JP2007103192A - Vehicular lighting fixture - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a vehicular lighting fixture using a self-light-emission semiconductor type light source such as an LED, an EL (organic EL) or the like, excellent in heat radiation efficiency. <P>SOLUTION: The vehicular lighting fixture has a semiconductor type light source 6, a heat sink part 7 on which the semiconductor type light source 6 is directly mounted in a slanted state, a lower heat radiation part 15 arranged on a lower face of a stand part 14 of the heat sink part 7, and a rear heat radiation part 16 arranged on a back face of the stand part 14 of the heat sink part 7. As a result, since the lower heat radiation part 15 and the rear heat radiation part 16 can be arranged in an ideal form at a neighboring area of the semiconductor type light source 6 in a heat convection direction, heat generated at the semiconductor type light source 6 can be effectively radiated from the lower heat radiation part 15 and the rear heat radiation part 16. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a vehicular lamp that uses a semiconductor-type light source, for example, a self-luminous semiconductor-type light source such as an LED or an EL (organic EL). In particular, the present invention relates to a vehicular lamp that has an excellent heat dissipation effect.

  This type of vehicular lamp is conventionally known (for example, Patent Document 1). Hereinafter, a conventional vehicle lamp will be described. A conventional vehicular lamp is obtained by fixing a substrate holding an LED to a heat radiating fin via an insulating heat conductive sheet. In the conventional vehicular lamp, the LED is fixed to the heat radiating fin via the substrate and the insulating heat conductive sheet, so that the heat generated in the LED can be efficiently radiated by the heat radiating fin. For this reason, conventional vehicular lamps can use high-wattage LEDs that output a high luminous flux.

  However, the conventional vehicular lamp is simply the LED fixed to the heat radiating fin via the substrate and the insulating heat conductive sheet, and no means for further improving the heat radiating effect is provided. For this reason, the conventional vehicle lamp cannot further improve the heat dissipation effect.

JP 2002-93206 A

  The problem to be solved by the present invention is that the conventional vehicle lamp cannot further improve the heat dissipation effect.

  The present invention (the invention according to claim 1) is provided on a semiconductor-type light source, a heat sink portion directly attached in a state where the semiconductor-type light source is inclined, and a lower surface of the heat sink portion to which the semiconductor-type light source is attached. And a rear heat dissipating part provided on the rear surface (rear surface) to which the semiconductor light source of the heat sink part is attached.

  The present invention (the invention according to claim 2) is characterized in that a thick portion is integrally provided at a connecting portion between the lower heat radiating portion and the rear heat radiating portion.

  In the present invention (the invention according to claim 3), a reflector is provided in the heat sink, and a first reflecting surface based on an ellipse that reflects light from a semiconductor light source, and reflection from the first reflecting surface. A second reflecting surface based on a parabolic surface that reflects light is provided in each reflector, and a rear heat radiating portion is disposed in a space between the first reflecting surface and the second reflecting surface, It is characterized by that.

  In the present invention (the invention according to claim 4), a reflector is provided in the heat sink part, a first reflecting surface based on an ellipse that reflects light from a semiconductor light source, and reflection from the first reflecting surface. A second reflecting surface based on a parabolic surface that reflects light is provided on the reflector, and an auxiliary heat radiating portion is integrally provided on the back side of the second reflecting surface. .

  Since the vehicular lamp according to the present invention (the invention according to claim 1) is mounted directly on the heat sink portion in a state where the semiconductor light source is inclined, the lower surface and the rear surface of the mounting portion of the semiconductor light source of the heat sink portion A lower heat radiating portion and a rear heat radiating portion that match the heat convection direction can be provided respectively. For this reason, in the vehicular lamp of the present invention (the invention according to claim 1), the lower heat radiating portion and the rear heat radiating portion can be arranged in an ideal shape in the vicinity of the semiconductor light source and in the heat convection direction. The heat generated in the semiconductor-type light source can be efficiently radiated by the lower heat radiating portion and the rear heat radiating portion, and the heat radiation effect can be further improved as compared with the conventional vehicle lamp. Moreover, the vehicular lamp of the present invention (the invention according to claim 1) is provided with a rear heat radiating portion on the rear surface of the mounting portion of the semiconductor light source of the heat sink portion in a shape along an ideal shape in the heat convection direction. As a result, the rear heat radiating portion is less noticeable and the appearance can be improved accordingly.

  Further, in the vehicular lamp according to the present invention (the invention according to claim 2), the thick portion is integrally provided at the connecting portion between the lower heat radiating portion and the rear heat radiating portion. The heat conductivity from the part to the lower heat radiating part and the rear heat radiating part is good, and the heat radiation effect can be further improved.

  Furthermore, in the vehicular lamp according to the present invention (the invention according to claim 3), the rear heat radiating portion is located in the space between the first reflecting surface and the second reflecting surface of the reflector. The air flow is good and the heat dissipation effect is even better. And since the reflector for the heat sink is provided in the vehicle lamp of this invention (invention concerning Claim 3), the whole lamp can be made compact.

  Furthermore, in the vehicular lamp according to the present invention (the invention according to claim 4), since the auxiliary heat radiating portion is integrally provided on the back side of the second reflecting surface of the reflector, the heat radiation effect is further improved, and the parts The number of points can be reduced, and the manufacturing cost can be reduced.

  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 and / or claims, “up”, “down”, “front (front)”, “rear (back)”, “left”, and “right” are used for the vehicle according to the present invention. “Up”, “Down”, “Front (front)”, “Rear (back)”, “Left”, “Right” when the lamp is mounted on the vehicle.

  Hereinafter, the configuration of the vehicular lamp in this embodiment will be described. In FIG. 1, reference numeral 1 denotes a vehicular lamp in this embodiment. As shown in FIG. 1, the vehicular lamp 1 includes a lamp housing 3 and a lamp lens (not shown) that define a lamp chamber 2, a head lamp unit 4 and a swivel lamp disposed in the lamp chamber 2. And a unit 5.

  The headlamp unit 4 is a projector type headlamp unit, a reflection type headlamp unit, or the like. The swivel lamp unit 5 is a bending lamp unit, an additional lamp unit, a curve lamp unit, or the like.

  The swivel lamp unit 5 includes a semiconductor light source 6, a heat sink 7, a swivel device 8, a reflector 9, and a shade 10.

  As the semiconductor-type light source 6, for example, a self-luminous semiconductor-type light source (LED in this embodiment) such as LED or EL (organic EL) is used. 2 to 5, the semiconductor-type light source 6 includes a substrate 11, a light source chip (semiconductor chip) light emitter (not shown) fixed to one surface of the substrate 11, and the light emitter. And a light transmitting member 12 to be covered. The semiconductor light source 6 is directly attached to the heat sink portion 7. That is, the substrate 11 of the semiconductor light source 6 is directly and integrally attached to the inclined mounting surface 13 of the heat sink portion 7. When the heat sink portion 7 is made of metal, an insulating heat conductive film or the like is interposed between the substrate 11 and the heat sink portion 7.

  The heat sink portion 7 is made of a material having good thermal conductivity, for example, aluminum die cast in this example. As shown in FIGS. 2 to 5, the heat sink portion 7 has a flat or curved upper surface. A pedestal portion 14 is integrally provided at substantially the center of the upper surface of the heat sink portion 7. On the front surface (front surface) of the pedestal portion 14 of the heat sink portion 7, the inclined mounting surface 13 is provided to be inclined forward and backward from the top to the bottom. The heat sink portion 7 constitutes a pedestal for the semiconductor-type light source 6.

  A fin-shaped lower heat radiating portion 15 is integrally provided on the lower surface of the heat sink portion 7. Further, the shade 10 is integrally provided on the rear surface (back surface) of the pedestal portion 14 of the heat sink portion 7. Further, a fin-shaped rear heat radiating portion 16 as an auxiliary heat sink portion is integrally provided on the rear surface (back surface) of the pedestal portion 14 and the shade 10 of the heat sink portion 7. In addition, the fin shape of the said lower heat radiation part 15 and the said rear heat radiation part 16 and the formation direction of a fin are not specifically limited. Further, the lower heat radiating portion 15 and the rear heat radiating portion 16 may have a plate shape or a pin shape in addition to the fin shape. Further, the lower heat radiating portion 15 and the rear heat radiating portion 16 are not integrated and may be provided separately.

  The connecting portion between the lower heat dissipating portion 15 and the rear heat dissipating portion 16 of the heat sink portion 7, that is, the connecting portion between the upper surface of the heat sink portion 7 and the pedestal portion 14, is a thick portion 17. Are provided integrally. Further, the lower heat radiating part 15 of the heat sink part 7 is divided into a central part including the pedestal part 14, the rear heat radiating part 16 and the thick part 17, and right and left side parts via a groove part. Yes. The said groove part is for improving the heat dissipation effect.

  A swivel shaft 18 is integrally provided on the lower surface of the heat sink portion 7, that is, on the lower heat radiating portion 15. The swivel shaft 18 may be provided between the fin-shaped lower heat radiating portion 15 and the lower heat radiating portion 15, or a part of the fin-shaped lower heat radiating portion 15 may be cut away. good. The swivel shaft 18 is connected to the swivel device 8. The swivel device 8 is attached to the lower part of the lamp housing 3. The lamp housing 3 is provided with a through hole 19. A part of the heat sink portion 7 is inserted into the through hole 19. As a result, the inclined mounting surface 13, the pedestal portion 14, the rear heat radiating portion 16, and the semiconductor-type light source 6 side of the heat sink portion 7 are located in the lamp chamber 2, while The heat radiating part 15 and the swivel shaft 18 side are located outside the lamp chamber 2.

  The reflector 9 is attached to the pedestal part 14 of the heat sink part 7 by an appropriate attachment means such as a screw. As a result, the reflector 9 is provided in the heat sink portion 7. The reflector 9 is made of a material having good thermal conductivity, for example, aluminum die casting in this example, like the heat sink portion 7. As shown in FIGS. 6 to 9, the reflector 9 is provided with a first reflecting surface 21 and a second reflecting surface 22, respectively. The first reflective surface 21 is a reflective surface based on an elliptical surface, and the second reflective surface 22 is a reflective surface based on a parabolic surface.

  A light emitter of the light source chip of the semiconductor light source 6 is located at or near the first focal point of the first reflecting surface 21. Further, an edge of the shade 10 is located at or near the second focal point of the first reflecting surface. Further, the first reflecting surface 21 is located slightly in front of the semiconductor light source 6. On the other hand, the second reflecting surface 22 is located above and behind the semiconductor light source 6 and above the first reflecting surface 21. A space 20 is formed between the first reflecting surface 21 and the second reflecting surface 22. The shade 10 is located in the space 20. The semiconductor-type light source 6 faces the first reflective surface 21 so that the 0 ° axis of the semiconductor-type light source 6 is substantially perpendicular to the first reflective surface 21. As a result, light having a high luminous intensity from the semiconductor-type light source 6 enters the first reflecting surface 21.

  On the back side of the second reflecting surface 22 of the reflector 9, a fin-shaped auxiliary heat radiating portion 23 is integrally provided. In addition, the fin shape of the auxiliary heat radiating portion 23 and the direction of fin formation are not particularly limited. Further, the auxiliary heat radiating portion 23 may have a plate shape, a pin shape, or a small unevenness in addition to the fin shape.

  The vehicular lamp 1 in this embodiment has the above-described configuration, and the operation thereof will be described below. First, the semiconductor light source 6 is turned on. Then, the light from the semiconductor light source 6 enters the first reflecting surface 21 and is primarily reflected. A part of the primary reflected light is cut off by the shade 10, and the remainder of the primary reflected light is incident on the second reflecting surface 22 and secondarily reflected. This secondary reflected light is irradiated to the outside with a light distribution pattern of a predetermined shape.

  Further, when the swivel device 8 is driven, the rotating part (semiconductor light source 6, heat sink part 7, reflector 9, shade 10) of the swivel lamp unit 5 rotates to the left and right around the center line of the swivel axis 18 through the swivel shaft 18. To do. Along with this, the light distribution pattern of a predetermined shape rotates left and right.

  Further, the heat generated in the semiconductor light source 6 is transmitted to the pedestal portion 14 of the heat sink portion 7 through the substrate 11 of the semiconductor light source 6. The heat transferred to the pedestal portion 14 is radiated (dissipated) from the lower heat radiating portion 15 and the rear heat radiating portion 16 to the lower side and the rear side of the semiconductor light source 6 as indicated by the white arrows in FIG. The Moreover, since the rear heat radiating portion 16 is located in the space 20 between the first reflecting surface 21 and the second reflecting surface 22 of the reflector 9, it does not interfere with the heat convection direction, and the air flow is good, and the heat radiation effect Is good.

  On the other hand, the heat transmitted to the pedestal portion 14 is radiated from the auxiliary heat radiating portion 23 of the second reflecting surface 22 to the rear side of the semiconductor-type light source 6 through the reflector 9 as shown by a thick solid arrow in FIG. The Moreover, since the auxiliary heat radiating portion 23 is located at the rear upper side of the semiconductor-type light source 6, that is, in the heat convection direction, heat can be radiated efficiently.

  The vehicular lamp 1 in this embodiment has the above-described configuration and operation, and the effects thereof will be described below. The vehicular lamp 1 (swivel lamp unit 5) according to this embodiment can irradiate light from the semiconductor light source 6 with the first reflecting surface 21 and the second reflecting surface 22 and irradiate it in a predetermined direction. The semiconductor light source 6 can be disposed in an inclined state. As a result, the vehicular lamp 1 (swivel lamp unit 5) according to this embodiment is mounted with the semiconductor-type light source 6 inclined on the inclined mounting surface 13 of the pedestal portion 14 of the heat sink portion 7, Since the lower heat radiating portion 15 and the rear heat radiating portion 16 can be provided on the lower surface and the back surface, respectively, the lower heat radiating portion 15 and the rear heat radiating portion 16 are aligned in the heat convection direction. For this reason, the vehicular lamp 1 (swive lamp unit 5) according to this embodiment arranges the lower heat radiating portion 15 and the rear heat radiating portion 16 close to the semiconductor light source 6 and in an ideal shape in the heat convection direction. Therefore, the heat generated in the semiconductor-type light source 6 can be efficiently radiated by the lower heat radiating portion 15 and the rear heat radiating portion 16, and the heat radiation effect can be further improved as compared with the conventional vehicle lamp. . In addition, the vehicular lamp 1 (swive lamp unit 5) according to this embodiment can be provided with the rear heat radiating portion 16 on the back surface of the pedestal portion 14 along the ideal shape in the heat convection direction. The heat radiation part 16 is not conspicuous, and the appearance can be improved accordingly.

  Further, the vehicular lamp 1 (swivel lamp unit 5) according to this embodiment is thick at the connecting portion between the heat radiating portion 15 and the rear heat radiating portion 16, that is, at the connecting portion between the upper surface of the heat sink portion 7 and the pedestal portion 14. Since the part (vain part) 17 is provided integrally, the thermal conductivity from the base part 14 to the lower heat radiation part 15 and the rear heat radiation part 16 is good, and the heat radiation effect can be further improved.

  Further, in the vehicular lamp 1 (swive lamp unit 5) according to this embodiment, since the rear heat radiating portion 16 is located in the space 20 between the first reflecting surface 21 and the second reflecting surface 22 of the reflector 9, It does not interfere with the convection direction, has a good air flow, and has a better heat dissipation effect. Moreover, the vehicular lamp 1 (swive lamp unit 5) according to this embodiment is provided with the reflector 9 in the heat sink portion 7, so that the lamp (lamp unit) can be made compact.

  Furthermore, in the vehicular lamp 1 (swive lamp unit 5) according to this embodiment, the fin-shaped auxiliary heat dissipating portion 23 is integrally provided on the back side of the second reflecting surface 22 of the reflector 9, so that a heat dissipation effect is obtained. In addition, the number of parts can be reduced and the manufacturing cost can be reduced.

  Furthermore, in the vehicular lamp 1 (swive lamp unit 5) according to this embodiment, the heat sink portion 7 and the reflector 9 are made of a material having good thermal conductivity, for example, made of aluminum die casting in this example. Even better.

  As described above, the vehicular lamp 1 (swive lamp unit 5) according to this embodiment is such that the semiconductor light source 6 is directly fixed to the heat sink portion 7, and therefore heat generated in the semiconductor light source 6 is generated by the heat sink portion. 7 can be efficiently radiated by the lower heat radiating portion 15 and the rear heat radiating portion 16 and the auxiliary heat radiating portion 23 of the reflector 9. For this reason, the vehicular lamp 1 (swivel lamp unit 5) according to this embodiment can use a high-wattage LED that outputs a high luminous flux.

  In particular, in the vehicular lamp 1 (swivel lamp unit 5) according to this embodiment, a semiconductor type light source 6 and a heat sink portion 7 to which the semiconductor type light source 6 is directly attached include a swivel device via a swivel shaft 18. 8 is a vehicular lamp using the semiconductor-type light source 6 as a light source, and the light irradiation direction can be swiveled. In addition, the vehicular lamp 1 (swivel lamp unit 5) according to this embodiment has the swivel shaft 18 connected to the swivel device 8 provided integrally with the heat sink portion 7, so that the number of parts can be reduced. In addition, the manufacturing cost can be reduced. In addition, the vehicular lamp 1 (swivel lamp unit 5) according to this embodiment is configured such that the swivel shaft 18 and the semiconductor light source 6 are integrated by integrating the swivel shaft 18 and the heat sink portion 7 on the semiconductor light source 6 side. Can be reliably prevented, and the light irradiation direction can be swiveled reliably and accurately.

  Further, the vehicular lamp 1 (swivel lamp unit 5) according to this embodiment includes a first reflecting surface 21 based on an elliptical surface, a second reflecting surface 22 based on a parabolic surface, and a shade 10 so as to be predetermined. A light distribution pattern of the shape can be formed. Moreover, the vehicular lamp 1 (swive lamp unit 5) according to this embodiment is generated in the semiconductor light source 6 because the rear heat radiating portion 16 as an auxiliary heat sink portion is integrally provided on the shade 10 (base portion 14). Heat can be radiated more efficiently, and the number of parts can be reduced, and the manufacturing cost can be reduced. Furthermore, since the vehicular lamp 1 (swivel lamp unit 5) according to this embodiment has the shade 10 (the pedestal portion 14) provided integrally with the heat sink portion 7, the number of parts can be reduced accordingly, and The manufacturing cost can be reduced.

  In this embodiment, the swivel type lamp unit 5 has been described. However, the present invention can also be applied to a fixed type lamp unit.

It is a front view which shows the Example of the vehicle lamp concerning this invention, Comprising: It is a front view of the state which fractured | ruptured one part except the lamp lens. Similarly, it is a perspective view which shows the semiconductor type light source and heat sink part of a swivel lamp unit. Similarly, it is a side view which shows the semiconductor type light source and heat sink part of a swivel lamp unit. Similarly, it is a top view which shows the semiconductor type light source and heat sink part of a swivel lamp unit. Similarly, it is a front view which shows the semiconductor type light source and heat sink part of a swivel lamp unit. Similarly, it is a perspective view which shows the semiconductor type light source of the swivel lamp unit, a heat sink part, and a reflector. Similarly, it is a side view which shows the semiconductor type light source of the swivel lamp unit, a heat sink part, and a reflector. Similarly, it is a top view which shows the semiconductor type light source, heat sink part, and reflector of a swivel lamp unit. Similarly, it is a front view which shows the semiconductor type light source of the swivel lamp unit, a heat sink part, and a reflector.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Vehicle lamp 2 Lamp chamber 3 Lamp housing 4 Head lamp unit 5 Swivel lamp unit 6 Semiconductor type light source 7 Heat sink part 8 Swivel device 9 Reflector 10 Shade 11 Substrate 12 Light transmission member 13 Inclined mounting surface 14 Base part 15 Lower heat radiation part 16 Rear heat radiation part 17 Thick part 18 Swivel shaft 19 Through hole 20 Space 21 First reflection surface 22 Second reflection surface 23 Auxiliary heat radiation part

Claims (4)

In vehicular lamps that use semiconductor-type light sources,
The semiconductor-type light source;
A heat sink part directly attached with the semiconductor-type light source tilted;
A lower heat dissipating part provided on a lower surface of the heat sink part to which the semiconductor light source is attached;
A rear heat dissipating part provided on the rear surface of the heat sink part to which the semiconductor light source is attached;
Comprising
A vehicular lamp characterized by the above. The connecting portion between the lower heat radiating portion and the rear heat radiating portion is integrally provided with a thick portion,
The vehicular lamp according to claim 1. The heat sink part is provided with a reflector,
The reflector includes a first reflecting surface based on an ellipse that reflects light from the semiconductor-type light source, and a second reflecting surface based on a parabolic surface that reflects reflected light from the first reflecting surface; , Each is provided,
In the space between the first reflecting surface and the second reflecting surface, the rear heat radiating portion is disposed.
The vehicular lamp according to claim 1 or 2. The heat sink part is provided with a reflector,
The reflector includes a first reflecting surface based on an ellipse that reflects light from the semiconductor-type light source, and a second reflecting surface based on a parabolic surface that reflects reflected light from the first reflecting surface; , Each is provided,
On the back side of the second reflecting surface, an auxiliary heat radiating portion is provided integrally.
The vehicular lamp according to any one of claims 1 to 3.

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