EP0780849A2 - Process of manufacturing a PTC resistor material - Google Patents

Abstract

This novel procedure makes a resistance material with positive temperature coefficient (PTC). A powder filler is admixed into a polymeric melt of matrix material. The powder filler contains one or more of a boride, carbide, nitride, oxide or silicide. The material is solidified and the matrix cross linked, using electron irradiation. In this new procedure, the radiation dose is 10kGy-75kGy preferably 25kGy-50kGy. The material thickness is 3 mm at most, preferably 1.3-2.5 mm. The material includes a polyethylene or ethylene copolymer, and may be a high density polyethylene. The filler is preferably titanium boride. Filler particle size is 50 mm at most. The filler is etched before mixing in. The mixture is extruded, sprayed or pressed from the melt, into plates.

Description

The invention relates to a method for producing a material for PTC resistors according to the preamble of claim 1. Such a method is known from US-A-5 313 184.

It has long been known that the mechanical and electrical stability of PTC resistors made from a semicrystalline thermoplastic polymer such as polyethylene, polypropylene and the like. a. as a matrix material, to which a powdery filler made of electrically conductive material, in particular carbon black, is admixed, by ionizing radiation, in particular by electron radiation.

In US-A-3 351 882 and US-A-4 534 889, in which not only carbon black but also graphite, metal powder, metal salts and oxides as well as boron and phosphorus-doped silicon and germanium are mentioned as possible fillers, radiation doses of 500 kGy to 1 MGy recommended.

In US-A-3 858 144 and US-A-3 861 029 a range of 20 kGy to 1.5 MGy for possible radiation doses is given for materials with carbon black as filler, but a dose of 1.2 MGy is recommended .

In known concrete examples (see, for example, WO-A-90/00825, EP-B-198 598), the radiation doses for materials with fillers based on carbon are consistently at least 100 kGy, in most cases they are considerably higher. According to EP-A-0 311 142 tests with a material on the Made of polyethylene with carbon black as filler, which showed that radiation doses of 800 kGy and 1.6 MGy resulted in higher stability of the response of the PTC resistor than a dose of 200 kGy.

Materials that do not contain carbon, but metal-based fillers have long been mentioned in the literature and their use is e.g. B. specifically described in the aforementioned US-A-5 313 184. Because of the high conductivity of the filling material, such materials have very good cold-conducting properties, but the stability of the characteristic curve, i. H. the stability of the resistance-temperature characteristic, known materials of this type are generally rather precarious. Attempts with crosslinking by electron radiation do not appear to have been carried out on a large scale so far.

As such, it would have been expected that due to the higher density of such fillers, the scattering of the electrons would be greater and their penetration depth would be less than, for example, with soot-filled materials and that this would result in higher radiation doses. However, the latter is obviously not the case.

On the contrary, it has been found that with an irradiation dose in a range from approximately 10 kGy to 60 kGy the tensile strength reaches favorable values and the stability of the characteristic curve is also very high. The former then drops somewhat up to an irradiation dose of 100 kGy, but then increases again, especially at higher sample temperatures, but the stability of the characteristic curve reaches its maximum at doses from 25 kGy to 50 kGy and decreases at even higher doses.

On the basis of this knowledge, the method characterized in the claims for the production of materials for generic PTC resistors was developed.

The method according to the invention permits the production of PTC resistors which not only have very good cold-conducting properties due to the high conductivity of the filler, but also good tensile strength and very high stability of the characteristic curve. In addition, the relatively low radiation doses have the advantage of short throughput times and generally lower manufacturing costs compared to the usual higher doses.

Fig. 1

die Zugfestigkeit eines nach dem erfindungsgemässen Verfahren hergestellten Materials bei 25°C und 100°C als Funktion der Bestrahlungsdosis,

Fig. 2a

den spezifischen Widerstand eines nach dem erfindungsgemässen Verfahren hergestellten, mit 25 kGy bestrahlten Materials als Funktion der Temperatur bei mehreren aufeinanderfolgenden Schaltungen,

Fig. 2b

eine Darstellung entsprechend Fig. 2a, wobei die Bestrahlungsdosis 50 kGy beträgt und

Fig. 3

eine Darstellung entsprechend Fig. 2a, wobei die Bestrahlungsdosis ausserhalb des erfindungsgemässen Bereichs bei 100 kGy liegt.

The invention is illustrated in detail below using an exemplary embodiment and explained using figures. Show it

Fig. 1

the tensile strength of a material produced by the process according to the invention at 25 ° C. and 100 ° C. as a function of the radiation dose,

Fig. 2a

the specific resistance of a material produced by the method according to the invention and irradiated with 25 kGy as a function of the temperature in several successive circuits,

Fig. 2b

a representation corresponding to Fig. 2a, wherein the radiation dose is 50 kGy and

Fig. 3

a representation corresponding to FIG. 2a, the radiation dose outside the range according to the invention being 100 kGy.

The HD polyethylene Lupolen 5231X from BASF was melted and TiB ₂ powder with a particle size <45mm, which had previously been etched to clean the particle surfaces of oxides, was added as a filler. The proportion of filler in the mixture was 50% by volume. After mixing, the material was extruded through a slit and sheets 160 mm long, 40 mm wide and 1.3 mm - 2.5 mm thick were produced and irradiated in the direction of minimum expansion with electrons with an energy of 2 MeV.

Several samples were produced and exposed to different radiation doses, namely 25 kGy, 50 kGy and 100 kGy, in order to achieve different degrees of cross-linking of the matrix material. Another sample was irradiated with 100 kGy, then heated to 100 ° C. and kept at this temperature for 5 min and, after cooling, irradiated again with a dose of 400 kGy. In order to achieve the most homogeneous crosslinking profile possible, half of the radiation dose was applied to one side and the other half to the other side of the plate. The results shown in FIG. 1 were achieved when the samples were subjected to tensile loads and an unirradiated comparative sample up to the tear limit. The tensile strength both at 25 ° C (white bars, reference value of the unirradiated Sample 11 MPa) as well as at 100 ° C (hatched bars, reference value 3.15 MPa) was significantly higher with irradiation doses of 25 kGy and 50 kGy than with the unirradiated and with 100 kGy irradiated sample. For the sample irradiated with a total of 500 kGy, it was again higher than for the sample irradiated with 100 kGy and even considerably at a sample temperature of 100 ° C.

Even more important than this result are the results that were determined with regard to the stability of the characteristic curve. It follows from Fig. 2a that in a sample irradiated with 25 kGy, the specific resistance as a function of temperature in a series of circuits carried out in series (cycles 1, 3, 5, 7 are indicated by different line types) is only slightly scattered and there is no systematic shift towards lower switching temperatures. The same favorable result is obtained for a sample irradiated with 50 kGy from FIG. 2b. In contrast, as can be seen from FIG. 3, a comparison test with a sample which was irradiated with 100 kGy showed a relatively pronounced systematic decrease in the switching temperature and also a more pronounced hysteresis in the individual circuits.

The material described, irradiated with 10-75 kGy, preferably 25-50 kGy, is therefore excellently suitable for producing stable PTC resistors with good cold-conducting properties or also more complex components with a PTC component. The contacting and possibly also the assembly with other components can take place after the completion of the PTC material or even before the irradiation thereof.

The production of plates or other shaped parts can also be done by injection molding or pressing instead of extrusion.

Claims (10)

Process for producing a material for PTC resistors, in which a polymeric matrix material in the melt is mixed with a powdery filler, which consists essentially of at least one metal compound from one of the groups borides, carbides, nitrides, oxides, silicides, solidifies the mixture and that Matrix material is cross-linked by electron radiation, characterized in that the radiation dose is between 10 kGy and 75 kGy. A method according to claim 1, characterized in that the radiation dose is between 25 kGy and 50 kGy. A method according to claim 1 or 2, characterized in that the layer thickness of the material in the direction of irradiation is at most 3 mm. A method according to claim 3, characterized in that the layer thickness of the material in the direction of irradiation is between 1.3 mm and 2.5 mm. Method according to one of claims 1 to 4, characterized in that the matrix material contains at least one polyethylene or ethylene copolymer. A method according to claim 5, characterized in that the matrix material is an HD polyethylene. Method according to one of claims 1 to 6, characterized in that the filler consists essentially of titanium boride. Method according to one of claims 1 to 7, characterized in that the particle size of the filler is at most 50mm. Method according to one of claims 1 to 8, characterized in that the filler is etched before the admixture. Method according to one of claims 1 to 9, characterized in that the mixture is extruded from the melt into sheets, injected or pressed.

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