RU235005U1 - Folded module - Google Patents

Abstract

The utility model relates to the field of construction, namely to spatial structural folded modules used as composite coverings for buildings and structures, as well as elements of composite screen systems with a complex relief scattering and absorbing surface (acoustic ceilings, walls, stage canopies for concert halls and recording studios, etc.). The technical result ensured by the given set of features is a reduction in the labor intensity of module manufacturing by reducing the standard sizes and decreasing the number of component elements. This technical result is achieved by the fact that in a folded module having two orthogonal planes of mirror symmetry, outlined by a closed flat polygonal contour and composed of four quadrangular ruled shells connected along the edges, two opposite mirror-symmetrical corner vertices of the closed polygonal contour are connected by an L-shaped mirror-symmetrical rib located in one of the planes of mirror symmetry of the module; wherein the top of the L-shaped rib is connected to the polygonal contour by a pair of identical arc-shaped ribs located in the orthogonal plane of mirror symmetry of the module, and the constituent shells are made in the form of mirror-symmetric sections of a conoid.

Description

The utility model relates to the field of construction, namely to spatial structural modules used as composite coverings of buildings and structures, small forms, as well as elements of continuous composite screen systems with a complex relief scattering and absorbing surface (acoustic ceilings and walls, stage canopies of concert halls and recording studios, etc.).

From the existing list of similar technical solutions, a spatial pyramidal module is known, made in the form of a tetrahedral pyramid with angular triangular corrugations of variable cross-section, as a result of which the flat base of the module has a cross-shaped star-shaped outline (USSR patent No. 301415; Cross-ribbed coating; E04B 1/08; 1971).

The disadvantages of this technical solution, which prevent the achievement of the technical result provided by the utility model, are the high deformability of the flat faces of the module and the extended range of constituent elements.

A dome-shaped module is known, which has a general pyramidal outline, a star-shaped multi-beam base contour and is composed of radial folds converging at the central axial apex (Ayrapetov D.P., Zavarihin S.P., Makotinsky M.P. Plastics in Architecture. - Moscow: Stroyizdat, 1981. - p. 40, fig. top right).

The disadvantages of this technical solution are high deformability and a large variety of folded module elements, which determines the low operational qualities of the structure.

A dome-shaped pyramidal module is known, which has a star-shaped three-beam flat polygonal base of equal rectilinear sections and is composed of different types of quadrangular shells of double curvature of the hypar type with straight edges, where L-shaped ribs are installed in the corner vertices of the base every other one, joined at the central axial vertex and alternating with inclined ribs connecting the central axial vertex with the intermediate vertices of the polygonal base (Trushchev A.G. Formation and design of spatial coverings of buildings in architectural design: Textbook. - M .: Publishing House MArHI, 1987. - p. 38, Fig. 1.26-g).

The disadvantages of the known solution include a significant number of ribs converging at the central axial vertex and the different types of components of the quadrangular shells, which ultimately leads to significant labor intensity in the manufacture of elements and installation of the pyramidal module.

The closest in terms of the set of essential features to the claimed technical solution is a mirror-symmetrical dome-shaped composite module used as a roof for buildings and structures, formed by different types of hyperbolic shells joined along polygonal edges connecting the sides of a flat polygonal contour in directions orthogonal to the contour (USSR patent No. 747954, E04B 7/08, 1980). The disadvantage of this solution is the different types and significant number of hyperbolic elements within the dome-shaped shell of the module.

The task that the claimed utility model is aimed at solving is to reduce the labor intensity of module manufacturing by reducing the standard sizes and decreasing the number of component elements.

This problem is solved due to the fact that in a folded module having two orthogonal planes of mirror symmetry, outlined by a closed flat polygonal contour and composed of four quadrangular ruled shells connected along the edges, two opposite mirror-symmetrical corner vertices of the closed polygonal contour are connected by an L-shaped mirror-symmetrical rib located in one of the planes of mirror symmetry of the module; in this case, the vertex of the L-shaped rib is connected to the polygonal contour by a pair of identical arc-shaped ribs located in the orthogonal plane of mirror symmetry of the module, and the constituent shells are made in the form of mirror-symmetrical sections of a conoid.

In a folded module, a closed contour can be made octagonal; in this case, the top of the L-shaped edge is connected by a pair of identical arc-shaped edges with the opposite corner vertices of the contour.

In a folded module, a closed contour can be made hexagonal; in this case, the top of the L-shaped edge is connected by a pair of identical arc-shaped edges with the midpoints of the opposite parallel sides of the contour.

The technical result provided by the given set of features is a reduction in the labor intensity of module manufacturing by reducing the standard sizes and decreasing the number of component elements.

The essence of the utility model is explained by drawings.

Fig. 1-2 shows variants of a folded module with a convex and non-convex octagonal contour, as well as possible layout schemes for joining modules (general view).

Fig. 3-4 shows variants of a folded module with a non-convex and convex hexagonal contour, as well as possible layout schemes for joining modules (general view).

The folded module has two orthogonal planes of mirror symmetry, is outlined by a closed flat polygonal contour 1 and is composed of four quadrangular ruled shells 2 connected along the edges. Two opposite mirror-symmetrical corner vertices 3 of the polygonal contour 1 are connected by an L-shaped mirror-symmetrical edge 4 located in one of the planes of mirror symmetry of the module. In this case, the vertex 5 of the L-shaped edge 4 is connected to the polygonal contour 1 by a pair of identical arc-shaped edges 6 located in the orthogonal plane of mirror symmetry of the module, and the constituent shells 2 are made in the form of mirror-symmetrical sections of a conoid.

In the folded module, the closed contour is made octagonal; in this case, the vertex 5 of the L-shaped rib 4 is connected by a pair of identical arc-shaped ribs 6 with the opposite angular vertices 7 of the contour 1.

In the folded module, the closed contour is made hexagonal; in this case, the top 5 of the L-shaped rib 4 is connected by a pair of identical arc-shaped ribs 6 with the midpoints of the opposite parallel sides 8 of the contour 1.

The mirror-symmetrical flat polygonal contour of 1 folded module can be made convex or non-convex. In this case, the resulting prefabricated structures based on the module can have a common planar or curvilinear outline.

Conoidal shells of 2 folded modules are made, for example, from reinforced concrete, are joined to each other along straight and arcuate edges and are connected along the reinforcement outlets by welding, followed by concreting of the joints.

Claims (3)

1. A folded module having two orthogonal planes of mirror symmetry, outlined by a closed flat polygonal contour and composed of four quadrangular ruled shells connected along the edges, characterized in that two opposite mirror-symmetrical corner vertices of the closed polygonal contour are connected by an L-shaped mirror-symmetrical rib located in one of the planes of mirror symmetry of the module, wherein the vertex of the L-shaped rib is connected to the polygonal contour by a pair of identical arc-shaped ribs located in the orthogonal plane of mirror symmetry of the module, and the constituent shells are made in the form of mirror-symmetrical sections of a conoid. 2. A folded module according to item 1, characterized in that the closed contour is made octagonal, and the top of the L-shaped rib is connected by a pair of identical arc-shaped ribs with opposite corner vertices of the contour. 3. A folded module according to item 1, characterized in that the closed contour is made hexagonal, and the top of the L-shaped rib is connected by a pair of identical arc-shaped ribs to the midpoints of the opposite parallel sides of the contour.

Images