DE4118918A1 - DC=DC converter with two sec. output stages - has two current-controlled transductor chokes in series supplying one of two rectifying and smoothing circuits - Google Patents

Abstract

A transistor switch (S) in the prim. circuit of the transformer (Tr) is controlled by a pulse width modulator (St) driven by a regulator (R) of the voltage (U3) of the sec. winding (N1) rectified by a diode (D5) and smoothing capacitor (C3). The main sec. output circuit fed via a controlled choke (L1) is divided into two branches with separate rectifiers (D1,D2) and free-wheel diodes (D3,D4). The second branch has its own choke (L2) with control current (I2) holding the output voltage (U2) to a predetermined stable level. ADVANTAGE - More than one regulated output voltage is obtd. from a circuit of low complexity.

Description

The invention relates to a DC-DC converter a primary circuit with a controllable switch and with a primary winding of a transformer and with one a first secondary circuit having a transducer choke with a secondary winding of the transformer and with at least one a second transducer choke pointing secondary secondary.

For the supply of electronic devices become equal voltage converters needed that have one or more equals deliver tension. With clocked DC voltage wall The basic types are flyback converters and To distinguish flow transducers. A z. B. from the mains voltage by rectification and sieving won DC voltage with the help of a controllable scarf ters converted into a square wave voltage. This is with With the help of a transformer, which in the case of Flyback converter also takes over the energy storage. On finally, rectification and sieving takes place. At a Flyback converter is controllable during the flyback phase Switch and a flow converter during the Lead phase transfer energy into the secondary circuit.

From DE-A 38 37 933 is a DC-DC converter known type. This is used to generate each output voltage, a secondary circuit with egg ner separate secondary winding used.

The invention has for its object a like to specify voltage transformers of the type mentioned at the outset,  which in a simple manner with little component effort Generation of several regulated output chips enables.

This task is the case of a DC voltage converter type mentioned solved in that the second Se secondary to the secondary winding and the second Transductor choke to the first transducer choke is closed.

With the help of the first transducer choke of the first second därkreises is a first regulated output voltage witnessable. By connecting the also with the help of second transducer choke regulated second secondary circuit to the first transducer choke is a second positive or negative output voltage can be generated. This is the amount of the secondary secondary output voltage generated by the dimension tion of the transducer choke is determined during its pola rity by designing the second secondary circuit as Flyback or flow converter is set. Both the the first and the second secondary circuit have a ge common secondary winding. The associated one saving additional secondary windings causes a ge wrestle component effort. It also will otherwise between several secondary windings avoiding disturbing leakage inductances, which especially at high switching frequencies, for example se over 100 KHz disruptive. The Transfor mator can be set up very easily, otherwise for the generation of multiple output voltages is a ratio represents moderately complex component.

Is the transducer choke of the second secondary circuit the transducer choke of the first secondary circuit  switches, the second transducer choke can be the second Secondary circuit a smaller, more space-saving and so with a cheaper core than one direct connection of the transducer choke to the secondary would be necessary.

In a further embodiment, the Sekun at least a third secondary circuit without Transducer choke control connected. Such one third secondary circuit without transducer choke control particularly advantageous if the transformer egg has a core with an air gap. In this case it can continue after turning off the controllable switch in the Air gap of the transformer stored energy to the third secondary circuit. So that becomes a necessary demagnetization of the transformer during the time it takes for the second transducer choke of the second secondary circuit is still blocked.

In a further embodiment, the third controls Secondary circuit a pulse width modulator for controlling the Pulse width of the controllable switch. In the case in that the DC-DC converter does not already have a primary regulation, can with the help of a pulse widths controlled by the third secondary circuit modulation the off generated by the third secondary circuit output voltage, which has no transducer choke control points to be regulated.

In one embodiment, the second transducer Gate choke of the second secondary circuit at least one further transducer choke of a fourth secondary circuit connectable, whereby to the transducer choke of the four th secondary circuit as a cascade of further secondary circuits can be connected. The amount is one with help  of the fourth secondary circuit generated output voltage lower than the amount of using the second second Därkreis generated output voltage. From each downstream transducer chokes a "cas kadenschaltung ". This has the advantage that the core of the downstream transducer chokes smaller can be dimensioned as this with the direct approach the secondary winding would be the case.

In one embodiment, the secondary winding a tap to which at least one further trans Ductor choke of at least one other secondary circuit can be connected. With the help of the tap on the secondary winding becomes a further output voltage only derived from a secondary winding.

In one embodiment, the DC voltage converter on the primary side. The Duty cycle, for example, depending on On adjusted voltage fluctuations and so already the Se generated using the DC-DC converter pre-regulated secondary voltages. Through the transductors Then a more precise readjustment takes place the output voltages of the secondary circuits.

The invention is described below with reference to the figures illustrated embodiments explained.

Fig. 1 shows an embodiment of a DC voltage converter for generating three output voltages.

Fig. 2 shows a further embodiment of a DC-DC converter for generating various positive and negative output voltages.

Fig. 1 shows a DC-DC converter with a transformer Tr, which has a primary winding N 0 and a secondary winding N 1 of a first secondary circuit be. A controllable switch S designed as a transistor is arranged in series with the primary winding N 0 , for example. A first capacitor C 0 is connected in parallel with the input terminals at which an input voltage U 0 is present. A first transducer choke L 1 and a first rectifier diode D 1 are arranged in series with the secondary winding N 1 . Parallel to the series circuit from the secondary winding N 1 , the first transducer inductor L 1 and the first diode D 1 is a freewheeling diode D 3 . In series with the arrangement of secondary winding N 1 , transducer choke L 1 , rectifier diode D 1 and freewheeling diode D 3 , a storage choke L 3 is arranged in the first secondary circuit. Parallel to the output terminals of the first secondary circuit is a first capacitor C 1 , at which a reference potential OV be referenced first output voltage U 1 .

Furthermore, a second transducer inductor L 2 of a second secondary circuit is connected to the first transducer inductor L 1 of the first secondary circuit. In series with the second transducer inductor L 2 is a second rectifying diode D 2 . In parallel with the arrangement of the secondary winding N 1 , the first transducer inductor L 1 , the second transducer inductor L 2 and the second rectifier diode D 2, there is a second freewheeling diode D 4 . In series with the arrangement of the secondary winding N 1 of the first and second transducer chokes L 1 , L 2 and the diodes D 2 , D 4 , a second storage choke L 4 is arranged in the second secondary circuit. Parallel to the output terminals of the two-th secondary circuit is a second capacitor C 2 , on which a second output voltage U 2 can be tapped. The transducer chokes L 1 , L 2 are each controlled by control currents I 1 , I 2 . For the sake of clarity, in the exemplary embodiment shown in FIG. 1, the associated control devices are not shown. Such a control device is connected on the input side to the output terminals of the respective secondary circuit. In this way, a control criterion is obtained, which results in a corresponding control signal in the form of the control current I 1 , I 2 at the output of the control device. The current flowing to the transductor L 1, L 2 control current I 1, I 2 causes a change of the conductance of the transductor and thus a control or stabilization of the respective secondary voltage to the predetermined value.

In the embodiment shown in the figure, the possibility of generating a negative third output voltage is also shown. For this purpose, a rectifier diode D 5 of a third secondary circuit is connected between the first transducer choke L 1 and the secondary winding N 1 of the first secondary circuit.

Parallel to the output terminals of the third secondary circuit is a third capacitor C 3 , on which a negative third output voltage U 3, which is related to the reference potential OV, can be tapped. The output terminals of the third secondary circuit are connected to a control circuit R which supplies a control signal for regulating the pulse width of the controllable switch S via a pulse width modulator St.

During the conducting phase of the controllable switch S, the first rectifier diode D 1 of the first secondary circuit is conductive, the current flows after switching through the first transducer choke L 1 to the load, not shown, and the storage choke L 3 takes up energy, the free-wheeling diode D 3 being blocked. During the blocking phase of the controllable switch S, the current flows from the storage choke L 3 to the load via the freewheeling diode D 3 . In this way, the first output voltage of, for example, +12 V is generated. The generation of the second output voltage U 2 also takes place during the leading phase of the controllable switch S. The current flows after switching the second transducer inductor L 2 to the load, also not shown, and the second storage inductor L 4 takes up energy, the free-wheeling diode D 4 Is blocked. During the blocking phase of the controllable switch S, the current flows from the second storage inductor L 4 to the load via the freewheeling diode D 4 . In this way, the second output voltage of, for example, +5 V is obtained. The second transducer choke of the second secondary circuit can have a smaller, space-saving and thus cost-effective core or a smaller number of turns than would be necessary for a direct connection of the transducer chokes sel to the secondary winding by connecting to the first transducer choke L 1 of the first secondary circuit . The direct connection to only one secondary winding also leads to the saving of a further secondary winding. This multiple use of a secondary winding to generate a plurality of output voltages also avoids disturbing leakage inductances which occur in the case of a plurality of secondary windings between them and which would interfere at high switching frequencies.

With the help of the third secondary circuit, the negative third output voltage U 3 can be obtained in a simple manner in the exemplary embodiment shown in the figure. This is gained during the blocking phase of the controllable switch S.

Such a third secondary circuit without a transducer choke control is particularly advantageous when the transformer Tr has a core with an air gap. In this case, the energy stored in the air gap of the transformer Tr can be given to the third secondary circuit immediately after the controllable switch S has been switched off. This results in a necessary demagnetization of the transformer Tr, while the transformer chokes L 1 , L 2 of the first and second secondary circuits are still blocked in this operating state. The controlled by the third output voltage U 3 in example designed as a pulse width modulator control circuit St for controlling the pulse width of the controllable switch S causes a pre-regulation of the two output voltages U 1 , U 2 , while using the transducer inductor L 1 , L 2, the output voltages U 1 , U 2 are stabilized to even more precise and precise values.

Fig. 2 shows an embodiment of a DC voltage converter for generating various positive and negative output voltages. The output voltages are in each case between the potentials U 1 +, U 2 +. . . U 6 +, U 1 -. . U 7 - and the reference potential OV. In the embodiment shown in FIG. 2, for the secondary circuits with the potential U 1 +, U 3 +, U 1- , the reference symbols introduced in connection with FIG. 1 are already used. In addition, in the Darge shown in Fig. 2 DC converter on the secondary winding N 1, a tap is provided to which at least one further transducer choke L 5 at least one other secondary circuit is connected. In addition, at least one further 2 Trans duktordrossel L 6, wherein at least ei ne transductor L connectable to this Transduk tordrossel L 6 via a transductor L 7 connected as a cascade more secondary circuits. This has the advantage that the core of the respective downstream reactor chokes can be dimensioned smaller or fewer windings are necessary than would be the case when connecting directly to the secondary winding.

In the exemplary embodiment shown in FIG. 2, for the sake of clarity, the secondary circuits have not been drawn in completely. The operation of the individual secondary circuits of the DC-DC converter shown in FIG. 2 corresponds to the secondary circuits already described in connection with FIG. 1.

Claims (6)

1. DC-DC converter with a primary circuit with a controllable switch (S) and with a primary winding (N 0 ) of a transformer (Tr) and with a first transducer choke (L 1 ) having the first secondary circuit with a secondary winding (N 1 ) of the transformer tors (Tr) and with at least one second transducer choke (L 2 ) having a second secondary circuit, characterized in that the second secondary circuit to the secondary winding (N 1 ) and via the second transducer choke (L 2 ) to the first transducer choke (L 1 ) connected. 2. DC-DC converter according to claim 1, characterized in that at least one third secondary circuit is closed to the secondary winding (N 1 ) without a transducer choke control. 3. DC-DC converter according to claim 2, characterized, that the third secondary circuit has a pulse width modulator For regulating the pulse width of the controllable switch (S) controls. 4. DC-DC converter according to one of claims 1 to 3, characterized in that to the second transducer choke (L 2 ) of the second secondary circuit Se at least one further transducer choke (L 6 ) of a fourth secondary circuit can be connected, where at the transducer choke (L 6 ) of the fourth secondary circuit, further secondary circuits can be connected as a cascade. 5. DC-DC converter according to one of claims 1 to 4, characterized in that the secondary winding (N 1 ) has a tap to which at least one further transducer choke (L 5 ) is connected at least one further secondary circuit. 6. DC-DC converter according to one of claims 1 to 5, characterized, that the DC-DC converter has a primary-side rain lung.