DE20009598U1 - Short-circuit protected heater - Google Patents

Description

Short-circuit protected heating device

The present invention relates to a heating device with at least one heating layer, through which electric current can flow at least partially in a heatable region during operation, and which can be connected to a direct voltage source via at least two electrodes in order to connect at least one of the electrodes as a supply electrode to an electrical supply potential.

State of the art

Heating devices are known, particularly for vehicle seats, which are operated with direct current. They usually have a flat, electrically conductive heating layer. This is provided with an electrode on each of two opposite edges. These are connected to the heating layer in an electrically conductive manner over their entire length. The two electrodes are connected to two poles of a direct current source to supply the heating layer with electricity.

In order to achieve uniform heating of the heated area, e.g. the seat, the heating layer covers the entire seat and is evenly supplied with current. To achieve this, the electrodes are arranged as close to the edge as possible. In order to ensure that the current passes from the electrodes to the heating layer over the entire length of the electrodes, the electrodes must be bare.

The disadvantage of this arrangement is that special safety precautions against short circuits are required at the edges of the heating element. Conductive components, such as guy wires, must be kept at greater distances.

Subject of the invention

According to the invention, the supply electrode is spaced from the edges of the heatable area.

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Prevents short circuits due to interactions with conductive objects in the environment.

It may be expedient for at least one of the electrodes to be essentially potential-free as a grounding electrode and to be arranged at least close to the edge with respect to the outer contour of the heatable area. In the sense used here, potential-free means that the applied potential is below a critical value for short circuits, preferably close to zero. This allows the entire surface of the heating layer to be used electrically without the risk of short circuits.

It may be expedient for the heatable region to be heatable by at least two resistance elements and for the potential-carrying supply electrodes of the resistance elements to be arranged at a distance from the edges of the heatable region formed jointly by the resistance elements. This also allows the construction of complex geometries using simple individual elements.

It may be expedient for the heatable area to have at least one intermediate zone through which no current flows even during operation. This enables local adjustment of the temperature of the heatable area.

It may be expedient for the heating layer to be made of a flat, electrically conductive material with a foil-like or textile structure. In the sense used here, textile structure means that the material is made of fibers or threads made of any material - in particular metallic and/or carbon-containing materials. This simplifies three-dimensional adaptation of the heating device.

It may be expedient for the electrodes to be formed by strips of electrically conductive material which are conductive over at least part of

their length are connected to the heating layer. This increases the flexibility of the heating element.

It may be useful for the heating layer to have a network of metallic filaments, wires or conductively coated threads. This increases the flexibility of the heating element.

It may be expedient for the grounding electrode to be arranged at least partially along the outer contour of the heatable area. This maximizes the usable area of the heating layer.

It may be advisable for all supply electrodes to be spaced away from the outer contour of the heated area. This ensures optimum short-circuit protection.

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The following description deals with possible embodiments of the invention. These statements are to be understood as examples only and are made with reference to:

Figure 1 shows a first embodiment of a heating device from above
Figure 2 a second embodiment of a heating device from above
Figure 3 a third embodiment of a heating device from above
Figure 4 a fourth embodiment of a heating device from above
Figure 5 a fifth embodiment of a heating device from above
Figure 6 a sixth embodiment of a heating device from above

Description of the invention

Figure 1 shows a heating device with a heating layer 2. The heating layer 2 has a polygonal, approximately round contour. In the exemplary embodiment, it is made of an electrically conductive material with a defined electrical surface resistance. For example, electrically

conductive textiles, e.g. carbon fabrics or carbon woven fabrics, wire mesh, or plastic film with embedded, electrically conductive particles. In the example, a textile with sewn-on carbon threads is provided.

Two electrodes 4, 6 are provided on the heating layer 2. These are designed in an approximately semicircular shape. They are arranged opposite one another in mirror image and form an approximately oval, heatable area 15 between them. They are each connected to a zero potential (not shown) via a connecting line 20, 21. A further electrode 8 is attached to the heating layer 2 as a supply electrode. It runs along the longitudinal axis of the oval area 15 and is equidistant from both electrodes 4, 6. The supply electrode 8 is connected to a supply potential (not shown) via a connecting line 22. The supply electrode 8 forms a resistance element 25, 25' with the grounding electrodes 4, 6.

During operation, current is fed into the supply electrode 8 via the connecting line 22. From there, the current flows via the resistance elements 25, 25' to the grounding electrodes 4, 6. In the process, the area 15 formed by the two resistance elements 25, 25' heats up. The current then flows from the grounding electrodes 4, 6 via the connecting lines 20, 21 to the ground potential.

Figure 2 shows a heating device 1 whose heating layer 2 has a rectangular outer contour. Two grounding electrodes 4, 6 are attached to the heating layer 2. The grounding electrodes 4, 6 run in a straight line and parallel to one another. They run parallel to the short central axis of the rectangular heating layer 2. The grounding electrodes 4, 6 are spaced far apart from one another and are connected to one another in an electrically conductive manner. They are connected to a grounding potential (not shown) via a connecting line 21.

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Two supply electrodes 8, 8' are provided on the heating layer 2. They run in a straight line, close to each other and parallel to each other. They run parallel to the grounding electrodes 4, 6 and are arranged approximately centrally between these two. The electrodes 4, 8' form a resistance element 25. The electrodes 6 and 8 form a resistance element 25'. An intermediate zone 27 is formed between the supply electrodes 8, 8'.

The electrodes 8, 8 ¹ are connected to a supply potential (not shown) via connecting lines 20, 22.

During operation, current is fed into the supply electrodes 8, 8' via the connecting lines 20, 22. From there, the current flows through the resistance elements 25, 25' to the earthing electrodes 4, 6. From there, it flows via the connecting line 21 to the earthing potential.

The resistance elements 25, 25' heat up and thereby heat the heatable area 15. Because the potentials are the same, no current flows in the intermediate zone 27 between the supply electrodes 8, 8'. The intermediate zone 27 cannot therefore be heated directly.

Figure 3 shows a heating device 1 which essentially corresponds to the embodiment of Figure 1. However, the supply electrode is U-shaped and has two legs 8, 8'. These largely enclose an intermediate zone 27. Since no current flows through the intermediate zone 27 during operation due to the potential of the same name on the electrode legs 8, 8', this remains unheated.

Figure 4 shows a heating device 1 with two supply electrodes 8, 8'. These run at a distance from each other and parallel to each other. They are connected to each other in a U-shape at one of their ends and connected to a supply potential via a connecting line 22.

The heating device 1 also has three grounding electrodes 4, 6, 10. These also run at a distance from one another and parallel to one another. They also run parallel to the supply electrodes 8, 8'. The grounding electrode 10 runs between the supply electrodes 8, 8'. The other two grounding electrodes 4, 6 run outside the U formed by the supply electrodes 8, 8'.

The three grounding electrodes 4, 6, 10 are each electrically connected to one another at one of their ends, which is opposite the connection end of the supply electrodes 8, 8'. In addition, the grounding electrodes 4, 6 are each connected to a ground potential at their opposite end via supply lines 20, 21.

The grounding electrodes 4, 6, 10 and the supply electrodes 8, 8' are arranged alternately next to one another at constant distances. As a result, a resistance element 25, 25", 25", 25"' is formed on the heating layer 2 between a supply electrode and a grounding electrode. In the present embodiment, these each have the same resistance and thus the same heating power. With the present arrangement, larger areas can also be heated with low voltage.

Figure 5 shows a heating device 1, on whose heating layer 2 a first, rectangular grounding electrode 4 is provided. Concentric to this grounding electrode 4 a second, also rectangular grounding electrode 6 is provided. Its dimensions are significantly smaller. It encloses an intermediate zone 27.

A rectangular supply electrode 8 is arranged between the first and the second supply electrode 4, 6. The sides of the rectangle run parallel to those of the two ground electrodes 4, 6. In the exemplary embodiment, the distance between the supply electrode 8 and the

Grounding electrodes 4, 6 are each the same size. The grounding electrodes 4, 6 are each connected to a grounding potential via connecting lines 20, 21. The supply electrode 8 is connected to a supply potential via a connecting line 22. The supply electrode 8 thus forms two rectangular resistance elements 25, 25' with the grounding electrodes 4, 6.

In heating mode, the area 15 enclosed by the outer grounding electrode 4 is heated. This results from a current flow through the rectangular resistance elements 25, 25' formed by the electrodes, which is directed essentially perpendicular to the electrodes 4, 6, 8. However, the current can only flow from the supply electrode 8 to the grounding electrode 6 in the direction of the center of the heatable area 15. The intermediate zone 27 enclosed by the grounding electrode 6 is not flowed through and therefore remains unheated.

The embodiment of Figure 6 corresponds essentially to the embodiment of Figure 5. However, the grounding electrode 6 does not have its own connecting line. It is connected to the outer grounding electrode 4 via a bridging line 23.

In order to achieve an optimal current flow in all directions in the heating layer, fibers or threads in textile carrier materials should cross, overlap or be arranged in a network.

The heating layer 2 can be constructed over its entire surface from an electrically conductive resistance material. To save material, an electrically non-conductive carrier textile can also be used and the application of conductive material can be limited to the heatable areas 25. The conductivity can also be homogeneous in all directions or preferably directed in certain directions.

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The heating layer can also be made up of several layers or partial areas. These can also be arranged overlapping in order to obtain zones with different heating output in the transition area.

The heating layer should preferably be able to flow through its entire surface in the heatable area. However, flow can also be provided through parts of the heatable area.

Claims (9)

1. Device for heating with at least one heating layer ( 2 ) through which electric current can flow at least partially in a heatable region ( 15 ) during operation and which can be connected to a direct voltage source via at least two electrodes ( 8 , 8 ', 4 , 6 , 10 ) in order to connect at least one of the electrodes as a supply electrode ( 8 , 8 ') to an electrical supply potential, characterized in that the supply electrode ( 8 , 8 ') is spaced from the edges of the heatable region ( 15 , 15 '). 2. Device according to claim 1, characterized in that at least one of the electrodes ( 4 , 6 , 8 , 8 ', 10 ) as a grounding electrode ( 4 , 6 , 10 ) is essentially potential-free and is arranged at least close to the edge with respect to the outer contour of the heatable region ( 15 ). 3. Device according to claim 1 or 2, characterized in that the heatable region ( 15 ) can be heated by at least two resistance elements ( 25 , 25 '), and that the potential-carrying supply electrodes ( 8 , 8 ') of the resistance elements ( 25 , 25 ') are arranged at a distance from the edges of the heatable region ( 15 ) formed jointly by the resistance elements ( 25 , 25 '). 4. Device according to one of the preceding claims, characterized in that the heatable region ( 15 ) has at least one intermediate zone ( 27 ) through which no current flows even during operation. 5. Device according to one of the preceding methods, characterized in that the heating layer ( 2 ') is formed from a flat, electrically conductive material with a film-like or textile structure. 6. Device according to one of the preceding claims, characterized in that the electrodes ( 4 , 6 , 8 , 8 ', 10 ) are formed by strips of electrically conductive material which are conductively connected to the heating layer ( 2 ) over at least part of their length. 7. Device according to one of the preceding claims, characterized in that the heating layer ( 2 ) comprises a network of metallic filaments, wires or conductively coated threads. 8. Device according to one of the preceding claims, characterized in that the grounding electrode ( 4 , 6 , 10 ) is arranged at least partially along the outer contour of the heatable region ( 115 ). 9. Device according to one of the preceding claims, characterized in that all supply electrodes ( 8 , 8 ') are spaced from the outer contour of the heatable region ( 15 ).