1. Field of the Invention
This invention relates to light-emitting diodes or devices (LEDs), such as LED lighting assemblies and methods of manufacturing them. More particularly, this invention relates to white-light LED lighting assemblies, devices, and components, methods for packaging white-light LEDs, and LED devices produced thereby.
2. Description of the Related Art
In 1996, Nichia Chemical Industries in Japan developed a white-light LED by covering a blue LED with phosphor thereby mixing blue light and yellow light to create high brightness white light. Nowadays, the white-light LED is widely used for illumination.
Packaging is a very important process in producing the white-light LED. Conventionally, a packaging process comprises dropping transparent glue on a surface of an LED chip and coating the transparent glue with fluorescent powder. There are disadvantages, however, with such a method, including that the process is complex, and heat dispersion and light emission efficiency are poor, which makes it generally unsuitable for mass serial production. A similar known packaging method is described, for example, in U.S. Pat. No. 7,470,935.
Moreover, white-light LEDs, devices, components, and assemblies prepared by conventional packaging methods often exhibit undesirable characteristics, including that such devices are typically of complex structure, have low light emission efficiency, and have non-uniform chromatic light, which affect performance and popularity of the white-light LED.
In view of the above-described issues with conventionally-prepared white-light LED assemblies and devices, it is an objective of the present invention to provide a method for packaging a white-light LED comprising a simple production process, good heat dispersion, and high light emission efficiency, which is especially suitable for mass serial production.
It is another objective of the present invention to provide an LED device with simple structure, high light emission efficiency, and uniform chromatic light.
In accordance with one embodiment of the invention, provided is a method for packaging a white-light LED, comprising providing a substrate with a resin injection hole and a vent hole, a packaging housing, at least one LED chip, a supporting frame, and resin, and installing the LED chip on the substrate, coating an inner wall of the packaging housing with fluorescent powder, connecting the packaging housing to the substrate by way of the supporting frame, so that a cavity is formed therebetween, injecting the resin into the cavity between the packaging housing and the substrate by way of the resin injection hole so that gas within the cavity is discharged by way of the vent hole, and curing the resin.
Further, in one embodiment, installing an LED chip (semiconductor chip) on the substrate can comprise providing an adhesive on a concave part of the substrate, attaching the LED chip to the adhesive, and connecting electrodes on the LED chip to a conductive layer on the substrate.
In a further embodiment, coating an inner wall of the packaging housing with fluorescent powder can comprise combining inorganic non-baking glue, non-baking consolidant, non-baking dispersants, non-baking plasticizer and fluorescent powder into a mixture, adding ceramic grinding balls to the mixture and stirring using, for example, a ball-milling method. Optionally continuous stirring of the mixture can be employed to deter or prevent the fluorescent powder from precipitating. An inner wall of the packaging housing can be coated with the fluorescent powder coating mixture and the coating can be exposed to air, so as to dry or partially dry the coating and fix it onto the packaging housing. A fan can be used to provide a stream of air for exposing the coating to air for a time sufficient to stiffen said coating sufficiently so as to fix the coating on the packaging housing and make the coating immobile in shape. The coating can be cured by exposing the packaging housing to air, preferably hot and dry, or by putting the packaging housing into an oven. Excess or residual fluorescent powder can be removed from the packaging housing, if desired, after the fluorescent powder coating dries by evaporation.
In one embodiment, connecting the packaging housing to the substrate by way of a supporting frame, so that a cavity is formed therebetween, can comprise coating or plating part of the inner wall of the supporting frame with high reflecting material(s), installing the supporting frame on the substrate and installing the packaging housing on the supporting frame.
In embodiments, the supporting frame can be combined with the substrate by PLCC packaging.
In embodiments, the packaging housing can be installed on the supporting frame in a manner of interference fit.
Additionally, in embodiments, the packaging housing can be installed on the supporting frame in a manner of adhesion.
In accordance with the invention, LED devices are provided which comprise a substrate having at least one resin injection hole and at least one vent hole, at least one or a plurality of LED chips, a packaging housing and a supporting frame, wherein the supporting frame connects the packaging housing to the substrate, fluorescent powder is coated on an inner wall of the packaging housing, and resin is injected between the packaging housing and the substrate, so as to separate the LED chip from the fluorescent powder.
In embodiments of the invention, an upper surface of the substrate (typically the surface of the substrate intended to face the inner wall of the packaging housing) can comprise at least one or a plurality of concave depressions. The concave depressions operate to receive the LED chip(s) and can correspond in number with the number of desired LED chips. Optionally, a reflecting layer can be disposed on the outer surface of the concave depression.
Even further, according to the invention, embodiments can comprise a substrate comprising a printed circuit board (PCB), optionally with heat sink capabilities, a ceramic substrate, a metal circuit board, or a metal frame.
In embodiments of the invention, the substrate or a cross section of the substrate can be any shape, for example, rectangular, square, or circular, with a rectangular or circular shape being preferred.
In embodiments of the invention, the surface of the supporting frame can be configured so as to provide means or partial means for supporting the packaging housing and maintaining the packaging housing at a desired distance from the substrate when the LED device components are assembled. For example, the supporting frame can be shaped similar to a picture frame and comprise an upper surface defined by two surfaces, wherein a first surface lies in one horizontal plane and the second surface is interiorly concentric with the first surface and in a lower horizontal plane so as to form a step down from the first surface. The interior outline of the first surface defined by the step down of the second surface can comprise a shape which is complementary in shape to the outline of the packaging housing. The interior outline of the first surface and the stepped down second surface can together provide means for receiving and supporting the packaging housing within the supporting frame, i.e., the surface that faces the substrate when the LED device is assembled. Likewise, the invention includes a supporting frame capable of supporting the packaging housing in a similar manner but on the lower surface of the supporting frame. In a preferred embodiment, the supporting frame comprises means for receiving and supporting the packaging housing by way of the upper surface of the supporting frame, i.e., the surface that faces away from the substrate when the LED device components are assembled.
In embodiments of the invention, a plurality of positioning pins can be disposed on a lower surface of the supporting frame, i.e., the surface of the supporting frame that faces the substrate when the LED device components are assembled, so as to maintain a desired spacing between the packaging housing and the substrate and/or LED chips. This spacing, or cavity formed between the packaging housing and the substrate, provides for separation between the LED chips and the fluorescent powder coating by providing a cavity capable of being filled with resin to maintain the separation.
Even further, in embodiments, a plurality of positioning holes can be disposed on the substrate for receiving the positioning pins. Positioning holes can be holes that traverse the substrate and/or depressions in the substrate, typically complimentary in shape to the corresponding positioning pins.
In some embodiments, the substrate is combined with the substrate in a manner of PLCC packaging, wherein the substrate is a metal frame and the supporting frame is made of plastic.
Other embodiments can further comprise a supporting frame comprising high reflecting materials, which can be due to the material of the supporting frame itself or the inner wall (wall that faces the substrate when assembled) of the supporting frame can comprise a highly reflective material, for example, the inner wall of the supporting frame can be coated with a highly reflective material.
In a class of this embodiment or in another embodiment, the resin is made of transparent and soft silica.
In a class of this embodiment or in another embodiment, the packaging housing is made of glass.
In a class of this embodiment or in another embodiment, an outer surface of the packaging housing is planar free.
In a class of this embodiment or in another embodiment, the LED chips are disposed on the substrate in a rectangular or circular manner.
The method for packaging a white-light LED of the invention features a simple production process and is especially suitable for mass serial production and packaging having multiple chips, large area and white light generated by activating fluorescent powder with LED chips. Moreover, products produced by the method tend to have good luminous efficiency and heat dissipation performance. In addition, color and brightness of the white light are improved. One feature of the LED devices of the invention is the simple structure. Since the fluorescent powder is disposed on the inner wall of the packaging housing, the LED device emits white light with uniform chromatic light. In addition, the resin disposed between the packaging housing and the substrate improves heat dispersion and light emission efficiency of the LED device.
Reference will now be made in detail to various exemplary embodiments of the invention. The following detailed description is presented for the purpose of describing certain embodiments in detail. Thus, the following detailed description is not to be considered as limiting the invention to the embodiments described. Rather, the true scope of the invention is defined by the claims.
As shown in
In step S102, one or more LED chip(s) can be installed on the substrate, or can be provided as part of the substrate, for example, if previously installed or otherwise incorporated into or combined with the substrate.
In step S103, fluorescent powder can be coated on an inner wall of the packaging housing, which can be can be made of glass or other equivalent material, including but not limited to various plastics.
In step S104, the packaging housing can be connected to the substrate, for example as in this embodiment, by way of the supporting frame, so that a cavity is formed between the packaging housing and the substrate.
In step S105, the resin can be injected into the cavity formed between the substrate and the packaging housing by way of the resin injection hole(s) and gas within the cavity can be discharged by way of the vent hole(s). In embodiments, material injected into the cavity between the substrate and packaging housing can consist essentially of resin, i.e., not comprise fluorescent material. In this embodiment, the resin is made of transparent and soft silica. Compared with protected gas, thermal conductivity of the silica is even greater, and thus heat dissipation performance of the silica is even better. Moreover, since the refractive index of the silica is between that of the packaging housing and that of the LED chip, while refractive index of the protected gas is close to that of air, luminous efficiency of the silica is even better.
During the resin injection process, the resin can be injected from a bottom surface of the substrate, as shown in
It should be noted that the resin injection process can be performed manually or mechanically.
Optionally, step S106 shows one embodiment in which the resin can be cured. The curing processing generally enables LED components to have higher intensity and reliability. In embodiments, curing can be performed by way of high-temperature baking. In other embodiments, ambient curing can also be employed. For example, the resin can be cured by way of high temperature baking in an oven at about 150+5° C., or at ambient temperature, such as about 25° C. The curing temperature is not critical and typically will depend on the resin material being cured. Indeed, any temperature from approximately room temperature to a high baking temperature, such as from 25° C. to 200° C., or any temperature in this range can be used depending on the specific resin material, other components of the assembly, and certain applications.
As shown in
As shown in
In step S1032, an inner wall of the packaging housing is coated with the mixture and air is blown on the coating to assist with fixing the coating in place on the inner wall of the packaging housing and making the coating immobile in shape. The amount of fluorescent powder in the coating and/or the amount of coating applied to the packaging housing can be adjusted for particular applications. In an exemplary embodiment, the fluorescent powder coating can be applied to the packaging housing with a thickness of the applied coating in the range of, for example, about 5 to 500 microns. Any thickness in this range can be used for the coating. Even further, various desirable thicknesses can be determined by the amount of fluorescent powder needed in combination with a particular light source to produce a desired lighting result.
In step S1033, the coating on the packaging housing can be cured by way of exposure to air, which is preferably hot and dry, or the packaging housing can be placed in an oven, and residual fluorescent powder on the packaging housing can be removed after the mixed solution evaporates.
As shown in
The method for packaging a white-light LED of the invention features a simple production process and is especially suitable for mass serial production and packaging having multiple chips, large area, and white light generated by activating fluorescent powder by way of LED chips. Moreover, products produced by the method have good luminous efficiency and heat dissipation performance. In addition, color and brightness of the white light are improved.
A conductive layer 11 is printed on a top surface and a bottom surface of the substrate 10 (referring to the orientation of the components shown in
An upper surface of the substrate 10 can comprise a plurality of concave parts 12 (depressions), as means for receiving the LED chip 20, which can be formed by an inwardly bent surface. In another embodiment, the concave part 12 is formed by stamping the heat sink, and optionally a reflective cup can be formed by coating the surface of the heat sink with silver. A reflecting layer (not shown) can be disposed on an outer surface of the concave part 12, such as a reflecting layer made of silver and capable of improving light efficiency.
As further shown in
Additionally, in other embodiments, the combination of the substrate and the supporting frame can be in a manner of PLCC packaging, wherein the substrate is a metal frame and the supporting frame is made of plastic. In typical PLCC (plastic leaded chip carrier) packaging, a metal frame (substrate) provides means for supporting one or more LED chips and provides electrical leads for the LED chip(s), while plastic is used to encapsulate the metal frame and can provide means for supporting a packaging housing, such as a lens.
The LED chips 20 are disposed at the bottom of the concave part 12. In this embodiment, the LED chips 20 are blue-light LED chips capable of emitting blue light, and are disposed on the substrate 10 in a matrix to form a planar light source. In another embodiment, the LED chips 20 can be disposed on the substrate 10 in other arrangements, and the number of LED chips 20 may be one.
The outer surface of the packaging housing 30 is typically planar as in this embodiment, and the packaging housing 30 is installed on the step 51 of the supporting frame 50 in a manner of interference fit or adhesion. The outer surface of the packaging housing can also be planar free in some embodiments. Upon installation of the supporting frame 50 and the packaging housing 30 on substrate 10, a closed cavity is formed between the packaging housing 30 and the substrate 10. The size of the cavity will depend on the lighting application.
The fluorescent powder can be disposed on the inner wall of the packaging housing 30 (referring to the surface of the packaging housing 30 that faces the substrate when installed), and is capable of emitting yellow light as being activated by the blue light from the LED chip 20. The yellow light is mixed with part of the blue light passing through the fluorescent powder, and white light generated from the combination emerges from the device. For white-light emitting devices and applications, any type of fluorescent material, such as powder, and LED chip combination can be used, so long as the combination emits white light. For example, a yellow phosphor and blue LED chip(s), or yellow and red phosphors and blue LED chip (s), or green and red phosphors and blue LED chip(s), or RGB (red-green-blue) or multi-colored phosphors and UV LED chip(s) can be used to name a few. Even further, examples of fluorescent powders and light sources that can be used are described in U.S. Pat. Nos. 7,470,935; 7,071,616; 7,026,756; and 6,753,646; and U.S. Published Patent Application No. 2007/0262288, which are herein incorporated by reference in their entireties.
In particular embodiments, the number of the LED chips is not critical and can be any number appropriate for a particular application. For example, the substrate can comprise one or more than one LED chip. Further, for example, when more than one LED chip is desired, the LED chips can be arranged in any order, or format, or matrix desired. Multiple LED chips can be arranged in circular, square, or rectangular configurations if desired.
Further, for example,
It is important to note that the shape of the substrate does not dictate the multiple LED chip pattern and need not be the same shape as the arrangement of LED chips. Any combination of substrates and LED chips can be used. For example, a circular substrate can comprise multiple LED chips arranged in a rectangular or square configuration, if desired, or a rectangular or square substrate can comprise multiple LED chips in a circular format. If the number of the LED chips is greater than two, the conductive layer can be connected thereto in a manner of serial connection, parallel connection, or a combination thereof.
As shown in
Benefits of the LED device of the invention include simple structure, which contributes to ease of manufacturing, and uniform chromatic light produced as a result of fluorescent powder disposed on the inner wall of packaging housing 30. In addition, resin 40 disposed between packaging housing 30 and substrate 10 improves heat dispersion and light emission efficiency of the LED device.
The inventive LED assemblies and devices and methods of making them are applicable to a wide variety of applications, including for general illumination purposes, safety and security, signaling, backlighting, signage, decorative lighting, street lighting, and other area lighting, such as wall-mounted flood lights, post-mounted lights, and lights emitting large-area lighting, to name a few. Further, for example, the LED devices can be configured for various types of area lighting by designing the devices to comprise an appropriate number and formatting of the LED chips on the substrate to accommodate a desired range of lighting area. The devices can also be adapted to generate other colors of light in addition to white light by substituting the LED chip(s) and/or fluorescent material(s) accordingly.
The present invention has been described with reference to particular embodiments having various features. It will be apparent to those skilled in the art that various modifications and variations can be made in the practice of the present invention without departing from the scope or spirit of the invention. One skilled in the art will recognize that these features may be used singularly or in any combination based on the requirements and specifications of a given application or design. Other embodiments of the invention will be apparent to those skilled in the art from consideration of the specification and practice of the invention. The description of the invention provided is merely exemplary in nature and, thus, variations that do not depart from the essence of the invention are intended to be within the scope of the invention.
Number | Date | Country | Kind |
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200810141820.7 | Sep 2008 | CN | national |
This application relies on the disclosure and claims the benefit of the filing date of Chinese Patent Application No. 200810141820.7 filed Sep. 5, 2008 and of U.S. Provisional Application No. 61/091,072 filed Aug. 22, 2008, the disclosures of which are hereby incorporated by reference in their entireties.
Number | Date | Country | |
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61091072 | Aug 2008 | US |