DE19517310A1 - Component made of thermistor material - Google Patents

Description

The present invention relates to a module made of PTC thermistors material, in particular for a terminal contact, with at least two contact surfaces for an electrical connection.

The invention further relates to a temperature monitor with a in the event of overtemperature switching bimetal switchgear and one thus connected PTC resistor, which in the sense of a Self-holding function works.  

Such modules made of PTC thermistor material are general known, they will z. B. as heating resistors or as a rule resistors used. You use that with the temperature increasing resistance of a PTC thermistor for control purposes or to protect the device heated by the PTC resistor out. Since the PTC resistor is temperature-dependent as a result of this dependent resistance value, which with increasing temperature increases, its temperature output is adjustable, or regulates itself, can cause irreversible damage to the heating part due to excess temperatures can be avoided.

Such PTC thermistors or PTC semiconductors exist, for. B. from a sintered barium titanate ceramic after the sintering process is subjected to an after-treatment, because on the surface Form oxide layers that make direct contact oppose.

The ceramic is therefore first ground after the sintering process to remove the oxide layers. Then one metallic contact layer usually made of aluminum or silver applied, either by screen printing or Sputtering occurs. The conventional contact then takes place over these metallic contact layers. This contact usually consists of a clamping technique, whereby the with contact surfaces provided with a contact layer Counter contacts brought into contact and clamped to them will. It is also known to wire strands directly onto the contact solder layers or otherwise attach them.

An area of application for such components made of PTC thermistor material is the temperature monitor mentioned at the beginning, which comes from the EP-A-0 284 916 is known.  

The known temperature monitor includes one of a cover part made of PTC thermistor material, in which the Rear derailleur is arranged. The bimetal rear derailleur includes in known a bimetallic snap disc and a spring disc on which a movable contact part is held. Below the response temperature of the bimetallic snap disc the movable contact part is countered by the spring washer pressed a fixed contact part on the cover, which is in accordance with Art a rivet extends through the lid and into the outside of a head transforms. The housing part is made of electrically conductive material manufactured so that the rear derailleur at low temperatures a conductive connection between the housing part and the head of the fixed contact part. The lid is in conductive Connection both with the fixed contact part and with the Housing part so that it is electrically parallel to the rear derailleur is switched.

If the rear derailleur is now due to excessive temperature opens, the current flows from the fixed contact part through the PTC resistor to the housing formed by the cover part, which heats up the PTC resistor and that Rear derailleur keeps open, even if the one that triggers the switching Excess temperature is no longer present. That way it works the PTC resistor in the sense of a self-holding function.

Based on this, it is an object of the present invention the above-mentioned module made of PTC thermistor material to further develop that it is cheaper to manufacture. Especially the new block is to replace the previous block without changes on the device in which it is used. So should it z. B. be possible, the new block at the beginning to use mentioned temperature monitor without the construct tion of the temperature monitor must be changed.  

This task is invented in the above-mentioned module solved according to the invention in that at least one of the contact surfaces of the block is ground, and that the contacting without Interposition of contacting layers immediately the ground PTC thermistor material.

In the case of the temperature monitor mentioned at the beginning, the Accordingly, the object underlying the invention solved that the new module as a PTC resistor for the Temperature monitor is used.

The object on which the invention is based is achieved in this way completely solved. It was found that the applicant that surprisingly dispense with the contacting layers can be tet if the contact areas are only sufficient be sanded. At least from a certain company voltage that drops over the new component in use shows this is a characteristic curve, i.e. a voltage-dependent temperature Change that the characteristic of comparable blocks with Contacting layer corresponds. Slight shifts in The characteristic curve can be changed slightly together settlement of the PTC thermistor material can be compensated.

In summary, it is now possible to do so by using suitable Grinding the z. B. sintered building block this on the to bring the desired gauge block while maintaining the contact prepare surfaces for the required connection technology. The new component can thus be manufactured significantly cheaper than when it was the case with the known module. There such modules during production always with Made oversize and then ground to the actual final dimension can be opened only by using a finer one Abrasive in a single step the new building block made to measure and prepared for the connection technology.  

For the technical function of such a PTC resistor standes is its resistance value at the respective company temperatures and the change in resistance with increasing Crucial temperature. The temperature is raised by the current flowing through the resistor, the ohmic heat generated. However, it follows that with increasing operating voltage a greater heat is generated in the PTC resistor, so that it heats up. As a result of the heating up Resistance value of the building block according to its characteristic Characteristic curve, which counteracts the temperature increase becomes.

In a surprisingly simple way it is now possible to use such PTC resistors with the desired electrical properties and create mechanical dimensions without the usual contacting layers are required. In the literature, this contact is often mentioned layers not expressis verbis pointed out to the specialist however, before the filing date of the present invention itself understandable, PTC resistors always with contacting layers of aluminum or silver. Both mechanical final dimensions of such known building blocks had to hence the additional thickness of this contact layer are taken into account.

As these additional layers continue with the new building block fall, it can also be more accurate and true to size manufacture.

Overall, it is preferred if the one or more of the Contact surfaces are finely ground, preferably lapped.  

The advantage here is that a known grinding process, namely The lapping is used to fine the contact surfaces grind. In such lapping techniques, an abrasive made of SiC, for example, as was originally used for the manufacture of PTC thermistor components was used. At the known method, however, was only a rough grinding or finishing that is not used according to the invention required fineness of grinding the contact surface leads. Rather, it was only found in the applicant's company that that such finishes allow the cold conductor material can be contacted directly.

It can then either only one or more of the contact surfaces are so finely sanded for various uses to meet conditions. So it can e.g. B. be that the new thermistor module on one of its contact surfaces with a Terminal contacting is made during one or more contacted other of the contact areas via a solder connection that may still require contacting layers.

It is further preferred if the operating voltage is approx. 100 V and is preferably greater than 110 V.

It was found that at these operating voltages the characteristic curve of the new module with the Characteristic curve of an otherwise comparable building block together falls, but the additional contact layers having.

If such a block is preferred as a heating resistor in an aquarium heater or a bimetal temperature switch is used, so in addition to the smaller manufacturers other costs for the PTC resistor  Benefits. In the above-mentioned temperature monitor z. B. the PTC resistor also serves as a cover part and is flanged against a shoulder of the Lower part of the housing pressed. Because the PTC thermistor material does not high pressures are special requirements to set the thickness of the lid part. This cover part must namely with mechanical tolerances in the range of a tenth Millimeters and less can be made so that it can Flaring process is not destroyed. Precisely because of the so far required contacting layers, their final thickness often cannot be specified with the required accuracy can, it came with the well-known temperature monitor with the known PTC resistor again and again that at too thick lid part that was destroyed during the flanging, or with a cover part with undersize the contact pressure was too low, so that the required electrical contact not be made between the housing and the cover part could.

As already mentioned in detail above, the new one PTC resistor in a single working process to final dimensions are manufactured, subsequent coatings, the final dimension unpredictable changes are not required. Because with that new block also uses a finer grinding process, the overall result is a finer ground surface, the also ensures greater mechanical dimensional accuracy.

It is further preferred if the PTC resistor is electrically connected in parallel to the bimetal switchgear.

The advantage here is that the self-holding function is based on electrically particularly simple way results as this per se is already known from the prior art.  

It is then preferred if the PTC resistor is included its at least one ground contact surface with the Housing parts in plant, and if the housing part one Has flanged edge, which serves as a cover part PTC thermistor resistance clamped to the housing part.

It is advantageous here that the previously used method for Assembling the known temperature monitor can be maintained can, it is only a cover part of the new building block put. Since this now has greater mechanical dimensional accuracy flanging now leads to a safe mecha African seat and electrical contact, so that the reject rate is reduced in the manufacture of the new temperature monitor.

It is further preferred if a fixed contact part, the assigned to a movable contact part of the bimetal rear derailleur net is arranged on the cover part such that it with another ground contact surface is in contact, is preferably clamped to this.

This has the further advantage that the further connection technology with the new temperature monitor can be done as this is already known from the prior art, however the problems associated with dimensional accuracy according to the invention have been eliminated.

Finally, it should be noted that due to the direct Clamp contact on the ground PTC thermistor material Deviation in the voltage-dependent resistance characteristic at the new building block in so far as that with lower ones Operating voltages the measurable resistance value of the new Building block is significantly higher than that of the known building block with contacting layers. For the electrical operation of the  However, this is not a hindrance to new building blocks as long as the approximate linear characteristic curve of that of the known building block corresponds to the voltage ranges in which the new module to be used.

The temperature monitor mentioned above is used for. B. electrically connected in series with a consumer to be protected, the is operated with 220 V AC or DC voltage. As long as the temperature of the consumer is within the permissible range remains, is the PTC resistance due to the bimetal switching factory short-circuited, so that the resistance value of the PTC thermistor no resistance to the function of the temperature monitor Has influence.

Now the temperature of the consumer to be protected rises in an impermissible manner, the bimetal switchgear opens and a large part of the supply voltage falls above the cold ladder module. This designated with operating voltage Voltage that drops across the new PTC thermistor module is usually above 100 V, where the characteristic of the new Building block of the old building block is so close that the electrical function of the temperature monitor also replaced PTC resistor is retained.

Further advantages result from the description and the attached drawing.

It is understood that the above and the following standing features to be explained not only in each specified combination, but also in other combinations or can be used alone, without the scope of leaving the above invention.  

The invention is illustrated in the drawing and is in the following description explained in more detail. Show it:

Figure 1 shows a new temperature monitor with a new PTC resistor as a cover part. and

Fig. 2 is a diagram showing the voltage-dependent resistance curve of the new device compared to that of a known device with contacting layer.

A temperature monitor 10 is shown in FIG. 1 as an example of an application for the new module made of thermistor material. The temperature controller 10 comprises a cup-shaped housing part 11 and a housing part 11 closing off the cover portion 12, which rests on a circumferential shoulder 13 of the housing part. 11 The temperature monitor 10 is closed by a flange 14 which presses the cover part 12 onto the circumferential shoulder 13 .

In the interior of the housing part 11 there is a bimetallic switching mechanism 15 which is of conventional construction. It comprises a spring washer 16 which carries a movable contact part 17 , over which a bimetallic snap disk 18 is placed. The spring washer 16 is supported on a bottom 19 of the cup-shaped housing part 11 and thus prestresses the movable contact part 17 against a fixed contact part 20 , which extends like a rivet through the cover part 12 to the outside, where a head 21 is visible.

In the state shown in FIG. 1, the switching mechanism 15 has a temperature below its response temperature, so that it is in the closed state. If the temperature of the switching mechanism 15 is increased, the bimetallic snap disk 18 snaps suddenly from the convex shape shown into a concave shape and is supported on the underside of the cover part 12 in such a way that it moves the movable contact part 17 against the force of the Spring washer 16 lifts off the fixed contact part 20 , as is generally known.

Essential for the new temperature monitor 10 is the design of the cover part 12 , which is a module 22 made of PTC thermistor material and here acts as a heating resistor 23 , i.e. as a PTC resistor 24 , which is electrically connected in parallel to the bimetallic switching mechanism 15 and by this is short-circuited in the switching state shown in FIG. 1.

Blackening indicates contact surfaces 25 , 26 of the block 22 in FIG. 1, which are ground particularly finely because they were subjected to a lapping process with very fine abrasive. Although it is possible to process all the surfaces of the component 22 in such a fine manner, it is sufficient for technical use if the contact surfaces 25 , 26 have been subjected to such processing. Due to the fine machining of the surfaces of the component 22 , this has very defined mechanical dimensions, so that it is ensured that a corresponding clamping contact is produced on the contact surfaces 25 , 26 in a reproducible manner by the flanged edge 14 and the rivet 21 .

While the contact surface 25 rests on the shoulder 13 and ensures good electrical contact between the PTC resistor 24 and the housing part 11 made of electrically conductive material, the contact surface 26 is located in the region of the fixed contact part 20 and provides a corresponding electrical connection conductive connection between the PTC resistor 24 and the contact part 20 . Since the mechanical dimensions of the cover part 12 can be adjusted very precisely because of the finely ground surface, the mentioned clamping ensures a firm and thus electrically secure fit of the cover part 12 in the flanged edge 14 or the rivet 21 in the cover part 12 , a Mechanical damage to the cover part 12 is avoided.

Due to the described arrangement, the PTC resistor 24 is connected in parallel with the network 15 and with a closed switching unit 15 is bridged by this, so that its resistance is in this switching state for the function of the temperature monitor 10 without significance value. As soon as the switching mechanism 15 opens, however, the PTC resistor 24 lies in the current path between the fixed contact part 20 and the housing part 11 . An operating voltage now drops across the PTC resistor 24 , which is generally greater than 120 to 130 V. In this voltage range, the component 22 shows a behavior comparable to that of the cover part known from EP-A-0 284 916 mentioned at the beginning, with corresponding contact layers.

Because of its temperature-dependent change in resistance, the PTC resistor 24 now ensures that a corresponding internal temperature is generated by the current now taken over by it, which is sufficiently high to keep the switching mechanism 15 open, but is limited to such an extent that irreversible damage to the switching mechanism is caused 15 can be avoided.

In Fig. 2 is a graph 31 is shown representing a typical PTC resistance with contacting layers, a characteristic curve 32, which represents the resistance change of this block as a function of the operating U represents. A further curve 33 can be seen in the diagram 31 , which shows the corresponding characteristic curve for the new module 22 . Both the operating voltage U and the resistance value R are shown in FIG. 2 in arbitrary units. It can be seen that the characteristic curves 32 and 33 run parallel to one another above an operating voltage 34 , it being possible to ensure that the two characteristic curves 32 , 33 coincide by appropriate selection of the composition of the PTC thermistor material.

This behavior is completely surprising, since experts have always assumed that a contacting intermediate layer is required to contact such a module 22 made of thermistor material. The characteristic curves 32 , 33 were recorded in the applicant's operation for a PTC resistor with a reference temperature of 140 ° -150 ° C., the black and light squares representing respective measuring points for the characteristic curves 32 , 33 . In one measurement, the units on the voltage axis corresponded to one volt division and those on the resistance axis corresponded to one division in kΩ.

Since the application of the metallic contact layers the most expensive to manufacture PTC resistors Step, comes the new module made of thermistor material, who no longer needs such contacting layers, one significant economic importance.

By a suitable choice of the production parameters, an approximately linear R (U) characteristic can be achieved even at voltages lower than the 120-130 V mentioned, so that the new components made of PTC thermistor material can be used not only as a heating resistor 23 for temperature monitors, but also also for many other devices that use PTC elements (PTC resistors). So it is z. B. possible to use the new building blocks for aquarium heating, where panes of thermistor material are clamped between metallic contact plates, via which the panes are not only held mechanically but also electrically contacted. With regard to the mechanical breakage problems and the clamping contacts, the same problems occur as in the temperature monitor 10 discussed here by way of example, so that the use of the new module made of thermistor material also brings the corresponding advantages.

Claims (11)

1. Module made of PTC thermistor material, in particular for a terminal contact, with at least two contact surfaces ( 25 , 26 ) for an electrical connection, characterized in that at least one of the contact surfaces ( 25 , 26 ) of the building stone ( 22 ) is ground, and that Contact is made without the interposition of contact layers directly on the ground PTC thermistor material. 2. Module according to claim 1, characterized in that one or more of the contact surfaces ( 25 , 26 ) are finely ground, preferably lapped. 3. Module according to claim 1 or 2, characterized in that an operating voltage ( 34 ) of approximately 100 V, preferably greater than 110 V drops over it in use. 4. Module according to claim 3, characterized in that the operating voltage ( 34 ) is greater than 120 V, preferably greater than 130 V. 5. Use of the module ( 22 ) according to one of claims 1 to 4 as a heating resistor ( 23 ), preferably in an aquarium heater or in a bimetallic temperature switch ( 10 ). 6. Temperature monitor with a bimetal switching mechanism ( 15 ) that switches at excess temperature and a PTC resistor ( 24 ) connected to it, which acts in the sense of a self-holding function, characterized in that the PTC resistor ( 24 ) of the module ( 22 ) according to one of Claims 1 to 4. 7. Temperature monitor according to claim 6, characterized in that it has a switchgear ( 15 ) receiving housing part ( 11 ) and a housing part ( 11 ) closing cover part ( 12 ), which is formed by the PTC resistor ( 24 ). 8th . Temperature monitor according to claim 6 or 7, characterized in that the PTC resistor ( 24 ) is electrically connected in parallel to the bimetallic switching mechanism ( 15 ). 9. Temperature monitor according to claim 7, characterized in that the PTC resistor ( 24 ) with its at least one ground contact surface ( 25 ) with the housing part ( 11 ) is in contact. 10. Temperature monitor according to claim 9, characterized in that the housing part ( 11 ) has a flanged edge ( 14 ) which clamps the PTC resistor ( 24 ) serving as a cover part ( 12 ) on the housing part ( 11 ). 11. Temperature monitor according to one of claims 6 to 10, characterized in that a fixed contact part ( 20 ) which is assigned to a movable contact part ( 17 ) of the bimetallic switching mechanism ( 15 ) on the cover part ( 12 ) is arranged in such a way that it is in contact with another ground contact surface ( 26 ), preferably clamped to it.