DE102016207257A1 - Bus system for the electrical supply of operating devices for lamps and for communication with the operating devices - Google Patents

Abstract

The present invention provides an apparatus adapted to be set up as a master in a bus system comprising at least one lighting device and a bus arranged as a slave; the device comprising an actively clocked DC / DC converter and a discharge circuit connected to the output of the DC / DC converter. The device is further configured to be connected to the at least one operating device for lighting means in such a way that the output of the DC / DC converter is connected via the bus to the at least one operating device for lighting means, the DC / DC converter being set up for this purpose is to provide a DC output voltage at its output for an electrical supply of the at least one operating device for lighting means and is adapted to transmit data via the bus to the at least one operating device. The discharge circuit of the device according to the invention is set up to provide an ohmic load at the output of the DC / DC converter during a data transmission from the DC / DC converter via the bus to the at least one operating device. Furthermore, the present invention provides a bus system with a device according to the invention configured as a master as well as a method for operating the device according to the invention.

Description

1. Field of the invention

The present invention relates to a bus system, in particular a DC bus system, for the electrical supply of operating devices for lamps and for communication with the operating devices. Furthermore, the present invention relates to a device that is adapted to be configured as a master in such a bus system, and to a method for operating such a device.

2. Background

Bus systems, in particular DC bus systems, are known from the prior art in which a device configured as a master comprises a DC / DC converter for providing a DC voltage V _{BUS in} order to connect to the bus of the bus system connected slaves, such. B. equipment for lighting, to supply the DC voltage V _BUS electrically.

In such bus systems, the device configured as a master comprises a PLC transmitter and a PLC interface for communication with the slaves via the bus (PLC = "Powerline Communication"). In this case, each slave must also include a PLC interface to provide a load impedance for the high-frequency PLC signals.

According to the state of the art, therefore, a PLC interface and a PLC transmitter in the master and in each case a PLC interface in each of the slaves are required for PLC communication between the master and the slaves via the bus. This is disadvantageous because these components required for communication cause additional costs in the bus system.

In the light of this prior art, it is therefore an object of the present invention to provide a device which is adapted to provide in a bus system as a master both a DC voltage for an electrical supply of slaves, in particular of operating devices for lighting means, as well to enable more cost-effective communication with the slaves via the bus.

These and other objects, which will become apparent upon reading the following description or which will be recognized by those skilled in the art, are achieved by the subject-matter of the independent claims. The dependent claims further form the central idea of the present invention in a particularly advantageous manner.

3. Detailed description of the invention

According to the present invention, there is provided a device adapted to be set up as a master in a bus system comprising at least one lighting device and a bus arranged as a slave; the device comprising an actively clocked DC / DC converter and a discharge circuit connected to the output of the DC / DC converter. The device is further configured to be connected to the at least one operating device for lighting means in such a way that the output of the DC / DC converter is connected via the bus to the at least one operating device for lighting means, the DC / DC converter being set up for this purpose is to provide a DC output voltage at its output for an electrical supply of the at least one operating device for lighting means and is adapted to transmit data via the bus to the at least one operating device. The discharge circuit of the device according to the invention is set up to provide an ohmic load at the output of the DC / DC converter during a data transmission from the DC / DC converter via the bus to the at least one operating device.

A "bus system" is understood to mean a lighting bus system in which at least one operating device for lighting means represents a slave and is electrically supplied via the bus with a DC voltage starting from a device designed as a master. It can be at least one other operating device, which is no operating device for lighting, such. As a control gear for a blind, be connected in the bus system as a slave to the bus and thus be supplied via the bus with the DC voltage.

Under "control gear for lamps" electrical circuits or components understood that are adapted to lighting, such. As light-emitting diodes to operate by providing a current or a voltage. In other words, these are circuits or components which are set up for the electrical supply of lighting means and control the light emission of the lighting means by providing the electrical supply of the lighting means. An operating device for lighting means preferably comprises at least one actively clocked DC / DC converter for providing electrical energy for the lighting means, i. H. for the electrical supply of the bulbs.

By "illuminant" is meant a device which is adapted to emit light. Preferably, a luminous means corresponds to a light-emitting diode path, with one or more light-emitting diodes.

An "actively clocked DC / DC converter" is understood to mean an electrical circuit having at least one switch, in which a DC voltage or rectified and preferably smoothed AC voltage (DC voltage) is switched to a higher, lower or inverted voltage by clocking the at least one switch DC voltage or rectified and preferably smoothed AC voltage is converted. DC / DC converters are also referred to as DC-DC converters. The actively clocked DC / DC converter can be a floating clocked DC / DC converter (clocked DC / DC converter with galvanic isolation between input and output), such. As a flyback converter, push-pull converter or a resonant converter, or a non-isolated or non-isolated clocked DC / DC converter (clocked DC / DC converter without galvanic isolation between input and output), such as. A buck converter, step-down converter, boost converter, step-up converter, or buck-boost converter.

The DC / DC converter according to the device according to the invention may be preceded by an AC / DC converter, wherein the AC / DC converter is preferably designed as a PFC circuit. A "PFC circuit" is understood to mean a power factor correction circuit. In other words, a PFC circuit corresponds to an electrical circuit which is designed to ensure a power factor close to 1 or in accordance with legal requirements. The DC / DC converter may be configured, for example, to change the amplitude of the DC voltage output by the AC / DC converter, to transmit them in an isolated manner or else to stabilize the DC voltage. The DC / DC converter according to the device according to the invention is therefore preferably set up to change the amplitude of the DC voltage output by the AC / DC converter and / or to transmit them electrically isolated and / or to stabilize the DC voltage.

However, the DC / DC converter according to the invention may, for example, also be integrated into an AC / DC converter, in which case the converter converts an AC voltage into a DC voltage and preferably both the function of a power factor correction circuit and provides a DC output voltage at its output for an electrical supply of the at least one operating device for lighting means.

Preferably, the DC / DC converter corresponds to a converter stage of a plurality of converter stages of the device according to the invention.

A "DC voltage" is understood to be a DC voltage or a rectified and preferably smoothed AC voltage.

A "discharge circuit" is understood to mean an electrical circuit which is set up to provide an ohmic load during a data transmission via the bus at the output of the DC / DC converter. In other words, the discharge circuit is configured to operate during a particular state, such as a period of time. B. the state of a data transfer over the bus to provide an ohmic load.

A "data transmission" means a transmission of data via a bus, which is also provided for an electrical supply to the slaves connected to the bus. In other words, it is understood to mean a transfer of data over a bus that provides a DC voltage for electrical supply to the slaves connected to the bus. Such a transmission or communication of data is also referred to as PLC transmission or PLC communication (PLC = "Power Line Communication"). To transmit the data via the bus, the data or data reproducing signals, so-called PLC signals, preferably modulated onto the DC voltage of the bus.

The device according to the invention is able to communicate or transmit data via a bus to the slaves connected to the bus without a PLC transmitter and PLC interfaces. This is advantageous because it reduces costs due to the saved components.

Preferably, the output of the DC / DC converter comprises an output capacitance, at which the DC output voltage for the electrical supply of the at least one operating device is applied, wherein the discharge circuit is connected in parallel with the output capacitance.

Due to the parallel connection of the discharge circuit with the output capacitance can in the case of a high-impedance load at the output of the DC / DC converter by means of the discharge circuit provided by the resistive load, the discharge time of the output capacitance of the DC / DC converter during one of the DC / DC converter outgoing Data transmission can be reduced. This is advantageous, as a result of which data transmission from the device according to the invention via a bus to one or more slaves is also possible for the case when the one or more slaves represent a high resistive load.

Furthermore, the device preferably comprises a control circuit which is set up to determine a high-impedance load state in which the at least one operating device represents a high resistive load.

A "high-impedance load state" is understood to be the state in which a high resistive load is present at the output of the device and thus at the output of the DC / DC converter of the device. In other words, in a bus system in which the device according to the invention is connected as a master via a bus with at least one (corresponding to a slave) operating device for lamps, a high-impedance load state, if the at least one operating device is a high resistive load, d. H. receives a small or small current from the bus.

The control circuit is preferably a microcontroller, ASIC or a hybrid thereof. The control circuit is preferably further configured to control the DC / DC converter and / or the discharge circuit to provide a DC output voltage as a supply voltage for a bus system and to enable communication of data over the bus in a bus system.

Preferably, the at least one operating device for lighting means represents a high ohmic load when the at least one operating device is switched off or is in a dimming operation of the lighting means.

Namely, if the at least one operating device is switched off or is in a dimming operation of the lighting means, the at least one operating device receives no or less current (small current) for the operation of the lighting means. Ie. In a bus system described above, the at least one operating device receives less power from the bus.

Furthermore, the control circuit is preferably configured to determine the high-impedance load state on the basis of the current absorbed by the at least one operating device.

This is advantageous because the high-resistance load state can be determined or determined by the control circuit by a simple current measurement.

Furthermore, the control circuit is preferably configured to control the discharge circuit in such a way that, during the data transmission, the discharge circuit at the output of the DC / DC converter provides an ohmic load when the control circuit determines a presence of the high-resistance load state.

This is advantageous since, by providing or adding in the additional resistive load of the discharge circuit at the output of the DC / DC converter, the long discharge time of the output capacitance of the DC / DC converter caused by the high-resistance load state is reduced in such a way that data transmission with sufficient data transmission rate or data transmission speed is made possible. It is possible to achieve a data transmission speed within the range of the DALI industry standard.

Preferably, the discharge circuit of the device according to the invention comprises a resistor circuit having at least one resistor and a discharge switch connected in series with the resistor circuit, wherein the control circuit of the device according to the invention is preferably arranged to control the discharge switch such that the discharge switch is conductive when the control circuit determines during the data transmission a presence of the high-impedance load state.

This is advantageous because with the use of inexpensive electrical components, such as at least one resistor and a discharge switch, the discharge circuit can be formed. A "discharge switch" is understood to mean a switch. The discharge switch is preferably an electrical switch, such. B. a transistor.

Furthermore, the control circuit is preferably configured to control the DC / DC converter on the basis of a voltage setpoint such that the DC output voltage of the DC / DC converter corresponds to the voltage setpoint; wherein the control circuit is preferably adapted to control the DC / DC converter for a transmission of data such that a modulation voltage corresponding to the data of the DC output voltage of the DC / DC converter is modulated.

By "modulating a modulation voltage on the DC output voltage" is meant superimposing a voltage varying according to the data to be transmitted with the DC output voltage of the DC / DC converter, the control circuit controlling the DC output voltage according to the voltage command value. The modulation voltage preferably corresponds to a voltage that changes between two voltage levels. Thus, by means of the modulation voltage, a digital transmission of data can be performed. For example, each rising or falling edge of the modulation voltage corresponds to one bit of data.

Furthermore, the device according to the invention preferably comprises a control loop which supplies the control circuit with the DC output voltage of the DC / DC converter as a controlled variable; wherein the control circuit is preferably configured to control the DC / DC converter based on the voltage setpoint and the controlled variable.

In other words, the control circuit is configured to control the DC output voltage of the DC / DC converter based on the DC output voltage feedback value and a DC output voltage command value.

The control circuit is preferably set up to change the voltage setpoint in accordance with the data, preferably in an erratic manner, for a transmission of data.

In other words, the control circuit is preferably configured to change the voltage setpoint according to the data so that the DC output voltage of the DC / DC converter reproduces the data for transmission of data. By a step change in the voltage setpoint, a substantially rectangular DC output voltage can be generated which varies between two voltage levels and thus represents a train of voltage pulses, each voltage pulse corresponding to one bit of data. Further, a change from one voltage level to the other voltage level of the DC output voltage, i. H. a rising or falling edge of the DC output voltage corresponding to a data bit.

This is advantageous because the components (DC / DC converter and the control circuit) for providing a DC voltage to a bus for a supply of one or more operating devices, a cost-effective data transmission is enabled.

Further, the control circuit is preferably configured to change the voltage command value corresponding to the data so that the DC output voltage of the DC / DC converter is between a first voltage level and a second voltage level higher than the first voltage level changes.

This corresponds to a digital transmission of data, for example via rising or falling edges, d. H. via a change from one voltage level to the other voltage level, data can be transmitted digitally. For example, each level change may correspond to one data bit.

A "voltage level" is understood to be a voltage level or voltage value.

This is advantageous since in a bus system PLC information or data can be transmitted digitally from the device according to the invention via a bus or digitally modulated onto the bus.

Preferably, the voltage difference between the first and second voltage levels is between 1% and 5% of the average DC output voltage of the DC / DC converter.

In other words, the data transfer control circuit controls the DC / DC converter so that the DC output voltage changes between a first and second voltage level according to the data to be transferred, the voltage difference between the first and second Voltage level is between 1% and 5% of the mean value of the DC output voltage.

This is advantageous since, during the data transmission, an electrical supply of operating devices with a corresponding DC voltage is possible as a result.

Furthermore, preferably, a transition from the second to the first voltage level corresponds to a falling edge, wherein the control circuit is preferably configured to control the discharge circuit such that the discharge circuit during the time period of the falling edge at the output of the DC / DC converter is an ohmic Load provides.

This is advantageous since this limits or limits the electrical losses of the ohmic load provided by the discharge circuit to the duration of a falling edge.

Further, preferably, a transition from the second to the first voltage level corresponds to a falling edge; wherein the control circuit is preferably configured to control the discharge circuit such that the discharge switch is turned on during the time period of the falling edge.

This is advantageous since this limits or limits the electrical losses of the ohmic load provided by the discharge circuit to the duration of a falling edge.

The above-mentioned optional features can be arbitrarily combined according to the present invention to give the device according to the invention.

According to the present invention, a bus system is furthermore provided which comprises a device according to the invention set up as a master, at least one operating device for lamps arranged as a slave and a bus, the device according to the invention being connected via the bus to the at least one operating device for lighting means.

Preferably, the bus system still includes at least one other operating device, which is not a control device for lighting, such. As an operating device for operating a blind, wherein the device according to the invention is preferably adapted to electrically supply the at least one operating device via the bus and to send data to this operating device.

• a) Bereitstellen der erfindungsgemäßen Vorrichtung,
• b) Verbinden der Vorrichtung mit dem wenigstens einen Betriebsgerät für Leuchtmittel derart, dass der Ausgang des DC/DC-Wandlers über den Bus mit dem wenigstens einen Betriebsgeräte für Leuchtmittel verbunden ist;
• c) Bereitstellen einer DC-Ausgangsspannung durch den DC/DC-Wandler an seinem Ausgang für eine elektrische Versorgung des wenigstens einen Betriebsgerätes für Leuchtmittel;
• d) Übermitteln von Daten durch den DC/DC-Wandler über den Bus an das wenigstens eine Betriebsgerät; und
• e) Bereitstellen einer ohmsche Last am Ausgang des DC/DC-Wandlers durch die Entladeschaltung während einer Datenübertragung von dem DC/DC-Wandler über den Bus an das wenigstens eine Betriebsgerät.

Furthermore, according to the present invention, a method is provided for operating a device according to the invention, the method comprising the following method steps:

• a) providing the device according to the invention,
• b) connecting the device to the at least one operating device for lighting means in such a way that the output of the DC / DC converter is connected via the bus to the at least one operating device for lighting means;
• c) providing a DC output voltage through the DC / DC converter at its output for an electrical supply of the at least one operating device for lighting means;
• d) transmitting data through the DC / DC converter via the bus to the at least one operating device; and
• e) providing an ohmic load at the output of the DC / DC converter by the discharge circuit during a data transfer from the DC / DC converter via the bus to the at least one operating device.

The data transmission technology that can be implemented by the device according to the invention in a bus system in which the device according to the invention represents the master has the advantage that, for example, DALI bits can be converted essentially one-to-one into voltage states on the bus of the bus system and thus on the receiver side (slave Page) a DALI interface in a known manner can evaluate the falling and rising edges.

4. Description of preferred embodiments

Hereinafter, a detailed description of the figures will be given. It shows:

1 schematically a bus system for the electrical supply of operating devices for lamps according to the prior art.

2 schematically a preferred embodiment of a bus system according to the invention for the electrical supply of operating devices for lighting means and a preferred embodiment of a device according to the invention, which is adapted to be set up as the master of such a bus system.

3 schematically temporal profiles of the DC output voltage V _{BUS of} the DC / DC converter of a preferred embodiment of a device according to the invention, which is adapted to be configured as a master of a bus system according to the invention.

4 schematically a preferred embodiment of a bus system according to the invention for the electrical supply of operating devices for lighting means and a preferred embodiment of a device according to the invention, which is adapted to be set up as the master of such a bus system.

5 schematically a preferred embodiment of a bus system according to the invention for the electrical supply of operating devices for lighting means and a preferred embodiment of a device according to the invention, which is adapted to be set up as the master of such a bus system.

1 schematically shows a bus system for the electrical supply of operating devices for lighting means according to the prior art.

It is a device designed as a master, a bus, and designed as a slave operating device for lighting means shown, wherein the device comprises a DC / DC converter to electrically supply the slave with a DC voltage across the bus. For a transmission of data over the bus, which is provided for the electrical supply of the operating device designed as a slave (PLC data transmission, PLC = Power Line Communication), the master comprises a PLC transmitter and a PLC interface to the data as a PLC Signals to the operating device via the bus. The operating device includes a PLC interface to provide a load impedance for high frequency PLC signals.

2 schematically shows a preferred embodiment of a bus system according to the invention for the electrical supply of operating devices for lighting means and a preferred embodiment of a device according to the invention, which is adapted to be set up as the master of such a bus system.

The bus system 1 includes a device 2 , a bus 3 as well as a control gear 4 for lighting, the device 2 and the operating device 4 connected to the bus and the device 2 a master and the operating device 4 represent a slave.

In 2 is only a control gear 4 However, there can be more than just a control gear for bulbs as slaves with the bus 3 be connected. In other words, the bus system includes 1 at least one operating device 4 , In addition to a control gear for lamps includes the operating device 1 preferably at least one operating device as a slave, which does not represent a control device for lighting means. For example, this operating device may be an operating device for operating a venetian blind.

The device according to the invention 2 includes an active clocked DC / DC converter 5 , a discharge circuit 6 and a control circuit 7 , The control circuit 7 can also not be part of the device according to the invention, ie be an external control circuit. The DC / DC converter 5 is with the discharge circuit 6 connected, wherein the discharge circuit 6 in parallel with the output capacitance C _{1 of} the DC / DC converter 5 connected is. The DC / DC converter 5 is about the discharge circuit 6 by bus 3 connected, so that the output voltage V _{BUS of} the DC / DC converter 5 the bus 3 provided. In other words, that corresponds to the bus 3 applied voltage or the voltage of the bus 3 with which the operating device 4 is supplied, the DC output voltage V _{BUS of} the DC / DC converter 5 ,

The DC / DC converter 5 is connected to a power supply, which is a part of the device 2 may be or may be located externally. Preferably, the power supply is designed as an AC / DC converter, in particular as a PFC circuit. Preferably, the DC / DC converter provides 5 a converter stage or converter stage of several converter stages of the device 2 representing the bus 3 supplied with a DC voltage (in 2 Not shown). Ie. it can switch between the power supply and the DC / DC converter 5 be arranged further converter stages, wherein the DC / DC converter 5 the converter stage is in the chain of converter stages connecting the bus 3 supplied with a DC voltage. The control circuit 7 is to set up the actively clocked DC / DC converter 5 , In particular, the least one switch of the active clocked DC / DC converter, and the discharge circuit 6 to control. The control circuit 7 may also be adapted to control the power supply, in particular the least one switch of an actively clocked PFC circuit (in 2 Not shown). It can, for example, the power supply as AC / DC converter and the DC / DC converter 5 be integrated in a transducer unit, for example, as an isolated flyback converter, Buck converter, buck-boost converter, boost converter, SEPIC converter, or other actively clocked switching regulator topology 2 Not shown).

For providing the DC output voltage V _BUS , the control _circuit controls 7 the DC / DC converter 5 on the basis of a voltage setpoint V _REF and preferably the actual value of the DC output voltage, which by means of a control loop of the control circuit 7 is supplied. For a data transmission controls the control circuit 7 the DC / DC converter on the basis of the voltage setpoint V _REF , preferably the actual value of the output voltage and the data to be transmitted so that the DC output voltage V _BUS reproduces the data.

Preferably, the control circuit controls 7 the DC / DC converter 5 during a data transmission such that a voltage representing the data is at the DC output voltage for the supply of the operating device 4 is modulated. Further, the control circuit controls 7 Preferably, the DC / DC converter for data transmission such that the voltage setpoint is changed in accordance with the data to be transmitted.

Preferably, the control circuit controls 7 during a data transfer the DC / DC converter 5 such that the DC output voltage of the DC / DC converter 5 changes according to the data to be transmitted between two voltage levels. Ie. during a data transmission, the DC output voltage of the DC / DC converter preferably changes 5 which on the bus 3 is applied and therefore from the control gear 4 is received between a first voltage level and a second voltage level which is higher than the first voltage level. This corresponds to a digital transmission of data, wherein preferably a voltage level change, such. B. a rising edge from the first voltage level to the second voltage level corresponds to a data bit.

Preferably, the voltage level difference between the first and second voltage levels is between 1% and 5% of the average of the DC output voltage of the DC / DC converter 5 , In other words, the modulation swing is the DC output voltage of the DC / DC converter 5 for data transmission between 1% and 5% of the mean value of the DC output voltage of the DC / DC converter 5 ,

As already mentioned, the control circuit 7 preferably configured to control the discharge circuit such that the discharge circuit an ohmic load at the output of the DC / DC converter 5 provides when the operating device 4 represents a high resistive load, ie, when the operating equipment is only a small current from the bus 3 receives.

When the DC output voltage of the DC / DC converter 5 During a data transmission between two voltage levels corresponding to the data to be transmitted, the output capacitance C _{1 is} charged and discharged. Therefore, the data transfer rate depends on the discharge time of the output capacitance C _{1 of} the DC / DC converter 5 from.

In the event that the operating device 4 a high resistive load at the output of the DC / DC converter 5 represents (high-impedance load condition), the discharge time of the output capacitance C _{1 increases} such that a data transmission with sufficient data rate or data speed can not be guaranteed. The operating device 4 represents a high resistive load when it is turned off or operates the bulbs in a dimming operation because the operating device 4 then no or only a small stream from the bus 3 receives.

Consequently, the control circuit controls 7 the discharge circuit 6 in such a way that, in the case of a high-impedance load state during a data transmission, the discharge circuit 6 provides a resistive load. By providing this additional ohmic load, the discharge time of the output capacitance C _{1 is} reduced, whereby a transfer rate according to the DALI standard can be achieved.

3 shows schematically temporal profiles of the DC output voltage V _{BUS of} the DC / DC converter of a preferred embodiment of a device according to the invention, which is adapted to be configured as a master of a bus system according to the invention.

The above statements regarding the 2 are essentially also for the 3 applicable.

In the 3 four graphs are shown, where graph a) shows data to be transmitted. The graphs b), c) and d) show the corresponding time profile of the voltage applied to the output capacitance C ₁ output voltage V _{BUS of} the actively clocked DC / DC converter 5 for different load conditions at the output of the DC / DC converter 5 during data transmission. In particular, the charging and discharging operation of the output capacitance C _{1 of} the DC / DC converter 5 during transmission of the data shown in graph a).

In detail, the graph b) shows the time profile of the output voltage V _{BUS of} the DC / DC converter 5 when at the output of the DC / DC converter 5 a low-impedance load is applied, ie when the operating device 4 is in normal operation and has a corresponding current from the bus 3 absorbs (low-impedance load condition). The discharge time of the capacitor C ₁ is accordingly sufficiently small or short, so that a transmission of the data by means of the DC output voltage V _{BUS is} possible.

The graph c) shows the time profile of the output voltage V _{BUS of} the DC / DC converter 5 when at the output of the DC / DC converter 5 a high-impedance load is applied, ie when the operating device is switched off or is in a dimming mode, so that no current or only a very small current from the bus 3 through the operating device 4 is recorded (high-impedance load condition). It can be seen in graph c) that due to the high-impedance load state at the output of the DC / DC converter 5 , the discharge time of the output capacitance C ₁ for transmission of the data shown in graph a) is too long. In the case shown in graph c), no resistive load is generated by the discharge circuit 6 provided.

The graph d) shows the time profile of the output voltage V _{BUS of} the DC / DC converter 5 when at the output of the DC / DC converter 5 a high-impedance load is applied and the discharge circuit 6 at the output of the DC / DC converter 5 provides an additional resistive load. Due to this additional ohmic load of the discharge circuit 6 For example, the discharge time of the output capacitance C ₁ during a high-ohmic load state is reduced such that transmission of the data shown in graph a) is possible by the DC voltage.

4 schematically shows a preferred embodiment of a bus system according to the invention for the electrical supply of operating devices for lighting means and a preferred embodiment of a device according to the invention, which is adapted to be set up as the master of such a bus system.

The above statements regarding the 2 and 3 are essentially also for the 4 applicable.

In the 4 shown preferred embodiment corresponds to in 2 shown preferred embodiment, wherein now a preferred embodiment of the discharge circuit 6 is shown.

The discharge circuit 6 includes a resistor R ₁ and a discharge switch S ₁ , which is connected in series with the resistor R ₁ . The resistor R ₁ represents an ohmic load and can be replaced by a resistor circuit with multiple resistors. In other words, the discharge circuit includes 6 a resistor circuit having at least one resistor and a discharge switch connected in series with the resistor circuit.

The control circuit 7 is configured to switch in parallel by controlling the switch S _1, the resistance R _{1 of} the output capacitance C ₁ to the output of the DC / DC converter 5 to provide an additional ohmic load R ₁ to the ohmic load R _load . The resistive load R _load corresponds to that through the bus 3 connected slaves (operating devices 4 ) at the output of the DC / DC converter 5 provided ohmic load.

When the discharge switch S ₁ is turned on, then the discharge circuit 6 the resistive load R ₁ ready at the output of the DC / DC converter. If the discharge switch S _{1 is} not turned on, then sets the discharge circuit 6 no ohmic load at the output of the DC / DC converter ready.

According to the 4 is connected via a voltage divider, which is parallel to the output capacitance C _{1 of} the DC / DC converter 5 is arranged, the output voltage V _BUS detected or determined. For this purpose, however, any other known to the expert device for voltage detection can be used.

5 schematically shows a preferred embodiment of a bus system according to the invention for the electrical supply of operating devices for lighting means and a preferred embodiment of a device according to the invention, which is adapted to be set up as the master of such a bus system.

The above statements regarding the 2 to 4 are essentially also for the 5 applicable.

In the 5 shown preferred embodiment corresponds to in 2 and 4 shown preferred embodiment, wherein now a preferred embodiment of a control of the discharge circuit 6 is shown.

As already described above, the control circuit controls 7 the discharge circuit 6 , in particular the discharge switch S ₁ , for a data transmission preferably such that in the case of a high-impedance load state of the discharge switch S _{1 is turned on} during the time range of a falling edge of the DC output voltage. In other words, the control circuit controls 7 the discharge circuit 6 during a data transmission preferably such that in the case of a high-impedance load state, the discharge circuit 6 only during the time periods of the falling edges of the DC output voltage, an ohmic load R ₁ at the output of the DC / DC converter 5 wherein the DC output voltage preferably changes according to the data between two voltage levels.

For such control of the discharge circuit 6 in the case of a high-impedance load state, the control circuit comprises 7 For example, a comparator and a bistable flip-flop or flip-flop. The control circuit 7 may be arranged in any other manner known to those skilled in the art for such control. Ie. the comparator and the bistable flip-flop is merely an exemplary description of the control of the discharge circuit 6 through the control circuit 7 during a data transmission in the case of a high-impedance state.

In the in 5 The box shown is an example of a transmitted data bit. At the beginning of the time range of a falling edge of the DC output voltage V _BUS is the discharge switch S ₁ by the control circuit 7 switched on. If the DC output voltage has fallen below a reference voltage V ₁ (which represents an end of the time range of the falling edge), the switch S _{1 is} not turned on.

Claims (16)

Contraption ( 2 ), which is set up in a bus system ( 1 ), which has at least one operating device ( 4 ) for bulbs and a bus ( 3 ) to be established as a master; a) the device ( 2 ) an actively clocked DC / DC converter ( 5 ) and a discharge circuit ( 6 ) connected to the output of the DC / DC converter ( 5 ); b) the device ( 2 ) is adapted to the at least one operating device ( 4 ) for lamps such that the output of the DC / DC converter ( 5 ) over the bus ( 3 ) with the at least one operating device ( 4 ) is connected for lighting; c) wherein the DC / DC converter ( 5 ) is adapted to provide a DC output voltage (V _BUS ) at its output for electrical supply to the at least one operating device ( 4 ) for illuminants; d) wherein the DC / DC converter ( 5 ) is adapted to receive data over the bus ( 3 ) to the at least one operating device ( 4 ) to transmit; and e) the discharge circuit ( 6 ) is adapted during a data transmission from the DC / DC converter ( 5 ) over the bus ( 3 ) to the at least one operating device ( 4 ) an ohmic load at the output of the DC / DC converter ( 5 ). Contraption ( 2 ) according to claim 1, - wherein the output of the DC / DC converter ( 5 ) comprises an output capacitance (C ₁ ) at which the DC output voltage for the electrical supply of the at least one operating device ( 4 ) is present; and - wherein the discharge circuit ( 6 ) is connected in parallel with the output capacitance (C ₁ ). Contraption ( 2 ) according to claim 1 or 2, wherein the device ( 2 ) a control circuit ( 7 ), which is adapted to determine a high-impedance load state, in which the at least one operating device ( 4 ) represents a high resistive load. Contraption ( 2 ) according to claim 3, wherein the at least one operating device ( 4 ) represents a high ohmic load for lamps, if the at least one operating device ( 4 ) is switched off or is in a dimming operation of the bulbs. Contraption ( 2 ) according to claim 3 or 4, wherein the control circuit ( 7 ) is adapted to the high-impedance load condition on the basis of the at least one operating device ( 4 ). Contraption ( 2 ) according to one of claims 3 to 5, wherein the control circuit ( 7 ) is adapted to the discharge circuit ( 6 ) such that during the data transmission the discharge circuit ( 6 ) at the output of the DC / DC converter ( 5 ) provides an ohmic load when the control circuit ( 7 ) determines a presence of the high-impedance load condition. Contraption ( 2 ) according to one of claims 3 to 6, - wherein the discharge circuit ( 6 ) comprises a resistor circuit having at least one resistor (R ₁ ) and a discharge switch (S ₁ ) connected in series with the resistor circuit, and - wherein the control circuit ( 7 ) is arranged to control the discharge switch (S ₁ ) such that the discharge switch (S ₁ ) is conductive when the control circuit ( 7 ) determines during the data transmission, a presence of the high-impedance load condition. Contraption ( 2 ) according to one of claims 3 to 7, - wherein the control circuit ( 7 ) is adapted to the DC / DC converter ( 5 ) in such a way on the basis of a voltage _setpoint (V _REF ) that the DC output voltage (V _BUS ) of the DC / DC converter ( 5 ) corresponds to the voltage _setpoint (V _REF ); and - wherein the control circuit ( 7 ) is adapted to the DC / DC converter ( 5 ) for transmission of data such that a modulation voltage corresponding to the data of the DC output voltage (V _BUS ) of the DC / DC converter is modulated. Contraption ( 2 ) according to claim 8, - wherein the device ( 2 ) comprises a control loop, which the control circuit ( 7 ) the DC output voltage V _{BUS of} the DC / DC converter ( 5 ) as a controlled variable; and - wherein the control circuit ( 7 ) is adapted to the DC / DC converter ( 5 ) based on the voltage _setpoint (V _REF ) and the controlled variable (V _BUS ). Contraption ( 2 ) according to one of claims 3 to 9, wherein the control circuit ( 7 ) is _adapted to change the voltage _setpoint (V _REF ) according to the data preferably in a leap-like manner for a transmission of data. Contraption ( 2 ) according to one of claims 3 to 10, wherein the control circuit ( 7 ) is arranged to change the voltage _setpoint (V _REF ) according to the data in such a way that the DC output voltage (V _BUS ) of the DC / DC converter ( 5 ) according to the data between a first voltage level and a second voltage level higher than the first voltage level. Contraption ( 2 ) according to claim 11, wherein the voltage difference between the first and second voltage level between 1% and 5% of the average value of the DC output voltage (V _BUS ) of the DC / DC converter corresponds. Contraption ( 2 ) according to claim 11 or 12, - wherein a transition from the second to the first voltage level corresponds to a falling edge; and - wherein the control circuit ( 7 ) is adapted to the discharge circuit ( 6 ) such that the discharge circuit ( 6 ) during the time period of the falling edge at the output of the DC / DC converter ( 5 ) provides an ohmic load. Contraption ( 2 ) according to claim 11 or 12, - wherein a transition from the second to the first voltage level corresponds to a falling edge; and - wherein the control circuit ( 7 ) is adapted to the discharge circuit ( 6 ) in such a way that the discharge switch (S ₁ ) is turned on during the time range of the falling edge. Bus system ( 1 ), with - a device set up as master ( 2 ) according to one of the preceding claims, - at least one operating device configured as a slave ( 4 ) for bulbs, and - a bus ( 3 ); - wherein the device ( 2 ) over the bus ( 3 ) with the at least one operating device ( 4 ) is connected to bulbs. Method for operating a device ( 2 ) according to one of claims 1 to 13, with the following process steps: a) providing the device ( 2 ) according to one of claims 1 to 13, b) connecting the device ( 2 ) with the at least one operating device ( 4 ) for illuminants such that the output of the DC / DC converter ( 5 ) over the bus ( 3 ) with the at least one operating device ( 4 ) is connected for lighting; c) providing a DC output voltage (V _BUS ) by the DC / DC converter ( 5 ) at its output for an electrical supply of the at least one operating device ( 4 ) for bulbs; d) transmission of data by the DC / DC converter ( 5 ) over the bus ( 3 ) to the at least one operating device ( 4 ); and e) providing an ohmic load at the output of the DC / DC converter ( 5 ) by the discharge circuit ( 6 ) during data transmission from the DC / DC converter ( 5 ) over the bus ( 3 ) to the at least one operating device ( 4 ).

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