DE1236656B - Water-cooled ceramic tube capacitor - Google Patents

Description

Water-cooled ceramic tube capacitor In high-frequency generators for industrial purposes, the oscillating circuits are dimensioned for a reactive power that is 30 to 100 times the real power to be transmitted. The reactive power of the capacitor batteries is therefore for smaller generators of z. B. 4 kW 150 to 300 kVA and larger of z. B. at 100 kW up to 6000 kVA. More and more water-cooled ceramic capacitors are used for such stresses, since they are cheaper and take up less space than those with compressed gas, mica and CSl insulation. Capacity values of 1000 to 5000 pF are used, which can be loaded up to 800 kVA. Pot capacitors are used, which are liquid-cooled either outside or inside. The ceramic body is specially designed for attaching the water cooling fitting. Together with this fitting, it forms a structural unit.

The price of a water-cooled ceramic capacitor is three to five times the size of a condenser of the same size for normal air cooling, the basic structure of which is a tubular condenser. The advantage of water cooling is therefore bought very dearly. The water-cooled pot capacitors also have the disadvantage that the mostly soldered connection between the metal coating of the ceramic and cooling fitting often leaks and repair is not possible. With larger capacitor banks access to the individual capacitors is also made more difficult. Furthermore is this requires a considerable effort in connection lines for the cooling water.

There are also water-cooled ceramic capacitors known to their End faces press-fitted waterproof end plates through which the cooling water flows in and out. The cooling water circulates between one that runs inside the pipe cylindrical body and the metallic inner lining of the capacitor.

The invention relates to a water-cooled ceramic tube capacitor, its pipe ends with end plates through which the cooling water is supplied and discharged is, are watertight and inside is a cylindrical Body is located along the inner lining a cooling channel with an annular cross-section leaves free and serves as a power supply to the inner lining.

The invention consists in that the cylindrical body is a bolt is, which by means of screw connections, the end plates against sealing rings presses the pipe ends and furthermore via resilient connecting plates with the inner lining is electrically connected.

The invention is explained in more detail using exemplary embodiments.

F i g. 1 and 1 a show a longitudinal section and cross section through a capacitor with opposite cooling water connections; F i g. 1 b shows a detail; F i g. 2 shows a longitudinal section through a condenser with cooling water connections on one side; F i g. 3 shows the arrangement of two capacitors connected in series.

In FIG. 1 shows a water-cooled ceramic tube condenser with cooling water connection on both sides. 1 is the ceramic tube body of the usual design. 14 is the outer covering in the usual silver deposit design with the connection tab 14 a. 15 is the inner lining, expediently also designed as a silver deposit. At the end faces 1 a and 1 b, the connecting plates 2 and 3 are pressed watertight with the sealing rings 4 and 5 in between Resilient connecting plates 16 are inserted into a gap and serve as a power supply from bolts 6 to metal covering 15 (FIG. 1 a, 16). To even out the resilient pressure, slots 17 are provided in the connecting plates. Screws 7 and 8 are also provided on the bolt, which allow the end plates 2 and 3 to be pressed onto the end faces 1 a and 1 b, respectively. In the end plates 2 and 3 there are flow channels 11 and 12, respectively, which lead into the region of the gap. They serve to supply and discharge the cooling water which flows through the gap 13 and cools the ceramic tube condenser from the inside. Sockets 9 and 10 are provided on the flow channels for connecting the supply and discharge of the cooling water.

F i g. FIG. 2 shows an embodiment of the condenser in which both flow channels 11 and 12 run in an end plate 3. The flow channel 11 leads from the sleeve 10 into a longitudinal bore 23-24 of the bolt 6, which has two connections 25 after the gap 13 in the vicinity of the other end plate. The flow channel 12 leads from the sleeve 9 directly into the gap 13. The closure is effected by a cover 2 with sealing rings 4 by pressing on the cover by means of the screw 7. This results in simple assembly and interchangeability. The level of the condenser is not more precisely defined.

F i g. 3 shows an embodiment in which ceramic tube capacitors are arranged one above the other in the same axis. The transition from one capacitor to the other takes place via a watertight intermediate ring 18 with the sealing rings 19.

The bolt 6 with the hole for the cooling water extends over both capacitors. This design is suitable for circuits balanced to ground with the center of the capacitor lying on earth or also for asymmetrical cases where a high high frequency voltage requires the series connection of capacitors.

Claims (4)

Claims: 1. Water-cooled ceramic tube capacitor, whose Pipe ends with end plates through which the cooling water is supplied and discharged, are watertight, and inside is a cylindrical body is located, which along the inner lining has a cooling channel with an annular cross-section leaves free and serves as a power supply to the inner surface, which is not possible It is noted that the cylindrical body is a bolt which by means of screw connections presses the end plates against the pipe ends via sealing rings, and furthermore Electrically connected to the inner lining via resilient connecting plates is. 2. Water-cooled ceramic tube capacitor according to claim 1, characterized in that that each end plate has a flow channel. 3. Water-cooled ceramic tube condenser according to claim 1, characterized in that a closure plate has two flow channels has, of which one (water drain) directly into the cooling channel and the other (Water inflow) leads into a longitudinal bore of the bolt, which is close to the other End plate is in connection with the cooling channel. 4. Water-cooled ceramic tube condenser according to claims 1 to 3, characterized in that it consists of two in the same Axis one behind the other arranged ceramic tube capacitors, the transition from one capacitor to the other via a watertight intermediate ring takes place and the bolt is extended according to the total height of both capacitors is. Documents considered: German Patent No. 878 400; German Utility model no. 1726 891; Patent No. 11594 of the Office for Invention and Patent system in the Soviet zone of occupation in Germany.