RU142953U1 - DIODE TRANSISTOR BRIDGE - Google Patents

Abstract

1. A diode-transistor bridge containing a diagonal of power, which includes transistors included in the shoulders of the bridge, while in the shoulders of the bridge they do not have a common connection point, a capacitor and an isolation diode, the anode of which is connected to the positive terminal of the power source, while in the diagonal the load is connected in series with a choke and at least one inductor, and an RC circuit is connected in parallel with the choke, characterized in that an observer (computer) of the magnetic flux is introduced into the diode-transistor bridge, input which is connected to the rotor position sensor, and the adder, whose input is connected to the controller supplying the reference signal to the adder, the adder outputs are connected to the bases or transistor gates, while the current sensor and the voltage sensor are connected to the inductor circuit, the outputs of which are connected to the observer inputs (computer) magnetic flux, the output of which is connected to the input of the adder. 2. The diode-transistor bridge according to claim 1, characterized in that in the load diagonal after the inductor, a choke is connected in series to it, in parallel with which an RC circuit is connected.

Description

The utility model relates to electrical engineering, designed to convert DC energy at the input to DC energy at the output with automatic control of the output voltage and can be used in constructive conjugation with magnetic bearings.

Known diode-transistor bridge containing a power diagonal and a load diagonal (patent RU No. 2215357, H02K 7/09), in which a transistor is connected to each diode - collector to the diode cathode, and an emitter to the diode anode.

The disadvantage of the diode-transistor bridge is the dependence of the mass-volume characteristics of the power source on the power consumed by it and the low rate of current rise in the inductor, which depends on the supply voltage of the source.

As the closest analogue, a diode-transistor bridge (RU patent No. 2379816, H02M 3/156) is selected, containing a power diagonal, which includes transistors that are included in the shoulders of the bridge and do not have a common connection point. A capacitor and a separation diode are included in the diagonal of the power supply, the anode of which is connected to the positive terminal of the power source, and the cathode is connected to the cathodes of the two diodes. A choke and at least one inductor are sequentially included in the load diagonal, and an RC circuit of a resistor and capacitor is connected in parallel with the choke. The specified diode-transistor bridge can significantly reduce power consumption due to the reversible use of energy.

The disadvantage of the diode-transistor bridge is the low speed of the inductor (low slew rate), which depends on the parameters of the inductor and the voltage of the power source, and its low reliability.

The technical result of the claimed utility model is to increase the speed of the inductor included in the load diagonal of the diode-transistor bridge when using a power source with a voltage exceeding the self-inductance EMF of the inductor due to the use of means transmitting information about the current flowing in the inductor about the voltage applied to the inductor, and the position of the rotor on the actuator, which when the magnetic flux reaches the desired value reduces the voltage setting on the inductor to the necessary for normal operation of the inductor, which also improves the reliability of its operation.

The technical result is achieved by the fact that in the diode-transistor bridge containing the power diagonal, which includes transistors included in the shoulders of the bridge, while in the bridge shoulders they do not have a common connection point, a capacitor and an isolation diode, the anode of which is connected to the positive terminal of the power source in this case, a choke and at least one inductor are sequentially connected to the load diagonal, moreover, an RC circuit is connected in parallel with the choke, according to a utility model, it is inserted into the diode-transistor bridge at the observer (calculator) of the magnetic flux, the input of which is connected to the rotor position sensor, and the adder, the input of which is connected to the controller supplying the reference signal to the adder, the outputs of the adder are connected to the bases or gates of the transistors, while the current sensor and the sensor are connected to the inductor circuit voltage, the outputs of which are connected to the inputs of the observer (computer) of the magnetic flux, the output of which is connected to the input of the adder.

In a particular case, in the load diagonal of the diode-transistor bridge after the inductance coil, a choke is connected to it in series, in parallel to which an RC circuit is connected.

The essence of the utility model is explained as follows.

The speed of the inductor is determined by the time constant, which depends on the slew rate of the current in the coil, which in turn depends on the magnitude of the source voltage. However, the use of a power source with a voltage that is several times higher than the EMF of self-induction of the inductor can lead to its failure.

Introduction to the diode-transistor bridge of an observer (calculator) of a magnetic flux, the input of which is connected to the rotor position sensor, and an adder, the input of which is connected to a controller supplying a reference signal to the adder, the outputs of the adder are connected to the bases or gates of the transistors, as well as a connection to the circuit the inductance coils of the current sensor, voltage sensor, the outputs of which are connected to the inputs of the observer of the magnetic flux, the output of which is connected to the input of the adder, made it possible to use a power source with a voltage that Only once higher than the EMF of self-induction of the inductor, which led to an increase in the speed of the coil, it allowed to reduce the voltage applied to the inductor when the current reached the operating value, and thereby limit the current flowing through the coil.

In addition, the limitation of current and voltage flowing through the inductor, prevented the coil from malfunctioning, which led to increased reliability of the coil.

The inclusion in the diagonal of the load after the inductor in series with the inductor and in parallel with it the RC-circuit eliminated overvoltage on the second transistor, which led to increased reliability of the diode-transistor bridge.

Thus, the proposed utility model allows forcing the diode-transistor bridge with reverse energy use.

The essence of the utility model is illustrated by the diode-transistor bridge circuit shown in figure 1.

The diode-transistor bridge contains a power diagonal and a load diagonal. The diagonal of the power supply includes four diodes 1, 2, 3, 4, two transistors 5, 6, connected to the shoulders of the bridge, a capacitor 7, and, through a diode diode 8, a power source whose voltage is several times higher than the self-inductance EMF of the inductor. The anode of the separation diode 8 is connected to the positive terminal of the power source, and its cathode is connected to the cathodes of the two diodes 1, 3. In this case, the separation diode 8 provides the minimum direction of energy from the power source and prevents transistors 5 and 6 from failing if the polarity of the power source is inadvertently changed . In addition, the separation diode 8 prevents the flow of EMF current through the power source.

A choke 9, an inductor 10, whose voltage is several times lower than the supply voltage, a choke 11, is sequentially included in the load diagonal. The capacitor 7 is selected from the condition of the inductance of the coil 10 to ensure resonance at the frequency of a pulse-width modulator (not shown in the diagram) with parallel connection. In parallel to the inductor 9, an RC circuit 12 is connected, and parallel to the inductor 11, an RC circuit 13 is included. Each RC circuit 12, 13 consists of resistors 14, 15 and capacitors 16, 17.

A current sensor 18, a voltage sensor 19 are connected to the circuit of the inductor 10. In this case, an observer (calculator) of the magnetic flux 20 is introduced into the diode-transistor bridge, the input of which is connected to the rotor position sensor 21 (not shown in the diagram), and the adder 22. Outputs a current sensor 18, a voltage sensor 19 and a position sensor 21 are connected to the inputs of the observer of the magnetic flux 20, the output of which is connected to the adder 22, and the outputs of the adder are connected to the bases or gates (depending on the type of transistor) of the transistors 5, 6.

The diode-transistor bridge operates as follows.

When you turn on the power source and there is no reference signal at the input of the adder 22, the capacitor 7 is charged through the isolation diode 8 to the voltage of the power source. When the reference signal arrives at the adder 22, a positive pulse with a predetermined duration is generated at the output of the adder 22, which goes to transistors 5 and 6. Transistors 5 and 6 open, the load diagonal of the bridge is connected to capacitor 7. Capacitor 7 is discharged through transistor 5, chokes 9 and 11, the inductor 10 and the transistor 6. In this case, the RC circuit 12 and 13 limit the overvoltage on the transistors 5 and 6.

At the initial moment of time, an EMF of self-induction appears in the inductor 10, which counteracts the increase in current in it. The self-induction current flows through the circuit: inductor 9, diode 1, capacitor 7, diode 4, inductor 11. But since the supply voltage of the source is several times higher than the self-induction EMF, the time constant of the inductor 10 decreases several times. For example, to reduce the time constant of the inductor by 100 times with a self-induction EMF of 3 V, a power source with a voltage of 300 V was used.

When the current in the inductor 10 reaches the set value, the magnetic flux observer 20 and the adder 22 limit the current flowing through the inductor 17. This is as follows. The current sensor 18, the voltage sensor 19 and the position sensor 21 transmit their signals to the magnetic flux observer 20. Based on the signals of the sensors 18, 19 and 21, the magnetic flux observer 20 calculates the magnetic flux value in the inductor 10 and transmits a signal corresponding to the calculated magnetic flux value , to the adder 22. The adder 22 also receives a reference signal from the controller (not shown in the diagram). In the adder 22, the reference signal is summed with the signal from the observer of the magnetic flux 20 and the control of the pulse-width modulator, which is part of the adder 22, is formed. The control pulses from the adder 22 are fed to the gates of the transistors 5 and 6. With a steady current, there is no EMF.

At the end of the control pulse from the adder 22, the transistors 5 and 6 are closed. In this case, there is a sharp decrease in the current flowing through the chokes 9 and 11, and the inductor 10. This leads to the emergence of EMF self-induction inductor 10, which tends to hold a decreasing current in the circuit. The self-induction current flows through the circuit: the positive component of the current is the inductor 10, inductor 11, diode 3, the positive lining of the capacitor 7; the negative component of the current is the inductor 10, inductor 9, diode 2, the negative lining of the capacitor 7. The self-induction EMF tends to restore the voltage on the capacitor 7, which decreased in the absence of control pulses. With the subsequent appearance of the control pulse from the adder 22, the process is repeated.

When a voltage occurs on the capacitor 7 below the voltage of the power source, an isolation diode 8 opens and the capacitor 7 is additionally charged from the power source. In operation, the inductor 10 and the capacitor 7 form an oscillatory circuit in which the energy of the electric field accumulated by the capacitor 7 is converted into the magnetic field energy of the inductor 10 and vice versa. In this case, the direction of the current in the inductor 10 does not change.

Thus, the introduction into the diode-transistor bridge of the magnetic flux observer associated with the rotor position sensor and an adder, the outputs of which are connected to the transistors, as well as the connection of a current sensor, a voltage sensor, transmitting their signals to the magnetic flux observer, the value of the magnetic flux in the inductor and transmitting the calculated value of the magnetic flux to the adder, which, when the magnetic flux reaches the required value, reduces the voltage reference on coil until required for its normal operation, can improve performance of the inductor due to the possibility to use a power source with a voltage several times greater than the self-induction EMF coils, and to limit the current flowing through the coil, preventing it from failure.

Claims (2)

1. A diode-transistor bridge containing a diagonal of power, which includes transistors included in the shoulders of the bridge, while in the shoulders of the bridge they do not have a common connection point, a capacitor and an isolation diode, the anode of which is connected to the positive terminal of the power source, while in the diagonal the load is connected in series with a choke and at least one inductor, and an RC circuit is connected in parallel with the choke, characterized in that an observer (computer) of the magnetic flux is introduced into the diode-transistor bridge, input which is connected to the rotor position sensor, and the adder, whose input is connected to the controller supplying the reference signal to the adder, the adder outputs are connected to the bases or gates of transistors, while a current sensor and a voltage sensor are connected to the inductor circuit, the outputs of which are connected to the inputs of the observer (computer) magnetic flux, the output of which is connected to the input of the adder. 2. The diode-transistor bridge according to claim 1, characterized in that a choke is connected in series to the load diagonal after the inductance coil, in parallel with which an RC circuit is connected.