The present invention relates to a heating device and, more particularly concerns a flexible heating element for a vehicle seat or vehicle contact surface.
Heating elements such as those disclosed in U.S. Pat. No. 4,616,125 or U.S. Pat. No. 5,849,137 include two conductive films embedding a positive temperature coefficient (PTC) layer between them. Heating elements comprising conductive films are not very air-permeable and lack flexibility.
U.S. Pat. No. 5,002,336 discloses a seat with air conditioning means. It has an air-distributing layer made up of spiral springs. The air conditioning of the seat, however, is based on feeding fully conditioned air into the air distributing layer and distributing it uniformly in the seat. Such a system is bulky and lacks the ability to accurately and rapidly heat or condition the seating surface.
DE 1,993,174 discloses a heating element whose heating conductor is composed of film segments arranged in a labyrinth-fashion. In that case, the current heats by conventional resistance heating, while it flows labyrinth-fashion along the plane of the heating elements. Such heating elements are not very air-permeable and require an external temperature-regulating means.
Accordingly, there exists a need for an improved areal heating element that is highly flexible, air permeable, robust and responsive.
The present invention provides a heating element comprising at least one flexible heating resistor and at least two flexible electrodes arranged at a distance from each other and at least partially embedding the heating resistor between them. The electrodes are arranged such that current flow is directed essentially parallel to the vertical extent of the layered heating element. Both the heating resistor and the electrodes include a plurality of recesses formed therein in the direction of the vertical extent of the layered heating element. The heating element is advantageous in that it is mechanically robust and air-permeable.
The plurality of recesses can form a plurality of webs. The recesses of the various layers can be arranged congruently such that the resulting layered structure forms a net-like structure. The webs can also be stretched in at least one direction perpendicular to the vertical extent of the layered structure. This arrangement of the heating element is advantageous in that it comprises little material and is space efficient.
The heating resistor can comprise a positive temperature coefficient (PTC) material such that it limits the effective temperature range of the heating element. Some examples of temperature ranges include 35° to 90° C., 60° to 90° C. and 70° to 80° C. This embodiment has the advantage of being self-regulating.
The heating element can also include a contacting mechanism with at least two supply conductors arranged at different sides of the heating element with regard to the vertical extent of the layered structure. The supply conductors can be arranged in parallel or at substantially uniform mean intervals. This embodiment has robust electrical contacts.
The flexible heating element is adaptable to use in vehicle seats, steering wheels or other interior surfaces of the vehicle contacting or being contacted by, a vehicle occupant. The heating element may also advantageously be incorporated into a plastic such as the upholstery cushion of a vehicle seat whether the upholstery cushion is foam or cast. In this way, the heating element can act as an independent functional module within the overall seating system.
The present heating element may also be used in an air-conditioned vehicle seat. Because the heating element includes recesses, it can be arranged such that it is traversed by a stream of air, including a non-uniform stream of air, from an air conditioning system, i.e., a fan or a blower. This embodiment makes possible a uniform tempering of surfaces in contact with the occupant dispute unlike cooling tendencies.
In another embodiment, the heating element can be applied to an air-transmissive spacer layer within a vehicle seat. For example, it may be laminated to the spacer layer which may be a knotted fabric or coil springs within the seat. This embodiment also provides a lightweight, compact functional module for vehicle seating systems.
The present invention itself, together with further objects and attendant advantages, will be best understood by reference to the following detailed description, taken in conjunction with the accompanying drawing.
For a more complete understanding of this invention reference should now be had to the embodiments illustrated in greater detail in the accompanying figures and described below by way of examples of the invention wherein:
In the following figures, the same reference numerals are used to refer to the same components. While the present invention is described as a heating element for use within a vehicle seating system, it may be adapted and applied to various systems including steering wheel systems or other vehicle or non-vehicle systems requiring a heated tactile surface. In this regard, in the following description, various operating parameters and components are described for several constructed embodiments. These specific parameters and components are included as examples only and are not meant to be limiting.
Referring now to
The heating element 1 comprises a thin-layered electrical heating resistance element 5. The heating resistance element layer is about 0.5 to 1.0 mm thick. The heating resistance element 5 is made up at least in part of a positive temperature coefficient (PTC) material. A PTC material exhibits a higher specific electrical resistance at high temperatures than at lower temperatures. In particular, when the electric heating resistance element 5 is connected to an electric potential, a certain temperature cannot be exceeded, because the specific resistance of the heating resistance 5 will approach infinity. The PTC material may for example be a polymer treated with carbon black particles.
On the areal heating resistance element 5, areal, thin-layered supply electrodes 3, 3′ are arranged, and can essentially cover over the resistance element 5. The supply electrodes 3, 3′ are arranged on mutually opposed sides of the heating resistance element 5, and at the same time substantially cover the same area such that they substantially cover each other. They thereby essentially embed the heating resistance element 5 between them. The supply electrodes 3, 3′ are so arranged that in operation, they make possible a flow of electric current essentially over the entire area of the heating resistance element 5, which flow is directed essentially parallel to the vertical extent 9 of the layer. The supply electrodes 3, 3′ have a thickness of about 10 to 50μ, more specifically about 20μ. They have a substantially higher specific conductivity than the material of the heating resistance element 5.
At least one, and advantageously all of the supply electrodes 3, 3′ are made up of an electrically conductive textile. Suitable materials include knotted, woven, knitted and fleeced fabrics. Metallic fibers or synthetic fibers with metallic coating are particularly suitable for this purpose. They form a large area of contact between the electric heating resistance element 5 and the supply electrodes 3, 3′. Alternatively, at least one and advantageously all of the supply electrodes 3, 3′ are made up of a metallic or metallically coated film. The films can have a microtextured, enlarged surface area from a suitable pretreatment as is known in the art.
The supply electrodes 3, 3′ are in integral material connection with the heating resistance element 5. This may, for example, be accomplished by bonding, galvanizing, vapor deposition, laminating or other known processes.
The heating element 1 can also include at least one covering layer 7, 7′ with which at least one of the supply electrodes 3, 3′ is shielded from the environment. For example, the heating element 1, as shown, is protected on both sides (with respect to its vertical extent 9) by covering layers 7, 7′ from chemically aggressive or electrically conductive components of the surroundings. The covering layers 7, 7′ may cover over the full area of the heating element 1. Alternatively, provision may be made so that the recesses 22 described below are not overlapped by the covering layer 7.
The covering layers 7, 7′ have a thickness of about 40μ. They are made up of polyethylene or polypropylene, for example. Materials of high tearing strength are serviceable and desirable for the covering layers 7, 7′. In particular, the selection of pre-stressed, including doubly pre-stressed, films may be useful.
Each of the layers, i.e., the supply electrodes 3, 3′ and the electric heating resistance element 5, and even the covering layers 7, 7′ may be the same or different colors. Differential coloration makes possible good visual recognition of the electric contact areas. Like coloration causes the heating element to appear as a homogeneous configuration.
The recesses 22 are arranged such that essentially the entire material of the penetrated layers 3, 3′, 5 remains in the form of webs 20 in the heating element 1. In other words, the openings 22 are aligned in the several layers to create a net-like structure for the resulting heating element 1.
The heating element 1 also has a contacting members 10. The contacting members 10 comprise at least two, preferably a plurality, of supply conductors 14 running more or less parallel to each other. The supply conductors 14 have a substantially higher specific electrical conductivity than the resistance element 5, and can also have a higher specific electrical conductivity than the supply electrodes 3, 3′. The contacting members 10 comprise, for example, carbon and/or steel fibers. They can be extruded during the production of the composite of supply electrodes 3, 3′ and heating resistance element 5. In this way, an enlarged contact area is formed between the supply conductors 14 and the supply electrodes 3, 3′.
The supply conductors 14, 14′ sweep at least a portion of the heating element 1, and can sweep essentially the entire heating element 1, in at least one direction of extent of the heating element plane. Thus, they are electrically conductively connected, linearly or at a multitude of points, with the heating element 1 and, in particular, with the supply electrodes 3, 3′.
The supply conductors 14, 14′ can be arranged at more or less uniform intervals from each other. In the example of
To produce the present heating element 1, two supply electrodes 3, 3′ are first connected to the electric heating resistance element 5 to form an areal, layered structure. In this layered structure, recesses 22 are then punched. These can be in the form of lineal slits.
After introduction of the recesses 22, the heating element 1 is stretched. The stretching takes place perpendicular to the lengthwise orientation of the recesses 22. As a result, the first linear recesses 22 are widened to honeycomb-like openings. If a correspondingly great deformation takes place, the change of shape will be lasting. In other words, the heating element 1 will plastically deform to some extent to retain a net-like or honeycomb structure. After stretching, the heating element 1 also exhibits a directional texture.
The stretching takes place in at least one direction perpendicular to the vertical extent 9 of the layer. A stretch in two directions is likewise contemplated. This may, for example, be expedient to produce different zones with different heat output due to different mesh size of the grid network. Thus, the resulting mesh structure can have a higher density in some areas as compared to other areas due to additional localized stretching.
The recesses 22 are worked such that the webs 20 remaining between them in the initial state exhibit a width of about 0.1–2.0 mm, and in the later stretched state, a width of about 0.2–2.0 mm. Alternatively, the width of the webs may be greater. During stretching, however, the webs 20 may rise due to twisting in the direction of vertical extent. This may be undesirable in some applications. The length of the slits forming the recesses should be modified to avoid any undesirable raising of the webs 20 during stretching.
The recesses 22 can be of more or less equal length. In the unstretched state, they can be about 1.0–3.0 cm, such as 2.0 cm, in length. The mutually neighboring recesses 22 in the unstretched state are offset by about ¼ to ¾ of their length, and preferably about half their length, from each other. The offset takes place along the lengthwise axis of the recesses, or perpendicular to the direction of stretch and parallel to the plane of the heating element. Of course, the length of the recesses 22, or their distances from each other in a heating element, can be different. In this way, zones of non-uniform heat density can be established.
The heating element 1 is about 2 to 20 times longer in the stretched condition than in the unstretched condition. Depending upon the recess configuration, suitable ratios may include 5 to 15 times longer and, in particular, 10 times longer in the stretched state.
The heating element in the unstretched condition exhibits a thickness of about 1.0 mm. This thickness varies only slightly with stretching although, as mentioned above, some heightening may occur during stretching.
The supply conductors 14 associated with the supply electrode 3, as in the previous embodiment by way of example, are arranged offset from the supply conductors 14′ of the supply electrode 3′. The contact poles of the contacting member 10, 10′ are likewise arranged to not cover over each other, to simplify the contacting.
The web 20 made up of the heating resistance element 5 and the supply electrodes 3 is here clamped between the supply conductors 14, 14′, and thus contacted.
In operation, an electric potential is provided on the contacting members 10, 10′. This potential is passed on uniformly to the supply electrodes 3, 3′ by way of the supply conductors 14, 14′. The voltage present affects a flow of current through the heating resistance element 5. This flow of current is dependent on the resistance of the heating resistor. The local flow of current thus depends on the local temperature present. In other words, at relatively high current flows, a corresponding increase in temperature occurs, where the process starts from a low temperature. Conversely, when little current flows, little heating is done, when the process starts from a relatively high temperature due to the nature of the PTC material.
The sitting surface comprises two areas 42, 44. The area 42 is traversable by air. Here, air is transported through the sitting surface by a blower or fan 46, for example by suction or pressure. In the unventilated area 44, arranged at the margins of the ventilated area 42, the surface of the seat is merely heated. It is not traversed by air.
In the sitting surface of the seat 40, between the ventilated and unventilated areas on the one hand, and, due to non-homogeneous air flows in the ventilated area 42 on the other hand, there results a highly non-uniform cooling of the integrated heating element. Nevertheless, the heating element according to the invention can re-regulate its temperature independently with local adaptation. Thus, more current flows through the heating element parallel to its vertical extent of layer 9 in the more intensely cooled locations. In this way, the already warm areas of the seat do not continue to rise in temperature, whereas the cooler portions of the seating surface continue to warm to the desired temperature setting. A similar arrangement can be constructed in the backrest of the seat, as well.
While the invention has been described in connection with one or more embodiments, it is to be understood that the specific mechanisms and techniques which have been described are merely illustrative of the principles of the invention, numerous modifications may be made to the apparatus described without departing from the spirit and scope of the invention as defined by the appended claims.
Number | Date | Country | Kind |
---|---|---|---|
103 04 761 | Feb 2003 | DE | national |
Number | Name | Date | Kind |
---|---|---|---|
4538054 | de la Bretoniere | Aug 1985 | A |
4616125 | Oppitz | Oct 1986 | A |
5002336 | Feher | Mar 1991 | A |
5298722 | Tanaka | Mar 1994 | A |
5723845 | Partington et al. | Mar 1998 | A |
5824996 | Kochman et al. | Oct 1998 | A |
5849137 | Hogge et al. | Dec 1998 | A |
6057530 | Gurevich | May 2000 | A |
6229123 | Kochman et al. | May 2001 | B1 |
6713733 | Kochman et al. | Mar 2004 | B2 |
Number | Date | Country |
---|---|---|
1 993 174 | Sep 1968 | DE |
Number | Date | Country | |
---|---|---|---|
20040173594 A1 | Sep 2004 | US |