KR101177865B1 - Three-Dimensional Polarized Light Film and Three-Dimensional Display - Google Patents

Abstract

The present invention is laminated on top of a first triacetyl cellulose (TAC) film, the first triacetyl cellulose (TAC) film, the polyvinyl alcohol (PVA) film having a polarization characteristic, the polyvinyl alcohol (PVA) film 3D optical film including a 3D pattern forming film laminated on the second triacetyl cellulose (TAC) film and the second triacetyl cellulose (TAC) film, and having a structure capable of refracting incident light from the outside It provides a polarizing film and a 3D display using the same.

Description

Polarizing film employing 3D optical film and 3D display using same {Three-Dimensional Polarized Light Film and Three-Dimensional Display}

The present invention relates to a polarizing film employing a 3D optical film and a 3D display using the same, and more particularly, to a polarizing film employing a 3D optical film capable of realizing a 3D image without special glasses for 3D and a 3D display using the same. It is about.

3D is an abbreviation of three-dimensional (3D) stereoscopic image when a human gazes at an object and the image obtained through one single image is an image in which two images are synthesized due to the visual difference between the left and right eyes. The stereoscopic image technology has been widely applied to the development of industrial products such as mobile phones, movies, games, and animations. Since 3D stereoscopic technology is a visual technology that allows humans to feel as if they are present in the place where the image is being made, its application fields such as information communication, broadcasting, medical, education, military, and industrial technology are very important. It is a core technology commonly required in various and next generation 3D stereoscopic multimedia information communication fields, and is rapidly emerging as a new growth engine industry.

In particular, in the TV field, the loss caused by the price drop caused by the fierce competition in the LCD flat panel TV market has been overcome by the strategy of increasing the size and quality of the image quality. To overcome the shortcomings of consumption, research and development on LED and OLED TV are being made. However, the LED and OLED TV products are still difficult to be large-scaled and mass-produced due to lack of price competitiveness and technological power. On the other hand, 3D TV corresponds to a new image realization method different from the existing image realization method, and 3D technology capable of realizing 3D images of broadcasting, movies, and games has recently emerged as a new alternative.

The display of 3D TV which is generally used currently uses 3D special glasses that allow viewers to recognize the left and right eye images separately by using the principle of binocular disparity.Anaglyph and polarized glasses (Passive Glass), shutter glasses (Active Glass) can be classified. However, the method of using the 3D special glasses have a problem in that the glasses must be worn when watching 3D TV, in particular, the red and blue glasses have poor color reproducibility, the polarized glasses have poor resolution, and the shutter glasses have a high price. It was heavy, and there was a problem that compatibility was not excellent. In order to solve this problem, products that can watch 3D TV without special glasses for 3D have been developed, but it is difficult to mass-produce them because of difficulty in implementing 3D and using too many display panels. .

Therefore, the implementation of 3D images by adding special films to conventional displays such as LCD TVs can reduce manufacturing costs and eliminate inconvenience for viewers to watch 3D TVs. Will be the best choice. Recently, the thin film transistor liquid crystal display is composed of a thin film transistor and a lower plate on which pixel electrodes are arranged, a top plate composed of a color filter and a common electrode for displaying colors, and a liquid crystal filled between the two glass substrates. Both sides of the glass substrate are TFT-LCDs each having a polarizing plate for linearly displaying visible light (natural light). In the case of a TFT-LCD, a polarizing plate is used as a basic component, and the polarizing plate has an upper tri-acetyl cellulose (TAC) film (1), a polyvinyl acetate film (PVA), and a lower TAC, as shown in FIG. It consists of the film 3. The upper and lower TAC films 1 and 3 do not have polarization characteristics, but since the PVA film 2 has polarization characteristics, polarization is represented by the stretching direction of the PVA film.

2 is a configuration diagram schematically showing a polarizing plate for a wide view type LCD. As shown in FIG. 2, the polarizer may be configured in a wide view type. Specifically, the wide view type polarizer has an antiglare layer for preventing glare on the upper part of the upper TAC film 1 with respect to the basic configuration of the upper TAC film 1, the PVA film 2, and the lower TAC film 3. A coating layer of the AG layer 4 and the LR / AR layer 5 is formed, and the protective film 6 is formed on top of the LR / AR layer 5. Is attached. In addition, a release film 7, an adhesive layer 8, and a viewing angle compensation coating layer (WV DLC) 9 are sequentially formed below the lower TAC film 3. When the structure of the polarizing plate of FIG. 2 mainly improves the characteristics that the TAC film does not have, for example, scratch resistance, low reflection characteristics, viewing angle characteristics, and the like, the above-described various types of films are laminated Will be used.

The present inventors can implement a three-dimensional image without the use of special glasses for 3D pointed out as a problem of the prior art by effectively arranging the optical phase difference generated by the lens sheet by laminating a micro lens film or a wave-shaped film in a conventional polarizing plate In order to realize the phase difference of the lens, the lens sheet is formed with curves in different directions to create a focal length difference, thereby providing two focal points without wearing special glasses for 3D. It has led to the development of a polarizing film employing a 3D optical film that can have a natural distance difference and a 3D display using the same.

An object of the present invention is to provide a polarizing film employing a 3D optical film that can realize a three-dimensional image without the use of special glasses for 3D and a 3D display using the same.

Another object of the present invention is to provide a focal length difference by attaching a lens sheet curved in different directions to realize the phase difference of the lens to provide two focal points without wearing special glasses for 3D It is to provide a polarizing film and a 3D display using the 3D optical film that can have a natural focal length difference of the eye.

The above and other objects of the present invention can be achieved by the present invention described below.

Polarizing film employing the 3D optical film according to the present invention is a first triacetyl cellulose (TAC) film; A polyvinyl alcohol (PVA) film laminated on top of the first triacetyl cellulose (TAC) film and having polarization characteristics; A second triacetyl cellulose (TAC) film laminated on top of the polyvinyl alcohol (PVA) film; And a 3D pattern forming film laminated on the second triacetyl cellulose (TAC) film and having a structure capable of refracting incident light from the outside.

Here, the 3D pattern forming film, the base film; And a pattern portion formed on one surface of the base film.

The pattern portion may have a wave shape or a micro lens shape.

The pattern portion is characterized in that the pattern having the same shape on one surface of the base film is continuously formed at a predetermined interval.

The continuous arrangement of the pattern is characterized in that arranged in the same direction as the polarization axis.

Polarizing film employing the 3D optical film is characterized in that it further comprises an antiglare layer that can prevent glare.

Polarizing film employing the 3D optical film is characterized in that it further comprises a low reflection and anti-reflection layer that can prevent glare that can prevent reflection.

Polarizing film employing the 3D optical film is characterized in that it further comprises a viewing angle compensation coating layer that can compensate for the viewing angle.

Polarizing film employing the 3D optical film is characterized in that it further comprises an adhesive layer and a release film on the lower film.

The polarizing film employing the 3D optical film is characterized in that it further comprises a protective film on the film.

In addition, the 3D display according to the present invention is a display element; 3D having a structure capable of refracting incident light from the outside on a first triacetyl cellulose (TAC) film, a polyvinyl alcohol (PVA) film having a polarization characteristic, a second triacetyl cellulose (TAC) film on the upper surface of the display device A polarizing film unit employing an upper 3D optical film having a structure in which a dragon pattern forming film is sequentially stacked; And a first triacetyl cellulose (TAC) film, a polyvinyl alcohol (PVA) film having a polarization characteristic, a second triacetyl cellulose (TAC) film, and a structure capable of refracting incident light from the outside on the lower surface of the display device. It characterized in that it comprises a polarizing film portion employing a lower 3D optical film having a structure in which the 3D pattern forming film is laminated sequentially.

Here, the 3D pattern forming film for the polarizing film portion employing the upper 3D optical film and the polarizing film portion employing the lower 3D optical film is a base film; And a pattern portion formed on one surface of the base film.

The pattern portion may have a wave shape or a micro lens shape.

The pattern portion is characterized in that the pattern having the same shape on one surface of the base film is continuously formed at a predetermined interval.

The display device may include a lower glass layer, a liquid crystal layer, and an upper glass layer.

The polarizing film part employing the upper 3D optical film has an adhesive layer at the bottom thereof, and the polarizing film part employing the lower 3D optical film has an adhesive layer at the top thereof.

The 3D display may further include an antiglare layer capable of preventing glare at predetermined positions of the polarizing film unit employing the upper 3D optical film and the polarizing film unit employing the lower 3D optical film, respectively.

The 3D display further includes a low reflection and anti-reflection layer capable of preventing glare that can prevent reflection at a predetermined position of the polarizing film portion employing the upper 3D optical film and the polarizing film portion employing the lower 3D optical film. It is characterized by.

The 3D display may further include a viewing angle compensation coating layer capable of compensating a viewing angle at a predetermined position of the polarizing film unit employing the upper 3D optical film and the polarizing film unit employing the lower 3D optical film.

At least one coordinate may be differently disposed with respect to the X, Y, and Z coordinates of the pattern part of the polarizing film part employing the upper 3D optical film and the polarizing film part employing the lower 3D optical film.

The polarizing film portion employing the upper 3D optical film and the pattern portion of the polarizing film portion employing the lower 3D optical film have a symmetric pattern or an asymmetric pattern, respectively.

The continuous arrangement of the pattern is characterized in that arranged in the same direction as the polarization axis.

The present invention can realize a three-dimensional image without the use of special glasses for 3D, in order to realize the phase difference of the lens by attaching a lens sheet with a curve formed in different directions to generate a focal length difference (3D special glasses) There is an effect of providing a polarizing film and a 3D display using the 3D optical film that can provide two focal points without having to naturally have a focal length difference of the human eye.

1 is a configuration diagram schematically showing a basic configuration of a polarizing plate
2 is a schematic view showing a wide view type polarizer
Figure 3 (A) is a cross-sectional view schematically showing a polarizing film employing a 3D optical film according to an embodiment of the present invention having a wave pattern, (B) is another embodiment of the present invention having a micro lens pattern Cross-sectional view schematically showing a polarizing film employing a 3D optical film
4 is a cross-sectional view schematically showing a 3D display including a polarizing film employing a 3D optical film according to an embodiment of the present invention
5 is an explanatory diagram showing a change in optical focal length when the X and Y coordinates of the lens are the same when using the 3D display according to the present invention;
FIG. 6 is an explanatory diagram showing a phase difference generating path of light rays in a point light source when the X coordinates are the same and the Y and Z coordinates are different when the 3D display is used according to the present invention.
7 is an explanatory diagram showing a phase difference generating path of light rays in a surface light source when the X coordinates are the same and the Y and Z coordinates are different when the 3D display is used according to the present invention.
8 is an explanatory diagram showing phase difference generation data when X coordinates are the same and Y and Z coordinates are different when the 3D display is used according to the present invention.

Figure 3 (A) is a cross-sectional view schematically showing a polarizing film employing a 3D optical film according to an embodiment of the present invention having a wave pattern, (B) is another embodiment of the present invention having a micro lens pattern It is sectional drawing which shows schematically the polarizing film which employ | adopted 3D optical film.

As shown in FIG. 3 (A), the polarizing film 100 employing the wave-shaped 3D optical film according to the present invention is a first triacetyl cellulose (TAC) film 10, poly having polarization characteristics And a vinyl alcohol (PVA) film 20, a second triacetyl cellulose (TAC) film 30, and a 3D pattern forming film 40. In addition, the 3D pattern forming film 40 is composed of a base film 41 and a wave pattern 42 formed on the base film. Here, the first tricetyl cellulose film 10 and the second triacetyl cellulose film 30 are films for protecting the polarizing film, and have no optical anisotropy and hydrophilicity, thereby discharging moisture present in the polarizing film to the outside. Has the function to In addition, since the polyvinyl alcohol film 20 includes moisture in the interior or exterior, a problem arises that durability is poor, so it is preferable to manufacture a polarizing film employing a 3D optical film in a condition in which moisture is blocked.

In addition, as shown in Figure 3 (B), the polarizing film 200 employing a micro-lens type 3D optical film according to the present invention is a first Triacetyl Cellulose (TAC) film 10, polarization characteristics It comprises a poly vinyl alcohol (PVA) film 20 having a, a second triacetyl cellulose (TAC) film 30 and a pattern forming film 40 for 3D. In addition, the 3D pattern forming film 40 is composed of a base film 41 and the micro lens pattern 43 formed on the base film.

Regarding the shape of the pattern forming film 40 for 3D, the wave pattern and the micro lens pattern have been described in the present specification. However, the shape of the pattern is not necessarily limited thereto, and the structure capable of effectively refracting incident light from the outside. It will be seen that any modification of the pattern shape which can be easily implemented by those skilled in the art by the idea of the present specification among the shapes having the scope of the present invention. In addition, the material of the 3D pattern forming film 40 is not particularly limited because a transparent resin having excellent optical and physicochemical properties can be used.

In addition, the pattern of the 3D pattern-forming film 40 can be configured such that a pattern having the same shape on one surface of the base film 41 is continuously arranged at a predetermined interval. Here, the continuous arrangement of the patterns is in the same direction as the polarization axis. Polarizing film employing the 3D optical film according to the present invention is a functional film layer, such as anti-glare layer (not shown), low reflection and anti-reflection layer (not shown), viewing angle compensation coating layer (not shown) that can prevent glare It can be laminated and included in a predetermined position. In addition, the polarizing film employing the 3D optical film according to the present invention may further include an adhesive layer and a release film on the lower portion of the polarizing film employing the 3D optical film for the purpose of adhesion and protection, and employing the 3D optical film A protective film may be further included on the polarizing film.

4 is a cross-sectional view schematically showing a 3D display including a polarizing film employing a 3D optical film according to an embodiment of the present invention.

As shown in FIG. 4, the 3D display according to the present invention includes an upper 3D optical film formed on an upper surface of a display device including a liquid crystal layer 300, an upper glass layer 310, and a lower glass layer 320. It comprises a polarizing film 110 employing a polarizing film 120 employing a lower 3D optical film formed on the lower surface of the display element. Here, the polarizing film 110 employing the upper 3D optical film is the upper adhesive layer 111 and the upper release film (below) of the polarizing film 110 employing the upper 3D optical film in order to be bonded to the upper glass layer 310. 112) may be further included. In addition, the polarizing film 120 employing the lower 3D optical film has a lower adhesive layer 121 and a lower release film on the upper portion of the polarizing film 120 employing the lower 3D optical film in order to be bonded to the lower glass layer 320. 122) may be further included. The upper adhesive layer 111 and the lower adhesive layer 121 respectively separate the upper release film 112 and the lower release film 122 and attach them to the glass layer.

In the present specification, the TFT-LCD structure has been described with reference to the display device. However, the present invention is not limited thereto, and the polarizing film employing the 3D optical film of the present invention may be applied to various display devices such as PDP, LED, and OLED. It should be understood that it is possible.

5 is an explanatory diagram showing a change in optical focal length when the lens has the same X and Y coordinates when using a 3D display according to the present invention.

As shown in FIG. 5, when the primary lens and the secondary lens are arranged such that the X and Y coordinates are the same and only the Z coordinate is different, the primary focal position is the secondary of the light having a large angle incident on the primary lens. The primary image is formed by condensing by the lens. In addition, the secondary focal position is a light beam having a small angle incident on the primary lens is collected by the secondary lens to form a secondary image. That is, the primary image according to the primary focus position is formed in the right eye of the person, and the secondary image according to the secondary focus position is formed in the left eye of the person.

Therefore, the 3D display according to the present invention can realize a three-dimensional shape because the focal positions of the right eye and the left eye can be formed at different positions without 3D special glasses. For example, the light incident on the primary lens causes the primary focusing position and the secondary focusing position to occur according to the case where a light beam having an angle of less than 20 degrees above and below the Z axis is incident and a light beam having an angle of 20 degrees above and below. do. However, since the angle is only a numerical value based on the experiment, the angle may vary depending on the material and the size of the lens, so the angle corresponds to a factor that can be controlled according to the purpose of use.

6 is an explanatory view showing a phase difference generation path of a light ray in a point light source when the X coordinates are the same and the Y and Z coordinates are different when using the 3D display according to the present invention, and FIG. 7 is the X coordinate when using the 3D display according to the present invention. Is the same, and when the Y and Z coordinates are different, it is explanatory drawing which showed the phase difference generating path | route of the light ray in a surface light source.

As shown in FIGS. 6 and 7, when the lens is in the same X position, and the Y and Z coordinates are changed, the primary focal position is the focal length of the light incident on the primary lens and the light incident on the secondary lens. (Focal length) changes, resulting in a phase difference. In addition, the shape of the lens may be a left-right symmetric lens or an asymmetric lens, and the curvature (Curvature) may be configured to change the focal length. That is, since the phase difference between the light beams in the point light source and the surface light source occurs, the primary focusing position and the secondary focusing position are formed at different positions, thereby enabling 3D stereoscopic image.

8 is an explanatory diagram showing phase difference generation data when X coordinates are the same and Y and Z coordinates are different when the 3D display is used.

As shown in FIG. 8, even when the X coordinates are the same and the Y and Z coordinates are different, the secondary focal position is generated at a relatively high position compared to the primary focal position to form the focal point of the human right eye and the left eye. Differences occur in depth of position. Therefore, even in this case, it is possible to implement a 3D image.

The polarizing film employing the 3D optical film according to the present invention and the 3D display using the same can be manufactured by additionally configuring the pattern film according to the present invention to the existing polarizing film or display products, the manufacturing cost is low, the configuration is simple In addition, since the 3D special glasses are not used, they can be widely applied to 3D displays having excellent compatibility.

10: first TAC film 20: PVA film
30: 2nd TAC film 40: Pattern formation film for 3D
41: base film 42: wave pattern
43: microlens pattern
100: polarizing film using a wave type 3D optical film
110: polarizing film using the upper 3D optical film
111: top adhesive layer
112: upper release film 120: polarizing film employing the lower 3D optical film
121: lower adhesive layer 122: lower release film
200: polarizing film using micro lens type 3D optical film
300: liquid crystal layer 310: upper glass layer
320: lower glass layer

Claims (22)

Display elements;
3D having a structure capable of refracting incident light from the outside on a first triacetyl cellulose (TAC) film, a polyvinyl alcohol (PVA) film having a polarization characteristic, a second triacetyl cellulose (TAC) film on the upper surface of the display device A polarizing film unit employing an upper 3D optical film having a structure in which a dragon pattern forming film is sequentially stacked; And
3D having a structure capable of refracting incident light from the outside on the lower surface of the display device, a first triacetyl cellulose (TAC) film, a polyvinyl alcohol (PVA) film having polarization characteristics, a second triacetyl cellulose (TAC) film A polarizing film unit employing a lower 3D optical film having a structure in which a dragon pattern forming film is sequentially stacked;
3D display comprising a. The 3D pattern forming film of claim 1, wherein the polarizing film portion employing the upper 3D optical film and the polarizing film portion employing the lower 3D optical film comprise: a base film; And
A pattern portion formed on one surface of the base film;
3D display comprising a. The 3D display of claim 2, wherein the pattern portion has a wave shape or a micro lens shape. The 3D display according to claim 2, wherein the pattern portion is formed continuously at predetermined intervals with a pattern having the same shape on one surface of the base film. The 3D display of claim 1, wherein the display device comprises a lower glass layer, a liquid crystal layer, and an upper glass layer. The 3D display according to claim 1, wherein the polarizing film portion employing the upper 3D optical film has an adhesive layer at the bottom, and the polarizing film portion employing the lower 3D optical film has an adhesive layer at the top. According to any one of claims 1 to 6, wherein the 3D display can prevent glare at a predetermined position respectively in the polarizing film portion employing the upper 3D optical film and the polarizing film portion employing the lower 3D optical film. 3D display, characterized in that it further comprises an antiglare layer. According to any one of claims 1 to 6, wherein the 3D display is capable of preventing reflection at a predetermined position of the polarizing film portion employing the upper 3D optical film and the polarizing film portion employing the lower 3D optical film. 3D display, characterized in that it further comprises a low reflection and anti-reflection layer that can prevent glare. The display device of claim 1, wherein the 3D display is capable of compensating a viewing angle at a predetermined position of a polarizing film part employing an upper 3D optical film and a polarizing film part employing a lower 3D optical film. And a viewing angle compensation coating layer. According to claim 2, wherein the polarizing film portion employing the upper 3D optical film and the pattern portion of the polarizing film portion employing the lower 3D optical film is characterized in that at least one coordinate is arranged differently with respect to the X, Y and Z coordinates, respectively. 3D display. The 3D display according to claim 2, wherein the pattern portion of the polarizing film portion employing the upper 3D optical film and the polarizing film portion employing the lower 3D optical film have a symmetric pattern or an asymmetric pattern, respectively. The 3D display according to claim 4, wherein the continuous arrangement of the patterns is arranged in the same direction as the polarization axis. delete delete delete delete delete delete delete delete delete delete

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