 can be connected to one another in an electrical series connection, for example. Alternatively, several heating foils 1 can also each be connected to their own voltage source 4.

A heating foil 1 can also have a plurality of safety conductors 8, wherein the safety conductors 8 can be arranged parallel to one another and can extend over the entire length of the heating foil 1. In this way, the sensitivity of the heating foil to local temperature increases can be increased.

The heating film 1 according to the invention can consist of a base film and a cover film, which in Fig. 1 are not shown in detail, the current conductors 2, the heating conductor 7 and the safety conductor 8 are immobilized between the foils. The base film and the cover film can, for example, be glued to one another in order to fix the position of the conductors 2, 7, 8 arranged between them relative to one another.

In Fig. 2 a heating plate 12 with a heating foil 1 according to the invention is shown. The heating plate 12 has a base plate 13, which is preferably made of wood or chipboard. A recess 14 is provided in the base plate 13, which essentially corresponds to the size of the heating foil 1. An insulation layer 15, for example made of polystyrene, can be arranged in the recess 14. The heating film 1 can then be applied to the insulation layer 15. Alternatively, the heating foil 1 can also be arranged at a distance from the insulation layer 15.

In addition, a cover plate 16 is provided, the cover plate 16 preferably having essentially the same base area and geometry as the base plate 12. The cover plate 16 is arranged on the base plate 13 and covers the heating foil 1, the recess 14 and the insulation layer 15 completely. The cover plate 16 is preferably fixed to the base plate 13. The cover plate 16 preferably has a lower height than the base plate 13. A decorative layer 17 can be arranged on the cover plate 16.

The arrangement of the insulation layer 14 and the heating film 1 within the heating plate 13 ensures that a large part of the heat generated by the heating film 1 when it is energized is dissipated in the direction of the decorative layer 17 and released to the environment. For this purpose, the heating plate 12 is arranged in a room to be heated such that the base plate 13 rests on a floor or bears against a wall or a ceiling. <b> List of reference symbols: </b> 1 Heating foil 10th Heating section 2nd Conductor 11 Heating area 3rd connection cable 12th Hot plate 4th Voltage source 13 Base plate 5 anode 14 Recess 6 cathode 15 Insulation layer 7 Heating conductor 16 Cover plate 8th Security manager 17th Decorative layer 9 Security section

Claims (10)

Heating film (1) for a heating plate (12), in particular for heating the interior of vehicles, buildings or containers on walls, ceilings and / or floors, with at least one conductor arrangement, the conductor arrangement comprising a plurality of current conductors (2) and a plurality of Has heating conductors (7) for heating the heating plate (10) which can be connected via the current conductors (2) to a voltage source (4), characterized in that at least one heating conductor (7), preferably all heating conductors (7), has at least one heating section (10) and at least one safety section (9) for regulating the temperature of the heating conductor (7), the temperature dependence of the electrical resistance of the heating conductor (7) in the region of the heating section (10) and the temperature dependence of the electrical resistance of the heating conductor (7) in the region of Security section (9) are different. Heating film (1) according to claim 1, characterized in that the security section (9) has a temperature-dependent electrical resistance with a higher positive temperature coefficient than the heating section (10). Heating foil (1) according to one of Claims 1 or 2, characterized in that at least one safety conductor (8), which is electrically connected to at least one heating conductor (7), preferably a plurality of heating conductors (7), for regulating the temperature of the heating conductor (7) The safety conductor (8) has a temperature-dependent resistance with a higher temperature coefficient than the heating conductor (7) in the region of the heating section (10). Heating film (1) according to one of the preceding claims, characterized in that a safety section (9) is formed by electrical connection of the safety conductor (8) to the heating conductor (7). Heating foil (1) according to one of the preceding claims, characterized in that the heating foil (1) is substantially web-shaped, a first current conductor (2) on one longitudinal edge of the heating foil (1) and a on the other longitudinal edge of the heating foil (1) second current conductor (2) is arranged, and wherein, preferably, the current conductors (2) run parallel to the longitudinal edges. Heating foil (1) according to one of the preceding claims, characterized in that the heating conductors (7) are arranged in a parallel connection between the current conductors (2). Heating foil (1) according to one of the preceding claims, characterized in that the heating conductors (7) preferably extend essentially over the entire width of the foil. Heating film (1) according to one of the preceding claims, characterized in that the security section (9) is provided in the region of half the length of the heating conductor (7). Heating film (1) according to one of the preceding claims, characterized in that the current conductors (7) and the safety conductor (8) preferably extend essentially over the entire length of the film. Heating plate (12) in particular for heating interiors of vehicles, buildings or containers on walls, on a ceiling and / or on the floor, with at least one heating foil (1) according to one of the preceding claims.

Images