SU1377988A1 - Self-excited inverter - Google Patents

Abstract

The invention relates to a converter technique and m. used in the technique of induction heating. S Ui. 1 VA and melting metals. The goal is to reduce the start time. The device contains a bridge on thyristors 2-5 with a switching capacitor 6, to which the threshold element 22 is connected with the generator 15 control pulses. The working winding 17 of the magnetic amplifier 16 is turned on in the reset circuit. an additional thyristor 21, the control electrode of which is connected to the generator 15. When starting the inverter, the dropping diode 1 2 is closed, since the magnetic amplifier 16 does not work until the voltage on the capacitor 6 reaches nominal value .2 cl. (L 00 vj 00 OS

Description

The invention relates to a conversion technique and may find wide application in the technique of induction heating and melting of metals.

The purpose of the invention is to reduce the start time.

FIG. 1 shows an electrical circuit diagram of an inverter; FIG. 2 - the process of an autonomous inverter output to the steady state operation: a) the bridge thyristors current, b) the discharge diode current, c) the voltage across the switching capacitor.

The self-contained inverter contains bridge 1 on thyristors 2-5 with switching capacitor 6 in the diagonal of alternating current connected to the power source 7 through serially connected input choke 8 and the primary winding 9 of switching throttle 10, the secondary winding 11 of which with a resetting diode 12 forms a circuit discharge of excess reactive energy, while the series-connected separation capacitor 13 and the load 14 are shunted by a chain of excess reactive energy and connected in parallel in series Ennm of the primary winding 9 of the switching throttle 10 and thyristor bridge 1, the generator of control pulses 15, the magnetic amplifier 16, the working winding 17 of which is connected in series with the secondary winding 11 of the switching throttle 10 and the resetting diode 12, and the control winding 18 is connected with an additional HbW power source 19 via a resistor 20 and an additional thyristor 21, the control electrode of which through a generator of control of the pulse 15 and the threshold element 22 is connected with the switching capacitor 6.

Autonomous inverter in the quasi-established mode operates as follows.

The isolating capacitor 13 is normally charged up to the voltage of the power source 7 through the input choke 8 and the load 14.

Let the switch capacitor 6 have the polarity of the voltage indicated in FIG. one.

When control pulses are applied to the thyristors 2 and 4, they turn on and the oscillating overcharge of the switching capacitor 6 starts over the circuit.

g

ten

15 20 25 30, with Q.

50

five

pi 19-9-2-6-4-14-13. The polarity of the voltage on the windings 9 and 11 of the commutating throttle 10 at the same time, as shown in FIG. one.

When the thyristors 2 and 4 pass through the maximum value, the polarity of the voltage on the windings 9 and 11 is reversed. In addition, when the voltage on the switching capacitor 6 reaches the rated value, the threshold element 22 is turned on, the control pulse generator 15 is started, which outputs a continuous high-frequency sequence of control pulses to turn on the thyristor 21. When the thyristor 21 is turned on and the control winding 18 of the magnetic amplifier 16 the voltage of the additional power source 19 is applied, and as soon as the total voltage of the windings 11, 17 (respectively, the switching throttle 10 and the magnetic amplifier 16) becomes higher ummarnogo voltage capacitor 13 and load 14, the diode 12 is turned on, dumping the excess reactive power with commutating choke 10 to capacitor 13 and load 14. This provides restriction of the amplitude of the voltage on the capacitor 6 commute.

Further, thyristors 3 and 5 work similarly.

When the inverter is started, the reset diode 12 is closed, since the magnetic amplifier 16 does not work until the voltage on the switching capacitor 6 reaches the nominal value (Fig. 2), which significantly reduces the startup time of the inverter, since the accumulation time of the switching terminal is eliminated the capacitor 6 of the charge value during the start-up process corresponding to the amplitude of the voltage across it in the steady state mode of operation of the inverter.

As soon as the voltage on the switching capacitor 6 reaches the nominal value, the inverter starts to work as described.

Claims (1)

Invention Formula A standalone inverter containing a thyristor bridge with a switching capacitor in the AC diagonal, connected to a power source through a series-connected input choke and the primary winding of the switching throttle, the secondary winding of which with a resetting diode form a discharge circuit of excess reactive energy, with the series-connected separation capacitor and the load circuit shunted by the specified fault circuit and connected in parallel and in series with the primary winding mutating choke and a thyristor bridge, and also controls the pulse generator guides. characterized in that, in order to reduce the start-up time, it is equipped with an additional thyristor, a resistor, a threshold element and a magnetic amplifier, the working winding of which is connected in series to the reset circuit and the control winding is connected to the additional power source introduced through a resistor and an additional thyristor , the control electrode of which is through the generator of control pulses and the threshold element is connected to the switching capacitor. F (/ r. 2