DE102015203114A1 - PTC thermistor - Google Patents

Abstract

The present invention relates to a PTC thermistor (1) having at least one PTC thermistor element (2) with a ceramic plate (3) with two opposing main surfaces (4, 5). It is essential to the invention that at least one heat radiating element (6), which is soldered directly to the main surface (4, 5) of the PTC thermistor element (2), is arranged on at least one main surface (4, 5). This makes it easier to produce with less weight and improved heating capacity can be achieved.

Description

The present invention relates to a PTC thermistor having a PTC thermistor element with a ceramic plate and two opposite major surfaces according to the preamble of claim 1. The invention also relates to a heating device of an air conditioning system of a motor vehicle with such a PTC thermistor.

From the DE 68 917 259 T2 a generic PTC thermistor is known with a PTC thermistor element which is essentially made of a ceramic plate and having a pair of opposite electrodes on the two major surfaces of the PTC thermistor element. In addition, heat radiating fins are provided, which are made of metal sheets and connected by a plurality of vertices with the associated, opposite electrodes by soldering. This is intended to achieve improved heating performance due to the improved heat transfer between the PTC thermistor element and the heat radiating elements.

As already known from the previous paragraph, heat radiating elements are connected, for example, to heat transfer with electrodes of a PTC thermistor element located on the outside of main surfaces, for example soldered. Alternatively, bonding of the heat radiating elements with the electrodes arranged on the main surfaces of the PTC thermistor element can also take place.

A disadvantage of the PTC thermistors known from the prior art, however, is their comparatively complex production, since, for example, first the electrodes are applied to the opposing main surfaces of the PTC thermistor element and then glued or soldered onto the heat radiation element. However, the electrodes resting on the main surfaces not only produce an increased installation effort, but also an increased weight and increased costs.

The present invention therefore deals with the problem of providing for a PTC thermistor of the generic type an improved or at least one alternative embodiment which overcomes in particular the disadvantages known from the prior art.

This problem is solved according to the invention by the subject matter of independent claim 1. Advantageous embodiments are the subject of the dependent claims.

The present invention is based on the general idea of soldering corresponding heat radiating elements directly onto a main surface of a PTC thermistor element and omitting the electrodes previously provided on the main surface. The PTC thermistor according to the invention in this case has a PTC thermistor element with a ceramic plate with the two opposite major surfaces described above. According to the invention, at least one heat-radiating element is now arranged on at least one of these main surfaces and at the same time is soldered directly onto the main surface of the PTC thermistor element. In this way, a PTC thermistor can be created with a significantly reduced installation effort, which is thereby not only less expensive to produce, but also has a lower weight in comparison to known from the prior art PTC thermistors. Due to the direct soldering of the heat radiating elements on the main surface and an optimal heat transfer of the PTC thermistor element can be carried out on the heat radiating elements, without first still an interposed electrode would have to be heated.

The soldering of the heat radiating elements with the associated main surfaces of the PTC thermistor element takes place exclusively by soft soldering at a temperature which is in any case below a harmful for the PTC thermistor elements temperature. Such a harmless for the PTC thermistor temperature is, for example, at 260 ° C, so that for the solder material, a tin alloy can be used, for example, already melts from about 200 ° C and thus allows a solder joint whose soldering temperature no negative impact on the PTC thermistor element has. Of course, the operating temperature, in particular the maximum temperature of the PTC thermistor elements during operation, below the melting temperature of the solder material used, so that the solder joint during operation of the PTC thermistor can be solved under any circumstances.

Suitably, the PTC thermistor element and / or the at least one heat-radiating element is / are solder-plated. Such a solder plating not only facilitates the production of the solder joint, for example in a soldering oven, but also allows for a solder-plated PTC thermistor element to provide a surface optimized for heat conduction on the two opposing major surfaces.

In a further advantageous embodiment of the solution according to the invention, the PTC thermistor element is exclusively in a central region of its main surfaces, in which it is in direct contact with the heat radiating elements, solder-plated. In this way, in particular, an undesirable current flow or current passage at the longitudinal ends of the PTC thermistor elements can be prevented, wherein the PTC thermistor elements are usually electrically contacting at their longitudinal ends connected to a power source or a control device.

In a further advantageous embodiment of the solution according to the invention, the at least one heat-radiating element is designed as a corrugated fin and moreover has gills. Such gills allow the passage of air, the formation of turbulence, which improve the heat transfer and thus the heating of the medium to be heated. Such gills can be produced efficiently, for example, in simple punching processes, wherein the heat radiating element may have, for example, a wave-shaped, in particular meander-shaped or even zig-zag-shaped contour and is soldered at each adjacent vertex to a major surface of an associated PTC thermistor element.

In a further advantageous embodiment of the solution according to the invention, the PTC thermistor element at opposite longitudinal ends of a contact device for electrically contacting each of an electrode and / or for holding in a heat exchanger. The contact device thus fulfills two functions simultaneously, namely once the electrical contacting of the PTC thermistor element, for example, with a power source and on the other hand fixing it in a corresponding frame, which is for example part of a heat exchanger. In addition, these contact devices can be designed such that they can be connected to one another, in particular can be inserted into one another, whereby series-connected PTC thermistor elements can be produced. For example, it is conceivable that in each case a contact device of a PTC thermistor element as a male part and the second contact device are formed as a female part.

Suitably, the contact device is connected via a clamping connection or a clip connection with the PTC thermistor element. Such a clamp or clip connection facilitates the mounting of the contact device on the PTC thermistor element and, moreover, through the use of a wide variety of contact devices, enables a respective adaptation to different frames or heat exchangers.

The present invention is further based on the general idea of equipping an automotive air conditioning system with such a PTC thermistor and thereby reducing the disadvantages known from the prior art, such as high assembly costs and high weight.

Other important features and advantages of the invention will become apparent from the dependent claims, from the drawings and from the associated figure description with reference to the drawings.

It is understood that the features mentioned above and those yet to be explained below can be used not only in the particular combination given, but also in other combinations or in isolation, without departing from the scope of the present invention.

Preferred embodiments of the invention are illustrated in the drawings and will be described in more detail in the following description, wherein like reference numerals refer to the same or similar or functionally identical components.

Show, in each case schematically,

1 a PTC thermistor according to the invention,

2 two series-connected PTC thermistors according to the invention,

3 to 6 different possible interconnections, individual PTC thermistors in a heat exchanger,

7 a first embodiment of a contact device,

8th different views of a second embodiment of a contact device,

9 according to the 8th shown contact device connected to the PTC thermistor state,

10 a representation like in 9 , but with 7 shown contact device.

According to the 1 to 6 has a PTC thermistor according to the invention 1 at least one PTC thermistor element 2 with a ceramic plate 3 and two opposite major surfaces 4 and 5 on (PTC - Positive Temperature Coefficient). According to the invention is now on at least one main surface 4 . 5 at least one heat radiating element 6 arranged, which directly on the main surface 4 . 5 of the PTC thermistor element 2 is soldered. By the direct soldering of the heat radiating elements 6 with the main surface 4 . 5 in particular one so far on the respective main surface 4 . 5 arranged electrode omitted, which not only brings additional weight, but also a higher installation cost and thus higher costs. An electrical contact of the PTC thermistor element 2 takes place via electrodes 7 either inside the PTC thermistor element 2 run or on a narrow flank, that is connected to a narrow longitudinal side of the same.

For simplified production of the PTC thermistor according to the invention 1 are / is the PTC thermistor element 2 and / or the at least one heat-radiating element 6 Lotplattiert, whereby the entire main surfaces 4 . 5 of the PTC thermistor element 2 may be solder plated, or just an area 8th , in particular a middle range 8th in which a direct contact with the heat radiating elements 6 , in particular their vertices, is given.

The at least one heat radiating element 6 like in the 1 to 6 is shown, for example, be designed as a corrugated fin and gills in addition 9 (see. 2 ) for improved heat transfer, in particular by generating turbulence, have.

To both an electrical contact of the PTC thermistor 1 with a power source 17 or a control device 18 , as well as a fixation of the respective PTC thermistors 1 in an appropriate context 10 (see. 3 , a heat exchanger 11 to ensure at least one longitudinal end (see 4 and 5 ) or at both, opposite longitudinal ends (see. 6 . 9 and 10 ) a contact device 12 (See in particular the 7 to 10 ) be provided. Such contact devices 12 are also in the 1 and 2 are shown and preferably designed such that they each have a male part and a female part and are thereby connectable to each other, whereby a series of individual PTC thermistor elements 2 becomes possible.

Looking at the contact device 12 according to the 7 to 10 closer, so you can see that these are usually an electrically conductive part 13 and an isolated part 14 have, wherein the electrically conductive part 13 an electrical contact area 15 via which it is electrically conductive with the PTC thermistor element 2 or an electrode 7 the same is connected. The electrically conductive contact area 15 can be either designed as a contact point, as in the 7 and 10 is shown, or as a parked nose 16 like this according to the 8th and 9 is shown. A connection between the PTC thermistor element 2 and the contact device 12 takes place for example by a simple sliding, that is a clamp or clip connection.

Like that 3 to 6 can be seen, a variety of interconnections are conceivable in which individual PTC thermistors 1 via a respective contact device 12 with a plus or a minus pole of a power source 17 are connected and via their heat radiating elements 6 in electrically conductive contact with an adjacent PTC thermistor element 2 stand, which then an electrical line to the other pole of the power source 17 represents. Of course, the arrangement of two opposing contact devices 12 conceivable (cf. 6 ), so that each PTC thermistor element 2 directly connected to a plus and a negative pole.

In general, with the PTC thermistor according to the invention 1 a significant cost-effective and also weight-optimized production can be achieved, since so far on the main surfaces 4 . 5 planar electrodes now omitted. In addition, an improved heating power can be achieved because the PTC thermistor element 2 the heat generated directly to the heat radiating elements 6 and not one between the PTC thermistor element 2 and the heat radiating element 6 must heat up arranged electrode.

The maximum operating temperature of such a PTC thermistor 1 is about 170 ° C, that is well below the soldering temperature for soldering the heat radiating elements 6 , the main surface 4 . 5 of the PTC thermistor element 2 required soldering temperature of about 200 to 230 ° C. Since the PTC thermistor elements 2 Withstand temperatures of up to 260 ° C without complaint, the soldering can be done without any impact on the life of the PTC thermistor elements 2 respectively.

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 68917259 T2 [0002]

Claims (10)

PTC thermistor ( 1 ) with at least one PTC thermistor element ( 2 ) with a ceramic plate ( 3 ) with two opposing major surfaces ( 4 . 5 ), characterized in that on at least one main surface ( 4 . 5 ) at least one heat radiating element ( 6 ) arranged directly on the main surface ( 4 . 5 ) of the PTC thermistor element ( 2 ) is soldered. PTC thermistor according to claim 1, characterized in that the PTC thermistor element ( 2 ) and / or the at least one heat-radiating element ( 6 ) are at least partially solder plated / is. PTC thermistor according to claim 1 or 2, characterized in that the PTC thermistor element ( 2 ) only in a medium range ( 8th ) of its main surfaces ( 4 . 5 ), where it is in contact with the heat radiating elements ( 6 ), is solder plated. PTC thermistor according to one of claims 1 to 3, characterized in that at least one heat radiating element ( 6 ) is designed as a corrugated fin. PTC thermistor according to claim 4, characterized in that the corrugated rib gills ( 9 ) having. PTC thermistor according to one of claims 1 to 5, characterized in that - the PTC thermistor element ( 2 ) internal or on a narrow front side connected electrodes ( 7 ), or - that the PTC thermistor element ( 2 ) electrodes connected to a narrow flank ( 7 ) having. PTC thermistor according to one of claims 1 to 5, characterized in that the PTC thermistor element ( 2 ) at at least one longitudinal end a contact device ( 12 ) for electrically contacting each with an electrode ( 7 ) and a power source ( 17 ) or a control device ( 18 ) and / or for holding in a heat exchanger ( 11 ) having. PTC thermistor according to claim 7, characterized in that the contact devices ( 12 ) are formed such that these connectable to each other and thus connected in series PTC thermistor elements ( 2 ) can be produced. PTC thermistor according to claim 7 or 8, characterized in that the contact device ( 12 ) via a clamping connection or a clip connection with the PTC thermistor element ( 2 ) connected is. Heating device or heat exchanger ( 11 ) an air conditioning system of a motor vehicle with a PTC thermistor ( 1 ) according to one of claims 1 to 9.

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