1. Field of the Invention
The present invention relates to a vehicle headlight, and more particularly to a poly-ellipsoid system (PES) vehicle headlight capable of compensating for light intensity of a dark region.
2. Description of the Related Art
When vehicles run on the road, to accommodate different traffic situations and visual demands, vehicle headlights may be classified into high-beam headlights, low-beam headlights, and vehicle headlights capable of being switched between the high-beam headlight and the low-beam headlight, and recently the design applied to the vehicle headlight is called a poly-ellipsoid system (PES) vehicle headlight. Referring to
Referring to
The insufficient light intensity in the dark region may affect safety during driving, so recently many designs for compensating for the light intensity in the dark region of the low-beam headlight were proposed. Referring to FIG. 2, for example, in U.S. Pat. No. 6,736,533, in the vehicle headlight of the prior art, an auxiliary shielding board 72 is added on a front side of a light shield 71, and the auxiliary shielding board 72 may reflect a part of the light rays emitted downwards, such that after passing through the lens 73, the light rays form compensation light rays A1 refracted upwards and are emitted, thereby compensating for the light intensity in the dark region. Referring to FIG. 3, in the US patent, a perforation 810 is opened on a light shield 81, and an auxiliary shielding board 82 is disposed on an inner side of the light shield 81, such that light intensity in the dark region is compensated through the modified structures.
On the other hand, some vehicle headlights can be switched between the high-beam headlight and the low-beam headlight, in which case, an electromagnetic valve is used to drive a modulatable light shield to rotate, thereby changing an outward projecting path of the light rays, so as to switch between the high-beam headlight and the low-beam headlight. However, the light shield 71 and the auxiliary shielding board 72 are combined in a link-up manner, and the perforation 810 is disposed on the light shield 81. The structural modification of the light shields 71 and 81 may compensate for light intensity of the dark region, but the demands of the high-beam headlight cannot be met. Therefore, the above design for compensating for light intensity in the dark region is applied to only the low-beam headlight, and cannot be applied to the vehicle headlight capable of being switched between the high-beam headlight and the low-beam headlight. Therefore, the design applicability is poor, and needs to be modified.
In addition, in U.S. Pat. No. 6,494,603, the light shield disposed in front of the light source is used to compensate for light intensity of the dark region, but the light shield and a supporting case are integrally formed by casting. During casting, the accuracy must be improved; otherwise, after the light shield is shaped, the disposition angle easily generates deviation, such that the light rays cannot be reflected to a preset direction. Moreover, the design cannot be applied to the vehicle headlight capable of being switched between the high-beam headlight and the low-beam headlight.
The present invention is directed to a vehicle headlight, having a simple light guide structure and a better applicability, and capable of compensating for light intensity in a dark region.
The present invention provides a vehicle headlight capable of compensating for light intensity in a dark region, which includes a lamp holder, a light source, a light shield, and a light guide. The lamp holder includes a reflector, a case attached to a front side of the reflector and defining an accommodation space together with the reflector, and a lens installed on a front side of the case. The light source is installed in the accommodation space and disposed along an optical axis, and light rays emitted from the light source are refracted by the lens and emitted forwards.
The light shield is assembled on the lamp holder and located between the light source and the lens, and the light shield is used to shield some of the light rays emitted from the light source. The light guide is disposed in the accommodation space and located between the light shield and the lens, and has a light incident surface facing the light shield and a light exit surface facing the lens. The light exit surface increasingly extends backwards from top to bottom. The light guide conducts the light rays from the light source towards the lens, such that the light rays conducted from the lens are emitted forwards and upwards.
The patent or application file contains at least one drawing executed in color. Copies of this patent or patent application publication with color drawing(s) will be provided by the Office upon request and payment of the necessary fee.
A detailed description of the above and other technical contents, features, and efficacies of the present invention is given as follows with accompanying drawings and a preferred embodiment.
Referring to
The lamp holder 1 includes a reflector 11, a case 12 and a lens 13. The reflector 11 surrounds a horizontally extending optical axis L and has a light emission installing portion 111 installed on a back side of the reflector 11. The case 12 is screwed on a front side of the reflector 11 and defines an accommodation space 10 together with the reflector 11. The lens 13 is installed on a front side of the case 12. The lens 13 is assembled on the case 12 and is located in front of the light source 2, and refracts the light rays emitted from the light source 2, such that the light rays are emitted forwards. The light source 2 is installed on the light emission installing portion 111 and extends towards the accommodation space 10, and a central position of the light source 2 is located on the optical axis L.
A peripheral profile of the light shield 3 is designed to match the reflector 11, and is screwed between the reflector 11 and the case 12. The light shield 3 includes a light shielding portion 31 and a connection portion 32. The light shielding portion 31 is located on a lower part. The connection portion 32 extends upwards from left and right sides of the light shielding portion 31 and defines a light transmissive space 30 together with the light shielding portion 31. The light shield 3 is used to shield a part of the light rays emitted from the light source 2.
The light guide 4 may be made of glass, polyethersulfone (PES), Indium Tin oxide (ITO), polyvinyl chloride (PVC) material, or other light transmissive materials. In order to prevent the light guide 4 from being affected by the heat energy of the light source 2, the light guide 4 is made of a material with excellent heat resistance. The light guide 4 is located between the light shield 3 and the lens 13, and includes a light transmissive portion 41 and a base 42. The light transmissive portion 41 is located on an upper part thereof. The base 42 extends downwards from the light transmissive portion 41 and connected to the case 12.
Some of the light rays emitted from the light source 2 are emitted forwards through the light transmissive portion 41. The light transmissive portion 41 has a light incident surface 411, a light exit surface 412 and a top surface 413. The light incident surface 411 faces the light shield 3. The light exit surface 412 inversely is spaced from the light incident surface 411 and faces the lens 13. The top surface 413 connects to the upper parts of the light incident surface 411 and the light exit surface 412 and has a height lower than the optical axis L. The light incident surface 411 is a plane vertically extending from top to bottom. The light exit surface 412 protrudes in an arc from left and right sides to a center, and increasingly obliquely extends backwards from top to bottom, such that from a side view, the light transmissive portion 41 assumes an appearance of having a top wider than the bottom. The base 42 is used to fix the light transmissive portion 41 to an inner surface of a bottom of the case 12.
In the present invention, while in use, the light rays emitted from the light source 2 are reflected by the reflector 11, and some of the light rays which are emitted upwards from the light source 2 are emitted from the light transmissive space 30 after being reflected by the reflector 11, and are refracted by the lens 13 to project under the optical axis L to create the effects of the low-beam headlight. Some of the light rays are incident towards the light incident surface 411 of the light guide 4, pass through the light exit surface 412, and are refracted by the lens 13 to form a compensation light ray B to travel upwards, and the compensation light ray B may be projected to the dark region approximately 25 meters in front of the light source 2, such that the dark region becomes brighter.
Referring to
To sum up, through the refraction effect of the light exit surface 412, the light rays passing through the light exit surface 412 and traveling towards the lens 13 are refracted upwards, such that with the changes of the upper and lower thickness, the light transmissive portion 41 controls the light rays, causing them to refract upwards, and the light exit surface 412 increasingly protrudes in an arc forwards from the left and right sides to the center, so the light rays which are emitted forwards cover the adequate area in the left and right directions. Therefore, in the present invention, with the structural design of the light guide 4 and the refraction effect of the lens 13, the light intensity in the dark region is compensated indeed. The structure of the light guide 4 is simple, and the disposition position does not interfere with the light shield 3. In this embodiment, although the vehicle headlight is, for example, the low-beam headlight, during implementation, an electromagnetic valve is added to drive the light shield 3 to rotate, and the rotation of the light shield 3 is not affected by the light guide 4, such that the present invention is also applicable to the vehicle headlight capable of being switched between the high-beam headlight and the low-beam headlight, and has wide applicability.
While the embodiment of the present invention have been illustrated and described, various modifications and improvements can be made by those skilled in the art. The embodiments of the present invention are therefore described in an illustrative but not restrictive sense. It is intended that the present invention may not be limited to the particular forms as illustrated, and that all modifications that maintain the spirit and scope of the present invention are within the scope as defined in the appended claims.
Number | Date | Country | Kind |
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97121186 A | Jun 2008 | TW | national |
Number | Name | Date | Kind |
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5307247 | Cejnek | Apr 1994 | A |
7722233 | Meyrenaud | May 2010 | B2 |
7789545 | Cheng et al. | Sep 2010 | B2 |
Number | Date | Country | |
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20090303741 A1 | Dec 2009 | US |