DE3405785A1 - Free-running flyback-converter switched-mode power supply - Google Patents

Abstract

The invention is based on a refinement of a flyback converter switched-mode power supply as is described in DE-OS 3,032,034. The object is to increase the starting speed of the flyback converter. According to the invention, the known flyback-converter switched-mode power supply is accordingly modified in such a manner that the two half cycles supplied by the full-wave rectifier to which the AC supply network is applied are made use of for the switching-on supply of the control circuit of the switched-mode power supply. In the case of the known refinements, only the one half cycle is used. Furthermore, as a comparison between Fig. 1 (prior art) and Fig. 2 (preferred refinement of the invention) shows, the invention can be implemented without any additional cost in terms of switching means. <IMAGE>

Description

Free-swinging flyback converter switch-mode power supply

The invention relates to a free-running flyback switched-mode power supply for supplying an electrical device in which the primary winding of a transformer in series with the section of a switching transistor that carries the current to be switched to the rectification of the AC mains voltage using a full-wave rectifier applied DC voltage and a secondary winding of the transformer to Power supply of the electrical device is provided, in which the control electrode of the switching transistor is controlled by the output of a control circuit which in turn by the rectified AC mains voltage as the actual value and by a predetermined setpoint is applied.

A free-running flyback switched-mode power supply is preferred configured that a start-up circuit for further control of the switching transistor is provided.

In addition, the control circuit is constructed so that its power supply is given by means of a further secondary winding of the transformer, which in turn a circuit part serving to generate the control voltage with a downstream one Control amplifier and furthermore a circuit part serving for pulse processing contains, both the output of the control amplifier and the output of the Pulse processing system at one input each of the control electrode of the switching transistor acting on and the output of the control circuit forming the pulse duration modulator is placed, which is also acted upon by a current-voltage converter. These Design, e.g. in DE patent application P 33 40 138.1 (VPA 83 P 1874) or in the patent application P 33 36 442.2 (VPA 83 P 1834) is described also preferably used in the case of the invention.

As is well known, a switched-mode power supply of the type defined above has the task of an electrical device, e.g. a television receiver, with stabilized and regulated To supply operating voltages. The core of such a switching power supply is therefore given by a control circuit, the actuator of which by the aforementioned and in particular switching transistor implemented by a bipolar power transistor given is. There is also a high operating frequency and an extremely high operating frequency Aligned transformer provided, as there is generally a high degree of isolation of the electrical device to be supplied from the supply network is desired.

In the case of self-oscillating or freely oscillating flyback converter switched-mode power supply units it is important if an acceleration of the transient process can be achieved, because experience has shown that the switch-on process in such flyback converters is used for many applications, e.g. television sets, takes place relatively slowly, which leads to operational disruptions can. It is therefore desirable for an acceleration that can be achieved in a simple manner of the switch-on process is made available. This task deals the present invention.

To solve this problem, according to the invention, a freely oscillating one is used Switching power supply of the definition given at the beginning with regard to the connection of the Control circuit designed with the full-wave rectifier circuit in such a way that all Half-waves resulting from the rectification to act on the control circuit are used.

With the usual design of a full-wave rectifier as a Graetz circuit is in a free-swinging flyback converter switch-mode power supply, e.g. also in the DE-OS 30 32 034 (VPA 80 P 1135) shown the emitter of the Schalttranstors with the Cathode of one pair of the four circuit forming Diodes and on its collector via the primary winding of the transformer with the Cathode of the other pair connected while the other two nodes between the four diodes of the Graetz circuit each to one of the two through the AC power supply connections of the switched-mode power supply are located. One input connection is also connected to the anode of another diode connected, the cathode of which to act on the control circuit, in particular below Mediation of a limiting resistor is used. This type of connection now causes only one half sine wave of the supplied from the alternating current network Supply voltage is involved in the startup of the flyback converter switched-mode power supply. Of the Start-up of the switched-mode power supply is therefore also half-wave, so that the The energy required to start the freely oscillating flyback converter is only delayed reaches the control circuit.

This disadvantage becomes apparent in an embodiment corresponding to the invention avoided, as due to the utilization of the two half-waves of the rectified AC voltage of the energy required for the flyback converter to start build up considerably faster than with the previous free-running flyback converters leaves.

This fact is now described with reference to Figures 1 and 2, wherein in Fig. 1 the previous embodiment and in Fig. 2 the preferred embodiment according to the invention is shown.

In both cases the actuator is used as the output of the control circuit RS acts, an npn power transistor is used, with its emitter-collector path in series with the primary winding Wp one provided with several secondary windings Transformer Tr is switched.

The emitter-collector path of the transistor T is from from bridged by a capacitor Cs. The power transistor T is through at its base the output part of the control circuit RS controlled, which is preferably controlled by a pulse duration modulator PDM is given.

An auxiliary winding WH of the transformer Tr, which in the case of the two Figures visible configuration is given by a secondary winding, is used as a sensor for the control circuit RS and is therefore one end to the im In connection with the full-wave rectifier Gr, the base point potential still to be defined and at the other end to the input to which the sensor is to act Control circuit RS.

The control circuit RS consists of those shown in the two drawings Case from the control transistor T at its base and as a pulse duration modulator trained: circuit part PDM and two by the mentioned auxiliary winding WH (i.e. the sensor) controlled input part. One input part RSE is used for Control voltage generation and outputs a control signal via a control amplifier Ru UA for the pulse duration modulator PDM abt The other input part IAB is used for pulse processing and supplies a signal UN to the output part PDM of the control circuit RS. In the end a current-voltage converter SSW is also provided, which controls the actual value of the Control circuit RS forms and the primary current 1p of the primary winding Wp proportional Sends voltage UIP to the pulse duration modulator PDM.

The electrical device to be supplied by the flyback switched-mode power supply RL is mediated via the actual secondary winding Wß of the transformer Tr another rectifier circuit GL is supplied. Need more details here in the present case, however, not to be discussed.

The AC mains voltage is applied to the two supply terminals 1 and 2 of a full-wave rectifier, i.e. a Graetz circuit Gr, placed its output terminal 3 supplies the potential Up used to act on the primary winding Wp, while the base point potential is made available at the other output terminal 4 is.

Between the two output terminals 3 and 4 of the full-wave rectifier The series connection of the primary winding of the transformer Tr is thus Gr of the winding Wp, with the emitter-collector path bridged by the capacitor Cs of the switching transistor T. In addition, the two output terminals 3 and 4 are via a Smoothing capacitor CN connected to each other.

The usual connection of the full-wave rectifier Gr to the power supply SV of the control circuit RS is shown in Fig.1, while Fig. 2 of the invention is equivalent to. In both cases there is another secondary winding Wt of the transformer Tr provided, which at one end with the base point potential (i.e. the output terminal 4 of the full wave rectifier) is connected, while its second connection to the The anode of a diode DB, the cathode of which is connected to the power supply SV on the one hand Control circuit RS connected and on the other hand via a capacitor C3 with the Base point potential, that is to say the output 4 of the rectifier Gr, is connected.

In the present Fig. 1 (and. Also Fig. 1 of DE-OS 30 32 034 (VPA 80 P 1135)) corresponding circuit is now the one input terminal, E.g. terminal 2 of the rectifier Gr at the anode of another diode DA, whose Cathode through a resistor RA to the cathode of said diode DB and thus is connected to the input of the power supply SV of the control circuit RS.

The further secondary winding Wt of the transformer Tr U now takes over in the circuit shown in FIG in steady operation The power supply of the control circuit RS via the diode DB. This is what the cathode is for connected to the power supply of the control circuit. The capacitor CB takes care of that Smoothing of the positive half-wave pulses and works during the start-up time as energy storage.

The diode DA now forms together with the resistor RA in cooperation with the diode DB and the secondary winding Wt a start-up circuit. After turning on of the switched-mode power supply build up at the collector of the switching transistor T and at the input the power supply SV of the control circuit RS DC voltages as a function of time from the given time constants. The positive half sine waves load the Capacity CB via the starting diode DA and the associated starting resistor RA in Dependence on the time constant RAOCB, as described in detail in DE-OS 30 32 034 can be removed. In the present case, it is sufficient to point out that that the diode DA together with the resistor RA, the capacitor CB, the diode DB and the transformer winding Wt performs the function of a starting circuit.

In the embodiment according to the invention according to FIG you now have the following features: a) Between output terminal 3 of the full-wave rectifier Gr and from the current-carrying path of the switching transistor T and the primary winding Wp of the transformer Tr existing series connection, a diode D5 is provided, which with its cathode at one connection point of the series circuit (in the drawing Example case on the winding W) and with its anode on the said output terminal me 3 lies. In addition, the cathode of the diode D5 is connected to one pole of the (also in Fig. 1) smoothing capacitor CN, the other pole of which with the base point potential (i.e. the output terminal 4) is connected.

b) The output terminal 3 of the Grätz circuit Gr is also via a Resistor RS to the cathode connected to the further secondary winding Wt and Diodew already provided in Fig. 1, connected. Since the connection of the diode DB via the capacitor CB to the base point potential and to the input of the power supply SV is unchanged compared to FIG. 1, is therefore in the circuit according to FIG. 2 and thus, according to the invention, the anode of the diode D5 not only directly at the output 3 of the Grätz circuit Gr but also via the resistor on the power supply SV of the control circuit RS, at the cathode of the diode DB and via the capacitor CB at the base point potential.

It has now been shown that the combination of the diode D5, des Resistor R5, the capacitor i, the diode DB and the secondary winding Wt also the function of a start-up circuit is guaranteed and that the in Fig. 1 The illustrated combination of the starting diode DA with the resistor RA is superfluous. It is therefore not included in the circuit shown in FIG.

In addition, it can be seen immediately that in contrast to the known embodiment According to FIG. 1, both half-waves of the supply voltage supplied by the Grätz circuit Gr Influence the power supply SV of the control circuit RS, so that the invention solves the task at hand in a simple way.

Finally, it should be noted that the embodiment described Control circuit is particularly advantageous, but that it is also through another known design is replaceable.

2 Figures 3 claims

Claims (3)

Patent claims Freely oscillating flyback converter switched-mode power supply for Supplying an electrical device in which the primary winding of a transformer in series with the section of a switching transistor that carries the current to be switched to the rectification of the AC mains voltage using a full-wave rectifier applied DC voltage and a secondary winding of the transformer to Power supply of the electrical device is provided, in which the control electrode of the switching transistor is controlled by the output of a control circuit which in turn through the rectified AC mains voltage as the actual value and through a predetermined setpoint is applied, characterized in that the connection the control circuit (RS) with the full-wave rectifier circuit (Gr) designed in this way is that all half-waves resulting from the rectification are applied the control circuit (RS) can be used. 2.) Device according to claim 1, characterized in that between one output terminal (3) of the full-wave rectifier (Gr) and the series connection from the primary winding (W) of the transformer (Tr) and the current-carrying path of the switching transistor (.?) A diode (D5) is provided in such a way that it connects to its Cathode on the series circuit (W, T) and also via a capacitor p (CN) to the one supplied by the other output terminal (4) of the full wave rectifier (Gr) Base point potential lies, while its anode is both directly connected to the output terminal (3) of the full wave rectifier (Gr) and connected via a resistor (R5) on the one hand to the input for the power supply (SV) of the control circuit (RS) and on the other hand via this resistor to the cathode of another diode (DB) connected and connected to the base point potential via a further capacitor (CB) is placed, and that finally the anode of the further diode (£>) via an additional Secondary winding (Wt) is at the base point potential. 3.) Device according to claim 2, characterized in that the only one Connection between the input terminals (1,2) and the power supply (SV) of the control circuit (RS) leads via the diodes that form the full-wave rectifier (Gr).