JP2012169182A - Vehicular headlight - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a vehicular headlight capable of improving light-distribution accuracy of a high beam light-distribution pattern and a low beam light-distribution pattern (a light-distribution pattern for a daytime running light).SOLUTION: The vehicular headlight includes a heat sink member 7, semiconductor type light sources 5U, 5D, a light source mounting member 6, a fixed reflector 3, movable reflectors 13U, 13D, a mounting bracket 4, and a drive device 14. Positioning sections 25, 26, 32, 38 for positioning each other are arranged at the light source mounting member 6, the fixed reflector 3, and the mounting bracket 4. Consequently, the vehicular headlight can improve the light-distribution accuracy of the low beam light-distribution pattern and the high beam light-distribution pattern (the light-distribution pattern for daytime running light).

Description

  The present invention relates to a low beam light distribution pattern (passing light distribution pattern) and at least a high beam light distribution pattern (running light distribution pattern), that is, a high beam light distribution pattern (running light distribution pattern) and a daytime running light. The present invention relates to a vehicle headlamp that switches between a light distribution pattern and irradiates the front of the vehicle.

  This type of vehicle headlamp has been conventionally used (for example, Patent Document 1). Hereinafter, a conventional vehicle headlamp will be described. A conventional vehicle headlamp includes a heat sink member, a semiconductor-type light source, a light source mounting member, a fixed reflector, a movable reflector, a mounting bracket, and a driving device. Hereinafter, the operation of the conventional vehicle headlamp will be described. When the semiconductor-type light source is turned on when the movable reflector is located at the first position, a low beam light distribution pattern is obtained. When the movable reflector is positioned at the second position by the driving device, a high beam light distribution pattern is obtained. Such conventional vehicle headlamps can be reduced in size, weight, power saving, and cost reduction.

  In such a vehicle headlamp, the relative positional accuracy of the semiconductor-type light source, the fixed reflector, and the movable reflector is improved, and the low beam light distribution pattern and the high beam light distribution pattern (light distribution pattern for the daytime running light) It is important to improve the light distribution accuracy.

JP 2010-108775 A

  SUMMARY OF THE INVENTION Problems to be solved by the present invention include a low beam distribution pattern and a high beam distribution pattern (daytime running) in a vehicle headlamp that can be reduced in size, weight, power saving, and cost reduction. The light distribution accuracy of the light distribution pattern is improved.

  The present invention (the invention according to claim 1) includes a heat sink member, a semiconductor light source, a light source mounting member that holds the semiconductor light source, and is mounted on the heat sink member, and a reflection made of a parabolic free curved surface. A fixed reflector having a surface and attached to a heat sink member, a movable reflector having a parabolic free-form reflecting surface, and the movable reflector is rotatably attached between a first position and at least a second position A mounting bracket that is attached to the heat sink member, and a drive device that is attached to the heat sink member and rotates the movable reflector between the first position and at least the second position. The fixed reflector and the mounting bracket are provided with positioning parts for mutual positioning. The features.

  In the invention (the invention according to claim 2), the light source mounting member is provided with a contact portion, and at least a two-stage coaxial positioning pin portion composed of a small diameter portion and a large diameter portion is provided. The mounting bracket is provided with a contact portion that contacts the contact portion of the light source mounting member, and the large-diameter positioning hole that fits into the large-diameter positioning pin portion. At least two parts are provided, and the fixed reflector is provided with an abutting part that abuts a stepped part of the positioning pin part of the light source mounting member or the mounting bracket, and is fitted to the positioning pin part of the small diameter part. It is characterized in that at least two positioning hole portions of small diameter portions to be combined are provided.

  Further, the present invention (the invention according to claim 3) is characterized in that a positioning portion for positioning the light source mounting member and the heat sink member is provided.

  In the vehicle headlamp according to the present invention (the invention according to claim 1), the light source mounting member, the fixed reflector, and the mounting bracket are positioned with high accuracy by the positioning portion. Therefore, the light source mounting member, the fixed reflector, The relative positional accuracy with respect to the mounting bracket is improved, and as a result, the light distribution accuracy of the low beam distribution pattern, the high beam distribution pattern, and the daytime running light distribution pattern can be improved.

  In the vehicle headlamp of the present invention (the invention according to claim 2), at least two large-diameter positioning hole portions of the mounting bracket are fitted into the large-diameter portion of at least two positioning pin portions of the light source mounting member. As a result, the movement of the positioning pin portion in the radial direction and the movement in the rotational direction around the positioning pin portion are restricted between the light source mounting member and the mounting bracket. In the vehicle headlamp according to the present invention (the invention according to claim 2), the abutment portion of the mounting bracket is brought into contact with the abutment portion of the light source attachment member, whereby the light source attachment member and the attachment bracket are mutually connected. The movement of the positioning pin portion in the axial fitting direction is restricted. The vehicle headlamp according to the present invention (the invention according to claim 2) is configured such that the positioning hole portion of the small-diameter portion of the fixed reflector is fitted to the small-diameter portion of the positioning pin portion of the light source mounting member. The movement of the positioning pin portion in the radial direction and the movement of the rotation direction around the positioning pin portion are restricted. And the vehicle headlamp of this invention (invention concerning Claim 2) makes the light source attachment member contact | abut the contact part of a fixed reflector to the step part or attachment bracket of the positioning pin part of a light source attachment member. And the movement in the fitting direction in the axial direction of the positioning pin portion is restricted. As a result, in the vehicle headlamp of the present invention (the invention according to claim 2), the light source mounting member, the fixed reflector, and the mounting bracket are positioned with high accuracy relative to each other, and the light source mounting member, the fixed reflector, the mounting bracket, Relative position accuracy is improved, and the light distribution accuracy of the low beam distribution pattern, the high beam distribution pattern, and the daytime running light distribution pattern can be improved.

  In the vehicle headlamp of this invention (the invention according to claim 3), the light source mounting member can be mounted on the heat sink member with high accuracy by the positioning portion, and the light source mounting member has high accuracy. The mounting bracket and the fixed reflector that are positioned on the heat sink member can be attached to the heat sink member. As a result, the vehicle headlamp according to the present invention (the invention according to claim 3) can attach the light source mounting member, the mounting bracket, and the fixed reflector, which are positioned with high accuracy to each other, to the heat sink member with high accuracy. Therefore, the relative positional accuracy of the light source mounting member, the fixed reflector, and the mounting bracket is improved, and the light distribution accuracy of the low beam distribution pattern, the high beam distribution pattern, and the daytime running light distribution pattern can be improved. .

FIG. 1 is a partially enlarged cross-sectional view of a main part showing Embodiment 1 of a vehicle headlamp according to the present invention. FIG. 2 is also a front view when the upper movable reflector and the lower movable reflector are located at the first position. FIG. 3 is also a side view when the upper movable reflector and the lower movable reflector are located at the first position (or the second position). FIG. 4 is a perspective view when the upper movable reflector and the lower movable reflector are located at the first position, similarly. FIG. 5 is also a perspective view (a perspective view seen from the opposite direction to FIG. 4) when the upper movable reflector and the lower movable reflector are located at the second position. FIG. 6 is also a front view showing the heat sink portion. FIG. 7 is also a front view showing a semiconductor light source and a light source mounting member. FIG. 8 is also a front view showing the mounting bracket. FIG. 9 is a front view showing the fixed reflector, similarly. FIG. 10 is also a plan view showing a heat sink, a semiconductor-type light source and a light source mounting member, a mounting bracket, and a fixed reflector. FIG. 11 is also an explanatory diagram showing a low beam light distribution pattern having an oblique cutoff line and a horizontal cutoff line. FIG. 12 is also an explanatory diagram showing a high beam light distribution pattern. FIG. 13 is an explanatory view showing a daylight running light distribution pattern according to a second embodiment of the vehicle headlamp according to the present invention.

  Embodiments of a vehicle headlamp according to the present invention will be described below in detail with reference to the drawings. Note that the present invention is not limited to the embodiments. In the drawing, reference sign “VU-VD” indicates vertical lines on the upper and lower sides of the screen. Reference sign “HL-HR” indicates horizontal lines on the left and right of the screen. In this specification and claims, “up, down, front, back, left, right” means “the vehicle headlight when the vehicle headlamp according to the present invention is attached to the vehicle (automobile)”. Top, bottom, front, back, left, right ".

(Description of configuration)
1 to 12 show a first embodiment of a vehicle headlamp according to the present invention. Hereinafter, the configuration of the vehicle headlamp in the first embodiment will be described. In the figure, reference numeral 1 denotes a vehicle headlamp (automobile headlamp) in the first embodiment. The vehicle headlamp 1 has a light distribution pattern for passing shown in FIG. 11 (light distribution pattern for low beam), that is, an oblique cut-off line CL1 on the traveling lane side (left side) with the elbow point E as a boundary, In addition, a low beam light distribution pattern LP having a horizontal cutoff line CL2 on the opposite lane side (right side), and a travel light distribution pattern (high beam light distribution pattern) shown in FIG. 12, that is, a first high beam light distribution pattern HP1. The second high beam light distribution pattern HP2, the third high beam light distribution pattern HP3, and the dimming low beam light distribution pattern LP1 are switched to irradiate the front of the vehicle. The angle formed between the oblique cut-off line CL1 and the horizontal line HL-HR of the screen is about 15 °.

  As shown in FIGS. 2 to 5, the vehicle headlamp 1 includes a fixed reflector 3 having an upper reflecting surface 2U and a lower reflecting surface 2D made of a parabolic free curved surface (NURBS curved surface), and a parabolic system. Upper movable reflector 13U having an upper reflective surface 12U composed of a free curved surface (NURBS curved surface) and a lower movable reflector 13D having a lower reflective surface 12D, and a planar rectangular (planar rectangular) light emitting chip (not shown) An upper semiconductor light source 5U and a lower semiconductor light source 5D (see FIG. 7), a light source mounting member (LED base) 6, a heat sink member 7, a mounting bracket 4, a driving device 14, and a lamp housing (not shown). And a lamp lens (for example, a plain outer lens).

  The fixed reflector 3, the upper movable reflector 13U, the lower movable reflector 13D, the upper semiconductor light source 5U, the lower semiconductor light source 5D, the light source mounting member 6, the heat sink member 7, the mounting bracket 4, and the The driving device 14 constitutes a lamp unit. The lamp units 3, 4, 5U, 5D, 6, 7, 13U, 13D, and 14 are disposed, for example, via an optical axis adjusting mechanism in a lamp chamber defined by the lamp housing and the lamp lens. . In addition to the lamp units 3, 4, 5U, 5D, 6, 7, 13U, 13D, and 14, other lamp units such as fog lamps, cornering lamps, clearance lamps, and turn signal lamps are disposed in the lamp chamber. May have been.

  As shown in FIGS. 6 and 10, the heat sink member 7 has a substantially rectangular plate shape in which the front portion 22 as a contact portion is vertical, and a portion from the intermediate portion to the rear portion has a fin shape. The heat sink member 7 is made of, for example, a resin member or a metal member having a high thermal conductivity. In this example, the heat sink member 7 is made of aluminum die casting.

  On the front (front) mounting surface of the front portion 22 of the heat sink member 7, the positioning holes 8 and 9 of the two light source mounting members 6 and the mounting holes 10 of the two light source mounting members 6 are provided. And four mounting boss portions (fixed boss portions) 11 of the fixed reflector 3 and four mounting boss portions (fixed boss portions) 15 of the mounting bracket 4 are provided. One of the two positioning holes 8 and 9 has a circular shape, and the other 9 has a long oval shape in the direction connecting the two positioning holes 8 and 9. At the three corners of the four corners of the heat sink member 7, an attachment portion 16 for the optical axis adjusting mechanism is provided. A mounting portion 17 of the driving device 14 is provided in the middle of the right side of the heat sink member 7 (the side on the side where one mounting portion 16 of the optical axis adjusting mechanism is provided).

  As shown in FIGS. 7 and 10, the light source mounting member 6 has a plate shape in which a rear portion 23 as a contact portion is vertical and a portion extending from the front portion to an intermediate portion 24 as a contact portion is a horizontal plate. Make a shape. The light source mounting member 6 is made of, for example, a resin member or a metal member having high thermal conductivity, and is made of aluminum die casting in this example. The upper semiconductor-type light source 5U and the lower-side semiconductor-type light source 5D are provided on the upper mounting member 18U on the upper fixing surface and the lower fixing surface of the portion from the horizontal front portion of the light source mounting member 6 to the intermediate portion 24. And the lower attachment member 18D.

  The semiconductor-type light sources 5U and 5D include a substrate (not shown), the light emitting chip provided on the substrate, and a thin rectangular parallelepiped sealing resin member (not shown) for sealing the light emitting chip. , Is composed of. The light emitting chip is formed by arranging a plurality of square chips in the horizontal axis direction. A single rectangular chip may be used.

  Two positioning pin portions 19 of the heat sink member 7 are provided on the rear surface (back surface) of the rear portion 23 of the light source mounting member 6. The two positioning pin portions 19 have a small diameter cylindrical shape. The outer diameters of the two positioning pin portions 19 are substantially equal to or slightly smaller than the inner diameters of the two positioning hole portions 8 and 9. By fitting the two positioning pin portions 19 of the light source mounting member 6 into the two positioning hole portions 8 and 9 of the heat sink member 7, the two positioning pin portions 19 and the positioning hole portions are provided. The movement in the radial direction of 8 is regulated to perform positioning in the vertical direction and the horizontal direction, and the movement in the rotational direction around the positioning pin portion 19 and the positioning hole portion 8 is regulated to perform positioning in the rotational direction. Made. In addition, when the rear surface of the rear portion 23 of the light source mounting member 6 contacts the front surface of the front portion 22 of the heat sink member 7, the rearward movement is restricted from the front, and the rearward positioning is performed. As a result, the light source mounting member 6 and the heat sink member 7 are positioned with high accuracy relative to each other.

  Attachment pieces 20 are respectively provided on the left and right ends of the rear portion 23 of the light source attachment member 6. The two attachment pieces 20 are provided with small circular through holes 33. By screwing the screw 21 into the mounting hole 10 through the through hole 33 of the mounting piece 20, the light source mounting member 6 positioned with high accuracy is attached (fixed) to the heat sink member 7. .

  Two stages of coaxial positioning pin portions 25 and 26 each having a small-diameter portion 25 and a large-diameter portion 26 are provided on the front surfaces (front surfaces) of the right and left ends of the intermediate portion 24 of the light source mounting member 6. A step portion 27 is formed between the small diameter portion 25 and the large diameter portion 26 of the two positioning pin portions 25, 26. The two positioning pin portions 25 and 26 have a cylindrical shape having the stepped portion 27.

  As shown in FIGS. 8 and 10, the mounting bracket 4 includes an intermediate first mounting portion 28 as a contact portion, and left and right end portions formed by bending the left and right end portions of the first mounting portion 28 forward. The second mounting portion 29 and the third mounting portion 30 provided above and below the right side second mounting portion 29. A square opening 31 is provided at the center of the first mounting portion 28. A circular large-diameter positioning hole 32 is provided in the middle of the left and right sides of the first mounting portion 28. The inner diameters of the two large-diameter positioning holes 32 are substantially equal to or slightly larger than the outer diameter of the large-diameter positioning pin portion 26. By fitting the positioning holes 32 of the two large diameter portions of the mounting bracket 4 to the positioning pin portions 26 of the two large diameter portions of the light source mounting member 6, the two large diameter portions The positioning holes 32 and the positioning pins 26 of the two large-diameter portions are regulated in the radial direction so as to be positioned in the vertical and horizontal directions, and the positioning holes of the two large-diameter portions 32 and the positioning pin portion 26 of the large-diameter portion are restricted to move in the rotational direction, thereby positioning in the rotational direction. In addition, the rear surface of the first mounting portion 28 of the mounting bracket 4 abuts against the front surface of the intermediate portion 24 of the light source mounting member 6 so that the rearward movement is restricted from the front, and the rearward positioning is performed. The As a result, the mounting bracket 4 and the light source mounting member 6 are positioned with high accuracy relative to each other. The mounting bracket 4 and the heat sink member 7 are positioned with high accuracy with respect to each other via the light source mounting member 6.

  Small circular through holes 34 are provided at the four corners of the first mounting portion 28 of the mounting bracket 4. By screwing the screw 40 into the mounting boss portion 15 through the through hole 34 of the first mounting portion 28, the mounting brackets 4 positioned with high accuracy are connected to the heat sink member via the light source mounting member 6. 7 (fixed).

  As shown in FIGS. 9 and 10, the fixed reflector 3 is made of, for example, a light-impermeable resin member. The fixed reflector 3 has a substantially parabolic shape. The front side of the fixed reflector 3 is opened in a substantially circular shape. On the other hand, the rear side 36 as a contact portion of the fixed reflector 3 is closed. A horizontally elongated substantially rectangular window portion 37 is provided at an intermediate portion of the closing portion 36 of the fixed reflector 3. A circular small-diameter positioning hole 38 is provided at each of the left and right ends of the intermediate portion of the closing portion 36 of the fixed reflector 3. The inner diameters of the two small-diameter positioning holes 38 are substantially equal to or slightly larger than the outer diameter of the small-diameter positioning pin portion 25. By fitting the positioning holes 38 of the two small diameter portions of the fixed reflector 3 to the positioning pin portions 25 of the two small diameter portions of the light source mounting member 6, the positioning holes of the two small diameter portions The movement in the radial direction of the positioning pin portion 25 of the portion 38 and the two small diameter portions is restricted so that the vertical and horizontal positioning is performed, and the positioning holes 38 of the two small diameter portions and the small diameter portion The movement in the rotational direction around the positioning pin portion 25 is restricted and positioning in the rotational direction is performed. In addition, when the rear surface of the blocking portion 36 of the fixed reflector 3 comes into contact with the front surface of the intermediate portion 24 of the light source mounting member 6, the rearward movement is restricted from the front, and the rearward positioning is performed. As a result, the fixed reflector 3 and the light source mounting member 6 are positioned with high accuracy relative to each other. The fixed reflector 3 and the heat sink member 7 are positioned with high accuracy with respect to each other via the light source mounting member 6. At this time, the light source mounting member 6 is inserted and positioned in the window portion 37 of the fixed reflector 3.

  Four mounting legs 39 are provided on the outer side (rear side) of the closed portion of the fixed reflector 3. The mounting leg portion 39 is provided with a small circular through hole 35. By screwing the screw 41 into the mounting boss portion 11 through the through hole 35 of the mounting leg portion 39, the fixed reflector 3 positioned with high accuracy can be connected to the heat sink member 7 via the light source mounting member 6. Attached (fixed).

  The upper reflecting surface 2U of the fixed reflector 3, the upper reflecting surface 12U of the upper movable reflector 13U, and the upper semiconductor light source 5U constitute an upper unit in which the light emitting surface of the light emitting chip is upward in the vertical axis direction. . Further, the lower reflective surface 2D of the fixed reflector 3, the lower reflective surface 12D of the lower movable reflector 13D, and the lower semiconductor light source 5D are such that the light emitting surface of the light emitting chip is downward in the vertical axis direction. Configure the lower unit. The upper units 2U, 5U, 12U, and 13U and the lower units 2D, 5D, 12D, and 13D are point-symmetric about the rotation axis of the fixed reflector 3 that has a substantially parabolic shape. It is arranged to be in a state. The reflective surface design of the upper reflective surfaces 2U and 12U and the reflective surface design of the lower reflective surfaces 2D and 12D are not mere point symmetry (inversion).

  The upper reflective surface 2U and the lower reflective surface 2D are respectively provided on the upper side and the lower side of the window 37 within the closed portion 36 of the fixed reflector 3. The upper reflecting surface 2U and the lower reflecting surface 2D made of parabolic free-form surfaces (NURBS curved surfaces) have a reference focus (pseudo focus) and a reference optical axis (pseudo optical axis).

  The upper reflective surface 2U and the lower reflective surface 2D of the fixed reflector 3 are a low-beam reflective surface that forms the low-beam light distribution pattern LP and the dimming low-beam light distribution pattern LP1, and the first high-beam reflective surface. The first high beam reflecting surface and the second high beam reflecting surface that form the light distribution pattern HP1 and the second high beam light distribution pattern HP2.

  The upper movable reflector 13U and the lower movable reflector 13D are attached to the second attachment portion 29 of the attachment bracket 4 so as to be rotatable about a horizontal axis. The upper movable reflector 13U and the lower movable reflector 13D are made of, for example, a light-impermeable resin member. The upper movable reflector 13U and the lower movable reflector 13D located at the second position have a substantially parabolic shape with the rotation axis of the fixed reflector 3 having a substantially parabolic shape as a rotation axis. The front sides of the upper movable reflector 13U and the lower movable reflector 13D located at the second position are opened in a substantially circular shape.

  Semicircular through holes are respectively provided in the central portions of the upper movable reflector 13U and the lower movable reflector 13D. In addition, rectangular flanges are integrally provided in the middle part of the periphery of the upper movable reflector 13U and the lower movable reflector 13D. The upper reflective surface 12U and the lower reflective surface 12D are respectively provided on the surfaces of the upper movable reflector 13U and the lower movable reflector 13D that face the upper semiconductor light source 5U and the lower semiconductor light source 5D. Is provided. The upper reflecting surface 12U and the lower reflecting surface 12D, which are parabolic free-form surfaces (NURBS curved surfaces), have a reference focus (pseudo focus) and a reference optical axis (pseudo optical axis).

  The upper reflective surface 12U of the upper movable reflector 13U and the lower reflective surface 12D of the lower movable reflector 13D are configured by a third high beam reflective surface that forms the third high beam light distribution pattern HP3. .

  The drive device 14 is attached to the third attachment portion 30 of the attachment bracket 4 and the attachment portion 17 of the heat sink member 7. The driving device 14 includes a motor (not shown), a driving force transmission mechanism (not shown), and a movable reflector return spring (not shown). The driving force transmission mechanism is provided between the motor and the upper movable reflector 13U and the lower movable reflector 13D. The drive device 14 moves the upper movable reflector 13U and the lower movable reflector 13D to a first position (position shown in FIGS. 2 and 4) around the horizontal axis with respect to the light source mounting member 6. And the second position (the position in the state shown in FIG. 5).

  When the movable reflectors 13U and 13D are located at the first position, the light emitted from the light emitting chip to the first high beam reflecting surface of the fixed reflector 3 and the second high beam for the fixed reflector 3 The reflected light reflected by the reflecting surface is shielded by the movable reflectors 13U and 13D. As a result, the reflected light L3 reflected by the low beam reflecting surface of the fixed reflector 3 is irradiated in front of the vehicle as the low beam light distribution pattern LP (passing light distribution pattern) shown in FIG.

  When the movable reflectors 13U and 13D are positioned at the second position, the reflected light reflected by the third high beam reflecting surfaces (the reflecting surfaces 12U and 12D) of the movable reflectors 13U and 13D is shown in FIG. As the third high beam light distribution pattern HP3, the reflected light reflected by the first high beam reflective surface and the second high beam reflective surface of the fixed reflector 3 is the first high beam light distribution pattern shown in FIG. As HP1, the second high beam light distribution pattern HP2, and the reflected light reflected by the low beam reflection surface of the fixed reflector 3 as the dimming low beam light distribution pattern LP1 shown in FIG. Irradiated forward. As shown in FIG. 12, the first high beam light distribution pattern HP1, the second high beam light distribution pattern HP2, the third high beam light distribution pattern HP3, and the dimming low beam light distribution pattern LP1 are used. A light distribution pattern (running light distribution pattern) is formed and irradiated to the front of the vehicle.

  When the movable reflectors 13U and 13D are positioned at the second position, a part of light emitted from the light emitting chip to the low-beam reflecting surface of the fixed reflector 3 is shielded by the movable reflectors 13U and 13D. And it is reflected as reflected light by the third high beam reflecting surfaces (the reflecting surfaces 12U and 12D) of the movable reflectors 13U and 13D. That is, part of the light from the light emitting chip 4 is switched from the dimming low beam light distribution pattern LP1 to the third high beam light distribution pattern HP3. For this reason, the light amount of the dimming low beam light distribution pattern LP1 shown in FIG. 12 is smaller than the light amount of the low beam light distribution pattern LP shown in FIG. On the other hand, when the movable reflectors 13U and 13D are positioned at the first position, the light from the light emitting chip that has been shielded by the movable reflectors 13U and 13D is the first high-beam light distribution pattern HP1 and the second light distribution pattern HP1. It is used as a high beam light distribution pattern HP2. At this time, the reflecting surfaces 12U and 12D of the movable reflectors 13U and 13D are located in a high energy range in the energy distribution of the light emitting chip. As a result, the light quantity of the high beam light distribution pattern (running light distribution pattern) HP1, HP2, HP3, LP1 shown in FIG. 12 is the same as the low beam light distribution pattern (passing light distribution pattern) shown in FIG. ) It becomes larger than the light quantity of LP.

(Description of action)
Hereinafter, the vehicle headlamp 1 according to the first embodiment is configured as described above, and the operation thereof will be described below.

  First, the upper movable reflector 13U and the lower movable reflector 13D are positioned at the first position (the position shown in FIGS. 2 and 4). That is, when energization of the motor of the drive device 14 is interrupted, the upper movable reflector 13U and the lower movable reflector 13D are positioned at the first position by the action of the spring and the action of a stopper (not shown). At this time, the light emitting chips of the upper semiconductor light source 5U and the lower semiconductor light source 5D are turned on. Then, light is emitted from the light emitting chips of the upper semiconductor light source 5U and the lower semiconductor light source 5D.

  Part of this light, that is, the light emitted to the first high beam reflecting surface of the fixed reflector 3 is shielded by the upper movable reflector 13U and the lower movable reflector 13D. Further, a part of this light, that is, the reflected light reflected by the second high beam reflecting surface of the fixed reflector 3 is shielded by the upper movable reflector 13U and the lower movable reflector 13D. Further, the remaining light is reflected by the low-beam reflecting surfaces of the upper reflecting surface 2U and the lower reflecting surface 2D of the fixed reflector 3. This reflected light is irradiated in front of the vehicle as a low beam light distribution pattern LP shown in FIG. Direct light (not shown) from the light emitting chips of the upper semiconductor light source 5U and the lower semiconductor light source 5D is shielded by the flanges of the upper movable reflector 13U and the lower movable reflector 13D. As described above, the low beam light distribution pattern LP shown in FIG. 11 is irradiated in front of the vehicle.

  Next, the upper movable reflector 13U and the lower movable reflector 13D are positioned at the second position (position shown in FIG. 5). That is, when the motor of the driving device 14 is energized to drive the motor, the driving force of the motor is transmitted to the upper movable reflector 13U and the lower movable reflector 13D via the driving force transmission mechanism, and the upper movable reflector 13U and the lower movable reflector 13U. The side movable reflector 13D rotates in synchronization with the second position against the spring force and is positioned at the second position by the action of a stopper (not shown). At this time, the light emitting chips of the upper semiconductor light source 5U and the lower semiconductor light source 5D are turned on. Then, light is emitted from the light emitting chips of the upper semiconductor light source 5U and the lower semiconductor light source 5D.

  Part of this light, which is part of the light emitted to the low-beam reflecting surfaces of the upper reflecting surface 2U and the lower reflecting surface 2D of the fixed reflector 3, is the third high-beam reflecting surface of the movable reflectors 13U, 13D. Reflected by the (reflecting surfaces 12U, 12D), the reflected light is irradiated in front of the vehicle as the third high beam light distribution pattern HP3 shown in FIG. Further, the light is emitted to the low-beam reflecting surfaces of the upper reflecting surface 2U and the lower reflecting surface 2D of the fixed reflector 3, and is applied to the third high-beam reflecting surfaces (reflecting surfaces 12U and 12D) of the movable reflectors 13U and 13D. The remaining light that has not entered is reflected by the low-beam reflecting surface of the fixed reflector 3, and the reflected light L3 is applied to the front of the vehicle as a dimming low-beam light distribution pattern LP1 shown in FIG. Further, when the upper movable reflector 13U and the lower movable reflector 13D are positioned at the first position, the first high beam reflecting surface of the fixed reflector 3 that is shielded by the upper movable reflector 13U and the lower movable reflector 13D is provided. The emitted light is reflected by the first high beam reflecting surface of the fixed reflector 3, and the reflected light is irradiated to the front of the vehicle as a first high beam light distribution pattern HP1 shown in FIG. Furthermore, when the upper movable reflector 13U and the lower movable reflector 13D are located at the first position, the second high beam reflecting surface of the fixed reflector 3 that is shielded by the upper movable reflector 13U and the lower movable reflector 13D. The reflected light from the light passes through a gap formed between the upper movable reflector 13U and the lower movable reflector 13D located at the second position, and is transmitted to the front of the vehicle as a second high beam light distribution pattern HP2 shown in FIG. Irradiated. As described above, the high beam light distribution patterns HP1, HP2, HP3, and LP1 shown in FIG.

(Explanation of effect)
The vehicle headlamp 1 according to the first embodiment is configured and operated as described above, and the effects thereof will be described below.

  The vehicle headlamp 1 according to the first embodiment includes a positioning portion (a positioning pin portion 25 of a small diameter portion of the light source mounting member 6, a positioning pin portion 26 of a large diameter portion, and a positioning hole portion 38 of a small diameter portion of the fixed reflector 3. And the light source mounting member 6, the fixed reflector 3, and the mounting bracket 4 are positioned with high accuracy relative to each other by the large-diameter positioning hole 32) of the mounting bracket 4, so that the light source mounting member 6, the fixed reflector 3 and The relative positional accuracy with respect to the mounting bracket 4 is improved, and as a result, the light distribution accuracy of the low beam light distribution pattern LP and the high beam light distribution patterns HP1, HP2, HP3, LP1 can be improved.

  In particular, in the vehicle headlamp 1 according to the first embodiment, the positioning holes 32 of the two large diameter portions of the mounting bracket 4 are formed in the large diameter portions 26 of the two positioning pin portions 25, 26 of the light source mounting member 6. , The movement between the light source mounting member 6 and the mounting bracket 4, and the movement of the positioning pin portion 26 in the radial direction, that is, the vertical and horizontal directions, and the positioning pin portion 26 as the center. The movement in the rotating direction is restricted. And the vehicle headlamp 1 in this Example 1 makes the intermediate | middle part 24 as a contact part of the light source attachment member 6 contact | abut the 1st attachment part 28 as a contact part of the attachment bracket 4, It is a movement between the light source mounting member 6 and the mounting bracket 4, and the axial fitting direction of the positioning pin portion 25, that is, the movement from the front to the rear is restricted. In addition, the vehicle headlamp 1 according to the first embodiment is configured such that the positioning hole portion 38 of the small-diameter portion of the fixed reflector 3 is fitted to the small-diameter portion 25 of the positioning pin portions 25 and 26 of the light source mounting member 6. It is a movement between the mounting member 6 and the fixed reflector 3, and the movement of the positioning pin portion 25 in the radial direction, that is, the vertical and horizontal directions, and the rotation direction around the positioning pin portion 25 are restricted. The In addition, the vehicle headlamp 1 according to the first embodiment has a first mounting as a mounting portion of the mounting pin 4 or the stepped portion 27 (see FIG. 1B) of the positioning pin portions 25 and 26 of the light source mounting member 6. When the closing portion 36 as the contact portion of the fixed reflector 3 is brought into contact with the portion 28 (see FIG. 1A), the movement between the light source mounting member 6 and the fixed reflector 3 is achieved. The axial direction fitting direction of the portion 25, that is, the movement from the front to the rear is restricted. In the vehicle headlamp 1 according to the first embodiment, the light source mounting member 6, the fixed reflector 3, and the mounting bracket 4 are positioned with high accuracy relative to each other, and the light source mounting member 6, the fixed reflector 3, and the mounting bracket 4 are relative to each other. The positional accuracy is improved, and the light distribution accuracy of the low beam light distribution pattern LP and the high beam light distribution patterns HP1, HP2, HP3, LP1 can be improved.

  Further, in the vehicle headlamp 1 according to the first embodiment, the light source mounting member 6 is attached to the heat sink member 7 by positioning portions (the positioning pin portion 19 of the light source mounting member 6 and the positioning holes 8 and 9 of the heat sink member 7). The mounting bracket 4 and the fixed reflector 3 that can be mounted in a state of being positioned with high accuracy and that are positioned with high accuracy on the light source mounting member 6 can be mounted on the heat sink member 7. As a result, the vehicle headlamp 1 according to the first embodiment can attach the light source attachment member 6, the attachment bracket 4, and the fixed reflector 3 that are positioned with high accuracy to the heat sink member 7 with high accuracy. The relative positional accuracy of the light source mounting member 6, the fixed reflector 3, and the mounting bracket 4 is improved, and the light distribution accuracy of the low beam light distribution pattern LP and the high beam light distribution patterns HP1, HP2, HP3, and LP1 can be improved. it can.

(Description of Example 2)
FIG. 13 shows a second embodiment of a vehicle headlamp according to the present invention. Hereinafter, the vehicle headlamp in the second embodiment will be described. In the figure, the same reference numerals as those in FIGS. 1 to 12 denote the same components.

  The vehicle headlamp 1 according to the first embodiment can obtain the high beam light distribution patterns HP1, HP2, HP3, and LP1 when the movable reflectors 13U and 13D are located at the second position. On the other hand, in the vehicle headlamp according to the second embodiment, when the movable reflectors 13U and 13D are at least in the second position, that is, when the movable reflectors 13U and 13D are located in the second position, the high beam distribution is performed as described above. When the light patterns HP1, HP2, HP3, LP1 are obtained and the movable reflectors 13U, 13D are located at the third position, as shown in FIG. 13, the light distribution patterns DP1, DP2, DP3, DP4 for the daytime running light, DP5 is obtained.

(Description of examples other than Examples 1 and 2)
In the first and second embodiments, the low beam light distribution pattern LP will be described. However, in the present invention, a light distribution pattern other than the low beam light distribution pattern LP, for example, a highway light distribution pattern, a fog lamp light distribution pattern, etc., has an oblique cut-off line on the traveling lane side at the elbow point. And a light distribution pattern having a horizontal cut-off line on the opposite lane side.

  Moreover, in the said Example 1, 2, the vehicle headlamp 1 for left side driving lanes is demonstrated. However, the present invention can also be applied to a vehicle headlamp for the right lane.

  Further, in the first and second embodiments, the upper unit composed of the upper reflective surfaces 2U and 12U and the upper semiconductor light source 5U, and the lower unit composed of the lower reflective surfaces 2D and 12D and the lower semiconductor light source 5D. The vehicle headlamp 1 in which the units are arranged in a point-symmetric state will be described. However, in the present invention, the vehicle headlamp composed of only the upper unit composed of the upper reflecting surfaces 2U and 12U and the upper semiconductor light source 5U, or the lower reflecting surfaces 2D and 12D and the lower semiconductor type. The vehicle headlamp comprised only from the lower unit which consists of light source 5D may be sufficient.

DESCRIPTION OF SYMBOLS 1 Vehicle headlamp 2U Upper reflective surface 2D Lower reflective surface 3 Fixed reflector 4 Mounting bracket 5U Upper semiconductor type light source 5D Lower semiconductor type light source 6 Light source mounting member 7 Heat sink member 8 Positioning hole portion 9 Positioning hole portion 10 Mounting hole Part 11 Mounting boss part 12U Upper reflecting surface (third high beam reflecting surface)
12D Lower reflective surface (3rd high beam reflective surface)
13U Upper movable reflector 13D Lower movable reflector 14 Drive device 15 Mounting boss portion 16 Mounting portion 17 Mounting portion 18U Upper mounting member 18D Lower mounting member 19 Positioning pin portion 20 Mounting piece 21 Screw 22 Front portion 23 Rear portion 24 Intermediate portion 25 Small diameter Positioning pin part 26 large-diameter positioning pin part 27 step part 28 first attachment part 29 second attachment part 30 third attachment part 31 opening part 32 large-diameter part positioning hole part 33 through-hole 34 through-hole 35 through-hole Hole 36 Blocking part (rear side)
37 Window part 38 Positioning hole part of small diameter part 39 Mounting leg part 40 Screw 41 Screw E Elbow point CL1 Oblique cut-off line CL2 Horizontal cut-off line LP Low beam light distribution pattern LP1 Dimming low beam light distribution pattern (High beam light distribution pattern)
HP1 Light distribution pattern for first high beam HP2 Light distribution pattern for second high beam HP3 Light distribution pattern for third high beam HL-HR Horizontal lines on the left and right of the screen VU-VD Vertical lines on the top and bottom of the screen DP1 Distribution for the first daytime running light Light pattern DP2 Light distribution pattern for second daytime running light DP3 Light distribution pattern for third daytime running light DP4 Light distribution pattern for fourth daytime running light DP5 Light distribution pattern for fifth daytime running light

Claims (3)

In a vehicle headlamp that switches between a low beam distribution pattern and a high beam distribution pattern and irradiates the front of the vehicle,
A heat sink member;
A semiconductor light source;
A light source mounting member that holds the semiconductor-type light source and is attached to the heat sink member;
A fixed reflector having a reflecting surface made of a parabolic free-form surface and attached to the heat sink member;
A movable reflector having a reflecting surface made of a parabolic free-form surface;
A mounting bracket attached to the heat sink member, wherein the movable reflector is rotatably mounted between a first position and at least a second position;
A drive device attached to the heat sink member for rotating the movable reflector between a first position and at least a second position;
With
The light source mounting member, the fixed reflector, and the mounting bracket are provided with positioning portions that position each other.
A vehicle headlamp characterized by that. The light source mounting member is provided with a contact portion, and at least two coaxial positioning pin portions each having a small diameter portion and a large diameter portion are provided.
The mounting bracket is provided with an abutting portion that abuts on the abutting portion of the light source mounting portion, and at least a large-diameter positioning hole portion that fits into the positioning pin portion of the large-diameter portion. Two are provided,
The fixed reflector is provided with a contact portion that contacts the stepped portion of the positioning pin portion or the mounting bracket of the light source mounting portion, and a small diameter portion that fits into the positioning pin portion of the small diameter portion. At least two positioning holes are provided,
The vehicle headlamp according to claim 1. The light source mounting member and the heat sink member are provided with positioning portions that position each other.
The vehicle headlamp according to claim 1 or 2, characterized in that

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