EP1978787A1 - Interface for lamp operating devices with low standby losses - Google Patents

Abstract

The device has at least one input connection (1,2) for connecting bus lines or for connection to a button and/or switch, evaluation logic (3) for processing signals applied to the input connection and for generating output signals for controlling the lamp operating unit and at least one electrical isolation element (4) for decoupling the input connection from the operating unit. The logic is arranged on the side of the isolation element towards the at least one input element. Independent claims are also included for the following: (A) a lamp operating unit (B) and a method of controlling a lamp operating unit via an interface.

Description

The present invention relates generally to interfaces for lamp operating devices, such as electronic ballasts for gas discharge lamps. The invention further relates to lamp operating devices with such interfaces and to methods for controlling a lamp operating device by means of an interface.

By means of such interfaces it becomes possible to transmit signals from a bus or a switch or switch connected to the mains voltage to a lamp operating device. In this case, an evaluation logic is usually provided in the interface, which converts the present at the inputs of the interface digital or analog signals into control signals for the lamp operating device. The signals supplied to the interface can reproduce commands (setpoints for manipulated variables, etc.) as well as status information. In particular, when a bidirectional interface is provided, state information may be transmitted from the lamp operating device to a bus connected to the interface.

Such interfaces are used for example in connection with the so-called DALI (D igital A dress able L ightening I nterface) over industry.

From the DE 197 57 295 A1 is (see there Fig. 7 ) discloses an example of an interface to which signals from a push button / switch or digital signals from a bus can be selectively applied. In the case of a connected button then a connected electronic ballast can be switched on or off, for example, by pressing a button. Furthermore, a setpoint for a brightness control can be achieved by a corresponding time duration of the push-button operation, since the connected evaluation logic of the interface converts the duration of the push-button operation into a setpoint signal for the electronic ballast (ECG).

As in FIG. 6 is shown schematically between the input-side terminals 1,2 of such an interface 12 and the operating device 13 for one or more lamps 14, a galvanic isolating element 4, such as an optocoupler provided. The digital signals supplied, for example, from a bus are transmitted via this galvanic separating element 4 to the evaluation logic 3, which is thus located behind the galvanic separating element 4 as seen from the bus. On the other hand, since the evaluation logic 3 must respond to incoming signals from the terminals of the interface 12 out immediately, there is the problem in the prior art that the lamp operating device can never be turned off completely, otherwise the evaluation logic would be switched off with. The evaluation logic must therefore be constantly supplied with mains voltage 15, which is reflected in corresponding standby losses (power that drops in standby mode).

FIG. 7 schematically shows how the power / voltage supply 27 for the evaluation logic 3 in the ballast 13 by means of an AC / DC converter 16 to the mains voltage supply 15 of the ballast 13th recourse. Furthermore, in the ballast 13 is still schematically the inverter 17, the output driver for the lamp (s) 4 and the bidirectionally communicating with the evaluation logic 3 lamp control / regulation 19 can be seen.

Standby losses are at odds with the enormous efforts that have been made lately in energy saving in the lamp industry. As an example, be it the WO 02/082618 A1 which shows a way to reduce standby losses in a DALI interface. According to this prior art, a DALI processor is placed in a standby mode when no signals are transmitted on the connected DALI bus. Otherwise shows Fig. 3 of the WO 02/082618 A1 an example of the generally prevailing trend that the Auswertelogik seen from the DALI bus behind the galvanic separating element (insulation 310 in Fig. 3 ) must be arranged.

From the US 6,388,399 a control system for controlling a plurality of distributed arranged consumer is known, are provided in the control units, which are provided for controlling consumers assigned to them. The possibility of brightness control of lamps is opened up by the control units respectively generating a control signal corresponding to the desired brightness between 0 and 10 volts, which is then converted by a lamp operating device connected downstream of the control unit for operating a lamp. However, the configuration of the required for converting the control signal 0-10 volt interface is not described in detail.

The present invention now has the object to reduce the standby losses in an interface for a lamp operating device.

This object is solved by the features of the independent claims. The dependent claims further form the central idea of the invention in a particularly advantageous manner.

According to a first aspect of the invention, therefore, an interface for a lamp operating device is provided which has at least one input-side connection for a bus line or for connection to a pushbutton or switch. Furthermore, an evaluation logic is provided for processing signals applied to the input-side connection and for generating output-side signals for controlling the lamp operating device. A galvanic isolating element galvanically decouples the at least one input-side connection from the output of the interface to which a lamp operating device can be connected. According to this aspect of the invention, the evaluation logic is arranged on that side of the galvanic separation element which faces the input-side connection. In other words, as seen from a connected bus from now is now the evaluation logic in front of the galvanic separation element. This has quite generally the advantage that the evaluation logic can be designed independently of the (arranged behind the galvanic separating element) lamp operating device, so that for example the lamp operating device can be switched off partially or completely and the evaluation logic can still be put into a mode, enabling immediate processing of incoming signals on the bus.

The evaluation logic can accordingly be designed to switch off a connected lamp operating device at least partially (eg only the inverter). The fact that the lamp operating device can now be at least partially switched off (and still guaranteed is that incoming signals from the bus line can be evaluated immediately without the first incoming signals are not recognized) standby losses can be reduced in the lamp operating device.

In particular, the evaluation logic can be designed to transmit commands to the connected lamp operating device by means of the galvanic separating element, by means of which commands the lamp operating device can be separated from the mains voltage. The lamp operating device may be separable from the mains, for example, by means of a relay or an optocoupler-controlled triac.

The evaluation logic can be designed to transmit control values to the connected lamp operating device by means of the same and / or by means of a separate galvanic separating element. In other words, if the possibility of complete mains disconnection for the lamp operating device is provided, the corresponding commands for this function via the same galvanic isolation or via a separate galvanic separator, such as the manipulated variable commands (for example, set values for a lamp brightness control) can be transmitted.

Moreover, the galvanic isolating element can be designed to transmit in bidirectional manner also signals from a connected lamp operating device to the input-side terminals and optionally a bus connected thereto. Such signals are, for example, status information from the connected lamp operating device, which can represent actual values or even errors.

In the idle state in which no signals are transmitted, for example, according to the DALI standard, a high-level signal is applied to the input-side terminals. According to the invention, this high-level signal is used to supply power to the evaluation logic. This would be obviously not possible if, as in the prior art, the Auswertelogik considered from the bus behind the galvanic separation element.

Meanwhile, the invention can also be applied to systems in which a low-level signal is applied to the input-side terminals in the idle state (in which no signals are thus transmitted via the bus). In this case, the evaluation logic is activated so quickly when changing the bus to a high level signal that certainly the first bits of the incoming digital signal can be detected.

According to a further aspect of the present invention, an interface for a lamp operating device, such as an ECG for a gas discharge lamp is provided which has an evaluation logic, which is supplied by at least one input-side signal terminal of the interface with voltage. This connection thus has a double function.

According to a further aspect of the invention, a lamp operating device is provided with such an interface.

Finally, the invention also proposes a method for controlling a lamp operating device by means of an interface, in which, for example, via a bus incoming signals first processed, for example, by a Auswertelogik and converted into control signals for a lamp operating device before being transmitted by means of a galvanic separating element to the lamp operating device become. The conversion of the incoming signals is thus carried out before the transfer of the converted control commands via the Galvanic separator.

Fig. 1

zeigt dabei eine schematische Ansicht einer erfindungsgemäßen Schnittstelle für ein Lampenbetriebsgerät,

Fig. 2

zeigt einen Ausschnitt von Fig. 1, nämlich die Schnittstellenschaltung mit Auswertelogik sowie die galvanische Kopplung für den Fall einer unidirektionalen Schnittstelle,

Fig. 3

zeigt einen Ausschnitt vergleichbar zu Fig. 2, aber für eine bidirektionale Schnittstelle,

Fig. 4

zeigt einen Ausschnitt von Fig. 1, nämlich die galvanische Kopplung sowie schematisch die Vorschaltgerät-Elektronik für ein Ausführungsbeispiel der Erfindung, bei dem die Vorschaltgerät-Elektronik lediglich vom Netz getrennt werden kann,

Fig. 5

zeigt eine Darstellung vergleichbar zu Fig. 4, allerdings für ein Ausführungsbeispiel, bei dem über eine zusätzliche galvanische Kopplung einerseits Stellwerte für eine Lampensteuerung/-regelung und andererseits Rückmeldungen von der Vorschaltgerät-Elektronik übertragen werden können, und

Fig. 6

und Fig. 7 zeigen Schnittstellen, von denen die vorliegende Erfindung ausgeht.

Further features, advantages and features of the present invention will become apparent from the following detailed description of an embodiment and with reference to the figures of the accompanying drawings.

Fig. 1

shows a schematic view of an inventive interface for a lamp operating device,

Fig. 2

shows a section of Fig. 1 namely, the interface circuit with evaluation logic and the galvanic coupling in the case of a unidirectional interface,

Fig. 3

shows a section comparable to Fig. 2 but for a bidirectional interface,

Fig. 4

shows a section of Fig. 1 namely, the galvanic coupling and schematically the ballast electronics for an embodiment of the invention in which the ballast electronics can only be disconnected from the mains,

Fig. 5

shows a representation comparable to Fig. 4 However, for an embodiment in which via an additional galvanic coupling on the one hand control values for a lamp control / regulation and on the other hand feedback from the ballast electronics can be transmitted, and

Fig. 6

and Fig. 7 show interfaces from which the present invention proceeds.

As in Fig. 1 schematically illustrated, control signals are applied to at least one input-side terminal 1, 2 of an interface circuit 12 according to the invention.

Although in the exemplary embodiments two connections 1, 2 for a bus line pair or a button / switch are shown, it should be emphasized that the present invention can also be applied to the interface for connecting a single signal line.

The control signals can be, for example, digital signals (for example according to the DALI standard) or signals from a pushbutton / switch. In the interface circuit 12, an evaluation logic 3 is provided which converts the control signals supplied to the input-side terminals 1, 2 into control signals for a ballast electronics 13. These already converted control signals are transmitted from the evaluation logic 3 via a galvanic coupling, for example. An optocoupler 4 or a transformer to the ballast electronics 13 out, the ballast electronics 13 then in turn one or more lamps 14 accordingly controls. The ballast electronics 13 is supplied in a known manner with mains voltage 15.

In contrast, according to this embodiment, the evaluation logic 3 is not supplied by means of the mains voltage supply 15 of the operating device (ballast here), but via the input-side terminals 1, 2 (for example, bus lines) with energy. The evaluation logic 3 is therefore independent of the power supply of the operating device with respect to their power supply.

The evaluation logic 3 according to the invention is thus part of the interface 3 and no longer part of the operating device 13 as in the prior art.

The evaluation logic 3 may, for example, be designed as an ASIC, microcontroller or DSP.

In this case, on the one hand the case is possible that in the idle state of the bus (for example, the DALI standard), in which no signals are transmitted via the bus, to the input-side terminals 1, 2, a high-level signal is present (for example, +10 v), the thus forms a power supply for the evaluation logic 3.

If no voltage at the input-side terminals 1, 2 is present in the idle state of the bus, the evaluation logic 3 is designed so that it is activated only when a change of the bus line to a high level signal by this voltage (wake-up), which Activation is sufficiently fast to ensure a secure detection of the first bit of the incoming digital signal.

Fig. 2 shows in a detailed view, the interface circuit 12 with the evaluation logic 3 and the galvanic coupling 4. The ballast electronics 13, however, is in this Fig. 2 (as also explained in the following Fig. 3 ) not described further.

As in Fig. 2 it can be seen that the input to the input terminals 1 and 2 incoming control signals are rectified by a diode circuit 8.

In the DALI standard, a high-level signal is known to be applied to the input-side terminals 1, 2 of the interface circuit 12 at rest, so that this high-level signal is used by means of a constant current source 5 (impressed current) and a diode 7 as the power supply 8 for the evaluation logic 3 can be.

Moreover, the evaluation logic 3 detects by means of a voltage divider to the input-side terminals 1, 2 applied control signals (in the DALI standard, for example, the edges of the digital signals), it implements according to a logic implemented in the evaluation logic 3 in control signals and supplies these output control signals 23 to the galvanic separator 4, which according to the embodiment of FIGS. 2 and 3 is designed as an optocoupler. However, other galvanic separating elements, such as transformers, etc., are conceivable.

The embodiment of Fig. 3 differs from the according to Fig. 2 in that the interface 12 is formed overall as a bidirectional interface. That is, in the galvanic isolation element 4, a first branch 10 for transmitting signals or commands to a connected operating device and a second branch 9 for retransmission of signals or commands from a connected operating device to the terminals 1, 2 are provided. In addition to the according to Fig. 2 In this case, the evaluation logic 3 is also supplied with input signals 25 from the galvanic isolating element 4, the evaluation logic 3 now converting these signals 25 into, for example, digital bus signals 24 and driving a bus driver 11 with these output signals. The output signals from the bus driver 11 can then be transmitted by means of the terminals 1, 2, for example, to a connected bus line.

It should be noted that according to the embodiments of FIGS. 2 and 3 the evaluation logic 3 of the input-side terminals 1, 2 of the interface 12 seen from arranged in front of the galvanic separation element 4 and thus is a genuine part of the interface 12. Furthermore, it should be noted that the evaluation logic 3 is not based on the mains voltage supply 15 of the operating device 13, but starting from the signal input terminals 1, 2 of the interface 12 is supplied with voltage.

Referring to 4 and 5 The galvanic coupling 4 and the relevant sections of the ballast electronics 13 will now be explained in more detail. On the other hand, the interface 12 with the evaluation logic 3 connected to the galvanic coupling 4 is also in 4 and 5 not shown.

As in Fig. 4 it can be seen, the galvanic coupling 4 may be formed as optocoupler-controlled triac, which can separate the entire ballast electronics 13 from the mains voltage 15 depending on the control by the evaluation logic 3. In this case fall in the ballast 13 in standby mode no more losses.

Of course, it can also be provided that in standby mode only parts of the ballast 13 (eg the inverter) are switched off.

The ballast electronics 13 is in 4 and 5 is shown only schematically and includes in particular an AC / DC converter 16, a DC / HF inverter 17 (for example, a half-bridge circuit), an output driver circuit 18 and a lamp control 19, for example, the lamp parameters (current, voltage, etc.) detects and Depending on this detection according to a control algorithm, the setpoint for the high frequency and / or the DC bus voltage (DC link voltage) 26 pretends and, for example, the switching frequency of the inverter 17 sets accordingly.

The embodiment according to Fig. 5 is opposite to that of Fig. 4 extended to the effect that the evaluation logic 3 (known in 4 and 5 not shown) not only controls a galvanic isolating element 4 for switching on / off the mains voltage 15 for the ballast electronics 13, but also about the same or as in Fig. 5 shown, a separate galvanic separating element 20 control values (for example, set values) for the lamp control 19 and other signals transmitted.

In addition or alternatively, the galvanic isolating element 20 (in the exemplary embodiment, an optocoupler) may be designed to be bidirectional and, in addition to the first transmission branch 22 for the manipulated variables, also have a feedback branch 21 for status information and / or error messages from the lamp control 19 or others To transfer components of the ballast electronics 13 via the branch 21 of the galvanic isolator 20 to the evaluation logic 3, so that these corresponding digital signals (24 in accordance with Fig. 3 ) can output at the terminals 1, 2 of the interface 12.

Claims (14)

Interface for a lamp operating device (13), comprising - At least one input-side terminal (1, 2) for connecting bus lines or for connection to a button or switch, and - An evaluation logic (3) for processing of the input-side terminal (1, 2) applied signals and for generating output-side signals for controlling the lamp operating device (3), and at least one galvanic isolating element (4) in order to decouple the input-side connection (1, 2) galvanically from the lamp operating device (13), characterized,
that in the idle state, in which no signals are transmitted, a high-level signal is present at the input-side terminals, which supplies the evaluation logic (3) with energy. Interface according to claim 1,
characterized,
that in idle state in which no signals are transmitted to the input-side terminals a low level signal is applied and the evaluation logic unit (3) by a switch to a high-level signal can be activated is. Interface according to claim 1 or 2,
characterized,
in that the evaluation logic (3) is designed to at least partially switch off a connected lamp operating device (13). Interface according to claim 3,
characterized,
in that the lamp operating device (13) can be disconnected from the mains by means of a relay or an optocoupler-controlled triac. Interface according to one of the preceding claims,
characterized,
in that the evaluation logic (13) is designed to transmit control values to the connected lamp operating device (13) by means of the same and / or by means of a separate galvanic isolating element (4). Interface according to one of the preceding claims,
characterized,
in that the galvanic isolating element (4) is designed to also transmit in a bidirectional manner signals from a connected lamp operating device (13) to the input-side terminals and possibly to a bus connected thereto. Interface according to one of the preceding claims, wherein the transmitter is designed as ASIC, microprocessor or DSP. Interface according to one of the preceding claims, wherein the transmitter is specified for the DALI standard. Lamp operating device, in particular ballast for a fluorescent tube, comprising an interface (12) according to one of the preceding claims. Method for controlling a lamp operating device via an interface (12), comprising the following steps: Applying bus signals or push-button / switch signals to at least one input-side connection (1, 2) of the interface (12), Processing of signals applied to the input-side terminal and generation of output-side signals for controlling the lamp operating device (13) by evaluation electronics, wherein in the idle state, in which no signals are transmitted to the input-side terminals (1, 2), a high-level signal is present, which supplies the evaluation logic (3) with energy, or
wherein in the idle state, in which no signals are transmitted to the input side terminals (1, 2) is present a low level signal and the evaluation logic (3) activated by a change to a high level signal becomes. Method according to claim 10,
characterized,
that by means of a galvanic isolating element (4) signals or commands are transmitted to the connected lamp operating device (13), by which this is separated from the mains voltage (15). Method according to claim 11,
characterized,
that the lamp operating device (13) by means of a relay or an optocoupler controlled triac is disconnected from the network. Method according to one of claims 11 or 12,
characterized,
that control values are transmitted to the connected lamp operating device (13) by means of the galvanic isolating element (4). Method according to one of claims 11 to 13,
characterized,
in that signals are transmitted from a connected lamp operating device (13) to the input-side terminals (1, 2) and possibly to a bus connected thereto.

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