JP5491691B2 - Light emitting device and lighting apparatus - Google Patents

Description

本発明は、ＬＥＤチップ（発光ダイオードチップ）を利用した発光装置および照明器具に関するものである。   The present invention relates to a light emitting device and a lighting fixture using an LED chip (light emitting diode chip).

従来から、図１０に示すように、ＬＥＤチップ１’と、ＬＥＤチップ１’が一表面側に実装された実装基板２’と、ＬＥＤチップ１’から放射された光によって励起されてＬＥＤチップ１’の発光色とは異なる色の光を放射する蛍光体を含有した透光性材料により形成されたドーム状の色変換部材４’とを備えた発光装置Ａ’が提案されている（例えば、特許文献１参照）。   Conventionally, as shown in FIG. 10, the LED chip 1 ′, the mounting substrate 2 ′ on which the LED chip 1 ′ is mounted on one surface side, and the LED chip 1, excited by light emitted from the LED chip 1 ′. A light emitting device A ′ including a dome-shaped color conversion member 4 ′ formed of a translucent material containing a phosphor that emits light of a color different from the light emission color of “a” has been proposed (for example, Patent Document 1).

ここにおいて、図１０に示した発光装置Ａ’の実装基板２’は、絶縁性基板の一表面側にＬＥＤチップ１’への給電用の配線パターン（図示せず）が形成されており、上記一表面側の中央部においてＬＥＤチップ１’がフリップチップ実装されている。また、図１０に示した構成の発光装置Ａ’では、色変換部材４’が実装基板２’の上記一表面側にＬＥＤチップ１’を覆うように配置されている。なお、上述の発光装置Ａ’では、ＬＥＤチップ１’として青色光を放射する青色ＬＥＤチップを採用し、色変換部材４’の蛍光体として黄色蛍光体を採用することにより、ＬＥＤチップ１’から放射された青色光と黄色蛍光体から放射された黄色光とが色変換部材４’の光出射面から放射されることとなり、白色光を得ることができる。   Here, the mounting substrate 2 ′ of the light emitting device A ′ shown in FIG. 10 has a wiring pattern (not shown) for supplying power to the LED chip 1 ′ formed on one surface side of the insulating substrate. The LED chip 1 ′ is flip-chip mounted at the center on the one surface side. Further, in the light emitting device A ′ having the configuration shown in FIG. 10, the color conversion member 4 ′ is disposed on the one surface side of the mounting substrate 2 ′ so as to cover the LED chip 1 ′. In the light emitting device A ′ described above, a blue LED chip that emits blue light is employed as the LED chip 1 ′, and a yellow phosphor is employed as the phosphor of the color conversion member 4 ′. The emitted blue light and the yellow light emitted from the yellow phosphor are emitted from the light exit surface of the color conversion member 4 ′, and white light can be obtained.

また、図１０に示した発光装置Ａ’を光源として組み込んだ照明器具の一例として、図１１や図１２に示す構成のものが考えられている（公知文献にかかるものではない）。   Moreover, the thing of the structure shown in FIG.11 and FIG.12 is considered as an example of the lighting fixture incorporating the light-emitting device A 'shown in FIG. 10 as a light source (it does not depend on well-known literature).

ここにおいて、図１１および図１２それぞれに示した照明器具は、上述の発光装置Ａ’と、発光装置Ａ’が収納される有底円筒状の器具本体９’と、器具本体９’内に収納され発光装置Ａ’の色変換部材４’の光出射面から放射される光の配光を制御する配光制御部材である椀状の反射鏡５’と、透光性材料（例えば、アクリル樹脂、ガラスなど）により形成され反射鏡５’の開口面を閉塞する形で配設される円板状の透光性カバー８’と、器具本体９’の開口縁に形成された溝部９ｂ’の底面との間に透光性カバー８’の周部と反射鏡５’の開口縁から外方へ延設された外鍔部５ｃ’とを重ねた形で保持する円環状の保持枠１０’とを備えている。なお、配光制御部材である反射鏡５’は、照明器具の小型化（コンパクト化）および高効率化のために設けられている。 Here, each of the lighting fixtures shown in FIGS. 11 and 12 is housed in the above-described light emitting device A ′, a bottomed cylindrical fixture body 9 ′ in which the light emitting device A ′ is housed, and the fixture body 9 ′. And a bowl-shaped reflecting mirror 5 ′, which is a light distribution control member for controlling the light distribution of the light emitted from the light exit surface of the color conversion member 4 ′ of the light emitting device A ′, and a translucent material (for example, acrylic resin) Disk-shaped translucent cover 8 ′ formed by closing the opening surface of reflecting mirror 5 ′ and groove 9b ′ formed at the opening edge of instrument body 9 ′. holding frame 10 of the annular holding in a form of repeating an outer collar portion 5c 'which extends outward from the opening edge of' the peripheral portion of the reflecting mirror 5 'translucent cover 8 between the bottom surface 'And features. Note that the reflecting mirror 5 ′, which is a light distribution control member, is provided to reduce the size (compact) of the lighting fixture and increase the efficiency.

ここで、図１１の照明器具では、外部への光取り出し効率を向上させるために、反射鏡５’の底部の開口部５ａ’のサイズが色変換部材４’よりも大きく且つ実装基板２’よりも小さく設定され、反射鏡５’の開口部５ａ’の内側面が色変換部材４’の周部に近接している。要するに、図１１の照明器具では、色変換部材４’の開口端（実装基板２’側の端縁）を含む平面Ｐ１よりも反射鏡５ａ’の底部の開口面を含む平面Ｐ２の方が器具本体９’の内底面から遠くなるように反射鏡５ａ’の形状が設計されている。   Here, in the lighting fixture of FIG. 11, in order to improve the light extraction efficiency to the outside, the size of the opening 5a ′ at the bottom of the reflecting mirror 5 ′ is larger than that of the color conversion member 4 ′ and more than the mounting substrate 2 ′. Also, the inner surface of the opening 5a ′ of the reflecting mirror 5 ′ is close to the peripheral portion of the color conversion member 4 ′. In short, in the lighting apparatus of FIG. 11, the plane P2 including the opening surface at the bottom of the reflecting mirror 5a ′ is more suitable than the plane P1 including the opening end of the color conversion member 4 ′ (end edge on the mounting substrate 2 ′ side). The shape of the reflecting mirror 5a ′ is designed so as to be far from the inner bottom surface of the main body 9 ′.

一方、図１２の照明器具では、外部への光取り出し効率を向上させるために、反射鏡５’の底部の開口部５ａ’の内側面が実装基板２’の外側面に対向するように反射鏡５’が設計されている。要するに、図１２の照明器具では、色変換部材４’の開口端を含む平面Ｐ１よりも反射鏡５ａ’の底部の開口面を含む平面Ｐ２の方が器具本体９’の内底面に近くなるように反射鏡５ａ’の形状が設計されている。   On the other hand, in the illuminating device of FIG. 12, in order to improve the light extraction efficiency to the outside, the reflecting mirror is arranged so that the inner surface of the opening 5a ′ at the bottom of the reflecting mirror 5 ′ faces the outer surface of the mounting substrate 2 ′. 5 'is designed. In short, in the lighting fixture of FIG. 12, the plane P2 including the opening surface of the bottom of the reflecting mirror 5a ′ is closer to the inner bottom surface of the fixture body 9 ′ than the plane P1 including the opening end of the color conversion member 4 ′. The shape of the reflecting mirror 5a 'is designed.

また、図１０に示した構成の発光装置Ａ’を光源として組み込んだ照明器具としては、図１３に示す構成のものも考えられている（公知文献にかかるものではない）。   Further, as a lighting fixture in which the light emitting device A ′ having the configuration shown in FIG. 10 is incorporated as a light source, the lighting fixture having the configuration shown in FIG. 13 is also considered (not related to known literature).

ここにおいて、図１３（ａ）に示した照明器具の基本構成は図１１と略同じであり、配光制御部材として反射鏡５’の代わりに、発光装置Ａ’から放射される光の配光を制御するハイブリッドレンズ６’を備えており、ハイブリッドレンズ６’の外側面から外方へ延設された外鍔部６ｄ’が、器具本体９’の開口縁に形成された溝部９ｂ’の底面と保持枠１０’との間に保持されている。   Here, the basic configuration of the luminaire shown in FIG. 13A is substantially the same as that in FIG. 11, and the light distribution of the light emitted from the light emitting device A ′ instead of the reflecting mirror 5 ′ as a light distribution control member. And an outer flange portion 6d 'extending outward from the outer surface of the hybrid lens 6' is a bottom surface of a groove 9b 'formed at the opening edge of the instrument body 9'. And the holding frame 10 '.

上述のハイブリッドレンズ６’は、図１３（ｂ）に示すように、発光装置Ａ’側に形成された凹所６１’の内底面６１ａ’と内側面６１ｂ’とが光入射面６ａ’を構成しており、光入射面６ａ’側の焦点Ｆから凹所６１’の内底面６１ａ’へ入射した光を屈折させて更に光出射面６ｂ’で屈折させる機能と、光入射面６ａ’側の焦点Ｆから凹所６１’の内側面６１ｂ’へ入射した光を屈折させた後に外側面６ｃ’で全反射させ更に光出射面６ｂ’で屈折させる機能とを有しており、図１３（ｂ）中に矢印で示すように焦点Ｆから放射され光入射面６ａ’へ入射した光が光出射面６ｂ’から出射される。なお、ハイブリッドレンズ６’は、外側面６ｃ’が回転放物面状に形成され、光出射面６ｂ’が凸曲面状に形成されているが、外側面６ｃ’はＬＥＤチップ１’の光軸方向においてＬＥＤチップ１’から離れるにつれて外形が徐々に大きくなる曲面状であって凹所６１’の内側面６１ｂ’から入射した光を光出射面６ｂ’側へ全反射できる形状であればよく、光出射面６ｂ’は平面状でもよいし、フレネルレンズ状でもよい。
特開２００７−４９００１９号公報（段落〔００１２〕−〔００１７〕および図１） In the hybrid lens 6 ′ described above, as shown in FIG. 13B, the inner bottom surface 61a ′ and the inner side surface 61b ′ of the recess 61 ′ formed on the light emitting device A ′ side constitute a light incident surface 6a ′. The light incident from the focal point F on the light incident surface 6a ′ side to the inner bottom surface 61a ′ of the recess 61 ′ and further refracted by the light exit surface 6b ′; The light incident from the focal point F to the inner side surface 61b ′ of the recess 61 ′ is refracted and then totally reflected by the outer side surface 6c ′ and further refracted by the light emitting surface 6b ′. ), The light emitted from the focal point F and incident on the light incident surface 6a ′ is emitted from the light emitting surface 6b ′. The hybrid lens 6 ′ has an outer surface 6c ′ formed in a paraboloid shape and a light exit surface 6b ′ formed in a convex curve shape, but the outer surface 6c ′ is an optical axis of the LED chip 1 ′. As long as it is a curved shape whose outer shape gradually increases as it moves away from the LED chip 1 ′ in the direction, the light incident from the inner surface 61 b ′ of the recess 61 ′ can be totally reflected to the light emitting surface 6 b ′ side. The light exit surface 6b ′ may be planar or may be a Fresnel lens.
Japanese Patent Laying-Open No. 2007-490019 (paragraphs [0012]-[0017] and FIG. 1)

ところで、図１０に示した発光装置Ａ’は、同図中に矢印で示すようにドーム状の色変換部材４’の光出射面の任意の点から放射される光の配光が拡散配光となるが、平面視における色変換部材４’のサイズよりも実装基板２’のサイズが大きいので、色変換部材４’の光出射面から放射され実装基板２’の上記一表面に入射した光の一部が実装基板２’に吸収され、外部への光取り出し効率が低下してしまう。また、上述の発光装置Ａ’は、実装基板２’が絶縁性基板を用いて形成されているので、当該絶縁性基板の熱伝導率が低く、ＬＥＤチップ１’で発生した熱を効率良く放熱させることができず、ＬＥＤチップ１’の温度上昇による光束低下、寿命および信頼性低下を抑制するために、ＬＥＤチップ１’のジャンクション温度が最大ジャンクション温度を超えないようにＬＥＤチップ１’への入力電力を制限する必要があり、光出力の高出力化が難しかった。   Incidentally, in the light emitting device A ′ shown in FIG. 10, the light distribution of light emitted from an arbitrary point on the light exit surface of the dome-shaped color conversion member 4 ′ is diffused as shown by the arrows in FIG. However, since the size of the mounting substrate 2 ′ is larger than the size of the color conversion member 4 ′ in plan view, the light emitted from the light emitting surface of the color conversion member 4 ′ and incident on the one surface of the mounting substrate 2 ′ Part of the light is absorbed by the mounting substrate 2 ′, and the light extraction efficiency to the outside is reduced. In the above-described light emitting device A ′, since the mounting substrate 2 ′ is formed using an insulating substrate, the thermal conductivity of the insulating substrate is low, and the heat generated in the LED chip 1 ′ is efficiently radiated. In order to suppress the decrease in luminous flux, the lifetime, and the reliability due to the temperature rise of the LED chip 1 ′, the LED chip 1 ′ can be connected to the LED chip 1 ′ so that the junction temperature does not exceed the maximum junction temperature. It was necessary to limit the input power, and it was difficult to increase the optical output.

また、上述のように小型化および高効率化が望まれる照明器具に用いる配光制御部材には、コンパクト且つ高い光入射効率が要求され、図１１に示した照明器具では、外部への光取り出し効率を向上させるために、発光装置Ａ’の光軸に直交する面内において色変換部材４’と反射鏡５’の開口部５ａ’の内側面とを接触しないように近接させてあるが、反射鏡５’の底部が実装基板２’の上記一表面側において実装基板２’から離間して位置しているので、色変換部材４’と反射鏡５’の開口部５ａ’の内側面との間の隙間から同図中に矢印で示すように光が漏れて損失となるので、照明器具全体としての外部への光取り出し効率が低下してしまう。   Further, as described above, the light distribution control member used in a lighting fixture that is desired to be downsized and highly efficient is required to have a compact and high light incidence efficiency. In the lighting fixture shown in FIG. In order to improve the efficiency, the color conversion member 4 ′ and the inner surface of the opening 5a ′ of the reflecting mirror 5 ′ are brought close to each other in a plane orthogonal to the optical axis of the light emitting device A ′. Since the bottom portion of the reflecting mirror 5 ′ is positioned away from the mounting substrate 2 ′ on the one surface side of the mounting substrate 2 ′, the color conversion member 4 ′ and the inner surface of the opening 5a ′ of the reflecting mirror 5 ′ As shown by the arrows in the figure, light leaks from the gap between them and becomes a loss, so that the light extraction efficiency to the outside as the entire lighting fixture is reduced.

また、図１１に示した照明器具では、当該照明器具を正面から見た場合、色変換部材４’と反射鏡５’の開口部５ａ’の内側面との間の隙間が非発光部となるため、正面から見た光度が低下してしまう。なお、このような正面から見た光度の低下を抑制するためには、反射鏡５’の光出射側の開口部５ｂ’のサイズを大きくする必要があり、照明器具全体のサイズが大きくなってしまう。   Moreover, in the lighting fixture shown in FIG. 11, when the said lighting fixture is seen from the front, the clearance gap between color conversion member 4 'and the inner surface of opening part 5a' of reflecting mirror 5 'becomes a non-light-emitting part. Therefore, the luminous intensity seen from the front will fall. In order to suppress such a decrease in luminous intensity as viewed from the front, it is necessary to increase the size of the opening 5b ′ on the light exit side of the reflecting mirror 5 ′, which increases the size of the entire lighting fixture. End up.

また、図１２に示した照明器具では、色変換部材４’の開口端を含む平面Ｐ１よりも反射鏡５ａ’の底部の開口面を含む平面Ｐ２の方が器具本体９’の内底面に近くなるように反射鏡５ａ’の形状が設計されているので、図１１の照明器具に比べて、色変換部材４’の周部から放射された光の反射鏡５’への入射効率を高めることができるが、色変換部材４’の光出射面から放射され実装基板２’の上記一表面に入射した光の一部が実装基板２’に吸収され、照明器具全体としての外部への光取り出し効率が低下してしまう。また、図１２に示した照明器具では、反射鏡５’の開口部５ａ’のサイズを実装基板２’のサイズよりも大きくする必要があるので、色変換部材４’と反射鏡５’の内側面との間の隙間が非発光部となるため、正面から見た光度が低下してしまう。   In the lighting fixture shown in FIG. 12, the plane P2 including the opening surface at the bottom of the reflecting mirror 5a ′ is closer to the inner bottom surface of the fixture body 9 ′ than the plane P1 including the opening end of the color conversion member 4 ′. Since the shape of the reflecting mirror 5a ′ is designed so that the incident efficiency of the light emitted from the peripheral portion of the color conversion member 4 ′ to the reflecting mirror 5 ′ is increased as compared with the lighting fixture of FIG. However, a part of the light emitted from the light emitting surface of the color conversion member 4 ′ and incident on the one surface of the mounting substrate 2 ′ is absorbed by the mounting substrate 2 ′, and the light is extracted to the outside as the entire lighting fixture. Efficiency will decrease. In the lighting fixture shown in FIG. 12, since the size of the opening 5a ′ of the reflecting mirror 5 ′ needs to be larger than the size of the mounting substrate 2 ′, the color conversion member 4 ′ and the reflecting mirror 5 ′ have the same size. Since the gap between the side surfaces becomes a non-light emitting portion, the luminous intensity viewed from the front is lowered.

また、図１３（ａ）に示した照明器具では、ハイブリッドレンズ６’の凹所６１’の内面を発光装置Ａ’の色変換部材４’に近接させることにより、ハイブリッドレンズ６’の凹所６１’の開口面のサイズを小さくしてハイブリッドレンズ６’のコンパクト化を図るとともに、発光装置Ａ’から放射された光のハイブリッドレンズ６’への入射効率を高めてあるが、ハイブリッドレンズ６’が実装基板２’の上記一表面に接触しないように、ハイブリッドレンズ６’の凹所６１’の開口面を含む平面Ｐ３を発光装置Ａ’の実装基板２’の上記一表面を含む平面Ｐ１から離間して配置する必要があり、発光装置Ａ’の光軸方向において実装基板２’とハイブリッドレンズ６’との間に隙間が生じるので、図１３（ａ）中に矢印で示すように光が漏れ、光漏れによる損失が生じてしまう。また、このような光漏れによる損失の発生を抑制するために、ハイブリッドレンズ６’の凹所６１’の開口面のサイズを実装基板２’のサイズよりも大きくし、ハイブリッドレンズ６’の凹所６１’内に発光装置Ａ’全体が収まるようにハイブリッドレンズ６’を配置することも考えられるが、この場合には、ハイブリッドレンズ６’のサイズが大きくなってしまう。   Further, in the lighting fixture shown in FIG. 13A, the inner surface of the recess 61 ′ of the hybrid lens 6 ′ is brought close to the color conversion member 4 ′ of the light emitting device A ′, thereby the recess 61 of the hybrid lens 6 ′. The size of the aperture surface of 'is reduced to make the hybrid lens 6' compact and the incident efficiency of the light emitted from the light emitting device A 'to the hybrid lens 6' is increased. The plane P3 including the opening surface of the recess 61 ′ of the hybrid lens 6 ′ is separated from the plane P1 including the one surface of the mounting substrate 2 ′ of the light emitting device A ′ so as not to contact the one surface of the mounting substrate 2 ′. Since there is a gap between the mounting substrate 2 ′ and the hybrid lens 6 ′ in the optical axis direction of the light emitting device A ′, light is emitted as shown by an arrow in FIG. It is the loss due to light leakage occurs. Further, in order to suppress the occurrence of loss due to such light leakage, the size of the opening surface of the recess 61 ′ of the hybrid lens 6 ′ is made larger than the size of the mounting substrate 2 ′, and the recess of the hybrid lens 6 ′. Although it is conceivable to arrange the hybrid lens 6 ′ so that the entire light emitting device A ′ fits in the 61 ′, in this case, the size of the hybrid lens 6 ′ becomes large.

本発明は上記事由に鑑みて為されたものであり、その目的は、外部への光取り出し効率を向上させることができる発光装置および照明器具を提供することにある。   This invention is made | formed in view of the said reason, The objective is to provide the light-emitting device and lighting fixture which can improve the light extraction efficiency to the exterior.

請求項１の発明は、ＬＥＤチップと、前記ＬＥＤチップが一表面側に実装された実装基板と、前記ＬＥＤチップから放射された光によって励起されて前記ＬＥＤチップの発光色とは異なる色の光を放射する蛍光体を含有した透光性材料により形成され前記実装基板の前記一表面側に配設された色変換部材とを備え、前記色変換部材がドーム状であり、平面視において前記色変換部材の外周線よりも前記実装基板の外周線が内側に位置し、前記色変換部材の開口端が前記実装基板の前記一表面側で前記実装基板の外周部と接合されてなることを特徴とする。 The invention of claim 1 is different from the LED chip, and the L ED mounting substrate chip is mounted on one surface side, and the L ED is excited by the light emitted from the chip by the L ED chip luminescent color and a color conversion member is formed by a translucent material containing a fluorescent substance disposed on said one surface side of the implementation substrate that emits color light, the color conversion member is dome-shaped, peripheral line of the implementation substrate than the outer peripheral line of the color converting member Te flat surface viewed smell located inside, the outer circumference of the implementation substrate opening end of the color converting member at the one surface side of the mounting substrate It is characterized by being joined to the part.

この発明によれば、平面視において色変換部材の外周線よりも実装基板の外周線が内側に位置し色変換部材の開口端が実装基板の外周部と接合されているので、色変換部材の周部から放射された光が実装基板に吸収されることなく外部へ出射されることとなり、発光装置全体としての外部への光取り出し効率を向上させることができる。   According to the present invention, the outer peripheral line of the mounting board is located on the inner side than the outer peripheral line of the color conversion member in plan view, and the opening end of the color conversion member is joined to the outer peripheral part of the mounting board. The light emitted from the peripheral portion is emitted to the outside without being absorbed by the mounting substrate, and the light extraction efficiency to the outside as the entire light emitting device can be improved.

請求項２の発明は、請求項１の発明において、前記ＬＥＤチップと前記色変換部材との間に、前記ＬＥＤチップを封止した透光性材料からなる封止部が設けられてなることを特徴とする。   According to a second aspect of the present invention, in the first aspect of the invention, a sealing portion made of a translucent material that seals the LED chip is provided between the LED chip and the color conversion member. Features.

この発明によれば、前記ＬＥＤチップの光取り出し面が接する媒質が空気の場合に比べて前記ＬＥＤチップと前記光取り出し面が接する媒質との屈折率差が小さくなり、前記ＬＥＤチップからの光取り出し効率が向上し、結果的に発光装置全体としての光取り出し効率が向上する。   According to the present invention, the refractive index difference between the LED chip and the medium with which the light extraction surface is in contact is smaller than when the medium with which the light extraction surface of the LED chip is in contact is air, and light extraction from the LED chip is performed. The efficiency is improved, and as a result, the light extraction efficiency of the entire light emitting device is improved.

請求項３の発明は、請求項１または請求項２の発明において、前記実装基板の他表面側に、前記実装基板よりも熱伝導率の高い材料により形成され前記ＬＥＤチップで発生した熱が伝熱される伝熱プレートが埋設されてなり、平面視における前記伝熱プレートの外周線が前記ＬＥＤチップの外周線の外側に位置していることを特徴とする。 According to a third aspect of the present invention, in the first or second aspect of the present invention, heat generated by the LED chip formed on the other surface side of the mounting substrate is made of a material having a higher thermal conductivity than the mounting substrate. heated by heat transfer plates will have is embedded, characterized in that the peripheral line of the heat transfer plate that put in plan view is located outside the peripheral line of the LED chip.

この発明によれば、前記ＬＥＤチップで発生した熱が前記ＬＥＤチップよりも広い伝熱プレートへ伝熱されて放熱されるので、前記ＬＥＤチップの温度上昇が抑制され、光束の向上を図れるとともに、寿命および信頼性の向上を図れる。   According to this invention, the heat generated in the LED chip is transferred to a heat transfer plate wider than the LED chip and dissipated, so that the temperature rise of the LED chip is suppressed and the luminous flux can be improved. The life and reliability can be improved.

請求項４の発明は、請求項３の発明において、前記伝熱プレートは、前記実装基板の前記一表面側に露出するマウント部が突設されてなり、前記ＬＥＤチップは、前記マウント部に搭載されてなることを特徴とする。 The invention of claim 4 is the invention of claim 3, wherein the heat transfer plate is made mounted portion projecting exposed to the one surface of the mounting substrate, the LED chip, the mount portion It is characterized by being mounted.

この発明によれば、前記ＬＥＤチップで発生した熱が前記伝熱プレートへ直接伝熱されるので、放熱性が向上し、光束の向上を図れるとともに、寿命および信頼性の向上を図れる。   According to the present invention, the heat generated in the LED chip is directly transferred to the heat transfer plate, so that the heat dissipation can be improved, the luminous flux can be improved, and the life and reliability can be improved.

請求項５の発明は、請求項４の発明において、前記マウント部は、前記実装基板の前記一表面を含む平面から突出していることを特徴とする。   According to a fifth aspect of the invention, in the invention of the fourth aspect, the mount portion protrudes from a plane including the one surface of the mounting substrate.

この発明によれば、前記ＬＥＤチップから放射される光のうち前記実装基板の前記一表面へ入射して吸収される成分を低減できて、前記色変換部材に直接入射する成分が増えるから、発光装置全体としての外部への光取り出し効率を向上できる。   According to the present invention, the light emitted from the LED chip can be reduced in the component incident on and absorbed by the one surface of the mounting substrate, and the component directly incident on the color conversion member is increased. The light extraction efficiency to the outside as the whole apparatus can be improved.

請求項６の発明は、請求項３ないし請求項５の発明において、前記伝熱プレートは、前記実装基板の前記他表面側と同じ面側に中央から外側に向かって幅の広くなる溝が形成されてなることを特徴とする。 According to a sixth aspect of the present invention, in the third to fifth aspects of the present invention, the heat transfer plate is formed with a groove that becomes wider from the center toward the outer side on the same surface side as the other surface side of the mounting substrate. It is characterized by being made.

この発明によれば、発光装置を配線基板に実装して用いるにあたって、前記伝熱プレートを配線基板に半田により接合する際に、半田の溶融から硬化の過程で生じるフラックスなどのガスおよび気泡が溝に沿って外部に抜けやすくなり、硬化後の半田からなる接合部の内部にボイドが生じるのを抑制することができ、結果的に、前記ＬＥＤチップと前記配線基板との間の熱抵抗のばらつきを小さくすることができるとともに、温度サイクルがかかった時に実装基板と配線基板との線膨張率差によって生じる応力変化に対する接合部の耐性が高くなって信頼性が向上する。   According to the present invention, when the light-emitting device is mounted on a wiring board and used, when the heat transfer plate is joined to the wiring board by solder, gas and bubbles such as flux generated in the process of melting from the solder are grooved. It is possible to prevent the voids from being generated inside the joint made of solder after curing, resulting in variations in thermal resistance between the LED chip and the wiring board. Can be reduced, and when the temperature cycle is applied, the resistance of the bonded portion to the stress change caused by the difference in linear expansion coefficient between the mounting substrate and the wiring substrate is increased, and the reliability is improved.

請求項７の発明は、請求項４ないし請求項６の発明において、前記マウント部は、前記ＬＥＤチップの搭載領域の周囲に短絡防止溝が形成されてなることを特徴とする。   According to a seventh aspect of the present invention, in the fourth to sixth aspects of the present invention, the mount portion is formed with a short-circuit preventing groove around the LED chip mounting region.

この発明によれば、前記ＬＥＤチップを前記搭載領域に半田により接合する際に前記ＬＥＤチップ直下から溢れ出た余分な半田が短絡防止溝に溜まるので、余分な半田が前記実装基板の前記一表面側の配線パターン上まで流れ出ることによる短絡を防止することができる。   According to the present invention, when the LED chip is joined to the mounting region by solder, excess solder overflowing from immediately below the LED chip is accumulated in the short-circuit prevention groove, so that excess solder is collected on the one surface of the mounting substrate. It is possible to prevent a short circuit caused by flowing out to the wiring pattern on the side.

請求項８の発明は、請求項１ないし請求項７のいずれか１項に記載の発光装置と、前記発光装置から放射される光の配光を制御する反射鏡であって底部に前記発光装置が挿入される開口部を有する前記反射鏡と、前記発光装置および前記反射鏡が収納される器具本体とを備えてなることを特徴とする。 The invention of claim 8, the calling to the light emitting device, a reflecting mirror for controlling the light distribution of light emitted from the light - emitting device bottom according to any one of claims 1 to 7 wherein the anti Ikyo that having a opening optical device is inserted, the light - emitting device and said reflection mirror is characterized by comprising a device body to be housed.

この発明によれば、発光装置の色変換部材の周部と反射鏡における底部の開口部の内側面との間の隙間を小さくすることができ、照明器具を正面から見た時の非発光部の面積が小さくなって正面光度が向上するとともに、照明器具の小型化を図りつつ照明器具全体としての外部への光取り出し効率を向上させることができる。   According to the present invention, the gap between the peripheral portion of the color conversion member of the light emitting device and the inner surface of the bottom opening of the reflecting mirror can be reduced, and the non-light emitting portion when the lighting fixture is viewed from the front. As a result, the front luminous intensity is improved, and the light extraction efficiency as a whole of the lighting fixture can be improved while downsizing the lighting fixture.

請求項９の発明は、請求項８の発明において、前記反射鏡は、前記開口部の周部の厚みが前記発光装置における前記実装基板の厚みよりも薄く、前記開口部の開口縁が前記色変換部材の前記開口端を含む平面よりも後退して位置するように配置されてなることを特徴とする。 According to a ninth aspect of the present invention, in the eighth aspect of the invention, the reflecting mirror has a thickness of a peripheral portion of the opening that is thinner than a thickness of the mounting substrate in the light emitting device, and an opening edge of the opening has the color. It is arranged to be positioned recessed from the plane including the open mouth end of the conversion member, characterized by comprising.

この発明によれば、前記色変換部材の周部から放射された光の前記反射鏡への入射効率を高めることができ、照明器具全体としての外部への光取り出し効率を向上させることができる。   According to this invention, it is possible to increase the incident efficiency of the light emitted from the peripheral portion of the color conversion member to the reflecting mirror, and it is possible to improve the light extraction efficiency to the outside as the entire lighting fixture.

請求項１の発明では、発光装置全体としての外部への光取り出し効率を向上させることができるという効果がある。   In the invention of claim 1, there is an effect that the light extraction efficiency to the outside as the whole light emitting device can be improved.

請求項８の発明では、照明器具全体としての外部への光取り出し効率を向上させることができるという効果がある。   In the invention of claim 8, there is an effect that the light extraction efficiency to the outside as the entire lighting fixture can be improved.

（実施形態１）
本実施形態の発光装置Ａは、図１に示すように、ＬＥＤチップ１と、ＬＥＤチップ１が一表面側に実装された実装基板２と、ＬＥＤチップ１から放射された光によって励起されてＬＥＤチップ１の発光色とは異なる色の光を放射する蛍光体を含有した透光性材料により形成されＬＥＤチップ１を実装基板２との間に囲む形で実装基板２の上記一表面側に配設されたドーム状の色変換部材４と、ＬＥＤチップ１と色変換部材４との間に設けられＬＥＤチップ１を封止した透光性材料からなる封止部３とを備えている。ここにおいて、本実施形態の発光装置Ａは、ＬＥＤチップ１を実装基板２との間に囲む形で実装基板２の上記一表面側に配設されたドーム状の光学部材１５を備えており、色変換部材４が、光学部材１５の光出射面との間に空気層１６が形成される形で実装基板２に接合されており、光学部材１５と実装基板２とで囲まれた空間に封止部３が充実されている。 (Embodiment 1)
As shown in FIG. 1, the light emitting device A of the present embodiment is an LED chip 1, a mounting substrate 2 on which the LED chip 1 is mounted on one surface side, and an LED excited by light emitted from the LED chip 1. It is formed of a translucent material containing a phosphor that emits light of a color different from the emission color of the chip 1 and is arranged on the one surface side of the mounting substrate 2 so as to surround the LED chip 1 with the mounting substrate 2. A dome-shaped color conversion member 4 provided, and a sealing portion 3 made of a translucent material provided between the LED chip 1 and the color conversion member 4 and sealing the LED chip 1 are provided. Here, the light-emitting device A of the present embodiment includes a dome-shaped optical member 15 disposed on the one surface side of the mounting substrate 2 so as to surround the LED chip 1 with the mounting substrate 2. The color conversion member 4 is bonded to the mounting substrate 2 in such a manner that an air layer 16 is formed between the light emitting surface of the optical member 15 and sealed in a space surrounded by the optical member 15 and the mounting substrate 2. Stop part 3 is substantial.

なお、本実施形態の発光装置では、ＬＥＤチップ１として、青色光を放射するＧａＮ系青色ＬＥＤチップを用い、色変換部材４の蛍光体として、ＬＥＤチップ１から放射された青色光によって励起されてブロードな黄色系の光を放射する粒子状の黄色蛍光体を用いており、ＬＥＤチップ１から放射され封止部３および光学部材１５および色変換部材４を透過した青色光と、色変換部材４の黄色蛍光体から放射された黄色光とが色変換部材４の光出射面から拡散した配光となって出射されることとなり、白色光を得ることができる。   In the light emitting device of the present embodiment, a GaN blue LED chip that emits blue light is used as the LED chip 1, and the phosphor of the color conversion member 4 is excited by the blue light emitted from the LED chip 1. Blue light emitted from the LED chip 1 and transmitted through the sealing portion 3, the optical member 15, and the color conversion member 4, using the particulate yellow phosphor that emits broad yellowish light, and the color conversion member 4. The yellow light emitted from the yellow phosphor is emitted as a light distribution diffused from the light exit surface of the color conversion member 4, and white light can be obtained.

実装基板２は、ＬＥＤチップ１が電気的に接続される配線パターン２１が一表面側に設けられた多層セラミック基板により構成されている。ここにおいて、実装基板２の他表面側には外部接続用電極２３が形成されており、配線パターン２１がビア２２ａを介して内部の導体パターン２２ｂと繋がっており、当該導体パターン２２ｂが側面に沿って形成された導体パターン２２ｃを介して外部接続用電極２３と電気的に接続されている。なお、実装基板２の材料はセラミックに限らず、絶縁性の高いガラスエポキシ樹脂や液晶ポリマーなどの耐熱性樹脂でもよい。   The mounting substrate 2 is composed of a multilayer ceramic substrate in which a wiring pattern 21 to which the LED chip 1 is electrically connected is provided on one surface side. Here, an external connection electrode 23 is formed on the other surface side of the mounting substrate 2, the wiring pattern 21 is connected to the internal conductor pattern 22b via the via 22a, and the conductor pattern 22b extends along the side surface. It is electrically connected to the external connection electrode 23 through the conductor pattern 22c formed in this way. The material of the mounting substrate 2 is not limited to ceramic, but may be a heat-resistant resin such as a highly insulating glass epoxy resin or liquid crystal polymer.

また、本実施形態の発光装置Ａは、実装基板２の他表面側に、実装基板２よりも熱伝導率の高い材料（例えば、Ｃｕなど）により形成されＬＥＤチップ１で発生した熱が伝熱される伝熱プレート２５が埋設されており、平面視における伝熱プレート２５の外周線がＬＥＤチップ１の外周線の外側に位置している。要するに、伝熱プレート２５の投影領域内にＬＥＤチップ１が配置されている。したがって、ＬＥＤチップ１で発生した熱がＬＥＤチップ１よりも広い伝熱プレート２５へ伝熱されて放熱されるので、ＬＥＤチップ１の温度上昇が抑制され、光束の向上を図れるとともに、寿命および信頼性の向上を図れる。ここにおいて、伝熱プレート２５は、実装基板２の上記一表面側に露出するマウント部２５ｂが一表面の中央部から連続一体に突設されており、ＬＥＤチップ１は、マウント部２５ｂに搭載されているので、ＬＥＤチップ１で発生した熱が伝熱プレート２５へ直接伝熱されるから、放熱性が向上し、光束の向上を図れるとともに、寿命および信頼性の向上を図れる。ここにおいて、実装基板２は、上記他表面の中央部に伝熱プレート２５が埋設される埋込穴２４ａが設けられるとともに上記一表面と埋込穴２４ａの内底面との間の部位にマウント部２５ｂが挿入される貫通孔２４ｂが設けられ、埋込穴２４ａの内底面（伝熱プレート２５との接合部位）にメッキが施されており、伝熱プレート２５がロウ付けなどで接合されている。また、伝熱プレート２５は、他表面が実装基板２の上記他表面を含む平面よりも僅かに突出しており、伝熱プレート２５の上記他表面が実装基板２の上記他表面を含む平面と平行になっている。なお、伝熱プレート２５の材料は、Ｃｕに限らず、例えば、ＣｕＷなどでもよい。   Further, the light emitting device A of the present embodiment is formed on the other surface side of the mounting substrate 2 by a material having a higher thermal conductivity than the mounting substrate 2 (for example, Cu or the like), and heat generated by the LED chip 1 is transferred. The heat transfer plate 25 is embedded, and the outer peripheral line of the heat transfer plate 25 in a plan view is located outside the outer peripheral line of the LED chip 1. In short, the LED chip 1 is arranged in the projection area of the heat transfer plate 25. Therefore, since the heat generated in the LED chip 1 is transferred to the heat transfer plate 25 wider than the LED chip 1 and is radiated, the temperature rise of the LED chip 1 is suppressed, the luminous flux can be improved, and the lifetime and reliability can be improved. Can improve the performance. Here, the heat transfer plate 25 has a mounting portion 25b exposed on the one surface side of the mounting substrate 2 protruding continuously from the central portion of the one surface, and the LED chip 1 is mounted on the mounting portion 25b. Therefore, since the heat generated in the LED chip 1 is directly transferred to the heat transfer plate 25, the heat dissipation can be improved, the luminous flux can be improved, and the life and reliability can be improved. Here, the mounting substrate 2 is provided with an embedding hole 24a in which the heat transfer plate 25 is embedded in the central portion of the other surface, and at a portion between the one surface and the inner bottom surface of the embedding hole 24a. A through hole 24b into which 25b is inserted is provided, and the inner bottom surface (joining portion with the heat transfer plate 25) of the embedded hole 24a is plated, and the heat transfer plate 25 is joined by brazing or the like. . Further, the other surface of the heat transfer plate 25 slightly protrudes from the plane including the other surface of the mounting substrate 2, and the other surface of the heat transfer plate 25 is parallel to the plane including the other surface of the mounting substrate 2. It has become. The material of the heat transfer plate 25 is not limited to Cu, and may be CuW, for example.

また、本実施形態では、マウント部２５ｂが実装基板２の上記一表面を含む平面から突出しているので、ＬＥＤチップ１から放射される光のうち実装基板２の上記一表面へ入射して吸収される成分を低減できて、色変換部材４に直接入射する成分が増え、発光装置Ａ全体としての外部への光取り出し効率を向上できる。   In the present embodiment, since the mount portion 25b protrudes from the plane including the one surface of the mounting substrate 2, the light emitted from the LED chip 1 enters the one surface of the mounting substrate 2 and is absorbed. Component to be directly incident on the color conversion member 4 can be increased, and the light extraction efficiency of the light emitting device A as a whole can be improved.

ところで、ＬＥＤチップ１は、厚み方向の両面に電極（図示せず）が形成されており、実装基板２側とは反対側の一方の電極が金細線からなるボンディングワイヤ１４を介して配線パターン２１と電気的に接続され、実装基板２側の電極が半田からなる接合部１２を介してマウント部２５ｂに接合されて電気的に接続されるとともに熱結合されている。なお、接合部１２の材料は半田に限らず、導電性の高い銀ペーストなどを採用してもよい。   By the way, the LED chip 1 has electrodes (not shown) formed on both surfaces in the thickness direction, and the wiring pattern 21 is formed via a bonding wire 14 in which one electrode on the side opposite to the mounting substrate 2 side is made of a fine gold wire. The electrode on the mounting substrate 2 side is joined to the mount portion 25b via the joint portion 12 made of solder, and is electrically connected and thermally coupled. Note that the material of the joint 12 is not limited to solder, and a highly conductive silver paste or the like may be employed.

実装基板２は、上述のように上記他表面側に外部接続用電極２３が形成されるとともに、伝熱プレート２５が外部接続用電極を兼ねているので、一対の配線パターン７３，７５が形成された配線基板７に実装する際に、前者の外部接続用電極２３を半田からなる接合部８３を介して配線基板７の配線パターン７３と接合して電気的に接続するとともに、伝熱プレート２５を半田からなる接合部８５を介して配線基板７の配線パターン７５と接合して電気的に接続し且つ熱結合させることにより、ＬＥＤチップ１で発生した熱は上述の接合部１２を通して伝熱プレート２５へ直接伝熱され伝熱プレート２５で拡散しつつ配線基板７へ伝熱されて外部へ放熱される。なお、配線基板７は、Ｃｕ製あるはＡｌ製の金属板７１上に絶縁層７２が形成され、絶縁層７２上に配線パターン７３，７５が形成された金属ベース基板（金属ベースプリント配線板）により構成されているが、金属ベース基板に限らず、例えば、ガラスエポキシ樹脂製の絶縁性基板上に配線パターン７３，７５が形成されたものでもよい。   As described above, the mounting substrate 2 has the external connection electrode 23 formed on the other surface side, and the heat transfer plate 25 also serves as the external connection electrode, so that a pair of wiring patterns 73 and 75 are formed. When mounting on the wiring board 7, the former external connection electrode 23 is joined and electrically connected to the wiring pattern 73 of the wiring board 7 via the joint 83 made of solder, and the heat transfer plate 25 is attached to the wiring board 7. The heat generated in the LED chip 1 is transmitted through the joint 12 described above by being electrically connected and thermally coupled to the wiring pattern 75 of the wiring board 7 through the joint 85 made of solder. Heat is transferred directly to the wiring board 7 while being diffused by the heat transfer plate 25 and is radiated to the outside. The wiring substrate 7 is a metal base substrate (metal base printed wiring board) in which an insulating layer 72 is formed on a metal plate 71 made of Cu or Al, and wiring patterns 73 and 75 are formed on the insulating layer 72. However, the invention is not limited to a metal base substrate, and for example, wiring patterns 73 and 75 may be formed on an insulating substrate made of glass epoxy resin.

また、ＬＥＤチップ１およびボンディングワイヤ１４は、上述の封止部３により封止されている。ここにおいて、封止部３は、実装基板２の上記一表面側においてＬＥＤチップ１およびボンディングワイヤ１４を覆う凸レンズ状に形成されており、光出射面が光学部材１５の光入射面と密着している。しかして、本実施形態の発光装置Ａでは、ＬＥＤチップ１と色変換部材４との間に、ＬＥＤチップ１を封止した透光性材料からなる封止部３が設けられているので、ＬＥＤチップ１の光取り出し面が接する媒質が空気の場合に比べてＬＥＤチップ１と当該ＬＥＤチップ１の光取り出し面が接する媒質との屈折率差が小さくなり、ＬＥＤチップ１からの光取り出し効率が向上し、結果的に発光装置Ａ全体としての光取り出し効率が向上する。なお、本実施形態では、封止部３の透光性材料としてシリコーン樹脂を採用しているが、シリコーン樹脂に限らず、エポキシ樹脂などを採用してもよい。   Further, the LED chip 1 and the bonding wire 14 are sealed by the sealing portion 3 described above. Here, the sealing portion 3 is formed in a convex lens shape covering the LED chip 1 and the bonding wire 14 on the one surface side of the mounting substrate 2, and the light emitting surface is in close contact with the light incident surface of the optical member 15. Yes. Therefore, in the light emitting device A of the present embodiment, the sealing portion 3 made of a translucent material that seals the LED chip 1 is provided between the LED chip 1 and the color conversion member 4. The refractive index difference between the LED chip 1 and the medium with which the light extraction surface of the LED chip 1 contacts is smaller than when the medium with which the light extraction surface of the chip 1 is in contact is air, and the light extraction efficiency from the LED chip 1 is improved. As a result, the light extraction efficiency of the light emitting device A as a whole is improved. In the present embodiment, a silicone resin is employed as the translucent material of the sealing portion 3, but not limited to the silicone resin, an epoxy resin or the like may be employed.

上述の光学部材１５は、透光性材料（例えば、シリコーン樹脂など）により形成されている。ここで、本実施形態では、光学部材１５をシリコーン樹脂により形成してあるので、光学部材１５と封止部３との屈折率差および線膨張率差を小さくすることができる。   The above-described optical member 15 is formed of a translucent material (for example, a silicone resin). Here, in this embodiment, since the optical member 15 is formed of silicone resin, the difference in refractive index and the linear expansion coefficient between the optical member 15 and the sealing portion 3 can be reduced.

ところで、光学部材１５は、光出射面が、光入射面から入射した光を光出射面と上述の空気層１６との境界で全反射させない凸曲面状に形成されている。ここで、光学部材１５は、光出射面が球面（楕円球面も含む）の一部により形成されており、当該球面の中心がＬＥＤチップ１の光軸上に位置するように配置されている。したがって、ＬＥＤチップ１から放射され光学部材１５の光入射面に入射された光が光出射面と空気層１６との境界で全反射されることなく色変換部材４まで到達しやすくなり、全光束を高めることができる。なお、ＬＥＤチップ１の側面から放射された光は封止部３および光学部材１５および空気層１６を伝搬して色変換部材４まで到達し色変換部材４の蛍光体を励起したり蛍光体には衝突せずに色変換部材４を透過したりする。また、光学部材１５は、位置によらず法線方向に沿った肉厚が一様となるように形成されている。   By the way, the optical member 15 has a light exit surface formed in a convex curved surface shape that does not totally reflect the light incident from the light incident surface at the boundary between the light exit surface and the air layer 16 described above. Here, the optical member 15 has a light exit surface formed by a part of a spherical surface (including an elliptical spherical surface), and is arranged so that the center of the spherical surface is located on the optical axis of the LED chip 1. Therefore, the light emitted from the LED chip 1 and incident on the light incident surface of the optical member 15 can easily reach the color conversion member 4 without being totally reflected at the boundary between the light emitting surface and the air layer 16, and the total luminous flux. Can be increased. The light emitted from the side surface of the LED chip 1 propagates through the sealing portion 3, the optical member 15, and the air layer 16 to reach the color conversion member 4 to excite the phosphor of the color conversion member 4 or to the phosphor. Passes through the color conversion member 4 without colliding. Moreover, the optical member 15 is formed so that the thickness along the normal direction is uniform regardless of the position.

色変換部材４は、シリコーン樹脂からなる透光性材料にＬＥＤチップ１から放射された青色光によって励起されて黄色光を放射する粒子状の黄色蛍光体を分散させた混合材料を用いてドーム状に形成されている。なお、色変換部材４の材料として用いる透光性材料は、シリコーン樹脂に限らず、例えば、アクリル樹脂、ガラス、有機成分と無機成分とがｎｍレベルもしくは分子レベルで混合、結合した有機・無機ハイブリッド材料などを採用してもよい。また、色変換部材４の材料として用いる透光性材料に含有させる蛍光体も黄色蛍光体に限らず、色調整や演色性を高めるなどの目的で複数種類の蛍光体を用いてもよく、例えば、赤色蛍光体と緑色蛍光体とを用いることで演色性の高い白色光を得ることができる。ここで、複数種類の蛍光体を用いる場合には必ずしも発光色の異なる蛍光体の組み合わせに限らず、例えば、発光色はいずれも黄色で発光スペクトルの異なる複数種類の蛍光体を組み合わせてもよい。   The color conversion member 4 is formed in a dome shape using a mixed material in which a particulate yellow phosphor that is excited by blue light emitted from the LED chip 1 and emits yellow light is dispersed in a translucent material made of silicone resin. Is formed. The translucent material used as the material of the color conversion member 4 is not limited to a silicone resin. For example, an organic / inorganic hybrid in which an acrylic resin, glass, an organic component and an inorganic component are mixed and combined at the nm level or the molecular level. Materials etc. may be adopted. Further, the phosphor to be contained in the translucent material used as the material of the color conversion member 4 is not limited to the yellow phosphor, and a plurality of types of phosphors may be used for the purpose of improving color adjustment and color rendering. White light with high color rendering properties can be obtained by using a red phosphor and a green phosphor. Here, when a plurality of types of phosphors are used, the phosphor is not necessarily a combination of phosphors having different emission colors, and for example, a plurality of types of phosphors having an emission color of yellow and different emission spectra may be combined.

ところで、色変換部材４は、実装基板２の上記一表面側が開口され光入射面および光出射面それぞれが球面の一部からなるドーム状に形成されており、実装基板２を内包する形で実装基板２に接合されている。具体的には、色変換部材４および実装基板２それぞれの平面視における外周形状が円形状であり、平面視において色変換部材４の外周線よりも実装基板２の外周線が内側に位置し色変換部材４の開口端（実装基板２側の端縁）が実装基板２の外周部とシリコーン樹脂などの接着剤により接合されている。ここにおいて、色変換部材４の開口端には、実装基板２の外周部から突設された環状の突部２ｂが係合する切欠部４ｂが形成されている。なお、実装基板２の環状の突部２ｂは、色変換部材４および光学部材１５の位置決め部を兼ねるとともに、上述の封止部３の形成時に封止部３の透光性材料が実装基板２の側面へ流れるのを防止する堰部として機能する。また、本実施形態では、実装基板２の外周形状が円形状となっているが、円形状に限らず、多角形状でもよい。   By the way, the color conversion member 4 is mounted in such a manner that the one surface side of the mounting substrate 2 is opened and each of the light incident surface and the light emitting surface is formed in a dome shape formed of a part of a spherical surface. Bonded to the substrate 2. Specifically, the outer peripheral shape of each of the color conversion member 4 and the mounting substrate 2 in a plan view is circular, and the outer peripheral line of the mounting substrate 2 is located on the inner side of the outer periphery of the color conversion member 4 in the plan view. The opening end (end edge on the mounting substrate 2 side) of the conversion member 4 is joined to the outer peripheral portion of the mounting substrate 2 by an adhesive such as silicone resin. Here, at the opening end of the color conversion member 4, a notch 4 b that engages with an annular protrusion 2 b that protrudes from the outer periphery of the mounting substrate 2 is formed. The annular protrusion 2b of the mounting substrate 2 also serves as a positioning portion for the color conversion member 4 and the optical member 15, and the translucent material of the sealing portion 3 is mounted on the mounting substrate 2 when the sealing portion 3 is formed. It functions as a weir part that prevents it from flowing to the side surface of the water. In the present embodiment, the outer peripheral shape of the mounting substrate 2 is circular, but is not limited to a circular shape, and may be a polygonal shape.

以上説明した本実施形態の発光装置Ａでは、平面視において色変換部材４の外周線よりも実装基板２の外周線が内側に位置し色変換部材４の開口端が実装基板２の外周部と接合されているので、色変換部材４の周部から放射された光が実装基板２に吸収されることなく外部へ出射されることとなり、発光装置Ａ全体としての外部への光取り出し効率を向上させることができる。   In the light-emitting device A of the present embodiment described above, the outer peripheral line of the mounting substrate 2 is located inside the outer peripheral line of the color conversion member 4 in plan view, and the open end of the color conversion member 4 is connected to the outer peripheral portion of the mounting substrate 2. Since it is joined, the light emitted from the peripheral portion of the color conversion member 4 is emitted to the outside without being absorbed by the mounting substrate 2, and the light extraction efficiency as a whole of the light emitting device A is improved. Can be made.

（実施形態２）
本実施形態の発光装置Ａの基本構成は実施形態１と略同じであり、ＬＥＤチップ１として一表面側に各電極が形成されたものを用い、図２に示すように、ＬＥＤチップ１が、当該ＬＥＤチップ１と伝熱プレート２５との線膨張率差に起因してＬＥＤチップ１に働く応力を緩和するサブマウント部材３０を介して伝熱プレート２５のマウント部２５ｂに搭載されている点などが相違する。なお、実施形態１と同様の構成要素には同一の符号を付して説明を適宜省略する。 (Embodiment 2)
The basic configuration of the light emitting device A of the present embodiment is substantially the same as that of the first embodiment, and the LED chip 1 is formed by forming each electrode on one surface side, and as shown in FIG. It is mounted on the mount portion 25b of the heat transfer plate 25 via a submount member 30 that relieves stress acting on the LED chip 1 due to the difference in linear expansion coefficient between the LED chip 1 and the heat transfer plate 25. Is different. In addition, the same code | symbol is attached | subjected to the component similar to Embodiment 1, and description is abbreviate | omitted suitably.

サブマウント部材３０は、ＬＥＤチップ１のチップサイズよりも大きなサイズの矩形板状に形成されている。ここにおいて、サブマウント部材３０は、上記応力を緩和する機能だけでなく、ＬＥＤチップ１で発生した熱を伝熱プレート２５のマウント部２５ｂにおいてＬＥＤチップ１のチップサイズよりも広い範囲に伝熱させる熱伝導機能を有している。したがって、本実施形態の発光装置Ａでは、ＬＥＤチップ１がサブマウント部材３０を介して伝熱プレート２５のマウント部２５ｂに搭載されているので、ＬＥＤチップ１で発生した熱をサブマウント部材３０および伝熱プレート２５を介して効率良く放熱させることができるとともに、ＬＥＤチップ１と伝熱プレート２５との線膨張率差に起因してＬＥＤチップ１に働く応力を緩和することができる。なお、サブマウント部材３０は、上述の熱伝導機能を有しており、伝熱プレート２５のマウント部２５ｂにおけるＬＥＤチップ１側の表面の面積はＬＥＤチップ１におけるマウント部２５ｂ側の表面の面積よりも十分に大きいことが望ましい。   The submount member 30 is formed in a rectangular plate shape having a size larger than the chip size of the LED chip 1. Here, the submount member 30 not only has a function of relieving the stress, but also transfers heat generated in the LED chip 1 to a range wider than the chip size of the LED chip 1 in the mount portion 25b of the heat transfer plate 25. It has a heat conduction function. Therefore, in the light emitting device A of the present embodiment, since the LED chip 1 is mounted on the mount portion 25b of the heat transfer plate 25 via the submount member 30, the heat generated in the LED chip 1 is transferred to the submount member 30 and Heat can be efficiently radiated through the heat transfer plate 25, and stress acting on the LED chip 1 due to a difference in linear expansion coefficient between the LED chip 1 and the heat transfer plate 25 can be reduced. The submount member 30 has the above-described heat conduction function, and the surface area of the LED chip 1 side in the mount portion 25b of the heat transfer plate 25 is larger than the surface area of the LED chip 1 on the mount portion 25b side. Is also sufficiently large.

本実施形態では、サブマウント部材３０の材料として熱伝導率が比較的高く且つ絶縁性を有するＡｌＮを採用し、サブマウント部材３０の厚み方向の両面にＡｕ層をめっきしてあり、ＬＥＤチップ１とサブマウント部材３０とが半田からなる接合部１２により接合され、サブマウント部材３０と伝熱プレート２５のマウント部２５ｂとが半田からなる接合部３１により接合されている。なお、サブマウント部材３０の材料はＡｌＮに限らず、例えば、熱伝導率の高いセラミックやＳｉＣなどを採用してもよい。また、サブマウント部材３０の厚みは０．１μｍに設定してあるが、この厚みは一例であって特に限定するものではない。   In the present embodiment, AlN having a relatively high thermal conductivity and insulation is adopted as the material of the submount member 30, and Au layers are plated on both surfaces in the thickness direction of the submount member 30. The submount member 30 and the submount member 30 are joined together by a joining portion 12 made of solder, and the submount member 30 and the mount portion 25b of the heat transfer plate 25 are joined by a joining portion 31 made of solder. The material of the submount member 30 is not limited to AlN, and for example, ceramic or SiC having high thermal conductivity may be employed. Moreover, although the thickness of the submount member 30 is set to 0.1 μm, this thickness is an example and is not particularly limited.

また、実装基板２は、上記一表面側にＬＥＤチップ１の各電極それぞれがボンディングワイヤ１４を介して電気的に接続される配線パターン２１が２つ設けられており、上記他表面側に外部接続用電極２３が２つ設けられている。   In addition, the mounting substrate 2 is provided with two wiring patterns 21 on the one surface side where each electrode of the LED chip 1 is electrically connected via the bonding wire 14, and external connection is made on the other surface side. Two working electrodes 23 are provided.

本実施形態の発光装置Ａは、実施形態１と同様、平面視において色変換部材４の外周線よりも実装基板２の外周線が内側に位置し色変換部材４の開口端が実装基板２の外周部と接合されているので、色変換部材４の周部から放射された光が実装基板２に吸収されることなく外部へ出射されることとなり、発光装置Ａ全体としての外部への光取り出し効率を向上させることができる。   As in the first embodiment, the light emitting device A of the present embodiment has the outer peripheral line of the mounting substrate 2 positioned on the inner side of the outer peripheral line of the color conversion member 4 in plan view, and the open end of the color conversion member 4 is the mounting substrate 2. Since it is joined to the outer peripheral portion, the light emitted from the peripheral portion of the color conversion member 4 is emitted to the outside without being absorbed by the mounting substrate 2, and the light is extracted to the outside as the entire light emitting device A. Efficiency can be improved.

なお、本実施形態では、ＬＥＤチップ１として一表面側に各電極が形成されたものを用いているが、実施形態１と同様にＬＥＤチップ１として厚み方向の両面に電極が形成されたものを用いる場合には、サブマウント部材３０におけるＬＥＤチップ１側のＡｕ層と実装基板２の配線パターン２１とをボンディングワイヤ１４を介して電気的に接続することにより、ＬＥＤチップ１におけるサブマウント部材３０側の電極を配線パターン２１と電気的に接続するようにすればよい。また、ＬＥＤチップ１として厚み方向の両面に電極が形成されたものを用いる場合、実施形態１と同様に伝熱プレート２５が外部接続用電極を兼ねる実装基板２を用い、サブマウント部材３０に厚み方向の両面のＡｕ層同士を電気的に接続するビアを設けるようにしてもよい。   In this embodiment, the LED chip 1 is used in which each electrode is formed on one surface side. However, as in the first embodiment, the LED chip 1 in which electrodes are formed on both surfaces in the thickness direction is used. When used, the Au layer on the LED chip 1 side of the submount member 30 and the wiring pattern 21 of the mounting substrate 2 are electrically connected via the bonding wires 14, so that the submount member 30 side of the LED chip 1 is used. These electrodes may be electrically connected to the wiring pattern 21. Further, when the LED chip 1 having electrodes formed on both surfaces in the thickness direction is used, the mounting plate 2 in which the heat transfer plate 25 also serves as an external connection electrode is used as in the first embodiment, and the submount member 30 has a thickness. Vias that electrically connect the Au layers on both sides in the direction may be provided.

（実施形態３）
本実施形態の発光装置Ａの基本構成は実施形態１と略同じであり、図３に示すように、伝熱プレート２５に実施形態１で説明したマウント部２５ｂ（図１（ｂ）参照）が設けられておらず、実装基板２の上記一表面側に、ＬＥＤチップ１における実装基板２側の電極が接合される配線パターン２１（要するに、ＬＥＤチップ１が搭載されるダイパッド部）が設けられており、当該配線パターン２１がビア２２ａを介して伝熱プレート２５と電気的に接続されている点が相違する。なお、実施形態１と同様の構成要素には同一の符号を付して説明を適宜省略する。 (Embodiment 3)
The basic configuration of the light-emitting device A of the present embodiment is substantially the same as that of the first embodiment. As shown in FIG. 3, the heat transfer plate 25 includes the mount portion 25b described in the first embodiment (see FIG. 1B). A wiring pattern 21 (in short, a die pad portion on which the LED chip 1 is mounted) is provided on the one surface side of the mounting substrate 2 that is not provided, and the electrode on the mounting substrate 2 side of the LED chip 1 is bonded. The wiring pattern 21 is electrically connected to the heat transfer plate 25 through the via 22a. In addition, the same code | symbol is attached | subjected to the component similar to Embodiment 1, and description is abbreviate | omitted suitably.

しかして、本実施形態の発光装置Ａは、実施形態１と同様、平面視において色変換部材４の外周線よりも実装基板２の外周線が内側に位置し色変換部材４の開口端が実装基板２の外周部と接合されているので、色変換部材４の周部から放射された光が実装基板２に吸収されることなく外部へ出射されることとなり、発光装置Ａ全体としての外部への光取り出し効率を向上させることができる。なお、本実施形態の発光装置Ａでは、ＬＥＤチップ１で発生した熱が実装基板２の上記一表面と埋込穴２４ａの内底面との間の薄肉部を通して伝熱プレート２５へ伝熱されるので、熱抵抗を小さくする観点から上記薄肉部の厚みは薄い方が望ましい。   Accordingly, in the light emitting device A of the present embodiment, as in the first embodiment, the outer peripheral line of the mounting substrate 2 is located on the inner side of the outer peripheral line of the color conversion member 4 in plan view, and the open end of the color conversion member 4 is mounted. Since it is joined to the outer peripheral portion of the substrate 2, the light emitted from the peripheral portion of the color conversion member 4 is emitted to the outside without being absorbed by the mounting substrate 2, so that the light emitting device A as a whole is exposed to the outside. The light extraction efficiency can be improved. In the light emitting device A of the present embodiment, the heat generated in the LED chip 1 is transferred to the heat transfer plate 25 through the thin portion between the one surface of the mounting substrate 2 and the inner bottom surface of the embedded hole 24a. From the viewpoint of reducing the thermal resistance, it is desirable that the thickness of the thin portion is thinner.

（実施形態４）
本実施形態の発光装置Ａの基本構成は実施形態１と略同じであり、図４に示すように、伝熱プレート２５の上記他表面側（つまり、実装基板２の上記他表面側と同じ面側）に、中央から外側に向かって幅の広くなる複数の溝２５ｄが放射状に形成されている点が相違する。ここにおいて、各溝２５ｄは、伝熱プレート２５の上記他表面の中央から外側に向かって幅寸法が徐々に大きくなるとともに深さ寸法も徐々に大きくなっている。なお、実施形態１と同様の構成要素には同一の符号を付して説明を適宜省略する。 (Embodiment 4)
The basic configuration of the light emitting device A of the present embodiment is substantially the same as that of the first embodiment, and as shown in FIG. 4, the other surface side of the heat transfer plate 25 (that is, the same surface as the other surface side of the mounting substrate 2). The difference is that a plurality of grooves 25d that are wider from the center toward the outside are formed radially. Here, each groove 25d has a width dimension that gradually increases from the center of the other surface of the heat transfer plate 25 to the outside and a depth dimension that gradually increases. In addition, the same code | symbol is attached | subjected to the component similar to Embodiment 1, and description is abbreviate | omitted suitably.

ところで、実施形態１で説明したように実装基板２の伝熱プレート２５を配線基板７の配線パターン７５に半田からなる接合部８５により接合した構成では、伝熱プレート２５の上記他表面が平面であり外部接続用電極２３に比べて面積がかなり大きいので、接合部８５にボイドが発生する恐れがあり、接合部８５にボイドがあると、温度サイクルがかかった時に実装基板２と配線基板７との線膨張率差によって生じる応力変化に起因して、接合部８５に、当該接合部８５のボイドが基点となってクラックが発生することがある。   By the way, in the configuration in which the heat transfer plate 25 of the mounting substrate 2 is bonded to the wiring pattern 75 of the wiring substrate 7 by the bonding portion 85 made of solder as described in the first embodiment, the other surface of the heat transfer plate 25 is flat. Since the area is considerably larger than that of the external connection electrode 23, there is a possibility that a void is generated in the joint 85. If there is a void in the joint 85, the mounting substrate 2 and the wiring board 7 Due to a change in stress caused by the difference in linear expansion coefficient, cracks may occur in the joint portion 85 with the void of the joint portion 85 as a base point.

これに対して、本実施形態の発光装置Ａでは、伝熱プレート２５の上記他表面側に、中央から外側に向かって幅の広くなる溝２５ｄが形成されているので、発光装置Ａを配線基板７に実装して用いるにあたって、図４（ｃ）に示すように伝熱プレート２５を配線基板７の配線パターン７５に半田８５’により接合する際に、半田８５’の溶融から硬化の過程で生じるフラックスなどのガス８６および気泡（図示せず）が溝２５ｄに沿って外部に抜けやすくなり、硬化後の半田８５’からなる接合部８５の内部にボイドが生じるのを抑制することができ、結果的に、ＬＥＤチップ１と配線基板７との間の熱抵抗のばらつきを小さくすることができるとともに、温度サイクルがかかった時に実装基板２と配線基板７との線膨張率差によって生じる応力変化に対する接合部８５の耐性が高くなって信頼性が向上する。なお、実施形態２，３の発光装置Ａにおける伝熱プレート２５の上記他表面に、本実施形態で説明した複数の溝２５ｄを形成してもよいことは勿論である。   On the other hand, in the light emitting device A of the present embodiment, the other surface side of the heat transfer plate 25 is formed with a groove 25d that becomes wider from the center toward the outside. When the heat transfer plate 25 is joined to the wiring pattern 75 of the wiring board 7 with the solder 85 ′ as shown in FIG. 4C, the solder 85 ′ is melted and hardened as shown in FIG. Gas 86 such as flux and air bubbles (not shown) can easily escape to the outside along the groove 25d, and it is possible to suppress the formation of voids inside the joint portion 85 made of the cured solder 85 ′. In particular, the variation in thermal resistance between the LED chip 1 and the wiring board 7 can be reduced, and it is caused by the difference in linear expansion coefficient between the mounting board 2 and the wiring board 7 when a temperature cycle is applied. Resistance of the joint portion 85 thereby improving reliability leading to high power variation. Of course, the plurality of grooves 25d described in the present embodiment may be formed on the other surface of the heat transfer plate 25 in the light emitting device A of the second and third embodiments.

（実施形態５）
本実施形態の発光装置Ａの基本構成は実施形態１と略同じであり、図５に示すように、伝熱プレート２５のマウント部２５ｂにおけるＬＥＤチップ１の搭載領域の周囲に短絡防止溝２５ｃが形成されている点が相違する。なお、実施形態１と同様の構成要素には同一の符号を付して説明を適宜省略する。 (Embodiment 5)
The basic configuration of the light-emitting device A of the present embodiment is substantially the same as that of the first embodiment. As shown in FIG. 5, a short-circuit prevention groove 25 c is provided around the LED chip 1 mounting region in the mount portion 25 b of the heat transfer plate 25. It differs in that it is formed. In addition, the same code | symbol is attached | subjected to the component similar to Embodiment 1, and description is abbreviate | omitted suitably.

しかして、本実施形態の発光装置Ａでは、ＬＥＤチップ１をマウント部２５ｂの搭載領域に半田により接合する際にＬＥＤチップ１直下から溢れ出た余分な半田１２ｃが短絡防止溝２５ｃに溜まるので、余分な半田１２ｃが実装基板２の上記一表面側の配線パターン２１上まで流れ出ることによる短絡を防止することができる。なお、実施形態４の発光装置Ａにおいても、マウント部２５ｂにおけるＬＥＤチップ１の搭載領域の周囲に短絡防止溝２５ｃを設けてもよいし、実施形態２の発光装置Ａにおいて、マウント部２５ｂにおけるサブマウント部材３０の搭載領域の周囲に短絡防止溝２５を設けてもよい。   Therefore, in the light emitting device A of the present embodiment, when the LED chip 1 is joined to the mounting region of the mount portion 25b by solder, excess solder 12c overflowing from immediately below the LED chip 1 is accumulated in the short-circuit prevention groove 25c. A short circuit caused by excess solder 12c flowing out onto the wiring pattern 21 on the one surface side of the mounting substrate 2 can be prevented. In the light emitting device A of the fourth embodiment, the short-circuit prevention groove 25c may be provided around the mounting area of the LED chip 1 in the mount portion 25b. In the light emitting device A of the second embodiment, the sub-mount in the mount portion 25b may be provided. A short-circuit prevention groove 25 may be provided around the mounting region of the mount member 30.

（実施形態６）
本実施形態の発光装置Ａの基本構成は実施形態１と略同じであり、図６に示すように、色変換部材４が箱型のドーム状に形成されている点などが相違する。なお、実施形態１と同様の構成要素には同一の符号を付して説明を適宜省略する。 (Embodiment 6)
The basic configuration of the light emitting device A of the present embodiment is substantially the same as that of the first embodiment, and is different in that the color conversion member 4 is formed in a box-shaped dome shape as shown in FIG. In addition, the same code | symbol is attached | subjected to the component similar to Embodiment 1, and description is abbreviate | omitted suitably.

本実施形態における色変換部材４は、シリコーン樹脂からなる透光性材料にＬＥＤチップ１から放射された青色光によって励起されて黄色光を放射する粒子状の黄色蛍光体を分散させた混合材料を用いて円筒状に形成された色変換部４１と、液晶ポリマー系の樹脂あるいはセラミックにより形成され色変換部４１の一端側の開口面を閉塞する形で配設されてＬＥＤチップ１からの光を拡散反射する円板状の反射部４２とを結合することにより形成されている。したがって、ＬＥＤチップ１から放射され封止部３および光学部材６および空気層１１を伝搬する光は、色変換部４１に直接入射したり、反射部４２で反射されて色変換部４１に入射する。ここにおいて、反射部４２として、Ａｌ板の表面に高反射の白塗装を施したものや、Ａｌ板の表面にＡｇ蒸着などおによる鏡面仕上げを施したものを用いてもよく、これらを用いた場合には、色変換部材４の色変換部４１で発生した熱が反射部４２から効率良く放熱されるので、色変換部材４の変換効率が向上するとともに信頼性が向上する。なお、色変換部４１は、実装基板２から離れるにつれて内径および外径が徐々に小さくなるテーパを有する円筒状に形成されている。また、反射部４２の形状は、図７に示すように、ＬＥＤチップ１に近づくにつれて断面積が小さく錐状に形成されていてもよい。   The color conversion member 4 in the present embodiment is a mixed material in which a particulate yellow phosphor that emits yellow light when excited by blue light emitted from the LED chip 1 is dispersed in a translucent material made of silicone resin. The color conversion part 41 formed into a cylindrical shape by using the liquid crystal polymer resin or ceramic is disposed so as to close the opening surface on one end side of the color conversion part 41, and the light from the LED chip 1 is used. It is formed by coupling a disk-shaped reflecting portion 42 that diffusely reflects. Therefore, the light emitted from the LED chip 1 and propagating through the sealing unit 3, the optical member 6, and the air layer 11 directly enters the color conversion unit 41 or is reflected by the reflection unit 42 and enters the color conversion unit 41. . Here, as the reflecting portion 42, a surface of the Al plate that has been subjected to highly reflective white coating or a surface of the Al plate that has been subjected to a mirror finish such as Ag vapor deposition may be used. In this case, since the heat generated in the color conversion unit 41 of the color conversion member 4 is efficiently radiated from the reflection unit 42, the conversion efficiency of the color conversion member 4 is improved and the reliability is improved. The color conversion unit 41 is formed in a cylindrical shape having a taper in which the inner diameter and the outer diameter gradually decrease as the distance from the mounting substrate 2 increases. In addition, as shown in FIG. 7, the shape of the reflective portion 42 may be formed in a cone shape with a smaller cross-sectional area as it approaches the LED chip 1.

しかして、本実施形態の発光装置Ａは、実施形態１と同様、平面視において色変換部材４の外周線よりも実装基板２の外周線が内側に位置し色変換部材４の開口端が実装基板２の外周部と接合されているので、色変換部材４の周部から放射された光が実装基板２に吸収されることなく外部へ出射されることとなり、発光装置Ａ全体としての外部への光取り出し効率を向上させることができる。なお、他の実施形態２〜５における色変換部材４の代わりに、本実施形態における色変換部材４を用いてもよい。   Accordingly, in the light emitting device A of the present embodiment, as in the first embodiment, the outer peripheral line of the mounting substrate 2 is located on the inner side of the outer peripheral line of the color conversion member 4 in plan view, and the open end of the color conversion member 4 is mounted. Since it is joined to the outer peripheral portion of the substrate 2, the light emitted from the peripheral portion of the color conversion member 4 is emitted to the outside without being absorbed by the mounting substrate 2, so that the light emitting device A as a whole is exposed to the outside. The light extraction efficiency can be improved. In addition, you may use the color conversion member 4 in this embodiment instead of the color conversion member 4 in other Embodiments 2-5.

（実施形態７）
本実施形態では、実施形態１にて説明した発光装置Ａを備えた照明器具を例示する。 (Embodiment 7)
In this embodiment, the lighting fixture provided with the light-emitting device A demonstrated in Embodiment 1 is illustrated.

本実施形態の照明器具は、図８に示すように、発光装置Ａと、発光装置Ａが実装された配線基板７と、発光装置Ａから放射される光の配光を制御する反射鏡５と、配線基板７、発光装置Ａおよび反射鏡５が収納される有底円筒状の器具本体９とを備えてなる。ここにおいて、反射鏡５は、椀状に形成され、底部に、発光装置Ａが挿入される開口部５ａを有しており、発光装置Ａの周囲を囲む形で器具本体９内に配置されている。また、器具本体９は、金属材料（例えば、Ａｌなど）により形成されている。   As shown in FIG. 8, the lighting fixture of the present embodiment includes a light emitting device A, a wiring board 7 on which the light emitting device A is mounted, and a reflecting mirror 5 that controls the light distribution of light emitted from the light emitting device A. And a bottomed cylindrical instrument body 9 in which the wiring board 7, the light emitting device A, and the reflecting mirror 5 are housed. Here, the reflecting mirror 5 is formed in a bowl shape, has an opening 5a into which the light emitting device A is inserted at the bottom, and is disposed in the instrument body 9 so as to surround the periphery of the light emitting device A. Yes. The instrument body 9 is made of a metal material (for example, Al).

また、本実施形態の照明器具は、透光性材料（例えば、アクリル樹脂、ガラスなど）により形成され反射鏡５の開口面を閉塞する形で配設される円板状の透光性カバー８と、器具本体９の開口縁に形成された溝部９ｂの底面との間に透光性カバー８の周部と反射鏡５の開口縁から外方へ延設された外鍔部５ｃとを重ねた形で保持する円環状の保持枠１０とを備えている。ここで、保持枠１０は、外郭９に対して接着剤により固定されている。   In addition, the lighting fixture of the present embodiment is a disc-shaped translucent cover 8 that is formed of a translucent material (for example, acrylic resin, glass, etc.) and is disposed so as to close the opening surface of the reflecting mirror 5. And a peripheral portion of the translucent cover 8 and an outer flange portion 5c extending outward from the opening edge of the reflecting mirror 5 between the bottom surface of the groove portion 9b formed at the opening edge of the instrument body 9 And an annular holding frame 10 held in a round shape. Here, the holding frame 10 is fixed to the outer shell 9 with an adhesive.

また、配線基板７は、シリカやアルミナなどのフィラーからなる充填材を含有し且つ加熱時に低粘度化する樹脂シート（例えば、溶融シリカを高充填したエポキシ樹脂シートのような有機グリーンシート）を用い、当該樹脂シートにより配線基板７と器具本体９の底壁とを接合し、更に複数本の固定ねじ９１により固定してある。上記樹脂シートは電気絶縁性を有するとともに熱伝導率が高く、しかも、加熱時の流動性が高く凹凸面への密着性が高いので、上記樹脂シートと配線基板７および器具本体９の底壁との間に空隙が発生するのを防止することができて、密着不足による熱抵抗の増大やばらつきの発生を防止することができ、ゴムシート状の放熱シートを用いる場合に比べて、ＬＥＤチップ１から器具本体９までの熱抵抗を小さくすることができて放熱性が向上するとともに熱抵抗のばらつきが小さくなり、ＬＥＤチップ１のジャンクション温度の温度上昇を抑制できるから、入力電力を大きくでき、光出力の高出力化を図れる。   Further, the wiring board 7 uses a resin sheet containing a filler made of a filler such as silica or alumina and having a low viscosity when heated (for example, an organic green sheet such as an epoxy resin sheet highly filled with fused silica). The wiring board 7 and the bottom wall of the instrument body 9 are joined by the resin sheet, and further fixed by a plurality of fixing screws 91. Since the resin sheet has electrical insulation and high thermal conductivity, and has high fluidity during heating and high adhesion to an uneven surface, the resin sheet, the wiring board 7 and the bottom wall of the instrument body 9 It is possible to prevent the occurrence of voids between the two, and it is possible to prevent an increase in thermal resistance and variations due to insufficient adhesion, and the LED chip 1 can be compared with a case where a rubber sheet-like heat dissipation sheet is used. The heat resistance from the tool body 9 to the fixture body 9 can be reduced, the heat dissipation is improved, the variation in the heat resistance is reduced, and the temperature rise of the junction temperature of the LED chip 1 can be suppressed, so that the input power can be increased, the light High output can be achieved.

反射鏡５は、色変換部材４の光出射面から放射されて入射した光を透光性カバー８側へ反射させ狭角配光が得られるように内側面の形状が設計されており、当該内側面がドーム状の色変換部材４の頂点を焦点とする放物面状に形成されている。なお、反射鏡５の内周面の形状は特に限定するものではなく、反射鏡５は、所望の配光特性に応じて、ＬＥＤチップ１の光軸方向においてＬＥＤチップ１から離れるにつれて開口面積が徐々に大きくなる椀状の形状に形成されていればよい。   The reflecting mirror 5 is designed to have a shape on the inner surface so that light emitted from the light exit surface of the color conversion member 4 is reflected toward the light-transmitting cover 8 and a narrow-angle light distribution is obtained. The inner surface is formed in a parabolic shape with the vertex of the dome-shaped color conversion member 4 as a focal point. In addition, the shape of the inner peripheral surface of the reflecting mirror 5 is not particularly limited, and the reflecting mirror 5 has an opening area as the distance from the LED chip 1 increases in the optical axis direction of the LED chip 1 according to desired light distribution characteristics. What is necessary is just to be formed in the bowl-shaped shape which becomes large gradually.

反射鏡５の材料としては、例えば、ＬＥＤチップ１や蛍光体から放射される光の反射率が高い金属（例えば、Ａｌなど）などを採用すればよく、本実施形態では、Ａｌを採用している。また、反射鏡５の内側面は、ＡｌやＡｇなどを蒸着したり、白色塗装したり、拡散反射面としたりすることで所望の反射率を確保している。なお、反射鏡５の材料は金属に限らず、高耐熱の樹脂（例えば、ＰＢＴなど）などを採用してもよい。   As a material of the reflecting mirror 5, for example, a metal (for example, Al) having a high reflectance of light emitted from the LED chip 1 or the phosphor may be employed. In this embodiment, Al is employed. Yes. Further, the inner side surface of the reflecting mirror 5 ensures a desired reflectivity by evaporating Al, Ag, or the like, or coating it with white or using a diffuse reflection surface. The material of the reflecting mirror 5 is not limited to a metal, and a high heat-resistant resin (for example, PBT) may be used.

なお、本実施形態における反射鏡５は、外鍔部５ｃが器具本体９と保持枠１０との間に透光性カバー８の周部を介して保持され、実装基板２や配線基板７へ直接固定する必要がないから、反射鏡５を実装基板２や配線基板７に直接固定する場合に比べて、反射鏡５の機械的強度の制約が少なくなるとともに実装基板２と配線基板７との接合部８３，８５に機械的ストレスを与えるのを防止することができる。   In the reflecting mirror 5 in this embodiment, the outer flange portion 5 c is held between the instrument main body 9 and the holding frame 10 via the peripheral portion of the translucent cover 8, and directly to the mounting substrate 2 and the wiring substrate 7. Since it is not necessary to fix the reflecting mirror 5 to the mounting substrate 2 or the wiring substrate 7, the mechanical strength of the reflecting mirror 5 is less restricted and the bonding between the mounting substrate 2 and the wiring substrate 7 is reduced. It is possible to prevent the parts 83 and 85 from being subjected to mechanical stress.

以上説明した本実施形態の照明器具では、実施形態１の発光装置Ａと、発光装置Ａから放射される光の配光を制御する反射鏡５であって底部に発光装置Ａが挿入される開口部５ａを有する反射鏡５と、発光装置Ａおよび反射鏡５が収納される器具本体９とを備えているので、発光装置Ａの色変換部材４の周部と反射鏡５における底部の開口部５ａの内側面との間の隙間を小さくすることができ、照明器具を正面から見た時の非発光部の面積が小さくなって正面光度が向上するとともに、配光制御部材である反射鏡５の小型化による照明器具の小型化を図りつつ照明器具全体としての外部への光取り出し効率を向上させることができる。ここにおいて、発光装置Ａの色変換部材４の周部と反射鏡５における底部の開口部５ａの内側面との間の隙間は小さい方が望ましく（要するに、色変換部材４の周部と反射鏡５における底部の開口部５ａの内側面とを近接させることが望ましく）、当該隙間の寸法は、反射鏡５および発光装置Ａの設置公差などを考慮して設定すればよい。   In the lighting fixture of the present embodiment described above, the light emitting device A of the first embodiment and the reflecting mirror 5 that controls the light distribution of the light emitted from the light emitting device A, in which the light emitting device A is inserted at the bottom. Since the reflecting mirror 5 having the portion 5a and the fixture main body 9 in which the light emitting device A and the reflecting mirror 5 are housed are provided, the periphery of the color conversion member 4 of the light emitting device A and the opening at the bottom of the reflecting mirror 5 The gap between the inner surface of 5a can be reduced, the area of the non-light-emitting portion when the luminaire is viewed from the front is reduced, the front luminous intensity is improved, and the reflecting mirror 5 which is a light distribution control member. The light extraction efficiency to the outside as the whole lighting fixture can be improved while reducing the size of the lighting fixture by reducing the size of the lighting fixture. Here, it is desirable that the gap between the peripheral portion of the color conversion member 4 of the light emitting device A and the inner surface of the opening 5a at the bottom of the reflecting mirror 5 is small (in short, the peripheral portion of the color converting member 4 and the reflecting mirror). 5 is preferably close to the inner surface of the bottom opening 5a), and the dimension of the gap may be set in consideration of the installation tolerance of the reflecting mirror 5 and the light emitting device A, and the like.

また、本実施形態の照明器具では、反射鏡５は、底部の開口部５ａの周部の厚みが発光装置Ａにおける実装基板２の厚みよりも薄く、開口部５ａの開口縁を含む平面Ｐ２が色変換部材４の開口端を含む平面Ｐ１よりも後退して位置するように配置されているので、色変換部材４の周部から放射された光の反射鏡５への入射効率を高めることができ、照明器具全体としての外部への光取り出し効率を向上させることができる。図８（ｃ）中には色変換部材４の周部から放射された光の進行経路を矢印で例示してある。   In the lighting fixture of the present embodiment, the reflecting mirror 5 has a thickness of the peripheral portion of the opening 5a at the bottom that is thinner than the thickness of the mounting substrate 2 in the light emitting device A, and a plane P2 including the opening edge of the opening 5a. Since the color conversion member 4 is disposed so as to recede from the plane P <b> 1 including the opening end of the color conversion member 4, it is possible to increase the incident efficiency of the light emitted from the peripheral portion of the color conversion member 4 to the reflecting mirror 5. It is possible to improve the light extraction efficiency to the outside as the entire lighting fixture. In FIG. 8C, the traveling path of light emitted from the peripheral portion of the color conversion member 4 is illustrated by arrows.

なお、本実施形態では、光源として実施形態１の発光装置Ａを備えた照明器具について例示したが、光源としては実施形態２〜６のいずれかの発光装置Ａを用いてもよい。   In addition, in this embodiment, although illustrated about the lighting fixture provided with the light-emitting device A of Embodiment 1 as a light source, you may use the light-emitting device A in any one of Embodiment 2-6 as a light source.

（実施形態８）
図９に示す本実施形態の照明器具の基本構成は実施形態７と略同じであり、発光装置Ａから放射される光の配光を制御する配光制御部材として、実施形態７で説明した反射鏡５の代わりに、ハイブリッドレンズ（配光レンズ）６を備えている点が相違する。なお、実施形態７と同様の構成要素には同一の符号を付して説明を省略する。 (Embodiment 8)
The basic configuration of the lighting fixture of the present embodiment shown in FIG. 9 is substantially the same as that of the seventh embodiment, and the reflection described in the seventh embodiment as a light distribution control member that controls the light distribution of the light emitted from the light emitting device A. The difference is that a hybrid lens (light distribution lens) 6 is provided instead of the mirror 5. In addition, the same code | symbol is attached | subjected to the component similar to Embodiment 7, and description is abbreviate | omitted.

本実施形態の照明器具では、ハイブリッドレンズ６の外側面から外方へ延設された外鍔部６ｄが、器具本体９の開口縁に形成された溝部９ｂの底面と保持枠１０との間に保持されている。   In the lighting fixture of this embodiment, the outer flange portion 6 d extending outward from the outer surface of the hybrid lens 6 is between the bottom surface of the groove portion 9 b formed on the opening edge of the fixture body 9 and the holding frame 10. Is retained.

ハイブリッドレンズ６は、発光装置Ａ側に、発光装置Ａが挿入される凹所６１が形成されている。ここにおいて、ハイブリッドレンズ６は、凹所６１の内底面６１ａと内側面６１ｂとが光入射面６ａを構成しており、光入射面６ａ側の焦点（図示せず）から凹所６１の内底面６１ａへ入射した光を屈折させて更に光出射面６ｂで屈折させる機能と、光入射面６ａ側の上記焦点から凹所６１の内側面６１ｂへ入射した光を屈折させた後に外側面６ｃで全反射させ更に光出射面６ｂで屈折させる機能とを有しており、発光装置Ａから放射され光入射面６ａへ入射した光が光出射面６ｂから出射される。なお、ハイブリッドレンズ６は、外側面６ｃが回転放物面状に形成され、光出射面６ａが凸曲面状に形成されているが、外側面６ｃはＬＥＤチップ１の光軸方向においてＬＥＤチップ１から離れるにつれて外形が徐々に大きくなる曲面状であって凹所６１の内側面６１ｂから入射した光を光出射面６ａ側へ全反射できる形状であればよく、光出射面６ａは平面状でもよいし、フレネルレンズ状でもよい。   In the hybrid lens 6, a recess 61 into which the light emitting device A is inserted is formed on the light emitting device A side. Here, in the hybrid lens 6, the inner bottom surface 61a and the inner side surface 61b of the recess 61 constitute a light incident surface 6a, and the inner bottom surface of the recess 61 from the focal point (not shown) on the light incident surface 6a side. The function of refracting the light incident on 61a and further refracting the light on the light exit surface 6b, and the light incident on the inner side surface 61b of the recess 61 from the focal point on the light incident surface 6a side and then refracting all the light on the outer surface 6c. The light is reflected and further refracted by the light emitting surface 6b, and the light emitted from the light emitting device A and incident on the light incident surface 6a is emitted from the light emitting surface 6b. In the hybrid lens 6, the outer surface 6 c is formed in a paraboloid shape and the light emitting surface 6 a is formed in a convex curved surface, but the outer surface 6 c is formed in the LED chip 1 in the optical axis direction of the LED chip 1. As long as it is a curved surface shape whose outer shape gradually increases as it moves away from the surface, it can be any shape that can totally reflect the light incident from the inner surface 61b of the recess 61 toward the light emitting surface 6a, and the light emitting surface 6a may be planar. However, it may be in the form of a Fresnel lens.

本実施形態の照明器具では、光源として、実施形態１にて説明した発光装置Ａを用いているので、色変換部材４とハイブリッドレン６の凹所６１の光入射面６ａとを近接して配置することが可能となるから、配光制御部材であるハイブリッドレンズ６の小型化による照明器具の小型化を図りつつ照明器具全体としての外部への光取り出し効率を向上させることができる。ここにおいて、発光装置Ａの色変換部材４の周部とハイブリッドレンズ６における凹所６１の内側面６１ｂとの間の隙間は小さい方が望ましく（要するに、色変換部材４の周部とハイブリッドレンズ６における凹所６１の内側面６１ｂとを近接させることが望ましく）、当該隙間の寸法は、例えば、ハイブリッドレンズ６および発光装置Ａの組立て公差に設定すればよい。   In the lighting fixture of this embodiment, since the light emitting device A described in Embodiment 1 is used as a light source, the color conversion member 4 and the light incident surface 6a of the recess 61 of the hybrid lens 6 are arranged close to each other. Therefore, it is possible to improve the light extraction efficiency as a whole of the lighting fixture while reducing the size of the lighting fixture by reducing the size of the hybrid lens 6 that is a light distribution control member. Here, it is desirable that the gap between the peripheral portion of the color conversion member 4 of the light emitting device A and the inner side surface 61b of the recess 61 in the hybrid lens 6 is small (in short, the peripheral portion of the color conversion member 4 and the hybrid lens 6). It is desirable that the inner surface 61b of the recess 61 be close to each other), and the dimension of the gap may be set to an assembly tolerance of the hybrid lens 6 and the light emitting device A, for example.

また、本実施形態の照明器具では、ハイブリッドレンズ６における凹所６１の開口面を含む平面Ｐ３が色変換部材４の開口端を含む平面Ｐ１よりも配線基板７に近くなるように配置されているので、色変換部材４の周部から放射された光のハイブリッドレンズ６への入射効率を高めることができ、照明器具全体としての外部への光取り出し効率を向上させることができる。   Further, in the lighting fixture of the present embodiment, the plane P3 including the opening surface of the recess 61 in the hybrid lens 6 is disposed closer to the wiring board 7 than the plane P1 including the opening end of the color conversion member 4. Therefore, the incident efficiency to the hybrid lens 6 of the light radiated | emitted from the peripheral part of the color conversion member 4 can be improved, and the light extraction efficiency to the exterior as the whole lighting fixture can be improved.

なお、本実施形態では、光源として実施形態１の発光装置Ａを備えた照明器具について例示したが、光源としては実施形態２〜６のいずれかの発光装置Ａを用いてもよい。   In addition, in this embodiment, although illustrated about the lighting fixture provided with the light-emitting device A of Embodiment 1 as a light source, you may use the light-emitting device A in any one of Embodiment 2-6 as a light source.

ところで、上述の各実施形態では、ＬＥＤチップ１として、青色光を放射する青色ＬＥＤチップを採用しているが、ＬＥＤチップ１は青色光を放射するものに限らず、例えば、紫外光を放射するものでもよく、色変換部材４における蛍光体の発光色も特に限定するものではない。   By the way, in each above-mentioned embodiment, although the blue LED chip which radiates | emits blue light is employ | adopted as LED chip 1, LED chip 1 is not restricted to what radiates | emits blue light, For example, radiates | emits ultraviolet light. The light emission color of the phosphor in the color conversion member 4 is not particularly limited.

実施形態１の発光装置を示し、（ａ）は概略斜視図、（ｂ）は配線基板に実装した状態の概略断面図である。The light-emitting device of Embodiment 1 is shown, (a) is a schematic perspective view, (b) is a schematic sectional drawing of the state mounted in the wiring board. 実施形態２の発光装置を示す概略断面図である。6 is a schematic cross-sectional view showing a light emitting device of Embodiment 2. FIG. 実施形態３の発光装置を示す概略断面図である。6 is a schematic cross-sectional view showing a light emitting device according to Embodiment 3. FIG. 実施形態４の発光装置を示し、（ａ）は配線基板に実装した状態の概略断面図、（ｂ）は伝熱プレートの下面側から見た概略斜視図、（ｃ）は要部説明図である。The light-emitting device of Embodiment 4 is shown, (a) is a schematic sectional drawing of the state mounted in the wiring board, (b) is a schematic perspective view seen from the lower surface side of the heat-transfer plate, (c) is principal part explanatory drawing. is there. 実施形態５の発光装置を示し、（ａ）は配線基板に実装した状態の概略断面図、（ｂ）は要部概略平面図、（ｃ）は要部概略断面図である。7 shows a light emitting device of Embodiment 5, wherein (a) is a schematic cross-sectional view of a state where the light-emitting device is mounted on a wiring board, (b) is a main part schematic plan view, and (c) is a main part schematic cross-sectional view. 実施形態６の発光装置を示す概略断面図である。10 is a schematic cross-sectional view showing a light emitting device according to Embodiment 6. FIG. 同上の他の構成例を示す概略断面図である。It is a schematic sectional drawing which shows the other structural example same as the above. 実施形態７の照明器具を示し、（ａ）は概略正面図、（ｂ）は概略断面図である。The lighting fixture of Embodiment 7 is shown, (a) is a schematic front view, (b) is a schematic sectional drawing. 実施形態８の照明器具を示す概略断面図である。It is a schematic sectional drawing which shows the lighting fixture of Embodiment 8. 従来例を示す発光装置の概略断面図である。It is a schematic sectional drawing of the light-emitting device which shows a prior art example. 従来例を示す照明器具の概略断面図である。It is a schematic sectional drawing of the lighting fixture which shows a prior art example. 他の従来例の照明器具を示し、（ａ）は概略正面図、（ｂ）は概略断面図である。The lighting fixture of another prior art example is shown, (a) is a schematic front view, (b) is a schematic sectional drawing. 別の従来例の照明器具を示し、（ａ）は概略断面図、（ｂ）は要部の機能説明図である。The lighting fixture of another prior art example is shown, (a) is a schematic sectional drawing, (b) is function explanatory drawing of the principal part.

符号の説明Explanation of symbols

Ａ 発光装置
１ ＬＥＤチップ
２ 実装基板
３ 封止部
４ 色変換部材
５ 反射鏡
５ａ 開口部
６ ハイブリッドレンズ
９ 器具本体
２５ 伝熱プレート
２５ｂ マウント部
２５ｃ 短絡防止溝
２５ｄ 溝 A light emitting device 1 LED chip 2 mounting substrate 3 sealing portion 4 color conversion member 5 reflecting mirror 5a opening 6 hybrid lens 9 instrument body 25 heat transfer plate 25b mount portion 25c short-circuit prevention groove 25d groove

Claims (9)

ＬＥＤチップと、前記ＬＥＤチップが一表面側に実装された実装基板と、前記ＬＥＤチップから放射された光によって励起されて前記ＬＥＤチップの発光色とは異なる色の光を放射する蛍光体を含有した透光性材料により形成され前記実装基板の前記一表面側に配設された色変換部材とを備え、前記色変換部材がドーム状であり、平面視において前記色変換部材の外周線よりも前記実装基板の外周線が内側に位置し、前記色変換部材の開口端が前記実装基板の前記一表面側で前記実装基板の外周部と接合されてなることを特徴とする発光装置。 An LED chip, and the L ED chip mounting board mounted on the one surface, fluorescence emitting light of a different color from that of the L ED is excited by the light emitted from the chip the L ED chip luminescent color is formed by translucent material containing body and a color conversion member, wherein disposed on one surface side of the implementation substrate, the color conversion member is dome-shaped, the color Te flat surface when viewed smell than peripheral line of the converting member located peripheral line is on the inside of the implementation substrate, the open end of the color conversion member is joined to the outer peripheral portion of the implementation substrate by the one surface of the mounting substrate A light emitting device characterized by the above. 前記ＬＥＤチップと前記色変換部材との間に、前記ＬＥＤチップを封止した透光性材料からなる封止部が設けられてなることを特徴とする請求項１記載の発光装置。   The light emitting device according to claim 1, wherein a sealing portion made of a translucent material sealing the LED chip is provided between the LED chip and the color conversion member. 前記実装基板の他表面側に、前記実装基板よりも熱伝導率の高い材料により形成され前記ＬＥＤチップで発生した熱が伝熱される伝熱プレートが埋設されてなり、平面視における前記伝熱プレートの外周線が前記ＬＥＤチップの外周線の外側に位置していることを特徴とする請求項１または請求項２記載の発光装置。 Other surface side of the mounting substrate, said mounting substrate is embedded a heat transfer plate the heat generated by the LED chip is formed by a material having high thermal conductivity is heat is transferred it becomes than the heat transfer that put in plan view The light emitting device according to claim 1, wherein an outer peripheral line of the heat plate is located outside an outer peripheral line of the LED chip. 前記伝熱プレートは、前記実装基板の前記一表面側に露出するマウント部が突設されてなり、前記ＬＥＤチップは、前記マウント部に搭載されてなることを特徴とする請求項３記載の発光装置。 The heat transfer plate is made by mounting section exposed is projected to the one surface side of the mounting substrate, the LED chip according to claim 3, characterized by being mounted on the mount portion Light emitting device. 前記マウント部は、前記実装基板の前記一表面を含む平面から突出していることを特徴とする請求項４記載の発光装置。   The light emitting device according to claim 4, wherein the mount portion protrudes from a plane including the one surface of the mounting substrate. 前記伝熱プレートは、前記実装基板の前記他表面側と同じ面側に中央から外側に向かって幅の広くなる溝が形成されてなることを特徴とする請求項３ないし請求項５のいずれか１項に記載の発光装置。 6. The heat transfer plate according to any one of claims 3 to 5, wherein a groove that is wider from the center toward the outside is formed on the same surface side as the other surface side of the mounting substrate. 2. The light emitting device according to item 1. 前記マウント部は、前記ＬＥＤチップの搭載領域の周囲に短絡防止溝が形成されてなることを特徴とする請求項４ないし請求項６のいずれか１項に記載の発光装置。   The light emitting device according to claim 4, wherein the mount portion is formed with a short-circuit prevention groove around a mounting region of the LED chip. 請求項１ないし請求項７のいずれか１項に記載の発光装置と、前記発光装置から放射される光の配光を制御する反射鏡であって底部に前記発光装置が挿入される開口部を有する前記反射鏡と、前記発光装置および前記反射鏡が収納される器具本体とを備えてなることを特徴とする照明器具。 A light emitting device according to any one of claims 1 to 7, opening the light - emitting device is inserted into the bottom a reflecting mirror for controlling the light distribution of light emitted from the light - emitting device wherein the anti Ikyo that have a part, luminaire the light - emitting device and said reflection mirror is characterized by comprising a device body to be housed. 前記反射鏡は、前記開口部の周部の厚みが前記発光装置における前記実装基板の厚みよりも薄く、前記開口部の周部が前記色変換部材の前記開口端を含む平面よりも後退して位置するように配置されてなることを特徴とする請求項８記載の照明器具。 The reflecting mirror, the thickness of the peripheral portion of the opening is smaller than the thickness of the mounting substrate in the light emitting device, also recessed from the flat peripheral portion of the opening containing said open mouth end of the color converting member The lighting fixture according to claim 8, wherein the lighting fixture is disposed so as to be positioned at a distance.

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