JP2014056777A - Lighting fixture unit for vehicle headlight - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a lighting fixture unit for a vehicle headlight capable of eliminating light distribution unevenness in which a nearer side of an illuminated region becomes especially darker than other illuminated regions.SOLUTION: A lighting fixture unit for a vehicle headlight comprises: a first light-shielding shade 18 arranged between a reflector 17 (20) and a projection lens 15, and for shielding a part of light reflected from the reflector 17 (20) and forming a predetermined light distribution pattern; and a second light-shielding shade 19 arranged in the upper side of the first light-shielding shade 18, and for shielding a part of the light reflected from the reflector 17 (21) and making luminous intensity in the lower region in the predetermined light distribution pattern lower than that of other regions in the predetermined light distribution pattern. With this configuration, regarding light-shielding properties in the light reflected from the reflector 17 (20, 21), the second light-shielding shade 19 is set such that the luminous intensity in the lower region in the predetermined light distribution pattern becomes higher from the lower to upper sides, and brightness becomes gradually higher from nearer to farther sides of the illumination region.

Description

  The present invention relates to a lamp unit for a vehicle headlamp that suppresses uneven orientation in a lower region in a predetermined light distribution pattern.

  As a projector-type lamp unit in a vehicle headlamp, as shown in Patent Document 1, a projection lens disposed on an optical axis extending in the vehicle front-rear direction, and a rear focal point of the projection lens are disposed. A light source, a reflector that reflects the light from the light source toward the projection lens, and a part of the reflected light from the reflector that is disposed between the reflector and the projection lens to block a predetermined light distribution pattern What is provided with the light-shielding shade to form is generally known.

In recent years, it has been desired that such projector-type lamp units also be highly efficient and downsized. In order to achieve this high efficiency and miniaturization, it is considered effective to shorten the focal length of the reflector and the projection lens. However, when the optical system is made highly efficient and downsized as described above, the light source does not become small with respect to the optical system, and therefore the light distribution pattern spreads in the vertical direction. Of these, the front side (the front side of the vehicle) becomes too bright. For this reason, when a lamp unit is made highly efficient and downsized with an optical system, a new problem arises that the distance visibility is lowered.
For this, as described in the above-mentioned Patent Document 1, a second light-shielding shade having no translucency is arranged above the light-shielding shade (first light-shielding shade), and a reflector is provided. It is conceivable that the light intensity of the lower region in the predetermined light distribution pattern is reduced as compared with the light intensity of other regions in the predetermined light distribution pattern by shielding part of the reflected light from the light.

JP 2009-214312 A

  However, in the lamp unit of the vehicle headlamp, as described above, the second light-shielding shade is disposed above the first light-shielding shade, and the light intensity of the lower region in the predetermined light distribution pattern is set to the predetermined light distribution. When the brightness is lowered as compared with the brightness of other areas in the pattern, the second light-shielding shade has no translucency, so that the front side of the illumination area is particularly dark compared to the other illumination areas. Unevenness of light distribution occurs, causing the passenger to feel uncomfortable.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a lamp unit for a vehicle headlamp that can eliminate unevenness in light distribution in which the front side of the illumination area is particularly dark compared to other illumination areas. It is to provide.

In order to achieve the above object, the present invention (the invention according to claim 1)
A projection lens disposed on an optical axis extending in the vehicle front-rear direction, a light source disposed behind a rear focal point of the projection lens, a reflector that reflects light from the light source toward the projection lens, and A first light-shielding shade that is disposed between the reflector and the projection lens and shields part of the reflected light from the reflector to form a predetermined light distribution pattern; and the reflector that is disposed above the first light-shielding shade. A second light-shielding shade provided with a second light-shielding shade that shields a part of the reflected light from the light and makes a light intensity of a lower region in the predetermined light distribution pattern smaller than a light intensity of other regions in the predetermined light distribution pattern In the lighting lamp unit,
The second light-shielding shade is configured to increase the light intensity of the lower region in the predetermined light distribution pattern from the lower side toward the upper side with respect to the light-shielding property with respect to the reflected light from the reflector. The preferred embodiment of claim 1 is as described in claim 2 and the following.

  According to the present invention (the invention according to claim 1), the second light shielding shade increases the light intensity of the lower region in the predetermined light distribution pattern from the lower side toward the upper side with respect to the light blocking property of the reflected light from the reflector. Therefore, it is possible to eliminate unevenness of light distribution that becomes brighter from the front side of the illumination area toward the far side of the illumination area, and the front side of the illumination area is particularly darker than the other illumination areas. Thereby, the uncomfortable feeling based on the light distribution nonuniformity in which the near side of the illumination area becomes particularly dark compared to the other illumination areas can be greatly relieved.

According to the second aspect of the invention, the reflector includes the first reflector that is disposed so as to cover at least the light source and reflects the light from the light source toward the projection lens, and the second light-shielding shade includes the first light-shielding shade. Since the light-shielding property decreases as it goes from the upper side to the lower side of the two light-shielding shades, the second light-shielding shade shields the reflected light from the first reflector, so that the lower region in the predetermined light distribution pattern In FIG. 2, a reverse image corresponding to the second light-shielding shade is projected, and the light intensity of the transmitted light based on the light-shielding property of the second light-shielding shade is reflected in the reverse image, so that the lower region in the predetermined light distribution pattern Can be increased from the lower side toward the upper side. For this reason, the effect of the said Claim 1 can be specifically acquired by using the 2nd light-shielding shade from which light-shielding property becomes low as it goes to the lower side from the upper side.
In addition, the reflected light from the first reflector (light from the light source) that has been shielded by the second light-shielding shade so far is effectively used as transmitted light in order to greatly alleviate the uncomfortable feeling due to the light distribution unevenness. For this reason, it can suppress as much as possible that the light of a light source is wasted.

  According to the invention of claim 3, the reflector includes the second reflector that reflects the reflected light from the first reflector toward the projection lens behind the light shielding edge of the first light shielding shade in the optical axis direction. Therefore, in the lower region in the predetermined light distribution pattern, the inverted image corresponding to the second light-shielding shade is also reflected from the first reflector by the reflected light from the second reflector having a light flux density lower than the reflected light from the first reflector. The reversal image corresponding to the second light-shielding shade based on the reflected light is projected while being shifted downward and overlapped, and the reversal image also reflects the intensity of the transmitted light based on the light-shielding property of the second light-shielding shade. Will be. For this reason, in the lower region of the predetermined light distribution pattern, the difference in brightness of the inverted image corresponding to the second light-shielding shade based on the light flux density difference between the reflected light from the first reflector and the reflected light from the second reflector, In the inverted image, the luminous intensity increases from the lower side to the upper side, so that the luminous intensity can be increased from the lower side to the upper side. For this reason, the effect of the said Claim 1 is realizable more finely.

  According to the invention of claim 4, the second light-shielding shade is set so that the light-shielding property decreases as it goes from the upper side to the lower side by being coated with a gradation state on the transparent base material. Therefore, a specific embodiment of the second light-shielding shade according to claim 2 or 3 can be provided.

  According to the invention according to claim 5, the second light-shielding shade is configured with a textured surface obtained by performing a textured process on a transparent base material, and the textured surface is textured as it goes from the upper side to the lower side. Since the density is set to be low, the amount of light transmitted through the second light-shielding shade can be adjusted through diffusion by embossing, and the second light-shielding shade according to claim 2 or 3 is embodied. Can provide.

  According to the sixth aspect of the present invention, the reflector is disposed so as to cover the light source and reflects the light from the light source toward the projection lens, and the optical axis from the light shielding edge of the first light shielding shade. A second reflector that is disposed rearward in the direction and reflects the reflected light from the first reflector toward the projection lens, and the second light-shielding shade shields the reflected light from the first reflector. A shade, and a front-side second light-shielding shade that is arranged at a predetermined distance from the rear-side second light-shielding shade in the optical axis direction and shields the reflected light from the second reflector. In the lower region of the predetermined light distribution pattern, the reverse image formed by the front second light-shielding shade blocking the reflected light from the second reflector is the rear second light-shielding shade as the first reflector. The reflected light from the second reflector is projected downward with respect to the inverted image formed by shielding the reflected light, and the light flux density of the reflected light from the second reflector is the same as that of the reflected light from the first reflector. The brightness of the inverted image based on the reflected light from the second reflector is smaller than that of the inverted image based on the reflected light from the first reflector. For this reason, the inverted image based on the reflected light from the second reflector can be used as a light / dark boundary below the predetermined light distribution pattern, so that the light / dark difference at the light / dark boundary below the predetermined light distribution pattern can be made almost inconspicuous. In the lower region of the light pattern, the brightness can be gradually increased from the lower side to the upper side depending on the luminous intensity state of each inverted image based on the reflected light from the first and second reflectors. As a result, it is possible to eliminate unevenness of light distribution in which the front side of the illumination area is particularly dark compared to the other illumination areas, and it is possible to greatly relieve the uncomfortable feeling based on that.

The front view which shows the vehicle headlamp which concerns on 1st Embodiment. The horizontal sectional view of FIG. The longitudinal cross-sectional view which shows the low beam unit in FIG. The enlarged view of FIG. Explanatory drawing explaining the light distribution pattern formed by being light-shielded by the 1st light-shielding shade. The front view which shows the 2nd light-shielding shade which concerns on 1st Embodiment. The figure which shows the light distribution pattern which the lamp unit which concerns on 1st Embodiment forms. Explanatory drawing explaining the reverse image formed when the reflected light from a 1st reflector is light-shielded by the 2nd light-shielding shade in the lower area | region of the light distribution pattern which the lamp unit which concerns on 1st Embodiment forms. Explanatory drawing explaining the inversion image formed when the reflected light from a 2nd reflector is light-shielded by the 2nd light-shielding shade in the lower area | region of the light distribution pattern which the lamp unit which concerns on 1st Embodiment forms. In the lower region of the light distribution pattern formed by the lamp unit according to the first embodiment, the inverted image based on the reflected light from the first reflector and the inverted image based on the reflected light from the second reflector are vertically shifted Explanatory drawing explaining what is projected by. The longitudinal cross-sectional view which shows the lamp unit which concerns on 2nd Embodiment. The enlarged view of FIG. Explanatory drawing explaining the reverse image formed when a back side 2nd shade shields the reflected light from a 1st reflector. Explanatory drawing explaining the inversion image formed when a front side 2nd shade shields the reflected light from a 2nd reflector. In the lower region of the light distribution pattern formed by the lamp unit according to the second embodiment, the reverse second light-shielding shade is formed by blocking the reflected light from the first reflector, and the front second light-shielding shade is the first. Explanatory drawing explaining that the reverse image formed by light-shielding the reflected light from 2 reflectors is projected in the state shifted | deviated up and down.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
1 and 2, reference numeral 1 denotes a vehicle headlamp according to the first embodiment. The vehicular headlamp 1 is formed by a lamp body 2 whose front is opened and a front cover 3 that covers the opening of the lamp body 2.

The lamp body 2 includes a back wall portion 2a that stands up and down, and a peripheral wall portion 2b that projects forward from the peripheral edge of the back wall portion 2a. The back wall 2a extends in the lateral direction (left and right in FIGS. 1 and 2) while maintaining a constant height, and the back wall 2a has a laterally inner portion 2aa (see FIGS. 1 and 2). 2 on the left side) and a laterally outer portion 2ab (right side in FIGS. 1 and 2), a stepped portion 2ac is provided, and the laterally outer portion 2ab of the back wall portion 2a is lateral to the back wall portion 2a. Retracted rearward (upward in FIG. 2) from the direction inner portion 2aa. In the peripheral wall 2b, the amount of protrusion to the front decreases from the inner side in the horizontal direction toward the outer side in the horizontal direction. It is inclined to open outward in the lateral direction as it goes to. The peripheral wall portion 2b defines a storage space 4 in cooperation with the back wall portion 2a, and the distal end portion of the peripheral wall portion 2b defines a horizontally elongated opening 5.

  As shown in FIG. 2, the front cover 3 is detachably attached to the distal end portion of the peripheral wall portion 2 b of the lamp body 2. The front cover 3 has a horizontally long shape corresponding to the opening 5 of the lamp body 2, and the front cover 3 extends in a substantially horizontal direction from the inner side in the horizontal direction to the vicinity of the approximate center in the lateral direction, and substantially in the vicinity of the approximate center in the lateral direction. Is curved backward as it goes outward in the lateral direction. As a result, the front cover 3 and the lamp body 2 extend in the substantially horizontal direction while maintaining a constant length in the front-rear direction from the inner side in the horizontal direction to the vicinity of the approximate center in the horizontal direction, A sealed space 6 shifted rearward is formed on the outer side. The front cover 3 is made of a light-transmitting material, and light emitted in the sealed space 6 is irradiated to the outside through the front cover 3.

  As shown in FIGS. 2 and 3, a plate-shaped metal support member 7 (for example, an aluminum die cast product) 7 is disposed in the sealed space 6. The support member 7 is supported on the back wall portion 2a of the lamp body 2 via an aiming screw 8a and an aiming pivot 8b. The plate surface of the support member 7 faces the front side from the back wall portion 2a while facing the front-rear direction. It is arrange | positioned in the state spaced apart. The support member 7 is bent in a step shape to form a plurality of support portions 7a to 7d having a predetermined length in the lateral direction (see FIG. 2). The plurality of support portions 7a to 7d are arranged rearwardly from the inner side in the horizontal direction toward the outer side in the horizontal direction based on the step-like bending with respect to the support member 7, and the support portion 7d arranged on the outermost side in the horizontal direction The support part 7c arrange | positioned adjacent to the horizontal direction inner side is located in the front side rather than it. The rear surfaces 9a (upper surfaces in FIG. 2) of the respective support portions 7a to 7d are directed rearward in a flat state, and the heat radiation fins 10 for radiating heat are respectively provided on the rear surfaces 9a. Installed. A lamp unit 11 is attached to the front surface 9b (the lower surface in FIG. 2) of each of the support portions 7a to 7d. Specifically, a direct-type high beam unit 11A for irradiating a high beam is attached to the front surface 9b of the support portion 7a, and a projector-type low beam unit 11B for irradiating the low beam to the support portions 7b and 7c. , 11C are respectively attached. A front turn signal lamp unit 11D is attached to the support portion 7d, and the light blinking by the amber light emitting LED 12 is emitted to the outside through the light guide lens 13 by the front turn signal lamp unit 11D.

  The low beam units 11B and 11C constitute the lamp unit 11 according to this embodiment. Since the low beam units 11B and 11C basically have the same configuration, the low beam unit 11B will be described below, and the low beam unit 11C will be denoted by the same reference numeral and the description thereof will be omitted.

  In this embodiment, the protrusion part 14 which protrudes ahead is provided in the front surface 9b of the support part 7b, and the upper surface of the protrusion part 14 is made into the flat surface. A low beam unit 11B is attached to the projecting portion 14 and the like. The low beam unit 11B includes a projection lens 15, a light emitting element 16 as a light source, a reflector 17, a first light shielding shade 18, and a plate-like shape. A second light-shielding shade 19.

  As shown in FIGS. 3 and 4, the projection lens 15 is disposed on the optical axis L extending in the vehicle front-rear direction on the front side of the projecting portion 14 in the support portion 7 b. The projection lens 15 is a plano-convex aspherical lens having a convex front surface and a flat rear surface. In the present embodiment, the projection lens 15 is formed as a rectangular shape extending in a strip shape in the lateral direction. (See FIG. 1). As a result, the projection lens 15 is designed to be compact, and a light source image formed on the rear focal plane (that is, the focal plane including the rear focal point F) is converted into a virtual vertical arrangement in front of the low beam unit 11B as an inverted image. Projected on a light screen.

  As shown in FIGS. 2 to 4, the light emitting element 16 is disposed behind the rear focal point F of the projection lens 15 on the optical axis L. Specifically, the optical axis L is set so as to pass on the upper surface of the protruding portion 14 in the support portion 7b, and the light emitting element 16 is disposed on the upper surface of the protruding portion 14 on the optical axis L. The light emitting element 16 includes an LED substrate 16a that is positioned and fixed on the upper surface of the protruding portion 14, and a plurality of LEDs (white light emitting diodes in the present embodiment) that are arranged on the surface (upper surface) and whose irradiation direction is directed upward. The plurality of LEDs 16b are arranged in parallel in the horizontal direction. Specifically, four square LEDs 16b each having a side of 1 mm are arranged in the horizontal direction.

  In the present embodiment, the reflector 17 includes a first reflector 20 and a second reflector 21 as shown in FIGS. The first reflector 20 is disposed so as to cover the light emitting element 16 from above, and has an effective reflection surface 20 a that reflects light from the light emitting element 16 toward the front (projection lens 15) toward the optical axis L. ing. The effective reflection surface 20a of the reflector is formed so that the cross-sectional shape including the optical axis L is substantially elliptical, and the eccentricity is set to gradually increase from the vertical cross section toward the horizontal cross section. In this case, the effective reflecting surface 20a of the reflector is formed of a substantially elliptical curved surface, the light emission center of the light emitting element 16 is positioned at the first focal point f1, and the projection lens 15 is disposed at the second focal point f2. The rear focal point F is located. The effective reflection surface 20a of the reflector 20 substantially converges the light from the light emitting element 16 to the substantially elliptical second focal point f2 which is also the rear focal point F of the projection lens 15 in the vertical section, and in the horizontal section. Will have its convergence position quite forward.

  The second reflector 21 uses an upper surface 22 of a metal first light-shielding shade 18 to be described later that is attached to the distal end side of the protruding portion 14. The upper surface 22 of the first light-shielding shade 18 extends as a second reflector 21 (reflecting surface) from the protruding portion 14 toward the projection lens 15 while maintaining a flush state with the upper surface of the protruding portion 14. The upper surface 22 of the first light-shielding shade 18 is set so as to reflect the reflected light from the first reflector 20 toward the projection lens 15.

The first light-shielding shade 18 is disposed between the projection lens 15 and the first reflector 20 as shown in FIGS. As described above, the first light-shielding shade 18 is attached to the front end side of the protruding portion 14, and the upper surface 22 of the first light-shielding shade 18 is rear side of the projection lens 15 while maintaining the same state as the upper surface of the protruding portion 14. A light / dark boundary forming part (tip) for forming a cut-off line CL at the upper edge of the predetermined light distribution pattern is formed at the focal point F (second point focal point f2) or in the vicinity thereof, and at the upper edge (light-shielding edge) 23 thereof. The same reference numerals as those of the upper edge 23 are used.). Thereby, the first light shielding shade 18 shields a part of the reflected light from the first reflector 20 with the upper surface 22, and based on this, as shown in FIG. A reverse image 24 is projected forward. At this time, the light / dark boundary forming part 23 of the first light-shielding shade 18 forms a cut-off line CL with a step on the low light distribution pattern P for the low beam, which is low on the opposite lane side and high on the own lane side (see FIG. 5). ).
Regarding the relationship between the first light-shielding shade 18 and the second reflector 21, as described above, since the second reflector 21 uses the upper surface of the first light-shielding shade 18, the second reflector 21 has the first light shielding shade. The shade 18 is disposed behind the upper edge (light-shielding edge) 23 in the optical axis L direction.
Further, a front extension 18 </ b> A is provided at the lower end of the first light shielding shade 18. The front extending portion 18A extends toward the projection lens 15, and the projection lens 15 is fixed and integrated at the tip thereof.

As shown in FIGS. 2 to 4, the second light-shielding shade 19 is integrally attached to the front edge portion of the first reflector 20. The second light-shielding shade 19 extends downward from the front edge of the first reflector 20 with the plate thickness direction directed to the optical axis L direction on the upper side of the first light-shielding shade 18. The rear side surface 19a of the two light-shielding shade 19 is in the same position as the rear focal point F (second point focal point f2) of the projection lens 15 in the optical axis L direction. This second shading shade 19 is
As shown in FIG. 6, a transparent base material, such as a glass plate or a resin plate, is coated in a gradation state, and the second light-shielding shade 19 is directed from the upper side to the lower side by the coating. The light shielding property is set to be low. In this case, in FIG. 6, the dark portion indicates that the coating film is thick and the light shielding property is high, and the thin color portion indicates that the coating film is thin and the light shielding property is low.

  Such a second light-shielding shade 19 shields the reflected light from the first reflector 20 and the reflected light from the second reflector 21, so that in the lower region Pb in the predetermined light distribution pattern P, as shown in FIG. In addition, inverted images 25 and 26 corresponding to the second light-shielding shade 19 are projected.

  Specifically, the reverse image 25 based on the reflected light from the first reflector 20 is formed such that the light shielding property of the second light shielding shade 19 decreases from the upper side to the lower side. A part of the reflected light from the reflector 20 is transmitted based on the light shielding property of the second light shielding shade 19, and the inverted image 25 has a luminous intensity by the transmitted light based on the light shielding property of the second light shielding shade 19, as shown in FIG. Is reflected. For this reason, in the lower region Pb in the predetermined light distribution pattern P, the luminous intensity of the inverted image 25 increases from the lower side toward the upper side.

With respect to the inverted image 26 based on the reflected light from the second reflector 21, part of the reflected light from the second reflector 21 is also transmitted through the second light shielding shade 19 according to the light shielding property. As shown in FIG. 9, the light intensity of the transmitted light based on the light shielding property of the second light shielding shade 19 is reflected. For this reason, also with respect to the inverted image 26 based on the reflected light from the second reflector 21, the luminous intensity increases from the lower side toward the upper side.
In this case, since the luminous flux density of the reflected light from the second reflector 21 is smaller than the luminous flux density of the reflected light from the first reflector 20, the intensity of the inverted image based on the reflected light from the second reflector 21 is shown in FIG. As shown in FIG. 9, the luminous intensity of the inverted image based on the reflected light from the first reflector 21 is smaller as a whole. Further, the inverted image 26 based on the reflected light from the second reflector 21 is projected in a state of being overlapped while being shifted downward with respect to the inverted image 25 based on the reflected light from the first reflector 20.

  The light rays forming the inverted images 25 and 26 are shown in FIGS. 3 and 4. In FIGS. 3 and 4, reference numeral LB1 is reflected light from the first reflector 20, and is projected. The light rays that pass through the rear focal point F (second focal point f2) of the lens 15 and form the cutoff line CL at the upper edge of the predetermined light distribution pattern P are shown. LB2 is reflected light from the first reflector 20, and proceeds directly toward the projection lens 15 without passing through the second light-shielding shade 19, and cuts the upper edge of the inverted image 25 corresponding to the second light-shielding shade 19. The light rays forming the off-line CL1-1 are shown. Reference numeral LB3 denotes a light beam reflected from the first reflector 20 and transmitted through the second light-shielding shade 19. LC1 is reflected light from the second reflector 21 and directly travels toward the projection lens 15 without passing through the second light-shielding shade 19, and the upper edge of the reverse image 26 corresponding to the second light-shielding shade 19. The light beam which makes the cut-off line CL1-2 is shown. LC <b> 2 indicates a light beam reflected from the second reflector 21 and transmitted through the second light shielding shade 19.

  Therefore, in the lower region Pb in the predetermined light distribution pattern P, as shown in FIG. 10, the second light-shielding shade based on the light flux density difference between the reflected light from the first reflector 20 and the reflected light from the second reflector 21. The brightness difference between the inverted images 25 and 26 corresponding to 19 and the luminous intensity state in which the inverted images 25 and 26 increase from the lower side to the upper side in the respective inverted images 25 and 26, the luminous intensity increases from the lower side to the upper side. . In FIG. 10, in order to exaggerate and clarify the presence of the inverted image 25 based on the reflected light from the first reflector 20 and the inverted image 26 based on the reflected light from the second reflector 21. Are slightly shifted in the left-right direction.

Therefore, in the first embodiment, the light intensity of the lower region Pb in the predetermined light distribution pattern P is set so as to increase from the lower side to the upper side, so that from the front side of the illumination region to the far side of the illumination region The light distribution unevenness in which the front side of the illumination area is particularly dark compared to other illumination areas can be eliminated. Thereby, the uncomfortable feeling based on the light distribution unevenness in which the near side of the illumination area becomes particularly dark compared to the other illumination areas can be relieved greatly.
In the present embodiment, the reflected light (light of the light emitting element 16) from the first reflector 20 that has been shielded by the second shading shade 19 so far is transmitted to greatly relieve the uncomfortable feeling due to the uneven light distribution. It is effectively used as light. For this reason, it can suppress as much as possible that the light of the light emitting element 16 is wasted.

  11 to 15 show a second embodiment. In the second embodiment, the same components as those in the first embodiment are denoted by the same reference numerals, and the description thereof is omitted.

The second embodiment shown in FIGS. 11 to 15 shows a modification of the second light-shielding shade 19 according to the first embodiment. In the second embodiment, assuming that the reflector 17 includes a first reflector 20 and a second reflector 21, the second light-shielding shade 19, the rear-side second light-shielding shade 27, and the front-side first light-shielding shade 27 are provided. 2 light-shielding shades 28.
That is, the second light-shielding shade 19 is integrated in a state where a pair of horizontally long plate members face each other with a predetermined interval therebetween, and one of the plate members serves as the rear second light-shielding shade 27. The other plate material is the front second light-shielding shade 28. Such a second light-shielding shade 19 is attached to the front edge of the first reflector 20. With this attachment, the rear-side second light-shielding shade 27 and the front-side second light-shielding shade 28 have their respective plate surfaces. It hangs down (first shading shade 18) in a state of extending in the lateral direction while being directed in the front-rear direction of the optical axis L, and both lower ends thereof have the same height. In this case, the rear second light-shielding shade 27 is disposed rearward in the optical axis L direction with respect to the rear focal point F (second point focal point f2) of the projection lens 15, and the front second light-shielding shade 28 is disposed on the projection lens 15. The rear second light-shielding shade 27 and the front second light-shielding shade 28 are arranged at the front end of the first light-shielding shade 18 with respect to the rear focal point F (second point focal point f2). Arranged at a predetermined interval above the upper edge.

  As a result, the rear second light shielding shade 27 shields the reflected light from the first reflector 20, projects a reverse image 29 based on the reflected light 29 onto the lower region Pb of the predetermined light distribution pattern P, and the front second light shielding shade 28. In this case, the reflected light from the second reflector 21 is shielded, and the inverted image 30 based thereon is projected onto the lower region Pb of the predetermined light distribution pattern P. In this case, in the lower region Pb of the predetermined light distribution pattern P, as shown in FIG. 15, the inverted image 30 is projected to be shifted downward with respect to the inverted image 29, and from the second reflector 21. Based on the fact that the luminous flux density of the reflected light is lower than the luminous flux density of the reflected light from the first reflector 20, the luminous intensity of the inverted image 30 is smaller than the luminous intensity of the inverted image 29 (see FIGS. 13 to 15).

  Therefore, the reverse image 30 becomes a light / dark boundary below the predetermined light distribution pattern P, and the difference in brightness at the light / dark boundary below the predetermined light distribution pattern P can be made hardly noticeable. In the region Pb, the brightness can be gradually increased from the inverted image 30 toward the inverted image 29 (from the lower side toward the upper side) based on the luminous intensity of each of the inverted images 29 and 30. As a result, it is possible to eliminate light distribution unevenness in which the front side of the illumination area is particularly dark compared to the other illumination areas, and to relieve a sense of discomfort based on that.

  In the second embodiment, the rear side second light-shielding shade 27 and the front side second light-shielding shade 28 are spaced apart from each other by a predetermined distance in the front-rear direction of the optical axis L. This is to provide a gap that deviates between the two. For this reason, by adjusting the predetermined interval between the rear second light-shielding shade 27 and the front second light-shielding shade 28, the shift interval between the reversed images 29 and 30 can be adjusted in the vertical direction. In addition, the rear focal point F (second point focal point f2) of the projection lens 15 is arranged between the rear second light-shielding shade 27 and the front second light-shielding shade 28. This is because when one of the shades 27 (or 28) is arranged immediately above F (second point focal point f2), the reverse image 29 (or 30) is projected clearly.

  The light rays forming the inverted images 29 and 30 are shown in FIGS. 11 and 12. In FIGS. 11 and 12, reference numeral LB1 is the reflected light from the first reflector 20, and A light beam that passes through the rear focal point F (second focal point f2) of the projection lens 15 and forms the cutoff line CL of the upper edge of the predetermined alignment pattern P is shown. LB <b> 2 is reflected light from the first reflector 20, proceeds directly toward the projection lens 15 without passing through the rear second light shielding shade 27, and is an inverted image corresponding to the rear second light shielding shade 27. 29 shows rays forming the cut-off line CL2-1 at the upper edge. LC1 is reflected light from the second reflector 21 and directly goes to the projection lens 15 without passing through the front second light-shielding shade 28, and at the upper edge of the inverted image 30 corresponding to the front second light-shielding shade 28. The light beam which forms cut-off line CL2-2 is shown.

Although the embodiments have been described above, the present invention includes the following aspects.
(1) In the first embodiment, the second reflector 21 is not provided, and only the first reflector 20 is used.
(2) In the first embodiment, the second light-shielding shade 19 is subjected to a texture treatment on a transparent base material (for example, a glass plate or a resin plate) to form a texture treatment surface. Set so that the wrinkle processing density decreases toward the bottom. As a result, the amount of light transmitted through the second light-shielding shade 19 can be adjusted through diffusion caused by embossing.
(3) The light emitting element 16 is used without being provided on the optical axis L.
(4) The lower end height of the rear second light shielding shade 27 is different from the lower end height of the front second light shielding shade 28.

1 Vehicle headlamps 11B, 11C Low beam unit (lamp unit)
15 Projection lens 16 Light emitting element (light source)
17 Reflector 18 First Shading Shade 19 Second Shading Shade 20 First Reflector 21 Second Reflector 25 Inverted Image 26 Inverted Image 27 Rear Second Shading Shade (Second Shading Shade)
28 Front side second shading shade (second shading shade)
29 Inverted image 30 Inverted image L Optical axis P Predetermined light distribution pattern Pb Lower region of the predetermined light distribution pattern

Claims (6)

A projection lens disposed on an optical axis extending in the vehicle front-rear direction, a light source disposed behind a rear focal point of the projection lens, a reflector that reflects light from the light source toward the projection lens, and A first light-shielding shade that is disposed between the reflector and the projection lens and shields part of the reflected light from the reflector to form a predetermined light distribution pattern; and the reflector that is disposed above the first light-shielding shade. A second light-shielding shade provided with a second light-shielding shade that shields a part of the reflected light from the light and makes a light intensity of a lower region in the predetermined light distribution pattern smaller than a light intensity of other regions in the predetermined light distribution pattern In the lighting lamp unit,
The second light-shielding shade is set to increase the light intensity of the lower region in the predetermined light distribution pattern from the lower side to the upper side with respect to the light-shielding property with respect to the reflected light from the reflector.
A vehicle headlamp lamp unit characterized by the above. In claim 1,
The reflector includes at least a first reflector arranged to cover the light source and reflecting light from the light source toward the projection lens;
The second light-shielding shade is formed so that the light-shielding property decreases as it goes from the upper side to the lower side of the second light-shielding shade.
A vehicle headlamp lamp unit characterized by the above. In claim 2,
The reflector includes a second reflector that reflects the reflected light from the first reflector toward the projection lens behind the light-shielding edge in the first light-shielding shade in the optical axis direction.
A vehicle headlamp lamp unit characterized by the above. In claim 2 or 3,
The second light-shielding shade is set so that the light-shielding property decreases as it goes from the upper side to the lower side by being coated with a gradation state on the transparent base material.
A vehicle headlamp lamp unit characterized by the above. In claim 2 or 3,
The second shading shade is configured with a textured surface obtained by performing a textured process on a transparent base material,
The wrinkle treatment surface is set so that the wrinkle treatment density decreases as it goes from the upper side to the lower side.
A vehicle headlamp lamp unit characterized by the above. In claim 1,
The reflector is disposed so as to cover the light source, and is disposed behind the light shielding edge in the first light shielding shade in the optical axis direction, and a first reflector that reflects light from the light source toward the projection lens. A second reflector that reflects reflected light from the first reflector toward the projection lens;
The second light-shielding shade is disposed in a state of being separated from the rear second light-shielding shade that shields the reflected light from the first reflector by a predetermined distance forward from the rear second light-shielding shade in the optical axis direction. A front second light-shielding shade that shields reflected light from the second reflector.
A vehicle headlamp lamp unit characterized by the above.