JP6716259B2 - Vehicle lighting - Google Patents

Description

The present invention relates to a vehicular lamp, and more particularly to a vehicular lamp containing a lamp unit formed by combining a light source and a light guide.

Conventionally, as this type of vehicle lamp, for example, there is one disclosed in Patent Document 1 (name: vehicle lamp).

In the disclosed vehicular lamp, as shown in FIG. 16, end portions of two light guide rods 80 extending in the vertical direction along the periphery of the vehicular lamp are arranged to face each other in the vertical direction. A substrate 82 on which two LEDs 81 are mounted is erected on the rear side of the end portion.

Each of the light guide rods 80 has, at an end, an internal reflection surface 84 formed of a light incident surface 83 facing each of the LEDs 81, 81 and a total reflection surface located in front of the light incident surface 83. In FIG. 6, a surface 86 on the opposite side of the light emitting surface 85 is provided with an appropriate lens cut.

Then, the light emitted from each LED 81 enters the light guide rod 80 from the light incident surface 83 of each light guide rod 80, is guided inside the light guide rod 80, and extends in the direction of the extending portion at the internal reflection surface. The light that has been reflected by the lens and reaches the lens cut surface 86 while being guided through the extended portion is reflected by the lens cut surface 86 in the direction of the light emission surface 85 and emitted from the light emission surface 85 to the outside.

Japanese Patent Laid-Open No. 2012-169116

By the way, the vehicular lamp having the above-mentioned configuration is described as being similar to a conventionally known lens cut for the extending portion, but the conventionally known lens cut is such that continuous unevenness is formed in a predetermined direction. It has a configuration in which it is extended in parallel, and it is difficult to suppress the uneven brightness of the emitted light only with such a lens cut.

Further, regardless of the light guide rod, it is necessary to provide an extension for shielding an unnecessary portion and ensuring a good appearance, and the cost of the extension causes a cost increase in the manufacturing cost of the vehicle lamp.

Therefore, the present invention has been made in view of the above problems, and an object thereof is to realize a vehicular lamp that can reduce the manufacturing cost and obtain emitted light with suppressed uneven brightness. Especially.

In order to solve the above-mentioned problems, the invention as set forth in claim 1 of the present invention is characterized in that a lamp chamber formed by a housing having an opening on the front surface and an outer lens mounted so as to close the opening of the housing A vehicular lamp including a first lamp unit and a second lamp unit, wherein the second lamp unit is arranged between the outer lens and the first lamp unit, wherein the first lamp unit is a first lamp unit . One light source and a reflector that reflects the light emitted from the first light source toward the outer lens, and the second lamp unit includes an extension part and a second light source . , said annular light guiding portion becomes disposed along the inner surface ring of the outer lens with extending along the outer peripheral edge of the outer lens, provided in a part of the inside of the annular light guide window The hole portion and the shielding portion which is located between the first light source and the second light source and the outer lens and which is provided inside the annular light guide portion at a position other than the window hole portion are integrally formed. The annular light guide portion is formed, the flange portion extending outward in the radial direction, a tubular rearward extending tubular portion extending rearward from the flange portion, and extending forward from the flange portion. The rearwardly extending cylindrical portion has a light entrance portion including a light incident region for allowing light from the second light source to enter the annular light guide portion, and the rearward extension cylindrical portion is provided on an outer surface of the light entrance portion. An inclined surface is formed so as to be opposed to the emission surface of the second light source, and a second lens cut surface provided with a diffusion lens cut is formed on the front surface of the front extension portion. A metal reflective film is formed on the surfaces of the annular light guide portion and the shield portion, excluding the light incident region on the inner side surface of the grooved portion, and the light emitted from the first light source is reflected by the reflector, and The light is emitted from the vicinity of the central portion of the outer lens through the window portion, the light emitting surface of the second light source is arranged in a direction opposite to the light emitting surface of the first light source, and the light incident area is provided. some of the light from the second light source incident on said annular guide portion from being reflected by the metal reflective film is guided to cover the rear surface toward the rear surface of the rear extension tubular portion, the other Part of the light is guided toward the inclined surface and is reflected by the reflection film coated on the inclined surface, and the reflected light is guided inside the rearward extending cylindrical portion , and The light is emitted from the vicinity of the outer edge to the outside.

Further, the invention described in claim 2 of the present invention is, in claim 1, wherein the rear surface of the rearward extending cylindrical portion excluding the light incident portion has a triangular cross-section extending in a direction orthogonal to the annular direction of the rear surface. The first lens cut surface provided with the prism lens cut is formed .

Further, the invention described in claim 3 of the present invention, the inclination according to claim 2, wherein the rear extension tubular portion, toward the downwardly from said entrance section, at a predetermined angle in a direction approaching the flange portion It is characterized by doing.

Further, in the invention described in claim 4 of the present invention, in any one of claims 1 to 3, the second light source is composed of two light emitting elements, and light from each of the light emitting elements is the same as each other. It is characterized in that almost half of the area inside the annular light guide is guided.

According to the present invention, the second lamp unit constituting the vehicular lamp is provided with the second light source and the light guide body, and the light guide body among them is the annular light guide section located at the outer edge portion and the window located inside thereof. In addition to having the holes, the reflecting member is provided in the area on the back surface side other than the area that becomes the incident surface of the light emitted from the second light source in the annular light guide portion.

As a result, since the light guide body has the reflection member, the light guide body has the function of the extension, and the manufacturing cost for the extension is reduced, and the manufacturing cost of the vehicle lamp is reduced accordingly.

Further, the annular light guide portion is provided with a light emitting surface and a light reflecting surface for directing the light guided in the annular light guide portion toward the light emitting surface side, and the light reflecting surface is arranged in the annular direction of the light reflecting surface. The convex lens cut extending in the orthogonal direction is constituted by a convex knurled lens cut surface which is continuously extended in parallel in the annular direction, and the light emitting surface has an annular convex lens cut extending along the annular direction of the light emitting surface. The convex knurled lens cut surface is formed by continuously extending in parallel with the axial direction of.

As a result, the light diffused at a wide angle in the annular circumferential direction by the convex knurled lens cut surface of the light reflecting surface is diffused at a wide angle in the annular radial direction by the convex knurled lens cut surface of the light emitting surface, thereby Due to the complementary effect of the optical path control on the convex knurled lens cut surface, the occurrence of uneven brightness of the light emitted from the light emitting surface is suppressed.

It is a front view of the vehicular lamp of the embodiment. Similarly, it is a side view of the vehicle lamp of the embodiment. It is an AA sectional view of FIG. It is the perspective view which looked at the decoration lamp unit from the front diagonally upward. Similarly, it is the perspective view which looked at the decoration lamp unit from the back diagonally upward. FIG. 4 is a partially enlarged view of a light incident part and its vicinity. It is a side view of a decoration lamp unit. It is a front view of a decoration lamp unit. FIG. 9 is a sectional view taken along line BB of FIG. 8. Similarly, it is CC sectional drawing of FIG. It is an optical path explanatory view in the part shown in FIG. It is an optical-path explanatory drawing in the part shown in FIG. It is an optical path explanatory drawing by the side view of a decoration lamp unit. It is an optical path explanatory drawing by the front diagonally upper perspective view of a decoration lamp unit. It is an optical-path explanatory drawing of the vehicle lamp of embodiment. It is explanatory drawing of a prior art example.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to FIGS. 1 to 15 (the same portions are denoted by the same reference numerals). Since the embodiments described below are preferred specific examples of the present invention, various technically preferable limitations are attached, but the scope of the present invention particularly limits the present invention in the following description. The present invention is not limited to these embodiments, unless otherwise stated.

FIG. 1 is a front view of a vehicular lamp of the present embodiment, FIG. 2 is a side view, and FIG. 3 is a sectional view (longitudinal section) taken along the line AA of FIG.

The terms “front”, “rear”, “upper”, and “lower” used in the following description refer to the vehicle lamp according to the present invention attached to a vehicle, unless otherwise specified. In this case, the directions corresponding to “vehicle front direction”, “vehicle rear direction”, “vehicle upward direction”, and “vehicle downward direction” are shown.

A vehicle lamp (hereinafter abbreviated as “lamp”) 1 includes a housing 2 made of an opaque resin and having an opening at one end, and an outer lens 3 made of a transparent resin and attached to the housing 2 so as to close the opening. The lamp chamber 4 formed by means of and has a structure in which two types of lamp units having different lamp functions are accommodated.

In the present embodiment, the two types of lamp units are composed of the fog lamp unit 10 and the decorative lamp unit 30, and the fog lamp unit 10 has an optical system composed of the LED 11 and the reflector 12 of the light source. An optical system is configured by a pair of LEDs 31, 32 of a light source and a light guide 33 which also serves as an extension.

The fog lamp unit 10 includes a substrate holder 13 located at the center of the lamp chamber 4 in the vertical direction, and a reflector 12 located below the substrate holder 13.

An LED mounting substrate 15 on which the LED 11 is mounted is attached to the substrate holder 13 on the base portion 14 with the light emitting surface 11a of the LED 11 facing the lower reflector 12 side, and the reflector 12 is a front outer member. It has a curved shape that is formed by a free curved surface that is concave upward and extends obliquely downward toward the lens 3 side, and at least the concave inner surface has a metal reflection film made of a reflection metal such as aluminum or silver (hereinafter referred to as “reflection film”). 12a) is formed.

Then, the light emitted from the LED 11 toward the reflector 12 located below is reflected toward the front outer lens 3 by the reflection film 12a of the reflector 12, and the reflected light is a window hole of the light guide 33 described later. It reaches the outer lens 3 through the portion 36, passes through the outer lens 3, and is emitted forward.

On the other hand, the decorative lamp unit 30 is arranged in the lamp chamber 4 between the LED mounting substrate 15 and the reflector 12 mounted on the base portion 14 of the substrate holder 13 and the outer lens 3, and the light guide 33. An LED mounting board 34, on which a pair of LEDs 31 and 32 are mounted, is provided.

The light guide 33 is provided in a ring-shaped (annular) annular portion 35 extending along the outer peripheral edge of the outer lens 3 located in the front, and disposed inside the annular portion 35 and in front of the reflector 12. The window hole portion 36 and the curved portion 37 extending upward from the upper end portion of the window hole portion 36 and having a free curved surface convex in the front-rear direction.

Hereinafter, the decorative lamp unit 30 will be described in detail with reference to FIGS. 4 to 14.

FIG. 4 is a perspective view of the decorative lamp unit as seen obliquely from above and front, and FIG. 5 is a perspective view of the decorative lamp unit as seen from obliquely above rear.

The annular portion 35 of the decorative lamp unit 30 has a tubular light guide portion 38 extending in the front-rear direction and a flange portion 39 annularly extending outward from the light guide portion 38 in the radial direction. 38, a cylindrical rearward extending tubular portion 40 extending rearward from the position of the flange portion 39 and a tubular forward extending tubular portion 50 extending forward from the position of the flange portion 39 are positioned.

The rearward extending tubular portion 40 has a pair of inclined surfaces 42, 43 on the outer side surface 40b of the upper light incident portion 41, which are opened at a predetermined angle toward the opposite directions of the annular direction at predetermined intervals. ..

An LED mounting board 34, on which a pair of LEDs 31 and 32 are mounted, is arranged below the light incident portion 41 of the rearward extending tubular portion 40. The LEDs 31 and 32 are mounted directly on the inclined surfaces 42 and 43, respectively, and are mounted on the substrate with the light emitting surfaces 31a and 32a facing the upper inclined surfaces 42 and 43, respectively.

Each of the pair of inclined surfaces 42, 43 provided on the rearward extending tubular portion 40 has an angle of 45° with respect to the optical axis X ₁ , X _{2 of} each of the pair of LEDs 31, 32 positioned below ( θ) (see FIG. 6 (a partially enlarged view of the light incident portion and the vicinity thereof in FIGS. 4 and 5)).

Further, the rearward extending tubular portion 40 has a lens cut surface (first lens cut surface) 44 on the rear surface excluding the light incident portion 41, and the first lens cut surface 44 is orthogonal to the annular direction of the rear surface. The convex lens cut surface (specifically, for example, a prism lens cut having a triangular cross section) 45 extending in the direction of the arrow is formed by a convex knurled lens cut surface formed by continuously extending in parallel in the annular direction.

As shown in FIG. 7 (side view of the decorative lamp unit), the rearward extending cylindrical portion 40 having the first lens cut surface 44 formed on the rear surface is shortened in length from the upper light incident portion 41 toward the lower portion. Has become. In other words, the first lens cut surface 44 is inclined from the upper light incident portion 41 toward the lower portion toward the flange portion 39. The inclination angle (α) of the first lens cut surface 44 with respect to the flange portion 39 is preferably 4°.

On the other hand, the frontward extending cylindrical portion 50 has a lens cut surface (second lens cut surface) 51 on the front surface, and the second lens cut surface 51 has a convex lens cut (concretely) extending annularly along the front surface. Has a convex knurled lens cut surface formed by, for example, a cylindrical lens cut having an arcuate cross section) extending continuously in parallel in the axial direction of the ring (see FIG. 8 (front view of the decorative lamp unit)). ).

As shown in FIG. 9 (cross-sectional view taken along the line BB of FIG. 8) and FIG. 10 (cross-sectional view taken along the line C-C of FIG. 8) from the flange portion 39 of the light guide 33, as shown in FIG. The inner surface 40a of the elongated tubular portion 40 is made of aluminum, silver, or the like over the entire surface including the annular portion 35 and the curved portion 37, except for the light incident region 46 of the light emitted from the LEDs 31, 32 in the light incident portion 41 portion. A metal reflection film (hereinafter abbreviated as “reflection film”) 47 made of a reflection metal is formed.

A part of the light incident part 41 on the inner side surface 40a of the rearward extending tubular part 40 is provided with a parting step 48 at the time of vapor deposition of aluminum, silver or the like at the boundary part between the light incident area 46 and the other area. On the rear surface of the light incident portion 41 of the rearward extending tubular portion 40, it is possible to prevent the incident light from the light emitted from the LEDs 31, 32 from directly heading to the second lens cut surface 51 on the front surface of the frontward extending tubular portion 50. A textured surface 49 for light diffusion is formed.

Next, the optical paths of the light emitted from the LEDs 31 and 32 will be described with reference to FIGS. 11 to 14.

First, as shown in FIG. 11 (light path explanatory diagram in the portion shown in FIG. 10), the light emitted from the LED 31 is transmitted from the light incident area 46 of the light incident portion 41 of the rearward extending tubular portion 40 to the light incident portion 41. And a part of the incident light is guided inside the light incident portion 41 toward the rear surface and diffused and reflected by the reflection film 47 coated on the rear surface grain surface 49, whereby the second lens cut surface. The light directed to 51 is suppressed, and the light emission near the light source (LED 31) is suppressed.

On the other hand, most of the incident light from the light incident region 46 is guided in the light incident portion 41 toward the inclined surface 42 located above, as shown in FIG. 12 (a schematic view of the portion of FIG. 6). The reflection film 47 covered by the inclined surface 42 is reflected in the direction opposite to the inclined surface (the other inclined surface) 43, and the reflected light passes through the inside of the rear extended cylindrical portion 40. The light is guided toward the lower side while repeating reflection between the reflective film 47 coated on the inner side surface 40a and the reflective surface 47 coated on the outer side surface 40b.

Then, of the light being guided inside the rearward extending tubular portion 40 toward the lower side, the light that reaches the first lens cut surface 44 that is inclined toward the flange portion 39 side toward the lower side is the first lens. The reflection film 47 coated on the cut surface 44 is reflected in the direction of the second lens cut surface 51 on the front surface of the front extension cylindrical portion 50, and the reflected light is directed inside the light guide portion 38 toward the second lens cut surface 51. And is guided to the outside through the second lens cut surface 51 (see FIG. 13 (side view of the decorative lamp unit)).

Then, the light emitted from the second lens cut surface 51 passes through the outer lens 3 and is emitted forward.

Similarly, the light emitted from the LED 32 enters the light incident portion 41 from the light incident area 46 of the light incident portion 41 of the rearward extending tubular portion 40, and a part of the incident light is incident on the rear surface inside the light incident portion 41. Is reflected toward the second lens cut surface 51 by the reflection film 47 that covers the rear surface of the embossed surface 49, and the light directed toward the second lens cut surface 51 is suppressed, and the light spot near the light source (LED 32) is suppressed. (See FIG. 11).

On the other hand, most of the incident light from the light incident region 46 is guided to the inclined surface 43 located above in the light incident portion 41 and is reflected by the reflection film 47 covered by the inclined surface 43 (the other surface). (Inclined surface 42) of the rearward extending cylindrical portion 40, and the reflected light is reflected by the inner surface 40a of the rearward extending cylindrical portion 40 and the outer surface 40b. The light is guided toward the lower side while repeating reflection with the reflecting surface 47 (see FIG. 12).

Then, of the light being guided inside the rearward extending tubular portion 40 toward the lower side, the light that reaches the first lens cut surface 44 that is inclined toward the flange portion 39 side toward the lower side is the first lens. The reflection film 47 coated on the cut surface 44 is reflected in the direction of the second lens cut surface 51 on the front surface of the front extension cylindrical portion 50, and the reflected light is directed inside the light guide portion 38 toward the second lens cut surface 51. And is guided to the outside through the second lens cut surface 51 (see FIG. 13).

By the way, as described above, the first lens cut surface 44 is a convex lens cut extending in a direction orthogonal to the annular direction (circumferential direction) of the rear surface of the rearward extending tubular portion 40 (specifically, for example, a prism lens having a triangular cross section). (Cut) 45 is formed by a convex knurled lens cut surface formed by continuously extending in parallel in the annular direction. Therefore, the light reflected by the first lens cut surface 51 is cut by the first lens cut surface 51 in a direction orthogonal to the extending direction of the convex lens cut (prism lens cut) 45 (circumferential direction of the annular rear surface). The 45 lens effect radially spreads (spreads) at a wide angle.

Further, as described above, in the second lens cut surface 51, the convex lens cut (specifically, for example, a cylindrical lens cut having an arc-shaped cross section) 52 extending annularly along the front surface of the front extending tubular portion 50 has an annular axial direction. Is formed by a convex knurled lens cut surface that is continuously extended in parallel. Therefore, the light emitted from the second lens cut surface 51 is the convex lens in the second lens cut surface 51 in the direction orthogonal to the extending direction of the convex lens cut (cylindrical lens cut) 52 (radial direction of the annular front surface). It is radially widened (diffused) by the lens effect of the cut 52 (see FIG. 14 (a perspective view of the decorative lamp unit viewed from diagonally above and front)).

Therefore, from the front surface (the second lens cut surface 51) of the front extending tubular portion 50 which is the light emitting surface of the decorative lamp unit 30 to the outside, it is substantially in both the annular circumferential direction and the radial direction. Emitted light having an even luminance distribution is obtained.

Then, the light emitted from the decorative lamp unit 30 passes through the outer lens 3 as it is and is emitted forward as the light emitted from the lamp 1.

Therefore, in the lamp 1 in which the fog lamp unit 10 and the decorative lamp unit 30 are housed, as shown in FIG. 15 (a longitudinal sectional view of the lamp), the fog lamp unit 10 emits from the LED 11 and is reflected by the reflector 12. The light passes through the window hole portion 36 of the light guide 33 forming the decorative lamp unit 30 and passes through the outer lens 3 located further forward and is emitted toward the front side. The light emitted from 32 and guided in the light guide 33 is emitted from the second lens cut surface 51 on the front surface, passes through the outer lens 3 located in the front, and is emitted forward.

When this lamp 1 is viewed from the front, when both the fog lamp unit 10 and the decoration lamp unit 30 are not lit (in the daytime), the fog lamps are covered with the reflection film 47 over almost the entire surface through the outer lens 3. The extension by the reflector 12 of the unit 10 and the light guide 33 of the decorative lamp unit 30 is viewed.

This extension enhances the appearance by enhancing the appearance of the lamp when it is not lit in the daytime by the metallic bright reflection light and enhances the product appeal, and at the same time, the housing 2, the LED mounting board 15 and the LED mounting located at the rear side. The internal appearance such as the substrate holder 13 to which the substrate 15 is attached is shielded so as not to be seen to improve the appearance.

Further, when the fog lamp unit 10 is turned on, the reflected light emitted from the LED 11 and reflected by the reflector 12 located below passes through the central portion side region of the outer lens 3 and is emitted to the outside, and the emitted light is emitted from the fog lamp. Form a light distribution pattern.

Further, when the decoration lamp unit 30 is turned on, the light emitted from the LED 31 and guided in the light guide portion 38 of the light guide 33 is transmitted through the semi-annular outer edge side region of the outer lens 3 on the side where the LED 31 is located. Then, the emitted light forms a semi-circular (half-circumferential) decoration light. At the same time, the light emitted from the LED 32 and guided in the light guide portion 38 of the light guide 33 passes through the semi-annular outer edge side region of the outer lens on the side where the LED 32 is located and is emitted to the outside. The emitted light forms a semi-circular (half circle) decorative light.

Therefore, from the front of the lamp 1, an annular shape (entire circumference) obtained by light emitted from each of the LED 31 and the LED 32, guided inside the light guide portion 38 of the light guide 33, and transmitted through the outer lens 3. Decorative light is seen.

When the fog lamp unit 10 is turned on during the daytime, the portion other than the reflector 12 that reflects the emitted light from the LED 11 is viewed as an extension, and when the decorative lamp unit 30 is turned on, it is emitted from each of the LED 31 and the LED 32. Then, a portion other than the second lens cut surface 51 from which the light guided in the light guide portion 38 of the light guide 33 is emitted is viewed as an extension.

When the fog lamp unit 10 and the decorative lamp unit 30 are turned on at the same time during the daytime, the portions other than the reflector 12 and the second lens cut surface 51 are viewed as extensions.

By the way, the above-described lamp 1 is particularly used in the decorative lamp unit 30, and in particular, the first lens cut surface 44, the inner side surface 40a, the outer side surface 40b, and the front extended cylindrical shape of the rear surface of the rear extended cylindrical portion 40 of the light guide 33. The reflection film 47 was formed on the inner surface of the portion 50. Thereby, the utilization efficiency of the light emitted from the LEDs 31 and 32 is improved, and the brightness of the light emitted from the second lens cut surface 51 on the front surface of the front extending tubular portion 50 is guided by being guided in the light guide portion 38. The occurrence is suppressed.

Further, the light diffused at the first lens cut surface 44 of the rearward extending tubular portion 40 in a wide angle in the annular circumferential direction is made wide in the annular radial direction at the second lens cutting surface 51 of the frontward extending tubular portion 50. By diffusing, the unevenness of the brightness of the light emitted from the second lens cut surface 51 is also suppressed by the complementary effect of the optical path control of the first lens cut surface 44 and the second lens cut surface 51.

The LED 11 serving as the light source of the fog lamp unit 10 is located below the LEDs 31 and 32 serving as the light source of the decorative lamp unit 30 and is arranged with the light emitting surface 11a facing downward, and the LED 31 serving as the light source of the decorative lamp unit 30. , 32 are located above the LED 11 serving as the light source of the fog lamp unit 10, and are arranged with their respective light emitting surfaces 31a, 32a facing upward. Therefore, the emitted lights from the respective light sources do not interfere with each other, and the emitted lights from the fog lamp unit 10 and the decorative lamp unit 30 do not affect each other.

By the way, in terms of manufacturing cost of the lamp 1, the light guide 33 forming the decorative lamp unit 30 also has an extension function, so that the manufacturing cost of the decorative lamp unit 30 is reduced, and accordingly, the lamp. The manufacturing cost of No. 1 is also reduced.

1...Vehicle lamp 2...Housing 3...Outer lens 4...Light room 10...Fog lamp unit 11...LED
11a... Light emitting surface 12... Reflector 12a... Reflective film 13... Substrate holder 14... Base part 15... LED mounting substrate 30... Decorative lamp unit 31... LED
31a... Light emitting surface 32... LED
32a... Light emitting surface 33... Light guide 34... LED mounting substrate 35... Annular part 36... Window part 37... Curved part 38... Light guide part 39... Flange part 40... Rear extension cylindrical part 40a... Inner side surface 40b... Outer side surface 41... Light incident portion 42... Inclined surface 43... Inclined surface 44... First lens cut surface 45... Convex lens cut 46... Light incident area 47... Reflective film 48... Parting step 49... Wrinkled surface 50... Front extension cylindrical portion 51... Second lens cut surface 52... Convex lens cut

Claims (4)

A first lamp unit and a second lamp unit are provided in a lamp chamber formed by a housing having an opening on the front surface and an outer lens mounted so as to close the opening of the housing, and the outer lens and the first lamp unit are provided. A vehicle lamp in which the second lamp unit is arranged between
The first lamp unit includes a first light source and a reflector that reflects light emitted from the first light source toward the outer lens ,
The second lamp unit includes an extension part and a second light source,
In the extension portion, and the annular light guide portion becomes disposed along the inner surface ring of the outer lens with extending along the outer peripheral edge of the outer lens, a part of the inside of the annular light guide portion A window portion provided, and a shielding portion that is located between the first light source, the second light source, and the outer lens and that is provided inside the annular light guide portion at a position other than the window portion. , Are formed integrally ,
The annular light guide portion has a flange portion that extends outward in the radial direction, a cylindrical rearward extension tubular portion that extends rearward from the flange portion, and a front extension portion that extends forward from the flange portion. Then
The rearward extending tubular portion includes a light incident portion including a light incident region that allows light from the second light source to enter the annular light guide portion,
An inclined surface is formed on the outer surface of the light entrance portion so as to face the exit surface of the second light source,
A second lens cut surface provided with a diffusion lens cut is formed on the front surface of the front extension portion,
A metal reflective film is formed on the surfaces of the annular light guide portion and the shield portion, excluding the light incident region on the inner side surface of the rearward extending tubular portion ,
The light emitted from the first light source is reflected by the reflector and is emitted to the outside from the vicinity of the central portion of the outer lens through the window portion.
The light emitting surface of the second light source is arranged in a direction opposite to the light emitting surface of the first light source,
Part of the light from the second light source that has entered the annular light guide portion from the light incident region is guided toward the rear surface of the rearward extending tubular portion and is covered by the metal reflection film. The other part of the reflected light is guided toward the inclined surface and reflected by the reflection film coated on the inclined surface, and the reflected light is guided inside the rearward extending cylindrical portion, A vehicular lamp which is emitted from the vicinity of the outer edge of the outer lens to the outside. A first lens cut surface provided with a prism lens cut having a triangular cross-section that extends in a direction orthogonal to the annular direction of the rear surface is formed on the rear surface of the rearward extending cylindrical portion excluding the light incident portion. The vehicle lamp according to claim 1. Extending tubular portion after the can as it goes downward from the entrance section, the vehicular lamp according to claim 2, characterized in that it is inclined at a predetermined angle in a direction approaching to the flange portion. The said 2nd light source is comprised by two light emitting elements, and the light from each light emitting element mutually guides the substantially half area|region in the said annular light guide part, The claim 1 characterized by the above-mentioned. The vehicle lamp according to any one of the above.