KR20050048726A - Method for manufacturing lenticular plastic sheets - Google Patents

Abstract

The present invention relates to a three-dimensional plastic sheet and a method for manufacturing the same, and more particularly, a semi-circular convex lens or a hemispherical convex lens is arranged on the surface of the plastic sheet to view a three-dimensional image. The present invention relates to a stereoscopic sheet configured to recognize a special character or a fine character such as a barcode, and to enable stereoscopic expression of only a specific part of a three-dimensional plastic sheet.

The characteristics of the present invention described above, made of a transparent synthetic resin, the upper surface is formed in a semi-circular or hemispherical convex lens 11 is formed in an arrangement, the transparent ink resin layer 20 on a portion of the upper surface of the block lens 11 A convex lens layer 10 formed thereon; It is formed of a transparent synthetic resin plate material having a thickness corresponding to the focal length of the convex lens 11, the bottom surface by a three-dimensional plastic sheet, characterized in that the transparent plate 30, the focal length printed layer 40 is formed is sequentially stacked It can be achieved.

Description

Three-dimensional plastic sheet having a transparent window and a method for manufacturing the same {Method for manufacturing lenticular plastic sheets}

The present invention relates to a three-dimensional plastic sheet, and more particularly, a semi-cylindrical or hemispherical convex lens is arranged on the surface of the plastic sheet to view a three-dimensional image as well as special characters such as barcodes or fine The present invention relates to a three-dimensional plastic sheet configured to allow a character to be recognized by a sensor and to partially display any specific portion of the three-dimensional plastic sheet.

The above-described three-dimensional method has a configuration in which semi-cylindrical or hemispherical lenses having a constant pitch on the front surface of the sheet are continuously formed in an array of regular intervals. I) Record and print the image of the object on one sheet plate, and look at the front of the sheet with both eyes to see the three-dimensional image of the object floating or entering the space.

Mainly this method is a three-dimensional method produced by a continuous lens sheet by plastic molding, the sheet is a transparent material, the printing surface calculated according to the arrangement of the lens three-dimensional by human binocular disparity when viewed from the front of the lens This is how it works.

However, these methods have some problems in the commercialization of three-dimensional objects.

First, these three-dimensional fabric sheets are not high resolution like normal printing due to the embossed surface of the lens type, and thus cannot provide clear and clean prints.

In other words, when printing a printed material on one side of the three-dimensional fabric sheet in the printing of elaborate and dataized special characters such as a barcode, a failure occurs that is not recognized at all by the terminal that recognizes the barcode. This is because the embossed surface refracts light.

Secondly, these stereoscopic sheets are formed on the embossed surface formed on one surface of the sheet due to their morphological characteristics, that is, small lenses having a constant bone shape in the lenticular method and small radial convex lenses in the integral method. When viewed from the canal, it is seen as an opaque material due to the refraction of light.

For example, if the box is made of such a three-dimensional sheet, the part to be three-dimensional can be seen by the printing surface expressing the three-dimensional, but in order to make the contents inside the box intentionally visible, it is necessary to cut a portion of the sheet even if it is a transparent material. You have no choice but to produce an incomplete product.

Third, in this three-dimensional plastic sheet, due to the valley shape of the semi-circular or hemispherical convex lens, sometimes a normal sticker or hologram sticker, which is necessary for a product, is very difficult to attach to the front surface of the lens.

Therefore, the present invention provides a manufacturing method of a three-dimensional image sheet that can be mass-produced by combining plastic molding technology and advanced printing technology, and when printing a special character such as a barcode on such sheets, a machine such as a barcode recognizer When reading the printed matter through the sheet, it can be recognized normally, there is no problem in recognizing the fine letters as well, it is easy to attach stickers on the front of the sheet, and the part of the sheet is made transparent. There is this.

The present invention has been made to solve the above problems, the object of which is that the semi-circular or hemispherical convex lenses are arranged on the surface of the plastic sheet to view stereoscopic images, as well as special characters such as barcodes or fine It is to provide a high-quality three-dimensional plastic sheet and a method of manufacturing the same to enable the recognition of the characters in the sensor, to make the three-dimensional plastic sheet partially transparent, and to be able to stereoscopic representation of any specific part.

A feature of the present invention for achieving the above object is made of a transparent synthetic resin, the upper surface is formed in a semi-circular or hemispherical convex lens 11 is formed in an arrangement, the transparent portion of the upper surface of the convex lens 11 A convex lens layer 10 on which an ink resin layer 20 is formed; The three-dimensional plastic sheet is formed of a transparent synthetic resin plate material having a thickness corresponding to the focal length of the convex lens 11, and the bottom surface thereof is laminated and bonded to the transparent plate 30 having the focal length print layer 40 in turn. It can be achieved by.

Hereinafter, described in detail by the accompanying drawings a preferred embodiment for achieving the above object is as follows.

As shown in Fig. 1 or 4, the convex lens layer 10 is formed on the uppermost side of the three-dimensional card 1 according to the present invention. The convex lens layer 10 is formed by forming a transparent synthetic resin on the upper surface thereof. The semi-circular convex lenses 11 are arranged in an arrangement in which they are spread at regular intervals.

A part of the upper surface of the convex lenses 11 arranged on the upper surface of the convex lens layer 10 is formed with a see-through window made of a transparent ink resin layer 20, so that a small letter printed with a picture is clearly displayed or a hologram is displayed. The sticker can be attached.

On the bottom of the same position of the transparent ink resin layer 20, a non-focal printing surface 41 is formed as a part of the focal length printing layer 40, and the non-focal printing surface 41 is provided with information related to the manufacturer. Consists of pictures, letters. The image of the non-focal print surface 41 belongs to a range that does not exhibit a three-dimensional effect or a special effect, and is composed of special characters such as pictures, characters, or barcodes that represent photorealistic images with vivid image quality.

When printing a special character such as a bar code on this area, the effect of the convex lens disappears because of the transparent ink resin layer 20 interposed between the convex lenses 11, and thus the refraction of light generated from the convex lens disappears. Therefore, it is possible to print the fine characters that could not be expressed due to the characteristics of the conventional three-dimensional sheet, or to print a special character that can recognize the barcode sensor.

A transparent plate 30 made of a transparent synthetic resin is positioned below the convex lens layer 10, and the thickness of the transparent plate 30 is equal to the focal length of the convex lens 11.

The bottom surface of the transparent plate 30 has the same spacing arrangement as that of the convex lens layer 10, and a three-dimensional printing surface 42 having a calculated graphic shape for expressing a three-dimensional effect is formed on the focal length printing layer 40. It is.

However, in the printing positioned on the focal length printed layer 40, it is difficult to express the fine microprinting. The reason is that the three-dimensional sheet for expressing the three-dimensional surface of the convex lens 11 and the binocular parallax due to human binocular parallax due to the characteristics of the three-dimensional feeling, the convex lens of the convex lens is always convex lens resolution in the related feeling This is because the density of array spacing of (10) or more cannot be expressed.

That is, no matter how high-resolution printing is printed on the focal length print layer 40 on the bottom surface of the convex lens layer 10, a three-dimensional sheet (for example, can only be seen through the refracted convex lens layer 10 of light). The resolution of 1) can never see more than the arrangement density of the convex lens layer 10.

Therefore, the convex lens layer 10, the transparent ink resin layer 20, the transparent plate 30, and the focal length printing layer 40 are sequentially stacked to complete the three-dimensional sheet 1.

The three-dimensional card (1) having the above-described configuration, by the transparent ink resin layer 20 located on the upper surface of the convex lens layer 10 and the non-focal printing surface 41 can be seen through the various information related to the manufacturer or Text and pictures can be seen clearly. At the same time, the picture printing surface having the same tendency as the convex lens spacing of the three-dimensional sheet, that is, the three-dimensional printing surface 42 of the focal length printing layer 40 is larger than the depth of the transparent plate 30 due to the convex lens effect and binocular parallax. A stereoscopic effect such as a figure or pattern floating deeper or above the surface of the convex lens layer 10 can be obtained in contrast to the non-focus printing surface 41 which can clearly and precisely observe.

Therefore, such stereoscopic expression has the advantage of providing a high-quality stereoscopic card that has both a stereoscopic feeling not seen in a conventional stereoscopic sheet and at the same time, a functionality that can simultaneously carry functions such as a barcode.

The manufacturing process of the three-dimensional sheet 1 according to the present invention is as follows. Forming a transparent ink resin layer 20 by printing the upper surface of the convex lens layer 10 formed of a flat plate; Forming a focal length printed layer 40 by printing on the bottom of the transparent plate 30 made of a transparent synthetic resin: non-focus printing surface on the focal length printed layer 40 at the same position as the transparent ink resin layer 20 41 is formed; It is achieved by a three-dimensional plastic sheet and a method for manufacturing the same, characterized in that the laminated convex lens layer 10 is formed on the transparent ink resin layer 20, the transparent plate 30 formed with the focal length printing layer 40 is sequentially laminated. It can be.

Hereinafter, the embodiment according to the above-described manufacturing method will be described in detail.

Example

The transparent synthetic resin was printed on the upper surface of the convex lens layer 10 formed of a flat plate with transparent ink and then dried. Then, the transparent ink resin layer 20 was formed on the upper surface of the convex lens layer 10.

Subsequently, the bottom surface of the transparent plate 30 made of transparent synthetic resin was printed and dried to form a focal length print layer 40.

The three-dimensional printing surface 42 of the focal length printing layer 40 is a printing surface having the same alignment interval tendency as that of the convex lens layer 10, and the image printing surface can see a three-dimensional image.

At the same time, a bar code or fine printing was performed on the non-focus printing surface 41 of the focal length printing layer 40 located at the same position as the transparent ink resin layer 20, thereby obtaining a clear and sensory print.

Subsequently, as shown in FIGS. 3A and 3B, two transparent ink resin layers 20 are formed on the front surface of the box made of a three-dimensional sheet, and a bar code is placed on one non-focused printing surface 41 located on the bottom surface thereof. When printing a special character such as a clear high-resolution prints were obtained, another non-focused printing surface 41 was not printed on the product contents 50 inside the box could be transparently observed.

Subsequently, when the hologram 90 or sticker of the manufacturer was attached to the top surface of the transparent ink resin layer 20 on the surface of the three-dimensional sheet 1 according to the type of the product, firm adhesion was possible.

In addition, the process of attaching the printed matter or the synthetic resin material 60, etc. according to the use of the product at the bottom of the three-dimensional sheet (1) was to be further included, so that the three-dimensional sheet (1) can be used for more various purposes

3A and 3B, the three-dimensional sheet 1 is composed of a semi-circular convex lens 11 of a lenticular method and a hemispherical convex lens 11-1 of an integral method, as shown in FIGS. It can be produced as a three-dimensional sheet (1), and the thickness is not only formed differently depending on the type and use, as the focal length is formed differently depending on the size of the convex lens 11, eventually convex lens layer 10 and transparent Since the thickness of the plate 30 is to be adjusted, the thicknesses of the materials are not accurately indicated.

Although the preferred embodiments of the present invention have been illustrated and described above, the present invention is not limited to the above-described embodiments, and the present invention is not limited to the above-described embodiments without departing from the spirit of the present invention as claimed in the claims. Various modifications may be made by those skilled in the art, and such modifications are intended to fall within the scope of the appended claims.

As described above, the three-dimensional sheet 1 of the present invention is a non-focal printing surface of the transparent ink resin layer 20 printed on the upper surface of the convex lens layer 10 and the ultra-short distance printing layer 40 seen through the same. Various information printed on (41) can be clearly seen by the characters and pictures deviated from the refraction of the light of the convex lens (11), enabling sensor-sensitive printing such as bar codes, and at the same time the focal length printed layer (40). The three-dimensional printing surface 42 of) may be floating above the surface of the three-dimensional or convex lens layer 10 such that a figure or a pattern is placed deeper than the depth of the transparent plate 30 by the convex lens 11 effect. By the three-dimensional effect of the figures, not only can obtain a three-dimensional contrast with the non-focus printing surface 41 that appears clearly, the transparent ink resin layer 20 serves as a transparent window, is formed on the convex lens layer 10 at the same time Transparent or fine text It can be observed without refraction of the light of the convex lens 11, easy to work when attaching the hologram sticker 90, etc., and can satisfy the purchase desire of modern consumers who pursue a variety of designs. There is an advantage such as to provide a high quality three-dimensional sheet.

1 is an exploded perspective view illustrating an embodiment of a three-dimensional plastic sheet according to the present invention;

2 is a cross-sectional view of FIG.

Figure 3a is a view showing the commercialization effect of the lenticular three-dimensional plastic sheet according to the present invention,

Figure 3b is a view showing the effect of commercializing the integral three-dimensional plastic sheet according to the present invention,

Figure 4 is an exploded perspective view illustrating an embodiment in an integral manner in the three-dimensional plastic sheet according to the present invention,

Explanation of symbols on the main parts of the drawings

1: solid sheet 10: semi-circular convex lens layer

10-1: hemispherical block lens layer 11: semi-circular convex lens

11-1: hemispherical convex lens 14: focus forming angle of the convex lens

20: transparent ink resin layer 30: transparent plate

40: focal length printing layer 41: non-focus printing surface

42: three-dimensional printing surface 50: the contents of the box

60: printed matter or synthetic resin attachment

90: sticker

Claims (4)

Convex lens layer 10 formed of a transparent synthetic resin, the upper surface of the semi-circular or hemispherical convex lens 11 is formed in an arrangement, the upper surface is a transparent ink resin layer 20; It is formed of a transparent synthetic resin plate material having a thickness corresponding to the focal length of the convex lens (11), the bottom of the three-dimensional plastic sheet, characterized in that the transparent plate 30 is formed with the focal length printed layer 40 is laminated in sequence. The planar viewing window formed of the transparent ink resin layer 20 is formed on a part of the convex lenses 11 arranged on the top surface of the convex lens layer 10 so as to sharpen special characters or fine characters such as barcodes. Or a sticker such as a hologram 90 can be attached. The three-dimensional plastic sheet according to claim 1, wherein a printed matter or a synthetic resin (60) is attached to the lower surface of the three-dimensional plastic sheet (1). Forming a transparent ink resin layer 20 by printing the upper surface of the convex lens layer 10 formed of a flat plate; Forming a focal length printed layer 40 by printing on the bottom of the transparent plate 30 made of a transparent synthetic resin: non-focus printing surface on the focal length printed layer 40 at the same position as the transparent ink resin layer 20 41 is formed; A three-dimensional plastic sheet and a method of manufacturing the same, comprising a laminate of a convex lens layer 10 on which the transparent ink resin layer 20 is formed, and a transparent plate 30 on which the focal length printing layer 40 is formed.