This invention relates generally to canopy luminaires and more particularly to canopy luminaires adapted to direct light in a desired direction.
Luminaires are used in many commercial and consumer venues to illuminate particular areas of a site, such as lighting for a service station, storefront or restaurant, and are typically mounted on or within a support structure such as a ceiling, canopy structure or building exterior.
Luminaires of currently existing designs are typically mounted on their support structures either by direct attachment to the structure or by creating an opening and installing the recessed luminaire into the opening. A typical drawback associated with many existing luminaires is that the lamp is mounted in a fixed position on or within the support structure, thereby prohibiting redirection of the light emanating from the lamp toward specific, desired areas below. Although lenses can be used to direct the light toward a particular area and focus the light output downward, a substantial portion of the luminous output of the lamp is nevertheless emitted in other directions.
Some existing luminaires permit movement of the luminaire body to direct the light output, most notably track lighting. However, such existing luminaires are not designed to withstand outside environments, such as weather and insects. Further, many have limitations in the rotational range of the lamps and cannot be easily locked into place. Still further, recent environmental regulations such as Title 24 in California, which went into effect in October of 2005, require a canopy luminaire to have a flat lens and not protrude below the level of the canopy.
One other drawback associated with existing luminaires, again relating to the difficulty in directing the light output toward the intended area, involves the need for using a larger lamp, such as a high intensity discharge (HID) lamp, to provide the desired level of lighting. As the lens cannot efficiently direct the high intensity light to specific areas, much of the light is scattered toward unintended local and distant destinations. This scattering results in light pollution issues ranging from the disturbance of neighbors to interference of night sky viewing.
Thus, there is a substantial need for a luminaire that may be easily and quickly adjusted to direct light toward a particular target area without scattering light to unintended areas. There is also a need for an adjustable canopy luminaire in which the lamp does not protrude below the canopy. Further, there is a significant need for a luminaire that is capable of using a smaller lamp and consuming less electricity in its operation while providing the same degree of illumination.
The present invention provides a directional canopy luminaire that overcomes the drawbacks associated with currently existing luminaires. One aspect of the directional canopy luminaire of the present invention comprises an outer housing having an aperture; a directional support rotatably mounted within the outer housing; an inner support pivotally affixed to the directional support; and a light supporting means affixed to the inner support and configured to support a replaceable lamp that is electrically connectable to an electric power source, wherein the light supporting means is operable to aim light emitted from the replaceable lamp in any desired direction through the aperture of the outer housing.
Another aspect of the present invention is a directional canopy luminaire comprising an outer housing having an aperture; an inner support including a socket end adapted to hold a lamp socket that is electrically connected to a power source, and an open end adapted to receive a reflector that surrounds a replaceable lamp received in the lamp socket; and a directional support rotatably mounted on a vertical axis within the outer housing and adapted to pivotally affix the inner support on a horizontal axis within the outer housing, wherein the directional support and the inner support cooperate to permit light emitted from the replaceable lamp to be aimed in any desired direction through the aperture.
Another aspect of the present invention is a directional canopy luminaire comprising an outer housing having an aperture and configured to be secured to a canopy, an inner support for a light supporting means, the light supporting means including a replaceable lamp electrically connectable to an electric power source; and a directional support rotatably mounted on a vertical axis within the outer housing and adapted to pivotally affix the inner support on a horizontal axis within the outer housing, wherein the luminaire is operable to aim light emitted from the replaceable lamp in any desired direction through the aperture of the outer housing. The directional support is typically adapted to be rotatably mounted within the outer housing and can include a first and a second side arm at its lower end to pivotally affix the inner support about the horizontal axis within the outer housing.
The outer housing of the various aspects of the invention typically includes a body having an upper portion, a neck extending upwardly from the upper portion, at least one external securing member to secure the outer housing to the canopy, a base defining the aperture, and a mounting means situated within the outer housing proximate the upper portion (i.e. on the inside of the outer housing, between the neck and the body) that is adapted to rotatably mount the directional support. A cover for the outer housing can be hingedly connected to the base, and comprise a cover lens extending over the aperture.
The light supporting means of the various aspects of the invention can include any means that cooperates with a replaceable lamp to produce light, so that the luminaire can preferably function to aim the emitted light through the aperture of the outer housing. The light supporting means typically includes a lamp socket electrically connected to the power source, and, in one embodiment, a reflector that surrounds the replaceable lamp and reflects incident light from the lamp outwardly through the aperture of the outer housing. The reflector typically includes a reflective dome having an inner reflective surface, a lower rim defining a light-emitting opening and an upper rim defining a hole for the replaceable lamp to pass through to the lamp socket. The inner reflective surface reflects incident light through the light-emitting opening of the dome. One embodiment of the reflector can include a lower rim with at least one spring connector configured to removably secure the reflector within an inner support that fully encloses the reflector. This fully-encircling inner support is also known herein as an inner housing.
A typical embodiment provides a luminaire that can be easily and quickly adjusted to direct light toward a particular target area without scattering light to unintended areas, and houses a lamp that does not protrude below the ceiling of the canopy. The adjustable canopy luminaire can use a smaller lamp and consume less electricity in its operation while providing the same degree of illumination to a target location as does a larger lamp size in a conventional luminaire.
The nature and advantages of the present invention will be more fully appreciated from the following drawings, detailed description, and appending claims.
The directional canopy luminaire 10 depicted in
As will be described in more detail below, a rotational adjustment connector 72 rotatably attaches the upper end of the directional support 18 to a mounting means 70 within the outer housing 12, so that the directional support 18 is rotatable about an axis AA. Pivotal adjustment connectors 82, 84 pivotally attach the reflector 30 and the inner support 14 to the directional support 18, so that the reflector 30 and the inner support 14 are pivotable about an axis BB. The pivotal adjustment connectors 82, 84, in the form of threaded screws, pass through holes proximate the distal end of the directional support 18 and are threadably attached to the open end 28 of the inner support 14, and through openings near the outer rim of the reflector 30. The inner support 14 is illustrated in
The luminaire 10 of the present invention is operable to aim light in any desired direction through the aperture 52 of the outer housing 12. In
The directional support 18 as illustrated in
As further illustrated in
The lower rim 42 of the reflector 30 of
As indicated above, the embodiment of the inner support 14 illustrated in
In practice, the directional support and the inner support cooperate to permit light to be aimed in any desired direction through the aperture of the outer housing. Thus, a light beam originating from the lamp of the luminaire can be adjusted as desired, both on a vertical plane and along a horizontal vector. For example, the rotational adjustment connector 72 permits the directional support 18 to be rotated from within a 360° rotation about vertical axis AA within the outer housing, thereby allowing the horizontal vector of the light to be aimed radially outwardly in any desired direction.
Similarly, the pivotal adjustment connectors 82, 84 permit the inner support and associated light supporting means to pivot along a vertical plan about horizontal axis BB within the outer housing. The inner support 15 is free to be pivoted about horizontal axis BB typically from between about 0° to about 60° from nadir (i.e., from true vertical), more typically from between about 0° to about 40° from nadir, thereby allowing light to be aimed in a desired vertical angle through the aperture 52 of the outer housing 12. When the desired vertical alignment has been achieved, then the inner support 15 can be secured into place by tightening the pivotal adjustment connectors 82, 84 through side arms 78, 80 and into bolt holes 86, 88.
The directional support of the various aspects of the invention is typically radially rotatable within the outer housing, and light originating from the inner support is typically vertically pivotable. That is, typically the directional support is able to rotate within a 360° rotation on a vertical axis within the outer housing. Rotation of more than a full 360° turn is typically not permitted or possible, due to potential tangling of electrical wires 40A, 40B that exit the lamp socket and proceed to the electrical power source 22. Similarly, typically the inner support pivots from about 0° (i.e. pointing straight down) to about 60° from nadir on a horizontal axis within the outer housing. In a preferred embodiment, the inner support pivots from 0° to about 40° from nadir The directional support and the inner support thus can cooperate to permit light from the lamp or light supporting means to be aimed in any desired radial direction and along any vertical angle below the level of the aperture of the outer housing.
The rotational range of the lamp within the luminaire allows the light to be aimed in any desired direction beneath the canopy, to efficiently direct the high intensity light to the intended display item(s). For example, since the aperture of the outer housing is typically flush with the lower portion of the canopy it is mounted in, and the light from the lamp will target a display item below the canopy, then the light will typically be required to be aimed along an angle from about 0° (straight down) up to about 60° from nadir. Thus, the luminaire of the present invention can direct light to a display item located in any radial direction, from directly below the luminaire out to any angle from about 0° to about 60°. After the direction of light is properly positioned, the lamp direction can then be easily locked into place.
The invention also relates to a means for aligning the direction of the light beam emitted from the aperture of the outer housing onto an outside surface. As a non-limiting example, a battery-powered visible light laser device can comprise a visible light laser attached and secured into a position normal to the base of a suction cup. The device can be placed on the distal end of the lamp along the central axis of the lamp, corresponding to the center of the pattern of light emitted from the reflector. The laser beam can then be aimed at the desired outside surface, such as a display item, representing the pattern of light that would emanate from the light source. When the desired position of the lamp has been determined by use of the laser guidance (i.e., by directing the laser light onto the desired outside surface), then the adjustment connectors for the directional support (if any) and the inner support (which determine the vertical angle of the beam) can be optionally locked into place. The suction cup end of the laser device can then be removed from the lamp, and the luminaire is ready for use. This means of aligning the light beam coming from the luminaire, which employs a laser beam, is advantageous for aligning the beam direction during the daytime, thus avoiding the need to wait for darkness in order to align the luminaire to shine upon the desired display.
The invention also relates to a method for positioning the emitted light from a directional luminaire onto an outside surface, comprising the steps of: 1) providing a directional luminaire having a lamp and means for directing the emitted light from the lamp in a principle direction; 2) providing a visible light laser device comprising a visible light laser, a means for attaching the device to a substantially planar surface of the luminaire, and a means for aligning the emitted laser light in a direction normal to the planar surface; 3) securing the visible light laser device to the planar surface, typically the distal end of the lamp, wherein line of visible laser light is aligned along the center of the pattern of light emitted from the reflector by the lamp; 4) positioning the directing means whereby the line of visible laser light alights upon the outside surface; 5) optionally securing the directing means into such position; and 6) removing the visible light laser device from the planar surface.
The luminaire of the present invention is designed to withstand outside environments and is typically constructed of durable materials such as aluminum, steel, fiberglass, plastic, or the like. For example, the housing is preferably manufactured from die cast aluminum that provides a light but strong construction, and that readily dissipates heat to prolong component life. The cover, internal housing, directional support, spring clips, etc. can be manufactured from galvanized or stainless steel, tempered aluminum, plastic, or other material. The reflector can be manufactured from specular aluminum; however, any reflective material may be used.
While the present invention has been illustrated by the description of embodiments and examples thereof, it is not intended to restrict or in any way limit the scope of the appended claims to such detail. Additional advantages and modifications will be readily apparent to those skilled in the art. Accordingly, departures may be made from such details without departing from the scope or spirit of the invention.
The present application claims the benefit of co-pending U.S. provisional patent application 60/753,873, filed Dec. 23, 2005.
Number | Date | Country | |
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60753873 | Dec 2005 | US |