KR101336939B1 - Multi-sheet for back light unit and method thereof - Google Patents

Abstract

The present invention relates to a composite sheet for a backlight unit using a non-printing light guide plate of a liquid crystal display device and a manufacturing method thereof.
In the present invention, the first base layer made of a first PET film for positioning on a non-printing light guide plate, the first functional layer of the lenticular pattern formed on the upper surface of the first base layer, the second base layer made of a second PET film and And a first adhesive layer for adhering the acid portion of the lenticular pattern of the first functional layer and the lower surface of the second base layer, and a prism pattern formed on the upper surface of the second base layer in a direction perpendicular to the first functional layer. A second base layer made of a second functional layer, a third PET film, a second adhesive layer for bonding the acid portion of the prism pattern of the second functional layer and the bottom surface of the third base layer, and an upper surface of the third base layer A composite sheet for a backlight unit including a third functional layer having a microlens pattern formed thereon and a method of manufacturing the same are provided.

Description

Composite sheet for backlight unit and manufacturing method thereof

The present invention relates to a three-layer composite sheet for a backlight unit (BLU) for use in a liquid crystal display (LCD) and a method of manufacturing the same. More specifically, a three-layer composite sheet for a backlight unit of a liquid crystal display device used as a display unit such as an LCD TV, and a method of manufacturing the same, which is used for an unprinted light guide plate in an edge lighting backlight unit of the liquid crystal display device. It relates to a three-layer composite optical sheet and a method of manufacturing the same.

As a light guide plate used for an edge lighting backlight unit (BLU) of a liquid crystal display device, a prism light guide plate using only refraction of light and an unprinted light guide plate using scattering and condensing of light are generally used. 1 is a schematic configuration diagram of a backlight unit using the prism light guide plate. As shown in FIG. 1, a prism light guide plate 11 having a prism 10 formed on a bottom surface thereof, and an inverted prism sheet 13 having a prism 12 formed on a bottom surface of an upper surface of the prism light guide plate 11 are provided. It is a combined configuration. As shown in FIG. 1, the structure of one optical sheet on a prism light guide plate using a prism light guide plate is reduced rather than enlarged due to an extremely narrow viewing angle and difficulty in manufacturing the prism light guide plate. 2 is a schematic diagram of a backlight unit using the non-printing light guide plate. As shown in FIG. 2, the non-printing light guide plate 20, the diffusion sheet 21 coupled to the top surface of the non-printing light guide plate 20, and the top surface of the diffusion sheet 21 and a prism shape on the top surface thereof. The prism sheet 22 formed in the vertical direction, the prism sheet 23 coupled to the upper surface of the prism sheet 22 and having a prism shape formed on the upper surface in the horizontal direction, and the prism sheet 23 It is a configuration including a protective sheet 24 is coupled to the upper surface. In addition, a configuration in which the protective sheet 24 is omitted in a backlight unit using the non-printing light guide plate is also used. In the case of the non-prism light guide plate, which is not a prism light guide plate, light scattering and focusing are used, so that the diffusion sheet 21, the prism sheet (vertical) 22, and the prism sheet (horizontal) (as shown in FIG. 2) ( 23) or an optical sheet of three to four combinations of a diffusion sheet 21 / prism sheet (vertical) 22 / prism sheet (horizontal) 23 / protective sheet 24 is used. The prism sheet (horizontal) 23 / prism sheet (vertical) 22 is also used in this order.

 FIG. 3 is a configuration diagram for explaining a light propagation direction of a backlight unit using two upper and lower prism sheets. FIG. As shown in FIG. 3, the diffusion sheet 31 also serves to raise the light lying sideways from the light guide plate 30 to the vertical direction in addition to the function of covering the pattern of the light guide plate 30 to scatter light. The prism sheet 32 serves to condense the light raised in the vertical direction to some extent through the diffusion sheet 31 toward the vertical direction. In the backlight unit for notebook PC, the vertical prism sheet (bottom) 32 and the horizontal prism sheet (top) 33 are condensed in a completely vertical direction as shown in FIG. 3, but in the backlight unit for LCD-TV, the prism sheet is When two sheets are used, the luminance increases but the left and right viewing angles are narrowed. Therefore, one horizontal prism sheet is used. The prism sheet is exposed to the prism-shaped surface of the pillars, which is easy to scratch during handling or assembly. A prism sheet is also mounted on the prism sheet to solve this problem or to improve the viewing angle. In addition, as a composite sheet for a backlight unit, as shown in FIG. 4, the example of the two-layer composite sheet which laminated | stacked the lens sheet 41 on the prism sheet 40 is shown.

However, as shown in the performance comparison table of FIG. 9, the luminance is too small to replace the diffusion sheet / prism sheet (vertical) / prism sheet (horizontal) / protective sheet, and thus, it is a two-layered composite sheet that can replace only two lens sheets. . The reason why the existing two-layer composite sheet is low in brightness is that the prism sheet below raises the light lying sideways like the diffusion sheet, but the lens sheet of the above has a lower light collection ability than the prism sheet. In order to increase the brightness while using the two-layered composite sheet, a diffusion sheet should be used at the bottom and a lens sheet at the top. The prism sheet and the two lens sheets make the best use of the light condensing function, but all three should be used including the two-layer composite sheet. did.

As described above, in the case of using a non-printing light guide plate in a liquid crystal display device, particularly in a liquid crystal display device for television, there are problems in that the thickness is increased, the assembly productivity is lowered, and the cost of the backlight unit is increased because several optical sheets are used.

Therefore, there is a need for an invention regarding a composite optical sheet and a method of manufacturing the same, which are thin and can increase assembly productivity while using a non-printing light guide plate in a liquid crystal display for a television.

The present invention is to solve the problems of the prior art, an object of the present invention in the optical sheet for the backlight unit of the liquid crystal display for television, while using a non-printing light guide plate is thin, two-layer or to increase assembly productivity or It is to provide a three-layered composite sheet and a method of manufacturing the same.

As a technical solution for achieving the object of the present invention, a first aspect of the present invention, in the composite sheet for a non-printing light guide plate for a backlight unit of a liquid crystal display for television, the first aspect 1 a first base layer made of a polyethylene terephthalate (PET) (hereinafter referred to as 'PET') film, a first functional layer of a lenticular pattern formed on an upper surface of the first base layer, and a second PET film A base layer, an adhesive layer for adhering an acid portion of the lenticular pattern of the first functional layer and a lower surface of the second base layer, and a prism pattern formed on the upper surface of the second base layer in a direction perpendicular to the first functional layer A two layer composite sheet is provided comprising a second functional layer.

In addition, in a second aspect of the present invention, the first base layer made of a first PET film, the first functional layer of the lenticular pattern formed on the upper surface of the first base layer, the second base layer made of a second PET film, A first adhesive layer for adhering an acid portion of the lenticular pattern of the first functional layer and a lower surface of the second base layer, and a prism pattern formed on the upper surface of the second base layer in a direction perpendicular to the first functional layer A second functional layer, a third base layer made of a third PET film, a second adhesive layer for bonding the acid portion of the prism pattern of the second functional layer and the bottom surface of the third base layer, and an upper surface of the third base layer A three-layered composite sheet including a third functional layer formed by distributing microlens patterns is provided.

In addition, as a third aspect of the present invention, forming a lenticular pattern with a UV resin on the first PET film and curing with UV to make a lower layer lenticular sheet; Forming an adhesive layer by applying a thin UV resin on the lower surface of the second PET film; Making a flat lenticular sheet by curing the UV portion of the lenticular pattern of the lower layer lenticular sheet of the first PET film with the adhesive layer of the second PET film while being in close contact with each other; A method of manufacturing a two-layered composite sheet is provided that includes forming a prism pattern with a UV resin in a direction perpendicular to the lenticular pattern on the first PET film on the flat plate lenticular sheet and curing the sheet with UV. .

In addition, as a fourth aspect of the present invention, forming a lenticular pattern with a UV resin on the first PET film and curing with UV to make a lower layer lenticular sheet; Forming a first adhesive layer by applying a thin UV resin on the lower surface of the second PET film; Making a flat lenticular sheet by curing the UV portion of the lenticular pattern of the lower layer lenticular sheet of the first PET film and the first adhesive layer of the second PET film while being in close contact with each other; Forming a prism pattern on the flat plate lenticular sheet with a UV resin in a direction perpendicular to the lenticular pattern on the first PET film and curing with UV to form a prism sheet; Forming a second adhesive layer by applying a thin UV resin on the lower surface of the third PET film; Making a flat prism sheet / lenticular sheet by bringing the acid portion of the first prism sheet of the flat plate lenticular sheet and the second adhesive layer of the third PET film into close contact with each other and curing with UV; Provided is a three-layer composite sheet manufacturing method including forming a microlens pattern with UV resin on the flat prism sheet / lenticular sheet and curing with UV to make a lens sheet.

According to the present invention, in the optical sheet for backlight unit of a liquid crystal display device for television, a two-layer or three-layer composite sheet can be manufactured while using a non-printing light guide plate and having a small thickness and increasing assembly productivity.

1 is a schematic configuration diagram of a backlight unit using a conventional prism light guide plate.
2 is a schematic configuration diagram of a backlight unit using a conventional non-printing light guide plate.
3 is an explanatory diagram of a traveling direction of light showing the principle of a backlight unit.
4 is a schematic configuration diagram of a two-layer composite sheet used in a conventional backlight unit.
5 is a schematic configuration diagram of an embodiment of a two-layer composite sheet for a backlight unit of the present invention.
6 is a schematic diagram of an embodiment of a three-layer composite sheet for a backlight unit of the present invention.
7 is a flowchart illustrating an embodiment of a method for manufacturing a two-layer composite sheet for a backlight unit of the present invention.
8 is a flowchart illustrating an embodiment of a method for manufacturing a three-layer composite sheet for a backlight unit of the present invention.
9 is a performance comparison table of various optical sheets including the composite sheet of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the structure of the invention of an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

5 is a schematic configuration diagram of an embodiment of a two-layer composite sheet for a backlight unit of the present invention. As shown in FIG. 5, the composite sheet for backlight unit of the present invention is located directly above the non-printing light guide plate 100 in the composite sheet for backlight unit using the non-printing light guide plate 100 of the liquid crystal display for a television. A first base layer 110 made of a first polyethylene terephthalate (PET :) film (hereinafter referred to as 'PET') film and a first functional layer of a lenticular pattern formed on an upper surface of the first base layer 110 ( 120, an adhesive layer 130 for adhering the second base layer 140 made of the second PET film, the acid portion of the lenticular pattern of the first functional layer 120, and the bottom surface of the second base layer 140. ) And a second functional layer 150 having a prism pattern formed on the upper surface of the second base layer 140 in a direction perpendicular to the first functional layer 120.

As described above, after the UV resin is coated on the thin first PET film to form a lenticular pattern, a lenticular sheet is manufactured by using UV curing means, and UV is applied to the bottom surface of the second PET. After applying a thin resin to form an adhesive layer, the acid portion of the lenticular sheet of the first PET film and the adhesive layer of the second PET film are in close contact with each other and UV-cured to prepare a flat lenticular sheet. A UV resin is applied to the upper surface of the flat lenticular sheet to form a prism pattern in a direction perpendicular to the lenticular pattern, and then UV cured to form a prism sheet. In this way, the adhesive layer 130 bonds the first base layer 110, the first functional layer 120, which is a lenticular sheet, and the lower surface of the second base layer 140, and the acid portion of the lenticular sheet of the first functional layer 120. ) And the second functional layer 150 including the prism sheet on the second base layer 140 is completed. It is impossible to laminate the prism sheet on the diffusion sheet and the conventional diffusion sheet positioned on the non-printing light guide plate 100. Therefore, in the present invention instead of the diffusion sheet, the lenticular sheet is used, and the prism sheet is laminated on the lenticular sheet in the vertical direction. At this time, the lenticular sheet of the prism sheet Alain, like the diffusion sheet, raises the light lying on the side of the light guide plate in the vertical direction to some extent and widens the viewing angle. The prism sheet on the lenticular sheet serves to condense light toward a more vertical direction.

6 is a schematic diagram of an embodiment of a three-layer composite sheet for a backlight unit of the present invention. Although some configurations are the same as those of the two-layered composite sheet of FIG. 5, the same reference numerals will be described with reference to FIG. 5 to distinguish the embodiments of the present invention. As shown in FIG. 6, the composite sheet for backlight unit of the present invention is located directly above the non-printing light guide plate 200 in the composite sheet for backlight unit using the non-printing light guide plate 200 of the liquid crystal display for a television. A first base layer 210 made of a first polyethylene terephthalate (PET :) (hereinafter referred to as a 'PET') film and a first functional layer of a lenticular pattern formed on an upper surface of the first base layer 210 220, a second base layer 240 made of a second PET film, and a first adhesive layer for bonding an acid portion of the lenticular pattern of the first functional layer 220 and a bottom surface of the second base layer 240. 230, a second functional layer 250 having a prism pattern formed on the upper surface of the second base layer 240 in a direction perpendicular to the first functional layer 220, and a third base layer made of a third PET film. 270, an acid portion of the prism pattern of the second functional layer 250, and the A second adhesive layer 260 for bonding the bottom surface of the third base layer 270 and a third functional layer 280 formed by distributing a microlens pattern on the top surface of the third base layer 270 are included.

As described above, after the UV resin is coated on the thin first PET film to form a lenticular pattern, a lenticular sheet is manufactured by using UV curing means, and UV is applied to the bottom surface of the second PET. After applying a thin resin to form a first adhesive layer, the acid portion of the lenticular sheet of the first PET film and the adhesive layer of the second PET film are in close contact with each other and UV-cured to prepare a flat lenticular sheet. A UV resin is applied to the upper surface of the flat lenticular sheet to form a prism pattern in a direction perpendicular to the lenticular pattern, and then UV cured to form a prism sheet. After applying a thin UV resin on the lower surface of the third PET to form a second adhesive layer, the acid portion of the prism sheet of the second PET film and the second adhesive layer of the third PET film are in close contact with each other and UV-cured to form a flat prism. Prepare sheet / lenticular sheet. A microlens pattern is formed on the top surface of the flat prism sheet / lenticular sheet with UV resin and UV cured to form a lens sheet.

In this manner, the first adhesive layer bonds the first base layer 210, the first functional layer 220, which is the lenticular sheet, and the lower surface of the second base layer 240, and the acid portion of the lenticular sheet of the first functional layer 220. 230, a second functional layer 250 composed of a prism sheet on the second base layer 240, a lower surface of the third base layer 270, and an acid portion of the prism sheet on the second base layer 240. A three-layered composite sheet including a second adhesive layer 260 and a third functional layer 280 composed of a lens sheet of a microlens pattern on the third base layer 270 is completed.

The lens sheet of the microlens pattern has a diffusing function as much as that of the diffusing sheet and has a light condensing function of about 80% of the prism sheet. Therefore, two sheets including one sheet of the three-layer composite sheet of the present invention or one sheet of diffusion sheet underneath are sufficient for a backlight unit using a non-printing light guide plate of a liquid crystal display for television. In addition, when the laminated using a thin PET film to reduce the thickness of the three-layer composite sheet becomes a composite structure can solve problems such as thermal deformation and sheet thickness like an optical sheet using a thick PET film.

The thickness of the first PET constituting the first base layer is 40um ~ 60um, the thickness of the second PET constituting the second base layer is 40um ~ 60um, the thickness of the third PET constituting the third base layer is in the range of 100um ~ 140um Can be adopted optionally. Preferably, the thickness of the first PET layer forming the first base layer is 50um, the thickness of the second PET layer forming the second base layer is 50um, and the thickness of the third PET layer forming the third base layer is preferably 125um.

7 is a flowchart illustrating an embodiment of a method for manufacturing a two-layer composite sheet for a backlight unit of the present invention. As shown in Figure 7, the method for manufacturing a two-layer composite sheet for a backlight unit of the present invention, the step of forming a lenticular pattern with a UV resin on the first PET film and cured with UV to make a lower layer lenticular sheet ( S100); Forming an adhesive layer by applying a thin UV resin on the lower surface of the second PET film (S102); Making a flat lenticular sheet by curing the UV portion of the lenticular pattern of the lower layer lenticular sheet of the first PET film and the adhesive layer of the second PET film while being in close contact with each other (S104); Forming a prism pattern with a UV resin in a direction perpendicular to the lenticular pattern on the first PET film on the flat plate lenticular sheet and curing with UV to form a prism sheet (S106).

8 is a flowchart illustrating an embodiment of a method for manufacturing a three-layer composite sheet for a backlight unit of the present invention. As shown in Figure 8, the manufacturing method of the three-layer composite sheet for the backlight unit of the present invention, the step of forming a lenticular pattern with a UV resin on the first PET film and cured with UV to make a lower layer lenticular sheet ( S200); Forming a first adhesive layer by applying a thin UV resin on the lower surface of the second PET film (S202); Making a flat lenticular sheet by curing the UV portion of the lenticular pattern of the lower layer lenticular sheet of the first PET film and the first adhesive layer of the second PET film while being in close contact with each other (S204); Forming a prism pattern with a UV resin in a direction perpendicular to the lenticular pattern on the first PET film on the flat plate lenticular sheet and curing with UV to form a multilayer prism sheet (S206); Forming a second adhesive layer by applying a thin UV resin on the lower surface of the third PET film (S208); Making a flat prism sheet / lenticular sheet by bringing the acid portion of the first prism sheet of the flat plate lenticular sheet and the second adhesive layer of the third PET film into close contact with each other and curing with UV; Forming a microlens pattern with a UV resin on the flat prism sheet / lenticular sheet and cured with UV to create a lens sheet (S212).

In the method of manufacturing a composite sheet for a backlight unit of the present invention, a UV resin in a gel state is coated on a thin upper surface of the first PET film, and a lenticular pattern structure is used on the upper surface of the first PET film. Form a lenticular pattern. The first PET film having a lenticular pattern formed on the upper surface thereof is cured with UV to prepare a lenticular sheet. The lenticular sheet is positioned directly on the non-printing light guide plate to perform a function such as a diffusion sheet. In addition, the first adhesive layer is formed by applying a gel-type UV resin to a predetermined thickness on the lower surface of the thin second PET film. Subsequently, a portion of the rib of the lenticular pattern on the first PET film is adhered to be inserted into the first adhesive layer, and cured with UV to prepare a flat lenticular sheet. Subsequently, a UV resin in a gel state is applied to the upper surface of the flat lenticular sheet to a predetermined thickness, and a prism pattern is formed using a prism pattern structure. The prism pattern has a direction perpendicular to the direction of the lenticular pattern. A prism sheet is prepared by curing the second PET film having a prism pattern formed on the upper surface with UV. The prism sheet is a component for converting light incident from the lenticular sheet into a vertical direction. In the process so far, the production of the two-layer composite sheet of the present invention is completed. Subsequently, a gel adhesive UV resin is applied to a lower surface of the thinner third PET film to a predetermined thickness to form a second adhesive layer. A portion of the ribs of the prism sheet is brought into close contact with the second adhesive layer and cured with UV to prepare a flat prism sheet / lenticular sheet. Subsequently, a UV resin in a gel state is applied to the upper surface of the flat prism sheet / lenticular sheet to a predetermined thickness, and a microlens pattern is formed using a microlens pattern structure. Subsequently, manufacture of the three-layer composite sheet of this invention is completed by hardening with UV and manufacturing a lens sheet.

In addition, in the embodiment of the present invention, instead of the lens sheet on which the microlens pattern is formed, the scattering beads may be distributed on a PET film and may be configured as a UV cured protective film.

9 is a performance comparison table of the two-layer composite sheet and the three-layer composite sheet and the other optical sheet of the embodiment of the present invention. Existing optical sheet is too thick and contrasts when using three to four optical films each of diffusion sheet / prism sheet (vertical) / prism sheet (horizontal) / protective sheet or two lens sheets. It can be seen that the luminance is lowered. It can be seen that the two-layer composite sheet or three-layer composite sheet of the present invention is composed of one composite sheet each integrated, and the thickness thereof is extremely thin, and the luminance performance is excellent compared to the thickness.

Instead of the microlens pattern, scattering beads may be distributed on the upper surface of the flat prism sheet / lenticular sheet and cured with UV to prepare a three-layer composite sheet of the present invention.

The embodiments of the present invention described above are only some of the various embodiments of the present invention. In a composite sheet for a backlight unit using a non-printing light guide plate of a television liquid crystal display according to the present invention, a lenticular sheet for performing a diffusion sheet function, the prism sheet for performing a condensing function, or the configuration Of course, various embodiments of the two-layer and three-layer composite sheet including a lens sheet integrally formed on the upper side of the prism sheet and a manufacturing method thereof are included in the protection scope of the present invention.

100: non-printing light guide plate
110,210: first base layer
120, 220: first functional layer
130, 230: first adhesive layer
140, 240: second base layer
150, 250: second functional layer
160, 260: second adhesive layer
170, 270: third base layer
180, 280: third functional layer

Claims (15)

delete A lenticular sheet for positioning on a non-printing light guide plate,
A prism sheet having a prism pattern formed in a direction orthogonal to the direction of the lenticular pattern of the lenticular sheet;
A lens sheet having a microlens pattern,
And the acid portion of the lenticular sheet and the lower surface of the prism sheet are bonded to each other, and the acid portion of the prism sheet and the lower surface of the lens sheet are bonded to each other to be integrated. A lenticular sheet for positioning on a non-printing light guide plate,
A prism sheet having a prism pattern formed in a direction orthogonal to the direction of the lenticular pattern of the lenticular sheet;
Includes a protective sheet with scattering beads on the upper surface,
And a lower portion of the prism sheet and an acid portion of the lenticular sheet are bonded to each other, and the lower portion of the prism sheet and the lower surface of the protective sheet are bonded to each other. The method according to claim 2 or 3,
The lenticular pattern and the prism pattern are each formed on a PET film composite sheet for a backlight unit. The method according to claim 2,
The microlens pattern is a composite sheet for a backlight unit, characterized in that formed on the PET film. The method according to claim 3,
The protective sheet is a composite sheet for a backlight unit, characterized in that the PET film. delete A first base layer made of a first PET film to be positioned on the non-printing light guide plate, a first functional layer of a lenticular pattern formed on an upper surface of the first base layer, a second base layer made of a second PET film, and the first base layer A second functional layer having a first adhesive layer for adhering the acid portion of the lenticular pattern of the functional layer and the lower surface of the second base layer, and a prism pattern formed on the upper surface of the second base layer in a direction perpendicular to the first functional layer. And a third base layer made of a third PET film, a second adhesive layer for adhering an acid portion of the prism pattern of the second functional layer and a bottom surface of the third base layer, and a microlens pattern on an upper surface of the third base layer. Composite sheet for a backlight unit comprising a third functional layer formed. A first base layer made of a first PET film to be positioned on the non-printing light guide plate, a first functional layer of a lenticular pattern formed on an upper surface of the first base layer, a second base layer made of a second PET film, and the first base layer A second functional layer having a first adhesive layer for adhering the acid portion of the lenticular pattern of the functional layer and the lower surface of the second base layer, and a prism pattern formed on the upper surface of the second base layer in a direction perpendicular to the first functional layer. And a third base layer made of a third PET film, a second adhesive layer for bonding the acid portion of the prism pattern of the second functional layer and the bottom surface of the third base layer, and scattering beads on the top surface of the third base layer. Composite sheet for a backlight unit comprising a third functional layer formed by distribution. delete Forming a lenticular pattern with UV resin on the first PET film and curing with UV to make a lower layer lenticular sheet; Forming a first adhesive layer by applying a thin UV resin on the lower surface of the second PET film; Making a flat lenticular sheet by curing the UV portion of the lenticular pattern of the lower layer lenticular sheet of the first PET film and the first adhesive layer of the second PET film while being in close contact with each other; Forming a prism pattern on the flat plate lenticular sheet with a UV resin in a direction perpendicular to the lenticular pattern on the first PET film and curing with UV to form a multilayer prism sheet; Forming a second adhesive layer by applying a thin UV resin on the lower surface of the third PET film; Making a flat prism sheet / lenticular sheet by bringing the acid portion of the first prism sheet of the flat plate lenticular sheet and the second adhesive layer of the third PET film into close contact with each other and curing with UV; Forming a microlens pattern with UV resin on the flat prism sheet / lenticular sheet and curing with UV to create a lens sheet for a composite sheet for a backlight unit. Forming a lenticular pattern with UV resin on the first PET film and curing with UV to make a lower layer lenticular sheet; Forming a first adhesive layer by applying a thin UV resin on the lower surface of the second PET film; Making a flat lenticular sheet by curing the UV portion of the lenticular pattern of the lower layer lenticular sheet of the first PET film and the first adhesive layer of the second PET film while being in close contact with each other; Forming a prism pattern on the flat plate lenticular sheet with a UV resin in a direction perpendicular to the lenticular pattern on the first PET film and curing with UV to form a multilayer prism sheet; Forming a second adhesive layer by applying a thin UV resin on the lower surface of the third PET film; Making a flat prism sheet / lenticular sheet by bringing the acid portion of the first prism sheet of the flat plate lenticular sheet and the second adhesive layer of the third PET film into close contact with each other and curing with UV; A method of manufacturing a composite sheet for a backlight unit, comprising the steps of: forming scattering beads on the flat prism sheet / lenticular sheet and curing with UV to form a protective sheet. delete Applying a gel UV resin to a top surface of the first PET film to a predetermined thickness and forming a lenticular pattern on the top surface of the first PET film by using a lenticular pattern structure;
Curing the first PET film having a lenticular pattern formed on an upper surface thereof by UV to make a lenticular sheet;
Forming a first adhesive layer by applying a gel-type UV resin to a lower surface of the second PET film to a predetermined thickness;
A part of the rib of the lenticular pattern on the first PET film is adhered to the first adhesive layer and cured with UV to form a flat lenticular sheet;
Applying a gel-type UV resin to a top surface of the flat plate lenticular sheet to a predetermined thickness and forming a prism pattern using a prism pattern structure;
Curing the second PET film having a prism pattern formed on an upper surface thereof by UV to make a prism sheet;
Forming a second adhesive layer by applying a gel-type UV resin to a lower surface of the third PET film to a predetermined thickness;
Contacting a portion of the rib of the prism sheet to be inserted into the second adhesive layer and curing with UV to form a flat prism sheet / lenticular sheet;
Applying a gel-type UV resin to a top surface of the flat prism sheet / lenticular sheet to a predetermined thickness and forming a microlens pattern using a microlens pattern structure;
Method of manufacturing a composite sheet for a backlight unit comprising the step of making the lens sheet by curing the microlens pattern with UV. Applying a gel UV resin to a top surface of the first PET film to a predetermined thickness and forming a lenticular pattern on the top surface of the first PET film by using a lenticular pattern structure;
Curing the first PET film having a lenticular pattern formed on an upper surface thereof by UV to make a lenticular sheet;
Forming a first adhesive layer by applying a gel-type UV resin to a lower surface of the second PET film to a predetermined thickness;
A part of the rib of the lenticular pattern on the first PET film is adhered to the first adhesive layer and cured with UV to form a flat lenticular sheet;
Applying a gel-type UV resin to a top surface of the flat plate lenticular sheet to a predetermined thickness and forming a prism pattern using a prism pattern structure;
Curing the second PET film having a prism pattern formed on an upper surface thereof by UV to make a prism sheet;
Forming a second adhesive layer by applying a gel-type UV resin to a lower surface of the third PET film to a predetermined thickness;
Contacting a portion of the rib of the prism sheet to be inserted into the second adhesive layer and curing with UV to form a flat prism sheet / lenticular sheet;
Distributing scattering beads on an upper surface of the flat prism sheet / lenticular sheet;
Method for producing a composite sheet for a backlight unit comprising the step of curing the scattering beads with UV to make a protective sheet.

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