DE10051528B4 - Modular lighting system - Google Patents

Abstract

lighting device
with a supply device (2) which has a power output (12) for providing electrical supply and which has a signal input (16) at which the operating current of the supply device (2) can be controlled by a signal,
with a plurality of lighting modules (3) each having at least one light source (DL), wherein the plurality of lighting modules (3, 4) are arranged on a common carrier (36, 66), the separating points (37) for separating the lighting modules (3 , 4), and
with an encoding device (34) which identifies the current required by the connected lighting modules (3) and which is connected to the control unit of the supply device (2) with its signal input (16).

Description

The The invention relates to a lighting device, in particular for Room lighting.

Except conventional lightbulbs find increasingly light sources for room lighting application, the a separate operating device need for voltage or power supply. The light sources used have often a non-linear current / voltage characteristic. Desired working points are on to comply with this characteristic relatively precisely, to the desired Luminous efficacy and lifetime of the light source to achieve.

The To operate such light sources required operating equipment must thus be adapted to the type of light source in each case. Should from a control gear If several light sources are operated, the operating device must be furnished. This restricts the design options on the user side.

From the DE 298 09 093 U1 a light mat is known which has a plurality of light emitting diodes and is connected to a power supply unit. The power supply device is arranged according to the number and the circuit of the light emitting diodes with respect to the output voltage and the output current for supplying the LED circuit. The supply circuit is connected to a controller which is adapted to drive the LEDs in groups.

A Adaptation of the supply circuit to different light mats is not scheduled.

From the utility model DE 200 07 495 U1 a string lighting control device is known, which includes a timer circuit to switch the string of lights after a maximum time in a partial load condition. The fairy lights have several circuits, each of which can be controlled individually. Due to the predetermined by the timer circuit switching from full load to partial load, the power consumption of the fairy lights is reduced.

From the utility model DE 87 08 648 U1 is known a light strip with individual lamps, which are each controlled by its own transistor. The transistors are interconnected via a control circuit. A drive signal is passed on from control circuit to control circuit. In this way, for example, running light can be generated.

The DE 198 37 224 A1 deals with the control of several different colored light emitting diodes in order to achieve different luminous colors. This has significance, for example, in traffic signaling devices. However, there are no indications as to how different lighting modules can be operated with one and the same operating device.

The DE 29 50 399 A1 discloses the interconnection of individual lighting modules, each containing several neon lamps. Each glow lamp has its own current limiting resistor. Thus, such lighting modules can be connected in parallel as desired. In the series resistors considerable power is implemented.

From the DE 198 14 495 A1 is a light-emitting diode with an internal coding known, which is associated with a supply device. The supply device contains an evaluation circuit for evaluating the coding and a transistor which supplies a current at its output which is predetermined by the coding of the light-emitting diode. In that regard, the supply device has a control input via which the brightness to be achieved with the diode can be controlled.

From that starting it is an object of the invention, a lighting device to create in a simple way to different circumstances is customizable.

These The object is achieved with a lighting device according to claim 1.

To the lighting device according to the invention belongs a supply device, the operating device for to be connected lighting modules forms. This operating device has at least one power output for connecting at least a light module on. Furthermore a signal input is provided. A signal applied to this signal input Signal determines the current delivered at the power output or the voltage delivered to it. To determine the current or the voltage or the power, d. H. for generating the control signal for the Signal input is an encoder that is part of the light source, the Light module or a separate component can be. The coding device is thus of the operating device separated. Due to the separation of operating device and encoder can a control gear for different use cases be used. By the encoder, it is possible with one and the same operating device alternatively only one light module, several light modules, a powerful one Light module, several powerful light modules or only to operate a low-power lighting module.

Preferably, the coding device is part of the light module. The operating device then automatically supplies the connected lighting module with the current determined by the coercion device or the specified voltage. A faulty connection, which could lead to the destruction or damage of the operating device or the light module, is therefore not to be feared. The fixed association between the light module and the encoder prevents this.

each Light module preferably has a plurality of light sources. This can, for example. Be light emitting diodes. Preference is given to white LEDs that are used for illumination purposes are well usable. If necessary, colored LEDs can also be provided these being arranged and thus selected by their color can, that in total white Light is created. Thus, such lighting modules for lighting purposes suitable. The light-emitting diodes are preferably connected in series, with operating voltages between 10 and 42, preferably around 24 Volt and not too big Stream to work.

The Illuminating modules are preferably arranged adjacent to one another. This is achieved by having each light module one input and one output has, wherein the alignment of the lighting modules thereby takes place, that in each case an input of a light module to the output of connected in the row of lighting modules preceding light module becomes. The at the entrances and exits arranged connections (Contacts) are each arranged the same, so in the ranked Condition immediately adjacent contacts of input and output directly can be connected to each other. With increasing number of lighting modules is created by the increasing Number of existing encoders also a corresponding ge changes Signal at the signal input of the operating device and thus one of the increasing Number of lighting modules corresponding operating power. To this Way you can the lighting modules with one and the same operating device in different Number each with the for they are intended to be operated individually.

It creates a very flexible lighting system, for example, for room lighting, for showcase lighting as well as for signal purposes or for decorative purposes Purpose is usable.

The Light modules have at their input and at their output, respectively at least one reference potential terminal and an operating voltage terminal on, so that all lighting modules, when connected, are connected in parallel. The encoder can between the Operating voltage connection and the reference potential connection effective be. This particular, when the light sources used only use a current direction, as it is z. B. in light-emitting diodes the case is. The operating device queries the encoder then, for example, by the fact that the appended Operating voltage is occasionally reversed briefly, which the light sources for a preferably invisible short time (eg 1 ms) goes out and the encoder is queried.

alternative can the lighting modules have a separate signal connection both at the entrance as well as at the exit. The coding device, for example a Resistor network, is then between the signal terminal and the Reference potential connection effective. Are the light modules together connected, thus become the resistors or resistor networks the individual lighting modules automatically switched in parallel, thereby at the signal input of the operating device with increasing number of Light modules a decreasing resistance value appears.

alternative can the resistances or resistor networks between the input signal port and the output signal terminal of the lighting modules to be switched. By juxtaposing the lighting modules, the resistors or Resistor networks thus connected in series. While that control gear connected to one end of the row formed by the light modules is, then the free end of the light module row must be through a terminator which closes the output signal terminal with the output reference potential terminal combines. This to close the signal current path. With increasing number of light modules grows here at the signal input of the operating device visible resistance. The disadvantage of this solution is the risk If the line is interrupted, the operating current is too high signal. This can be counteracted by exceeding of a maximum resistance value, the power supply is set (interrupted).

Of the Signal input of the operating device is additional usable as dimming input. This is done by placing between the lighting modules and the operating device a dimming module is switched, that of the encoders signaled resistance changed appropriately.

If necessary, can the operating device However, also have a separate dimming input, which has a corresponding dimming input Adjustment device, for example a potentiometer with a signal voltage for Brightness adjustment is adjustable.

The lighting modules can be formed, for example, by strip-shaped printed circuit boards. It can a strip-shaped circuit board include a plurality of lighting modules that are separable from each other at intended separation points. Flexible printed circuit board material can also be used so that the lighting modules are delivered on an endless strip of printed circuit board. This can be wound up on a roll. If necessary, then the desired lengths are cut off from the strip-shaped printed circuit board material. Depending on the length cut off, a smaller or larger number of lighting modules are obtained, which are connected in parallel with each other and automatically signal the required operating current to the operating device.

It is possible, too, rigid strip-shaped printed circuit boards to combine with flexible connectors and as endless, leporelloartig to deliver folded chain of light modules. According to demand from this light module chain then the desired number of light modules be separated.

It is possible, too, separate lighting modules by connector means or other connection means. To be favoured here direct plug contacts with contact surfaces on the circuit boards and corresponding spring contacts in the connector means.

When Alternative to arranging the encoders (i.e., in, on or as part of) the lighting modules, the coding devices can also be housed in the connector means that as a socket for the Light modules act. Thus, such lighting modules are in the Lighting system can be incorporated, which does not have its own coding devices exhibit.

When Encoding device preferably resistor networks are used, by a series circuit of a linear resistor and a Resistor with positive temperature characteristic are formed. These are determined by the operating temperature of the respective lighting module controlled. Reaching or exceeding the operating temperature is a permissible Value, the PTC resistor reaches its critical temperature and increases the resistance value the coding of the respective lighting module abruptly. As a result, the relevant light module logs in the operating device practically from. Accordingly, the operating current decreases.

The control gear is preferably a power source, in particular a chopped Power source. For example. it can be designed as a flux converter. Prefers become operating devices with mains voltage supply.

details preferred embodiments The invention will become apparent from the drawing, the description or Dependent claims.

In the drawing are embodiments of Invention illustrated. Show it:

1 a lighting device with an operating device and a plurality of lighting modules, in a schematic representation as a block diagram,

2 the operating device of the lighting device after 1 in a schematic representation,

3 a lighting module of the lighting device according to 1 in a schematic representation,

4 a module comprising two light modules, constructed on a strip-shaped printed circuit board, in a schematic representation,

5 two light modules opposite each other with their ends, in a sectional illustration and on an enlarged scale, in perspective view,

6 two lighting modules interconnected by a plug connection device, in a sectional detail,

7 a plug connection device for connecting two lighting modules with coding device in the plug connection device, in a schematic representation,

8th a lighting device with dimming module,

9 the supply device 2 in a schematic diagram,

10 a lighting device with series switching resistors in the lighting modules, as an encoding device,

11 a modified embodiment of the illumination device as a block diagram,

12 formed on flexible circuit board band lighting modules, in a simplified perspective view,

13 leporello-like folded light modules, in perspective simplified representation,

14 a resistor network, which is used as an encoder on the light modules or connectors application, as a circuit diagram, and

15 a lighting device with three operating devices and a control unit for Light color control.

In 1 is a lighting device 1 illustrates to which a control gear 2 and at least one light module 3 , In the present embodiment, several lighting modules 3 . 4 . 5 . 6 belong. The light modules 3 . 4 . 5 . 6 as well as others possibly between the lighting modules 5 . 6 arranged light modules are interconnected by electrical connection means 7 . 8th . 9 connected. They thus form a chain. The first light module in the chain 3 is via an electrical connection means 11 with the operating device 2 connected, which serves the power supply of the entire chain.

The operating device 2 is schematic in 2 illustrated while the light module 3 representative of the principle of the same design other lighting modules 4 . 5 . 6 in 3 is illustrated. As can be seen, the operating device 2 a power output 12 on, to which two connections 14 . 15 belong. In addition, there is a signal input 16 provided at the power output 12 delivered electrical power that affects voltage or current. In the present embodiment, the operating device 2 as a power source formed at its power output 12 emits an operating current through a at the signal input 16 applied signal is controlled. The operating device 2 thus forms from the point of view of the lighting modules 3 . 4 . 5 . 6 a controlled power source 17 , Its supply power receives the operating device 2 For example, from an electrical supply system to which it is connected to its input 18 connected.

This in 3 Illustrated light module has a plurality of light sources. As such, light-emitting diodes DL are used, each lighting module 3 . 4 . 5 . 6 preferably carries a plurality of light-emitting diodes DL. The light-emitting diodes DL are preferably connected in series at least in groups and the same polarity in the row. According to the present embodiment 3 three light-emitting diode groups DLG1, DLG2 and DLG3 are provided, each containing red, green and blue light-emitting diodes, so that all three light-emitting diode rows in the sum have the same forward voltage and are connected in parallel. The rows are the same polarity (DC operation). Alternatively, the rows can also be oppositely poled (AC operation). It is also possible to provide more or fewer light-emitting diode groups. It is also possible to manage with only one light-emitting diode group DLG1. In addition, instead of colored LEDs and white LEDs can be used. If, on the other hand, colored light-emitting diodes are used, they are preferably matched in terms of their number and luminosity in such a way that white light is produced overall. If colored light is desired, this can be achieved by preference or exclusive use of light emitting diodes of the desired color.

It is also possible to produce any mixed colors by each LED basic color (red, green and blue) is assigned its own operating device, which is controlled by different dimming the color location and a common dimming the brightness of the mixed colors. This will be on 15 referenced, which illustrates a corresponding embodiment. The existing light module there 3 indicates a reference potential line 33 and three operating voltage lines 31-r for the red LEDs, an operating voltage line 31-b for the blue LEDs and an operating voltage line 31 g for the green LEDs on. In addition, a coding resistor RC is provided. Otherwise the module corresponds 3 the modules described above or below.

For the green LEDs is a control gear 2-g intended. The operating device is for the blue LEDs 2 B provided and the operation of the red LEDs is a control gear 2-r , Each operating device 2-g . 2 B . 2-r has a dimming input 61 g . 61-b respectively. 61-r on, which are controllable via a control unit S. This is equipped with an interface Dimm for receiving electrical dimming signals. In addition, it has three controls, the first of which controls the overall brightness of all control gear 2-g . 2 B . 2-r accordingly influenced in the same direction. Three other controls then only affect one of the operating devices 2-g . 2 B . 2-r , For this purpose, the control unit S via corresponding lines with the dimming inputs 61 g . 61-b . 61-r connected.

to Symmetrization of the light-emitting diode groups DLG1, DLG2 and DLG3 can at each embodiment If necessary, each light-emitting diode group DLG1, DLG2, DLG3 resistors RD1, RD2, RD3 are connected in series.

The light module 3 has an entrance 21 and an exit 22 on. The input includes an input operating voltage connection 23 , an input reference potential connection 24 and an input signal terminal 25 , To the exit 22 include an output operating voltage connection 26 , an output reference potential connection 27 and an output signal terminal 28 , The input operating voltage connection 23 is via a connection line 31 with the output operating voltage connection 26 connected. The input reference potential connection 24 is via a connection line 32 with the output reference potential connection 27 connected. The input signal connector 25 is via a connection line 33 with the output signal connector 28 connected.

The light-emitting diode series circuits formed by the diode groups DLG1, DLG2, DLG3 each connect the connecting line 31 with the connection line 32 ,

The light module 3 carries an encoder 34 that of the light module 3 required operating current. The coding device 34 is formed in the present embodiment by a coding resistor RC, which is between the connecting line 32 (Reference potential) and the connection line 33 (Signal line) is switched. The resistance value of the resistance element RC characterizes the module 3 associated operating current. If the resistance value of the resistance element RC is large, this signals a low current, while a low value of the resistance element RC signals a high operating current.

The function and use of the lighting device 1 after the 1 to 3 are as follows:
If a corresponding lighting system is set up, the operating device is first 2 and at least one light module 3 provided. For connection of the light module 3 to the operating device 2 become the input operating voltage connection 23 to the output terminal 14 , the input reference potential terminal 24 to the output terminal 15 and the input signal terminal 25 to the signal input 16 connected. The lighting device 1 is thus ready for operation in its smallest configuration. The coding resistor RC is applied to the signal input 16 of the operating device 2 effective against the internal equipment reference potential at the connection 15 is applied. The resistance value is determined by the operating device 2 interrogated, for example by the coding resistor RC in a control circuit of the operating device 2 is included. In this, for example, a current can be sent through the coding resistor RC and the resulting voltage drop can be registered. Alternatively, a voltage can be applied and the resulting current monitored. The operating device 2 now provides a current associated with the resistance value of the resistance device RC between its outputs 14 . 15 ready. The LEDs DL are thus fed by a power source. The balancing resistors RD1, RD2, RD3 have no current-limiting function here. They can also be omitted if necessary.

Should the other lighting modules 4 . 5 . 6 connected, this is done according to the scheme according to 1 , The light module 4 that is basically the same as in 3 illustrated light module 3 is constructed, with its corresponding input 21 to the exit 22 connected, and that by each of the directly opposite operating voltage terminals 23 . 26 as well as the directly opposite each other the reference potential terminals 24 . 27 and the signal terminals directly opposite each other 25 . 28 be connected to each other. In this way, the light emitting diodes DL of the two lighting modules 3 . 4 parallel to that of the operating device 2 connected power source connected. This must now deliver a correspondingly higher power. The coding resistances RC of the two lighting modules 3 . 4 are connected in parallel by said interconnection. This results in a correspondingly lower resistance value at the signal input 16 , which signals and requests a correspondingly higher desired operating current. Is the resistance value to the resistance value of only one light module 3 halved, doubled the operating current. The operating current of the operating device 2 is thus inversely proportional to that at the signal input 16 effective resistance value against the reference potential.

Further lighting modules 5 . 6 are connected in the same way, so that the whole of the lighting modules 3 . 4 . 5 . 6 formed chain from the operating device 2 is supplied with operating current. The size of the operating current corresponds to the sum of the individual lighting modules 3 . 4 . 5 . 6 required operating currents. The current adjusts itself automatically by the coding and parallel connection of the coding resistances. It can also light modules 3 . 4 . 5 . 6 different size and different operating power requirements are interconnected, what in 1 through the smaller representation of the light module 6 is illustrated. The light module 6 then has a coding resistor with respect to the other lighting modules 3 . 4 . 5 higher resistance value.

A possible spatial formation of lighting modules 3 . 4 illustrates 4 , The light modules 3 . 4 are on a common strip-shaped circuit board 36 educated. On its narrow sides, this double light module has 3 . 4 his entrance 21 and his exit 22 on. The connections 23 to 28 are designed as conductor strips for the formation of direct connectors. Even such conductor strips are in the middle of the strip-shaped circuit board as connections 23 to 28 educated. Here is a breaking point 37 (possible separation point) provided in which the lighting modules 3 . 4 can be separated from each other by means of a suitable scissors, a saw or other separator. Is a corresponding weakening, for example, provided by notches or a row of holes, the lighting modules 3 . 4 Here also be separated from each other by the PCB strip at the separation point 37 is broken.

5 illustrates the separate circuit board 36 and thus the output 22 and the entrance 21 the lighting modules 3 . 4 , The connection can be made with a connection module 38 done as it is in 6 is illustrated. This is, for example, by a plastic molding 39 with an interior 40 formed by three electrically isolated and resilient contact terminals 41 are arranged. The spring contact terminals 41 each have a resilient section for the output 22 and a resilient section for the exit 21 to contact them safely when they are in the interior 40 are inserted.

The strip-shaped circuit board 36 ( 4 ) carries three continuous conductor tracks that gene the Verbindungsleitun 31 . 32 . 33 form. Here are the operating current leading connection lines 31 . 32 each arranged outside. The connecting line serving as a signal line 33 is arranged in the middle.

The light-emitting diodes DL, in the present embodiment in each case only in a group DLG1 sorted, are in a row in the middle of the circuit board 36 arranged and connected in series. If necessary, several such rows on a light module 3 . 4 can be arranged, whereby this can be made longer. If lower operating voltages are desired, the illustrated light-emitting diode series circuit DLG1 can also be divided into individual groups DLG1, DLG2, DLG3 (FIG. 3 ). The light-emitting diodes DL are arranged equidistantly. This especially in the vicinity of the entrance 21 and the output 22 , so at the designated point of interruption 37 no other distance between the adjacent light emitting diodes DL is provided as between the others, in the respective light module 3 . 4 internal light emitting diodes.

Both on the light module 3 as well as on the light module 4 is about the middle of the coding resistor RC soldered as a component, the signal line (connecting line 33 ) with the reference potential line (connecting line 32 ) connects.

Instead of a single resistance device according to 14 find a resistor network application. This can be formed, for example, by a series connection of a fixed resistor R1 and a temperature-dependent resistor PTC. The resistance PTC has a positive temperature characteristic, ie its resistance increases with increasing temperature. Here, a non-linear characteristic can be present, which shows a strong resistance increase at a certain temperature (transition temperature).

This has the consequence that when exceeding a limit temperature at the light module 3 through the relevant light module 3 is signaled that no electricity is needed. The operating device 2 then reduces its operating current accordingly.

How out 8th can be seen, the signal input 16 of the operating device 2 at the same time be used as a dimming input. This is a dimming module 44 between the entrance 21 of the first light module in the row 3 and the operating device switched. The dimming module 44 has an entrance 45 with three connections 46 . 47 . 48 and an exit 49 with three connections 51 . 52 . 53 on. The operating current leading terminal 46 is with the connection 51 low impedance connected. The same applies to the connections 48 . 53 , The connections 47 . 52 are however the signal line and thus the signal input 16 assigned. Between the connections 47 . 52 is a potentiometer 54 switched, that is adjustable from the resistance value zero to higher resistance values. If the resistance value is set to zero, the lighting modules are received 3 . 4 . 5 . 6 their full operating current and thus shine with maximum brightness. Will the potentiometer 54 adjusted to higher resistance values, correspondingly reduces the operating current, ie the light-emitting diodes DL light less bright until they eventually go out completely at high resistance values.

In the above embodiments, the coding resistances RC are part of the lighting modules 3 . 4 . 5 . 6 , Alternatively, the coding resistors RC can also be used in the connection modules 38 to be ordered. This is schematically in 7 illustrated. This embodiment has the advantage, even lighting modules to the operating device 2 to be able to connect, which have no coding resistances. For example. is then the corresponding with the specially selected resistor provided plug-in module 38 between the operating device 2 and the first light module 3 arranged, to which the other lighting modules 4 . 5 . 6 without further resistance in the plug-in modules 38 are connected. Thus, the signal line can be omitted.

A possible embodiment of the operating device 2 is in 9 illustrated. The operating device 2 has an input rectifier 56 on the network side, for example, is powered by alternating current. On the output side, it provides a DC voltage. This is provided by a suitable switching transistor or other electronic switch 57 under the control of a drive circuit 58 chopped up.

The of the transistor 57 delivered chopped DC voltage is preferably according to the flux converter principle in an operating current for the lighting modules 3 . 4 . 5 . 6 implemented. Serve at least one freewheeling diode DF, a transformer, the potential separation and the desired Span tion reduction effect. Secondary is on the transformer 58 a rectifier diode DG connected. The control device 58 detects that through the transformer 58 flowing current through a current bulb transformer 59 or by tapping across a shunt. It controls the switching transistor 57 so that between the terminals 14 . 15 the desired operating current flows through the at the control input 16 applied resistance value is set.

The control device 58 can except the control input 16 a dimming input 61 exhibit. At this then appropriate adjustment can be connected. For example, the control input 61 be controlled by binary codes, binary words, voltages or currents, which can be provided as needed.

In 10 is an alternative embodiment of the operating device 2 and the light modules 3 . 4 illustrated. In contrast to the above-described embodiment, the resistors RC are not as in the above-described embodiment between the reference potential line 32 and the signal line 33 but they are in series in the signal line 33 , The operating device 2 Here, the operating current is proportional to that at the input 16 detected resistance increases. In this embodiment, a termination module 64 required that at the last exit in the chain 22 is connected and the signal line 33 with the reference potential line 32 combines.

Another alternative embodiment is in 11 illustrated. In this embodiment, the connection line 31 , which serves as an operating voltage line, also used as a signal line. Between the connection line 31 and the connection line 32 , which serves as a reference potential line, is in each light module 3 . 4 a high-impedance resistor RC connected, which serves as a coding device. Its resistance value is so high that no appreciable current flows through it, when the operating voltage or the operating current lie in a polarity in which the light-emitting diodes DL are poled in the forward direction. If the operating voltage is lowered or reversed below the forward voltage of the series connection of the LEDs, which the operating device 2 from time to time, to detect the desired coding, the one between the terminals 14 . 15 to be measured resistance determined only by the parallel connection of the high-impedance resistors RC, which is thus recognizable as a signal to adjust the current. The interrogation of the resistors RC can be done both in rapid succession and only occasionally. This embodiment is particularly suitable for light modules with light sources whose characteristic has a kink and thus define a defined forward voltage, below which they are high impedance. In addition, this embodiment is suitable for light sources with valve characteristics (diode).

Should low resistance RC application are decoupling diodes DE with the resistors RC connected in series. These prevent a flow of current through the resistors RC during the operation of the light-emitting diodes DL and leave a polling of the coding resistances only by Umpolung the operating voltage too.

The Decoupling diodes DE are poled accordingly, d. H. they are the Light diodes DL exactly opposite.

Another practical embodiment of the lighting modules 3 . 4 is in 12 illustrated. Here are the light modules 3 . 4 , as well as other lighting modules on a flexible conductor carrier 66 arranged, the example. As a role 67 can be delivered. The individual lighting modules 3 . 4 are by breaking points 37 separated from each other. Here appropriate modules can be cut off.

Alternatively, single modules or double modules 3 . 4 , as in 4 illustrated, trained and at their entrances and exits 21 . 22 via flexible connection means 68 , For example, be flexible interconnected with each other. In this structure, the lighting modules 3 . 4 . 5 . 6 , as well as other lighting modules are delivered folded like a fan-fold. If necessary, then a light module chain of the desired length can be separated from the preconfigured soon.

To create a lighting system is a control gear 2 provided that a control input 16 and a current output 12 having. At the control entrance 16 and the current output 12 are light modules 3 . 4 . 5 . 6 connectable, which can be connected in a chain. Each light module 3 . 4 . 5 . 6 , is preferably provided with a coding device RC, which is switchable with other coding devices of other lighting modules in series or in parallel. This way, at the control input 16 a uniform one of the coding devices RC of the lighting modules 3 . 4 . 5 . 6 generated cumulatively provided signal that sets the operating current, so that the operating device 2 regardless of the number of connected lighting modules 3 . 4 . 5 . 6 each generates the correct operating current.

Claims (23)

lighting device with a supply device ( 2 ), which provide a power output for providing electrical 12 ) and which has a signal input ( 16 ), at which the operating current of the supply device ( 2 ) is controllable by a signal, with a plurality of lighting modules ( 3 ), each having at least one light source (DL), wherein the plurality of light modules ( 3 . 4 ) on a common carrier ( 36 . 66 ), the separation points ( 37 ) for on-demand separation of the lighting modules ( 3 . 4 ), and with an encoder ( 34 ), which corresponds to that of the connected lighting modules ( 3 ) and the power required to control the power supply ( 2 ) with their signal input ( 16 ) connected is. Lighting device according to claim 1, characterized in that the coding device ( 34 ) on the light module ( 3 ) is arranged. Lighting device according to claim 1, characterized in that each light module ( 3 . 4 ) has a plurality of light sources (DL). Lighting device according to claim 3, characterized in that the light sources (DL) are light-emitting diodes. Lighting device according to claim 4, characterized characterized in that at least some light-emitting diodes (DL) with each other are connected in series in the same direction. Lighting device according to claim 1, characterized in that each light module ( 3 . 4 ) an entrance ( 21 ) and an output ( 22 ), to the entrance ( 21 ) an input operating voltage terminal ( 23 ) and an input reference potential terminal ( 24 ) and to the output ( 22 ) an output operating voltage terminal ( 26 ) and an output reference potential terminal ( 27 ) belong. Lighting device according to claim 6, characterized in that to the input ( 21 ) additionally an input signal connection ( 25 ) and to the output ( 22 ) additionally an output signal connection ( 27 ) belong. Lighting device according to claim 6, characterized in that the input operating voltage connection ( 23 ) with the output operating voltage connection ( 26 ), the input reference potential terminal ( 24 ) to the output reference potential terminal ( 27 ) and the input signal connector ( 25 ) with the output signal connector ( 28 ) connected is. Lighting device according to claim 6 or 8, characterized in that the input ( 21 ) and the output ( 22 ) of the lighting modules ( 3 . 4 ) are respectively arranged on opposite sides thereof. Lighting device according to claim 1, characterized in that the lighting module ( 3 ) on a support ( 36 ) is arranged, which is formed by a printed circuit board. Lighting device according to claim 10, characterized in that the printed circuit board has an at least partially flexible printed circuit board ( 66 ). Lighting device according to claim 1, characterized in that the printed circuit board ( 36 ) with further printed circuit boards ( 36 ) via flexible spacers ( 68 ) and foldable in a fan-shaped manner. Lighting device according to claim 10, characterized in that the opposing terminals ( 23 - 28 ) of the output ( 22 ) and the input ( 21 ) are arranged coincidentally. Lighting device according to claim 1, characterized in that to the lighting device ( 1 ) Connecting means ( 38 ) for connecting lighting modules ( 3 . 4 ) belong together. Lighting device according to claim 14, characterized in that the connecting means ( 38 ) Are connector means. Lighting device according to claim 15, characterized in that the coding device ( 34 ) in or on the connector means ( 38 ) is arranged. Lighting device according to claim 1, characterized in that the coding device ( 34 ) in each case has at least one resistance value which corresponds to the power requirement of the lighting module ( 3 . 4 ) is characteristic. Lighting device according to Claims 7 and 17, characterized in that the resistance value is determined by a resistance component (RC) or a resistance network (R1, PTC) which is connected to both the input signal terminal ( 25 ) as well as with the output signal connection ( 28 ) connected is. Lighting device according to claim 18, characterized in that the resistance component (RC) or the resistance network (R1, PTC) between a signal connecting line ( 33 ) the the input signal connection ( 25 ) with the output signal connector ( 28 ), and a reference potential connection line ( 32 ) which connects the input reference potential terminal ( 24 ) and the output reference potential terminal ( 27 ) connects to each other. Lighting device according to claim 18, characterized in that the resistance component (RC) or the resistance network (R1, PTC) the input signal terminal ( 25 ) and the output signal connector ( 27 ) connects to each other. Lighting device according to claim 1, characterized in that the supply device ( 2 ) is designed as a power source and at its power output ( 12 ) emits a current the size of which depends on a signal supplied by the encoders ( 34 ) of the lighting modules ( 3 . 4 ) is generated. Lighting device according to claim 1, characterized in that the signal input ( 16 ) with an interrogator ( 58 ), which is part of the supply device ( 2 ), the interrogator ( 58 ) a permanent query of the coding devices ( 34 ). Lighting device according to claim 1, characterized in that the light source (DL) is connected or formed such that operating current flows in only one direction through the light source (DL), while the other current direction of the interrogation of the coding device ( 34 ) serves.