JP6986341B2 - Vehicle headlights - Google Patents

Description

The present invention relates to a vehicle headlight.

In recent years, as shown in Patent Document 1, many vehicle headlights are equipped with a lamp unit that illuminates the front and a marker lamp such as a daytime running lamp (DRL) or a clearance lamp that lights in the daytime. It is becoming. According to this, the existence of the own vehicle can be clearly recognized by a pedestrian or the like.

By the way, in recent years, the design of headlights for vehicles has been diversifying. As one of them, there is an increasing demand to make a sign lamp such as a daytime running light (DRL) stand out while making a lamp unit that illuminates the front of the vehicle inconspicuous.

Japanese Unexamined Patent Publication No. 2015-196479

However, in headlights, not only is the lamp unit playing a central role in illuminating the front, but the light distribution based on the lamp unit is severely restricted by the light distribution regulations, and the lamp unit is a vehicle. In order to illuminate the front accurately, it is necessary to arrange it so that it appears in front of the headlight. For this reason, in the headlight, the presence of the lamp unit is not a little conspicuous from the outside, and the above-mentioned design request cannot be fully satisfied.

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a vehicle headlight that can make the lighting unit inconspicuous from the outside while ensuring the basic function of accurately illuminating the front of the vehicle. To provide.

In order to achieve the above object, the present invention has the following configurations (1) to (6).
(1) In a vehicle headlight equipped with a sign lamp unit together with a lamp unit that illuminates the front of the vehicle.
An inner lens is arranged in front of the lamp unit so as to cover the lamp unit.
The inner lens is configured to reflect a part of external light from the outside to the inside.
According to this configuration, based on the nature of the inner lens, it is possible to prevent the emission light of the lamp unit from the inside to the outside from being restricted, while the external light from the outside to the inside is not restricted. A part of it can be reflected to obscure the lamp unit.

(2) Under the configuration of (1) above,
The inner lens is configured to be tilted forward so as to go from the lower side to the upper side.
According to this configuration, when the lamp unit is lit, the emitted light of the lamp unit can be emitted from the inside of the inner lens to the outside without any problem, while when the lamp unit is turned off, it is incident on the inner lens from the viewpoint side of a human outside the vehicle. It is possible to enhance the reflection of the external light on the surface of the inner lens, suppress the external light from entering the inside of the inner lens, and make the lamp unit concretely difficult to see.

(3) Under the configuration of (1) above,
At least one of the surface and the inner surface of the inner lens is formed as a reflecting surface that reflects a part of incident light from the outside to the inside.
According to this configuration, when the lighting equipment unit is lit, the emitted light of the lighting equipment unit can be passed from the inside to the outside of the inner lens as usual based on the transparency of the reflective surface of the inner lens, while the lighting equipment unit. When the light is off, even if you look at the reflective surface of the inner lens from the bright outside, the bright external reflected light reaches your eyes because it overlaps with the weak light transmitted from the inside of the inner lens on the dark side, so it is from the inside of the inner lens. The transmitted light of the lens is made inconspicuous, and the lighting unit can be made difficult to see concretely.

(4) Under the configuration of (1) above,
The front surface of the sign lamp unit is arranged in front of the front surface of the lamp unit.
According to this, by lighting the indicator lamp, the existing area of the lamp unit located behind the indicator lamp can be relatively darkened, and the lamp unit can be obscured.

(5) Under the configuration of (2) above,
At least one of the surface and the inner surface of the inner lens is formed as a reflective surface that reflects a part of external light from the outside to the inside.
According to this configuration, the action / effect based on the above-mentioned configuration (2) and the action / effect based on the configuration (3) can be obtained at the same time.

(6) Under the configuration of (5) above,
The front surface of the sign lamp unit is arranged in front of the front surface of the lamp unit.
According to this configuration, the action / effect based on the above-mentioned configuration (5) and the action / effect based on the configuration (4) can be obtained at the same time.

According to the present invention, it is possible to provide a vehicle headlight that can make the lighting unit inconspicuous from the outside while ensuring the basic function of accurately illuminating the front of the vehicle.

The front view which shows the headlight which concerns on 1st Embodiment. FIG. 1 is a cross-sectional view taken along the line X2-X2 of FIG. The front view which shows the light emitting element used in the sign lamp unit which concerns on 1st Embodiment. The explanatory view explaining the function based on the inclination of the front surface part of the inner lens which concerns on 1st Embodiment. The explanatory view explaining the function based on the reflective film coated on the front surface of the inner lens which concerns on 1st Embodiment. The front view which shows the headlight which concerns on 2nd Embodiment. FIG. 6 is a cross-sectional view taken along the line X7-X7 of FIG.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
In FIG. 1, reference numeral 1 indicates a right headlight (hereinafter referred to as a headlight) as a vehicle lighting tool according to the first embodiment. This headlight 1 is attached to the front part of the vehicle together with other headlights (left headlight) and illuminates the front of the vehicle.

As shown in FIGS. 1 and 2, the headlight 1 includes a lamp body 2 having a front opening and a translucent cover 3 covering the opening of the lamp body 2.

As shown in FIGS. 1 and 2, the lamp body 2 has a back wall portion 2a that stands up in the vertical direction and a peripheral wall portion that projects forward (to the left in FIG. 1) from the peripheral portion of the back wall portion 2a. It is composed of 2b and. The back wall portion 2a extends in the lateral direction (in FIG. 2, in the direction orthogonal to the paper surface) while maintaining a constant height, and the peripheral wall portion 2b cooperates with the back wall portion 2a to partition the storage space 4. The tip of the peripheral wall portion 2b forms a horizontally long opening 5 in the storage space 4.

As shown in FIG. 2, the translucent cover 3 is detachably attached to the tip end portion of the peripheral wall portion 2b of the lamp body 2. As a result, the translucent cover 3 and the lamp body 2 form a lamp housing and a sealed lamp chamber 6 inside the housing. The translucent cover 3 has translucency, and the light emitted in the lamp chamber 6 is irradiated to the outside through the translucent cover 3. In the present embodiment, a resin lens is used as the translucent cover 3, and the front surface portion of the translucent cover 3 is inclined so as to be directed backward as it is directed upward.

As shown in FIG. 2, a plate-shaped metal support member (for example, an aluminum die-cast product) 8 is arranged in the light chamber 6. The support member 8 is formed in a shape that extends while maintaining a constant width, and the support member 8 is attached to the back wall portion 2a of the lamp body 2 via an aiming screw 11a or the like, whereby the support member 7 is formed. The plate surface (front-rear surface) is oriented in the front-rear direction, and is extended in the lateral direction (left-right direction in FIG. 1) under a state of being separated from the back wall portion 2a to the front side.

As shown in FIG. 2, the support member 8 has a rear surface 8a formed on a flat surface, while the front surface 8b thereof has a sign lamp unit arrangement area 9, a low beam unit arrangement area 12, and a high beam unit arrangement. Each setting area 13 is set.
The indicator lamp unit arrangement area 9 is set in each of the upper, outer side (left side in FIG. 1, left side) and lower areas 9a, 9b, 9c of the support member front surface 8b, and the indicator lamp unit arrangement thereof. The setting region 9 occupies the outer peripheral portion of the support member front surface 8b in a continuous manner except for the inner side portion of the support member front surface 8b (see the shape of the light guide lens 16a described later in FIG. 1). In the upper region 9a of the indicator lamp unit arrangement region 9, the support member front surface 8b is slightly larger than the outer peripheral edge portion of the support member front surface 8b (for example, the outer peripheral edge portion attached by the aiming screw 11a or the like). It has a protruding portion 41, and the protruding portion 41 is extended in the lateral direction while making the tip surface 41a a flat surface having a constant width in the vertical direction. In the outer side region 9b, the thickness of the front surface 8b of the support member at the upper portion is to increase stepwise toward the lower side. In the lower region 9c, the front surface 8b of the support member has a protrusion 42 that protrudes more than the upper region 9a, and the protrusion 42 has a flat tip surface 42a and a flat upper surface 42b. It is formed (see FIG. 2). The vertical range of the upper region 9a and the lower region 9c in the indicator lamp unit arrangement region 9 is the range indicated by the arrow in FIG.

The low beam unit arrangement area 12 and the high beam unit arrangement area 13 are set in a state of being arranged side by side in the lateral direction between the upper area 9a and the lower area 9c in the indicator lamp unit arrangement area 9. In the present embodiment, the low beam unit arrangement area 12 is arranged on the outer side (outer side in the vehicle width direction) of the high beam unit arrangement area 13, and in both areas 12 and 13, the front surface of the support member is provided. The 8b is formed as a flat surface under the basic wall thickness of the support member 8 (for example, the wall thickness of the outer peripheral edge portion attached by the aiming screw 11a or the like). The horizontal range of the low beam unit arrangement area 12 and the high beam unit arrangement area 13 is the range indicated by the arrow in FIG. 1, and the vertical range thereof is the range indicated by the arrow in FIG. It has become. Regarding the vertical range of the low beam unit arrangement region 12 and the high beam unit arrangement area 13, in the present embodiment, the lower portion thereof is the upper portion of the lower region 9c in the indicator lamp unit arrangement region 9. Partially overlaps with (see Fig. 2).

As shown in FIGS. 1 and 2, a sign lamp unit 16 is attached to the front surface 8b of the support member in the sign lamp unit arrangement region 9.
The indicator lamp unit 16 is provided with a light guide lens 16a and a plurality of light emitting elements (for example, LEDs (Light Emitting Diodes) 16b) as a light source.
As the light guide lens 16a, a lens having a shape corresponding to the shape of the indicator lamp unit arrangement region 9 is used. Specifically, the light guide lens 16a integrally includes an upper lens portion 16aa, a side lens portion 16ab, and a lower lens portion 16ac, and the light guide lens 16a is attached to the support member 8. As a result, in front of the support member front surface 8b, the upper lens portion 16aa covers the upper region 9a of the support member front surface 8b, the side lens portion 16ab covers the outer side region 9b of the support member front surface 8b, and the lower lens portion. 16ac covers the lower region 9c of the front surface 8b of the support member. The front surface 16af of the light guide lens 16a is tilted so as to be rearward as it goes upward as the front surface of the translucent cover 3 is tilted, and the rear end of the upper lens portion 16aa of the light guide lens 16a is formed. It is retracted rearward from the rear end of the lower lens portion 16ac.
The plurality of light emitting elements 16b are attached to the front surface 8b of the support member in the sign lamp unit arrangement region 9, and the plurality of light emitting elements 16b are arranged at regular intervals in the extension direction of the sign lamp unit arrangement region 9. Has been done.

Specifically, the indicator lamp unit 16 can function as a daytime running lamp and a clearance lamp, and a vehicle equipped with an automatic driving mode is a situation of its own vehicle with respect to pedestrians and other vehicles. It can also function as a lamp (communication lamp) that displays the intention of behavior. For example, display that automatic driving is in progress, display the level of automatic driving, display the presence or absence of a driver / occupant, display a stop notice, display the direction of travel, display detection of pedestrians, etc. as communication lamps. You may do it. In such a case, the light emitting element 16b may emit a color other than white light, may emit not only white light but also other colors, and may emit a plurality of colors to change color. It is preferable to use. For example, as shown in FIG. 3, on the substrate 43, a red LED chip R that emits red light, a green LED chip G that emits green light, a blue LED chip B that emits blue light, and a white LED chip W that emits white light. A light emitting element 16b can be used.
In FIG. 1, reference numeral 18 indicates an extension reflector that covers the periphery of the light guide lens 16a.

As shown in FIG. 1, a low beam unit LU is attached to the front surface 8b of the support member in the low beam unit arrangement region 12.
The low beam unit LU is set to perform low beam irradiation and form a low beam light distribution pattern in front (for example, on a virtual vertical screen arranged 25 m in front) based on the low beam irradiation, and as such a low beam unit LU, for example. A low beam unit such as a projector type is used. Therefore, as shown in FIG. 1, the low beam unit LU includes components (not shown) such as a light source, a reflector, and a light-shielding shade, including a projection lens 19 arranged on an optical axis extending in the front-rear direction of the vehicle. It is prepared.

As shown in FIGS. 1 and 2, a high beam unit HU is attached to the front surface 8b of the support member in the high beam unit arrangement region 13.
In the present embodiment, the high beam unit HU is a projection lens 25 arranged on an optical axis extending in the front-rear direction of the vehicle, and a laser light source as a light source unit arranged behind the projection lens 25 to generate white laser light. It includes a unit 26 and an emission direction adjusting mechanism 27 that reflects white laser light emitted from the laser light source unit 26 toward the projection lens 25 as a high beam.

The projection lens 25 is arranged between the upper lens portion 16aa and the lower lens portion 16ac of the light guide lens 16a near the rear portion of the lower lens portion 16ac, and the projection lens 25 is a light guide lens. It is arranged sufficiently behind the front surface 16af of 16a. The projection lens 25 is attached to a lens holder (not shown) attached to the front surface 8b of the support member.
The laser light source unit 26 is a housing 44 arranged on the upper surface 42b of the protrusion, a laser diode (for example, a blue laser diode) 45 provided in the housing 44, and a region where laser light is emitted from the laser diode 45. A phosphor (for example, a yellow phosphor) 46, which is held in a through hole in the upper part of a housing 44 and converts a laser beam into a white laser beam, is provided, and the laser light source unit 26 converts the white laser beam into a phosphor. 46 It emits upward. Of course, in this laser beam unit 26, an optical system (for example, a condenser lens) may be provided in the housing 44, if necessary.
In the present embodiment, the MEMS mirror 27A is used as the emission direction adjusting mechanism 27. The MEMS mirror 27A is attached to the front surface 8b of the support member in the rear region (high beam arrangement region 13) of the projection lens 25, and the MEMS mirror 27A is oriented in the vertical and horizontal directions by an actuator (not shown). It is provided with a reflective part (not shown) that can be changed. The reflecting portion of the MEMS mirror 27A receives the white laser light from the laser light source unit 26 and reflects the white laser light toward the projection lens. At this time, the reflecting portion of the MEMS mirror 27A causes the white laser beam to be appropriately scanned toward the front.
As a result, the high beam unit HU performs high beam irradiation and forms a high beam light distribution pattern forward based on the high beam irradiation. Of course, in this case, by using the laser light source unit 26 and the MEMS mirror 27A, the high beam unit HU can be made compact and the light distribution pattern can be changed as appropriate.

As shown in FIGS. 1 and 2, an inner lens 47 is arranged in front of the high beam unit HU and the low beam unit LU in order to define their light distribution pattern shapes.
The inner lens 47 integrally has a front surface portion 47a and a peripheral wall portion 47b extending rearward from the peripheral edge portion of the front surface portion 47a.
The front surface portion 47a is formed in a strip shape extending under a certain width, and the front surface portion 47a straddles between the upper lens portion 16aa and the lower lens portion 16ac in the light guide lens 16a. , Extends in the lateral direction (left and right in FIG. 1). Therefore, the entire opening between the upper lens portion 16aa and the lower lens portion 16ac is covered by the front surface portion 47a.
As shown in FIG. 2, the front surface portion 47a is inclined so as to face forward from the lower side toward the upper side. As a result, as shown in FIG. 4, when the high beam unit HU and the low beam unit LU are turned off, when the external light 48 is incident on the inner lens front portion 47a from the viewpoint side of a human outside the vehicle, the inner lens front portion 47a is exposed. Compared to the case of standing up (in FIG. 4, the inner lens front surface 47a and the external light 48 are shown by virtual lines), the reflection of the external light 48 on the inner lens front surface 47aa (front surface) is enhanced. Therefore, the external light 48 is suppressed from entering the inside of the inner lens 47 (in FIG. 4, the inner lens front surface portion 47a and the external light 48 are shown by solid lines). Therefore, the transmitted light from the inside to the outside of the inner lens 47 (based on the reflection inside) is suppressed, and the high beam unit HU and the low beam unit LU are difficult to see from the outside. The inclination angle of the inner lens front surface portion 47a is preferably in the range of 20 ° to 45 ° with respect to the vertical direction.
Of course, in this case, even if the inner lens front surface portion 47a is tilted, when the high beam unit HU or the low beam unit LU is lit, the emitted light of the high beam unit HU or the low beam unit LU is the inner lens 47 based on the properties of the inner lens 47. It will be emitted from the inside of the lens to the outside without any problem.

The peripheral wall portion 47b of the inner lens 47 is arranged between the upper lens portion 16aa and the lower lens portion 16ac so as to be aligned with the light guide lens 16a in the front-rear direction. The peripheral wall portion 47b cooperates with the front surface portion 47a to partition a horizontally long space 49 that opens at the rear, and the projection lens 25 of the high beam unit HU and the projection of the low beam unit LU are projected in the space 49. The lens 19 is housed, and the front surface (projection lenses 25, 19) of both the high beam unit HU and the low beam unit LU is located behind the front surface (projection lens 16a) of the indicator lamp unit 16. Therefore, the indicator lamp unit 16 is lit in a state of being arranged in front of the high beam unit HU and the low beam unit LU, and from this point as well, the high beam unit HU and the low beam unit LU are difficult to see.
In FIG. 1, an inner lens 47 exists in front of the low beam unit LU and the high beam unit HU, and a translucent cover 3 exists in front of the inner lens 47. However, for convenience of viewing, the low beam unit LU, The high beam unit HU, the inner lens 47, etc. are drawn with solid lines.

As shown in FIGS. 2 and 5, a reflective film 50 is coated on the front surface 47aa (surface) of the front surface portion 47a of the inner lens 47 so as to form a reflective surface. The reflective film 50 is called a half mirror coating film or a magic mirror coating film, and as is known, the reflective film 50 has a property of partially reflecting and transmitting a part of incident light. There is. Therefore, when the reflective film 50 is viewed from the bright outside when the high beam unit HU and the low beam unit LU are turned off, as shown in FIG. 5, weak transmitted light transmitted from the inside of the inner lens 47 on the dark side is transmitted. The reflected light of the bright external light 48 that overlaps with 62 (indicated by a one-point chain line in FIG. 5) reaches the eyes, the transmitted light 62 from the inner side of the inner lens 47 is made inconspicuous, and the high beam unit HU and the low beam are made inconspicuous. The unit LU becomes difficult to see. In order to explain the function of the reflective film 50, in FIG. 5, the front surface portion 47a of the inner lens 47 is not tilted, but this is to explain only the function of the reflective film 50 itself. be.
When such a reflective film 50 is formed on the front surface 47aa of the front surface of the inner lens 47, tin, silver, aluminum, etc. are plated or vapor-deposited, and the ratio of the reflected light to the transmitted light is the thickness of the reflective film 50. Is adjusted by.
Of course, in this case, when the high beam unit HU or the low beam unit LU is turned on, the high beam or the low beam passes through the inner lens 47 and the reflective film 50 and illuminates the front based on the transparency of the reflective film 50.
In the present embodiment, as shown in FIG. 2, an overhanging portion 47d is provided so as to project forward from the lower part of the inner lens 47, and this overhanging portion when the reflective film 50 is viewed from the front side. 47d is made visible. Therefore, it is suppressed that the reflective film 50 and the front surface 47aa of the front surface of the inner lens appear to shine due to external light.

Therefore, in the headlight 1, while the irradiation functions of the high beam unit HU and the low beam unit LU can be ensured, the inclination of the front surface 47aa of the inner lens 47 and the reflection covered with the front surface 47aa of the inner lens 47. The high beam unit is based on an arrangement structure in which the front surface of the film 50 and the indicator lamp unit 16 (light guide lens 16a) is arranged in front of the front surfaces of the high beam unit HU and the low beam unit LU (projection lenses 19 and 25). Since the HU and the low beam unit LU can be obscured, the high beam unit HU and the low beam unit LU can be made almost inconspicuous. Moreover, in the present embodiment, since the high beam unit HU uses the laser light source unit 26 that forms a high-luminance light source, the laser light source unit 26 has a margin capacity to reduce the brightness until the standard brightness is reached. Utilizing this, the high beam unit (lamp unit) HU can be miniaturized, which also makes the high beam unit HU inconspicuous.
As a result, the sign lamp unit 16 can be made relatively conspicuous, and the design requirement can be satisfied.

6 and 7 show a second embodiment. In this second embodiment, the same components as those in the first embodiment are designated by the same reference numerals, and the description thereof will be omitted.

The second embodiment shown in FIGS. 6 and 7 shows a modification of the first embodiment. In this second embodiment, a modified structure is shown with respect to the low beam unit LU, the indicator lamp unit 16, etc., while maintaining the inclination of the front surface portion 47aa of the inner lens 47 of the first embodiment and the configuration of the reflective film 50. ing. This will be described in detail.

As shown in FIG. 7, the low beam unit LU according to the second embodiment includes a projection lens 19, a laser light source unit 52 as a light source unit for generating white laser light, a reflector 53, and a light-shielding shade 54. It is prepared.
The projection lens 19 is arranged on an optical axis extending in the front-rear direction of the vehicle as in the first embodiment, and the projection lens 19 is an inner lens 47 (space 49 in the peripheral wall portion 47) together with the projection lens 25 of the high beam unit HU. It is located inside.
The laser light source unit 52 is arranged behind the rear focal point of the projection lens 19 on the flat upper surface 55a of the protrusion 55 protruding from the front surface 8b of the support member. As the laser light source unit 52, a laser light source unit 52 having the same structure as the laser light source unit 52 of the high beam unit HU is used, and the laser light source unit 52 is a laser diode (for example, a blue laser diode) 57 provided in the housing 56. The laser light emitted from the housing 56 is wavelength-converted by a phosphor (for example, a yellow phosphor) 58 held in the through hole at the upper part of the housing 56, so that the white laser light is emitted above the phosphor 58. In this case, since the laser light from the laser diode 57 is scattered by the phosphor 58, the white laser light becomes diffused light.
The reflector 53 is arranged so as to cover the laser light source unit 52 from above, and the reflecting surface of the reflector 53 reflects the white laser light from the laser light source unit 52 toward the projection lens 19.
The light-shielding shade 54 shields a part of the reflected light from the reflector 21 and forms a low beam light distribution pattern in front of the projection lens 19 (in front of the vehicle).

Further, as shown in FIGS. 6 and 7, the sign lamp unit 16 according to the second embodiment includes a first sign lamp unit 16A and a second sign lamp unit 16B.
The first indicator lamp unit 16A is arranged above the inner lens peripheral wall portion 47b, and the first indicator lamp unit 16A has a reflector 16Ar that replaces the upper lens portion of the light guide lens 16 according to the first embodiment. And a light emitting element (for example, LED) 16Ab. The reflector 16Ar has a configuration in which a plurality of reflector constituent portions 59 are adjacent to each other in the lateral direction on the inner lens peripheral wall portion 47b, and the reflector 16Ar is extended in a state parallel to the inner lens 47. Each of the reflector components 59 is curved so as to be forward toward the downward direction, and the curved convex surface thereof is directed diagonally downward to the right (see FIG. 7). The light emitting element 16Ab is provided for each reflector component 59, and each light emitting element 16Ab is arranged in the upper region of each reflector component 59, and the emitted light emitted from each light emitting element 16Ab is each. It is supposed to be emitted to the front of the vehicle body by being reflected by the reflector component 59.

The second indicator lamp unit 16B is arranged below the inner lens peripheral wall portion 47b, and the second indicator lamp unit 16B also includes a reflector 16Br and a light emitting element (for example, LED) 16Bb. The reflector 16Br has a configuration in which a plurality of reflector constituent portions 60 are laterally adjacent to each other on the lower side of the inner lens peripheral wall portion 47b, and the reflector 16Br is also extended in a state parallel to the inner lens 47. Each reflector component 60 of the reflector 16Br is curved so as to be forward as it goes upward, and its curved convex surface is directed diagonally upward to the right (see FIG. 7). The light emitting element 16Bb is provided for each reflector component 60, and each light emitting element 16Bb is arranged in a lower region of each reflector component 60, and the light emitted from each light emitting element 16Bb is a reflector. It is supposed to be emitted to the front of the vehicle body by being reflected by the component 60.

Further, each of the light emitting elements 16Bb pays attention to the inclination of the front surface portion 47aa of the inner lens 47, and the reflective film 50 coated on the front surface portion front surface 47aa thereof is used as a part of the optical system of the indicator lamp unit 16. The emitted light is to be emitted even toward the reflective film 50 on the front surface 47aa of the front surface thereof, and the emitted light from each light emitting element 16Bb is reflected by the reflective film 50 on the front surface 47aa on the front surface to the front of the vehicle body. It is supposed to be emitted. Therefore, when the high beam unit HU and the low beam unit LU are turned off (in the daytime), the high beam unit HU and the low beam unit LU are difficult to see due to the inclination of the front surface 47aa of the inner lens 47, the reflective film 50, and the like. The high beam unit and the low beam unit can be obscured by reflecting the light emitted from each light emitting element 16Bb in the indicator lamp unit 16 by the reflective film 50 in front of the projection lens 19. As a result, the sign lamp unit 16 (first sign lamp unit 16A, second sign lamp unit 16B) can be made relatively conspicuous.

Although the embodiment has been described above, in the present invention, (1) the reflective film 50 including the following aspects is coated on the inner surface of the inner lens front portion 47a.
(2) Various light sources (LEDs, laser diodes, etc.) should be appropriately selected and used as the light source of the high beam unit and the low beam unit.

1 Headlights (vehicle headlights)
16 Marker lamp unit 16A 1st marker lamp unit 16B 2nd marker lamp unit 19 Low beam unit projection lens 25 High beam unit projection lens 47 Inner lens 47a Front part of inner lens 47aa Front part of inner lens Front (front surface)
50 Reflective film (reflective surface)
LU low beam unit (lamp unit)
HU high beam unit (lamp unit)

Claims (3)

In a vehicle headlight equipped with a lamp unit that illuminates the front of the vehicle and a sign lamp unit that lights up in the daytime below the lamp unit.
An inner lens is arranged in front of the lamp unit so as to cover the lamp unit.
The inner lens is a vehicle headlight configured to reflect a part of external light from the outside to the inside by inclining toward the front from the lower side to the upper side. hand,
The sign lamp unit includes a light source that emits light upward and a reflector that reflects the light emitted from the light source and emits light to the front of the vehicle body.
The inner lens is configured to reflect a part of the light emitted from the light source of the indicator lamp unit and emit it to the front of the vehicle body.
A headlight for vehicles that is characterized by that. In claim 1,
At least one of the surface and the inner surface of the inner lens is formed as a reflective surface that reflects a part of external light from the outside to the inside.
A headlight for vehicles that is characterized by that. In claim 2,
The reflective surface is formed of a reflective film that reflects a part of the incident light and transmits a part of the incident light.
A headlight for vehicles that is characterized by that.

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