AT16613U1 - Operating circuit for supplying a lamp, LED converter and method for operating an operating circuit - Google Patents

Abstract

An operating circuit for supplying a light source (5), which comprises at least one light emitting diode (6), has a primary side (11) and a secondary side (12) which is electrically isolated therefrom. The operating circuit comprises a clocked converter (14) which comprises a primary coil and a secondary coil (18). The operating circuit comprises a detection device (20) for determining an output voltage (Vout) of the operating circuit, the detection device (20) being an inductor (21) which is arranged on the primary side (11) of the operating circuit and is inductively coupled to the secondary coil (18), includes.

Description

OPERATING CIRCUIT FOR SUPPLYING A LUMINAIRE, LED CONVERTER AND METHOD FOR OPERATING AN OPERATING CIRCUIT The invention relates to an operating circuit for supplying a lamp, an LED converter and a method for operating such an operating circuit. The invention relates in particular to devices and methods of this type in which an illuminant, in particular an illuminant, which comprises one or more light-emitting diodes, is supplied with energy by an operating circuit which has electrical isolation.

Converters with electrical isolation are used for the galvanically decoupled transmission of electrical energy from an input side to an output side. Such converters are used in various applications for supplying current or voltage, such as, for example, in switched mode power supplies. In the case of clocked converters, controllable switches, which can be in the form of circuit breakers, are used and operated in a clocked manner in order to transmit electrical energy to the output side. A galvanically decoupled energy transmission can be achieved by using a transformer or other transformer. Such a potential separation is required, for example, for safety reasons in the case of operating devices for lamps, in order to separate an ELV (“extra-low voltage”) area from areas with a higher voltage by means of a potential barrier.

To control or regulate the converter, information about an output voltage of the converter may be required. In the case of converters clocked on the primary side, this can be achieved by detecting the output voltage on a secondary side of the converter and transmitting it to the primary side via the potential barrier. Optocouplers can be used for this. This leads to increased costs and effort.

There is a need for devices and methods in which the circuit complexity and / or the costs associated with conventional devices for bridging a potential barrier can be reduced or avoided. There is a need for such devices and methods that enable the output power to be controlled or regulated during operation.

According to embodiments, an operating circuit, an LED converter and a method are specified with the features specified in the independent claims. The dependent claims define embodiments.

According to embodiments of the invention, an inductance on a primary side of an operating circuit is used to detect an output voltage of the operating circuit for a lamp. The inductance is inductively coupled to a secondary coil of a converter of the operating circuit.

[0007] The inductance can comprise, for example, a winding different from the primary coil of the converter.

[0008] To determine the output voltage, a maximum value of the voltage across the inductance can be detected in at least one switching cycle of the clocked converter. A voltage correction can be subtracted from the maximum value in order to determine the output voltage. The voltage correction can depend on an output current of the operating circuit. The voltage correction can depend on a differential resistance of a diode and on the output current.

According to one embodiment, an operating circuit for supplying a lamp, which comprises at least one light emitting diode, is specified. The operating circuit has a primary side and a galvanically isolated secondary side. The operating circuit comprises a clocked converter. The operating circuit comprises a detection device for determining an output voltage of the operating circuit, wherein the detection device comprises an inductance arranged on the primary side of the converter

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AT 16 613 U1 2020-02-15 Austrian patent office is inductively coupled to a secondary coil on the secondary side of the converter.

A voltage detected with the inductance on the primary side can thus be processed in order to determine the output voltage. Detection of the output voltage in the secondary circuit and feedback via the SELV barrier is no longer absolutely necessary. Power regulation can take place depending on the voltage detected on the primary side with the inductance, without the output voltage having to be detected in the secondary circuit.

The detection device can be set up to determine the output voltage depending on the voltage across the inductor and depending on an output current of the operating circuit. In this way, a possible voltage drop between the secondary coil and an output of the operating circuit can be taken into account.

The detection device can be set up to determine the output voltage as a function of a maximum value of the voltage across the inductance and as a function of the output current. The maximum value can be determined in at least every second switching cycle of the clocked converter.

The detection device can be set up to determine the output voltage as the difference between the maximum value of the voltage and a voltage correction dependent on the output current.

A diode can be provided between the secondary coil and an output of the operating circuit. The voltage correction can be a product of the output current and a differential resistance of the diode.

The operating circuit may include a transformer for sensing the output current. The transformer can comprise at least one secondary-side inductance, which is connected between the secondary coil and the diode, and a primary-side inductance coupled therewith.

The operating circuit can be set up to switch at least one controllable switch of the converter in a clocked manner depending on the specific output voltage.

The operating circuit can be set up to set a switching frequency and / or a switching threshold value for the at least one controllable switch depending on the output voltage.

The operating circuit can be set up for a power control and / or a power limitation of an output power of the operating circuit depending on the output voltage.

The inductance, which is inductively coupled to the secondary coil, can be different from a primary coil of the converter.

The converter can be an LLC resonance converter with half-bridge control, clocked on the primary side.

An LED converter according to one embodiment comprises the operating circuit according to an embodiment.

A system according to an embodiment comprises the LED converter according to an embodiment and a lamp which is connected to the output of the operating circuit. The illuminant comprises at least one light emitting diode.

According to one embodiment, a method for operating an operating circuit for supplying a lamp, which comprises at least one light emitting diode, is specified. The operating circuit has a primary side and a galvanically isolated secondary side. The method comprises clocked switching of at least one controllable switch of a converter. The method comprises determining an output voltage of the operating circuit as a function of a voltage at an inductance on the primary side of the

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AT 16 613 U1 2020-02-15 Austrian patent office

Converter, wherein the inductance is inductively coupled to a secondary coil of the secondary side of the converter.

In the method, the output voltage can be determined depending on the voltage across the inductor and depending on an output current of the operating circuit. In this way, a possible voltage drop between the secondary coil and an output of the operating circuit can be taken into account.

In the method, the output voltage can be determined depending on a maximum value of the voltage across the inductor and depending on the output current. The maximum value can be determined in at least every second switching cycle of the clocked converter.

In the method, the output voltage can be determined as the difference between the maximum value of the voltage and a voltage correction dependent on the output current.

A diode can be provided between the secondary coil and an output of the operating circuit. The voltage correction can be a product of the output current and a differential resistance of the diode.

[0028] The method may include sensing the output current using a transformer. The transformer can comprise at least one secondary-side inductance, which is connected between the secondary coil and the diode, and a primary-side inductance coupled therewith.

The at least one controllable switch of the converter can be switched clocked depending on the specific output voltage.

[0030] A switching frequency and / or a switching threshold value for switching the at least one controllable switch can be set as a function of the output voltage.

The at least one controllable switch can be switched in a clocked manner in such a way that a power control and / or a power limitation of an output power of the operating circuit takes place as a function of the output voltage.

The inductance, which is inductively coupled to the secondary coil, can be different from a primary coil of the converter.

The method can be carried out automatically by the operating circuit or the LED converter according to one embodiment.

The invention is explained in more detail below with reference to the accompanying drawing using preferred exemplary embodiments.

[0035] FIG. 1 shows a schematic representation of a lighting system with an LED converter according to an embodiment. [0036] FIG. 2 [0037] FIG. 3 shows a circuit diagram of an operating circuit according to an embodiment, shows a circuit diagram of an operating circuit according to another embodiment. [0038] FIG. 4 shows a circuit diagram of an operating circuit according to a further embodiment. [0039] FIG. 5 shows a circuit diagram of an operating circuit according to a further embodiment. [0040] FIG. 6 illustrates a voltage sensed on a primary side of a converter for determining the output voltage. [0041] FIG. 7 illustrates the determination of the output voltage depending on the voltage detected on the primary side.

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AT 16 613 U1 2020-02-15 Austrian Patent Office [0042] FIG. 8 is a flowchart of a method according to an embodiment.

The invention is described in more detail below using exemplary embodiments with reference to the figures, in which identical reference numerals represent identical or corresponding elements. The features of different exemplary embodiments can be combined with one another, unless this is expressly excluded in the description. Even if some exemplary embodiments are described in more detail in the context of specific applications, for example in the context of operating devices for LED modules, the exemplary embodiments are not restricted to these applications.

[0044] FIG. 1 shows a system 1 in which an LED converter 3 supplies a light source 5 with energy according to one exemplary embodiment. The illuminant 5 can comprise a light emitting diode (LED) or a plurality of LEDs. The LEDs 6 can be inorganic or organic LEDs.

During operation, the LED converter 3 is coupled on the input side to a supply voltage source 2, for example a mains voltage. The LED converter 3 can include a rectifier 13. The LED converter 3 can optionally comprise a power factor correction formwork (PFC, “Power Factor Correction”) 13. The LED converter 3 comprises a converter 14. The converter 11 can be a DC / DC converter.

The converter 14 is designed as a clocked converter and has a controllable switch 16. The controllable switch 16 can be a circuit breaker. Controllable switch 16 may be an insulated gate transistor. Controllable switch 16 may be a MOSFET. As will be described in detail below, the converter 14 is a converter clocked on the primary side, in which a control device 19 switches the controllable switch 16 clocked. While only one controllable switch 16 is shown schematically in FIG. 1, the converter 14 can also have a plurality of controllable switches on the primary side, for example for a half-bridge control of the converter 14.

The converter 14 can have electrical isolation. A primary side of the converter 14 and a secondary side of the converter 14 can be electrically isolated. This enables a potential separation between different areas 11, 12 of the LED converter to be generated. The output side 12 with the secondary side of the converter can be designed as a SELV (“Separated Extra Low Voltage”) area and can be separated from the input side 13 by a SELV barrier 10. The potential barrier 10 does not necessarily have to be a SELV barrier, but can also be another potential barrier.

The LED converter 3 can optionally have an output circuit 15 which is coupled to a secondary coil 18 of the converter 14.

The LED converter 3 is set up to determine an output voltage at the output of the LED converter 3 by a voltage measurement that is carried out on the primary side 11. For this purpose, the operating circuit of the LED converter 3 can comprise a device 20 for determining the output voltage. The device 20 comprises an inductor 21 which is arranged on the primary side 11 of the operating circuit and is thus galvanically isolated from the output of the operating circuit. The inductor 21 is inductively coupled to the secondary coil 18 of the converter 14.

As will be described in more detail, a voltage across inductor 20 can be sensed and further processed to determine the output voltage. A maximum value of the voltage at the inductor 20 can be detected. The maximum value of the voltage at the inductor 20 itself or a variable derived therefrom can be used as a parameter for the output voltage. For example, a correction term can be subtracted from the maximum value of the voltage at inductor 20, which is detected in one or more switching cycles of clocked converter 14. The correction term can depend on an output current of the LED converter 3.

The inductance 21 can be different from a primary coil (not shown in FIG. 1) of the converter 14. The device 20 can be set up so that the primary side

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Voltage detection is not carried out at the primary coil of the converter 14 itself, but at an inductance 21 different therefrom. The risk of falsification due to leakage inductances can thus be reduced. The output voltage can be determined more reliably.

The inductor 21 can be arranged closely coupled to the primary coil and the secondary coil of the converter 14. The inductor 21 can be arranged on the same transformer core as the secondary coil 18 and the primary coil of the converter 14.

The device 20 may comprise a voltage divider for tapping the voltage on the inductor 21. The voltage divider can be an ohmic voltage divider.

As shown in FIG. 1 is shown schematically, the output voltage can be determined in the LED converter 3 without a measurement having to be carried out on the SELV side and / or without a corresponding measurement result having to be fed back via the SELV barrier. The control device 19 can be set up such that it can determine the output voltage of the LED converter 3 as a function of a voltage measured on the primary side and can use it, for example, for power regulation.

[0055] FIG. 2 is a circuit diagram of an operating circuit 39 according to an embodiment. The operating circuit 39 comprises a converter with a primary-side circuit 40 and a secondary-side circuit 50. There is potential isolation between the primary-side circuit 40 and the secondary-side circuit 50. A transformer with a primary coil 17 and a secondary coil 18 can be provided for separation.

The transducer can be designed as an LLC resonance transducer. The main inductor of the transformer can act as one of the inductors of the LLC resonant circuit. A separate inductive element 43 or a leakage inductance of the transformer can act as a further inductance of the LLC resonant circuit. A capacitive element or a stray capacitance can form a capacitance of the LLC resonant circuit. According to the general terminology in this technical field, the term “LLC resonance circuit” or “LLC resonance converter” is used here to mean a resonance circuit with two inductors and one capacitance or a corresponding converter, it being irrelevant whether as in FIG. 2, one of the inductors is connected between the capacitance 45 and the inductor 43 or whether the capacitor is connected between the two inductors. Likewise, the inductor 43 can be integrated into the primary coil 17 of the transformer as a leakage inductor.

[0057] The converter can be a DC / DC converter. The secondary-side circuit 50 can be a SELV region, which is separated from the primary-side region by a SELV barrier 10. The primary circuit can contain all components that do not belong to the SELV range.

The primary-side circuit 40 comprises a half-bridge circuit with a first switch 41, which can be a circuit breaker, and a second switch 42, which can be a circuit breaker. The first switch 41 and the second switch 42 can be identical, and the half-bridge circuit can be designed as a symmetrical half-bridge circuit. The resonance circuit is connected to a node between the first switch 41 and the second switch 42. The resonance circuit is connected to the center of the half-bridge circuit between the two switches 41 and 42. A first connection of the first inductor 43 of the LLC resonant circuit can be connected to the node between the first switch 41 and the second switch 42 of the half-bridge circuit. A second connection of the first inductance 43 can be connected to a first connection of a further inductance of the LLC resonance circuit. A second connection of the further inductance can be connected to the capacitance 45 of the resonance circuit.

In the operation of the converter 39, the control device 19 controls the first switch 41 and the second switch 42. Each of the switches can be switched on and off with the same predetermined frequency. The control device 19 can the first switch 41

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AT 16 613 U1 2020-02-15 Austrian patent office and control the second switch 42 so that a maximum of one of the two switches is always turned on. The first switch 41 and the second switch 42 can be operated alternately clocked by the control device 19. A dead time between switching off a switch and switching on the other switch can be short, in particular much smaller than the inverse of the switching frequency.

The primary-side circuit 40 is designed such that a voltage V_sns can be detected, which is induced on the inductor 21. The inductance 21 is different from the primary coil 17, so that the voltage detection is not carried out directly on the primary coil 17. The inductor 21 is inductively coupled to the secondary coil 18.

The secondary-side circuit 50 has a rectifier connected to the secondary coil 18, which can be formed, for example, by a first diode 51 and a second diode 52. An output capacitor 53 can be provided. The output capacitor 53 can be coupled directly or via an optionally available inductor 54 to an output 55 of the operating circuit.

A load 5 connected to the output 55 of the operating circuit can comprise one LED, one LED section, several LEDs or several LED sections. The LEDs can be LEDs of an LED module.

The output voltage at the output 55 of the operating circuit is determined based on the voltage V_sns detected in the primary-side circuit 40. The voltage V_sns detected in the primary-side circuit 40 at the inductance 21 is supplied to the control device 19. The voltage V_sns detected in the primary-side circuit 40 at the inductance 21 can be A / D converted before it is supplied to the control device 19.

When the switches 41, 42 of the half-bridge circuit are switched, energy is transferred until the capacitor 53 is charged. The load 5 clamps the voltage across the capacitor 53 to a value that corresponds to the forward voltage of the LEDs of the lamp. The voltage on the secondary coil corresponds to the output voltage of the circuit minus the voltage drop across the rectifier diodes 51, 52.

Correspondingly, information about the output voltage at the output 55 can be derived from the maximum value of the voltage that occurs on the secondary coil 18 when the switches 41, 42 are switched. For this purpose, the maximum value of the voltage at the inductor 21 is detected, for example, via a voltage divider 22.

The voltage divider 22 can be a high-resistance voltage divider. The voltage divider 22 can be an ohmic voltage divider with at least two resistors 23, 24. A diode 25 can optionally be provided in parallel with a resistor 24 of the voltage divider. The diode 25 can serve to protect a subsequent A / D converter and / or a subsequent integrated semiconductor circuit, for example the control device 19, in order to limit negative voltages in the second switching phase to a minimum voltage. In the case of negative voltages, the voltage is limited to the forward voltage of the diode.

The voltage V_sns across the resistor 24 can be supplied to the control device 19, optionally after A / D conversion.

In order to determine the output voltage of the operating circuit 39, the forward voltage of the rectifier diodes 31, 32 can be taken into account. The output voltage can be determined as

Vout ~ V_sns - V _c (l _ou t) (1) where V_sns is the maximum value of the voltage detected at the inductor 21 via the voltage divider 22 and V _c (l _out ) is a correction term dependent on the output current of the operating circuit.

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AT 16 613 U1 2020-02-15 Austrian Patent Office The output voltage can be determined, for example, as

Vout ~ V_sns - Rdiff lout (2) where R _dif f is the differential resistance of the rectifier diodes 51, 52.

When determining the output voltage, the setpoint of a current control can be used for the output current I _out . Alternatively, the output current I _{out can} also be measured with a further transformer, as with reference to FIG. 3 is described in more detail.

In further exemplary embodiments, the voltage at the rectifier diodes 51, 52 can be neglected and the correction term V _c (l _out ) in equation (1) can be set to zero.

The output voltage, which is determined on the basis of the voltage across the inductor 21, can be used for different purposes. For example, fault conditions such as a short circuit at output 55 or an open output 55 can be recognized. An emergency shutdown or a power limitation of the output power can take place depending on the voltage at the inductor 21.

The voltage across the inductor 21 can also be used as a control variable for power control. The output power of the operating circuit can thus be regulated with the voltage on the inductance 21 detected on the primary side.

[0074] FIG. 3 is a circuit diagram of an operating circuit according to another embodiment.

The operating circuit is set up in such a way that an output current of the operating circuit can be determined by a measurement. A transformer for current measurement is provided, which comprises at least one inductance 61, 62. The at least one inductance 61, 62 can be connected between the secondary coil 18 and the rectifier diode 51, 52. There may be a first inductor 61 in the path between the secondary coil 18 and the rectifier diode 51. There may be a second inductor 62 in the path between the secondary coil 18 and the rectifier diode 52.

The first inductor 61 and the second inductor 62 can be inductively coupled to an inductor 63 of the transformer for the current measurement via the potential barrier. The inductance 63 is provided on the primary side of the operating circuit. The inductance can be connected to a capacitor 65 via a rectifier 64 and a resistor. Another resistor 66 can be connected in parallel with the capacitor 65. The voltage across the capacitor 65 is proportional to the output current and represents a measured value l_sns, which can be detected on the primary side of the operating circuit and represents the output current.

The measured value I_sns, which represents the output current of the operating circuit, can be used in combination with the voltage V_sns detected at the inductor 63 in order to determine the output voltage of the operating circuit. For example, the output voltage can be determined according to equation (2).

The operating circuit can optionally comprise a capacitance 58 and / or at least one inductor 56, 57 on the secondary side. These components can also be omitted. For example, depending on whether the operating circuit is to be operated as a constant current source or as a constant voltage source, the inductance 56, 57 can be omitted.

In the circuits as described with reference to FIG. 2 and FIG. 3 have been described in more detail, the voltage V_sns can be sampled in each case in order to determine a maximum value of the voltage at the inductor 21. The diode 25 clamps a negative voltage, so that the determination of the maximum value in every second half-wave can be carried out at positive voltages. A correction term dependent on the output current of the operating circuit can optionally be subtracted from the respectively determined maximum value in order to

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AT 16 613 U1 2020-02-15 Austrian patent office to determine the output voltage.

In order to determine the maximum value of the voltage at the inductor 21, which is measured via the voltage divider 22, an A / D conversion and digital further processing can take place.

In further configurations, a capacitor can be provided in parallel with the resistor 22, as with reference to FIG. 4 is explained in more detail.

[0082] FIG. 4 is a circuit diagram of an operating circuit according to another embodiment. The device for determining the output voltage comprises a capacitor 26 which is connected in parallel with a resistor 24 of the voltage divider 22. A diode 27 is provided between the voltage divider 22 and the inductor 21. The capacitor 26 is connected in parallel with one of the resistors of the voltage divider 22, for example in parallel with the resistor 24.

The capacitor 26 is charged in one phase of each switching cycle via the diode 27 and the resistor 23. The capacitor 26 is used for low-pass filtering. A voltage is present at the capacitor 26, which represents the maximum value of the voltage across the inductor 21. When the output voltage of the operating circuit changes, capacitor 26 can slowly discharge through resistor 24 until the voltage across capacitor 26 again has a value representative of the output voltage of the operating circuit.

The voltage across capacitor 26 is a DC voltage that represents the maximum voltage of the voltage induced across inductor 21. This voltage can be supplied to the control device 19. A temporal sampling and determination of the maximum value of the voltage no longer necessarily have to be carried out.

[0085] FIG. 5 is a circuit diagram of an operating circuit according to another embodiment. The device for determining the output voltage comprises a capacitor 26 which is connected in parallel to the voltage divider 22. A diode 27 is provided between the capacitor 26 and the inductor 21.

The capacitor 26 is charged in one phase of each switching cycle via the diode 27. A voltage is present at the capacitor 26, which represents the maximum value of the voltage across the inductor 21. If the output voltage of the operating circuit changes, the capacitor 26 can slowly discharge via the resistors 23, 24 until the voltage across the capacitor 26 again has a value representing the output voltage of the operating circuit.

The voltage across capacitor 26 is a DC voltage that represents the maximum voltage of the voltage induced across inductor 21. This voltage can be supplied to the control device 19 via the voltage divider 22. A temporal sampling and determination of the maximum value of the voltage no longer necessarily have to be carried out.

[0088] FIG. 6 shows an exemplary voltage V_sns across the resistor 24, such as that used, for example, with the circuits of FIG. 2 or FIG. 3 can be recorded. The diode 25 clamps negative half-waves at a negative clamping voltage 73. The voltage V_sns across the resistor 24 has a time-dependent profile. A maximum value 71 of the voltage in the positive half-wave represents a value that is slightly larger than the output voltage 72 of the operating circuit.

The maximum value 71 of the voltage can be determined by sampling after D / A conversion or by low-pass filtering, as with reference to FIG. 4 can be determined.

The maximum value 71 of the voltage across the inductor 21 can itself be used as a measure of the output voltage or can be corrected by a correction term which depends on the output current of the operating circuit.

[0091] FIG. 7 shows an enlarged representation of the voltage across the inductance 21, which is about

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AT 16 613 U1 2020-02-15 Austrian patent office the voltage divider 22 is detected. A correction term 74 can be subtracted from the maximum value 71 in order to determine the output voltage 72. The correction term 74 can be dependent on the output current and can in particular be proportional to the output current. The correction term 74 can take into account the voltage drop across the rectifier diodes 51, 52.

The output voltage, which is determined via the voltage drop across the inductor 21, can be used in different ways in the control or regulation. The voltage drop across the inductor 21 or a variable derived therefrom can be used as a controlled variable of a power control loop with which the output power of the operating circuit is regulated. The voltage drop across the inductor 21 or a variable derived therefrom can be used for the detection of fault conditions, for example for the detection of a short circuit at the output 55 or an open output 55.

[0093] FIG. 8 is a flow diagram of a method 80 according to an embodiment.

[0094] At step 81, at least one switch of a converter is switched in a clocked manner.

In step 82, a voltage across an inductor 21 on the primary side of the operating circuit is detected. The inductor 21 is inductively coupled to the secondary coil 18 of the converter. The inductance 21 is different from the primary coil of the converter. The detected voltage can be a maximum value of the voltage at the inductance 21, which is tapped via a voltage divider 22.

At step 83, the output power of the operating circuit is determined based on the detected voltage. For this purpose, a correction term, which depends on the output current, can be subtracted from the detected maximum value of the voltage on the inductor 21. The correction term can be determined depending on a setpoint of a current control loop. The correction term can be determined by detecting the actual output current, for example via a further transformer 61, 62, 63. The output power can be determined from the output voltage and the output current.

At step 84, it can be checked whether the output power is within an allowable range. For this purpose, it can be determined whether the output power is greater than a first threshold value and / or less than a second threshold value. The second threshold can be greater than the first threshold. If the output power is within the allowable range, the method may return to step 81.

If it is determined in step 84 that the output power is not in the permissible range, a procedure for power limitation can be carried out in step 85. For example, the power limitation can take place in such a way that the output power always remains greater than the first threshold value or at least equal to the first threshold value. For this purpose, dimming to lower currents can be prevented, for example, or the output current can be regulated again to a higher current intensity if the output power for the determined output voltage is already equal to the first threshold value. As an alternative or in addition, the power limitation can take place in such a way that the output power always remains lower than the second threshold value or at most equal to the second threshold value. For this purpose, dimming to higher currents can be prevented, for example, or the output current can be regulated to a lower current again if the output power for the determined output voltage is already equal to the second threshold value.

[0099] While exemplary embodiments have been described with reference to the figures, modifications can be implemented in further exemplary embodiments. While the maximum voltage that occurs at an inductance that is inductively coupled to the secondary coil of the transformer can be used as an indicator for the output voltage of the operating circuit, other parameters can also be used to determine the output voltage.

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AT 16 613 U1 2020-02-15 Austrian Patent Office [00100] Inductors or capacitors can each be formed by corresponding inductive or capacitive elements, for example as coils or capacitors. However, it is also possible for smaller inductors, for example the smaller inductor of the LLC resonant circuit, to be designed as leakage inductors. Similarly, smaller capacities can be designed as stray capacities.

[00101] Converters and methods according to exemplary embodiments can be used in particular to supply a light source that comprises LEDs.

Claims (15)

Operating circuit for supplying a lighting means (5), which comprises at least one light-emitting diode (6), the operating circuit having a primary side (11) and a galvanically isolated secondary side (12), and wherein the operating circuit comprises: a clocked converter (14 ), which comprises a primary coil (17) and a secondary coil (18), and a detection device (20) for determining an output voltage (V _out ) of the operating circuit, the detection device (20) being arranged on the primary side (11) of the operating circuit (21), which is inductively coupled to the secondary coil (18). 2. Operating circuit according to claim 1, wherein the detection device (20) is set up to determine the output voltage depending on the voltage at the inductor (21) and depending on an output current (l _out ) of the operating circuit. 3. Operating circuit according to claim 2, wherein the detection device (20) is set up to determine the output voltage (V _Out ) depending on a maximum value of the voltage across the inductor (21) and depending on the output current. 4. Operating circuit according to claim 3, wherein the detection device is set up to determine the output voltage (V _out ) as the difference between the maximum value (71) of the voltage and a voltage correction (74) dependent on the output current. 5. Operating circuit according to claim 4, wherein a diode (51, 52) between the secondary coil (18) and an output (55) of the operating circuit is provided, wherein the voltage correction (74) is a product of the output current (l _out ) and a differential resistor the diode is. 6. Operating circuit according to one of claims 2 to 5, comprising a transformer (61, 62, 63) for detecting the output current (l _out ). 7. Operating circuit according to one of the preceding claims, wherein the operating circuit is set up to switch at least one controllable switch (41, 42) of the converter (14) in a manner dependent on the determined output voltage (V _out ). 8. Operating circuit according to one of the preceding claims, wherein the operating circuit for a power control and / or a power limitation of an output power of the operating circuit is set up depending on the determined output voltage (V _out ). 9. Operating circuit according to one of the preceding claims, wherein the inductance (21) from the primary coil (17) is different. 10. Operating circuit according to one of the preceding claims, wherein the converter (14) is a primary-side clocked LLC resonance converter (14) with half-bridge control. 11. LED converter comprising an operating circuit according to one of the preceding claims. 12. A method for operating an operating circuit for supplying a light source (5) which comprises at least one light-emitting diode (6), the operating circuit having a primary side (11) and a galvanically separated secondary side (12), and the method comprising: 11/18 AT 16 613 U1 2020-02-15 Austrian patent office clocked switching of at least one controllable switch of a converter (14), which comprises a primary coil (17) and a secondary coil (18), and Determining an output voltage (V _out ) of the operating circuit as a function of a voltage at an inductor (21), the inductor (21) being arranged on the primary side (11) and being inductively coupled to the secondary coil (18). 13. The method according to claim 12, wherein the output voltage (V _out ) of the operating circuit is determined depending on the voltage across the inductor (21) and depending on an output current (l _out ) of the operating circuit. 14. The method according to claim 12 or claim 13, wherein the inductance (21) is different from the primary coil (17). 15. The method according to any one of claims 12 to 14, which is carried out by the operating circuit according to one of claims 1 to 10 or by the LED converter (3) according to claim 11.