DE3544955C2 - - Google Patents

Description

The invention relates to a power supply unit with the features the preamble of claim 1.

Such a power supply can be used in a wide variety of applications Apparatus are used, for example in connection with Televisions, typewriters and teleprinters.

Such devices have the major changes Mains voltage a reasonably satisfactory performance ability, but also relatively high stress fluctuations can be absorbed.  

A power supply with the features from the preamble of Claim 1 is in the Japanese patent publication JP 54-1 48 222 from Patents Abstracts of Japan Sect: E, Vol 4, No. 8, 1980 (E-166). Details about the exact structure and mode of operation of this Known device circuits are this Document cannot be removed.

EP 24 523 B1 describes a single-ended flow converter for Generation of galvanically isolated DC output voltages described, which has a transformer with a Primary winding and one or more secondary windings. In the primary circuit of the transformer is a first one Voltage chopper switched on and in the secondary circuit are a second voltage chopper and a smoothing circuit and a control device switched on. Through the Regulating device is the smoothed voltage of the Secondary circuit of the transformer with a reference voltage compared and a difference signal is formed, and the second voltage chopper is dependent on that Differential signal and the voltage pulses at the Secondary winding of the transformer controlled. The one and Switching off the second voltage chopper is done with this known circuit of different control circuits from over two different windings of a control transfer controlled tragers. Furthermore, in this publication pointed out that from DE-C3-26 08 167 a through flux converter is known, in which shutdown signals for one arranged in the secondary circuit of the transformer Shutdown transistor abge from an auxiliary control circuit be conducted, which contains a bistable flip-flop. Here will depend on the great effort of the auxiliary control circuit pointed, among other things, to the bistable flip-flop can be traced.

The known circuit is relatively complex overall  built up and not easily on more than two Secondary circles expandable.

The invention has for its object a power supply that described in the preamble of claim 1 Kind so that with circuitry special simple means good efficiency and high Control accuracy can be achieved and with little technical effort several secondary circuits with a ge regulated voltage are available.

This object is achieved with the Features from the characterizing part of patent claim 1. Advantageous developments of the invention are in the Subclaims described.

The basic idea of the invention is the rule to build device with a flip-flop through which the second voltage chopper is controlled such that he during the rising leading edge of the tension transmits impulse at the secondary winding while he at the times when the output voltages the connections of the load the reference voltage exceeds, locks. It is determined by a certain Ratio of turns between the primary winding and the secondary winding of the transformer that the second voltage chopper each time before first voltage chopper locks and the bistable tipping circuit controls the on state of the second Voltage chopper is delayed, resulting in a significant Loss reduction leads.

The following are embodiments of the invention Power supply unit described in more detail with reference to the drawing. It shows

Figure 1 shows the electrical circuit diagram of a power supply with a single load circuit.

Fig. 2 shows the electrical circuit diagram of a supply device with two load circuits;

Figs. 3A to 3C, the curves of the primary voltage, the primary current and the switching losses of the control transistor for the transformer of the device;

FIGS. 4A to 4C, the representation of FIG. 3 analog curves with a feeding of blocking the secondary transistors, and

Fig. 5A to 5C is analogous to the illustration of FIG. 4 curves but with a delay of the passage state of the secondary transistors.

Referring to FIG. 1, the DC voltage power supply of a load 1 is prepared starting from an alternating voltage of a network 2 facts available. The device comprises an insulating high-frequency transformer 3 - for example designed for 30 kHz - with high mutual induction, low leakage inductance and equipped with primary and secondary windings 4 and 5 of the same polarity. The primary winding 4 of the transformer 3 is connected to the output of a conventional diode rectifier bridge 6 , the input of which is connected to the network 2 .

The rectified voltage of the network 2 is applied to the primary winding 4 of the transformer and chopped by means of a fixed frequency oscillator 7 which controls a switching transistor 8 with a fixed conduction ratio via the base. This transistor 8 is connected in series with the primary winding 4 . The voltage rectified by the bridge 6 is filtered by a capacitor 9 .

The secondary winding 5 of the transformer 3 is connected to the load 1 with the interposition of a chopper switch 10 and a smoothing circuit 11 lying in series. The smoothing circuit 11 contains an induction coil 12 lying in series with the switch 10 , which is connected between a capacitor 13 and a protective diode 14 , which is referred to as "freewheeling" and which bridges the secondary winding 5 and the switch 10 in series, such that that only the discharge current of the capacitor 13 is passed in parallel to the load 1 when the switch 10 is open. In parallel to the load 1 , a voltage divider consisting of the resistors 15 and 16 is connected with predetermined values in order to branch off a part of the DC output voltage and to compare it with a reference voltage V _ref in a comparator 17 which is connected to one of its inputs, namely the negative part the output voltage and at its other input, the positive, receives the reference voltage V _ref . The output of the comparator 17 is connected to the zero reset input 18 of a bistable multivibrator 19 whose input 20 is connected to the input of the switch 10 and whose output 21 controls the switching of the switch 10 . The voltage divider 15 , 16 , the comparator 17 and the flip-flop 19 form a control loop. During the rising leading edge of voltage pulses at the connections of the secondary winding 5 of the transformer 3 , that is to say the pulses which are generated by the chopper transistor 8 of the primary winding 4 , the flip-flop 19 changes its state in order to close the switch 10 before again causing a change in state to control the opening of the switch 10 as soon as the branched part of the output voltage at the terminals of the load 1 exceeds the reference voltage V _ref .

According to FIG. 2, the chopper function of the switch is preferably ensured by a pnp transistor 10 . So that this transistor 10 is not damaged or impaired by the negative half-periods of the voltage at the connections of the secondary winding 5 of the transformer 3 , a protective diode 23 is connected in series between the secondary winding 5 and the transistor 10 according to FIG . In the event that the switching function of the load circuit is effected, for example by means of a thyristor, such a protective diode is not required. The closing of the switch corresponds to the on state of the transistor 10 , and the opening of the switch corresponds to the blocking state of the transistor when the not agile energy is transmitted in the coil 12 .

If several loads with different voltages have to be provided, as is the case, for example, with a teletype machine, which contains individual microprocessors, a motor and a printhead, parallel to the secondary winding 5 of the transformer 3, the loads to be supplied are correspondingly many identical Circles that supply different voltages with their control loops. FIG. 2 shows two load circuits with their corresponding elements, which have the same reference numerals as in FIG. 1, the reference symbols of the second circle being assigned an index line. These two circuits are independent of one another, and the stabilization of the output voltage of one circuit has no influence on that of the other circuit.

The performance of the load circuit according to FIG. 1 or a circuit according to FIG. 2 depends heavily on the switching losses of the transistor 8 of the first circuit.

In FIGS. 3A and 3B are respectively as a function of time t, of the transformer 3 flowing in the primary winding 4 of current I, which includes the sum of those due to the primary winding of secondary flows, and the voltage at the terminals of the transistor 8 Darge provides . The switching losses in the transistor 8 are illustrated in FIG. 3C by the signal P, specifically as a multiplication of the signals I and V. These are non-negligible pulse losses which occur at every change in state at the time t _i (closing) t _{i +1} (open or lock). . . of transistor 8 occur.

If one determines the ratio between the number of turns of the primary winding 4 and the number of turns of the secondary winding 5 of the transformer 3 so that the switches or transistors 10, 10 ' ,. . . systematically interrupt or block in front of the transistor 8 , and that is exactly what the control is aiming for, considering the coupling between the windings and corresponding to the curves according to FIGS. 4A, 4B, 4C, the primary current I 'is almost on Zero when the transistor 8 turns off and the voltage V 'begins to grow, whereby the opening losses P' of the transistor 8 are considerably reduced, the primary current I 'before opening the transistor 8 a first time when opening t₀¹ one of the two Transistors 10, 10 ' and a second time when opening t₀² the other of the two transistors 10, 10' begins to fall off.

If you also delayed by means of delay elements, as are common in secondary circuits, the action of the flip-flop 19 , which controls the on state of the transistors 10, 10 ' based on the transistor 8 , corresponding to the curves of Fig. 5A, 5B, 5C the voltage V '' is almost to zero when the transistor 8 becomes conductive and the primary current I '' reaches a remarkable value, you considerably reduce the losses when closing, the primary current I '' after closing the transistor 8 alone begins to rise, namely a first time when closing t _F one of the two transistors 10, 10 ' and a second time when closing t² _{F of} the other of the two transistors 10, 10' .

In the case of leading, blocking and in the case of delaying the on state of the transistors 10, 10 ' , based in each case on the states of the transistor 8 , the commutation losses are thus negligible. In this case, the auxiliary networks for the commutation of the transistor 8 cannot be provided if the rectified voltage of the network 2 is increased.

The regulation of the power supply is how it results from the results above, very simple, and the corresponding Device can be integrated into a housing that is not takes up more space than a linear regulator housing.

The control circuit described above can also Protection circuits are assigned, for example a Current limiting circuit, one Surge protection circuit, a temperature fuse etc. . .

Although a power supply with positive voltages has been described, the invention can also be used in connection with the power supply of loads with negative DC voltages. For this it is sufficient, for example, to interchange the connections of the protective diodes 23, 23 ' , and those of the "freewheeling" diodes 14, 14' and the smoothing capacitors 13, 13 ' and to provide chopper transistors of the npn type.

Claims (6)

1. Power supply unit with a rectifier ( 6 ) for rectifying the AC voltage of a network ( 2 ) and a high-frequency insulating transformer ( 3 ) with primary and secondary windings ( 4, 5 ) of the same polarity, of which the primary winding ( 4 ) to the rectifier (6) and the secondary winding (5) are connected to at least one load (1), wherein in the primary circuit of the transformer (3), a first Spannungszerhacker (7, 8) is switched on and in the secondary circuit of the transformer (3), a second Spannungszerhacker ( 10 ), a smoothing circuit ( 11 ) for smoothing the chopped voltage of the secondary circuit and a control device ( 22 ) for regulating the DC voltage at the terminals of the load ( 1 ), which are able to the chopped and smoothed voltage of the To compare the secondary circuit of the transformer ( 3 ) with a reference voltage and to form a comparison signal, the first voltage chopper ( 7, 8 ) being a fixed one Has conductivity and the second voltage chopper ( 10 ) and the control device ( 22 ) are designed and switched such that the second voltage chopper ( 10 ) via the Regelvor direction ( 22 ) in dependence on the impulses on the secondary winding ( 5 ) and the difference signal is controlled. Characterized by the following features:

• a) The control device ( 22 ) contains a bistable multivibrator ( 19 ), whose input ( 20 ) to the secondary winding ( 5 ) of the transformer ( 3 ) before the second voltage chopper ( 10 ) and whose output to the control input of the second voltage chopper ( 10 ) is connected and the zero reset input of the comparison signal is supplied, the control being such that the second voltage chopper ( 10 ) during the rising leading edge of the voltage pulse on the secondary winding ( 5 ) in the on state and at the times when the output voltage the terminals of the load ( 1 ) exceed the reference voltage, is controlled in the blocking state;
• b) the ratio between the number of turns of the primary winding ( 4 ) and the number of turns of the secondary winding ( 5 ) of the transformer ( 3 ) is set such that the time for the start of the blocking state of the second voltage chopper ( 10 ) systematically before that of the first voltage chopper ( 7, 8 );
• c) the bistable multivibrator ( 19 ) contains a delay element for the time-delayed activation of the on state of the second voltage chopper ( 100 ).

2. Power supply according to claim 1, characterized in that the first voltage chopper contains a fixed frequency oscillator ( 7 ) which controls a switching element ( 8 ) which completely or not at all by in series with the primary winding ( 4 ) of the transformer ( 3rd ) lies. 3. Power supply according to claim 1 or 2, characterized in that the second voltage chopper has a switching element ( 10 ) which is completely or not at all permeable. 4. Power supply according to claim 3, characterized in that the switching element ( 10 ) is a thyristor. 5. Power supply according to claim 3, characterized in that the switching element ( 10 ) is a transistor which is in series with a protective diode ( 23 ). 6. Power supply according to one of claims 1 to 5, characterized in that several load circuits, each of which has a second voltage chopper ( 10, 10 ' ) for the secondary voltage, smoothing elements ( 11, 11' ) and control devices ( 22, 22 ' ) , are connected in parallel to the secondary winding ( 5 ) of the transformer ( 3 ).