AT18171U1 - Lighting system with photovoltaic cell as ambient light sensor - Google Patents

Abstract

A lighting system (1) includes at least one component of a lighting system (12, 15) and a system for converting light into electrical energy (11). The at least one component of a lighting system (12, 15) is connected to the light-to-electrical energy conversion system (11) via an interface connection. The conversion system of light into electrical energy (11) includes a conversion cell which is designed to determine ambient brightness. The conversion system of light into electrical energy (11) also has a data transmission module (21), which is designed to transmit a control signal to the at least one component of a lighting system (12, 15) depending on the determined ambient brightness.

Description

Description

LIGHTING SYSTEM WITH PHOTOVOLTAIC CELL AS AMBIENT LIGHT SENSOR

The invention relates to a lighting system, in particular a DALI lighting system.

[0002] Conventionally, the power supply in DALI lighting systems is network-dependent. This means that the functionality of the lighting system depends on the presence of a functioning mains supply.

In order to ensure a grid-independent function, the use of photovoltaic cells and/or energy storage is conceivable.

If a lighting system is to be operated depending on ambient brightness, it is possible to measure the ambient brightness using an ambient brightness sensor. However, such a solution is disadvantageous because the ambient light sensor not only measures the ambient brightness, but also the brightness of the lights of the lighting system.

To solve this problem, document WO 2016/110304 shows the operation of a lamp with pulse width modulation.

The invention is based on the object of creating a lighting system which can determine ambient brightness with minimal hardware effort and at the same time can work at least partially independent of the mains.

The object is achieved according to the invention for the device by the features of independent claim 1. Advantageous further training is the subject of the related subclaims.

A lighting system according to the invention includes at least one component of a lighting system, preferably an operating device, and a conversion system of light into electrical energy, preferably a photovoltaic unit. The at least one component of a lighting system is connected via an interface connection to the conversion system of light into electrical energy, preferably to the photovoltaic unit. The conversion system of light into electrical energy, preferably the photovoltaic unit, includes a conversion cell, preferably a photovoltaic cell, which is designed to determine ambient brightness. The conversion system of light into electrical energy, preferably the photovoltaic unit, also has a data transmission module which is designed to transmit a control signal to the at least one component of a lighting system depending on the determined ambient brightness. This makes it possible to generate energy in the lighting system independently of the mains, and at the same time to operate the lighting system depending on the ambient brightness with minimal hardware effort.

[0009] Preferably, the control signal is a switch-on command and/or a switch-off command and/or dimming command. It is thus possible to control lights connected to at least one component of a lighting system based on the ambient brightness.

The lighting system preferably has at least one lamp, which is connected to the at least one component of a lighting system. The at least one component of a lighting system is then designed to then control the at least one lamp based on the control signal. This makes it possible to control at least one light based on the ambient brightness with minimal hardware effort.

[0011] Preferably, the lighting system has a plurality of components of a lighting system, each of which is connected to the conversion system of light into electrical energy, preferably to the photovoltaic unit. The lighting system has at least one lamp per component of a lighting system. The lamp is connected to the respective component of a lighting system. The components of a

A lighting system is designed to control the respective lights based on the control signal. This makes it possible to control a large number of lights based on the ambient brightness with minimal hardware effort.

Preferably, the conversion cell, preferably the photovoltaic cell, is arranged in such a way that there is no direct line of sight between a light-sensitive side of the conversion cell, preferably the photovoltaic cell, and all lights of the lighting system. This makes it possible to significantly reduce the influence of the light generated by the lights of the lighting system on the measured ambient brightness.

[0013] Preferably, the conversion cell, preferably the photovoltaic cell, is arranged such that the conversion cell, preferably the photovoltaic cell, receives essentially natural light and receives essentially no light from all the lights of the lighting system. This can also reduce the influence of the light generated by the lights on the measured ambient brightness.

Alternatively or preferably additionally, the at least one component of a lighting system is designed to control all lights of the lighting system with pulse width modulation. The conversion cell, preferably the photovoltaic cell, is then designed to determine the ambient brightness when the pulse width modulation is switched off. In this way, an influence of the light generated by the lights on the measured ambient brightness can be avoided.

[0015] The lighting system preferably also has a DALI BUS power supply. The conversion cell, preferably the photovoltaic cell, is designed in this case to supply the DALI BUS power supply with energy. This achieves network-independent operation of the DALI BUS energy supply.

[0016] The lighting system preferably also has an energy storage device. The conversion cell, preferably the photovoltaic cell, is then designed to charge the energy storage device. This makes it possible to operate the lighting system and in particular the DALI BUS energy supply independently of the mains, even if the photovoltaics do not provide any energy.

[0017] In addition, it is conceivable to charge the energy storage device with energy not only through the conversion system of light into electrical energy, preferably through the photovoltaic unit, but through a mains supply. In this way, mains-independent emergency lighting operation can be guaranteed, especially in long periods of insufficient natural light. The lighting system preferably also has a DALIBUS control device, which is designed to control the at least one component of a lighting system.

Preferably, the DALI BUS control device and the transmission module of the light-to-electrical energy conversion system, preferably the photovoltaic unit, use different communication protocols. This ensures that the components of a lighting system can distinguish whether a received DALI command comes from the DALIBUS control device or from the data transmission module of the photovoltaic unit.

The DALI BUS control device is preferably designed to send control commands with a higher priority than the data transmission module of the light-to-electrical energy conversion system, preferably the photovoltaic unit. This ensures that when there are conflicting commands, it is clear which command has higher priority.

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

1 shows a first exemplary embodiment of the lighting system according to the invention, and

2. a part of the second exemplary embodiment of the lighting system according to the invention.

First, the general structure and general function of an exemplary embodiment of the lighting system according to the invention will be explained with reference to FIG.

[0024] Details of the functioning of another embodiment will be discussed below with reference to Fig. 2. Identical elements were shown and described in similar figures, some of which are not repeated.

A first exemplary embodiment of the lighting system 1 according to the invention is shown in FIG. The lighting system 1 includes a DALI BUS energy supply device 10 connected to a conversion system of light into electrical energy, preferably a photovoltaic unit 11, which in turn is connected to a component of a lighting system, preferably an operating device 12.

The operating device 12 is connected to a lamp 13. An energy storage device 14 is also connected to the photovoltaic unit 11. Optionally, another operating device 15 is also connected to the photovoltaic unit 11, which in turn is connected to another light 16.

Optionally, further components of a lighting system, preferably operating devices, which are each connected to a lamp, are connected to the photovoltaic unit 11.

The lighting system 1 also optionally has a network-based energy supply, which is connected to the energy storage device 14, the DALI BUS energy supply device 10 and the operating devices 12, 15, if it is present. However, the grid-based energy supply is not shown here.

The energy is stored in the energy storage device 14 by means of capacitors, in particular supercaps or accumulators, in particular lithium-ion accumulators.

[0030] Optionally, the lighting system 1 can further comprise a DALI bus control device 17, which is connected via the DALI BUS to the components of a lighting system, preferably operating devices 12, 15.

The DALI BUS power supply 10 is shown here as an external device compared to the components of a lighting system, preferably operating devices 12, 15. An integration of the DALI BUS power supply device 10 into one of the components of a lighting system, preferably into one of the operating devices 12, 15, is also conceivable.

[0032] In the following, the structure of the embodiment in Fig. 2 will first be discussed before the function of the embodiments from Fig. 1 and Fig. 2 will be discussed together.

[0033] In Fig. 2, a second embodiment of the lighting system 1 according to the invention is shown.

In particular, the internal structure of the conversion system of light into electrical energy is shown here. In general, the light-to-electrical energy conversion system includes a conversion cell and a data transmission device 21. In this embodiment, the light-to-electrical energy conversion system is formed by a photovoltaic device 11 and the conversion cell is formed by a photovoltaic cell.

The conversion cell, preferably the photovoltaic cell 20, can be arranged next to a lamp or outside a lamp, for example near a window. Sensors, operating devices and lights of the lighting system 1 can be equipped with photovoltaic cells.

The conversion cell, preferably the photovoltaic cell 20, is connected to the energy storage device 14, the DALI BUS energy supply device 10 and optionally the components of a lighting system, preferably the operating devices 12, 15. The data transmission device 21 is connected to the components of a lighting system, preferably the operating devices 12, 15, via an interface connection.

The conversion cell, preferably the photovoltaic cell 20 of the system for converting light into electrical energy, preferably the photovoltaic unit 11, receives light and uses it to determine the ambient brightness. The data transmission device 21 generates a control signal based on the ambient brightness determined by the conversion cell, preferably the photovoltaic cell 20. The control signal is preferably a switch-on command and/or a switch-off command and/or a dimming command. This control command is transmitted to the component of a lighting system, preferably the operating device 12, or to the components of a lighting system, preferably the operating devices 12, 15. The control command controls the components of a lighting system, preferably the operating devices 12, 15. The components of a lighting system, preferably the operating devices 12, 15, control the respectively connected lights 13, 16 based on the control command that they received from the data transmission unit. So Automatic switching on, switching off and dimming of the lights 13, 16 is possible without an additional DALI control device.

[0038] Preferably, the conversion cell, preferably the photovoltaic cell 20, is arranged in such a way that light emitted by the lights 13, 16 does not fall on a light-sensitive side of the conversion cell, preferably the photovoltaic cell 20, in order to prevent the artificially generated light from influencing the determined ambient brightness to minimize.

An influence can be completely excluded if the operating devices 12, 15 operate the lights 13, 16 using pulse width modulation and the conversion cell, preferably the photovoltaic cell 20, determines the ambient brightness during switch-off times of the pulse width modulation.

[0040] If pulse width modulation is used, the brightness is preferably measured twice. The brightness is measured once during a pulse width modulation switch-on time, and the brightness is measured once during a pulse width modulation switch-off time. During the switch-on time, a sum of the amount of light generated by the lights and the ambient brightness is measured. During the switch-off time, only the ambient brightness is measured.

If the DALI BUS power supply 10 is part of the lighting system 1, the photovoltaic device 11 supplies the DALI BUS power supply 10 with energy. However, this is only the case when the conversion system of light into electrical energy, preferably the photovoltaic unit 11, receives light energy. If the conversion system of light into electrical energy, preferably the photovoltaic unit 11, does not receive any light energy, the DALI BUS power supply 10 can be supplied with energy from the optional energy storage device 14, provided energy is stored there. Alternatively, the DALI BUS power supply 10 is supplied with energy by means of the network-based power supply, not shown here.

Preferably, components of a lighting system, preferably the operating devices 12, 15, can be configured in such a way that they automatically turn on the lights 13, 16 in the absence of a control signal from the data transmission device 21 of the light-to-electrical energy conversion system, preferably the photovoltaic unit 11 a predetermined way, e.g. maximum brightness. This would be the case if there is no ambient light and thus the conversion system of light into electrical energy, preferably the photovoltaic unit 11, has no energy to send out control commands using the data transmission device 21.

As described above, the lighting system 1 can also have an optional DALI bus control device 17. If available, this is connected to the components of a lighting system, preferably the operating devices 12, 15, via the DALI bus. If such a DALI bus control device 17 is present, a distinction must be made between the commands of the data transmission device 21 of the light-to-electrical energy conversion system, preferably the photovoltaic unit 11, and DALI signals of the DALI BUS control device 17. This can be achieved by the DALI BUS control device 17 sending out the control commands with a higher priority than the data transfer.

transmission device 21. Alternatively or additionally, the DALI BUS control device 17 and the data transmission device 21 can use different transmission protocols.

[0044] Optionally, the components of a lighting system, preferably the operating devices 12, 15, can also be configured in such a way that commands from the data transmission device 21 are ignored at certain preset times. In particular, it can be set that the lighting by means of the lights 13, 16 should remain deactivated at certain times, e.g. on weekends or holidays. However, using the optional DALI BUS control device 17, it is possible to override these presets and control the components of a lighting system, preferably the operating devices 12, 15 or the connected lights 13, 16, at any time.

The invention is not limited to the illustrated embodiment. A wide variety of devices can be used in the lighting system 1. Different storage media and energy generation means can also be used instead of a photovoltaic cell. All features described above or features shown in the figures can be advantageously combined with one another within the scope of the invention.

Claims (10)

Expectations 1. Lighting system (1) with at least one component of a lighting system (12, 15), and a conversion system of light into electrical energy (11), wherein the at least one component of a lighting system (12, 15) via an interface connection with the conversion system of light into electrical energy (11), characterized in that the light-to-electrical energy conversion system (11) includes a conversion cell (20) which is designed to determine an ambient brightness, the light-to-electrical energy conversion system (11 ) has a data transmission module (21), which is designed to transmit a control signal to the at least one component of a lighting system (12, 15) depending on the determined ambient brightness. 2. Lighting system (1) according to claim 1, characterized in that the control signal is a switch-on command and / or a switch-off command and / or a dimming command. 3. Lighting system (1) according to claim 1 or 2, characterized in that the lighting system (1) has at least one lamp (13, 16) which is connected to the at least one component of a lighting system (12, 15), and where the at least one component of a lighting system (12, 15) is designed to control the at least one lamp (13, 16) based on the control signal. 4. Lighting system (1) according to claim 1 or 2, characterized in that the lighting system (1) has a plurality of components of a lighting system (12, 15), each of which is connected to the conversion system of light into electrical energy (11), wherein the lighting system (1) has one lamp (13, 16) per component of a lighting system (12, 15), which is connected to the respective component of a lighting system (12, 15), and wherein the components of a lighting system (12, 15 ) are designed to control the respective lamp (13, 16) based on the control signal. 5. Lighting system (1) according to claim 3 or 4, characterized in that the conversion cell (20) is arranged such that there is no direct line of sight between a light-sensitive side of the conversion cell (20) and all lights (13, 16) of the lighting system (1 ) consists. 6. Lighting system (1) according to one of claims 3 to 5, characterized in that the conversion cell (20) is arranged such that the conversion cell (20) - receives essentially natural light, and - essentially no light from all the lights (13 , 16) of the lighting system (1). 7. Lighting system (1) according to one of claims 3 to 6, characterized in that the at least one component of a lighting system (12, 15) is designed to control all lights (13, 16) of the lighting system (1) with pulse width modulation, and wherein the conversion cell (20) is designed to determine the ambient brightness when the pulse width modulation is switched off. 8. Lighting system (1) according to one of claims 1 to 7, characterized in that the lighting system (1) has a DALI-BUS power supply (10), and wherein the conversion cell (20) is designed to provide the DALI-BUS power supply (10) to supply energy. 9. Lighting system (1) according to one of claims 1 to 8, characterized in that the lighting system (1) has an energy storage device (14), and wherein the conversion cell (20) is designed to charge the energy storage device (14). 10. Lighting system (1) according to one of claims 1 to 9, characterized in that the lighting system (1) has a DALI-BUS control device (17) which is designed to control the at least one component of a lighting system (12, 15), wherein the DALI-BUS control device (17) and the data transmission module (21) of the light-to-electrical energy conversion system (11) use different communication protocols, wherein the DALI-BUS control device (17) is designed to send control commands with a higher priority than the data transmission module (21) of the light-to-electrical energy conversion system (11). 1 sheet of drawings