Patent Grant
9406654
The present disclosure relates generally to light devices incorporating LEDs and in particular to a package for a high-power LED device.
A light-emitting diode (LED) is a semiconductor device that produces light when an electric current is passed through it. LEDs have many advantages over conventional lighting sources, including compact size, improved energy efficiency, longer life, and higher reliability. LEDs have traditionally been used in applications such as indicator lights. More recently, LEDs also have become an important alternative light source for various applications where incandescent and fluorescent lamps have traditionally dominated. For such applications, high brightness (and therefore high operating current) is generally desirable.
To provide an operational lamp, one or more LEDs are typically mounted on a an electrically insulating substrate (e.g., ceramic) that can be patterned with conductive pathways to supply electrical current to the LEDs. For example, LEDs can be wire-bonded to the conductive pathways using metal pads disposed on an upper surface of the substrate. The LEDs and portions (or all) of the substrate are usually covered with one or more layers of optically transparent and/or wavelength-shifting materials, in some cases including a primary lens to direct the exiting light. The substrate is mounted on and electrically connected to a metal-core printed circuit board (MCPCB). The MCPCB provides electrical contacts and mechanical couplings. This combination of LEDs, substrate, MCPCB, and optical materials is sometimes referred to as a “package.” A package can be incorporated into a lamp or other lighting apparatus that may include additional components such as a secondary lens, heat sink, mechanical and/or electrical connections allowing installation into a light fixture, and so on.
In operation, an LED package generates heat, partly due to the LEDs themselves and partly due to the resistivity of the electrical paths connected through the MCPCB and substrate to the LEDs. A buildup of heat within the package can adversely affect device performance and/or cause device failure. Accordingly, packages that can prevent excessive heat buildup during device operation are desirable.
Certain embodiments of the present invention provide interface structures that can facilitate heat transfer from an LED package to a heat sink. The package can include a number of LEDs (e.g., four or more, although no particular number is required) mounted on a ceramic substrate that provides electrically conductive pathways to the LEDs. In some embodiments, a peripheral region of a top surface of the substrate is patterned with contact pads that can be used to electrically connect the substrate (directly or indirectly) to a power source, while a bottom surface of the substrate is patterned with a thick, thermally conductive supporting plate (which can be made of metal and/or other materials with high thermal conductivity) that can be attached to an external heat sink. The peripheral contact pads on the top surface and the supporting plate on the bottom surface can be roughly of equal thickness to help balance thermal stresses on the substrate and prevent deformation or warping.
Certain aspects of the invention relate to light device packages. In some embodiments, a package can include a substrate (e.g., a square substrate). The substrate can have or more light-emitting diode (LED) chips disposed on a top surface. A thick supporting plate (e.g., a circular plate made of metal such as copper and/or other materials with high thermal conductivity) can be disposed over at least a portion of the bottom surface of the substrate, and thick contact pads (e.g., made of metal and/or other electrically conductive materials) can be disposed on the top surface of the substrate. The thick contact pad can be electrically connected to the one or more light-emitting diode chips. For example, the substrate can include one or more ceramic layers, and metal traces can be disposed on and/or between the layers.
The bottom supporting plate and the thick contact pads can each include an interface layer made up of sub-layers of different metals, including, e.g., a tungsten sub-layer and a nickel sub-layer, a gold sub-layer, and/or a silver sub-layer. The interface layer can be disposed directly on the surface of the substrate and a layer of copper or other metal (which can be considerably thicker than the interface layer) can be disposed directly on the interface layer. In some embodiments, the bottom supporting plate can have grooves on its surface that terminate at a peripheral edge of the plate.
In some embodiments, a cover member can be disposed over the top surface of the substrate. The cover member can have a housing made, e.g., of an electrically insulating material such as plastic, with an opening to emit light from the one or more LED chips and a metal contact attached to an underside of the housing. The metal contact can be arranged such that a portion of the metal contact is held in contact with the thick contact pad on the top surface of the substrate by a spring force. An external electrical connector can be disposed at a peripheral edge of the housing, and the metal contact can be electrically connected to the electrical connector.
In some embodiments, the light device package can be incorporated into an assembly that includes a heat sink. For example, the supporting plate on the bottom surface of the substrate can be secured to the heat sink, e.g., using thermally conductive adhesives or solder. The cover member can be secured to the heat sink using fasteners (e.g., screws, nails, pins, clamps, adhesives, etc.) at the peripheral edge of the housing.
The following detailed description together with the accompanying drawings will provide a better understanding of the nature and advantages of the present invention.
Certain embodiments of the present invention provide interface structures that can facilitate heat transfer from an LED package to a heat sink. The package can include a number of LEDs (typically four or more, although no particular number is required) mounted on a ceramic substrate that provides electrically conductive pathways to the LEDs. In some embodiments, a peripheral region of a top surface of the substrate is patterned with metal contact pads that can be used to electrically connect the substrate (directly or indirectly) to a power source, while a bottom surface of the substrate is patterned with a thick supporting plate (which can be made of metal and/or other materials with high thermal conductivity) that can be attached to an external heat sink. The peripheral contact pads on the top surface and the supporting plate on the bottom surface can be roughly of equal thickness to help balance thermal stresses on the substrate and prevent deformation.
LEDs 106 can be light-emitting diodes that generate light of a particular frequency. Any type, color, or combination of LEDs can be used. For example, LEDs 106 can be blue LEDs (i.e., LEDs that emit light in the blue region of the electromagnetic spectrum) coated with yellow phosphors to produce white light. LEDs 106 can also include red LEDs, green LEDs, amber LEDs, blue LEDs, ultraviolet LEDs, infrared LEDs, and/or any other type of LED, with or without phosphor or other wavelength-shifting coatings.
Substrate 104 can be a single-layer or multi-layer ceramic substrate. In some embodiments, substrate 104 is formed from multiple layers of a ceramic material (e.g., alumina) that are patterned with metal traces (not shown), then fused together. Vias can be formed to connect metal traces at different layers. In some embodiments, the metal traces are arranged to provide separate electrical connections to different ones of LEDs 106, thereby allowing separate control of different LEDs, e.g., to adjust the color of emitted light.
In some embodiments, LEDs 106 are disposed within a circular recess region 112 on the top side of substrate 104. The top surface of substrate 104 within recess region 112 can be patterned with metal contact pads 107 (e.g., as shown in
In some embodiments, substrate 104 can be similar to substrates described in U.S. Patent Application Publication No. 2010/0259930. Other types of substrates can also be used. The dimensions of substrate 104 can be varied as desired, e.g., depending in part on the number and arrangement of LEDs 106. For example, substrate 104 can be square with dimensions of 0.7-5.0 cm on a side (e.g., 0.9 cm for one example of a substrate with sixteen LEDs 106) and a thickness of 0.5-2.0 mm (e.g., 1.0 mm for one example of a substrate with 16 LEDs 106).
Primary lens 108 can be used to focus or direct light generated by LEDs 106. In some embodiments, the lower portion of lens 108 is shaped to fit into and partially fill recess region 112 as shown in
The bottom surface of substrate 104 can be partially covered by a supporting plate 118 (shown in
In some embodiments, part or all of the bottom surface of substrate 104 can be covered with thin sub-layers of other metals, to provide an interface layer that reduces thermal stress between supporting plate 118 and the ceramic material of substrate 104.
To facilitate electrical connections, substrate 104 can have metal contact pads 114 disposed in a peripheral region surrounding recess region 112, as shown in
Substrate 104 can provide electrical pathways connecting peripheral contact pads 114 to LED contact pads 107. For example, as described above, metal traces can be disposed on and/or between layers of substrate 104, and these traces can provide the electrically conductive pathways. Accordingly, peripheral contact pads 114 be used to provide operating power to LEDs 106. As described below with reference to
As shown in
Cover 110, which can include an electrical connector 116, can provide electrical connectivity to substrate 104, as well as protection from the elements.
As shown in
Projecting leads 316 of frame 310 as well as metal leads 312, 314 can each be bent downward to provide a spring-force contact with peripheral contact pads 114 (
As noted above, in some embodiments, bottom supporting plate 118 can be solder bonded to a heat sink 102.
In this arrangement, it is desirable to reduce or prevent the occurrence of solder voids in solder 504, which can interfere with heat transfer and cause local “hot spots” in bottom supporting plate 118 and/or substrate 104. In some embodiments, solder voids can be reduced or eliminated by providing grooves in bottom supporting plate 118.
As shown, the bottom surface of substrate 604 is largely covered by a supporting plate 618 (e.g., a copper plate) that has grooves 620 formed therein. In this example, grooves 620 extend all the way across the diameter of supporting plate 618. In other embodiments, other groove patterns can be used, including curved patterns and patterns in which the grooves do not extend all the way to the center of supporting plate 618. Grooves 620 can provide a channel for air to escape during the soldering process, thereby reducing the number and/or size of solder voids in solder layer 504 of
The number and dimensions of grooves 620 can be selected to provide one or more paths for air to escape. In some embodiments, grooves 620 can have a depth equal to or less than the thickness of supporting plate 618. For example, in one embodiment, grooves 620 can be approximately 0.23 mm wide and 0.07 mm deep; width and depth can be varied. In some embodiments, the number and width of grooves 620 can be chosen such the area occupied by the grooves is 15% or less of the area of plate 618.
Grooves 620 can be formed by various processes, e.g., cutting or stripping away metal after plate 618 is formed on or attached to the bottom of substrate 604.
Where thermal adhesives are used instead of solder to attach package 100 to a heat sink, it may be useful to use a bottom supporting plate that does not have grooves. Accordingly, it is to be understood that bottom supporting plate 118 of
In some embodiments, bottom supporting plate 118 provides efficient heat transfer from substrate 104. The thickness of bottom supporting plate 118 can also provide mechanical support that can facilitate attaching substrate 104 directly to a heat sink without an intervening MCPCB, even if the surface of the heat sink is not particularly flat or smooth.
Previous packages have relied on a metal-core printed circuit board (MCPCB) disposed under the ceramic substrate to provide mechanical support and external electrical connections, as well as heat spreading. Embodiments described above allow for elimination of the MCPCB. For example, mechanical support can be provided by a bottom plate (which can be made of thermally conductive materials, such as copper or other metals, graphite or graphene, and/or other thermally conductive materials). External electrical connections can be provided by peripheral contact pads on the top side of the substrate. In some embodiments, the peripheral contact pads can be designed to balance thermal stress associated with the bottom plate. A cover member can be provided to protect the substrate and to facilitate electrical connections to the peripheral contact pads. Where the MCPCB is eliminated, manufacturing cost saving and reduced form factors can be achieved.
In addition, the bottom plate can provide very efficient thermal transfer to a heat sink or other heat dissipation system, in some instances exceeding the thermal transfer performance of packages that use MCPCBs. The bottom plate can also act to spread heat generated locally within the substrate (e.g., within the metal traces), reducing the occurrence of hot spots that can limit device performance. Thermal resistance in some embodiments can be reduced by 50% or more relative to conventional packages. In some embodiments, packages described herein may allow an LED-based lighting device to operate at higher current (and therefore higher brightness) than has previously been possible.
While the invention has been described with respect to specific embodiments, one skilled in the art will recognize that numerous modifications are possible. For instance, all specific dimensions and materials identified herein are illustrative and not limiting, and drawings are not intended to be to scale.
Packages as described herein can be manufactured using conventional or other techniques. For example, a substrate can be formed by applying metal in desired patterns to layers of a ceramic material, then aligning and co-firing the layers to fuse them into a substrate, after which vias can be formed to interconnect metal at different layers. The bottom metal layer and top-side metal contacts can be formed before or after co-firing of the ceramic layers as desired. In some embodiments, interface layers can formed on the top and bottom surfaces of the substrate before co-firing the layers, and thicker metal (or other) layers can be applied after co-firing. LEDs can be attached and connected, e.g., using wire-bonding or the like, after the substrate (including top and bottom metal) has been fabricated.
While substrates formed from layers of ceramic material patterned with metal traces are described, other types of substrates can also be used. For example, some substrates can incorporate highly thermally-conductive materials such as graphite or graphene, e.g., between ceramic layers. The number and electrical connectivity of the LEDs can be varied as desired. In some embodiments, LEDs can be connected so as to form multiple independently-addressable groups of serially-connected LEDs, allowing different operating currents to be supplied to different groups of LEDs, e.g., to facilitate control of the color of output light. The shape and size of the substrate can be varied, e.g., depending on the size, number, and arrangement of LEDs and peripheral contacts.
Any type(s) of LED (broadly understood as any semiconductor device that emits light when a current is applied) can be used, including but not limited to conventional red, green, blue, amber, infrared, and ultraviolet LEDs. Further, different types of LEDs can coexist on the same substrate. Wavelength-shifting material (e.g., phosphor-containing material) may be applied to the surface of an LED, incorporated into the recess and/or optical elements such as a primary lens, or omitted entirely as desired. In addition, light sensors may be incorporated in place of some of the LEDs, and such light sensors might be used to provide feedback for adjusting the light output using automatic or manual control systems. Thus, any type of solid-state light device (including light emitters, light sensors, and/or any combination thereof) can be used in connection with packages described herein.
The cover described herein is also illustrative and can be varied. The cover housing can match the shape of the substrate or any other shape as desired. In some instances, a cover can be customized for a particular lighting application. Any type of connector can be incorporated into the cover, or electrical leads can simply be exposed at one or more sides (or on top) of the cover, allowing wires or the like to be attached. In some embodiments, the package may be supplied as a kit, with the substrate (including top-side contacts and bottom-side plate), LEDs, and lens as one assembled component and the cover as a separate component. A heat sink can be provided separately from the package, and any type of heat sink or other cooling technology can be used with the packages described herein.
Further, all materials, processes, and tools described herein are also merely examples and can be varied. For example, the particular metal sub-layers herein can be replaced or augmented with other electrically conductive materials, and more or fewer sub-layers could be used. Different processing techniques can be employed. In addition, all dimensions stated herein are for purposes of illustration and can be varied as desired.
The overall form factor of substrates or packages may be varied from the examples shown herein. Packages can be larger or smaller and need not be square in area; rectangular, circular, or other shapes can be substituted. Substrate thickness can also be varied; the recess can be varied in size and shape (or omitted entirely), and other form-factor modifications can be made.
In some embodiments, a package can include a primary lens or other refractive media and/or optically transparent media overlying and protecting the LEDs on the substrate. A packages can be incorporated into a lamp having any desired form factor; for example, using the compact substrates described herein, a lamp can be sized and shaped as a replacement for existing incandescent, halogen, or compact fluorescent light bulbs. Entirely new form factors are also contemplated. A lamp can incorporate a heat sink and/or any other thermal management structures that may be desirable to keep the bottom surface of the substrate sufficiently cool, i.e., at a temperature that provides safe operation of the LEDs given the intended device power.
Thus, although the invention has been described with respect to specific embodiments, it will be appreciated that the invention is intended to cover all modifications and equivalents within the scope of the following claims.
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