JP2021197252A - Vehicular lighting fixture - Google Patents

Abstract

To provide a vehicular lighting fixture that can be downsized while forming an irradiation pattern having a desired size.SOLUTION: A vehicular lighting fixture 1 comprises first units (10, 20, and 30) comprising first irradiation lenses (12, 22, and 32) for emitting light incident from first light sources (11, 21, and 31), and second units (40 and 50) comprising second irradiation lenses (42 and 52) for emitting a portion of light incident from second light sources (41 and 51), and emitting the other portion of the light after internally reflecting it. A desired light distribution pattern (low-beam irradiation pattern LP) is formed by superimposing light condensing patterns (LP1, LP2, and LP3) formed by the first units and distribution patterns (LP4 and LP5) formed by the second units.SELECTED DRAWING: Figure 1

Description

The present disclosure relates to vehicle lamps.

As a vehicle lamp, it is considered that a plurality of units are used, each unit individually forms a light distribution pattern, and the irradiation pattern is formed by appropriately superimposing them (see, for example, Patent Document 1 and the like). ).

This vehicle lighting fixture uses a reflector reflection type unit that reflects the light from the light source with a reflector to form a light distribution pattern that spreads over a desired range, and directly irradiates the light from the light source with a direct irradiation lens. By using this unit, a light distribution pattern with a high amount of light is formed in a narrow range. Therefore, in this vehicle lighting equipment, by superimposing each light distribution pattern, it is possible to form an irradiation pattern that illuminates a desired range with a desired brightness distribution.

Japanese Unexamined Patent Publication No. 2004-95481

Here, since the above-mentioned vehicle lamp has a desired size of the irradiation pattern by using a plurality of reflector reflection type units, the overall configuration is large.

The present disclosure has been made in view of the above circumstances, and an object of the present invention is to provide a lamp for a vehicle that can be miniaturized while forming an irradiation pattern of a desired size.

The vehicle lamp of the present disclosure includes a first unit having a first irradiation lens that emits light incident from a first light source, and emits a part of light incident from a second light source and emits other parts of light. A second unit having a second irradiation lens that is internally reflected and then emitted is provided, and it is desired to superimpose a light collecting pattern formed by the first unit and a diffusion pattern formed by the second unit. It is characterized by forming a light distribution pattern of.

According to the vehicle lamp of the present disclosure, it is possible to reduce the size while forming an irradiation pattern of a desired size.

It is explanatory drawing which disassembles and shows the structure of the vehicle lamp as an example which concerns on one Embodiment of the vehicle lamp which concerns on this disclosure. It is sectional drawing which shows the vertical cross section (vertical cross section) orthogonal to the left-right direction obtained along the line I-I of FIG. It is explanatory drawing which shows the 1st light distribution pattern. It is sectional drawing obtained along the line II-II of FIG. It is explanatory drawing which shows the 2nd light distribution pattern. It is sectional drawing obtained along the line III-III of FIG. It is explanatory drawing which shows the 3rd light distribution pattern. The irradiation lens of the 4th low beam unit is shown in a cross section (horizontal cross section) orthogonal to the vertical direction, and is also an explanatory diagram showing how the light incident from the curved incident surface portion and emitted from the central exit surface portion travels. .. It is explanatory drawing which shows the irradiation lens of the 4th low beam unit in the cross section, and also shows the traveling of the light which is reflected by the reflection surface and is emitted from the upper emission surface part (lower emission surface part). It is explanatory drawing which shows the state which the irradiation lens of the 4th low beam unit was seen from the exit surface side. It is explanatory drawing which shows the a pattern part of the 4th light distribution pattern. It is explanatory drawing which shows the b pattern part of the 4th light distribution pattern. It is explanatory drawing which shows the 4th light distribution pattern. It is explanatory drawing which shows the irradiation lens of the 5th low beam unit in the cross section. It is explanatory drawing which shows the state which the irradiation lens of the 5th low beam unit was seen from the exit surface side. It is explanatory drawing which shows the a pattern part of the 5th light distribution pattern. It is explanatory drawing which shows the b pattern part of the 5th light distribution pattern. It is explanatory drawing which shows the c pattern part of the 5th light distribution pattern. It is explanatory drawing which shows the irradiation lens of the 5th low beam unit in a vertical cross section, and also shows how the light incident from a curved incident surface portion and emitted from an OH emission surface portion travels. It is explanatory drawing which shows the irradiation lens of the 5th low beam unit in a vertical cross section, and also shows how the light which is reflected by the reflection surface and is emitted from the OH emission surface portion progresses. It is explanatory drawing which shows the d pattern part of the 5th light distribution pattern. It is explanatory drawing which shows the e-pattern part of the 5th light distribution pattern. It is explanatory drawing which shows the 5th light distribution pattern. The irradiation lens of the right side high beam unit (left side high beam unit) is shown in a cross section, and it is an explanatory diagram showing how the light incident from the curved incident surface portion and emitted from the central exit surface portion travels. It is explanatory drawing which shows the irradiation lens of the right side high beam unit (the left side high beam unit) in the cross section, and also shows how the light which is reflected by the reflection surface and is emitted from the outer emission surface portion progresses. It is explanatory drawing which shows the irradiation lens of the right side high beam unit (the left side high beam unit) in the cross section, and also shows how the light which is reflected by the reflection surface and is emitted from the inner emission surface portion progresses. It is explanatory drawing which shows the state which the irradiation lens of the right side high beam unit (the left side high beam unit) was seen from the exit surface side. It is explanatory drawing which shows the a pattern part of the 6th light distribution pattern (7th light distribution pattern). It is explanatory drawing which shows the b pattern part of the 6th light distribution pattern (7th light distribution pattern). It is explanatory drawing which shows the c pattern part of the 6th light distribution pattern (7th light distribution pattern). It is explanatory drawing which shows the 6th light distribution pattern (7th light distribution pattern). It is sectional drawing obtained along the IV-IV line of FIG. It is explanatory drawing which shows the irradiation pattern for passing. It is explanatory drawing which shows the irradiation pattern for running.

Hereinafter, the first embodiment of the vehicle lamp 1 as an embodiment of the vehicle lamp according to the present disclosure will be described with reference to FIGS. 1 to 34. It should be noted that in FIGS. 8, 9, 14, 24, 25, and 26 in which each irradiation lens is shown in a cross section, and in FIGS. 19 and 20 in which each irradiation lens is shown in a vertical cross section, it becomes complicated. The hatch showing the cross section is omitted to avoid. In addition, FIG. 3, FIG. 5, FIG. 7, FIG. 11, FIG. 12, FIG. 13, FIG. 16, FIG. 17, FIG. 18, FIG. 21, FIG. 22, FIG. 23, and FIG. 28 showing each light distribution pattern or each irradiation pattern. 29, 30, FIG. 31, FIG. 33, FIG. 34 show that the distribution of brightness is medium on the screen where the horizontal line H and the vertical line V intersect with the center position O of the irradiation by the vehicle lamp 1 as the origin. It is shown as a contour line where the brightness increases toward. In each of the figures shown on the screen, the angle centered on the horizon H (+ on the upper side) is shown at the right end, and the angle centered on the vertical line V (+ on the right side) is shown at the lower end.

The vehicle lighting tool 1 is used as a lighting tool used for a vehicle such as an automobile, and is used for, for example, a head lamp, a fog lamp, or the like. The vehicle lamp 1 has a unit group 2 (see FIG. 1) composed of a plurality of units (10, 20, 30, 40, 50, 60, 70). The vehicle lighting fixture 1 has a unit group 2 on both the left and right sides of the front part of the vehicle, and a lamp chamber in which the open front end of the lamp housing is covered with an outer lens. It is provided via the optical axis adjustment mechanism. In the following description, in the vehicle lighting tool 1, the direction of irradiating light is the front-rear direction (Z in the drawing), and the vertical direction when the front-rear direction is along the horizontal plane is the vertical direction (Y in the drawing). ), And the direction (horizontal direction) orthogonal to the front-back direction and the up-down direction is the left-right direction (X in the drawing). The front side in the front-rear direction points to the front of the vehicle in the vehicle lamp 1.

As shown in FIG. 1, the vehicle lighting fixture 1 has a first low beam unit 10, a second low beam unit 20, a third low beam unit 30, a fourth low beam unit 40, a fifth low beam unit 50, and a right high beam in the unit group 2. A unit 60 and a left high beam unit 70 are provided. This vehicle lighting tool 1 forms an irradiation pattern LP for passing (see FIG. 33) by lighting five low beam units (10, 20, 30, 40, 50) at the same time, and two high beam units (60, 70). ) Are simultaneously lit to form a traveling irradiation pattern HP (see FIG. 34), which will be described later. When forming the traveling irradiation pattern HP, the vehicle lighting tool 1 also forms the passing irradiation pattern LP. The seven units substantially coincide with the center position O (the center position of irradiation by the vehicle lamp 1) on the screen in which the lens axes are arranged so as to be orthogonal to each other in the front-rear direction. The lens axis is the optical center axis of each unit. In the following, the one of the first low beam unit 10 will be referred to as the lens axis La1, the one of the second low beam unit 20 will be referred to as the lens axis La2, and the one of the third low beam unit 30 will be referred to as the lens axis La3. The fourth low beam unit 40 is the lens axis La4, the fifth low beam unit 50 is the lens axis La5, the right high beam unit 60 is the lens axis La6, and the left high beam unit 70 is the lens axis La7. And.

As shown in FIGS. 1 and 2, the first low beam unit 10 has a light source 11 and an irradiation lens 12. The light source 11 is composed of a light emitting element such as an LED (Light Emitting Diode) and is mounted on the substrate 3. The substrate 3 has a flat plate shape. The substrate 3 of the first embodiment is also mounted with the light sources (21, 31, 41, 51, 61, 71) described later of the remaining units (20 to 70), and corresponds to seven units. It is a flat plate of the size. The light source 11 is appropriately turned on by being supplied with electric power from the lighting control circuit.

The light source 11 is appropriately provided with a heat sink member. The heat sink member is a heat radiating member that releases heat generated by a light source 11 or the like to the outside, and is made of a metal material or a resin material having high thermal conductivity. The heat sink member may not be provided if the substrate 3 can sufficiently release heat to the outside.

The irradiation lens 12 is provided on the emission light axis of the light source 11, and is basically a cylindrical lens that extends in the left-right direction and has a refractive power only in the up-down direction. It has a rectangular shape (see FIG. 1). The irradiation lens 12 has an incident surface 13 facing the light source 11 and an emitting surface 14 facing the opposite side thereof. In the irradiation lens 12 of the first embodiment, the entrance surface 13 and the emission surface 14 are convex surfaces. If the irradiation lens 12 is a convex lens based on a cylindrical lens, the entrance surface 13 and the emission surface 14 may be a flat surface or a concave surface, and are not limited to the configuration of the first embodiment.

The irradiation lens 12 is integrally formed with each irradiation lens (22, 32, 42, 52, 62, 72) described later of each of the remaining units to form a lens body 4 (see FIG. 1). The lens body 4 has a lens surface portion 5 provided with seven irradiation lenses (12 to 72), and a peripheral wall portion 6 extending from the lens surface portion 5 to the rear side in the front-rear direction. The lens surface portion 5 has a rectangular shape when viewed in the front-rear direction, and seven irradiation lenses (12 to 72) are arranged in two upper and lower stages in the left-right direction, and three irradiation lenses (12 to 32) are arranged in the upper stage. Four irradiation lenses (42 to 72) are provided in the lower row, respectively. In this lens surface portion 5, when the portion where the irradiation lens is not provided (upper right in FIG. 1) is used as the reference surface, the upper three irradiation lenses (12 to 32) are projected from the reference surface to the front side in the front-rear direction. The lower two irradiation lenses (42, 52) are projected from the reference plane toward the rear side (light sources 41, 51) in the front-rear direction. The peripheral wall portion 6 has a cylindrical shape extending rearward from the four outer edges of the rectangular lens surface portion 5, and the rear end portion can be addressed to the substrate 3 over the entire circumference. In the lens body 4, the leakage of light and the generation of stray light can be suppressed by appropriately providing a coating film or a coating film that blocks light transmission at locations other than the seven irradiation lenses (12 to 72). In the lens body 4, the screw member 7 passed through the substrate 3 from the rear side is fitted into the screw hole of the lens surface portion 5 in a state where the rear end portion of the peripheral wall portion 6 is addressed to the substrate 3. It is assembled with 3. Then, the irradiation lens 12 is positioned with respect to the light source 11 on the substrate 3 (see FIG. 2).

In the irradiation lens 12, the rear focal point F1 is set in the vicinity of the light source 11 on the substrate 3. The focal length of the irradiation lens 12 (distance to the rear focal length F1) is made larger than the focal lengths of the remaining six irradiation lenses. Further, the irradiation lens 12 has a larger dimension (size) in the vertical direction than the irradiation lenses 22 and 32 of the second low beam unit 20 and the third low beam unit 30. As a result, the irradiation lens 12 can collect the light from the light source 11 within the narrowest range while making the light distribution image of the light source 11 the smallest as compared with each of the remaining irradiation lenses (22 to 72). ..

By irradiating the irradiation lens 12 with the light from the light source 11, a plurality of light distribution images of the light source 11 are appropriately superimposed on the screen at positions corresponding to the optical characteristics. This optical characteristic can be set by adjusting the curvature (plane shape) of the incident surface 13 and the exit surface 14 for each location. Due to the set optical characteristics, the irradiation lens 12 arranges each light distribution image in a substantially horizontal direction in the vicinity of the center position O (lens axis La1) on the screen, and two horizontal cut-off lines at their upper edges. Shall be connected in a slanted cut offline.

The first low beam unit 10 irradiates the light from the light source 11 with the irradiation lens 12 to form the first low light distribution pattern LP1 on the screen as shown in FIG. This first low light distribution pattern LP1 has a cut-off line CL from a horizontal cut-off line to a horizontal cut-off line in the vicinity of the center position O, and the difference in brightness from the outside (upper side) is clarified. The cut-off line CL is clear. Further, the first low light distribution pattern LP1 is a condensing pattern that is brightened by collecting the light from the light source 11 within a narrow range, and is the brightest in the vicinity of the center position O in the passing irradiation pattern LP. Corresponds to the demand.

As described above, the first low beam unit 10 is a first unit (direct irradiation type unit) that directly emits the light incident from the light source 11 from the irradiation lens 12. Therefore, the light source 11 becomes a first light source (direct irradiation light source), and the irradiation lens 12 becomes a first irradiation lens (direct irradiation type irradiation lens).

The second low beam unit 20 has a light source 21 and an irradiation lens 22 as shown in FIGS. 1 and 4. The light source 21 is composed of a light emitting element such as an LED, is mounted on the same substrate 3 as the above light source 11, and is appropriately lit by being supplied with electric power from a lighting control circuit. The irradiation lens 22 is basically a cylindrical lens that extends in the left-right direction and has a refractive power only in the up-down direction, and is a convex lens with a cross section orthogonal to the left-right direction. The irradiation lens 22 has a rectangular shape when viewed from the front, and its size (dimensions) in the vertical direction is smaller than that of the irradiation lens 12 (see FIG. 1). The irradiation lens 22 has an incident surface 23 facing the light source 21 and an emitting surface 24 facing the opposite side thereof. In the irradiation lens 22 of the first embodiment, the entrance surface 23 and the emission surface 24 are convex surfaces. If the irradiation lens 22 is a convex lens based on a cylindrical lens, the incident surface 23 and the exit surface 24 may be a flat surface or a concave surface, and the configuration is not limited to the first embodiment.

The irradiation lens 22 is provided on the emission light axis of the light source 21, and the rear focal point F2 is set in the vicinity of the light source 21 on the substrate 3 in a state where the lens body 4 is assembled with the substrate 3. The focal length of the irradiation lens 22 (distance to the rear focal length F2) is smaller than the focal length of the irradiation lens 12 and larger than the focal lengths of the remaining five irradiation lenses (32 to 72). In this irradiation lens 22, the light source 21 is mounted on the same substrate 3 as the light source 11, and is provided on the substrate 3 side, that is, on the rear side in the front-rear direction as compared with the irradiation lens 12. Is also in the retracted position (see Fig. 1). As a result, the irradiation lens 22 irradiates the light from the light source 21 while making the light distribution image of the light source 21 larger than that of the irradiation lens 12 and smaller than the remaining five irradiation lenses (32 to 72). It has a wider range than the lens 12, and can be collected within a narrow range as compared with the remaining five irradiation lenses.

By irradiating the light from the light source 21, the irradiation lens 22 forms a plurality of light distribution images of the light source 21 on the screen at positions corresponding to the optical characteristics. This optical characteristic can be set by adjusting the curvature (plane shape) of the incident surface 23 and the exit surface 24 for each location. Due to the set optical characteristics, the irradiation lens 22 has a first low arrangement in which the light distribution images are arranged in a substantially horizontal direction while the upper edge is positioned near the center position O (lens axis La2) on the screen. The light is focused in a larger range in the horizontal direction than the optical pattern LP1.

As a result, the second low beam unit 20 irradiates the light from the light source 21 with the irradiation lens 22 to form the second low light distribution pattern LP2 on the screen as shown in FIG. This second row light distribution pattern LP2 spreads horizontally and extends substantially horizontally from the first row light distribution pattern LP1 in the vicinity of the center position O, and forms a part of the cut-off line CL at the upper edge. .. Further, the second low light distribution pattern LP2 is a condensing pattern that is brightened by collecting the light from the light source 21 within a narrow range, and can brighten the vicinity of the center position O in the passing irradiation pattern LP. It corresponds to the demand.

As described above, the second low beam unit 20 is a first unit (direct irradiation type unit) that directly emits the light incident from the light source 21 from the irradiation lens 22. Therefore, the light source 21 becomes a first light source (direct irradiation light source), and the irradiation lens 22 becomes a first irradiation lens (direct irradiation type irradiation lens).

As shown in FIGS. 1 and 6, the third low beam unit 30 has a light source 31 and an irradiation lens 32. The light source 31 is composed of a light emitting element such as an LED, is mounted on the same substrate 3 as both of the above light sources (11, 21), and is appropriately lit by being supplied with electric power from a lighting control circuit. The irradiation lens 32 is provided on the emission light axis of the light source 31, and is basically a cylindrical lens that extends in the left-right direction and has a refractive power only in the up-down direction, and is a convex lens with a cross section orthogonal to the left-right direction. The irradiation lens 32 has a rectangular shape when viewed from the front, and its size (dimensions) in the vertical direction is smaller than that of the irradiation lens 22 (see FIG. 1). The irradiation lens 32 has an incident surface 33 facing the light source 31 and an emitting surface 34 facing the opposite side thereof. In the irradiation lens 32 of the first embodiment, the entrance surface 33 and the emission surface 34 are convex surfaces. If the irradiation lens 32 is a convex lens based on a cylindrical lens, the entrance surface 33 and the emission surface 34 may be a flat surface or a concave surface, and the configuration is not limited to the first embodiment.

In the irradiation lens 32, the rear focal point F3 is set in the vicinity of the light source 31 on the substrate 3 in a state where the lens body 4 is assembled with the substrate 3. The focal length of the irradiation lens 32 (distance to the rear focal length F3) is smaller than the focal length of the irradiation lens 22 and larger than the focal lengths of the remaining four irradiation lenses (42 to 72). In the irradiation lens 32, the light source 31 is mounted on the same substrate 3 as the light sources 11 and 21, and is provided on the substrate 3 side, that is, on the rear side in the front-rear direction as compared with the irradiation lenses 12 and 22. It is provided at a position retracted from the irradiation lenses 12 and 22 (see FIG. 1). As a result, the irradiation lens 32 allows the light from the light source 31 to be emitted while making the light distribution image of the light source 31 larger than the irradiation lenses 12 and 22 and smaller than the remaining four irradiation lenses (42 to 72). , It is a wider range than the irradiation lenses 12 and 22, and can be collected within a narrow range as compared with the remaining four irradiation lenses (42 to 72).

By irradiating the irradiation lens 32 with the light from the light source 31, a plurality of light distribution images of the light source 31 are appropriately superimposed on the screen at positions corresponding to the optical characteristics. This optical characteristic can be set by adjusting the curvature (plane shape) of the incident surface 33 and the exit surface 34 for each location. Due to the set optical characteristics, the irradiation lens 32 arranges each light distribution image in a substantially horizontal direction while locating the upper edge in the vicinity of the center position O (lens axis La3) on the screen, and arranges the second row. Irradiate a larger area in the horizontal direction than the optical pattern LP2 (see FIG. 5).

As a result, the third low beam unit 30 irradiates the light from the light source 31 with the irradiation lens 32 to form the third low light distribution pattern LP3 on the screen as shown in FIG. 7. The third row light distribution pattern LP3 extends substantially horizontally below the center position O and extends more horizontally than the second row light distribution pattern LP2, and forms a part of the cut-off line CL at the upper edge. .. Further, the third low light distribution pattern LP3 is a condensing pattern that is brightened by collecting the light from the light source 31 within a predetermined range, and brightens the vicinity of the center position O in the passing irradiation pattern LP. Corresponds to the demand.

As described above, the third low beam unit 30 is a first unit (direct irradiation type unit) that directly emits the light incident from the light source 31 from the irradiation lens 32. Therefore, the light source 31 becomes a first light source (direct irradiation light source), and the irradiation lens 32 becomes a first irradiation lens (direct irradiation type irradiation lens).

The fourth low beam unit 40 has a light source 41 and an irradiation lens 42, as shown in FIGS. 1 and 6. The light source 41 is composed of a light emitting element such as an LED, is mounted on the same substrate 3 as the above three light sources (11 to 31), and is appropriately lit by being supplied with electric power from a lighting control circuit. The irradiation lens 42 is provided on the emission light axis of the light source 41, is a convex lens, and has a circular shape when viewed from the front (see FIG. 1). The irradiation lens 42 has an incident surface 43 facing the corresponding light source 41 and an emitting surface 44 facing the opposite side. As shown in FIGS. 8 and 9, the incident surface 43 has a curved incident surface portion in which the central portion is recessed inside the irradiation lens 42 (the side opposite to the light source 41) and is convexly curved outward at the center thereof. It has a 43a and an annular incident surface portion 43b surrounding the 43a. Further, around the incident surface 43, a truncated cone-shaped reflecting surface 43c surrounding the annular incident surface portion 43b is provided.

As shown in FIG. 8, the curved incident surface portion 43a faces the light source 41 in the optical axis direction in a state where the lens body 4 is assembled with the substrate 3, and the light source 41 is located in the vicinity of the rear focal point F4 on the rear side. Is located. The focal length (distance to the rear focal length F4) of the irradiation lens 42 (curved incident surface portion 43a) is smaller than the focal length of the irradiation lens 32. In this irradiation lens 42, the light source 41 is mounted on the same substrate 3 as each light source (11 to 31), and is provided on the substrate 3 side, that is, on the rear side in the front-rear direction as compared with each irradiation lens (12 to 32). The lens body 4 is provided at a position retracted from the irradiation lens (12 to 32) (see FIG. 1). The curved incident surface portion 43a causes the light emitted from the light source 41 to enter the irradiation lens 42 as parallel light traveling in parallel with the lens axis La4. The parallel light (parallel light) refers to light in a collimated state as the light passes through the curved incident surface portion 43a.

As shown in FIG. 9, the annular incident surface portion 43b is provided so as to project toward the light source 41, and the light from the light source 41 that does not travel to the curved incident surface portion 43a is incident on the irradiation lens 42. .. The reflective surface 43c is formed at a position where the light incident on the irradiation lens 42 from the annular incident surface portion 43b travels. When the light incident from the annular incident surface portion 43b is reflected, the reflecting surface 43c is a parallel light traveling in parallel with the lens axis La4. The reflective surface 43c may reflect light by utilizing total reflection, or may reflect light by adhering aluminum, silver, or the like by vapor deposition, painting, or the like. From these facts, the incident surface 43 causes the light emitted from the light source 41 to travel in the irradiation lens 42 as parallel light traveling in parallel with the lens axis La4, and guides the light to the emitting surface 44.

The emission surface 44 emits light incident from the incident surface 43 to be parallel light toward the front side in the front-rear direction. As shown in FIG. 10, the emission surface 44 has a circular shape when viewed from the front, and has a central emission surface portion 44a, an upper emission surface portion 44b, and a lower emission surface portion 44c having different optical settings. As shown in FIG. 8, the central exit surface portion 44a is provided in a region near the center of the emission surface 44 where light traveling through the curved incident surface portion 43a travels. The central exit surface portion 44a of the first embodiment has a rectangular shape when viewed from the front. The central emission surface portion 44a is recessed inside the irradiation lens 42 (incident surface 43 side) from the upper emission surface portion 44b and the lower emission surface portion 44c, and the difference from the lower emission surface portion 44c in the front-rear direction is a depth d1. It is said that. The central exit surface portion 44a refracts the light that has been made parallel light through the curved incident surface portion 43a, so that the light is largely diffused in the left-right direction and travels toward the front side in the front-rear direction.

The central exit surface portion 44a irradiates light from the light source 41 through the curved incident surface portion 43a to form a plurality of light distribution images of the light source 41 on the screen at positions corresponding to the optical characteristics. This optical characteristic can be set by adjusting the curvature (plane shape) of the central exit surface portion 44a for each location, and in the first embodiment, the curvature is gradually changed. Due to the set optical characteristics, the central emission surface portion 44a arranges the light distribution images in the substantially horizontal direction while locating the upper edge in the vicinity of the center position O (lens axis La4) on the screen, and arranges the light distribution images in the third row. The light distribution pattern is diffused in a larger range than LP3 (see FIG. 7).

As shown in FIG. 10, the central exit surface portion 44a of the first embodiment is provided with a diffusion portion 44d on the surface. The diffusion portion 44d is formed by arranging at least one of a concave portion and a convex portion extending in the vertical direction side by side. There is. The diffusion unit 44d uniformly diffuses the light (light ray group) emitted from the central emission surface portion 44a in the left-right direction (widens the distance between the traveling directions). Therefore, the central exit surface portion 44a irradiates the light passing through the curved incident surface portion 43a along the above optical characteristics while receiving the auxiliary action of the diffusion portion 44d.

As a result, as shown in FIG. 11, the central emission surface portion 44a forms an a pattern portion Pp4a that is a part of the fourth low light distribution pattern LP4 (see FIG. 13) on the screen. This a pattern portion Pp4a extends in a substantially horizontal direction below the center position O and is diffused in a larger range than the third row light distribution pattern LP3, whereby the overall shape of the fourth row light distribution pattern LP4 ( The outer shape) is formed and the entire area is irradiated.

As shown in FIGS. 8 to 10, the upper emission surface portion 44b is a region surrounding the central emission surface portion 44a and is provided on substantially the upper half of the emission surface 44, and is located on the substantially upper half of the curved incident surface portion 43a. It is located in a region where the light reflected by the reflecting surface 43c travels. The upper emission surface portion 44b is located (projected) outside the irradiation lens 42 by a depth d1 from the central emission surface portion 44a. The surface of the upper emission surface portion 44b is provided with a diffusion portion 44d similar to the central emission surface portion 44a, and the emitted light is auxiliary diffused in the left-right direction and made uniform.

The lower emission surface portion 44c is a region surrounding the central emission surface portion 44a and is provided in substantially the lower half of the emission surface 44, and the light reflected by the reflection surface 43c located in the substantially lower half of the curved incident surface portion 43a is emitted. It is located in the area of progress. The lower emission surface portion 44c is located (projected) outside the irradiation lens 42 with respect to the central emission surface portion 44a. The surface of the lower emission surface portion 44c is provided with a diffusion portion 44d similar to the central emission surface portion 44a, and the emitted light is auxiliary diffused in the left-right direction and made uniform. The diffusion portion 44d has a knurled shape that is continuous in the vertical direction straddling the central exit surface portion 44a, the upper emission surface portion 44b, and the lower emission surface portion 44c, and has a unified appearance over the entire emission surface 44. ..

The upper emission surface portion 44b and the lower emission surface portion 44c each irradiate light that is reflected from the light source 41 by the reflection surface 43c to be parallel light, so that the light source is located at a position corresponding to the optical characteristics on the screen. A plurality of light distribution images of 41 are appropriately superimposed and formed. Each optical characteristic can be set by adjusting the curvature (plane shape) of the upper emitting surface portion 44b and the lower emitting surface portion 44c for each location, and in Example 1, those curvatures are gradually changed and set. There is. Both emission surface portions (44b, 44c) have optical characteristics of diffusing light into a range of the same shape with the same brightness distribution on the screen, and the ranges irradiated by each other are set to the same height position. The inclination in the vertical direction is different. Therefore, both emission surface portions (44b, 44c) are abbreviated as a range in which a pattern portion Pp4a (see FIG. 11) is formed by arranging each light distribution image in a substantially horizontal direction below the center position O on the screen. Spread over the same area so that they overlap each other.

As a result, both emission surface portions (44b, 44c) form a b pattern portion Pp4b on the screen, which is another part of the fourth low light distribution pattern LP4 (see FIG. 13), as shown in FIG. .. This b pattern portion Pp4b extends in a substantially horizontal direction in the vicinity of the center position O, and is diffused in a larger range than the third low light distribution pattern LP3 (see FIG. 7) to illuminate the entire area. The brightness distribution in the fourth row light distribution pattern LP4 is formed.

The fourth low beam unit 40 irradiates the light from the light source 41 with the irradiation lens 42 and superimposes the a pattern portion Pp4a and the b pattern portion Pp4b on the screen, so that the fourth low beam unit 40 is as shown in FIG. The light distribution pattern LP4 is formed. The fourth row light distribution pattern LP4 is a diffusion pattern that extends substantially horizontally below the center position O and is diffused in a larger range than the third row light distribution pattern LP3. Therefore, the fourth low beam unit 40 can diffuse the light from the light source 41 in a wider range than each of the above low beam units (10 to 30) by setting the irradiation lens 42 as described above.

As described above, the fourth low beam unit 40 directly emits a part of the light incident from the light source 41 from the irradiation lens 42, and reflects the other part of the light inside the irradiation lens 42 and then emits the desired light. It is a second unit (direct reflection type unit) that forms a light distribution pattern (LP4). Therefore, the light source 41 becomes a second light source (direct reflection light source), and the irradiation lens 42 becomes a second irradiation lens (direct reflection type irradiation lens). Then, in the fourth low beam unit 40, the light passing through the curved incident surface portion 43a becomes the direct light directly directed to the exit surface 44, and the light reflected by the reflecting surface 43c via the annular incident surface portion 43b is internally reflected. It becomes the reflected light toward the exit surface 44.

As shown in FIGS. 1 and 4, the fifth low beam unit 50 has a light source 51 and an irradiation lens 52. The light source 51 is composed of a light emitting element such as an LED, is mounted on the same substrate 3 as the above four light sources (11 to 41), and is appropriately lit by being supplied with electric power from a lighting control circuit. The irradiation lens 52 is provided on the emission light axis of the light source 51, is a convex lens, and has a circular shape when viewed from the front (see FIG. 1). The irradiation lens 52 has an incident surface 53 facing the corresponding light source 51 and an emitting surface 54 facing the opposite side. As shown in FIG. 14, the incident surface 53 has a curved incident surface portion 53a whose central portion is recessed inside the irradiation lens 52 (the side opposite to the light source 51) and which is convexly curved outward at the center thereof. It has an annular incident surface portion 53b surrounding it. Further, around the incident surface 53, a truncated cone-shaped reflecting surface 53c surrounding the annular incident surface portion 53b is provided.

The curved incident surface portion 53a faces the light source 51 in the optical axis direction in a state where the lens body 4 is assembled with the substrate 3, and the light source 51 is located in the vicinity of the rear focal point F5 on the rear side. The focal length of the irradiation lens 52 (distance to the rear focal length F5) is substantially equal to the focal length of the irradiation lens 42. The irradiation lens 52 is provided at a position retracted from the above-mentioned three irradiation lenses (12 to 32) in the lens body 4 in the front-rear direction and at a position substantially equal to the irradiation lens 42. The curved incident surface portion 53a causes the light emitted from the light source 51 to enter the irradiation lens 52 as parallel light traveling substantially parallel to the lens axis La5. The annular incident surface portion 53b is provided so as to project toward the light source 51, and the light from the light source 51 that does not travel to the curved incident surface portion 53a is incident on the irradiation lens 52.

The reflective surface 53c is formed at a position where the light incident on the irradiation lens 52 from the annular incident surface portion 53b travels. When the light incident from the annular incident surface portion 53b is reflected, the reflecting surface 53c is focused so as to be slightly closer to the lens axis La5 than parallel to the lens axis La5. The reflective surface 53c may reflect light by utilizing total reflection, or may reflect light by adhering aluminum, silver, or the like by vapor deposition, painting, or the like.

The emitting surface 54 emits the light incident from the incident surface 53 to the front side in the front-rear direction. As shown in FIG. 15, the emission surface 54 has a circular shape when viewed from the front, and has a central emission surface portion 54a, an upper emission surface portion 54b, a lower emission surface portion 54c, and an OH (overhead) emission surface portion having different optical settings. It has 54d and. The central exit surface portion 54a is provided in a region near the center of the emission surface 54 where most of the light passing through the curved incident surface portion 53a travels. The central exit surface portion 54a of the first embodiment has a rectangular shape when viewed from the front. As shown in FIG. 14, the central emission surface portion 54a is recessed inside the irradiation lens 52 (light source 51 side) from the upper emission surface portion 54b and the lower emission surface portion 54c, and the difference in the front-rear direction is the depth d2. It is said that. This depth d2 is made larger than the depth d1 (see FIG. 8) of the central exit surface portion 44a on the emission surface 44. The central exit surface portion 54a refracts the light that has been made parallel light through the curved incident surface portion 53a, so that the light is largely diffused in the left-right direction and travels toward the front side in the front-rear direction. As a result, the irradiation lens 52 can diffuse the light from the light source 51 in a wider range than the irradiation lens 42.

The central emission surface portion 54a irradiates light from the light source 51 through the curved incident surface portion 53a to form a plurality of light distribution images of the light source 51 on the screen at positions corresponding to the optical characteristics. This optical characteristic can be set by adjusting the curvature (plane shape) of the central exit surface portion 54a for each location, and in the first embodiment, the curvature is gradually changed. Due to the set optical characteristics, the central emission surface portion 54a arranges each light distribution image in a substantially horizontal direction below the center position O (lens axis La5) on the screen, and the third low light distribution pattern LP3 (FIG. 7). See) Spread over a larger area.

As shown in FIG. 15, the central exit surface portion 54a of the first embodiment is provided with a diffusion portion 54e. The diffusion portion 54e is formed by arranging at least one of a concave portion and a convex portion extending in the vertical direction side by side. There is. The diffusing portion 54e auxiliary diffuses the light emitted from the central emitting surface portion 54a in the left-right direction and makes it uniform. Therefore, the central exit surface portion 54a irradiates the light passing through the curved incident surface portion 53a along the above optical characteristics while receiving the auxiliary action of the diffusion portion 54e.

As a result, as shown in FIG. 16, the central emission surface portion 54a forms an a pattern portion Pp5a that is a part of the fifth low light distribution pattern LP5 (see FIG. 23) on the screen. The a pattern portion Pp5a extends in a substantially horizontal direction below the center position O, is diffused in a larger range than the fourth low light distribution pattern LP4, and irradiates the entire area.

As shown in FIGS. 14 and 15, the upper emission surface portion 54b is a region surrounding the central emission surface portion 54a and is provided in substantially the upper half of the emission surface 54, and is located in the substantially upper half of the curved incident surface portion 53a. Most of the light reflected by the reflecting surface 53c is located in the traveling region. The upper emission surface portion 54b protrudes to the outside of the irradiation lens 52 by a depth d2 from the central emission surface portion 54a. The upper emission surface portion 54b is provided with a diffusion portion 54e similar to the central emission surface portion 54a, and the emitted light is auxiliary diffused in the left-right direction and made uniform.

The upper emission surface portion 54b irradiates light reflected from the light source 51 by substantially the upper half of the reflection surface 53c to form parallel light, whereby a plurality of light sources 51 are arranged at positions on the screen according to optical characteristics. The optical images are appropriately superimposed and formed. The optical characteristics can be set by adjusting the curvature (plane shape) of the upper emitting surface portion 54b for each location, and in the first embodiment, the curvature is gradually changed and set. Due to the set optical characteristics, the upper emission surface portion 54b arranges the light distribution images substantially horizontally below the center position O on the screen and diffuses them in a range substantially equal to the a pattern portion Pp5a.

As a result, the upper emission surface portion 54b forms a b pattern portion Pp5b on the screen, which is another part of the fifth low light distribution pattern LP5 (see FIG. 23), as shown in FIG. This b pattern portion Pp5b extends in a substantially horizontal direction in the vicinity of the center position O, and is diffused in a range substantially equal to that of the a pattern portion Pp5a, so that the entire area is illuminated and the inside of the fifth low light distribution pattern LP5. Form a brightness distribution of.

As shown in FIGS. 14 and 15, the lower emission surface portion 54c is a region surrounding the central emission surface portion 54a and is provided in substantially the lower half of the emission surface 54, and is located in the substantially lower half of the curved incident surface portion 53a. It is located in the region where the light reflected by the reflecting surface 53c travels. The lower emission surface portion 54c protrudes to the outside of the irradiation lens 52 by a depth d2 from the central emission surface portion 54a and the lower emission surface portion 54c. The lower emission surface portion 54c is provided with a diffusion portion 54e similar to the central emission surface portion 54a, and the emitted light is auxiliary diffused in the left-right direction and made uniform.

The lower emission surface portion 54c is irradiated with light that is reflected from the light source 51 by substantially the lower half of the reflection surface 53c to be parallel light, so that a plurality of light sources 51 are positioned on the screen according to the optical characteristics. The light distribution images are appropriately superimposed and formed. The optical characteristics can be set by adjusting the curvature (plane shape) of the lower emitting surface portion 54c for each location, and in the first embodiment, the curvature is gradually changed and set. Due to the set optical characteristics, the lower emission surface portion 54c diffuses the light distribution images below the center position O in a substantially horizontal direction on the screen and diffuses below the a pattern portion Pp5a and the b pattern portion Pp5b. Let me.

As a result, the lower emission surface portion 54c forms a c-pattern portion Pp5c on the screen, which is another part of the fifth low light distribution pattern LP5 (see FIG. 23), as shown in FIG. The c-pattern portion Pp5c extends substantially horizontally below the center position O, and is spread over a range substantially equal to the a-pattern portion Pp5a in the horizontal direction and a wider range than the a-pattern portion Pp5a in the vertical direction. As a result, the brightness distribution in the fifth row light distribution pattern LP5 is formed while illuminating the entire area.

As shown in FIG. 15, the OH emission surface portion 54d is provided above the central emission surface portion 54a on the emission surface 54 and inside the upper emission surface portion 54b. In Example 1, the central emission surface portion is viewed from the front. It has a rectangular shape with 54a extended upward. As shown in FIGS. 19 and 20, the OH emitting surface portion 54d includes a part of light (direct light) passing through the curved incident surface portion 53a and a part of light (reflected light) reflected by the reflecting surface 53c. It is located in the area of progress. Specifically, the OH emission surface portion 54d is located in a region where light that has passed through the upper portion of the curved incident surface portion 53a, that is, light that has passed through the curved incident surface portion 53a and does not travel to the central exit surface portion 54a, travels. See FIG. 19). Further, the OH emitting surface portion 54d is reflected by the light reflected by a part of the reflecting surface 53c above the annular incident surface portion 53b (curved incident surface portion 53a) (hereinafter referred to as the OH reflecting surface portion 53d), that is, the reflecting surface 53c. It is located in a region where light that does not travel to the upper emission surface portion 54b of the light that has traveled travels (see FIG. 20).

In the vertical cross section, the OH exit surface portion 54d is recessed rearward in the front-rear direction with respect to the upper end of the central exit surface portion 54a, and is inclined so as to be displaced forward as it goes upward, and the upper exit surface portion 54b. It is a continuous flat surface at the lower end of. Therefore, the OH emission surface portion 54d is partially recessed in the emission surface 54 of the irradiation lens 52. The OH emission surface portion 54d refracts parallel light traveling substantially parallel to the lens axis La5 upward as compared with the case where the parallel light is emitted from the central emission surface portion 54a. The OH emission surface portion 54d is provided with a diffusion portion 54e similar to the central emission surface portion 54a, and diffuses the emitted light in the left-right direction to make it uniform. The diffusion portion 54e has a knurled shape that is continuous in the vertical direction straddling the central emission surface portion 54a, the upper emission surface portion 54b, the lower emission surface portion 54c, and the OH emission surface portion 54d, and is unified over the entire emission surface 54. It has a nice appearance.

As shown in FIG. 19, the OH emission surface portion 54d irradiates light from the light source 51 through the upper portion of the curved incident surface portion 53a, so that the light source 51 is positioned on the screen according to the optical characteristics of the curved incident surface portion 53a. A plurality of light distribution images are appropriately superimposed and formed. This optical characteristic can be set by adjusting the curvature (plane shape) of the OH reflecting surface portion 53d for each location, and is made substantially flat in Example 1. The OH emitting surface portion 54d emits light that has passed through the curved incident surface portion 53a toward a position at about 4 degrees above the center position O on the screen, and diffuses the light so as to spread in the horizontal direction. As a result, as shown in FIG. 21, the OH emission surface portion 54d forms a d pattern portion Pp5d which is another part of the fifth low light distribution pattern LP5 (see FIG. 23) on the screen. This d-pattern portion Pp5d is diffused in a range of about 5 degrees in the vertical direction centered on a position of about 4 degrees above the center position O, and a range slightly exceeding about 8 degrees in the horizontal direction centered on the vertical line V. Diffuse with and irradiate.

Further, as shown in FIG. 20, the OH emitting surface portion 54d is irradiated with the light reflected by the OH reflecting surface portion 53d from the light source 51, so that the OH emitting surface portion 54d is positioned on the screen according to the optical characteristics of the OH reflecting surface portion 53d. A plurality of light distribution images of the light source 51 are appropriately superimposed and formed. This optical characteristic can be set by adjusting the curvature (plane shape) of the OH reflecting surface portion 53d for each location, and is made substantially flat in Example 1. The OH emitting surface portion 54d emits the light reflected by the OH reflecting surface portion 53d toward a position approximately 2 degrees above the center position O on the screen, and diffuses the light so as to spread in the horizontal direction. As a result, as shown in FIG. 22, the OH emission surface portion 54d forms an e-pattern portion Pp5e which is another part of the fifth low light distribution pattern LP5 (see FIG. 23) on the screen. This e-pattern portion Pp5e is diffused in a range of about 5 degrees in the vertical direction around a position of about 2 degrees above the center position O, and a range slightly exceeding about 8 degrees in the horizontal direction around the vertical line V. Diffuse with and irradiate.

The fifth low beam unit 50 irradiates the light from the light source 51 with the irradiation lens 52 to display the a pattern portion Pp5a, the b pattern portion Pp5b, the c pattern portion Pp5c, the d pattern portion Pp5d, and the e pattern portion Pp5e on the screen. Layer on. Then, as shown in FIG. 23, the fifth low light distribution pattern LP5 is formed on the screen. The fifth row light distribution pattern LP5 is substantially horizontal in a range larger than each row light distribution pattern (LP1 to LP4) below the center position O by the a pattern portion Pp5a, the b pattern portion Pp5b, and the c pattern portion Pp5c. It is a diffusion pattern extending in the directional and vertical directions. As a result, visibility over a wide range can be ensured. Further, the fifth low light distribution pattern LP5 has a range of about 8 degrees centered on a position of about 2 degrees and a position of about 4 degrees above the center position O by the d pattern portion Pp5d and the e pattern portion Pp5e. It extends almost horizontally in a range slightly beyond. As a result, the d-pattern portion Pp5d and the e-pattern portion Pp5e become an OH (overhead) light distribution pattern portion OHP that illuminates an upper sign or the like, and upper visibility from the own vehicle can be ensured.

As described above, the fifth low beam unit 50 directly emits a part of the light incident from the light source 51 from the irradiation lens 52, and reflects the other part of the light inside the irradiation lens 52 before emitting the desired light. It is a second unit (direct reflection type unit) that forms a light distribution pattern (LP5). Therefore, the light source 51 becomes a second light source (direct reflection light source), and the irradiation lens 52 becomes a second irradiation lens (direct reflection type irradiation lens). Then, in the fifth low beam unit 50, the light passing through the curved incident surface portion 53a becomes direct light directly directed to the exit surface 54, and the light reflected by the reflecting surface 53c via the annular incident surface portion 53b is internally reflected. It becomes the reflected light toward the exit surface 54.

The right high beam unit 60 has a light source 61 and an irradiation lens 62 as shown in FIGS. 1 and 2. The light source 61 is composed of a light emitting element such as an LED, is mounted on the same substrate 3 as the above five light sources (11 to 51), and is appropriately lit by being supplied with electric power from a lighting control circuit. The irradiation lens 62 is provided on the emission light axis of the light source 61, is a convex lens, and has a circular shape when viewed from the front (see FIG. 1). The irradiation lens 62 has an incident surface 63 facing the corresponding light source 61 and an emitting surface 64 facing the opposite side. As shown in FIGS. 24 to 26, the incident surface 63 has a curved incident surface portion whose central portion is recessed inside the irradiation lens 62 (on the side opposite to the light source 61) and which is convexly curved outward at the center thereof. It has a 63a and an annular incident surface portion 63b surrounding the 63a. Further, around the incident surface 63, a truncated cone-shaped reflecting surface 63c surrounding the annular incident surface portion 63b is provided.

The curved incident surface portion 63a, the annular incident surface portion 63b, and the reflecting surface 63c have the same design concept as the curved incident surface portion 43a, the annular incident surface portion 43b, and the reflecting surface 43c of the irradiation lens 42 of the fourth low beam unit 40. Therefore, the curved incident surface portion 63a faces the light source 61 in the optical axis direction in a state where the lens body 4 is assembled with the substrate 3, and the light source 61 is located in the vicinity of the rear focal point F6 on the rear side. .. The focal length of the irradiation lens 62 (distance to the rear focal length F6) is substantially equal to the focal length of the irradiation lens 42 and the irradiation lens 52. The irradiation lens 62 is provided at a position retracted from the above-mentioned three irradiation lenses (12 to 32) in the lens body 4 in the front-rear direction, and is provided at a position substantially equal to the irradiation lens 42 and the irradiation lens 52.

As shown in FIG. 24, the curved incident surface portion 63a causes the light emitted from the light source 61 to enter the irradiation lens 62 as parallel light traveling substantially parallel to the lens axis La6. As shown in FIGS. 25 and 26, the annular incident surface portion 63b is provided so as to project toward the light source 61, and the light from the light source 61 that does not travel to the curved incident surface portion 63a is directed to the irradiation lens 62. Make it incident. The reflecting surface 63c reflects the light incident on the irradiation lens 62 from the annular incident surface portion 63b to obtain parallel light traveling substantially parallel to the lens axis La6. From these facts, the incident surface 63 causes the light emitted from the light source 61 to travel in the irradiation lens 62 as parallel light traveling substantially in parallel with the lens axis La6, and guides the light to the emitting surface 64.

The emission surface 64 emits light incident from the incident surface 63 to be substantially parallel light to the front side in the front-rear direction. As shown in FIG. 27, the emission surface 64 has a circular shape when viewed from the front, and has a central emission surface portion 64a, an outer emission surface portion 64b, and an inner emission surface portion 64c having different optical settings. As shown in FIG. 24, the central exit surface portion 64a is provided in a region near the center of the emission surface 64 where light traveling through the curved incident surface portion 63a travels. In the first embodiment, the central exit surface portion 64a has a circular shape when viewed from the front. The central emission surface portion 64a is recessed inside the irradiation lens 62 (light source 61 side) from the outer emission surface portion 64b and the inner emission surface portion 64c, and the difference from the outer emission surface portion 64b in the front-rear direction is defined as a depth d3. There is. This depth d3 is made larger than the depth d1 of the central exit surface portion 44a on the emission surface 44 (see FIG. 8) and the depth d2 of the central exit surface portion 54a on the emission surface 54 (see FIG. 14). Therefore, the central emission surface portion 64a has the largest dent amount among the central emission surface portion 44a and the central emission surface portion 54a. The central exit surface portion 64a refracts light that is made to be substantially parallel light through the curved incident surface portion 63a, so that the light is largely diffused in the left-right direction and travels toward the front side in the front-rear direction.

The central exit surface portion 64a irradiates light from the light source 61 through the curved incident surface portion 63a to be substantially parallel light, whereby a plurality of light distribution images of the light source 61 are appropriately arranged at positions corresponding to optical characteristics on the screen. Form in layers. The optical characteristics can be set by adjusting the curvature (plane shape) of the central exit surface portion 64a for each location, and in the first embodiment, those curvatures are gradually changed and set. On the screen, the central emission surface portion 64a includes the center position O (lens axis La6) and arranges and diffuses each light distribution image in a substantially horizontal direction above the center position O (lens axis La6).

As shown in FIG. 27, the central exit surface portion 64a is provided with a diffusion portion 64d. The diffusion portion 64d is formed by arranging at least one of a concave portion and a convex portion extending in the vertical direction side by side. There is. The diffusing portion 64d auxiliary diffuses the light emitted from the central emitting surface portion 64a in the left-right direction and makes it uniform. Therefore, the central exit surface portion 64a irradiates the light passing through the curved incident surface portion 63a along the above optical characteristics while receiving the auxiliary action of the diffusion portion 64d.

As a result, as shown in FIG. 28, the central emission surface portion 64a forms an a pattern portion Pp6a that is a part of the sixth high light distribution pattern HP6 (see FIG. 31) on the screen. The a pattern portion Pp6a extends in a substantially horizontal direction above the central position O while including the center position O, and irradiates the entire area thereof.

As shown in FIGS. 24 to 27, the outer emission surface portion 64b is provided outside the diffusion portion 64d provided on the outer side in the left-right direction with respect to the central emission surface portion 64a, and is provided at both end portions in the left-right direction. It is located. The outer emitting surface portion 64b is located in a region where the light reflected by the reflecting surfaces 63c located on both ends in the left-right direction of the curved incident surface portion 63a travels. The outer emitting surface portion 64b is located outside the irradiation lens 62, that is, is relatively protruding from the central emitting surface portion 64a and the inner emitting surface portion 64c in the front-rear direction. The outer emitting surface portion 64b collects the light in the vicinity of the center position O on the screen by refracting the light which is regarded as substantially parallel light through the reflecting surface 63c.

The outer emitting surface portion 64b irradiates light reflected from the light source 61 by the reflecting surface 63c to be substantially parallel light, so that a plurality of light distribution images of the light source 61 are arranged at positions on the screen according to the optical characteristics. It is formed by stacking as appropriate. The optical characteristics can be set by adjusting the curvature (plane shape) of the outer emitting surface portion 64b for each location, and in the first embodiment, those curvatures are gradually changed and set. The outer exit surface portions 64b are provided in pairs on the left and right sides, and each of them collects light so as to overlap a narrow range centered slightly above the center position O on the screen.

As a result, as shown in FIG. 29, the outer emission surface portion 64b forms a b pattern portion Pp6b which is another part of the sixth high light distribution pattern HP6 (see FIG. 31) on the screen. The b pattern portion Pp6b is brightened by collecting the light from the light source 61 in a narrow small circular area centered slightly above the center position O, and is in the vicinity of the center position O in the traveling irradiation pattern HP. Corresponds to the demand for brightening.

As shown in FIGS. 24 to 27, the inner emitting surface portion 64c is inside the outer emitting surface portion 64b in the left-right direction and surrounds the central emitting surface portion 64a. The inner emitting surface portion 64c is located in a region where the light reflected by the reflecting surfaces 63c located on both ends in the left-right direction of the curved incident surface portion 63a travels. The inner emitting surface portion 64c is positioned (protruded) outside the irradiation lens 62 from the central emitting surface portion 64a in the front-rear direction, and is recessed inside the irradiation lens 62 from the outer emitting surface portion 64b. The inner emitting surface portion 64c collects the light in the vicinity of the center position O on the screen by refracting the light which is regarded as substantially parallel light through the reflecting surface 63c.

The inner emitting surface portion 64c irradiates light reflected from the light source 61 by the reflecting surface 63c to be substantially parallel light, so that a plurality of light distribution images of the light source 61 are arranged at positions on the screen according to the optical characteristics. It is formed by stacking as appropriate. The optical characteristics can be set by adjusting the curvature (plane shape) of the inner emitting surface portion 64c for each place, and in Example 1, those curvatures are gradually changed and set. The inner emitting surface portion 64c irradiates a wider range than the b pattern portion Pp6b centered slightly above the center position O on the screen. The inner emission surface portion 64c is provided with a diffusion portion 64d (see FIG. 27) similar to the central emission surface portion 64a, and diffuses the emitted light in the left-right direction to make it uniform. The diffusion portion 64d has a knurled shape that is continuous in the vertical direction straddling the central exit surface portion 64a and the inner emission surface portion 64c, and has a unified appearance over the entire emission surface 64.

As a result, as shown in FIG. 30, the inner emission surface portion 64c forms the c pattern portion Pp6c which is another part of the sixth high light distribution pattern HP6 (see FIG. 31) on the screen. The c-pattern portion Pp6c is brightened by collecting the light from the light source 61 in a wider range than the b-pattern portion Pp6b centered slightly above the center position O, and is brightened by the action of the diffusion portion 64d in the left-right direction. It is formed by being diffused into. Therefore, the c-pattern portion Pp6c is diffused in a wide range in the left-right direction from the left and right sides of the center position O while being brightest.

The right side high beam unit 60 irradiates the light from the light source 61 with the irradiation lens 62 and superimposes the a pattern portion Pp6a, the b pattern portion Pp6b, and the c pattern portion Pp6c on the screen, as shown in FIG. , 6th high light distribution pattern HP6 is formed. This sixth high light distribution pattern HP6 is a diffusion pattern that brightens the vicinity of the center position O most, extends from there in a substantially horizontal direction, and is diffused in a large range.

As described above, the right high beam unit 60 directly emits a part of the light incident from the light source 61 from the irradiation lens 62, and reflects the other part of the light inside the irradiation lens 62 before emitting the desired arrangement. It is a third unit (direct reflection type unit) that forms an optical pattern (HP6). Therefore, the light source 61 becomes a third light source (direct reflection light source), and the irradiation lens 62 becomes a third irradiation lens (direct reflection type irradiation lens). Then, in the right high beam unit 60, the light passing through the curved incident surface portion 63a becomes direct light directly directed to the exit surface 64, and the light reflected by the reflecting surface 63c via the annular incident surface portion 63b is internally reflected and then emitted. It becomes the reflected light toward the surface 64.

The left high beam unit 70 has the same configuration as the right high beam unit 60, except that the positions provided are different. As shown in FIGS. 1 and 32, the left side high beam unit 70 has a light source 71 mounted on the substrate 3 and an irradiation lens 72 configured as a part of the lens body 4. The light source 71 is appropriately turned on by being supplied with electric power from the lighting control circuit. The irradiation lens 72 is provided on the emission light axis of the light source 71, is a convex lens, and has a circular shape when viewed from the front (see FIG. 1).

The irradiation lens 72 has an incident surface 73 and an exit surface 74, the incident surface 73 has a curved incident surface portion 73a and an annular incident surface portion 73b, and a reflecting surface 73c is provided around the incident surface 73. .. The curved incident surface portion 73a faces the light source 71 in the optical axis direction in a state where the lens body 4 is assembled with the substrate 3, and the light source 71 is located in the vicinity of the rear focal point F7 on the rear side. The focal length of the irradiation lens 72 (distance to the rear focal length F7) is substantially equal to the focal length of the irradiation lens 62. The irradiation lens 72 is provided at a position retracted from the three irradiation lenses (12 to 32) on the upper side in the vertical direction in the lens body 4 in the front-rear direction and at a position substantially equal to the irradiation lens 62 and the like. The incident surface 73 travels substantially parallel to the lens axis La7 by reflecting the light emitted from the light source 71 on the reflecting surface 73c after passing through the curved incident surface portion 73a or the annular incident surface portion 73b. It is incident on the irradiation lens 72 as light (see FIGS. 24 to 26).

The emission surface 74 has a circular shape when viewed from the front, and has a central emission surface portion 74a, an outer emission surface portion 74b, and an inner emission surface portion 74c having different optical settings (see FIG. 27). The central emission surface portion 74a has the same configuration (including optical characteristics) as the central emission surface portion 64a, the outer emission surface portion 74b as the outer emission surface portion 64b, and the inner emission surface portion 74c as the inner emission surface portion 64c. The central emission surface portion 74a and the inner emission surface portion 74c are provided with a diffusion portion 74d similar to the diffusion portion 64d, and the light emitted from both emission surface portions (74a, 74c) is assisted in the left-right direction. Make it uniform while diffusing. The diffusion portion 74d has a knurled shape that is continuous in the vertical direction straddling the central exit surface portion 74a and the inner emission surface portion 74c, and has a unified appearance over the entire emission surface 74. As a result, the central exit surface portion 74a forms an a pattern portion Pp7a having a shape substantially equal to that of the a pattern portion Pp6a on the screen (see FIG. 28). The outer emission surface portion 74b forms a b-pattern portion Pp7b having a shape substantially equal to that of the b-pattern portion Pp6b (see FIG. 29). The inner emitting surface portion 74c forms a c-pattern portion Pp7c having a shape substantially equal to that of the c-pattern portion Pp6c (see FIG. 30).

The left high beam unit 70 irradiates the light from the light source 71 with the irradiation lens 72, and the a pattern portion Pp7a, the b pattern portion Pp7b, and the c pattern portion Pp7c are overlapped on the screen to form a seventh high light distribution pattern. It forms HP7 (see FIG. 31). The 7th high light distribution pattern HP7 has a shape substantially equal to that of the 6th high light distribution pattern HP6, and is substantially horizontal from the center position O (lens axis La7) while making the vicinity of the center position O brightest. It is a diffusion pattern that extends in the direction and is diffused in a large range.

As described above, the left high beam unit 70 emits a part of the light incident from the light source 71 directly from the irradiation lens 72, and reflects the other part of the light inside the irradiation lens 72 and then emits the desired arrangement. It is a third unit (direct reflection type unit) that forms an optical pattern (HP7). Therefore, the light source 71 becomes a third light source (direct reflection light source), and the irradiation lens 72 becomes a third irradiation lens (direct reflection type irradiation lens). Then, in the left high beam unit 70, the light passing through the curved incident surface portion 73a becomes direct light directly directed to the emitting surface 74, and the light reflected by the reflecting surface 73c via the annular incident surface portion 73b is internally reflected and then emitted. It becomes the reflected light toward the surface 74.

Next, lighting of the vehicle lamp 1 will be described. In each unit (10 to 70) provided in the lighting chamber, the vehicle lighting tool 1 is supplied with electric power from the lighting control circuit to each light source (11 to 71) mounted on the substrate 3, so that each unit (10 to 70) is supplied with electric power. The light sources (11 to 71) are turned on and off as appropriate. When the light sources (11 to 51) of the five low beam units (10 to 50) are turned on, the vehicle lighting tool 1 forms the first to fifth five light distribution patterns (LP1 to LP5) while appropriately overlapping them. As a result, the passing irradiation pattern LP shown in FIG. 33 is formed. This passing irradiation pattern LP illuminates a wide range extending in the horizontal direction while including the center position O, and a cut-off line CL is formed on the upper edge and an OH light distribution pattern portion OHP is formed above the cut-off line CL. ing. Therefore, the vehicle lamp 1 can secure upward visibility from the own vehicle by forming the irradiation pattern LP for passing each other.

Further, when the light sources (61, 71) of the two high beam units (60, 70) are turned on, the vehicle lamp 1 forms two sixth and seventh light distribution patterns (LP6, LP7). By superimposing them, the traveling irradiation pattern HP shown in FIG. 34 is formed. This traveling irradiation pattern HP basically illuminates a wide range extending in the left-right direction above the horizontal direction including the center position O, and the lower portion thereof overlaps with the upper portion of the passing irradiation pattern LP. .. Therefore, the vehicle lighting tool 1 can illuminate a wide range including the height position of an oncoming vehicle occupant or the like by forming the traveling irradiation pattern HP, and visibility can be ensured.

By lighting five low beam units (10 to 50), the vehicle lamp 1 can form a passing irradiation pattern LP having a cut-off line CL, and can be used as a light distribution (so-called low beam) at the time of passing. .. Further, the vehicle lighting tool 1 can form a traveling irradiation pattern HP by superimposing it on the passing irradiation pattern LP by lighting two high beam units (60, 70) in addition to the five low beam units. It can be the light distribution of time (so-called high beam).

Next, the operation in the vehicle lamp 1 will be described. In conventional vehicle lighting equipment, a reflector reflection type unit forms a light distribution pattern that spreads over a desired range, and a direct light type unit forms a light distribution pattern with a high amount of light in a narrow range, and these are appropriately overlapped. , An irradiation pattern for passing is formed that illuminates a desired range with a desired brightness distribution. In this vehicle lamp, the reflector reflection type unit has a large configuration, so that the overall configuration is large.

On the other hand, in the vehicle lamp 1, the first unit (10 to 30 in the first embodiment) that irradiates the light from the light source with the irradiation lens, and a part of the light from the light source is irradiated with the irradiation lens and the light is emitted. The second unit (40, 50 in Example 1) that internally reflects the other portion and then irradiates the other portion to form an irradiation pattern LP for passing each other. Since the first unit can efficiently collect the light from the light source in the vehicle lamp 1, the brightest part near the center position O in the irradiation pattern LP for passing by the first unit (the first in the first embodiment). To form a third light distribution pattern (LP1 to LP3). In addition, since the second unit can efficiently diffuse the light from the light source in the vehicle lamp 1, the second unit greatly expands in the substantially horizontal direction below the center position O in the passing irradiation pattern LP (Example). In 1, the fourth and fifth light distribution patterns (LP4, LP5)) are formed. Therefore, in the vehicle lamp 1, the desired range can be brightened by the second unit and the brightness can be secured at a predetermined position by the first unit without using the reflector reflection type unit having a large configuration. As a result, the vehicle lamp 1 can be miniaturized as compared with the conventional vehicle lamp, and can efficiently form a bright spot and brighten over a sufficiently wide range to form a passing irradiation pattern LP. ..

Further, in the vehicle lighting equipment 1, in the unit group 2, each light source (11 to 71) of each unit (10 to 70) is mounted on the same substrate 3. Therefore, although the vehicle lamp 1 uses seven units, the substrate 3 can be shared, the configuration and wiring of the lighting control circuit can be simplified, and the number of parts can be reduced. can. In addition, the vehicle lamp 1 is formed as a lens body 4 in which each irradiation lens (12 to 72) of each unit (10 to 70) is integrated. Therefore, the vehicle lamp 1 can form the unit group 2 by positioning and assembling the single substrate 3 and the lens body 4, and as a simpler configuration, the number of parts can be reduced and the assembling work can be performed. It can be easy.

Further, the vehicle lamp 1 is a second unit (fifth low beam unit 50 in the first embodiment), and forms an OH light distribution pattern portion OHP which is a portion for illuminating an upper sign or the like in the passing irradiation pattern LP. Therefore, the vehicle lamp 1 can efficiently form a bright spot and brighten it over a sufficiently wide range to form a passing irradiation pattern LP, while ensuring upward visibility from the own vehicle.

In the second irradiation lens (irradiation lens (42, 52)), the vehicle lamp 1 has an incident surface (43, 53) having a curved incident surface portion (43a, 53a) and an annular incident surface portion (43b, 53b). , A reflective surface (43c, 53c) is provided so as to surround the annular incident surface portion. Therefore, in the second irradiation lens, the vehicle lamp 1 directly irradiates a part of the light from the light source (direct light) and reflects the other part of the light internally (reflected light) in the second irradiation lens. It can be irradiated and the light from the corresponding light source (41, 51) can be efficiently used.

In the vehicle lamp 1, in the second irradiation lens (irradiation lens (42, 52)), the emission surface (44, 54) is the central emission surface portion (44a, 54a), the upper emission surface portion (44b, 54b), and the lower side. It is configured to have an exit surface portion (44c, 54c). Then, in the second irradiation lens, the vehicle lamp 1 individually forms a pattern portion on each emission surface portion, and forms a light distribution pattern (LP4, LP5) individually by appropriately superimposing them. Therefore, the vehicle lamp 1 can be formed as an appropriate brightness distribution while having a desired shape even if the light distribution pattern (LP4, LP5) illuminates a large range.

The smaller the size of the light distribution pattern (LP1 to LP3) formed in the three first units (10 to 30) of the vehicle lamp 1, the light source (11 to 31) to each irradiation lens (12 to 32). The interval (focal length) is large. Therefore, in the vehicle lamp 1, the degree of collecting the light from the light source (11 to 31) is increased by increasing the distance from the light source to each irradiation lens, so that each first unit is efficient and efficient. Light distribution patterns (LP1 to LP3) having different sizes can be appropriately formed. In particular, in the vehicle lamp 1 of the first embodiment, each irradiation lens is integrated to form a lens body 4, and the position of each irradiation lens (12 to 32) in the lens body 4 in the front-rear direction is changed. The distance from the corresponding light source is set. Therefore, in the vehicle lamp 1 of the first embodiment, each light source (11 to 31) can be mounted on the same substrate 3, and three light distribution patterns (LP1 to LP3) having different sizes are formed while having a simple configuration. can.

In the vehicle lamp 1, five low beam units (10 to 50 in Example 1) form a passing irradiation pattern LP, and two high beam units (60, 70 in Example 1) form a traveling irradiation pattern HP. is doing. Therefore, the vehicle lamp 1 can appropriately form a passing irradiation pattern LP that is required to illuminate a predetermined range while making the cut-off line CL clear and satisfying the requirements for brightness at various positions. Further, the vehicle lamp 1 can appropriately form the traveling irradiation pattern HP, which has less requirements than the passing irradiation pattern LP, while having a simple configuration.

The vehicle lighting tool 1 includes a part of light (direct light) that has passed through the curved incident surface portion 53a and a part of light (reflected light) that has been reflected by the OH reflecting surface portion 53d on the reflecting surface 53c in the irradiation lens 52. An OH light distribution pattern section OHP is provided at a position where both are incident. Therefore, since the vehicle lamp 1 can emit both the direct light and the reflected light that have passed through two different optical paths from the OH emission surface portion 54d, the OH emission surface portion 54d does not have to have a complicated configuration. The light distribution pattern portion OHP can have a brightness distribution in which a plurality of locations have a predetermined amount of light.

The vehicle lamp 1 is provided with an OH emission surface portion 54d that is partially recessed in the emission surface 54 of the irradiation lens 52 of the fifth low beam unit 50, so that when the irradiation lens 52 irradiates light from the light source 51. The OH light distribution pattern portion OHP in the passing irradiation pattern LP is formed. Therefore, the vehicle lamp 1 has a simple structure, but a part of the light from the light source 51 forming the irradiation pattern LP for passing each other (the fifth low light distribution pattern LP5 which is a part thereof in the first embodiment) is emitted. It can be used to form an OH light distribution pattern portion OHP.

The vehicle lamp 1 is provided with an OH emission surface portion 54d in the vicinity of the lens shaft La 5 on the emission surface 54 of the irradiation lens 52. Therefore, the vehicle lamp 1 can reduce the angle and distance between the traveling direction of the direct light and the reflected light traveling to the OH emission surface portion 54d and the lens axis La5. From this, even if the angle of the OH emission surface portion 54d with respect to the emission surface 54 is reduced, the vehicle lamp 1 can advance the direct light and the reflected light toward the position required as the OH light distribution pattern portion OHP. .. From this, the vehicle lamp 1 can easily produce the irradiation lens 52 (lens body 4 in the first embodiment) by resin molding using a mold, and the OH emission surface portion 54d is appropriately formed. This makes it possible to appropriately form the OH light distribution pattern portion OHP while improving the appearance of the irradiation lens 52.

The vehicle lamp 1 diffuses the direct light in the irradiation lens 52 at a position of about 4 degrees above the center position O in the vertical direction and in a range slightly exceeding about 8 degrees in the horizontal direction around the center position O. To form the d-pattern portion Pp5d. Further, the vehicle lamp 1 has the reflected light of the irradiation lens 52 at a position of about 2 degrees above the center position O in the vertical direction and in a range slightly exceeding about 8 degrees in the horizontal direction with the center position O as the center. It is diffused to form the e-pattern portion Pp5e. Therefore, the vehicle lighting tool 1 is located in the OH light distribution pattern portion OHP at a position that coincides with the vertical line V in the horizontal direction at both a position of about 2 degrees and a position of about 4 degrees above the center position O. It is possible to secure the brightness of (0 degree), the position of about 4 degrees plus or minus from the vertical line V, and the position of about 8 degrees plus or minus from the vertical line V. Here, in the overhead light distribution, at each of the position of about 2 degrees and the position of about 4 degrees above the center position O, the position corresponding to the vertical line V in the horizontal direction and the position corresponding to the vertical line V are plus or minus. There is a regulation (rule) that sets the brightness at a total of 10 positions (so-called regulation points), that is, a position of about 4 degrees and a position of about 8 degrees plus or minus from the vertical line V, to the upper limit predetermined value or less. be. Further, in the overhead light distribution, the above-mentioned five positions (0 degree, ± 4 degree, ± 8 degree) are obtained in the horizontal direction at the position of about 2 degrees and the position of about 4 degrees above the center position O, respectively. There is a regulation that the value obtained by adding the brightness of the position) is equal to or higher than the lower limit predetermined value. With the above configuration, the vehicle lamp 1 can adjust the brightness of the above 10 positions, so that a plurality of regulation points can be set to a predetermined amount of light, and the above two regulations can be applied. It can be appropriately satisfied, and the upward visibility from the own vehicle can be ensured more appropriately.

In the vehicle lighting fixture 1, the emission surface (64, 74) of the irradiation lens (62, 72) of the high beam unit (60, 70 in the first embodiment) has the central emission surface portion (64a, 74a) and the outer emission surface portion (64b). , 74b) and the inner exit surface portion (64c, 74c). Therefore, the vehicle lamp 1 can be formed as an appropriate brightness distribution while having a desired shape even if the light distribution pattern (LP6, LP7) illuminates a large range. In particular, the vehicle lamp 1 of the first embodiment has two high beam units (60, 70) having similar optical characteristics to each other, and each forms a light distribution pattern (LP6, LP7) having substantially the same shape at substantially the same position. As a result, the two light distribution patterns are overlapped with each other to form the traveling irradiation pattern HP. Therefore, the vehicle lighting tool 1 can easily secure the required brightness and can form a more appropriate traveling irradiation pattern HP.

The vehicle lighting fixture 1 is larger than the depth d1 of the central emission surface portion 44a of the emission surface 44 of the irradiation lens 42 of the fourth low beam unit 40 and the depth d2 of the center emission surface portion 54a of the irradiation lens 52 of the fifth low beam unit 50. The depth d3 of the central exit surface portion 64a of the irradiation lens 62 of the right side high beam unit 60 and the center emission surface portion 74a of the irradiation lens 72 of the left side high beam unit 70 is increased. Therefore, the vehicle lamp 1 appropriately diffuses light by the central emission surface portion 44a and the central emission surface portion 54a by reducing the depth d1 in the fourth low beam unit 40 and the depth d2 in the fifth low beam unit 50. .. Here, in the vehicle lamp 1, the upper emission surface portion 44b and the lower emission surface portion 44c adjacent to the central emission surface portion 44a, and the upper emission surface portion 54b and the lower emission surface portion 54c adjacent to the central emission surface portion 54a are illuminated. To spread. Therefore, in the vehicle lamp 1, the three surface portions (44a to 44c and 54a to 54c) having similar actions to each other can be appropriately diffused by the three surface portions (44a to 44c and 54a to 54c) having substantially equal positions in the front-rear direction. Further, the vehicle lamp 1 appropriately diffuses light by the central emission surface portion 64a and the central emission surface portion 74a by increasing the depth d3 in the right side high beam unit 60 and the left side high beam unit 70. Here, in the vehicle lamp 1, the outer emission surface portion 64b and the inner emission surface portion 64c adjacent to the central emission surface portion 64a and the outer emission surface portion 74b and the inner emission surface portion 74c adjacent to the central emission surface portion 74a collect light. .. Therefore, in the vehicle lighting tool 1, the central emission surface portion 64a and the central emission surface portion 74a are positioned at different positions in the front-rear direction with respect to the surrounding surface portions (64b, 64c, 74b, 74c) for condensing light. Light can be diffused appropriately.

In the vehicle lighting equipment 1, the central emission surface portion 44a of the emission surface 44 of the irradiation lens 42 of the fourth low beam unit 40 and the center emission surface portion 54a of the irradiation lens 52 of the fifth low beam unit 50 are rectangular, and the right high beam unit 60 is provided. The central exit surface portion 64a of the irradiation lens 62 and the center emission surface portion 74a of the irradiation lens 72 of the left high beam unit 70 have a circular shape. Therefore, the difference in the light distribution pattern formed by the vehicle lamp 1 can be determined from the appearance of each irradiation lens (42 to 72).

In the vehicle lamp 1, the fifth low beam unit 50 forming the OH light distribution pattern portion OHP forms a desired light distribution pattern (fifth low light distribution pattern LP5) that is at least a part of the passing irradiation pattern LP. ing. Therefore, the vehicle lamp 1 can simultaneously form the passing irradiation pattern LP (a part thereof) used together with the OH light distribution pattern portion OHP by the light from the light source 51, so that the configuration can be miniaturized. It can contribute to space saving.

The vehicle lamp 1 of the first embodiment can obtain the following effects.

The vehicle lighting fixture 1 includes a light collecting pattern (LP1, LP2, LP3) formed by the first unit (10, 20, 30) and a diffusion pattern (LP4, LP5) formed by the second unit (40, 50). , To form a desired light distribution pattern (irradiation pattern LP for passing in Example 1). Therefore, in the vehicle lighting fixture 1, the brightness can be secured at a predetermined position by the first unit and the desired range can be brightened by the second unit without using a reflector reflection type unit having a large configuration. It is possible to form an irradiation pattern that illuminates a desired range with a desired brightness distribution.

Further, in the vehicle lamp 1, a plurality of first units are provided with different intervals from the first light source (11, 21, 31) to the first irradiation lens (12, 22, 32), and the second unit is provided. , The distance from the second light source (41, 51) to the second irradiation lens (42, 52) is shorter than that of the first unit. Therefore, in the vehicle lamp 1, each first unit can efficiently and appropriately form a light-collecting pattern (LP1 to LP3) having different sizes from each other, and the second unit is diffused more than any light-collecting pattern. A diffusion pattern (LP4, LP5) can be formed.

Further, in the vehicle lamp 1, when the plurality of first units have a large dimension in the vertical direction of the first irradiation lens, the distance from the first light source to the first irradiation lens is large, and the distance between the first light source and the first irradiation lens is large in the vertical direction of the first irradiation lens. If the size of the lens is small, the distance from the first light source to the first irradiation lens is reduced. Therefore, in the vehicle lamp 1, each first unit can more efficiently and more appropriately form light distribution patterns (LP1 to LP3) having different sizes from each other.

In the vehicle lamp 1, the second unit has a plurality of emission surface portions (44a to 44c, 54a to 54d) having different emission surfaces (44, 54) having different optical settings, and a plurality of emission surface portions (44a to 44c, 54a to 54d) are formed on the surface of the emission surface. A continuous diffusion portion (44d, 54e) is formed so as to straddle the emission surface portion of the above. For this reason, the vehicle lamp 1 diffuses and equalizes the light emitted from the second unit, and even if the emission surface is divided into a plurality of emission surface portions, the appearance is unified as a whole and the appearance is improved. Can be improved. Further, in the vehicle lamp 1, the light emitted from each emission surface portion is diffused and uniformized in substantially the same manner, and even at the boundary between different emission surface portions, the light is diffused and uniformized in substantially the same manner without a break. Can be done. Therefore, when at least a part of the diffusion pattern formed by each emission surface portion is superimposed, the vehicle lamp 1 can suppress a sense of discomfort such as light unevenness at the superimposed portion.

The vehicle lamp 1 constitutes a lens body 4 by integrating a first irradiation lens and a second irradiation lens. Therefore, even if the first unit and the second unit are used, the vehicle lamp 1 can reduce the number of constituent parts as compared with the case where the irradiation lens is separately provided, and has a simple configuration. Can be easily assembled with.

In the vehicle lamp 1, the lens body 4 projects the first irradiation lens toward the side to irradiate the light and the second irradiation lens toward the second light source side. Therefore, the vehicle lamp 1 can easily secure the distance between the first light source and the second light source while having the lens body 4 in a simple configuration.

In the vehicle lamp 1, the first light source and the second light source are provided on a common substrate 3. Therefore, the vehicle lamp 1 can be easily configured as a whole and can be easily miniaturized.

The light distribution pattern formed in the vehicle lamp 1 is at least a part of the passing irradiation pattern LP. Therefore, the vehicle lamp 1 can appropriately form a passing irradiation pattern LP that illuminates a predetermined range while making the cut-off line CL clear and satisfying the requirements for brightness at various positions.

Therefore, the vehicle lamp 1 of the first embodiment as the vehicle lamp according to the present disclosure can be miniaturized while forming an irradiation pattern of a desired size (in the first embodiment, the irradiation pattern LP for passing).

Although the vehicle lamps of the present disclosure have been described above 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 within the scope of the claims. Unless otherwise, design changes or additions are allowed.

In Example 1, five low beam units (10 to 50 in Example 1) form a passing irradiation pattern LP, and two high beam units (60, 70 in Example 1) form a traveling irradiation pattern HP. Is forming. However, the vehicle lamp 1 may be any as long as it forms a desired light distribution pattern (irradiation pattern combining them), and is not limited to the configuration of the first embodiment. Further, even in the case of forming the passing irradiation pattern LP and the traveling irradiation pattern HP, the number of low beam units and high beam units may be appropriately set, and is not limited to the configuration of the first embodiment.

Further, in the first embodiment, three first units (10 to 30) are provided and two second units (40, 50) are provided. However, the number of the first unit and the second unit may be appropriately set, and is not limited to the configuration of the first embodiment. Further, although the second unit is provided with a plurality of emission surface portions (44a to 44c, 54a to 54d) on the emission surface (44, 54), if a plurality of emission surface portions having different optical settings are provided, the second unit may be provided. The number and optical settings may be appropriately set, and are not limited to the configuration of the first embodiment.

Further, in the first embodiment, the irradiation lens 52 of the fifth low beam unit 50 is provided with the OH emission surface portion 54d, but it may be provided in another unit and is not limited to the configuration of the first embodiment.

In the first embodiment, the OH emission surface portion 54d has a position (0 degree) that coincides with the center position O in the horizontal direction at each of the position of about 2 degrees and the position of about 4 degrees above the center position O. The OH light distribution pattern portion OHP that secures the brightness of the position of about 4 degrees plus or minus from the center position O and the position of about 8 degrees plus or minus from the center position O is formed. However, the OH emission surface portion 54d may form an OH light distribution pattern portion OHP according to the required brightness distribution, and is not limited to the configuration of the first embodiment.

In the first embodiment, the OH emission surface portion 54d is made substantially flat. However, the OH emission surface portion 54d emits one of the direct light and the reflected light toward a position at about 4 degrees above the center position O, and at a position where the other is about 2 degrees above the center position O. The curvature of the OH emitting surface portion 54d may be gradually changed as long as the light is emitted toward the surface, and the configuration is not limited to that of the first embodiment.

1 Vehicle lighting equipment 3 Substrate 10 (as an example of the first unit) First low beam unit 11 (as an example of the first light source) Light source 12 (as an example of the first irradiation lens) Irradiation lens 20 (as an example of the first irradiation lens) Second low beam unit 21 (as an example) Light source 22 (as an example of a first light source) Irradiation lens 30 (as an example of a first irradiation lens) Third low beam unit 31 (as an example of a first unit) 31 (first) Light source (as an example of a light source) Light source 32 (as an example of a first irradiation lens) Irradiation lens 40 (as an example of a second unit) Fourth low beam unit 41 (as an example of a second light source) Light source 42 (as an example of a second light source) 42 (second irradiation) Irradiation lens 44 (as an example of a lens) Emission surface 44a (as an example of an emission surface portion) Central emission surface portion 44b (as an example of an emission surface portion) Upper exit surface portion 44c (as an example of an emission surface portion) Lower exit surface portion 44d Diffuse Part 50 (as an example of the second unit) Fifth low beam unit 51 (as an example of the second light source) Light source 52 (as an example of the second irradiation lens) Irradiation lens 54 Emission surface 54a (as an example of the emission surface part) ) Central emission surface portion 54b (as an example of the emission surface portion) Upper emission surface portion 54c (as an example of the emission surface portion) Lower emission surface portion 54d (as an example of the emission surface portion) OH emission surface portion 54e Diffuse part LP (desired light distribution) Irradiation pattern for passing (as an example of the pattern) LP1 (as an example of the light collection pattern) 1st low light distribution pattern LP2 (as an example of the light collection pattern) 2nd low light distribution pattern LP3 (as an example of the light collection pattern) 3rd row light distribution pattern LP4 (as an example of diffusion pattern) 4th row light distribution pattern LP5 (as an example of diffusion pattern) 5th row light distribution pattern

Claims (8)

A first unit having a first irradiation lens that emits light incident from a first light source, and
A second unit having a second irradiation lens that emits a part of the light incident from the second light source and internally reflects the other part of the light and then emits the light.
A vehicle lighting fixture characterized in that a desired light distribution pattern is formed by superimposing a light collecting pattern formed by the first unit and a diffusion pattern formed by the second unit. A plurality of the first units are provided with different intervals from the first light source to the first irradiation lens.
The vehicle lamp according to claim 1, wherein the second unit has a shorter distance from the second light source to the second irradiation lens than the first unit. When the vertical dimension of the first irradiation lens is large, the distance between the first light source and the first irradiation lens is large in the plurality of the first units, and the vertical dimension of the first irradiation lens is large. The vehicle lamp according to claim 2, wherein if the distance is small, the distance from the first light source to the first irradiation lens is small. The second unit has a plurality of emission surface portions whose emission surfaces have different optical settings.
The vehicle lamp according to any one of claims 1 to 3, wherein a continuous diffusion portion is formed on the surface of the emission surface portion so as to straddle the plurality of emission surface portions. The vehicle lamp according to any one of claims 1 to 4, wherein the first irradiation lens and the second irradiation lens are integrated to form a lens body. The fifth aspect of claim 5, wherein the lens body projects the first irradiation lens toward the side to be irradiated with light and the second irradiation lens toward the second light source side. Vehicle lighting equipment. The vehicle lamp according to claim 5 or 6, wherein the first light source and the second light source are provided on a common substrate. The vehicle lamp according to any one of claims 1 to 7, wherein the light distribution pattern is at least a part of a passing irradiation pattern.

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