KR101897964B1 - 3d display device interchangeable 2d and 3d images - Google Patents

Abstract

A 3D display device capable of two-dimensional and three-dimensional conversion is disclosed. A 3D display device capable of two-dimensional and three-dimensional conversion is provided. The 3D display device includes: a 3D sheet part, a real image display part provided apart from the 3D sheet part, and a transparency intervening between the 3D sheet part and the real image display part, And a control unit.

Description

TECHNICAL FIELD [0001] The present invention relates to a 3D display device capable of two-dimensional and three-dimensional conversion,

The present invention relates to a 3D display device capable of two-dimensional and three-dimensional conversion, and more particularly, to a 3D display device capable of two-dimensional and three-dimensional conversion will be.

In general, in order to produce a transparent three-dimensional sheet exhibiting a visual three-dimensional effect, a lenticular lens sheet and an intergral photography technique have been used conventionally, and a three- A printing pattern is formed on the lower portion of the lens using an analog printing method or a digital printing method, and a stereoscopic effect is realized through the lens

On the other hand, Korean Patent Laid-Open No. 10-2008-0105704 (published on Dec. 4, 2008) discloses "a stereoscopic image sheet structure and a manufacturing method thereof ".

In general, a 3D sheet converts a 2D image into a 3D image to implement only a 3D image. Therefore, the entire area of the image is always displayed, which is monotonous and can not implement various contents. Therefore, it needs to be improved.

The present invention has been made in view of the above-mentioned need, and it is an object of the present invention to provide an image processing apparatus and a 3D image processing method, in which a 2D image and a 3D image are switched by applying a transparency control unit, And a display device.

According to an aspect of the present invention, there is provided a 3D display device capable of two-dimensional and three-dimensional conversion, comprising: a 3D sheet part; a real image display part provided apart from the 3D sheet part; And a transparency control unit interlocked with the power source and varying transparency.

The 3D sheet portion may include a convex lens portion having a predetermined pattern structure of the convex lens, a transparent portion provided below the convex lens portion and having a thickness corresponding to the focal distance of the convex lens, And a stereoscopic printing unit provided at a lower portion of the transparent portion and provided at the upper portion of the convex lens portion and configured to have the same pattern angle and arrangement as the convex lens portion.

The 3D sheet portion may include a convex lens portion having a convex lens having a predetermined pattern structure, a transparent portion provided below the convex lens portion and having a thickness corresponding to the focal distance of the convex lens, A stereoscopic printing unit provided at the same pattern angle and arrangement as the convex lens unit, and an actual transparent printing unit provided on at least one of the auxiliary transparent unit provided on the convex lens unit and the auxiliary transparent unit, .

The 3D sheet portion may include a composite lens portion including a convex lens having a predetermined pattern structure and a partially transparent window, a transparent portion provided below the composite lens portion and having a thickness corresponding to the focal distance of the convex lens, And a composite printing unit provided at a lower portion of the transparent portion and including a stereoscopic printing unit formed to correspond to the convex lens and a real image printing unit corresponding to the transparent window.

The 3D sheet part may include a pure 3D sheet part and a real image printing part provided on at least one of the upper part and the lower part of the pure 3D sheet part.

The real image display unit may be at least one of a transparent image panel and a real image printing sheet.

Further, an electrification film is provided between the real image display section and the transparency control section.

In addition, a 2D white print unit corresponding to the real image printing unit is further provided in the lower portion of the real image printing unit to increase the stereoscopic effect.

In addition, a 2D gradation unit is further provided on the lower portion of the 2D white print unit to increase the stereoscopic effect.

Further, the stereoscopic printing unit is characterized in that it is printed in a four-degree (C, M, Y, K) primary color process or a spot color.

Further, a white silk printing unit is provided below the stereoscopic printing unit.

According to another aspect of the present invention, there is provided a 3D display device capable of two-dimensional and three-dimensional conversion, comprising: a convex lens portion having a predetermined pattern structure; a real image display portion provided below the convex lens portion; A transparency control unit provided between the real image display unit and the real image printing unit, the transparency control unit being interlocked with the power source and varying the transparency of the image, And a stereoscopic printing unit having the same pattern angle and arrangement as the convex lens unit.

The real image display unit may be at least one of a transparent image panel and a real image printing sheet.

In addition, a 2D white print unit corresponding to the real image printing unit is further provided in the lower portion of the real image printing unit to increase the stereoscopic effect.

In addition, a 2D gradation unit is further provided on the lower portion of the 2D white print unit to increase the stereoscopic effect.

Further, the stereoscopic printing unit is characterized in that it is printed in a four-degree (C, M, Y, K) primary color process or a spot color.

Further, a white silk printing unit is provided below the stereoscopic printing unit.

The 3D display device capable of two-dimensional and three-dimensional conversion according to the present invention has a effect of implementing various contents by switching a 2D image and a 3D image by applying a transparency control unit that changes the transparency by interworking with a power source.

In addition, the present invention has the effect of reducing the moiré phenomenon of the 3D sheet portion, reducing the fatigue of the eyes that can be seen in ordinary 3D images, and expressing stereoscopic effect even in the up and down directions.

Further, since the present invention does not need to precisely focus the lens and the print layer like a lenticular method, the loss rate due to defects disappears, and the productivity is improved at low cost.

In addition, the present invention can realize a dynamic 3D image by adopting a transparent image panel as a real-life display unit, and can be used as a general monitor, so that it can be used for various purposes.

1 is an exploded perspective view showing a 3D display device capable of two-dimensional and three-dimensional conversion according to the first embodiment of the present invention,
FIG. 2 is a sectional view showing a 3D display device capable of two-dimensional and three-dimensional conversion according to the first embodiment of the present invention;
3 and 4 are views showing a convex lens pattern of a 3D display device capable of two-dimensional and three-dimensional conversion according to the first embodiment of the present invention,
5 to 9 are views showing a modification of the 3D display device capable of two-dimensional and three-dimensional conversion according to the first embodiment of the present invention,
10 is a cross-sectional view illustrating a 3D display device capable of two-dimensional and three-dimensional conversion according to a second embodiment of the present invention.

Hereinafter, an embodiment of a 3D display device capable of two-dimensional and three-dimensional conversion according to the present invention will be described with reference to the accompanying drawings. In this process, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, the terms described below are defined in consideration of the functions of the present invention, which may vary depending on the intention or custom of the user, the operator. Therefore, definitions of these terms should be made based on the contents throughout this specification.

FIG. 1 is an exploded perspective view showing a 3D display device capable of two-dimensional and three-dimensional conversion according to a first embodiment of the present invention. FIG. 2 is a perspective view illustrating a 3D FIGS. 3 and 4 are views showing a convex lens pattern of a 3D display device capable of two-dimensional and three-dimensional conversion according to the first embodiment of the present invention, and FIGS. 5 to 9 are cross- Dimensional and three-dimensional conversion according to the first embodiment of the present invention.

1 to 4, a 3D display device 100 capable of two-dimensional and three-dimensional conversion according to the first embodiment of the present invention includes a 3D sheet unit 110, a real image display unit 150, and a transparency control unit 160 ).

The 3D display device 100 capable of two-dimensional and three-dimensional conversion according to the first embodiment of the present invention may stack the 3D sheet part 110, the real image display part 150 and the transparency control part 160 in the vertical direction And can be laminated in various directions such as lamination in the left-right direction, but they are laminated in the vertical direction for convenience of explanation.

The 3D sheet portion 110 includes a convex lens portion 112 having a predetermined pattern structure on the front surface of the convex lens 113 and a convex lens portion 112 provided on the bottom of the convex lens portion 112 and corresponding to the focal distance of the convex lens 113 A real image printing section 116 provided on the transparent section 114 and a pattern structure having the same pattern structure as that of the convex lens section 112 provided below the transparent section 114 And a stereoscopic printing unit 118 composed of an array.

The convex lens part 112 is made of a transparent synthetic resin, and the convex lens 113 can be arranged in various shapes such as a hemispherical shape, and can be arranged longitudinally, laterally, or radially. 3, the crossing angle of the hypothetical line passing through the center of the convex lens 113 is 90 degrees, and the inclination of the convex lens 113 is 45 degrees , Or a pattern in which the intersection angle of imaginary lines passing through the center of the convex lens 113 is 60 degrees and the inclination of the convex lens 113 is 60 degrees as shown in Fig. 4 is preferable.

The real image printing portion 116 is formed by offset printing on the upper surface of the transparent portion 114. [ The real image printing unit 116 is represented by a picture to be a subject, a photograph of a product, and various patterns.

The stereoscopic printing unit 118 is formed on the lower surface of the transparent part 114 and is mainly used for expressing stereoscopic or special effects of the upper, lower, left, and right continuous patterns. That is, the real image printing section 116 is located at the non-focal distance of the convex lens 113, and the stereoscopic printing section 118 is located at the focal distance of the convex lens 113. Therefore, the stereoscopic printing unit 118 and the real image printing unit 116 can simultaneously provide the depth sense, the surface feeling, and the protruding feeling. At this time, the stereoscopic printing unit 118 is printed in the primary color 4-degree (C, M, Y, K) process or a spot color, and is produced by computer graphics image separation. In the image segmentation process, the left and right lenticular image segmentation methods and the upper and lower lenticular image segmentation methods are simultaneously executed to obtain an output image. That is, the separated images are arranged in both the vertical and horizontal directions, considering the parallax of the right and left eyes.

The convex lens part 112, the real image printing part 116, the transparent part 114 and the three-dimensional printing part 118 constituting the 3D sheet part 110 are thermally adhered by a laminating operation or adhered to each other by an adhesive .

The real image display unit 150 is provided apart from the 3D sheet unit 110. The real image display unit 150 is provided on the 3D sheet unit 110 and is formed in the same manner as the real image printing unit 116 so that the depth of real image printing can be felt. In one embodiment, the real image display unit 150 is at least one of a transparent image panel and a real image printing sheet.

When a real-life print sheet is applied, a static 3D image can be implemented, and when a transparent image panel is applied, a dynamic 3D image can be implemented.

Transparent image panels can be applied to various panels such as transparent LCD panels, transparent LED panels, and OLED panels.

The transparency control unit 160 is provided between the 3D sheet unit 110 and the real image display unit 150, and changes the transparency of the 3D sheet unit 110 in conjunction with the power source. In the present embodiment, a polymer dispersed liquid crystal (PDLC) is described as an example of the transparency controller 160 that operates in a transparent or opaque manner in conjunction with a power source. However, the present invention is not limited thereto, The present invention is not limited to the above embodiments and various changes and modifications may be made without departing from the scope of the present invention.

9, when the real image display unit 150 is a transparent image panel, a charging film 155 may be further provided between the real image display unit 150 and the transparency control unit 160. [ This charging film 155 can prevent the real image display unit 150 made of a transparent image film and the transparency controller 160 from adhering to each other.

In the present embodiment, the transparency controller 160 is a dual polymer dispersed liquid crystal panel, in which a transparent conductive film is formed on a pair of substrates, liquid crystal molecules become irregular when there is no polymer voltage between the substrates, Scattering occurs to maintain the opaque state, and when a voltage is applied, the directions of the liquid crystals are aligned, and the refractive indexes of the liquid crystals coincide with each other to maintain a transparent state. That is, in a polymer dispersed liquid crystal layer, liquid crystal molecules become irregular in the absence of a voltage, and scattering occurs at an interface (interface) where the refractive index with the medium is different to maintain the opaque state. When voltage is applied, The refractive index is matched and the transparent state is maintained. Therefore, since the real image display unit 150 is provided on the upper part of the transparency controller 160 and the 3D sheet unit 110 is provided on the lower part, the 2D image and the 3D image are switched according to transparency or opacity of the transparency controller 160 .

5 to 9, a 3D sheet portion 110 is provided on the upper surface of the convex lens portion 112 so as to have the same stereoscopic effect as the 3D sheet portion 110, Can be obtained. This requires high-level printing because of the convexity of the convex lens 113 formed on the front surface of the convex lens portion 112.

6 and 7 complement the 3D sheet part 110 shown in FIG. 5. The 3D sheet part 120 includes a convex lens part 122 having a certain pattern structure and a convex lens part 122 having a predetermined pattern structure, A transparent portion 124 provided at a lower portion of the transparent portion 124 and having a thickness corresponding to the focal distance of the convex lens 123, And the auxiliary transparent part 129 and the auxiliary transparent part 129 provided on the upper part of the convex lens part 122. The auxiliary transparent part 129 and the sub- And a real image printing unit 126.

The auxiliary transparent portion 129 is provided on the upper portion of the convex lens portion 122 so that the real printed portion 126 can be easily formed and the actual printed portion 126 ) To form the same three-dimensional feeling.

8, the 3D sheet portion 130 includes a composite lens portion 132 having a convex lens 132a having a predetermined pattern structure and a partially transparent view window 132b, A transparent portion 134 provided at a lower portion of the transparent portion 132 and formed at a thickness corresponding to the focal distance of the convex lens 132a and a concave portion 132 formed at a lower portion of the transparent portion 134 and corresponding to the convex lens 132a And a composite printing unit 136 including a printing unit 136b and a real printing unit 136a corresponding to the viewing window 132b. The composite printing unit 136 can increase the printing efficiency by forming the stereoscopic printing unit 136b and the real printing unit 136a together and can realize a clearer image even if the real printing unit 136a includes fine characters or graphics. . With this configuration, it is possible to solve the problem that the resolution is lowered due to the interference caused by the refraction of the light of the convex lens 132a even if the resolution of the real printing portion 136a is high. At this time, the viewing window 132b of the compound lens unit 132 can be formed by applying a transparent resin to the convex lens 132a and curing it, which does not limit the processing method of the viewing window 132b.

9, the 3D sheet part 140 includes a real printing part 146 provided on at least one of the upper part or the lower part of the pure 3D sheet part 142 and the pure 3D sheet part 142 do. In this embodiment, the case where the pure 3D sheet portion 142 is formed by extruding a convex lens having a predetermined pattern structure will be described as an example.

The Pure 3D sheet portion 142 is formed by extruding a polypropylene sheet (PP Sheet) shaped into a convex lens, and a deep feeling can be felt even in a single sheet. The real image printing unit 146 is printed on at least one of the front surface and the back surface of the pure 3D sheet unit 142 to feel a relative depth feeling according to the pattern. In the present embodiment, the polypropylene sheet is extruded to form the pure 3D sheet portion 142. However, the present invention is not limited thereto, and various modifications such as acrylic may be used.

As described above, the 3D sheet units 110, 120, 130 and 140 can be variously modified. A transparency control unit 160 is provided on the 3D sheet units 110, 120, 130 and 140 and a real image display unit 150 is provided on the transparency control unit 160. The transparency control unit 160 is transparent or opaque, And 3D images can be switched.

9, when the real image display unit 150 is formed of a transparent image panel, a charging film 155 is provided between the real image display unit 150 and the transparency control unit 160, Can be prevented. Although the configuration of the charging film 155 is shown in FIG. 9 only, it can be similarly applied to a modification to which the present invention can be applied.

In addition, as shown in FIG. 9, a light unit 195 is provided on the back surface of the 3D sheet part 140, and the same can be applied to the modified examples. The light unit 195 provides light to the 3D sheet units 110, 120, 130 and 140 and may be a Diffuser, a Light Guide Panel (LGP), a Back Light Unit (BLU), an LED, or the like.

A 2D white printing unit 170 corresponding to the actual printing units 116, 126, 136a, and 146 is further provided under the actual printing units 116, 126, 136a, and 146 to increase the stereoscopic effect, Can be made clearer.

Further, a 2D gradation unit 180 is provided under the 2D white print unit 170 to increase the stereoscopic effect.

In addition, the white silk printing unit 190 is provided under the three-dimensional printing units 118, 128, and 136b to improve the sharpness of the three-dimensional printing units 118, 128, and 136b.

10 is a cross-sectional view illustrating a 3D display device capable of two-dimensional and three-dimensional conversion according to a second embodiment of the present invention.

For the sake of convenience of description, detailed description of the same components as those of the first embodiment will be omitted.

A 3D display device 200 capable of two-dimensional and three-dimensional conversion according to the second embodiment of the present invention includes a convex lens part 210 having a certain pattern structure, a convex lens part 210 having a convex lens part 212 having a constant pattern structure, A real image printing unit 230 provided at a lower portion of the real image display unit 220 and a real image printing unit 230 provided between the real image display unit 220 and the real image printing unit 230, A transparent control unit 240 and a transparency control unit 240. The transparent control unit 240 and the convex lens unit 210 are disposed at a distance corresponding to the focal distance of the convex lens 212, And a stereoscopic printing unit 250 for forming a stereoscopic image.

The 3D display device 200 capable of two-dimensional and three-dimensional conversion according to the second embodiment is provided with a transparency control unit 160 inside the 3D sheet units 110, 120 and 130 of the first embodiment, Structure.

That is, a transparency control unit 240 is provided between the real image display unit 220 and the real image printing unit 230, and the transparency control unit 240 is formed to have a thickness corresponding to the focal distance of the convex lens 212.

As described above, since the transparent portion can be removed, the entire thickness can be reduced.

As in the first embodiment, the 2D white printing unit 260 corresponding to the real image printing unit 230 is further provided below the real image printing unit 230 to increase the stereoscopic effect and make the real image printing clearer .

A 2D gradation unit 270 is provided below the 2D white printing unit 260 to increase the stereoscopic effect and a white silk printing unit 280 is provided below the stereoscopic printing unit 250 to form a stereoscopic printing unit 250 can be improved.

The operation of the 3D display device capable of two-dimensional and three-dimensional conversion according to an embodiment of the present invention having the above-described structure will now be described.

The 3D sheet portions 110, 120 and 130 are provided with actual print portions 116, 126 and 136a at the non-focal distances of the convex lenses 113, 123 and 132a, and stereoscopic print portions 118, 128 and 136b at the focal lengths of the convex lenses 113, The three-dimensional printing unit 118, 128, and 136b) is printed in a primary color 4-degree (C, M, Y, K) process or a spot color so that a visually disturbing moire ) Phenomenon can be minimized.

Alternatively, the 3D sheet part 140 may include a pure 3D sheet part 142 and a real printing part 146 provided on the front surface or the rear surface of the 3D sheet part 140, so that even a single sheet of paper can feel a sense of depth.

A real image display unit 150 is provided above the 3D sheet units 110, 120, 130 and 140 and a transparency control unit 160 interposed between the real image display unit 150 and the 3D sheet units 110, 120, When the transparency control unit 160 is transparent, the 3D sheet units 110, 120, 130 and 140 and the real image display unit 150 implement a 3D image. When the transparency control unit 160 is opaque, the 3D sheet units 110, 120, And the 2D image of the real image display unit 150 is implemented by the control unit 160.

In this case, a static 3D image can be implemented when the real image print sheet is applied to the real image display unit 150, and a dynamic 3D image can be realized when the transparent image panel is applied. When the transparency control unit 160 is opaque, It can also be used as a monitor.

In addition, when the real image display unit 150 is a transparent image panel, a charging film 155 may be provided between the real image display unit 150 and the transparency control unit 160 to prevent them from sticking together.

As described above, the 3D display device 100 is capable of two-dimensional and three-dimensional conversion by the operation of the transparency controller 160, thereby realizing various contents.

The 2D white printing unit 170 and the 2D gradation unit 180 are provided in the lower part of the real image display unit 150 to provide a feeling of depth of the stereoscopic image. Not only sharpness but also stereoscopic effect can be increased.

In addition, the white silk printing unit 190 is provided under the three-dimensional printing units 118, 128, and 136b to increase the stereoscopic effect.

As shown in FIG. 10, in the 3D display device 200 capable of two-dimensional and three-dimensional conversion according to the second embodiment of the present invention, the transparency controller 240 The stereoscopic printing unit 250 is positioned at the focal distance according to the thickness of the PDLC unit 240 and thus the 2D image and the 3D image are switched by the transparent or opaque operation by the transparency control unit 240 But also has a remarkable effect of reducing the thickness.

The 2D white printing unit 260 and the 2D gradation unit 270 are provided on the rear side of the real printing unit 230 which is the lower side of the real image display unit 220 to increase the stereoscopic effect as well as the sharpness of the actual printing, A white silk printing unit 280 is provided below the stereoscopic printing unit 250 to increase the stereoscopic effect.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. will be.

Accordingly, the true scope of protection of the present invention should be defined by the claims.

100, 200: 3D display device 110, 120, 130, 140:
112, 122, 210: convex lens parts 113, 123, 132a, 212:
114, 124, 134: Transparent portions 116, 126, 136a, 146, 230:
118, 128, 136b, 250: stereoscopic printing unit 129: auxiliary transparent part
132: composite lens unit 132b:
150, 220: Actual display part 160, 240: Transparency control part
170, 260: 2D white printing unit 180, 270: 2D gradation unit
190, 280: white silk printing unit 195: light unit

Claims (17)

delete 3D sheet part;
A real image display unit provided separately from the 3D sheet unit; And
A transparency control unit provided between the 3D sheet unit and the real image display unit, the transparency control unit being interlocked with a power source and varying transparency; Lt; / RTI >
The 3D sheet portion may include a convex lens portion having a convex lens having a predetermined pattern structure, a transparent portion provided below the convex lens portion and having a thickness corresponding to the focal distance of the convex lens, And a stereoscopic printing unit provided at a lower portion of the transparent unit and having a pattern angle and an arrangement identical to those of the convex lens unit,
A 2D white printing unit corresponding to the real printing unit is provided on the lower portion of the real printing unit to increase the stereoscopic effect,
A 2D gradient unit is provided below the 2D white print unit to increase the stereoscopic effect,
The stereoscopic printing unit is printed in a primary color 4-degree (C, M, Y, K) process or a spot color,
The actual printing portion is located at a non-focal distance of the convex lens, the stereoscopic printing portion is located at a focal distance of the convex lens,
Wherein the transparency control unit implements the 3D image by the action of the 3D sheet unit and the real image display unit when the transparency control unit is transparent and implements the 2D image of the real image display unit by blocking the 3D sheet unit when the transparency control unit is opaque. 3D display device capable of dimensional conversion.
3D sheet part;
A real image display unit provided separately from the 3D sheet unit; And
A transparency control unit provided between the 3D sheet unit and the real image display unit, the transparency control unit being interlocked with a power source and varying transparency; Lt; / RTI >
The 3D sheet portion may include a convex lens portion having a convex lens having a predetermined pattern structure, a transparent portion provided below the convex lens portion and having a thickness corresponding to the focal distance of the convex lens, A stereoscopic printing unit configured to have the same pattern angle and arrangement as the convex lens unit; and an imitation printing unit provided on at least one of the auxiliary transparent unit provided on the convex lens unit and the auxiliary transparent unit, ,
A 2D white printing unit corresponding to the real printing unit is provided on the lower portion of the real printing unit to increase the stereoscopic effect,
A 2D gradient unit is provided below the 2D white print unit to increase the stereoscopic effect,
The stereoscopic printing unit is printed in a primary color 4-degree (C, M, Y, K) process or a spot color,
The actual printing portion is located at a non-focal distance of the convex lens, the stereoscopic printing portion is located at a focal distance of the convex lens,
Wherein the transparency control unit implements the 3D image by the action of the 3D sheet unit and the real image display unit when the transparency control unit is transparent and implements the 2D image of the real image display unit by blocking the 3D sheet unit when the transparency control unit is opaque. 3D display device capable of dimensional conversion.
3D sheet part;
A real image display unit provided separately from the 3D sheet unit; And
A transparency control unit provided between the 3D sheet unit and the real image display unit, the transparency control unit being interlocked with a power source and varying transparency; Lt; / RTI >
The 3D sheet portion may include a convex lens portion having a convex lens having a predetermined pattern structure, a transparent portion provided below the convex lens portion and having a thickness corresponding to the focal distance of the convex lens, A stereoscopic printing unit configured to have the same pattern angle and arrangement as the convex lens unit; and an imitation printing unit provided on at least one of the auxiliary transparent unit provided on the convex lens unit and the auxiliary transparent unit, ,
A 2D white printing unit corresponding to the real printing unit is provided on the lower portion of the real printing unit to increase the stereoscopic effect,
A 2D gradient unit is provided below the 2D white print unit to increase the stereoscopic effect,
The stereoscopic printing unit is printed in a primary color 4-degree (C, M, Y, K) process or a spot color,
The actual printing portion is located at a non-focal distance of the convex lens, the stereoscopic printing portion is located at a focal distance of the convex lens,
Wherein the transparency control unit implements the 3D image by the action of the 3D sheet unit and the real image display unit when the transparency control unit is transparent and implements the 2D image of the real image display unit by blocking the 3D sheet unit when the transparency control unit is opaque. 3D display device capable of dimensional conversion.
delete 5. The method according to any one of claims 2 to 4,
Wherein the real image display unit is at least one of a transparent image panel and a real image printing sheet.
The method according to claim 6,
And a charging film is further provided between the real image display unit and the transparency control unit.
delete delete delete 5. The method according to any one of claims 2 to 4,
And a white silk printing unit is provided at a lower portion of the stereoscopic printing unit.
A convex lens part in which the convex lens has a constant pattern structure;
A real image display unit provided below the convex lens unit;
A real image printing unit provided below the actual image display unit;
A transparency control unit provided between the real image display unit and the real image printing unit, the transparency control unit interchanging the transparency with the power source; And
And a stereoscopic printing unit disposed at a lower portion of the transparency control unit at a distance corresponding to the focal length of the convex lens, the stereoscopic printing unit having the same pattern angle and arrangement as the convex lens unit,
A 2D white printing unit corresponding to the real printing unit is provided on the lower portion of the real printing unit to increase the stereoscopic effect,
A 2D gradient unit is provided below the 2D white print unit to increase the stereoscopic effect,
The stereoscopic printing unit is printed in a primary color 4-degree (C, M, Y, K) process or a spot color,
The actual printing portion is located at a non-focal distance of the convex lens, the stereoscopic printing portion is located at a focal distance of the convex lens,
Wherein the transparency control unit implements a 3D image by the action of the convex lens unit and the real image display unit when the transparency control unit is transparent and implements a 2D image of the real image display unit by blocking the convex lens unit when the transparency control unit is opaque. A 3D display device capable of three-dimensional conversion.
13. The method of claim 12,
Wherein the real image display unit is at least one of a transparent image panel and a real image printing sheet.
delete delete delete 13. The method of claim 12,
And a white silk printing unit is further provided at a lower portion of the stereoscopic printing unit.

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