KR101035201B1 - Surface Treated Lenticular Sheet - Google Patents

Abstract

The present invention provides a lenticular sheet which is surface-treated to form another lens layer having a minimum thickness without forming a focal length of an adhesive between the transparent sheet and the lenticular sheet having a continuous array convex lens in a line form. It relates to a manufacturing method.

The present invention uses a high-transparent, low refractive adhesive on the focal length adjusting transparent sheet 3 to arrange the first lens layer 1 viewed from the observation surface 7 direction to face the focal length adjusting transparent sheet 3. Applying as a whole, the second lens layer 2 is formed, and a surface such as matt, semi-glow, fine sanding, etc. is selectively applied to the surface 2-2 of the high refractive first lens layer 1 capable of forming this focal length. After the surface treatment with the surface reflectance adjusting layer 4 to form easily, it is formed into an integrated lenticular sheet, and then a computer-wide plane image is applied to the focal plane 3-1 of the lenticular sheet. Composed of a three-dimensional stereoscopic image layer 6 which has undergone the dividing and compression process, the first lens layer 9 of the transparent sheet inherent to the three-dimensional sheet for printing is not exposed to the outside, and the surface reflectance can be adjusted freely. Distance adjustment transparent sheet (3 It relates to a lenticular sheet surface-treated to have a high transparency, high refractive index, high resolution three-dimensional image for printing advertisement that can easily control the viewing angle (11) by) and a method of manufacturing the same.

Solid sheets, lenticulars, adhesives, coatings, solid lenses

Description

Surface Treated Lenticular Sheet

The present invention relates to a three-dimensional lenticular sheet for printing, wherein the transparent sheet is formed to form another lens layer having a minimum thickness without a focal length formed of a lenticular sheet composed of a line-shaped continuous array convex lens and an adhesive. The treated lenticular sheet and its manufacturing method are related.

The three-dimensional implementation method in the three-dimensional sheet for printing advertisements is a semi-spherical shape of the optional line form consisting of a horizontal or vertical curvature radius designed for the purpose of use for the transparent sheet 3 of the transparent resin as shown in Figs. 1A and 1B An emboss in the form of a concave lens is formed in the mold to form the convex lens 9. The mold is used to produce a solid or rigid three-dimensional sheet 100 through a mechanical production process of extrusion, injection, and pressing. Thus produced three-dimensional sheet 100 is made of a suitable thickness to have a suitable visible distance, radius of curvature, refractive index, unit pitch. In this way, the sheet composed of the convex lens 9 on one side forms the three-dimensional image layer 6 directly on its back or through indirect printing.

The printed stereoscopic sheet 100 for advertisement is generally arranged with 5 to 150 convex lenses 9 per inch, and the 3D sheet arranged in this manner is a planar 2D image to be implemented according to the purpose of the observer. Image is divided into two or more frame units by a computer and placed at the lens focal length through printing, digital printing, or photo printing, and then observed as an image such as stereoscopic, conversion, and zoom due to the optical illusion of binocular parallax. You can do it.

Representative disadvantages of the three-dimensional sheet having such a conventional lenticular lens is as follows.

First, because the surface of the convex lens is exposed to the outside, the height of the embossed lens, that is, the reflection of external light at the top and bottom of the hemispherical shape is wrong, which makes the eye easily tired when viewing a stereoscopic image.

Second, due to the surface embossed convex lens, the quality of the video image is inferior, and in particular, the readability is poor for parts such as characters or barcodes.

Thirdly, when printing on the surface part of the convex lens, since it is embossed, the ink does not penetrate evenly as a whole, and thus clean printing is not possible.

Fourthly, it is not possible to adjust the surface gloss or apply external coating to the lens part depending on the intended use.

Fifth, changes in the field of view and refractive index of the lenses produced are not possible after production.

Sixthly, the lenticular lens implemented in three-dimensional lens has a hemispherical embossed lens arranged repeatedly to form a valley between the lens and the lens, and foreign matter easily enters into the valley, and scratches easily occur during removal. do.

Seventhly, due to the productive limitation of the horizontal size, there is a disadvantage that the seam becomes unseen when the large work is connected in the horizontal direction.

In the case of the existing three-dimensional sheet, as shown in FIG. 1B, the curvature radius 10 and the refractive index of the material are determined as lenses having a thickness according to the unit pitch 8. For example, a lens sheet having a viewing angle of 30 degrees or less due to a radius of curvature 10 and a refractive index is a lens for stereoscopic effects, and a lens having a viewing angle of 11 degrees or less is a lens for a stereoscopic effect and a conversion effect. Lenses with a viewing angle of 60 degrees or less are largely classified as conversion lenses. When a lens sheet produced with such a radius of curvature is combined with a sheet having a concave lens having the same refractive index as that of a convex lens, or when surface coating is made of a resin such as epoxy having a high refractive index, the valley of the convex lens is blocked and No role.

Furthermore, there were cases where the reverse coating was used to partially coat the part that should be intentionally prevented from acting as a lens, or to coat the epoxy while protecting the bone of the lens. As a representative prior art thereof, a lenticular lens containing an epoxy resin is disclosed in Registered Utility Model Registration No. 20-0268779.

In addition, Patent No. 632917 is disclosed as a representative publicly known technique for forming and forming a lenticular lens layer by itself by partial embossing so as to selectively use only a portion necessary for lenticular lenses. This patent relates to a three-dimensional sheet partially coated with a lenticular lens layer and a method of manufacturing the same, to create a portion that intentionally does not have a stereoscopic effect in the lenticular lens with respect to the lenticular lens layer. However, this method does not visually express the shape of the lens when it is observed from the surface by completely filling the valley of the lens with respect to the entire lens, and cannot be said to improve the inherent effect of the lenticular lens. To form a three-dimensional layer in the focal length layer below the convex lens portion.

In addition, in some optical lenses, the refractive index of the microlens of Patent No. 185598 is a representative prior art that performs surface treatment with the convex lens facing upward in the form for adjusting the refractive index and concentrates the image on the focal length layer opposite to the convex lens. Twill control device is disclosed. The patent eliminates the need to protect the convex lens and the valleys between the lenses.

That is, as shown in FIG. 1B, an unillustrated resin layer having an adhesive function having a refractive index of 1% to 13% lower than that of the lenticular lens has a focal length plane (3-) on the top surface of the convex lens layer 1-1. In consideration of 1), it is uniformly applied throughout and adhered to and integrated with the transparent sheet 3 for adjusting the focal length, thereby making the convex lens 9 formed in the form of an emboss visually invisible and improving the color development of expressing a three-dimensional image. In addition, the visible angle of view and the three-dimensional effect can be improved. However, in order to meet the conditions for improving the extreme effect, the three-dimensional sheet 100 is low on the surface convex lens 9 portion of the three-dimensional sheet produced at the angle of view and thickness that is suited to the appropriate thickness generally produced as described above. If the focal length is applied after applying the refractive adhesive, the thickness of the three-dimensional sheet becomes extremely thick, which is not only a price increase factor of the lens, but also loses its value as a popular product.

Moreover, since the lenticular lens sheet is accompanied by the production of the appropriate thickness adjusted to the focal length, it is more expensive to produce the same amount as the conventional three-dimensional sheet. For example, if a 20-line lenticular lens has a thickness of 2.3 mm and a specification of 1200 mm * 2400 mm, it is possible to produce about 5 pieces if the product is produced with a minimum thickness of forming only one convex lens as the quantity to be produced normally. When the viewing angle 11 of the three-dimensional lens is 49 degrees and the lens is formed in an array structure of 30 pieces per inch, and the material is PET and the adhesive coating treatment is performed on the three-dimensional sheet having a thickness of about 1.3 mm, the thickness of the final three-dimensional sheet is Is normal stereo focal formation at about 6.5 mm. That is, if the thickness of the flat lens visually concealed the convex lens is 6.5 mm compared to 1.3 mm of the existing block lens protruding from the surface of the convex lens 9 will not have marketability even if the quality is improved.

Therefore, preferably, the lenticular sheet should be designed in a manner other than the design of a lens having a normal curvature radius and thickness in the design process.

In order to solve the above problems, the present invention not only maintains the inherent function of the three-dimensional sheet, but also makes the convex lens of the three-dimensional sheet visually invisible and makes it possible to observe the three-dimensional image in a planar portion, so that the image expression effect is relatively. It is a main object to provide a surface-treated lenticular sheet and a method for producing the same for stereoscopic advertising and stereoscopic printing for improving.

Another object of the present invention is a lenticular sheet which is surface-treated to form another lens layer having a minimum thickness without forming a focal length made of a lenticular sheet composed of a continuous array of convex lenses in a line form and an adhesive, and It is to provide a manufacturing method thereof.

Another object of the present invention is to direct the lenticular sheet protruding outward from the observation plane toward the focal plane when the stereoscopic observation, and to apply another low refractive adhesive layer to the transparent sheet for adjusting the focal length with respect to the convex lens layer. An object of the present invention is to provide a lenticular sheet and a method of manufacturing the same by forming a focal length adjusting layer on the lenticular sheet.

The present invention is applied entirely on the transparent sheet 3 using a high-transparent, low-refractive adhesive on the transparent sheet 3 so that the first lens layer 1 seen in the direction of the observation surface 7 faces the focusing distance adjusting transparent lens 3. To easily form a surface such as matte, semi-light, fine sanding, etc. on the lens surface 2-2 of the high refractive lens layer 1 capable of forming a focal length of the second lens layer 2 formed of an adhesive layer. After the surface treatment with the surface reflectivity adjustment adjusting layer 4 to form a single sheet of lenticular sheet, the image of the unit of the plane on the focal plane 3-1 of the lenticular sheet is computer-generated. The three-dimensional stereoscopic image layer 6, which has undergone the dividing and compression process, can be configured so that the first lens layer 1 of the lenticular sheet inherent to the three-dimensional printing sheet can be exposed to the outside, and the surface reflectivity can be adjusted freely. Can and seconds Distance adjustment transparent sheet (3), each (11) controlled easily printed advertising high transparency, high refractive index, surface treated to have a three-dimensional image of high resolution which may have a visualized by the lenticular sheet and a process for their preparation.

The present invention forms a hemispherical first lens layer formed on the three-dimensional sheet, for example, a second lens layer consisting of a convex lens layer and an adhesive layer, so that the lens layers are not visually visible, and the adjustment layer and the release film are selected thereon. It is possible to adjust the thickness of the transparent sheet for adjusting the focal length by changing the viewing angle divided into conversion, three-dimensional use, etc. at the same time by freely adjusting the surface reflectivity.

Accordingly, it is easy to improve the transparency of the three-dimensional sheet and adjust the viewing angle, the surface is clean, the surface strength is improved, and the reflection angle of the surface is easily adjusted, thereby improving the expression effect, and there is no distinction between top, bottom, left and right. The three-dimensional sheet will be made. In addition, by providing an illuminating device on the back of the three-dimensional image formed on the focal plane at a predetermined focal length with respect to the lenticular sheet thus produced, the color development and three-dimensionality of the image can be further improved.

The present invention will be described in detail with reference to the accompanying drawings.

As shown in Figs. 2A and 2B and Fig. 3, a first embodiment according to the present invention is illustrated. The three-dimensional sheet 20, which is a lenticular lens, includes a transparent sheet 3, which is arranged on the transparent sheet 3 so as to face the first lens layer 1 viewed from the viewing surface 7 direction. The second lens layer 2 is formed by applying it as a whole using the refractive adhesive. On the second lens layer 2, a surface such as matte, semi-light, fine sanding, etc. is easily formed on the lens surface 2-2 of the high refractive first lens layer 1, which can form a focal length. Surface treatment is performed with the surface reflectance adjusting liquid so as to be integrated into the adjusting layer 4.

The transparent sheet 3 is formed with a focal plane 3-1 of the convex lens, and the focal plane 3-1 has a three-dimensional three-dimensional image which is subjected to the image segmentation and compression process of a plane-based image through a computer. Image layers 6 to be formed are adjacent to each other.

In addition, an additional concave portion 5 is formed on the left and right side surfaces of the first lens layer 1. The concave portion 5 forms the first lens layer 1 or the focal length in the process of forming the second lens layer 2 by applying an adhesive liquid between the transparent sheet 3 and the first lens layer 1. The left and right ends of the transparent sheet 3 allow the adhesive liquid pushed out by pressure.

The first lens layer 1 has a predetermined radius of curvature 10 and a second lens layer 2 is formed with a minimum thickness around the arc of the arc, and the light is refracted from the first lens layer 1 and enters the incident light. It functions to diffract by changing direction.

In FIG. 4, another 2nd Example is shown, the same code | symbol is attached | subjected to the component same as 1st Example, and the detailed description is abbreviate | omitted here. In this embodiment, the three-dimensional sheet 20 forms the adjustment layer 4 with the surface reflectance adjusting liquid when selective curing for gloss and surface reflectance adjustment is required for the surface 2-2 of the first lens layer 2. And a release film 4-1 serving as a protective layer thereon.

In FIG. 5, another 3rd Example is shown, the same code | symbol is attached | subjected to the component same as 1st Example, and the detailed description is abbreviate | omitted here. In this embodiment, the three-dimensional sheet 20 has a printing layer 12 on the first lens layer 1. To this end, the surface of the first lens layer 1 is directly or indirectly printed on the surface of the first lens layer 1 by concave plate printing or convex plate printing through printing methods such as stencil printing, flat plate printing, live-print printing, and the like. The coating layer 12-1 is formed.

6 shows another third embodiment, in which the same components as those in the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted here. In this embodiment, the three-dimensional sheet 20 has a three-dimensional image layer 6 on the focal plane 3-1, and the image layer 6 for observing this image is in a smooth state with the surface smooth. Therefore, by forming the anti-slip layer 13 on the back side of the image layer 6, it is possible to cope with the three-dimensional optical mouse pad, and various fields together with the adjustment layer 4 and the release film 4-1 for adjusting the surface reflectance. A wider range of products can be produced.

7 shows another fourth embodiment, in which the same components as those in the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted here. As described above, the three-dimensional sheet 20 according to the present invention inverts the convex lens seen from the observation surface 7 when the three-dimensional observation, and adjusts the focal length and the first lens layer 1 facing downward. Between the transparent sheets 3 having one focal plane 3-1, an adhesive layer 2 integrated with a low low refractive adhesive liquid is formed. On this adhesive layer 2, the adjustment layer 4 and / or the peeling film 4-1 are formed, and it is set as the structure which adjusts surface reflectance. In this embodiment, the color development and the three-dimensional effect of the image can be further improved by placing the illumination device 14 on the back surface of the three-dimensional image layer 6 formed on the focal plane 3-1, which becomes the focal length layer with respect to the sheet thus produced. It becomes possible.

8 shows lens layers arranged differently. As described above, a separate concave portion 5 extends on the left and right side surfaces of the first lens layer 1. Convex lens portions 15, 16, and 17 that form three different first lens layers are formed with respect to the concave portion 5. That is, in the case of the lenticular lens formed of the hemispherical convex lens portion 15 in the form of a 90-degree array line, the human eye recognizes the stereoscopic effect on the left and right stereoscopic constitutions while the stereoscopic effect is recognized on the upper and lower stereoscopic constitutions. Do not let it. As such, the convex lens portion 16 having an array structure inclined at 45 degrees vertically rather than a straight line results in equalizing the image compression of the stereoscopic image 45 degrees with respect to the focal plane that becomes the stereoscopic focal length, thereby distinguishing the top, bottom, left, and right sides. It becomes a lenticular lens without. In addition, in the case of a lenticular lens made of a semispherical convex lens unit 17 which is made completely vertical and has an array line of 180 degrees, the human eye cannot recognize the three-dimensional constitution of the left and right, while the upper and lower three-dimensional constitution are not recognized. Recognize steric effects Therefore, the convex lens portions 15, 16 and 17 can be selectively used.

9 shows a method for producing a three-dimensional sheet according to the present invention. The transparent sheet 3 is continuously moved and supplied on the conveyor 30. As the transparent sheet 3 is moved, the adhesive liquid is first applied to the upper surface thereof by a spray nozzle 41 of the adhesive liquid supplier 40 to form a second lens layer 2. Then, the convex first lens layer 1 is positioned on the second lens layer 2 by the lens sheet feeder 50. The reflectance adjusting liquid supplier 42 for adjusting the surface reflectivity is applied to the first lens layer 1 by a predetermined thickness through the nozzle 43 to form the adjusting layer 4. To this end, first and second pressure rollers 60 and 61 are installed in pairs adjacent to the nozzle 43 at regular intervals, and the first and second pressure rollers 60 and 61 are installed. On top of each of them, the supply roller 70 for supplying the thin film 4-1 and the peeling roller 71, which can be installed to remove the thin film 4-1, are installed to interlock with each other. In addition, a curing machine 80 is provided adjacent to the first pressure roller 60 so that the second lens layer 2, the first lens layer, the adjustment layer 4, and the release film 4-1 by the adhesive are formed. At the same time performs a curing function to be bonded.

That is, the first and second pressure rollers 60 and 61 rotate at a uniform speed until the transparent sheet 3 starts to be supplied and is discharged to the three-dimensional sheet 20 through an integration process. In this state, the transparent sheet 3 is in a state where the adhesive liquid is applied by the thin film liquid nozzle part 41 to be applied to the entire surface, and the lens sheet is supplied by the lens feeder 50 thereon, so that the first lens It consists of the layer 1, and the adjustment liquid is apply | coated by the refractive index adjustment liquid supply 43 on the lens surface 2-2 of this 1st lens layer 1, and the adjustment layer 4 is formed. The lenticular sheet layered in this way has a second lens layer (2), a first lens layer (1), an adjustment layer (1) on the transparent sheet (3) via the first pressure roller (61) and the curing machine (80) in turn. 4) to complete the three-dimensional sheet 20 integrating the thin film (4-1). On the other hand, the adhesive liquid that has reached the first pressure roller 60 is coated on the transparent sheet 3 under a constant pressure to be coated with the low refractive second lens layer 2 and not remain as the second lens layer 2. The adhesive liquid is guided to the grooves of the recesses 5 at the left and right ends of the first lens layer 1 to be recovered.

On the other hand, the 2nd thin film 4-1 for glossiness and reflectance adjustment which adhered to the upper surface of the adjustment layer 4 can be isolate | separated by the peeling roller 71. FIG.

Therefore, the adhesive layer has a lower refractive index than the three-dimensional sheet, is highly transparent, easily adjusts the refractive index, hardly deforms during the adhesion and coating process to the three-dimensional lens, and is a high transparency, low refractive adhesive that can be cured in a short time. Since the UV adhesive is applied evenly between the transparent sheet and the lens layer with a minimum thickness, one or more thin film films for adjusting the focal length are selectively adhered to, for example, a film made of UV resin. The three-dimensional sheet is made to be invisible from the surface. The thin film 4-1 for reflectance adjustment, which has a surface in the form of glossy, matte, semi-gloss and has no adhesive force, is coated on the adjustment layer 4 and then peeled off again if necessary. It is possible to adjust the reflectance, i.e., glossiness.

As described above, the embodiment of the present invention has been described, but the above description does not limit the scope of the present invention, and should be interpreted as an example of a more preferred embodiment, and the scope of the present invention should be defined by the technical spirit described in the claims. will be

1A and 1B are views showing the relationship between the refractive index and the viewing angle of a lenticular sheet, which is a part of the overall sectional view of a conventional convex lenticular sheet,

2A and 2B are cross-sectional views of a three-dimensional lens integrated with a lenticular sheet of a first lens layer and a second lens layer and a part of a lenticular sheet according to a first embodiment of the present invention;

3 is an exploded perspective view showing an exploded state of the three-dimensional sheet according to the principle of the first embodiment of the present invention;

4 is a cross-sectional view showing a structure according to a second embodiment of the present invention;

5 is a cross-sectional view showing a structure according to a third embodiment of the present invention;

6 is a cross-sectional view showing a structure according to a fourth embodiment of the present invention;

7 is a cross-sectional view showing a structure according to a second embodiment of the present invention;

8 is a perspective view showing a method of arranging a plurality of convex lenses of a lenticular sheet according to the principles of the present invention;

9 is a schematic process diagram showing a method of manufacturing a lenticular sheet in accordance with the principles of the present invention.

          <Explanation of symbols for the main parts of the drawings>

1: first lens layer 2: second lens layer

2-2: lens surface 3: transparent sheet

3-1: focal plane 4: adjustment layer

4-1: release film 5: recessed portion

6 image layer 7 observation surface

9 convex lens 10 radius of curvature

11: visible angle 12: printed layer

12-1: protective layer 13: non-slip layer

14 lighting device 15 90 degree array convex lens

16: 45 degree array convex 17: 0 degree array convex

40: adhesive liquid feeder 50: lens sheet feeder

42: adjusting liquid supply 60, 61: pressure roller

Claims (7)

delete In the lenticular sheet formed of a transparent sheet 3 made of a transparent material and a lens layer provided on the upper surface of the transparent sheet 3, A first lens layer 1 facing the viewing distance direction and facing the transparent sheet 3 for adjusting the focal length, A second lens layer 2 formed by coating the whole of the first lens layer 1 and the transparent sheet 3 using a high transparency and low refractive adhesive; Surface reflectance adjustment is integrated in the second lens layer 2 by surface treatment with matt, semi-light, fine sanding, etc. on the lens surface 2-2 of the high refractive first lens layer 1 which can form a focal length. Adjusting layer (4), On the focal plane 3-1 of the lens layers formed on the transparent sheet 3, an image layer 6 in which a plane image through a computer is formed into a three-dimensional image through image segmentation and compression in units of frames. and The first lens layer 1 is composed of recesses 5 formed separately from the left and right sides thereof, In order to adjust the gloss and surface reflectance of the surface 2-2 of the first lens layer 1, the adjustment layer 4 formed by surface treatment with the surface reflectance adjusting liquid and the thin film 4-1 optionally installed are A surface treated lenticular sheet. delete delete delete delete delete

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