RU62409U1 - EXTERIOR WALL OF THE COTTAGE - Google Patents

Abstract

The invention relates to the field of individual construction and can be used in the construction of low-rise buildings: cottages, cottages, garages, etc. The proposed technical solution includes a protective layer in the form of brick walls 5, 6, the middle layer 7 of foam, located between the columns 3 (figure 1 -3) and the inner layer 8 of sheet material. The wall has a frame of monolithic reinforced concrete, made in the form of a series of columns 3 inside the wall, installed in increments on the foundation of the building, connected by a monolithic reinforced concrete belt 9 (Fig. 4). The brick columns 12, the insulation 10 and the inner layer 8 form the formwork for the columns 3. There is a flexible connection in the form of rods 14 between the columns 3, the belt 9 and the walls 5, 6. The corner column 3 is provided with an L-shaped insulation 18, and the columns 12 here installed at an angle of 90 ° (figure 5). There is also a L-shaped corner 19 made of stainless steel for sealing the junction of the columns 12. If it is necessary to build the second and subsequent floors, instead of the monolithic belt 9, flat plates 20 are installed, equipped with outlets 21 of the reinforcement passing through the rods 16 of the columns, as well as thermal liners 24. 4 dependent paragraph of the formula, 10 illustrations.

Description

The invention relates to the field of construction, in particular, to the construction of buildings with a supporting frame, and can be used in the construction of low-rise buildings, such as cottages, summer houses, garages, etc.

Known designs of external walls, consisting of external brickwork and a heat-insulating layer in the form of aerated concrete blocks (see US Pat. RF No. 2148129 class. 7 E 04 B 2/02, 1998). The disadvantages of such designs are the costs of transporting the blocks, raising them to the floors, battle, etc.

The closest analogue to the claimed technical solution is an outer wall containing a protective layer of small blocks, a middle layer of foam concrete and an inner layer of sheet materials connected by a protective layer (see US Pat. No. 24481 for utility model, Cl .. 7 E 04 V 2/02, 2001).

The main disadvantage of the analogue is the reduced structural strength. The objective of the claimed technical solution is to increase strength, providing the possibility of erecting buildings directly at the construction site, which significantly reduces costs while ensuring strength and comfort.

The technical result is achieved by the fact that in the known outer wall containing a protective layer of small blocks, the middle layer of foam concrete and the inner layer of sheet materials connected by a protective

layer, there is a frame of monolithic reinforced concrete, made in the form of a series of columns installed with a step inside the wall on the foundation, interconnected by a monolithic reinforced concrete belt around the perimeter of the building.

In addition, the technical result is achieved by the fact that along the perimeter of the cross section of each middle column there are columns of brick, and a heater is mounted between the protective layer and the columns with a monolithic belt, and the columns and insulation form a permanent formwork for the column.

Further, the technical result is achieved by the fact that the reinforcing casing of the column and the monolithic belt are connected to the protective layer by flexible elements passing through the insulation.

The technical result is achieved by the fact that the corner column is equipped with an L-shaped insulation, the columns of brick are installed at an angle of 90 °, and a L-shaped corner made of stainless steel is mounted at the point of contact from the side of the column.

The technical result is also achieved by the fact that the monolithic reinforced concrete belt is made in the form of flat slabs covering the column, having reinforcing outlets passing through the reinforcing cage of the columns, and diamond-shaped and triangular cavities filled with thermal liners of heat-insulating material, the width of the slabs being equal to the total wall thickness.

The installation of columns inside the wall with a monolithic reinforced concrete belt significantly increases the strength of the outer wall and the entire building as a whole.

The installation of insulation between the protective layer and columns with a monolithic belt eliminates the "cold bridges", increases comfort.

Flat slabs with thermal liners additionally strengthen the frame of the wall during the construction of the second and subsequent floors with simultaneous thermal insulation of the building.

The proposed wall design of the cottage is very simple in execution, has increased strength while providing comfort and insulation and allows you to perform all the work directly on the construction site, which significantly reduces the complexity of the construction.

The following is an example of the implementation of the claimed technical solution, illustrated by the drawings.

Figure 1 shows a floor plan of a building; figure 2 - node "A" in figure 1; figure 3 is a section along aa of figure 2; figure 4 is a section along BB of figure 2; figure 5 - node "B" in figure 1; figure 6 is a section along bb In figure 1; in Fig.7 is a section along G-G of Fig.1; in Fig.8 is a section along DD DD of Fig.1; figure 9 shows a flat plate (key 20); figure 10 - connection of the plates with the middle column.

The building of the cottage, which includes the proposed external wall, consists of a strip foundation 1, in which reinforcing bars 2 are installed at the locations of the columns 3. Inside the building there is a main wall 4. The claimed construction of the external wall consists of a protective layer, represented by a longitudinal brick wall 5 and transverse brick

wall 6, installed on the outer contour of the foundation 1, the middle layer 7 of foam concrete with low bulk density, located between the columns 3. The inner layer 8 of the outer wall is made of sheet material, for example of gypsum fiber sheets. Columns 3 are installed on the foundation 1 with a step and are an integral part of the wall. On top of the column are connected with a monolithic reinforced concrete belt 9 around the entire perimeter of the building. A heater 10 is installed between the belt 9 and the walls 5, 6. Between the machines 5, 6 and the surface of the columns 3 a heater 11 is installed from an effective heat-insulating material. Along the perimeter of the cross section of columns 3 are columns 12 of brick. Together with the insulation 10, the inner layer 8, the posts 12 form a fixed formwork for the column 3. The walls 5 and 6 are reinforced with nets 13 in height.

Between the walls 5, 6 at the locations of the columns through the insulation 10 installed flexible elements 14 in the form of rods. These rods pass inside the columns 3 and brick columns 12 and are made of stainless metal. In addition, the columns 12 are interconnected by nets 15. The reinforcing cage of the column 3 is represented by rods 16 and clamps 17. The rods 16 are connected to the rods 2 of the foundation 1. The rods 14 are also installed between the monolithic belt 9 and the walls 5, 6.

The presence of rods 14 ensures the stability of the entire building.

At the intersection of the longitudinal and transverse walls, a L-shaped insulation 18 of effective heat-insulating material is installed.

Columns 12 are installed here at an angle of 90 °. In the place of their contact in the cavity of the column 3 installed L-shaped corner 19 of stainless steel for sealing.

During the construction of two or more floors, the need arises for a more rigid connection of columns 3 and walls 5, 6. Instead of a monolithic belt 9, flat plates 20 are installed, overlapping walls 5, 6, columns 12 and covering columns 3. Flat plates 20 have reinforcing outlets 21, which located between the rods of the columns 3. The flat plate 20 contains a cavity 22 and 23 of a diamond-shaped and triangular shape, filled with thermal liners 24 of an effective heat-insulating material. The width of the plate 20 is equal to the thickness of the wall (Fig.9, 10).

Columns 3 are formed in several stages with a height of up to 1000 mm, then, as the walls 5, 6, columns 12 are erected, the next section is formed with a height of 1000 mm and so on to the full height of the floor. Upon reaching the required height of the column 3, a monolithic reinforced concrete belt 9 is constructed along the entire perimeter of the building. Reinforcing rods 14 of the belt 9 are located between the rods 16 of the columns 3. After the concrete reaches the monolithic belt 9 of the required strength, an overlap of hollow slabs 25 is installed on it (Fig. 6). Between the end of the hollow plates 25 and the longitudinal wall 5, a heater 26 is installed.

After concrete reaches columns 3, monolithic belt 9 or flat plates 20 of sufficient strength, a formwork system is produced

buildings for filling walls with monolithic foam concrete with a volume weight of 300 kg / m ³ . A frame formwork system is created by fastening the guide profiles 27 with anchors 28 to the foundation 1 and the monolithic belt 9 or flat plate 20. Rack profiles 29 are installed in the guide profiles 27 by means of self-tapping screws 30. The rack profiles 29 are attached to the walls 5, 6 by connecting elements 31, which are fastened at one end with self-tapping screws 30 on the rack element 29, and at the second end on the masonry net 13 in the walls 5, 6. This creates a frame formwork system of the building, gypsum is attached to the frame using self-tapping screws 30 leaflets 32. Then the formwork is filled with foam concrete 33 with a volume weight of γ = 300 kg / m ³ , which gives the building high heat-insulating properties, fire resistance, durability and comfortable living conditions with a low weight of building envelopes and a significant reduction in labor costs for building construction.

For a thorough filling of the upper part of the wall with foam concrete in the heater 10, a device for filling tubes 34 is provided.

Claims (5)

1. The outer wall of the cottage, containing a protective layer of small blocks, a middle layer of foam concrete and an inner layer of sheet materials associated with a protective layer, characterized in that it has a frame of monolithic reinforced concrete, made in the form of a series of columns inside the wall on the foundation of the building interconnected by a monolithic reinforced concrete belt around the perimeter of the building. 2. The outer wall of the cottage according to claim 1, characterized in that columns of brick are located along the perimeter of the column section from the middle layer, and a heater is mounted between the protective layer and the columns with a monolithic belt, and the columns and insulation form a fixed formwork for the column. 3. The outer wall of the cottage according to claim 2, characterized in that the reinforcing cage of the column and the monolithic belt are connected to the protective layer by flexible elements passing through the insulation. 4. The outer wall of the cottage according to claim 2, characterized in that the corner column is equipped with an L-shaped heater, the columns of brick are installed at an angle of 90 °, and a L-shaped corner made of stainless steel is mounted at the point of contact from the side of the column. 5. The outer wall of the cottage according to claim 1, characterized in that the monolithic reinforced concrete belt is made in the form of covering columns of flat slabs having reinforcing outlets passing through the reinforcing frame of the column, and diamond-shaped and triangular cavities filled with thermal liners of heat-insulating material, the width slabs is equal to the total wall thickness.