JP2014229353A - Vehicular headlamp - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a vehicular headlamp in which a movable lens sufficiently bears an impact caused when a stopper of the movable lens is brought into contact with a stopper on a stationary side.SOLUTION: The vehicular headlamp includes a semiconductor light source 2, a lens 3, and a light control member 4. The light control member 4 has a stopper 44 for positioning the light control member 4 at a first position and a second position. The light control member 4 is made of a material having an impact strength higher than that of the material of the lens 3. Thus, in the vehicular headlamp, the light control member 4 can sufficiently bear the impact caused when the stopper 44 of the light control member 4 is brought into contact with a stopper 73 on the stationary side.

Description

  The present invention relates to a vehicle headlamp including a movable lens and a fixed lens.

  This type of vehicle headlamp has been conventionally used (for example, Patent Document 1). Hereinafter, a conventional vehicle headlamp will be described.

  A conventional vehicle headlamp includes a semiconductor light source, a movable lens, and a fixed lens. In the conventional vehicle headlamp, two different light distribution patterns can be obtained by moving the movable lens.

JP 2010-153181 A

  In such a vehicle headlamp, in order to position the movable lens at a predetermined position, there is a case where a stopper that contacts the stopper on the fixed side is provided. In this case, it is necessary for the movable lens to sufficiently withstand the impact when the movable lens stopper comes into contact with the fixed stopper.

  The problem to be solved by the present invention is that the movable lens needs to sufficiently withstand the impact when the stopper of the movable lens contacts the stopper on the fixed side.

  The present invention (invention according to claim 1) includes a semiconductor-type light source, a movable lens, and a fixed lens. The movable lens has a fixed-side stopper for positioning the movable lens at a predetermined position. The stopper which contacts is provided, The movable lens is comprised from the material whose impact strength is larger than a fixed lens, It is characterized by the above-mentioned.

  In this invention (the invention according to claim 2), the movable lens is arranged closer to the semiconductor light source than the fixed lens, and the movable lens is made of a material having higher heat resistance than the fixed lens. It is characterized by that.

  In this invention (the invention according to claim 3), the movable lens is arranged closer to the semiconductor-type light source than the fixed lens, and the movable lens is made of a material having a higher refractive index than the fixed lens. It is characterized by that.

  In the present invention (the invention according to claim 4), the movable lens is arranged closer to the semiconductor-type light source than the fixed lens, and the movable lens is made of a material having lower weather resistance than the fixed lens. It is characterized by that.

  The present invention (invention according to claim 5) is characterized in that the movable lens is rotatably attached to the bearing member, and the movable lens is made of a material having greater elasticity than the fixed lens. To do.

  In the present invention (the invention according to claim 6), the movable lens includes a lens portion and an attachment portion, and the lens portion and the attachment portion have an integral structure, and at least the lens portion is constituted by a light transmitting member. It is characterized by being.

  In the vehicle headlamp according to the present invention, since the movable lens is made of a material having a larger impact strength than the fixed lens, the movable lens stopper is resistant to an impact when it comes into contact with the fixed stopper. The movable lens can sufficiently withstand compared to the fixed lens.

FIG. 1 is an exploded perspective view of main components of a lamp unit showing an embodiment of a vehicle headlamp according to the present invention. FIG. 2 is a perspective view showing the lamp unit. FIG. 3 is a front view showing the lamp unit. FIG. 4 is an explanatory diagram (an explanatory diagram corresponding to the cross-sectional view taken along the line IV-IV in FIG. 3) illustrating the optical path when the light control member is located at the first position. FIG. 5 is an explanatory diagram showing an optical path when the light control member is located at the second position (an explanatory diagram corresponding to the sectional view taken along the line IV-IV in FIG. 3). FIG. 6 is an explanatory diagram of an isoillumination curve showing a low beam light distribution pattern and a high beam light distribution pattern. FIG. 7 is a perspective view showing the entire light control member. FIG. 8 is a front view showing the entire light control member. FIG. 9 is an explanatory diagram showing the impact strength of PC and the impact strength of PMMA.

  Hereinafter, an example of an embodiment (example) of a vehicle headlamp according to the present invention will be described in detail with reference to the drawings. In addition, this invention is not limited by this embodiment. FIG. 6 is an explanatory diagram of an isoilluminance curve that shows a simplified light distribution pattern on a road surface drawn by computer simulation. In the explanatory diagram of the isoilluminance curve, the central isoilluminance curve indicates high illuminance, and the outer isoilluminance curve indicates low illuminance. The unit of the number is “m”. 4 and 5, the cross sections of the lens and the light control member are not hatched. In this specification, front, rear, upper, lower, left, and right are front, rear, upper, lower, left, and right when the vehicle headlamp according to the present invention is mounted on a vehicle.

(Description of Configuration of Embodiment)
Hereinafter, the configuration of the vehicle headlamp according to this embodiment will be described. In FIG. 1, reference numeral 1 denotes a vehicle headlamp (for example, a headlamp) according to this embodiment. The vehicle headlamp 1 is mounted on both left and right ends of the front portion of the vehicle C.

(Explanation of lamp unit)
The vehicle headlamp 1 includes a lamp housing (not shown), a lamp lens (not shown), a semiconductor light source 2, and a lens 3 as a fixed lens, as shown in FIGS. A light control member 4 as a movable lens, a drive member 5, a lens cover member 6, a bearing member 7, a base member 8, and a cooling member 9 are provided.

  The semiconductor-type light source 2, the lens 3, the light control member 4, the drive member 5, the lens cover member 6, the bearing member 7, the base member 8, and the cooling member 9 constitute a lamp unit. The lamp housing and the lamp lens define a lamp chamber (not shown). The lamp units 2, 3, 4, 5, 6, 7, 8, and 9 are disposed in the lamp chamber, and have an optical axis adjustment mechanism for vertical direction (not shown) and an optical axis adjustment for horizontal direction. It is attached to the lamp housing via a mechanism (not shown).

(Description of the semiconductor-type light source 2)
As shown in FIGS. 1, 4, and 5, the semiconductor-type light source 2 is a self-luminous semiconductor-type light source such as an LED, an OEL, or an OLED (organic EL) in this example. The semiconductor light source 2 includes a light emitting chip (LED chip) 20, a package (LED package) in which the light emitting chip 20 is sealed with a sealing resin member, a substrate 21 on which the package is mounted, and an attachment to the substrate 21. And a connector 22 for supplying a current from a power source (battery) to the light emitting chip 20. In FIGS. 4 and 5, the connector 22 is not shown.

  The substrate 21 is positioned on the light source mounting portion 80 of the base member 8 by positioning holes and positioning pins, and is mounted on the light source mounting portion 80 of the base member 8 by screws or the like. As a result, the semiconductor light source 2 is attached to the base member 8.

  In this example, the light emitting chip 20 has a planar rectangular shape (planar rectangular shape). That is, four square chips are arranged in the X-axis direction (horizontal direction). Two, three, or five or more square chips, one rectangular chip, or one square chip may be used. Front of the light emitting chip 20 In this example, the rectangular front forms the light emitting surface 23. The light emitting surface 23 faces the front side of the reference optical axis (reference axis) Z of the lens 3. The center O of the light emitting surface 23 of the light emitting chip 20 is located at or near the reference focal point F of the lens 3 and on or near the reference optical axis Z of the lens 3.

  In FIG. 1, X, Y, and Z constitute an orthogonal coordinate (XYZ orthogonal coordinate system). The X axis is a horizontal axis in the left-right direction passing through the center O of the light emitting surface 23 of the light emitting chip 20, and in this embodiment, the right side is the + direction and the left side is the-direction. The Y axis is a vertical axis passing through the center O of the light emitting surface 23 of the light emitting chip 20. In this embodiment, the upper side is the + direction and the lower side is the − direction. Furthermore, the Z axis is a normal line (perpendicular) passing through the center O of the light emitting surface 23 of the light emitting chip 20, that is, an axis in the front-rear direction orthogonal to the X axis and the Y axis. The front side is the + direction and the rear side is the − direction.

(Description of lens 3)
The lens 3 is made of a light transmissive member, in this example, PMMA (polymethacrylic resin). As shown in FIGS. 1 to 5, the lens 3 includes a main lens part 30, an auxiliary lens part (additional lens part) 31, and an attachment part 32. The attachment portion 32 is integrally provided at both left and right end portions of the main lens portion 30. The mounting portion 32 is positioned on the lens mounting portion 81 of the base member 8 by a positioning hole and a positioning pin through the lens cover member 6, and the lens mounting portion 81 of the base member 8 by a screw or the like. Is attached. As a result, the lens 3 is attached to the base member 8 via the lens cover member 6. In this example, the attachment portion 32 has an integral structure with the lens 3, but may have a separate structure from the lens 3.

  The lens 3 converts light from the semiconductor-type light source 2 into a low beam light distribution pattern (passing light distribution pattern) LP shown in FIG. 6A and a high beam light distribution pattern shown in FIG. 6B. (Light distribution pattern for travel) The light is irradiated forward of the vehicle C as HP. The low-beam light distribution pattern LP has a lower horizontal cutoff line, an oblique cutoff line, and an upper horizontal cutoff line. The high beam light distribution pattern HP has a hot zone (high luminous intensity band) at the center.

(Description of the main lens unit 30)
The main lens unit 30 has the reference optical axis Z and the reference focal point F as shown in FIGS. The main lens unit 30 uses the central light L1 and a part of the ambient light among the light emitted from the semiconductor light source 2. The central light L1 is light having a predetermined angle (in this example, about 60 °) or more from the X-axis or Y-axis of the hemispherical emission range of the semiconductor-type light source 2, and is the center of the main lens unit 30. It is light incident on the part. The ambient light is light having a predetermined angle (about 60 ° in this example) or less from the X axis or Y axis of the hemispherical emission range of the semiconductor light source 2. A part of the ambient light is light that is incident on a peripheral part of the main lens unit 30 in the peripheral light. In this example, the main lens unit 30 is a transmissive lens unit that transmits light from the semiconductor light source 2.

  The main lens unit 30 uses the light from the semiconductor-type light source 2 (the central light L1 and part of the ambient light) as a main light distribution pattern (basic light distribution pattern), and in this embodiment, a low beam light distribution. The light is irradiated in front of the vehicle C as the main light distribution pattern of the pattern LP and the main light distribution pattern of the high beam light distribution pattern HP. That is, the main lens unit 30 uses the light directly incident from the semiconductor light source 2 (the central light L1 and part of the ambient light) as the main light distribution pattern of the low beam light distribution pattern LP. Light radiated forward and transmitted from the semiconductor-type light source 2 through the light control member 4 (the central light L1 and part of the ambient light in the X-axis direction) and directly from the semiconductor-type light source 2 Incident light (a part of the remaining ambient light excluding the part of the ambient light in the X-axis direction) is irradiated in front of the vehicle C as the main light distribution pattern of the high beam light distribution pattern HP.

  The main lens unit 30 includes an incident surface 300 on which light from the semiconductor-type light source 2 enters the main lens unit 30 and an output surface 301 on which light incident on the main lens unit 30 exits. Has been. The entrance surface 300 of the main lens unit 30 is composed of a free-form surface or a composite quadric surface. The exit surface 301 of the main lens portion 30 has a convex shape protruding to the opposite side of the semiconductor light source 2, and is composed of a free curved surface or a compound quadratic curved surface.

(Description of the auxiliary lens unit 31)
As shown in FIGS. 4 and 5, the auxiliary lens portion 31 is provided around the main lens portion 30 on the lower side (lower side) in this embodiment. As a result, an opening (upper opening) is formed between the semiconductor-type light source 2 and the upper portion of the lens 3.

  The auxiliary lens unit 31 effectively uses another part L2 of ambient light among the light emitted from the semiconductor-type light source 2. The other part L2 of the ambient light is light that is incident on the auxiliary lens unit 31 among the ambient light. In this example, the auxiliary lens portion 31 is a total reflection type lens portion that totally reflects the other part L2 of the ambient light. The auxiliary lens unit 31 is integral with the main lens unit 30.

  The auxiliary lens unit 31 uses the other part L2 of the ambient light as an auxiliary light distribution pattern, and in this embodiment, the auxiliary light distribution pattern of the low beam light distribution pattern LP and the auxiliary light distribution pattern HP of the high beam. Irradiate the front of the vehicle C as a light distribution pattern. That is, the auxiliary lens unit 31 uses the light transmitted through the light control member 4 from the semiconductor light source 2 (the other part L2 of the ambient light) as an auxiliary light distribution pattern of the low beam light distribution pattern LP. Light directly incident from C and directly incident from the semiconductor light source 2 (the other part L2 of the ambient light) is used as an auxiliary light distribution pattern of the high beam light distribution pattern HP in front of the vehicle C. Irradiate.

  The auxiliary lens unit 31 includes an incident surface 310 on which another part L2 of the ambient light is incident on the auxiliary lens unit 31, and a reflection on which light incident on the auxiliary lens unit 31 from the incident surface 310 is reflected. A surface 311 and an exit surface 312 from which reflected light reflected by the reflecting surface 311 exits from the auxiliary lens portion 31 to the outside are configured. The entrance surface 310, the reflection surface 311 and the exit surface 312 are each composed of a free-form surface or a composite quadric surface.

(Description of light control member 4)
As shown in FIGS. 7 and 8, the light control member 4 includes a varifocal lens portion 40, a mounting portion 41, and a stopper 44. The variable focus lens part 40, the attachment part 41, and the stopper 44 of the light control member 4 form an integral structure. The light control member 4 is disposed closer to the semiconductor light source 2 than the lens 3.

  The light control member 4 is composed of a light transmitting member, in this example, PC (polycarbonate). As a result, the light control member 4 has a greater impact strength (see FIG. 9), higher heat resistance, higher refractive index, lower weather resistance, and higher elasticity than the lens 3 (see FIG. 9). (See the tensile strain at break).

  The varifocal lens portion 40 is provided in a central portion. The mounting portion 41 is provided on both the left and right sides. The stopper 44 is integrally provided from above and below the mounting portion 41 on the right side.

  Rotating holes 43 are respectively provided in the X-axis direction in the mounting portions 41 on both the left and right sides. The attachment portions 41 on both the left and right sides are rotatably attached to the bearing member 7 through the rotation holes 43 and the shaft portion 72. The bearing member 7 is positioned and attached to the base member 8. As a result, the light control member 4 is attached to the base member 8 via the bearing member 7 so as to be rotatable between a first position and a second position. The rotation center O <b> 1 of the light control member 4 is located behind and below the center O of the light emitting surface 23.

  The light control member 4 is configured to be switchable (rotated) between the first position and the second position by the drive member 5. The first position is such that the lower stopper 44 of the light control member 4 is in contact with the lower stopper 73 of the bearing member 7, and as shown in FIG. This is a position located between the light emitting surface 23 of the semiconductor light source 2 and the incident surface 310 of the auxiliary lens portion 31. In the second position, the upper stopper 44 of the light control member 4 is in contact with the upper stopper 73 of the bearing member 7, and as shown in FIG. This is a position located between the light emitting surface 23 of the light source 2 and the central portion of the incident surface 300 of the main lens portion 30 where the central light L1 is incident. When the light control member 4 is located at the second position, as shown in FIG. 8, the variable focus lens portion 40 and the left and right attachment portions 41 are arranged in parallel in the X-axis direction.

  As shown in FIG. 4, a part (most part) of the variable focus lens part 40 of the light control member 4 and the auxiliary lens part 31 of the lens 3 overlap each other in the vertical direction. As a result, a slight opening (lower opening) is formed between the semiconductor-type light source 2 and the lower portion of the lens 3 and the light control member 4.

(Description of the variable focus lens unit 40)
When the varifocal lens unit 40 is located at the first position, as shown in FIG. 4, the other part L <b> 2 of the ambient light is transmitted and incident into the auxiliary lens unit 31. As a result, the auxiliary light distribution pattern of the low beam light distribution pattern LP is irradiated forward of the vehicle C from the emission surface 312 of the auxiliary lens unit 31.

  When the varifocal lens unit 40 is located at the second position, as shown in FIG. 5, the varifocal lens unit 40 transmits the central light L <b> 1 and enters the central part of the main lens unit 30. As a result, the main light distribution pattern of the high beam light distribution pattern HP is irradiated from the center of the exit surface 301 of the main lens unit 30 to the front of the vehicle C.

  As shown in FIGS. 1, 4, and 5, the incident surface 400 of the varifocal lens unit 40 is in the optical axis (light emission axis) direction of the varifocal lens unit 40, that is, the semiconductor-type light source 2. A concave shape is formed inside the varifocal lens portion 40 with respect to the light emitting surface 23. The exit surface 401 of the varifocal lens unit 40 is in the optical axis (light exit axis) direction of the varifocal lens unit 40, that is, with respect to the light emitting surface 23 of the semiconductor-type light source 2. Convex shape outside.

  The variable focus lens unit 40 changes the focus of the auxiliary lens unit 31. That is, the focal point (pseudo focal point) F1 of the auxiliary lens unit 31 when positioned at the first position is on the upper side and the right side with respect to the focal point F of the auxiliary lens unit 31 when positioned at the second position. It is to be displaced. The upper displacement of the pseudo focus F1 is shown in FIG. 4, but the right displacement is not shown. The pseudo focus F <b> 1 is a pseudo focus of the auxiliary lens unit 31 through the variable focus lens unit 40.

  In the horizontal section, the variable focus lens portion 40 gradually decreases in distance from the incident surface 400 and the exit surface 401 from the right side in this example to the left side in this example. That is, the distance between the entrance surface 400 and the exit surface 401 at the right end of the variable focus lens unit 40 is long, and the entrance surface 400 and the exit surface 401 at the left end of the variable focus lens unit 40 are long. The distance between is short.

  In the variable focus lens unit 40, the distance between the incident surface 400 and the exit surface 401 gradually decreases from the upper side to the lower side in the vertical cross section. That is, the distance between the entrance surface 400 and the exit surface 401 at the upper end of the variable focus lens unit 40 is long, and the entrance surface 400 and the exit surface at the lower end of the variable focus lens unit 40. The distance to 401 is short. In the vertical cross section, the distance between the upper entrance surface 400 and the exit surface 401 and the distance between the lower entrance surface 400 and the exit surface 401 may not change.

  When the variable focus lens unit 40 of the light control member 4 is located at the first position shown in FIG. 4, the focus of the portion on the reference optical axis Z side of the main lens unit 30 is other than It is displaced downward with respect to the focal point of the part.

(Description of drive member 5)
As shown in FIGS. 1 and 2, the drive member 5 positions the light control member 4 so that the movement (rotation and rotation) can be switched between the first position and the second position. The drive member 5 includes a solenoid 50, a connecting pin 51, and a spring 52.

  A mounting portion 53 is provided integrally with the solenoid 50. The mounting portion 53 is positioned on the back side of the base mounting portion 82 of the base member 8 by positioning holes and positioning pins, and is mounted on the back side of the base mounting portion 82 of the base member 8 by screws or the like. It has been. As a result, the solenoid 50 of the drive member 5 is attached to the base member 8. The solenoid 50 has an advance / retreat rod 54.

  One end of the connecting pin 51 is fixed to the tip of the advance / retreat rod 54. The other end of the connecting pin 51 is inserted into a long hole 42 provided in the mounting portion 41 of the light control member 4. As a result, the forward / backward movement of the forward / backward rod 54 of the solenoid 50 is converted into the rotational movement of the light control member 4 via the connecting pin 51 and the long hole 42.

  The spring 52 is attached to the bearing member 7. One end of the spring 52 is in elastic contact with the bearing member 7. The other end of the spring 52 is in elastic contact with the light control member 4. As a result, during normal operation, that is, when the solenoid 50 is not energized, the light control member 4 is positioned at the first position by the force of the spring 52. When the solenoid 50 is energized, the advancing / retracting rod 54 positioned at the forward movement position moves against the force of the spring 52, and the light control member 4 rotates from the first position to the second position. Located in the second position. When the energization of the solenoid 50 is cut off, the advance / retreat rod 54 located at the retracted position moves forward by the force of the spring 52, and the light control member 4 rotates from the second position to the first position. Located in the first position.

(Description of the lens cover member 6)
The lens cover member 6 has a shape that covers the lens 3 as shown in FIGS. The lens cover member 6 is made of a light impermeable member, for example. An opening 60 through which light from the semiconductor-type light source 2 passes through the main lens portion 30 and the auxiliary lens portion 31 of the lens 3 is provided at the center of the lens cover member 6. Attachment portions 61 are integrally provided at both left and right ends of the lens cover member 6. The mounting portion 61 is positioned on the lens mounting portion 81 of the base member 8 together with the mounting portion 32 of the lens 3 by a positioning hole, a positioning pin, and the like, and the lens of the base member 8 by a screw or the like. It is attached to the attachment part 81. As a result, the lens cover member 6 is attached to the base member 8 together with the lens 3.

(Description of bearing member 7)
As shown in FIGS. 1 and 2, the bearing member 7 has a shape that covers the semiconductor light source 2 and the light source mounting portion 80 of the base member 8. The bearing member 7 is made of a light-impermeable member, for example. An opening through which light from the semiconductor-type light source 2 passes through the main lens portion 30 and the auxiliary lens portion 31 of the lens 3 and the variable focus lens portion 40 of the light control member 4 is provided at the center of the bearing member 7. A portion 70 is provided. Mounting portions 71 are integrally provided at the four corners of the bearing member 7. The mounting portion 71 is positioned on the front side of the base mounting portion 82 of the base member 8 by positioning holes and positioning pins, and is positioned on the front side of the base mounting portion 82 of the base member 8 by screws or the like. It is attached. As a result, the bearing member 7 is attached to the base member 8.

  The shaft portions 72 are integrally provided at the center portions on both the left and right sides of the bearing member 7. The rotation holes 43 of the mounting portions 41 on the left and right sides of the light control member 4 are rotatably supported by the shaft portions 72 on the left and right sides by elastic fitting (snap fit). As a result, the light control member 4 is attached to the bearing member 7 so as to be rotatable between the first position and the second position.

  The stoppers 73 are integrally provided above and below the right side of the bearing member 7. The stopper 44 on the lower side of the light control member 4 on the movable side abuts on the stopper 73 on the lower side of the bearing member 7 on the fixed side, so that the light control member 4 is in contact with the bearing member 7. Located in the first position. When the stopper 44 on the upper side of the light control member 4 on the movable side abuts on the stopper 73 on the upper side of the bearing member 7 on the fixed side, the light control member 4 makes the second with respect to the bearing member 7. Located in position.

(Description of base member 8)
As shown in FIGS. 1 to 3, the base member 8 includes the base mounting portion 82, the light source mounting portion 80 at the center of the front side of the base mounting portion 82, and the front side of the base mounting portion 82. And the lens mounting portions 81 at both the left and right end portions. The semiconductor light source 2 is attached to the light source attachment portion 80. The lens 3 is attached to the lens attachment portion 81 via the lens cover member 6. The bearing member 7 on which the light control member 4 is rotatably supported between the first position and the second position is attached to the front side of the base attachment portion 82. The drive member 5 and the cooling member 9 are respectively attached to the back side of the base attachment portion 82.

(Description of cooling member 9)
The cooling member 9 has a cooling fan as shown in FIGS. The cooling member 9 is positioned on the back side of the base mounting portion 82 of the base member 8 and is mounted on the back side of the base mounting portion 82 of the base member 8 with a screw or the like. As a result, the cooling member 9 is attached to the base member 8.

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

  Under normal conditions, that is, when the solenoid 50 is not energized, the advance / retreat rod 54 is positioned at the advance position by the spring force of the spring 52, and the lower stopper 44 of the light control member 4 is the lower stopper of the bearing member 7. 73, the light control member 4 is located at the first position. At this time, as shown in FIG. 4, the variable focus lens unit 40 of the light control member 4 is positioned between the light emitting surface 23 of the semiconductor light source 2 and the incident surface 310 of the auxiliary lens unit 31 of the lens 3. .

  In this normal time, the light emitting chip 20 of the semiconductor light source 2 is turned on. Then, among the light radiated from the light emitting surface 23 of the light emitting chip 20, the central light L1 and the part of the peripheral light of the semiconductor light source 2 are directly from the main lens portion 30 of the lens 3 as shown in FIG. The light enters the main lens unit 30 from the incident surface 300. At this time, the light distribution of the incident light is controlled on the incident surface 300. Incident light that enters the main lens unit 30 exits from the exit surface 301 of the main lens unit 30. At this time, the light distribution of the outgoing light is controlled on the outgoing surface 301. The light emitted from the main lens unit 30 is irradiated in front of the vehicle C as a main light distribution pattern of a low beam light distribution pattern LP having a lower horizontal cut-off line, an oblique cut-off line, and an upper horizontal cut-off line. .

  On the other hand, among the light emitted from the light emitting surface 23 of the light emitting chip 20, the other part L2 of the ambient light of the semiconductor light source 2 is as shown in FIG. 4 of the variable focus lens unit 40 of the light control member 4. The light enters from the incident surface 400 into the variable focus lens unit 40. At this time, the light distribution of the incident light is controlled on the incident surface 400. Incident light that enters the varifocal lens unit 40 exits from the exit surface 401 of the varifocal lens unit 40. At this time, the emitted light is subjected to light distribution control on the emission surface 401.

  Light emitted from the variable focus lens unit 40 enters the auxiliary lens unit 31 from the incident surface 310 of the auxiliary lens unit 31. At this time, the light distribution of the incident light is controlled on the incident surface 310. Incident light that has entered the auxiliary lens unit 31 is totally reflected by the reflecting surface 311 of the auxiliary lens unit 31. At this time, the reflected light is subjected to light distribution control on the reflecting surface 311. The totally reflected light is emitted from the emission surface 312. At this time, the light distribution of the outgoing light is controlled on the outgoing surface 312. The emitted light from the auxiliary lens unit 31 is irradiated in front of the vehicle C as an auxiliary light distribution pattern of the low beam light distribution pattern LP.

  Then, the main light distribution pattern and the auxiliary light distribution pattern are combined (superimposed) to obtain a low beam light distribution pattern LP shown in FIG.

  Then, the solenoid 50 is energized. Then, the advancing / retreating rod 54 moves backward against the spring force of the spring 52, the light control member 4 rotates from the first position toward the second position, and the stopper 44 on the upper side of the light control member 4 moves to the bearing member. 7, the light control member 4 is positioned at the second position. That is, the light control member 4 that has been positioned between the semiconductor-type light source 2 and the auxiliary lens unit 31 until now has the light-emitting surface 23 of the semiconductor-type light source 2 and the main lens unit 30 of the lens 3 as shown in FIG. Between the light incident surface 300 and the light incident surface 300.

  Of the light emitted from the light emitting surface 23 of the light emitting chip 20, the central light L <b> 1 of the semiconductor-type light source 2 enters the variable focus lens unit 40 from the incident surface 400 of the variable focus lens unit 40 of the light control member 4. To do. At this time, the light distribution of the incident light is controlled on the incident surface 400. Incident light that enters the varifocal lens unit 40 exits from the exit surface 401 of the varifocal lens unit 40. At this time, the emitted light is subjected to light distribution control on the emission surface 401.

  Light emitted from the variable focus lens unit 40 enters the main lens unit 30 from the incident surface 300 of the main lens unit 30. A part of the ambient light of the semiconductor light source 2 is directly incident on the main lens unit 30 from the incident surface 300 of the main lens unit 30. At this time, the light distribution of the incident light is controlled on the incident surface 300. Incident light that enters the main lens unit 30 exits from the exit surface 301 of the main lens unit 30. At this time, the light distribution of the outgoing light is controlled on the outgoing surface 301. The emitted light from the main lens unit 30 is irradiated in front of the vehicle C as the main light distribution pattern of the high beam light distribution pattern HP.

  On the other hand, among the light emitted from the light emitting surface 23 of the light emitting chip 20, the other part L2 of the ambient light of the semiconductor light source 2 is directly from the incident surface 310 of the auxiliary lens unit 31, as shown in FIG. The light enters the auxiliary lens unit 31. At this time, the light distribution of the incident light is controlled on the incident surface 310. Incident light that has entered the auxiliary lens unit 31 is totally reflected by the reflecting surface 311 of the auxiliary lens unit 31. At this time, the reflected light is subjected to light distribution control on the reflecting surface 311. The totally reflected light is emitted from the emission surface 312. At this time, the light distribution of the outgoing light is controlled on the outgoing surface 312. The light emitted from the auxiliary lens unit 31 is irradiated in front of the vehicle C as an auxiliary light distribution pattern of the high beam light distribution pattern HP.

  Then, the main light distribution pattern and the auxiliary light distribution pattern are combined (superimposed) to obtain a high beam light distribution pattern HP shown in FIG. 6B.

  Then, the energization to the solenoid 50 is cut off. Then, the advance / retreat rod 54 moves forward by the spring force of the spring 52, the light control member 4 rotates from the second position toward the first position, and the stopper 44 on the lower side of the light control member 4 moves to the bearing member 7. When the light control member 4 contacts the lower stopper 73, the light control member 4 is positioned at the first position. That is, the light control member 4 that has been positioned between the semiconductor-type light source 2 and the main lens unit 30 is positioned between the semiconductor-type light source 2 and the auxiliary lens unit 31.

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

  In the vehicle headlamp 1 according to this embodiment, the light control member 4 as a movable lens is made of a material having a larger impact strength than the lens 3 as a fixed lens. For this reason, the light control member 4 is more sufficient than the lens 3 against an impact when the upper and lower stoppers 44 of the movable side light control member 4 come into contact with the upper and lower stoppers 73 of the fixed side bearing member 7. Can withstand.

  In the vehicle headlamp 1 according to this embodiment, the lower stopper 44 of the light control member 4 is in contact with the lower stopper 73 of the bearing member 7 so that the light control member 4 is positioned at the first position. Thus, a low beam light distribution pattern LP shown in FIG. 6A is obtained. When the upper stopper 44 of the light control member 4 abuts on the upper stopper 73 of the bearing member 7 and the light control member 4 is positioned at the second position, the high beam light distribution pattern HP shown in FIG. Is obtained.

  In the vehicle headlamp 1 according to this embodiment, the light control member 4 is made of a material having higher heat resistance than the lens 3. For this reason, the light control member 4 can be disposed closer to the semiconductor light source 2 than the lens 3. In the vehicle headlamp 1 according to this embodiment, the light control member 4 is made of a material having a higher refractive index than that of the lens 3. For this reason, the light control member 4 can be made thin. Thereby, size reduction and weight reduction of the light control member 4 can be achieved. As a result, the drive member 5 that rotates the light control member 4 can be an inexpensive member with low output.

  Since the vehicle headlamp 1 according to this embodiment can reduce the size of the light control member 4, the angle between the normal of the lens surface of the variable focus lens unit 40 and the incident direction of light from the semiconductor light source 2. Is small. For this reason, even if the light control member 4 is made of a material having a high refractive index, the influence of spectroscopy due to the high refractive index is slight.

  In the vehicle headlamp 1 according to this embodiment, the light control member 4 is made of a material having weather resistance lower than that of the lens 3, and the light control member 4 is closer to the semiconductor light source 2 than the lens 3, that is, The lens 3 is disposed outside the light control member 4. For this reason, even if the light control member 4 made of a material having a weather resistance lower than that of the lens 3 turns yellow, the light control member 4 cannot be directly seen from the outside by the outer lens 3 so that the appearance is damaged. There is nothing.

In the vehicle headlamp 1 according to this embodiment, the light control member 4 is made of a material having elasticity larger than that of the lens 3. For this reason, the rotation holes 43 of the left and right attachment portions 41 of the light control member 4 can be rotatably attached to the shaft portions 72 on the left and right sides of the bearing member 7 by elastic fitting (snap fit). In addition, since the stopper 44 and the mounting portion 41 can be integrated, further downsizing and weight reduction can be achieved.

  In the vehicle headlamp 1 according to this embodiment, the variable focus lens portion 40 and the mounting portion 41 of the light control member 4 have an integral structure, so that the entire light control member 4 can be made compact and light. it can. Moreover, since at least the variable focus lens portion 40 can be used as a light transmitting member and the mounting portion 41 can be used as a non-transmitting member, light from the semiconductor-type light source 2 can leak from the mounting portion 41 other than the variable focus lens portion 40. Can be prevented.

(Description of example other than embodiment)
In this embodiment, the vehicle headlamp 1 when the vehicle C is left-hand traffic will be described. However, the present invention can also be applied to a vehicle headlamp when the vehicle C is right-hand traffic.

  In this embodiment, the main lens portion 30 and the auxiliary lens portion 31 of the lens 3 are integrated. However, in the present invention, the main lens portion 30 and the auxiliary lens portion 31 of the lens 3 may be separate.

  Furthermore, in this embodiment, the light control member 4 is rotated between the first position and the second position. However, in the present invention, the light control member 4 may be slid between the first position and the second position. In this case, a slide means is provided instead of the rotating shaft.

  Furthermore, in this embodiment, a solenoid 50 is used as the drive member 5. However, in the present invention, a member other than the solenoid 50 such as a motor may be used as the drive member 5. In this case, a driving force transmission mechanism is provided between the motor and the light control member 4.

  Furthermore, in this embodiment, the auxiliary lens portion 31 of the lens 3 is a total reflection type lens portion. However, in the present invention, the auxiliary lens portion of the lens 3 may be a lens portion other than the total reflection type lens portion, for example, a refraction type lens portion or a Fresnel type lens portion.

  Furthermore, in this embodiment, a PC is used as the light control member 4. However, in the present invention, a light control member 4 other than PC, such as a silicone resin, may be used.

  Furthermore, in this embodiment, PMMA is used as the lens 3. However, in the present invention, a lens other than PMMA may be used as the lens 3.

  Furthermore, in this embodiment, the light control member 4 and the lens 3 are made of different materials. However, in the present invention, the light control member 4 and the lens 3 may be made of the same material and having different characteristics.

DESCRIPTION OF SYMBOLS 1 Vehicle headlamp 2 Semiconductor type light source 20 Light emitting chip 21 Board | substrate 22 Connector 23 Light emitting surface 3 Lens 30 Main lens part 300 Incident surface of main lens part 301 Outgoing surface of main lens part 31 Auxiliary lens part 310 Incident of auxiliary lens part Surface 311 Reflecting surface of auxiliary lens unit 312 Output surface of auxiliary lens unit 32 Mounting unit 4 Light control member 40 Variable focus lens unit 400 Incident surface 401 Output surface 41 Mounting unit 42 Long hole 43 Rotating hole 44 Stopper 5 Driving member 50 Solenoid 51 Connecting pin 52 Spring 53 Attaching part 54 Advancing / retracting rod 6 Lens cover member 60 Opening part 61 Attaching part 7 Bearing member 70 Opening part 71 Attaching part 72 Shaft part 73 Stopper 8 Base member 80 Light source attaching part 81 Lens attaching part 82 Base attaching part 9 Cooling member C Vehicle F Lens standard focus F1 Pseudo focus HP for high beam light distribution pattern L1 center O1 center of rotation of the other part LP light distribution pattern O emitting surface for low beam of the central light L2 ambient light X X axis Y Y-axis reference optical axis Z lens (Z-axis)

Claims (6)

A semiconductor-type light source, a movable lens, and a fixed lens;
In order to position the movable lens at a predetermined position, the movable lens is provided with a stopper that comes into contact with a fixed-side stopper,
The movable lens is made of a material having a larger impact strength than the fixed lens.
A vehicle headlamp characterized by that. The movable lens is disposed closer to the semiconductor-type light source than the fixed lens,
The movable lens is made of a material having higher heat resistance than the fixed lens.
The vehicle headlamp according to claim 1. The movable lens is disposed closer to the semiconductor-type light source than the fixed lens,
The movable lens is made of a material having a higher refractive index than the fixed lens.
The vehicle headlamp according to claim 1. The movable lens is disposed closer to the semiconductor-type light source than the fixed lens,
The movable lens is made of a material having lower weather resistance than the fixed lens,
The vehicle headlamp according to claim 1. The movable lens is rotatably attached to the bearing member,
The movable lens is made of a material having greater elasticity than the fixed lens.
The vehicle headlamp according to claim 1. The movable lens includes a lens portion and an attachment portion,
The lens portion and the attachment portion have an integral structure,
At least the lens unit is composed of a light transmitting member.
The vehicular headlamp according to any one of claims 1 to 5, wherein

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