JP6920015B2 - Vehicle lighting - Google Patents

Description

The present invention relates to a vehicle lamp provided in front of a vehicle such as a headlamp provided in a two-wheeled vehicle or a four-wheeled vehicle, and is particularly suitable for a daytime lamp using a light emitting element such as an LED as a light source.

In recent years, many lamps for vehicles using LEDs (light emitting diodes) as a light source can be seen. LEDs have advantages such as small size and long life as compared with conventionally known light sources such as incandescent light bulbs and halogen light bulbs, and are widely applied to vehicle lighting fixtures for various purposes.
For example, the vehicle lighting equipment of Patent Document 1 includes a DRL light source unit using an LED as a light source, and the DRL light source unit mounts a plurality of LED light sources on a stepped substrate and is in front of each LED. A horizontally long light emitting surface is provided by providing an inner lens formed in a stepped shape on the side. DRL is an abbreviation for Daytime Runnin Lights and means a daytime lamp.

Japanese Unexamined Patent Publication No. 2012-48896

In the DRL of Patent Document 1, the light emitted from the LEDs arranged in a stepped manner facing the front direction is irradiated as an orientation pattern for a predetermined DRL through the stepped inner lens. Since the inner lens is intended to form a predetermined orientation pattern, little consideration has been given to the design of the appearance both when it is lit and when it is not lit.

In particular, in order to directly incident light from the LED onto the inner lens to form a predetermined orientation pattern, a Fresnel lens cut must be provided on the inside of the inner lens and a predetermined lens cut must be provided on the outside. Therefore, the surface of the inner lens, which becomes the light emitting surface when the LED is turned on, has unevenness in which the portion corresponding to the LED position becomes bright in a dot shape according to each staircase. It has been difficult to obtain a light emitting surface that gives a planar impression of a uniform diffusion surface such as frosted glass. Further, the DRL of Patent Document 1 is provided as one light emitting unit in the headlamp, but the headlamp in recent years has a slant shape inclined in the front-rear direction from the front of the vehicle to the bonnet, and the DRL is also in the front direction. Not only that, it will be observed from above. At that time, the inner lens surface provided with the lens cut is observed as it is, and only gives a similar impression when viewed from two directions, the front direction and the upward direction, and gives a different impression depending on the viewing direction. It was difficult.

The present invention has been proposed in view of such conventional circumstances, and provides a vehicle lamp that gives an impression different depending on the viewing direction and also gives an impression of a uniform diffused surface emitting surface such as frosted glass. The purpose is.

In order to achieve the above object, the vehicle lamp according to claim 1 is
It has a lighting chamber separated by a housing that opens toward the front and a lens cover that covers the front opening of the housing, and a light emitting assembly with an inner lens that is long in one direction when viewed from the front is arranged in the lighting chamber. It is a lighting fixture for vehicles
The light emitting assembly is located behind the lens cover and has a first reflector having a concave first reflecting surface toward the lens cover, and an inner arranged between the lens cover and the first reflector. A lens, a light emitting element located between the first reflector and the inner lens, and a second reflector having a planar second reflecting surface located between the first reflector and the inner lens are provided. ,
The first reflecting surface is a single smooth reflecting surface or a composite reflecting surface composed of a plurality of smooth reflecting surfaces, and a part of the light emitted from the light emitting element is reflected toward the inner lens.
The second reflecting surface is formed on the diffuse reflecting surface, and a part of the light radiated from the light emitting element is diffusely reflected through the inner lens so as to go upward .
The inner lens has a front emitting surface inclined forward downward from the rear edge to the front edge, and a rear incident surface located on the opposite side of the front emitting surface and facing the first reflecting surface. It is a transparent member with and
As for the front side emitting surface, all of the inclined surfaces of the front side emitting surface overlap with the second reflecting surface in the top view.
When the light emitting assembly emits light, the first reflecting surface passes through the inner lens and is visually recognized as a light emitting surface in front view.

The invention according to claim 2 is the vehicle lamp according to claim 1.
The inner lens is formed of a transparent plate-shaped member or a block body, and is formed of a transparent plate-shaped member or a block body.
The front exit surface is characterized by having a bent portion extending in a direction parallel to the one direction.

The invention according to claim 3 is the vehicle lamp according to claim 1 or 2.
The second reflecting surface is a diffuse reflecting surface provided with fine irregularities on the surface of the second reflector.

The invention according to claim 4 is the vehicle lamp according to any one of claims 1 to 3.
The light emitting element is mounted on a substrate, and the light emitting element is mounted on the substrate.
The substrate and the light emitting element are arranged so as to face the second reflecting surface.

The vehicle lamp according to claim 5 is
It has a lighting chamber separated by a housing that opens toward the front and a lens cover that covers the front opening of the housing, and a light emitting assembly with an inner lens that is long in one direction when viewed from the front is arranged in the lighting chamber. It is a lighting fixture for vehicles
The light emitting assembly is located behind the lens cover and has a first reflector having a concave first reflecting surface toward the lens cover, and an inner arranged between the lens cover and the first reflector. A lens, a light emitting element located between the first reflector and the inner lens, a second reflector having a planar second reflecting surface located between the first reflector and the inner lens, and the above. A third reflector, which is between the first reflecting surface and the inner lens and has a third reflecting surface at a position facing the light emitting element, is provided.
The first reflecting surface is a single smooth reflecting surface or a composite reflecting surface composed of a plurality of smooth reflecting surfaces, and a part of the light emitted from the light emitting element is reflected toward the inner lens.
The third reflecting surface reflects a part of the light radiated from the light emitting element toward the second reflecting surface.
The second reflecting surface is formed on the diffuse reflecting surface, faces the third reflecting surface, and transmits a part of the light emitted from the light emitting element and reflected by the third reflecting surface through the inner lens. Diffuse and reflect upward
The inner lens has a front emitting surface inclined forward downward from the rear edge to the front edge, and a rear incident surface located on the opposite side of the front emitting surface and facing the first reflecting surface. It is a transparent member with and
As for the front side emitting surface, all of the inclined surfaces of the front side emitting surface overlap with the second reflecting surface in the top view.
When the light emitting assembly emits light, the first reflecting surface passes through the inner lens and is visually recognized as a light emitting surface in front view.

According to the first aspect of the present invention, since the inner lens is formed of a transparent member having a front emitting surface inclined downward, the inner lens is viewed from above when the vehicle lighting equipment is observed from above. The second reflective surface formed as the diffuse reflective surface is visually recognized. On the other hand, when observing from the front direction of the irradiation direction, the first reflector is visually recognized through the inner lens. This makes it possible to provide vehicle lighting fixtures having two different impressions. Further, by forming a predetermined orientation pattern by the reflected light from the first reflector, it is possible to achieve both the light distribution characteristics and the uniform appearance.

According to the second aspect of the present invention, since the inner lens is further formed of a block body and the front exit surface has a bent portion extending in a direction parallel to the one direction, the observation is made from the front direction. In this case, the first reflector is visually recognized in a plurality of steps through the inner lens having a block feeling. This makes it possible to enhance the sense of depth.

According to the invention of claim 3, since it is sufficient to integrally form the diffuse reflection surface when manufacturing the second reflector, it is possible to form the second reflector by a well-known method such as injection molding at a relatively low cost. Can be provided.

According to the invention of claim 4, since the light emitting element is mounted and arranged on the substrate, the light emitting assembly is provided with an opening having a shape corresponding to the LED, and the opening is covered with the substrate to cause light leakage. It is possible to provide light fixtures for vehicles with a small amount of light.

Further, according to the invention of claim 5, since the third reflecting surface is further provided, the light diffusely reflected by the second reflecting surface can be further diffused and reflected, and the light can be further diffused and reflected through the inner lens. It can be enhanced from the surface texture of the diffuse reflection surface that is visually recognized.

It is a perspective view which shows the outline of the state which attached the vehicle lighting equipment which concerns on one Embodiment to the front part of a vehicle. It is a vertical sectional view of the vehicle lamp 1 of FIG. FIG. 3 is a perspective view of the light emitting assembly. FIG. 4 is a schematic perspective view showing the light emitting assembly in an exploded manner. FIG. 5 is a front view of the light emitting assembly. FIG. 6 is a cross-sectional view taken along the line AA of the light emitting assembly of FIG. FIG. 7 is a cross-sectional view taken along the line BB of the light emitting assembly of FIG. FIG. 8 is a photograph of a main part when the light emitting assembly is observed from the front direction and from the upper direction. FIG. 9 is a cross-sectional view of the light emitting assembly of the third embodiment. FIG. 10 is a cross-sectional view of the light emitting assembly of the fourth embodiment.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a perspective view showing an outline of a state in which the vehicle lamp 1 according to the present invention is attached to the front portion of the vehicle, and FIG. 2 is a vertical sectional view of the vehicle lamp 1 of FIG. In the following description, the descriptions "front", "rear", "left", "right", "top", and "bottom" refer to the direction seen from the vehicle lamp 1.

FIG. 1 schematically shows a vehicle lamp 1 which is a headlamp provided in the front left corner of the vehicle. Inside the vehicle lamp 1, a plurality of lamp assemblies having a light source and an optical system as a minimum unit are provided. The passing beam lamp assemblies 4b and 4c and the traveling beam lamp assembly 4a, which are responsible for the headlamp function, are located in the upper part of the vehicle lighting equipment in order from the outside of the vehicle, and the DRL assembly 6 and the turn lamp assembly 4a are located in the lower part in order from the outside of the vehicle. 5 is provided. As shown in FIG. 2, these lamp assemblies are arranged inside a light chamber 7 separated by a housing 2 that opens forward and a transparent lens cover 3 that covers the front opening of the housing 2. The housing 2 and the lens cover 3 are watertightly integrated with the lens cover 3 by an adhesive material such as hot melt at the sealing portion 8 of the front opening edge of the housing 2. The irradiation light of each lamp assembly passes through the translucent outer cover 3 and irradiates the front of the vehicle, which is the outside of the vehicle lighting fixture 1.

Next, as an example of the light emitting assembly, the DRL assembly 6 will be described in detail from the first embodiment to the fourth embodiment. In the description of these embodiments, an example applied to the DRL assembly 6 will be described, but the lamp assembly is not limited to the DRL assembly, and is a lamp assembly for other purposes such as a turn light assembly, a fog light assembly, and a traveling beam assembly. May be applied to.

(First Embodiment)
3 to 8 are for explaining the light emitting assembly 10 of the first embodiment used as the DRL assembly 6, FIG. 3 is a perspective view of the light emitting assembly, and FIG. 4 is a schematic perspective view showing the light emitting assembly in an exploded manner. 5 and 5 are front views of the light emitting assembly, FIG. 6 is a cross-sectional view taken along line AA of the light emitting assembly of FIG. 5, and FIG. 7 is a cross-sectional view taken along line BB of the light emitting assembly of FIG. .. Further, FIG. 8 is a photograph of a main part when the light emitting assembly is observed from the front direction and from the upper direction.

In the DRL assembly 6, the light emitting assembly 10 has a horizontally long light emitting surface. As shown in FIGS. 3 to 7, each light emitting assembly has a first reflector 11 provided with a first reflecting surface 11a having a concave shape in the diagonally upward forward direction, and a first reflecting surface 11a extending forward from the lower end of the first reflecting surface 11a. On the second reflector 12 provided with the two reflecting surfaces 12a, the substrate 11 located above the first reflecting surface 11a and the second reflecting surface 12a and extending substantially parallel to the second reflecting surface 12a, and the lower surface of the substrate 11. The provided LED (light emitting diode) 15 is assembled so as to be in a predetermined position to form one unit structure. One end of a connector (not shown) is connected to the light emitting assembly 10, and the other end of the connector is connected to a lighting control board 9 attached to the housing 2 (see FIG. 2).

The LED 15 is used as the light source of the light emitting assembly 10. The LED 15 uses a white LED having the brightness and chromaticity required to function for DRL. The white LED 15 uses a surface-mounted LED package in which a blue LED and a phosphor that is excited by the blue LED and emits a color of another wavelength are provided in a reflection frame. The optical axis of the LED 15 is provided at an angle intersecting the first reflecting surface 11a.

As the substrate 14, a metal-based wiring board in which an insulating film and an electrode film are attached on a thick metal substrate is used. By using a metal-based substrate as the substrate 14, heat transfer and heat dissipation can be improved. In this embodiment, a total of two LEDs 15 are arranged in a row on the substrate 14 along the left-right direction. Further, the substrate 14 is arranged so as to cover the upper opening of the space between the first reflector 11 and the inner lens 16 to prevent light leakage from the light emitting assembly 10 and also to act as a reflecting surface. It is provided as follows. As shown in FIG. 6, the substrate is provided so that the LED 15 faces downward.

The first reflector 11 has an inner surface having a curved curved surface that is concave toward the front in the irradiation direction as the first reflecting surface 11a. The first reflecting surface 11a is provided with aluminum vapor deposition on the surface of the first reflector 11 to increase the reflectance. The concave curved curved surface has a basic shape of a rotational reflection surface with the position of the LED 15 as the focal position, and is formed so that a part of the light emitted from the LED 15 is reflected in the forward direction as substantially parallel rays. In the present embodiment, the rotational reflection surface is divided into a plurality of reflection regions, and each divided reflection region is a composite reflection surface that expands in the horizontal direction as compared with the vertical direction. Each split reflection region is formed as a smooth diffuse reflection surface. Each split reflection region is formed so as to satisfy the orientation characteristics for DRL as a whole of the DRL assembly 6. The first reflecting surface 11a is not limited to the composite reflecting surface, and may be formed as a single smooth reflecting surface composed of a free curved surface that reflects so as to satisfy the orientation characteristics for DRL.

The second reflector 12 is formed in a plate shape extending substantially parallel to the substrate 14 on which the LED 15 is mounted. The upper surface of the second reflector 12, that is, the surface on the LED15 side is formed as the second reflecting surface 12a. The second reflecting surface 12a is a diffuse reflecting surface provided with fine irregularities on the surface of the second reflector. Fine irregularities include, for example, an uneven surface having matrix-like grooves at a pitch smaller than 1.0 mm, an uneven surface having grooves extending in various directions by hairline processing or grain processing, and a large number of dots smaller than 0.5 mm. The provided uneven surface can be used. It may be a diffuse reflection surface in which an aluminum reflection film is provided at the same time as the first reflection surface on the ground under the fine unevenness by means such as thin film deposition. The second reflecting surface 12a extends from the front lower end of the first reflecting surface to the front of the light emitting assembly 10 in the irradiation direction, specifically, to the front edge 16c of the inner lens 16 as shown in FIG. Further, the position of the rear end of the second reflecting surface 12a, that is, the position of the boundary with the first reflecting surface 11a is on the front side of the virtual intersection of the optical axis of the LED 15 and the line extending to the rear side of the second reflecting surface. It is formed so as to be located at a position where the direct light from the LED 15 is incident.

The first reflector 11 and the second reflector 12 are integrally formed by injection molding using a thermoplastic resin material such as ASA resin (acrylate styrene acrylonitrile), ABS resin (acrylonitrile butadiene styrene), acrylic resin, and polycarbonate resin. There is. Further, as shown by the broken line in FIG. 7, a plurality of light emitting assemblies 10 are formed by integrally forming the first reflector 11 and the second reflector 12 of the other light emitting assemblies 10 in the vicinity of one light emitting assembly 10. May be arranged close to each other in the left-right direction to form a horizontally long light emitting surface as a whole. By integrally forming the reflectors of the plurality of light emitting assemblies 10, it is possible to enhance the uniformity of the light emitting surface of the DRL assembly 6 composed of the plurality of light emitting assemblies 10. Reference numeral 17 is a side wall 17 formed in the front-rear direction. Further, since a plurality of light emitting assemblies can be formed at the same time, the assembly man-hours can be reduced. Further, since the light distribution characteristics required for the DRL assembly may be satisfied by the aggregate of the plurality of light emitting assemblies 10, it is not necessary to use the high brightness type as the LED 15 used for each light emitting assembly. As a result, the current flowing to light the LED can be reduced, and heat generation can be suppressed.

The inner lens 16 is arranged in front of the first reflector 11 and the LED 15 and above the second reflector 12. The light emitting assembly 10 is provided so that the inner lens 16 is located rearward adjacent to the transparent lens cover 3 so as to face the lens cover 3 of the vehicle lamp 1 shown in FIGS. 1 and 2. As a result, the inner lens 16 is easily viewed by an observer such as a pedestrian in front of the vehicle through the lens cover 3. The distance between the rear edge 16d of the inner lens 16 and the first reflecting surface 11a is equivalent to the projected distance from the front edge 16c of the inner lens 16 to the posterior edge 16d, specifically, the front edge. The first reflecting surface 11a is arranged recessed with respect to the inner lens 16 so that the projected distance from the edge 16c to the posterior edge 16d is 0.8 to 1.4 times. This makes it difficult for the first reflecting surface 11a to be seen through the inner lens 16.

The inner lens 16 is formed of a transparent plate-shaped member such as an acrylic resin or a polycarbonate resin, and includes a rear side incident surface 16a located on the opposite side of the front side emitting surface 16a and the front side emitting surface 16a. The front exit surface 16a faces the lens cover 3, and the rear entrance surface 16b faces the first reflection surface 11a. The front exit surface 16a is an inclined surface that is inclined forward downward from the rear edge 16d toward the front edge 16c. In the upward view, the entire inclined front side emitting surface 16a is formed to have a length overlapping the second reflecting surface 12a in the front-rear direction. As a result, the second reflecting surface 12a can be viewed by an observer such as a pedestrian in front of the vehicle through the lens cover 3 and the inner lens 16. In order to facilitate viewing of the second reflecting surface 12a, it is preferable that the front emitting surface 16a and the rear incident surface 16b are formed as smooth surfaces that allow light to pass through. The rear side incident surface 16b is also an inclined surface inclined forward downward like the front side exit surface 16a. Reference numeral 161 is an inner lens bending portion having a different inclination angle as shown in FIG. 7, and a bending line 161a is observed in the left-right direction as shown in FIG.

Next, the lighting state of the light emitting assembly 10 will be described.

When the lighting switch (not shown) is turned on, the light emitted from the LED 15 irradiates both the first reflecting surface 11a and the second reflecting surface 12a. The light reflected by the first reflecting surface 11a is referred to as a light ray L1, the light reflected by the second reflecting surface is referred to as a light ray L2, and typical light rays are shown in FIGS. 6 and 2. Since the optical axis of the LED 15 is directed to the first reflecting surface 11a, the light ray L1 includes the brightest light ray. Since the first reflecting surface 11a is based on a rotating paraboloid with the LED 15 as the focal position as shown in FIG. 7, the light emitted from the LED 15 is reflected toward the inner lens 16 in the forward direction. .. Further, a part of the light is also reflected by the side wall 17 and is formed so as not to leak to the outside of the light emitting assembly 10. To be precise, a plurality of reflection regions are provided on the first reflection surface, and the reflection direction is controlled for each reflection region to obtain a predetermined diffusion orientation so as to satisfy the orientation characteristics for DRL as a whole. I am trying to do it. In the drawing showing the cross section of the reflecting surface, it is shown as a cross section of one parabolic reflecting surface for simplification.

After being reflected by the first reflecting surface 11a, the light ray L1 spreads in the left-right direction as compared with the up-down direction and is reflected toward the inner lens 16. The light incident from the rear side incident surface 16b of the inner lens 16 passes through the inner lens 16 and is emitted from the front side exit surface 16a. Since the inner lens 16 is tilted, refraction occurs at each interface. The first reflecting surface 11a is formed so that the light ray L1 satisfies the orientation pattern for DRL, and is fixed to the light emitting assembly 10 at a predetermined mounting angle. Specifically, on a predetermined virtual screen provided in front of the vehicle lighting equipment, a range surrounded by 10 degrees in the vertical direction and 20 degrees in the horizontal direction is irradiated with a predetermined brightness.

The light ray L2 is diffused and reflected by the second reflecting surface 12a, and then is emitted from the front exit surface 16a through the inner lens 16. The light ray L2 is light that is far from the optical axis of the LED, which is lower in brightness than the light ray L1. The low-brightness light is further diffused by the second reflecting surface formed as the diffuse reflecting surface. The light ray L2 emitted through the inner lens 16 becomes low-intensity diffused light and becomes light radiated from the front to the upper side. The optical axis direction of the LED 15, the boundary position between the first reflecting surface 11a and the second reflecting surface 12a, and the degree of diffusion of the second reflecting surface 12a are adjusted so that the brightness of the light ray L2 does not become glare light to the driver of the oncoming vehicle. The positions of each other are determined by adjustment.

FIG. 8A shows the light emitting assembly 10 when the LED 15 is turned on, and is a photograph when the light emitting assembly 10 is viewed from the position indicated by V1 in FIG. 2, that is, from the front direction. A horizontally long first reflecting surface 11a is observed through the inner lens 16 in the vicinity of the front view. At this time, since the first reflecting surface 11a is formed as a composite reflecting surface, many light emitting points are scattered in the left-right direction. This light emitting point is for observing the reflected light from the LED 15. In FIG. 8A, it appears to be substantially double up and down in the vertical direction. This double-looking boundary corresponds to the bending line 161a of the inner lens bending portion 161. Since the inner lens bending portion 161 is bent from the upper side to the lower side, the bending line 161a is observed extending in the left-right direction as shown in FIG. Since the refraction angle of the light ray L1 changes with the bending line 161a as a boundary, it can be observed multiple times in the vertical direction and give a three-dimensional impression with a high sense of depth. When FIG. 8 (A) is observed in detail, it is not a double layer, but a triple layer consisting of an upper narrow area, a wide interruption area, and a lower area corresponding to the two bending lines. As a result, it is viewed as an inner lens 16 having a horizontally long light emitting surface.

FIG. 8B shows the light emitting assembly 10 when the LED 15 is turned on, and is a photograph when the light emitting assembly 10 is viewed from the position indicated by V2 in FIG. 2, that is, from the upper direction. The second reflecting surface 12a is viewed through the inner lens 16 in the vicinity of the upward view. At this time, since the second reflecting surface 12a is formed as a diffuse reflecting surface, it looks like a uniform surface that shines white as a whole due to the light rays L2 that diffuse and irradiate. As a result, the diffused light emission is viewed as a light emitting surface that gives the impression of an inner lens 16 that shines white like frosted glass.

Even when the LED 15 is not lit, light is emitted from the position indicated by V1 in FIG. 2, that is, when the light emitting assembly 10 is viewed from the front direction and from the position indicated by V2 in FIG. 2, that is, from the upper direction. In both cases when the assembly 10 is viewed, it is viewed as a light emitting surface having a different impression so as to be similar to each of FIGS. 8 (A) and 8 (B). When viewed from the front, the first reflective surface 11a of metallic color (aluminum reflective film color) is observed through the transparent inner lens 16, and when viewed from above, diffuse reflection is observed through the transparent inner lens 16. The second reflecting surface 12a, which is a surface, is observed with the impression of a uniform surface such as whitish frosted glass, which is different from the metallic color due to diffuse reflection.

According to the vehicle lamp 1 provided with the light emitting assembly 10 of the present embodiment, the inner lens 16 of the light emitting assembly 10 is observed through the lens cover 3. A lamp that emits the same function can give different impressions depending on whether it is viewed from the front of the lamp or from above.

If the surface of the inner lens 16 is used as a diffusing surface to give an overall whitish impression like frosted glass, all of the irradiation light will pass through the diffusing surface. Is difficult to satisfy. However, according to the vehicle lamp 1 provided with the light emitting assembly 10 of the present embodiment, it can be viewed as a diffuse reflection surface through the inner lens, and for a vehicle that gives the impression of a uniform diffuse surface light emitting surface such as frosted glass. Lighting equipment can be provided. Since the inclined inner lens 16 is arranged so as to overlap the second reflecting surface 12a and the first reflecting surface 11a is arranged in the depth, when observed from most directions, the frosted glass is as shown in FIG. 8 (B). It gives the impression of a uniform diffused light emitting surface, that is, the impression that the whole is whitish. At the same time, the DRL light distribution can be satisfied while giving a transparent depth feeling in the front direction.

(Second embodiment)
Next, the second embodiment will be described. The same reference numerals are used for those showing the same functions and the same configurations as those of the first embodiment, and detailed description thereof will be omitted. The second embodiment has a different light source from the first embodiment. Although the point that the LED 15 is used as the light source is the same, two types of LEDs are used as the LED 15. Specifically, in addition to the high-brightness white LED having the brightness and chromaticity necessary for functioning as a DRL, the brightness is lower than that of the high-brightness white LED for DRL in order to exert the function as a position lamp. A low-brightness white LED is provided. The high-brightness white LED is provided at the focal position of the first reflecting surface 11a as in the first embodiment. The low-brightness white LED is provided at a position away from the focal position of the first reflecting surface 11a with respect to the high-brightness white LED 15. As a result, the light emitted by the low-brightness white LED is reflected by the first reflecting surface 11a to irradiate the outside, and the light is diffused as compared with the high-brightness white LED for DRL, and also functions as a position lamp. do. By reducing the drive current of the high-brightness white LED 15 instead of the low-brightness LED to reduce the light emission brightness, it is possible to obtain a light emission assembly that fulfills both the DRL function and the position lamp function. Further, instead of the low-brightness LED, an LED having another light emitting color such as orange can also be used as an accessory lamp.

(Third Embodiment)
Next, the third embodiment will be described. FIG. 9 is a cross-sectional view of the light emitting assembly 20 of the third embodiment. The same reference numerals are used for those showing the same functions and the same configurations as those of the first embodiment, and detailed description thereof will be omitted.

The light emitting assembly 20 of the third embodiment has a different inner lens 26 as compared with the first embodiment. The inner lens 26 is formed of a solid block body including a front exit surface 26a, a rear entrance surface 26b, and a bottom surface. The front side emitting surface 26a is provided with a bent portion 261 similar to the front side emitting surface 16a of the inner lens 16 in the first embodiment. The rear incident surface 26b is formed as a flat surface extending in a substantially vertical direction in the vertical direction with respect to the second reflecting surface 12a. By forming the incident surface 26b on the rear side so as to be substantially perpendicular to the light beam L1, the reflection loss at this interface can be reduced.

(Fourth Embodiment)
Next, the fourth embodiment will be described. FIG. 10 is a cross-sectional view of the light emitting assembly 20 of the fourth embodiment. The same reference numerals are used for those showing the same functions and the same configurations as those of the first embodiment, and detailed description thereof will be omitted.

The light emitting assembly 30 of the fourth embodiment adds a third reflecting surface 33a as compared with the first embodiment. The substrate 14 on which the LED 15 is mounted is provided so that the optical axis faces diagonally rearward and upward. The first reflecting surface 31a is arranged so as to cover the upper part of the LED 15 so as to reflect the light from the LED 15 provided below toward the inner lens 16. A third reflector 33 having a third reflecting surface 33a is formed integrally with the first reflecting surface 31 from the upper front end surface of the first reflecting surface 31a toward the front. The third reflector 33 is located between the first reflector 31 and the inner lens 16 and is arranged so as to face the substrate 14.

A second reflector provided with a second reflecting surface 32a is arranged below the third reflecting surface 33a. The second reflector 32 is formed in a plate shape extending substantially parallel to the third reflecting surface 33a, and is provided between the substrate 14 and the front edge 16c of the inner lens 16. The upper surface of the second reflector 32, that is, the surface on the third reflector 33 side is formed as the second reflecting surface 32a. The second reflecting surface 32a is a diffuse reflecting surface provided with fine irregularities on the surface of the second reflector, similarly to the second reflecting surface 12a of the first embodiment. If the diffuse reflection surface is provided with an aluminum reflective film on the ground under the fine irregularities, the aluminum diffuse reflection film with an impression of turbidity in white can be obtained. The second reflecting surface 32a extends from the front end of the substrate 14 to the front of the light emitting assembly 10 in the irradiation direction, specifically, to the front edge 16c of the inner lens 16 as shown in FIG.

When viewed from above, the inner lens 16 is formed to have a length that overlaps with the second reflecting surface 32a as a whole over the front-rear direction of the inclined front side emitting surface 16a as in the first embodiment. There is. As a result, the second reflecting surface 32a can be viewed by an observer such as a pedestrian in front of the vehicle through the lens cover 3 and the inner lens 16. The second reflecting surface 32a is formed so as to extend rearward from the inner lens 16 in top view.

The third reflective surface 33a is formed on a flat surface provided with a high-reflectivity reflective surface provided with an aluminum reflective film like the first reflective surface 31a, and is formed with the second reflective surface 32a at least at a position on the front side. Facing each other. The third reflecting surface 33a is not limited to a reflecting surface having a high reflectance, and may be a diffuse reflecting surface, or a reflecting surface having a difference in the degree of diffusion so that the degree of diffusion becomes stronger toward the front side. By increasing the degree of diffusion reflection at the position on the front side of the third reflection surface 33a facing the second reflection surface 32a, the diffusion reflection on the second reflection surface 32a can be further enhanced, and even more uniform planar diffusion can be achieved. The impression of the light emitting surface that becomes the surface can be enhanced.

Next, the lighting state of the light emitting assembly 30 will be described.

When the lighting switch (not shown) is turned on, the light emitted from the LED 15 irradiates both the first reflecting surface 31a and the third reflecting surface 33a. The light reflected by the first reflecting surface 31a is referred to as a light ray L1, the light reflected by the second reflecting surface is referred to as a light ray L2, and a typical light ray is shown in FIG. Since the optical axis of the LED 15 is directed to the first reflecting surface 31a, the light ray L1 includes the brightest light ray.

After being reflected by the first reflecting surface 31a, the light ray L1 spreads in the left-right direction as compared with the up-down direction and is reflected toward the inner lens 16. The light incident from the rear side incident surface 16b of the inner lens 16 passes through the inner lens 16 and is emitted from the front side exit surface 16a. Since the inner lens 16 is tilted, refraction occurs at each interface. The first reflecting surface 11a is formed so that the light ray L1 satisfies the orientation pattern for DRL, and is fixed to the light emitting assembly 10 at a predetermined mounting angle. Specifically, on a predetermined virtual screen provided in front of the vehicle lighting equipment, a range surrounded by 10 degrees in the vertical direction and 20 degrees in the horizontal direction is irradiated with a predetermined brightness.

A part of the light emitted from the LED 15 reaches the third reflecting surface 33a, and the light reflected by the third reflecting surface 33a travels toward the second reflecting surface 32a. Then, after diffusing and reflecting on the second reflecting surface 32a, the light is emitted from the front exit surface 16a through the inner lens 16. The light ray L2 is light that is far from the optical axis of the LED, which is lower in brightness than the light ray L1. Light with low brightness is reflected by the third reflecting surface 33a and then further diffused by the second reflecting surface 32a formed as a diffuse reflecting surface. The light ray L2 emitted through the inner lens 16 becomes low-intensity diffused light and becomes light radiated from the front to the upper side. The optical axis direction of the LED 15, the boundary position between the first reflecting surface 11a and the third reflecting surface 33a, the degree of diffusion of the second reflecting surface 32a, and the degree of diffusion of the second reflecting surface 32a so that the brightness of the light ray L2 does not become glare light to the driver of the oncoming vehicle. The positions of the third reflecting surfaces 33a are determined by adjusting the combination such as the degree of diffusion.

As a result, the light beam L2 can give the impression of even more uniform surface emission. Further, the vehicle lighting equipment can provide a vehicle lighting equipment having an inner lens that gives an impression different depending on the viewing direction and also having a DRL assembly that gives an impression of a uniform diffused surface emitting surface such as frosted glass. .. In addition, the DRL light distribution can be satisfied while having the impression of a uniform diffuse reflection surface.

Although the embodiments of the present invention have been described above, the above-described embodiments are merely examples in all respects. These descriptions do not limit the present invention. The present invention can be added, omitted, replaced and other modifications of the configuration in various other ways without departing from its gist.
For example, although the light emitting assembly described in the first to fourth embodiments is used as a DRL assembly having a horizontally long light emitting surface long in the left-right direction, the vehicle is used as a DRL unit having a vertically long light emitting surface long in the vertical direction. It may be arranged in the lamp 1.

1 ... Vehicle lighting equipment (headlamp)
2 ... Housing 3 ... Lens cover 4 ... Headlamp assembly 5 ... Turn lamp assembly 6 ... DRL assembly 7 ... Light room 8 ... Seal 10 ... Light emitting assembly (DRL assembly)
11 ... 1st reflector 11a ... 1st reflecting surface 12 ... 2nd reflector 12a ... 2nd reflecting surface 14 ... Substrate 15 ... Light source (LED)
16 ... Inner lens 16a ... Front side exit surface 16b ... Rear side incident surface 16c ... Front side edge 16d ... Rear side end edge 161 ... Inner lens bent portion 17 ... Side wall 20 ... Light emitting assembly (DRL assembly)
26 ... Inner lens 30 ... Light emitting assembly (DRL assembly)
31 ... 1st reflector 32 ... 2nd reflector 33 ... 3rd reflector

Claims (5)

It has a lighting chamber separated by a housing that opens toward the front and a lens cover that covers the front opening of the housing, and a light emitting assembly with an inner lens that is long in one direction when viewed from the front is arranged in the lighting chamber. It is a lighting fixture for vehicles
The light emitting assembly is located behind the lens cover and has a first reflector having a concave first reflecting surface toward the lens cover, and an inner arranged between the lens cover and the first reflector. A lens, a light emitting element located between the first reflector and the inner lens, and a second reflector having a planar second reflecting surface located between the first reflector and the inner lens are provided. ,
The first reflecting surface is a single smooth reflecting surface or a composite reflecting surface composed of a plurality of smooth reflecting surfaces, and a part of the light emitted from the light emitting element is reflected toward the inner lens.
The second reflecting surface is formed on the diffuse reflecting surface, and a part of the light radiated from the light emitting element is diffusely reflected through the inner lens so as to go upward .
The inner lens has a front emitting surface inclined forward downward from the rear edge to the front edge, and a rear incident surface located on the opposite side of the front emitting surface and facing the first reflecting surface. It is a transparent member with and
As for the front side emitting surface, all of the inclined surfaces of the front side emitting surface overlap with the second reflecting surface in the top view.
A vehicle lighting fixture characterized in that when the light emitting assembly emits light, the first reflecting surface passes through the inner lens and is visually recognized as a light emitting surface in a front view. The inner lens is formed of a transparent plate-shaped member or a block body, and is formed of a transparent plate-shaped member or a block body.
The vehicle lamp according to claim 1, wherein the front exit surface has a bent portion extending in a direction parallel to the one direction. The vehicle lamp according to claim 1 or 2, wherein the second reflecting surface is a diffuse reflecting surface provided with fine irregularities on the surface of the second reflector. The light emitting element is mounted on a substrate, and the light emitting element is mounted on the substrate.
The vehicle lighting device according to any one of claims 1 to 3, wherein the substrate and the light emitting element are arranged so as to face the second reflecting surface. It has a lighting chamber separated by a housing that opens toward the front and a lens cover that covers the front opening of the housing, and a light emitting assembly with an inner lens that is long in one direction when viewed from the front is arranged in the lighting chamber. It is a lighting fixture for vehicles
The light emitting assembly is located behind the lens cover and has a first reflector having a concave first reflecting surface toward the lens cover, and an inner arranged between the lens cover and the first reflector. A lens, a light emitting element located between the first reflector and the inner lens, a second reflector having a planar second reflecting surface located between the first reflector and the inner lens, and the above. A third reflector, which is between the first reflecting surface and the inner lens and has a third reflecting surface at a position facing the light emitting element, is provided.
The first reflecting surface is a single smooth reflecting surface or a composite reflecting surface composed of a plurality of smooth reflecting surfaces, and a part of the light emitted from the light emitting element is reflected toward the inner lens.
The third reflecting surface reflects a part of the light radiated from the light emitting element toward the second reflecting surface.
The second reflecting surface is formed on the diffuse reflecting surface, faces the third reflecting surface, and transmits a part of the light emitted from the light emitting element and reflected by the third reflecting surface through the inner lens. Diffuse and reflect upward
The inner lens has a front emitting surface inclined forward downward from the rear edge to the front edge, and a rear incident surface located on the opposite side of the front emitting surface and facing the first reflecting surface. It is a transparent member with and
As for the front side emitting surface, all of the inclined surfaces of the front side emitting surface overlap with the second reflecting surface in the top view.
A vehicle lighting fixture characterized in that when the light emitting assembly emits light, the first reflecting surface passes through the inner lens and is visually recognized as a light emitting surface in a front view.

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