Nothing Special   »   [go: up one dir, main page]

JP6150106B2 - Vehicle lighting - Google Patents

Vehicle lighting Download PDF

Info

Publication number
JP6150106B2
JP6150106B2 JP2013053590A JP2013053590A JP6150106B2 JP 6150106 B2 JP6150106 B2 JP 6150106B2 JP 2013053590 A JP2013053590 A JP 2013053590A JP 2013053590 A JP2013053590 A JP 2013053590A JP 6150106 B2 JP6150106 B2 JP 6150106B2
Authority
JP
Japan
Prior art keywords
optical member
light source
front surface
rear surface
light
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Active
Application number
JP2013053590A
Other languages
Japanese (ja)
Other versions
JP2014179282A (en
Inventor
紀勝 明神
紀勝 明神
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Stanley Electric Co Ltd
Original Assignee
Stanley Electric Co Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Stanley Electric Co Ltd filed Critical Stanley Electric Co Ltd
Priority to JP2013053590A priority Critical patent/JP6150106B2/en
Publication of JP2014179282A publication Critical patent/JP2014179282A/en
Application granted granted Critical
Publication of JP6150106B2 publication Critical patent/JP6150106B2/en
Active legal-status Critical Current
Anticipated expiration legal-status Critical

Links

Images

Landscapes

  • Non-Portable Lighting Devices Or Systems Thereof (AREA)
  • Arrangement Of Elements, Cooling, Sealing, Or The Like Of Lighting Devices (AREA)

Description

本発明は、車両用灯具に係り、特に、半導体発光素子を含む光源と光学部材とを組み合わせた構造の車両用灯具に関する。   The present invention relates to a vehicular lamp, and more particularly to a vehicular lamp having a structure in which a light source including a semiconductor light emitting element and an optical member are combined.

従来、車両用前照灯の分野においては、半導体発光素子を含む光源と光学部材とを組み合わせた構造の車両用灯具が提案されている(例えば、特許文献1参照)。   Conventionally, in the field of vehicle headlamps, a vehicle lamp having a structure in which a light source including a semiconductor light emitting element and an optical member are combined has been proposed (for example, see Patent Document 1).

図12は、特許文献1に記載の車両用灯具200の斜視図である。   FIG. 12 is a perspective view of the vehicular lamp 200 described in Patent Document 1. FIG.

図12に示すように、特許文献1に記載の車両用灯具200は、光学部材210と半導体発光素子を含む光源220とを備えている。光学部材210は、車両前方側に配置される前面212、車両後方側に配置される後面214、入光面218を含む凹部216を含んでいる。光源220は凹部216内に配置されており、入光面218は光源220からの光が効率よく入光するように、光源220を取り囲むように配置されている。   As shown in FIG. 12, the vehicular lamp 200 described in Patent Literature 1 includes an optical member 210 and a light source 220 including a semiconductor light emitting element. The optical member 210 includes a front surface 212 disposed on the vehicle front side, a rear surface 214 disposed on the vehicle rear side, and a recess 216 including a light incident surface 218. The light source 220 is disposed in the recess 216, and the light incident surface 218 is disposed so as to surround the light source 220 so that light from the light source 220 is efficiently incident.

前面212は、入光面218から光学部材210内部に入光した光源220からの光を後面214に向けて反射するとともに、後面214からの反射光が出射する面で、後面214は、前面212で反射された光源220からの光を、前面212に向けて反射する面である。   The front surface 212 is a surface that reflects the light from the light source 220 that has entered the optical member 210 from the light incident surface 218 toward the rear surface 214 and the reflected light from the rear surface 214 is emitted. The rear surface 214 is the front surface 212. This is a surface that reflects the light from the light source 220 reflected by the light toward the front surface 212.

光源220からの光は、入光面218から光学部材210内部に入光し、前面212及び後面214で反射された後に、前面212から出射して前方に照射される。前面212、後面214及び入光面218のうちの少なくとも一つは、入光面218から光学部材210内部に入光し、前面212及び後面214で反射された後に、前面212から出射して前方に照射される光(光源220の光源像220i)が、所定配光パターンを形成するように、その面形状が設計されている。   Light from the light source 220 enters the optical member 210 from the light incident surface 218, is reflected by the front surface 212 and the rear surface 214, then exits from the front surface 212 and is irradiated forward. At least one of the front surface 212, the rear surface 214, and the light incident surface 218 enters the optical member 210 from the light incident surface 218, is reflected by the front surface 212 and the rear surface 214, and then exits from the front surface 212 and forwards. The surface shape is designed so that the light (light source image 220i of the light source 220) irradiated on the light forms a predetermined light distribution pattern.

米国特許第7460985号U.S. Pat. No. 7,460,985

しかしながら、上記構成の車両用灯具200においては、光源220からの光が効率よく入光するように、入光面218が光源220を取り囲むように配置されている(すなわち、光源220と光学部材210とが接近して配置されている)ため、光源220の熱の影響により光学部材210が黄変及び/又は変形するという問題がある(特に、光学部材210が樹脂レンズである場合)。   However, in the vehicular lamp 200 having the above-described configuration, the light incident surface 218 is disposed so as to surround the light source 220 so that light from the light source 220 efficiently enters (that is, the light source 220 and the optical member 210). Therefore, there is a problem that the optical member 210 is yellowed and / or deformed due to the heat of the light source 220 (particularly, when the optical member 210 is a resin lens).

本発明は、このような事情に鑑みてなされたものであり、半導体発光素子を含む光源と光学部材とを組み合わせた構造の車両用灯具において、光源の熱の影響により光学部材が黄変及び/又は変形するのを抑制することができる車両用灯具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 in a vehicular lamp having a structure in which a light source including a semiconductor light emitting element and an optical member are combined, the optical member is yellowed and / or affected by the heat of the light source. Alternatively, an object of the present invention is to provide a vehicular lamp that can suppress deformation.

上記目的を達成するため、請求項1に記載の発明は、半導体発光素子を含む光源と、光学部材と、前記光源と前記光学部材とを支持する支持部材と、を含む少なくとも一つの光学モジュールを備えた車両用灯具において、前記光源は、前記光学部材と前記支持部材との間に配置されており、前記光学部材は、後面、前面を含んでおり、前記光学部材の後面は、前記光源が対向する箇所に入光面を含んでおり、前記光学部材は、前記入光面から入光する前記光源からの光が前記前面の少なくとも一部で反射し、さらに、前記後面の少なくとも一部で反射した後、前記前面の少なくとも一部から出射して前方に照射されるように構成されており、前記光学部材は、前記光学部材と前記支持部材との間に、空気が対流する空間が構成された状態で、前記支持部材に支持されており、前記支持部材は、ベース部と、前記ベース部の前面から前方に突出した台座部と、を含んでおり、前記光学部材の後面は、前記台座部が対向する箇所に形成された前記入光面を含む上下方向に延びた溝部を含んでおり、前記光学部材は、前記溝部と前記台座部との間に、前記空気が対流する空間としての筒部が構成された状態で、前記支持部材に支持されており、前記光源は、前記台座部に支持されて前記筒部内に配置されていることを特徴とする。 To achieve the above object, the invention described in claim 1 includes at least one optical module including a light source including a semiconductor light emitting element, an optical member, and a support member supporting the light source and the optical member. In the vehicular lamp provided, the light source is disposed between the optical member and the support member, the optical member includes a rear surface and a front surface, and the rear surface of the optical member includes the light source. The optical member includes a light incident surface at an opposite position, and the optical member reflects light from the light source that is incident from the light incident surface on at least a part of the front surface, and further on at least a part of the rear surface. After reflection, the light is emitted from at least a part of the front surface and irradiated forward, and the optical member has a space in which air convects between the optical member and the support member. In the state Serial is supported on the support member, the support member includes a base portion, a pedestal portion protruding forward from the front surface of the base portion includes a rear face of the optical member, wherein the base portion is opposed The optical member includes a groove portion that extends in the vertical direction including the light incident surface formed at a location, and the optical member includes a cylindrical portion as a space for convection of the air between the groove portion and the pedestal portion. In this state, the light source is supported by the support member, and the light source is supported by the pedestal part and disposed in the cylindrical part .

請求項1に記載の発明によれば、光学部材と支持部材との間に空気が対流する空間が構成され、当該空間において空気が対流することで、光源で発生する熱が効率よく放熱される結果、半導体発光素子を含む光源と光学部材とを組み合わせた構造の車両用灯具において、光源の熱の影響により光学部材が黄変及び/又は変形するのを抑制することができる。   According to the first aspect of the present invention, a space in which air is convected is formed between the optical member and the support member, and heat generated in the light source is efficiently radiated by convection of air in the space. As a result, in a vehicular lamp having a structure in which a light source including a semiconductor light emitting element and an optical member are combined, the optical member can be prevented from being yellowed and / or deformed due to the influence of heat from the light source.

請求項に記載の発明によれば、溝部と台座部との間に空気が対流する空間としての筒部が構成され、当該筒部において空気が対流することで、光源で発生する熱が効率よく放熱される結果、半導体発光素子を含む光源と光学部材とを組み合わせた構造の車両用灯具において、光源の熱の影響により光学部材が黄変及び/又は変形するのを抑制することができる。 According to the first aspect of the present invention, a cylindrical portion as a space in which air convects is configured between the groove portion and the pedestal portion, and heat generated by the light source is efficiently generated by convection of air in the cylindrical portion. As a result of heat dissipation, in a vehicular lamp having a structure in which a light source including a semiconductor light emitting element and an optical member are combined, the optical member can be prevented from being yellowed and / or deformed due to the influence of heat from the light source.

請求項に記載の発明は、請求項に記載の発明において、前記光学部材と前記ベース部との間には、前記空気が対流する空間が構成されていることを特徴とする。 According to a second aspect of the present invention, in the first aspect of the present invention, a space for convection of the air is formed between the optical member and the base portion.

請求項に記載の発明によれば、光学部材とベース部との間に空気が対流する空間が構成され、当該空間において空気が対流することで、光源で発生する熱(特に、光源で発生し、光学部材へ伝わる熱)が「さらに」効率よく放熱される結果、半導体発光素子を含む光源と光学部材とを組み合わせた構造の車両用灯具において、光源の熱の影響により光学部材が黄変及び/又は変形するのを「さらに」抑制することができる。 According to the second aspect of the present invention, a space in which air is convected is formed between the optical member and the base portion, and heat generated by the light source (especially, generated by the light source) by convection of air in the space. As a result, the heat transmitted to the optical member is efficiently dissipated. As a result, in the vehicular lamp having a structure in which the light source including the semiconductor light emitting element and the optical member are combined, the optical member is yellowed due to the heat of the light source And / or can be “further” inhibited from deforming.

請求項に記載の発明は、請求項1又は2に記載の発明において、前記光学部材は、光学部材本体と、前記光学部材本体を前記支持部材に固定する固定部と、を含むことを特徴とする。 According to a third aspect of the present invention, in the first or second aspect of the present invention, the optical member includes an optical member main body and a fixing portion that fixes the optical member main body to the support member. And

請求項に記載の発明によれば、光学部材が光学部材本体と光学部材本体を支持部材に固定する固定部とを含んでいるため、固定部を単独の部品として構成しなくてもよい。 According to the third aspect of the invention, since the optical member includes the optical member main body and the fixing portion that fixes the optical member main body to the support member, the fixing portion may not be configured as a single component.

請求項に記載の発明は、請求項又はに記載の発明において、前記ベース部の後面は、複数の放熱フィンを備えており、前記複数の放熱フィンは、前記筒部が開口している方向と平行の方向へ延伸していることを特徴とする。 According to a fourth aspect of the present invention, in the first or second aspect of the present invention, the rear surface of the base portion includes a plurality of heat radiation fins, and the plurality of heat radiation fins have the cylindrical portions opened. It is characterized by extending in a direction parallel to the direction in which it is present.

請求項に記載の発明によれば、複数の放熱フィンが、筒部が開口している方向と平行の方向へ延伸して、複数の放熱フィン間に空気が対流する空間が構成され、当該空間において空気が対流することで、光源で発生する熱が「さらに」効率よく放熱される結果、半導体発光素子を含む光源と光学部材とを組み合わせた構造の車両用灯具において、光源の熱の影響により光学部材が黄変及び/又は変形するのを「さらに」抑制することができる。 According to the invention described in claim 4 , the plurality of radiating fins extend in a direction parallel to the direction in which the cylindrical portion is open, and a space in which air convects between the plurality of radiating fins is configured. As a result of convection of air in the space, the heat generated by the light source is `` dissipated '' more efficiently, resulting in the influence of the heat of the light source in a vehicular lamp having a structure combining a light source including a semiconductor light emitting element and an optical member. Thus, it is possible to further suppress the yellowing and / or deformation of the optical member.

請求項に記載の発明は、半導体発光素子を含む光源と、光学部材と、前記光源と前記光学部材とを支持する支持部材と、を含む少なくとも一つの光学モジュールを備えた車両用灯具において、前記支持部材は、ベース部を含んでおり、前記ベース部の前面は、当該前面から前方に突出した台座部と、当該台座部の両側に配置された第1領域、第2領域と、を含んでおり、前記光学部材の後面は、前記台座部が対向する箇所に形成された入光面を含む上下方向に延びた溝部と、当該溝部の両側に配置された第1後面、第2後面と、を含んでおり、前記光学部材の前面は、前記第1後面の前方に配置された第1前面と、前記第2後面の前方に配置された第2前面と、を含んでおり、前記光学部材は、前記入光面から入光する前記光源からの光が前記第1前面及び前記第2前面の少なくとも一部で反射し、さらに、前記第1後面及び前記第2後面の少なくとも一部で反射した後、前記第1前面及び前記第2前面の少なくとも一部から出射して前方に照射されるように構成されており、前記光学部材は、前記溝部と前記台座部との間に、空気が対流する空間としての筒部が構成された状態で、前記支持部材に支持されており、前記光源は、前記台座部に支持されて前記筒部内に配置されていることを特徴とする。 The invention according to claim 5 is a vehicle lamp comprising at least one optical module including a light source including a semiconductor light emitting element, an optical member, and a support member that supports the light source and the optical member. The support member includes a base portion, and a front surface of the base portion includes a pedestal portion protruding forward from the front surface, and a first region and a second region disposed on both sides of the pedestal portion. And the rear surface of the optical member includes a groove portion extending in a vertical direction including a light incident surface formed at a position where the pedestal portion faces, a first rear surface and a second rear surface disposed on both sides of the groove portion. The front surface of the optical member includes a first front surface disposed in front of the first rear surface, and a second front surface disposed in front of the second rear surface. The member receives light from the light source that enters from the light incident surface. After reflecting on at least a part of the first front surface and the second front surface, and further reflecting on at least a part of the first rear surface and the second rear surface, at least a part of the first front surface and the second front surface. The optical member is configured to be irradiated to the front, and the optical member is supported in a state where a cylindrical portion as a space in which air is convected is formed between the groove portion and the pedestal portion. It is supported by the member, The said light source is supported by the said base part, and is arrange | positioned in the said cylinder part, It is characterized by the above-mentioned.

請求項に記載の発明によれば、溝部と台座部との間に空気が対流する空間としての筒部が構成され、当該筒部において空気が対流することで、光源で発生する熱が効率よく放熱される結果、半導体発光素子を含む光源と光学部材とを組み合わせた構造の車両用灯具において、光源の熱の影響により光学部材が黄変及び/又は変形するのを抑制することができる。 According to the fifth aspect of the present invention, a cylindrical portion is formed as a space in which air convects between the groove portion and the pedestal portion, and heat generated by the light source is efficiently generated by convection of air in the cylindrical portion. As a result of heat dissipation, in a vehicular lamp having a structure in which a light source including a semiconductor light emitting element and an optical member are combined, the optical member can be prevented from being yellowed and / or deformed due to the influence of heat from the light source.

請求項に記載の発明は、請求項に記載の発明において、前記光学部材の第1後面及び第2後面と前記ベース部の前面の第1領域及び第2領域との間には、空気が対流する空間が構成されていることを特徴とする。 According to a sixth aspect of the present invention, in the fifth aspect of the present invention, there is air between the first rear surface and the second rear surface of the optical member and the first region and the second region of the front surface of the base portion. It is characterized in that a space for convection is formed.

請求項に記載の発明によれば、光学部材の第1後面及び第2後面とベース部の前面の第1領域及び第2領域との間に空気が対流する空間が構成され、当該空間において空気が対流することで、光源で発生する熱(特に、光源で発生し、光学部材へ伝わる熱)が「さらに」効率よく放熱される結果、半導体発光素子を含む光源と光学部材とを組み合わせた構造の車両用灯具において、光源の熱の影響により光学部材が黄変及び/又は変形するのを「さらに」抑制することができる。 According to invention of Claim 6 , the space where air convects is comprised between the 1st back surface and 2nd back surface of an optical member, and the 1st area | region and 2nd area | region of the front surface of a base part, In the said space, As a result of the convection of air, the heat generated by the light source (particularly, the heat generated by the light source and transmitted to the optical member) is radiated more efficiently, resulting in the combination of the light source including the semiconductor light emitting element and the optical member. In the vehicular lamp having the structure, it is possible to further suppress the yellowing and / or deformation of the optical member due to the influence of the heat of the light source.

請求項に記載の発明は、請求項又はに記載の発明において、前記溝部は、V溝であることを特徴とする。 The invention according to claim 7 is the invention according to claim 5 or 6 , wherein the groove is a V-groove.

請求項に記載の発明によれば、V溝を一対の入光面として用いることができる。
According to the seventh aspect of the invention, the V-groove can be used as a pair of light incident surfaces.

本発明によれば、半導体発光素子を含む光源と光学部材とを組み合わせた構造の車両用灯具において、光源の熱の影響により光学部材が黄変及び/又は変形するのを抑制することができる車両用灯具を提供することが可能となる。   According to the present invention, in a vehicular lamp having a structure in which a light source including a semiconductor light emitting element is combined with an optical member, the vehicle can suppress yellowing and / or deformation of the optical member due to the influence of heat from the light source. It becomes possible to provide a lighting fixture.

(a)本発明の一実施形態である車両用灯具10の上面図、(b)正面図、(c)斜視図、(d)側面図である。BRIEF DESCRIPTION OF THE DRAWINGS (a) Top view of the vehicle lamp 10 which is one Embodiment of this invention, (b) Front view, (c) Perspective view, (d) It is a side view. (a)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)上に形成されるロービーム用配光パターンPLoの例、(b)ハイビーム用配光パターンPHiの例である。(A) An example of a low beam light distribution pattern P Lo formed on a virtual vertical screen (disposed approximately 25 m ahead from the front of the vehicle) facing the front of the vehicle, (b) a high beam light distribution pattern P Hi It is an example. ハイビーム用光学モジュール20の分解斜視図である。It is a disassembled perspective view of the optical module 20 for high beams. (a)ハイビーム用光学モジュール20の上面図、(b)正面図、(c)斜視図、(d)側面図である。(A) Top view of high beam optical module 20, (b) Front view, (c) Perspective view, (d) Side view. (a)図4(b)に示したハイビーム用光学モジュール20のA−A断面図、(b)B−B断面図である。(A) It is AA sectional drawing of the optical module 20 for high beams shown in FIG.4 (b), (b) It is BB sectional drawing. (a)支持部材26の上面図、(b)正面図、(c)斜視図、(d)側面図である。(A) Top view of support member 26, (b) Front view, (c) Perspective view, (d) Side view. (a)光学部材24の上面図、(b)正面図、(c)背面図、(d)斜視図、(e)側面図である。(A) Top view of optical member 24, (b) Front view, (c) Rear view, (d) Perspective view, (e) Side view. (a)車両用灯具10の正面図、(b)車両用灯具10の正面図(ロービーム用配光パターンPLoを形成する場合の発光領域)、(c)車両用灯具10の正面図(ハイビーム用配光パターンPHiを形成する場合の発光領域)である。(A) Front view of the vehicular lamp 10 (b) Front view of the vehicular lamp 10 (light emitting area when the low beam light distribution pattern P Lo is formed), (c) Front view of the vehicular lamp 10 (high beam) Light emission region in the case of forming the light distribution pattern P Hi for use. (a)支持部材26Aの上面図、(b)正面図、(c)斜視図、(d)側面図である。(A) Top view of support member 26A, (b) Front view, (c) Perspective view, (d) Side view. (a)光学部材24Aの上面図、(b)正面図、(c)背面図、(d)斜視図、(e)側面図である。(A) Top view of optical member 24A, (b) Front view, (c) Rear view, (d) Perspective view, (e) Side view. 支持部材26A及び光学部材24Aを用いた光学モジュール20(30A、30Bも同様)の上面図である。It is a top view of optical module 20 (30A and 30B are the same) using support member 26A and optical member 24A. 特許文献1に記載の車両用灯具200の斜視図である。1 is a perspective view of a vehicular lamp 200 described in Patent Document 1. FIG.

以下、本発明の一実施形態である車両用灯具(車両用前照灯)について、図面を参照しながら説明する。図1(a)は自動車等の車両の前部の左右に配置される車両用灯具のうち、左側に配置される車両用灯具10の上面図、図1(b)は正面図、図1(c)は斜視図、図1(d)は側面図である。左側に配置される車両用灯具10と右側に配置される車両用灯具とは、左右対称で実質的に同一の構成である。このため、以下、左側に配置される車両用灯具10を中心に説明し、右側に配置される車両用灯具の説明は省略する。   Hereinafter, a vehicle lamp (vehicle headlamp) according to an embodiment of the present invention will be described with reference to the drawings. FIG. 1A is a top view of a vehicle lamp 10 arranged on the left side of the vehicle lamps arranged on the left and right of the front part of a vehicle such as an automobile, FIG. 1B is a front view, FIG. c) is a perspective view, and FIG. 1 (d) is a side view. The vehicular lamp 10 arranged on the left side and the vehicular lamp arranged on the right side are symmetrical and have substantially the same configuration. For this reason, the following description will focus on the vehicular lamp 10 disposed on the left side, and the description of the vehicular lamp disposed on the right side will be omitted.

図1(a)〜図1(d)に示すように、車両用灯具10は、2つのハイビーム用光学モジュール20、2つのロービーム用光学モジュール30A、30Bの合計4つの光学モジュールを備えている。各光学モジュール20、30A、30Bは、灯具正面から見て、斜め右上がりの方向に一列に並んだ状態で配置され、かつ、車両中心寄りのユニットほど車両前方側に配置されている。各光学モジュール20、30A、30Bは、それぞれの発光領域間の距離が15mm以下となるように、ブラケット(図示せず)に固定されている。これにより、各光学モジュール20、30A、30Bの発光領域を全体で一つの発光領域として視認させることができる。   As shown in FIGS. 1A to 1D, the vehicular lamp 10 includes a total of four optical modules including two high beam optical modules 20, and two low beam optical modules 30A and 30B. The optical modules 20, 30A, 30B are arranged in a line in a diagonally upward direction when viewed from the front of the lamp, and the units closer to the vehicle center are arranged on the vehicle front side. Each optical module 20, 30A, 30B is fixed to a bracket (not shown) so that the distance between the respective light emitting areas is 15 mm or less. Thereby, the light emission area | region of each optical module 20, 30A, 30B can be visually recognized as one light emission area as a whole.

まず、ハイビーム用光学モジュール20について説明する。   First, the high beam optical module 20 will be described.

図2(b)は、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)上に形成されるハイビーム用配光パターンPHiの例である。 FIG. 2B is an example of a high beam light distribution pattern P Hi formed on a virtual vertical screen (disposed approximately 25 m ahead from the front of the vehicle) facing the front of the vehicle.

2つのハイビーム用光学モジュール20は、ハイビーム用配光パターンPHi中の集光領域P1(図2(b)参照)を形成する光学モジュールである。 Two high-beam optical module 20 is an optical module which forms a condensing region in the high-beam light distribution pattern P Hi P1 (see Figure 2 (b)).

図3は、ハイビーム用光学モジュール20の分解斜視図である。図4(a)はハイビーム用光学モジュール20の上面図、図4(b)は正面図、図4(c)は斜視図、図4(d)は側面図である。図5(a)は図4(b)に示したハイビーム用光学モジュール20のA−A断面図、図5(b)はB−B断面図である。   FIG. 3 is an exploded perspective view of the high beam optical module 20. 4A is a top view of the high beam optical module 20, FIG. 4B is a front view, FIG. 4C is a perspective view, and FIG. 4D is a side view. 5A is a cross-sectional view of the high beam optical module 20 shown in FIG. 4B, taken along line AA, and FIG. 5B is a cross-sectional view taken along line BB.

図3に示すように、ハイビーム用光学モジュール20は、半導体発光素子22bを含む光源22、光学部材24、光源22と光学部材24とを支持する支持部材26を含み、これらが図4、図5に示すように組み合わされて、いわゆるダイレクトプロジェクション型(直射型とも称される)の光学モジュール(又は灯具ユニット)を構成している。   As shown in FIG. 3, the high beam optical module 20 includes a light source 22 including a semiconductor light emitting element 22b, an optical member 24, and a support member 26 that supports the light source 22 and the optical member 24, which are illustrated in FIGS. These are combined to form a so-called direct projection type (also called direct-light type) optical module (or lamp unit).

図6(a)は支持部材26の上面図、図6(b)は正面図、図6(c)は斜視図、図6(d)は側面図である。   6A is a top view of the support member 26, FIG. 6B is a front view, FIG. 6C is a perspective view, and FIG. 6D is a side view.

支持部材26は、アルミダイカスト等の金属製で、図6(a)〜図6(d)に示すように、矩形板状のベース部26a、ベース部26aの前面の四隅にそれぞれ配置され、光学部材24が当接する台座部26b、ベース部26aの前面のうち左右方向の略中央に配置され、光源22が固定される台座部26c、ベース部26aの左右両端部に配置され、光学部材24の脚部30の係止穴30aに係合する爪部26d、ベース部26aの後面に水平方向に間隔をおいて配置される複数の放熱フィン26g等を備えている。   The support members 26 are made of metal such as aluminum die-casting, and are arranged at four corners on the front surface of the rectangular plate-like base portion 26a and the base portion 26a, as shown in FIGS. 6 (a) to 6 (d). The pedestal portion 26b with which the member 24 abuts and the front surface of the base portion 26a are disposed at substantially the center in the left-right direction. The pedestal portion 26c to which the light source 22 is fixed are disposed at both left and right ends of the base portion 26a. A claw portion 26d that engages with the locking hole 30a of the leg portion 30 and a plurality of radiating fins 26g disposed at intervals in the horizontal direction on the rear surface of the base portion 26a are provided.

ベース部26aの前面は、四隅から前方に一段高く突出した、光学部材24が当接する台座部26b、左右方向の略中央部から前方に一段高く突出した、光源22が固定される台座部26c、台座部26cの左右両側に配置された第1領域26e、第2領域26fを含んでいる。   The front surface of the base portion 26a protrudes one step higher from the four corners, a pedestal portion 26b that contacts the optical member 24, and a pedestal portion 26c that protrudes one step forward from a substantially central portion in the left-right direction, to which the light source 22 is fixed, It includes a first region 26e and a second region 26f arranged on both the left and right sides of the pedestal portion 26c.

下側の2つの台座部26bの先端面は、位置決めピン26b1を含んでいる。位置決めピン26b1は、光学部材24に形成された位置決め穴28dに挿入されるピンで、光学部材24を支持部材26に対して位置決めするために用いられる。   The tip surfaces of the two lower pedestals 26b include positioning pins 26b1. The positioning pin 26 b 1 is a pin inserted into a positioning hole 28 d formed in the optical member 24 and is used for positioning the optical member 24 with respect to the support member 26.

台座部26cは、ベース部26aの下端縁からベース部26aの上端縁より所定距離h下方の位置まで延びている(図5(b)、図6(b)参照)。台座部26cの先端面は、位置決めピン26c1、ネジ穴26c2、熱伝導部材用溝部26c3を含んでいる。位置決めピン26c1は、光源22(基板22aの裏面)に形成された位置決め穴(図示せず)に挿入されるピンで、光源22を支持部材26に対して位置決めするために用いられる。   The pedestal portion 26c extends from the lower end edge of the base portion 26a to a position below the upper end edge of the base portion 26a by a predetermined distance h (see FIGS. 5B and 6B). The distal end surface of the pedestal portion 26c includes a positioning pin 26c1, a screw hole 26c2, and a heat conducting member groove portion 26c3. The positioning pin 26c1 is a pin inserted into a positioning hole (not shown) formed in the light source 22 (the back surface of the substrate 22a), and is used to position the light source 22 with respect to the support member 26.

図3に示すように、光源22は、例えば、金属製の基板22a、当該基板22aの表面に実装された半導体発光素子22b等を備えている。半導体発光素子22bは、例えば、発光色が青系のLEDとこれを覆う黄色系の蛍光体(例えば、YAG蛍光体)とを組み合わせた構造の半導体発光素子(例えば、1mm角の発光面を含む発光ダイオード×4)で、基板22aの表面に所定間隔をおいて一列に実装されて、横長矩形の発光面(発光部)を構成している。   As shown in FIG. 3, the light source 22 includes, for example, a metal substrate 22a, a semiconductor light emitting element 22b mounted on the surface of the substrate 22a, and the like. The semiconductor light emitting element 22b includes, for example, a semiconductor light emitting element (for example, a 1 mm square light emitting surface) having a combination of a blue light emitting LED and a yellow fluorescent material (for example, YAG fluorescent material) covering the LED. Light emitting diodes × 4) are mounted in a line at a predetermined interval on the surface of the substrate 22a to constitute a horizontally long light emitting surface (light emitting portion).

半導体発光素子22bは、上記に限られず、RGB三色のLED(又はレーザーダイオード)を組み合わせた構造の半導体発光素子であってもよいし、その他構造の半導体発光素子であってもよい。なお、半導体発光素子22bは、1以上であればよい。   The semiconductor light emitting element 22b is not limited to the above, and may be a semiconductor light emitting element having a structure in which RGB three-color LEDs (or laser diodes) are combined, or may be a semiconductor light emitting element having another structure. The semiconductor light emitting element 22b may be one or more.

光源22は、支持部材26の台座部26cに支持されて、光学部材24と支持部材26との間に配置されている。具体的には、光源22は、基板22aの裏面に形成された位置決め穴(図示せず)に支持部材26の位置決めピン26c1を挿入することで、支持部材26に対して位置決めされている。そして、光源22は、図5(b)に示すように、基板22aに形成された貫通穴22a1に挿入されたネジN1が、支持部材26(台座部26c)のネジ穴26c2に螺合することで、支持部材26(台座部26c)に固定されている。   The light source 22 is supported by the pedestal portion 26 c of the support member 26 and is disposed between the optical member 24 and the support member 26. Specifically, the light source 22 is positioned with respect to the support member 26 by inserting positioning pins 26c1 of the support member 26 into positioning holes (not shown) formed on the back surface of the substrate 22a. In the light source 22, as shown in FIG. 5B, the screw N1 inserted into the through hole 22a1 formed in the substrate 22a is screwed into the screw hole 26c2 of the support member 26 (base portion 26c). Thus, it is fixed to the support member 26 (base part 26c).

光源22(基板22aの裏面)と支持部材26(台座部26cの先端面に形成された熱伝導部材用溝部26c3)との間には、光源22と支持部材26との間の伝熱性を高める観点から、熱伝導グリス(サーマルグリス)、熱伝導シート等の熱伝導性部材(図示せず)が配置されている。これにより、光源22(半導体発光素子22b)で発生する熱の放熱経路(すなわち、基板22a→熱伝導性部材→台座部26c→ベース部26a→放熱フィン26g)が構成されている。   Between the light source 22 (the back surface of the substrate 22a) and the support member 26 (the heat conducting member groove 26c3 formed on the front end surface of the pedestal portion 26c), the heat transfer between the light source 22 and the support member 26 is enhanced. From the viewpoint, a heat conductive member (not shown) such as a heat conductive grease (thermal grease) or a heat conductive sheet is disposed. Thus, a heat radiation path for heat generated in the light source 22 (semiconductor light emitting element 22b) (that is, the substrate 22a → the thermally conductive member → the base portion 26c → the base portion 26a → the heat radiation fin 26g) is configured.

なお、半導体発光素子22bの駆動電流は、基板22aの下端部に装着されるカプラ(図示せず)から基板22a上の配線パターン(図示せず)を介して供給されるように構成されている。   The driving current of the semiconductor light emitting element 22b is configured to be supplied from a coupler (not shown) attached to the lower end of the substrate 22a via a wiring pattern (not shown) on the substrate 22a. .

図7(a)は光学部材24の上面図、図7(b)は正面図、図7(c)は背面図、図7(d)は斜視図、図7(e)は側面図である。   7A is a top view of the optical member 24, FIG. 7B is a front view, FIG. 7C is a rear view, FIG. 7D is a perspective view, and FIG. 7E is a side view. .

光学部材24は、アクリルやポリカーボネイト等の透明樹脂製で、図7(a)〜図7(e)に示すように、光学部材本体28、光学部材本体28の左右両側から支持部材26に向かって延びる一対の脚部30等を含んでいる。光学部材24は、例えば、射出成形により一体成形されている。   The optical member 24 is made of a transparent resin such as acrylic or polycarbonate. As shown in FIGS. 7A to 7E, the optical member main body 28 and the left and right sides of the optical member main body 28 are directed toward the support member 26. A pair of extending leg portions 30 and the like are included. The optical member 24 is integrally formed by injection molding, for example.

図5(a)等に示すように、光学部材本体28は、入光面28a、前面28b、後面28c及び入光面28a側の光学設計上の基準点Fを含む透光部材で、入光面28aから入光する光源22からの光が光学部材本体28の前面28b(第1前面28b1及び第2前面28b2)の少なくとも一部で反射し、さらに、後面28c(第1後面28c1及び第2後面28c2)の少なくとも一部で反射した後、前面28b(第1前面28b1及び第2前面28b2)の少なくとも一部から出射して前方に照射されるように構成されている。   As shown in FIG. 5A and the like, the optical member main body 28 is a light transmitting member including a light incident surface 28a, a front surface 28b, a rear surface 28c, and a reference point F in the optical design on the light incident surface 28a side. Light from the light source 22 entering from the surface 28a is reflected by at least a part of the front surface 28b (first front surface 28b1 and second front surface 28b2) of the optical member main body 28, and further, the rear surface 28c (first rear surface 28c1 and second surface 28c1). After being reflected by at least a part of the rear surface 28c2), it is emitted from at least a part of the front surface 28b (the first front surface 28b1 and the second front surface 28b2) and irradiated forward.

図7(b)、図7(d)に示すように、光学部材本体28の前面28bは、第1後面28c1の前方に配置された第1前面28b1と、第2後面28c2の前方に配置された第2前面28b2と、第1前面28b1と第2前面28b2との間の中間領域28b3を含んでいる。   As shown in FIGS. 7B and 7D, the front surface 28b of the optical member main body 28 is disposed in front of the first rear surface 28c1 and the second rear surface 28c2. The second front surface 28b2 and an intermediate region 28b3 between the first front surface 28b1 and the second front surface 28b2.

第1前面28b1及び第2前面28b2は、入光面28aから入光する光源22からの光の入射角が臨界角を超える領域で、入光面28aから入光する光源22からの光を後面28c(第1後面28c1及び第2後面28c2)に向けて全反射するとともに、後面28c(第1後面28c1及び第2後面28c2)からの反射光が出射する領域である。   The first front surface 28b1 and the second front surface 28b2 are rear regions that receive light from the light source 22 incident from the light incident surface 28a in a region where the incident angle of light from the light source 22 incident from the light incident surface 28a exceeds the critical angle. This is a region where the light is totally reflected toward 28c (first rear surface 28c1 and second rear surface 28c2) and reflected light from the rear surface 28c (first rear surface 28c1 and second rear surface 28c2) is emitted.

中間領域28b3は、入光面28aから入光する光源22からの光の入射角が臨界角未満となる領域で、当該入光面28aから入光する臨界角未満の光を後面28c(第1後面28c1及び第2後面28c2)に向けて反射する領域である。入光面28aから入光する臨界角未満の光を後面28cに向けて反射するため、中間領域28b3には、アルミ蒸着等による鏡面処理が施されて反射膜が形成されている(図7(b)、図7(d)中のハッチング領域参照)。   The intermediate region 28b3 is a region where the incident angle of the light from the light source 22 entering from the light incident surface 28a is less than the critical angle, and the light incident from the light incident surface 28a is less than the critical angle on the rear surface 28c (first surface 28c3). This is a region that reflects toward the rear surface 28c1 and the second rear surface 28c2). In order to reflect the light having a light incident angle less than the critical angle from the light incident surface 28a toward the rear surface 28c, the intermediate region 28b3 is subjected to a mirror surface treatment such as aluminum deposition to form a reflective film (FIG. 7 ( b), see the hatched area in FIG.

図5(a)、図7(c)に示すように、光学部材本体28の後面28cは、支持部材26の台座部26cが対向する箇所に形成された矩形溝部28c3と、矩形溝部28c3の底面に形成された入光面28aを含むV溝部28c4と、矩形溝部28c3(V溝部28c4)の両側に配置された第1後面28c1、第2後面28c2と、を含んでいる。   As shown in FIGS. 5A and 7C, the rear surface 28c of the optical member main body 28 includes a rectangular groove portion 28c3 formed at a position where the pedestal portion 26c of the support member 26 faces, and a bottom surface of the rectangular groove portion 28c3. A V-groove portion 28c4 including a light incident surface 28a formed on the first and second rear surfaces 28c1 and 28c2 disposed on both sides of the rectangular groove portion 28c3 (V-groove portion 28c4).

第1後面28c1及び第2後面28c2は、前面28bからの反射光を前面28b(第1前面28b1、第2前面28b2)に向けて反射し、前面28b(第1前面28b1、第2前面28b2)から出射させる領域である。前面28bからの反射光を前面28b(第1前面28b1、第2前面28b2)に向けて反射し、前面28b(第1前面28b1、第2前面28b2)から出射させるため、第1後面28c1及び第2後面28c2には、アルミ蒸着等による鏡面処理が施されて反射膜が形成されている(図7(c)中のハッチング領域参照)。   The first rear surface 28c1 and the second rear surface 28c2 reflect the reflected light from the front surface 28b toward the front surface 28b (first front surface 28b1, second front surface 28b2), and the front surface 28b (first front surface 28b1, second front surface 28b2). It is an area to be emitted from. The reflected light from the front surface 28b is reflected toward the front surface 28b (first front surface 28b1, second front surface 28b2) and emitted from the front surface 28b (first front surface 28b1, second front surface 28b2). (2) A reflective film is formed on the rear surface 28c2 by performing a mirror surface treatment such as aluminum vapor deposition (see the hatched area in FIG. 7C).

矩形溝部28c3は、支持部材26の台座部26cの先端部が挿入される溝部で、光学部材本体28の後面28cのうち支持部材26の台座部26cが対向する箇所において上下方向に延びた状態で形成されている。   The rectangular groove portion 28c3 is a groove portion into which the distal end portion of the pedestal portion 26c of the support member 26 is inserted, and extends in a vertical direction at a portion of the rear surface 28c of the optical member main body 28 where the pedestal portion 26c of the support member 26 faces. Is formed.

V溝部28c4は、矩形溝部28c3の底面において上下方向に延びた状態で形成されている。V溝部28c4を構成する左右の面(図7(c)参照)は、一対の入光面28aとして用いられる。なお、V溝部28c4を構成する左右の面(一対の入光面28a)は、平面であってもよいし、曲面であってもよい。   The V-groove portion 28c4 is formed in a state extending in the vertical direction on the bottom surface of the rectangular groove portion 28c3. The left and right surfaces (see FIG. 7C) constituting the V-groove portion 28c4 are used as a pair of light incident surfaces 28a. Note that the left and right surfaces (the pair of light incident surfaces 28a) constituting the V groove 28c4 may be flat surfaces or curved surfaces.

光学部材24(光学部材本体28)の基準点Fは、V溝部28c4内に位置していてもよいし、V溝部28c4外に位置していてもよい。本実施形態では、光学部材24への入光効率を高める観点から、光学部材24(光学部材本体28)の基準点Fは、V溝部28c4内に位置している(図5(a)参照)。   The reference point F of the optical member 24 (optical member main body 28) may be located in the V-groove portion 28c4 or may be located outside the V-groove portion 28c4. In the present embodiment, the reference point F of the optical member 24 (optical member main body 28) is located in the V groove portion 28c4 from the viewpoint of increasing the light incident efficiency into the optical member 24 (see FIG. 5A). .

光学部材本体28の入光面28a、前面28b及び後面28c(第1後面28c1及び第2後面28c2)のうち少なくとも一つは、入光面28aから光学部材本体28内部に入光し、前面28b及び後面28c(第1後面28c1及び第2後面28c2)で反射された後に、前面28b(第1前面28b1、第2前面28b2)から出射して前方に照射される光源22からの光(半導体発光素子の光源像)が、仮想鉛直スクリーン上に、ハイビーム用配光パターンPHi中の集光領域P1(図2(b)参照)を形成するように、その面形状が設計されている。各面の設計手法については、例えば、米国特許第7460985号に詳しく記載されている。 At least one of the light incident surface 28a, the front surface 28b, and the rear surface 28c (the first rear surface 28c1 and the second rear surface 28c2) of the optical member main body 28 enters the optical member main body 28 from the light incident surface 28a, and the front surface 28b. Then, after being reflected by the rear surface 28c (the first rear surface 28c1 and the second rear surface 28c2), light from the light source 22 emitted from the front surface 28b (first front surface 28b1, second front surface 28b2) and irradiated forward (semiconductor light emission) The surface shape of the light source image of the element is designed so as to form a condensing region P1 (see FIG. 2B) in the high beam light distribution pattern P Hi on the virtual vertical screen. The design method of each surface is described in detail in US Pat. No. 7,460,985, for example.

光学部材24は、支持部材26に支持されて、光源22の前方に配置されている。具体的には、光学部材24は、光学部材24に形成された位置決め穴28dに支持部材26の位置決めピン26b1を挿入し、かつ、光学部材24の矩形溝部28c3に光源22が固定された支持部材26の台座部26cの先端部を挿入することで、支持部材26に対して位置決めされている。そして、光学部材24は、脚部30の係止穴30aに支持部材26のベース部26aの爪部26dが係合することで、支持部材26に固定されている(図4(c)、図5(a)参照)。光源22(横長矩形の発光面)は、光学部材24(光学部材本体28)の基準点F(又はその近傍)に位置している。なお、光学部材24と支持部材26とは、上記フック構造に代えて、ネジで固定してもよい。   The optical member 24 is supported by the support member 26 and is disposed in front of the light source 22. Specifically, the optical member 24 is a support member in which the positioning pin 26b1 of the support member 26 is inserted into the positioning hole 28d formed in the optical member 24, and the light source 22 is fixed to the rectangular groove 28c3 of the optical member 24. The distal end portion of the pedestal portion 26c of the 26 is inserted, so that it is positioned with respect to the support member 26. The optical member 24 is fixed to the support member 26 by engaging the claw portion 26d of the base portion 26a of the support member 26 with the locking hole 30a of the leg portion 30 (FIG. 4C). 5 (a)). The light source 22 (horizontally long light emitting surface) is located at the reference point F (or the vicinity thereof) of the optical member 24 (optical member main body 28). The optical member 24 and the support member 26 may be fixed with screws instead of the hook structure.

図5(a)、図5(b)に示すように、光学部材24は、V溝部28c4と支持部材26の台座部26cとの間に、空気が対流する空間としての筒部S1(上下方向に貫通している)が構成された状態で、支持部材26に固定されている。そして、光源22は、筒部S1内に配置された状態で支持部材26の台座部26c(先端面)に固定されている。   As shown in FIGS. 5A and 5B, the optical member 24 includes a cylindrical portion S1 (vertical direction) as a space in which air convects between the V groove portion 28c4 and the pedestal portion 26c of the support member 26. And is fixed to the support member 26. And the light source 22 is being fixed to the base part 26c (tip surface) of the support member 26 in the state arrange | positioned in cylinder part S1.

図5(b)に示すように、光学部材本体28の上端部は、上方に向かうに従って支持部材26のベース部26a側へ近づくように延びて、光学部材本体28の上端部とベース部26aの上端部との間に筒部S1が連続する空間S2を構成するとともに、前方斜め上方から筒部S1の上端開口が視認されないように、筒部S1の上端開口を覆っている。   As shown in FIG. 5B, the upper end portion of the optical member main body 28 extends so as to approach the base portion 26a side of the support member 26 as it goes upward, and the upper end portion of the optical member main body 28 and the base portion 26a. A space S2 in which the cylinder part S1 is continuous with the upper end part is formed, and the upper end opening of the cylinder part S1 is covered so that the upper end opening of the cylinder part S1 is not visually recognized from the upper front side.

図5(a)に示すように、光学部材24の後面(第1後面28c1及び第2後面28c2)とベース部26aの前面(第1領域26e及び第2領域26f)との間には、空気が対流する空間S3、S4が構成されている。   As shown in FIG. 5A, there is air between the rear surface (first rear surface 28c1 and second rear surface 28c2) of the optical member 24 and the front surface (first region 26e and second region 26f) of the base portion 26a. The spaces S3 and S4 in which the convection flows are configured.

上記構成のハイビーム用光学モジュール20においては、光源22(半導体発光素子22b)で発生する熱は、空気が対流する空間としての筒部S1及びこれに連続する空間S2において空気が上下方向に対流する(煙突効果)ことで、効率よく放熱される。なお、筒部S1における空気の対流特性を高める観点から、V溝部28c4を構成する左右の面(一対の入光面28a)は、平面(例えば、鉛直面)であるのが望ましい。   In the high beam optical module 20 configured as described above, the heat generated by the light source 22 (semiconductor light emitting element 22b) is convected in the vertical direction in the cylindrical portion S1 as a space in which air convects and in the space S2 continuous therewith. By (chimney effect), it is radiated efficiently. From the viewpoint of improving the air convection characteristics in the cylindrical portion S1, the left and right surfaces (the pair of light incident surfaces 28a) constituting the V groove portion 28c4 are preferably flat surfaces (for example, vertical surfaces).

また、光源22(半導体発光素子22b)で発生する熱(特に、光源22で発生し、光学部材24へ伝わる熱)は、空気が対流する空間S3、S4において空気が上下方向に対流することで、「さらに」効率よく放熱される。   Further, the heat generated by the light source 22 (semiconductor light emitting element 22b) (particularly, the heat generated by the light source 22 and transmitted to the optical member 24) is convected in the vertical direction in the spaces S3 and S4 where the air convects. , "More" efficiently radiates heat.

また、上記構成のハイビーム用光学モジュール20においては、光源22(半導体発光素子22b)で発生する熱は、基板22a→熱伝導性部材→台座部26c→ベース部26a→放熱フィン26gの経路を経て、放熱フィン26gから周辺空気へ放出される。その際、図4(c)に示すように、複数の放熱フィン26gは支持部材26のベース部26aの後面に水平方向に間隔をおいて配置されている(すなわち、複数の放熱フィン26gは、筒部S1が開口している方向(図4(c)中上下方向)と平行の方向へ延伸している)ため、光源22(半導体発光素子22b)で発生する熱は、複数の放熱フィン26g間の空間において空気が上下方向に対流することで、「さらに」効率よく放熱される。   Further, in the high beam optical module 20 having the above configuration, the heat generated by the light source 22 (semiconductor light emitting element 22b) passes through the path of the substrate 22a → the thermally conductive member → the base portion 26c → the base portion 26a → the heat radiation fin 26g. Then, the heat is released from the radiation fins 26g to the surrounding air. At that time, as shown in FIG. 4 (c), the plurality of heat radiation fins 26g are horizontally spaced on the rear surface of the base portion 26a of the support member 26 (that is, the plurality of heat radiation fins 26g are Since the cylindrical portion S1 extends in a direction parallel to the opening direction (the vertical direction in FIG. 4C), the heat generated in the light source 22 (semiconductor light emitting element 22b) is a plurality of radiation fins 26g. Air is convected in the vertical direction in the space between them, so that heat is radiated more efficiently.

次に、ロービーム用光学モジュール30Aについて説明する。   Next, the low beam optical module 30A will be described.

図2(a)は、仮想鉛直スクリーン上に形成されるロービーム用配光パターンPLoの例である。 FIG. 2A is an example of a low beam light distribution pattern P Lo formed on a virtual vertical screen.

ロービーム用光学モジュール30Aは、ロービーム用配光パターンPLo中の集光領域P2(図2(a)参照)を形成する光学モジュールである。 The low beam optical module 30A is an optical module that forms a condensing region P2 (see FIG. 2A) in the low beam light distribution pattern PLo .

ロービーム用光学モジュール30Aは、ハイビーム用光学モジュール20と同様、半導体発光素子22bを含む光源22、光学部材24、光源22と光学部材24とを支持する支持部材26を含み、これらが図4、図5に示すように組み合わされて、いわゆるダイレクトプロジェクション型(直射型とも称される)の光学モジュール(又は灯具ユニット)を構成している。   Similar to the high beam optical module 20, the low beam optical module 30A includes a light source 22 including a semiconductor light emitting element 22b, an optical member 24, and a support member 26 that supports the light source 22 and the optical member 24. 5 are combined to constitute a so-called direct projection type (also called direct-light type) optical module (or lamp unit).

一方、ロービーム用光学モジュール30Aは、ハイビーム用光学モジュール20と比べ、光学部材本体28の入光面28a、前面28b及び後面28c(第1後面28c1及び第2後面28c2)のうち少なくとも一つが、入光面28aから光学部材本体28内部に入光し、前面28b及び後面28c(第1後面28c1及び第2後面28c2)で反射された後に、前面28b(第1前面28b1、第2前面28b2)から出射して前方に照射される光源22からの光(半導体発光素子の光源像)が、仮想鉛直スクリーン上に、ロービーム用配光パターンLo中の集光領域P2(図2(a)参照)を形成するように、その面形状が設計されている点で異なっている。 On the other hand, in the low beam optical module 30A, at least one of the light incident surface 28a, the front surface 28b, and the rear surface 28c (the first rear surface 28c1 and the second rear surface 28c2) of the optical member main body 28 is smaller than the high beam optical module 20. The light enters the optical member main body 28 from the light surface 28a and is reflected by the front surface 28b and the rear surface 28c (first rear surface 28c1 and second rear surface 28c2), and then from the front surface 28b (first front surface 28b1, second front surface 28b2). The light (light source image of the semiconductor light emitting element) emitted from the light source 22 emitted and irradiated forward is focused on the condensing region P2 (see FIG. 2A) in the low beam light distribution pattern Lo on the virtual vertical screen. It differs in that the surface shape is designed to form.

次に、ロービーム用光学モジュール30Bについて説明する。   Next, the low beam optical module 30B will be described.

ロービーム用光学モジュール30Bは、ロービーム用配光パターンPLo中の拡散領域P3(図2(a)参照)を形成する光学モジュールである。 The low beam optical module 30 </ b> B is an optical module that forms a diffusion region P < b> 3 (see FIG. 2A) in the low beam light distribution pattern P Lo .

ロービーム用光学モジュール30Bは、ハイビーム用光学モジュール20と同様、半導体発光素子22bを含む光源22、光学部材24、光源22と光学部材24とを支持する支持部材26を含み、これらが図4、図5に示すように組み合わされて、いわゆるダイレクトプロジェクション型(直射型とも称される)の光学モジュール(又は光学モジュール)を構成している。   Similar to the high beam optical module 20, the low beam optical module 30B includes a light source 22 including a semiconductor light emitting element 22b, an optical member 24, and a support member 26 that supports the light source 22 and the optical member 24. 5 are combined to form a so-called direct projection type (also called direct-light type) optical module (or optical module).

一方、ロービーム用光学モジュール30Bは、ハイビーム用光学モジュール20と比べ、光学部材本体28の入光面28a、前面28b及び後面28c(第1後面28c1及び第2後面28c2)のうち少なくとも一つが、入光面28aから光学部材本体28内部に入光し、前面28b及び後面28c(第1後面28c1及び第2後面28c2)で反射された後に、前面28b(第1前面28b1、第2前面28b2)から出射して前方に照射される光源22からの光(半導体発光素子の光源像)が、仮想鉛直スクリーン上に、ロービーム用配光パターンLo中の拡散領域P3(図2(a)参照)を形成するように、その面形状が設計されている点で異なっている。 On the other hand, in the low beam optical module 30B, at least one of the light incident surface 28a, the front surface 28b, and the rear surface 28c (the first rear surface 28c1 and the second rear surface 28c2) of the optical member main body 28 is smaller than the high beam optical module 20. The light enters the optical member main body 28 from the light surface 28a and is reflected by the front surface 28b and the rear surface 28c (first rear surface 28c1 and second rear surface 28c2), and then from the front surface 28b (first front surface 28b1, second front surface 28b2). Light from the light source 22 that is emitted and emitted forward (a light source image of the semiconductor light emitting element) forms a diffusion region P3 (see FIG. 2A) in the low beam light distribution pattern Lo on the virtual vertical screen. Thus, the surface shape is different in that it is designed.

次に、各光学モジュール20、30A、30Bの動作例(ハイビーム用配光パターンPHi又はロービーム用配光パターンPLoに切り換える動作例)について説明する。 Next, an operation example of the optical modules 20, 30 </ b> A, and 30 </ b> B (an operation example of switching to the high beam light distribution pattern P Hi or the low beam light distribution pattern P Lo ) will be described.

ハイビーム用配光パターンPHi又はロービーム用配光パターンPLoの切り換えは、各光学モジュール20、30A、30B(それぞれの光源22)が電気的に接続されたECU等の制御回路(図示せず)によって行われる。 Switching between the high beam distribution pattern P Hi or the low beam distribution pattern P Lo is a control circuit (not shown) such as an ECU to which the optical modules 20, 30A, 30B (each light source 22) are electrically connected. Is done by.

制御回路は、各光学モジュール20、30A、30B(それぞれの光源22)の点灯状態(点灯又は消灯)を個別に制御することで、ハイビーム用配光パターンPHi又はロービーム用配光パターンPLoに切り換える。 The control circuit individually controls the lighting state (lighting or extinguishing) of each optical module 20, 30A, 30B (each light source 22), so that the high beam light distribution pattern P Hi or the low beam light distribution pattern P Lo is obtained. Switch.

例えば、ハイビーム用配光パターンPHiを形成する場合、制御回路は、図8(c)に示すように、各光学モジュール20、30A、30B(それぞれの光源22)が点灯するように、各光学モジュール20、30A、30B(それぞれの光源22)を制御する。図8(c)中、ハッチングされていない白色の領域は、各光学モジュール20、30A、30B(それぞれの光源22)が点灯されて発光している発光領域を表している。 For example, in the case of forming the high beam light distribution pattern P Hi , as shown in FIG. 8C, the control circuit sets each optical module 20, 30A, 30B (each light source 22) to light. The modules 20, 30A, 30B (each light source 22) are controlled. In FIG. 8C, white areas that are not hatched represent light emitting areas in which the optical modules 20, 30A, and 30B (each light source 22) are turned on to emit light.

以上のように、各光学モジュール20、30A、30B(それぞれの光源22)が点灯することで、図2(b)に示すように、2つのハイビーム用光学ユニット20により形成されるハイビーム用配光パターンPHi中の集光領域P1と、ロービーム用光学モジュール30Aにより形成される集光領域P2と、ロービーム用光学モジュール30Bにより形成される拡散領域P3とが重畳されたハイビーム用配光パターンPHiが形成される。 As described above, when each of the optical modules 20, 30A, 30B (each light source 22) is turned on, the high beam light distribution formed by the two high beam optical units 20 as shown in FIG. 2B. a condensing region P1 in the pattern P Hi, the condensing area P2 is formed by the optical module 30A for low beam, light distribution pattern for high beam and diffusion region P3 is superimposed which is formed by the optical module 30B for a low beam P Hi Is formed.

一方、ロービーム用配光パターンPLoを形成する場合、制御回路は、図8(b)に示すように、光学モジュール20(光源22)が消灯し、光学モジュール30A、30B(それぞれの光源22)が点灯するように、各光学モジュール20、30A、30B(それぞれの光源22)を制御する。図8(b)中、ハッチングされていない白色の領域は、光学モジュール30A、30B(それぞれの光源22)が点灯されて発光している発光領域を表している。 On the other hand, when forming the low beam light distribution pattern P Lo , the control circuit turns off the optical module 20 (light source 22) and the optical modules 30A and 30B (respective light sources 22) as shown in FIG. 8B. Each of the optical modules 20, 30A, 30B (each light source 22) is controlled so that is lit. In FIG. 8B, white areas that are not hatched represent light emitting areas in which the optical modules 30A and 30B (the respective light sources 22) are turned on to emit light.

以上のように、光学モジュール20(光源22)が消灯し、光学モジュール30A、30B(それぞれの光源22)が点灯することで、図2(a)に示すように、ロービーム用光学モジュール30Aにより形成される集光領域P2と、ロービーム用光学モジュール30Bにより形成される拡散領域P3とが重畳されたロービーム用配光パターンPLoが形成される。 As described above, the optical module 20 (light source 22) is turned off and the optical modules 30A and 30B (respective light sources 22) are turned on to form the low beam optical module 30A as shown in FIG. The light distribution pattern P Lo for low beam is formed by superimposing the light condensing region P2 and the diffusion region P3 formed by the low beam optical module 30B.

以上説明したように、本実施形態の車両用灯具10を構成する各光学モジュール20、30A、30Bによれば、V溝部28c4と台座部26cとの間に空気が上下方向に対流する空間としての筒部S1(及びこれに連続する空間S2)が構成され、当該筒部S1(及びこれに連続する空間S2)において空気が上下方向に対流することで、光源22で発生する熱が効率よく放熱される結果、半導体発光素子22bを含む光源22と光学部材24とを組み合わせた構造の車両用灯具10において、光源22の熱の影響により光学部材24が黄変及び/又は変形するのを抑制することができる。   As described above, according to each optical module 20, 30A, 30B constituting the vehicular lamp 10 of the present embodiment, the space between the V-groove portion 28c4 and the pedestal portion 26c serves as a space in which air convects in the vertical direction. A cylindrical portion S1 (and a space S2 continuous with the cylindrical portion S1) is configured, and heat generated in the light source 22 is efficiently radiated by air convection in the vertical direction in the cylindrical portion S1 (and the space S2 continuous therewith). As a result, in the vehicular lamp 10 having a structure in which the light source 22 including the semiconductor light emitting element 22b and the optical member 24 are combined, the optical member 24 is prevented from being yellowed and / or deformed due to the heat of the light source 22. be able to.

また、本実施形態の車両用灯具10を構成する各光学モジュール20、30A、30Bによれば、光学部材24の第1後面28c1及び第2後面28c2とベース部26aの前面の第1領域26e及び第2領域26fとの間に空気が上下方向に対流する空間S3、S4が構成され、当該空間S3、S4において空気が上下方向に対流することで、光源22で発生する熱(特に、光源22で発生し、光学部材24へ伝わる熱)が「さらに」効率よく放熱される結果、半導体発光素子22bを含む光源22と光学部材24とを組み合わせた構造の車両用灯具10において、光源22の熱の影響により光学部材24が黄変及び/又は変形するのを「さらに」抑制することができる。   Moreover, according to each optical module 20, 30A, 30B which comprises the vehicle lamp 10 of this embodiment, the 1st area | region 26e of the 1st area | region 26e of the 1st rear surface 28c1 and the 2nd rear surface 28c2 of the optical member 24, and the front surface of the base part 26a, and Spaces S3 and S4 in which air convects in the vertical direction are formed between the second region 26f, and heat generated by the light source 22 (particularly, the light source 22) by convection in the vertical direction in the spaces S3 and S4. In the vehicular lamp 10 having a structure in which the light source 22 including the semiconductor light emitting element 22b and the optical member 24 are combined, the heat of the light source 22 is generated. It is possible to “further” suppress the yellowing and / or deformation of the optical member 24 due to the influence of the above.

また、本実施形態の車両用灯具10を構成する各光学モジュール20、30A、30Bによれば、複数の放熱フィン26gが、筒部S1が開口している方向と平行の方向へ延伸して、複数の放熱フィン26g間に空気が上下方向に対流する空間が構成され、当該空間において空気が上下方向に対流することで、光源22で発生する熱が「さらに」効率よく放熱される結果、半導体発光素子22bを含む光源22と光学部材24とを組み合わせた構造の車両用灯具10において、光源22の熱の影響により光学部材24が黄変及び/又は変形するのを「さらに」抑制することができる。   Moreover, according to each optical module 20, 30A, 30B which comprises the vehicle lamp 10 of this embodiment, the several radiation fin 26g is extended in the direction parallel to the direction where the cylinder part S1 is open, A space in which air convects in the vertical direction is formed between the plurality of heat radiating fins 26g, and the air generated in the space convects in the vertical direction, so that the heat generated in the light source 22 can be radiated "more" efficiently. In the vehicular lamp 10 having a structure in which the light source 22 including the light emitting element 22b and the optical member 24 are combined, “further” suppressing the yellowing and / or deformation of the optical member 24 due to the influence of the heat of the light source 22 is suppressed. it can.

次に、支持部材26及び光学部材24の変形例(支持部材26A及び光学部材24A)について説明する。   Next, modifications of the support member 26 and the optical member 24 (support member 26A and optical member 24A) will be described.

本変形例の支持部材26A及び光学部材24Aによれば、空気が対流する空間としての筒部S1Aを、上下方向にストレートに延びる筒部(上下方向に貫通している)として構成することができるため、上記実施形態の筒部S1と比べ、空気の対流特性をより高めることができる。その結果、光源22(半導体発光素子22b)で発生する熱をより効率よく放熱することができる。   According to the support member 26 </ b> A and the optical member 24 </ b> A of the present modified example, the cylindrical portion S <b> 1 </ b> A as a space in which air convects can be configured as a cylindrical portion (through the vertical direction) that extends straight in the vertical direction. Therefore, the air convection characteristics can be further enhanced as compared with the cylindrical portion S1 of the above embodiment. As a result, the heat generated in the light source 22 (semiconductor light emitting element 22b) can be radiated more efficiently.

これを実現するため、本変形例の支持部材26A及び光学部材24Aは、次のように構成されている。   In order to realize this, the support member 26A and the optical member 24A of the present modification are configured as follows.

図9(a)は支持部材26Aの上面図、図9(b)は正面図、図9(c)は斜視図、図9(d)は側面図である。   9A is a top view of the support member 26A, FIG. 9B is a front view, FIG. 9C is a perspective view, and FIG. 9D is a side view.

図9(a)〜図9(d)に示すように、本変形例の支持部材26Aの台座部26cは、ベース部26aの下端縁からベース部26aの上端縁まで延びている。そして、支持部材26Aの台座部26cの先端面は、鉛直面とされている。   As shown in FIGS. 9A to 9D, the pedestal portion 26c of the support member 26A of the present modification extends from the lower end edge of the base portion 26a to the upper end edge of the base portion 26a. And the front end surface of the base part 26c of 26 A of support members is made into the perpendicular surface.

図10(a)は光学部材24Aの上面図、図10(b)は正面図、図10(c)は背面図、図10(d)は斜視図、図10(e)は側面図である。   10 (a) is a top view of the optical member 24A, FIG. 10 (b) is a front view, FIG. 10 (c) is a rear view, FIG. 10 (d) is a perspective view, and FIG. 10 (e) is a side view. .

図10(a)〜図10(e)に示すように、本変形例の光学部材本体28の後面28cのうち、支持部材26の台座部26cが対向する箇所に形成された矩形溝部28c3及び矩形溝部28c3の底面に形成されたV溝部28c4は、光学部材本体28の後面28cの下端縁から光学部材本体28の後面28cの上端縁までストレートに延びている。そして、V溝部28c4を構成する左右の面(一対の入光面28a)は、鉛直面とされている。   As shown in FIGS. 10A to 10E, a rectangular groove portion 28c3 and a rectangular shape formed in a portion of the rear surface 28c of the optical member main body 28 according to the present modification where the pedestal portion 26c of the support member 26 faces. The V-groove portion 28c4 formed on the bottom surface of the groove portion 28c3 extends straight from the lower end edge of the rear surface 28c of the optical member body 28 to the upper end edge of the rear surface 28c of the optical member body 28. The left and right surfaces (the pair of light incident surfaces 28a) that form the V groove 28c4 are vertical surfaces.

本変形例の光学部材24Aは、図11に示すように、V溝部28c4と支持部材26の台座部26cとの間に、空気が対流する空間としての上下方向にストレートに延びる筒部S1Aが構成された状態で、支持部材26Aに固定されている。   As shown in FIG. 11, the optical member 24A according to the present modification includes a cylindrical portion S1A that extends straight in the vertical direction as a space in which air convects between the V groove portion 28c4 and the pedestal portion 26c of the support member 26. In this state, it is fixed to the support member 26A.

以上説明したように、本変形例の支持部材26A及び光学部材24Aを用いた各光学モジュール20、30A、30Bによれば、V溝部28c4と台座部26cとの間に空気が上下方向に対流する空間としての上下方向にストレートに延びる筒部S1Aが構成され、当該筒部S1Aにおいて空気が上下方向に対流することで、光源22で発生する熱が効率よく放熱される結果、半導体発光素子22bを含む光源22と光学部材24Aとを組み合わせた構造の車両用灯具10において、光源22の熱の影響により光学部材24Aが黄変及び/又は変形するのを抑制することができる。   As described above, according to the optical modules 20, 30A, and 30B using the support member 26A and the optical member 24A of this modification, air convects in the vertical direction between the V-groove portion 28c4 and the pedestal portion 26c. A cylindrical portion S1A that extends straight in the vertical direction as a space is configured, and air is convected in the vertical direction in the cylindrical portion S1A, so that the heat generated in the light source 22 is efficiently dissipated. As a result, the semiconductor light emitting element 22b In the vehicular lamp 10 having a structure in which the included light source 22 and the optical member 24A are combined, the optical member 24A can be prevented from being yellowed and / or deformed due to the heat of the light source 22.

また、本変形例の支持部材26A及び光学部材24Aを用いた各光学モジュール20、30A、30Bによれば、光学部材24の第1後面28c1及び第2後面28c2とベース部26aの前面の第1領域26e及び第2領域26fとの間に空気が上下方向に対流する空間S3、S4が構成され、当該空間S3、S4において空気が上下方向に対流することで、光源22で発生する熱(特に、光源22で発生し、光学部材22へ伝わる熱)が「さらに」効率よく放熱される結果、半導体発光素子22bを含む光源22と光学部材24Aとを組み合わせた構造の車両用灯具10において、光源22の熱の影響により光学部材24Aが黄変及び/又は変形するのを「さらに」抑制することができる。   Further, according to the optical modules 20, 30A, 30B using the support member 26A and the optical member 24A of the present modification, the first rear surface 28c1 and the second rear surface 28c2 of the optical member 24 and the first front surface of the base portion 26a. Spaces S3 and S4 in which air convects in the vertical direction are formed between the region 26e and the second region 26f, and heat generated in the light source 22 (particularly, in the spaces S3 and S4 convects in the vertical direction). In the vehicular lamp 10 having a structure in which the light source 22 including the semiconductor light-emitting element 22b and the optical member 24A are combined, as a result of efficiently further radiating the heat generated in the light source 22 and transmitted to the optical member 22) It is possible to “further” suppress the yellowing and / or deformation of the optical member 24 </ b> A due to the influence of the heat of 22.

また、本変形例の支持部材26A及び光学部材24Aを用いた各光学モジュール20、30A、30Bによれば、複数の放熱フィン26gが、筒部S1Aが開口している方向と平行の方向へ延伸して、複数の放熱フィン26g間に空気が上下方向に対流する空間が構成され、当該空間において空気が上下方向に対流することで、光源22で発生する熱が「さらに」効率よく放熱される結果、半導体発光素子22bを含む光源22と光学部材24Aとを組み合わせた構造の車両用灯具10において、光源22の熱の影響により光学部材24Aが黄変及び/又は変形するのを「さらに」抑制することができる。   Moreover, according to each optical module 20, 30A, 30B using the supporting member 26A and the optical member 24A of this modification, the plurality of heat radiating fins 26g extend in a direction parallel to the direction in which the cylindrical portion S1A is opened. Thus, a space in which air convects in the vertical direction is formed between the plurality of heat radiating fins 26g, and the air generated in the space convects in the vertical direction, so that the heat generated in the light source 22 is radiated more efficiently. As a result, in the vehicular lamp 10 having a structure in which the light source 22 including the semiconductor light emitting element 22b and the optical member 24A are combined, the optical member 24A is further “suppressed” from being yellowed and / or deformed due to the heat of the light source 22. can do.

なお、各光学モジュール20、30A、30Bは、第1前面28b1と第2前面28b2が左右方向に配置された状態だけでなく、第1前面28b1と第2前面28b2が上下方向又は斜め方向に配置された状態で用いることもできる。   Each optical module 20, 30A, 30B is not only in a state where the first front surface 28b1 and the second front surface 28b2 are arranged in the left-right direction, but also in the vertical direction or the oblique direction, the first front surface 28b1 and the second front surface 28b2. It can also be used in the state that has been achieved.

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。本発明はその精神また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…車両用灯具、20…ハイビーム用光学モジュール、22…光源、22a…基板、22a1…貫通穴、22b…半導体発光素子、24、22A…光学部材、26、26A…支持部材、26a…ベース部、26b…台座部、26b1…位置決めピン、26c…台座部、26c1…位置決めピン、26c2…ネジ穴、26c3…熱伝導部材用溝部、26d…爪部、26e…第1領域、、26f…第2領域、26g…放熱フィン、28…光学部材本体、28a…入光面、28b…前面、28b1…第1前面、28b2…第2前面、28b3…中間領域、28c…後面、28c1…第1後面、28c2…第2後面、28c3…矩形溝部、28c4…V溝部、28d…穴、30…脚部、30a…係止穴、30A、30B…ロービーム用光学モジュール   DESCRIPTION OF SYMBOLS 10 ... Vehicle lamp, 20 ... High beam optical module, 22 ... Light source, 22a ... Board | substrate, 22a1 ... Through-hole, 22b ... Semiconductor light emitting element, 24, 22A ... Optical member, 26, 26A ... Support member, 26a ... Base part , 26b ... pedestal part, 26b1 ... positioning pin, 26c ... pedestal part, 26c1 ... positioning pin, 26c2 ... screw hole, 26c3 ... groove part for heat conduction member, 26d ... claw part, 26e ... first region, 26f ... second Area, 26g ... radiating fin, 28 ... optical member body, 28a ... light incident surface, 28b ... front face, 28b1 ... first front face, 28b2 ... second front face, 28b3 ... intermediate area, 28c ... rear face, 28c1 ... first rear face, 28c2 ... second rear surface, 28c3 ... rectangular groove, 28c4 ... V-groove, 28d ... hole, 30 ... leg, 30a ... locking hole, 30A, 30B ... low beam optical module

Claims (7)

半導体発光素子を含む光源と、光学部材と、前記光源と前記光学部材とを支持する支持部材と、を含む少なくとも一つの光学モジュールを備えた車両用灯具において、
前記光源は、前記光学部材と前記支持部材との間に配置されており、
前記光学部材は、後面、前面を含んでおり、
前記光学部材の後面は、前記光源が対向する箇所に入光面を含んでおり、
前記光学部材は、前記入光面から入光する前記光源からの光が前記前面の少なくとも一部で反射し、さらに、前記後面の少なくとも一部で反射した後、前記前面の少なくとも一部から出射して前方に照射されるように構成されており、
前記光学部材は、前記光学部材と前記支持部材との間に、空気が対流する空間が構成された状態で、前記支持部材に支持されており、
前記支持部材は、ベース部と、前記ベース部の前面から前方に突出した台座部と、を含んでおり、
前記光学部材の後面は、前記台座部が対向する箇所に形成された前記入光面を含む上下方向に延びた溝部を含んでおり、
前記光学部材は、前記溝部と前記台座部との間に、前記空気が対流する空間としての筒部が構成された状態で、前記支持部材に支持されており、
前記光源は、前記台座部に支持されて前記筒部内に配置されていることを特徴とする車両用灯具。
In a vehicular lamp including at least one optical module including a light source including a semiconductor light emitting element, an optical member, and a support member that supports the light source and the optical member,
The light source is disposed between the optical member and the support member;
The optical member includes a rear surface and a front surface,
The rear surface of the optical member includes a light incident surface at a location facing the light source,
The optical member reflects light from the light source that is incident from the light incident surface on at least a portion of the front surface, and further reflects on at least a portion of the rear surface and then exits from at least a portion of the front surface. Is configured to irradiate forward,
The optical member is supported by the support member in a state where a space in which air is convected is formed between the optical member and the support member .
The support member includes a base portion and a pedestal portion protruding forward from the front surface of the base portion,
The rear surface of the optical member includes a groove portion extending in the vertical direction including the light incident surface formed at a location where the pedestal portion faces.
The optical member is supported by the support member in a state where a cylindrical portion as a space in which the air convects is configured between the groove portion and the pedestal portion,
The vehicular lamp , wherein the light source is supported by the pedestal portion and disposed in the cylindrical portion .
前記光学部材と前記ベース部との間には、前記空気が対流する空間が構成されていることを特徴とする請求項に記載の車両用灯具。 Wherein between the optical member and said base portion, a vehicle lamp according to claim 1, wherein the air, characterized in that a space for convection is configured. 前記光学部材は、光学部材本体と、前記光学部材本体を前記支持部材に固定する固定部と、を含むことを特徴とする請求項1又は2に記載の車両用灯具。 The optical member includes an optical member body, the vehicular lamp according to claim 1 or 2, characterized in that it comprises a fixing portion for fixing the optical member body to the support member. 前記ベース部の後面は、複数の放熱フィンを備えており、
前記複数の放熱フィンは、前記筒部が開口している方向と平行の方向へ延伸していることを特徴とする請求項又はに記載の車両用灯具。
The rear surface of the base portion includes a plurality of heat radiation fins,
Wherein the plurality of heat dissipating fins, the vehicle lamp according to claim 1 or 2, characterized in that the cylindrical portion is stretched in the direction parallel to the direction that opens.
半導体発光素子を含む光源と、光学部材と、前記光源と前記光学部材とを支持する支持部材と、を含む少なくとも一つの光学モジュールを備えた車両用灯具において、
前記支持部材は、ベース部を含んでおり、
前記ベース部の前面は、当該前面から前方に突出した台座部と、当該台座部の両側に配置された第1領域、第2領域と、を含んでおり、
前記光学部材の後面は、前記台座部が対向する箇所に形成された入光面を含む上下方向に延びた溝部と、当該溝部の両側に配置された第1後面、第2後面と、を含んでおり、
前記光学部材の前面は、前記第1後面の前方に配置された第1前面と、前記第2後面の前方に配置された第2前面と、を含んでおり、
前記光学部材は、前記入光面から入光する前記光源からの光が前記第1前面及び前記第2前面の少なくとも一部で反射し、さらに、前記第1後面及び前記第2後面の少なくとも一部で反射した後、前記第1前面及び前記第2前面の少なくとも一部から出射して前方に照射されるように構成されており、
前記光学部材は、前記溝部と前記台座部との間に、空気が対流する空間としての筒部が構成された状態で、前記支持部材に支持されており、
前記光源は、前記台座部に支持されて前記筒部内に配置されていることを特徴とする車両用灯具。
In a vehicular lamp including at least one optical module including a light source including a semiconductor light emitting element, an optical member, and a support member that supports the light source and the optical member,
The support member includes a base portion;
The front surface of the base portion includes a pedestal portion protruding forward from the front surface, and a first region and a second region disposed on both sides of the pedestal portion,
The rear surface of the optical member includes a groove portion extending in a vertical direction including a light incident surface formed at a position where the pedestal portion faces, and a first rear surface and a second rear surface disposed on both sides of the groove portion. And
The front surface of the optical member includes a first front surface disposed in front of the first rear surface, and a second front surface disposed in front of the second rear surface,
The optical member reflects light from the light source incident from the light incident surface at at least a part of the first front surface and the second front surface, and further, at least one of the first rear surface and the second rear surface. After being reflected by the part, it is configured to be emitted from at least a part of the first front surface and the second front surface and irradiated forward.
The optical member is supported by the support member in a state where a cylindrical portion as a space in which air convects is configured between the groove portion and the pedestal portion,
The vehicular lamp, wherein the light source is supported by the pedestal portion and disposed in the cylindrical portion.
前記光学部材の第1後面及び第2後面と前記ベース部の前面の第1領域及び第2領域との間には、空気が対流する空間が構成されていることを特徴とする請求項に記載の車両用灯具。 Between the first region and the second region of the front surface of the first back side and a second rear surface of the optical member and the base part, in claim 5, wherein a space where air convection is configured The vehicle lamp as described. 前記溝部は、V溝であることを特徴とする請求項又はに記載の車両用灯具。 The vehicular lamp according to claim 5 or 6 , wherein the groove portion is a V-groove.
JP2013053590A 2013-03-15 2013-03-15 Vehicle lighting Active JP6150106B2 (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
JP2013053590A JP6150106B2 (en) 2013-03-15 2013-03-15 Vehicle lighting

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
JP2013053590A JP6150106B2 (en) 2013-03-15 2013-03-15 Vehicle lighting

Publications (2)

Publication Number Publication Date
JP2014179282A JP2014179282A (en) 2014-09-25
JP6150106B2 true JP6150106B2 (en) 2017-06-21

Family

ID=51699019

Family Applications (1)

Application Number Title Priority Date Filing Date
JP2013053590A Active JP6150106B2 (en) 2013-03-15 2013-03-15 Vehicle lighting

Country Status (1)

Country Link
JP (1) JP6150106B2 (en)

Families Citing this family (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP6476663B2 (en) * 2014-08-29 2019-03-06 市光工業株式会社 Vehicle lighting
FR3056699B1 (en) * 2016-09-26 2019-06-28 Valeo Vision LUMINOUS MODULE AND LUMINOUS DEVICE FOR SELF-MOVING VEHICLE COMPRISING SUCH A LIGHT MODULE
DE202018101190U1 (en) * 2017-03-03 2018-03-12 Liquidbeam Gmbh Ceiling or wall luminaire with integrated electrical heating, ventilation and control

Family Cites Families (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP1664851B1 (en) * 2003-07-28 2014-11-12 Light Prescriptions Innovators, LLC. Three-dimensional simultaneous multiple-surface method and free-form illumination-optics designed therefrom
JP5627863B2 (en) * 2009-09-03 2014-11-19 スタンレー電気株式会社 Vehicle headlamp
JP5497408B2 (en) * 2009-11-09 2014-05-21 株式会社小糸製作所 Vehicle headlamp
JP5538307B2 (en) * 2011-06-21 2014-07-02 本田技研工業株式会社 Lamp body and vehicle lamp unit

Also Published As

Publication number Publication date
JP2014179282A (en) 2014-09-25

Similar Documents

Publication Publication Date Title
JP6164464B2 (en) Vehicle lighting
JP6864633B2 (en) Vehicle lighting fixtures and boards
JP4047266B2 (en) Lamp
KR101099877B1 (en) Light emitting element modularizing member and lamp unit
JP5666977B2 (en) Vehicle lighting
JP5659835B2 (en) Vehicle lighting
US9347636B2 (en) Vehicle lighting unit
JP6648430B2 (en) Vehicle lighting
JP2005166589A (en) Vehicular headlamp
JP2009230959A (en) Light source module, and vehicular lighting fixture
JP7180212B2 (en) vehicle lamp
JP5266034B2 (en) Vehicle lighting
CN109563975A (en) Lamps apparatus for vehicle
JP2014089868A (en) Lighting appliance
JP2013175391A (en) Vehicle headlight
JP6150106B2 (en) Vehicle lighting
JP2024524459A (en) Light emitting module and vehicle
JP7108359B2 (en) vehicle lamp
JP6226669B2 (en) Vehicle lighting
JP6780068B2 (en) Vehicle lighting
JP2016054093A (en) Vehicular lighting fixture
JP2016110818A (en) Vehicular lighting fixture
JP6801344B2 (en) Vehicle lighting
CN111692564B (en) Lamp unit and vehicle lamp
JP7218038B2 (en) vehicle lamp

Legal Events

Date Code Title Description
A621 Written request for application examination

Free format text: JAPANESE INTERMEDIATE CODE: A621

Effective date: 20160208

A977 Report on retrieval

Free format text: JAPANESE INTERMEDIATE CODE: A971007

Effective date: 20161118

A131 Notification of reasons for refusal

Free format text: JAPANESE INTERMEDIATE CODE: A131

Effective date: 20161129

A521 Request for written amendment filed

Free format text: JAPANESE INTERMEDIATE CODE: A523

Effective date: 20170126

TRDD Decision of grant or rejection written
A01 Written decision to grant a patent or to grant a registration (utility model)

Free format text: JAPANESE INTERMEDIATE CODE: A01

Effective date: 20170427

A61 First payment of annual fees (during grant procedure)

Free format text: JAPANESE INTERMEDIATE CODE: A61

Effective date: 20170510

R150 Certificate of patent or registration of utility model

Ref document number: 6150106

Country of ref document: JP

Free format text: JAPANESE INTERMEDIATE CODE: R150

R250 Receipt of annual fees

Free format text: JAPANESE INTERMEDIATE CODE: R250

R250 Receipt of annual fees

Free format text: JAPANESE INTERMEDIATE CODE: R250

R250 Receipt of annual fees

Free format text: JAPANESE INTERMEDIATE CODE: R250

R250 Receipt of annual fees

Free format text: JAPANESE INTERMEDIATE CODE: R250

R250 Receipt of annual fees

Free format text: JAPANESE INTERMEDIATE CODE: R250