DE102009010260A1 - Circuit arrangement and method for operating a lighting device - Google Patents

Abstract

The invention relates to a circuit arrangement (132) for operating at least one lighting device (50). The circuit arrangement (132) comprises a primary circuit (38) and a secondary circuit (40) which is galvanically isolated from the primary circuit (38). It electrical impulses from the primary circuit (38) via a flyback converter (24) to the secondary circuit (40) are transmitted. A control signal with at least one control command is supplied to a control unit (52) of the primary circuit (38). The control unit (52) of the primary circuit (38) transmits the at least one control command to the secondary circuit (40) by generating or omitting individual predetermined pulses of the transmitted electrical pulses.

Description

Technical area

The The invention relates to a circuit arrangement for operating at least a lighting device, having an input with a first and a second input terminal for applying a supply AC voltage; with an output having a first and a second output terminal for providing an operating voltage for the at least one illumination device; with a primary circuit, which is coupled to the first and second input terminals and a control unit; with a secondary circuit, whose output is coupled to the output of the circuit arrangement is; with a flyback converter, which has a flyback switch, a Flyback converter diode and a transformer having a first and a second winding, wherein the first winding of the primary circuit and the second winding is associated with the secondary circuit; and wherein the control unit of the primary circuit is designed is to drive the flyback switch with a sequence of pulses. The invention also relates to a corresponding procedure.

State of the art

present it is particularly about the operation of a lamp or so called LED retrofit lamp, which has a variety of individual light sources, such as B. LEDs includes. Such LED retrofit lamps provide one energy budget Alternative for the usual Light bulbs They consume significantly less energy and are therefore more economical. There such lamps for the purpose of heat dissipation by encased an electrically conductive heat sink are, must additional Safety measures The same applies to luminaires. There will be flyback converters with safety transformers (also known as SELV or equivalent SELV (safety extra low voltage) flyback converter known) used, and the secondary circuit is from the primary circuit galvanically isolated. The secondary circuit, to which the LEDs are connected is from the primary circuit powered by the flyback converter with electrical energy.

It is often desirable to vary the degree of brightness of the light emitted by the LEDs, as well switch between bulbs of different colors to be able to. In addition, should by a suitable arrangement of different colored LEDs of the color rendering index can be improved. The control of the bulbs finds but their limits due to the galvanic decoupling of the secondary circuit from the primary circuit. It would have to additional exclusively for Purpose of driving the LEDs provided components used be flexible to drive the LEDs from the side of the primary circuit to enable. These components would have too the separation between the primary and the secondary circuit to ensure. The use of such additional components is on the one hand expensive, on the other hand would the components additional Take up space. Especially with LED retrofit lamps but no or little space for such additional Components available.

Presentation of the invention

It The object of the invention is to indicate a solution, such as the at least a lighting device reliably controlled by the side of the primary circuit can be, especially without the use of additional, exclusively for this purpose provided components.

These The object is achieved by a Circuit arrangement solved with the features according to claim 1, as also by a method having the features according to claim 12. Advantageous Embodiments of the invention are the subject of the dependent claims.

at the circuit arrangement according to the invention is thus intended that the control unit of the primary circuit at least one terminal for supplying a control signal with at least one control command for which comprises at least one illumination device. The control unit of the primary circuit is designed to send the at least one control command to the Secondary circuit by generating or omitting individual predetermined pulses of the Sequence of impulses in dependence from the at least one control command to transmit.

The invention thus exploits the fact that energy pulses are transmitted from the primary circuit to the secondary circuit. The invention now goes the way to generate or omit individual predetermined energy pulses to transmit the at least one control command to the secondary circuit as data. The at least one lighting device can thus be controlled reliably and on demand by the primary circuit, z. B. control commands Lich respect of the degree of brightness and / or the color of the light can be transmitted to the secondary circuit. The circuit arrangement comes without additional, provided exclusively for this purpose components such. B. an optocoupler. Thus, the use of additional components with the associated Disadvantages such as space requirements, costs and the like.

With the circuit arrangement according to the invention Is it possible, different control commands from the primary circuit to the secondary circuit transferred to. By generating or omitting individual predetermined pulses can in fact be quasi binary Data, d. H. Bits transmitted to the secondary circuit become. The preferred applications relate in particular the dimming of at least one luminous means of the illumination device, switching between bulbs of different colors as well correcting the perceived color, d. H. a color rendering index a light generated by at least one light source by switching at least one light source of different color. At the latter Application can be the color rendering index (CRI) of a lighting device be improved.

at the omission of individual pulses are in the circuit arrangement preferably measures made that ensure the operating voltage at the output of the secondary circuit is predeterminable Value does not fall below. This is especially true for several in Row of interconnected LEDs; then the flyback switch in the transmission of the at least one control command preferably controlled such that the operating voltage is the sum of the forward voltages of all the output of connected and connected in series LEDs do not fall below. Then it is guaranteed that a sufficient operating voltage for the at least one illumination device to disposal is placed.

The Control unit of the primary circuit is preferably adapted to the at least one control command by a digital word with a length of k bits and the sequence of pulses corresponding to the digital word produce. Accordingly, the at least one control command is on the primary flow side in the form of a digital word, making it particularly easy transferred by omitting or generating predetermined pulses to the secondary circuit can be.

The control unit of the primary circuit may divide the pulses into a predetermined number n of groups of pulses. Now two different ways are provided for the transmission of the at least one control command:
Each group of n pulses may represent a separate digital word correlated to the at least one control command. Thus, in this embodiment, the sequence of pulses is subdivided into groups of n pulses each, and each group of n pulses represents a separate control command. This may, for example, be such that at least one pulse of n pulses of each group is a logical "zero". is omitted. Then, the location of the logical "zero" in each group is critical to the particular digital word and thus to the control command. For example, a sequence of pulses with a total of four groups of five pulses may look like this:
10111, 01111, 11101, 11110

In In this case, each group represents a separate digital word. For example, the first group represents the word 10111. This digital Word is then with a corresponding control command for the at least a lighting device correlates.

According to another, alternative or additional - the control commands can be transmitted in different ways with a time delay - embodiment is generated or omitted at least one pulse of each group for reproducing a bit of a digital word. Accordingly, pulses of different groups are combined into a digital word, which is correlated with the at least one control command. It may for example look like that in each case a predetermined pulse, z. B. each of the first pulse of each group is used as a bit playback pulse, namely omitted as a logical "zero" or as a logical "one" is generated. A sequence of pulses may, for. B. look like this:
11111, 01111, 01111, 11111

Here Each of the first pulses of each group represents a bit playback pulse group; the first pulse of each group is omitted or generated. The bit playback pulses each provide a bit of one digital words. The bit playback pulses of all groups become into a digital word 1001, which corresponds to a corresponding one Control command is correlated. In the case considered here becomes so every fifth Pulse of the sequence of pulses used as a bit-replay pulse. The advantage of this approach is that only a few Energy pulses are omitted, namely only when a logical "zero" transmitted shall be; the operating voltage at the output of the secondary circuit is thus less affected.

To evaluate the electrical pulses transmitted to the secondary circuit, the secondary circuit preferably has an evaluation unit. The evaluation unit then recovers the at least one control command from the transmitted electrical pulses and controls the at least one illumination device as a function of the at least one control command. The evaluation unit may comprise passive and / or active components. For example, the evaluation unit a pas include siven filter, which emits a control signal to the at least one illumination device depending on the transmitted electrical pulses. However, it has proved to be particularly advantageous if the evaluation unit has an active control unit, in particular a microcontroller. Then, applications such as dimming, changing the color and correcting the perceived color are particularly easy to perform: the control unit evaluates the transmitted pulses by outputting corresponding signals to the at least one illumination device.

Around an accurate recording of the transmitted to achieve electrical impulses and thus the appearance of a To avoid errors in the evaluation, a decision unit, in particular a Schmitt trigger, coupled to the evaluation unit be. Then, the decision unit picks up the data transmitted through the transformer electrical pulses on one with the second winding of the transformer coupled tap pole and gives a correlated with the transmitted electrical pulses, especially the transferred Impulse reproducing, signal to the evaluation from. Consequently receives the evaluation unit an ideal, with the transmitted electrical pulses correlated signal, so that errors in the evaluation and recovering the at least one control command excluded by the evaluation unit are.

Preferably, the beginning and / or the termination of the transmission of the at least one control command of the evaluation unit is signaled by the control unit of the primary circuit. The evaluation unit thus contains information that the at least one control command is to be expected. Thus, a synchronization between the control unit and the evaluation is possible. The synchronization can z. B. by transmitting at least one agreed predetermined trigger word. This synchronization can z. B. look like that the control unit of the primary circuit signals the beginning and / or termination of the transmission by omitting a predetermined number of pulses. In particular, a predetermined number of i-th pulses are skipped to signal the transmission. For example, three fifth pulses for signaling the beginning and / or termination of the transmission are output. The signaling of the beginning of the transmission can thus look like this:
01111, 01111, 01111, x1111, ...

Receives the Evaluation unit now the first logical "zero", so she begins to count. Become a total of three fifths Impulses omitted as a logical "zero", so the next one fifth Pulse x a bit playback pulse, so one bit of a digital These are words next fifth Pulse is either generated or omitted. Below the bit playback pulse becomes the presence or absence of a pulse understood at a predetermined location in the sequence of pulses.

The Control signal with the at least one control command, the control unit via the at least one control terminal to be supplied. The at least a control terminal may be coupled to an external terminal of the circuitry be over which the control signal from outside the circuit arrangement can be transmitted to the control unit. hereby can the control unit control commands z. B. by an operator or from an external sensor, eg. B. a brightness sensor transmitted become; an operator can thus dimming, changing the Color as well as correcting the perceived color itself make appropriate control signals.

Complementary or Alternatively, the at least one control terminal of the control unit of the primary circuit with one of the input terminals of Circuitry be connected. The control unit extracts then the at least one control command from the supply change voltage. It can thus control commands from the side of the AC supply voltage the control unit transmits become. The preferred application here is dimming the light, z. For example: An operator switches when the light is on several times a power switch off and on again. The control unit is now designed to change the Course of the mains voltage, in particular the number of times the Turning the power switch off and on to recognize. Depending on transmitted this recognition the control unit commands to the secondary circuit, which is a corresponding Actuation of at least one illumination device performs. The number of times the switching on and off can here z. B. one Brightness level correspond. In this embodiment may further be provided be that the at least one control terminal of the control unit with the input of the circuit arrangement by means of a Dimming device is connected. Such a dimming device is then designed to detect a phase angle or phase section and a control signal with a corresponding control command, in particular a corresponding digital word, for the secondary circuit to transmit to the control unit.

In the method according to the invention it is provided that a control signal with at least one control command for the at least one lighting device is supplied to the control unit of the primary circuit and the at least one control command to the secondary circuit by Er witnessing or omitting individual predetermined pulses of the sequence of pulses in response to the at least one control command is transmitted.

The with reference to the circuit arrangement according to the invention presented preferred embodiments and their advantages apply correspondingly for the method according to the invention.

Further Features of the invention will become apparent from the claims, the Figures and the description of the figures. The above in the description mentioned features and feature combinations and the following mentioned in the description of the figures and / or in the figures alone shown features and feature combinations are not only in the each specified combination, but also in other combinations or used alone, without the scope of the invention to leave.

The Invention will now be described with reference to individual preferred embodiments and with reference to the drawings, wherein

1 a schematic diagram of a circuit arrangement according to an embodiment of the invention illustrated;

2 an exemplary lighting device illustrated by means of the circuit arrangement according to 1 is controlled;

3 Fig. 10 illustrates an exemplary sequence of pulses transmitted from a primary circuit through a flyback converter to a secondary circuit, with the pulses transmitting a control command;

4 another example of a sequence of pulses, with which a control command is transmitted from the primary circuit to the secondary circuit;

5 a control unit for the primary circuit according to an embodiment of the invention illustrated;

6 a circuit arrangement according to an embodiment of the invention illustrated;

7 illustrates a time course of an operating voltage, a course of a current and a time sequence of electrical pulses transmitted to the secondary circuit; and

8th a lamp with the circuit according to 6 illustrated.

Preferred embodiment of invention

1 FIG. 3 illustrates a schematic drawing of a circuit arrangement according to an embodiment of the invention. The circuit arrangement comprises an input 10 with a first input terminal 12 and a second input port 14 , Between the input terminals 12 . 14 is an AC supply voltage U _N on. The entrance 10 is with a rectifier 18 coupled to rectify the AC supply voltage U _N. Between a DC link 20 and a reference potential 16 is thus a rectified voltage. This voltage is with a between the DC link 20 and the reference potential 16 switched DC link capacitor 22 smoothed.

The circuit arrangement further comprises a SELV-designed flyback converter 24 , which is a safety transformer 26 including a first and a second winding 28 . 30 , a flyback diode 32 , a flyback converter capacitor 34 and a flyback switch 36 having. In this case, the circuit arrangement in a the first winding 28 having primary circuit 38 and one the second winding 30 having secondary circuit 40 divided. A potential barrier between the primary circuit 38 and the secondary current 40 is in 1 with the help of the dashed line 42 indicated. To the primary circuit 38 thus belong the entrance 10 , the rectifier 18 , the DC link capacitor 22 and the first winding 28 of the safety transformer 26 , To the secondary circuit 40 belong except the second winding 30 also the flyback converter diode 32 and the flyback converter capacitor 34 ,

The secondary circuit 40 has an exit 44 which simultaneously represents an output of the circuit arrangement. The exit 44 includes a first output port 46 , as well as a second output terminal 48 , between which an operating voltage U _B for a lighting device 50 is available.

The flyback switch 36 is by means of a control unit 52 driven. The control unit 52 may be, for example, a microcontroller, which the flyback converter switch 36 with a sequence of pulses drives. So the flyback converter switch 36 pulsed, that is controlled by a pulsed or rectangular signal. The flyback switch 36 For example, it can be driven by a frequency with a value in the range of 40 kHz to 120 kHz. The control unit 52 So generates between 40,000 and 120,000 pulses per second.

The electrical energy is from the primary current circuit 38 through the safety transformer 26 to the secondary circuit 40 transfer. Since the control of the flyback switch 36 pulse-wise, the energy transfer from the primary circuit also takes place 38 to the secondary circuit 40 pulsed. The transmitted electrical pulses are then connected to the flyback converter diode 32 rectified and by means of the flyback converter capacitor 34 smoothed. At the flyback converter capacitor 34 Thus, there is a DC voltage, the operating voltage U _B for the lighting device 50 equivalent.

The control unit 52 includes one with the first input port 12 coupled supply connection 54 as well as a control connection 56 , Via the control connection 56 can the control unit 52 Control signals with control commands for the lighting device 50 be supplied. Alternatively, the supply connection 54 with an additional winding (in 1 not shown) of the safety transformer 25 be connected; then put the supply connection 54 a permanent supply connection of the control unit 52 It is essential that the control unit 52 a feedback from the flyback converter 24 via the to the secondary circuit 40 receives transmitted electrical impulses.

The control connection 56 the control unit 52 is with an external connection or an interface 58 connected to the circuit arrangement. About the connection 58 are the control unit 52 Control signals supplied from outside the circuit, namely, for example, by an internal sensor such. B. a brightness sensor and / or an evaluation for Phasenan- or section.

So the control unit receives 52 Control signals with control commands for the lighting device 50 , These control commands are now to the secondary circuit 40 be transmitted. Since the requirements for safety must be met, no electrical cables may be routed from the primary circuit to the secondary circuit for this purpose. Also on additional components should be omitted; they require a lot of space.

It is provided that the control commands to the secondary electricity price 40 by appropriate variation of the flyback switch 36 delivered sequence of pulses and thus to the secondary circuit 40 transmitted electrical pulses are transmitted. By generating or omitting individual predetermined pulses to the Sperrwandelschalter 36 delivered sequence of pulses can thus to the secondary circuit 40 digital data correlated with the control commands.

So they are connected to the secondary circuit 40 transmitted electrical impulses control commands for the lighting device 50 , These control commands are now to be evaluated kundärstromseitig, and the lighting device 50 must be controlled accordingly. For this purpose, the transmitted electrical pulses at a tap pole 60 tapped, which with the second winding 30 directly connected. These electrical pulses are fed to an evaluation unit 62 , the lighting device depending on the recovered control commands 50 controls. Here is the tap pole 60 via a rectification diode 61 as well as a voltage divider including the ohmic resistors 63a and 63b with an input of a decision unit 116 coupled. The decision-making unit 116 here has the task of transmitting an ideal signal reproducing the transmitted electrical impulses to the evaluation unit. The evaluation unit 62 then controls the lighting device 50 depending on this ideal signal. This control may concern, for example, dimming, changing the color and / or correcting the perceived color or the color rendering index. These applications will now be referred to 2 explained in more detail:

2 shows the evaluation unit 62 and the lighting device 50 according to an example of the invention. In 2 is the exit 44 of the secondary circuit 40 shown with the DC operating voltage U _B provided thereto. At the exit 44 is a first group 64 connected by three light-emitting diodes of white color. This is in series a power transistor 66 switched, which by means of the evaluation 62 is controlled. Parallel to the first group 64 of light emitting diodes and the power transistor 66 is a second group 68 of two light-emitting diodes of white color with another power transistor 70 connected. Also the power transistor 70 is by means of the evaluation unit 62 controllable. At the exit 44 is also a third group 72 connected by three LEDs of green color. In series is a power transistor 74 connected. Parallel to the exit 44 is finally a light emitting diode 76 red color with a serially connected power transistor 78 connected. The power transistor 78 is also by means of the evaluation unit 62 controllable. The evaluation unit 62 So controls the power transistors 66 . 70 . 74 . 78 depending on the control commands. With the in 2 pictured illumination device 50 For example, a total of 3 brightness levels of white light can be generated by switching between the first and second groups 64 . 68 the white LEDs or by simultaneously switching on at the groups 64 . 68 , In addition, in the lighting device 50 a green light with the LEDs of the third group 72 be generated. It can thus be switched between at least 2 colors of light. The red LED 76 is used to correct the perceived color or the color rendering index.

Is connected to the secondary circuit 40 For example, transmit a control command, after which a white light is to be generated with the brightness of the third stage, then the first and the second group 64 . 68 the white LEDs through the evaluation 62 switched on. The white LEDs of the first and the second group 64 . 68 each produce a white light with different quality. The total light is therefore not an ideal white light, the color rendering index is usually between 70% and 80%. Information about the color rendering index and thus about the quality of the light can be obtained, for example, with the aid of a sensor. This information can be the control unit 56 supplied to the circuit arrangement and to the secondary circuit 40 be transmitted. Then the evaluation unit controls 62 the red LED 76 depending on this information; the color rendering index and thus the quality of the light can with the red light emitting diode 76 Getting corrected.

Referring to the 3 and 4 Now, two examples of the transmission of the control commands to the secondary circuit 44 explained in more detail:

3 represents an exemplary sequence of pulses as applied to the flyback switch 36 (please refer 1 ). Because no information from the secondary circuit 40 to the primary circuit 38 can be transmitted, the transmission of control commands between the control unit 52 and the evaluation unit 62 be synchronized, that is, the evaluation unit 62 must know when the control commands are transmitted. To signal the beginning of the transmission of the control commands, three fifth pulses are omitted, which is in 3 with the reference number 80 is indicated schematically. In other words, instead of the three fifth pulses 80 transmit a logical "0". Detects the evaluation unit 62 that a momentum 80 Missing, she starts to count. Detects the evaluation unit 62 that a total of three fifth pulses 80 is missing, this indicates that the next fifth pulse is a first bit replay impulse 82 represents - it is transmitted or omitted. So after three pulses 80 are omitted to signal the transmission, then every fifth pulse 82 generated as a bit-playing pulse as a logical "1" or omitted as a logical "0". The bit reproduction pulse is therefore the point in the sequence of pulses at which a bit, be it "0" or "1", is to be transmitted.

Thus, according to the previous example, the pulses are divided into groups of five pulses each. In doing so, the first impulse represents 82 of each group represents a bit reproducing pulse, that is, it is generated or omitted. The first pulses 82 of each group are grouped into one digital word, such as in 3 indicated. The digital word, here 101 , is then koreliiert with a control command to be transmitted, in particular, returns the control command. The evaluation unit 62 thus extracts the digital word from the transmitted electrical pulses 101 and controls the lighting device 50 depending on that word.

The termination of the transmission of the control command is the evaluation unit 62 in particular, by omitting a certain number of electrical pulses, as is done in the signaling of the beginning of the transmission.

Another example of the transmission of the control commands to the secondary circuit 40 is referred to 4 explains:
The electrical pulses transmitted to the secondary circuit are divided into groups of five pulses each. The evaluation unit 62 So always looks at five impulses, that is, it counts each one to five. Each group of five impulses represents a separate digital word. One or more digital words can be corelated with a control command. At the first in 4 The group of five pulses shown, the second pulse is omitted as a logical "0"; the evaluation unit 62 So receives 10111. This digital word can mean, for example, that the founding light emitting diodes 72 to be controlled.

At the in 4 If necessary, the signaling of the beginning and the end of the transmission may be omitted. The evaluation unit 62 It counts from one to five every time - it no longer has to go with the control unit 52 synchronized or tuned to the transmitted pulses. However, in order to prevent erroneous transmission of the control commands, the beginning or the termination of the transmission of control commands can be signaled.

When transferring the control commands to the secondary circuit 40 care is taken that the operating voltage U _B does not fall below a predeterminable value. In particular, the operating voltage U _{B is} the sum of the forward voltages of all light-emitting diodes of each group 64 . 68 . 72 . 76 do not fall short. It has been found that omitting every fifth pulse ensures proper operation of the lighting device 50 not impaired.

When omitting pulses should also be taken to ensure that the Sperrwandelschalter 36 , which is a MOSFET, for example, is not thermally overloaded. After a missed pulse, the flyback switch switches 36 namely at zero again. The number of missed pulses should therefore be reduced to a minimum.

5 puts the control unit 52 according to one example. As already stated, the control unit comprises 52 the control terminal 56 , via which the control unit 52 Control signals can be supplied with control commands from outside the circuit arrangement. Now, two embodiments are provided: The control unit may comprise a single microcontroller, which also has this control terminal 56 has and is programmed accordingly. Alternatively, the control unit 52 - as in 5 is shown - a conventional switching regulator 84 which is to output a sequence 86 is formed of pulses at a constant frequency. The sequence 86 of pulses is over an ohmic resistance 85 to the flyback switch 36 transmitted. The sequence 86 of impulses can by means of a unit 88 be tapped via the control port 56 receives the control signal with control commands. In the unit 88 there is a temporal synchronization between the tapped sequence 86 of pulses and the control signal. The unit 88 then controls a transistor 90 via which a control input 92 the flyback switch 36 against the reference potential 16 can be shorted. So every impulse of the sequence can 86 of pulses connected to the flyback switch 36 are discharged, by driving the transistor 90 are omitted, and a control command can thus be transmitted.

6 illustrates the circuit arrangement according to another embodiment of the invention:
In the 6 shown circuit arrangement is based essentially on the circuit arrangement according to 1 and represents a concretization of the same. So is the entrance 10 a line filter 94 downstream, which has an ohmic resistance R1, an ohmic resistance R2 and a choke L1. The net filter 94 is between the entrance 10 and the rectifier 18 connected. The rectifier 18 is provided here as a bridge rectifier with four diodes D1. At the DC link capacitor 22 , so between the pole 20 and the reference potential 16 is a DC voltage to supply the circuit to.

The control unit 52 includes a supply connection 96 over which the control unit 52 can be supplied with electrical energy. The supply connection 90 is via two ohmic resistors R13 and R14 with the DC link 20 coupled. About the resistors R13 and R14 is the control unit 52 put into operation, namely immediately after the application of the AC supply voltage U _N. The resistors R13 and R14 are high-impedance, the resistance values are each a few megohms. After commissioning, the control unit is supplied 52 however, via an additional winding 98 of the safety transformer 26 , The supply connection 96 this is via an ohmic resistor R12 and a diode D3 with the additional winding 98 coupled. The diode D3 is used to rectify the over the auxiliary winding 98 transmitted electrical impulses. The supply connection 90 is also a smoothing capacitor C2 with the reference potential 16 coupled. Parallel to the smoothing capacitor C2, a Zener diode D4 is connected. The zener diode D4 sets a predetermined voltage at the supply terminal 96 one.

The flyback switch 36 is a MOSFET in this example. The control unit 52 controls the mosfet 36 via an ohmic resistor R6. The gate connection 100 of the MOSFET 36 is also via an ohmic resistor R7 to the reference potential 16 coupled. The drain connection 102 is with the first winding 28 of the safety transformer 26 coupled. The source connection 104 of the MOSFET 36 is via a current detection resistor R10 (shunt) with the reference potential 16 coupled. The drain connection 102 of the MOSFET 36 is also connected via a diode D2 and a parallel circuit of a capacitor C3 and an ohmic resistor R5 with the DC link 20 coupled. The circuit comprising the diode D2 and the parallel circuit of the capacitor C3 and the resistor R5 is parallel to the first winding 28 connected. This circuit is used to relieve the MOSFET 36 ,

At one between the source port 104 and the current detection resistor R10 formed pole 106 attacks the control unit 50 via the MOSFET 36 flowing current. This stream becomes the control unit 52 over an entrance 108 which is further connected via an ohmic resistor R11 to the reference potential 16 is coupled. In addition, the control unit detects 50 one at the additional winding 98 applied electrical voltage, namely via a voltage divider including the ohmic resistors R8, R9. For this purpose, one is between the resistors the pole formed by R8 and R9 110 with another entrance 112 the control unit 52 coupled. The pole 110 is also a capacitor C5 with the reference potential 16 coupled. So the control unit can 52 both via the MOSFET 36 flowing current as well as the MOSFET 36 detect the applied voltage. The values for the current and the voltage are then included in the control unit 52 compared stored values, and depending on this comparison, the operating voltage U _{B is} inferred. In the control unit 52 Thus, a voltage-current matrix is stored, and there is a regulation of the operating voltage U _B depending on the detected values for the current and the voltage.

In 6 is also the control terminal 56 for supplying control signals with control commands shown schematically.

The secondary flow side arranged evaluation 62 is a microcontroller in this example. The evaluation unit 62 has a supply connection 114 over which the evaluation unit 62 is supplied with electrical energy. The supply connection 114 is via an ohmic resistor R19 with the first output terminal 46 coupled. Between the second output port 48 and the supply connection 114 a Zener diode D8 is connected, by means of which the voltage at the supply connection 114 is set. So the evaluation unit 62 with the at the exit 44 supplied operating voltage U _B supplies. The evaluation unit 69 controls via a control output 120 the lighting device 50 at. In addition, an ohmic resistor R15 is parallel to the flyback converter capacitor 34 connected.

Description Input stage of the evaluation: As already stated, those to the secondary circuit 40 transmitted electrical impulses at the tap pole 60 tapped, which with the second winding 30 of the safety transformer 26 connected is. Here is the tap pole 60 via a diode D6 with a Schmitt trigger 116 coupled. The Schmitt trigger 116 represents a decision unit. The diode D6 is used to rectify the transmitted pulses. The entrance of the Schmitt trigger 116 is also on the one hand via an ohmic resistor R16 to the diode D6 and on the other hand via an ohmic resistor R17 to the one reference potential of the secondary circuit 40 representing the second output terminal 48 coupled. The resistors R16 and R17 represent a total of a voltage divider. Hereby, the switching threshold is set as needed, due to the design of the transformer.

The Schmitt trigger 116 So accesses the secondary circuit 40 transmitted electrical impulses at the tap pole 60 and outputs an ideal signal reproducing these pulses to an evaluation port 118 the evaluation unit 62 from. Here is the output of the Schmitt trigger 116 via an ohmic resistor R18 with the evaluation connection 118 the evaluation unit 62 coupled. The evaluation connection 118 is also a Zener diode D7 with the second output terminal 48 coupled. The zener diode D7 is used to standardize the value at the connection 118 required applied voltage.

As already stated, the operating voltage U _B may be at the transmission of the control commands to the secondary circuit 40 do not fall below the sum of the forward voltages of all diodes connected to the output. 7 represents a profile of the operating voltage U _B and one via the output terminals 46 . 48 in operation flowing current I _B at the omission of a pulse. As out 7 shows, the third pulse is omitted. Then the operating voltage U _B drops to a value U1. The voltage U _B rises again as soon as the fourth pulse is transmitted. The value U1 must therefore be greater than the sum of the forward voltages of all light-emitting diodes.

8th represents an application example of the switching arrangement according to 1 or 6 represents. 8th shows a LED retrofit lamp 122 containing a plurality of light-emitting diodes 124 having. The light-emitting diodes 124 are on an aluminum plate 126 attached, which in a hollow pear body 128 made of glass. To the pear body 128 closes immediately a hollow cylinder body 130 on, in which the circuit arrangement is arranged. The circuit arrangement is in 8th with the reference number 132 Mistake. Here is the secondary circuit 40 the aluminum plate 126 facing. The hollow cylinder body 130 represents a heat sink. For heat dissipation it is with the aluminum plate 126 connected. This is the reason for the use of the safety transformer 26 and the galvanic decoupling of the primary circuit 38 from the secondary circuit 40 ,

Claims (15)

Circuit arrangement ( 132 ) for operating at least one illumination device ( 50 ), with: - an entrance ( 10 ) with a first and a second input terminal ( 12 . 14 ) for applying an AC supply voltage (U _N ); An output ( 44 ) with a first and a second output terminal ( 46 . 48 ) for providing an operating voltage (U _B ) for the at least one illumination device ( 50 ); A primary circuit ( 38 ) connected to the first and second input terminals ( 12 . 14 gekop pelt is and a control unit ( 52 ) having; - a secondary circuit ( 40 ) whose output ( 44 ) with the output ( 44 ) of the circuit arrangement ( 132 ) is coupled; - a flyback converter ( 24 ), which has a flyback converter switch ( 36 ), a flyback converter diode ( 32 ) and a transformer ( 26 ) with a first and a second winding ( 28 . 30 ), wherein the first winding ( 28 ) the primary circuit ( 38 ) and the second winding ( 30 ) the secondary circuit ( 40 ) assigned; the control unit ( 52 ) of the primary circuit ( 38 ) is adapted to the flyback switch ( 36 ) with a sequence ( 86 ) of pulses, characterized in that the control unit ( 52 ) of the primary circuit ( 38 ) at least one control terminal ( 56 ) for supplying a control signal with at least one control command for the at least one illumination device ( 50 ), wherein the control unit ( 52 ) of the primary circuit ( 38 ) is adapted to the at least one control command to the secondary circuit ( 40 ) by generating or omitting individual predetermined pulses of the sequence ( 86 ) of pulses in response to the at least one control command. Circuit arrangement ( 132 ) according to claim 1, characterized in that the control unit ( 52 ) is adapted to reproduce the at least one control command by a digital word having a length of k bits and the sequence ( 86 ) of pulses corresponding to the digital word. Circuit arrangement ( 132 ) according to claim 2, characterized in that the control unit ( 52 ) of the primary circuit ( 38 ) is arranged to divide the pulses into a predetermined number n of groups of pulses, each group of n pulses representing a separate digital word correlated to the at least one control command. Circuit arrangement ( 132 ) according to claim 2 or 3, characterized in that the control unit ( 52 ) of the primary circuit ( 38 ) is arranged to divide the pulses into a predetermined number n of groups of pulses and in each case at least one pulse ( 82 ) of each group to reproduce or omit a bit of the digital word. Circuit arrangement ( 132 ) according to claim 4, characterized in that the control unit ( 52 ) of the primary circuit ( 38 ) is designed in each case to have an ith pulse ( 82 ) of each group to reproduce or omit a bit of the digital word. Circuit arrangement ( 132 ) according to one of the preceding claims, characterized in that the secondary circuit ( 40 ) an evaluation unit ( 62 ), which is adapted to from the over the flyback converter ( 24 ) to the secondary circuit ( 40 ) transmitted electrical pulses to recover the at least one control command and depending on the at least one control command the at least one illumination device ( 50 ) head for. Circuit arrangement ( 132 ) according to claim 6, characterized in that a decision unit ( 116 ) with the evaluation unit ( 62 ), the decision unit ( 116 ) through the transformer ( 26 ) transmitted electrical pulses at one with the second winding ( 30 ) of the transformer ( 26 ) coupled tapping pole ( 60 ) and a correlated with the transmitted electrical pulses signal to the evaluation unit ( 62 ). Circuit arrangement ( 132 ) according to claim 6 or 7, characterized in that the control unit ( 52 ) of the primary circuit ( 38 ) is adapted to the beginning and / or the termination of the transmission of the at least one control command of the evaluation unit ( 62 ). Circuit arrangement ( 132 ) according to claim 8, characterized in that the control unit ( 52 ) of the primary circuit ( 38 ) is adapted to start and / or end the transmission of the at least one control command by omitting a predetermined number of pulses ( 80 ), in particular of ith pulses ( 80 ), to signal. Circuit arrangement ( 132 ) according to one of the preceding claims, characterized in that the circuit arrangement ( 132 ) one with the at least one control terminal ( 56 ) of the control unit ( 52 ) of the primary circuit ( 38 ) coupled connection ( 58 ) for supplying the control signal with the at least one control command from outside the circuit arrangement ( 132 ) having. Circuit arrangement ( 132 ) according to one of the preceding claims, characterized in that the at least one control terminal ( 56 ) of the control unit ( 52 ) of the primary circuit ( 38 ) with one of the input terminals ( 12 . 14 ) the Schaltungsanord tion ( 132 ), the control unit ( 52 ) is adapted to extract the at least one control command from the AC supply voltage (U _N ). Method for operating at least one illumination device ( 50 ) by means of a circuit arrangement ( 132 ) With - an entrance ( 10 ) with a first and a second input terminal ( 12 . 14 ) for applying an AC supply voltage (U _N ); An output ( 44 ) with a first and a second output terminal ( 46 . 48 ) for providing an operating voltage (U _B ) for the at least one illumination device ( 50 ); A primary circuit ( 38 ) connected to the first and second input terminals ( 12 . 14 ) and a control unit ( 52 ) having; - a secondary circuit ( 40 ) whose output ( 44 ) with the output ( 44 ) of the circuit arrangement ( 132 ) is coupled; - a flyback converter ( 24 ), which has a flyback converter switch ( 36 ), a flyback converter diode ( 32 ) and a transformer ( 26 ) with a first and a second winding ( 28 . 30 ), wherein the first winding ( 28 ) the primary circuit ( 38 ) and the second winding ( 30 ) the secondary circuit ( 40 ) assigned; the control unit ( 52 ) of the primary circuit ( 38 ) the flyback converter switch ( 36 ) with a sequence ( 86 ) of pulses, characterized by - supplying a control signal with at least one control command for the at least one illumination device ( 50 ) to the control unit ( 52 ) of the primary circuit ( 38 ) and - transmitting the at least one control command to the secondary circuit ( 40 ) by generating or omitting individual predetermined pulses of the sequence ( 86 ) of pulses in response to the at least one control command. The method of claim 12, wherein the at least one control command is represented by a digital word, the control unit ( 52 ) the sequence ( 86 ) of pulses corresponding to the digital word. Method according to Claim 12 or 13, in which the beginning and / or the termination of the data transmission by means of the control unit ( 52 ) of the primary circuit ( 38 ) the secondary circuit ( 40 ), wherein the signaling preferably takes place in such a way that a predetermined number of i-th pulses are omitted as logic zero. Method according to one of claims 12 to 14, in which the by the flyback converter ( 24 ) transmitted electrical pulses by an evaluation unit ( 62 ) of the secondary circuit ( 40 ) which, depending on this evaluation, evaluate the at least one illumination device ( 50 ).