AT17913U1 - Lamp control gear with flexibly usable control connection - Google Patents

Abstract

An operating device (31) for lamps has a control connection (32). The operating device (31) is designed to read an ohmic resistance at the control terminal (32) in a first operating phase after switching on the operating device (31), to set at least one first operating parameter of the operating device (31) based on the ohmic resistance, in a second operating phase, after the first operating phase a control signal present at the control connection (32) is read out, and at least one second operating parameter of the operating device (31) is set based on the control signal.

Description

Description

LAMP CONTROL GEAR WITH FLEXIBLE USE CONTROL CONNECTION

The invention relates to an operating device for lamps, in particular an operating device for the targeted control of lamps.

[0002] Conventional operating devices for lamps have a communication interface. They are connected to a DALI bus, for example, via this communication interface. The operation of the illuminant can be controlled via this communication interface. In a very simple application, only a single sensor is connected to the communication interface. The control gear then controls the light source based solely on the sensor value. However, since the communication interface with the sensor is occupied, manual switching of the lamp is no longer possible in this simple application.

[0003] In addition, operating devices can have a further connection, which is only used to be terminated with a resistor, the value of which can be used to set an operating parameter of the operating device, for example a maximum brightness.

A conventional operating device for lighting means is shown, for example, by document DE 20 2016 007 619 U1.

[0005] The object of the invention is to improve an operating device in such a way that it has a high level of operating flexibility with very little hardware outlay.

The invention is achieved according to the invention for the operating device by the features of independent claim 1, for a control module by the features of independent claim 6. In addition, the underlying object is achieved by the method according to independent claim 14. Advantageous further developments are the subject matter of the subclaims which refer back thereto.

[0007] An operating device according to the invention for lighting means has a control connection. The operating device is designed to read an ohmic resistance at the control terminal in a first operating phase after switching on the operating device, to set at least one first operating parameter of the operating device based on the ohmic resistance, in a second operating phase, after the first operating phase, to set an at the Read control terminal applied control signal, and set at least one second operating parameter of the operating device based on the control signal. In this way, it is achieved that both at least one first operating parameter and at least one second operating parameter can be set using only one control connection.

Preferably, the at least one first operating parameter is a maximum current flow through the light source or a maximum degree of dimming of the light source or a maximum brightness of the light source. In this way, the maximum illuminance can be set very easily in sensor mode.

The control signal is preferably a short circuit of the control connection or an amplitude modulated control signal or a frequency modulated control signal or a pulse width modulated control signal. In this way, it is possible to react very flexibly to different communication needs.

The at least one second operating parameter is preferably a current flow of current through the light source or a current degree of dimming of the light source or a current brightness of the light source. In this way, the current illuminance can also be influenced during exemplary sensor operation.

[0011] The control signal is preferably a short circuit of the control connection. The at least one second operating parameter is a current flow of current through the light source or a current degree of dimming of the light source or a current brightness of the light source. The

Operating device is designed to reduce the current flow of current through the light source or the current dimming level of the light source or the current brightness of the light source to zero when a first short circuit is read out within the second operating phase, and when a second short circuit is read out within the second Operating phase to set the second current flow through the lamp or the current dimming level of the lamp or the current brightness of the lamp to an original value before reading the first short circuit. In this way, the light can also be very easily deactivated and reactivated during exemplary sensor operation.

[0012] In addition to the control connection, the operating device preferably has only one DALI interface, but no further control connections.

[0013] The control connection is preferably not a DALI interface.

A control module according to the invention for an operating device for lamps contains a connection for connecting to a control connection of the operating device and a control device. The control device is designed to connect an ohmic resistor to the connection at the top in a first operating phase after switching on the operating device, and to generate a control signal after the first operating phase and to switch it to the connection in a second operating phase. It is thus possible with very little hardware outlay to provide the two different control signals for the control connection of the operating device.

[0015] The control unit is preferably designed to internally simulate the ohmic resistance connected to the connection in the first operating phase. This achieves a very high flexibility of the control.

Alternatively, the control unit is designed to connect an ohmic resistor externally connected to the control unit to the connection in the first operating phase. This means that conventional control resistors can be connected to set the first operating parameter.

The control unit is preferably designed to generate the control signal generated in the second operating phase as a short circuit of the control connection or as an amplitude modulated control signal or as a frequency modulated control signal or as a pulse width modulated control signal. This achieves a very high flexibility of the control.

[0018] The control unit preferably has an input device which is designed to accept a user input at the top. The control unit is then further developed to generate the control signal generated in the second operating phase based on this user input. This enables very simple manual control of the lighting.

The input device is preferably a button or a switch. A particularly simple control is achieved in this way.

A control module system according to the invention includes a previously described control module and an ohmic resistor. This achieves very simple control.

A system according to the invention includes an operating device and a control module as described above or an operating device and a control module system as described above. A particularly simple lighting control is achieved in this way.

A method according to the invention serves to control light sources. It comprises reading out an ohmic resistance at a control connection of an operating device of the lamp in a first operating phase after switching on the operating device, setting at least one first operating parameter of the operating device based on the ohmic resistance, reading out a control signal present at the control connection, in a second operating phase after the first operating phase, and setting at least one second operating parameter of the operating device based on the control signal. In this way it is achieved that by means of only one control connection both at least a first operating parameter

as well as at least one second operating parameter can be set.

The invention is described by way of example with reference to the drawing, in which an advantageous embodiment of the invention is shown.

[0024] The drawing shows: [0025] FIG. 1 a first exemplary operating device for lighting means; [0026] FIG. 2 shows a detail of a second exemplary operating device for lighting means;

3 shows a first exemplary embodiment of the system according to the invention, including a first exemplary embodiment of the operating device according to the invention and a first exemplary embodiment of the control module according to the invention;

4 shows a second exemplary embodiment of the control module according to the invention;

5 shows a detail of a second embodiment of the operating device according to the invention and a detailed construction of a third embodiment of the control module according to the invention;

[0030] FIG. 6 shows an exemplary voltage curve at a control terminal of a third exemplary embodiment of the operating device according to the invention; and

7 shows an exemplary embodiment of the method according to the invention in a flowchart.

[0032] Firstly, the underlying problem is presented using exemplary operating devices with reference to FIG. 1 and FIG. Details of the design and function and signaling of different exemplary embodiments of the invention are then discussed with reference to FIGS. 3-6. Finally, the detailed function of the method according to the invention will be discussed with reference to FIG. Identical elements were sometimes not shown and described repeatedly in similar illustrations.

In Fig. 1, a first exemplary operating device 1 is shown for lamps. The operating device 1 has a control connection 2 to which an ohmic resistor 3 can be connected. An operating parameter of the operating device 1 is set by means of the value of this connected ohmic resistance 3 . In particular, a voltage is applied to the control terminal 2 by the operating device 1 , as a result of which a current is established through the ohmic resistor 3 .

The current or a voltage resulting therefrom is detected by the control unit 1 and used to set the operating parameters. For example, a maximum brightness of the illuminant is set as a result.

In Fig. 2 the detailed construction of a part of the control device 1 of Fig. 1 is shown. It is important to point out that only the wiring of the control connection 2 is shown in detail here. Further components of the operating device 1 are not shown here. In particular, components necessary for the actual operation of the lighting means are not shown.

The operating device 1 has an analog-to-digital converter 3 which is connected to ground via a filter capacitor 4 . An ohmic resistor 5 is connected to the same connection of the analog/digital converter 3 . The opposite connection of the ohmic resistor 5 is connected to a first pole of the control connection 2 . A second pole of the control connection 2 is connected to ground. In addition, another ohmic resistor 6 is connected to the end of the ohmic resistor 5 facing away from the analog/digital converter 3 . A voltage 3V3 is fed in via this further ohmic resistor 6 . An ohmic resistor 3 is connected to the control terminal 2 here.

The voltage 3V3 ensures a current flow through the ohmic resistor 3 to ground. As a result, a voltage is established at the first pole of the control connection 2, which is transmitted via the resistor 5 to the capacitor 4 and charges it. The voltage that is established is measured by the analog-to-digital converter 3 .

The operating device 1 uses this measured voltage to define an operating parameter. For example, the maximum brightness or a maximum current flow or a maximum degree of dimming of the light source is defined as a result.

In particular, if the operating device 1 is only connected to a sensor by means of a further communication interface, e.g. a DALI interface, not shown here, and is thus working in pure sensor mode, the operating device 1 has no further control interface, so that operation by manual intervention is not possible.

3 shows a first embodiment of the system 30 according to the invention, a first embodiment of the operating device 31 according to the invention and a first embodiment of the control module 33 according to the invention.

The system 30 according to the invention includes an operating device 31 which has a control connection 32 . A control module 33 is connected via the control connection 32 . The operating device 31 reads an ohmic resistance at the control connection 32 in a first operating phase after the operating device 31 has been switched on. At least one first operating parameter of the operating device 31 is set by the operating device 31 based on this ohmic resistance that has been read out. In a second operating phase after the first operating phase, the operating device 31 reads a control signal at the control terminal 32 and sets at least one second operating parameter based thereon.

The control module 33 provides both the ohmic resistance during the first operating phase and the control signal during the second operating phase. Details of the function of the control module 33 are discussed with reference to FIGS. 4-6. Further details of the function of the operating device 31 are also discussed in more detail with reference to FIG. 5 .

The first operating parameter is, for example, a maximum brightness or a maximum degree of dimming or a maximum current flow of the lamp operated by the operating device 31 . The second operating parameter is, for example, a current brightness or a current current flow or a current degree of dimming of the lighting means operated by the operating device 31 . However, other operating parameters of the lighting means can also be set as the first and second operating parameters. For example, it is also possible to set a color of the lighting by the light source or to set a flashing frequency. Setting a colored flashing pattern is also conceivable.

4 shows another exemplary embodiment of the control module 33 according to the invention. The control module 33 is connected to the control connection 32 of the operating device 31 . The control module 33 here includes a connection 44 for connection to the control connection 32 of the operating device 31 from Fig. 3. The control module also includes a control unit 41. The control unit 41 is designed to, in a first operating phase after switching on the operating device 31 from Fig. 3 to switch an ohmic resistance to the connection 44 and thus to the control connection 32 of the operating device 31 .

[0045] On the one hand, in a first embodiment, the control unit 41 can simulate the ohmic resistance internally for this purpose. This leads to great flexibility, but requires the ohmic resistance to be defined within the control unit 41. Alternatively, the control unit 41 can have an ohmic resistance 43 connected to the control unit 41, which is shown as an optional component in FIG. 4, during the first operating phase to the connection 44 and thus to the control connection 32 of the operating device 31.

[0046] In addition, the control unit 41 is designed to generate a control signal in a second operating phase after the first operating phase and to switch it to the connection. In the exemplary embodiment shown here, the control signal is a short circuit in connection 44 and thus a short circuit in control connection 32 of operating device 31 . This is symbolized here by a switch 40 connected to control unit 41 . In fact, however, the control signal is also transmitted via the connection 44 of the control device 41 to the control connection 32 of the operating device 31 . The switch 40 shown here is therefore only symbolic as a short circuit of the two poles of the connection 44

to understand.

In addition, a further switch 42, connected to the control unit 41, is shown in this exemplary embodiment. In this case, the switch 42 represents an input device which accepts a user input. In this embodiment, the user input is to close switch 42 . In the simplest possible embodiment, the closing of the switch 42 leads to a short-circuit of the connection 44 by the control unit 41 if the second operating phase has already been reached. During the first phase of operation, the position of switch 42 is ignored by control unit 41 .

Instead of a simple switch 42, however, a button or a more complex input device can also be used. What is relevant is that the control unit 41 generates the control signal based on the user input and transmits it to the control connection 32 of the operating device 31 by means of the connection 44 during the second operating phase.

The operating device 31 receives the control signal during the second operating phase and sets at least one second operating parameter based thereon.

In Fig. 5 a detailed embodiment of an embodiment of the control module 33 as well as a part of the operating device 31 is shown. The representation shown here corresponds to the representation from FIG. Furthermore, an ohmic resistor 53 is connected to the analog/digital converter 50 , the opposite connection of which is connected to the control connection 32 . Also connected to this first pole of the control connection 32 is an ohmic resistor 54, at whose opposite connection a voltage 3V3 from a voltage source 59 is fed.

A connection 44 of the control module 33 is connected to the control connection 32 of the operating device 31 . The control module 33 here includes a switch 55 which is switched between an open circuit and a connection to ground under the control of a control signal from a voltage source 58 . A second switch 56 is also connected to the terminal 44 and switches between an open circuit and a connection to an ohmic resistor 43 connected to ground. In this case, the second switch 56 is switched by a control signal which is generated by a voltage source 57 .

During the first phase of operation, switch 55 is open and switch 56 is closed. The ohmic resistor 43 is thus connected to the control connection 32 of the operating device 31 . Switch 56 is open during the second phase of operation. The switch 55 now generates the control signal by means of a pulsed circuit.

The signal resulting from the analog-to-digital converter 50 from FIG. 5 is shown in FIG. During a first operating phase 60, a largely constant voltage is present, which is established by the current flow through the ohmic resistance. During the second operating phase 61, a pulsed control signal is present, which is achieved by pulsed short-circuiting of the control connection 32. Based on the constant voltage of approx. 2.1 V during the first operating phase, a maximum brightness of the light source is set, for example. A further operating parameter, for example a current brightness of the lighting means, is set by means of the control signal during the second operating phase.

[0054] Finally, an exemplary embodiment of the method according to the invention is shown in a flow chart in FIG. In a first step 70, an ohmic resistance is read out at a control terminal of an operating device of a light source during a first operating phase after the operating device has been switched on. In a second step 71, at least one first operating parameter of the operating device is set based on the ohmic resistance read out. In a third step 72, a control signal present at the control connection is read out in a second operating phase after the first operating phase. In a fourth step 73, at least one second operating parameter of the operating device is now set based on the control signal. Steps 72 and 73 are carried out continuously during the second operating phase, which corresponds to normal operation.

guided. The user can thus change the at least one second operating parameter at any time.

Since the method and the device according to the present invention correspond closely to one another, the corresponding statements on the device can also be applied to the method.

The invention is not limited to the illustrated embodiment. As already mentioned, a wide variety of operating parameters can be set both by the ohmic resistance and by the control signal. All features described above or features shown in the figures can be advantageously combined with one another as desired within the scope of the invention.

Claims (10)

Expectations 1. Operating device (31) for lamps with a control terminal (32), wherein the operating device (31) is designed to - in a first operating phase (60) after switching on the operating device (31), reading an ohmic resistance (43) at the control connection (32), - set at least one first operating parameter of the operating device (31) based on the ohmic resistance (43), - In a second operating phase (61), after the first operating phase (60), a control signal present at the control connection (32) is read out, and - Set at least one second operating parameter of the operating device (31) based on the control signal. 2. Operating device (31) according to claim 1, characterized in that the at least one first operating parameter is a maximum current flow through the lamp or a maximum degree of dimming of the lamp, or a maximum brightness of the lamp. 3. Operating device (31) according to claim 1 or 2, characterized in that the control signal is a short circuit of the control connection (32) or an amplitude modulated control signal or a frequency modulated control signal or a pulse width modulated control signal. 4. Operating device (31) according to one of claims 1 to 3, characterized in that the at least one second operating parameter is a current flow of current through the lamp or a current degree of dimming of the lamp, or a current brightness of the lamp. 5. Operating device (31) according to one of Claims 1 to 4, characterized in that the control signal is a short circuit of the control connection (32), that the at least one second operating parameter is a current flow of current through the light source or a current degree of dimming of the light source, or a current brightness of the light source, and that the operating device (31) is designed to - when reading out a first short circuit within the second operating phase (61), the current current flow through the light source or the current dimming level of the light source or the current brightness of the to reduce the illuminant to zero, and - when reading out a second short circuit within the second operating phase (61), the current flow of current through the illuminant or the current dimming level of the illuminant or the current brightness of the illuminant to an original value before the first short circuit was read out to put. 6. Control module (33) for an operating device (31) for lamps, with a connection (44) for connection to a control connection (32) of the operating device (31), and a control unit, wherein the control unit (41) is designed to - in a first operating phase (60) after switching on the operating device (31), to switch an ohmic resistor (43) to the connection, and - In a second operating phase (61), after the first operating phase (60), to generate a control signal and to switch it to the connection (44). 7. Control module (33) according to claim 6, characterized in that the control unit (41) is designed to internally simulate the ohmic resistance connected to the connection (44) in the first operating phase (60). 8. Control module (33) according to claim 6, characterized in that the control unit (41) is designed to connect an ohmic resistor (43) externally connected to the control unit (41) to the connection (44) in the first operating phase (60). to switch. 9. Control module (33) according to one of Claims 6 to 8, characterized in that the control unit (41) is designed to use the control signal generated in the second operating phase (61) as a short circuit of the connection (44) or as an amplitude-modulated control signal or as a generate a frequency-modulated control signal or a pulse-width modulated control signal. 10. Control module (33) according to any one of claims 6 to 9, characterized in that the control module (33) has an input device (42) which is designed to receive a user input, and that the control unit (41) is designed to generate the control signal generated in the second operational phase (61) based on the user input. 5 sheets of drawings