SU993414A1 - Single-phase inverter - Google Patents

Description

(5) SINGLE PHASE INVERTER

one. ...

The invention relates to converter equipment and is intended for use in electrical and radio installations for various purposes.

Inverters on controlled valves are known, which contain a switching capacitance, saturating reactors connected in series to the anode circuits of the valves, and damping chains SP.

The closest to the present invention is a single-phase inverter containing a transformer, the primary winding of which is sectional and connected by an average output to a positive input terminal, and the ends to cut-off diodes, in series with each of which a thyristor is connected, the cathodes of the latter being combined and through a choke connected a negative input terminal connected through diodes to the point of connection of sections of the transformer primary winding, the secondary winding of which is connected to the output terminals, connection points between the diodes with thyristors included commutating capacitor and the additional winding of the transformer C 2.

Claims (2)

Placing an additional secondary winding on the common magnetic system of the main transformer is effective only to accelerate the unlocking of the thyristors during the period of the charge of the switching capacitor, but adversely affects the reverse process of locking the thyristors during the period of its discharge. This is due to the fact that the additional winding shunts the capacitor at the time of discharge to the thyristors and in the res1 (Tata this significantly reduces the load of 20 thyranor capacitors on it, which does not ensure reliable operation of the inverter, especially at maximum loads. 3 "Effect of the bias component direct current and magnetic flux from the discharge current of the capacitor and the throttle on the magnetic flux of the transformer core causes a magnetic oversaturation of its system with nonlinear magnetic processes. This in turn means This method is to simplify and improve the output voltage shape. To achieve this goal, the inverter containing the main transformer, the middle output of which is connected to the positive input voltage. the output, the ends of the specified winding through the thyristors to the negative input terminal, and the secondary winding is connected to the output terminals, and a transformer is connected between the anodes of the thyristors and the winding connected to the switching capacitor, as the transformer winding, the primary winding of the inserted additional transformer is used, the half windings of which are connected in series and connected by a common point through the switching capacitor with a negative input terminal, and the secondary winding is connected consistently with the secondary winding main transformer torus. FIG. 1 is a schematic diagram of an inverter; in fig. 2 - time diagrams of the circuit operation. A single-phase inverter has a main transformer 1, on the core of which secondary winding 2 is located and primary winding 3 which is made sectional and middle output is connected to the positive input terminal, and ends to thyristors 4 and 5, the cathodes of which are combined and connected to the negative input terminal. Moreover, the control circuits in the phase of the thyristor A and 5 are shifted by 180 ° (not shown). At the points of connection of thyristors 4 and 5, an additional transformer 6 is connected with the secondary winding 7 and the primary winding consisting of two half windings 8 and 9. connected by a common point through the switching capacitor 10 to the negative input terminal. The secondary winding 2 of the main transformer 1 and the secondary winding 7 of the additional transformer 6 are interconnected according to — in series, and the cores of the mentioned transformers can be made, for example, of ferrite rods. Single-phase inverter works as follows. When voltage is applied to the middle positive input terminal of the primary winding 3 of the main transformer 1 (Fig. 1), a current pulse passes through the left section of the primary winding 3 of transformer 1 and left section 8 of transformer 6 and to the output of switching capacitor 10. At the initial moment of passage of a pulse current is the saturation of the magnetic system of the transformer 6. FIG. 2, curve 11 shows a single spreading impulse with a flat front and a vertical rear linear front, which means the end of saturation of the transformer 6 core. After that, the potential on the capacitor 10 increases (FIG. 2, curve 12) and opens at the same time the thyristor, which for the entire half-period of charge and discharge of the switching capacitor 10 remains open and only when the potential on the capacitor 10 is equal to the potential of the left semi-winding 8, is zero, the thyristor k abruptly the thyristor 5 is closed and opens, which was locked by the negative potential of the right half winding 9 of the transformer 6. In the second half period, a current pulse passes through the right section of the primary winding 3 of the main transformer 1, through the right half winding, of the additional transformer 6 to the switching capacitor 10. When the magnetic system of the transformer is saturated 6 from the passage of the current pulse along the right half winding 9, at the end of the left half winding 8, a negative potential is formed which keeps the tiris in the locked state Op 4 on all the pulse transit time of the second half cycle. FIG. 2, curve 11 shows the second pulse with a rectangular leading edge and a flat falling front Uynp. 5 By & saturation of the core of the transformer 6, the potential builds up on the capacitor 10. In FIG. 2, curve 12 shows the second half-cycle of charge and discharge of a 10 U capacitor (in the reverse direction of the current pulse. As the potential on the capacitor 10 increases, thyristor 5 opens abruptly and remains open until the capacitor 10 is fully discharged and the transformer core is demagnetized. ., In Fig. 2, curve 11 shows a sloping falling edge of the second pulse in the reverse direction of the current pulse in the secondary windings 2 and 7 of the main and auxiliary transformers 1 and 6, taking into account the transformation ratio An output alternating voltage Ug, rectangular in shape, which is shown in Fig. 2, curve 13, includes saturation curve 11 of the magnetic system of the transformer 6, and charge and discharge curve 12 of the comicating capacitor 10 is increased. the addition in the secondary windings 2 and 7 of the main current pulse and the remagnetizing pulse of the core of the transformer 6, which, with its primary winding consisting of half-windings 8 and 9, is a spare protective load for the main transformer 1, and k.z. output secondary windings 2 and 7. Formula of Invention A single-phase inverter containing a main transformer, the middle output of the primary winding of which is connected to the positive input terminal, the ends of the specified winding through the thyristors to the negative input terminal, and the secondary winding connected to the output terminals, and between the anodes of the thyristors A transformer winding connected to a switching capacitor is included, characterized in that, in order to simplify and improve the shape of the output voltage curve, as a transformer The primary winding of the introduced additional transformer is used in the rmator winding, the half windings of which are connected in series and are connected by a common point through a switching capacitor to the negative input terminal, and the secondary winding is connected according to - in series with the secondary winding of the main transformer. Sources of information taken into account during the examination 1. USSR author's certificate № 1в02 5, cl. H 02 M 7A8, 1965. 2. USSR author's certificate number 782101, cl. And 02 M 7/515, 1979. I z .ЛЗГД 1 ... V, A. iJgnp