JP2020202087A - Vehicular lighting fixture - Google Patents

Abstract

To provide a vehicular lighting fixture for allowing a user to readily recognize a shape of an irradiation pattern without causing an increase in light volume of a light source.SOLUTION: A vehicular lighting fixture 10 includes: a light source 21; and a projection lens 12 for forming an irradiation pattern Pi with multiple light-dark boundary lines B by projecting light that is emitted from the light source 21. The projection lens 12 highlights the light-dark boundary lines B by gathering light in at least part of the light-dark boundary lines. The vehicular lighting fixture 10 is installed in a vehicle 1 to form the irradiation pattern Pi around the vehicle 1.SELECTED DRAWING: Figure 2

Description

The present disclosure relates to vehicle lamps.

Vehicle lighting fixtures are considered to illuminate the periphery of the vehicle (see, for example, Patent Document 1 and the like).

This vehicle lighting tool forms an irradiation pattern around the vehicle by projecting an irradiation pattern on the road surface around the vehicle.

US 2018/0257546

However, since the above technique merely projects the irradiation pattern on the road surface around the vehicle, it becomes difficult to recognize the shape of the irradiation pattern unless the amount of light from the light source is increased.

The present disclosure has been made in view of the above circumstances, and an object of the present disclosure is to provide a vehicle lamp capable of easily recognizing the shape of an irradiation pattern without causing an increase in the amount of light of a light source.

The vehicle lamp of the present disclosure includes a light source and a projection lens that projects light emitted from the light source to form an irradiation pattern having a plurality of light-dark boundaries, and the projection lens is the light-dark boundary line. It is characterized by collecting and emphasizing light in at least a part of.

According to the vehicle lamps of the present disclosure, it is possible to easily recognize the shape of the irradiation pattern without causing an increase in the amount of light from the light source.

It is explanatory drawing which shows the state that the vehicle lamp according to this disclosure was mounted on a vehicle, and formed an irradiation pattern. It is explanatory drawing which shows the structure of the vehicle lamp of Example 1. It is explanatory drawing which shows the state of adjustment of the optical setting of a projection lens, and shows the relationship between a plurality of light distribution images of a light source on a screen, and an irradiation pattern. It is explanatory drawing which shows the shape of the exit surface of a projection lens. It is explanatory drawing which shows the shape of the incident surface of a projection lens. It has a shape suitable for forming a diffused light distribution pattern having. It is explanatory drawing which shows the use example as an example of an irradiation pattern formed by a vehicle lamp. It is explanatory drawing which shows the other example of the appearance that the lamp for a vehicle is mounted on a vehicle and formed an irradiation pattern.

Hereinafter, Example 1 of the vehicle lamp 10 as an example of the vehicle lamp according to the present disclosure will be described with reference to the drawings. In addition, in FIG. 1, the size of the vehicle lamp 10 with respect to the vehicle 1 is exaggerated in order to make it easy to grasp the state in which the vehicle lamp 10 is provided, which does not necessarily match the actual state. It's not something to do.

The vehicle lamp 10 of the first embodiment according to the embodiment of the vehicle lamp according to the present disclosure will be described with reference to FIGS. 1 to 7. As shown in FIG. 1, the vehicle lighting fixture 10 of the first embodiment is used as a lighting fixture of a vehicle 1 such as an automobile, and is used on a road surface 2 around the vehicle 1 in addition to the headlights provided in the vehicle 1. The irradiation pattern Pi is formed. Here, the periphery of the vehicle 1 always includes a proximity region closer to the vehicle 1 than the headlight region illuminated by the headlights provided in the vehicle 1, and partially includes the headlight region. In some cases. In the first embodiment, the vehicle lighting fixture 10 is arranged in the lighting chambers on both the left and right sides of the front portion of the vehicle. The lamp chamber is formed by covering the open front end of the lamp housing with an outer lens. The vehicle lamp 10 is provided in a state where the optical axis La is inclined with respect to the road surface 2. This is because the light room is provided at a position higher than the road surface 2. In the following description, as shown in FIG. 2, in the vehicle lighting equipment 10, the direction in which the optical axis La, which is the direction of irradiating light, extends is defined as the optical axis direction (Z in the drawing), and the optical axis direction is horizontal. The vertical direction when the state is along is the vertical direction (Y in the drawing), and the direction orthogonal to the optical axis direction and the vertical direction (horizontal direction) is the width direction (X in the drawing).

The vehicle lamp 10 is assembled with a light source unit 11 and a projection lens 12 to form a direct projection type road surface projection unit. The vehicle lighting fixture 10 is appropriately housed in a housing and provided in the vehicle 1 in a state in which the light source unit 11 and the projection lens 12 are assembled.

In the light source unit 11, the light source 21 is mounted on the substrate 22. The light source 21 is composed of a light emitting element such as an LED (Light Emitting Diode), and is provided so that the emitted optical axis coincides with the optical axis La. In Example 1, the light source 21 emits amber-colored monochromatic light (one peak in a graph with the vertical axis as the amount of light and the horizontal axis as the wavelength) with a Lambersian distribution centered on the optical axis La. To do. The light source 21 has a light emitting portion (a region that emits monochromatic light) having a rectangular shape when viewed from the direction of the optical axis. The light source 21 may appropriately set the color (wavelength band), the mode of distribution, the number of colors (the number of peaks in the above graph), and the like in the emitted light, and is configured in the first embodiment. Not limited.

The substrate 22 appropriately supplies electric power from the lighting control circuit to light the light source 21. The substrate 22 is formed in a plate shape and has a quadrangular shape when viewed from the optical axis direction. The substrate 22 is provided with mounting holes 22a at four corners.

Aluminum is used for the substrate 22 in the first embodiment, and the substrate 22 also functions as a heat sink member for releasing the heat generated by the mounted light source 21 to the outside. The substrate 22 may be provided with a plurality of heat radiation fins as appropriate. Further, the light source unit 11 may have a configuration in which another heat radiating member is addressed to the substrate 22. The light emitted from the light source 21 of the light source unit 11 is projected onto the road surface 2 by the projection lens 12.

The projection lens 12 includes a lens main body portion 23 which is a convex lens having a quadrangular shape when viewed in the optical axis direction, and attachment portions 24 provided on both sides. The quadrangular shape may be a quadrangular shape as long as it has four corners (including a chamfered one on a spherical surface or the like), and each side may be curved. The lens body 23 forms an irradiation pattern Pi on a projection target (road surface 2 in Example 1) by projecting light from the light source 21 while forming it, and the incident surface 25 and the emitting surface 26 are free curved surfaces. There is. The optical setting in the lens body 23 (projection lens 12) will be described later. The projection lens 12 has a lens axis extending in the optical axis direction. The lens axis is an axis that is the optical center of the lens body 23.

The mounting portions 24 are provided in pairs on both side portions in the width direction of the lens main body portion 23, and each protrudes to the rear side (light source portion 11 side) in the optical axis direction. Each mounting portion 24 is provided with a mounting protrusion 27 at an end portion in the vertical direction. Each mounting protrusion 27 has a cylindrical shape that protrudes rearward in the optical axis direction, and can be fitted into the mounting hole 22a of the substrate 22. By fitting each mounting protrusion 27 into the corresponding mounting hole 22a, the mounting portion 24 aligns the lens axis of the lens body portion 23 with the optical axis La of the light source 21 of the light source portion 11.

The projection lens 12 is provided with a diffusing portion 28 on the end face in the left-right direction. The left-right end surface has both side surfaces 23a of the lens body 23 and an outer surface 24a of each mounting portion 24. The diffusing portion 28 is guided into the projection lens 12 and diffuses the light emitted from both side surfaces 23a and the outer surface 24a. For example, each side surface (23a, 24a) is textured or blasted. It is formed by.

Next, the optical setting of the lens body 23 (projection lens 12) will be described with reference to FIGS. 3 to 5. FIG. 3 shows an irradiation pattern Pi formed on a screen arranged orthogonally to the optical axis La, and has a shape different from that when projected on the road surface 2. Further, FIG. 5 shows the projection lens 12 in a state where only the lens main body portion 23 is used and the mounting portion 24 is omitted. In the following, the direction orthogonal to the optical axis La is defined as the radial direction. As shown in FIG. 3, the lens body 23 has a quadrangular contour line (shape) of the irradiation pattern Pi formed on the projection target, which is similar to that of the projection lens 12. In other words, the irradiation pattern Pi is formed by being surrounded by four terminators B. When the light-dark boundary line B is shown individually, the upper side in the vertical direction is the upper boundary line B1, the lower side in the vertical direction is the lower boundary line B2, and the right side in the width direction is the right side boundary line B3. The left side of the direction is the left side boundary line B4. When the irradiation pattern Pi is projected onto the road surface 2, the optical axis La is inclined with respect to the road surface 2, so that the irradiation pattern Pi has a substantially trapezoidal shape as shown in FIG.

In the cross section including the optical axis direction and the width direction, that is, the cross section orthogonal to the vertical direction, the lens body 23 diverges the light from the light source 21 in the radial direction and diverges the luminous flux passing near the optical axis La, and has a diameter. The luminous flux passing through the position away from the optical axis La in the direction is made parallel. That is, the lens body 23 diffuses light in the vicinity of the optical axis La having a Lambersian distribution and a high amount of light, and collects light from the vicinity of the optical axis La toward the outside. Therefore, the lens body 23 disperses the light from the light source 21 substantially evenly so as to have a substantially equal light amount distribution in the cross section, that is, the width direction, and the light-dark boundary line B of the irradiation pattern Pi formed by projection. Light is collected on the right side boundary line B3 and the left side boundary line B4 located in the width direction to emphasize both boundary lines B3 and B4.

Further, as shown in FIG. 4, the lens body portion 23 is formed of an upper lens portion 31 and a lower lens portion 32 in the vertical direction with the optical axis La as the center. In the lens body 23, the upper lens portion 31 forms the far side pattern portion Pf (see FIG. 3) in the irradiation pattern Pi, and the lower lens portion 32 forms the near side pattern portion Pn in the irradiation pattern Pi (see FIG. 3). To form. The far-side pattern portion Pf is a side away from the vehicle lamp 10 (vehicle 1) in the irradiation pattern Pi, that is, a distant portion. The near-side pattern portion Pn is a side close to the vehicle lamp 10 (vehicle 1) in the irradiation pattern Pi, that is, a portion close to the vehicle lighting tool 10 (vehicle 1). The lens body 23 includes a front end portion (near side pattern portion Pn side end portion) of the far side pattern portion Pf formed by the upper lens portion 31 and a near side pattern portion Pn formed by the lower lens portion 32. The back end portion (the end portion on the distant side pattern portion Pf side) is projected in an overlapping manner, and a line portion Lp having a higher light intensity (brighter) than the periphery is formed at the overlapping portion.

The upper lens portion 31 radiates the light from the light source 21 in the radial direction and emits the luminous flux passing through the vicinity of the optical axis La in the vertical cross section including the optical axis direction and the vertical direction, that is, the vertical cross section orthogonal to the width direction, and has a diameter. The luminous flux passing through the position away from the optical axis La in the direction is made parallel. That is, the upper lens portion 31 diffuses light in the vicinity of the optical axis La having a Lambersian distribution and a high amount of light, and collects light from the vicinity of the optical axis La toward the outside. Therefore, the upper lens portion 31 disperses the light from the light source 21 substantially evenly so as to have a substantially equal light amount distribution in the vertical cross section, that is, the upper side in the vertical direction, and the far side pattern portion Pf formed by projection. Light is collected on the upper boundary line B1 located on the upper side in the vertical direction on the light-dark boundary line B, and the upper boundary line B1 is emphasized.

In the above vertical cross section, the lower lens portion 32 diverges the light from the light source 21 in the radial direction and passes through the vicinity of the optical axis La, and parallels the light flux passing through the position away from the optical axis La in the radial direction. To let. That is, the lower lens portion 32 diffuses light in the vicinity of the optical axis La having a Lambersian distribution and a high amount of light, and collects light from the vicinity of the optical axis La toward the outside. Therefore, the lower lens portion 32 distributes the light from the light source 21 substantially evenly so as to have a substantially equal light amount distribution in the vertical cross section, that is, the lower side in the vertical direction, and the near side pattern formed by projection. Light is collected on the lower boundary line B2 located on the lower side in the vertical direction on the light-dark boundary line B of the portion Pn to emphasize the lower boundary line B2.

As described above, the irradiation pattern Pi is formed by the far side pattern portion Pf and the near side pattern portion Pn. In the irradiation pattern Pi, as shown in FIG. 3, a plurality of light distribution images Li of the light source 21 are appropriately superimposed on the screen to form a light-dark boundary line B. Here, each light distribution image Li is basically formed into a quadrangular shape by projecting the light source 21, but the formed position and shape change according to the optical setting in the lens main body 23. Since the lens body 23 is optically set as described above, the irradiation pattern Pi is basically formed with the above-mentioned distribution, but each light distribution image Li is basically set only by the above-mentioned basic setting. (The outer edge thereof) may not be aligned properly, and the terminator B may not be clear. Therefore, the lens body 23 is optically set so as to appropriately align the light distribution images Li forming the outer edge in the irradiation pattern Pi. Here, the lens body 23 can adjust the position where each light distribution image Li is formed on the screen mainly by adjusting the shape of the exit surface 26, and mainly adjusts the shape of the incident surface 25. By adjusting, the shape of each light distribution image Li can be adjusted.

On the screen, the exit surface 26 appropriately aligns the light distribution images Li forming the outer edge of the irradiation pattern Pi, and forms a line (light-dark boundary line B) by arranging the outer edges of the light distribution image Li. In addition, the curvature (plane shape) of the corresponding portion is adjusted. That is, the light distribution image Li shifted to the upper side of the upper boundary line B1 is on the lower side, the light distribution image Li shifted to the lower side of the lower boundary line B2 is on the upper side, and the right side of the right boundary line B3 is on the right side. The curvature of the corresponding portion of the emission surface 26 is adjusted so as to be displaced on the left side of the light distribution image Li shifted to the left side and on the right side of the light distribution image Li shifted to the left side of the left boundary line B4. In FIG. 3, the leftmost light distribution image Li displaced upward from the upper boundary line B1 is displaced downward, and the rightmost light distribution image Li displaced downward from the lower boundary line B2 is displaced upward. The state of displacement and the state of displacement are shown by a two-dot chain line.

The exit surface 26 has the shape shown in FIG. 4 according to the above settings. In FIG. 4, it is shown that the darker the color, the larger the curvature and the relative protrusion, and the lighter the color, the smaller the curvature and the relatively concave. Here, the straight line extending in the width direction through the optical axis La is referred to as the width direction line L1, and the straight line extending in the vertical direction through the optical axis La is referred to as the vertical direction line L2. The exit surface 26 is relatively recessed around the width direction line L1 and around the vertical direction line L2, and is from the first quadrant when the width direction line L1 is the x-axis and the vertical direction line L2 is the y-axis. The portion corresponding to the fourth quadrant is relatively projected. By having such a shape, the emission surface 26 forms an irradiation pattern Pi by appropriately arranging all the light distribution images Li while forming lines in the arrangement of the outer edges of each light distribution image Li. be able to. As a result, the lens body 23 can make the light-dark boundary line B emphasized by the above-mentioned basic light amount distribution clearer. This is because a line is formed by arranging the outer edges of each light distribution image Li, so that each light distribution image Li is arranged inside the line and no light distribution image Li is arranged outside. Therefore, this line becomes a clear terminator B.

Further, the surface shape of the incident surface 25 is adjusted on the screen so that distortion in each light distribution image Li is reduced. Here, the incident surface 25 is individually set to have a shape in the cross section and a shape in the vertical cross section.

As shown in FIG. 5, the incident surface 25 is a concave surface in the cross section, that is, a curved surface protruding toward the side opposite to the light source 21 (front side in the optical axis direction). This is because when the incident surface 25 is a flat surface, the distortion in each light distribution image Li is larger than when the incident surface 25 is a concave surface, and when the incident surface 25 is a convex surface, the distortion in each light distribution image Li is further increased.

Further, the incident surface 25 is a convex surface in the vertical cross section, that is, a curved surface that protrudes toward the light source 21 side (rear side in the optical axis direction). This is because when the incident surface 25 is a flat surface, the distortion in each light distribution image Li is larger than when the incident surface 25 is a convex surface, and when the incident surface 25 is a concave surface, the distortion in each light distribution image Li is further increased.

As described above, the incident surface 25 is a toroidal surface (toroidal lens) having different radii of curvature in the cross section, that is, the width direction, and the vertical section, that is, the vertical direction. If the incident surface 25 has a convex surface in the vertical cross section and a concave surface in the cross section, the respective radius of curvature (curvature) may be appropriately set. By forming the incident surface 25 in such a shape, distortion of each light distribution image Li can be suppressed, and an irradiation pattern Pi can be formed by using each light distribution image Li. As a result, the lens body 23 can have a more desired shape of the irradiation pattern Pi. This is because when the distortion of each light distribution image Li is small, a line is formed by the arrangement of the outer edges of each light distribution image Li as described above, as compared with the case where each light distribution image Li having a large distortion is used. This is because it becomes easy to appropriately arrange the light distribution image Li up to the corner of the set light-dark boundary line B.

The vehicle lamp 10 is assembled as follows with reference to FIG. First, the light source 21 is mounted on the substrate 22 and the light source unit 11 is assembled in a state of being positioned with respect to the substrate 22. After that, each mounting projection 27 of both mounting portions 24 in the projection lens 12 is fitted into the corresponding mounting hole 22a of the substrate 22 of the light source portion 11 to fix both mounting portions 24 to the substrate 22. As a result, the light source unit 11 and the projection lens 12 are attached so that the lens axes of the lens body 23 of the projection lens 12 are aligned on the optical axis La of the light source 21 of the light source unit 11 and at a predetermined interval. The vehicle lighting equipment 10 is assembled.

The vehicle lighting fixture 10 is provided in the lighting chamber in a state where the optical axis La is directed to the side of the vehicle 1 and is inclined with respect to the road surface 2 around the vehicle 1 (see FIG. 1). The vehicle lamp 10 can turn on and off the light source 21 as appropriate by supplying electric power from the lighting control circuit from the substrate 22 to the light source 21. As shown in FIG. 1, the light from the light source 21 is projected while being controlled by the projection lens 12, so that the light is projected from the front end portion of the far side pattern portion Pf and the back end portion of the near side pattern portion Pn. Are overlapped to form an irradiation pattern Pi having a line portion Lp on the road surface 2. The irradiation pattern Pi has a trapezoidal shape that expands as the distance from the vehicle 1 increases due to the fact that the optical axis La is inclined with respect to the road surface 2. The irradiation pattern Pi can partially illuminate the left and right side road surfaces 2 in the vicinity of the front end of the vehicle 1. This irradiation pattern Pi is formed in conjunction with the turn lamp as an example in the first embodiment, and can notify the surroundings that the vehicle 1 is turning left or right.

Next, the operation of the vehicle lamp 10 will be described with reference to FIG. Note that, in FIG. 6, the driver of the motorcycle 3 is omitted for ease of understanding. The vehicle lighting tool 10 is interlocked with the turn lamp, and when either the left or right turn lamp is turned on, the light source 21 of the one provided on the turned on side is turned on, and the irradiation pattern Pi is displayed on the road surface 2. To form. For example, FIG. 6 shows a scene in which a vehicle 1 traveling straight on a road is about to turn left. In the vehicle 1, the turn lamp on the left side blinks, so that the vehicle lighting tool 10 provided on the left front side forms the irradiation pattern Pi on the road surface 2. Then, the driver of the two-wheeled vehicle 3 traveling behind the vehicle 1 can visually recognize the irradiation pattern Pi formed on the road surface 2 even when the turn lamp of the vehicle 1 cannot be visually recognized, and the vehicle 1 can visually recognize the irradiation pattern Pi. You can see that you can turn left.

Further, in the vehicle 1, since the left and right vehicle lamps 10 are interlocked with the turn lamps, when both turn lamps are turned on as hazard lamps, the two left and right vehicle lamps 10 simultaneously perform the irradiation pattern Pi. It will be formed on the road surface 2 (see FIG. 1). Therefore, as compared with the case where only the left and right turn lamps are blinking, the vehicle lighting tool 10 makes the person in the vicinity of the vehicle 1 more surely recognize that the lamp is lit as a hazard lamp. be able to.

Further, since the projection lens 12 of the vehicle lamp 10 is optically set as described above, it is possible to form an irradiation pattern Pi with clear four light-dark boundary lines B as contours by collecting light. Therefore, the vehicle lamp 10 makes it possible to recognize the shape of the irradiation pattern Pi without increasing the amount of light of the light source 21, and the formed irradiation pattern Pi makes it possible for the driver to have some intention (for those around him). In the first embodiment, it is possible to convey (turn left or right, etc.).

Here, the conventional vehicle lighting fixture described in the prior art document merely projects the irradiation pattern on the road surface around the vehicle, and does not emphasize the outline (light-dark boundary line) of the irradiation pattern. For this reason, the conventional vehicle lamps form a vaguely shining region as an irradiation pattern, and it is difficult to recognize the shape of the irradiation pattern. Such an irradiation pattern makes it difficult to distinguish whether the light is formed by the light from the vehicle or the light from a different source from the vehicle, and conveys some intention of the driver to the surrounding people. Becomes difficult. In addition, the irradiation pattern may represent some intention of the driver by a shape, but if it is difficult to recognize the shape, it is also difficult to convey the intention. Therefore, it is conceivable to increase the amount of light from the light source in the conventional vehicle lamps in order to recognize the shape of the irradiation pattern. Etc. will be invited.

On the other hand, in the vehicle lamp 10 of the present invention, the projection lens 12 collects and emphasizes the light from the light source 21 on each terminator B of the irradiation pattern Pi, thereby emphasizing the light from each terminator B of the irradiation pattern Pi. Line B is clear (see FIG. 1). Even when the irradiation pattern Pi is formed with a brightness substantially equal to that of the conventional vehicle lamp, the vehicle lamp 10 is more appropriately than the irradiation pattern formed by the conventional vehicle lamp (the irradiation pattern Pi). The shape) can be recognized. Therefore, the vehicle lamp 10 can recognize the irradiation pattern Pi (its shape) without increasing the amount of light of the light source 21 as compared with the conventional vehicle lamp. Then, since the vehicle lamp 10 can make the peripheral person recognize the irradiation pattern Pi of the intended shape, the driver's intention (turn right or left in the first embodiment, etc.) is appropriately given to the peripheral person. I can tell.

In particular, in the vehicle lamp 10 of the first embodiment, since the light source 21 is monochromatic light, the influence of chromatic aberration on the projection lens 12 can be significantly suppressed. Therefore, the vehicle lamp 10 can form an irradiation pattern Pi in which each light-dark boundary line B is clearer.

In addition, in the vehicle lamp 10 of the first embodiment, in the irradiation pattern Pi, the front end portion of the far side pattern portion Pf formed by the upper lens portion 31 and the near side pattern portion Pn formed by the lower lens portion 32. By overlapping with the back end portion of the lens, a line portion Lp having a higher light intensity (brighter) than the periphery is formed. Here, in the above-mentioned conventional vehicle lighting equipment, a line portion is formed in the irradiation pattern by providing a light source that forms a line portion in addition to the light source that forms the irradiation pattern. Therefore, unlike the conventional vehicle lighting equipment, the vehicle lighting equipment 10 forms a line portion Lp in the irradiation pattern Pi with a simple configuration including the light source unit 11 and the projection lens 12 without using a new light source. This makes it easier to recognize the irradiation pattern Pi.

The vehicle lighting fixture 10 of the first embodiment is provided with diffusion portions 28 on both side surfaces 23a of the lens main body portion 23 and the outer surface 24a of each mounting portion 24, which are end faces in the left-right direction of the projection lens 12. Therefore, in the vehicle lamp 10, even when the light from the light source 21 guided into the projection lens 12 is emitted from both side surfaces 23a of the lens main body 23 and the outer surface 24a of each mounting portion 24. , The light can be diffused by the diffusing unit 28. As a result, the vehicle lamp 10 can prevent the light emitted from both side surfaces 23a and both outer surface 24a from becoming leakage light that illuminates the irradiation pattern Pi and an unintended portion around it. Therefore, the vehicle lamp 10 can suppress blurring of each light-dark boundary line B due to leakage light, can emphasize each light-dark boundary line B more appropriately, and can appropriately form an irradiation pattern Pi.

The vehicle lamp 10 of the first embodiment can obtain the following effects.

The vehicle lamp 10 includes a light source 21 and a projection lens 12 that projects light emitted from the light source 21 to form an irradiation pattern Pi having a plurality of light-dark boundary lines B, and the projection lens 12 is light-dark. Light is collected and emphasized at least part of the boundary line B. Therefore, since the vehicle lamp 10 can make at least a part of the light-dark boundary line B in the irradiation pattern Pi clear, the shape of the irradiation pattern Pi can be easily recognized. The vehicle lamp 10 is compared with the conventional vehicle lamp because the shape of the irradiation pattern Pi can be easily recognized by the light source portion 11 and the projection lens 12 without increasing the amount of light of the light source 21. It can be made into a simple configuration.

Further, in the vehicle lamp 10, the projection lens 12 concentrates the light from the light source 21 inside the light-dark boundary line B and diffuses it in other parts of the irradiation pattern Pi. Therefore, the vehicle lamp 10 can easily form the irradiation pattern Pi (its shape) by controlling the light from the light source 21 by the projection lens 12, and can more appropriately obtain the irradiation pattern Pi. Can be formed.

Further, in the vehicle lamp 10, the emission surface 26 of the projection lens 12 is made a convex surface, and the periphery of the width direction line L1 passing through the optical axis La and the periphery of the vertical direction line L2 passing through the optical axis La are located at other places. On the other hand, it is dented. Therefore, in the vehicle lamp 10, each light distribution image Li forming the irradiation pattern Pi can be positioned inside the emphasized light-dark boundary line B, and the light-dark boundary line B can be made clearer.

In the vehicle lamp 10, the incident surface 25 of the projection lens 12 is a convex surface in a cross section orthogonal to the width direction and a concave surface in a cross section orthogonal to the vertical direction. Therefore, the vehicle lamp 10 can effectively suppress the distortion in each light distribution image Li forming the irradiation pattern Pi, and can form the irradiation pattern Pi more appropriately.

In the vehicle lamp 10, the projection lens 12 is formed by the upper lens portion 31 and the lower lens portion 32 in the vertical direction, and the upper lens portion 31 forms a distant pattern portion Pf which is a distant portion in the irradiation pattern Pi. The lower lens portion 32 forms a near pattern portion Pn that is close to the irradiation pattern Pi. Then, the vehicle lamp 10 overlaps the front end portion of the far side pattern portion Pf and the back end portion of the near side pattern portion Pn to obtain a line portion Lp having a higher light intensity than the periphery in the irradiation pattern Pi. Is forming. Therefore, the vehicle lamp 10 can form the line portion Lp in the irradiation pattern Pi with a simple configuration including the light source portion 11 and the projection lens 12.

The vehicle lamp 10 is provided with a diffusing portion 28 in at least a part of the projection lens 12 other than the incident surface 25 and the exit surface 26. Therefore, the vehicle lamp 10 can suppress blurring of the light-dark boundary line B emphasized by the leaked light, can emphasize the light-dark boundary line B more appropriately, and can appropriately form the irradiation pattern Pi.

Therefore, the vehicle lamp 10 of the first embodiment as the vehicle lamp according to the present disclosure can easily recognize the shape of the irradiation pattern Pi without causing an increase in the amount of light of the light source 21.

Although the vehicle lamps of the present disclosure have been described based on the first embodiment, the specific configuration is not limited to the first embodiment and deviates from the gist of the invention according to each claim of the claims. Unless otherwise, design changes and additions are allowed.

In Example 1, the irradiation pattern Pi has a quadrangular shape having four terminators B. However, the irradiation pattern Pi is formed on the road surface 2 around the vehicle 1 to inform the surrounding people of some intention of the driver, and includes a plurality of corner portions (including those chamfered on a spherical surface or the like). ) And a polygonal shape having a plurality of light-dark boundary lines B, the number and shape of the corners thereof may be appropriately set, and the configuration is not limited to the first embodiment.

Further, in the first embodiment, the projection lens 12 collects and emphasizes the four light-dark boundary lines B, that is, all sides of the rectangular irradiation pattern Pi. However, if the projection lens 12 collects and emphasizes light on at least a part of each light-dark boundary line B of the irradiation pattern Pi, the range of the light-dark boundary line B to be emphasized may be appropriately set, and the configuration of the first embodiment may be used. Not limited. In this case, for example, in the square-shaped irradiation pattern Pi as in the first embodiment, only one side (one terminator B) farthest from the vehicle 1 is not emphasized, as shown in FIG. , It is possible to show the state of moving away from the vehicle 1 while facilitating the recognition of the shape of the irradiation pattern Pi.

Further, in the first embodiment, in the projection lens 12, the diffusion portion 28 is provided on both side surfaces 23a of the lens main body portion 23 and the outer surface 24a of each mounting portion 24. However, if the diffuser 28 is a portion other than the incident surface 25 and the exit surface 26 of the projection lens 12 and the light from the light source 21 guided into the projection lens 12 becomes leakage light, both side surfaces thereof. Other than 23a and both outer surfaces 24a, it may be provided as appropriate, and is not limited to the configuration of the first embodiment.

In the first embodiment, the projection lens 12 superimposes the front end portion of the far side pattern portion Pf and the back end portion of the near side pattern portion Pn to project, thereby forming an irradiation pattern Pi having a line portion Lp. ing. However, the projection lens 12 does not have to form the line portion Lp as long as it projects the light emitted from the light source 21 to form a polygonal irradiation pattern Pi having a plurality of light-dark boundary lines B. , A line portion Lp having another shape may be formed, and the configuration is not limited to that of the first embodiment. The position and shape of the line portion Lp can be set by adjusting the shape of the front end portion of the far side pattern portion Pf and the shape of the back end portion of the near side pattern portion Pn. It can be a line that bends or a line that bends.

10 Vehicle lighting 12 Projection lens 21 Light source 25 Incident surface 26 Exit surface 31 Upper lens part 32 Lower lens part L1 Width direction line L2 Vertical direction line La Optical axis Lp line part B Terminator Pf Far side pattern part Pn Near Side pattern part Pi irradiation pattern

Claims (6)

Light source and
A projection lens that projects light emitted from the light source to form an irradiation pattern having a plurality of light-dark boundaries.
The projection lens is a vehicle lamp that collects and emphasizes light at least a part of the light-dark boundary line. The vehicle lamp according to claim 1, wherein the projection lens collects light from the light source inside the light-dark boundary line and diffuses it at other parts of the irradiation pattern. .. The emission surface of the projection lens is a convex surface, and the periphery of the vertical line extending in the vertical direction through the optical axis and the periphery of the width direction line extending in the width direction through the optical axis are recessed with respect to other parts. The vehicle lighting fixture according to claim 2, wherein the lamp is provided. Any of claims 1 to 3, wherein the incident surface of the projection lens is a convex surface in a cross section orthogonal to the width direction and a concave surface in a cross section orthogonal to the vertical direction. The vehicle lighting equipment according to item 1. The projection lens is formed of an upper lens portion and a lower lens portion in the vertical direction.
The upper lens portion forms a distant side pattern portion that is a distant portion in the irradiation pattern.
The lower lens portion forms a near pattern portion that is a close portion in the irradiation pattern.
By overlapping the front end portion of the far side pattern portion and the back end portion of the near side pattern portion, the projection lens forms a line portion having a higher light intensity than the periphery in the irradiation pattern. The vehicle lamp according to any one of claims 1 to 4, which is characteristic. The vehicle lamp according to any one of claims 1 to 5, wherein the projection lens is provided with a diffusing portion at least a part other than an incident surface and an emitted surface.