RU168364U1 - Facade construction - Google Patents

Abstract

The invention relates to the field of construction, namely to the production of building structures from hollow aluminum profiles, which can be used, in particular, for facade walls lined with translucent material with the inclusion of decorative and protective elements, facade fencing openings of buildings and structures, for example, in the form window and / or door blocks, as well as in the manufacture of showcases, dividing partitions, etc. The design of the front fence contains box-shaped profiles of a vertical rack and horizon impost made with grooves for installing the sealing element and mounting protrusions for the fastener element made in the form of a glazing bead for attaching the filling element, the profiles of the rack and impost consist of internal and external profiles, protrusions are made on the surfaces of the internal and external profiles facing each other thermal insert installations, which form thermally insulated profiles with the main and additional profiles of the rack and impost, while the vertical internal profiles of the rack are attached to the plate the floor of the building, in the groove of the horizontal internal profile of the impost, support aluminum pads are installed, on which leveling pads are installed, on which the filling is installed. The technical result is to increase the stability of the structure to loads, namely, eliminating the displacement of the halves of the vertical profile of the rack relative to each other under the action of the vertical weight load.

Description

The invention relates to the field of construction, and in particular to the production of building structures from hollow aluminum profiles, which can be used in particular for facade walls lined with translucent material with the inclusion of decorative and protective elements, facade fencing openings of buildings and structures, for example, in the form of window and / or door blocks, as well as in the manufacture of display cases, dividing walls, etc.

Translucent structures of the facade fencing are widely known, they provide high sound and heat insulation indicators, protect the outside of the building from the aggressive effects of environmental factors, and are also characterized by high-tech and quick installation.

It is known that during operation, the structural elements of vertical facade structures are affected by wind and weight loads (load from the fill weight and the dead weight of the structure frame). The weight load acts on the horizontal imposts and their attachment points to the racks, as well as on the attachment points of the racks to the bearing brackets. During operation under the action of loads, the structure can be deformed, namely, the halves of the vertical profile of the rack can move relative to each other under the action of the vertical weight load.

Widely known are various aluminum profile systems for façade fencing, produced by both domestic and foreign manufacturers, the technical solution is an integrated window (RF Patent for Utility Model No. 76058, Е06В 1/38, publ. 2008), according to which installation and glazing is done from the outside of the building, from scaffolding.

The closest analogue, prototype, of the claimed technical solution is a technical solution, a set of profiles for assembling suspended facade blocks (RF Patent for utility model No. 69904, EV 3/00, publ. 2008). In a known design, block modules (fragments of the facade) are made and assembled at the factory together with a double-glazed window. Modules are delivered ready-made to the construction site, where the facade fence construction is assembled from them. Blocks with the help of a crane rise to the desired floor and are mounted on top of each other, forming a ready-made translucent facade. This technical solution is not economical in production and installation.

A common disadvantage of the known solutions is the use of a backing pad only to isolate the metal profile from glass. The design of the known support pads does not exclude the shift of the vertical profiles relative to each other.

The objective of the invention is to remedy the above disadvantages, namely the creation of a thermally insulated structure of aluminum profiles for assembling a facade fence economical in production and with reduced installation complexity.

The technical result, which cannot be achieved by any of the above described similar technical solutions, is to increase the stability of the structure to loads, namely the elimination of the displacement of the halves of the vertical profile of the rack relative to each other under the influence of the vertical weight load.

Given the characteristics and analysis of known similar technical solutions, we can conclude that the creation of the design of the facade fencing with high resistance to stress is relevant today.

The technical result indicated above is achieved by the fact that the design of the facade fence comprises box-shaped profiles of a vertical rack and horizontal impost made with grooves for installing the sealing element and mounting tabs for the fastener element made in the form of a glazing bead for attaching the filling element, the profiles of the rack and impost consist from the internal and external profiles, on the facing surfaces of the internal and external profiles, protrusions are made for installing thermal inserts, which are thermally insulated profiles are connected with the main and additional profiles of the rack and the impost, while the vertical internal profiles of the rack are attached to the floor slab of the building, in the groove of the horizontal internal profile of the impost, supporting aluminum pads are installed on which the leveling pads on which the filling is installed are installed.

Increasing the stability of the proposed technical solution to loads occurs due to the transfer of the fill weight and opening elements to the inside of the combined profile of a thermally insulated system of aluminum profiles. In this case, the external part of the profile and the connecting thermal inserts (polyamide or plastic) are in an unloaded state. They perceive loads only from their own weight, as well as loads from wind pressure. Thus, the main load is directed in a horizontal direction perpendicular to the plane of the glazing of the structure, because the load of the fill weight and opening elements falls on the inside of the combined profile. This eliminates the displacement of the halves of the vertical profile of the rack relative to each other under the influence of the vertical weight load.

The transfer of the weight load to the inside of the combined profile is achieved by installing a support pad on which the filling is installed (glass, double-glazed window, sandwich panel, etc.). The support lining is inserted into the groove of the inner half of the horizontal impost, and has no points of contact with the outer half of the profile. The unit for attaching the stained-glass window rack to the bracket and floor slab through the rack "cracker" and an aluminum strip is also made only to the inner half of the rack vertical profile. As a result, all weight loads transferred from horizontal imposts are distributed to the inner half of the vertical profile of the rack.

The proposed device is illustrated by the following description of an example implementation of the device and the drawings.

In FIG. 1 - an example of the design of the facade fence, where 1 is the horizontal profile of the impost, 2 is the vertical profile of the rack, 3 is the floor slab of the building, 4 is the bracket for attaching to the floor slab of the building 3, 5 is the glass packet filling, 6 is the sandwich panel filling, 7 is opening element, swing wing.

In FIG. 2 - cross section of the vertical profile of the rack, where 8 is the external profile of the rack, 9 is the internal profile of the rack, 10 is a thermal insert.

In FIG. 3 - cross section of the horizontal profile of the impost, where 11 is the external profile of the impost, 12 is the internal profile of the impost.

In FIG. 4 - cross section of the horizontal profile of the impost with the installed filling, where 13 - glazing bead, 14 - supporting aluminum lining, 15 - straightening plastic lining.

In FIG. 5 - shows the supporting aluminum lining 14.

The translucent design of the front fence consists of a supporting frame, fillings, gaskets, fasteners and accessories. The frame of the structure is assembled from aluminum profiles - vertical profiles of the rack 2 and horizontal profiles of the impost 1. The vertical profiles of the rack 2 are attached to the floor slab of the building 3 with a support bracket 4 made, for example, of galvanized steel. The horizontal profiles of the impost 1 are attached to the posts 2 using T-shaped embedded elements 16. The cells formed by the posts 2 and the imposts 1 are filled, for example, glass, filling a double-glazed window 5, filling a sandwich panel 6 or other sheet material, which is installed on supporting aluminum pads 14, excluding direct contact of glass with the metal of the frame.

On the supporting aluminum pads 14, which are necessary for even distribution of the filling weight on the frame, plastic straightening pads 15 are installed, which are necessary to “burst” the filling in the cell of the frame (to prevent free movement of the filling). Fixed filling installation of aluminum profiles-holders glazing beads 13 with the subsequent installation of proppants.

Also, opening elements, for example, hinged leaves 7 or hinged, suspended or tilt-open windows (not shown in the figures), can be installed in the structural cells. A window, for example, consists of a rectangular frame made of aluminum profiles, fixed to the frame of the structure using rotary hinges or tilt-and-turn fittings. In the sash frame, filling is established according to the same principle as in the design cell - on the support pads 14 and is fixed with glazing beads 13.

The proposed design of the facade fence is thermally insulated, i.e. profiles of these systems consist of two “halves” (external and internal), not touching each other. These "halves" are separate aluminum profiles, 8 - the external profile of the rack, 9 - the internal profile of the rack and 11 - the external profile of the impost, 12 - the internal profile of the impost. They are connected to each other by means of polyamide or plastic inserts, thermal inserts 10. Thus, aluminum profiles do not form a “cold bridge” - when the external profile is cooled, the internal profile changes its temperature slightly. The design does not freeze. During installation, the profiles are oriented so that the outer halves are always directed in the opposite direction from the interior of the building.

The external profile of the rack 8, the internal profile of the rack 9, the external profile of the impost 11, the internal profile of the impost 12 are box sections. On the external profile of the rack 8 and the external profile of the impost 11 there are protruding parts directed parallel to the glazing plane - mock shelves. At the ends of the mock shelves is a longitudinal groove for installing the seal. The groove for installing the seal is directed towards the room. On the internal profile of the rack 9 and the internal profile of the impost 12 there is a groove for installing a glazing bead 13 - a profile that fixes the filling in the cells of the structure. Near the groove for the glazing bead 13 there is a groove for installing the supporting aluminum lining 14, perceiving the filling weight.

Installation of translucent structures from profile systems is carried out at the construction site. The frame is assembled from racks and imposts and fastened to the floor slab of building 3. After installing the construction frame, seals are installed in the grooves of the external profile of the rack 8 and the external profile of the impost 11, and aluminum support pads 14 are installed in the grooves of the internal profile of the impost 12 for filling. The leveling plastic pads 15 are placed on the support pads 14 and the filling is installed. After that, in the grooves of the internal profile of the rack 9 and the internal profile of the impost 12, the glazing beads 13 are fixed, fixing the filling. Between the glazing beads 13 and the filling, proppant seals are installed to prevent direct contact between the filling and glazing bead 13 and to ensure reliable fixation of the filling in the structural cell.

The entire installation of structures (installation of the frame, laying of gaskets, insertion of fillings, fixing glazing beads and proppant seals) is carried out outside the room. The use of scaffolding during the installation of structures is optional.

Thus, increasing the stability of the structure to loads, namely the lack of displacement of the halves of the vertical profile of the rack under the action of the vertical weight load, is due to the support lining 14, which not only isolates the glass from the metal, but also transfers the entire filling weight to the inner ladle profile, while the outer half of the profile experiences only wind loads, and does not perceive weight loads from a double-glazed window. In addition, the proposed heat-insulated design of the facade fence is more economical in production and the complexity of installation is reduced in comparison with the prototype, due to the fact that the installation is carried out from the inside of the building without the use of scaffolding.

Claims (1)

The design of the front fence, containing box-shaped profiles of a vertical rack and horizontal impost, made with grooves for installing the sealing element and mounting tabs for the fastener element, made in the form of a glazing bead for attaching the filling element, the profiles of the rack and impost consist of internal and external profiles facing each other protrusions for installing thermal inserts are made to the other surfaces of the internal and external profiles, which form with the main and additional profiles racks and importers one hundred thermally insulated profiles, characterized in that the vertical internal profiles of the rack are attached to the floor slab of the building, in the groove of the horizontal internal profile of the impost, support aluminum pads are installed on which the alignment pads on which the filling is installed are installed.

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