JP2008204914A - Vehicular lamp fixture - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To solve the problem that in a conventional vehicular lamp fixture, light from a semiconductor light source is not effectively used. <P>SOLUTION: In the vehicular lamp fixture, a planar reflecting face 7 is arranged to be crossed to a lens optical axis Z1-Z1 of a projection lens 6 between the projection lens 6 and its lens focus FL1, a light-shielding member 8 blocking direct incident light L6 from a semiconductor light source 4 off from the projection lens 6 is arranged between the semiconductor light source 4 and the projection lens 6, and a translucent hole 22 made to transmit light L3 from the semiconductor light source 4 to a predetermined direction is fitted to the light-shielding member 8. As a result, the light L3 from the semiconductor light source 4 can be effectively used as a light distribution pattern P5 for overhead signature. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a projector-type vehicular lamp that uses a semiconductor-type light source such as an LED as a light source. In particular, the present invention is a vertical projector lamp capable of reducing the depth dimension and the height dimension, and the light other than the predetermined light distribution pattern projected from the projection lens, that is, the light distribution is controlled. The present invention relates to a vehicular lamp that can prevent light from being emitted from a projection lens and that can effectively utilize (utilize) light from a semiconductor-type light source.

  Conventionally, this type of vehicle lamp is known (for example, Patent Document 1, Patent Document 2, and Patent Document 3). Hereinafter, this conventional vehicle lamp will be described. This conventional vehicle lamp is provided in a reflector having an elliptical reflecting surface, a semiconductor-type light source such as an LED arranged so that a light emitting portion is positioned at the first focal point of the elliptical reflecting surface, and the reflector. And a projection lens that projects a predetermined light distribution pattern in a predetermined direction.

  Hereinafter, the operation of this conventional vehicle lamp will be described. A semiconductor-type light source such as an LED is turned on to emit light. Then, light from a semiconductor-type light source such as an LED is reflected by the elliptical reflecting surface and projected (irradiated, emitted, and emitted) in a predetermined direction as a predetermined light distribution pattern from the projection lens.

  However, in this conventional vehicular lamp, the optical axis of the elliptical reflecting surface and the optical axis of the projection lens are horizontal, and the semiconductor-type light source such as an LED, the reflector, and the projection lens are arranged in the horizontal direction. , The horizontal depth dimension increases. For this reason, this conventional vehicular lamp cannot meet the need to reduce the depth dimension.

  Conventionally, a vehicular lamp that uses a planar reflecting surface to shorten the front-rear length (decreases the depth dimension) has been conventionally used (for example, Patent Document 4). However, this conventional vehicular lamp uses a discharge bulb as a light source, and does not use a semiconductor-type light source such as an LED. In addition, in this conventional vehicular lamp, the optical axis of the projection lens extends in the vehicle longitudinal direction (horizontal direction), the optical axis of the reflector intersects the optical axis of the projection lens, and the reflected light from the reflector is planar. The reflection surface reflects the light toward the projection lens. For this reason, this conventional vehicular lamp is similar to the vehicular lamp (Patent Documents 1 to 3) because the discharge bulb, the reflector, the projection lens, and the planar reflection surface are arranged in the vehicle front-rear direction. In addition, the depth dimension in the horizontal direction becomes large, and the need for reducing the depth dimension cannot be met.

  Further, a vehicular lamp that has a compact module (small depth dimension) by intersecting the optical axis of the first reflecting mirror and the optical axis of the second reflecting mirror is conventionally known (for example, Patent Document 5). . However, this conventional vehicular lamp is not a projector type that does not use a projection lens. In addition, since this conventional vehicular lamp crosses the optical axis of the first reflecting mirror and the optical axis of the second reflecting mirror, if the horizontal depth dimension is reduced, the vertical height dimension is reduced. Can not meet the need to reduce the depth and height dimensions.

  And the said conventional vehicle lamp (patent documents 1-5) is not considered about the means which prevents that lights other than the predetermined light distribution pattern projected from a projection lens are radiate | emitted from a projection lens. For this reason, in the conventional vehicular lamp, light other than the predetermined light distribution pattern projected from the projection lens, that is, light that is not subjected to light distribution control may be emitted from the projection lens. In addition, the conventional vehicular lamp described above does not consider means for effectively using light from a semiconductor light source. For this reason, the conventional vehicular lamp described above does not effectively use light from a semiconductor-type light source.

JP 2006-107955 A JP 2005-302328 A JP 2004-31224 A JP 2005-228715 A JP 2004-207235 A

  The problems to be solved by the present invention are that the conventional vehicular lamp cannot respond to the need to reduce the depth dimension in the horizontal direction and the height dimension in the vertical direction, and is projected from the projection lens. In other words, light other than a predetermined light distribution pattern that is not subjected to light distribution control may be emitted from the projection lens, and that light from a semiconductor-type light source is not effectively used. is there.

  According to the present invention (the invention according to claim 1), a plane reflection surface is disposed between the projection lens and the lens focal point of the projection lens so as to intersect the lens optical axis of the projection lens, and direct irradiation from a semiconductor light source. A light-shielding member that blocks light from entering the projection lens is disposed between the semiconductor-type light source and the projection lens, and a light-transmitting hole that allows light from the semiconductor-type light source to pass in a predetermined direction is provided in the light-shielding member. And

  Further, according to the present invention (the invention according to claim 2), an additional reflection surface for reflecting light from a semiconductor-type light source as a light distribution pattern for an overhead sign is provided on a surface on which a through hole is formed. Features.

  Furthermore, the present invention (the invention according to claim 3) is characterized in that the additional reflection surface is an elliptical reflection surface.

  In the vehicle lamp of the present invention (the invention according to claim 1), a plane reflecting surface is arranged so as to intersect the lens optical axis of the projection lens between the projection lens and the lens focal point of the projection lens. . As a result, the vehicular lamp of the present invention (the invention according to claim 1) exists as a pseudo lens focus at a position where the lens focus of the projection lens is symmetrical with respect to the plane reflection surface by the plane reflection surface. The lens focal point is located at the second focal point of the elliptical reflecting surface, and the lens optical axis of the horizontal projection lens exists as a vertical pseudo lens optical axis perpendicular to the lens optical axis by the plane reflecting surface, and the pseudo lens The optical axis coincides with the optical axis of the elliptical reflecting surface. Thus, in the vehicular lamp of the present invention (the invention according to claim 1), the projection lens and the plane reflecting surface are arranged in the horizontal direction, and the projection lens, the plane reflecting surface, the reflector, the semiconductor light source and the shade are arranged. Can be arranged vertically. Therefore, the vehicular lamp according to the present invention (the invention according to claim 1) can reduce the horizontal depth dimension and the vertical height dimension, and meets the need to reduce the depth dimension and the height dimension. can do.

  Moreover, in the vehicular lamp according to the present invention (the invention according to claim 1), a light shielding member for blocking direct light from the semiconductor light source from entering the projection lens is disposed between the semiconductor light source and the projection lens. It is possible to prevent light other than the predetermined light distribution pattern projected from the projection lens, that is, light that is not subjected to light distribution control, from being emitted from the projection lens, thereby contributing to traffic safety. it can. In addition, the vehicular lamp according to the present invention (the invention according to claim 1) is conversely moved from the projection lens to the elliptical reflection surface side on the semiconductor type light source side by a light shielding member disposed between the semiconductor type light source and the projection lens. External light to be incident can be blocked. As a result, the vehicular lamp of the present invention (the invention according to claim 1) is a semiconductor even if the external light is reflected by the ellipsoidal reflecting surface and is emitted from the projection lens to the outside and the semiconductor light source is not lit. Pseudo lighting that appears as if the mold light source is lit can be prevented.

  In addition, the vehicular lamp of the present invention (the invention according to claim 1) is provided with a through hole for allowing light from the semiconductor-type light source to pass in a predetermined direction in the light shielding member. The light from the mold light source can be used effectively.

  Further, the vehicle lamp of the present invention (the invention according to claim 2) effectively uses light from a semiconductor light source as a light distribution pattern for an overhead sign by an additional reflecting surface provided on a surface forming a through hole. Can be used.

  Furthermore, in the vehicular lamp of the present invention (the invention according to claim 3), the additional reflection surface is an elliptical reflection surface, so that the light distribution pattern for the overhead sign can be evenly distributed and the visibility is excellent. A light distribution pattern for overhead signs is obtained.

  Embodiments of a vehicular lamp according to the present invention will be described below in detail with reference to the drawings. Note that the present invention is not limited to the embodiments. In this specification, “front, rear, upper, lower, left, right” is “front, rear, upper, lower, left, right” of the vehicle when the vehicle lamp is mounted on the vehicle. In the drawing, reference sign “VU-VD” indicates vertical lines on the upper and lower sides of the screen. Reference sign “HL-HR” indicates horizontal lines on the left and right of the screen. In this specification and claims, “horizontal” means “horizontal or substantially horizontal”, and “vertical” means “vertical or almost vertical”.

  Hereinafter, the configuration of the vehicular lamp according to this embodiment will be described. In the figure, reference numeral 1 denotes a vehicular lamp according to this embodiment, and this example is, for example, an automotive headlamp. The vehicular lamp 1 includes a front first reflector (main reflector, light-shielding member / reflector) 2, a rear second reflector (sub-reflector / shade / reflector) 3, a semiconductor light source 4, and a shade 5. , A projection lens (convex lens, condenser lens) 6, a plane reflecting surface 7, a heat sink member (not shown), a light shielding member 8, a lamp housing and a lamp lens (for example, a through lens) of an automotive headlamp not shown. And outer lens).

  The first reflector 2, the second reflector 3, the semiconductor light source 4, the shade 5, the projection lens 6, the planar reflecting surface 7, the heat sink member, and the light shielding member 8 constitute a lamp unit. As shown in the figure, the lamp unit is a vertical projector type and has a unit structure. One or a plurality of the lamp units are arranged, for example, via an optical axis adjusting mechanism in a lamp chamber defined by a lamp housing and a lamp lens of an automotive headlamp. In some cases, a lamp unit other than the lamp unit is arranged in the lamp chamber to constitute the vehicular lamp according to the present invention.

  The first reflector 2 and the second reflector 3 are composed of a light-impermeable resin member and the like, and are also used as holding members such as a casing, a housing, and a holder. Further, the first reflector 2 and the second reflector 3 are divided into two parts in the front-rear direction along the vertical optical axis Z2-Z2 of the first reflecting surface 9 described later. The first reflector 2, the second reflector 3, and the heat sink member are integrally fixed by a fixing member (not shown) (for example, a bolt nut, a screw, a caulking, a clip, or a screw in this example). . Note that the first reflector 2 and the second reflector 3 may be integrally formed.

  As shown in FIG. 2, the first reflector 2 has an upper half opened in a semicircular shape on the lower side, a rear portion on the lower half opened, and a front portion on the lower half opened. Blocked. The closed portion of the front half of the lower half of the first reflector 2 has a convex shape that swells outward (from the rear side to the front side). A first reflecting surface 9 is provided on the concave inner surface of the closed portion of the front half of the lower half of the first reflector 2 by applying aluminum vapor deposition or silver coating. At the four corners of the first reflector 2, screw holes 10 (or through holes through which the screws of the fixing member pass) are respectively provided.

  The first reflection surface 9 is an elliptical reflection surface, that is, an ellipse or a reflection surface based on an ellipse. The ellipsoidal reflecting surface of the first reflecting surface 9 is a reflecting surface such as a spheroid surface or a free-form surface (NURBS surface) based on an ellipse (the vertical cross section in FIGS. 1 and 5 to 8 is an ellipse surface). And a reflecting surface whose horizontal cross section (not shown) forms a paraboloid or a deformed paraboloid). For this reason, the first reflecting surface 9 has a first focal point F1 and a second focal point or a focal line on a horizontal section (that is, both ends are located on the upper side and the center is located on the lower side when viewed from the front (front)). Curved focal line) F2. The “second focal point or focal line F2 on the horizontal section” will be simply referred to as “second focal point F2”. In this specification and claims, the second focal point of the elliptical reflecting surface and the second focal point of the first reflecting surface refer to the “second focal point or focal line F2 on the horizontal section”.

  As shown in FIG. 3, the second reflector 3 comprises a vertical plate portion, the upper portion of the plate portion opens in a semicircular shape on the upper side, and the lower portion of the plate portion has a recess. 11 is provided. The front surface of the plate portion of the second reflector 3 is subjected to aluminum deposition, silver coating, or the like, and a second reflecting surface that is flat or substantially flat along the optical axis Z2-Z2 of the first reflecting surface 9. 12 is provided. The second reflecting surface 12 is provided between the second focal point F <b> 2 (that is, the second focal point F <b> 2 or the vicinity thereof) of the first reflecting surface 9 and the semiconductor light source 4. Screw holes (or through-holes through which the screws of the fixing member pass) 13 into which the screws of the fixing member are screwed are provided at the four corners of the plate portion of the second reflector 3, respectively.

  As the semiconductor-type light source 4, for example, a self-luminous semiconductor-type light source (LED in this embodiment) such as LED or EL (organic EL) is used. The semiconductor-type light source 4 covers a substrate 14, a light emitter (not shown) of a light source chip (semiconductor chip) having a small rectangular shape (square shape) fixed to one surface of the substrate 14, and the light emitter. The light transmissive member 15 includes a connector or a harness (not shown) connected to a power source (not shown). The semiconductor light source 4 is fixed to the bottom of the concave portion 11 of the second reflector 3. The semiconductor light source 4 may be fixed to the heat sink member by providing an opening in the recess 11 of the second reflector 3. The light emitter (light emitting portion) of the semiconductor-type light source 4 is located at the first focal point F1 (that is, the first focal point or the vicinity thereof) of the first reflecting surface 9.

  The shade 5 is provided integrally with the second reflector 3. That is, the shade 5 is also used as the plate portion of the second reflector 3. As a result, the shade 5 is provided with the second reflecting surface 12. The second reflector 3 and the shade 5 may be provided separately and fixed integrally by a fixing means. The shade 5 is disposed between the second focal point F2 (that is, the second focal point F2 or the vicinity thereof) of the first reflecting surface 9 and the semiconductor-type light source 4. In the shade 5, the edge 16 has a second focal point (second focal line) of the first reflective surface 9 at a portion of the second reflective point 9 of the first reflective surface 9 (that is, the second focal point F2 or its vicinity). ) It is provided along F2.

  The shade 5 is a predetermined light distribution pattern that cuts off a part of the reflected light L4 emitted from the semiconductor-type light source 4 and reflected by the first reflecting surface 9, and has a cut-off line CL with the remaining reflected light. P, for example, a light distribution pattern for passing and a light distribution pattern for highways are formed (see FIG. 4). The edge 16 of the shade 5 forms a cut-off line CL and an elbow point E of the predetermined light distribution pattern P (see FIG. 4). Further, the second reflecting surface 12 reflects the reflected light L4 cut off by the shade 5 as a reflected light L9 in a predetermined direction, that is, on the plane reflecting surface 7 side, and thereby a predetermined auxiliary light distribution pattern (not shown). Z).

  The projection lens 6 includes an edge of a semicircular opening that forms a lower semicircle of the first reflector 2 and an edge of a semicircular opening that forms an upper semicircle of the second reflector 3. It is attached. The projection lens 6 may be directly attached to the first reflector 2 and the second reflector 3 as in this example, or may be attached using a ring member (not shown) or the like. . The projection lens 6 is an aspheric lens convex lens. The front side (external side) of the projection lens 6 is a convex aspheric surface having a large curvature (the curvature radius is small), while the rear side (the plane reflecting surface 7 side) of the projection lens 6 is a small curvature. Convex aspherical surface (large curvature radius). By using such a projection lens 6, the focal length of the projection lens 6 is reduced, and accordingly, the horizontal lens optical axes Z1-Z1 of the projection lens 6 of the vehicular lamp 1 according to this embodiment. The direction dimension becomes compact. The rear side of the projection lens 6 may be a flat aspheric surface (plane).

  The projection lens 6 includes a lens focal point FL1 that is a front focal point (focal point on the plane reflecting surface 7 side) located at a position of a front focus (front focal length) FF from the projection lens 6, and a back focal point from the projection lens 6. A rear focal point (external focal point) located at a position of (rear focal distance), and a horizontal lens optical axis Z1-Z1 connecting the lens focal point FL1 of the front focal point and the rear focal point. The optical axis Z2-Z2 of the vertical first reflecting surface 9 and the lens optical axis Z1-Z1 of the horizontal projection lens 6 are orthogonal to each other. The lens focal point FL1 of the projection lens 6 is a meridional image plane that is a focal plane on the object space side. In addition, since the light from the semiconductor light source 4 does not have high heat, a resin lens can be used as the projection lens 6. The projection lens 6 uses acrylic in this example. The projection lens 6 projects forward the predetermined light distribution pattern P having the cut-off line CL reflected by the planar reflecting surface 7 and auxiliary light distribution patterns P1, P2, P3, P4, and P5 described later ( (See FIG. 4). The auxiliary light distribution pattern (not shown) is also projected forward from the planar reflecting surface 7 through the projection lens 6.

  The flat reflecting surface 7 has a flat plate shape, and is provided integrally between the semicircular opening on the upper side of the second reflector 3 and the edge 16 of the shade 5. The second reflector 3 and the shade 5 and the planar reflecting surface 7 may be provided separately and fixed integrally by a fixing means. The surface of the planar reflecting surface 7 is subjected to aluminum vapor deposition or silver coating. The plane reflecting surface 7 is disposed between the projection lens 6 and the lens focal point FL1 of the projection lens 6 so as to intersect the lens optical axis Z1-Z1 at 45 ° or substantially 45 °. The plane reflecting surface 7 reflects the predetermined light distribution pattern P having the cut-off line CL and the auxiliary light distribution patterns P1, P2, P3, P4, P5 and the auxiliary light distribution pattern (not shown) to the projection lens 6 side. It is something to be made.

  As shown in FIGS. 5 to 7, the lens focal point FL <b> 1 of the projection lens 6 exists as a pseudo lens focal point FL <b> 2 at a position symmetric with respect to the planar reflecting surface 7 due to the planar reflecting surface 7. The pseudo lens focal point FL2 is located at the second focal point F2 of the first reflecting surface 9 (that is, the second focal point F2 or the vicinity thereof). Further, the lens optical axis Z1-Z1 of the horizontal projection lens 6 is perpendicular to the horizontal lens optical axis Z1-Z1 by the plane reflecting surface 7, as shown in FIGS. The pseudo lens optical axis Z3-Z3 exists. The vertical pseudo lens optical axis Z3-Z3 coincides with or substantially coincides with the optical axis Z2-Z2 of the first reflecting surface 9.

  As a result, as shown in FIG. 5, when the parallel light L1 of the extraneous light enters the projection lens 6 from the outside, passes through the projection lens 6 and exits from the projection lens 6, the lens focal point of the projection lens 6 is obtained. Trying to focus on FL1. The emitted light from the projection lens 6 to be focused is reflected by the planar reflecting surface 7, and the reflected light L2 is focused on the pseudo lens focal point FL2, that is, the second focal point F2 of the first reflecting surface 9. . As shown in FIGS. 5 to 7, the horizontal lens optical axis Z1-Z1 is a vertical pseudo lens optical axis Z3-Z3 bent at a right angle by the plane reflecting surface 7, that is, the first optical axis Z1-Z3. It becomes the optical axis Z2-Z2 of the reflecting surface 9.

  The heat sink member is formed by integrally providing a plurality of fins on the rear surface (back surface, back surface) of the flat plate with an appropriate interval in the vertical direction. The heat sink member is provided vertically or vertically. The front surface (front surface, front surface) of the flat plate of the heat sink member is attached to the rear surface (back surface, back surface) of the plate portion of the second reflector 3. The heat sink member radiates heat generated in the semiconductor light source 4 to the outside.

  The light shielding member 8 is provided integrally with the first reflector 2 and is made of a light impermeable member. The light shielding member 8 and the first reflector 2 may be provided separately and fixed integrally by a fixing means. As shown in FIGS. 1 and 5 to 7, the light shielding member 8 is disposed between the semiconductor light source 4 and the projection lens 6. That is, the light shielding member 8 has a direct light L6 from the semiconductor-type light source 4, a reflected light L7 from the second reflective surface 12, and a second additional reflection described later, from the projection lens 6 side to the planar reflective surface 7 side. The reflected light L8 from the surface 23 (25 to 27) is blocked from entering the projection lens 6, and the reflected light L4 from the first reflecting surface 9 and the reflected light L9 from the second reflecting surface 12 and Reflected lights L12, L14, and L16 from the second additional reflecting surface 23 (25 to 27) can be incident on the planar reflecting surface 7, and reflected light L10 from the planar reflecting surface 7 is incident on the projection lens 6. It is provided in a range where it can be incident. That is, one end of the light shielding member 8 is fixed to the base of the edge of the semicircular opening of the first reflector 2 and the front blocking portion of the lower half, and the other end is the shade 5 and the The second reflection surface 12 extends to the second focal point F2 of the first reflection surface 9 or to the plane reflection surface 7 side. The light shielding member 8 may have a flat plate shape, a curved plate shape, or other shapes.

  The light shielding member 8 is provided with first additional reflection surfaces 17, 18, 19, 20, and 21 that reflect the light L <b> 3 from the semiconductor-type light source 4 in a predetermined direction. As shown in FIG. 1, the first additional reflection surface includes a first portion 17, a second portion 18, a third portion 19, a fourth portion 20, and a fifth portion 21. . The light guide member 8 is provided with a through hole 22. The through hole 22 is provided between the fourth portion 20 and the fifth portion 21.

  The first portion 17 of the first additional reflection surface is composed of an elliptical reflection surface similar to the first reflection surface 9, and a first focus F11 located at or near the first focus F1 of the first reflection surface 9. And a second focal point 21 positioned above the first focal point F11. The second portion 18 of the first additional reflection surface is formed of an elliptical reflection surface similar to the first reflection surface 9, and the first focus located at or near the first focus F1 of the first reflection surface 9. F12 and a second focal point 22 positioned above the second focal point F21 of the first portion 17. Further, the third portion 19 of the first additional reflection surface is formed of an elliptical reflection surface similar to the first reflection surface 9, and the first focus located at or near the first focus F1 of the first reflection surface 9. F13 and a second focal point 23 located at or near the second focal point F22 of the second portion 18. Furthermore, the fourth portion 20 of the first additional reflection surface is composed of an elliptical reflection surface similar to the first reflection surface 9, and is a first focus F1 of the first reflection surface 9 or the first focus F1 located in the vicinity thereof. A focal point F14; and a second focal point 24 positioned above the second focal point F22 of the second portion 18 and the second focal point F23 of the third portion 19. Furthermore, the fifth portion 21 of the first additional reflection surface is formed of an elliptical reflection surface similar to the first reflection surface 9, and is a first focus F1 of the first reflection surface 9 or a first focus located in the vicinity thereof. A focal point F15, and a second focal point 25 located obliquely forward and above the first focal point with the light shielding member 8 interposed therebetween.

  The shade 5 includes the second reflective surface 12 that reflects the reflected light L4 cut off by the shade 5 as reflected light L9 in a predetermined direction, and the second additional reflective surface 23 (25 to 27). , Are provided respectively. The second additional reflection surface 23 (25 to 27) is located in the middle of the second reflection surface 12. The shade 5 is provided with the through holes 24. The through holes 24 are formed between the planar reflecting surface 7 and the upper second reflecting surface 12 and between the upper second reflecting surface 12 and the second additional reflecting surface 23 (25 to 27). Is provided. The second additional reflection surface 23 (25 to 27) is inclined from the front side to the rear side from the lower side to the upper side.

  As shown in FIG. 3, the second additional reflection surface includes a first portion 25, a second portion 26, and a third portion 27. The first portion 25 of the second additional reflecting surface 23 reflects the reflected light L11 from the first portion 17 of the first additional reflecting surface as a reflected light L12 in a predetermined direction, that is, on the plane reflecting surface 7 side. is there. The second portion 26 of the second additional reflective surface 23 reflects the reflected light L13 from the second portion 18 of the first additional reflective surface as a reflected light L14 in a predetermined direction, that is, on the plane reflective surface 7 side. In addition, the reflected light L15 from the third portion 19 of the first additional reflective surface is reflected as a reflected light L16 in a predetermined direction, that is, on the plane reflective surface 7 side. Further, the third portion 27 of the second additional reflection surface 23 allows the reflected light L17 from the fourth portion 20 of the first additional reflection surface to pass through a predetermined direction, that is, the through hole 24 as reflected light L18. The light is reflected on the plane reflecting surface 7 side. The first portion 25, the second portion 26, and the third portion 27 of the second additional reflection surface are formed of an elliptical reflection surface, another curved reflection surface, or a flat reflection surface.

  The reflected light L11 from the first portion 17 of the first additional reflective surface, and the reflected light L12 from the first portion 25 of the second additional reflective surface 23, as a predetermined first auxiliary light distribution pattern P1, The light is reflected by the plane reflecting surface 7 toward the projection lens 6, passes through the projection lens 6, and is projected forward. The reflected light L13 from the second portion 18 of the first additional reflective surface and the reflected light L14 from the second portion 26 of the second additional reflective surface 23 is a predetermined second auxiliary light distribution pattern P2. As described above, the light is reflected by the plane reflecting surface 7 toward the projection lens 6, passes through the projection lens 6, and is projected forward. Further, the reflected light L15 from the third portion 19 of the first additional reflective surface and the reflected light L16 from the second portion 26 of the second additional reflective surface 23 is a predetermined third auxiliary light distribution pattern P3. As described above, the light is reflected by the plane reflecting surface 7 toward the projection lens 6, passes through the projection lens 6, and is projected forward. Furthermore, the reflected light L17 from the fourth portion 20 of the first additional reflective surface, and the reflected light L18 from the third portion 27 of the second additional reflective surface 23 is a predetermined fourth auxiliary light distribution pattern. As P4, the light is reflected by the plane reflecting surface 7 toward the projection lens 6 and is transmitted through the projection lens 6 and projected forward.

  The fifth portion 21 of the first additional reflection surface reflects the light L3 from the semiconductor-type light source 4 as reflected light L20 in a predetermined direction, that is, toward the projection lens 6 in the through hole 22. The reflected light L20 from the fifth portion 21 of the first additional reflection surface is transmitted through the projection lens 6 and projected forward as a predetermined fifth auxiliary light distribution pattern P5.

  The vehicular lamp 1 according to this embodiment is configured as described above, and the operation thereof will be described below.

  First, the light emitter of the semiconductor light source 4 of the vehicular lamp 1 is turned on. Then, as shown in FIG. 6, light L <b> 3 is emitted from the light emitter of the semiconductor light source 4. A part of the light L3 is reflected by the first reflecting surface 9, and the reflected light L4 is focused on the second focal point F2 and the pseudo lens focal point FL2 of the first reflecting surface 9. A part of the reflected light L4 focused on the second focus F2 and the pseudo lens focus FL2 is cut off by the shade 5. The reflected light L4 cut off by the shade 5 is reflected by the second reflecting surface 12 integral with the shade 5, and reflected as a reflected light L9 in a predetermined direction, that is, on the plane reflecting surface 7 side. The reflected light L9 forms a predetermined auxiliary light distribution pattern (not shown). On the other hand, a predetermined light distribution pattern P having a cutoff line CL is formed by the remaining reflected light L4.

  The reflected light L9 that forms the predetermined auxiliary light distribution pattern and the reflected light L4 that forms the predetermined light distribution pattern P having the cut-off line CL are reflected by the planar reflection surface 7 as reflected light L10, as if it were a projection lens 6 is transmitted through the projection lens 6 and synthesized as light emitted from the lens focal point FL1, and is projected in front of an automobile (vehicle) as a predetermined light distribution pattern (light L5 projected from the projection lens 6). Illuminate.

  Further, as shown in FIG. 1, a part of the light L3 from the light emitter of the semiconductor-type light source 4 is reflected as reflected light L11 by the first portion 17 of the first additional reflection surface, and the second additional reflection surface. The first portion 25 is reflected as reflected light L12 to form a predetermined first auxiliary light distribution pattern P1. The reflected light L12 that forms this predetermined first auxiliary light distribution pattern P1 is reflected by the planar reflecting surface 7, passes through the projection lens 6, and is projected forward.

  Similarly, as shown in FIG. 1, a part of the light L3 from the light emitter of the semiconductor-type light source 4 is reflected as reflected light L13 by the second portion 18 of the first additional reflection surface, and the second additional reflection surface. 12 is reflected as reflected light L14 by the second portion 26 to form a predetermined second auxiliary light distribution pattern P2. The reflected light L14 that forms the predetermined second auxiliary light distribution pattern P2 is reflected by the planar reflecting surface 7, passes through the projection lens 6, and is projected forward.

  Similarly, as shown in FIG. 1, a part of the light L3 from the light emitter of the semiconductor-type light source 4 is reflected as reflected light L15 by the third portion 19 of the first additional reflection surface, and the second additional reflection surface. 12 is reflected as reflected light L16 by the second portion 26 to form a predetermined third auxiliary light distribution pattern P3. The reflected light L16 that forms the predetermined third auxiliary light distribution pattern P3 is reflected by the planar reflecting surface 7, passes through the projection lens 6, and is projected forward.

  Similarly, as shown in FIG. 1, a part of the light L3 from the light emitter of the semiconductor-type light source 4 is reflected as reflected light L17 by the fourth portion 20 of the first additional reflection surface, and the second additional reflection surface. The reflected light L18 is reflected by the 12 third portions 27 to form a predetermined fourth auxiliary light distribution pattern P4. The reflected light L18 forming the predetermined fourth auxiliary light distribution pattern P4 passes through the through holes 24 of the shade 5 and is reflected by the plane reflecting surface 7, and is transmitted through the projection lens 6 as reflected light L19 and projected forward. Is done.

  Similarly, as shown in FIGS. 1 and 8, a part of the light L3 from the light emitter of the semiconductor-type light source 4 passes through the through hole 22 of the light shielding member 8 and is in the fifth portion 21 of the first additional reflection surface. Reflected as reflected light L20, a predetermined fifth auxiliary light distribution pattern P5 is formed. The reflected light L20 that forms the predetermined fifth auxiliary light distribution pattern P5 passes through the projection lens 6 and is projected forward.

  In this way, as shown in FIG. 4, the predetermined light distribution pattern P having the cut-off line CL, the first auxiliary light distribution pattern P1, the second auxiliary light distribution pattern P2, and the third auxiliary distribution. The light pattern P3, the fourth auxiliary light distribution pattern P4, the fifth auxiliary light distribution pattern P5, and the auxiliary light distribution pattern (not shown) are transmitted through the projection lens 6 and projected in front of the automobile (vehicle). To light the road surface. As shown in FIG. 4, the first auxiliary light distribution pattern P1, the second auxiliary light distribution pattern P2, and the third auxiliary light distribution pattern P3 are high positions positioned below the cut-off line CL at the center of the predetermined light distribution pattern P. A luminous intensity distribution pattern is formed. Further, as shown in FIG. 4, the fourth auxiliary light distribution pattern P4 and the fifth auxiliary light distribution pattern P5 are overhead sign light distribution patterns located above the cut-off line CL of the predetermined light distribution pattern P. Form.

  On the other hand, as shown in FIG. 7, of the light L <b> 3 from the semiconductor-type light source 4, the direct light L <b> 6 that is about to enter the projection lens 6 is blocked by the light shielding member 8 from entering the projection lens 6. Here, when there is no light blocking member 8 and direct light L21 (reflected light indicated by a broken line) from the semiconductor-type light source 4, that is, direct light L21 not subjected to light distribution control is incident on the projection lens 6, the front of the projection lens 6 May slip off diagonally, resulting in glare. However, the vehicular lamp 1 of this embodiment can prevent the glare by the light shielding member 8. In FIG. 7, the direct light L21 passing through the projection lens 6 is shown in a straight line, but actually refracted when entering and exiting the projection lens 6. Further, of the light L3 from the semiconductor light source 4, there is also light (not shown) that is directly incident on the planar reflecting surface 7 without being blocked by the light blocking member 8. This light is reflected on the plane reflecting surface 7 in a predetermined direction, that is, on the projection lens 6 side, and is transmitted through the projection lens 6 and projected forward as light subjected to light distribution control.

  Similarly, of the reflected light from the second reflecting surface 12, the reflected light L 7 that is to be directly incident on the projection lens 6 is blocked from entering the projection lens 6 by the light shielding member 8, as shown in FIG. Here, when there is no light shielding member 8 and reflected light L22 (reflected light indicated by a broken line) from the second reflecting surface 12, that is, reflected light L22 not subjected to light distribution control, enters the projection lens 6, the projection lens 6 There are cases where glare occurs due to slanting upward. However, the vehicular lamp 1 of this embodiment can prevent the glare by the light shielding member 8. In FIG. 7, the reflected light L22 passing through the projection lens 6 is shown in a straight line, but actually refracted when entering and exiting the projection lens 6.

  Similarly, of the reflected light from the second additional reflecting surface 23, the reflected light L8 that is about to enter the projection lens 6 is blocked by the light shielding member 8 from entering the projection lens 6 as shown in FIG. Here, when there is no light shielding member 8 and reflected light L23 (reflected light indicated by a broken line) from the second additional reflecting surface 23, that is, reflected light L23 not subjected to light distribution control, is incident on the projection lens 6. There is a possibility that glare will occur. However, the vehicular lamp 1 of this embodiment can prevent the glare by the light shielding member 8. In FIG. 7, the reflected light L23 passing through the projection lens 6 is shown in a straight line, but actually refracted when entering and exiting the projection lens 6.

  Here, when heat is generated in the semiconductor light source 4 due to the light emission of the light emitter of the semiconductor light source 4, the heat is transmitted to the heat sink member and dissipated to the outside air (external) via the heat sink member. The Further, when the diplomacy tries to enter the first reflecting surface 9 and the second reflecting surface 12 on the semiconductor-type light source 4 side, the first additional reflecting surfaces 17 to 21 and the second additional reflecting surface 23 side from the projection lens 6, the light shielding member. 8 is shielded. Thereby, pseudo lighting of the semiconductor-type light source 4 can be prevented.

  The vehicular lamp 1 according to this embodiment is configured and operated as described above, and the effects thereof will be described below.

  The vehicular lamp 1 according to this embodiment is provided with a through hole 22 in the light shielding member 8 through which the light L3 from the semiconductor light source 4 passes in a predetermined direction. The light L3 from 4 can be used effectively. Moreover, the vehicular lamp 1 according to this embodiment distributes the light L3 from the semiconductor-type light source 4 for the overhead sign by the fifth portion 21 of the first additional reflecting surface provided on the surface where the through hole 22 is formed. It can be effectively used as the light pattern P5. Moreover, in the vehicular lamp 1 according to this embodiment, the fifth portion 21 of the first additional reflection surface is formed of an elliptical reflection surface, so that the light distribution pattern P5 for the overhead sign can be uniformly distributed. The light distribution pattern P5 for overhead sign with excellent visibility is obtained.

  Since the vehicular lamp 1 according to this embodiment is provided with the first additional reflection surfaces 17 to 21 as additional reflection surfaces for reflecting the light L3 from the semiconductor light source 4 in a predetermined direction on the light shielding member 8, this first The additional reflection surfaces 17 to 21 can effectively utilize the light L3 from the semiconductor-type light source 4. That is, the vehicular lamp 1 according to this embodiment uses the first additional reflection surfaces 17 to 21 to transmit the light L3 from the semiconductor light source 4 to the auxiliary light distribution patterns P1 to P5 with respect to the predetermined light distribution pattern P. Can be used effectively as In particular, the vehicular lamp 1 according to this embodiment has the first additional reflection surface of the first additional reflection surface by the first portion 25, the second portion 26, and the third portion 27 of the second additional reflection surface 23 provided in the shade 5. The reflected lights L11, L13, L15, and L17 from the first part 17, the second part 18, the third part 19, and the fourth part 20 can be reflected in a predetermined direction as reflected lights L12, L14, L16, and L18. Thereby, the vehicular lamp 1 according to this embodiment can use the light from the semiconductor light source 4 more effectively and more reliably.

  Further, the vehicular lamp 1 according to this embodiment includes the direct light L6 from the semiconductor light source 4, the reflected light L7 from the second reflecting surface 12, and the reflected light L8 from the second additional reflecting surface 23 (25 to 27). Is arranged between the semiconductor light source 4 and the projection lens 6. For this reason, the vehicular lamp 1 according to this embodiment includes light L21, L22, L23 other than the predetermined light distribution pattern P projected from the projection lens 6, that is, light L21, L22, which is not subjected to light distribution control. It is possible to prevent L23 from being emitted from the projection lens 6. Thereby, the vehicular lamp 1 according to this embodiment can contribute to traffic safety.

  Furthermore, the vehicular lamp 1 according to this embodiment has a plane reflecting surface 7 intersecting the lens optical axis Z1-Z1 of the projection lens 6 between the projection lens 6 and the lens focal point FL1 of the projection lens 6. Is to be placed. As a result, in the vehicular lamp 1 according to this embodiment, the lens focal point FL1 of the projection lens 6 exists as a pseudo lens focal point FL2 at a position symmetric with respect to the planar reflecting surface 7 by the planar reflecting surface 7, and the pseudo lens focal point FL2 The lens focal point FL2 is positioned at the second focal point F2 of the first reflecting surface 9 which is an elliptical reflecting surface, and the lens optical axis Z1-Z1 of the horizontal projection lens 6 is horizontal by the plane reflecting surface 7 and the horizontal lens optical axis Z1-Z1. Is present as a vertical pseudo lens optical axis Z3-Z3 orthogonal to the optical axis Z2-Z2 of the first reflecting surface 9 of the elliptical reflecting surface (that is, the vertical pseudo lens optical axis Z3-Z3). Match or nearly match). Thereby, the vehicular lamp 1 according to this embodiment has the projection lens 6 and the plane reflecting surface 7 arranged in the horizontal direction, and the projection lens 6 and the plane reflecting surface 7, the first reflector 2 and the second reflector. 3 and the semiconductor-type light source 4 and the shade 5 can be arranged in the vertical direction. Therefore, the vehicular lamp 1 according to this embodiment can reduce the depth dimension W in the horizontal direction and the height dimension H in the vertical direction, and meets the need to reduce the depth dimension W and the height dimension H. be able to. A depth dimension W shown in FIG. 6 is a dimension from the front end of the projection lens 6 to the rear end of the second reflector 3. If the heat sink member is fixed to the rear surface of the second reflector 3, the depth dimension is the dimension from the front end of the projection lens 6 to the rear end of the heat sink member.

  In particular, since the vehicular lamp 1 according to this embodiment is configured to block the direct light L6 that is not directly distributed from the semiconductor-type light source 4 and incident on the projection lens 6 by the light blocking member 8, the height dimension H is reduced. It can be further reduced. That is, in the absence of the light shielding member 8, in order to prevent the direct light L6 not subjected to light distribution control from directly entering the projection lens 6 from the semiconductor type light source 4, the semiconductor type light source 4 and the projection lens 6 are arranged in the vertical direction. (The height dimension H is increased). On the other hand, since the vehicular lamp 1 according to this embodiment is provided with the light shielding member 8, the direct light L6 that is not light-distributed by the light shielding member 8 is directly incident on the projection lens 6 from the semiconductor-type light source 4. Can be prevented, and the height dimension H can be reduced.

  Furthermore, in the vehicular lamp 1 according to this embodiment, external light (not shown) is transmitted from the projection lens 6 to the semiconductor light source 4 side by the light shielding member 8 disposed between the semiconductor light source 4 and the projection lens 6. It is possible to shield the light incident on the first reflecting surface 9, the second reflecting surface 12, the first additional reflecting surfaces 17 to 21 and the second additional reflecting surface 23 (25 to 27). As a result, in the vehicular lamp 1 according to this embodiment, external light is transmitted from the first reflecting surface 9, the second reflecting surface 12, the first additional reflecting surfaces 17 to 21, and the second additional reflecting surface 23 (25 to 27). Even if the semiconductor-type light source 4 is reflected and emitted again from the projection lens 6 and the semiconductor-type light source 4 is not lit, pseudo-lighting that appears as if the semiconductor-type light source 4 is lit can be prevented.

  Furthermore, in the vehicular lamp 1 according to this embodiment, since the light shielding member 8 is provided in a predetermined range from the projection lens 6 side to the plane reflecting surface 7 side, direct light L6 from the semiconductor-type light source 4 and The reflected light L7 from the second reflecting surface 12 and the reflected light L8 from the second additional reflecting surface 23 (25 to 27) are blocked from entering the projection lens 6, and the reflected light L4 from the first reflecting surface 9 is used. The reflected light L9 from the second reflecting surface 12 and the reflected lights L12, L14, L16 from the second additional reflecting surface 23 (25 to 27) can be incident on the planar reflecting surface 7 and from the planar reflecting surface 7. The reflected lights L10 and L19 can enter the projection lens 6. For this reason, the vehicular lamp 1 according to this embodiment includes the direct light L6 from the semiconductor light source 4, the reflected light L7 from the second reflecting surface 12, and the reflection from the second additional reflecting surface 23 (25 to 27). A portion of the light L8 that is blocked from entering the projection lens 6 can be used effectively, and a lamp with good light utilization efficiency can be provided. Moreover, the vehicular lamp 1 according to this embodiment includes the reflected light L4 from the first reflecting surface 9, the reflected light L9 from the second reflecting surface 12, and the reflected light from the second additional reflecting surface 23 (25 to 27). L12, L14, and L16 can be reliably incident on the planar reflecting surface 7 without being blocked by the light shielding member 8, and the projection lenses 6 can be made without reflecting the reflected lights L10 and L19 from the planar reflecting surface 7 with the light shielding member 8. Can be reliably incident. Thereby, the vehicular lamp 1 according to this embodiment can provide a lamp that can be reliably used without losing the light subjected to the light distribution control.

  Furthermore, the vehicular lamp 1 according to this embodiment is provided from the semiconductor-type light source 4 by the shade 5 disposed between the second focal point F2 of the first reflection surface 9 of the elliptical reflection surface and the semiconductor-type light source 4. A part of the reflected light L4 radiated and reflected by the first reflecting surface 9 can be cut off, and a predetermined light distribution pattern P having a cut-off line CL can be formed by the remaining reflected light L4. In addition, the vehicular lamp 1 according to this embodiment has the second reflecting surface 12 provided on the shade 5 and the reflected light L4 cut off by the shade 5 as the reflected light L9 in a predetermined direction, that is, the planar reflecting surface 7. Therefore, the light utilization efficiency is good. In addition, the vehicular lamp 1 according to this embodiment emits light (not shown) directly incident on the flat reflecting surface 7 without being blocked by the light blocking member 8 out of the light from the semiconductor-type light source 4. 7, the light is reflected in a predetermined direction, that is, on the projection lens 6 side, is transmitted through the projection lens 6 as light subjected to light distribution control, and is projected forward. Therefore, out of the light from the semiconductor-type light source 4, the first reflection surface 9. And a part of light which does not enter into the 1st additional reflective surfaces 17-21 can be used effectively, and the utilization efficiency of light is good.

  Furthermore, in the vehicular lamp 1 according to this embodiment, the first additional reflection surfaces 17 to 21 include five reflection surfaces, and the second additional reflection surface 23 (25 to 27) includes three reflection surfaces. Therefore, it is easy to design the five auxiliary light distribution patterns P1 to P2 into a desired auxiliary light distribution pattern such as a high-luminance band light distribution pattern or an overhead sign light distribution pattern.

  Furthermore, in the vehicular lamp 1 according to this embodiment, the flat reflecting surface 7 and the shade 5 have an integral structure, and the first reflector 2 and the light shielding member 8 have an integral structure, thereby reducing the number of parts. The manufacturing cost can be reduced accordingly. Moreover, in the vehicular lamp 1 according to this embodiment, the flat reflecting surface 7 that forms the pseudo focal point FL2 of the projection lens 6 and the shade 5 that forms the cut-off line CL of the predetermined light distribution pattern P form an integral structure. The accuracy of the predetermined light distribution pattern P having the cut-off line CL can be improved. In addition, the vehicular lamp 1 according to this embodiment includes a first reflector 2 having a first reflecting surface 9 and a light shielding member 8 that causes reflected light L4 from the first reflecting surface 9 to be incident on the planar reflecting surface 7. Therefore, the reflected light L4 from the first reflecting surface 9 can be reliably incident on the planar reflecting surface 7, and the light subjected to light distribution control can be used reliably without loss.

  Furthermore, in the vehicular lamp 1 according to this embodiment, the semiconductor light source 4 is attached to the recess 11 of the second reflector 3 so that the plane of the substrate 14 of the semiconductor light source 4 is vertical. A heat sink member is provided vertically on the rear surface of the second reflector 3. As a result, in the vehicular lamp 1 according to this embodiment, the semiconductor-type light source 4 and the heat sink member are arranged horizontally (front and rear), so that the heat generated in the semiconductor-type light source 4 is transmitted through the vertically placed heat sink member. It can diverge efficiently. Moreover, in the vehicular lamp 1 according to this embodiment, the first reflector 2, the second reflector 3, the semiconductor light source 4, the shade 5, the projection lens 6, the plane reflecting surface 7, and the heat sink member are arranged horizontally (front and rear). Therefore, the upper part of the heat sink member can be opened to the outside air. Thereby, the vehicular lamp 1 according to this embodiment can dissipate the heat of the semiconductor light source 4 from the bottom to the outside more efficiently to the outside air.

  The vehicular lamp 1 according to this embodiment is provided with the fourth portion 20 of the first additional reflection surface that reflects the light L3 from the semiconductor-type light source 4 toward the shade 5, and the first additional reflection surface. Since the through hole 24 through which the reflected light L17 from the fourth portion 20 of the light shielding member 8 passes to the flat reflecting surface 7 side is provided in the shade 5, the fourth portion 20 of the first additional reflecting surface of the light shielding member 8 and the transmission of the shade 5 are provided. Through the hole 24, the light L3 from the semiconductor light source 4 can be effectively utilized. Moreover, the vehicular lamp 1 according to this embodiment has the second additional reflecting surface 23 that reflects the reflected light L17 from the fourth portion 20 of the first additional reflecting surface to the planar reflecting surface 7 through the through hole 24. Since the third portion 27 is provided in the shade 5, the light L3 from the semiconductor-type light source 4 is distributed for the overhead sign by the fourth portion 20 of the first additional reflection surface and the third portion 27 of the second additional reflection surface 23. It can be effectively used as the light pattern P4. Moreover, in the vehicular lamp 1 according to this embodiment, since the fourth portion 20 of the first additional reflection surface is formed of an elliptical reflection surface, the light distribution pattern P4 for the overhead sign can be evenly distributed, The light distribution pattern P4 for overhead signs with excellent visibility is obtained.

  In addition, in the said Example, the headlamp for motor vehicles is demonstrated as a vehicle lamp. However, in the present invention, the vehicle lamp may be a lamp other than the automotive headlamp, for example, a rear combination lamp tail lamp, brake lamp, tail brake lamp, backup lamp, or the like.

  Moreover, in the said Example, it has the 1st reflective surface 9, the 2nd reflective surface 12, the 1st additional reflective surfaces 17-21, 29, and the 2nd additional reflective surfaces 23 (25-27), 28, 30. An example will be described. However, in this invention, it may have an elliptical reflection surface (first reflection surface 9) provided on the reflector and an additional reflection surface provided on the light shielding member. That is, in this invention, it is not necessary to provide the 2nd reflective surface 12 and the 2nd additional reflective surface 23 (25-27), 28, 30. FIG. In this case, since the reflected light from the second reflecting surface and the reflected light from the second additional reflecting surface are not generated, the light shielding member reflects the reflected light from the second reflecting surface and the reflected from the second additional reflecting surface. There is no need to block light.

  Furthermore, in the said Example, the predetermined light distribution pattern P and auxiliary light distribution pattern P1-P7 which have the cut-off line CL are irradiated. However, in the present invention, the predetermined light distribution pattern includes a light distribution pattern having no cut-off line, for example, a fog lamp light distribution pattern, a wet road light distribution pattern, a detime lamp light distribution pattern, and a tail lamp distribution. It may be a light pattern, a brake lamp light distribution pattern, a tail / brake lamp light distribution pattern, a backup lamp light distribution pattern, or the like.

  Furthermore, in the said Example, the 1st reflector 2 and the 2nd reflector 3 are formed separately, and it fixes integrally with a heat sink member by a fixing member. However, in the present invention, the first reflector 2 and the second reflector 3 may be integrally formed.

  Furthermore, in the above-described embodiment, the projection lens 6 and the first reflector 2 and the second reflector 3 are separately formed and attached to each other. However, in the present invention, the projection lens 6 and the first reflector 2 and the second reflector 3 may be integrally formed. In this case, a ring member, an attachment part, etc. are unnecessary.

  Furthermore, in the above-described embodiment, the light shielding member 8 projects the direct light L6 from the semiconductor-type light source 4 directly incident on the projection lens 6 and the reflected light L7 from the second reflecting surface 12 directly incident on the projection lens 6. It blocks the reflected light L8 from the second additional reflecting surfaces 23 (25 to 27), 28, and 30 that are directly incident on the lens 6. However, in the present invention, at least the direct light L6 from the semiconductor light source 4 that is directly incident on the projection lens 6 may be blocked.

  Furthermore, in the said Example, the 1st additional reflective surfaces 17-21, 29 consist of the same elliptical reflective surface as the 1st reflective surface 9. As shown in FIG. However, in the present invention, the first additional reflection surface may be formed of another curved surface or a flat surface.

  Furthermore, in the above-described embodiment, the fifth additional portion 21 of the first additional reflecting surface that reflects the light L3 from the semiconductor light source 4 as the light distribution pattern P5 for the overhead sign is formed on the surface on which the through hole 22 is formed. It is provided. However, in the present invention, the light shielding member 8 may be provided with the through hole 22 that allows the light L4 from the semiconductor-type light source 4 to pass in a predetermined direction without providing the reflecting surface on the surface on which the through hole 22 is formed.

It is optical path explanatory drawing of the light from the semiconductor type light source which shows the Example of the vehicle lamp concerning this invention. Similarly, it is a perspective view which shows the 1st reflector of the component of the principal part. Similarly, it is a perspective view which shows the 2nd reflector of the component of the principal part. Similarly, it is explanatory drawing which shows the light distribution pattern obtained with the vehicle lamp of this Example. Similarly, it is explanatory drawing which shows the reflective action principle of a plane reflective surface. Similarly, it is explanatory drawing which shows the reflective action principle of a 1st reflective surface and a 2nd reflective surface. Similarly, it is explanatory drawing which shows the light-shielding action principle of a light-shielding member. Similarly, it is explanatory drawing which shows the state in which the light from a semiconductor type light source passes through a through-hole, and is reflected as an auxiliary light distribution pattern in the 5th part of the 1st additional reflective surface.

Explanation of symbols

1, 1A, 1B Vehicle lamp 2 First reflector (main reflector, light shielding member / reflector)
3 Second reflector (sub-reflector, shade / reflector)
4 Semiconductor light source (LED)
DESCRIPTION OF SYMBOLS 5 Shade 6 Projection lens 7 Planar reflective surface 8 Light-shielding member 9 1st reflective surface 10 Screw hole (or through-hole)
11 Concave portion 12 Second reflecting surface 13 Screw hole (or through hole)
14 substrate 15 light transmitting member 16 edge 17 first portion of first additional reflection obtaining surface 18 second portion of first additional reflection obtaining surface 19 third portion of first additional reflection obtaining surface 20 first portion of first additional reflection obtaining surface 20 4 part 21 5th part of 1st additional reflection acquisition surface 22 Through-hole 23 2nd additional reflection surface 24 Through-hole 25 1st part of 2nd additional reflection acquisition surface 26 2nd part of 2nd additional reflection acquisition surface 27 2nd The third portion of the additional reflection surface 28 The common reflection surface of the second additional reflection surface 29 The first additional reflection surface 30 The second additional reflection surface 31 The second focal point of the first reflection surface and the apex of the semiconductor light source Connecting line F1 First focal point of first reflective surface F2 Second focal point of first reflective surface FL1 Lens focal point FL2 Pseudo lens focal point Z1-Z1 Lens optical axis Z2-Z2 Optical axis of first reflective surface Z3-Z3 Pseudo lens optical axis FF Front focus W Horizontal depth dimension Height dimension in the vertical direction L1 Parallel light of extraneous light L2 Reflected light from planar reflection surface of extraneous light L3 Light from semiconductor light source L4 Reflected light from first reflection surface L5 Projected light from projection lens L6 To projection lens Direct light from a semiconductor-type light source to be directly incident L7 Reflected light from the second reflecting surface to be directly incident on the projection lens L8 Reflected light from the second additional reflecting surface to be directly incident on the projection lens L9 Planar reflection Reflected light from the second reflecting surface incident on the surface L10, L19, L26, L29 Reflected light from the flat reflecting surface L11, L13, L15, L17, L20, L24, L27 Reflected light from the first additional reflecting surface L12, L14, L16, L18, L25, L28 Reflected light from the second additional reflecting surface L21, L22, L23 Light having no light distribution control P Cut-off line Predetermined light distribution pattern CL Cut-off line E Elbow point P1 to P7 Auxiliary light distribution pattern

Claims (3)

In a projector-type vehicular lamp that uses a semiconductor-type light source as a light source,
A reflector having an elliptical reflecting surface;
The semiconductor-type light source disposed so that a light-emitting portion is positioned at the first focal point of the elliptical reflecting surface;
A projection lens for projecting a predetermined light distribution pattern in a predetermined direction with the lens optical axis being horizontal;
A plane reflecting surface disposed between the projection lens and the lens focal point of the projection lens so as to intersect the lens optical axis and reflecting a predetermined light distribution pattern toward the projection lens;
A light shielding member that is disposed between the semiconductor-type light source and the projection lens, and that blocks direct light from the semiconductor-type light source from entering the projection lens;
With
The lens focal point exists as a pseudo lens focal point at a position that is symmetric with respect to the planar reflecting surface by the planar reflecting surface;
The pseudo lens focus is located at the second focus of the elliptical reflecting surface;
The lens optical axis exists as a pseudo lens optical axis orthogonal to the lens optical axis by the plane reflecting surface,
The pseudo lens optical axis coincides with the optical axis of the elliptical reflecting surface,
The light shielding member is provided with a through hole through which light from the semiconductor-type light source passes in a predetermined direction.
A vehicular lamp characterized by the above. The surface that forms the through hole is provided with an additional reflection surface that reflects light from the semiconductor-type light source as a light distribution pattern for an overhead sign,
The vehicular lamp according to claim 1. The additional reflective surface is an elliptical reflective surface.
The vehicular lamp according to claim 2.

Images