Patent Grant
7891835
The invention relates generally to the field of lighting systems and, more particularly, to apparatus for utilizing LED light sources for illuminating areas with predefined patterns of light intensity.
There is a continuing need for lighting apparatus which is low-cost and energy efficient. LEDs (light-emitting diodes) provide light sources which are energy efficient, and advances in LED technology are providing even greater efficiencies over time.
Some of the newer applications for LED-based lighting systems are roadway and parking lot lighting in which there are desired performance and light-distribution characteristics. More specifically, it is desirable that certain regions generally beneath a light fixture be illuminated, while certain neighboring regions are essentially non-illuminated. Along roadways and in parking lots, there is a need to be able to direct light in a particular preferential lateral direction (e.g., to illuminate a roadway) while avoiding so-called “trespass light” in an opposite lateral direction (a non-preferential lateral direction), e.g., toward roadside houses.
The importance of avoiding trespass light (or the like) is such that in some cases sacrifices are made in lighting efficiency, by virtue of allowing absorption of tight by shielding members. It would be highly desirable to provide a high-efficiency LED lighting system for roadways, parking lots and the like that avoids trespass light without significant efficiency losses.
It would be further desirable to provide a lighting fixture that maintains the desired light-directing characteristics and efficiency of operation at a substantially constant level throughout the fixture life. Such continued combination of advantages can be difficult to achieve because of susceptibility of light-managing components to damage, degradation and wear over a period of time.
It is an object of this invention to provide a light-directing apparatus and lighting fixture, preferably LED-based devices, which distribute light from light emitters in a preferential lateral direction and which overcomes some of the problems and shortcomings of the prior art.
Another object of this invention is to provide light-directing apparatus and lighting fixture which maximize the light directed toward a preferential side and minimize light directed toward the opposite (non-preferential) side.
Another object of this invention is to provide lighting fixtures for uses such as roadway and parking-lot illumination that have high-efficiency light-directing apparatus while satisfying requirements for minimizing trespass light.
Still another object of this invention is to provide a light-directing apparatus which directs a maximum amount of emitted light toward an area intended to be illuminated.
Yet another object of this invention is to provide an LED-based light-directing apparatus which maintains the light-directing characteristics at a substantially constant level throughout its life.
Another object of this invention is to provide an LED-based light-directing apparatus having light-managing components which are protected from damage, degradation and wear over an extended period of time, even in difficult use environments.
These and other objects of the invention will be apparent from the following descriptions and the drawings.
One aspect of the present invention is an improved light-directing apparatus for off-axial preferential-side distribution of light from a light emitter which has an emitter axis. Another aspect of this invention is a lighting fixture utilizing such light-directing apparatus.
The inventive light-directing apparatus includes a lensing member positioned over the light emitter and a shield member. The lensing member has a proximal end substantially transverse the emitter axis and an outer surface configured for refracting light from the emitter.
The shield member may be embedded within the lensing member in a position in the path of light emitted toward the non-preferential side. In some of such embodiments, the shield member is embedded by the lensing member having been molded thereabout.
In some preferred embodiments, the proximal end defines a shield-insertion opening. In such embodiments, the lensing member further includes an inner surface defining an off-axis shield-receiving void extending from the shield-insertion opening. The shield member is snugly received in the shield-receiving void in a position in the path of light emitted toward a non-preferential side. The positioning of the shield-receiving void and the shield member therein are preferably such that the shield is off-set from the emitter axis.
The proximal end of the lensing member may further define an emitter-insertion opening and the inner surface defines an emitter-receiving void extending from the emitter-insertion opening and facing the emitter. The shield-insertion opening and the emitter-receiving opening are preferably in communication and form a single proximal-end opening. The shield-receiving void is preferably contiguous with the emitter-receiving void. The lensing member is most typically bilaterally symmetric, as is the shield member.
The outer surface of the lensing member is preferably a compound surface configured for refracting light from the emitter in a predominantly off-axial direction toward a preferential side. One type of a compound outer surface is disclosed in U.S. Pat. No. 7,618,163, the contents of which are incorporated herein by reference. The term “compound surface,” as used herein with respect to the outer surface of a lensing member (a lens), means a surface having portions of differing geometric shapes and/or including inflection regions between different portions thereof, e.g., convex portions on either side of a concave portion. “Compound surface” does not imply any particular shape, but the shape will be chosen for the desired lensing properties.
In preferred embodiments, the shield member includes a reflective front surface in the path of light emitted toward the non-preferential side to redirect such light toward the preferential side. The shield member may be formed of various plastic materials with a reflective coating. Such coated plastics are known to have a light-reflecting efficiency of about 85%. A sill more efficient alternative is an anodized metal, such as aluminum, which provides a higher light-reflection efficiency, of about 95%.
The reflective front surface is preferably entirely within the lensing member. Such enclosure provides highly desirable protection for the reflective surface, virtually eliminating damage, degradation and wear from exposure to elements.
The reflective front surface of the shield member is preferably of non-planar configuration. In some embodiments, the reflective front surface may have a plurality of sections angled with respect to each other. The sections may each be substantially planar. Alternatively, the reflective front surface may be formed by a single section, which may be flat or curved. The exact configuration of the shield portion, and its reflective front surface, whether it is planar or has a radius of curvature, are chosen to achieve the desired light-emitting characteristic for whatever product is being developed.
In preferred embodiments, the shield member includes a shield portion and a base portion. The reflective front surface is on the shield portion that extends from the base portion into the path of light emitted toward the non-preferential side. The base portion extends from the shield portion away from the light emitter at the proximal end of the lensing member.
In preferred embodiments of the inventive light-directing apparatus, the light emitter is an LED package which includes at least one LED and a primary lens over the LED. In such embodiments, the lensing member is a secondary lens placed over the primary lens, and the reflective front surface faces the primary lens. In some other embodiments, there is space between the primary and secondary lenses and the space is filled with optical-grade gel. In preferred embodiments, the primary lens is substantially rotationally symmetrical around the emitter axis; preferably the primary lens is substantially hemispherical.
The term “LED package” is well known in the industry. LED packages have either a single light-emitting diode (LED) or a few closely-spaced LEDs on a base. Many LED packages include a primary reflector, which may be in the form of a so-called reflector cup mounted to the base or a reflective surface associated with the primary lens proximal the LED(s). One example of LED packages illustrated here in connection with the present invention includes a ring, preferably made of aluminum, around the primary lens on the base, which ring serves to position the primary lens and to reflect some light from the emitter to assist in the generation of an illumination pattern. Persons skilled in the art will appreciate that a broad variety of available LED packages are useful with the light-directing apparatus of the present invention.
The lensing member preferably includes an outward flange around the opening(s) at the proximal end. The flange has an inner surface facing the mounting board. The base portion of the shield member is preferably at least partially against the inner surface of the flange. The outward flange may include a reference mark indicating an orientation with respect to the preferential side. Alternatively, the flange may have a specific shape, such as cut corners or the like, to indicate the orientation with respect to the preferential side. Such features are helpful in assembly of lighting fixtures using such light-directing apparatus.
The lighting fixture of this invention utilizes a plurality of light emitters, preferably LED packages, spaced from one another on a mounting board and oriented with substantially parallel axes. A light-directing apparatus is positioned over the light emitters for off-axial preferential-side distribution of light from the emitters. The light-directing apparatus includes a plurality of lenses, each positioned over one light emitter, and a plurality of shield members. Each lens has a proximal end transverse the emitter axis and defines a shield-insertion opening. Each lens has an inner surface defining an off-axis shield-receiving void extending from the shield-insertion opening, and a compound outer surface configured for refracting light from the emitter in a predominantly off-axial direction toward a preferential side. Each shield member is snugly received in the shield-receiving void of a corresponding one of the lenses in a position in the path of light emitted from the corresponding light emitter toward a non-preferential side.
In some embodiments of the inventive lighting fixture, the lenses have preferential sides in the same lateral direction, thereby to facilitate illumination toward one lateral direction.
In other embodiments, the lenses have preferential sides in different lateral directions, thereby to facilitate illumination in different lateral directions. The lenses may be arranged in a substantially circular pattern, and each lens has a preferential side oriented in a substantially radially outward direction with respect to the circular pattern. Some of such other embodiments may have subsets of the emitters and the corresponding lenses, with the subsets configured for directing light in different lateral directions.
One example of such other embodiments may have two subsets, one subset with its light-directing apparatuses configured for directing light toward a broad area (e.g., of a parking lot), and another smaller subset with its light-directing apparatuses configured for illumination of an adjacent sidewalk. In some other examples of the above-described embodiments, the emitters and their corresponding lenses are arranged in a substantially circular pattern, with each lens having a preferential side oriented in a substantially radially outward direction with respect to the circular pattern.
In the preferred embodiment, which are illustrated, each lensing member (secondary lens) is a separate piece. In certain other embodiments, the plurality of lenses in the light-directing apparatus maybe formed as portions of a single unitary piece, with the lens portions each positioned for proper placement over its corresponding emitter.
The term “preferential side,” as used herein with respect to the light-distribution direction, means the lateral direction (with respect to the emitter axis) toward which illumination is desired. The term “non-preferential side,” as used herein with respect to the direction of the light distribution, means the lateral direction toward which illumination is not desired. The non-preferential side is typically substantially radially opposite from the preferential side.
The term “snugly,” as used herein with respect to positioning of the shield member inside the lensing member, means that inner surface of the lensing member which defines the shield-receiving void is configured for fitting closely against at least a portion of the shield-member surfaces to support the shield member in substantially fixed position with respect to the emitter axis. In other words, the shield-receiving void and the shield member are configured for a mating relationship sufficient to fix the position of the shield member with respect to the lensing member, whether or not all surfaces of the shield member are in contact with surfaces of the lensing member.
The term “being in communication,” when used in reference to the emitter-insertion opening and the shield-insertion opening, means that the emitter-insertion opening may encompass the entire shield-insertion opening or that such openings may partially overlap. In either case, the term “being in communication” means that there is no barrier between such openings. (It should be understood that “opening” does not refer to something having volume, while “void” does imply volume.)
Inventive light-directing apparatus 10 includes a lensing member 40 positioned over light emitter 20 and a shield member 50. As best seen in
FIGS. 5 and 7-9 illustrate that proximal end 41 of light-directing apparatus 10 defines a shield-insertion opening 43. Lensing member 40 further includes an inner surface 45 which defines an off-axis shield-receiving void 46 extending from shield-insertion opening 43 and terminating at a close end. Shield member 50 is snugly received in shield-receiving void 46 in a position in the path of light emitted toward non-preferential side 12. As best seen in
As best illustrated in
Shield member 50 includes a reflective front surface 51 in the path of light emitted toward non-preferential side 12 to redirect such light toward preferential side 11. Reflective front surface 51 is entirely within lensing member 40.
Shield member 50 further includes a shield portion 53 which extends from a base portion 54 into the path of light emitted toward non-preferential side 12. Base portion 54 extends from shield portion 53 away from light emitter 20 at proximal end 41 of lensing member 40. Reflective front surface 51 is on shield portion 53.
LED package 22 shown in
Lensing member 40 includes an outward flange 48 around the opening(s) at proximal end 41. Flange 48, and thus lensing member 40, are secured with respect to a mounting board 14 which is part of a lighting fixture that includes a plurality of light-directing apparatuses of the sort described. (See
Lighting fixture 30 shown in
While
Referring now to
Light patterns 61 and 62 were generated using optical ray-tracing software to simulate the illumination intensity emanating from the respective apparatus.
While the principles of this invention have been described in connection with specific embodiments, it should be understood clearly that these descriptions are made only by way of example and are not intended to limit the scope of the invention.
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