PL243927B1 - Optically variable spacial element and method for producing the optically variable spacial element - Google Patents

Abstract

The subject of the application is a three-dimensional optically variable element and a method of producing a three-dimensional optically variable element. An optically variable three-dimensional element containing a sheet of lenticular foil with a lenticular image compatible with lenticular lenses applied to its flat side, characterized in that the element has a surface with convex and/or concave areas (2) made in the process of thermoforming the sheet of lenticular foil with the lenticular image applied .

Description

Description of the invention

The subject of the invention is a three-dimensional, non-planar optically variable element and a method of producing a three-dimensional, non-planar optically variable element.

Various types of optically variable elements are known. Most often, these are flat elements with a print containing a specially prepared lenticular image under transparent lenticular (lenticular) foil, usually in the form of business cards, stickers, posters or labels. Lenticular foil contains longitudinal semi-circular (or semi-oval) lenses arranged in a row, one next to the other, which cause different parts of the image to be visible depending on the angle at which the image is viewed through the lens (this is called the spatial effect). In order to obtain the correct view of the lenticular image, the dimensions of the lenticular lenses (in particular the radius and height) are selected according to the parameters of the lenticular image, so that the lenses are compatible with the image.

Optically variable elements are usually produced by sticking a lenticular foil made in a separate technological process onto a lenticular image printed on a substrate in one technological process. This type of action is quite complicated and expensive.

There are known methods of integrating the process of producing lenticular foil with the process of combining the foil with a substrate with a lenticular image in the injection process. For example, a method for obtaining packaging with a label with a spatial effect is known from Polish patent application No. 385696. The packaging is produced by injection molding, where a monolithic material with light transmitting properties is injected into a matrix consisting of two parts. On the piston of one part of the matrix there is a label containing a lenticular image, consistent with the seat of the other part of the matrix, which contains a parallel series of longitudinal grooves with a cylindrical outline. The package produced in this way has the shape of a cylinder, and on the surface of the side wall of this package there are lenticular lenses running perpendicular to its base.

However, this type of process is quite expensive due to the high costs of making an injection mold and the high costs of machinery (injection molding machines), especially for large-sized elements.

It would be advisable to develop an alternative form of optically variable elements, as well as a method of their production, to enable even wider use of this type of elements, especially as spatial (in other words: non-flat, three-dimensional) decorative elements of large sizes.

The subject of the invention is a three-dimensional, non-planar optically variable element containing a processed sheet of lenticular foil with a lenticular image compatible with the lenticular matrix of the lenticular foil applied to its flat side, characterized by the fact that the element has a surface with convex and/or concave areas whose height is significantly greater than the height of the lenses in the lenticular matrix, made in the process of processing by thermoforming a previously prepared flat sheet of lenticular foil with a lenticular image placed on it.

Preferably, a transparent protective layer is placed on the surface of the lens matrix of the lenticular lens sheet.

Preferably, there is an opaque security layer on the lenticular image print layer.

Preferably, the lenticular image contains component images that have a uniform single-color fill.

Preferably, the spatial element is a wall covering.

The subject of the invention is also a method of producing a three-dimensional, non-planar optically variable element from a sheet of lenticular foil with a lenticular image compatible with the lenticular matrix of the lenticular foil applied to its flat side, characterized by the following steps: preparing the lenticular image; a lenticular image is applied to a sheet of lenticular foil; Convex and/or concave areas are formed in a sheet of lenticular foil with a lenticular image in the thermoforming process.

Preferably, a lenticular image is prepared in accordance with the expected deformation values of the lens matrix in the process of thermoforming the convex and/or concave areas.

Preferably, after applying a lenticular image to a sheet of lenticular foil, the sheet of lenticular foil is laminated with a transparent protective layer on the side of the lenticular matrix.

Preferably, after applying a lenticular image to a sheet of lenticular foil, the sheet of lenticular foil is laminated with an opaque protective layer on the flat side.

The subject of the invention is presented in an embodiment in the drawing, in which:

Fig. 1a-1d show three-dimensional, non-planar elements optically variable (at different angles);

Figs. 2a-2f show the components of a three-dimensional, non-planar optically variable element made by the method according to the invention;

Fig. 3 shows the subsequent steps of the method for producing a three-dimensional, non-planar optically variable element.

Figs. 1a-1d show embodiments of a three-dimensional, non-planar optically variable element according to the invention. The surface of this element contains convex and/or concave areas on which there is a lenticular image covered with lenticular foil with lenses (in the form of a lenticular matrix) compatible with this image. Methods of matching lens parameters to image parameters so that they are mutually compatible are known from the state of the art and do not require further explanation.

This type of three-dimensional, non-planar optically variable element can be used in particular for architectural applications, for example as wall or ceiling cladding, outdoors or indoors.

The elements shown in Fig. 1a-1d are three-dimensional elements, i.e. non-planar, three-dimensional elements. These elements have a base 1 (the edges of which are preferably located on a flat surface) within which protrusions 2 are formed. The protrusions may have the form of any geometric solid, in particular a pyramid.

The element shown in Fig. 1a has a base 1, the edges of which form a triangle outline, and the protrusions 2 have the shape of a regular pyramid with a triangular base.

The element shown in Fig. 1b has a base whose edges form a hexagonal outline, and the protrusions have the shape of a truncated pyramid with a hexagonal base.

The element shown in Fig. 1c has a base whose edges form a rectangular outline, and the protrusions have the shape of four polyhedra with a sharp upper edge, formed within the base.

The element shown in Fig. 1d has a base whose edges form a triangle outline, and the protrusions have the shape of six polyhedra with flat upper surfaces formed within the base.

As shown in Fig. 1a-1d by different shades of color of the side walls of the elements, the visibility of individual surfaces of the convexity of the spatial element is different because the viewing angle at a given surface is different. Unlike elements with a flat surface (in which visibility varies only due to chiaroscuro), in the element according to the invention the lenticular lenses influence the area of the lenticular image that is visible from a given viewing angle.

For example, when the elements according to the invention are installed as a wall cladding, in such a way that the entire wall is covered with adjacent elements, the visibility of individual walls of individual elements will be different because the viewing angle between the observer and a given surface is different. Moreover, this visibility will change as the observer moves. In this way, it is possible to obtain a wall covering whose appearance changes as the observer moves along the wall.

Figs. 2a-2f show the components of a three-dimensional, non-planar optically variable element manufactured by the method according to the invention shown in Fig. 3.

In the first step 101 of the interlacing process, a lenticular image is prepared from two different component images.

Fig. 2a shows exemplary pairs 10, 20 of component images 10a, 10b, 20a, 20b used to create a lenticular image.

Component images may have a uniform, single-color fill and differ only in color (10a, 10b). In such a case, the color of the spatial element changes depending on the angle at which this element is viewed.

The component images may contain various graphic elements (20a, 20b). In such a case, when a spatial element is viewed from a certain angle, a different image may be visible than when the element is viewed from a different angle, and for certain angles a composite of more than two images may be visible. In this way, you can create wall coverings that force the observer, intuitively, to take an appropriate position in the room - so that a specific image is legible.

Fig. 2b shows the lenticular image 11 created in the interlacing process from the combination of component images 10a, 10b of the first pair 10 and the lenticular image 21 created in the interlacing process from the combination of component images 20a, 20b of the second pair 20. The interlacing process consists in alternately taking lines of one image and the lines of the second image, and inserting them into the lenticular image. As a result, the odd lines (marked N in Fig. 2b) of the lenticular image 11 are taken from the first image 10a, and the even lines (marked P in Fig. 2b) of the lenticular image 11 are taken from the second image 10b. Similarly, for the lenticular image 21 formed from the second pair of images 20a, 20b, the odd N lines of the lenticular image 21 are taken from the first image 20a and the even P lines of the lenticular image 21 are taken from the second image 20b. The line width is selected so that the lenticular image 11, 21 is compatible with the lenticular lenses (lens array).

In order to compensate for geometric changes in the material from which a three-dimensional, non-flat, optically variable element will be thermoformed later in the process, in step 101a the lenticular image 11 may be appropriately distorted, in accordance with the expected deformations of the shape of the lenses that will occur in the thermoforming process (lenses located in near the top of the formed element will be distorted more than lenses near the base). For this purpose, appropriate mathematical transformations can be used, distorting the shape of the lenticular image lines to the expected distortion of the shape of the lenses, so that after the thermoforming operation, the three-dimensional, non-flat, optically variable element presents an image with proportions consistent with the original lenticular image (before printing).

In the next step 102, the lenticular image is integrated with the lenticular film. Lenticular foil has the form of a sheet which is flat on one side and has lenticular lenses (lenticular matrix) formed on the other side. The lenticular image is applied to the flat surface of the sheet. For example, the image may be printed directly on the sheet, using UV offset printing or UV digital printing, or any other printing technique appropriate to the application. Alternatively, the lenticular image may first be printed on a separate sheet substrate (preferably the same material as the lenticular film), which is then bonded to the flat side of the lenticular film.

Fig. 2c shows a cross-sectional view of a sheet of lenticular foil 30 with a print layer 31 containing a lenticular image 11.

Then, optionally, in step 102a, the printed lenticular film sheet may be laminated on the flat and/or convex side with a protective layer.

Fig. 2d shows a cross-sectional view of a sheet of lenticular foil after lamination, with a protective layer 32 on the flat side and a protective layer 33 on the lens side. The protective layer 32 on the flat side may be opaque (e.g., white) and may serve to increase the visibility of the lenticular image as well as protect it from scratches, especially when the lenticular image is printed directly on the lenticular film. The protective layer 33 on the convex side should be transparent; it can be used to protect the surface of the element against scratches and to increase the resistance of the element, especially the print layer, to UV light.

In the next step 103, a sheet of lenticular foil with print is formed in the thermoforming process in order to obtain the target spatial shape (geometric form) of a three-dimensional, non-flat, optically variable element. The thermoforming process involves plasticizing a sheet of lenticular foil and then vacuum forming it in a master mold. The reference form is a physical reflection of the target geometric form of a spatial element. The mold can be made of various materials such as: MDF (medium density chipboard), epoxy resin, aluminum, etc. Process parameters such as heating time, temperature, pressure are selected depending on the material from which the lenticular foil sheet is made. . Preferably, during forming, the sheet is pressed from its flat side so as not to flatten the lenses.

Fig. 2e shows a laminated sheet of lens foil with a lenticular image, after the thermoforming process, which results in the final shape of the plane of a three-dimensional, non-planar optically variable element, as shown in Fig. 1a-1d.

In the final step 104, excess material from the thermoforming process is removed.

Fig. 2f shows a three-dimensional, non-planar, optically variable element after removing excess material.

The method presented here for producing a three-dimensional, non-planar optically variable element allows its surface to be formed into virtually any shape using unadvanced thermoforming techniques. As a result, the production process is simple and fast. The produced elements faithfully reflect the original component images when viewed from different angles. The use of the thermoforming process allows the production of spatial, non-flat, optically variable elements of considerable size. The presented process is relatively simple and cheaper to use compared to the injection molding processes known from the state of the art, due to lower costs of making a thermoforming mold and lower costs of machinery.

Claims (9)

Patent claims 1. A three-dimensional, non-planar optically variable element obtained from a processed sheet of lenticular foil with a lenticular image compatible with the lenticular matrix of the lenticular foil applied to its flat side, characterized in that the three-dimensional, non-planar element has a surface with convex and/or concave areas (2) and, the height of which is much greater than the height of the lenses in the lens matrix, made in the process of processing by thermoforming a previously prepared flat sheet of lenticular foil (30) with a lenticular image placed on it. 2. A three-dimensional, non-planar element according to claim 1, characterized in that a transparent protective layer (33) is placed on the surface of the lens matrix of the lenticular lens sheet (30). 3. A three-dimensional, non-planar element according to claim 1 or 2, characterized in that there is an opaque protective layer (32) on the print layer (31) with the lenticular image. 4. A spatial, non-planar element according to any of the preceding claims, characterized in that the lenticular image (11) contains component images (10a, 10b) that have a uniform, single-color filling. 5. A three-dimensional, non-planar element according to any of the preceding claims, characterized in that it is a wall covering. 6. A method for producing a three-dimensional, non-planar optically variable element defined in claims 1-5 from a sheet of lenticular foil with a lenticular image compatible with the lenticular matrix of the lenticular foil sheet applied to its flat side, characterized in that it includes successive steps in which: - a (101) lenticular image is being prepared; - a lenticular image (102) is applied to a sheet of lenticular foil (30); - convex and/or concave areas (2) are formed in the sheet of lenticular foil (30) together with the lenticular image (31) in the thermoforming process. 7. A method of producing a three-dimensional, non-flat element according to claim. 6, characterized in that a lenticular image (101a) is prepared in accordance with the expected deformation values of the lens matrix in the process of thermoforming convex and/or concave areas. 8. A method of producing a three-dimensional, non-planar element according to any of the claims. 6-7, characterized in that after applying a lenticular image to a sheet of lenticular foil, the sheet of lenticular foil (102a) is laminated with a transparent protective layer (33) on the side of the lenticular matrix. 9. A method of producing a three-dimensional, non-planar element according to any of the claims. 6-8, characterized in that after applying a lenticular image to a sheet of lenticular foil, the sheet of lenticular foil (102a) is laminated with an opaque protective layer (32) on the flat side.