DEP0004332BA - High voltage capacitor - Google Patents

Description

The invention relates to an electrical capacitor, in particular for high voltage in high frequency technology, which is built up in layers from metal coatings and insulating material, e.g. mica. Column-type capacitors of this type require a great overall length, since many partial capacitances are connected in series because of the high voltage. The condenser column is held together by pressure plates at the ends that are screwed together. Insulating stones are also required at the ends to insulate the connections of the capacitor from the pressure plates and fastening parts. If many partial capacities are connected in series, the total capacity becomes low. In order to achieve the necessary capacity, a simple layer-by-layer structure is therefore not always possible, but each partial capacity must be built up from capacities connected in parallel. Such capacities connected in parallel within a stack of capacities connected in series are obtained by building up the partial capacities in foil pockets. A particular disadvantage of these capacitor columns is the large inductance that is caused by the long current path from one end of the column to the other.

In contrast to such known constructions, in the capacitor according to the invention, which is built up in layers from metal coatings and insulating material, one power connection is fed to the center of the column and the second to the parallel-connected ends of the column. This circuit offers several advantages. The inductance is reduced to about a quarter compared to the conventional designs. The insulating stones at the ends of the capacitor are no longer necessary, since the capacitors are generally unipolarly connected to ground and the voltage is fed to the center. In addition to saving the insulating bricks, there is also a lower overall height than before. Since the parallel connection of the two halves of the capacitor means that the capacitance is four times greater than when connected in series, the individual partial capacitances can be smaller. The foil pocket construction is no longer necessary. This also brings savings in mica with it.

The details of the invention can be seen from the figures. Fig. 1 shows schematically a capacitor in the usual design. The pressure plates for holding the capacitor stack together are marked with a, the insulating stones at the ends of the column with b. The stones b isolate the connections c, c 'from the pressure plates. The parts d are the partial capacities or foil pockets that are connected in series. In Fig. 2, the capacitor according to the invention is shown. With a are again the printing plates, with d the partial capacities. The voltage is supplied on the one hand to the interconnected connections c, and on the other hand to the interconnected connections c 'in the middle of the stack. b represents an insulating stone. The two

Connections c 'and the insulating stone between them are not absolutely necessary. However, these parts make testing easier in manufacture. In order to ensure an even load on both capacitor halves, both halves must have the same capacitance. By measuring the capacitance separately for each half during the manufacture of the capacitors, it is achieved that the two halves can be compared. In the case of a simple center connection without an insulating block, it would not be possible to measure one half alone.

Claims (2)

1. Capacitor, especially for high voltage in high frequency technology, in column construction, which is built up in layers from partial capacities, characterized in that the power connection is made in the electrical and mechanical center of the capacitor column on the one hand and at the interconnected ends of the column on the other. 2. Capacitor according to claim 1, characterized in that the two halves of the capacitor are separated by insulating material in the middle of the column.