JP6127538B2 - Vehicle lighting - Google Patents

Description

  The present invention is a vehicular lamp including a semiconductor light source and a lens member, such as a tail lamp, a stop lamp, a tail / stop lamp, a clearance lamp, a turn signal lamp, a rear fog lamp, and a daytime running lamp. The present invention relates to a vehicular lamp. In particular, the present invention relates to a vehicular lamp in which an emission surface extends in a direction perpendicular to the optical axis of a lens member, and a light emission surface has a long shape such as a rectangular shape.

  This type of vehicular lamp is conventionally known (for example, Patent Document 1). Hereinafter, a conventional vehicle lamp will be described. A conventional vehicle lamp includes an LED light source and a lens, and the lens includes a convex curved incident surface, a curved or linearly curved curved incident surface, a reflecting surface, and an emitting surface. Yes. Part of the light from the LED light source enters the lens from the incident surface of the convex curved surface and exits from the output surface, and the other part of the light from the LED light source is an incident surface lens of a linearly rotating curved surface The light enters the inside, is reflected by the reflecting surface, and exits from the emitting surface.

JP 2012-190677 A

  However, in the conventional vehicular lamp, incident light incident from the incident surface having a convex curved surface is emitted from the exit surface as parallel light. For this reason, a part of the emission surface (the central portion, the location where the parallel light is emitted) shines with high brightness. That is, it is lit up and is not preferable in appearance.

  The problem to be solved by the present invention is that the conventional vehicular lamp is lit in an undesirable manner.

The present invention (the invention according to claim 1) includes a semiconductor-type light source and a lens member, and the lens member has an emission surface extending in a direction orthogonal to the optical axis of the lens member, and a semiconductor. A first incident surface that diffuses and injects light emitted from the central portion of the mold light source toward the exit surface, and is disposed on both sides of the first entrance surface and on the extending direction side of the exit surface; A second incident surface on which light emitted from a side portion of the mold light source is incident as parallel light, and both sides of the second incident surface, which are disposed on the extending direction side of the emission surface, and from the second incident surface possess one or more reflecting surfaces to reflect toward the exit surface parallel light incident, the first plane of incidence is incident toward a light emitted from a central portion of the semiconductor-type light source on the exit surface side The light emitted from the center of the semiconductor light source is spread toward the exit surface on the basic first entrance surface. The basic first incident surface is a refracting surface of a rotating hyperboloid formed by rotating a hyperbola with a semiconductor-type light source as a focal point about the main axis of the hyperbola as a rotation axis. Is a cylindrical prism in which a plurality of convex curved surfaces protruding in the semiconductor light source side are provided in the vertical direction .

  In the vehicular lamp according to the present invention, the first incident surface diffuses the light emitted from the central portion of the semiconductor-type light source toward the exit surface, so that the light incident from the first entrance surface covers the entire exit surface. Is spread. Thereby, so-called spotlight in which the emission surface shines almost uniformly over the entire surface and a part of the emission surface shines with high brightness can be prevented, and the appearance can be improved.

FIG. 1 is an explanatory view of a semiconductor-type light source and a lens member showing Embodiment 1 of a vehicular lamp according to the present invention. FIG. 2 is an explanatory diagram showing an exit surface, a first entrance surface, a second entrance surface, and a reflection surface of the lens member. FIG. 3 is an explanatory diagram showing an optical path in the lens member. FIG. 4 is an explanatory view showing a state in which a long emission surface (light emission surface) emits light. FIG. 5 is an explanatory view of a semiconductor-type light source and a lens member showing Embodiment 2 of the vehicular lamp according to the present invention.

  Hereinafter, two examples of an embodiment (example) of a vehicular lamp according to the present invention will be described in detail with reference to the drawings. In addition, this invention is not limited by this embodiment. In the description of the claims, “parallel” defines “parallel or substantially parallel”, and “orthogonal” defines “orthogonal or substantially orthogonal”.

(Description of Configuration of Embodiment 1)
1 to 4 show Embodiment 1 of a vehicular lamp according to the present invention. FIG. 1A is an explanatory plan view showing a semiconductor-type light source and a lens member. FIG. 1B is a view as viewed in the direction of arrow B in FIG. FIG. 1C is a view taken in the direction of arrow C in FIG. 1A (a side explanatory view showing a semiconductor light source and a lens member).

  Hereinafter, the configuration of the vehicular lamp in the first embodiment will be described. The vehicular lamp according to the first embodiment includes a lamp housing (not shown) and a lamp lens (not shown) that define a lamp chamber (not shown), and a semiconductor-type light source 1 and a lens arranged in the lamp chamber. The member 2 is provided.

  In this example, the semiconductor light source 1 and the lens member 2 constitute a lamp unit of a tail lamp. The semiconductor light source 1 and the lamp unit of the tail lamp of the lens member 2 are arranged in one or more units in the lamp chamber. The lamp unit of the tail lamp of the semiconductor light source 1 and the lens member 2 constitutes a rear combination lamp together with a lamp unit of other functions. The rear combination lamps are mounted on both the left and right sides of the rear portion of the vehicle (not shown).

(Description of the semiconductor-type light source 1)
In this example, the semiconductor-type light source 1 is a self-luminous semiconductor-type light source such as an LED, an OEL, or an OLED (organic EL). The semiconductor-type light source 1 has a package structure in which a light emitting chip (LED chip) 11 is sealed with a sealing resin member. The semiconductor-type light source 1 is mounted on a substrate (not shown). The substrate is attached to the lamp housing via an attachment member or the like (not shown). The semiconductor-type light source 1 is supplied with power through the substrate. As shown in FIG. 4, light L1 and L2 from the light emitting chip 11 of the semiconductor-type light source 1 is substantially hemispherical at a wide angle (a solid angle with the light emitting chip 11 as a point (corner apex) is about 180 °). To be emitted.

(Description of the lens member 2)
As shown in FIG. 1A, the lens member 2 has a shape in plan view (a shape seen from above the vehicle below the vehicle, a shape seen in the direction opposite to the arrow X direction). It has a fan shape with the center or the center. Further, as shown in FIG. 4, the lens member 2 has a rectangular shape (long shape) when viewed from the front (the shape when the rear portion of the vehicle is viewed from the rear of the vehicle). Further, as shown in FIGS. 1B and 1C, the lens member 2 has a plate shape in which the vertical direction (the arrow X is the upward direction) is the plate thickness direction.

  In this example, the lens member 2 is made of a transparent resin material such as PC (polycarbonate) or PMMA (polymethyl methacrylate, methacrylic resin). The lens member 2 is attached to the lamp housing via an attachment member or the like (not shown). That is, the semiconductor-type light source 1 and the lens member 2 are attached to the lamp housing in a state where the relative attachment position is maintained.

  The lens member 2 includes an exit surface 20, a first incident surface 21, a second incident surface 22, a first reflecting surface 231, a second reflecting surface 232, a first step surface 241, and a second step surface. 242.

  In this example, the emission surface 20 has a rectangular shape (long shape) as shown in FIG. The exit surface 20 is a plane that emits light (L3, L5) perpendicularly or substantially perpendicularly to a measurement screen (not shown). The exit surface 20 is provided in front of the lens member 2.

  The first incident surface 21 radiates from a central portion of the light emitting chip 11 of the semiconductor-type light source 1 (a central portion having a solid angle of about 70 ° to 80 ° with the light emitting chip 11 as a point (corner apex)). This is a surface on which the incident light L1 is diffusely incident toward the exit surface 20 as diffuse incident light L3. The first incident surface 21 is provided at the center of the surface (back surface) of the lens member 2 facing the semiconductor light source 1. That is, the first incident surface 21 is provided corresponding to the central portion of the semiconductor light source 1.

  The first incident surface 21 is formed on the basic first incident surface 210 that allows the light L1 emitted from the central portion of the light emitting chip 11 of the semiconductor light source 1 to enter the emission surface 20 side. The light-emitting chip 11 is provided with a diffusion portion 25 that diffuses and enters the light L1 emitted from the central portion of the light-emitting chip 11 toward the emission surface 20 side.

  The basic first incident surface 210 makes light L1 emitted from the central portion of the light emitting chip 11 of the semiconductor-type light source 1 incident as parallel light or substantially parallel light (hereinafter simply referred to as “parallel light”) not shown. It is a surface to be made. The parallel incident light is parallel or substantially parallel to the optical axis Z of the lens member 2.

  That is, the basic first incident surface 210 has a hyperbola having a focal point F1 at or near the light emitting chip 11 of the semiconductor-type light source 1, as indicated by a two-dot chain line in FIG. It is a refracting surface of a rotating hyperboloid formed by rotating the optical axis Z) of the lens member 2 as a rotation axis.

  The diffusing unit 25 uses the parallel light incident from the basic first incident surface 210 as the diffuse incident light L3 (particularly, the diffuse incident light L3 diffused in the left-right direction) toward the emission surface 20 side. Diffuse incidence is performed. As shown in FIGS. 1 to 3, the diffusing portion 25 is provided with a plurality of convex curved surfaces protruding in the vertical direction in this example, protruding toward the semiconductor light source 1. That is, the diffusion unit 25 is a plurality of vertical cylindrical (kamaboko) prisms.

  The second incident surface 22 has a solid angle of about 70 ° to 80 ° to about 180 ° with the side of the light emitting chip 11 of the semiconductor light source 1 (the light emitting chip 11 being a point (corner apex)). This is a surface on which the light L2 emitted from the side portion between the light beams is incident as parallel light or substantially parallel light (hereinafter simply referred to as “parallel light”) L4. The parallel incident light L4 is parallel or substantially parallel to the optical axis Z. The second incident surface 22 is provided on a side portion of the surface (back surface) of the lens member 2 facing the semiconductor light source 1. That is, the second incident surface 22 is provided on both the left and right sides of the first incident surface 21 at the center and corresponding to the side portion of the semiconductor-type light source 1.

  The second incident surface 22 is a refracting surface formed of a part of a rotation surface having a straight line or a curve as a rotation axis. The second incident surface 22 is a refractive surface that is inclined with respect to the optical axis Z direction by a draft angle (not shown) of a molding die (not shown) of the lens member 2. The drawing direction of the molding die is the direction opposite to the arrow direction of the optical axis Z.

  The first reflecting surface 231 and the second reflecting surface 232 are configured so that the parallel incident light L4 incident from the second incident surface 22 is parallel reflected light or substantially parallel reflected light (hereinafter referred to as “parallel reflected light”). This is a surface that is totally reflected as L5. The first reflecting surface 231 and the second reflecting surface 232 are reflecting surfaces formed of a part of a rotating surface whose curved axis is the optical axis Z. The first reflecting surface 231 and the second reflecting surface 232 are provided on the left and right side portions of the second incident surface 22 and on the left and right side surfaces of the lens member 2.

  The first step surface 241 is provided between the second incident surface 22 and the first reflecting surface 231. The first step surface 241 is a surface that reflects the parallel incident light L4 incident from the second incident surface 22 on the first reflecting surface 231 without being interrupted by anything.

  The second step surface 242 is provided between the first reflecting surface 231 and the second reflecting surface 232. The second step surface 242 is a surface that reflects the parallel incident light L <b> 4 incident from the second incident surface 22 on the second reflecting surface 232 without being blocked by the first reflecting surface 231.

  The first step surface 241 and the second step surface 242 are surfaces for extending the emission surface 20 in the left-right direction.

(Description of the operation of the first embodiment)
The vehicular lamp in the first embodiment is configured as described above, and the operation thereof will be described below.

  The light emitting chip 11 of the semiconductor light source 1 is turned on. Then, the light L1 radiated from the central portion of the light emitting chip 11 of the semiconductor light source 1 enters the lens member 2 from the first incident surface 21 of the lens member 2 as diffuse incident light L3. In particular, the light L1 is incident as diffused incident light L3 diffused particularly to the left and right by the diffusion unit 25. On the other hand, the light L2 emitted from the side of the light emitting chip 11 of the semiconductor light source 1 enters the lens member 2 from the second incident surface 22 of the lens member 2 as parallel incident light L4.

  Diffused incident light L3 incident on the lens member 2 from the first incident surface 21 is emitted to the outside as diffused emitted light from the entire exit surface 20 of the lens member 2.

  On the other hand, the parallel incident light L4 incident on the lens member 2 from the second incident surface 22 is reflected by the first reflecting surface 231 and the second reflecting surface 232 of the lens member 2 in parallel with the optical axis Z of the lens member 2. Total reflection as light L5. The parallel reflected light L5 is emitted to the outside as parallel emitted light that is perpendicular to the measurement screen and parallel to the optical axis Z of the lens member 2 from the left and right sides of the exit surface 20 of the lens member 2.

  As a result, the rectangular (long shape) emission surface 20 emits light in a substantially rectangular shape (long shape) and substantially uniformly as indicated by the dots in FIG.

(Description of the effect of Embodiment 1)
The vehicular lamp according to the first embodiment is configured and operated as described above, and the effects thereof will be described below.

  In the vehicular lamp according to the first embodiment, the first incident surface 21 diffuses the light L1 emitted from the central portion of the light-emitting chip 11 of the semiconductor light source 1 toward the emission surface 20 as diffuse incident light L3. The diffuse incident light L3 incident from the first incident surface 21 is diffused over the entire exit surface 20. As a result, as shown in FIG. 4, the emission surface 20 shines almost evenly over the entire surface, and a part of the emission surface 20 (for example, the location where the semiconductor light source 1 is located) shines with high brightness. Light can be prevented and appearance can be improved.

  In the vehicular lamp according to the first embodiment, the first incident surface 21 allows the first incident surface 21 to enter the light L1 emitted from the center of the light emitting chip 11 of the semiconductor light source 1 toward the emitting surface 20 side. In addition, a diffusing portion 25 for diffusing and injecting light L1 emitted from the central portion of the light emitting chip 11 of the semiconductor light source 1 toward the emitting surface 20 side is provided. As a result, the first incident surface 21 surely diffuses the light L1 emitted from the central portion of the light emitting chip 11 of the semiconductor-type light source 1 toward the emission surface 20 as diffused incident light L3 that is diffused particularly to the left and right. Since it can enter, a spotlight can be prevented reliably and appearance can be improved reliably.

  In the vehicular lamp according to the first embodiment, the basic first incident surface 210 of the first incident surface 21 has a hyperbola having the focal point F1 at or near the light emitting chip 11 of the semiconductor light source 1 as the main axis of the hyperbola (the lens member 2). Is a refracting surface of a rotating hyperboloid formed by rotating the optical axis Z) as a rotation axis. For this reason, the light L1 from the semiconductor-type light source 1 can be reliably incident on the lens member 2 from the basic first incident surface 210 as parallel incident light. Thereby, the parallel incident light incident on the lens member 2 from the basic first incident surface 210 is not emitted to the outside from the upper surface or the lower surface of the lens member 2 (exited outside). As a result, there is no case where the light L1 from the semiconductor light source 1 is lost, so that the light L1 from the semiconductor light source 1 can be used effectively, and the light emission of a long shape such as a rectangular shape of the emission surface 20 is achieved. In terms of surface, spotlight can be prevented more reliably, and the appearance can be further improved.

  In the vehicular lamp according to the first embodiment, since the first reflecting surface 231 and the second reflecting surface 232 are reflecting surfaces formed of a part of a rotating surface with the optical axis Z as the rotation axis, the second incident surface. The parallel incident light L4 incident on the lens member 2 from the surface 22 can be reliably reflected to the exit surface 20 side. As a result, a long light emitting surface such as a rectangular shape of the emission surface 20 can be obtained more reliably, and spotlight can be more reliably prevented, and the appearance can be improved more reliably.

(Description of Configuration of Embodiment 2)
FIG. 5 shows Embodiment 2 of the vehicular lamp according to the present invention. In the figure, the same reference numerals as those in FIGS. 1 to 4 denote the same components. Hereinafter, the configuration of the vehicular lamp in the second embodiment will be described.

  The vehicular lamp according to the second embodiment uses a single unit composed of one semiconductor-type light source 1 and one lens member 2 in a plurality of units, in this example, three units. That is, one unit (1, 2) is arranged horizontally, and the remaining two units (1, 2, 1, 2, 2) are arranged vertically, and the exit surface 20 is formed in an L shape as a whole. It is.

(Description of the effect of Embodiment 2)
Since the vehicular lamp in the second embodiment is configured as described above, it is possible to achieve substantially the same operational effects as the vehicular lamp in the first embodiment. Moreover, since the emission surface 20 has an L shape, the appearance is further improved.

(Description of examples other than Embodiments 1 and 2)
In the first and second embodiments, the tail lamp of the rear combination lamp will be described. However, in the present invention, a vehicle lamp other than the rear combination lamp tail lamp, for example, a rear combination lamp stop lamp, tail stop lamp, turn signal lamp, clearance lamp, or front combination lamp clearance lamp, turn signal. It can also be applied to lamps and daytime running lamps.

  In the first and second embodiments, the basic first incident surface 210 has a hyperbola having the focal point F1 at or near the light emitting chip 11 of the semiconductor light source 1 as the main axis of the hyperbola (the optical axis Z of the lens member 2). ) Is a refracting surface of a rotating hyperboloid that is rotated about the rotation axis. However, in the present invention, the first first incident surface may be another surface.

  Furthermore, in the first and second embodiments, the second incident surface 22 is a refracting surface formed of a part of a rotating surface having a straight line or a curved line as the rotation axis. However, in the present invention, the second incident surface is a refracting surface formed by extending a hyperbola focusing on the light emitting chip or the vicinity thereof while being inclined in the optical axis direction by the draft angle of the molding die of the lens member. It may be a refracting surface formed by extending a convex curve protruding toward the semiconductor-type light source in the optical axis direction, or another surface.

  Furthermore, in the first and second embodiments, the reflecting surfaces 231 and 232 are reflecting surfaces that are formed by a part of a rotating surface whose curved axis is the optical axis Z. However, in the present invention, the reflecting surface may be a reflecting surface made of a part of a rotating surface with the optical axis as the rotating axis, or a curved line or a straight line between the optical axis and the emitting surface. It may be a reflecting surface extending in a direction (vertical direction, plate thickness direction of the lens member) orthogonal to the extending direction (left-right direction).

  Furthermore, in the first and second embodiments, the two reflecting surfaces 231 and 232 are provided. However, in the present invention, one or three or more reflection surfaces may be used.

  Furthermore, in the second embodiment, a plurality of units (three units) are used for one semiconductor light source 1 and one lens member 2, and the emission surface 20 is formed in an L shape. . However, in the present invention, the shape of the exit surface may be any shape other than the L shape, such as a long linear shape or a V shape.

DESCRIPTION OF SYMBOLS 1 Semiconductor type light source 11 Light emitting chip 2 Lens member 20 Outgoing surface 21 1st incident surface 210 Basic 1st incident surface 22 2nd incident surface 231 1st reflective surface 232 2nd reflective surface 241 1st level | step difference surface 242 2nd level | step difference surface 25 Diffuser F1 Hyperbolic focus of first incident surface L1, L2 Light from semiconductor light source L3 Diffused incident light L4 Parallel incident light L5 Parallel reflected light X Up direction Z Optical axis of lens member

Claims (1)

A semiconductor-type light source and a lens member;
The lens member is
An exit surface extending in a direction perpendicular to the optical axis of the lens member;
A first incident surface that diffuses and injects light emitted from a central portion of the semiconductor-type light source toward the emission surface;
A second incident surface that is disposed on both sides of the first incident surface and on the extending direction side of the emission surface, and that makes light emitted from a side portion of the semiconductor-type light source incident as parallel light;
One or a plurality of reflections that are disposed on both sides of the second incident surface and on the extending direction side of the emission surface and reflect the parallel light incident from the second incident surface toward the emission surface side Surface,
I have a,
The first incident surface has a basic first incident surface on which light emitted from the central portion of the semiconductor-type light source is incident toward the emission surface, and the light emitted from the central portion of the semiconductor-type light source is A diffusing portion that diffuses and injects toward the exit surface side is provided, and is configured.
The basic first incident surface is a refracting surface of a rotating hyperboloid obtained by rotating a hyperbola with the semiconductor-type light source as a focal point with the main axis of the hyperbola as a rotation axis,
The diffusion unit is a cylindrical prism having a plurality of convex curved surfaces protruding in the vertical direction protruding toward the semiconductor light source.
A vehicular lamp characterized by the above.

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