DE888880C - Process for the production of electrical resistors from pressed parts based on hardenable synthetic resins - Google Patents

Description

The invention relates to molded parts based on hardenable materials Synthetic resins, with the admixture of z. B. electrically conductive substances than electrical High resistance resistors can be used. Knowing that given chemical composition of the mass the electrical resistance largely from the pressing pressure depends, under which the pressed parts are produced, is according to the invention Proposed application of a pressure in which the achievable resistance of the concerned pressed part under given physical conditions and given chemical compositions of the molding compound-a minimum.

Under otherwise identical physical conditions and the same chemical composition of the molding compound, the electrical resistance of the part to be pressed decreases with increasing molding pressure. This is understandable if one considers that in the initially loosely prabletted mass or in the mass powder loosely poured into the mold, the contact between the individual particles and thus the necessary electrical contact is still very small. As the volume is reduced by increased pressure, the contact of the particles becomes more intimate. It has now been found that the electrical resistance increases again with a further increase in the pressing pressure, so that the electrical resistance passes through a minimum. While the decrease in the electrical resistance occurs very rapidly with the increase in pressure from low values, the increase in the electrical resistance proceeds much more slowly as the pressure rises above already higher values. The diagram in the figure shows in principle the dependence of the electrical resistance on the pressing pressure in arbitrary units of measurement. The electrical resistance r falls during the pressure of po on. p 3 increases and has the smallest value r3 at p 3. As the pressure increases further above p 3, the resistance also increases, but this type of pr curve is flatter than that at lower pressures below p 3. The curve shows that the resistance values, with the exception of the value p 3 marked as the minimum, are better two different press pressures can be obtained.

Since compliance with a certain compression pressure is known to depend on factors that are not readily in hand, z. B. from the constant filling weight of the molding compound, the permissible lower and upper limits (tolerances) for the nominal value of the electrical resistance of a molded part are easily exceeded in practice and lead to undesirable rejects. If you now work z. B. with Sollpreßdrucken of the values pi or p 2, it can be seen from the curve of the figure that changes in pressure cause greater changes in resistance than when the Sollpreßdrucken p 3 is applied; which corresponds to the minimum value r 3 of the resistance. The curve is flattest in the vicinity of the minimum value r 3, and large changes in pressure are therefore offset by the smallest possible changes in resistance under otherwise identical conditions. It is therefore advantageous for better compliance with the tolerance to choose the minimum value of the resistance as the lowest tolerance limit and to work with the associated pressing pressure. In addition, the tolerance range of the electrical resistance can be narrowed and thus higher quality pressed parts can be obtained.

Claims (1)

PATEN TANSPR1, CIi: Process for the production of electrical resistors made of molded parts based on hardenable synthetic resins, characterized in that that a pressing pressure is used in which the achievable electrical resistance of the relevant pressed part under given physical conditions and given chemical composition of the molding compound represents a minimum.