KR101199109B1 - Sunlight dispersion structure of aspheric lens for head lamp - Google Patents

Abstract

The present invention relates to a solar dispersion structure of an aspherical lens for a headlamp, in particular an aspherical lens 100 is inserted into the center of the bezel 10 coupled with the reflector (not shown); The aspherical lens 100 is formed with a light scattering surface 110 to mitigate the concentration of sunlight irradiated from the outside, the magnifier phenomenon generated by the sunlight and aspheric lens when irradiated with sunlight on the aspherical lens of the headlamp As a result, sunlight is concentrated on the bezel, thereby preventing the surface of the bezel from melting or discoloring.

Description

Sunlight dispersion structure of aspheric lens for head lamp

The present invention relates to a solar light scattering structure of an aspherical lens for a headlamp, and in particular, to prevent the phenomenon that damage to the outer surface of the bezel due to the magnification phenomenon when the solar irradiation on the aspherical lens of the headlamp. A solar dispersion structure of an aspherical lens for a headlamp.

In general, the vehicle is equipped with a headlamp, the headlamp has a light that serves as a main function to shine the path ahead at night, and requires a brightness that can identify traffic obstacles at a distance of about 100m ahead at night However, performance standards vary from country to country.

The headlamp according to the prior art has a light source embedded in the housing, and a reflection plate for reflecting light generated from the light source is installed on the inner surface of the housing.

In the case of the projection optical system, a light source is built-in, a reflector reflecting the light generated from the light source, a shield to prevent the light reflected from the reflector is irradiated upward, and the light from the reflector is refracted forward to An aspherical lens for forming an optical pattern is provided.

Since the surface of the aspherical lens is formed as an aspherical surface, the light source is turned on when power is supplied to the light source embedded in the housing, and the light generated from the light source is reflected to the front through the lens.

In this case, the blocking plate installed at the inner lower portion of the front cover blocks the light irradiated to the upper portion of the lens, thereby securing a view of the driver or the driver traveling in the opposite direction.

On the other hand, due to the high quality of the vehicle and the pursuit of the dynamic design, the application of the projection type is increasing as the slim head lamp is applied, and as shown in FIG. 1, the position of the projection type aspherical lens 1 is moved forward. There is a trend to implement an appearance image that protrudes.

However, in the conventional headlamp structure, as shown in FIG. 1, since the aspherical lens 1 of the headlamp is provided in a protruding shape, the solar light passes through the aspherical lens 1 when sunlight is irradiated from the outside. If there is a problem that the bezel outer surface is damaged due to the magnifier phenomenon that the sunlight passed through it is concentrated on the bezel (2).

The present invention relates to a solar light scattering structure of an aspherical lens for a headlamp to solve the above problems, in particular, when the solar irradiation on the aspherical lens of the headlamp due to the magnification phenomenon damage to the outer surface of the bezel The purpose is to prevent the phenomenon.

This invention is an aspherical lens is inserted into the center of the bezel coupled with the reflector; The aspherical lens is achieved by having a light scattering surface formed on a part to alleviate the concentration of sunlight emitted from the outside.

According to the present invention as described above, when the solar light is irradiated to the aspherical lens of the headlamp, sunlight is concentrated on the bezel due to the magnifier phenomenon generated by the solar light and the aspherical lens, thereby preventing the phenomenon that the outer surface of the bezel melts or discolors. It is an invention effective for improving.

1 is a view showing an aspherical lens for a conventional headlamp;
2 (a) is a view showing a light emitting region and a non-light emitting region in the solar dispersion structure of the aspherical lens for a head lamp of the present invention,
Figure 2 (b) is a view showing a light scattering surface in the solar dispersion structure of the aspherical lens for headlamps of the present invention,
Figure 3 (a) to (e) is a view showing a corrosion dispersion, convex knurling, concave knurling, cutting, concave processing, which is a light scattering surface in the solar dispersion structure of the aspherical lens for a head lamp of the present invention. ,
Figure 4 (a) to (e) is an embodiment of the corrosion, convex knurling, concave knurling, cutting, concave processing of the light scattering surface in the solar dispersion structure of the aspherical lens for the head lamp of the present invention The figure which shows.

2 to 4 are related to the solar dispersion structure of the aspherical lens for headlamps of the present invention, Figure 2 is a view showing the solar dispersion structure of the aspherical lens for headlamps of the present invention, Figure 3 Fig. 4 is a view showing the corrosion dispersion, convex knurling, concave knurling, cutting, and concave processing in the solar dispersion structure of the aspherical lens for the headlamp of the present invention, and FIG. 4 is an aspherical lens for the headlamp of the present invention. Figure 1 shows an embodiment of the light scattering surface of the corrosion dispersion, convex knurling, concave knurling, cutting, concave processing in the solar dispersion structure of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIGS. 2 to 4, the solar light scattering structure of the aspherical lens for the headlamp of the present invention has a light scattering surface 110 at an aspherical lens 100 in the center of a bezel 10 coupled with a reflector (not shown). It is a basic feature of the technology to prevent the phenomenon that the outer surface of the bezel melts or discolors by relieving the magnifier phenomenon in which the sunlight is refracted and concentrated on the bezel even when sunlight is irradiated with an aspherical lens.

Hereinafter, each component of the solar dispersion structure of the aspherical lens for a headlamp of the present invention will be described with reference to the accompanying drawings, one by one.

As shown in FIG. 2, the present invention is based on the insertion of an aspherical lens 100 in the center of a bezel 10 coupled with a reflector (not shown), and the light scattering surface 110 in the aspherical lens 100. ) Is formed in part.

When the light emitted from the outside is projected to the aspherical lens 100, the light scattering surface 110 passes through the aspherical lens 100, and the sun light passing through the light is refracted to a part of the bezel 10. It is formed to alleviate the magnifying glass that is concentrated on.

As shown in FIG. 2A, the aspherical lens 100 includes a light emitting region 101 in which light transmission is concentrated from a reflector (not shown), and a non-light emitting region 102 in which light transmission is small from the reflector. Is done.

At this time, the light scattering surface 110 to mitigate the magnifier phenomenon in which sunlight is concentrated on the bezel 10 due to refraction is not shown in the non-light emitting region 102 of the aspherical lens 100 as shown in FIG. It is desirable to form at the bottom.

Here, the reason why the light scattering surface 110 is formed only in the non-light emitting region 102 of the aspherical lens 100 is because the aspheric lens 100 needs to be processed to disperse the concentration of sunlight. In more detail, when the processing operation is performed on the aspherical lens 100, the light transmission performance is reduced. When such processing is performed on the light emitting area 101, light distribution from the light source to be irradiated to a predetermined amount or more to the outside Since it violates the law, the light scattering surface 110 is formed by performing the machining operation only on the non-light emitting area 102 so that the concentration of sunlight can be dispersed regardless of the light distribution law.

As shown in FIG. 3, the light scattering surface 110 formed in the non-light emitting region 102 of the aspherical lens 100 is corroded 111, knurled 112, cut 113, and concave. Is formed through the processing of any one of the processing 114, it is preferable that the knurling 112 comprises a convex knurling (112a) and concave knurling (112b).

Referring to the light scattering surface 110, as shown in (a) of FIG. 3, the corrosion processing 111 forcibly consumes a portion of the non-light emitting region 102 of the aspherical lens 100 through chemical action. As shown in (b) and (c) of FIG. 3, the nulling processing 112 processes a portion of the non-light emitting region 102 of the aspherical lens 100 so as to make a gritty feeling. ) Are convex knurling 112a and concave knurling 112b.

In addition, as shown in (d) of FIG. 3, the cutting processing 113 cuts off a portion of the non-light emitting region 102 of the aspherical lens 100 to form an inclined surface, as shown in (e) of FIG. As described above, the concave processing 114 recesses a portion of the non-light emitting region 102 of the aspherical lens 100 to form a groove.

As such, when the light scattering surface 110 is formed in the non-light emitting region 102 of the aspherical lens 100, the sun is applied to the aspherical lens 100 of the head lamp as shown in FIGS. 4A to 4E. When the light is irradiated by the light scattering surface 110, such as corrosion processing 111, convex knurling (112a), concave knurling (112b), cutting processing 113, concave processing 114 to disperse the sunlight It is possible to prevent the magnifier phenomenon due to the concentration of sunlight that has conventionally occurred.

Hereinafter, functions and effects of the present invention will be described.

As shown in FIG. 2, the present invention allows the light scattering surface 110 to be formed in the aspheric lens 100 at the center of the bezel 10 coupled with the reflector (not shown), thereby allowing sunlight to flow into the aspherical lens 100. Even when irradiated, solar light is refracted to alleviate the magnifier phenomenon concentrated on the bezel 10.

Meanwhile, as illustrated in FIGS. 2 and 3, the light scattering surface 110 for alleviating the magnification of the aspherical lens 100 is formed in the non-light emitting region 102 of the aspheric lens 100, and the light scattering is performed. The surface 110 is formed by any one of the corrosion processing 111, the convex knurling 112a, the concave knurling 112b, the cutting 113, the concave processing 114.

As such, when the light scattering surface 110 is formed in the non-light emitting region 102 of the aspherical lens 100, as shown in FIGS. 4A to 4E, sunlight is emitted from the aspherical lens 100 of the headlamp. By irradiating the sunlight by the light scattering surface 110, such as corrosion processing 111, convex knurling 112a, concave knurling 112b, cutting 113, concave processing 114 during irradiation Due to the magnifying glass caused by the sunlight and the aspherical lens 100, sunlight is concentrated on the bezel 10 to prevent the bezel 10 from melting or deteriorating.

In the solar dispersion structure of the aspherical lens for the headlamp of the present invention configured as described above, the aspherical lens is inserted into the center of the bezel coupled with the reflector; The aspheric lens is formed with a light scattering surface for mitigating the concentration of sunlight emitted from the outside, the outer surface of the bezel due to the magnifying glass caused by the sunlight and aspheric lens when the solar light irradiation to the aspherical lens of the headlamp It is an invention having an excellent advantage to improve the commerciality by preventing the phenomenon or discoloration.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It is to be understood that various changes and modifications may be made without departing from the scope of the appended claims.

10: bezel 100: aspherical lens
101: light emitting area 102: non-light emitting area
110: dispersion means 111: corrosion processing
112: knurled machining 112a: convex knurled machining
112b: concave knurling 113: cutting
114: concave processing

Claims (4)

An aspherical lens is inserted in the center of the bezel coupled with the reflector;
The aspherical lens has a light scattering surface formed to partially relax the concentration of sunlight emitted from the outside,
The aspherical lens comprises a light emitting region in which light transmission is concentrated from the reflector, and a non-light emitting region in which light transmission is small from the reflector;
And the light scattering surface is formed in the non-light emitting region of the aspheric lens.
delete The method of claim 1,
The light scattering surface is a solar dispersion structure of an aspherical lens for a headlamp, characterized in that the non-light emitting region of the aspherical lens is made through one of the process of corrosion, knurling, cutting, or concave processing.
The method of claim 3, wherein
The knurling processing is a solar dispersion structure of an aspherical lens for a head lamp, characterized in that it comprises a convex knurling processing and concave knurling processing.

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