JP2019061912A - Vehicular lighting fixture - Google Patents

Abstract

To provide a vehicular lighting fixture that actualizes artificial lighting with a luminous body and enhances heat radiation properties of a light source (light-emitting element).SOLUTION: A vehicular lighting fixture comprises an LED 133 (light source) mounted on one surface of a light source substrate 131 and a reflector 122 arranged on the one surface side of the light source substrate 131 and having a reflection part 122 reflecting light emitted from the LED 133. A heat radiation body 161 radiating heat generated by the LED 133 and a luminous body 162 accumulating light and emitting the accumulated light toward the reflection part 122 are arranged between the LED 133 and reflection part 122.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a lamp of a vehicle such as a car, and more particularly to a lamp for vehicles for performing pseudo-lighting of the lamp using luminous energy.

  A luminous material is applied to a part of a lamp such as a car headlight or a marker lamp, and the light stored in the luminous material is used to simulate lighting (in this case, the lamp has an appearance as if it were lit) A technique has been proposed that is designed to do. Patent Document 1 is a lamp unit having an LED mounted on a base plate as a light source, and a phosphorescent material is disposed in the vicinity of the base plate and the reflector, and light emitted by the phosphorescent material when the lamp unit is not lit I am doing the pseudo lighting of the lamp using it.

JP, 2015-149157, A

  In the technology of Patent Document 1, as a measure for heat generated at the time of light emission of the LED, a configuration is adopted in which heat is dissipated through the base plate or conducted from the base plate to the reflector to dissipate heat. The base plate and the reflector are often formed of resin, and the thermal conductivity of these is not necessarily high, so it is difficult to enhance the heat dissipation of the LED. It is known that when the heat radiation effect of the LED is low, the light emission efficiency of the LED is lowered and the lighting effect of the lamp, for example, the light distribution characteristic is lowered. In addition, the decrease in heat dissipation is not preferable in terms of the luminous characteristics and luminous characteristics of the luminous material.

  An object of the present invention is to provide a vehicular lamp which realizes the pseudo lighting by means of stored light while enhancing the heat dissipation of the light source, particularly the light emitting element.

  The present invention comprises a light source mounted on one surface of a light source substrate, and a reflector provided on the one surface side of the light source substrate and having a reflecting portion for reflecting light emitted from the light source. Between the light source and the reflecting portion, a heat dissipating member for radiating heat generated by the light source, and a light storing body for storing light and emitting light toward the reflecting portion are disposed. .

  In a preferred embodiment of the present invention, the heat dissipating body is formed separately from the light source substrate, and the luminous body is formed on the heat dissipating body. Moreover, as another preferable form of this invention, a luminous body is set as the structure which contained the luminous material in the soldering resist provided in one side of the light source board | substrate. Furthermore, it is preferable that the heat dissipating body be constituted by a part of the reflector.

  According to the present invention, the light from the light source is effectively stored in the luminous body, and the heat generated by the light source is efficiently dissipated by the heat radiating body. Thereby, while realizing the pseudo lighting by a luminous body, the light distribution characteristic of the lamp by a light source is improved.

The external view which applied this invention to the headlamp of a motor vehicle. The disassembled perspective view of the lamp unit of the headlamp of FIG. FIG. 2 is a longitudinal sectional view of the lamp unit of the first embodiment. The enlarged view of the principal part of FIG. The perspective view which looked at the phosphorescent board from the downward direction. FIG. 7 is a longitudinal sectional view of a lamp unit of Modification 1; FIG. 10 is a longitudinal sectional view of a lamp unit of Modification 2; FIG. 7 is a longitudinal sectional view of a lamp unit of a second embodiment. The enlarged view of the principal part of FIG.

(Embodiment 1)
Next, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is an external perspective view of a left headlamp HL of a car to which the present invention is applied. As shown in FIG. 1, a lamp unit 1 of a reflector type is installed in a lamp housing 2 of a left head lamp HL mounted on the front left side of a vehicle body of an automobile. When the lamp unit 1 is turned on, the head lamp HL is turned on. The right headlamp (not shown) is formed symmetrically with the left headlamp HL, but the basic structure is almost the same.

  FIG. 2 is a partially exploded perspective view of the lamp unit 1 installed in the left head lamp HL. In FIG. 1 and FIG. 2, the lamp unit 1 has a block-shaped base body 11 in which a front surface 111 is formed stepwise in the left-right direction. The step shape of the front surface 111 of the base body 11 is directed toward the outside in the vehicle width direction of the car, that is, in the case of the above-mentioned left headlamp HL, the front surface 111 is stepped toward the right when viewed from the front. It is configured to retreat. In the following, front and rear, left and right, and upper and lower are directions based on the car, in other words, directions based on the lamp unit 1 or the headlamp HL.

  A reflector 12 is supported on the front surface 111 of the base body 11. The reflector 12 is composed of two separate reflectors for high beam 12H and low beam reflector 12L. In each of the reflectors 12H and 12L, a plurality of reflectors 122 are arranged in parallel, and for the high beam reflector 12H, four reflectors 122 are arranged, and for the low beam reflector, five reflectors 122 are arranged side by side in the left-right direction. Configuration.

  The support portion 121 is formed substantially in a plate shape, and at a plurality of locations respectively corresponding to the plurality of reflection portions 122, a rectangular light transmission window 124 having a required size is opened in the vertical direction. A light source unit 13 is attached to the support portion 121 so as to cover the upper side thereof. The light source unit 13 has a light source substrate 131 on which an LED 133 as a light source is mounted on the lower surface. Further, a heat sink 15 is laminated on the upper surface of the light source substrate 131 via a heat transfer sheet 14.

  FIG. 3 is a longitudinal sectional view of the lamp unit 1 and the base body 11 is not shown. In the following description, since the reflectors 12H and 12L have substantially the same configuration, they will be described using the same reference numerals. As described above, the reflector 12 has the support portion 121 for supporting the light source, and the parabolic reflection portion 122 extended from the support portion 121 in a slanted state forward and downward of the lamp. There is. The reflector 12 is formed by resin molding, and a metal film 123 having light reflectivity such as aluminum is formed by vapor deposition or the like on the front surface of the reflecting portion 122 to form a light reflecting surface. Further, the support portion 121 has a configuration in which a plurality of rectangular frames corresponding to a plurality of reflection portions 122 are arranged in parallel, and the light transmission window 124 described above is formed in each.

  FIG. 4 is an enlarged view of the main part of FIG. A circuit pattern 132 is formed on the lower surface of the light source substrate 131, and a plurality of chip-shaped LEDs 133 are mounted by surface mounting corresponding to the plurality of reflecting portions 122. Here, one LED 133 is mounted on one reflection unit 122. Further, in the lower surface of the light source substrate 131, a protective solder resist 134 is applied to a region where the LED 133 is not mounted.

  The light emitting surface of the LED 133 is directed downward, and when the light source substrate 131 is mounted on the support portion 121 of the reflector 12, each LED 133 is disposed at a position facing the light transmitting window 124 of the corresponding support portion 121. Be done. The LED 133 is supplied with power through the circuit pattern 132 to emit light, and the emitted light is emitted toward the lower side of the light source substrate 131, transmitted through the corresponding light transmitting window 124, and directed to the corresponding reflecting portion 122.

  The reflection part 122 of the reflector 12 is formed on a paraboloid whose focal point is the corresponding LED 133, and reflects the light emitted from the LED 133 toward the front of the lamp. Each reflecting portion 122 is basically designed to have substantially the same shape, but the sizes and shapes of the individual reflecting portions 122 are partially different in order to form the required light distribution required for the lamp unit 1 There is. That is, the reflectors 122 for the high beam reflector 12H and the low beam reflector 12L have different shapes so as to form predetermined light distributions, respectively.

  On the lower surface side of the light source unit 13, that is, on the lower surface side of the light source substrate 131, a luminous plate 16 is disposed between the LED 133 and the reflecting portion 122 of the reflector 12, here, the supporting portion 121 of the reflector 12. It is arranged. As shown in FIG. 5 which is a perspective view of the light storage plate 16 as viewed from below, the light storage plate 16 includes a heat sink 161 made of a material having high heat conductivity, and a light storage body 162 applied to the lower surface of the heat sink 161. It consists of In the light storing plate 16, rectangular openings 163 are formed in a portion corresponding to the support portion 121 of the reflector 12, in other words, a portion corresponding to each LED 133 mounted on the light source substrate 131. The opening 163 is smaller than the light transmitting window 124 formed in the support portion 121.

  The heat dissipating member 161 is formed of a material having a thermal conductivity greater than at least air. That is, since the thermal conductivity of air is 0.02 W / m · k, any material larger than that may be used. Further, as described above, when the solder resist 134 for circuit protection is formed on the lower surface of the light source substrate 131, the heat dissipating member 161 has a thermal conductivity of 0.17 W / m · k, for example, of the solder resist 134. Preferably, it is formed of a large metal plate such as aluminum or copper.

  With regard to the luminous material constituting the luminous body 162, since various luminous materials have already been proposed, the luminous body made of a suitable material is selected in consideration of the durability etc. when it is used for a vehicle lamp. can do. For example, a luminous body capable of accumulating light of each color of yellow green, blue, purple, red and yellow can be selected. The luminous body 162 is formed in a region surrounding the opening 163 of the luminous plate 16.

  The light storing plate 16 is integrally supported by the reflector 12 and the light source substrate 131 in a state of being sandwiched between the support portion 121 of the reflector 12 and the light source substrate 131. In the first embodiment, in particular, a predetermined gap is provided between the lower surface of the light storage plate 16 and the upper surface of the support portion 121. In such a support structure, a part of the luminous body 162, in particular, the luminous body 162 in a region along the periphery of the opening 163, is exposed downward through the translucent window 124 larger than this.

  According to the lamp unit 1 of the first embodiment, when the head lamp HL is lit, that is, when the lamp unit 1 is lit, the light emitted downward from each of the emitted LEDs 133 as shown by the solid line in FIG. Are respectively reflected forward in the corresponding reflectors 122 of the reflector 12 and transmitted through the translucent surface of the lamp housing 2 to be irradiated to the front area of the vehicle. And the light of each LED133 reflected towards the lamp front in each reflector 122 is superimposed on each other in the front area of the lamp to illuminate the required area in front of the car, ie, high beam distribution or low beam distribution Is formed.

  When the lamp unit 1 is lit, part of the light emitted from the LED 133 is accumulated in the luminous body 162 of the luminous plate 16. That is, a part of the light emitted from the LED 133 is directly irradiated to the luminous body 162, or another part is reflected by a part of the reflector 12 and then irradiated to the luminous body 162 to be accumulated.

  When the lamp unit 1 is lit, part of the heat generated along with the light emission of the LED 133 is conducted from the light source unit 13, particularly the light source substrate 131, to the heat sink 15 via the heat transfer sheet 14 and dissipated therefrom. In addition, another part of the generated heat is radiatively conducted from the LED 133 directly or through the solder resist 134 of the light source substrate 131 to the heat dissipating member 161 of the heat storage plate 16. As described above, since the heat radiating body 161 has a thermal conductivity higher than that of air, the radiated heat is diffused inside the heat radiating body 161 and is efficiently dissipated from the heat radiating body 161. Incidentally, when the heat sink 161 does not exist, the heat radiated from the light source unit 13 is conducted to the reflector 12 via the air layer and dissipated, but the heat conductivity of the air layer is low, so the heat is high. It is difficult to expect a heat dissipation effect.

  As described above, the luminous plate 16 is disposed in the vicinity of the LED 133, and the heat dissipating member 161 of the luminous plate 16 is made of a material having a thermal conductivity higher than that of air, thereby enhancing the heat dissipation effect of the LED 133 Thus, it is possible to obtain a headlamp having a high lighting effect by preventing the deterioration of the light emission characteristics of the At the same time, the characteristic deterioration due to heat in the luminous body 162 is prevented.

  Further, by forming the heat dissipating member 161 of the phosphor plate 16 with a material having a thermal conductivity larger than that of the solder resist 134, the heat conducted through the solder resist 134 can be absorbed by the heat dissipating member 161 to increase the heat conduction effect as a whole. Also from this aspect, the heat dissipation effect of the LED 133 is enhanced to prevent the deterioration of the light emission characteristics of the LED 133, and a headlamp having a high lighting effect can be obtained.

  When the lamp unit 1 is turned off, the illumination by the light emitted from the LED 133 is ended, but as shown by the broken line in FIG. 3, the light storing body 162 stored at the time of lighting is emitted, and the light is transmitted. The light is reflected by the reflecting portion 122 through the light window 124 and illuminated forward. As a result, when the headlamp HL is observed from the front of the car, the reflecting portion 122 is brightly illuminated through the light transmitting surface, and the lamp unit 1, in other words, the headlamp HL looks like it is lit. . That is, it will be in the state of false lighting. This pseudo-lighting makes it possible to visually recognize the area immediately in front of the host vehicle, and allows other vehicles and pedestrians to recognize the presence of the host vehicle, which is preferable from the viewpoint of traffic safety.

  By selecting the luminous material emitting light with any color light as described above as the luminous body 162 of the luminous plate 16, the lamp unit 1 to the headlamp HL look like being lit with the color light during pseudo lighting. As a result, the designability of the headlamp HL at the time of pseudo lighting is improved.

(Modification 1)
As a first modification of the first embodiment, the support portion 121 of the reflector 12 may be configured as a luminous plate. That is, as shown in the longitudinal sectional view of the first modification in FIG. 6, when depositing the metal film 123 such as aluminum on the reflecting portion 122 of the resin-molded reflector 12, the metal film 123 is also deposited on the supporting portion 121. doing. By forming the metal film 123, the thermal conductivity of the entire support portion 121 is increased. Further, a luminous material is applied to a selected required region on the upper surface or the lower surface of the support portion 121 to form a luminous body 162. As a result, in the support portion 121, the metal film 123 has a configuration equivalent to the heat radiating body 161 of the first embodiment, and a configuration substantially equivalent to the phosphor plate 16 of the first embodiment with the luminous body 162 coated therewith. Will be realized.

  This modification 1 is the same as Embodiment 1 in the emission form of light when the lamp unit 1 is lit, and the luminous body 162 provided on the support portion 121 of the reflector 12 when the LED 133 of the light source portion 13 emits light. Light is luminous. Since the heat conductivity of the support portion 121 is larger than the heat conductivity of air and further the heat conductivity of resin by forming the metal film 123, the support portion 121 functions as a heat radiator and enhances the heat radiation effect of the LED 133 be able to.

  When the lamp unit 1 is turned off, the light accumulated in the luminous body 162 passes through the light transmitting window 124, is reflected by the reflection portion 122, and is emitted forward. In the first modification, since the independent light storing plate 16 as in the first embodiment is not necessary, the number of parts of the lamp unit 1 can be reduced. In addition, the height dimension of the lamp unit 1 can be reduced.

(Modification 2)
FIG. 7 is a longitudinal sectional view of the second modification. In the second modification, the reflector 12 is formed by insert molding, the support portion 121M of the reflector 12 is formed of metal, and the reflection portion 122 is formed of resin. Then, a metal film 123 such as aluminum having light reflectivity is vapor-deposited on the surface of the reflecting portion 122. The light transmission window 124 is opened in the support portion 121 M, and the LED 133 mounted on the light source substrate 131 of the light source unit 13 disposed above the light transmission window 124 faces the light transmission window 124. It is attached as it is. The heat transfer sheet 14 and the heat sink 15 have the same configuration as in the first embodiment.

  Further, the luminous body 162 is applied to a selected required area on the upper surface or the lower surface of the support portion 121M. As a result, the support portion 121M has a configuration equivalent to the heat radiating body 161 of the first embodiment, and a configuration substantially equivalent to the phosphor plate 16 of the first embodiment can be realized with the luminous body 162 applied thereto. Become.

  In the second modification, when the LED 133 emits light when the lamp unit 1 is lit, light is accumulated in the luminous body 162 provided in the support portion 121M of the reflector 12. The support portion 121M is made of a metal whose thermal conductivity is higher than that of air and further that of resin, and thus functions as a heat dissipation body, and can enhance the heat dissipation effect of the LED 133.

  When the lamp unit 1 is turned off, the light accumulated in the luminous body 162 is reflected by the reflecting portion 122 through the light transmitting window 124 and is emitted forward. In this modification 2 as well, since an independent light storage plate as in the first embodiment is not necessary, the number of parts of the lamp unit 1 can be reduced and the height dimension of the lamp unit 1 can be reduced.

Second Embodiment
FIG. 8 is a longitudinal sectional view of the lamp unit of the second embodiment, and FIG. 9 is an enlarged view of the main part thereof. As in the first embodiment, the circuit pattern 132 is provided on the lower surface of the light source substrate 131 of the light source unit 13, and a plurality of chip-shaped LEDs 133 are mounted. Each LED 133 is mounted so as to correspond to each of a plurality of reflecting portions of the reflector 12. The light emitting surface of each LED 133 is directed downward, and when the light source substrate 131 is attached to the reflector 12, each LED 133 is disposed at a position facing the corresponding light transmitting window 124.

  On the lower surface of the light source substrate 131, a solder resist 134 for circuit protection is applied and formed in an area excluding the LED 133. In the second embodiment, a luminous material is contained in the solder resist 134, whereby the solder resist 134 functions as a luminous body. That is, it is equivalent to the luminous body 162 of the first embodiment.

  As in the second modification, the reflector 12 is formed by insert molding, the support portion 121M of the reflector 12 is formed of metal, the reflection portion 122 is formed of resin, and aluminum 123 is vapor-deposited on the surface. The light transmitting window 124 is opened in the supporting portion 121M, and the LEDs 133 of the light source unit 13 are attached so as to be opposed to each other.

  As described above, in the second embodiment, the solder resist 134 provided on one surface of the light source substrate 131 on which the LED 133 is mounted is configured as the luminous body 162. In addition, the supporting portion 121M of the reflector 12, which is in close proximity to one surface of the antigen substrate 131, is formed of metal and configured as a radiator 161 having a thermal conductivity larger than that of air or resin. Become.

  In the second embodiment, when the lamp unit 1 is lit, the light emitted by the LED 133 is reflected by the reflecting portion 122 as in the first embodiment and is emitted forward. At the same time, part of the light is stored in the luminous body 162, ie, the solder resist 134. A part of the heat generated in the LED 133 is dissipated by the heat sink 15, but another part is dissipated by radiation to the supporting portion 121M of the reflector 12 configured as the radiator 161, and is diffused and dissipated here It will be.

  When the lamp unit 1 is turned off, the light emitted by the light storing member 162 (solder resist 134) passes through the light transmitting window 124, is reflected by the reflecting portion 122, and is emitted forward. Thereby, pseudo lighting is performed.

  In the second embodiment, since an independent light storing plate as in the first embodiment is unnecessary, the number of parts of the lamp unit 1 can be reduced, and the height dimension of the lamp unit 1 can be reduced. Further, if the light source unit 13 is formed, that is, the LED 133 is mounted on the light source substrate 131 and the solder resist 134 is applied, the luminous body 162 can be formed.

  Here, although not shown, as a modification of the second embodiment, the reflector is resin-molded as in the first modification, aluminum is vapor-deposited on the reflective portion, and aluminum is also vapor-deposited on the support portion. The supporting portion including may be configured as a heat dissipating member.

  Furthermore, as another modification, although not shown, the light source is a range in which the light emitted from the LED and the light emitted from the luminous body are not inhibited from being emitted toward the reflection portion through the light transmission window. A plate-like heat dissipating member, for example, a metal plate, may be interposed between the substrate and the support portion of the reflector to extend over the required area. In this case, the heat generated by the LED is dissipated through the radiator.

  In the above embodiment and modification, since the luminous body 162 is disposed at a position near the LED 133, the luminous body 133 is disposed at the focal position of the reflection portion 122 or a position near the focal position. Therefore, the light emitted by the light storing body 162 is reflected forward in the reflecting portion 122 in the same manner as the light emitted from the LED 133. As a result, the light from the luminous body 162 is irradiated toward the wide area in front of the car with the same light distribution as when the lamp unit 1 is lit, and the headlight HL is simulated from the wide area in front of the car. It becomes possible to improve the visibility of lighting.

  Furthermore, the luminous body 162 is disposed on the upper side of the support portion 121 of the reflector 12, or on the support portions 121 and 121M, and this position is not a position exposed directly to the outside when viewed from the front of the headlamp HL. In particular, when the lamp unit HL is not lit, it is difficult to observe a luminous body through the translucent cover, and the appearance of the headlamp HL is not deteriorated.

  In the present invention, the light source substrate may be assembled in contact with the luminous plate or the support. As a result, it is possible to efficiently conduct the heat generated by the LED to the heat dissipation body to further enhance the heat dissipation effect of the LED. Further, in each of the embodiments and modifications described above, the support portion and the reflection portion of the reflector may be integrally formed of a metal material.

  The luminous body in the present invention is not limited to the case where the light emitted from the light source of the lamp is accumulated, but it is also possible to condense the sunlight at daytime and emit light at the time of non-lighting at night to simulate lighting.

HL Headlamps (lights for vehicles)
DESCRIPTION OF SYMBOLS 1 lamp unit 2 lamp housing 11 base body 12 (12H, 12L) reflector 13 light source part 14 heat transfer sheet 15 heat sink 16 light storing plate 121, 121M support part 122 reflection part 123 metal film 131 light source substrate 133 LED (light source)
134 Solder resist 161 Heat dissipation body 162 Phosphorescent body

Claims (6)

  The light source includes: a light source mounted on one surface of the light source substrate; and a reflector disposed on the one surface side of the light source substrate and having a reflecting portion for reflecting light emitted from the light source, the light source and the light source A heat dissipating member for dissipating heat generated by the light source and a light storing material for storing light and emitting light toward the reflecting portion are disposed between the light emitting portion and the reflecting portion. Lamps for vehicles.   The vehicle lamp according to claim 1, wherein the heat dissipating body is configured separately from the light source substrate, and the luminous body is formed on the heat dissipating body.   The vehicle lamp according to claim 2, wherein the heat dissipating member is configured of a part of the reflector, and the light storing member is configured of a part of the reflector.   A solder resist is provided on the one surface of the light source substrate, and the luminous body is configured to contain a luminous material in the solder resist, and the heat radiating body is configured separately from the light source substrate. The vehicle lamp according to 1.   The vehicle lamp according to claim 4, wherein the heat dissipating body is constituted by a part of the reflector. The vehicle radiator according to any one of claims 1 to 5, wherein the heat dissipating body includes a material having a thermal conductivity larger than that of air.

Images