The present invention relates to a headlight for moving object, and particularly, relates to a light source for the headlight.
Conventionally, as a light source for vehicle-mounted headlight, an electric lamp employing a tungsten filament as a light emitting body, an electric-discharge lamp emitting light through arc discharge, or the like is used.
Further, recently, in place of electric lamps and electric-discharge lamps, light emitting diodes (LEDs) have become widespread. Because LEDs have a long life, can ensure brightness needed for headlights with low power consumption, and can stabilize brightness under a simple control operation of supplying a constant current thereto, LEDs are suitable for use as light sources for vehicle-mounted headlight. Further, LEDs have many variations in size and brightness, so that the number of light sources used to form a light distribution of a headlight, and the shape of each of the light sources can be selected freely. Therefore, a headlight with high originality or a reduced size headlight which, conventionally, was not able to be implemented because of restrictions on the number of light sources or their shapes can be implemented.
In each of Patent Literatures 1 to 3, a headlight having alight source, a reflector for reflecting light emitted by the light source, and a projection lens for projecting the light reflected by the reflector onto an area ahead of a vehicle is disclosed. In particular, in each of Patent Literatures 2 and 3, a headlight in which an LED is used as a light source, and a reflector and a projection lens being integrally formed of a transparent material is also disclosed.
Patent Literature 1: Japanese Unexamined Utility Model (Registration) Application Publication No. Hei 1-130203 (1989-130203)
Patent Literature 2: Japanese Unexamined Patent Application Publication No. 2010-108639
Patent Literature 3: Japanese Unexamined Patent Application Publication No. 2012-84330
In recent years, there is a demand for further downsizing vehicle-mounted headlights, and a demand for further downsizing light sources for vehicle-mounted headlights. As a method of implementing downsizing of light sources, a method of shortening the focal length of a projection lens can be considered. However, generally, a convex lens with a short focal length has a large curvature, and it is therefore difficult to form such a convex lens. Further, various kinds of aberration tend to become large, and it is therefore difficult to produce a lens having desired optical characteristics. Therefore, it is difficult to form a projection lens by using a single convex lens while shortening the focal length.
To cope with this problem, a configuration in which an auxiliary convex lens opposite to a projection lens is disposed, thereby shortening the focal length with a combination of two convex lenses can be considered. However, in this configuration, the number of parts increases due to the auxiliary convex lens, and this results in increase in the cost.
The reflector and the projection lens which are described in Patent Literatures 1 to 3 do not fully utilize their optical characteristics in order to downsize the light source.
The present invention is made for solving the above-mentioned problems, and it is therefore an object of the present invention to provide a light source for headlight that can shorten its focal length without increasing the number of parts. Another object of the present invention is to provide a headlight for a moving object which employs such a light source for headlight.
A light source for headlight according to the present invention includes: a light emitting element; and a light guide member having a reflection surface part reflecting light emitted by the light emitting element, and a projection lens part projecting the light reflected by the reflection surface part onto an area ahead of a moving object. The light emitting element is arranged to be displaced from an optical axis of the projection lens part. The reflection surface part is in a shape of a concave mirror having an optical axis and one focal point on the optical axis. An optical center which is an intersection of the reflection surface part and the optical axis of the reflection surface part is arranged on the optical axis of the projection lens part and between the projection lens part and a focal point of the projection lens part. The optical axis of the reflection surface part is oriented in a direction passing a position between a central part of a light emitting surface of the light emitting element and a central part of the projection lens part.
A headlight for a moving object according to the present invention includes the light source for headlight described above.
According to the light source for headlight of the present invention, the focal length can be shorten, without increasing the number of parts in comparison with a configuration in which an auxiliary convex lens is disposed. Further, according to the present invention, a headlight for moving object which employs this light source for headlight can be provided.
Hereafter, in order to explain the present invention in more detail, some embodiments of the present invention will be described with reference to the accompanying drawings.
The light emitting element 1 is, for example, a semiconductor light emitting element, such as a light emitting diode (LED), an organic light emitting diode (OLED), or a laser diode (LD). The light emitting element 1 emits light from a light emitting surface 11 when an electric current is supplied.
The light emitting element 1 is fixed to a fixing member 2. The fixing member 2 is, for example, a circuit board for semiconductor light emitting element, and functions as a heat radiating member for dissipating heat generated by the light emitting element 1.
The light guide member 3 is arranged opposite to the light emitting surface 11 of the light emitting element 1. The light guide member 3 is integrally formed of, for example, a transparent resin, such as acrylics or polycarbonate, or glass. The light guide member 3 has an incidence surface part 31 to which light emitted by the light emitting element 1 is incident, a reflection surface part 32 that reflects the light incident from the incidence surface part 31, and a projection lens part 33 that focuses the light reflected by the reflection surface part 32 and projects the light onto an area ahead of a vehicle.
Further, in the light guide member 3, a reflection surface part for light distribution formation 34 is formed between the incidence surface part 31 and the reflection surface part 32. The reflection surface part for light distribution formation 34 reflects apart of the light incident to the incidence surface part 31, thereby forming a light distribution used in a case when the light source is used for a low-beam light of a vehicle-mounted headlight.
An example of the low-beam light distribution of the vehicle-mounted headlight is shown in
The light emitting element 1, the fixing member 2, and the light guide member 3 compose the light source for headlight 100. Namely, the light source for headlight 100 shown in
Next, a detailed configuration of the light source for headlight 100 will be explained with reference to
As shown in
The reflection surface part 32 is formed in the shape of a concave mirror having an optical axis C2 and also having one focal point F2 on the optical axis C2. Concretely, the reflection surface part 32 has a shape extending along, for example, a paraboloid or a spherical surface. In the example shown in
Further, the optical axis C2 of the reflection surface part 32 is oriented toward the center of an angle θ1 which the optical axis C1 of the projection lens part 33 forms with a straight line L1 passing through the optical center O of the reflection surface part 32 and the central part of the edge 35 of the reflection surface part for light distribution formation 34, the edge being on a side of the reflection surface part 32. In the example shown in
Further, an edge 12 of the light emitting surface 11 of the light emitting element 1, the edge being on the rear side of the vehicle, is arranged on a surface S2 extending along the reflection surface part for light distribution formation 34. In the example of
Next, an operation and effects of the light source for headlight 100 will be explained with reference to
Because the optical axis C2 of the reflection surface part 32 is oriented toward the center of the angle θ1 which the optical axis C1 forms with the straight line L1, the reflection surface part 32 reflects the light which is emitted by the light emitting element 1 and is incident to the incidence surface part 31 toward the projection lens part 33. At this time, because the reflection surface part 32 is in the shape of a concave mirror having the focal point F2, the incident light is reflected and converged by the reflection surface part 32 to be a reflected light. Further, because the optical center O of the reflection surface part 32 is arranged between the projection lens part 33 and the focal point F1 of the projection lens part 33, the projection lens part 33 further converges the light converged by the reflection surface part 32 and projects the light onto an area ahead of the vehicle.
As described above, due to the configuration in which the projection lens part 33 in the shape of a convex lens further converges the light converged by the reflection surface part 32 in the shape of a concave mirror, the light source for headlight 100 according to Embodiment 1 can reduce the focal length to less than the focal length in a conventional light source for headlight. Further, by forming the reflection surface part 32 into the shape of a concave mirror, the focal length can be reduced to less than, for example, that in the case in which the reflection surface part is formed into the shape of a plane mirror. More specifically, in the case in which the reflection surface part is formed into the shape of a plane mirror, the focal length (f1+f2′) from the projection lens part 33 to a combined focal point F1′ of the projection lens part 33 and the reflection surface part has the same value as the focal length (f1+f2) from the projection lens part 33 to the focal point F1 of the sole projection lens part 33. In contrast, in the case in which the reflection surface part 32 is formed into the shape of a concave mirror, the focal length (f1+f2″) from the projection lens part 33 to a combined focal point F1″ of the projection lens part 33 and the reflection surface part 32 can be reduced to less than the focal length (f1+f2) from the projection lens part 33 to the focal point F1 of the sole projection lens part 33. By shortening the focal length, like in the case of a configuration in which an auxiliary convex lens opposite to the projection lens part 33 is disposed as a member separate from the light guide member 3, the light source for headlight 100 can be downsized.
Note that, in the configuration of shortening the focal length by using the combination of the projection lens part 33 and the reflection surface part 32 in the shape of a concave mirror, the above-mentioned auxiliary convex lens is not required so that the number of parts can be decreased.
Further, in the configuration of shortening the focal length by using the combination of the projection lens part 33 and the reflection surface part 32 in the shape of a concave mirror, the curvature of the projection lens part 33 can be reduced to less than that in a configuration in which a convex lens having a short focal length is used as the projection lens part 33. For this reason, the forming of the projection lens part 33 can be facilitated and the forming accuracy can be improved. Further, aberration of the projection lens part 33 can be reduced.
Further, by forming the reflection surface part 32 into the shape of a concave mirror extending along the paraboloid S1, the occurrence of chromatic aberration by the reflection surface part 32 can be prevented. By combining the projection lens part 33 having a small curvature, and the reflection surface part 32 having no chromatic aberration, the color separation occurring in the vicinity of the cutoff line CL in the low-beam light distribution can be suppressed.
Further, by arranging the edge 12 of the light emitting surface 11 of the light emitting element 1 on the surface S2, the edge being on the rear side of the vehicle, the whole surface of the light emitting surface 11 is positioned opposite to the incidence surface part 31. As a result, the light emitted by the light emitting element 1 is effectively used, and the utilization efficiency of the light can be increased.
Further, as shown in
In the case in which the edge 35 of the reflection surface part for light distribution formation 34 is formed into a linear shape as shown in
To solve this problem, as shown in
The shape of the edge 35 of the reflection surface part for light distribution formation 34 is not limited to any of the ones shown in
First, by inclining the edge 35 of the reflection surface part for light distribution formation 34 in the front-rear direction of the vehicle, the cutoff line CL can be inclined in the vertical direction.
Concretely, for example, as shown in
As an alternative, for example, from the state shown in
In this case, the cutoff line CL has a shape which gradually rises from the opposite lane side thereof toward the sidewalk side thereof.
By inclining a part or all of the cutoff line CL in the low-beam light distribution, to enlarge the illumination area on the sidewalk side in the upward direction relatively to the illumination area on the opposite lane side, a light distribution which prevents the drivers of oncoming vehicles from being dazzled while making it easy for the driver of the user's vehicle to visually recognize the sidewalk can be implemented.
Further, by rotating the light guide member 3 shown in
Further, the edge 35 of the reflection surface part for light distribution formation 34 can be formed into a curved shape in such away that the center thereof protrudes, relative to both ends thereof, toward the rear or front side of the vehicle.
For example, as shown in
Next, some modifications of the light source for headlight 100 will be explained with reference to
As shown in
Further, as shown in
In the light source for headlight 100 in which the light emitting element 1 is arranged below the optical axis C1, as shown in
Further, the optical axis C2 of the reflection surface part 32 can be disposed in such a way that the optical axis C2 is not oriented strictly toward the center of the angle θ1 which the optical axis C1 forms with the straight line L1, and may be oriented in such a way that there is a difference between the angle θ2 and the angle θ3. By at least orienting the optical axis C2 of the reflection surface part 32 in such a way that the optical axis C2 passes between the light emitting element 1 and the projection lens parts 33, the reflection surface part 32 can be made to reflect the light emitted by the light emitting element 1 toward the projection lens part 33.
Further, the reflection surface part 32 may have a reflection structure which differs dependently on the incident angle of the light.
More specifically, the minimum value of the incident angle at which the reflection surface part 32 can total-reflect the light is called the “critical angle”, and the value of the critical angle is determined by both the index of refraction of a transparent material which constructs the light guide member 3, and the index of refraction of the air outside the light guide member 3. In a case in which the reflection surface part 32 is oriented in such a way that the incident angle is equal to or larger than the critical angle, the reflection surface part 32 can total-reflect the light at the internal surface portion of the light guide member 3. On the other hand, in a case in which the reflection surface part 32 is oriented in such a way that the incident angle is smaller than the critical angle, the reflection surface part 32 cannot total-reflect the light at the internal surface portion of the light guide member 3, so that a part of the incident light leaks out of the light guide member 3.
Then, in a case in which the reflection surface part 32 is oriented in such a way that the incident angle is smaller than the critical angle, in the reflection surface part 32, the external surface of the light guide member 3 is plated by using, for example, vacuum deposition of metal such as silver or aluminum. By reflecting the light with this plating, the light can be prevented from leaking out of the light guide member 3, so that the utilization efficiency of the light can be increased. Further, instead of the plating, a coating including plural layers of materials having different indices of refraction, respectively, may be laminated on the external surface of the light guide member 3, so that a light reflection layer is formed on the external surface.
In contrast, in a case in which the reflection surface part 32 is oriented in such a way that the incident angle is equal to or larger than the critical angle, the plating or the coating is not required, and the reflection surface part 32 is configured so as to total-reflect the incident light at the internal surface of the light guide member 3. As a result, the manufacturing cost of the light source for headlight 100 can be reduced in comparison with the case in which the plating or the like is required.
Further, the reflection surface part for light distribution formation 34 may form a light distribution of a cornering lamp or a fog lamp instead of or in addition to the low-beam light distribution. Namely, the light source for headlight 100 for low-beam light can also be used as a light source for cornering lamp or a light source for fog lamp. In other words, the use of the light source for headlight 100 for low-beam light is not limited to the low-beam light.
Further, the arrangement position of the combined focal point F1″ is not limited to the positions shown in
Further, the light emitting surface 11 of the light emitting element 1 and the incidence surface part 31 of the light guide member 3 do not have to be parallel to each other, and the optical axis C1 of the projection lens part 33 and the normal N of the light emitting surface 11 at the central part thereof do not have to be perpendicular to each other.
Further, the headlight in which the light source for headlight 100 according to Embodiment 1 is disposed is not limited to a vehicle-mounted headlight. The light source for headlight 100 can be used for a headlight for any type of moving object including a vehicle, a rail car, a ship, or an airplane.
As described above, a light source for headlight 100 according to Embodiment 1 includes: a light emitting element 1; and a light guide member 3 having a reflection surface part 32 reflecting light emitted by the light emitting element 1, and a projection lens part 33 projecting the light reflected by the reflection surface part 32 onto an area ahead of a moving object. The light emitting element 1 is arranged to be displaced from an optical axis C1 of the projection lens part 33. The reflection surface part 32 is in a shape of a concave mirror having an optical axis C2 and one focal point F2 on the optical axis C2. An optical center O which is an intersection of the reflection surface part 32 and the optical axis C2 of the reflection surface part 32 is arranged on the optical axis C1 of the projection lens part 33 and between the projection lens part 33 and a focal point F1 of the projection lens part 33. The optical axis C2 of the reflection surface part 32 is oriented in a direction passing a position between a central part of a light emitting surface of the light emitting element 1 and a central part of the projection lens part 32. With a configuration in which the projection lens part 33 in the shape of a convex lens further focuses light focused by the reflection surface part 32 in the shape of a concave mirror, an auxiliary convex lens becomes unnecessary so that the number of parts is reduced, and the focal length can be shortened so that the light source for headlight 100 can be further downsized. Further, in comparison with the configuration of shortening the focal length of the projection lens part 33 by increasing the curvature of the projection lens part 33, the forming of the projection lens part 33 can be facilitated, the forming accuracy can be increased, and the aberration of the projection lens part 33 can be reduced.
Further, the light source for headlight 100 is a light source for low-beam light. The light guide member 3 has a reflection surface part for light distribution formation 34 disposed between the light emitting element 1 and the reflection surface part 32. An edge 35 of the reflection surface part for light distribution formation 34, the edge being on a side of the reflection surface part 32, is arranged at a combined focal point F1″ of the projection lens part 33 and the reflection surface part 32. The optical axis C2 of the reflection surface part 32 is oriented toward a center of an angle θ1 which the optical axis C1 of the projection lens part 33 forms with a straight line L1 passing through the optical center O of the reflection surface part 32 and a central part of the edge 35 of the reflection surface part for light distribution formation 34, the edge being on a side of the reflection surface part 32. By disposing the reflection surface part for light distribution formation 34, the light source for low-beam light can be configured. Further, this light source for low-beam light can also be used as a light source for a vehicle-mounted cornering lamp or a light source for a vehicle-mounted fog lamp.
Further, The light emitting element 1 is arranged above the optical axis C1 of the projection lens part 33. An edge 13 of the light emitting surface 11 of the light emitting element 1, the edge being on a front side of the moving object, is arranged either on a surface S2 extending along the reflection surface part for light distribution formation 34, or closer to a rear side of the moving object with respect to the surface S2 extending along the reflection surface part for light distribution formation 34. Alternatively, in the light source for headlight 100, the light emitting element 1 is arranged below the optical axis C1 of the projection lens part 33. An edge 12 of the light emitting surface 11 of the light emitting element 1, the edge being on a rear side of the moving object, is arranged either on a surface S2 extending along the reflection surface part for light distribution formation 34, or closer to a front side of the moving object with respect to the surface S2 extending along the reflection surface part for light distribution formation 34. As a result, the whole surface of the light emitting surface 11 is positioned opposite to the incidence surface part 31, so that the utilization efficiency of the light can be increased.
Further, the edge 35 of the reflection surface part for light distribution formation 34, the edge being on the side of the reflection surface part 32, is formed into a curved shape in such a way that both ends thereof are closer to the optical axis C1 of the projection lens part 33 than a center thereof. By matching the curvature of the edge 35 with that of the projection lens part 33, the whole edge 35 of the reflection surface part for light distribution formation 34 is arranged at the combined focal point F1″ of the projection lens part 33 and the reflection surface part 32, and the whole cutoff line CL in the low-beam light distribution can be made sharper.
Further, the edge 35 of the reflection surface part for light distribution formation 34, the edge being on the side of the reflection surface part 32, is shaped in such a way that at least a part thereof is inclined in a front-rear direction of the moving object. As a result, a light distribution in which the cutoff line CL on the sidewalk side is inclined upward can be formed, and the degree of flexibility of the arrangement of the light emitting element 1 for a required cutoff line CL can be increased.
Further, the edge 35 of the reflection surface part for light distribution formation 34, the edge being on the side of the reflection surface part 32, is formed into a curved shape in such a way that a center thereof protrudes toward a rear or front side of the moving object in comparison with both ends thereof. As a result, a light distribution in which the cutoff line CL is curved in the vertical direction can be formed.
Further, the reflection surface part 32 is configured so as to receive incident light emitted by the light emitting element 1 incident to the reflection surface part at an angle equal to or larger than a critical angle and reflect the incident light at an internal surface portion of the light guide member 3, or so as to reflect incident light emitted by the light emitting element 1 with a plating or a coating formed on an external surface portion of the light guide member 3. In the case in which the reflection surface part 32 is oriented in such a way that the incident angle is smaller than the critical angle, by reflecting the light with the plating or the coating, the light can be prevented from leaking out of the light guide member 3, so that the utilization efficiency of the light can be increased. On the other hand, in the case in which the reflection surface part 32 is oriented in such a way that the incident angle is equal to or larger than the critical angle, the plating or the coating becomes unnecessary, and the manufacturing cost of the light source for headlight 100 can be reduced.
Some modifications of the light source for headlight 100 will be explained with reference to
In the light source for headlight 100 shown in
The refracting member 5 refracts the light emitted from the central part of the light emitting surface 11 of the light emitting element 1 in such a way that the light travels toward the central part of the edge 35 of the reflection surface part for light distribution formation 34, the edge being on the side of the reflection surface part 32, as shown by an arrow A1 in the figure. As a result, in the low-beam light distribution, a light distribution which has the highest degree of brightness just below the central part of the cutoff line and gradually becomes dark with the distance from the central part can be acquired.
When both right and left ends of the low-beam light distribution are made too bright, the boundary between the illuminated area and a dark area outside the illuminated area is conspicuous, and which is felt unnatural by the driver. Further, when a lower edge portion of the low-beam light distribution is made too bright, such a light distribution rather makes it difficult for the driver to recognize an area ahead of the vehicle, because the light is reflected on the road. In contrast with these cases, by providing the low-beam light distribution in which the brightness is the highest just below the central part of the cutoff line and gradually becomes dark with the distance from the central part, the light distribution can reduce the driver's feeling of unnaturalness and makes it possible for the driver to easily recognize an area ahead of the vehicle.
In the light source for headlight 100 shown in
In the light source for headlight 100 shown in
In general, light which is emitted by a semiconductor light emitting element, such as an LED, from the light emitting surface 11 thereof is diffused light, and in addition to emitting the strongest light in the direction along the normal N, weak light is emitted in directions other than the direction of the normal N. The incidence part 38 reflects light traveling toward directions different from the direction of the normal N, the light being included in the light emitted by the light emitting element 1, toward either the reflection surface part 32 or the reflection surface part for light distribution formation 34, as shown by an arrow A2 in the figure. In a configuration not having the incidence part 38, because these light beams do not enter the light guide member 3 and therefore cannot be used for the formation of a light distribution, the utilization efficiency of the light is decreased. By disposing the incidence part 38, these light beams can also be used for the formation of a light distribution, and therefore the utilization efficiency of the light can be increased.
In the light source for headlight 100 shown in
Further, in association with the rotation of the reflection surface part 32, the angle θ1 which the optical axis C1 of the projection lens part 33 forms with the straight line L1 passing through the optical center O and the central part of the edge 35 becomes larger than 90 degrees. As a result, the angle θ2 which the optical axis C1 forms with the optical axis C2 becomes larger than 45 degrees, and the angle θ3 which the straight line L1 forms with the optical axis C2 becomes larger than 45 degrees.
In the example shown in
In the light source for headlight 100 shown in
Because the strongest light traveling along the normal N travels toward the central part of the edge 35 due to the rotation of the reflection surface part 32, without refracting the incident light, the refracting part 37a as shown in
In the light source for headlight 100 shown in
In the light source for headlight 100 shown in
The headlight in which the light source for headlight 100 according to Embodiment 2 is disposed is not limited to a vehicle-mounted headlight. The light source for headlight 100 can be used for a headlight for any type of moving object including a vehicle, a rail car, a ship, or an airplane.
As described above, in the light source for headlight 100 according to Embodiment 2, the normal N of the light emitting surface 11 of the light emitting element 1 at the central part thereof is oriented toward the central part of the edge 35 of the reflection surface part for light distribution formation 34, the edge being on a side of the reflection surface part 32. As a result, a light distribution which has the highest degree of brightness just below the central part of the cutoff line and gradually becomes dark with the distance from the central part can be formed. Namely, a low-beam light which reduces the driver's feeling of unnaturalness and makes it easy for the driver to recognize an area ahead of the moving object can be implemented.
Further, the light emitting element 1 is arranged outside the light guide member 3, and the incidence member 6 for guiding the light emitted by the light emitting element 1 into the light guide member 3 is disposed. The incidence member 6 makes it possible to also use light traveling toward directions different from the direction of the normal N, the light being included in the light emitted by the light emitting element 1, for the light distribution of the light source for headlight 100, so that the utilization efficiency of the light can be further increased.
A light source for headlight 100 in which a light emitting element 1 is enclosed in a light guide member 3 will be explained with reference to
The light source for headlight 100 shown in
The light source for headlight 100 shown in
By arranging the light emitting surface 11 of the light emitting element 1 at the combined focal point F1″, the shape of the light emitting surface 11 is not imaged on an area ahead of the vehicle. Namely, strong light emitted from the light emitting surface 11 in the direction of the normal N is irradiated horizontally onto an area ahead of the vehicle while weak light emitted from the light emitting surface 11 in directions other than the direction of the normal N is irradiated onto surrounding areas, so that the light distribution of a high-beam light can be formed as shown in
The light source for headlight 100 shown in
The light source for headlight 100 shown in
The principle of the specific direction illumination light will be explained with reference to
In this case, the distance between the convex lens 33′ and the light emitting surface 11 is denoted by La, the distance between the convex lens 33′ and the real image 11′ is denoted by Lb, the width of the light emitting surface 11 of the light emitting element 1 is denoted by Wa, and the width of the real image 11′ is denoted by Wb. La, Lb, Wa, and Wb satisfy a relationship shown by the following equation (1).
Wb/Wa≈Lb/La (1)
Namely, the real image 11′ has an enlarged size which is Lb/La times as large as the light emitting surface 11. As a result, as shown in
When the focal length of the convex lens 33′ is denoted by L (i.e., L is equal to f1+f2″ shown in
Lb/La=1/{(La/L)−1} (2)
Namely, the magnification of the real image 11′ to the light emitting surface 11 can be set in accordance with the space between the light emitting surface 11 and the focal point F1″. Concretely, for example, by making the space between the light emitting surface 11 and the focal point F1″ equal to 1/100 of the focal length of the convex lens 33′, i.e., 1/100 of the combined focal length of the projection lens part 33 and the reflection surface part 32, the size of the real image 11′, i.e., the size of the area illuminated with the specific direction illumination light can be made 100 times as large as the area of the light emitting surface 11. Similarly, by making the space between the light emitting surface 11 and the focal point F1″ equal to 1/1,000 of the combined focal length, the size of the area illuminated with the specific direction illumination light can be made 1,000 times as large as the area of the light emitting surface 11.
By disposing a plurality of light sources for specific direction illumination light in a headlight, and, with setting the illumination areas of the light sources to be different from one another, controlling switching on and off of each of the light sources individually, it is possible, for example, to illuminate an obstacle existing ahead of the vehicle brightly, so that the driver's attention is drawn. As an alternative, by selectively switching off light sources each of which irradiates light to oncoming vehicles, a light distribution which prevents the drivers of oncoming vehicles from being dazzled like in the case of the low-beam light, while making it easy for the driver of the user's vehicle to visually recognize an area excluding oncoming vehicles can be implemented.
The light source for headlight 100 which is used for a specific direction illumination light can also be used as a light source for sign pole illumination which irradiates light to a motorway direction sign (a so-called “sign pole”) during travel of the vehicle. In this way, the use of the light source for headlight 100 for specific direction illumination light is not limited to the above-mentioned light source.
The light source for headlight 100 shown in
In each of the light sources for headlight 100 explained in Embodiments 1 to 3, which is used for a low-beam light and in which the light emitting element 1 is arranged outside the light guide member 3, instead of forming a reflection surface part for light distribution formation in the light guide member 3, a reflecting member for light distribution formation may be enclosed in the light guide member 3, like in the case of the light source for headlight 100 shown in
Further, the headlight in which the light source for headlight 100 according to Embodiment 3 is disposed is not limited to a vehicle-mounted headlight. The light source for headlight 100 can also be used for a headlight for any type of moving object including a vehicle, a rail car, a ship, or an airplane.
As described above, in the light source for headlight 100 according to Embodiment 3, the light emitting element 1 is enclosed in the light guide member 3. As a result, a positional displacement of the light emitting element 1 with respect to the light guide member 3 can be prevented in a state in which the light source for headlight 100 is assembled, so that the light source for headlight 100 can be easily handled.
Further, the light source for headlight 100 is a light source for low-beam light. The light guide member 3 has a reflection surface part for light distribution formation 34 disposed between the light emitting element 1 and the reflection surface part 32. An edge 35 of the reflection surface part for light distribution formation 34, the edge being on a side of the reflection surface part 32, is arranged at a combined focal point F1″ of the projection lens part 33 and the reflection surface part 32. The optical axis C2 of the reflection surface part 32 is oriented toward a center of an angle θ1′ which the optical axis C1 of the projection lens part 33 forms with a straight line L2 passing through the optical center O of the reflection surface part 32 and the central part of the light emitting surface 11 of the light emitting element 1. By disposing the reflection surface part for light distribution formation 34, a light source for low-beam light can be configured. Further, such a light source for low-beam light can also be used as a light source for vehicle-mounted cornering lamp, and a light source for vehicle-mounted fog lamp.
Further, the light source for headlight 100 is a light source for high-beam light. The central part of the light emitting surface 11 of the light emitting element 1 is arranged at a combined focal point F1″ of the projection lens part 33 and the reflection surface part 32. The optical axis C2 of the reflection surface part 32 is oriented toward a center of an angle θ1′ which the optical axis C1 of the projection lens part 33 forms with a straight line L2 passing through the optical center O of the reflection surface part 32 and the central part of the light emitting surface 11 of the light emitting element 1. By arranging the central part of the light emitting surface 11 at the combined focal point F1″, a light source for high-beam light can be configured. Further, such a light source for high-beam light can also be used as a light source for vehicle-mounted DRL.
Further, the light source for headlight 100 is a light source for specific direction illumination light. The central part of the light emitting surface 11 of the light emitting element 1 is arranged apart from the optical axis C1 of the projection lens part 33 at a longer distance than a combined focal point F1″ of the projection lens part 33 and the reflection surface part 32. The optical axis C2 of the reflection surface part 32 is oriented toward a center of an angle θ1′ which the optical axis C1 of the projection lens part 33 forms with a straight line L2 passing through the optical center O of the reflection surface part 32 and the central part of the light emitting surface 11 of the light emitting element 1. By arranging the central part of the light emitting surface 11 apart from the optical axis C1 at a longer distance than the combined focal point F1″, a light source for specific direction illumination light can be configured. Further, such a light source for specific direction illumination light can also be used as a light source for sign pole illumination.
A vehicle-mounted headlight 200 in which light sources for headlight 100 each according to any of Embodiments 1 to 3 are disposed will be explained with reference to
In the figure, the numeral 8 denotes a case. The case 8 has a front opening, and a front lens 81 is disposed in this front opening. In the case 8, a plurality of light sources for headlight 100 is arranged, and a projection lens part 33 of each of the light sources for headlight 100 is oriented toward the front lens 81. The headlight 200 is configured in this way.
The headlight 200 can implement various light distributions by freely selecting, as each of the plurality of light sources for headlight 100, a light source for headlight from among the light sources for headlight 100 illustrated in Embodiments 1 to 3, and their modifications. Hereafter, examples of a light distribution implemented by the headlight 200 will be explained with reference to
For example, in the headlight 200, the light source for headlight 100 shown in
As an alternative, in the headlight 200 which forms a light distribution shown in
As an alternative, in the headlight 200 which forms a light distribution shown in
As an alternative, in the headlight 200, a combination of a light source for headlight 100 which is used for a low-beam light, and a plurality of light sources for headlight 100 which are used for a specific direction illumination light is used. For example, it is assumed that each of the light sources for headlight 100 which are used for the specific direction illumination light illuminates an area including an area above the cutoff line CL, and illuminates an area different and adjacent to each other, as shown in
As described above, since the number of light sources for headlight 100 and the light distribution of each of the light sources for headlight 100 can be freely selected, the degree of flexibility in the design of the internal structure, the external shape, the light distribution formation, and so on of the headlight 200 can be increased. As a result, a headlight 200 suitable for the use, the requirement specifications, and so on can be easily configured.
As described above, the headlight 200 according to Embodiment 4 includes light sources for headlight 100. By freely combining a plurality of light sources for headlight 100 each of which is a light for a low-beam light, a high-beam light, or a specific direction illumination light, the degree of flexibility in the design of the headlight 200 can be increased.
It is to be understood that any combination of two or more of the above-mentioned embodiments can be made, various modifications can be made in any component according to any one of the embodiments, and any component according to any one of the embodiments can be omitted within the scope of the invention.
The light source for headlight according to the present invention can be used for a headlight for a moving object such as a vehicle, a rail car, a ship, or an airplane. In particular, the light source for headlight is suitable for a vehicle-mounted headlight.
1 light emitting element, 2 fixing member, 3 light guide member, 4 screw, 5 refracting member, 6 incidence member, 7 reflecting member for light distribution formation, 8 case, 11 light-emitting surface, 12 edge, 13 edge, 31 incidence surface part, 32 reflection surface part, 33 projection lens part, 34 reflection surface part for light distribution formation, 35 edge, 36 fixing part, 37, 37a refracting part, 38, 38a incidence part, 81 front lens, 100 light source for headlight, and 200 headlight.
Filing Document | Filing Date | Country | Kind |
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PCT/JP2015/078905 | 10/13/2015 | WO | 00 |