JP2012174656A - Vehicle light unit - Google Patents

Abstract

To provide a vehicular lamp unit in which a projection lens does not move (or hardly moves) during optical axis adjustment and does not affect (or hardly influence) appearance.
A projection lens, a light source that is disposed at or near the focal point of the projection lens, emits light for forming a predetermined light distribution pattern through the projection lens, and the light source includes the projection lens. In contrast, a support means for supporting the light source so as to be movable in a vertical direction and / or a horizontal direction in a vertical plane orthogonal to the lamp optical axis, and a fixing means for fixing the light source at an arbitrary position after the movement is provided. The projection lens is fixed to the vehicle side.
[Selection] Figure 1

Description

  The present invention relates to a vehicular lamp unit, and more particularly to a vehicular lamp unit capable of adjusting an optical axis.

  Conventionally, in the field of vehicle lamps, as shown in FIG. 10, a support member 220 (that is, fixed to the support member 220) by an aiming mechanism 230 connected to a support member 220 to which a plurality of vehicle lamp units 210 are fixed. A vehicular lamp 200 is known that performs optical axis adjustment by tilting the entire vehicular lamp unit 210) (see, for example, Patent Document 1).

Japanese Patent No. 4264335

  However, since the vehicular lamp 200 described in Patent Document 1 is configured to tilt the entire vehicular lamp unit 210 (including the projection lens 211) to adjust the optical axis, each vehicular lamp unit is adjusted when adjusting the optical axis. There is a problem in that the projection lens 211 of 210 moves greatly and a gap is not formed between the projection lens 211 and a member (such as the inner panel 240) arranged around the projection lens 211, which affects the appearance.

  The present invention has been made in view of such circumstances, and a vehicular lamp that the projection lens does not move (or hardly moves) during optical axis adjustment and does not affect (or hardly influence) the appearance. The purpose is to provide units.

  In order to achieve the above object, an invention according to claim 1 is provided with a projection lens and light that is disposed at or near the focal point of the projection lens and transmits the projection lens to form a predetermined light distribution pattern. A plurality of optical systems including a light source that emits light, a movable member to which the light sources of each of the plurality of optical systems are fixed, and the movable member with respect to a projection lens of each of the plurality of optical systems. A supporting means for supporting the movable member so as to be movable in a vertical direction and / or a horizontal direction within a vertical plane orthogonal to the axis; and a fixing means for fixing the movable member at an arbitrary position after the movement. The projection lens of each optical system is fixed on the vehicle side, and the projection lens of each of the plurality of optical systems has the same focal length.

  According to the first aspect of the present invention, unlike the conventional case in which the entire vehicular lamp unit is tilted to adjust the optical axis, the projection lens of each of the plurality of optical systems is fixed to the vehicle side. The movable member (that is, each light source fixed to the movable member) that is a part of the projector is moved in the vertical direction and / or the horizontal direction with respect to each projection lens fixed to the vehicle side to adjust the optical axis. Therefore, it is possible to realize a vehicular lamp unit in which the projection lens does not move at all when adjusting the optical axis and does not affect the appearance at all.

  According to the first aspect of the present invention, since the projection lens does not move at all when the optical axis is adjusted, the space for moving the projection lens of the vehicular lamp unit, which has been conventionally required, becomes unnecessary.

  The invention according to claim 2 includes a projection lens, and a light source that is disposed at or near the focal point of the projection lens and emits light for forming a predetermined light distribution pattern through the projection lens. A plurality of optical systems, a movable member to which a projection lens of each of the plurality of optical systems is fixed, and the movable member in a vertical plane perpendicular to the lamp optical axis with respect to each light source of the plurality of optical systems. Support means for supporting movement in the vertical direction and / or horizontal direction, and fixing means for fixing the movable member at an arbitrary position after the movement, and each of the light sources of the plurality of optical systems includes: The projection lens of each of the plurality of optical systems is fixed on the vehicle side, and has the same focal length.

  According to the invention described in claim 2, unlike the conventional case in which the entire vehicle lamp unit is tilted to adjust the optical axis, the light sources of each of the plurality of optical systems are fixed to the vehicle side. The movable member (that is, each projection lens fixed to the movable member), which is a part, is moved in the vertical direction and / or the horizontal direction with respect to each light source fixed on the vehicle side to adjust the optical axis. Therefore, it is possible to realize a vehicular lamp unit in which the projection lens hardly moves during the optical axis adjustment, and hardly affects the appearance as compared with the conventional case.

  According to the second aspect of the present invention, since the projection lens hardly moves during the optical axis adjustment, the space for moving the projection lens of the vehicular lamp unit can be reduced as compared with the conventional case.

  According to a third aspect of the present invention, the projection lens, the light source, and the light emitted from the light source are arranged in the radiation direction of the light source, and the light incident from the light source is transmitted to the projection lens. The projection with the reflecting surface configured to be condensed near the optical axis and transmitted through the projection lens to form a predetermined light distribution pattern, and the upper edge located at or near the focal point of the projection lens In a vehicle lamp unit comprising a lens and a shade disposed between the light sources, a movable member to which a projection lens of each of the plurality of optical systems is fixed, the movable member, and the plurality of optical systems. Support means for supporting each light source, reflecting surface and shade so as to be movable in a vertical direction and / or a horizontal direction within a vertical plane perpendicular to the optical axis of the lamp, and an arbitrary after moving the movable member A light source, a reflecting surface, and a shade of each of the plurality of optical systems are fixed to the vehicle side, and the projection lenses of the plurality of optical systems have the same focal length. It is characterized by being.

  According to the third aspect of the invention, unlike the conventional case in which the entire vehicular lamp unit is tilted to adjust the optical axis, the light sources of the plurality of optical systems are fixed to the vehicle side. A movable member (that is, each projection lens fixed to the movable member) that is a part is moved in the vertical direction and / or the horizontal direction with respect to each light source, each reflecting surface, and each shade fixed to the vehicle side. Since the configuration is such that the optical axis is adjusted, it is possible to realize a vehicular lamp unit in which the projection lens hardly moves during the optical axis adjustment and hardly affects the appearance as compared with the conventional case.

  According to the third aspect of the present invention, since the projection lens hardly moves during the optical axis adjustment, the space for moving the projection lens of the vehicular lamp unit can be reduced as compared with the conventional case.

  The invention according to claim 4 includes a projection lens, and a light source that is disposed at or near the focal point of the projection lens and emits light for forming a predetermined light distribution pattern through the projection lens. A plurality of optical systems, a movable member to which a light source of each of the plurality of optical systems is fixed, and the movable member in a direction parallel to a lamp optical axis with respect to each projection lens of the plurality of optical systems. A support means for supporting the movable member so as to be swingable about an extending rotation shaft; and a fixing means for fixing the movable member at an arbitrary position after the swinging. The projection lenses of the plurality of optical systems include: It is fixed to the vehicle side, and the ratio of the distance from the rotating shaft to the light source of each of the plurality of optical systems is equal to the ratio of the focal length of the projection lens of each of the plurality of optical systems.

  According to the fourth aspect of the present invention, unlike the conventional case in which the entire vehicular lamp unit is tilted to adjust the optical axis, the projection lens of each of the plurality of optical systems is fixed to the vehicle side. Since the movable member (that is, each light source fixed to the movable member) that is a part of the movable member is swung with respect to each projection lens fixed to the vehicle side, the optical axis is adjusted. It is possible to realize a vehicular lamp unit in which the projection lens does not move at all and does not affect the appearance at all.

  According to the fourth aspect of the present invention, since the projection lens does not move at all when adjusting the optical axis, the movement space for the projection lens of the vehicular lamp unit, which has been conventionally required, becomes unnecessary.

  The invention according to claim 5 includes a projection lens, and a light source that is disposed at or near the focal point of the projection lens and emits light for forming a predetermined light distribution pattern through the projection lens. A plurality of optical systems, a movable member to which a projection lens of each of the plurality of optical systems is fixed, and the movable member in a direction parallel to a lamp optical axis with respect to each light source of the plurality of optical systems. And a support means for supporting the movable member so as to be swingable about an extending rotation shaft; and a fixing means for fixing the movable member at an arbitrary position after the swinging. A light source for each of the plurality of optical systems is a vehicle. The ratio of the distance from the rotation axis to the light source of each of the plurality of optical systems is equal to the ratio of the focal length of the projection lens of each of the plurality of optical systems.

  According to the invention described in claim 5, unlike the conventional case in which the entire vehicle lamp unit is tilted to adjust the optical axis, the light sources of the plurality of optical systems are fixed to the vehicle side, Since the movable member (that is, each projection lens fixed to the movable member), which is a part, is oscillated with respect to each light source fixed to the vehicle side to adjust the optical axis, projection is performed when adjusting the optical axis. It is possible to realize a vehicular lamp unit in which the lens hardly moves and hardly affects the appearance as compared with the conventional case.

  According to the fifth aspect of the present invention, since the projection lens hardly moves during the optical axis adjustment, the space for moving the projection lens of the vehicular lamp unit can be reduced as compared with the conventional case.

  According to a sixth aspect of the present invention, the projection lens, the light source, and the light emitted from the light source are arranged in the radiation direction of the light source, and the light incident from the light source is transmitted to the projection lens. The projection with the reflecting surface configured to be condensed near the optical axis and transmitted through the projection lens to form a predetermined light distribution pattern, and the upper edge located at or near the focal point of the projection lens In a vehicle lamp unit comprising a lens and a shade disposed between the light sources, a movable member to which a projection lens of each of the plurality of optical systems is fixed, the movable member, and the plurality of optical systems. For each light source, reflecting surface and shade, support means for supporting the light source, the reflecting surface and the shade so as to be swingable about a rotation axis extending in a direction parallel to the lamp optical axis, and fixing the movable member to an arbitrary position after the swing Do A light source, a reflecting surface and a shade of each of the plurality of optical systems are fixed to the vehicle side, and from the rotation axis to the optical axis of the projection lens of each of the plurality of optical systems. The ratio of the distance is equal to the ratio of the focal length of the projection lens of each of the plurality of optical systems.

  According to the sixth aspect of the invention, unlike the conventional case in which the entire vehicular lamp unit is tilted to adjust the optical axis, the light sources of each of the plurality of optical systems are fixed to the vehicle side. A movable member (that is, each projection lens fixed to the movable member), which is a part, is oscillated with respect to each light source, each reflecting surface, and each shade fixed to the vehicle side to adjust the optical axis. Therefore, it is possible to realize a vehicular lamp unit in which the projection lens hardly moves during the optical axis adjustment, and hardly affects the appearance as compared with the conventional case.

  According to the invention described in claim 6, since the projection lens hardly moves during the optical axis adjustment, the movement space of the projection lens of the vehicular lamp unit can be saved as compared with the conventional case.

  According to the present invention, it is possible to provide a vehicular lamp unit in which the projection lens does not move (or hardly moves) when adjusting the optical axis and does not affect (or hardly influence) the appearance.

(A) The perspective view of the vehicle lamp unit 10 which is 1st Embodiment of this invention, (b) It is a front view. 1 is a plan view of a vehicular lamp unit 10. FIG. (A) Example of partial light distribution pattern P1 formed by the vehicle lamp unit 10 (lens 11 _L1 , lens 11 _L2 ), (b) formed by the vehicle lamp unit 10 (lens 11 _L3 , lens 11 _L4 ). It is an example of partial distribution light pattern P2. It is an example of the bracket support mechanism. (A), (b) Depending on the positional relationship between each light source 12 and each lens 11 _{L1 to} 11 _L4 (the vehicle rear side focus), the light is emitted from each light source 12 and passes through each lens 11 _{L1 to} 11 _L4 . It is sectional drawing for demonstrating that the irradiation direction of light changes. It is a longitudinal cross-sectional view of the vehicle lamp unit 10 (modification) which is 1st Embodiment. (A) The perspective view of the vehicle lamp unit 20 which is 2nd Embodiment of this invention, (b) It is a front view. 3 is a plan view of the vehicular lamp unit 20. FIG. (A) ~ (h) in accordance with the positional relationship between the light source 22 and the lens ₂₁ L1 _{through 21 L4} (vehicle rear side focal point of the) transmitted through each lens ₂₁ L1 _{through 21 L4} is emitted from the light sources 22 It is a figure for demonstrating that the irradiation direction of light changes. It is a horizontal sectional view of the vehicular lamp 200 that performs conventional optical axis adjustment.

[First Embodiment]
Hereinafter, a vehicle lamp unit according to a first embodiment of the present invention will be described with reference to the drawings.

  The vehicular lamp unit 10 of the present embodiment is a headlamp, and is disposed on each of the left and right sides of the front portion of the vehicle. Since the left and right vehicle lamp units 10 are substantially symmetrical and have the same configuration, the following description will focus on the vehicle lamp unit 10 arranged on the left side.

As shown in FIG. 1A, FIG. 1B, and FIG. 2, the vehicular lamp unit 10 includes a lens 11 disposed on the front side of the vehicle and a vehicle rear side focal point F _{L1 to} F _{L4 of the} lens 11 (or A plurality of optical systems (so-called direct projection type optical systems) provided with a light source 12 that is disposed in the vicinity thereof and emits light for transmitting a lens 11 and forming (part of) a light distribution pattern for low beam. And a bracket 13 disposed on the vehicle rear side.

Hereinafter, in FIG. 1A, the lenses 11 are referred to as a lens 11 _L1 , a lens 11 _L2 , a lens 11 _L3 , and a lens 11 _{L4 in} order from the leftmost side. The focal points on the vehicle rear side of the lenses 11 _{L1 to} 11 _L4 are referred to as F _{L1 to} F _L4 (see FIG. 2). The optical axes of the lenses 11 _{L1 to} 11 _L4 are referred to as AX _L1 to AX _L4 (see FIG. 2).

Each lens 11 is fixed to the vehicle side such as a housing or an extension. Each lens 11 is a projection lens having the same focal length. The vehicle rear-side focal points F _{L1 to} F _L4 of each lens 11 are located in the same vertical plane orthogonal to the lamp optical axis AX (see FIG. 2).

The lenses 11 _L1 and 11 _L2 are, for example, partial distribution light patterns P1 in which light emitted from the light source 12 and transmitted through the lenses 11 _L1 and 11 _L2 is a part of the low beam light distribution pattern (see FIG. 3A). The exit surface shape and / or the entrance surface shape are designed so as to form a The partial light distribution pattern P1 has an oblique cut (for example, 45 °) connecting the own lane side cut-off line CL1 extending in the horizontal direction, the opposite lane side cut-off line CL2 extending in the horizontal direction, and both the cut-off lines CL1 and CL2 at the upper edge. Includes offline CL3.

The lenses 11 _L3 and 11 _L4 are partially distributed light patterns P2 in which light emitted from the light source 12 and transmitted through the lenses 11 _L3 and 11 _L4 is a part of the low beam light distribution pattern (horizontal than the partial light distribution pattern P1). The exit surface shape and / or the entrance surface shape are designed so as to form (see FIG. 3B).

  The light distribution patterns for low beam are formed by superimposing the respective part distribution light patterns P1 and P2.

  Each light source 12 is fixed to a vertical surface 13a perpendicular to the lamp optical axis AX of a bracket 13 (corresponding to the movable member of the present invention) made of a material having excellent thermal conductivity such as aluminum alloy (FIG. 1 ( a)). The bracket 13 includes heat radiating fins 13b. In order to further improve the heat dissipation performance, it is preferable to interpose a heat conducting member such as heat conducting grease between each light source 12 and the vertical surface 13a of the bracket 13.

As each light source 12, for example, a light source module in which a semiconductor light emitting element (for example, white LED) having a rectangular light emitting unit is mounted on a substrate can be used. As shown in FIG. 2, each light source 12 is configured such that one side of the rectangular light emitting unit (for example, the lower end edge of the rectangular light emitting unit) has the vehicle rear side focal points F _{L1 to} F _L4 (or the vicinity thereof) of the lenses 11 _{L1 to} 11 _L4. Is arranged.

  As shown in FIG. 4, the bracket 13 is supported so as to be movable in the vertical direction V and / or the horizontal direction H in a vertical plane orthogonal to the lamp optical axis AX. FIG. 4 is an example of the bracket support mechanism 14. The bracket support mechanism 14 has two vertical guides 14a that are arranged at regular intervals and extend in the vertical direction. The vertical guides 14a have two vertical guides 14a that can move in the vertical direction with respect to the two vertical guides 14a. The horizontal guide 14b etc. which are connected to the horizontal direction and extend in the horizontal direction are provided. The bracket 13 is connected to the horizontal guide 14b so as to be movable in the horizontal direction with respect to the horizontal guide 14b.

According to the bracket supporting mechanism 14 having the above structure, the bracket 13 (the light source 12), it is possible to move in the vertical direction V and / or horizontal direction H with respect to the lenses ₁₁ L1 _{to 11 L4.} The bracket 13 is tightened by tightening the screws N1 and N2 until the tips of the screw N1 screwed to the two vertical guides 14a and the screw N2 screwed to the horizontal guide 14b come into contact with the horizontal guide 14a and the bracket 13, respectively. (Each light source 12) can be fixed at an arbitrary position after the movement.

When the bracket 13 (the light source 12) is moved in the vertical direction V and / or horizontal direction H, the positional relationship changes between the light source 12 and the lens ₁₁ L1 _{to 11 L4} (vehicle rear side focal point _F L1 _{to F L4)} of To do. In accordance with the change in the positional relationship, the irradiation direction of the light emitted from each light source 12 and transmitted through each lens 11 _{L1 to} 11 _L4 changes as follows.

For example, as shown in the cross-sectional view of FIG. 5A, when each light source 12 is positioned at the vehicle rear side focal point F _{L1 to} F _L4 (or the vicinity thereof) of each lens 11 _{L1 to} 11 _L4 , from each light source 12. The light emitted and transmitted through each lens 11 is irradiated in a direction parallel (or substantially parallel) to the optical axes AX _{L1 to} AX _{L4 of} each lens 11.

On the other hand, when each light source 12 is positioned above the vehicle rear side focal points F _{L1 to} F _L4 of the lenses 11 _{L1 to} 11 _L4 as shown in the cross-sectional view of FIG. light transmitted through the lens ₁₁ L1 _{to 11 L4} is irradiated obliquely downward with respect to the optical axis _AX L1 _{~AX L4} of each lens ₁₁ L1 _{to 11 L4.}

Similarly, if each light source 12 is positioned below the rear side focal point _F L1 _{to F L4} of each lens ₁₁ L1 _{to 11 L4,} light transmitted radiated each lens ₁₁ L1 _{to 11 L4} from the light sources 12 It is irradiated obliquely upward with respect to the optical axis _AX L1 _{~AX L4} of each lens ₁₁ L1 _{to 11 L4.}

Similarly, if each light source 12 is positioned on the right side of the vehicle rear-side focal point _F L1 _{to F L4} of each lens ₁₁ L1 _{to 11 L4,} light transmitted radiated each lens ₁₁ L1 _{to 11 L4} from the light sources 12 It is irradiated obliquely left direction with respect to the optical axis _AX L1 _{~AX L4} of each lens ₁₁ L1 _{to 11 L4.}

Similarly, if each light source 12 is positioned on the left side of the vehicle rear-side focal point _F L1 _{to F L4} of each lens ₁₁ L1 _{to 11 L4,} light transmitted radiated each lens ₁₁ L1 _{to 11 L4} from the light sources 12 It is irradiated obliquely right direction with respect to the optical axis _AX L1 _{~AX L4} of each lens ₁₁ L1 _{to 11 L4.}

As described above, each light source 12 and in response to positional relationship between each lens ₁₁ L1 _{to 11 L4} (vehicle rear side focal point _F L1 _{to F L4)} of each lens ₁₁ is emitted from each light source 12 L1 _{to 11 L4} transmits for irradiating direction of light changes, the bracket 13 (the light source 12), the vertical direction V and the horizontal direction H with respect to the lenses ₁₁ L1 _{to 11 L4} (vehicle rear side focal point _F L1 _{to F L4)} of (I.e., by changing the positional relationship between the light sources 12 and the focal points F _{L1 to} F _L4 of the respective lenses 11 _{L1 to} 11 _L4 ), the optical axis can be adjusted.

Further, according to the present embodiment, unlike the conventional case in which the entire vehicular lamp unit is tilted to adjust the optical axis, the lenses 11 _{L1 to} 11 _L4 are fixed to the vehicle side, and one of the vehicular lamp units 10 is fixed. the bracket 13 (the light source 12) is a part, because moved is configured to adjust the optical axis in the vehicle each fixed to side lens 11 _L1 to 11 _L4 vertical direction V and / or horizontal direction H with respect to When the optical axis is adjusted, the lenses 11 _{L1 to} 11 _L4 do not move at all, and it is possible to realize the vehicular optical unit 10 that does not affect the appearance at all.

Further, according to the present embodiment, since the lenses 11 _{L1 to} 11 _L4 do not move at all when adjusting the optical axis, the space for moving the projection lens of the vehicular lamp unit, which has been conventionally required, becomes unnecessary.

  Next, a comparative example will be described.

  For example, in a conventional vehicle lamp unit (unit length: 100 [mm]), when the optical axis adjustment angle is 2.0 °, the movement amount of the end of the vehicle lamp unit is 3.5 [mm]. Become.

On the other hand, in the vehicular lamp unit 10 (focal length f = 10 [mm] of the lenses 11 _{L1 to} 11 _L4 ) of the present embodiment, when the optical axis adjustment angle is 2.0 °, the lenses 11 _{L1 to} 11 _L4. Is 0 mm, and the bracket 13 is 0.35 mm (see FIG. 2).

  As is clear from the above comparative example, according to the present embodiment, since the moving amount of the movable portion is smaller than that of the conventional vehicle lamp unit (conventional: 3.5 [mm], this embodiment:. 35 [mm]), the moving space of the movable part can be reduced as compared with the conventional case.

  Next, a modified example will be described.

In the above embodiment, the lenses ₁₁ L1 _{to 11 L4} fixed to the vehicle side, such as a housing or an extension, with a bracket support mechanism 14, the bracket 13 (the light source 12), for each lens ₁₁ L1 _{to 11 L4} Although the example in which the optical axis is adjusted by moving in the vertical direction V and the horizontal direction H has been described, the present invention is not limited to this.

For example, conversely, the brackets 13 (the light source 12) is fixed to the vehicle side, such as a housing or an extension, the bracket support mechanism 14 using the same mechanism (see FIG. 3), the lens 11 _L1 to 11 _The optical axis may be adjusted by moving _L4 in the vertical direction V and the horizontal direction H with respect to the bracket 13 (each light source 12).

According to this modification, unlike the conventional case in which the entire vehicle lamp unit is tilted to adjust the optical axis, each light source 12 is fixed to the vehicle side, and the bracket 13 which is a part of the vehicle lamp unit 10 is attached to the bracket 13. The corresponding movable member (the lenses 11 _{L1 to} 11 _L4 are fixed) is moved in the vertical direction V and / or the horizontal direction H with respect to each light source 12 fixed on the vehicle side to adjust the optical axis. because the configuration, a lens 11 _L1 to 11 _L4 is hardly moved during the optical axis adjustment, it is possible to realize a vehicle lamp unit which little effect on appearance than conventional.

In addition, according to the present modification, the lenses 11 _{L1 to} 11 _L4 hardly move during the optical axis adjustment, so that the movement space of the lenses 11 _{L1 to} 11 _L4 of the vehicular lamp unit 10 can be reduced as compared with the conventional case.

Moreover, although the said embodiment demonstrated the example using four optical systems provided with the lens 11 (lens 11 _L1 etc.) and the light source 12, this invention is not limited to this. The optical system including the lens 11 (lens 11 _L1 or the like) and the light source 12 may be 1 to 3 or 5 or more.

Moreover, although the said embodiment demonstrated the example using the so-called direct projection type | mold optical system provided with the lens 11 (lens _11L1 etc.) and the light source 12, this invention is not limited to this. For example, as shown in FIG. 6, the projection lens 15 disposed on the front side of the vehicle, the light source 16 disposed on the rear side of the vehicle, and the light emitted from the light source 16 are arranged in the radiation direction of the light source 16. In addition, the light incident from the light source 16 is condensed near the optical axis AX of the projection lens 15 and transmitted through the projection lens 15 to form a low beam light distribution pattern (part or all). A so-called projector-type optical system is used that includes a reflecting surface 17 and a shade 18 disposed between the projection lens 15 and the light source 16 in a state where the upper end edge is positioned at the focal point F (or the vicinity thereof) of the projection lens 15. May be.

  In this case, the light source 16, the reflecting surface 17 and the shade 18 are fixed to the vehicle side such as a housing, and the projection lens 15 is replaced with the light source 16 and the reflecting surface 17 by using a mechanism similar to the bracket support mechanism 14 (see FIG. 3). The optical axis can be adjusted by moving the shade 18 in the vertical direction V and the horizontal direction H.

According to this modification, unlike the conventional case in which the entire vehicle lamp unit is tilted to adjust the optical axis, each light source 15, each reflecting surface 17 and each shade 18 are fixed to the vehicle side, and the vehicle lamp unit A movable member (lenses 11 _{L1 to} 11 _L4 are fixed) corresponding to the bracket 13 which is a part of the light source 15, the reflecting surface 17 and the shade 18 fixed to the vehicle side. Since the optical axis is adjusted by moving in the direction V and / or the horizontal direction H, the lenses 11 _{L1 to} 11 _L4 hardly move during the optical axis adjustment, and the vehicle has little influence on the appearance as compared with the conventional case. A lamp unit can be realized.

In addition, according to the present modification, the lenses 11 _{L1 to} 11 _L4 hardly move during the optical axis adjustment, so that the movement space of the lenses 11 _{L1 to} 11 _L4 of the vehicular lamp unit 10 can be reduced as compared with the conventional case.

  In the above embodiment, the lens 11 is designed to form a (part of) a low beam light distribution pattern (that is, the vehicle lamp unit 10 is a headlamp). The present invention is not limited to this. For example, the lens 11 may be designed to form a fog lamp light distribution pattern (that is, the vehicle lamp unit 10 may be configured as a fog lamp). Alternatively, the lens 11 may be designed to form a light distribution pattern for other vehicular lamps.

[Second Embodiment]
Next, a vehicle lamp unit according to a second embodiment of the present invention will be described with reference to the drawings.

  The vehicular lamp unit 20 of the present embodiment is a headlamp, and is disposed on each of the left and right sides of the front portion of the vehicle. Since the left and right vehicle lamp units 20 are substantially symmetrical and have the same configuration, the following description will focus on the vehicle lamp unit 20 arranged on the left side.

As shown in FIG. 7A, FIG. 7B, and FIG. 8, the vehicular lamp unit 20 includes a lens 21 disposed on the front side of the vehicle, and a vehicle rear side focal point F _{L1 to} F _{L4 of the} lens 21 (or A plurality of optical systems (so-called direct projection type optical systems) provided with a light source 22 that is disposed in the vicinity thereof and emits light for forming a (part of) low beam light distribution pattern through the lens 21 And a bracket 23 disposed on the rear side of the vehicle.

Hereinafter, in FIG. 7A, the lenses 21 are referred to as a lens 21 _L1 , a lens 21 _L2 , a lens 21 _L3 , and a lens 21 _{L4 in} order from the left side. Moreover, the vehicle rear side focal points of the lenses 21 _{L1 to} 21 _L4 are referred to as F _{L1 to} F _L4 (see FIG. 8). The optical axes of the lenses 21 _{L1 to} 21 _L4 are referred to as AX _L1 to AX _L4 (see FIG. 8).

Each lens 21 is fixed to the vehicle side such as a housing or an extension. Unlike the first embodiment, each lens 21 is a projection lens having a different focal length. The vehicle rear-side focal points F _{L1 to} F _L4 of each lens 21 are located in the same vertical plane orthogonal to the lamp optical axis AX (see FIG. 8).

The lenses 21 _L1 and 21 _L2 are, for example, partial distribution light patterns P1 in which light emitted from the light source 22 and transmitted through the lenses 21 _L1 and 21 _L2 is part of the low beam light distribution pattern (see FIG. 3A). The exit surface shape and / or the entrance surface shape are designed so as to form a The partial light distribution pattern P1 has an oblique cut (for example, 45 °) connecting the own lane side cut-off line CL1 extending in the horizontal direction, the opposite lane side cut-off line CL2 extending in the horizontal direction, and both the cut-off lines CL1 and CL2 at the upper edge. Includes offline CL3.

The lenses 21 _L3 and 21 _L4 are partially distributed light patterns P2 in which the light emitted from the light source 22 and transmitted through the lenses 21 _L3 and 21 _L4 is part of the low beam light distribution pattern (horizontal than the partial light distribution pattern P1). The exit surface shape and / or the entrance surface shape are designed so as to form (see FIG. 3B).

  The light distribution patterns for low beam are formed by superimposing the respective part distribution light patterns P1 and P2.

  Each light source 22 is fixed to a vertical surface 23a perpendicular to the lamp optical axis AX of a bracket 23 (corresponding to the movable member of the present invention) made of a material having excellent thermal conductivity such as aluminum alloy (FIG. 7 ( a)). The bracket 23 includes heat radiating fins 23b. In order to further improve the heat dissipation performance, it is preferable to interpose a heat conducting member such as heat conducting grease between each light source 22 and the vertical surface 23a of the bracket 23.

As each light source 22, for example, a light source module in which a semiconductor light emitting element (for example, a white LED) having a rectangular light emitting unit is mounted on a substrate can be used. As shown in FIG. 8, each light source 22 has one side of the rectangular light emitting unit (for example, the lower end edge of the rectangular light emitting unit), and the vehicle rear side focal points F _{L1 to} F _L4 (or the vicinity thereof) of the lenses 21 _{L1 to} 21 _L4. Is arranged.

  As shown in FIGS. 7A and 7B, the bracket 23 is supported so as to be swingable about a rotation shaft 24 extending in a direction parallel (or substantially parallel) to the lamp optical axis AX. Yes. The bracket 23 (each light source 22) is fixed at an arbitrary position after swinging by a known fixing means (for example, a screw).

When the bracket 23 (the light sources 22) is swung, the positional relationship between the light sources 22 and the lenses ₂₁ L1 _{through 21 L4} (vehicle rear side focal point _F L1 _{to F L4} of) changes. In accordance with the change in the positional relationship, the irradiation direction of the light emitted from each light source 22 and transmitted through each lens 21 _{L1 to} 21 _L4 changes as follows.

For example, as shown in FIGS. 9A to 9D, when each light source 22 is positioned at the vehicle rear side focal point F _{L1 to} F _L4 (or the vicinity thereof) of each lens 21 _{L1 to} 21 _L4 , light transmitted radiated each lens ₂₁ L1 _{through 21 L4} from the light source 22 is irradiated in a direction parallel (or substantially parallel) to the optical axis _AX L1 _{~AX L4} of each lens ₂₁ L1 _{through 21 L4.}

On the other hand, as shown in FIGS. 9E to 9H, when each light source 22 is positioned above the vehicle rear side focal points F _{L1 to} F _L4 of the lenses 21 _{L1 to} 21 _L4 , light transmitted radiated each lens ₂₁ L1 _{through 21 L4} is irradiated obliquely downward with respect to the optical axis _AX L1 _{~AX L4} of each lens ₂₁ L1 _{through 21 L4.}

Similarly, if the light sources 22 is positioned below the rear side focal point _F L1 _{to F L4} of each lens ₂₁ L1 _{through 21 L4,} light transmitted through the lens ₂₁ L1 _{through 21 L4} is emitted from the light sources 22 It is irradiated obliquely upward with respect to the optical axis _AX L1 _{~AX L4} of each lens ₂₁ L1 _{through 21 L4.}

Similarly, if the light sources 22 is positioned on the right side of the vehicle rear-side focal point _F L1 _{to F L4} of each lens ₂₁ L1 _{through 21 L4,} light transmitted through the lens ₂₁ L1 _{through 21 L4} is emitted from the light sources 22 It is irradiated obliquely left direction with respect to the optical axis _AX L1 _{~AX L4} of each lens ₂₁ L1 _{through 21 L4.}

Similarly, if the light sources 22 is positioned on the left side of the vehicle rear-side focal point _F L1 _{to F L4} of each lens ₂₁ L1 _{through 21 L4,} light transmitted through the lens ₂₁ L1 _{through 21 L4} is emitted from the light sources 22 It is irradiated obliquely right direction with respect to the optical axis _AX L1 _{~AX L4} of each lens ₂₁ L1 _{through 21 L4.}

Incidentally, when the bracket 23 (the light sources 22) is swung, but greatly moved vertically farther light source 22 from the axis of rotation 24, if the focal length of each lens ₂₁ L1 _{through 21 L4} are identical, each light source Due to the difference in the amount of movement 22, the irradiation direction of light passing through the lens 21 (for example, the lens 21 _L4 ) close to the rotation axis 24 and the light passing through the lens 21 (for example, the lens 21 _L1 ) far from the rotation axis 24. The direction of irradiation is misaligned.

In order to absorb this shift and align the irradiation direction of the light transmitted through the lenses 21 _{L1 to} 21 _L4 , the following conditions are employed.

[Equation 1]
The ratio of the distance from the rotation axis 24 to the light sources 22 (Distance l1: Distance l2: distance l3, the distance l4) = the focal length f1 of the focal ratio of the distance (lens _{21 L1} of the lens ₂₁ L1 _{through 21 L4:} Lens _{21 L2} Focal length f2: focal length f3 of lens 21 _L3 : focal length f4 of lens 21 _L4 )
In this embodiment, f1 = 8 [mm], f2 = 6 [mm], f3 = 4 [mm], f4 = 2 [mm], l1 = 100 [mm], l2 = 75 [mm], l3 = 50 [Mm], l4 = 25 mm is adopted. That is, the ratio of the distance from the rotating shaft 24 to each light source 22 (distance 11: distance 12: distance 13; distance 14) = the ratio of the focal lengths of the lenses 21 _{L1 to} 21 _L4 (focal length f1: lens 21 _L1 ) 21 _L2 focal length f2: lens 21 _L3 focal length f3: lens 21 _L4 focal length f4) = 4: 3: 2: 1.

  When the bracket 23 (each light source 22) swings by the angle θ under the above conditions, the vertical movement amounts h1 to h4 of each light source 22 are expressed by the following equations.

[Equation 2]
A vertical movement amount h1 = l1 × sin θ of the light source 22 corresponding to the lens 21 _L1.
Vertical moving amount of light source 22 corresponding to the lens _{21 L2} h2 = l2 × _sinθ
Vertical moving amount of light source 22 corresponding to the lens _{21 L3} h3 = l3 × _sinθ
Vertical moving amount of light source 22 corresponding to the lens _{21 L4} h4 = l4 × _sinθ
Here, the ratio of the optical axis change of the lenses 21 _{L1 to} 21 _L4 is expressed by the following equation.

h1 / f1 = 4 × 14 × sin θ / (4 × f4) = 14 × sin θ / f4
h2 / f2 = 3 × 14 × sin θ / (3 × f4) = 14 × sin θ / f4
h3 / f3 = 2 × 14 × sin θ / (2 × f4) = 14 × sin θ / f4
h4 / f4 = l4 × sin θ / F4
From the above, when the above condition is satisfied, even if the bracket 23 (each light source 22) is swung by the angle θ, the ratio of the optical axis change of each lens 21 _{L1 to} 21 _L4 becomes equal (that is, each lens 21 _L1 to 21 _L1 . It can be seen that the irradiation direction of light passing through 21 _L4 is aligned.

As described above, according to the positional relationship between the light sources 22 and the lenses ₂₁ L1 _{through 21 L4} (vehicle rear side focal point _F L1 _{to F L4)} of each lens ₂₁ L1 _{through 21 L4} is emitted from the light sources 22 since the irradiation direction of the transmitted light is changed, the bracket 23 (the light source 22), is swung in against each lens ₂₁ L1 _{through 21 L4} (vehicle rear side focal point _F L1 _{to F L4)} of (i.e. The optical axis can be adjusted by changing the positional relationship between the light sources 22 and the rear focal points F _{L1 to} F _L4 of the lenses 21 _{L1 to} 21 _L4 .

Further, according to the present embodiment, unlike the conventional case where the entire vehicle lamp unit 20 is tilted to adjust the optical axis, the lenses 21 _{L1 to} 21 _L4 are fixed to the vehicle side, and the vehicle lamp unit 10 the bracket 23 (the light sources 22) is a part, because rocked by a structure for adjusting the optical axis with respect to each lens 21 _L1 through 21 _L4 fixed to the vehicle side, each lens when the optical axis adjustment 21 _L1 through 21 _L4 does not move at all, it is possible to realize a vehicular optical unit 20 does not at all affect the appearance.

In addition, according to the present embodiment, since the lenses 21 _{L1 to} 21 _L4 do not move at all when adjusting the optical axis, a space for moving the projection lens of the vehicular lamp unit, which has been conventionally required, becomes unnecessary.

  Next, a comparative example will be described.

  For example, in a conventional vehicle lamp unit (unit length: 100 [mm]), when the optical axis adjustment angle is 2.0 °, the amount of movement of the vehicle lamp unit end (at the time of vertical adjustment) is 1. 4 [mm].

  On the other hand, in the vehicular lamp unit 20 of the present embodiment, when the optical axis adjustment angle is 2.0 °, the movement amount of the end portion of the bracket 23 is 0.35 [mm] (the rotation angle of the bracket 13 is 0. 0). 2 °).

  As is clear from the above comparative example, according to the present embodiment, the amount of movement of the movable portion is smaller than that of the conventional vehicle lamp unit (conventional: 1.4 [mm]; 35 [mm]), the moving space of the movable part can be reduced as compared with the conventional case.

  Next, a modified example will be described.

In the above embodiment, the lenses 21 _{L1 to} 21 _L4 are fixed to the vehicle side such as the housing and the extension, and the bracket 23 (each light source 22) is shaken by using the mechanism (rotary shaft 24) shown in FIG. Although the example of adjusting the optical axis by moving is described, the present invention is not limited to this.

For example, on the contrary, the bracket 23 (each light source 22) is fixed to the vehicle side such as a housing or an extension, and each lens is used by using a mechanism similar to the mechanism (rotary shaft 24) shown in FIG. 21 _{L1 to} 21 _L4 may be swung to adjust the optical axis.

According to this modification, unlike the conventional case in which the entire vehicular lamp unit is tilted to adjust the optical axis, each light source 22 is fixed to the vehicle side and attached to the bracket 23 that is a part of the vehicular lamp unit 20. Since the corresponding movable member (the lenses 21 _{L1 to} 21 _L4 are fixed) is oscillated with respect to the light sources 22 fixed on the vehicle side to adjust the optical axis, the optical axis is adjusted. It is possible to realize a vehicular lamp unit in which the lenses 21 _{L1 to} 11 _L4 hardly move and hardly affect the appearance as compared with the conventional case.

In addition, according to this modification, the lenses 21 _{L1 to} 21 _L4 hardly move during the optical axis adjustment, so that the moving space of the lenses 21 _{L1 to} 21 _L4 of the vehicle lamp unit 20 can be saved as compared with the conventional case.

Moreover, although the said embodiment demonstrated the example using four optical systems provided with the lens 21 (lens 21 _L1 etc.) and the light source 22, this invention is not limited to this. The optical system including the lens 21 (lens 21 _L1 or the like) and the light source 22 may be 1 to 3 or 5 or more.

Moreover, although the said embodiment demonstrated the example using the so-called direct projection type | mold optical system provided with the lens 21 (lens _21L1 etc.) and the light source 22, this invention is not limited to this. For example, as shown in FIG. 6, the projection lens 15 disposed on the front side of the vehicle, the light source 16 disposed on the rear side of the vehicle, and the light emitted from the light source 16 are arranged in the radiation direction of the light source 16. In addition, the light incident from the light source 16 is condensed near the optical axis AX of the projection lens 15 and transmitted through the projection lens 15 to form a low beam light distribution pattern (part or all). A so-called projector-type optical system is used that includes a reflecting surface 17 and a shade 18 disposed between the projection lens 15 and the light source 16 in a state where the upper end edge is positioned at the focal point F (or the vicinity thereof) of the projection lens 15. May be.

  In this case, the light source 16, the reflecting surface 17, and the shade 18 are fixed to the vehicle side such as a housing, and the projection lens 15 is swung using a mechanism similar to the mechanism (rotary shaft 24) shown in FIG. Thus, the optical axis can be adjusted.

According to this modification, unlike the conventional case in which the entire vehicular lamp unit is tilted to adjust the optical axis, each light source 16, the reflecting surface 17, and the shade 18 are fixed to the vehicle side, and the vehicular lamp unit 20 A movable member (each lens 21 _{L1 to} 21 _L4 is fixed) corresponding to a part of the bracket 23 is swung with respect to each light source 22 fixed on the vehicle side to adjust the optical axis. Therefore, it is possible to realize a vehicular lamp unit in which the lenses 21 _{L1 to} 21 _L4 hardly move during the optical axis adjustment and hardly affect the appearance as compared with the conventional case.

In addition, according to this modification, the lenses 21 _{L1 to} 21 _L4 hardly move during the optical axis adjustment, so that the moving space of the lenses 21 _{L1 to} 21 _L4 of the vehicle lamp unit 20 can be saved as compared with the conventional case.

  In the above embodiment, the lens 21 is designed to form a (part of) the light distribution pattern for low beam (that is, the vehicle lamp unit 20 is a headlamp). The present invention is not limited to this. For example, the lens 21 may be designed to form a fog lamp light distribution pattern (that is, the vehicle lamp unit 20 may be configured as a fog lamp). Alternatively, the lens 21 may be designed to form a light distribution pattern for other vehicle lamps.

  The above embodiment is merely an example in all respects. The present invention is not construed as being limited to these descriptions. The present invention can be implemented in various other forms without departing from the spirit or main features thereof.

10 ... vehicle lamp _{unit, 11 (11 L1 ~11 L4)} ... lens, 12 ... light source, 13 ... Bracket, 13a ... vertical plane, 13b ... radiation fins 14 ... bracket support mechanism, 15 ... projection lens 16 ... light source , 17 ... Reflecting surface, 18 ... Shade, 20 ... Vehicle lamp unit, 21 (21 _{L1 to} 21 _L4 ) ... Lens, 22 ... Light source, 23 ... Bracket, 23a ... Vertical surface, 23b ... Radiating fin, 24 ... Rotating shaft

Claims (6)

A plurality of optical systems comprising: a projection lens; and a light source that is disposed at or near the focal point of the projection lens and that emits light for transmitting the projection lens to form a predetermined light distribution pattern;
A movable member to which a light source of each of the plurality of optical systems is fixed;
Support means for supporting the movable member so as to be movable in a vertical direction and / or a horizontal direction in a vertical plane orthogonal to the lamp optical axis with respect to the projection lenses of the plurality of optical systems;
Fixing means for fixing the movable member at an arbitrary position after movement;
With
A projection lens of each of the plurality of optical systems is fixed to the vehicle side,
The projection lamp of each of the plurality of optical systems has the same focal length. A plurality of optical systems comprising: a projection lens; and a light source that is disposed at or near the focal point of the projection lens and that emits light for transmitting the projection lens to form a predetermined light distribution pattern;
A movable member to which a projection lens of each of the plurality of optical systems is fixed;
Support means for supporting the movable member so as to be movable in a vertical direction and / or a horizontal direction in a vertical plane orthogonal to a lamp optical axis with respect to each light source of the plurality of optical systems;
Fixing means for fixing the movable member at an arbitrary position after movement;
With
The light sources of the plurality of optical systems are fixed to the vehicle side,
The projection lamp of each of the plurality of optical systems has the same focal length. The projection lens, the light source, and the light emitted from the light source are arranged in the radiation direction of the light source, and the light incident from the light source is condensed near the optical axis of the projection lens, A reflecting surface configured to transmit a projection lens to form a predetermined light distribution pattern, and disposed between the projection lens and the light source in a state where an upper end edge is positioned at or near the focal point of the projection lens A vehicle lamp unit comprising:
A movable member to which a projection lens of each of the plurality of optical systems is fixed;
A support means for supporting the movable member so as to be movable in a vertical direction and / or a horizontal direction within a vertical plane perpendicular to the lamp optical axis with respect to the light source, the reflecting surface, and the shade of each of the plurality of optical systems;
Fixing means for fixing the movable member at an arbitrary position after movement;
With
The light source, reflecting surface, and shade of each of the plurality of optical systems are fixed to the vehicle side,
The projection lamp of each of the plurality of optical systems has the same focal length. A plurality of optical systems comprising: a projection lens; and a light source that is disposed at or near the focal point of the projection lens and that emits light for transmitting the projection lens to form a predetermined light distribution pattern;
A movable member to which a light source of each of the plurality of optical systems is fixed;
Support means for supporting the movable member so as to be swingable about a rotation axis extending in a direction parallel to the optical axis of the lamp with respect to each of the projection lenses of the plurality of optical systems;
Fixing means for fixing the movable member at an arbitrary position after swinging;
With
A projection lens of each of the plurality of optical systems is fixed to the vehicle side,
A vehicular lamp unit, wherein a ratio of a distance from the rotation axis to a light source of each of the plurality of optical systems is equal to a ratio of a focal length of a projection lens of each of the plurality of optical systems. A plurality of optical systems comprising: a projection lens; and a light source that is disposed at or near the focal point of the projection lens and that emits light for transmitting the projection lens to form a predetermined light distribution pattern;
A movable member to which a projection lens of each of the plurality of optical systems is fixed;
A support means for supporting the movable member so as to be swingable about a rotation axis extending in a direction parallel to a lamp optical axis with respect to each of the light sources of the plurality of optical systems;
Fixing means for fixing the movable member at an arbitrary position after swinging;
With
The light sources of the plurality of optical systems are fixed to the vehicle side,
A vehicular lamp unit, wherein a ratio of a distance from the rotation axis to a light source of each of the plurality of optical systems is equal to a ratio of a focal length of a projection lens of each of the plurality of optical systems. The projection lens, the light source, and the light emitted from the light source are arranged in the radiation direction of the light source, and the light incident from the light source is condensed near the optical axis of the projection lens, A reflecting surface configured to transmit a projection lens to form a predetermined light distribution pattern, and disposed between the projection lens and the light source in a state where an upper end edge is positioned at or near the focal point of the projection lens A vehicle lamp unit comprising:
A movable member to which a projection lens of each of the plurality of optical systems is fixed;
A support means for supporting the movable member so as to be swingable around a rotation axis extending in a direction parallel to the lamp optical axis with respect to the light source, the reflection surface, and the shade of each of the plurality of optical systems;
Fixing means for fixing the movable member at an arbitrary position after swinging;
With
The light source, reflecting surface, and shade of each of the plurality of optical systems are fixed to the vehicle side,
A vehicular lamp unit, wherein a ratio of a distance from the rotation axis to an optical axis of a projection lens of each of the plurality of optical systems is equal to a ratio of a focal length of each projection lens of the plurality of optical systems.

Images