JP6576719B2 - Vehicle lighting - Google Patents

Description

  The present invention relates to a vehicular lamp mounted on a vehicle.

Conventionally, in a vehicular lamp mounted on a vehicle, a plurality of light sources have been used when a relatively wide light emitting unit is to emit light.
For example, in the vehicular lamp described in Patent Document 1, a wide light-emitting portion is caused to emit light by increasing light source images from a plurality of light sources using a half mirror and a reflecting surface.

Japanese Patent No. 4323065

  However, the conventional vehicle lamp described above is not preferable in terms of the number of parts and the cost because a light source having a quantity corresponding to the width (or quantity) of the light emitting section is required.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a vehicular lamp that can emit a wide light-emitting portion with a single light source.

In order to achieve the above object, the invention according to claim 1 is characterized in that the LED having the characteristic that the light intensity decreases as the emission angle of the light with respect to the optical axis increases, and the LED in front of the LED. A vehicle lamp comprising a light guide lens disposed, a half mirror lens disposed in front of the light guide lens, and a reflector disposed between the light guide lens and the half mirror lens ,
The light guide lens is
A light incident part for causing the light emitted from the LED to enter the light guide lens;
A reflective surface for reflecting light from the light incident part to the side;
A plurality of other positions that are located on the sides of the reflecting surface and are provided at different positions in the front-rear direction and the distance from the reflecting surface, and individually reflect light from the reflecting surface forward. The reflective surface of
A plurality of emission surfaces provided in front of the plurality of other reflection surfaces corresponding to the plurality of other reflection surfaces;
I have a,
The reflective surface reflects the first light around the optical axis of the LED out of the light emitted from the LED toward the first other reflective surface of the plurality of other reflective surfaces. And reflecting the second light farther from the optical axis than the first light toward the second other reflecting surface of the plurality of other reflecting surfaces,
The plurality of emission surfaces project forward from the first emission surface, the first emission surface for emitting the first light reflected by the first other reflection surface forward, and the first A second emission surface for emitting the second light reflected by two other reflection surfaces forward;
The half mirror lens is
A part of the first light emitted from the first emission surface is disposed in front of the first emission surface while covering the light incident portion of the light guide lens and the front of the reflection surface. A half mirror that reflects the remainder of the first light obliquely backward while transmitting forward; and
The portion that is on the side of the half mirror portion, is located in front of the second exit surface of the light guide lens, and forwards the second light emitted from the second exit surface. A transmitting lamp part;
With
The reflector is disposed so as to cover the light incident part of the light guide lens and the front of the reflection surface, and reflects the first light reflected by the half mirror part toward the half mirror part. Let
The half mirror part and the reflector are formed in a flat plate shape that is substantially parallel to each other while being inclined with respect to the front-rear direction .

The invention according to claim 2 is the vehicle lamp according to claim 1,
The plurality of other reflecting surfaces are respectively provided on a plurality of different direction sides in front view with respect to the reflecting surface.

The invention according to claim 3 is the vehicle lamp according to claim 2,
The other reflecting surfaces provided on the plurality of direction sides are each formed in a substantially linear shape intersecting each other in a front view,
The LED, the light incident portion, and the reflection surface are provided on a substantially bisector of the other reflection surface provided on the plurality of direction sides in a front view.

Invention of Claim 4 is the vehicle lamp as described in any one of Claims 1-3,
Each of the first emission surface and the second emission surface is formed in an L shape in a front view .

Invention of Claim 5 is a vehicle lamp as described in any one of Claims 1-4 ,
The half mirror lens has a light blocking portion that does not transmit light at a portion connecting the half mirror portion and the lamp portion .

According to the present invention, after the light emitted from the LED as the light source enters the light guide lens from the light incident portion and is reflected to the side by the reflection surface, the light is emitted from the side of the reflection surface. Thus, the position in the front-rear direction and the distance from the reflecting surface are individually reflected forward by a plurality of other reflecting surfaces provided at different positions. Then, the light exits the light guide lens from a plurality of exit surfaces provided in front of the other reflective surfaces, and the plurality of exit surfaces emit light.
Therefore, it is possible to emit a wide light emitting portion composed of a plurality of emission surfaces with a single LED.

It is a front view of the vehicular lamp in an embodiment. It is a disassembled perspective view of the principal part of the vehicle lamp in embodiment. It is a disassembled side view of the principal part of the vehicle lamp in embodiment. It is sectional drawing of the vehicle lamp in the IV-IV line | wire of FIG. It is a figure for demonstrating the light emission aspect of the vehicle lamp in embodiment. It is a figure for demonstrating the modification of the vehicle lamp in embodiment.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

FIG. 1 is a front view of a vehicular lamp 1 according to the present embodiment, FIG. 2 and FIG. 3 are an exploded perspective view and an exploded side view of a main part of the vehicular lamp 1, and FIG. It is sectional drawing of the vehicle lamp 1 in the IV-IV line.
In the following description, “front”, “rear”, “left”, “right”, “upper”, and “lower” refer to the direction viewed from the vehicular lamp 1 unless otherwise specified. .

The vehicular lamp 1 is mounted on a vehicle (not shown). In the present embodiment, the vehicular lamp 1 is a tail lamp mounted on the rear portion of the vehicle.
Specifically, as shown in FIGS. 1 to 4, the vehicular lamp 1 includes a housing 2 whose front surface is open and an outer lens 3 that covers the front opening of the housing 2 (FIGS. 2 and 2). 3, the illustration of the housing 2 is omitted). Among these, the outer lens 3 has the half mirror part 30 and the lamp | ramp part 33 which light-emit toward the front so that it may mention later.

Inside the lamp chamber defined by the housing 2 and the outer lens 3, an LED (light emitting diode) 4, an inner lens 5, and a reflector 6 are accommodated.
Among these, the LED 4 is mounted on the front surface of the substrate 40 with its optical axis Ax facing forward, and is fixed to the housing 2 via the substrate 40. The LED 4 has a so-called Lambertian distribution directivity characteristic in which the light intensity decreases as the light emission angle with respect to the optical axis Ax becomes larger.

  The inner lens 5 is formed in a substantially triangular flat plate shape orthogonal to the front-rear direction, and is disposed in front of the LED 4. More specifically, the inner lens 5 includes, in a front view, a linear lower side that is substantially along the left-right direction, a linear right side that forms an L-shape that is connected to the lower side at an acute angle, and a left end of the lower side and an upper end of the right side. Are formed in a substantially triangular shape when viewed from the front.

A light incident portion that causes light from the LED 4 to enter the inner lens 5 at a portion of the rear surface of the inner lens 5 that is located on a substantially bisector of the lower side and the right side and near the upper left side in front view 51 is provided.
The light incident portion 51 is located in front of the LED 4 and is formed in an axially symmetrical shape that protrudes rearward with the optical axis Ax of the LED 4 as a rotational symmetry axis.
A convex (aspherical) first incident surface 511 that bulges rearward is provided at the center of the rear surface of the light incident portion 51. The first incident surface 511 is provided so that the LED 4 is positioned in the vicinity of the focal point thereof. The light emitted from the LED 4 and incident on the first incident surface 511 is converted into parallel light substantially along the optical axis Ax. The light is incident on the light entrance 51.
A portion of the light incident portion 51 outside the first incident surface 511 is formed in a substantially truncated cone shape protruding rearward, and an inner peripheral surface thereof is a second incident surface 512. The second incident surface 512 is a substantially cylindrical surface erected rearward from the peripheral edge of the first incident surface 511, and the light emitted from the LED 4 is directed to the side of the first incident surface 511. The light enters the light incident part 51.
The outer peripheral surface of the light incident portion 51 is a light incident portion reflecting surface 513. The light incident portion reflecting surface 513 is a substantially truncated cone surface inclined so as to spread outward from the front end (rear end) of the second incident surface 512 toward the front side, and from the second incident surface 512 to the light incident portion 51. The light incident on the inside is internally reflected (totally reflected) so as to substantially follow the optical axis Ax to be parallel light forward.
With such a configuration, the light incident portion 51 causes the light emitted forward from the LED 4 to enter the inner lens 5 while making the light parallel to the optical axis Ax (that is, substantially along the front-rear direction). .

A concave first reflecting surface 52 is provided in a portion of the front surface of the inner lens 5 positioned in front of the light incident portion 51.
The first reflecting surface 52 is formed in a conical surface shape having the optical axis Ax as a rotation axis, and its generating line forms an angle of approximately 45 ° with respect to the optical axis Ax. Therefore, the first reflecting surface 52 diffuses the light guided forward from the light incident portion 51 substantially along the optical axis Ax in a radial manner from the optical axis Ax in a front view in a plane substantially orthogonal to the optical axis Ax. So that it is internally reflected (totally reflected) to the side.

  The lower end portion and the right end portion of the rear surface of the inner lens 5 are each formed in a single stepped shape that is positioned forward stepwise as the end portion is approached. Among the stepped portions, two second reflecting surfaces 53 are formed on the inner side (side closer to the optical axis Ax) on the lower side and the right side, and the outer stepped portion (that is, the outer side surface) Two third reflecting surfaces 54 are formed on the lower side and the right side in the continuous portion. The second reflecting surface 53 and the third reflecting surface 54 are positions on the side of the first reflecting surface 52, as will be described later, and the distance between the position in the front-rear direction and the first reflecting surface 52 (optical axis Ax). And the distance to the side in the plane including) are different from each other.

Of these, the two second reflecting surfaces 53 are each formed in a straight line along the lower side and the right side of the inner lens 5 in a front view, and the two second reflecting surfaces 53 are L-shaped. Each of the second reflecting surfaces 53 is an inclined surface that forms an angle of 45 ° with respect to the front-rear direction in a cross section orthogonal to the extending direction (that is, the left-right direction or the oblique up-down direction) in the front view. Yes. Each of the second reflecting surfaces 53 is positioned on the side of the substantially half of the rear side of the first reflecting surface 52, and the light guided radially from the first reflecting surface 52 in a front view is internally forward. A plurality of lens cuts (not shown) for reflection (total reflection) are provided over the entire surface.
In the following description, of the two second reflecting surfaces 53, the one along the lower side of the inner lens 5 in front view is referred to as the “lower second reflecting surface 53”, and the one along the right side is also the same. This is referred to as “the right second reflecting surface 53”. The same applies to the two third reflecting surfaces 54, two first emission portions 55 (first emission surface 55a), and two second emission portions 56 (second emission surface 56a) described later.

  On the other hand, the two third reflecting surfaces 54 are respectively formed in a straight line along the lower side and the right side of the inner lens 5 in a front view, and two L-shaped ones are larger than the second reflecting surface 53. It has a shape. Each third reflecting surface 54 is an inclined surface that forms an angle of 45 ° with respect to the front-rear direction in a cross section orthogonal to the extending direction (that is, the left-right direction or the diagonally up-down direction) in the front view. Yes. Each of the third reflecting surfaces 54 is located on the side of the front half of the first reflecting surface 52 and internally reflects light guided radially from the first reflecting surface 52 in a front view. A plurality of lens cuts (not shown) for total reflection are provided over the entire surface.

  Two first emission portions 55 and two second emission portions 56 are provided on the front surface of the inner lens 5 in front of the two second reflection surfaces 53 and the two third reflection surfaces 54. ing.

  Among these, the two first emitting portions 55 are provided corresponding to the two second reflecting surfaces 53 while slightly projecting forward from the surrounding front portion. That is, the two first emitting portions 55 are each formed in a straight line along the lower side and the right side of the inner lens 5 in front view, and the two first emitting portions 55 are L-shaped. The front surface of each first emitting portion 55 is the first emitting surface 55a, and the light that is internally reflected by the corresponding second reflecting surface 53 and guided forward is forward from the first emitting surface 55a. Let it emit.

  On the other hand, the two second emitting portions 56 are provided corresponding to the two third reflecting surfaces 54 while protruding forward larger than the first emitting portion 55. That is, the two second emission portions 56 are formed in a straight line along the lower side and the right side of the inner lens 5 in a front view, respectively, and two are L-shaped larger than the first emission portion 55. It has a shape. The front surface of each of the second emission parts 56 is a second emission surface 56a, and the light that is internally reflected by the corresponding third reflection surface 54 and guided forward is forward from the second emission surface 56a. Let it emit.

The reflector 6 is formed in a rectangular plate shape that is slightly larger than the inner lens 5 in front view, and is disposed so as to cover the front of the inner lens 5.
Among the reflectors 6, the inner side of the two first emission parts 55 of the inner lens 5 in front view (that is, the upper side of the lower first emission part 55 and the left side of the right first emission part 55). ) Is a reflecting portion 60 formed in the shape of a truncated pyramid plate that protrudes forward as it goes to the upper left in front view.

  The reflection part 60 is a part that reflects light reflected back by a half mirror part of the outer lens 3 described later, and includes a lower reflection part 61 and a right reflection part 62. The lower reflecting portion 61 and the right reflecting portion 62 are connected on a substantially bisector of the two first emitting portions 55 in a front view.

Of these, the lower reflecting portion 61 has the lower edge located immediately above the lower first emitting portion 55 as a base end portion, and the extending direction of the first emitting portion 55 in the front view (that is, left and right). In the cross-section orthogonal to the direction, the plane orthogonal to the front-rear direction is formed in an inclined flat plate shape that is inclined forward by a predetermined inclination angle (acute angle).
The front surface of the lower reflecting portion 61 is a reflecting surface that reflects light reflected backward by the lower half mirror portion 31 of the outer lens 3 to be described later.

On the other hand, the right reflecting portion 62 has the right edge located immediately to the left of the right first emitting portion 55 as a base end portion, and the extending direction of the first emitting portion 55 in the front view (that is, the oblique vertical direction). In the cross-section orthogonal to the plane, the plane orthogonal to the front-rear direction is formed in an inclined flat plate shape that is inclined forward by a predetermined inclination angle (acute angle).
The front surface of the right reflecting portion 62 is a reflecting surface that reflects the light reflected rearward by the right half mirror portion 32 of the outer lens 3 to be described later.

  Further, a portion of the reflector 6 that is outside of the reflecting portion 60 (that is, below the lower first emitting portion 55 and on the right side of the right first emitting portion 55) is directed outward. Accordingly, it is formed in a staircase shape that is located forward in steps (two steps). Among the stepped portions, the lower stepped surface portion and the middle stepped surface portion are each provided with an L-shaped through hole 63 and a through-hole corresponding to the two first emitting portions 55 and the two second emitting portions 56. A hole 64 is formed. Two first emission portions 55 and two second emission portions 56 are individually inserted into the through holes 63 and the through holes 64, and these two first emission surfaces 55a and two second emission surfaces 56a. Is exposed in front of the reflector 6.

The outer lens 3 is formed in a rectangular plate shape that is slightly larger than the reflector 6 in a front view, and is disposed so as to cover the front of the reflector 6.
Among the outer lenses 3, the front side is inside of the two second emission parts 56 of the inner lens 5 (that is, the upper side of the lower second emission part 56 and the right side of the second emission part 56. The portion on the left side is a half mirror portion 30 formed in the shape of a truncated pyramid plate that protrudes forward as it goes to the upper left in front view.

  The half mirror part 30 is a part in which the transmittance and the reflectance are substantially equal, and a part of the light from the rear is transmitted forward while the rest is reflected rearward. The lower half mirror part 31 and the right half mirror Part 32. The lower half mirror portion 31 and the right half mirror portion 32 are connected on a straight line slightly lower in front view than the bisector of the two first emitting portions 55 in front view.

  Among these, the lower half mirror part 31 has the lower edge located immediately above the lower second emission part 56 as a base end part, and the extending direction of the second emission part 56 in a front view (that is, in other words, In the cross section orthogonal to the (left-right direction), it is formed in an inclined flat plate shape in which a plane orthogonal to the front-rear direction is inclined forward by a predetermined inclination angle (acute angle). This inclination angle is substantially the same as that of the lower reflection part 61 of the reflector 6, that is, the lower half mirror part 31 is provided substantially parallel to the lower reflection part 61.

  On the other hand, the right half mirror part 32 has the right edge located immediately to the left of the right second emission part 56 as a base end part, and the extending direction of the second emission part 56 in the front view (that is, the oblique vertical direction). ) In a cross-section orthogonal to the front and rear direction is formed in an inclined flat plate shape that is inclined forward by a predetermined inclination angle (acute angle). This inclination angle is substantially the same as that of the right reflecting portion 62 of the reflector 6, that is, the right half mirror portion 32 is provided substantially parallel to the right reflecting portion 62.

Further, a portion of the outer lens 3 outside the half mirror portion 30 and positioned in front of the two second emitting portions 56 of the inner lens 5 is a lamp portion 33. The lamp portion 33 is formed in an L shape that is wider in front view than the second emitting portion 56 while protruding forward from the periphery thereof, and its front surface is coated in red.
Further, in the outer lens 3, the standing wall portion connecting the half mirror portion 30 and the lamp portion 33 and the flat plate portion around the half mirror portion 30 and the lamp portion 33 (the portion indicated by a thick line in FIG. 4) are black resin. Is molded (or coated with a black paint) to form a light-shielding portion that does not transmit light.

Then, the light emission aspect of the vehicle lamp 1 is demonstrated.
As shown in FIG. 4, in the vehicle lamp 1 of the present embodiment, the light emitted forward from the LED 4 is first converted into parallel light substantially along the optical axis Ax by the light incident portion 51 of the inner lens 5. The light enters the inner lens 5.

  Of this incident light, light having a relatively high luminous intensity around the optical axis Ax is internally reflected radially to the front by the rear portion of the first reflecting surface 52, and the lower side and the right side thereof are reflected. The heading is internally reflected forward by the two second reflecting surfaces 53. And this light is radiate | emitted ahead from the two 1st output surfaces 55a located ahead of the two 2nd reflective surfaces 53. FIG.

A part of the light emitted from the two first emission surfaces 55a to the outside of the inner lens 5 is partially reflected by the half mirror part 30 (the lower half mirror part 31 and the right half mirror part 32) of the outer lens 3. The light is transmitted through 30 to the front of the lamp and the rest is reflected backward. At this time, the light reflected backward by the half mirror unit 30 is reflected toward the inner side (upper side or left side) according to the inclination angle of the half mirror unit 30.
The light reflected by the half mirror unit 30 is again reflected forward by the reflecting unit 60 of the reflector 6 toward the half mirror unit 30. Specifically, the light reflected by the lower half mirror part 31 is reflected forward by the lower reflecting part 61, and the light reflected by the right half mirror part 32 is reflected forward by the right reflecting part 62. At this time, the lower half mirror part 31 and the lower reflection part 61, and the right half mirror part 32 and the right reflection part 62 are substantially parallel to each other, and therefore from the lower reflection part 61 and the right reflection part 62, respectively. The reflected light is substantially along the front-rear direction (correctly, it is parallel to the light from the first emission surface 55a).
Similarly, the transmission / reflection at the half mirror part 30 and the reflection at the reflection part 60 are continuously repeated, so that the L-shape in front view by the light from the two first emission surfaces 55a of the inner lens 5 is obtained. A plurality of L-shaped virtual images, which are similarly L-shaped in front view, appear with a depth inside the real image (see FIG. 5).

On the other hand, of the light that has entered the inner lens 5 from the light incident portion 51, light having a relatively low luminous intensity that is farther from the optical axis Ax than the light that travels toward the second reflective surface 53 described above is the first reflective surface 52. Of the two are internally reflected in the radial direction when viewed from the front, and those that are directed downward and to the right are internally reflected forward by the two third reflecting surfaces 54. And this light is radiate | emitted ahead from the 2nd 2nd output surface 56a located ahead of the two 3rd reflective surfaces 54. FIG.
The light emitted from the two second emission surfaces 56a to the outside of the inner lens 5 is transmitted through the lamp part 33 of the outer lens 3 positioned in front of the inner lens 5, and is irradiated forward of the lamp.

  Thus, as shown in FIG. 5, in the outer lens 3, the lamp portion 33 emits light, and a real image and a plurality of virtual images thereof are formed by light from the two first emission surfaces 55 a on the inner side. Emits light in multiple L-shapes when viewed from the front.

As described above, according to the vehicular lamp 1 of the present embodiment, the light emitted from the LED 4 enters the inner lens 5 from the light incident portion 51 and is reflected laterally by the first reflecting surface 52. Later, the second reflecting surface 53 and the third reflecting surface which are provided on the sides of the first reflecting surface 52 at positions where the position in the front-rear direction and the distance from the first reflecting surface 52 are different from each other. Reflected individually by 54. Then, this light exits from the first exit surface 55a and the second exit surface 56a provided in front of the second reflecting surface 53 and the third reflecting surface 54 to the outside of the inner lens 5 and is then outer lens 3. , The portion of the outer lens 3 located in front of the first emission surface 55a and the second emission surface 56a emits light.
Therefore, the single LED 4 can emit light from a wide light emitting portion including the first emission surface 55a and the second emission surface 56a.

Further, the light from the LED 4 around the optical axis Ax is internally reflected by the rear portion of the first reflecting surface 52 and the second reflecting surface 53 of the inner lens 5 and emitted from the first emitting surface 55a. Transmission and reflection at the half mirror part 30 (lower half mirror part 31 and right half mirror part 32) of the outer lens 3 and reflection at the reflection part 60 (lower reflection part 61 and right reflection part 62) of the reflector 6 Is repeated continuously.
Thereby, a plurality of virtual images having the same shape appear with a depth inside the real image by the light from the first emission surface 55a of the inner lens 5.
Therefore, a multiple light image over a wide light emission range can be formed by light of high luminous intensity around the optical axis Ax emitted from the LED 4.

  The embodiments to which the present invention can be applied are not limited to the above-described embodiments, and can be appropriately changed without departing from the spirit of the present invention.

For example, in the above embodiment, the light internally reflected by the first reflection surface 52 of the inner lens 5 is directed to two other reflection surfaces, the second reflection surface 53 and the third reflection surface 54. The reflection surfaces of the first reflection surface 52 are provided on the sides of the first reflection surface 52 at positions where the position in the front-rear direction and the distance from the first reflection surface 52 are different from each other. 3 or more may be provided as long as they are individually reflected forward.
Specifically, as shown in FIG. 6A, for example, the inner lens 5 internally transmits light that has been made parallel light along the optical axis Ax through the light incident portion 51A to the side by the first reflecting surface 52A. After the reflection, the front and back direction and the distance from the first reflecting surface 52A are individually moved forward by the second reflecting surface 53A, the third reflecting surface 54A and the fourth reflecting surface 55A provided at different positions. It may be configured to internally reflect.

Further, in the inner lens 5, the light around the optical axis Ax of the light from the LED 4 is internally reflected by the rear portion of the first reflecting surface 52, and then is relatively rear and the first reflecting surface 52. Is reflected by the second reflecting surface 53 close to, while the light further away from the optical axis Ax is internally reflected by the front portion of the first reflecting surface 52 and then relatively front and first reflected. Although the light is internally reflected by the third reflecting surface 54 far from the surface 52, the light around the optical axis Ax may be internally reflected forward by the reflecting surface farther from the first reflecting surface 52.
Specifically, for example, as shown in FIG. 6B, the inner lens 5 internally transmits the parallel light along the optical axis Ax through the light incident portion 51B to the side by the first reflecting surface 52B. After reflection, the light that is closer to the optical axis Ax is internally reflected by any one of the second reflecting surface 53B, the third reflecting surface 54B, and the fourth reflecting surface 55B that is relatively rear and farther from the first reflecting surface 52B. You may be comprised so that it may make.

Further, the light internally reflected laterally by the first reflecting surface 52 of the inner lens 5 may be reflected forward by a reflecting plate separate from the inner lens 5.
Specifically, as shown in FIG. 6C, for example, the inner lens 5 converts the light that has been made parallel light along the optical axis Ax through the light incident portion 51C from the position in the front-rear direction and the optical axis Ax. A plurality of first reflecting surfaces 52C having different distances from each other are configured to be internally reflected to the side and emitted, and on the side, a plurality of reflecting plates 7C corresponding to the plurality of first reflecting surfaces 52C. May be provided.

  Further, the transmittance and the reflectance of the half mirror portion 30 of the outer lens 3 may not be equal, and the ratio between the transmittance and the reflectance may be adjusted according to a desired light emission mode (lighting feeling) or the like. Good.

  The vehicular lamp according to the present invention can be widely applied to vehicular lamps other than the tail lamp.

DESCRIPTION OF SYMBOLS 1 Vehicle lamp 3 Outer lens 30 Half mirror part 31 Lower half mirror part (half mirror lens)
32 Right half mirror (half mirror lens)
33 Lamp part 4 LED
Ax Optical axis 5 Inner lens (light guide lens)
51 Light-incident part 52 1st reflective surface (reflective surface)
53 Second reflecting surface (first other reflecting surface)
54 Third reflective surface (second other reflective surface)
55 1st light emission part 55a 1st light emission surface 56 2nd light emission part 56a 2nd light emission surface 6 Reflector 60 reflection part 61 lower side reflection part 62 right side reflection part

Claims (5)

An LED having a characteristic in which the intensity is low As the exit angle of light relative to the optical axis increases, and the light guide lens disposed in front of the LED, which is disposed in front of the light guide lens A vehicle lamp comprising a half mirror lens, and a reflector disposed between the light guide lens and the half mirror lens ,
The light guide lens is
A light incident part for causing the light emitted from the LED to enter the light guide lens;
A reflective surface for reflecting light from the light incident part to the side;
A plurality of other positions that are located on the sides of the reflecting surface and are provided at different positions in the front-rear direction and the distance from the reflecting surface, and individually reflect light from the reflecting surface forward. The reflective surface of
A plurality of emission surfaces provided in front of the plurality of other reflection surfaces corresponding to the plurality of other reflection surfaces;
I have a,
The reflective surface reflects the first light around the optical axis of the LED out of the light emitted from the LED toward the first other reflective surface of the plurality of other reflective surfaces. And reflecting the second light farther from the optical axis than the first light toward the second other reflecting surface of the plurality of other reflecting surfaces,
The plurality of emission surfaces project forward from the first emission surface, the first emission surface for emitting the first light reflected by the first other reflection surface forward, and the first A second emission surface for emitting the second light reflected by two other reflection surfaces forward;
The half mirror lens is
A part of the first light emitted from the first emission surface is disposed in front of the first emission surface while covering the light incident portion of the light guide lens and the front of the reflection surface. A half mirror that reflects the remainder of the first light obliquely backward while transmitting forward; and
The portion that is on the side of the half mirror portion, is located in front of the second exit surface of the light guide lens, and forwards the second light emitted from the second exit surface. A transmitting lamp part;
With
The reflector is disposed so as to cover the light incident part of the light guide lens and the front of the reflection surface, and reflects the first light reflected by the half mirror part toward the half mirror part. Let
The vehicular lamp, wherein the half mirror part and the reflector are formed in a flat plate shape that is substantially parallel to each other while being inclined with respect to the front-rear direction .   2. The vehicular lamp according to claim 1, wherein the plurality of other reflection surfaces are respectively provided on a plurality of different direction sides in front view with respect to the reflection surface. The other reflecting surfaces provided on the plurality of direction sides are each formed in a substantially linear shape intersecting each other in a front view,
The LED, the light incident portion, and the reflection surface are provided on a substantially bisector of the other reflection surface provided on the plurality of direction sides in a front view. The vehicle lamp as described in 2. 4. The vehicular lamp according to claim 1, wherein each of the first emission surface and the second emission surface is formed in an L shape when viewed from the front . The said half mirror lens has a light-shielding part which does not permeate | transmit light in the part which connects the said half mirror part and the said lamp | ramp part, The Claim 1 characterized by the above-mentioned. Vehicle lamp.