DE102014225828A1 - Operating device with detection means for the detection of phase cuts and / or sections in the supply voltage - Google Patents

Abstract

The invention relates to a control gear for lighting and a corresponding method. The operating device (6) has a first input terminal L and a second input terminal N, by means of which the operating device (6) can be connected to a supply voltage source. Furthermore, it has detecting means (13) for separately detecting a first voltage corresponding to a positive voltage component of the mains supply voltage, and a second voltage corresponding to a negative voltage component of the mains supply voltage, and an evaluation unit (14) for Evaluation of the detected voltages. As a detection means (13) between the first input terminal L and a ground potential of the operating device (6), a first voltage divider (22) for generating a first measurement mains mains1 and between the second input terminal N and the ground potential, a second voltage divider (23) for generating a second Measuring signal mains2 arranged. The detection means (13) for supplying the two measuring signals mains1, mains2 are connected to the evaluation unit (14).

Description

The invention relates to an operating device for the operation of light sources, in particular LED lamps, and a method for controlling a light source by means of the operating device.

In order to operate modern bulbs on a house power network is often a so-called operating device required. The operating device converts the supply voltage into a voltage and current supply adapted to the respective luminous means, for example and in particular an LED or a plurality of LEDs. This adaptation can also be variable, d. H. Adjustments can be made with the aid of which the illuminant can be dimmed, for example, or adapted with regard to the emitted color spectrum. In general, separate control devices are used to interact with the operating device. The operating device has to control terminals over which the command signals are received. It is problematic if such, an operating device requiring bulbs are used in exchange for conventional bulbs, such as light bulbs. Usually, no control line is provided on the building side and retrofitting is correspondingly expensive.

In order to simplify the replacement of obsolete bulbs with modern bulbs, bulbs have been developed in the past, in which the operating device is housed in a screw base. Thus, the light source and the operating device are integrated together in a bulb-like lamp. In order to be able to provide the operating device with information which correspond to user commands for example, it goes without saying that in such a case a separate control line is not available. In the past, therefore, possibilities have already been created for transmitting information about the operating device via lines with which a voltage and current supply takes place. Such a system is for example from the DE 10 2012 206 056 A1 known. Here it is described that the pulsating supply voltage information can be impressed by, for example, a temporary rectification of the AC voltage. As an alternative, it is also described to use phase cuts or phase sections. In principle, any change in the voltage profile can be used to transmit information, as long as the receiving side, in this case the operating device, is able to recover the information.

According to the DE 10 2012 206 056 A1 To recover this information, a current flow is generated via a measuring resistor and the associated voltage drop is measured. For the positive and for the negative half-wave of the supplied supply voltage different voltage drops are generated at the measuring resistor, since two resistors of different dimensions are provided between the L-wire and the N-wire. The midpoint of these two resistors is connected to the sense resistor to produce the already described current flow. During the measurement, only one of the two resistors is connected in series with the measuring resistor in the current path.

The problem with the circuit described is that the detection of phase sections or phase sections can not always be performed reliably. Disturbances, as they occur, for example, by parasitic capacitances, in particular in the region of the zero crossing of the pulsating supply voltage, make it difficult to reliably detect a phase cut.

It is therefore an object of the invention to provide a control device for lighting means and a method for the reliable determination of a supply voltage impressed information. For the sake of uniform representation, it is assumed below that such information is impressed as a phase angle or phase section of the supply voltage. However, the operating device according to the invention and the method can readily recognize, for example, the transition from a pulsating supply voltage to a DC voltage. Such a situation can occur if switching to an emergency power supply takes place due to a power failure, which is usually operated from an accumulator or a battery and thus feeds a DC voltage into the supply network. Targeted switching of polarities in the pulsating power supply can also be detected.

The operating device according to the invention has a first input terminal and a second input terminal. By means of these connections, the operating device can be connected to a pulsating supply voltage source in order to supply electrical power to the operating device with which a lighting device connected to the operating device can be supplied. The operating device further comprises detection means, which enable separate detection of a first voltage, which corresponds to a positive half-wave, and a second voltage, which corresponds to a negative half-wave of the supply voltage. The measurement signals generated by the detection means based on the first voltage and the second voltage are used for further determination of the information. This is an evaluation provided for evaluating these measurement signals.

According to the invention, a first voltage divider is arranged between the first input terminal and a ground potential of the operating device as detection means, and a second voltage divider is arranged between the second input terminal and the ground potential. With the aid of the first voltage divider, a first measurement signal for the first voltage is generated, and with the aid of the second voltage divider, a second measurement signal for the second voltage is generated. The measuring signals are the voltages picked up at the respective center points of the voltage dividers. These are fed to the evaluation unit.

In contrast to the prior art, the advantage in the described procedure is that there are two independent signals, each signal being associated with one half-wave of the supply voltage. The difference between these two signals makes it possible to obtain an accurate image of the original supply voltage. In contrast to the prior art, parasitic capacitances therefore do not have a negative effect. In particular, when using phase slices or phase sections for transmitting information to the operating device so that the robustness of the detection is significantly improved.

In the dependent claims advantageous developments of the operating device according to the invention are executed.

As already explained above, the evaluation unit is supplied with two input signals, wherein each input signal is to be assigned to a half-wave of the pulsating supply voltage. In the evaluation then a difference signal is formed. The further evaluation can then take place on the basis of this difference signal, it being particularly advantageous that the described signal errors can be avoided by parasitic effects, in particular in the region of the zero crossing.

Furthermore, rectification of the difference signal is preferably carried out. The processing performed in the evaluation unit preferably takes place digitally, for which purpose the two measurement signals are digitized before the further processing, in particular before the formation of the difference signal.

Finally, before the result of this evaluation is supplied to a control unit, the rectified differential signal is supplied to a comparator, an integrating circuit or a differentiating circuit. With the aid of the comparator, the integrating circuit or the differentiating circuit, the information which was impressed on the operating voltage supplied to the operating device can be more easily recognized in the control unit. The resulting signal curves are characteristic for the impressed information and are made visible by means of the comparator, the integrating circuit or the differentiating circuit.

Further features, advantages and features of the present invention will be explained below with reference to the accompanying drawings with reference to embodiments.

Show it:

1 a representation of the basic structure of a system in which the present invention is used,

2 a diagram for illustrating the disadvantages of the prior art and the advantage of the inventive solution,

3 a schematic representation of a control gear with attached light source,

4 a detailed representation of a part of the operating device according to the invention,

5 a schematic representation of the evaluation unit of the operating device according to the invention and the subsequent control unit,

6 a diagram illustrating the procedure for obtaining the difference signal in the evaluation, and

7 a diagram for explaining the processing further processing of the difference signal in the evaluation unit.

The invention finds z. B. Application in the field of so-called. Retrofit LED lamps that replace z. B. of incandescent or halogen lamps are used. Retrofit lamps accordingly have connection socket, with which they are introduced into known lamp sockets, z. B. screwed or plugged, can be. However, the invention can be used whenever information is to be transmitted to an operating device, but for the transmission of information only supply lines are available. This can of course also be the case with an external operating device.

LED lamps have one or more LED (s), of which at least one preferably emits white light with color conversion. However, alternatively or in addition to the one or more White LED (s) also monochromatic, preferably in the red spectrum emitting LEDs are present.

With a view to 1 By way of example, a schematic structure of a lamp or retrofit lamp, in particular retrofit LED lamps, with integrated operating device will now be described. However, it is to be understood that other, appropriately designed operating devices for lighting means should be included. The retrofit LED lamp L according to the present invention includes a screw base 2 , a glass flask 3 and lighting, z. As one or more inorganic LED or OLED bulbs 8th , Other bulbs, such as, for example, halogen lamps or gas discharge lamps can be operated by the operating device.

The screw base 2 is suitable for a socket of a corresponding incandescent lamp, which is to be replaced by the retrofit LED lamp L. A metal screw thread 5 and an end pole 4 The lamp L form terminal contacts, via which the retrofit LED lamp L from a signal generator 1 a supply voltage Vmains is supplied. The supply voltage Vmains is based on the mains AC voltage VN from the signal generator 1 generated.

The signal generator 1 includes a switch S and a push-button T. Upon actuation of the switch S, the signal generator 1 separated from the AC mains voltage VN, so that the output side no supply voltage Vmains is present. The button T is responsible for manipulating the mains voltage VN. If this button T is not pressed, the supply voltage Vmains corresponds to the mains voltage VN. On the other hand, the waveform of the supply voltage Vmains is changed as long as the button T is pressed. It is also possible to provide a plurality of buttons, so that a plurality of different forms of the supply voltage Vmains can also be generated. The manipulation of the mains voltage is carried out in accordance with a specific protocol which determines which information to be transmitted is to be transmitted by means of which voltage curve.

The arrow 9 indicates that and how the supply voltage Vmains z. B in the form of AC half-waves to a located in the LED lamp L operating device 6 is forwarded. The operating device 6 generates a DC voltage which - as indicated by the arrow 10 is indicated - an LED module 7 is supplied, on which the light emitting LEDs 8th to sit.

For a better understanding of the following description of the details of the invention is first based on the diagram of the 2 the problem in determining information impressed on the supply voltage will be explained. As already stated, it is assumed for the following explanations that information is impressed on the supply signal by using phase slices or phase sections. Other possibilities, such as, for example, temporary rectification of the supply voltage, are however permitted and can also be evaluated with the aid of the invention in a particularly reliable and simple manner.

First is in the 2 the course of a supply voltage Vmains shown. The course shown shows no additional information contained and thus the pure, not manipulated supply voltage. The supply voltage Vmains is composed of positive and negative half-waves, which in the diagram are labeled "lpar" and "npar". Compared with the internal equipment ground potential, these half-waves are always positive. It can be seen that the half-waves labeled "lpar" are each distorted as they rise from 0 volts. Such deformations in the signal curve arise, for example, due to parasitic capacitances and are thus unavoidable in practice. If now the further evaluation is based on a common mode signal, as it is in the 2 with "comode" in the diagram of the 2 are shown, it is precisely these areas that would coincide with a phase angle or phase portion that are affected by such distortions in the range of the zero crossing. The finding and evaluation of the phase cuts is thus made more difficult. The area highlighted in the diagram 21 clearly shows the disturbance in the waveform. The signal does not fall here, as would be the case with an undisturbed signal, down to 0 volts. According to the invention, a difference signal is now used instead of such a common-mode signal. This causes the resulting distortions in the two signals "lpar" and "inpar" to exist so that they cancel each other out. If you look at the difference between "lpar" and "npar" you get that in the diagram of 2 signal denoted "diffmode", which corresponds exactly to the input signal, that is to say the supply voltage Vmains as an image.

To the representation becomes in the 2 used a 220 volt AC, as is standard in Europe, for example.

In the 3 is now an inventive operating device 6 shown in a highly simplified representation. The operating device 6 is supplied with a supply voltage Vmains, as indicated by the arrow 9 is shown. In the 3 is shown that over the operating device 6 an LED module 7 with an LED bulb 8th with electrical power is supplied. In addition, it is indicated that in addition to this LED module 7 also at least one more LED module 7 ' may be provided whose structure is either equal to the LED module 7 or different from the LED module 7 is. So that the LED modules 7 . 7 ' can be operated at the supply voltage Vmains, a rectification of this AC voltage is required. For this purpose, the supply voltage Vmains an AC / DC converter 11 fed and the rectified AC voltage then a DC / DC converter 12 forwarded. To a variable operation of the LED module 7 to enable the DC / DC converter 12 from a control unit 15 which specifies parameters, their implementation by the DC / DC converter 12 a z. B. allows dimming. The basic procedure for dimming or changing the color value of the emitted light of the LED module 7 this does not differ from systems known per se, in which information on the operating device is provided via separate control lines 6 be transmitted.

In the operating device according to the invention 6 However, the information is not transmitted via separate control lines, but the supply voltage is impressed by manipulation of the temporal voltage curve and then in the operating device 6 extracted from the supply voltage again. This results in a control command from the control unit 15 generated and, as indicated by the arrow 16 is indicated, the DC / DC converter 12 fed to the implementation.

According to the invention are now detection means 13 provided, with which a first voltage and a second voltage are determined separately from each other. The first voltage is the voltage of the first terminal of the operating device 6 , ie the L-conductor, compared to the ground potential of the operating device 6 , The second voltage is accordingly the voltage of the second terminal of the operating device 6 , ie the N conductor, compared to the ground potential of the operating device 6 , In the manner described below, measuring signals are generated from the voltages. These measurement signals, referred to as mains1 or mains2, then become the evaluation unit 14 supplied, in which a further processing of the measuring signals mains1 and mains2 takes place. By processing the measuring signals in the evaluation unit 14 a signal characteristic characteristic of the originally impressed information is generated in the control unit 15 is evaluated. The control unit 15 determines the control command underlying this signal and generates a control signal for driving the DC / DC converter 12 ,

The generation of the measuring signals mains1 and mains1 will now be based on the 4 described, making it a part of the control gear 6 in more detail shows. The supplied supply voltage Vmains is supplied by the operating device 6 received at a first input terminal L and a second input terminal N. It can first be done preprocessing of the supply voltage Vmains, for example, for filtering unwanted portions of the supply voltage Vmains. In the 4 For example, shown is a capacitance C02 provided between the first input terminal L and the second input terminal N, that is, between the L-wire and the N-wire, and inductors L01 provided in each branch. The two branches, L and N, are both with the detection means 13 as well as with the AC / DC converter 11 connected. In the 4 is still a capacity C10 shown with the output terminals of the bridge rectifier (AC / DC converter 11 ) is connected to smooth the wavy DC voltage obtained there. This capacitance C10 is between the positive output terminal of the bridge rectifier and the ground potential of the control gear 6 arranged. The detection means 13 consist of at least a first voltage divider 22 and a second voltage divider 23 , The first voltage divider 22 includes a series connection of a first resistor R1 with a second resistor R2. The series circuit is connected to the L branch, ie the first input terminal on the one hand and the ground potential of the operating device 6 on the other hand. At the lying between the two resistors R1 and R2 first center point M1, a first measurement signal is tapped, which is designated mains1.

The second voltage divider 23 Also includes two resistors, namely a third resistor R3 and a fourth resistor R4, which are also connected in series. The second voltage divider 23 is on the one hand with the N branch (second input terminal) and on the other hand also with the ground potential of the operating device 6 connected. At the second center point M2 of the second voltage divider 23 a second measuring signal is tapped, which is referred to as mains2.

In the 4 Furthermore, it can be seen that both the first center point M1 and the second center point M2 additionally have a respective capacitance C03 or C04 with the ground potential of the operating device 6 are connected. With the help of these capacitances C03, C04 unwanted harmonics can be removed from the tapped first measuring signal mains1 and the tapped second measuring signal mains2. Schematically is in the 4 still showing how the two measuring signals look like: They form the respective half-wave of the L-branch or the N-branch with respect to the ground potential of the operating device 6 from, the amplitudes due to the voltage divider 22 . 23 lower than the first and the second voltage of the L or N conductor relative to the ground potential.

In the 4 Furthermore, a parasitic capacitance C _{p is} given, which for the zu 2 explained interference in the common-mode signal is responsible. Since this parasitic capacitance C _{p is of} course not an explicit part of the circuit, it has been drawn in dashed lines in the illustration.

The 4 is a schematic representation and it is therefore understood that in a real circuit to adapt to the specific circumstances even more components are available. Is exemplary in the 4 still a capacitance C1 and an inductance L02 specified, which serve to stabilize the ground potential.

The further processing of the measuring signals mains1 and mains2, which at the midpoints M1 and M2 of the independent voltage divider 22 and 23 are now based on the 5 explained. The 5 shows the evaluation unit 14 of the 3 in a more concrete embodiment. The two measuring signals mains1 and mains2 are first of all a means for forming a difference signal 17 fed. For this purpose, the values of the measuring signal mains2 are subtracted, for example, from the values of the measuring signal mains1. The result is a difference signal. The difference signal then becomes a means for rectifying the difference signal 19 fed. Its output signal, that is, the rectified differential signal, will then actually detect whether the supply voltage Vmains has been impressed by changing the signal form of the supply voltage Vmains, at least fed to an analysis device. In the illustrated embodiment, a comparator for analysis 25 , a differentiating circuit 26 and an integrating circuit 27 shown. With the help of the comparator 25 the rectified differential signal is compared with a reference voltage V _Ref . The output signal Vout of the comparator 25 indicates at which point in time the rectified differential signal was above a threshold defined by the reference voltage V _Ref . The resulting course of the output voltage Vout of the comparator 25 can then be compared with a pattern. Different patterns represent different transmitted information. If the output voltage Vout matched, the supply voltage Vmains was thus impressed with information that corresponds to the control command assigned to this pattern. This check whether the course of the output voltage Vout of the comparator 25 a control command, takes place in the control unit 15 , For this purpose, the output signal Vout of the comparator 25 supplied to a logic. The command determined by this logic then becomes a device 20 fed, which generates a control signal with which then as 3 already explained, the DC / DC converter 12 is controlled.

Alternatively or in addition to the comparator 25 can also be a differentiating circuit 26 be provided. As differentiation circuit 26 For example, a high pass can be used. That at the output AA of the differentiating circuit 26 output signal is again the logic of the control unit 15 supplied for determining an associated control command. In the logic of the control unit 15 becomes the occurrence of values above a threshold at the output AA of the differentiating circuit 26 and, if appropriate, assigned to an underlying command or an underlying information that was impressed on the supply voltage Vmains.

The rectified differential signal may also be an integrating circuit 27 , realized for example as a low-pass filter, be supplied. The low-pass filtering corresponds to the formation of an average value MW. This mean value, or its time course, is likewise characteristic of the original signal form of the supply voltage Vmains and thus also suitable for detecting impressed information. This mean value is also the logic of the control unit 15 supplied to the recognition of commands.

The processing of the two measuring signals mains1 and mains2 in the evaluation unit 14 is preferably done digitally. For this purpose, the two measuring signals mains1 and mains2 are digitized in a device, not shown, before they are supplied for further processing.

Based on 6 and 7 The processing of the measuring signals mains1 and mains2 will be explained again below, as already briefly described above with reference to FIGS 4 and 5 took place. In 6 First, a supply voltage is shown, which is impressed information, referred to here as mains. The impressing of the information in the example shown is a phase control of the negative half-wave. With the help of the first voltage divider 22 the detection device 13 the voltage curve of the positive half cycle of the mains mains voltage is detected. The measuring signal mains1 is thus a signal that reflects the potential profile of the L-conductor with respect to the ground potential of the operating device. It thus corresponds to the positive half-wave of the mains supply voltage.

In the range of negative half-waves, the measuring signal mains1, however, is largely 0, wherein the transition to the in the 6 shown second half-wave interference by the parasitic Capacity is recognizable. It should also be noted that the amplitude of the measuring signal mains1 is determined by the selected resistances of the first and the second resistor R01, R02. For ease of calculation, the two voltage dividers 22 and 23 be the same size. With a symmetrical alternating voltage, as in the uppermost part of the diagram of the 6 is shown, thus the amplitudes of the measuring signals mains1 and mains2 are the same. In the third part of the diagram of the 6 the time profile of the second measuring signal mains2 is shown, with the aid of the second voltage divider 23 is generated for the N conductor. In this case, the temporal potential profile of the second input terminal N is reproduced relative to the ground potential by the second measuring signal mains2. It can be seen that the amplitude of the half-wave of the measuring signal mains1 and the half-wave of the measuring signal mains2 are the same and that the phase angle in the second measuring signal mains2 can be clearly recognized. Also to be recognized is again the fault in the area of the zero crossing of the mains supply voltage.

The lowest part of the diagram now shows the time profile of the difference signal Diffmains, which is formed from the first measuring signal mains1 and the second measuring signal mains2. The disturbances which were detectable in the region of the zero crossing of the mains supply voltage in the two measuring signals mains1 and mains2 compensate each other, so that the differential signal Diffmains in its course corresponds exactly to the original mains supply signal except for a proportionality factor. This signal "diffmains", with the means for forming a difference signal 17 in the evaluation unit 14 was generated is the basis for further evaluation.

The sequence of the further evaluation is in the 7 shown, wherein the difference signal for the sake of completeness in the top part of the diagram is shown again. Starting from the difference signal, the amount of the difference signal "absns" is now formed, which is in the evaluation unit 14 with the help of the means of rectification 19 the difference signal takes place. Since the difference signal "diffmains" has no interference even in the region of its zero crossing, the rectified differential signal "absns" actually drops to 0 during the transition from the negative half-wave to the positive half-wave of the mains supply voltage mains. The above in explaining the problem with reference to the 2 explained distortion of the common-mode signal does not occur here.

This rectified difference signal "absns" is now, as briefly with reference to 5 has already been explained, a comparator 25 , a differentiating circuit 26 or an integrating circuit 27 or more thereof. The course of the output voltage Vout of the comparator 25 is in the diagram of 7 denoted by "cmp". The reference voltage V _{ref of} the comparator 25 is set to a small, positive value, for example, 0.1 volts. While in the areas of the phase angle, the rectified differential signal is relatively long below this threshold, at zero crossing at the transition from the negative half-wave to the positive half-wave of the differential signal, the rectified differential signal "absns" only relatively short below this threshold. This results in the time course, as shown in the third part of the diagram and is referred to as "cmp". It can be seen that the course of "cmp" in the area of the phase angle falls significantly longer in time than in the area of a zero crossing of the difference signal "diffmains" without a phase angle or section, which reliably detects the existence of a phase angle (or phase angle). section). By means of different phase cuts, combinations with phase sections and / or temporal pauses between the phase gates, more complex information can also be transmitted, depending on a defined communication protocol.

Also with the help of the integrating circuit 27 the rectified difference signal "absns" can be evaluated. The resulting waveform at the output of the integrator 27 is the "int" in the fourth part of the diagram 7 designated. Again, there is a significant difference between the range corresponding to the phase angle in the supply voltage and the range without phase angle. The signal only drops to zero in the area of the phase angle, so that the zeros can be used to determine the existence of a phase angle. Finally, in the bottom of the diagram is the 7 nor the output signal at the terminal AA of the differentiating circuit 26 shown. As a result of the steep rise at the end of the phase angle, a peak on the side of the control unit results in the time course of this signal "diff" 15 can be easily detected.

All evaluations have in common that the determination of the temporal position of the detected phase cuts can be used to identify different commands. The resulting patterns have to correspond only to a specific protocol, which concretizes the use of phase cuts and phase sections for impressing information on the supply voltage.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102012206056 A1 [0003, 0004]

Claims (10)

Operating device for lighting means, comprising: a first input terminal L and a second input terminal N, by means of which the operating device ( 6 ) is connectable to a supply voltage source, detection means ( 13 ), for separately detecting a first voltage, which corresponds to a positive voltage component of the supply voltage "mains", and a second voltage, which corresponds to a negative voltage component of the supply voltage "mains", and an evaluation unit ( 14 ) for evaluating the detected voltages, characterized in that as detection means ( 13 ) between the first input terminal L and a ground potential of the operating device ( 6 ) a first voltage divider ( 22 ) is arranged to generate a first measurement signal mains1 and between the second input terminal N and the ground potential, a second voltage divider ( 23 ) is arranged to generate a second measurement signal mains1 and that the detection means ( 13 ) for supplying the two measuring signals mains1, mains1 with the evaluation unit ( 14 ) are connected. Operating device according to claim I, characterized in that the evaluation unit ( 14 ) Means for forming a difference signal ( 17 ) from the first measuring signal mains1 and the second measuring signal mains2. Operating device according to claim 1 or 2, characterized in that the evaluation unit ( 14 ) Means for rectifying the difference signal ( 19 ) contains. Operating device according to claim 3, characterized in that the evaluation unit ( 14 ) a comparator ( 25 ), an integrating circuit ( 27 ) or a differentiating circuit ( 26 ), to which the rectified differential signal or the amplified and rectified differential signal is supplied. Operating device according to one of claims 1 to 4, characterized in that the evaluation unit ( 14 ) Has means for digitizing the first and second measurement signals. Method for determining a supply voltage "mains" of impressed information by an operating device ( 6 ), whereby the operating device ( 6 ) is supplied via a first terminal L and a second terminal N, the supply voltage "mains", generating a first measurement signal "mains1" by means of a first, between the first terminal L and a ground potential arranged voltage divider ( 22 ), and a second measurement signal "mains2" by means of a second, between the second terminal N and the ground potential arranged second voltage divider ( 23 ), Feeding the first measuring signal "mains1" and the second measuring signal "mains2" to an evaluation unit ( 14 ), and evaluating the two measuring signals "mains1", "mains2" in the evaluation unit ( 14 ). A method according to claim 6, characterized in that from the two measuring signals "mains1", "mains2" a difference signal "diffsns" is generated. A method according to claim 7, characterized in that the difference signal "diffsns" is rectified. A method according to claim 10, characterized in that the rectified difference signal "diffsns" is compared with a reference value V _ref , integrated or differentiated. Method according to one of claims 7 to 11, characterized in that the two measuring signals "mains2", "mains2" are digitized.

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