RU2111550C1 - Decorative or souvenir device for displaying images - Google Patents

Abstract

FIELD: advertisement, arts and crafts, optical instruments, in particular, advertising and show optical instruments which provide optical effect of three-dimensional color images, as well as patterns and pictures of unusual optical effect using reflecting lens systems for generation of three-dimensional color picture for decorative or advertising purposes, production of various souvenirs, show-room stands and windows, stained-glass windows, interior design articles. SUBSTANCE: device has at least one lens which has reflecting layer which is made from metal high-reflecting layer or layer of powder with highly reflecting surface dispersed in binder and applied on convex surface of each lens in order to generate three-dimensional mirror picture of corresponding lens over its hinder surface. In addition device has at least one observable three-dimensional article which is located on one side of corresponding lens in space of transparent plate which is located before mirror images of lenses. It is optically conjugated to mirror image of corresponding lens in order to generate direct image of observable articles on opposite side of corresponding lends in front of its mirror image in space behind plate. In addition device has light source which is located for illumination of at least one observable article. In addition device has base and may have at least one normal or Fresnel lens which has reflecting layer which is applied on convex hinder surface or on shaped surface of each normal lens or Fresnel lens respectively in order to generate three- dimensional mirror image of corresponding normal or Fresnel lens over their hinder or shaped surfaces. In addition device has at least one observable three-dimensional article which is located on one side of axis of corresponding normal or Fresnel lens which is optically conjugated with it by mirror image in order to generate direct image of corresponding observable article on opposite side of axis of normal or Fresnel lens in front of their mirror three- dimensional images. All above-mentioned designs of device may involve normal or Fresnel lenses using only one lens or their various combinations. EFFECT: increased functional capabilities. 33 cl, 7 dwg

Description

 The invention relates to advertising, various fields of design, arts and crafts, as well as to the optical industry, in particular to various advertising and demonstration optical devices with a special optical effect, providing the creation of visually observable volumetric color images, as well as patterns and drawings with unusual a lighting effect using optical reflective lens systems to create volumetric color images of an artistic-decorative or (and) advertising nature, and may be used to obtain a variety of artistic and decorative and souvenir products, exhibition stands, shop windows, panels, stained-glass windows, display boards, elements of the decorative interior, etc. that use a special decorative effect in the form of voluminous dynamically changing colorful decorative-artistic and advertising images reproduced over their front surfaces under light exposure.

 To date, the problem of creating a variety of highly aesthetically attractive artistic and decorative products, exhibition stands, shop windows, panels, stained glass windows, display boards, decorative interior elements, etc., including, if necessary, the distinguishing characteristics of the manufacturer, its trademark and other advertising information character, got up quite sharply.

 This is due to the fact that the existing art and decorative products, exhibition stands, shop windows, panels, stained glass windows, display boards, elements of the decorative interior, etc. with their relatively high aesthetic attractiveness, they do not provide the creation of original volumetric images with a special optical and unusual lighting effect, or such created volumetric images are not aesthetically attractive, and for the manifestation of a special optical effect they require a system of mirrors of complex curvilinear shape, limiting their scope and becoming more expensive products themselves.

 A decorative or souvenir device for displaying an image is known, comprising at least one pair of mirrors mounted in series and in pairs on the same optical axis, the mirrors in each pair being mounted to each other with their paraboloid reflecting surfaces so that the foci of each of the mirrors in the pair placed in the central, made in the form of holes, parts of another mirror of this pair, an object placed in one of the holes in the system of pairs of mirrors with the ability to create the correct volume th image of the object in one of the external openings of the system of pairs of mirrors, and a flat glass plate disposed between the two members of a pair of mirrors in or adjacent to the outer opening to be created by the three-dimensional image [1].

 However, the known technical solution has a low aesthetic appeal, since to obtain a small three-dimensional image of an object visible in a narrow range of viewing angles limited by openings, a system of disproportionately large curved-shaped mirrors compared to the three-dimensional image created that limits the scope and increases the cost of the product itself is required .

 The closest technical solution (prototype) is a decorative or souvenir device for displaying an image, containing a concave mirror of a hemispherical shape and with a dark reflective surface, a plate mounted horizontally in front of the reflective surface of a concave mirror, and a fluorescent screen of a cathode ray tube installed to display the image, installed on one of the sides of the axis of the concave mirror with the possibility of reflection by the latter of the incident radiation from the luminescent screen and the formation of the real and siderations on the opposite side of the axis of the concave mirror to the reflecting surface in the space above the plate, the plate may be made transparent, and the radiation transfer from the luminescent screen to the reflecting surface of the concave mirror can be implemented by a plane mirror [2].

 However, the known technical solution has a low aesthetic appeal, since the image is flat and also expensive due to the presence of a cathode ray tube with a fluorescent screen (television installation) and a constant energy source. In addition, the presence of a system of mirrors, including complex curvilinear shapes, to create an image complicates the very functioning of the device due to the need for their precise optical conjugation.

 A new achieved technical result of the invention is to increase the aesthetic attractiveness of the created decorative and artistic image while simplifying the device.

 This is achieved by the fact that in a decorative or souvenir device for displaying an image containing an optical element with a convex back surface and applying a reflective layer on it, a transparent plate mounted in front of the reflective surface of the optical element and an observed object mounted on one of the sides of the optical axis element with the possibility of forming a real image of the observed object from the opposite side of the axis of the optical element in front of its reflective surface in spaces behind the plate, in contrast to the prototype, the optical element is made in the form of at least one lens with a reflective layer deposited on the convex back surface of each lens to create a three-dimensional mirror image of the corresponding lens above its back surface, the observed object is made in the form of at least one volume of the observed object, each of which is installed in the volume of the plate along one of the sides of the axis of the corresponding lens optically conjugated with it with its mirror image to form an action an actual image of the corresponding observed object from the opposite side of the lens axis, with the plate mounted in front of the mirror images of the lenses.

 The volumetric observable object can be performed using laser graphics.

 Each observed object in the plate can be mounted at a different level relative to another and at a distance of 1 - 1.5 focus from the lens optically conjugated with the corresponding observed object.

 Lenses and plate can be made in a single design.

 The plate may be made with a refractive index different from the refractive index of the lenses.

 Part of the plate with the observed objects can be made with an opaque screen having at least one hole in the mirror image direction of each lens to enable the formation of a real image of each observed object above the mirror image of the corresponding lens in the space behind the plate.

 The lenses can be arranged so that their outer contour corresponds to the contour of the three-dimensional image of a given type.

 At least one lens can be made with a focus different from the focus of the other lenses.

 At least a portion of at least one lens may be made of a color-bearing light-transmitting material with a color different from the color of the material of the rest of the lens from the rest of the lenses.

 At least part of the front surface of at least one lens can be coated with a light-transmitting light-transmitting coating in the form of a given image with a color different from the color of the material of the corresponding lens.

 At least a portion of the reflective layer corresponding to at least a portion of at least one lens can be made in the form of an image of a given form or its element.

 At least a part of the reflective layer corresponding to at least one volumetric image element of a given kind or at least part of at least one lens can be made with a color of the reflective surface different from the color of the rest of the surface of the reflective coating or at least the color of that lenses, the color of a portion of the reflective surface of which is changed.

 In front of the reflective layer, at least a portion of the back surface of at least one lens can be coated with an additional color-bearing light transmission coating in the form of a predetermined image with a color different from the color of the material of the corresponding lens and reflective layer.

 The reflective layer may be made in the form of a metal highly reflective layer or a powder layer with a highly reflective surface dispersed in a binder.

 The lens can be made in the form of a Fresnel type lens, while the reflective layer is deposited on its profiled surface.

 The profiled surface of at least one Fresnel lens can be made with a geometric profile, providing the ability to create a three-dimensional image of a given type or its elements.

 The device may be provided with a base.

 The device may be equipped with a lighting source that is installed with the possibility of illumination of at least one object.

 A new technical result is also achieved by the fact that in a decorative or souvenir device for displaying an image containing an optical element with a convex back surface and with a reflective layer deposited on it and an observed object mounted on one of the sides of the axis of the optical element with the possibility of forming a real image of the observed object on the opposite side of the axis of the optical element in front of its reflective surface, in contrast to the prototype, the optical element is made in the form of at least e one lens with a reflective layer deposited on the convex rear surface of each lens to create a three-dimensional mirror image of the corresponding lens above its rear surface, the observed object is made in the form of at least one volumetric observed object, each of which is installed on one side of the axis of the corresponding optically conjugated with it by its mirror image of the lens to form a valid image of the corresponding observed object from the opposite side of the axis of the lens.

 Each observed object can be mounted at a different level relative to another and at a distance of 1-1.5 focus from the optical lens conjugated with the corresponding observed object.

 The observed objects can be made with an opaque screen having at least one hole in the mirror image direction of each lens to enable the formation of a real image of each observed object above the mirror image of the corresponding lens.

 The lenses can be arranged so that their outer contour corresponds to the contour of the three-dimensional image of a given type.

 At least one lens can be made with a focus different from the focus of the other lenses.

 At least a portion of at least one lens may be made of a color-bearing light-transmitting material with a color different from the color of the material of the rest of the lens from the rest of the lenses.

 At least part of the front surface of at least one lens can be coated with a light-transmitting light-transmitting coating in the form of a given image with a color different from the color of the material of the corresponding lens.

 At least a portion of the reflective layer corresponding to at least a portion of at least one lens can be made in the form of an image of a given form or its element.

 At least a part of the reflective layer corresponding to at least one volumetric image element of a given kind or at least part of at least one lens can be made with a color of the reflective surface different from the color of the rest of the surface of the reflective coating or at least the color of that lenses, the color of a portion of the reflective surface of which is changed.

 In front of the reflective layer, at least a portion of the back surface of at least one lens can be coated with an additional color-bearing light transmission coating in the form of a predetermined image with a color different from the color of the material of the corresponding lens and reflective layer.

 The reflective layer may be made in the form of a metal highly reflective layer or a powder layer with a highly reflective surface dispersed in a binder.

 The lens can be made in the form of a Fresnel type lens, while the reflective layer is deposited on its profiled surface.

 The profiled surface of at least one Fresnel lens can be made with a geometric profile, providing the ability to create a three-dimensional image of a given type or its elements.

 The device may be provided with a base.

 The device may be equipped with a lighting source that is installed with the possibility of illumination of at least one observed object.

 In FIG. Figures 1 to 4 show a decorative or souvenir device with observable objects mounted in a plate and with their volumetric real images created by ordinary lenses; in FIG. 5 - decorative or souvenir device with observable objects mounted in the plate, and with their volumetric real images created by Fresnel lenses; in FIG. 6 - decorative or souvenir device with volumetric real images of observed objects created by ordinary lenses; in FIG. 7 is a decorative or souvenir device with volumetric real images of the observed objects created by Fresnel lenses. Schematic diagrams of the proposed decorative or souvenir device for displaying images are presented.

 A decorative or souvenir device 1 for displaying an image comprises at least one lens 2 with a metal highly reflective layer 3 deposited on the convex rear surface 4 of each lens 2 to create a three-dimensional mirror image 5 of the corresponding lens 2 above its rear surface 4, at least one observed volumetric object 6, each of which is installed on one side of the axis 8 of the corresponding lens 2 in the volume of the transparent plate 7, placed in front of the mirror images 5 of the lenses 2, and is optically coupled to a grain cial image 5 corresponding to the lens 2 to form a real image 9 of the observed objects 6 from the opposite side of the axis 8 of the lens 2 corresponding to its mirror image 5 in the space behind the plate 7 and the base 10 (FIG. 1).

 Each volumetric observable object 6 in the plate 7 can be made by laser graphics and installed at a different level relative to another and at a distance of 1-1.5 focus from the lens 2 optically conjugated with the corresponding observed object 6, while the plate 7 can be made with an indicator refraction different from the refractive index of lenses 2 in a single design with lenses 2, which can be arranged so that their outer contour 11 corresponds to the contour of the three-dimensional image of a given type 12 (Fig. 2).

Part of the plate 7 with the observed objects 6 can be made with an opaque screen 13 having at least one hole 14 in the direction of the mirror image 5 of each lens 2 to enable the formation of a valid image 9 of each observed object 6 above the mirror image 5 of the corresponding lens 2 in space behind the plate 7, with at least one lens 15 may be configured to focus f ^i, different from the remaining lens focus f 2, and at least part of at least one lens 2, 15 may be l is made of a color-bearing light-transmitting material 16 with a color different from the color of the material of the rest of the lens 2, 15, from the rest of the lenses 2, 15, with at least part of the reflective layer 3 corresponding to at least part of at least one lens 2, 15 can be made in the form of an image of a given type 12 or its element and from a powder layer 17 with a highly reflective surface dispersed in a binder 18 (Fig. 3).

 At least a part of the front surface 19 or (and) in front of the reflecting layer 3, at least a part of the back surface 4 of at least one lens 2, 15 can be coated with light-transmitting light-transmitting coatings 20, 21, respectively, in the form of a predetermined image with a color different from the color of the material of the respective lenses 2, 15 and the reflective layer 3, while at least a portion of the reflective layer 2 corresponding to at least one volumetric image element of a given type 12 or at least part of at least one lens 2, 1 5 can be made with the color of the reflecting surface 22 different from the color of the rest of the surface of the reflecting layer 3, at least from the color of that lens 2, 15, the color of which part of the reflecting surface 3 is changed (Fig. 4).

 Lens 2, 15 can be made in the form of a Fresnel type lens 23 with a reflective coating 3, 22 deposited on its profiled surface 24, made with a geometric profile, providing the possibility of creating a three-dimensional image of a given type 12 or its elements, and the device 1 can be provided a lighting source 25 mounted to illuminate at least one observable object 6 (FIG. 5).

 Decorative or souvenir device 26 for the image shown contains at least one lens 2 with a metal highly reflective layer 3 deposited on the convex rear surface 4 of each lens 2 to create a three-dimensional mirror image 5 of the corresponding lens 3 above its rear surface 4, at least one observed volumetric object 27, each of which is installed on one side of the axis 8 of the corresponding lens 5 optically conjugated with it with its mirror image 5 with the possibility of forming a real mapping 28 corresponds to the observed object 27 on the opposite side of the lens axis 8 2 before its mirror image 5, the base 10 and illumination source 25 mounted to illumination of at least one observed object 27 (FIG. 6).

 Lens 2 can be made in the form of a Fresnel type lens 23 with a reflective layer 3 deposited on its profiled surface 24, and the observed objects 27 can be made with an opaque screen 29 having at least one hole 30 in the direction of the mirror image 5 of each lens 23 Fresnel to enable the formation of a valid image 28 of each observed object 27 above the mirror image 5 of the corresponding lens 2 (Fig. 7).

 All structural elements of the proposed decorative or souvenir device 1, 26 with conventional lenses 2, 15 shown in FIG. 1 - 4 and 6 are also performed with Fresnel lenses 23 (Fig. 5, 7) and vice versa.

 The proposed decorative or souvenir device 1, 26 operate as follows.

 In FIG. 1 shows a decorative or souvenir device 1 for displaying an image comprising a lens 2 with a highly reflective metal layer 3 deposited on the convex rear surface 4 of the lens 2, to create a three-dimensional mirror image 5 of the lens 2 above its rear surface 4, the observed three-dimensional object 6, mounted on one of the sides of the axis 8 of the lens 2 in the volume of the transparent plate 7 located in front of the mirror image 5 of the lens 2 and optically conjugated to its mirror image 5 with the possibility of forming a real image location 9 of the observed object 6 on the opposite side of the axis 8 of the lens 2 in front of its mirror image 5 in the space behind the plate 7, and the base 10.

 In FIG. 2 shows a decorative or souvenir device for displaying an image in which three-dimensional observable objects 6 in the plate 7 are mounted at different levels relative to each other and at a distance of 1 - 1.5 focus from the lens 2 optically conjugated with the corresponding observable object 6, while the plate 7 made in a single design with the lenses 2, the latter are arranged in such a way that their outer contour 11 corresponds to the contour of the three-dimensional image of a given type 12.

 Incident rays, for example, from the surrounding direction or scattered light are refracted on the front surface of the corresponding lens 2, and the light beams converted accordingly, depending on the type of lens 6, interact with the reflective layer 3 deposited on the rear convex surface 4 of each lens 2, and are reflected from it and again, passing through the front surface of the corresponding lens 2, create a three-dimensional mirror image 5 of each lens 2 above their respective front (depending on the type of lens 2) or rear surfaces 4 (in the case of plate 7 and lens 2 in a single design) from the side of the incident beam at a distance provided by the foci F of the corresponding lenses 6.

 At the same time, as an constructed volume mirror image 5 of lens 2, the observer can see both the image of only one or several separately taken lenses 2 (if any), and the image of their composition (if these lenses 2 are placed with their path 11 corresponding to the path three-dimensional image of a given type 12 (Fig. 2), for example, as it were, soaring above the front or rear surfaces of the 4 lens groups 2 of a butterfly, a crocodile, flying Carlson, an image of fruit, etc., the name of the manufacturer or its trademark aka, etc., and see in the color corresponding to the color of the material 16 of the corresponding lenses 2, 15, the color of the light-transmitting coatings 20, 21 (if any) or the color of the reflective coating 3, 22 (Fig. 4).

 Observed volumetric objects 6, for example, an image of a Russian eagle, a temple, etc., made in the volume of a transparent plate 7 placed in front of the mirror image 5 of the lenses 2, for example, by the method of computer laser graphics, are placed on one side of the axis 8 of the corresponding lens 2 in this way that they are optically conjugated with its mirror image 5. It should be noted that the volumetric observable objects 6 can be placed at different levels relative to each other, but at the optimal distance provided by a range of 1 - 1.5 focus from the lens 2 optically conjugated with the corresponding observed object 6; In this case, the mirror volumetric image 5 of each lens 2 forms a volumetric real image 9 of the corresponding observed volumetric object 6 from the opposite position of the observed objects 6 of the axis 8 of the lens 2 side in front of its mirror image 5 in the space behind the plate 7. In the case of the placement of volumetric observable objects 6 outside the range of 1 - 1.5 focal length F relative to the optically conjugated lens 2 formed by the action An accurate image 9 of the corresponding observable object 6 spreads out and becomes fuzzy.

 It should be noted that the volumetric observed objects 6 can be performed in the volume of the plate 7 and other methods, for example, by melting volumetric products 6 during casting, molding, etc. plates 6.

 The implementation of the plate 7 with a refractive index different from the refractive index of lenses 2, in a single design with lenses 2 allows you to vary the height of the placement of the mirror volumetric images 5 in addition to the method of varying their height, provided by the focus of the corresponding lenses 2. That is, it is possible to raise (lower) the mirror volume images 5 and, as a result, the corresponding real images of volumetric observable objects 6 optically conjugated to them at a given height relative to the level, еч еч ива ива ива 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. 2. Lens 2 and plate 7 in a single design, for example in the form of a cube, parallelepiped, etc. and also simplify the technology of the device.

 In the case of making the plate 7 separately from the lens 2, 15, it can be placed both on both sides of the axis 8 of the lens (lenses 2, 15), and only on one side of the axis 8 in the case of using in a decorative or souvenir device 1, for example, only one lenses 2, 15.

 It should also be noted that when using a convex-convex type lens 2, 15 or in the case of performing a plate 7 in a single design with lenses 2, 15, a three-dimensional mirror image 5 created above the back surface 4 of the corresponding lenses 2, 15 will be observed, as a rule, in the volume of the corresponding lens 2, 15, or in the volume of the plate 7 made in the same version of the plate.

In FIG. 3 shows a decorative or souvenir device for displaying an image in which a part of the plate 7 with the observed objects 6 is made with an opaque screen 13 having a hole 14 in the direction of the mirror image 5 of each lens 2 to enable the formation of a valid image 9 of the observed objects 6 above the mirror image 5 the corresponding lens 2 in the space behind the plate 7, while part of the lenses 15 is made with a focus f ⁱ different from the focus F of the other lenses 2, and part of the lenses 2, 15 is made of color carrying light-transmitting material 16 with a color different from the color of the material of the remaining lenses 2, 15, and a part of the reflecting layer 3 corresponding to the part of the lenses 2, 15 is made in the form of an image of a given type 12 or its element and from a powder layer 17 with a highly reflective surface dispersed in the binder 18.

The size and distance from the rear surfaces 4 of the lenses 2, 15 of the 3D mirror image 5 depends on the focal length F ⁱ , F of these lenses 2, 15. Moreover, part of the lenses 2, 15 may have different focal lengths F ¹ , F ² ..., F ⁱ , which allows you to generate a three-dimensional image of a given type 12 above the rear surfaces 4 of the corresponding lenses 2, 15 with multi-level individual image elements 12. In other words, the individual image elements of a given type 12 (trunk, wings, head, antennae, etc. butterflies or other predetermined image 12 ) can be at different heights above the back surface 4 of the corresponding lenses 2, 15 (Fig. 3).

 The implementation of the reflective layer 3 in the form of a powder layer 17 with a highly reflective surface dispersed in the binder 18 allows you to widely vary the color of the reflective layer due to the use of various materials such as "eye gloss" white, pearlescent, lilac and other exotic colors, and these materials can be made of both metal and non-metals or non-metals with a metal reflective coating. It can be aluminum, bronze, silver, brass, etc. powder, particles of mica, particles of polymer, for example, lavsan, films with a reflective layer such as "eye gloss" deposited on them, titanium oxide, etc. with a particle size of 0.2-0.3 microns. As a binder, for example, Metafont varnish manufactured by the LIT enterprise in Pereyaslavl-Zalessky or another suitable binder of the type of optical glue can be used.

 The implementation of the plate 7 with an opaque screen 13 having one or more holes 14 in the direction of the mirror image 5 of each lens 2 to enable the formation of a real image 9 of the observed objects 6 allows you to hide the observed objects 6 from the view of the observer, allowing him to see only real three-dimensional images 9 of these observed objects, which allows to increase the mystery and originality of a decorative or souvenir device 1. In this case, the screen 13 itself can be made as a medium by coloring the part of the plate 7 in which the observed objects 6 are placed, or the plate 7 can be placed in some opaque casing, etc. with the presence, naturally, of 9 observable objects 6 holes 14 necessary for constructing real three-dimensional images.

 In FIG. 4 shows a decorative or souvenir device for showing an image in which color-bearing light-transmitting coatings 20, 21, respectively, are applied to a part of the front surface and / or in front of the reflecting layer 3 on the back surface 4 of the lenses 2, 15, respectively, in the form of a predetermined image with a color different from the color the material of the corresponding lenses 2, 15 and the reflective layer 3, while the part of the reflective layer 3 corresponding to the volumetric image element of a given type 12 or part of the lens 2, 15 is made with the color of the reflecting surface 22 different from colors of the remaining surface of the reflective layer 3 or from the color of that lens 2, 15, the color of which part of the reflective surface 3 is changed.

 Applying on a part of the front and back surfaces 4 lenses 2, 15 of color-bearing transparent coatings 20, 21, for example, color-bearing transparent varnish of the “zapon” type, blue, etc., with a color different from the color of the material of the corresponding lens 2, 15, allows you to highlight individual elements of the three-dimensional image of a given type 12 in a given color (Fig. 4). It should also be noted that in this case, certain parts of the three-dimensional mirror image 5 of a given type 12, for example, butterflies, company names, trademarks, etc. may have a different color for the above reason. So, butterfly wings can be in one or several shades, the head in a different color, the body in a third, etc.

 The implementation of the reflective layer 3 with the color of the reflecting surface 22, corresponding to the individual image elements 12 or individual lenses 2, 15, different from the color of the rest of the surface of the reflecting layer 3 of the same and the rest of the lenses 2, 15, allows you to create an image of a given type 12 above the corresponding back surfaces 4 of these lenses painted in colors corresponding to the painted parts of the corresponding part of the reflecting surface 22 (Fig. 4). So, for example, reflective surface 22 made of aluminum corresponds to silver, copper - golden, brass - yellow, bronze - reddish, steel and molybdenum - steel-gray, etc. In this case, the reflective layer 3 can be applied directly to the back surface 4, for example, by thermal vacuum spraying on a unit 3A-5100 of the corresponding metal with highly reflective properties or, for example, by spraying the powder 17 in the binder 18.

 As lenses 2, 15, for example, convex-concave, plane-convex or convex-convex type lenses are used.

If I is the average size of the mirrored volumetric image 5 created above the back surface 4 of the lens 2, 15, h is the average height of the mirrored volumetric image 5 above the back surface 4 of the lens 2, 15, r is the radius of the lens 2, 15, and F is the focus of the lens 2 , 15, then when constructing a mirror volumetric image 5, the following ratios are most optimal:
I≈h, I≈0.74 F and r <1 + (1-3) mm.

 In FIG. 5 shows a decorative or souvenir device for displaying images, in which the lens 2, 15 is made in the form of a Fresnel lens 23 with a reflective coating 3, 22 deposited on its profiled surface 24, made with a geometric profile, allowing the creation of a three-dimensional image of a given type 12 or its elements, while the device 1 can be equipped with a source of lighting 25, installed with the possibility of highlighting the observed objects 6.

The principle of operation of the Fresnel lens 23 is that incident rays, for example, from the ambient directional or scattered light are refracted on the front surface of the corresponding Fresnel lens 23 and are converted accordingly depending on the type of Fresnel lens 23 used in accordance with the slopes of the edges of its working areas profiled surface 24, light beams interact with the reflective layer 3 of each Fresnel lens 23, are reflected from it and again, passing through the profiled surface 24 and the front surface nce (if any) of the corresponding Fresnel lenses 23, create volumetric mirror image 5 each Fresnel lens 23 in front of their respective profiled surfaces 24 on the part of the beam of rays falling in the distance, provides a focal point F ^{to the} posed slopes working areas corresponding edges 23 of the Fresnel lens. As a result, the incident wave front incident on the Fresnel lens 23 is converted to another front, which provides the required focusing process in accordance with the specified shape of the volume mirror image 5 obtained above its back surface 4.

 The use of Fresnel lenses 23 instead of conventional lenses 2, 15 makes it possible to make more compact decorative or souvenir devices 1, eliminating, for example, the need for a base 1, which is necessary when lenses 2, 15 are placed at the bottom of the device 1, the back surface of which 4 it is unstable, while the manufacturing process, including in a single version with 23 Fresnel lenses, is more technologically advanced due to the use of flat, small thickness 23 Fresnel lenses. It should be noted that Fresnel lenses 23 can be made in the form of a disk, a rectangle, a square, a regular triangle or hexagon or other geometric shape, specified if necessary in accordance with the contour of the created volumetric mirror image 5 or in accordance with the contour 11 of the composition of the Fresnel lens 23, corresponding to the contour of the image of a given type 12 created with their help, composed of mirrored three-dimensional images 5. The shape given to the Fresnel lens 23 may correspond to the appearance of a given species 12 entirely, for example, a butterfly, a crocodile, Carlson, an image of a fruit, the name or trademark of a prestigious company, etc., as well as individual elements of the image 12, in the case of using a group of Fresnel lenses 23 that create the given image 12 in the complex or in the corresponding composition (Fig. 5).

 At the same time, the observer sees the volume image 12 of the Fresnel lens 23 as an image, for example, in the form of an image of a butterfly, a crocodile, flying Carlson, an image of fruit, the name of the country and manufacturer, its trademark, etc., as if “soaring” "in the air above their rear surfaces 4, in a color corresponding to the color of the reflecting surface 3, 22, the color of the material 16 from which they are made, or the color of the coating 20, 21 applied to their face (if any) or (and) profiled surface 24 (if at least one of the coatings) (Fig. 5).

 As lenses 23 of the Fresnel type, zone plates can also be used in the form of, for example, phase optical zone reflecting elements using reflective kinoforms with a stepped profile of zones, which are described mathematically in accordance with the shape of a volumetric image of a given type 12 specified above the back surface of 4 zone plates.

 Use, for example, phase reflective zone plates or Fresnel lenses 23, consisting of an internal carrier layer with a profiled surface 24, made in the form of, for example, concentric refractive elements of the working areas.

где
tgα_i= r_i/n_i.
Если I - средний размер создаваемого над тыльной поверхностью 4 линзы 23 Френеля зеркального объемного изображения 5, h - средняя высота зеркального объемного изображения 5, а r - максимальный радиус внешнего кольца линзы Френеля 23, то при построении зеркального объемного изображения 5 наиболее оптимальными являются следующие соотношения:
I≈0,9 h; I≈0,14 F и r < 1 +(1 - 3) мм.Given the radius r _i of the ring corresponding to the Fresnel lens 23, the Fresnel around axis O - O distance F ¹ of the lens 23, Fresnel refractive index n _i corresponding zone and reaches deviation δ _i can determine the angle of inclination α _i edges working zones from the following equation:

Where
tgα _i = r _i / n _i .
If I is the average size of the mirrored volumetric image 5 created above the back surface 4 of the Fresnel lens 23, h is the average height of the mirrored volumetric image 5, and r is the maximum radius of the outer ring of the Fresnel lens 23, then the following ratios are most optimal when constructing the mirrored volumetric image 5 :
I≈0.9 h; I≈0.14 F and r <1 + (1 - 3) mm.

 The formation of real images 9 of the corresponding observable objects 6 by means of Fresnel lenses 23 is carried out in the same way as described above, as for ordinary lenses 2, 15.

 The preparation of Fresnel lenses 23 is carried out by imparting from a predetermined geometric shape, for example, in the form of an image of a predetermined kind 12 as a result of molding material 16 of the appropriate type, for example, in a matrix with a surface pattern that provides a given profile on the profiled surface of the Fresnel lens 23.

 It should also be noted that the creation of a three-dimensional, color, dynamically changing image of a given type 12 can be achieved both with a group of Fresnel lenses 23 and with only one Fresnel lens 23.

 Lighting source 25 is designed to illuminate and increase the brightness of the obtained real volumetric images 9 of the observed volumetric objects 6 by highlighting, for example, one of them, which is the center of the composition from the created real images 9 of the observed objects 6, or a series, including, possibly and all observed objects 6.

 It should be noted that all of the above and presented in FIG. 1 - 5 manufacturing options of a decorative or souvenir device 1 for displaying an image can be performed both with volume lenses 2, 15, and with Fresnel lenses 23, both in the presence of only one lens 2, 15, 23, and in their various combinations or compositions .

 Fresnel lenses 23, conventional lenses 2, 15 and plate 7 can be made of transparent materials such as glass, quartz, polystyrene, polycarbonate, polyethylene, polymethylmethacrylate, etc., including color-bearing transparent material 16, in accordance with coloring of the created volumetric mirror image 5 and the image of a given type 12 created with their help.

 In FIG. 6 shows a decorative or souvenir device 26 for displaying an image containing a lens 2 with a metal highly reflective layer 3 deposited on its convex rear surface 4 to create a three-dimensional mirror image 5 of the lens 2 above its rear surface 4, the observed three-dimensional object 27, mounted on one of the sides of the axis 8 of the lens 2 optically conjugated with it with its mirror image 5 with the possibility of forming a real image 28 of the observed object 27 from the opposite side of the axis 8 of the lens 2 before Calne image 5, the base 10 and illumination source 25 mounted to the backlight 27 of the observed objects.

 In FIG. 7 shows a decorative or souvenir device 26 for displaying an image in which Fresnel lenses 23 are used with a reflective layer 3 deposited on its profiled surface 24, and the observed objects 27 are made with an opaque screen 29 having an opening 30 in the mirror image direction 5 of each lens 23 Fresnel to enable the formation of a valid image 28 of each observed object 27 above the mirror image 5 of the corresponding lens 2.

 It should be noted that the generated real images of 9 volumetric observable objects 6 can either be included as one of the elements in a multilevel composition of the created volumetric color mirror images 5 of a given type 12, including being at the corresponding given level in this composition, they may not be at all related to the composition of volumetric mirror images 5.

 Observed volumetric objects 27, for example, an image of a Russian eagle, a temple, etc., are installed, for example, by means of fasteners in front of mirror images of 5 ordinary lenses 2, 15 or 23 Fresnel lenses on one side of the axis 8 of the corresponding ordinary lenses 2, 15 or Fresnel lenses 23 in such a way that they are optically conjugated with their mirror images 5. It should be noted that the volumetric observable objects 27 can be placed at different levels relative to each other, but at an optimal distance provided by a range of 1 - 1.5 focal lengths sa from the optically conjugate with the observed object 27 corresponding conventional lens 2, 15 or 23 of the Fresnel lens. In this case, the mirror volumetric image 5 of each ordinary lens 2, 15 forms a real image 9 of the corresponding observed object 27 from the opposite position of the observed objects 27 of the axis 8 of the ordinary lens 2, 15 or Fresnel lens 23 in front of its mirror image 5 in the space behind the plate 7. B in the case of placement of volumetric observable objects 27 outside the range of 1 - 1.5 of the focal length relative to the optically conjugated lens 2, 15 or Fresnel lens 23, the actual image formed 9 corresponds to present the observed object 27 spreads out and becomes fuzzy.

 All observable volumetric objects 27 can be installed in an opaque protective screen 29 with a hole 30 made in the direction of the mirror image 5 of each ordinary lens 2, 15 or Fresnel lens 23 to enable the formation of a valid image 28 of each observed object 27 above the mirror image 5 corresponding to the usual lenses 2, 15 or Fresnel lenses 23.

 All of the above design options of a decorative or souvenir device 1 for displaying the image shown in FIG. 1-4 and concerning conventional lenses 2, 15, Fresnel lenses 23, the base 10 and the light source 25, are also competent in design variants for a decorative or souvenir device 26 for displaying the image shown in FIG. 6, 7.

Based on the foregoing, a new achieved positive technical result of the invention is:
increasing the aesthetic attractiveness and originality of a decorative or souvenir device for displaying images through the use of volumetric observable objects performed in the volume of a transparent plate by means of computer laser graphics and ensuring the creation of their volumetric real images, as well as optical lenses, providing original optical effects observed above their surface in a volumetric mirror, as it were, “floating” in the air, a multi-level colorful dynamic changing from a company of a given type, which together contributes to increasing the commercial attractiveness of both the device itself and the companies that produce it;
simplification of a decorative or souvenir device for displaying an image by refusing to use complex mirrors with a curved reflective surface and replacing them with more easily processed lenses, including a flat Fresnel lens, as well as by performing observable objects in the volume of a transparent plate, and the latter in a single design with lenses;
increasing the degree of development of artistic taste, color perception and spatial imagination of the observer by creating volumetric real images of the observed volumetric objects built in the volume of a transparent plate using computer laser graphics, as well as optical elements that ensure the creation of aesthetically attractive original optical effects over their surface, observed through volume mirrored, as it were, "floating" in the air multilevel colorful dynamic and changing a certain type of images;
providing the ability to create both a composition of real three-dimensional images of observed objects and three-dimensional mirror images of lenses, and their joint composition;
providing the possibility of varying the color gamut of the created compositions of real images of observed objects and mirror images of lenses;
providing the ability to consider the resulting three-dimensional image in a wide range of angles in scattered light.

Claims (33)

 1. A decorative or souvenir device for displaying an image comprising an optical element with a convex rear surface and a reflective layer deposited thereon, a transparent plate mounted in front of the reflective surface of the optical element, and an observed object mounted on one of the sides of the axis of the optical element with the possibility of forming a real image of the observed object from the opposite side of the axis of the optical element in front of its reflecting surface in the space behind the plate, distinguishing I mean that the optical element is made in the form of at least one lens with a reflective layer deposited on the convex back surface of each lens to create a three-dimensional mirror image of the corresponding lens above its back surface, the observed object is made in the form of at least one volume observed object, each of which is installed in the volume of the plate along one of the sides of the axis of the corresponding lens optically conjugated with it with its mirror image to form a valid image, respectively of the observed object on the opposite side of the lens axis, with the plate mounted in front of the mirror images of the lenses.  2. The device according to claim 1, characterized in that the volumetric observed object is made by means of laser graphics.  3. The device according to claim 1 or 2, characterized in that each observed object in the plate is mounted at a different level relative to each other and at a distance of 1 - 1.5 focus from the lens optically conjugated with the corresponding observed object.  4. The device according to claim 1 or 3, characterized in that the lenses and the plate are made in a single design.  5. The device according to claim 4, characterized in that the plate is made with a refractive index different from the refractive index of the lenses.  6. The device according to any one of claims 1 to 5, characterized in that the part of the plate with the observed objects is made with an opaque screen having at least one hole in the mirror image direction of each lens to enable the formation of a valid image of each observed object above the mirror image corresponding lens into the space behind the plate.  7. The device according to claims 1, 5 or 6, characterized in that the lenses are arranged so that their external contour corresponds to the contour of a three-dimensional image of a given type.  8. The device according to any one of claims 1 or 5 to 7, characterized in that at least one lens is made with a focus different from the focus of the other lenses.  9. The device according to any one of claims 1 or 5 to 8, characterized in that at least a portion of at least one lens is made of a color-bearing light-transmitting material with a color different from the color of the material of the rest of the lens from the rest of the lenses.  10. The device according to any one of claims 1 or 5 to 9, characterized in that at least part of the front surface of at least one lens is coated with a light-transmitting light-transmitting coating in the form of a given image with a color different from the color of the material of the corresponding lens.  11. The device according to any one of claims 1 or 5 to 10, characterized in that at least a portion of the reflective layer corresponding to at least a portion of at least one lens is made in the form of an image of a given form or its element.  12. The device according to any one of claims 1 or 5 to 11, characterized in that at least a portion of the reflective layer corresponding to at least one element of the three-dimensional image of a given type or at least part of at least one lens is made with the color of the reflective a surface other than the color of the rest of the surface of the reflective coating, or at least the color of the lens whose color of the part of the reflective surface is changed.  13. The device according to any one of claims 1 or 5 to 12, characterized in that in front of the reflective layer at least on the back surface of at least one lens, an additional color-bearing light-transmitting coating is applied in the form of a given image with a color different from the color of the material of the respective lenses and reflective layer.  14. The device according to any one of claims 1 or 11 to 13, characterized in that the reflective layer is made in the form of a metal highly reflective layer or a layer of powder with a highly reflective surface dispersed in a binder.  15. The device according to any one of claims 1 or 5 to 13, characterized in that the lens is made in the form of a Fresnel type lens, while the reflective layer is deposited on its profiled surface.  16. The device according to p. 15, characterized in that the profiled surface of at least one Fresnel lens is made with a geometric profile that provides the ability to create a three-dimensional image of a given type or its elements.  17. The device according to any one of claims 1 to 16, characterized in that it is provided with a base.  18. The device according to any one of paragraphs.1 to 17, characterized in that it is equipped with a lighting source that is installed with the possibility of illumination of at least one object.  19. A decorative or souvenir device for displaying an image containing an optical element with a convex back surface and a reflective layer deposited on it and an observed object mounted on one of the sides of the axis of the optical element with the possibility of forming a real image of the observed object from the opposite side of the axis of the optical element in front of it reflective surface, characterized in that the optical element is made in the form of at least one lens with a reflective layer deposited on a convex t the back surface of each lens to create a three-dimensional mirror image of the corresponding lens above its back surface, the observed object is made in the form of at least one three-dimensional observed object, each of which is mounted on one side of the axis corresponding to its optical mirror image to form a real lens images of the corresponding observed object from the opposite side of the lens axis.  20. The device according to claim 19, characterized in that each observed object is mounted at a different level relative to each other and at a distance of 1 to 1.5 focus from the lens optically conjugated with the corresponding observed object.  21. The device according to claim 19 or 20, characterized in that the observed objects are made with an opaque screen having at least one hole in the mirror image direction of each lens to enable the formation of a valid image of each observed object above the mirror image of the corresponding lens.  22. The device according to any one of paragraphs.19 to 21, characterized in that the lenses are arranged so that their external contour corresponds to the contour of the three-dimensional image of a given type.  23. The device according to any one of paragraphs.19 to 22, characterized in that at least one lens is made with a focus different from the focus of the other lenses.  24. The device according to any one of paragraphs.19 to 23, characterized in that at least a portion of at least one lens is made of a color-bearing light-transmitting material with a color different from the color of the material of the rest of the lens from other lenses.  25. The device according to any one of paragraphs.19 to 24, characterized in that at least part of the front surface of at least one lens is coated with a light-transmitting light-transmitting coating in the form of a given image with a color different from the color of the material of the corresponding lens.  26. The device according to any one of paragraphs.19 to 25, characterized in that at least part of the reflective layer corresponding to at least part of at least one lens is made in the form of an image of a given form or its element.  27. The device according to any one of paragraphs.19 to 26, characterized in that at least a portion of the reflective layer corresponding to at least one element of the three-dimensional image of a given type or at least part of at least one lens is made with the color of the reflecting surface different from the color of the rest of the surface of the reflective coating, or at least from the color of the lens whose color of the part of the reflective surface is changed.  28. The device according to any one of paragraphs.19 to 27, characterized in that in front of the reflective layer at least part of the back surface of at least one lens is applied additional color-bearing light-transmitting coating in the form of a given image with a color different from the color of the material of the corresponding lens and reflective layer.  29. The device according to any one of paragraphs.19 or 26 to 28, characterized in that the reflective layer is made in the form of a metal highly reflective layer or a layer of powder with a highly reflective surface dispersed in a binder.  30. The device according to any one of paragraphs.19 to 28, characterized in that the lens is made in the form of a Fresnel type lens, while the reflective layer is deposited on its profiled surface.  31. The device according to p. 30, characterized in that the profiled surface of at least one Fresnel lens is made with a geometric profile that provides the ability to create a three-dimensional image of a given type or its elements.  32. The device according to any one of paragraphs. 19 to 31, characterized in that it is provided with a base.  33. The device according to any one of paragraphs. 19 - 32, characterized in that it is equipped with a lighting source that is installed with the possibility of illumination of at least one observed object.

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