DE3027754A1 - Pulse generator controls transistor to regulate power - has comparator controlling third transistor in primary circuit of transformer - Google Patents

Abstract

The pulse generator has a third transistor (T3) in series between the dc supply (UB) and one end of a transformer's (Tr) primary winding. A second transistor (T2) is in series between the dc supply and the other end of the primary. The transformer's secondary winding controls the power transistor (T1). A fourth transistor (T4) acts as a comparator and compares a reference voltage (Uo) (applied to its base) with the voltage appearing at the emitter of the second transistor (applied to its emitter). The comparator output (collector of transistor) is applied via a resistor to the base of the third transistor.

Description

Circuit arrangement for pulse control of the basis of a line

Stungstransistors, especially for switching regulators The invention relates a circuit arrangement for pulse control of the base of a power transistor especially for switching regulators.

In some electronic circuits, e.g. in switching regulators, there is the need to periodically turn a power switching transistor on and off. The control circuit of the base of such a transistor should have the required value the current to be supplied to the base when the transistor is switched on, as well as the possibility of rapid discharge of excess loads from the base ensure when switching off.

A circuit for pulse control of the base is known, which is shown in simplified form is shown in Fig. 1 (Mullard Technical Information No. 19, "TDA 2640 control IC for switched mode power supplies" Fig. 22). In this circuit is the base-emitter path of a power transistor T1 with the Secondary winding a control transformer Tr connected, the primary winding of the transformer from a DC voltage source connected in series with a control transistor T2 UB is fed. The base of the control transistor T2 is with signals with periodic Rectangular shape scanned, with the duty cycle £, which is equal to the ratio of the required Conduction time of the controlled power transistor to the duty cycle T is adjustable can be.

When the control transistor T2 is energized, the energy of the decreases magnetic flux in the core of the control transformer Tr to. Remains in this state the power transistor T1 blocked. At the moment of switching off the control transistor T2 arises in the secondary winding of the transformer Tr a current, which over the Base-emitter path of the controlled power transistor T1 flows. The value of the Base current is unique to the value in the primary winding at the moment of switching off of the control transistor T2 linked current flowing. As a result of the energy transfer from the transformer Tr to the base-emitter path takes the one stored in the core Energy. In the next period, the energy is replenished in the core in the current-carrying state of the control transistor T2, and a new one takes place Control of the base-emitter path of the power transistor T1, while the control transistor T2 is turned off again.

A disadvantage of the circuit described is that the Base-emitter path of the power transistor controlling current in the secondary winding greatly both on the value of the supply voltage on the primary side of the control transformer as well as the duty cycle & is dependent.

In certain applications, the dependency of the base current of the power transistor T1 of the duty cycle g decrease, if a correspondingly sized and with a block capacitor Cb decoupled limiting resistor R is connected in series with the 0 primary winding of the transformer Tr.

Such a process can be successful provided that the duty cycle S does not become too large, e.g. g $ 0.6. With this procedure, however, it is it is not possible to make the base current independent of the supply voltage UB. The limiting resistor Ro has power losses result, the entire Reduce the efficiency of the control circuit. An additional disadvantage of the considered Method consists in that the limiting resistor Ro and the blocking capacitor Cb form an integrator, which the response of the control circuit to abrupt Changes in the duty cycle g or the supply voltage UB delayed, resulting in a Deterioration of the dynamic properties of the circuit leads. While the Control circuit works with a low duty cycle g, occurs across the blocking capacitor Cb only a very small voltage. In the case of a sudden transition to a A larger duty cycle value results in a temporary reduction in the base current. The power transistor T1 remains unsaturated for a while, which may be the cause its destruction can be. This is particularly dangerous with power transistors, that work in high voltage circuits. It should be noted that with low duty cycle values because of the small voltage across the blocking capacitor Cb, unfavorable conditions for the turning off of the power transistor T1 arise, which in turn is the cause for possible destruction.

The aim of the invention is to create a circuit arrangement which a regular base control of a power transistor regardless of both Duty cycle value as well as from the supply voltage ensures by a high Efficiency as well as favorable dynamic properties of the circuit ensured will.

The circuit arrangement for pulse control of the base of a power transistor, especially for switching regulators with a Control transformer, whose Secondary winding with the base-emitter path of the controlled power transistor is connected and its primary winding by means of a square wave signal keyed control transistor is periodically connected to the supply voltage, which is provided according to the invention with an additional transistor switch, the on the one hand with the positive pole of the supply voltage, on the other hand with the upper one Connection of the primary winding of the control transformer and its base to the output of a comparator is connected, one of the inputs of the comparator with a a reference voltage source containing internal resistance and the second input is connected to the emitter of the control transistor and to a test resistor, the second connection of which is connected to the negative pole of the supply voltage, by the connection point of the additional transistor switch and the transformer connection connected to the cathodes of a support diode and a blocking diode, while the anode of the support diode to the negative pole of the supply voltage and the The anode of the blocking diode is connected to the first input of the comparator.

The task of the comparator is to control the additional transistor switch to lock after the predetermined current value in the primary winding of the transformer is reached. Therefore one of the inputs of the comparator is with the reference voltage source connected, while the second input through the one occurring across the test resistor Voltage drop is controlled, which is proportional to the current in the primary winding of the transformer. It would be an equivalent solution instead of the test resistor to use a different type of current sensor. The role of the support diode it is the continuity of the current through the primary winding, as well as through the test resistor or by a current sensor of another type, to keep after the additional transistor switch Is blocked. The task of the blocking diode remains, the additional transistor switch until the moment of power interruption in the primary winding in the blocked To hold state, which is achieved as a result of the keying of the control transistor.

One advantage of the control circuit according to the invention is the stabilization of the current in the primary winding. This increases the base current of the controlled power transistor neither on the supply voltage nor on the duty cycle g. The introduction the additional transistor switch instead of the previous limiting resistor eliminates the power loss, and improves the error of the integrator the dynamic properties of the circuit. Another advantage is that the additional transistor switch at the moment of switching on the control transistor has already been brought into the conductive state and the full supply voltage is over the primary winding of the control transformer occurs, what favorable conditions for forms the effective shutdown of the base of the controlled power transistor, even if the circuit works with a low duty cycle OT.

The subject matter of the invention is based on an exemplary embodiment shown in the drawing. In the drawing Fig. 1 shows a known circuit arrangement, FIG. 2 is a block diagram of the control circuit according to the invention, and FIG. 3 is a particularly advantageous practical embodiment of the circuit according to FIG. 2, in which as a comparator a transistor is used that does not need any additional supply voltages.

Those contained in the circuit of FIG. 2, in previously known The components used in circuits are a control transformer Tr, its secondary winding with the base emitter Path of a controlled power transistor T1 is connected and a control transistor T2 gated with a controllable duty cycle g, which is connected in series with the primary winding.

A new component that is essential to the invention is an additional one Transistor switch T3, which is connected to the primary winding of the transformer Tr on the the control transistor T2 opposite side is connected in series. The base of the additional transistor switch T3 is connected to the output of a comparator K. connected, the first input of which with an internal resistance R having Reference voltage source w UO and its second input with one in series with the Control transistor T2 switched test resistor R is connected.

p A support diode D is on the one hand with the connection point the primary winding of the transformer Tr and the additional transistor switch T3 and on the other hand connected to the negative pole of the supply voltage UB. Same The connection point is with the first input of the comparator via a blocking diode Db connected.

The circuit arrangement works as follows: After the control transistor T2 and the additional transistor switch T3 simultaneously in the current-conducting Are brought state, the current flowing through the test resistor Rp increases in the Primary winding of the transformer Tr to. As soon as the occurring across the test resistor R. Voltage drop p exceeds a reference voltage value U0, the changes State at the output of the comparator and the additional transistor switch T3 is locked. As a result, the primary winding of the transformer becomes a fine side separated from the supply voltage UB, whereby the current in the winding is about the support diode D closes. At the same time p causes the blocking diode D a Lowering of the reference voltage b at the input of the comparator K, which leads to the blocking of the Circuit in the non-conductive state of the transistor switch T3 leads.

When the control transistor T2 is switched off, the voltage drops across the test resistor R. As a result, p changes the state at the comparator output and the transistor circuit T3 is turned on. During the control transistor T2 remains non-conductive, the energy stored in the transformer core is converted into the Output base-emitter path of the controlled power transistor T1. After this When the control transistor T2 is switched on, the power transistor T1 is switched off and a new work cycle of energy supplement follows.

In the circuit shown in Fig. 3, the power transistor is T1 connected to the secondary winding of the control transformer Tr similar to FIG. The collector of the n p n control transistor T2 is on the lower terminal of the Primary winding of the transformer Tr switched. The test resistance Rp is between the emitter of the control transistor T2 and the negative pole of the supply voltage UB arranged.

The additional transistor switch T3, designed as a p n p transistor, is with its emitter on the positive pole of the supply voltage UB and with its Collector connected to the upper terminal of the primary winding of the transformer Tr A transistor T4, the emitter of which is connected to the test resistor, acts as a comparator K Rp, and its base is connected to a reference voltage U0. In the considered Embodiment is the reference voltage UO as the voltage drop across the Series connection of two by means of a resistor Rb to the positive pole of the Supply voltage applied, forward-polarized diodes D1 and D2 reached. The base of the transistor T3 is controlled by a voltage divider Rb, Rc, the serves to limit the collector current of transistor T4.

The support diode Dp is between the upper terminal of the primary winding of the transformer Tr and the negative pole of the supply voltage, the blocking diode Db on the other hand between the same transformer connection and the base of the transistor T4 switched. The resistor R is a blocking capacitor in parallel switches.

The effect of the circuit according to FIG. 3 is the same as in connection with Fig. 2, with the exception that turning off the transistor switch T3 occurs at the moment when the voltage across the resistor Rp exceeds the value that of the voltage drop across the base-emitter path of the conductive transistor Tq is less than the reference voltage UO. The capacitor C contributes to high p To achieve current pulses when switching on the control transistor T2, what for that rapid switching off of the power transistor T1 is required.

The characteristic values of the control circuit according to the invention are to be calculated in this way be that at the lowest supply voltage and at the highest duty cycle S max the current in the primary winding of the control transformer in the time interval (1st - d) max) T can reach the predetermined value.

The control according to the invention is based on the return principle a control transformer realized. The control circuit includes one in series additional transistor switch connected to the primary winding of the control transformer T3, which is controlled by the output of a comparator K. The inputs of the comparator is a reference voltage and one proportional to the current in the primary winding Voltage supplied. As soon as the current in the primary winding is a prescribed When the value is reached, the additional transistor switch T3 switches off, whereby the continuity of the current is ensured by a support diode Dp. In this way stabilization of the current in the primary winding is achieved, and as a result the base current of the controlled power transistor is neither dependent on the supply voltage still dependent on the duty cycle.

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Claims (1)

Circuit arrangement for pulse control of the base of a power transistor, In particular for switching regulators Patent claim: Circuit arrangement for pulse control the base of a power transistor, especially for switching regulators, with a control transformer, its secondary winding with the base-emitter path of the controlled power transistor is connected and its primary winding by means of a square wave signal keyed control transistor is periodically connected to the supply voltage, g e k e n n n z e i c h -n e t by an additional transistor switch (T3), the on the one hand with the positive pole of the supply voltage (UB), on the other hand with the upper one Connection of the primary winding of the control transformer (Tr) and its base with the Output of a comparator (K) is connected, one of the inputs of the comparator with a reference voltage source (UO) containing an internal resistance and the second input with the emitter of the control transistor (T2) and with a test resistor (Rp) is connected, its second connection to the negative pole of the supply voltage (UB) is switched by the connection point of the additional transistor switch (T3) and the transformer connection with the cathodes of a support diode (D) and a blocking diode (Db) is connected, p while the anode of the support diode to the negative pole of the supply voltage and the anode of the blocking diode to the first Input of the comparator is switched.