JP2021125448A - Vehicular lighting fixture - Google Patents

Abstract

To provide a vehicular lighting fixture such that it is easy to see the surface of the vehicular lighting fixture uniformly when a light source emits no light.SOLUTION: A turn signal lamp 5 has an LED 7 and an inner lens 10 with a lens body 10a. The lens body 10a is arranged before the LED 7 in a light traveling direction to diverge light from the LED 7 radially. The lens body 10a has an outer diffusion lens face 12a for diffusing light from the lens body 10a formed on a front face 12 thereof. The lens body 10a has a concave part 14 which is formed concavely, and extended in a direction crossing the radiation direction. On a front face 14b or rear face 14a of the concave part 14, an inner diffusion lens face 15 is provided which diffuses the light from the LED 7 toward the outer diffusion lens face 12a.SELECTED DRAWING: Figure 3

Description

The present invention relates to a vehicle lamp. Vehicle lighting fixtures are provided by vehicles such as automobiles.

An automobile is generally equipped with vehicle lighting equipment such as a turn signal lamp for notifying the surroundings of a change in the course of the vehicle and a stop lamp for notifying the vehicle behind the vehicle of braking. A vehicle lamp has a light source that emits light and a light emitting surface that irradiates light from the light source to the outside. The light emitting surface has a wide shape that is long in the horizontal direction, for example, along the outer surface of the vehicle body.

The vehicle lamps disclosed in Patent Documents 1 to 3 have a light bulb as a light source, an inner lens, and a light emitting surface. The inner lens is placed between the bulb and the light emitting surface. The inner lens has a diffusing lens surface (for example, a diffusing step, a diffusing cut) that diffuses light on each of the front and rear surfaces. The diffusion step is composed of a plurality of minute irregularities. The diffusion step is, for example, a Fresnel step having serrated irregularities, a prism step having polyhedral irregularities, and a cylindrical step having columnar irregularities. The light from the light source spreads radially and reaches the inner lens. Light is diffused by the diffusion step of the inner lens. As a result, the light emitting surface can be made to shine uniformly.

Jikkai Sho 63-39808 Jikkenhei 5-27903 Gazette Japanese Unexamined Patent Publication No. 9-180516

However, when the vehicle lamp is viewed from the outside when the light source does not emit light, the light emitting surface located on the surface of the lamp may not be seen uniformly. The light emitting surface seen from the outside may be diffused by the diffusing lens surface of the inner lens to make the appearance look uniform, but it may not look sufficiently uniform. For example, if the outer shape of the inner lens has an uneven shape that causes a large step, or if there is a light source or substrate located behind the inner lens, color unevenness or black streaks can be seen on the light emitting surface of the lamp due to these. There is. Therefore, a vehicle lamp that allows the surface of the vehicle lamp to be seen uniformly even when the light source does not emit light has been conventionally desired.

According to one feature of the present disclosure, a vehicle lamp has a light source and a lens body arranged in front of the light source in the light traveling direction to radially spread the light from the light source. An outer diffusing lens surface that diffuses light from the lens body is formed on the front surface of the lens body. The lens body has recesses that are recessed and extend in a direction that intersects the direction of light emission. At least one of the front surface or the rear surface of the recess is provided with an inner diffusing lens surface that diffuses the light from the light source toward the outer diffusing lens surface.

Therefore, when the lens body is viewed from the outside, the object on the back side is seen through the outer diffusing lens surface and the inner diffusing lens surface. In other words, the object on the back side is seen as light diffused twice through the inner diffusing lens surface and the outer diffusing lens surface. Therefore, the surface of the lens body seen from the outside appears as uniform or nearly uniform brightness and color. Thus, the surface of the vehicle lamp can be seen uniformly when the light source does not emit light.

According to another feature of the present disclosure, the lens body is fan-shaped, has a side surface extending in the radial direction, and a reflecting portion for reflecting light is arranged along the side surface. Therefore, the reflecting portion faces the surface of the lens body (front surface in the light traveling direction). As a result, the reflecting unit can guide the light from the light source forward reliably and efficiently. Further, the line of sight when viewed from the outside is also reflected by the reflecting portion, and the line of sight path makes it easy to make the appearance of the lens body uniform.

According to another feature of the present disclosure, it has a bridging portion that bridges the front and rear portions of the recess at a height deviating from the recess in the thickness direction of the lens body. Therefore, the lens body in the front region of the recess and the lens body in the rear region of the recess can be integrated by the bridging portion. Moreover, the bridging portion is provided at a height away from the recess through which light is transmitted. This makes it possible to prevent the bridging portion from being seen when the lens body is viewed from the outside.

According to another feature of the present disclosure, the light source is an LED. Therefore, the light from the light source having a small irradiation angle can be diffused uniformly while spreading in the radiation direction. As a result, it is possible to uniformly illuminate, for example, a wide light emitting surface by using an LED having low power consumption.

It is a schematic perspective view of the rear part of the automobile provided with the vehicle lighting equipment (lighting equipment) according to this embodiment. It is a front view of a vehicle lamp from the rear of the vehicle (front in the light traveling direction). FIG. 3 is a cross-sectional view taken along line III-III in FIG. FIG. 3 is a cross-sectional view taken along the line IV-IV in FIG. It is a perspective view seen from the lower side of the inner lens of a vehicle lamp.

Preferred embodiments of the present disclosure will be described in detail below with reference to FIGS. 1-5. The same reference number in the description means the same element having the same function without duplicate explanation. FIG. 1 shows an automobile whose forward direction is to the left and in the depth direction. A bumper 2 is provided below the rear part of the vehicle 1. The bumper 2 has lamp portions (lamps) 3 on both left and right sides. The lamp unit 3 has a backup lamp 4 and a turn signal lamp 5 as vehicle lighting equipment. The backup lamp 4 lights up when the vehicle 1 is retracted. The backup lamp 4 can notify the surroundings of the retreat of the vehicle 1. Alternatively, the visibility of obstacles behind the vehicle 1 can be improved. One of the pair of left and right turn signal lamps 5 can blink. As a result, it is possible to notify the surroundings of the change of course of the vehicle 1. Alternatively, a pair of left and right turn signal lamps 5 can be blinked at the same time.

As shown in FIG. 1, the lamp unit 3 has a housing 6 for mounting a backup lamp 4 and a turn signal lamp 5. The housing 6 is long to the left and right when viewed from the rear of the vehicle 1. The backup lamp 4 has a light emitting surface 4a that is substantially circular when viewed from the rear of the vehicle 1. The turn signal lamp 5 has, for example, a substantially parallelogram light emitting surface 5a that is long to the left and right when viewed from the rear of the vehicle 1. The light emitting surfaces 4a and 5a emit light to the rear of the vehicle 1.

As shown in FIGS. 3 and 4, the housing 6 extends substantially in the left-right direction along the outer shape of the bumper 2. The housing 6 slightly inclines in the forward direction of the vehicle 1 as it approaches the left and right ends of the vehicle 1. The housing 6 has a substantially box-shaped lens accommodating chamber 6c inside. A window portion 6a opened in the front-rear direction is provided on the front surface of the lens accommodating chamber 6c. An outer lens 20 is attached to the front portion of the housing 6. The outer lens 20 covers the front surface of the housing 6 together with the backup lamp 4 (see FIG. 1) and the turn signal lamp 5. The outer lens 20 is a plate-shaped member provided with a substantially constant thickness in the traveling direction of light. The outer lens 20 is integrally molded of transparent resin, glass, or the like. The outer lens 20 may be colorless, and may be colored, for example, red or gray.

As shown in FIGS. 1 and 4, the housing 6 has a reflector 9 below the backup lamp 4 and the turn signal lamp 5. The reflector 9 has a reflecting surface that scatters and reflects light incident from the outside. The reflective surface of the reflector 9 faces the rear of the vehicle 1. The reflector 9 reflects, for example, the light emitted toward the vehicle 1 by the lighting of the vehicle following the vehicle 1. The reflector 9 can notify the following vehicle or the like of the position of the vehicle 1 traveling at night, for example.

In the following description, the front-rear direction is defined based on the traveling direction of the light emitted from the light emitting surface 5a. That is, the front-rear direction of the vehicle and the traveling direction of the light are opposite in this example. The vertical and horizontal directions are defined based on the vehicle 1. As shown in FIGS. 3 to 5, the turn signal lamp 5 has an inner lens 10 and an LED holding portion 8. An LED (light source) 7 is attached to the front end of the cylindrical LED holding portion 8. The LED 7 emits light toward the front, and the light has directivity and is emitted at a small irradiation angle. A fitting portion 8a for mounting on the housing 6 is provided on the front portion of the LED holding portion 8.

As shown in FIGS. 3 to 5, the inner lens 10 is housed in the lens housing 6c. The inner lens 10 is made of a colorless and transparent resin, glass, or the like. The inner lens 10 is formed by one member. The inner lens 10 has a flat lens body 10a whose vertical direction is the plate thickness direction. The plate thickness of the lens body 10a is substantially constant. The lens body 10a has a fan shape that radiates from the rear to the front when viewed from above. The rear surface 11 of the lens body 10a stands up substantially vertically. The rear surface 11 has a concave arc shape toward the inside of the lens body 10a when viewed from above.

As shown in FIGS. 3 to 5, the front surface 12 of the lens body 10a stands up substantially vertically. The front surface 12 has a convex arc shape facing outward of the lens body 10a when viewed from above. The outer diffusion lens surface 12a is formed over the entire front surface 12. The outer diffusion lens surface 12a is composed of a plurality of minute irregularities, so-called diffusion steps. The plurality of minute convex surfaces of the outer diffusion lens surface 12a project with substantially the same size in a substantially arc shape. The plurality of convex surfaces of the outer diffusion lens surface 12a are bundled at substantially equal intervals in the circumferential direction and the vertical direction of the fan-shaped lens body 10a. A groove is formed between the plurality of convex surfaces. Therefore, the plurality of grooves of the outer diffusion lens surface 12a are arranged at substantially equal intervals in the circumferential direction and the vertical direction of the lens body 10a. The outer diffusing lens surface 12a diffuses the light incident on the lens body 10a or the light emitted from the lens body 10a in various directions.

As shown in FIG. 5, the lens body 10a has side surfaces 13 at both left and right ends. The side surface 13 is a vertically standing flat surface. The side surface 13 extends between the left and right ends of the front surface 12 and the left and right ends of the rear surface 11. A reflector (reflecting portion) 21 is arranged along each side surface 13. The surface 21a of the reflector 21 is a mirror-like flat surface. The reflector 21 is adjacent to the side surface 13 in parallel with the surface 21a facing the lens body 10a. The reflector 21 extends from the rear end of the side surface 13 to near the front end of the side surface 13.

As shown in FIGS. 3 to 5, the lens body 10a has a recess 14 which is opened downward and recessed upward. The recess 14 is recessed to a depth substantially the same as the plate thickness of the lens body 10a. The recess 14 extends from the left end region to the right end region of the lens body 10a substantially parallel to the front surface 12 and in a substantially arc shape centered on the LED 7. The recess 14 is formed at a position closer to the front surface 12 than the rear surface 11. The rear surface 14a and the front surface 14b of the recess 14 stand up substantially vertically. The rear surface 14a and the front surface 14b are slightly tapered downward toward the opening of the recess 14. The rear surface 14a and the front surface 14b extend substantially parallel to each other. The rear surface 14a is arranged in front of the front end of the reflector 21, the front end of at least one reflector 21. The recess 14 has a connecting portion in the front-rear direction in which the lens body 10a is not recessed between the recess 14 and the side surface 13.

As shown in FIGS. 3 and 5, the front surface 14b is formed on a smooth arcuate surface without unevenness. On the other hand, the inner diffusing lens surface 15 is formed on the rear surface 14a as a whole. The inner diffusion lens surface 15 is composed of a plurality of minute irregularities, so-called diffusion steps. The unevenness of the inner diffusion lens surface 15 is a triangular columnar shape arranged in parallel at predetermined intervals in the horizontal direction or the arc direction. Therefore, the inner diffusion lens surface 15 is serrated in a plan view. The groove depth of the unevenness of the inner diffusion lens surface 15 is small in the central region of the concave portion 14, and increases toward the left and right regions of the concave portion 14. Each of the minute lens surfaces constituting the inner diffusing lens surface 15 stands upright. The inner diffusing lens surface 15 diffuses the light incident on the lens body 10a or the light emitted from the lens body 10a in various directions.

As shown in FIGS. 4 and 5, the inner lens 10 has a bridging portion 16 arranged above the upper surface of the recess 14. The bridging portion 16 covers the entire upper part of the recess 14. The bridging portion 16 projects upward from the upper part of the lens body 10a. The bridging portion 16 bridges the lens body 10a rearward from the rear surface 14a and the lens body 10a in the front region from the front surface 14b. The inner lens 10 has an extending portion 17 extending downward along the front surface 14b of the recess 14.

As shown in FIGS. 2 to 4, the opening shape of the window portion 6a is a substantially parallelogram that is long on the left and right, and corresponds to the outer shape of the light emitting surface 5a. At the upper and lower ends of the window portion 6a, overhanging portions 6b extending horizontally toward the rear (inside the vehicle) are provided. A fitting hole 6d opened in a circular shape in the front-rear direction is provided on the rear surface of the lens accommodating chamber 6c.

As shown in FIGS. 3 and 4, the LED holding portion 8 is attached to the rear portion of the lens accommodating chamber 6c by fitting the fitting portion 8a into the fitting hole 6d with a packing (not shown) interposed therebetween. The inner lens 10 is housed in the lens accommodating chamber 6c and is arranged behind the LED 7 and in front of the outer lens 20. The lens body 10a is arranged at a position where the fan shape radiates from the LED 7 as the center. The front surface 12 is arranged between the upper and lower overhanging portions 6b. The upper and lower overhanging portions 6b extend to the vicinity of the bridging portion 16 and the extending portion 17. By wrapping the bridging portion 16 and the extending portion 17 and each overhanging portion 6b to fill the gap between them, the inside of the turn signal lamp 5 can be made invisible from the outside.

When the light emitting surface 5a of the turn signal lamp 5 is viewed from the outside as shown in FIG. 3, an object on the back side of the lens body 10a is seen through the outer diffusing lens surface 12a and the inner diffusing lens surface 15. The diffused light passes through the outer diffusing lens surface 12a and the inner diffusing lens surface 15. The light diffused twice by the outer diffusing lens surface 12a and the inner diffusing lens surface 15 appears to have uniform brightness in each region of the light emitting surface 5a.

As described above, the turn signal lamp 5 has an LED 7 and an inner lens 10 including a lens body 10a as shown in FIGS. 3 and 4. The lens body 10a is arranged in front of the LED 7 in the light traveling direction to radially spread the light from the LED 7. An outer diffusion lens surface 12a for diffusing light from the lens body 10a is formed on the front surface 12 of the lens body 10a. The lens body 10a has a recess 14 that is recessed and extends in a direction intersecting the radiation direction of light. At least one of the front surface 14b or the rear surface 14a of the recess 14 is provided with an inner diffusing lens surface 15 that diffuses the light from the LED 7 toward the outer diffusing lens surface 12a.

Therefore, when the lens body 10a is viewed from the outside, the object on the back side is seen through the outer diffusion lens surface 12a and the inner diffusion lens surface 15. In other words, the object on the back side is seen as light diffused twice through the inner diffusing lens surface 15 and the outer diffusing lens surface 12a. Therefore, the front surface 12 of the lens body 10a seen from the outside appears as uniform or nearly uniform brightness and color. Thus, the light emitting surface 5a of the turn signal lamp 5 can be seen uniformly when the LED 7 does not emit light.

As shown in FIG. 3, the recess 14 extends on an arc line centered on the LED 7. Therefore, the distance to the LED 7 at each location of the recess 14 is substantially the same. As a result, when the lens body 10a is viewed from the outside, the region behind the recess 14 appears to be substantially uniform. Thus, the front surface 12 of the lens body 10a and the light emitting surface 5a of the turn signal lamp 5 can appear to be in a state with less unevenness, that is, in a more uniform state.

As shown in FIG. 4, it has a bridging portion 16 that bridges the front surface 14b and the rear surface 14a of the recess 14 at a height deviating from the recess 14 in the thickness direction of the lens body 10a. Therefore, the lens body 10a in the front region of the recess 14 and the lens body 10a in the rear region of the recess 14 can be integrated by the bridging portion 16. Moreover, the bridging portion 16 is provided at a height away from the recess 14 through which light is transmitted. As a result, when the LED 7 is viewed from the direction perpendicular to the surface of the front surface 12 of the lens body 10a, the LED 7 is viewed through the same cross section from any direction, so that the LED 7 looks more uniform.

As shown in FIG. 3, the light source of the turn signal lamp 5 is LED 7. Therefore, the light from the LED 7 having a small irradiation angle can be uniformly diffused while being spread in the radiation direction. As a result, for example, the wide light emitting surface 5a can be uniformly illuminated by using the LED 7 having low power consumption.

Various changes can be made to the vehicle lighting fixtures of the present embodiment described above. An example of a turn signal lamp 5 provided behind the vehicle 1 as a vehicle lighting tool. Instead of this, it may be applied to vehicle lighting equipment such as a stop lamp, a clearance lamp, a tail lamp, and a turn signal lamp in front of the vehicle. Further, the present invention is not limited to vehicle lighting fixtures, and may be applied to, for example, marine lighting fixtures, outdoor lighting fixtures, indoor lighting fixtures, and the like. The lens body 10a has one recess 14 extending in a direction intersecting the radial direction and a row of inner diffusion lens surfaces 15 as described above. Instead of this, for example, a plurality of recesses may be arranged in a radial direction of the lens body. Alternatively, the inner diffusion lens surfaces may be arranged in a plurality of rows in the radial direction of the lens body. As described above, the lens body 10a has a connecting portion in the front-rear direction that is not recessed between the side surface 13 and the recess 14. Instead of this, for example, the recess 14 may be extended to the side surface 13.

As described above, the inner diffusion lens surface 15 is formed with minute triangular columnar irregularities arranged in parallel at predetermined intervals. Instead of this, the shape of the inner diffusion lens surface may be changed, and for example, minute irregularities extending in an arc shape may be formed in parallel. Alternatively, the unevenness of the inner diffusion lens surface may be formed in parallel at random intervals. As described above, the vehicle lamp 5 has an LED 7 as a light source. Instead of this, a light source having a small irradiation angle such as HID (high pressure mercury lamp) may be applied.

1 ... Vehicle 2 ... Bumper 3 ... Lamp part (lamp)
4 ... Backup lamp (vehicle lamp), 4a ... Light emitting surface 5 ... Turn signal lamp (vehicle lamp), 5a ... Light emitting surface 6 ... Housing, 6a ... Window, 6b ... Overhang, 6c ... Lens housing, 6d ... Fitting hole 7 ... LED (light source)
8 ... LED holding part, 8a ... Fitting part 9 ... Reflector 10 ... Inner lens, 10a ... Lens body 11 ... Rear surface 12 ... Front surface, 12a ... Outer diffusion lens surface 13 ... Side surface 14 ... Recessed surface, 14a ... Rear surface, 14b ... Front surface ,
15 ... Inner diffusion lens surface 16 ... Bridging part 17 ... Extension part 20 ... Outer lens 21 ... Reflector (reflecting part), 21a ... Surface

Claims (7)

It is a lamp for vehicles,
Light source and
A lens body that is arranged in front of the light source in the light traveling direction and radially spreads the light from the light source.
An outer diffusing lens surface formed on the front surface of the lens body to diffuse light from the lens body,
A recess that is recessed in the lens body and extends in a direction that intersects the radiation direction of light,
A vehicle lamp having an inner diffusing lens surface formed on at least one of the front surface or the rear surface of the recess and diffusing light from the light source toward the outer diffusing lens surface. The vehicle lamp according to claim 1.
The recess is a vehicle lamp extending on an arc line centered on the light source. The vehicle lamp according to claim 1 or 2.
The inner diffusion lens surface is a vehicle lamp that is formed on the rear surface of the recess and is not formed on the front surface. The vehicle lamp according to any one of claims 1 to 3.
The lens body has a fan shape and has a side surface extending in the radial direction.
A vehicle lamp in which a reflecting portion that reflects light is arranged along the side surface. The vehicle lamp according to any one of claims 1 to 4.
A vehicle lamp in which the inner diffusion lens surface is located in front of the front end of the reflecting portion. The vehicle lamp according to any one of claims 1 to 5.
A vehicle lamp having a bridging portion that bridges the front and rear portions of the recess at a height deviating from the recess in the thickness direction of the lens body. The vehicle lamp according to any one of claims 1 to 6.
The light source is a vehicle lamp that is an LED.

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