RU210975U1 - The dome is pyramidal - Google Patents

Abstract

The utility model relates to the field of construction, namely to the spatial domed composite coatings of industrial, civil and agricultural buildings and structures, as well as small architectural forms.

The technical result provided by the given combination of features is an increase in overall and local rigidity while reducing the dimensions of the constituent shells due to the introduction of additional prefabricated folds and stiffeners into the internal structure of the inventive pyramid-shaped dome.

This problem is solved due to the fact that in a pyramid-shaped dome, which includes elements of the same type, composed of quadrangular shells of double curvature with straight edges forming contour sections of a flat polygonal base, as well as ribs inclined to the base and joining at the central axial vertex, each element is composed of of two lateral and central shells joined to form an inner vertex located at the level between the flat polygonal base and the central axial vertex and connected by a radial rib to the central axial vertex of the dome, as well as a pair of ribs with nearby sections of the polygonal base of the dome.

Description

The utility model relates to the field of construction, namely to the spatial domed composite coatings of industrial, civil and agricultural buildings and structures, as well as small architectural forms.

From the existing list of similar technical solutions, a composite dome coating is known that has a polygonal base contour and is formed by the same type of pyramidal folded elements from triangular panels (AS USSR No. 185039; Folded coating; MKI E04V 7/10; 1966). The disadvantage of this technical solution, which prevents obtaining the technical result provided by the utility model, is the low local rigidity of the coating.

Known coating in the form of a pyramidal dome, having a rectangular base and formed by four hyperbolic shells, docked in the central axial vertex (U.S. Pat. No. 3206895; Domed coating; class 52-15; 1961). The disadvantage of this solution is the low local rigidity of the coating.

The closest in technical essence to the claimed solution is a composite domed coating, including the same type of elements, composed of shells in the form of quadrangular compartments of a hyperbolic paraboloid with straight edges and having a spatial quadrangular contour; moreover, for each of the elements, two adjacent straight edges are made horizontal, form sections of a flat polygonal base and are joined at its corner vertex, and two other adjacent straight edges are made inclined and are joined at the central axial vertex (U.S. Pat. No. 3090162; Dome-shaped coating; class 52-80, 1953). Additional elements of a triangular or rectangular configuration can be introduced between hyperbolic shells. The disadvantages of this technical solution, which impede the obtaining of the technical result provided by the utility model, should be considered low local stiffness, as well as significant dimensions of the components of the hyperbolic shells.

The task to be solved by the claimed utility model is to increase the overall and local stiffness while reducing the dimensions of the component shells.

This problem is solved due to the fact that in a pyramid-shaped dome, which includes elements of the same type, composed of quadrangular shells of double curvature with straight edges forming contour sections of a flat polygonal base, as well as ribs inclined to the base and joining at the central axial vertex, each element is composed of of two lateral and central shells joined to form an inner vertex located at the level between the flat polygonal base and the central axial vertex and connected by a radial rib to the central axial vertex of the dome, as well as a pair of ribs with nearby sections of the polygonal base of the dome.

The technical result provided by the given combination of features is an increase in overall and local rigidity while reducing the dimensions of the constituent shells due to the introduction of additional prefabricated folds and stiffeners into the internal structure of the inventive pyramid-shaped dome.

The essence of the utility model is illustrated by drawings.

In FIG. 1 shows a general view of a pyramidal dome having a hexagonal flat base, as well as its top view.

In FIG. 2 shows possible layout diagrams of a pyramid-shaped dome with a triangular, pentagonal, hexagonal, octagonal and decagonal base, incl. correct, convex or stellate (top views).

The pyramid-shaped dome includes elements of the same type 1, composed of quadrangular shells 2, 3 of double curvature with straight edges. Each element 1 is composed of two side shells 2 and a central shell 3; while the side edges 4 of each of the side shells 2 of the element 1 are made inclined to the polygonal base and are joined in the central axial vertex 5 of the dome, and the contour edges 6, 7 of each of the side and central shells 2, 3 form sections of the polygonal base of the dome. The side and central shells 2, 3 of each element 1 are joined to form an inner vertex 9 located at the level between the flat polygonal base and the central axial vertex 5 and connected by a radial rib 10 to the central axial vertex 5 of the dome, as well as a pair of ribs 8 with nearby sections of the polygonal dome base.

The base of a pyramidal dome can be made in the form of a convex, regular or star-shaped polygon with any number of sides.

The shells 2, 3 of the elements 1 are made in the form of compartments of surfaces of double curvature, are made, for example, of reinforced concrete, are joined to each other along straight edges and are connected along the outlets of the reinforcement by welding, followed by concreting of the joints.

Claims (1)

The dome is pyramidal, including elements of the same type, composed of quadrangular shells of double curvature with straight edges forming contour sections of a flat polygonal base, as well as ribs inclined to the base and joining at the central axial vertex, characterized in that each element is composed of two lateral and central shells docked to form an inner vertex located at the level between the flat polygonal base and the central axial vertex and connected by a radial rib to the central axial vertex of the dome, as well as a pair of ribs with nearby sections of the polygonal base of the dome.

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