RU2381334C1 - Frame building - Google Patents

Abstract

FIELD: construction industry.

SUBSTANCE: invention refers to the field of construction industry, to frame building in particular. Frame building contains slabs 1 with cantilevers 2, columns 3, multilayer outer walls bearing against cantilevers 2 and including inner 4, middle and front 5 layers. Each cantilever 2 is designed in form of trapezoid which larger base is located inside floor slab 1. Cantilever 2 span is equal to value not more than outer wall thickness. Middle layer of outer wall includes tridimensional panel made of light thin-walled elements - bands 6, struts 7, trusses, inclined braces 8 formed tridimensional panel. Space between cantilevers 2, inner layer 4 and front layer 5 of outer wall is filled with heat insulation material 9.

EFFECT: improvement of thermal properties of wall, comfort, reliability and bearing capacity of building, reduction of labour costs and gross weight of building.

6 cl, 5 dwg

Description

The invention relates to the field of construction, namely to frame buildings, and can be used in the construction of buildings with self-supporting walls.

Known frame building according to the patent of the Russian Federation No. 2104371, class. EB04B 1/18, 2/28, 1998, containing floor slabs and multilayer outer walls in the form of an outer layer of small pieces, preferably brick, half a brick thick with buttresses protruding into the wall, thermal insulation of the middle wall layer and the inner wall layer. The outer layer of the wall is mounted flush with the end of the floor slab, in the body of which, through the grooves of the wall parallel to its outer edge, through grooves are filled with heat-insulating material, and the thickness of the thermal insulation exceeds the length of the protrusions of the buttresses. As thermal insulation, polystyrene foam, or mineral wool, or foam-gypsum board, or foam board are used. As the inner layer, gypsum tongue-and-groove partition plates or cement-sand blocks can be mounted.

The disadvantages of this building design are unreliable and insufficient wall insulation at the top of the wall adjoining the floor slab, the restriction of the architectural design of the building facade due to horizontal cuts, since the outer layer is mounted flush with the end of the floor slab, high labor costs when installing external walls due to low-tech works with the presence of a large number of different materials in the wall structure.

Known frame building according to the patent of the Russian Federation №2168590, class. EB04 1/18, 5/43, 2001, adopted by the applicant for the prototype. It contains floor slabs, multilayer external walls, including brick and thermal insulation of the middle layer. Each floor slab along the outer perimeter of the building is made with W-shaped consoles, on the ends of which embedded parts are fixed, and the outer layer of the outer wall is placed behind the end of the floor slab and installed on a corner that is rigidly fixed to the embedded parts, the inner layer of the outer plate is made of piece hollow blocks. At least a part of the outer layer of the outer wall is made of brick and reinforced with armoframes or individual rods layer-by-layer multiple to the height of the hollow block of the inner layer of the wall, and each armature is connected to the hollow block by means of a T-shaped plate. The outer wall is made of hollow blocks, the thickness of each block is equal to the thickness of the wall, and the outer edge of the wall is placed behind the end of the W-shaped consoles. In the outer layer of the outer wall, in the plane of the floor slab, additional hollow piece blocks are installed to a height equal to the thickness of the floor slab. The space between the W-shaped consoles and the corner and between the W-shaped consoles and additional hollow blocks, as well as the structural gap between the wall and the bottom of the floor slab, are filled, for example, with polyurethane foam. The voids of the hollow blocks are filled with lightweight foam concrete or, for example, polyurethane foam, and at least part of the horizontal and vertical voids are reinforced with reinforcement with an anti-corrosion coating. Armokaras are installed in the voids of the hollow blocks and are filled with heavy concrete, and on the outer part of the wall a heater is installed, for example, from polyurethane foam, or from expanded polystyrene, or from a mineral wool board, with a protective coating. Hollow blocks are made of structural foam concrete, or of expanded clay concrete, or fired ceramic, each hollow block having dividing walls, in which through holes are made in the center, and two half-holes are made at the upper and lower ends of the walls.

However, the construction of the outer wall of the building requires increased labor costs and does not exclude the implementation of "wet processes", increases the weight of the building.

An object of the invention is the creation of structural elements of a frame building that increase the thermal properties of the outer wall, reduce labor costs when installing external walls, regardless of climatic conditions and time of year of work, namely the elimination of “wet processes” through the use of a spatial panel, increasing comfort, reliability and the bearing capacity of the frame building, reducing the total weight of the building and creating an expressive architectural appearance of the building using temporary materials and structures.

The problem is solved in that in the proposed solution, each console is made in the form of a trapezoid, the larger base of which is placed inside the floor slab, and the overhang of the console is no more than the thickness of the outer wall, and the middle layer of the outer wall includes a spatial panel of light thin-walled elements - belts, racks, ties, braces that formed a spatial panel, and the space between the consoles, the inner layer and the facade layer of the outer wall is filled with insulation.

In addition, the width of the light thin-walled element is equal to the thickness of the outer wall without the thickness of the facade and inner layers of the outer wall, the fastening elements of the facade layer, waterproofing, windproof and vapor barrier layers.

In addition, the outer wall is mounted on the floor slab, with the spatial panel on ¾ parts of its thickness placed on the consoles, and at least ¼ part of its thickness placed on the floor slab.

In addition, the step of placing the racks in the spatial panel is equal to the step of the consoles, and the wall of each light thin-walled element is made with perforation, and the perforation occupies no more than half the wall width of the light thin-walled element.

In addition, the fastening element of the facade layer, which is made of piece blocks, is made in the form of an additional rack of a C-shaped profile and an elastic element, the ends of which are not closed and made in the form of grips, with the additional rack connected to the spatial panel, the ends of the C-shaped the profile of the additional strut is bent into the inside of the profile, and the grips of the elastic element are wound behind the bent ends of the C-shaped profile.

In addition, the elastic element is made in the form of a geometric figure either from a plate or from a bar, and the thickness or diameter of the elastic element is not less than не and not more than ½ of the thickness of the masonry seam of piece blocks, and the height of the elastic element is not more than the thickness of the facade layer of the outer wall .

Figure 1 shows a fragment of a building with a prefabricated outer wall and floor slab with consoles;

figure 2 is a view of figure 1;

figure 3 - connection of the spatial panel and the facade layer of the outer wall made of piece blocks;

figure 4 - connection of the elastic element with an additional rack C-shaped profile;

figure 5 - elastic element in the form of various geometric shapes.

The frame building contains a floor slab 1 with consoles 2 mounted on a column 3, multilayer outer walls resting on the console 2, including the inner layer 4 and the facade layer 5, which, in turn, can also consist of several layers.

Each console 2 of the floor slab 1 is made in the form of a trapezoid, the larger base of which is placed inside the floor slab 1, and the extension L of the consoles 2 is no more than the thickness N of the outer wall (L <N). This configuration of the console 2 reinforces the floor slab 1 and increases the bearing capacity of the console 2 itself, on which the external wall is subsequently mounted.

To facilitate the construction of the building, the inner part of the outer wall is made in the form of a spatial panel of light thin-walled elements, consisting of, including: belts 6, racks 7, braces 8, ties forming this spatial panel. The space between the consoles 2, the inner layer 4 of the outer wall and the facade layer 5 of the outer wall is filled with a heater 9, for which mineral wool, basalt fiber, cellulose insulation, polystyrene foam, polyurethane foam, etc. can be used.

A light thin-walled element, for example, a stand 7 or a belt 6, is selected in width B to be equal to the thickness N of the outer wall, minus the thicknesses: front 5 and inner 4 layers of the outer wall, fasteners made in the form of a fastening profile 10, front layer 5, windproof film waterproofing 11 and vapor barrier 12 layers, respectively made of waterproofing fabric and vapor barrier film.

Due to the lightweight construction of the spatial panel, the outer wall is mounted on the floor slab 1, and the spatial panel on ¾ of its thickness B is placed on the trapezoidal consoles 2, and on ¼ of its thickness B is placed on the floor slab 1. In this case, the step of placing the racks 7 in the spatial panel the outer wall is equal to the step of the consoles 2, and the wall of each light thin-walled element included in the spatial panel is made with perforation 13 placed in a “checkerboard” order, and perforation 13 in width occupies not more than half the width of a light thin walled member. Perforation 13 facilitates a lightweight thin-walled element, without reducing its rigidity, and increases the thermal properties of the structure.

Installation of the building is as follows.

The building frame is erected, including installing a floor slab 1 with consoles 2 on the columns 3. Then, the outer wall is mounted, for which the spatial panel with a belt 6 is laid on the console 2 so that the racks 7 are placed directly on the consoles 2, and it took about ¼ part of the floor slab 1 and ¾ of the part of the consoles 2, after having previously placed a thermal insulation strip 14 under the spatial panel.

After that, a windproof film and / or waterproofing layer 11 is placed on the spatial panel from the outside and mounting profiles 10 are mounted on which the facade layer 5 of the outer wall is fixed. Then, the inner layer 4 of the outer wall is mounted on the inner side, having previously installed the vapor barrier layer 12. The inner cavity between the inner layer 4 and the facade layer 5 of the outer wall is filled with a heater 9.

In the case of the manufacture of the facade layer 5, which includes piece blocks 15, an element is used to attach the piece blocks 15 to the spatial panel in the form of an additional rack 16 of a C-shaped profile and an elastic element 17, the ends of which are not closed and made in the form of grips, and the additional rack 16 rigidly connected to the spatial panel, and the ends of the C-shaped profile are bent into the inside of the profile. In this case, the grips of the elastic element 17 are wound behind the bent ends of the C-shaped profile, forming a sufficiently rigid connection, reliably holding the masonry of piece elements 15.

The elastic element 17 is made in the form of a geometric figure, for example in the form of a triangle, in the form of the letter "P" or "Ω", from a plate or bar. Moreover, the thickness or diameter d of the elastic element 17 is equal to not less than ⅓ and not more than ½ of the thickness t of the masonry seam 18 of the piece blocks 15, and the height h of the elastic element 17 is equal to no more than the thickness of the facade layer 5 of the outer wall (⅓ t <d <½ t).

After mounting the external walls of the proposed design, the internal walls and partitions are mounted according to known technology.

Using the proposed technical solution allowed us to create structural elements of the frame building that increase the thermal properties of the outer wall, reduce labor costs for installing the frame building, including the outer walls, regardless of climatic conditions, namely, they eliminate the “wet processes” due to the use of a spatial panel, increase reliability and bearing capacity of the frame building, reduce the total weight of the building, give an expressive architectural facade to a building made of modern x materials and structures.

Claims (6)

1. A frame building containing floor slabs with consoles, columns resting on the console multilayer external walls, including the inner, middle and facade layers, characterized in that each console is made in the form of a trapezoid, the larger base of which is placed inside the floor slab, and the departure the console is equal to no more than the thickness of the outer wall, and the middle layer of the outer wall includes a spatial panel of light thin-walled elements - belts, racks, ties, braces that formed a spatial panel, and space between the consoles, the inner layer and the facade layer of the outer wall is filled with insulation. 2. The building according to claim 1, characterized in that the width of the light thin-walled element is equal to the thickness of the outer wall without the thickness of the front and inner layers of the outer wall, the fastening elements of the front layer, waterproofing, windproof and vapor barrier layers. 3. The building according to claim 1, characterized in that the outer wall is installed on the floor slab, and the spatial panel on ¾ parts of its thickness is placed on the consoles, and at least ¼ part of its thickness is placed on the floor slab. 4. The building according to claim 1, characterized in that the step of placing the racks in the spatial panel is equal to the step of the consoles, and the wall of each light thin-walled element is made with perforation, and the perforation occupies no more than half the width of the wall of the light thin-walled element. 5. The building according to claim 1, characterized in that the fastening element of the facade layer, which is made of piece blocks, is made in the form of an additional rack of a C-shaped profile and an elastic element, the ends of which are not closed and made in the form of grips, moreover, an additional rack connected to the spatial panel, the ends of the C-shaped profile of the additional rack are bent into the inside of the profile, and the grips of the elastic element are wound behind the bent ends of the C-shaped profile. 6. The building according to claim 5, characterized in that the elastic element is made in the form of a geometric figure, either from a plate or from a bar, the thickness or diameter of the elastic element being at least ⅓ and not more than ½ the thickness of the masonry joint of piece blocks, and the height an elastic element is equal to not more than the thickness of the facade layer of the outer wall.

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