DE877627C - Electrolytic feed-through capacitor for interference suppression purposes - Google Patents

Description

Recently, electrolytic feedthrough capacitor for anti-interference purposes one has switched to electrolytic capacitors for interference suppression purposes to use; in particular the high specific capacitance of such capacitors to take advantage of. However, the use of an electrolytic capacitor of the usual type leads therefore not the desired goal, since z. B. in the so-called dry electrolytic Capacitors in which the electrolyte is essentially pasty has a complete connection of the protruding from the capacitor body Edges of the electrodes under each other is not flawlessly possible, and there in the so-called liquid electrolytic capacitors, in which the electrolyte is essentially easy to move, difficulties because of the connection of the layered Electrode plates with the housing or with the leading through the capacitor body electrically conductive axis are to be expected. These difficulties are particularly evident in a strong increase in the transition resistance, in a bad formation the anodic electrode that forms the dielectric of the capacitor Barrier layer is to be provided and in an undesirable corrosion, which is detrimental affects the life of the capacitor. It has also already been suggested to use electrolytic capacitors as so-called feedthrough capacitors, but had to find with the known arrangements that in particular the capacitive dissipation the interference currents were generally not very good.

The present invention now relates to an electrolytic Feedthrough capacitor for interference suppression purposes and the purposes mentioned at the beginning Eliminate disadvantages.

According to the invention this is achieved in that the electrodes of the capacitor intermesh helically with a spacing and symmetrically around the conductor leading through the capacitor are arranged. more details of the invention emerge from the following description of the drawing, in an embodiment is shown in longitudinal section.

The cathodic electrode; which generally does not have a barrier layer, is essentially designed as a housing i, in which a preferably with the housing out of one piece. existing thread relatively high pitch and pitch is appropriate. The execution is made so that the individual threads represent the actual cathodic electrode area. The cathodic threads are marked with: 2. The housing i is on one side, as shown in the drawing on the lower side, open, so that the thread turns accordingly trained, e.g. B. provided with a barrier, anodic electrode effortlessly can be screwed into the housing. The anodic threads are 3 designated. They are in a suitable shape with the electrically conductive axis 4 of the Capacitor connected. For example, it is possible to use the entire anodic body in one piece, preferably by injection molding or the like. After screwing in The anodic electrode requires the distance between the anodic and regulate the cathodic threads. This is preferably done using the screw connections 5 and 6 arranged at the exit points. The screw connection 5 is attached directly to an eye-like projection 7 of the housing, wherein another seal 8 made of elastic material such as rubber between the conductive Implementation axis 4 and the housing i is provided. Same rubber seal 9 is provided in the screw connection 6, namely this arrangement is located in the lid io or bottoms of the housing i. As can be seen from the drawing, If the lid is screwed into the housing, the housing wall has the internal thread having. It is useful between the lid io and the first gear of the anodic or the cathodic electrode a further insulating material base i i, likewise in particular made of rubber. It is recommended as an electrolyte for the electrolytic capacitor to use those which have a low specific resistance. the end for this reason, the capacitor according to the present invention is preferable used as an electrolytic liquid feed-through capacitor. It is natural also possible, the housing or the threads of the housing with a barrier layer and to leave the counter-electrode bare, depending on the purpose the capacitor is to be used with regard to its interference suppression effect. aside from that can be used to further increase the specific capacity by a known method enlarge the surface of the corresponding electrodes.

Claims (7)

PATENT CLAIMS: i. Electrolytic feed-through capacitor for interference suppression purposes, characterized in that the electrodes of the capacitor are helical with Interdigitated spacing and symmetrical about the one passing through the capacitor Heads are arranged. 2. Capacitor according to claim i, characterized in that that the cathodic electrode is preferably designed essentially as a housing (i) is, in which a with the housing (i), in particular consisting of one piece Thread (2), relatively high pitch and pitch is attached. 3. Capacitor according to claims 1 and 2, characterized in that the anodic electrode consists of the electrically conductive bushing axis (4), which is anodic Thread turns (3) is provided in such a way that the anodic electrode body is in the cathodic electrode body can be screwed. 4. Capacitor according to claim i to 3, characterized in that the entire anodic electrode body (3, 4) consists of one piece. 5. Capacitor according to claim i to 4, characterized in that that at the points where the electrically conductive bushing axis (4) from the housing (i) or from the cover (io) of the housing emerges, screw connections (5, 6) are provided, with the help of which the distance between the opposing thread turns (2; 3) can be adjusted. 6. Capacitor according to claim i to 5, characterized in that that at the points of passage of the electrically conductive axis (4) in addition Seals (8 and 9), in particular consisting of rubber, are located. 7. Capacitor according to claim z to 6, characterized in that between the cover (io) des Housing (i) and the first thread of one of the two electrodes a further Isolierstoffünterläge (i i), in particular consisting of rubber, is provided. B. Capacitor according to Claims 1 to 7, characterized by the use of electrolytes low resistivity, especially of liquid electrolytes. G. Capacitor according to Claims i to 8, characterized in that the electrodes in their surface are enlarged.