DE3232404A1 - Ceramic PTC thermistor having metal plates and power supply leads connected thereto by means of a clamping contact - Google Patents

Abstract

The ceramic PTC thermistor (PTC thermistor 1) is provided on opposite surfaces with metal plates (2, 3) as electrodes, to which power supply leads are connected which in each case consist of electrically conductive spring elements (4, 5) and rest against the metal plates (2, 3) of the PTC thermistor (1) such that they exert pressure (clamping contact), the contact points (6, 7) of the spring elements (4, 5) with the metal plates (2, 3) in each case additionally being enveloped with a layer (8, 9) of conductive adhesive, for the clamping contact. <IMAGE>

Description

Ceramic PTC thermistor with metal coverings and through it

Terminal contact connected power supplies.

The invention relates to a ceramic PTC resistor in disc, tube or rod form, the one on opposite surfaces with metal coverings is provided as electrodes to which power leads are connected, each consist of electrically conductive spring elements and exert pressure on the metal coverings of the PTC thermistor and thus form a clamping contact.

The designation ceramic PTC thermistor or also "PTC resistance" is used here for a temperature-dependent resistor (thermistor), which is a semiconducting T is the state that with the change in his body temperature, there is a substantial change learns of its electrical resistance. Such temperature-dependent resistances are in the German standard DIN 44080 of December 1976 PTC thermistors with regard to Defined terms and properties. As a rule, there is such a ceramic PTC thermistor made from a ceramic-made polycrystalline body on the base of material with perovskite structure doped by non-lattice substances, mainly Barium titanate, which has semiconducting properties. Such ceramic PTC thermistors are sufficiently described in the patent literature and in the specialist literature.

A ceramic PTC thermistor with the features mentioned above is for example in the following printing writings described: DE-PS 21 07 365, DE-AS 27 05 438, US-PS 3 705 082, EP-A1 0 028 423. Also in the German Patent application P, ...... (VPA 81 E 1077 + 82 E 7025b), which has the same priority as of the present patent application is in the context of a level sensor for liquids a ceramic PTC thermistor is described which has the features specified in the introduction having.

Since the ceramic known from the cited publications PTC thermistors are relatively large bodies (diameter at least 10 mm, thickness at least 2 mm) and two PTC thermistors arranged between the terminal contacts are, there are used as spring elements that are relatively strong and stable are executed. In addition, the well-known ceramic PTC thermistors in one Housing are housed, through which it is ensured that an immediate Touching the PTC thermistor body, which could loosen the clamping contact, does not occur.

The situation is different if the ceramic PTC thermistor is used directly must come into contact with a medium, as is particularly the case with level measurement the case is. But also in other contexts, for example when with a such ceramic PTC thermistors the temperature of another body can be monitored should, there is direct contact with the PTC thermistor body.

In DE-PS 24 29 438 there is an arrangement for monitoring the level conductive and / or corrosive and / or explosive liquids with a shrink tube encased PTC thermistor, in which the ends of the shrink tubing have a moisture-proof seal made of a potting resin. Will be at this known arrangement a relatively large PTC thermistor body used, so plays the Thermal conductivity of the material from which the shrink tube is made, not an essential role, and short response times are not important.

In DE-OS 20 49 834 a liquid level sensor is described (referred to there as universal limit value transmitter), which is also covered with a shrink tubing PTC thermistor is used.

In these known shrink-tubed ceramic PTC thermistors are the power supplies in the form of wires directly with the metal coverings of the ceramic PTC thermistor body firmly connected, for example by soldering.

DE-PS 1 665 582 describes a ceramic PTC thermistor for liquid level sensors described, which has the lowest possible response delay, mechanically is insensitive and chemically resistant to alkaline liquids by the ceramic PTC thermistor, its electrodes and power supply lines initially with a thin, insulating, good heat-resistant, for example produced by dip painting and flexible plastic layer are coated on which a tightly adhering dense Metal coating is applied by electroless metal deposition.

But when it comes down to it, especially small ceramic PTC thermistor bodies use (maximum diameter 5 mm, maximum thickness 1.5 mm), the advantage of which is is that due to their low heat capacity there are very short response times, so there is the difficulty that these very small bodies are poorly soldered because the heat stress during the soldering process is considerable.

The mere use of spring elements made of electrically conductive Metal with good spring properties brings significant improvements here, however such spring elements have a very small cross-section and are therefore half due to the heating during the switching cycles of the ceramic PTC thermistor in increased Dimensions subject to aging. This is shown by the fact that if more than 5000 to 6000 switching cycles a paralysis occurs, through which a perfect contact between the spring elements and the metal coatings on the PTC thermistor body are no longer guaranteed is.

The present invention has for its object to be a ceramic To improve PTC thermistors of the type specified in such a way that with small dimensions of the PTC thermistor body, even with very high switching cycles (10,000 to 12,000) before proper mechanical and electrical contact is guaranteed.

The ceramic PTC thermistor is the solution to this problem specified type according to the invention characterized in that the contact points of the spring elements with the metal coverings in addition to the clamping contact with one each Are encased by conductive adhesive.

It is advantageous if the conductive adhesive has thermoplastic properties possesses and has a softening temperature which is in the range of the temperature of the steep rise in the resistance value of the ceramic PTC thermistor.

This ensures that the conductive adhesive is applied with every switching process softens and the spring pressure of the spring elements can be effective without these spring elements can stand out from the metal coverings of the ceramic PTC thermistor.

The PTC thermistor can be used together with the power supply Spring elements and the pads enveloping the contact points with a through Sheath produced by dip coating, as it is for example in in DE-PS 1 665 582 already mentioned above is. A Metal plating applied by metal deposition may or may not be present usually not required.

It is particularly advantageous to use a PTC thermistor according to the present invention in a liquid level sensor in which the PTC thermistor housed together with power supplies in the cavity of a sleeve provided with openings is.

Such a liquid level sensor has a number of characteristics described in DE-OS 20 49 438 and in relation to a special embodiment Subject of the patent application with the same priority as the present application P ....... (VPA 81 E 1077 + VPA 82 E 7025b).

In DE-PS 975 725 it is described that electrical capacitors, the one flat electrical one with an assignment on one side Body included, thereby connected with their occupancy with a metallic device part can be that the unoccupied area of the dielectric body by means of a they are attached to the metallic part of the device with conductive adhesive covering them.

Conductive adhesive layers, for example in the form of lacquers or Kittens are known per se and have the property that they are cold can harden by themselves in air even without increasing the temperature. You insist made of a plastic material with adhesive properties that has a dieXconductivity resulting component is filled, for example with metal powder particles, graphite particles, Particles made of good semiconducting material. The plastic component can be thermoset be, that is, it does not soften when heated; the plastic component but can also have thermoplastic properties, so that with a agreed Material-dependent temperature softening occurs without softening goes so far that the material flows off.

DE-PS 1 007 860 describes that power supply wires body preformed in tensile strength in blind holes, for example made of resistance material, Can be attached by before or after inserting the power lead wires in the blind holes the free space of the holes with adhesives and / or conductive material Masses being filled out.

A similar process is described in DE-PS 1,054,541. at all of these uses conductive adhesive for attaching power supply wires on electrical components, the power supply lines are not resilient, so that the the advantage of the spring action achieved by the present invention as power supply lines serving spring elements, namely suitability for the highest possible number of switching operations, is not given.

The invention is described below with reference to the accompanying drawings explained in more detail.

The figures show: FIG. 1 a preferred embodiment of the invention in FIG Side view, Figure 2 shows another embodiment of the invention and Figure 3 shows the Use of a ceramic PTC thermistor according to the invention in a level sensor for liquids.

In the figures, the same parts are provided with the same reference numerals.

The ceramic PTC thermistor 1 has metal coatings on its large surfaces 2 and 3, which serve as electrodes. The spring elements serving as power supply lines 4 and 5 are formed at their ends to round contact parts 12 and 13, which the metal coverings Touch 2 and 3 at points 6 and 7. These points of contact 6 and 7 between the round contact parts 12 and 13 of the spring elements 4 and 5 with the metal coverings 2 and 3 are each covered with a layer 8 and 9 made of conductive adhesive.

The straight parts of the spring elements 4 and 5 are in a base 10 made of insulating material firmly anchored so that the spring effect can come into its own.

In Figure 1 it is also shown that the entire arrangement made of ceramic PTC thermistors 1, contact parts 12, 13, spring elements 4, 5 and in part also the base 10 with a sheath 11 produced by dip painting (here by a dash-dot line indicated) are enveloped.

The embodiment according to FIG. 2 differs from the embodiment according to Figure 1 in that the spring elements 4 and 5 initially on the PTC thermistor 1 to a certain extent passed and then inwards, to the PTC resistor 1 towards resilient extensions 14 and 15 are bent back to form, between which the PTC thermistor 1 is clamped. Here, too, the contact points 6 and 7 are each with a support 8 and 9 made of conductive adhesive enveloped.

While in the embodiment of Figure 1, the application of the conductive adhesive is easier on the points of contact, ensures the embodiment according to Figure 2 a sufficiently strong clamping contact, even if the spring properties the spring elements 4 and 5 are not particularly good.

In FIG. 3, the embodiment according to FIG. 1 is shown as in one Sleeve 16 of insulating material shown housed.

The insulating sleeve 16 forms a cavity 17 for this purpose and is provided with longitudinal slots 18 provided through which the liquid will pass and in direct contact can come with the PTC thermistor.

The free ends of the contact elements 4 and 5, which come from the base 10 protrude are fixed with external power leads 19 and 20, for example through Welding, connected. These external power supply lines 19 and 20 are located in a housing 21 made of metal, which has a bore 22 with insulating Plastic (cast resin) is filled.

4 Patent Claims 3 Figures 1 List of Reference Numbers 1 Summary Reference list 1 PTC resistor (PTC resistor) 2 Metal coating on the PTC thermistor 3 Metal coating on the PTC thermistor 4 spring element for the clamping contact 5 spring element for the clamping contact 5 contact point of the spring element 7 contact point of the spring element 8 support made of conductive adhesive 9 overlay made of conductive adhesive 10 base 11 dip coating 12 round Contact part 13 round contact part 14 resilient extension 15 resilient extension 16 Sleeve 17 cavity 18 longitudinal slot 19 outer power supply line 20 outer power supply line 21 metal housing 22 hole

Claims (4)

Claims ceramic PTC resistor (1) in Schei- < n, tube or rod shape, which is covered on opposite surfaces with metal coverings (2, 3) is provided as electrodes to which power supplies are connected, the each consist of electrically conductive spring elements (4, 5) and exert pressure the metal coverings (2, 3) of the PTC thermistor (1) rest (clamping contact), d a d u r c h g a k e n n n z e i c h n e t that the contact points (6, 7) of the spring elements (4, 5) with the metal coverings (2, 3) in addition to the clamping contact with one support each (8, 9) are encased in conductive adhesive. 2. Ceramic PTC thermistor according to claim 1, d a d u r c h g e k e n notify that the conductive adhesive has thermoplastic properties and has a softening temperature which is in the range of the temperature of the steep rise of the resistance value of the ceramic PTC thermistor. 3. Ceramic PTC thermistor according to claim 1 or 2, d a -d u r c h g e k e n n n n e i n e t that the PTC thermistor (1) together with that of the power supply serving spring elements (4, 5) and the pads surrounding the contact points (8, 9) are provided with a coating (11) produced by dip painting. 4. Use of a ceramic PTC thermistor according to one of the claims 1 to 3 in a liquid level sensor, in which the PTC thermistor (1) including power supplies is accommodated in the cavity (17) of a sleeve (16) provided with openings (18).