WO2007120071A1 - Device for forming three-dimensional bodies - Google Patents

Abstract

The invention relates to devices for forming three-dimensional bodies which can be used for producing dismountable kid stuff and in building construction for mounting small pavilions, houses etc. The inventive device for forming three-dimensional bodies comprises a module element (1) embodied in the form of a three-dimensional polyhedron, for example in the form of a cub or parallelepiped provided with thought non-crossing holes (2). In order to combine the individual module elements (1) into a single solid body, the device comprises rods (3) and keys (4, 5) whose cross-section shape mates the cross-section shape of the holes (2). The transverse size of the rods (3) and the keys (4, 5) corresponds to the transverse size of the holes, wherein the elements are jointed in a preloaded manner associated with the sufficiently easy assembling thereof. The cross-section of the holes (2), rods (3) and the keys (4, 5) can be circle- or triangle- or square-shaped. The keys (4, 5) are embodied in such a way that they have different lengths since they are assigned to different purposes, i.e. the key (4) is used for adjusting the position of rods (3) during assembling and the key (5) for disassembling the assembled structure.

Description

 Device for creating volumetric bodies

The field of technology.

The utility model relates to devices with which it is possible to form three-dimensional bodies and can be used both for the production of collapsible toys for children, and in construction for the assembly of small pavilions, houses, etc. State of the art

A known building element in the form of a wall hollow concrete stone having the shape of a rectangular parallelepiped (RF patent Ns 2166037, IPC 7 E04C1 / 40, 2000).

The disadvantage of this building element is that the connection with the adjacent elements located nearby is not rigid enough, provided only through the use of a solution that binds adjacent elements.

Known building element made in the form of a plate with grooves on its longitudinal sides for connection with other building elements (AS USSR N2831936, IPC 3 E04C1 / 10, 1981)

The disadvantage of this solution is the flat shape of the building element, which requires two-layer addition to fill the space between the rows of building elements with additional heat and sound insulating material to ensure comfortable thermal conditions in the building.

A known container design containing a set of parts, each of which is made in the form of a three-dimensional figure and has nodes and elements for connecting parts into a single structure, formed by grooves, protrusions and a recess in the bottom for docking with the neck of the next part (patent RF Ns2169111, MPK 7 A63PZZ / 10, 2001)

The disadvantage of this solution is excessive overload with additional elements that do not carry a special functional load. The technical problem.

The problem solved by the utility model is the creation of a compact, fairly lightweight, technologically advanced, easy-to-use device designed both for creating full-scale building structures and for use as a children's designer, taking into account changes in the overall dimensions of individual elements of the device.

The problem is solved due to the fact that a device has been developed for creating volumetric bodies, containing a modular element made in the form of a volumetric polyhedron with through disjoint holes, rods and keys, the cross-sectional profile of which corresponds to the profile of the sections of the holes.

The transverse dimension of the rods and keys corresponds to the transverse dimension of the holes of the modular element.

The element is made in the form of a cube or parallelepiped. The cross section of the holes and rods is in the form of a circle, or a triangle, or a square, or another polygon. The keys are made of different lengths.

Non-intersecting holes have a through exit to the corresponding hole of the polygon face, made in the form of a longitudinal groove.

The technical result from the use of the utility model is that the created device for creating volumetric bodies containing a modular element, made in the form of a volumetric polyhedron with through disjoint holes, rods and keys, allows you to easily and quickly connect modular elements of the device using rods, thus forming volumetric bodies of any shapes and configurations.

Due to the fact that the cross-sectional profile of the rods and keys corresponds to the cross-sectional profile of the holes, the assembly can be carried out in a short time, while reliable connections of the elements to each other will be ensured, since the rods are inserted into the hole with an interference fit.

The location of the holes in disjoint planes allows you to form shapes of any configuration. The presence of keys allows, if necessary, to disassemble the assembled and reassemble it without violating the integrity of each of the modular elements of the device.

FIG. 1 is a general view of the device (in a particular embodiment with longitudinal slots).

FIG. 2 is a section along one of the disjoint holes of the assembled two elements with a key for adjusting the position of the rod during assembly.

FIG. 3 is a section along one of the disjoint holes of the assembled two elements with a disassembly key.

FIG. 4 is an isometric view of the assembled elements forming a spatial angle.

An embodiment of the claimed invention.

A device for creating volumetric bodies contains a modular element 1 made in the form of a volumetric polyhedron, for example, in the form of a cube or parallelepiped with through disjoint holes 2. To connect individual modular elements 1 into a single unit and create a volumetric body, the device contains rods 3 and keys 4, 5, the cross-sectional profile of which corresponds to the cross-sectional profile of the holes 2. The transverse dimension of the rods 3 and keys 4, 5 corresponds to the transverse size of the holes, while connecting the elements ditsya "vnatyag" but provide sufficient ease of assembly.

The cross section of the holes 2, rods 3 and keys 4, 5 may take the form of a circle, or a triangle, or a square, or another polygon. Keys 4, 5 are made of different lengths, since they are designed for different purposes - key 4 - to adjust the position of the rod 3 during assembly, and key 5 - to disassemble the assembled structure.

Non-intersecting holes 2 can have a through exit to the corresponding hole of the face 6 of the polygon, made in the form of a longitudinal groove 7 (see Fig. 1). The presence of such a groove 7 will facilitate the dismantling of the structure.

The device can be made of known materials, preferably lightweight, for example by casting. Usage example.

The assembly of a three-dimensional spatial body is carried out as follows:

The elements 1 are installed in the direction in which it is necessary to ensure the construction of the structure (three directions can be selected at once, and thus the angle of the structure is formed). Then, the rod 3 is installed in the corresponding hole 2 of one of the assembled modular elements 1 and the key 4 is installed in such a position that part of the rod is in the first element 1, and part in the second (see figure 2). In the same way, the subsequent modular elements 1 are connected to increase the length (or height).

If the device is used as a toy, then the connection of the elements 1 can be carried out in different directions, while forming a variety of shapes. You can disassemble the assembled volumetric body by applying the key 5 and pushing the rod 3 outward (see Fig.Z)

Claims

The utility model formula. 1. A device for creating volumetric bodies, containing a modular element made in the form of a volumetric polyhedron with through disjoint holes, rods and keys, the cross-sectional profile of which corresponds to the profile of the cross-sections of the holes of the modular element. 2. The device according to claim 1, characterized in that the transverse size of the rods and keys corresponds to the transverse size of the holes of the modular element. 3. The device according to claim 1, characterized in that the modular element is made in the form of a cube or parallelepiped. 4. The device according to claim 1, characterized in that the cross section of the holes, rods and keys has the form of a circle, or a triangle, or a square, or another polygon. 5. The device according to claim 1, characterized in that the keys are made of different lengths. 6. The device according to claim 1, characterized in that the disjoint holes have a through exit to the corresponding hole of the polygon face, made in the form of a longitudinal groove.