KR20160057919A - Backlight unit and display apparatus using the same - Google Patents

Abstract

Disclosed are a backlight unit and a display device using the same. The backlight unit of the present invention comprises: a substrate; at least one light assembly which is disposed on the substrate; and a reflective sheet in which at least one through hole corresponding to the at least one light assembly is formed. The light assembly comprises: a light source; a lens which is disposed above the light source; and a reflective ring which is disposed inside the through hole, is spaced apart from the light source by a predetermined distance, and includes an opening portion adapted to be smaller than the diameter of the lens and a sidewall disposed to face the light source in the opening portion. According to the present invention, the reflective ring which surrounds the light source is included, thereby improving uniformity of luminance of the backlight unit.

Description

BACKLIT UNIT AND DISPLAY APPARATUS USING THE SAME [0002]

The present invention relates to a backlight unit and a display device using the same.

(PDP), an electro luminescent display (ELD), a vacuum fluorescent display (VFD), a liquid crystal display (PDP), and the like have been developed in recent years. Display) have been studied and used.

Among them, a liquid crystal panel of an LCD includes a TFT substrate and a color filter substrate facing each other with a liquid crystal layer and a liquid crystal layer interposed therebetween, and an image can be displayed using light provided from the backlight unit.

The present invention is directed to solving the above-mentioned problems and other problems. Another object of the present invention is to provide a backlight unit including a reflection ring for improving luminance uniformity and a display device using the same.

According to an aspect of the present invention there is provided a substrate, comprising: at least one light assembly positioned on the substrate; and at least one through hole corresponding to the at least one light assembly, A light source, a lens positioned above the light source, and an opening portion located inside the aperture and spaced apart from the light source by a distance smaller than the diameter of the lens, And a reflecting ring provided with a sidewall disposed at the opening to face the light source.

The reflective ring may further include an upper surface extending in the radial direction of the lens at the opening.

And may include an inclined surface inclined with respect to the light source.

The side wall may include at least one of a first side wall on the side of the opening where the light source is located and a second side wall outside the reflection ring.

The sidewall may include a sloped surface of at least a partial region and a vertical plane of at least another region.

The inclined surface may be formed at an inclination angle of 60 degrees or more and 90 degrees or less.

The outer side wall of the reflection ring can be in contact with the reflection sheet.

At least a part of the reflection ring may be arranged to overlap with at least a part of the reflection sheet.

The side wall and the light source may have a constant spacing.

The separation distance may be 500 micrometers or more and 1 millimeter or less.

The opening may be in the shape of a circle, a triangle, or a pentagon.

The ratio of the height of the side wall to the height of the light source may be 0.4 or more and 1.0 or less.

The at least one optical assembly may include a COB (Chip On Board) type light source.

The thickness of the reflective ring may be different from the thickness of the reflective sheet.

The diameter of the reflective ring may be smaller than the diameter of the lens included in the optical assembly.

The reflectance of the sidewall may be greater than the reflectivity of the substrate.

At least one pattern may be formed on at least a part of the side wall and the upper side of the reflection ring.

The at least one pattern may include a plurality of regions in which at least one of a position, a shape, and a hue is different, and the plurality of regions may be formed with one region and another region repeatedly.

According to an aspect of the present invention, there is provided a backlight unit including a backlight unit including at least one light source, a display panel disposed on a front surface of the backlight unit, and a back cover disposed on a rear surface of the backlight unit, Wherein the backlight unit comprises a substrate, at least one light assembly positioned on the substrate, and a reflective sheet having at least one through hole corresponding to the at least one optical assembly, The optical assembly includes a light source, a lens positioned on the upper side of the light source, an opening portion located inside the through hole and spaced apart from the light source by a predetermined distance, the opening portion being smaller than the diameter of the lens, There is provided a display device including a reflection ring provided with a sidewall disposed to be opposed thereto.

The reflective ring may further include an upper surface extending in the radial direction of the lens at the opening.

Effects of the backlight unit and the display device using the same according to the present invention are as follows.

According to at least one of the embodiments of the present invention, there is an advantage that the luminance uniformity of the backlight unit can be improved by including the reflection ring that surrounds the light source.

Further scope of applicability of the present invention will become apparent from the following detailed description. It should be understood, however, that the detailed description and specific examples, such as the preferred embodiments of the invention, are given by way of illustration only, since various changes and modifications within the spirit and scope of the invention will become apparent to those skilled in the art.

1 to 5 are views showing the configuration of a display device related to the present invention.
6 to 29 are views for explaining the display device according to the present invention in detail.
30 to 42 are views showing another configuration of a display apparatus according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, wherein like reference numerals are used to designate identical or similar elements, and redundant description thereof will be omitted. The suffix "module" and " part "for the components used in the following description are given or mixed in consideration of ease of specification, and do not have their own meaning or role. In the following description of the embodiments of the present invention, a detailed description of related arts will be omitted when it is determined that the gist of the embodiments disclosed herein may be blurred. It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are intended to provide further explanation of the invention as claimed. , ≪ / RTI > equivalents, and alternatives.

1 to 5 are views showing the configuration of a display device related to the present invention.

Referring to FIG. 1, a display device 100 according to the present invention may include a front cover 105, a display panel 110, a backlight unit 120, and a back cover 130.

The front cover 105 may cover the upper surface and the side surface of the display panel 110. The front cover 105 may be in the form of a rectangular frame having a hollow center. Since the center of the front cover 105 is empty, the image of the display panel 110 can be displayed externally.

The display panel 110 is provided on the front surface of the display device 100 and images can be displayed. The display panel 110 may divide the image into a plurality of pixels and output an image by controlling color, brightness, and saturation for each pixel to emit light. The display panel 110 may be divided into an active area in which an image is displayed and an inactive area in which no image is displayed. The display panel 110 may include a front substrate and a rear substrate facing each other with a liquid crystal layer interposed therebetween.

The front substrate may include a plurality of pixels consisting of red (R), green (G) and blue (B) sub-pixels. The front substrate may generate an image corresponding to the red, green, or blue color when light is applied.

The back substrate may include switching elements. The rear substrate can switch the pixel electrodes. For example, the pixel electrode can change the molecular arrangement of the liquid crystal layer according to a voltage applied from the outside.

The liquid crystal layer may include a plurality of liquid crystal molecules. The liquid crystal molecules can change the arrangement in accordance with the voltage difference generated between the pixel electrode and the common electrode. The liquid crystal layer can transmit light provided from the backlight unit 120 to the front substrate.

The backlight unit 120 may be positioned on the rear surface of the display panel 110. The backlight unit 120 may provide light from the rear surface of the display panel 110 to the display panel 110. The detailed structure of the backlight unit 120 will be described later.

The backlight unit 120 may be closely attached to the rear surface of the display panel 110. For example, the backlight unit 120 may be attached to the back surface of the display panel 110 and fixed thereto. An adhesive layer may be formed between the backlight unit 120 and the display panel 110 to attach the backlight unit 120 to the display panel 110. [

Since the display panel 110 and the backlight unit 120 are in close contact with each other, the thickness of the display device 100 can be reduced. Further, since the structure for fixing the backlight unit 120 is not required, the manufacturing process can be simplified. Since the space between the backlight unit 120 and the display panel 110 is reduced, malfunction of the display device due to insertion of foreign substances into the space can be prevented.

The back cover 130 may be positioned on the back surface of the backlight unit 120. The back cover 130 can protect the backlight unit 120 from the outside.

The back cover 130 can be coupled with the front cover 105. [ The display panel 110 and the backlight unit 120 can be modularized by the back cover 130 and the front cover 105. [

Referring to FIG. 2, the optical sheet 125 may be positioned on the back cover 130. The optical sheet 125 can be engaged with the back cover 130 at the edge of the back cover 130. [ The optical sheet 125 can be seated directly on the edge of the back cover 30. [ That is, the optical sheet 125 can be supported by the back cover 30. The upper surface of the edge of the reflective sheet 125 may be surrounded by the upper guide panel 117. [ In detail, the optical sheet 125 can be positioned between the edge of the back cover 130 and the upper guide panel 117.

The display panel 110 may be positioned on the optical sheet 125. [ The display panel 110 can be engaged with the upper guide panel 117 at the edge. The display panel 110 may be seated directly on the upper guide panel 117. That is, the display panel 110 can be supported by the upper guide panel 117. The side of the display panel 110 can be guided by the upper guide panel 117. The upper surface of the edge of the display panel 110 may be enclosed by the front cover 105. In detail, the display panel 110 may be positioned between the upper guide panel 117 and the front cover 105.

Meanwhile, the display device according to the present invention may further include a lower guide panel 113 between the back cover 13 and the optical sheet 125. In this case, the optical sheet 125 can be directly seated on the lower guide panel 113. That is, the optical sheet 125 can be supported by the lower guide panel 117.

3 and 4, the backlight unit 120 includes a printed circuit board 122, at least one optical assembly 124, a reflective sheet 126, a diffuser plate 129, and an optical sheet 125 .

The printed circuit board 122 may include a plurality of strips extending in a first direction and spaced apart from each other by a predetermined distance in a second direction orthogonal to the first direction. The printed circuit board 122 may be a substrate on which at least one optical assembly 124 is mounted. The printed circuit board 122 may be formed with an electrode pattern for connecting the adapter and the optical assembly 124. For example, the printed circuit board 122 may be formed with a carbon nanotube electrode pattern for connecting the optical assembly 124 and the adapter.

The printed circuit board 122 may be composed of polyethylene terephthalate (PET), glass, polycarbonate (PC), silicon, or the like. The printed circuit board 122 may be a printed circuit board (PCB) board on which at least one optical assembly 124 is mounted.

The optical assembly 124 may be mounted on the printed circuit board 122 at a predetermined interval in the first direction. The diameter of the optical assembly 124 may be greater than the width of the first layer 122 in the second direction. The optical assembly 124 may be one of a light emitting diode (LED) light emitting diode package or a light emitting diode package including at least one light emitting diode chip.

The optical assembly 124 may be comprised of a colored LED or white LED emitting at least one color from among colors such as red, blue, green, and the like. The colored LED may include at least one of a red LED, a blue LED, and a green LED.

 A reflective sheet 126 may be positioned on the printed circuit board 122. The reflective sheet 126 may be located on an area other than the area where the optical assembly 124 of the printed circuit board 122 is formed. That is, the reflective sheet 126 may have a through hole 235 in the region where the optical assembly 124 is formed.

The reflective sheet 126 may reflect light emitted from the optical assembly 124. Further, the reflective sheet 126 can reflect the light totally reflected from the diffuser plate 129 again. Accordingly, the reflective sheet 126 can cause the light emitted from the optical assembly 124 to diffuse more widely.

The reflective sheet 126 may include at least one of a metal or a metal oxide that is a reflective material. For example, the reflective sheet 126 is an aluminum (Al), silver (Ag), gold may comprise a metal or metal oxide having high reflectance, such as any one of (Au), and titanium dioxide (TiO ₂₎ .

The reflective sheet 126 may be formed by depositing or coating a metal or metal oxide on the printed circuit board 122. The reflective sheet 126 can be formed by printing metallic ink. The reflective sheet 126 may be deposited using a vacuum deposition method such as a thermal evaporation method, an evaporation method, or a sputtering method. The reflective sheet 126 can be coated or printed using a printing method, a gravure coating method, or a silk screen method.

An air gap may be located on the optical assembly 124 and the reflective sheet 126. The air gap can serve as a buffer through which light emitted from the optical assembly 124 can spread widely. On the other hand, the resin can be deposited on the optical assembly 124 and the reflective sheet 126. In this case, the resin may act to diffuse the light emitted from the optical assembly 124.

The diffuser plate 129 may be positioned on the air gap. The diffuser plate 129 may diffuse the light emitted from the optical assembly 124 upward.

The optical sheet 125 may be placed on the diffuser plate 129. [ The optical sheet 125 may include at least one sheet. In detail, the optical sheet 125 may include one or more prism sheets and / or one or more diffusion sheets.

The plurality of sheets contained in the optical sheet 125 may be provided without being separated from each other and adhered to or adhered to each other to reduce the thickness of the optical sheet 125 or the backlight unit 120. [

The lower surface of the optical sheet 125 is in close contact with the diffusion plate 129 and the upper surface of the optical sheet 125 is in close contact with the lower surface of the display panel 110. [

The diffusion sheet in the optical sheet 125 can prevent the light from the diffusing plate from being partially concentrated, thereby making the brightness of the light more uniform. In addition, the prism sheet of the optical sheet 125 may condense the light emitted from the diffusion sheet to allow light to be vertically incident on the display panel 110.

The optical sheet 125 may be composed of a plurality of sheets having different functions. For example, the optical sheet 125 may include first to third optical sheets 125a to 125c, wherein the first optical sheet 125a has the function of a diffusing sheet, 125b, and 125c may have the function of a prism sheet.

On the other hand, the optical sheet 125 may include first and second optical sheets 125a and 125b. The first optical sheet 125a has the function of a diffusing sheet and the second optical sheet 125b can function as a prism sheet.

The backlight unit 120 may be driven by a whole driving method or a partial driving method such as local dimming, impulsive, or the like. However, the present invention is not limited thereto, and the driving method of the backlight unit 120 may be variously changed according to the circuit design. Accordingly, the display device according to the present invention can display a dark part and a bright part on the screen clearly, and thus the image quality can be improved.

5, a printed circuit board 122 may be provided on the back cover 130 and may include a plurality of strips extending in a first direction and spaced apart from each other by a predetermined distance in a second direction orthogonal to the first direction . One end of the plurality of printed circuit boards 122 may be connected to the wiring electrodes 232.

The wiring electrode 232 may extend in the second direction. The wiring electrodes 232 may be connected to one end of the first layer 122 at regular intervals in the second direction. The wiring electrode 232 can electrically connect the printed circuit board 122 to the adapter.

The optical assembly 124 may be mounted on the printed circuit board 122 at a predetermined interval in the first direction. The diameter of the optical assembly 124 may be greater than the width of the first layer 122 in the second direction. Accordingly, the outer region of the optical assembly 124 can penetrate into the region where the first layer 122 is not provided.

FIGS. 6 to 29 are views for explaining a display device according to the present invention in detail.

Referring to FIG. 6, the light source package 303 may be located on the printed circuit board 122. The light source package 303 may be located at the center of the optical assembly 124. The light source package 303 may be located in a portion of the optical assembly 124 that is not the center.

The light source package 303 may include a light source 203, a lead frame 305, a package body 307, and a reflector 309.

The package body 307 may be located on the printed circuit board 122. The lead frame 305 may wrap the package body 307. The lead frame 305 can connect the light source 203 and the printed circuit board 122 through wires. Accordingly, a predetermined voltage, which is transmitted from the printed circuit board 122 through the wire, can be transmitted to the light source 203.

The light source 203 may be positioned on the lead frame 305. [ The light source 203 can be mounted on the lead frame 305 in detail.

The reflection plate 309 may be positioned on the lead frame 305. [ The reflection plate 309 may surround the side surface of the light source 203. The reflection plate 309 may reflect light emitted from the side surface of the light source 203 to improve the luminous efficiency of the light source 203. The reflection plate 309 can adjust the inclination angle in consideration of the characteristics of light from the light source 203.

The optical assembly 124 may be a package on board (POB) type optical assembly 124. In particular, the optical assembly 124 may be an optical assembly 124 that mounts a chip-mounted package to the board rather than a chip.

Referring to FIG. 7, the POB type optical assembly 124 may include at least one wire 313 on both upper sides of the light source 203. At least one wire 313 may electrically connect the light source 203 and the lead frame 305. [

The light source 203 may be a combination of a p-type semiconductor providing pores as a light source generating light and an n-type semiconductor providing electrons.

The fluorescent layer 137 may be positioned on the light source 203 between the reflection plates 309. [ The fluorescent layer 137 may cover the light source. Further, the fluorescent layer 137 may be surrounded by the reflection plate 309. The fluorescent layer 137 may include a fluorescent material that converts the light of the spectrum generated from the light source 203 into white light. The fluorescent layer 137 may have the same thickness on the light source 203. Further, the fluorescent layer 137 may have the same height as the height of the upper portion of the reflection plate 309. The fluorescent layer 137 may have a refractive index of 1.4 to 2.0.

The optical assembly 124 according to the present invention can have high process reliability. Accordingly, additional investment may not be required when fabricating the optical assembly 124. However, since the heat dissipation characteristics are limited, it may not be easy to drive at a high current.

8, the optical assembly 124 may include a light source 203, a lens 205, and a reflective ring 207. As shown in FIG.

The light source 203 may be located on the printed circuit board 122. The light source 203 may be located in the center of the optical assembly 124. The light source 203 may be located in a portion of the optical assembly 124 that is not the center portion.

The light source 203 can emit light by an electric signal. For example, the light source 203 can emit light in a third direction by an electrical signal. However, the present invention is not limited thereto, and the light source 203 may emit light in a direction tilted by a predetermined angle from the third direction by an electric signal.

The lens 205 may be located above the light source 203. The lens 205 may be larger than the diameter of the light source 203. In other words, the lens 205 may be shaped to surround the light source 203. The lens 205 can change the direction of light emitted from the light source 203 to transmit light to the display panel. The detailed structure of the lens 205 will be described later.

The upper portion of the lens 205 may include a protrusion 213 to which an outer portion protrudes. In other words, the diameter of the upper portion of the lens 205 may be larger than the diameter of the lower portion of the lens 205.

The lens 205 may be surrounded by the reflective sheet 126. The diameter of the area where the reflective sheet 126 is not provided may be larger than the diameter of the lower portion of the lens 205 and smaller than the diameter of the upper portion of the lens 205. [ That is, the outer region above the lens 205 may overlap with the one end of the reflective sheet 126 in the first and second directions.

The lens 205 may include a material having a refractive index of 1 or more and 1.5 or less. For example, the lens 205 may comprise any one of PMMA (Poly Methyl Mata Acrylate), COC (Cylic Olefin Copolymer), or a combination thereof.

The upper surface of reflective sheet 126 may be higher than the lower surface of lens 205 and lower than the upper surface. But the upper surface of the reflective sheet 126 may be lower than the lower surface of the lens 205. [

A reflective ring 207 may be positioned surrounding the light source 203. The reflecting ring 207 may not contact the light source 203. The reflective ring 207 has a first surface 217 facing the light source 203, a second surface 219 facing the reflective sheet 126, and a third surface 221 facing the lens 205 .

The reflective ring 207 may comprise the same or similar material as the reflective sheet 126. For example, the reflective ring 207 may include at least one of a metal or a metal oxide that is a reflective material. The reflective ring 207 may have a higher reflectivity than the printed circuit board 122.

The reflective ring 207 may be spaced apart from the reflective sheet 126 at a certain distance. Unlike the reflective sheet 126, the reflective ring 207 can reflect light incident into the lens diameter. The detailed function and structure of the reflection ring 207 will be described later.

The optical assembly 124 may be a COB (Chip on Board) type optical assembly 124. In detail, the optical assembly 124 may be an optical assembly 124 that directly mounts the chip on the board.

The optical assembly 124 according to this embodiment may be positioned on the printed circuit board 122 directly by the light source 203. Accordingly, it is possible to reduce the size and weight of the optical assembly 124.

9, the light source 203 of the optical assembly 124 according to an embodiment of the present invention may be a COB type. The light source 203 of the COB type optical assembly 124 may include at least one of the light emitting layer 135, the first and second electrodes 147 and 149, and the fluorescent layer 137.

The light emitting layer 135 may be located on the printed circuit board 122. The light emitting layer 135 may emit light of any one of blue, red, and green. The light-emitting layer 135 is _{Firpic, (CF3ppy) 2 Ir (} pic), 9, 10-di (2-naphthyl) anthracene (AND), Perylene, distyrybiphenyl, PVK, OXD-7, UGH-3 (Blue), and these Or a combination thereof.

The first and second electrodes 147 and 149 may be located on both sides of the lower surface of the light emitting layer 135. The first and second electrodes 147 and 149 may transmit an external driving signal to the light emitting layer 135.

The fluorescent layer 137 may cover the light emitting layer 135 and the first and second electrodes 147 and 149. The fluorescent layer 137 may include a fluorescent material that converts the light of the spectrum generated from the light emitting layer 135 into white light. The fluorescent layer 137 may have the same thickness on the light emitting layer 135. The fluorescent layer 137 may have a refractive index of 1.4 to 2.0.

The optical assembly 124 according to the present invention may have a high luminous efficiency because the light source 203 is directly disposed on the printed circuit board 122. Accordingly, the size of the optical assembly 124 can be reduced.

In addition, since the light source 203 is directly disposed on the first layer 122 and the heat dissipation is excellent, the optical assembly 124 can be driven at a high current. Accordingly, the number of optical assemblies 124 required for the backlight unit 120 can be reduced.

In addition, the optical assembly 124 may be located on the printed circuit board 122 directly without the need for a wire bonding process. Thus, the cost can be saved by simplifying the process.

Unlike the conventional POB type optical assembly, since the COB type optical assembly 124 has no reflecting plate, the light can escape to the side without passing through the lens 205. This can prevent the reflective ring 207 from leaking to the side.

Hereinafter, the light source package 303 is located on the printed circuit board 122, and the light source 203 is shown on the printed circuit board 122 for convenience of explanation.

11, the lens 205 includes a lower surface 413, a conical groove 415, a support 417, a conical side surface 419, an inverted conical groove 423, an inverted conical side surface 425, And a surface 427.

The conical groove 415 may be located at the center of the lower surface 413. In detail, the conical groove 415 may be shaped so as to penetrate from the central portion of the lower surface 413 toward the upper portion. The conical groove 415 may be a conical shape with a vertex surrounding the light source. The conical groove 415 can transmit the light incident from the light source to the side surface or the upper surface of the lens 205.

The support portion 417 may be located in an outer circumferential region where the conical groove 415 is connected to the lower surface 413. The supporting portion 417 may be located at a position where the conical groove 415 is divided into three parts, which are connected to the lower surface 413. The supporting portion 417 may be located at a position where the conical groove 415 divides the outer side connected to the lower surface 413 into three or more. The support portion 417 may protrude from the lower surface 413 to the outside of the lens 205. The support 417 may be cylindrical, triangular, or rectangular parallelepiped.

The supporting portion 417 can couple the lens 205 and the printed circuit board. The lens 205 may be spaced apart from the printed circuit board by a predetermined distance. Accordingly, the light source and the reflection ring can be positioned between the lens 205 and the first layer.

  The conical side surface portion 419 may extend from the lower surface 413 toward the upper surface 427. The length of the conical side surface portion 419 in the third direction may coincide with the length of the conical groove 415 in the third direction. And the length of the conical side surface portion 419 in the third direction may be longer than the length of the conical groove 415 in the third direction. The conical side surface portion 419 may refract light reflected from the inverted conical groove 423 or directly from the conical groove 415. [

The inverted conical groove 423 may be located at the center of the upper surface 427. Specifically, the inverted conical groove 423 may be shaped to penetrate from the central portion of the upper surface 427 to the lower surface. The inverted conical groove 423 may be a shape in which a vertex-cut cone is inverted. The center of the inverted conical groove 423 may coincide with the center of the conical groove 415. [ The open conical groove 423 may induce total reflection of incident light and may transmit light to the side or bottom surface 413.

The inverted conical side surface portion 425 may extend from the upper surface toward the lower surface 413. The inverted conical side surface portion 425 may extend from the conical side surface portion 419. The length of the inverted conical side surface portion 425 in the third direction may coincide with the length of the conical groove 415 in the third direction. The length of the inverted conical side surface portion 425 in the third direction may be longer than the length of the inverted conical trough 423 in the third direction. The inverted conical side surface portion 425 can refract the light totally reflected in the inverted conical trough 423.

11, when there is no reflecting ring 207, the light emitted upward from the light source 203 can be totally reflected in the inverted conical groove 423. [ The light totally reflected in the inverted conical groove 423 may be totally reflected from the inverted conical side surface portion 425 to the lower surface 413. The light totally reflected by the lower surface 413 may be refracted and directed to the printed circuit board 122.

At least a portion of the light refracted by the first layer 122 may be absorbed by the first layer 122. Accordingly, the amount of light transmitted to the upper portion of the lens 205 may be small. Therefore, the luminance uniformity of the backlight unit can be low.

Conversely, when the reflective ring 207 is present, the light refracted toward the printed circuit board 122 can be reflected by the reflective ring 207 and refracted at the lower surface 413. The light refracted at the lower surface 413 may be refracted again in the inverted conical groove 423 and directed to the lens upper surface 427. Accordingly, the amount of light transmitted to the upper portion of the lens 205 may be large. Therefore, the luminance uniformity of the backlight unit can be increased.

Referring to FIG. 12, the diameter LD of the lens 205 may be larger than the diameter RD of the reflection ring 207. For example, when the diameter (LD) of the lens is 25 mm or more and 28 mm or less, the diameter RD of the reflection ring 207 may be 22.5 mm.

The thickness of the reflective ring 207 may be different from the height of the reflective sheet 126. The reflection sheet 207 reflects the light incident on the lens 205 and the reflection ring 207 reflects the light incident on the light source 203 lower than the lens 205. Therefore, The thickness of the reflective sheet 126 may be smaller than the thickness of the reflective sheet 126.

The diameter RD of the reflecting ring 207 may not be larger than the diameter LD of the lens 205 because the reflecting ring 207 has a function of reflecting the light incident on the lower portion of the lens 205. [

The reflective sheet 126 may be shaped to surround the lens 205. Accordingly, the reflection sheet 126 can be located outside the lens 205. Since the reflective sheet 126 surrounds the lens 205, the height of the upper surface may be higher than the height of the lower surface 413 of the lens 205.

Referring to Figures 13-15, the reflective ring 207 may be circular, triangular, or pentagonal in shape surrounding the light source 203. Both the outer side 207a and the inner side 207b of the reflective ring 207 may have a circular, triangular, or pentagonal shape. When the reflecting ring 207 is in a circular, triangular, or pentagonal shape surrounding the light source 203, the peripheral portion of the lens may be brighter than the central portion of the lens.

The reflective ring 207 may include an opening 263. The opening 263 may be spaced a certain distance from the light source.

The width L1 of the reflective ring 207 in the second direction may be larger than the width L2 of the printed circuit board 122 in the second direction. The diameter of the lens may be greater than the width of the printed circuit board 122 in the second direction. The width L1 of the reflecting ring 207 in the second direction is substantially equal to the diameter of the lens since it must be located at a portion where light is incident on the lower portion of the lens. Accordingly, it can be larger than the width L2 of the printed circuit board 122 in the second direction.

Since the reflecting ring 207 surrounds the light source 203, the backlight unit according to the present invention reflects at least a part of light in all directions incident on the lower portion of the lens 205 to the upper portion of the lens 205 . Thus, the luminance uniformity of the backlight unit can be increased.

Referring to FIG. 16, the reflecting ring 207 may be shaped to surround the light source 203. In particular, the inside 207b of the reflective ring 207 can have at least three protrusions. Accordingly, the distance between the inside 207a and the outside 207b of the reflecting ring 207 can be gradually changed from the first distance OL1 to the second distance OL2. When the reflecting ring 207 surrounds the light source 203 and the distance between the inner side 207a and the outer side 207b gradually changes and the shape changes, the backlight unit has a center portion of the lens brighter Can be.

The width L1 of the reflective ring 207 in the second direction may be larger than the width L2 of the printed circuit board 122 in the second direction. The diameter of the lens may be greater than the width of the printed circuit board 122 in the second direction. The width L1 of the reflecting ring 207 in the second direction is substantially equal to the diameter of the lens since it must be located at a portion where light is incident on the lower portion of the lens. Accordingly, it can be larger than the width L2 of the printed circuit board 122 in the second direction.

Since the reflecting ring 207 surrounds the light source 203, the backlight unit according to the present invention reflects at least a part of light in all directions incident on the lower portion of the lens 205 to the upper portion of the lens 205 . Thus, the luminance uniformity of the backlight unit can be increased.

Referring to Fig. 17, at least one groove 238 may be located on the inner side 207a of the reflection ring 207. In Fig. At least one groove 238 may protrude from the inner side 207a toward the outer side 207b. At least one groove 238 may be a hemispherical shape. But not limited thereto, at least one groove 238 may be triangular, circular, or rectangular in shape.

At least one groove 238 may fit into at least one projection located on the printed circuit board 122. Accordingly, the reflection ring 207 can be more easily mounted when the reflection ring 207 is mounted on the printed circuit board 122.

The backlight unit according to the present invention may include at least one groove 238 in the inner side 207a of the reflection ring 207. [ Thus, when the reflective ring 207 is mounted, the position where the reflective ring 207 is mounted by the at least one groove 238 can be aligned.

Referring to FIG. 18, the reflective ring 207 may include at least one pattern 249 on its upper surface. At least one pattern 249 may be a circular shape. However, the present invention is not limited thereto, and at least one pattern 249 may have a shape such as a triangle, a square, or a star.

The at least one pattern 249 may include a plurality of regions in which at least one of the position, shape, color, and the like is different. One of the plurality of regions and one of the regions may be repeatedly formed.

The at least one pattern 249 may be located a third distance F1 away from the inside 207a of the reflective ring 207. [ The at least one pattern 249 may also be located at a distance away from the inner side 207a of the reflective ring 207 by a fourth distance F2.

Only one pattern 249 can be positioned at a position where the inner side 207a and the outer side 207b of the reflection ring 207 are connected by a single line. In other words, at least one pattern 249 may be staggered on the reflective ring 207.

The reflective ring 207 according to the present invention may have at least one pattern 249 engraved in zigzags. Accordingly, the backlight unit can maintain a uniform luminance by adjusting the amount of light reflected to the upper portion of the lens.

Referring to FIG. 19, at least one pattern 249 may correspond only to a distance from the inside 207a of the reflective ring 207. At least one pattern 249 may be located at an intermediate portion between the inner side 207a and the outer side 207b of the reflective ring 207.

Since the reflective ring 207 according to the present invention is located in one line instead of zigzag, the process is simplified and the cost can be reduced.

Referring to FIG. 20, at least one pattern 249 located in a zigzag fashion may lead to one. The resulting pattern 249 may surround the light source 203. The subsequent pattern 249 may be a shape in which the protrusions are repeated.

Since the reflective ring 207 according to the present invention has at least one pattern 249 connected thereto, the light amount of the omni-directional light can be adjusted more than when it is apart. Therefore, the backlight unit can maintain a uniform brightness.

21, at least one pattern 249 may be located at a third distance F1 and a fourth distance F2 from the inner side 207a of the reflective ring 207. As shown in FIG. The reflective ring 207 may include at least one pattern 249 at a fourth distance F2 that is greater than the third distance F1. For example, at least one pattern 249 located a third distance F 1 from the inner side 207a may be at least one pattern 249 located a fourth distance F2 from the inside 207a More than twice as many can be.

The reflective ring 207 according to the present invention includes at least one pattern 249 at a fourth distance F2 that is greater than the third distance F1 so that the outer periphery of the reflective ring 207, So that the reflection can be reduced. Therefore, the backlight unit can maintain a uniform brightness.

22, the inner side 207a of the reflective ring 207 has at least three protrusions, and the distance between the inner side 207a and the outer side 207b of the reflective ring 207 is the distance 2 < / RTI > distance OL2.

The at least one pattern 249 may be located at a third distance F1 and a fourth distance F2 away from the recessed portion of the inner side 207a of the reflective ring 207. [ At least one pattern 249 may be staggered on the reflective ring 207.

When the reflecting ring 207 according to the present invention surrounds the light source 203 and the distance between the inner side 207a and the outer side 207b gradually changes alternately, The center can be brighter.

Also, the reflective ring 207 according to the present invention may have at least one pattern 249 engraved in zigzags. Accordingly, the backlight unit can maintain a uniform luminance by adjusting the amount of light reflected to the upper portion of the lens.

23, the inner side 207a of the reflective ring 207 has at least three protrusions, and the distance between the inner side 207a and the outer side 207b of the reflective ring 207 is the distance 2 < / RTI > distance OL2.

The reflective ring 207 may be followed by at least one pattern 249 located in a zigzag fashion. The resulting pattern 249 may surround the light source 203. The subsequent pattern 249 may be a shape in which the protrusions are repeated.

When the reflecting ring 207 according to the present invention surrounds the light source 203 and the distance between the inner side 207a and the outer side 207b gradually changes and changes in shape, The center can be brighter.

In addition, since at least one pattern 249 is connected to the reflection ring 207 according to the present invention, the light amount of the omnidirectional light can be adjusted more than when it is apart. Therefore, the backlight unit can maintain a uniform brightness.

Referring to FIG. 24, at least one pattern 249 may be positioned on the surface 217 facing the light source 203 in the reflective ring 207. At least one pattern 249 may be zigzagged on the first side 217.

The first surface 217 of the reflective ring 207 may be inclined. When the first surface 217 of the reflective ring 207 is inclined, the reflection of light incident on the side surface is greater than when the first surface 217 is vertical, so that the light efficiency can be increased.

The reflective ring 207 according to the present invention may have at least one pattern 249 engraved on the first surface 217 in zigzag. Accordingly, the backlight unit can maintain a uniform luminance by adjusting the amount of light reflected to the upper portion of the lens.

Referring to FIG. 25, at least one pattern 249 may be located on the first surface 217 of the reflective ring 207. At least one pattern 249 may be staggered on the first side 217 of the reflective ring 207.

The first surface 217 of the reflective ring 207 may be inclined. When the first surface 217 of the reflective ring 207 is inclined, the reflection of light incident on the side surface is greater than when the first surface 217 is vertical, so that the light efficiency can be increased.

The number of patterns 249 may be increased as the first surface 217 of the reflection ring 207 is farther from the ground. In other words, the number of the patterns 249 can be increased as the height of the first surface 217 of the reflection ring 207 is higher.

Since the number of the patterns 249 increases as the first surface 217 is farther away from the ground surface, the reflection ring 207 according to the present invention has less reflection on the first surface 217, . Therefore, the backlight unit can maintain a uniform brightness.

Referring to FIG. 26, when light is incident on two media having different refractive indices, light may be refracted through the boundary between the two materials. The refractive index may be different depending on the wavelength of light. Accordingly, when light is refracted, the light can be refracted at different angles according to each wavelength. For example, when light is incident on one medium from one medium, the angle at which the yellow light is refracted compared to the blue light may be larger.

White LEDs have a large wavelength difference between yellow and blue, so that when the light is incident on the lens, the color can be separated into yellow and blue. When the colors are separated into yellow and blue, the uniformity of color may be lowered. In other words, the color coordinates are low around the lens and the color coordinates between the lens and the lens may be high.

Referring to FIG. 27, when light is incident on the lens 205 from a light source 203, a general backlight unit can separate colors into blue (B) and yellow (Y) due to a difference in refractive index depending on wavelength. Accordingly, the light of yellow (Y) can be reflected to the outside of the reflection ring 207 as compared with the light of blue (B).

The light reflected by the reflecting ring 207 is again refracted by the lens 205 and blue (B) may appear at the center of the lens more than yellow (Y).

The backlight unit according to the present invention may be such that at least one pattern 249 of the reflective ring 207 is yellow. Thus, as well as the yellow light being reflected, the blue light can also be reflected by the at least one pattern 249 to a more yellowish light when it is reflected. Accordingly, color separation phenomenon of incident light can be reduced.

28, only the pattern 249 at the third distance F1 from the inside 207a of the reflection ring 207 may contain yellow. In other words, the pattern 249 at the third distance F1 from the inside 207a of the reflection ring 207 includes yellow and the pattern 249 at the fourth distance F2 from the outside 207b ) May include black.

The black pattern 249 and the yellow pattern 249 may be staggered with respect to each other.

Since the pattern 249 at the third distance F1 from the inner side 207a of the reflecting ring 207 according to the present invention includes yellow, the blue light incident on the inside can be made to approach yellow light. Accordingly, color separation phenomenon of incident light can be reduced.

In addition, since the pattern 249 at the portion away from the inner side 207a by the fourth distance F2 reduces the amount of reflected light, the brightness of the backlight unit can be made uniform.

29, the projection 274 may be positioned at the third distance F1 and the fourth distance F2 from the inside 207a of the reflecting ring 207. [ Only one projection 274 can be positioned at a position where the inside 207a and the outside 207b of the reflection ring 207 are connected by a single line. In other words, at least one projection 274 may be staggered on the reflective ring 207.

Since the reflecting ring 207 according to the present invention is arranged in a staggered manner, the angle of light reflected by the reflecting ring 207 can be adjusted to make the brightness of the backlight unit uniform.

30 to 42 are views showing another configuration of a display device according to the present invention.

Referring to FIG. 30, a package on board (POB) type optical assembly as shown in FIG. 6 may have less light leaking laterally because a reflector (309 in FIG. 6) is located.

However, the optical assembly of a COB (Chip On Board) type as shown in Fig. 8 may not have a reflector. In this case, light can leak to the side surface of the light source 203. When light leaks to the side surface of the light source 203, a luminescent spot or a fringing may occur on the lens 205. Accordingly, the image quality of the upper portion of the lens 205 may be uneven or not smooth.

The light incident on the side of the conventional light source 203 without the reflection ring 207 can be refracted to the lower surface 413 of the lens 205. [ The refracted light may be totally reflected at the inverted conical side surface portion 425 of the lens 205. The totally-reflected light may be refracted into the inverted conical groove 423 and incident on the upper portion of the lens.

Light incident on the side of the light source 203 may be directed to the top of the lens 205. The light directed toward the upper portion of the lens 205 may gather to form a bright spot or a fringe. Accordingly, the luminance uniformity of the backlight unit may not be maintained.

The backlight unit according to the present invention may surround the light source 203 and the reflective ring 207 may be positioned. The reflecting ring 207 may include an opening 263 spaced a certain distance from the light source 203 and a side wall 267 reflecting the light emitted from the light source 203. The light incident on the side of the light source 203 may be reflected to the side wall 267 of the reflection ring 207. [ The reflected light may be refracted into the lower surface 413 of the lens 205 or the conical groove 415. The refracted light may be refracted to the inverted conical side surface portion 425 or reflected to the inverted conical trough 423 and refracted to the inverted conical side surface portion 425. [

The light refracted at the inverted conical side surface portion 425 can be dispersed to various places unlike the case where there is no reflecting ring 207. [

The backlight unit according to the present invention can distribute the side light of the light source 203 by the reflection ring 207 without being concentrated in one place but in four directions. Thus, the luminance uniformity of the backlight unit can be maintained.

Referring to FIG. 31, the height H2 of the reflecting ring 207 may be lower than the height H1 of the light source 203. The reflecting ring 207 can prevent light leaking from the side of the light source 203. In addition, the light incident on the non-side surface of the light source 203 can be diffused by reflection inside the lens 205. The height H2 of the reflecting ring 207 may be lower than the height H1 of the light source 203 in order to block the light leaking from the side of the light source 203. [

The height H2 of the reflecting ring 207 may be higher than 40% of the height H1 of the light source 203. [ The reflective ring 207 can function to block and reflect the light leaking from the side surface. However, if the height H2 of the reflecting ring 207 is less than 40% of the height H1 of the light source 203, the light may not be blocked. The height H2 of the reflecting ring 207 may be higher than 40% of the height H1 of the light source 203. [

Referring to FIG. 32, the outer side 207b of the reflection ring 207 according to the present invention has a circular shape, and the inner side 207a may be the same as or similar to the shape of the light source 203. FIG. The inside 207a of the reflecting ring 207 may be the same or similar to the shape of the light source 203 in order to maintain a predetermined distance from the light source 203 at all positions.

The inside 207a of the reflecting ring 207 may be spaced apart from the light source 203 by a predetermined distance D1. For example, the inside 207a of the reflecting ring 207 may have an interval of 500 micrometers or more and 1 millimeter or less with the light source 203. [ The interval between the inner side 207a of the reflection ring 207 and the light source 203 should be 500 micrometers or more and 1 millimeter or less to prevent light leaking to the side of the light source 203. If the distance between the inner side 207a of the reflection ring 207 and the light source 203 is less than 500 micrometers, the reflection ring 207 is less able to be reflected. If the distance is more than 1 millimeter, the leakage light can not be blocked.

33, the reflection ring 207 and the reflection sheet 126 can be in contact with each other. One side of the reflective ring 207 may protrude out of the lens 205 because the reflective ring 207 must contact the reflective sheet 126.

The space between the reflection ring 207 and the reflection sheet 126 can be removed since the reflection ring 207 according to the present invention is in contact with the reflection sheet 126. [ Thus, it is possible to prevent light from entering the space between the reflection ring 207 and the reflection sheet 126 and being absorbed by the printed circuit board 122. Therefore, the light efficiency of the backlight unit can be improved.

Referring to Fig. 34, the reflection ring 207 and the reflection sheet 126 may overlap each other. One side of the reflective sheet 126 may span the top of the reflective ring 207. Accordingly, one side of the reflective sheet 126 can penetrate into the lower portion of the lens 205. The height including the reflection ring 207 and the reflection sheet 126 may be higher than the height of the light source 203 because one side of the reflection sheet 126 overlaps the upper side of the reflection ring 207. [

The reflecting ring 207 according to the present invention may not leak light between the reflecting ring 207 and the reflecting sheet 126 because the reflecting ring 207 and the reflecting sheet 126 overlap each other. Accordingly, the light absorbed by the printed circuit board 122 is reduced and the light efficiency can be increased.

35 and 36, the surface 217 of the reflecting ring 207 facing the light source 203 may be inclined. The angle A1 of the surface 217 of the reflecting ring 207 facing the light source 203 can be 60 degrees or more and 90 degrees or less from the ground. If the angle A1 of the reflecting ring 207 with respect to the light source 203 facing the light source 203 is less than 60 degrees, the light leaking from the side of the light source 203 is not reflected by the lens 205 but leaks sideways I can go out.

The amount of light incident on the side surface of the light source 203 may be larger than the amount of light incident on the lower surface side toward the upper side. The light on the upper side of the light source 203 can be reflected on the upper side of the first surface 217 of the reflection ring 207 when the first surface 217 of the reflection ring 207 is inclined. The reflected light can be totally reflected in the inverted conical groove 423 of the lens and dispersed laterally.

The light on the lower side of the light source 203 can be reflected on the lower side of the surface 217 facing the light source 203 of the reflection ring 207. The reflected light can be totally reflected in the inverted conical groove 423 of the lens and dispersed laterally. The light on the lower side of the light source 203 can be dispersed to a portion closer to the light on the upper side.

Since the reflecting ring 207 according to the present invention is inclined on the surface 217 facing the light source 203, the light incident on the upper side surface of the light source 203 having a large light amount is scattered farther, The light incident on the lower side can be dispersed relatively close to each other.

Referring to FIG. 37, the lower portion of the first surface 217 of the reflection ring 207 is not inclined and only the upper portion may be inclined. In other words, the first surface 217 of the reflective ring 207 may include at least a sloped surface of a region and a vertical surface of at least another region. The reflective ring 207 may have a trapezoidal shape. The angle A2 at the top of the first surface 217 of the reflective ring 207 may be at least 60 degrees from the ground. Light leaking from the side of the light source 203 can leak sideways without being reflected by the lens 205 if the angle A2 on the upper side of the first surface 217 of the reflecting ring 207 is smaller than 60 degrees .

Since the lower surface of the first surface 217 of the reflecting ring 207 according to the present invention is not inclined and only the upper portion may be inclined, the light incident on the upper surface of the light source 203 having a large light amount is scattered far away, The light incident on the lower side surface of the light guide plate 203 may be relatively closely dispersed.

Further, since the lower portion of the first surface 217 of the reflection ring 207 is not inclined, the dispersion according to the amount of light can be more uniform as compared with the case where the entire first surface 217 is inclined.

38, the first surface 217 of the reflective ring 207 may be convexly inclined. The angle of the first surface 217 of the reflective ring 207 may be 60 degrees or more and 90 degrees or less from the ground at all the contacts. If the angle of the first surface 217 of the reflecting ring 207 is smaller than 60 degrees, light leaking from the side surface of the light source 203 can leak sideways without being reflected by the lens 205.

Since the reflecting ring 207 according to the present invention is inclined to the convex surface 217 facing the light source 203, the dispersion of the light can be better than when the reflecting ring 207 is inclined at a constant angle.

39 and 40, the surface 219 of the reflective ring 207 that faces the reflective sheet 126 may be inclined. In detail, the angle of the second surface 219 of the reflective ring 207 may be 60 degrees or more and 90 degrees or less from the ground. If the angle of the second surface 219 of the reflecting ring 207 is smaller than 60 degrees, the light reflected by the lens 205 can be absorbed into the printed circuit board 122 without being reflected by the reflecting ring 207.

The light incident on the upper portion of the light source 203 may be bent in the conical groove 415. The bent light can be totally reflected in the inverted conical groove 423. The light totally reflected in the inverted conical groove 423 can be reflected back to the conical conical side surface portion 425. At least a portion of the reflected light may be incident on the second surface 219 of the reflective ring 207.

Light incident on the second surface 219 of the reflective ring 207 is reflected back to the printed circuit board 122 without being reflected back to the lens 205 when the second surface 219 of the reflective ring 207 is not tilted. Lt; / RTI >

However, when the second surface 219 of the reflective ring 207 is tilted, the light incident on the second surface 219 of the reflective ring 207 is reflected back to the lens 205, Lt; / RTI >

The reflecting ring 207 according to the present invention can reflect more light to the lens 205 because the second surface 219 of the reflecting ring 207 is inclined. Thus, the light efficiency of the backlight unit can be increased.

41, the second surface 219 of the reflective ring 207 may be convexly inclined. The angle of the second surface 219 of the reflective ring 207 may be at least 60 degrees and no more than 90 degrees from the ground at all contacts. If the angle of the second surface 219 of the reflective ring 207 is less than 60 degrees, the light incident on the second surface 219 of the reflective ring 207 is not reflected back to the lens 205, 122, respectively.

Since the reflecting ring 207 according to the present invention has the convexly inclined surface 219 facing the reflective sheet 126, the light can be more uniformly dispersed than when it is inclined at a constant angle.

Referring to FIG. 42, the reflective ring 207 may include a plurality of convex projections on the first surface 217. In other words, the reflective ring 207 may have the first surface 217 with at least one convex projection.

Since the reflecting ring 207 according to the present invention includes at least one convex projection on the first surface 217, the light incident on the side of the light source 203 can be dispersed irregularly in various directions. Therefore, the brightness of the backlight unit can be made uniform.

The foregoing detailed description should not be construed in all aspects as limiting and should be considered illustrative. The scope of the present invention should be determined by rational interpretation of the appended claims, and all changes within the scope of equivalents of the present invention are included in the scope of the present invention.

Claims (20)

Board;
At least one light assembly positioned on the substrate; And
And a reflective sheet having at least one through hole corresponding to the at least one optical assembly,
The optical assembly includes:
A light source,
A lens positioned above the light source,
A backlight unit disposed inside the through hole and spaced apart from the light source by an opening portion having a diameter smaller than the diameter of the lens and having a sidewall disposed to face the light source at the opening portion, .
The method according to claim 1,
Wherein the reflective ring comprises:
Further comprising an upper surface extending in the radial direction of the lens at the opening.
The method according to claim 1,
The sidewall,
And a slope inclined with respect to the light source.
The method according to claim 1,
The sidewall,
A first side wall on the side of the opening where the light source is located,
And a second side wall outside the reflection ring.
The method according to claim 1,
The sidewall,
And a vertical plane of at least another region and an inclined plane of at least a partial region.
The method of claim 3,
The inclined surface
Wherein the light emitting device is formed at an inclination angle of 60 degrees or more and 90 degrees or less.
The method according to claim 1,
The outer side wall of the reflection ring
And a backlight unit contacting the reflective sheet.
The method according to claim 1,
At least a portion of the reflective ring
And at least a part of the reflective sheet is superposed on the backlight unit.
The method according to claim 1,
Wherein the side wall and the light source have a constant spacing distance.
10. The method of claim 9,
The distance,
A backlight unit of 500 micrometers or more and 1 millimeter or less.
The method according to claim 1,
The opening
The backlight unit is in the shape of any one of a circle, a triangle, and a pentagon.
The method according to claim 1,
The ratio of the height of the sidewall to the height of the light source,
0.4 or more and 1.0 or less.
The method according to claim 1,
Wherein the at least one optical assembly comprises:
A backlight unit including a COB (Chip On Board) type light source.
The method according to claim 1,
The thickness of the reflective ring may be,
Wherein the thickness of the reflective sheet is different from that of the reflective sheet.
The method according to claim 1,
The diameter of the reflecting ring is preferably,
The backlight unit being smaller in diameter than the lens included in the optical assembly.
The method according to claim 1,
The reflectance of the sidewalls,
Wherein the reflectance of the backlight unit is larger than that of the substrate.
The method according to claim 1,
And at least a part of the upper surface of the side wall and the reflection ring,
A backlight unit in which at least one pattern is formed.
18. The method of claim 17,
Wherein the at least one pattern includes a plurality of regions in which at least one of a position, a shape, and a hue is different,
Wherein the plurality of regions are formed such that one region and the other region are repeatedly formed.
A backlight unit including at least one light source;
A display panel disposed on a front surface of the backlight unit; And
And a back cover positioned on a rear surface of the backlight unit,
The backlight unit includes:
A substrate;
At least one light assembly positioned on the substrate,
And a reflective sheet having at least one through hole corresponding to the at least one optical assembly,
The optical assembly includes:
A light source,
A lens positioned above the light source,
And a reflective ring disposed inside the through hole and spaced apart from the light source by an opening portion having a diameter smaller than the diameter of the lens and having a sidewall disposed to face the light source at the opening portion, .
20. The method of claim 19,
Wherein the reflective ring comprises:
And an upper surface extending in the radial direction of the lens at the opening.

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