KR101795368B1 - Optical Lens for LED Lighting - Google Patents

Abstract

The present invention relates to an optical lens for an LED light unit, which includes a lens body for diffusing light which an LED emits, a lens flange formed to protrude from the lens body to the outside, and a reflection unit coupled to the lens flange to be located at a position separated from the lens body in a first direction and reflecting the light which the LED emits. The reflection unit reflects the light emitted from the lens body toward the first direction.

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 comprises: a lens body for diffusing light emitted by an LED; A lens flange protruding outward from the lens body; And a reflector coupled to the lens flange so as to be located at a position spaced apart from the lens body in the first direction, for reflecting the light emitted by the LED. The reflector may reflect light emitted from the lens body toward the first direction.

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

The present invention is embodied such that light is irradiated with a larger amount of light for a wider area for an area requiring illumination, thereby enhancing the illumination function for the LED illumination.

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 plan view of an optical lens for an LED illumination according to the present invention.
3 is a schematic exploded side sectional view of the optical lens for LED illumination according to the present invention,
Fig. 4 is a schematic cross-sectional side view of the optical lens for LED illumination according to the present invention,
FIG. 5 is a schematic side cross-sectional view of the optical lens for LED illumination according to the present invention, in which the engaging groove and the engaging member are shown enlarged on the line II in FIG. 2
Figs. 6 to 8 are schematic side cross-sectional views
FIG. 9 is a schematic side cross-sectional view of the optical lens for an LED illumination according to the present invention, which is an enlarged view of the reflecting member with reference to line II in FIG. 2
10 is a schematic plan sectional view of the optical lens for LED illumination according to the present invention, taken along the line II-II in FIG. 3

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 to 4, the optical lens 1 for an 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. The LED light is installed to illuminate a street or an alleyway on the road where the vehicle travels, a residence, or the like. For example, the LED illumination may be a street lamp, a road lighting lamp, or the like. The LED includes a molding part (not shown) for receiving the LED chip therein after the packaging process has been completed.

An optical lens 1 for an LED illumination according to the present invention includes a lens body 2 for diffusing light emitted by an LED, a lens flange 3 formed to protrude outward from the lens body 2, And a reflecting portion 4 coupled to the lens flange 3 so as to be located at a position spaced apart from the lens flange 3 in the first direction (FD arrow direction). The reflective portion 4 reflects light emitted from the lens body 2 toward the first direction (arrow direction of the FD).

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 LED illumination according to the present invention can reduce the amount of light for light emitted from the lens body 2 toward the first direction (arrow direction of the FD) by using the reflector 4 have. In the lens body 2, the first direction (arrow direction of the FD arrow) may correspond to an area where illumination is not required (hereinafter, referred to as a 'non-illuminated area'). Accordingly, the optical lens 1 for LED illumination according to the present invention can reduce the light pollution in the non-illuminated area by using the reflector 4.

Second, the optical lens 1 for LED illumination according to the present invention can be implemented so that the reflection portion 4 reflects light in a region requiring illumination (hereinafter referred to as an 'illumination region'). 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.

Hereinafter, the lens body 2, the lens flange 3, and the reflecting portion 4 will be described in detail with reference to the accompanying drawings.

Referring to FIGS. 2 to 4, the lens body 2 can provide an overall appearance of the optical lens 1 for LED illumination according to the present invention. And the LED is positioned inside the lens body 2. [ The lens body 2 is 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 formed symmetrically with respect to the LED in the first axis direction (X-axis direction). The lens body 2 may be formed in a non-symmetrical manner with respect to the LED in the second axial direction (Y-axis direction). The lens body 2 may be formed to be reduced in size toward the upper direction (UD arrow direction, as shown in FIG. 3).

The lens body 2 is formed to have a shorter length in the second axial direction (Y-axis direction) than the first axial direction (X-axis direction). 2, the lens main 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. Accordingly, the lens body 2 can further diffuse the light emitted by the LED in the first axis direction (X axis direction) as compared with the second axis direction (Y axis direction). Therefore, the optical lens 1 for LED illumination according to the present invention is designed such that the light emitted by the LED is radiated onto a wider area in the first axial direction (X-axis direction) as compared with the second axial direction (Y-axis direction) The light distribution of the light emitted by the LED can be controlled. In this case, both sides of the lens body 2 may correspond to the illuminated area with respect to the first axial direction (X-axis direction). Either one of the two sides of the lens body 2 may correspond to the non-illuminated area with respect to the second axial direction (Y-axis direction).

The lens body 2 may be installed such that the non-illuminated region is located in the first direction (FD arrow direction) and the illuminated region is located in the second direction (SD arrow direction). For example, when the optical lens 1 for LED illumination according to the present invention is applied to an LED illumination installed on a road, a road is located on the side of the lens body 2 in the first direction (FD arrow direction) (In the direction of the arrow SD) on the outside of the road. In this case, the lens body 2 may be installed so that both sides of the lens body 2 are disposed along the running direction in which the vehicle runs on the road, with respect to the first axial direction (X-axis direction).

The lens body 2 may include a bottom surface 21 (shown in Fig. 3). The bottom surface 21 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 21 to the substrate.

2 to 5, the lens flange 3 is formed so as to protrude outward from the lens body 2. The lens flange 3 may be formed to protrude outward from the bottom surface 21 of the lens body 2. The lens flange 3 is formed to protrude from the lens body 2 in a radial direction including a first axial direction (X-axis direction) and a second axial direction (Y-axis direction) with respect to the lens body 2 . The lens body 2 may be located inside the lens flange 3. The lens flange 3 may be formed in a plate shape in which corners are chamfered as a whole, but it is not limited thereto and may be formed in various other forms.

The lens flange 3 may include an engagement groove 31 (shown in FIG. 5). The reflection portion 4 may be inserted into the coupling groove 31 and coupled therewith. The coupling groove 31 may be formed through the lens flange 3. The engaging groove 31 may be formed through the lens flange 3 at a position spaced apart from the lens body 2 in the first direction (arrow direction of the FD).

2 to 5, the reflective portion 4 is for reflecting light emitted by the LED. The reflective portion 4 may reflect light emitted from the lens body 2 toward 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 reduces the amount of light for the light emitted from the lens body 2 in the first direction (arrow direction of the FD) by using the reflecting portion 4 . The first direction (arrow direction of the FD) may correspond to the non-illuminated area. In this case, the optical lens 1 for an LED illumination according to the present invention can reduce the light pollution to the non-illuminated area by using the reflector 4.

The reflector (4) is coupled to the lens flange (3). The reflective portion 4 may be coupled to the lens flange 3 so as to be located at a position spaced apart from the lens body 2 in the first direction (arrow direction of the FD). Accordingly, the reflective portion 4 may be arranged so as not to interfere with light emitted in the remaining directions except for the first direction (arrow direction of the FD) in the lens body 2 out of the light emitted by the LED . Therefore, the optical lens 1 for an LED illumination according to the present invention is characterized in that the light emitted from the lens body 2 in the other direction except for the first direction (arrow direction of the FD) It is possible to prevent degradation of performance.

The reflective portion 4 may reflect light emitted from the reflective body 2 toward the first direction (FD arrow direction) toward a direction other than the first direction (FD arrow direction). The reflective portion 4 may reflect light emitted toward the first direction (arrow direction of the FD) from the reflective main body 2 toward a direction requiring further illumination.

For example, as shown in FIG. 4, the reflection unit 4 may reflect light emitted toward the first direction (arrow direction of the FD) from the reflection body 2 toward the second direction have. In this case, the lens body 2 may be installed such that the non-illuminated area is located in the first direction (arrow direction of the FD) and the illuminated area is located in the second direction (SD arrow direction).

Accordingly, the optical lens 1 for an LED illumination according to the present invention is configured such that the reflective portion 4 reflects light emitted toward the non-illuminated region from the LED toward the illuminated region, The amount of light irradiated per area can be increased. Therefore, the optical lens 1 for LED illumination according to the present invention can reduce the light pollution for the non-illuminated area and can contribute to enhance the illumination function for the illuminated area.

The reflector 4 may be formed of a material different from that of the lens body 2 and may be assembled to the lens flange 3 and coupled thereto. Therefore, the optical lens 1 for LED illumination according to the present invention can be easily manufactured in comparison with the comparative example in which the reflection portion 4, the lens body 2, and the lens flange 3 are integrally formed. Can be improved. In addition, since the optical lens 1 for LED illumination according to the present invention can simplify the mold for manufacturing the lens body 2 and the lens flange 3 in comparison with the comparative example, The manufacturing cost can be lowered. The reflector 4 may be formed of a material having a higher reflectivity than the lens body 2. For example, the reflective portion 4 may be formed of a metal material. The reflector 4 may be formed of stainless steel.

The reflective portion 4 may include a coupling member 41 (shown in Fig. 3).

The engaging member 41 is for engaging with the lens flange 3. The engaging member 41 may be coupled to the lens flange 3 such that the engaging member 41 is located at a position spaced apart from the lens body 2 in the first direction (FD arrow direction). The engaging member 41 can be inserted into the engaging groove 31 to be engaged with the stanchion flange 3.

The engaging member 41 may be interference fit with the engaging groove 31 and may be coupled to the lens flange 3. [ Accordingly, the optical lens 1 for LED illumination according to the present invention not only improves the ease of assembling the reflecting portion 4 and the lens flange 3, The coupling force to the lens flange 3 can be increased. When the coupling member 41 is coupled to the lens flange 3 using an adhesive, it is difficult to apply the adhesive so that the adhesive does not overflow from the coupling groove 31, And the lens flange 3 are made of different materials, the adhesive strength may be lowered. On the other hand, when the adhesive overflows from the coupling groove 31, interference may occur between the overflowed adhesive and the light emitted from the LED, which may lower the illumination performance for the LED illumination. Alternatively, the optical lens 1 for LED illumination according to the present invention can couple the engaging member 41 to the lens flange 3 without using an adhesive, so that deterioration of illumination performance due to an overflowed adhesive can be prevented .

As shown in FIG. 5, the engaging member 41 and the engaging groove 31 may have a shape and a size corresponding to each other.

For example, the engaging member 41 may be formed to have a thickness 41T corresponding to the depth 31D of the engaging groove 31. In this case, the engaging member 41 may be formed to have the same thickness 41T with respect to the depth 31D of the engaging groove 31. The engaging member 41 may be formed to have a thickness 41T that is thicker than the depth 31D of the engaging groove 31 so as to be interference fit with the engaging groove 31. [

For example, the engaging member 41 may be formed to have an area corresponding to the area of the engaging groove 31. The engaging member 41 may be formed to have a length 41L corresponding to the length 31L of the engaging groove 31 with reference to the second axial direction (Y axis direction). In this case, the engaging member 41 may be formed to have the same length 41L with respect to the length 31L of the engaging groove 31, with reference to the second axial direction (Y-axis direction). The engaging member 41 has a longer length 31L than the length 31L of the engaging groove 31 so that the engaging member 41 can be forcedly engaged with the engaging groove 31 with reference to the second axial direction (41L). Although not shown, the coupling member 41 may be formed to have a length corresponding to the length of the coupling groove 31, with reference to the first axial direction (X-axis direction). In this case, the coupling member 41 may be formed to have the same length with respect to the length of the coupling groove 31 with reference to the first axial direction (X-axis direction). The engaging member 41 is formed to have a length longer than the length of the engaging groove 31 so that the engaging member 41 can be forcedly engaged with the engaging groove 31 with reference to the first axial direction .

The coupling member 41 may be formed as a rectangular plate as a whole. For example, the engaging member 41 may be formed in a rectangular plate shape having a longer length in the first axial direction (X-axis direction) than the second axial direction (Y-axis direction). The surface of the engaging member 41 facing the second direction (SD arrow direction) may be formed as an inclined surface inclined toward the first direction (FD arrow direction).

2 to 5, the reflective portion 4 may include a reflective member 42. [

The reflecting member 42 is for reflecting the light emitted by the LED. The engaging member 41 may be coupled to the lens flange 3 such that the reflecting member 42 is located at a position spaced apart from the lens body 2 in the first direction (FD arrow direction). Accordingly, the reflective member 42 can reflect light emitted from the lens body 2 toward the first direction (arrow direction of the arrow FD), and can reflect light emitted from the lens body 2 in the first direction FD arrow direction) of the light guide plate.

The reflecting member 42 is coupled to the engaging member 41. The reflective member 42 may be coupled to the engaging member 41 so as to protrude upward from the engaging member 41 in the direction of the arrow UD. In this case, the engaging member 41 may be positioned on the lower side of the reflective member 42 (in the direction of the arrow DD). The reflecting member 42 and the engaging member 41 may be integrally formed.

The reflecting member 42 may be positioned to protrude upward from the upper surface of the lens flange 3 in the upward direction (UD arrow direction) as the engaging member 41 is inserted into the engaging groove 31. 3, when the reflective member 42 and the engaging member 41 are positioned in the lower direction (DD arrow direction) of the lens flange 3, the upper direction (UD arrow direction) The engaging member 41 is engaged with the engaging groove 31 so that the reflecting member 42 protrudes from the upper surface of the lens flange 3 in the upward direction (UD arrow direction) , As shown in Fig. 3). In this case, as shown in FIG. 3, a part of the engaging groove 31 may be recessed from the lower surface of the lens flange 3 by a predetermined depth, and a part of the engaging groove 31 may be formed through the lens flange 3. The engaging member 41 may be supported by the lens flange 3 located at a portion of the engaging groove 31 which is recessed from the lower surface of the lens flange 3 by a predetermined depth.

6 to 8, the reflective portion 4 may be coupled to the lens flange 3 such that an angle of inclination 42a is present between the reflective member 42 and the upper surface of the lens flange 3 have.

6, the reflection portion 4 is formed on the lens flange 3 so that the angle of inclination 42a between the reflecting member 42 and the upper surface of the lens flange 3 is obtuse (obtuse) Lt; / RTI > In this case, the reflecting member 42 is arranged between the second direction (SD arrow direction) and the upward direction (UD arrow direction) between the light emitted from the lens body 2 in the first direction In the diagonal direction of FIG. Accordingly, the optical lens 1 for LED illumination according to the present invention has an advantage that the amount of light irradiated to the illumination region located in the second direction (the direction of the arrow SD) can be increased. The reflector 4 is formed to have an obtuse angle formed between the reflective member 42 and the upper surface of the engaging member 41 so that the inclined angle between the reflective member 42 and the upper surface of the lens flange 3 (42a) may be coupled to the lens flange (3) to form an obtuse angle.

7, the reflection portion 4 is formed on the lens flange 3 so that the angle of inclination 42a between the reflecting member 42 and the upper surface of the lens flange 3 is perpendicular to the angle. Lt; / RTI > In this case, the reflecting member 42 is arranged between the second direction (SD arrow direction) and the upward direction (UD arrow direction) between the light emitted from the lens body 2 in the first direction In a direction diagonally opposite to the second direction (SD arrow direction), as compared with the embodiment where the subtended angle 42a is an obtuse angle. Accordingly, the optical lens 1 for LED illumination according to the present invention is configured such that light farther toward the second direction (direction of the SD arrow) is irradiated in comparison with the embodiment where the inclined angle 42a is at an obtuse angle, It is possible to increase the area irradiated with light toward the second direction (SD arrow direction). The reflector 4 is formed so that the angle of inclination between the reflecting member 42 and the upper surface of the engaging member 41 is perpendicular to the angle of inclination between the reflecting member 42 and the upper surface of the lens flange 3, Can be coupled to the lens flange (3) so that the lens flange (42a) is at right angles.

8, the reflection portion 4 is formed on the lens flange 3 so that the angle of inclination 42a between the reflecting member 42 and the upper surface of the lens flange 3 is an acute angle, Lt; / RTI > In this case, the reflective member 42 is provided between the second direction (SD arrow direction) and the lower direction (DD arrow direction) and the light emitted from the lens body 2 toward the first direction In the diagonal direction of FIG. Accordingly, the optical lens 1 for LED illumination according to the present invention is implemented so as to reduce the amount of light directly irradiated on the illumination region along the optical axis among the light emitted by the LED. In this case, the optical lens 1 for LED illumination according to the present invention has an advantage of improving the uniformity with respect to the amount of light irradiated to the illuminated area by reducing the brightness difference between the region located on the optical axis of the LED and the other region have. The reflector 4 is formed to have an acute angle formed between the reflective member 42 and the upper surface of the engaging member 41 so that the inclined angle between the reflective member 42 and the upper surface of the lens flange 3 The lens flange 3 may be coupled to the lens flange 42a at an acute angle.

Referring to FIGS. 4 and 9, the reflective member 42 may include a reflective surface 421 for reflecting the light emitted by the LED.

The reflecting surface 421 is a surface (surface) facing the second direction (the direction of the arrow SD) in the reflecting member 42. The light emitted from the lens body 2 toward the first direction (arrow direction of the arrow FD) may be reflected on the reflecting surface 421 and irradiated to an illuminated area located in the second direction (SD arrow direction).

As shown in FIG. 4, the reflecting surface 421 may be formed to be flat (plane). In this case, the reflective portion 4 is formed at an obtuse angle (shown in FIG. 6), a right angle (shown in FIG. 6) , Or an acute angle (shown in FIG. 8). The reflecting surface 421 may be formed to have a flat surface by embodying the reflecting member 42 as a whole in a rectangular plate shape. Although not shown, only the reflective surface 421 of the reflective member 42 is formed as a flat surface, and the remaining surface of the reflective member 42 except for the reflective surface 421 may be formed in a shape other than a flat surface have.

As shown in FIG. 9, the reflective surface 421 may be formed to have a curved surface. Accordingly, the optical lens 1 for LED illumination according to the present invention can maintain the light distribution control efficiency for the light emitted by the LEDs to be substantially the same when compared with the embodiment in which the reflecting surface 421 is formed to be flat There is an advantage that the height of the reflecting surface 421 can be reduced based on the upward direction (UD arrow direction). The reflective surface 421 may be formed to be curved so that the center of curvature is located at a position spaced toward the second direction (FD arrow direction). The reflecting surface 421 may be formed to have a curved surface by being formed to have a curved surface as a whole. Although not shown, only the reflective surface 421 of the reflective member 42 is formed as a curved surface, and the surface of the reflective member 42 other than the reflective surface 421 may be formed in a shape other than a curved surface have.

Referring to FIG. 10, the optical lens 1 for an LED illumination according to the present invention may include an incidence groove 5.

The incident groove 5 is formed in the lens main body 2. The incident groove 5 may receive the LED. Accordingly, the LED may be positioned inside the lens body 2 through the incidence groove 5. The incident groove 5 may be formed to have a larger size than the LED so that the LED can be positioned inside the lens body 2. [ The incident groove 5 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. The incidence grooves 5 may be recessed from the bottom surface 21 of the lens body 2 to a predetermined depth in the upward direction (UD arrow direction, as shown in FIG. 3).

Referring to FIG. 10, the optical lens 1 for LED illumination according to the present invention may include a first communication hole 6.

The first communication hole (6) is formed through the lens body (2). Accordingly, the first communication hole 6 can communicate the incidence groove 5 located inside the lens body 2 with the outside of the lens body 2. Therefore, the first communication hole 6 can discharge the heat generated by the LED located inside the lens body 2 to the outside of the lens body 2. Accordingly, the optical lens 1 for LED illumination according to the present invention can reduce the heat generation problem due to the heat generated when the LED installed in the LED illumination light emits light.

The first communication hole 6 may be formed in a rectangular parallelepiped shape, but is not limited thereto. The first communication hole 6 may be formed in a different shape as long as the incidence groove 5 can communicate with the outside of the lens body 2 have.

The first communication hole 6 may be formed through the lens body 2 along the first axis direction (X axis direction). The first communication hole 6 may be formed to have a shorter length than the incident groove 5 in the second axis direction (Y axis direction). Accordingly, the optical lens 1 for LED illumination according to the present invention can not only reduce the heat generation problem due to heat generated while the LEDs emit light through the first communication hole 6, The degree of reduction of the area of the bottom surface 21 due to the holes 6 can be reduced, so that the bonding force to the substrate can be enhanced.

The first communication hole 6 may be formed through the lens body 2 along the second axial direction (Y-axis direction). The first communication hole 6 may be formed to have a shorter length than the incident groove 5 in the first axis direction (X-axis direction). In this case, the optical lens 1 for an LED illumination according to the present invention is formed in such a manner that when the first communication hole 6 is formed along the first axis direction (X axis direction) Since the area occupied by the first communication hole 6 can be further reduced, the bonding force to the substrate can be further enhanced. In contrast to the embodiment in which the first communication hole 6 is formed along the first axial direction (X-axis direction), the optical lens 1 for LED illumination according to the present invention has the first communication hole 6 ) Can be reduced. Accordingly, the optical lens 1 for LED illumination according to the present invention is characterized in that, when compared with the embodiment in which the first communication hole 6 is formed along the first axis direction (X axis direction) The movement distance for supplying air existing outside the lens body 2 to the incident groove 5 and the moving distance for discharging the air present in the incident groove 5 to the outside of the lens body 2 can be reduced . Therefore, in contrast to the embodiment in which the first communication hole 6 is formed along the first axis direction (X-axis direction), the optical lens 1 for LED illumination according to the present invention, There is an advantage that the heat generation problem due to generated heat can be further reduced.

 Although not shown, the first communication hole 6 is formed in the lens main body 2 along a direction inclined at a predetermined angle from each of the first axial direction (X-axis direction) and the second axial direction (Y-axis direction) As shown in FIG.

Referring to FIG. 10, the optical lens 1 for LED illumination according to the present invention may include a second communication hole 7.

The second communication hole (7) is formed through the lens body (2). Accordingly, the second communication hole 7 can communicate the incident groove 5 located inside the lens body 2 with the outside of the lens body 2. [ Therefore, the second communication hole 7 can discharge the heat generated by the LED located in the lens body 2 to the outside of the lens body 2. [ Accordingly, the optical lens 1 for LED illumination according to the present invention can reduce the heat generation problem due to the heat generated when the LED installed in the LED illumination light emits light.

The second communication hole 7 may be formed in a rectangular parallelepiped shape, but is not limited thereto. The second communication hole 7 may be formed in a different shape as long as the incidence groove 5 can communicate with the outside of the lens body 2 have.

The second communication hole 7 may be formed through the lens body 2 along the first axial direction (X-axis direction). The second communication hole 7 may be formed to have a shorter length than the incident groove 5 in the second axial direction (Y-axis direction). Accordingly, the optical lens for LED illumination according to the present invention can not only reduce the heat generation problem due to the heat generated while the LEDs emit light through the second communication hole 7, The degree of reduction of the area of the bottom surface 21 due to the holes 7 can be reduced, so that the bonding force to the substrate can be enhanced.

The second communication hole 7 may be formed through the lens body 2 along the second axis direction (Y-axis direction). The second communication hole 7 may be formed to have a shorter length than the incident groove 5 in the first axial direction (X-axis direction). In this case, the optical lens 1 for an LED illumination according to the present invention is characterized in that, when compared with the embodiment in which the second communication hole 7 is formed along the first axis direction (X axis direction) Since the area occupied by the second communication hole 7 can be further reduced, the bonding force to the substrate can be further enhanced. In contrast to the embodiment in which the second communication hole 7 is formed along the first axial direction (X-axis direction), the optical lens 1 for LED illumination according to the present invention has the second communication hole 7 ) Can be reduced. Accordingly, the optical lens 1 for LED illumination according to the present invention is characterized in that, when compared with the embodiment in which the second communication hole 7 is formed along the first axial direction (X-axis direction) It is possible to reduce a traveling distance for supplying cool air existing outside the lens body 2 to the incident groove 5 and a traveling distance for discharging the heat existing in the incident groove 5 to the outside of the lens body 2 . Therefore, in contrast to the embodiment in which the second communication hole 7 is formed along the first axis direction (X-axis direction), the optical lens 1 for LED illumination according to the present invention, There is an advantage that the heat generation problem due to generated heat can be further reduced.

 Although not shown, the second communication hole 7 is formed in the lens main body 2 along a direction inclined at a predetermined angle from each of the first axial direction (X-axis direction) and the second axial direction (Y-axis direction) As shown in FIG.

The second communication hole (7) may be formed through the lens body (2) at a position spaced apart from the first communication hole (6). The second communication hole (7) and the first communication hole (6) may be formed in the lens body (2) so as to be positioned opposite to each other. In this case, any one of the second communication hole (7) and the first communication hole (6) functions to introduce air existing outside the lens body (2) It is possible to realize a function of discharging the air existing inside the air conditioner 2. Therefore, the optical lens 1 for LED illumination according to the present invention increases the ventilation force through the second communication hole 7 and the first communication hole 6, so that the air existing in the outside of the lens body 2 And to increase the output power to the air existing in the lens main body 2. Accordingly, the optical lens 1 for LED illumination according to the present invention can further reduce the heat generation problem due to heat generated when the LEDs emit light.

The second communication hole (7) and the first communication hole (6) may have different sizes. Accordingly, the optical lens 1 for LED illumination according to the present invention is able to reduce the difference between the air volume of the air flowing along the second communication hole 7 and the air volume of air flowing along the first communication hole 6 , It is possible to induce a pressure difference between the second communication hole (7) and the first communication hole (6) to occur. Therefore, since the optical lens 1 for LED illumination according to the present invention can further increase the ventilation force by using the difference in air pressure between the second communication hole 7 and the first communication hole 6, There is an advantage that the problem of heat generation due to the heat generated during the emission can be further reduced.

The second communication hole 7 is formed to have a larger width 7W than the width 6W of the first communication hole 6 with reference to the second axial direction (Y axis direction) 1 can be formed to have a larger size than the one communication hole 6. Although not shown, the second communication hole 7 is formed to have a height higher than the height of the first communication hole 6 in the upward direction (UD arrow direction, shown in FIG. 3) May be formed to have a larger size than the communication hole (6).

11, according to a modified embodiment of the present invention, the lens flange 3 may be formed to protrude outward from the upper surface of the lens body 2. [ In this case, the lens body 2 may be formed so as to be reduced in size from the lower side of the lens flange 3 toward the lower side (DD arrow direction). For example, the lens body 2 may be formed in the form of a circular trencated cone whose size decreases toward the lower direction (direction of the arrow DD). The first communication hole 6 and the second communication hole 7 may be formed through the lens body 2 so as to be connected to the incident grooves 5, respectively. In this case, the second communication hole 7 may be formed to have a larger size than the first communication hole 6.

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: Lens flange 4: Reflective portion
5: incidence groove 6: first communication hole
7: second communicating hole 21: bottom surface
31: engaging groove 41: engaging member
42: reflective member 421: reflective surface

Claims (10)

A lens body for diffusing light emitted by the LED;
A lens flange protruding outward from the lens body; And
A reflection part coupled to the lens flange so as to be positioned at a position spaced apart from the lens body in a first direction and reflecting light emitted by the LED;
An incident groove formed in the lens body such that the LED is positioned inside the lens body;
A first communication hole formed through the lens body to communicate the incident groove with the outside of the lens body; And
And a second communication hole formed through the lens body at a position spaced apart from the first communication hole,
The reflector reflects light emitted from the lens body toward the first direction,
Wherein the second communication hole is formed to have a larger size than the first communication hole so that a pressure difference occurs between the second communication hole and the first communication hole. The method according to claim 1,
Wherein the reflective portion reflects light emitted from the lens body toward the first direction toward the second direction so that an amount of light irradiated from the lens body toward a second direction opposite to the first direction is increased,
Wherein the lens body is installed such that a non-illuminated region in which illumination is unnecessary in the first direction side is located and an illuminated region in which illumination is required is located in the second direction side. The method according to claim 1,
Wherein the reflecting portion includes a coupling member for coupling to the lens flange, and a reflecting member for reflecting the light emitted by the LED,
Wherein the coupling member is coupled to the lens flange such that the reflecting member is located at a position spaced apart from the lens body in the first direction. The method of claim 3,
Wherein the lens flange includes an engaging groove into which the engaging member is inserted,
Wherein the engaging member is engaged with the engaging groove and is engaged with the lens flange. 5. The method of claim 4,
Wherein the coupling groove is formed to have a depth corresponding to the thickness of the coupling member and has a shape and an area corresponding to the coupling member. The method according to claim 1,
Wherein the reflective portion is formed of a material different from that of the lens body and is assembled to the lens flange. The method according to claim 1,
Wherein the reflective portion includes a reflective member for reflecting light emitted by the LED,
Wherein an inclined angle between an upper surface of the reflecting member and the upper surface of the lens flange is a right angle or an obtuse angle. The method according to claim 1,
Wherein the reflective portion includes a reflective member for reflecting light emitted by the LED,
Wherein an angle of inclination between the reflective member and the upper surface of the lens flange is an acute angle. The method according to claim 1,
Wherein the reflecting portion includes a reflecting member formed to protrude upward from the lens flange,
Wherein the reflective member includes a reflective surface for reflecting light emitted by the LED,
Wherein the reflective surface is formed to have a curved surface. The method according to claim 1,
Wherein the reflecting portion includes a reflecting member formed to protrude upward from the lens flange,
Wherein the second communication hole is formed at a height higher than the height of the first communication hole in the upward direction.

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