JP2017103200A - Lens body, lens combination and vehicular lighting fixture - Google Patents

Abstract

Provided is a lens body that can form a light distribution pattern with a clear cut-off line while preventing the occurrence of blur and the like in a lens body having a camber angle provided on an exit surface. An incident portion, a reflecting surface 12b, and an exit surface 12d are lens bodies 12 arranged in this order, and the exit surface 12d is a traveling direction of light L emitted from the exit surface 12d. On the other hand, the front end portion 12c of the reflecting surface 12b is inclined at a predetermined angle θx toward the direction in which the other end side recedes from the one end side in the horizontal direction across the first reference axis AX1. Has a shape adjusted in accordance with the angle θx of the inclination. Thereby, the light path of the light L can be optimized between the front end portion 12c of the reflection surface 12b and the emission surface 12d, and a light distribution pattern with a clear cut-off line can be formed while preventing the occurrence of blurring and the like. [Selection] Figure 4

Description

  The present invention relates to a lens body, a lens combination, and a vehicular lamp, and more particularly, to a lens body and a lens combination that are used in combination with a light source, and a vehicular lamp that includes these.

  Conventionally, a vehicular lamp in which a light source and a lens body are combined has been proposed (see, for example, Patent Document 1). In a vehicular lamp, light from a light source is incident on the inside of a lens body from an incident portion of the lens body, and is partially reflected by the reflecting surface of the lens body, and then from the exit surface of the lens body to the outside of the lens body. Is emitted. Thereby, the light irradiated in front of the lens body reversely projects a light source image formed in the vicinity of the focal point of the exit surface of the lens body, and includes a cut-off line defined by the front end portion of the reflecting surface at the upper edge. A low beam light distribution pattern is formed.

JP 2004-241349 A

  By the way, in the vehicle lamp described above, a slant angle (also referred to as a camber angle depending on the tilting direction) may be imparted to the exit surface of the lens body in accordance with the slant shape imparted to the corner portion on the vehicle front end side. . For example, in a lens body in which a camber angle is given to the exit surface, the exit surface is inclined at a predetermined angle toward a direction in which the outside recedes from the inside in the vehicle width direction with respect to the vehicle traveling direction.

  However, in the lens body in which the camber angle is given to the exit surface, the optical path of light changes between the front end portion of the reflection surface that defines the cut-off line and the exit surface by inclining the exit surface. The cut-off line of the light distribution pattern for low beam may not be clear and may be blurred twice.

  In addition, in a lens body with a camber angle provided on the exit surface, tilting the exit surface may cause Fresnel reflection loss and the like, and the light utilization efficiency of the light emitted from the light source may be reduced. .

  The present invention has been proposed in view of such a conventional situation, and in a lens body in which a camber angle (slant angle) is provided on the exit surface, the occurrence of blur and the like is prevented, and the cut-off line is clear. It is an object of the present invention to provide a lens body and a lens combination body that can form a light distribution pattern, and a vehicular lamp provided with these.

  In order to achieve the above object, according to a first aspect of the present invention, an incident portion, a reflection surface, and an emission surface are arranged in this order along a first reference axis extending in a horizontal direction, and light from a light source is provided. However, after being incident on the inside of the lens from the incident portion and partially reflected by the reflecting surface, light is emitted from the emitting surface to the outside of the lens, so that the light irradiated to the front of the lens is A lens body configured to reversely project a light source image formed in the vicinity of the focal point on the exit surface side to form a predetermined light distribution pattern including a cut-off line defined by the front end portion of the reflection surface at the upper edge. The exit surface has a predetermined direction toward the direction in which the other end side recedes from the one end side in the horizontal direction across the first reference axis with respect to the traveling direction of the light emitted from the exit surface. The front end of the reflecting surface is inclined at an angle A lens body characterized by having an adjusted shape according to the angle which the exit surface is inclined.

  In the first aspect of the invention, the optical path of the light changes between the front end portion of the reflecting surface and the exit surface according to the angle at which the exit surface is inclined. In accordance with this, the shape at the front end of the reflecting surface is adjusted (corrected) so as to cancel the change from when the exit surface is not inclined. As a result, a light distribution pattern with a clear cut-off line can be formed while optimizing the optical path of light between the front end portion of the reflecting surface and the exit surface and preventing the occurrence of blur and the like.

  According to a second aspect of the present invention, in the lens body according to the first aspect, the front end portion of the reflecting surface has the first reference axis with respect to the traveling direction of the light emitted from the emitting surface. It is characterized by having a shape in which one end side in the sandwiched horizontal direction is relatively retracted and the other end side is relatively advanced.

  In the second aspect of the invention, the light path between the front end portion of the reflecting surface and the exit surface is optimized by forming the front end portion of the reflecting surface in accordance with the angle at which the exit surface is inclined. Thus, it is possible to form a light distribution pattern with a clear cut-off line while preventing the occurrence of blur and the like.

  According to a third aspect of the present invention, in the lens body according to the first or second aspect, the front end portion of the reflection surface is most receded with respect to the traveling direction of the light emitted from the emission surface. The position is shifted to one end side in the horizontal direction across the first reference axis.

  In the invention according to claim 3, the light path between the front end of the reflecting surface and the exit surface is optimized by forming the front end of the reflecting surface in accordance with the angle at which the exit surface is inclined. Thus, it is possible to form a light distribution pattern with a clear cut-off line while preventing the occurrence of blur and the like.

  According to a fourth aspect of the present invention, in the lens body according to any one of the first to third aspects, the emission surface is inclined at a predetermined angle in a direction of rotation about the first reference axis. The front end of the reflecting surface is inclined in a direction opposite to the rotation direction of the emitting surface with the first reference axis as a center according to an angle at which the emitting surface is inclined. To do.

  In the invention according to claim 4, even when the emission surface is inclined at a predetermined angle in the direction of rotation about the first reference axis, the light distribution pattern is rotated in a direction corresponding to the rotation direction. It is possible to suppress.

  The invention according to claim 5 is the lens body according to any one of claims 1 to 4, wherein the focal point on the exit surface side is set in the vicinity of the front end portion of the reflection surface. To do.

  According to the fifth aspect of the present invention, the light source image formed near the focal point on the exit surface side is reversely projected to form a predetermined light distribution pattern including a cutoff line defined by the front end portion of the reflecting surface at the upper edge. can do.

  A sixth aspect of the present invention is the lens body according to any one of the first to fifth aspects, wherein the reflecting surface is inclined obliquely downward and forward with respect to the first reference axis. It is characterized by.

  In the invention according to claim 6, the use efficiency of the light reflected by the reflecting surface is increased while suppressing that a part of the light reflected by the reflecting surface becomes light (stray light) traveling in a direction not entering the emitting surface. be able to.

  The invention according to claim 7 is the lens body according to any one of claims 1 to 6, wherein the incident portion includes an incident surface on which light from the light source is incident and an incident surface incident from the incident surface. A condensing reflection surface that collects light toward the reflection surface while reflecting the light of the portion, and the condensing reflection surface is the other end in the horizontal direction across the first reference axis of the reflection surface A part of the light reflected toward the side is condensed so that the focal point is positioned at least in front of the front end portion of the reflecting surface or at a point at infinity.

  According to the seventh aspect of the present invention, the glare is generated when a part of the light reflected from the condensing reflection surface toward the other end in the horizontal direction across the first reference axis of the reflection surface is emitted from the emission surface. Can be prevented.

  The invention according to claim 8 is the lens unit according to any one of claims 1 to 7, wherein the first lens part includes the first incident surface, the reflection surface, and the first emission surface that serve as the incident part. And a second lens portion including a second incident surface and a second emitting surface serving as the emitting surface, and the first emitting surface condenses light emitted from the first emitting surface in the horizontal direction. The cylindrical axis is configured as a semi-cylindrical lens surface extending in the vertical direction, and the second emission surface is configured to condense light emitted from the second emission surface in the vertical direction. The cylindrical axis is configured as a semi-cylindrical lens surface extending in the horizontal direction.

  In the invention according to claim 8, it is possible to form a predetermined light distribution pattern condensed in the horizontal direction and the vertical direction while disassembling the condensing function between the first emission surface and the second emission surface.

  The invention according to claim 9 is the lens body according to claim 8, further comprising a connecting portion for connecting the first lens portion and the second lens portion, wherein the connecting portion is the first emission surface. The first lens unit and the second lens unit are connected in a state where a space is formed between the first lens unit and the second incident surface.

  According to the ninth aspect of the present invention, it is possible to obtain a lens body in which the first lens portion and the second lens portion are integrally molded via the connecting portion.

  A tenth aspect of the invention includes the lens body according to the eighth or ninth aspect, and in a state where a plurality of the lens bodies are arranged, each of the emission surfaces is coupled to form a line in the horizontal direction. A lens combination having a continuous emission surface extending.

  In the invention according to the tenth aspect, it is possible to provide a lens assembly having an appearance with a sense of unity extending in a line shape in the horizontal direction.

  An invention according to claim 11 is provided with the lens body according to any one of claims 1 to 9 and a light source that emits light toward the incident portion of the lens body. Lamp.

  According to the eleventh aspect of the present invention, it is possible to provide a vehicular lamp including a lens body that can form a light distribution pattern with a clear cut-off line while preventing occurrence of blur and the like.

  A twelfth aspect of the present invention is directed to a plurality of light sources that irradiate light toward each of the incident portions with respect to the lens combination body according to the tenth aspect and a plurality of lens bodies constituting the lens combination body. And a vehicular lamp.

  According to the invention described in claim 12, it is possible to provide a vehicular lamp provided with a lens assembly having a great unity extending in a line shape in the horizontal direction.

  As described above, according to the present invention, in a lens body in which a camber angle (slant angle) is provided on the exit surface, a lens body capable of forming a light distribution pattern with a clear cut-off line while preventing occurrence of blur and the like, and It is possible to provide a lens combination body and a vehicular lamp including these.

It is sectional drawing which shows schematic structure of the vehicle lamp provided with the lens body which concerns on the 1st Embodiment of this invention. It is a schematic diagram for demonstrating the shape of the front-end part of the reflective surface in the lens body shown in FIG. It is a luminous intensity distribution diagram which shows the light distribution pattern formed on the surface of the virtual vertical screen by LB light. It is a top view for demonstrating the difference in the shape of the front-end part of the reflective surface adjusted according to the camber angle, and the front-end part of the reflective surface before adjustment. It is a top view which shows the shape of the front-end part of a reflective surface when receding angle (theta) x is 0 degree, 10 degrees 20 degrees, 30 degrees, and 40 degrees. It is an XY coordinate diagram showing the position where the front end of the reflecting surface is most retracted when the receding angle θx is 0 °, 10 ° 20 °, 30 °, and 40 °. It is a luminous intensity distribution diagram showing a light distribution pattern formed on the surface of the virtual vertical screen when the receding angle θx is 0 °. It is a luminous intensity distribution diagram showing a light distribution pattern formed on the surface of the virtual vertical screen when the receding angle θx is 10 °. It is a luminous intensity distribution diagram showing a light distribution pattern formed on the surface of the virtual vertical screen when the receding angle θx is 20 °. It is a luminous intensity distribution diagram showing a light distribution pattern formed on the surface of the virtual vertical screen when the receding angle θx is 30 °. It is a luminous intensity distribution diagram showing a light distribution pattern formed on the surface of the virtual vertical screen when the receding angle θx is 40 °. It is a front view which shows the rotation direction of the output surface to which the angle of fishery angle was provided, and the front-end part of a reflective surface. It is a top view which shows schematic structure of the vehicle lamp provided with the lens body which concerns on the 2nd Embodiment of this invention. It is a top view which shows the structure of the 1st incident part of the lens body shown in FIG. It is a top view which shows the optical path of the light reflected by the condensing reflective surface before adjustment. FIG. 16 is a luminous intensity distribution diagram showing a light distribution pattern formed on the surface of the virtual vertical screen before adjustment shown in FIG. 15. It is a top view which shows the optical path of the light reflected by the condensing reflective surface after adjustment. FIG. 18 is a luminous intensity distribution diagram showing a light distribution pattern formed on the surface of the adjusted virtual vertical screen shown in FIG. 17. It is a top view which shows schematic structure of the vehicle lamp provided with the lens coupling body which concerns on the 3rd Embodiment of this invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
In the drawings used in the following description, in order to make each component easy to see, the scales of the dimensions may be different depending on the component, and the dimensional ratio of each component is not always the same as the actual. Absent.

(First embodiment)
First, a vehicular lamp 10 including a lens body 12 shown in FIG. 1 will be described as a first embodiment of the present invention. FIG. 1 is a cross-sectional view showing a schematic configuration of the vehicular lamp 10. In FIG. 1, the optical path of the light L incident on the lens body 12 from the light source 14 of the vehicular lamp 10 is indicated by a broken line. In the drawings shown below, an XYZ orthogonal coordinate system is set, the X-axis direction is the front-rear direction of the vehicle lamp 10 (lens body 12), the Y-axis direction is the left-right direction of the vehicle lamp 10 (lens body 12), The Z-axis direction is shown as the vertical direction of the vehicular lamp 10 (lens body 12).

  As shown in FIG. 1, the vehicular lamp 10 includes a lens body 12 to which the present invention is applied, and a light source 14 that emits light L toward an incident surface 12 a that is an incident portion of the lens body 12.

  The lens body 12 is a polyhedral lens body having a shape extending along the first reference axis AX1 extending in the horizontal direction (X-axis direction). Specifically, the lens body 12 has an incident surface 12a, a reflecting surface 12b, a front end portion 12c of the reflecting surface 12b, and an emitting surface 12d in this order along the first reference axis AX1 extending in the horizontal direction. It has the structure arranged by. The lens body 12 may be made of a material having a refractive index higher than that of air, such as a transparent resin such as polycarbonate or acrylic, or glass. When a transparent resin is used for the lens body 12, the lens body 12 can be formed by injection molding using a mold.

  The incident surface 12a is positioned at the rear end portion (rear surface) of the lens body 12, and the light L from the light source 14 (precisely, the reference point F in optical design) disposed near the incident surface 12a is refracted. Thus, a lens surface that enters the inside of the lens body 12 (for example, a free curved surface that is convex toward the light source 14) is formed.

The incident surface 12a is at least in the vertical direction (Z-axis direction), and the light L from the light source 14 disposed in the vicinity of the incident surface 12a is near the center (reference point F) of the light source 14 and the front end portion 12c of the reflecting surface 12b. passes through the point (focal point F _12d of the exit surface 12d _side), and, as focused on the second reference axis AX2 towards inclined forwardly obliquely downward with respect to the first reference axis AX1, the surface The shape has been adjusted.

  In addition, in the horizontal direction (Y-axis direction), the incident surface 12a collects the light L from the light source 14 incident on the inside of the lens body 12 toward the first reference axis AX1 toward the front end portion 12c of the reflective surface 12b. The surface shape is configured to shine. The incident surface 12a has a surface shape with respect to the horizontal direction (Y-axis direction) so that light from the light source 14 incident on the inside of the lens body 12 becomes light parallel to the first reference axis AX1. May be configured. Further, the incident portion is not limited to such an incident surface 12a, but may be configured such that an incident concave portion is provided on the rear end side of the lens body 12, and the light source 14 is disposed inside the incident concave portion.

  The reflecting surface 12b has a planar shape extending from the lower end edge of the incident surface 12a toward the front (+ X axis direction). Of the light L from the light source 14 incident on the inside of the lens body 12, the reflecting surface 12b reflects the light L1 incident on the reflecting surface 12b toward the front exit surface 12d inside the lens body 12 (total reflection). reflect. Thereby, in the lens body 12, since the reflective surface 12b can be formed, without using the metal reflective film by metal vapor deposition, it is possible to prevent a cost increase, a fall of a reflectance, etc.

  Further, the reflecting surface 12b is inclined forward and obliquely downward with respect to the first reference axis AX1. In this case, it is possible to improve the utilization efficiency of the light reflected by the reflecting surface 12b while suppressing that part of the light L1 reflected by the reflecting surface 12b becomes light (stray light) traveling in a direction not incident on the emitting surface 12d. it can.

  The front end portion 12c of the reflection surface 12b defines a cut-off line for the light L that has entered the lens body 12 from the light source 14.

  Here, the shape of the front end portion 12c of the reflection surface 12b will be described with reference to FIGS. 2A is a schematic diagram showing a front view shape (a shape when viewed from the incident surface 12a side (+ X axis direction)) of the front end portion 12c of the reflection surface 12b. 2B to 2D are schematic views showing examples of the shape of the front end portion 12c of the reflecting surface 12b viewed from the side (the shape when viewed from the side surface (+ Y-axis direction)).

  As shown in FIGS. 1 and 2A, the front end portion 12c of the reflecting surface 12b is formed to extend in the left-right direction (Y-axis direction) of the lens body 12 at the tip portion of the reflecting surface 12b. Specifically, the front end portion 12c of the reflecting surface 12b includes a side e1 corresponding to the left horizontal cutoff line, a side e2 corresponding to the right horizontal cutoff line, and a space between the left horizontal cutoff line and the right horizontal cutoff line. It has a step shape including a side e3 corresponding to the oblique cut-off line to be connected.

  The shape of the front end portion 12c of the reflecting surface 12b shown in FIG. 2A exemplifies a case where the vehicle is on the right side. On the other hand, when the vehicle is on the left side, the shape of the front end portion 12c of the reflecting surface 12b is a stepped shape in which the heights of the side e1 corresponding to the left horizontal cutoff line and the side e2 corresponding to the right horizontal cutoff line are reversed. . Further, the shape of the front end portion 12c of the reflecting surface 12b is not limited to these shapes, and may be a shape including only a side corresponding to a horizontal cut-off line extending linearly in the horizontal direction.

  As shown in FIG. 2B, the side view shape of the front end portion 12c of the reflection surface 12b has a shape extending linearly from the front end portion of the reflection surface 12b upward (+ Z-axis direction). . Further, the side view shape of the front end portion 12c of the reflection surface 12b may be a shape extending linearly toward the front obliquely upward as shown in FIG. 2C, as shown in FIG. Thus, the shape may be curved and extended toward the upper front obliquely.

  In addition, about the front-end part 12c of the reflective surface 12b, it is not necessarily limited to the shape mentioned above, It is possible to add a change suitably in the range which can prescribe | regulate a cut-off line. Further, the front end portion 12c of the reflecting surface 12b is not limited to the step shape described above, and can be formed by a groove portion corresponding to a cut-off line.

As shown in FIG. 1, the exit surface 12 d is located at the front end (front surface) of the lens body 12, and proceeds toward the exit surface 12 d out of the light L from the light source 14 that has entered the lens body 12. Light (hereinafter referred to as straight light) L2 and light (hereinafter referred to as reflected light) L1 that is reflected by the reflection surface 12b and then travels toward the emission surface 12d is emitted to the outside of the lens body 12. A lens surface (for example, a free curved surface convex forward) is formed. The focal _{F 12d} of the exit surface 12d side is set to the front end portion 12c vicinity of the reflecting surface 12b (e.g., near the center in the lateral direction of the front end portion 12c of the reflecting surface 12b (Y axis direction)).

  Of the surfaces constituting the lens body 12, a surface (upper surface) 12f that connects the upper end edge of the incident surface 12a and the upper end edge of the exit surface 12d, and the tip of the reflecting surface 12b (the front end of the reflecting surface 12b) 12c) and the surface (lower surface) 12g that connects the lower end edge of the exit surface 12d are not specifically described, but the upper surface 12f and the lower surface 12g have an adverse effect on the light L passing through the inside of the lens body 12 ( For example, it is possible to design freely within a range that does not provide shielding.

  As the light source 14, for example, a semiconductor light emitting element such as a white light emitting diode (LED) or a white laser diode (LD) can be used. In the present embodiment, one white LED is used. The type of the light source 14 is not particularly limited, and a light source other than the semiconductor light emitting element described above may be used. Further, the number of light sources 14 is not limited to one and may be plural.

  The light source 14 is in the vicinity of the incident surface 12a of the lens body 12 (at the reference point F) in a state where the light emitting surface is directed obliquely downward and forward, that is, in a state where the optical axis of the light source 14 coincides with the second reference axis AX2. In the vicinity). The light source 14 is a lens body in a state where the optical axis of the light source 14 does not coincide with the second reference axis AX2 (for example, the optical axis of the light source 14 is arranged in parallel to the first reference axis AX1). It may be arranged in the vicinity of the 12 incident surfaces 12a (in the vicinity of the reference point F).

  In the vehicle lamp 10 of the present embodiment, the reflected light that travels toward the exit surface 12d after being reflected by the reflecting surface 12b out of the light L from the light source 14 that has entered the lens body 12 from the entrance surface 12a. L1 and the straight light L2 traveling toward the exit surface 12d are emitted from the exit surface 12d to the outside of the lens body 12.

As a result, the light irradiated in front of the lens body 12 (hereinafter referred to as low beam (LB) light L _LOW ) reversely projects a light source image formed near the focal point F _12d on the exit surface 12d side, and A predetermined low beam (LB) light distribution pattern including a cut-off line defined by the front end portion 12c of the reflecting surface 12b is formed at the edge.

Here, FIG. 3 shows a light source image when the LB light L _LOW is projected on the virtual vertical screen facing the lens body 12 by simulation. FIG. 3 is a luminous intensity distribution diagram showing the LB light distribution pattern P _LOW formed on the surface of the virtual vertical screen. Further, the virtual vertical screen is disposed approximately 25 m ahead from the exit surface 12 d of the lens body 12.

The light source image by the LB light L _LOW includes the cut-off lines CL1 to CL3 corresponding to the sides e1 to e3 of the front end portion 12c of the reflecting surface 12b on the upper end edge on the surface of the virtual vertical screen shown in FIG. A light distribution pattern P _LOW is formed.

The degree of diffusion in the horizontal direction (Y-axis direction) of the LB light distribution pattern P _LOW is adjusted by adjusting the surface shape of the incident surface 12a (for example, the curvature of the incident surface 12a in the horizontal direction (Y-axis direction)). Can be adjusted freely. Further, the degree of diffusion of the LB light distribution pattern _{PLOW in} the horizontal direction (Y-axis direction) and the vertical direction (Z-axis direction) can be freely adjusted by adjusting the surface shape of the emission surface 12d. is there.

  By the way, the vehicular lamp 10 according to the present embodiment is a vehicular headlamp disposed at both corner portions on the front end side of the vehicle (the left corner portion is illustrated in this example). A camber angle is given to the exit surface 12d of the lens body 12 in accordance with the slant shape given to the part. On the other hand, the front end 12c of the reflecting surface 12b has a shape adjusted according to the camber angle.

  Here, the shape of the exit surface 12d provided with the camber angle and the front end portion 12c of the reflection surface 12b will be described with reference to FIG. FIG. 4 is a top view showing the difference in shape between the front end portion 12c of the reflection surface 12b adjusted according to the camber angle and the front end portion 12c of the reflection surface 12b before adjustment.

  As shown in FIG. 4, the exit surface 12d to which the camber angle is given is in a horizontal direction with the first reference axis AX1 sandwiched with respect to the traveling direction of light emitted from the exit surface 12d (+ X axis direction) ( Inclined at a predetermined angle (hereinafter referred to as a receding angle) θx toward a direction (−X axis direction) in which the other end (+ Y axis) side recedes from one end (−Y axis) side of the Y axis direction). . The traveling direction of the light emitted from the exit surface 12d corresponds to the traveling direction of the vehicle, the one end side in the horizontal direction across the first reference axis AX1 corresponds to the inside in the vehicle width direction, and the first reference axis The other end in the horizontal direction across AX1 corresponds to the outside in the vehicle width direction.

  The front end portion 12c of the reflection surface 12b before adjustment has its most receding position B ′ on the first reference axis AX1 with respect to the traveling direction (+ X axis direction) of the light L emitted from the emission surface 12d. In addition, one end (−Y axis) side and the other end (+ X axis) side in the horizontal direction (Y axis direction) sandwiching the first reference axis AX1 have a shape C ′ that is symmetrically curved.

  On the other hand, in the lens body 12 of the present embodiment, the optical path of the light L changes between the front end portion 12c of the reflecting surface 12b and the emitting surface 12d depending on the angle (retraction angle) θx at which the emitting surface 12d is inclined. . In accordance with this, the shape of the front end portion 12c of the reflecting surface 12b is adjusted (corrected) so as to cancel the change from when the emission surface 12d is not inclined (before adjustment).

  Specifically, the front end portion 12c of the reflecting surface 12b has a horizontal position where the most receded position B sandwiches the first reference axis AX1 with respect to the traveling direction (+ X axis direction) of the light L emitted from the emitting surface 12d. It has an asymmetrical shape C shifted toward one end (−Y axis) in the direction (Y axis direction). Further, the front end portion 12c of the reflecting surface 12b has one end in the horizontal direction (Y-axis direction) sandwiching the first reference axis AX1 with respect to the traveling direction (+ X-axis direction) of the light L emitted from the emitting surface 12d ( It has a shape C that is curved so that the (−Y axis) side is relatively retracted before adjustment and the other end (+ Y axis) side is relatively advanced than before adjustment.

As described above, in the vehicular lamp 10 according to the present embodiment, in the lens body 12 in which the camber angle is given to the exit surface 12d, the reflecting surface 12b depends on the angle (retraction angle) θx that the exit surface 12d is inclined. The shape C of the front end 12c is adjusted. Thereby, the optical path of the light L is optimized between the front end portion 12c of the reflection surface 12b and the emission surface 12d, and the LB light distribution pattern P _LOW with a clear cutoff line is formed while preventing the occurrence of blurring and the like. Is possible.

In addition, the camber angle (receding angle θx) given to the emission surface 12d is preferably in the range of 0 ° <θx ≦ 40 °. Here, the shape C (C ′) of the front end portion 12c of the reflecting surface 12b when the angle (retraction angle) θx at which the exit surface 12d is inclined is 0 °, 10 °, 20 °, 30 °, and 40 °. The line is shown in FIG. FIG. 6 shows the XY coordinates of the position B (B ′) where the front end portion 12c of the reflecting surface 12b is most retracted when the receding angle θx is 0 °, 10 ° 20 °, 30 °, and 40 °. Show. 7 to 11 show the LB light distribution pattern P _LOW formed on the surface of the virtual vertical screen when the receding angle θx is 0 °, 10 ° 20 °, 30 °, and 40 °.

  In FIG. 5, when the receding angle θx is 0 °, the shape C ′ of the front end portion 12c of the reflecting surface 12b before adjustment is shown. In FIG. 6, when the receding angle θx is 0 °, the most receding position B ′ of the front end portion 12c of the reflecting surface 12b before adjustment is defined as the origin (0, 0) of the XY coordinates.

  As shown in FIGS. 5 and 6, it can be seen that the position B shifts from the origin in the −X axis direction and the −Y axis direction as the receding angle θx increases. Further, as the receding angle θx increases, the receding amount in the line on one end (−Y axis) side in the horizontal direction (Y axis direction) sandwiching the first reference axis AX1 of the shape C, and the other end (+ X axis) side It can be seen that the amount of advance in the line increases together.

As shown in FIG. 7, the light distribution pattern P _LOW for LB when the receding angle θx is 0 ° is doubled in the vertical direction on the surface of the virtual vertical screen without making the left cutoff line clear. I'm out of focus.

On the other hand, the LB light distribution pattern P _LOW when the receding angle θx is 10 °, 20 °, 30 °, and 40 ° is clear on the surface of the virtual vertical screen as shown in FIGS. It can be seen that a simple cut-off line is formed.

When the receding angle θx exceeds 40 °, the boundary of the LB light distribution pattern P _LOW is shifted to the left side from 30 ° on the right side. In this case, the overlapping range of the LB light L _LOW from the vehicle headlamp on the left side of the vehicle and the LB light L _LOW from the vehicle headlamp on the right side of the vehicle is far from the front of the vehicle, and is out of the practical range. This is not preferable.

  Further, as shown in FIG. 12, the lens body 12 of the present embodiment is configured such that the emission surface 12d is inclined at a predetermined angle (fish angle) θz in the direction of rotation about the first reference axis AX1. It is good. FIG. 12 is a front view showing the rotation direction of the emission surface 12d to which the fish angle θz is given and the front end portion 12c of the reflection surface 12b.

In this case, in accordance with the angle (fish angle) θz at which the emission surface 12d is inclined, a predetermined direction (− direction) opposite to the rotation direction (+ direction) of the emission surface 12d is centered on the first reference axis AX1. The front end portion 12c of the reflecting surface 12b is inclined at an angle −θz. Thereby, even when the emission surface 12d is inclined at a predetermined angle (fishing angle) θz, it is possible to suppress the rotation of the LB light distribution pattern P _{LOW in} the direction corresponding to the rotation direction. is there.

  The angle θz at which the exit surface 12d is inclined and the angle −θz at which the front end portion 12c of the reflecting surface 12b is inclined do not necessarily coincide with each other. For example, in this embodiment, θz is 5 When θ, -θz is about -7.5 °.

(Second Embodiment)
Next, a vehicular lamp 10A including the lens body 12A shown in FIG. 13 will be described as a second embodiment of the present invention. FIG. 13 is a top view showing a schematic configuration of the vehicular lamp 10A. Moreover, in the following description, about the site | part equivalent to the said vehicle lamp 10 (lens body 12), while omitting description, the same code | symbol shall be attached | subjected in drawing.

  As shown in FIG. 13, the vehicular lamp 10 </ b> A includes a lens body 12 </ b> A to which the present invention is applied and a light source 14 that emits light toward the first incident portion 13 of the lens body 12 </ b> A. In other words, the vehicular lamp 10A has a lens body 12A instead of the lens body 12 included in the vehicular lamp 10.

  The lens body 12A includes a first lens portion 12A1 including a first incident portion 13, a reflecting surface 12b, and a first exit surface 12A1a, and a second lens portion 12A2 including a second entrance surface 12A2a and a second exit surface 12A2b. doing. The first lens portion 12A1 and the second lens portion 12A2 are connected between the first exit surface 12A1a and the second entrance surface 12A2a by the connecting portion 12A3.

  The lens body 12A is a polyhedral lens body having a shape extending along the first reference axis AX1 extending in the horizontal direction (X-axis direction). Specifically, the lens body 12 includes a first incident portion 13, a reflecting surface 12b, a first emitting surface 12A1a, a second incident surface 12A2a, and a first axis AX1 extending in the horizontal direction. The two exit surfaces 12A2b are arranged in this order. The first exit surface 12A1a and the second entrance surface 12A2a are opposed to each other across the space S surrounded by the first lens portion 12A1, the second lens portion 12A2, and the connecting portion 12A3.

  Among the surfaces constituting the lens body 12A, the first incident portion 13, the reflection surface 12b, and the front end portion 12c of the reflection surface 12b are formed on the incident surface 12a, the reflection surface 12b, and the front end portion 12c of the reflection surface 12b. It is a corresponding surface. On the other hand, among the surfaces constituting the lens body 12 </ b> A, the first exit surface 12 </ b> A <b> 1 a and the second entrance surface 12 </ b> A <b> 2 a constitute surfaces different from the lens body 12.

  Among these, the 1st incident part 13 is located in the rear-end (rear surface) side of 1st lens part 12 A1, and the light source 14 arrange | positioned in the vicinity of this 1st incident part 13 (to be exact, the reference | standard on optical design) An incident surface that refracts the light L from the point F) and enters the inside of the first lens unit 13 is configured. Specifically, the first incident portion 13 has a configuration as shown in FIG. 14, for example. FIG. 14 is a plan view showing the configuration of the first incident portion 13.

  As shown in FIG. 14, the first incident portion 13 has a first condensing incident surface 13a, a second condensing incident surface 13b, and a condensing reflection surface 13c at a position facing the light source 14. Yes. The 1st condensing entrance surface 13a is comprised by the free-form surface (aspherical surface) which becomes convex toward the back from the center part. The 2nd condensing incident surface 13b is comprised by the substantially cylindrical internal peripheral surface of the part which protruded back from the position surrounding the circumference | surroundings of the 1st incident part 13. As shown in FIG. The condensing reflection surface 13 c is configured by a substantially frustoconical outer peripheral surface of a portion protruding rearward from a position surrounding the first incident portion 13.

  In the 1st incident part 13, the light L11 incident from the 1st condensing incident surface 13a among the light L radiate | emitted from the light source 14 is condensed toward the reflective surface 12b. On the other hand, the light L12 incident from the second condensing incident surface 13b is reflected (totally reflected) by the condensing / reflecting surface 13c to be condensed toward the reflecting surface 12b.

  As a result, the first incident portion 13 is parallel to the first reference axis AX1 in the horizontal section (Y-axis section) in which the light L incident from the first incident section 13 into the first lens section 12A1. It is configured to be light.

  Note that the first incident portion 13 collects the light L incident from the first incident portion 13 into the first lens portion 12A1 toward the first reference axis AX1 in the horizontal section (Y-axis section). It may be configured.

On the other hand, the first incident portion 13 reflects the light L incident on the inside of the first lens portion 12A1 from the first incident portion 11 and the center (reference point F) of the light source 14 in the vertical section (Z-axis section). through a front end portion 12c near the point of the surface 12b (the combined focal _{F 12A4} below synthesizing lens 12A4), and the second reference axis AX2 towards inclined forwardly obliquely downward with respect to the first reference axis AX1 It is comprised so that it may concentrate on.

  As shown in FIG. 13, the first emission surface 12A1a is located at the front end (front surface) of the first lens unit 12A1, and the first emission surface 12A1a is related to the horizontal direction (Y-axis direction) that is the first direction. The surface shape is adjusted so as to collect the light emitted from the surface. Specifically, the first emission surface 12A1a is configured as a semi-cylindrical lens surface whose cylindrical axis extends in the vertical direction (Z-axis direction). Further, the focal line of the first emission surface 12A1a extends in the vertical direction (Z-axis direction) in the vicinity of the front end portion 12c of the reflection surface 12b.

  The second incident surface 12A2a is positioned at the rear end (rear surface) of the second lens portion 12A2, and forms a plane as a surface on which light emitted from the first emission surface 12A1a is incident. Note that the shape of the second incident surface 12A2a is not limited to such a flat surface, but may be a curved surface (lens surface).

  The second emission surface 12A2b is a surface corresponding to the emission surface 12d of the lens body 12, and is located at the front end (front surface) of the second lens portion 12A2, and is a vertical direction (Z-axis direction) serving as the second direction. The surface shape is adjusted so as to collect the light emitted from the second emission surface 12A2b. Specifically, the second emission surface 12A2a is configured as a semi-cylindrical lens surface whose cylindrical axis extends in the horizontal direction (Y-axis direction). Further, the focal line of the second emission surface 12A2b extends in the horizontal direction (Y-axis direction) in the vicinity of the front end portion 12c of the reflection surface 12b.

Further, it corresponds to the synthetic focus F _12A4 (the focal point F _12d on the emission surface 12d side) of the synthetic lens 12A4 composed of the first emission surface 12A1a and the second lens portion 12A2 (second incidence surface 12A2a and second emission surface 12A2b). ) Is set near the front end 12c of the reflecting surface 12b (for example, near the center in the left-right direction of the front end 12c of the reflecting surface 12b).

  The connecting part 12A3 connects the upper part between the first lens part 12A1 and the second lens part 12A2 with the space S therebetween. The lens body 12A can be formed by injection molding using a mold using the same material as the lens body 12.

  By the way, the vehicular lamp 10A according to the present embodiment has a camber angle provided to the second emission surface 12A2b of the lens body 12A, similarly to the vehicular lamp 10 described above. On the other hand, the front end 12c of the reflecting surface 12b has a shape adjusted according to the camber angle.

  That is, in the lens body 12A of the present embodiment, similarly to the lens body 12 shown in FIG. 4 described above, the front end portion 12c of the reflecting surface 12b and the second emission surface depend on the angle (retraction angle) θx of the second emission surface 12A2b. The optical path of light changes between the surface 12A2b. In accordance with this, the shape of the front end portion 12c of the reflection surface 12b is adjusted (corrected) so as to cancel the change from when the second emission surface 12A2b is not inclined (before adjustment).

  Specifically, the front end portion 12c of the reflection surface 12b is located at the most receded position B with respect to the traveling direction (+ X axis direction) of the light emitted from the second emission surface 12A2b with the first reference axis AX1 interposed therebetween. It has an asymmetric shape C shifted to one end (+ Y axis) in the horizontal direction (Y axis direction). The front end 12c of the reflecting surface 12b is one end in the horizontal direction (Y-axis direction) sandwiching the first reference axis AX1 with respect to the traveling direction (+ X-axis direction) of the light emitted from the second emission surface 12A2b. It has a shape C that is curved so that the (+ Y axis) side is relatively retracted before adjustment and the other end (−Y axis) side is relatively advanced than before adjustment.

  As described above, in the vehicular lamp 10A of the present embodiment, in the lens body 12A in which the camber angle is given to the second emission surface 12A2b, the second emission surface 12A2b is inclined according to the angle (retraction angle) θx. The shape C of the front end portion 12c of the reflecting surface 12b is adjusted. Thereby, an optical path of light is optimized between the front end portion 12c of the reflection surface 12b and the second emission surface 12A2b, and an LB light distribution pattern with a clear cutoff line can be formed while preventing occurrence of blurring and the like. Is possible.

  Further, in the lens body 12A of the present embodiment, similarly to the lens body 12 shown in FIG. 12, the second emission surface 12A2b is a predetermined angle (fishing angle) in the direction of rotation about the first reference axis AX1. It may be configured to be inclined at θz.

  In this case, the direction (− direction) opposite to the rotation direction (+ direction) of the second emission surface 12A2b around the first reference axis AX1 according to the angle (fishing angle) θz at which the second emission surface 12A2b is inclined. The front end 12c of the reflecting surface 12b is inclined. Accordingly, even when the second emission surface 12A2b is inclined at a predetermined angle (fishing angle) θz, it is possible to suppress the LB light distribution pattern from rotating in a direction corresponding to the rotation direction. is there.

By the way, in the said lens body 10A, the optical path of the light L12 reflected by the condensing reflective surface 13c before adjustment is shown in FIG. FIG. 16 shows the LB light distribution pattern P _LOW formed on the virtual vertical screen at this time.

  As shown in FIG. 15, the front end portion 12c of the reflecting surface 12b has an asymmetric shape C that is curved so that the other end (+ Y axis) side advances from the one end (−Y axis) side described above. In this case, of the light L12 reflected by the condensing reflection surface 13c before adjustment, a part of the light L12 collected toward the other end (+ Y axis) side of the front end portion 12c (−Y in FIG. 15). The light beam Lx) shown on the axis side may become stray light, and may be emitted from the second emission surface 12A2b after being reflected by the front end portion 12c of the reflection surface 12b.

In this case, as in the LB light distribution pattern P _LOW shown in FIG. 16, glare P _Lx may be generated above the cut-off line by this light ray Lx.

On the other hand, the optical path of the light L12 reflected by the adjusted condensing reflection surface 13c in the lens body 10A is shown in FIG. FIG. 18 shows the LB light distribution pattern P _LOW formed on the virtual vertical screen at this time.

  As shown in FIG. 17, in the adjusted condensing reflection surface 13c after the adjustment, the light L12 reflected by the condensing reflection surface 13c is condensed toward the other end (+ Y axis) side of the front end portion 12c. A part of the light L12 is condensed so that the focal point is located at least in front of the front end portion 12c of the reflecting surface 12b or at a point at infinity.

  That is, in the 1st incident part 13, the light L12 condensed toward the other end (+ Y-axis) side of the front end part 12c from the condensing reflection surface 13c is focused in front of the front end part 12c of the reflection surface 12b. It is preferable to adjust the surface of the condensing / reflecting surface 13c so that the light is connected or parallel light.

Thereby, like the LB light distribution pattern P _LOW shown in FIG. 18, the light L12 reflected by the condensing reflection surface 13c is condensed toward the other end (+ Y axis) side of the front end portion 12c. It can be prevented that part of the light L12 becomes stray light and causes the above-described glare.

(Third embodiment)
Next, a vehicular lamp 20A including the lens combination 22A shown in FIG. 14 will be described as a third embodiment of the present invention. FIG. 14 is a top view showing a schematic configuration of the vehicular lamp 20A. Moreover, in the following description, about the site | part equivalent to the said vehicle lamp 10A (lens body 12A), while omitting description, the same code | symbol shall be attached | subjected in drawing.

  As shown in FIG. 14, the vehicular lamp 20A is directed toward each first incident surface 12a with respect to the lens combination 22A to which the present invention is applied and the plurality of lens bodies 12A constituting the lens combination 22A. And a plurality of light sources 14 for emitting light.

  That is, the vehicular lamp 20A has a configuration in which a plurality of vehicular lamps 10A (a plurality of lens bodies 12A) are arranged in a line in the horizontal direction (Y-axis direction). The lens combination 22A has a continuous emission surface 12A2B extending in a line shape in the horizontal direction (Y-axis direction) by combining the second emission surfaces 12A2b in a state where a plurality of the lens bodies 12A are arranged. ing.

  In the vehicular lamp 20A of the present embodiment, it is possible to improve the design by providing such a lens combined body 22A having a sense of unity extending in a line shape in the horizontal direction.

  The lens combined body 22A is not limited to the one in which the plurality of lens bodies 12A are integrally molded, and after the plurality of lens bodies 12A are molded separately, these are held by a holding member such as a lens holder. It is also possible to have an integral configuration.

  As described above, in the vehicular lamp 20A of the present embodiment, in the lens combined body 22A in which the camber angle is given to the continuous emission surface 12A2B (second emission surface 12A2b), the continuous emission surface 12A2B (second emission surface 12A2b). The shape C of the front end portion 12c of the reflection surface 12b included in each lens body 12A is adjusted in accordance with the angle (retraction angle) θx at which the angle. Thereby, in each lens body 12A, the light path between the front end portion 12c of the reflecting surface 12b and the second emitting surface 12A2b is optimized, and the LB light distribution with a clear cut-off line is prevented while preventing blurring and the like. A pattern can be formed.

  Further, in the lens body 22A of the present embodiment, the continuous emission surface 12A2B (second emission surface 12A2b) has a predetermined direction in the direction of rotation about the first reference axis AX1, similarly to the lens body 12 shown in FIG. It is good also as a structure which inclines at angle (fish angle) (theta) z.

  In this case, the rotation direction of the continuous emission surface 12A2B (second emission surface 12A2b) about the first reference axis AX1 according to the angle (fish angle) θz at which the continuous emission surface 12A2B (second emission surface 12A2b) is inclined. The front end portion 12c of the reflecting surface 12b included in each lens body 12A is inclined in a direction (− direction) opposite to the (+ direction). Thus, even when the continuous emission surface 12A2B (second emission surface 12A2b) is inclined at a predetermined angle (fishing angle) θz, the LB light distribution pattern is rotated in a direction corresponding to the rotation direction. It is possible to suppress.

DESCRIPTION OF SYMBOLS 10,10A ... Vehicle lamp 12, 12A ... Lens body 12a ... (1st) Incident surface (incident part) 12b ... Reflective surface 12c ... Front end part of reflective surface 12d ... Outgoing surface 12A1 ... First lens part 12A2 ... Second Lens part 12A3 ... Connecting part 12A4 ... Synthetic lens 12A1a ... First exit surface 12A2a ... Second entrance surface 12A2b ... Second exit surface 12A2B ... Continuous exit surface 14 ... Light source 20A ... Vehicle lamp 22A ... Lens combined body AX1 ... First Reference axis F _12d ... Focus F _12A4 ... Composite focus L ... Light L _LOW ... Low beam (LB) light P _LOW ... Light distribution pattern for low beam (LB) θx ... Retraction angle (camber angle) θz ... Fishing angle

Claims (12)

An incident portion, a reflecting surface, and an exit surface are arranged in this order along a first reference axis extending in the horizontal direction, and light from a light source enters the lens from the incident portion, and the reflecting surface. After a part of the light is reflected by the light, light is emitted from the exit surface to the outside of the lens, so that the light irradiated in front of the lens reversely projects a light source image formed near the focal point on the exit surface side. A lens body configured to form a predetermined light distribution pattern including a cut-off line defined by a front end portion of the reflecting surface at an upper end edge,
The emission surface is inclined at a predetermined angle with respect to a traveling direction of light emitted from the emission surface toward a direction in which the other end side recedes from one end side in the horizontal direction across the first reference axis. And
The lens body, wherein the front end portion of the reflecting surface has a shape adjusted according to an angle at which the exit surface is inclined.   The front end portion of the reflecting surface is relatively retracted at one end side in the horizontal direction across the first reference axis and relatively advanced at the other end side with respect to the traveling direction of the light emitted from the emitting surface. The lens body according to claim 1, wherein the lens body has a shape.   The front end portion of the reflecting surface has a shape in which the most receded position with respect to the traveling direction of the light emitted from the emitting surface is shifted to one end in the horizontal direction across the first reference axis. The lens body according to claim 1 or 2, characterized in that: The exit surface is inclined at a predetermined angle in a direction of rotation about the first reference axis;
The front end portion of the reflection surface has a shape inclined in a direction opposite to a rotation direction of the emission surface about the first reference axis according to an angle at which the emission surface is inclined. The lens body as described in any one of 1-3.   5. The lens body according to claim 1, wherein the focal point on the emission surface side is set in the vicinity of a front end portion of the reflection surface.   6. The lens body according to claim 1, wherein the reflecting surface is inclined obliquely downward and forward with respect to the first reference axis. The incident portion includes an incident surface on which light from the light source is incident, and a condensing reflection surface that collects light toward the reflecting surface while reflecting a portion of the light incident from the incident surface,
The condensing reflection surface is configured such that a part of light reflected toward the other end side in the horizontal direction across the first reference axis of the reflection surface has a focal point at least in front of the front end portion of the reflection surface. Or it concentrates so that it may be located in an infinite point, The lens body as described in any one of Claims 1-6 characterized by the above-mentioned. A first lens unit including a first incident surface serving as the incident unit, the reflection surface, and a first emission surface;
A second lens portion including a second incident surface and a second emitting surface to be the emitting surface;
The first emission surface is configured as a semi-cylindrical lens surface whose cylinder axis extends in the vertical direction so as to collect light emitted from the first emission surface in the horizontal direction,
The second emission surface is configured as a semi-cylindrical lens surface whose cylinder axis extends in the horizontal direction so as to collect light emitted from the second emission surface in the vertical direction. The lens body according to any one of claims 1 to 7. A connecting portion that connects the first lens portion and the second lens portion;
The connecting portion connects the first lens portion and the second lens portion in a state where a space is formed between the first exit surface and the second entrance surface. The lens body according to claim 8. A lens body according to claim 8 or 9,
A lens combination, wherein a plurality of the lens bodies are arranged, and the emission surfaces are combined to form a continuous emission surface extending in a line in the horizontal direction. The lens body according to any one of claims 1 to 9,
A vehicular lamp comprising: a light source that emits light toward the incident portion of the lens body. The lens combination according to claim 10,
A vehicular lamp, comprising: a plurality of light sources that irradiate light toward each of the incident portions with respect to the plurality of lens bodies constituting the lens combination body.