DE102010054784A1 - Lighting system for illuminating e.g. shelf, has master component that controls operation of LED component and power supply unit that supplies power supply voltage to LED component - Google Patents

Abstract

The lighting system has LED component (3) that includes several LEDs. A master component (2) controls the operation of LED component and a power supply unit (1) supplies the power supply voltage to LED component. The master component includes a modulator for modulating the power supply voltage according to control instruction, and demodulator for demodulating the power supply voltage according to control instruction.

Description

The present invention relates to an LED-based lighting system, and more particularly to a lighting system comprising a plurality of LED packages or expandable to a plurality of LED packages.

LEDs have been used for decades essentially only for small-sized, low-light displays, especially on electrical or electronic devices. In recent years, LEDs are increasingly coming onto the market, which are also suitable for general lighting purposes due to their high light output. Thanks to their small dimensions and their low heat output, LEDs can be installed in places where conventional incandescent light sources can not be used. For example, they can be integrated into furniture panels of market strength to illuminate individual compartments of a shelf or cupboard, for example.

If it is desired to selectively control individual LEDs or groups of them, for example, to illuminate only individual ones of several compartments of a cabinet or shelf, then this requires either a plurality of distributed in the furniture in question, consuming to install switches or, starting from a centralized switch assembly or other type of control unit, a cumbersome and error prone wiring. Expenditure and possibilities for error increase when, for example in shop and trade fair construction, LED assemblies are not only coordinated in a single piece of furniture, but also in several pieces of furniture or a whole room, or if light is not just on and off switched off, but also dimmed and / or its color should be controlled. Controlling complex lighting systems may also involve the use of bus systems such as the EIB or CAN bus, but the multi-core cables required for this are costly and cumbersome to handle, and their diameter makes them difficult to lay concealed.

Even large-format neon signs can be realized with LEDs with high luminosity and high reliability, but need to represent moving elements or changing messages, also an elaborate control.

Object of the present invention is therefore to provide a lighting system with at least one controllable by a central master assembly LED assembly in which the wiring costs for a selective control of modules regardless of their number is low.

The object is achieved in which, in a lighting system with at least one LED assembly having at least one LED, a master assembly for controlling the operation of the LED assembly and a supply line to which the LED assembly for supplying an electrical Operating voltage is connected, the master module comprises a modulator for modulating control commands to the electrical operating voltage and the LED assembly comprises a demodulator for recovering the control commands from the electrical operating voltage. Using the supply line to transmit commands to the LED assemblies eliminates the need for dedicated control lines and can largely eliminate wiring module wiring errors.

In order to specifically address a single individual among several LED modules, the modulator is preferably configured to modulate the electrical operating voltage to a control command address information, which designates an LED module for which the control command is determined, the LED module is at least one Address is assigned, and it is set up control commands whose address information does not correspond to an address of the LED module, not to execute.

The lighting system according to the invention may comprise at least one set of LED assemblies, each associated with an identical address specific to that set; All of these assemblies are simultaneously addressable by a single control command sent to this address.

An LED module can be addressed under several addresses. In order to allow individual control of the LED modules of a group, each of them should also be assigned a specific address for them alone. However, the addresses of two or more sets of a same LED package may also be associated so that the particular LED package responds to commands sent to each of the sets.

Among the commands defined for the lighting system should be at least one that allows control of the brightness of an LED assembly or its LEDs. Preferably, at least one control command is defined, which makes it possible to control the brightness of a single LED in an assembly or the ratio of the brightnesses of several LEDs of the same assembly to each other. If the LEDs of such an assembly have different colors, such a command can control the hue of the light emitted by the assembly.

Such an instruction may in particular comprise a plurality of time stamps, in particular in the form of pulses, the time interval between each two of the time stamps each representing a control variable for one of the LEDs of the module.

If the electrical operating voltage with which the assemblies are supplied, is a DC voltage, the commands from the modulator can be conveniently modulated as AC signals to the DC voltage.

In this case, the modulator can be configured to aufzumodulieren the commands with different discrete frequencies to the operating voltage. Complementary to this, the demodulator of each LED module can then expediently have a narrowband filter which is permeable only to one or to individual discrete frequencies. The frequency with which an operating voltage command is modulated then has the function of an address, since it determines which demodulator (or possibly which demodulators) of the LED assemblies of the system demodulate the command.

In order to implement a closed loop, it is expedient if the at least one LED module in turn comprises a modulator for modulating operating state information to the electrical operating voltage and the master unit comprises a demodulator for recovering the operating state information from the electrical operating voltage.

In order to avoid interactions between the modulated signal and electrical loads of the assemblies, at least one supply terminal of at least one consumer such as the modulator itself, a demodulator, an LED or the like is preferably connected in at least one of the assemblies via a coil to the supply line while a Output of the modulator of the module directly, bypassing the coil, is connected to the supply line.

In order to be able to connect the lighting system flexibly, it is expedient if at least one of the LED assemblies has a plurality of identical connections for the operating voltage. Such an assembly may form a node in a tree-like cable system from which supply cables for several other assemblies originate.

When the LED package includes an elongate printed circuit board, terminals for the operating voltage are preferably provided at opposite ends of the printed circuit board. Thus, the assembly itself can form part of a supply line leading to another assembly, and long distances can be bridged with relatively little effort on supply cables.

In order to transmit the control commands over long distances with limited transmission power, a series resonant circuit is preferably provided as the output stage of the modulator.

This series resonant circuit can preferably be connected to a switched on / off digital transmission signal whose sampling frequency is tuned to the resonance frequency of the series resonant circuit.

An input stage of the demodulator can be expediently also formed by a series resonant circuit.

In order to allow correct demodulation of a transmitted control command in substantial independence of the length of the transmission path and the signal attenuation experienced in this way, the demodulator preferably comprises an automatic gain control circuit.

Further features and advantages of the invention will become apparent from the following description of embodiments with reference to the accompanying figures. Show it:

1 a block diagram of a luminaire system according to the invention;

2 a schematic perspective view of components of the lighting system;

3 a circuit diagram of a modulator of the lighting system;

4 a circuit diagram of a demodulator;

5 a circuit diagram of a with the modulator of 4 equipped LED assembly;

6 a circuit diagram of an LED assembly with a modulator for sending operating state information to a master assembly; and

7 a control command signal according to a modification of the invention.

This in 1 schematically illustrated light system comprises a connectable to the mains power supply 1 , the secondary DC voltage in the low voltage range, z. B. 12 volts. At the output of the power supply 1 are in parallel a master module 2 and a plurality of module 2 controllable LED modules 3 parallel to each other via a supply voltage line 4 and a ground line 5 connected. The master assembly 2 can into the housing of one of its controlled LED assemblies 3 be integrated. The wires 4 . 5 can be designed in the manner of a busbar to which the various modules 2 . 3 are also connected spatially parallel to each other, as in 1 indicated.

However, preferred is a flexible modular tree-like structure, as for example with the in 2 shown components can be realized. The LED assemblies 3 Here are elongated elements, for example in the form of a hollow profile, which is composed of an aluminum extruded profile 6 of substantially C-shaped cross-section, one in the open side of the C-profile 6 inserted light exit profile 7 made of a transparent plastic and an elongated, periodically equipped with LEDs PCB, which in a cavity between the profiles 6 . 7 inside the assembly 3 housed and in 2 is not visible. LED modules 3 This type can be made with little effort in any lengths, each suitable, for example, to the length of shelves where they are to be mounted.

At the ends of the assembly 3 is the inner cavity through inserted plastic blocks 8th closed, with two contacts on the outside 9 . 10 for the supply voltage line 4 or the ground line 5 exhibit. As contacts 9 . 10 For example, the interlockable contacts conventionally used with 9V block batteries are contemplated. In general, however, any pair of mutually complementary contacts is suitable.

The supply voltage line 4 and the ground line 5 extend in each LED assembly 3 from a graduation block 8th to the opposite end block 8th , wherein the supply voltage line at both end blocks 8th with identical contacts 9 and the ground line with its identical contacts 10 connected is.

Adjacent to the contacts 9 . 10 is at every graduation block 8th a recess 11 educated.

The LED assemblies 3 are with each other and with the (in 2 not shown) power supply 1 via inexpensive two-core supply cable 12 connected to each other at their ends with contact carrier plates 13 are provided. Each contact carrier plate 13 has a recess on one side 11 corresponding to those of the contact blocks 8th and on the opposite side one to the recess 11 complementary projection 14 on. contacts 9 . 10 are each on each side of each contact carrier plate 13 arranged, each with contacts of different types 9 respectively. 10 on different sides of the plate 13 opposite each other and are conductively connected. If a contact carrier plate 13 on one of the contact blocks 8th is snapped, leaving the lead 14 the plate 13 in the recess 11 of the block 8th engages and one contact each 9 of the block 8th with a contact 10 the plate 13 and a contact 10 of the block 8th with a contact 9 the plate 13 is connected, then forms the of the LED assembly 3 opposite side of this contact carrier plate 13 an arrangement of contacts 9 . 10 , that of the block 8th exactly like. It can therefore further contact carrier plates as needed 13 other connection cable 12 be plugged in to create an arbitrarily branched cable system. Because connecting cable 12 at both ends of each LED assembly 3 can be attached, even elongated arrangements can be wired quickly and easily.

To all LED modules 3 of the lighting system can be controlled independently, has the master module 2 via a microcontroller 15 (please refer 3 ). This can be the LED assemblies 3 according to a predetermined timing, for example by a in the microcontroller 15 stored program is implemented. It is also conceivable, the microcontroller 15 to connect with various environmental sensors to control the LED assemblies 3 to allow for environmental influences. The microcontroller 15 could also be connected to a PC to give a user a comfortable user interface for controlling the LED assemblies 3 in real time.

The microcontroller 15 controls the LED modules 3 by means of instructions, each in the form of a serial sequence of bits of predetermined bit duration T, as represented by diagram A of FIG 3 shown. Such an instruction may comprise, for example, a sequence of 4n bits, a first word of n bits specifying the address of an LED assembly for which the instruction is intended, and the three subsequent words each having brightness values for red, green and blue LEDs thereof Specify LED assembly.

A modulator 16 that sends the commands from the microcontroller 15 receives, comprises as first modulator stage an oscillator 17 and a logic gate 18 which generates a logical link, here a logical AND, the oscillator signal and the command. The period of the oscillator 17 is a fraction of the bit period T of the instruction such that each "1" bit of the instruction is chopped into a plurality of "1" pulses as in diagram B of FIG 3 shown. In order to achieve a sufficient data transfer rate, should the frequency of the oscillator 17 therefore at least some 10 kHz. Too high an oscillator frequency, however, would result in excessive attenuation of the command signals on the interconnecting cables 12 or on the boards of the modules 3 lead whose line length in practice can easily reach over 100 meters. An oscillator frequency in the range 80 to 150 kHz is therefore expedient; in practice a frequency of 125 kHz was chosen.

One from the microcontroller 15 output "0" bit is through the logic gate 18 not changed, as can also be seen on diagram B.

A second stage of the modulator 16 includes an amplifier stage formed by a transistor 20 one between the base of the transistor 20 and the output of the logic gate 18 attached resistor 21 and one between the emitter of the transistor 20 and mass 5 designed resistance 22 , as well as an LC series circuit, which on the one hand with the supply voltage line 4 on the other hand with the collector of the transistor 20 connected coil 23 and one on the one hand with the collector and on the other hand with ground 5 connected capacitor 24 includes. A capacitor 19 can be between the output of the logic gate 18 and ground to be spectral components of the output signal of the logic gate 18 at harmonics of the oscillator frequency to attenuate.

The resonant frequency of the LC series circuit 23 . 24 is on the frequency of the oscillator 17 Voted. In this way, a harmonic components very poor, almost pure sinusoidal data signal to the supply voltage line 4 modulated whose amplitude in the immediate vicinity of the modulator can reach up to 2000 mV and even after a transmission distance of over 100 m with about 200 mV is still safely evaluated.

To attenuate the data signal through to the supply voltage line 4 Connected loads of the master module 2 , a reaction of the data signal to the microprocessor 15 itself and / or a corruption of the data signal by emissions of the microprocessor 15 to avoid its supply connection and all other consumers of the master module 2 , such as LEDs contained in it, via a coil 47 with the supply voltage line 4 connected.

4 shows a circuit diagram of a demodulator 25 as he especially in each LED assembly 3 is provided to by the master assembly 2 to receive and demodulate originating orders. A preamplifier stage of the demodulator 25 includes in analogy to coil 23 and capacitor 24 on the side of the modulator a capacitor 26 and a coil 27 connected in series between the supply voltage line 4 and ground, and a junction FET 29 , The resonant frequency of the through the capacitor 26 and a coil 27 formed LC series circuit is also equal to the frequency of the oscillator 17 , A mid point of this series connection is via a series resistor 28 with the gate of the junction FET 29 connected. Source and drain of the junction FET 29 are each about a resistor 30 and a coil suppressing the data signal 47 or a resistor 31 with the 12 V supply voltage or with the ground line 5 connected. The ratio of resistances 30 . 31 to the drain and source of the junction FET 29 determines its amplification. The drain of the junction FET 29 forms the signal output of the preamplifier stage.

The at the drain of the junction FET 29 the present amplified data signal is shown schematically in the diagram D '; it comprises oscillation time intervals each corresponding to the transmission of a "1" bit and constant time intervals corresponding to the transmission of a "0" bit. The amplified data signal is passed through the DC component in the output of the junction FET 29 suppressing capacitor 33 on the one hand an output stage, on the other hand supplied to a gain control circuit.

The gain control circuit comprises two diodes 34 . 35 of which one 34 short-circuits the negative half cycle of the amplified signal to ground, resulting in the waveform shown in diagram C '. The positive half-wave charges over the other diode 35 a capacitor 36 , The over the capacitor 36 resulting smoothed voltage is therefore proportional to the strength of the signal at the output of the preamplifier stage. This smoothed voltage controls via a series resistor 37 one to the resistance 31 parallel transistor 38 , The higher the voltage across the capacitor 36 the more permeable the transistor becomes 38 the lower the resistance between the source terminal of the junction FET 29 and ground, and the lower the gain of the junction FET 29 , As a result, at the drain of the junction FET 29 receive a signal whose amplitude is largely independent of the amplitude of the input to the demodulator 25 applied data signal is.

The capacitor 33 forms together with a resistance 48 a high-pass filter which passes substantially unimpeded for the carrier frequency component of the amplified data signal, effectively suppresses low-frequency components which are due to residual ripple of a power supply unit, for example. So will be at the output of the resistor 48 obtained from substantially sinusoidal half-wave signal of the diagram C '.

This signal first passes successively through a bipolar transistor in the post-amplifier stage 39 which is arranged as a modified emitter follower with emitter connected directly to ground. This arrangement provides a high gain which, while not linear, does not have to be for converting the sinusoidal halfwaves of the diagram C 'into square pulses. Two resistors 49 . 50 connect the base of the transistor 39 with supply potential or ground and lay the operating point of the transistor 39 firmly. One with the collector terminal of the transistor 39 and ground connected smoothing capacitor 36 ' reduces the spectral component of the oscillator 17 in the output signal of the transistor 39 as shown in diagram B ', so that at the drain of the MOSFET 40 the binary signal in its in the diagram A of 3 Form shown again.

The microcontroller 41 identifies the address contained in the binary signal and compares it to one or more addresses associated with it. Only in the case of coincidence with one of the stored addresses does it decode the three subsequent data words in order to store them as desired brightness values and thus complete the demodulation.

A control of the LEDs of the module 3 Using the stored values can also be done with the help of the microcontroller 41 respectively.

5 shows schematically the circuit structure of the complete LED assembly 3 , where the demodulator 25 of the 4 schematically in the form of two circuit blocks, the receiver amplifier stage 42 and the microcontroller 41 , is summarized. Supply connections (not shown) of the microcontroller 41 and the amplifier stage 42 as well as LEDs 44R . 44G . 44B are with the supply voltage line 4 over the coil 47 connected. The microcontroller 41 controls three MOSFETs based on the brightness values contained in a command demodulated by it as described above 43R . 43G . 43B whose gate is in each case connected to the ground line 5 is connected and their source in each case via a plurality of parallel-connected LEDs 44R . 44G . 44B with the supply voltage line 4 connected is. The LEDs 44R . 44G . 44B are in groups of three closely spaced LEDs of different colors over the length of the assembly 3 distributed. Each triplet contains one of the MOSFETs 43R controlled red glowing LED 44R , one through the mosfet 43G controlled green glowing LED 44G and one through the MOSFET 43B controlled blue glowing LED 44B , The control of the MOSFETs 43R . 43G . 43B through the microcontroller 41 is on the efficiencies of different colored LEDs 44R . 44G . 44B so tuned that the light of each triplet 44R . 44G . 44B for a viewer white, if the brightness values obtained in the current command are the same for all three LED types. So is both the brightness and the light color of each LED assembly 3 individually controllable.

In the embodiment of 6 is in one of several groups of three LEDs each LED 44R . 44G . 44B a photodiode 45 assigned (as in the figure only for the LED 44R shown) to detect the intensity of the LED in question and to the microcontroller 41 transferred to. This provides feedback about the brightness of the LEDs 44R . 44G . 44B via a modulator 46 back to the master module 2 , The modulator 46 is built like the one in 3 shown modulator 16 , differs from this, however, by the frequency of the oscillator 17 , Like the microcontroller 41 and the amplifier stage 42 has the modulator 46 one with the supply voltage line 4 over the coil 47 connected supply connection. A data signal output of the modulator 46 is directly with the supply voltage line 4 connected. By using a corresponding demodulator 25 with on the modulator 46 tuned resonant frequency equipped master assembly 2 a feedback about the realized brightness of the LEDs 44R . 44G . 44B If necessary, it can take these into account when generating further control commands and thus precisely control the light color and brightness in a closed control loop. Changes in the efficiency of the LEDs 44R . 44G . 44B , which may be due to heating, aging or the like, have no influence on the quality of the light produced. Alternatively, the modulator 46 also just serve to confirm about received commands to the master assembly 2 so that it is able to detect transmission errors and, if necessary, resend an incorrectly received command.

According to a second embodiment of the luminaire system according to the invention, the oscillator 17 and the LC resonant circuit 23 . 24 of the modulator 16 tunable to a plurality of frequencies each associated with a plurality of LED assemblies. The LC resonant circuits 26 . 27 on the side of the demodulators 25 the LED modules, however, have only a fixed resonant frequency. One from the modulator 16 Therefore, a command signal sent on a given frequency speaks only those LED assemblies 3 on, in which the resonant frequency of the LC resonant circuit coincides with the transmitted frequency. An LED assembly may include a plurality of parallel demodulators to be addressable at different frequencies. If one of these frequencies is specific to the particular LED assembly, but another is common to several LED assemblies, then a command sent on one frequency can be targeted to that particular LED assembly, whereas to a command sent to the other frequency all LED modules respond that have a tuned to this other frequency demodulator.

A possible time course of one between the modules 2 . 3 transmitted command signal according to the second embodiment is in 7 shown. The microcontroller 41 on the side of the LED module, the onset of an oscillation initiating the command signal registers with the resonance frequency at the beginning of a time tR. The duration tR of the oscillation represents that of the control unit 2 desired brightness of the red LEDs 44R the addressed assemblies 3 , The value of one at the beginning of the period in the microcontroller 41 In operation, if at the end of the period tR the cancellation of the oscillation is registered, a counter representative of the desired brightness is included. A subsequent period of time tG during which no oscillation is transmitted represents the desired brightness of the green LEDs 44G and is from the microcontroller 41 measured by means of a second counter set in each case at the transition between the time periods tR and tG. The microcontroller determines accordingly 41 the desired brightness of the blue LEDs 44B on the basis of the duration of a time interval tB which follows the time interval tG and transmits the oscillation.

Claims (17)

Light system with at least one LED module ( 3 ), which has at least one LED ( 44R . 44G . 44B ), a master assembly ( 2 ) for controlling the operation of the LED assembly ( 3 ) and a supply line ( 4 . 5 ) to which the LED assembly ( 3 ) is connected to the supply of an electrical operating voltage, characterized in that the master module ( 2 ) a modulator ( 16 ) for modulating control commands on the electrical operating voltage and the LED assembly ( 3 ) a demodulator ( 25 ) for recovering the control commands from the electrical operating voltage. Lighting system according to claim 1, characterized in that the modulator ( 16 ) is arranged to aufzumodulieren the electrical operating voltage to a control command address information that the LED assembly ( 3 ) at least one address is assigned and the LED assembly ( 3 ), control commands whose address information does not address the LED assembly ( 3 ) corresponds to not execute. Lighting system according to claim 2, characterized in that it comprises a plurality of LED assemblies ( 3 ), to which an identical address is assigned. Lighting system according to claim 2, characterized in that each of the plurality of LED assemblies ( 3 ) is further associated with a specific address for them. Luminaire system according to one of the preceding claims, characterized in that at least one control command is defined, which is a change in the ratio of the brightnesses of a plurality of LEDs ( 44R . 44G . 44B ) of a same assembly ( 3 ) allowed. Luminaire system according to claim 5, characterized in that the control command comprises a plurality of timestamps, and that the time interval (tR, tG, tB) between each two of the timestamps each have a control variable for one of the LEDs ( 44R . 44G . 44B ). Lighting system according to one of the preceding claims, characterized in that the electrical operating voltage is a DC voltage, the commands from the modulator ( 16 ) are modulated as AC signals. Lighting system according to one of the preceding claims, characterized in that the at least one LED assembly ( 3 ) a modulator ( 46 ) for modulating operating state information, in particular the brightness of at least one of the LEDs of the LED assembly ( 3 ), the electrical operating voltage and the master unit ( 2 ) comprises a demodulator for recovering the operating state information from the electrical operating voltage. Lighting system according to one of the preceding claims, characterized in that in at least one of the assemblies ( 2 ; 3 ) at least one supply connection of at least one consumer ( 15 ; 42 ; 44R . 44G . 44B ) via a coil ( 47 ) with the supply line ( 4 ) and an output of the modulator ( 16 ; 46 ) of the module directly to the supply line ( 4 ) connected is. Lighting system according to one of the preceding claims, characterized in that the at least one LED assembly ( 3 ) several identical connections ( 8th ) for the operating voltage. Lighting system according to claim 10, characterized in that at opposite ends of the elongated LED assembly ( 3 ) one connection each ( 8th ) is arranged for the operating voltage. Lighting system according to claim 10 or 11, characterized in that a supply cable ( 12 ) for connecting the at least one LED assembly ( 3 ) with another LED assembly ( 3 ) and / or with the master module ( 2 ) at least one contact carrier ( 13 ), which has at least one connection ( 8th ) of the LED assembly ( 3 ) complementary port and at least one with the port ( 8th ) of the LED assembly ( 3 ) carries identical connection. Lighting system according to claim 12, characterized in that the contact carrier ( 13 ) has two major surfaces, one carrying the complementary terminal and the other the identical terminal. Lighting system according to one of the preceding claims, characterized in that the modulator ( 16 ) a series resonant circuit ( 23 . 24 ) as the output stage. Lighting system according to claim 14, characterized in that the series resonant circuit ( 23 . 24 ) can be connected to a switched on / off digital transmission signal (B) whose sampling frequency to the resonance frequency of the series resonant circuit ( 23 . 24 ) is tuned. Lighting system according to one of the preceding claims, characterized in that an input stage of the demodulator ( 25 ) through a series resonant circuit ( 26 . 27 ) is formed. Lighting system according to one of the preceding claims, characterized in that the demodulator ( 25 ) an automatic gain control circuit ( 35 - 38 ) having.

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