CS257656B1 - Connection for electric current multiplication - Google Patents

Abstract

M It is usable in Source electronics and electronic devices and appliances. The wiring is formed capacitors and diodes connected in series wherein the condensers are discharged diodes and semiconductor switch connected to output. The effect is multiple greater output current against input, effect with it is achieved by the capacitors being charged in series and discharged in parallel connection. Used in designing resources and better theorem parameters. and efficiency.

Description

BACKGROUND OF THE INVENTION The present invention relates to a circuit for multiplying an electric current which allows the output to be drawn several times greater than the current passing through the circuit input.

So far, transformers have been used to obtain larger currents in which the output current of the secondary winding of the transformer is several times greater than the input current of the primary winding, with a multiplier equal to the ratio of the number of primary and secondary windings of the transformer windings. For these reasons, transformers that have better efficiency than voltage dividers and less distort the sinusoidal voltage in the grid than thyristor phase-controlled power supplies are used for power supplies for electrical and electronic equipment that require low voltages and high currents. The disadvantages of transformers, however, are their relatively high weight and high material consumption of copper for transformer windings and high-quality steel for transformer sheets. ·.

The above-mentioned drawbacks are eliminated with the current multiplication circuit according to the invention, which is based on the fact that it is connected to a parallel combination of m stages formed from a diode to which a cathode is connected via a capacitor anode of a discharge diode. the parallel combination step is connected by the anode of a charging diode whose cathode is connected between the capacitor and the discharge diode of the next stage of the parallel combination, between the capacitor and the discharge diode of the first stage of the parallel combination connected by an output modulator whose input is also the input terminal of the wiring. A charging diode is connected between the cathode of the diode and the capacitor of the last stage of the parallel combination, the cathode forming the output terminal of the wiring and connected to the filter capacitor and the semiconductor switch, the input of which is connected to the discharge cathodes of all stages of the parallel combination. The second terminal of the filter capacitor is connected to the anode diodes of all stages of the parallel combination and forms an input reset terminal and an output reset terminal.

The wiring according to the invention is advantageous in that conventional electrolytic capacitors and diodes are only loaded by the input current, which means that smaller types can be used. The whole circuit consists only of capacitors and semiconductors, which can be combined into integrated circuits. The transistor or thyristor switch in the wiring can advantageously be used to stabilize the output voltage or current by controlling the switching angle.

In the accompanying drawing, an example of a circuit for multiplying the electric current according to the invention is shown in the diagram.

To the parallel combination of the m stages formed from the diode 1 to which the cathode is connected via the capacitor 4, the discharge diode anode between the cathode-diodes T ^{and the} capacitor 4 of each stage of the parallel combination is connected by the anode charge diode 2 and an anode of the discharging diode 16 of the next stage of the parallel combination, between the capacitor 4 and the anode of the discharging diode 6 of the first stage of the parallel combination, connected by an output modulator 2 whose input is also the input terminal J1 of the circuit. A charge diode 5 is connected between the cathode of the diode T and the capacitor 2 of the last stage of the parallel combination, the cathode of which forms the output terminal 10 of the wiring and is connected to the filter capacitor 9 and the semiconductor switch. 6 diodes of all stages of parallel combination. In this case the second terminal of the filter capacitor 2 ^e j conjunction with the anode of the diode 7 of the parallel combination of all levels and constitutes the input terminal 2 and a reset output reset terminal Li.

A line voltage is connected to the input terminals with a phase conductor to the input terminal J. and a neutral conductor to the input neutral terminal 2, or another voltage can be applied to the input terminals. The modulator 3 modulates the input voltage to a pulsating DC voltage in polarity such that the charging diodes are in the forward direction. Semiconductor switch 2 ^e j is closed only in such part of the period of the modulated input voltage, the modulator 2 ^e j in the non-conductive state. The function of the circuit is that the capacitors 6 are in the first half-period modulated

the input current, when the modulator 2 is ^{in the} closed state, is charged in series connection. In the second half-period, on the other hand, when the semiconductor switch 2 is in the closed state, the capacitors are discharged in parallel connection to the filter capacitor 6 and to the load connected to the output terminal 10 and the output reset terminal 11. + Warmth greater than the mean input current, where m is the number of degrees of the parallel combination.

The circuitry according to the invention is applicable in the source parts of electrical and electronic devices and appliances, unless it is expressly required to isolate the output and input for a reason other than protecting against dangerous contact voltage. Protection of the output from dangerous contact voltage is accomplished by interconnecting the output neutral terminal 11 with the neutral conductor via the input neutral terminal 2.

Claims (1)

A circuit for multiplying an electric current modulated by a semiconductor element, characterized in that an anode of a discharge diode (6) is connected to a parallel combination of m stages formed from a diode (7) to which a cathode is connected via a capacitor (4). ) and a capacitor (4) of each stage of the parallel combination is connected by an anode of the charging diode (5) whose cathode is connected between the capacitor (4) and the anode of the discharge diode (6) of the following stage of parallel combination the parallel combination stage is connected to the output of a modulator (3), the input of which is also the input terminal (1) of the circuit, whereby a charging diode (5) is connected between the cathode of the diode (7) and the capacitor (4) of the last stage of the parallel combination. a wiring terminal (10) and is connected to a filter capacitor (9), the second terminal of which is connected to the anode di from (7) all stages of the parallel combination, they form an input reset terminal (2) and an output reset terminal (11), and on the other, a semiconductor switch (8), the input of which is connected to the discharge cathodes (6) of all stages of the parallel combination.