RU215864U1 - STICKER - Google Patents

Abstract

The utility model relates to the production of stickers with a pseudo-volumetric (3D, stereoscopic) image. A sticker with a pseudo-volume image is proposed, which is a complementary pair of layers of a thin transparent self-adhesive material with a printed image and implies the application of one layer on the front and the other on the back side of a transparent planar surface. The layer applied to the front surface consists of a plurality of lenses printed on the material in a certain order with a programmable focal length of each lens, given by the thickness of the flat transparent surface on which the sticker is applied. The layer applied to the back side is characterized by the fact that it consists of a printed full-color image in which there are two types of patterns in the form of predetermined regularly repeated unprinted microelements. The first pattern, when combined with the layer of the front side, exhibits on it a pre-predicted moiré effect, the pattern of which determines the virtual depth of the pseudo-volumetric image, and the second pattern, rotated relative to the first at an angle of 45 degrees and located within the boundaries of the contour of the geometric figure of an alphabetic or digital sign, forms on On the front layer, there is a hidden additional pseudo-volumetric image of this geometric figure, and this effect is visible when illuminated from both the front and back sides. The utility model provides an extension of the options for a printed image with an increased value of the virtual depth of a pseudo-volumetric image, including a hidden one, for its application on flat transparent surfaces with combined illumination. 6 ill.

Description

The utility model relates to the production of stickers with a pseudo-volumetric (3D, stereoscopic) image.

State of the art

A sticker is a type of paper or plastic that is sticky on one side and usually has a design on the other, and is used for decoration and/or information, as the case may be. This offer applies to stickers on flat transparent surfaces (mainly glass), such as car windows, shop windows, office and other partitions, glass doors.

The creation of pseudo-volumetric images enhances the imagery of the sticker design. Moreover, a greater effect of pseudo-volume perception is observed when the foreground image shifts relative to the background image when the observation point changes. For example, this can be achieved by printing on lenticular lenses with special preparation of the printed file (patent US 6751024 B1). This effect is noticeable when the observation point is moved perpendicular to the direction of the parallel row of lenses. Also, there is no illusion of distance between foreground and background images.

In the prior art, a method is known to obtain an "auto stereo image" visible without the requirement of special glasses (Yutaka Igarashi, Hiroshi Murata, Mitsuhiro Ueda (1978) 3-D Display System Using a Computer Generated Integral Photograph. Japanese Journal of Applied Physics, vol. 17, number 9, p. 1683). An integral image consists of a huge number of microimages (patterns) that are viewed by an observer through an array of spherical convex "objective lenses", one "objective" for each microimage. Moreover, spherical lenses are on one side of a flat transparent material, and microimages are on the opposite side. Strict requirements for spherical lenses: their centers must be strictly located at the same distance from each other (at the corners of a regular triangle or square) and have the same focal length equal to the thickness of the transparent flat material on the surface of which they are formed. A layer of special hexagonal spherical lenses is usually formed on the surface of a thin sheet of polyester or polypropylene (MicroLux™ fly's-eye lens), or printed. Thus, patent RU 2526682 shows a method for forming a lens layer by screen printing.

In all these variants, the formed lenses are integral with a flat transparent material, on the reverse side of which certain printing procedures are carried out (usually printing a pattern and a layer of white) to form a three-dimensional image. The focal length of the lenses during their formation is chosen equal to the thickness of the flat transparent material. The three-dimensionality of the image formed in this way, in contrast to the lenticular one, is observed inside a solid angle of at least 90 degrees perpendicular to the plane of the lens layer, remaining clear and readable. And, what is very important, it is well distinguishable for people with monocular vision. The virtual depth of a pseudo-volumetric image depends on several factors and can be an order of magnitude greater than the real thickness of a flat transparent material.

Traditional stickers, due to their consumer properties, usually have a thickness of fractions of a millimeter. If you make a sticker with a pseudo-volumetric image on a material of similar thickness, a well-read virtual image depth will be observed no more than 10 mm, and when you try to increase it, the objects will “blur” (the image will become blurry). This is clearly visible when the observer is either in close proximity to it, or at a distance of up to 1.2 meters. The described principles for creating a pseudo-volumetric image make it possible to manufacture products with a virtual depth of several (up to 10 or more) centimeters. In this case, the pseudo-volumetric image will be distinguishable already at distances of 2-5 meters or more, but this requires the use of a transparent material of several millimeters, which limits their use in this capacity.

The technical solution for creating stickers with pseudo-volume images with increased information content of the printed image - an increased value of the virtual depth of the pseudo-volume image for use on flat transparent surfaces is given in patent RU 188364. refrigerators, and others. Typically, these transparent surfaces have a thickness of 3 to 8 mm.

The essence of this solution lies in the fact that a sticker with a pseudo-volumetric image is a complementary pair of layers of a thin transparent self-adhesive material with a printed image. The layer applied to the front surface of the transparent material consists of a plurality of lenses printed in a certain order on the material with a programmable focal length of each lens determined by the thickness of the flat transparent material on which the sticker is applied. The layer applied to the back side consists of printed objects of any shape (pattern), and applied in such an order that, when combined with the front side layer, a predictable moiré effect appears, the pattern of which determines the virtual depth of the pseudo-volumetric image. Moreover, the pseudo-volume effect is formed in the volume of the transparent material directly under the image on the front surface, configured by the geometry of the location of the printed lenses and limited by the back side with a printed pattern.

The considered technical solution has a number of limitations. So, the pattern is usually printed in dark tones on a light / white background for contrast. This makes it possible to clearly see the considered pseudo-volume effect in reflected light when the light is incident from the face layer side. But the solution (quote) "... can be implemented in display windows, transparent partitions and doors of premises, on doors in commercial refrigerators ...", where there may be (and sometimes necessary) internal illumination, and in intensity comparable or even superior external. In this case, the "dark" printed pattern is ineffective for creating a pseudo-volume effect.

The essence of the proposal

The objective of the claimed utility model is to expand the options for a printed image with an increased value of the virtual depth of a pseudo-volumetric image, including a hidden one, for its application on flat transparent surfaces with combined illumination.

The technical result consists in the fact that the sticker is a complementary pair of layers of thin (fractions of mm) transparent self-adhesive material with a printed image and implies the application of one layer on the front and the other on the back side of the transparent flat surface, while the layer applied to the front surface , consists of a plurality of lenses printed on a material in a certain order with a programmable focal length of each lens, a given thickness of a flat transparent surface on which the sticker is applied, and the layer applied to the back side is characterized by the fact that it consists of a printed full-color image in which there are two types of patterns in the form of given regularly repeating unprinted microelements, and the first pattern, when combined with the front side layer, exhibits a pre-predicted moiré effect on it, the pattern of which determines the virtual depth of the pseudo-volumetric image, and the second pattern, turn 45 degrees relative to the first one and located within the boundaries of the contour of the geometric figure of an alphabetic or digital sign, forms a hidden additional pseudo-volumetric image of this geometric figure on the front layer.

The technical result is provided by the design and technological features of the implementation of the variants of the stickers described below, and the methods for their manufacture.

The proposal is illustrated with examples of performance and photographs (figure 1 and 2).

The formation of the front layer with microlenses is carried out mainly by screen printing. In the same layer, an image that is supposed to be "raised" can also be formed.

A full-color image is applied to the back layer of the sticker, where the “role” of the printed pattern is played by regularly located unprinted microelements (“holes” in the image) in the area of the printed background (Fig. 1, Fig. 1.1). An enlarged fragment of a rectangular shape of this image, marked with a line, is shown in Fig. 1.2 (fig.1). Figure 1.3 (fig.1) shows a photo of the sticker assembly (with an intermediate glass of 5 mm). Full-color alphanumeric characters seem to “float” above the plane of the pattern, which is clearly visible both with binocular and monocular vision, even with a slight change in the angle of view. Moreover, this effect is visible under illumination both from the front and from the back.

Figure 2.1 (fig.2) shows a photo of a full-color image, completely “covered” with unprinted microelements. Figure 2.2 (fig.2) shows a rectangular fragment of this image in an enlarged (more than 3 times) form. You can see that in the peripheral area of this image, the pattern (unprinted elements) is identical to that shown in Figure 1.1 (Figure 1). In the central area of the image, within the boundaries of the virtual letter figures 10, the pattern is rotated relative to the original at an angle of 45 degrees, which is clearly seen in Figure 2.2 (Figure 2). Figure 2.3 (fig.2) shows a photo from the side of the lens layer of the sticker assembly. The difference between the two areas of patterns is clearly visible. The first, located in the peripheral area and "synchronized" with the focal length of the lenses, is observed in a significantly enlarged form, and in the second area of the pattern (within the boundaries of letter-sign figures), the elements look much smaller and more frequent, and "hidden" letter figures are easily "read" . They also look “raised” above the plane of the original pattern and are visible both with binocular and monocular vision even with a slight change in the angle of view, and with illumination both from the front and from the back.

Thus, the problem of the claimed utility model is solved - the variants of the printed image with an increased value of the virtual depth of the pseudo-volumetric image, including the hidden one, are expanded for its application on flat transparent surfaces with combined illumination.

Claims (1)

A sticker with a pseudo-volumetric image, which is a complementary pair of layers of a thin transparent self-adhesive material with a printed image and involves applying one layer to the front and the other to the back side of a transparent planar surface, while the layer applied to the front surface consists of a plurality of printed lenses on the material in a certain order with a programmable focal length of each lens, a given thickness of a flat transparent surface on which the sticker is applied, and the layer applied to the back side is characterized by the fact that it consists of a printed full-color image in which there are two types of patterns in the form of given regularly repeating unprinted microelements, and the first pattern, when combined with the layer of the front side, exhibits on it a pre-predicted moiré effect, the pattern of which determines the virtual depth of the pseudo-volumetric image, and the second pattern, rotated relative to The first one at an angle of 45 degrees and located within the boundaries of the contour of the geometric figure of an alphabetic or digital sign, forms on the front layer a hidden additional pseudo-volumetric image of this geometric figure, and this effect is visible when illuminated from both the front and back sides.

Images