SU824389A1 - Inverter - Google Patents

Description

(54) INVERTER

I

The invention relates to electrical engineering and can be used in automatic and communication systems.

Inverters are known that are made using a push-pull transistor circuit of an auto-generator with a transformer positive feedback fl, 2 and 3.

The prior art devices do not provide an intermittent voltage conversion mode with the active and inductive nature of the load.

The closest in technical essence to the invention is an inverter containing a transformer, the power winding of which is connected by an average lead to one of the input leads, and the extreme leads to the collectors of two power transistors, the emitters of which are combined and connected to the midpoint of a resistive voltage divider connected to the input pins, while the bases of the power transistors are connected to the extreme terminals of the positive feedback winding of the transformer, the midpoint of which is through the resistive sensor The charge capacitor is connected to the middle point of the power winding. The device provides

intermittent voltage conversion mode for any type of load 4.

However, in the known inverter it is impossible to provide an initial delay in the start of the converter, since the capacitor of the latter is in a discharged state until the supply voltage is applied. Therefore, the start occurs simultaneously with the supply voltage, although in functional equipment it is often necessary to start the inverter with a time delay relative to the supply voltage.

The purpose of the invention is to extend the functionality of the inverter.

The goal is achieved by the fact that in an inverter containing a transformer, the power winding of which is connected by an average lead to one of the input leads, and the extreme leads to the collectors of two power transistors, the emitters of which are combined and connected to the midpoint of a resistive voltage divider connected to the input terminals, while the base of the power transistors are connected to the extreme terminals of the positive feedback winding, as well as a chain of successors

but included a capacitor and a resistive charge current sensor, the middle lead of which is connected to the middle feedback winding lead directly or through an additionally introduced capacitor, while the resistance lead of the chain is connected to the middle lead of the power winding, and the capacitor lead to the second input lead, In addition, an additional resistive voltage divider was introduced, connected to the middle feedback winding terminal.

FIG. 1-3 shows the variants of the circuit diagrams of the proposed inverter.

The inverter contains a transformer 1 with a power winding 2, an output 3 and a positive feedback winding 4, the extreme terminals of which are connected to the bases of the power transistors 5 and b, a resistive voltage divider 7, 8 connected to the input terminals, the midpoint of which is connected to emitters transistors, but a sequential chain of capacitor 9 and resistive sensor 10 of charge current, the middle point of this chain is connected to the middle output of the feedback winding directly or through an additional capacitor 11, its resistor The input is connected to the middle terminal of the power winding and the capacitor input to the second input terminal, as well as an additional resistive voltage divider 12, 13 connected to the input terminals, and to the middle point the feedback winding.

The inverter works as follows. At the moment the power supply voltage is applied to the resistive sensor 10, and, consequently, the full voltage of the power supply is applied to the midpoint of the feedback winding 4, the input voltage of the inverter is reduced at the same time due to the divider 7, 8. As a result, the inverter is inhibited mode. As the capacitor 9 charges, the voltage drop across resistive sensor 10 also decreases at the moment it reaches Ufi, o U (j + U9f; current flows in the base circuit of one or both transistors. Asymmetry of transistor currents and positive feedback leads to the avalanche-like unlocking of one of the transistors and active locking of the other transistor, i.e. the inverter switches to the voltage conversion mode,

Thus, the transition of the inverter to the conversion mode does not occur at the moment when the supply voltage is applied, but with a time delay. The delay time is regulated over a wide range by varying the capacitance of the capacitor 9 and the resistance of the resistive sensor 10.

By connecting to the output winding 3 different actuators, you can

make switching electrical circuits with a given time delay.

The introduction to the circuit (Fig. 2) of the second capacitor 11 provides a discontinuous voltage conversion mode with an initial time delay.

The operation of the circuit shown in FIG. 2, prior to transition to voltage conversion mode, does not differ from that described above. After the excitation of the oscillations, the newly introduced capacitor 11 is charged through the resistive sensor 10. When the voltage across the capacitor reaches a certain value, the generation stops. As the capacitor discharges due to leakage currents or a discharge resistor, the voltage across the capacitor decreases and the power supply current flows through the base-emitter junction of the transistors, which leads to the resumption of oscillations. Capacitor 11 is charged, oscillations are broken, etc.

The introduction of an additional resistive voltage divider 12, 13 (Fig. 3) provides a short-term conversion mode followed by a transition to the inhibited mode. In this case, the operation of the device is similar to that of the inverter (Fig. 2), however, after the conversion mode, a decelerated mode occurs, which is provided by a constant voltage divider 12, 13.

The proposed inverter allows to expand the field of application of devices of this type, to avoid the use of additional devices (for example, a time relay), to simplify and unify a number of automation schemes and impulse technology using transistor inverters.

Claims (4)

1. An inverter containing a transformer, the power winding of which is connected by an average lead to one of the input leads, and the extreme leads to the collectors of two power transistors, the emitters of which are combined and connected to the midpoint of a resistive voltage divider connected to the input leads, while the base power transistors are connected to the extreme terminals of the positive feedback winding, as well as a chain of series-connected capacitors and a resistive charge current sensor, characterized in that, in order to extension functionality, said series circuit of a capacitor and a resistive sensor charge current and its mean output associated with an average output feedback winding connection directly connected to a terminal of the resistive midpoint of the power winding and the capacitor - to the second input terminal. 2. The inverter according to Claim 1, characterized in that the middle terminal of said series circuit is connected with the middle terminal of the feedback winding through the additionally introduced capacitor. 3. Inverter on PP. 1 and 2, characterized in that the additionally introduced resistive divider connected to the input terminals, with its middle point is connected to the middle terminal of the feedback winding. Sources of information taken into account in the examination 1. US Patent No. 3348119, cl. 321-2, 1969. 2. US patent number 3453520, cl. 321-2, 1972. 3. The UK patent number 994808, cl. H 2 F, 1973. 4. USSR author's certificate in certificate No. 2774593 / 24-07, cl. H 02 M 7/537, 04.06.79. 4-0 - about & // H .four fO -Fig .2 13 Fig.Z to