KR20110099525A - Method and apparatus for imprinting pattern of optical micro structures upon light guide panel - Google Patents

Abstract

The present invention relates to a method and apparatus for imprinting an optical microstructure pattern on a light guide plate, the method comprising: forming a masking pattern of a fine stripe pattern having a predetermined thickness and spacing on a screen plate, disposing the screen plate on the light guide plate; The light guide plate comprising a coating method of a low viscosity ultraviolet curable resin comprising a step of pushing the screen plate with a squeegee and dropping the low viscosity ultraviolet curable resin between the masking patterns, a bottom surface on which the light guide plate is disposed, and a transparent and flexible organic material. An optical microstructure pattern is engraved on the lower surface of the upper surface of the upper surface of the stamp, pressurizing means for applying pressure to the stamp to closely adhere to the light guide plate, and an ultraviolet irradiation mechanism for irradiating ultraviolet rays from the upper portion of the stamp; Including microstructure pattern stamping device, can be low viscosity UV curing It is possible to omit the pretreatment process associated with the use of the film and to prevent the bubbles and defects generated during the coating and stamping of the low-viscosity UV curable resin, thereby producing a high-quality light guide plate having a high degree of transfer of the optical microstructure pattern. have.

Description

METHOD AND APPARATUS FOR IMPRINTING PATTERN OF OPTICAL MICRO STRUCTURES UPON LIGHT GUIDE PANEL}

The present invention relates to a method and apparatus for imprinting an optical microstructure pattern on a light guide plate. In particular, a high-quality large-area light guide plate is formed by screen-coating a low-viscosity UV curable resin on a light guide plate and then UV-printing the optical microstructure pattern on a coating surface. It relates to a method and apparatus for manufacturing.

BACKGROUND ART In general, a light guide plate for a backlight used in a liquid crystal display includes optical microstructure patterns on one or both surfaces thereof so that a light source (CCFL or LED) incident through a side part may be emitted to the front part.

As a method of forming an optical microstructure pattern, a method of screen printing a light scattering dot (dot) pattern using ink containing reflective particles on one surface of the light guide plate (hereinafter referred to as a 'printing light guide plate'), optical fine A method of stamping a pattern simultaneously with injection molding by attaching a metal stamper having a negative structure to the mold (hereinafter referred to as an 'injection-free light guide plate'), or a method of marking a pattern by drawing a line with a diamond bite on one surface of the light guide plate ( Hereinafter, a method of melting a surface of a light guide plate in a dot form using a laser and imprinting a dot pattern (hereinafter referred to as a laser processing light guide plate) is known.

In this case, an injection-free printed light guide plate is used for a backlight constituting a liquid crystal display device of a mobile device such as a laptop, a PC, a mobile phone, and the like. In manufacturing such a backlight for a mobile device, an optical microstructure pattern having a higher light efficiency in a mold is used. By imprinting, the optical loss is lowered and the luminance is increased.

On the other hand, a printed light guide plate is used for a backlight constituting a liquid crystal display such as a 17-inch or larger monitor and a small TV. This is because even when the light guide plate is enlarged, when the injection molding method is used, the processing time is long and productivity is decreased and the cost is increased.

On the other hand, the use of a laser processing light guide plate together with a printed light guide plate is increasing in the backlight which comprises liquid crystal display devices, such as a 32-inch or larger large TV. However, when the light guide plate is made larger, the printing method increases the defective area by increasing the printing area and increases the possibility of the post deformation of the light guide plate due to the use of ink and solvent. In addition, since the laser processing light guide plate is manufactured by sequentially imprinting a dot pattern one by one, there is a high possibility that a defect in a unit of dots may occur, a production cycle is long, and a cost required for equipment installation is increased.

In addition, a method of stamping an optical microstructure pattern by hot stamping a light guide plate by applying heat to a metal stamper is also known, but due to problems such as incomplete imprinting, deformation of the light guide plate, and decrease in productivity, a method of manufacturing a large light guide plate is known. It is not commercialized.

In order to overcome this problem, in recent years, hot stamping or ultraviolet curing resins have been used to improve productivity by increasing optical performance such as brightness and lowering defect rate by adding optical microstructure patterns having high light efficiency to large area monitors and light guide plates for TVs. Attempts have been made to imprint optical microstructure patterns in a short time (UV imprinting).

The UV stamping method is coated with a thin film of an ultraviolet curable resin (hereinafter referred to as a resin) on one surface of a light guide plate made of PMMA, and the UV light is adhered to a metal or elastic stamp in which an optical microstructure pattern is engraved. By curing the resin, the stamp is separated and the stamp is imprinted on the light guide plate. When using a stamp having a high efficiency optical microstructure pattern, there is an advantage that a large quantity of light guide plate of the same quality can be rapidly produced.

However, roll coating, wire-wound bar, or D-bar coating or E-roll coating method is generally used to coat a UV light-curing resin on a light guide plate with a thin film having a thickness of 10 to 100 μm. It is suitable for films with a small thickness and relatively small thickness variation, and the slit coating, spin coating, and spray coating method of dropping a certain amount of resin onto a substrate has complicated equipment. If the light guide plate has a large area, the cost increases, and there is a disadvantage that additional measures must be taken so that the edge portion of the light guide plate is not coated.

The light guide plate made of PMMA is relatively thicker and has a larger thickness variation than that of a general film. For example, a 4 mm thick light guide plate has a thickness variation of +/− 300 μm, which is greater than the thickness of the thin film to be coated. . In addition, due to the nature of the plastic may be bent depending on the environmental conditions such as the handling conditions, temperature, humidity, etc., and therefore entails a completely different condition from the coating of the film.

On the other hand, the coating method by screen printing can coat a thin film with a uniform thickness even when the thickness variation and curvature of the substrate exists, and the edge of the light guide plate by using masking as a screen for the part where coating is not required on the light guide plate. If the resin sticks out and the appearance is damaged, it is not only possible to omit the post-process to be adopted but also to carry out at low cost.

For conventional resin coatings the viscosity ranges between low viscosity of approximately 1 to 2500 cps and high viscosity of 6000 to 100000 cps. In this case, when the medium-high viscosity ultraviolet curable resin (viscosity of about 1000 ~ 10000cps) is coated by the screen printing method, the coating of the light guide plate made of PMMA is not well coated and must be pretreated such as primer treatment. In addition, coating is attempted in a vacuum environment in order to suppress bubble generation, but the UV marking method through such a process does not reach the stage of commercializing the light guide plate. In addition, when the viscosity of the resin is lowered to 1000 cps or less in order to omit a costly pretreatment process, the surface tension of the screen and the resin is increased to increase the generation of vortices during coating, thereby increasing the fine bubbles.

The prism sheet, one of the backlight components, is roll-coated with a UV curable resin on a film, mass-produced by a continuous process in which an optical fine prism is adhered to a roll stamp (embossing roll) engraved with an optical microprism, and then cured with ultraviolet rays to imprint a pattern. Although it is in the step, the substrate with a certain thickness, such as the light guide plate, the substrate having a thickness deviation and warpage, when the roll process is applied, the coating layer of the light guide plate and the stamp is not well adhered, so that an empty space occurs in the adhesive layer. Therefore, even after UV curing, the light guide plate by the UV stamping method is not commercialized due to various problems such as incomplete imprinting of the optical microstructure or inclusion of air bubbles in the optical product.

In addition, a method of applying pressure to the front surface of the stamp at the same time in a state where the surface of the light-curing plate coated with the UV curable resin and the optical microstructure of the stamp are overlapped with each other (planar pressing) In order to apply, a surface pressure device capable of applying isotropic pressure and a vacuum device for suppressing bubbles are introduced, but there are limitations in performance and quality as optical products without overcoming the bubble and incomplete imprinting problems. In addition, the application of the vacuum and isostatic pressurization device has a disadvantage in that the equipment structure becomes complicated and the cost increases due to the increase in cost.

The present invention was devised to solve the above-described problems, and provides a method for manufacturing a high quality light guide plate by omitting the pretreatment step performed when screen printing low-viscosity ultraviolet curable resin, and suppressing the generation of bubbles. There is a purpose.

In addition, another object of the present invention is to provide a device capable of UV-engraving high-quality optical microstructure pattern by overcoming the thickness variation and warpage of the light guide plate and the stamper in close contact with the light guide plate and the stamper.

As a means for solving the above technical problem,

The present invention is a method of coating a light guide plate with a low viscosity ultraviolet curable resin by a screen printing method and then stamping the optical microstructure pattern by an ultraviolet engraving method, wherein the coating method of the low viscosity ultraviolet curable resin is (a) a screen plate. Forming a fine stripe masking pattern having a predetermined thickness and spacing; (b) placing the screen plate on the light guide plate; and (c) pushing the screen plate with a squeegee to form the low viscosity ultraviolet curable resin. It provides a method for imprinting the optical microstructure pattern on the light guide plate comprising the step of dropping between the masking pattern.

Here, the viscosity of the low-viscosity ultraviolet curable resin is preferably 1000 cps or less.

In addition, the masking pattern is preferably formed with a thickness of 10 ~ 500㎛ and intervals of 10 ~ 1000㎛ using an oil or photoresist.

The present invention is an apparatus for ultraviolet-engraving an optical microstructure pattern on a light guide plate manufactured according to the above method, comprising a bottom surface on which the light guide plate is disposed, and a transparent and flexible organic material, installed on an upper part of the light guide plate, The stamp includes a stamp in which an optical microstructure pattern is engraved, a pressing means for applying pressure to the stamp to closely adhere to the light guide plate, and an ultraviolet irradiation mechanism for irradiating ultraviolet rays from the upper portion of the stamp. Provide the device.

The optical microstructure pattern marking device may further include a buffer sheet stacked on top of the stamp, the buffer sheet made of a transparent and flexible organic material, and a clamp fixing the stack of the buffer sheet and the stamp. have.

In this case, at least one clamp is formed at each end of the stack, and the clamp formed at one end thereof is preferably provided with a lifting means for linearly moving up and down in conjunction with the pressing means.

In addition, the pressing means may be a roller or a squeegee made of a flexible organic material.

In addition, the pressing means may be a roller composed of a core layer made of a high hardness material, an intermediate layer made of a fluid or foam material, and a surface layer made of an elastic material.

On the other hand, the buffer sheet is preferably provided with a foam layer on the inside, or has an uneven portion on the bottom surface.

Subsequently, the ultraviolet irradiation mechanism can irradiate ultraviolet rays with line illumination or surface illumination.

In addition, the light guide plate may be fixed to the bottom surface by fixing means.

The optical microstructure pattern imprinting device may be formed on the bottom surface to fix the light guide plate to the bottom surface by discharging air using a vacuum pump from a plurality of light guide plate adsorption holes disposed under the light guide plate. have.

The optical microstructure pattern imprinting device may be embedded in a case opened and closed by a sealing member, and the inside may be formed in a vacuum by discharging air from the plurality of air suction holes formed in the bottom surface by using the vacuum pump. Can be.

According to the present invention, a light guide plate having high transmittance and no defect in the optical microstructure pattern can be produced by suppressing the generation of bubbles caused by the use of a low viscosity ultraviolet curable resin.

In addition, by using a low-viscosity ultraviolet curable resin, not only the adhesive strength of a thin film is high but a pretreatment process can be skipped.

In addition, since the thickness of the thin film can be adjusted, an optically excellent thin film can be coated on a light guide plate made of PMMA material having a thickness variation and warpage.

In addition, the light guide plate and the stamper are closely adhered to each other at an even pressure to prevent optical quality defects caused by UV engraving, while the configuration is relatively simple, so the installation and maintenance costs are low, and the light guide plate of the same quality can be quickly mass-produced. .

In addition, when the light guide plate manufactured according to the present invention is used for a backlight of a medium / large liquid crystal display device, it is possible to improve the performance of the backlight, the color, and the like, as well as to reduce the number of light sources.

1 is a schematic view showing a process of screen printing a low viscosity ultraviolet curable resin on a light guide plate according to the present invention;
2 is a view showing an optical microstructure pattern marking device according to the present invention,
3 is a view comparing the shape of the buffer sheet according to the present invention;
Figure 4 is a view showing an embodiment of the lifting means according to the invention,
5 is a view showing the internal structure of the roller of the optical microstructure pattern marking device according to the present invention,
6 is a view showing a modification of the optical microstructure pattern marking device according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

BACKGROUND OF THE INVENTION Field of the Invention The present invention is roughly classified into a method and an apparatus for marking an optical microstructure pattern on a light guide plate used for a backlight of a liquid crystal display device.

First, the method of imprinting the optical microstructure pattern on the light guide plate is performed by screen printing a low-viscosity UV curable resin on the light guide plate, and attaching a stamp in which the optical microstructure pattern is engraved to the light guide plate coated with the low-viscosity UV curable resin to apply ultraviolet rays. It is comprised including the process of investigating. Hereinafter, each process is demonstrated more concretely.

1 is a schematic view showing a step of screen printing a low viscosity ultraviolet curable resin on a light guide plate according to the present invention.

Referring to FIG. 1, a process of screen printing a low-viscosity ultraviolet curable resin on a light guide plate may include applying a masking pattern 140 of a micro stripe pattern having a predetermined thickness and spacing on the screen plate 110. Forming, arranging the screen plate 110 on the light guide plate 10 and pushing the screen plate 110 onto the squeegee 120 to drop the low-viscosity ultraviolet curable resin 20 between the masking patterns 140. Is made of.

In this case, the viscosity of the low-viscosity ultraviolet curable resin 20 is preferably 1000 cps or less. This is because the high-viscosity ultraviolet curable resin is not coated well on the light guide plate 10 which is usually made of PMMA, so additional primer treatment is required. That is, the present invention uses a low viscosity ultraviolet curable resin 20 in order to omit such a pretreatment process, but in general, the low viscosity ultraviolet curable resin 20 has a problem that a lot of bubbles are generated during screen coating.

In detail, the screen coating pushes the low-viscosity UV curable resin 20 on the screen plate 110 with the squeegee 120 while the screen plate 110 is spaced apart from the light guide plate 10. ) And then the screen plate 110 is separated from the light guide plate 10 again. The low viscosity ultraviolet curable resin 20 rolls in the advancing direction of the squeegee 120. Bubbles are generated due to the generated vortices and the vortices generated by the surface tension when the screen mesh 130 and the low-viscosity ultraviolet curable resin 20 fall. In addition, the absence of free space for the bubbles generated in this process to be released to the atmosphere is also a factor to prevent or delay the disappearance of bubbles.

The present invention is characterized in that the masking pattern 140 is formed on the screen plate 110 as described above in order to prevent the occurrence of such bubbles. That is, when the squeegee 120 moves, the low-viscosity ultraviolet curable resin 20 is dropped into the space between the masking patterns 140 to reduce the vortex to suppress the generation of bubbles, while the screen plate 110 is coated after the light guide plate. When separating from (10), the low-viscosity ultraviolet curable resin 20 is spread by the masking pattern 140 to the undropped portion so that bubbles are naturally released, thereby coating a thin film of excellent quality UV-curable resin without bubbles.

For this purpose, the masking pattern 140 may be manufactured by photochemical photolithography using an emulsion or a photo resist. In this case, the masking pattern 140 may have a thickness of 10 μm to 500 μm, and the interval between the masking patterns 140 may be 10 μm to 1000 μm so as to maximize the bubble generation suppression effect.

On the other hand, the coating method as described above is similar to the bar coating (bar coating) in that the coating in a linear shape, but in the present invention, the flexible screen plate 110 to be applied to a light guide plate having a large thickness variation in the plane After unfolding, the low-viscosity ultraviolet curable resin 20 is dropped into a line shape and is coated at a constant thickness.

In this case, according to the present invention, when the masking pattern 140 is formed, the thickness of the screen mesh 130 and the transmission volume according to the mesh count, the thickness of the emulsion, and the bottom point according to the width and the interval of the masking pattern 140 In addition, it is also possible to control the thickness of the thin film by freely adjusting the total transmission volume of the ultraviolet curable resin 20.

For reference, define an eye carpenter with a straight line distance of 25.4 mm (1 ") from the screen plate, n for the screen mesh diameter, and d for the mesh opening. n = 25400 / (d + w) (unit is mesh, μm) Meanwhile, the ratio of the space area of the screen mesh (space rate,%) is calculated as (w / (w + d)) ² × 100. If the thickness of the screen mesh is D, the theoretical resin coating volume is Vth [cm 3 / m 2] = (w / (w + d)) 2 × D (w, d, D is μm).

In addition, the width of the banding pattern of the masking pattern is defined as s, the pitch between the bands and the bands as p, and the thickness as t, and t is greater than D and the viscosity of the resin is low, so that the banding masking pattern part after coating is coated. Assuming that it spreads evenly, the coating volume of the resin after coating becomes (w / (w + d)) ² × (p / (s + p)) × t and when the contraction by solvent volatilization does not start after coating The theoretical thickness of the thin film is (p / (s + p)) × t. When t is smaller than D, the coating volume of the resin after coating becomes (w / (w + d)) ² × (p / (s + p)) × D, and the thickness of the thin film after coating is (p / (s + p)) x D.

Based on this, a low viscosity ultraviolet curable resin was prepared as follows to evaluate the performance.

Firstly, a light guide plate made of PMMA material is mounted on the bottom surface, and a light guide plate is formed of a 300 mesh (about 250 mesh) polyester mesh and a masking pattern formed by a 80 mm wide and 20 μm thick stripe pattern at 80 μm intervals. The coating was applied by discharging an ultraviolet curable resin having a viscosity of 500 cps to the screen plate and then pushing it with a squeegee.

Subsequently, as a comparative example, a screen plate of the same standard was coated under the same conditions without a masking pattern, and both were visually compared. As a result, many bubbles were generated in the comparative example, but the bubbles were remarkable in the embodiment according to the present invention. Can be observed.

As mentioned above, the method of screen-printing low-viscosity ultraviolet-ray cured resin on the light guide plate was demonstrated concretely. Hereinafter, a method of UV-engraving an optical microstructure pattern on a light guide plate coated with a low-viscosity ultraviolet curable resin will be described with reference to the accompanying drawings.

2 is a view showing an optical microstructure pattern marking device according to the present invention.

The method of irradiating ultraviolet rays by closely attaching a stamp having an optical microstructure pattern engraved to a light guide plate coated with a low-viscosity ultraviolet curable resin of the present invention is made by the optical microstructure pattern marking device 200 shown in FIG. It is a constitution.

The optical microstructure pattern marking device 200 includes a bottom surface 250, a stamp 210, a pressing means, and an ultraviolet irradiation mechanism 260.

Specifically, the bottom surface 250 is a configuration for mounting the light guide plate 10, the fixing means of the light guide plate 10 is formed at a predetermined position.

Subsequently, the stamp 210 is provided on the upper part of the light guide plate 10 by the marking means of the optical microstructure pattern. To this end, an optical microstructure pattern (not shown) is engraved on the lower surface of the stamp 210. In addition, the stamp 210 may be manufactured to about 1 mm using a transparent and flexible organic material such as PDMS (polydimethylsiloxane) so as to be in close contact with the light guide plate 10.

Figure 3 is a view showing a comparison of the shape of the buffer sheet according to the present invention.

Referring to FIG. 3 additionally, a buffer sheet 220 for buffering may be additionally stacked (FIG. 3A) on the upper portion of the stamp 210. In this case, the bottom surface of the buffer sheet 220 is preferably formed with an uneven portion (Fig. 3 (c)) so that the lamination with the stamp 210 can be made smoothly. In the present invention, the buffer sheet 220 is manufactured using a transparent and flexible organic material to evenly disperse the difference in the contact pressure due to the thickness variation of the light guide plate 10 and the stamp 210, preferably in the air It is also possible to give elasticity by foaming etc. (FIG. 3 (b)).

The stack of the stamp 210 and the buffer sheet 220 configured as described above is fixed by the clamps 230a and 230b. At least one clamp 230a, 230b may be formed at both ends of the stack, in this case, it is preferable that the clamp 230a formed at one end has a lifting means 240.

The elevating means 240 may be assembled to include a mechanical / electric elevating mechanism for controlling the height in conjunction with the movement of the pressing means in a configuration for forming a slope between the light guide plate 10 and the stack.

Figure 4 is a view showing an embodiment of the lifting means according to the invention.

As shown in FIG. 4, the raising and lowering means 240 is installed perpendicular to the bottom surface 250 to vertically move the driving shaft 241 to vertically move the clamp 230a and the clamp 230a. The guide motors 242a and 242b, the lower end of the drive shaft 241 and the gear 245 are coupled to the step motor 246 for transmitting power to the drive shaft 241 and the step motor 246 according to the movement of the pressing means. It may be configured to include a control unit (not shown) for controlling the height of the clamp 230a by adjusting the operation. In this case, reference numerals 243 and 244 in FIG. 4 denote bearings and induction cylinders, respectively.

By the above-described configuration, the clamp 230a descends at the same time as the pressing means moves forward, and the stamp stack is adhered to the coated LGP 10 after UV irradiation ends. The clamp 230a is lifted to be separated and when the separation is made, the clamp 230a is lowered to its original position.

Although one embodiment of the lifting means 240 has been described above, the configuration of the lifting means 240 is not limited thereto, and it should be understood that the present invention can be modified in various forms. For example, the above-described step motor 246 may be replaced with a pneumatic cylinder if necessary.

As a result, when the inclination is formed as described above, one end of the laminate spaced upward from the light guide plate 10 is maintained by the elevating means 240 to be higher than the other end, and gradually lowers as the pressure means moves. The adhesion of the layer 10 and the laminate can be made continuously and precisely.

Subsequently, the pressing means is a means for applying pressure to the stamp 210 to be in close contact with the light guide plate 10 so as to be movable in one direction on the top of the stamp 210. In this case, the pressing means may be a roller 300 or a squeegee made of a flexible organic material such that the contact portion forms a linear shape, but for the convenience of description, the roller 300 will be described as an example.

5 is a view showing the internal structure of the roller of the optical microstructure pattern marking device according to the present invention.

As shown in FIG. 5, the roller 300 includes a core layer 310 made of a hard material such as metal, an intermediate layer 320 made of a fluid or foamed material such as air, oil, and the like, and a urethane, silicone, rubber, or the like. It may be composed of a surface layer 330 made of the same elastic material. When the roller 300 is configured as described above, pressure distribution is smoothly performed, so that the stamp 210 and the light guide plate 10 can be adhered more effectively.

Finally, the ultraviolet irradiation mechanism 260 is installed on the upper portion of the stamp 210 as a means for irradiating and curing ultraviolet rays in the form of line illumination or surface illumination to the part in close contact with the pressing means. In this case, when the ultraviolet irradiation mechanism 260 is installed in conjunction with the pressurizing means, it is preferable that the laminate and the light guide plate 10 are pressed and cured at the same time. In the present invention, the ultraviolet irradiation mechanism 260 is not particularly limited, and various known forms may be used.

6 is a view showing a modification of the optical microstructure pattern marking device according to the present invention.

As shown in FIG. 6, the optical microstructure pattern marking device 200 according to the present invention sucks air from the light guide plate adsorption holes 282 and the light guide plate adsorption holes 282, which are formed on the bottom surface 250. It may be configured to further include a vacuum pump (not shown) to discharge through the air outlet 281. By such a configuration, the light guide plate 10 may be fixed to the bottom surface 250 to minimize the occurrence of incomplete stamping and bubbles.

On the other hand, it is also possible to incorporate the above-described optical microstructure pattern marking device 200 in the case 270. In this case, the case 270 is sealed by the sealing member 290, and the vacuum is sucked out of the air suction hole 283 formed in the bottom surface 250 by a vacuum pump and discharged to the air outlet 281. Can be formed. Such a vacuum atmosphere can further suppress generation of incomplete imprinting and bubbles.

Preferred embodiments of the present invention have been described in detail above with reference to the drawings. The description of the present invention is intended for illustration, and it will be understood by those skilled in the art that the present invention may be easily modified in other specific forms without changing the technical spirit or essential features of the present invention.

Therefore, the scope of the present invention is represented by the following claims rather than the detailed description, and all changes or modifications derived from the meaning, scope, and equivalent concepts of the claims are included in the scope of the present invention. Should be interpreted as

10: Light guide plate 20: Low viscosity ultraviolet curing resin
100: screen printing device 110: screen plate
120: squeegee 130: mesh
140: masking pattern
200: optical microstructure pattern stamping device
210: stamp 220: buffer sheet
230: clamp 240: lifting and lowering means
241: drive shaft 242a, 242b: guide shaft
243: bearing 244: induction cylinder
245 gear 246 step motor
250: bottom surface 260: ultraviolet irradiation apparatus
270: case 280: air passage
281: air outlet 282: light guide plate adsorption holes
283: air suction hole 290: sealing member
300: roller 310: core layer
320: intermediate layer 330: surface layer

Claims (16)

As a method of coating the light guide plate with a low-viscosity UV curable resin by screen printing method, and then imprinting the optical microstructure pattern by UV engraving method,
Coating method of the said low viscosity ultraviolet curable resin,
(a) forming a fine stripe masking pattern having a constant thickness and spacing on the screen plate;
(b) disposing the screen plate on the light guide plate; And
(c) pushing the screen plate with a squeegee to drop a low-viscosity ultraviolet curable resin between the masking patterns;
Imprinting optical microstructure pattern on the light guide plate comprising a. The method of claim 1,
And a viscosity of the low-viscosity ultraviolet curable resin is 1000 cps or less. The method of claim 1,
The thickness of the masking pattern is 10 ~ 500㎛, the interval is 10 ~ 1000㎛ method for imprinting the optical microstructure pattern on the light guide plate. The method according to claim 1 or 3,
The material of the masking pattern is a method of imprinting the optical microstructure pattern on the light guide plate, characterized in that the emulsion or photoresist. An apparatus for ultraviolet-engraving an optical microstructure pattern on a light guide plate manufactured according to any one of claims 1 to 4,
A bottom surface on which the light guide plate is disposed;
A stamp formed of a transparent and flexible organic material and installed on an upper portion of the light guide plate, and having an optical microstructure pattern engraved on a lower surface thereof;
Pressurizing means for applying pressure to the stamp to closely adhere to the light guide plate; And
An ultraviolet irradiation mechanism for irradiating ultraviolet rays from the upper portion of the stamp;
Optical microstructure patterned marking device comprising a. The method of claim 5, wherein
The optical microstructure pattern marking device,
A buffer sheet stacked on top of the stamp and made of a transparent and flexible organic material; And
A clamp for securing a stack of the buffer sheet and the stamp;
Optical microstructure pattern marking device further comprising a. The method according to claim 6,
At least one clamp is formed at both ends of the stack, respectively, wherein the clamp is formed at one end of the optical micro-structure pattern stamping device, characterized in that the lifting device is installed in a linear movement up and down in conjunction with the pressing means. The method of claim 5, wherein
The pressing means is an optical microstructure pattern stamping device, characterized in that the roller made of a flexible organic material. The method of claim 5, wherein
And the pressing means is a squeegee made of a flexible organic material. The method of claim 5, wherein
And said pressing means is a roller comprising a core layer made of a high hardness material, an intermediate layer made of a fluid or foam material, and a surface layer made of an elastic material. The method according to claim 6,
The buffer sheet is optical microstructure pattern stamping device, characterized in that provided with a foam layer therein. The method according to claim 6,
The buffer sheet is an optical microstructure pattern stamping device, characterized in that provided with a concave-convex portion on the lower surface. The method of claim 5, wherein
The ultraviolet irradiation mechanism is an optical microstructure pattern stamping device, characterized in that for irradiating ultraviolet light with line illumination or surface illumination. The method of claim 5, wherein
And the light guide plate is fixed to the bottom surface by fixing means. The method of claim 5, wherein
The optical microstructure pattern marking device,
And an optical microstructure pattern imprinting device formed on the bottom surface and fixing the light guide plate to the bottom surface by discharging air from a plurality of light guide plate adsorption holes positioned under the light guide plate using a vacuum pump. The method of claim 15,
The optical microstructure pattern marking device,
An optical microstructure pattern marking device built in a case that is opened and closed by a sealing member, the inside of which is formed in a vacuum by discharging air by using the vacuum pump from a plurality of air suction holes formed in the bottom surface.

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