DE2554826A1 - TRANSFER ARRANGEMENT FOR A CURRENT CONVERTER CIRCUIT - Google Patents

Description

BIPLOM INGBIiIEUR

KARL-HEINZ SCHAITMBITRG 2554826

PATENT ADVOCATE

8OOO MUNICH

MATJEBKIRCHERSTR.

TELEPHONE 089- «8 1979

". , "_. , _ 98 7531

Nixdorf Computer AG τει, βχ ez & ow

4790 Paderborn

P.O. Box 939

1N5 2875 D

Transformer arrangement for a current transformer circuit

The invention relates to a transmitter arrangement for ₅ a power converter circuit in which is primarily switchable since ig via a switching element, a DC voltage source and clocked secondary se given it strength through a rectifier arrangement, a DC voltage

Current converter circuits of this type can be constructed either as forward converters or as flyback converters will. They have in common that by clock-controlled switching on of the primary winding via the switch element the primary winding is traversed by a chopped direct current, so that a AC voltage occurs, which is rectified and to supply a load resistance with a direct current can be exploited. The clock control of the switch element can be done with a variable clock ratio, In order to reduce the secondary output DC voltage due to such a variation even with fluctuations in the load resistance keep constant. In general, circuit

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arrangements that work according to this principle, also known as clocked power supplies.

A current converter working on the principle of the forward converter is switched so that during the switched on State of the switch element also the load via the rectifier to the secondary winding of the transformer is turned on. The one recorded on the primary side Current has one inductive and one due to the transformation of the load resistance on the primary side ohmic component. In the locked state of the switch element, the load through the rectifier is from the Secondary side of the transformer switched off.

A current converter connected as a flyback converter works in such a way that during the switch-on time of the switch element the load is disconnected from the secondary side of the transformer by the rectifier. This is going through Corresponding polarity of the secondary winding achieved in conjunction with the associated rectifier. During the The switch-on time of the switch element is thus derived from the Direct current source absorbs energy on the primary side, which is stored in the transformer. It is at

approximately this current consumption by a / linearly increasing inductive current. In the case of flyback converters, it must be avoided that the transformer is operated to saturation will. Before switching off, the primary current would then increase sharply without any particular benefit achieve, in particular, the efficiency would be reduced. The disconnection of the switch element must therefore become a Take place at which the saturation has not yet been reached. When the switch element is blocked, the

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Primary winding disconnected from the voltage source. Through this the result is a voltage opposite to the previous DC voltage, which is the voltage applied to the secondary winding The rectifier opens so that the energy stored in the transformer can be released.

Converters that work according to the principle of the forward converter or the flyback converter explained above, each have specific disadvantages. A particular disadvantage of the flow converter is that the connected to the switch element primary winding of the transformer can be very easily saturated. The saturation the primary winding can occur if there is no complete demagnetization in each case before switching on of the switch element is carried out if the switch element has too long a switch-on time and if the voltage of the supplying DC voltage source is too high. Becomes the primary winding of the forward converter When saturated, the magnetizing current rises sharply, which damages or destroys the switch element can be. Effects of the type described above can be particularly in the event of an incorrect operation of a Voltage converter, so for example if the switch-off time of the switch element is too short, when an interference voltage occurs in the control circuit of the switch element or when a Overvoltage in the feeding primary circuit.

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A particular disadvantage of the flyback converter is that the supply of the stored in the transformer Energy during the switch-off phase of the switch element in the secondary circuit has a very high current ripple occurs at the load resistance, which requires a correspondingly high value of the filter capacitor provided there, however this filter capacitor is also very heavily loaded.

The invention is now based on the object of a transmitter arrangement for a current transformer circuit in which, on the one hand, the risk of saturation of the forward transformer, on the other hand, the large current ripple of the flyback converter is avoided.

In order to achieve this object, a transmitter arrangement of the type mentioned at the beginning is designed according to the invention in such a way that that two transformers each with a downstream η rectifier with primary windings connected in series are provided, one of which is connected as a flyback converter and the other as a forward converter is, and that the two rectifiers are connected to a common load.

The above-described disadvantages of the flyback converter and of the forward converter with regard to the conditions at the load to be fed is completely avoided. It turns out a very small current ripple on the load resistor or on the charging capacitor assigned to it, which only the change in magnetizing current of the two

Transformer corresponds. Furthermore,

through the series connection of the two primary windings achieved that the current in the primary windings, which could rise very sharply in the event of saturation of the primary winding of the forward converter, through the in

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Series connected inductance of the primary winding of the flyback converter is limited.

The transformer arrangement can expediently be constructed in such a way that the two transformers have a common primary winding for two separate magnetic circuits. In this way it is possible to have a space-saving arrangement to realize, for the construction of which a particularly low manufacturing cost is required. In addition, minor occur Copper losses.

As a switch element in a further development of the inventive concept a switching semiconductor, preferably a switching transistor or a controlled silicon rectifier, intended. Such switching semiconductors are generally used as controllable switch elements in clocked power supplies used, the control of their switching frequency and / or their current flow angle is then dependent on one Comparison of the DC voltage generated on the secondary side with a predetermined reference voltage, so that the secondary side generated DC voltage can be kept constant regardless of external influences.

The two primary windings are expediently connected directly to one another, although the switch element too can be arranged between them in the series circuit. With a direct connection it is possible to have both Primary windings to be covered together, e.g. with voltage-limiting Switching elements, as a result of which increased circuit complexity is avoided.

Since both transformers work with their associated rectifiers on a common load, the two transformers have appropriately matching gear ratios. This creates a current imbalance in the two secondary circuits and an associated current ripple avoided.

Embodiments of the invention are described below with reference to the figures. Show it:

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1 shows a basic illustration of a transmitter arrangement

according to the invention.
2 a to e y voltage and current curves in the in

Fig. 1 shown transmitter arrangement and Fig. 3 an embodiment of a clocked power supply, which is constructed with a transmitter arrangement according to the invention.

1 shows a transformer arrangement according to the invention, which essentially consists of a switch element 1 designed as a transistor, a transformer 2 connected as a flyback converter, and a transformer 3 connected as a forward converter. The primary windings 21 and 31 of the transformers 2 and 3 are connected in series with the switching transistor 1; this series connection can be connected to a DC voltage + U. The secondary windings 22 and 32 of both ^ over-j ^ a ^ r | _e ^^ 3 _ze have _t e _e one opposite to one another, / Vickelsense, a rectifier 4 or 5 is assigned to each of them. The two rectifiers 4 and 5 work on a common load resistor 7, the voltage is reduced by a filter capacitor 6, which works as a charging capacitor.

In the circuit arrangement shown in Fig. 1, the load resistor 7 is fed with a direct current when the primary-side switching transistor 1 is switched on and off periodically or clock-controlled and thus in a pulsating direct current flows in the primary circuit. When the switching transistor 1 is switched on, the full DC voltage + U is applied to the series circuit of the two primary windings 21 and 31. In this state, the forward converter works so that its rectifier 5 becomes conductive, while the rectifier 4 is blocked in the flyback converter. At the same time a current flows through the series-connected primary windings 21 and 31 »of which

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Increase due to the inductance of the primary winding 21 and the voltage dropping across this primary winding 21 is determined. This flow of current creates a corresponding secondary flow of current that depends on the gear ratio of the transformer 3 depends.

When the switching transistor 1 is switched off, the polarity of the voltages on the primary windings is reversed 21 and 31,. so that a demagnetizing current can flow. In this state, the rectifier 4 conductive, which is assigned to the transformer 2 of the flyback converter. The in the inductance of the primary winding 21 of the Transformer 2 during the switch-on phase of the switching transistor

1 stored magnetic energy is fed into the secondary circuit, as has already been done for the flyback converter principle has been described.

The mode of operation of the circuit arrangement shown in FIG. 1 can therefore be understood that in the on-time and in the off-time of the switching transistor 1 always the Magnetizing current of the primary winding 21 of the transformer

2 is transformed with the respective associated gear ratio to the secondary side if the slight magnetizing current of the transformer 3 is neglected. It can be seen from this that it is expedient to dimension the transmission ratios of the two transformers 2 and 3 to match.

In Fig. 2, the relationships described above are shown on the basis of voltage and current curves. Fig. 2a shows the voltage profile on the two series-connected primary windings 21 and 31 for the on and off times of the switching transistor 1, these times

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denoted by ti and t2. It can be seen that while the switch-on time the voltage U at the series connection and that this voltage occurs with the opposite sign during the switch-off time. Fig. 2t> shows the current flowing through the primary windings during the switch-on time of the switching transistor 1 of starting from an initial current value, determined by the inductance of the primary winding 21 and its voltage, increases linearly. During the switch-off time of the switching transistor 1, there is no primary current flow. Fig. 2c and d show the course of the voltages on the two secondary windings 32 and 22. It can be seen that these two courses have opposite signs and that in each case during the switch-on time ti and the switch-off time t2 a voltage of a certain polarity is available on the secondary side. Fig. 2e finally shows the combined current flow of the secondary side caused by these two voltages, which results from the with the secondary voltages on the two Windings 32 and 22 generated partial current flows composed. The respective increasing part is due to the voltage on the secondary winding 32, the decreasing part by the voltage on the secondary winding 22 be-ε » originates. It can be seen that through this compound Partial currents a total current is created, the ripple speed is very low, and much less than that Ripple is only a partial current that would only be generated with the transformer 3 of the forward converter.

In Fig. 3, the application of the invention for a clocked power supply is shown, with the three output voltages can be generated, one of which is used as a control variable to keep the voltage constant and the the other two be carried in accordance with the regulation. A mains power supply is used as the DC voltage source.

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- Gr-

judge 31, the one supplied via the input terminals 30 Rectifies AC mains voltage and leads to a charging capacitor 32. With this DC voltage the series connection of two transformers 34 and 35 and a switching transistor 33 are fed. The primary windings 36 and 38 of the two transformers 34 and 35 are connected in series, the secondary windings supply in a still to be described Way different DC voltages. The base of the switching transistor 33 is connected to a transformer connected, via which the switching transistor 33 is supplied with a control variable with which the switching transistor 33 can be switched on and off cyclically. The pulse ratio of this control variable is determined by a comparator determined, which is supplied with a reference voltage Ur and one of the DC voltages U1, U2 or U3 as a comparison variable will. In the illustrated embodiment, a dashed connection with the voltage + U1 is shown for this purpose, however, other voltages can also be fed individually or jointly to the comparator 53.

The secondary windings 37 and 39 of the two transformers 34 and 35 are each provided with two taps, see above that they can deliver three different voltages. As In the embodiment shown in FIG. 1, the two secondary windings 37 and 39 operate separately Rectifier, they also have opposite winding directions. The principle of connecting with one at a time The rectifier is shown for the two taps of each secondary winding and for one end of the winding. The taps or winding ends are connected in such a way that voltages of different polarity arise, i.e. one of the taps of each secondary winding 37 and 39 is used to derive the reference potential for the two positive voltages + U1 and + Ü2 and the negative one

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- 1 <he

Voltage -U3, which is applied to the load resistors 52, 51st and 50 fall off. The connection points of two rectifiers are each with a charging capacitor 46, 47 and 48 connected, which is followed by the respective load resistor 50, 51 or 52.

The circuit arrangement shown in Fig. 3 thus enables the generation of several DC voltages, of which one or more are used as actual values to keep the voltage constant. Those not fed to the comparator 53 Voltages are concurrent voltages, i.e. they are regulated via the switching transistor 33, their regulation ent speaks of the control characteristic caused by the voltage derived as an actual variable.

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Claims (5)

Claims 1. Transformer arrangement for a current transformer circuit, V / at the primary side via a switch element DC voltage source can be switched on clock-controlled and on the secondary side via a rectifier arrangement a DC voltage is output, characterized in that two transformers (2, 3) each with a downstream rectifier (4, 5) with primary windings (21, 31) connected in series are provided, of which one (2) is connected as a flyback converter and the other (3) as a forward converter is, and that the two rectifiers (4, 5) are connected to a common load (7). 2. Transmitter arrangement according to claim 1, characterized in that that the two transformers have a common primary winding for two separate magnetic circuits. 3. Transformer arrangement according to claim 1 or 2, characterized in that the primary windings (21, 31) directly are connected to each other. 4. Transmitter arrangement according to one of claims 1 to 3, characterized in that the switch element (1) a switching semiconductor, preferably a switching transistor or a controlled silicon rectifier, is provided is. 5. transformer arrangement according to one of claims 1 to 4, characterized in that both transformers (2, 3) have matching gear ratios. 709823/0564 ORIGINAL INSPECTED