The present invention relates to a luminaire for illuminating an area of a building, in particular an office, comprising lighting means for providing light, a support means on which the lighting means can be mounted, a control unit for controlling the lighting means by means of control commands, and a communication means for communicating with the control unit, the communication means comprising a data carrier in which data that can be read out by the control unit are stored for the purpose of controlling the luminaire. Such luminaires typically also have a power source of their own, or at least a connection for a power source, for supplying the luminaire with power.
Luminaires of this type are also known as “intelligent luminaires” and are used for illuminating areas of buildings, in particular open-plan offices. Frequently, these luminaires also have presence detection means. These means typically consist of a detector for detecting the presence of persons in an area surrounding the luminaire, so that the luminaire can switch on automatically when persons are detected, and after a certain follow-on time, the luminaire can switch off automatically if, after a certain period of time, no persons are detected in the area surrounding the luminaire. In the scope of the description of the present invention, areas of buildings are also meant to include the entry areas of buildings, therefore the luminaire according to the invention may also be located outside of a building.
DE 10 2006 057755 A1 discloses a controllable lighting system having a number of intelligent luminaires which are connected to one another via cables, and which are controlled dependent on daylight or in accordance with the movement of persons or animals present in the area of the lighting system. Also disclosed is a control of the lighting system in which individual lights or groups of lights are dimmed dependent on the position of a person, or are switched off when no user is present in the room. Corresponding control commands for the lighting system as a whole are generated in response to a signal or a lack of a signal indicating the presence of persons or animals.
Another lighting system having a number of intelligent luminaires is described in EP 2048916 B1. In that case, the luminaires are connected to control and/or sensor elements via a wired luminaire network. The essential feature of this luminaire network is that each of the luminaires is equipped with a single-strand or multi-strand data signal line, which is inserted into the power supply rails and is thus a component of the common power supply device. This makes it possible for each of the luminaires to transmit data to the other luminaires via a wired connection. If a control and/or sensor element assigned directly to the luminaire triggers a control signal, the luminaire may act on this control signal autonomously to control the lighting means, but may also forward it to the other luminaires in the network via the wired data transmission channel. The data signal line is configured particularly as a single-wire or multiwire bus.
DE 10 2011 002 478 A1 discloses a wired lighting system.
One problem with such wired, intelligent lighting systems is the fact that the installation effort required is relatively great, and increases the more luminaires are to be integrated into the overall lighting system. Moreover, changes to the lighting system, i.e. a repositioning of the individual luminaires, for example in open-plan offices, or changes between different rooms are difficult. Moreover, a special wired communications channel must he provided in order to even make such an intelligent lighting system possible.
DE 10 2012 204579 A1 describes an intelligent lighting system in which the luminaires communicate wirelessly a communication means. In this case, individual luminaires can be combined into groups, so that only luminaires that are located in a specific section of an open-plan office or on a particular floor of a building are switched on or off or dimmed to a certain illumination level. Here, three illumination levels are stored in the luminaires, for example, and are adjusted according to a fixed set of rules in order to prevent pools of light. For instance, the luminaires can contain detectors, which detect the presence of persons in the area surrounding the luminaires, so that when a person enters the office, the luminaire that is closest to the entry area is switched on first. At that point, the luminaire can be switched to the second illumination level. At the same time, the remaining luminaires are switched to the first illumination level. If the person proceeds to his workspace, those luminaires that detect the presence of the person in their vicinity are switched to the second illumination level. The remaining units are returned to the first illumination level.
The rules according to which the various luminaires are controlled are permanently defined and cannot be changed. Only the assignment of the individual lighting means to a particular group can be changed. A time-dependent control of the luminaires also is not possible.
The object of the present invention is to further develop the luminaires of the aforementioned type in such a way that they can be controlled flexibly and particularly in a time-dependent manner, independently of a lighting or data network.
This object is attained with a luminaire according to claim 1, and with a lighting system according to claim 8 and a method according to claim 9. Advantageous developments are the subject matter of the dependent claims.
The essential feature of the invention is that a timing module capable of independently providing the current time and optionally the current date is provided in or on the luminaire. The data stored in the data carrier, which is preferably detachably mounted on the luminaire, can be read out based on the time information provided by said timing module for the time-dependent control of the luminaire. Since the luminaire according to the invention has a timing module, no external timer is necessary. The luminaire can thus be controlled in a complex, time-dependent manner, without requiring a data or lighting network, that is to say some type of cabling, to be provided outside of the luminaire. The luminaire is therefore autonomous. The time information of the data is synchronized with the current time, and preferably also with the current date. Thus if the data specify that an action is to be executed on a certain date and at a certain time, the control unit will compare the current date and the current time with those specified by the data. If the date and time match, the prescribed action is executed. The control unit converts the data into corresponding control commands, with which the lighting means may be switched on or dimmed, for example, in order to change the illumination level. The lighting means may also comprise a number of LEDs (“light-emitting diodes”), in Which case some of the LEDs are switched on or off to change the illumination level.
Widely differing parameters can be taken into consideration. For example, if the luminaire is used for illuminating an office, the luminaire may be operated differently on weekdays from its operation on weekends or holidays, In addition, office hours may be taken into consideration, so that the luminaire is controlled differently during office hours from outside of office hours. With regard to the date, daylight saving time and standard time can be taken into consideration. When the office is closed, some or all of the lighting means may be switched off. For safety reasons, however, it may be prudent for the luminaires to be switched on for a certain period of time even after office hours, or for the illumination level to be changed at certain intervals.
It is also possible for the color of the light emitted by the lighting means to be changed based on the time of day. For example, the lighting means may be set to emit a blue tone in the morning and an orange tone in the evening, in order to synchronize the lighting with the biorhythms of the people working in the office, that is to say, to create the most natural lighting situation possible during the course of the day. In the following, the timing defined by the data with which the lighting means are controlled, according to the above specifications, will be referred to as the “illumination pattern”.
The data carrier can be permanently mounted and disposed in the luminaire, and the communication means can be embodied as an electric cable. The illumination pattern defined on the data carrier can be defined in the factory, in which case the buyer may be given the opportunity when ordering the luminaires to provide customized specifications, for example with respect to office hours or colors.
The means for detecting the presence of persons in the area surrounding the luminaire, e.g. a detector for detecting the presence of a person in the area surrounding the luminaire, may operate using ultrasound, infrared detection (e.g. by means of passive infrared sensors), radar, or the like. What is important is that persons can be detected even when they are working at their desks and thus have a low level of movement activity.
It is thereby possible to control the luminaire according to the invention so as to provide a level of illumination that is pleasant to people, while at the same time minimizing energy consumption, without requiring an external infrastructure to be present or provided.
In a preferred embodiment, the data carrier is designed as a portable storage medium. In this embodiment, the data carrier is not permanently mounted in the luminaire, and can instead be connected to the luminaire at any time by a user or removed therefrom. This results in the significant advantage that the user can conveniently design the illumination pattern as desired, using a computer and software, and can store the defined illumination pattern on the portable storage medium. He can then connect the portable storage medium to the luminaire, so that the luminaire can be operated using the defined customized illumination pattern. Changes to the illumination pattern can be implemented quickly enough to provide a special illumination pattern for a specific occasion, for example, or to adjust the illumination pattern to changes in office equipment or the arrangement of furniture in the office.
The communication means preferably comprises an SD card slot for insertion of an SD card, a USB port for connecting a USB-enabled device and/or a wireless interface for wirelessly communicating with an appropriately equipped device. Other suitable interfaces that can be used as alternatives to the USB port are also conceivable. The purchaser of the luminaire can also be supplied with software, which the user can use to define the desired illumination pattern on a computer. The defined illumination pattern is then stored on a USB flash drive or an SD card, which is then connected to the luminaire, so that the data are provided to the control unit. In this embodiment example, the USB flash drive or SD card functions as the data carrier, which in this case is portable rather than being permanently located in the luminaire. Alternatively, the computer can be connected directly to the USB port and the illumination pattern can be stored on the data carrier, which is permanently located in or on the luminaire. The same process may also be carried out via the wireless interface, in which case the illumination pattern can be designed, for example, on a smartphone using an app and transmitted via the wireless interface to the data carrier that is permanently disposed in the luminaire, where it can be stored.
It is thereby possible to flexibly and easily design the illumination pattern and transmit it to the luminaire. In addition, the illumination pattern can be easily changed, for example if the luminaire is moved to a different location. The software may have a feature that calculates the energy consumption per unit of time, for example per week or per month, enabling the user to determine and optimize the energy consumption.
In a preferred embodiment, the lumninaire has a transmitting means, with Which the control commands can be transmitted to a number of secondary luminaires, wherein the secondary luminaires can be controlled with the control commands and have a receiving means for receiving the control commands, which communicates with the transmitting means. In this case, the luminaire itself functions as a master luminaire, the transmitting means of which transmits the control commands to the secondary luminaires, which are then operated using the corresponding illumination pattern. This master luminaire effectively teaches the secondary luminaires.
Externally, the secondary luminaires can be identical in configuration to the master luminaire, but do not require their own communication means and their own data carrier, and do not need to be capable of communicating with the external data carrier. The secondary luminaires need only to be configured in such a way that the lighting means of the secondary luminaires can be controlled by means of the control commands received by the receiving means. As a result, the secondary luminaires can be somewhat simpler in design, making them less costly to produce. However, it is equally possible to use software to designate one master luminaire as the actual master luminaire from a number of identical master luminaires and to designate the other master luminaires as secondary luminaires.
Furthermore, the process is simplified for the user if he has to provide the illumination pattern only via the master luminaire. The control commands are preferably transmitted wirelessly to the secondary luminaires, so that the luminaires can be easily installed and their location easily changed. The receiving unit of the secondary luminaires can also be configured such that it can itself transmit signals, which can in turn be received by the transmitting means of the master luminaire. In particular, this enables a specific secondary luminaire to be clearly identified. A specific secondary luminaire can thereby be assigned a different illumination pattern from the master luminaire or another secondary luminaire. Additionally, one or more secondary luminaires may be combined into one or more groups, to which a different illumination pattern is assigned from the master luminaire or other secondary luminaires or other groups. The master luminaire can itself be part of a group. The software that is used to create the illumination pattern can have corresponding features. The user can thereby assign a highly complex illumination pattern individually to each secondary luminaire, each group and/or the master luminaire by inputting the illumination pattern solely via the master luminaire. Thus highly complex illumination patterns can be achieved easily and quickly.
A further aspect relates to a lighting system for illuminating an area of a building, in particular an office, comprising a luminaire according to any of the embodiments discussed above, which has a transmitting means, a number of secondary luminaires that can be controlled by means of the luminaire, wherein the secondary luminaires have a receiving means that communicates with the transmitting means. A customized network of luminaires can be constructed, without requiring any major installation and assembly work. The further advantages and technical effects that can be achieved with the lighting system according to the invention correspond to those that have been described for the luminaire according to the invention.
The object is further achieved by a method for illuminating an area of a building, in particular an office, with a luminaire according to any of the aforementioned embodiments, comprising the following steps:
With the method according to the invention, it is possible to control the luminaire in a time-dependent manner, autonomously, and independently of a luminaire network or data network, so that a time-dependent illumination pattern can be achieved, which nevertheless requires little energy. In addition, the presence of a person can be taken into consideration, with the lighting means typically being controlled as prescribed by the data only when a person is present in the office. This means, for example, that a stored illumination pattern is output by the luminaire or the lighting means only when the presence of a person in the region of the luminaire is actually detected. For example, if the illumination pattern involves changing the intensity and/or the color of the emitted light within a predetermined time interval during a day, for example 7:00 to 19:00, this will be carried out only if a person is actually detected by the presence detection means in the luminaire. In contrast, if no person is detected in the region around the luminaire, the luminaire will remain in its switched-off state. However, if a person enters the region around the luminaire, the stated illumination pattern will be activated by the luminaire. Thus according to the invention, when the presence of a person is detected, not only is the luminaire switched on, the illumination pattern stored on the mobile data carrier is implemented according to the respective programming in the control unit of the luminaire. Additionally, or independently thereof, it is also possible for other control functions for the luminaire to be stored on the portable data carrier. For example, information as to whether or not the luminaire actually activates its presence detection means at all may be stored in the portable data carrier. For instance, for a certain period of time during the day, typically during office hours, the presence detection means may be set to “highly sensitive”. For all other times, however, the presence detection means is deactivated.
If a person enters in the office at a very unusual time, for example in the middle of the night, the lighting means may intentionally not be actuated, or the lighting means may be intentionally actuated in a manner corresponding to a visual alarm, for example, a flashing red light, to make the presence of the person, who might be a burglar, as uncomfortable for him as possible, and to make others aware of his presence.
Additional advantages and technical effects of the method according to the invention correspond to those that have been described for the luminaire according to the invention.
The method according to the invention is preferably further enhanced in that the lighting means are switched off by means of the control unit as soon as the presence detection means have determined that no persons are present. If no persons will be present in the office during office hours due to a company outing or other event, it is not necessary to deactivate an illumination pattern. Thus energy can be saved by switching off the lighting means. However, it may also be specified that when no persons are present, the lighting means are switched off only during a certain time period. If no persons are present beyond this period of time, the lighting means may be dimmed, for example, to a low illumination level.
A further enhancement of the method according to the invention is characterized by the following steps:
The advantages and technical effects that can be achieved thereby correspond with those that have been discussed for the luminaire according to the invention and the secondary luminaires.
A further aspect of the invention relates to the use of the luminaire according to the invention and/or the lighting system according to the invention to illuminate an area of a building, in particular an office.
In the following, the invention will be described in detail in the context of preferred embodiments, with reference to the accompanying drawings. The drawings show
A control unit 22, a communication means 24, a data carrier 26, a timing module 28 and a power source 30 are disposed in luminaire pole 16, and are illustrated in greater detail in
In
Luminaire 10 according to the invention further comprises a detector 36 (see
With respect to the embodiment shown in
In particular, the data contain time information, according to which a specific control command is to be executed at a very specific point in time, that is to say, at a very specific time of day. To enable this, timing module 28 supplies the current time and preferably also the current date. Timing module 28 can be configured as a real-time clock 42, which can have a receiver that can receive a time signal emitted by a time signal transmitter via radio. This enables the real-time clock to be synchronized regularly, similarly to a clock radio, so that the time supplied by timing module 28 is highly accurate. The timing module may also be configured independently of radio clock signals, however, using a timing module that operates on the basis of quartz time, for example. Control unit 22 draws the current time and the current date from timing module 28 in short intervals. As soon as the time information supplied from the data for a specific control command matches the current date and the current time, control unit 22 executes the control command. In this case the data are stored on data carrier 26 in the factory.
In the embodiment shown in
The data may also factor in the presence of a person in the area surrounding luminaire 10. For instance, certain illumination patterns may he activated only when a person is present in the area surrounding luminaire 10. It is also possible to activate a first illumination pattern when a person is present at a first time and a second illumination pattern when a person is present at a second time. Detector 36 supplies the information as to whether or not a person is present in the area surrounding luminaire 10.
As a result, secondary luminaires 401, 402 can be operated using the same illumination pattern as master luminaire 44. It is also possible, however, for secondary luminaires 40 to be operated using a specific illumination pattern only when a person is present in the area surrounding said luminaires. Secondary luminaires 401, 402 may also activate the illumination pattern on a delayed basis, or may activate a different illumination pattern. Receiving means 46 of secondary luminaires 401, 402 may be configured to transmit information, such as its distinct identification, to transmitting means 38 of master luminaire 44. Master luminaire 44 can thus be operated using a first illumination pattern, first secondary luminaire 401 using a second illumination pattern, and second secondary luminaire 402 using a third illumination pattern. It is also possible, however, for the two secondary luminaires 40 or the master luminaire 44 and one of the secondary luminaires 401, 402 to be combined into a group and controlled identically.
In
It is clear that from April to September at any given time, a different number of commands will be executed from between October and March. This is due to the different lighting conditions during the two periods. However, control command 1, which can switch on detector 36, for example, is always executed. Thus information as to whether or not a person is present in the area surrounding luminaire 10 is always available.
In addition, it is programmed as the next set value on the SD card, and thus on data carrier 26, that at 09:00 the dimming value is to be increased to 90%. When timing module 28 supplies the time signal 09:00, a new control command to increase accordingly the luminous value of the luminaire, which is not shown in
Finally, additional setting information is stored on data carrier 26, namely at the luminaire is to be switched off at 22:30, along with the presence detection means. When timing module 28 supplies the time information 22:30, corresponding control commands are transmitted via communication means 24 to control unit 22. The luminaire is switched off and the presence detection means in that area is deactivated. The next day at 05:10, as described above, the luminaire is switched back on accordingly, the presence detection means is activated and the luminaire is set to provide a brightness value of 70% of the maximum luminous intensity.
Number | Date | Country | Kind |
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102014103197.0 | Mar 2014 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2015/055005 | 3/11/2015 | WO | 00 |