WO2017065634A1

WO2017065634A1 - Load-bearing module

Info

Publication number: WO2017065634A1
Application number: PCT/RU2016/000166
Authority: WO
Inventors: Александр Васильевич НОВИЧКОВ
Original assignee: НОВИЧКОВА, Светлана Александровна
Priority date: 2015-10-12
Filing date: 2016-03-24
Publication date: 2017-04-20
Also published as: RU2015143297A

Abstract

The present invention comprises a load-bearing module device. The technical problem and technical goal of the present invention consists in creating a load-bearing module device exhibiting enhanced strength characteristics, ease of assembly, disassembly and transportation, and affordable production. The technical result is achieved in a load-bearing module design which includes rings and rods, distinguished in that the rings form a spheroidal core of the load-bearing module, said core having regular rectangular pyramids, which are formed by the rods, installed thereon, the pyramids being disposed symmetrically. The module may be used as a construction element; in aviation for the installation of propulsion units, radar dishes, and supports for helicopter rotors; in cosmonautics for the deployment of spatial antennas on the ISS; in automobile transport for the installation of propulsion units (wheels) as a support element of the suspension; in maritime transport as the support elements of hulls, catamarans, trimarans, quadmarans, etc.

Description

BEARING MODULE

FIELD OF TECHNOLOGY

The present invention is a carrier module device. The supporting module can be used for the manufacture of household products: tables, podiums, pendant lights, as well as for use in other areas in which structural elements with increased strength and easy assembly are required.

BACKGROUND OF THE INVENTION The task of creating structural elements with optimal geometry, which would allow the use of these elements in construction and other fields, is quite relevant. At the same time, these elements should have a simple assembly and an economical method of production.

Currently, most of these structures are made in the form of a parallelepiped or a rectangular parallelepiped. However, these structures are often not strong enough due to the uneven distribution of the load throughout the structure. In addition, there is a need to create elements with a different geometry that can be used as connecting or supporting systems. In the prior art, in particular, a structural system is made of plastic volumetric spherical joints. The system is made of two connectable plastic hemispheres and a central plate connected by a single screw, which allows easy assembly of the system. From 8 to 12 beams (supports) with an adjustable angle of inclination are placed in the cavity between the hemispheres (patent document ITNA20080024 (A1), published 26.1.2002).

It seems that this structural system has insufficient strength due to the fact that polymer plastic materials are used as construction materials, which limits the scope of the construction.

In addition, the design has a rather complicated device - elements of complex spatial shape are used as elements - two hemispheres with threaded sections, a central disk with an intermediate hole and side cavities to accommodate beams (supports), as well as beams (supports) with specific geometry. This complicates the production process of the structural system.

one

SUBSTITUTE SHEET (RULE 26) Known design, including many rods and connecting means that connect the ends of the rods. The design is a volumetric frame made in the form of an octahedron with triangular faces. It is indicated that this design can be used as a demonstration stand (patent document JP2002336099 (A), published November 26, 2002).

This design has the aforementioned drawback - because of its device in some applications, the main load can be on one of the rods or one of the faces, which can lead to deformation or damage to the structure. In addition, the scope of this design is quite limited.

Thus, the prior art is not known design with a similar device and geometry, which would meet the requirements for quick assembly and disassembly, strength and efficiency.

SUMMARY OF THE INVENTION

The technical problem and the technical result of the present invention was to create a carrier module device, which would have improved strength characteristics, ease of assembly, disassembly and transportation and an economical method of production.

The technical result is ensured by the design of the carrier module, which includes rings and rods, characterized in that the rings form the core of the carrier module in the form of a spheroid, consisting of rings, on which the regular triangular pyramids formed by the rods are installed, and the pyramids are located symmetrically with respect to one point - center.

Improving the structural strength characteristics is ensured by creating a supporting module, made in the form of a spheroid and pyramids, and having increased strength.

Convenience of assembly, disassembly and transportation is ensured due to the fact that the module is a collapsible design, which takes up little space during transportation, assembly and fastening of the elements of the supporting module is carried out through the use of threaded joints, bolts and nuts.

Elements of the module are simple elements: rings, rods, lugs and discs, which can be manufactured on conventional equipment.

2

SUBSTITUTE SHEET (RULE 26) BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 - The geometric shape of the core of the carrier module. FIG. 2 - The geometric shape of the carrier module.

FIG. 3 - The geometric shape of the core of the bearing module formed by circles (rings).

FIG. 4 - The geometric shape of the carrier module, including the core of circles (rings).

FIG. 5 is a front view of the carrier module.

FIG. 6 is a side view of the carrier module.

DETAILED DESCRIPTION OF THE INVENTION

This description is an example implementation of the present invention and cannot limit the essence of the technical solution in the form in which it is claimed in the patent application.

The basis of the present invention is the idea of preserving the supporting properties of the cube (the supporting points of the cube are located at its vertices) and at the same time replace the edges of the cube with the supporting elements located inside the cube. In the middle of the cube is the core, from which the supporting elements emanate, resting against the vertices of the cube.

Geometrically, the design of the supporting module includes a cuboid-shaped core and pyramid-shaped supporting elements, with the base of the pyramids being the triangular faces of the cuboctahedron, and the edges abut against the vertices of the cube.

The geometric shape of the core is shown in FIG. one.

The geometric shape of the carrier module is shown in FIG. 2.

Unlike the cube, the cuboctahedron and the trihedral pyramid are rigid geometric figures, the combination of the cuboctahedron and eight trihedral pyramids is also a rigid geometric figure, which ensures the strength of the carrier module.

In the present invention, the core of the carrier module has the shape of a spheroid, which is formed by circles, at least some of which have the same diameter; the circles touch each other, the planes of the rings are mutually perpendicular. The geometric bonds of the spheroid are equivalent to the geometric bonds of the cuboctahedron: all vertices of the cuboctahedron are at the centers of the circles. The edges of the pyramids in this case in

3

SUBSTITUTE SHEET (RULE 26) the base will rest against these circles “normally”, that is, their extensions pass through the centers of these circles.

If we replace the circles with rings, and the edges of the pyramids with steel rods, we get a rigid frame - a bearing module, similar to a bearing module with the shape of a “cuboctahedron and eight pyramids”.

The geometric shape of the core of the carrier module formed by circles (rings) is shown in FIG. 3.

The geometric shape of the carrier module, comprising a core of circles (rings) is shown in FIG. four.

The following describes the device of the carrier module in accordance with the present invention.

The bearing module is a structure made of rings 1 and rods 2. Each ring 1 is equipped with holes in which the rods 2 and nuts 6 are placed, which allow the rings 2 to be fastened to each other. The holes can be spaced at regular intervals relative to each other.

Rings 1 and rods 2 can be connected to each other in any other way known from the prior art.

Three rods 2, placed in the corresponding holes of the rings 1, form regular triangular pyramids. Pyramids can be located symmetrically relative to the center point of the module. The height of the pyramids can vary indefinitely. The dimensions of the spheroid formed by the rings 1 can also be changed by resizing the rings 1 used.

The angle of inclination of the rods 2 can be from 0 to 90 degrees.

The tops of the rods 2 are connected to each other by a bundle 4, which is a spatial structure with three holes to accommodate the rods 2 and a central hole to accommodate the support 5. The rods 2 are placed in the bundle 4 so that the imaginary intersection point of the rods 2 is the top of a regular triangular pyramid . The imaginary intersection point of the rods 2 is also a carrier or reference point of the module.

On the bunch 4 are installed support or mounting elements. Supporting elements allow the mounting module to be mounted on the surface, and fastening elements can be used to place other structural elements.

four

SUBSTITUTE SHEET (RULE 26) Support or mounting elements may include discs 3, which are connected to the bundle 4 by means of a support 5.

Elements of the carrier module, such as rings 1, rods 2, and other elements, may be made of steel or any other material. The sizes of a nucleus having the shape of a spheroid and pyramids can change, which leads to a change in the load-bearing properties of the module. In particular, changing the size of the pyramids for a given base means changing the angles between the edges and the base in the range from zero to ninety degrees. The larger the angle, the farther away the peripheral bearing points from the spheroid-shaped core. A spheroid can be made of rings, at least some of which have different diameters.

In this example embodiment of the invention, there is provided a construction of a carrier module in which the axis of the pyramids pass through the center of the spheroid and all the pyramids are the same. However, this description should not be construed as limiting the implementation of the design of the carrier module.

In particular, embodiments of the carrier module are possible in which the pyramids have different heights. For example, the lower pyramids may have a greater height than the upper ones. In this case, the carrier points of the module will not be located at the vertices of the cube, but at the vertices of the truncated pyramid. The heights of the pyramids may not pass through the center of the spheroid. In this case, the device of the carrier module will have axial symmetry, in which the axis of symmetry will be a vertical or horizontal axis.

The vertices of the pyramids can also be located inside the spheroid, which allows you to get the bearing points for an object located inside the carrier module. The module can be used as a building element, in aviation for the location of propulsors, "plates:" radar, bearings for rotors of helicopters; in astronautics - for deployment of spatial antennas on the ISS; in automobile transport - for the location of propulsors (wheels), as a supporting element of the suspension; in maritime transport as supporting elements for hulls, catamarans, trimarans, quadromarans.

5

SUBSTITUTE SHEET (RULE 26)

Claims

CLAIM

1. The bearing module, which includes rings and rods, characterized in that the rings are attached to each other and form the core of the bearing module in the form of a spheroid with triangular faces, the rods are attached to the rings and form regular triangular pyramids, and the pyramids are located symmetrically.

2. The bearing module according to claim 1, characterized in that the tops of the rods are connected by a bundle.

3. The bearing module according to claim 2, characterized in that the module is equipped with support and mounting elements, which are located on top of regular triangular pyramids formed by rods, and are attached to the bundle.

4. The bearing module according to claim 3, characterized in that the supporting and mounting elements are disks that are attached to the bundle by means of bolts.

5. The bearing module according to claim 1, characterized in that the module is made of steel or other high-strength material.

6. The carrier module according to claim 1, characterized in that the angle of inclination of the rods in the carrier module is from 0 to 90 degrees.

7. The bearing module according to claim 1, characterized in that at least part of the rings have different diameters.

8. The bearing module according to claim 1, characterized in that the pyramids have different heights.

9. The bearing module according to claim 1, characterized in that the pyramids are located symmetrically with respect to the center of the spheroid.

10. The carrier module according to claim 1, characterized in that the pyramids are located relative to the vertical or horizontal axis of the carrier module.

1 1. The bearing module according to claim 1, characterized in that the vertices of the pyramids are located inside the spheroid.

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SUBSTITUTE SHEET (RULE 26)