JP7131250B2 - vehicle lamp - Google Patents

Description

The present invention relates to a vehicle lamp.

Patent Document 1 discloses a light source having an optical axis extending substantially horizontally toward the front in the light irradiation direction, a concave elliptical reflecting surface opening toward the front in the light irradiation direction, and an elliptical reflecting surface on the optical axis. and a projection lens disposed forward in the light irradiation direction, and the elliptical reflecting surface has a first focal position positioned near the light source so as to reflect the light from the light source forward in the light irradiation direction. , and the second focal position is positioned on the optical axis, and the projection lens has a convex optical surface in front of the light irradiation direction and a flat optical surface behind the light irradiation direction. It is arranged so that the focal position on the rear side of the irradiation direction is located near the second focal position, and of the optical surface on the rear side of the light irradiation direction, a predetermined area in the center in the vertical direction has a laterally extending A vehicle headlamp is disclosed in which a plurality of columnar curved portions arranged in the vertical direction are concavely or convexly provided.

In Patent Document 1, the projection lens has a convex optical surface in front of the light irradiation direction and a flat optical surface behind the light irradiation direction. In the predetermined region, a plurality of columnar curved portions extending in the horizontal direction and arranged in the vertical direction are provided concavely or convexly, so that the light emitted from the light source is incident on the optical surface behind the light irradiation direction. Of the light, the light that enters the central portion is refracted in the vertical direction by each curved portion. It is explained that the bright-dark boundary can be blurred by such a simple configuration.

JP 2012-199156 A

However, as disclosed in Patent Document 1, if a columnar body having a semicircular cross-section extending in the horizontal direction is provided on the rear surface (incident surface) of the lens, the cutoff line may be blurred more than necessary. be.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a vehicle lamp capable of appropriately blurring the cutoff line.

The present invention is grasped by the following configurations in order to achieve the above object.
(1) A vehicle lamp according to the present invention includes a first light source that emits light for low-beam distribution, a lens arranged in front of the first light source, and arranged between the first light source and the lens. a shade that forms a cutoff line of a low-beam light distribution pattern; and a reflector that reflects light from the first light source toward the lens. and an emission surface for irradiating the light forward, wherein the incidence surface is provided in a central region on which the light emitted within a predetermined range in the horizontal direction from the vertical reference line on the screen is incident. a light diffusing part; and a second light diffusing part provided in the central region and connected to the lower side of the first light diffusing part, wherein the first light diffusing part and the second light A boundary of the diffusing portion is positioned within a first range in the vertical direction for allowing the light irradiated onto the cutoff line of the incident surface to enter, and the second light diffusing portion is located in the first light diffusing portion. Wider light diffusion than

(2) In the configuration of (1) above, the boundary between the first light diffusing section and the second light diffusing section is provided at substantially the middle position in the vertical direction of the first range.

(3) In the configuration of (1) or (2) above, the vehicle lamp includes a second light source disposed between the first light source and the lens for emitting light for high beam additional light distribution, The incident surface includes a third light diffusing part provided in a region where light from at least the first light source and the second light source is incident in a horizontally outer region contiguous to the central region, has the same light diffusion width as the light diffusion width of the first light diffusion portion.

(4) In the configuration of (3) above, the first light diffusion section is provided up to the upper end in the vertical direction of the incident surface, and the second light diffusion section is provided in the vertical direction of the incident surface. It is provided up to the lower end, and the third light diffusing section is provided over the entire outer region of the incident surface.

(5) In the configuration of any one of (1) to (4) above, the light diffusing section includes rhombic prisms formed so as to protrude from the incident surface and arranged in a row without gaps, and the light is set by the protrusion height of the rhombic prism.

(6) In the configuration of any one of (1) to (5) above, the central area is an area where light emitted within a range of 10 degrees in the horizontal direction from a vertical reference line on the screen is incident. is.

(7) In any one of the configurations (1) to (6) above, the boundary between the first light diffusion section and the second light diffusion section is below the lens optical axis of the lens by 5 mm or more in the vertical direction. located on the side.

According to the present invention, it is possible to provide a vehicle lamp capable of appropriately blurring the cutoff line.

1 is a plan view of a vehicle equipped with a vehicle lamp according to an embodiment of the invention; FIG. 1 is a side view of a lamp unit according to an embodiment of the present invention; FIG. 1 is a cross-sectional view of a lighting unit according to an embodiment of the present invention; FIG. 1 is a partially exploded perspective view of a lamp unit according to an embodiment of the present invention; FIG. FIG. 2 is an exploded perspective view of the lamp unit of the embodiment according to the present invention, excluding the lens and the lens holder; It is the figure which showed typically the light distribution pattern projected on the screen of embodiment which concerns on this invention. It is a figure which shows the entrance surface of the lens (lens part) of embodiment which concerns on this invention. It is a figure for demonstrating how a cut-off line is blurred by the 1st light-diffusion part of embodiment which concerns on this invention, and a 2nd light-diffusion part.

EMBODIMENT OF THE INVENTION Hereinafter, with reference to an accompanying drawing, the form (henceforth "embodiment" is called) for implementing this invention is demonstrated in detail.
The same numbers or symbols are given to the same elements throughout the description of the embodiment.

In the embodiments and drawings, unless otherwise specified, "front" and "rear" indicate the "forward direction" and "reverse direction" of the vehicle, respectively, and "up", "down", and "left". ” and “Right” respectively indicate the direction viewed from the driver who gets into the vehicle.
Needless to say, "top" and "bottom" are also "top" and "bottom" in the vertical direction, and "left" and "right" are also "left" and "right" in the horizontal direction.

FIG. 1 is a plan view of a vehicle 102 equipped with a vehicle lamp according to an embodiment of the invention.
As shown in FIG. 1, the vehicle lamp according to the embodiment of the present invention is a vehicle headlamp (101L, 101R) provided on each of the left and right sides in front of a vehicle 102. Hereinafter, the vehicle lamp will be simply referred to as a vehicle lamp. and described.

The vehicular lamp of this embodiment includes a housing (not shown) that opens toward the front of the vehicle and an outer lens (not shown) that is attached to the housing so as to cover the opening, and is formed by the housing and the outer lens. A lamp unit 1 (see FIG. 2) and the like are arranged in the lamp chamber.

2 is a side view of the lamp unit 1, and FIG. 3 is a sectional view of the lamp unit 1 along the lamp unit optical axis (hereinafter also referred to as lamp optical axis Z) shown in FIG.
4 is a partially exploded perspective view of the lamp unit 1, and FIG. 5 is an exploded perspective view of the lamp unit 1 excluding the lens 70 and the lens holder 60. As shown in FIG.

Furthermore, FIG. 6 is a diagram schematically showing the light distribution pattern projected on the screen. Specifically, a low beam light distribution pattern LP and a high beam light distribution pattern HP (high beam additional light distribution HAP) will be described. It is a figure for doing.
Line VU-VL in FIG. 6 indicates a vertical reference line on the screen, and line HL-HR in FIG. 6 indicates a horizontal reference line on the screen.

As shown in FIGS. 3 and 5, the lamp unit 1 mainly includes a heat sink 10, a cooling fan 20, a first light source L, a reflector 30, a shade 40, a second light source H, and a reflecting member 50. , a lens holder 60 and a lens 70 .

(Heat sink 10)
The heat sink 10 is made of metal or resin having good thermal conductivity in order to efficiently dissipate the heat generated by the first light source L and the second light source H. In this embodiment, each part of the heat sink 10 described later is is a heat sink 10 made of aluminum die-cast integrally molded.
However, the heat sink 10 is not necessarily limited to the integrally molded heat sink 10 as in the present embodiment, and the heat sink 10 may be partly formed of separate parts and assembled.

The heat sink 10 includes a first base portion 12 on which the first light source L is arranged, and the heat sink 10 is positioned on the front side of the first base portion 12 and below the first base portion 12 and is inclined forward and downward. The base portion 11 has a second base portion 13 on which the second light source H is arranged.

As shown in FIG. 5, the first base portion 12 has a first light source arrangement portion 12A formed integrally with the upper surface thereof and on which the first light source L is arranged.
The first light source L arranged in the first light source arrangement portion 12A is fixed to the first light source arrangement portion 12A by a light source holder 80 fixed to the first base portion 12 with a pair of screws 12N1.

On the other hand, the front surface of the second base portion 13 facing forward receives the second light source H and forms a second light source placement portion 13A in which the second light source H is placed.
A pair of left and right positioning pins 13AA are formed in the second light source placement portion 13A so as to protrude forward, and a pair of left and right screw fixing holes 13AB are formed slightly above the positioning pins 13AA. It is

As will be described later, the second light source H, the shade 40, and the reflecting member 50 each have a pair of positioning pin insertion holes (positioning pin insertion holes H11, positioning pin insertion holes 42A, positioning pin 52A) and a pair of screw insertion holes (screw insertion hole H12, screw insertion hole 42B, screw insertion hole 52B) corresponding to the screw fixing hole 13AB. The light source H, shade 40, and reflecting member 50 are fixed to the second base portion 13 with screws 13N1.

Further, as shown in FIG. 3 , the heat sink 10 includes a plurality of heat radiation fins 11</b>F provided integrally with the base portion 11 on the lower side of the base portion 11 .
Specifically, the radiating fins 11F extend downward from the first base portion 12 and are provided integrally with the first base portion 12 and arranged in the front-rear direction. A plurality of second heat radiation fins 13</b>F extend rearward from the portion 13 and are provided integrally with the second base portion 13 and arranged horizontally.

The first heat radiating fins 12F are formed in a thin plate shape, and are formed such that the thin plate surface faces in the front-rear direction, and the air blown between the first heat radiating fins 12F from the cooling fan 20 is directed horizontally. flow in one direction.

In recent years, there has been a tendency for the rear inner wall surface of the lamp chamber in which the lamp unit 1 is arranged to be positioned near the rear of the lamp unit 1 due to the miniaturization of vehicle lamps.
In this case, if the airflow is directed rearward, the rearward inner wall surface of the lamp chamber located near the rear of the lamp unit 1 may hinder the airflow and reduce the cooling efficiency. However, such a decrease in cooling efficiency can be avoided by making the air flow in the horizontal direction as in the present embodiment.

On the other hand, the second heat radiating fins 13</b>F are formed in a thin plate shape so that the thin plate surface faces in the left-right direction (horizontal direction). It is made to flow upward along.
A horizontally elongated opening 11A opening vertically is formed between the first base portion 12 and the second base portion 13 so as not to obstruct the flow of air.

For this reason, as shown in FIG. 5, it is possible to avoid a decrease in cooling efficiency due to the influence of the pair of lens holder attachment portions 14 and the like for attaching the lens holders 60 provided on the left and right outer sides of the second base portion 13 . can be done.

In addition, as the wind flows along the second base portion 13, it absorbs heat and raises its temperature. It is possible to increase

Furthermore, the wind flows into the reflector 30 side through the opening 11A and contributes to the cooling of the space between the first base 12 and the reflector 30, so that the cooling efficiency of the first light source L can be further improved. can.

As mentioned earlier, the heat sink 10 has a pair of lens holder mounting portions 14 provided on the left and right outer sides of the second base portion 13 as shown in FIG. Each of the lens holder mounting portions 14 has a positioning pin 14A and a pair of screw fixing holes 14B vertically provided with the positioning pin 14A interposed therebetween.

As will be described later, the lens holder 60 has positioning pin insertion holes (positioning pin insertion holes 61BA, positioning pin insertion holes 62BA) corresponding to the positioning pins 14A, and screw insertion holes (screw insertion holes) corresponding to the screw fixing holes 14B. A hole 61BB and a screw insertion hole 62BB) are provided, and as shown in FIG.

As shown in FIG. 2, the heat sink 10 has a cooling fan mounting leg portion 15 formed with a screw fixing hole opening downward. is installed.

(Cooling fan 20)
The cooling fan 20 is arranged below the radiation fins 11F of the heat sink 10, as shown in FIG. .

By driving the cooling fan 20, air is sent between the plurality of radiation fins 11F, the cooling efficiency of the heat sink 10 is enhanced, and the first light source L and the second light source H can be efficiently cooled. can.

(First light source L)
The first light source L is a light source that emits light for low beam distribution, and includes a substrate L1 and one first light emitting chip L2 provided on the substrate L1.
Note that the number of first light emitting chips L2 is not necessarily limited to one, and a plurality of first light emitting chips L2 (for example, four chips) may be provided on the substrate L1.

The first light source L is arranged on the first base portion 12 so as to emit light upward. reflected to

In the present embodiment, the first light source L uses an LED light source whose first light emitting chip L2 is an LED chip, but a laser light source whose first light emitting chip L2 is an LD chip (laser diode chip). etc., and for the first light source L, a semiconductor light source is preferably used.

(Reflector 30)
As shown in FIG. 5, the reflector 30 includes a reflecting portion 30A having a reflecting surface 31 (see FIG. 3) that reflects the light from the first light source L toward the lens 70, and a reflecting portion 30A provided around the lower end of the reflecting portion 30A. and a flange portion 30B.

A pair of left and right positioning pins 12B for positioning the reflector 30 and a pair of left and right screw fixing holes 12C for fixing a pair of screws 12N2 for screw fixing the reflector 30 are provided on the first base portion 12. The flange portion 30B of the reflector 30 has a pair of left and right pin insertion holes 30BA corresponding to the positioning pins 12B and a pair of left and right screw insertion holes 30BB corresponding to the screw fixing holes 12C.

Therefore, after the reflector 30 is positioned on the first base portion 12 so as to be positioned by the positioning pin 12B, the reflector 30 is attached to the first base portion 12 by screwing the screw 12N2 into the screw fixing hole 12C. can be fixed.

As shown in FIG. 3, the reflector 30 fixed in this manner is in a state in which the front side is open and the top of the first light source L is covered in a half-dome shape. is irradiated to the lens 70 side through the opening of .

In addition, in this embodiment, a plate member 90 is provided to block the vicinity of the front side of the first light source L, and the plate member 90 is fixed to the first base portion 12 together with the reflector 30 .
The reflector 30 has a reflecting surface 31 formed in an ellipsoidal shape having two focal points. ) substantially coincides with the light emission center of the first light-emitting chip L2 of the first light source L, and the second focal point BP of the reflecting surface 31 (also referred to as the second focal point BP on the front side of the reflector 30) serving as the front focal point. ) is arranged on the first base portion 12 so as to be positioned below the shade 40 within a range overlapping the shade 40 when viewed in the front-rear direction.

(Shade 40)
As shown in FIGS. 3 and 4, the shade 40 is arranged between the first light source L and the lens 70 when viewed in the front-rear direction, and the light from the first light source L reflected by the reflector 30 to the lens 70 side. Of these, it is a member for blocking part of the light directed toward the lower side of the lens 70 and forming the cutoff line CL (see FIG. 6) of the low beam light distribution pattern LP (see FIG. 6).

Therefore, as shown in FIG. 5, the shade 40 has a shape that matches the shape of the cutoff line CL (see FIG. 6), and is positioned above the second light emitting chip H2 of the second light source H described later. A light shielding portion 41 forming a cutoff line CL (see FIG. 6) is provided.

Specifically, the cutoff line CL includes an upper horizontal cutoff line CL1 extending in the horizontal direction and an upper horizontal cutoff line CL1 extending below the clean horizontal reference line (see HL-HR line). diagonal cut-off line CL2 extending diagonally downward from the edge of the screen on the vertical reference line (see VU-VL line) toward the vertical reference line (see VU-VL line), and in the direction away from the diagonal cut-off line CL2 and a lower horizontal cutoff line CL3 extending horizontally from the edge of the diagonal cutoff line CL2 on the vertical reference line (see VU-VL line) side of the screen, and the shade 40 is provided as shown in FIG. , there is provided a light shielding portion 41 having a shape adapted to form an upper horizontal cutoff line CL1, an oblique cutoff line CL2, and a lower horizontal cutoff line CL3.

Further, the shade 40 is integrally provided at each of the left and right ends (that is, both ends) of the light shielding portion 41, and a pair of arms for fixing to the heat sink 10 (more specifically, the second base portion 13). A portion 42 is provided.

Each of the pair of left and right arm portions 42 has a positioning pin insertion hole 42A corresponding to the positioning pin 13AA of the second light source placement portion 13A of the second base portion 13, and a second light source placement portion of the second base portion 13. A screw insertion hole 42B corresponding to the screw fixing hole 13AB of 13A is formed, and as described above, it can be fixed to the second base portion 13 with the screw 13N1.

(Second light source H)
The second light source H is a light source that emits light for high beam additional light distribution, and as shown in FIG.

As shown in FIG. 5, the second light source H includes a substrate H1 and a plurality of second light emitting chips H2 provided on the substrate H1 and arranged in the horizontal direction. 6), the high beam additional light distribution HAP (see FIG. 6) formed by the light from the second light source H is added above the low beam light distribution pattern LP (see FIG. 6). , a high beam light distribution pattern HP (see FIG. 6) is formed.

For this reason, by turning on and off part or all of the second light emitting chip H2, the high beam light distribution pattern HP (more specifically, the high beam additional light distribution HAP) is controlled so as to suppress the glare to the oncoming vehicle and the preceding vehicle. A variable high beam (Adaptive Driving Beam) control that changes the state) can be performed.

In this embodiment, like the first light source L, the second light source H is also an LED light source using an LED chip as the second light emitting chip H2.

However, in the same manner as described for the first light source L, the second light emitting chip H2 may be a laser light source or the like that is an LD chip (laser diode chip), and the second light source H is preferably a semiconductor light source. used for

The substrate H1 has a pair of left and right positioning pin insertion holes H11 corresponding to the positioning pins 13AA of the second light source placement portion 13A of the second base portion 13, and screws of the second light source placement portion 13A of the second base portion 13. A pair of left and right screw insertion holes H12 corresponding to the fixing holes 13AB are formed, and as described above, it can be fixed to the second base portion 13 with the screws 13N1.

(Reflection member 50)
The reflecting member 50 is arranged below the second light emitting chip H2 and is a member that reflects part of the light from the second light emitting chip H2 toward the upper side of the lens 70. The second light source H (second A reflecting portion 51 that reflects light from the light-emitting chip (H2) toward the lens 70, and fixing portions 52 provided integrally on the left and right sides of the reflecting portion 51 for fixing to the second base portion 13 are provided. .

By reflecting the light incident on the lower side of the lens 70 by the reflecting portion 51 to the upper side of the lens 70, the high beam additional light distribution HAP formed by the light from the second light source H (second light emitting chip H2) is generated. The light distribution spreads upward.

Further, each of the pair of left and right fixing portions 52 has a positioning pin insertion hole 52A corresponding to the positioning pin 13AA of the second light source placement portion 13A of the second base portion 13, and a second light source placement portion of the second base portion 13. A screw insertion hole 52B corresponding to the screw fixing hole 13AB of 13A is formed, and as described above, it can be fixed to the second base portion 13 with the screw 13N1.

(lens holder 60)
As shown in FIGS. 3 and 4, the lens holder 60 includes a first holder 61 that receives a rear side of a lens 70 (more specifically, a flange portion 72), which will be described later, and a lens 70 (more specifically, a flange portion 72). and a second holder 62 that presses the lens 70 (more specifically, the flange portion 72) toward the first holder 61 from the front side.

The first holder 61 has a receiving portion 61AA that receives the rear side of the flange portion 72 of the lens 70 at the peripheral edge portion of the opening corresponding to the incident surface 71A of the lens 70 on which the light is incident. a first holder body portion 61A formed so that the lens 70 is positioned at a predetermined position on the front side; A pair of left and right first attachment portions 61B for fixing to 14 are provided.

A pair of left and right positioning projections 61AB that engage with a pair of left and right positioning recesses 72A of the lens 70 are provided on the receiving portion 61AA.

On the other hand, the second holder 62 has a pressing portion 62AA that presses the flange portion 72 of the lens 70 toward the receiving portion 61AA of the first holder 61. A second holder main body portion 62A externally mounted on the first holder main body portion 61A of the first holder 61, and a pair of left and right second mounting portions 62B for fixing the heat sink 10 to the pair of lens holder mounting portions 14. , is equipped with

The first mounting portions 61B of the pair of left and right first holders 61 and the second mounting portions 62B of the pair of left and right second holders 62 correspond to the positioning pins 14A of the lens holder mounting portions 14 of the heat sink 10, respectively. A positioning pin insertion hole (positioning pin insertion hole 61BA, positioning pin insertion hole 62BA) and a pair of heat sinks 10 provided above and below the positioning pin insertion hole (positioning pin insertion hole 61BA, positioning pin insertion hole 62BA). A screw insertion hole (screw insertion hole 61BB, screw insertion hole 62BB) corresponding to the screw fixing hole 14B of the lens holder mounting portion 14 is provided.

Therefore, the lens holder 60 is attached to the lens holder attachment portion 14 of the heat sink 10 with the screws 14N1 while holding the flange portion 72 of the lens 70 between the first holder 61 and the second holder 62. there is

(Lens 70)
As shown in FIGS. 3 and 4, the lens 70 is arranged in front of the first light source L when viewed in the front-rear direction. The flange portion 72 is integrally provided and, as described above, is sandwiched by the lens holder 60 (the receiving portion 61AA of the first holder 61 and the pressing portion 62AA of the second holder 62).

In addition, the flange portion 72 is provided with a pair of right and left positioning recesses 72A open to the outside for receiving the pair of left and right positioning projections 61AB provided on the receiving portion 61AA of the first holder 61 .

The lens 70 (more specifically, the lens portion 71) has an incident surface 71A on which light is incident and an output surface 71B for irradiating the incident light forward. Light from the first light source L and the second light source H is incident, and is irradiated forward from the exit surface 71B from which the incident light is emitted.

Here, as shown in FIG. 3, the second light source arrangement portion 13A of the second base portion 13 is directed obliquely forward and upward, so that the second light source H is also directed obliquely forward and upward. It's becoming

Then, by making this inclination to the oblique upper front direction appropriate, the high beam additional light distribution HAP formed by the light from the second light source H (the second light emitting chip H2) is reduced to the first light source L (the first The light from the light-emitting chip L2) is in a state of being almost inseparable from the low-beam light distribution pattern LP formed by the light.

For this reason, the lens 70 mainly corrects the overall curvature of the entire exit surface 71B below the lens optical axis O of the lens 70 (more specifically, the lens portion 71) to slightly correct the light from the first light source L. If the low beam light distribution pattern LP (see FIG. 6) formed by light is positioned slightly above (for example, about a few commas), the low beam light distribution pattern LP (see FIG. 6) and the high beam additional light distribution HAP (see FIG. 6) and , can be inseparable.

Therefore, in the present embodiment, only a slight modification of the exit surface 71B of the lens 70 is required, so that the appearance of distortion in the exit surface 71B of the lens 70 can be suppressed.

Further, in this embodiment, as shown in FIG. 3, in order to suppress the appearance of bright streaks with high luminous intensity between the low beam light distribution pattern LP and the high beam light distribution pattern HP (high beam additional light distribution HAP), The rear focal point P of the lens 70 (more specifically, the lens portion 71 ) is positioned forward of the second focal point BP, which is the front focal point of the reflector 30 .

The cutoff line CL (see FIG. 6 ) moves upward in the vertical direction, as shown in FIG. Assuming that the lens optical axis O is tilted around the rear focal point P as a rotation axis, the lens is tilted downward and forward with respect to the lamp optical axis Z, and the light emitted from the lens 70 is directed forward. The cutoff line CL appears at an appropriate position on the screen by shifting the whole downward.

Specifically, by setting the flange portion 72 of the lens 70 held by the lens holder 60 , the rear focal point P of the lens 70 (more specifically, the lens portion 71 ) becomes the front focal point of the reflector 30 . It is positioned about 0.7 mm forward of a certain second focal point BP, and the lens optical axis O is inclined forward and obliquely downward by about 0.4 degrees with respect to the lamp optical axis Z.

However, it is not necessary to be limited to the setting of the flange portion 72. For example, by setting the lens holder 60 side, the rear focal point P of the lens 70 (more specifically, the lens portion 71) is the focal point of the front side of the reflector 30. It may be positioned about 0.7 mm forward of the second focal point BP, and the lens optical axis O may be inclined forward and obliquely downward by about 0.4 degrees with respect to the lamp optical axis Z.

On the other hand, in this embodiment, a light diffusing portion capable of appropriately blurring the cutoff line CL is provided on the incident surface 71A of the lens 70 (lens portion 71), which will be described in detail below.

FIG. 7 is a diagram showing an incident surface 71A of the lens 70 (lens portion 71).
As shown in FIG. 7, the incident surface 71A is illuminated within a predetermined horizontal range from the vertical reference line (VU-VL line in FIG. 6) on the screen when viewed in the horizontal direction (horizontal direction in the figure). It has a central area ZN1 into which light is incident and an outer area ZN2 on the outer side in the horizontal direction which is connected to the central area ZN1.
In addition, in this embodiment, the diameter of the incident surface 71A is about 65 mm.

Specifically, in this embodiment, a predetermined range in the horizontal direction from the vertical reference line on the screen (VU-VL line in FIG. 6) is horizontally moved from the vertical reference line on the screen (VU-VL line in FIG. 6). Since the range RN (see FIG. 6) is within 10 degrees in the direction, the central area ZN1 illuminates the range RN within 10 degrees in the horizontal direction from the vertical reference line (VU-VL line in FIG. 6) on the screen. It is an area where the light that is applied is incident.

The incident surface 71A includes the first light diffusion part OPD1 provided in the central region ZN1 and the second light diffusion part OPD1 provided in the central region ZN1 and connected to the lower side of the first light diffusion part OPD1. and a diffusion part OPD2.

In this embodiment, the first light diffusing part OPD1 is provided up to the upper end in the vertical direction of the incident surface 71A, and the second light diffusing part OPD2 is provided up to the lower end in the vertical direction of the incident surface 71A. It is

However, the first light diffusion part OPD1 does not need to be provided up to the upper end in the vertical direction of the incident surface 71A, and is provided up to slightly above the range where the light from the first light source L is incident. All you have to do is
For example, the upper end of the first light diffusion part OPD1 may be provided so as to be positioned above the lens optical axis O within a range of 3 mm or more and 15 mm or less.

However, in this embodiment, the lens 70 is also used for light distribution control of the light from the second light source H forming the high beam additional light distribution HAP. He is trying to provide up to the upper end in the vertical direction.

In addition, since the light from the second light source H does not reach the upper end of the incidence surface 71A in the vertical direction, the light from the second light source H is also 3 mm or more and 10 mm from the upper position of the incidence surface 71A in the vertical direction. The upper end of the first light diffusion part OPD1 may be positioned within the following range.

A boundary BL between the first light diffusion portion OPD1 and the second light diffusion portion OPD2 is irradiated onto the cutoff line CL of the incident surface 71A. In this embodiment, the boundary BL between the first light diffusing part OPD1 and the second light diffusing part OPD2 It is provided at substantially the middle position of the first range W in the vertical direction.

Specifically, as shown in FIG. 6, a portion of the upper horizontal cutoff line CL1 of the cutoff line CL is located within a range of 10 degrees to the left and right from the vertical reference line (VU-VL line in FIG. 6) on the screen. , an oblique cutoff line CL2, and a part of the lower horizontal cutoff line CL3, and the width of the incident surface 71A corresponding to the width in the vertical direction between the upper horizontal cutoff line CL1 and the lower horizontal cutoff line CL3. The part is the first range W.

However, the first range W is slightly larger than the width corresponding to the vertical width between the upper horizontal cut-off line CL1 and the lower horizontal cut-off line CL3 in consideration of positional misalignment when the lens 70 is attached. A larger width (for example, a width that is wider by about 5 mm than the corresponding width as a reference) is used.

Needless to say, the width corresponding to the width in the vertical direction between the upper horizontal cut-off line CL1 and the lower horizontal cut-off line CL3 is the actual size on the screen. It does not mean the same width as the width seen in the vertical direction between CL3, but the width before being illuminated forward through the lens 70 .

Further, in this embodiment, as described above, the overall curvature of the exit surface 71B below the lens optical axis O of the lens 70 (more specifically, the lens portion 71) is slightly modified to achieve the first Since the low-beam light distribution pattern LP formed by the light from the light source L is positioned slightly above (for example, about several commas), the first range W (more precisely, the first range W (upper end) is located below the lens optical axis O of the lens 70 by 5 mm or more in the vertical direction.

In this embodiment, both the first light diffusing portion OPD1 and the second light diffusing portion OPD2 are formed to protrude from the incident surface 71A, and a plurality of rhomboidal prisms are provided so as to be connected without gaps. The second light diffusing part OPD2 has a larger light diffusion width than the first light diffusing part OPD1 due to the height of the projection of the rhombic prism.

The rhomboidal prisms provided in the first light diffusing portion OPD1 and the second light diffusing portion OPD2 have the same outer shape when viewed from the front of the incident surface 71A. , differing only in the protrusion height.

Specifically, in the present embodiment, the protrusion height of the rhombus prism of the first light diffusion part OPD1 is set to about 7 to 8 μm, and the protrusion height of the rhombus prism of the second light diffusion part OPD2 is set to about 10 μm. Thus, the second light diffusion portion OPD2 has a larger light diffusion width than the first light diffusion portion OPD1.

FIG. 8 is a diagram for explaining how the cutoff line CL is blurred by the first light diffusion part OPD1 and the second light diffusion part OPD2.

The cutoff line CL indicated by the solid line in FIG. 8 is the original cutoff line CL.
The light incident near the first range W shown in FIG. 7 is originally irradiated below the cutoff line CL shown in FIG. Since the second light diffusing part OPD2 is provided, the light is diffused when incident from the incident surface 71A, so that the light is also irradiated above the cutoff line CL.

Specifically, the light diffused by the first light diffusing part OPD1, which has a low projection height of the rhombic prism and a small light diffusion width, is irradiated from the lens 70 so as to spread to the dotted line SLM shown in FIG. be done.

On the other hand, the light diffused by the second light diffusing part OPD2, which has a rhombic prism with a high projection height and a large light diffusion width, is irradiated from the lens 70 so as to spread to the dashed-dotted line SL shown in FIG. .

Therefore, the range from the cutoff line CL to the dotted line SLM shown in FIG. 8 is a region where the light diffused by the first light diffusion part OPD1 and the light diffused by the second light diffusion part OPD2 are multiplexed. On the other hand, since the range from the dotted line SLM shown in FIG. 8 to the one-dot chain line SL shown in FIG. Since it is possible to realize a luminous intensity distribution in which the luminous intensity gradually decreases as the distance from CL increases in the vertical direction, the low-beam light distribution pattern LP with good visibility can be obtained.

Moreover, since the light diffusion width varies depending on the projection height of the rhomboidal prism, it is possible to set an appropriate light diffusion width required, and it is possible to design to avoid excessive blurring of the cutoff line CL.

On the other hand, in order not to give an uneven blurring of the light distribution pattern (low beam light distribution pattern LP, high beam light distribution pattern HP), the incident surface 71A is, for example, at least the first polarizer of the outer region ZN2 (see FIG. 7). It is preferable to provide a third light diffusion part OPD3 provided in a region where the light from the light source L and the second light source H is incident. A third light diffusing part OPD3 is provided.

Specifically, the third light diffusing part OPD3 is also formed so as to protrude from the incident surface 71A, and includes a plurality of rhombic prisms that are provided so as to be connected without gaps, and have a rhombic shape when the incident surface 71A is viewed from the front. When viewed from the rhombus shape of the prism, it has the same shape as the rhombus prisms of the first light diffusion part OPD1 and the second light diffusion part OPD2.

On the other hand, since the third light diffusing part OPD3 does not need to diffuse light greatly, the protrusion height of the rhombic prism of the third light diffusing part OPD3 is equal to the protrusion height of the rhombic prism of the first light diffusing part OPD1. (approximately 7 to 8 μm), and the light diffusion width of the third light diffusion portion OPD3 is substantially the same as the light diffusion width of the first light diffusion portion OPD1.

In this way, by providing the light diffusing portion also in the outer region ZN2, the light is partially diffused, resulting in a light distribution pattern (low beam light distribution pattern LP, high beam light distribution pattern HP) that gives a sense of discomfort. can be suppressed.

Although the present invention has been described above based on specific embodiments, the present invention is not limited to the above embodiments, and modifications and improvements have been made without departing from the technical idea. Anything is also included in the technical scope of the invention, which is obvious to a person skilled in the art from the description of the claims.

1 lamp unit 10 heat sink 11 base portion 11A opening 11F heat radiation fin 12 first base portion 12A first light source placement portion 12B positioning pin 12C screw fixing hole 12F first heat radiation fins 12N1, 12N2 screw 13 second base portion 13A second light source Placement portion 13AA Positioning pin 13AB Screw fixing hole 13F Second radiation fin 13N1 Screw 14 Lens holder mounting portion 14A Positioning pin 14B Screw fixing hole 14N1 Screw 15 Cooling fan mounting leg portion 15N1 Screw 20 Cooling fan 30 Reflector 30A Reflector 30B Flange portion 30BA Pin insertion hole 30BB Screw insertion hole 31 Reflecting surface 40 Shade 41 Light shielding part 42 Arm part 42A Positioning pin insertion hole 42B Screw insertion hole 50 Reflecting member 51 Reflecting part 52 Fixing part 52A Positioning pin insertion hole 52B Screw insertion hole 60 Lens holder 61 1 holder 61A first holder main body 61AA receiving part 61AB positioning projection 61B first mounting part 61BA positioning pin insertion hole 61BB screw insertion hole 62 second holder 62A second holder main body 62AA pressing part 62B second mounting part 62BA positioning pin insertion Hole 62BB Screw insertion hole 70 Lens 71 Lens portion 71A Entrance surface 71B Output surface 72 Flange portion 72A Positioning concave portion 80 Light source holder 90 Plate member BL Boundary BP Second focal point CL Cutoff line CL1 Upper horizontal cutoff line CL2 Diagonal cutoff line CL3 Lower horizontal Cutoff line H Second light source H1 Substrate H11 Positioning pin insertion hole H12 Screw insertion hole H2 Second light emitting chip HAP High beam additional light distribution HP High beam light distribution pattern L First light source L1 Substrate L2 First light emitting chip LP Low beam light distribution pattern O Lens Optical axis OPD1 First light diffusing part OPD2 Second light diffusing part OPD3 Third light diffusing part P Back focus RN Range within 10 degrees W First range Z Lamp optical axis ZN1 Central side area ZN2 Outer areas 101L, 101R Vehicle headlight 102 Vehicle

Claims (7)

A vehicle lamp,
The vehicle lamp includes:
a first light source that emits light for low beam distribution;
a lens arranged in front of the first light source;
a shade disposed between the first light source and the lens and forming a cutoff line of the low-beam light distribution pattern;
a reflector that reflects light from the first light source toward the lens;
The lens is
an incident surface on which light is incident;
and an emission surface for irradiating the incident light forward,
The incident surface is
a first light diffusing portion provided in a central region where light emitted within a predetermined range in the horizontal direction from a vertical reference line on the screen is incident;
a second light diffusing section provided in the central region and connected to the lower side of the first light diffusing section;
a boundary between the first light diffusing portion and the second light diffusing portion is positioned within a first range in the vertical direction for allowing the light irradiated onto the cutoff line of the incident surface to enter;
The vehicular lamp, wherein the second light diffusing portion has a light diffusion width larger than that of the first light diffusing portion. 2. The vehicular lamp according to claim 1, wherein a boundary between the first light diffusion portion and the second light diffusion portion is provided at a substantially middle position in the vertical direction of the first range. The vehicle lamp includes a second light source arranged between the first light source and the lens and emitting light for high beam additional light distribution,
The incident surface includes a third light diffusing portion provided in a region where light from at least the first light source and the second light source is incident in a horizontally outer region contiguous to the central region,
3. The vehicular lamp according to claim 1, wherein the third light diffusing portion has the same light diffusion width as the light diffusing width of the first light diffusing portion. The first light diffusing portion is provided up to the upper end of the incident surface in the vertical direction,
The second light diffusing portion is provided up to the lower end of the incident surface in the vertical direction,
4. The vehicle lamp according to claim 3, wherein the third light diffusing portion is provided on the entire outer region of the incident surface. The light diffusing portion includes a rhombic prism formed to protrude from the incident surface and provided so as to be continuous without gaps,
The vehicular lamp according to any one of claims 1 to 4, wherein the diffusion width of light is set by a protrusion height of the rhombic prism. 6. The central region is a region on which light emitted within a range of 10 degrees in the horizontal direction from a vertical reference line on the screen is incident. The vehicle lamp according to . 7. A boundary between the first light diffusing portion and the second light diffusing portion is located vertically below the lens optical axis of the lens by 5 mm or more. 1. The vehicle lamp according to item 1.

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