JP2015176745A - Lens body and vehicle lighting appliance - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a lens body which eliminates metal deposition causing a cost increase, and can suppress the fusion of the lens body caused by the heat of a light source, and the lowering of a light source output, and a vehicle lighting appliance using the lens body.SOLUTION: In a lens body 12 having a shape which extends along a first reference axis AX1, an incident face 12a formed at a rear end part of the lens body, a reflection face 12b extending frontward from a lower end edge of the incident face, a shade 12c formed at a tip part of the reflection face, and an emission face 12d are arranged along the first reference axis AX1 in this order. The light of a light source 14 which is made incident into the lens body 12 from the incident face 12a passes a center of the light source 14 and a point in the vicinity of the shade 12c, and is condensed to a side shifted to a second reference axis AX2 which is inclined frontward-obliquely and downwardly with respect to the first reference axis AX1. The emission face 12d is constituted as a lens part whose focus is set in the vicinity of the shade 12c.

Description

  The present invention relates to a lens body and a vehicular lamp, and more particularly to a lens body used in combination with a light source and a vehicular lamp using the same.

  Conventionally, a vehicular lamp having a structure in which a light source and a lens body are combined has been proposed (see, for example, Patent Document 1).

  FIG. 16 is a longitudinal sectional view of the vehicular lamp 200 described in Patent Document 1.

  As shown in FIG. 16, the vehicular lamp 200 described in Patent Document 1 includes a light source 210 having a semiconductor light emitting element and a lens body 220, and the lens body 220 has a surface with a light emitting surface facing upward. A hemispherical incident surface 221 that covers the light source 210 from above, a first reflecting surface 222 (reflecting surface by metal deposition) disposed in the traveling direction of light from the light source 210 that enters the lens body 220 from the incident surface 221, A second reflecting surface 223 (a reflecting surface by metal vapor deposition), a convex lens surface 224, and the like extending forward from the lower end edge of the first reflecting surface 222 are formed.

JP-A-2005-228502

  However, in the vehicular lamp 200 having the above-described configuration, the reflective surfaces 222 and 223 formed by metal vapor deposition are used to control the light from the light source 210 that has entered the lens body 220, which increases the cost. is there.

  Further, in the vehicular lamp 200 having the above-described configuration, the light source 210 is covered from above with the hemispherical incident surface 221, and heat generated by the light source 210 cannot be released upward. There is a problem that the lens body 220 is melted or the output of the light source 210 is greatly reduced.

  The present invention has been made in view of such circumstances, and firstly, to provide a lens body in which a reflective surface by metal vapor deposition that causes a cost increase is omitted, and a vehicle lamp using the lens body. Objective. Secondly, an object of the present invention is to provide a lens body that can prevent the lens body from melting or the light source output from being reduced due to heat generated by the light source, and a vehicle lamp using the lens body. To do.

  In order to achieve the above object, according to a first aspect of the present invention, there is provided a lens body having a shape extending along a first reference axis extending in a horizontal direction, wherein the lens body includes an incident surface, a reflective surface, a shade, and an output surface. The incident surface, the reflective surface, the shade and the exit surface are arranged in this order along the first reference axis, the incident surface is formed at the rear end of the lens body, The light from the light source disposed in the vicinity of the incident surface is refracted and incident on the inside of the lens body, and the light from the light source incident on the lens body is at least in the vertical direction and the center of the light source. Passing through a point in the vicinity of the shade and condensing toward a second reference axis inclined obliquely forward and downward with respect to the first reference axis, and the reflecting surface is the incident surface Extending forward from the lower edge of the The shade is formed at the tip of the reflecting surface, and the exit surface includes direct light that travels toward the exit surface out of the light from the light source that has entered the lens body, and It is a surface on which reflected light that travels toward the exit surface after being internally reflected by the reflective surface is emitted, and is configured as a lens unit having a focal point in the vicinity of the shade.

  According to the first aspect of the present invention, firstly, it is possible to provide a lens body in which a reflective surface by metal vapor deposition that causes a cost increase is omitted. Second, it is possible to provide a lens body capable of suppressing the melting of the lens body and the decrease in the light source output due to the heat generated by the light source.

  The reason why the reflective surface by metal vapor deposition, which causes an increase in cost, can be omitted is that light from the light source is controlled not by the reflective surface by metal vapor deposition but by refraction at the incident surface and internal reflection at the reflective surface. It is because.

  The lens body can be prevented from melting or the light source output from being reduced due to the heat generated by the light source. The incident surface is formed at the rear end of the lens body and the light source This is because it is arranged outside the lens body (that is, at a position away from the incident surface of the lens body).

  According to a second aspect of the present invention, in the first aspect of the present invention, the reflective surface is a reflective surface that is inclined forward and downwardly downward with respect to the first reference axis from a lower end edge of the incident surface. It is characterized by that.

  According to invention of Claim 2, compared with the case where a reflective surface is made into the reflective surface extended in the horizontal direction toward the front from the lower end edge of the incident surface (that is, when a reflective surface is arrange | positioned in a horizontal direction), Reduction of stray light and higher efficiency can be achieved.

  According to a third aspect of the present invention, there is provided a vehicular lamp including a lens body having a shape extending along a first reference axis extending in a horizontal direction, and a light source. The lens body includes an incident surface, a reflective surface, The light source is disposed in the vicinity of the incident surface, and the incident surface, the reflecting surface, the shade, and the light emitting surface are disposed in this order along the first reference axis. The incident surface is formed at the rear end portion of the lens body, and is a surface on which light from a light source disposed in the vicinity of the incident surface is refracted and is incident on the lens body, and is incident on the lens body. The light from the light source passes through the center of the light source and a point in the vicinity of the shade at least in the vertical direction, and is closer to the second reference axis inclined forward and downward with respect to the first reference axis. Configured to condense and front The reflecting surface extends forward from the lower end edge of the incident surface, the shade is formed at the tip of the reflecting surface, and the exit surface is from the light source incident inside the lens body. The focal point is set in the vicinity of the shade on the surface where the direct light that travels toward the exit surface and the reflected light that travels toward the exit surface after being internally reflected by the reflective surface. It is configured as a lens unit.

  According to the invention described in claim 3, firstly, it is possible to provide a vehicular lamp using a lens body in which a reflecting surface by metal vapor deposition that causes a cost increase is omitted. Secondly, it is possible to provide a vehicular lamp using a lens body that can prevent the lens body from melting or light source output from being reduced due to heat generated by the light source.

  The reason why the reflective surface by metal vapor deposition, which causes an increase in cost, can be omitted is that light from the light source is controlled not by the reflective surface by metal vapor deposition but by refraction at the incident surface and internal reflection at the reflective surface. It is because.

  The lens body can be prevented from melting or the light source output from being reduced due to the heat generated by the light source. The incident surface is formed at the rear end of the lens body and the light source This is because it is arranged outside the lens body (that is, at a position away from the incident surface of the lens body).

  According to a fourth aspect of the present invention, in the third aspect of the invention, the reflective surface is a reflective surface that is inclined obliquely forward and downward with respect to the first reference axis from a lower end edge of the incident surface. It is characterized by that.

  According to the invention described in claim 4, compared to a case where the reflecting surface is a reflecting surface extending in the horizontal direction from the lower end edge of the incident surface (that is, when the reflecting surface is arranged in the horizontal direction), Reduction of stray light and higher efficiency can be achieved.

  The invention according to claim 5 is the invention according to claim 3 or 4, wherein the light source is disposed in the vicinity of the incident surface in a posture in which the optical axis of the light source coincides with the second reference axis. It is characterized by.

  According to the fifth aspect of the present invention, it is possible to form a light distribution pattern for low beam which has a relatively high central luminous intensity and is excellent in distance visibility.

  According to the present invention, firstly, it is possible to provide a lens body in which a reflection surface by metal vapor deposition that causes cost increase is omitted, and a vehicular lamp using the lens body. Second, it is possible to provide a lens body that can prevent the lens body from melting or the light source output from being lowered due to heat generated by the light source, and a vehicle lamp using the lens body. Become.

It is a longitudinal section of vehicular lamp 10 which is a 1st embodiment of the present invention. (A) The perspective view of the lens body 12 seen from the front, (b) The perspective view of the lens body 12 seen from the back. (A) Top view of lens body 12, (b) Bottom view, (c) Side view. (A) The figure showing a mode that the light from the light source 14 (precisely the reference point F) injects into the entrance plane 12a, (b) The light (direct light RayA) from the light source 14 which injected into the lens body 12 inside. It is a figure showing a mode that it condenses. It is an example (transverse sectional view) of the incident surface 12a. It is another example (transverse cross section) of the entrance plane 12a. (A) (b) It is a figure for demonstrating the distance between the entrance plane 12a and the light source 14. FIG. It is a figure for demonstrating the role of the shade 12c. (A) Schematic diagram of the shade 12c viewed from the position of the light source 14, (b) An enlarged perspective view enlarging the reflecting surface 12b (including the shade 12c) shown in FIG. 2 (a), (c) FIG. 2 (a). It is a top view of the reflective surface 12b (including shade 12c) shown in FIG. (A)-(c) It is the modification (side view) of the shade 12c. (A) An example of a low beam light distribution pattern P1 formed on a virtual vertical screen (disposed approximately 25 m ahead from the front of the vehicle) by the vehicular lamp 10 of the present embodiment, b) An example of the low beam light distribution pattern P2, and (c) an example of the low beam light distribution pattern P3. It is a figure for demonstrating light source image ICs1-ICs4 by the light from the light source 14 in each cross section _{Cs1- Cs4} . (A) When reflecting surface 12b is arranged in the horizontal direction, a diagram depicting a situation in which reflected light RayB ′ internally reflected by reflecting surface 12b travels in a direction not incident on exit surface 12d, (b) reflecting surface 12b FIG. 6 is a diagram illustrating a state in which the reflected light RayB internally reflected by the reflecting surface 12b travels in a direction to enter the exit surface 12d when it is arranged to be inclined with respect to the first reference axis AX1. (A) When the reflective surface 12b is arranged in the horizontal direction, a diagram depicting a state in which the reflected light RayB ′ traveling in the direction not incident on the exit surface 12d can be captured by extending the reflective surface 12b upward; b) When the reflecting surface 12b is disposed so as to be inclined with respect to the first reference axis AX1, more light (reflected light RayB internally reflected by the reflecting surface 12b) is captured without extending the reflecting surface 12b upward. FIG. (A) The second reference axis AX2 is arranged in the horizontal direction, and the light from the light source 14 incident on the lens body 12 is condensed toward the second reference axis AX2 toward the shade 12c at least in the vertical direction. In this case, a diagram depicting a state in which most of the light from the light source 14 incident on the inside of the lens body 12 is shielded by the shade 12c. When the light from the light source 14 incident on the inside of the lens body 12 is condensed toward the second reference axis AX2 toward the shade 12c at least in the vertical direction, the light captured by the emission surface 12d (the inner surface of the reflection surface 12b) It is the figure which showed a mode that reflected reflected light RayB) increased. It is a longitudinal cross-sectional view of the vehicular lamp 200 described in Patent Document 1.

  Hereinafter, the vehicle lamp which is 1st Embodiment of this invention is demonstrated, referring drawings.

  FIG. 1 is a longitudinal sectional view of a vehicular lamp 10 according to a first embodiment of the present invention.

  As shown in FIG. 1, the vehicular lamp 10 of the present embodiment includes a lens body 12, a light source 14 disposed in the vicinity of the incident surface 12 a of the lens body 12, and the like, and a virtual vertical screen (vehicle) It is configured as a vehicle headlamp that forms a low beam light distribution pattern P1 including cut-off lines CL1 to CL3 on the upper edge shown in FIG. ing.

  2A is a perspective view of the lens body 12 viewed from the front, FIG. 2B is a perspective view of the lens body 12 viewed from the rear, FIG. 3A is a top view of the lens body 12, and FIG. FIG. 3B is a bottom view, and FIG. 3C is a side view.

  As shown in FIG. 1, the lens body 12 is a lens body having a shape extending along a first reference axis AX1 extending in the horizontal direction, and includes an entrance surface 12a, a reflection surface 12b, a shade 12c, an exit surface 12d, and an entrance surface 12a. The reference point F in the optical design arranged in the vicinity is included. The entrance surface 12a, the reflection surface 12b, the shade 12c, and the exit surface 12d are arranged in this order along the first reference axis AX1. The material of the lens body 12 may be polycarbonate, other transparent resin such as acrylic, or glass.

  A dotted line with an arrow at the tip in FIG. 1 represents an optical path of light from the light source 14 (more precisely, the reference point F) that has entered the lens body 12.

The main functions of the lens body 12 are firstly to capture the light from the light source 14 into the lens body 12, and secondly to proceed toward the exit surface 12d of the light captured into the lens body 12. The light intensity distribution (light source image) formed in the vicinity of the focal point F _12d of the exit surface 12d (lens portion) is reversely projected by the direct light RayA and the reflected light RayB that is internally reflected by the reflecting surface 12b, and is cut off on the upper edge. Forming a light distribution pattern for low beam including

  4A shows a state in which light from the light source 14 (precisely, the reference point F) enters the incident surface 12a, and FIG. 4B shows light from the light source 14 that has entered the lens body 12. FIG. It is a figure showing a mode that (direct light RayA) condenses.

  The incident surface 12a is formed at the rear end of the lens body 12, and is light from the light source 14 (precisely, the reference point F in optical design) disposed in the vicinity of the incident surface 12a (see FIG. 4A). ) Is refracted and incident on the inside of the lens body 12 (for example, a free-form curved surface convex toward the light source 14), and light (direct light RayA) incident on the lens body 12 is at least in the vertical direction. , The surface shape is configured so as to converge toward the second reference axis AX2 toward the shade 12c (see FIG. 4B). The second reference axis AX2 passes through the center of the light source 14 (precisely, the reference point F) and a point near the shade 12c, and is inclined obliquely forward and downward with respect to the first reference axis AX1 ( (See FIG. 1).

The light source 14 includes, for example, a semiconductor substrate (not shown) such as a metal substrate (not shown) and a white LED light source (or white LD light source) mounted on the surface of the substrate. The number of semiconductor light emitting elements may be one or more. The light source 14 may be a light source other than a semiconductor light emitting element such as a white LED light source (or a white LD light source). The light source 14 is in the vicinity of the incident surface 12a of the lens body 12 in a posture in which the light emitting surface (not shown) is directed obliquely forward and downward, that is, in a posture in which the optical axis AX ₁₄ of the light source 14 coincides with the second reference axis AX2. (Near reference point F). The light source 14 is configured so that the optical axis AX ₁₄ of the light source 14 does not coincide with the second reference axis AX2 (for example, the optical axis AX ₁₄ of the light source 14 is disposed in the horizontal direction). You may arrange | position in the entrance plane 12a vicinity (reference point F vicinity).

When the light source 14 is a semiconductor light emitting element (for example, a white LED light source), the directivity characteristic of light emitted from the light source 14 (light emitting surface) is Lambertian and can be expressed as I (θ) = I ₀ × cos θ. . This represents the spread of light emitted by the light source 14. However, I (θ) represents the light intensity from the optical axis _{AX 14} of the angle theta inclined direction of the light source 14, _{I 0} represents the intensity on the optical axis _{AX 14.} In the light source 14, the luminous intensity on the optical axis AX ₁₄ (θ = 0) is maximized.

  FIG. 5 is an example (transverse sectional view) of the incident surface 12a, and FIG. 6 is another example (transverse sectional view) of the incident surface 12a.

  As shown in FIG. 5, in the horizontal direction, the incident surface 12 a condenses light from the light source 14 that has entered the lens body 12 (direct light RayA) toward the first reference axis AX1 toward the shade 12 c. Thus, the surface shape is configured. In addition, as shown in FIG. 6, the incident surface 12a is such that the light from the light source 14 (direct light RayA) incident on the inside of the lens body 12 is parallel to the reference axis AX1 in the horizontal direction. The surface shape may be configured.

  The degree of horizontal diffusion of the low beam light distribution pattern can be freely adjusted by adjusting the shape of the incident surface 12a (for example, the curvature of the incident surface 12a in the horizontal direction).

  FIG. 7A and FIG. 7B are diagrams for explaining the distance between the incident surface 12 a and the light source 14.

Compared with the case where the distance between the incident surface 12a and the light source 14 is increased (see FIG. 7A) by shortening the distance between the incident surface 12a and the light source 14 (see FIG. 7B). The light source image becomes smaller. As a result, the maximum luminous intensity of the luminous intensity distribution (and the low beam light distribution pattern) formed in the vicinity of the focal point F _{12d of} the emission surface 12d (lens portion) can be increased.

  Further, by shortening the distance between the incident surface 12a and the light source 14 (see FIG. 7B), the distance between the incident surface 12a and the light source 14 is increased (see FIG. 7A). As compared with the above, light from the light source 14 taken into the lens body 12 increases (β> α). As a result, a highly efficient lens body is obtained.

  The reflecting surface 12b is a planar reflecting surface extending in the horizontal direction from the lower end edge of the incident surface 12a toward the front. The reflective surface 12b is a reflective surface that totally reflects the light incident on the reflective surface 12b out of the light from the light source 14 that has entered the lens body 12, and metal deposition is not used. Of the light from the light source 14 that has entered the lens body 12, the light that has entered the reflecting surface 12 b is internally reflected by the reflecting surface 12 b and travels toward the exit surface 12 d, and is refracted by the exit surface 12 d and travels in the road surface direction. That is, the reflected light RayB internally reflected by the reflecting surface 12b is folded back at the cutoff line and superimposed on the light distribution pattern below the cutoff line. Thereby, a cut-off line is formed at the upper edge of the low beam light distribution pattern.

  The reflective surface 12b may be a planar reflective surface that is inclined obliquely forward and downward with respect to the first reference axis AX1 from the lower end edge of the incident surface 12a (see FIG. 14B). The advantage of arranging the reflecting surface 12b so as to be inclined with respect to the first reference axis AX1 will be described later.

  A shade 12c extending in the left-right direction is formed at the tip of the reflecting surface 12b.

  FIG. 8 is a diagram for explaining the role of the shade 12c.

As shown in FIG. 8, the main role of the shade 12c is to block a part of the light from the light source 14 that has entered the lens body 12, and at the bottom edge near the focal point F _{12d of the} exit surface 12d (lens portion). Forming a light intensity distribution (light source image) including a side corresponding to the cutoff line defined by the shade 12c.

  FIG. 9A is a schematic view of the shade 12c viewed from the position of the light source 14, and FIG. 9B is an enlarged perspective view of the reflecting surface 12b (including the shade 12c) shown in FIG. FIG. 3C is a top view of the reflecting surface 12b (including the shade 12c) shown in FIG.

  As shown in FIGS. 2A and 9A to 9C, the shade 12c includes a side e1 corresponding to the left horizontal cutoff line, a side e2 corresponding to the right horizontal cutoff line, and the left horizontal. An edge e3 corresponding to the oblique cut-off line connecting the cut-off line and the right horizontal cut-off line is included.

  The reflective surface 12b is a first reflective region 12b1 between the lower edge of the incident surface 12a and the side e1 corresponding to the left horizontal cutoff line, and between the lower edge of the incident surface 12a and the side e2 corresponding to the right horizontal cutoff line. The second reflection area 12b2 and the third reflection area 12b3 between the first reflection area 12b1 and the second reflection area 12b2.

  The first reflection region 12b1 is gradually curved upward as it approaches the side e1 corresponding to the left horizontal cut-off line from the lower end edge of the incident surface 12a, while the second reflection region 12b2 is lower end edge of the incident surface 12a. Extends horizontally from the front to the front.

  As a result, the side e1 corresponding to the left horizontal cut-off line is arranged at a level higher than the side e2 corresponding to the right horizontal cut-off line in the vertical direction (in the case of right-hand traffic). Of course, the side e1 corresponding to the left horizontal cutoff line may be arranged at a position one step lower than the side e2 corresponding to the right horizontal cutoff line in the vertical direction (in the case of left-hand traffic).

  The shade 12c has a groove corresponding to the left horizontal cut-off line, a groove corresponding to the right horizontal cut-off line, and an oblique cut-off line connecting the left horizontal cut-off line and the right horizontal cut-off line at the tip of the reflecting surface 12b. It can also form by forming the groove part containing the groove part corresponding to.

  10 (a) to 10 (c) show a modified example (side view) of the shade 12c. The shade 12c may extend upward from the tip of the reflecting surface 12b in a side view (see FIG. 10A), or may extend obliquely upward in the front direction (FIG. 10 ( b)), and may be curved and extended forward and obliquely upward (see FIG. 10C). The shade 12c is not limited to these, and may have any shape as long as a part of the light from the light source 14 entering the lens body 12 is shielded so as not to travel toward the exit surface 12d. In addition, you may use the light-shielded light for another light distribution and light guide.

As shown in FIG. 1, the exit surface 12 d is internally reflected by the direct light RayA that travels toward the exit surface 12 d and the reflection surface 12 b of the light from the light source 14 that has entered the lens body 12. A lens in which the focal point F _12d is set in the vicinity of the shade 12c (for example, near the center in the left-right direction of the shade 12c) on the surface from which the reflected light RayB traveling toward 12d is emitted (for example, a convex surface convex forward). It is configured as a part. Exit surface 12d is the direct light RayA and reflected light RayB travels toward to the exit surface 12d, the light intensity distribution formed on the focal point _{F 12d} near the exit face 12d (lens unit) a (light source image) inverted projected to Then, a low beam light distribution pattern including a cut-off line at the upper end edge is formed.

Note that by increasing the distance (focal length) between the shade 12c and the exit surface 12d, the light source image becomes smaller than when the distance (focal length) between the shade 12c and the exit surface 12d is shortened. . As a result, the maximum luminous intensity of the luminous intensity distribution (and the low beam light distribution pattern) formed in the vicinity of the focal point F _{12d of} the emission surface 12d (lens portion) can be increased.

  In addition, by shortening the distance between the exit surface 12d and the light source 14 (or shade 12c), the exit surface 12d is longer than when the distance between the exit surface 12d and the light source 14 (or shade 12c) is increased. The direct light RayA and the reflected light B that are taken in are increased. As a result, efficiency increases.

  The degree of diffusion of the low beam light distribution pattern in the horizontal direction and the vertical direction can be freely adjusted by adjusting the surface shape of the exit surface 12d.

  A surface that connects the leading edge of the reflecting surface 12b and the lower edge of the emitting surface 12d is an inclined surface that extends obliquely forward and downward from the leading edge of the reflecting surface 12b. In addition, the surface which connects the front-end edge of the reflective surface 12b and the lower end edge of the output surface 12d is not limited to this, and any surface that does not block the direct light RayA and the reflected light RayB traveling toward the output surface 12d. It may be a surface. Similarly, the surface connecting the upper end edge of the incident surface 12a and the upper end edge of the exit surface 12d is a planar surface extending in the horizontal direction between the upper end edge of the entrance surface 12a and the upper end edge of the exit surface 12d. Has been. The surface connecting the upper end edge of the incident surface 12a and the upper end edge of the output surface 12d is not limited to this, and any surface that does not block the direct light RayA and the reflected light RayB traveling toward the output surface 12d. It may be a surface.

  In the lens body 12 configured as described above, the light that has entered the lens body 12 from the incident surface 12a is condensed toward the second reference axis AX2 toward the shade 12c in the vertical direction as shown in FIG. For example, the light is condensed at the center of the shade 12c). And when the surface shape of the incident surface 12a is comprised as shown in FIG. 5, the light which injected into the lens body inside the incident surface 12a is toward the shade 12c regarding a horizontal direction, as shown in FIG. The light is condensed toward the first reference axis AX1 (for example, condensed at the center of the shade 12c).

As described above, the direct light RayA collected in the vertical direction and the horizontal direction and the reflected light RayB internally reflected by the reflecting surface 12b travel toward the emitting surface 12d and are emitted from the emitting surface 12d. At that time, the direct light RayA and reflected light RayB traveling toward the exit surface 12d, the focal _{F 12d} near the exit face 12d (lens unit), the side corresponding to the cut-off line defined in the lower edge by the shade 12c A luminous intensity distribution (light source image) is formed. Then, the exit surface 12d reversely projects this luminous intensity distribution to form a low beam light distribution pattern P1 including a cut-off line at the upper edge shown in FIG. 11A on the virtual vertical screen.

The low-beam light distribution pattern P1 has a relatively high central luminous intensity and excellent distant visibility. This is because the light source 14 is disposed in the vicinity of the incident surface 12a of the lens body 12 (in the vicinity of the reference point F) in such a posture that the optical axis AX ₁₄ of the light source 14 coincides with the second reference axis AX2. intensity (luminosity) is high light on axis AX ₁₄ of the light (direct light) is condensed on the second reference axis AX2 closer toward the shade 12c (e.g., condensed at the center of the shade 12c) be due to is there.

  In addition, by adjusting the surface shape (for example, curvature) of the entrance surface 12a and / or the exit surface 12d, as shown in FIG. 11B, a low beam light distribution pattern P2 diffused in the horizontal direction is formed. You can also.

  Further, by increasing the inclination of the second reference axis AX2 (see the angle θ shown in FIG. 1) with respect to the first reference axis AX1, the lower edge of the low beam light distribution patterns P1, P2 can be extended downward.

  On the other hand, when the surface shape of the incident surface 12a is configured as shown in FIG. 6, the light that has entered the lens body 12 from the incident surface 12a has a first reference axis in the horizontal direction as shown in FIG. The light is parallel to AX1.

As described above, the direct light RayA collected in the vertical direction and parallel to the horizontal direction and the reflected light RayB internally reflected by the reflection surface 12b travel toward the emission surface 12d and are emitted from the emission surface 12d. . At that time, the direct light RayA and reflected light RayB traveling toward the exit surface 12d, the focal _{F 12d} near the exit face 12d (lens unit), corresponding to the cutoff line CL1~CL3 defined in the lower edge by the shade 12c A luminous intensity distribution (light source image) including a side to be formed is formed. The exit surface 12d reversely projects this luminous intensity distribution to form a low beam light distribution pattern P3 including cut-off lines CL1 to CL3 at the upper edge shown in FIG. 11C on the virtual vertical screen. The low beam light distribution pattern P3 shown in FIG. 11C is more diffused in the horizontal direction than the low beam light distribution pattern P1 shown in FIG.

  Next, the relationship between the light source image by the light from the light source 14 that has entered the lens body 12 and the low beam light distribution pattern will be described.

  FIG. 12 is a diagram for explaining a light source image by light from the light source 14 in each of the cross sections Cs1 to Cs3.

As shown in FIG. 12, the external shape of the cross section Cs1, the light source image _I Cs1 in _{Cs2, I Cs2} becomes the same as the outer shape of the light source (larger as the light source image in the external shape and similar type of light source 14).

On the other hand, the outer shape of the light source image _{I Cs3} in section Cs3 after passing through the reflecting surface 12b and the shade 12c includes an edge e1, e2, e3 corresponding to cutoff line CL1~CL3 defined in the lower edge by the shade 12c It will be a thing. This light source image I _Cs3 is inverted by the action of the exit surface 12d (lens portion) and includes edges e1, e2, e3 corresponding to the cut-off lines CL1 to CL3 defined by the shade 12c at the upper end edge.

  The light distribution patterns P1 to P3 for low beams shown in FIGS. 11A to 11C include light sources including sides e1, e2, and e3 corresponding to the cut-off lines CL1 to CL3 defined by the shade 12c at the upper end edge. Since it is formed on the basis of an image, clear cut-off lines CL1, CL2, and CL3 are included at the upper edge.

  Next, the advantage of disposing the reflecting surface 12b with respect to the first reference axis AX1 will be described in comparison with the case where the reflecting surface 12b is disposed in the horizontal direction.

  The first advantage is that stray light can be reduced and efficiency can be increased as compared with the case where the reflecting surface 12b is arranged in the horizontal direction.

  That is, as shown in FIG. 13A, when the reflecting surface 12b is arranged in the horizontal direction, the reflected light RayB ′ internally reflected by the reflecting surface 12b travels in the direction not entering the exit surface 12d. It becomes. As a result, efficiency is reduced.

  On the other hand, as shown in FIG. 13B, when the reflecting surface 12b is inclined with respect to the first reference axis AX1, the reflection is reflected from the reflecting surface 12b and proceeds toward the emitting surface 12d. The light RayB increases, and the light captured by the emission surface 12d (the reflected light reflected from the inner surface by the reflection surface 12b) increases. As a result, the stray light can be reduced and the efficiency can be increased as compared with the case where the reflecting surface 12b is arranged in the horizontal direction.

  In the simulation performed by the inventors of the present application, the efficiency increases by 33.8% when the reflecting surface 12b is tilted by 5 ° with respect to the first reference axis AX1, and the efficiency increases when the reflecting surface 12b is tilted by 10 °. Increased by 60%.

  The second advantage is that the lens body 12 can be reduced in size as compared with the case where the reflecting surface 12b is arranged in the horizontal direction.

  That is, as shown in FIG. 13A, when the reflecting surface 12b is arranged in the horizontal direction, the reflected light RayB ′ internally reflected by the reflecting surface 12b travels in the direction not entering the exit surface 12d. It becomes. The exit surface 12d can capture stray light RayB 'by extending it upward as shown in FIG. 14 (a), but the exit surface 12d becomes larger as it extends upward.

  On the other hand, as shown in FIG. 14B, when the reflecting surface 12b is inclined with respect to the first reference axis AX1, the exit surface 12d has more light (without extending it upward). The reflected light RayB) internally reflected by the reflecting surface 12b can be taken in. As a result, as compared with the case where the reflecting surface 12b is arranged in the horizontal direction, it is possible to reduce the size of the exit surface 12d (and thus the lens body 12).

  In the simulation performed by the inventors of the present application, when the reflecting surface 12b is inclined at 5 ° with respect to the first reference axis AX1, the height A (light emitted from the emitting surface 12d) shown in FIG. 14 (a) is reduced by 8% compared to the case shown in FIG. 14 (a), and the height A shown in FIG. 14 (b) is shown in FIG. Compared to the case shown, it decreased by 18.1%.

  Next, the second reference axis AX2 is arranged so as to be inclined with respect to the first reference axis AX1, and the light from the light source 14 incident on the lens body 12 enters the second reference axis toward the shade 12c at least in the vertical direction. Regarding the advantage of condensing near AX2, the second reference axis AX2 is arranged in the horizontal direction, and the light from the light source 14 incident on the inside of the lens body 12 is directed to the shade 12c at least in the vertical direction. The description will be made in comparison with the case where light is condensed near the axis AX2.

  The advantage is that the second reference axis AX2 is arranged in the horizontal direction, and the light from the light source 14 incident on the lens body 12 is condensed toward the second reference axis AX2 toward the shade 12c at least in the vertical direction. Compared to the case, the stray light can be reduced and the efficiency can be increased.

  That is, as shown in FIG. 15A, the second reference axis AX2 is arranged in the horizontal direction, and the light from the light source 14 incident on the lens body 12 is secondly directed toward the shade 12c at least in the vertical direction. When the light is condensed near the reference axis AX2, much of the light from the light source 14 that has entered the lens body 12 is blocked by the shade 12c. As a result, efficiency is greatly reduced. Further, in FIG. 15A, assuming that a reflecting surface corresponding to the reflecting surface 12b is added, the reflected light that is internally reflected by the reflecting surface becomes stray light that travels in a direction not incident on the exit surface 12d.

  On the other hand, as shown in FIG. 15B, the second reference axis AX2 is inclined with respect to the first reference axis AX1, and the light from the light source 14 incident on the lens body 12 is at least vertically. Regarding the direction, when the light is condensed toward the second reference axis AX2 toward the shade 12c, the light captured by the exit surface 12d (the reflected light RayB internally reflected by the reflective surface 12b) increases. As a result, the second reference axis AX2 is arranged in the horizontal direction, and the light from the light source 14 incident on the lens body 12 is condensed toward the second reference axis AX2 toward the shade 12c at least in the vertical direction. Compared to the above, the stray light can be reduced and the efficiency can be increased.

  As described above, according to the present embodiment, firstly, it is possible to provide the lens body 12 and the vehicle lamp 10 using the lens body 12 in which the reflective surface by metal vapor deposition that causes a cost increase is omitted. Second, the lens body 12 that can prevent the lens body 12 from melting or the output of the light source 14 from being lowered due to the heat generated in the light source 14 and a vehicle lamp 10 using the lens body 12 are provided. can do.

  The reason why the reflective surface by metal vapor deposition, which causes an increase in cost, can be omitted is that the light from the light source 14 is not reflected by the metal vapor deposition, but by refraction at the incident surface 12a and internal reflection at the reflective surface 12b. It is by being controlled.

  The reason why the lens body 12 can be prevented from melting or the output of the light source 14 from being lowered due to the heat generated by the light source 14 is that the incident surface 12a is formed at the rear end of the lens body 12. This is because the light source 14 is disposed outside the lens body 12 (that is, at a position separated from the incident surface 12a of the lens body 12).

  Each numerical value shown in the above embodiment and each modified example is an exemplification, and any appropriate numerical value different from this can be used.

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

10 ... vehicle lamp 12 ... lens body, 12a ... entrance surface, 12b ... reflecting surface, 12c ... Shade, 12c ... Shade, 12d ... exit surface 14 ... light source, AX _{14 ...} optical axis

Claims (5)

In the lens body having a shape extending along the first reference axis extending in the horizontal direction,
The lens body includes an incident surface, a reflective surface, a shade, and an output surface,
The entrance surface, the reflection surface, the shade, and the exit surface are arranged in this order along the first reference axis,
The incident surface is formed at a rear end portion of the lens body, and is a surface on which light from a light source disposed in the vicinity of the incident surface is refracted and is incident on the lens body, and is incident on the lens body. Light from the light source passes through the center of the light source and a point in the vicinity of the shade, at least in the vertical direction, and is condensed near the second reference axis inclined forward and downward with respect to the first reference axis. Is configured to
The reflective surface extends forward from the lower end edge of the incident surface,
The shade is formed at the tip of the reflecting surface,
The exit surface includes direct light that travels toward the exit surface among the light from the light source that has entered the lens body, and reflected light that travels toward the exit surface after being internally reflected by the reflection surface. Is a lens body configured as a lens unit in which the focal point is set in the vicinity of the shade on the surface from which light is emitted.   The lens body according to claim 1, wherein the reflection surface is a reflection surface that is inclined obliquely forward and downward with respect to the first reference axis from a lower end edge of the incident surface. In a vehicle lamp comprising a lens body having a shape extending along a first reference axis extending in the horizontal direction, and a light source,
The lens body includes an incident surface, a reflective surface, a shade, and an output surface,
The light source is disposed in the vicinity of the incident surface;
The entrance surface, the reflection surface, the shade, and the exit surface are arranged in this order along the first reference axis,
The incident surface is formed at a rear end portion of the lens body, and is a surface on which light from a light source disposed in the vicinity of the incident surface is refracted and is incident on the lens body, and is incident on the lens body. Light from the light source passes through the center of the light source and a point in the vicinity of the shade, at least in the vertical direction, and is condensed near the second reference axis inclined forward and downward with respect to the first reference axis. Is configured to
The reflective surface extends forward from the lower end edge of the incident surface,
The shade is formed at the tip of the reflecting surface,
The exit surface includes direct light that travels toward the exit surface among the light from the light source that has entered the lens body, and reflected light that travels toward the exit surface after being internally reflected by the reflection surface. A vehicular lamp configured as a lens unit having a focal point set in the vicinity of the shade on the surface from which light is emitted.   4. The vehicular lamp according to claim 3, wherein the reflection surface is a reflection surface inclined obliquely forward and downward with respect to the first reference axis from a lower end edge of the incident surface. 5.   5. The vehicular lamp according to claim 3, wherein the light source is disposed in the vicinity of the incident surface in a posture in which an optical axis of the light source coincides with the second reference axis.