WO2012090576A1 - 発光装置及びその製造方法 - Google Patents
発光装置及びその製造方法 Download PDFInfo
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- WO2012090576A1 WO2012090576A1 PCT/JP2011/074139 JP2011074139W WO2012090576A1 WO 2012090576 A1 WO2012090576 A1 WO 2012090576A1 JP 2011074139 W JP2011074139 W JP 2011074139W WO 2012090576 A1 WO2012090576 A1 WO 2012090576A1
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- Prior art keywords
- light emitting
- light
- emitting device
- metal member
- covering member
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Classifications
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F21—LIGHTING
- F21V—FUNCTIONAL FEATURES OR DETAILS OF LIGHTING DEVICES OR SYSTEMS THEREOF; STRUCTURAL COMBINATIONS OF LIGHTING DEVICES WITH OTHER ARTICLES, NOT OTHERWISE PROVIDED FOR
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- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L33/00—Semiconductor devices having potential barriers specially adapted for light emission; Processes or apparatus specially adapted for the manufacture or treatment thereof or of parts thereof; Details thereof
- H01L33/48—Semiconductor devices having potential barriers specially adapted for light emission; Processes or apparatus specially adapted for the manufacture or treatment thereof or of parts thereof; Details thereof characterised by the semiconductor body packages
- H01L33/50—Wavelength conversion elements
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L33/00—Semiconductor devices having potential barriers specially adapted for light emission; Processes or apparatus specially adapted for the manufacture or treatment thereof or of parts thereof; Details thereof
- H01L33/48—Semiconductor devices having potential barriers specially adapted for light emission; Processes or apparatus specially adapted for the manufacture or treatment thereof or of parts thereof; Details thereof characterised by the semiconductor body packages
- H01L33/52—Encapsulations
- H01L33/54—Encapsulations having a particular shape
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L33/00—Semiconductor devices having potential barriers specially adapted for light emission; Processes or apparatus specially adapted for the manufacture or treatment thereof or of parts thereof; Details thereof
- H01L33/48—Semiconductor devices having potential barriers specially adapted for light emission; Processes or apparatus specially adapted for the manufacture or treatment thereof or of parts thereof; Details thereof characterised by the semiconductor body packages
- H01L33/62—Arrangements for conducting electric current to or from the semiconductor body, e.g. lead-frames, wire-bonds or solder balls
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10—TECHNICAL SUBJECTS COVERED BY FORMER USPC
- Y10T—TECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
- Y10T29/00—Metal working
- Y10T29/49—Method of mechanical manufacture
- Y10T29/49826—Assembling or joining
Definitions
- the present invention relates to a light emitting device and a manufacturing method thereof.
- a pair of lead terminals is configured by a metal member 42 on which the light emitting element 41 is placed and a metal member 43 that is a pair thereof.
- the light emitting element 41 and the metal members 42 and 43 are embedded in the translucent member 44, and the sealing member 44 forms a convex portion 44a in a lens shape above the light emitting element 41. Further, the lead terminal is bent outside the sealing member.
- the mounting surface side of the light emitting element 51 of the metal member 50 is covered with a translucent resin 53, and the portion excluding the periphery of the light emitting element 51 of the metal member 50.
- a black resin 52 to prevent reflection on the metal member 50 other than the periphery of the light emitting element 51 and to prevent scattered light.
- the present invention has been made in view of the above problems, and an object of the present invention is to provide a light-emitting device capable of ensuring improved performance as well as improved light extraction efficiency.
- the present inventors have designed a light emitting device including the shape and arrangement of a metal member and a sealing member accompanying the downsizing and thinning of the light emitting device while ensuring high light extraction efficiency, and manufacturing efficiency for realizing the design.
- the present inventors have found a structure of a light-emitting device that can improve various characteristics, such as heat dissipation, strength of the light-emitting device, and lifetime, and have completed the present invention.
- a light emitting device comprising: a metal member having one surface on which the light emitting element is mounted and another surface opposite to the one surface; and a translucent member that seals the light emitting element and a part of the metal member.
- the metal member has an element mounting portion on which the light emitting element is mounted, and a flat portion disposed around the element mounting portion, A covering member is disposed on the other surface side of the flat portion, An upper surface and a side surface of the covering member are covered with the translucent member.
- the light emitting device according to [1] or [2], wherein the covering member exposes the one surface of the flat portion.
- the covering member covers the other surface of the flat portion and the outer periphery of the flat portion, the upper surface of the covering member substantially coincides with one surface of the flat portion, and the upper surface of the covering member and the The light emitting device according to any one of [1] to [3], wherein an upper surface of the flat portion is covered with the light transmissive member.
- the translucent member includes a convex portion and a flange portion disposed around the convex portion, and the flange portion is disposed outside the irradiation range of the light emitted from the light emitting element.
- the light emitting device according to any one of [1] to [4].
- [6] The light emitting device according to [5], wherein a part of the flat portion of the metal member is disposed in the flange portion.
- the metal member has a first bent portion bent toward the bottom surface side of the light emitting device continuously from the flat portion, and a second bent portion bent toward the side surface side of the light emitting device.
- the light emitting device according to any one of [1] to [6], wherein the covering member is covered from one bent portion to the second bent portion.
- the thickness of the flange on the upper surface of the flat part and the covering member is any one of [5] to [7], which is smaller than the thickness of the translucent member on the side surface of the covering member.
- Light-emitting device [9] The light-emitting device according to any one of [1] to [8], wherein the thickness of the translucent member on the flat portion and the upper surface of the covering member is 50 to 100 ⁇ m. [10] The light emitting device according to any one of [1] to [3] and [5] to [9], wherein the covering member further covers an outer periphery of the flat portion. [11] The light emitting device according to any one of [1] to [10], wherein the covering member exposes a bottom surface of the element mounting portion of the metal member and is disposed on an outer periphery of the element mounting portion. apparatus.
- the element mounting portion of the metal member is bent as a bottom portion of the light emitting device with respect to the flat portion, and is formed as a concave portion, [1] to [11] Light emitting device.
- a method for manufacturing a light emitting device of the present invention includes: (A) A metal member having an element mounting portion on which the light emitting element is mounted on one surface and a flat portion disposed around the element mounting portion is disposed in a mold, and at least the metal member Forming a covering member that covers the other side of the flat portion opposite to the one surface; (B) mounting a light emitting element on the element mounting portion of the metal member; (C) The metal member covered with the covering member is disposed in a second mold, and the upper surface and the lower surface of the covering member are sandwiched by the second mold, and a part of the metal member and the The method includes a step of forming a translucent member that covers an upper surface and a side surface of the covering member.
- step (a) In the step (a), one surface of the flat portion is exposed to form the covering member, In the step (c), the method of manufacturing a light emitting device according to [14], wherein the second mold sandwiches one surface of the flat portion, the upper surface of the covering member, and the lower surface of the covering member. [16] In the step (a), the bottom surface of the element mounting portion is exposed to form the covering member, The method for manufacturing a light emitting device according to [14] or [15], wherein in the step (c), the translucent member that exposes a bottom surface of the element mounting portion is formed.
- the light-emitting device of the present invention it is possible to obtain a light-emitting device that can ensure improved light extraction efficiency and further improved performance.
- the method for manufacturing a light emitting device of the present invention it is possible to efficiently manufacture a light emitting device with improved characteristics and excellent luminous efficiency.
- FIG. 1 is a perspective view showing an outer shape of a light-emitting device according to an embodiment of the present invention, in particular, a translucent member 14. It is a perspective view which shows the form except the translucent member in the light-emitting device of FIG. 1A. It is a top view of the light-emitting device (having the translucent member 14) of FIG. 1B. 1E is a cross-sectional view of the light emitting device of FIG. 1C taken along the line EE ′.
- FIG. 2 is a cross-sectional view taken along the line FF ′ for explaining the shape of the translucent member of the light-emitting device of FIG. 1C. It is a top view which shows the metal member 12 in the light-emitting device of FIG. 1A.
- FIG. 6 is a schematic cross-sectional view of a manufacturing process (corresponding to a cross section taken along line AA ′ in FIG. 4B) for explaining the molding of the covering member 15 of the light emitting device of the present invention. It is one manufacturing process schematic plan view for demonstrating shaping
- FIG. 6 is a schematic cross-sectional view of a manufacturing process (corresponding to a cross section taken along line AA ′ in FIG. 5B) for explaining the molding of the light-transmissive member 14 of the light emitting device of the present invention. It is a manufacturing process schematic top view for demonstrating shaping
- FIG. 10 is another schematic cross-sectional view of a manufacturing process (corresponding to a cross section taken along line AA ′ in FIG. 5B) for explaining the molding of the light-transmissive member 14 of the light-emitting device of the present invention.
- FIG. 5 is a schematic cross-sectional view (corresponding to a cross section taken along line EE ′ of FIG. 1C) of a main part showing another embodiment of the light-emitting device of the present invention. It is a perspective view which shows the external shape of another translucent member 24 of the light-emitting device of this invention. It is a perspective view which shows the form except the translucent member in the light-emitting device of FIG. 8A.
- FIG. 6 is a schematic cross-sectional view (corresponding to a cross section taken along line EE ′ of FIG. 1C) of a main part showing still another embodiment of the light-emitting device of the present invention. It is a schematic sectional drawing which shows the conventional light-emitting device. It is a schematic sectional drawing which shows another conventional light-emitting device.
- the light emitting device of the present invention is mainly composed of a light emitting element, a metal member, a translucent member, and a covering member.
- the translucent member and the covering member are members constituting a so-called package, and the both may be simply referred to as “sealing member”.
- “Sealing” means sealing by direct contact or non-contact.
- “upper surface” and “one surface (first surface)” are surfaces on the light extraction surface side of the light emitting device, in particular, “one surface” refers to the surface of the metal member, and “bottom surface” and “other surface (first surface)”.
- “Two surfaces” refer to the surface opposite to the upper surface and one surface (first surface), and in particular,“ other surface ” refer to the surface of the metal member.
- the “bottom surface of the light emitting device” refers to the bottom surface of the sealing member constituting the light emitting device.
- the light-transmitting property means a property of transmitting light emitted from the light emitting element by about 70% or more, preferably about 80% or more, about 90% or more, or about 95% or more.
- the light emitting element is a semiconductor light emitting element, and any element may be used as long as it is a so-called light emitting diode.
- a laminated structure including a light emitting layer is formed on a substrate by various semiconductors such as nitride semiconductors such as InN, AlN, GaN, InGaN, AlGaN, and InGaAlN, III-V compound semiconductors, II-VI compound semiconductors, and the like. What was formed is mentioned.
- an insulating substrate such as sapphire or spinel (MgA1 2 O 4 ) whose main surface is any one of C-plane, A-plane and R-plane, silicon carbide (6H, 4H, 3C), silicon, ZnS ZnO, GaAs, diamond; oxide substrates such as lithium niobate and neodymium gallate, nitride semiconductor substrates (GaN, AlN, etc.), and the like.
- Examples of the semiconductor structure include a homostructure such as a MIS junction, a PIN junction, and a PN junction, a hetero bond, and a double hetero bond.
- Each semiconductor layer constituting the light emitting element may be doped with donor impurities such as Si and Ge and / or acceptor impurities such as Zn and Mg.
- the light emitting layer may have a single quantum well structure or a multiple quantum well structure formed in a thin film in which a quantum effect occurs.
- the emission wavelength of the light-emitting element can be changed from the ultraviolet region to red by changing the semiconductor material, the mixed crystal ratio, the In content of InGaN in the light-emitting layer, and the type of impurities doped in the light-emitting layer.
- the metal member is usually electrically connected to a light emitting element and optionally a protective element or the like (hereinafter sometimes referred to as “light emitting element or the like”), and generally functions as a lead electrode and mounts the light emitting element or the like. Fulfill the function.
- a part of the metal member is embedded in a sealing member described later together with the light emitting element and the like. For this reason, the metal member extends within the sealing member as a mounting table for the light-emitting element and / or as a lead electrode (for example, an internal terminal) and the outside of the sealing member, and is electrically connected to the outside.
- a portion for example, an external terminal having a function of establishing a general connection.
- the material of the metal member is not particularly limited as long as it can fulfill these functions, but it is preferably formed of a material having a relatively large thermal conductivity. By forming with such a material, heat generated in the light emitting element can be efficiently released.
- a material having a thermal conductivity of about 200 W / (m ⁇ K) or more, a material having a relatively large mechanical strength, and a material that can be easily punched or etched are preferable.
- a metal such as copper, aluminum, gold, silver, tungsten, iron, nickel, or an iron-nickel alloy, phosphor bronze, iron-containing copper, etc. Examples include rubbed ones.
- the metal member is preferably formed of a conductive material (for example, Au or Au plating) having good electrical connection. Further, the surface of the metal member is preferably smooth in order to improve the reflectance.
- the element mounting portion or the element mounting portion and the outer peripheral portion thereof are preferably formed of a material having high reflectivity (for example, Ag or Ag plating).
- the metal member is usually formed with a uniform film thickness, but may be partially thick or thin.
- the entire metal member is made of Au or a surface thereof made of an Au plating material, and Ag or a surface thereof is made of an Ag plating material on the element mounting portion.
- Ag or Ag plating may extend not only in the concave portion but also on the flat portion, and the flat portion located on the outer periphery of the concave portion It is preferable that When the outer periphery of the concave portion is formed of an Ag plating material, if the width is too small, a portion of the concave portion may not be covered with the Ag plating material when misalignment occurs in the Ag plating spot.
- the outer peripheral width is suitably about 0.3 mm or less, and about 0.2 mm or less is suitable.
- the metal member has one surface on which the light emitting element is placed, and another surface opposite to the one surface, and an element placement portion on which the light emitting element is placed, and the element placement portion. And a flat portion arranged around the periphery.
- the shape of the metal member is not particularly limited, and can be appropriately determined in consideration of the shape of the light-emitting device, the number of light-emitting elements, the arrangement, the space where the light-emitting element can be arranged, and the like.
- the element mounting portion is a part that performs the function of mounting the light emitting element, and is preferably flat in order to efficiently emit light of the light emitting element to the upper surface thereof.
- the flat portion of the metal member 12 has a concave portion that is bent toward the bottom side of the light emitting device and is formed into a concave shape, and one surface (upper surface) of the bottom of the concave portion is formed. It is good also as the element mounting part 12a.
- the element mounting portion and the concave portion only have to have at least a bottom area on which the light emitting element can be mounted.
- a circular shape, an elliptical shape, a polygonal shape with rounded corners, or these shapes are used.
- the shape can be originally deformed.
- the size of the concave portion and the depth of the concave portion are such that when the light emitting element to be mounted is arranged at an appropriate position in the concave portion, the emission of light emitted from the light emitting element and its reflected light is not interrupted. Is suitable. In particular, it is preferable that the light emitted from the light emitting element and the reflected light are not blocked by the side surface or the upper edge of the concave portion. For example, it is suitable that the size of the bottom surface of the concave portion is larger than the occupied area of the light emitting element, and more than about 1.2 times the occupied area. The depth should just be more than the height of a light emitting element, about 0.1 mm or more is preferable and about 0.5 mm or less is preferable.
- the side surface of the concave portion may be vertical, but is preferably inclined so as to become narrower toward the bottom surface. For example, it is suitable to incline at about 0 to 45 ° and about 20 to 40 ° in the normal direction to the bottom surface. Thereby, the light from a light emitting element can be efficiently guide
- the flat portion 12d is arranged so as to surround the periphery of the element mounting portion (for example, the concave portion) 12a, and usually indicates a portion covered with a sealing member.
- a covering member is arranged on the other surface side of the flat portion.
- the flat portion may exist on the same plane as the element mounting portion. However, as described above, when the element mounting portion has a concave shape, the flat portion has a height different from the bottom surface of the concave portion. Has been placed.
- the planar shape of the flat part surrounding the periphery of the concave part is not particularly limited.
- a part of the flat part continuous from the concave part substantially follows the shape of the adjacent concave part ( In other words, it is preferably formed in the same or substantially the same shape as the concave portion or a corresponding shape (see a in FIG. 3).
- a round shape, an oval shape, a polygonal shape with arbitrarily rounded corners, or a deformed shape thereof can be used.
- the sealing member which seals a light emitting element can be stably formed in the shape along the outer periphery of a concave shape part.
- the flat part formed so that the shape of this adjacent concave part may be made to oppose the 2nd metal member 13 mentioned later.
- the outer contours of some other flat portions other than the above-described portions are similar to the planar shape of the sealing member (that is, the same or substantially the same shape).
- the shape may be a shape obtained by rounding corners of a polygon or a shape deformed based on these shapes. Thereby, the intensity
- Still another part of the flat portion is a region that functions as a so-called internal terminal and / or external terminal. Accordingly, it is suitable to have a shape extending to the side opposite to the above-described concave portion.
- the width of the region functioning as the extended terminal can be set as appropriate depending on the performance of the light emitting device to be obtained. For example, it is preferable that the diameter is equal to or slightly larger than the diameter of the concave portion.
- the flat portion can further be a region on which the above-described protective element or the like is placed. Further, when the metal member is sealed with a translucent member and / or a covering member, which will be described later, the flat portion can be easily sandwiched (held, clamped, etc.) by a simple upper and lower mold.
- the metal member having the element mounting portion is usually opposed to the second metal member serving as a pair of positive and negative electrodes with respect to the element mounting portion.
- the second metal member has a flat portion, and the flat portion preferably corresponds to the flat portion of the metal member described above.
- the flat part of the second metal member and the light emitting element are connected by a wire. Thereby, when a light emitting element is mounted on the element mounting portion, the distance of the wire between the light emitting element and the second metal member can be shortened, and wire breakage or the like can be prevented.
- the second metal member preferably has a shape that faces the element mounting portion of the metal member described above as an internal terminal and extends in a predetermined direction as an external terminal.
- These metal members and the second metal member do not need to protrude outside from the same surface (same direction) of the sealing member described later, and can protrude outside from a plurality of different surfaces (directions).
- the tips (that is, external terminals) of the metal member and the second metal member may be bent toward the bottom surface of the light emitting device, or may be bent toward the opposite side surfaces.
- the metal member and the second metal member preferably have a bent portion (see 12e in FIG. 3) that is bent toward the bottom surface of the light emitting device in the sealing member.
- the metal member has a bent portion (for example, a first portion) bent in the bottom direction in a sealing member (for example, a main body portion of a translucent member to be described later), particularly in a main body portion or a collar portion to be described later, depending on the width. It is preferable to arrange a bent portion.
- a bent portion By bending the metal member, the contact area between the metal member present in the sealing member and the sealing member can be increased, and as a result, peeling of the sealing member can be prevented. Further, the bent portion of the metal member acts like a fastener, and separation between the sealing member and the metal member can be effectively prevented.
- the metal member is bent in the sealing member toward the bottom surface of the light emitting device (preferably in a collar portion described later) (first bent portion), and further bent in the side surface direction of the light emitting device. It is preferable to have a bent portion (see 12f in FIG. 3) (second bent portion) and to protrude outside the sealing member. Thereby, the peeling and separation effects described above can be further ensured.
- the 1st bending part and the 2nd bending part are coat
- the other surface (lower surface) of the protruding portion of the metal member (that is, a part of the flat portion) is disposed on the bottom surface (most bottom) of the sealing member.
- the bottom surface of the light emitting device Preferably matches the bottom surface of the light emitting device.
- the bottom surface of the light emitting device is flush with the sealing member. Accordingly, the sealing member can be reinforced by the metal member, and the strength of the light emitting device itself can be improved.
- the flat portion of the metal member may be bent with a height difference that is larger than the depth of the concave portion.
- the other surface of a part of the flat portion of the metal member substantially coincides with the bottom surface of the concave portion (becomes substantially flush).
- a metal member for example, a surface near the flat portion and / or the bent portion has a depression, a through-hole 12 b or a notch 12 c (hereinafter referred to as “notch”) that determines or anchors the formation of the sealing member. It may be preferable to form a dent or the like.
- the depression or the like may be any one that can be disposed inside the sealing member to increase the contact area between them, or can fix a part of the sealing member. Thereby, the adhesiveness of a metal member and a sealing member can be improved more.
- the planar shape and arrangement, size, depth, and the like of the depressions are not particularly limited, and can be appropriately adjusted depending on the size of the light emitting device, the material of the sealing member to be used, and the like.
- the depression or the like is preferably disposed outside the light irradiation range from the light-emitting element, which can prevent light from being lost.
- the metal member usually has an electrical connection with the light emitting element, and optionally with the protective element, by wire bonding using a wire.
- the wire preferably has good ohmic properties with the electrode of the light emitting element, good mechanical connectivity, or good electrical and thermal conductivity.
- the thermal conductivity preferably 0.01cal / S ⁇ cm 2 ⁇ °C / than about cm further 0.5cal / S ⁇ cm 2 ⁇ °C / cm or higher order is more preferable.
- the diameter of the wire is preferably about 10 ⁇ m to 45 ⁇ m. Examples of such wires include metals such as gold, copper, platinum, and aluminum, and alloys thereof. The wire can be easily connected to the light emitting element, the metal member for wire bonding, and the wire bonding apparatus.
- the metal member may be provided with at least two of the first and second components described above in one light emitting device.
- the number of metal members is small, so that a shift in arranging each member substantially flush can be reduced. Therefore, manufacturing efficiency can be improved.
- the number of light emitting elements mounted on the metal member + 1 or more, or the number of light emitting elements mounted on the metal member may be two or more. For example, when only one light emitting element is mounted, the light emitting element is placed on one of the metal members, and is electrically connected to one electrode of the light emitting element, and the other metal member is the light emitting element. An electrical connection with another electrode may be taken.
- each light emitting element is mounted on a separate metal member, and electrical connection is made. Further, another metal member is configured to take another electrical connection corresponding to each light emitting element. Also good. In this way, a plurality of light emitting elements are mounted, and for each of them, independent wiring that is electrically connected to a metal member independently, various wirings such as series or parallel on the mounting surface of the light emitting device. It is possible to select a pattern and design a free circuit.
- the independent wiring it is easy to adjust the light emission intensity of the light emitting element to be mounted, which is particularly advantageous when using a plurality of light emitting elements having different light emission colors such as full color LEDs.
- the heat dissipation paths of the light emitting elements can be formed without overlapping. Therefore, the heat generated from each light emitting element can be dissipated uniformly, and the heat dissipation becomes better.
- the covering member is a member that functions as a package of the light emitting device together with a light transmitting member that will be described later.
- the covering member is made of a material harder than the light transmissive member. Harder than the covering member generally means that the hardness is high. The hardness in this case means that when both the light-transmitting member and the covering member described later are tested by the same hardness test method, the hardness value is larger than that of the light-transmitting member.
- the hardness value of the covering member varies depending on the test method, it is suitable that the hardness value of the translucent member is about 5% or more, about 10% or more, or about 15% or more (hard) by any test method. Yes.
- the covering member is preferably harder (harder) than the translucent member so that the test method of the covering member corresponds to its hardness and is different from the test method suitable for the translucent member.
- the covering member is formed of a material that does not have rubber-like elasticity. Or it can be said that it is formed with the material which has the hardness represented by indentation hardness.
- the indentation hardness is generally represented by the hardness according to the Rockwell hardness test and / or the Vickers hardness test.
- the Rockwell / Vickers hardness test is a well-known test method.
- the Rockwell hardness test when an initial test force is applied using an indenter, then the test force is applied and then returned to the initial test force, the penetration depth of the indenter with the initial test force twice before and after is returned. This is a method for measuring the thickness.
- the hardness can be calculated from the difference in penetration depth.
- the Vickers hardness test is a method in which a test force is applied to an indenter, the indenter is pushed into a sample, and a contact area between the indenter and the sample is measured. The hardness can be calculated as a value obtained by dividing the test force applied to the indenter by the contact area.
- the covering member may be represented by a Shore A hardness or a hardness according to a JIS-A hardness test.
- the Shore A hardness or JIS-A hardness test is a known test method. For example, there is a method in which an indenter is pushed into the surface of the object to be measured and deformed, and the amount of deformation (indentation depth) is measured and digitized.
- the Shore A hardness or JIS-A hardness exceeds 90, the Shore D hardness is usually used. Therefore, the covering member is preferably a material whose hardness is expressed by Shore D hardness.
- the Shore D hardness test is a known test method. This method differs from the JIS-A hardness test in the shape and size of the indenter and the indentation load.
- the Shore D hardness test is suitable for measuring a sample having a lower elasticity than the JIS-A hardness test.
- the fact that the covering member is hard means that, for example, the viscosity at the time of molding (melting) is larger than that of the translucent member.
- the viscosity at the time of molding differs depending on the material, but when the material constituting the covering member in an ordinary semiconductor process is melted at an appropriate temperature suitable for the material, the viscosity is about 10 Pa ⁇ s or more. It is suitable to have In consideration of actual production, about 100 Pa ⁇ s or less is preferable.
- An example of the molding temperature is 150 to 180 ° C.
- the difference in linear thermal expansion coefficient between the covering member and the metal member is smaller than the difference in linear thermal expansion coefficient between the translucent member and the metal member.
- the linear thermal expansion coefficient of the covering member is suitably about 100 ppm / K or less, preferably about 50 ppm / K or less. Furthermore, about 20 ppm / K or more is suitable.
- the linear thermal expansion coefficient of the metal member is smaller than that of a material normally used as a sealing member, for example, about 5 to 20 ppm / K.
- the difference in linear thermal expansion coefficient between the covering member and the metal member is preferably about 10 to 100 ppm / K.
- the covering member can be formed of, for example, polyphthalamide (PPA), epoxy resin, or the like.
- PPA polyphthalamide
- the covering member may be used by mixing various dyes or pigments as the colorant or diffusing agent partially described above with the material described above.
- the covering member is preferably arranged outside the irradiation range of the light emitted from the light emitting element. As a result, the light output of the light emitting device does not decrease even when a material having low light reflectivity such as a material mixed with carbon black or the like having a large light absorption as a colorant is mixed.
- a suitable material can be selected as the covering member.
- Such a covering member is disposed on at least the other surface side of the metal member (for example, refer to 15 in FIG. 1D). That is, it is suitable to cover at least a part of the other surface side of the flat portion of the metal member. Furthermore, it is preferable that a part of the outer periphery of the flat portion is covered, and it is more preferable that the entire outer periphery is covered (for example, refer to 15 in FIGS. 1B and 1D). In addition, the coating
- the covering member disposed on the outer periphery of such a flat portion has a part of the top surface of the metal member. It is preferable that it is substantially flush with one surface of the flat portion and is flush (see FIGS. 1B and 1D). In particular, it is more preferable that the corner portion of the flat portion substantially coincides with one surface of the flat portion, and it is preferable that the entire surface of the flat portion is flush with the one surface of the flat portion.
- the covering member is preferably arranged so that the upper surface and the lower surface thereof are in contact with the upper and lower molds, respectively.
- the covering member is arranged so that a part of the upper surface of the covering member substantially coincides with a collar portion described later, and the lower surface of the covering member constitutes the lower surface (bottom surface) of the light emitting device (see FIGS. 1C and 1D).
- the covering member is preferably disposed on the outer periphery of the element mounting portion with at least the bottom surface of the element mounting portion of the metal member exposed.
- the element mounting portion is formed of a concave portion, it is more preferable that the bottom surface of the concave portion is exposed and disposed on the outer periphery of the concave portion.
- route of a light emitting element is securable.
- the covering member is filled so as to surround the concave portion of the metal member, and the height of the lower surface (bottom surface) of the covering member substantially matches the height of the lower surface of the concave portion (that is, the lower surface of the covering member).
- the lower surface of the concave portion are preferably substantially flush with each other).
- the translucent translucent member is a member that seals a part of the light emitting element, optionally a protective element, and a metal member.
- a main body part 14c and a convex part 14a Have It is preferable that the translucent member covers at least a part of the upper surface of the covering member and the upper surface of the flat portion of the metal member, and further covers the side surface of the covering member. Therefore, it is preferable that a part of the flat portion of the metal member is disposed in the translucent member, in particular, in the collar portion described later.
- a light-emitting device can be generally formed into a cylindrical shape, an elliptical column, a sphere, an oval, a triangular column, a quadrangular column, a polygonal column, or a shape similar to these as a basic shape (the shape of a sealing member). Is formed into a square pole. Therefore, in the translucent member of the present invention, a main body portion constituting the basic shape and a convex portion functioning as a lens for condensing light, for example, are integrally disposed on one surface of the main body portion.
- the shape of the convex portion can be adjusted as appropriate depending on the light distribution form of the light-emitting device.
- various shapes such as a part of a sphere or egg shape, a polygonal bowl shape such as a square bottom surface, or a dome shape can be used.
- a part of a sphere or egg shape, particularly a hemispherical shape is preferable, and a shape whose center is located near the center of the light emitting element or the light emitting element mounting portion is preferable.
- the light extraction efficiency can be improved by increasing the size of the convex portion, and it is preferable that the convex portion be at least larger than the light emitting element mounting portion.
- the translucent member 14 is mainly composed of a light emitting element (not shown) and a metal member (not shown). It has a block-shaped main body part 14c that seals a part thereof. Furthermore, it is preferable to have a portion called a convex portion 14a disposed on the main body portion 14c and in a shape protruding from the main body portion 14c above the light emitting element (and its peripheral portion). .
- the flange portion 14b is integrally arranged on the outer periphery of the main body portion together with the main body portion and the convex portion. That is, as shown in FIG. 2, it is preferable that the surface is continuous with the convex part 14a, and it has the collar part 14b arrange
- the translucent member has a body portion 14 c having a width W, a depth, and a height H
- the convex portion 14 a has a diameter D and a height at a maximum value.
- T the collar portion 14b has a height equivalent to that of the main body.
- the width W, the depth, the diameter D, and the heights H and T are not particularly limited.
- the diameter D of the convex portion is substantially equal to the width W and / or the depth of the main body.
- the height T of the convex portion is preferably about 1 to 10 times the height H of the main body, and more preferably about 5 to 10 times.
- the width W is about 1 to 10 mm
- the depth is about 1 to 10 mm
- the height H is about 0.05 to 5 mm
- the diameter D is about 1 to 10 mm
- the height T is about 0.5 to 6 mm.
- the width W is preferably about 2 to 7 mm
- the depth is about 2 to 7 mm
- the height H is about 0.1 to 1 mm
- the diameter D is about 2 to 7 mm
- the height T is about 1 to 3 mm.
- the width W and the depth of the main body are substantially equal (for example, within a range of a length of ⁇ 5%). Thereby, the light distribution in the width direction and the light distribution in the depth direction can be made substantially equal.
- the width and the depth of the convex portion are substantially equal.
- the collar portion is outside the irradiation range of the light emitted from the light emitting element. It is suitable that it is shaped so as to be disposed in the area. It is preferable that the light emitting device is disposed in the bottom direction (downward) of the light irradiation range from the light emitting element.
- the irradiation range of light from the light emitting element is a range in which light emitted from the light emitting element reaches directly. Specifically, it can be defined by a straight line connecting the light emitting layer of the light emitting element and the surrounding light shielding member (for example, a metal member).
- the upper surface of the light emitting element may be used as a reference.
- the light irradiation range is defined by the shape and size of the concave portion of the metal member.
- the surface of the flange is infinitely close to the flat portion of the metal member so that the portion is not disposed at a position where the light emitted from the light emitting element passes but is disposed outside the region where the light reaches. It is suitable to be arranged. That is, it is preferable that the height (position) of the upper surface of the flange portion of the translucent member is substantially the same height (position) as the upper surface of the flat portion of the metal member.
- the translucent member preferably covers the light emitting element and the metal member so that the upper surface of the collar portion of the translucent member is substantially flush with the upper surface of the flat portion of the metal member.
- the substantially equivalent height here means that the upper surface of the metal member (and the covering member) existing inside the translucent member in plan view is not exposed from the translucent member, but is covered with a minimum covering thickness. From the side, it means that the minimum thickness is not generated. Similarly, “substantially flush” means that they are substantially flush or are coplanar with no height difference of only a minimum coating thickness.
- the minimum covering thickness means, for example, a degree that can be realized in the manufacturing process. Specifically, the thickness of the light-transmitting member on the flat portion of the metal member and the upper surface of the covering member is about 50 to 100 ⁇ m. 70 to 80 ⁇ m is preferable.
- the thickness is preferably about 1/5 to 1/10, more preferably about 1/5 to 1/7, of the height of the collar portion of the translucent member.
- this thickness is the transparent thickness that covers the side surface of the covering member.
- the thickness is preferably smaller than the thickness of the optical member.
- the collar portion By arranging / molding the collar portion in this way, the light from the light emitting element is transmitted to the upper surface of the metal member while ensuring the contact area between the translucent member and the metal member and preventing the peeling of both.
- the light extraction efficiency can be maximized without blocking the translucent member disposed.
- the total reflection of light on the surface thereof can be suppressed, so that absorption of light in the covering member can be prevented.
- the strength of the translucent member in the collar portion can be improved by the metal member and the covering member, a relatively thin collar portion can be formed while maintaining the strength, and the thickness of the entire light emitting device can be reduced.
- the surface of the convex portion can be used as a main light extraction surface. Therefore, when the light emitting device is handled, the main light extraction is performed. Devices such as tweezers can be brought into contact with the heel that is not a surface. Thereby, deformation and damage of the main light extraction surface of the light emitting device can be prevented, and a change in light distribution characteristics and a decrease in light output can be prevented.
- the element mounting portion of the metal member is arranged so that the bottom surface thereof is exposed from the bottom surface of the main body portion of the translucent member regardless of whether or not the element mounting portion has a concave shape.
- the concave portion it is suitable that the bottom surface of the concave portion is disposed so as to be exposed from the bottom surface of the main body portion. In the case of the latter, it is preferable to arrange
- position so that it may become substantially flush with the bottom face of a concave shape part.
- the bottom surface of the translucent member and the bottom surface of the concave portion substantially flush, the bottom surface of the light emitting element can be reinforced with the metal member. Therefore, it is preferable that the height H of the main body portion and the collar portion is slightly thicker (for example, +100 ⁇ m) than the sum of the depth of the concave portion and the thickness of the metal member.
- the translucent member Preferably covers at least part of the upper surface and side surfaces of the covering member, and more preferably covers all of the upper surface and side surfaces of the covering member. Furthermore, the translucent member may coat part or all of the bottom surface of the covering member. In this way, by covering the covering member with the light-transmitting member, that is, by covering the hard covering member with a softer light-transmitting member as will be described later, external stress on the covering member is absorbed. can do.
- the translucent member and / or the covering member that defines the bottom surface of the light emitting device are formed to be flush with each other. Thereby, the strength of the bottom surface of the light emitting device can be improved, and the reliability can be improved.
- the concave part is formed in the metal member, it is preferable that the translucent member and / or the covering member that defines the bottom surface coincide with the bottom surface of the concave part, that is, be flush with each other. .
- the bottom face of the concave portion can be reliably exposed from the sealing member, and the heat dissipation can be improved.
- the bottom surface of the concave portion can be brought into contact with the mounting substrate, and the mounting substrate can be used as a heat dissipation path, thereby further improving heat dissipation.
- the translucent member is formed of a material softer than the above-described covering member. Softer than the covering member generally means that the hardness is small. It can also be said that the translucent member is formed of a material having rubber-like elasticity. Or it can be said that it is formed with the material which has the hardness represented by dynamic hardness (rebound hardness).
- the dynamic hardness is generally represented by a Shore A hardness or a hardness according to a JIS-A hardness test.
- the hardness of the translucent member according to the JIS-A hardness test is, for example, about 65 or less, and preferably about 60 or less. By using such a soft material, the fatigue of the wire in the thermal shock test can be reduced.
- the hardness according to the JIS-A hardness test is about 20 or more, and preferably about 30 or more.
- the linear thermal expansion coefficient of such a highly elastic translucent member is, for example, about 200 to 300 ppm / K.
- the fact that the translucent member is soft means that, for example, the viscosity during molding (melting) is smaller than that of the covering member.
- the viscosity at the time of molding here differs depending on the material, but when the material constituting the translucent member in an ordinary semiconductor process is melted at an appropriate temperature suitable for the material, it is about 9 Pa ⁇ s or less. It is suitable to have a viscosity of about 5 Pa ⁇ s or less. By using such a material, molding defects can be prevented. Considering actual production, about 2.5 Pa ⁇ s or more is preferable.
- a silicone resin having a viscosity at 25 ° C. of about 3 Pa ⁇ s can be used.
- the translucent member is selected from materials that can ensure the insulation of the light emitting element and the metal member. Accordingly, for example, a translucent silicone resin is preferable as the one having the above-described hardness and characteristics. It has rubber-like elasticity, exhibits heat resistance, withstands high temperatures exceeding 200 ° C., and at high temperatures, the rate of deformation and decomposition is slow, that is, it has low temperature dependence and little influence on other members. This is because long-term reliability can be expected.
- the translucent member may be partially used by mixing various dyes or pigments as a colorant or a diffusing agent with the materials described above.
- the colorant include Cr 2 O 3 , MnO 2 , Fe 2 O 3 , and carbon black
- examples of the diffusing agent include calcium carbonate, aluminum oxide, and titanium oxide.
- a material in which a colorant and a diffusing agent are not mixed is used. Thereby, light scattering by the colorant or the diffusing agent can be prevented and total reflection on the surface of the translucent member can be suppressed, so that the light extraction efficiency can be improved.
- the translucent covering member may be disposed so as to cover the light emitting element.
- the translucent covering member is usually disposed in contact with the light emitting element.
- a translucent covering member may be disposed on a part or all of the concave portion so as to rise further from the concave portion.
- the translucent covering member is preferably formed of a material that can protect the light emitting element from external force, moisture, and the like and protect the wire that secures the connection between the light emitting element and the metal member.
- the translucent covering member examples include transparent resin or glass having excellent weather resistance such as epoxy resin, silicone resin, acrylic resin, urea resin, or a combination thereof.
- the translucent covering member may have any hardness.
- the translucent covering member is preferably made of the same material and the same composition as the sealing member, and may contain a diffusing agent or a phosphor substance.
- the thermal expansion coefficients of the sealing member and the translucent covering member can be made substantially equal. Therefore, it is possible to improve the impact resistance against a wire or the like arranged over both the sealing member and the translucent covering member. Furthermore, since the refractive index can be substantially equal, loss of light passing from the translucent covering member to the sealing member can be suppressed, and light extraction efficiency can be improved.
- the translucent covering member may use a different material, a different composition, or the like.
- the moisture contained in the resin can be obtained by baking at about 100 ° C. for about 14 hours or more. You can escape to the open air. Accordingly, it is possible to prevent water vapor explosion and peeling of the light emitting element and the above-described translucent member.
- the translucent covering member takes into account the adhesion between the translucent member and the translucent covering member when affected by the heat generated from the light emitting element, etc. It is preferable to select one with a smaller value.
- the translucent covering member may contain a diffusing agent or a fluorescent material.
- the diffusing agent diffuses light and can reduce the directivity from the light emitting element and increase the viewing angle.
- the fluorescent substance converts light from the light emitting element, and can convert the wavelength of light emitted from the light emitting element to the outside of the sealing member.
- Inorganic fluorescent materials such as 3 -SiO 2 are suitably used.
- the present invention when white light is obtained, in particular, when a YAG: Ce fluorescent material is used, light from the blue light emitting element and a yellow color which is a complementary color by partially absorbing the light can be emitted depending on the content.
- the system can be formed relatively easily and reliably.
- a nitrogen-containing CaO—Al 2 O 3 —SiO 2 fluorescent material activated with Eu and / or Cr is used in combination, the light from the blue light emitting element and a part of the light are absorbed depending on the content.
- a red color can be emitted, and a white color with improved color rendering can be formed relatively easily and reliably.
- the diffusing agent and the fluorescent material are contained only in the translucent covering member and not contained in the translucent member. Accordingly, light can be prevented from leaking to the side surface or the bottom surface side of the light emitting device due to light scattering by the diffusing agent or the fluorescent material.
- the translucent covering member can be formed by filling the recess as described above, and may be formed only around the light emitting element by screen printing, electrophoretic deposition, or the like. At this time, the translucent covering member may be composed of only a fluorescent material.
- the protective element is not particularly limited, and may be any known element mounted on the light emitting device.
- an element capable of short-circuiting a reverse voltage applied to the light-emitting element or short-circuiting a forward voltage higher than a predetermined voltage higher than the operating voltage of the light-emitting element, that is, overheating, overvoltage, overcurrent, protection A circuit, an electrostatic protection element, etc. are mentioned.
- a Zener diode, a transistor diode, or the like can be used.
- the protective element is placed outside the irradiation range of the light emitted from the light emitting element. Thereby, the light absorption in a protection element can be suppressed.
- the protective element is preferably placed on a metal member provided with the light emitting element placement portion and a metal member separated from the metal member to which the wire of the light emitting element is connected. Furthermore, it is preferable to mount on the metal member arrange
- the protection element may be placed on the first metal member (metal member on which the light emitting element is placed).
- the protective element is placed on the first metal member at a position facing the light emitting element with the depression interposed therebetween, whereby the bonding member of the protective element can be prevented from flowing out toward the concave portion.
- only one protective element is mounted, but two or more protective elements may be mounted.
- various components such as a reflecting member, an antireflection member, and a light diffusing member may be provided in order to efficiently extract light from the light emitting element.
- the light-emitting device of the present invention is manufactured in accordance with the recent downsizing and thinning of the light-emitting device.
- a metal member is sandwiched between upper and lower molds (dies) constituting a cavity and sealed in the cavity.
- the area of the metal member sandwiched between the upper and lower molds is dramatically reduced. For this reason, floating (gap, deviation, etc.) of the metal member in the upper and lower molds tends to occur, and it becomes difficult to securely fix the metal member with the upper and lower molds.
- the metal member in order to improve the adhesion between the metal member and the sealing member, when forming a concave portion and a bent portion in the metal member and burying them with the sealing member, in general, the metal member is surely secured. It becomes more difficult to fix with the upper and lower molds. Moreover, since the above-mentioned translucent member has a very low viscosity at the time of molding, it penetrates into a slight gap between the mold and the metal member sandwiched therebetween. For this reason, the thin film by the translucent member may be formed to the site
- the above-described light-transmitting member that is relatively soft or has a low viscosity at the time of molding when used, it is preliminarily provided on the other surface side of the flat portion of the metal member, preferably further on the outer periphery of the flat portion.
- a covering member that is relatively hard or has a large viscosity at the time of molding is disposed. Then, with the integrated metal member and the covering member, the contact area between the upper and lower molds and the metal members at the time of molding the translucent member is increased, and the upper and lower molds are securely fixed. . This avoids the penetration of the translucent member to unnecessary parts during molding, prevents the formation of a thin film on the external terminal of the metal member, etc., and further increases the yield, thereby improving the production efficiency. Can be improved.
- a metal member having an element mounting portion on which the light emitting element is mounted on one surface and a flat portion disposed around the element mounting portion is disposed in a mold, and at least the metal member Molding a covering member that covers the other side of the flat part, (B) mounting a light emitting element on the element mounting portion of the metal member; (C) The metal member covered with the covering member is disposed in a second mold, and the upper surface and the lower surface of the covering member are sandwiched by the second mold, and a part of the metal member and the Forming a translucent member that covers the top and side surfaces of the covering member;
- a metal member is placed in a mold and a covering member is formed.
- the metal member has an element mounting portion on which the light emitting element is mounted on one surface, and a flat portion disposed around the element mounting portion.
- the covering member covers at least the other surface side of the flat portion of the metal member.
- the covering member used here has a small contact area when the metal member is sandwiched between the upper and lower molds, and the metal member is not sufficiently fixed. It is suitable to use a relatively hard resin that does not enter the gap even if a slight gap exists at the site. In other words, it is suitable to use a material having a viscosity of the covering material when forming the covering member that is higher than that of the light transmitting material when forming the light transmitting member.
- the covering member does not enter the gap between the metal mold and the metal member sandwiched between the metal mold and the metal member is sandwiched between the second metal mold as will be described later.
- the contact area between at least one mold and the metal member can be increased. As a result, it becomes possible to fix / clamp more stably, and reliably prevent the formation of a thin film of a sealing member on an unintended part of a metal member even by molding using a relatively low viscosity or soft resin. Can do.
- a joining member is used for mounting the light emitting element on the metal member.
- a metal layer such as Al may be provided in advance on the back surface of the light emitting element, without using a resin, solder such as Au—Sn eutectic, low melting point, etc.
- a brazing material such as metal may be used.
- die bonding may be performed using a conductive paste such as silver, gold, or palladium. Only one light emitting element may be mounted on one metal member, but two or more light emitting elements may be mounted.
- a light emitting element in a metal member via a support body (submount).
- a support using ceramics is formed by firing after forming a predetermined shape.
- Conductor wiring connected to the light emitting element is provided on the upper surface side of the support.
- the conductor wiring is usually formed by, for example, vapor deposition or sputtering, a photolithography process, printing, or the like, or electrolytic plating.
- the conductor wiring may be provided in the support body.
- the conductor wiring is formed from a paste-like material in which a refractory metal such as tungsten or molybdenum is contained in a resin binder, for example.
- the paste material is formed into a desired shape through a through-hole provided in the green sheet by a method such as screen printing, and then fired to form a ceramic support and a conductor wiring disposed on the surface or inside thereof.
- the support may be insert-molded with resin using a pair of positive and negative lead electrodes as a conductive member.
- the light emitting element may be placed on the upper surface of such a support and electrically connected to the conductor wiring of the support. When such a support is used, the conductor wiring of the support is electrically connected to a metal member described later.
- the light-emitting element may be mounted face-down, in which case the above-described support is preferably used.
- the light emitting element is mounted face-down on the support, and the conductor wiring of the support and the metal member are connected by a wire. As long as it performs before a process (c), you may perform a process (b) before a process (a).
- a translucent covering member is preferably formed by a simple method such as potting. According to such a method, undesired pressure due to the light-transmitting coating member is not applied to the light emitting element as in molding, and disconnection of a wire or the like can be reliably prevented. In addition, by appropriately adjusting the amount of resin at the time of potting, it becomes possible to easily cover part or all of the light emitting element, its periphery, or the concave portion.
- a relatively soft resin as described above that is, a material softer than the covering member can be used. It is preferable to use a light-transmitting member having a viscosity lower than that of the covering member when the covering member is formed.
- a translucent member composed of at least a main body portion and a convex portion that covers a part of the light emitting element and the metal member and at least a part of the covering member can be formed.
- a translucent member disposed at an appropriate site formation of a thin film at an unintended site is avoided, and by covering the coating member, cracks and chips due to the hardness of the coating member are generated. Can be prevented.
- Embodiments of a light emitting device and a method for manufacturing the same according to the present invention will be described below in detail with reference to the drawings.
- Embodiment 1 Light emitting device
- the light-emitting device 10 of this embodiment is a surface-mount type light-emitting device, and mainly includes a light-emitting element 11, a metal member 12, a second metal member 13, and these metals.
- a covering member 15 made of polyphthalamide (PPA) covering a part of the member 12 and the second metal member 13 and a translucent translucent member 14 made of silicone resin are formed.
- the light emitting element 11, the metal member 12, and the second metal member 13 are integrally sealed with the covering member 15 and the translucent member 14.
- the light-emitting element 11 includes an n-type contact layer made of n-type GaN on a sapphire substrate, a light-emitting layer made of a nitride semiconductor such as InN, AlN, GaN, InGaN, AlGaN, InGaAlN, and p made of p-type AlGaN or InGaN.
- a type cladding layer and a p-type contact layer made of p-type GaN are sequentially stacked to form a GaN-based semiconductor having a blue light emission having a dominant wavelength of about 470 nm.
- the die bonding of the light emitting element 11 is performed using, for example, a silver paste or an epoxy resin.
- the electrode (refer FIG. 1C) formed in the light emitting element 11 and the flat part of the metal member 12 are connected by the wire which consists of a 30 micrometers diameter gold wire.
- the metal member 12 has a concave element mounting portion 12 a for mounting the light emitting element 11, and a flat portion 12 d is disposed in the periphery thereof.
- the concave element mounting portion 12a has a diameter of about 2.4 mm, for example.
- the 2nd metal member 13 is arrange
- the metal member 12 and the second metal member 13 have a bent portion 12e that is bent toward the bottom surface by about 60 ° in the covering member 15 and / or the translucent member 14 or the flange portion 14b described later. Further, it has a bent portion 12f bent toward the side surface by about 120 °. Therefore, the end portion is a side surface of the translucent member 14 and the covering member 15 and protrudes so as to be substantially flush with the bottom surface of the light emitting device 10, and functions as an external terminal.
- the metal member 12 and the second metal member 13 are formed, for example, by punching a silver-plated copper plate having a thickness of 0.25 mm with a press.
- the height difference due to the two-step bending of the metal member 12 is about 0.35 mm.
- the light emitting element 11 in the concave element mounting portion 12a of the metal member 12 includes a fluorescent material (for example, YAG: Ce) and a diffusing agent (for example, an oxidation material). It is embedded by a translucent covering member 17 made of a silicone resin containing titanium. The translucent covering member 17 is formed by potting.
- the covering member 15 exposes the bottom surface of the concave portion 12a of the metal member 12, and the outer periphery of the concave portion 12a (the flat portion 12d of the metal member 12).
- the other surface is covered, and further, the outer periphery of the flat portion of the metal member 12 is covered, and part of the metal member 12 is formed so as to extend to one surface side. Further, a part of the other surface of the second metal member 13 is covered and disposed between the first metal member 12 and the second metal member 13.
- the upper surface of the covering member 15 coincides with one surface of the flat portion 12d of the first metal member 12 and one surface of a part of the second metal member 13, and is flush with the surface.
- PPA used as the covering member 15 is harder than the translucent member.
- the linear thermal expansion coefficient is, for example, about several tens of ppm / K.
- the translucent member 14 is mainly embedded integrally, and has a substantially rectangular parallelepiped main body portion 14 c and the main body portion 14 c above the light emitting element 11.
- positioned at the outer periphery of the main-body part 14b are provided.
- the side surface and the upper surface of the covering member 15 are all covered with the translucent member 14 (see FIG. 5B).
- the main body 14c of the sealing member 14 has a width W of about 5 mm, a depth of about 5 mm, and a height H of about 0.6 mm.
- the convex portion 14a has a diameter D of about 4.7 mm and a height T of about 2.15 mm.
- the silicone resin used as the translucent member 14 is softer than the covering member 15 and has a hardness of, for example, about JIS-A hardness 50-60.
- the linear thermal expansion coefficient is, for example, about 200 to 300 ppm / K.
- the coating is It is adjusted to be the minimum thickness.
- the film thickness is about 75 ⁇ m.
- the translucent member 14 substantially covers the side surface and the upper surface of the covering member 15, it is possible to effectively prevent the occurrence of cracks and chips due to the hardness of the covering member 15.
- the covering member 15 can be made closer to the linear thermal expansion coefficient of the metal members 12 and 13 by using a material having a smaller linear thermal expansion coefficient than the translucent member 14. Therefore, peeling and cracking at the time of temperature change can be suppressed, and a light emitting device with improved reliability can be obtained.
- a metal plate is punched and bent by a known method to prepare a metal member 12 having a concave portion 12a and a flat portion 12d and a metal member to be the second metal member 13 (see FIG. 4B).
- the metal members to be the metal member 12 and the second metal member 13 are disposed in the upper and lower molds 26 and 27.
- the lower mold 27 is in contact with the bottom surface of the concave portion (element mounting portion 12a), and at the same time, is in contact with the bottom surface of a metal member that extends to the side serving as an external terminal.
- the upper mold 26 is in contact with the flat portion 12 d and the upper surface of the concave portion of the metal member that becomes the metal member 12 and the second metal member 13.
- the inside of the concave portion is a cavity in which a coating member to be described later is not injected.
- the upper mold 26 is in contact with the lower mold 27 in a portion where the covering member 15 is not formed.
- the resin constituting the covering member 15 is injected into the molds 26 and 27.
- the resin in this case is usually a relatively hard PPA resin well known as a sealing member used in a semiconductor device. Thereafter, the resin is cured and removed from the mold.
- a covering member that covers the flat portion and the outer periphery thereof can be formed on the other surface side of the metal member.
- this covering member is substantially flush with one surface of the metal member in the area extending to the outer periphery of the flat portion of the metal member (see 15a in FIGS. 1B and 4B).
- a step may be formed on the outer periphery thereof.
- the bottom surface of the covering member is substantially the same as the concave portion and the other surface (lower surface) of the terminal portion.
- the light emitting element 11 is mounted in a concave portion formed in a portion to be the metal member 12 by a known method, and wire bonding is performed to perform electrical connection.
- a protective element is mounted, the protective element is mounted and wire bonding is performed simultaneously with or before and after the mounting of the light emitting element.
- a light-transmitting covering member 17 containing a fluorescent material is potted in the concave portion to cover the light emitting element 11.
- the obtained metal member is placed in the second upper and lower molds 36 and 37.
- a translucent covering member 17 is filled in the cavity.
- the light emitting element 11 is mounted in the cavity filled with the translucent covering member 17.
- the lower mold 37 contacts the bottom surface of the concave portion 12d, and at the same time, serves as an external terminal, contacts the bottom surface of the metal member extending sideways, and further contacts the bottom surface of the covering member.
- the upper mold 36 contacts the flat portion 12d of the metal member 12 and the metal member to be the second metal member 13, and at the same time, part of the side surface and the upper surface of the covering member 15 previously sealed (in FIG. 5B). , M).
- a resin constituting the translucent member is injected into the mold.
- the resin in this case is, for example, a relatively soft silicone resin.
- a slight gap is provided between the upper surface of the covering member 15 and the upper mold 36.
- the upper surface of the covering member 15 and the upper mold 39 are completely in contact with each other. It is preferable to contact.
- the material of the translucent member 14 enters between the upper mold 39 and the covering member 15, and the upper surface and side surfaces of the covering member 15.
- a release film (release film) 38 is preferably sandwiched between the lower mold and the bottom surfaces of the metal members 12 and 13 and the covering member 15. Thereby, the translucent member 14 is easily formed between the upper mold 39 and the covering member 15, and the translucent member 14 is formed between the lower mold 37, the metal members 12, 13 and the covering member 15. Can be formed.
- the release film 38 is used for easily peeling the mold from the resin.
- a material having a predetermined heat resistance and a good releasability from a mold and a resin is used.
- an FEP sheet film, a PET sheet film, or the like can be used.
- the resin is cured and removed from the mold.
- the translucent light is composed of a light emitting element (not shown), a part of the metal member, and at least a part of the covering member 15, and a main body part 14c, a convex part 14a, and a flange part 14b.
- the elastic member 14 can be molded.
- the metal member is cut to obtain the light emitting device 10 as shown in FIGS. 1A to 1D.
- the soft sealing member absorbs the impact force and can effectively prevent cracking and chipping of the covering member.
- the light extraction efficiency can be improved. That is, in the case of a light-emitting device using a light-transmitting member, the light-transmitting member that covers the metal member transmits light from the light-emitting element, and thus is extracted from a direction other than the front direction that is the light extraction surface of the light-emitting device. There was a thing. However, even if the translucent member is formed of a translucent material, some light is absorbed depending on the material of the translucent member, the shape, and the like.
- the translucent member on the metal member has a minimum film thickness in the flange portion of the sealing member, that is, the upper surface of the flange portion is the flat portion of the metal member and
- the collar portion is disposed outside the light irradiation range from the light emitting element. Therefore, the light does not pass through the collar and is not extracted.
- the light extraction from the light emitting element can be condensed on the convex portion, and the light extraction efficiency of the light emitting device can be greatly improved.
- the light extraction efficiency was simulated for two types of light emitting devices in which the size of the convex portion and the coating thickness of the flat portion of the metal member in the collar portion were different. As a result, it was confirmed that the light extraction efficiency was improved by increasing the diameter of the convex portion and decreasing the coating thickness of the flat portion in the collar portion. Specifically, the length of one side of the light emitting device (the length of one side of the main body portion of the sealing member) is set to about 5 mm, the diameter of the lens-shaped convex portion is set to about 5 mm, and the height of the collar portion is set to 0. The light extraction efficiency of the first light-emitting device in which the thickness of the flat portion in the collar portion was about 75 ⁇ m with a thickness of about 5 mm was 95.2%.
- the length of one side of the light emitting device is about 5 mm
- the diameter of the lens-shaped convex portion is about 3.5 mm
- the height of the heel portion is about 0.85 mm
- the coating thickness of the flat portion in the heel portion is 0.
- the light extraction efficiency of the second light emitting device of about .35 mm was 88.1%. As described above, it was confirmed that the light extraction efficiency was improved by about 8% in the first light emitting device over the second light emitting device.
- the adhesion between the translucent member and the metal member can be improved.
- the material of the translucent member is more elastic than the material of the covering member and tends to be deformed by a temperature rise, an external force, etc., so that it is difficult to obtain sufficient adhesion and strength. If the adhesion between the metal member and the translucent member is insufficient, the gap between the metal member and the translucent member becomes an entry path for moisture or ionic impurities, etc., and the reliability of the light emitting device is improved. It may be damaged.
- the bonding area between the sealing member and the metal member is bent by bending the metal member in the covering member or the translucent member (particularly in the vicinity of the flange). Can be increased. Moreover, the fixation by bending of the metal member can be strengthened, and the adhesion between the metal member and the sealing member can be improved. Furthermore, the strength of the collar portion can be improved, and the reliability of the light emitting device can be improved. In addition, since it can be formed relatively thin while maintaining the strength of the collar portion, the height of the light emitting device can be reduced.
- the upper and lower molds are used when the metal member is sandwiched between the upper and lower molds and the sealing member is injected into the cavity. Since the area of the metal member sandwiched between the two is dramatically reduced, the metal member is liable to float in the upper and lower molds. Therefore, it is difficult to securely fix the metal member with the upper and lower molds. Moreover, since the above-mentioned translucent member has a very low viscosity at the time of molding, it penetrates into a slight gap between the mold and the metal member sandwiched therebetween.
- an undesired thin film made of a translucent member may be formed up to a portion that functions as an external terminal of the metal member. Furthermore, the translucent member could not be reliably removed by a simple etching process such as a blasting process after it was formed as a thin film at an unintended site.
- a covering member having a relatively high hardness (relatively high viscosity during molding) is used before molding with a translucent member having a relatively low hardness (relatively low viscosity during molding).
- a predetermined portion on the other surface side of the metal member that does not affect the extraction of light is covered.
- Embodiment 2 As shown in FIG. 7, gold plating is performed on the entire surface of the metal member 12 and the second metal member 13 made of a copper plate with a thickness of 0.005 ⁇ m, and then the entire inner surface of the concave portion 12 a (diameter of about 3.0 mm) and A silver plating film 28 having a thickness of 3 ⁇ m was applied to the outer periphery (width of about 0.2 mm) of the concave portion 12a across the flat portion.
- the silver plating film 28 in the concave portion 12a is covered with the translucent covering member 17, but the silver plating film 28 formed on the outer periphery thereof is exposed from the translucent covering member 17, and the translucent member 14 and Contact.
- the wire bonding portion is gold-plated with better adhesion to the wire than silver, the adhesion between the wire and the metal member can be improved. Furthermore, the adhesiveness between the translucent member 14 and the metal member can be further improved due to the good adhesiveness to the silver resin compared to gold.
- This embodiment has the same effect as that of the first embodiment.
- the light-emitting device has substantially the same configuration as that of Embodiment 2 except that the shapes of the translucent member 24 and the covering member 25 are different, and can be manufactured by the same manufacturing method.
- the translucent member 24 is formed in a shape along a step on the outer periphery of the covering member 25, and a protruding portion 25b is formed on a side surface of the covering member 25 (see FIG. 8C).
- the protruding portion 25b can be fixed by the metal members 12 and 13, and when forming the translucent member 24, the metal members 12 and 13 and the covering member 25 are further stabilized. Can be fixed. Thereby, the wraparound of the translucent member 24 to the back surfaces of the metal members 12 and 13 can be further suppressed.
- This embodiment also has the same effect as the first and second embodiments.
- the flat portion 12d of the metal member 12 has substantially the same configuration as that of the first embodiment except that the hole 12b and the notch 12c for adhesion to the covering member 15 are formed. It is a light-emitting device and can be manufactured by the same manufacturing method. This embodiment has the same effect as that of the first embodiment.
- the element mounting portion 22 a is not formed in a concave shape, but the light emitting element is mounted on a flat portion continuous with the flat portion 22 d, and the light emitting element 11 is mounted via a support 29 made of ceramics.
- the covering member 35 is disposed on the other surface side of the metal member 22 in a region (region corresponding to the flat portion 22d) other than a region corresponding to the placement and the region (element mounting portion 22a) where the support 29 is mounted. Except for this, the configuration is substantially the same as in the first embodiment.
- the upper surface of the flange portion 14 b of the translucent member 14 is disposed at a position lower than the upper surface of the support 29.
- the flange portion 14b is disposed outside the irradiation range of the light emitted from the light emitting element.
- the half-value angle is slightly increased, but good light emission efficiency can be obtained.
- a part of the flat part may be protruded into the convex part, and the element mounting part may be arranged at a position higher than the collar part. In this case, the support can be omitted.
- the light emitting device of this embodiment can also be manufactured substantially in the same manner as in the first embodiment. This embodiment has the same effect as that of the first embodiment.
- illumination light sources various indicator light sources
- in-vehicle light sources display light sources
- liquid crystal backlight light sources traffic lights, in-vehicle components, and signboard channel letters.
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Abstract
Description
この発光装置40では、発光素子41が載置された金属部材42と、その対となる金属部材43とで一対のリード端子が構成されている。これら発光素子41と金属部材42、43とは、透光性部材44に埋め込まれており、発光素子41の上方において、封止部材44がレンズ状に凸部44aを構成している。また、リード端子は、封止部材の外側で屈曲している。
このような発光装置では、発光装置の使用環境における過酷な温度変化を考慮すると、金属部材と封止部材との密着性が懸念される。また、封止部材の強度確保のため、金属部材の周囲を比較的厚膜の封止部材によって包囲しているが、発光装置の側面や底面から意図しない光が漏れ、発光装置の上面側への光取り出し効率が低下する傾向にある。
本発明は、上記課題に鑑みなされたものであり、光の取り出し効率の向上とともに、さらに性能の向上を確保することができる発光装置を提供することを目的とする。
〔1〕発光素子、
該発光素子が載置された一面と、該一面とは反対面である他面とを有する金属部材及び
前記発光素子と金属部材の一部とを封止する透光性部材を備えてなる発光装置であって、
前記金属部材は、前記発光素子が載置された素子載置部と、該素子載置部の周囲に配置された平坦部とを有し、
前記平坦部の他面側には、被覆部材が配置されており、
該被覆部材の上面及び側面は、前記透光性部材に被覆されていることを特徴とする。
〔2〕前記透光性部材は、前記被覆部材よりも柔らかい〔1〕に記載の発光装置。
〔3〕前記被覆部材は、前記平坦部の前記一面を露出している〔1〕又は〔2〕に記載の発光装置。
〔4〕前記被覆部材は、前記平坦部の他面と平坦部の外周とを被覆しており、前記被覆部材の上面が前記平坦部の一面と略一致し、かつ前記被覆部材の上面及び前記平坦部の上面が前記透光性部材で被覆されている〔1〕~〔3〕のいずれか1つに記載の発光装置。
〔5〕前記透光性部材は、凸部と、前記凸部の周囲に配置された鍔部とを有し、該鍔部は、前記発光素子から出射される光の照射範囲外に配置されている〔1〕~〔4〕のいずれか1つに記載の発光装置。
〔6〕前記金属部材の平坦部は、その一部が前記鍔部内に配置されている〔5〕に記載の発光装置。
〔7〕前記金属部材は、前記平坦部から連続して発光装置の底面側に屈曲した第1屈曲部と、さらに前記発光装置の側面側に屈曲した第2屈曲部とを有し、前記第1屈曲部から前記第2屈曲部にかけて、前記被覆部材に被覆されている〔1〕~〔6〕のいずれか1つに記載の発光装置。
〔8〕前記平坦部及び前記被覆部材の上面における前記鍔部の厚みは、前記被覆部材の側面における前記透光性部材の厚みよりも小さい〔5〕~〔7〕のいずれか1つに記載の発光装置。
〔9〕前記平坦部及び前記被覆部材の上面における前記透光性部材の厚みは、50~100μmである〔1〕~〔8〕のいずれか1つに記載の発光装置。
〔10〕前記被覆部材は、さらに、前記平坦部の外周を被覆している〔1〕~〔3〕、〔5〕~〔9〕のいずれか1つに記載の発光装置。
〔11〕前記被覆部材は、前記金属部材の素子載置部の底面を露出し、該素子載置部の外周に配置されている〔1〕~〔10〕のいずれか1つに記載の発光装置。
〔12〕前記金属部材の素子載置部は、平坦部に対して発光装置の底面側に屈曲して凹形部として成形されている〔1〕~〔11〕のいずれか1つに記載の発光装置。
〔13〕前記凹形部を囲むように前記被覆部材が充填されており、該被覆部材の下面の高さが前記凹形部の下面の高さと略一致する〔12〕に記載の発光装置。
(a)発光素子が一面に載置される素子載置部と、該素子載置部の周囲に配置された平坦部とを有する金属部材を金型内に配置し、前記金属部材の少なくとも前記平坦部における、前記一面とは反対面である他面側を被覆する被覆部材を成形し、
(b)前記金属部材の素子載置部に発光素子を搭載し、
(c)前記被覆部材に被覆された金属部材を第2の金型内に配置し、前記第2の金型により前記被覆部材の上面及び下面を挟持して、前記金属部材の一部と前記被覆部材の上面及び側面とを被覆する透光性部材を成形する工程を含むことを特徴とする。
〔15〕前記工程(a)において、前記平坦部の一面を露出して前記被覆部材を形成し、
前記工程(c)において、前記第2の金型により、前記平坦部の一面及び前記被覆部材の上面と、前記被覆部材の下面とを挟持する〔14〕に記載の発光装置の製造方法。
〔16〕前記工程(a)において、前記素子載置部の底面を露出して前記被覆部材を形成し、
前記工程(c)において、前記素子載置部の底面を露出する前記透光性部材を成形する〔14〕又は〔15〕に記載の発光装置の製造方法。
〔17〕前記被覆部材を成形する時の被覆部材料の粘度が、前記透光性部材を形成する時の透光性部材料の粘度よりも大きい〔14〕~〔16〕に記載の発光装置の製造方法。
また、本発明の発光装置の製造方法によれば、効率的に、諸特性を向上させた、発光効率の良好な発光装置を製造することが可能となる。
11 発光素子
12、22 金属部材
12a、22a 素子載置部
12b 貫通孔
12c 切欠部
12d、22d 平坦部
12e、12f 屈曲部
13 第2金属部材
14、24 透光性部材
14a 凸部
14b 鍔部
14c 本体部
15、25、35 被覆部材
25b 突出部
16 保護素子
17 透光性被覆部材
26、27 上下金型
28 銀メッキ膜
29 支持体
36、37 第2の上下金型
38 リリースフィルム
本願においては、「上面」及び「一面(第1面)」とは、発光装置の光取り出し面側の面、特に「一面」は金属部材の面を指し、「底面」及び「他面(第2面)」とは、上面及び一面(第1面)と反対側の面を指し、特に「他面」は金属部材の面を指す。「発光装置の底面」とは、発光装置を構成する封止部材の底面を指す。
透光性とは、発光素子から出射された光を70%程度以上、好ましくは80%程度以上、90%程度以上、95%程度以上透過させる性質を意味する。
発光素子は、半導体発光素子であり、いわゆる発光ダイオードと呼ばれる素子であればどのようなものでもよい。例えば、基板上に、InN、AlN、GaN、InGaN、AlGaN、InGaAlN等の窒化物半導体、III-V族化合物半導体、II-VI族化合物半導体等、種々の半導体によって、発光層を含む積層構造が形成されたものが挙げられる。
基板としては、C面、A面、R面のいずれかを主面とするサファイアやスピネル(MgA12O4)のような絶縁性基板、また炭化珪素(6H、4H、3C)、シリコン、ZnS、ZnO、GaAs、ダイヤモンド;ニオブ酸リチウム、ガリウム酸ネオジウム等の酸化物基板、窒化物半導体基板(GaN、AlN等)等が挙げられる。
発光素子を構成する各半導体層には、Si、Ge等のドナー不純物及び/又はZn、Mg等のアクセプター不純物がドープされていてもよい。
発光層は、量子効果が生ずる薄膜に形成した単一量子井戸構造、多重量子井戸構造としてもよい。
発光素子の発光波長は、半導体の材料、混晶比、発光層のInGaNのIn含有量、発光層にドープする不純物の種類を変化させるなどによって、紫外領域から赤色まで変化させることができる。
金属部材は、通常、発光素子及び任意に保護素子等(以下「発光素子等」と記載することがある)と電気的に接続され、一般にリード電極としての機能と、発光素子等を載置する機能とを果たす。金属部材は、発光素子等とともに、その一部が後述する封止部材内に埋設されている。そのため、金属部材は、封止部材内で、発光素子等の載置台として及び/又はリード電極として機能する部位(例えば、内部端子)と、封止部材外にまで延設され、外部との電気的な接続をとる機能を有する部位(例えば、外部端子)とを備える。
金属部材の形状は、特に限定されず、発光装置の形状、発光素子の個数、配列、配置可能なスペース等を考慮して適宜決定することができる。
平坦部は、素子載置部と同一平面に存在させてもよいが、上述したように、素子載置部が凹形状となっている場合には、凹形部の底面とは異なる高さに配置されている。
凹形部の周囲を取り囲む平坦部の平面形状は、特に限定されず、例えば、上述したように、凹形部から連続するその一部が、隣接する凹形部の形状に略沿うように(つまり、凹形部と同様又は略同様の形状か、対応する形状で)形成されていることが好ましい(図3中、a参照)。例えば、円形、楕円形、多角形の角を任意に丸めた形状又はこれらの変形形状とすることができる。これにより、発光素子を封止する封止部材を凹形部の外周に沿った形状に安定して形成することができる。なお、この隣接する凹形部の形状に略沿うように形成された平坦部は、図3に示すように、後述する第2金属部材13に対向させることが好ましい。
平坦部のさらに他の一部(例えば、図3中、c参照)は、いわゆる内部端子及び/又は外部端子として機能する領域となる。従って、上述した凹形部とは反対側に延長する形状とすることが適している。延長する端子として機能する領域の幅(図3中、幅n)は、得ようとする発光装置の性能等に応じて適宜設定することができる。例えば、凹形部の直径と同等か若干大きい程度が好ましい。
平坦部は、さらに、上述した保護素子等を載置する領域とすることができる。また、金属部材を後述する透光性部材及び/又は被覆部材で封止する際に、単純な形状の上下金型により容易に平坦部を挟持する(保持する、クランプする等)ことができる。
第2金属部材は、平坦部を有し、この平坦部は、上述した金属部材の平坦部に対応していることが好ましい。第2金属部材の平坦部と発光素子とは、ワイヤによって接続される。これにより、素子載置部に発光素子を搭載した際に、その発光素子と第2の金属部材とのワイヤの距離を短くし、ワイヤ切れ等を防止することができる。
第2金属部材は、内部端子としては、上述した金属部材の素子載置部に対向し、外部端子として、所定の方向に延長する形状であることが好ましい。
さらに、金属部材は、封止部材内において、発光装置の底面方向に向けて屈曲させた(好ましくは、後述する鍔部内において)(第1屈曲部)後、さらに発光装置の側面方向に屈曲させた屈曲部(図3中、12f参照)(第2屈曲部)を有し、封止部材の外側に突出させることが好ましい。これにより、上述した剥がれ及び分離効果をより確保することができる。なお、第1屈曲部及び第2屈曲部は、封止部材、特に、後述する被覆部材に被覆されていることが好ましい。
金属部材が、素子載置部として凹形部を有している場合は、金属部材の平坦部を、凹形部の深さよりも大きくなるような高低差を有して屈曲させてもよいが、凹形部の深さに一致するような高低差を有して屈曲させることが好ましい。つまり、金属部材の平坦部の一部の他面が、凹形部の底面と略一致する(略面一とする)ことが好ましい。
窪み等の平面形状及び配置、大きさ、深さ等は、特に限定されず、発光装置のサイズ、用いる封止部材の材料等によって適宜調整することができる。窪み等は、発光素子からの光の照射範囲外に配置することが好ましく、これによって光の抜けを防止することができる。
金属部材は、金属部材に搭載する発光素子の数+1本以上、あるいは、金属部材に搭載する発光素子の数の2倍本以上を備えていてもよい。例えば、発光素子が1つのみ搭載される場合には、金属部材の一方に発光素子を載置するとともに、発光素子の一方の電極と電気的な接続をとり、他の金属部材が発光素子の別の電極との電気的接続をとってもよい。
また、発光素子それぞれを別個の金属部材に載置するとともに、電気的な接続をとり、さらに別の金属部材が各発光素子に対応してそれぞれ別の電気的な接続をとるように構成してもよい。
このように、発光素子が複数搭載され、それぞれについて、独立して金属部材と電気的に接続されるような独立配線をすることによって、発光装置の実装面において、直列又は並列等、種々の配線パターンを選択することが可能となり、自由な回路設計ができる。また、独立配線の場合、載置される発光素子の発光強度を調整することが容易となるため、特に、フルカラーLED等の異なった発光色を有する複数の発光素子を使用する際に有利である。加えて、各発光素子の放熱経路を重複させることなく形成できる。よって、各発光素子から発生した熱を均等に放熱でき、より放熱性が良好となる。
被覆部材は、後述する透光性の透光性部材とともに、発光装置のパッケージとして機能させる部材である。
被覆部材は、透光性部材よりも硬い材料によって形成されている。被覆部材よりも硬いとは、一般に硬度が大きいことを意味する。この場合の硬度とは、後述する透光性部材及び被覆部材をともに同じ硬度試験法によって試験した場合、その硬度値が、透光性部材よりも大きいことを意味する。以下、いずれの試験法においても25℃にて行ったものとする。
被覆部材の硬度値は、試験法によって異なるが、いずれの試験法によっても、透光性部材の硬度値の5%程度以上、10%程度以上、15%程度以上大きい(硬い)ことが適している。
被覆部材は、被覆部材の試験法がその硬さに対応し、かつ透光性部材のために適する試験法とは異なるように、透光性部材よりも硬度が大きい(硬い)ことが好ましい。
例えば、ロックウェル硬さ試験は、圧子を用いて、まず初試験力を加え、次に試験力を加え、再び初試験力に戻したとき、前後2回の初試験力のおける圧子の侵入深さを測定する方法である。その硬度は、侵入深さの差から算出することができる。
ビッカース硬さ試験は、圧子に試験力を加えて、圧子を試料に押し込み、圧子と試料との接触面積を測定する方法である。その硬度は、圧子に加えた試験力を接触面積で割った値として算出することができる。
ショアA硬さ試験により硬度を測定すると、例えば、70程度以上が適しており、90程度以上が好ましい。
ショアA硬さ又はJIS-A硬さ試験とは、公知の試験方法である。例えば、被測定物の表面に圧子を押し込んで変形させ、その変形量(押込み深さ)を測定し、数値化する方法である。
ショアA硬さ又はJIS-A硬さが90を超える場合は、通常、ショアD硬さが用いられる。
従って、被覆部材は、ショアD硬さによって硬さが表される材料が好ましい。
ショアD硬さ試験とは、公知の試験方法である。この方法は、JIS-A硬さ試験とは、圧子の形状及びサイズ、押し込み荷重が異なる。ショアD硬さ試験はJIS-A硬試験さよりも弾性の小さい試料の測定に適している。
金属部材の線熱膨張係数は、封止部材として通常使用される材料よりも小さく、例えば5~20ppm/K程度である。被覆部材と金属部材との線熱膨張係数の差は、10~100ppm/K程度であることが好ましい。
被覆部材を直接金属部材に接触させることにより、金属部材を直接透光性部材で被覆する場合の線熱膨張係数の差を緩和することができ、封止部材と金属部材との熱による密着性低下を低減することができる。
被覆部材は、上述した材料に、部分的に上述したような着色剤又は拡散剤として、種々の染料又は顔料等を混合して用いてもよい。被覆部材は、発光素子から出射される光の照射範囲外に配置されることが好ましい。これにより、着色剤としてカーボンブラック等の光の吸収が大きなものが混合された材料のように光反射性が低い材料を用いても発光装置の光出力が低下しないため、光反射性の低い安価な材料を被覆部材として選択することができる。
被覆部材が平坦部の外周を被覆する場合は、平坦部の端面を被覆することに相当する。平坦部の端面を被覆する場合には、被覆部材が金属部材の一面側にまで及ぶことになるが、このような平坦部の外周に配置する被覆部材は、その上面の一部が、金属部材の平坦部の一面と略一致し、面一となっていることが好ましい(図1B及び図1D参照)。特に、平坦部の角部において、平坦部の一面と略一致していることがより好ましく、平坦部の全外周にわたって、平坦部の一面と面一となってことが好ましい。
これにより、後述する透光性部材を上下金型によって成形する際、面一となった部位(特に角部、図5B中、M参照)を、上下金型の間で安定して挟持することができ、封止部材の材料漏れ等を防止することができる。さらに、このように上下金型の間で安定して挟持されるために、被覆部材は、その上面と下面とがそれぞれ上下金型に接するように配置することが好ましい。好ましくは、被覆部材の上面の一部が後述する鍔部と略一致し、被覆部材の下面が発光装置の下面(底面)を構成するように配置する(図1C及び図1D参照)。
透光性の透光性部材は、発光素子、任意に保護素子及び金属部材の一部を封止する部材であって、例えば、図2に示すように、少なくとも本体部14cと凸部14aとを有する。透光性部材は、少なくとも、被覆部材の上面及び金属部材の平坦部の上面の一部を被覆しており、さらに、被覆部材の側面を被覆していることが好ましい。従って、金属部材の平坦部は、その一部が透光性部材内、特に、後述する鍔部内に配置されていることが好ましい。
発光装置は、通常、基本形状(封止部材の形状)として、円柱、楕円柱、球、卵形、三角柱、四角柱、多角柱又はこれらに近似する形状等に成形することができ、一般的には、四角柱に成形されている。従って、本発明における透光性部材は、基本形状を構成する本体部と、本体部の一面に、例えば、集光のためのレンズとして機能する凸部が一体的に配置されている。
例えば、図2(図1CのF-F'線断面図に相当)に示すように、透光性部材14は、主に、発光素子(図示せず)等及び金属部材(図示せず)の一部を一体的に封止するブロック状の本体部14cを有する。さらに、本体部14c上であって、発光素子(及びその周辺部分)の上方において、本体部14cから突出した形状で配置された凸部14aと称される部位とを有していることが好ましい。
金属部材と透光性部材との間の隙間は水分又はイオン性不純物等の進入経路になる。従って、このように金属部材の上面を透光性部材によって被覆することにより、発光装置の上面における水分又はイオン性不純物等の進入を防止でき、発光装置の信頼性を向上することができる。
従って、本体部及び鍔部の高さHは、凹形部の深さと、金属部材の厚みとの合計より若干厚い(例えば、+100μm)程度とすることが好ましい。
また、透光性部材は、ゴム状の弾性を備えた材料により形成されているともいうことができる。あるいは、動的硬さ(反発硬さ)で表される硬さを有する材料によって形成されているともいうことができる。
動的硬さは、一般に、ショアA硬さ又はJIS-A硬さ試験による硬度で表される。
透光性部材のJIS-A硬さ試験による硬度は、例えば、65程度以下が挙げられ、60程度以下が好ましい。このような柔らかい材料を用いることによって、熱衝撃試験におけるワイヤの疲労を小さくできる。また、発光装置を取り扱う際のワイヤの曲がり及び発光装置同士の付着等を防止することを考慮して、JIS-A硬さ試験による硬度は20程度以上が挙げられ、30程度以上が好ましい。このような弾性の高い透光性部材の線熱膨張係数は、例えば、200~300ppm/K程度が挙げられる。
従って、上述した硬度及び特性を備えるものとして、例えば、透光性のシリコーン樹脂が好ましい。ゴム状の弾性を有し、耐熱性を発揮し、200℃を超える高温に耐え、さらに高温では変形、分解の速度が緩やかで、つまり、温度依存性が小さく、他の部材への影響が小さいことから、長期の信頼性を見込むことができるからである。
本発明の発光装置では、発光素子を金属部材に搭載した後、発光素子を被覆するように、透光性被覆部材を配置してもよい。透光性被覆部材は、通常、発光素子に接触して配置している。例えば、金属部材が凹形状の素子載置部を有する場合には、凹形部の一部又は全部に、さらに凹形部から盛り上がるように、透光性被覆部材を配置してもよい。
透光性被覆部材は、外力、水分等から発光素子を保護し、発光素子と金属部材との接続を確保するワイヤを保護し得る材料によって形成することが好ましい。
保護素子は、特に限定されるものではなく、発光装置に搭載される公知のもののいずれでもよい。例えば、発光素子に印加される逆方向の電圧を短絡したり、発光素子の動作電圧より高い所定の電圧以上の順方向電圧を短絡させることができる素子、つまり、過熱、過電圧、過電流、保護回路、静電保護素子等が挙げられる。具体的には、ツェナーダイオード、トランジスタのダイオード等が利用できる。
保護素子は、第1の金属部材(発光素子が載置されている金属部材)に載置されていてもよい。この場合、保護素子は、第1の金属部材上であって、窪みを挟んで発光素子と対向する位置に載置されることにより、保護素子の接合部材が凹部方向へ流れ出すことを防止できる。保護素子は、通常、1つのみが搭載されていているが、2つ以上搭載されていてもよい。
本発明の発光装置では、発光素子からの光の取り出しを効率的に行うために、反射部材、反射防止部材、光拡散部材等、種々の部品が備えられていてもよい。
本発明の発光装置は、近年の発光装置の小型化及び薄型化に伴って、その製造時、例えば、キャビティを構成する上下金型(ダイ)で金属部材を挟持し、そのキャビティ内に封止部材を注入するモールド成形による製造時において、上下金型で挟持する金属部材の面積が劇的に縮小している。そのため、金属部材の上下金型内での浮き(隙間、ずれなど)が発生しやすく、金属部材を確実に上下金型で固定することが困難となる。特に、金属部材と封止部材との密着性を向上するために、金属部材に凹形部及び屈曲部を形成し、封止部材によってそれらを埋没させる場合には、一般に、金属部材を確実に上下金型で固定することがさらに困難となる。また、上述した透光性部材は、その性質上、成形時においては非常に粘度が小さいために、金型とそれに挟持された金属部材との間のわずかの隙間にも侵入する。このため、金属部材の外部端子として機能する部位にまで、透光性部材による薄膜が形成されることがあった。さらに、透光性部材は、その性質上、意図しない部位に薄膜として形成された後は、ブラスト処理などの簡便なエッチング等の処理によっても、確実に除去することができない。
(a)発光素子が一面に載置される素子載置部と、該素子載置部の周囲に配置された平坦部とを有する金属部材を金型内に配置し、前記金属部材の少なくとも前記平坦部における他面側を被覆する被覆部材を成形し、
(b)前記金属部材の素子載置部に発光素子を搭載し、
(c)前記被覆部材に被覆された金属部材を第2の金型内に配置し、前記第2の金型により前記被覆部材の上面及び下面を挟持して、前記金属部材の一部と前記被覆部材の上面及び側面とを被覆する透光性部材を成形する工程を含む。
金属部材を金型内に配置して被覆部材を成形する。
金属部材は、上述したように、発光素子が一面に載置される素子載置部と、素子載置部の周囲に配置された平坦部とを有する。また、被覆部材は、金属部材の少なくとも平坦部における他面側を被覆する。
ここで用いる被覆部材は、上述したように、金属部材を上下金型で挟持する場合に、これらの当接面積が小さく、金属部材の固定が十分でなく、上下金型と金属部材との挟持部位において、若干の隙間が存在しても、その隙間に進入しないような、比較的硬い樹脂を用いることが適している。つまり、被覆部材を形成する時の被覆部材料の粘度が、透光性部材を成形する時の透光性部材料の粘度より大きいものを用いることが適している。
金属部材への発光素子の搭載には、通常、接合部材が用いられる。例えば、青及び緑発光を有し、サファイア基板上に窒化物半導体を成長させた発光素子の場合には、エポキシ樹脂、シリコーン等を用いることができる。また、発光素子からの光や熱による劣化を考慮して、発光素子裏面に予めAl等の金属層を設けてもよいし、樹脂を使用せず、Au-Sn共晶などの半田、低融点金属等のろう材を用いてもよい。さらに、GaAs等からなり、赤色発光を有する発光素子のように、両面に電極が形成された発光素子の場合には、銀、金、パラジウムなどの導電性ペースト等によってダイボンディングしてもよい。
1つの金属部材には1つのみの発光素子が搭載されていてもよいが、2つ以上搭載されていてもよい。
発光素子はフェースダウン実装してもよく、この場合、上述の支持体を用いることが好ましい。つまり、発光素子を支持体にフェースダウン実装し、支持体の導体配線と金属部材とをワイヤで接続することが好ましい。
工程(b)は、工程(c)の前に行う限り、工程(a)の前に行ってもよい。
このような透光性被覆部材は、例えば、ポッティグなどの簡易な方法により形成することが好ましい。このような方法によれば、モールド成形のように、発光素子に透光性被覆部材による望まない圧力が負荷されることがなく、ワイヤ等の断線などを確実に防止することができる。また、ポッティング時の樹脂量を適宜調整することにより、発光素子、その周辺又は凹形部内の一部又は全部を簡便に被覆することが可能となる。
被覆部材で被覆された金属部材を第2の金型内に配置して、金属部材の一部と被覆部材の上面及び側面とを被覆する透光性部材を成形する。第2の金型では、被覆部材の上面及び下面を挟持する。
なお、上述した工程(a)において、平坦部の一面を露出して被覆部材を形成する場合には、工程(c)において、第2の金型により、平坦部の一面及び被覆部材の上面と、被覆部材の下面とを挟持することが好ましい。
また、工程(a)において、素子載置部の底面を露出して前記被覆部材を形成する場合には、工程(c)において、第2の金型での適切な挟持によって、素子載置部の底面を露出する透光性部材を成形することが好ましい。
このような適切な部位に配置した透光性部材は、意図しない部位への薄膜形成が回避されており、被覆部材を被覆することによって、被覆部材の硬さに起因するクラック及び欠け等の発生を防止することが可能となる。
実施形態1
(発光装置)
この実施形態の発光装置10は、図1A~図1Dに示したように、表面実装タイプの発光装置であって、主として、発光素子11と、金属部材12及び第2金属部材13と、これら金属部材12及び第2金属部材13の一部を被覆するポリフタルアミド(PPA)からなる被覆部材15と、シリコーン樹脂からなる透光性の透光性部材14とを備えて形成されている。
発光素子11、金属部材12、第2金属部材13は、被覆部材15及び透光性部材14とで、一体的に封止されている。
発光素子11のダイボンディングは、例えば、銀ペースト又はエポキシ樹脂を用いて行われている。また、直径30μmの金線からなるワイヤによって、発光素子11に形成された電極(図1C参照)と金属部材12の平坦部とが接続されている。
金属部材12の素子載置部12aに対向するように、第2金属部材13が配置されている。
これら金属部材12及び第2金属部材13は、例えば、0.25mm厚の銀メッキ銅板を、プレスによる打ち抜き加工により形成されている。ここでの金属部材12の2段屈曲による高低差は、略0.35mm程度である。
被覆部材15として用いるPPAは、透光性部材よりも硬い。また、その線熱膨張係数は、例えば数十ppm/K程度である。
発光装置10の一辺の長さ、つまり、封止部材14の本体部14cの一辺の長さ(幅W=奥行)と凸部の直径Dとは略同じである。従って、平面視において、鍔部14bは、ほぼ、本体部14cの外周の対角線状に対向する4箇所において配置しているのみである。
まず、公知の方法により、金属板を打ち抜き及び屈曲加工して、凹形部12aと平坦部12dとを有する金属部材12及び第2金属部材13となる金属部材を準備する(図4B参照)。
金属部材12、13を固定した状態で、金型26、27内に、被覆部材15を構成する樹脂を注入する。この場合の樹脂は、通常、半導体装置に使用される封止部材としてよく知られている比較的硬い、PPA樹脂である。
その後、樹脂を硬化させ、金型から取り出す。
さらに、蛍光物質を含有する透光性被覆部材17を、凹形部内にポッティングして、発光素子11を被覆する。
その後、樹脂を硬化させ、金型から取り出す。
この透光性部材の封止により、発光素子(図示せず)及び金属部材の一部と被覆部材15の少なくとも一部とを被覆する本体部14c、凸部14a及び鍔部14bからなる透光性部材14を成形することができる。
最後に、金属部材を切断し、図1A~図1Dに示すような発光装置10を得る。
つまり、透光性部材を用いた発光装置の場合、金属部材を被覆する透光性部材が発光素子からの光を透過するため、発光装置の光取り出し面である正面方向以外の方向から取り出されることがあった。しかし、透光性部材が透光性材料によって形成されているとしても、透光性部材の材料、さらに形状等によって、いくらかの光が吸収されることとなる。
具体的には、発光装置の一辺の長さ(封止部材の本体部の一辺の長さ)を5mm程度とし、レンズ状の凸部の直径を5mm程度とし、鍔部の高さを0.5mm程度として鍔部における平坦部の被覆膜厚を75μm程度とした第1の発光装置の光取り出し効率は、95.2%であった。
このように、光取り出し効率は、第1の発光装置が第2の発光装置に対して、約8%向上することが確認された。
図7に示すように、銅板からなる金属部材12及び第2金属部材13の全面に、厚さ0.005μmで金メッキを施し、その後、凹形部12a(直径3.0mm程度)の内面全面及び平坦部に渡る凹形部12aの外周(幅0.2mm程度)に、厚さ3μmで銀メッキ膜28を施した。凹形部12a内の銀メッキ膜28は透光性被覆部材17によって被覆されるが、その外周に形成された銀メッキ膜28は透光性被覆部材17から露出し、透光性部材14と接触する。
この実施形態でも、実施形態1と同様の効果を有する。
図8A及び図8Bに示したように、透光性部材24と被覆部材25の形状が異なる以外、実施形態2と略同様の構成の発光装置であり、同様の製造方法によって製造することができる。
透光性部材24は、被覆部材25の外周における段差に沿った形状で成形されているとともに、被覆部材25の側面に、突出部25bが形成されている(図8C参照)。
この突出部25bを設けることにより、突出部25bを金属部材12、13によって固定することができ、透光性部材24を成形する際に、金属部材12、13及び被覆部材25をさらに安定して固定することができる。これによって、透光性部材24の金属部材12、13裏面への回り込みをさらに抑制することができる。
この実施形態でも、実施形態1及び2と同様の効果を有する。
図9に示したように、金属部材12の平坦部12dに、被覆部材15との密着性を図るための孔12b及び切欠き12cが形成されている以外、実施形態1と略同様の構成の発光装置であり、同様の製造方法によって製造することができる。
この実施形態でも、実施形態1と同様の効果を有する。
図10に示したように、素子載置部22aを凹形状とせず、平坦部22dと連続する平坦部に発光素子を載置すること、セラミックスからなる支持体29を介して発光素子11を載置すること及び支持体29が搭載されている領域(素子載置部22a)に相当する領域以外の領域(平坦部22dに相当する領域)の金属部材22の他面側において被覆部材35が配置されている以外、実質的に実施形態1と同様の構成とする。透光性部材14の鍔部14bの上面は、支持体29の上面より低い位置に配置される。
この構成の発光装置では、半値角がやや増大するが、良好な発光効率が得られる。
また、平坦部の一部を凸部内に突出させ、素子載置部を鍔部より高い位置に配置されるようにしてもよい。この場合、支持体は省略できる。
この実施形態の発光装置も、実質的には、実施形態1と同様に製造することができる。
この実施形態でも、実施形態1と同様の効果を有する。
Claims (17)
- 発光素子、
該発光素子が載置された一面と、該一面とは反対面である他面とを有する金属部材及び
前記発光素子と金属部材の一部とを封止する透光性部材を備えてなる発光装置であって、
前記金属部材は、前記発光素子が載置された素子載置部と、該素子載置部の周囲に配置された平坦部とを有し、
前記平坦部の他面側には、被覆部材が配置されており、
該被覆部材の上面及び側面は、前記透光性部材に被覆されていることを特徴とする発光装置。 - 前記透光性部材は、前記被覆部材よりも柔らかい請求項1に記載の発光装置。
- 前記被覆部材は、前記平坦部の前記一面を露出している請求項1又は2に記載の発光装置。
- 前記被覆部材は、前記平坦部の他面と平坦部の外周とを被覆しており、前記被覆部材の上面が前記平坦部の一面と略一致し、かつ前記被覆部材の上面及び前記平坦部の上面が前記透光性部材で被覆されている請求項1~3のいずれか1つに記載の発光装置。
- 前記透光性部材は、凸部と、前記凸部の周囲に配置された鍔部とを有し、該鍔部は、前記発光素子から出射される光の照射範囲外に配置されている請求項1~4のいずれか1つに記載の発光装置。
- 前記金属部材の平坦部は、その一部が前記鍔部内に配置されている請求項5に記載の発光装置。
- 前記金属部材は、前記平坦部から連続して発光装置の底面側に屈曲した第1屈曲部と、さらに前記発光装置の側面側に屈曲した第2屈曲部とを有し、前記金属部材の前記第1屈曲部から前記第2屈曲部にかけて、前記被覆部材に被覆されている請求項1~6のいずれか1つに記載の発光装置。
- 前記平坦部及び前記被覆部材の上面における前記鍔部の厚みは、前記被覆部材の側面における前記透光性部材の厚みよりも小さい請求項5~7のいずれか1つに記載の発光装置。
- 前記平坦部及び前記被覆部材の上面における前記透光性部材の厚みは、50~100μmである請求項1~8のいずれか1つに記載の発光装置。
- 前記被覆部材は、さらに、前記平坦部の外周を被覆している請求項1~3、5~9のいずれか1つに記載の発光装置。
- 前記被覆部材は、前記金属部材の素子載置部の底面を露出し、該素子載置部の外周に配置されている請求項1~10のいずれか1つに記載の発光装置。
- 前記金属部材の素子載置部は、平坦部に対して発光装置の底面側に屈曲して凹形部として成形されている請求項1~11のいずれか1つに記載の発光装置。
- 前記凹形部を囲むように前記被覆部材が充填されており、該被覆部材の下面の高さが前記凹形部の下面の高さと略一致する請求項12に記載の発光装置。
- (a)発光素子が一面に載置される素子載置部と、該素子載置部の周囲に配置された平坦部とを有する金属部材を金型内に配置し、前記金属部材の少なくとも前記平坦部における他面側を被覆する被覆部材を成形し、
(b)前記金属部材の素子載置部に発光素子を搭載し、
(c)前記被覆部材に被覆された金属部材を第2の金型内に配置し、前記第2の金型により前記被覆部材の上面及び下面を挟持して、前記金属部材の一部と前記被覆部材の上面及び側面とを被覆する透光性部材を成形する工程を含むことを特徴とする発光装置の製造方法。 - 前記工程(a)において、前記平坦部の一面を露出して前記被覆部材を形成し、
前記工程(c)において、前記第2の金型により、前記平坦部の一面及び前記被覆部材の上面と、前記被覆部材の下面とを挟持する請求項14に記載の発光装置の製造方法。 - 前記工程(a)において、前記素子載置部の底面を露出して前記被覆部材を形成し、
前記工程(c)において、前記素子載置部の底面を露出する前記透光性部材を成形する請求項14に記載の発光装置の製造方法。 - 前記被覆部材を成形する時の被覆部材料の粘度が、前記透光性部材を形成する時の透光性部材料の粘度よりも大きい請求項15に記載の発光装置の製造方法。
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