WO2018095619A1 - Actuation assembly for voltage-controlled switching elements - Google Patents

Abstract

The invention relates to an actuation assembly for voltage-controlled switching elements (SE1, SE2), in particular in a switch power supply. The actuation assembly comprises an actuation transmitter which transmits pulsed control signals that are generated by signal drivers (ST1, ST2) for at least two voltage-controlled switching elements (SE1, SE2) and which has at least one secondary coil (W1, W2) on a secondary side for each of the at least two voltage-controlled switching elements (SE1, SE2). Additionally, an actuation unit (AN1, AN2) which at least has a driver functionality is paired with each voltage-controlled switching element (SE1, SE2) on the secondary side. The actuation unit (AN1, AN2) which is paired with the respective voltage-controlled switching element (SE1, SE2) is connected to the at least one secondary coil (W1, W2) for the switching element (SE1, SE2) such that a positive supply voltage (U+) and a negative supply voltage (U-) can be derived from an output voltage (UW1, UW2) of the at least one secondary coil (W1, W2) for the driver functionality, and the output voltage (UW1, UW2) of the at least one secondary coil (W1, W2) can be compared with a reference voltage (REF), wherein actuation information (UGS1, UGS2) for switching the voltage-controlled switching element (SE1, SE2) can be derived therefrom. The voltage-controlled switching elements (SE1, SE2) are reliably deactivated during a down time (t_D) by means of the actuation assembly according to the invention.

Description

Besehreibung

Drive arrangement for voltage-controlled switching elements

Technical area

The present invention relates generally to the field of electrical engineering, in particular the field of power electronics and power electronic circuits for power supply. In particular, the present invention relates to a drive arrangement for voltage-controlled switching elements, such as e.g. Power semiconductors, in one

Switching power supply. For this purpose, the drive arrangement comprises a drive transformer from which pulsed control signals generated by signal drivers are transmitted for at least two voltage-controlled switching elements. For this purpose, the drive transformer has, in addition to at least one primary winding, at least one secondary winding on the secondary side for each voltage-controlled switching element.

State of the art

Nowadays, in many applications in the field of power electronics, e.g. used in switching power supplies with transducers, in particular with resonant converter bridge circuits. These bridge circuits or switching bridges are based primarily on voltage-controlled switching elements or so-called power semiconductors and can be designed, for example, as so-called half bridges (for example consisting of two switching elements) or as so-called full bridges (consisting of, for example, four switching elements).

When bridge circuits are used in switching power supplies, there is generally at least one voltage-controlled switching element in the upper half of the bridge circuit (high-side) and at least one voltage-controlled switching element in the lower half of the bridge circuit (low-side). A control of the at least one low-side switching element usually causes little problems, since the source terminal of the low-side switching element with a defined reference potential - usually with the reference potential 0V and the ground potential - is connected. Since in the bridge circuit the at least one high-side switching element is usually at a sliding potential, special driver units often have to be used for the high-side switching elements or a supply of the associated driver units must be made separately. That is, a supply voltage circuit for the driver unit must be constructed, for example, insulated from the remaining circuitry. Therefore, so-called ISO couplers (digital isolators) or ISO drivers (isolated gate drivers) with isolated supply are used for the control. The supply can be done for example via galvanically isolated DC-DC converter. Such AnSteuerung the bridge circuit, in particular the high-side switching element, however, is associated with rather high costs.

A more cost-effective variant for the control of voltage-controlled switching elements in a bridge circuit is made possible for example by the use of a drive transformer or a Ansteuerübertragers. The drive transformer galvanically separates the control circuit from the power circuit. With the help of the Ansteuerübertragers can be by means of electro-magnetic coupling both energy for the supply and information (for example in the form of control signals) for the control of the voltage-controlled

Switching elements or power semiconductors are provided. To both high-side and low-side switching elements of a bridge circuit using a

To be able to drive Ansteuerübertragers, usually two signal drivers are necessary whose outputs are connected to the primary winding of the Ansteuerübertragers. On the secondary side, the drive transformer has at least one secondary winding per voltage-controlled switching element. Usually, the control signals for the switching elements are generated by means of signal drivers, which are provided on the primary side of the Ansteuerübertragers. A control signal is a sequence of alternating positive and negative pulses. Between the pulses of the control signal, a so-called dead time is provided, which is intended to protect against a simultaneous switching of the switching elements of a bridge circuit - a so-called "shoot through." A "shoot through" is understood to mean a forbidden state in the bridge circuit in which both High-side and low-side switching elements are switched on at the same time. A simultaneous switching of switching elements can cause a short circuit and thus damage to the respective circuit such as a switching power supply. Therefore, between the switching off of a switching element and the switching of the other switching element mandatory a minimum period of time - the dead time - provided by which a safe switching off and on of the respective switching elements to be ensured.

When using a Ansteuerübertragers it may, however, in particular due to the necessary dead time to problems. During the dead time, for example, vibrations may occur, whereby the switching elements do not lock properly. This problem can be promoted for example by leakage currents and unfavorable conditions (eg high temperatures) and ultimately lead to a simultaneous switching through of the switching elements or to a "shoot through", causing damage to the respective circuit or the switching power supply due to Furthermore, the oscillations during switching of the switching elements can impair the electromagnetic compatibility.

From document EP 2 961 049 A1, a drive circuit for driving a power bridge for a resonant converter is known. In the solution described, a clamping circuit is arranged at the output of each signal driver, which during the dead time between two signal pulses of the control signal, the primary winding of the Ansteuerübertragers clamped against a ground potential. This ensures that the gates of the voltage-controlled switching elements are held at a potential of 0 volts during this time, in order to avoid an undesired switch-on. However, this solution has the disadvantage that on the primary side additional clamping circuits must be inserted, which can lead to a more complicated circuit structure and higher costs. Especially with power semiconductors such as

 Silicon carbide or SiC field-effect transistors, which switch at a small gate-source threshold voltage, can be switched through in spite of the clamping circuits, since the terminal circuits clamp the primary winding of the drive transformer in the dead time only to the ground potential or 0 volt.

The invention is therefore based on the object to provide a drive arrangement of the type mentioned for voltage-controlled switching elements, which ensures a simple and cost-effective manner safe switching of the voltage-controlled switching elements and safe compliance with a dead time when switching a bridge circuit.

This object is achieved by a drive arrangement of the type specified in the introduction with the features of the independent patent claim. Advantageous embodiments of the present invention are described in the dependent claims.

According to the invention, the object is achieved by a drive arrangement of the type mentioned, which comprises a on control transmitter, which transmits generated by means of signal drivers, pulsed control signals for at least two voltage-controlled switching elements. On the secondary side, the drive transformer has at least one secondary winding for each the at least two voltage-controlled switching elements. Each voltage-controlled switching element is assigned on the secondary side a drive unit, which has at least driver functionality. The control unit associated with the respective voltage-controlled switching element is connected to the at least one secondary winding for this voltage-controlled switching element in such a way that a positive supply voltage and a negative supply voltage for the driver functionality of the drive unit can be derived in a simple manner from an output voltage of the at least one secondary winding and that Output voltage of the at least one secondary winding with a reference voltage is comparable. From this, a control information for the driver functionality of the drive unit for switching the voltage-controlled switching element can be derived.

The main aspect of the proposed solution according to the invention is that the input side via signal driver to the drive transformer, the drive information for the voltage-controlled switching elements is supplied. This control information or these control signals are the output side or secondary side of the secondary windings of the

Ansteuerübertragers in almost the same extent available. In this case, at least one secondary winding is provided for each voltage-controlled switching element, from which the respective control signal is provided on the secondary side as an output voltage. Furthermore, each drive-controlled switching element is assigned on the secondary side a drive unit with at least driver functionality. From the drive signal or from the output voltage of the respective secondary winding, the drive information for the respective switching element and, secondly, the supply voltage for the driver functionality of the drive unit assigned to the respective voltage-controlled switching element are generated with the aid of the respective drive unit. In this case, a negative supply voltage is derived from the drive signal or the output voltage of the respective secondary winding in addition to a positive supply voltage. From the drive unit is ensured that the signal is used to turn on the respective switching element only from a predetermined amplitude of the output voltage to the respective secondary winding for the driver functionality of the respective drive unit or for switching the respective switching element. Due to the driver functionality of the respective drive unit, the voltage-controlled switching element, to which the respective drive unit is assigned, can be switched on or off between the positive and the negative supply voltage. That is, when switching the respective switching element is charged with the positive voltage. However, if the switching element is to be safely switched off (eg in the dead time and during a switch-off period), then the corresponding voltage-controlled switching element is charged by the associated drive unit to a negative voltage. Thus, a dead time when switching the bridge circuit can be maintained safely in a simple manner.

Furthermore, for the indicated solution, the use of cost-intensive circuit components such as e.g. galvanically isolated DC-DC converters and ISO couplers (digital isolators) or ISO drivers (isolated gate drivers) are not necessary. The specified solution also does not have the problem that it may possibly during the dead time to vibrate, which may affect the electromagnetic compatibility or cause other disturbances, which can lead to damage to the switching elements and / or the circuit.

The AnSteuereinheit assigned to a voltage-controlled switching element may ideally comprise a driver unit for the driver functionality, by which the voltage-controlled switching element to which the respective drive unit is assigned between the positive and the negative supply voltage on or off. The driver unit is connected to the positive and negative supply voltage of the respective drive unit. WEI terhin, the respective drive unit for a comparison of the output voltage of the respective at least one secondary winding of the respective voltage-controlled switching element with the reference voltage having a comparator unit. The reference voltage is designed as a so-called floating voltage and can be related, for example, to a reference potential of the respective drive unit.

Alternatively, the drive unit associated with the respective voltage-controlled switching element may comprise a combined comparator driver unit. On the one hand, the comparator driver unit has the driver functionality in order to switch the voltage-controlled switching element, to which the respective drive unit is assigned, between the positive and the negative supply voltage on or off. On the other hand, the comparison between the output voltage of the respective at least one secondary winding of the respective voltage-controlled switching element with the reference voltage is performed by the comparator drive unit. The reference voltage may in this case be integrated in the combined comparator driver unit, wherein as a reference point for the reference voltage, e.g. the negative supply voltage is used.

Furthermore, it is advantageous if the drive unit assigned to the respective voltage-controlled switching element has at least one rectifier unit. With the aid of the rectifier unit, the positive and the negative supply voltage for the driver functionality of the respective drive unit can be formed in a simple manner in the drive unit for the respective voltage-controlled switching element on the secondary side from the drive signal or the output voltage of the respective secondary winding. These supply voltages are then also used for switching on and off the respective voltage-controlled switching element. An advantageous embodiment of the AnSteuerung invention provides that the drive transformer has a secondary winding per voltage-controlled switching element. For the formation of the positive and the negative supply voltage, the respective voltage-controlled

Switching element associated drive unit then a rectifier unit. This rectifier unit may in the simplest case consist of at least two diodes and two capacitors - i. be designed as a simple peak rectifier. For stabilization, the rectifier unit may comprise, for example, at least one Zener diode or at least one linear regulator. The rectifier unit generates a stable, constant positive and a stable, constant negative voltage for the driver functionality or for supplying the driver unit of the drive unit from the pulsed drive signal which is present at the output of the secondary winding for the respective voltage-controlled switching element.

By appropriate selection of the Zener diodes or the linear regulator for stabilization in the rectifier unit, different values for the positive or negative supply voltage can be selected in terms of amount. In this way, for example, the value of the positive supply voltage can be selected so that the voltage-controlled switching element completely turns on, and thus has minimal forward losses (for example, + 15V). The value of the negative supply voltage, on the other hand, can be chosen so that a certain safety distance to the threshold voltage of the voltage-controlled switching element is maintained so that it safely blocks (for example -2V). This is advantageous so that the gate of the respective voltage-controlled switching element in the negative direction is not charged unnecessarily high, whereby unnecessary delays in switching and Umladeverluste can be avoided.

In a further advantageous embodiment of the control according to the invention, the drive transformer has a second on the därseitig two secondary windings per voltage-controlled switching element. In this case, the respective voltage-controlled switching element associated drive unit is connected to the two secondary windings for this voltage-controlled switching element that from the output voltage of a first secondary winding, the positive supply voltage and from the output voltage of the second secondary winding, the negative supply voltage can be derived. By two secondary windings, the positive and the negative supply voltages can be generated separately by means of the drive unit. A voltage ratio between the positive and the negative supply voltage can be determined in a very simple manner by a ratio of the number of turns of the first and the second secondary winding for the respective voltage-controlled switching element. The determination based on the number of turns of the two secondary windings of the Ansteuerübertragers can be made such that the positive supply voltage is greater in magnitude than the negative supply voltage. The negative supply voltage can thus be adjusted very easily and without additional effort to a negative voltage value, which is necessary for a secure locking of the respective voltage-controlled switching element.

When using two secondary windings per voltage-controlled switching element, the control unit assigned to the respective voltage-controlled switching element ideally comprises two rectifier units, a first rectifier unit being used to form the positive supply voltage and a second rectifier unit being used to form the negative supply voltage. These two

Rectifier units may in the simplest case consist of at least one diode and one capacitor and further comprise a zener diode or a linear regulator for voltage stabilization. The two rectifier units generate a stable constant positive and a stable constant negative voltage from the respective pulsed output voltages at the two secondary windings for the driver functionality or for the supply of the drive unit of the drive unit and for a safe switching of the respective voltage-controlled switching element can be used.

Advantageously, the positive supply voltage and the negative supply voltage of the respective drive unit - for all embodiments - implemented as floating or so-called floating voltages. The positive and negative supply voltages are related to a common reference potential. This common reference potential is the reference potential of the drive unit. Due to the design of the positive and negative supply voltage for the driver functionality or for the driver unit of the respective drive unit as floating voltages, the drive arrangement can ideally be used when voltage-controlled switching elements are components of a bridge circuits.

In particular, voltage-controlled switching elements can be switched on the high-side in a simple, cost-effective and secure manner by the drive arrangement according to the invention or the secondary-side drive unit per switching element. The drive arrangement according to the invention can be advantageously used for voltage-controlled switching elements in bridge circuits, by which transducers such as e.g. Resonant converter are switched. Furthermore, the drive arrangement according to the invention can be used advantageously in converters in which at least one voltage-controlled switching element must be controlled floating, as for example in flow converters (2-switch forward) or flyback converters (2-switch flyback) for higher voltages Case is.

As a voltage-controlled switching elements are ideally field effect transistors, in particular so-called MOSFETs or so-called SiC MOSFETs or bipolar transistors with insulated gate electrode (IGBTs short) can be used - in particular if these switching elements are driven opposite or if a dead time is to be observed during switching operations. Especially with SiC MOSFETs, which typically have a low and falling when heated threshold voltage, a safe switching can be maintained by the drive arrangement according to the invention or the respective switching elements associated drive unit. The drive unit charges the SiC-MOSFET when it is switched off to a negative supply voltage and therefore blocks it safely.

Brief description of the drawing

The invention will now be described by way of example with reference to the accompanying drawings. It shows:

1 shows a schematic and exemplary construction variant of the drive arrangement according to the invention with a secondary winding per voltage-controlled switching element, in particular for switching resonant converters

Figure 2 shows exemplary voltage waveforms on the secondary windings and for driving the switching elements for an exemplary drive arrangement with a secondary winding per voltage-controlled switching element

3 shows a schematic construction variant of the drive arrangement according to the invention with two secondary windings per voltage-controlled Sehaltelement

Figure 4 shows another exemplary construction variant of the drive arrangement according to the invention with a secondary winding per voltage-controlled switching element, in particular for switching flux and flyback converters

Embodiment of the invention FIG. 1 schematically shows an exemplary structure of the drive arrangement according to the invention for at least two voltage-controlled switching elements SE1, SE2, which are, for example, components of a bridge circuit. The embodiment shown by way of example in FIG. 1 has two voltage-controlled switching elements SE1, SE2, which are components of a half-bridge circuit and which can be used, for example, for switching a resonant converter. The resonant converter to be switched can be connected, for example, via connections AI, A2, A3 to the switching elements SE1, SE2, wherein for example a first terminal AI connected to an input voltage for the resonant converter, to a second terminal A2 a resonant inductance of the resonant converter and a third connection A3 is connected to a reference potential for the resonant converter (eg ground potential). Depending on the application requirement (eg voltages to be switched, switching times, etc.), metal-oxide-semiconductor field-effect transistors (MOSFETs), silicon carbide MOSFETs (SiC-MOSFETs), or

Insulated Gate Bipolar Transistors (IGBTs) are used, which are alternately turned on and off to switch the resonant converter.

The drive arrangement for the voltage-controlled switching elements SEI, SE2 comprises a drive transformer which comprises a primary winding PW on the primary side. Furthermore, two signal drivers ST1, ST2 are provided on the primary side, the outputs of which are connected via the primary winding PW of the control transformer. The signal drivers ST1, ST2 generate pulsed control signals for the at least two voltage-controlled switching elements SE1, SE2, which are transmitted by the drive transformer.

On the secondary side, the drive transformer to two secondary windings Wl, W2, wherein, for example, a first secondary winding Wl a first voltage-controlled switching element SEI and a second secondary winding W2 is assigned to a second voltage-controlled switching elements SE2. The Secondary windings W1, W2 are wound, for example, in the opposite direction, as a result of which the pulsed output voltages UW1, UW2 applied to the secondary windings W1, W2 likewise turn out to be opposite. That is, an output voltage UWl at the first secondary winding Wl is positive, while the voltage applied to the second secondary winding W2 output voltage UW2 is negative and vice versa.

Furthermore, a drive unit AN1, AN2 is assigned to the secondary side of each voltage-controlled switching element SEI, SE2. A first drive unit AN1, which is assigned to the first voltage-controlled switching element SEI, is connected on the input side to the first secondary winding W1 and has as input voltage the output voltage UW1 of the first secondary winding W1. A second drive unit AN2 is assigned to the second voltage-controlled switching element SE2 and is connected on the input side to the second secondary winding W2. The output voltage UW2 of the second secondary winding W2 thus forms the input voltage of the second drive unit AN2. The input-side connection of the respective drive unit AN1, AN2 to the respective secondary winding Wl, W2 is designed such that from the respective output voltage UWl, UW2 of the respective secondary winding Wl, W2 a positive supply voltage U + and a negative supply voltage U- is derived. The positive supply voltage U + and the negative supply voltage U- are designed as so-called floating voltages and related to a reference potential Ubl, Ub2 of the respective drive unit AN1, AN2.

To form the positive and the negative supply voltage U +, U-, the respective drive unit AN1, AN2 has a rectifier unit Gl, G2. This rectifier unit Gl, G2 can be designed, for example, as a simple peak value rectifier and to this consist of at least two diodes and two capacitors. For a voltage stabilization and the choice in magnitude different value for the positive and negative supply voltage U +, U- can the rectifier unit Gl, G2 include Z-diodes or linear regulators, for example, whereby the positive supply voltage U + can be adjusted in magnitude greater than the negative supply voltage U-.

Furthermore, the respective drive unit AN1, AN2 has a comparator unit K1, K2 and a driver unit T1, T2. The driver unit Tl, T2 of the respective drive unit AN1, AN2 is connected to the positive and the negative supply voltage U +, U-. The comparator unit K1, K2 of the respective drive unit AN1, AN2 is connected to the respective secondary winding in such a way that the output voltage UW1, UW2 of the respective secondary winding W1, W2 can be compared with a reference voltage REF from the respective comparator unit K1, K2. The reference voltage REF is also designed as a so-called floating voltage and related to the reference potential Ubl, Ub2 of the respective AnSteuereinheit AN1, AN2. On the output side is the

Comparator Kl, K2 of the respective drive unit AN1, AN2 with the driver unit Tl, T2 of the respective drive unit AN1, A 2 connected.

From the comparator unit K1, K2 of the respective control unit AN1, AN2, a control information for the driver unit T1, T2 of the respective control unit AN1, AN2 is generated by comparing the output voltage UW1, UW2 of the respective secondary winding W1, W2 with the reference voltage REF. In this case, it is ensured that the switch-on information of the respective secondary winding W1, W2 does not start to be applied until the amplitude of the reference signal REF has been changed

Comparator Kl, K2 to the driver unit Tl, T2 for driving or switching of the respective switching element SEI, SE2 is passed. For this purpose, the respective drive unit AN1, AN2 or the

Driver unit Tl, T2 of the respective drive unit AN1, AN2 output side connected to a gate terminal of the respectively associated voltage-controlled switching element SEI, SE2. Furthermore, the respective drive unit AN1, AN2 is the output side with the so-called source terminal of the respective voltage-controlled switching element SEI, SE2 (when using MOSFETs or SiC MOSFETs) or with the so-called emitter terminal of the respective voltage-controlled

Switching element SEI, SE2 (when using IGBTs), wherein the connection to the source or emitter terminal of the respective switching element SEI, SE2 on the reference potential Ubl, Ub2 the respective drive unit AN1, AN2 is located. From the driver unit Tl, T2 of the respective drive unit AN1, AN2 the respective voltage-controlled switching element SEI, SE2 between the positive supply voltage U + and negative supply voltage U- is then on or off based on the control information, which as so-called gate source or Gate-emitter voltage UGS1, UGS2 between gate and source or gate and emitter of the respective switching element SEI, SE2 is applied. That when switching on, the respective switching element SEI, SE2 is charged with the positive voltage U +. When switching off and during a dead time between see the switching of the two switching elements SEI, SE2, the respective switching element SEI, SE2 is charged by the associated AnSteuereinheit to the negative voltage U-.

FIG. 2 shows, by way of example, voltage profiles of the output voltages UW1, UW2 at the secondary windings W1, W2 and voltage profiles of gate-source and gate-emitter voltages UGS1, UGS2 of the switching elements SE1, SE2 of the inventive and exemplary embodiments shown in FIG drive arrangement. A first voltage curve in FIG. 2 shows the time profile of the output voltage UW1 at the first secondary winding W1 of FIG

Drive transformer. The output voltage UW1 is based on the pulsed control signals generated on the primary side by the signal drivers ST1, ST2 and has a sequence of positive and negative voltage pulses. Between the positive and negative voltage pulses, a so-called dead time t _{D is} provided, during which the output voltage UW1 has a value of about 0 volts. On a longitudinal axis of the first Voltage curve is the reference voltage REF plotted, with which the output voltage UWL of the first secondary winding Wl is compared by the comparator Kl of the first drive unit.

A second voltage profile shows a time profile of the drive information generated by the drive unit AN1 or the gate-source or gate-emitter voltage UGS1 of the first voltage-controlled switching element SEI, which is assigned to the first secondary winding Wl and the first drive unit AN1. In this case, the positive and the negative supply voltage U +, U- are plotted on a longitudinal axis of the second voltage profile, which are derived from the output voltage UW1 of the first secondary winding W1 by the on-control unit AN1. The second voltage curve shows that in the case of a positive pulse of the output voltage UW1 of the first secondary winding W1, the drive information or the gate-source or gate-emitter voltage UGS1 of the first switching element SEI assumes the value of the positive supply voltage U +. That is, the first switching element SEI is turned on. Upon termination of the positive pulse of the output voltage UWL of the first secondary winding Wl or at the beginning of the dead time t _D is the driving information or the gate-source or gate-emitter voltage of the first switching element SEI by the driver Tl of the first drive unit on the Value of the negative supply voltage U- set. That is, the first switching element SEI is safely switched off. By comparing the output voltage UW1 of the first secondary winding Wl with the reference voltage REF, the drive information from the comparator unit Kl is only passed on from a predetermined amplitude to the driver unit T1 of the first drive unit AN1.

A third and a fourth voltage curve show time profiles of the output voltage UW2 of the second secondary winding W2 and the drive information or the gate-source or gate-emitter voltage at the associated second voltage-controlled switching element SE2, which is the same as the first voltage-controlled switching element SEI is driven. That is, when the first switching element SEI is turned on, the second switching element SE2 is turned off and vice versa. During the dead time t _D , both switching elements SEI, SE2 are switched off. The opposite control or a gegengleiches

Switching the voltage-controlled switching elements SEI, SE2 can be achieved by the opposite winding of the secondary windings Wl, W2. The third voltage curve shows the time course of the output voltage UW2 of the second secondary winding, which fails by the opposite winding of the secondary windings Wl, W2 opposite to the first voltage waveform, which shows the output voltage UW1 of the first secondary winding Wl. As the third voltage waveform shows, the output voltage UW2 of the second secondary winding W2 is negative when the output voltage UW1 of the first secondary winding Wl is positive and vice versa. Only during the dead time t _D are the first and third voltage waveforms zero.

The fourth voltage curve shows a time profile of the drive information or the gate-source or gate-emitter voltage at the associated second voltage-controlled switching element SE2. In the case of a negative pulse and during the dead time t _D, the drive information or the gate source or gate emitter voltage at the associated second voltage-controlled switching element SE 2 has the value of the negative supply voltage U U, which is derived from the output voltage UW 2 second secondary winding W2 is derived by the drive unit AN2. In the case of a positive pulse of the output voltage UW2, the drive information or the gate-source or gate-emitter voltage at the associated second voltage-controlled switching element SE2 has the value of the positive supply voltage U +, which consists of the output voltage UW2 of the second secondary winding W2 through the on - Control unit AN2 is derived. The second and fourth voltage profile of the control information or the gate-source or gate-emitter voltages UGS1, UGS2 of the two switching elements SEI, SE2 also show the opposite switching, or that during the dead time t _D both switching elements SE1, SE2 are switched off or charged to the negative supply voltage U-.

 FIG. 3 shows, by way of example and schematically, a further embodiment variant of the drive arrangement according to the invention for at least two voltage-controlled switching elements SE1, SE2.

The drive arrangement shown in FIG. 3 again has a drive transformer with a primary winding PW and two primary-side signal drivers ST1, ST2 for generating the pulsed control signal for the at least two voltage-controlled switching elements SE1, SE2. On the secondary side, however, the drive arrangement has two secondary windings W11, W12, W21, W22 per voltage-controlled switching element SE1, SE2, which are wound in opposite directions, for example, so that the activation or switching of the voltage-controlled switching elements SE1, SE2 takes place in the same way. The first voltage controlled switching element SEI are e.g. a first and a second secondary winding Wll, W12 and the first control unit AN1 assigned. The second voltage controlled switching element SE2 is e.g. a third and a fourth secondary winding W21, W22 and the second drive unit AN2 assigned. With the respective drive unit AN1, AN2, the two secondary windings Wll, W12, W21, W22 are connected such that from an output voltage of the first and the third secondary winding Wll, W21, the positive supply voltage U + and from an output voltage of the second and the fourth Secondary winding W12, W22 a negative supply voltage U- for the driver unit Tl, T2 of the respective drive unit AN1, AN2 can be derived. The positive and negative supply voltages U +, U- are configured again as so-called floating voltages and referenced to a reference potential Ubl, Ub2 of the respective drive unit AN1, AN2.

In order to form the positive and the negative supply voltage U +, U- for the driver unit T1, T2, the respective drive unit AN1, AN2 has two rectifier units G11, G12 or G21, G22. With a first rectifier unit Gll or G21, the positive supply voltage U + is derived from the output voltage of the first or third secondary winding W11, W21. With a second rectifier unit G12 or G22, the negative supply voltage U- is derived from the output voltage of the second or fourth secondary winding W12, W22. In the simplest case, these rectifier units G11, G12, G21, G22 can, for example, consist of at least one diode and one capacitor and, for example, have a Zener diode or a linear regulator for voltage stabilization.

A voltage ratio between the positive supply voltage U + and the negative supply voltage U- can be adjusted by a ratio of the number of turns of the respective secondary windings Wll, W12 or W21, W22, which are assigned to the respective drive unit AN1, AN2. The stress ratio can be determined by the ratio of the number of turns, e.g. be set such that the positive supply voltage U + is greater in magnitude than the negative supply voltage U-.

Furthermore, the control units AN1, AN2 of the embodiment variant of the drive arrangement illustrated in FIG. 3 each include a comparator unit K1, K2 and a driver unit T1, T2. From the comparator Kl, K2 the output voltage on the secondary side of the Ansteuerübertragers is compared with a reference voltage to derive therefrom a control information for the driver unit Tl, T2 for switching the respective voltage-controlled switching element SEI, SE2, which in the embodiment shown in Figure 3 again be switched against the same. For example, a resonant converter can be switched on again via the connections AI, A2, A3.

FIG. 4 shows a further exemplary embodiment of the drive arrangement according to the invention with at least two

Switching elements SEI, SE2 shown, which in particular for Switching of, for example, 2-switch-forward or 2-switch-flyback converters is suitable for higher voltages. The drive arrangement again has a primary winding PW on the primary side and two signal drivers ST1, ST2 for generating the control signals for the at least two voltage-controlled switching elements SE1, SE2 (eg MOSFETs, SiC-MOSFETs or IGBTs). On the secondary side, at least one secondary winding W1, W2 and a drive unit AN1, AN2 are again provided for each of the voltage-controlled switching elements SE1, SE2. The drive unit AN1, AN2 in this case again comprises a comparator unit Kl, K2 and a driver unit Tl, T2 and can - for example by means of a rectifier unit Gl, G2 - from the output voltage of the respective secondary winding Wl, W2 a positive and negative supply voltage U +, U- for the Derive driver unit Tl, T2. With the

Comparator unit Kl, K2 of the respective drive unit AN1, AN2, the output voltage UW1, UW2 of the respective secondary winding is compared with a reference voltage REF and derived therefrom the control information for the driver unit Tl, T2. The supply voltages U +, U- and the reference voltage are again designed as floating voltages and related to the reference potential Ubl, Ub2 of the respective drive unit AN1, AN2.

For the switching of a flyback converter or a flux converter, however, the switching elements SEI, SE2 are not counter-balanced, but simultaneously switched on or off. Therefore, the secondary windings Wl, W2 of the Ansteuerübertragers are wound the same. That is to say that the output voltages or tapped pulses applied to the secondary windings W1, W2 are likewise the same, and thus also the associated gate source or gate emitter voltages at the switching elements SE1, SE2. For the connection of a flyback converter or a flux converter, the drive arrangement further comprises an inductor LW - a primary-side winding LW -, which is inserted between the voltage-controlled switching elements SEI, SE2 and connected in series with them. The connections AI, A2 are connected to the input voltage or to the reference potential or ground potential for the flyback converter or flux transformer connected.

The on-control arrangements shown by way of example in FIGS. 1, 3 or 4 have on-control units (AN1, AN2) which each have at least one comparator unit (K1, K2) and a driver unit (T1, T2). Alternatively, there is also the possibility that the control units (AN1, AN2) each comprise a combined comparator driver unit, which performs the comparison of the output voltage (UW1, UW2) of the respective secondary winding with a reference voltage REF and assumes the driver functionality. The reference voltage REF can be integrated into the comparator driver unit and is then related to the negative supply voltage U, for example.

Claims

claims

1. Drive arrangement for voltage-controlled switching elements (SEI, SE2), in particular in a switched-mode power supply, comprises a drive transformer which transmits, by means of signal drivers (ST1, ST2), pulsed control signals for at least two voltage-controlled switching elements (SEI, SE2), and wherein Control transformer for each of the at least two voltage-controlled switching elements (SEI, SE2) on the secondary side at least one secondary winding

(Wl, W2), characterized in that each voltage-controlled switching element (SEI, SE2) on the secondary side a drive unit (AN1, AN2) is assigned, which has at least driver functionality, and that the respective voltage-controlled switching element (SEI, SE2) associated drive unit ( AN1, AN2) with the at least one secondary winding (Wl, W2) for this voltage-controlled switching element (SEI, SE2) is connected in such a way that from an output voltage (UW1, UW2) of at least one secondary winding (Wl, W2) a positive supply voltage (U +) and a negative supply voltage (U-) for the driver functionality are derivable, and that the output voltage (UW1, UW2) of at least one secondary winding (Wl, W2) with a reference voltage (REF) is comparable and from this a control information

(UGS1, UGS2) for switching the voltage-controlled switching element (SEI, SE2) is derivable.

2. Drive arrangement according to claim 1, characterized in that the respective voltage-controlled switching element

(SE1, SE2) associated drive unit (AN1, AN2) a comparator unit (Kl, K2) for comparing the output voltage (UW1, UW2) of the respective at least one secondary winding (Wl, W2) with the reference voltage (REF) and a driver unit (Tl , T2) for the driver functionality.

3. Control arrangement according to claim 1, characterized in that the respective voltage-controlled switching element (SEI, SE2) associated drive unit (AN1, AN2) comprises a combined comparator driver unit, which the output voltage (UW1, UW2) of the respective at least one secondary winding (Wl , W2) compares with the reference voltage (REF) and which has the driver functionality.

4. Drive arrangement according to one of claims 1 to 3, characterized in that the respective voltage-controlled switching element (SEI, SE2) associated drive unit (AN1, AN2) further at least one rectifier unit (Gl, G2) to form the positive and the negative Supply voltage (U +, U-) has.

5. Control arrangement according to one of claims 1 to 4, characterized in that the drive transformer has a secondary winding (Wl, W2) per voltage-controlled switching element (SEI, SE2), and that the respective voltage-controlled switching element (SEI, SE2) associated drive unit (AN1, AN2) has a rectifier unit (Gl, G2) for forming the positive and the negative supply voltage (U +, U-).

6. Control arrangement according to claim 5, characterized in that the rectifier unit (G1, G2) of the respective control unit (AN1, AN2) further comprises at least one Zener diode or at least one linear regulator, by which a voltage distribution between the positive and the negative supply voltage ( U +, U-) can be fixed in such a way that the positive supply voltage (U +) is greater in magnitude than the negative supply voltage (U-).

7. Drive arrangement according to one of claims 1 to 4, characterized in that the drive transformer per voltage-controlled switching element (SEI, SE2) has two secondary windings (Wll, W12, W21, W22) on the secondary side, and that the respective voltage-controlled switching element (SEI, SE2) associated with drive unit (AN1, AN2) with the two secondary windings (Wll, W12, W21, W22) are connected for this voltage-controlled switching element (SEI, SE2) in such a way that from a Output voltage of a first secondary winding (Wll, W21), the positive supply voltage (U +) and from an output voltage of a second secondary winding (W12, W22), the negative supply voltage (U) for the driver functionality can be derived.

8. A drive arrangement according to claim 7, characterized in that a voltage ratio between the positive and the negative supply voltage (U +, U-) of the respective drive unit (AN1, AN2) by a ratio of the number of turns of the first secondary winding (Wll, W21) and the second Secondary winding (W12, W22) is determinable such that the positive supply voltage (U +) is greater in magnitude than the negative supply voltage (U-).

9. Drive arrangement according to one of claims 7 to 8, characterized in that the respective voltage-controlled switching element (SEI, SE2) associated drive unit (AN1, AN2) a first rectifier unit (Gll, G21) to form the positive supply voltage (U +) and a second rectifier unit (G12, G22) for forming the negative supply voltage (U-).

10. A drive arrangement according to one of the preceding claims, characterized in that the positive supply voltage (U +) and the negative supply voltage (U) of the respective drive unit (AN1, AN2) are designed as floating or floating voltages, which refer to the reference potential ( Ubl, Ub2) of the respective drive unit (AN1, AN2) are related.

11. Drive arrangement according to one of the preceding claims, characterized in that the voltage-controlled Switching elements (SEI, SE2) are components of a bridge circuit, which can be used in particular for switching converters.

12. Control according to one of the preceding claims, characterized in that are used as voltage-controlled switching elements (SEI, SE2) field effect transistors, in particular MOSFETs or SiC-MOSFETs, or bipolar transistors with insulated gate electrode.