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JP6825636B2 - Light emitting device - Google Patents

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JP6825636B2
JP6825636B2 JP2019033698A JP2019033698A JP6825636B2 JP 6825636 B2 JP6825636 B2 JP 6825636B2 JP 2019033698 A JP2019033698 A JP 2019033698A JP 2019033698 A JP2019033698 A JP 2019033698A JP 6825636 B2 JP6825636 B2 JP 6825636B2
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light emitting
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emitting element
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JP2019083343A (en
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佐野 雅彦
雅彦 佐野
俊介 湊
俊介 湊
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Nichia Corp
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Nichia Corp
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Description

本発明は、発光装置に関し、特に発光効率を高める導光部材を備える発光装置に関する。 The present invention relates to a light emitting device, and more particularly to a light emitting device including a light guide member for increasing luminous efficiency.

近年、光源として発光ダイオード(Light Emitting Diode:LED)やレーザダイオード(Laser Diode:LD)等の半導体発光素子を搭載した発光装置は、各種の照明や表示装置に利用されている。特に、これら半導体発光素子は消費電力が低く長寿命であるため、蛍光灯に代替可能な次世代照明の光源として注目を集めており、さらなる発光出力および発光効率の向上が求められている。また、車のヘッドライトなどの投光照明のように、配光特性が良く高輝度な光源も求められている。 In recent years, light emitting devices equipped with semiconductor light emitting elements such as light emitting diodes (LEDs) and laser diodes (LDs) as light sources have been used in various lighting and display devices. In particular, since these semiconductor light emitting elements have low power consumption and long life, they are attracting attention as a light source for next-generation lighting that can replace fluorescent lamps, and further improvement in light emission output and light emission efficiency is required. In addition, a light source having good light distribution characteristics and high brightness, such as floodlights such as car headlights, is also required.

例えば特許文献1には、LEDチップに光透過性の接着剤により蛍光体チップを固着したLEDチップ組立体を、リードフレームのカップ部や絶縁性基板上に実装し、光散乱剤を混合した保護層や封止樹脂により該LEDチップ組立体を封止した発光装置が提案されている。 For example, in Patent Document 1, an LED chip assembly in which a phosphor chip is fixed to an LED chip with a light-transmitting adhesive is mounted on a cup portion of a lead frame or an insulating substrate, and is protected by mixing a light scattering agent. A light emitting device in which the LED chip assembly is sealed with a layer or a sealing resin has been proposed.

特開2002−141559号公報JP-A-2002-141559 特開2007−019096号公報Japanese Unexamined Patent Publication No. 2007-019096 特開2002−305328号公報JP-A-2002-305328 特開平10−151794号公報Japanese Unexamined Patent Publication No. 10-151794 特開2009−043764号公報Japanese Unexamined Patent Publication No. 2009-043764 特開2008−300621号公報Japanese Unexamined Patent Publication No. 2008-300621 特開2008−277592号公報Japanese Unexamined Patent Publication No. 2008-277592

しかしながら、引用文献1に記載された発光装置において、LEDチップ上に蛍光体チップを接着する光透過性の接着剤が、蛍光体チップから直接あるいは発光素子の側面を伝って、リードフレームのカップ部や絶縁性基板まで垂れる虞があり、LEDチップや蛍光体チップからの出射光が該接着剤により導光されて、絶縁性基板やその上に設けられた電極やリードフレームの表面で吸収されることで、発光装置の光出力が低下するという問題があり、また発光素子や蛍光体チップと、上記基板、電極などの表面とを被覆する透光性樹脂にも同様の問題がある。また、このような透光性の部材による光経路は小さく、狭いものであっても発光装置の特性に及ぼす影響は大きい。さらに、引用文献1のLEDチッ
プと蛍光体チップは、接着剤によりその対向面同士が固着されているに過ぎず、LEDチップから放出される光の蛍光体チップへの結合効率が低いこと、両者の外形の整合が悪い場合に輝度むら、色むらや指向性が悪化することが懸念される。
However, in the light emitting device described in Reference 1, the light-transmitting adhesive that adheres the phosphor chip to the LED chip directly from the phosphor chip or travels along the side surface of the light emitting element to the cup portion of the lead frame. And there is a risk of dripping to the insulating substrate, and the light emitted from the LED chip or phosphor chip is guided by the adhesive and absorbed by the surface of the insulating substrate or the electrodes or lead frames provided on it. As a result, there is a problem that the light output of the light emitting device is lowered, and there is a similar problem in the translucent resin that covers the light emitting element or the phosphor chip and the surface of the substrate, the electrode, or the like. Further, the optical path of such a translucent member is small, and even if it is narrow, it has a great influence on the characteristics of the light emitting device. Further, the LED chip and the phosphor chip of Cited Document 1 are merely fixed to each other by an adhesive, and the light emitted from the LED chip has a low bonding efficiency to the phosphor chip. If the outer shape of the LED is poorly matched, there is a concern that uneven brightness, uneven color, and directivity may deteriorate.

本発明は、上記課題に鑑みてなされたものであり、その目的は、発光素子から出射される光の損失を低減してその利用効率を高め、発光素子から光透過部材への光結合効率を高め、発光効率、輝度を高められる発光装置を提供することである。 The present invention has been made in view of the above problems, and an object of the present invention is to reduce the loss of light emitted from a light emitting element, improve its utilization efficiency, and improve the light coupling efficiency from the light emitting element to a light transmitting member. The purpose of the present invention is to provide a light emitting device capable of increasing light emission efficiency and brightness.

本発明に係る発光装置は、下記(1)〜(15)の構成により、上記目的を達成することができる。
(1) 発光装置の発光面と受光面を有する光透過部材と、該受光面に対向する出射面を備えて、前記光透過部材に接合される発光素子と、前記発光素子表面から前記光透過部材表面まで延在して設けられて、前記発光素子からの出射光を前記光透過部材に導光する導光部材と、を備え、前記導光部材は、前記発光素子の出射面と前記光透過部材の受光面を互いに対向させて接合する接合領域と、前記接合領域より延在して、該接合領域より外側に突出された前記発光素子及び光透過部材の一方の表面を被覆する第1の被覆領域と、を有すると共に、前記出射光を前記光透過部材側に反射させる第1の反射面が、前記第1の被覆領域の外表面に設けられている発光装置。
(2) 前記発光装置は、光反射材料を有する被覆部材を備え、該被覆部材が、前記導光部材の表面を覆い、前記発光面を露出させて前記発光素子及び光透過部材の表面を被覆する上記(1)に記載の発光装置。
(3) 前記光透過部材は、前記発光素子の出射光で励起される波長変換部材である上記(1)又は(2)に記載の発光装置。
(4) 前記第1の被覆領域は、前記発光素子及び光透過部材の一方の前記突出表面と他方の側面を被覆し、前記第1の反射面は、前記側面に対向して設けられている上記(1)乃至(3)のいずれかに記載の発光装置。
(5) 前記被覆部材は、前記他方の側面を第1の被覆領域の導光部材を介して該表面を覆い、該導光部材から露出された前記発光素子又は光透過部材の側面の表面を覆う上記(4)に記載の発光装置。
(6) 前記光透過部材の受光面の一部が前記出射面より外側に突出しており、前記第1の反射面は、前記発光素子の側面から前記受光面側に傾斜した傾斜面である上記(1)乃至(5)のいずれかに記載の発光装置。
(7) 前記光透過部材の受光面が、前記発光素子の出射面より大きく、該出射面を内包する上記(6)に記載の発光装置。
(8) 前記発光素子の出射面の一部が該受光面より外側に突出しており、前記第1の反射面は、前記光透過部材の側面から前記出射面側に傾斜した傾斜面である上記(1)乃至(5)のいずれかに記載の発光装置。
(9) 前記発光素子の出射面が、前記光透過部材の受光面より大きく、該受光面を内包する上記(8)に記載の発光装置。
(10) 前記発光素子が互いに離間されて、前記光透過部材の受光面側に複数接合されており、前記導光部材は、前記離間された発光素子に挟まれた前記受光面の一部を前記接合領域から延在して被覆する第2の被覆領域を有すると共に、前記隣接する発光素子からの出射光をそれぞれ前記受光面側に反射させる第2の反射面が、前記第2の被覆領域の外表面に設けられている上記(1)乃至(9)のいずれかに記載の発光装置。
(11) 前記第2の被覆領域が、前記離間された発光素子の互いに対向する側面を被覆する上記(10)に記載の発光装置。
(12) 前記複数の発光素子は、少なくとも1組が該出射面から前記光透過部材の受光面までの距離が互いに異なる上記(10)又は(11)に記載の発光装置。
(13) 前記発光素子が、半導体層と、該半導体層より出射面側の基板とを有し、前記導光部材が、前記基板の側面まで延在して覆い、前記半導体側面を露出させている上記(1)乃至(12)のいずれかに記載の発光装置。
(14) 前記発光装置は、光反射性材料を含有し、前記発光面を露出させて、前記発光素子及び前記光透過部材の一部を被覆する被覆部材を備え、前記第1の反射面又は第2の反射面は、前記導光部材と前記被覆部材との界面に設けられている上記(1)乃至(13)のいずれに記載の発光装置。
(15) 前記第1の反射面又は第2の反射面は、前記側面に向かって凸な凸曲面である上記(1)乃至(14)のいずれかに記載の発光装置。
The light emitting device according to the present invention can achieve the above object by the following configurations (1) to (15).
(1) A light transmitting member having a light emitting surface and a light receiving surface of the light emitting device, a light emitting element provided with an emitting surface facing the light receiving surface and bonded to the light transmitting member, and the light transmitting from the surface of the light emitting element. The light guide member is provided so as to extend to the surface of the member and guides the light emitted from the light emitting element to the light transmitting member, and the light guide member includes the light emitting surface of the light emitting element and the light. A first that covers one surface of the light emitting element and the light transmitting member extending outward from the bonding region and extending from the bonding region to join the light receiving surfaces of the transmitting members so as to face each other. A light emitting device having a covering region of the above, and having a first reflecting surface for reflecting the emitted light toward the light transmitting member side on the outer surface of the first covering region.
(2) The light emitting device includes a coating member having a light reflecting material, and the coating member covers the surface of the light guide member and exposes the light emitting surface to cover the surfaces of the light emitting element and the light transmitting member. The light emitting device according to (1) above.
(3) The light emitting device according to (1) or (2) above, wherein the light transmitting member is a wavelength conversion member excited by the emitted light of the light emitting element.
(4) The first covering region covers the protruding surface of one of the light emitting element and the light transmitting member and the other side surface, and the first reflecting surface is provided so as to face the side surface. The light emitting device according to any one of (1) to (3) above.
(5) The covering member covers the other side surface of the other side surface via the light guide member of the first covering region, and covers the surface of the side surface of the light emitting element or the light transmitting member exposed from the light guide member. The light emitting device according to (4) above.
(6) A part of the light receiving surface of the light transmitting member projects outward from the emitting surface, and the first reflecting surface is an inclined surface inclined from the side surface of the light emitting element toward the light receiving surface side. The light emitting device according to any one of (1) to (5).
(7) The light emitting device according to (6) above, wherein the light receiving surface of the light transmitting member is larger than the emitting surface of the light emitting element and includes the emitting surface.
(8) A part of the emitting surface of the light emitting element projects outward from the light receiving surface, and the first reflecting surface is an inclined surface inclined from the side surface of the light transmitting member toward the emitting surface side. The light emitting device according to any one of (1) to (5).
(9) The light emitting device according to (8) above, wherein the light emitting surface of the light emitting element is larger than the light receiving surface of the light transmitting member and includes the light receiving surface.
(10) The light emitting elements are separated from each other, and a plurality of the light emitting elements are joined to the light receiving surface side of the light transmitting member, and the light guide member is a part of the light receiving surface sandwiched between the separated light emitting elements. The second covering region has a second covering region extending from the bonding region and covering the light receiving surface side, and the second reflecting surface for reflecting the light emitted from the adjacent light emitting element toward the light receiving surface side is the second covering region. The light emitting device according to any one of (1) to (9) above, which is provided on the outer surface of the above.
(11) The light emitting device according to (10) above, wherein the second covering region covers the side surfaces of the separated light emitting elements facing each other.
(12) The light emitting device according to (10) or (11) above, wherein at least one set of the plurality of light emitting elements has different distances from the emitting surface to the light receiving surface of the light transmitting member.
(13) The light emitting element has a semiconductor layer and a substrate on the exit surface side of the semiconductor layer, and the light guide member extends to and covers the side surface of the substrate to expose the semiconductor side surface. The light emitting device according to any one of (1) to (12) above.
(14) The light emitting device includes the light reflecting material, exposes the light emitting surface, includes the light emitting element and a covering member that covers a part of the light transmitting member, and the first reflecting surface or The light emitting device according to any one of (1) to (13) above, wherein the second reflecting surface is provided at an interface between the light guide member and the covering member.
(15) The light emitting device according to any one of (1) to (14) above, wherein the first reflecting surface or the second reflecting surface is a convex curved surface that is convex toward the side surface.

本発明によれば、互いに対向して配置された光透過部材と発光素子とを、その間とそこから延在した領域に設けられる導光部材により接合させることによって、発光素子から光を効率良く取り出し、導光して光透過部材に光結合することができ、高い発光効率を有し高輝度の発光が可能な発光装置を提供することができる。また、上記導光部材により接合された光透過部材および発光素子を、さらに光反射性の被覆部材により被覆して光透過部材の一部に発光面を備えた発光装置とすることにより、さらに効率良く導光することができ、また光透過部材が波長変換部材である場合には色むらの少ない配光特性および高い発光効率を有し高輝度発光が可能な発光装置を提供することができる。また、このような構
造により、発光素子と光透過部材の外形、大きさ、配置が異ならしめて、所望形状、外形寸法の光源できるため、小型化容易な発光装置が得られ、更には適宜光束、輝度などの発光特性を調節可能な発光装置とできる。
According to the present invention, light is efficiently extracted from a light emitting element by joining a light transmitting member and a light emitting element arranged so as to face each other with a light guide member provided between the light transmitting member and a region extending from the light transmitting member. It is possible to provide a light emitting device that can guide light and lightly couple to a light transmitting member, has high luminous efficiency, and can emit light with high brightness. Further, the light transmitting member and the light emitting element joined by the light guide member are further covered with a light reflecting coating member to form a light emitting device having a light emitting surface as a part of the light transmitting member, thereby further improving efficiency. It is possible to provide a light emitting device capable of guiding light well, and when the light transmitting member is a wavelength conversion member, has light distribution characteristics with less color unevenness and high luminous efficiency, and is capable of high-luminance light emission. Further, with such a structure, the outer shape, size, and arrangement of the light emitting element and the light transmitting member can be made different, so that a light source having a desired shape and outer size can be obtained. Therefore, a light emitting device that can be easily miniaturized can be obtained. It can be a light emitting device whose light emitting characteristics such as brightness can be adjusted.

本発明の一実施の形態に係る発光装置の概略上面図(b)と、そのAA断面における概略断面図(a)である。It is a schematic top view (b) of the light emitting device which concerns on one Embodiment of this invention, and is a schematic sectional view (a) in the AA cross section. 本発明の一実施の形態に係る発光装置の光源部周辺を説明する概略断面図である。It is schematic cross-sectional view explaining the periphery of the light source part of the light emitting device which concerns on one Embodiment of this invention. 本発明に係る比較例の発光装置の光源部周辺を説明する概略断面図である。It is schematic cross-sectional view explaining the periphery of the light source part of the light emitting device of the comparative example which concerns on this invention. 本発明の一実施の形態に係る発光素子の概略断面図である。It is the schematic sectional drawing of the light emitting element which concerns on one Embodiment of this invention. 本発明の一実施の形態に係る発光装置の概略断面図(a)と、その光源部周辺を説明する概略断面図(b)である。It is a schematic sectional view (a) of the light emitting device which concerns on one Embodiment of this invention, and is a schematic sectional view (b) explaining the periphery of the light source part. 本発明の一実施の形態に係る発光装置の光源部周辺を説明する概略断面図である。It is schematic cross-sectional view explaining the periphery of the light source part of the light emitting device which concerns on one Embodiment of this invention. 本発明の一実施の形態に係る発光装置の光源部周辺を説明するための概略断面図である。It is schematic cross-sectional view for demonstrating the periphery of the light source part of the light emitting device which concerns on one Embodiment of this invention. 本発明の一実施の形態に係る発光装置を説明する概略断面図である。It is schematic cross-sectional view explaining the light emitting device which concerns on one Embodiment of this invention. 本発明の一実施の形態に係る発光装置を説明する概略断面図である。It is schematic cross-sectional view explaining the light emitting device which concerns on one Embodiment of this invention.

以下、発明の実施の形態について適宜図面を参照して説明する。ただし、以下に説明する発光素子・装置は、本発明の技術思想を具体化するためのものであって、本発明を以下のものに特定しない。特に、以下に記載されている構成部品の寸法、材質、形状、その相対的配置等は特定的な記載がない限りは、本発明の範囲をそれのみに限定する趣旨ではなく、単なる説明例にすぎない。なお、各図面が示す部材の大きさや位置関係等は、説明を明確にするため誇張していることがある。さらに、本発明を構成する各要素は、複数の要素を同一の部材で構成して一の部材で複数の要素を兼用する態様としてもよいし、逆に一の部材の機能を複数の部材で分担して実現することもできる。また、以下に記載されている各実施の形態についても同様に、特に排除する記載が無い限りは各構成等を適宜組み合わせて適用できる。 Hereinafter, embodiments of the invention will be described with reference to the drawings as appropriate. However, the light emitting elements / devices described below are for embodying the technical idea of the present invention, and do not specify the present invention as the following. In particular, the dimensions, materials, shapes, relative arrangements, etc. of the components described below are not intended to limit the scope of the present invention to that alone, but are merely explanatory examples unless otherwise specified. Only. The size and positional relationship of the members shown in each drawing may be exaggerated to clarify the explanation. Further, each element constituting the present invention may be configured such that a plurality of elements are composed of the same member and the plurality of elements are combined with one member, or conversely, the function of one member is performed by the plurality of members. It can also be shared and realized. Similarly, with respect to each of the embodiments described below, each configuration and the like can be appropriately combined and applied unless otherwise specified.

本発明の発光装置は、図1,2に示すように、主として、発光素子10、光透過部材20、導光部材30、から構成される。発光素子10は、出射面を有し、光透過部材20は、外部に露出された表面21(発光面90)と、該表面21に対向する受光面22と、側面と、を各々有し、発光素子10は、その出射面を光透過部材の受光面22に対向させて配置して、発光素子10および光透過部材20の一方の部材を、他方の部材より外側に突出させる。導光部材30は、発光素子10と光透過部材20とを固着させる接着剤を適用でき、透光性を有して発光素子と光透過部材の表面、具体的には発光素子表面から光透過部材表面まで延在して設けられ、発光素子10の出射光を光透過部材20に導光する機能
を有する。この導光部材30は、互いに対向する発光素子の出射面と光透過部材の受光面22とを接合する接合領域31と、この接合領域より延在して、上記突出した表面(発光素子の出射面又は光透過部材の受光面22の一部)を被覆する被覆領域(32,37)と、を有している。導光部材は基板の実装面から離間され、発光素子10の実装側表面より後退して前記光透過部材20側に位置している。したがって、発光素子10から出射される光が導光部材30を伝搬して基板50に導光され、吸収されることを防止することができる。そして、該被覆領域の外表面には、発光素子10から出射される光を光透過部材20側に反射させる反射面が設けられている。このように、導光部材30の外表面の反射に
より、光の拡散を抑制し導光部材30中に光を集束させて、光透過部材20に導光することができ、吸収による光の損失を低減し、発光素子10から出射される光を効率良く光透過部材20に結合することができ、発光面の輝度分布を改善できる。また、発光素子と光変換部材を接合させることにより、発光面内の輝度や色度を良好な分布にできる。
As shown in FIGS. 1 and 2, the light emitting device of the present invention is mainly composed of a light emitting element 10, a light transmitting member 20, and a light guide member 30. The light emitting element 10 has an emitting surface, and the light transmitting member 20 has a surface 21 (light emitting surface 90) exposed to the outside, a light receiving surface 22 facing the surface 21, and a side surface, respectively. The light emitting element 10 is arranged so that its emitting surface faces the light receiving surface 22 of the light transmitting member, and one member of the light emitting element 10 and the light transmitting member 20 is projected outward from the other member. An adhesive that fixes the light emitting element 10 and the light transmitting member 20 can be applied to the light guide member 30, and the light transmitting member 30 has light transmittance and transmits light from the surface of the light emitting element and the light transmitting member, specifically, the surface of the light transmitting element. It is provided so as to extend to the surface of the member and has a function of guiding the emitted light of the light emitting element 10 to the light transmitting member 20. The light guide member 30 has a joint region 31 that joins an exit surface of a light emitting element facing each other and a light receiving surface 22 of a light transmitting member, and a protruding surface (emission of the light emitting element) extending from the joint region. It has a covering region (32, 37) that covers a surface or a part of a light receiving surface 22 of the light transmitting member. The light guide member is separated from the mounting surface of the substrate, recedes from the mounting side surface of the light emitting element 10, and is located on the light transmitting member 20 side. Therefore, it is possible to prevent the light emitted from the light emitting element 10 from propagating through the light guide member 30 and being guided to the substrate 50 and being absorbed. The outer surface of the covering region is provided with a reflecting surface that reflects the light emitted from the light emitting element 10 toward the light transmitting member 20. In this way, the reflection of the outer surface of the light guide member 30 suppresses the diffusion of light, and the light can be focused in the light guide member 30 to guide the light to the light transmitting member 20, and the light loss due to absorption. It is possible to efficiently combine the light emitted from the light emitting element 10 with the light transmitting member 20, and improve the brightness distribution of the light emitting surface. Further, by joining the light emitting element and the light conversion member, the brightness and chromaticity in the light emitting surface can be made a good distribution.

さらに、この被覆領域は、図1,2,5,6に示すように、上記突出部の表面と他方の側面とを接続するように被覆して、その被覆された側面に対向する導光部材の外表面に前記反射面が設けられていることが好ましい。一方の突出部の表面と、他方の側面と、を接続する傾斜面を外表面とすることで、被覆領域の外側への膨らみを抑え、その外表面で反射される光の光透過部材20までの光路長を短くし、更に外表面が凹曲面であることで、凸曲面の反射面となり導光部材30による導光機能を高めることができる。 Further, as shown in FIGS. 1, 2, 5 and 6, this covering region is covered so as to connect the surface of the protrusion and the other side surface, and the light guide member faces the covered side surface. It is preferable that the reflective surface is provided on the outer surface of the above. By using the inclined surface connecting the surface of one protruding portion and the other side surface as the outer surface, the bulge to the outside of the covering region is suppressed, and up to the light transmitting member 20 of the light reflected by the outer surface. By shortening the optical path length of the light path and making the outer surface a concave curved surface, it becomes a reflecting surface of a convex curved surface, and the light guiding function of the light guide member 30 can be enhanced.

また、本発明の発光装置は、図1,2に示すように、さらに光反射性の被覆部材40を備え、発光素子10および光透過部材20の一部をこの被覆部材40により被覆して、光透過部材の露出された表面21を装置の発光面90とでき、面発光型の発光装置とすることもできる。被覆部材40は、光反射性材料45を含有する充填材、封止材としても機能して、発光装置の小型化が実現できる。また、その光反射性により、導光部材30表面を被覆して設けることで、その導光作用を補助し、発光素子10からの出射光の光透過部材への光結合効率をさらに高めることができる。また、発光素子及び光透過部材の表面において、導光部材に被覆された領域と、該領域から露出された領域とを設け、それらの領域を被覆部材で覆うこと、すなわち、露出領域は直接、被覆領域は導光部材を介して、被覆部材に覆うことが好ましい。具体的には被覆部材が、上記被覆領域内の一方の側面を、導光部材30を介して被覆し、導光部材30から露出される他方の側面を被覆する。これにより、被覆部材による光反射機能でもって、被覆領域で導光部材30中の光の閉じ込め作用を強化しながら、露出領域で発光素子10から光透過部材20への光の伝搬領域を制限して、導光部材30により光を光透過部材20に効率良く導くことができる。さらに、前記被覆領域の反射面が、前記導光部材と前記被覆部材との界面に設けられていることにより、さらにその機能を高められ好ましい。このような構成により、発光素子10から出射される光の利用効率を高め、色むらが少なく配光特性に優れた高輝度な発光を実現することができる。 Further, as shown in FIGS. 1 and 2, the light emitting device of the present invention further includes a light-reflecting coating member 40, and a part of the light emitting element 10 and the light transmitting member 20 is covered with the coating member 40. The exposed surface 21 of the light transmitting member can be used as the light emitting surface 90 of the device, and can also be a surface light emitting device. The covering member 40 also functions as a filler and a sealing material containing the light-reflecting material 45, and the light emitting device can be miniaturized. Further, by covering the surface of the light guide member 30 with its light reflectivity, the light guide action can be assisted and the light coupling efficiency of the light emitted from the light emitting element 10 to the light transmitting member can be further enhanced. it can. Further, on the surface of the light emitting element and the light transmitting member, a region covered with the light guide member and a region exposed from the region are provided, and the region is covered with the covering member, that is, the exposed region is directly. It is preferable that the covering region is covered with the covering member via the light guide member. Specifically, the covering member covers one side surface in the covering region via the light guide member 30, and covers the other side surface exposed from the light guide member 30. As a result, the light reflection function of the covering member enhances the light confinement action in the light guide member 30 in the covering region, and limits the light propagation region from the light emitting element 10 to the light transmitting member 20 in the exposed region. Therefore, the light guide member 30 can efficiently guide the light to the light transmitting member 20. Further, it is preferable that the reflective surface of the covering region is provided at the interface between the light guide member and the covering member, so that its function can be further enhanced. With such a configuration, it is possible to improve the utilization efficiency of the light emitted from the light emitting element 10 and realize high-luminance light emission with less color unevenness and excellent light distribution characteristics.

(実施の形態1)
図1,2は、本発明の実施の形態1に係る発光装置100であり、図1(a)の断面は、概略上面の図1(b)のA−Aにおける概略断面図であり、図2はその光源部周辺の概略断面図である。図1に示す例の発光装置100は、発光面90を有する面発光型の発光装置である。この発光装置100は、主として、成長基板1上に半導体素子構造11を有する発光素子10と、発光面90となる表面21が露出され、該表面21と対向する受光面22を有する板状の光透過部材20と、発光素子10の出射光を光透過部材20に導光する導光部材30と、光反射性材料45を含有する被覆部材40と、から構成される。発光素子10は、その成長基板1の裏面である出射面を光透過部材の受光面22に対向させ
て、基板50の配線層51上にフリップチップ実装されており、介在する導光部材30により光透過部材20と光結合されている。基板50上には、発光素子10および光透過部材20を包囲する枠体55が設けられており、その内側に被覆部材40が充填されて、発光素子10と光透過部材20の一部は被覆部材40により被覆されている。このような発光装置100の発光領域つまり光放出の窓部は、実質的に光透過部材20の表面21にほぼ限定され、この表面21を発光面90とする面発光型の発光装置となる。また、発光装置100は、光透過部材20の表面21の形状、大きさによって、この表面21すなわち発光面90から放出される光の輝度、並びに配光の分布を制御可能となっている。さらに
、発光面内の輝度、色度が比較的均一な発光装置となる。ここで、光透過部材、発光素子の平面形状は図示するように矩形状であり、平面で発光素子が光透過部材に内包されている。
(Embodiment 1)
1 and 2 are a light emitting device 100 according to the first embodiment of the present invention, and the cross section of FIG. 1 (a) is a schematic cross-sectional view taken along the line AA of FIG. 1 (b) on the schematic upper surface. 2 is a schematic cross-sectional view around the light source portion. The light emitting device 100 of the example shown in FIG. 1 is a surface light emitting device having a light emitting surface 90. The light emitting device 100 mainly has a plate-shaped light having a light emitting element 10 having a semiconductor element structure 11 on a growth substrate 1 and a surface 21 to be a light emitting surface 90 exposed and having a light receiving surface 22 facing the surface 21. It is composed of a transmitting member 20, a light guide member 30 that guides the emitted light of the light emitting element 10 to the light transmitting member 20, and a coating member 40 containing a light reflecting material 45. The light emitting element 10 is flip-chip mounted on the wiring layer 51 of the substrate 50 with the emission surface, which is the back surface of the growth substrate 1, facing the light receiving surface 22 of the light transmitting member, and is mounted by the intervening light guide member 30. It is optically coupled to the light transmitting member 20. A frame 55 that surrounds the light emitting element 10 and the light transmitting member 20 is provided on the substrate 50, and a covering member 40 is filled inside the frame body 55, and the light emitting element 10 and a part of the light transmitting member 20 are covered. It is covered with a member 40. The light emitting region of the light emitting device 100, that is, the window portion for emitting light is substantially limited to the surface 21 of the light transmitting member 20, and the surface emitting device is a surface emitting type light emitting device having the surface 21 as the light emitting surface 90. Further, the light emitting device 100 can control the brightness of the light emitted from the surface 21, that is, the light emitting surface 90, and the distribution of the light distribution, depending on the shape and size of the surface 21 of the light transmitting member 20. Further, the light emitting device has a relatively uniform brightness and chromaticity in the light emitting surface. Here, the planar shapes of the light transmitting member and the light emitting element are rectangular as shown in the drawing, and the light emitting element is included in the light transmitting member in a plane.

図2を用いて、その光源部を詳述すると、導光部材30は、発光素子10と光透過部材20とを互いに対向させて接合する接合領域31を有し、より詳細には、光透過部材の受光面22において、発光素子10の出射面と対向する領域に設けられる。具体例、例えば後述の実施例、において、この接合領域の厚さは、0.01μm〜100μm程度である。導光部材30が接合領域で介在することで、発光素子と光透過部材とが離間され、大気などの気体が介在する場合に比して、発光素子10の出射面における屈折率差を緩和し、発光素子10から光を効率良く取り出すことができる。したがって、発光素子10の出射面からの光は、接合領域31内に透過されて光透過部材の受光面22に直接的に光結合する。 When the light source portion thereof is described in detail with reference to FIG. 2, the light guide member 30 has a bonding region 31 for joining the light emitting element 10 and the light transmitting member 20 so as to face each other, and more specifically, light transmitting. The light receiving surface 22 of the member is provided in a region facing the exit surface of the light emitting element 10. In a specific example, for example, an example described later, the thickness of this bonding region is about 0.01 μm to 100 μm. By interposing the light guide member 30 at the junction region, the light emitting element and the light transmitting member are separated from each other, and the difference in refractive index on the emission surface of the light emitting element 10 is relaxed as compared with the case where a gas such as atmosphere is present. , Light can be efficiently extracted from the light emitting element 10. Therefore, the light from the light emitting surface of the light emitting element 10 is transmitted into the bonding region 31 and directly coupled to the light receiving surface 22 of the light transmitting member.

本実施の形態では光透過部材の受光面22は、発光素子10の出射面より大きく、それを内包して、受光面22の一部が発光素子10の出射面より外側に突出している。言い換えれば、光透過部材20の側面は発光素子10の側面より外側に位置し、その周縁全体に突出部が設けられている。このような発光装置100は、発光装置の発光面90を、素子の出射面より、比較的大きい光放出の窓部として、放出光の光束を高くできる。そして、導光部材30は、上述の接合領域31から延在して、光透過部材の突出表面と、発光素子10の側面の一部に垂下した該側面とを被覆する第1の被覆領域32を有し、具体的には、この領域は上記接合領域より外側に突出した領域に設けられている。ここで、発光素子10から出射光は、通常、出射面だけでなく、側面や底面側(実装面側)からも放射されるため、その光の一部は主に発光素子の側面から第1の被覆領域32に入射され、導光される。つまり、上述の接合領域の場合と同様に、第1の被覆領域32においても、その発光素子の放射面の屈折率差を緩和し、光取り出し効率を高くできる。ここで、第1の被覆領域32の被覆部材40側に面する外表面、すなわち第1の被覆領域32の発光素子10の側面と対向する外表面は、発光素子10の出射光を、光透過部材20側に反射させる第1の反射面33を有し、従ってその出射光の反射光は、第1の反射面33により光透過部材20の受光面22側に反射されて導光されて、光透過部材20に光結合される。このように、発光素子10から側方への出射光を導光部材30内に一度取り出してから第1の反射面33により反射させることで、導光部材から露出され、発光素子10を光反射性の被覆部材40により直接被覆する形態に比して、発光素子10内での吸収による光の損失を低減でき、一旦、導光部材内で光が伝搬して広がることから、光結合効率や発光特性を高めることができる。 In the present embodiment, the light receiving surface 22 of the light transmitting member is larger than the emitting surface of the light emitting element 10, and includes the light receiving surface 22 so that a part of the light receiving surface 22 projects outward from the emitting surface of the light emitting element 10. In other words, the side surface of the light transmitting member 20 is located outside the side surface of the light emitting element 10, and a protrusion is provided on the entire peripheral edge thereof. In such a light emitting device 100, the luminous flux of the emitted light can be increased by using the light emitting surface 90 of the light emitting device as a window portion for emitting light that is relatively larger than the emitting surface of the element. Then, the light guide member 30 extends from the above-mentioned joining region 31 and covers the protruding surface of the light transmitting member and the side surface hanging on a part of the side surface of the light emitting element 10. Specifically, this region is provided in a region protruding outward from the joint region. Here, since the light emitted from the light emitting element 10 is usually emitted not only from the emitting surface but also from the side surface and the bottom surface side (mounting surface side), a part of the light is mainly from the side surface of the light emitting element. It is incident on the covering region 32 of the above and is guided. That is, as in the case of the above-mentioned bonding region, the difference in the refractive index of the radiation surface of the light emitting element can be alleviated and the light extraction efficiency can be increased in the first covering region 32 as well. Here, the outer surface of the first covering region 32 facing the covering member 40 side, that is, the outer surface facing the side surface of the light emitting element 10 of the first covering region 32 transmits the emitted light of the light emitting element 10. It has a first reflecting surface 33 that is reflected to the member 20 side, and therefore the reflected light of the emitted light is reflected by the first reflecting surface 33 to the light receiving surface 22 side of the light transmitting member 20 and guided. It is lightly coupled to the light transmitting member 20. In this way, the light emitted from the light emitting element 10 to the side is once taken out into the light guide member 30 and then reflected by the first reflecting surface 33, so that the light is exposed from the light guide member and the light emitting element 10 is reflected. Compared with the form of directly covering with the property covering member 40, the loss of light due to absorption in the light emitting element 10 can be reduced, and the light once propagates and spreads in the light guide member, so that the light coupling efficiency and the light coupling efficiency can be improved. The light emission characteristics can be improved.

上述したように、本実施の形態のように図1及び図2に示すように、導光部材30の第1の反射面33が被覆部材40との界面に設けられること反射機能を高められる。また、その界面はこの透光性の導光部材30と透光性基材中に光反射性材料を含有する被覆部材40とで構成されるため、被覆部材中にしみ出す緩やかな反射界面となる。このような構成は、導光部材30に第1の被覆領域32を形成後、被覆部材40を充填することで容易に形成可能であり量産性に優れた構造である。なお、第1の反射面33は、必ずしも被覆部材40との界面に設けられなくてもよい。例えば、第1の被覆領域32の被覆部材40側に面する外表面と被覆部材40とが離間され、その間に空隙が設けられ、第1の反射面
33が導光部材30と空気との界面に設けられる形態であってもよい。この形態によれば、この界面において導光部材30側が高屈折率となって、第1の被覆領域32内にて多くの光を反射させることができる。さらに、第1の被覆領域32から空隙内に透過した光成分も被覆部材40の表面にて再度反射させることも可能である。この形態のほか、例えば、第1の被覆領域32の外面に、銀(Ag)やアルミニウム(Al)などの高反射性の金属膜や誘電体多層膜や透光性粒子からなる層を設けて第1の反射面33を形成してもよい。
As described above, as shown in FIGS. 1 and 2 as in the present embodiment, the reflection function can be enhanced by providing the first reflection surface 33 of the light guide member 30 at the interface with the covering member 40. Further, since the interface is composed of the translucent light guide member 30 and the coating member 40 containing a light-reflecting material in the translucent base material, the interface is a gentle reflective interface that seeps into the coating member. Become. Such a configuration can be easily formed by forming the first covering region 32 in the light guide member 30 and then filling the covering member 40, and is a structure excellent in mass productivity. The first reflecting surface 33 does not necessarily have to be provided at the interface with the covering member 40. For example, the outer surface of the first covering region 32 facing the covering member 40 side and the covering member 40 are separated from each other, a gap is provided between them, and the first reflecting surface 33 is the interface between the light guide member 30 and air. It may be in the form provided in. According to this form, the light guide member 30 side has a high refractive index at this interface, and a large amount of light can be reflected in the first covering region 32. Further, the light component transmitted from the first covering region 32 into the void can also be reflected again on the surface of the covering member 40. In addition to this form, for example, a highly reflective metal film such as silver (Ag) or aluminum (Al), a dielectric multilayer film, or a layer made of translucent particles is provided on the outer surface of the first covering region 32. The first reflecting surface 33 may be formed.

また、発光装置100において、第1の被覆領域32の発光素子10の側面と対向する面は、該側面から光透過部材の受光面22側に傾斜した傾斜面であることが好ましい。これにより、発光素子10から側方に出射される光を光透過部材の受光面22側に良好に反射させることができ、また断面幅が突出表面に向かって広がる形態のため良好な光結合とできる。さらに、この傾斜面は平面であってもよいが、接合領域31に向かって凸な凸曲面であることで、平面である場合に比して第1の反射面33の表面積を増大でき、光の反射効率を高めることができるので好ましい。 Further, in the light emitting device 100, the surface of the first covering region 32 facing the side surface of the light emitting element 10 is preferably an inclined surface inclined from the side surface toward the light receiving surface 22 side of the light transmitting member. As a result, the light emitted laterally from the light emitting element 10 can be satisfactorily reflected toward the light receiving surface 22 side of the light transmitting member, and the cross-sectional width expands toward the protruding surface, so that good optical coupling is achieved. it can. Further, although the inclined surface may be a flat surface, the surface area of the first reflecting surface 33 can be increased as compared with the case where the inclined surface is a flat surface by having a convex curved surface convex toward the joint region 31, and the light can be increased. It is preferable because the reflection efficiency of the light can be increased.

第1の被覆領域32の形成方法は、特に限定されないが、例えば導光部材30を構成する樹脂材料を発光素子10の出射面上に適量塗布した後、光透過部材20を搭載することで形成することができる。この際、光透過部材20を適度に押圧してもよい。樹脂の塗布は、ディスペンス法、スタンピング法などで、光透過部材20の載置についても、光透過部材20を吸着、搬送、押圧可能なコレットを備えたダイボンディング装置で量産できる。 The method for forming the first covering region 32 is not particularly limited, but is formed by, for example, applying an appropriate amount of the resin material constituting the light guide member 30 on the exit surface of the light emitting element 10 and then mounting the light transmitting member 20. can do. At this time, the light transmitting member 20 may be pressed appropriately. The resin is applied by a dispensing method, a stamping method, or the like, and the light transmitting member 20 can be mass-produced by a die bonding apparatus equipped with a collet capable of adsorbing, transporting, and pressing the light transmitting member 20.

なお、導光部材30を構成する樹脂材料は、発光素子10又は光透過部材20の突出部から直接又は発光素子10の側面を伝って滴り、実装基板50上に達することがある。図3は、そのような導光部材36に垂下部が設けられる形態を説明するための概略断面図である。本発明と比較されるこの形態は、図3に示すように、導光部材36の接着樹脂が発光素子10の側面を伝って実装基板50上にまで連続的に垂れると、その垂下部で光経路が形成される。このため、発光素子10から側方又は下方に出射された光が、この垂下部により実装基板50側に導光されて、実装基板50の表面や配線51に到達して、吸収による光損失を生じる。また、垂下部の形成によって、発光素子10と基板50との間の領域へのアンダーフィル70等の形成、被覆部材40の浸入が遮断される場合があり、その空洞化で光の漏れる場合に光損失が起きる。特に、樹脂材料の塗布量が多過ぎると光透過部材20の突出部から基板50上に導光部材36が直接垂下したり、上記接合領域から分離して発光素子10と基板50と架橋したり、しても上記同様に光経路が形成され、光損失を招く虞がある。また、後述の実施の形態3では、本実施の形態のように光透過部材が突出する場合に比して、形成され難い構造であるものの同様に側面を被覆して実装基板に到達する垂下部が設けられ得る。そのため、樹脂材料の塗布量が過剰とならないように適宜調節し、また後述のように突出表面の面積、突出部の位置で調節する。 The resin material constituting the light guide member 30 may drip directly from the projecting portion of the light emitting element 10 or the light transmitting member 20 or along the side surface of the light emitting element 10 and reach the mounting substrate 50. FIG. 3 is a schematic cross-sectional view for explaining a mode in which a hanging portion is provided on such a light guide member 36. In this embodiment compared with the present invention, as shown in FIG. 3, when the adhesive resin of the light guide member 36 continuously hangs down on the mounting substrate 50 along the side surface of the light emitting element 10, light is emitted at the hanging portion thereof. A route is formed. Therefore, the light emitted laterally or downward from the light emitting element 10 is guided to the mounting substrate 50 side by the hanging portion and reaches the surface of the mounting substrate 50 or the wiring 51, resulting in light loss due to absorption. Occurs. Further, the formation of the hanging portion may block the formation of the underfill 70 or the like in the region between the light emitting element 10 and the substrate 50 and the infiltration of the covering member 40, and when the hollowing thereof causes light to leak. Light loss occurs. In particular, if the amount of the resin material applied is too large, the light guide member 36 may hang directly on the substrate 50 from the protruding portion of the light transmitting member 20, or may be separated from the bonding region and crosslinked with the light emitting element 10 and the substrate 50. However, an optical path is formed in the same manner as described above, which may lead to optical loss. Further, in the third embodiment described later, as compared with the case where the light transmitting member protrudes as in the present embodiment, the hanging portion which covers the side surface and reaches the mounting substrate in the same manner as the structure which is difficult to form. Can be provided. Therefore, the amount of the resin material applied is appropriately adjusted so as not to be excessive, and the area of the protruding surface and the position of the protruding portion are adjusted as described later.

したがって、第1の被覆領域32の外表面は、発光素子10の底面、実装面より前記光透過部材20側に位置していることが好ましく、第1の被覆領域32が被覆する範囲は、発光素子10の側面の途中までであることが好ましい。つまり、図1,2に示すように、発光素子10の側面において、導光部材に対して、出射面(上方)側に被覆された領域(第1の被覆領域32)と、底面、実装面(下方)側に露出された領域と、が設けられていることが望ましい。さらには、この露出領域は、被覆部材40で被覆されていることが好ましい。より具体的には、発光素子10が素子構造である半導体層11と該半導体層より出射面側の基板1とを有する場合、導光部材30が該基板の側面まで延在して被覆し、該半導体層11の側面を露出させていることが好ましい。これにより、発光層を含む半導体層11側の光反射性を高める一方、基板側の光透過性を高めることができる。また、第1の被覆領域32は、接合領域31から発光素子10の側面に一様に延在して形成されてもよいが、離散的、部分的に接合領域31から発光素子10の側面に垂下して形成されてもよい。 Therefore, the outer surface of the first covering region 32 is preferably located on the light transmitting member 20 side of the bottom surface and mounting surface of the light emitting element 10, and the range covered by the first covering region 32 is light emitting. It is preferably halfway on the side surface of the element 10. That is, as shown in FIGS. 1 and 2, on the side surface of the light emitting element 10, the region (first coated region 32) covered on the exit surface (upper side) side with respect to the light guide member, the bottom surface, and the mounting surface. It is desirable that an exposed area is provided on the (lower) side. Further, it is preferable that this exposed region is covered with the covering member 40. More specifically, when the light emitting element 10 has a semiconductor layer 11 having an element structure and a substrate 1 on the exit surface side of the semiconductor layer, the light guide member 30 extends to the side surface of the substrate and covers the substrate 1. It is preferable that the side surface of the semiconductor layer 11 is exposed. As a result, the light reflectivity on the semiconductor layer 11 side including the light emitting layer can be enhanced, while the light transmissivity on the substrate side can be enhanced. Further, the first covering region 32 may be formed so as to extend uniformly from the junction region 31 to the side surface of the light emitting element 10, but discretely or partially from the junction region 31 to the side surface of the light emitting element 10. It may be formed by hanging down.

このような形態は、導光部材30から露出させたい領域に予め離型剤を塗布するなど表面処理して、その領域が導光部材30等により被覆され難くすることにより達成しやすくなる。離型剤には、一般的に市販されているものを用いることができ、例えばダイキン社製の噴霧タイプのダイフリー、薬液タイプのオプツールなど、フッ素系離型剤を用いることができる。特に、発光素子10の出射面と対向する表面、実装面には表面処理されていることが好ましく、さらにはそこから連続する側面の一部、特に半導体層11の側面、すなわち半導体層11の露出表面に表面処理されていることが好ましい。また、この表面処理と被覆部材40とが一致していなくても良く、一部重なったり、離間されたり、する場合がある。 Such a form can be easily achieved by subjecting a region to be exposed from the light guide member 30 to a surface treatment such as applying a mold release agent in advance to make it difficult for the region to be covered with the light guide member 30 or the like. As the release agent, a commercially available one can be used, and for example, a fluorine-based release agent such as a spray type die-free or a chemical solution type optool manufactured by Daikin Corporation can be used. In particular, it is preferable that the surface facing the exit surface and the mounting surface of the light emitting element 10 are surface-treated, and further, a part of the side surface continuous from the surface, particularly the side surface of the semiconductor layer 11, that is, the exposure of the semiconductor layer 11. It is preferable that the surface is surface-treated. Further, the surface treatment and the covering member 40 do not have to be in agreement with each other, and may partially overlap or be separated from each other.

一方、図1,2に示す例の発光装置100において、光透過部材20の側面は導光部材30から露出され、更に光反射性の被覆部材40により被覆されていることが好ましい。このように、導光部材30が光透過部材20の側面も被覆する場合に比べて、導光部材30の外表面の外側への膨らみを抑えられ、したがって光透過部材20までの光路長を短くでき、光結合効率を高められる。また、上述したように受光面22側への光反射に適した形状、傾斜角を有する第1の反射面33を形成しやすくなり好ましい。 On the other hand, in the light emitting device 100 of the example shown in FIGS. 1 and 2, it is preferable that the side surface of the light transmitting member 20 is exposed from the light guide member 30 and further covered with the light reflecting covering member 40. In this way, as compared with the case where the light guide member 30 also covers the side surface of the light transmitting member 20, the outward bulge of the outer surface of the light guide member 30 can be suppressed, and therefore the optical path length to the light transmitting member 20 is shortened. It is possible to improve the optical coupling efficiency. Further, as described above, it is preferable to easily form the first reflecting surface 33 having a shape and an inclination angle suitable for light reflection toward the light receiving surface 22 side.

次に、本発明の発光装置の各構成部材および構造について、以下に詳述する。 Next, each component and structure of the light emitting device of the present invention will be described in detail below.

(発光素子)
発光素子10は公知のもの、具体的には半導体発光素子を利用でき、特にGaN系化合物半導体であれば、蛍光物質を効率良く励起できる短波長の可視光や紫外光が発光可能であるため好ましい。具体的な発光ピーク波長は240nm以上560nm以下、好ましくは380nm以上470nm以下である。なお、このほか、ZnSe系、InGaAs系、AlInGaP系半導体の発光素子でもよい。
(Light emitting element)
As the light emitting element 10, a known one, specifically, a semiconductor light emitting element can be used, and in particular, a GaN-based compound semiconductor is preferable because it can emit short-wavelength visible light or ultraviolet light capable of efficiently exciting a fluorescent substance. .. The specific emission peak wavelength is 240 nm or more and 560 nm or less, preferably 380 nm or more and 470 nm or less. In addition, a ZnSe-based, InGaAs-based, or AlInGaP-based semiconductor light-emitting element may be used.

(発光素子構造)
半導体層による発光素子構造11は、図4に例示するように少なくとも第1導電型(n型)層2と第2導電型(p型)層3とにより構成され、更にその間に活性層3を有する構造が好ましい。また、電極構造は、一方の主面側に第1導電型(負)、第2導電型(正)の両電極6,7が設けられる同一面側電極構造が好ましいが、半導体層の各主面に対向して電極が各々設けられる対向電極構造でも良い。発光素子10の実装形態も、例えば上記同一面側電極構造では、電極形成面を実装面として、それに対向する基板1側を主な出射面とするフリップチップ実装が、その出射面と光透過部材20との光学的な接続上好ましい。この他、電極形成面側を主な出射面として、その上に光透過部材を結合する実装、フ
ェイスアップ実装、また配線構造を備えた光透過部材にフリップチップ実装、上記対向電極構造で光透過部材と実装基板に接続すること、ができ、好ましくは発光素子と光透過部材に配線、電極を備えない実施例の実装が良い。なお、半導体層11の成長基板1は、発光素子構造を構成しない場合には除去してもよく、成長基板が除去された半導体層に、支持基板、例えば導電性基板または別の透光性部材・基板を接着した構造とすることもできる。この支持基板に光透過部材20を用いることもでき、その他、ガラス、樹脂などの光透過部材により半導体層が接着・被覆されて、支持された構造の素子でもよい。成長基板の除去は、例えば支持体、装置又はサブマウントに実装又は保持して、剥離、研磨、若しくはLLO(Laser Lift Off)で実施できる。また、発光素子10は光反
射構造を有することができ、具体的には、半導体層11の互いに対向する2つの主面の内、光取り出し側(出射面側)と対向する他方の主面を光反射側(図1における下側)とし、この光反射側の半導体層内や電極などに光反射構造を設けることができる。光反射構造の例として、半導体層内に多層膜反射層が設ける構造、あるいは半導体層の上にAg、Al等の光反射性の高い金属膜や誘電体多層膜を有する電極、反射層を設けた構造がある。
(Light emitting element structure)
As illustrated in FIG. 4, the light emitting device structure 11 made of a semiconductor layer is composed of at least a first conductive type (n type) layer 2 and a second conductive type (p type) layer 3, and an active layer 3 is further formed between them. The structure having is preferable. Further, the electrode structure is preferably the same surface side electrode structure in which both the first conductive type (negative) and the second conductive type (positive) electrodes 6 and 7 are provided on one main surface side, but each main surface of the semiconductor layer. A counter electrode structure in which electrodes are provided so as to face each other may be used. As for the mounting form of the light emitting element 10, for example, in the same surface side electrode structure, the flip chip mounting in which the electrode forming surface is the mounting surface and the substrate 1 side facing the electrode forming surface is the main emitting surface is the emitting surface and the light transmitting member. It is preferable in terms of optical connection with 20. In addition, mounting with the electrode forming surface side as the main emission surface and connecting a light transmitting member on it, face-up mounting, flip chip mounting on a light transmitting member having a wiring structure, and light transmission by the counter electrode structure. It is possible to connect the member to the mounting substrate, and it is preferable to mount the embodiment in which the light emitting element and the light transmitting member are not provided with wiring or electrodes. The growth substrate 1 of the semiconductor layer 11 may be removed when the light emitting element structure is not formed, and a support substrate, for example, a conductive substrate or another translucent member may be removed from the semiconductor layer from which the growth substrate has been removed. -It is also possible to have a structure in which a substrate is bonded. A light transmitting member 20 can be used for this support substrate, and an element having a structure in which a semiconductor layer is adhered and coated with a light transmitting member such as glass or resin may be used. Removal of the growth substrate can be carried out, for example, by mounting or holding it on a support, device or submount, peeling, polishing, or LLO (Laser Lift Off). Further, the light emitting element 10 can have a light reflection structure, and specifically, of the two main surfaces of the semiconductor layer 11 facing each other, the other main surface facing the light extraction side (emission surface side) is used. A light reflection structure can be provided in the semiconductor layer or electrodes on the light reflection side on the light reflection side (lower side in FIG. 1). As an example of the light reflection structure, a structure in which a multilayer reflective layer is provided in the semiconductor layer, or an electrode or a reflective layer having a metal film having high light reflectivity such as Ag or Al or a dielectric multilayer film is provided on the semiconductor layer. There is a structure.

(窒化物半導体発光素子)
発光素子10の一例として、図4の窒化物半導体の発光素子10では、成長基板1であるC面サファイア基板の上に、第1の窒化物半導体層2であるn型半導体層、活性層3である発光層、第2の窒化物半導体層4であるp型半導体層が順にエピタキシャル成長されている。そして、n型層2の一部が露出されて第1の電極7であるn型パッド電極を形成し、p型層4のほぼ全面にITO等の透光性導電層5、第2の電極6であるp型パッド電極が形成されている。さらに、保護膜8をn型、p型パッド電極6,7の表面を露出し、半導体層を被覆して設けられる。なお、n型パッド電極7は、p型同様に透光性導電層を介して形成してもよい。成長基板1は、C面サファイアの他、R面、及びA面、スピネル
(MgAl)のような絶縁性基板、また炭化珪素(6H、4H、3C)、Si、ZnS、ZnO、GaAs、GaNやAlN等の半導体の導電性基板がある。窒化物半導体の例としては、一般式がInAlGa1−x−yN(0≦x、0≦y、x+y≦1)の他、BやP、Asを混晶してもよい。また、n型、p型半導体層2,4は、単層、多層を特に限定されず、活性層3は単一(SQW)又は多重量子井戸構造(MQW)が好ましい。青色発光の素子構造11の例としては、サファイア基板上に、バッファ層などの窒化物半導体の下地層、例えば低温成長薄膜GaNとGaN層、を介して、n型半導体層として、例えばSiドープGaNのn型コンタクト層とGaN/InGaNのn型多層膜層が積層され、続いてInGaN/GaNのMQWの活性層、更にp型半導体層として、例えばMgドープのInGaN/AlGaNのp型多層膜層とMgドープGaNのp型コンタクト層が積層された構造がある。
(Nitride semiconductor light emitting device)
As an example of the light emitting element 10, in the nitride semiconductor light emitting element 10 of FIG. 4, the n-type semiconductor layer and the active layer 3 which are the first nitride semiconductor layers 2 are placed on the C-plane sapphire substrate which is the growth substrate 1. The light emitting layer and the p-type semiconductor layer, which is the second nitride semiconductor layer 4, are epitaxially grown in this order. Then, a part of the n-type layer 2 is exposed to form the n-type pad electrode which is the first electrode 7, and the translucent conductive layer 5 such as ITO and the second electrode cover almost the entire surface of the p-type layer 4. A p-type pad electrode of No. 6 is formed. Further, the protective film 8 is provided by exposing the surfaces of the n-type and p-type pad electrodes 6 and 7 and covering the semiconductor layer. The n-type pad electrode 7 may be formed via a translucent conductive layer as in the p-type. The growth substrate 1 includes C-plane sapphire, R-plane, A-plane, an insulating substrate such as spinel (MgAl 2 O 4 ), silicon carbide (6H, 4H, 3C), Si, ZnS, ZnO, and GaAs. , GaN, AlN and other semiconductor conductive substrates. As an example of the nitride semiconductor, in addition to the general formula In x Al y Ga 1-x-y N (0 ≦ x, 0 ≦ y, x + y ≦ 1), B, P, and As may be mixed. .. The n-type and p-type semiconductor layers 2 and 4 are not particularly limited to a single layer or a multilayer, and the active layer 3 is preferably a single (SQW) or multiple quantum well structure (MQW). As an example of the element structure 11 that emits blue light, an n-type semiconductor layer, for example, Si-doped GaN, is formed on a sapphire substrate via a base layer of a nitride semiconductor such as a buffer layer, for example, a low-temperature growth thin film GaN and a GaN layer. N-type contact layer and GaN / InGaN n-type multilayer film layer are laminated, followed by an InGaN / GaN MQW active layer, and further as a p-type semiconductor layer, for example, an Mg-doped InGaN / AlGaN p-type multilayer film layer. There is a structure in which a p-type contact layer of Mg-doped GaN is laminated.

(光透過部材)
また図1の発光装置100は、発光素子10からの光を透過する光透過部材20を備える。光透過部材20は、通過する光の少なくとも一部を波長変換可能な波長変換材料を有する光変換部材であることが好ましい。例えば実施例のように、光源からの一次光が、光透過部材20中の波長変換材料としての蛍光体を励起することで、一次光と異なった波長を持つ二次光が得られ、さらに一次光との混色により、所望の色相を有する出射光を実現できる。
(Light transmitting member)
Further, the light emitting device 100 of FIG. 1 includes a light transmitting member 20 that transmits light from the light emitting element 10. The light transmitting member 20 is preferably a light conversion member having a wavelength conversion material capable of wavelength-converting at least a part of the passing light. For example, as in the embodiment, the primary light from the light source excites a phosphor as a wavelength conversion material in the light transmitting member 20, so that secondary light having a wavelength different from that of the primary light is obtained, and further primary. By mixing the color with light, it is possible to realize an emitted light having a desired hue.

上述の通り、実施の形態1の光透過部材20は、表面21(発光面90)からの平面視において発光素子10を内包し、その側面が、発光素子10の側面(端面)よりも外方に突出し、発光素子10の出射面より幅広な受光面22でもって導光部材を介して光学的に接続されるため損失が少ない。なお、光透過部材の側面の発光素子の側面に対する突出長さは、発光素子の厚さに比して、例えば0.25倍以上5倍以下であり、具体的には0.5倍以上2倍以下である。例として、実施例1の発光装置においては、光透過部材20の終端に約50μmの幅で突出している。このほか、後述の実施の形態3に示すように、光透過部材の側面が、発光素子の側面よりも内側に位置する、つまり発光素子の出射面が突出させる形態でもよく、この例のように光透過部材の受光面22を発光素子10の出射面より小さくした形態であってもよい。この形態であれば、その突出長さは、光透過部材の厚さに比して、例えば0.25倍以上5倍以下であり、具体的には0.5倍以上2倍以下である。発光素子に対して発光領域を絞ることで相対的に輝度が高められ、また混色の均一化が図れ、色ムラが低減される。また、光透過部材20の側面が発光素子10の側面と略同一面上に位置する形態であれば、光透過部材の外縁部において、発光素子10からの光量が不足して色ムラが発生しやすくなるのを抑制できる。 As described above, the light transmitting member 20 of the first embodiment includes the light emitting element 10 in a plan view from the surface 21 (light emitting surface 90), and the side surface thereof is outward from the side surface (end surface) of the light emitting element 10. The light receiving surface 22 is wider than the emitting surface of the light emitting element 10 and is optically connected via the light guide member, so that the loss is small. The protruding length of the side surface of the light transmitting member with respect to the side surface of the light emitting element is, for example, 0.25 times or more and 5 times or less, specifically 0.5 times or more and 2 times, as compared with the thickness of the light emitting element. It is less than double. As an example, in the light emitting device of the first embodiment, the light emitting device has a width of about 50 μm protruding from the end of the light transmitting member 20. In addition, as shown in the third embodiment described later, the side surface of the light transmitting member may be located inside the side surface of the light emitting element, that is, the emitting surface of the light emitting element may protrude, as in this example. The light receiving surface 22 of the light transmitting member may be smaller than the emitting surface of the light emitting element 10. In this form, the protruding length is, for example, 0.25 times or more and 5 times or less, specifically 0.5 times or more and 2 times or less, as compared with the thickness of the light transmitting member. By narrowing the light emitting region with respect to the light emitting element, the brightness is relatively increased, the color mixing can be made uniform, and the color unevenness is reduced. Further, if the side surface of the light transmitting member 20 is located on substantially the same surface as the side surface of the light emitting element 10, the amount of light from the light emitting element 10 is insufficient at the outer edge of the light transmitting member 10 and color unevenness occurs. It can be suppressed from becoming easy.

ここで、光透過部材20の母材となる透光性材料としては、下記被覆部材40と同様な材料を用いることができ、例えば樹脂、又はガラスなどの無機物を用いることができる。変換機能を備えない場合も、蛍光体を除いて、又はそれに置換して、光変換の光透過部材と同様の材料を用いることが好ましい。また、表面21、受光面22は、実施例のように光透過部材が板状である場合には、両面とも略平坦な面であること、更には対向する両面が互いに略平行であることが本発明の導光部材を介した光結合の効率が高まり、また接合が容易となり好ましい。一方で、板状に限らず、全体又は一部に曲面を有する形態、凹凸面などの面状の形態など、種々の形状若しくは形態、例えば集光、分散するための形状、例えばレンズ状などのような光学的な形状とすることもできる。また、波長変換機能として、発光素子の一次光とその変換光(二次光)の混色光を発光する他に、例えば発光素子の紫外光による変換光、若しくは複数の変換光による混色光のように、一次光から変換された二次光を主に出射する発光装置とすることもできる。 Here, as the translucent material used as the base material of the light transmitting member 20, the same material as the following covering member 40 can be used, and for example, an inorganic substance such as resin or glass can be used. Even if it does not have a conversion function, it is preferable to use a material similar to the light transmitting member for light conversion by removing or replacing the phosphor. Further, when the light transmitting member is plate-shaped as in the embodiment, the surface 21 and the light receiving surface 22 are both substantially flat surfaces, and the opposing surfaces are substantially parallel to each other. It is preferable that the efficiency of optical coupling via the light guide member of the present invention is increased and the bonding is easy. On the other hand, it is not limited to a plate shape, but various shapes or forms such as a shape having a curved surface in whole or a part, a planar shape such as an uneven surface, for example, a shape for condensing and dispersing, for example, a lens shape, etc. It can also have such an optical shape. Further, as a wavelength conversion function, in addition to emitting mixed color light of the primary light of the light emitting element and its converted light (secondary light), for example, conversion light by ultraviolet light of the light emitting element or mixed color light by a plurality of converted lights. In addition, it can also be a light emitting device that mainly emits secondary light converted from primary light.

波長変換機能を備えた光透過部材20は、具体的にガラス板、それに光変換部材を備えたもの、あるいは光変換部材の蛍光体結晶若しくはその相を有する単結晶体、多結晶体、アモルファス体、セラミック体、あるいは蛍光体結晶粒子による、それと適宜付加された透光性材料との焼結体、凝集体、多孔質性材料、それらに透光性材料、例えば透光性樹脂を混入、含浸したもの、あるいは蛍光体粒子を含有する透光性部材、例えば透光性樹脂の成形体等から構成される。なお、光透過部材20は、樹脂等の有機材料よりも無機材料で構成されることが耐熱性の観点からは好ましい。具体的には蛍光体を含有する透光性の無機材料からなることが好ましく、特に蛍光体と無機物(結合材、バインダー)との焼結体
、あるいは蛍光体からなる焼結体や結晶とすることで信頼性が高まる。なお、実施例のYAGの蛍光体を用いる場合、YAGの単結晶や高純度の焼結体のほか、アルミナ(Al)を結合材とするYAG/アルミナの焼結体、ガラスを結合材とした焼結体が信頼性の観点から好ましい。また、光透過部材20を板状とすることで、面状に構成される発光素子10の出射面との結合効率が良く、光透過部材20の主面とが略平行になるよう容易に位置合わせできる。加えて、光透過部材20の厚みを略一定とすることで、通過する光の波長変換量を略均一として混色の割合を安定させ、発光面90の部位における色むらを抑止できる。このため、1つの光透過部材20に複数の発光素子10を搭載する場合において、個々の発光素子10の配置に起因する発光面90内の輝度や色度の分布にむらが少なく略均一で高輝度の発光を得ることができる。なお、波長変換機能を備えた光透過部材20の厚みは、発光効率や色度調整において、10μm以上500μm以下であることが好ましく、さらには50μm以上300μm以下であることがより好ましい。
The light transmitting member 20 having a wavelength conversion function is specifically a glass plate, a member provided with the light conversion member, or a phosphor crystal of the light conversion member or a monocrystal, a polycrystal, or an amorphous body having a phase thereof. , Ceramic body, or a sintered body of a translucent material added appropriately by a ceramic body or a fluorescent material, an aggregate, a porous material, and a translucent material, for example, a translucent resin, mixed and impregnated therein. It is composed of a light-transmitting member or a light-transmitting member containing phosphor particles, for example, a molded body of a light-transmitting resin. From the viewpoint of heat resistance, it is preferable that the light transmitting member 20 is made of an inorganic material rather than an organic material such as a resin. Specifically, it is preferably made of a translucent inorganic material containing a fluorescent substance, and in particular, a sintered body of a fluorescent substance and an inorganic substance (bonding material, binder), or a sintered body or crystal made of a fluorescent substance. This increases reliability. When the YAG phosphor of the example is used, in addition to a single crystal of YAG and a high-purity sintered body, a YAG / alumina sintered body using alumina (Al 2 O 3 ) as a binder and glass are bonded. A sintered body used as a material is preferable from the viewpoint of reliability. Further, by making the light transmitting member 20 plate-shaped, the coupling efficiency with the emitting surface of the light emitting element 10 formed in a planar shape is good, and the position is easily positioned so as to be substantially parallel to the main surface of the light transmitting member 20. Can be matched. In addition, by making the thickness of the light transmitting member 20 substantially constant, the wavelength conversion amount of the passing light can be made substantially uniform, the ratio of color mixing can be stabilized, and color unevenness at the portion of the light emitting surface 90 can be suppressed. Therefore, when a plurality of light emitting elements 10 are mounted on one light transmitting member 20, the distribution of brightness and chromaticity in the light emitting surface 90 due to the arrangement of the individual light emitting elements 10 is not uneven and is substantially uniform and high. Luminance emission can be obtained. The thickness of the light transmitting member 20 having a wavelength conversion function is preferably 10 μm or more and 500 μm or less, and more preferably 50 μm or more and 300 μm or less in terms of luminous efficiency and chromaticity adjustment.

波長変換部材は、青色発光素子と好適に組み合わせて白色発光とでき、波長変換部材に用いられる代表的な蛍光体としては、ガーネット構造のセリウムで付括されたYAG系蛍光体(イットリウム・アルミニウム・ガーネット)及びLAG系蛍光体(ルテチウム・アルミニウム・ガーネット)が挙げられ、特に、高輝度且つ長時間の使用時においては(Re1−xSm(Al1−yGa12:Ce(0≦x<1、0≦y≦1、但し、Reは、Y、Gd、La、Luからなる群より選択される少なくとも一種の元素である。)等が好ましい。またYAG、LAG、BAM、BAM:Mn、(Zn、Cd)Zn:Cu、CCA、SCA、SCESN、SESN、CESN、CASBN及びCaAlSiN:Euからなる群から選択される少なくとも1種を含む蛍光体が使用できる。波長変換部材は、光透過部材の他に、例えば光透過部材と発光素子との間、その結合部材中、発光素子と被覆部材との間、にも設けることもできる。光透過部材、波長変換部材及び焼結体も同様に発光装置中に配置できる。黄〜赤色発光を有する窒化物系蛍光体等を用いて赤味成分を増し、平均演色評価数Raの高い照明や電球色LED等を実現することもできる。具体的には、発光素子の発光波長に合わせてCIEの色度図上の色度点の異なる蛍光体の量を調整し含有させることでその蛍光体間と発光素子で結ばれる色度図上の任意の点を発光させることができる。その他に、近紫外〜可視光を黄色〜赤色域に変換する窒化物蛍光体、酸窒化物蛍光体、珪酸塩蛍光体を用いることができる。例えば、LSiO:Eu(Lはアルカリ土類金属)、特に(SrMae1−xSiO:Eu(MaeはCa、Baなどのアルカリ土類金属)などが挙げられる。窒化物系蛍光体、オキシナイトライド(酸窒化物)蛍光体としては、Sr−Ca−Si−N:Eu、Ca−Si−N:Eu、Sr−Si−N:Eu、Sr−Ca−Si−O−N:Eu、Ca−Si−O−N:Eu、Sr−Si−O−N:Euなどがあり、アルカリ土類窒化ケイ素蛍光体としては、一般式LSi:Eu、一般式LSi(2/3x+4/3y):Eu若しくはLSi(2/3x+4/3y−2/3z):Eu(Lは、Sr、Ca、SrとCaのいずれか)で表される。 The wavelength conversion member can be preferably combined with a blue light emitting element to emit white light, and a typical phosphor used for the wavelength conversion member is a YAG-based phosphor (yttrium, aluminum, etc.) enclosed in cerium having a garnet structure. garnet) and LAG-based phosphor (lutetium aluminum garnet) can be mentioned, in particular, at the time of high luminance and long-term use (Re 1-x Sm x) 3 (Al 1-y Ga y) 5 O 12 : Ce (0 ≦ x <1, 0 ≦ y ≦ 1, where Re is at least one element selected from the group consisting of Y, Gd, La, and Lu) and the like are preferable. Further, a phosphor containing at least one selected from the group consisting of YAG, LAG, BAM, BAM: Mn, (Zn, Cd) Zn: Cu, CCA, SCA, SCESN, SESN, CESN, CASBN and CaAlSiN 3 : Eu. Can be used. In addition to the light transmitting member, the wavelength conversion member may be provided, for example, between the light transmitting member and the light emitting element, in the coupling member thereof, and between the light emitting element and the covering member. Similarly, the light transmitting member, the wavelength conversion member, and the sintered body can be arranged in the light emitting device. It is also possible to increase the reddish component by using a nitride-based phosphor or the like having yellow to red light emission, and to realize lighting, a light bulb color LED, or the like having a high average color rendering index Ra. Specifically, by adjusting and containing the amount of phosphors having different chromaticity points on the CIE chromaticity diagram according to the emission wavelength of the light emitting element, the phosphors and the chromaticity diagram connected by the light emitting element are connected. Any point of can be made to emit light. In addition, a nitride phosphor, an oxynitride phosphor, and a silicate phosphor that convert near-ultraviolet to visible light into a yellow to red region can be used. For example, L 2 SiO 4 : Eu (L is an alkaline earth metal), in particular (Sr x Mae 1-x ) 2 SiO 4 : Eu (Mae is an alkaline earth metal such as Ca, Ba) and the like can be mentioned. Nitride-based phosphors and oxynitride (oxynitride) phosphors include Sr-Ca-Si-N: Eu, Ca-Si-N: Eu, Sr-Si-N: Eu, Sr-Ca-Si. -O-N: Eu, Ca-Si-ON: Eu, Sr-Si-ON: Eu, etc. As an alkaline earth silicon nitride phosphor, the general formula LSi 2 O 2 N 2 : Eu , General formula L x S y N (2 / 3x + 4 / 3y) : Eu or L x S y O z N (2 / 3x + 4 / 3y-2 / 3z) : Eu (L is Sr, Ca, Sr and Ca It is represented by either).

(被覆部材)
被覆部材40は、図1に示すように、光透過部材20の一部を被覆し、具体的には光透過部材20の側面の少なくとも一部を被覆する。そして、本発明においては、被覆部材が素子等から垂下され、光の漏れ経路の形成を防ぐことから、基板、更にはそれに設けられた配線より、被覆部材の反射率が高いことが好ましい。また、光反射材料を含有する被覆部材40は、その基材は透光性の樹脂材料が好ましく、シリコーン樹脂組成物、変性シリコーン樹脂組成物等を使用することが好ましいが、エポキシ樹脂組成物、変性エポキシ樹脂組成物、アクリル樹脂組成物等の透光性を有する絶縁樹脂組成物を用いることができる。また、これらの樹脂を少なくとも一種以上含むハイブリッド樹脂等、耐候性に優れた被覆部材も利用できる。さらに、ガラス、シリカゲル等の耐光性に優れた無機物を用いることもできる。また、樹脂材料を成形することで、所望の形状に成形でき、また所望領域を被覆でき、本発明では光源部の発光素子、導光部材、光透過部材の表面、特にその側面を被覆して形成できる。また、その発光面側の表面も同様に所望形状とでき、図示するような平坦な面状の他、凹や凸の曲面とできる。実施の形態1では耐熱性・耐候性の観点から被覆部材としてシリコーン樹脂を使用する。
(Coating member)
As shown in FIG. 1, the covering member 40 covers a part of the light transmitting member 20, specifically, at least a part of the side surface of the light transmitting member 20. In the present invention, the covering member is hung from the element or the like to prevent the formation of a light leakage path. Therefore, it is preferable that the covering member has a higher reflectance than the substrate and the wiring provided therein. The base material of the coating member 40 containing the light-reflecting material is preferably a translucent resin material, and a silicone resin composition, a modified silicone resin composition, or the like is preferably used. A translucent insulating resin composition such as a modified epoxy resin composition or an acrylic resin composition can be used. Further, a coating member having excellent weather resistance, such as a hybrid resin containing at least one of these resins, can also be used. Further, an inorganic substance having excellent light resistance such as glass and silica gel can also be used. Further, by molding the resin material, it can be molded into a desired shape and can cover a desired region. In the present invention, the surface of the light emitting element, the light guide member, and the light transmitting member of the light source portion, particularly the side surface thereof is coated. Can be formed. Further, the surface on the light emitting surface side can be similarly formed into a desired shape, and can be a flat surface as shown in the figure, or a concave or convex curved surface. In the first embodiment, a silicone resin is used as a coating member from the viewpoint of heat resistance and weather resistance.

また、被覆部材40は、上記基材中に少なくとも1種類の光反射性材料45を含有してなる。光反射性材料45を含有することで、被覆部材40の反射率が高まり、更に好適には低吸収性の粒子を用いると、光吸収、損失が低減され、光散乱性を備えた被覆部材とできる。被覆部材40中に含有される光反射性材料45は、Ti、Zr、Nb、Al、Siからなる群から選択される1種の酸化物、若しくはAlN、MgFの少なくとも1種であり、具体的にはTiO、ZrO、Nb、Al、MgF、AlN、SiOよりなる群から選択される少なくとも1種である。光反射性材料の粒子が、Ti、Zr、Nb、Alからなる群から選択される1種の酸化物であることで、材料の高い反射性及び低吸収性とでき、基材、特に透光性樹脂との屈折率差を高められ、好ましい。また、被
覆部材40は、上記光反射性材料による成形体でもって構成することもでき、具体的には上記粒子を凝集した凝集体、焼結体、などの多孔質材料とすることもでき、その他に、ゾル・ゲル法による成形体でもよく、上記光反射性材料と多孔質内の空気との屈折率差を大きくし、光反射性を高められるため、また無機材料で構成できるため、好ましい。一方、上記樹脂などの母材を備えた被覆部材と比較すると、所望の形状に成形すること及びその被覆領域の制御性が良く、また封止性能、気密性能を高めること、ができ、本発明では上記母材を備えた被覆部材とする方が好ましい。また、両者の被覆部材の特性を考慮して、両者の複合的な成形体とでき、例えば、多孔質成形体の外表面側に樹脂を含浸させ、発光素子側の内表面側では多孔質とした構造とできる。このように、被覆部材若しくはそれに
よる包囲体は、内部領域と外部とが連通されたり、気体透過性であったりしてもよく、少なくとも光が漏れ出さない形態であれば良い。
Further, the covering member 40 contains at least one kind of light-reflecting material 45 in the base material. By containing the light-reflecting material 45, the reflectance of the covering member 40 is increased, and more preferably, when low-absorbing particles are used, light absorption and loss are reduced, and the covering member has light scattering property. it can. The light-reflecting material 45 contained in the coating member 40 is one kind of oxide selected from the group consisting of Ti, Zr, Nb, Al, and Si, or at least one kind of AlN and MgF, and is specifically. Is at least one selected from the group consisting of TiO 2 , ZrO 2 , Nb 2 O 5 , Al 2 O 3 , MgF, Al N, and SiO 2 . Since the particles of the light-reflecting material are one kind of oxide selected from the group consisting of Ti, Zr, Nb, and Al, the material can have high reflectivity and low absorbency, and the base material, particularly translucent. It is preferable because the difference in refractive index from the sex resin can be increased. Further, the covering member 40 can be formed of a molded body made of the light-reflecting material, and specifically, can be a porous material such as an agglomerate or a sintered body in which the particles are aggregated. In addition, a molded product obtained by a sol-gel method may be used, which is preferable because the difference in refractive index between the light-reflecting material and the air in the porous material can be increased, the light reflectivity can be enhanced, and the material can be composed of an inorganic material. .. On the other hand, as compared with a covering member provided with a base material such as the above resin, it is possible to form a desired shape, have better controllability of the covering region, and improve sealing performance and airtightness. Then, it is preferable to use a covering member provided with the above base material. Further, in consideration of the characteristics of both covering members, a composite molded body of both can be obtained. For example, the outer surface side of the porous molded body is impregnated with resin, and the inner surface side of the light emitting element side is porous. The structure can be made. As described above, the covering member or the surrounding body thereof may be in a form in which the inner region and the outer region are communicated with each other or the outer region is gas-permeable, and at least the light does not leak out.

上述した母材中に光反射性材料45を含有する被覆部材40では、その含有濃度、密度により光の漏れ出す深さが異なるため、発光装置形状、大きさに応じて、適宜濃度、密度を調整すると良い。例えば比較的小さな発光装置で肉厚を小さくする場合は、高濃度の光反射性材料45を備えることが好ましい。一方で、光反射性材料45を含有する被覆部材40の原料の調製、その原料の塗布、成形などの製造過程において、それに適したようにその濃度を調整する。上記多孔質体についても同様である。一例として、実施例の場合には、光反射性材料45の含有濃度は20重量パーセント濃度(wt%)以上、その肉厚は20μm以上とするのが好適であり、発光面90から高輝度で指向性の高い放出光が得られ、適度な粘性で被覆部材によるアンダーフィルの形成など容易にできる。また、光反射性材料の濃度を高くすれば被覆部材の熱拡散性を高めることができる。 In the coating member 40 containing the light-reflecting material 45 in the base material described above, the depth at which light leaks differs depending on the concentration and density thereof. Therefore, the concentration and density are appropriately adjusted according to the shape and size of the light emitting device. You should adjust it. For example, when the wall thickness is reduced with a relatively small light emitting device, it is preferable to provide a high-concentration light-reflecting material 45. On the other hand, in the manufacturing process such as preparation of the raw material of the coating member 40 containing the light-reflecting material 45, coating of the raw material, and molding, the concentration is adjusted so as to be suitable for it. The same applies to the above-mentioned porous body. As an example, in the case of Examples, it is preferable that the content concentration of the light-reflecting material 45 is 20% by weight (wt%) or more, and the wall thickness thereof is 20 μm or more, and the light emitting surface 90 has high brightness. Emitted light with high directivity can be obtained, and underfill can be easily formed by the covering member with appropriate viscosity. Further, if the concentration of the light-reflecting material is increased, the thermal diffusivity of the covering member can be enhanced.

被覆部材の形成領域は、光透過部材20における少なくとも側面に被覆部材40を設け、好ましくは発光素子の側面も被覆し、更に好ましくは、光透過部材及び発光素子を含む光源部において発光面を露出させてその他を被覆し、導光部材30を介する場合も同様である。これにより、光透過部材の側面から光が漏れ出すのを回避でき、その側面からの比較的強度の大きい、また光り変換部材を有する場合は色味差を有する光を抑止して、放射光の指向性を良好にし、輝度ムラ、色ムラを低減できる。また、各部材、素子の側面を被覆して、光取り出し方向側へ制限することで、指向性、輝度を高められる。また、光透過部材20が波長変換材料を含有する場合には、この波長変換材料の発熱が特に著しいため、それを改善できる。光透過部材20の側面が被覆部材40により被覆され、かつ表面21が露出されていれば、その外面形状は特に限定されず、図1に示すように表出面が光透過部材の表面21よりも窪んだ構造でもよい。この発光面90が突出することで被覆部材40による遮光を回避でき、また略同一面でもよく、所望の表面とできる。実施の形態1において、被覆部材40は受光面22の一部も被覆し、図示するように、発光素子10の周囲を、具体的に光透過部材の受光面22において発光素子10との対向域を除く領域を、被覆する。この構成により、図2に観るように、受光面22において、光学的な接続領域(接合領域31)と、導光部材(被覆領域32,33)を介して被覆される被覆領域とが設けられる。また、被覆領域で、光透過部材の受光面22側へと進行した光を光取り出
し側へと反射させ、基板50での光吸収などによる一次光の光損失を抑制できる。図5,8に示すように、複数の発光素子10が1つの光透過部材20に接合される場合には、その発光素子間(第2の被覆領域34)についても被覆部材40が充填されて、受光面22の離間領域を被覆することが好ましい。接合領域の光変換部材の熱に対し、この構成により上記離間領域の放熱性を高めることができ、上述のように光透過部材の突出部、第1の被覆領域32においても同様に好ましい。
In the forming region of the covering member, the covering member 40 is provided on at least the side surface of the light transmitting member 20, preferably the side surface of the light emitting element is also covered, and more preferably, the light emitting surface is exposed in the light source portion including the light transmitting member and the light emitting element. The same applies to the case where the light source member 30 is used to cover the other material. As a result, it is possible to prevent light from leaking from the side surface of the light transmitting member, and when a light conversion member is provided, the light having a relatively high intensity and having a color difference is suppressed to suppress the emitted light. The directivity can be improved and uneven brightness and uneven color can be reduced. Further, the directivity and the brightness can be improved by covering the side surfaces of each member and the element and limiting the light extraction direction side. Further, when the light transmitting member 20 contains a wavelength conversion material, the heat generation of the wavelength conversion material is particularly remarkable, which can be improved. If the side surface of the light transmitting member 20 is covered with the covering member 40 and the surface 21 is exposed, the outer surface shape thereof is not particularly limited, and as shown in FIG. 1, the exposed surface is larger than the surface 21 of the light transmitting member. It may have a recessed structure. By projecting the light emitting surface 90, it is possible to avoid shading by the covering member 40, and the surface may be substantially the same surface, and a desired surface can be obtained. In the first embodiment, the covering member 40 also covers a part of the light receiving surface 22, and as shown in the drawing, the periphery of the light emitting element 10 is specifically a region facing the light emitting element 10 on the light receiving surface 22 of the light transmitting member. Cover the area excluding. With this configuration, as seen in FIG. 2, the light receiving surface 22 is provided with an optical connection region (joining region 31) and a coating region covered via a light guide member (covering regions 32 and 33). .. Further, in the covering region, the light that has traveled to the light receiving surface 22 side of the light transmitting member is reflected to the light extraction side, and the light loss of the primary light due to the light absorption by the substrate 50 can be suppressed. As shown in FIGS. 5 and 8, when a plurality of light emitting elements 10 are joined to one light transmitting member 20, the covering member 40 is also filled between the light emitting elements (second covering region 34). , It is preferable to cover the separated region of the light receiving surface 22. With this configuration, it is possible to enhance the heat dissipation of the separated region with respect to the heat of the light conversion member in the bonded region, and it is also preferable in the protruding portion of the light transmitting member and the first covering region 32 as described above.

(添加部材)
また、被覆部材40には、光反射性材料45、光変換部材の他、粘度増量剤等を適宜添加することができ、これによって所望の発光色、それら部材若しくは装置表面の色、例えば高コントラスト化の為の黒色など、また所望の指向特性を有する発光装置が得られる。同様に不要な波長をカットするフィルター材として各種着色剤を添加できる。他の部材、また導光部材、封止部材、光透過部材などの光透過性材料も同様である。
(Additional member)
Further, in addition to the light-reflecting material 45 and the light conversion member, a viscosity modifier or the like can be appropriately added to the covering member 40, whereby a desired emission color, a color of the member or the surface of the device, for example, high contrast can be added. A light emitting device having a desired directional characteristic such as black color for conversion can be obtained. Similarly, various colorants can be added as a filter material that cuts unnecessary wavelengths. The same applies to other members, as well as light-transmitting materials such as light guide members, sealing members, and light-transmitting members.

(導光部材)
導光部材30は、発光素子10と光透過部材20との間に介在して双方の部材を固着する接着剤に用いられる。この導光部材は、透光性を有して、発光素子10の出射光を光透過部材側へ導光でき、双方の部材を光学的に結合できる材質が好ましい。その材料としては上記各部材に用いられる樹脂材料が挙げられ、シリコーン樹脂やエポキシ樹脂など透光性の熱硬化性樹脂がよく、シリコーン樹脂は耐熱性、耐光性に優れるため好ましい。また、シリコーン樹脂を使用すれば、上記フッ素系離型剤の効果が高いため好ましい。さらに、ジメチル系シリコーン樹脂であれば高温耐性など信頼性において優れ、フェニル系シリコーン樹脂であれば屈折率を高くして発光素子10からの光の取り出し効率を高めることができる。
(Light guide member)
The light guide member 30 is used as an adhesive that is interposed between the light emitting element 10 and the light transmitting member 20 to fix both members. The light guide member is preferably made of a material that has translucency, can guide the emitted light of the light emitting element 10 to the light transmitting member side, and can optically combine both members. Examples of the material include resin materials used for the above-mentioned members, and a translucent thermosetting resin such as a silicone resin or an epoxy resin is preferable, and the silicone resin is preferable because it has excellent heat resistance and light resistance. Further, it is preferable to use a silicone resin because the effect of the fluorine-based mold release agent is high. Further, the dimethyl-based silicone resin is excellent in reliability such as high-temperature resistance, and the phenyl-based silicone resin can increase the refractive index to improve the efficiency of extracting light from the light emitting element 10.

(実装基板50)
一方、図1の発光装置100において、上記の発光素子10が実装される基板50は、少なくとも表面が素子の電極と接続される配線51を形成したものが利用でき、また外部接続用の配線52などが設けられても良い。基板の材料は、例として窒化アルミニウム(AlN)で構成され、単結晶、多結晶、焼結基板、他の材料としてアルミナ等のセラミック、ガラス、Si等の半金属あるいは金属基板、またそれらの積層体、複合体が使用でき、金属性、セラミックは放熱性が高いため好ましい。なお、基板50は配線が無くてもよく、例えば図4の素子で成長基板側を実装して素子の電極を装置の電極にワイヤー接続する形態、光透過部材に配線を設けて接続する形態でもでもよい。また、図示する発光装置
のように、被覆部材40が実装基板50の上に設けられる形態の他、実装基板50の外側側面も覆う形態でもよい。また実装基板50は、少なくともその表面が高反射性材料で構成されることが好ましい。図1,2に示すように、発光素子10は、導電性接着材60により配線51上に接着されて外部と電気的に接続される。導電性接着材60は、半田、Agペースト、Auバンプなどが利用できる。
(Mounting board 50)
On the other hand, in the light emitting device 100 of FIG. 1, as the substrate 50 on which the above light emitting element 10 is mounted, at least one having a wiring 51 whose surface is connected to the electrode of the element can be used, and the wiring 52 for external connection is available. Etc. may be provided. The substrate material is composed of aluminum nitride (AlN) as an example, and is a single crystal, polycrystalline, sintered substrate, ceramics such as alumina as other materials, semi-metals or metal substrates such as glass and Si, and laminates thereof. Body and composite can be used, and metallic and ceramic are preferable because they have high heat dissipation. The substrate 50 may not have wiring. For example, the element shown in FIG. 4 may be mounted on the growth substrate side and the electrode of the element may be connected to the electrode of the device by wire, or the light transmitting member may be connected by providing wiring. It may be. Further, as in the illustrated light emitting device, the covering member 40 may be provided on the mounting substrate 50, or may also cover the outer side surface of the mounting substrate 50. Further, it is preferable that at least the surface of the mounting substrate 50 is made of a highly reflective material. As shown in FIGS. 1 and 2, the light emitting element 10 is adhered on the wiring 51 by the conductive adhesive material 60 and electrically connected to the outside. As the conductive adhesive 60, solder, Ag paste, Au bumps and the like can be used.

(枠体、積層基板、基材)
図1に示す発光装置100は、枠体55を有し、被覆部材40の保持部材である。枠体55は、セラミックや樹脂などで形成することができる。光反射性の高いアルミナが好ましいが、表面に反射膜を形成すればこれに限らない。樹脂であれば、スクリーン印刷等を用いるほか、成形体を実装基板に接着してもよい。また、被覆部材40と同様に光反射性材料を用いるなどして、反射率を高くすると好ましい。また、上記添加部材同様に、枠体を目的に応じて着色してもよい。なお、この枠体は、被覆部材を充填又は成形後に、取り外すこともできる。また、枠体として、積層基板56、基材などでキャビティ構造を有する装置基体など、発光素子の実装基板に一体に形成されている形態でもよい。
(Frame, laminated substrate, base material)
The light emitting device 100 shown in FIG. 1 has a frame body 55 and is a holding member for the covering member 40. The frame body 55 can be formed of ceramic, resin, or the like. Alumina having high light reflectivity is preferable, but it is not limited to this as long as a reflective film is formed on the surface. If it is a resin, screen printing or the like may be used, or the molded product may be adhered to the mounting substrate. Further, it is preferable to increase the reflectance by using a light-reflecting material as in the covering member 40. Further, similarly to the above-mentioned additive member, the frame body may be colored according to the purpose. The frame can also be removed after filling or molding the covering member. Further, the frame may be formed integrally with the mounting substrate of the light emitting element, such as a laminated substrate 56, a device substrate having a cavity structure with a substrate or the like.

(発光装置の製造方法)
図1に示される例の発光装置100の製造方法の一例として以下に説明する。まず、実装基板50上または発光素子10にバンプ60を形成しフリップチップ実装する。この例では個片化前の基板50上で、1つの発光装置に対応する領域に1個のLEDチップを並べて実装する。次に、発光素子10の出射面側(サファイア基板裏面あるいはLLOで基板除去した場合であれば窒化物半導体露出面)に、導光部材30を塗布して、光透過部材20を積層し、その樹脂30を熱硬化して接合する。次に、発光素子10の周囲に立設された枠体55内に、光透過部材20の側面を被覆するように、ディスペンサ(液体定量吐出装置)等により、被覆部材40を構成する樹脂をポッティングする。滴下された樹脂40は、表面張力によって発光素子10、光透過部材20の側面を這い上がり被覆し、表面21より枠体55に向かって低くなる傾斜表面が形成される。また、樹脂40の表出面を表面21と略同一面となるよう平坦化してもよい。そして、樹脂40を硬化させた後、所定の位置でダイシングを行い、所望の大きさに切り出して発光装置100を得る。
(Manufacturing method of light emitting device)
An example of a method for manufacturing the light emitting device 100 of the example shown in FIG. 1 will be described below. First, a bump 60 is formed on the mounting substrate 50 or on the light emitting element 10 and mounted on a flip chip. In this example, one LED chip is mounted side by side in the area corresponding to one light emitting device on the substrate 50 before the individualization. Next, the light guide member 30 is applied to the light emitting surface side of the light emitting element 10 (the back surface of the sapphire substrate or the exposed surface of the nitride semiconductor when the substrate is removed by LLO), and the light transmitting member 20 is laminated. The resin 30 is thermoset and joined. Next, the resin constituting the covering member 40 is potted by a dispenser (liquid metering discharge device) or the like so as to cover the side surface of the light transmitting member 20 in the frame body 55 erected around the light emitting element 10. To do. The dropped resin 40 crawls up and covers the side surfaces of the light emitting element 10 and the light transmitting member 20 due to surface tension, and forms an inclined surface lower than the surface 21 toward the frame 55. Further, the exposed surface of the resin 40 may be flattened so as to be substantially the same surface as the surface 21. Then, after the resin 40 is cured, dicing is performed at a predetermined position, and the resin 40 is cut out to a desired size to obtain a light emitting device 100.

(実施の形態2)
図5(a)は、本発明の実施の形態2に係る発光装置200の概略断面図であり、図5(b)はその光源部周辺を説明するための概略断面図である。発光装置200において、発光素子10の個数および導光部材30の構造を除く他の構成については、上述の実施の形態1と実質上同様であり、したがって同様の構成については同一の符号を付して適宜説明を省略する。
(Embodiment 2)
FIG. 5A is a schematic cross-sectional view of the light emitting device 200 according to the second embodiment of the present invention, and FIG. 5B is a schematic cross-sectional view for explaining the periphery of the light source portion thereof. In the light emitting device 200, the other configurations except the number of light emitting elements 10 and the structure of the light guide member 30 are substantially the same as those in the first embodiment described above, and therefore the same reference numerals are given to the same configurations. The description will be omitted as appropriate.

本発明の発光装置において、1つの光透過部材20に接合される発光素子10の個数は特に限定されない。実施の形態1の単数に対して、発光素子10を複数とすることで、光透過部材、発光面の大きさ、形状に応じて、また所望の発光特性とするために、複数の発光素子を適宜配置でき、また個別に駆動させることもでき、所望形状、発光特性の発光面が得られ好ましい。なお、複数の発光素子10を搭載する場合、互いに適度に離間して設けられ、またこの離間距離は、発光装置の配光特性、放熱性、並びに発光素子の実装精度を考慮して適宜決めることができ、例えば、発光素子の寸法に比して10%以内とする。このほか、複数の発光素子10は互いに結合されていてもよい。また、本実施の形態では、2つを列状に並べているが、これに限らず、格子状配置など、また規則的、不規則的など、種々の配置が可能であり、好適には各素子間を略等間隔で配置して強度分布を小さくすると良い。 In the light emitting device of the present invention, the number of light emitting elements 10 bonded to one light transmitting member 20 is not particularly limited. By using a plurality of light emitting elements 10 with respect to the singular number of the first embodiment, a plurality of light emitting elements can be used according to the size and shape of the light transmitting member and the light emitting surface and in order to obtain desired light emitting characteristics. It can be arranged as appropriate and can be driven individually, and a light emitting surface having a desired shape and light emitting characteristics can be obtained, which is preferable. When a plurality of light emitting elements 10 are mounted, they are provided at appropriate distances from each other, and the distance is appropriately determined in consideration of the light distribution characteristics and heat dissipation of the light emitting device and the mounting accuracy of the light emitting elements. For example, it should be within 10% of the size of the light emitting element. In addition, the plurality of light emitting elements 10 may be coupled to each other. Further, in the present embodiment, the two are arranged in a row, but the present invention is not limited to this, and various arrangements such as a grid arrangement and regular and irregular arrangements are possible, and each element is preferable. It is advisable to arrange the spaces at substantially equal intervals to reduce the intensity distribution.

発光装置200は、実装基板50上に複数(図中は2個)の発光素子10が互いに離間されて実装されており、その複数の発光素子10を包含する大きさの受光面22を有する光透過部材20が、その上に導光部材30を介して接合されている。なお、この発光装置200では、枠体は基板50に積層されてキャビティ構造を有する基体56となっており、また、上面側の実装素子用の配線層51とそれに電気的に接続され、外部接続用の配線層52が基体56下面側にも設けられている。 In the light emitting device 200, a plurality of (two in the drawing) light emitting elements 10 are mounted on a mounting substrate 50 so as to be separated from each other, and the light emitting device 200 has a light receiving surface 22 having a size including the plurality of light emitting elements 10. The transmission member 20 is joined onto the transmission member 20 via a light guide member 30. In the light emitting device 200, the frame is laminated on the substrate 50 to form a substrate 56 having a cavity structure, and is electrically connected to the wiring layer 51 for the mounting element on the upper surface side to be externally connected. A wiring layer 52 for use is also provided on the lower surface side of the substrate 56.

このような発光装置200において、接合領域31は、光透過部材の受光面22と各発光素子10の出射面との対向領域に各々設けられる。また、上述した第1の被覆領域32は、複数の発光素子の中で、受光面内で外側に配置される発光素子10で、その外側に面した側面に設けられ、また受光面22の周縁部を突出表面として被覆し、その外表面に第1の反射面33が設けられて、発光素子10から側方に出射される光を光透過部材の受光面22側に反射し、導光することができる。また、この例では、図示していないが、受光面の一端部に複数の発光素子が配置され、その端部側の側面に第1の被覆領域、第1反射面が各々設けられるが、それが各素子単位で分離されていても良い。好ましくは互いに接合され、1つの第1の被覆領域、第1反射面が共通であると良く、それが形成される程度に近接して配置されると良い。この時、素子間で、凹みが設けられた第1の被覆領域で有っても良い。 In such a light emitting device 200, the bonding region 31 is provided in a region facing the light receiving surface 22 of the light transmitting member and the emitting surface of each light emitting element 10. Further, the above-mentioned first covering region 32 is a light emitting element 10 arranged on the outside in the light receiving surface among the plurality of light emitting elements, and is provided on the side surface facing the outside thereof, and the peripheral edge of the light receiving surface 22. The portion is covered as a protruding surface, and a first reflecting surface 33 is provided on the outer surface thereof, and the light emitted laterally from the light emitting element 10 is reflected to the light receiving surface 22 side of the light transmitting member to guide the light. be able to. Further, in this example, although not shown, a plurality of light emitting elements are arranged at one end of the light receiving surface, and a first covering region and a first reflecting surface are provided on the side surface on the end side thereof. May be separated for each element. It is preferable that they are joined to each other and that one first covering region and the first reflecting surface are common, and they are arranged so close to each other that they are formed. At this time, it may be a first covering region in which a recess is provided between the elements.

また、1つの光透過部材20の受光面22側に複数個の発光素子10を接合する場合、導光部材30は、隣接する発光素子に挟まれた離間領域においても垂下し、すなわち隣接する発光素子10の互いに対向する側面の一部と、該素子に挟まれた受光面22の一部と、を接合領域31から延在して被覆する第2の被覆領域34を有する。この第2の被覆領域34は通常、隣接する発光素子10の互いに対向する側面同士を接続するように設けられる。また、この第2の被覆領域34の外表面も、発光素子10の実装面より光透過部材20側に位置していることにより、すなわち実装基板から導光部材が分離されることで、基板50に導光、漏洩して吸収されることを防止できる。そして、この第2の被覆領域3
4の外表面に、発光素子10から出射される光を受光面22側に反射させる第2の反射面35が設けられている。このように、1つの光透過部材20の受光面22に複数の発光素子10が搭載される発光装置において、導光部材30の第2の反射面35により、複数の発光素子10から側方、その離間領域に出射される光を良好に取り出し、光透過部材の受光面22側に反射して光透過部材20に光結合できる。また、この第2の反射面35についても、実施の形態1の発光装置100における第1の反射面と同様の傾斜面を有することが好ましい。特に、図示するように、素子間で1つの凸曲面であると、離間領域において好適に各素子からの出射光を反射して、相互に混合させることができ好ましい。
Further, when a plurality of light emitting elements 10 are joined to the light receiving surface 22 side of one light transmitting member 20, the light guide member 30 hangs down even in a separated region sandwiched between the adjacent light emitting elements, that is, the adjacent light emitting elements. It has a second covering region 34 that extends and covers a part of the side surfaces of the element 10 facing each other and a part of the light receiving surface 22 sandwiched between the elements 10 from the bonding region 31. The second covering region 34 is usually provided so as to connect the side surfaces of the adjacent light emitting elements 10 facing each other. Further, the outer surface of the second covering region 34 is also located on the light transmitting member 20 side of the mounting surface of the light emitting element 10, that is, the light guide member is separated from the mounting substrate, so that the substrate 50 It is possible to prevent the light from leaking and being absorbed. And this second covering area 3
A second reflecting surface 35 that reflects the light emitted from the light emitting element 10 toward the light receiving surface 22 is provided on the outer surface of the fourth. As described above, in the light emitting device in which the plurality of light emitting elements 10 are mounted on the light receiving surface 22 of one light transmitting member 20, the second reflecting surface 35 of the light guide member 30 laterally displays from the plurality of light emitting elements 10. The light emitted to the separated region can be satisfactorily taken out, reflected on the light receiving surface 22 side of the light transmitting member, and lightly coupled to the light transmitting member 20. Further, it is preferable that the second reflecting surface 35 also has an inclined surface similar to that of the first reflecting surface in the light emitting device 100 of the first embodiment. In particular, as shown in the drawing, it is preferable that one convex curved surface is formed between the elements because the light emitted from each element can be preferably reflected in the separated region and mixed with each other.

なお、第2の反射面35は、光透過部材の受光面22からの距離が、その発光素子10における各出射面より遠くに設けられていることが好ましい。これにより、図8(実施の形態5)のように出射面より受光面の近くに反射面35、又は上記凸曲面の突端が設けられる場合、出射面と受光面との間に設けられる場合に比べて、各発光素子10の出射光を広範に拡散して導光することができ、離間領域における光束の低下を軽減し、したがって、各発光素子10の配置及びその配光に起因する輝度むら、色度むらを低減することができ、発光面内の輝度を均一化することができる。他方、図8に見るような前者の場合は、各発光素子を分離しやすく、輝度むらが大きくなるが、光取り出し効率を高められ、それを利用する場合には好ましい。 It is preferable that the second reflecting surface 35 is provided so that the distance from the light receiving surface 22 of the light transmitting member is farther than each emitting surface of the light emitting element 10. As a result, as shown in FIG. 8 (Embodiment 5), when the reflecting surface 35 or the tip of the convex curved surface is provided closer to the light receiving surface than the emitting surface, or when it is provided between the emitting surface and the light receiving surface. In comparison, the emitted light of each light emitting element 10 can be widely diffused and guided, reducing the decrease of the luminous flux in the separated region, and therefore, the brightness unevenness due to the arrangement of each light emitting element 10 and its light distribution. , The chromaticity unevenness can be reduced, and the brightness in the light emitting surface can be made uniform. On the other hand, in the former case as shown in FIG. 8, each light emitting element can be easily separated and the brightness unevenness becomes large, but the light extraction efficiency can be improved, which is preferable when it is used.

また、複数の発光素子10は、少なくとも1組が、実装ズレなどにより出射面の高さが異なり、その各発光素子の出射面から光透過部材の受光面22までの距離が互いに異なように、導光部材を介在させると良い。これにより、1つの発光素子10からその隣接する発光素子10への光入射を低減し、発光素子10内での光吸収による光束の損失を抑えることができる。このような形態は、発光素子10を実装基板50上に接着させる導電性接着材60の厚みなどにより調整することができる。 Further, at least one set of the plurality of light emitting elements 10 has a different height of the emitting surface due to mounting misalignment or the like, and the distance from the emitting surface of each light emitting element to the light receiving surface 22 of the light transmitting member is different from each other. It is advisable to interpose a light guide member. As a result, it is possible to reduce the light incident from one light emitting element 10 to the adjacent light emitting element 10 and suppress the loss of the luminous flux due to the light absorption in the light emitting element 10. Such a form can be adjusted by adjusting the thickness of the conductive adhesive 60 for adhering the light emitting element 10 onto the mounting substrate 50.

第2の反射面35は、第1の反射面同様に、導光部材30と隣接する発光素子10に挟まれた被覆部材40との界面に設けられていることが好ましい。隣接する発光素子に挟まれた離間領域は、実装基板50上には、配線などの金属膜が形成されず基板表面が露出される場合も多く、光吸収を生じやすいため、少なくともこの基板の表面が被覆部材により被覆されていることが好ましく、被覆部材40が充填され、第2の反射面35が被覆部材40との界面に設けられていることが更に好ましい。また、上述のように、離間領域に充填された被覆部材40と第2の反射面35との間に空隙が設けられた形態でもよい。 Like the first reflection surface, the second reflection surface 35 is preferably provided at the interface between the light guide member 30 and the covering member 40 sandwiched between the light emitting elements 10 adjacent to the light guide member 30. In the separated region sandwiched between adjacent light emitting elements, a metal film such as wiring is not formed on the mounting substrate 50 and the substrate surface is often exposed, and light absorption is likely to occur. Therefore, at least the surface of this substrate Is preferably covered with a covering member, and more preferably, the covering member 40 is filled and the second reflecting surface 35 is provided at the interface with the covering member 40. Further, as described above, a gap may be provided between the covering member 40 filled in the separated region and the second reflecting surface 35.

(実施の形態3)
図6は、本発明の実施の形態3に係る発光装置の光源部周辺を説明する概略断面図である。この発光装置において、発光素子10と光透過部材20との大きさの関係および導光部材30の構造を除く他の構成については、上述の実施の形態1と同様であり、したがって同様の構成については同一の符号を付して適宜説明を省略する。図6に示す例の発光装置において、光透過部材の受光面22は、発光素子10の出射面より小さく、出射面の一部が受光面22より外側に突出している。言い換えれば、光透過部材20の側面は発光素子10の側面より内側に位置している。このような発光装置は、発光装置の発光面90を比較的小さい光放出の窓部として、放出光の輝度を高めることができる。すなわち、上述
の実施の形態1,2と異なり、導光部材が発光素子の突出表面と、その突出した端部より内側に設けられた光透過部材の側面とに延在されて、その領域を被覆している。
(Embodiment 3)
FIG. 6 is a schematic cross-sectional view illustrating the periphery of the light source portion of the light emitting device according to the third embodiment of the present invention. In this light emitting device, the relationship between the sizes of the light emitting element 10 and the light transmitting member 20 and other configurations except for the structure of the light guide member 30 are the same as those in the above-described first embodiment, and therefore, the same configuration. Have the same reference numerals and description thereof will be omitted as appropriate. In the light emitting device of the example shown in FIG. 6, the light receiving surface 22 of the light transmitting member is smaller than the emitting surface of the light emitting element 10, and a part of the emitting surface projects outward from the light receiving surface 22. In other words, the side surface of the light transmitting member 20 is located inside the side surface of the light emitting element 10. In such a light emitting device, the brightness of the emitted light can be increased by using the light emitting surface 90 of the light emitting device as a window portion for emitting relatively small light. That is, unlike the above-described first and second embodiments, the light guide member extends to the protruding surface of the light emitting element and the side surface of the light transmitting member provided inside the protruding end portion to extend the region. It is covered.

本実施形態の発光装置において、導光部材30は、発光素子10の出射面の光透過部材との対向領域と、光透過部材の受光面22と、を接合する接合領域31を有する。また、導光部材30は、この接合領域31から延在して、光透過部材20の側面に這い上がり、光透過部材20の側面を被覆する第1の被覆領域32を有している。この光透過部材20の側面を被覆する第1の被覆領域32は、発光素子10の出射光を反射して集光し、特にその端部の光を反射して、光透過部材20側に導光することができる。また、この第1の被覆領域32の外表面も、発光素子10の実装面より光透過部材20側に位置していることにより、実装基板50への光の漏洩を防止できる。ここで、第1の被覆領域32の被覆部材40側に面する外表面、すなわち第1の被覆領域32の光透過部材の側面と対向する外表面は、発光素子10の出射光を光透過部材20側に反射させる第1の反射面33を有している。したがって、第1の被覆領域32に透過された光は、第1の反射面33により光透過部材20側に反射されて、該反射光が光透過部材20に光結合し、発光面90から装置外部へ放出される。このように、発光素子10から光透過部材の受光面22側に出射される光を、光透過部材に効率良く光結合させることにより、発光素子10から出射される光の利用効率を高めることができる。 In the light emitting device of the present embodiment, the light guide member 30 has a joining region 31 for joining the light emitting surface of the light emitting element 10 with the light transmitting member and the light receiving surface 22 of the light transmitting member. Further, the light guide member 30 has a first covering region 32 that extends from the joining region 31, crawls up to the side surface of the light transmitting member 20, and covers the side surface of the light transmitting member 20. The first covering region 32 that covers the side surface of the light transmitting member 20 reflects and collects the emitted light of the light emitting element 10, and particularly reflects the light at the end thereof and guides it to the light transmitting member 20 side. Can shine. Further, since the outer surface of the first covering region 32 is also located on the light transmitting member 20 side of the mounting surface of the light emitting element 10, it is possible to prevent light from leaking to the mounting substrate 50. Here, the outer surface of the first covering region 32 facing the covering member 40 side, that is, the outer surface facing the side surface of the light transmitting member of the first covering region 32, transmits the emitted light of the light emitting element 10 to the light transmitting member. It has a first reflecting surface 33 that reflects on the 20 side. Therefore, the light transmitted through the first covering region 32 is reflected to the light transmitting member 20 side by the first reflecting surface 33, the reflected light is photocoupled to the light transmitting member 20, and the device is transmitted from the light emitting surface 90. It is released to the outside. In this way, by efficiently coupling the light emitted from the light emitting element 10 to the light receiving surface 22 side of the light transmitting member with the light transmitting member, it is possible to improve the utilization efficiency of the light emitted from the light emitting element 10. it can.

本実施の形態の発光装置における第1の反射面33も、実施の形態1,2の発光装置100における第1の反射面33と同様の界面の構成とすることができ、また同様に、特に被覆部材40との界面に設けられていることが好ましい。また、第1の被覆領域32の光透過部材20の側面と対向する外表面は、該側面から発光素子10の出射面側に傾斜した傾斜面であるで、第1の反射面33も同様に傾斜した傾斜面となり、光透過部材20側に良好に反射させることができ好ましい。さらに、この傾斜面は平面であってもよいが、上述したように接合領域31に向かって凸な凸曲面であることで第1の反射面33の表面積を増大でき、光の反射効率を高めることができるので好ましい。 The first reflecting surface 33 in the light emitting device of the present embodiment can also have the same interface configuration as the first reflecting surface 33 in the light emitting devices 100 of the first and second embodiments, and also in particular. It is preferably provided at the interface with the covering member 40. Further, the outer surface of the first covering region 32 facing the side surface of the light transmitting member 20 is an inclined surface inclined from the side surface toward the emission surface side of the light emitting element 10, and the first reflecting surface 33 is also the same. It is preferable that the surface is inclined and can be reflected well to the light transmitting member 20 side. Further, although the inclined surface may be a flat surface, the surface area of the first reflecting surface 33 can be increased by having a convex curved surface convex toward the joining region 31 as described above, and the light reflection efficiency is enhanced. It is preferable because it can be used.

一方、図6に示す例の発光装置において、発光素子10の側面は導光部材30から露出されており、光反射性の被覆部材40により被覆されていることが好ましい。このように、導光部材30の外表面が、発光素子10の出射面と光透過部材20の側面とを接続するように設けられることにより、導光部材30が発光素子10の側面も被覆する場合に比べて、導光部材30の外表面の外側への膨らみを抑えることができる。したがって、導光部材30の外表面で反射される光の光透過部材20までの光路長を短くすることができ、導光部材30内での光吸収を低減し、光透過部材20への光結合効率を高めることができる。また、光透過部材20側への光反射に適した形状、傾斜角を有する第1の反射面33を形成しやすくなり、第1の反射面33による反射効率を高めることができる。 On the other hand, in the light emitting device of the example shown in FIG. 6, it is preferable that the side surface of the light emitting element 10 is exposed from the light guide member 30 and is covered with the light reflecting covering member 40. In this way, the outer surface of the light guide member 30 is provided so as to connect the exit surface of the light emitting element 10 and the side surface of the light transmitting member 20, so that the light guide member 30 also covers the side surface of the light emitting element 10. Compared with the case, it is possible to suppress the bulge of the outer surface of the light guide member 30 to the outside. Therefore, the optical path length of the light reflected on the outer surface of the light guide member 30 to the light transmitting member 20 can be shortened, the light absorption in the light guide member 30 is reduced, and the light to the light transmitting member 20 is reduced. The binding efficiency can be increased. Further, it becomes easy to form the first reflecting surface 33 having a shape and an inclination angle suitable for light reflection toward the light transmitting member 20, and the reflection efficiency by the first reflecting surface 33 can be improved.

(実施の形態4)
図7は、本発明の実施の形態4に係る発光装置の光源部周辺を説明する概略断面図である。図7に示す例において、導光部材30の形態、並びに光透過部材の表面21の形状を除く他の構成については、上述の実施の形態1と実質上同様であり、したがって同様の構成については同一の符号を付して適宜説明を省略する。図7に示す例の発光装置において、光透過部材の受光面22は、発光素子10の出射面より大きく、受光面22の一部が発光素子10の出射面より外側に突出している。そして、導光部材30は、光透過部材の受光面22の発光素子との対向領域と、発光素子10の出射面と、を接合する接合領域31を有し、また接合領域31から延在して光透過部材20の突出部の受光面22を被覆し、
発光素子10の実装面より光透過部材20側に外表面を有する第3の被覆領域37を有している。また発光素子10の側面及び光透過部材20の側面は、導光部材30から露出されている。そして、この第3の被覆領域37の外表面は、発光素子10から出射される光を、光透過部材20の受光面22側に反射させる第3の反射面38を有している。ここで、第3の被覆領域、第3の反射面は、それぞれ上述の第1の被覆領域、第1の反射面の一形態である。
(Embodiment 4)
FIG. 7 is a schematic cross-sectional view illustrating the periphery of the light source portion of the light emitting device according to the fourth embodiment of the present invention. In the example shown in FIG. 7, the form of the light guide member 30 and the other configurations except for the shape of the surface 21 of the light transmitting member are substantially the same as those of the first embodiment described above, and therefore, the same configuration is used. The same reference numerals are given and the description thereof will be omitted as appropriate. In the light emitting device of the example shown in FIG. 7, the light receiving surface 22 of the light transmitting member is larger than the emitting surface of the light emitting element 10, and a part of the light receiving surface 22 projects outward from the emitting surface of the light emitting element 10. The light guide member 30 has a joining region 31 for joining the light receiving surface 22 of the light transmitting member facing the light emitting element and the emitting surface of the light emitting element 10, and extends from the joining region 31. Covers the light receiving surface 22 of the protruding portion of the light transmitting member 20.
It has a third covering region 37 having an outer surface on the light transmitting member 20 side of the mounting surface of the light emitting element 10. Further, the side surface of the light emitting element 10 and the side surface of the light transmitting member 20 are exposed from the light guide member 30. The outer surface of the third covering region 37 has a third reflecting surface 38 that reflects the light emitted from the light emitting element 10 toward the light receiving surface 22 side of the light transmitting member 20. Here, the third covering region and the third reflecting surface are one form of the above-mentioned first covering region and the first reflecting surface, respectively.

第3の被覆領域37の外表面は、発光素子10の出射面の終端から光透過部材20の突出部の受光面22側に傾斜した傾斜面であることが好ましい。これにより、第3の反射面38が発光素子10の出射面の端部から光透過部材20の突出部の受光面22側に傾斜した傾斜面となり、発光素子10の出射光、光透過部材からの反射光、発光を光透過部材の受光面22側に良好に反射させることができる。さらに、この傾斜面は平面であってもよいが、接合領域31に向かって凸な凸曲面であることで、平面である場合に比して第3の反射面38の表面積を増大でき、光の反射効率を高めることができるので好ましい。また、第3の反射面38は、実施の形態1の第1の反射面33と同様に、被覆部材40との界面に設けられていることが好ましいが、空隙により被覆部材40とが離間されてもよいし、金属膜や誘電体多層膜を設けて形成することもできる。 The outer surface of the third covering region 37 is preferably an inclined surface inclined from the end of the exit surface of the light emitting element 10 toward the light receiving surface 22 side of the protruding portion of the light transmitting member 20. As a result, the third reflecting surface 38 becomes an inclined surface inclined from the end of the emitting surface of the light emitting element 10 toward the light receiving surface 22 side of the protruding portion of the light transmitting member 20, and from the emitted light of the light emitting element 10 and the light transmitting member. The reflected light and light emission of the above can be satisfactorily reflected on the light receiving surface 22 side of the light transmitting member. Further, although the inclined surface may be a flat surface, the surface area of the third reflecting surface 38 can be increased as compared with the case where the inclined surface is a flat surface by having a convex curved surface convex toward the joint region 31, and the light can be increased. It is preferable because the reflection efficiency of the light can be increased. Further, it is preferable that the third reflecting surface 38 is provided at the interface with the covering member 40 as in the case of the first reflecting surface 33 of the first embodiment, but the covering member 40 is separated from the covering member 40 by a gap. Alternatively, it may be formed by providing a metal film or a dielectric multilayer film.

このような導光部材30でもって、発光素子10と光透過部材20とを接合することにより、接合領域31だけで発光素子10と光透過部材20とを接合する場合に比して、発光素子10の出射光を好適に結合することができ、発光面内の輝度や色度分布の均一化を図ることができる。このような導光部材30の導光機能は、光透過部材20の側面に対する発光素子10の側面の突出長さに依るため、例えば上述の範囲とするとよい。このような導光部材30の被覆形態は、導光部材の量、突出幅、表面積を適宜調整することで達成でき、また発光素子10の側面の略全域に離型剤を塗布し発光素子10の側面への導光部材30の垂下を妨げることにより達成できる。光透過部材20の側面にも離型剤を塗布しても良く、高精度に作製できる。この例では、発光素子の側面が露出されるため、実施の形態1,2のように側面が被覆されないことで、戻り光、変換光に対して導光部材による素子への再入光を抑えることができ、すなわち、導光部材と発光素子との接触面積を最小にして、結合効率を高められる。また、図7に示す例で光透過部材の表面23は凹凸面となっており、光透過部材20を透過する光を該凹凸により散乱させ、光透過部材20からの光の取り出し効率の向上、また輝度むらや色むらの低減、均一な配光を図ることができる。特に、複数の発光素子10を搭載する場合には、そのことに起因する輝度むら、色むらが低減されるので好ましい。このような凹凸は、光透過部材の表面に研磨、ドライエッ
チング、ウエットエッチングなどの処理を形成でき、不規則な凹凸構造のほか、規則的なパターンの凹凸構造も形成できる。また、このような凹凸構造は、光透過部材の表面だけでなく、受光面、さらに光路上にある各部材の表面に設けて同様な効果を得ることができ、特に導光部材との界面若しくはそれと接する部材の表面、例えば、基板1の半導体層11側表面に設けてもよく、実施例では詳述していないがそのような構造を用いている。
By joining the light emitting element 10 and the light transmitting member 20 with such a light guide member 30, the light emitting element is compared with the case where the light emitting element 10 and the light transmitting member 20 are joined only in the joining region 31. The emitted light of 10 can be suitably combined, and the brightness and chromaticity distribution in the light emitting surface can be made uniform. Since the light guide function of the light guide member 30 depends on the protruding length of the side surface of the light emitting element 10 with respect to the side surface of the light transmitting member 20, for example, it may be in the above range. Such a coating form of the light guide member 30 can be achieved by appropriately adjusting the amount, protrusion width, and surface area of the light guide member, and the light emitting element 10 is coated with a release agent over substantially the entire side surface of the light emitting element 10. This can be achieved by preventing the light guide member 30 from hanging down to the side surface of the light guide member 30. A mold release agent may be applied to the side surface of the light transmitting member 20, and the light transmitting member 20 can be manufactured with high accuracy. In this example, since the side surface of the light emitting element is exposed, the side surface is not covered as in the first and second embodiments, so that the return light and the converted light are suppressed from re-entering the element by the light guide member. That is, the contact area between the light guide member and the light emitting element can be minimized, and the coupling efficiency can be improved. Further, in the example shown in FIG. 7, the surface 23 of the light transmitting member is an uneven surface, and the light transmitted through the light transmitting member 20 is scattered by the unevenness to improve the efficiency of extracting light from the light transmitting member 20. In addition, uneven brightness and uneven color can be reduced, and uniform light distribution can be achieved. In particular, when a plurality of light emitting elements 10 are mounted, the brightness unevenness and the color unevenness caused by the mounting are reduced, which is preferable. Such irregularities can be processed by polishing, dry etching, wet etching, or the like on the surface of the light transmitting member, and can form irregular irregularities as well as irregular patterns. Further, such an uneven structure can be provided not only on the surface of the light transmitting member but also on the light receiving surface and the surface of each member on the optical path to obtain the same effect, and in particular, the interface with the light guide member or It may be provided on the surface of a member in contact with the member, for example, the surface on the semiconductor layer 11 side of the substrate 1, and such a structure is used although not described in detail in the examples.

(変形例)
なお、上述の実施の形態1〜4では、主として発光素子及び光透過部材のいずれか一方が、他方に内包される、つまり他方の内側にある場合について記述したが、本発明の発光装置における発光素子と光透過部材の関係は、この形態に限られず、一方が、他方より外側に突出した突出部を少なくとも部分的に有していればよい。例えば、発光素子を構成する側面のうちの1つ、あるいは1つの側面の一部が、光透過部材を構成する側面から外側に突出して、他の側面が互いに略同一面となる、又は光透過部材が突出しているような形態でもよく、またその逆の形態でもよい。このような形態では、その突出した1つの側面又はその側面の一部に第1の被覆領域が設けられる。また、上面視において、発光素子及び光透過部材のいずれか一方の両側に突出部が設けられる形態であってもよい。このような形態の場合、突出部を有する領域の断面において、実施の形態1及び実施の形態2で説明した第1の被覆領域32の少なくとも一方が設けられる。また、発光素子が複数の場合には、各素子でそれぞれ発光素子と光透過部材に第1の被覆領域が設けられて混在することもある。好適には、いずれか一方に第1の被覆領域が設けられる形態、すなわち第1,3の実施形態のいずれかとすることがその導光部材の機能上好ましく、またその一部側面に略同一面が混在しても良い。更に好ましくは、光透過部材の外周全体で発光素子との間で第1の被覆領域がいずれかの形態で統一されていると良い。これは、発光面内の輝度および色度にむらを低減できるためであり、発光素子及び光透過部材のいずれか一方の側面が他方より内側に内包されていることが最も好ましい。
(Modification example)
In the above-described first to fourth embodiments, the case where one of the light emitting element and the light transmitting member is included in the other, that is, inside the other is described, but the light emitting device in the light emitting device of the present invention emits light. The relationship between the element and the light transmitting member is not limited to this form, and one of them may have at least a partially protruding portion protruding outward from the other. For example, one of the side surfaces constituting the light emitting element, or a part of one side surface protrudes outward from the side surface constituting the light transmitting member, and the other side surfaces are substantially the same surface as each other, or light transmission. The form may be such that the member protrudes, and vice versa. In such a form, a first covering region is provided on one of the protruding side surfaces or a part of the side surface thereof. Further, in top view, protrusions may be provided on both sides of either the light emitting element or the light transmitting member. In the case of such a form, at least one of the first covering area 32 described in the first embodiment and the second embodiment is provided in the cross section of the region having the protruding portion. Further, when there are a plurality of light emitting elements, a first covering region may be provided on the light emitting element and the light transmitting member in each element and may be mixed. Preferably, it is preferable in terms of the function of the light guide member to have a form in which the first covering region is provided on either one, that is, one of the first and third embodiments, and substantially the same surface on a part of the side surface thereof. May be mixed. More preferably, it is preferable that the first covering region is unified with the light emitting element over the entire outer circumference of the light transmitting member in any form. This is because unevenness in the brightness and chromaticity in the light emitting surface can be reduced, and it is most preferable that one side surface of the light emitting element and the light transmitting member is included inside the other.

以上説明したように、本発明における導光部材は、発光素子と光透過部材の表面と、その間に設けられ、両者を光結合させ、それにより複合光源を形成するものであり、その素子と部材間で、それらが対向する接合領域と、一方の突出表面、又はそれとその端部より内側に設けられた他方の端面は、その接合領域から延在して被覆した上記第1の被覆領域と、が設けられる。導光部材は、具体的には、樹脂材料を用い、接着剤としても利用するため、上述した通り、突出表面を設けることで、接合領域からその表面まで濡れて広がり、また、その突出表面から更に他方の端部となる側面にまで濡れて広がっても良い。このように、導光部材はその作製時、具体的には樹脂硬化前に、各表面への樹脂の濡れを利用しているため、先ず、その材料の量及びその塗布方法と、上記突出表面の突出幅、面積で
制御し、それに加えて、離型剤を用いて他の領域への広がりを制御できる。従って、導光部材の具体的な形態としては、接合領域においてその肉厚は、光透過部材より小さく、更に成長基板より小さくして、複合光源を小さくし、その結合効率を高めることが好ましい。また、その時の突出幅は、発光素子又は光透過部材の肉厚に比して0.25倍〜5倍程度とすることで製造時の制御が容易で、好適な素子からの光の拡散、集光ができる。上述の通り、実施の形態1,3に示すように、一方の突出部から他方の端部を被覆する場合は、突出部側の端部は露出されていることが好ましく、被覆される場合に比して、光源の広がりを抑えて、本発明の各特性の向上を図ることができ好ましい。また、被覆する場合には、上記他方の端部のそれより薄肉であると、その影響を小さくでき、また後述の被覆部材と同様な効果が期待でき好ましい。
As described above, the light guide member in the present invention is provided between the surfaces of the light emitting element and the light transmitting member and between them, and the two are photocoupled to form a composite light source, and the element and the member are formed. In between, the junction region to which they face and one protruding surface, or the other end face provided inside it and its end, extend from the junction region and are covered with the first coating region. Is provided. Specifically, since the light guide member uses a resin material and is also used as an adhesive, as described above, by providing a protruding surface, the light guide member wets and spreads from the joint region to the surface, and also from the protruding surface. Further, it may be wet and spread to the side surface which is the other end. As described above, since the light guide member utilizes the wetting of the resin on each surface at the time of its production, specifically before the resin is cured, first, the amount of the material, the coating method thereof, and the protruding surface are described. It can be controlled by the protrusion width and area of, and in addition, the spread to other regions can be controlled by using a mold release agent. Therefore, as a specific form of the light guide member, it is preferable that the wall thickness of the light guide member is smaller than that of the light transmitting member and further smaller than that of the growth substrate in the joint region to reduce the composite light source and increase its coupling efficiency. Further, the protruding width at that time is set to about 0.25 to 5 times the wall thickness of the light emitting element or the light transmitting member so that it can be easily controlled at the time of manufacturing, and the diffusion of light from a suitable element can be achieved. Can collect light. As described above, as shown in the first and third embodiments, when covering the other end from one protruding portion, it is preferable that the end on the protruding portion side is exposed, and when it is covered. In comparison, it is preferable that the spread of the light source can be suppressed and each characteristic of the present invention can be improved. Further, in the case of coating, if the wall thickness is thinner than that of the other end portion, the influence thereof can be reduced, and the same effect as that of the coating member described later can be expected, which is preferable.

また、突出表面の被覆領域は、上述の通り、図7に示すように接合領域より薄肉にすると好ましいが、素子側面を離型処理して露出させ、厚肉にしても、本発明の効果を期待できる。第1,3の実施の形態に観るように、素子側面の被覆領域により、各種特性が影響を受けるが、半導体層11と異なる異種材料の透光性基板1を有する場合には、その基板を被覆することで、導光部材と同様に、光透過部材と素子間の光伝搬領域として、その導光部材の機能を補助させることができ好ましい。特に、光変換部材の場合には変換光の成分もその領域に含まれるため、色度むら、配向性に効果がある。また、基板1が除去された素子では、出射面からの光成分が側面よりも極めて多くなるため、素子側面が露出されても良い。上述の通り、被覆部材があることで、複合光源への光閉じ込め、発光面からの光放出、及びその結合における導光部材の機能を補助できるが、金属膜や誘電体多層膜のような反射膜でも代用できる。実施例のように、光反射材料を有する場合には、基材中に光がしみ出すため、被覆内部よりも光源の光が広がることになり、これにより、光の拡散、集光の効率が高められ、更に、発光特性、輝度ムラ、指向性に好適に、特に導光部材の機能に相乗的に寄与し、好ましい。また、光変換部材の場合にも、色むら、配向性に好適に寄与して好ましく、更に、その側面が被覆されることで、表面21と色、波長成分比の異なり、比較的高い、側面発光を抑えられ好ましい。 Further, as described above, it is preferable that the covering region of the protruding surface is thinner than the bonding region as shown in FIG. 7, but the effect of the present invention can be obtained even if the side surface of the element is exposed by mold release treatment to be thickened. You can expect it. As seen in the first and third embodiments, various characteristics are affected by the covering region on the side surface of the device, but when the translucent substrate 1 made of a different material from the semiconductor layer 11 is provided, the substrate is used. By covering the light guide member, the function of the light guide member can be assisted as a light propagation region between the light transmitting member and the element, which is preferable. In particular, in the case of an optical conversion member, since the component of the converted light is also included in the region, it is effective in chromaticity unevenness and orientation. Further, in the element from which the substrate 1 has been removed, the light component from the exit surface is much larger than that on the side surface, so that the side surface of the element may be exposed. As described above, the presence of the covering member can assist the function of the light guide member in confining light to the composite light source, emitting light from the light emitting surface, and coupling the light, but reflects like a metal film or a dielectric multilayer film. A membrane can also be used as a substitute. When the light-reflecting material is used as in the embodiment, the light seeps into the base material, so that the light of the light source spreads more than the inside of the coating, which improves the efficiency of light diffusion and condensing. Further, it is preferable because it contributes synergistically to the function of the light guide member, and is preferable for light emission characteristics, uneven brightness, and directivity. Further, also in the case of an optical conversion member, it is preferable that it contributes to color unevenness and orientation, and further, by coating the side surface thereof, the color and wavelength component ratio are different from those of the surface 21, and the side surface is relatively high. It is preferable because the light emission can be suppressed.

また、発光素子10及び光透過部材20,24のいずれか突出部を有するほうの部材は、他方の部材と対向する側の表面と該表面から連続する側面とに明確な境界がなくてもよい。例えば、実施の形態1の発光装置100において、光透過部材20の受光面22と側面とが一体化されて1つの曲面、例えば球面又はその一部により構成されていてもよい。さらに、光透過部材の受光面22と発光素子10の出射面とを熱圧着による結晶接合等により直接接合して、突出部に第1の被覆領域を有し、複数の発光素子を有する場合にはその素子間に第2の被覆領域を有する導光部材30を形成することもできる。 Further, the member having the protruding portion of the light emitting element 10 and the light transmitting members 20 and 24 does not have to have a clear boundary between the surface on the side facing the other member and the side surface continuous from the surface. .. For example, in the light emitting device 100 of the first embodiment, the light receiving surface 22 and the side surface of the light transmitting member 20 may be integrated into one curved surface, for example, a spherical surface or a part thereof. Further, when the light receiving surface 22 of the light transmitting member and the emitting surface of the light emitting element 10 are directly bonded by crystal bonding or the like by thermocompression bonding, the protruding portion has a first coating region, and a plurality of light emitting elements are provided. Can also form a light guide member 30 having a second covering region between the elements.

(実施の形態5)
図8は、本発明の実施の形態5に係る発光装置300の概略断面図であり、発光装置300において、上述の実施の形態1乃至4と実質上同様の構成については同一の符号を付して適宜説明を省略する。図8に示す例は、光反射性材料45を含有する被覆部材40により発光素子10及び光透過部材20を被覆して、光透過部材20の表面21を発光面とする面発光型の光源を形成し、その光源を覆って、更に被覆部材の一部を覆って、半球状の光学レンズとなる封止部材80を設けたものである。この発光装置300は、実装基板50の上面側の配線パターン51上に複数(図中は2個)の発光素子10がフリップチップ実装されており、その上に1つの光透過部材20が導光部材30により接合されている。なお、実施の形態1で見る枠体は、この例では被覆部材40を成形後に除去しており、被覆部材40の側面が外部に露出されて発光装置の外表面を構成している。光透過部材の受光面22の断面の幅は、最も外側に位置する発光素子10の各外側の側面間の距離より小さく、言い換えれば、複数の発光素子が設けられる領域の幅より小さい。また、最外郭に位置する発光素子10の側面は、光透過部材20の側面より外側に突出している。そして、導光部材30は、隣接する発光素子に挟まれた離間領域には、実施の形態2と同様の第2の被覆領域及び第2の反射面35を有し、光透過部材20の側面と最外郭に位置する発光素子10の出射面の突出部とを接続する領域に実施の形態3と同様の第1の被覆領域及び第1の反射面33を有している。
(Embodiment 5)
FIG. 8 is a schematic cross-sectional view of the light emitting device 300 according to the fifth embodiment of the present invention, and the same reference numerals are given to the light emitting device 300 having substantially the same configurations as those of the above-described first to fourth embodiments. The description will be omitted as appropriate. In the example shown in FIG. 8, a surface emitting type light source in which the light emitting element 10 and the light transmitting member 20 are covered with a coating member 40 containing a light reflecting material 45 and the surface 21 of the light transmitting member 20 is used as a light emitting surface is used. A sealing member 80 which is formed, covers the light source, and further covers a part of the covering member to form a hemispherical optical lens is provided. In this light emitting device 300, a plurality of (two in the figure) light emitting elements 10 are flip-chip mounted on a wiring pattern 51 on the upper surface side of the mounting substrate 50, and one light transmitting member 20 guides the light emitting element 20 on the flip chip. It is joined by a member 30. In the frame body seen in the first embodiment, the covering member 40 is removed after molding in this example, and the side surface of the covering member 40 is exposed to the outside to form the outer surface of the light emitting device. The width of the cross section of the light receiving surface 22 of the light transmitting member is smaller than the distance between the outer side surfaces of the light emitting element 10 located on the outermost side, in other words, the width of the region where the plurality of light emitting elements are provided. Further, the side surface of the light emitting element 10 located at the outermost surface projects outward from the side surface of the light transmitting member 20. The light guide member 30 has a second covering region and a second reflecting surface 35 similar to those in the second embodiment in a separated region sandwiched between adjacent light emitting elements, and has a side surface of the light transmitting member 20. A first covering region and a first reflecting surface 33 similar to those in the third embodiment are provided in a region connecting the light emitting element 10 and the protruding portion of the emitting surface of the light emitting element 10 located at the outermost surface.

このような発光装置300の構成によれば、導光部材30の第1及び第2の被覆領域、第1及び第2の反射面33,35により、発光素子10から出射される光を光透過部材20へ効率良く結合することができ、また光透過部材20から封止部材80へ光を効率良く取り出すことができ、より高出力の発光装置が得られる。また、光学レンズ80により、光透過部材の表面21における配光特性よりその放出光は誇張される或いは変化するが、本発明の導光部材30により、光の輝度、色度のむらを均一化できるため、配光特性に優れた発光装置が得られる。さらに、該封止部材80は、光透過部材の表面21と被覆部材40の表面の一部を連続して被覆しており、封止部材80の光を、被覆部材40表面で反
射させ外部に効率良く取り出せ、被覆部材40の発光側の表面を光透過部材20の側面から基板50側に傾斜した凹面とすることで、光が拡散され、発光装置の放出光を広い配向とできる。このように本発明の発光装置には、発光面の光透過部材表面に光学部材を接合して、所望の発光特性とすることができる。
According to such a configuration of the light emitting device 300, the light emitted from the light emitting element 10 is transmitted by the first and second covering regions of the light guide member 30, the first and second reflecting surfaces 33 and 35. The light can be efficiently coupled to the member 20 and light can be efficiently taken out from the light transmitting member 20 to the sealing member 80, so that a light emitting device having a higher output can be obtained. Further, the optical lens 80 exaggerates or changes the emitted light due to the light distribution characteristics on the surface 21 of the light transmitting member, but the light guide member 30 of the present invention can make the brightness and chromaticity unevenness of the light uniform. Therefore, a light emitting device having excellent light distribution characteristics can be obtained. Further, the sealing member 80 continuously covers the surface 21 of the light transmitting member and a part of the surface of the covering member 40, and reflects the light of the sealing member 80 on the surface of the covering member 40 to the outside. By efficiently taking out the light and making the surface of the covering member 40 on the light emitting side a concave surface inclined from the side surface of the light transmitting member 20 toward the substrate 50, the light is diffused and the emitted light of the light emitting device can be oriented widely. As described above, in the light emitting device of the present invention, an optical member can be bonded to the surface of the light transmitting member on the light emitting surface to obtain desired light emitting characteristics.

(封止部材)
ここで、封止部材80は、光透過部材より屈折率が低いと、その表面21と接合して光の取り出し効率を向上させることができる。封止部材80の発光側の表面は目的に応じて種々の形状に形成することができる。例えば図8に示すように、発光側の表面を球面状(半球面状)のレンズ形状、凸曲面とすることで、光透過部材の発光に対し効率良く外部に取り出すことができる。また、これに限らず、種々の光学素子、所望形状の光学部材とでき、凹レンズ形状、放物曲面、先端が平坦な凸形状とでき、また凹凸面として光を散乱させてもよい。
(Sealing member)
Here, when the sealing member 80 has a lower refractive index than the light transmitting member, the sealing member 80 can be joined to the surface 21 to improve the light extraction efficiency. The surface of the sealing member 80 on the light emitting side can be formed into various shapes depending on the purpose. For example, as shown in FIG. 8, by forming the surface on the light emitting side into a spherical (hemispherical) lens shape and a convex curved surface, it is possible to efficiently take out the light emitted from the light transmitting member to the outside. Further, the present invention is not limited to this, and various optical elements and optical members having a desired shape can be formed, a concave lens shape, a radial curved surface, and a convex shape having a flat tip can be formed, and light may be scattered as an uneven surface.

封止部材80は、上述の被覆部材30の基材、導光部材と同様に、例えばエポキシ樹脂、シリコーン樹脂、変成シリコーン樹脂、ユリア樹脂、ウレタン樹脂、アクリル樹脂、ポリカーボネイト樹脂、ポリイミド樹脂などの樹脂材料を用いて形成することができる。また、封止部材80は、発光素子10や光透過部材20を保護する封止材としての役割も果たすため、耐候性、耐熱性、硬度に優れる材料が好ましく、上記のなかではエポキシ樹脂、又は硬質のシリコーン樹脂が好ましい。このほか、ガラスを用いてもよい。さらに、封止部材80に、上述のような蛍光体、及び/又はTiOなどの光散乱粒子、及び/又は石英ガラス等のフィラーなどを適宜添加することができる。封止部材80は圧縮成形、トランスファー成形などにより形成する。 The sealing member 80 is a resin such as an epoxy resin, a silicone resin, a modified silicone resin, a urea resin, a urethane resin, an acrylic resin, a polycarbonate resin, or a polyimide resin, similarly to the base material and the light guide member of the coating member 30 described above. It can be formed using a material. Further, since the sealing member 80 also serves as a sealing material for protecting the light emitting element 10 and the light transmitting member 20, a material having excellent weather resistance, heat resistance, and hardness is preferable, and among the above, epoxy resin or epoxy resin or A hard silicone resin is preferred. In addition, glass may be used. Further, the above-mentioned phosphor and / or light scattering particles such as TiO 2 and / or a filler such as quartz glass can be appropriately added to the sealing member 80. The sealing member 80 is formed by compression molding, transfer molding, or the like.

(実施の形態6)
図9は、本発明の実施の形態6に係る発光装置400の概略断面図であり、上述の実施の形態1,2と実質上同様の構成については同一の符号を付して適宜説明を省略する。図9に示す例の発光装置400において、凹部を有する実装基体(パッケージ)56の底部の略中央に発光素子10がフリップチップ実装されている。その実装部は、実装基体56の一部であるが、サブマウントであってもよい。発光素子10上には、導光部材30を介して光透過部材24が載置され、接合されている。そして、凹部が封止部材84で充填されて、発光装置400の発光面82となる表面を有する光変換部材81により、凹部が閉蓋されている。光透過部材24、光変換部材81は、それぞれ上述の光透過部材、上述の光透過部材20が波長変換材料を含有する場合と同様の構成とすることができ、封止部材も実施の形態5と同様の構成、例えば透光性樹脂で構成できる。特にこの例では、光透過部材24に波長変換材料を含まずともよく、図示するような板状の他、集光、拡散可能な光学素子でも良く、光散乱材を混合してもよい。また、凹部の内面から実装部の凸部側面を被覆するように、凹曲面の表面を有する反射膜が設けられ、各部材24,84に向かって反射・集光させることができる。ここでは、この反射膜を、上記光反射性材料46を含有する被覆部材41により形成して、上述した樹脂の這い上がりにより凹曲反射面としている。なお、被覆部材41は、その表面に被覆部材41の代替としてAgやAl等高反射性の金属膜を形成してもよいし、上述のような蛍光体を含有する光変換部材を設けてもよいし、被覆部材を設けず、従来のように実装基体の内面を反射面とする形態でも良い。また凹部内は、封止部材84に光変換部材が含有されても良く、気密封止、大気であっても良く、また上記部材81は、部材24同様に光変換部材を含有しない部材でも良い。すなわち、各部材24,41,81,84のいずれかに光変換部材を設けて変換光を含む発光装置とでき、いずれにも含まれずに発光素子の発光を取り出す発光装置とすることもできる。
(Embodiment 6)
FIG. 9 is a schematic cross-sectional view of the light emitting device 400 according to the sixth embodiment of the present invention, and the same reference numerals are given to substantially the same configurations as those of the first and second embodiments described above, and the description thereof will be omitted as appropriate. To do. In the light emitting device 400 of the example shown in FIG. 9, the light emitting element 10 is flip-chip mounted at substantially the center of the bottom of the mounting base (package) 56 having a recess. The mounting portion is a part of the mounting base 56, but may be a submount. A light transmitting member 24 is placed and joined on the light emitting element 10 via a light guide member 30. Then, the recess is filled with the sealing member 84, and the recess is closed by the light conversion member 81 having a surface that becomes the light emitting surface 82 of the light emitting device 400. The light transmitting member 24 and the light converting member 81 can have the same configuration as when the above-mentioned light transmitting member and the above-mentioned light transmitting member 20 contain a wavelength conversion material, respectively, and the sealing member is also the fifth embodiment. It can be composed of the same structure as that of the above, for example, a translucent resin. In particular, in this example, the light transmitting member 24 does not have to contain a wavelength conversion material, and in addition to the plate shape as shown in the figure, an optical element capable of condensing and diffusing may be used, and a light scattering material may be mixed. Further, a reflective film having a concave curved surface is provided so as to cover the convex side surface of the mounting portion from the inner surface of the concave portion, and reflection and light can be collected toward the respective members 24 and 84. Here, the reflective film is formed of the covering member 41 containing the light-reflecting material 46, and is formed as a concave reflective surface by the above-mentioned creeping up of the resin. The coating member 41 may have a highly reflective metal film such as Ag or Al formed on its surface as a substitute for the coating member 41, or may be provided with a light conversion member containing a phosphor as described above. Alternatively, the inner surface of the mounting substrate may be a reflective surface as in the conventional case without providing a covering member. Further, in the recess, the sealing member 84 may contain a light conversion member, may be airtightly sealed, or may be in the atmosphere, and the member 81 may be a member that does not contain a light conversion member like the member 24. .. That is, an optical conversion member may be provided on any of the members 24, 41, 81, and 84 to form a light emitting device that includes the converted light, and a light emitting device that extracts the light emitted from the light emitting element without being included in any of the members may be used.

このような発光装置400においても、上記実施の形態2と同様に、導光部材30は上述の接合領域31と第1の被覆領域と第1の反射面33を有し、凹部内は封止部材84で充填されるため、第1の被覆領域の外表面は透光性の封止部材との界面を成しており、第1の反射面33はその界面に設けられている。すなわち、導光部材と封止部材とに屈折率差を設けると、その界面反射を利用でき、第1の被覆領域側を高屈折率にすると反射率を高くでき好ましく、気密封止の場合も同様である。発光素子10から光は全方位に拡散されて放出されるが、その一部の光成分を、第1の反射面33の内面により光透過部材24の受光面26側に光を反射させてその発光面25から出射させ、一部を凹部で反射させ、
光透過部材81から取り出すことができる。したがって、発光素子10の光を光透過部材24で集光させて表面25から放出し、正面方向、発光面82の輝度を高め、凹部内での光の拡散を抑制して光吸収を低減することができる。また第2の反射面35及びその第2の被覆領域も同様である。
In such a light emitting device 400, similarly to the second embodiment, the light guide member 30 has the above-mentioned joining region 31, the first covering region, and the first reflecting surface 33, and the inside of the recess is sealed. Since it is filled with the member 84, the outer surface of the first covering region forms an interface with the translucent sealing member, and the first reflecting surface 33 is provided at the interface. That is, if a difference in refractive index is provided between the light guide member and the sealing member, the interfacial reflection can be utilized, and if the first covering region side has a high refractive index, the reflectance can be increased, which is preferable, and even in the case of airtight sealing. The same is true. Light is diffused and emitted from the light emitting element 10 in all directions, and a part of the light component is reflected by the inner surface of the first reflecting surface 33 toward the light receiving surface 26 side of the light transmitting member 24. It is emitted from the light emitting surface 25, and a part of it is reflected by the concave portion.
It can be taken out from the light transmitting member 81. Therefore, the light of the light emitting element 10 is collected by the light transmitting member 24 and emitted from the surface 25 to increase the brightness of the light emitting surface 82 in the front direction, suppress the diffusion of light in the recess, and reduce the light absorption. be able to. The same applies to the second reflecting surface 35 and its second covering region.

さらに、発光素子10が光反射性の被覆部材40に被覆されていない本実施の形態4の場合には、発光素子10の側面に設けられる第1及び第2の被覆領域の被覆範囲は、実施の形態1と同様、又は実施の形態1より広範なほうが好ましい。発光素子10側面の導光部材30による被覆範囲が広ければ、発光素子10から導光部材30内への光の取り出し効率を高められ、さらに第1及び第2の反射面33,35の表面積を増大でき、光透過部材20への光の結合効率を高められる。但し、上述のように、実装基体56での光吸収による光の損失を回避するため、導光部材30は、発光素子10の実装面より光透過部材20側に位置する外表面を有し、実装基体56の表面と離間されていることが好ましい。 Further, in the case of the fourth embodiment in which the light emitting element 10 is not coated on the light reflecting covering member 40, the covering range of the first and second covering regions provided on the side surface of the light emitting element 10 is implemented. It is preferable that it is similar to the first embodiment or wider than the first embodiment. If the coverage range of the light guide member 30 on the side surface of the light emitting element 10 is wide, the efficiency of extracting light from the light emitting element 10 into the light guide member 30 can be improved, and the surface areas of the first and second reflecting surfaces 33 and 35 can be further increased. It can be increased, and the efficiency of binding light to the light transmitting member 20 can be increased. However, as described above, in order to avoid loss of light due to light absorption by the mounting substrate 56, the light guide member 30 has an outer surface located on the light transmitting member 20 side of the mounting surface of the light emitting element 10. It is preferable that the mounting base 56 is separated from the surface of the mounting base 56.

以下、本発明に係る実施例について詳述する。なお、本発明は以下に示す実施例のみに限定されないことは言うまでもない。 Hereinafter, examples according to the present invention will be described in detail. Needless to say, the present invention is not limited to the examples shown below.

(実施例1)
実施例1の発光装置の光源部は、図5に示すように、AlNのセラミックス基板50の配線51上に、発光素子10として約1mm×1mmの略正方形のLEDチップ(サファイア基板10上に窒化物半導体11が積層された構造で発光波長455nm)2個をフリップチップ実装し、その上に板状の光変換部材である光透過部材20としてYAGとアルミナ(Al)との焼結体、この表面21及び受光面22の外形は約1.1mm×2.2mmの略矩形状であり、厚みは約150μm、を1枚載置し、導光部材30により互いに接合する。このとき、導光部材30となるシリコーン樹脂は、各LEDの出射面(基板1の裏面)上に適量をピンセットで塗布し、その上に光透過部材20をピンセットで載
置し、発光素子10の側面の一部に垂下させ、150℃のオーブン内で60分間樹脂を熱硬化し、図示するように2つのLEDが光透過部材の受光面に内包されるように接着する。このようにして、導光部材30に、LEDと光透過部材間の接合領域31と、LEDの光源の外側の側面を被覆する第1の被覆領域32と、LED間の内側の側面を被覆する第2の被覆領域34が形成され、この時、LED側面は、基板と、半導体層11の一部又は略全部に導光部材が形成される。そして、図1に示すように、基板50の配線51上にLEDを実装し、発光素子10及び光透過部材20を包囲する枠体の内側の凹所に被覆部材40を充填し、光透過部材20の表面21が発光面として露出される状態、発光素子10
および光透過部材20が被覆部材40により被包し、図8に示すように枠体を除去して発光装置を得る。ここで、被覆部材40は、粒径約270nmのTiOの微粒子である光反射性材料45を約23重量パーセント濃度で含有するシリコーン樹脂である。この実施例1の発光装置は、電流350mAで駆動させると、光束約167[lm](色度y値約0.339)、最大輝度6086[cd/cm]、平均輝度3524[cd/cm]で発光する、高光束かつ高輝度のものが得られる。
(Example 1)
As shown in FIG. 5, the light source portion of the light emitting device of the first embodiment is a substantially square LED chip (nitride on the sapphire substrate 10) of about 1 mm × 1 mm as the light emitting element 10 on the wiring 51 of the AlN ceramic substrate 50. Two light-emitting wavelengths (455 nm) are mounted on a flip chip in a structure in which physical semiconductors 11 are laminated, and YAG and alumina (Al 2 O 3 ) are sintered as a light transmitting member 20 which is a plate-shaped light conversion member. The outer shape of the body, the surface 21 and the light receiving surface 22 is approximately 1.1 mm × 2.2 mm in a substantially rectangular shape, and one sheet having a thickness of about 150 μm is placed and joined to each other by a light guide member 30. At this time, an appropriate amount of the silicone resin to be the light guide member 30 is applied with tweezers on the exit surface (back surface of the substrate 1) of each LED, and the light transmitting member 20 is placed on the light transmitting member 20 with tweezers, and the light emitting element 10 The resin is heat-cured in an oven at 150 ° C. for 60 minutes, and the two LEDs are adhered so as to be included in the light receiving surface of the light transmitting member as shown in the figure. In this way, the light guide member 30 covers the joint region 31 between the LED and the light transmitting member, the first covering region 32 that covers the outer side surface of the light source of the LED, and the inner side surface between the LEDs. A second covering region 34 is formed, and at this time, a light guide member is formed on a substrate and a part or substantially all of the semiconductor layer 11 on the side surface of the LED. Then, as shown in FIG. 1, the LED is mounted on the wiring 51 of the substrate 50, the coating member 40 is filled in the recess inside the frame surrounding the light emitting element 10 and the light transmitting member 20, and the light transmitting member is filled. Light emitting element 10 in a state where the surface 21 of 20 is exposed as a light emitting surface.
The light transmitting member 20 is covered with the covering member 40, and the frame is removed as shown in FIG. 8 to obtain a light emitting device. Here, the coating member 40 is a silicone resin containing a light-reflecting material 45, which is a fine particle of TiO 2 having a particle size of about 270 nm, at a concentration of about 23 weight percent. When driven by a current of 350 mA, the light emitting device of the first embodiment has a luminous flux of about 167 [lm] (chromaticity y value of about 0.339), a maximum brightness of 6086 [cd / cm 2 ], and an average brightness of 3524 [cd / cm]. A high luminous flux and high brightness that emits light in 2 ] can be obtained.

(実施例2)
実施例2の発光装置は、図6に示すように、1つの発光素子の出射面に1つの光透過部材の受光面が内包される形態であり、実施例1における発光素子を、1つのサファイア基板上に6つの素子構造が設けられた約1mm×6.5mmの略矩形状の1個のLEDチップ10とし、さらに光透過部材20を約0.8mm×6.3mmの略矩形状として、実施例1と同様に発光装置を作製する。なお、光透過部材20の載置時に、軽く押圧して、導光部材30を光透過部材20の側面の一部に這い上がらせ第1の被覆領域32を形成する。この実施例2の発光装置は、電流700mAで駆動させると、光束約740[lm](色度y値約0.280)、最大輝度4629[cd/cm]、平均輝度4123[cd/cm]で発光する、高光束かつ高輝度のものが得られる。
(Example 2)
As shown in FIG. 6, the light emitting device of the second embodiment has a form in which a light receiving surface of one light transmitting member is included in the emitting surface of one light emitting element, and the light emitting element of the first embodiment is a sapphire. One LED chip 10 having a substantially rectangular shape of about 1 mm × 6.5 mm having six element structures provided on the substrate, and the light transmitting member 20 having a substantially rectangular shape of about 0.8 mm × 6.3 mm. A light emitting device is produced in the same manner as in Example 1. When the light transmitting member 20 is placed, the light transmitting member 30 is lightly pressed to crawl up on a part of the side surface of the light transmitting member 20 to form the first covering region 32. When driven by a current of 700 mA, the light emitting device of the second embodiment has a luminous flux of about 740 [lm] (chromaticity y value of about 0.280), a maximum brightness of 4629 [cd / cm 2 ], and an average brightness of 4123 [cd / cm]. A high luminous flux and high brightness that emits light in 2 ] can be obtained.

本発明の発光装置は、照明用光源、LEDディスプレイ、液晶表示装置などのバックライト光源、信号機、照明式スイッチ、各種センサ及び各種インジケータ等に好適に利用できる。 The light emitting device of the present invention can be suitably used for a lighting light source, an LED display, a backlight light source such as a liquid crystal display device, a traffic light, an illuminated switch, various sensors, various indicators and the like.

10…発光素子(1…成長基板、2…第1導電型(n型)半導体層、3…活性層、4…第2導電型(p型)半導体層、5…透光性導電層、6…第2の電極(p側パッド電極)、7…第1の電極(n側パッド電極)、8…保護膜、11…素子構造)
20,24…光透過部材(21,23,25…表面、22,26…受光面)
30…導光部材(31…接合領域、32…第1の被覆領域、33…第1の反射面、34…第2の被覆領域、35…第2の反射面、37…第3の被覆領域、38…第3の反射面)、40,41…被覆部材、45,46…光反射性材料
50…実装基板(51,52…配線、55…枠体、56…積層基板又は基材)、60…導電性接着材
10 ... Light emitting element (1 ... Growth substrate, 2 ... First conductive type (n type) semiconductor layer, 3 ... Active layer, 4 ... Second conductive type (p type) semiconductor layer, 5 ... Translucent conductive layer, 6 ... 2nd electrode (p-side pad electrode), 7 ... 1st electrode (n-side pad electrode), 8 ... protective film, 11 ... element structure)
20, 24 ... Light transmitting member (21, 23, 25 ... Surface, 22, 26 ... Light receiving surface)
30 ... light guide member (31 ... joint region, 32 ... first covering region, 33 ... first reflecting surface, 34 ... second covering region, 35 ... second reflecting surface, 37 ... third covering region , 38 ... 3rd reflective surface), 40, 41 ... Covering member, 45, 46 ... Light reflective material 50 ... Mounting substrate (51, 52 ... Wiring, 55 ... Frame, 56 ... Laminated substrate or base material), 60 ... Conductive adhesive

Claims (12)

発光面と受光面とを有し、発光素子からの光の少なくとも一部を波長変換可能な波長変換材料を含む光透過部材と、
前記受光面に対向する出射面を備える前記発光素子と、
前記発光素子表面から前記光透過部材表面まで延在して設けられて、前記発光素子からの出射光を前記光透過部材に導光する導光部材と、
前記発光素子を実装する基板と、
前記導光部材の側面を覆い、前記発光面を露出させて前記発光素子及び前記光透過部材の側面を被覆する被覆部材と、を備え、
前記被覆部材は、光反射性材料及び波長変換機能を備えた光変換部材を有する発光装置。
A light transmitting member having a light emitting surface and a light receiving surface and containing a wavelength conversion material capable of wavelength-converting at least a part of light from a light emitting element.
The light emitting element having an exit surface facing the light receiving surface and
A light guide member that extends from the surface of the light emitting element to the surface of the light transmitting member and guides the light emitted from the light emitting element to the light transmitting member.
A substrate on which the light emitting element is mounted and
The cover the side surface of the light guide member, and a covering member covering the side surface of the light emitting element and the light transmitting member to expose the light emitting surface,
The covering member is a light emitting device having a light reflecting material and a light conversion member having a wavelength conversion function.
前記被覆部材の側面は前記発光装置の外表面を構成している請求項1に記載の発光装置。 The light emitting device according to claim 1, wherein the side surface of the covering member constitutes the outer surface of the light emitting device. 前記被覆部材は着色剤を有する請求項1または2に記載の発光装置。 The light emitting device according to claim 1 or 2, wherein the covering member has a colorant. 前記導光部材は、前記発光素子の実装側表面より前記光透過部材側に位置している請求項1乃至3のいずれか1項に記載の発光装置。 The light emitting device according to any one of claims 1 to 3, wherein the light guide member is located on the light transmitting member side from the mounting side surface of the light emitting element. 前記出射面は、前記受光面より面積が大きく、平面視において前記受光面を内包する領域と、平面視において前記受光面より外側に突出する領域と、を有し、
前記導光部材は、前記出射面と前記受光面が互いに対向するように、前記出射面が有する前記内包する領域と前記受光面とを接合する接合領域を有し、
前記導光部材は、さらに、前記接合領域より延在し、前記出射面が有する前記外側に突出する領域を被覆する第1の被覆領域を有する請求項1〜4のいずれか1項に記載の発光装置。
The emitting surface has a larger area than the light receiving surface, and has a region including the light receiving surface in a plan view and a region protruding outward from the light receiving surface in a plan view.
The light guide member has a joining region for joining the included region of the exit surface and the light receiving surface so that the emission surface and the light receiving surface face each other.
The one according to any one of claims 1 to 4, wherein the light guide member further has a first covering region extending from the joint region and covering the outwardly projecting region of the exit surface . Light emitting device.
前記第1の被覆領域は、前記受光面より延在する前記光透過部材の側面を被覆する領域を有し、
前記第1の被覆領域の外表面は、前記受光面より延在する前記光透過部材の側面に対向し、前記出射光を前記光透過部材側に反射させる第1の反射面を有する請求項5に記載の発光装置。
The first covering region has a region covering the side surface of the light transmitting member extending from the light receiving surface.
5. The outer surface of the first covering region has a first reflecting surface that faces the side surface of the light transmitting member extending from the light receiving surface and reflects the emitted light toward the light transmitting member. The light emitting device according to.
前記被覆部材は、前記受光面より延在する前記光透過部材の側面のうち、前記第1の被覆領域にある前記導光部材から露出された領域を覆い、且つ、前記第1の被覆領域にある前記導光部材に被覆されている領域を前記第1の被覆領域にある前記導光部材を介して覆う請求項5又は6に記載の発光装置。 The covering member covers a region of the side surface of the light transmitting member extending from the light receiving surface, which is exposed from the light guide member in the first covering region, and covers the first covering region. The light emitting device according to claim 5 or 6, wherein a region covered with the light guide member is covered with the light guide member in the first covered region. 記第1の反射面は、前記光透過部材の側面から前記出射面側に傾斜した傾斜面である請求項6又は請求項6を引用する請求項7に記載の発光装置。 Before SL first reflecting surface, the light emitting device according to claim 7, citing claim 6 or claim 6 from a side surface of the light transmitting member is an inclined surface inclined to the emission surface side. 前記受光面は、前記出射面より面積が大きく、平面視において前記出射面を内包する領域と、平面視において前記出射面より外側に突出する領域と、を有し、
前記導光部材は、前記出射面と前記受光面が互いに対向するように、前記受光面が有する前記内包する領域と前記出射面とを接合する接合領域を有し、
前記導光部材は、さらに、前記接合領域より延在し、前記受光面が有する前記突出する領域を被覆する第1の被覆領域を有する請求項1〜4のいずれか1項に記載の発光装置。
The light receiving surface has a larger area than the emitting surface and has a region including the emitting surface in a plan view and a region projecting outward from the emitting surface in a plan view.
The light guide member has a joining region for joining the included region of the light receiving surface and the emitting surface so that the emitting surface and the light receiving surface face each other.
The light emitting device according to any one of claims 1 to 4, wherein the light guide member further extends from the joint region and has a first covering region that covers the protruding region of the light receiving surface. ..
前記第1の被覆領域は、前記出射面より延在する前記発光素子の側面を被覆する領域を有し、
前記第1の被覆領域の外表面は、前記出射面より延在する前記発光素子の側面に対向し、前記出射光を前記光透過部材側に反射させる第1の反射面を有する請求項に記載の発光装置。
The first covering region has a region covering the side surface of the light emitting element extending from the emission surface.
The ninth aspect of the present invention has a first reflecting surface in which the outer surface of the first covering region faces the side surface of the light emitting element extending from the emitting surface and reflects the emitted light toward the light transmitting member side. The light emitting device described.
前記被覆部材は、前記出射面より延在する前記発光素子の側面のうち、前記第1の被覆領域にある前記導光部材から露出された領域を覆い、且つ、前記第1の被覆領域にある前記導光部材に被覆されている領域を前記第1の被覆領域にある前記導光部材を介して覆う請求項9又は10に記載の発光装置。 The covering member covers a region exposed from the light guide member in the first covering region of the side surface of the light emitting element extending from the emitting surface , and is in the first covering region. The light emitting device according to claim 9 or 10 , wherein the region covered with the light guide member is covered with the light guide member in the first covering region. 記第1の反射面は、前記発光素子の側面から前記受光面側に傾斜した傾斜面である請求項10又は請求項10を引用する請求項11に記載の発光装置。 Before SL first reflecting surface, the light emitting device of claim 11, citing claim 10 or claim 10 is an inclined surface which is inclined to the light-receiving surface side from the side surface of the light emitting element.
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