RU77516U1 - VOLTAGE TRANSFORMER - Google Patents

Abstract

The utility model relates to power electronics, in particular to secondary sources of electrical power from a rectified network or from autonomous DC voltage sources using DC to DC conversion, and can be used to create DC voltage sources. The objective of the utility model is to increase the efficiency of monitors due to the use of inductive voltage surge energy on the first winding of the transformer. The essence of the utility model is that in the voltage converter, which includes a transformer with at least two windings and a key, a control circuit, the output of which is connected to the control terminal of the key, the first and second diodes, the first and second capacitors, in which the first terminal of the first transformer winding it is designed to supply a constant voltage of positive polarity to it, the second terminal of the first transformer winding is connected to the first terminal of the switch, the second terminal of the switch is intended to supply constant voltage to it negative polarity, the first terminal of the second transformer winding is connected to the anode of the first diode, the cathode of which is connected to the first terminal of the first capacitor, the first terminal of the key is connected to the anode of the second diode, the cathode of which is connected to the first terminal of the second capacitor, the second terminal of the second transformer winding is connected to the cathode the second diode, the second terminal of the first capacitor is connected to the second terminal of the second capacitor and is designed to supply a constant voltage of negative polarity to it. 1 Fig.

Description

The utility model relates to power electronics, in particular to secondary sources of electrical power from a rectified network or from autonomous DC voltage sources using DC to DC conversion, and can be used to create DC voltage sources.

Known DC-DC converter (DC) with intermediate conversion of direct current energy into alternating current energy [1], including a generator powered by a constant voltage source, a transformer with two windings, the first of which is the load of the generator, the key to turn on and off the power generator, key control unit, connected in series circuit to the second winding of the transformer, rectifier bridge, charging inductor, storage capacitor.

When the voltage at the storage capacitor is less than the specified value, the control unit turns on the key, the generator generates a pulsed alternating voltage on the first winding of the transformer. The pulsed alternating current from the second winding of the transformer is rectified by a rectifier bridge and begins to charge the storage capacitor through the inductor. The key control unit turns off the key when the set maximum charge current of the storage capacitor is reached and turns on the key when the set minimum charge current of the storage capacitor is reached. In this case, the voltage on the storage capacitor is cyclically increased to the set value.

At the moment of closing the key on the first winding of the transformer, an inductive voltage surge occurs, associated with both inductance

windings, so with spurious parameters, and which can damage the key and the first winding of the transformer.

Measures to protect the key and the first winding of the transformer from voltage surges were taken in PN [2], which is the closest in technical essence and the achieved result and selected as a prototype.

The PN contains a transformer with three windings W ₁ , W ₂ , W ₃ and a key that serves to close and open the circuit of the first winding W _{1 of the} transformer, a control circuit whose output is connected through a resistor to the control terminal of the key.

In this case, the first terminal of the first winding W _{1 of the} transformer is designed to supply a constant voltage of positive polarity to it from the rectifier, the second terminal of the first winding W _{1 of the} transformer is connected to the first terminal of the switch, and the second terminal of the switch is designed to supply it with a constant voltage of negative polarity.

The PN also has first and second diodes, first and second capacitors.

In the described circuit, the first terminal of the second winding W _{2 of the} transformer is connected to the anode of the first diode, the cathode of which is connected to the first terminal of the first capacitor.

To protect the first winding _of transformer W ₁ from overvoltage when the key is opened, a chain is introduced in which the first output of the key is connected to the anode of the second diode, the cathode of which is connected to the first output of the second capacitor, and the second output of the latter is used to supply a constant voltage of positive polarity to it from the rectifier .

The transformer windings W ₁ and W ₂ are connected in such a way that the inductive voltage pulses on said windings have the same polarity at the "beginnings" of the windings (the first terminal of the first transformer winding W1 and the second terminal of the second transformer winding W ₂ ) and the opposite (polarity to the beginnings of the "transformer windings) polarity at the" ends "of the transformer windings (second

the output of the first winding W1 of the transformer and the first output of the second winding W _{2 of the} transformer). This means that when a voltage pulse of positive polarity appears on the first output of the first transformer winding, then an inductive voltage pulse of positive polarity also appears on the second output of the second transformer winding W ₂ .

A control circuit on a microcircuit containing a resistor-capacitor circuit provides a PN operating frequency of about 25 kHz.

PN operates from a rectified DC voltage source.

During the first part of the operating period, the control circuit opens the key. In the first winding W _{1 of the} transformer current flows, increasing with time. The voltage pulse at the first terminal of the first winding W1 of the transformer has a positive polarity. Due to the previously indicated connection diagram of the transformer windings, the voltage pulse at the second terminal of the second transformer winding W ₂ also has a positive polarity, and at the first terminal of the second transformer winding W _{2, the} voltage pulse has a negative polarity and is applied in the opposite direction to the first diode, at which time the first the diode is in a closed state.

In the next part of the operating period, the key management circuit on the chip closes the key. At this moment, the polarity of the voltage pulse at the terminals of the windings W ₁ and W _{2 of the} transformer, due to the phenomenon of self-induction, is reversed. The first diode opens, the current of the second winding W _{2 of the} transformer charges the first capacitor.

At the moment the key is closed, an inductive positive voltage surge occurs at the second terminal of the first winding W1 of the transformer, associated with both the winding inductance and the stray parameters. At the moment when the current value of the voltage of this surge is greater than the voltage on the second capacitor, the second diode opens, and the energy of the inductive voltage surge flows into the second capacitor.

Thus, the first transformer winding W ₁ and the switch are protected against large inductive voltage surges.

Subsequently, the second capacitor is discharged through a resistor. It can be seen that the circuit from the second diode and the second capacitor is an additional load on the transformer, and the energy of inductive voltage surge is uselessly lost.

The objective of the utility model is to increase the efficiency of monitors due to the use of inductive voltage surge energy on the first winding of the transformer.

The essence of the utility model is that in the voltage converter, which includes a transformer with at least two windings and a key, a control circuit, the output of which is connected to the control terminal of the key, the first and second diodes, the first and second capacitors, in which the first terminal of the first transformer winding it is designed to supply a constant voltage of positive polarity to it, the second terminal of the first transformer winding is connected to the first terminal of the switch, the second terminal of the switch is intended to supply constant voltage to it negative polarity, the first terminal of the second winding of the transformer is connected to the anode of the first diode, the cathode of which is connected to the first terminal of the first capacitor, the first terminal of the key is connected to the anode of the second diode, the cathode of which is connected to the first terminal of the second capacitor, in contrast to the prototype, the second terminal of the second the transformer windings are connected to the cathode of the second diode, the second terminal of the first capacitor is connected to the second terminal of the second capacitor and is designed to supply a constant voltage to it negatively oh polarity.

The connection of the second terminal of the second winding of the transformer with the cathode of the second diode and the connection of the second terminal of the first capacitor with the second terminal of the second capacitor, designed to supply a constant voltage of negative polarity to it, allows, firstly, to charge the second capacitor to the voltage of the power supply PN at that

the time when the key is closed, secondly, charge the second capacitor to the inductive surge voltage at the time of closing the key, thirdly, since the voltage of the charged second capacitor is applied to the first diode in the forward direction, and the discharge circuit of the second capacitor to the first capacitor is closed, charge the first capacitor with the inductive discharge energy stored in the second capacitor, which leads to an increase in the efficiency of the inverter.

The utility model is illustrated in the drawing.

The figure shows the electrical circuit of the PN.

The PN includes a transformer 1 with two windings W ₁ and W ₂ , a key 2, implemented on a field transistor KP750A, and a control circuit 3, the output of which is connected to the control terminal of the key 2. The first terminal of the first winding W _{1 of the} transformer 1 is connected to a voltage terminal of positive polarity DC voltage source (not shown in the figure). The second terminal of the first winding W _{1 of the} transformer 1 is connected to the first terminal of the switch 2, the second terminal of the switch 2 is connected to the voltage terminal of negative polarity of the DC voltage source.

In the circuit of the second winding W _{2 of the} transformer 1, the second winding W _{2 of the} transformer 1, the first diode 4, which uses the RHRD4120 diode, the first and second capacitors 5 and 6, respectively, are connected in series. As the first capacitor 5, the capacitor K75-40V-750V-10 μF ± 10% - V is used, as the second capacitor 6 is K73-16-250V-0.47 μF ± 10% - V. In this case, the first output of the second winding W _{2 of the} transformer 1 is connected to the anode of the first diode 4, the cathode of which is connected to the first terminal of the first capacitor 5. The second terminal of the first capacitor 5 is connected to the second terminal of the second capacitor 6 and to the voltage terminal of negative polarity of the DC voltage source.

The protection circuit of the first winding W _{1 of the} transformer 1 from inductive emissions includes a second diode 7, which is used as a diode

RHRD4120, and the second capacitor 6. In this case, the first output of the key 2 is connected to the anode of the second diode 7, to the cathode of which the first output of the second capacitor 6 is connected.

The windings W ₁ and W _{2 of the} transformer 1 are connected in a circuit so that the inductive voltage pulses on the mentioned windings have the same polarity at the "beginnings" of the windings (the first terminal of the first winding W1 of the transformer 1 and the second terminal of the second winding W _{2 of the} transformer 1) and the opposite and the same polarity at the "ends" of the transformer 1 windings (the second terminal of the first winding W1 of the transformer 1 and the first terminal of the second winding W _{2 of the} transformer 1). This means that when a voltage pulse of positive polarity appears on the first output of the first winding of transformer 1, then an inductive voltage pulse of positive polarity also appears on the second output of the second winding W _{2 of} transformer 1.

The control circuit 3 is assembled on 564TL1 and 1401CA1 microcircuits and has an output connected to the control output of the key 2. The control circuit 3 performs the following functions:

- provides periodic (with a frequency in the range from 20 to 30 kHz) supply of pulses for opening and closing the key 2 until the voltage on the first capacitor 5 is less than the voltage specified by the control circuit 3;

- provides closing of the key 2, as soon as the voltage on the first capacitor 5 becomes equal to the voltage specified by the control circuit 3.

The implementation of the control circuit 3 may be different and using different elements.

PN works as follows.

As long as the voltage across the first capacitor 5 is equal to the voltage set by the control circuit 3, the control circuit 3 keeps the key 2 closed. At this time, the second capacitor 6 is charged to voltage

the power source through the first winding W _{1 of the} transformer 1 and the second diode 7, and the first diode 4 is closed by reverse voltage on the first capacitor 5.

As soon as the voltage on the first capacitor 5 becomes less than that specified by the control circuit 3, the control circuit 3 begins to send periodic pulses of opening and closing of the key 2 to the control output of the key 2 with a certain frequency.

During the first part of the operating period, the control circuit 3 keeps the key 2 open. In the first winding W _{1 of the} transformer 1, a current flows linearly increasing with time. At this time, the transformer 1 accumulates energy.

The voltage pulse at the first terminal of the first winding W1 of the transformer 1 has a positive polarity. Due to the previously indicated connection diagram of the transformer 1 windings, the voltage pulse at the second terminal of the second winding W _{2 of the} transformer 1 also has a positive polarity, and at the first terminal of the second winding W _{2 of the} transformer 1 has a negative polarity and is applied in the opposite direction to the first diode 4, and this while this diode is in the closed state. The current in the second winding W _{2 of the} transformer 1 does not flow at this time, the capacitor 5 is discharged to the load.

During the second part of the operating period, the control circuit 3 closes the key 2. At this moment, the polarity of the voltage pulse at the terminals of the windings W ₁ and W _{2 of the} transformer 1, due to the phenomenon of self-induction, is reversed. At the first output of the second winding W _{2 of} transformer 1, the voltage pulse has a positive polarity and is applied in the forward direction to the first diode 4. The first diode 4 opens, current flows in the second winding W _{2 of the} transformer 1, and the energy stored in the transformer 1 is transferred to the capacitor 5 and charges it.

At the moment of closing the key 2 on the second terminal of the first winding W _{1 of the} transformer 1, an inductive positive surge occurs

voltage associated with both the inductance of the winding and spurious parameters. At the moment when the current voltage value of this voltage surge becomes larger than the voltage across the capacitor 6, the second diode 7 opens, and the inductive voltage surge energy is transferred to the capacitor 6, charging it. After the end of the voltage surge, the indicated energy stored in the capacitor 6 is transmitted through the second winding W _{2 of the} transformer 1 and through the first diode 4 to the capacitor 5. In this case, the capacitor 5 is recharged with inductive emission energy.

The control circuit 3 provides in the frequency mode a periodic supply of pulses of opening and closing the key 2 until the voltage on the first capacitor 5 is less than the voltage specified by the control circuit 3. The control circuit 3 provides the closure of the key 2 as soon as the voltage on the first capacitor 5 becomes equal voltage set by control circuit 3.

Thus, the energy of the inductive voltage surge on the first winding W _{1 of the} transformer 1 PN transfers to the capacitor 5, and from it to the load, and due to this, the efficiency of the PN increases.

Information sources.

1 Shmelev K.D., Korolev G.V. Laser power supplies. - M. Energoizdat, 1981. - P.77, 79.

2 Semenov B.Yu. Power electronics: from simple to complex. - M. SOLON-PRESS, 2006. - S.312-320. - The prototype.

Claims (1)

A voltage converter comprising a transformer with at least two windings, a key, a control circuit, the output of which is connected to the control terminal of the key, the first and second diodes, the first and second capacitors, while the first terminal of the first winding of the transformer is designed to supply a constant voltage of positive polarity to it , the second terminal of the first transformer winding is connected to the first terminal of the switch, the second terminal of the switch is designed to supply a constant voltage of negative polarity to it, the first terminal is the transformer winding is connected to the anode of the first diode, the cathode of which is connected to the first terminal of the first capacitor, the first key terminal is connected to the anode of the second diode, the cathode of which is connected to the first terminal of the second capacitor, characterized in that the second terminal of the second transformer winding is connected to the cathode of the second diode , the second terminal of the first capacitor is connected to the second terminal of the second capacitor and is designed to supply a constant voltage of negative polarity to it.