KR200435173Y1 - Brightness enhancement structure of luminescent assembly with light source capable of emitting blue/ultraviolet light - Google Patents

Abstract

The present invention relates to a light emitting structure having an improved brightness of a light emitting assembly having a light source capable of emitting blue light / ultraviolet light, and more particularly to a structure capable of improving the brightness of a discharge lamp having a blue light / ultraviolet light emitting source. The light emitting structure with improved brightness of the light emitting assembly includes: a blue light / ultraviolet light emitting source having a side coated with a cover layer; A light screen having a first visible light layer and arranged outside the light source at a position opposite the coated side of the cover layer of the light source, wherein the first visible light layer is immediately visible or visible when irradiated with ultraviolet or blue light of the light source; While white light, which is a mixture of, is emitted, the cover layer of the light source is excited to block harmful ultraviolet rays and to generate other visible light, thereby improving the brightness of the light emitting assembly.

Light emitting assembly, light source, light emitting structure, light emitting device

Description

Brightness enhancement structure of luminescent assembly with light source capable of emitting blue / ultraviolet light}

1A and 1B are schematic views showing the brightness of two conventional fluorescent lamps.

2 is a cross-sectional view of a box-shaped light emitting assembly having a plurality of conventional fluorescent lamps arranged in the opening.

3 is a cross-sectional view of an arc-shaped light emitting assembly having a conventional fluorescent lamp arranged in a concave portion;

4 is a schematic view showing a light emitting assembly according to a first embodiment of the present invention;

FIG. 5 is a perspective view showing a cross section of a light-enhanced light emitting structure used in the light emitting assembly of the first embodiment of the present invention in which a cover layer is coated on the inner circumference of a light-emitting source;

FIG. 6 is a cross-sectional view of the light emitting structure of FIG. 5 with improved brightness. FIG.

6A is a cross-sectional view of the light-enhanced light emitting structure of FIG. 5 with an additional light reflecting layer having a plurality of holes formed on the cover layer.

7 is a cross-sectional view of the light-enhanced light emitting structure of FIG. 5 with an additional light reflecting layer interposed between the inner circumference of the light screen and the first visible light layer.

FIG. 8 is a cross-sectional view of the light emitting structure of the improved brightness of FIG. 5 in which a cross section of the light emitting source is formed in a semicircular shape. FIG.

FIG. 9 is a cross-sectional view of the improved light emission structure of FIG. 5 in which a cross section of the light emission source is formed in a triangle; FIG.

FIG. 10 is a cross-sectional view of the light enhanced light emitting structure of FIG. 5 in which a cross section of the light emitting source is formed in a quadrangle.

FIG. 11 is a cross-sectional view of another form of the light enhanced light emitting structure used in the light emitting assembly of the first embodiment of the present invention in which the cover layer is coated on the outer circumference of the light emitting source; FIG.

FIG. 11A is a cross-sectional view of the light-enhanced light emitting structure of FIG. 11 with an additional light reflecting layer interposed between the outer circumference of the light emitting source and the cover layer.

12 is a view illustrating an appearance of the light emitting assembly of FIG. 4.

13 is a view showing another appearance of the light emitting assembly of FIG.

14 is a view showing still another appearance of the light emitting assembly of FIG.

15 is a view showing still another appearance of the light emitting assembly of FIG.

16 is a view showing still another appearance of the light emitting assembly of FIG.

17 is a view showing a state in which the light emitting source may be formed in any shape and is accommodated in a box-shaped optical screen, and the cover layer is coated on the inner circumference of the light emitting source. Schematic diagram showing a light emission source with improved brightness of a light emitting assembly according to an example.

FIG. 18 is a schematic representation of another form of the brightness enhanced light emitter of FIG. 17 in which the cover layer is coated on the outer periphery of the light emitter;

19A-19D are cross-sectional views of four differently shaped optical screens used in the light emitting assembly of FIG.

FIG. 20 is a sectional view of yet another form of light emission source having improved brightness of FIG. 17; FIG.

FIG. 21 is a light emitting structure of which the brightness of the light emitting assembly according to the third embodiment of the present invention is formed, in which the optical screen is a solid semi-circular base and a cross section of the light emitting source is formed in a quadrangular shape. Section.

FIG. 22 is a cross-sectional view of another form of the brightness-enhanced light emitting structure of FIG. 21 in which the light emitting source has a semicircular cross section. FIG.

FIG. 23 is a cross-sectional view of another form of the light-emitting enhancement structure of FIG. 21 in which the cross section of the light emitting source is formed in a triangle; FIG.

FIG. 24 is a cross-sectional view of another form of the improved light emission structure of FIG. 21 in which the cross section of the light emission source is circular;

FIG. 25 is a cross-sectional view of the enhanced light emitting structure of FIG. 21 showing the light reflecting layer of FIG. 21 being replaced with a transparent cover which is partially coated with a fluorescent coating and whose other portion is covered by the reflecting layer;

FIG. 26 is a cross-sectional view of another form of the light-enhanced light emitting structure of FIG. 21 in which the solid solid base shaped optical screen is replaced with a hollow base.

27 is a perspective view of a light emission source of the light emission structure with improved brightness according to the fourth embodiment of the present invention.

FIG. 28 is a perspective view of another form of the light emission structure of FIG. 27 with improved brightness. FIG.

FIG. 29 is a perspective view of another form of the light emitting structure of FIG. 27 with improved brightness. FIG.

30 is a schematic view showing a light emission improved light emitting structure of the present invention used as a backlight module of a liquid crystal display device;

The present invention relates to a brightness improving structure of a light emitting assembly having a light source capable of emitting blue light / ultraviolet light, and more particularly, to a light emitting assembly having a light source capable of emitting blue light / ultraviolet light which can use a fluorescent lamp as a discharge lamp. It relates to a brightness enhancement structure of the.

In general, the brightness of a conventional light emitting device such as a fluorescent lamp depends on the luminous intensity of the light source used. Since most of the energy consumed is converted into usable light rather than heat, the fluorescent lamp can be used more efficiently than incandescent bulbs with the same brightness and also cooler. Such fluorescent lamps are used. The fluorescent lamp consists of a glass tube filled with an inert gas and mercury vapor, and the inner surface of the glass tube is coated with fluorescent paint made by modifying a mixture of fluorescent substances. When the lamp is turned on, electric power heats the cathode of the fluorescent lamp to emit electrons, and these electrons collide with an inert gas atom in the glass tube to form a plasma by a collision ionization process that ionizes the inert gas. As a result of this chain ionization process, the conductivity of the ionized gas rapidly increases, allowing a higher current to flow through the lamp, and then mercury ionizes in the same way to emit light in the ultraviolet region. This ultraviolet light is absorbed by the fluorescent coating to emit visible light by radiating again low frequency energy. The mixture of phosphors controls the color of the light and also prevents harmful ultraviolet radiation from escaping together with the glass of the glass tube. However, the aforementioned fluorescent lamps have the following disadvantages:

(1) The fluorescent coating is a fluorescent film having a constant thickness, the surface of the fluorescent film can be easily excited by ultraviolet light to emit visible light, the intensity is reduced when the ultraviolet light penetrates deep into the fluorescent film, The visible light generated deep in the fluorescent film is less than the visible light generated on the surface of the fluorescent coating, as a result, the fluorescent coating emits most of the light from the surface and a small amount of light from the inside light emitting device Can be considered as.

(2) The fluorescent coating is not a good translucent material, and the luminance of visible light generated at its surface is weakened when visible light passes through the fluorescent coating and exits the glass tube. That is, the brightness of the visible light is adversely affected by the fluorescent coating.

FIG. 1A shows a sealed glass tube having a fluorescent coating 2 coated therein as a conventional fluorescent lamp, and most of the visible light generated from the inner surface of the fluorescent coating 2 is a fluorescent coating. (2) Blocked by itself, the brightness inside the glass tube becomes substantially brighter than the outside of the glass tube. That is, the brightness of the fluorescent lamp 1 mainly depends on the visible light generated inside the fluorescent coating 2, so that the conventional fluorescent lamp has a weak brightness in most cases. Moreover, when the visible light generated on the inner surface of the fluorescent coating 2 passes through the filtering action of the fluorescent coating 2 and reaches the glass tube, the residual visible light is once again filtered by the glass tube and weakened further. Therefore, since most conventional fluorescent lamps are filtered by the fluorescent coating, as will be discussed later in the specification, their luminous efficacy is not satisfactory.

Furthermore, as shown in FIG. 1B, when the fluorescent coating 2 is coated on only half of the inner surface of the fluorescent lamp 1 'glass tube, and the other half of the glass tube is transparent, the fluorescent coating 2 Visible light generated on the surface of the N can be emitted directly from the fluorescent lamp (1 ') through the transparent half of the glass tube without filtering by the fluorescent coating (2), by filtering by the fluorescent coating (2) Unsatisfactory brightness problems can be avoided. However, ultraviolet light can also be emitted directly from the fluorescent lamp 1 'through the transparent half of the glass tube without filtering by the fluorescent coating 2, which is human eye and skin even though most of the ultraviolet light is filtered by the glass tube. Can damage. Therefore, the half coated fluorescent lamp 1 'is not recommended. Apart from the reason why this is not recommended, ultraviolet light emitted directly from the fluorescent lamp 1 'without hitting the fluorescent coating 2 is wasted because it is not used to excite usable visible light. Therefore, if the wasted ultraviolet rays can be recovered and used, the brightness of the half-coated fluorescent lamp 1 'can be greatly improved.

1A and 1B, if the visible light generated on the surface of the fluorescent coating 2 is quantified in brightness by 1.0 unit, the brightness measured outside the fluorescent lamp 1, that is, the fluorescent coating The total of visible light generated inside the part 2 and the residual visible light generated by the inner surface of the fluorescent coating part 2 and filtered by the fluorescent coating part 2 is about 0.9 units, and the fluorescent lamp 1 ' The brightness measured outside of the coated half is only 0.47 units due to the waste of ultraviolet light described above. Thus, the box-shaped light emitting assembly 3 having a plurality of fluorescent lamps 1 arranged in the opening as shown in FIG. 2 or the fluorescent lamps 1 arranged in the concave portion as shown in FIG. Like the arc-shaped light emitting assembly 4, most of the conventional light emitting assemblies using the fluorescent lamp 1 shown in FIG. 1A as a light source have a reflection sheet 5 therein to increase the brightness. Although configured to have, the conventional light emitting assemblies still have unsatisfactory brightness because the luminous efficacy of the light source employing the fluorescent lamp 1 is not satisfactory.

The main object of the present invention is to overcome the disadvantages of the conventional unsatisfactory brightness, and to provide a structure that can improve the brightness of the discharge lamp having a blue light / ultraviolet radiation source.

In order to achieve the above object, the present invention is a light emitting structure with improved brightness of a light emitting assembly having a light source capable of emitting blue light / ultraviolet light, a bar-shaped tube, a cover layer formed on the top of the circumference A blue light / ultraviolet light emitting source having; A first bar-shaped tube disposed to surround the bar-shaped light emitting source, the first bar being formed on a portion of an inner surface of the light screen at a position corresponding to a circumferential lower portion of the light emitting source not covered by the cover layer; And an optical screen having a visible light layer, wherein as soon as the first visible light layer is irradiated and excited by ultraviolet or blue light of the light source, visible light is emitted from the first visible light layer, and the cover layer of the light source blocks harmful ultraviolet light. The brightness of the light emitting assembly is enhanced by being excited at the same time and generating other visible light.

Other aspects and advantages of the present invention will become apparent from the following detailed description that sets forth examples of principles of the invention in conjunction with the accompanying drawings.

Example

Some preferred embodiments are provided as follows in order to provide a thorough understanding and appreciation of the complete functionality and structural features of the present invention.

4, 5, and 6, which show light emission structures with improved brightness of the light emitting assembly according to the first embodiment of the present invention, the light emission structures with improved brightness of the first embodiment may emit ultraviolet light or blue light. A light emitting source 10 formed on the top of the inner circumference with a bar-shaped tube and preferably having a cover layer 11 substantially as a light reflecting layer; And a substantially bar-shaped tube arranged to enclose the bar-shaped light emitter 10, at a position corresponding to a circumferential lower portion of the light emitter 10 not covered by the cover layer 11. It is formed on a part of its inner surface and is preferably composed of an optical screen 20 having a first visible light layer 21 which is a fluorescent coating or a phosphorescent coating.

When the light emitting source 10 is operated by electricity, it is driven to discharge blue light or ultraviolet light, and the blue light / ultraviolet light is radiated from the light emitting source 10 through a side not covered by the cover layer 11. The first visible light layer 21 disposed on the optical screen 20 is excited to emit visible light. Since the excited visible light is discharged from the optical screen 20 through the side which is not covered by the first visible light layer 21, the visible light is mainly excited from the surface of the first visible light layer 21, and thus As in the conventional structure, the brightness is improved because it is not filtered by the first visible light layer 21 before being discharged. Moreover, the inner circumferential upper portion of the light emitting source 10 at a position corresponding to the circumference of the optical screen 20 which is substantially covered by the cover layer 11, which is not covered by the first visible light layer 21. Since the cover layer 11 can block harmful ultraviolet rays and at the same time, it can reflect the blocked ultraviolet rays to illuminate the first visible light layer 21, and thus from the light emitting source 10 Nearly all of the emitted ultraviolet / blue light can be directed to illuminate the first visible light layer 21 that excites visible light, so that the brightness of the light emitting assembly of the first embodiment is greatly improved.

In addition, since the light emission source 10 having the cover layer 11 is disposed at a position corresponding to the first visible light layer 21 of the optical screen 20, the light emission protrudes onto the optical screen 20. It is important to have an area of the first visible light layer 21 that is certainly larger than the area of the circle 10 and a first visible light layer 21 that is constantly spaced apart from the cover layer 11 of the light emitting source 10. In this way, the blue light / ultraviolet light emitted from the light emitting source 10 can sufficiently light the first visible light layer 21 while preventing the excited visible light from being blocked by the cover layer 11. The brightness of the light emitting assembly is improved.

Furthermore, the cover layer 11, which is formed on the inner circumference of the light emitting source 10 and which is a substantially light reflecting layer, can be replaced by a fluorescent coating or a phosphorescent coating, whereby the blue light / ultraviolet rays are removed. It is directed to illuminate the visible light layer 21 so as to excite the visible light emitted therefrom as described above, and the blue / ultraviolet light which illuminates the cover layer 11 transmits other visible light through the cover layer 11. While being filtered by the cover layer 11 can be excited to be discharged from the light emitting source 10.

If the cover layer 11 is substantially a fluorescent coating or a phosphorescent coating, as shown in FIG. 6A, the light reflecting layer 16 having a plurality of holes 15 is formed by the fluorescent / absorption of the cover layer 11. It is preferable to arrange so as to overlap on the phosphorescent coating. The light reflecting layer 16 having the plurality of holes 15 is disposed so that the blue light / ultraviolet light is filtered by the cover layer 11 while passing through the cover layer 11 as described above. Most of the blue light / illuminating the cover layer 11 can be directed to illuminate the fluorescent / phosphorescent coating of the cover layer 11 through a plurality of holes 15 to excite it to be discharged from the emission source 10. Ultraviolet light is reflected and directed towards the first visible light layer 21 so that it can be used to excite more visible light, and visible light excited from the first visible light layer 21 is not filtered by the first visible light layer 21. Can be discharged from the light emitting assembly without causing the brightness to decrease.

Referring to FIG. 7, which shows a cross-sectional view of the light-emitting structure of FIG. 5 having an additional light reflecting layer interposed between an inner circumference of the optical screen and a first visible light layer, in FIG. 7, the first visible light layer ( 21 is coated on the light reflecting layer 22, which is disposed on the bottom of the inner circumference of the light screen 20. By interposing the light reflecting layer 22 between the inner circumference of the light screen 20 and the first visible light layer 21, visible light that is excited from the first visible light layer 21 and passes therethrough is transmitted to the light reflecting layer 22. Can be prevented from being emitted from the light screen 20 when reflected by it. In addition, a cap 90 capable of absorbing ultraviolet rays is disposed on the outer circumference of the optical screen 20 to absorb the emitted ultraviolet rays.

The above-described embodiments are merely illustrative and are not intended to limit the structure of the present invention. Those skilled in the art will appreciate that all parts mentioned in the above embodiments may be replaced and replaced by other parts having the same function. For example, the light emitting source 10 having a circular cross section may be a light emitting source 12 having a semicircular cross section shown in FIG. 8, or a light emitting source 13 having a triangular cross section shown in FIG. 9. Alternatively, it may be replaced by a light emitting source 14 having a rectangular cross section shown in FIG. 10, or other light emitting sources having a polygonal cross section. Similarly, the optical screen 20 having a circular cross section is exchanged by an optical screen having a semicircular cross section, or an optical screen having a triangular cross section, or an optical screen having a square cross section, or an optical screen having a polygonal cross section. Can be replaced. Such exchanges and substitutions can be easily made by those skilled in the art and are protected by the appended claims of the present invention. In addition, the above-described exchange and replacement does not affect or modify the structure of the above embodiments, and detailed descriptions of such exchange and replacement are omitted.

Referring to FIG. 11, which shows a cross-sectional view of another form of the light emitting structure of the improved brightness used in the light emitting assembly of the first embodiment of the present invention, wherein the cover layer is coated on the outer circumference of the light emitting source, FIGS. 6 and 11. The difference between the light emitting structures with improved brightness of is that the cover layer 11 is formed on top of the outer circumference, instead of being formed and used on the inner circumference of the light emitting source 10. In the light emission structure with improved brightness of FIG. 11, the cover layer 11 reflects the blue light / ultraviolet light reflected from the cover layer 11 toward the first visible light layer 21 formed on the optical screen 20. A substantially light reflective layer used to direct reflected blue light / ultraviolet light, whereby most of the blue light / ultraviolet light can be used to shine on the first visible light layer 21 to excite more visible light therefrom, the first visible light layer Since the visible light excited from 21 can be discharged from the light emitting assembly without being filtered, the brightness is greatly improved.

Furthermore, the cover layer 11 reflecting light can be exchanged with a light reflecting layer having a plurality of holes filled with a material selected from the group comprising phosphors and phosphors, whereby the light emitting source 10 A portion of the blue light / ultraviolet light may be reflected and directed to illuminate the first visible light layer 21, and the remaining blue light / ultraviolet light is excited by the visible light and filtered by the cover layer 11 while passing through the cover layer 11. After the light is discharged from the light emitting assembly it is possible to light the hole filled with the fluorescent / phosphor. In addition, the cover layer 11 may be a transparent cap 17 having an inner surface coated with a layer formed of a fluorescent coating or a phosphorescent coating, as shown in FIG. 11A, whereby the cover layer 11 ) Acts similarly to the first visible light layer 21, unlike the filtered visible light being filtered by the cover layer 11 itself before being discharged from the light emitting assembly. Similarly, a light reflecting layer having a plurality of holes filled with a material selected from the group consisting of phosphors and phosphors is interposed between the fluorescent / phosphorescent coating of the transparent cap 17 and the outer periphery of the light emitting source 10 or It can be directly coated and superimposed on the fluorescent / phosphorescent coating of the transparent cap 17, whereby the blue light / ultraviolet light is filtered by the cover layer 11 while transmitting visible light through the cover layer 11 Can be directed to illuminate the fluorescent / phosphorescent coating of the transparent cap 17 through a plurality of holes 15 filled with fluorescent / phosphorescent material to excite it to be discharged from the light emitting source 10 afterwards. Most of the blue / ultraviolet light that illuminates the cover layer 11 can be used to excite more visible light by being reflected and directed towards the first visible light layer 21, a detailed description of which is omitted. .

Referring to FIG. 12 showing the appearance of the light emitting assembly of FIG. 4, the light emitting assembly of FIG. 12 is simply a U-shaped bar-shaped tube of the light emitting assembly of FIG. 4. The function is the same. Likewise, the appearance of the light emitting assembly may be formed in the form of a circular tube, a flat spiral tube, a three-dimensional spiral tube, and a three-dimensional conical spiral tube, as shown in FIGS. 13, 14, 15, and 16. In addition, they may have other appearances that affect their structure and function.

According to the second embodiment of the present invention, the light emitting source may be formed in any shape and accommodated in a box-shaped optical screen, and the cover layer is coated on the inner circumference of the light emitting source. Referring to FIG. 17, which is a schematic view of a light emitting structure having improved brightness of a light emitting assembly, the light emitting structure having improved brightness according to the second embodiment is a bar-shaped tube capable of emitting blue light / ultraviolet light, and is disposed on the upper portion of the inner circumference. A light emission source 30 having a cover layer 31 formed; And an optical screen 40 having a first visible light layer 41 formed on an inner surface of a lower side and a side of the box in a box shape having an opening formed thereon. As in the first embodiment, the cover layer 31 is substantially a light reflecting layer, and the first visible light layer 41 is formed as a fluorescent coating or a phosphorescent coating, while an additional light reflecting layer is the fluorescent / phosphorescent coating. It may be arranged outside the coating to block the visible light excited to prevent the visible light from penetrating the first visible light layer 41 to be discharged to the outside. In FIG. 17, the light emitting source 30 is a zigzag tube located at the top opening of the box-shaped light screen 40. As shown in FIG. In addition, the cover layer 31 formed on the inner circumference of the light emission source 30 may be formed of a fluorescent coating or phosphorescent coating, if the cover layer 31 is formed of a fluorescent coating or phosphorescent coating It is preferable to arrange the light reflection layer having a plurality of holes so as to overlap the fluorescent / phosphorescent coating of the cover layer 31.

As in the first embodiment shown in FIG. 6, when the light emitting source 10 is operated by electricity, it is driven to discharge blue light or ultraviolet light, and the blue light / ultraviolet light is not covered by the cover layer 31. It is radiated from the light emitting source 10 through the non-side surface to excite the first visible light layer 41 to emit visible light. Since the excited visible light is discharged from the optical screen 40 through the side which is not covered by the first visible light layer 41, the visible light is mainly excited from the surface of the first visible light layer 41, and thus As in the conventional structure, the brightness is improved because it is not filtered by the first visible light layer 41 before being discharged. Furthermore, since the cover layer 31 is substantially a light reflecting layer, the cover layer 31 may reflect blue light / ultraviolet rays to illuminate the first visible light layer 41, and thus, the light emitting source. Most of the blue light / ultraviolet light emitted from the 30 can be directed to excite the visible light by illuminating the first visible light layer 41, thereby greatly improving the brightness of the light emitting assembly according to the second embodiment.

Referring to FIG. 18 schematically showing another form of the light enhanced light emitting structure of FIG. 17 in which the cover layer is coated on the outer circumference of the light emitting source, between the light enhanced light emitting structures of FIGS. 17 and 18. The difference is that the cover layer 31 is formed on top of the outer circumference, instead of being formed and used on the inner circumference of the light emission source 30. As in the first embodiment, the cover layer 31 is substantially coated with one of a light reflecting layer, a fluorescent coating or a phosphor coating having a plurality of holes filled with a light reflecting layer, a fluorescent material or a phosphor. A transparent cap having an inner surface, a transparent cap having an inner surface coated with a layer of a fluorescent coating / phosphorescent coating layer superimposed on a light reflecting layer having a plurality of holes, and a plurality of holes directly coated on the inner surface and filled with fluorescent or phosphors And a layer selected from the group consisting of a transparent cap having a light reflecting layer.

Further, as in the first embodiment, the cross section of the light emission source 30 arranged in the upper opening of the box-shaped light screen 40 is in a shape selected from the group consisting of circular, semicircular, triangular, square and polygonal. Can be formed. In addition, the outer shape of the light emitting assembly using the light emitting structure with improved brightness is formed in a shape selected from the group consisting of a bar-shaped tube, a U-shaped tube, a circular tube, and the like.

Moreover, the lower portion of the cross section of the optical screen is shaped in a shape selected from the group consisting of straight lines, V-shaped lines, saw-shaped lines, single arcs, a series of connected arcs, as shown in FIGS. 19A-19D. Is formed.

Preferably, at least one light emitting source 30 may be configured as a light emitting structure having improved brightness. Furthermore, in order to further improve the brightness of the light emitting assembly of the present invention, as shown in FIG. 20, the integrated transparent cap 45 is positioned at a predetermined position of the at least one light emitting source 30. The unitary transparent cap has at least one recess 46 formed below the cap 45 to accommodate at least one light emitting source 30, each recess 46 having a A cover layer 47 is arranged which is formed on the inner surface of the corresponding recess 46. As in the first embodiment, the cover layer 47 is substantially coated with one of a light reflecting layer, a fluorescent coating or a phosphor coating having a plurality of holes filled with a light reflecting layer, a fluorescent material or a phosphor. Transparent cap with inner surface, transparent cap with inner surface coated with layer of fluorescent coating / phosphorescent coating superimposed on light reflecting layer with multiple holes and multiple holes directly coated on inner surface and filled with fluorescent or phosphor It is a layer selected from the group consisting of a transparent cap having a light reflecting layer having a.

The light screen is a cross-sectional view of an improved light emission structure of the light emitting assembly according to the third embodiment of the present invention, wherein the light screen is a solid semi-circular base and the cross section of the light emission source is formed in a quadrangular shape. Referring to FIG. 21, the light emitting structure having the improved brightness of the third embodiment is a bar-shaped tube having a rectangular cross section, and may emit infrared or blue light, and a cover layer 51 formed on the inner circumference thereof. A light emission source having a; A solid type transparent base having a substantially semi-circular columnar shape, the light having an upper surface capable of fixing the light emitting source 50 thereon and a lower portion having a first visible light layer 61 formed thereon. And screen 60. Preferably the cover layer 51 is substantially a light reflecting layer.

As in the first embodiment, the cover layer 51 formed on the inner circumference of the light emission source 50 may be formed of a fluorescent coating or a phosphorescent coating, if the cover layer 51 is a fluorescent coating Alternatively, when formed with a phosphorescent coating, it is preferable to arrange the light reflection layer having a plurality of holes so as to overlap on the fluorescent / phosphorescent coating of the cover layer 51.

The above-described embodiments are merely illustrative and are not intended to limit the structure of the present invention. Those skilled in the art will appreciate that all parts mentioned in the above embodiments may be replaced and replaced by other parts having the same function. For example, the light emitting source 50 having a rectangular cross section may be a light emitting source 52 having a semicircular cross section shown in FIG. 22, or a light emitting source 53 having a triangular cross section shown in FIG. 23. Or other light emitting sources having a polygonal cross section. Such exchanges and substitutions can be easily made by those skilled in the art and are protected by the appended claims of the present invention. In addition, the above-described exchange and replacement does not affect or modify the structure of the above embodiments, and detailed descriptions of such exchange and replacement are omitted.

Moreover, the light emitter 50 having a rectangular cross section can be replaced with the light emitter 54 having a circular cross section shown in FIG. However, for the light emitting source 54 having such a circular cross section, it is arranged outside the light emitting source 54 and emits light of the circular cross section to prevent the ultraviolet rays from leaking out of the light reflecting layer 55. There is a need for a specially designed light reflecting layer 55 that can completely cover the circle 54, whereby all ultraviolet light emitted from the light emitting source 54 having the circular cross section is reflected by the light reflecting layer 55. As a result, the first visible light layer 61 is illuminated, so that the ultraviolet rays emitted from the light emission source 54 are not wasted and brightness is improved. As described in the first embodiment, the light reflection layer 55 may be formed to have a plurality of holes filled with a material selected from the group consisting of a fluorescent material or a phosphor. In addition, the light reflecting layer 55 may be exchanged and replaced by a transparent cap 56 that can completely cover the light emission source 54 having the circular cross section, as shown in FIG. Preferably, the transparent cap 56 is a transparent cap having an inner surface completely covered by the fluorescent / phosphor coating 561, or one portion is covered by the fluorescent / phosphor coating 561 and the other portion is It may be formed of a transparent cap having an inner surface covered by the light reflecting layer 562. As described in the first embodiment, the light reflecting layer having a plurality of holes filled with a material selected from the group consisting of a fluorescent material or a phosphor material includes a fluorescent / phosphorescent coating part of the transparent cap 56 and the light emitting source ( 54 may be interposed between the outer periphery or directly coated to overlap the fluorescent / phosphorescent coating of the transparent cap 56.

In another preferred aspect, the optical screen 60 formed as the solid transparent base of the third embodiment can be exchanged and replaced by the hollow base 62 shown in FIG. The hollow base 62 may be made of a completely transparent material, or may be a base formed only of a transparent material on an upper surface thereof. Basically, the first visible light layer 61 is coated on the inner circumference of the hollow base 62. However, if the hollow base 62 is completely transparent, the first visible light layer 61 may be coated on the outer circumference of the hollow base 62. Such exchanges and substitutions can be easily made by those skilled in the art and are protected by the appended claims of the present invention. In addition, the above-described exchange and replacement does not affect or modify the structure of the above embodiments, and detailed descriptions of such exchange and replacement are omitted.

27 and 28 showing perspective views of a light emission source of a light emission structure with improved brightness according to a fourth embodiment of the present invention, the light emission structure with improved brightness according to the fourth embodiment includes at least one light emission. Circle 70; At least one optical screen 80. A light reflecting layer 72 having a plurality of holes 71 filled with one material selected from the group consisting of phosphors and phosphors is located on top of each corresponding light emitting source 70 and each light reflecting layer 72 is attached on the transparent cover sheet 73. Preferably, if the plurality of holes 71 are not filled with the selected fluorescent / phosphorescent material, the transparent cover sheet 73 should be coated by a fluorescent coating or a phosphorescent coating, and thus the light The ultraviolet rays of the emission source 70 are prevented from being discharged from the light emitting assembly through the plurality of holes 71 and directly irradiated to the human body. In the fourth embodiment of the present invention, each having a cover sheet 73 and a light reflecting layer 72 on a columnar transparent light screen 80 having a first visible light layer 81 coated on its inner circumference. In addition to positioning the light emitting sources 70, a mask plate 82 formed of a transparent material is arranged on the side of each light emitting source 70. The blue / ultraviolet light of each light emitting source 70 is reflected by the light reflecting layer 72 to illuminate and excite the first visible light layer 81 of the corresponding light screen 80 to emit visible light. Since the excited visible light is discharged from the optical screen 80 through the side which is not covered by the first visible light layer 81, the visible light is mainly excited from the surface of the first visible light layer 81, thus The brightness is improved by being guided by the mask plate 82 to be discharged from the light emitting assembly without being filtered by the first visible light layer 81 before being discharged. Furthermore, blue light / ultraviolet light of each light emitting source 70 passing through the plurality of holes 71 of the light reflecting layer excites the fluorescent / phosphorescent coatings filled in the plurality of holes 71 or the transparent cover sheet ( 73) to excite the fluorescent / phosphorescent coating coated on, and in both cases, other visible light is excited to pass through the light emitter 70 and thereby be filtered and discharged from the light emitter 70. Since most excited visible light is irradiated directly from the light emitting assembly without being filtered, the brightness of the light emitting assembly is greatly improved.

Furthermore, it should be noted that the brightness of the visible light excited from the fluorescent / phosphorescent coating filled in the plurality of holes 71 of the light reflecting layer 72 may vary with respect to the distance between the light reflecting layer and the light emitting source 70. . That is, for the same light reflecting layer 72, the brightness of the visible light excited from the fluorescent / phosphorescent coating portion filled in the plurality of holes 71 of the light reflecting layer 72 is determined between the light reflecting layer and the light emitting source 70. It decreases as the distance increases, and increases as the distance between the light reflecting layer and the light emission source 70 decreases. Thus, the uniformity of brightness can be controlled by adjusting the size and density of the holes 71 arranged on the light reflecting layer 72.

Referring to FIG. 29, which shows another perspective view of the light emitting structure of FIG. 27 with improved brightness, in FIG. 29, the light emitting structure with improved brightness is shown in the box-shaped optical screen 40 of the second embodiment of FIG. 17. By arranging the light emission sources 70 of FIG. 27 in the same, the light emitting assembly of the second embodiment is provided.

Referring to FIG. 30 schematically showing an improved light emission structure of the present invention used as a light source of a lateral backlight module of a liquid crystal display (LCD), the light emission source 150 of FIG. ) Is completely reflected and directed to illuminate the first visible light layer 161 arranged on the light screen 160. The first visible light layer 161 is substantially a fluorescent coating or a phosphorescent coating, and the ultraviolet rays excite the first visible light layer 161 to emit the visible light to the right. The excited visible light is discharged directly without being filtered, thereby improving brightness. After the excited visible light passes through the ultraviolet absorbing cap 170, the visible light is guided by the light guide plate 180 arranged on the right side of the light emitting source 150 to illuminate the rear surface of the LCD. The light emitting structure with improved brightness of the design can be used as the light source of the side backlight module of the LCD.

Since the light emitting source of the present invention can emit blue light or ultraviolet light, the ultraviolet light absorbing cap for absorbing residual ultraviolet light is transmitted at a predetermined position corresponding to the projection direction of the excited visible light while allowing visible light to be discharged to be transmitted. It is important that damage by ultraviolet rays is thereby prevented. In addition, all the components used in the light-emitting structure of the present invention with improved brightness, i.e., need to transmit ultraviolet rays, include anhydrous silica glass, synthetic quartz glass or borosilicate glass. Likewise, it should be formed of a material that can transmit ultraviolet rays.

Preferred embodiments of the present invention are for the purpose of explanation, and variations of other embodiments as well as the described embodiments of the present invention are possible by those skilled in the art. Accordingly, the appended claims are intended to cover all embodiments without departing from the spirit and scope of the present invention.

Claims (77)

A light emitting structure having improved brightness of a light emitting assembly having a light source capable of emitting blue light / ultraviolet light, A bar-shaped tube, comprising: a blue light / ultraviolet light emission source having a cover layer formed on top of a circumference; Another bar-shaped tube disposed to surround the bar-shaped light emitting source, wherein the first visible light is formed on a portion of the inner surface of the optical screen at a position corresponding to the circumference of the light emitting source not covered by the cover layer. An optical screen having a layer, The area of the first visible light layer is larger than the area of the light emitting source protruding onto the optical screen, and the first visible light layer is capable of sufficiently shining blue light / ultraviolet light emitted from the light emitting source to the first visible light layer. The light emitting structure with improved brightness, characterized in that arranged to be spaced apart from the cover layer of the light emitting source in order to prevent the visible light excited therefrom to be blocked by the cover layer. The light reflecting layer of claim 1, wherein the cover layer is formed on an inner surface of the blue light / ultraviolet emission source, and the first visible light layer has an inner surface coated with at least one of a fluorescent coating, a phosphorescent coating, and the coatings. Light enhanced light emitting structure, characterized in that the layer selected from the group consisting of. 3. The light emitting structure of claim 2, wherein the cover layer is a light reflecting layer. 3. The light emitting structure of claim 2, wherein the cover layer is a layer selected from the group consisting of a fluorescent coating and a phosphorescent coating. 5. The light emitting structure of claim 4, wherein the cover layer further comprises a light reflecting layer having a plurality of holes formed thereon and overlapping the fluorescent / phosphorescent coating of the cover layer. . The light reflecting layer of claim 1, wherein the cover layer is formed on an upper surface of a blue light / ultraviolet emission source, and the first visible light layer has an inner surface coated with at least one of a fluorescent coating, a phosphorescent coating, and the coatings. Light enhanced light emitting structure, characterized in that the layer selected from the group consisting of. 7. The light emitting structure of claim 6, wherein the cover layer is a light reflecting layer. 8. The light emitting structure of claim 7, wherein the light reflecting layer has a plurality of holes filled with one material selected from the group consisting of phosphor and phosphor. 7. The transparent layer of claim 6, wherein the cover layer has an inner surface coated with a layer selected from a fluorescent coating and a phosphorescent coating, and covers the blue light / ultraviolet light emission source and faces the inner surface toward the blue light / ultraviolet light emission source. Brightness-enhanced light emitting structure, characterized in that the cap. 10. The light emitting structure of claim 9, wherein the cover layer further includes a light reflecting layer having a plurality of holes formed thereon and overlapping the fluorescent / phosphorescent coating of the cover layer. . The method of claim 6, wherein the cover layer is a transparent cap having an inner surface coated with a light reflecting layer having a plurality of holes filled with a single material selected from the group consisting of a fluorescent material and a phosphor material Light emitting structure. 12. The light emitting assembly according to claim 11, wherein the appearance of the light emitting assembly using the improved light emission structure is a group consisting of a bar-shaped tube, a U-shaped tube, a circular tube, a flat spiral tube, a three-dimensional spiral tube, and a three-dimensional conical spiral tube. The light emission structure with improved brightness, characterized in that formed in the shape selected from. 13. The light emission structure of claim 12, wherein the cross section of the blue light / ultraviolet emission source is a shape selected from the group consisting of circular, semicircular, triangular, square and polygonal shapes. 14. The light emitting structure of claim 13, wherein the cross section of the optical screen is a shape selected from the group consisting of circular, semicircular, triangular, square, and polygonal shapes. 15. The light emitting structure of claim 14, wherein a cap capable of absorbing ultraviolet rays is arranged on the outer circumference of the light screen. 16. The light emission structure of claim 15, wherein the blue light / ultraviolet emission source is made of a quartz glass substrate. A light emitting structure having improved brightness of a light emitting assembly having a light source capable of emitting blue light / ultraviolet light, A bar-shaped tube, comprising: at least one blue light / ultraviolet light emission source having a cover layer formed on top of a circumferential surface; An optical screen having a first visible light layer formed on an inner surface of a lower side and a lower side of the box in a box shape having an opening formed at an upper side thereof, the optical screen capable of placing at least one blue light / ultraviolet emission source thereon; An area of the first visible light layer is larger than an entire area of at least one light emitting source protruding onto the optical screen, and the first visible light layer is configured to display blue light / ultraviolet light emitted from the at least one light emitting source. Disposed so as to be spaced apart from the cover layer of the at least one light emitting source so as to be sufficiently visible to the layer and to prevent visible light excited therefrom from being blocked by the cover layer of the at least one light emitting source. Characterized by improved light emission structure. 18. The light reflection layer of claim 17, wherein the cover layer is formed on an inner surface of the blue light / ultraviolet emission source, and the first visible light layer has an inner surface coated with at least one of a fluorescent coating, a phosphorescent coating, and the coatings. Light enhanced light emitting structure, characterized in that the layer selected from the group consisting of. 19. The light emitting structure of claim 18, wherein each cover layer is a light reflecting layer. 19. The light emitting structure of claim 18, wherein each cover layer is a layer selected from the group comprising a fluorescent coating and a phosphorescent coating. 21. The light with enhanced brightness of claim 20, wherein each cover layer further comprises a light reflecting layer having a plurality of holes formed thereon and formed to overlap on the fluorescent / phosphorescent coating of the cover layer. Emission structure. 18. The method of claim 17, wherein each cover layer is formed on top of an outer surface of the blue light / ultraviolet emission source, and the first visible light layer has a fluorescent coating, a phosphorescent coating, and an inner surface coated with at least one of the coatings. And wherein the layer is selected from the group consisting of light reflecting layers. 23. The light emitting structure of claim 22, wherein each cover layer is a light reflecting layer. 24. The light emitting structure of claim 23, wherein the light reflecting layer has a plurality of holes filled with one material selected from the group consisting of phosphors and phosphors. The transparent layer of claim 22, wherein the cover layer has an inner surface coated with a layer selected from a fluorescent coating and a phosphorescent coating, and covers the blue light / ultraviolet emission source while facing the inner surface toward the blue light / ultraviolet emission source. Brightness-enhanced light emitting structure, characterized in that the cap. 27. The light emitting structure of claim 25, wherein the cover layer further comprises a light reflecting layer having a plurality of holes formed thereon and overlapping the fluorescent / phosphorescent coating of the cover layer. . 23. The method of claim 22, wherein the cover layer is a transparent cap having an inner surface coated with a light reflecting layer having a plurality of holes filled with one material selected from the group consisting of a fluorescent material and a phosphor material Light emitting structure. 28. The device of any one of claims 17-27, wherein the lower portion of the cross section of the optical screen is selected from the group consisting of straight lines, V-shaped lines, saw blade lines, single arcs, a series of connected arcs. Brightness-enhanced light emitting structure, characterized in that formed in the shape. 29. The light emitting structure of claim 28, wherein the cross section of the blue / ultraviolet light emitting source is a shape selected from the group consisting of circular, semicircular, triangular, square and polygonal shapes. 30. The light having improved brightness according to claim 29, wherein the external appearance of the blue light / ultraviolet emission source is formed in a shape selected from the group consisting of a bar-shaped tube, a U-shaped tube, a circular tube, and a saw blade tube. Emission structure. 31. The light emitting structure of claim 30, wherein a cap capable of absorbing ultraviolet rays is arranged on the outer circumference of the light screen. 32. The light emitting structure of claim 31, wherein the blue light / ultraviolet light emitting source is made of a quartz glass substrate. A light emitting structure having improved brightness of a light emitting assembly having a light source capable of emitting blue light / ultraviolet light, At least one blue light / ultraviolet emission source formed of a bar-shaped tube; Transparent cap; A box having an opening formed therein, the light screen having a first visible light layer formed on the inner surfaces of the bottom and sides of the box, the light screen being capable of placing at least one blue / ultraviolet emission source thereon; The transparent cap further comprises at least one recess formed under the cap to receive at least one blue light / ultraviolet emission source, the at least one recess formed on an inner surface of the corresponding recess. Each has a An area of the first visible light layer is larger than an entire area of at least one light emitting source protruding onto the optical screen, and the first visible light layer is configured to display blue light / ultraviolet light emitted from the at least one light emitting source. Disposed so as to be spaced apart from the cover layer of the at least one light emitting source so as to be sufficiently visible to the layer and to prevent visible light excited therefrom from being blocked by the cover layer of the at least one light emitting source. Characterized by improved light emission structure. 34. The light emitting structure of claim 33, wherein each cover layer is a light reflecting layer. 35. The light emitting structure of claim 34, wherein the light reflecting layer has a plurality of holes filled with one material selected from the group consisting of phosphors and phosphors. 34. The light emitting structure of claim 33, wherein each cover layer is a layer selected from the group consisting of a fluorescent coating and a phosphorescent coating. 37. The light having enhanced brightness of claim 36, wherein each cover layer further comprises a light reflecting layer having a plurality of holes formed thereon and formed to overlap on the fluorescent / phosphorescent coating of the cover layer. Emission structure. 34. The light emitting structure of claim 33, wherein the cover layer is a light reflecting layer having a plurality of holes filled with one material selected from the group consisting of phosphors and phosphors. 39. The method of any one of claims 33 to 38, wherein the first visible light layer is a layer selected from the group consisting of a fluorescent coating, a phosphorescent coating and a light reflecting layer having an inner surface coated with at least one of the coatings. Light emission structure with improved brightness. 40. The method of claim 39, wherein the lower portion of the cross section of the optical screen is formed in a shape selected from the group consisting of straight lines, V-shaped lines, saw blade lines, single arcs, and series of connected arcs. Light emission structure with improved brightness. 41. The light emitting structure of claim 40, wherein the cross section of the blue / ultraviolet emission source is a shape selected from the group consisting of circular, semicircular, triangular, square and polygonal shapes. 42. The brightness-enhanced light emission according to claim 41, wherein the external appearance of the blue light / ultraviolet emission source is formed in a shape selected from the group consisting of a bar-shaped tube, a U-shaped tube, a circular tube, and a saw blade tube. rescue. 43. The light emitting structure of claim 42, wherein a cap capable of absorbing ultraviolet rays is arranged on the outer circumference of the light screen. 44. The light emitting structure of claim 43, wherein the blue / ultraviolet light emitting source is made of a quartz glass substrate. A light emitting structure having improved brightness of a light emitting assembly having a light source capable of emitting blue light / ultraviolet light, A light emitting source having a cover layer formed on an upper portion of the circumference as a bar-shaped tube capable of emitting ultraviolet rays; A substantially solid transparent base, comprising: an optical screen having an upper surface capable of fixing the light emitting source thereon and a lower portion having a first visible light layer formed thereon; The area of the first visible light layer is larger than the area of the light emitting source protruding onto the optical screen, and the first visible light layer is capable of sufficiently shining blue light / ultraviolet light emitted from the light emitting source to the first visible light layer. The light emitting structure with improved brightness, characterized in that disposed to be spaced apart from the cover layer of the light emitting source to prevent visible light excited therefrom is blocked by the cover layer of the light emitting source. 46. The light reflecting layer of claim 45, wherein the cover layer is formed on an inner surface of the blue light / ultraviolet emission source, and the first visible light layer has an inner surface coated with at least one of a fluorescent coating, a phosphorescent coating, and the coatings. Light enhanced light emitting structure, characterized in that the layer selected from the group consisting of. 47. The light emitting structure of claim 46, wherein the cover layer is a light reflecting layer. 47. The light emitting structure of claim 46, wherein the cover layer is a layer selected from the group consisting of a fluorescent coating and a phosphorescent coating. 49. The light emitting structure of claim 48, wherein the cover layer further comprises a light reflecting layer having a plurality of holes formed thereon and overlapping the fluorescent / phosphorescent coating of the cover layer. . 46. The light reflecting layer of claim 45, wherein the cover layer is formed on an upper surface of the blue light / ultraviolet emission source, and the first visible light layer has an inner surface coated with at least one of a fluorescent coating, a phosphorescent coating, and the coatings. Light enhanced light emitting structure, characterized in that the layer selected from the group consisting of. 51. The light emitting structure of claim 50, wherein the cover layer is a light reflecting layer. 51. The transparent material of claim 50, wherein the cover layer has an inner surface coated with a layer selected from a fluorescent coating and a phosphorescent coating, the cover layer covering the blue light / ultraviolet emission source and facing the inner surface toward the blue light / ultraviolet emission source. Brightness-enhanced light emitting structure, characterized in that the cap. 53. The light emitting structure of claim 52, wherein the cover layer further comprises a light reflecting layer having a plurality of holes formed thereon and overlapping the fluorescent / phosphorescent coating of the cover layer. . 55. The method of any one of claims 45 to 53, wherein the appearance of the solid transparent base is formed in a shape selected from the group consisting of semicircular pillars, triangular pillars, square pillars and polygonal pillars. Light emitting structure. 55. The light emitting structure of claim 54, wherein the cross section of the light emitting source is a shape selected from the group consisting of circular, semicircular, triangular, square and polygonal shapes. 56. The light emission structure of claim 55, wherein the light emission source and the solid transparent base are made of a quartz glass substrate. 59. The light emitting structure of claim 56, wherein a cap capable of absorbing ultraviolet rays is arranged on the outer circumference of the light emitting source. A light emitting structure having improved brightness of a light emitting assembly having a light source capable of emitting blue light / ultraviolet light, A light emitting source having a cover layer formed on an upper portion of the circumference as a bar-shaped tube capable of emitting ultraviolet rays; An optical screen formed of a substantially hollow base and having an upper surface capable of fixing the light emitting source thereon and a lower portion having a first visible light layer formed thereon; The area of the first visible light layer is larger than the area of the light emitting source protruding onto the optical screen, and the first visible light layer allows the ultraviolet light emitted from the light emitting source to sufficiently shine into the first visible light layer. And a light emitting structure with enhanced brightness, characterized in that it is arranged spaced apart from the cover layer of the light emitting source to prevent the visible visible light from being blocked by the cover layer of the light emitting source. 60. The light reflecting layer of claim 58, wherein the cover layer is formed on an inner surface of the blue light / ultraviolet emission source, and the first visible light layer has an inner surface coated with at least one of a fluorescent coating, a phosphorescent coating, and the coatings. Light enhanced light emitting structure, characterized in that the layer selected from the group consisting of. 60. The light emitting structure of claim 59, wherein the cover layer is a light reflecting layer. 60. The light emitting structure of claim 59, wherein the cover layer is a layer selected from the group consisting of a fluorescent coating and a phosphorescent coating. 62. The light emitting structure of claim 61, wherein the cover layer further comprises a light reflecting layer having a plurality of holes formed thereon and overlapping the fluorescent / phosphorescent coating of the cover layer. . 60. The light reflecting layer of claim 58, wherein the cover layer is formed on an upper surface of the blue light / ultraviolet emission source, and the first visible light layer has a fluorescent coating, a phosphorescent coating, and an inner surface coated with at least one of the coatings. Light enhanced light emitting structure, characterized in that the layer selected from the group consisting of. 64. The light emitting structure of claim 63, wherein the cover layer is a light reflecting layer. 64. The transparent layer of claim 63, wherein the cover layer has an inner surface coated with a layer selected from a fluorescent coating and a phosphorescent coating and covers the blue light / ultraviolet emission source while facing the inner surface toward the blue light / ultraviolet emission source. Brightness-enhanced light emitting structure, characterized in that the cap. 59. The light emitting structure of claim 58, wherein the cover layer further comprises a light reflecting layer having a plurality of holes formed thereon and overlapping the fluorescent / phosphorescent coating of the cover layer. . 67. The light with improved brightness according to any one of claims 58 to 66, wherein the outer appearance of the hollow base is formed in a shape selected from the group consisting of semicircular pillars, triangular pillars, square pillars and polygonal pillars. Emission structure. 68. The light emitting structure of claim 67, wherein the hollow base is formed of a transparent substrate. 68. The light emission structure of claim 67, wherein the upper surface of the hollow base is formed of a transparent substrate. 68. The light emitting structure of claim 67, wherein the cross section of the light emitting source is a shape selected from the group consisting of circular, semicircular, triangular, square and polygonal shapes. 70. The light emission structure of claim 70, wherein the light emission source and the hollow base are made of a quartz glass substrate. 72. The light emitting structure of claim 71, wherein a cap capable of absorbing ultraviolet rays is arranged on the outer circumference of the light emitting source. A light emitting structure having improved brightness of a light emitting assembly having a light source capable of emitting blue light / ultraviolet light, A light emitting source selected from the group consisting of ultraviolet light and blue light having a cover layer formed on an upper portion of the circumference as a bar-shaped tube capable of emitting ultraviolet light; At least one optical screen formed of a plurality of interconnected concave column bases and having an open area capable of fixing the corresponding light emitting source thereon and an arc wall for forming a first visible light layer thereon; Include, The area of the first visible light layer is larger than the area of the light emitting source protruding onto the optical screen, and the first visible light layer allows the ultraviolet light emitted from the light emitting source to sufficiently shine into the first visible light layer. And a light emitting structure with enhanced brightness, characterized in that it is arranged spaced apart from the cover layer of the light emitting source to prevent the visible visible light from being blocked by the cover layer of the light emitting source. 74. The light emitting structure of claim 73, wherein the cover layer is a light reflecting layer having a plurality of holes filled with one material selected from the group consisting of phosphors and phosphors. 74. The method of claim 73, wherein the cover layer comprises: a transparent cover sheet coated with a layer selected from the group consisting of fluorescent coatings to cover at least one light emitting source; And a light reflection layer having a plurality of holes formed thereon and arranged below the transparent cover sheet. 76. The light emitting structure of any of claims 73 to 75, wherein a mask formed of a transparent material is arranged on the side of the at least one light emitting source. 77. The brightness-enhanced light emitting structure of claim 76, wherein a cap capable of absorbing ultraviolet rays is arranged on an outer circumference of the at least one light emitting source.

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