DE2505642C3 - Voltage converter device - Google Patents

Description

The invention relates to a voltage converter device having a transformer with a primary winding and a secondary winding, the primary winding being converted into a first winding half and divided into a second winding half and by a switching device alternately with an input DC voltage to the first winding half or to the second winding half a predetermined frequency is applied by a clock and an output circuit with the Secondary winding is connected, which provides an output voltage when the device is working, with a Sampling circuit, which is based on value differences in the current, in the first and in the second half of the winding generated currents that are generated by the alternating application of the input DC voltage in the Winding halves are created, and with a compensation device, which is connected to said scanning circuits and when operating the device the switch-on time during which said input DC voltage is applied to one half of the winding is controlled so that a decrease in the mentioned difference in value is caused

Voltage converter devices of the aforementioned type are used in DC-DC voltage conversion. In such an application, the output circuitry may include rectifiers and filters so that the AC voltage signals from the Transformer secondary winding can be converted into DC voltage signals. Such DC-DC converters are suitable for generating low DC voltages, e.g. B. in the On the order of a few volts, for integrated circuits. The DC output voltage of such Converters can be regulated by using feedback signals derived from the DC output voltage can be derived, so that in each case the switching time for applying the input DC voltage the primary winding half is determined.

From DE-OS 2062 294 such a device is already known in which the from an astable Multivibrator as a clock controlled positive and negative half-waves for current balancing in the Transformer can be changed in opposite directions in time, by appropriately controlling the duty cycle of the astable multivibrator. In this known device, it is disadvantageous that the Time setting range of the compensation device for current balancing extends over the entire Pulse duration extends although relatively small changes are required.

The object of the invention is, in a voltage converter device of the type mentioned with a simple structure of the compensation device To increase the setting and thus control accuracy for the balancing.

This object is achieved according to the invention in that the compensation device has two monostable Contains flip-flops and an element which is the time constant of one of these monostable flip-flops is co-determined and controlled as a function of the mentioned value differences, and that the two monostable multivibrator and one bistable multivibrator are controlled by the clock and the output of a monostable multivibrator and a first output of the bistable multivibrator a first AND gate and the output of the other monostable multivibrator and a second, inverse to the first output Output of the bistable multivibrator are fed to a second AND gate, the outputs of the specify the switch-on time mentioned above for both AND gates.

From US-PS 30 27 508 a similar device is known, but in which no current sensing circuit and compensation device is available. This device is also from Clock controlled a bistable multivibrator and a device for delivering pulses of controllable duration and the output of the last-mentioned device and a first output of the bistable multivibrator one first AND gate and also the output of the aforementioned device and a second, to the first Output inverse output of the bistable multivibrator is fed to a second AND element, the The outputs of the two AND gates specify the switch-on time. In this known voltage converter device However, as already mentioned, no current balancing is provided. Rather, the

Duration of the impulses emitted by the device in Controlled as a function of the output voltage for the purpose of regulating it

The advantage of the arrangement according to the invention is that the time setting range for the Current balancing is smaller than the total pulse duration, since the end of the pulse is that of the monostable Flip-flops delivered pulses the respective beginning of the duty cycle of the primary winding halves of the Transformer determined, but not the pulses of the monostable multivibrator are equal to the duty cycle This results in increased setting and control accuracy

An embodiment of the invention is described below with reference to a drawing. In the The drawing shows a voltage converter device according to the invention

In the figure, a rectifier and filter 1 is shown directly with a nominal AC voltage of 117 volts which is applied as input voltage to terminal 50. At the output of the rectifier 1 an unregulated direct voltage of 150 volts is created The voltage applied to terminal 50 is also applied directly to an internal power supply unit 2 it contains the necessary circuitry for energizing and biasing the control circuits in the Voltage converter device.

The 150 volt DC voltage is applied to the midpoint tap the primary winding of a high-frequency switching transformer 3 applied by alternating Turning on the transistors 4 and 5, i; n same rhythm currents through the associated Winding halves of the primary winding of the transformer 3 formed The switching frequency with which the two Transistors are operated is in the ultrasonic range, i. H. for example at 20 kHz to get a high To achieve current with a low voltage in the secondary winding of the transformer 3. That over the The signal generated by the secondary winding of the transformer 3 is passed through the power rectifiers 6 and 7 fed to a full wave rectification and by means of a serially connected coil 8 and one in the shunt path lying capacitor 9 filtered, so that between the output terminals 10 and 11 a Nominal DC voltage of 5 volts is created. Terminal 11 can be connected to ground.

In practice, the power switching transistors 4 and 5 consist of a large number of transistors connected in parallel, the number of which depends on the occurring Amperage is determined. The performance monitor transistor 4 is controlled by a driver stage 12, which is controlled by a pulse from an AND gate 13. The AND gate 13 delivers in each case a pulse if the respective switching conditions, d. H. simultaneous presence of a predetermined logical level at its inputs. In the same way, the Power switching transistor 5 effective through a driver stage 14, which in turn is controlled by an AND gate 15 is controlled, which also emits a pulse when its switching conditions are met

As can be seen from the drawing, each of the AND gates 13 and 15 has four inputs, of which two are connected to each other. Conventional safety circuits, such as the Safety circuits shown in block form are linked and generated via internal OR circles an output signal which is applied to one of the two AND gates 13 and 15, if none abnormal condition, d. H. Overtemperature, excessive input voltage, The output voltage is exceeded, there is no bias voltage, etc. Thus is during normal operation at the inputs of the AND gates 13 and 15, which with the Safety circuit 16 are connected, a "condition signal" and in the presence of an abnormal Situation a »important condition signal«, which prevents the AND gates 13 and 15 so long no impulses to driver stages 12 and 14 until the abnormal situation is resolved

A pair of resistors 17 and 18 are in the emitter current paths of the power switching transistors 4 and 5 arranged. These resistors each have a low resistance value and enable a high current flow rate, e.g. B. 0.1 Ohm and 10 Watt Die The basic function of the resistors 17 and 18 is described below in connection with the voltage equalization regulation described. However, they also serve as short-circuit detectors in order to generate a dynamic Form overcurrent protection for the power switching transistors 4 and 5. The voltage on the emitter electrodes of the power switching transistors shows the level of the respective current through the corresponding resistors 17 and 18 on. These voltages are applied to threshold comparison circuits 19 and 20, at the outputs of each a signal occurs when the current through the resistor 17 or 18 or exceeds a predetermined value by both resistors These signals are an OR gate 21 forwarded

The output of the OR gate 21 is connected to the reset input of a flip-flop 34 which its "1" output is connected to one input of the AND gates 13 and 14 each. If now a Overcurrent occurs, a signal is generated at the output of the OR gate 21, which the flip-flop 34 resets, so that the AND gates 13 and 15 remain blocked and thus the control of the switching transistors 4 and 5 affect.

The basic clock cycle for the system is derived from a 40 kHz clock generator 36, which can consist of a simple tilting oscillator. The output signals of the clock generator 36 are fed to the clock input of a JK flip-flop 35, by which the frequency is divided so that a 20 kHz square wave form is produced at the Q output and an inverse wave form at the ^ output. The Q and ^ output of the flip-flop 35 is each connected to a separate input of the AND gates 13 and 15.

The normal voltage regulation is carried out by sending a synchronization signal from the clock generator 36 is applied to the voltage regulator 22, which also receives a voltage signal from the Output terminal 10 receives In response to the synchronization pulse and after a delay period which is directly related to the voltage level is at the output terminal 10, the voltage regulator 22 generates a pulse, the monostable Multivibrators 23 and 24 is fed so that an operation cycle is triggered in each of them.

To provide an electrical isolation reference point between To generate the output and the control circuit in the power supply, it is advantageous from the photocoupling technology to make use of the voltage regulator 22. This allows the Synchronize! ion impulse dem Voltage regulator 22 as an increasing function over

each side of the high frequency switch transformer 3 currents flowing.

However, it is not appropriate to feed the aforementioned signals directly to the differential amplifier 31, rather, an integration of several hundred cycles should be carried out, since that is more desirable As an instantaneous response, the signals are therefore low pass filters 32 and 33 in which a corresponding processing takes place before they are sent to the inputs of the differential amplifier 13 can be forwarded. The individual modules are selected and dimensioned so that the Differential amplifier 31 does not detect any differences at its input terminals, the resistor networks, in which the resistor 28 and the resistor 29 and the transistor 30 are arranged, a total of approximately correspond to the value of the resistor 25, the delay of the monostable multivibrators 23 and 24 is about the same

However, if a certain divergence trend is noticeable, e.g. B. an increase in the current the switching transistor 5, which is detected by an increase in voltage at its emitter, is effected by this Trend an increase in the voltage at the output of the low-pass filter 33, which is connected to the corresponding input of the differential amplifier 31 is connected the resulting at the output of the differential amplifier 31 Signal becomes more positive than normal, causing the resistance of transistor 30 to rise, whereby the time constant of the monostable multivibrator 24 is correspondingly larger. This has the effect that the pulse width determines the duty cycle the pulses in the AND gate 15, which are fed to the switching transistor 5 as driver pulses, is slightly decreased. -

This causes a reduction in the current flow through the switching transistor 5 and the corresponding Primary winding half of the high-frequency switching transformer 3 back to a balanced state.

On the other hand, if there is a deviation in the direction of a higher current through the power switching transistor 4 an increase in the voltage at its emitter electrode is determined after processing in the low-pass filter 32 in the differential amplifier 31 causes a decrease, i.e. a more negative voltage at its output whereby the resistance of the transistor 30 and thus the total resistance in the time constant of the monostable multivibrator 24 is reduced. Thus, the AND gate 15 is able to conduct what a little earlier causes an increase in the width of the drive pulses for the switching transistor 5, whereby the current through the Primary winding halves of the high-frequency switching transformer 3 is brought back into balance.

a light emitting diode or a photosensitive diode can be supplied. In the same way the moment, moreover, the increasing function can set a predetermined reference level in the voltage regulator 22 generates the monostable via a light-emitting diode or a photosensitive diode Multivibrators 23 and 24 are fed.

The output pulses of the voltage regulator 22 are also applied to the set input of the flip-flop 34 fed, whereby the flip-flop a suitable logic level that AND gate 13 or 15 that is connected to the "1" output. The above was done during normal surgery the flip-flop 34 by a clock pulse, which is applied to its reset input for temporary activation the AND gates! 3 and 15 was applied. So if not an abnormal condition the AND element 13 is then able to become conductive when the monostable multivibrator 23 has expired and at the Q output of the flip-flop 35 a high level is present. In the same way, the AND gate 15 can only be conductive when the monostable multivibrator 24 has expired and the ^ ■ output of the flip-flop 35 is in its high State. Since each of the AND gates 13 and 15, if it was conductive, then blocked when the The next clock pulse resets the flip-flop 34, the driver period of the corresponding one extends Switching transistor 4 or 5 from the time of the corresponding monostable multivibrator 23 or 24 expires until the next clock pulse occurs, so that the voltage regulation in carried out in the manner previously described.

The delay of the monostable multivibrator 23 is constant and depends on the values of the Resistor 25 and the capacitor 26. The monostable multivibrator 24 is also with a fixed time capacitor 27 is provided. However, the value of the resistance of this multivibrator stage depends of the total value of a resistor 28 and a parallel connected to this with a transistor 30 in Series lying resistor 29. This creates a variable resistance value which is effective becoming value of the transistor 30 is determined by the output signal of the differential amplifier 31, the The different inputs on the differential amplifier 31 are derived from the emitter electrode of the power transistor 4 and the emitter electrode of the Power transistor 5. These low voltage level signals are unc 18 generated and thus represent the value of the

1 sheet of drawings

Claims (1)

Claim: Voltage converter device with a transformer with a primary winding and a secondary winding, the primary winding being divided into a first winding half and a second winding half by S a center tap and a switching device alternating an input DC voltage to the first winding half or to the second winding half with a clock predetermined frequency is applied and an output circuit is connected to the secondary winding, which provides an output voltage when the device is working, with a sampling circuit that responds to differences in the value of the instantaneous currents generated in the first and second winding halves caused by the alternating application of the DC input voltage arise in the winding halves, and with a compensation device which is connected to the above-mentioned sampling circuits and, when the device is working, the switch-on period during which said on DC input voltage is applied to one winding half, controls in such a way that a reduction of the mentioned value difference is brought about, characterized in that the compensation device contains two monostable multivibrators (23, 24) and an element (transistor 30) which determines the time constant of one (24) this monostable multivibrator (23, 24) is determined and controlled as a function of the mentioned value differences, and that the two monostable multivibrators (23,24) and a bistable multivibrator (35) are controlled by the clock (36) and the output of one monostable flip-flop (23) and a first output (Q) of the bistable flip-flop (35) a first AND element (13) and the output of the other monostable flip-flop (24) and a second output (Q) of the bistable that is inverse to the first output Flip-flop (35) are fed to a second AND element (15), the outputs of the two AND elements (13, 15) specifying the above-mentioned switch-on time. 45