RU94245U1 - LARGE-PANEL MULTI-STOREY RESIDENTIAL BUILDING WITH COMBINED WALLS SERIES 93 - Google Patents

Abstract

 1. A large-panel multi-storey building, characterized in that each floor of the building contains internal load-bearing walls, floor slabs and external walls, consisting of internal, insulating and facade layers, while the inner layer is a reinforced concrete wall panel with anchors, and in the same plane a slab is placed reinforced concrete beam, pinched between reinforced concrete wall panels, and which are installed insulation and facade layers, and each facade layer contains vertical internal pilasters in the area of which masonry anchors are installed, associated with anchors of a reinforced concrete wall panel. ! 2. The building according to claim 1, characterized in that the masonry anchors are monolithic with a solution for masonry at the joints of the anchors. ! 3. The building according to claim 1, characterized in that the facade layer is made of brickwork, and the insulation layer is made of polystyrene foam boards. ! 4. The building according to claim 1, characterized in that the masonry anchors are located in the horizontal seams of the inner pilasters of the brickwork of the facade layer. ! 5. The building according to claim 2, characterized in that the masonry anchors are made of galvanized wire. ! 6. The building according to claim 1, characterized in that each reinforced concrete beam is made with rectangular holes. ! 7. The building according to claim 6, characterized in that the openings in the reinforced concrete beams are filled with mineral wool basalt slab to create a fire barrier between floors. ! 8. The building according to claim 1, characterized in that between the reinforced concrete beam and the last row of masonry of each floor is a synthetic tourniquet and mastic tiokolova.

Description

The utility model relates to the field of construction, in particular to multi-storey buildings with reinforced concrete facade elements, intended primarily for large-panel residential buildings of the 93 series and structures, and can be used in the construction of residential and public buildings of high floors.

The external wall of a building is known from the prior art, including elements of fixed formwork in the form of external and internal shells, bonds combining them, insulation located on the inner surface of the external shell, reinforcing cages and a layer of cast concrete between elements of fixed formwork. The shells are made of wood-cement materials, reinforcing cages are installed vertically and horizontally. The vertical frames are separated by groups from each other and the locations of the groups are filled with heavy concrete, forming columns, and the horizontal reinforcing frames are installed in the upper part of the floor wall of the building, their location is filled with heavy concrete, forming a monolithic reinforced concrete belt, and the space between the reinforced concrete columns is filled with a monolithic light concrete (RU 85924, 08.20.2009).

Known external thermal insulation of the wall of the building, including the base in the form of wall structures, thermal insulation layer, coating thermal insulation layer, fasteners. The coating of the heat-insulating layer attached to the wall is made in the form of containers tightly pressed against each other, strained by the weight of the insulation material located in them, or specially filled with gas before the location of the insulation (RU 2291258, 01/10/2007).

The closest analogue of the proposed utility model is a multi-storey building, the outer wall of which is made of an internal supporting layer in the form of single-layer panels of structural concrete or reinforced concrete. The heat-insulating and facing layers are sequentially fixed on the outer side of the single-layer panel, and the connecting elements are made in the form of flexible connections placed in the body of the single-layer panels during installation. The facing layer is made of brick and rests on beams made of structural reinforced concrete, each of which is connected to a single-layer panel and the overlap panel by means of ties made of stainless steel (RU 48558, 10.27.2005).

The disadvantages of the known solutions are:

- Increased requirements for the quality of joints between structural reinforced concrete beams and stainless steel ties, as well as stainless steel ties and a single-layer panel and a floor panel.

- The use of stainless steel, and electrodes for stainless steel in the application of welding leads to higher construction costs.

- The complexity of the building envelope at the construction site, because in the case of welding, additional measures are required to protect the heat-insulating layer made of synthetic materials or expanded polystyrene.

- Mandatory sequential installation of heat-insulating and facing layers.

The problem to which the proposed utility model is directed is to create a large-panel multi-storey building that would eliminate the above disadvantages.

The technical result achieved by the implementation of this utility model is to reduce the complexity of construction, increase the thermal insulation properties of the external fence, improve the quality of construction and installation works due to the simplicity of the proposed solution and reduce the cost of construction through the use of inexpensive building materials, as well as the opportunity to organize more flexibly the installation process of the building, taking into account climatic factors, the exclusion of possible deformative destruction of the facade th layer and improving the maintainability of the design in the field.

The specified technical result is achieved in a large-panel multi-storey building, consisting of: internal load-bearing walls, floor slabs and external walls (combined), consisting of internal, insulation and facade layers. The inner layer of the outer wall is a reinforced concrete wall panel with anchors manufactured in the factory. The insulation layer is made of polystyrene foam slabs installed floor-by-floor on reinforced concrete beams. A facade layer made of brickwork also rests on reinforced concrete beams. The beams are installed in the same plane of the floor slabs and are pinched between the upper and lower reinforced concrete wall panels, so the beams receive the load from the facade and insulation layers floor by floor and transfer it to the inner layer of the combined exterior wall, that is, the loads from the facade and insulation layers from the upper floors do not transferred to the lower floors. In addition, the facade layer made of brickwork (brick) has vertical internal pilasters, while in the horizontal seams of the brickwork in the zone of the pilasters masonry galvanized wire anchors are laid, connected with the anchors of the reinforced concrete wall panel to prevent deformation of the facade layer. Each reinforced concrete beam is made with rectangular openings in order to exclude cold bridges in the area of the junction with the floor slab. The holes in the reinforced concrete beams are filled with mineral wool basalt slab to create a fire barrier between floors. Between the reinforced concrete beam and the last row of brickwork of each floor there is a synthetic tourniquet and mastic thiokol.

The essence of the utility model is illustrated by drawings, where in Fig.1 shows a General view of the outer wall; figure 2 is a section aa in figure 1 of the outer wall with the inner pilasters of brickwork; figure 3 is a section bB of figure 1 fixation of reinforced concrete beams.

Figure 1 shows the device of the combined outer wall. The specified combined wall consists of an inner 1, insulation 6 and a facade 5 layers. The inner layer 1 is a reinforced concrete wall panel with anchors 4 (shown in figure 2), which have a corrosion-resistant coating. This panel is prefabricated from heavy concrete and reinforced in accordance with the working drawings. In the plane of the slab 2, a reinforced concrete beam 3 is installed, which is pinched between the upper and lower reinforced concrete wall panel. Next, the installation process is repeated. Simultaneously with the installation of the building, as well as on the partially or fully mounted box of the building, polystyrene boards of the insulation layer 6 are installed floor-by-stage, brickwork of the facade layer 5 is performed. To seal the upper seam between the beam 3 and the last row of brickwork of the facade layer 5 of each floor, a synthetic tourniquet of the type "Vilaterm" 7 and mastic thiokolova 8.

Figure 2 shows the device of internal pilasters 14 of brickwork to give deformation resistance to the facade layer 5, namely, masonry anchors 9 made of galvanized wire are installed in the corresponding seams of the brickwork. The masonry anchors 9 are inserted into the anchors 4 of the reinforced concrete wall panel and monolithic with the masonry mortar 10.

Figure 3 shows a method of fixing reinforced concrete beams 3 in the design position using ties 11 to install the upper reinforced concrete wall panel. Connection 11 is made of sheet steel, and welded to embedded parts of the floor slab 2 and reinforced concrete beams 3 by electric arc welding 13.

Reinforced concrete beams, on which the insulation layer and the facade layer (brickwork) are based on the floor, are pinched between the lower and upper wall panels in the plane of the floor slab during the installation of the building and transfer the load from the facade layer of the combined external wall to the internal one. This solution eliminates the use of stainless steel ties, and also makes it possible to carry out installation work on the building’s box and the insulation and facade layers both sequentially and with a time offset. That is, the device of the insulation and facade layers can be performed at any convenient time, after partial or full installation of the building's box. All this allows you to more rationally organize the process of construction and installation work and reduce the cost of construction. In addition, the proposed technical solution provides high maintainability of the building under operating conditions.

In addition, in order to give the facade layer greater resistance to deformation inside the brickwork, pilasters were made, and masonry anchors made of galvanized wire monolithic with masonry mortar at the junction with the wall panel anchors were laid in the seams of the brickwork in the pilaster zone.

This constructive solution was successfully tested in the factory on a specially made stand. In the future, the proposed solution was put into practice in the conditions of the construction site, where its high efficiency was proved.

Claims (8)

1. A large-panel multi-storey building, characterized in that each floor of the building contains internal load-bearing walls, floor slabs and external walls, consisting of internal, insulating and facade layers, while the inner layer is a reinforced concrete wall panel with anchors, and in the same plane a slab is placed reinforced concrete beam, pinched between reinforced concrete wall panels, and which are installed insulation and facade layers, and each facade layer contains vertical internal pilasters in the area of which masonry anchors are installed, associated with anchors of a reinforced concrete wall panel. 2. The building according to claim 1, characterized in that the masonry anchors are monolithic with a solution for masonry at the joints of the anchors. 3. The building according to claim 1, characterized in that the facade layer is made of brickwork, and the insulation layer is made of polystyrene foam boards. 4. The building according to claim 1, characterized in that the masonry anchors are located in the horizontal seams of the inner pilasters of the brickwork of the facade layer. 5. The building according to claim 2, characterized in that the masonry anchors are made of galvanized wire. 6. The building according to claim 1, characterized in that each reinforced concrete beam is made with rectangular holes. 7. The building according to claim 6, characterized in that the openings in the reinforced concrete beams are filled with mineral wool basalt slab to create a fire barrier between floors. 8. The building according to claim 1, characterized in that between the reinforced concrete beam and the last row of brickwork of each floor is a synthetic tourniquet and mastic tiokolova.