RU205021U1 - Spherical module - Google Patents

Abstract

The utility model relates to the field of construction, namely to spherical structural modules used as spherical dome coverings, shells of tanks / gas tanks, as well as prefabricated residential blocks of settlements in hard-to-reach territories and in zones of extreme natural and climatic conditions, incl. spherical living compartments of orbital space multi-module stations. The technical result provided by the given set of features is to reduce the labor intensity of mounting a spherical shell by increasing the number of sides of the constituent elements and reducing the number of spherical elements joining at the vertices. This problem is solved due to the fact that in a spherical module, formed by identical polygonal elements of a spherical surface, docked along arcuate edges, the elements are made in the form of pentagonal spherical compartments, the arcuate edges of which are outlined by sections of geodesic lines, of which four edges are made in pairs identical; wherein one of the corner vertices of each element is the vertex of joining four adjacent similar elements, and the other four corner vertices of the element are the vertices of joining three adjacent elements; moreover, the full spherical shell of the module is made up of twenty-four identical pentagonal elements.

Description

The utility model relates to the field of construction, namely to spherical structural modules used as spherical dome coverings, shells of tanks / gas tanks, as well as prefabricated residential blocks of settlements in hard-to-reach territories and in zones of extreme natural and climatic conditions, incl. spherical living compartments of orbital space multi-module stations.

From the existing list of similar technical solutions, a spherical shell of a gas holder is known, composed of the same type of lenticular spherical leaf segments, which have an additional subdivision in length and docked along the meridians of the sphere with the formation of two opposite vertices-poles on its surface (Architecture of industrial enterprises, buildings and structures: a designer's guide / V.A. Drozdov, L.F. Goldengersh, E.S.Matveev and others; under the general editorship of Kim N.N. - 2nd ed., Revised and supplemented - M .: Stroyizdat, 1990. - p. 617, fig. 32.15).

The disadvantage of this technical solution, which prevents the technical result, which is provided by the utility model, is the complex cutting of the composite lenticular spherical elements, as well as the significant laboriousness of the exact connection of numerous vertices of the constituent elements in the two vertices-poles of the spherical shell.

A spherical shell of a gas holder is known, composed of different-sized rectangular sheet strips, the longitudinal edges of which are oriented along its meridians (Kostov K. Architecture of engineering structures and industrial interior. - M .: Stroyizdat, 1983. - p. 131, Fig. 4.46-b).

The disadvantage of this technical solution, which prevents the obtaining of the technical result, which is provided by the utility model, is the diversity and complex cutting of the quadrangular strips that make up the shell, and, consequently, the significant laboriousness of its manufacture and installation.

The closest in technical essence to the claimed utility model is an equal-element spherical breakdown, where the total spherical surface is made up of 30 identical diamond-shaped compartments docked along the edges so that in two opposite corner vertices of each compartment, five adjacent compartments converge, and in the other two opposite corner vertices - three each. (Faibishenko V.K. Metal structures: Textbook for universities. - M .: Stroyizdat, 1984. - p. 213, fig. 186-a).

The disadvantage of this technical solution, which prevents the obtaining of the technical result, which is provided by the utility model, is a significant number of spherical elements joining at the tops of the shell, which ultimately determines the laboriousness of its installation.

The problem to be solved by the claimed utility model is to reduce the labor intensity of mounting a spherical shell by increasing the number of sides of the constituent elements and reducing the number of spherical elements joining at the vertices.

This problem is solved due to the fact that in a spherical module, formed by identical polygonal elements of a spherical surface, docked along arcuate edges, the elements are made in the form of pentagonal spherical compartments, the arcuate edges of which are outlined by sections of geodesic lines, of which four edges are made in pairs identical; wherein one of the corner vertices of each element is the vertex of joining four adjacent similar elements, and the other four corner vertices of the element are the vertices of joining three adjacent elements; moreover, the full spherical shell of the module is made up of twenty-four identical pentagonal elements.

The technical result provided by the given set of features is to reduce the labor intensity of mounting a spherical shell by increasing the number of sides of the constituent elements and reducing the number of spherical elements joining at the vertices.

The essence of the utility model is illustrated by drawings.

FIG. 1-2 shows a general view of the spherical module from various angles.

The spherical module is formed by the same pentagonal elements 1- sections of the spherical surface, docked along the arcuate edges 2,3,4, which are outlined by sections of geodetic lines; of them, four edges 2 and 3 are identical in pairs. In this case, one corner vertex 5 of each element 1 is the vertex of joining four adjacent similar elements 1, and the four remaining corner vertices of element 1 are the vertices of joining three adjacent elements 1; moreover, the full spherical shell of the module is made up of twenty-four identical pentagonal elements 1.

The spherical shell of the inventive module is made, for example, of multilayer composite materials with an internal foamed insulating insulation. It is possible to manufacture the prefabricated shell of the module from hot-formed metal sheet elements 1 with their subsequent connection along the contour arcs 2-4 by welding.

Spherical modules can collectively form three-dimensional composite objects of various spatial configurations, sequentially joining each other by known methods. At the same time, the fully assembled design of a spherical module can provide its completely autonomous, isolated life support as a volumetric component of a composite structure.

Claims (1)

The module is spherical, formed by identical polygonal elements of a spherical surface, docked along arcuate edges, characterized in that the elements are made in the form of pentagonal spherical compartments, the arcuate edges of which are outlined by sections of geodesic lines, of which four edges are identical in pairs; wherein one of the corner vertices of each element is the vertex of joining four adjacent similar elements, and the other four corner vertices of the element are the vertices of joining three adjacent elements; moreover, the full spherical shell of the module is made up of twenty-four identical pentagonal elements.

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