DE102015004004A1 - Heating element for user-accessible surfaces - Google Patents

Abstract

The invention relates to a heating element for surfaces which can be touched by the user, in particular a surface in a vehicle interior, wherein the heating element has at least one carrier material, on which at least one heating conductor, which in particular runs in waves or meanders, and at least one temperature sensing element are arranged, characterized the at least one temperature detection element is embodied as at least one temperature detection conductor separate from the heating conductor, which changes its electrical resistance as a function of its temperature, wherein the temperature detection conductor follows the course of the heat conductor at least partially substantially parallel to one another.

Description

The present invention relates to a heating element for user berührbare surfaces, in particular a surface in a vehicle interior, wherein the heating element comprises at least one carrier material on which at least one heating conductor, which in particular wavy or meandering, and at least one temperature sensing element are attached.

Heating elements for heating surfaces in vehicles that a user comes in contact with, such as seats, are now standard features. In addition to seats but increasingly steering wheels are equipped with heating elements.

The temperature of such heated surfaces can usually be adjusted by the user. In order to detect the respective actual temperature, a temperature sensor is provided, which is part of a control loop. As a temperature sensor, for example, an NTC sensor is used, which has the shape similar to a soldering point or a soldering pin with connecting wires. Consequently, such an NTC sensor detects the temperature of the heating element only at certain points and can be due to its shape on the surface of the heated surface.

The DE 100 48 181 A1 describes a heating handle with a heating element that is used for motorcycles. The heating handle comprises a handle tube, on the outer circumference of a heating wire is wound spirally. The heating wire consists of a material with a relatively high temperature coefficient, for example, of pure nickel. To control the temperature of the heating handle, a comparison of the actual temperature is made with a target temperature, for which the heating of the heating element is interrupted at certain intervals to determine the temperature of the heating handle on the voltage drop in the measuring current to the heating element. The voltage value is compared with a reference value that corresponds to the setpoint temperature. If the measured value is below the reference value, a new heating process is started.

The DE-OS 2 208 485 describes a method and a device for the electrical heating of workpieces or molds with a heating resistor, which is also used as a sensor for a heating or influencing control or regulating device. For this purpose, the heating resistor is alternately connected to a heating current source and to a measuring circuit of the control or regulating device.

The DE 100 55 141 A1 relates to a heating conductor, in particular for heating elements of a motor vehicle seat. So that the heat conductor used is resistant to the corrosion phenomena occurring in seats and has a high mechanical flexibility, at least one individual conductor is electrically separated from all the other individual conductors by the conductors, which are combined in one strand and come into contact with one another from a conductive material of the heating conductor. In addition, at least one individual conductor may be made of a material which changes its electrical resistance as a function of the temperature of its own, such a single conductor functioning as a temperature sensor. As a material for this single conductor nickel, iron or alloys are used, which have a high temperature coefficient and thus produce a large output signal in the form of a change in resistance.

The present invention is based on the object to provide a heating element that reproducible temperature measurements corresponding to the temperature on the surface of the heated surface, due to the temperature detection used for the control loop, in which the heating element is integrated supplies, and in which the Temperature sensing element has no surface-visible dimensions, as is the case with NTC temperature sensors.

This object is achieved by a heating element with the features of claim 1. Preferred embodiments of this heating element are specified in the dependent claims.

The heating element according to the invention is characterized in that the at least one temperature detection element is designed as at least one temperature detection conductor separate from the heating conductor, which changes its electrical resistance as a function of its temperature. In addition, the at least one temperature detection conductor is substantially parallel to the heating conductor and spaced therefrom and follows the course of the heating conductor at least partially, this means in particular that the heating conductor runs parallel to this over at least a portion of the length of the heating conductor, regardless of whether the heating element is rectilinear, wavy or meandering or otherwise positioned. Such a temperature detection conductor is designed as a thin wire, which preferably has a diameter which is smaller than the diameter of the heating conductor, so that it is not characterized by a surface material, such as a reference material.

With the heating element, the temperature is detected over a larger area, so that the effect of so-called hotspots is avoided. Furthermore, the temperature of the heating element and thus ideally the surface of the heated area is detected.

It is preferably provided that the length of the temperature detection conductor, with which it runs at a distance substantially parallel to the heating conductor, is at least 1/10 of the length of the heating conductor. This length of the temperature detection conductor can also be divided into several sections; Also, the temperature detection conductor can run in a loop between the heating conductor, by starting from a terminal end and is returned with its other end back to this terminal end. In any case, it is ensured that the temperature detection conductor detects the temperature of the heating element over a large area.

Preferably, the temperature detection conductor is made of metal or a metal alloy. In addition, it should preferably be ensured that the temperature detection conductor has a higher temperature coefficient than the temperature coefficient of the heating conductor. For many applications, it is advantageous that the temperature detection conductor consists of nickel or a pure nickel material. Furthermore, it is preferred that the temperature detection conductor consists of carbon (carbon) or of carbon-containing, electrically conductive plastic or a plastic which has metal particles.

Particularly preferred is a monofilament temperature sensing conductor, i. H. a detection conductor with only one strand, so that in case of failure due to a conductor break a correct detection is possible and no false, but realistic temperature is measured. Such a temperature detection conductor may have a diameter or a strand thickness of in each case 40 μm to 200 μm, preferably from 50 μm to 150 μm, particularly preferably between 70 μm and 110 μm. The diameter of the temperature sensing conductor, particularly when implemented as a monofilament temperature sensing conductor, may be less than, for example, the fibrous structure or weave structure of a substrate on which the heating conductor and temperature sensing conductor are deposited, or a fibrous structure in which the heating conductor and the temperature sensing conductor are embedded are, be.

However, it is also provided for some applications of the heating element, the temperature sensing conductor mehrlitzig, preferably 2- to 6-litzig form, so that the temperature detection conductor gains strength, if it can be assumed that the temperature detection conductor is subjected to high stresses. The number of strands results from the basic resistance of the temperature detection conductor, its temperature coefficient and the expected temperature range. The change in resistance when a single strand breaks must lead to a measured temperature that is outside the expected temperature range. However, in a use of the heating element in a steering wheel for steering wheel heating or as heating a cladding surface in a vehicle interior, a 1-litziger, optionally also a 2-litziger, temperature sensing conductor is preferred.

By the heating element according to the invention a better control of the surface temperature of the heated surface is achieved. The temperature of the heating element is averaged over a larger area while the heating element is in operation so that the surface temperature can be more sensitively and thus better controlled. Since the temperature is not measured locally at a single point via the temperature detection conductor, the influence of the high temperature of the heating element in the connection region is also reduced for heating elements with a small surface area.

Unless otherwise indicated, the dimensions and geometries of the various structures shown herein are not intended to limit the invention, but other dimensions or geometries are possible.

Further details and features of the invention will become apparent from the following description of exemplary embodiments with reference to the drawing. In the drawing shows

1 a heating element according to the invention, which is provided for the heating of a steering wheel, in its development,

2 a steering wheel in a schematic representation in which the heating element of 1 is used

3 a section through a heating element, in which the heating conductors and the conductors of the temperature sensing element are mounted on a support material with an auxiliary thread, and

4 a cut according to the 3 in which the heating conductors and the conductors of the temperature sensing element are fixed on a carrier material by means of an adhesive layer,

5 a section of a heating element in a further embodiment according to the invention, and

6 a section of another heating element according to the invention.

The heating element as it is in 1 represented and with the reference numeral 1 is designated, finds its application in areas with which a user comes into contact, especially surfaces in the automotive sector. This includes trim parts, the grip surfaces of a steering wheel, a gear knob, door panels, armrests, but also surfaces of a seat. The preferred area of use, however, are heated surfaces that are not padded, and those in which a substrate is directly related to a reference and in which the temperature sensing element is not intended to be apparent from the reference.

As the 1 and 3 to 6 show comprises the heating element 1 a carrier material 2 , For example, a knitted or woven fabric, but especially a non-woven or a film, which form a thin pad. The heating element 1 as it is in 1 is shown, in particular for heating the surface of a steering wheel rim 3 a steering wheel 4 that is schematically in 2 is shown provided and correspondingly has a length which corresponds to the outer circumference of the steering wheel rim 3 equivalent. For the clear assignment of the heating element 1 of the 1 to the steering wheel of 2 is a dash-dotted reference line drawn in both figures.

On this carrier material 2 are, starting from a connection area 5 , several heating conductors 6 distributed over the surface in a meandering or undulating course such that the two ends of each heat conductor 6 at the connection area 5 end up. Between these heating conductors 6 runs a temperature detection conductor 7 which forms a temperature sensing element. The course of this temperature detection conductor 7 is set so that the temperature sensing conductor 7 from the heating conductors 6 is disconnected and nowhere with a heat conductor 6 crosses. In addition, the temperature detection conductor runs 7 at least to the one heating conductor 6 who in 1 represented by a broken line (in contrast to the heating conductors 6 in dotted line), substantially parallel spaced.

Also, the two ends of the temperature sensing conductor running in a loop 7 ends at the connection area 5 , from which also the ends of the heating conductors 6 go out there and arrive again, so that the ends of both the heating conductor 6 as well as the temperature detection conductor 7 at the connection area 5 can be connected.

As in the cross sections of the 3 and 4 is indicated, is the temperature detection conductor 7 with a very small diameter as a strand or as a multi-stranded conductor such that the diameter of the temperature sensing conductor 7 less than the diameter of the heating conductor 6 , This ensures that the temperature sensing conductor is not affected by a reference that the heating element 1 covering, as in any case the structure of the heating element 1 is chosen so that the heating conductors 6 not by a reference and then certainly not the temperature detection conductor 7 sign off by reference.

The heating conductors 6 and / or the temperature detection conductor 7 can with a thread 8th on the carrier material 2 attached, for example, sewn. As an alternative, it is also provided, the heating conductor 6 and / or the temperature detection conductors 7 over an adhesive layer 9 with the carrier material 2 connect to. For the adhesive layer 9 For example, a suitable adhesive, preferably a hot melt adhesive or a laminating adhesive, may be used. Also it is beneficial to the adhesive layer 9 only occasionally on the carrier material 2 apply, for example, by a dot pattern or dot pattern of an adhesive material. Another possibility is the heating element 6 and the temperature detection conductor 7 between two carrier materials 2 , which are connected to each other via an adhesive layer to attach.

An essential feature of the heating element 1 can be seen in that the temperature detection conductor 7 over at least 1/10 of the length of one of the heating conductors 6 is substantially parallel thereto, that is, the temperature detection conductor 7 follows the meandering or undulating course of the corresponding heating conductor 6 at a defined distance.

The temperature detection conductor 7 , which forms the temperature detecting element, is part of a control circuit to the temperature of the heating element 1 to regulate, via the temperature sensing element, the actual value of the temperature of the heating conductor 6 heated surface is determined and from this under comparison with a target value, the heating power of the heating element 6 is set. Since the temperature detection conductor 7 extends over a large surface area, the temperature is averaged over the correspondingly large surface area. As a result, the temperature is above the temperature detection conductor 7 not locally derived from a single location, but captured over a large area. The temperature detection is based on that by increasing the temperature caused by the heating conductors 6 , the resistance of the temperature sense conductor 7 changes.

For the temperature detection element, a temperature detection conductor is preferred 7 used with a high temperature coefficient, preferably a nickel wire or a conductor of carbon (carbon) or of carbon-containing (carbon-containing) plastic whose Resistance change is used to determine the temperature of the heater and to control the surface temperature.

The thickness of a filament of the temperature sensing conductor 7 is 40 μm to 200 μm. A thickness or a diameter of 50 .mu.m to 150 .mu.m is provided as well as a diameter of 70 .mu.m and 110 .mu.m. The heating conductor becomes as well as the temperature detection conductor 7 by means of thread 8th corresponding 3 or in gluing technique according to the 4 on the carrier material 2 attached. The temperature detection conductor 7 should have a resistance of 7 ohms / m to 15 ohms / m. Preferably, the high resistance value should be selected, since at a higher voltage in the temperature detection conductor 7 flowing currents can be kept relatively small and thus the self-heating of the temperature sensing conductor 7 is reduced.

The distance between the temperature detection conductor is preferred 7 and heating conductor 6 chosen so that in the case of several heating conductors or Heizleiterkreisen the temperature detection conductor 7 runs centrally between two heating conductors, with no intersection between heating conductor 6 and temperature detection conductor 7 he follows. In the event that, for reasons of space, a crossing free laying is not feasible, shows 5 a possible embodiment of the heating element according to the invention 1 with only one heating circuit forming a single heating circuit 6 , In this embodiment, the temperature detection conductor runs 7 between the back and the return part approximately in the middle of the wavy or meandering structure of the heating element 6 so that the number of crossing points 10 is minimized.

Out 6 is another possible embodiment of the heating element according to the invention 1 can be seen, in which the distance between the temperature detection conductor 7 and heating conductor 6 is chosen so that the temperature detection conductor 7 between the substantially parallel spaced heating conductor 6 , which forms, for example, a heating circuit, a round trip, so that the heating conductor 6 and the temperature detection conductor 7 do not cross and thus no intersection 10 as in the embodiment of the 5 the case results.

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

• DE 10048181 A1 [0004]
• DE 2208485 A [0005]
• DE 10055141 A1 [0006]

Claims (10)

Heating element ( 1 ) for user-touchable surfaces, in particular an area in a vehicle interior, wherein the heating element ( 1 ) at least one carrier material ( 2 ), on which at least one heating conductor ( 6 ), which runs in particular wave-shaped or meander-shaped, and at least one temperature sensing element are arranged, characterized in that the at least one temperature sensing element as at least one separate from the heating conductor temperature sensing conductor ( 7 ) is executed, which changes its electrical resistance as a function of its temperature, wherein the temperature sensing conductor ( 7 ) spaced substantially parallel to the course of the heating conductor ( 6 ) follows at least in part. Heating element according to claim 1, characterized in that the length of the temperature sensing conductor ( 7 ) over at least 1/10 of the length of the heating conductor ( 6 ) is spaced substantially parallel to this. Heating element according to one of the preceding claims, characterized in that the temperature detection conductor ( 7 ) consists of metal or a metal alloy. Heating element according to one of the preceding claims, characterized in that the temperature detection conductor ( 7 ) has a higher temperature coefficient than the temperature coefficient of the heating conductor ( 6 ) having. Heating element according to one of the preceding claims, characterized in that the temperature detection conductor ( 7 ) consists of nickel or a pure nickel material. Heating element according to one of the preceding claims, characterized in that the temperature detection conductor ( 7 ) consists of carbon or carbon containing, electrically conductive plastic. Heating element according to one of the preceding claims, characterized in that the temperature detection conductor ( 7 ) monofilament is formed. Heating element according to one of the preceding claims, characterized in that the temperature detection conductor ( 7 ) is formed mehrlitzig. Heating element according to claim 8, characterized in that the temperature detection conductor ( 7 ) Is formed 2- to 6-litzig. Heating element according to one of claims 7 to 9, characterized in that the thickness of the strand (s) of the temperature sensing conductor ( 7 ) is in each case 40 μm to 200 μm, preferably 50 μm to 150 μm, particularly preferably between 70 μm and 110 μm.

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