This application claims the priority benefit under 35 U.S.C. §119 of Japanese Patent Application No. 2010-268049 filed on Dec. 1, 2010, which is hereby incorporated in its entirety by reference.
1. Field
The presently disclosed subject matter relates to a vehicle lighting device.
2. Description of the Related Art
Conventionally, a semiconductor light-emitting device such as a light-emitting diode (LED) is widely used as a light source in a vehicle lighting device such as a headlight for a car. With this type of vehicle lighting device, it is possible to form a light distribution pattern having a desired shape, for example, by properly arranging a plurality of semiconductor light-emitting devices. However, it is difficult to form a light distribution pattern having a desired luminous intensity distribution therewith.
Accordingly, for example, Japanese Patent No. 4002159 proposes a vehicle lighting device with which a light distribution pattern having a desired shape and a desired luminous intensity distribution can be formed by combining a plurality of types of lighting units having different light-illumination modes.
However, in the vehicle lighting device disclosed by Japanese Patent No. 4002159, a projector lens which emits light to the front of a vehicle is provided for each lighting unit. Hence, when light is emitted, a dark portion is generated between the exit surfaces (light-emitting surfaces) of the projector lenses. That is, a light-emitting portion does not emit light as a whole, and the vehicle lighting device does not look good when emitting light.
Furthermore, in general, the exit surface of a projector lens is convex in order to control light distribution. Hence, a light-emitting portion is formed by intermittently arranging a plurality of convex surfaces. Therefore, a light-emitting portion cannot be formed in a smooth shape, or cannot fit the design of the external appearance of a vehicle. That is, the external appearance of a vehicle lighting device is not desirable.
Furthermore, in order to obtain a desired light distribution pattern, a plurality of projector lenses is needed to be combined in an appropriate positional relation. Hence, the costs for combining the projector lenses increase, and also light distribution performance may be decreased by the errors made in combining the projector lenses.
It may seem that the problems described above can be solved by integrating a plurality of projector lenses into one. A single projector lens may be obtained by simply connecting a plurality of projector lenses with each other, but the exit surface of the obtained single projector lens has a plurality of convex portions. That is, although the necessity to combine a plurality of projector lenses is eliminated thereby, the problems about the looks of a vehicle lighting device at the time of emitting light and the external appearance thereof are still unsolved.
The presently disclosed subject matter is made in the view of the circumstances, and one aspect of the presently disclosed subject matter is to provide a vehicle lighting device using a semiconductor light-emitting device as a light source, the vehicle lighting device which looks excellent when emitting light and has an excellent external appearance.
According to another aspect of the presently disclosed subject matter, there is provided a vehicle lighting device including: a plurality of semiconductor light-emitting devices; a projector lens which illuminates a front of a vehicle with light emitted from the semiconductor light-emitting devices, the projector lens including: a plurality of incidence surfaces which performs main control of light distribution, and respectively corresponds to the semiconductor light-emitting devices; and a single exit surface including a plurality of exit regions which emits the light entering through the incidence surfaces into the projector lens, wherein the exit regions provided next to each other overlap with each other.
The above and other characteristics, advantageous effects, and features of the presently disclosed subject matter will become more fully understood from the detailed description given hereinbelow and the accompanying drawings which are given by way of illustration only, and thus are not intended as definitions of limits of the presently disclosed subject matter, wherein:
In the following, an exemplary embodiment of the presently disclosed subject matter is described with reference to the accompanying drawings.
Vehicle lighting devices are respectively fixed onto the right and the left of the front part of a vehicle. However, in the following, the vehicle lighting device 1 fixed onto the left of the front part of a vehicle is described, and the description of a vehicle lighting device fixed onto the right thereof is omitted. Furthermore, words of “up”, “down”, “front”, “back”, “left”, and “right” used hereinbelow respectively indicate directions viewed from a vehicle (not shown) onto which the vehicle lighting device 1 is fixed, and the words respectively correspond to the words in the drawings, unless different explanation is made.
As shown in
The LEDs 2 are semiconductor light-emitting devices (an LED package) of the presently disclosed subject matter, and are respectively fixed on steps 41 of a bracket 4 which is formed stepwise. The bracket 4 is long and inclines upward and backward from the right to the left. The steps 41 are at right angles to the front-back direction, and the further left a step 41 is located on the bracket 4, the further back the step 41 is located. More specifically, the steps 41 of the bracket 4 are arranged at predetermined intervals so as to respectively face incidence surfaces 31 (described below) of the projector lens 3. In addition, among the steps 41, four steps 41 on the left of the bracket 4 face in a direction inclined at an angle of 20 degrees from the front to the left. Each LED 2 is fixed onto the center of the front surface of its corresponding step 41. Among the LEDs 2, eight LEDs 2 provided on the right emit light forward, and the rest of the LEDs 2, namely, four LEDs 2 provided on the left, emit light in a direction inclined at an angle of 20 degrees from the front to the left. Radiation fins 42 are formed on the back surface of each step 41 of the bracket 4.
The projector lens 3 illuminates the front of the vehicle with the light emitted from the LEDs 2. The projector lens 3 is long and inclines upward and backward from the right to the left. The projector lens 3 is fixed to the bracket 4 with four screws 5 in a state in which the projector lens 3 covers the front of the LEDs 2. On the back surface of the projector lens 3, twelve incidence surfaces 31 are arranged in the longer direction, the incidence surfaces 31 through which the light emitted from the LEDs 2 respectively enters so as to enter into the projector lens 3. The front surface of the projector lens 3 is plane with the upper part thereof inclined backward, and constitutes an exit surface 32 which emits the light from the projector lens 3.
Each incidence surface 31 of the projector lens 3 is convex, and has an optical axis Ax (shown in
Each of the first incidence surfaces 311 is composed of a first refracting surface 311a formed on the own-lane side (left), a second refracting surface 311b formed on the opposite-lane side (right), and a third refracting surface 311c formed between the first refracting surface 311a and the second refracting surface 311b (shown in
In a similar manner to each of the first incidence surfaces 311, each of the second incidence surfaces 312 is composed of a first refracting surface 312a formed on the own-lane side (left), a second refracting surface 312b formed on the opposite-lane side (right), and a third refracting surface 312c formed between the first refracting surface 312a and the second refracting surface 312b (shown in
As shown in
As shown in
Of the first incidence surface 311, the first refracting surface 311a provided on the own-lane side refracts the light emitted from its corresponding LED 2 in such a way that, on the up-down direction section, some of the light is emitted from the exit surface 32 to travel downward from the optical axis Ax, and the rest of the light is emitted from the exit surface 32 to travel along the optical axis Ax. Furthermore, of the first incidence surface 311, the second refracting surface 311b and the third refracting surface 311c refract the light emitted from their corresponding LED 2 in such a way that, on the up-down direction section, the light is emitted from the exit surface 32 to travel downward from the optical axis Ax. In addition, the second refracting surface 311b refracts the light emitted from its corresponding LED 2 in such a way that the light is emitted from the exit surface 32 to travel further down than the light passing through the first refracting surface 311a. The first, second, and third refracting surfaces 311a, 311b, and 311c refract the light emitted from their corresponding LED 2 by making the deflection angle to emit the light from the exit surface 32 downward become gradually larger as the light is emitted away from the optical axis Ax in the up-down direction.
The first, second, and third refracting surfaces 312a, 312b, and 312c of the second incidence surface 312 refract the light emitted from their corresponding LED 2 in a similar matter to the first, second, and third refracting surfaces 311a, 311b, and 311c of the first incidence surface 311, respectively.
Next, a light distribution pattern (low beams) formed in front of the vehicle through the projector lens 3 is described.
As shown in
As shown in
As shown in
In the illumination regions B1, B2, and B3, the vicinities of the own-lane side horizontal cutoff line C1, the opposite-lane side horizontal cutoff line C2, and the oblique cutoff line C3 are the brightest, respectively. Then, as it is away from the cutoff lines downward, it becomes gradually darker. This is because the deflection angle to emit the light downward with the first refracting surface 311a, the second refracting surface 311b, or the third refracting surface 311c becomes gradually larger as the light is emitted away from the optical axis Ax in the up-down direction.
A first cutoff line portion B which includes the cutoff lines C1, C2, and C3 is formed by combining the illumination regions B1, B2, and B3.
As shown in
More specifically, although not being shown, in a similar manner to the light emitted to the front of the vehicle through the first refracting surface 311a of the first incidence surface 311 and the exit surface 32, the light emitted to the front of the vehicle through the first refracting surface 312a of the second incidence surface 312 and the exit surface 32 illuminates a region. The region is a region, the upper edge of which coincides with the own-lane side horizontal cutoff line C1, and which is larger than the illumination region B1 in the left direction and in the down direction. Also, in a similar manner to the light emitted to the front of the vehicle through the second refracting surface 311b of the first incidence surface 311 and the exit surface 32, the light emitted to the front of the vehicle through the second refracting surface 312b of the second incidence surface 312 and the exit surface 32 illuminates a region. The region is a region, the upper edge of which coincides with the opposite-lane side horizontal cutoff line C2, and which is larger than the illumination region B2 in the right direction and in the down direction. Also, in a similar manner to the light emitted to the front of the vehicle through the third refracting surface 311c of the first incidence surface 311 and the exit surface 32, the light emitted to the front of the vehicle through the third refracting surface 312c of the second incidence surface 312 and the exit surface 32 illuminates a region. The region is a region, the upper edge of which coincides with the oblique cutoff line C3 and the horizontal line H, and which is larger than the illumination region B3 in the down direction. The second cutoff line portion D which includes the cutoff lines C1, C2, and C3 is formed by combining these regions.
The light emitted to the front of the vehicle through the third incidence surface 313 and the exit surface 32 forms a diffusion light distribution portion R. The diffusion light distribution portion R is located below the point E1, and is larger than the second cutoff line portion D in the right direction, in the left direction, and in the down direction. The diffusion light distribution portion R is larger than the second cutoff line portion D in the left direction, in particular.
Low beams P are formed by combining the first cutoff line portion B, the second cutoff line portion D, and the diffusion light distribution portion R.
According to the vehicle lighting device 1 described above, the projector lens 3 includes the incidence surfaces 31 which respectively correspond to the LEDs 2, and the single exit surface 32. In the exit surface 32, the exit regions which are next to each other overlap with each other. The exit regions emit the light entering through the incidence surfaces 31 into the projector lens 3, respectively. Accordingly, the light emitted from the LEDs 2 can be emitted from the single exit surface 32 with no gap. Therefore, on the contrary to the case where a plurality of projector lenses is arranged or connected, the exit surface 32 does not have a dark portion therein, and accordingly, can emit light as a whole. Hence, the vehicle lighting device 1 looks excellent when emitting light.
Furthermore, the incidence surfaces 31 of the projector lens 3 perform the main control of the light distribution. Accordingly, on the contrary to the case where a plurality of convex exit surfaces which performs the control of the light distribution is arranged or connected, the exit surface 32 can be a single surface having high degree of freedom in designing. Consequently, the exit surface 32 which acts as a light-emitting portion (a light-emitting portion of the vehicle lighting device 1) can be formed in a smooth shape, and can fit the design of the external appearance of a vehicle. Hence, the external appearance of the vehicle lighting device 1 can be excellent.
Next, a modification of the exemplary embodiment is described. The components similar to the components in the exemplary embodiment are denoted by the same numeral references, and the description thereof is omitted.
As shown in
More specifically, the first incidence surface 311A is composed of a first refracting surface 311d formed on the own-lane side (left) and a second refracting surface 31 le formed on the opposite-lane side (right). The second incidence surface 312A is composed of a first refracting surface 312d formed on the own-lane side (left) and a second refracting surface 312e formed on the opposite-lane side (right).
As shown in
As shown in
A first cutoff line portion Ba which includes the own-lane side oblique cutoff line C4 and the opposite-lane side horizontal cutoff line C2 is formed by combining the illumination regions B4 and B2.
As shown in
More specifically, although not being shown, in a similar manner to the light emitted to the front of the vehicle through the first refracting surface 311d of the first incidence surface 311A and the exit surface 32, the light emitted to the front of the vehicle through the first refracting surface 312d of the second incidence surface 312A and the exit surface 32 illuminates a region. The region is a region, the upper edge of which coincides with the own-lane side oblique cutoff line C4, and which is larger than the illumination region B4 in the left direction and in the down direction. Also, in a similar manner to the light emitted to the front of the vehicle through the second refracting surface 311e of the first incidence surface 311A and the exit surface 32, the light emitted to the front of the vehicle through the second refracting surface 312e of the second incidence surface 312A and the exit surface 32 illuminates a region. The region is a region, the upper edge of which coincides with the opposite-lane side horizontal cutoff line C2, and which is larger than the illumination region B2 in the right direction and in the down direction. The second cutoff line portion Da which includes the own-lane side oblique cutoff line C4 and the opposite-lane side horizontal cutoff line C2 is formed by combining these regions.
Low beams Pa are formed by combining the diffusion light distribution portion R, which is formed by the third incidence surface 313 and the exit surface 32, with the first cutoff line portion Ba and the second cutoff line portion Da. The low beams Pa include the own-lane side oblique cutoff line C4 which is inclined at an angle of about 15 degrees.
The vehicle lighting device 1A of the modification can obtain the same advantageous effects as the vehicle lighting device 1 of the exemplary embodiment.
The presently disclosed subject matter is not limited to the exemplary embodiment and the modification, and, needless to say, appropriate changes and improvements can be made.
For example, in the exemplary embodiment and the modification, the first incidence surface 311 or 311A and the second incidence surface 312 or 312A are composed of three or two refracting surfaces, whereby the first cutoff line portion B or Ba and the second cutoff line portion D or Da are formed. Alternatively, light blocking materials which can form cutoff lines may be provided for the light-emitting portions of the LEDs 2.
More specifically, as shown in
Furthermore, as shown in
The exit surface 32 of the projector lens 3 is not necessary to be an inclined plane. As long as a desired light distribution pattern can be obtained with the incidence surfaces 31, the exit surface 32 may be an adjustable surface such as a two-dimensional surface.
Bracket 4 which holds the LEDs 2 can be made of a material having excellent thermal conductivity, such as an aluminum alloy, in order to effectively remove heat generated by the LEDs 2. It is also possible to place an element between the bracket 4 and the LEDs 2, for example, an element which facilitates thermal conduction, such as thermal conductive grease.
According to the exemplary embodiment of the presently disclosed subject matter, there is provided a vehicle lighting device including: a plurality of semiconductor light-emitting devices; a projector lens which illuminates a front of a vehicle with light emitted from the semiconductor light-emitting devices, the projector lens including: a plurality of incidence surfaces which performs main control of light distribution, and respectively corresponds to the semiconductor light-emitting devices; and a single exit surface including a plurality of exit regions which emits the light entering through the incidence surfaces into the projector lens, wherein the exit regions provided next to each other overlap with each other.
In the vehicle lighting device, the incidence surfaces can include a cutoff-line-making incidence surface which makes a cutoff line of a low beam, and the cutoff-line-making incidence surface includes: a first refracting surface provided on an own-lane side of the cutoff-line-making incidence surface, the first refracting surface which makes an own-lane side horizontal cutoff line; a second refracting surface provided on an opposite-lane side of the cutoff-line-making incidence surface, the second refracting surface which makes an opposite-lane side horizontal cutoff line; and a third refracting surface provided between the first refracting surface and the second refracting surface of the cutoff-line-making incidence surface, the third refracting surface which makes an oblique cutoff line connecting the own-lane side horizontal cutoff line to the opposite-lane side horizontal cutoff line.
In the vehicle lighting device, the incidence surfaces can include a cutoff-line-making incidence surface which makes a cutoff line of a low beam, and the cutoff-line-making incidence surface includes: a first refracting surface provided on an own-lane side of the cutoff-line-making incidence surface, the first refracting surface which makes an own-lane side oblique cutoff line; and a second refracting surface provided on an opposite-lane side of the cutoff-line-making incidence surface, the second refracting surface which makes an opposite-lane side horizontal cutoff line.
In the vehicle lighting device, the semiconductor light-emitting devices can include a blocking-material-provided light-emitting device provided with a light blocking material in front of a light-emitting portion of the blocking-material-provided light-emitting device, and the light blocking material blocks a part of light emitted from the blocking-material-provided light-emitting device so as to make a cutoff line of a low beam.
According to the exemplary embodiment and the modification of the presently disclosed subject matter, a projector lens includes a plurality of incidence surfaces respectively corresponding to a plurality of semiconductor light-emitting devices, and a single exit surface. The exit surface includes a plurality of exit regions which emits light entering through the incidence surfaces into the projector lens, respectively. The exit regions which are next to each other overlap with each other. Consequently, the light emitted from the semiconductor light-emitting devices can be emitted from the single exit surface with no gap. Accordingly, on the contrary to the case where a plurality of projector lenses is arranged or connected, the exit surface can emit light as a whole, and a vehicle lighting device looks excellent when emitting light.
Furthermore, because the plurality of incidence surfaces performs the main control of the light distribution, on the contrary to the case where a plurality of convex exit surfaces which performs the control of the light distribution is arranged or connected, the exit surface can be a single surface having high degree of freedom in designing. Accordingly, the exit surface which acts as a light-emitting portion (a light-emitting portion of the vehicle lighting device) can be formed in a smooth shape, and can fit the design of the eternal appearance of a vehicle. Hence, the external appearance of the vehicle lighting device can be excellent.
The entire disclosure of Japanese Patent Application No. 2010-268049 filed on Dec. 1, 2010 including description, claims, drawings, and abstract are incorporated herein by reference in its entirety.
Although various exemplary embodiments have been shown and described, the presently disclosed subject matter is not limited to the exemplary embodiments shown. The scope of the presently disclosed subject matter is intended to be limited solely by the scope of the claims that follow.
Number | Date | Country | Kind |
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JP2010-268049 | Dec 2010 | JP | national |