RU49046U1 - FENCING WALL DESIGN - Google Patents

Abstract

The utility model relates to the field of construction, namely to the technology of frame-monolithic and prefabricated frame house-building and can be used to warm the load-bearing exterior structures of buildings by eliminating cold bridges in the places where reinforced concrete floors are joined with load-bearing walls and / or columns. The utility model is aimed at solving the problem of creating a simple and cheap building walling for frame-monolithic and prefabricated-frame house building with high thermophysical properties due to the exclusion of cold bridges in the places where reinforced concrete floors are supported with load-bearing elements (walls and / or columns) . To solve this problem, in the enclosing wall structure formed by the end surfaces of the load-bearing elements located between the monolithic reinforced concrete floor floors, between which the blocks fastened with mortar are placed, and having a heater, according to the utility model, the blocks are made protruding outward with respect to the end surfaces of the load-bearing elements made in the form of walls and / or columns, at a distance of at least 1/6 of the width of the block, and the insulation is located in niches whose walls are vertically vertical us projecting end surfaces of the blocks and the carrier elements, and horizontal - the upper and lower surfaces of the projecting units and the end faces of concrete slabs. If the blocks are displaced outward by a distance equal to half the width of the blocks, the end surfaces of the monolithic reinforced concrete floors of the enclosing wall structure are provided with a support frame rigidly connected to them, which is a corner located parallel to the end surface of the reinforced concrete floor, the reinforcement sections are welded perpendicular to it, and the blocks are made resting on corner.

Description

The utility model relates to the field of construction, namely to the technology of frame-monolithic and prefabricated frame house-building and can be used for warming load-bearing external structures of buildings by eliminating cold bridges at the junctions of reinforced concrete floors with load-bearing elements (walls and / or columns)

The problem of increasing the level of thermal insulation of building envelopes is very significant, since heat losses through the building structures along the cold bridges account for up to 80% of all heat losses in buildings (see TSP 23-305-99-SarO "Energy Efficiency in Residential and Public Buildings. Standards for the Thermal Protection of Buildings" )

One of the ways to increase the level of thermal protection of buildings in frame-monolithic housing construction is the use of multilayer panels with effective insulation.

Known enclosing wall structure in the form of a multilayer wall, used in the construction of prefabricated monolithic external walls of residential buildings (see RF patent No. 2193635 according to class E 04 B 1/16, publ. November 27, 2002). The design contains a facade plate, on the inner surface of which a layer of insulation is fixed using anchor elements, on which the reinforcing cage is located. As a heater, polystyrene foam 200 mm thick is used.

However, this design is expensive and requires significant labor costs in the manufacture. The thermophysical properties of this design are low due to the presence of a cold bridge at the interface between the facade plate and the wall panels. Besides,

an increase in the thickness of the insulation along the entire facade of the building up to 200 mm leads to a sharp rise in the cost of the entire structure.

The task of eliminating cold bridges at the junction of the wall with the coating plate was solved in the wall structure (see RF patent No. 2190734 according to class E 04 B 1/38, publ. 10.10.2002), containing the outer, facing, wall layer, inner, continuous carrier, wall layer, middle, insulation layer of the wall, coating plate resting on the bearing layer of the wall, insulation layer laid on the coating plate. Apertures are made in the inner bearing layer of the wall so that their lower mark coincides with the vapor barrier layer laid on the coating plate, and the height of the apertures is less than or equal to the thickness of the insulation, while the openings themselves are filled with insulation, and the width of the walls between the openings is determined by their bearing capacity for perception of loads from the parapet.

However, this design is not intended for monolithic-frame and prefabricated frame housing construction.

Closest to the claimed is the enclosing wall structure (see RF patent No. 2148129 according to class E 04 B 2/02, publ. 04/27/2000), containing an inner layer of blocks placed between monolithic reinforced concrete floors of the floors and an outer layer of brickwork. The blocks are made of aerated concrete and interconnected by reinforcing meshes. The design contains a heater located in the openings - cold bridges in the place of interfacing of the floor slab with the wall. This design is intended for block housing construction.

However, the design does not solve the problem of effective thermal protection due to the presence of insulation only in floor slabs. In addition, the implementation of the outer layer in the form of brickwork significantly increases the cost of the entire building.

The utility model is aimed at solving the problem of creating a simple and cheap building walling for frame-monolithic and prefabricated-frame house building with high thermophysical properties due to the exclusion of cold bridges at the junctions of reinforced concrete floors with load-bearing elements (walls and / or columns) .

To solve this problem, in the enclosing wall structure formed by the end surfaces of the load-bearing elements located between the monolithic reinforced concrete floor floors, between which the blocks fastened with mortar are placed, and having a heater, according to the utility model, the blocks are made protruding outward with respect to the end surfaces of the load-bearing elements representing walls and / or columns, at a distance of not less than 1/6 of the block width, and the insulation is located in niches, the walls of which are vertically ar They are indicated by the butt protruding surfaces of the blocks and load-bearing elements, and horizontally by the lower and upper protruding surfaces of the blocks and the end surfaces of the reinforced concrete floors.

If the blocks are displaced outward by a distance equal to half the width of the blocks, the end surfaces of the monolithic reinforced concrete floors of the enclosing wall structure are provided with a support frame rigidly connected to them, which is a corner located parallel to the end surface of the reinforced concrete floor, the reinforcement sections are welded perpendicular to it, and the blocks are based on corner.

The utility model is illustrated by drawings, in which Fig. 1 is a general view of a wall enclosure, Fig. 2 is an embodiment of a wall structure with a displacement of blocks by a distance equal to half the block width, and Fig. 3 is a section A-A and B-B figure 2.

In the drawings:

1 - monolithic reinforced concrete interfloor overlap, 2 - end surface of the supporting column, 3 - end surface of the bearing monolithic wall, 4 - blocks, 5 - niche for insulation, 6 - insulation, 7 - corner, 8 - pieces of reinforcement (reinforcement outlets), 9 the layer of fastening solution, b is the distance by which the blocks 4 are extended and, accordingly, the thickness of the insulation 6, d is the width of the blocks 4, h is the depth of the cold bridges.

Enclosing wall structure is made as follows. After the erection of the cast-in-place reinforced concrete frame of the building, consisting of supporting structures of internal walls, columns, monolithic interfloor reinforced concrete flooring, a layer of blocks 4 is mounted, which can be either gas silicate (foam silicate) or cellular expanded clay concrete. At the same time, the blocks are mounted protruding outward relative to the end surfaces of the bearing walls 3 and / or the supporting columns 2 (see Fig. 1). The displacement of the blocks is determined by calculation, based on the value of the required heat engineering resistance R _{0 of the} supporting structures for a specific climatic zone of the Russian Federation, consisting of heavy reinforced concrete and a layer of insulation. According to SP 23-101-2000 “Design of thermal protection of buildings”, the required heat engineering resistance R _{0 of} such structures must be at least 5.0 m ² · ° C / W for the northern climatic zone with a heating period of 10300 ° C days .. Maximum distance , on which the blocks can be shifted, should not exceed half the width of the block (for safety reasons) (see figure 2).

As a result of the displacement of the blocks 4, niches 5 are formed, the walls of which vertically are the protruding end surfaces of the blocks 4, the end surfaces of the bearing walls 3 and / or the supporting columns 2 (see Figs. 1 and 2), and the lower and upper protruding horizontally

the surfaces of blocks 4 and the end surfaces of reinforced concrete floors 1. In niches 5, insulation 6 is placed, for example, of polyurethane foam, thereby excluding cold bridges at the junctions of reinforced concrete floors 1 with bearing walls 3 and / or bearing columns 2. The thickness of insulation 6 is determined by the distance b , on which the blocks 4 are advanced and depends on the climatic zone and the materials used.

On the outer surface of blocks 4 and insulation 6, a facade insulation and a protective layer can be applied, for example, in the form of plaster, facing tile or facing ceramic brick, which do not affect the thermal characteristics of the building. At the same time, the thickness of the facade insulation is calculated based on the need for heat insulation for a given climatic zone and the materials used.

In the case of using gas silicate blocks with a width of d = 300 mm (see Fig. 1), extended by a value of b = 100 mm and having a polyurethane foam insulation (thereby eliminating cold bridges) in the resulting niches with a thickness of b = 100 mm and a front insulation with thickness = 75 mm, the inner plaster and the protective layer of plaster 10 mm thick (not shown in the drawings), the thermal resistance will be 5.68 m ² · ° C / W, i.e. 0.68 units more than recommended by standards.

In the case of using blocks with a specific heat resistance of blocks higher than that of gas silicate blocks (for example, cellular blocks of expanded clay concrete), with a width of d = 200 mm, with their extension to the width of the block and the foam insulation b = 100 mm (see Fig. 2, 3), the internal plaster, the facade insulation = 100 mm and the facing layer of plaster with a cross section of 10 mm (not shown in the drawings), the thermal resistance in the places of the cold bridges will be be at least 4.0 m ² · ° C / W., which is for the climatic zone.

Saratov region is quite acceptable, since the required thermal resistance R ₀ should be equal to 3.2 m ² · ° C / W.

The claimed constructive solution of wall fencing allows:

- completely eliminate the cold bridges in the supporting structures of buildings with the least labor and material costs;

- increase the heating performance of the building in accordance with the requirements of SNiP II-3-79 *, SP 23-101-2000 and TSP 23-305-99-SarO;

- do not change the design and architectural solutions of the facade;

- not to reduce the strength characteristics of the supporting structures of the building;

- reduce the volumetric weight of walling;

- increase the "commercial space" throughout the building;

- not to complicate, laid down by the project, the technology of erection of building envelopes.

For example, for a 10-story residential building with a building area of 500m ² and apartment height of 3 m, the increase in commercial space will be 175 m ² , savings on the volume of masonry of external walls from gas-silicate blocks - up to 263 m ³ , reduction of the section of facade insulation by 40-50% , additional insulation in niches - up to 83 m ³ .

Thus, the enclosing wall structure is easy to manufacture, cheap, has high thermal properties, ensuring uniform distribution of thermal resistance due to the exclusion of cold bridges at the junctions of reinforced concrete floors with load-bearing walls and / or columns.

Claims (2)

1. The enclosing wall structure formed by the end surfaces of the load-bearing elements located between the monolithic reinforced concrete floor floors, between which the blocks fastened with mortar are placed, and having insulation, characterized in that the blocks are made protruding outward with respect to the end surfaces of the load-bearing elements made in the form of walls and / or columns, at a distance of not less than 1/6 of the block width, and the insulation is located in niches, the walls of which are vertically formed by end protruding surfaces s blocks and bearing elements, and horizontal - the upper and lower protruding surfaces of the blocks and the end faces of concrete slabs. 2. The enclosing wall structure according to claim 1, characterized in that the end surfaces of the monolithic reinforced concrete floors are provided with a support frame rigidly connected to them, which is a corner located parallel to the end surface of the reinforced concrete floor, the reinforcement sections are welded perpendicular to it, and the blocks are protruding outwardly at a distance equal to half the width of the block, and leaning on a corner.