RU2161227C1 - Method for erection of buildings of curvilinear shape - Google Patents

Abstract

FIELD: construction. SUBSTANCE: method consists in erection of foundation and attachment of pre-bent reinforcing members to it forming a rigid net. A layer of warmth-keeping lagging is laid on top the net, and unit is applied first to the inner surface of the building and then to the outer one. EFFECT: erection of buildings of various shape. 9 cl, 36 dwg

Description

 The invention relates to the field of construction, in particular to methods of erecting heated, mainly small-sized buildings of various functional purposes: cottages, garden houses, cafes, pavilions, etc.

 A known method of building a building, including the installation of foam plastic panels with wire mesh on them, which are sewn together with one another and grids of adjacent panels, and applying raw concrete to the outer surface of the building (US patent N 4094110, CL E 04 B 1/32 , 1978).

 In this method, foamed plastic panels are elements of fixed formwork, the manufacture of which in the form of a building curvilinear requires a significant number of their sizes, which increases the labor costs for the construction of this structure.

 A known method of erecting a building in which arched elements of an I-beam profile are rigidly connected at the top is installed on prefabricated foundations. A grid is attached to the arched elements with a structure-forming material laid on it and reinforcing rods filled with cementitious material (US Pat. No. 4,352,260, class E 04 1/32, 1980).

 The main bearing element in the known design is the arch, which receives compressive forces and struts from the grid. In buildings with small spans, where the requirements for stiffness can be reduced, the use of profile arched elements will lead to an excessive consumption of material. In addition, the significant weight of the arches requires industrial construction methods using crane equipment.

 The closest analogue to the proposed invention is a method of erecting a building of a curvilinear shape, including making a foundation, installing vertical reinforcing elements on it and attaching them to them at an angle of reinforcing elements of the second direction with the formation of a mesh that forms a given building envelope, and applying shotcrete to the mesh ( U.S. Patent No. 5,305,576, CL E 04 B 1/32, 1994).

 In the known method, the ends of the vertical reinforcing rods are monolithic around the foundation perimeter without first bending them, i.e. straightforward. Then, in the center of the foundation, a special device is installed in the form of a mast with a vertically and horizontally rotating arrow, with the help of which the reinforcing elements are bent and connected to form a mesh, on which shotcrete is subsequently applied.

 The mesh shell in the known method has low rigidity and is able to withstand only a small weight of the shotcrete layer, and therefore, the known method can only be used for unheated buildings.

 The technical task of the present invention is the creation of a mesh shell with pre-curved reinforcing rods, forming a rigid structure with minimal costs for its manufacture and increase the thermal characteristics of the building.

 The problem is solved in that in the method of erecting a building of a curvilinear shape, including the manufacture of a foundation, installation of vertical reinforcing elements on it and joining them at an angle of reinforcing elements of the second direction with the formation of a mesh forming the shell of the building, and the application of shotcrete to the mesh, foundation they are manufactured with reinforcement outlets to which they are preliminarily bent with initial curvature, vertical reinforcing elements corresponding to the curvature of the shell of this direction You, together with the reinforcing elements of the second direction, form a rigid mesh, then at least on the part of the outer surface of the rigid mesh, a heater and a flexible mesh are laid in series, the rods of which are connected to the reinforcing elements of the rigid mesh, the maximum diameter of the rods of which is from 2.1 to 4, 6 diameters of the rods of the flexible mesh, after which a layer of shotcrete is applied to the inner surface of the rigid mesh and then to the outer surface of the flexible mesh.

 The shotcrete concrete layer applied to the inner surface of the rigid mesh is made of a variable thickness increasing towards the base of the shell, and the thickness of the shotcrete concrete outer layer is from 0.3 to 0.7 times the thickness of the inner layer.

 At least part of the vertical reinforcing elements are made of two rods, between which the reinforcing elements of the second direction are located.

 The foundation of the building is made in the form of a pile grillage, tape or in the form of a plate.

 A rigid grid can be made in the form of a spherical or hyperbolic or toroidal shell.

 A rigid grid can be made in the form of a shell of arbitrary shape.

 The rigid shell can be made in the form of spherical segments articulated in height in at least two tiers, while the base of the shell can be located below ground level.

 The hard shell can be made in the form of at least two segments articulated along the vertical planes.

 The rigid shell can be made in the form of spherical segments articulated along radial and / or parallel vertical planes.

 Visors above the entrance and / or window openings are in the form of a cylindrical or spherical, or hyperbolic shell.

The invention is illustrated by drawings, which depict
in FIG. 1 - section of the shell of a building being erected by the proposed method;
in FIG. 2 is a general view of a building with a rigid grid made in the form of a spherical shell;
in FIG. 3 - section 1-1 in figure 2;
in FIG. 4 - a fragment of a rigid grid of a spherical shell;
in FIG. 5 is a general view of a building with a rigid grid in the form of a hyperbolic shell;
in FIG. 6 is a section 2-2, in FIG. 5;
in FIG. 7 is a section 3-3 in FIG. 5;
in FIG. 8 is a general view of a building of three jointed spherical segments;
in FIG. 9 is a section 4-4 in FIG. 8;
in FIG. 10 is a general view of a building of three spherical segments;
in FIG. 11 is a longitudinal section of the building of FIG. eight;
in FIG. 12 - a building with the location of the base of the shell below ground level;
in FIG. 13, 14 - general view of the building from multi-tier spherical segments;
in FIG. 15, 17 - a building of spherical sectors articulated on radial planes;
in FIG. 16 is a cross-sectional view of a building of spherical sectors joined along radial planes;
on Fig - section 6-6 in Fig. 15, 17;
in FIG. 19 is a plan of an open-loop building;
in FIG. 20, 22, 24 - embodiments of a building with toroidal shells;
in FIG. 21 is a section 7-7 in FIG. 20;
in FIG. 23 is a section 8-8 in FIG. 22;
in FIG. 25, 26, 28 - 36 - shells of arbitrary shape;
in FIG. 27 is a section 9-9 in FIG. 26;
in FIG. 29 is a section 10-10 in FIG. 28;
in FIG. 36 is a section 11-11 in FIG. 35.

 The construction of the building is curved in the following way.

 The foundation 1 is made in the form of a slab, tape or in the form of a pile grillage, predominantly from monolithic concrete with releases of reinforcement.

 Pre-made reinforcing elements 2 and 3 with an initial curvature corresponding to the curvature of the shell of the building. Vertical reinforcing elements 2 are attached to the outlets of the foundation reinforcement by means of an annular element, the cross section of which exceeds the cross section of the reinforcing element of the second direction.

 Depending on the shape of the building’s shell, the elements of the second direction 3 intersecting with the vertical elements 2 can be horizontal and intersect at right angles with vertical elements, or inclined, located at an angle to the vertical elements other than the right angle.

 The vertical reinforcing elements connected to the elements of the second direction form a rigid grid 4, the shape of which corresponds to the shape of the shell of the building.

 Then, predominantly plate insulation 5 is laid on the rigid mesh 4 and a flexible mesh 6 is placed on top of it.

 Insulation can be installed on the outside of the rigid grid only on part of the surface of the shell. For example, on the protruding parts of the shell, forming a visor above the entrance, the insulation may not be laid.

 The rods of the flexible mesh with reinforcing elements of the rigid mesh through flexible ties passing through the insulation layer 5.

 Depending on the dimensions of the building’s shell, the adopted mesh cell, and the current loads, the maximum diameter of the rigid mesh rods is from 2.1 to 4.6 the diameter of the flexible mesh rods.

 After connecting flexible and rigid grids, a layer of shotcrete concrete is applied to the inner surface of the latter, forming a supporting shell structure. Then a layer of shotcrete is applied from the outside of the shell, while providing additional rigidity and increasing the thermal insulation properties of the building.

 The proposed method of erecting a building with a curved shape allows it to be widely used for various types of shells, mainly of "small forms", for which the requirement is prevailing not so much to cover large spans, but rather to create an architecturally expressive structure.

 Variants of the most characteristic shells using this method are given below.

 The rigid grid of the building can be made in the form of a spherical shell round in plan 7 of vertical meridian reinforcing elements connected to reinforcing elements of the second direction, in this case horizontal.

 Part of the vertical elements 8 may consist of two reinforcing rods, between which the horizontal reinforcing elements 3 are passed. Between the vertical elements 8 there are at least two vertical elements 3.

 In the middle part of the rigid grid along its contour, openings 9 are made, edged with additional reinforcement. An entrance aperture 10 is made in the lower zone of the rigid grid, the edges of which are connected by internal walls-partitions 11, united by an internal annular partition 12 to form a terrace 13 or a loggia of the building.

 The rigid mesh can also be made in the form of a hyperbolic shell 14 with a cantilevered overhang 15 above the entrance to the building.

 Variants of performing a rigid grid in the form of articulated spherical segments are also possible.

 In FIG. 8 shows a wavy shell in plan, consisting of three spherical segments 16, articulated to each other along vertical parallel planes.

 The rigid mesh of the extreme segment is made with a notch in the form of a spherical diagon formed by the intersection of horizontal 16 and inclined 17 planes. At the same time, the surface of the shell thus obtained performs the function of a fence 18 and a canopy 19 of the terrace. A rigid grid can be made in the form of multi-tiered articulated spherical segments: in two tiers 20 or in three tiers 21 with the formation of a pyramidal structure of the building.

 To increase the edge rigidity of the openings of the rigid mesh, visors 22 are arranged, which are also part of a spherical segment bounded by a vertical plane and intersecting with it in the lower zone by an inclined plane.

 With a multi-tiered arrangement of rigid grids in the form of spherical segments, the base of the shell 23 can be located below ground level.

 Hard grids in the form of spherical shells can be joined along radial planes 24 around the cylindrical shell 25 to form the perimeter of the building in plan in the form of a semicircle 26, sector 27, or open circle 28.

 In the cylindrical shell 25, a staircase may be located, the natural lighting of which is carried out by the device of a light lamp 29, the height of which exceeds the height of the spherical segments adjacent to the cylindrical shell.

 In public buildings in the Central cylindrical shell can be arranged pool 30.

 Rigid meshes can also be made in the form of toroidal shells having a constant cross section 31 or variable 32.

 The manufacture of a rigid grid in the form of a toroidal shell of variable cross-section allows you to shift the central annular part of the shell from the center and thereby ensure a variety of layouts of interior spaces separated by radial partitions.

 The inner surface of the toroidal shell can be limited by a cylindrical surface 33, the coating of which can also be made in the form of a rigid grid of spherical shape 34.

 The proposed method of erecting a building of a curved shape allows you to produce it not only with simple geometric shapes such as a sphere, cylinder, torus, but also any other arbitrary shape, the surface of which is formed by pairing several shapes.

 A rigid grid of a building can be made in the form of groups of shells installed on a common foundation, each of which consists of vertical and horizontal reinforcing elements that form shells in the form of a single-band hyperboloid 35. These shells are evenly installed around the perimeter of the foundation and form the racks of the building. In the center of the building there is a similarly shaped shell of a larger size 36, which is both a rack and a hall of the building. These shells are connected by the upper parts with a toroidal shell 37 mounted on them, the central part of which is overlapped by a sphere 38.

 A rigid grid can be formed in the form of segments 39, articulated in a single tier along parallel vertical surfaces, and in height with a smooth shell 40 of negative Gaussian curvature.

 The rigid grid can also be made in the form of a three-tiered shell, the lower two tiers of which are a spherical shell of radially spaced wave-shells 41 of double curvature, and the upper tier is a hanging shell 42.

Buildings constructed by the proposed method can be teardrop-shaped 43, conjugated with a group of annular shells 44 or consist of several domed shells 45 with vertical planes cut off perpendicular to the planes, segments running at an angle of 60 ^o and conjugated to the adjacent domed shells, ring shells 46 or three-beam shells 47 negative Gaussian curvature.

 A rigid grid can be formed by joining spherical sectors 48 with different diameters arranged in a spiral plan.

Claims (9)

 1. A method of erecting a building of a curved shape, including making a foundation, installing vertical reinforcing elements on it and attaching them to them at an angle of reinforcing elements of the second direction with the formation of a mesh forming a given building envelope, and applying shotcrete to the mesh, characterized in that the foundation vertical reinforcing elements are manufactured with reinforcement outlets, to which they are preliminarily bent with an initial curvature corresponding to the curvature of the shell of a given direction together with reinforcing elements of the second direction, a rigid mesh, then at least part of the outer surface of the rigid mesh is laid sequentially insulation and flexible mesh, the rods of which are connected with reinforcing elements of a rigid mesh, the maximum diameter of the rods of which is 2.1 to 4.6 of the diameter of the rods flexible mesh, after which a layer of shotcrete is applied to the inner surface of the rigid mesh and then to the outer surface of the flexible mesh.  2. The method according to claim 1, characterized in that the shotcrete concrete layer applied to the inner surface of the rigid mesh is made of a variable thickness increasing toward the base of the shell, while the thickness of the outer shotcrete concrete layer is 0.3-0.7 thickness inner layer.  3. The method according to p. 1 or 2, characterized in that at least a portion of the vertical reinforcing elements are made of two rods, between which the reinforcing elements of the second direction are located.  4. The method according to any one of claims 1 to 3, characterized in that the foundation of the building is made in the form of a pile grillage, slab or strip.  5. The method according to any one of claims 1 to 4, characterized in that the rigid grid is made in the form of a spherical, or hyperbolic, or toroidal, or arbitrary shell.  6. The method according to any one of claims 1 to 4, characterized in that the rigid grid is made in the form of at least two spherical segments articulated on vertical planes.  7. The method according to any one of claims 1 to 4, characterized in that the rigid mesh is made in the form of spherical segments articulated in height in at least two tiers, while the base of the shell can be located below ground level.  8. The method according to any one of claims 1 to 4, characterized in that the rigid grid is made in the form of spherical segments joined along radial planes and / or parallel vertical planes.  9. The method according to any one of claims 1 to 8, characterized in that the visors above the inlet and / or window openings are made in the form of a cylindrical, or part of a spherical, or hyperbolic shell.

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