EP2554021B1 - System-voltage transmission branch of an interface of an operating device for light-emitting means - Google Patents

Description

The present invention relates to the transmission of data or energy from an operating device for lighting, in particular to a method and a device and a system for data and / or energy transmission, in the field of building technology, in particular lighting technology.

As an example of a data transmission in the field of lighting equipment is from the WO 0152607 A1 an electrical lamp control gear having a control signal input through which the operating device receives digital control signals for controlling the electric lamps. At the same time, it is provided that analog control signals can also control the operation of the lamps and of the operating device via the same control signal input.

Also known is the transmission of data over the power grid. With this technology, also called Powerline Communication (PLC), the carrier frequency of the mains voltage is modulated with a high-frequency signal. Devices that are connected to the power grid within a building can thus transmit data via the power lines laid in the building or receive signals from other devices through appropriate demodulation.

The present invention is based on the object of specifying an alternative system, or to provide a system for the transmission of optional data or energy, which is particularly suitable for building services equipment.

The central idea is to provide an interface of a control device for lighting means with a mains voltage transmitting branch, which selectively switches a mains voltage on a bus to another operating device. Thus, a data and energy transfer take place, wherein the protocol of the data transmission, the states "mains voltage on" and "mains voltage off", the presence, number and / or duration of the receiving side can be evaluated by the other operating device. The protocol, however, preferably and thus in Ggs., For example, to PLC before no modulation to a mains voltage wave before.

According to the present invention, it is provided that an operating device for lighting means, in particular an electronic ballast, can emit signals via an interface which has at least one transmission branch. The signals are emitted in such a way that one of the interface separately (ie via a further input of the operating device) supplied to the mains voltage selectively, for example, over a predetermined period, is switched to the bus. The mains voltage is connected to the said bus by a separately provided mains voltage supply of the operating device. Thus, the electronic ballast or the operating device signals one or more other operating devices or other sensors or actuators in the Building technology send out signals. These can evaluate the signals by, for example, evaluating the repetition number of the network switching processes or their duration.

In contrast to powerline communication, a higher-frequency signal is not modulated onto a continuous mains wave, but selectively switches the mains voltage on and off. This selective switching of the mains voltage can, for example, have a positive effect on the emission of interfering frequencies.

The transmitting branch of an interface of a control device for lighting means can selectively switch mains voltage to a bus line, wherein on the receiving side an evaluation in the sense of data transmission or else only one evaluation can be provided as energy for a "wake-up phase". A "wake-up phase" is usually the amount of time it takes for a powered control unit to start up its own power supply.

The possibility of evaluating the bus voltage generated by an electronic ballast either as data transmission and / or as power supply is another advantage of the present invention over the transmission possibilities known from the prior art.

The object of the present invention is solved by the subject matter of the independent claims. Advantageous developments of the invention are the subject of the dependent claims.

• wenigstens einen Versorgungsanschluss zum Anschließen des Betriebsgeräts an einer von einer Versorgungsquelle zur Verfügung gestellten Versorgungsspannung, insbesondere einer ggf. gleichgerichteten Wechselspannung wie bspw. einer Netzspannung,
• Ausgangsanschlüsse zum Steuern eines zugeordneten Leuchtmittels, wie bspw. wenigstens einer LED, OLED, oder Gasentladungslampe,
• eine Schnittstelle zum Anschließen an einen Bus, und
• einen mit der Schnittstelle gekoppelten Sendezweig, wobei der Sendezweig dazu ausgebildet ist, die zugeführte Versorgungsspannung, vorzugsweise eine AC-Spannung, selektiv, d.h. mit einer von einer Steuereinheit des Betriebsgeräts vorgegebenen Taktung, auf den Bus zu schalten.

According to a first aspect of the present invention, an operating device for operating, in particular, a lighting means is proposed, wherein the operating device has:

• at least one supply connection for connecting the operating device to a supply voltage provided by a supply source, in particular an optionally rectified AC voltage such as, for example, a mains voltage,
• Output terminals for controlling an associated light source, such as at least one LED, OLED, or gas discharge lamp,
• an interface for connecting to a bus, and
• a transmitting branch coupled to the interface, wherein the transmitting branch is designed to switch the supplied supply voltage, preferably an AC voltage, selectively, ie with a predetermined by a control unit of the operating device clocking on the bus.

The signal transmission by the pulsed switching on of the supply voltage to the bus and thus the coding of the bus signal can be done with a higher frequency than the frequency of the AC supply voltage.

The supply voltage is preferably connected to the bus for signal transmission.

The signal transmitted over the bus must be coded by means of the time duration of the switching on of the supply voltage, or the number or the frequency of the Aufschaltvorgänge.

The supply voltage can preferably be connected to the bus for supplying energy to another device or receiver connected to the bus.

The operating device can be configured as master and the further device or receiver as slave.

The supply voltage applied to the bus can serve as starting energy of an active device or receiver connected to the bus, which has a separate power supply.

The switched-on supply voltage can be used as start-up energy for another operating device connected to the bus.

The supply voltage applied to the bus can serve as electrical supply to a passive device or receiver connected to the bus which does not have a separate power supply.

The passive device may be a sensor, in particular a brightness sensor or daylight sensor.

The interface may have a mains voltage-proof switch for connecting the supply voltage to the bus.

Preferably, the operating device may have a receiving branch coupled to the interface, wherein the receiving branch is designed to evaluate a supply voltage applied to the bus.

The supply connections can be designed to connect a mains voltage.

According to a further aspect of the present invention, a system is proposed with at least one operating device having a receiving branch described above.

The system may include a switch or button that, when actuated by a user, is configured to selectively connect a voltage, in particular the supply voltage, to the bus.

A further aspect of the invention relates to a lighting system, comprising a plurality of operating devices for operating a lighting device, wherein the operating devices are each connected to a bus via an interface, and at least one supply connection for connecting the operating device to a supply voltage provided by a supply source, in particular an alternating voltage such as, for example, a mains voltage and output terminals for controlling the lighting means,
wherein at least one operating device is connected via connections to a sensor,
and this operating device has a transmitting branch coupled to the interface, a control unit of the operating device switching the supplied and possibly rectified supply voltage clocked to the bus line in order to send data to another operating device, the data being analog or digitally encoded by the timing of the switching on of the supply voltage.

• das erste Betriebsgerät von einer Versorgungsspannung versorgt wird,
• das erste Betriebsgerät diese empfangene ggf. gleichgerichtete Versorgungsspannung über einen Sendezweig getaktet auf den Bus schaltet, um die Daten an das zweite Betriebsgerät zu senden, wobei die Daten analog oder digital durch die Taktung des Aufschaltens der Versorgungsspannung kodiert sind,
• der Empfänger über einen Empfangszweig die auf den Bus aufgeschaltete Versorgungsspannung auswertet.

According to a further aspect of the present invention, a method is proposed for transmitting data via a bus starting from a first operating device for operating, in particular, a lighting device to a second operating device, wherein

• the first operating device is supplied by a supply voltage,
• the first operating device switches this received, possibly rectified supply voltage via a transmitting branch clocked to the bus to send the data to the second operating device, wherein the data is encoded analog or digital by the timing of the switching of the supply voltage,
• the receiver evaluates the supply voltage applied to the bus via a reception branch.

• Fig. 1 zeigt eine schematische Darstellung eines Beleuchtungssystems gemäß einem Ausführungsbeispiel der vorliegenden Erfindung mit mehreren Betriebsgeräten mit und ohne Sensorik, wobei diese Betriebsgeräte über einen Kommunikations-Bus miteinander verbunden sind.
• Fig. 2A zeigt den Verlauf der Netzspannung aus dem Netzversorgungsnetz und Fig. 2B und 2C zeigen einen möglichen Verlauf der Spannung auf dem Bus.
• Fig. 3 ist eine schematische Darstellung eines Vorschaltgeräts gemäß der vorliegenden Erfindung.
• Fig. 4A zeigt einen möglichen Verlauf der Spannung auf dem Bus und Fig. 4B den Verlauf der Netzspannung.
• Fig. 5 ist eine schematische Darstellung eines Vorschaltgeräts gemäß einem weiteren Ausführungsbeispiel der vorliegenden Erfindung.

The subject matter of the invention will be explained in more detail below on the basis of preferred exemplary embodiments, which are illustrated in the accompanying drawings.

• Fig. 1 shows a schematic representation of a lighting system according to an embodiment of the present invention with multiple operating devices with and without sensors, said operating devices are connected to each other via a communication bus.
• Fig. 2A shows the course of the mains voltage from the mains supply network and Figs. 2B and 2C show a possible course of the voltage on the bus.
• Fig. 3 is a schematic representation of a ballast according to the present invention.
• Fig. 4A shows a possible course of the voltage on the bus and Fig. 4B the course of the mains voltage.
• Fig. 5 is a schematic representation of a ballast according to another embodiment of the present invention.

The Fig. 1 shows a schematic representation of a lighting system 1 according to a first embodiment of the present invention. The communication system 1 comprises three electronic ballasts 3, 4, 5 for operating bulbs 12, wherein the ballasts are connected to a power supply network 2.

The illustrated electronic ballasts 3, 4, 5 each have two terminals 6, 7 which are connected to a bus 2. Via this bus 2 data and / or energy can be transmitted between the ballasts 3, 4, 5 and other components connected thereto. A ballast 3, 4, 5 connected to the bus 2 has an interface 21, which has a transmitting branch and / or a receiving branch, so that the electronic ballast 3, 4, 5 can emit and / or receive signals. The bus may preferably comprise two lines 14, 15, namely a neutral conductor 14 and a phase conductor 15 Designations refer to the fact that according to the invention - as explained in detail later - selectively an AC voltage or a rectified version thereof, in particular an AC line voltage is switched to these lines 14, 15. Basically, the provision of one or two conductors to which a voltage can be applied is sufficient.

Each electronic ballast 3, 4, 5 also has two terminals 16, 17 which are connected to the neutral conductor or neutral conductor 18 and to the phase conductor 19 of the AC voltage source network 20 made available AC voltage source. Alternatively, it is also provided that the electronic ballasts 3, 4, 5 in addition to the two terminals 16, 17 still a third terminal (not shown) may have, which three terminals corresponding to the earth, the phase 19 and the neutral conductor 18 a Voltage supply are connectable.

In addition, the electronic ballasts 3, 4, 5 control lines 10 for controlling a lamp 12. In addition, the electronic ballasts 3, 5 preferably also have an interface with two terminals 8, 9 for connection to a sensor 11, for example, a brightness sensor or daylight sensor , on.

It has already been pointed out in the introduction that the electronic ballasts 3, 4, 5 each represent only one example of a building services equipment, in particular for a control gear for lamps. The present invention can be applied to any lamps.

As a light source both electric lamps such as incandescent or gas discharge lamps and light emitting diodes (LEDs, OLEDs) can be used.

Furthermore, a switch or pusher 13 is optionally connected to the lines 15 of the bus 2 such that the bus phase conductor 15 can be acted upon by an external voltage, in particular a mains voltage.

According to the present invention, it is provided that the electronic ballast 3, 4, 5 for lamps via the interface 21, which has at least one transmitting branch, can emit signals by one of the interface 21 separately supplied mains voltage selectively by a mains voltage resistant switch of the interface 21st is switched to the bus 2. The timing of the switch is predetermined by a control unit of the operating device, so that the control unit can transmit data generated or present internally in the operating device as well as externally supplied data to another operating device.

This control unit may be an integrated circuit such as an ASIC, microprocessor or a hybrid thereof.

The control unit may be a special control unit for controlling the transmission and possibly reception operation of the interface. In this case, the control unit is in data communication with another control unit that controls the lighting mode.

Alternatively, this control unit can also control the lighting mode. At least in this case will the control unit vorzugseise with a potential separation (optocoupler, transformer, etc.) are connected to the mains voltage-resistant switch.

The control unit is used for digital or analog coded transmission and optionally also for receiving data. The data to be sent can be internally generated or existing data, such as data relating to optical (color, color temperature, light output, temperature, ...) or electrical parameters of the connected bulbs. The transmission of internal data is particularly suitable for setting up a master-slave operation.

Alternatively or additionally, these data may also be externally supplied data, which, for example, have been supplied to the operating device via a further interface and optionally also another protocol (for example DALI).

The data to be sent can also come from a sensor, for example a light sensor, color sensor or motion detector.

The connection of the supply voltage to the bus can be provided over a predetermined period. According to one embodiment of the invention, signals may be transmitted in accordance with an analog protocol. An example of such an analog protocol is the evaluation of the duration of the connection of the mains voltage. The duration of the connection corresponds in this case to a previously defined signal or control signal. As Aufschalt-duration is preferably a number of periods or half periods of the mains current selected.

An example of such an analog signal transmission over the bus 2 will now be in connection with the Fig. 2A to 2C shown. The course of the mains voltage V from the mains supply network 20 is on Fig. 2A shown. The mains voltage V has a period T0.

Fig. 2B shows the course of the voltage on the bus 2 and on the phase conductor 15. The bus voltage Vb = Vb1 is equal to zero until the time t = T1. At t = T1, a first electronic ballast 3 begins to connect the mains voltage V received via the supply connections 16, 17 to the bus lines 14, 15 of the bus. This is caused by the ballast for a certain period T2-T1. This period of time is preferably greater than the period T0 of the mains voltage V.

Other analog protocols may be based on the repetition rate or repetition rate of a particular on-hook pattern. So, for example, in Fig. 2C have shown that the supply voltage V of the power network 20 can be connected several times in succession for a short time. In the Fig. 2C Bus voltage Vb = Vb2 shown and used for data communication is generated by, within half a period between t = T0 and t = 3T0 / 2, the mains voltage V three times in succession for a time t <T0 / (2 * 3) which is less than half the period is switched to the bus line of the bus. In such a modulation, for example, the repetition rate or repetition rate of the connection is detected by a receiver and evaluated accordingly.

The signal transmission by the clocked connecting the supply voltage to the bus and thus the coding of the bus signal can be done with a higher frequency than the frequency of the AV supply voltage of the operating device.

For signal transmission, the coding of the bus signal can also be defined over the time span of the switch-on (for example over a plurality of half-waves of the supply voltage) or the number of switched half-waves.

Alternatively or additionally, of course, the connection / disconnection of the supply voltage can be used as respective edges of a digital bit.

So it can be implemented a digital or an analog protocol.

The in the Figs. 2B and 2C shown bus voltages show a connection of the mains voltage within a period of T1 to T2 or from T0 to 3T0 / 2. Outside this period, the bus voltage is equal to zero or does not correspond to the mains supply voltage V. The idle state of the bus 2 is then preferably a state where there is no mains voltage. Receivers connected to bus 2 evaluate the bus signal by, for example, determining the duration of a network switching operation or network switching processes ( Fig. 2B ) or the number of network switching operations ( Fig. 2C ) evaluate.

Alternatively, it is also provided that the idle state of the bus line 6, 7 of the bus, the applied mains voltage V is. The course of in Fig. 2B shown bus voltage in this case looks like that between t = T1 and t = T2, the bus voltage Vb is equal to zero. Outside this range, the bus voltage corresponds to the mains voltage. A receiver then evaluates not the duration of a Netzzuschaltvorgangs but the duration of a power off operation. For the electrical load and thus also the thermal load of the particular switch of the interface 21, it is advantageous, however, if this only has to be transmitted for a short time, and otherwise the idle state is the non-switched mains voltage.

The related to Figs. 2B and 2C Examples described in particular the evaluation of the duration of the connection of the mains voltage to the bus line of the bus or the evaluation of the number of successive Aufschaltvorgänge represent examples of an analog protocol. According to the invention, it is also intended to implement a digital protocol. For example, certain phases of the mains voltage can be assigned to specific bits. In particular, if such a digital protocol is present, the actual drive data can be provided with a kind of header, which reproduces the priority of the corresponding following signals. The header may contain additional information about the payload itself. It may also include, for example, additional information or identification information about the ballast 3, 4, 5, which transmits the signal via the bus 2.

According to a further embodiment of the invention, the bus 2 can also be provided to transmit via a reception and / or transmit branch also to the terminals 6, 7 of the interface 21 to transmit digital signals, for example, according to a protocol for lighting systems such as DALI standard (Digital Addressable Lighting Interface) to transfer. From the ballast 3, 4, 5 corresponding signals, in the form of a DC voltage with in comparison to the mains voltage V substantially lower amplitude (for example, a maximum of 12 volts) can be transmitted. In this case, the said transmission branch, ie the switch of the transmission branch, designed mains voltage resistant. According to the invention and in contrast to the DALI transmission mode, the bus 2 is not selectively short-circuited, but selectively mains voltage V is applied to the bus lines 14, 15 of the bus.

The operating device 3, 4, 5, in addition to the said interface 21 for connecting to the bus line 2 of the bus have further communication options, in particular a further interface 22 for example, digital protocols such as the above-mentioned DALI or used for dimming electronic ballasts DSI Protocol (Digital Serial Interface).

According to a further embodiment of the invention, the selectively applied in the sense of signal transmission mains voltage from a receiver can also be used as electrical energy. This may be, for example, the electrical starting energy for a ballast, or else the electrical supply (possibly using a buffer such as a capacitor) for a sensor 23, which requires a power supply.

In order to enable the evaluation of transmitted data as start-up energy of a control unit (eg ASIC) of the receiver device, provision can be made for redundant data to be sent, for example pure wake-up signals or a multiple transmission of real data signals.

The selective connection of the mains voltage by an operating device 3, 4, 5 is evaluated in this case by a receiver not in the sense of a useful signal, but provides only the necessary starting energy for the startup phase of the receiver. A receiver is in the sense a ballast 3, 4, 5 or another unit connected to the bus 2, which can use the bus voltage via a receiving branch. If this bus voltage Vb is used on the receiving side as electrical energy, the receiver needs no special intelligence concerning the evaluation of the bus signal and in particular regarding the repetition rate, the repetition rate or the duration of the switched-on mains voltage.

Rather, the system 1 in this case is a hierarchical master-slave system, where at least one ballast 3, 4, 5 as master provides electrical energy on the bus 2 available. The other units of the system (ballasts or sensors, for example) function as a slave and are dependent on the energy provided on the bus 2.

This starting energy is typically that energy which is necessary to be able to start a low-voltage power supply in an operating device 3, 4, 5, this low-voltage power supply, for example, a Integrated circuit such as an ASIC 31 or a microcontroller starts, which then starts up (in particular, its own power supply in operation) and can control the operation of the operating device. Thus, there would be no actual data transmission but only the transmission of a kind of wake-up energy.

According to one scenario of the present invention, a ballast 3, 4, 5 is connected to a sensor which transmits data such as brightness data to the ballast. The sensor 11 can be connected to the ballast 3, 4, 5 via the two connections 8, 9 designed for this purpose. Alternatively, the sensor 23 can be connected via the bus 2 to the ballast, in which case appropriate electrical energy should then be made available on the bus 2 if the sensor 23 itself does not have its own power supply. The operating device or ballast can then use the received sensor data on the said selective connection of the mains voltage to the bus line 2 of the bus then control further slave devices or slave sensors or slave actuators.
Thus, it is possible to build a control system for a lighting, where, for example, only a single Vorschalgerät is connected to a sensor 11. This ballast can evaluate the signals received by the sensor 11 and then both adapt its own operation accordingly and also transmit corresponding data via the bus 2 to the further ballasts. It is thus also possible that various sensors are connected to each ballast. For example, a brightness sensor as a sensor 11 to a first ballast 3 are connected and a motion sensor connected as a sensor 11 to another ballast 5. In this case, the two Vorschalgeräte 3 and 5 communicate with each other via the bus 2. For example, the ballast 5 can detect a movement via its sensor 11 and inform the other ballasts, in particular the ballast 3 with the brightness sensor accordingly. The ballast 3 can query the brightness on the sensor 11 upon receipt of this data. If it is determined that the current brightness does not coincide with the brightness predetermined for the case of a detected movement, then the ballast 3 can adjust the brightness of its connected illuminant accordingly and / or a corresponding brightness change in the other ballasts 4, 5 connected to the bus 2 initiate via corresponding bus signals.

The corresponding bus signals can be prioritized in this case, for example, a prioritization of the bus signals can thus take place depending on the type or priority of the respectively connected sensor 11. For example, the bus signals that are emitted by the ballast 5, have a higher priority than the bus signals of the ballast 3.

The sensors 11 may be different types of sensors, for example presence sensors, color sensors, artifact sensors, external light sensors, temperature sensors or receivers for infrared signals or radio signals.

Thus, a lighting system is made possible, which has a plurality of operating devices 3, 4, 5 for operating a luminous means 12, wherein the operating devices 3, 4, 5 are each connected via an interface 21 to a bus line 2. The operating devices 3, 4, 5 have at least one supply connection 16, 17 for connecting the operating device to a supply voltage provided by a supply source 20, in particular an alternating voltage such as a mains voltage, and an output terminals 10 for controlling the lighting means 12. At least an operating device 3 is connected to a sensor 11 via ports 8, 9 designed for this purpose. This operating device 3 has a transmitting branch coupled to the interface 21, a control unit of the operating device switching the supplied and possibly rectified supply voltage clocked to the bus line 2 in order to send data to another operating device, the data being analog or digital through the clocking the switching-on of the supply voltage are coded. These data are preferably dependent on the monitoring of the sensor 11.

Preferably, the interface 21 is designed to be bidirectional for connection to the bus line of the bus. That is, any device that can send to the bus 2 by selectively switching from the mains voltage, can accordingly evaluate mains voltage resistant such signals from the bus 2 and pass under potential isolation to its own ASIC or other integrated circuits.

In an illumination system 1 according to the invention, which has at least one operating device 3, 4, 5 which, as described above, can selectively transmit data or at least energy by switching on mains voltage V, it is also possible to provide switches or push buttons which can initiate processes as a manual interface. An example of such a switch is the in Fig. 1 shown switch 13, with which a user can cause the selective connection of a mains voltage. When switching on the switch 13, the phase conductor 19 of the supply network is in fact connected to the phase conductor 15 of the bus.

A typical bus voltage generated upon actuation of the switch 13 is in FIG Fig. 2B shown. The switch 13 is switched on at t = T1 by the user and released again at t = T2. Manual actuation of the switch 13 generally results in a number of mains voltage cycles being applied to the bus. In the bus signal the Fig. 2B If more than two half periods have been switched to bus 2 manually.

It is desirable to distinguish a manual impact of a mains voltage from a triggered by a ballast 3, 4, 5 Aufschlagens. In order to discriminate a manual actuation switch and thus a manual impact from the signals emitted by an operating device, the protocol for transmitting from an operating device is preferably such that the mains voltage is not continuously applied as in manual operation.

Correspondingly, for transmission starting from an operating device, coding can take place over a phase angle. Accordingly, no complete half waves are transmitted as in the operation of the button or switch. An exemplary bus voltage that may result is in FIG Fig. 2C shown. During a half-wave of the mains voltage, the impact of the mains voltage on the bus 2 is interrupted at least once. In the example of Fig. 2C the impact is even interrupted twice, so that the half-wave shown is not transmitted continuously.

As an alternative to the phase angle, for example, a phase section or a combined phase-angle section or similar waveforms are possible.

A receiver can then very well differentiate between a bus voltage based on a user or a ballast, depending on whether the half-waves of the bus voltage are continuous or not. It is therefore also possible to make the priority of a bus signal dependent on the type of impact. A user-initiated bus signal may be given a higher (or lower) priority than a bus signal from an operating device.

Furthermore, a switch 30 in a ballast 3 can pass only positive or only negative half-waves, which represents a phase-angle coding and on the other hand also enables switching in the zero crossing. Such a switch 30 is in Fig. 3 shown. Fig. 3 shows in particular a ballast 3 with an ASIC 31 and a transmission branch coupled to the two bus terminals 6, 7.

As in FIG. 5 As shown, interface 21 with terminals 6 and 7 can also be designed for connection to a digital bus. For example, the interface can alternatively be connected to a DALI bus (according to the DALI protocol) and receive and evaluate digital signals. For this purpose, the interface behind the internal rectifier may have a receive and transmit circuit for DALI commands.

If the interface 21 is to be connected to a DALI bus, only the connection between the connection for neutral or neutral conductor 18 and the one input 6 of the bus connection must be interrupted or not set. In the FIG. 5 shown circuit variant shows a separate DALI return channel (driven via the output DA of the control circuit 31). However, it is also possible to design the interface circuit in such a way that a common transmission stage for both the DALI transmission mode and for the transmission mode according to the invention is made possible by connecting the mains voltage to the bus line 2.

As in Fig. 3 shown, the neutral conductor 18 may be connected to one of the two terminals of the interface 21, for example to the bus terminal 6. Such a connection can be made outside the ballast or even within the ballast. Preferably, this connection can be merged or interrupted by the user, especially if the Interface 21 should only be used optionally for the connection according to the invention and, if appropriate, should also be used for other data transmission (for example, for a bus connection according to the DALI protocol). For example, a detachable connection between the neutral conductor 18 with one of the two terminals of the interface 21 may be present, such as by means of jumper, jumper or switch. If this connection is present, it is made possible for the electronic ballast 3, 4, 5 for lamps to emit signals via the interface 21, by a mains voltage supplied separately to the interface 21 (by means of this connection) selectively by a preferably mains voltage-resistant switch of the interface 21 is switched to the bus 2. The timing of the switch is predetermined by a control unit of the operating device, so that the control unit can transmit data generated or present internally in the operating device as well as externally supplied data to another operating device. If a corresponding protection circuit is present, it is also possible to dispense with a power-voltage-proof design of the switch 30.

While Fig. 4B shows the course of the mains voltage V is in Fig. 4A shown the voltage Vb3, which is switched by the ballast 3 via the two bus terminals 6, 7 on the bus 2. The mains voltage is modulated in such a way that only the positive half-waves or only the negative half-waves of the mains voltage are switched on. This modulation also makes it possible to discriminate between the application of a mains voltage from a ballast and a ballast from a user via actuation of a switch 13 generated continuous bus voltage.

Furthermore, a coding of the bus signal, for example over the length of the phase angle, so that, for example, the length of the phase angle (phase angle difference) is used as Dimmwertvorgabe. On the reception side, a ballast can evaluate this signal and derive corresponding dimming commands for the light sources that the input-side ballast has to control.

LIST OF REFERENCE NUMBERS

1

communication system

2

bus

3, 4, 5

Electronic ballasts

6, 7

Bus connections of the electronic ballast

8, 9

Connections of the electronic ballast

10

control line

11

sensor

12

Lamp

13

Switch or pusher

14

Bus-neutral

15

Bus-phase conductor

16, 17

Mains connections of the electronic ballast

18

Neutral conductor or neutral conductor of the supply network

19

Phase conductor of the supply network

20

Power supply network

21

Interface for connection to a bus line of the bus

22

Further interface for digital protocols

23

Slave sensor

30

switch

31

ASIC

Claims (16)

1. Operating device for operating in particular a light-emitting means (12), having

   - at least one supply terminal (16, 17) for connecting the operating device to a supply voltage provided by a supply source (20), in particular an AC voltage such as, for example, a mains voltage,

   - output terminals (10) for controlling the light-emitting means (12),

   - an interface (21) for connection to a bus (2), and characterized in that the operating device additionally has

   - a transmission branch which is coupled to the interface (21), wherein a control unit of the operating device connects the supplied and possibly rectified supply voltage, clocked, to the bus (2) in order to transmit data to a further operating device, wherein the data are encoded in analogue or digital form by virtue of the clocking of the connection of the supply voltage.
2. Operating device according to Claim 1, wherein the supply voltage is connected to the bus (2) for signal transmission.
3. Operating device according to Claim 2, wherein the signal transmitted via the bus (2) is encoded in analogue or digital form by means of the temporal duration of the connection of the supply voltage, the number or the frequency of connection operations.
4. Operating device according to one of the preceding claims, wherein the supply voltage for supplying energy to a further device or receiver connected to the bus (2) is connected to the bus (2).
5. Operating device according to Claim 4, wherein the operating device is configured as master and the further device or receiver is configured as slave.
6. Operating device according to one of the preceding claims, wherein the supply voltage connected to the bus (2) acts as runup energy of an active device or receiver, which is connected to the bus (2) and which has a separate voltage supply.
7. Operating device according to Claim 6, wherein the connected supply voltage is used as runup energy for a further operating device connected to the bus (2).
8. Operating device according to one of Claims 1 to 5, wherein the supply voltage connected to the bus line (2) acts as electrical supply for a passive device or receiver, which is connected to the bus (2) and which does not have a separate voltage supply.
9. Operating device according to Claim 8, wherein the passive device is a sensor, in particular a brightness sensor or daylight sensor.
10. Operating device according to one of the preceding claims, wherein the interface (21) has a mains-voltage-fixed switch for connecting the supply voltage to the bus (2).
11. Operating device according to one of the preceding claims, having a reception branch which is coupled to the interface (21), wherein the reception branch is designed to evaluate a supply voltage connected to the bus (2).
12. Operating device according to one of the preceding claims, wherein the supply terminals (16, 17) are designed for connecting a mains voltage.
13. System comprising at least one operating device according to Claim 11 or 12, having a reception branch.
14. System according to Claim 13, having a switch or pushbutton (13), which is designed to connect, on actuation by a user, a voltage, in particular the supply voltage, selectively to the bus (2).
15. Lighting system, having a plurality of operating devices (3, 4, 5) for operating a light-emitting means (12), wherein

    - the operating devices (3, 4, 5) are each connected to a bus line (2) via an interface (21),

    - and have in each case at least one supply terminal (16, 17) for connecting the operating device to a supply voltage provided by a supply source (20), in particular an AC voltage such as, for example, a mains voltage, and in each case at least one output terminal (10) for controlling the light-emitting means (12), and characterized in that the lighting system additionally has

    - at least one operating device (3), which is connected via terminals (8, 9) to a sensor (11), and this operating device (3) has a transmission branch which is coupled to the interface (21), and

    - a control unit of the operating device, which connects the supplied and possibly rectified supply voltage, clocked, to the bus line (2) in order to transmit data to a further operating device, wherein the data are encoded in analogue or digital form by virtue of the clocking of the connection of the supply voltage.
16. Method for transmitting data via a bus (2) starting from a first operating device for operating in particular a light-emitting means (12) to a second operating device, wherein

    - the first operating device is supplied by a supply voltage, and characterized in that

    - the first operating device connects the supplied and possibly rectified supply voltage via a transmission branch, clocked, to the bus (2) in order to transmit the data to the second operating device, wherein the data are encoded in analogue or digital form by virtue of the clocking of the connection of the supply voltage,

    - the receiver evaluates the supply voltage connected to the bus (2) via a reception branch.

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