RU196310U1 - Design with inner and outer lining on the LSTK frame with filling the inner cavity with foam concrete - Google Patents

Abstract

The utility model relates to the field of construction and can be used in the construction of buildings and structures. Essence: the design contains C-profiles LSTK, inner and outer sheet material, the space between which is filled with foam concrete. LSTK C-profiles are made in the form of guides located on opposite sides, with rack-mount C-profiles fixed in them, to the end sides of which a lath is fixed to which sheet material is attached. Moreover, rack-mount C-profiles are fixed in guide C-profiles with equal pitch and the crate made in the form of an omega-profile is fixed to the end sides of rack C-profiles with equal pitch. The technical result is the isolation of steel racks of the structure from the direct influence of low ambient temperatures by eliminating the effect of “cold bridge” in view of the increase in the volume of the internal cavity of the structure to fill it with foam concrete and improving the thermal characteristics of the claimed design, while ensuring spatial stiffness of the structure by minimizing the impact bending moment of steel structures on sheet material. 3 s.p. f-ly, 4 ill.

Description

The utility model relates to the field of construction and can be used in the construction of buildings and structures. The inventive design, depending on the structural design of the erected building or structure, can fulfill the function of the supporting and (or) enclosing structure.

Known enclosing structure of a multi-storey building, containing internal and external fixed formwork with monolithic ultralight foam concrete placed between them, where both fixed formwork are made in the form of sheet materials mounted on a metal frame attached to the ceilings. Moreover, the metal frame is formed by separate wide-shelf metal profiles coming from the foundation and fastened to the ends of the floors (see RF Application for the invention No. 2006116143, EV 2/02).

A disadvantage of the known design is that it contains a “cold bridge”, since the sheet material is mounted on a metal frame that is perpendicular to the entire width of the structure, which contributes to the complete freezing of the structure, the presence of a dew point, moisture collection inside the structure with the appearance of mold and decay of internal filling.

The building frame is known, which consists of frame-forming elements from the C-shaped profile of LSTK, the outer and inner sheet material, the space between which contains a filler in the form of light concrete, is additionally equipped with an outer and inner row of steel frame-forming elements from the C-shaped profile of LSTK installed on the distance L equal to the width of the wall, while to each row of LSTC fixed, respectively, the outer and inner sheet material (see US Pat. RF 121831, EV 1/24).

The disadvantage of this design is a slight improvement in thermal characteristics, due to the simultaneous deterioration of humidity characteristics due to the temperature difference between the outer and inner wall panels, separated by a thermal gap, which causes the formation of a dew point and a large accumulation of moisture in the interpanel space. In addition, the known design has a large metal consumption and a high consumption of materials, and also due to the complexity of the design and its installation.

The closest analogue to the claimed utility model is a structure containing C-profiles of LSTC, inner and outer sheet material, the space between which is filled with foam concrete (see STO 82866678-3.01.01-2013, pp. 2-3).

A disadvantage of the known design is the presence of a “cold bridge”, since the sheet material is mounted on a steel C-profile LSTK, which is perpendicular to the entire width of the structure, which contributes to freezing of the structure when exposed to negative temperatures on the outer wall.

The technical problem of the known technical solutions lies in the low thermal performance of the structures in view of the presence of a “cold bridge”, dew point and moisture accumulation inside the layer of aggregate material while at the same time high metal consumption of the structures.

The essence of the claimed utility model lies in the fact that the design contains C-profiles LSTC, inner and outer sheet material, the space between which is filled with foam concrete. LSTK C-profiles are made in the form of guides located on opposite sides, with rack-mount C-profiles fixed in them, to the end sides of which a lath is fixed to which sheet material is attached. Moreover, rack-mount C-profiles are fixed in guide C-profiles with equal pitch and the crate made in the form of an omega-profile is fixed to the end sides of rack C-profiles with equal pitch.

The technical result achieved by the claimed technical solution is to isolate the steel struts of the structure from the direct influence of low ambient temperatures by eliminating the effect of the "cold bridge" in view of the increase in the volume of the internal cavity of the structure for filling it with foam concrete and improving the thermal characteristics of the claimed design, while simultaneously providing spatial structural rigidity by minimizing the effect of the bending moment of steel structures on the sheet howling material.

The essence of the claimed utility model is illustrated by drawings, where:

in FIG. 1 schematically shows a General view of the claimed design;

in FIG. 2 is a section AA in FIG. 1;

in FIG. 3 is a cross section BB in FIG. 1;

in FIG. 4 is an isometric view of the claimed design.

The design consists of guides 1 and 2 of steel LSTK C-profiles installed on the lower side of the upper and upper side of the lower floor 3 and secured with anchor screws 4. The rails 5 C- are mounted in the upper 1 and lower 2 C-profiles of LSTK with the set design pitch profiles that perform the function of load-bearing structural elements. The fixing of rack-mount 5 C-profiles in guides 1 and 2 is made by self-tapping screws 6. To give spatial rigidity of the structure, the susceptibility of structural elements to bending and eliminate the effect of the “cold bridge” to both end faces of the rack 5 C-profiles, a steel crate is mounted with a calculated step 7, made in the form of an omega profile. The fastening of the omega-profiles 7 to the rack profiles 5 is made by self-tapping screws 6 with an established design pitch. On the omega-profile 7 is fixed facing moisture-resistant sheet material 8, which also performs the function of a fixed formwork. Thus, cavities are formed inside the structure, separated from each other by steel rack 5 C-profiles, and from the external environment separated by sheet material 8 and guides 1 and 2 C-profiles installed on the ceilings 3. These cavities are filled with non-autoclaved monolithic foam concrete 9, performing heat-insulating, sound-insulating, and for rack-mount 5 C-profiles and fire-retardant function. In addition, the presence in the claimed design of a layer of monolithic foam concrete 9 enhances the bearing capacity of the structure as a whole, which is confirmed by laboratory tests. Omega-profile 7 eliminates the fact of direct contact of the rack-mount 5 C-profile with the environment, minimizing the possibility of the appearance of “cold bridges”. In this case, the omega profile 7 is located inside the foam concrete layer 9. In addition, its presence in the structure allows to increase the volume of foam concrete 9 without increasing the cross-sectional height of the steel rack 5 C-profile. This significantly, up to 1.5 times, increases the wall thickness without a significant increase in metal consumption and at the same time enhances the thermal characteristics of the structure.

The assembly of the claimed utility model is as follows.

The LSTK steel C-profiles 1 and 2 are installed on the lower side of the upper and upper side of the lower floor 3, respectively, and fastened with anchor screws 4. In the upper 1 and lower 2 C-profiles, the LSTK with installed calculation step install rack-mount 5 C-profiles that perform function of load-bearing structural elements. Rack-mounted 5 C-profiles are fixed in guides 1 and 2 by means of self-tapping screws 6. To impart spatial rigidity of the structure, the susceptibility of structural elements to bending and to eliminate the effect of the “cold bridge” to both end faces of the rack 5 C-profiles, a steel crate is installed with the calculated step 7, made in the form of an omega profile. The latter is attached to the rack profiles 5 by means of self-tapping screws 6 with an established design pitch. On the omega-profile 7 is fixed facing moisture-resistant sheet material 8, which also performs the function of fixed formwork. As a result of the assembly of this structure, cavities are formed inside it, separated from each other by steel rack 5 C-profiles, and from the external environment by sheet material 8 and guides 1 and 2 C-profiles installed on the ceilings 3. These cavities are filled with non-autoclaved monolithic foam concrete 9 performing heat-insulating, sound-insulating, and for rack-mount 5 C-profiles and fire-retardant function.

Thus, the claimed technical solution allows to eliminate direct contact of the rack-mount C-profile with the environment, which minimizes the possibility of the appearance of "cold bridges", as well as moisture accumulation inside the structure. The presence of an omega profile in the structure allows to increase the volume of foam concrete in the building without increasing the cross-sectional height of the steel rack-mounted C-profile, significantly increasing the value of the thermal characteristics.

Claims (4)

1. A structure containing LSTK C-profiles, inner and outer sheet material, the space between which is filled with foam concrete, characterized in that the LSTK C-profiles are made in the form of guides located on opposite sides, with rack-mount C-profiles fixed to them, to the ends of which the lath is fixed to which the sheet material is attached. 2. The construction according to p. 1, characterized in that the rack-mount C-profiles are fixed in the guide C-profiles with equal pitch. 3. The design according to p. 2, characterized in that the crate is fixed to the end sides of the rack-mount C-profiles with equal pitch. 4. The construction according to paragraphs. 1-3, characterized in that the crate is made in the form of an omega profile.

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