KR20090103359A - The Lens of the car's LED-lamp - Google Patents

Abstract

PURPOSE: A lens of LED-lamp for the car is provided to irradiate the light of the luminous body in which the directivity is strong by mounting the lens which maintains the fixed curved surface on the luminous body(LED) frontal surface. CONSTITUTION: A lens of LED-lamp for the car includes a lamp housing in which a luminous body(3) is mounted within the opened lantern seated; the lens and a reflector formed on the inner side of protective cover which covers and protects the opened lantern. The lens(10) includes the flat entrance side which is arranged in a crossing direction from the luminous bodies and irradiates the emitted light. A refraction side(12) refracts the light which passes through the entrance side to right and left.

Description

Lens of the car's LED-lamp}

The present invention relates to a lens, such as an LED lamp installed in the front or rear of the vehicle, in more detail, a plurality of light emitting diodes (LED) are overlapped while passing through the lens, the LED for the vehicle to emit a wide downward downward surrounding the vehicle It relates to a lens of (LED-Lamp).

In general, an LED lamp is a lamp that is mounted at the rear or front of a vehicle that is driving, and is a lamp that irradiates light around the vehicle to secure a view of the surroundings at night.

In addition, the lamp includes a lamp (LED) and a lamp housing in the lamp compartment which forms an open indentation space, and a protective cover and an inner reflector which cover the opened lamp compartment.

The lens or transparent cover provided on the front surface of the lamp is simply for projecting the light emitted by the light emitting body to the front side, and is usually formed by arranging a plurality of light emitting bodies having strong straightness at regular intervals together with a reflector. Irradiating light around the vehicle while forming an oval light distribution pattern.

That is, since the lamp (LED) has a strong straightness, in order to spray light widely around the vehicle, a plurality of light emitting bodies were only arranged at regular intervals.

Accordingly, the present invention is intended to allow the lens to maintain a constant curved surface to the front of the light emitter (LED), so that the light of the light emitter with strong straightness passes through the lens to be irradiated around the vehicle while maintaining a constant illuminance.

To this end, the present invention is mounted in a lamp housing that is equipped with a plurality of light emitting body in the opened lamp compartment, and also in a vehicle LED and the like provided with a lens and a reflector inside the protective cover for covering the open lamp compartment,

The lens is formed by integrally bending a flat incidence surface placed in a direction perpendicular to the plurality of light emitters to project the irradiated light in front and a convex shape refracted surface that refracts the light passing through the incidence side to side. In other words, the light distribution patterns of long and vertical crosses are formed to overlap each other.

The present invention is as described above. By making the lens 10 having a flat incident surface and a convex surface convex in a curved shape from the top to the bottom, and installing it on the front of the luminous body, it is possible to provide a cross-shaped light distribution pattern that is stretched vertically and spreads from side to side. In particular, the number of light emitting units (LEDs) to be installed can be reduced, thereby reducing installation and manufacturing costs.

In addition, as the straightness of the light is widely distributed, it is characterized by minimizing the direct impact of light directly on the driver's eyes of the vehicle located behind or on the opposite vehicle to minimize accident damage caused by irradiation.

1 is a perspective view of a lens and a lamp of a vehicle LED lamp according to an embodiment of the present invention.

Figure 2 is a perspective view of the lens and lamp of the LED lamp for a vehicle according to the embodiment of the present invention.

Figure 3 is a cross-sectional view of the lens and the lamp of the LED lamp for vehicles according to an embodiment of the present invention.

4 is a cross-sectional view showing the direction of light propagation in the refractive surface of FIG.

5 is a longitudinal sectional view of the lens and the lamp of the LED lamp for a vehicle according to the embodiment of the present invention.

FIG. 6 is a longitudinal sectional view showing a propagation direction of light in the refractive surface of FIG. 5; FIG.

7 is a perspective view showing a light distribution pattern of a lens according to an embodiment of the present invention.

8 is a perspective view illustrating a light distribution pattern of a lens according to an exemplary embodiment of the present invention.

9 is a state diagram used in the headlights for vehicles according to an embodiment of the present invention.

10 is a perspective view illustrating a light distribution pattern of a lens according to the exemplary embodiment of FIG. 9.

<Description of the symbols for the main parts of the drawings>

1: lamp 2: lamp housing

3: illuminant 10: lens

11: incident surface 12: refractive surface

13: home

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS In describing the operating principles of the preferred embodiments of the present invention in detail with reference to the accompanying drawings, when it is determined that detailed descriptions of related well-known functions or configurations may unnecessarily obscure the subject matter of the present invention, the detailed descriptions thereof will be made. Will be omitted.)

1 and 2 are perspective views showing the lens and the light emitting body in a vehicle LED lamp according to an embodiment of the present invention, Figures 3 to 6 is the light injected by the light emitting body according to an embodiment of the present invention passes through the lens. 7 and 8 are cross-sectional piping patterns overlapping while light emitted by a plurality of light emitters passes through the lens. 9 and 10 show a state in which a shade is formed between the lens and the light emitting body to irradiate light in a downward direction.

As shown, the present invention is a reflector for seating the lamp housing in which the light emitter 3 is mounted in the opened lamp compartment, and reflects the emitted light to the front surface opened to open the lamp; It is installed with a transparent cover or lens to cover the part.

Here, the lens is convex for refracting the light passing through the incident surface to the right and left while the shape of the cross-section is perpendicular to the light emitting body placed vertically with respect to the center and maintains substantially perpendicular to the irradiated light. The semicircular refracting surface is integrally formed. Here, the incident surface and the refractive surface of the lens formed as described above are curved at the same angle from the top to the bottom while maintaining the same distance. And between the incidence surface and the refracting surface is formed with a protruding part protruding from left to right, so that it can be mounted fixed to the holding portion inside the back room.

In addition, grooves 13 having a predetermined depth are formed on the refractive surface 12 of the convex lens, and light passing through the grooves of the refractive surface is concave while forming a long band along the refractive surface 12 of the lens 10. It is to spread as it bends.

When the light emitted by the plurality of light emitters is irradiated from the incident surface 11 of the lens 10, the light irradiated onto the incident surface 11 of the lens 10 is applied to the lens 10. Normal (A) perpendicular to the plane of incidence An angle of incidence is achieved, and at the same time, light passing through the incident surface 11 of the lens 10 is normal to the incident surface of the lens A and normal. The refraction angle of the refraction is achieved.

And then through the incident surface of the lens When irradiated to the refracting surface of the lens at an angle of, the light irradiated to the refracting surface 12 of the lens 10 again, the normal line (B) perpendicular to the refracting surface of the lens 10 and The light passing through the refractive surface 12 of the lens 10 is again normal to the incident surface of the lens and Will be refracted to achieve the refractive angle of.

That is, when light is irradiated to the lens 10 of a very dense medium in which the incidence surface and the refractive surface are parallel and the refractive index is twice, the incidence angle of the incidence surface is 10 degrees. At the same time, the angle of refraction of light passing through the incident surface of the lens is bent by 0.5 times in proportion to the refractive index of air and the lens to achieve a refractive angle of 5 degrees.

Then, when the light passing through the incident surface reaches the refractive surface of the lens, the incident angle formed by the normal and the light irradiated from the refractive surface of the lens becomes 5 degrees, and the light passing through the refractive surface of the lens is the It is bent by 2.0 times in proportion to the refractive index to achieve a refractive angle of 10 degrees.

If the light emitted from the emitter is incident on the plane of incidence of the lens, the angle of incidence between the normal line of the lens and the irradiated light becomes 0 degrees while the angle of refraction of the light passing through the plane of incidence is also 0 degrees. It passes through the incident and refractive surfaces of the lens in a straight line.

In addition, when light passing through the plane of incidence of the lens is irradiated onto the convex refracting surface of the lens, the angle of incidence between the normal of the inclined refracting surface and the irradiated light forms an angle of incidence that is wider as the inclined surface is inclined. . That is, when light passing through the incident surface of the lens inclined about 5 degrees is incident on the refracting surface which is inclined about 10 degrees about the normal line, the incident angle of the light incident on the refractive surface of the lens is 15 degrees plus 5 degrees and 10 degrees. It will come true. Therefore, when the light is irradiated at an angle of 15 degrees to the refractive surface of the lens, the light passing through the refractive surface of the lens is bent by 2.0 times proportional to the refractive index of the lens and the air to form a refractive angle of 30 degrees.

Thus as shown. The light passing through the refraction surface of the lens is centered around the light having an incident angle and the refraction angle of 0 degrees, and the angle of refraction and the angle of refraction are also widened by the inclination angle of the refraction surface that gradually increases from side to side or up and down, and the light is refracted toward the center direction. Will be concentrated.

Therefore, the lens forms a dense light distribution pattern along the curved surface from the top to the bottom, centering on the light passing vertically through the refractive surface, and at the same time forms a dense light distribution pattern with the convex refractive surface from the right and left to form an overall cross shape. To form a light distribution pattern. That is, a cross-shaped light distribution pattern is formed by forming a long band of light bands left and right and a long band of light bands vertically.

Thus as shown. A plurality of light emitters are installed on the rear surface of the lens to overlap light irradiated in a plurality of cross shapes horizontally to each other to form a high-density light distribution pattern from side to side, and at the same time to position the vertical axis of the light distribution pattern at regular intervals. It is possible to form a uniform light distribution pattern with a predetermined illuminance or more vertically.

That is, conventional taillights and headlamps are simply circular or oval light distribution patterns, and even when overlapping with each other, it is difficult to form a light distribution pattern that is uniform and long left and right overall. By overlapping and using it, it is possible to form a long halo from side to side and at the same time a halo of more than a certain level of illumination.

The light condensed around the light vertically passing through the center of the lens 10 may be circularly concave to a certain depth in order to prevent light from being directly irradiated to the driver's eyes of the vehicle located behind the lens 10. The groove 13 is formed and dispersed.

Also. As shown, according to another embodiment, by providing a shade and a reflector between the lens 10 and the light emitter 3, such as a headlight, the light irradiated to the lens 10 of the driver of the vehicle driving behind It is also possible to form only a light distribution pattern that is irradiated downward so that light is not directly irradiated to the eye.

Claims (3)

In a vehicle LED lamp including a lens and a reflector installed inside a protective cover that seats a lamp housing in which a plurality of light emitting bodies are mounted in an opened lamp compartment, and covers an open lamp compartment. The lens is formed by integrally bending a flat incidence surface placed in a direction perpendicular to the plurality of light emitters to project the irradiated light in front and a convex shape refracted surface that refracts the light passing through the incidence side to side. And a lens such as an LED for a vehicle, wherein the light distribution pattern of a long crosswise and long crosswise shape is superimposed and used. The method of claim 1, And a recessed groove formed at a predetermined depth on the center of the convex refractive surface of the lens to diffuse light vertically passing through the refractive surface to the left and right. The method according to claim 1 or 2, A shade is provided between the lens and the plurality of light emitters to cover a portion of the light irradiated to the front, so that the light irradiated by the lens is irradiated downward so as not to directly irradiate the driver's eyes of another vehicle located near the vehicle. A lens such as a vehicle LED, characterized in that.