SU1097985A1 - A.c. voltage stabilizer - Google Patents

Abstract

AC VOLTAGE STABILIZER, containing a booster transformer with two primary windings, the secondary winding of which is connected between the respective input and output pins, a reversing switch for semiconductor P JO 13 I AC switches connected via a bridge circuit, and the diagonal of this bridge is connected to the bridge. and the output diagonal is connected to the first primary winding of the booster transformer, control unit, the inputs connected to the E-pin, which is connected to the input of said bridge diagonal, characterized in that, in order to improve mass-dimensional parameters, increasing the reliability and efficiency, a second primary winding of the transformer Volto extension is included in one of the arms of said bridge. CO h CO 00 ate

Description

The invention is electrical engineering and can be used in the construction of variable voltage stabilizers in cases where higher quality output and input currents are required. An alternating voltage regulator with a voltage boost transformer is known, the secondary winding of which has tapings and is connected to the output and input terminals of the stabilizer via alternating current semiconductor switches J. A disadvantage of the known device is the complexity of the voltage booster transformer and, consequently, poor overall dimensions. The closest to the proposed by means and Achievable result is a voltage regulator containing a booster transformer with two primary windings, the secondary winding of which is connected between the input and output pins, and a reversible KO 4mutator on AC semiconductor switches connected in a bridge circuit moreover, the input diagonal of this bridge is connected to the output of the stabilizer outputs, and the first primary winding of the additional voltage circuit is connected to the output diagonal of the formator, the second primary winding of the booster transformer is connected through an additional semiconductor switch parallel to the first primary winding 2 3. Disadvantages of the known devices are low QDC, the complexity of the volt of the additional transformer having two primary windings, rated nominal supply voltage and a large number of switching elements and, therefore, the presence of a complex control system, which causes poor mass-dimensional stabilizer parameters and viscous reliability. The purpose of the invention is to improve the mass-dimensional parameters, increase reliability and efficiency. The goal is achieved by the fact that in an AC voltage regulator containing a booster transformer with two primary windings, the secondary winding of which is connected between the corresponding input and output terminals, a reverse switch on AC semiconductor switches connected via a bridge circuit, and the diagonal of this bridge connected to the corresponding power terminals, and the output diagonal is connected to the first primary winding of the booster transformer, the control unit , the inputs are connected to the same power terminals to which the input diagonal of the specified bridge is connected, the second primary winding of the booster transformer is included in one of the arms of the specified bridge. The drawing shows a schematic diagram of a stabilizer (one of the variants of a key management scheme). A secondary winding 1 booster transformer is connected between the input and output pins of the stabilizer. The first primary winding 2 booster transformer is connected to the output diagonal of the reversing switch, built on a bridge circuit on semiconductor switches 3-6 AC. The input diagonal of the reversing switch is connected to the input pins 7 of the stabilizer. The second primary winding 8 of the booster transformer is connected to the bridge arm in series with the key 5. The control circuits of the two opposite switch arms, built on keys 3 and 4, are connected in series and connected via diode 9 and a resistor 10 to the output of the nonlinear bridge 11. Nonlinear bridge 11 through the controller A torus on the resistor 12 of the polarity of the output voltage of the nonlinear bridge is connected to the output of the high voltage sensor 13 connected to the input terminals 7 of the stabilizer. The control circuits of the two other jjg opposite switches, built on keys 5 to 6, are also connected in series and connected via Zener diode 14, diode 15 and resistor 16 to the output of nonlinear bridge 11. Conclusions 17 are the outputs of the stabilizer. Capacitor 18 is connected to the rectifier output. The stabilizer works in the following way. The resistors and zener diodes of the nonlinear bridge 11 are selected so that the zener diodes of the nonlinear bridge are pierced at the minimum acceptable voltage at the output of the stabilizers. The adjustment of the moment of the breakdown of the stabilitrons is made by the resistor 12. The zener diode 14 is selected so that its breakdown occurs at the maximum allowed voltage at the output of the stabilizer. When the mains voltage fluctuates within 1x limits, the control circuits of semiconductor switches 3-6 are de-energized, because current flow through control targets keys 3 and 4 is prevented by diode 9, and current flow in control circuits keys 5 and 6 The zener diode 14 is prevented. In this case, the primary windings 2 and 8 are de-energized and the secondary winding 1 of the booster transformer does not affect the voltage at the stabilizer output, since the voltage drop on this winding is insignificant. When the voltage at the output of the stabilizer decreases to the minimum allowable value, the zener diodes of the nonlinear bridge are locked. At the same time, the polarity of the voltage at points 19 and 20 of the nonlinear bridge changes and further reduces the voltage of the mains under the influence of this voltage across the circuit: point 20 of the nonlinear bridge 11, resistor 10, diode 9, control circuit of semiconductor switches 4 and 3, point 19 of the non-linear bridge, the switches 3 and 4 of the switch open. At the same time, the supply voltage is applied to the first primary winding 2 of the booster transformer, and a voltage is applied to the secondary winding 1, which is added to the supply voltage, and the output voltage of the stabilizer is restored to its nominal value. When the supply voltage rises to the nominal value, the polarity of the voltage at points 19 and 20 of the nonlinear bridge returns to its original state. In this case, the control circuits of the keys 3 and 4 are de-energized and the winding 2 is disconnected from the supply voltage. By increasing the voltage at the output of the stabilizer to the maximum allowable value, the voltage at points 19 and 20 of the nonlinear bridge becomes sufficient for the breakdown of the zener diode 14. Therefore, with a further increase in the supply voltage under the influence of this voltage along the circuit: point 19 of the nonlinear bridge 11, the circuit controlling the keys 5 and b, the zener diode 14, the diode 15, the resistor 16, the point 20 of the nonlinear bridge, the keys 5 and 6 of the switch open. In this case, the supply voltage is applied to the first primary winding 2 of a booster transformer with a phase shift of 180 and on its secondary. The winding 1 is induced with a voltage that is subtracted from the supply voltage and the voltage at the output of the stabilizer is restored to its nominal value. In this case, when unlocking the key 5 in series with the first primary winding 2, the winding 8 of the booster transformer is turned on, which provides the normal current through the secondary winding of the booster transformer with an increased supply voltage. The invention allows to improve the mass-dimensional indicators of the stabilizer, increase the efficiency, simplify the control circuit and increase its reliability.

Claims (1)

AC VOLTAGE STABILIZER, comprising a boost booster transformer with two primary windings, the secondary winding of which is connected between the corresponding input and output terminals, a reversing switch on AC semiconductor switches connected in a bridge circuit, the input diagonal of this bridge being connected to the corresponding power terminals, and the output diagonal connected to the first primary winding of the boost booster transformer, the control unit, the inputs connected to the power terminals, which is connected input diagonal of said bridge, characterized in that, in order to improve mass-dimensional parameters, to improve reliability and efficiency of the second booster transformer primary winding is included in one of the arms of said bridge.