1. Field of the Invention
The present invention is in the field of illumination devices and, more specifically, light emitting diode (LED)-based illumination devices.
2. Description of the Related Art
Most lighting applications utilize incandescent or gas-filled bulbs, particularly lighting applications that require more than a low level of illumination. Incandescent bulbs typically do not have long operating lifetimes and thus require frequent replacement. Gas-filled tubes, such as fluorescent or neon tubes, may have longer lifetimes, but operate using dangerously high voltages, are relatively expensive, and include hazardous materials such as mercury. Further, both bulbs and gas-filled tubes consume substantial amounts of power.
In contrast, light emitting diodes (LEDs) are relatively inexpensive, operate at low voltage, and have long operating lifetimes. Additionally, LEDs consume relatively little power, are compact, and do not include toxic substances. These attributes make LEDs particularly desirable and well suited for many applications.
Although it is known that the brightness of the light emitted by an LED can be increased by increasing the electrical current supplied to the LED, increased current also increases the junction temperature of the LED. Excessive heat reduces the efficiency and lifetime of the LED. Advances in LED technology have brought increasingly bright LEDs. However, such increased brightness is accompanied by increased heat-generation.
Accordingly, there is a need in the art for lighting systems utilizing LEDs and which efficiently evacuate heat away from the LEDs so as to preserve LED lifetime.
In accordance with one embodiment, the present invention provides a light engine comprising, a light emitting diode (LED) module, a first housing, and a second housing. The LED module comprises an electrically nonconductive substrate having a first face and a second face, a first plurality of thermally conductive plates provided on the first face, and a second plurality of thermally conductive plates provided on the second face. Each of the second plurality of plates generally corresponds to a respective one of the first plurality of plates. The LED module further comprises a plurality of thermally conductive vias extending through the substrate. The vias are configured to transfer heat between respective ones of the first plurality of plates and the second plurality of plates. The LED module further comprises a plurality of LEDs arranged in a circuit defined on the first face, where heat generated by the plurality of LEDs is transferred to the first and second plurality of plates. The first housing is formed of a heat-conductive material and has an aperture. The LED module is mounted on the first housing so that the first plurality of plates is disposed adjacent to and thermally connected to the first housing and light from the plurality of LEDs is directed through the aperture. The second housing is formed of a heat-conductive material and connected to the first housing so that the second plurality of plates is adjacent to and thermally connected to the second housing. The LED module is sandwiched between the first and second housings.
In another embodiment, the first and second housings are fastened together such that the LED module sandwiched therebetween is subjected to substantial compression.
In another embodiment, the first and second housings comprise a cavity adapted to accept the LED module therewithin. The cavity has a depth that is less than a thickness of the LED module substrate.
In another embodiment the aperture is formed through a mount wall of the first housing, and the first face generally engages the mount wall so that the LEDs extend past the mount wall and into the cavity. The first face has an inner zone and an outer zone, and the LEDs are disposed in the inner zone, and the outer zone engages the mount wall.
In accordance with another embodiment, the present invention provides a light engine comprising a light emitting diode (LED) module, a first housing, and a second housing. The LED module comprises a generally flat metallic substrate having a first side and a second side, a circuit portion defined on the first side, and a mounting portion formed on the first side. A thin dielectric layer is formed on the circuit portion, a plurality of electrically conductive traces are disposed on the dielectric layer, and a plurality of LEDs are attached to the traces so as to be electrically connected one to another. The mounting portion is characterized by an absence of a dielectric layer. The first housing is formed of a heat-conductive material. The first housing has a mount surface with an aperture formed therethrough, the aperture is sized and configured so that the entire circuit portion fits within the aperture and at least part of the mounting portion of the first side engages the first housing mount surface. The second housing is formed of a heat conductive material and has a mount surface. The first and second housings are connected to one another so that the second housing mount surface engages the second side of the LED module substrate. The LED module is sandwiched between the first and second housings. First and second heat paths are defined, the heat paths extend from the LEDs to an associated circuit trace through the dielectric and to the metallic substrate. The first heat path extends from the metallic substrate through the first face to the first housing and to the environment. The second heat path extends from the metallic substrate through the second face and to the second housing and to the environment.
In another embodiment, the first face mounting portion comprises a substantially bare metal surface, wherein the first housing is metallic, and wherein the first housing mount surface engages the first face mounting portion so as to have metal-to-metal contact between the first face mounting portion and the first housing mount surface.
In another embodiment, the second face comprises a substantially bare metal surface and the second housing is metallic. The second face engages the second housing mount surface so as to have metal-to-metal contact between the second face and the second housing mount surface. The first and second housings may be connected so as to apply compression to the LED module mounted therebetween.
In a further embodiment, the second housing defines a compartment, and further comprising a power conditioner disposed generally within the compartment, the power conditioner conditioning an input power so as to transform the input power to an output power. The power conditioner is spaced from the second housing compartment so as to be thermally insulated from the second housing. The second housing compartment is defined in part by a compartment wall, and comprising a plurality of apertures formed through the compartment wall so as to provide ventilation to the compartment. The apertures may comprise slots.
In accordance with another embodiment, the present invention provides a light engine comprising a light emitting diode (LED) module and a first housing. The LED module comprises a nonconductive substrate having a first side and a second side, the first side having a first region and a second region. The LED module further comprises a plurality of conductive contact pads on the first region, a first plurality of thermally conductive plates on the second region, a plurality of light emitting diodes arranged in a circuit on the second region, a plurality of conductive circuit traces formed on the first side that communicate selectively with the plurality of conductive contact pads and the light emitting diodes, and a plurality of electrical components disposed on the plurality of contact pads. The plurality of electrical components is thermally insulated from the plurality of light emitting diodes such that a substantial portion of the thermal energy generated by the plurality of light emitting diodes is transferred to the first plurality of plates. The first housing is formed of a thermally conductive material and has an aperture. The light emitting diode module is mounted on the first housing so that light from the plurality of light emitting diodes is directed through the aperture. The first plurality of thermally conductive plates of the second region engage the first housing so that heat from the light emitting diodes is directed to the thermally conductive plates and further to the first housing.
In another embodiment, a thermally conductive plate is formed on the second side of the substrate and a conductive via extends through the substrate to thermally connect the second side plate with at least one of the contact pads in the first region.
In another embodiment, the light engine further comprises a second housing formed of a thermally conductive material. The second housing engages the second side plate so that heat from the first region is directed to the second side plate and further to the second housing. The light emitting diode module is sandwiched between the first and second housings. A first heat path is defined from the second region to the first housing, and a second heat path is defined from the first region to the second housing.
In another embodiment, the light engine further comprises a power driver power adapted to receive an input power and output a conditioned power, wherein the power driver is attached to the substrate so as to communicate with at least one of the contact of the first region while being thermally insulated from the second region. The second housing has an aperture formed therethrough. The second housing is attached to the first housing so that the substrate is sandwiched between the first and second housings and the power driver is thermally spaced from each of the first and second housings.
In another embodiment, the light engine further comprises a second plurality of thermally conductive plates formed on the second side of the substrate, each of the second plurality of plates generally corresponding to a respective one of the first plurality of plates. A plurality of thermally conductive vias extends through the substrate. The vias are configured to transfer heat between respective ones of the first plurality of plates and the second plurality of plates. The second plurality of plates is configured such that the first region is substantially thermally insulated from the second region. The second housing engages the second plurality of plates.
Further embodiments can include additional inventive aspects, and apply additional inventive principles that are discussed below in connection with preferred embodiments.
The present specification and figures present and discuss embodiments of light emitting diode (LED) modules and LED-based luminaires and LED-based light engines that employ such modules. Structure for the illustrated embodiments is discussed herein, as are methods for making such embodiments in accordance with the structure. It is to be understood that the specific embodiments disclosed herein are presented as examples, and the technology and principles described herein can be applied to other configurations and technologies that involve a circuit board with componentry mounted thereon.
Preferably, the circuit board comprises a body, or core, formed of a dielectric material, such as conventional FR4 material. Such material is not electrically conductive; thus electrical circuit traces, contact pads and the like can be placed on the circuit board body and be electrically insulated relative to one another. In the illustrated embodiment, the material from which the circuit board body 52 is FR4, which is not particularly heat conductive. More specifically, FR4 material has low heat conductance properties. Other embodiments may employ other materials for the core.
With reference to
The illustrated plates 68 are electrically conductive and are preferably large and flat. As such, the plates 68 spread heat generated by components mounted thereon over a large area. Heat generated by the components is drawn out of the components and spread across the corresponding plate. The plates are not limited to any particular shape or size, but preferably, the plates are sized to make the most effective use of the circuit board.
The contact pads 64, 72, 74 or solder pads, are configured to enable and support the mounting of certain electrical components on the circuit board 52 in a conventional manner in which connectors of the components are soldered to the contact pads 64, 72, 74. The electrical leads 76, or circuit leads, are electrically conductive portions that communicate electric current to contact pads 72. The contact pads 64, 72, 74 and electrical leads 76 are generally contiguous with one of the corresponding plates.
With continued reference to
A second lead 76b extends from the first front plate 68a into, but not electrically communicating with, a second front plate 68b. A second LED mount 70b comprises a first connector pad 72b disposed on the second lead 76b so as to be adjacent a slug pad 64b and second connector pad 74b disposed on the second plate 68b.
As shown in
In the illustrated embodiment the pads are portions or zones of associated leads and plates that are configured to accept attachment of components. More specifically, the pads are coated with a solder layer to facilitate such attachment, while the remainder of the leads and plates is covered with a protective mask layer.
The illustrated ninth plate 68i has a power return aperture 60 formed therethrough, which aperture 60 extends through the circuit board 52. A power return contact pad 62 is disposed about the power return aperture 60. The return power contact pad 62 communicates with and is part of the ninth plate 68i, and is also adapted to support wires of a power wire to be soldered onto the return power contact pad 62.
The illustrated embodiment provides a circuit architecture in which the first through ninth LED mounts 70a-i are arranged electrically in series.
With continued reference to
With continued reference to
In operation, each of the first through ninth LEDs 106a-i produces significant heat. Such heat is communicated to a larger surface area by transferring the heat to the associated front 68 and back plates 88 through both the smaller 84 and larger vias 80. The heat can then be evacuated from the plates 68, 88 to the housing 102 and the ambient environment. Thus, heat generated by each LED 106 is drawn away from the LED 106 and into the environment. In order to avoid potential damage to the die, heat is preferably transferred from the LED 106 at a rate that maintains the junction temperature of the die below a threshold value.
In the embodiment illustrated in
Thus, in the embodiment illustrated in
The LED module discussed above employs a particular structure in which nine LEDs are connected in electrical series. It is to be understood that other embodiments may employ principles as discussed above on configurations having more or fewer plates, leads and LEDs employing different mounting configurations and circuit architecture, such as electrically parallel configurations.
With reference next to
The illustrated luminaire 240 comprises the light engine 200 and an attached trim portion 210, and is configured to be used as a ceiling-mounted down-light. The trim 210 in this embodiment is generally bowl-shaped, so as to help direct light in a generally downward direction, and includes mount members 220 to help mount the luminaire 240 in place. The trim 210 is connected to the light engine 200 at a flange 230.
The light engine 200 comprises a first housing 204 and a second housing 206. Preferably both the first and second housings 204, 206 are formed of a heat-conductive material such as aluminum. As such, both housings can function as heat sinks. Although both illustrated housings comprise fins 218 to help transfer heat to the environment, it is to be understood that other structures that facilitate heat transfer may be employed.
The first housing 204 comprises a flange 226 adapted to complement and engage the trim flange 230. In some embodiments a lens 208 is arranged between the first housing 204 and the attached trim 210. Preferably the first housing 204 comprises a bowl portion 205, which generally aligns with a bowl portion 211 of the trim 210. A cavity 222 is formed in the back side of the illustrated first housing 204. The cavity 222 is defined by a cavity surface 223 and a surrounding circumferential cavity wall 225. The cavity wall 225 preferably is sized to accommodate at least a portion of the thickness of the LED module 202. Preferably the cavity wall 225 has a longitudinal length that is less than a thickness of the LED module circuit board 52. An aperture 224 is formed through the first housing 204, and allows light from the LEDs on the LED module 202 to be directed into the bowl portion 205 of the first housing 204 and out of the light engine 200. In the illustrated embodiment, the LED packages 106 extend through the aperture 224 beyond the cavity surface 223. In a preferred embodiment, bolts 236 extend through the first housing flange 226 to engage the trim 210 and secure it in place against the first housing flange 226.
With continued reference to
A compartment 228 is formed in the second housing 206, and, preferably, a power conditioner 216 is disposed in the compartment 228. The power conditioner 216 conditions power into a form palatable for LEDs. For example, in one embodiment the power conditioner 216 receives 120 VAC wall power and converts it into a DC current of 9V, 10V, 12V or the like, as necessary for the LEDs on the LED module. The power conditioner can also be configured to perform other functions with regard to power delivery, such as varying current or voltage to affect LED brightness. Preferably wires from the power conditioner extend through apertures in the front wall 209 of the second housing 206 and further through apertures in the LED module 202 to connect to contact pads on the LED module 202 so as to supply power to the circuit defined on the module.
A plate 212 preferably encloses the compartment 228 of the second housing 206. Preferably an o-ring 214 is provided about the circumference of the compartment opening so that the compartment 228 is substantially sealed from the environment when the plate 212 is secured to the second housing 206 using bolts 232 or a similar fastener. Preferably a watertight pathway is provided for outside power to be supplied to the power conditioner 216 in the compartment 228.
In assembly, preferably a tape such as a VHB tape is applied to the second side of the LED module 202, and the module 202 is adhered to the front wall 209 of the second housing 206. This ensures maintenance of a desired alignment of the LED module 202 to facilitate assembly, and also provides an electrically insulative layer preventing a short between contacts on the module 202 in embodiments where the second housing 206 is formed from metal. In some embodiments a thin dielectric gasket or tape is disposed between the cavity wall first housing and the front side of the LED module, also to electrically isolate the module contacts from the first housing. Preferably the dielectric is chosen to have low resistance to heat flowing therethrough so as to facilitate a heat pathway from the front plates to the first housing.
During manufacture of a circuit board, the copper surfaces of the leads, plates, and the like typically is “tinned,” which involves depositing a thin layer of solder on top of the copper. This thin layer of solder covers the copper layer, and prevents formation of an oxide on the copper layer, which oxide forms naturally upon exposure of the copper to the environment.
In one embodiment, when “tinning” a two-sided PCB, such as the circuit board of the LED module described above, both the first and second sides are “tinned,” even though the circuit components are mounted only on the first side. Thus, a thin layer of solder is applied to the copper layers on both the first and second sides. In some embodiments, a masking layer is applied on top of or instead of one or more of the tinning layers. The masking layer preferably serves a purpose of protecting the circuit board and giving it a finished look.
Another embodiment is depicted in
The back face of the circuit board 250 has copper back plates 262, and a thin layer of naturally-occurring oxide layer 266 is allowed to form on the back plates 262. In another embodiment, a mask layer may be disposed over the oxide layer 266.
The oxide that is allowed to form on the second side is difficult to remove, and would remain in place even if there were subsequent soldering. Solder does not stick particularly well to the oxide; thus, later-soldered-on components would not stick particularly well. On the other hand, the oxide layer does not form on the solder pads on the tinned first side. Thus, when electrical components are soldered into place on the solder pads, the solder process works well and the newly applied solder and components stick together very well, enabling a secure soldered connection of the electrical component to the associated solder pad on the circuit board.
Preferably, as discussed above, electrical components are soldered only onto the first side, and the second side of the circuit board is mounted flush with a heat sink or other high-heat-transfer material so that heat from the electrical components is directed from the first side of the PCB through the vias to the second side and then to the heat sink.
By purposefully not “tinning” the copper plates on its second side, the illustrated circuit board avoids the deposition of a layer of solder, which is not a good heat conductor. The naturally-occurring oxide layer is extremely thin, and thus heat transfer from the non-tinned second-side copper plates to the environment encounters significantly less resistance than if the second-side copper plates were tinned. As such, tinning only the first, component bearing side of the PCB improves the heat transfer properties of the module.
In still another embodiment, only a portion of the copper traces, even on a component-mounting side of a PCB, are tinned. For example, the solder layer for tinning is only applied to solder pads and the rest of the plates and traces are allowed to grow the oxide.
With reference next to
The embodiment depicted in
The illustrated circuit board body has a first, or front, side and a second, or back, side. Preferably the first side has areas of conductive material disposed thereon. More particularly, a plurality of conductive circuit traces 318, 328, 330, 340 are formed on the first side, and communicate selectively with several conductive contact pads 316, 332, 334 and plates 308, also formed on the first side. The contact pads 316, 332, 334, or solder pads, are configured to enable and support mounting of certain electrical componentry on the circuit board in a conventional manner in which connectors of the componentry are soldered to the contact pads. The circuit traces, pads and plates 308 preferably are formed of a layer of an electrically conductive material such as copper or other metals that have been etched, printed, or otherwise provided on the front side of the dielectric circuit board body.
The illustrated circuit board 302 is generally circular and has a circumferential outer portion 306, or second portion, and an inner portion 304, or first portion, surrounded by the outer portion 306. In the inner portion 304, first and second apertures 320, 324 are formed through the body 300 to provide an access for first and second power wires. A conductive power supply contact pad 322, 326 is provided at and around each power aperture 320, 324 so that a respective power wire extending through the aperture can be soldered or otherwise connected to the circuit board. As shown, the inner portion 304 of the circuit board 302 comprises several thin circuit traces 318 configured to communicate electrical power from the power-supply contact pads 322, 326 to several component contact pads 316, which provide solder pads for selected electrical components 319 such as, for example, controllers, integrated circuits, jumpers, power conditioners, dimmers, or the like. The circuit traces 318 effectively communicate electrical energy. However, due to their thin and narrow construction, they do not communicate much heat very effectively. A masking material may be provided over the traces 318, and a solder mask may be provided on the solder pads 316.
Continuing with reference to
Each of the plates 308 includes first and second inwardly-extending portions 314. An LED package mounting pad arrangement (LED mount) 338 is provided on and adjacent each inwardly-extending portion. Each LED mount 338 comprises a first LED connector pad 332 adjacent the associated inwardly-extending portion but not electrically connected thereto, a second connector pad 334 defined on the inwardly-extending portion, and a slug pad 336 also defined on the inwardly-extending portion.
Continuing with reference to
First and second LED mounts 338a, 338b are associated with the first plate 308a. As discussed above, circuitry disposed in the inner portion 304 of the circuit board is directed to conditioning the power for delivery to LEDs 106. A power supply trace 328 extends from the circuitry in the inner portion 304 and is split into first and second power traces 330a, 330b, which each lead to a respective first connecting pad 332a, 332b of each of the first and second LED mounts 338a, 338b.
With particular reference to
Continuing with reference to
Fifth and sixth LED mounts 338e, 338f are disposed at and adjacent a third mount plate 308c. A fifth power trace 330e extends from the second mount plate 308b to a first connector pad 332e of the fifth LED mount 338e, and a sixth power trace 330f extends from the first connector pad 332e of the fifth LED mount 338e to the first connector pad 332f of the sixth LED mount 338f. The second connector pads 334e, 334f of the fifth and sixth LED mounts 338e, 338f are contiguous with the third plate 308c as shown in
A return power trace 340 extends from the second pad 334f of the sixth LED mount 338f, which is electrically contiguous with the third plate 308c, back to the circuitry in the inner portion 304 of the circuit board. In summary, in the illustrated embodiment, electric power is provided to the inner portion, which includes circuitry and componentry to condition, dim or otherwise treat such electric power. The treated power is then communicated to the outer portion, in which LEDs convert the power into light and heat.
As discussed above, the body of the circuit board preferably is made of a non-heat-conductive material. Further, in the illustrated embodiment there is no conductive layer on the opposite or back face of the circuit board. Thus, heat that is created by each LED 106a-f is communicated through the corresponding slug to one of the first, second, and third plates 308a-c that are disposed in the outer portion 306 of the front face of the circuit board 302. Due to their relatively-large size, the plates are amenable to accepting such heat, and heat flows readily into the plates. A relatively small portion of heat from the LED die is communicated to the first and second connectors 124, 126 of the LED package 106. The heat that goes to the second connector 126 of the LED package 106 is also communicated to the associated plate 308. However, the first connector 124 is attached to a very narrow circuit trace 318. Although this circuit trace 318 will conduct some heat, its narrow construction and relatively-long length severely limits the amount of heat that it can conduct. The same is true for the power delivery trace 328 and the power return trace 340.
Due to this construction, substantially all of the heat generated by the LEDs is communicated to the relatively-large plates, which function as heat sinks. At the very least, each plate functions as a heat spreader to distribute the heat across a relatively large surface area for more efficient dispersion to the environment or an appropriate mount portion.
As just discussed, the power supply trace 328 and power return trace 340 preferably are sufficiently long and thin that they do not communicate a substantial amount of heat from the LEDs to the circuitry and componentry in the inner portion 304. Also, as discussed above, the componentry in the inner portion 304 of the circuit board 302 is mounted on a heat insulating material. Thus, the inner portion 304 is, in effect, a heat insulated zone, while the outer portion 306 is a heat management zone in which heat is generated and managed. In fact, since the heat from the LEDs is disposed on inwardly-extending portions 314 of each respective plate, and heat flows from LEDs to the respective inwardly-extending portions and then out to the rest of the plate, a heat pathway is defined from the LEDs outwardly toward the outer circumference of the circuit board and away from the inner portion 304, or insulated zone. As such, the componentry in the inner or insulated zone 304 is insulated from the heat generated by the LEDs.
With reference next to
The cavity 414 is configured so that the LED module 300 fits therein with the outer plates 308 of the front face of the circuit board 302 engaged with the engagement surface 420 and the LEDs aligned with the aperture 416. Preferably, an electrically-insulative material 417 is disposed between the engagement surface 420 and the plates 308. Preferably, such material is comparatively thin and most preferably has good heat conductance properties so that heat from the plates will readily flow through the layer and into the housing 404 through the engagement surface 420, but the plates 308 will be electrically insulated from the housing 404. In the illustrated embodiment, the inner portion, or insulated zone 304, of the circuit board 302 does not contact the housing 404. Thus, heat from the LEDs 106 that is communicated to the plates 308 and further to the housing 404 is not communicated to the inner portion 304. Most specifically, a heat pathway is established from the LEDs 106 away from the inner portion 304 to the plates 308, and further to the housing 404 for dispersal to the environment.
In the illustrated embodiment, the aperture 416 in the housing 404 preferably leads to a bowl-shaped portion 438 adapted to direct light in desired direction. The housing has a flange 418. A trim piece 410 preferably has a complementary flange 422 and a further light-directing bowl 423. The housing and trim piece flanges 418, 422 are preferably engaged so as to attach the housing 404 to the trim piece 410, thus constructing an attractive and effective luminaire. Preferably the trim piece is constructed of a heat-conductive material, and tightly engages the housing so as to further assist in heat dispersal to the environment. Mounts 412 may be provided for mounting the luminaire as desired.
In the illustrated embodiment, a lens 408 is provided in a space between the housing 404 and the trim piece 410. Fasteners 424 such as bolts preferably attach the trim flange to the housing flange. Bolts 425 can also be employed to attach the circuit board body 302 to the housing 404. In other embodiments, the circuit board 302 may be attached by an adhesive. Preferably, such an adhesive would be electronically nonconductive, but would allow heat to flow from the circuit board 302 to the housing 404.
In the illustrated embodiment, and as best shown in
In another embodiment, the housing is configured to include a trim portion integrally formed therewith. The housing and its associated trim portion can be configured into various shapes and sizes, and may or may not include a cavity for mounting the LED module.
In each of the above-discussed embodiments, the circuit board is circular, as is the housing cavity, which preferably is specially configured to accommodate the circuit board. It is to be understood that, in other embodiments, circuit boards having various shapes and sizes may be employed as desired, while still practicing inventive principles as disclosed herein.
With reference next to
Since there is no substantial heat pathway between the plates 456 on the first side of the board 452, which are associated with the LED heat, and the plates on the second side of the board 454, which are associated with the first zone heat 462, the heat from a second or heat management zone 464 and the heat from the first zone 462 is managed separately, along generally independent heat pathways. This is particularly beneficial when the heat generated in the second zone 464 (such as by the LEDs) is substantially greater than the heat generated by componentry in the first zone 462, because managing such heat-generating components in common could result in componentry of the first zone 462 being exposed to greater temperatures because of common heat management with the LEDs. In another embodiment, a separate heat management system for the insulated zone may be used even if the componentry does not generate substantial heat on its own.
In the illustrated embodiment, there is substantially no overlap between the plates 456 on the first side 452 of the circuit board 450 and the plates 458 on the second side 454 of the circuit board 450. In other embodiments, there may be overlap, but the opposing plates are still insulated relative to one another by the heat-insulative thickness of the circuit board.
Preferably, and as shown in
With reference next to
In the illustrated embodiment, preferably no heat conductive plate is disposed opposite or overlapping the first or insulated zone 532 of the circuit board 520. This in addition to the heat-insulative character of the circuit board material itself, helps assure that the first zone 532 is insulated from heat generated by the LEDs and communicated to the second or heat management zone 534 of the board. In another embodiment, the back plates may overlap portions of the insulated zone. However, the heat-insulative circuit board material is still disposed between the plates and the insulated zone.
The embodiments of
With reference next to
In the illustrated embodiment, a power driver 554 extends through the aperture 560 in the second housing 546 and directly engages the circuit board 520. Though mounted to the same circuit board 520 on which the LEDs are mounted, preferably the power driver 554 communicates initially with componentry in the first, or insulated zone 532, and is thus insulated from heat generated by the LEDs. Since the power driver 554 also does not contact either housing 544, 546, it is isolated from the heat path from the LEDs to the housings 544, 546.
With reference next to
In one embodiment, the circuit board body 580 is a heat-conductive material such as aluminum. In the first zone, a thin dielectric layer is disposed on a first, or front, face of the aluminum body 580, and a circuit comprising a plurality of conductive traces, such as copper traces, contact pads, plates and the like is defined on the dielectric layer so as to be electrically insulated from the conductive aluminum body 580. A plurality of LEDs 106 is mounted on the conductive traces so as to complete a circuit.
A pair of apertures 591 is formed through the body 580 in the first zone 590. Preferably a conductive contact pad 593 surrounds each aperture 591, and a circuit through the LEDs 106 is defined between the pads 593 so that power provided across the pads 593 supplies power to the LEDs 106.
As the body 580 in this embodiment is aluminum, it readily accepts heat flowing from the LEDs 106 to associated traces, through the dielectric layer and to the body 580, which can function as a heat sink. Preferably the dielectric layer is configured to electrically insulate the traces, but facilitates heat flow therethrough. Also, preferably the second zone 592 of the first face and a second, or back, face of the body are configured to facilitate heat transfer to the environment or one or more adjacent heat sinks. Most preferably, the second zone and the second face are substantially uncoated, bare aluminum so as to minimize resistance to heat transfer to an engaged surface. In other embodiments a thin thermal pad such as a silicone gasket can facilitate adhesion between surface and/or can enhance surface contact for rough-surfaced metal surfaces.
The first housing 604 comprises a flange 630, or circular rim, adapted to complement and engage a decorative trim, which may be similar to the trim illustrated in
A compartment 634 is formed in the second housing 606 having a front wall 636 and a circumferential wall 637. A plurality of spaced-apart longitudinal slots 608 are formed through the wall 637 between successive fins 616 about the circumference of the compartment 634. A plurality of apertures (not pictured) extends through the front wall 636. A cavity 638 is also formed on the front wall 636 of the second housing 606. The cavity 638 is defined by a cavity surface and a surrounding circumferential cavity wall. The cavity wall preferably is sized to accommodate at least a portion of the thickness of the LED module 602.
The second housing 606 fits generally behind the first housing 604 and, preferably, is aligned therewith. The LED module 602 thus is sandwiched between the back face 629 of the first housing 604 and the front wall 636 of the second housing 606. Preferably substantial compression is exerted on the LED module 602, so that conductive faces of the module 602 fit tightly against the housing surfaces 629, 636, thus providing a more efficient and effective heat transfer junction between the module 602 and the housings 604, 606. It should also be noted that because the LED module 602 is formed from a conductive material, no adhesive is necessary to engage the LED module 602 with the first and second housings 604, 606, and preferably no dielectric layer is disposed on either the second zone 592 of the body 580 front face or on the second face of the body. As such, when the module 602 is sandwiched between the housings 604, 606, the aluminum body 580 makes metal-to-metal contact with opposing housing surfaces 629, 636.
Preferably, a power conditioner 614 is disposed in the compartment 634 in the second housing 606. The power conditioner 614 comprises componentry 615 that conditions input power into a form palatable for LEDs and supplies the power across power nodes 617. For example, in one embodiment the power conditioner receives 120 VAC wall power and transfers it into a DC current of 9V, 10V, 12V or the like, as necessary for the LEDs on the LED module. The power conditioner can also be configured to perform other functions with regard to power delivery, such as varying current or voltage to affect LED brightness.
In the illustrated embodiment, the power conditioner 614 does not have its own separate enclosure; rather, the components 615 are mounted on a circuit board 613. The circuit board 613 employs spacers 646 that electrically isolate the board from the second housing 606, thereby preventing a short from occurring between the power conditioner 614 and the second housing 606. Preferably, the spacers 646 are formed from a material that is not substantially heat conductive, and thus also thermally isolate the board 613 from the second housing 606. Preferably the board 613 fits within the compartment 634 so that it does not contact the wall 637.
Preferably, conductive bolts 622 extend through the apertures 591 in the LED module 602 and through apertures in the wall 636 of the second housing 606 to engage the power nodes 617 on the power conditioner 614. Preferably the heads of the bolts 622 engaged the contact pads 593, so as to supply power from the nodes 617 to the circuit on the LED module 602. A bolt guide 619 preferably accommodates the shanks of the bolts 622 through the space between the module 602 and the power conditioner 614 so as to electrically insulate the bolts from the housing. The mechanical and electrical configuration and interaction between the bolts and the module preferably shares similarities with the embodiments disclosed in copending U.S. application Ser. No. 11/434,663, filed May 15, 2006, which is owned by the assignee of the present application, and which is incorporated by reference in its entirety, particularly the disclosure relating to metal-core LED modules and supply of power from a power driver to LED modules by way of fasteners.
With continued reference to
With reference again to
Although certain componentry such as LEDs and integrated circuit chips are typically placed and soldered onto circuit boards through the “pick and place” machine and oven soldering procedure discussed above, typically such circuit boards are attached to power delivery wires after the LED module has been initially manufactured. For example, power delivery wires may not be soldered into place until an LED module 202 is place on a housing 102.
In some embodiments employing thermally managed configurations, it can be difficult to heat a contact pad sufficient to melt the solder so as to attach a power wire or the like because heat is evacuated from the contact pad faster than it can be added by a soldering iron. Also, in some instances, heat from soldering may be communicated to components mounted onto the circuit board. As such, soldering a component such as a wire to the circuit board outside of an oven can be difficult, time-consuming, and may require expensive materials and/or specialized, complex procedures.
Hand-soldering presents issues not encountered in the oven soldering process. During the oven soldering process, heat transfer away from the solder contact pads is not a problem because the entire circuit board is heated to the same temperature, and thus there is no substantial heat transfer between pads and plates.
In a preferred embodiment, a power contact pad or other pad to which a component is soldered is disposed on a plate or contact that has only limited heat transfer opportunity or ability. For example, with continued reference to
With reference next to
Continuing with reference specifically to
With additional reference to
With particular reference to
A first LED package 756 is mounted on the first LED mount 716 so as to extend electrically between the first connector pad 718 on the transition plate 714 and the second connector pad 720 on the first LED plate 706. Similarly, a second LED package 758 is mounted on the second LED mount 724 so as to extend between the first connector pad 726 on the first LED plate 706 and the second connector pad 728 on the second LED plate 708. Notably, the heat slug of the first LED package engages the slug pad 722 of the first LED plate, and thus heat generated by the first LED package is communicated to the first LED plate 706. Similarly, the heat slug of the second LED package engages the slug pad 730 of the second LED plate 708. As such, the majority of heat generated by the second LED package is communicated to the second LED plate. As shown in
With continued reference to
In this arrangement each of the power supply plates 710, 712 is insulated relative to electrical components that could be damaged if exposed to the heat of hand soldering. Also, the power supply plates 710, 712 are disconnected from structure that would evacuate heat from the plate. As such, the plates retain heat, and wires can be hand-soldered to the power supply contact pads on the power supply plates quickly and easily and without subjecting any components to potential heat damage. Preferably, and as discussed above, the electrical components mounted on the LED module are installed using a pick-and-place machine and soldering oven, but leaving select contact pads such as the power supply contact pads, to later be soldered to power supply wires.
With reference next to
Although this invention has been disclosed in the context of certain preferred embodiments and examples, it will be understood by those skilled in the art that the present invention extends beyond the specifically disclosed embodiments to other alternative embodiments and/or uses of the invention and obvious modifications and equivalents thereof. In addition, while a number of variations of the invention have been shown and described in detail, other modifications, which are within the scope of this invention, will be readily apparent to those of skill in the art based upon this disclosure. It is also contemplated that various combinations or subcombinations of the specific features and aspects of the embodiments may be made and still fall within the scope of the invention. For example, the principles discussed in connection with
This application is a continuation of U.S. application Ser. No. 12/632,759, filed on Dec. 7, 2009. This application also claims the benefit of U.S. Provisional Application Nos. 61/171,741, filed on Apr. 22, 2009, 61/154,106, filed on Feb. 20, 2009, 61/152,202, filed on Feb. 12, 2009, and 61/120,390, filed on Dec. 5, 2008. The entireties of each of these priority applications are hereby incorporated by reference.
Number | Date | Country | |
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61171741 | Apr 2009 | US | |
61154106 | Feb 2009 | US | |
61152202 | Feb 2009 | US | |
61120390 | Dec 2008 | US |
Number | Date | Country | |
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Parent | 12632759 | Dec 2009 | US |
Child | 13776543 | US |