JP5896212B2 - LIGHT EMITTING DEVICE, VEHICLE LIGHT, AND VEHICLE - Google Patents
LIGHT EMITTING DEVICE, VEHICLE LIGHT, AND VEHICLE Download PDFInfo
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Classifications
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F21—LIGHTING
- F21W—INDEXING SCHEME ASSOCIATED WITH SUBCLASSES F21K, F21L, F21S and F21V, RELATING TO USES OR APPLICATIONS OF LIGHTING DEVICES OR SYSTEMS
- F21W2102/00—Exterior vehicle lighting devices for illuminating purposes
- F21W2102/10—Arrangement or contour of the emitted light
- F21W2102/17—Arrangement or contour of the emitted light for regions other than high beam or low beam
- F21W2102/18—Arrangement or contour of the emitted light for regions other than high beam or low beam for overhead signs
Landscapes
- Led Device Packages (AREA)
- Semiconductor Lasers (AREA)
- Non-Portable Lighting Devices Or Systems Thereof (AREA)
Description
本発明は、発光装置、これを用いた車両用灯具及びこれを搭載した車両に係り、特に、波長変換部材が高温となるのを抑えることが可能な発光装置、これを用いた車両用灯具及びこれを搭載した車両に関する。 The present invention relates to a light emitting device, a vehicular lamp using the light emitting device, and a vehicle equipped with the same, and in particular, a light emitting device capable of suppressing the wavelength conversion member from becoming high temperature, a vehicular lamp using the same, and It relates to a vehicle equipped with this.
従来、励起光を吸収し、波長変換して所定の波長域の光を放出する波長変換部材を用いた発光装置が提案されている(例えば、特許文献1参照)。 Conventionally, a light-emitting device using a wavelength conversion member that absorbs excitation light, converts the wavelength, and emits light in a predetermined wavelength region has been proposed (see, for example, Patent Document 1).
図37は、従来の波長変換部材を用いた内視鏡用の発光装置300の例である。 FIG. 37 shows an example of a light-emitting device 300 for an endoscope using a conventional wavelength conversion member.
図37に示すように、発光装置300は、励起光源から放出された励起光を伝送するための光ファイバ等のライトガイド310、ライトガイド310の端面に配置された反射膜321、322付き波長変換部材320等を備えている。 As shown in FIG. 37, the light-emitting device 300 includes a light guide 310 such as an optical fiber for transmitting excitation light emitted from an excitation light source, and wavelength conversion with reflection films 321 and 322 disposed on the end face of the light guide 310. The member 320 etc. are provided.
上記構成の発光装置300においては、波長変換部材320は、ライトガイド310の端面から出射される励起光を吸収し、波長変換して所定の波長域の光を放出する。 In the light emitting device 300 configured as described above, the wavelength conversion member 320 absorbs excitation light emitted from the end face of the light guide 310, converts the wavelength, and emits light in a predetermined wavelength range.
しかしながら、上記構成の発光装置300においては、ライトガイド310の端面と波長変換部材320とが密着しているため、励起光の出力が上がるにつれ波長変換部材320を照射する励起光の光密度が高くなって波長変換部材320が高温となり、波長変換部材320が劣化、変色し、効率が低下するという問題がある。特に、励起光源がLD(レーザーダイオード)である場合、この問題は顕著となる。 However, in the light emitting device 300 configured as described above, since the end face of the light guide 310 and the wavelength conversion member 320 are in close contact with each other, the light density of the excitation light that irradiates the wavelength conversion member 320 increases as the output of the excitation light increases. Thus, there is a problem that the wavelength conversion member 320 becomes high temperature, the wavelength conversion member 320 is deteriorated and discolored, and the efficiency is lowered. In particular, when the excitation light source is an LD (laser diode), this problem becomes significant.
本発明は、このような事情に鑑みてなされたものであり、波長変換部材が高温となるのを抑えることが可能な(従って、励起光源を高出力化しても波長変換部材が劣化し、効率が低下するのを抑えることが可能な)発光装置、これを用いた車両用灯具及びこれを搭載した車両を提供することを目的とする。 The present invention has been made in view of such circumstances, and it is possible to suppress the wavelength conversion member from becoming high temperature (therefore, the wavelength conversion member is deteriorated even if the output power of the excitation light source is increased, and the efficiency is increased). It is an object of the present invention to provide a light emitting device capable of suppressing a decrease in the brightness, a vehicle lamp using the light emitting device, and a vehicle equipped with the same.
上記課題を解決するため、本発明は、車両用灯具に用いられる発光装置において、励起光を発生する励起光源と、励起光を吸収し、波長変換して所定の波長域の光を放出する波長変換部材と、前記励起光源からの励起光の進行方向を変化させて前記波長変換部材を照射する光偏向手段と、を含む発光部と、前記励起光源からの励起光を前記光偏向手段へ照射する第1光学系と、を備え、前記波長変換部材は、リング型の波長変換部材であり、前記光偏向手段は、前記リング型の波長変換部材のリング内側に配置され、前記励起光源からの励起光の光密度を小さくしかつ進行方向を変化させて前記波長変換部材の内側リング面を照射する光偏向手段であることを特徴とする。 In order to solve the above-described problems, the present invention provides a pumping light source that generates pumping light and a wavelength that absorbs pumping light, converts the wavelength, and emits light in a predetermined wavelength range in a light emitting device used in a vehicle lamp A light emitting unit including a conversion member, a light deflection unit that irradiates the wavelength conversion member by changing a traveling direction of excitation light from the excitation light source, and irradiating the light deflection unit with excitation light from the excitation light source The wavelength conversion member is a ring-type wavelength conversion member, and the light deflecting means is disposed inside the ring of the ring-type wavelength conversion member, and is from the excitation light source. It is a light deflecting means for irradiating the inner ring surface of the wavelength conversion member by reducing the light density of the excitation light and changing the traveling direction.
本発明によれば、光偏向手段の作用により、励起光源からの励起光の進行方向を変化させた上で波長変換部材を照射する構成であり、波長変換部材が励起光源による熱、高強度の光等に直接さらされることがないため、励起光源からの励起光の進行方向を変化させることなく波長変換部材を照射する場合と比べ、波長変換部材が高温となるのを抑えることが可能となる。従って、励起光源を高出力化しても波長変換部材が劣化し、効率が低下するのを抑えることが可能となる。
また、本発明によれば、光偏向手段の作用により、光密度が小さくなりかつ進行方向が変化させられた励起光源からの励起光で波長変換部材を照射する構成であるため、励起光源からの励起光の進行方向を変化させることなく波長変換部材を照射する場合と比べ、波長変換部材が高温となるのを抑えることが可能となる。従って、励起光源を高出力化しても波長変換部材が劣化し、効率が低下するのを抑えることが可能となる。
According to the present invention, the wavelength conversion member is irradiated after changing the traveling direction of the excitation light from the excitation light source by the action of the light deflecting unit. Since it is not directly exposed to light or the like, it is possible to suppress the wavelength conversion member from becoming high temperature compared to the case where the wavelength conversion member is irradiated without changing the traveling direction of the excitation light from the excitation light source. . Therefore, even if the excitation light source has a high output, it is possible to prevent the wavelength conversion member from deteriorating and the efficiency from decreasing.
In addition, according to the present invention, the wavelength conversion member is irradiated with the excitation light from the excitation light source whose light density is reduced and the traveling direction is changed by the action of the light deflecting unit. Compared with the case where the wavelength conversion member is irradiated without changing the traveling direction of the excitation light, it is possible to suppress the wavelength conversion member from becoming high temperature. Therefore, even if the excitation light source has a high output, it is possible to prevent the wavelength conversion member from deteriorating and the efficiency from decreasing.
本発明によれば、光偏向手段の作用により、励起光源からの励起光の光密度を小さくしかつ進行方向を変化させた上で波長変換部材を照射する構成であり、波長変換部材が励起光源による熱、高強度の光等に直接さらされることがないため、波長変換部材が高温となるのを抑えることが可能となる。従って、励起光源を高出力化しても波長変換部材が劣化、変色し、効率が低下するのを抑えることが可能となる。 According to the present invention, the wavelength conversion member is irradiated with the wavelength conversion member after the light density of the excitation light from the excitation light source is reduced and the traveling direction is changed by the action of the light deflection unit. Therefore, the wavelength conversion member can be prevented from being heated to a high temperature. Therefore, it is possible to prevent the wavelength conversion member from deteriorating or discoloring even when the output of the excitation light source is increased, thereby reducing efficiency.
本発明は、前記発光部の上面の少なくとも一部は、遮光手段で覆われていることを特徴とする。 The present invention, at least a portion of the upper surface of the front Symbol emitting portion, characterized in that it is covered with a light shielding means.
本発明によれば、遮光手段の作用により、発光部の上面から光が放出されるのを防止することが可能となる。 According to the present invention, it is possible to prevent light from being emitted from the upper surface of the light emitting unit by the action of the light shielding means.
本発明は、前記遮光手段は、第1反射手段であることを特徴とする。 The present invention, before Symbol shielding means, characterized in that it is a first reflecting means.
本発明によれば、第1反射手段の作用により、光の取り出し効率を高めることが可能となる。 According to the present invention, it is possible to increase the light extraction efficiency by the action of the first reflecting means.
本発明は、前記発光部の下面の少なくとも一部は、第2反射手段で覆われていることを特徴とする。 The present invention, at least a portion of the lower surface of the front Symbol emitting unit is characterized by being covered by the second reflecting means.
本発明によれば、第2反射手段の作用により、光の取り出し効率を高めることが可能となる。 According to the present invention, it is possible to increase the light extraction efficiency by the action of the second reflecting means.
本発明は、前記発光部の下面の周囲には、前記発光部から放出される光を反射する第3反射手段が配置されていることを特徴とする。 The present invention, in the periphery of the lower surface of the front Symbol emitting portion, wherein the third reflection means for reflecting the light emitted from the light emitting portion is disposed.
本発明によれば、第3反射手段の作用により、波長変換部材の周端面から放出される双指向性の分布を持つ光が反射されるため、双指向性を半分にした半双指向性の分布を持つ光を放出する、車両用灯具の鉛直方向の薄型化に適した光源装置を構成することが可能となる。 According to the present invention, since the light having the bi-directional distribution emitted from the peripheral end face of the wavelength conversion member is reflected by the action of the third reflecting means, the semi-bidirectional distribution in which the bi-directional characteristic is halved. Thus, it is possible to configure a light source device that emits light having a shape suitable for thinning the vehicular lamp in the vertical direction.
本発明は、車両用灯具の発明として次のように特定することもできる。 This invention can also be specified as follows as invention of a vehicle lamp.
本発明の発光装置と、前記発光装置の前記発光部から放出される光を車両前方に照射するように構成された第2光学系と、を備えることを特徴とする車両用灯具。 A vehicular lamp comprising: the light-emitting device of the present invention; and a second optical system configured to irradiate light emitted from the light-emitting portion of the light-emitting device to the front of the vehicle.
また、本発明は、車両の発明として次のように特定することもできる。 Moreover, this invention can also be specified as follows as invention of a vehicle.
本発明の車両用灯具が搭載された車両。
A vehicle equipped with the vehicular lamp of the present invention .
以上説明したように、本発明によれば、波長変換部材が高温となるのを抑えることが可能な(従って、励起光源を高出力化しても波長変換部材が劣化し、効率が低下するのを抑えることが可能な)発光装置、これを用いた車両用灯具及びこれを搭載した車両を提供することが可能となる。 As described above, according to the present invention, it is possible to prevent the wavelength conversion member from reaching a high temperature (therefore, even if the excitation light source is increased in output, the wavelength conversion member is deteriorated and the efficiency is reduced). It is possible to provide a light emitting device that can be suppressed, a vehicle lamp using the light emitting device, and a vehicle equipped with the same.
以下、本発明の一実施形態である車両用灯具ユニット20について、図面を参照しながら説明する。 Hereinafter, a vehicle lamp unit 20 according to an embodiment of the present invention will be described with reference to the drawings.
まず、本実施形態の車両用灯具ユニット20に用いられる発光装置10について説明する。 First, the light-emitting device 10 used for the vehicle lamp unit 20 of this embodiment will be described.
図1は本実施形態の車両用灯具ユニット20をその光軸AXを含む鉛直面で切断した断面図、図2(a)は発光装置10の波長変換部材13周辺を拡大した拡大図である。 FIG. 1 is a cross-sectional view of the vehicular lamp unit 20 of the present embodiment cut along a vertical plane including the optical axis AX, and FIG. 2A is an enlarged view of the vicinity of the wavelength conversion member 13 of the light emitting device 10.
[発光装置10]
図1、図2(a)に示すように、発光装置10は、フェルール11、ライトガイド12、波長変換部材13、励起光源14等を備えている。
[Light Emitting Device 10]
As shown in FIGS. 1 and 2A, the light emitting device 10 includes a ferrule 11, a light guide 12, a wavelength conversion member 13, an excitation light source 14, and the like.
フェルール11は、ライトガイド12を保持するための部材であり、上面11a中心と下面11b中心とを連通するライトガイド用貫通穴11cが形成されている。ライトガイド12は、その出射端側がライトガイド用貫通穴11cに挿入されてフェルール11に保持されている。ライトガイド12の出光面12bとフェルール11の上面11aとは、フェルール11の上面11aを研磨することで、同一平面とされている。 The ferrule 11 is a member for holding the light guide 12, and has a light guide through hole 11c that communicates the center of the upper surface 11a and the center of the lower surface 11b. The light guide 12 is held by the ferrule 11 at the light emitting end thereof inserted into the light guide through hole 11c. The light exit surface 12b of the light guide 12 and the upper surface 11a of the ferrule 11 are flush with each other by polishing the upper surface 11a of the ferrule 11.
フェルール11は、ライトガイド12を保持することができるものであればよく、その材質は特に問わない。例えば、フェルール11は、ステンレス製、ニッケル製、ジルコニア製であってもよいし、その他の金属製、樹脂製、ガラス製であってもよい。 The ferrule 11 is not particularly limited as long as it can hold the light guide 12. For example, the ferrule 11 may be made of stainless steel, nickel, or zirconia, or may be made of other metal, resin, or glass.
フェルール11の上面11aは、例えば、円形で、図2(a)、図4に示すように、反射手段16で覆われている。反射手段16は、波長変換部材13が発する光を波長変換部材13側に反射するものであればよく、例えば、フェルール11の上面11aに対してアルミや銀等の金属蒸着を施すことで形成された反射層(又は反射面)であってもよいし、又は、フェルール11が導電性を有する場合には、フェルール11の上面11aに対してメッキを施すことで形成された反射層(誘電体膜)であってもよい。このようにフェルール11の上面11aに対して反射層(又は反射面)を形成する方法については、例えば、特開2007−121502号公報に記載されている方法を用いることが可能である。あるいは、反射手段16は、フェルール11の上面11a(上面11aのうちライトガイド12の出光面12b以外の領域)に接着された薄い板状の反射部材であってもよいし、フェルール11が金属製の場合には、フェルール11の上面11aに対して鏡面研磨を施すことで形成された反射面であってもよい。 The upper surface 11a of the ferrule 11 is circular, for example, and is covered with the reflecting means 16 as shown in FIG. 2 (a) and FIG. The reflection means 16 may be any means as long as it reflects the light emitted from the wavelength conversion member 13 toward the wavelength conversion member 13. For example, the reflection means 16 is formed by depositing metal such as aluminum or silver on the upper surface 11 a of the ferrule 11. A reflective layer (or reflective surface), or when the ferrule 11 is conductive, the reflective layer (dielectric film) formed by plating the upper surface 11a of the ferrule 11 ). As a method for forming the reflective layer (or reflective surface) on the upper surface 11a of the ferrule 11 as described above, for example, a method described in JP 2007-121502 A can be used. Alternatively, the reflecting means 16 may be a thin plate-like reflecting member bonded to the upper surface 11a of the ferrule 11 (a region of the upper surface 11a other than the light exit surface 12b of the light guide 12), or the ferrule 11 is made of metal. In this case, it may be a reflecting surface formed by mirror polishing the upper surface 11a of the ferrule 11.
ライトガイド12は、励起光源14からの励起光を導光(又は伝搬)して波長変換部材13を照射する導光部材である。ライトガイド12は、例えば、中心部のコア(例えば、コア径:0.2mm)とその周囲を覆うクラッド(いずれも図示せず)とを含む光ファイバである。コアは、クラッドと比較して屈折率が高い。従って、ライトガイド12の一端面(以下入光面12aと称す)からライトガイド12内に導入された励起光は、コアとクラッドとの境界の全反射を利用してコア内部に閉じこめられた状態で他端面(以下出光面12bと称す)まで導光されて、出光面12bから出射する。 The light guide 12 is a light guide member that guides (or propagates) excitation light from the excitation light source 14 and irradiates the wavelength conversion member 13. The light guide 12 is, for example, an optical fiber including a central core (for example, core diameter: 0.2 mm) and a cladding (none of which is shown) covering the periphery thereof. The core has a higher refractive index than the clad. Therefore, the excitation light introduced into the light guide 12 from one end surface of the light guide 12 (hereinafter referred to as the light incident surface 12a) is confined inside the core using the total reflection at the boundary between the core and the clad. Then, the light is guided to the other end surface (hereinafter referred to as the light exit surface 12b) and emitted from the light exit surface 12b.
ライトガイド12は、励起光源14からの励起光を導光することができるものであればよく、単線ファイバであってもよいし、多線ファイバであってもよい。また、ライトガイド12は、単一モードファイバであってもよいし、多モードファイバであってもよい。また、ライトガイド12の材質は特に問わない。例えば、ライトガイド12は、石英ガラス製であってもよいし、プラスチック製であってもよい。なお、ライトガイド12は、単線ファイバ、多モードファイバが好ましい。 The light guide 12 only needs to be able to guide the excitation light from the excitation light source 14, and may be a single-wire fiber or a multi-wire fiber. The light guide 12 may be a single mode fiber or a multimode fiber. The material of the light guide 12 is not particularly limited. For example, the light guide 12 may be made of quartz glass or plastic. The light guide 12 is preferably a single fiber or a multimode fiber.
ライトガイド12の入光面12aは、例えば、励起光源14の前方近傍に配置されている。励起光源14からの励起光が効率よく入光するように、ライトガイド12の入光面12aと励起光源14との間に集光レンズ(図示せず)を配置してもよい。 The light incident surface 12 a of the light guide 12 is disposed, for example, near the front of the excitation light source 14. A condensing lens (not shown) may be disposed between the light incident surface 12a of the light guide 12 and the excitation light source 14 so that the excitation light from the excitation light source 14 is efficiently incident.
図3は、波長変換部材13の斜視図である。 FIG. 3 is a perspective view of the wavelength conversion member 13.
図3に示すように、波長変換部材13は、励起光を吸収し、波長変換して所定の波長域の光を放出する波長変換部材で、例えば、円形をフェルール11の上面11aに対して面直方向に引き延ばした円盤型のYAG等の蛍光体(Ce:YAG等の蛍光物質が望ましい)である。波長変換部材13は、円形の上面13a(本発明の第二面に相当)、円形の下面13b(本発明の第一面に相当)及びリング状の周端面13c(側面)を含んでいる(例えば、厚み:0.2mm、直径:1.0mm)。 As shown in FIG. 3, the wavelength conversion member 13 is a wavelength conversion member that absorbs excitation light, converts the wavelength, and emits light in a predetermined wavelength range. For example, a circular shape faces the upper surface 11 a of the ferrule 11. It is a disk-shaped phosphor such as YAG extended in a straight direction (a phosphor such as Ce: YAG is desirable). The wavelength conversion member 13 includes a circular upper surface 13a (corresponding to the second surface of the present invention), a circular lower surface 13b (corresponding to the first surface of the present invention), and a ring-shaped peripheral end surface 13c (side surface) ( For example, thickness: 0.2 mm, diameter: 1.0 mm).
波長変換部材13として、円形をフェルール11の上面11aに対して面直方向に引き延ばした円盤型のYAG等の蛍光体を用いれば、ライトガイド12の出光面12bから波長変換部材13の周端面13cまでの光路長がその全周に渡り均一となるため、波長変換部材13の周端面13cの色ムラ、輝度ムラを抑えることが可能となる。 If a phosphor such as a disk-shaped YAG having a circular shape extending in a direction perpendicular to the upper surface 11 a of the ferrule 11 is used as the wavelength conversion member 13, the peripheral end surface 13 c of the wavelength conversion member 13 from the light exit surface 12 b of the light guide 12. Since the optical path length up to the entire circumference is uniform, it is possible to suppress color unevenness and brightness unevenness of the peripheral end surface 13c of the wavelength conversion member 13.
なお、波長変換部材13は、多角形又はその他の形状を、フェルール11の上面11aに対して面直方向に引き延ばした円盤型のYAG等の蛍光体であってもよい。波長変換部材13は、黄色蛍光体の濃度(例えば、Ceの添加量等)を調整することで、発光色が法規で規定されたCIE色度図上の白色範囲を満たすように調整されている。 The wavelength converting member 13 may be a disk-shaped phosphor such as a disk-shaped YAG in which a polygon or other shape is extended in a direction perpendicular to the upper surface 11 a of the ferrule 11. The wavelength conversion member 13 is adjusted so that the emission color satisfies the white range on the CIE chromaticity diagram defined by law by adjusting the concentration of the yellow phosphor (for example, the amount of Ce added). .
波長変換部材13の上面13aは、遮光手段15で覆われている。遮光手段15は、波長変換部材13が発する光のうちその上面13aから出射しようとする光を遮光するものであればよく、例えば、波長変換部材13の上面13aに対して施された黒色塗装であってもよいし、波長変換部材13の上面13aに対してアルミや銀等の金属蒸着を施すことで形成された反射層(又は反射面)であってもよいし、波長変換部材13の上面13aに接着された薄い板状の反射部材又は白樹脂等の拡散反射部材であってもよい。また、遮光手段15は、励起光源14の波長で最適設計された誘電体多層膜であってもよい。 The upper surface 13 a of the wavelength conversion member 13 is covered with the light shielding means 15. The light shielding means 15 may be any means as long as it shields light to be emitted from the upper surface 13a among the light emitted from the wavelength converting member 13, and is, for example, black paint applied to the upper surface 13a of the wavelength converting member 13. It may be a reflection layer (or reflection surface) formed by performing metal deposition such as aluminum or silver on the upper surface 13a of the wavelength conversion member 13, or the upper surface of the wavelength conversion member 13. It may be a thin plate-like reflecting member bonded to 13a or a diffuse reflecting member such as white resin. The light shielding means 15 may be a dielectric multilayer film optimally designed with the wavelength of the excitation light source 14.
遮光手段15として反射層や反射板等の反射面を用いれば、波長変換部材13が発する光のうち波長変換部材13の上面13aから出射しようとする光は、遮光手段15で反射されて波長変換部材13側に戻されるため(図2(a)参照)、波長変換部材13の周端面13cから放出される光の取り出し効率を高めることが可能となる。 If a reflection surface such as a reflection layer or a reflection plate is used as the light shielding means 15, the light that is going to be emitted from the upper surface 13 a of the wavelength conversion member 13 out of the light emitted from the wavelength conversion member 13 is reflected by the light shielding means 15 and wavelength converted. Since it is returned to the member 13 side (see FIG. 2A), it is possible to increase the extraction efficiency of light emitted from the peripheral end surface 13c of the wavelength conversion member 13.
図2(a)に示すように、波長変換部材13の下面13bは、フェルール11の上面11a(反射手段16)のうちライトガイド用貫通穴11c周囲の領域に接着されて、ライトガイド用貫通穴11c(ライトガイド12の出光面12b)を覆っている。 As shown in FIG. 2 (a), the lower surface 13b of the wavelength conversion member 13 is bonded to the area around the light guide through hole 11c on the upper surface 11a (reflecting means 16) of the ferrule 11 to provide a light guide through hole. 11c (the light exit surface 12b of the light guide 12) is covered.
図4は、フェルール11の上面図である。図4に示すように、波長変換部材13は、フェルール11の上面11aの中心に配置されている。また、図2(a)に示すように、波長変換部材13の下面13b中心とライトガイド用貫通穴11cの中心(ライトガイド12の出光面12bの中心)とは一致している。従って、波長変換部材13の下面13bは、ライトガイド用貫通穴11c(ライトガイド12の出光面12b)が対向する領域以外、反射手段16で覆われている(図2(a)参照)。従って、波長変換部材13が発する光のうち波長変換部材13の下面13bから出射しようとする光は、反射手段16で反射されて波長変換部材13側に戻される。これにより、光の取り出し効率が向上する。 FIG. 4 is a top view of the ferrule 11. As shown in FIG. 4, the wavelength conversion member 13 is disposed at the center of the upper surface 11 a of the ferrule 11. As shown in FIG. 2A, the center of the lower surface 13b of the wavelength conversion member 13 and the center of the light guide through hole 11c (the center of the light output surface 12b of the light guide 12) coincide with each other. Therefore, the lower surface 13b of the wavelength conversion member 13 is covered with the reflecting means 16 except for the region where the light guide through hole 11c (the light exit surface 12b of the light guide 12) faces (see FIG. 2A). Therefore, the light which is going to be emitted from the lower surface 13b of the wavelength conversion member 13 among the light emitted from the wavelength conversion member 13 is reflected by the reflecting means 16 and returned to the wavelength conversion member 13 side. Thereby, the light extraction efficiency is improved.
ライトガイド12の出光面12bは、フェルール11の上面11aと同一平面である。従って、波長変換部材13の下面13bとライトガイド12の出光面12bとは密着している。なお、波長変換部材13の下面13bとライトガイド12の出光面12bとの間には若干の隙間が存在していてもよい。 The light exit surface 12 b of the light guide 12 is flush with the upper surface 11 a of the ferrule 11. Therefore, the lower surface 13b of the wavelength conversion member 13 and the light exit surface 12b of the light guide 12 are in close contact. A slight gap may exist between the lower surface 13 b of the wavelength conversion member 13 and the light exit surface 12 b of the light guide 12.
反射手段16(フェルール11の上面11a)は、波長変換部材13より大径で、波長変換部材13の下面13bの外径より外側に延伸している(図2(a)、図4参照)。すなわち、反射手段16は、波長変換部材13の下面13bの周囲にも配置されている(本発明の第3反射手段に相当)。従って、波長変換部材13の周端面13c全周から下方に放出される光は、反射手段16で反射されて折り返されて上方に向かう(図2(a)参照)。これにより、双指向性を半分にした半双指向性の分布(図2(b)参照)を持つ光を放出する発光装置10が構成される。 The reflecting means 16 (the upper surface 11a of the ferrule 11) has a larger diameter than the wavelength conversion member 13, and extends outward from the outer diameter of the lower surface 13b of the wavelength conversion member 13 (see FIGS. 2A and 4). That is, the reflecting means 16 is also disposed around the lower surface 13b of the wavelength conversion member 13 (corresponding to the third reflecting means of the present invention). Therefore, the light emitted downward from the entire circumference of the peripheral end face 13c of the wavelength converting member 13 is reflected by the reflecting means 16 and turned up to go upward (see FIG. 2A). As a result, the light emitting device 10 that emits light having a half-bidirectional distribution (see FIG. 2B) in which the bidirectionality is halved is configured.
励起光源14は、励起光を発生する励起光源で、LEDやLD等の半導体発光素子が望ましく、特に、光利用効率の観点から、LD(レーザーダイオード)が望ましい。本実施形態では、励起光源14として、発光波長が400〜450nm程度のLDを用いている。なお、励起光源14は、車両用灯具ユニット20以外の適宜の箇所(例えば車体フレームや車体フレームに固定されたハウジング)にネジ等の公知の手段で固定されている。 The excitation light source 14 is an excitation light source that generates excitation light, and is preferably a semiconductor light emitting element such as an LED or an LD. In particular, from the viewpoint of light utilization efficiency, an LD (laser diode) is desirable. In the present embodiment, an LD having an emission wavelength of about 400 to 450 nm is used as the excitation light source 14. The excitation light source 14 is fixed to an appropriate place other than the vehicle lamp unit 20 (for example, a body frame or a housing fixed to the body frame) by a known means such as a screw.
上記構成の発光装置10によれば、図1、図2(a)に示すように、励起光源14からの励起光Ray1は、ライトガイド12の入光面12aからライトガイド12内に導入され出光面12bまで導光されて、出光面12bから出射し、波長変換部材13を照射する。 According to the light emitting device 10 having the above configuration, as shown in FIGS. 1 and 2A, the excitation light Ray1 from the excitation light source 14 is introduced into the light guide 12 from the light incident surface 12a of the light guide 12, and is emitted. The light is guided to the surface 12b, is emitted from the light exit surface 12b, and irradiates the wavelength conversion member 13.
励起光源14からの励起光が入射した波長変換部材13は、励起光源14からの励起光により励起される光と波長変換部材13を透過する励起光源14からの励起光との混色による白色光Ray2を発する。 The wavelength conversion member 13 to which the excitation light from the excitation light source 14 is incident is white light Ray2 due to the color mixture of the light excited by the excitation light from the excitation light source 14 and the excitation light from the excitation light source 14 that passes through the wavelength conversion member 13. To emit.
波長変換部材13が発する白色光Ray2は、遮光手段15及び/又は反射手段16で反射されて(又は遮光手段15又は反射手段16で反射されることなく直接)、波長変換部材13の周端面13c全周から放出される。 The white light Ray2 emitted from the wavelength conversion member 13 is reflected by the light shielding means 15 and / or the reflection means 16 (or directly without being reflected by the light shielding means 15 or the reflection means 16), and the peripheral end surface 13c of the wavelength conversion member 13 is used. Released from the entire circumference.
図5は、波長変換部材13の指向特性を説明するための図である。図5中、実線は波長変換部材13の、光軸AX10(ライトガイド用貫通穴11cの中心軸)を含む鉛直面で切断した断面(波長変換部材13の周端面13cの断面)における指向特性(双指向性)を表し、二点鎖線は波長変換部材13の上面13aから見た指向特性を表している。 FIG. 5 is a diagram for explaining the directivity characteristics of the wavelength conversion member 13. In FIG. 5, the solid line indicates the directional characteristics of the wavelength conversion member 13 in a cross section (cross section of the peripheral end surface 13 c of the wavelength conversion member 13) cut along a vertical plane including the optical axis AX 10 (the central axis of the light guide through hole 11 c). (Double directivity) is represented, and a two-dot chain line represents a directivity characteristic viewed from the upper surface 13 a of the wavelength conversion member 13.
波長変換部材13の上面13aが遮光手段15で覆われているため、波長変換部材13の、光軸AX10(ライトガイド用貫通穴11cの中心軸)を含む鉛直面で切断した断面(波長変換部材13の周端面13cの断面)における指向特性は、図5に実線で示すように、上下対象の双指向性の分布となる(光軸AXを含む水平面内の強度が最大となる)。 Since the upper surface 13a of the wavelength conversion member 13 is covered with a light shielding means 15, the wavelength converting member 13, section cut (wavelength conversion in the vertical plane including the optical axis AX 10 (center axis of the light guide through holes 11c) The directional characteristic in the cross section of the peripheral end surface 13c of the member 13 is a bi-directional distribution of vertical targets (the intensity in the horizontal plane including the optical axis AX is maximized) as shown by the solid line in FIG.
一方、波長変換部材13の周端面13cがリング状の面であるため、波長変換部材13の上面13aから見た指向特性は、図5に二点鎖線で示すように、波長変換部材13を中心に放射状に広がる分布となる。 On the other hand, since the peripheral end surface 13c of the wavelength conversion member 13 is a ring-shaped surface, the directivity seen from the upper surface 13a of the wavelength conversion member 13 is centered on the wavelength conversion member 13 as shown by a two-dot chain line in FIG. The distribution spreads radially.
波長変換部材13の周端面13c全周から下方に放出される白色光Ray2は、波長変換部材13の下面13bの周囲に配置された反射手段16で反射されて折り返されて上方に向かう(図2(a)参照)。 The white light Ray2 emitted downward from the entire circumference of the peripheral end surface 13c of the wavelength conversion member 13 is reflected by the reflecting means 16 disposed around the lower surface 13b of the wavelength conversion member 13 and is turned upward (FIG. 2). (See (a)).
その結果、発光装置10の、光軸AX10を含む鉛直面で切断した断面における指向特性は、図2(b)に実線で示すように、双指向性を上半分にした半双指向性の分布となる(光軸AXを含む水平面内の強度が最大となる)。 As a result, the light emitting device 10, the directivity characteristics in the cross section taken along a vertical plane including the optical axis AX 10, as shown by the solid line in FIG. 2 (b), Hanso directional distributions in upper half of the bi-directional (The intensity in the horizontal plane including the optical axis AX is maximized).
一方、波長変換部材13の周端面13cはリング状の面であるため、発光装置10の上面から見た指向特性は、図2(b)に二点鎖線で示すように、波長変換部材13を中心に放射状に広がる分布となる。 On the other hand, since the peripheral end surface 13c of the wavelength conversion member 13 is a ring-shaped surface, the directivity seen from the upper surface of the light emitting device 10 is the wavelength conversion member 13 as shown by a two-dot chain line in FIG. The distribution spreads radially in the center.
図2(b)は、発光装置10の指向特性を説明するための図である。図2(b)中、実線は発光装置10の、光軸AX10を含む鉛直面で切断した断面における指向特性(半双指向性)を表し、二点鎖線は発光装置10の上面から見た指向特性を表している。 FIG. 2B is a diagram for explaining the directivity characteristics of the light emitting device 10. In FIG. 2B, the solid line represents the directivity characteristic (semi-bidirectionality) in the cross section of the light emitting device 10 taken along the vertical plane including the optical axis AX 10 , and the two-dot chain line represents the directivity viewed from the top surface of the light emitting device 10. It represents a characteristic.
以上のように、発光装置10の指向特性は、図2(b)に実線で示す円弧を、光軸AX10を中心に360°回転させた立体形状の分布、すなわち、光軸AXを含む水平面内の強度が最大で水平面から離れるに従って強度が低下する、配光パターン(例えば、ロービーム用配光パターン)の分布に略一致した立体形状の分布となる。 As described above, the directivity characteristics of the light emitting device 10, the horizontal plane containing the arc shown by the solid line in FIG. 2 (b), the distribution of the three-dimensional shape obtained by rotating 360 ° around the optical axis AX 10, i.e., the optical axis AX The distribution is a three-dimensional shape that substantially matches the distribution of the light distribution pattern (for example, the low beam light distribution pattern), the intensity of which is the maximum and the intensity decreases as the distance from the horizontal plane increases.
以上説明したように、本実施形態の発光装置10によれば、遮光手段15及び波長変換部材13の下面13bの周囲に配置された反射手段16の作用により、波長変換部材13の周端面13cから放出される双指向性の分布を持つ光が反射されるため、双指向性を半分にした半双指向性の分布を持つ光を放出する、車両用灯具の鉛直方向の薄型化に適した発光装置10を構成することが可能となる。 As described above, according to the light emitting device 10 of the present embodiment, the light shielding unit 15 and the reflection unit 16 disposed around the lower surface 13b of the wavelength conversion member 13 act from the peripheral end surface 13c of the wavelength conversion member 13. A light emitting device that emits light with a half-bidirectional distribution that halves the bi-directionality and that is suitable for thinning the vehicle lamp in the vertical direction because the emitted light with the bi-directional distribution is reflected. 10 can be configured.
[発光装置10A]
次に、発光装置10の変形例として、双指向性の分布を持つ光を放出する発光装置10Aについて説明する。
[Light Emitting Device 10A]
Next, as a modification of the light emitting device 10, a light emitting device 10A that emits light having a bi-directional distribution will be described.
図6は、発光装置10Aの波長変換部材13周辺を拡大した拡大図である。 FIG. 6 is an enlarged view in which the periphery of the wavelength conversion member 13 of the light emitting device 10A is enlarged.
発光装置10Aは、発光装置10と比べ、反射手段16(フェルール11の上面11a)が、波長変換部材13と同径(又は略同径)で、波長変換部材13の下面13bにのみ配置されている点(すなわち、反射手段16が波長変換部材13の下面13bの外径より外側に延伸していない点)が相違する。それ以外、発光装置10と同様の構成である。以下、発光装置10との相違点を中心に説明し、発光装置10と同一の構成については同一の符号を付してその説明を省略する。 Compared with the light emitting device 10, the light emitting device 10 </ b> A has the reflecting means 16 (the upper surface 11 a of the ferrule 11) having the same diameter (or substantially the same diameter) as the wavelength converting member 13 and is disposed only on the lower surface 13 b of the wavelength converting member 13. (That is, the reflecting means 16 does not extend outward from the outer diameter of the lower surface 13b of the wavelength conversion member 13). Other than that, the configuration is the same as that of the light emitting device 10. Hereinafter, the difference from the light-emitting device 10 will be mainly described, and the same components as those of the light-emitting device 10 will be denoted by the same reference numerals and description thereof will be omitted.
波長変換部材13の上面13aが遮光手段15で覆われているため、波長変換部材13の、光軸AX10を含む鉛直面で切断した断面(波長変換部材13の周端面13cの断面)における指向特性は、図5に実線で示すように、上下対象の双指向性の分布となる(光軸AXを含む水平面内の強度が最大となる)。 Since the upper surface 13 a of the wavelength conversion member 13 is covered with the light shielding means 15, the orientation of the wavelength conversion member 13 in a cross section (cross section of the peripheral end surface 13 c of the wavelength conversion member 13) cut along a vertical plane including the optical axis AX 10. As shown by the solid line in FIG. 5, the characteristic is a bi-directional distribution of the upper and lower objects (the intensity in the horizontal plane including the optical axis AX is maximized).
一方、波長変換部材13の周端面13cがリング状の面であるため、波長変換部材13の上面13aから見た指向特性は、図5に二点鎖線で示すように、波長変換部材13を中心に放射状に広がる分布となる。 On the other hand, since the peripheral end surface 13c of the wavelength conversion member 13 is a ring-shaped surface, the directivity seen from the upper surface 13a of the wavelength conversion member 13 is centered on the wavelength conversion member 13 as shown by a two-dot chain line in FIG. The distribution spreads radially.
以上のように、発光装置10Aの指向特性は、図5に実線で示す円を、光軸AX10を中心に360°回転させた立体形状の分布、すなわち、光軸AX10を含む水平面内の強度が最大で水平面から離れるに従って強度が低下する、配光パターン(例えば、ロービーム用配光パターン)の分布に略一致した立体形状の分布となる。 As described above, the directivity characteristics of the light emitting device 10A, a circle indicated by a solid line in FIG. 5, the three-dimensional shape obtained by rotating 360 ° around the optical axis AX 10 distribution, i.e., in the horizontal plane including the optical axis AX 10 The distribution is a three-dimensional shape that substantially matches the distribution of the light distribution pattern (for example, the low-beam light distribution pattern) in which the intensity is maximum and decreases as the distance from the horizontal plane increases.
本変形例の発光装置10Aによれば、遮光手段15の作用により、双指向性の分布を持つ光を放出する、車両用灯具の鉛直方向の薄型化に適した発光装置10Aを構成することが可能となる。 According to the light-emitting device 10A of the present modification, the light-emitting device 10A that emits light having a bi-directional distribution by the action of the light shielding unit 15 and that is suitable for thinning the vehicle lamp in the vertical direction can be configured. It becomes possible.
[発光装置10B]
従来、励起光を吸収し、波長変換して所定の波長域の光を放出する波長変換部材を用いた発光装置が提案されている(例えば、特許第4379531号公報参照)。
[Light Emitting Device 10B]
Conventionally, a light-emitting device using a wavelength conversion member that absorbs excitation light, converts the wavelength, and emits light in a predetermined wavelength range has been proposed (see, for example, Japanese Patent No. 4379531).
図37は、従来の波長変換部材を用いた内視鏡用の発光装置300の例である。 FIG. 37 shows an example of a light-emitting device 300 for an endoscope using a conventional wavelength conversion member.
図37に示すように、発光装置300は、励起光源から放出された励起光を伝送するための光ファイバ等のライトガイド310、ライトガイド310の端面に配置された反射膜321、322付き波長変換部材320等を備えている。 As shown in FIG. 37, the light-emitting device 300 includes a light guide 310 such as an optical fiber for transmitting excitation light emitted from an excitation light source, and wavelength conversion with reflection films 321 and 322 disposed on the end face of the light guide 310. The member 320 etc. are provided.
上記構成の発光装置300においては、波長変換部材320は、ライトガイド310の端面から出射される励起光を吸収し、波長変換して所定の波長域の光を放出する。 In the light emitting device 300 configured as described above, the wavelength conversion member 320 absorbs excitation light emitted from the end face of the light guide 310, converts the wavelength, and emits light in a predetermined wavelength range.
しかしながら、上記構成の発光装置300においては、ライトガイド310の端面と波長変換部材320とが密着しているため、励起光の出力が上がるにつれ波長変換部材320を照射する励起光の光密度が高くなって波長変換部材320が高温となり、波長変換部材320が劣化、変色し、効率が低下するという問題がある。特に、励起光源がLD(レーザーダイオード)である場合、この問題は顕著となる。 However, in the light emitting device 300 configured as described above, since the end face of the light guide 310 and the wavelength conversion member 320 are in close contact with each other, the light density of the excitation light that irradiates the wavelength conversion member 320 increases as the output of the excitation light increases. Thus, there is a problem that the wavelength conversion member 320 becomes high temperature, the wavelength conversion member 320 is deteriorated and discolored, and the efficiency is lowered. In particular, when the excitation light source is an LD (laser diode), this problem becomes significant.
以下、発光装置10の変形例として、波長変換部材が高温となるのを抑えることが可能な(従って、励起光源を高出力化しても波長変換部材が劣化し、効率が低下するのを抑えることが可能な)発光装置10Bについて説明する。 Hereinafter, as a modification of the light emitting device 10, it is possible to suppress the wavelength conversion member from becoming high temperature (thus suppressing the deterioration of the wavelength conversion member and lowering the efficiency even when the excitation light source is increased in output). The light emitting device 10B is described.
図7は、発光装置10Bをその光軸AX10を含む鉛直面で切断した断面斜視図である。図8は、発光装置10Bをその光軸AX10を含む鉛直面で切断した断面図である。 Figure 7 is a cross-sectional perspective view obtained by cutting the light emitting device 10B in the vertical plane including the optical axis AX 10. Figure 8 is a cross-sectional view of the light emitting device 10B in the vertical plane including the optical axis AX 10.
発光装置10Bは、発光装置10と比べ、円盤型の波長変換部材13に代えてリング型の波長変換部材13Bを用いている点が相違する。それ以外、発光装置10と同様の構成である。以下、発光装置10との相違点を中心に説明し、発光装置10と同一の構成については同一の符号を付してその説明を省略する。 The light emitting device 10B is different from the light emitting device 10 in that a ring type wavelength converting member 13B is used instead of the disk type wavelength converting member 13. Other than that, the configuration is the same as that of the light emitting device 10. Hereinafter, the difference from the light-emitting device 10 will be mainly described, and the same components as those of the light-emitting device 10 will be denoted by the same reference numerals and description thereof will be omitted.
図7に示すように、波長変換部材13Bは、リング型のYAG等の蛍光体(Ce:YAG等の蛍光物質が望ましい)であり(例えば、軸方向厚み:0.2mm、径方向厚み:0.05〜0.2mm、直径:1.0mm)、そのリング内側に配置された光偏向手段17a等を備えている(本発明の発光部に相当)。 As shown in FIG. 7, the wavelength conversion member 13B is a ring-type phosphor such as YAG (a phosphor such as Ce: YAG is desirable) (for example, axial thickness: 0.2 mm, radial thickness: 0). 0.05 to 0.2 mm, diameter: 1.0 mm), and light deflection means 17a and the like disposed inside the ring (corresponding to the light emitting portion of the present invention).
波長変換部材13Bは、光偏向手段17aが形成された透明体17との接着性を高めるために、蛍光物質に樹脂などを混合した複合材料を用いてもよいし、熱伝導性を向上するために、アルミナなどを複合したものを用いてもよい。また、特許第4730227号公報に開示されているように、異種の蛍光物質を複数の領域/層で構成してもよい。波長変換部材13Bは、黄色蛍光体の濃度(例えば、Ceの添加量等)を調整することで、発光色が法規で規定されたCIE色度図上の白色範囲を満たすように調整されている。 The wavelength conversion member 13B may use a composite material in which a fluorescent material is mixed with a resin or the like in order to improve the adhesiveness with the transparent body 17 on which the light deflecting means 17a is formed, or in order to improve the thermal conductivity. In addition, a composite of alumina or the like may be used. Further, as disclosed in Japanese Patent No. 4730227, a different type of fluorescent substance may be composed of a plurality of regions / layers. The wavelength conversion member 13B is adjusted so that the emission color satisfies the white range on the CIE chromaticity diagram specified by law by adjusting the concentration of the yellow phosphor (for example, the amount of Ce added). .
光偏向手段17aは、ライトガイド12(本発明の第1光学系に相当)の出光面12bから出射される励起光源14からの励起光の進行方向を変化させて波長変換部材13Bを照射するためのものである。 The light deflection means 17a irradiates the wavelength conversion member 13B by changing the traveling direction of the excitation light from the excitation light source 14 emitted from the light exit surface 12b of the light guide 12 (corresponding to the first optical system of the present invention). belongs to.
光偏向手段17aは、ライトガイド12の出光面12bから出射される励起光源14からの励起光の進行方向を変化させて波長変換部材13Bを照射することができるものであればよく、例えば、図7、図8に示すように、波長変換部材13Bのリング内側に配置されたガラス製又は透明樹脂製の透明体17の上面中央(光軸AX10上)に、円錐型の凹部を形成し、この円錐型の凹部を遮光手段15(本発明の遮光手段に相当)で覆った円錐型反射面であってもよい。 The light deflection unit 17a may be any device that can irradiate the wavelength conversion member 13B by changing the traveling direction of the excitation light from the excitation light source 14 emitted from the light exit surface 12b of the light guide 12, for example, FIG. 7, as shown in FIG. 8, the center of the upper surface of the wavelength conversion member 13B made of glass are arranged in a ring inside or transparent resin of the transparent body 17 (optical axis AX 10 above), a recess of conical, A conical reflection surface in which the conical recess is covered with the light shielding means 15 (corresponding to the light shielding means of the present invention) may be used.
遮光手段15として反射層や反射板等の反射面を用いれば、発光部(透明体17)の上面から出射しようとする光は、遮光手段15で反射されて透明体17側に戻されるため、波長変換部材13Bの周端面13cから放出される光の取り出し効率を高めることが可能となる。 If a reflection surface such as a reflection layer or a reflection plate is used as the light shielding means 15, light that is about to be emitted from the upper surface of the light emitting portion (transparent body 17) is reflected by the light shielding means 15 and returned to the transparent body 17 side. It is possible to increase the extraction efficiency of light emitted from the peripheral end surface 13c of the wavelength conversion member 13B.
透明体17は、例えば、円形をフェルール11の上面11aに対して面直方向に引き延ばした透明円盤である。透明体17は、円形の上面、円形の下面を含んでいる。透明体17の上面中央(光軸AX10上)に形成された円錐型の凹部は、光軸AX10上に頂部を持ち、透明体17の上面に底面を持っており、ライトガイド12の出光面12bから出射される励起光の光路上(励起光の光軸と同軸上)に配置されている(図8参照)。光偏向手段17a付きの波長変換部材13Bは、透明体17の下面に設けられた位置決め用の凸部17bをフェルール11の上面11aに形成された凹部に挿入することで、フェルール11の上面11a上に位置決めされて接着されている。 The transparent body 17 is, for example, a transparent disk obtained by extending a circle in a direction perpendicular to the upper surface 11 a of the ferrule 11. The transparent body 17 includes a circular upper surface and a circular lower surface. The conical recess formed in the center of the upper surface of the transparent body 17 (on the optical axis AX 10 ) has a top on the optical axis AX 10 and a bottom on the upper surface of the transparent body 17. It is arranged on the optical path of the excitation light emitted from the surface 12b (coaxial with the optical axis of the excitation light) (see FIG. 8). The wavelength conversion member 13 </ b> B with the light deflecting unit 17 a is inserted on the concave portion formed on the upper surface 11 a of the ferrule 11 by inserting the positioning convex portion 17 b provided on the lower surface of the transparent body 17 on the upper surface 11 a of the ferrule 11. Is positioned and glued.
透明体17は、励起光源14の波長に対して透過性の高いものであればその材質は特に限定されない。例えば、透明体17は、石英、透明樹脂、単結晶サファイア、ノンドープのYAG等の透明セラミックスであってもよい。透明体17は、励起光の不要な散乱を避けるため、気孔や不純物などの散乱源を含まないほうがより望ましい。 The material of the transparent body 17 is not particularly limited as long as it is highly transmissive with respect to the wavelength of the excitation light source 14. For example, the transparent body 17 may be transparent ceramics such as quartz, transparent resin, single crystal sapphire, and non-doped YAG. In order to avoid unnecessary scattering of the excitation light, it is more preferable that the transparent body 17 does not include scattering sources such as pores and impurities.
光偏向手段17a付きの波長変換部材13Bは、例えば、次のようにして製造される。 The wavelength conversion member 13B with the light deflecting unit 17a is manufactured, for example, as follows.
まず、YAG等の蛍光体粉末を金型に入れこれをプレスして焼き固めることで、リング型の波長変換部材13Bを製造する。 First, a phosphor powder such as YAG is put into a mold, and this is pressed and baked to produce a ring-type wavelength conversion member 13B.
次に、ディスペンサ等を用い、透明樹脂(例えばシリコン樹脂)をリング型の波長変換部材13Bのリング内側に八分目程度まで充填する。その後、円錐状のプリズムをその充填された透明樹脂の中央に上方から挿入する。これにより、透明樹脂(例えばシリコン樹脂)がリング型の波長変換部材13Bのリング内側上端縁付近まで充填される。そして、透明樹脂が硬化した後、円錐状のプリズムを取り除く。これにより、硬化した透明樹脂(透明体17)の上面中央に、円錐状のプリズムの跡からなる光偏向手段17aが形成される。そして、発光部(波長変換部材13B及び透明体17)の上面を遮光部材15で覆う。 Next, using a dispenser or the like, a transparent resin (for example, silicon resin) is filled into the ring inside of the ring-type wavelength conversion member 13B up to about the eighth. Thereafter, a conical prism is inserted into the center of the filled transparent resin from above. Thereby, transparent resin (for example, silicon resin) is filled up to the vicinity of the inner edge of the ring-shaped wavelength conversion member 13B. Then, after the transparent resin is cured, the conical prism is removed. As a result, a light deflection means 17a made of a conical prism trace is formed at the center of the upper surface of the cured transparent resin (transparent body 17). And the upper surface of the light emission part (the wavelength conversion member 13B and the transparent body 17) is covered with the light shielding member 15.
以上のようにして、リング内側に光偏向手段17aが配置された波長変換部材13Bが製造される。 As described above, the wavelength conversion member 13B in which the light deflecting means 17a is disposed inside the ring is manufactured.
なお、光偏向手段17a付きの波長変換部材13Bの製造方法は上記に限定されない。例えば、上面中央(光軸AX10上)に円錐型の凹部を形成した円盤型の透明体17を先に製造し、これの周端面に対して波長変換部材を薄く塗布することで、光偏向手段17a付きの波長変換部材13Bを製造してもよい。 In addition, the manufacturing method of the wavelength conversion member 13B with the optical deflection | deviation means 17a is not limited above. For example, possible to produce a top central (optical axis AX 10 above) in conical transparent body 17 has a disk shape forming a recess in the first, thinly coated a wavelength conversion member with respect to the peripheral end face of this optical deflector You may manufacture the wavelength conversion member 13B with the means 17a.
本変形例の発光装置10Bによれば、図9に示すように、励起光源14からの励起光Ray1は、ライトガイド12の入光面12aからライトガイド12内に導入され出光面12bまで導光されて、出光面12bから出射し、透明体17内に導入されて、光偏向手段17aを照射する。 According to the light emitting device 10B of this modification, as shown in FIG. 9, the excitation light Ray1 from the excitation light source 14 is introduced from the light incident surface 12a of the light guide 12 into the light guide 12 and guided to the light output surface 12b. Then, the light exits from the light exit surface 12b, is introduced into the transparent body 17, and irradiates the light deflection means 17a.
光偏向手段17aは、これに入射する励起光Ray1の進行方向を光軸AX10に対して略垂直な方向に変化させてリング型の波長変換部材13B(リング型の波長変換部材13Bの内側リング面)を照射する。光偏向手段17aは円錐状のプリズムの跡であるため、光偏向手段17aにより進行方向が変化させられた励起光Ray1は、光軸AX10を中心に放射状に進行する。従って、光偏向手段17aにより進行方向が変化させられた励起光Ray1は、進行方向が変化させられる前と比べ、光密度が小さくなる。 Light deflector 17a is substantially varied in the direction perpendicular to the ring type wavelength conversion member 13B (ring inner ring of the wavelength conversion member 13B of the optical axis AX 10 the traveling direction of the excitation light Ray1 incident thereto Surface). Since light deflector 17a is traces of conical prisms, an excitation light Ray1 the traveling direction by the light deflecting means 17a was varied proceeds radially around the optical axis AX 10. Therefore, the excitation light Ray1 whose traveling direction is changed by the light deflecting unit 17a has a light density lower than that before the traveling direction is changed.
光偏向手段17aにより光密度が小さくなりかつ進行方向が変化させられた励起光源14からの励起光Ray1が入射したリング型の波長変換部材13Bは、励起光源14からの励起光により励起される光と波長変換部材13Bを透過する励起光源14からの励起光との混色による白色光Ray2を発する。 The ring-type wavelength conversion member 13B on which the excitation light Ray1 from the excitation light source 14 whose light density has been reduced by the light deflector 17a and whose traveling direction has been changed is incident on the ring-type wavelength conversion member 13B. And white light Ray2 generated by color mixture of excitation light from the excitation light source 14 that passes through the wavelength conversion member 13B.
波長変換部材13Bが発する白色光Ray2は、遮光手段15及び/又は反射手段16で反射されて(又は遮光手段15又は反射手段16で反射されることなく直接)、波長変換部材13Bの周端面13c全周から放出される。 The white light Ray2 emitted from the wavelength conversion member 13B is reflected by the light shielding unit 15 and / or the reflection unit 16 (or directly without being reflected by the light shielding unit 15 or the reflection unit 16), and the peripheral end surface 13c of the wavelength conversion member 13B. Released from the entire circumference.
すなわち、光偏向手段17aによって偏向された励起光が、波長変換部材13Bに入射し、一部の光は蛍光物質に吸収され波長変換光が外部に射出し、一部の光は波長変換されず、散乱されて外部に射出される。結果として、これらの光が混色された白色光が照明光として外部に射出される。 That is, the excitation light deflected by the light deflecting unit 17a enters the wavelength conversion member 13B, a part of the light is absorbed by the fluorescent material, and the wavelength converted light is emitted to the outside, and the part of the light is not wavelength-converted. Are scattered and ejected to the outside. As a result, white light in which these lights are mixed is emitted to the outside as illumination light.
発光部(波長変換部材13B及び透明体17)の上面が遮光手段15で覆われているため、発光部(波長変換部材13B及び透明体17)の、光軸AX10を含む鉛直面で切断した断面(波長変換部材13Bの周端面13cの断面)における指向特性は、図5に実線で示すように、上下対象の双指向性の分布となる(光軸AXを含む水平面内の強度が最大となる)。 Since the upper surface of the light emitting portion (wavelength conversion member 13B and the transparent body 17) is covered with a light shielding means 15, the light emitting portion (wavelength conversion member 13B and the transparent member 17), were cut with a vertical plane including the optical axis AX 10 The directivity in the cross section (the cross section of the peripheral end surface 13c of the wavelength conversion member 13B) is a bi-directional distribution of the upper and lower objects, as indicated by the solid line in FIG. 5 (the intensity in the horizontal plane including the optical axis AX is maximum). Become).
一方、波長変換部材13Bの周端面13cがリング状の面であるため、発光部(波長変換部材13B及び透明体17)の上面から見た指向特性は、図5に二点鎖線で示すように、波長変換部材13Bを中心に放射状に広がる分布となる。 On the other hand, since the peripheral end surface 13c of the wavelength conversion member 13B is a ring-shaped surface, the directivity seen from the upper surface of the light emitting part (the wavelength conversion member 13B and the transparent body 17) is as shown by a two-dot chain line in FIG. The distribution spreads radially around the wavelength conversion member 13B.
波長変換部材13Bの周端面13c全周から下方に放出される白色光Ray2は、波長変換部材13Bの下面13bの周囲に配置された反射手段16で反射されて折り返されて上方に向かう(図9参照)。 The white light Ray2 emitted downward from the entire circumference of the peripheral end surface 13c of the wavelength conversion member 13B is reflected by the reflecting means 16 disposed around the lower surface 13b of the wavelength conversion member 13B and is turned upward (FIG. 9). reference).
その結果、発光装置10Bの、光軸AX10を含む鉛直面で切断した断面における指向特性は、図9に示すように、双指向性を上半分にした半双指向性の分布となる(光軸AXを含む水平面内の強度が最大となる)。 As a result, as shown in FIG. 9, the directivity characteristic in the cross section cut by the vertical plane including the optical axis AX 10 of the light emitting device 10B becomes a half-bidirectional distribution with the upper half of the bi-directionality (optical axis). The intensity in the horizontal plane including AX is maximized).
一方、波長変換部材13Bの周端面13cはリング状の面であるため、発光装置10Bの上面から見た指向特性は、図2(b)に二点鎖線で示すように、波長変換部材13Bを中心に放射状に広がる分布となる。 On the other hand, since the peripheral end surface 13c of the wavelength conversion member 13B is a ring-shaped surface, the directivity characteristics viewed from the upper surface of the light emitting device 10B are as shown by the two-dot chain line in FIG. The distribution spreads radially in the center.
以上のように、発光装置10Bの指向特性は、図9に実線で示す円弧を、光軸AX10を中心に360°回転させた立体形状の分布、すなわち、光軸AXを含む水平面内の強度が最大で水平面から離れるに従って強度が低下する、配光パターン(例えば、ロービーム用配光パターン)の分布に略一致した立体形状の分布となる。 As described above, the directivity characteristics of the light emitting device 10B, the intensity of the horizontal plane including the arc indicated by the solid line, the distribution of the three-dimensional shape obtained by rotating 360 ° around the optical axis AX 10, i.e., the optical axis AX in FIG. 9 The distribution of the three-dimensional shape substantially coincides with the distribution of the light distribution pattern (for example, the low beam light distribution pattern) in which the intensity decreases as the distance from the horizontal plane increases.
以上説明したように、本変形例の発光装置10Bによれば、遮光手段15及び発光部(波長変換部材13B及び透明体17)の下面の周囲に配置された反射手段16の作用により、波長変換部材13Bの周端面13cから放出される双指向性の分布を持つ光が反射されるため、双指向性を半分にした半双指向性の分布を持つ光を放出する、車両用灯具の鉛直方向の薄型化に適した発光装置10Bを構成することが可能となる。 As described above, according to the light emitting device 10B of this modification, the wavelength conversion is performed by the action of the light shielding unit 15 and the reflection unit 16 disposed around the lower surface of the light emitting unit (the wavelength converting member 13B and the transparent body 17). Since the light having the bi-directional distribution emitted from the peripheral end surface 13c of the member 13B is reflected, the light in the vertical direction of the vehicular lamp that emits the light having the semi-bidirectional distribution in which the bi-directional property is halved is emitted. A light emitting device 10B suitable for thinning can be configured.
本変形例の発光装置10Bによれば、さらに次の効果を奏する。 According to the light emitting device 10B of the present modification, the following effects are further achieved.
第1に、波長変換部材13Bの温度が上昇することに起因する効率低下を抑えることが可能となる。 1stly, it becomes possible to suppress the efficiency fall resulting from the temperature of the wavelength conversion member 13B rising.
すなわち、発光装置10(図2(a)参照)や従来の発光装置300(図37参照)においては、ライトガイドの端面と波長変換部材とが密着しているため、励起光の出力が上がるにつれ波長変換部材を照射する励起光の光密度が高くなって波長変換部材が高温となり、波長変換部材が劣化、変色し、効率が低下するという問題がある。特に、励起光源がLD(レーザーダイオード)である場合、この問題は顕著となる。 That is, in the light emitting device 10 (see FIG. 2A) and the conventional light emitting device 300 (see FIG. 37), the end face of the light guide and the wavelength conversion member are in close contact with each other, so that the output of excitation light increases. There is a problem that the light density of the excitation light that irradiates the wavelength conversion member becomes high, the temperature of the wavelength conversion member becomes high, the wavelength conversion member is deteriorated and discolored, and the efficiency is lowered. In particular, when the excitation light source is an LD (laser diode), this problem becomes significant.
これに対して、本変形例の本変形例の発光装置10Bによれば、光偏向手段17aの作用により、励起光源14からの励起光の光密度を小さくしかつ進行方向を変化させた上で波長変換部材13Bを照射する構成であり、波長変換部材13Bが励起光源14による熱、高強度の光等に直接さらされることがないため、波長変換部材13Bが高温となるのを抑えることが可能となる。 On the other hand, according to the light emitting device 10B of the present modification of the present modification, the light deflection unit 17a acts to reduce the light density of the excitation light from the excitation light source 14 and change the traveling direction. The wavelength conversion member 13B is configured to irradiate, and since the wavelength conversion member 13B is not directly exposed to heat from the excitation light source 14, high-intensity light, or the like, it is possible to prevent the wavelength conversion member 13B from reaching a high temperature. It becomes.
例えば、本変形例の発光装置10Bでは、ライトガイド12の出光面12bの面積=π×0.12=π×10-2、波長変換部材13Bの周端面13cの面積=2×π×0.5×0.2=20π×10-2とすると、発光装置10と比べ、波長変換部材13Bに照射される光密度を1/20に抑えることが可能となる。 For example, in the light emitting device 10B of this modification, the area of the light exit surface 12b of the light guide 12 = π × 0.1 2 = π × 10 −2 , and the area of the peripheral end surface 13c of the wavelength conversion member 13B = 2 × π × 0.5 × 0.2. If it is set to = 20 (pi) * 10 <-2 >, compared with the light-emitting device 10, it will become possible to suppress the light density irradiated to the wavelength conversion member 13B to 1/20.
従って、本変形例の発光装置10Bによれば、励起光源14を高出力化しても波長変換部材13Bが劣化、変色し、効率が低下するのを抑えることが可能となる。また、色むらや輝度むらを生じない発光特性の良好な発光を実現することが可能となる。 Therefore, according to the light emitting device 10B of this modification, it is possible to prevent the wavelength conversion member 13B from being deteriorated or discolored even when the output of the excitation light source 14 is increased, and the efficiency from being lowered. In addition, it is possible to realize light emission with favorable light emission characteristics that does not cause color unevenness and luminance unevenness.
第2に、波長変換部材13内部で散乱を繰り返すことに起因する効率低下を抑えることが可能となる。 Second, it is possible to suppress a decrease in efficiency due to repeated scattering inside the wavelength conversion member 13.
すなわち、発光装置10(図2(a)参照)においては、中心から周端面まで密な円盤型の波長変換部材を用いているため、波長変換部材の中心から周端面までの間、波長変換部材内部で散乱を繰り返すこととなり(光が内部で閉じこめられることとなり)、光取り出し効率が低下するという問題がある。 That is, in the light emitting device 10 (see FIG. 2A), since a dense disk-shaped wavelength conversion member is used from the center to the peripheral end surface, the wavelength conversion member is provided between the center of the wavelength conversion member and the peripheral end surface. Scattering is repeated inside (light is confined inside), and there is a problem that the light extraction efficiency decreases.
これに対して、本変形例の発光装置10Bによれば、中心から周端面13cまで密な円盤型の波長変換部材13ではなく、中空のリング型の波長変換部材13Bを用いているため、波長変換部材13内部で散乱を繰り返す距離が、リング型の波長変換部材13Bの径方向厚み(例えば0.05〜0.2mm)となり、円盤型の波長変換部材13と比べ、散乱を繰り返す距離が短くなる。 On the other hand, according to the light emitting device 10B of the present modification, since the hollow ring type wavelength conversion member 13B is used instead of the dense disk type wavelength conversion member 13 from the center to the peripheral end surface 13c, the wavelength The distance at which scattering is repeated inside the conversion member 13 is the radial thickness of the ring-type wavelength conversion member 13B (for example, 0.05 to 0.2 mm), and the distance at which scattering is repeated is shorter than that of the disk-type wavelength conversion member 13. Become.
従って、本変形例の発光装置10Bによれば、波長変換部材13内部で散乱を繰り返すことに起因する効率低下を抑えることが可能となる。 Therefore, according to the light emitting device 10B of the present modification, it is possible to suppress a decrease in efficiency due to repeated scattering inside the wavelength conversion member 13.
第3に、ライトガイド12内を導光される励起光がライトガイド12と波長変換部材13との界面で反射されることに起因する効率低下を抑えることが可能となる。 Third, it is possible to suppress a decrease in efficiency due to the excitation light guided through the light guide 12 being reflected at the interface between the light guide 12 and the wavelength conversion member 13.
すなわち、発光装置10(図2(a)参照)や従来の発光装置300(図37参照)においては、屈折率が異なるライトガイドの端面と波長変換部材とが密着しているため、ライトガイド内を導光される励起光が、ライトガイドの端面から出射することなくライトガイドと波長変換部材との界面で反射し、ライトガイドを逆に通って励起光源まで導光されて、励起光源に対して悪影響を及ぼし、効率が低下するという問題がある。 That is, in the light emitting device 10 (see FIG. 2A) and the conventional light emitting device 300 (see FIG. 37), the end face of the light guide having a different refractive index and the wavelength conversion member are in close contact with each other. The excitation light guided through the light guide is reflected at the interface between the light guide and the wavelength conversion member without being emitted from the end face of the light guide, and is guided back to the excitation light source through the light guide. Adversely affecting the efficiency.
これに対して、本変形例の発光装置10Bによれば、ライトガイド12の端面(出光面12b)と波長変換部材13Bとが密着しておらず、光偏向手段17aの作用により、励起光源14からの励起光の進行方向を光軸AX10に対して略垂直な方向に変化させた上で波長変換部材13Bを照射する構成であるため、ライトガイド12内を導光される励起光がライトガイド12と波長変換部材13との界面で反射されることに起因する効率低下を抑えることが可能となる。 On the other hand, according to the light emitting device 10B of the present modification, the end face (light exit surface 12b) of the light guide 12 and the wavelength conversion member 13B are not in close contact with each other, and the excitation light source 14 is operated by the action of the light deflecting unit 17a. since it is configured to irradiate a wavelength conversion member 13B in terms of varying in a direction substantially perpendicular to the traveling direction of the excitation light with respect to the optical axis AX 10 from the excitation light light guided to the light guide 12 It is possible to suppress a reduction in efficiency due to reflection at the interface between the guide 12 and the wavelength conversion member 13.
次に、光偏向手段17aの変形例について説明する。 Next, a modified example of the light deflection unit 17a will be described.
図10、図11は、光偏向手段17aの変形例を説明するための図である。 10 and 11 are diagrams for explaining modifications of the light deflecting unit 17a.
光偏向手段17aは、図10に示すように、透明体17の上面中央(光軸AX10上)に形成された円錐型の凹部を遮光手段15で覆わない円錐型反射面であってもよい。この例では、ライトガイド12の出光面12bから出射される励起光が円錐型反射面で全反射されるように、透明体17の材質として屈折率が高いもの(例えばサファイア)を用いるのが望ましい。なお、透明体17の上面中央(光軸AX10上)のうち円錐型の凹部以外の領域及び波長変換部材13Bの上面を遮光手段15で覆うのが望ましい。 As shown in FIG. 10, the light deflecting unit 17 a may be a conical reflecting surface that does not cover the conical recess formed at the center of the upper surface of the transparent body 17 (on the optical axis AX 10 ) with the light shielding unit 15. . In this example, it is desirable to use a material having a high refractive index (for example, sapphire) as the material of the transparent body 17 so that the excitation light emitted from the light exit surface 12b of the light guide 12 is totally reflected by the conical reflection surface. . It is noted that the reason why the regions and the upper surface of the wavelength conversion member 13B other than the recess of conical of the upper surface center of the transparent body 17 (optical axis AX 10 above) covered with a shading means 15 is desirable.
あるいは、光偏向手段17aは、図11に示すように、透明体17の上面中央(光軸AX10上)に円錐型の凹部を形成することなく、透明体17の上面に散乱面(複数の微小な凹凸等)を形成し、透明体17の上面及び波長変換部材13Bの上面を遮光手段15で覆ったものであってもよい。 Alternatively, as shown in FIG. 11, the light deflecting unit 17 a can form a scattering surface (a plurality of scattering surfaces) on the upper surface of the transparent body 17 without forming a conical recess at the center of the upper surface of the transparent body 17 (on the optical axis AX 10 ). A minute unevenness or the like) may be formed, and the upper surface of the transparent body 17 and the upper surface of the wavelength conversion member 13B may be covered with the light shielding means 15.
あるいは、光偏向手段17aは、透明体17の上面中央(光軸AX10上)に円錐型の凹部を形成することなく、透明体17の上面に複数のV溝状や円錐状のプリズムカットを形成したものであってもよいし、透明体17の上面に白樹脂等の拡散反射部材を別途接着したものであってもよい。 Alternatively, the light deflecting means 17a without forming the recess of conical center of the upper surface of the transparent body 17 (optical axis AX 10 above), a plurality of V groove shape or conical prism cut into the top surface of the transparent body 17 It may be formed, or may be obtained by separately adhering a diffuse reflection member such as white resin on the upper surface of the transparent body 17.
上記各変形例によっても、発光装置10Bと同様の効果を奏することが可能となる。 Also according to each of the above modifications, it is possible to achieve the same effect as the light emitting device 10B.
[発光装置10C]
次に、発光装置10の変形例として、周端面13cの一部を遮光手段で覆った波長変換部材13Cを用いた発光装置10Cについて説明する。
[Light Emitting Device 10C]
Next, as a modification of the light emitting device 10, a light emitting device 10C using a wavelength conversion member 13C in which a part of the peripheral end surface 13c is covered with a light shielding unit will be described.
図12(a)は、発光装置10Cの波長変換部材13C周辺を拡大した拡大図である。図13は、波長変換部材13Cの斜視図である。 FIG. 12A is an enlarged view in which the periphery of the wavelength conversion member 13C of the light emitting device 10C is enlarged. FIG. 13 is a perspective view of the wavelength conversion member 13C.
発光装置10Cは、発光装置10と比べ、波長変換部材13に代えて周端面13cのうち一部範囲が遮光手段15で覆われた波長変換部材13Cを用いている点が相違する。それ以外、発光装置10と同様の構成である。以下、発光装置10との相違点を中心に説明し、発光装置10と同一の構成については同一の符号を付してその説明を省略する。 The light emitting device 10 </ b> C is different from the light emitting device 10 in that a wavelength conversion member 13 </ b> C in which a part of the peripheral end surface 13 c is covered with the light shielding unit 15 is used instead of the wavelength conversion member 13. Other than that, the configuration is the same as that of the light emitting device 10. Hereinafter, the difference from the light-emitting device 10 will be mainly described, and the same components as those of the light-emitting device 10 will be denoted by the same reference numerals and description thereof will be omitted.
図12(a)、図13に示すように、波長変換部材13Cは、その周端面13cのうち一部範囲、例えば、後述のメイン反射面22に入射する光を放出する範囲(例えば、光軸AXに対して左右120°(合計240°)の範囲)以外の範囲を遮光手段15で覆った例である。この周端面13cのうち一部範囲を覆う遮光手段15として反射層や反射板等の反射面を用いれば、波長変換部材13Cが発する光のうち波長変換部材13Cの周端面13cから出射しようとする光は、遮光手段15で反射されて波長変換部材13C側に戻されるため、波長変換部材13Cの周端面13cから放出される光の取り出し効率を高めることが可能となる。 As shown in FIGS. 12A and 13, the wavelength conversion member 13 </ b> C has a part of the peripheral end surface 13 c, for example, a range that emits light incident on a main reflection surface 22 described later (for example, an optical axis). In this example, the light shielding means 15 covers a range other than 120 ° to the left and right (range of 240 ° in total). If a reflection surface such as a reflection layer or a reflection plate is used as the light shielding means 15 that covers a part of the peripheral end surface 13c, the light emitted from the wavelength conversion member 13C tends to be emitted from the peripheral end surface 13c of the wavelength conversion member 13C. Since the light is reflected by the light shielding means 15 and returned to the wavelength conversion member 13C side, it is possible to increase the extraction efficiency of the light emitted from the peripheral end surface 13c of the wavelength conversion member 13C.
波長変換部材13Cの上面13a及び周端面13cの一部範囲が遮光手段15で覆われているため、発光装置10Cの、光軸AX10を含む鉛直面で切断した断面における指向特性は、図12(b)に実線で示すように、双指向性を上半分にした片半双指向性の分布となる(光軸AXを含む水平面内の強度が最大となる)。 Because some range of the upper surface 13a and the peripheral edge surface 13c of the wavelength conversion member 13C is covered with a light shielding means 15, the directivity characteristics in the light-emitting device 10C, taken along a vertical plane including the optical axis AX 10 cross section, FIG. 12 As shown by a solid line in (b), the distribution becomes a half-bidirectional distribution in which the bidirectionality is made the upper half (the intensity in the horizontal plane including the optical axis AX is maximized).
一方、波長変換部材13Cの周端面13cはリング状の面であるため、発光装置10Cの上面から見た指向特性は、図12(b)に二点鎖線で示すように、波長変換部材13Cを中心に放射状に広がる分布となる。 On the other hand, since the peripheral end surface 13c of the wavelength conversion member 13C is a ring-shaped surface, the directivity seen from the upper surface of the light emitting device 10C is the wavelength conversion member 13C as shown by a two-dot chain line in FIG. The distribution spreads radially in the center.
以上のように、発光装置10Cの指向特性は、図12(b)に実線で示す円弧を、光軸AX10を中心に、車両後方側に延びる光軸AXに対して左右120°(合計240°)回転させた立体形状の分布、すなわち、光軸AXを含む水平面内の強度が最大で水平面から離れるに従って強度が低下する、配光パターン(例えば、ロービーム用配光パターン)の分布に略一致した立体形状の分布となる。 As described above, the directivity characteristics of the light emitting device 10C are as follows. The arc indicated by the solid line in FIG. 12B is 120 ° to the left and right with respect to the optical axis AX extending toward the rear of the vehicle with the optical axis AX 10 as the center. °) Rotated three-dimensional shape distribution, that is, approximately the same as the distribution of the light distribution pattern (for example, the light distribution pattern for low beam) where the intensity in the horizontal plane including the optical axis AX is maximum and decreases as the distance from the horizontal plane increases. The distribution of the three-dimensional shape.
図12(b)は、発光装置10Cの指向特性を説明するための図である。図12(b)中、実線は発光装置10Cの、光軸AX10を含む鉛直面で切断した断面における指向特性(半双指向性)を表し、二点鎖線は発光装置10Cの上面から見た指向特性を表している。 FIG. 12B is a diagram for explaining the directivity characteristics of the light emitting device 10C. 12 in (b), the solid line of the light emitting device 10C, showing the directivity characteristics in the section cut by the vertical plane including the optical axis AX 10 (Hanso directional), directional two-dot chain line as viewed from the upper surface of the light emitting device 10C It represents a characteristic.
以上説明したように、本変形例の発光装置10Cによれば、遮光手段15及び波長変換部材13Cの下面13bの周囲に配置された反射手段16の作用により、波長変換部材13Cの周端面13cから放出される双指向性の分布を持つ光が反射されるため、双指向性を半分にした片半双指向性の分布を持つ光を放出する、車両用灯具の鉛直方向の薄型化に適した発光装置10Cを構成することが可能となる。 As described above, according to the light emitting device 10C of the present modification, the light shielding unit 15 and the reflecting unit 16 disposed around the lower surface 13b of the wavelength conversion member 13C act from the peripheral end surface 13c of the wavelength conversion member 13C. Light emitted with a bi-directional distribution is reflected, so it emits light with a half-bi-directional distribution that halves the bi-directional characteristics. The apparatus 10C can be configured.
また、本変形例の発光装置10Cによれば、波長変換部材13Cの周端面13cのうち一部範囲を覆う遮光手段15の作用により、波長変換部材13Cの周端面13cからグレア等の原因となる光が放出されるのを防止することが可能となる。 Further, according to the light emitting device 10C of the present modification, glare or the like is caused from the peripheral end surface 13c of the wavelength conversion member 13C by the action of the light shielding means 15 that covers a part of the peripheral end surface 13c of the wavelength conversion member 13C. It is possible to prevent light from being emitted.
以上、発光装置10を構成する波長変換部材13に代えて周端面13cのうち一部範囲が遮光手段15で覆われた波長変換部材13Cを用いて発光装置10Cを構成する例について説明したが、本発明はこれに限定されない。 The example in which the light emitting device 10C is configured using the wavelength converting member 13C in which a part of the peripheral end surface 13c is covered with the light shielding unit 15 instead of the wavelength converting member 13 configuring the light emitting device 10 has been described. The present invention is not limited to this.
例えば、発光装置10Aを構成する波長変換部材13に代えて周端面13cのうち一部範囲が遮光手段15で覆われた波長変換部材13を用いても、発光装置10Cと同様の発光装置を構成することが可能である。 For example, even if the wavelength conversion member 13 in which a part of the peripheral end surface 13c is covered with the light shielding means 15 is used instead of the wavelength conversion member 13 constituting the light emitting device 10A, a light emitting device similar to the light emitting device 10C is configured. Is possible.
また、発光装置10Bを構成する波長変換部材13Bに代えて周端面13cのうち一部範囲が遮光手段15で覆われた波長変換部材13Bを用いても、発光装置10Cと同様の発光装置を構成することが可能である。 Further, even if the wavelength conversion member 13B in which a part of the peripheral end surface 13c is covered with the light shielding means 15 is used instead of the wavelength conversion member 13B constituting the light emitting device 10B, a light emitting device similar to the light emitting device 10C is configured. Is possible.
[発光装置10D]
次に、発光装置10の変形例として、周端面13cのうち一部をカットし、その断面を遮光手段で覆った波長変換部材13Dを用いた発光装置10Dについて説明する。
[Light Emitting Device 10D]
Next, as a modification of the light emitting device 10, a light emitting device 10D using a wavelength conversion member 13D in which a part of the peripheral end surface 13c is cut and the cross section thereof is covered with a light shielding unit will be described.
図14は、波長変換部材13Dの斜視図である。 FIG. 14 is a perspective view of the wavelength conversion member 13D.
発光装置10Dは、発光装置10と比べ、波長変換部材13に代えて周端面13cの一部がカットされ、その断面が遮光手段15で覆われた波長変換部材13Dを用いている点が相違する。それ以外、発光装置10と同様の構成である。以下、発光装置10との相違点を中心に説明し、発光装置10と同一の構成については同一の符号を付してその説明を省略する。 The light emitting device 10 </ b> D is different from the light emitting device 10 in that a wavelength converting member 13 </ b> D in which a part of the peripheral end surface 13 c is cut instead of the wavelength converting member 13 and the cross section is covered with the light shielding unit 15 is used. . Other than that, the configuration is the same as that of the light emitting device 10. Hereinafter, the difference from the light-emitting device 10 will be mainly described, and the same components as those of the light-emitting device 10 will be denoted by the same reference numerals and description thereof will be omitted.
図14に示すように、波長変換部材13Dは、その周端面13cのうち一部範囲、例えば、後述のメイン反射面22に入射する光を放出する範囲(例えば、光軸AXに対して左右120°(合計240°)の範囲)以外の範囲をカットし、その断面を遮光手段15で覆った例である。この周端面13cのうち一部範囲を覆う遮光手段15として反射層や反射板等の反射面を用いれば、波長変換部材13Dが発する光のうち波長変換部材13Dの周端面13cから出射しようとする光は、遮光手段15で反射されて波長変換部材13D側に戻されるため、波長変換部材13Dの周端面13cから放出される光の取り出し効率を高めることが可能となる。 As shown in FIG. 14, the wavelength conversion member 13D has a part of its peripheral end surface 13c, for example, a range that emits light incident on a main reflection surface 22 described later (for example, 120 on the left and right sides with respect to the optical axis AX). This is an example in which a range other than ° (range of 240 ° in total) is cut and the cross section is covered with the light shielding means 15. If a reflection surface such as a reflection layer or a reflection plate is used as the light shielding means 15 that covers a part of the peripheral end surface 13c, the light from the wavelength conversion member 13D is about to be emitted from the peripheral end surface 13c of the wavelength conversion member 13D. Since the light is reflected by the light shielding means 15 and returned to the wavelength conversion member 13D side, it is possible to increase the extraction efficiency of the light emitted from the peripheral end surface 13c of the wavelength conversion member 13D.
波長変換部材13Dの上面13a及びカットされた断面が遮光手段15で覆われているため、発光装置10Dの、光軸AX10を含む鉛直面で切断した断面における指向特性は、図12(b)に実線で示すように、双指向性を上半分にした片半双指向性の分布となる(光軸AXを含む水平面内の強度が最大となる)。 Since the upper surface 13a and the cut cross section of the wavelength conversion member 13D are covered with the light shielding means 15, the directivity characteristic in the cross section cut by the vertical plane including the optical axis AX 10 of the light emitting device 10D is shown in FIG. As shown by a solid line, the distribution is a half-bidirectional distribution in which the bidirectionality is made the upper half (the intensity in the horizontal plane including the optical axis AX is maximized).
一方、波長変換部材13Dの周端面13cはリング状の面であるため、発光装置10Dの上面から見た指向特性は、図12(b)に二点鎖線で示すように、波長変換部材13Dを中心に放射状に広がる分布となる。 On the other hand, since the peripheral end surface 13c of the wavelength conversion member 13D is a ring-shaped surface, the directivity seen from the upper surface of the light emitting device 10D is the wavelength conversion member 13D as shown by a two-dot chain line in FIG. The distribution spreads radially in the center.
以上のように、発光装置10Dの指向特性は、図12(b)に実線で示す円弧を、光軸AX10を中心に、車両後方側に延びる光軸AXに対して左右120°(合計240°)回転させた立体形状の分布、すなわち、光軸AXを含む水平面内の強度が最大で水平面から離れるに従って強度が低下する、配光パターン(例えば、ロービーム用配光パターン)の分布に略一致した立体形状の分布となる。 As described above, the directivity characteristic of the light emitting device 10D is that the arc indicated by the solid line in FIG. 12B is 120 ° to the left and right with respect to the optical axis AX extending on the vehicle rear side with the optical axis AX 10 as the center (240 in total). °) Rotated three-dimensional shape distribution, that is, approximately the same as the distribution of the light distribution pattern (for example, the light distribution pattern for low beam) where the intensity in the horizontal plane including the optical axis AX is maximum and decreases as the distance from the horizontal plane increases. The distribution of the three-dimensional shape.
以上説明したように、本変形例の発光装置10Dによれば、遮光手段15及び波長変換部材13Dの下面13bの周囲に配置された反射手段16の作用により、波長変換部材13Dの周端面13cから放出される双指向性の分布を持つ光が反射されるため、双指向性を半分にした片半双指向性の分布を持つ光を放出する、車両用灯具の鉛直方向の薄型化に適した発光装置10Dを構成することが可能となる。 As described above, according to the light emitting device 10D of the present modification, the light shielding device 15 and the reflecting means 16 disposed around the lower surface 13b of the wavelength conversion member 13D act from the peripheral end surface 13c of the wavelength conversion member 13D. Light emitted with a bi-directional distribution is reflected, so it emits light with a half-bi-directional distribution that halves the bi-directional characteristics. The device 10D can be configured.
また、本変形例の発光装置10Dによれば、波長変換部材13Dの周端面13cのうち一部範囲を覆う遮光手段15の作用により、波長変換部材13Dの周端面13cからグレア等の原因となる光が放出されるのを防止することが可能となる。 Further, according to the light emitting device 10D of the present modification, glare or the like is caused from the peripheral end surface 13c of the wavelength conversion member 13D by the action of the light shielding means 15 that covers a part of the peripheral end surface 13c of the wavelength conversion member 13D. It is possible to prevent light from being emitted.
また、本変形例の発光装置10Dによれば、カットの箇所に基づき、波長変換部材13Dの周端面13cに対する遮光手段15の設定範囲を容易に把握することが可能となる。 Further, according to the light emitting device 10D of the present modification, it is possible to easily grasp the setting range of the light shielding unit 15 with respect to the peripheral end surface 13c of the wavelength conversion member 13D based on the cut location.
また、本変形例の発光装置10Dによれば、カットの箇所に基づき、波長変換部材13Dの取付相手(本変形例では、フェルール11の上面11a)に対する取付方向等を容易に把握することが可能となる。 Further, according to the light emitting device 10D of the present modification, it is possible to easily grasp the mounting direction and the like of the wavelength conversion member 13D with respect to the mounting partner (in this modification, the upper surface 11a of the ferrule 11) based on the cut location. It becomes.
以上、発光装置10を構成する波長変換部材13に代えて周端面13cのうち一部をカットし、その断面を遮光手段15で覆った波長変換部材13Dを用いて発光装置10Dを構成する例について説明したが、本発明はこれに限定されない。 As mentioned above, it replaces with the wavelength conversion member 13 which comprises the light-emitting device 10, About the example which comprises light-emitting device 10D using the wavelength conversion member 13D which cut a part among the peripheral end surfaces 13c, and covered the cross section with the light-shielding means 15 Although described, the present invention is not limited to this.
例えば、発光装置10Aを構成する波長変換部材13に代えて周端面13cのうち一部をカットし、その断面を遮光手段15で覆った波長変換部材13を用いても、発光装置10Dと同様の発光装置を構成することが可能である。 For example, instead of the wavelength conversion member 13 constituting the light emitting device 10A, a part of the peripheral end surface 13c is cut, and the wavelength conversion member 13 whose cross section is covered with the light shielding means 15 is used. A light-emitting device can be formed.
また、発光装置10Bを構成する波長変換部材13Bに代えて周端面13cのうち一部をカットし、その断面を遮光手段15で覆った波長変換部材13Bを用いても、発光装置10Dと同様の発光装置を構成することが可能である。 In addition, even if the wavelength conversion member 13B in which a part of the peripheral end surface 13c is cut and the cross section thereof is covered with the light shielding unit 15 is used instead of the wavelength conversion member 13B constituting the light emitting device 10B, the same as the light emitting device 10D is used. A light-emitting device can be formed.
[発光装置10E]
次に、発光装置10の変形例として、三角柱型の波長変換部材13Eを用いた発光装置10Eについて説明する。
[Light Emitting Device 10E]
Next, as a modification of the light emitting device 10, a light emitting device 10E using a triangular prism type wavelength conversion member 13E will be described.
図15(a)は、波長変換部材13Eの斜視図である。 FIG. 15A is a perspective view of the wavelength conversion member 13E.
発光装置10Eは、発光装置10と比べ、円盤型の波長変換部材13に代えて三角柱型の波長変換部材13Eを用いている点が相違する。それ以外、発光装置10と同様の構成である。以下、発光装置10との相違点を中心に説明し、発光装置10と同一の構成については同一の符号を付してその説明を省略する。 The light emitting device 10E is different from the light emitting device 10 in that a triangular prism type wavelength conversion member 13E is used instead of the disk type wavelength conversion member 13. Other than that, the configuration is the same as that of the light emitting device 10. Hereinafter, the difference from the light-emitting device 10 will be mainly described, and the same components as those of the light-emitting device 10 will be denoted by the same reference numerals and description thereof will be omitted.
図15(a)に示すように、波長変換部材13Eは、三角形(光軸AX上の一辺と光軸AX10上の一辺を持つ三角形)を光軸AXと光軸AX10を含む鉛直面に対して面直方向にかつ対称に引き延ばした三角柱型のYAG等の蛍光体であり、矩形の底面13d、前端側が後端側の下方に位置するように、水平面に対して傾斜して配置された傾斜面13e、車両後方側の鉛直面13fを含んでいる。 As shown in FIG. 15 (a), the wavelength conversion member 13E has a triangle (a triangle with one side on the side with the optical axis AX 10 on the optical axis AX) in a vertical plane including the optical axis AX and the optical axis AX 10 It is a fluorescent material such as a triangular prism type YAG that extends in a direction perpendicular to the plane and symmetrically, and is arranged with a rectangular bottom surface 13d and inclined with respect to the horizontal plane so that the front end side is located below the rear end side. An inclined surface 13e and a vertical surface 13f on the vehicle rear side are included.
波長変換部材13Eの傾斜面13eは、遮光手段15で覆われている。遮光手段15として反射層や反射板等の反射面を用いれば、波長変換部材13Eが発する光のうち波長変換部材13Eの傾斜面13eから出射しようとする光は、遮光手段15で反射されて波長変換部材13E側に戻されるため、波長変換部材13Eの傾斜面13eから放出される光の取り出し効率を高めることが可能となる。 The inclined surface 13e of the wavelength conversion member 13E is covered with the light shielding means 15. If a reflection surface such as a reflection layer or a reflection plate is used as the light shielding means 15, light that is going to be emitted from the inclined surface 13e of the wavelength conversion member 13E out of the light emitted from the wavelength conversion member 13E is reflected by the light shielding means 15 and has a wavelength. Since the light is returned to the conversion member 13E side, it is possible to increase the extraction efficiency of light emitted from the inclined surface 13e of the wavelength conversion member 13E.
波長変換部材13Eの底面13dは、フェルール11の上面11a(反射手段16)のうちライトガイド用貫通穴11c周囲の領域に接着されて、ライトガイド用貫通穴11c(ライトガイド12の出光面12b)を覆っている。 The bottom surface 13d of the wavelength conversion member 13E is adhered to a region around the light guide through hole 11c on the upper surface 11a (reflecting means 16) of the ferrule 11, and the light guide through hole 11c (the light exit surface 12b of the light guide 12). Covering.
本変形例の発光装置10Eによれば、励起光源14からの励起光は、ライトガイド12の入光面12aからライトガイド12内に導入され出光面12bまで導光されて、出光面12bから出射し、波長変換部材13Eを照射する。 According to the light emitting device 10E of this modification, the excitation light from the excitation light source 14 is introduced into the light guide 12 from the light incident surface 12a of the light guide 12 and guided to the light output surface 12b, and is emitted from the light output surface 12b. Then, the wavelength conversion member 13E is irradiated.
励起光源14からの励起光が入射した波長変換部材13Eは、励起光源14からの励起光により励起される光と波長変換部材13Eを透過する励起光源14からの励起光との混色による白色光を発する。 The wavelength conversion member 13E on which the excitation light from the excitation light source 14 has entered the white light due to the color mixture of the light excited by the excitation light from the excitation light source 14 and the excitation light from the excitation light source 14 that passes through the wavelength conversion member 13E. To emit.
波長変換部材13Eが発する白色光は、遮光手段15及び/又は反射手段16で反射されて(又は遮光手段15又は反射手段16で反射されることなく直接)、波長変換部材13Eの鉛直面13fから放出される。 The white light emitted from the wavelength conversion member 13E is reflected by the light shielding means 15 and / or the reflection means 16 (or directly without being reflected by the light shielding means 15 or the reflection means 16), and is emitted from the vertical surface 13f of the wavelength conversion member 13E. Released.
波長変換部材13Eの傾斜面13eが遮光手段15で覆われているため、波長変換部材13Eの、光軸AX及び光軸AX10を含む鉛直面で切断した断面(波長変換部材13Eの鉛直面13eの断面)における指向特性は、上下対象の双指向性の分布となる(光軸AXを含む水平面内の強度が最大となる)。 Since the inclined surface 13e of the wavelength conversion member 13E is covered with a light shielding means 15, the wavelength conversion member 13E, a vertical surface 13e of the optical axis AX and the optical axis AX 10 taken along a vertical plane including a cross section (wavelength conversion member 13E The directional characteristic in the cross section) is a bi-directional distribution of the upper and lower objects (the intensity in the horizontal plane including the optical axis AX is maximized).
波長変換部材13Eの傾斜面13eから下方に放出される白色光は、波長変換部材13Eの底面13dの周囲に配置された反射手段16で反射されて折り返されて上方に向かう。 The white light emitted downward from the inclined surface 13e of the wavelength conversion member 13E is reflected by the reflecting means 16 disposed around the bottom surface 13d of the wavelength conversion member 13E and is turned upward.
その結果、発光装置10Eの、光軸AX10を含む鉛直面で切断した断面における指向特性は、図15(b)に円弧で示すように、双指向性を上半分にした片半双指向性の分布となる(光軸AXを含む水平面内の強度が最大となる)。 As a result, the directivity characteristic in the cross section cut by the vertical plane including the optical axis AX 10 of the light emitting device 10E is one-half bi-directional with the bi-directional property set to the upper half as shown by an arc in FIG. Distribution (the intensity in the horizontal plane including the optical axis AX is maximized).
図15(b)は、発光装置10Eの指向特性を説明するための図である。図15(b)中の円弧は発光装置10Eの、光軸AX及び光軸AX10を含む鉛直面で切断した断面における指向特性を表している。 FIG. 15B is a diagram for explaining the directivity characteristics of the light emitting device 10E. Arc 15 in (b) shows the directivity characteristic in the section taken along a vertical plane including the light emitting device 10E, the optical axis AX and the optical axis AX 10.
以上のように、発光装置10Eの指向特性は、図15(b)に実線で示す円弧を、光軸AXと光軸AX10を含む鉛直面に対して面直方向にかつ対称に引き延ばした立体形状の分布、すなわち、光軸AXを含む水平面内の強度が最大で水平面から離れるに従って強度が低下する、配光パターン(例えば、ロービーム用配光パターン)の分布に略一致した立体形状の分布となる。 As described above, the directivity characteristics of the light emitting device 10E has an arc indicated by the solid line in FIG. 15 (b), was drawn down and symmetrically in the orthogonal direction with respect to the vertical plane including the optical axis AX and the optical axis AX 10 solid The distribution of the shape, that is, the distribution of the three-dimensional shape that substantially matches the distribution of the light distribution pattern (for example, the light distribution pattern for low beam) whose intensity in the horizontal plane including the optical axis AX is maximum and decreases as the distance from the horizontal plane increases. Become.
以上説明したように、本変形例の発光装置10Eによれば、遮光手段15及び波長変換部材13Eの底面13dの周囲に配置された反射手段16の作用により、波長変換部材13Eの鉛直面13fから放出される双指向性の分布を持つ光が反射されるため、双指向性を半分にした片半双指向性の分布を持つ光を放出する、車両用灯具の鉛直方向の薄型化に適した発光装置10Eを構成することが可能となる。 As described above, according to the light emitting device 10E of the present modification, the action of the light shielding unit 15 and the reflection unit 16 disposed around the bottom surface 13d of the wavelength conversion member 13E causes the vertical surface 13f of the wavelength conversion member 13E. Light emitted with a bi-directional distribution is reflected, so it emits light with a half-bi-directional distribution that halves the bi-directional characteristics. The apparatus 10E can be configured.
以上、発光装置10を構成する波長変換部材13に代えて三角柱型の波長変換部材13Eを用いて発光装置10Eを構成する例について説明したが、本発明はこれに限定されない。 The example in which the light emitting device 10E is configured using the triangular prism type wavelength converting member 13E instead of the wavelength converting member 13 that configures the light emitting device 10 has been described, but the present invention is not limited thereto.
例えば、発光装置10Aを構成する波長変換部材13に代えて三角柱型の波長変換部材13Eを用いても、発光装置10Eと同様の発光装置を構成することが可能である。 For example, a light emitting device similar to the light emitting device 10E can be configured by using a triangular prism type wavelength converting member 13E instead of the wavelength converting member 13 constituting the light emitting device 10A.
また、発光装置10Bを構成する波長変換部材13Bに代えて三角柱型の波長変換部材13Eを用いても、発光装置10Eと同様の発光装置を構成することが可能である。 Further, even if a triangular prism-type wavelength conversion member 13E is used instead of the wavelength conversion member 13B constituting the light-emitting device 10B, a light-emitting device similar to the light-emitting device 10E can be configured.
[車両用灯具ユニットの構成例1]
次に、上記構成の発光装置10を用いた車両用灯具ユニット20の構成例について説明する。
[Example 1 of configuration of vehicle lamp unit]
Next, a configuration example of the vehicle lamp unit 20 using the light emitting device 10 having the above configuration will be described.
本実施形態の車両用灯具ユニット20は、自動車等の車両の前面の左右両側に配置されて車両用前照灯を構成している。図16は発光装置10を用いた車両用灯具ユニット20の構成例、図17は車両用灯具ユニット20の斜視図、図18(a)は上面図、図18(b)は正面図、図18(c)は側面図である。 The vehicular lamp unit 20 of the present embodiment is disposed on both the left and right sides of the front surface of a vehicle such as an automobile to constitute a vehicular headlamp. 16 is a configuration example of a vehicle lamp unit 20 using the light emitting device 10, FIG. 17 is a perspective view of the vehicle lamp unit 20, FIG. 18 (a) is a top view, FIG. 18 (b) is a front view, FIG. (C) is a side view.
図16に示すように、車両用灯具ユニット20は、前面レンズ91とハウジング92とで区画された灯室93内に配置されている。車両用灯具ユニット20には、その光軸調整が可能なように公知のエイミング機構(図示せず)が連結されている。 As shown in FIG. 16, the vehicular lamp unit 20 is disposed in a lamp chamber 93 defined by a front lens 91 and a housing 92. A known aiming mechanism (not shown) is connected to the vehicle lamp unit 20 so that the optical axis can be adjusted.
図1、図16〜図18に示すように、車両用灯具ユニット20は、ロービーム用配光パターンを形成するように構成されたプロジェクタ型の灯具ユニットであり、投影レンズ21、発光装置10、メイン反射面22、シェード23、第1サブ反射面24、第2サブ反射面25、ミラーシェード兼保持部材26等を備えている。なお、発光装置10に代えて、発光装置10A〜10E又は後述の発光装置10F〜10Hを用いてもよい。 As shown in FIGS. 1 and 16 to 18, the vehicular lamp unit 20 is a projector-type lamp unit configured to form a low-beam light distribution pattern, and includes a projection lens 21, a light-emitting device 10, a main lamp unit, and the like. A reflection surface 22, a shade 23, a first sub-reflection surface 24, a second sub-reflection surface 25, a mirror shade and holding member 26, and the like are provided. In place of the light emitting device 10, light emitting devices 10A to 10E or light emitting devices 10F to 10H described later may be used.
図1に示すように、発光装置10を構成するフェルール11は、コネクタ96をミラーシェード兼保持部材26にネジ止め固定することにより(又はコネクタ96をミラーシェード兼保持部材26に係合させることにより)着脱自在に固定されている。コネクタ96としては、例えば、JIS規格のFCコネクタやSCコネクタ等の公知のものを用いることが可能である。 As shown in FIG. 1, the ferrule 11 constituting the light emitting device 10 is fixed by screwing and fixing the connector 96 to the mirror shade and holding member 26 (or by engaging the connector 96 with the mirror shade and holding member 26. ) It is detachably fixed. As the connector 96, for example, a known connector such as a JIS standard FC connector or SC connector can be used.
図1に示すように、投影レンズ21は、アルミ等の金属製ミラーシェード兼保持部材26に保持されて、車両前後方向に延びる光軸AX上に配置されている。 As shown in FIG. 1, the projection lens 21 is held on a metal mirror shade and holding member 26 such as aluminum, and is disposed on an optical axis AX extending in the vehicle front-rear direction.
投影レンズ21は、例えば、車両前方側表面が凸面で車両後方側表面が平面の平凸非球面の投影レンズである。図16に示すように、投影レンズ21は、エクステンション94に形成された開口94aから露出するとともに、その外周縁がエクステンション94で覆われている。 The projection lens 21 is, for example, a plano-convex aspherical projection lens having a convex front surface and a flat rear surface. As shown in FIG. 16, the projection lens 21 is exposed from an opening 94 a formed in the extension 94, and its outer peripheral edge is covered with the extension 94.
図1に示すように、発光装置10は、その反射手段16を、光軸AXを含む上向きの水平面とした状態で、ミラーシェード兼保持部材26に固定されている。光軸AXは、波長変換部材13の中心を通っている(図3、図4参照)。従って、発光装置10の指向特性は、図2(b)に示すように、光軸AXを含む水平面内の強度が最大の半双指向性の分布となる。 As shown in FIG. 1, the light emitting device 10 is fixed to the mirror shade and holding member 26 in a state where the reflecting means 16 is an upward horizontal plane including the optical axis AX. The optical axis AX passes through the center of the wavelength conversion member 13 (see FIGS. 3 and 4). Therefore, as shown in FIG. 2B, the directivity characteristic of the light emitting device 10 has a half-bidirectional distribution with the maximum intensity in the horizontal plane including the optical axis AX.
図1に示すように、メイン反射面22は、第1焦点F122が波長変換部材13近傍に設定され、第2焦点F222が投影レンズ21の車両後方側焦点F21近傍に設定された回転楕円系の反射面(回転楕円面又はこれに類する自由曲面等)である。 As shown in FIG. 1, the main reflecting surface 22, rotating the first focus F1 22 is set in the vicinity of the wavelength conversion member 13, the second focal point F2 22 is set to the vehicle near the rear side focal point F 21 of the projection lens 21 It is an elliptical reflecting surface (a spheroid or similar free-form surface).
図19は車両用灯具ユニット20をその光軸AXを含む水平面で切断した断面図(光路含む)、図20は車両用灯具ユニット20をその光軸AXを含む鉛直面で切断した断面図(光路含む)である。 19 is a cross-sectional view (including an optical path) of the vehicular lamp unit 20 cut along a horizontal plane including the optical axis AX, and FIG. 20 is a cross-sectional view (optical path) of the vehicular lamp unit 20 cut along a vertical plane including the optical axis AX. Included).
メイン反射面22は、発光装置10からの光、例えば、図2(b)に実線で示す円弧を、光軸AX10を中心に、車両後方側に延びる光軸AXに対して左右120°(合計240°)回転させた立体形状の分布の光が入射するように、波長変換部材13(周端面13c)を覆っている。具体的には、メイン反射面22は、波長変換部材13の周囲、例えば、車両後方側に延びる光軸AXに対して左右120°(合計240°)の範囲(図19参照)から上方に延びて、波長変換部材13(周端面13c)を覆っている(図1、図18(a)、図18(c)、図19参照)。メイン反射面22の下端縁22aは、光軸AXを含む水平面上に位置している(図1参照)。 The main reflecting surface 22 is light 120 degrees from the light emitting device 10, for example, an arc indicated by a solid line in FIG. 2B with respect to the optical axis AX extending to the vehicle rear side with the optical axis AX 10 as the center ( The wavelength conversion member 13 (circumferential end face 13c) is covered so that light having a three-dimensional distribution rotated by 240 ° in total is incident. Specifically, the main reflection surface 22 extends upward from a range of 120 ° to the left and right (total 240 °) (see FIG. 19) around the wavelength conversion member 13, for example, the optical axis AX extending to the vehicle rear side. The wavelength conversion member 13 (the peripheral end surface 13c) is covered (see FIGS. 1, 18A, 18C, and 19). The lower end edge 22a of the main reflecting surface 22 is located on a horizontal plane including the optical axis AX (see FIG. 1).
従って、波長変換部材13の周端面13c(光軸AXに対して左右120°(合計240°)の範囲)から放出される相対的に高い光度の光Ray2(例えば、光度の割合が50%となる半値角から内の光(半双指向性))は、メイン反射面22のうち光軸AXを含む水平面近傍の領域22bに入射する(図19、図20参照)。 Accordingly, the light Ray2 having a relatively high luminous intensity (for example, the luminous intensity ratio is 50%) emitted from the peripheral end surface 13c of the wavelength conversion member 13 (in the range of 120 ° to the left and right with respect to the optical axis AX (total 240 °)) The light within the half-value angle (semi-bidirectionality) enters the region 22b in the vicinity of the horizontal plane including the optical axis AX of the main reflecting surface 22 (see FIGS. 19 and 20).
メイン反射面22(領域22b)は鉛直方向では楕円であるため、鉛直方向に関しては、メイン反射面22(領域22b)からの相対的に高い光度の反射光Ray2は、第2焦点F222に集光し投影レンズ21でほぼ平行光線となる(図20参照)。一方、メイン反射面22(領域22b)は水平方向では楕円ではないため、水平方向に関しては、投影レンズ21を透過したメイン反射面22(領域22b)からの相対的に高い光度の反射光Ray2は、いったん交差した後、水平方向に拡散される(図19参照)。これにより、図21に示すように、鉛直方向に薄く水平方向(左右方向)に広がりのある高い照度の部分配光パターンP1(高照度帯)が形成される。図21は、車両用灯具ユニット20により形成される部分配光パターンP1の例である。 Since the main reflection surface 22 (region 22b) is elliptical in the vertical direction, the reflected light Ray2 having a relatively high luminous intensity from the main reflection surface 22 (region 22b) is collected at the second focal point F2 22 in the vertical direction. The light is projected and becomes almost parallel light by the projection lens 21 (see FIG. 20). On the other hand, since the main reflection surface 22 (region 22b) is not elliptical in the horizontal direction, the reflected light Ray2 having a relatively high luminous intensity from the main reflection surface 22 (region 22b) transmitted through the projection lens 21 is horizontal. Once crossed, it is diffused in the horizontal direction (see FIG. 19). As a result, as shown in FIG. 21, a partial illumination pattern P1 (high illuminance band) with high illuminance that is thin in the vertical direction and spreads in the horizontal direction (left and right direction) is formed. FIG. 21 is an example of a partial distribution light pattern P1 formed by the vehicular lamp unit 20.
なお、メイン反射面22は、波長変換部材13の周囲に配置されていればよく、光軸AXに対して左右120°(合計240°)の範囲に限定されず、適宜の範囲に配置することが可能である。 The main reflection surface 22 only needs to be disposed around the wavelength conversion member 13 and is not limited to the range of 120 ° to the left and right (240 ° in total) with respect to the optical axis AX, and is disposed in an appropriate range. Is possible.
図1に示すように、シェード23は、投影レンズ21の車両後方側焦点F21から発光装置10(波長変換部材13)側に延びるミラー面23aを含んでいる。シェード23の前端縁は、投影レンズ21の車両後方側の焦点面に沿って凹に湾曲している。ミラー面23aに入射し上向きに反射される光は投影レンズ21で屈折して路面方向に向かう。すなわち、ミラー面23aに入射した光がカットオフラインを境に折り返されてカットオフライン以下の配光パターンに重畳される形となる。これにより、図21に示すように、ロービーム用配光パターンP1の上端縁にカットオフラインCLが形成される。 As shown in FIG. 1, the shade 23 includes a mirror surface 23 a that extends from the vehicle rear side focal point F 21 of the projection lens 21 toward the light emitting device 10 (wavelength conversion member 13). The front end edge of the shade 23 is concavely curved along the focal plane of the projection lens 21 on the vehicle rear side. Light incident on the mirror surface 23a and reflected upward is refracted by the projection lens 21 and travels in the road surface direction. That is, the light incident on the mirror surface 23a is folded back at the cutoff line and superimposed on the light distribution pattern below the cutoff line. As a result, as shown in FIG. 21, a cut-off line CL is formed at the upper edge of the low beam light distribution pattern P1.
第1サブ反射面24は、第1焦点F124が波長変換部材13近傍に設定され、第2焦点F224が第2サブ反射面25の下方の所定位置に設定された回転楕円系の反射面(回転楕円面又はこれに類する自由曲面等)である。 The first sub-reflecting surface 24 is a spheroidal reflecting surface in which the first focal point F1 24 is set in the vicinity of the wavelength conversion member 13 and the second focal point F2 24 is set at a predetermined position below the second sub-reflecting surface 25. (Spheroid surface or similar free-form surface).
第1サブ反射面24は、発光装置10から前方上向きに放出される光(半双指向性)が入射するように、メイン反射面22の先端付近から投影レンズ21に向かって延びて、投影レンズ21とメイン反射面22との間に配置されている。なお、第1サブ反射面24は、その先端が投影レンズ21に入射するメイン反射面22からの反射光を遮らない長さとされている。 The first sub-reflecting surface 24 extends from the vicinity of the front end of the main reflecting surface 22 toward the projection lens 21 so that the light (semi-bidirectionality) emitted upward and forward from the light emitting device 10 enters the projection lens 21. And the main reflecting surface 22. The first sub-reflection surface 24 has a length that does not block the reflected light from the main reflection surface 22 that is incident on the projection lens 21 at the tip.
メイン反射面22と第1サブ反射面24とは、金型を用いて一体成形されたリフレクタ基材に対してアルミ蒸着等の鏡面処理を施すことで、一つの部品として構成されている。これにより、各反射面22、24を個々の部品として構成する場合と比べ、部品点数の削減、各反射面22、24の組み付け工程の簡略化、さらには、各反射面22、24の組み付け誤差の低減等が可能となる。なお、メイン反射面22と第1サブ反射面24とは、一体成形することなく個々の部品として構成してもよい。 The main reflecting surface 22 and the first sub-reflecting surface 24 are configured as a single component by performing a mirror surface treatment such as aluminum deposition on a reflector base material integrally formed using a mold. Thereby, compared with the case where each reflective surface 22 and 24 is comprised as an individual component, reduction of a number of parts, simplification of the assembly process of each reflective surface 22 and 24, and also the assembly error of each reflective surface 22 and 24 Can be reduced. The main reflection surface 22 and the first sub-reflection surface 24 may be configured as individual parts without being integrally formed.
第2サブ反射面25は、第1サブ反射面24で反射されて第2焦点F224で集光する光が入射するように、投影レンズ21とその車両後方側焦点F21との間に配置されている。 The second sub-reflecting surface 25 is disposed between the projection lens 21 and the vehicle rear-side focal point F 21 so that the light reflected by the first sub-reflecting surface 24 and condensed at the second focal point F 2 24 is incident. Has been.
第2サブ反射面25は、例えば、平面鏡であり、車両前端側25aが車両後端側25bの下方に位置するように、水平面に対して傾斜して配置されている。 The second sub-reflection surface 25 is, for example, a plane mirror, and is inclined with respect to the horizontal plane so that the vehicle front end side 25a is located below the vehicle rear end side 25b.
上記構成の車両用灯具ユニット20によれば、発光装置10から放出される光のうち相対的に高い光度の光Ray2(例えば、光度の割合が50%となる半値角から内の光(半双指向性))は、メイン反射面22のうち光軸AXを含む水平面近傍の領域22bに入射する(図19、図20参照)。メイン反射面22(領域22b)は鉛直方向では楕円であるため、鉛直方向に関しては、メイン反射面22(領域22b)からの相対的に高い光度の反射光Ray2は、第2焦点F222に集光し投影レンズ21でほぼ平行光線となる(図20参照)。一方、メイン反射面22(領域22b)は水平方向では楕円ではないため、水平方向に関しては、投影レンズ21を透過したメイン反射面22(領域22b)からの相対的に高い光度の反射光Ray2は、いったん交差した後、水平方向に拡散される(図19参照)。これにより、図21に示すように、鉛直方向に薄く水平方向(左右方向)に広がりのある高い照度の部分配光パターンP1(高照度帯)が形成される。 According to the vehicular lamp unit 20 configured as described above, the light Ray2 having a relatively high luminous intensity out of the light emitted from the light emitting device 10 (for example, light within the half-value angle at which the ratio of luminous intensity is 50% (half-bidirectional) )) Enters the region 22b in the vicinity of the horizontal plane including the optical axis AX of the main reflecting surface 22 (see FIGS. 19 and 20). Since the main reflection surface 22 (region 22b) is elliptical in the vertical direction, the reflected light Ray2 having a relatively high luminous intensity from the main reflection surface 22 (region 22b) is collected at the second focal point F2 22 in the vertical direction. The light is projected and becomes almost parallel light by the projection lens 21 (see FIG. 20). On the other hand, since the main reflection surface 22 (region 22b) is not elliptical in the horizontal direction, the reflected light Ray2 having a relatively high luminous intensity from the main reflection surface 22 (region 22b) transmitted through the projection lens 21 is horizontal. Once crossed, it is diffused in the horizontal direction (see FIG. 19). As a result, as shown in FIG. 21, a partial illumination pattern P1 (high illuminance band) with high illuminance that is thin in the vertical direction and spreads in the horizontal direction (left and right direction) is formed.
一方、発光装置10から放出される光のうち領域22b以外のメイン反射面22に入射した光(相対的に低い光度の光。例えば、光度の割合が50%となる半値角から外の光)は、上記と同様、領域22b以外のメイン反射面22で反射されて、仮想鉛直スクリーン(車両前面から約25m前方に配置されている)上に、鉛直方向及び左右方向に広がりのある部分配光パターンP2を形成する。 On the other hand, light incident on the main reflecting surface 22 other than the region 22b out of the light emitted from the light emitting device 10 (light having a relatively low luminous intensity. For example, light outside the half-value angle at which the luminous intensity ratio is 50%). Is reflected by the main reflecting surface 22 other than the region 22b and spreads in the vertical direction and the left-right direction on the virtual vertical screen (arranged approximately 25 m ahead from the front of the vehicle). A pattern P2 is formed.
以上のようにして、部分配光パターンP1(高照度帯)と部分配光パターンP2とを含む遠方視認性に優れた合成配光パターン(ロービーム用配光パターン)が形成される。 As described above, a combined light distribution pattern (low beam light distribution pattern) excellent in distance visibility including the partial distribution light pattern P1 (high illuminance band) and the partial distribution light pattern P2 is formed.
また、発光装置10から放出されて第1サブ反射面24に入射する光は、当該第1サブ反射面24及び第2サブ反射面25で反射されて投影レンズ21を透過して、水平面に対して上向きの角度の方向(例えば、2〜4度の範囲)へ照射される。これにより、図21に示すように、仮想鉛直スクリーン(例えば、車両前面から約25m前方に配置されている)上のオーバーヘッドサイン領域Aに、オーバーヘッドサイン配光パターンP2が形成される。 In addition, the light emitted from the light emitting device 10 and incident on the first sub-reflecting surface 24 is reflected by the first sub-reflecting surface 24 and the second sub-reflecting surface 25, passes through the projection lens 21, and is directed to the horizontal plane. Then, the light is irradiated in an upward angle direction (for example, in a range of 2 to 4 degrees). As a result, as shown in FIG. 21, an overhead sign light distribution pattern P2 is formed in an overhead sign region A on a virtual vertical screen (for example, disposed about 25 m ahead from the front of the vehicle).
なお、車両用灯具ユニット20は、各配光パターンP1〜P3が仮想鉛直スクリーン上の適正範囲を照射するように公知のエイミング機構(図示せず)により光軸調整されている。 The vehicle lamp unit 20 is optically adjusted by a known aiming mechanism (not shown) so that each of the light distribution patterns P1 to P3 irradiates an appropriate range on the virtual vertical screen.
本実施形態の車両用灯具ユニット20によれば、発光装置10から放出される相対的に高い光度の光(例えば、光度の割合が50%となる半値角から内の光(半双指向性))が光軸AX10上の領域ではなくメイン反射面22のうち光軸AXを含む水平面近傍の領域22bに入射する構成であるため、鉛直方向寸法が薄型の車両用灯具ユニット20を構成することが可能となる。 According to the vehicle lamp unit 20 of the present embodiment, light having a relatively high luminous intensity emitted from the light emitting device 10 (for example, light within a half-value angle at which the ratio of luminous intensity is 50% (semi-bidirectionality)). Is incident not on the area on the optical axis AX 10 but on the area 22b in the vicinity of the horizontal plane including the optical axis AX in the main reflecting surface 22, so that the vehicular lamp unit 20 having a thin vertical dimension can be configured. It becomes possible.
次に、発光装置10が、車両用灯具(本実施形態の車両用灯具ユニット20等)の鉛直方向の薄型化に適した発光装置である理由について、車両用灯具ユニット20´と対比して説明する。 Next, the reason why the light-emitting device 10 is a light-emitting device suitable for thinning the vehicle lamp (the vehicle lamp unit 20 of the present embodiment) in the vertical direction will be described in comparison with the vehicle lamp unit 20 ′. To do.
図22は、車両用灯具ユニット20´をその光軸AXを含む水平面で切断した断面図(光路含む)である。図23は、車両用灯具ユニット20´の発光装置10´の指向特性(単一指向性)の例である。図24は、車両用灯具ユニット20´により形成される配光パターンP1´の例である。 FIG. 22 is a cross-sectional view (including the optical path) of the vehicular lamp unit 20 ′ cut along a horizontal plane including the optical axis AX. FIG. 23 is an example of the directivity (unidirectionality) of the light emitting device 10 ′ of the vehicle lamp unit 20 ′. FIG. 24 is an example of a light distribution pattern P1 ′ formed by the vehicle lamp unit 20 ′.
車両用灯具ユニット20´は、車両用灯具ユニット20と比べ、発光装置10に代えて、波長変換部材13の上面13aが遮光手段15で覆われていない発光装置10´を用いている点が相違する。それ以外、車両用灯具ユニット20と同様の構成である。以下、車両用灯具ユニット20との相違点を中心に説明し、車両用灯具ユニット20と同一の構成については同一の符号を付してその説明を省略する。 The vehicle lamp unit 20 ′ is different from the vehicle lamp unit 20 in that a light emitting device 10 ′ in which the upper surface 13 a of the wavelength conversion member 13 is not covered with the light shielding means 15 is used instead of the light emitting device 10. To do. Other than that, the configuration is the same as the vehicular lamp unit 20. Hereinafter, the difference from the vehicular lamp unit 20 will be mainly described, and the same components as those of the vehicular lamp unit 20 will be denoted by the same reference numerals and description thereof will be omitted.
波長変換部材13の上面13aが遮光手段15で覆われていないため、発光装置10´の指向特性は、図23に示すように、一般的なLED、LDと同様、光軸AX10上の強度が最大で、光軸AXを含む水平面内の光が少なくなる(単一指向性)。 Since the upper surface 13a of the wavelength conversion member 13 is not covered with the light shielding means 15, the directivity characteristic of the light emitting device 10 ′ is the intensity on the optical axis AX 10 as in general LEDs and LDs as shown in FIG. Is maximum, and light in a horizontal plane including the optical axis AX is reduced (unidirectionality).
図22に示すように、発光装置10´から放出される相対的に高い光度の光(例えば、光度の割合が50%となる半値角から内の光)は、メイン反射面22のうち光軸AX10上の領域Rfに入射する。 As shown in FIG. 22, light with relatively high luminous intensity (for example, light within a half-value angle at which the luminous intensity ratio is 50%) emitted from the light emitting device 10 ′ is the optical axis of the main reflecting surface 22. The light enters the region Rf on the AX 10 .
光軸AX10上の領域Rfで反射される相対的に高い光度の光Ray3の、投影レンズ21の車両後方側焦点F21に対する入射角は比較的きつくなるため、メイン反射面22からの相対的に高い光度の反射光を水平線付近に充分に集光させることができず、鉛直方向に厚く左右に広がりのない低い照度の配光パターンP1´となる(図24参照)。 The relatively high intensity of light Ray3 reflected by the region Rf on the optical axis AX 10, the incident angle is relatively tight for the vehicle rear-side focal point F 21 of the projection lens 21 relative to the main reflecting surface 22 The reflected light having a high luminous intensity cannot be sufficiently collected near the horizontal line, resulting in a light distribution pattern P1 ′ having a low illuminance that is thick in the vertical direction and does not spread left and right (see FIG. 24).
上記構成の車両用灯具ユニット20´においては、メイン反射面22からの相対的に高い光度の反射光を投影レンズ21の車両後方側焦点F21近傍に集光させることで、高い照度の配光パターンを形成することが可能となるものの、このようにすると、メイン反射面22からの反射光の、投影レンズ21の車両後方側焦点F21に対する入射角がきつくなるため、投影レンズ21の鉛直方向寸法が大きくなる(結果として、車両用灯具ユニット20´の鉛直方向寸法が大型化する)という問題がある。 In the vehicular lamp unit 20 ′ having the above configuration, the reflected light having a relatively high luminous intensity from the main reflecting surface 22 is condensed in the vicinity of the vehicle rear side focal point F 21 of the projection lens 21, thereby distributing light with high illuminance. Although it is possible to form a pattern, the incident angle of the reflected light from the main reflecting surface 22 with respect to the vehicle rear side focal point F 21 of the projection lens 21 becomes tight. There is a problem that the dimension becomes large (as a result, the vertical dimension of the vehicular lamp unit 20 ′ increases).
これに対して、発光装置10の指向特性は、波長変換部材13の上面13aを覆う遮光手段15及び波長変換部材13の下面13bの周囲に配置された反射手段16の作用により、図2(b)に示すように、光軸AXを含む水平面内の強度が最大の半双指向性の分布となる。従って、発光装置10から放出される相対的に高い光度の光Ray2(例えば、光度の割合が50%となる半値角から内の光(半双指向性))は光軸AX10上の領域Rfではなくメイン反射面22のうち光軸AXを含む水平面近傍の領域22bに入射する(図19、図20参照)。 On the other hand, the directivity of the light emitting device 10 is shown in FIG. 2 (b) by the action of the light shielding means 15 covering the upper surface 13a of the wavelength converting member 13 and the reflecting means 16 disposed around the lower surface 13b of the wavelength converting member 13. ), The intensity in the horizontal plane including the optical axis AX is a semi-bidirectional distribution having the maximum intensity. Accordingly, relatively high intensity of light Ray2 emitted from the light emitting device 10 (e.g., light (Hanso directivity of the inner from the half value angle the ratio of the luminous intensity is 50%)) is in the region Rf on the optical axis AX 10 Instead, the light enters the region 22b in the vicinity of the horizontal plane including the optical axis AX in the main reflecting surface 22 (see FIGS. 19 and 20).
メイン反射面22(領域22b)で反射される相対的に高い光度の光Ray2の、投影レンズ21の車両後方側焦点F21に対する入射角は比較的浅くなるため(図20参照)、車両用灯具ユニット20では、投影レンズ21の鉛直方向寸法を小さくしても(結果として、車両用灯具ユニット20の鉛直方向寸法を薄型化しても)、メイン反射面22(領域22b)からの相対的に高い光度の反射光を水平線付近に充分に集光させることが可能となり、鉛直方向に薄く水平方向(左右方向)に広がりのある高い照度の部分配光パターンP1(高照度帯)を形成することが可能となる(図21参照)。 The relatively high intensity of light Ray2 reflected by the main reflecting surface 22 (region 22b), the incident angle is relatively shallow with respect to the vehicle rear-side focal point F 21 of the projection lens 21 (see FIG. 20), the vehicle lamp In the unit 20, even if the vertical dimension of the projection lens 21 is reduced (as a result, the vertical dimension of the vehicular lamp unit 20 is reduced), it is relatively high from the main reflecting surface 22 (region 22b). Reflected light of luminous intensity can be sufficiently collected near the horizontal line, and a high-illuminance partial light distribution pattern P1 (high illuminance band) that is thin in the vertical direction and spread in the horizontal direction (left-right direction) can be formed. This is possible (see FIG. 21).
図20では、投影レンズ21のうちメイン反射面22(領域22b)からの相対的に高い光度の反射光が透過しない上下端部をカットすることで、投影レンズ21の鉛直方向寸法を小さくしている(結果として、車両用灯具ユニット20の鉛直方向寸法を薄型化している)。このように、投影レンズ21の上下端部を使用していない(カットしている)ため、車両用灯具ユニット20´と比べ、車両用灯具ユニット20の鉛直方向寸法の小型化が可能となるだけでなく、投影レンズ21の焦点F21付近に配置されたシェード23端部で発生する投影レンズ21の色収差を低減することが可能となる。 In FIG. 20, the vertical dimension of the projection lens 21 is reduced by cutting the upper and lower end portions of the projection lens 21 that do not transmit the reflected light having a relatively high luminous intensity from the main reflecting surface 22 (region 22 b). (As a result, the vertical dimension of the vehicular lamp unit 20 is reduced). Thus, since the upper and lower end portions of the projection lens 21 are not used (cut), the vertical size of the vehicular lamp unit 20 can only be reduced as compared with the vehicular lamp unit 20 ′. Instead, it becomes possible to reduce the chromatic aberration of the projection lens 21 generated at the end of the shade 23 arranged near the focal point F 21 of the projection lens 21.
本実施形態の車両用灯具ユニット20によれば、さらに次の効果を奏する。 According to the vehicle lamp unit 20 of the present embodiment, the following effects are further achieved.
第1に、車両用灯具ユニット20と励起光源14とを分離したため(図16参照)、励起光源14を車両内又は車室内の雰囲気温度が安定した場所に設置することが可能となる。すなわち、励起光源14の設置場所の自由度が増す。 First, since the vehicular lamp unit 20 and the excitation light source 14 are separated (see FIG. 16), the excitation light source 14 can be installed in a place where the ambient temperature in the vehicle or the passenger compartment is stable. That is, the degree of freedom of the installation location of the excitation light source 14 increases.
第2に、車両用灯具ユニット20と励起光源14(さらにはヒートシンク等の冷却装置97やECU等の駆動装置98)とを分離したため(図16参照)、励起光源14等を車両用灯具ユニット20内部に配置した場合と比べ、車両用灯具ユニット20の軽量化、エイミング機構等の簡素化が可能となる。 Secondly, since the vehicle lamp unit 20 and the excitation light source 14 (further, a cooling device 97 such as a heat sink and a drive device 98 such as an ECU) are separated (see FIG. 16), the excitation light source 14 and the like are used as the vehicle lamp unit 20. Compared with the case where it is arranged inside, it is possible to reduce the weight of the vehicular lamp unit 20 and simplify the aiming mechanism and the like.
第3に、上記のように車両用灯具ユニット20の軽量化が可能となるため、車両用灯具ユニット20に公知のエイミング機構を連結した場合に、当該エイミング機構に加わる重量負荷を低減することが可能となる。これにより、エイミング機構に加わる重量負荷に起因する各種不具合を低減することが可能となる。また、エイミング機構を構成するアクチュエータの小型化・省電力化も期待できる。なお、すれ違いビーム全体を構成するために、車両用灯具ユニット20は、単一でもよいし、複数でもよい。 Third, since the vehicle lamp unit 20 can be reduced in weight as described above, when a known aiming mechanism is connected to the vehicle lamp unit 20, the weight load applied to the aiming mechanism can be reduced. It becomes possible. Thereby, it is possible to reduce various problems caused by the weight load applied to the aiming mechanism. In addition, the actuator constituting the aiming mechanism can be expected to be reduced in size and power consumption. In addition, in order to comprise the whole passing beam, the vehicle lamp unit 20 may be single or plural.
以上、発光装置10を用いて車両用灯具ユニット20を構成する例について説明したが、発光装置10に代えて、発光装置10A〜10E又は後述の発光装置10F〜10Hを用いても、車両用灯具ユニット20と同様、鉛直方向寸法が薄型で、なおかつ、鉛直方向に薄く水平方向に広がりのある高い照度の部分配光パターン(高照度帯)を形成することが可能な車両用灯具ユニットを構成することが可能である。 As described above, the example in which the vehicular lamp unit 20 is configured using the light emitting device 10 has been described. However, the vehicular lamp can be used even if the light emitting devices 10A to 10E or the light emitting devices 10F to 10H described later are used instead of the light emitting device 10. Similar to the unit 20, a vehicular lamp unit that has a thin vertical dimension and is capable of forming a high-illuminance partial light distribution pattern (high illuminance band) that is thin in the vertical direction and spreads in the horizontal direction is configured. It is possible.
[発光装置10F]
従来、光ファイバ等のライトガイドにより伝送される励起光を吸収し、波長変換して所定の波長域の光を放出する波長変換部材を用いた発光装置が提案されている(例えば、特許第4379531号公報参照)。
[Light Emitting Device 10F]
Conventionally, a light-emitting device using a wavelength conversion member that absorbs excitation light transmitted by a light guide such as an optical fiber and converts the wavelength to emit light in a predetermined wavelength range has been proposed (for example, Japanese Patent No. 4379531). No. publication).
図37は、従来の光ファイバ等のライトガイドにより伝送される励起光を吸収し、波長変換して所定の波長域の光を放出する波長変換部材を用いた発光装置300の例である。 FIG. 37 shows an example of a light-emitting device 300 using a wavelength conversion member that absorbs excitation light transmitted by a conventional light guide such as an optical fiber, converts the wavelength, and emits light in a predetermined wavelength range.
図37に示すように、発光装置300は、励起光源から放出された励起光を伝送するための光ファイバ等のライトガイド310、ライトガイド310の端面に配置された反射膜321、322付き波長変換部材320等を備えている。 As shown in FIG. 37, the light-emitting device 300 includes a light guide 310 such as an optical fiber for transmitting excitation light emitted from an excitation light source, and wavelength conversion with reflection films 321 and 322 disposed on the end face of the light guide 310. The member 320 etc. are provided.
上記構成の発光装置300においては、波長変換部材320は、ライトガイド310の端面から出射される励起光を吸収し、波長変換して所定の波長域の光を放出する。 In the light emitting device 300 configured as described above, the wavelength conversion member 320 absorbs excitation light emitted from the end face of the light guide 310, converts the wavelength, and emits light in a predetermined wavelength range.
しかしながら、上記構成の発光装置300は、内視鏡用の発光装置であり、これを車両用灯具に適用すること及び車両用灯具に対してライトガイドを着脱自在に固定する構造を備えた発光装置については一切提案されていない。 However, the light-emitting device 300 having the above-described configuration is a light-emitting device for an endoscope. The light-emitting device includes a structure in which the light guide is applied to a vehicle lamp and the light guide is detachably fixed to the vehicle lamp. There is no suggestion about.
以下、発光装置10の変形例として、車両用灯具に対してライトガイドを着脱自在に固定する構造を備えた発光装置10Fについて説明する。 Hereinafter, as a modification of the light-emitting device 10, a light-emitting device 10F having a structure in which a light guide is detachably fixed to a vehicle lamp will be described.
図25は発光装置10Fを用いた車両用灯具ユニット20の側面図、図26は発光装置10Fを用いた車両用灯具ユニット20を、光軸AX10を含む鉛直面で切断した断面図である。 Figure 25 is a side view of a vehicular lamp unit 20 using the light emitting device 10F, 26 a vehicle lamp unit 20 using the light emitting device 10F, a cross-sectional view taken along a vertical plane including the optical axis AX 10.
発光装置10Fは、発光装置10と比べ、フェルール11に代えてフランジ付きスタブ11A及びフェルール11Bを用いている点、ライトガイド12に代えて第1ライトガイド12A及び第2ライトガイド12Bを備えている点が相違する。それ以外、発光装置10と同様の構成である。以下、発光装置10との相違点を中心に説明し、発光装置10と同一の構成については同一の符号を付してその説明を省略する。 The light emitting device 10F is different from the light emitting device 10 in that a flanged stub 11A and a ferrule 11B are used instead of the ferrule 11, and a first light guide 12A and a second light guide 12B are provided instead of the light guide 12. The point is different. Other than that, the configuration is the same as that of the light emitting device 10. Hereinafter, the difference from the light-emitting device 10 will be mainly described, and the same components as those of the light-emitting device 10 will be denoted by the same reference numerals and description thereof will be omitted.
図25、図26に示すように、発光装置10Fは、フランジ付きスタブ11A、フェルール11B、第1ライトガイド12A、第2ライトガイド12B等を備えている。 As shown in FIGS. 25 and 26, the light emitting device 10F includes a flanged stub 11A, a ferrule 11B, a first light guide 12A, a second light guide 12B, and the like.
フランジ付きスタブ11Aは、第1ライトガイド12Aと波長変換部材13とを保持するための部材であり、上面11Aa中心と下面11Ab中心とを連通するライトガイド用貫通穴11Acが形成されている。第1ライトガイド12Aは、ライトガイド用貫通穴11Acに挿入されてスタブ11Aに保持されている。 The flanged stub 11A is a member for holding the first light guide 12A and the wavelength conversion member 13, and is formed with a light guide through hole 11Ac that connects the center of the upper surface 11Aa and the center of the lower surface 11Ab. The first light guide 12A is inserted into the light guide through hole 11Ac and held by the stub 11A.
フランジ付きスタブ11Aは、上側スタブ11Adと下側スタブ11Afと両者の中間のフランジ11Aeとを含んでいる。 The flanged stub 11A includes an upper stub 11Ad, a lower stub 11Af, and an intermediate flange 11Ae.
上側スタブ11Adは、フランジ11Aeがミラーシェード兼保持部材26に接触するまでミラーシェード兼保持部材26のうち光軸AX10上に形成された開口26aに挿入されてこれに嵌合している。下側スタブ11Afは、フランジ11Aeがアダプタ95に接触するまでアダプタ95のスリーブ95aの一端側に挿入されてこれに嵌合している。 The upper stub 11Ad, the flange 11Ae are fitted thereto is inserted into the opening 26a formed on the optical axis AX 10 of the mirror shade and retaining member 26 until it contacts the mirror shade and holding member 26. The lower stub 11Af is inserted into and fitted to one end of the sleeve 95a of the adapter 95 until the flange 11Ae contacts the adapter 95.
フランジ付きスタブ11Aは、上記のように嵌合した状態で、アダプタ95をミラーシェード兼保持部材26にネジ止め固定することにより、車両用灯具ユニット20側に固定されている。これにより、発光装置10と車両用灯具ユニット20とを精度よく組み立てることが可能となる。 The flanged stub 11A is fixed to the vehicle lamp unit 20 side by screwing and fixing the adapter 95 to the mirror shade and holding member 26 in a state of being fitted as described above. Thereby, it becomes possible to assemble the light-emitting device 10 and the vehicle lamp unit 20 with high accuracy.
第1ライトガイド12Aの第1出光面12Abとフランジ付きスタブ11Aの上面11Aaとは、フランジ付きスタブ11Aの上面11Aaを研磨することで、同一平面とされている。同様に、第1ライトガイド12Aの第1入光面12Aaとフランジ付きスタブ11Aの下面11Abとは、フランジ付きスタブ11Aの下面11Abを研磨することで、同一平面とされている。 The first light output surface 12Ab of the first light guide 12A and the upper surface 11Aa of the flanged stub 11A are flush with each other by polishing the upper surface 11Aa of the flanged stub 11A. Similarly, the first light entrance surface 12Aa of the first light guide 12A and the lower surface 11Ab of the flanged stub 11A are flush with each other by polishing the lower surface 11Ab of the flanged stub 11A.
フランジ付きスタブ11Aは、第1ライトガイド12Aを保持することができるものであればよく、その材質は特に問わない。例えば、フランジ付きスタブ11Aは、ステンレス製、ニッケル製、ジルコニア製であってもよいし、その他の金属製、樹脂製、ガラス製であってもよい。 The flanged stub 11A is not particularly limited as long as it can hold the first light guide 12A. For example, the flanged stub 11A may be made of stainless steel, nickel, or zirconia, or may be made of other metal, resin, or glass.
フランジ付きスタブ11Aの上面11Aaは、例えば、円形で、図27、図28に示すように、反射手段16で覆われている。反射手段16は、波長変換部材13が発する光を波長変換部材13側に反射するものであればよく、例えば、スタブ11Aの上面11Aaに対してアルミや銀等の金属蒸着を施すことで形成された反射層(又は反射面)であってもよいし、又は、スタブ11Aが導電性を有する場合には、スタブ11Aの上面11Aaに対してメッキを施すことで形成された反射層(誘電体膜)であってもよい。このようにスタブ11Aの上面11Aaに対して反射層(又は反射面)を形成する方法については、例えば、特開2007−121502号公報に記載されている方法を用いることが可能である。あるいは、反射手段16は、スタブ11Aの上面11Aa(上面11Aaのうち第1ライトガイド12Aの第1出光面12Ab以外の領域)に接着された薄い板状の反射部材であってもよいし、スタブ11Aが金属製の場合には、スタブ11Aの上面11Aaに対して鏡面研磨を施すことで形成された反射面であってもよい。 The upper surface 11Aa of the flanged stub 11A is, for example, circular and covered with the reflecting means 16 as shown in FIGS. The reflection means 16 may be any means as long as it reflects the light emitted from the wavelength conversion member 13 toward the wavelength conversion member 13, and is formed, for example, by depositing metal such as aluminum or silver on the upper surface 11Aa of the stub 11A. Or a reflective layer (dielectric film) formed by plating the upper surface 11Aa of the stub 11A when the stub 11A has conductivity. ). As a method for forming the reflective layer (or reflective surface) on the upper surface 11Aa of the stub 11A in this way, for example, a method described in Japanese Patent Application Laid-Open No. 2007-121502 can be used. Alternatively, the reflecting means 16 may be a thin plate-like reflecting member bonded to the upper surface 11Aa of the stub 11A (a region of the upper surface 11Aa other than the first light exit surface 12Ab of the first light guide 12A). When 11A is made of metal, it may be a reflecting surface formed by performing mirror polishing on the upper surface 11Aa of the stub 11A.
スタブ11Aの径は、フェルール11Bの径より大きい方が望ましい。このようにすれば、フェルール11Bの端面より径の大きいスタブ11Aの端面(上面11Aa)に、波長変換部材13の周端面13cから放出される光を反射する反射手段16を配置することが可能となる。すなわち、フェルール11Bの端面に反射手段16を配置する場合と比べ、反射手段16の領域を広くすることが可能となるため、反射手段16で反射されて折り返されて上方に向かう光が増加する。従って、発光装置10Fの効率をより高めることが可能となる。 The diameter of the stub 11A is preferably larger than the diameter of the ferrule 11B. In this way, it is possible to arrange the reflecting means 16 that reflects the light emitted from the peripheral end surface 13c of the wavelength conversion member 13 on the end surface (upper surface 11Aa) of the stub 11A having a larger diameter than the end surface of the ferrule 11B. Become. That is, as compared with the case where the reflecting means 16 is disposed on the end face of the ferrule 11B, the area of the reflecting means 16 can be widened, so that the light reflected by the reflecting means 16 and folded back increases. Therefore, the efficiency of the light emitting device 10F can be further increased.
フェルール11Bは、第2ライトガイド12Bを保持するための部材であり、上面11Ba中心と下面11Bb中心とを連通するライトガイド用貫通穴11Bcが形成されている。第2ライトガイド12Bは、ライトガイド用貫通穴11Bcに挿入されてフェルール11Bに保持されている。 The ferrule 11B is a member for holding the second light guide 12B, and has a light guide through hole 11Bc that communicates the center of the upper surface 11Ba and the center of the lower surface 11Bb. The second light guide 12B is inserted into the light guide through hole 11Bc and held by the ferrule 11B.
フェルール11Bの先端部は、その上面11Ba(第2ライトガイド12Bの第2出光面12Bb)がフランジ付きスタブ11Aの下面11Ab(第1ライトガイド12Aの第1入光面12Aa)に突き当たるまでアダプタ95のスリーブ95aの他端側に挿入されてこれに嵌合している。これにより、第1ライトガイド12Aの第1入光面12Aaと第2ライトガイド12Bの第2出光面12Bbとが対向し、面接触した状態でかつ同軸に配置されている。なお、アダプタ95は、スリーブ構造によってスタブ11Aとフェルール11Bとを精度よく接続でき、接続損失が少なく、挿抜再現性に優れたものが望ましい。 The tip of the ferrule 11B has an adapter 95 until its upper surface 11Ba (second light output surface 12Bb of the second light guide 12B) abuts the lower surface 11Ab of the flanged stub 11A (first light input surface 12Aa of the first light guide 12A). Is inserted into the other end of the sleeve 95a and fitted therein. As a result, the first light entrance surface 12Aa of the first light guide 12A and the second light exit surface 12Bb of the second light guide 12B face each other, and are arranged coaxially in a state of surface contact. The adapter 95 is preferably one that can accurately connect the stub 11A and the ferrule 11B with a sleeve structure, has low connection loss, and is excellent in insertion / removal reproducibility.
スタブ11Aとフェルール11Bとは、上記のように第1ライトガイド12Aの第1入光面12Aaと第2ライトガイド12Bの第2出光面12Bbとを対向させた状態で、コネクタ96をアダプタ95にネジ止め固定することにより(又はコネクタ96をアダプタ95に係合させることにより)着脱自在に固定されている。コネクタ96としては、例えば、JIS規格のFCコネクタやSCコネクタ等の公知のものを用いることが可能である。 As described above, the stub 11A and the ferrule 11B connect the connector 96 to the adapter 95 in a state where the first light entrance surface 12Aa of the first light guide 12A and the second light exit surface 12Bb of the second light guide 12B face each other. It is detachably fixed by screwing (or by engaging the connector 96 with the adapter 95). As the connector 96, for example, a known connector such as a JIS standard FC connector or SC connector can be used.
第2ライトガイド12Bの第2出光面12Bbとフェルール11Bの上面11Baとは、フェルール11Bの上面11Baを研磨することで、同一平面とされている。 The second light exit surface 12Bb of the second light guide 12B and the upper surface 11Ba of the ferrule 11B are flush with each other by polishing the upper surface 11Ba of the ferrule 11B.
フェルール11Bは、第2ライトガイド12Bを保持することができるものであればよく、その材質は特に問わない。例えば、フェルール11Bは、ステンレス製、ニッケル製、ジルコニア製であってもよいし、その他の金属製、樹脂製であってもよい。 The ferrule 11B is not particularly limited as long as it can hold the second light guide 12B. For example, the ferrule 11B may be made of stainless steel, nickel, or zirconia, or may be made of other metal or resin.
第1ライトガイド12Aは、第1入光面12Aaと第1出光面12Abとを含み、第1入光面12Aaから内部に導入された励起光を第1出光面12Abまで導光(又は伝搬)し、第1出光面12Abから出射させる導光部材であり、例えば、中心部のコア(例えば、コア径:0.25mm)とその周囲を覆うクラッド(いずれも図示せず)とを含む光ファイバである。 The first light guide 12A includes a first light incident surface 12Aa and a first light output surface 12Ab, and guides (or propagates) excitation light introduced from the first light incident surface 12Aa to the first light output surface 12Ab. An optical fiber that is a light guide member that emits light from the first light exit surface 12Ab, and includes, for example, a central core (for example, core diameter: 0.25 mm) and a cladding (none of which is shown) that covers the periphery of the core. It is.
第2ライトガイド12Bは、第2入光面12Baと第2出光面12Bbとを含み、第2入光面12Baから内部に導入された励起光を第2出光面12Bbまで導光(又は伝搬)し、第2出光面12Bbから出射させる導光部材であり、例えば、中心部のコア(例えば、コア径:0.2mm)とその周囲を覆うクラッド(いずれも図示せず)とを含む光ファイバである。 The second light guide 12B includes a second light incident surface 12Ba and a second light output surface 12Bb, and guides (or propagates) excitation light introduced from the second light incident surface 12Ba to the second light output surface 12Bb. An optical fiber that is a light guide member that emits light from the second light exit surface 12Bb and includes, for example, a central core (for example, core diameter: 0.2 mm) and a clad (none of which is shown) that covers the periphery of the core. It is.
第1ライトガイド12A、12Bは、励起光源14からの励起光を導光することができるものであればよく、単線ファイバであってもよいし、多線ファイバであってもよい。また、第1ライトガイド12A、12Bは、単一モードファイバであってもよいし、多モードファイバであってもよい。また、第1ライトガイド12A、12Bの材質は特に問わない。例えば、第1ライトガイド12A、12Bは、石英ガラス製であってもよいし、プラスチック製であってもよい。なお、単線ファイバ、多モードファイバが好ましい。 The first light guides 12A and 12B may be any one that can guide the excitation light from the excitation light source 14, and may be a single-wire fiber or a multi-wire fiber. The first light guides 12A and 12B may be single mode fibers or multimode fibers. The material of the first light guides 12A and 12B is not particularly limited. For example, the first light guides 12A and 12B may be made of quartz glass or plastic. Single-wire fibers and multimode fibers are preferred.
第1ライトガイド12Aの径(コア径)と第2ライトガイド12Bの径(コア径)とは、同一であってもよいし、異なっていてもよい。 The diameter (core diameter) of the first light guide 12A and the diameter (core diameter) of the second light guide 12B may be the same or different.
第1ライトガイド12Aの径(コア径)は、第2ライトガイド12Bの径(コア径)より大きくするのが望ましい。このように、第1ライトガイド12Aの第1入光面12Aaの面積を、第2ライトガイド12Bの第2出光面12Bbの面積より大きくすれば、例えば、製造上の理由(例えば、第1ライトガイド12A、12Bやアダプタ95のスリーブ95a等の寸法誤差)で、第1ライトガイド12Aと第2ライトガイド12Bとが同軸から若干ずれたとしても、第2ライトガイド12Bからの励起光を損失無く第2ライトガイド12Aへ導光(伝搬)することが可能となる。すなわち、製造時のWiggle誤差を吸収することが可能となる。 The diameter (core diameter) of the first light guide 12A is desirably larger than the diameter (core diameter) of the second light guide 12B. As described above, if the area of the first light entrance surface 12Aa of the first light guide 12A is larger than the area of the second light exit surface 12Bb of the second light guide 12B, for example, for manufacturing reasons (for example, the first light guide Even if the first light guide 12A and the second light guide 12B slightly deviate from the same axis due to dimensional errors of the guides 12A and 12B and the sleeve 95a of the adapter 95, etc., the excitation light from the second light guide 12B is not lost. Light can be guided (propagated) to the second light guide 12A. That is, it becomes possible to absorb the Wiggle error during manufacturing.
図27に示すように、波長変換部材13の下面13bは、フランジ付きスタブ11Aの上面11Aa(反射手段16)のうちライトガイド用貫通穴11Ac周囲の領域に接着されて、ライトガイド用貫通穴11Ac(第1ライトガイド12Aの第1出光面12Ab)を覆っている。 As shown in FIG. 27, the lower surface 13b of the wavelength conversion member 13 is adhered to a region around the light guide through hole 11Ac on the upper surface 11Aa (reflecting means 16) of the flanged stub 11A, and the light guide through hole 11Ac. (The first light exit surface 12Ab of the first light guide 12A) is covered.
図28は、フランジ付きスタブ11Aの上面図である。図28に示すように、波長変換部材13は、フランジ付きスタブ11Aの上面11Aaの中心に配置されている。また、図27に示すように、波長変換部材13の下面13b中心とライトガイド用貫通穴11Acの中心(第1ライトガイド12Aの第1出光面12Abの中心)とは一致している。従って、波長変換部材13の下面13bは、ライトガイド用貫通穴11Ac(第1ライトガイド12Aの第1出光面12Ab)が対向する領域以外、反射手段16で覆われている(図27参照)。従って、波長変換部材13が発する光のうち波長変換部材13の下面13bから出射しようとする光は、反射手段16で反射されて波長変換部材13側に戻される。これにより、光の取り出し効率が向上する。 FIG. 28 is a top view of the flanged stub 11A. As shown in FIG. 28, the wavelength conversion member 13 is disposed at the center of the upper surface 11Aa of the flanged stub 11A. As shown in FIG. 27, the center of the lower surface 13b of the wavelength conversion member 13 and the center of the light guide through hole 11Ac (the center of the first light exit surface 12Ab of the first light guide 12A) coincide with each other. Accordingly, the lower surface 13b of the wavelength conversion member 13 is covered with the reflecting means 16 except for the region where the light guide through hole 11Ac (the first light exit surface 12Ab of the first light guide 12A) is opposed (see FIG. 27). Therefore, the light which is going to be emitted from the lower surface 13b of the wavelength conversion member 13 among the light emitted from the wavelength conversion member 13 is reflected by the reflecting means 16 and returned to the wavelength conversion member 13 side. Thereby, the light extraction efficiency is improved.
第1ライトガイド12Aの第1出光面12Abは、フランジ付きスタブ11Aの上面11Aaと同一平面である。従って、波長変換部材13の下面13bと第1ライトガイド12Aの第1出光面12Abとは密着している。なお、波長変換部材13の下面13bと第1ライトガイド12Aの第1出光面12Abとの間には若干の隙間が存在していてもよい。なお、波長変換部材13に代えて、波長変換部材13B〜13Eを用いてもよい。 The first light exit surface 12Ab of the first light guide 12A is flush with the upper surface 11Aa of the flanged stub 11A. Therefore, the lower surface 13b of the wavelength conversion member 13 and the first light exit surface 12Ab of the first light guide 12A are in close contact with each other. A slight gap may exist between the lower surface 13b of the wavelength conversion member 13 and the first light exit surface 12Ab of the first light guide 12A. Instead of the wavelength conversion member 13, the wavelength conversion members 13B to 13E may be used.
上記構成の発光装置10Fによれば、励起光源14からの励起光は、第2ライトガイド12Bの第2入光面12Baから第2ライトガイド12B内に導入され第2出光面12Bbまで導光されて、第2出光面12Bbから出射し、さらに、第1ライトガイド12Aの第1入光面12Aaから第1ライトガイド12A内に導入され第1出光面12Abまで導光されて、第1出光面12Abから出射し、波長変換部材13を照射する。 According to the light emitting device 10F configured as described above, the excitation light from the excitation light source 14 is introduced from the second light incident surface 12Ba of the second light guide 12B into the second light guide 12B and guided to the second light output surface 12Bb. Then, the light exits from the second light exit surface 12Bb, and is further introduced from the first light entrance surface 12Aa of the first light guide 12A into the first light guide 12A and guided to the first light exit surface 12Ab. The light is emitted from 12 Ab and irradiates the wavelength conversion member 13.
励起光源14からの励起光が入射した波長変換部材13は、励起光源14からの励起光により励起される光と波長変換部材13を透過する励起光源14からの励起光との混色による白色光Ray2を発する。 The wavelength conversion member 13 to which the excitation light from the excitation light source 14 is incident is white light Ray2 due to the color mixture of the light excited by the excitation light from the excitation light source 14 and the excitation light from the excitation light source 14 that passes through the wavelength conversion member 13. To emit.
波長変換部材13が発する白色光Ray2は、遮光手段15及び/又は反射手段16で反射されて(又は遮光手段15又は反射手段16で反射されることなく直接)、波長変換部材13の周端面13c全周から放出される。 The white light Ray2 emitted from the wavelength conversion member 13 is reflected by the light shielding means 15 and / or the reflection means 16 (or directly without being reflected by the light shielding means 15 or the reflection means 16), and the peripheral end surface 13c of the wavelength conversion member 13 is used. Released from the entire circumference.
波長変換部材13の上面13aが遮光手段15で覆われているため、波長変換部材13の、光軸AX10(ライトガイド用貫通穴11cの中心軸)を含む鉛直面で切断した断面における指向特性は、図5に実線で示すように、上下対象の双指向性の分布となる(光軸AXを含む水平面内の強度が最大となる)。 Since the upper surface 13a of the wavelength conversion member 13 is covered with a light shielding means 15, directional characteristics in the section cut in a vertical plane including the wavelength converting member 13, the optical axis AX 10 (center axis of the light guide through holes 11c) As shown by a solid line in FIG. 5, the distribution is bi-directional for the vertical target (the intensity in the horizontal plane including the optical axis AX is maximized).
一方、波長変換部材13の周端面13cがリング状の面であるため、波長変換部材13の上面13aから見た指向特性は、図5に二点鎖線で示すように、波長変換部材13を中心に放射状に広がる分布となる。 On the other hand, since the peripheral end surface 13c of the wavelength conversion member 13 is a ring-shaped surface, the directivity seen from the upper surface 13a of the wavelength conversion member 13 is centered on the wavelength conversion member 13 as shown by a two-dot chain line in FIG. The distribution spreads radially.
波長変換部材13の周端面13c全周から下方に放出される白色光Ray2は、波長変換部材13の下面13bの周囲に配置された反射手段16で反射されて折り返されて上方に向かう(図27参照)。 The white light Ray2 emitted downward from the entire circumference of the peripheral end surface 13c of the wavelength conversion member 13 is reflected by the reflecting means 16 disposed around the lower surface 13b of the wavelength conversion member 13 and is turned upward (FIG. 27). reference).
その結果、発光装置10Fの、光軸AX10を含む鉛直面で切断した断面における指向特性は、図2(b)に実線で示すように、双指向性を上半分にした半双指向性の分布となる(光軸AXを含む水平面内の強度が最大となる)。 As a result, the directivity characteristic in the cross section cut by the vertical plane including the optical axis AX 10 of the light emitting device 10F is a distribution of semi-bidirectional characteristics with the bi-directional characteristics set to the upper half as shown by the solid line in FIG. (The intensity in the horizontal plane including the optical axis AX is maximized).
一方、波長変換部材13の周端面13cはリング状の面であるため、発光装置10Fの上面から見た指向特性は、図2(b)に二点鎖線で示すように、波長変換部材13を中心に放射状に広がる分布となる。 On the other hand, since the peripheral end surface 13c of the wavelength conversion member 13 is a ring-shaped surface, the directivity characteristics viewed from the upper surface of the light emitting device 10F are as shown in FIG. The distribution spreads radially in the center.
以上のように、発光装置10Fの指向特性は、図2(b)に実線で示す円弧を、光軸AX10を中心に360°回転させた立体形状の分布、すなわち、光軸AXを含む水平面内の強度が最大で水平面から離れるに従って強度が低下する、配光パターン(例えば、ロービーム用配光パターン)の分布に略一致した立体形状の分布となる。 As described above, the directivity characteristics of the light emitting device 10F has a horizontal plane containing the arc shown by the solid line in FIG. 2 (b), the distribution of the three-dimensional shape obtained by rotating 360 ° around the optical axis AX 10, i.e., the optical axis AX The distribution is a three-dimensional shape that substantially matches the distribution of the light distribution pattern (for example, the low beam light distribution pattern), the intensity of which is the maximum and the intensity decreases as the distance from the horizontal plane increases.
以上説明したように、本変形例の発光装置10Fによれば、第1ライトガイド12Aと波長変換部材13とを保持したスタブ11A、第2ライトガイド12Bを保持したフェルール12B及びコネクタ96の作用により、車両用灯具ユニット20等の取付相手に対して第2ライトガイド12B(を保持したフェルール12B)を着脱自在に固定することが可能な発光装置10Fを構成することが可能となる。 As described above, according to the light emitting device 10F of the present modification, the stub 11A that holds the first light guide 12A and the wavelength conversion member 13, the ferrule 12B that holds the second light guide 12B, and the connector 96 function. Thus, it is possible to configure the light emitting device 10F capable of detachably fixing the second light guide 12B (holding the ferrule 12B) to an attachment counterpart of the vehicle lamp unit 20 or the like.
また、本変形例の発光装置10Fによれば、遮光手段15及び波長変換部材13の下面13bの周囲に配置された反射手段16の作用により、波長変換部材13の周端面13cから放出される双指向性の分布を持つ光が反射されるため、双指向性を半分にした半双指向性(片半双指向性)の分布を持つ光を放出する、車両用灯具の鉛直方向の薄型化に適した発光装置10Fを構成することが可能となる。 Further, according to the light emitting device 10F of the present modification, the twin light emitted from the peripheral end face 13c of the wavelength conversion member 13 is obtained by the action of the light shielding means 15 and the reflection means 16 disposed around the lower surface 13b of the wavelength conversion member 13. Because light with directional distribution is reflected, it is suitable for vertical thinning of vehicular lamps, which emits light with half-bidirectional (half-bidirectional) distribution that halves bi-directionality. The light emitting device 10F can be configured.
以上、波長変換部材13を用いて発光装置10Fを構成する例について説明したが、波長変換部材13に代えて、波長変換部材13B〜13Eを用いても、発光装置10Fと同様のライトガイドを着脱自在に装着するライトガイド装着構造を備えた発光装置を構成することが可能である。 The example in which the light-emitting device 10F is configured using the wavelength conversion member 13 has been described above. However, the light guide similar to the light-emitting device 10F can be attached and detached even if the wavelength conversion members 13B to 13E are used instead of the wavelength conversion member 13. It is possible to configure a light emitting device having a light guide mounting structure that is freely mounted.
上記構成の発光装置10Fによれば、さらに次の効果を奏する。 According to the light emitting device 10F configured as described above, the following effects are further achieved.
第1に、スタブ11A側とフェルール11B側とを分離し別々の部品として構成したため、スタブ11A側とフェルール11B側を別々の工程で製造することが可能となる。従って、波長変換部材13を取り付ける工程においてライトガイド12が邪魔にならず、組立が容易となる。 First, since the stub 11A side and the ferrule 11B side are separated and configured as separate parts, the stub 11A side and the ferrule 11B side can be manufactured in separate steps. Therefore, in the process of attaching the wavelength conversion member 13, the light guide 12 does not get in the way, and the assembly becomes easy.
第2に、スタブ11A側とフェルール11B側とを分離し別々の部品として構成したため、スタブ11A側又はフェルール11Bの一方のみを交換することが可能となる。 Second, since the stub 11A side and the ferrule 11B side are separated and configured as separate parts, only one of the stub 11A side or the ferrule 11B can be replaced.
第3に、スタブ11A側とフェルール11B側とを、アダプタ95のスリーブ構造で組み合わせる構成としたため、発光装置10Fと車両用灯具ユニット20とを精度よく組み合わせることが可能となる。 Third, since the stub 11A side and the ferrule 11B side are combined with the sleeve structure of the adapter 95, the light emitting device 10F and the vehicle lamp unit 20 can be combined with high accuracy.
第4に、フェルール11Bの端面より径の大きいスタブ11Aの端面(上面11Aa)に、波長変換部材13から放出される光を反射する反射手段16を配置することが可能となる。すなわち、フェルール11Bの端面に反射手段16を配置する場合と比べ、反射手段16の領域を広くすることが可能となるため、反射手段16で反射されて折り返されて上方に向かう光が増加する。従って、発光装置10Fの効率をより高めることが可能となる。 Fourth, it is possible to arrange the reflecting means 16 that reflects the light emitted from the wavelength conversion member 13 on the end surface (upper surface 11Aa) of the stub 11A having a larger diameter than the end surface of the ferrule 11B. That is, as compared with the case where the reflecting means 16 is disposed on the end face of the ferrule 11B, the area of the reflecting means 16 can be widened, so that the light reflected by the reflecting means 16 and folded back increases. Therefore, the efficiency of the light emitting device 10F can be further increased.
第5に、波長変換部材13の発熱による劣化を抑制することが可能となる。すなわち、スタブ11Aを金属等で形成することで、波長変換部材13の発熱を効率よく放熱することが可能となるため、波長変換部材13の熱劣化を抑えることが可能となる。 Fifth, it is possible to suppress deterioration of the wavelength conversion member 13 due to heat generation. That is, by forming the stub 11A with a metal or the like, it is possible to efficiently dissipate the heat generated by the wavelength conversion member 13, and thus thermal degradation of the wavelength conversion member 13 can be suppressed.
[車両用灯具ユニットの構成例2]
次に、上記構成の発光装置10を用いた車両用灯具ユニット30の構成例について説明する。
[Configuration example 2 of vehicle lamp unit]
Next, a configuration example of the vehicle lamp unit 30 using the light emitting device 10 having the above configuration will be described.
本実施形態の車両用灯具ユニット30は、自動車等の車両の前面の左右両側に配置されて車両用前照灯を構成している。図29は車両用灯具ユニット30の斜視図、図30(a)は上面図、図30(b)は正面図、図30(c)は側面図、図31は車両用灯具ユニット30をその光軸AXを含む鉛直面で切断した断面図、図32は車両用灯具ユニット30により形成される配光パターンP4の例である。 The vehicular lamp unit 30 of the present embodiment is arranged on both the left and right sides of the front surface of a vehicle such as an automobile to constitute a vehicular headlamp. 29 is a perspective view of the vehicular lamp unit 30, FIG. 30 (a) is a top view, FIG. 30 (b) is a front view, FIG. 30 (c) is a side view, and FIG. FIG. 32 is a cross-sectional view taken along a vertical plane including the axis AX, and FIG. 32 is an example of a light distribution pattern P4 formed by the vehicle lamp unit 30.
車両用灯具ユニット30には、その光軸調整が可能なように公知のエイミング機構(図示せず)が連結されている。 A known aiming mechanism (not shown) is connected to the vehicular lamp unit 30 so that the optical axis can be adjusted.
図29〜図31に示すように、車両用灯具ユニット30は、ハイビーム用配光パターンを形成するように構成されたリフレクタ型の灯具ユニットであり、反射面31、発光装置10、保持部材32等を備えている。なお、発光装置10に代えて、発光装置10A〜10F又は後述の発光装置10G〜10Hを用いてもよい。 As shown in FIGS. 29 to 31, the vehicle lamp unit 30 is a reflector-type lamp unit configured to form a high-beam light distribution pattern, and includes a reflecting surface 31, a light emitting device 10, a holding member 32, and the like. It has. In place of the light emitting device 10, light emitting devices 10A to 10F or light emitting devices 10G to 10H described later may be used.
図31に示すように、発光装置10は、その反射手段16を、光軸AXを含む上向きの水平面とした状態で、保持部材32に固定されている。光軸AXは、波長変換部材13の中心を通っている。従って、発光装置10の指向特性は、図2(b)に示すように、光軸AXを含む水平面内の強度が最大の半双指向性の分布となる。 As shown in FIG. 31, the light emitting device 10 is fixed to the holding member 32 in a state where the reflecting means 16 is an upward horizontal plane including the optical axis AX. The optical axis AX passes through the center of the wavelength conversion member 13. Therefore, as shown in FIG. 2B, the directivity characteristic of the light emitting device 10 has a half-bidirectional distribution with the maximum intensity in the horizontal plane including the optical axis AX.
図31に示すように、反射面31は、焦点F31が発光装置10の波長変換部材13近傍に設定され、車両前後方向に延びる光軸AX(回転軸)を持つ放物面系の反射面(回転放物面又はこれに類する自由曲面等)である。図29、図30(b)に示すように、反射面31は、複数の小区画反射面31bを含んでいる。反射面31(各小区画反射面31b)は、発光装置10から入射する光を予め定められた方向へ反射(配分)して、車両前面に正対した仮想鉛直スクリーン(例えば、車両前方約25mに配置されている)上に、図32に示すハイビーム用配光パターンP4を形成するように設計されている。 As shown in FIG. 31, the reflecting surface 31 has a focal point F 31 set in the vicinity of the wavelength conversion member 13 of the light emitting device 10 and has a parabolic reflecting surface having an optical axis AX (rotating axis) extending in the vehicle front-rear direction. (Rotary paraboloid or similar free-form surface). As shown in FIGS. 29 and 30 (b), the reflecting surface 31 includes a plurality of small section reflecting surfaces 31b. The reflecting surface 31 (each small section reflecting surface 31b) reflects (distributes) the light incident from the light emitting device 10 in a predetermined direction, and is a virtual vertical screen (for example, about 25 m ahead of the vehicle) facing the front of the vehicle. The high beam light distribution pattern P4 shown in FIG. 32 is formed.
反射面31は、発光装置10からの光、例えば、図2(b)に実線で示す円弧を、光軸AX10を中心に、車両後方側に延びる光軸AXに対して左右120°(合計240°)回転させた立体形状の分布の光が入射するように、波長変換部材13(周端面13c)の周囲を覆っている。具体的には、反射面31は、波長変換部材13の周囲、例えば、車両後方側に延びる光軸AXに対して左右120°(合計240°)の範囲(図19参照)から上方に延びて、波長変換部材13(周端面13c)を覆っている(図29〜図31参照)。反射面31の下端縁31aは、光軸AXを含む水平面上に位置している(図31参照)。 The reflecting surface 31 is a light beam from the light emitting device 10, for example, an arc indicated by a solid line in FIG. 2B, which is 120 ° left and right (total) with respect to the optical axis AX extending toward the vehicle rear side with the optical axis AX 10 as the center. 240 °) the wavelength conversion member 13 (the peripheral end surface 13c) is covered so that light having a three-dimensional distribution rotated may be incident. Specifically, the reflecting surface 31 extends upward from a range (see FIG. 19) of 120 ° (total 240 °) on the left and right with respect to the optical axis AX that extends around the wavelength conversion member 13, for example, on the vehicle rear side. The wavelength conversion member 13 (circumferential end surface 13c) is covered (see FIGS. 29 to 31). The lower end edge 31a of the reflecting surface 31 is located on a horizontal plane including the optical axis AX (see FIG. 31).
従って、波長変換部材13の周端面13c(光軸AXに対して左右120°(合計240°)の範囲)から放出される相対的に高い光度の光(例えば、光度の割合が50%となる半値角から内の光(半双指向性))は、反射面31のうち光軸AXを含む水平面近傍の領域31bに入射する。 Accordingly, light having a relatively high luminous intensity (for example, the luminous intensity ratio is 50%) emitted from the peripheral end surface 13c of the wavelength conversion member 13 (in the range of 120 ° to the left and right with respect to the optical axis AX (total 240 °)). The light (half-bidirectional) from the half-value angle enters the region 31b in the vicinity of the horizontal plane including the optical axis AX in the reflecting surface 31.
なお、反射面31は、波長変換部材13の周囲に配置されていればよく、光軸AXに対して左右120°(合計240°)の範囲に限定されず、適宜の範囲に配置することが可能である。 The reflecting surface 31 only needs to be disposed around the wavelength conversion member 13 and is not limited to a range of 120 ° to the left and right (240 ° in total) with respect to the optical axis AX, and may be disposed in an appropriate range. Is possible.
上記構成の車両用灯具ユニット30によれば、発光装置10から放出される光のうち相対的に高い光度の光(例えば、光度の割合が50%となる半値角から内の光(半双指向性))は、反射面31のうち光軸AXを含む水平面近傍の領域31bに入射し、当該領域31bで反射されて前方に照射される。これにより、図32に示すように、車両前面に正対した仮想鉛直スクリーン(車両前面から約25m前方に配置されている)上に、ハイビーム用配光パターンP4が形成される。 According to the vehicular lamp unit 30 having the above-described configuration, the light emitted from the light-emitting device 10 has a relatively high luminous intensity (for example, light within a half-value angle at which the luminous intensity ratio is 50% (half-bidirectionality). )) Is incident on a region 31b in the vicinity of the horizontal plane including the optical axis AX of the reflecting surface 31, is reflected by the region 31b, and is irradiated forward. Thus, as shown in FIG. 32, a high beam light distribution pattern P4 is formed on a virtual vertical screen (disposed approximately 25 m forward from the front of the vehicle) facing the front of the vehicle.
なお、車両用灯具ユニット30は、ハイビーム用配光パターンP4が仮想鉛直スクリーン上の適正範囲を照射するように公知のエイミング機構(図示せず)により光軸調整されている。 Note that the vehicular lamp unit 30 is optically adjusted by a known aiming mechanism (not shown) so that the high beam light distribution pattern P4 irradiates an appropriate range on the virtual vertical screen.
本実施形態の車両用灯具ユニット30によれば、車両用灯具ユニット20と同様、発光装置10から放出される相対的に高い光度の光(例えば、光度の割合が50%となる半値角から内の光(半双指向性))が光軸AX10上の領域ではなく反射面31のうち光軸AXを含む水平面近傍の領域31bに入射する構成であるため、鉛直方向寸法が薄型の車両用灯具ユニット30を構成することが可能となる。 According to the vehicular lamp unit 30 of the present embodiment, as in the vehicular lamp unit 20, light having a relatively high luminous intensity emitted from the light-emitting device 10 (for example, from the half-value angle at which the ratio of luminous intensity is 50%). Light (semi-bidirectional)) is not incident on the optical axis AX 10 but on the region 31b in the vicinity of the horizontal plane including the optical axis AX of the reflecting surface 31, so that the vehicle lamp has a thin vertical dimension. The unit 30 can be configured.
以上、発光装置10を用いて車両用灯具ユニット30を構成する例について説明したが、発光装置10に代えて、発光装置10A〜10F又は後述の発光装置10G〜10Hを用いても、車両用灯具ユニット30と同様の車両用灯具ユニットを構成することが可能である。 As described above, the example in which the vehicular lamp unit 30 is configured using the light emitting device 10 has been described. However, the vehicular lamp may be replaced with the light emitting devices 10A to 10F or the light emitting devices 10G to 10H described later instead of the light emitting device 10. A vehicle lamp unit similar to the unit 30 can be configured.
[発光装置10G]
次に、発光装置10の変形例として、複数のライトガイド及び複数の励起光源を用いた発光装置10Gについて説明する。
[Light Emitting Device 10G]
Next, as a modification of the light emitting device 10, a light emitting device 10G using a plurality of light guides and a plurality of excitation light sources will be described.
図33は、複数のライトガイド及び複数の励起光源を用いた発光装置10Gの斜視図である。 FIG. 33 is a perspective view of a light emitting device 10G using a plurality of light guides and a plurality of excitation light sources.
発光装置10Gは、発光装置10Eと比べ、複数のライトガイド12及び複数の励起光源14を用いている点が相違する。それ以外、発光装置10Eと同様の構成である。以下、発光装置10Eとの相違点を中心に説明し、発光装置10Eと同一の構成については同一の符号を付してその説明を省略する。 The light emitting device 10G is different from the light emitting device 10E in that a plurality of light guides 12 and a plurality of excitation light sources 14 are used. Other than that, it is the same structure as the light-emitting device 10E. Hereinafter, differences from the light emitting device 10E will be mainly described, and the same components as those of the light emitting device 10E will be denoted by the same reference numerals and description thereof will be omitted.
図33に示すように、波長変換部材13Eの底面13dは、フェルール11の上面11a(反射手段16)のうち複数のライトガイド用貫通穴11c周囲の領域に接着されて、複数のライトガイド用貫通穴11c(複数のライトガイド12の出光面12b)を覆っている。複数のライトガイド用貫通穴11c(複数のライトガイド12の出光面12b)は、車幅方向に一列に配置されている。なお、ライトガイド12及び励起光源14は複数であればよく、3つに限定されない。 As shown in FIG. 33, the bottom surface 13d of the wavelength conversion member 13E is adhered to a region around the plurality of light guide through holes 11c on the top surface 11a (reflecting means 16) of the ferrule 11, and the plurality of light guide through holes is formed. The hole 11c (the light exit surface 12b of the plurality of light guides 12) is covered. The plurality of light guide through holes 11c (the light exit surfaces 12b of the plurality of light guides 12) are arranged in a line in the vehicle width direction. In addition, the light guide 12 and the excitation light source 14 should just be plural, and are not limited to three.
本変形例の発光装置10Gによれば、複数の励起光源14からの励起光は、複数のライトガイド12の入光面12aからライトガイド12内に導入され出光面12bまで導光されて、出光面12bから出射し、波長変換部材13Eを照射する。 According to the light emitting device 10G of this modification, the excitation light from the plurality of excitation light sources 14 is introduced into the light guide 12 from the light incident surfaces 12a of the plurality of light guides 12 and guided to the light output surface 12b to be emitted. The light is emitted from the surface 12b and irradiated with the wavelength conversion member 13E.
励起光源14からの励起光が入射した波長変換部材13Eは、励起光源14からの励起光により励起される光と波長変換部材13Eを透過する励起光源14からの励起光との混色による白色光を発する。 The wavelength conversion member 13E on which the excitation light from the excitation light source 14 has entered the white light due to the color mixture of the light excited by the excitation light from the excitation light source 14 and the excitation light from the excitation light source 14 that passes through the wavelength conversion member 13E. To emit.
波長変換部材13Eが発する白色光は、遮光手段15及び/又は反射手段16で反射されて(又は遮光手段15又は反射手段16で反射されることなく直接)、波長変換部材13Eの鉛直面13fから放出される。 The white light emitted from the wavelength conversion member 13E is reflected by the light shielding means 15 and / or the reflection means 16 (or directly without being reflected by the light shielding means 15 or the reflection means 16), and is emitted from the vertical surface 13f of the wavelength conversion member 13E. Released.
波長変換部材13Eの傾斜面13eが遮光手段15で覆われているため、波長変換部材13Eの、光軸AX及び光軸AX10を含む鉛直面で切断した断面(波長変換部材13Eの鉛直面13eの断面)における指向特性は、上下対象の双指向性の分布となる(光軸AXを含む水平面内の強度が最大となる)。 Since the inclined surface 13e of the wavelength conversion member 13E is covered with a light shielding means 15, the wavelength conversion member 13E, a vertical surface 13e of the optical axis AX and the optical axis AX 10 taken along a vertical plane including a cross section (wavelength conversion member 13E The directional characteristic in the cross section) is a bi-directional distribution of the upper and lower objects (the intensity in the horizontal plane including the optical axis AX is maximized).
波長変換部材13Eの傾斜面13eから下方に放出される白色光は、波長変換部材13Eの底面13dの周囲に配置された反射手段16で反射されて折り返されて上方に向かう。 The white light emitted downward from the inclined surface 13e of the wavelength conversion member 13E is reflected by the reflecting means 16 disposed around the bottom surface 13d of the wavelength conversion member 13E and is turned upward.
その結果、発光装置10Gの、光軸AX10を含む鉛直面で切断した断面における指向特性は、図15(b)に円弧で示すように、双指向性を上半分にした片半双指向性の分布となる(光軸AXを含む水平面内の強度が最大となる)。 As a result, the light-emitting device 10G, directional characteristics in the section cut by the vertical plane including the optical axis AX 10, as indicated by arcs in FIG. 15 (b), and the top half of the bi-directional single Hanso directional Distribution (the intensity in the horizontal plane including the optical axis AX is maximized).
以上のように、発光装置10Gの指向特性は、図15(b)に実線で示す円弧を、光軸AXと光軸AX10を含む鉛直面に対して面直方向にかつ対称に引き延ばした立体形状の分布、すなわち、光軸AXを含む水平面内の強度が最大で水平面から離れるに従って強度が低下する、配光パターン(例えば、ロービーム用配光パターン)の分布に略一致した立体形状の分布となる。 As described above, the directivity characteristics of the light emitting device 10G is an arc indicated by the solid line in FIG. 15 (b), was drawn down and symmetrically in the orthogonal direction with respect to the vertical plane including the optical axis AX and the optical axis AX 10 solid The distribution of the shape, that is, the distribution of the three-dimensional shape that substantially matches the distribution of the light distribution pattern (for example, the light distribution pattern for low beam) whose intensity in the horizontal plane including the optical axis AX is maximum and decreases as the distance from the horizontal plane increases. Become.
以上説明したように、本変形例の発光装置10Gによれば、遮光手段15及び波長変換部材13Eの底面13dの周囲に配置された反射手段16の作用により、波長変換部材13Eの鉛直面13fから放出される双指向性の分布を持つ光が反射されるため、双指向性を半分にした片半双指向性の分布を持つ光を放出する、車両用灯具の鉛直方向の薄型化に適した発光装置10Gを構成することが可能となる。 As described above, according to the light emitting device 10G of the present modified example, the action of the light shielding unit 15 and the reflection unit 16 disposed around the bottom surface 13d of the wavelength conversion member 13E causes the vertical surface 13f of the wavelength conversion member 13E to be removed. Light emitted with a bi-directional distribution is reflected, so it emits light with a half-bi-directional distribution that halves the bi-directional characteristics. The apparatus 10G can be configured.
[発光装置10H]
次に、発光装置10の変形例として、ライトガイドを用いない発光装置10Hについて説明する。
[Light Emitting Device 10H]
Next, as a modification of the light emitting device 10, a light emitting device 10H that does not use a light guide will be described.
図34は、ライトガイドを用いない発光装置10Hをその光軸AX10を含む鉛直面で切断した断面図である。 Figure 34 is a sectional view taken along a vertical plane including the optical axis AX 10 a light emitting device 10H using no light guide.
発光装置10Hは、発光装置10と比べ、ライトガイド12を用いていない点で相違する。それ以外、発光装置10と同様の構成である。以下、発光装置10との相違点を中心に説明し、発光装置10と同一の構成については同一の符号を付してその説明を省略する。 The light emitting device 10H is different from the light emitting device 10 in that the light guide 12 is not used. Other than that, the configuration is the same as that of the light emitting device 10. Hereinafter, the difference from the light-emitting device 10 will be mainly described, and the same components as those of the light-emitting device 10 will be denoted by the same reference numerals and description thereof will be omitted.
図34に示すように、発光装置10Hは、レーザーホルダー18、波長変換部材13H、集光レンズ19、励起光源14等を備えている。 As shown in FIG. 34, the light emitting device 10H includes a laser holder 18, a wavelength conversion member 13H, a condenser lens 19, an excitation light source 14, and the like.
レーザーホルダー18は、波長変換部材13H、集光レンズ19及び励起光源14を保持するための部材であり、例えば、アルミ等の金属製円筒型筒部である。レーザーホルダー18は、その上部開口端を閉塞するプレート部18aを含んでいる。波長変換部材13H、集光レンズ19及び励起光源14は、レーザーホルダー18に保持されて、光軸AX10(レーザーホルダー18の中心軸)上に配置されている。プレート部18aのうち光軸AX10上には、テーパ型の貫通穴18bが形成されている。 The laser holder 18 is a member for holding the wavelength conversion member 13H, the condensing lens 19, and the excitation light source 14, and is, for example, a cylindrical cylindrical portion made of metal such as aluminum. The laser holder 18 includes a plate portion 18a that closes the upper opening end. The wavelength conversion member 13H, the condensing lens 19 and the excitation light source 14 are held by the laser holder 18 and arranged on the optical axis AX 10 (the central axis of the laser holder 18). On the optical axis AX 10 is out of the plate portion 18a, the through hole 18b of the tapered type is formed.
プレート部18aの上面は、例えば、円形で、図34に示すように、反射手段16で覆われている。反射手段16は、波長変換部材13Hが発する光を波長変換部材13H側に反射するものであればよく、例えば、プレート部18aの上面に対してアルミや銀等の金属蒸着を施すことで形成された反射層(又は反射面)であってもよいし、又は、プレート部18aが導電性を有する場合には、プレート部18aの上面に対してメッキを施すことで形成された反射層(誘電体膜)であってもよい。このようにプレート部18aの上面に対して反射層(又は反射面)を形成する方法については、例えば、特開2007−121502号公報に記載されている方法を用いることが可能である。あるいは、反射手段16は、プレート部18aの上面(上面のうち波長変換部材13以外の領域)に接着された薄い板状の反射部材であってもよいし、プレート部18aが金属製の場合には、プレート部18aの上面に対して鏡面研磨を施すことで形成された反射面であってもよい。 The upper surface of the plate portion 18a is, for example, circular and is covered with the reflecting means 16 as shown in FIG. The reflection means 16 may be any means as long as it reflects the light emitted from the wavelength conversion member 13H toward the wavelength conversion member 13H. For example, the reflection means 16 is formed by performing metal deposition such as aluminum or silver on the upper surface of the plate portion 18a. A reflective layer (or reflective surface), or when the plate portion 18a has conductivity, a reflective layer (dielectric material) formed by plating the upper surface of the plate portion 18a. Film). As a method for forming the reflective layer (or reflective surface) on the upper surface of the plate portion 18a as described above, for example, a method described in JP 2007-121502 A can be used. Alternatively, the reflecting means 16 may be a thin plate-like reflecting member bonded to the upper surface of the plate portion 18a (a region other than the wavelength conversion member 13 on the upper surface), or when the plate portion 18a is made of metal. May be a reflective surface formed by mirror polishing the upper surface of the plate portion 18a.
波長変換部材13Hは、円形をプレート部18aの上面に対して面直方向に引き延ばした円盤型部分13Haとその下部のテーパ部分13Hbとを含むYAG等の蛍光体(Ce:YAG等の蛍光物質が望ましい)である。円盤型部分13Haは、円形の上面13a及びリング状の周端面13cを含んでいる(例えば、厚み:0.2mm、直径:1.0mm)。 The wavelength converting member 13H includes a phosphor such as YAG (a fluorescent material such as Ce: YAG) including a disc-shaped portion 13Ha obtained by extending a circle in a direction perpendicular to the upper surface of the plate portion 18a and a tapered portion 13Hb below the circular portion. Desirable). The disk-shaped portion 13Ha includes a circular upper surface 13a and a ring-shaped peripheral end surface 13c (for example, thickness: 0.2 mm, diameter: 1.0 mm).
なお、円盤型部分13Haは、多角形又はその他の形状を、プレート部18aの上面に対して面直方向に引き延ばした円盤型のYAG等の蛍光体であってもよい。波長変換部材13Hは、黄色蛍光体の濃度(例えば、Ceの添加量等)を調整することで、発光色が法規で規定されたCIE色度図上の白色範囲を満たすように調整されている。 The disk-shaped portion 13Ha may be a disk-shaped phosphor such as a disk-shaped YAG in which a polygonal shape or other shapes are extended in a direction perpendicular to the upper surface of the plate portion 18a. The wavelength conversion member 13H is adjusted so that the emission color satisfies the white range on the CIE chromaticity diagram defined by law by adjusting the concentration of the yellow phosphor (for example, the amount of Ce added). .
テーパ部分13Hbは、プレート部18aに形成された貫通穴18bに挿入されこれに接着されて、貫通穴18bを覆っている。波長変換部材13Hは、プレート部18aの上面の中心に配置されている。また、波長変換部材13Hの下面中心と貫通穴18bの中心とは一致している。 The taper portion 13Hb is inserted into and bonded to the through hole 18b formed in the plate portion 18a to cover the through hole 18b. The wavelength conversion member 13H is disposed at the center of the upper surface of the plate portion 18a. Further, the center of the lower surface of the wavelength conversion member 13H and the center of the through hole 18b coincide.
波長変換部材13Hの上面13aは、遮光手段15で覆われている。 The upper surface 13a of the wavelength conversion member 13H is covered with the light shielding means 15.
反射手段16(プレート部18aの上面)は、波長変換部材13Hの周囲に配置されている。従って、波長変換部材13Hの周端面13c全周から下方に放出される光は、反射手段16で反射されて折り返されて上方に向かう。これにより、双指向性を半分にした半双指向性の分布(図2(b)参照)を持つ光を放出する発光装置10Hが構成される。 The reflection means 16 (the upper surface of the plate portion 18a) is disposed around the wavelength conversion member 13H. Therefore, the light emitted downward from the entire circumference of the peripheral end surface 13c of the wavelength conversion member 13H is reflected by the reflecting means 16 and is turned upward. Thus, a light emitting device 10H that emits light having a half-bidirectional distribution (see FIG. 2B) in which the bi-directionality is halved is configured.
励起光源14は、その光軸を光軸AX10に一致させるとともに、その発光面14aをプレート部18aに向けた状態でレーザーホルダー18の下端側に固定されている。 Excitation light source 14, along with match the optical axis to the optical axis AX 10, it is fixed to the lower end of the laser holder 18 in a state in which the light emitting surface 14a to the plate portion 18a.
励起光源14からの光Ray1が波長変換部材13Hへ効率よく入射するように、励起光源14と波長変換部材13Hとの間には、集光レンズ19が配置されている。 A condensing lens 19 is disposed between the excitation light source 14 and the wavelength conversion member 13H so that the light Ray1 from the excitation light source 14 efficiently enters the wavelength conversion member 13H.
本変形例の発光装置10Hによれば、励起光源14からの光Ray1は、集光レンズ19で集光されて、波長変換部材13Hを照射する。 According to the light emitting device 10H of this modification, the light Ray1 from the excitation light source 14 is condensed by the condenser lens 19 and irradiates the wavelength conversion member 13H.
励起光源14からの励起光が入射した波長変換部材13Hは、励起光源14からの励起光により励起される光と波長変換部材13Hを透過する励起光源14からの励起光との混色による白色光を発する。 The wavelength conversion member 13H to which the excitation light from the excitation light source 14 has entered emits white light resulting from a color mixture of the light excited by the excitation light from the excitation light source 14 and the excitation light from the excitation light source 14 that passes through the wavelength conversion member 13H. To emit.
波長変換部材13Hが発する白色光は、遮光手段15及び/又は反射手段16で反射されて(又は遮光手段15又は反射手段16で反射されることなく直接)、波長変換部材13Hの周端面13c全周から放出される。 The white light emitted from the wavelength conversion member 13H is reflected by the light shielding unit 15 and / or the reflection unit 16 (or directly without being reflected by the light shielding unit 15 or the reflection unit 16), and the entire peripheral end surface 13c of the wavelength conversion member 13H is obtained. Released from the lap.
波長変換部材13Hの上面13aが遮光手段15で覆われているため、波長変換部材13Hの、光軸AX10を含む鉛直面で切断した断面(波長変換部材13の周端面13cの断面)における指向特性は、図5に実線で示すように、上下対象の双指向性の分布となる(光軸AXを含む水平面内の強度が最大となる)。 Since the upper surface 13a of the wavelength conversion member 13H is covered by light shielding means 15, the directivity of the wavelength conversion member 13H, the cut with a vertical plane including the optical axis AX 10 section (the cross section of the peripheral edge surface 13c of the wavelength converting member 13) As shown by the solid line in FIG. 5, the characteristic is a bi-directional distribution of the upper and lower objects (the intensity in the horizontal plane including the optical axis AX is maximized).
一方、波長変換部材13Hの周端面13cがリング状の面であるため、波長変換部材13Hの上面13aから見た指向特性は、図5に二点鎖線で示すように、波長変換部材13を中心に放射状に広がる分布となる。 On the other hand, since the peripheral end surface 13c of the wavelength conversion member 13H is a ring-shaped surface, the directivity seen from the upper surface 13a of the wavelength conversion member 13H is centered on the wavelength conversion member 13 as shown by a two-dot chain line in FIG. The distribution spreads radially.
波長変換部材13Hの周端面13c全周から下方に放出される白色光は、波長変換部材13Hの周囲に配置された反射手段16で反射されて折り返されて上方に向かう。 The white light emitted downward from the entire circumference of the peripheral end surface 13c of the wavelength conversion member 13H is reflected by the reflecting means 16 disposed around the wavelength conversion member 13H and is turned upward.
その結果、発光装置10Hの、光軸AX10を含む鉛直面で切断した断面における指向特性は、図2(b)に実線で示すように、双指向性を上半分にした半双指向性の分布となる(光軸AXを含む水平面内の強度が最大となる)。 As a result, the light emitting device 10H, directional characteristics in the cross section taken along a vertical plane including the optical axis AX 10, as shown by the solid line in FIG. 2 (b), Hanso directional distributions in upper half of the bi-directional (The intensity in the horizontal plane including the optical axis AX is maximized).
一方、波長変換部材13Hの周端面13cはリング状の面であるため、発光装置10Hの上面から見た指向特性は、図2(b)に二点鎖線で示すように、波長変換部材13Hを中心に放射状に広がる分布となる。 On the other hand, since the peripheral end surface 13c of the wavelength conversion member 13H is a ring-shaped surface, the directivity characteristics viewed from the upper surface of the light emitting device 10H are as shown by the two-dot chain line in FIG. The distribution spreads radially in the center.
以上のように、発光装置10Hの指向特性は、図2(b)に実線で示す円弧を、光軸AX10を中心に360°回転させた立体形状の分布、すなわち、光軸AXを含む水平面内の強度が最大で水平面から離れるに従って強度が低下する、配光パターン(例えば、ロービーム用配光パターン)の分布に略一致した立体形状の分布となる。 As described above, the directivity characteristics of the light emitting device 10H has a horizontal plane containing the arc shown by the solid line in FIG. 2 (b), the distribution of the three-dimensional shape obtained by rotating 360 ° around the optical axis AX 10, i.e., the optical axis AX The distribution is a three-dimensional shape that substantially matches the distribution of the light distribution pattern (for example, the low beam light distribution pattern), the intensity of which is the maximum and the intensity decreases as the distance from the horizontal plane increases.
以上、円盤型部分13Haとその下部のテーパ部分13Hbとを含む波長変換部材13Hを用いて発光装置10Hを構成する例について説明したが、波長変換部材13Hに代えて、波長変換部材13、13B〜13Eを用いても、発光装置10Hと同様の発光装置を構成することが可能である。 The example in which the light-emitting device 10H is configured using the wavelength conversion member 13H including the disk-shaped portion 13Ha and the tapered portion 13Hb below the disk-shaped portion 13Ha has been described. However, the wavelength conversion members 13 and 13B are replaced with the wavelength conversion member 13H. Even if 13E is used, a light-emitting device similar to the light-emitting device 10H can be configured.
本変形例の発光装置10Hによれば、遮光手段15及び波長変換部材13の周囲に配置された反射手段16の作用により、波長変換部材13の周端面13cから放出される双指向性の分布を持つ光が反射されるため、双指向性を半分にした半双指向性の分布を持つ光を放出する、車両用灯具の鉛直方向の薄型化に適した発光装置10Hを構成することが可能となる。 According to the light emitting device 10H of this modification, the bi-directional distribution emitted from the peripheral end surface 13c of the wavelength conversion member 13 is obtained by the action of the reflection unit 16 arranged around the light shielding unit 15 and the wavelength conversion member 13. Since the light possessed is reflected, it is possible to configure the light emitting device 10H that emits light having a semi-bidirectional distribution in which the bi-directionality is halved and is suitable for thinning the vehicle lamp in the vertical direction. .
上記実施形態はあらゆる点で単なる例示にすぎない。これらの記載によって本発明は限定的に解釈されるものではない。本発明はその精神又は主要な特徴から逸脱することなく他の様々な形で実施することができる。 The above embodiment is merely an example in all respects. The present invention is not construed as being limited to these descriptions. The present invention can be implemented in various other forms without departing from the spirit or main features thereof.
10、10A-10H…発光装置、11…フェルール、11A…スタブ、11B…フェルール、12…ライトガイド、12A…第1ライトガイド、12B…第2ライトガイド、13…波長変換部材、14…励起光源、15…遮光手段、16…反射手段、17…透明体、17a…光偏向手段、18…レーザーホルダー、19…集光レンズ、20…車両用灯具ユニット、20´…車両用灯具ユニット、21…投影レンズ、22…メイン反射面、22…メイン反射面、23…シェード、23a…ミラー面、24…第1サブ反射面、25…第2サブ反射面、26…ミラーシェード兼保持部材、30…車両用灯具ユニット、31…反射面、32…保持部材、91…前面レンズ、92…ハウジング、93…灯室、94…エクステンション、95…アダプタ、95a…スリーブ、96…コネクタ DESCRIPTION OF SYMBOLS 10, 10A-10H ... Light-emitting device, 11 ... Ferrule, 11A ... Stub, 11B ... Ferrule, 12 ... Light guide, 12A ... 1st light guide, 12B ... 2nd light guide, 13 ... Wavelength conversion member, 14 ... Excitation light source , 15 ... light shielding means, 16 ... reflecting means, 17 ... transparent body, 17a ... light deflecting means, 18 ... laser holder, 19 ... condenser lens, 20 ... vehicle lamp unit, 20 '... vehicle lamp unit, 21 ... Projection lens, 22 ... main reflection surface, 22 ... main reflection surface, 23 ... shade, 23a ... mirror surface, 24 ... first sub reflection surface, 25 ... second sub reflection surface, 26 ... mirror shade and holding member, 30 ... Vehicular lamp unit, 31 ... reflecting surface, 32 ... holding member, 91 ... front lens, 92 ... housing, 93 ... light chamber, 94 ... extension, 95 ... adapter, 5a ... sleeve, 96 ... connector
Claims (7)
励起光を発生する励起光源と、
励起光を吸収し、波長変換して所定の波長域の光を放出する波長変換部材と、前記励起光源からの励起光の進行方向を変化させて前記波長変換部材を照射する光偏向手段と、を含む発光部と、
前記励起光源からの励起光を前記光偏向手段へ照射する第1光学系と、
を備え、
前記波長変換部材は、リング型の波長変換部材であり、
前記光偏向手段は、前記リング型の波長変換部材のリング内側に配置され、前記励起光源からの励起光の光密度を小さくしかつ進行方向を変化させて前記波長変換部材の内側リング面を照射する光偏向手段であることを特徴とする発光装置。 In a light emitting device used for a vehicle lamp,
An excitation light source that generates excitation light;
A wavelength conversion member that absorbs the excitation light, converts the wavelength and emits light in a predetermined wavelength range, and a light deflection unit that irradiates the wavelength conversion member by changing a traveling direction of the excitation light from the excitation light source; A light emitting unit including
A first optical system for irradiating the light deflection means with excitation light from the excitation light source;
With
The wavelength conversion member is a ring-type wavelength conversion member,
The light deflection means is disposed inside the ring of the ring-type wavelength conversion member, and irradiates the inner ring surface of the wavelength conversion member by reducing the light density of the excitation light from the excitation light source and changing the traveling direction. A light-emitting device characterized by being a light deflecting means.
前記発光装置の前記発光部から放出される光を車両前方に照射するように構成された第2光学系と、
を備えることを特徴とする車両用灯具。 A light emitting device according to any one of claims 1 to 5 ;
A second optical system configured to irradiate light emitted from the light emitting unit of the light emitting device forward of the vehicle;
A vehicular lamp characterized by comprising:
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CN201280063334.2A CN103998857B (en) | 2011-12-20 | 2012-12-18 | Light-emitting device, vehicle lamp and vehicle |
PCT/JP2012/082753 WO2013094590A1 (en) | 2011-12-20 | 2012-12-18 | Light emitting device, vehicle light fitting and vehicle |
EP12860201.8A EP2796771B1 (en) | 2011-12-20 | 2012-12-18 | Light emitting device, vehicle light fitting and vehicle |
EP14187153.3A EP2840302B1 (en) | 2011-12-20 | 2012-12-18 | Light emitting device, vehicle light and vehicle |
US14/367,386 US9335017B2 (en) | 2011-12-20 | 2012-12-18 | Light emitting device that can realize reduction in thickness of vehicle light fitting, vehicle light fitting using the light emitting device and vehicle provided with the vehicle light |
EP14187145.9A EP2840301A3 (en) | 2011-12-20 | 2012-12-18 | Light emitting device, vehicle light and vehicle |
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