KR20220132745A - Automotive lamp - Google Patents

Abstract

The present invention relates to an automotive lamp and more specifically, to an automotive lamp that forms a high beam pattern and a sub-low beam pattern through a single module. The automotive lamp according to an embodiment of the present invention includes: a first light source that emits a first light; a first lens that reflects the first light by a first reflector to form a first reflected light; a second reflector that reflects the first reflected light to form a second reflected light; a second lens that transmits the second reflected light to form a first beam pattern; a second light source that emits a second light used for forming the second beam pattern through the first lens and the second lens; and a lens bracket that secures the first lens to the first light source.

Description

Automotive lamp {Automotive lamp}

The present invention relates to a vehicle lamp, and more particularly, to a vehicle lamp that forms a high beam pattern and a sub low beam pattern.

In general, a vehicle is provided with various types of lamps having a lighting function for easily identifying an object located around the vehicle during night driving and a signal function for notifying other vehicles or road users of the driving state of the vehicle.

For example, a head lamp and a fog lamp mainly for the purpose of a lighting function, and a turn signal lamp, a tail lamp, and a brake for the purpose of a signal function It is equipped with a brake lamp, a side marker, etc., and the installation standards and standards for these lamps are stipulated by laws and regulations to fully demonstrate each function.

The headlamp forms a low-beam pattern or a high-beam pattern so that the driver's forward view can be secured when the vehicle is driven in a dark environment such as at night, and plays a very important role in safe driving.

In such a headlamp, a headlamp that selectively forms a low-beam pattern or a high-beam pattern according to the driving of the shield member is provided as a single lamp module, and a headlamp that forms a low-beam pattern and a head that forms a high-beam pattern In some cases, each lamp is provided as a separate lamp module.

The headlamps usually maintain a low beam pattern to prevent glare to the driver of the oncoming vehicle or the driver of the preceding vehicle traveling in the opposite direction. A high beam pattern is formed to promote safe driving.

However, in the case of a vehicle headlamp in which a headlamp forming a low beam pattern and a headlamp forming a high beam pattern are provided as separate lamp modules, the low beam pattern is formed while driving while maintaining the low beam pattern in normal times. As only the headlamp for the purpose of lighting is turned on and the headlamp for forming the high beam pattern remains turned off, there is a fear that the location of the vehicle may not be properly recognized by pedestrians or drivers of other vehicles.

In addition, among the two headlamps, only one of the headlamps is maintained in a lit state, so that there is a concern that the aesthetics is somewhat deteriorated.

Republic of Korea Patent Publication No. 10-2015-0118669 (2015.10.23)

An object of the present invention is to provide a vehicle lamp that forms a high beam pattern and a sub low beam pattern through one module.

The problems of the present invention are not limited to the problems mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

A vehicle lamp according to an embodiment of the present invention includes a first light source irradiating a first light, a first lens reflecting the first light by a first reflecting unit to form a first reflected light, and the first reflected light A second reflector to form a second reflected light by reflection, a second lens to transmit the second reflected light to form a first beam pattern, and a second beam pattern to be transmitted through the first and second lenses A second light source for irradiating a second light used for, and a lens bracket for fixing the first lens to the first light source.

The first lens includes a first guide rod for guiding the first light to the first reflector.

The first light incident to the inside of the first lens through the first guide rod is reflected on the reflective surface of the first reflector and is emitted to the outside of the first lens.

The first lens is made of a silicon material.

The lens bracket includes a cover part covering the reflective surface of the first reflective part.

The second reflector is provided in the first lens.

The second reflector is provided on the lens bracket.

The lens bracket is made of a resin material or a metal material, and the second reflective part includes a reflective layer formed by applying a reflective material.

The reflective surface of the second reflector is a flat surface or a curved surface.

The first reflector reflects the first light incident in the horizontal direction in an inclined downward direction to form the first reflected light, and the second reflector reflects the first reflected light in an inclined upward direction to form the second reflector. form reflected light.

The first beam pattern includes a sub-low beam pattern, and the second beam pattern includes a high beam pattern.

The details of other embodiments are included in the detailed description and drawings.

According to the vehicle lamp according to the embodiment of the present invention as described above, there is an advantage in that the structure of the device is simplified by forming the high beam pattern and the sub low beam pattern through one module.

1 is a view showing a vehicle lamp viewed from the front of the vehicle.
2 is a diagram illustrating a low beam pattern.
3 is a diagram illustrating a high beam pattern.
4 is a diagram illustrating a low beam pattern and a high beam pattern.
5 is a diagram illustrating that a sub-low beam pattern is included in a low beam pattern.
6 is a view for explaining an observation form of a vehicle lamp.
7 is a perspective view of a high beam lamp;
8 is an exploded perspective view of a high beam lamp;
9 is a side cross-sectional view of the first lens.
10 is a perspective view of the lens bracket.
11 is a view for explaining the coupling relationship between the base bracket and the lens bracket.
12 is a view showing that the lens bracket is coupled to the base bracket.
13 is a view illustrating a reflective surface of a second reflector.
14 is a view illustrating that light for forming a sub-low beam pattern is irradiated.
15 is a view illustrating irradiation of light for forming a high beam pattern.
16 is a view showing a high beam lamp according to another embodiment of the present invention.
17 is a view illustrating the first lens shown in FIG. 16 .

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Advantages and features of the present invention, and a method of achieving them will become apparent with reference to the embodiments described below in detail in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments published below, but may be implemented in various different forms, and only these embodiments allow the publication of the present invention to be complete, and common knowledge in the technical field to which the present invention pertains. It is provided to fully inform the possessor of the scope of the invention, and the present invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout.

Unless otherwise defined, all terms (including technical and scientific terms) used herein may be used with the meaning commonly understood by those of ordinary skill in the art to which the present invention belongs. In addition, terms defined in a commonly used dictionary are not to be interpreted ideally or excessively unless clearly defined in particular.

1 is a view showing a vehicle lamp as viewed from the front of the vehicle, FIG. 2 is a view showing a low beam pattern, FIG. 3 is a view showing a high beam pattern, and FIG. 4 is a view showing a low beam pattern and a high beam pattern and FIG. 5 is a view showing that a sub-low beam pattern is included in a low beam pattern, and FIG. 6 is a view for explaining an observation form of a vehicle lamp.

Referring to FIG. 1 , a vehicle lamp 30 according to an embodiment of the present invention includes a low beam lamp 400 and a high beam lamp 500 .

In the embodiment of the present invention, the vehicle lamp 30 is installed on both sides of the front side of the vehicle 40 so that the front view can be secured when the vehicle 40 drives at night or in a dark place such as a tunnel. Accordingly, a case in which the vehicle lamp 30 is used as a head lamp will be mainly described. However, this is only an example for helping understanding of the present invention, and the vehicle lamp 30 of the present invention is not limited to a head lamp, but a fog lamp, a tail lamp, a brake lamp, a turn signal lamp, a position lamp, and a daytime running lamp. It may also be used for various lamps installed in the vehicle 40 , such as.

The vehicle lamp 30 may form a low beam pattern LP to secure a near field of view in front of the vehicle, and a high beam pattern to secure a far field of view in front of the vehicle. In forming the high beam pattern, the vehicle lamp 30 prevents light from being irradiated to an area corresponding to the position of the opposing vehicle or reduces the amount of irradiated light when an opposing vehicle, such as an opposing vehicle or a preceding vehicle, exists in the dark zone. (Shadow area) can be formed. As the dark zone is formed, it is possible to prevent glare from being generated by the driver of the other vehicle.

The low beam lamp 400 may irradiate light to form a low beam pattern LP, and the high beam lamp 500 may irradiate light to form a high beam pattern. The low beam lamp 400 and the high beam lamp 500 may be disposed adjacent to each other.

Referring to FIG. 2 , the low beam pattern LP may include a cut-off line CL. The cut-off line CL may be an inclined line crossing the center of the beam pattern forming surface. Left and right sides of the low beam pattern LP may have different heights based on the cut-off line CL.

The low beam pattern LP may include a concentrated light region LHZ and a diffused light region LSZ. The concentrated light area LHZ represents a beam pattern formed by concentrating light, and the diffused light area LSZ represents a beam pattern formed by diffusing light at the edge of the concentrated light area LHZ. That is, the concentrated light region LHZ may exhibit higher brightness than the diffused light region LSZ.

The focused light area LHZ is a beam pattern irradiated to the near front area where the driver's attention is focused, and the near front view of the vehicle 40 may be more smoothly secured by the concentrated light area LHZ.

Referring to FIG. 3 , the high beam pattern HP may include a concentrated light region HHZ and a diffused light region HSZ. The concentrated light area HHZ represents a beam pattern formed by concentrating light, and the diffused light area HSZ represents a beam pattern formed by diffusing light at the edge of the concentrated light area HHZ. That is, the concentrated light region HHZ may exhibit higher brightness than the diffused light region HSZ.

The focused light area HHZ is a beam pattern irradiated to a far-off front area where the driver's attention is concentrated, and the far-field front view of the vehicle 40 may be more smoothly secured by the concentrated light area HHZ.

The high beam pattern HP may optionally include a dark zone SD. The dark zone SD represents a region to which light is not irradiated. For example, when a vehicle is present in front, the high beam pattern HP may include a dark zone SD so that light is not irradiated to the corresponding area. The position of the dark zone SD may be changed in the entire area of the high beam pattern HP, and the number thereof may be changed.

Referring to FIG. 4 , the low beam pattern LP and the high beam pattern HP may be simultaneously formed.

When the low beam pattern LP and the high beam pattern HP are simultaneously formed, an overlapping region in which at least a portion of each of the low beam pattern LP and the high beam pattern HP overlaps may be formed. Alternatively, according to some embodiments of the present invention, the low beam pattern LP and the high beam pattern HP may not include overlapping regions. For example, the high beam pattern HP may be formed to correspond to the boundary of the low beam pattern LP.

The vehicle lamp 30 according to the embodiment of the present invention forms only the low beam pattern LP as shown in FIG. 2 or the high beam pattern HP together with the low beam pattern LP as shown in FIG. 4 . ) can be formed simultaneously. On the other hand, when only the low beam lamp 400 is turned on to form only the low beam pattern LP and the high beam lamp 500 is turned off, visibility by pedestrians or drivers of other vehicles is reduced, and undesirable aesthetics are reduced. can be provided.

To prevent this, the vehicle lamp 30 according to the embodiment of the present invention may light the high beam lamp 500 even when the high beam pattern HP is not formed. In this case, since the low beam lamp 400 and the high beam lamp 500 are always turned on at the same time, the visibility of the vehicle 40 is improved and a desirable aesthetic can be provided.

Referring to FIG. 5 , a sub-low beam pattern SLP may be formed on top of the low beam pattern LP.

The low beam pattern LP may be formed by the low beam lamp 400 , and the sub low beam pattern SLP may be formed by the high beam lamp 500 . When the high beam pattern HP is not formed, the high beam lamp 500 may form the sub low beam pattern SLP.

The sub-low beam pattern SLP may be formed on top of the low beam pattern LP. Specifically, the sub-low beam pattern SLP may be positioned at the upper end of the cut-off line CL. Accordingly, the sub-low beam pattern SLP may improve the near-field vision of the vehicle 40 and improve the visibility of pedestrians. However, according to some embodiments of the present invention, the sub-low beam pattern SLP may be located within the area of the low beam pattern LP, and may partially or completely deviate from the boundary of the low beam pattern LP.

Referring to FIG. 6 , the low beam lamp 400 and the high beam lamp 500 may always be turned on at the same time.

When only the low beam lamp 400 is turned on and the high beam lamp 500 is not turned on, the visibility of the vehicle 40 is reduced, and undesirable aesthetics may be provided. As the lamp 500 is turned on at the same time, the visibility of the vehicle 40 may be improved, and a desirable aesthetic may be provided.

7 is a perspective view of the high beam lamp, and FIG. 8 is an exploded perspective view of the high beam lamp.

7 and 8 , the high beam lamp 500 includes a first light source 511 , a second light source 512 , a substrate 520 , a first lens 530 , a base bracket 540 , and a lens bracket. 550 , a second lens 560 and a lens holder 570 are included.

The light sources 511 and 512 may emit light. The light sources 511 and 512 are light emitting modules that generate light, and may be one of a light emitting diode (LED), a laser, or a bulb type light source. The light sources 511 and 512 may irradiate light having a certain angular range, and for this purpose, a separate lens (not shown) for concentrating or diffusing the light may be provided on the light irradiation path of the light sources 511 and 512 . can The light sources 511 and 512 may include a first light source 511 and a second light source 512 . Light from the first light source 511 may be used to form a first beam pattern, and light from the second light source 512 may be used to form a second beam pattern. Here, the first beam pattern may include a sub-low beam pattern, and the second beam pattern may include a high beam pattern. Hereinafter, the light irradiated by the first light source 511 is referred to as a first light, and the light irradiated by the second light source 512 is referred to as a second light.

The substrate 520 may support the light sources 511 and 512 . The light sources 511 and 512 may be disposed on the substrate 520 , and one surface of the light sources 511 and 512 may be disposed in close contact with the substrate 520 . The substrate 520 may receive power from the outside and transmit it to the light sources 511 and 512 . The light sources 511 and 512 may generate and irradiate light with power transmitted from the substrate 520 .

The first lens 530 may reflect the first light to form the first reflected light. To this end, the first lens 530 may include a first reflector 533 . The first light may be reflected by the first reflector 533 to form the first reflected light.

The base bracket 540 may support the first lens 530 with respect to the substrate 520 . The first lens 530 is supported by the base bracket 540 so that the position with respect to the substrate 520 can be fixed. For example, the base bracket 540 may be coupled to the substrate 520 by fastening means such as bolts, and the first lens 530 may be accommodated in an accommodation space formed in the base bracket 540 .

The lens bracket 550 serves to fix the first lens 530 to the first light source 511 and the second light source 512 . As the lens bracket 550 presses the first lens 530 in a state in which the first lens 530 is accommodated in the base bracket 540 coupled to the substrate 520, the first lens 530 is a light source 511, 512) can be fixed. As the positions are fixed by the base bracket 540 and the lens bracket 550 , the light from the first light source 511 and the second light source 512 is incident on the first lens 530 to be uniformly maintained. can

The lens bracket 550 may include a second reflection unit 553 . The second reflector 553 may reflect the first reflected light to form the second reflected light. The first reflected light emitted from the first reflector 533 of the first lens 530 may be reflected by the second reflector 553 to form the second reflected light.

The second lens 560 may transmit the second reflected light to form a first beam pattern, that is, a sub-low beam pattern. In the present invention, the second lens 560 may be an aspherical lens. The second reflected light emitted from the second reflector 553 of the lens bracket 550 may pass through the second lens 560 to form a sub-low beam pattern. Also, the second lens 560 may transmit the second light transmitted from the first lens 530 to form a high beam pattern. The second light from the second light source 512 may directly pass through the first lens 530 and the second lens 560 without a separate reflection process. The light sequentially transmitted through the first lens 530 and the second lens 560 may be used to form a high beam pattern.

The lens holder 570 serves to support the second lens 560 . Also, the lens holder 570 may prevent light emitted from the first lens 530 from being exposed to the outside. To this end, the lens holder 570 may include an accommodation space for accommodating at least one of the first lens 530 , the base bracket 540 , and the lens bracket 550 . Among the light emitted from the first lens 530 , the light that does not reach the second lens 560 may be prevented from leaking to the outside by the lens holder 570 .

9 is a side cross-sectional view of the first lens.

Referring to FIG. 9 , the first lens 530 includes a lens body 531 , a first guide rod 532a , a second guide rod 532b , and a first reflection unit 533 .

In the present invention, the first lens 530 may be made of a silicon material. Silicon is processed to manufacture the first lens 530 in which the lens body 531 , the first guide rod 532a , the second guide rod 532b and the first reflection unit 533 are integrally formed.

The lens body 531 may be provided in the shape of a substantially parallel plate. The first guide rod 532a , the second guide rod 532b , and the first reflection part 533 may protrude outward from the wide surface of the lens body 531 . The first guide rod 532a and the second guide rod 532b are formed to protrude from the lens body 531 toward the first light source 511 and the second light source 512, respectively, and the first reflector 533 is The first guide rod 532a and the second guide rod 532b may protrude from the lens body 531 in a different direction.

The first guide rod 532a serves to guide the first light to the first reflector 533 . The light incident on the first guide rod 532a may be guided to the first reflection unit 533 while being reflected on the inner surface of the first guide rod 532a.

The second guide rod 532b serves to guide the second light to the lens body 531 . The light incident on the second guide rod 532b may be guided to the lens body 531 while being reflected on the inner surface of the second guide rod 532b.

The first reflector 533 may reflect the first light guided by the first guide rod 532a. The first light incident into the interior of the first lens 530 through the first guide rod 532a is reflected by the reflection surface 533a of the first reflection unit 533 and is emitted to the outside of the first lens 530 . can be The first reflector 533 may be provided in the shape of a triangular pole. The first light may be incident through the first surface, the first light may be reflected through the second surface to form a first reflected light, and the first reflected light may be emitted through the third surface. The disposition angle of the reflective surface 533a of the first reflective part 533 may be determined such that the light reflectance is higher than the light transmittance.

10 is a perspective view of a lens bracket, FIG. 11 is a view for explaining the coupling relationship between the base bracket and the lens bracket, FIG. 12 is a view showing that the lens bracket is coupled to the base bracket, FIG. 13 is a second reflector A drawing showing a reflective surface.

Referring to FIG. 10 , the lens bracket 550 includes a bracket body 551 , a cover part 552 , and a second reflection part 553 .

The bracket body 551 may surround the first lens 530 . In addition, the bracket body 551 may be coupled to the base bracket 540 . 11 and 12, while the engaging portion 554 provided on the bracket body 551 is engaged with the engaging protrusion 541 provided on the base bracket 540, the bracket body 551 is connected to the base bracket. may be coupled to 540 . As the lens bracket 550 is coupled to the base bracket 540 , the position of the first lens 530 provided between the lens bracket 550 and the base bracket 540 may be fixed.

Referring to FIG. 10 again, the cover part 552 may cover the reflective surface 533a of the first reflective part 533 . As described above, the first lens 530 may be made of a silicon material. Accordingly, some of the first light introduced into the first reflection unit 533 of the first lens 530 is not reflected by the reflection surface 533a of the first reflection unit 533 but passes through the reflection surface 533a You may. As the cover part 552 covers the reflective surface 533a , the light passing through the reflective surface 533a may be prevented from being directly transmitted to the second lens 560 .

In addition, the cover part 552 may reflect the light transmitted through the reflective surface 533a. The light reflected by the cover part 552 may be transmitted to the second reflection part 553 .

The second reflector 553 may reflect the first reflected light emitted from the first reflector 533 of the first lens 530 to form second reflected light. The second reflected light may be irradiated to the second lens 560 . In the present invention, the lens bracket 550 may be made of a resin material or a metal material. For example, the lens bracket 550 may be made of an acrylic material or a stainless material. The second reflector 553 may reflect the first reflected light through the reflective surface 553a, which is a reflective surface, to form second reflected light.

Alternatively, the second reflective part 553 may include a reflective layer formed by applying a reflective material. For example, a reflective layer may be formed by applying a white paint to the reflective surface 553a of the second reflective part 553 . The reflective layer may reflect most of the incident first reflected light and may absorb only a portion.

Referring to FIG. 13 , the reflection surface 553a of the second reflection unit 553 may be flat or curved.

When the reflective surface 553a is a curved surface, the central portion may be provided in a shape recessed inward. The shape of the second reflected light incident to the second lens 560 may be determined according to the shape of the reflective surface 553a. For example, the second reflected light emitted from the reflective surface 553a of the second reflector 553 may be focused on a specific area of the second lens 560 or the second lens 560 depending on the shape of the reflective surface 553a. ) can be uniformly incident over the entire area.

Referring back to FIG. 10 , the bracket body 551 may include a through hole 555 .

The through hole 555 may be formed by drilling the bracket body 551 . The through hole 555 may be formed between the cover part 552 and the second reflective part 553 , but the position of the through hole 555 of the present invention is different from the cover part 552 and the second reflective part 553 . ) is not limited to

The through hole 555 serves to transmit the second light from the second light source 512 . The second light may be incident on the second lens 560 after sequentially passing through the first lens 530 and the through hole 555 .

14 is a view illustrating that light for forming a sub-low beam pattern is irradiated.

Referring to FIG. 14 , light for forming the sub-low beam pattern SLP may be irradiated through the high beam lamp 500 .

The first light 610 irradiated from the first light source 511 may be guided to the first reflector 533 by the first guide rod 532a of the first lens 530 . The first reflector 533 may reflect the first light 610 to form the first reflected light 611 . Specifically, the first reflector 533 may reflect the first light 610 incident in the horizontal direction in an inclined downward direction to form the first reflected light 611 . A portion of the first light 610 incident to the first reflection unit 533 may pass through the first reflection unit 533 without being reflected by the first reflection unit 533 . The light passing through the first reflection unit 533 may be blocked from being directly transmitted to the second lens 560 by the cover unit 552 of the lens bracket 550 . When the first light 610 is directly transmitted to the second lens 560 , a focused light region by the corresponding light may be included in the sub-low beam pattern SLP. As the first light 610 is directly blocked from being transmitted to the second lens 560 by the cover part 552 , the focused light region may be prevented from being formed in the sub-low beam pattern SLP.

The second reflector 553 may reflect the first reflected light 611 to form the second reflected light 612 . Specifically, the second reflector 553 may reflect the first reflected light 611 in an inclined upward direction to form the second reflected light 612 . The second reflected light 612 emitted from the second reflector 553 may pass through a point higher than the focal point F1 of the second lens 560 to be incident on the second lens 560 . Accordingly, the second reflected light 612 incident on the second lens 560 is refracted by the second lens 560 to form the sub-row light 613 inclined with respect to the optical axis Cx of the second lens 560 . In addition, the sub-row light 613 may form a sub-low beam pattern SLP that is mapped to an area higher than that of the low beam pattern LP.

15 is a view illustrating irradiation of light for forming a high beam pattern.

Referring to FIG. 15 , light for forming a high beam pattern may be irradiated through the high beam lamp 500 .

The second light 620 irradiated from the second light source 512 may be guided to the lens body 531 by the second guide rod 532b of the second lens 560 . The lens body 531 may transmit the second light 620 . For example, the lens body 531 may transmit the second light 620 without reflecting any physical change with respect to the second light 620 .

The second light 620 passing through the lens body 531 may pass through the through hole 555 of the lens bracket 550 to be incident on the second lens 560 .

The second light 620 passes through the focus F1 of the second lens 560 and is incident on the second lens 560 , and the second light 620 incident on the second lens 560 is generally the second light 620 . The high beam light 621 may be transmitted parallel to the optical axis Cx of the lens 560 . The high beam light 621 may form the above-described high beam pattern.

16 is a view showing a high beam lamp according to another embodiment of the present invention, and FIG. 17 is a view showing the first lens shown in FIG. 16 .

16 and 17 , the high beam lamp 700 includes a first light source 711 , a second light source 712 , a substrate 720 , a first lens 730 , a lens bracket 750 , and a second light source 712 . It is configured to include a lens (760).

Forms and functions of the first light source 711 , the second light source 712 , the substrate 720 , the first lens 730 , the lens bracket 750 , and the second lens 760 are the above-described first light source 511 . ), the second light source 512 , the substrate 520 , the first lens 530 , the lens bracket 550 , and the second lens 560 are the same as or similar in shape and function, so the differences will be mainly described.

The first lens 730 includes a lens body 731 , a first guide rod 732a , a second guide rod 732b , a first reflection unit 733 , and a second reflection unit 734 .

The lens body 731 may be provided in the shape of a substantially parallel plate. The first guide rod 732a , the second guide rod 732b , the first reflection part 733 , and the second reflection part 734 may be formed to protrude outward from the wide surface of the lens body 731 . The first guide rod 732a and the second guide rod 732b are formed to protrude from the lens body 731 toward the first light source 711 and the second light source 712, respectively, and the first reflector 733 and The second reflector 734 may protrude from the lens body 731 in a direction different from that of the first guide rod 732a and the second guide rod 732b.

The first guide rod 732a serves to guide the first light 810 to the first reflector 733 . The second guide rod 732b serves to guide the second light to the lens body 731 . The first reflector 733 may reflect the first light 810 guided by the first guide rod 732a.

The shape and function of the lens body 731, the first guide rod 732a, the second guide rod 732b, and the first reflection part 733 are the above-described lens body 531, the first guide rod 532a, Since the shapes and functions of the second guide rod 532b and the first reflective part 533 are the same as or similar to those of the second guide rod 532b, a detailed description thereof will be omitted.

The second reflector 734 may reflect the first reflected light 811 emitted from the first reflector 733 to form the second reflected light 812 . The second reflected light 812 may be irradiated to the second lens 760 . The first lens 730 may be made of a silicon material. The first reflected light 811 transmitted to the second reflector 734 through the air may be reflected by the reflective surface 734a of the second reflector 734 which is a medium different from air.

Alternatively, the second reflective part 734 may include a reflective layer formed by applying a reflective material. For example, a reflective layer may be formed by applying a white paint to the reflective surface 734a of the second reflective part 734 . The reflective layer may reflect most of the incident first reflected light 811 and absorb only a portion.

The reflection surface 734a of the second reflection unit 734 may be flat or curved. When the reflective surface 734a is a curved surface, the central portion may be provided in a shape recessed inward. The shape of the second reflected light 812 incident to the second lens 760 may be determined according to the shape of the reflective surface 734a. For example, the second reflected light 812 emitted from the reflective surface 734a is focused on a specific area of the second lens 760 or on the entire area of the second lens 760 depending on the shape of the reflective surface 734a. It can be uniformly incident across.

The first light 810 irradiated from the first light source 711 may be guided to the first reflector 733 by the first guide rod 732a of the first lens 730 . The first reflector 733 may reflect the first light 810 to form the first reflected light 811 . Specifically, the first reflector 733 may reflect the first light 810 incident in the horizontal direction in an inclined downward direction to form the first reflected light 811 . A portion of the first light 810 incident to the first reflector 733 may pass through the first reflector 733 without being reflected by the first reflector 733 . The light passing through the first reflection unit 733 may be blocked from being directly transmitted to the second lens 760 by the cover unit 752 of the lens bracket 750 . When the first light 810 is directly transmitted to the second lens 760 , a focused light region by the corresponding light may be included in the sub-low beam pattern SLP. As the first light 810 is directly blocked from being transmitted to the second lens 760 by the cover part 752 , the focused light region may be prevented from being formed in the sub-low beam pattern SLP.

The second reflector 734 provided in the first lens 730 may reflect the first reflected light 811 to form the second reflected light 812 . Specifically, the second reflector 734 may reflect the first reflected light 811 in an inclined upward direction to form the second reflected light 812 . The second reflected light 812 emitted from the second reflector 734 may pass through a point higher than the focal point F2 of the second lens 760 to be incident on the second lens 760 . Accordingly, the second reflected light 812 incident on the second lens 760 is refracted by the second lens 760 to form the sub-row light 813 inclined with respect to the optical axis Dx of the second lens 760 . In addition, the sub-row light 813 may form a sub-low beam pattern SLP that is mapped to an area higher than that of the low beam pattern LP.

Although the embodiments of the present invention have been described with reference to the above and the accompanying drawings, those of ordinary skill in the art to which the present invention pertains can practice the present invention in other specific forms without changing its technical spirit or essential features. You will understand that there is Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive.

30: vehicle lamp 40: vehicle
400: low beam lamp 500, 700: high beam lamp
511, 711: first light source 512, 712: second light source
520, 720: substrate 530, 730: first lens
531, 731: lens body 532a, 732a: first guide rod
532b, 732b: second guide rod 533, 733: first reflecting unit
540: base bracket 541: locking projection
550, 750: lens bracket 551: bracket body
552, 752: cover part 553, 734: second reflection part
554: catching part 560, 760: second lens
570: lens holder

Claims (11)

a first light source irradiating a first light;
a first lens reflecting the first light by a first reflecting unit to form a first reflected light;
a second reflector configured to reflect the first reflected light to form a second reflected light;
a second lens that transmits the second reflected light to form a first beam pattern;
a second light source passing through the first lens and the second lens and irradiating a second light used to form a second beam pattern; and
and a lens bracket for fixing the first lens to the first light source. The method of claim 1,
The first lens is a vehicle lamp including a first guide rod for guiding the first light to the first reflector. 3. The method of claim 2,
The first light incident to the inside of the first lens through the first guide rod is reflected on the reflective surface of the first reflector to be emitted to the outside of the first lens. The method of claim 1,
The first lens is a vehicle lamp made of a silicon material. The method of claim 1,
The lens bracket includes a cover part covering the reflective surface of the first reflective part. The method of claim 1,
The second reflector is a vehicle lamp provided in the first lens. The method of claim 1,
The second reflector is a vehicle lamp provided in the lens bracket. 8. The method of claim 7,
The lens bracket is made of a resin material or a metal material,
The second reflective part includes a reflective layer formed by coating a reflective material. The method of claim 1,
The reflective surface of the second reflector is a flat or curved vehicle lamp. The method of claim 1,
The first reflector forms the first reflected light by reflecting the first light incident in the horizontal direction in an inclined downward direction,
The second reflector reflects the first reflected light in an inclined upward direction to form the second reflected light. The method of claim 1,
The first beam pattern includes a sub-low beam pattern, and the second beam pattern includes a high beam pattern.

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