Patent Grant
7311423
The present invention is directed to a luminance, and more particularly to a luminance having a light source comprising light-emitting diodes (LEDs).
Conventional luminaires used in lighting systems are generally classified as direct or indirect lighting fixtures. Direct lighting shines directly on a surface, such as a desktop or work surface, without being reflected from another surface. Indirect lighting is ambient lighting that is reflected from another surface such as a ceiling before impinging on the lighted area or surface. More recently, hybrid type fixtures have been developed that include both direct and indirect lighting characteristics. Such lights may be specified with the percentage of direct/indirect light characteristics, for example, 65%/35%, where 65% is the portion of indirect and 35% the portion of direct, of the total light emitted by the fixture. These ratios are generally achieved using fluorescent lighting tubes that emit light equally in all directions.
The light distribution ratio between direct and indirect is accomplished through the geometry of the fixture in which the fluorescent tubes are mounted. Diffusers and parabolic reflectors are positioned below the fluorescent tubes to reflect portions of the downwardly directed light, which is then reflected to the ceiling. Ceilings normally have an irregular surface that further diffuses and scatters the light, rather than directly reflecting the light. The percentage of indirect to direct light may be designed with more or less direct light. Once the light distribution profile of a luminance is set in the manufacturing stage it is not capable of being varied without disassembling and rebuilding the entire fixture with different components.
U.S. Pat. No. 6,789,914 discloses a luminance that provides both direct and indirect lighting through elongated reflecting members and a main reflector for delivering a uniform illumination. Each reflecting member is a louver extending along the luminance sides and the main reflector extends between the luminance sides. The luminance reflects light directly and indirectly to furnish a uniform illumination without undesirable hot spots and glare.
U.S. Pat. No. 6,843,586 is directed to a luminance having a concave reflector suspended from the ceiling. The reflector is positioned directly in the path of the light. The light is shielded from the reflector and diffused by being reflected onto the walls and ceiling. A reflector dome may be positioned above the light source and opposite the pendant reflector. The luminance redirects diffused light reflected by the pendant reflector while shielding a viewer from the intense light present at its point source.
U.S. Pat. No. 6,705,742 is directed to a system for directing light from a luminance. The luminance includes a source of light removably positionable in the luminance, a first reflecting device installed in the luminance for transmitting substantially indirect lighting from the luminance, a second reflecting device mounted in the luminance for transmitting substantially direct lighting from the luminance, and a fascia engageable with the luminance for emitting substantially luminous direct lighting. The luminance is useful for providing combinations and permutations of direct and indirect lighting.
Referring first to
A portion of the light rays 20 emitted from the light source 12 are also directed toward the louver portion 14, as indicated by arrows 30 and 30′. The light rays 20 in the downward direction impinge on the louver portion 14 at various angles. The downward light rays 30, 30′ thus provide the direct component of the light distribution, and an additional portion of the indirect light distribution. Yet another portion of the light rays 20 are emitted horizontally, and do not impinge on either the diffuser portion 16 or the louver portion 14. This horizontally emitted portion of the light rays 20 accounts for ambient light in the general area.
The luminance shown in
LED light sources offer several benefits over fluorescent systems, such as reliability, longer life, reduced heat dissipation, and reduced energy consumption, with little or no added weight. High voltage ballasts that are required to start the fluorescent tubes are not needed for LED light sources.
A light source made from LEDs is highly directional, focusing most light in one orientation as opposed to the continuous radial distribution of light around a fluorescent tube. The combination of mounting, location, filtering and distribution of white LEDs in a multi-LED design is critical to achieving an aesthetic light output. The directional nature of the diodes themselves creates a situation where a slight angular change in the installation can significantly change the appearance of lighted areas. As a result, the primary usage of LED light sources to date has been for commercial signage and architectural accent lighting, rather than general-purpose lighting. LEDs offer many advantages, including low power consumption, low heat dissipation and much longer life compared to traditional fluorescent and incandescent bulbs.
Therefore what is needed is a luminance that can have variable ratios of direct/indirect lighting without the need to change the geometry of the luminance.
The present invention is directed to a rotatable directional lighting apparatus comprising a rigid strip having a first end and a second end opposite said first end portion. The rigid strip also has a first surface and a second surface opposite said first surface, the first and second surfaces extending between the first and second end. A first rotary support member and a second rotary support member are connected to the strip first and second ends, respectively. A plurality of electrical lighting elements is mounted on the first surface. The lighting elements are configured in at least one electrical circuit. The electrical lighting elements are preferably light emitting diodes (LEDs). Also, the first rotary support member includes an electrical actuator for automatically positioning the angle of rotation of the rigid strip.
In another aspect of the invention, there is a lighting fixture apparatus comprising a frame portion, a louver portion and a diffuser lens. The louver portion includes a baffle system for passing unobstructed at least a portion of light rays impinging thereon as direct lighting. The diffuser lens includes a surface for diffusing light rays impinging thereupon as indirect lighting. At least one directional lighting apparatus is attached to and supported by the frame portion, with the directional lighting apparatus being disposed between the louver portion and the diffuser portion.
The uni-directional lighting apparatus comprises a rigid strip having a first end and a second end opposite said first end. The rigid strip also has a first surface and a second surface opposite said second surface. A first rotary support member and a second rotary support member are connected to the strip portion first and second ends, respectively. A plurality of electrical lighting elements is mounted on the first surface. The lighting elements are configured in at least one electrical circuit. The electrical lighting elements are preferably light emitting diodes (LEDs). Also, the first rotary support member includes an electrical actuator for positioning the angle of rotation of the rigid strip.
One advantage of the present invention is the ability to vary the ratio of direct to indirect light emitted by a luminance.
Another advantage is the ability to change the ratio of direct to indirect light emitted by a luminance by rotating the light source, without the need to modify the geometry of the luminance.
Another advantage is the ability to provide a luminance with standard or non-standard ratio of direct to indirect light distribution.
A further advantage of the present invention is the elimination of high voltage ballasts.
Yet another advantage of the present invention is the ability to remotely control the ration of direct to indirect light emitted from luminaries after installation of the fixture in a ceiling or grid pattern.
Other features and advantages of the present invention will be apparent from the following more detailed description of the preferred embodiment, taken in conjunction with the accompanying drawings which illustrate, by way of example, the principles of the invention.
Referring to
The LED assembly may be fixed, however additional advantages are achieved when its position can be adjusted. A portion of the LED assemblies 100 is directed toward the ceiling 26 as indicated by arrows 28 and 28′. The upward light rays 20 penetrate the diffuser lens 16 and are spread or scattered by the diffuser lens 16 into a generally random pattern in the direction of the ceiling 26. The scattered light rays 20′ are then reflected from the ceiling 26 toward the area below the luminance 10, to provide the indirect component of the light distribution.
A portion of the LED assemblies 100 are also directed toward the louver portion 14, as indicated by arrows 30 and 30′. The LED assemblies 100 in the downward direction impinge on the louver portion 14 at various angles, with a portion of the rays passing unobstructed through the louver portion 14 as direct lighting and a portion of the rays being reflected, diffused or refracted by the louver portion 14 as indirect lighting, depending on the arrangement of the baffle portion 22. The downward light rays 30, 30′ thus provide the direct component of the light distribution, and an additional portion of the indirect light distribution of the luminance 10. Yet another portion of the LED assemblies 100 can be directed intermediately of the vertical plane, and impinge on reflector plates 24, 24′ connected to louver portion 14. This horizontally emitted portion of the light rays 20 accounts for ambient light in the general area. The portion of LED assemblies 100 directed toward the ceiling 26, toward the louver 14 or toward the reflector plates 24, 24′ can be varied as desired.
The LED assemblies 100 may be used in practically any configuration of luminance that uses fluorescent tubes, for suspension or mounting below a reflective ceiling and the invention is not limited to the configuration shown in the drawings, as will be readily apparent to those skilled in the art.
Referring next to
The LEDs 108 may be arranged in one or more rows, e.g., rows of two as shown in
The LED assemblies 100 are mounted in the luminance 10 instead of standard fluorescent tubes. One of the rotating assemblies 104 attached to the strip includes an electrical actuator (not shown). Preferably, each electrical actuator is a low voltage DC type actuator. The end of the LED assembly 100 opposite the electrically actuated rotating assembly 104 is supported in a non-actuated rotating assembly 104 that allows the respective LED assembly to rotate about a longitudinal axis in response to the position of the actuated assembly 104. The electrical actuator for the rotating assembly 104 is connected to a controller (not shown) that may be provided on each luminance 10; alternately, the actuator may be connected to a central controller located remote from the luminance 10. Remote control of the actuators may also be performed using infrared (IR) or radio frequency (RF) type controls.
Each LED assembly 100 turns independently of the other LED assembly or assemblies 100 mounted in the luminance 10, such that the LED assemblies 100 may be positioned at various angles relative to each other—e.g., two strips facing up and two stips facing down—to provide varying patterns of direct and indirect lighting. In an alternate embodiment (not shown), a single drive motor may be synchronously interconnected through a gear arrangement to rotating assemblies 104 such that some or all of the assemblies are driven simultaneously rather than independently.
It will be understood that in its simplest embodiment each LED assembly is controlled by a mechanical actuator that can control the ratio of direct/indirect lighting of the luminance, and LEDs on the assembly connected in a single circuit. It will be further understood that any one row having a plurality of LEDs may have a plurality of individual circuit connections (not shown), and a row of LEDs can be wired such that a plurality of electrical circuits can control one or more LEDs in the row. By selectively switching LED circuits in this manner, the intensity of light from LEDs in any one row may be varied if desired.
Each rotating assembly 104 is retentively positionable through at least one actuator 104. The rotating assembly 104 can be set at any angle from 0° to 360°, but preferably 0° to 180°, to provide a continuously variable ratio of direct and indirect lighting. If an LED assembly 100 is set at an angle between the horizontal plane and the vertical plane, the rotating assembly maintains the setting until the angle is readjusted.
Referring next to
Preferably, the LED assemblies 100 are wired to receive a DC voltage—e.g., 6V, 12V, 18V or 24V—from a ceiling grid with a power supply and wiring connected thereto. One such ceiling grid arrangement is described in detail in U.S. patent application Ser. No. 11/127,853, assigned to Armstrong World Industries, Inc., of Lancaster, Pa, which patent application is hereby incorporated by reference. Alternately, the LED assemblies may be connected to accommodate voltages that are standard in commercial, residential and industrial lighting distribution systems—e.g., 110V, 240V, 460V—to permit them to easily be retrofitted in place of traditional fluorescent and incandescent luminaires.
Other configurations of luminaires may include a mixture of rotating LED assemblies 100 and fixed, or non-rotating, LED assemblies 100, for example, where a certain minimum level of direct lighting is desired, or a minimum level of indirect lighting is desired. In such a case, one or more non-rotating LED 100 assemblies may be arranged to face downward to the lighted workspace in the case of a minimum fixed direct lighting level, or upward to the ceiling in the case of minimum fixed indirect lighting. The luminance 10 would include one or more rotating LED assemblies 100 to increase the direct or indirect lighting above the minimum fixed level.
While the invention has been described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the invention without departing from the essential scope thereof. Therefore, it is intended that the invention not be limited to the particular embodiment disclosed as the best mode contemplated for carrying out this invention, but that the invention will include all embodiments falling within the scope of the appended claims.
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