RU1831550C - Multi-store large-panel building - Google Patents

Abstract

Use: in prefabricated multi-storey buildings under static and dynamic loads. SUMMARY OF THE INVENTION: The wall panels of a building are made with vertical bevelled bevelled along the entire height, on top and bottom of which there are couplings for mounting the studs of the connecting elements. The floor slabs have cutouts in the corners above and below to accommodate the plates of the same connecting elements. The wall panels are connected to each other and to the floor slabs by an elastic-flexible connection, which provides either elastic couplings or the elasticity of the connecting elements themselves. Through the nodes of the connection, vertical tensioned ropes can be passed, and the outer walls of the building can be equipped with inserts that can be connected in the same way as panels. 4 s.p. f-ly, 13 ill.

Description

The invention relates to the field of construction, namely to prefabricated large-panel multi-storey buildings.

The aim of the invention is to reduce the complexity of building installation and improve the working conditions of structures under the influence of static and dynamic loads.

In FIG. 1 is a perspective view of a fragment of a building at the level of one floor; in FIG. 2 - composite coupling and its placement in a vertical supporting element; in FIG. 3 - connecting element with spikes and diagonal ribs; in FIG. 4 is an angle of the overlap panel with cutouts for positioning a connecting element with a location of ties in the assembly; in FIG. 5 - location of the coupling when mating the vertical load-bearing elements before installation

in them a connecting element with spikes; in FIG. 6 - connection unit for vertical supporting elements (couplings not shown conventionally) and floor slabs; in FIG. 7 is a vertical section through a joint assembly using a puff; in FIG. 8 is a design of another embodiment of a connecting element; in FIG. 9 is a panel connection unit using an elastic flexible connecting element; in FIG. 10 is a vertical sectional view of a panel joining assembly using an elastic-flexible connecting element: FIG. 11 shows a row assembly of panel joints using vertical inserts; in FIG. 12 is an angular panel connection unit using two inserts; in FIG. 13 is a corner assembly for connecting external panels without additional elements.

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A multi-storey large-panel building includes longitudinal and transverse wall panels 1 with couplings 2, separated by inter-floor slabs 3 of the floor and interconnected by connecting elements 4 with spikes 5 located in the couplings 2. Wall panels 1 are made with bevels along the entire height for adjoining at the connection nodes ( Fig. 5). The couplings 2 are located at the corners of the beveled ends of the wall panels 1. The panels 1 and the floor slabs 3 are made rigid, and between the wall panels 1 and between them and the floor slabs 3 elastic resilient connections are formed from the connecting elements 4 and the couplings 2, while the corners of the floor slabs 3 (Fig. 4), cutouts 8 are made on the upper side of the bis of the lower side 7 to accommodate the plates of the connecting elements 4 and the bevels 9, and the spikes 5 of the elements 4 enter the couplings 2 of the wall panels 1 from above and below (Fig. 7) .

The elastic connection is made of a connecting element 4 (Fig. 3) in the form of a rigid plate 10 with diagonal ribs 11, which act as limiters for the movement of the slabs 3, which enter the gap 12 between the plates 3 and the end surfaces adjacent to them (Fig. 6 ), and from couplings 2 made resiliently (Fig. 2) in the form of a box-shaped polyhedral element 13. closed from the end 14. with arcuate dividing walls 15 installed inside it, with a bulge located to the walls of the box-shaped element 13, with the formation a cavity for receiving the tenon 5, wherein the maximum distance A does not exceed the diameter of the stud. The space between the dividing walls 15 and the walls of the box element 13 is filled with elastic material 16.

The elastic flexible connection may include a connecting element 4 made of an elastic material (Fig. 8) with reinforcement 17 around the perimeter and with a protruding part located between the beveled corners 9 of the floor slabs 3. In this embodiment of the joint, the protruding part of the joint 4 will limit the horizontal movement of the floor slabs.

If it is necessary to increase the stability of the building (for example, in particularly seismically active areas), the connecting elements 4 are made with a central hole 18 and a reinforcement 19. In this case, the floor slabs 3 are made with truncated corners 9. The end faces 20 (Fig. 5) of the wall panels 1, holes 18 connecting

elements 4 and the vertical faces of the bevels 9 of the floor slabs 3, an axial channel of the connection nodes is formed, in which a strained rope 21 with fasteners 22 at its ends is placed.

When using the second variant of resilient communication (Figs. 8, 9), a multi-storey large-panel building also includes longitudinal and transverse wall panels 1 with couplings 2, floor slabs 3 and connecting elements 4 with spikes 5 placed in the couplings 2, and with restrictive protrusions 23 placed between the bevels 9 plates 3

5 overlap. The coupling 2 can be made of a pipe segment, any one corresponding to the spike 2. of cross-section and size, and the connecting element 4 is made with reinforcement 17 around the perimeter.

0 In addition, the building may be provided with vertical liners 24 corresponding to the height of the wall panels 1 and having bevels for adjoining the wall panels (Fig. 11) and the liner (Fig. 12).

5 On the top and bottom of the insert 24, in the corners formed by its beveled surfaces, couplings 2 are placed for installing the spikes 5 of the connecting elements 4 and cutouts are made to accommodate the plates of the connecting elements.

A multi-storey large-panel building is constructed as follows.

On the slabs 3 mounted on the foundation, overlap the cutouts 8 in the corners of these

5 plates 3 stack the connecting elements 4 in such a way that their stiffening ribs 11 fit into the gaps 12 between the floor plates 3, while the plates 10 of the connecting elements 4 are laid in cuts 8 flush with the plane of the plates 3. Couplings are mounted on the spikes 5 of the connecting elements 4 2 wall panels 1, while the spikes 5 enter between the dividing walls of 15 couplings 2. On installed

5 wall panels 1 in the couplings 2 with spikes 5 downward install the connecting elements 4, after which on the platforms limited by the ribs 11 of the connecting elements 4, overlap plates 3 are laid so that the lower cutouts 8 of the plates 3 cover flush the plates 10 of the connecting elements 4 The installation of the next floor is carried out in a similar manner.

5, if necessary, to increase the stability and strength of the building when exposed to energetic dynamic loads (for example, seismic), the end of the reinforcing rope 21 is closed into the foundation, and on it in the right amount through

the holes 18 put on the connecting elements 4, after which during installation the rope 21 is placed in the formed vertical channel. After the installation of the building is completed, the rope 21 is tensioned in any known manner and secured.

The installation of the building with the connecting elements 4 made according to the second embodiment is carried out similarly, with the protrusions 23 restricting the movement of the floor slabs 3 being placed between the bevels 9 of these slabs 3.

The installation of liners 24 is carried out similarly to the installation of the outer wall panels 1.

The device allows to increase the reliability of the building under the influence of static and dynamic loads, simplify installation and at the same time reduce the cost of construction by increasing the manufacturability of the assembly, the absence of many manual operations for filling the joints and welding embedded parts. In addition, during the moral aging of a building, the dismantling of its structures makes it possible to completely preserve all the supporting elements and use them for the construction of cottages and rural houses. Especially effective is the erection of buildings of this construction in eliminating the consequences of large earthquakes in seismically active areas.

Formulas of the invention 1. A multi-storey large-panel building including longitudinal and transverse wall rigid panels separated by interfloor rigid floor slabs and interconnected by connecting elements in the form of a plate with spikes for installing them in couplings, characterized in that, in order to reduce the complexity installation of the building and improvement of the working conditions of structures under the influence of static and dynamic loads.

wall panels are made with bevels in the corners along the entire height of the junction with couplings located at the bevels of the panels above and below, and between the wall panels and

floor slabs form elastically flexible couplings between the connecting elements and couplings, and cutouts are made in the corners of the floor slabs at the top and bottom to accommodate the plates of the connecting elements, with the latter having busbars installed in the wall panel couplings.

2. The building according to claim 1, characterized in that the elastic-flexible connection is made in the form of a rigid connecting plate

5 elements with diagonal ribs to limit movements adjacent to the vertical surfaces of the plates in the connection node and entering the gap between the plates, and the couplings are made

0 resilient.

3. The building according to claim 2, characterized in that each elastically flexible coupling is made in the form of a box-shaped polyhedral element with arcuate distribution walls installed inside it, convexly located to the walls of the box-like element with the formation of a cavity to accommodate the type of connecting element,

0 between the walls of the box element and the distribution walls is filled with elastic material.

4. The building according to claim 1. characterized in that the corners of the floor slabs are made in

5 in the form of vertical bevels, and the plate of the connecting element is made of elastic material with reinforcement along the perimeter and with a protruding part for placement of slabs between the bevels.

0 5. Building pop. 1, characterized in that, in order to increase stability, the plates of the connecting elements are made with a central hole for passing strained vertical ropes.

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