The present invention relates to illumination systems utilizing light emitting diodes (“LEDs”) to provide visible or substantially white light, and more specifically to a luminaire incorporating a row of LEDs located in a reflective channel with a heat sink disposed alongside or behind the channel.
LEDs offer benefits over incandescent and fluorescent lights as sources of illumination. Such benefits include high energy efficiency and longevity. To produce a given output of light, an LED consumes less electricity than an incandescent or a fluorescent light. And, on average, the LED will last longer before failing.
The level of light a typical LED outputs depends upon the amount of electrical current supplied to the LED and upon the operating temperature of the LED. That is, the intensity of light emitted by an LED changes according to electrical current and LED temperature. Operating temperature also impacts the usable lifetime of most LEDs.
As a byproduct of converting electricity into light, LEDs generate heat that can raise the operating temperature if allowed to accumulate, resulting in efficiency degradation and premature failure. The conventional technologies available for handling and removing this heat are generally limited in terms of performance and integration. For example, most heat management systems are separated from the optical systems that handle the light output by the LEDs. The lack of integration often fails to provide a desirable level of compactness or to support efficient luminaire manufacturing.
Accordingly, to address these representative deficiencies in the art, an improved technology for managing the heat and light LEDs produce is needed. A need also exists for an integrated system that can manage heat and light in an LED-base luminaire. Yet another need exists for technology to remove heat via convection and conduction while controlling light with a suitable level of finesse. Still another need exists for an integrated system that provides thermal management, mechanical support, and optical control. An additional need exists for a compact lighting system having a design supporting low-cost manufacture. A capability addressing one or more of the aforementioned needs (or some similar lacking in the field) would advance LED lighting.
The present invention can support illuminating an area or a space to promote observing or viewing items located therein. A lighting system comprising a light source, such as an LED, can comprise one or more provisions for managing light and heat generated by a light source. Managing heat can enhance efficiency and extend the source's life. Managing light can provide a beneficial illumination pattern.
In one aspect of the present invention, a lighting system, apparatus, luminaire, or device can comprise a row of LEDs. The row of LEDs, which are not necessarily in a perfect line with respect to one another, can emit or produce visible light, for example light that is white, red, blue, green, purple, violet, yellow, multicolor, etc. Additionally, the light can have a wavelength or frequency that a typical human can perceive visually. The emitted light can comprise photons, luminous energy, electromagnetic waves, radiation, or radiant energy.
The lighting system can further comprise one or more capabilities, elements, features, or provisions for managing light and heat produced by the row of LEDs. The row of LEDs can be disposed in a channel having a reflective lining or reflective sidewalls. That is, the LEDs can be located in a groove, an elongate cavity, a trough, or a trench with a surface for reflecting light the LEDs produce. The surface can be either smoothly polished to support specular reflection or roughened to support diffuse reflection. Accordingly, the channel can manage light from the LEDs via reflection. One or more features for managing heat produced by the LEDs can extend or run alongside the channel. For example, one or more protrusions, fins, or flutes can be located next to the channel. The features running alongside the channel can be behind the channel, in front of the channel, beside the channel, next to the channel, above the channel, adjacent the channel, beneath the channel, etc. Managing heat produced by the LEDs can comprise transferring the heat to air via air circulation or air movement.
The discussion of managing heat and light produced by LEDs presented in this summary is for illustrative purposes only. Various aspects of the present invention may be more clearly understood and appreciated from a review of the following detailed description of the disclosed embodiments and by reference to the drawings and the claims that follow. Moreover, other aspects, systems, methods, features, advantages, and objects of the present invention will become apparent to one having ordinary skill in the art upon examination of the following drawings and detailed description. It is intended that all such aspects, systems, methods, features, advantages, and objects are included within this description, are within the scope of the present invention, and are protected by the accompanying claims.
Many aspects of the invention can be better understood with reference to the above drawings. The elements and features shown in the drawings are not necessarily to scale, emphasis instead being placed upon clearly illustrating the principles of exemplary embodiments of the present invention. Additionally, certain dimensions may be exaggerated to help visually convey such principles. In the drawings, reference numerals designate like or corresponding, but not necessarily identical, elements throughout the several views.
An exemplary embodiment of the present invention supports reliably and efficiently operating an LED-based lighting system or luminaire that is compact and configured for cost-effective fabrication. The lighting system can comprise a structural element that manages heat and light output by one or more LEDs. Fins, protrusions, or grooves can provide thermal management via promoting convection. A channel comprising a reflective lining can provide light management via diffuse or specular reflection or a combination of diffuse and specular reflection.
A lighting system will now be described more fully hereinafter with reference to
The invention can be embodied in many different forms and should not be construed as limited to the embodiments set forth herein; rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those having ordinary skill in the art. Furthermore, all “examples” or “exemplary embodiments” given herein are intended to be non-limiting, and among others supported by representations of the present invention.
Turning now to
In an exemplary embodiment, the lighting system 100 can be a luminaire or a lighting fixture for illuminating a space or an area that people may occupy or observe. In one exemplary embodiment, the lighting system 100 can be a luminaire suited for mounting to a ceiling of a parking garage or a similar structure.
The term “luminaire,” as used herein, generally refers to a system for producing, controlling, and/or distributing light for illumination. A luminaire can be a system outputting or distributing light into an environment so that people can observe items in the environment. Such a system could be a complete lighting unit comprising: one or more LEDs for converting electrical energy into light; sockets, connectors, or receptacles for mechanically mounting and/or electrically connecting components to the system; optical elements for distributing light; and mechanical components for supporting or attaching the luminaire. Luminaries are sometimes referred to as “lighting fixtures” or as “light fixtures.” A lighting fixture that has a socket for a light source, but no light source installed in the socket, can still be considered a luminaire. That is, a lighting system lacking some provision for full operability may still fit the definition of a luminaire.
An optically transmissive cover (not illustrated) may be attached over the lighting system 100 to provide protection from dirt, dust, moisture, etc. Such a cover can control light via refraction or diffusion, for example. Moreover, the cover might comprise a refractor, a lens, an optic, or a milky plastic or glass element. As illustrated in
The exemplary lighting system 100 is generally rectangular in shape, and more particularly square. Other forms may be oval, circular, diamond-shaped, or any other geometric form. Two channels 115 extend around the periphery of the lighting system 100 to form a square perimeter. Two extrusions 110 provide the two channels 115. A row of LEDs 125 is disposed in each of the channels 115. Each channel 115 comprises a reflective surface 105 for manipulating light from the associated row of LEDs 125. The reflective surface 105 can comprise a lining of the channel 115, a film or coating of reflective or optical material applied to the channel 115, or a surface finish of the channel 115.
In one exemplary embodiment, the channel 115 has a uniform or homogenous composition, and the reflective surface 105 comprises a polished surface. Thus, the reflective surface 105 can be formed by polishing the channel 115 itself to support specular reflection or roughening the surface for diffuse reflection.
In one or more exemplary embodiments, each channel 115 can comprise a groove, a furrow, a trench, a slot, a trough, an extended cavity, a longitudinal opening, or a concave structure running lengthwise. A channel can include an open space as well as the physical structure defining that space. In other words, the channel 115 can comprise both a longitudinal space that is partially open and the sidewalls of that space.
In one exemplary embodiment, the reflective surfaces 105 are polished so as to be shiny or mirrored. In another exemplary embodiment, the reflective surfaces 105 are roughened to provide diffuse reflection. In another exemplary embodiment, each reflective surface 105 comprises a metallic coating or a metallic finish. For example, each reflective surface 105 can comprise a film of chromium or some other metal applied to a substrate of plastic or another material. In yet another exemplary embodiment, a conformal coating or a vapor-deposited coating can provide reflectivity.
Each extrusion 110 can have an aluminum composition or can comprise aluminum. As an alternative to fabrication via an extruding process, the channel 115 can be machined/cut into a bar of aluminum or other suitable metal, plastic, or composite material. Such machining can comprise milling, routing, or another suitable forming/shaping process involving material removal. In certain exemplary embodiments, the channels 115 can be formed via molding, casting, or die-based material processing. In one exemplary embodiment, the channels 115 are formed by bending strips of metal.
Each extrusion 110 comprises fins 120 opposite the channel 115 for managing heat produced by the associated row of LEDs 125. In an exemplary embodiment, the fins 120 and the channel 115 of each extrusion 110 are formed in one fabrication pass. That is, the fins 120 and the channel 115 are formed during extrusion, as the extrusion 110 is extruded.
As illustrated, the fins 120 of each extrusion 110 run or extend alongside, specifically behind, the associated channel 115. As discussed in further detail below, heat transfers from the LEDs via a heat-transfer path extending from the row of LEDs 125 to the fins 120. The fins 120 receive the conducted heat and transfer the conducted heat to the surrounding environment (typically air) via convection.
The two extrusions 110 extend around the periphery of the lighting system 100 to define a central opening 130 that supports convection-based cooling. An enclosure 135 located in the central opening 130 contains electrical support components, such as wiring, drivers, power supplies, terminals, connections, etc. In one exemplary embodiment, the enclosure 135 comprises a junction box or “j-box” for connecting the lighting system 100 to an alternating current power line. Alternatively, the lighting system 100 can comprise a separate junction box (not illustrated) located above the fixture.
Turning now to
In the illustrated exemplary embodiment, each row of LEDs 125 is attached to a flat area 320 of the associated extrusion 110. The term “row,” as used herein, generally refers to an arrangement or a configuration whereby items are disposed approximately in or along a line. Items in a row are not necessarily in perfect alignment with one another. Accordingly, one or more elements in the row of LEDs 125 might be slightly out of perfect alignment, for example in connection with manufacturing tolerances or assembly deviations. Moreover, elements might be purposely staggered.
Each row of LEDs 125 comprises multiple modules, each comprising at least one solid state light emitter or LED, represented at the reference number “305.” Each of these modules can be viewed as an exemplary embodiment of an LED and thus will be referred to hereinafter as LED 305. In another exemplary embodiment, an LED can be a single light emitting component (without necessarily being included in a module or housing potentially containing other items).
Each LED 305 is attached to a respective substrate 315, which can comprise one or more sheets of ceramic, metal, laminates, or circuit board material, for example. The attachment between LED 305 and substrate 315 can comprise a solder joint, a plug, an epoxy or bonding line, or another suitable provision for mounting an electrical/optical device on a surface. Support circuitry 310 is also mounted on each substrate 315 for supplying electrical power and control to the associated LED 305. The support circuitry 310 can comprise one or more transistors, operational amplifiers, resistors, controllers, digital logic elements, etc. for controlling and powering the LED.
In an exemplary embodiment, each substrate 315 adjoins, contacts, or touches the flat area 320 of the extrusion 110 onto which each substrate 315 is mounted. Accordingly, the thermal path between each LED 305 and the associated fins 120 can be a continuous path of solid or thermally conductive material. In one exemplary embodiment, that path can be void of any air interfaces, but may include multiple interfaces between various solid materials having distinct thermal conductivity properties. In other words, heat can flow from each LED 305 to the associated fins 120 freely or without substantive interruption or interference.
The substrates 315 can attach to the flat areas 320 of the extrusion 110 via solder, braze, welds, glue, plug-and-socket connections, epoxy, rivets, clamps, fasteners, etc. A ridge 325 provides an alignment surface so that each substrate 315 makes contact with the ridge 325. Moreover, contact between the substrates 315 and the ridge 325 provides an efficient thermal path from the LEDs 305 to the extrusion 110, and onto the fins 120, as discussed above. Accordingly, substrate-to-extrusion contact (physical contact and/or thermal contact) can occur at the flat area 320, at the ridge 325, or at both the flat area 320 and the ridge 325.
In an exemplary embodiment, the LEDs 305 comprise semiconductor diodes emitting incoherent light when electrically biased in a forward direction of a p-n junction. In an exemplary embodiment, each LED 305 emits blue or ultraviolet light, and the emitted light excites a phosphor that in turn emits red-shifted light. The LEDs 305 and the phosphors can collectively emit blue and red-shifted light that essentially matches blackbody radiation. Moreover, the emitted light may approximate or emulate incandescent light to a human observer. In one exemplary embodiment, the LEDs 305 and their associated phosphors emit substantially white light that may seem slightly blue, green, red, yellow, orange, or some other color or tint. Exemplary embodiments of the LEDs 305 can comprise indium gallium nitride (“InGaN”) or gallium nitride (“GaN”) for emitting blue light.
In an alternative embodiment, multiple LED elements (not illustrated) are mounted on each substrate 315 as a group. Each such mounted LED element can produce a distinct color of light. Meanwhile, the group of LED elements mounted on one substrate 315 can collectively produce substantially white light or light emulating a blackbody radiator.
In one exemplary embodiment, some of the LEDs 305 can produce red light, while others produce, blue, green, orange, or red, for example. Thus, the row of LEDs 125 can provide a spatial gradient of colors.
In one exemplary embodiment, optically transparent or clear material encapsulates each LED 305, either individually or collectively. Thus, one body of optical material can encapsulate multiple light emitters. Such an encapsulating material can comprise a conformal coating, a silicone gel, cured/curable polymer, adhesive, or some other material that provides environmental protection while transmitting light. In one exemplary embodiment, phosphors, for converting blue light to light of another color, are coated onto or dispersed in such encapsulating material.
Turning now to
The fins 120 run essentially parallel to each channel 115 (within typical manufacturing tolerances that accommodate some deviation). Moreover, the fins 120, the rows of LEDs 125, the extrusions 110, and the channels 115 extend along a common axis 420, which has been located in an arbitrary or illustrative position in
As further illustrated in
Turning now to
Inserting the protrusion 405 in the slot 410 typically comprises sliding the protrusion 405 into the slot 410. In an exemplary assembly procedure, two extrusions 110 are oriented end-to-end. Next, one of the two extrusions 110 is moved laterally until the end of the protrusion 405 is aligned with the end opening of the slot 410. The two extrusions 110 are then moved longitudinally towards one another so that the protrusion 405 slides into the slot 410. With the protrusion 405 so captured in the slot 410, disassembly entails sliding the two protrusions 405 apart, rather than applying lateral separation force.
While
Although
Turning now to
The illustrated cross section cuts though a lower cover 600 (not depicted in
Turning now to
The thermal management provisions of the lighting system 100 transfer heat away from the LEDs 305 to support efficient conversion of electricity into light and further to provide long LED life.
Turning now to
At step 805 of the method 800, the LEDs 305 receive electricity from a power supply that may be located in the enclosure 135 or mounted on the substrate 315, for example. In one exemplary embodiment, an LED power supply delivers electrical current to the LEDs 305 via circuit traces printed on the substrate 315. The current can be pulsed or continuous and can be pulse width modulated to support user-controlled dimming. In response to the applied current, the LEDs 305 produce heat while emitting or producing substantially white light or some color of light that a person can perceive. As discussed above, in one exemplary embodiment, at least one of the LEDs 305 produces blue or ultraviolet light that triggers photonic emissions from a phosphor. Those emissions can comprise green, yellow, orange, and/or red light, for example. In other words, the LEDs 305 produce light and heat as a byproduct.
At step 810, the reflective surfaces 105 of the channels 115 direct the light outward from the lighting system 100. The light emanates outward and, to a lesser degree, downward. Directing the light radially outward, while maintaining a downward aspect to the illumination pattern, helps the lighting system 100 illuminate a relatively large area, as may be useful for a parking garage or similar environment.
At step 815, the heat generated by the LEDs 305 transfers to the fins 120 via conduction. As discussed above, in an exemplary embodiment, the materials in the heat transfer path between the LEDs 305 and the fins 120 can have a high level of thermal conductivity, for example similar to or higher than any elemental metal. Accordingly, in an exemplary embodiment, the heat conduction can be efficient or unimpeded.
At step 820, the fins 120 transfer the heat to the air 610 via convection. In an exemplary embodiment, the heat raises the temperature of the air 610 causing the air 610 to circulate, flow, or otherwise move. The moving air carries additional heat away from the fins 120, thereby maintaining the LEDs 305 at an acceptable operating temperature. As discussed above, such a temperature can help extend LED life while promoting electrical efficiency.
Technology for managing heat and light of an LED-based lighting system has been described. From the description, it will be appreciated that an embodiment of the present invention overcomes limitations of the prior art. Those having ordinary skill in the art will appreciate that the present invention is not limited to any specifically discussed application or implementation and that the embodiments described herein are illustrative and not restrictive. From the description of the exemplary embodiments, equivalents of the elements shown herein will suggest themselves to those having ordinary in the art, and ways of constructing other embodiments of the present invention will appear to practitioners of the art. Therefore, the scope of the present invention is to be limited only by the claims that follow.
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