DE492043C - High resistance in a vacuum - Google Patents

Description

High resistance in vacuum in wireless telegraphy, however High-resistance resistors are also required in other branches of electrical engineering, which must combine a number of properties.

t. the resistance must be largely independent of the load; 2. Such a resistor must not show any electrical after-effects, d. H. it there must be no voltage at the ends of the resistor after a current has passed be more detectable; 3. Must be the capacity of the resistor if you have the same want to need, for example, for high-frequency vibrations, extremely low be; 4. It must also not have any noticeable self-induction; 5. Must such a resistance must be independent of the effects of temperature and humidity; 6. The connection of the supply and discharge lines to the resistor must be so reliable be that neither thermoelectric nor electrolytic or fritter-like fluctuations can enter at the crossing points; 7. the spatial dimensions of such Resistance must be very low, so when using the resistors in circuits a compact assembly is possible; B. the resistance with a low Costs can be produced. In particular, observations have shown that to a large extent electrical after-effects can occur, which these resistances render it unusable for receiving purposes of wireless telegraphy.

The subject of the invention is a high-ohmic resistor, which all meets these requirements.

It has been found that a carrier made of insulating material, preferably glass, at the ends of which the leads are attached and which is covered with a thin conductive layer, best meets the requirements. Such resistors are already known, e.g. B. by S chrac k patent 384837. It turns out, however, that the information contained in this patent specification about the type of layer to be applied to the glass substrate is not sufficient to generate perfect resistances. In particular, the graphite layer material mentioned as an example is unsuitable for producing high-value resistors, since its specific conductivity is much too high to produce the required high resistance values.

According to the invention, the layer material used is (once divided soot, whose specific resistance is much higher, so that it is actually possible will produce the very high resistance values desired. Those with the finest split soot as a layer provided resistors under use one Glass carrier, at the ends of which lead electrodes are melted, can in-the following Way to be made.

The stick is brought into a sooty flame, and that is first of all a relatively thick deposit of soot on the two ends where the wires were melted down, produced. Then -the surface of the glass rod becomes light sooted, ideally while simultaneously observing the respective resistance a switched on ohmmeter. As soon as the correct resistance value is reached, the further sooting is discontinued.

A particular advantage of this method is that the heating, which the insulating body experiences this, which drives away moisture, which otherwise the Resistance value significantly influenced.

Another great advantage is that the leads are at the ends can be covered with a thick layer of soot, and that there is no silver plating or other treatment of these ends is required to ensure good contact between the ends Establish supply line and the actual resistance layer.

Since soot is essentially chemically inactive, one so produced is subject to Resistance only to the changing influences of moisture and mechanical damage. In order to avoid this, the resistance body produced in the manner described is used Fused airtight into a small glass tube in a manner known per se and evacuated the tube. This also causes mechanical damage and moisture influences excluded. It is important that the Ends of the resistor carrier so far away from the melting points in the glass tube are that during the meltdown a considerable heating of the ends of the resistor carrier cannot occur.

Resistors produced in this way meet all of the above requirements and, above all, only take up a small amount of space. You have a great one here Advantage over vacuum resistors, which are based on other methods using cathode sputtering of metals or by applying graphite layers. Because of the The length of the resistor body must have a much higher conductivity of these layers be chosen much larger, with the result that. all resistance essential gets bigger and more expensive. The resistors made according to the invention are wise. on the other hand, externally only the size of the well-known Silitststabs and are therefore for practical apparatus construction is very advantageous.

Claims (1)

PATENT CLAIMS: i: High-ohmic resistance in the vacuum, characterized in that that the resistance layer consists of finely divided soot. z. High resistance according to claim i, characterized in -da ß the layer by a sooting flame is generated: