EP4358650A1 - Lighting device - Google Patents

Abstract

The lighting device (2) according to the invention comprises a circuit board (4) with at least two light segments (6), each of which has at least one LED unit (8) comprising at least one LED (10, 12) for generating light. The lighting device also comprises a controller (14) which is designed to generate different control signals (30) for controlling the LED units (8) of the light segments (6). The control signals (30) allow the LED units (8) of different light segments (6) to be switched on and/or off at different times by means of the controller (14) and to change the color temperature and/or the brightness of the light generated. The lighting device also comprises a two-wire transmission line (16), at least one filter device (18) and at least one microprocessor (20). These components are designed such that, during operation, the transmission line (16) transmits a voltage curve, which is a direct voltage (28) superimposed on at least one of the control signals (30) of the controller (14), to the filter device (18), the filter device separates the control signal (30) from the direct voltage (26) and transmits at least the direct voltage (26) to at least one of the LED units (8) and the separated control signal (30) to the microprocessor (20), which controls the LED unit (8) depending on the control signal (30).

Description

The invention relates to a lighting device. The lighting device has several LEDs whose color temperature and/or brightness can be changed by means of a controller. Such a lighting device is known in particular as an LED strip. The object of the invention is to expand the range of functions of the lighting device while requiring minimal installation space and being as easy to handle as possible.

According to the invention, the object is achieved by a lighting device which comprises a controller, a two-wire transmission line, at least one filter device, at least one microprocessor and a circuit board. The circuit board has at least two light segments, each of which comprises at least one LED unit for generating light. Each LED unit comprises at least one LED. The controller is designed to generate different control signals for controlling the LED units of the light segments. The control signals allow the LED units of different light segments to be switched on and/or off at different times using the controller. In addition, the color temperature and/or brightness of the light generated can be changed by the control signals using the controller. The transmission line, the filter device and the microprocessor are designed in such a way that the transmission line has a voltage curve during operation, which is a direct voltage superimposed with at least one of the control signals of the controller, to the filter device, the filter device separates the control signal from the direct voltage and transmits at least the direct voltage to at least one of the LED units and the separated control signal to the microprocessor, which controls the LED unit in dependence on the control signal.

The circuit board is in particular a rigid or flexible circuit board. The term "LED" refers to a light-emitting diode. This is a semiconductor component that is designed to emit light. The light-emitting diode usually comprises a semiconductor material and an electrical resistor. Usually, each light-emitting diode is designed to emit light with a certain color temperature that depends on the semiconductor material.

The LED units are preferably formed exclusively from the LED or LEDs. The LEDs of the lighting device are preferably arranged on/on the circuit board. Each lighting segment comprises one LED unit or several LED units that are controlled in particular uniformly during operation. In the case of several LED units, these are preferably controlled uniformly, in particular by the same microprocessor, and/or the LED units of the same lighting segment are preferably designed identically. Particularly preferably, all LED units are designed identically. The lighting segments preferably have the same number of LED units and are designed completely identically, in particular with regard to their components. Each lighting segment takes up a certain part of the Circuit board. The lighting device preferably has at least three, at least five or at least ten light segments.

The controller is in particular a driver. The controller comprises in particular a processor. The controller is preferably designed to generate the different control signals for controlling all LED units, in particular without controlling them directly. The controller is arranged on/on the circuit board or arranged at a distance from it. The controller is used in particular to encrypt information relating to the possible configurations of the light in the form of control signals. After selecting a specific intended configuration, the controller generates the control signal that is assigned to the configuration. In particular, the controller superimposes a direct voltage, in particular the supply voltage, with the control signal for the voltage curve, which the controller then transmits. After receiving the voltage curve, the filter device removes the superimposition, whereupon the microprocessor decrypts the control signal in order to control the at least one LED unit in accordance with the intended configuration of the light. The filter device enables both the energy supply to the LED unit(s) and the information transmission for controlling them to be achieved via a transmission line with only two wires.

The different control signals differ in their purpose. At least one of the control signals is used to switch the LED units of different light segments. At least one further control signal is used to set/change the color temperature of the light. Alternatively or additionally, another control signal is used to set/change the brightness of the light. In particular, the controller is designed to generate different control signals in such a way that at least three different brightnesses or color temperatures can be set using the control signals. Preferably, the color temperature and/or the brightness of the LED units of all light segments of the lighting device are to be changed uniformly. This means that the light of all LED units of the lighting device always has the same color temperature or brightness during operation.

The controller is preferably designed to generate a control signal by means of which the LED units of different light segments can be automatically switched on and/or off with a time delay. This means that, following the generation and transmission of the control signal to the at least one microprocessor, the time-delayed switching on or off takes place automatically and without further intervention or further instructions from the controller. The time-delayed switching on or off means that first the at least one LED unit of a first of the light segments is switched on or off and, with a time delay, i.e. after a time pause, the at least one LED unit of a second of the light segments is switched on or off, etc. The time offset or the time pause has a length of less than one second in particular, preferably less than a tenth of a second. The time pauses between switching on and off the LED units of more than two light segments in particular have a uniform length. The controller is preferably designed to generate such different control signals that the time pause varies depending on the control signals, whereby it is again uniform within a switching on or off process.

The transmission line has exactly two and no more than two wires, i.e. electrical conductors. The transmission line forms at least part of the connection between the controller and the filter device. The transmission line is used for communication between the controller and the filter device or the microprocessor. In particular, apart from the transmission line, there is no means of communication between the controller and the filter device or the microprocessor.

The voltage curve refers to the temporal progression of the transmitted voltage. The voltage curve can be illustrated in particular as a U-t curve. The voltage curve simultaneously transfers considerable electrical energy for the LEDs and the control signal to the filter device. The superimposed direct voltage is used to transfer the electrical energy.

The direct control of the LED units, i.e. in particular switching on or off, setting or changing the color temperature or brightness, is carried out directly by the at least one microprocessor. The microprocessor is preferably controlled in particular by means of an upstream Transistor/voltage regulator with a direct voltage of five volts. The direct voltage transmitted by the filter device to at least one of the LED units may be lower than the maximum voltage curve received by the filter device. The controller is supplied with electrical energy in particular by a 12 V or 24 V direct voltage. The maximum voltage along the voltage curve is in particular at least substantially 12 V or 24 V. The filter device transmits the direct voltage directly or indirectly to the at least one LED unit.

The above-described components of the lighting device according to the invention can be spatially separated from one another and/or housed individually or partially or completely collected and/or housed together. For example, the filter device and the microprocessor can be included in a filter and control device or unit that performs the filter and control function during operation. "Transmitting" does not have to mean complete transmission to the receiver without passing through intermediate components. The lighting device is in particular an LED strip with a flexible circuit board or a light for installation in furniture that has a rigid circuit board. The design of the lighting device according to the invention makes it possible to achieve a wide range of functions with only a small installation space requirement for the lighting device and in particular to achieve continuous switching on and off of the individual light sources in terms of time.

Preferably, the at least one LED unit of each of the light segments comprises at least, in particular exactly, two LEDs. These are a first LED and a second LED. In particular, the first LED and the second LED are each designed to generate white light. Particularly preferably, each LED unit comprises an even number of LEDs. The first LED and the second LED form an LED pair, of which the LED unit has one or more, in particular 3 to 7.

Preferably, the first LED has a first color temperature and the second LED has a second color temperature that differs from the first color temperature. This makes it particularly easy to vary the color temperature of the LED unit, particularly while maintaining white light. In particular, the first color temperature differs from the second color temperature by at least 1,000 K, preferably by at least 2,000 K, particularly preferably by at least 3,000 K. This makes it possible to vary the color temperature over a particularly wide color temperature range. In particular, the color temperature can be varied from cold white to warm white. In a particularly preferred embodiment, the first LED has a color temperature of 2,700 K and the second LED has a color temperature of 6,500 K. Preferably, the LED units do not comprise any LEDs that differ from the first LED and the second LED in terms of color and/or color temperature.

Preferably, the first LED and the second LED are connected in anti-parallel and/or are controlled by the same microprocessor during operation. The brightness of the LEDs is usually achieved by means of pulse width modulation. Based on the anti-parallel connection of the first and second LEDs, both the brightness and the color temperature can be adjusted using extended pulse width modulation. In accordance with extended pulse width modulation, the microprocessor is designed to control the LED unit using inverted voltages, i.e. voltages with different signs. For example, a control voltage with a positive sign activates the first LED. In the example, a control voltage with a negative sign activates the second LED. If the control voltage is absent, neither of the two LEDs is activated. This means that the time periods for which the two LEDs are activated can be varied as desired, although the two LEDs cannot be activated at the same time. The brightness of the light from the LED unit can be adjusted by varying the time period when the control voltage is absent. The color temperature of the light from the LED unit can be adjusted by varying the ratio of the time period of the control voltage with a positive sign on the one hand and the time period of the control voltage with a negative sign on the other.

Preferably, each of the light segments has at least one microprocessor and/or at least one filter device. Particularly preferably, the transmission line for transmitting the voltage curve to the filter device of each of the light segments is designed. Alternatively, the at least one microprocessor or the at least one filter device is assigned to several light segments as a central microprocessor or central filter device, but is not included in them. Because each light segment has its own microprocessor and/or its own filter device, only the voltage curve needs to be transmitted to each light segment via the two-wire transmission line. The transmission line runs in particular from the controller to all light segments, which are connected in series. This allows the circuit board to be made particularly narrow and a space advantage to be achieved, which also allows the technology according to the invention to be used in particularly small furniture lights. Furthermore, this design allows the length of the circuit board to be flexibly shortened, i.e. cutting off light segments, particularly when the lighting device is designed as an LED strip, without thereby impairing the function of the remaining light segments.

The microprocessors of the different lighting segments are particularly preferably configured differently at least in such a way that they switch on the at least one LED unit of their respective lighting segment with a different time delay even upon receipt of the same control signal used for switching on. The delay is to be understood with reference to the reception and/or generation or transmission of the control signal. This design means that the microprocessors interpret the same control signal differently. This means that a specific switching on sequence of the LED units of the different lighting segments can be achieved by transmitting just one control signal, for example. Alternatively or additionally, the above applies to switching off.

The circuit board preferably extends longitudinally. This means in particular that, apart from its thickness, the circuit board has an extension in a longitudinal direction that is at least five times, particularly preferably at least ten times, as large as its extension transverse to the longitudinal direction. The extension transverse to the longitudinal direction is preferably at most 12 mm, particularly preferably at most 10 mm, 8 mm, 7 mm or 6 mm. The light segments are arranged offset from one another in the longitudinal direction of the circuit board. The light segments are in particular directly adjacent to one another or are preferably uniformly spaced from one another. The light segments are preferably arranged in a single row offset in the longitudinal direction, i.e. there are no light segments offset transverse to the longitudinal direction. The extension of the light segments in the longitudinal direction is in particular at least substantially uniform and/or is in particular at most 75 mm, preferably at most 50 mm, and/or at least 10 mm.

The board preferably extends at least substantially or at least partially in a ring, rectangular, U, L or I shape (i.e. straight). This means that the longitudinal direction may vary along the longitudinal extent of the board. In the case of a ring-shaped board, the longitudinal direction is, for example, the circumferential direction.

The at least one microprocessor or the entirety of the microprocessors is preferably designed to switch on the LED units of the light segments one after the other in the order in which the light segments are arranged along the longitudinal direction, depending on the control signal generated for the time-delayed switching on. This optically creates a continuously/wandering light of the lighting device. Alternatively or additionally, the microprocessor or the entirety is designed to switch off the LED units of the light segments one after the other in response to a control signal generated for the time-delayed switching off, in reverse order to the order in which the light segments are arranged along the longitudinal direction. This means that the same effect can be achieved in the opposite direction when removing the formwork. Depending on the control signal, the order or direction in which the LED units are switched on or the time difference between the switching on of the individual LED units can be varied.

The at least one microprocessor is preferably designed to identify all control signals to be generated by the controller and/or to identify at least three, preferably at least five, particularly preferably at least ten different control signals. In particular, the same selection of control signals is stored in both the at least one microprocessor and the controller, which are to be transmitted between them in encrypted form. The at least one microprocessor and the controller therefore access the same library. The larger the selection of control signals, the more extensive the range of functions of the lighting device can be.

The voltage curve preferably consists exclusively of first sections in which the voltage is constantly at a nominal voltage > 0 V, and of second sections. In the second sections, the Voltage is particularly constant, the size of an intermediate voltage that is lower than the nominal voltage and > 0 V. Alternatively, there is no voltage in the second sections. The voltage thus changes along the voltage curve between the nominal voltage and intermediate voltage or no voltage. The information about the configuration of the light for control is encrypted by the times of the changes and/or the length of the sections.

The at least one filter device is preferably designed such that the direct voltage transmitted to the at least one of the LED units during operation has a smoothed course, in particular one free of second sections, compared to the voltage curve transmitted to the filter device. For this purpose, the filter device preferably comprises a smoothing device. In this context, the term direct voltage is not to be interpreted strictly in the sense of a strictly constant voltage value. The voltage can be variable at least to a small extent, but not change sign. The direct voltage does not vary in terms of time or at least to a lesser extent than the voltage according to the voltage curve. The freedom from second sections is to be understood as meaning that the direct voltage remains permanently > 0 volts.

The lighting device preferably comprises a triggering device which is coupled to the controller in a wired or wireless manner and which is designed to trigger the generation of at least one of the control signals, in particular all of the control signals, by the controller. The triggering device is in particular locally arranged away from the controller. The triggering device particularly preferably comprises a remote control that can be operated by a user and is in particular mobile relative to the controller. The remote control has in particular at least one first button for triggering the generation of a control signal for switching on and/or off at a different time, at least one second button for triggering the generation of a control signal for changing the color temperature and/or at least one further button for triggering the generation of a control signal for changing the brightness. In particular, the remote control has two buttons or a key combination both for triggering the generation of a control signal for changing the color temperature and for triggering the generation of a control signal for changing the brightness. Alternatively, the remote control has a touch screen for triggering. As an alternative to the remote control, the triggering device is preferably a motion detector or other type of sensor. This makes it particularly easy to use the different functions of the lighting device.

The lighting device preferably comprises a ballast for supplying the controller with electrical energy. The ballast is designed in particular to convert alternating voltage from a power grid, in particular with a nominal voltage of 230 volts, to direct voltage, in particular with a nominal voltage of 12 volts or 24 volts. The ballast in particular comprises a plug for connecting the lighting device to the household power grid. This makes the lighting device mobile and easy to use anywhere in the home.

Preferably, the LED units of the light segments are arranged on a front side of the circuit board and the at least one filter device and/or the at least one microprocessor are arranged on a rear side of the circuit board. In the case of a plurality of filter devices and/or microprocessors, these are arranged at least partially, in particular completely (in the sense of all) on the rear side of the circuit board. This allows a further installation space advantage to be achieved.

The invention also includes the method for operating the lighting device described above. Accordingly, the controller generates a control signal for switching the LED units of different light segments on and/or off at different times, for changing the color temperature and/or for changing the brightness of the light generated. The transmission line then transmits the voltage curve, which is a DC voltage superimposed on the control signal of the controller, to the filter device. The filter device separates the control signal from the DC voltage and transmits at least the DC voltage to at least one of the LED units (directly or indirectly). The filter device also transmits the separated control signal to the microprocessor. The LED unit controls the microprocessor depending on the control signal.

Fig. 1

eine schematische Darstellung des Aufbaus einer ersten erfindungsgemäßen Beleuchtungsvorrichtung,

Fig. 2

eine schematische Darstellung des Aufbaus einer zweiten erfindungsgemäßen Beleuchtungsvorrichtung,

Fig. 3

eine Darstellung einer Vorderseite einer Platine einer dritten erfindungsgemäßen Beleuchtungsvorrichtung,

Fig. 4

eine Darstellung einer Rückseite der Platine der dritten erfindungsgemäßen Beleuchtungsvorrichtung.

Further details and advantages of the invention can be found in the schematically illustrated embodiments described below; they show:

Fig.1

a schematic representation of the structure of a first lighting device according to the invention,

Fig.2

a schematic representation of the structure of a second lighting device according to the invention,

Fig.3

a representation of a front side of a circuit board of a third lighting device according to the invention,

Fig.4

a representation of a rear side of the circuit board of the third lighting device according to the invention.

The features of the embodiments according to the invention explained below can also be the subject of the invention individually or in combinations other than those shown or described, but always at least in combination with the features of claim 1. Where appropriate, parts with the same functional effect are provided with identical reference numbers.

The Fig.1 and 2 show different lighting devices 2 according to the invention, the common features of which are described below. The lighting devices 2 each have a circuit board 4 with a plurality of Light segments 6, each of which comprises an LED unit 8 for generating light. Each LED unit 8 in turn comprises 3 pairs of LEDs 10, 12, each pair comprising a first LED 10 and a second LED 12.

The lighting devices 2 each comprise a controller 14, which is designed to generate different control signals 30 for controlling the LED units 8 of the light segments 6. The control signals 30 allow the LED units 8 to be switched on and off at different times, and the color temperature and brightness of the light generated can be changed.

A triggering device 22 is wirelessly connected to the controller 14 and is designed to trigger the generation of the control signals 30 by the controller 14. For this purpose, the triggering device 22 transmits a triggering signal 34 during operation. The controller 14 is supplied with electrical energy in the form of direct current 26 by means of a ballast 24. The controller 14 generates a direct voltage 28 superimposed with the control signal 30. The controller 14 transmits the voltage curve of the direct voltage 28 by means of a Fig.1 and 2 not shown two-wire transmission line 16 to the at least one filter device 18 of the lighting device 2.

The at least one filter device 18 serves to separate the control signal 30 from the DC voltage 26 from the superimposed DC voltage 28. The DC voltage 26 is fed through the at least one filter device 18 to at least one of the LED units 8. The separated control signal 30 is transmitted to the at least one microprocessor 20, which is designed to control at least one of the LED units 8 depending on the control signal 30. For this purpose, the microprocessor 20 transmits a control signal 32 to the at least one LED unit 8.

The embodiments according to the invention according to the Fig.1 and 2 differ in particular with regard to the arrangement of the at least one filter device 18 and the at least one microprocessor 20. The embodiment according to Fig.1 has a filter device 18 and a microprocessor 20, which are arranged on the circuit board 4 and process the superimposed direct voltage 28 for all light segments 6. This means, among other things, that the microprocessor 20 sends the control signal 32 to all LED units 8 of the different light segments 6.

In contrast, the embodiment according to the invention has Fig.2 a filter device 18 and a microprocessor 20 per light segment 6. The filter devices 18 and microprocessors 20 are part of the light segments 6 and process the superimposed direct current 28 solely for the LED unit 8 of the respective light segment 6 in this case. The superimposed direct current 28 must therefore be transmitted by the controller 14 to all light segments 6. For the respective LED units 8, the superimposed direct current 28 or the control signal 30 contained therein is interpreted differently by the microprocessors 20.

The circuit board 4 of the second embodiment of the lighting device 2 according to the invention extends elongated in a longitudinal direction L. The light segments 6 are arranged offset in the longitudinal direction L. The LED units 8 of the light segments 6 are switched on one after the other or vice versa switched off depending on the control signal 30 in the order in which the light segments 6 are arranged along the longitudinal direction L.

The Fig. 3 and 4 show the different sides of a circuit board 4 of a third embodiment. The circuit board 4 extends in an elongated ring shape (cf. longitudinal direction L). A plurality of pairs 40 of a first LED 10 and a second LED 12 are arranged on the front side (only partially labeled), which also form the same LED units 8. Series resistors 42 are assigned to the pairs (again only partially labeled). A microprocessor 20, a voltage regulator 44 for the microprocessor 20, a filter device 18, an input of the transmission line 16 and LED transistors 46 assigned to each of the pairs 40 are arranged on the back side (again only partially labeled).

Claims (15)

Lighting device (2) comprising - a circuit board (4) with at least two light segments (6), each having at least one LED unit (8) comprising at least one LED (10, 12) for generating light, - a controller (14) which is designed to generate different control signals (30) for controlling the LED units (8) of the light segments (6), wherein the control signals (30) by means of the controller (14) allow the LED units (8) of different light segments (6) to be switched on and/or off at different times and the color temperature and/or the brightness of the light generated to be changed, - a two-wire transmission line (16), at least one filter device (18) and at least one microprocessor (20), which are designed such that, during operation, the transmission line (16) transmits a voltage curve which is a direct voltage (28) superimposed on at least one of the control signals (30) of the controller (14) to the filter device (18), the filter device separates the control signal (30) from the direct voltage (26) and transmits at least the direct voltage (26) to at least one of the LED units (8) and the separated control signal (30) to the microprocessor (20), which controls the LED unit (8) depending on the control signal (30). Lighting device according to claim 1, characterized in that the at least one LED unit (8) of each of the light segments (6) has one or more Pairs of a first LED (10) and a second LED (12), wherein in particular the first LED (10) and the second LED (12) are each designed to generate white light. Lighting device according to claim 2, characterized in that the first LED (10) has a first color temperature and a second LED (12) has a second color temperature which deviates from the first color temperature, wherein the first color temperature deviates from the second color temperature in particular by at least 1,000 K, preferably by at least 2,000 K, particularly preferably by at least 3,000 K. Lighting device according to claim 2 or 3, characterized in that the first LED (10) and the second LED (12) are connected in anti-parallel and are controlled by the same microprocessor (20). Lighting device according to one of the preceding claims, characterized in that each of the lighting segments (6) has at least one microprocessor (20) and/or at least one filter device (18) and the transmission line (16) is designed to transmit the voltage curve to the filter device (18) of each of the lighting segments (6). Lighting device according to claim 5, characterized in that the microprocessors (20) of the different lighting segments (6) are at least are configured differently so that they switch on at least one LED unit (8) of the respective light segment (6) with a different time delay upon receipt of the same control signal (30). Lighting device according to one of the preceding claims, characterized in that the circuit board (4) extends elongately and the light segments (6) are arranged offset from one another in a longitudinal direction (L) of the circuit board (4). Lighting device according to claim 7, characterized in that the at least one microprocessor (20) is designed to switch on the LED units (8) of the lighting segments (6) one after the other in the order of the arrangement of the lighting segments (6) along the longitudinal direction (L) depending on the control signal (30) generated for the time-delayed switching on and/or is designed to switch off the LED units (8) of the lighting segments (6) one after the other in the opposite direction to the order of the arrangement of the lighting segments along the longitudinal direction (L) depending on the control signal (30) generated for the time-delayed switching off. Lighting device according to one of the preceding claims, characterized in that the microprocessor (20) is designed to identify all control signals (30) to be generated by the controller (14) and/or to identify at least three, preferably at least five, particularly preferably at least ten different control signals (30). Lighting device according to one of the preceding claims, characterized in that the voltage curve is composed in particular exclusively of first sections in which the voltage constantly has the size of a nominal voltage > 0 V, and of second sections in which the voltage constantly has the size of an intermediate voltage which is lower than the nominal voltage, or in which no voltage is present. Lighting device according to one of the preceding claims, characterized in that the at least one filter device (18) is designed such that the direct voltage (26) transmitted to the at least one of the LED units (8) during operation has a smoothed, in particular gap-free, course compared to the voltage course transmitted to the filter device (18). Lighting device according to one of the preceding claims, characterized by a triggering device (22) which is coupled to the controller (14) in a wired or wireless manner and is designed to trigger the generation of one of the control signals (30) by the controller (14). Lighting device according to claim 12, characterized in that the triggering device (22) comprises a remote control which can be operated by a user and is in particular mobile relative to the controller (14), which remote control has at least one first button for triggering the generation of a control signal (30) for the time-delayed switching on and/or off, at least one second button for triggering the Generation of a control signal (30) for changing the color temperature and/or at least one further button for triggering the generation of a control signal (30) for changing the brightness. Lighting device according to one of the preceding claims, characterized by a ballast (24) which supplies the controller (14) with electrical energy and which is designed to convert alternating current from a power grid, in particular with a nominal voltage of 230 V, to direct current (26), in particular with a nominal voltage of 12 V or 24 V. Lighting device according to one of the preceding claims, characterized in that the LED units (8) of the lighting segments (6) are arranged on a front side of the circuit board (4) and the at least one filter device (18) and/or the at least one microprocessor (20) are/is arranged at least partially, in particular completely, on a rear side of the circuit board (4).

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