JP2014086301A - Vehicle headlight - Google Patents

Abstract

PROBLEM TO BE SOLVED: To achieve downsizing in the front-back direction.SOLUTION: A vehicle headlight comprises: a lighting fixture casing 4 constituted by a lamp housing 2 having an opening on at least one side and a cover 3 covering the opening of the lamp housing; a holding plate 12 that can rotate in at least either the vertical direction or the left-right direction; a lighting fixture unit 6 that is connected to the holding plate and has a light source 10b; and an optical axis adjustment mechanism 16 that is arranged below the lighting fixture unit and adjusts the orientation of the optical axis of the lighting fixture unit.

Description

  The present invention relates to a vehicle headlamp. More specifically, the present invention relates to a technical field relating to a vehicle headlamp including a lamp unit and a light amount adjustment mechanism.

JP 2001-130315 A

  Some vehicle headlamps include, for example, a lamp unit having a light source or the like disposed inside a lamp outer casing constituted by a cover and a lamp housing.

  An optical axis adjustment mechanism such as an aiming mechanism that performs initial adjustment of the direction of the optical axis and a leveling mechanism that adjusts the direction of the optical axis that changes according to the weight of a vehicle-mounted object is disposed in the vehicle headlamp. There are some (see, for example, Patent Document 1).

  In the vehicle headlamp described in Patent Document 1, an aiming mechanism and a leveling mechanism are provided, and the aiming mechanism and the leveling mechanism are arranged on the rear side of the lamp unit.

  However, when the optical axis adjustment mechanism is disposed on the rear side of the lamp unit as in the vehicle headlamp described in Patent Document 1, the lamp unit and the optical axis adjustment mechanism are positioned forward and backward. The entire vehicle headlamp is long in the front-rear direction and hinders downsizing.

  Particularly, since the optical axis adjusting mechanism is provided with an aiming axis and a leveling axis that extend in the front-rear direction, the size (length) in the front-rear direction tends to increase.

  Accordingly, an object of the vehicle headlamp of the present invention is to overcome the above-described problems and to reduce the size in the front-rear direction.

  In order to solve the above-described problem, a vehicle headlamp includes a lamp outer casing that includes a lamp housing having an opening on at least one side and a cover that covers the opening of the lamp housing, and a vertical or horizontal direction. A holding plate that is rotatable at least one of them, a lamp unit that is attached to the holding plate and has a light source, and an optical axis adjustment that is disposed below the lamp unit and adjusts the direction of the optical axis of the lamp unit And a mechanism.

  Therefore, in the vehicle headlamp, the lamp unit and the optical axis adjusting mechanism are positioned up and down.

  The vehicle headlamp according to the present invention has a lamp outer housing constituted by a lamp housing having an opening in at least one and a cover covering the opening of the lamp housing, and rotates in at least one of the vertical direction and the horizontal direction. A holding plate made possible, a lamp unit having a light source attached to the holding plate, and an optical axis adjusting mechanism that is arranged below the lamp unit and adjusts the direction of the optical axis of the lamp unit. Features.

  Accordingly, since the lamp unit and the optical axis adjusting mechanism are arranged vertically, it is possible to reduce the size in the front-rear direction.

  In the invention described in claim 2, the holding plate is rotatable in one of the vertical direction and the horizontal direction, and supports the holding plate so as to be rotatable in the vertical direction and the horizontal direction. A support plate that is rotatable in the other of the lamp housing in the vertical direction or the horizontal direction is provided, and the holding plate is rotated in one of the vertical direction or the horizontal direction to adjust the optical axis adjusting mechanism. The optical axis is adjusted in the vertical direction or the horizontal direction, and the support plate and the holding plate are integrally rotated to the other of the vertical direction or the horizontal direction by the optical axis adjustment mechanism. Adjustment of the vertical direction or the horizontal direction of the optical axis is performed.

  Accordingly, since the vertical rotation shaft and the horizontal rotation shaft are provided on different members, a torsional moment is unlikely to occur during the vertical and horizontal rotation, and smooth operation can be ensured. it can.

  In the invention described in claim 3, the holding plate and the support plate are arranged vertically.

  Therefore, further downsizing in the front-rear direction can be achieved.

  In the invention described in claim 4, the holding plate is provided with a holding portion for holding the lamp unit, and the holding portion is formed in a frame shape penetrating in the vertical direction.

  Therefore, it is possible to reduce the weight of the vehicle headlamp while ensuring high rigidity of the holding plate.

  In the invention described in claim 5, a vertical pivot point is integrally provided on the holding plate.

  Therefore, the manufacturing cost can be reduced by reducing the number of parts.

FIG. 2 to FIG. 12 show an embodiment of the present invention, and this figure is a side view showing a part of a vehicle headlamp in a first embodiment in section. It is a perspective view which shows the holding plate and optical axis adjustment mechanism in 1st Embodiment. It is a disassembled perspective view which shows the holding plate and optical axis adjustment mechanism in 1st Embodiment. It is a side view which shows a part of vehicle headlamp in 2nd Embodiment in cross section. It is a perspective view which shows the optical axis adjustment mechanism in 2nd Embodiment. It is a disassembled perspective view which shows the holding plate and optical axis adjustment mechanism in 2nd Embodiment. It is a perspective view which shows another example of the holding plate and optical axis adjustment mechanism in 2nd Embodiment. It is a perspective view which shows the vehicle headlamp in 3rd Embodiment. It is a disassembled perspective view which shows the holding plate and optical axis adjustment mechanism in 3rd Embodiment. It is a perspective view which shows the vehicle headlamp in 4th Embodiment. It is a disassembled perspective view which shows the holding plate and optical axis adjustment mechanism in 4th Embodiment. It is an enlarged side view which shows the structure where the urging | biasing part was provided.

  EMBODIMENT OF THE INVENTION Below, the form for implementing the vehicle headlamp of this invention is demonstrated with reference to an accompanying drawing.

<First Embodiment>
First, the vehicle headlamp 1 according to the first embodiment will be described (see FIGS. 1 to 3).

  The vehicle headlamps 1 are respectively attached to the left and right end portions of the front end portion of the vehicle body.

  The vehicle headlamp 1 includes a lamp housing 2 having a recessed portion opened forward and a cover 3 that closes the opening of the lamp housing 2 (see FIG. 1). The lamp housing 2 and the cover 3 constitute a lamp outer casing 4, and the inner space of the lamp outer casing 4 is formed as a lamp chamber 5.

  The lamp unit 6 includes a lens holder 7, a projection lens 8 held by the lens holder 7, a reflector 9 that reflects light, a light source unit 10 disposed below the reflector 9, and a cooling fan attached to the lower surface of the light source unit 10. 11.

  The lens holder 7 includes a substantially annular lens mounting portion 7a penetrating in the front-rear direction, side portions 7b, 7b,... 7b, 7b,... And a holding plate portion 7c provided between them.

  The projection lens 8 is formed in a substantially hemispherical shape and is attached to the lens attachment portion 7 a of the lens holder 7.

  The inner surface of the reflector 9 is formed as a reflecting surface. The reflector 9 is attached to the upper surface of the light source unit 10.

  The light source unit 10 is attached to the holding plate portion 7c of the lens holder 7, and has a circuit board 10a and a light source 10b mounted on the upper surface of the circuit board 10a. As the light source 10b, for example, a light emitting diode (LED) is used. It has been. The light source unit 10 is provided with a heat sink 10c located below the circuit board 10a.

  The cooling fan 11 is disposed inside the heat sink 10c.

  The lamp unit 6 is attached to and held by a holding plate 12 positioned below the lamp unit 6 (see FIGS. 1 to 3). The holding plate 12 holds a substantially rectangular frame-like holding part 13 penetrating up and down, and rotating fulcrum parts 14 and 14 projecting laterally (outward) from the left and right ends of the front end part of the holding part 13. It has sliding engagement parts 15 and 15 protruding from the left and right side edges of the part 13. The holding plate 12 is integrally formed with a holding portion 13, rotation fulcrum portions 14 and 14, and sliding engagement portions 15 and 15.

  The sliding engagement portions 15 and 15 protrude downward from the inner edges of the left and right sides of the holding portion 13, respectively, and cam portions 15a and 15a are provided at the lower end portions. The cam portions 15a and 15a are inclined so as to be displaced upward as going backward.

  An optical axis adjustment mechanism 16 is disposed below the lamp unit 6 (see FIG. 1). The optical axis adjustment mechanism 16 includes a base body 17, a support plate 18, a slider 19, an operation shaft 20, and an actuator 21 (see FIGS. 2 and 3).

  The base body 17 is formed in a substantially plate shape facing the vertical direction, and has a fulcrum hole 17a at a position near the rear end. The base body 17 is provided with support protrusions 17b, 17b, and 17b protruding upward on a circumference centered on the fulcrum hole 17a so as to be separated in the circumferential direction. The base body 17 is attached to the bottom surface portion 2 a of the lamp housing 2. The base body 17 may be formed integrally with the lamp housing 2.

  The support plate 18 has a substantially plate-like base surface portion 22 facing in the vertical direction and support protrusions 23, 23 projecting upward from both left and right end portions of the front end portion of the base surface portion 22 and upward from the rear end portion of the base surface portion 22. And a protruding nut mounting portion 24. In the support plate 18, a base surface portion 22, support protrusions 23 and 23, and a nut attachment portion 24 are integrally formed.

  A supported shaft 22 a that protrudes downward is provided at a position near the rear end of the base surface portion 22. Guide protrusions 22b and 22b that protrude upward and extend in the front-rear direction are provided at the rear end of the base surface portion 22 so as to be separated from each other in the left-right direction. Arc-shaped supported holes 22c, 22c, and 22c are formed in the base surface portion 22 so as to be separated in the circumferential direction.

  The support protrusions 23 and 23 are formed with support recesses 23a and 23a that open upward and laterally (inward).

  The nut mounting portion 24 is formed with a mounting hole 24a penetrating in the front-rear direction.

  The support plate 18 has a supported shaft 22a inserted into the fulcrum hole 17a from above, and is rotatably supported by the base body 17 with the supported shaft 22a as a fulcrum. The support protrusions 17b, 17b, and 17b of the base body 17 are slidably engaged with the supported holes 22c, 22c, and 22c of the support plate 18, respectively. Accordingly, the support plate 18 is prevented from falling off from the base body 17.

  Rotating fulcrum portions 14 and 14 of the holding plate 12 are inserted into the support recesses 23a and 23a of the support plate 18, respectively, and the holding plate 12 is rotatably supported on the support plate 18 with the rotation fulcrum portions 14 and 14 as fulcrums. Is done.

  The slider 19 is formed in a horizontally long shape, and has a holding hole 19a penetrating back and forth at the center in the left-right direction. Engagement pins 19b and 19b and cam drive portions 19c and 19c protruding laterally (outward) are provided on the left and right side surfaces of the slider 19 so as to be spaced apart from each other in the vertical direction. The cam drive portion 19c is inclined so as to be displaced upward as it goes rearward. Guided grooves 19d and 19d that are opened downward and extend in the front-rear direction are formed on the lower surface of the slider 19 so as to be separated from each other in the left-right direction.

  Guide protrusions 22b and 22b are inserted into the guided grooves 19d and 19d, respectively, and the slider 19 is supported by the support plate 18 so as to be movable in the front-rear direction. Cam portions 15a and 15a are inserted between the engagement pins 19b and 19b of the slider 19 and the cam drive portions 19c and 19c, respectively. The engagement pins 19b and 19b and the cam drive portions 19c and 19c are connected to the cam portions 15a and 15a, respectively. It is made slidable. At this time, since the lamp unit 6 is disposed above the cam portions 15a and 15a and the cam drive portions 19c and 19c, the cam portions 15a and 15a are pressed against the cam drive portions 19c and 19c, respectively, by the load of the lamp unit 6.

  The operation shaft 20 is supported by the lamp housing 2 so as to be rotatable around the axis. The operation shaft 20 includes a shaft portion 25 and an operation portion 26 continuous to the rear end of the shaft portion 25. The shaft portion 25 has an axial direction as a front-rear direction, and a portion near the front end is provided as a screwing portion 25a.

  The operation shaft 20 is inserted through the rear surface portion 2b of the lamp housing 2, and the operation portion 26 is positioned behind the rear surface portion 2b.

  The actuator 21 is attached to the rear surface portion 2 b of the lamp housing 2 at the side of the operation shaft 20. The actuator 21 has a drive part 27, a shaft part 28 and a gear part 29.

  The drive unit 27 is attached to the front surface of the rear surface portion 2 b in the lamp housing 2.

  The shaft portion 28 has an axial direction that is the front-rear direction, and is positioned inside the drive portion 27 except for a front portion. The front end portion of the shaft portion 28 is provided as a screwing portion 28a. The shaft portion 28 is moved in the front-rear direction by the driving force of the drive portion 27 and is manually rotated around the axis with respect to the drive portion 27.

  The gear portion 29 is connected to the shaft portion 28. When the gear part 29 is manually rotated, the shaft part 28 is rotated integrally with the gear part 29 in the direction around the axis.

  A part of the actuator 21 is inserted through the rear surface portion 2b of the lamp housing 2, and the gear portion 29 is positioned behind the rear surface portion 2b.

  The first nut member 30 is attached to the attachment hole 24 a of the support plate 18. A screw groove (not shown) is formed on the inner surface of the first nut member 30. A screwing portion 25 a of the operation shaft 20 is screwed into the screw groove of the first nut member 30.

  A second nut member 31 is inserted and held in the holding hole 19 a of the slider 19. The second nut member 31 is rotatable at least in the left-right direction with respect to the slider 19, and a screw groove is formed on the inner surface of the second nut member 31. A screw portion 28 a of the shaft portion 28 of the actuator 21 is screwed into the screw groove of the second nut member 31.

  In the above description, the drive unit 27 of the actuator 21 is attached to the front surface of the rear surface portion 2b of the lamp housing 2 and the gear portion 29 is positioned behind the rear surface portion 2b. Is attached to the rear surface of the rear surface portion 2b of the lamp housing 2, and the drive portion 27 and the gear portion 29 may be positioned behind the rear surface portion 2b.

  In the optical axis adjustment mechanism 16, when the operation portion 26 of the operation shaft 20 is rotated, the first nut member 30 is sent and moved in the front-rear direction according to the rotation direction of the operation shaft 20. When the first nut member 30 is moved in the front-rear direction, the support plate 18, the holding plate 12, the slider 19, and the lamp unit 6 are integrated with the movement of the first nut member 30 to move the supported shaft 22 a. It is rotated with respect to the base body 17 as a fulcrum, and left and right aiming adjustment, which is an initial adjustment of the optical axis, is performed. At this time, the slider 19 is rotated in the left-right direction with respect to the second nut member 31.

  In the optical axis adjustment mechanism 16, when the gear portion 29 of the actuator 21 is rotated, the second nut member 31 is sent and moved in the front-rear direction according to the rotation direction of the gear portion 29 and the shaft portion 28. The When the second nut member 31 is moved in the front-rear direction, the slider 19 is guided by the guide protrusions 22b, 22b relative to the support plate 18 and moved in the front-rear direction as the second nut member 31 moves. The When the slider 19 is moved in the front-rear direction, the engagement positions of the engagement pins 19b and 19b and the cam drive portions 19c and 19c with respect to the cam portions 15a and 15a are changed, and the holding plate 12 and the lamp unit 6 are rotated as fulcrums. 14, 14 are rotated with respect to the support plate 18 as fulcrums, and vertical aiming adjustment, which is an initial adjustment of the optical axis, is performed.

  On the other hand, when the shaft portion 28 is moved in the front-rear direction by the driving force of the drive portion 27 of the actuator 21, the second nut member 31 is moved in the front-rear direction according to the moving direction of the shaft portion 28. When the second nut member 31 is moved in the front-rear direction, the holding plate 12 and the lamp unit 6 rotate with respect to the support plate 18 using the rotation fulcrum portions 14 and 14 as fulcrums in the same manner as in the vertical aiming adjustment. Then, leveling adjustment is performed to adjust the direction of the optical axis that is changed according to the weight of the vehicle-mounted object.

<Second Embodiment>
Next, a vehicle headlamp 1A according to a second embodiment will be described (see FIGS. 4 to 7).

  The vehicle headlamp 1A according to the second embodiment has a partial configuration of the optical axis adjustment mechanism and a partial arrangement position of the optical axis adjustment mechanism, as compared with the vehicle headlamp 1 described above. Therefore, only the parts that are different from the vehicle headlamp 1 will be described in detail, and the other parts are the same as the reference numerals assigned to the same parts in the vehicle headlamp 1. Reference numerals are assigned and description is omitted.

  An optical axis adjusting mechanism 16A is disposed below the lamp unit 6 (see FIG. 4). The optical axis adjustment mechanism 16A includes a base body 17, a support plate 18, a lower slider 32, an upper slider 33, operation shafts 20 and 20, and an actuator 21A (see FIGS. 5 and 6).

  The lower slider 32 is formed in a horizontally long shape, and has a holding hole 32a penetrating in the front-rear direction at the rear end of the central portion in the left-right direction. The lower slider 32 has a substantially annular annular insertion portion 32b penetrating front and rear at the front end portion, and a rear portion of the annular insertion portion 32b is formed as a sliding recess 32c opened upward. The sliding recess 32c is located on the side of the holding hole 32a. Guide grooves 32d and 32d that are opened downward and extend in the front-rear direction are formed on the lower surface of the lower slider 32 so as to be separated from each other in the left-right direction. The lower slider 32 is provided with guide protrusions 32e, 32e extending in the front-rear direction so as to be separated from each other in the left-right direction.

  The guide sliders 22b and 22b are inserted into the guided grooves 32d and 32d, respectively, and the lower slider 32 is supported by the support plate 18 so as to be movable in the front-rear direction.

  The upper slider 33 is formed in a horizontally long shape. Guided projections 33a, 33a extending in the front-rear direction are provided on the lower surface of the upper slider 33 so as to be separated from each other in the left-right direction. Engagement pins 33b and 33b and cam drive portions 33c and 33c projecting laterally (outward) are provided on both the left and right side surfaces of the upper slider 33 so as to be spaced apart from each other in the vertical direction. The cam drive part 33c is inclined so as to be displaced upward as it goes rearward. A sliding coupling portion 33d and a sliding plate portion 33e are provided side by side at a substantially central portion in the left-right direction of the upper slider 33, and the outer periphery of the sliding coupling portion 33d is formed in a cylindrical shape. 33e is formed in a substantially arc shape convex upward.

  The upper slider 33 is supported by the lower slider 32 so that the guided protrusions 33a and 33a are slidably engaged with the guide protrusions 32e and 32e, respectively. Cam portions 15a and 15a are inserted between the engagement pins 33b and 33b of the upper slider 33 and the cam drive portions 33c and 33c, respectively. The engagement pins 33b and 33b and the cam drive portions 33c and 33c are connected to the cam portions 15a and 15a. It is possible to slide. At this time, since the lamp unit 6 is disposed above the cam portions 15a and 15a and the cam drive portions 33c and 33c, the cam portions 15a and 15a are pressed against the cam drive portions 33c and 33c by the load of the lamp unit 6, respectively.

  The upper slider 33 is slid with the sliding coupling portion 33 d inserted into the sliding recess 32 c of the lower slider 32.

  The operation shafts 20 and 20 are spaced apart from each other left and right, are inserted through the rear surface portion 2b of the lamp housing 2, and the operation portions 26 and 26 are positioned behind the rear surface portion 2b.

  The actuator 21A is disposed on the front side of the operation shafts 20 and 20. The actuator 21 </ b> A has a drive part 27 </ b> A and a shaft part 28 </ b> A, and the drive part 27 </ b> A is disposed on the upper surface of the support plate 18 so as to be movable in the front-rear direction.

  The drive unit 27A includes a main body 27a and an annular coupling protrusion 27b protruding rearward from the main body 27a, and a regulating protrusion 27c protruding outward on the outer periphery of the coupling protrusion 27b. 27c and 27c are spaced apart in the circumferential direction.

  The shaft portion 28A protrudes rearward from the coupling protrusion 27b of the drive portion 27A. The tip of the shaft portion 28A is provided as a spherical connecting portion 28b.

  In the actuator 21A, the spherical coupling portion 28b, the shaft portion 28A, and the coupling projection 27b are inserted from the rear into the annular insertion portion 32b of the lower slider 32, and the spherical coupling portion 28b is coupled to the sliding coupling portion 33d of the upper slider 33. The In a state where the coupling protrusion 27b of the actuator 21A is inserted into the annular insertion portion 32b, the annular insertion portion 32b is between the rear surface of the main body portion 27a of the actuator 21A and the restriction projections 27c, 27c, 27c. Is located in a state where a certain gap is generated.

  The first nut member 30 is attached to the attachment hole 24 a of the support plate 18. A screwing portion 25 a of one operation shaft 20 is screwed into the screw groove of the first nut member 30.

  The second nut member 31 is inserted and held in the holding hole 32 a of the lower slider 32. The threaded portion 25 a of the other operation shaft 20 is threadedly engaged with the threaded groove of the second nut member 31.

  In the optical axis adjustment mechanism 16 </ b> A, when the operation portion 26 of one operation shaft 20 is rotated, the first nut member 30 is sent according to the rotation direction of the operation shaft 20 and moved in the front-rear direction. When the first nut member 30 is moved in the front-rear direction, the support plate 18, the holding plate 12, the lower slider 32, the upper slider 33, the actuator 21 </ b> A, and the lamp unit 6 are moved along with the movement of the first nut member 30. It is integrally rotated with respect to the base body 17 with the supported shaft 22a as a fulcrum, and left and right aiming adjustment, which is an initial adjustment of the optical axis, is performed. At this time, the lower slider 32, the upper slider 33, and the actuator 21 </ b> A are rotated in the left-right direction with respect to the second nut member 31.

  Further, in the optical axis adjustment mechanism 16A, when the operation portion 26 of the other operation shaft 20 is rotated, the second nut member 31 is sent according to the rotation direction of the operation shaft 20 and moved in the front-rear direction. . When the second nut member 31 is moved in the front-rear direction, the lower slider 32 is guided by the guide protrusions 22b, 22b relative to the support plate 18 along with the movement of the second nut member 31, and is moved in the front-rear direction. Moved. At this time, the lower slider 32 can move with respect to the upper slider 33. However, when the lower slider 32 is moved and the annular insertion portion 32b comes into contact with the rear surface of the main body portion 27a or the restricting protrusions 27c, 27c, 27c, the lower slider 32 moves. The side slider 32, the upper slider 33, and the actuator 21A are moved together in the front-rear direction.

  When the upper slider 33 is moved in the front-rear direction integrally with the lower slider 32, the engagement positions of the engagement pins 33b and 33b and the cam drive portions 33c and 33c with respect to the cam portions 15a and 15a are changed, and the holding plate is changed. 12 and the lamp unit 6 are rotated with respect to the support plate 18 using the rotation fulcrum portions 14 and 14 as fulcrums, and vertical aiming adjustment, which is an initial adjustment of the optical axis, is performed.

  On the other hand, when the shaft portion 28A is moved in the front-rear direction by the driving force of the drive portion 27 of the actuator 21A, the upper slider 33 is moved in the front-rear direction according to the moving direction of the shaft portion 28A. At this time, the upper slider 33 can move with respect to the lower slider 32, but when the upper slider 33 is moved and a part of the upper slider 33 or the actuator 21 </ b> A contacts a part of the lower slider 32, the lower slider 32. And the upper slider 33 are integrally moved in the front-rear direction.

  When the upper slider 33 is moved in the front-rear direction integrally with the lower slider 32, the holding plate 12 and the lamp unit 6 are supported by the pivot fulcrum portions 14 and 14 as fulcrums in the same manner as in the vertical aiming adjustment. The leveling adjustment is performed to adjust the direction of the optical axis that is rotated with respect to the vehicle 18 and is changed according to the weight of the vehicle-mounted object.

  In the vehicle headlamp 1A according to the second embodiment described above, the shape and size of the lower slider 32 and the upper slider 33 are changed as follows, and the lower slider 32A and the upper slider are respectively changed. It can be provided as 33A and can be reduced in size in the left-right direction (see FIG. 7).

  The lower slider 32A has a holding hole 32a penetrating in the front-rear direction at the rear end of the central portion in the left-right direction. The lower slider 32A has a substantially annular annular insertion portion 32b penetrating front and rear at the front end portion, and the rear portion of the annular insertion portion 32b is formed as a sliding recess 32c opened upward. The sliding recess 32c is located above the holding hole 32a. Guided grooves 32d and 32d that are opened downward and extend in the front-rear direction are formed on the lower surface of the lower slider 32A so as to be separated from each other in the left-right direction. Guide protrusions 32e, 32e extending in the front-rear direction are provided on the upper surface of the lower slider 32A so as to be separated from each other in the left-right direction.

  Guided projections 33a, 33a extending in the front-rear direction are provided on the lower surface of the upper slider 33A so as to be separated from each other in the left-right direction. Engagement pins 33b and 33b and cam drive portions 33c and 33c projecting laterally (outward) are provided on both the left and right side surfaces of the upper slider 33A so as to be separated vertically. The cam drive part 33c is inclined so as to be displaced upward as it goes rearward. A slide coupling portion 33d is provided at a substantially central portion in the left-right direction of the upper slider 33A, and the outer periphery of the slide coupling portion 33d is formed in a cylindrical shape.

  The upper slider 33A is slid with the sliding coupling portion 33d inserted into the sliding recess 32c of the lower slider 32A.

  With this configuration, the sliding coupling portion 33d of the upper slider 33A that is slid in the sliding recess 32c is positioned above the holding hole 32a, and thus it is possible to reduce the size in the left-right direction. .

<Third Embodiment>
Next, a vehicle headlamp 1B according to a third embodiment will be described (see FIGS. 8 and 9).

  Note that the vehicle headlamp 1B according to the third embodiment is different from the vehicle headlamp 1 described above in the configuration of the holding plate, the configuration of a part of the optical axis adjustment mechanism, and the optical axis adjustment mechanism. Since only a part of the arrangement position is different, only the different parts compared to the vehicle headlamp 1 will be described in detail, and the other parts will be described in the same parts in the vehicle headlamp 1. The same reference numerals as those assigned are used and description thereof is omitted.

  The lamp unit 6 is attached to and held by a holding plate 12B positioned below the lamp unit 6 (see FIG. 8). The holding plate 12B includes a substantially rectangular frame-shaped holding portion 13 penetrating vertically, supported portions 34 and 34 that protrude downward from both left and right ends of the front end portion of the holding portion 13, and a sliding engagement portion 15B. There are mounting legs 35, 35,... Protruding upward from the holding part 13. The holding plate 12B is integrally formed with a holding portion 13, rotating fulcrum portions 14 and 14, supported portions 34 and 34, and a sliding engagement portion 15B. Each part of the lamp unit 6 is attached to the attachment legs 35, 35,... By screws or the like and is held by the holding plate 12B.

  Rotating fulcrum portions 34a and 34a projecting to the side (outward) are provided at the lower ends of the supported portions 34 and 34, respectively.

  The sliding engagement portion 15B protrudes downward from the inner edge of one side portion of the holding portion 13, and the lower surface is formed as a cam portion 15b. The cam portion 15b is inclined so as to be displaced downward as it goes rearward.

  An optical axis adjustment mechanism 16B is disposed below the lamp unit 6. The optical axis adjustment mechanism 16B includes a base body 17, a support plate 18B, a slider 19B, a cam member 36, operation shafts 20 and 20, and an actuator 21B.

  The support plate 18 </ b> B has a base surface portion 22 and a nut mounting portion 24. Bearing members 37 and 37 are attached to the left and right sides of the base surface portion 22 on the support plate 18B, respectively. Bearing rings 38 and 38 are supported on the upper ends of the bearing members 37 and 37, respectively. The bearing members 37 and 37 may be formed integrally with the lamp housing 2.

  The support plate 18B is rotatably supported by the base body 17 with the supported shaft 22a as a fulcrum.

  Rotating fulcrum portions 34a and 34a of the holding plate 12B are inserted into the bearing rings 38 and 38 supported by the bearing members 37 and 37, respectively, and the holding plate 12B is attached to the support plate 18B with the rotating fulcrum portions 34a and 34a as fulcrums. It is supported rotatably.

  The slider 19 </ b> B has a slide surface portion 39 that faces in the vertical direction, an actuator fixing portion 40 that protrudes upward from the front end portion of the slide surface portion 39, and a nut attachment portion 41 that protrudes upward from the rear end portion of the slide surface portion 39. Yes. Both left and right end portions of the slide surface portion 39 are provided as guided portions 39a and 39a. The actuator fixing portion 40 is formed with a shaft insertion hole 40a penetrating in the front-rear direction, and the nut attachment portion 41 is formed with an attachment hole 41a penetrating in the front-rear direction.

  In the slider 19B, guided portions 39a and 39a are slidably engaged with the guide protrusions 22b and 22b, respectively, and supported by the support plate 18B so as to be movable in the front-rear direction.

  The cam member 36 has a connecting portion 36a and a cam driving portion 36b protruding upward from the connecting portion 36a. The cam drive unit 36b is formed in a cylindrical shape whose axial direction is the left-right direction.

  The actuator 21B is disposed on the front side of the operation shafts 20 and 20. The actuator 21B has a drive part 27 and a shaft part 28B, and the drive part 27 is arranged on the upper surface of the support plate 18B so as to be movable in the front-rear direction.

  The connecting portion 36a of the cam member 36 is connected to the shaft portion 28B of the actuator 21B, and is moved in the front-rear direction along with the movement of the shaft portion 28B. The shaft portion 28B of the actuator 21B is inserted through the shaft insertion hole 40a formed in the actuator fixing portion 40 of the slider 19B, and the driving portion 27 is fixed to the actuator fixing portion 40.

  The cam member 36 is slidably engaged with the cam portion 15b of the holding plate 12 from below. At this time, since the lamp unit 6 is disposed above the cam portion 15b and the cam drive portion 36b, the cam portion 15b is pressed against the cam drive portion 36b by the load of the lamp unit 6.

  The first nut member 30 is attached to the attachment hole 24a of the support plate 18B, and the second nut member 31 is attached to the attachment hole 41a of the slider 19B.

  In the optical axis adjustment mechanism 16B, when the operation portion 26 of one operation shaft 20 is rotated, the first nut member 30 is sent according to the rotation direction of the operation shaft 20 and moved in the front-rear direction. When the first nut member 30 is moved in the front-rear direction, the support plate 18B, the holding plate 12B, the slider 19B, the cam member 36, the bearing members 37 and 37, the actuator 21B, The lamp unit 6 is united and rotated with respect to the base body 17 with the supported shaft 22a as a fulcrum, and left and right aiming adjustment, which is an initial adjustment of the optical axis, is performed. At this time, the slider 19B is rotated in the left-right direction with respect to the second nut member 31.

  Further, in the optical axis adjustment mechanism 16B, when the operation portion 26 of the other operation shaft 20 is rotated, the second nut member 31 is sent according to the rotation direction of the operation shaft 20 and moved in the front-rear direction. . When the second nut member 31 is moved in the front-rear direction, the slider 19B, the actuator 21B, and the cam member 36 are guided to the guide protrusions 22b and 22b with respect to the support plate 18B as the second nut member 31 moves. Is moved in the front-rear direction. When the slider 19B, the actuator 21B, and the cam member 36 are moved in the front-rear direction, the engagement position of the cam drive portion 36b of the cam member 36 with the cam portion 15b is changed, and the holding plate 12B and the lamp unit 6 are rotated as fulcrums. 34a and 34a are pivoted with respect to the support plate 18B as fulcrums, and vertical aiming adjustment, which is the initial adjustment of the optical axis, is performed.

  On the other hand, when the shaft portion 28B is moved in the front-rear direction by the driving force of the drive portion 27 of the actuator 21B, the cam member 36 is moved in the front-rear direction according to the moving direction of the shaft portion 28B. When the cam member 36 is moved in the front-rear direction, the holding plate 12B and the lamp unit 6 are rotated with respect to the support plate 18B with the rotation fulcrum portions 34a and 34a as fulcrums in the same manner as in the vertical aiming adjustment. Leveling adjustment is performed to adjust the direction of the optical axis, which is changed according to the weight of the object.

<Fourth embodiment>
Next, a vehicle headlamp 1C according to a fourth embodiment will be described (see FIGS. 10 and 11).

  Note that the vehicle headlamp 1C according to the fourth embodiment is different from the vehicle headlamp 1 described above in the configuration of the holding plate, the partial configuration of the optical axis adjustment mechanism, and the optical axis adjustment mechanism. Since only a part of the arrangement position is different, only the different parts compared to the vehicle headlamp 1 will be described in detail, and the other parts will be described in the same parts in the vehicle headlamp 1. The same reference numerals as those assigned are used and description thereof is omitted.

  The lamp unit 6 is attached to and held by a holding plate 12C positioned below the lamp unit 6. The holding plate 12C protrudes downward from one side portion of the holding portion 13C and the mounting leg portions 42, 42 protruding upward from the substantially rectangular frame-shaped holding portion 13C penetrating vertically. And a connecting surface portion 43.

  Support protrusions 13a, 13a, 13a protruding downward are provided on the lower surface of the holding portion 13C so as to be spaced apart in the circumferential direction.

  The connecting surface portion 43 is formed in a plate shape facing substantially in the left-right direction, the outer surface is formed in a gently arcuate surface shape protruding outward, and has a gear portion 43a on the outer surface.

  An optical axis adjusting mechanism 16 </ b> C is disposed below the lamp unit 6. The optical axis adjustment mechanism 16C includes a support plate 18C, a cam member 44, operation shafts 20 and 20C, and an actuator 21C. The optical axis adjustment mechanism 16C also includes a connecting surface portion 43 of the holding plate 12C.

  The support plate 18C protrudes diagonally inwardly from the supported portions 45 and 45 and the base surface portion 22C, which protrude downward from the left and right ends of the substantially annular base surface portion 22C and the front end portion of the base surface portion 22C. The connecting leg portions 46, 46,... And the sliding engagement portions 47 connected to the connecting leg portions 46, 46,.

  Arc-shaped supported holes 22c, 22c, and 22c are formed in the base surface portion 22C so as to be spaced apart in the circumferential direction.

  Rotating fulcrum portions 45a and 45a projecting laterally (outward) are provided at the lower ends of the supported portions 45 and 45, respectively.

  The sliding engagement portion 47 includes cam portions 47a and 47a that extend in the front-rear direction and are spaced apart from each other and a connecting side portion 47b that connects the rear ends of the cam portions 47a and 47a, and the cam portions 47a and 47a. Is inclined so as to be displaced upward as it goes backward.

  The support protrusions 13a, 13a, 13a of the holding plate 12C are slidably engaged with the supported holes 22c, 22c, 22c of the support plate 18C, respectively. Accordingly, the holding plate 12C is rotatably supported by the support plate 18C.

  The cam member 44 includes a block-shaped coupling portion 48, engaging pins 49, 49 projecting from the left and right side surfaces of the coupling portion 48 to the side (outward), and cam driving portions 50, 50. A threaded recess 48a that is opened downward is formed in the housing. A screw groove (not shown) is formed on the peripheral surface of the screw recess 48a. The cam drive unit 50 is inclined so as to be displaced upward as it goes rearward.

  Cam portions 47a and 47a of the support plate 18C are inserted between the engagement pins 49 and 49 of the cam member 44 and the cam drive portions 50 and 50, and the engagement pins 49 and 49 and the cam drive portions 50 and 50 are connected to the cam portion. 47a and 47a are slidable. At this time, since the lamp unit 6 is disposed above the cam portions 47a and 47a and the cam drive portions 50 and 50, the cam portions 47a and 47a are pressed against the cam drive portions 50 and 50, respectively, by the load of the lamp unit 6.

  The operating shaft 20 has a screwing portion 25a formed on the shaft portion 25 and screwed to a gear portion 43a formed on the connecting surface portion 43 of the holding plate 12C.

  The operation shaft 20C is shorter than the operation shaft 20, the screw portion is not formed in the shaft portion 25C, and a non-circular coupling hole 25b opened forward is formed in the shaft portion 25C. The operation shaft 20 </ b> C is supported on the lamp housing 2 so as to be rotatable in the direction around the axis, spaced apart from the operation shaft 20 in the left and right directions.

  The actuator 21C is disposed in front of the operation shafts 20 and 20C. The actuator 21C has a drive part 27 and a shaft part 28C. A screw portion 28a is formed on the shaft portion 28C.

  The shaft portion 28C of the actuator 21C is inserted into the coupling hole 25b of the shaft portion 25C and coupled to the operation shaft 20C. Therefore, the shaft portion 28C and the operation shaft 20C of the actuator 21C are rotated together.

  The screwing portion 28a formed on the shaft portion 28C of the actuator 21C is inserted into the screwing recess 48a of the cam member 44 and screwed.

  The actuator 21 </ b> C is attached to a mounting bracket 51 fixed to the bottom surface 2 a of the lamp housing 2. The mounting bracket 51 has mounting projections 51a, 51a,... For mounting the actuator 21C, and bearings 51b, 51b provided on the left and right of the mounting projections 51a, 51a,. . The mounting bracket 51 may be provided integrally with the lamp housing 2.

  The rotation fulcrum portions 45a and 45a of the holding plate 12C are supported on the bearing portions 51b and 51b of the mounting bracket 51. Accordingly, the holding plate 12C is rotatably supported by the mounting bracket 51 with the rotation fulcrum portions 45a and 45a serving as fulcrums.

  In the optical axis adjustment mechanism 16C, when the operation portion 26 of the operation shaft 20 is rotated, the holding plate 12C and the illumination unit 6 rotate integrally with the support plate 18C according to the rotation direction of the operation shaft 20. The left and right aiming adjustment, which is the initial adjustment of the optical axis, is performed.

  Further, in the optical axis adjustment mechanism 16C, when the operation portion 26 of the operation shaft 20C is rotated, the shaft portion 28C of the actuator 21C is rotated with the rotation of the operation shaft 20C, and the cam is rotated with the rotation of the shaft portion 28C. The member 44 is sent and moved in the front-rear direction. When the cam member 44 is moved in the front-rear direction, the engagement positions of the engagement pins 49, 49 and the cam drive portions 50, 50 with respect to the cam portions 47a, 47a are changed, and the holding plate 12C and the lamp unit 6 are pivoted. The parts 45a and 45a are rotated with respect to the mounting bracket 51 as fulcrums, and vertical aiming adjustment, which is the initial adjustment of the optical axis, is performed.

  On the other hand, when the shaft portion 28C is moved in the front-rear direction by the driving force of the drive portion 27 of the actuator 21C, the cam member 44 is moved in the front-rear direction according to the moving direction of the shaft portion 28C. When the cam member 44 is moved in the front-rear direction, the holding plate 12C and the lamp unit 6 are rotated with respect to the support plate 18C using the rotation fulcrum portions 45a and 45a as fulcrums in the same manner as in the vertical aiming adjustment. Leveling adjustment is performed to adjust the direction of the optical axis, which is changed according to the weight of the object.

<Others>
Below, the example of the structure which makes a cam part and a cam drive part slide reliably is demonstrated (refer FIG. 12).

  In the example shown below, the sliding structure of the cam portion 15a and the cam driving portion 19c in the first embodiment, the sliding structure of the cam portion 15a and the cam driving portion 19c in the second embodiment, The sliding structure of the cam part 15b and the cam driving part 36b in the embodiment and the sliding structure of the cam part 47a and the cam driving part 50 in the fourth embodiment can be applied. .

  Below, the structure which slides both reliably in the sliding structure of the cam part 15a of the holding plate 12 and the cam drive part 19c of the slider 19 is demonstrated as an example.

  The slider 19 is provided with biasing portions 52 and 52 above the cam drive portions 19c and 19c, respectively. As the urging unit 52, for example, a leaf spring is used. The urging portion 52 is located, for example, in front of the engagement pin 19b.

  In a state where the urging portion 52 is not elastically deformed, the distance H1 between the urging portion 52 and the cam driving portion 19c is set smaller than the distance H2 between the engaging pin 19b and the cam driving portion 19c. Accordingly, the cam portion 15a inserted between the engagement pin 19b and the cam drive portion 19c is pressed against the cam drive portion 19c by the urging portion 52, and the cam portion 15a and the cam drive portion 19c are reliably slid. .

  Since the urging portion 52 is provided in this way, the cam portion 15a is pressed against the cam drive portion 19c by the urging portion 52, and the two are surely slid without sliding. Shaking of the shaft can be prevented, and collision between the cam portion 15a and the cam drive portion 19c due to vibration or the like does not occur, and damage or the like can be prevented.

<Summary>
As described above, in the vehicle headlamps 1, 1A, 1B, and 1C, the optical axis adjustment mechanisms 16, 16A, 16B, and 16C that adjust the direction of the optical axis are disposed below the lamp unit 6. ing.

  Therefore, since the lamp unit 6 and the optical axis adjusting mechanisms 16, 16A, 16B, and 16C are arranged vertically, it is possible to reduce the size in the front-rear direction.

  Further, the holding plates 12, 12B, and 12C are rotated in the vertical direction, and the support plates 18, 18B, and 18C and the holding plates 12, 12B, and 12C are integrally rotated in the left and right directions, and are rotated in the vertical direction. Since the shaft and the rotation shaft in the left-right direction are provided on different members, a torsional moment is unlikely to occur during rotation in the vertical direction and the left-right direction, and a smooth operation can be ensured.

  In the above example, the holding plates 12, 12B, 12C are rotated in the vertical direction, and the support plates 18, 18B, 18C and the holding plates 12, 12B, 12C are integrally rotated in the left-right direction. However, conversely, the holding plates 12, 12B, 12C are rotated in the left-right direction and the support plates 18, 18B, 18C and the holding plates 12, 12B, 12C are integrally rotated in the up-down direction. It is also possible to adopt a configuration.

  Furthermore, since the holding plates 12, 12B, 12C and the support plates 18, 18B, 18C are arranged vertically, it is possible to further reduce the size in the front-rear direction.

  Furthermore, since the holding plates 12, 12B and 12C are provided with frame-like holding portions 13 and 13C penetrating in the vertical direction, the vehicle headlamp is secured after ensuring high rigidity of the holding plates 12 and 12B. 1, 1A, 1B, 1C can be reduced in weight.

  In addition, the holding plates 12, 12B, and 12C are integrally provided with the vertical fulcrum portions 14, 34a, and 45a, and the support plates 18 and 18B are integrally provided with the supported shaft 22a that is the horizontal fulcrum. Therefore, the manufacturing cost can be reduced by reducing the number of parts.

  Further, in the vehicle headlamps 1, 1A, 1B, 1C, cam portions 15a, 15b, 47a and cam portions are added to the optical axis adjusting mechanisms 16, 16A, 16B, 16C for adjusting the direction of the optical axis. Cam drive portions 19c, 33c, 36b, and 50 that are slidably engaged with 15a, 15b, and 47a and rotate the lamp unit 6 in the vertical direction and the horizontal direction are provided.

  Accordingly, since the cam mechanism is used as a mechanism for rotating the lamp unit 6, the degree of freedom in structural design is high, the arrangement space of each part is hardly limited, and the size is reduced by improving the degree of freedom in design. Can be achieved.

  Further, the lamp unit 6 is disposed above the cam portions 15a, 15b, 47a and the cam drive portions 19c, 33c, 36b, 50, and the cam portions 15a, 15b, 47a are connected to the cam drive portions 19c, 33c, 36b, 50. The unit 6 is pressed by the load.

  Therefore, it is possible to improve the reliability of the rotating operation of the lamp unit 6 while ensuring miniaturization in the front-rear direction.

DESCRIPTION OF SYMBOLS 1 ... Vehicle headlamp, 2 ... Lamp housing, 3 ... Cover, 4 ... Lamp outer casing, 6 ... Lamp unit, 10b ... Light source, 12 ... Holding plate, 13 ... Holding part, 14 ... Turning fulcrum part, 16 DESCRIPTION OF SYMBOLS ... Optical axis adjustment mechanism, 18 ... Support plate, 1A ... Vehicle headlamp, 16A ... Optical axis adjustment mechanism, 1B ... Vehicle headlamp, 12B ... Holding plate, 16B ... Optical axis adjustment mechanism, 18B ... Support plate DESCRIPTION OF SYMBOLS 1C ... Vehicle headlamp, 12C ... Holding plate, 13C ... Holding part, 16C ... Optical axis adjustment mechanism, 18C ... Support plate

Claims (5)

A lamp outer casing constituted by a lamp housing having an opening in at least one and a cover covering the opening of the lamp housing;
A holding plate that is rotatable in at least one of the vertical direction and the horizontal direction;
A lamp unit attached to the holding plate and having a light source;
A vehicle headlamp comprising: an optical axis adjustment mechanism that is disposed below the lamp unit and adjusts the direction of the optical axis of the lamp unit. The holding plate is rotatable in one of the vertical direction and the horizontal direction,
A support plate is provided that supports the holding plate so as to be rotatable in the vertical direction or the horizontal direction, and is rotatable in the other of the vertical direction and the horizontal direction with respect to the lamp housing.
The holding plate is rotated in one of the vertical direction and the horizontal direction, and the optical axis adjustment mechanism adjusts the vertical or horizontal direction of the optical axis, and the support plate and the holding plate are integrated. The vertical axis or the horizontal direction of the optical axis is adjusted by the optical axis adjusting mechanism by being rotated to the other of the vertical direction and the horizontal direction. The vehicle headlamp described in 1. The vehicle headlamp according to claim 2, wherein the holding plate and the support plate are arranged vertically. A holding portion for holding the lamp unit is provided on the holding plate,
The vehicle headlamp according to claim 1, 2 or 3, wherein the holding portion is formed in a frame shape penetrating in the vertical direction. The vehicle headlamp according to claim 1, 2, 3, or 4, wherein the holding plate is integrally provided with a pivot point in the vertical direction.

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