BG1735U1 - Multilayered three-dimensional model of sheet material and system for its receipt - Google Patents

Abstract

Utility model relates to a multilayered three-dimensional model of the sheet material and a system for its receipt, which can be applied to the physical construction of three-dimensional models of sheets that are replica existing museum exhibit, sculpture, and large-scale reproduction of the models of movable and immovable cultural and historical monuments, architectural buildings and tourist sites. The three-dimensional pattern is composed of "n" number of shape forming elements (1) arranged on top of one another, each shape forming element comprises an inner portion (3) and outer portion (4) linked by structural links (5) and separated from one another by divider circuit (6). Each part of the shape forming element comprises at least one opening (7, 8) in which is disposed a constructive leading element and which is fixed it to the respective parts of the shape forming elements (1).

Description

Field of application

The utility model refers to a multilayer three-dimensional sheet material model and system for its production, which may find application for the physical construction of spatial models of sheet material that represent an exact copy of an existing object / museum exhibit, sculpture and other / or freely generated such as scaling models of movable and immovable cultural and historical monuments, architectural buildings and tourist sites.

BACKGROUND OF THE INVENTION

A cube puzzle (US P 4662638) is known, consisting of a plurality of interconnected elements that completely fill the volume of the cube, the said elements being arranged so that they can be disassembled relative to one another. Characteristic of the known construction is that each of the elements that make up a cube puzzle is made up of several smaller cubes that contact through their sides and are tightly connected to each other. The construction of a puzzle cube requires at least two small building blocks to be placed opposite each other with respect to each of the elements oriented in the three directions of space.

The well-known cube puzzle has a relatively technically complex implementation of small cubes, which in turn determines the complexity of the shape and its high value.

A three-dimensional puzzle (US P 4874176) is known, which is a substantially three-dimensional picture puzzle comprising a plurality of elements of the same size and shape as determined by the upper, lower and lateral surfaces. The elements are connected to each other by their lower surfaces, their fixing being carried out by means of predetermined connecting parts, thus forming a three-dimensional shape.

With the well-known three-dimensional puzzle, in order to construct a three-dimensional shape, it is necessary to connect many identical in shape and size elements that do not contain an indication of their placement in space. An additional disadvantage is that the molding members are positioned and bonded to one another without being placed on a base, as a result of which the three-dimensional shape cannot be constructed with the necessary stability.

A three-dimensional object (US P 5817378) is known, made of paper sheet, folded in two, perpendicularly oriented halves, folding along a transverse line, wherein the sheet material is provided with cut-out elements projecting toward each other, being arranged parallel to one another, as well as parallel to one half of the folded sheet, and the shapes of the cut portions vary gradually from one to the other half of the folded sheet, resulting in a shape with a front other than the posterior h Senior three-dimensional form.

The disadvantage of a known three-dimensional object made of sheet material is that the construction of such a three-dimensional object requires the use of additional structural elements in order to achieve the necessary stability of the form, together with additional shaping elements arranged parallel to it.

A three-dimensional puzzle (US P 5681041) is known, comprising a plurality of elements, each with a predetermined shape made of solid sheet material. Basically, the elements are made up of parallel oriented flat surfaces, preferably the same thickness. For the purpose of steadily constructing the shape of the three-dimensional puzzle, depending on the shape being constructed, a predetermined number of elements are further provided with a frictionally engaged medium to achieve the necessary stability of the three-dimensional figure. Such stability is also achieved with the help of an additional supporting element, which also has the function of a guide in the arrangement of molding elements.

The famous puzzle has a complex construction of the puzzle, which also determines the inability to fully and continuously reproduce the

1735 Ul 3D object.

There is a method of constructing a three-dimensional object described in patent publication WO 2003/084622, which involves dividing a three-dimensional object by intersecting it with a horizontally oriented plane along one of the dimensions in space to determine the contour of the object, wherein the object is divided into multiple molding elements of different shapes, which are cut using known technical means and then stacked and fixed in succession to one another, indivisible in the direction of a sheet surface, bounded from its own contour, the next shape element being fixed to the previous shape element until full reproduction of the shape of the three-dimensional object.

In the known method, fixing the molding elements to the full reproduction of the shape of the three-dimensional object is highly sophisticated.

The technical nature of the utility model

In view of the prior art disclosed herein, the purpose of the present utility model is to provide a multilayer three-dimensional sheet material model that allows easy and accurate physical construction of a differently complex model with high precision of the contour of the constructs model. The utility model also relates to a system for producing a three-dimensional sheet material model.

The problem is solved with a multilayer three-dimensional model of sheet material, which consists of “n” number of forming elements arranged on top of each other in a predetermined sequence.

According to the utility model, each molding element consists of an inner and outer portion, interconnected by structural connections and separated by a dividing contour. Each part of the forming element comprises at least one opening in which a structural guiding element is located and secures it to the respective parts of the forming elements arranged in a coordinate system of the spatial object, wherein the plurality of internal parts of the forming elements is a spatial object of sheet material, and the plurality of outer parts of the forming members form a sheet matrix.

The multilayer three-dimensional model is characterized in that the structural guiding elements are at least one for each of the two parts of the forming elements and may be of different material types and thicknesses.

The multilayer three-dimensional model is also characterized in that the forming elements can be made of different material, for example recycled paper, printing waste, cardboard, glass, plexiglass, etc., respectively, the three-dimensional model can be made by a combination of different materials.

In one embodiment of the multilayer three-dimensional sheet material model according to the utility model, it is possible to use a combination of sheet materials, for example a combination of recycled paper and cardboard, a combination of glass and metal, and other materials of such characteristic.

In another embodiment of the multilayer three-dimensional object, the sheet material is machined bilaterally.

The utility model also relates to a multilayer 3D / spatial / object acquisition system consisting of a photographic means connected to a computer and a printing device, wherein at least one computer module is connected to a scanning module and the computer module is connected by a its side with a production module that includes interconnected printers, routers and cutting devices. The scanning module includes connected photographic, optical, micro and geoscanning devices. It is appropriate to use a laser head CNC platform and / or 3D printers as printers.

The main advantage of the utility model is that it allows the physical reproduction of a multilayered 3D model, with high image quality, in particular with respect to the stacking density of the individual forming elements, which in turn allows for high accuracy and smoothness on the outline,

1735 W as well as the stability needed. The utility model allows two objects to be obtained simultaneously - a sheet of matrix material and a multilayer three-dimensional model / object / of sheet material, the sheet matrix being possible to be used for multiple physical production of a three-dimensional model in material. High image quality is achieved through the use of technical means - computer stations, peripherals capable of scanning and / or converting digital objects, cropping, according to the utility model, with one operation, both parts internal and external of the forming unit are cut simultaneously. an element that constructs two, independent of each other, objects. The utility model allows easy access to any spatial form and its physical construction as a three-dimensional model of sheet material, for example in the form of a three-dimensional puzzle.

The 3D model, obtained according to the utility model, allows the reproduction of such objects of sheet material in the form of printing publications with new features, where the pages of the edition are used simultaneously as a medium of information and as a constructive element (sheet material from which the formers are separated. elements for obtaining the spatial object).

The utility model is extremely suitable for the production of spatial two- and three-dimensional objects, models of sheet material, allowing the use of recycled paper or printing waste.

The utility model allows the forming elements of the sheet matrix to be permanently or temporarily fixed, so that the sheet matrix can be used to reproduce three-dimensional spatial models or reproduce unique spatial objects in material.

Another advantage of the utility model is the fact that the sheet material used can be pre-treated with two-sided (face and back), resulting in the resulting spatial object of sheet material having an additional visual effect, depending on the fact that the angle of view of the object has a colored surface bounded by the outer contour.

Explanation of the annexed figures

The following are examples of embodiments of a three-dimensional model of sheet material illustrated with the help of the accompanying figures as follows:

Figure 1 shows the outer and inner part of the forming element;

Figure 2 shows a monoplastic three-dimensional model of sheet material;

Figure 3 represents a sheet matrix;

Figure 4 shows the thickness of the forming elements of a three-dimensional sheet metal head;

Figure 5 shows the thickness of the forming elements of a three-dimensional model (architectural building) of sheet material;

Figure 6 presents a system for obtaining a multilayer spatial, preferably three-dimensional, sheet material model.

Examples of implementation of the utility model

The spatial object of sheet material according to the utility model is presented by preferred examples for the implementation of a spatial object of different complexity and shape, and the described essential features of the individual objects - sheet matrix and spatial object of sheet material do not restrict the use of other constructive, similar elements by which spatial objects of the same quality and characteristics are obtained.

The multilayer three-dimensional model of sheet material consists of n number of forming elements 1, with a thickness of 2, determined by the particular used sheet material, which are arranged on top of each other in a predetermined sequence, whereby each forming element 1 of the spatial object of The sheet material consists of an inner part 3 and an outer part 4 connected together by means of structural connections 5, the inner 3 and the outer part 4 being separated from each other by a dividing contour. In each of the parts 3 and 4 of the forming element are provided respectively openings 7 and 8, in which is placed a structural

1735 Ul guiding element and fixing them to the corresponding parts of the forming elements 3 and 4 in the coordinate system of the spatial object. The described shaping and mutual arrangement of the forming elements results in a multilayer three-dimensional model, characterized by high precision of the outer contour, with the set of internal parts 3 of the forming elements 1 forming a three-dimensional model of sheet material and the set of outer parts 4 of the forming elements - sheet matrix.

The multilayer three-dimensional model of sheet material is obtained with the help of a system of technical means, whose consistent placement and connection allows to obtain spatial objects with high precision of the contour. The system includes a scanning module, which can be implemented by known technical means, such as photo, video, optical, micro or geoscanning techniques, allowing for contactless 3D scanning and capture of an existing object. The 3D digital model may also be obtained in other known ways by being processed in a computer module comprising a computer station connected to a database storage server, wherein the computer module is also connected to a production module consisting of printing devices and a router, preferably using CNC platforms with a laser head and 3D printers.

Application of utility model

According to the utility model, the multilayer three-dimensional sheet material model has the characteristics of a three-dimensional digital model generated by software designed to obtain a polygonal network of information captured by scanning and optical systems from points corresponding to the spatial elevations of an existing object. The processing of the 3D digital model involves its introduction in geometric form, which is performed with the help of specialized software, in which the geometric form contains the entire 3D dimensional model and represents its matrix, the outer contour of the 3D digital model is defined by many points, at appropriately at the same time the three-dimensional digital model and the geometric shape, and defines a dividing contour separating the two objects from each other.

Plane cross sections are drawn through the three-dimensional digital model, which establishes constructive connections between it and the matrix. At the same time constructive forms are constructed - openings intended for placement of structural guiding elements by which the forming elements of the sheet matrix and the spatial object of sheet material are fixed. When using a specialized software product, the processing of the 3D digital model continues with its cutting with a plane that intersects it in a predetermined direction and with a step that is determined depending on the sheet material that will be used to physically construct the spatial object from the sheet material. The resulting forming elements are pre-prepared using a suitable program and then cut from sheet material, preferably using a CNC platform with a laser head. The cut-out shaping elements are arranged in a predetermined sequence according to their marking, with the help of the structural guiding elements being fixed until the necessary stability of the spatial object is achieved. For the complete construction of the spatial object of sheet material, the outer part of the forming elements is separated from the inner part by breaking the pre-set structural connections. As a result of the operations performed in that sequence, two separate objects, respectively a spatial three-dimensional model of sheet material representing an exact copy of the three-dimensional digital model and a sheet matrix, are simultaneously obtained.

Claims (8)

Claims 1. A multilayer three-dimensional sheet material model consisting of η number of forming elements arranged on top of one another in a predetermined sequence, characterized in that 1735 Ul each of the forming elements (1) consists of an inner (3) and an outer (4) part connected together by structural links (5) and separated from each other by a dividing circuit (6), each part (3, 4) of the forming element (1) comprises at least one opening (7, 8) in which a structural guiding element is arranged for fixing to the respective parts (3, 4) of the forming elements (1), arranged in the coordinate system of the spatial an object in which the plurality of the inner parts (3) of the forming members (1) represent left space object of sheet material, and the set of outer parts (4) of the forming elements (1) forms a sheet matrix. Multilayer three-dimensional model according to claim 1, characterized in that the structural guiding elements are at least one for each of the two parts (3, 4) of the forming elements (1). Multilayer three-dimensional model according to claim 1, characterized in that the forming elements (1) are of different material, for example recycled paper, printing waste, cardboard, glass, plexiglass, etc. Multilayer three-dimensional model according to claim 1, characterized in that the three-dimensional model is made up of combining different types of materials, for example recycled paper and cardboard, glass and metal, etc. A multilayer three-dimensional model according to claim 1, characterized in that the sheet material is machined bilaterally. 6. A spatial object receiving system consisting of a photographic means connected to a computer and a printing device, characterized in that at least one computer module is connected to a scanning module, the computer module being connected in turn to a production module comprising a connected printing device, router and cutting devices. System according to claim 6, characterized in that the scanning module comprises interconnected photographic, optical, micro- and geoscanning devices. System according to claim 6, characterized in that the printing devices are a CNC platform with a laser head and / or a three-dimensional printer.