DE202015103899U1 - Carbon heating plate - Google Patents

Abstract

A carbon thermal plate (1) having a first layer in the form of a so-called front side (2) and a second layer in the form of a so-called rear side (3) and one between the front side (2) and the rear side (3) Carbon heating element (4), characterized in that the carbon heating element (4) is designed as a thread whose two ends (5) are connectable to an electrical power supply.

Description

The innovation relates to a carbon thermal plate according to the preamble of claim 1.

A generic carbon thermal plate is from the US 2006/0081612 A1 known.

In the known carbon thermal plates, the heating element is designed as a heating foil, that is, as a foil in which a plurality of individual carbon fibers are arranged in a confused manner.

The innovation is based on the object to improve a generic carbon-thermal plate to the effect that it can be configured as versatile as possible and thus can be optimally adapted to different uses manufacturer-side.

This object is achieved by a carbon-thermal plate having the features of claim 1. Advantageous embodiments are described in the subclaims.

The innovation proposes in other words, not to use a foil but a thread as a heating element. By using a thread, surprisingly, a higher heating power can be achieved than by the use of a film, since the power line can be made over the entire cross section of the thread, while using a heating foil, the individual carbon fibers contained in the film only at some, arbitrarily distributed and very small surface contact points abut each other to allow the conduction of the electric current over the entire surface of the film. The consistently same and comparatively much larger cross-section of the thread used according to the proposal, in contrast, allows the achievement of higher temperatures, so that thereby a particularly intense heating effect is enabled, if this should be required.

The course of how the thread is laid between the front side and the back side of the carbon heat plate can also influence the heating intensity of the heating plate. For example, in the case of a serpentine thread course, the distance between two adjacent sections of the thread can be selected depending on the desired heating effect of the heating plate.

In favor of a uniform heating effect, the course of the thread can be chosen so that this thread extends as evenly distributed over the surface of the carbon-heat plate between the front and the back. This can be provided, for example, if the carbon-heat plate for uniform radiation heating from above a living room, working room or stable is to serve.

Alternatively, by using a thread, however, a deliberately uneven distribution of the heating effect can be made possible by the carbon heater is arranged accordingly unevenly distributed between the front and the back. For example, rest areas or berths for animals can be created within a stable or a terrarium, while a reduced heating capacity is provided outside of these quiet zones.

The carbon fiber thread used according to the proposal may be designed in the manner of a strand, that is, configured from a plurality of individual fibers running parallel to one another. Alternatively, the carbon heating element can be configured as a monofilament yarn particularly advantageous. This makes it possible, for example, to use commercially available carbon fibers offered as semi-finished products, as are commercially available, for example, for the production of CFRP components. These carbon monofilament threads are offered in different diameters, and regardless of the course of the thread between the two front and back sides of the heat plate can also be influenced by the choice of the corresponding thread diameter, the heating power to be achieved by the manufacturer. In contrast, for example, to metallic conductors, which are used as resistance heating, no switching element is required in this case, which allows greater or lesser heat output by a staggered, repeated switching on and off, but can by the choice of carbon fiber diameter constructive adaptation of the carbon Allow heat plate in such a way that at a given supply voltage, the heating power of the heat plate can be determined.

When using a carbon foil, the electrical contact must be made at the two opposite ends of the film. By contrast, according to the proposal, the thread can be laid so that its two ends are arranged at a small distance from each other, so that a single connection point is created, to which an electrical supply cable for powering the carbon heat plate can be connected easily.

When using a carbon film, the electrical contacting of the film is usually carried out by means of soldered connections. A considerably simpler electrical contacting of the carbon fiber thread provided according to the proposal can advantageously take place in that the two ends of the caron heating element by means of mechanical Connecting elements are connected to the electrical power supply. For example, commercially available clips, crimp connections or the like can be used to connect an electrical connection cable to the carbon thread. The handling of a hot, liquid filler material - such as solder - is avoided in this way, so that, for example, no splashes of hot, liquid filler material can occur, as well as the emergence of vapors is avoided, which would otherwise be sucked, so that in Result, the production of the carbon-thermal plate is simplified in this way.

In a manner known per se, the front side and / or the rear side of the carbon heat plate can each consist of plastic material. This makes it possible, for example, to embed the carbon thread between the front and the back without requiring an additional intermediate layer. If the carbon thread, for example, between two hard, non-compliant plates made of glass, metal o. The like. Arranged so would have a gap that arises between the front and the back through the intervening carbon thread, filled, for example by means of a potting compound, the at the same time, for example, by adhesive properties, for fixing the carbon thread is used when it is to be arranged in a certain course between the two plates. By using plastic material for the front and / or the back, however, it is possible to use a deformable plastic, such as a thermoplastic or not yet cross-linked thermosetting material, which allows its proper formability, the real embedding of the carbon fiber in this material. The corresponding front or back of plastic material can be connected in this case without additional adhesive or filling layers with the respective opposite back or front, including the interposed carbon thread.

Advantageously, it can be provided to design both the front side and the rear side of so-called SMC material, that is to say as a so-called "sheet molding compound". The processing of the SMC material as so-called prepregs makes it possible, similar to the handling of prefabricated panels, to process the front and / or back as a layer material without the need for special casting molds or the like. The high adhesive strength of the resins present in such a prepreg ensures that when placing the carbon thread on such a prepreg, the carbon thread retains its position, so that the desired, possibly very different thread courses proposed carbon heat plates can be realized easily and with high repeatability ,

The high adhesive strength of the resins used in the SMC material makes it possible to connect the SMC layer designed front and back with an opposite back or front of a different material. Advantageously, however, both the front and the back can be configured as SMC layers, so that as few different materials are used in the carbon heat plate and, accordingly, a recycling of the proposed carbon heat plate is facilitated.

In any case, it is an advantage of a proposal designed according to the carbon heat plate that it can be designed free of metallic materials. If an electrical supply line is provided for supplying energy, which contains metallic electrical conductors, and if they connect to the carbon thread by means of metallic mechanical elements, then the proposed carbon thermal plate can advantageously be designed so that the two ends of the carbon fiber lead out of the actual heating plate are and all metallic elements, so both the mechanical connection elements and the electrical supply line outside the heat plate are arranged. In the case of recycling, then these metallic elements can be easily separated and the entire carbon heat plate can then be recycled without containing any interfering metallic admixtures. This applies to all embodiments of the carbon thermal plate, in which both the front and the back of non-metallic materials, such as plastic material, as already mentioned above.

An embodiment of a proposed carbon-heat plate will be explained in more detail below with reference to the purely schematic representation.

It is with 1 Overall, a carbon thermal plate called a front 2 and a back 3 having, wherein these two front and back sides 2 and 3 each configured as an SMC layer. Between the two front and back sides 2 and 3 is a carbon heater 4 embedded, which is designed as a thread. This thread has two ends 5 on, which end freely in the illustrated embodiment. These two ends 5 can be connected in various ways to an electrical power supply. For trouble-free installation and commissioning of the heating plate 1 may be advantageously provided, these two ends 5 of the heating element 4 to connect to an electrical supply, the For example, has a power plug and is designed as a two-wire electrical power cord, as is commercially available for many electrical devices. The two ends 5 of the carbon heater 4 are in silicone tube sections 6 led, extending a little way to the back 3 hineinerstrecken. Incidentally, the carbon thread runs freely, that is, without a silicone sheath, so that it directly to the front 2 and the back 3 borders. The course of the thread is indicated by dashed lines in the drawing. It can be seen that the thread runs substantially serpentine and in this way a very similar heating effect over the entire surface of the carbon-heat plate 1 is possible. In the drawing is just a corner of the overall much larger carbon-thermal plate 1 seen. An edge strip of the carbon heat plate 1 Remains free of the carbon heater 4 , so in this area the heat plate 1 For example, can be surrounded by a frame, or fasteners such as screws o. The like. Extend through this edge region to a mounting of the carbon-thermal plate 1 to enable.

For purely illustrative reasons, there is a dividing line between the front 2 and the back 3 indicated. In fact, however, the two front and back sides 2 and 3 monolithically connected to each other, so that such a dividing line is not visible in practice. In such a monolithic embodiment, a renewal thermal plate as a waterproof and dirt-resistant design can be used advantageously in bathrooms or stables.

In the illustrated embodiment is provided, the front and back sides 2 and 3 each designed as an SMC prepreg, so that the entire illustrated carbon heat plate 1 is free of metallic elements. In the case of recycling, for example, it can be comminuted to serve as a filler in the production of new plastic products.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• US 2006/0081612 A1 [0002]

Claims (7)

Carbon heat plate ( 1 ), with a first layer in the form of a so-called front side ( 2 ), and a second layer in the form of a so-called back ( 3 ), and one between the front ( 2 ) and the back ( 3 ) arranged carbon heating element ( 4 ), characterized in that the carbon heating element ( 4 ) is designed as a thread whose two ends ( 5 ) are connectable to an electrical power supply. Carbon heat plate according to claim 1, characterized in that the carbon heating element ( 4 ) is designed as a monofilament thread. Carbon heat plate according to claim 1 or 2, characterized in that the two ends ( 5 ) of the carbon heater ( 4 ) are connected by means of mechanical connecting elements to the electrical power supply. Carbon heat plate according to one of the preceding claims, characterized in that the front side ( 2 ) and / or the back ( 3 ) each consist of plastic material. Carbon heat plate according to claim 4, characterized in that the front side ( 2 ) and / or the back ( 4 ) are designed as SMC layers. Carbon heat plate according to one of the preceding claims, characterized in that the carbon heating element ( 4 ) is evenly distributed, such that the carbon heat plate ( 1 ) distributed over its surface has a substantially uniform heating effect. Carbon thermal plate according to one of claims 1 to 5, characterized in that the carbon heating element ( 4 ) is distributed unevenly, such that the carbon heat plate ( 1 ) distributed over its surface has at least one zone with comparatively weaker and at least one zone with compared to stronger heating effect.

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