WO2021156300A1 - Lighting module, lighting system and operating method - Google Patents

Abstract

In one embodiment, the invention relates to a lighting module (1) comprising a ballast (2) and a lighting assembly (3). The ballast (2) contains a control unit (21) for controlling the lighting assembly (3), an interface (22) to the lighting assembly (3), a memory (23) for lighting scenarios and a radio module (24) for receiving information. The lighting assembly (3) has at least one light source (31) for adjustable light generation. The lighting assembly (3) is wired to the ballast (2).

Description

description

LIGHTING MODULE, LIGHTING SYSTEM AND OPERATING PROCEDURES

A lighting module is specified. In addition, a lighting system is specified. An operating method for a lighting system is also specified.

The document WO 2010/088887 A2 relates to a method for operating a lighting system.

A method for localizing light sources is found in the publication US 2012/0105204 A1.

One problem to be solved is to specify a lighting system that can be efficiently controlled.

This object is achieved, inter alia, by a lighting module, by a lighting system and by an operating method with the features of the independent claims. Preferred developments are the subject of the remaining claims.

The lighting system described here preferably comprises several lighting modules that can receive trigger signals from a central system controller. Lighting scenarios that are started by the trigger signals are stored in the individual lighting modules. This means that there is no need for a permanent data connection with high data streams between the lighting modules and the central system control. Furthermore, the lighting scenarios for a large number of locations can be stored in each of the lighting modules. After a position of the relevant lighting module has been determined, in particular by this lighting module itself, the respective lighting modules can play the intended lighting scenarios automatically, in particular triggered by a trigger signal, without the lighting modules having to be addressed manually and / or assigned to a position.

According to at least one embodiment, the lighting modules each include a ballast and one or more lighting arrangements. There is preferably an unambiguous association between the at least one ballast and the at least one lighting arrangement. In particular, each luminaire arrangement is clearly assigned to exactly one ballast.

According to at least one embodiment, the at least one luminaire arrangement of the lighting module comprises one or, preferably, several light sources. The light sources or at least some of the light sources of the luminaire arrangement are set up for adjustable light generation. That is to say, an intensity and / or color of the relevant light sources can be controlled and adjusted. For example, the light sources are formed by RGB light-emitting diode components. RGB stands for red, green and blue. The light sources are preferably controllable by means of DMX, so that the light sources can be DMX lights, but can alternatively also be controllable via DALI, PLC or another, for example own, bus system and / or protocol. According to at least one embodiment, the ballast comprises a control unit. The control unit is set up to control the assigned luminaire arrangement.

The control unit is, for example, a microcontroller or a main control unit, or MCU for short.

According to at least one embodiment, the ballast comprises an interface. The interface is set up for data transmission and optionally for data reception to and optionally from the light-emitting diode arrangement. In particular, control data are transmitted from the control unit to the luminaire arrangement via the interface. It is possible that operating data of the luminaire arrangement can be transmitted to the ballast, in particular to the control unit, via the interface. In addition, it is possible that the interface contains at least one driver circuit for the light sources, for example one or more constant current sources for pulse width modulation, or PWM for short.

If the lighting module comprises several lighting arrangements, the ballast can have its own interface for each lighting arrangement. Alternatively, several of the lighting arrangements can be connected to a common interface.

According to at least one embodiment, the ballast comprises one or more memories. The at least one memory is set up to contain the lighting scenarios. The memory can preferably be overwritten so that new ones are created if necessary Lighting scenarios can be saved and lighting scenarios that are no longer required can be deleted.

According to at least one embodiment, the ballast comprises a radio module. The radio module is set up to receive information, in particular to receive trigger signals for triggering the lighting scenarios. Optionally, the radio module is also set up to send data, for example about an operating state and / or functionality of the luminaire arrangements and / or sensor data such as temperature or brightness.

According to at least one embodiment, the at least one lamp arrangement is connected to the ballast by wire. Wired means that the connection between the luminaire arrangement and the ballast is not a wireless optical or radio connection. The term “cable” thus relates to any electrical connection that is based on a wire or cable and / or that is plug-connected and / or conductor-track-connected.

In at least one embodiment, the lighting module comprises a ballast and at least one lighting arrangement. The ballast contains a control unit for controlling the lighting arrangement, an interface to the lighting arrangement, a memory for lighting scenarios and a radio module for receiving information. The luminaire arrangement has at least one light source for adjustable light generation. The luminaire arrangement is wired to the ballast. With the lighting modules described here, dynamic lighting, in particular alternating white and / or colored light, of a large, extended area can be achieved, with the lighting being able to be controlled synchronously. The extensive area is, for example, a city market, a fairground, a city park, a building complex, a district consisting of several buildings or a skyline.

One difficulty with such extensive lighting arrangements is that conventionally, data cables have to be run from luminaire to luminaire during installation. Depending on the installation location or topology, this can be very time-consuming. If radio-based technology is used for dynamic lighting, for example wireless DMX, the luminaires must be permanently connected to the radio network in order to enable constant data exchange in real time. If this radio link is disturbed, the dynamic lighting scene will also be disturbed.

Thus, the lights are usually installed in a large area and connected to one another with a data cable.

A master system is located at a central point, which calculates the dynamic lighting scene and sends the control signals to the luminaires in real time via the cabling or the radio network.

With the lighting modules described here, on the other hand, it is possible to build a lighting system, the ballasts of the lighting modules being used in particular for a chain of lights, such as DMX lights, DALI lights or lights controlled by means of PWM, which represent the luminaire arrangement. The ballasts can be separate components or can also be integrated in the lighting arrangement.

The ballast preferably consists essentially of a DMX interface, where DMX stands for digital multiplex, of a microcontroller as a control entity, of a sufficiently large memory and of a radio module; all of these components can be accommodated in a common housing of the ballast. The memory contains one or more scenes and lighting moods as a data record. In the case of DMX, for example, this is the complete DMX data stream for the individual scenes that the luminaire is to represent. A dynamic light scene can also be an effect that is calculated on the luminaire itself by the microcontroller.

A start signal or trigger signal with a scene identifier is received in particular via an LPWAN radio module (LPWAN: Low Power Wide Area Network), for example LoRa (Long Range), NB-IoT (Narrow Band Internet of Things) or Bluetooth or WiFi or 5G . Bluetooth (Mesh) or WiFi 6 (IEEE802.llax) are preferred for sending the trigger signals. The microcontroller then plays the dynamic scene from the memory, for example via a DMX bus, or calculates the desired scene and forwards the data in particular via DMX or DALI (DALI: Digital Addressable Lighting Interface). The trigger signal can also contain further information, such as brightness or the playback speed of the scenes to be calculated. A central system sends the trigger signals in real time, preferably via the LPWAN. In principle, this central system can also be integrated into other devices.

A scene can mean, for example, certain switch states of relays or the playback of an audio signal. In this case, the memory of the device contains the switching status of one or more relays or the audio data that are to be reproduced, for example as an MP3 file, for the corresponding scene.

Since a WAN radio system (WAN: Wide Area Network) with a low data rate can be used for the transmission, the trigger signals are preferably received by all ballasts and lighting arrangements at the same time. This leads to a synchronous display of the lighting scenarios. It is not necessary to send a continuous stream of data, as is necessary, for example, with radio-based DMX. A saved scene or scenery can, for example, take several minutes to play. Only then is a new trigger signal sent to start a new scene or scenery, or the scene or scenery starts again from the beginning if no new trigger signal or a stop signal is received. During installation, the lights only have to be connected to the usual existing power supply and are therefore also suitable for temporary or mobile installations, such as at a Christmas market.

According to at least one embodiment, the interface is set up for DMX and / or for DALI. In addition, interfaces for sound reproduction, in particular for controlling loudspeakers, can be provided. According to at least one embodiment, the luminaire arrangement comprises at least five or ten or 50 of the light sources. Alternatively or additionally, the number of light sources is at most 5000 or 500 or 200 or 170. That is to say, the lighting modules can contain a large number of light sources per ballast.

According to at least one embodiment, the light sources of a luminaire arrangement are connected to one another by means of one or more cable connections. This means that there are preferably no radio connections between the light sources within a luminaire arrangement. Alternatively, it is possible that the light sources also communicate with each other in a radio-based manner within a luminaire arrangement, for example via low power Bluetooth.

According to at least one embodiment, the memory is comparatively large. That is, the memory preferably has a size of at least 1 GB or 2 GB or 5 GB. Alternatively or additionally, the memory has a size of at most 32 GB or 16 GB or 8 GB or 4 GB. This makes it possible to store lighting scenarios on a large scale in the ballast and thus in the lighting module. The memory can be written to and read, for example, via the radio interface or via a separate interface suitable for this purpose, such as Bluetooth, WiFi, USB or Ethernet.

According to at least one embodiment, the ballast is integrated in the light-emitting diode arrangement or vice versa. This means, in particular, that the ballast is inseparably connected to the light-emitting diode arrangement, in particular via a device that is not detachable or reversible as intended detachable connection, such as a soldered connection or an adhesive connection.

According to at least one embodiment, the light-emitting diode arrangement and the ballast of the lighting module are separate components. This means that the lighting arrangement and the ballast can be reversibly separable from one another, for example via a plug connection. Alternatively, the lighting arrangement and the ballast can be produced as separate components and subsequently connected to one another, for example, via a cable connection, with a reversible attachment of the ballast to the lighting arrangement not being absolutely necessary.

According to at least one embodiment, the ballast further comprises a locating unit. The locating unit is set up to determine a location of the ballast. Localization takes place, for example, via a system such as GPS, Galileo, Ultra Wide Band, UWB for short, Bluetooth Low Energy, LoRa or WiFi. A position accuracy that can be achieved via the locating unit is preferably 20 m or better or 10 m or better or 5 m or better or 1 m or better. For example, a localization accuracy in the range of 20 cm can be achieved via UWB. Automatic commissioning of the lighting module is possible with such a locating unit.

With conventional arrangements for dynamic lighting control, an individual luminaire has to be assigned an address so that it can be controlled individually by the central control. Is now a dynamic lighting with many lights that operated in a network are displayed, the position of each luminaire and its associated address must be known in advance. When setting up on site, this must be taken into account by an electrician in particular.

Incorrect addressing or an incorrect installation location can lead to an undesired display of a light effect or a lighting scene. So traditionally one has to work very carefully during planning and installation. Manual addressing of the luminaires on site can be difficult and time-consuming due to the installation situation; for example, luminaires may not be accessible or not directly visible.

If such a locating unit is available, the scene memory is preferably designed to be larger. The memory contains not only the data that are required to operate the relevant actual location of the lighting module, but also the entire database or at least part of this database for operating the lights at all possible positions in the entire installation.

In addition, the spatial working area is optionally delimited in the luminaire, for example in the form of minimum / maximum position coordinates.

By using a locating unit that works via satellite signal or LoRa, it is also possible to synchronize the lighting units over time. The trigger signals can also in this case

Include time information, for example, "play scene 3 at midnight". The position determination system in the luminaire can now determine the exact location and link this position with the data set contained in the memory. When a trigger signal is received, for example via LPWAN, exactly the data record valid for this position is played and the relevant lighting scene is displayed.

This simplifies lighting planning and the installation of the lighting modules on site. When planning, the exact position and address of each individual luminaire do not need to be known. Only the topological area in which the luminaires are to be operated needs to be defined. In addition, this area is preferably divided into a grid. Each grid point can stand for a luminaire or a group of luminaires, so that individual scene data for the lighting scenarios should be generated for each grid point. The entire data set for all grid points is loaded into the memory of each lighting module.

On site during assembly, for example at a Christmas market, the lighting module then only needs to be connected to the power grid at the installation position. Thanks to the integrated position determination and the predefined area, the luminaire recognizes the defined grid point at which it is located and can play the desired scene when it receives a corresponding signal. In the foregoing, the lighting module can also be referred to as a light in a synonymously simplified manner.

In addition, a lighting system is specified. The lighting system comprises one or more of the lighting modules, as described in connection with one or more of the above-mentioned embodiments. features the lighting modules are therefore also disclosed for the lighting system and vice versa.

In at least one embodiment, the lighting system comprises a plurality of the lighting modules. In addition, the lighting system comprises one or more system controls, preferably a single central system control. The system controller can be a computer, for example a laptop, which is connected to a radio signal transmitter or which has a radio signal transmitter.

According to at least one embodiment, the system controller is set up to control the ballasts of the lighting modules by means of a radio link. The lighting modules are set up to be operated temporarily without a radio connection to the control system. This is possible due to the lighting scenarios that are stored in the memories of the lighting modules.

According to at least one embodiment, the lighting system has a spatial extent over all lighting modules, lighting arrangements and / or light sources taken together of at least 25 m or 50 m or 100 m or 200 m. Alternatively or additionally, this spatial extent is at most 10 km or 5 km or 2 km. This means that the lighting system is distributed over a comparatively large spatial area.

An operating procedure is also given. The operating method is set up for a lighting system, such as in connection with one or more of the described above embodiments. Features of the lighting system and the lighting modules contained therein are therefore also disclosed for the operating method and vice versa.

In at least one embodiment, the operating method comprises the following steps, for example in the order given:

A) Saving the lighting scenarios on the memories of the ballasts of the lighting modules

Lighting systems,

B) Construction and spatial arrangement of the lighting modules, and

C) Controlling the lighting modules by means of the radio link with the central control system, the radio link only sending data to the lighting modules at times or the radio link only existing temporarily.

That is, when the lighting modules are in operation, preferably no continuous data stream is sent from the central system control to the lighting modules, or vice versa.

According to at least one embodiment, the central control system sends a trigger signal to all lighting modules at the same time, optionally also with other information, in particular which lighting scene is to be played. In this way, the relevant lighting modules can begin with the respective lighting scenarios at the same time, so that coordinated light emission can be achieved across the entire lighting system. According to at least one embodiment, the radio connection pauses between successive trigger signals. This means that when the lighting system is operated as intended, only the comparatively short trigger signals are sent over the radio link and no data on a large scale.

According to at least one embodiment, the lighting modules determine their respective location by means of the associated locating device. In step A), the lighting scenarios for a large number of different locations are stored in the lighting modules, for example for all locations that occur and / or are relevant and / or possible for the lighting modules in the application in question.

According to at least one embodiment, a grid with a plurality of grid areas is specified, for example as part of planning the lighting system. In this case, several of the lighting modules are preferably placed in each grid area in step B). In step A), all lighting scenarios of the associated grid area are stored in the lighting modules, optionally the lighting scenarios of several or all grid areas.

According to at least one embodiment, only a comparatively rough localization of the lighting modules is carried out by means of the locating device. For example, localization only takes place in relation to which object, such as a hut at a Christmas market, the relevant lighting module is attached to. For this localization, only a comparatively low spatial resolution of, for example, 10 m or 5 m is necessary. According to at least one embodiment, a subsequent, more precise placement of the light arrangements takes place on the basis of a predetermined distribution plan, in particular by a fitter. This enables the luminaire arrangements to be positioned precisely even with a comparatively rough localization by the locating device.

According to at least one embodiment, the lighting scenarios each have a duration or playback duration of at least 10 s or 30 s or 1 min or 10 min. Alternatively or additionally, this duration is a maximum of 24 hours or 2 hours or 1 hour or 15 minutes.

According to at least one embodiment, the light sources are at least partially mechanically connected to one another in a flexible manner within the luminaire arrangements, for example via a power cable and data cable. That is, in step B) relative positions of the light sources to one another can be changed as intended. For example, the light sources or at least some of the light sources within the relevant luminaire arrangement are electrically and signal-technically connected to one another via flexible cables. These connections between the light sources are optionally only created in step B). This means that the light sources are then wired to one another and to the ballast in step B).

The light sources can also be operated with a battery and are therefore not necessarily mechanically connected to one another. According to at least one embodiment, the lighting modules each additionally comprise a maintenance interface. The maintenance interface can enable a radio connection or can also be an interface by means of a plug connection, for example a USB interface. The maintenance interfaces are set up to be used for maintenance of the lighting modules. For example, the lighting scenarios can be stored via the maintenance interface, in particular before regular operation of the lighting system. This maintenance can take place before, with or after step B).

The maintenance interface is preferably different from the interface to the lighting arrangement and from the radio module. Alternatively, in particular the maintenance interface and the radio module can be formed by the same electronic components or at least partially comprise the same electronic components.

In accordance with at least one embodiment, the method comprises the step of dismantling the lighting system. This means that the lighting system is only set up for temporary operation. For example, a period of time between step B) and the dismantling of the lighting system is at least one day or one week or one month and / or at most six months or three months or one month. The components of the lighting system are preferably set up for multiple, reversible assembly and dismantling of the entire lighting system.

The lighting system can also be a permanent installation which, as intended, is set up only once. A lighting module described here, a lighting system described here and an operating method described here are explained in more detail below with reference to the drawing on the basis of exemplary embodiments. The same reference symbols indicate the same elements in the individual figures. However, no references to scale are shown here; rather, individual elements can be shown exaggerated for a better understanding.

Show it:

Figure 1 is a schematic representation of a

Exemplary embodiment of a lighting system described here,

Figures 2 and 3 are schematic representations of

Embodiments of the lighting modules described here,

Figure 4 is a schematic representation of a

Exemplary embodiment of a lighting system described here,

Figure 5 is a schematic sectional view of a

Exemplary embodiment of a light source for the lighting modules described here,

FIGS. 6 and 7 are schematic block diagrams of FIG

Embodiments of operating methods described here, and Figures 8 to 10 are schematic representations of a

Localization of lighting modules in a lighting system described here within the scope of an exemplary embodiment of an operating method described here.

An exemplary embodiment of a lighting system 10 is illustrated schematically in FIG. The lighting system 10 includes a central system controller 5. The system controller 5 is, in particular, a computer that can send data via a radio link. The radio connection is, for example, LoRa, 5G or NB-IoT, i.e. in particular an LPWAN connection.

Furthermore, the lighting system 10 comprises a plurality of lighting modules 1. The lighting modules 1 receive trigger signals 44 from the system controller 5 via the radio link 4. The trigger signals 44 are preferably used to trigger lighting scenarios in all lighting modules 1 simultaneously and thus synchronously. In normal playback operation of the lighting system, only the trigger signals 44 are preferably sent via the radio link 4, so that the radio link 4 is only active for a small portion of the time and is otherwise paused. In addition, further, operational signals such as stop signals, switch-off signals, restart signals, time synchronization signals and / or switch-on signals can optionally be sent via the radio link 4.

An exemplary embodiment for lighting modules 1 is shown in FIG. The illustrated lighting module 1 comprises a ballast 2 and a lighting arrangement 3. Die Luminaire arrangement 3 is composed of several light sources 31.

The ballast 2 comprises, for example in a housing, a control unit 21 for controlling the lighting arrangement 3, an interface 22 to the lighting arrangement 3, a memory 23 for the lighting scenarios to be played and a radio module 24 for receiving information, in particular for receiving the trigger signals 44.

The radio module 24 is, for example, a WAN receiver. The control unit 21 is, in particular, an MCU.

The interface 22 is in particular a DMX / DALI interface. In the memory 23, for example an SD card, a large number of scenes or lighting scenarios are mapped, which are played back after the trigger signal 44 has been received. For example, 30 scenes are stored in the memory 23 per second of playing time.

Alternatively, as is also possible in all other exemplary embodiments, not all of the scenes are explicitly stored in the memory 23, but only information on the basis of which the control unit 21 can calculate control signals for the luminaire arrangement 3 after receiving the trigger signal 44.

Optionally, the lighting module 1 also includes a maintenance interface 25. The lighting module 1 can be serviced via the maintenance interface 25, for example a USB interface, an Ethernet interface or a BLE interface (BLE: Bluetooth Low Energy). The service can be, for example maintenance or the installation or deletion of lighting scenarios. This maintenance can be carried out before, during or after the lighting module is placed in a lighting system.

Furthermore, the lighting modules 1 optionally each include a locating unit 6, in particular in or on the ballast 2. The locating unit 6 is, for example, a receiver for satellite navigation signals or a UWB receiver. The locating unit 6 makes it possible for the ballasts 2 to independently determine and store their position and, optionally, to receive exact time information. Locating by the locating units 6 can be initiated, for example, by a control signal via the radio link 4 by the central control system 5.

In the exemplary embodiment in FIG. 2, the lighting arrangement 3 and the ballast 2 are designed as separate components. In contrast, the lighting arrangement 3 according to FIG. 3 is integrated in the ballast 2. The interface 22 can thus also be or contain a driver circuit for the light sources 31. It is possible for each of the light sources 31 to have its own connection or its own interface to the interface 22. In contrast, the light sources 31 of the luminaire arrangement 3, as can be seen in FIG. 2, are preferably connected in one or more linear chains.

Otherwise, the lighting module 1 in FIG. 3 corresponds to that in FIG. 2. The lighting system 10 can contain both lighting modules 1 according to FIG. 2 and lighting modules 1 according to FIG. Another exemplary embodiment of the lighting system 10 is shown in FIG. As an example, only one lighting module 1 of the lighting system 10 is shown, this lighting module 1 being located on an object 8. The object 8 is, for example, a hut on a Christmas market.

The ballast 2 is preferably attached to the object 8 at a predetermined, defined location. It is also possible for the individual light sources 31 to be attached distributed over the object 8 in accordance with a predetermined lighting plan. The light sources 31 can be present in several chains, which are implemented via cable connections 32. Such multiple chains in which the light sources 31 are arranged can also be present in all other exemplary embodiments of the lighting modules 1, in particular in the lighting modules 1 of FIGS. 2 and 3.

Since a position of the lighting module 1 is specified above the object 8, which is in particular spatially comparatively large, an optional automatic localization of the lighting module 1 by the ballast 2 only requires a comparatively low spatial resolution.

In addition, FIG. 4 shows that the lighting system 10 can comprise non-optically active components, for example a loudspeaker 82. The loudspeaker 82 is integrated into the lighting module 1 and thus connected to the ballast 2. As an alternative to the illustration in FIG. 4, the loudspeaker 82 can also be integrated into the chains 31, 32 with the light sources 31. An example of a light source 31 for the lighting modules 1 is shown in FIG. A cable connection 32 can preferably be looped through the light source 31. The light source 31, which is in particular a DMX luminaire, preferably comprises an address unit 35 in order to be able to uniquely identify the light source 31 along a light source chain, see for example FIG. 4, by the ballast 2.

It is also possible for the light sources 31 to each include a driver circuit 34. The driver circuit 34 can contain a microprocessor which converts control data or control signals, which are sent to the light source 31 via the cable connection 32, into current values, voltage values and / or energization times of a PWM.

The light source 31 contains one or more light-emitting diode components 33, alternatively also other light sources such as laser diodes. The light-emitting diode components 33 are preferably RGB components.

In addition, the light source 31 can have further components, for example movable mirrors or others

Having beam shaping components. It is thus possible for the light source 31 to emit light in certain directions as a function of time.

All components of the light source 31 are preferably accommodated in a housing 37.

In addition to, for example, light sources 31, as illustrated in FIG. 5, the lighting modules 1 can have further, contain predominantly non-optical active components such as loudspeakers or sensors. This applies equally to all exemplary embodiments.

An operating method is illustrated schematically in FIG. In a step S1, the lighting scenarios are stored on the memories 23 of the ballasts 2 of the relevant lighting modules 1 for the associated lighting system 10.

In the subsequent method step S2, the lighting system 10 is set up. That is, the lighting modules 1 with their ballasts 2 and lighting arrangements 3 are spatially arranged, for example at a Christmas market.

In the optional method step S3, localization or rough localization of the individual lighting modules is preferably carried out via the locating units 6. The lighting modules 1 can thus select and subsequently play those lighting scenarios that are provided for the determined location of the respective lighting module 1.

The lighting modules thereupon receive the trigger signals 44 via the central control unit 5 in step S4 in order to simultaneously play the intended lighting scenarios.

In the method of FIG. 7, the construction and the spatial arrangement of the lighting modules 1 take place first in step S2. The required lighting scenarios are then stored in step S1 and, optionally, the lighting modules 1 are localized in step S3.

Further possible method steps, such as performing maintenance on the lighting modules 1 or the control system 5 and dismantling the lighting system 10, are not illustrated in FIGS. 6 and 7, respectively.

Method step S3 is illustrated in greater detail in FIGS. 8 to 10. According to FIG. 8, a site plan 9 is provided. In particular, the positions provided for the lighting modules 1 are determined and entered in the site plan 9. That is to say, the lighting system 10 to be installed can be planned and designed using the site plan 9.

According to FIG. 9, a grid 7 with several grid areas 71 is created. Local areas and / or locations for the lighting modules 1, in particular in a digitized form, can be specified via the grid 7.

In FIG. 10 it is illustrated that the grid 7 is placed over the site plan 9. It is possible here for several grid areas 71 to be combined to form quadrants, for example.

The individual lighting modules 1 then receive a location signal 46, for example a satellite signal or a UWB signal. So that the lighting modules 1 can their Determine the position within the grid 7, in particular in which grid area 71 the respective lighting module 1 is located. Accordingly, the lighting module 1 can play the lighting scenarios provided for the corresponding grid area 71 from the memory 23.

If several lighting modules 1 are provided per grid area 71 or per quadrant, then preferably all lighting scenarios of all lighting scenarios provided in the relevant grid area 71 or quadrant are stored in the relevant lighting modules 1. A spatially resolved storage of lighting scenarios in the lighting modules 1 can thus be omitted and the effort involved in assembling the lighting system 10, in particular for temporary installations, is significantly reduced.

In summary, in the method described here, the memory of the control device contains not only static data, such as a light color or a color gradient across the connected light points, but also dynamic data. Dynamic means in particular that it can be changing light, like a rainbow effect, which can spread like a running light over the connected chain, or it can be data sequences for the light elements of the connected chain that were created from a video sequence. Each light point in the chain can therefore preferably be controlled individually.

The fact that the trigger signals can be sent over a WAN, i.e. a wide area network, means that these dynamic sequences can be started synchronized at all the corresponding receivers at the same time. This concept only requires a short signal, such as a trigger signal, to be sent over the radio to start the sequences stored in the memory of the ballast. The ballast then automatically outputs the data to the connected light chain. By using, for example, LoRa, NB-IoT or 5G as radio technology, the reception area is not limited to a small area, such as a piece of furniture or an apartment. It can also be, for example, an entire park or an entire district in which the ballasts with the chains are installed.

The invention described here is not restricted by the description based on the exemplary embodiments. Rather, the invention encompasses every new feature and every combination of features, which in particular includes every combination of features in the patent claims, even if this feature or this combination itself is not explicitly specified in the patent claims or exemplary embodiments. This patent application claims the priority of German patent application 102020 103 206.4, the disclosure content of which is hereby incorporated by reference.

List of reference symbols

1 lighting module

2 ballast

21 Control unit for controlling the luminaire arrangement

22 Interface to the luminaire arrangement

23 memory for lighting scenarios

24 radio module for receiving information

25 Maintenance Interface

3 luminaire arrangement

31 light source

32 Cable connection

33 LED component

34 Driver circuit

35 address unit

37 housing

4 radio link

44 trigger signal

46 location signal

5 central system control

6 Locating unit of the lighting module

7 grids

71 Grid Area

8 object

82 speakers

9 Site plan

10 lighting system

S .. process step

Claims

Claims

1. Lighting module (1) with a ballast (2) and with a lighting arrangement (3), wherein

- The ballast (2), a control unit (21) for controlling the lighting arrangement (3), an interface (22) to the lighting arrangement (3), a memory (23) for lighting scenarios, a radio module (24) for receiving information and a Locating unit (6), which is set up to determine a location of the ballast (2),

- The lamp arrangement (3) has at least one light source (31) for adjustable light generation,

- The luminaire arrangement (3) is connected to the ballast (2) by wire, and

- The lighting module (1) is set up to determine its location by means of the associated locating device (6) and the lighting scenarios for a large number of different possible locations of the lighting module (1) are stored in the memory (23).

2. Lighting module (1) according to the preceding claim, in which the interface (22) is set up for DMX and / or for DALI and / or for PLC, the lighting arrangement (3) comprising at least 10 and at most 200 of the light sources (31) , and wherein the light sources (31) are connected to one another by means of at least one cable connection (32).

3. Lighting module (1) according to one of the preceding claims, wherein the memory (23) has a size of at least 1 GB.

4. Lighting module (1) according to one of the preceding claims, in which the ballast (2) is integrated in the lighting arrangement (3).

5. Lighting module (1) according to one of claims 1 to 3, in which the lighting arrangement (2) and the ballast (3) are separate components.

6. Lighting module (1) according to one of the preceding claims, wherein the ballast (2) further comprises a locating unit (6) which is set up to determine a location of the ballast (2).

7. lighting system (10) with

- Several lighting modules (1) according to at least one of the preceding claims, and

- A central system controller (5), the central system controller (5) being set up to control the ballasts (2) of the lighting modules (1) by means of a radio link (4), and the lighting modules (1) being set up to do so, temporarily without Radio connection (4) to be operated to the central control system (5).

8. Lighting system (10) according to the preceding claim, in which a spatial extent of all lighting modules (1) taken together is at least 50 m.

9. Operating method for a lighting system (10) according to one of the two preceding claims with the steps: A) storing the lighting scenarios in the memory (23) the ballasts (2) of the lighting modules (1) of the lighting system (10),

B) Construction and spatial arrangement of the lighting modules (1), and

C) Controlling the lighting modules (1) by means of the radio link (4) with the central control system (5), the radio link (4) only sending data to the lighting modules (1) at times or the radio link (4) only being available temporarily.

10. The method according to the preceding claim, wherein the central control system (5) sends a trigger signal (44) to all lighting modules (1) at the same time, so that the lighting modules (1) begin with the respective lighting scenarios, with the radio link between successive trigger signals (44) (4) paused.

11. The method according to any one of the two preceding claims and claim 6, wherein each of the lighting modules (1) determine their respective location by means of the associated locating device (6), wherein in step A) in each of the lighting modules (1) the lighting scenarios for a plurality different locations can be saved.

12. The method according to the preceding claim, wherein a grid (7) with several grid areas (71) is specified and in each grid area (71) in step B) several of the lighting modules (1) are placed, in step A) in the lighting modules (1) all lighting scenarios of the associated grid area (71) are stored.

13. The method according to any one of the two preceding claims, wherein a coarser localization of the lighting modules (1) takes place by means of the locating device (6) and a subsequent more precise placement of the lamp assemblies (3) takes place on the basis of a predetermined distribution plan.

14. The method according to any one of claims 9 to 13, wherein the lighting scenes each have a duration of at least 1 min.

15. The method according to any one of claims 9 to 14, wherein the light sources (31) within the lamp assemblies (3) are at least partially flexibly mechanically connected to one another, so that in step B) relative positions of the light sources (3) to one another can be changed.

16. The method according to any one of claims 9 to 15, wherein the lighting modules (1) each additionally comprise a maintenance interface (25) and maintenance of the lighting modules (1) takes place via the maintenance interfaces (25).