RU204604U1 - Structural slab - Google Patents

Abstract

The utility model relates to the field of construction, namely to planar structural slabs and spatial structures of vaulted, domed and complex shapes. The technical result to which the claimed utility model is aimed and which is provided by the given set of features is an increase in the local and general stiffness of the claimed structural slab. due to the introduction of additional stiffeners and giving the resulting volumetric structure of the structure complete geometric immutability. This problem is solved due to the fact that in a structural slab, which includes docked with each other quadrangular shells of double curvature with straight edges, adjacent of which are connected along the edges in a continuous folded layer , bounded by two ribbed cellular belts, where one belt is formed by triangular cells, and the opposite one is diamond-shaped; moreover, each pair of vertices of any triangular cell of one belt is connected by normal edges with the two most distant from each other vertices of the corresponding opposite diamond-shaped cell of the other belt, and the middle of any edge of each of the triangular cells of one belt is connected by two pairs of internal ribs with four adjacent sides of the corresponding opposite diamond-shaped cell another belt.

Description

The utility model relates to the field of construction, namely to planar structural slabs and spatial structures of vaulted, domed and complex shapes.

From the existing list of similar technical solutions, a structural slab is known, which includes pyramidal blocks with a square base, composed of four shells of the same type in the form of a hyperbolic paraboloid with straight edges (Lubo L.N., Mironkov B.A. Plates of regular spatial structure. - L .: Stroyizdat , 1976. - p. 88, fig. 25c.). The disadvantage of the known solution lies in the low bending stiffness, deformability of the resulting composite structure and, as a result, the need for rigid fixation of the tops of the pyramids in the plane of the upper chord with additional flattening panels or rod elements.

Also known is a lamellar structural slab, including quadrangular compartments of a hyperbolic paraboloid, connected along the lateral inclined edges and fixed at the vertices for rigidity with a flat plate (USSR inventor's certificate No. 846685; Lamellar structural slab; E04C 2/30; 1981). The disadvantages of the known solution, which impede the obtaining of the technical result, which is provided by the claimed utility model, should be considered the low overall spatial rigidity of the structure, which depends entirely on the rigidity of the flat release plate.

The closest in technical essence to the claimed solution is a structural plate, including docked with each other quadrangular shells of double curvature with straight edges, adjacent of which are connected along the edges in a continuous folded layer, bounded by two ribbed cellular belts, where one of the belts is formed by triangular cells, and the opposite one is diamond-shaped; moreover, each pair of vertices of any triangular cell of one belt is connected by normal edges with the two most distant from each other vertices of the corresponding opposite rhomboid cell of the other belt (USSR inventor's certificate No. 1362799; Structural coating plate; E04B 7/00; 1987)

The problem to be solved by the claimed utility model is to increase the general and local stiffness of the composite structure of the structural slab.

This problem is solved due to the fact that in a structural slab, which includes docked with each other quadrangular shells of double curvature with straight edges, adjacent of which are connected along the edges into a continuous folded layer, bounded by two ribbed cellular belts, where one belt is formed by triangular cells, and opposite-diamond-shaped; moreover, each pair of vertices of any triangular cell of one belt is connected by normal edges with the two most distant from each other vertices of the corresponding opposite diamond-shaped cell of the other belt, and the middle of any edge of each of the triangular cells of one belt is connected by two pairs of internal ribs with four adjacent sides of the corresponding opposite diamond-shaped cell another belt.

The technical result provided by the given set of features is an increase in the local and general stiffness of the claimed structural slab due to the introduction of additional stiffeners and giving the resulting volumetric structure of the structure complete geometric immutability.

The essence of the utility model is illustrated by drawings.

FIG. 1 shows a general view of a structural slab.

FIG. 2 shows a geometrical layout diagram of a slab fragment.

The structural slab includes docked with each other quadrangular shells 1, 2, 3 of double curvature with straight edges. Adjacent shells 1, 2, 3 are joined along the edges in a continuous folded layer, bounded by two ribbed cellular belts 4, 5; the belt 4 is formed by triangular cells, and the opposite belt 5 is diamond-shaped. Each pair of vertices of any triangular cell of the belt 4 is connected by normal ribs 6 with the two most distant from each other vertices of the corresponding opposite rhomboid cell of the belt 5. In this case, the middle of any edge of each of the triangular cells of the belt 4 is connected by two pairs of internal ribs 7 with four adjacent sides of the corresponding opposite diamond-shaped belt cell 5.

In planar structural slabs and spatial structures of a vaulted, dome-shaped and complex shape, the cells of the network of one or both belts can be covered with flat polygonal panels of the corresponding configuration.

Shells 1, 2, 3 of a structural slab are made in the form of compartments of surfaces of double Gaussian curvature, are made, for example, of reinforced concrete, are joined to each other along rectilinear contour edges and are connected by welding outlets of reinforcement.

Claims (1)

Structural slab, including docked with each other quadrangular shells of double curvature with straight edges, adjacent of which are connected along the edges in a continuous folded layer, bounded by two ribbed cellular belts, where one belt is formed by triangular cells, and the opposite one is rhomboid; moreover, each pair of vertices of any triangular cell of one belt is connected by normal edges with the two most distant from each other vertices of the corresponding opposite rhomboid cell of the other belt, characterized in that the middle of any edge of each of the triangular cells of one belt is connected by two pairs of internal ribs with four adjacent sides of the corresponding the opposite rhomboid cell of another belt.

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