RU217251U1 - Externally Excited High Frequency Inverter - Google Patents

Abstract

The utility model relates to the field of electrical engineering and can be used in high-power pulse voltage converters for powering various radio engineering devices. EFFECT: increased output power and reliability of a high-frequency inverter with external excitation by turning on the power bipolar transistor in one arm only after the power bipolar transistor in the opposite arm is completely turned off. The high-frequency inverter with external excitation is controlled by an external master oscillator with two anti-phase outputs, and consists of two power bipolar transistors, in the collector circuits of which current transformers and primary windings of the output transformer are connected, the connection point of the primary windings is connected to the positive terminal of the power source. The device also contains two electronic switches connected in the control circuit of power bipolar transistors in parallel to the base-emitter transitions to create an automatic delay in their switching on until the power bipolar transistor is turned off in the opposite arm of the high-frequency inverter with external excitation. 8 ill.

Description

The utility model relates to the field of electrical engineering and can be used in high-power pulse voltage converters for powering various radio engineering devices.

A known device is a push-pull power amplifier (Power sources for electronic equipment: Handbook / G.S. Naivelt, K.B. Mazel, C.I. Khusainov and others; Edited by G.S. Naivelt. - M .: Radio and communication , 1986, pp. 364-365, Fig. 9.12), containing an inverter with input and output transformers and two bipolar transistors operating in the key mode, the secondary winding of the input transformer is made with a tap from the middle, from each half of which antiphase control signals are fed to the bases of bipolar transistors, to the collectors of which the outputs of the primary winding of the output transformer are connected, the middle terminal of which is connected to the positive terminal of the power source, the secondary winding of the output transformer is made with a tap from the middle and forms a full-wave rectifier with a midpoint with two diodes, the output of which is connected to the LC input -filter with a load resistor at its output.

However, the known device of a push-pull power amplifier is characterized by low reliability, since the control circuit does not provide the necessary time delay during the switching of transistors, which leads to a short-term increase in current consumption from the power source at the moment of switching, that is, at the moment of the open state of both transistors, an increase in the dissipated power their power, and, as a result, to a decrease in efficiency and reliability.

Known converter =12V/~220V (Journal "Radioconstructor", 1999, No. 5, p. 27), containing an inverter on bipolar transistors operating in key mode, and controlled from a master oscillator on a logic chip. The outputs of the primary winding of the output transformer are connected to the collectors of the output bipolar transistors, the middle output of which is connected to the positive output of the power source.

However, this converter is characterized by low reliability, since its control circuit does not provide a time delay during the switching of transistors, which leads to a short-term increase in current consumption from the power source at the moment of switching, that is, at the moment of the open state of both transistors, an increase in the power dissipated by them, and, as a result, to decrease in efficiency and reliability.

A voltage converter is known (A.S. USSR No. 760352, IPC H02M 7/515, publ. 08/30/1980, Bull. No. 24), containing a master oscillator and a power amplifier connected to it through a transformer, assembled on two transistors in a push-pull circuit, the base of each of the transistors is connected to the collector of the transistor of the opposite arm through a chain formed by a capacitor and one diode connected in series, to the common connection point of which the cathode of another diode is connected, the anode of which is connected to the connection point of the emitters of these transistors.

The disadvantage of this voltage converter is insufficiently high reliability, since the duration of the time delay during the switching of transistors depends on the capacitance of the capacitors, which leads, in case of a difference in the capacitance of the capacitors, to an unequal open state of the transistors, which leads to magnetization of the magnetic circuit of the output transformer and a decrease in the reliability of the converter.

Closest to the claimed utility model is a high-frequency inverter with external excitation (Romash E.M., Drabovich D.I., Yurchenko N.N., Shevchenko P.N. High-frequency transistor converters. - M .: Radio and communication, 1988, pp. 121-122, Fig. 4.23), consisting of a master oscillator, an input transformer containing two output windings connected at one end to the bases of bipolar transistors operating in the key mode, and at the other end through the windings of a saturating transformer and resistors - to the emitters of bipolar transistors. The second ends of the output windings of the input transformer are also connected to the emitters of bipolar transistors through chains consisting of a series-connected diode and resistor. The feedback windings of the power transformer are connected through diodes to the base-emitter junctions of bipolar transistors. The outputs of the primary windings of the output transformer are connected to the collectors of the output bipolar transistors, the connection point of which is connected to the positive output of the power source. In this high-frequency inverter with an external, the opening delay of bipolar transistors is implemented using a saturable transformer.

The disadvantage of this high-frequency inverter with external excitation is the insufficient accuracy of determining the moment of complete blocking of its transistors, which is mainly determined by the parameters of the saturable transformer, the characteristics of the magnetic circuit of which are subject to increased requirements due to the presence of a large spread in the magnetic characteristics of the magnetic circuit, and which determines the turn-on delay time of the opposite transistor. arms of a high-frequency inverter, and the feedback windings practically do not contribute to tracking the state of the transistor due to a smooth decrease in voltage across them in the process of turning off the transistor.

The task to be solved by the claimed utility model is to develop a high-frequency inverter with external excitation, which provides an automatic delay in the opening of power bipolar transistors in one arm only after the power bipolar transistors in the other arm of the high-frequency inverter with external excitation are completely turned off.

EFFECT: increased reliability of a high-frequency inverter with external excitation by increasing the accuracy of controlling the moment of complete blocking of the power bipolar transistor in the opposite arm of the high-frequency inverter with external excitation.

The technical result is achieved due to the fact that in a high-frequency inverter with external excitation, containing a master oscillator, two power bipolar transistors, the emitters of which are connected to the negative terminal of the power source, two resistors connected between the first and second outputs of the master oscillator and the bases of power bipolar transistors, output transformer with two primary and secondary windings, the connection point of the primary windings is connected to the positive terminal of the power source, while two current transformers are additionally connected between the collectors of power bipolar transistors and the terminals of the primary windings of the output transformer, two electronic switches connected in parallel with the base-emitter transitions of power bipolar transistors, control inputs of electronic switches are connected to the outputs of current transformers of the opposite arm of the high-frequency inverter with external excitation.

The essence of the proposed technical solution lies in the fact that the high-frequency inverter with external excitation additionally contains two transistor switches connected between the base and the emitter of power bipolar transistors, and controlled by current transformers included in the collector circuits of power bipolar transistors of the opposite arm of the high-frequency inverter with external excitation than , in contrast to the prototype, the switching on of the power bipolar transistor in one arm is achieved immediately after the power bipolar transistor is completely turned off in the opposite arm of the high-frequency inverter with external excitation.

In FIG. 1 shows a diagram of a high-frequency inverter with external excitation. In FIG. 2 and FIG. 3 shows the timing diagrams of the voltages, respectively, at the first and second outputs of the master oscillator. In FIG. 4 shows a timing diagram of the collector current of the power bipolar transistor 3. FIG. Figure 5 shows a timing diagram of the voltage at the base-emitter junction of a power bipolar transistor 3. Figure 6 shows a timing diagram of the collector current of a power bipolar transistor 9. FIG. 7 shows the timing diagram of the voltage at the base-emitter junction of the power bipolar transistor 9. FIG. 8 is a timing diagram of the output voltage of a high-frequency inverter with external excitation.

A high-frequency inverter with external excitation (Fig. 1) contains a master oscillator 1, on the two outputs of which there are pulse sequences in the form of a meander, phase-shifted one relative to the other by 180 degrees. The first output of the master oscillator 1 through a resistor 2 is connected to the base of the power bipolar transistor 3, the emitter of which is connected to the negative terminal -U of the power source. The primary winding 4 of the output transformer 5 is connected to the collector of the power bipolar transistor 3 through a current transformer 6. An electronic key 7 is connected between the terminals of the base and the emitter of the power bipolar transistor 3. The second output of the master oscillator 1 is connected through a resistor 8 to the base of the power bipolar transistor 9, the emitter of which connected to the negative -U terminal of the power supply. The primary winding 10 of the output transformer 5 is connected to the collector of the power bipolar transistor 9 through a current transformer 11. An electronic switch 12 is connected between the base and emitter terminals of the power bipolar transistor 9. The output of the current transformer 6 is connected to the input of the electronic switch 12, and the output of the current transformer 11 is connected to the input of the electronic key 7. The output transformer 5 has an output winding 12.

High-frequency inverter with external excitation operates as follows. At time t _1, a high voltage level U 1 appears at the first output of the master oscillator ₁ (Fig. 2), a low voltage level U ₂ appears at the second output of the master oscillator 1 (Fig. 3). At time t ₂ (Fig. 4), the collector current of the power bipolar transistor 9 of the high-frequency inverter with external excitation will become close to zero (Fig. 6, time t ₂ ), in this case, the output current of the current transformer 11 will also become close to zero, and the electronic key 7 will close. At this point in time, current begins to flow through resistor 2 into the base of the power bipolar transistor 3, and it opens, and the current from the positive terminal of the +U power source begins to flow through the primary winding 4 of the output transformer 5, through the current transformer 6 and the collector-emitter junction of the power bipolar transistor 3. The output current of the current transformer 6 flows into the electronic key 12 and opens it. Open electronic key 12 shunts the base-emitter junction of the power bipolar transistor 9, preventing it from turning on.

At time t ₃ , a high voltage level U ₂ appears at the second output of the master oscillator 1 (Fig. 3), a low voltage level U 1 appears at the first output of the master oscillator ₁ (Fig. 2). At time t ₄ (Fig. 4), the collector current of the power bipolar transistor 3 of the high-frequency inverter with external excitation will become close to zero, in this case the output current of the current transformer 6 will also become close to zero, and the electronic key 12 will close. At this point in time, the current through the resistor 8 begins to flow into the base of the power bipolar transistor 9, and it opens, and the current from the positive output of the power source +U begins to flow through the primary winding 10 of the output transformer 5, through the current transformer 11 and the collector-emitter junction of the power bipolar transistor 9. The output current of the current transformer 11 flows into the electronic key 7 and opens it. Open electronic key 7 shunts the base-emitter junction of the power bipolar transistor 3, preventing it from turning on.

At time t ₅ (Fig. 2 and Fig. 3) the voltage levels at the first and second outputs of the master oscillator change, and all processes are repeated. During the operation of the power bipolar transistors 3 and 9, the primary windings 4 and 10 are connected in turn to the power source through the collector-emitter junctions of the power bipolar transistors 3 and 9, respectively, and an output alternating voltage _Uout appears on the output winding 13 of the output transformer 5 (Fig. 8 ).

In a high-frequency inverter with external excitation, transistors of the KT825A type (power bipolar transistors 3 and 9) and electronic switches based on transistors of the KT503B type are used.

Thus, the proposed high-frequency inverter with external excitation provides an automatic delay in the opening of power bipolar transistors in each arm only after the power bipolar transistor is turned off in its other arm, which makes it possible to increase the output power and reliability of the high-frequency inverter with external excitation by increasing the accuracy of controlling the moment of switching off transistors .

Claims (1)

A high-frequency inverter with external excitation, containing a master oscillator, two power bipolar transistors, the emitters of which are connected to the negative terminal of the power source, two resistors connected between the first and second outputs of the master oscillator and the bases of power bipolar transistors, an output transformer with two primary and secondary windings, the connection point of the primary windings is connected to the positive output of the power source, characterized in that two current transformers are additionally connected between the collectors of the power bipolar transistors and the outputs of the primary windings of the output transformer, two electronic switches connected in parallel with the base-emitter junctions of the power bipolar transistors, control inputs electronic keys are connected to the outputs of the current transformers of the opposite arm of the high-frequency inverter with external excitation.

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