CS233612B1 - Connexion for compensation of high voltage ripple - Google Patents

Abstract

Wiring is suitable for high voltage resources for electron optical systems. It is sensed in the wiring power supply voltage ripple a the alternating component formed is of a suitable size and the phase with the control voltage width modulator derived from regulatory deviations.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a circuit for compensating ripple of a high voltage power supply suitable particularly for electrical cane optical devices.

In electron optical systems, an acceleration voltage is required for operation, which is obtained by means of high frequency high voltage sources. The power part of these sources operates with a constant pulse width, where the output voltage is controlled by changing the power supply voltage of the power stage by a converter converter e with a variable pulse width. The disadvantage of this circuit is that the choke converter acts as a cell with a constant transmission in the band from zero to hundreds of Hz, i. The pulse power portion has a relatively fast response to a change in the control voltage, and a strong 100 Hz load also appears in the output voltage. In the wiring used up to now, the ripple is eliminated either by increasing the gain of the control circuit in the critical frequency range of the rotors, resulting in problems of dynamic stability, or stabilization of the supply voltage, resulting in increased wiring complexity and possibly reduced efficiency.

These disadvantages are eliminated by the circuitry to compensate for the ripple of the high-voltage power supply according to the invention.

SUMMARY OF THE INVENTION The width modulator control input is connected via a second resistor to a deviation amplifier output and through a first resistor to a transmission cell output whose input is coupled via a capacitor to a power supply output.

The main advantage of this new circuit is the reduction of the power component of the ripple of the output voltage without increasing the gain of the control loop at the power frequency. In addition, the circuit suppresses the influence

233812 rapid changes in line voltage to output voltage.

BRIEF DESCRIPTION OF THE DRAWINGS The invention is illustrated in greater detail in the accompanying drawing, in which a block echema circuit for compensating a ripple high voltage source is shown.

The power supply 11 is connected via a choke converter 2 with a power stage 2 and a capacitor 7 with an input of a transmission cell 8, the output of which is connected via a first resistor 9 to a control input of a width modulator 4.

The width modulator control input is coupled via the second resistor 10 and the deviation amplifier 5e by the divider 11. The active flip-flop 6 is connected both to the width modulator input 4 and to the output stage power stage 3, the output of which is coupled 8 by the divider 11 and high-voltage power supply terminal.

In the circuit, the ripple of the voltage of the power supply unit 1 is sensed and the resulting AC component is read in suitable phase e phase by the control voltage of the width modulator 4 derived from the control deviation. If the static transmission of the width modulator 4 is negative, the transmission element 8 is formed only by a resistive divider. The advantage of this connection is a substantial reduction of the network component. In the case of capacitors with capacitive input filter, the compensation component under load changes and allows for correct operation of the wiring over a wide range of drawn currents.

A circuit for compensating ripple of the high voltage power supply is particularly suitable for high voltage power supplies intended for electron optical systems.

Claims (1)

Circuit for compensation of ripple of high voltage source consisting of power supply, choke converter, power stage, width modulator, deviation amplifier and astable flip-flop, characterized in that the width modulator control input (4) is connected to the amplifier output via a second resistor (10) deviations (5) and on the one hand through the first resistor (9) to the output of the transmission cell (8), whose vetup is connected via a capacitor (7) to the output of the power supply (1)