SU849461A1 - Capacitor charging device - Google Patents

Description

(54) DEVICE FOR CAPACITOR CHARGING

one

The invention relates to electrical engineering, in particular, to a pulsed technique, and can be used to power - pulsed optical quantum generators and pulsed radio installations.

A device for charging a capacitor, designed to operate in a constant-power mode, is consumed from the mains supply and contains two three-phase rectifiers, a charging choke and a bypass valve connected in parallel to one of the rectifiers and the choke 1.

The disadvantage of this device for charging a capacitor is a large oscillation, an instantaneous value of the power at small periods of charging the capacitor, which are close in duration to the period of the supply voltage.

Also known are devices for charging a capacitor, containing regulating elements, capacitors and chokes, and opu1, which have a constant power of 2 drives.

The disadvantages of such devices include the poor use of thyristors and

the need to install filters at the input of the device. Small fluctuations in the power consumed from the power source are ensured by installing a large number of energy-intensive capacitors, which reduces the reliability of the device.

The closest to the invention in its technical essence is a device for charging a capacitor, comprising a constant voltage source, a regulator, a storage capacitor, and a pulse load connected in parallel to the storage capacitor 3.

A disadvantage of this device for charging a capacitor is the presence of capacitive filters at the inlet and outlet of the regulator, which, given the reliability limits of the circuit, the capacitance values of the filter capacitors do not provide constant power consumed from the power source.

The purpose of the invention is to increase the constancy of the power consumed from a constant voltage source.

Claims (2)

This goal is achieved by the fact that in a device for charging a capacitor containing a constant voltage source, a regulator, a storage capacitor and a pulse load connected in parallel to the storage capacitor, the regulator consists of a current inverter, a transformer, the first droselsel, the rectifier and the second Drossel, with the current inverter connected between the positive terminal of the DC source and the first plate of the storage capacitor, and the DC terminal of the DC source is negative and The torus of the storage capacitor is connected to the common bus to which the negative output of the rectifier is connected, the AC outputs of which are connected via the first choke and the transformer to the AC leads of the current inverter, and the positive output of the rectifier is connected to the first facing of the storage capacitor. FIG. 1 shows a single-line diagram of a device for charging a capacitor; in fig. 2 - complete device diagram. The positive terminal of the constant voltage source L is connected to the positive terminal of the current inverter 2, the negative terminal of the current inverter 2 is connected to the first terminal of the storage capacitor 3, parallel to the storage capacitor is connected a pulse load 4, the second output of the storage capacitor 3, pulse load 4 and a negative terminal of the source constant voltage connected to a common bus. A negative output of the rectifier 5 is also connected to the common bus, the positive output of which through the second choke 6 is connected to the first output of the storage capacitor 3; the AC outputs of the rectifier 5 are connected via the first choke 7 to the secondary winding of the transformer 8, the primary winding of which is connected to the AC leads current inverter 2. The complete diagram of the device for charging a capacitor with a bridge inverter current 2 and a three-phase bridge rectifier 5 (Fig. 2) shows the capacitors of the current inverter 9 and the choke in the DC circuit of the current inverter 10. The device for charging the capacitor operates as follows. At the moment of discharge of the storage capacitor 3, the voltage across it decreases to the minimum level and almost all the voltage of the DC source is applied to the DC terminals of the current inverter 2. With a constant value of inverter current 2, the power is increased, supplied to the DC terminals of the current inverter and, consequently, the power at the AC outputs of the inverter increases and power is supplied to the rectifier 5. Power from the rectifier 5 with a small voltage The storage capacitor 3 is transmitted to it at high currents. With increasing voltage on the storage capacitor 3, the voltage at the input of the current inverter 2 decreases, and when its current is constant, the power at the input of the current inverter and at the input and output of the rectifier 5 decreases. With increasing voltage on the storage capacitor 3, the power increases supplied directly from the source of direct voltage 1. Thus, at the initial moments of the charging process, energy is supplied to the storage capacitor mainly through an alternating current circuit, in the middle of the process and is supplied both through an alternating current circuit and a direct current circuit, and at the end of the process, at voltages on a storage capacitor close to the maximum, the energy is supplied mainly through a direct current circuit. In the process of charging the storage capacitor, the load of the current inverter varies from maximum to minimum. The input resistance of the current inverter varies from maximum value to minimum value at the end of the charging process. The process of charging the storage capacitor in the proposed device is similar in nature to the process of charging the storage capacitor through a variable adjustable resistance. With a current inverter frequency exceeding the frequency of the storage capacitor 30-50 times and a three-phase bridge inverter circuit, the power is stabilized with an accuracy of up to 0.05-0.10 of the average power. Claims An apparatus for charging a capacitor, comprising a constant voltage source regulator, a storage capacitor, and a pulse load connected in parallel to the storage capacitor, characterized in that, in order to increase the constancy of the power consumed from the constant voltage source, the regulator The torus consists of a current inverter, a transformer, a first drossel, a rectifier, and a second drossel, with a current inverter connected between the positive terminal of the constant voltage source and the first A negative capacitor terminal and a negative terminal of the storage capacitor are connected to the common bus to which the negative terminal of the rectifier is connected, the AC terminals of which are connected via the first choke and the transformer to the AC terminals of the current inverter, and the positive terminal rectified via WTO