The present disclosure generally relates to a lighting or illumination assembly. More particularly, the present disclosure relates to a lighting or illumination assembly that uses light emitting diodes (LEDs).
Illumination assemblies are used in a variety of diverse applications. Traditional illumination assemblies have used lighting sources such as incandescent or fluorescent lights. More recently, other types of light emitting elements, and light emitting diodes (LEDs) in particular, have been used in illumination assemblies. LEDs have the advantages of small size, long life, and energy efficiency. These advantages of LEDs make them useful in many diverse applications.
For many lighting applications, it is desirable to have one or more LEDs supply the required luminous flux and/or illuminance. LEDs in an array are commonly connected to each other and to other electrical systems by mounting the LEDs onto a substrate. LEDs may be populated onto a substrate using techniques that are common to other areas of electronics manufacturing, e.g., locating components onto circuit board traces, followed by bonding the components to the substrate using one of a number of known technologies, including hand soldering, wave soldering, reflow soldering, and attachment using conductive adhesives.
In addition to light, LEDs generate heat during operation. The amount of heat and light generated by an LED is generally proportional to the current flow. Consequently, the more light an LED generates, the more heat the LED generates. Unfortunately, as LED current increases and temperature increases, less light is produced proportional to current, causing LED efficiency and lifetime to decrease.
One prior art attempt to reduce the total heat in a lighting system is shown schematically in
Another prior art attempt to reduce the total heat in a lighting system is shown schematically in
Planar heat pipe (or heat spreader) 6 as shown in
Another prior art attempt to reduce the total heat in a lighting system is shown schematically in
The inventors of the present application recognized that if a desired low LED temperature can be maintained, the LED can be operated at higher brightness (increased current). Increased brightness of each LED in a lighting system can also facilitate the use of fewer LEDs, resulting in a lower cost lighting system. Consequently, the inventors of the present application recognized that maintaining a desired low LED temperature produces more LED light, saves electricity, and lengthens the life of the LED.
The inventors of the present application discovered energy efficient lighting and illumination assemblies. Specifically, in the lighting system(s) and/or assemblies of the present application, heat is dissipated more efficiently from the heat source than in existing designs, resulting in improvements in, for example, electrical efficacy, lifespan, manufacturing costs, weight, and size.
The present disclosure relates to illumination or lighting assemblies and systems that provide illumination using LEDs. The illumination or lighting systems of the present application include high brightness, high intensity systems with controlled light distribution. The illumination assemblies and systems disclosed herein may be used for general lighting purposes, e.g., to illuminate an area or to generate light output appropriate for injection into many different lighting applications. Such assemblies are suitable for use in, for example, a street light, a backlight (including, for example, a sun-coupled backlight), a wall wash light, a billboard light, a parking ramp light, a high bay light, a parking lot light, a signage lit sign (also referred to as an electric sign), static signage (including, for example, sun-coupled static signage), illuminated signage, and other lighting applications.
In one aspect, the present disclosure provides a lighting assembly, comprising: one or more light emitting diodes that emit light; an optical system that directs the light emitted by the light emitting diodes, the optical system positioned adjacent to light emitting diodes; and a cooling fin including a two-phase cooling system, the cooling fin positioned adjacent to the light emitting diodes such that the two-phase cooling system removes heat from the light emitting diodes.
In another aspect, the present disclosure provides a lighting system including multiple lighting assemblies.
In another aspect, the present disclosure provides a street light, comprising: multiple light emitting diodes that emit light; an optical system that directs the light emitted by the light emitting diodes, the optical system positioned adjacent to the light emitting diodes; and multiple cooling fins each of which includes a two-phase cooling system, the multiple cooling fins positioned adjacent to the light emitting diodes such that the two-phase cooling systems within the cooling fins remove heat from the light emitting diodes.
In another aspect, the present disclosure provides a wall wash, comprising: a light emitting diode that emits light; an optical system that directs the light emitted by the light emitting diode; and a two-phase cooling system including a convective cooling surface, the two-phase cooling system positioned adjacent to the light emitting diode such that the two-phase cooling system diffuses heat away from the light emitting diode.
In another aspect, the present disclosure provides a lighting system, comprising: a light emitting diode that emits light; an optical system that directs the light emitted by the light emitting diode; and a two-phase cooling system including a convective cooling surface and the two-phase cooling system positioned adjacent to the light emitting diode such that the two-phase cooling system diffuses heat away from the light emitting diode.
One prior art attempt to reduce the total heat in a lighting system is shown schematically in
Another prior art attempt to reduce the total heat in a lighting system is shown schematically in
Another prior art attempt to reduce the total heat in a lighting system is shown schematically in
Any suitable material or materials may be used to form LED 12, e.g., metal, polymer, organic semiconducting materials, inorganic semiconducting materials, etc. As used herein, the terms “LED” and “light emitting diode” refer generally to light emitting semiconductor elements with contact areas for providing power to the diode. Different forms of inorganic LEDs may be formed, for example, from a combination of one or more Group III elements, one or more Group V elements (III-V semiconductor), one or more Group II elements, and one or more Group VI elements. Examples of III-V LED materials that can be used in an LED include nitrides, such as gallium nitride or indium gallium nitride, and phosphides, such as indium gallium phosphide. Other types of III-V materials can also be used, as can inorganic materials from other groups of the periodic table. Examples of II-VI LED materials include those listed in, for example, U.S. Pat. No. 7,402,831 (Miller et al.) or U.S. Patent Application Publication Nos. US2006-0124918 (Miller et al.) or US2006-0124938 (Miller et al.).
The LEDs may be in packaged or non-packaged form, including, for example, LED dies, surface-mounted LEDs, chip-on-board LEDs and LEDs of other configurations. Chip-on-board (COB) refers to LED dies (i.e., unpackaged LEDs) mounted directly onto a substrate. The term “LED” also includes LEDs packaged or associated with a phosphor where the phosphor converts light emitted from the LED to light at a different wavelength. Electrical connections to the LED can be made by, for example, wire bonding, tape automated bonding (TAB), or flip-chip bonding. The LEDs are schematically depicted in the illustrations, and can be, for example, unpackaged LED dies or packaged LEDs.
LEDs can be top emitting, such as those described in, for example, U.S. Pat. No. 5,998,925 (Shimizu et al.). Alternatively, LEDs can be side emitting, such as those described in, for example, U.S. Pat. No. 6,974,229 (West et al.). Exemplary commercially available LEDs for use with the lighting assemblies and systems of the present disclosure include, for example, Lambertian LEDs, including XLamp LEDs such as those sold by Cree; Luxeon® LEDS, such as those sold by Philips Lumileds; and side emitting or batwing distribution LEDs, including those sold by Philips Lumileds.
LEDs can be selected to emit at any desired wavelength, such as in the red, green, blue, ultraviolet, or infrared spectral regions. In an array of LEDs, the LEDs can each emit in the same spectral region, or can emit in different spectral regions. Different LEDs may be used to produce different colors where the color of light emitted from the light emitting element is selectable. Individual control of the different LEDs leads to the ability to control the color of the emitted light. In addition, if white light is desired, then a number of LEDs emitting light of different colors may be provided, whose combined effect is to emit light perceived by a viewer to be white. Another approach to producing white light is to use one or more LEDs that emit light at a relatively short wavelength and to convert the emitted light to white light using a phosphor wavelength converter. White light may be biased to the red (commonly referred to as warm white light) or to the blue (commonly referred to as cool white light).
Lighting assembly 10 can include more than one LED 12. Lighting assembly 10 also includes an optical system 20 that directs light 14 emitted by light emitting diode 12 and a cooling fin 30 including a two-phase cooling system. Optical system 20 and cooling fin 30 are positioned adjacent to and on opposite sides of LED 12 such that the two-phase cooling system removes heat generated by LED 12 and such that optical system 20 directs light 14 emitted by LED 12.
Optical system 20, as shown in
Optical system 20 may additionally or alternatively include any element that controls or directs light distribution including, for example, lenses (including, for example, moldable, UV-curable silicones used as lenses), diffusers, polarizers, baffles, filters, beam splitters, brightness enhancement films, reflectors (e.g., ESR), etc. alone or in combination to achieve the desired optical effects. For example, in one exemplary embodiment, the optical system includes the lens that is part of a commercially available LED, a solid or hollow wedge, and at least one or more reflectors.
Cooling fin 30, as shown in
More specifically, in the lighting assembly shown in
The amount of liquid 33 within cooling fin 30 is selected so that at all times, some liquid 33 will remain within cooling fin 30. Exemplary fluids for use in the lighting assembly include, for example, water, glycol, brines, alcohols, chlorinated liquids, brominated liquids, perfluorocarbons, silicones, hydrocarbon alkanes, hydrocarbon alkenes, hydrocarbon aromatics, hydrofluorocarbons, hydrofluoroethers, fluoroketones, hydrofluoroolefins, and non-flammable segregated HFEs. One advantage of using water is that it is relatively inexpensive and widely available, but some disadvantages of water include that the use of water can necessitate more expensive, all copper construction of the fin and can make the fin more vulnerable to rupture upon freezing. Most alcohol and hydrocarbon compounds (e.g., alkanes, alkenes, aromatics, ketones, esters, etc.) that have sufficient volatility for use in two-phase applications are also quite flammable. Many chlorinated and brominated compounds (e.g., tricholoroethylene) are either highly regulated for their toxicity or they deplete the ozone layer (e.g., CFCs). Perfluorocarbon and commercially significant hydrofluorocarbon fluids have high global warming potentials. For these reasons, fluoroketones and hydrofluoroethers are two exemplary preferred working fluids. Exemplary preferred fluids for use in the lighting assembly have boiling points that are between about −40° C. and 100° C.
Some exemplary advantages of two-phase cooling include: (1) large heat fluxes can be dissipated due to the latent heat of evaporation and condensation; (2) reduced lighting assembly and/or system weight and volume; (3) smaller heat transfer area compared to alternatives; (4) passive circulation and the ability to dissipate high heat fluxes with minimal temperature differences between the boiling surface and coolant when implemented with surface enhancements; and (5) the ability to have a minimal temperature difference between the LED and the convective wall surface. Further, the present application relates to a lighting system or assembly in which the convective cooling surface is the same surface as the two-phase cooling surface.
In at least some embodiments, it is preferable to minimize the thermal path between the LED 12 and the boiling surface 34. The size of cooling fin 30 is determined by the area that is needed to dissipate the heat generated by LED 12. The side walls 36 of cooling fin 30 are preferably sufficiently thin to minimize thermal resistance from the inside condensing surfaces 38 and the outside convective cooling surfaces 40 and preferably sufficiently thick to withstand the internal and external pressure differential. Side walls 36 of cooling fin 30 can be formed of any material that meets these requirements such as, for example, steel, aluminum, copper, plastic, or stainless steel. Some preferred clear materials include, for example, glass and plastic.
As shown in
The lighting assemblies of the present disclosure include an LED that is designed to be attachable to a substrate using a number of suitable techniques, e.g., soldering, press-fitting, piercing, screwing, etc. One exemplary substrate is a thermally conductive substrate that conducts heat away from the LED. In some embodiments, the substrates can be electrically conductive, thereby providing a circuit pathway for the LED (see, for example, U.S. Patent Publication No. US20070216274 (Schultz et al.)). Further, in some embodiments, the lighting assembly includes a reflective layer proximate a major surface of the substrate to reflect at least a portion of light emitted by the LED. Further, some embodiments include an LED having a post that can provide a direct thermal connection to the substrate (see, for example, U.S. Pat. Nos. 7,285,802 (Ouderkirk et al.) and 7,296,916 (Ouderkirk et al.)). In an exemplary embodiment, this direct thermal connection can allow a portion of heat generated by the LED to be directed away from the LED and into the substrate in a direction substantially orthogonal to a major surface of the substrate, thereby reducing the amount of generated heat that is spread laterally away from the LED.
The thermally conductive substrate may include any suitable material or materials that are thermally conductive, e.g., copper, nickel, gold, aluminum, tin, lead, silver, indium, gallium, zinc oxide, beryllium oxide, aluminum oxide, sapphire, diamond, aluminum nitride, silicon carbide, pyrolite, graphite, magnesium, tungsten, molybdenum, silicon, polymeric binders, inorganic binders, glass binders, polymers loaded with thermally conductive particles that may or may not be electrically conductive, and combinations thereof. In some embodiments, the substrate can be attached to another material or materials, e.g., ultrasonically or otherwise weldable to aluminum, copper, metal coated ceramic or polymer, or thermally conductive filled polymer. The substrate can be of any suitable size and shape. In some embodiments, the substrate may be electrically conductive. Such an electrically conductive substrate may include any suitable electrically conductive material or materials, e.g., copper, nickel, gold, aluminum, tin, lead, silver, indium, gallium, and combinations thereof. The substrate may serve a combination of purposes, including, for example, making an electrical connection to LED 12, providing a direct thermal pathway away from LED 12, providing heat spreading laterally away from the LED 12, and/or providing electrical connections to other systems.
The distance between adjacent fins 30 is selected in accordance with the conventional convection theory to maximize heat transfer between the lighting assembly and the surrounding environment. The fins are preferably a sufficient distance apart to permit enough air to flow past the fins and remove the heat. For example, in one exemplary embodiment the spacing is between about 1 mm and about 100 mm. In one exemplary embodiment, the spacing is about 25 mm. This spacing promotes effective convective cooling, which benefits from complete access for air flow from the bottom to the top of cooling fins 30. Cooling fins 30 preferably have an area that provides sufficient cooling and a fin spacing that facilitates convective air flow.
Lighting system 100 also includes multiple hollow wedges each of which directs the light emitted by LEDs 12 and each of which is positioned adjacent to LEDs 12. The distance between adjacent optical systems 20 is selected in accordance with the conventional convection theory to maximize and/or optimize heat transfer between the lighting assembly and the surrounding environment. The optical systems are preferably a sufficient distance apart to permit enough air to flow past the fins and remove the heat. This spacing promotes effective cooling, which benefits from complete access for air flow from the bottom of optical system 20 to the top of cooling fins 30. Optical system 20 preferably has a shape and size that provide for sufficient cooling and fin spacing that facilitates convective air flow.
LEDs can be positioned at or adjacent to the bottom of cooling fin 30.
LEDs 12 can also be tilted to point in a direction that gives a desired optical distribution (e.g., LEDs can be, for example, tilted in a direction parallel to cooling fin 30 or perpendicular to cooling fin 30). Optical system 20 adjacent to LEDs 12 can be, for example, parallel or perpendicular to cooling fin 30.
In another configuration, multiple cooling fins 30 can be tilted back such that light emitted by LEDs 12 is directed out or up, as is shown schematically in
The lighting assembly and/or lighting system described herein can be used in various devices, including, for example, street light, a backlight (including, for example, a sun-coupled backlight), a wall wash light, a billboard light, a parking ramp light, a high bay light, a parking lot light, a signage lit sign (also referred to as an electric sign), static signage (including, for example, sun-coupled static signage), illuminated signage, and other lighting applications. For purposes of illustration,
Exemplary applications for wall wash light fixtures include, for example, up-lighting large architectural surfaces (e.g., building exteriors) or other surfaces (e.g., billboards).
The following examples describe some exemplary constructions of various embodiments of the lighting assemblies and systems described in the present disclosure. The following examples also report some of the performance results of the lighting assemblies and systems.
A lighting assembly of the type shown generally in
Six LEDs (Cree XREWHT-L1-000-00D01) were attached in a line in series to a flex circuit (0.001″ thick polyimide film with copper traces) by soldering. Each of the six LEDs were thermally and mechanically attached to copper trace pads with thermally conductive epoxy (3M™ Thermally Conductive Epoxy Adhesive TC-2810) and electrically connected to the copper trace pads using solder. The flex circuit was in turn attached to the cooling fin along the 7 mm by 250 mm edge with the same thermally conductive epoxy. An LED driver (LEDDYNAMICs, 3021-D-E-1000) supplied power to the lighting assembly via wires attached to the two ends of the flex circuit.
The optical system was a hollow light guide formed from two aluminum sheets, 49.5 mm×250 mm×2 mm which enclosed the six LEDs. The aluminum sheets were attached to the cooling fin with Double Coated Tape 400 High Tack #415 sold by 3M Company. The hollow light guide had a trapezoidal cross section, with a 7 mm base width, 14 mm top width and height of 38 mm. Highly reflective film (Enhanced Specular Reflector ESR sold by 3M Company) was applied to the inside surface of the aluminum sheets with pressure sensitive adhesive structured for air release. This created a hollow light guiding cavity that directed light emitted by the six LEDs.
To a small hole near the top of the cooling fin was added approximately 15 cc of fluid (3M™ Novec™ Engineered Fluid HFE-7100 sold by 3M Company having a fluid density of 1.5 gm/cc). This volume of fluid was chosen to completely cover the bottom (boiling surface) of the cooling fin adjacent to the six LEDs. This amount of fluid included approximately 50% excess to allow for loss during the degassing procedure. The fluid was degassed by heating it to the boiling point (61° C.), by operating the LEDs with a current flow of 1 A. Heating the system by running the LEDs also forced the air to evacuate the hollow chamber of the cooling fin. The small hole was sealed with aluminum foil tape #425 sold by 3M Company. When sealed and cooled, the partially filled chamber was under vacuum. The resulting fluid volume of 6.6 cc was calculated using the fluid weight in the cooling fin and the fluid density.
The surface temperature of the cooling fin was measured near the top and bottom over a range of heat loads between 4.5 W and 14 W where “heat load” is defined as the difference between the total electrical power applied and the optical power output. The temperature difference between top and bottom ranged from 0.8° C. to 1.7° C. The temperature difference on a similarly sized solid aluminum plate of 2 mm thickness was modeled for comparative purposes. The results are shown in the Table I provided below.
Table I shows that the cooling fin of the lighting assembly of Example 1 had a much lower temperature range from top to bottom then the comparative solid plate.
Next, the efficacy of the lighting assembly of Example 1 was calculated by measuring the total light output divided by the input electrical power. The lighting assembly was placed inside a 1 m diameter integrating sphere to measure total light output while simultaneously monitoring input electrical power and LED temperature. The measurement system consisted of an OL-770 Multichannel Spectroradiometer (Optronic Laboratories), connected to an OL-IS-3900 1 Meter Integrating Sphere sold by Optronic Laboratories. The system was calibrated with a Standard of Total Spectral Flux and Total Luminous Flux, model OL 245-TSF, S/N L-909 sold by Optronics Laboratories and is traceable to NIST. Data was collected for operating currents of 350 mA, 700 mA, 900 mA and 1 A. Table II shows LED power (Watts), the measured light output (TLF) (lumens), LED temperature (° C.) and efficacy (lumen/Watt) for each specified current.
Table II shows the high efficacy (lumen/Watt) for each specified current.
A lighting system was made from ten lighting assemblies of the type described in Example 1. To verify that the performance of each individual lighting assembly in the lighting system was substantially similar to that of the single lighting assembly described in Example I, the light output for each individual lighting assembly was measured along with the amount of fluid remaining inside the lighting assembly after degassing at three different current levels, as is shown in Table III.
Table III shows the consistency of performance of each individual lighting assembly. Table III also shows that all ten individual lighting assemblies were performing as expected when compared with the lighting assembly described in Example I. The results also show that the performance of each lighting assembly is substantially similar for a fluid volume range of 6.5 cc-13.4 cc at all three specified levels of LED current.
A square frame structure was made to hold the ten lighting assemblies as follows. Aluminum tubing sections were machined and welded together in a u-shape with slots along the inner edges of the sides of the u-shape to hold the ten lighting assemblies. The u-shape was welded to a 290 mm×65 mm×6.4 mm plate creating a closed rectangular structure. A 75 mm section of 61 mm OD aluminum tubing was welded to the plate to mount the fixture when assembled. A decorative plastic trim was added to the sides of the fixture to protect and guide the wires from each of the ten lighting assemblies to a wiring box next to the mounting tube. The ten lighting assemblies were mounted at a pitch (center-to-center) of 32 mm in the frame structure.
The assembled lighting system was measured to quantify the efficacy of the system. The assembled unit was placed in a 2 m integrating sphere OL-IS-7600 2 Meter Integrating Sphere (Optronic Laboratories) connected to a spectroradiometer OL-770 Multichannel Spectroradiometer (Optronic Laboratories) and the total light output was measured according to the manufacturer's recommendations. The resulting data is shown in Table IV.
Table IV shows high efficacy for the lighting system at each specified current, similar to Table II. Radiation heat transfer from the lighting system was limited by the parallel plate configuration of the 10 lighting assemblies. The spacing between adjacent lighting assemblies was greater than the minimum distance for optimum natural convection because the optics were larger than the cooling fin thickness.
Radiation plates (237 mm×170 mm×3 mm aluminum painted with Ultra Flat Black paint (RUST-OLEUM)) were placed between adjacent lighting assemblies of the lighting system of Example 2. The radiation plates were positioned to avoid significantly reducing the convection heat transfer from each lighting assembly. The purpose of these radiation plates was to absorb radiated heat from the lighting assemblies and convey heat to the surroundings via natural convection. The radiation plates were approximately 25.4 mm taller than the cooling fins, which theoretically should have increased radiation heat transfer from the lighting system. The paint on the cooling fins should have theoretically increased the emissivity of the cooling fin surface.
The effect of the radiation plates was measured by running thermal experiments with the assembled lighting system. The experiment was performed at an LED drive current of I=0.5 A. Once steady state temperature was achieved, the radiation plates were removed and the system was monitored until steady state was reached. Thermocouples were used to monitor the temperature of light assemblies 1, 3, and 9. The thermocouples were attached to the substrate of one LED on each of the lighting assemblies. Temperature at a steady state for the three lighting assemblies, with and without radiation plates, is shown in Table V.
Table V shows the lower operating temperature observed with the radiation plates and demonstrates the advantage of using radiation plates.
Advantages of the lighting systems and assemblies of the present application include, for example, low maintenance, energy efficiency, low lifetime cost, up to 20% improved efficiency over competing lighting systems, up to 50% fewer LEDs required to generate the same brightness, dynamic control dimming, and improved light color.
Illustrative embodiments of this disclosure are discussed and reference has been made to possible variations within the scope of this disclosure. These and other variations and modifications in the disclosure will be apparent to those skilled in the art without departing from the scope of the disclosure, and it should be understood that this disclosure is not limited to the illustrative embodiments set forth herein. Accordingly, the disclosure is to be limited only by the claims provided below.
The present application claims priority to U.S. Provisional Patent Application Ser. No. 61/171,655 and filed Apr. 2, 2009, which is incorporated herein by reference as if fully set forth.
Number | Date | Country | |
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61171655 | Apr 2009 | US |