EP3183806A1 - Method and device for regulating a dead time in switching power supply units - Google Patents

Abstract

The invention relates to a method for adapting a dead time (t_dead) between the beginning of the opening process of a first switching element (1.5.1) and the beginning of the closing process of a second serially connected switching element (1.5.2) in a switching regulator (1.5) of a switching power supply unit (1), having the following steps: - a measurement voltage (U_out) across the second switching element (1.5.2) is measured, - the dead time (t_dead) is varied such that the deviation of the measured measurement voltage (U_out) from a target value (U_target) of the measurement voltage is minimized or limited, and - the first and second switching elements (1.5.1, 1.5.2) are actuated using the thus ascertained dead time (t_dead). The invention further relates to a device for carrying out such a method, comprising a measuring unit (2), a processing unit (3), and a control unit (4).

Description

description

Method and apparatus for dead time control in switching power supplies

The invention relates to a method and a device for determining and / or adjusting, in particular regulation and / or control of a dead time between the opening of a first switching element and the closing of a second switching element in a switching power supply with active freewheel.

Switching power supplies for converting a DC input voltage into a supply voltage are often constructed with active freewheel, in which a first switching element is connected in series with a second switching element, wherein the second

 Switching element takes over the function of the active freewheel. The switching regulator is supplied with the DC input voltage. Parallel to the second switching element, an inductor is connected in series with a capacitor. Over the second switching element, an output voltage or measurement voltage is tapped. About the capacity of the supply voltage is tapped to supply a consumer. The first and the second switching element are periodically opened and closed, wherein always at least one of the switching elements is open. The ratio of the closing time of the first switching element to the total duration of closing duration and subsequent opening duration of the first

Switching element is referred to as duty cycle. About the duty cycle can be set to a given input DC voltage and a given, parallel to the capacitance connected electrical load a desired supply voltage. The person skilled in various forms of this basic form of a switching power supply with active freewheel are known, for example as a buck converter or step-down converter.

The period of time between the opening of the first switching element and the closing of the second switching element, during which both switching elements are thus open, is referred to as dead time. Switching elements can be designed as transistors, for example as metal-oxide field-effect transistors (MOSFET). Due to the principle of such MOSFETs can not abrupt, so infinitesimally short switching operations implement, but require for the closing and opening a certain, dependent on the manufacture ^¬ technology and geometry time from a few tenths of a nanosecond up to a few nanoseconds. Furthermore, MOSFETs have technologically caused parasitic diodes between a drain and a source terminal. Such a parasitic diode of the second switching element acts in parallel to the series ^¬ circuit of the inductance and the capacitance across which the supply voltage is tapped.

Due to the production, due to wire-like or at least elongated metallic connections between the components, such a switching regulator has a parasitic inductance. Due to the recovery behavior of the para-university ^¬ diode of the second switching element, this parasitic inductance can elements dependent on the switching speed of the switch, the input DC voltage and the electric

Consumers parallel to the capacity at a too large dead time between the switching operations lead to resonance phenomena, whereby the output voltage or measurement voltage, and thus also the supply voltage, is superimposed by voltage spikes. These voltage spikes can be observed as a temporary overvoltage. The temporary overvoltage and an associated temporary current increase lead to an undesirably high electrical emission. Furthermore, too small a dead time may cause the turn-off phase of the first switching element and the turn-on phase of the second switching element to overlap. Such an overlap initially also causes an overvoltage at the measuring output of the switching regulator. In a further reduction of the dead time, a high short-circuit current through both switching elements is possible, which can lead to destruction of the switching elements. ^

The invention is based on the object to provide a method for determining and / or adjusting the dead time of a switching regulator with active freewheel in a switching power supply, which avoids overvoltage and / or destruction. Furthermore, the invention is based on the object to provide a device for carrying out the method.

With regard to the method, the object is achieved by the features of claim 1. With regard to the device, the object is achieved by the features of claim 10.

Advantageous embodiments of the invention are the subject of the dependent claims.

In the inventive method for determining and / or adjusting a dead time between the start of opening a first switching element and the beginning of closing a series-connected second switching element in a switching regulator with active freewheeling of a switching power supply, a measuring ^¬ voltage of the switching power supply via the second switching element are determined and based on the determined measurement voltage, a dead time is varied so that the deviation of the determined measurement voltage is minimized or limited by a desired value. The first and the second switching element in the switching regulator with active freewheel of the switching power supply are driven so that the second

Switching element is delayed by the determined dead time after the opening of the first switching element is closed. The inventive method can be embodied in the manner of a ge ^¬ closed regulation or control of the dead time by the dead time is determined several times in a loop and adjusted. In one embodiment of the method according to the invention, this comprises

in a first step, an initialization of a dead time, the initialization of a first overvoltage value of Measuring voltage with an overvoltage starting value greater than or equal to the maximum measurable overvoltage and the initialization of a positive correction direction for the change of the dead time,

- in a second step the measurement of a second overvoltage value in a coordinated to the dead time measurement ^¬ time window,

 in a third step, the reversal of the correction direction if the second overvoltage value is greater than the first overvoltage value,

 in a fourth step, the change of the dead time value in the correction direction by a dead time change and

 in a fifth step, the overwriting of the first overvoltage value with the second overvoltage value.

Optionally, the process may be continued by repeating the sequence of the second to fifth steps. In the case of a negative correction direction, the dead time value is reduced by the dead time change; in the case of a positive correction direction, the dead time value is increased by the dead time change. The dead time change may be predetermined by a fixed dead time change step size.

In the first step, the dead time is set to an initial value that is at least chosen so that a short-circuit current is avoided by overlapping opening and closing of the first and second switching element. It is possible to initialize the dead time value with a standard dead time value for which it is known that in the case of typical loads connected to the switching regulator it will cause no or only slight overshoot of the measuring voltage, and thus also of the supply voltage.

In the first step, the correction direction is furthermore initialized as a positive correction direction, so that the dead time value is increased by the dead time change step width when an overvoltage occurs.

The first overvoltage value is initialized with an overvoltage ^¬ start value. Such an overvoltage start value can be set, for example, as a maximum representable or maximum storable overvoltage value.

In the second step, the measured voltage measured with the current dead time setting is determined as the second overvoltage value in a measuring time window which is matched to the dead time.

It is possible for this purpose to use a circuit known to the person skilled in the art as a sample-and-hold element or instantaneous value sampling, which circuit can be operated with a trigger signal derived from the drive signals of the switching elements. For example, the measurement voltage can be measured at a point in time approximately at the middle of the dead time. However, it is also possible to determine as the second overvoltage value the maximum value of the voltage curve at the measuring output of the switching ^¬ controller during a predetermined period of time, for example, with or immediately after the opening of the first switching element beginning time interval.

In the third step, the second overvoltage value is compared with the first overvoltage value. If the second overvoltage ^{value is} below the first overvoltage value, the correction direction is maintained. Otherwise, the correction direction is reversed.

In the fourth step, the dead time is corrected according to the corrective ^¬ direction by the predetermined dead time change step size, that is increased at positive correction direction and reduced at negative correction direction.

In the fifth step, the second, ie the last measured, overvoltage value is assigned to the first overvoltage value and is thus available for comparison with a subsequent overvoltage value still to be measured in a subsequent pass of the second through fifth steps. If the third step is passed through for the first time, the second overvoltage value measured in the second step is never above the first overvoltage value, which was initialized in the first step with a maximum overvoltage starting value. Thus, for the first pass of the third step, it is ensured that the initialized positive correction direction is maintained.

For subsequent runs of the third step, however, the correction direction from the previous pass is maintained exactly if this correction direction has caused a reduction of the overvoltage, thus improving the behavior of the switching regulator. In all other cases, the correction direction is changed.

In an advantageous manner, dead time values are determined with this method, which oscillate around an at least locally optimal dead time value, which is characterized by an at least locally minimum overvoltage value of the measuring voltage. In other words, dead time values outside, but in the immediate vicinity of the commutated dead time interval would lead to larger overvoltage values of the measurement voltage. Thus, the adverse overvoltage is minimized by the described method.

For practical purposes, can be approximately assumed that between a high over-voltage caused by too low a dead time which a high overvoltage value caused by too much dead time, which results in an overshoot, a dead time is in a short-circuit current resul ^¬ advantage, and that in an optimal, namely compared to the setpoint of the measurement voltage not or only minimally increased measurement voltage during the switching of the first and second switching element results.

For this practically particularly significant approximation, the method leads to dead time values which are immediately around the optimum Float dead time, which leads to a minimum overvoltage value.

This is particularly advantageous in the case of changes in the load current which is absorbed by a consumer supplied by the switched-mode power supply or in the case of changes in the impedance, in particular of the capacitive impedance component of such a consumer. Such changes generally require a modified optimal deadtime value to minimize the overvoltage. By means of the method according to the invention, such a modified optimal dead time value can be determined at least approximately.

In a further embodiment of the invention, in a modified second step replacing the second step, the second overvoltage value is determined as the maximum value of the measurement voltage over a complete switching cycle of the switching regulator, wherein such switching cycle is determined by the time between the beginning of a first closing of the first switching element and the beginning a subsequent second closing of the first switching element is determined. In this embodiment of the invention, the third and fourth steps of the method are omitted when the second overvoltage value is less than or equal to a predetermined overvoltage limit.

Although in this embodiment of the invention, the at least approximately finding an at least locally optimal dead time value can no longer be guaranteed, but it is sufficient for many practical purposes, if a previously determined

Overvoltage limit is not significantly exceeded. For such applications, this embodiment represents an advantageously simplified method, since in this embodiment, the limitation of the measurement of the overvoltage profile to a predetermined, based on the current dead time measurement time window is omitted. In advantageous manner ^¬ characterized a simpler arrangement may be used for the measurement of an overvoltage value. In a further embodiment of the invention, the overvoltage limit value is determined as a function of a predetermined desired value of the measurement voltage. In many significant applications, electrical loads can be supplied with supply voltages, which in a certain amount

Corridor by a setpoint of a supply voltage. For example, variations of plus or minus ten percent of the setpoint of the supply voltage from such electrical loads may be tolerated. It is therefore not necessary in these cases to limit the overvoltage at the measuring output of a switching power supply to a minimum, but only necessary to avoid exceeding the tolerated corridor of supply voltages. So it is for example possible to determine a surge limit corresponding to 1.05 times the nominal value of the measured voltage when it is known that consumers tolerate fluctuations in the supply voltage ^¬ 10 percent to a target value. Advantageously, thus a safe operation of consumers with minimal control effort for the dead time is possible.

In a further embodiment of the invention, the

Dead time change determined from the difference between the first and the second overvoltage value.

The Totzeitänderung influenced on the one hand the number of passes of the second to fifth steps that are required to bring a dead time in the vicinity of an optimal value ^¬ Tot. For a fast adaptation of the dead time value, therefore, a large dead time change is advantageous.

On the other hand, the dead time change affects the width of the interval in which, under steady state conditions, the dead time value determined by the method oscillates around such an optimal dead time value. For a precise adaptation of the dead time value to this optimum, a small dead time change is thus advantageous. For example, the dead time change may be determined from the product of the difference between the first and second overvoltage values with a predetermined positive factor. Far from the optimal dead time value sought, a change in the deadtime values results in a large change in the generated

 Overvoltage values, thus to a large dead time change and thus to a rapid approximation to the desired optimal dead time value. By contrast, in the vicinity of the optimum dead time value sought, the variation of the dead time values leads only to a slight change in the overvoltage values produced, thus to a small dead time change and thus to a precise adaptation of the dead time value to the desired optimal dead time value. This embodiment of the invention thus advantageously combines a high adaptation speed with a high accuracy of approaching this optimum dead time value. The dead time change can also with as a product of a

Dead time change step size, a gain of at least one and a control deviation of the measurement voltage are formed, wherein the control deviation from the difference of the measured second overvoltage value and the predetermined setpoint value of the measurement voltage is formed. It is also possible to increase this error with an exponent of at least one. In an advantageous manner, the result is that a comparatively large dead time change is determined with comparatively large control deviations, while with comparatively small control deviations the dead time is changed only comparatively little.

It is possible that the load current consumed by the load changes over time. Such a change in the load current generally causes a control deviation of the measurement voltage. To limit these control deviation an adjustment of the dead time is necessary in order to limit undesirable over-voltage to avoid or ^¬ ver. Be gain factor and / or Exponent too small, the control deviation can not be compensated fast enough. If the amplification factor and / or the exponent are chosen too large, it is possible to override the measurement voltage by changing the dead time too much. An override of the measuring voltage is also favored by a high capacitive impedance component of the consumer, which causes a temporal offset of the change in the measured voltage with respect to the change in the dead time. Advantageously, therefore, the gain factor and the exponent in the described embodiment of the method are adapted to the typical switching behavior of a connected consumer, in particular to the typical speed and the typical amplitude of a change in the recorded load current, and to the capacitive impedance component of the connected consumer. The adaptation is carried out in such a way that a gain factor and an exponent are determined for a specific load, which in the case of typical changes in the recorded load current does not yet cause an override of the measuring voltage, and thus of the supply voltage.

In a further embodiment of the method, in the second step, the second overvoltage value is determined as the maximum value of the measuring voltage over a complete switching cycle of the switching regulator, wherein such a switching cycle is determined by the time between the beginning of a first closing of the first

Switching element and the beginning of a subsequent second closing of the first switching element is determined. In this embodiment of the invention, the third and fourth steps of the method are performed when the second overvoltage value is greater than a predetermined overvoltage limit. If, in a subsequent run of the method, the second overvoltage value is less than or equal to the predetermined one

Overvoltage limit, so instead of the third and fourth step, a modified fourth step is performed. In this modified fourth step, the dead time in the correcting direction by a certain step number by a predetermined multiple of the Totzeitänderungsschrittweite is hereby amended ^¬ changed. In other words, a change in the dead time to the desired fall below the surge limit ge ^¬ leads, then in a subsequent pass of the method, the dead time is again changed in the same correcting direction by a predetermined multiple of the Totzeitänderungsschrittweite which the product of the Totzeitänderungs- increment with a step number.

In all subsequent runs of the method, in this embodiment, the third and fourth steps are omitted when the second overvoltage value is less than or equal to the predetermined overvoltage threshold. In other words, the dead time remains unchanged until an overrun of the overvoltage limit is detected again.

Advantageously, in this embodiment of the invention by means of a further change in the dead time in

Direction of a previously successfully carried out dead time change a further reduction of the control deviation then achieved when this dead time change is adjusted by selecting the number of steps to the typical switching behavior of the supplied consumer. The adaptation can be carried out in a similar manner as the adjustment of the gain factor and the exponent by selecting a step number at which, with typical changes in the recorded load current, no overriding of the measuring voltage is effected.

The inventive device for determining and adjusting, in particular control or control of dead time according to the inventive method comprises a measuring unit for measuring the measuring voltage of the switching power supply, a processing unit for calculating a dead time and a control unit for driving the first and second switching element in the switching regulator of the switching power supply. The measuring unit is connected to the processing unit and measures the measuring voltage across the second switching element. From this voltage measurement, the processing unit determines a change in the erfor ^¬ derliche Totzeitwerts by the inventive process.

The processing unit is connected to the control unit and designed so that a control signal can be transmitted to the control unit via a connection, from which a required change in the dead time can be derived.

The control unit is connected to the first and the second switching ^¬ element. The control unit sets SchaltZeitpunkte for switching the first and the second switching element so that there is a dead time between the opening of the first switching ^¬ elements and the closing of the second switching element, which advantageously with the inventive device minimizing or at least limiting a Overvoltage at the measuring output of the switching power supply achieved.

In a further embodiment of the device according to the invention, the control unit is designed to drive MOSFETs. In this embodiment of the invention, the control unit is connected via electrical connections with switching elements designed as MOSFETs. Advantageously, thus the control of particularly common

Switching regulators in switching power supplies particularly simple and inexpensive possible. Further details and exemplary embodiments of the invention are explained in more detail below with reference to drawings.

1 shows schematically the circuit structure of a switching power supply with an adaptation, for. As regulation, the dead time, Figure 2 shows schematically the course of an overvoltage, caused by a too large dead time, FIG. 3 schematically shows the course of an overvoltage, caused by too small a dead time,

4 shows the flowchart for a method for minimizing the

 Overvoltage by dead time control,

Figure 5 shows schematically the course of an overvoltage at a

 Method for minimizing overvoltage by means of

Totzeitregelung,

FIG. 6 schematically shows a detailed view of the course of a

 Overvoltage in a method for minimizing the overvoltage by dead time control,

 7 shows the flowchart for a method for limiting the

 Overvoltage by dead time control and Figure 8 shows the flowchart for a method for limiting the

 Overvoltage via dead time control and dead time control.

Corresponding parts are provided in all figures with the same reference numerals. 1 shows by way of example and schematically the circuit configuration of a switching power supply 1 with a measuring unit 2, a Ver ^¬ processing unit 3 and a controller 4. The input of the switching power supply 1 is formed by two input contacts 1.1, 1.2, which are powered by a DC input voltage U_IN. The measuring output of the switched-mode power supply 1 is formed by two measuring output contacts 1.3, 1.4, between which a measuring voltage U_out drops. The measuring voltage U_out should assume a desired setpoint U_soll, which lies below the input direct voltage U_in.

In an input-side switching regulator 1.5 with active freewheeling of the switched-mode power supply 1, a first switching element 1.5.1 and a second switching element 1.5.2 are designed as MOSFETs and connected in series. The measuring output contacts 1.3, 1.4 are arranged parallel to the second switching element 1.5.2. Furthermore, between the measuring output contacts 1.3, 1.4, and thus parallel to the second switching element 1.5.2, an inductance L and a capacitance C, which when closing the first switching element is loaded from the input DC voltage source U_ein on ^¬ , connected in series. Parallel with the capacitance C a consumer or load resistance X_L is supplied with the supply voltage ^¬, which is discharged via the capacity C.

The switching elements 1.5.1, 1.5.2 are periodically opened and closed by the control unit 4 in such a way that a dead time t_tot elapses between the opening of the first switching element 1.5.1 and the closing of the second switching element 1.5.2, while the two switching elements 1.5 .1, 1.5.2 are open.

It is possible that the first and the second Schaltele ^¬ ment 1.5.1, 1.5.2 are arranged on the same semiconductor chip. The measurement unit 2 is at the measurement output 1.3, 1.4 of the switching power supply 1 connected ^¬ and connected to the processing unit. 3 The processing unit 3 is connected to the Steuerein ^¬ uniform. 4 The control unit 4 controls the opening and closing of the switching elements 1.5.1, 1.5.2.

The switching elements 1.5.1, 1.5.2 and the connections of the switching regulator 1.5 are electrically characterized by an ohmic resistance, a parasitic inductance and a parasitic capacitance.

For a very large dead time t_tot the parasitic inductances cause About ^¬ vibrate the measurement voltage U_OUT as t_schalt in Figure 2 for a switching time along the time axis t is illustrated within the switching regulator 1.5. Within a measurement time window t_mess 1.4 of the switching power supply 1 is effected by inducing vibration of the measuring voltage U_OUT, and thus exceeding the target value of the measurement voltage by the overvoltage U_Soll U_ueb the measuring ^¬ output 1.3. The setpoint value of the measuring voltage U_soll is set only after the oscillation has gradually decayed from the overvoltage U_ueb as the stationary value of the measuring voltage U_out. , _n

 15

The switching operations in the switching elements 1.5.1, 1.5.2 do not run abruptly, but when opening during an opening phase, the current is gradually reduced and gradually increased during closing during a closing phase. With a very small dead time t_tot, the opening phase of the first switching element 1.5.1 and the closing phase of the second switching element 1.5.2 overlap. As a result, exceeding the setpoint value U_soll of the measurement voltage, and thus an overvoltage U_ueb, is effected, as shown in FIG.

Figure 4 shows the flow chart for the inventive method by which minimizes the overvoltage U_ueb or at least re ^¬ is duced. The procedure starts at a starting point SO.

In a subsequent first step Sl, the dead time will t_tot with a value t_tot_start, a first voltage value over ^¬ U_uebl with a surge start value ^¬ U_ueb_start and a compensation direction d with

Initial value 1 initialized, expressed in formulas:

 t_tot: = t_tot_start

 d: = 1,

where the operator: = notes the assignment of a rightmost value to a leftmost variable. Furthermore, in the first step S1, a first overvoltage value U_uebl in a measuring window t_mess between the switching of the first

Switching element 1.5.1 and the switching of the second switching ^¬ elements 1.5.2 measured as the maximum value of the measuring voltage U_aus.

In a subsequent second step S2, the method waits for the switching between the first switching element 1.5.1 and the second switching element 1.5.2, thus for a time or for a period of time at which or during which the first switching element 1.5.1 already open is and the second switching element 1.5.2 is not yet closed.

At this point in time or during this period, the current value of the measuring voltage U_out is measured, and from this a second overvoltage value U_ueb2 is determined. For example, it is possible to determine a specific time from the control signals generated by the control unit 4 for the first switching element 1.5.1 and the second switching element 1.5.2. The second overvoltage value U_ueb2 can then be measured, for example, as the value of the measurement voltage U_out at this time.

However, it is also possible to measure the measurement voltage U_out during a predetermined measurement time window t_mess and to determine the second overvoltage value U_ueb2 as the maximum value of all values of the measurement voltage U_out measured within this measurement time window t_mess.

In a subsequent first decision step El, it is checked whether the second overvoltage value U_ueb2 is greater than or equal to the first overvoltage value U_uebl.

If the second overvoltage value U_ueb2 is greater than or equal to the first overvoltage value U_uebl, the correction direction d is reversed in a third step S3 following a positive flow path J to the first decision step El, expressed as a formula:

 d: = -d

and then a fourth step S4 is executed.

If the second overvoltage value U_ueb2 is smaller than the first overvoltage value U_uebl, the correction direction d is maintained and the fourth step S4 is executed immediately after the first decision step El along a negative drain path N.

In the fourth step S4, the dead time is t_tot in the corrective ^¬ turrichtung a Totzeitänderung d_t_tot changed, expressed as the formula:

t tot: = t tot + d * dt dead. In a subsequent fifth step S5, the second overvoltage value U_ueb2 is assigned to the first overvoltage value U_uebl, expressed as a formula:

 U_uebl: = U_ueb2.

Thereafter, the process is continued with any number of repetitions of the process from the second to the fifth step S2 to S5. Advantageously, a dead time t_tot is set by the described method, which leads to a minimum or approximately ^¬ approximately minimal second overvoltage value U_ueb2. For stationary conditions with unchanged input DC voltage U_in and unchanged consumer X_L at the measuring output 1.3, 1.4 of the switched-mode power supply 1, the dead time t_tot oscillates around an optimum which is associated with a minimum overvoltage, ie with a minimum overshoot of the measuring voltage U_out, which sets the reference value of the Measuring voltage U_soll does not exceed, as shown in Figure 5. Here, too, the measuring voltage U_out gradually adjusts to the setpoint value U setpoint and reaches it in steady-state steady state.

FIG. 6 schematically illustrates the course of the overvoltage U_ueb and the course of the setpoint U_setpoint of the measuring voltage U_out, which sets in the stationary state, as a function of the set dead time t_tot. It can be clearly seen that a certain optimum value t_tot * of the dead time exists, in which the overvoltage U_ueb becomes minimal. It can also be clearly seen that the overvoltage U_ueb for this optimum value of the dead time t_tot * is below the setpoint U setpoint.

Advantageously, thus a safe operation of both the switched-mode power supply 1 and the connected consumer X_L is given. Figure 7 shows the flow chart for an embodiment of the method according to the invention, with which the overvoltage U_ueb is limited. The procedure starts at a starting point SO. The sequence of the first step S1 corresponds to the sequence shown in FIG.

In a subsequent modified second step S2 ', the maximum value of the measuring voltage U_out is transmitted via a

Switching cycle determined and the second overvoltage ^{value ¬ assigned} , wherein such a switching cycle is determined by the time between the beginning of a first closing of the first switching element and the beginning of a subsequent second closing of the first switching element.

In a subsequent second decision step E2, it is checked whether the determined in step S2 second surge ^¬ U_ueb2 voltage value less than or equal to a threshold-voltage is U_ueb_grenz. If the second overvoltage value U_ueb2 determined in the modified second step S2 'is less than or equal to the overvoltage limit value U_ueb_grenz, the fifth step S5 is processed along the positive sequence path J as the next step. If the second overvoltage value U_ueb_grenz determined in the modified second step S2 'is greater than the overvoltage limit value U_ueb_grenz, the sequence of the first decision step El, optionally of the third step S3 and of the fourth step S4 is selected along the negative drain path, as already described in FIG :

In the first decision step E1, it is checked whether the second overvoltage value U_ueb2 is less than or equal to the first one

Overvoltage value U_uebl is.

If the first overvoltage value U_uebl is less than or equal to the second overvoltage value U_ueb2, the correction direction d is changed along the positive drain path J in the subsequent third step S3, expressed as a formula: d: = -d

and then the fourth step S4 is executed. If the first overvoltage value U_uebl is greater than the second overvoltage value U_ueb2, the correction direction d is maintained and the fourth step S4 is executed immediately after the first decision step El along the negative drain path N.

In the fourth step S4, the dead time is t_tot in the corrective ^¬ d turrichtung a Totzeitänderungsschrittweite d_t_tot changed, expressed as the formula:

 t_tot: = t_tot + d * d_t_tot.

In one embodiment of the invention, the dead time can änderungssschrittweite d_t_tot additionally with a Verstär ^¬ blocking factor K of at least 1 and one with a positive exponent x potentiated control deviation between the second overvoltage value U_ueb2 and the target value of the measured tension ^¬ voltage U_Soll will be multiplied, expressed as the formula : t_tot: = t_tot + d * K * (U_ueb2 - U_set) ^x where y ^{x represents} the value of y raised to the xth power.

Advantageously, in this embodiment of the invention, it is possible to carry out a comparatively large change in the dead time t_tot in the case of a large control deviation, and to carry out a comparatively smaller change in the dead time t_tot with a smaller control deviation. Thus, with a smaller number of passes of the fourth step S4 with approximately the same control accuracy, an approximately optimal dead time t_tot be set than in a method with a fixed step size, which remains constant regardless of the deviation of the last measured second overvoltage value U_ueb2 from the setpoint of the measurement voltage U_soll ,

Concrete values for the amplification factor K and the exponent x are advantageously selected as a function of the impedance and the switching behavior of the connected load X_L. Comparatively large values for the gain ^factor K be ^¬ act a faster change of the dead time t tot and thus a faster reduction of the control deviation than comparatively low values for the amplification factor K. However, an overshoot of the measuring voltage U_out can be caused if the amplification factor K exceeds a certain limit value. Advantageously, a gain K in the range of about 1 to about 10 is chosen.

By means of the exponent x, the nonlinearity of the regulation of the measuring voltage U_off can be controlled. By exponent x above 1 via a proportional change in the dead time ^¬ t_tot is effected with large control deviations. For a comparatively faster Verrin ^¬ delay the deviation is achieved in an advantageous manner as with an exponent x of 1. However, an overshoot of the measurement voltage U_OUT can be effected if the exponent x exceeds a certain limit. Advantageously, an exponent x in the range of about 1 to about 5 is chosen.

It is possible for a given consumer X_L with a given impedance and a given switching behavior, which describes the frequency, speed and amplitude of load fluctuations, particularly to determine appropriate values for the gain factor ^¬ K and the exponent x experimentally. For example, the amplification factor K and the exponent x can initially be increased until an overshoot of the measurement voltage U_out is observed. Thereafter, the values thus found to be reduced by a predetermined amount in order to achieve a safe operation of the process without any overshoot of the measurement voltage U from ^¬.

In the subsequent either to the fourth step S4 or to the second decision step E2 fifth step S5, the second surge voltage value ^¬ U_ueb2 is assigned to the first overvoltage value U_uebl, expressed as the formula:

U uebl: = U ueb2. Thereafter, the process is continued with any number of repetitions of the process from the second to the fifth step S2 to S5. Advantageously, in this embodiment of the method according to the invention, it is possible to select a dead time t_tot such that an overvoltage limit U_ueb_grenz is not substantially exceeded. Once in the second decision step E2 overvoltage exceeding this limit value is determined U_ueb_grenz, the dead time is ^¬ t_tot in the compensation direction d changed so that a decrease in measured second overvoltage value U_ueb2 occurs. The change in the dead time t_tot is set as soon as the overvoltage limit value U_ueb_grenz has been reached or fallen below and only resumed when the

Overvoltage limit U_ueb_grenz is exceeded again. Advantageously omitted in this embodiment of the method the need to continuously a measurement window of time between the switching of the first switching element 1.5.1 and the switching of the second switching element 1.5.2 to monitor, in which the maximum value of the voltage characteristic of the measuring chip ^¬ voltage U_OUT at the measurement output of the Switching controller 1.5 is to be detected. This embodiment of the method can thus be implemented with a lower expenditure on components such as comparators.

FIG. 8 shows the flow chart for a further embodiment of the method in which the overvoltage U_ueb is limited. The procedure starts at a starting point SO. The first step Sl, the modified second step S2 'and the second decision-making step ^¬ E2 are run through in the same way as described by Figure 7 embodiment of the method. If the second overvoltage value U_ueb_limit determined in the modified second step S2 'is greater than the overvoltage limit value U_ueb_grenz, an iteration number Z is set to 0 along the negative flow path N in a subsequent sixth step S6, expressed as a formula:

Z: = 0. The iteration number Z describes how often the method has been run since the last time the predetermined overvoltage limit value U_ueb_grenz was exceeded. Subsequent to the sixth step S6, the flow of the first decision step El, optionally of the third

Step S3 and the fourth step S4 selected as already described in Figure 4: In the first decision step El is checked whether the second overvoltage value U_ueb2 is less than or equal to the first

Overvoltage value U_uebl is.

If the first overvoltage value U_uebl is less than or equal to the second overvoltage value U_ueb2, the correction direction d is changed along the positive drain path J in the subsequent third step S3, expressed as a formula: d: = -d

and then the fourth step S4 is executed.

If the first overvoltage value U_uebl is greater than the second overvoltage value U_ueb2, the correction direction d is maintained and the fourth step S4 is executed immediately after the first decision step El along the negative drain path N.

In the fourth step S4, the dead time is t_tot in the corrective ^¬ d turrichtung the Totzeitänderungsschrittweite d_t_tot changed, expressed as the formula:

 t_tot: = t_tot + d * d_t_tot.

In one embodiment of the invention, the Totzeitänderungsschrittweite can d_t_tot additionally provided with a reinforcing ^¬ factor K of at least 1 and components having a positive Ex- x potentiated control deviation between the second overvoltage value U_ueb2 and the target value of the measured tension ^¬ voltage U_Soll will be multiplied, expressed as the formula : t tot: = t tot + d * K * (U ueb2 - U soll) ^x where y ^{x represents} the value of y raised to the xth power.

Subsequent to the fourth step S4, the fifth step S5 is executed as already described for FIG. 4, and subsequently the modified second step S2 'is continued.

When the second overvoltage value detected in the modified second step S2 'U_ueb2 less than or equal U_ueb_grenz the surge limit, is then guided to the second decision step E2, a seventh step S7 from ^¬ in which the iteration number Z is incremented, expressed as the formula:

 Z: = Z + 1. Subsequent to the seventh step S7, it is checked in a third decision step E3 whether the iteration number Z is greater than 1. If the iteration number Z is greater than 1, the fifth step S5 is processed along a positive flow path J as the next step, as already described for FIG. 4, and subsequently with the modified second one

Step S2 'continued.

If it is determined in the third decision step E3 that the iteration number Z is not greater than 1, a modified fourth step S4 'is processed along a negative flow path N as the next step. In the modified fourth step S4 ', the dead time t_tot in the correction direction d is changed by the dead time change step size d_t_tot multiplied by a predetermined number of steps n, expressed as a formula:

 t_tot: = d * n * d_t_tot.

In other words: in this embodiment of the method, a change in the dead time t_tot by a predetermined amount n * d_t_tot in the same direction is again carried out in the case of a passage following a change in the dead time t_tot in the fourth step S4. By adapting the predetermined number of steps n to the

Switching behavior of a consumer X_L, it is possible to choose the extent of this repeated change of the dead time t_tot so that in case of typical changes in the load current related to the load X_L an approximately minimum overvoltage U_ueb is achieved.

Subsequent to the modified fourth step S4 ', the fifth step S5 is executed as already described for FIG. 4 and subsequently with the modified second one

Step S2 'continued.

If it is determined in the third decision step E3 that the iteration number Z is greater than 1, the next step along a positive flow path J becomes the fifth step

Step S5 processed as already described for Figure 4 and subsequently proceeded ^¬ with the modified second step S2 '. Advantageously, the embodiment of the method illustrated in FIG. 8 permits a particularly rapid and stable reduction of a control deviation during a load change without continuous measurement of the measuring voltage U_out, if the switching behavior of a supplied consumer X_L can be determined in advance. Thus, particularly simple and stable switching power supplies can be developed, which by adjusting the gain K and / or the exponent x and / or the step number n easy for the supply of consumers X_L with different, but well-known

Adjust switching behavior. Reference sign list

1 switching power supply

1.1, 1.2 input contacts

1.3, 1.4 Measuring output contacts, measuring output

 1.5 Switching regulator

 1.5.1 first switching element

 1.5.2 second switching element

 2 measuring unit

3 processing unit

 4 control unit

X_L load resistor, consumer

 C capacity

 L inductance

 U_in DC input voltage

 U_aus measuring voltage

 U_soll Setpoint of the measuring voltage

 U_ueb overvoltage

t time, timeline

t_tot dead time

t_tot * optimal dead time

t_shift switchover point

t_mess measuring time window

SO starting point

 Sl to S7, first to seventh step

 S2 'modified second step

 S4 'modified fourth step

 El, El, E3 first to third decision step

J positive flow path

N negative flow path

Claims

claims

1. A method for adjusting a dead time (t_tot) between the beginning of the opening of a first switching element (1.5.1) and the

Beginning of the closing of a second switching element (1.5.2) connected in series therewith in a switching regulator (1.5) of a switched-mode power supply (1),

 - Wherein a measuring voltage (U_aus) over the second switching element (1.5.2) is measured and

- wherein the dead time (t_tot) is varied so that a Re ^¬ gelabweichung the measured measurement voltage (U_aus) is minimized or limited by a setpoint (U_soll) of the measuring voltage and

- Wherein the first and the second switching element (1.5.1, 1.5.2) are controlled with the thus determined dead time (t_tot).

2. The method according to claim 1, characterized by

a first step (Sl) comprising an initialization of the dead time (t_tot), an initialization of a first transfer ^¬ voltage value of the measuring voltage (U_OUT) with a surge start value greater than or equal to a maximum measurable over-voltage and an initialization of a correction direction for the change in the dead time (t_tot) .

- A second step (S2) comprising the measurement of a second overvoltage value of the measuring voltage (U_aus) in a measuring ^{¬ time} window (t_mess) within the dead time (t_tot), a third step (S3) comprising the reversal of the correction direction, if the second overvoltage value greater is considered the first overvoltage value,

 a fourth step (S4) comprising changing the dead time (t_tot) in the correction direction by a dead time change and

a fifth step (S5) comprising overwriting the first overvoltage value with the second overvoltage value, wherein the flow from the second to the fifth step (S2 to S5) is repeated at least once.

3. Method according to claim 2, characterized in that in a modified second step (S2 ') replacing the second step (S2) the second overvoltage value is measured as the maximum value of the measuring voltage (U_out) over a complete switching cycle and further characterized the third step (S3) and the fourth step (S4) are omitted if the second overvoltage value is less than or equal to an overvoltage limit value.

4. The method according to claim 3, characterized in that the overvoltage limit value from the setpoint (U_soll) for the measuring voltage (U_aus) by multiplication with a tolerance factor of at least 1 is determined.

5. The method according to any one of claims 2 to 4, characterized in that the dead time change by multiplying the difference between the first overvoltage value and the second overvoltage value with a dead time change step size he ^¬ mediates.

6. The method according to any one of claims 2 to 4, characterized in that the dead time change as a product

 an amplification factor of at least 1,

 the one with an exponent of at least 1 potentiated difference between the second overvoltage value and the

Setpoint (U_soll) of the measuring voltage (U_off) and

 a dead time change step size

is formed.

The method of claim 6, wherein the gain factor is in the range of 1 to 10 and wherein the exponent is selected in the range of 1 to 5.

8. Method according to claim 3, characterized in that a modified fourth step (S4 ') is carried out when the second overvoltage value is less than or equal to the overvoltage limit value and when in the ^previous run of the method second overvoltage value was larger than the surge limit value, wherein in the mo ^¬-modified fourth step (S4 ') is changed, the dead time (t_tot) in the correcting direction by a multiplied by a predetermined step number of at least 1 Totzeitänderungsschrittweite.

9. The method according to claim 8, characterized in that the number of steps is selected in the range of 1 to 10.

10. Device for adjusting the dead time (t_tot) according to a method according to one of the preceding claims, comprising a measuring unit (2) for measuring the measuring voltage (U_out) of the switched-mode power supply (1), a processing unit (3) which can be connected to the measuring unit (2). for calculating a dead time value (t_tot) and a control unit (4) which can be connected to the processing unit (3) for driving the first and second switching elements (1.5.1, 1.5.2) in the switching regulator (1.5) of the switched-mode power supply (1).

11. The device according to claim 10, characterized in that the first and second switching element (1.5.1, 1.5.2) are designed as Me ^¬ tall oxide semiconductor field effect transistors and that the control unit (4) for driving Me ^¬ tall Oxide semiconductor field effect transistors is formed.