CH209752A - Stress multiplier. - Google Patents

Description

  

  



  Stress multiplier.



   The voltage multiplier according to the present invention is primarily used to generate high DC voltages. For this purpose it has at least one group of individual capacitors held one behind the other, which are charged periodically one after the other by a voltage source via a switch.



   In the following, exemplary embodiments of the subject matter of the invention are explained in more detail using illustrations.



   In the example of FIG. 1, there is a group of individual capacitors connected in series. The end pumps 1 and 2 of the group form the terminals of the high voltage source. The individual capacitors 3 are charged one after the other periodically by a direct current generator 4 by means of a rotary switch 5-6; the latter is mechanically coupled to the generator shaft. The generator is isolated from the capacitor group and from earth. It is driven by a motor 7 via an insulating shaft 8.



  In Fig. 1 the number of individual capacitors is 8.



   In the example according to FIG. 2, there are two parallel groups of the same number of individual capacitors connected in series. The endpoints 1 and 2 of the groups form the terminals of the high voltage source. The individual capacitors 3 are charged one after the other periodically by a DC generator 4 by means of a rotary switch 5-6; the latter is mechanically coupled to the generator shaft. In FIG. 2, for example, the number of individual capacitors is eight per group. The generator is against. the Eondeizer groups and isolated from earth. It is driven by a motor 7 via an insulating shaft 8.



   In the example according to FIG. 3, as in example 2, two parallel groups of the same number of individual capacitors 4 connected in series occur. The endpoints 1 and 2 of the groups form the terminals of the high voltage source. The generator 3 is here a two-pole alternating current generator.



  The circle of condensers formed by the two parallel groups is subdivided into a certain number of equal subgroups 5 which are separated from one another by an angular step of. The relationship between the instantaneous voltage on the rotating switching arm 7 and the arrangement of the subgroups 5 on the capacitor circuit is shown in FIG. Each subgroup corresponds to a voltage maximum of the sine wave.

   The connections of the elements 4 with the steps 6 of the holder 7 are carried out in such a way that between the high-voltage terminals 1 and 2, which are advantageously located in the 3-please symmetrical subgroups. the voltages of the individual capacitors 4 add up. This is true. if the connections of the individual capacitors to switch stages are exchanged from one subgroup to another and via the high-voltage terminals. In Fig. 3 there are four subgroups of four individual capacitors each, and the generator has four poles.

   The switch 7 is mechanically connected to the shaft of the generator 3: this is also insulated from the capacitors and from earth and is driven by a motor 8 via an insulating shaft 9. It is also possible to increase the voltage of the individual capacitors by connecting a transformer between the generator and the switch.



   In general, the voltage source can be an electrical accumulator.



   In the example according to FIG. 5, the voltage source consists of an electrical capacitor 7. At least two stages 8 of the switch are then connected to an external electrical source 3. When the holder 4 sweeps the two steps 8. If the capacitor charges itself: er girl, then as a voltage source and can discharge itself onto the individual capacitors.



   The switch 4 is driven by a motor 5 by means of an insulating shaft 6.



   To limit the charging current of the individual capacitors, it is advantageous to insert resistors between these and the switch stages, or between the switch itself and the electrical voltage source.



   There is also the possibility of limiting the discharge current of the voltage multiplier in the event of a short circuit between its high-voltage terminals. to connect the individual capacitors in series by means of resistors
The device according to the invention can be used in the opposite sense to reduce a high voltage.



   To establish very high DC voltages, several arrangements according to FIGS. 2, 3 and 5 can be connected in series, as FIG. 6 shows. The various generators are arranged one above the other and form a simule; they are driven by the same motor via a common insulating shaft.



   The voltage multiplier made of the He-making can be used as the first stage of a Stōanlage after Marx circuit. The high-voltage transformer, the rectifier and the external charging resistors, which formed the charging device, can thus be omitted; this represents a considerable saving.

 

Claims (1)

PATENT CLAIM: Voltage multiplier, characterized in that it has at least one group of individual capacitors connected in series, which are charged periodically one after the other by an electrical voltage source via a switch. SUBClaims: 1. Voltage multiplier according to patent claim, characterized in that it has two parallel groups of individual capacitors connected in series. 3. Voltage multiplier according to patent claim, characterized in that a DC voltage generator serves as an electrical voltage source. 3. Voltage multiplier according to patent claim, characterized in that an electric accumulator serves as the electrical voltage source. 4. Voltage multiplier according to patent claim, characterized in that a loaded electrical capacitor serves as an electrical voltage source. 5. Voltage multiplier according to the patent claim, characterized in that an alternating current generator is used as the electrical voltage source. 6. Voltage multiplier according to claim and dependent claim 5, characterized in that a transformer is switched on between the voltage source and switch. 7. Voltage multiplier according to claim, characterized in that the electrical voltage source is isolated from the capacitor chain. 8. voltage multiplier according to patent claim, characterized in that the electrical voltage source is isolated from ground. 9. voltage multiplier according to claim, characterized in that the The switch consists of two rotating levers and two rows of steps. 10. voltage multiplier according to patent claim, characterized in that the Switch is mechanically connected to the generator shaft when the voltage source is an electric generator. 11. voltage multiplier according to patent claim, characterized in that the Switch is driven by an insulating shaft and a motor if the voltage source is not an electrical generator. 12. Voltage multiplier according to claim, characterized in that the Individual capacitors are connected in series by means of resistors. 13. Voltage multiplier according to patent claim. characterized in that the Voltage source with the switch over Resistors is coupled. 14. Voltage multiplier according to patent claim, daduroh characterized that the Individual capacitors are coupled to the Sohalter stages via resistors. 15. Voltage multiplier according to claim, characterized in that it works as a voltage divider. 16. Voltage multiplier according to patent claim, characterized in that it forms the first voltage level of a surge system.