KR101841141B1 - Optical Lens for LED Lighting - Google Patents

Abstract

The present invention provides an optical lens for an LED lighting capable of controlling light distribution for light emitted by an LED installed in an LED lighting. The optical lens for an LED lighting comprises: a lens body controlling the light distribution for the light emitted by the LED; a light distribution control part located on a first direction side with respect to the lens body; an incident groove formed in the lens body for receiving the LED; and a light distribution control groove formed in the light distribution control part at a position separated from the incident groove in the first direction. The light distribution control part includes: a reflective surface located in the light distribution control groove, and reflecting the light emitted in the first direction of the light emitted by the LED; and a scattering surface located in the light distribution control groove, and scattering the light emitted in the first direction of the light emitted by the LED.

Description

Optical Lens for LED Lighting

The present invention relates to an optical lens for controlling light distribution for light emitted by an LED.

Street lights and road lighting fixtures are installed along the roadside for street lighting, traffic safety, or aesthetics. A light source for emitting light is provided in such street lamps, road lighting lamps, and the like.

In recent years, a business of replacing a light source installed in a street light, a road lighting fixture, etc. with an LED (Light Emitting Diode) has been actively carried out. LED is not only an environmentally friendly, high-efficiency, long-life light source, but also a light source that can save energy and save energy. For example, recently, the company has invested about 2 billion won in Yanggu-gun, Gangwon-do to replace the light source installed in the existing streetlight with LED, and more than 600 cities in the US are in the process of replacing the existing light source with LED. In this way, projects are being actively implemented to implement street lights and road lighting luminaires (hereinafter referred to as "LED lighting") using LED as a light source not only in domestic but also in the world.

FIG. 1 is a conceptual diagram illustrating an LED lighting device according to the related art installed on a road.

Referring to FIG. 1, a plurality of LED lights 10 according to the related art are spaced apart from each other along a traveling direction (that is, a longitudinal direction of a road) (RD axis direction) in which a vehicle travels on the road 100. The LED light 10 according to the related art has one side of the road 100 or the road 100 in the width direction (i.e., the width direction of the road) (WD axis direction) perpendicular to the running direction (RD axis direction) Respectively.

Due to the light distribution characteristics of the LEDs forming the Lambertian distribution, the LED illumination 10 according to the related art has dark dark parts 20 (see FIG. 1) partially on the road 100 along the running direction , 20 '). Therefore, the LED light 10 according to the related art has a problem that can cause a safety accident such as a traffic accident.

In order to solve the above-mentioned problems, there is a method of reducing the spacing of the LED lights 10 according to the related art along the traveling direction (RD axis direction). However, And the amount of light irradiated per unit area with respect to the outside of the road 100 in the width direction (WD axis direction) also increases, thereby causing light pollution in the surrounding area of the road 100.

In addition, since the installation standard and the luminance standard such as the distance between the LED lights 10 and the like are defined by the standard and the standard, the corresponding light distribution should be implemented.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide an optical lens for LED illumination that can control light distribution for light emitted by an LED installed in an LED illumination.

In order to solve the above problems, the present invention may include the following configuration.

An optical lens for an LED illumination according to the present invention includes: a lens body for controlling light distribution to light emitted by an LED; A light distribution control unit located on a side of the lens body in a first direction; An incident groove formed in the lens body to accommodate the LED; And a light distribution control groove formed in the light distribution control unit at a position spaced apart from the incident groove in the first direction. Wherein the light distribution control unit includes a reflective surface for reflecting light emitted toward the first direction among the light emitted by the LED, the reflective surface being located in the light distribution control groove, And a scattering surface for scattering the light emitted toward the light source.

According to the present invention, the following effects can be achieved.

The present invention can reduce the light pollution to the periphery of the area requiring illumination in the area where the LED illumination is installed, by reducing the amount of light irradiated for the area where the illumination is unnecessary.

FIG. 1 is a conceptual view showing a state in which an LED light according to the related art is installed on a road;
2 is a schematic perspective view of an optical lens for an LED illumination according to the present invention.
3 is a schematic plan view of an optical lens for an LED illumination according to the present invention.
4 is a schematic bottom perspective view of an optical lens for an LED illumination according to the present invention.
5 is a schematic side cross-sectional view of an optical lens for an LED illumination according to the present invention with reference to line II in Fig.
6 is a conceptual plan view for explaining the arrangement and function of the incident scattering surface, the reflecting surface, the scattering surface, and the outer surface in the optical lens for LED illumination according to the present invention
7 is a schematic cross-sectional view showing an enlarged view of a scattering projection in an optical lens for an LED illumination according to the present invention
FIG. 8 is a schematic cross-sectional view of an optical lens for an LED illumination according to the present invention,

Hereinafter, embodiments of an optical lens for an LED illumination according to the present invention will be described in detail with reference to the accompanying drawings.

2 and 3, the optical lens 1 for LED illumination according to the present invention is for controlling the light distribution for light emitted by an LED (Light Emitting Diode) (not shown) installed in the LED illumination. LED lighting is installed to illuminate the street, alleyway, etc. located in the workplace, the road on which the vehicle runs, and the residence. For example, the LED illumination may be a security light, a street light, a road light, or the like. The LED includes a molding part (not shown) for receiving the LED chip therein.

The optical lens 1 for an LED illumination according to the present invention may include a lens body 2 and a light distribution control section 3. [

2 to 4, the lens main body 2 controls the light distribution for the light emitted by the LED. An LED is positioned inside the lens body 2. The lens body 2 may be coupled to a substrate (not shown) on which the LED is mounted. The lens body 2 may be coupled to the substrate through a tape or the like having adhesiveness. The lens body 2 may be coupled to the substrate in an interference fit manner.

The lens body 2 may be formed to have a longer length in the first axial direction (X-axis direction) than in the second axial direction (Y-axis direction). 3, the lens body 2 has a longer length in the first axial direction (X-axis direction) than the second axial direction (Y-axis direction) As shown in FIG.

The lens body 2 may include a bottom surface 20 (shown in FIG. 4). The bottom surface 20 may correspond to a lower surface of the lens body 2. [ The lens body 2 can be supported on the substrate by coupling the bottom surface 20 to the substrate.

The lens body 2 may include an incident groove 21. The incident groove 21 accommodates the LED. The LED may be located inside the lens body 2 by being received in the incident groove 21. The incident groove 21 may be formed to have a larger size than the LED so that the LED may be positioned inside the lens body 2. [ The incident grooves 21 may be formed to have a larger size than the sum of the LED chip of the LED and the molding portion that houses the LED chip therein. The incidence grooves 21 may be recessed from the bottom surface 20 of the lens body 2 in the upward direction (the direction of the arrow UD). The incident grooves 21 may be formed to have a decreasing size as they extend in the upward direction (the direction of the arrow UD).

2 to 6, the light distribution control unit 3 controls the light distribution of the light emitted by the LED. The light distribution control unit 3 may be positioned in the first direction (FD arrow direction) with respect to the lens main body 2. Accordingly, the light distribution control unit 3 can control the light distribution for the light emitted in the first direction (arrow direction of the FD) among the light emitted by the LED housed in the incident groove 21. [ The first direction (arrow direction of the arrow FD) with respect to the lens body 2 may correspond to a region in which no illumination is required (hereinafter referred to as a "non-illuminated region"). The second direction (SD arrow direction) opposite to the first direction (FD arrow direction) may correspond to an area where illumination is required (hereinafter referred to as an illuminated area). Therefore, the optical lens 1 for LED illumination according to the present invention uses the lens body 2 and the light distribution control unit 3 to control the light distribution control and the non- So that the emitted light is irradiated. The light distribution control unit 3 may be connected to the lens body 2. The light distribution control unit 3 and the lens body 2 may be integrally formed. The light distribution control unit 3 and the lens body 2 may be formed in different shapes.

The light distribution control unit 3 may be coupled to a substrate to which the lens body 2 is coupled. The light distribution control unit 3 may be coupled to the substrate through a tape or the like having adhesiveness. The light distribution control unit 3 may be coupled to the substrate in an interference fit manner. The light distribution control unit 3 may be coupled to the substrate by a supporting force as the lens body 2 is coupled to the substrate.

The light distribution control unit 3 may be formed to have a longer length in the first axis direction (X axis direction) than the second axis direction (Y axis direction). For example, as shown in FIG. 3, the light distribution controller 3 has a longer length in the first axis direction (X-axis direction) than the second axis direction (Y-axis direction) As shown in FIG.

The light distribution control unit 3 may include a bottom surface 30 (shown in FIG. 4). The bottom surface 30 may correspond to a lower surface of the light distribution control unit 3. The light distribution control unit 3 can be supported on the substrate by coupling the bottom surface 30 to the substrate. When the light distribution control unit 3 and the lens body 2 are integrally formed, the bottom surface 30 of the light distribution control unit 3 and the bottom surface 20 of the lens main body 2 are integrally formed .

The light distribution control unit 3 may include a light distribution control groove 31 (shown in FIG. 4). The light distribution control grooves 31 may be formed in the light distribution control unit 3. The light distribution control groove 31 may be formed to be recessed from the bottom surface 30 of the light distribution control unit 3 in the upward direction (the direction of the arrow UD). The light distribution control groove 31 may be formed in a shape that decreases in size as it extends in the upward direction (UD arrow direction). For example, the light distribution control groove 31 may be formed in a triangular prism shape having a decreasing size as it extends in the upward direction (UD arrow direction). The light distribution control groove 31 may be formed in the light distribution control unit 3 at a position spaced apart from the incident groove 21 in the first direction (arrow direction of the FD). A part of the lens main body 2 and a part of the light distribution control part 3 may be positioned between the light distribution control groove 31 and the incident groove 2. No LED is located in the light distribution control groove 31.

The light distribution control unit 3 may include a reflecting surface 32 (shown in FIG. 5).

The reflecting surface 32 may be located in the light distribution control groove 31. [ The reflective surface 32 may reflect light emitted in the first direction (arrow direction of the FD) among the light emitted by the LED. Thus, the optical lens 1 for LED illumination according to the present invention can achieve the following operational effects.

First, the optical lens 1 for an LED illumination according to the present invention reflects light emitted in the first direction (arrow direction of the FD) out of the light emitted by the LED by using the reflection surface 32, (In the arrow direction of the FD) can be reduced. Therefore, the optical lens 1 for LED illumination according to the present invention can reduce the light pollution for the non-illuminated area by using the reflective surface 32. [

Second, the optical lens 1 for LED illumination according to the present invention is characterized in that the reflective surface 32 emits light emitted in the first direction (FD arrow direction) out of the light emitted by the LED in the second direction (SD arrow direction) As shown in FIG. Accordingly, the optical lens 1 for LED illumination according to the present invention can increase the amount of light irradiated toward the second direction (the direction of the arrow SD). Accordingly, the optical lens 1 for LED illumination according to the present invention can enhance the illumination function for the LED illumination by increasing the amount of light irradiated per unit area with respect to the illumination area.

The reflective surface 32 may reflect a part of the light emitted in the first direction (the arrow direction of the FD) out of the light emitted by the LED. The reflective surface 32 may reflect all of the light emitted in the first direction (the arrow direction of the FD) out of the light emitted by the LED. The reflecting surface 32 may be formed in the process of forming the light distribution control groove 31 in the light distribution control unit 3. The reflective surface 32 may be disposed so as to be positioned on the side of the light distribution control groove 31 in the second direction (SD arrow direction). The reflecting surface 32 may be formed to be flat.

The reflective surface 32 may be formed so as to be inclined such that the distance from the optical axis 200 (shown in FIG. 5) of the light emitted by the LED increases in the upward direction (the direction of the arrow UD). The optical axis 200 is a direction parallel to the upper direction (UD arrow direction) in the vertical axis direction (Z-axis direction) toward the upper vertical direction of the LED with reference to FIG. In this case, the reflective surface 32 may be formed as an inclined surface inclined toward the first direction (FD arrow direction) with respect to the upward direction (UD arrow direction). Accordingly, the reflective surface 32 can reflect light emitted toward the first direction (arrow direction of the FD) among the light emitted by the LED toward the second direction (direction of the arrow SD).

The light distribution control unit 3 may include a scattering surface 33 (shown in FIG. 5).

The scattering surface 33 may be located in the light distribution control groove 31. The scattering surface 33 may scatter light emitted in the first direction (arrow direction of the FD) among the light emitted by the LED. Accordingly, the optical lens 1 for LED illumination according to the present invention can reduce the light amount of the light irradiated toward the first direction (arrow direction of FD) by using the scattering surface 33. Therefore, the optical lens 1 for the LED illumination according to the present invention can further reduce the light pollution for the non-illuminated area by using the scattering surface 33.

The scattering surface 33 may be formed in the process of forming the light distribution control groove 31 in the light distribution control unit 3. The scattering surface 33 may be arranged to be positioned in the first direction (FD arrow direction) with respect to the light distribution control groove 31. In this case, the scattering surface 33 may be arranged to be positioned in the first direction (FD arrow direction) with respect to the reflection surface 32. The scattering surface 33 scatters the light that has passed through the reflecting surface 32 without being reflected by the reflecting surface 32 so that the amount of light irradiated toward the first direction . Specifically, it is as follows.

First, among the light emitted from the LED, light traveling along the first optical path LP1 shown in FIG. 5 is reflected by the reflection surface 32 and can move toward the second direction (SD arrow direction) . Accordingly, the optical lens 1 for LED illumination according to the present invention reduces the amount of light irradiated to the non-illuminated area located in the first direction (arrow direction of the FD) by using the reflection of the light through the reflective surface 32 , It is possible to reduce light pollution in the non-illuminated area. In addition, the optical lens 1 for LED illumination according to the present invention increases the amount of light irradiated to the illumination region located in the second direction (SD arrow direction) by using the reflection of light through the reflection surface 32, Lighting can be enhanced for the lighting area.

Next, among the light emitted from the LED, light traveling along the second optical path LP2 shown in Fig. 5 can be scattered by the scattering surface 33 after passing through the reflection surface 32. [ Accordingly, the optical lens 1 for LED illumination according to the present invention reduces the amount of light irradiated to the non-illuminated area located in the first direction (arrow direction of the FD) by using scattering of light through the scattering surface 33 , It is possible to reduce light pollution in the non-illuminated area.

The scattering surface 33 may be formed to be inclined such that the distance from the optical axis 200 of the light emitted by the LED decreases in the upward direction (UD arrow direction). That is, the scattering surface 33 may be formed as an inclined surface inclined toward the second direction (SD arrow direction) with respect to the upward direction (UD arrow direction). Accordingly, light passing through the scattering surface 33 may be refracted in a direction in which the distance from the optical axis 200 increases, such as the second optical path LP2 shown in FIG. Therefore, in addition to the scattering of light through the scattering surface 33, the optical lens 1 for LED illumination according to the present invention further refracts the light passing through the scattering surface 33 to spread widely over the non- Light pollution can be further reduced in the illuminated area.

2 through 7, a plurality of scattering projections 34 may be formed on the scattering surface 33.

The scattering protrusions 34 scatter light. The scattering protrusions 34 may protrude from the scattering surface 33, respectively. The scattering protrusions 34 may protrude toward the second direction (SD arrow direction). The scattering protrusions 34 may be formed so as to protrude from the scattering surface 33 and decrease in size. For example, the scattering protrusions 34 may be formed in a triangular prism shape protruding from the scattering surface 33, respectively. The scattering protrusions 34 may scatter light by refracting the light in the second axis direction (Y-axis direction).

The scattering protrusions 34 may be arranged in parallel along the first axis direction (X axis direction). In this case, the scattering projections 34 include two opposing faces 341 and 342 (shown in FIG. 7) facing each other with respect to the first axis direction (X-axis direction), and two opposing faces 341 and 342 (Shown in FIG. 7) connecting the first and second ends 341, The connection surface 343 may be disposed between the two opposing surfaces 341 and 342. The connecting surface 343 may be formed so that the center of curvature forms a curved surface located between the two opposing surfaces 341 and 342. The portion located between the scattering projections 34 with respect to the first axis direction (X axis direction) may be formed so that the center of curvature forms a curved surface located between the two opposing surfaces 341 and 342 . The two opposing surfaces 341 and 342 may be formed flat.

2 to 6, the light distribution control unit 3 may include an outer surface 35 (shown in FIG. 5).

The outer surface 35 is an outer surface (surface) of the light distribution control unit 3 that faces the first direction (FD arrow direction). A plurality of scattering members 36 (shown in FIG. 6) may be formed on the outer surface 35. The scattering members 36 may scatter light that has passed through the reflecting surface 32 and the scattering surface 33. Accordingly, the optical lens 1 for LED illumination according to the present invention partially reflects light traveling toward the first direction (arrow direction of the FD) using the reflection surface 32, Light that travels in the first direction (arrow direction of the FD) passes through scattering projections 34 formed on the scattering surface 33 and scattering members 36 formed on the outer surface 35, . ≪ / RTI > Therefore, the optical lens 1 for LED illumination according to the present invention can further reduce light pollution for the non-illuminated area by further reducing the amount of light irradiated toward the first direction (arrow direction of the FD). Specifically, it is as follows.

First, among the light emitted from the LED, light traveling along the first optical path LP1 shown in FIG. 5 is reflected by the reflection surface 32 and can move toward the second direction (SD arrow direction) . Accordingly, the optical lens 1 for LED illumination according to the present invention reduces the amount of light irradiated to the non-illuminated area located in the first direction (arrow direction of the FD) by using the reflection of the light through the reflective surface 32 , It is possible to reduce light pollution in the non-illuminated area. In addition, the optical lens 1 for LED illumination according to the present invention increases the amount of light irradiated to the illumination region located in the second direction (SD arrow direction) by using the reflection of light through the reflection surface 32, Lighting can be enhanced for the lighting area.

Next, the light traveling along the second optical path LP2 shown in FIG. 5 among the light emitted from the LED is reflected by the scattering protrusions 34 and the scattering member 36 ). ≪ / RTI > Accordingly, the optical lens 1 for LED illumination according to the present invention is capable of detecting the scattering of light through the scattering projections 34 and the scattering members 36, The light pollution for the non-illuminated area can be further reduced.

The scattering members 36 may be formed to protrude from the outer surface 35, respectively. The scattering members 36 may be formed to protrude toward the first direction (FD arrow direction). The scattering members 36 may be formed in a shape of decreasing in size while protruding from the outer surface 35, respectively. For example, the scattering members 36 may be formed in the shape of a circular column protruding from the outer surface 35, respectively. As shown in FIG. 6, the scattering members 36 may each have a semi-elliptical cross section. The scattering members 36 may scatter light by refracting the light in the second axis direction (Y-axis direction). The scattering members 36 may be arranged in parallel along the first axis direction (X axis direction). The portion located between the scattering members 36 with respect to the first axis direction (X-axis direction) may be formed to have a curved surface.

The scattering member 36 and the scattering protrusions 34 may be formed in different shapes. Accordingly, the optical lens 1 for LED illumination according to the present invention is realized such that the scattering member 36 and the scattering projection 34 have different scattering characteristics, thereby further reducing the light pollution to the unlit area . The scattering member 36 and the scattering protrusions 34 may be formed to have different lengths with respect to the first axis direction (X axis direction). In this case, the scattering member 36 may be formed to have a longer length than the scattering protrusions 34 with respect to the first axis direction (X-axis direction).

2 to 8, the lens body 2 may include an incident scattering surface 22 (shown in FIG. 5).

The incidence scattering surface 22 may be located in the incidence groove 21. The incidence scattering surface 22 may scatter light emitted in the first direction (arrow direction of the FD) among the light emitted by the LED. Accordingly, the optical lens 1 for LED illumination according to the present invention can further reduce the light amount of the light irradiated toward the first direction (FD arrow direction) by using the incidence scattering surface 22. Therefore, the optical lens 1 for LED illumination according to the present invention can further reduce the light pollution for the non-illuminated area by using the incidence scattering surface 22.

The incidence scattering surface 22 may be formed in the process of forming the incidence groove 21 in the lens body 2. The incidence scattering surface 22 may be disposed so as to be positioned in the first direction (FD arrow direction) with respect to the incident groove 21. In this case, the reflecting surface 32 may be disposed to be positioned in the first direction (FD arrow direction) with respect to the incident scattering surface 22. [ The scattering surface 33 may be arranged to be positioned in the first direction (FD arrow direction) with respect to the reflecting surface 32. [ The outer surface 35 may be disposed on the scattering surface 33 in the first direction (FD arrow direction). A part of the light passing through the incidence scattering surface 22 is reflected by the reflection surface 32 and a part of the light passes through the reflection surface 32, (36). ≪ / RTI > Specifically, it is as follows.

6, light L1 traveling in the first direction (arrow direction of the FD) among the light emitted from the LED can be scattered by the incidence scattering surface 22. Accordingly, the optical lens 1 for LED illumination according to the present invention can reduce the light pollution for the non-illuminated area by using light scattering through the incidence scattering surface 22.

6, a part of the light L2 passing through the incidence scattering surface 22 may be reflected by the reflecting surface 32 and move toward the second direction (SD arrow direction). Accordingly, the optical lens 1 for LED illumination according to the present invention reduces the amount of light irradiated to the non-illuminated area located in the first direction (arrow direction of the FD) by using the reflection of the light through the reflective surface 32 , It is possible to reduce light pollution in the non-illuminated area. In addition, the optical lens 1 for LED illumination according to the present invention increases the amount of light irradiated to the illumination region located in the second direction (SD arrow direction) by using the reflection of light through the reflection surface 32, Lighting can be enhanced for the lighting area.

6, the light L3 having passed through the reflecting surface 32 may be scattered by the scattering protrusions 34 formed on the scattering surface 33. In this case, Accordingly, the optical lens 1 for LED illumination according to the present invention can reduce the light pollution to the non-illuminated area by using scattering of light through the scattering protrusions 34.

6, the light L4 having passed through the scattering surface 33 may be scattered by the scattering members 36 formed on the outer surface 35. In this case, Accordingly, the optical lens 1 for LED illumination according to the present invention can reduce the light pollution to the non-illuminated area by using the scattering of light through the scattering members 36.

As described above, the optical lens 1 for LED illumination according to the present invention diffuses scattering of light through the incidence scattering surface 22, the scattering projections 34, and the scattering members 36, The light pollution of the non-illuminated area can be reduced by reducing the amount of light irradiated to the non-illuminated area located in the first direction (arrow direction of the FD). In addition, the optical lens 1 for LED illumination according to the present invention increases the amount of light irradiated to the illumination region located in the second direction (SD arrow direction) by using the reflection of light through the reflection surface 32, Lighting can be enhanced for the lighting area.

The incidence scattering surface 22 may be formed to be inclined such that the distance from the optical axis 200 of the light emitted by the LED decreases as the light is further extended in the upward direction (UD arrow direction). That is, the incident scattering surface 22 may be formed as an inclined surface inclined toward the second direction (SD arrow direction) with respect to the upward direction (UD arrow direction). Accordingly, light passing through the incidence scattering surface 22 may be refracted in a direction in which the distance from the optical axis 200 increases, such as the first optical path LP1 shown in FIG. Therefore, in addition to the scattering of light through the incidence scattering surface 22, the optical lens 1 for LED illumination according to the present invention increases the amount of light reaching the reflection surface 32 through the incidence scattering surface 22 Thereby further reducing the light pollution for the non-illuminated area.

Referring to FIGS. 2 to 8, a plurality of incident scattering projections 23 (shown in FIG. 8) may be formed on the incident scattering surface 22.

The incidence scattering projections 23 scatter light. The incident scattering protrusions 23 may be formed to protrude from the incident scattering surface 22, respectively. The incident scattering protrusions 23 may protrude toward the second direction (SD arrow direction). The incidence scattering projections 23 may be formed to be protruded from the incidence scattering surface 22 and to be reduced in size. For example, the incident scattering protrusions 23 may be formed in a triangular column shape protruding from the incident scattering surface 22, respectively. The incidence scattering projections 23 can scatter light by refracting light in the second axial direction (Y-axis direction).

The incident scattering protrusions 23 may be arranged in parallel along the first axis direction (X axis direction). In this case, the incidence scattering projections 23 have two incident opposing surfaces 231 and 232 (shown in FIG. 8) facing each other with respect to the first axis direction (X axis direction) And an incidence connection surface 233 (shown in FIG. 8) connecting incidence opposed surfaces 231 and 232. The incidence coupling surface 233 may be disposed between the two incidence planes 231 and 232. The incidence coupling surface 233 may be formed so that the center of curvature forms a curved surface positioned between the two incidence opposing surfaces 231 and 232. The portion located between the incidence scattering projections 23 with respect to the first axis direction (X axis direction) is formed so that the center of curvature forms a curved surface positioned between the two incident facing surfaces 231 and 232 . The two incident facing surfaces 231 and 232 may be formed flat.

Referring to FIG. 5, the lens body 2 may include an incident surface 24. The incident surface 24 may be located in the incident groove 21. The incident surface 24 may be disposed to be positioned in the second direction (SD arrow direction) with respect to the incident scattering surface 22. [ The incident surface 24 and the incident scattering surface 22 may be connected to each other. The incident surface 24 and the incident scattering surface 22 may be formed in the process of forming the incident grooves 21 in the lens body 2.

The incident surface 24 may extend in the first direction (FD arrow direction) and the second direction (SD arrow direction) with respect to the optical axis 200, with reference to FIG. 5 . In this case, the incident scattering surface 22 may be disposed at a position spaced apart from the optical axis 200 toward the first direction (FD arrow direction). The incident surface 24 may be formed to have a height higher in the upward direction (UD arrow direction) as it extends in the first direction (FD arrow direction). The incident surface 24 may be curved.

The incident surface 24 may refract the light emitted by the LED. In this case, the incident surface 24 may refract the light emitted by the LED toward the optical axis 200. For example, the incident surface 24 positioned on the side of the optical axis 200 in the first direction (FD arrow direction) can refract the light emitted by the LED toward the second direction (SD arrow direction). The incident surface 24 positioned in the second direction (SD arrow direction) with respect to the optical axis 200 can refract the light emitted by the LED toward the first direction (FD arrow direction). Accordingly, the optical lens 1 for LED illumination according to the present invention can enhance the illumination function for the LED illumination by increasing the amount of light irradiated per unit area with respect to the illumination area.

2 to 4, the optical lens 1 for LED illumination according to the present invention may include a lens flange 4. [

The lens flange 4 may be formed to protrude outward from the lens body 2 and the light distribution control unit 3, respectively. The lens flange 4 may protrude outward from the bottom surface 20 of the lens body 2 and the bottom surface 30 of the light distribution control unit 3, respectively. The lens flange 4 protrudes in the radial direction including the first axial direction (X-axis direction) and the second axial direction (Y-axis direction) with reference to the lens body 2 and the light distribution control section 3 . The lens flange 4 may be formed in a plate shape in which corners are chamfered as a whole, but the present invention is not limited thereto and may be formed in various other forms.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. Will be clear to those who have knowledge of.

1: optical lens for LED illumination 2: lens body
3: light distribution control unit 4: lens flange
20: bottom surface 21: incidence groove
22: incidence scattering surface 23: incidence scattering projection
24: incidence surface 30: bottom surface
31: light distribution control groove 32: reflecting surface
33: scattering surface 34: scattering projection
35: outer surface 36: scattering member

Claims (10)

A lens body for controlling light distribution to light emitted by the LED;
A light distribution control unit located on a side of the lens body in a first direction;
An incident groove formed in the lens body to accommodate the LED; And
And a light distribution control groove formed in the light distribution control unit at a position spaced apart from the incident groove in the first direction,
Wherein the light distribution control unit includes: a reflective surface for reflecting light emitted toward the first direction among lights emitted by the LED, the reflective surface being located in the light distribution control groove; And a scattering surface for scattering the light emitted toward the light-
Wherein the scattering surface is positioned in the first direction with respect to the reflecting surface to scatter light passing through the reflecting surface. The method according to claim 1,
The reflective surface reflects the light emitted toward the first direction out of the light emitted by the LED toward the second direction opposite to the first direction, and the distance from the optical axis of the light emitted by the LED toward the upward direction Wherein the optical axis of the optical lens is substantially perpendicular to the optical axis. The method according to claim 1,
Wherein the scattering surface is formed so as to be inclined such that the distance from the optical axis of the light emitted by the LED decreases as the LED extends in the upward direction. The method according to claim 1,
Wherein a plurality of scattering projections for scattering light are formed on the scattering surface. 5. The method of claim 4,
Wherein the scattering protrusions are formed so as to protrude from the scattering surface and are formed to be protruded from the scattering surface and reduced in size. 6. The method of claim 5,
Wherein the scattering projections are arranged on the scattering surface in parallel along the first axis direction,
The scattering protrusions each include two opposing surfaces facing each other with respect to the first axis direction, and a connecting surface connecting the two opposing surfaces,
Wherein the connecting surface is formed so that a center of curvature forms a curved surface located between the two opposing surfaces. delete The method according to claim 1,
Wherein the light distribution control unit includes an outer surface facing the first direction,
And a plurality of scattering members for scattering the light having passed through the reflection surface and the scattering surface are formed on the outer surface. 9. The method of claim 8,
A plurality of scattering projections for scattering light are formed on the scattering surface,
Wherein the scattering protrusions and the scattering members are formed in different shapes from each other. The method according to claim 1,
Wherein the lens body includes an incident scattering surface for scattering light emitted from the LED in the first direction, the incident scattering surface being located in the incident groove,
A plurality of incident scattering projections for scattering light are formed on the incident scattering surface,
Wherein the reflective surface reflects the light that has passed through the incidence scattering projections on the first direction side with respect to the incident scattering surface.

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