• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    A luminaire (1) has a plurality of luminous means (2) for emitting light, a luminaire housing (3) for receiving the luminous means (2), a controller for driving the luminous means (2) and sensors (5) for detecting optical and / or structural features of a Ambient area of the lamp (1), in particular a mounting area (M) of the lamp (1), wherein the controller is designed such that the light emitting means (2) individually to control based on the data detected by the sensors (5) to the Visually adapt luminaire (1) to the surrounding area (M).
    公开号:AT15186U1
    申请号:TGM9011/2013U
    申请日:2013-09-04
    公开日:2017-02-15
    发明作者:
    申请人:Zumtobel Lighting Gmbh;
    IPC主号:
    专利说明:

    description
    LAMP
    The present invention relates to a lamp with a plurality of bulbs for emitting light, which are accommodated in a lamp housing and are controlled by means of a control based on data detected by sensors, and a lighting environment and a lighting system comprising the lamp.
    Lights with sensors are known from the prior art. For example, there are luminaires which are equipped with motion sensors and when a moving object is detected, the luminaire is switched on. There are also luminaires which are equipped with a light sensor and, for example, switch the luminaire on or off at a certain threshold value of an ambient light.
    Basically, the problem remains that luminaires do not fit harmoniously into the environment as a whole, which is regarded as disturbing especially in architects. For example, in the case of spotlights, it is conceivable to associate their luminaire housing project-specific with their own housing color. Moreover, it is known to provide luminaires with frames in which a fixed color can be set in the context of color design of an opaque edge surface. However, all the above known techniques have the disadvantage that the housing color is set once and does not adapt to changing external influences (such as a change in ambient light) accordingly, so that the lamp is not inserted optimally and harmoniously in the environment.
    In particular, in televisions, the so-called ambilight principle is known in which a light is directed to the back wall surface in the surrounding area of the television picture, wherein the light adapts to the television picture in terms of its color. In other words, using the Ambilight principle, information is projected onto the environment, so that the image of the TV is magnified.
    It is now an object of the present invention to provide a lamp that blends harmoniously into the environment as a whole; as well as a corresponding lighting environment and a lighting system.
    This object is solved by the subject matter of the independent claims. The dependent claims further form the central idea of the present invention in a particularly advantageous manner.
    According to a first aspect, the invention relates to a luminaire comprising a plurality of luminous means for emitting light, a luminaire housing for accommodating the luminous means, a controller for controlling the luminous means, and sensors for detecting optical and / or structural features of an ambient region of the luminaire, in particular an assembly area of the luminaire Lamp. Optical features are understood in the context of the invention, in particular the color; Structural features are, in particular, the structure or the material of the surrounding area of the luminaire, in particular an assembly area, such as a wall or ceiling. The controller is designed such that it controls the light source for emitting light on the basis of the data acquired by the sensors (for example color sensors or cameras) in order to visually adapt the luminaire to the surrounding area or to adapt it to the surrounding area.
    By means of the aforementioned luminaire, it is thus possible to detect by the attached to the lamp sensors color, material and / or structure of the environment (wall, ceiling, etc.) and depending on the color, material and / or structure of the luminaire housing to illuminate or emit light via the individually controlled bulbs in the appropriate color. In this way, the luminaire can be easily and preferably automatically adapted to the surrounding area, for example, the mounting surface, so that it is optically embedded in the environment and preferably becomes virtually invisible. It is thus also possible to use only a single luminaire in different environments in the same way and thus to considerably reduce the hardware variants of the luminaire, which at the same time leads to a reduction in the development and production costs. Due to the simple construction of the lamp, it is also possible to use the object according to the invention both in the case of a suspended luminaire and in a directly on the mounting surface (for example, wall, ceiling) mounted lamp. In the case of a direct mounting, the sensors therefore preferably detect the immediate surrounding area of the luminaire, in the case of a suspended mounting also the area of the ceiling or wall lying directly behind or above the luminaire.
    According to one embodiment, the lighting means can be arranged distributed in or on the lamp housing, preferably in the form of a matrix or a grid. Alternatively or additionally, it is also conceivable that the lighting means have at least a first light source for primary light output (that is, for example, for illuminating a room) and at least a second light source for illuminating the light housing. The controller is then designed to individually control at least the second lighting means in such a way that the luminaire housing is illuminated on the basis of the data detected by the sensors in order to visually adapt the luminaire housing to the surrounding area or to adapt it to the surrounding area. Moreover, it is also conceivable that the light output of the first luminous means is adjusted or driven accordingly on the basis of the data detected by the sensors.
    The luminaire housing may have a primary radiating surface (hereinafter also referred to as radiating area) for the primary light output, which is associated with the first light source, and a second radiating surface for illuminating the light housing, which is associated with the second light source, wherein the primary radiating area and the second radiation region is preferably separated from each other by a reflector which is designed and arranged for a directed radiation of the primary light emission.
    The luminaire housing may have openings and / or be at least partially made of a translucent, preferably opaque or transparent material. The opening or the (opaque) material preferably form the second emission surface. The luminous means, preferably the second luminous means, are associated with the openings or the areas of translucent or opaque material in such a way that they emit through the opening to the outside or backlight the areas from the inside in order to visually adapt the luminaire to the surrounding area; preferably to illuminate the luminaire housing accordingly. The openings may be filled with a translucent, preferably opaque material.
    As the light source preferably LEDs or OLEDs are used, preferably white LEDs and / or RGB LEDs and the like; in particular, illuminants which enable a different light output, in particular a different color light output, by corresponding activation. Preferably, the LEDs are arranged in clusters, for example in clusters each having different monochromatic LEDs to cover a wide color spectrum per lamp.
    The sensors preferably comprise color sensors for detecting optical features, in particular the color, of the surrounding area of the luminaire. According to a preferred embodiment, the sensors may also be cameras for detecting the optical and / or structural features of the surrounding area of the luminaire.
    The controller is preferably designed to detect the data of the sensors continuously or at predetermined intervals and to control the lamps accordingly continuously or discontinuously. In particular, it can be provided to control the light emitting means for emitting light in the respective regions of the light housing with respect to a defined color on the basis of the data sensors. The lamp itself is thus able to modify the light output in some areas in terms of their color, so that the
    Luminaire housing assumes the color of the surrounding area at least in an outer edge region. However, the visual adjustment of the lamp may also extend from the edge of the lamp housing in the direction and preferably to the center, the light adaptation to the center preferably continuously decreases or preferably continuously attenuates, so that the lamp accordingly in terms of their colored light output in the environment harmoniously embeds.
    The degree of visual adjustment may also be manually adjustable, so that the mode of the optical embedding can be individually adapted or selected by a user. For this purpose, for example, the intensity of the visual adjustment or the contrast can be continuously or stepwise adjustable and thus preferably freely selected by the user.
    The controller may further include a memory having predefined housing colors. In this case, the controller may be designed to control the lighting means on the basis of the data detected by the sensors in accordance with a housing color assigned to one of these data. In this way, the computing power can be reduced, while at the same time the luminaire independently depending on the current environment from the predefined housing colors selected according to the detected environment color (predefined) housing color.
    The controller may also be designed such that the sensors detect the optical and / or structural features of the ambient region of the lamp in the off state of the lamp, preferably using the ambient light, or in the on state. The optical and / or structural features of the ambient region of the luminaire are (then) preferably detected during predetermined PWM (pulse width modulation) cycle-outs in order to achieve particularly accurate measurement results of the housing color to be set.
    The sensors are preferably arranged on or in relation to the lamp opposite side of the lamp housing, preferably on the outside of the lamp housing, and the surrounding area of the lamp, in particular a mounting region of the lamp, facing side of the lamp housing.
    According to a second aspect, the invention relates to a luminaire having a luminaire housing for receiving bulbs, at least one first illuminant for the primary light output, at least a second illuminant for illuminating the luminaire housing, a controller for driving the bulbs, and sensors for detecting optical and Structural features of an ambient region of the luminaire, in particular a mounting region of the luminaire, wherein the controller is designed to individually control at least the second illuminant such that the luminaire housing is illuminated on the basis of the data detected by the sensors to visually attach the luminaire housing to the Adjust the environment or match the surrounding area.
    According to a third aspect, the invention relates to a lighting environment, such as a room comprising a luminaire according to the invention and a defined surrounding area of the luminaire, wherein the luminaire is visually adapted to the surrounding area or is adapted to the surrounding area.
    According to a fourth aspect, the invention relates to a lighting system comprising at least two lights according to the invention, each with an interface, preferably a DALI (Digital Addressable Lightning Interface) interface, and a central control, in particular a DALI control, to (control technology) Connection to the one or more lights, for example in the context of a building automation.
    Further features, advantages and features of the invention will now be explained with reference to embodiments by means of the figures of the accompanying drawings.
    FIG. 2 shows a bottom view according to a first embodiment of the luminaire of FIG. 1; FIG. 4 shows a side sectional view of the luminaire according to FIG. 3, FIG. 5 shows a lateral sectional view of a luminaire according to another
    FIG. 6 shows a visual adaptation of a perspective view of a luminaire according to the invention in suspended mounting, FIG. 7 shows a visual adaptation of a perspective luminaire according to the invention in wall or ceiling mounting, and [0030 ] FIG. 8 shows the visual adaptation of a further perspective (ball) light according to the invention in suspended mounting.
    Figures 1 to 8 show different embodiments or views of a lamp according to the invention 1. The lamp 1 has a plurality of lamps 2 for light output. In this case, the luminous means 2 in particular comprise LEDs or OLEDs, particularly preferably white LEDs and / or RGB LEDs and the like. The light sources 2 are preferably at least partially designed such that they allow a light emission in a wide color spectrum.
    The luminaire 1 also has a luminaire housing 3, in which the luminous means 2 are accommodated.
    As shown for example in Figure 2, the lamps 2 may be arranged distributed in or on the lamp housing 3. For this purpose, the luminous means 2 can be unstructured or preferably structured, for example in the form of a matrix or a grid.
    It is also conceivable that the lighting means 2 have a first light source 20 for the primary light output (that is, for example, to emit white light or for illuminating a room) and at least a second light source 21 for illuminating the light housing 3, as in Figures 3 to 5 shown. The first lighting means 20 may then also comprise, for example, an incandescent lamp, a halogen lamp or a fluorescent lamp or the like; however, they preferably also include LEDs and the like.
    It is also conceivable, for example, for the first luminous means 20, as shown in FIG. 2, to be arranged in a center of the luminaire housing 3, for example in the form of a matrix or a grid, while the second luminous means, as in FIGS. 3 and 4, for example are arranged within the lamp housing frame 30. Also, for example, the lighting means 2 shown in FIG. 2 can be divided into (at least) two groups, with a first group of light sources 2, preferably arranged in the center of the grid, forming the first light sources 20, while those surrounding the first light source 20 are located in the center Group of lamps 2, the second light source 21 form. Depending on the activation of the lighting means 2, the number of the first lighting means 20 can then be increased or reduced, while the number of the second lighting means 21 is correspondingly reduced or enlarged.
    As shown particularly in FIGS. 4 and 5, the luminaire housing 3 may have a primary emission surface or emission region 31 for the primary emission of light. This primary radiating surface 31 is preferably associated with the first lighting means 20. Furthermore, the luminaire housing can then have a second emission surface or emission region 32 for illuminating the luminaire housing 3. The second emitting means 32 are preferably associated with the second lighting means 21.
    The primary radiating surface 31 may be formed by an opening 37 in the lamp housing 3 and preferably in the main emission direction H of the first light-emitting means 20 may be arranged in front of them. The primary radiating surface 31 can also be filled with a translucent, preferably transparent or opaque material which, in accordance with the design of the luminaire 1, is designed as a flat plate (see FIG. 6) or arched (compare FIGS. 7 and 8) or in any other way can be. The material of the first radiating surface 31 can have scattering particles and / or color conversion particles, in particular when LEDs are used as the first luminous means 20. The second radiating surface 32 may also be filled with a translucent, preferably opaque material or formed from such a material and also have scattering or color conversion particles, as described below.
    The primary radiation area 31 and the second radiation area 32 are preferably separated from each other by a reflector, wherein the reflector is designed and arranged to a directed radiation of the primary light output, as shown in Figure 5. Alternatively, it is also conceivable that the primary emission region 31 and the second emission region 32 are separated by a part of the luminaire housing frame 30, as shown in FIG. In this case, the second lighting means 21 are preferably within the lamp housing frame 30. At least the inside or the entire lamp housing 3 is formed opaque in the latter case and is preferably made of a plastic or metal, such as aluminum or the like. Particularly preferably, the inner side 35 of such a lamp housing 3 is preferably designed to be reflective or provided with a reflective layer.
    As shown in Figure 4, the lamp housing 3 may have openings 33; especially in a case where the lamp housing 3 is otherwise opaque. The light sources 2, preferably the secondary light sources 21, are associated with the openings 33 in such a way that they emit through the openings 33 to the outside. For this purpose, the openings 33 can be filled with a light-permeable material, in particular an opaque material, as already described above. Alternatively, however, it is also conceivable that the luminaire housing 3, as shown in Figure 5, at least partially made of a translucent, preferably opaque material. In this case, the light sources 2, preferably the secondary light sources 21, are associated with the areas 34 of translucent or opaque material such that they backlight these areas 34 from the inside. The openings 33 or light-permeable areas 34 form the second emission area 32.
    In particular, in lights 1 for suspended mounting, as shown in Figures 1, 6 and 8, and the rear side of the lamp housing 3, so the primary radiation area opposite side of the lamp housing 3, secondary radiating surfaces 32, for example in the form of openings 33 or (opaque) areas 34 have.
    The luminaire 1 also has sensors 5. The sensors 5 are designed such that they detect optical and / or structural features of an ambient region of the luminaire 1, in particular of a mounting region M of the luminaire 1. In the context of the invention, optical features are understood in particular to mean the color of the surrounding area, such as that of the mounting area M. The structural features include, in particular, the structure and the material of the surrounding area of the luminaire 1, in particular a mounting area M, such as a wall or a ceiling , For this purpose, the sensors can have, for example, color sensors. In particular, such color sensors may be so-called true-color sensors, which are well known and will not be further described here. In addition, it is alternatively or additionally also possible to use cameras as sensors.
    Especially with a suspended mounting of the lamp 1, as shown in Figures 1 and 6, the sensors 5 are preferably on or in a respect. Of the lamps 2, in particular the first lamp 20, opposite side of the lamp housing 3, Preference, an outer side 36 of the lamp housing 3 is arranged and further the surrounding area of the lamp 1, in particular an assembly area M of the lamp 1, facing. As shown in FIG. 8, the sensors 5 can also be arranged near the mounting region M at an end of a mounting device 6 of the luminaire 1 facing the mounting region M. In the case of a direct mounting of the luminaire 1 on the mounting area M (eg ceiling, wall, etc.), the sensors 5 are preferably arranged in a lateral area of the outside of the luminaire housing 3 and as close as possible to the mounting area M, as shown in FIG is.
    In summary, it is thus preferred that the sensors 5 are arranged so as to preferably a surrounding the lamp 1 area M, for example, a ceiling or wall, in the case of a suspended mounting so also directly behind or above the lamp 1 lying Area, to capture. As shown, for example, in FIGS. 7 and 8, the sensors 5 may be embedded in the luminaire housing 3, so that they essentially do not protrude out of the luminaire housing 3 and are thus 'hidden'.
    The lamp 1 also has a control for driving the light emitting means 2, wherein the controller is not shown explicitly in the figures. This can preferably be provided within the lamp housing 3 or be provided externally. The control function is described below: According to the invention, the controller is designed such that the light source 2 for light output is individually controlled on the basis of the data acquired by the sensors 5 in order to visually adapt the luminaire 1 to the surrounding area or to match it to the surrounding area , For this purpose, the controller is connected to the sensors 5 and the lighting means 2 and preferably has a processor (CPU) for processing the received sensor signals and corresponding output of control commands to the lighting means 2.
    In particular, in the case of the embodiments of Figures 3 to 5, the controller is preferably designed so as to individually control at least the second light source 21 so that the luminaire housing 3 is illuminated based on the data detected by the sensors 5 to the luminaire housing 3 visually to adapt to the surrounding area M or to match the surrounding area M. Consequently, the luminaire 1 is able to modify the light output with respect to its color in individual areas in such a way that the luminaire 1 or its luminaire housing 3 harmoniously adapts to the environment and thus fits into the environment. Due to the simple and flexible construction of the lamp 1, this can be used in a wide variety of ambient conditions (color, structure, material, etc.); this at always consistently good adaptation of the lamp housing 3 to these environments. The controller is thus configured to control the light source 2 for light emission in respective areas of the lamp housing 3 with respect to a defined color on the basis of the data of the sensors 5, so that the lamp 1 is virtually invisible against the background. For this purpose, the controller may preferably individually control the lighting means 2 on the basis of the data detected by the sensors 5 such that the luminaire housing 3 assumes the color of the surrounding area M at least in an outer edge region R. The visual adaptation of the luminaire 1 preferably extends from the edge (region) R of the luminaire housing 3 in the direction and preferably as far as the center Z thereof in the horizontal (ie in the drawing plane of FIGS. 2 and 3), the light adaptation to the center Z down preferably decreases continuously or preferably continuously attenuates. It is also conceivable that, in particular when using LEDs in grid arrangement selectively individual materials in color and structure can be displayed on the lamp housing 3. Furthermore, it is conceivable that the control is designed such that the degree of visual adjustment, that is, for example, the intensity of the visual adjustment or the contrast, is manually adjustable, preferably continuously or stepwise.
    In addition, it is conceivable that the lamp 1 or the controller has a memory (for example, RAM or ROM) are stored in the predefined housing colors. The controller can then be designed to control the lighting means 2 on the basis of the data detected by the sensors 5 in accordance with a housing color assigned to this data. In this way, computing power can be saved, while at the same time a fixed set of n (ne N) environments per housing color can be used and the lamp 1 independently, depending on the current environment and therefore measured by the sensors 5 data from the predefined Housing colors which selects the determined data corresponding housing color and controls the light source 2 accordingly.
    The controller can also be designed so that it detects the optical and / or structural features of the surrounding area M of the lamp 1 in the off state of the lamp 1, preferably using the ambient light or in the on state using the sensors 5. The optical and / or structural features of the surrounding area of the luminaire 1 can also be detected during predetermined PWM (pulse width modulation) cycle-outs in order to increase the accuracy of the measured data and thus the activation of the luminous means 2.
    The controller may further be designed to detect the data of the sensors 5 continuously or at predetermined intervals and to control the lamps 2 according to continuously or discontinuously. In the case of continuous detection, a continuous adaptation of the housing color in full operation would consequently be possible, so that also direct and indirect components of all the light sources in the room are continuously included in the housing color calculation of the controller. In this way, for example, a tunable white effect would be possible, i. the housing color would change accordingly over the day and in accordance with changing light conditions and the luminaire housing 3 thus constantly adapt to its environment.
    The controller may further be configured to also set or control the light output of the first luminous means 20 on the basis of the data detected by the sensors 5. For this purpose, the first luminous means 20 can, for example, have either white LEDs for warm-white or cool-white light (in which at least the color temperature can be set) or differently colored LEDs-preferably arranged in clusters-by means of which colors are reproduced in a broad color spectrum can.
    The invention further comprises a lighting environment, such as a room comprising a lamp 1 according to the invention and a defined surrounding area of the lamp 1, in particular a mounting area M such as a ceiling area or wall area in the immediate vicinity of the lamp 1, wherein the Luminaire 1 is visually adapted to the surrounding area M is / is or the environment area M is / is adjusted.
    Furthermore, the invention comprises a lighting system with lights 1 according to the invention, each having an interface, preferably a DALI interface. The lighting system further comprises a central control, preferably a DALI control, which is connected to all lights 1 of the lighting system.
    In the following, a method for visual adaptation of a lamp 1 to a surrounding area of the lamp 1, in particular a mounting area M of the lamp 1, such as a wall or ceiling, is described.
    First, a lamp 1 comprising a plurality of light emitting means 2 for emitting light and a lamp housing 3 for receiving the light emitting means 2 and a controller for driving the light emitting means 2 and sensors 5 are provided in a range, preferably mounted in a mounting area. The sensors 5-preferably color sensors and / or cameras-detect optical and / or structural features of the surrounding area of the luminaire 1, in particular of the mounting area M of the luminaire 1.
    The light-emitting means 2 are then individually controlled by the controller on the basis of the data detected by the sensors 5, so that the light is visually adapted to the surrounding area, for example by taking the color of the surrounding area. The visual adaptation of the lamp 1 takes place at least in an outer edge region R of the lamp housing 3 and preferably extends from the edge R of the lamp housing 3 in the direction and preferably to the center Z (in which preferably the first lighting means 20 are provided). The light adaptation decreases or weakens towards the center Z, preferably continuously. For this purpose, the first luminous means 20 can either be color-matched to the surrounding area or, when using white light sources, emit at least with different color temperature according to warm white to cold white. The housing color can also be selected from a memory with predefined housing colors; This is done on the basis of the data detected by the sensors 5, based on which the light emitting means 2 according to one of these data associated housing color, which is stored in the memory predefined, are controlled.
    The triggering of the measurement of the sensors 5 or adjustment of the light output or light color of the lighting means 2 can be carried out either automatically on site or centrally (for example by means of DALI). In the latter case, it is possible, for example, that detected by sensors 5 data, for example, the determination of yellowing of a blanket or other change in the environment to a central controller, such as a DALI control system of a light system, are transmitted and thus directly into the calculation of the housing color received.
    For further possible method steps, reference is made in full to the preceding description, in particular with respect to the controller, which are to be understood in the same way as method steps and as such are therefore also encompassed by the invention.
    The invention is not limited to the previously described embodiments, as long as it is encompassed by the subject matter of the following claims. In particular, the invention is not limited to a particular arrangement, size or type of the lamps 2, as well as the invention is not limited to a specific size, shape or materials of the lamp housing 3.
    权利要求:
    Claims (20)
    [1]
    claims
    1. luminaire (1) comprising: a plurality of luminous means (2) for emitting light, a luminaire housing (3) for receiving the luminous means (2), a controller for driving the luminous means (2), and sensors (5) for detecting optical and / or Structural features of an ambient area of the lamp (1), in particular a mounting area (M) of the lamp (1), wherein the controller is designed such that the light emitting means (2) on the basis of the data detected by the sensors (5) individually to control the light (1) visually to the surrounding area (M).
    [2]
    2. Lamp (1) according to claim 1, wherein the lighting means (2) are arranged distributed in or on the lamp housing (3), preferably in the form of a matrix or a grid.
    [3]
    3. Lamp (1) according to claim 1 or 2, wherein the lighting means (2) at least a first light source (20) for the primary light output and at least a second light source (21) for illuminating the lamp housing (3), wherein the controller designed in such a way is, at least the second illuminant (21) to control individually such that the luminaire housing (3) is illuminated based on the data detected by the sensors (5) to visually adapt the luminaire housing (3) to the surrounding area.
    [4]
    The lamp (1) according to claim 3, wherein the controller is configured to adjust the light output of the first lighting means (20) based on the data detected by the sensors (5).
    [5]
    5. Lamp (1) according to any one of claims 3 or 4, wherein the lamp housing (3) has a primary emission surface (31) for the primary light output, which is associated with the first lighting means (20), and a second emitting surface (32) for illumination the luminaire housing (3), to which the second luminous means (21) is assigned, wherein the primary radiating surface (31) and the second radiating surface (32) are preferably separated from one another by a reflector (4) which leads to a directed emission of the primary light output is designed and arranged.
    [6]
    6. Lamp (1) according to one of the preceding claims, wherein the lamp housing (3) has openings (33) and / or at least partially made of a translucent, preferably opaque material (34), wherein the lighting means (2), preferably the second lighting means (21), the openings (33) or the areas (34) are made of translucent material such that they emit through the openings (33) to the outside or the areas (34) backlit from inside, wherein the openings (33) are preferably filled with a translucent, particularly preferably opaque material.
    [7]
    7. Lamp (1) according to any one of the preceding claims, wherein the lighting means (2) comprise LEDs or OLEDs, preferably white LEDs and / or RGB LEDs and the like, which are particularly preferably arranged in clusters.
    [8]
    8. Light (1) according to one of the preceding claims, wherein the sensors (5) color sensors for detecting optical features, in particular the color, and / or cameras for detecting optical and / or structural features of the surrounding area of the lamp (1), in particular one Assembly area (M), such as a wall o the ceiling have.
    [9]
    9. lamp (1) according to any one of the preceding claims, wherein the optical features in particular the color, the structural features, in particular the structure and the material of the surrounding area of the lamp (1), in particular a mounting area (M), such as a wall or ceiling , include.
    [10]
    10. Lamp (1) according to one of the preceding claims, wherein the controller is designed to detect the data of the sensors (5) continuously or at predetermined intervals and to control the lighting means (2) correspondingly continuously or discontinuously.
    [11]
    11. Lamp (1) according to any one of the preceding claims, wherein the controller is designed such that the lighting means (2) for emitting light in the respective areas of the lamp housing (3) with respect to a defined color on the basis of the data of the sensors (5) to control.
    [12]
    12. Light (1) according to any one of the preceding claims, wherein the control of the light-emitting means (2) based on the data detected by the sensors (5) individually so that the lamp housing (3) at least in an outer edge region (R) the Color of the surrounding area (M) assumes.
    [13]
    13. Lamp (1) according to one of the preceding claims, wherein the visual adaptation of the lamp (1) from the edge (R) of the lamp housing (3) in the direction and preferably extends to the center (Z), wherein the light adaptation to the center (Z) preferably continuously decreases or preferably attenuates continuously.
    [14]
    14, light (1) according to one of the preceding claims, wherein the controller is designed such that the degree of visual adjustment is manually adjustable, for example, the intensity of the visual adjustment or the contrast is infinitely or gradually adjustable.
    [15]
    15. Lamp (1) according to any one of the preceding claims, wherein the controller has a memory with predefined housing colors and is designed to control the lighting means (2) on the basis of the sensors (5) detected data corresponding to one of these data associated housing color.
    [16]
    16. Luminaire (1) according to any one of the preceding claims, wherein the controller is designed such that the sensors (5) the optical and / or structural features of the surrounding area (M) of the lamp (1) in the off state of the lamp ( 1) using the ambient light or in the on state, wherein the optical and / or structural features of the surrounding area of the luminaire (1) are preferably detected during predetermined PWM-Auszyklen.
    [17]
    17. Luminaire (1) according to one of the preceding claims, wherein the sensors (5) on or in a respect. The lighting means (2) opposite side of the lamp housing (3), preferably an outer side (36) of the lamp housing (3), and the surrounding area of the lamp (1), in particular a mounting region (M) of the lamp (1), facing side of the lamp housing (3) are arranged.
    [18]
    18. luminaire (1) comprising: a luminaire housing (3) for accommodating light sources (2, 20, 21), at least one first luminous means (20) for primary light output, at least one second luminous means (21) for illuminating the luminaire housing (3) a control for driving the lighting means (2), and sensors (5) for detecting optical and / or structural features of an ambient region of the light (1), in particular a mounting region (M) of the light (1), wherein the control is designed to individually control at least the second lighting means (21) in such a way that the luminaire housing (3) is illuminated on the basis of the data acquired by the sensors (5) in order to visually adapt the luminaire housing (3) to the surrounding area (M).
    [19]
    19. Lighting environment, such as a room, comprising a lamp (1) according to one of claims 1 to 18 and a defined surrounding area (M) of the lamp (1), wherein the lamp (1) is visually adapted to the surrounding area (M) or the environment is equalized.
    [20]
    20. Light system comprising at least two lights (1) according to one of claims 1 to 18, which each further comprise an interface, preferably a DALI interface, and a central controller, in particular a DALI controller, for connection to and / or Lights (1) via their interface.
    类似技术:
    公开号 | 公开日 | 专利标题
    EP2893775B1|2021-03-31|Light fitting
    EP1492701B1|2005-11-23|Aircraft window case that can be artificially illuminated in an indirect manner
    DE102010022477A1|2011-12-08|Lamp for use in daylight ceiling for illuminating surface e.g. floor surface of building, has organic LED attached to sensor that measures environment value of lamp, and controller for changing parameter of lighting current based on value
    AT12104U1|2011-10-15|LIGHTING FOR A CEILING LIGHT OF A TUNNEL
    DE102017115274A1|2018-01-18|ILLUMINATION DEVICE
    EP2418420A2|2012-02-15|Illumination device
    AT16754U1|2020-07-15|Lighting device
    DE202011051548U1|2013-01-08|Lighting device with natural and artificial light
    EP2454521B1|2013-05-29|Electric lamp
    DE102010011408A1|2011-09-15|Device with a lamp and method for its control
    DE102014212860A1|2015-01-08|Method for the control of a luminaire without touch by gesture control
    EP3042120B1|2017-03-29|Arrangement for emitting light
    EP2886950B1|2017-07-26|Light
    DE10056745B4|2006-06-29|Luminaire with colored indirect light component and method for its control
    DE102008017271B4|2018-09-13|Luminaire with two light sources in a recess of an at least partially photoconductive support, use of this lamp as a pendant, wall or floor lamp and lighting device for such a lamp
    DE102017104665A1|2017-09-07|Control device, lighting system and mobile object
    DE202013101827U1|2014-07-29|Lighting arrangement with elongated luminaire housing
    DE202009009051U1|2009-10-01|lamp
    EP2644987B1|2018-10-17|Lighting device and lighting method
    DE102013225889A1|2015-02-12|panel light
    EP2058582A1|2009-05-13|LED-lamp
    WO2011107479A1|2011-09-09|Luminaire comprising light-orienting elements
    EP3133334B1|2019-09-11|Modular lighting system having communication means
    DE10346506B4|2007-11-22|Regulated light
    DE202016000811U1|2016-04-25|Leuchtbild
    同族专利:
    公开号 | 公开日
    EP2893775B1|2021-03-31|
    EP2893775A1|2015-07-15|
    WO2014037359A1|2014-03-13|
    DE202012103365U1|2013-12-05|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    JP2004501496A|2000-06-23|2004-01-15|コーニンクレッカ フィリップス エレクトロニクス エヌ ヴィ|Illumination control device and illumination control method using CCD sensor|
    EP1551178A1|2003-12-18|2005-07-06|Koninklijke Philips Electronics N.V.|Supplementary visual display system|
    JP5235075B2|2004-11-30|2013-07-10|ティーピービジョンホールディングビーヴィ|Display system|
    WO2008146232A1|2007-05-29|2008-12-04|Koninklijke Philips Electronics N.V.|Lighting device|
    DE102008061777A1|2008-12-11|2010-06-17|Osram Gesellschaft mit beschränkter Haftung|Setting an RGB light module|
    EP2264560A1|2009-06-02|2010-12-22|Koninklijke Philips Electronics N.V.|Appliance with luminous housing control depending on environment color|CH709254A1|2014-02-03|2015-08-14|Regent Beleuchtungskörper Ag|Lamp.|
    DE102014208196A1|2014-04-30|2015-11-05|Zumtobel Lighting Gmbh|Method for operating a luminaire with a plurality of luminous means arranged behind one another|
    DE102014013148A1|2014-09-04|2016-03-10|Eaton Protection Systems Ip Gmbh & Co. Kg|Luminaire and method for detecting presence by means of such|
    NL2013445B1|2014-09-09|2016-09-28|Hak4T Facilities B V|Lighting fixture for supporting natural light, assembly of lighting fixtures and method for operating such a lighting fixture.|
    DE102014013467A1|2014-09-17|2016-03-17|Haworth Gmbh|lamp|
    DE202015101842U1|2015-04-15|2016-07-18|Zumtobel Lighting Gmbh|lighting device|
    CH711000A1|2015-04-28|2016-10-31|Iart Lab Gmbh|A lighting device and a method for controlling a lighting device.|
    CN106545804A|2016-08-30|2017-03-29|吕国良|A kind of double lamp body LED Line lamps of automatic sensing|
    CN106545806A|2016-08-30|2017-03-29|韦荣花|A kind of LED Line lamps of automatic sensing|
    CN106545808A|2016-08-30|2017-03-29|吕国良|A kind of LED Line lamps of the double lamp bodies of double control|
    法律状态:
    2018-05-15| MM01| Lapse because of not paying annual fees|Effective date: 20170930 |
    优先权:
    申请号 | 申请日 | 专利标题
    DE202012103365U|DE202012103365U1|2012-09-04|2012-09-04|lamp|
    PCT/EP2013/068211|WO2014037359A1|2012-09-04|2013-09-04|Light fitting|
    [返回顶部]