RU220442U1 - Mounting profile for a suspended ventilated façade system of a building wall - Google Patents

Abstract

The utility model relates to construction. The mounting profile of a ventilated façade system is made of a metal sheet blank by bending its parts to obtain a box open along the length of the profile with a bottom and side walls extending from it, from which shelves are bent, lying in the same plane, parallel to the surface of the bottom of the profile, and serving as platforms for support. the back top of the tiles. Between the shelves located distantly along the length of the profile, plates with hook-shaped elements on the free edge are bent from the side walls for hanging the upper parts of the tiles on them and support plates of a rectangular shape in plan for elastically supporting the back sides of the lower parts of the tiles on them. The support plates are bent from the surface of the shelves at an angle that is less than the angle of deflection from this surface of the plates with hook-shaped elements. The shelves, plates with hook-shaped elements and support plates are made equal in height in the direction from the line of their inflection from the side walls of the profile box to their free edges. And the distance from the shelf to the free edge of the bent plate with hook-shaped elements is made twice as large as the distance from the shelf to the free edge of the bent support plate. 3 ill.

Description

The utility model relates to construction, in particular, it considers the design of a mounting profile fixed to the wall of a building to be tiled and used as a holder for hanging facade tiles when installing a ventilated facade of a building.

The facade system (Fig. 1), in general, includes a number of elongated mounting profiles 1, vertically mounted on the wall of the building, bearing bends for supporting the hung tiles 2 and hook-shaped elements 3 for holding these rectangular facade facing tiles in a suspended state (see. for example, RU 2545584). Each façade cladding tile contains a front side rectangular in plan from the front side 4, which is configured to face away from the building and constitute the visible façade of the building. The back side of the tile contains a downwardly directed holding projection 5 for hanging the tile on said hook-shaped elements 3, while the front side of the tile contains a tongue groove and a downwardly directed ridge. Facade facing tiles are designed to be placed one above the other on the facade of a building (Fig. 1), and vertically located adjacent tiles overlap each other using their upper and lower edges in such a way that the ridge of each tile fits into the tongue groove of the underlying adjacent tiles.

For such facade systems, standard tiles are used, made of building material based on a cement-sand mixture and representing a rectangular body in plan with flat front and back surfaces, in the upper part of which, on the front side from the end side and along the length of the body, there is a reduction along the thickness with the formation of a protruding end, connected to the front surface by an inclined section, and on the back side there is a depression in thickness in the form of a ridge with the formation in the zone of transition of the upper part of the body into the depression of an angular recess in the form of a triangular depression, one wall of which is located in the plane of the flat surface of the section depression, and the inclined wall is brought into the transition zone of the rear flat surface of the upper part into the flat surface of the depression section in the lower part of the rear surface (RU 2101433, E04F 13/00, E04F 13/08, publ. 01/10/1998).

These facade tiles are hung on mounting profiles, which are vertically fixed at a distance from each other on the surface of the building wall.

Such a mounting profile for a hinged ventilated facade system of a building wall is made from a metal sheet blank by bending its parts to obtain a box open along the length of the profile with a bottom and side walls extending from it, from which shelves are bent, lying in the same plane, parallel to the surface of the bottom of the profile, and being platforms for supporting the back upper part of the tiles, between shelves located distantly along the length of the profile, plates with hook-shaped elements on the free edge are bent from the side walls for hanging the upper parts of the tiles on them and support plates of a rectangular shape in plan for resting the back sides of the lower parts on them tiles, while the support plates are bent from the surface of the shelves at an angle that is less than the angle of deflection from this surface of the plates with hook-shaped elements (RU 2213188, E04F 13/08, publ. 04/27/2022).

This solution was adopted as a prototype.

Despite the apparent simplicity of the design, the known mounting box has a significant drawback in the complexity of its assembly using the bending method. This disadvantage lies, firstly, in the large amount of waste when cutting out plates with hook-shaped elements, and secondly, due to the fact that the vector of application of forces to bend the side walls from the bottom, shelves from the side walls and plates with hook-shaped elements is not coincides with the vector of application of forces for bending the rectangular support plates from the side walls. If the first vector is directed transversely to the longitudinal axis of the profile box, then the second vector has a direction from the longitudinal axis upward with an inflection line transverse to the longitudinal axis of the profile. As a result, when forming a box, the bending of the side walls and shelves and plates with hook-shaped elements is carried out at a time using manipulators that implement actions directed transversely to the longitudinal axis of the workpiece. After this, another manipulator bends the support plates in the upward direction from the shelves. This indicates not so much the complexity of the assembly, but rather the inconvenience and loss of working time for additional bending operations.

The mounting profile, as bearing the load from the weight of the tiles, must maintain the strength of each structural element, excluding accidental deformations and bends of shelves or hook-shaped elements. In this profile, one element, namely a bent base plate of rectangular shape and small dimensions in area, is used as an element on which the back side of the ridge of the tile rests. This support is necessary for the correct positioning of the tiles. When laid on hooks, the tile warps slightly and its ridge tilts towards the mounting profile. When laying the next tile from below, you need to move this ridge away from the profile, as if turning it on hooks, and place the ridge on the end protrusion. In this case, the tile receives two points of support: on the hooks and on the lower end of the other tile. Said support plates under the hook-shaped elements serve to rest against the ridge and prevent it from tilting. In this case, the installer can easily hang the tiles. When hanging, the tile is placed with its cavity on the hook and is supported by a support plate, which straightens the ridge and prevents the tile from tilting relative to the support point in the cavity. But there is a peculiarity that when hanging tiles, the installer can press the support plate with the tile and it will change its angle of inclination. In this case, the ridge loses additional support. If such support is lost, the tiles become unsteadily installed and can dangle freely under the influence of wind load. The loss of support when the support plate collapses is due to the fact that the plate is made of small sizes with a small area, on which the elastic force does not manifest itself and the deformation takes on a plastic nature.

This utility model is aimed at achieving a technical result, which consists in improving the performance characteristics of the mounting profile by imparting an elastic component to the support plates as a result of changing the cut of the sheet blank of this profile.

The specified technical result is achieved by the fact that the mounting profile for the hinged ventilated facade system of the building wall is made of a metal sheet blank by bending its parts to obtain a box open along the length of the profile with a bottom and side walls extending from it, from which shelves lying in the same plane are bent , parallel to the surface of the bottom of the profile, and which are platforms for supporting the rear upper part of the tiles, between shelves distantly located along the length of the profile, plates with hook-shaped elements on the free edge are bent from the side walls for hanging the upper parts of the tiles on them and support plates of a rectangular shape in plan for elastic resting on them the back sides of the lower parts of the tiles, while the support plates are bent from the surface of the shelves to an angle that is less than the angle of bend from this surface of the plates with hook-shaped elements, characterized in that the shelves, plates with hook-shaped elements and the support plates are made the same in height direction from the line of their inflection from the side walls of the profile box to their free edges, while the distance from the shelf to the free edge of the bent plate with hook-shaped elements is twice the distance from the shelf to the free edge of the bent support plate.

These features are essential and are interrelated to form a stable set of essential features sufficient to obtain the required technical result.

This utility model is illustrated by a specific example of execution, which, however, is not the only possible one, but clearly demonstrates the possibility of achieving the required technical result.

Figure 1 is a schematic representation of a ventilated facade system with hanging facade tiles, state of the art;

fig. 2 - fragment of a sheet blank for obtaining a mounting profile;

fig. 3 - mounting profile in isometry.

According to this utility model, the design of a mounting profile fixed to the surface of a building wall and used for hanging facade tiles when installing a ventilated facade of a building is considered. At the same time, the design of the mounting profile, made from a metal sheet blank by bending its parts, is manufacturable due to the fact that all bent elements are made of the same length and are obtained by transverse straight cutting of the blank.

The sheet blank (Fig. 2) of the profile is a long rectangular sheet on which inflection lines 6 are formed, framing the bottom 7 of the profile (holes for fastening elements are made in the bottom), from which rectilinear sections extend on the sides, which are the side walls 8. These walls 8 along inflection lines 9 are connected to other straight sections 10, which are carriers of folded elements.

Each straight section 10 is conventionally divided along the length of the section into successive positions, each of which contains a shelf 11, a support plate 12 and a plate 13 with a hook-shaped element. This set of elements is present at each position on each side of the sheet section to form the side walls. All elements in position in the established order are separated from each other by cuts 14 of the sheet (Fig. 2).

On the sheet blank of Fig. 2, the plate 13 with the hook-shaped element is specially separated by a gap from the adjacent shelf 11 of another position in order to demonstrate the shape of this element. The size of this element and the shape of the hook-shaped element directly depend on the design features of the hung tile (in particular, on the shape of the recess hooked to the profile hook). In other embodiments, the plate 13 may be adjacent to the adjacent shelf 11. Its separation from the adjacent shelf is carried out by cutting the sheet by analogy with the cutting 14 of other elements in position.

The shelves 11, plates 13 with hook-shaped elements and support plates 12 are made the same in height in the direction from their inflection line from the side walls 8 of the profile box to their free edges. This eliminates or minimizes the volume of cut material considered waste.

In general, in the assembled state, the claimed long-length mounting profile (Fig. 3) is an open-length box with a bottom 7 and side walls 8 extending from it at an angle in different directions. The location of the side walls at an angle from the bottom is of primary importance, since how these walls, when installing façade tiles, can elastically resist loads and return to their original position. In principle, the side walls can be located at right angles to the surface of the bottom of the box. But in this case, with high shock loading, there is a possibility of deformation of the side wall and its collapse towards the bottom. Within the framework of this utility model, the material of the metal sheet of the workpiece is not specified. Therefore, both examples of side wall placement are considered a workable design solution.

From these side walls 8, shelves 11 are bent, which lie in the same plane, parallel to the surface of the bottom of the profile. These shelves 11 are platforms for supporting the rear upper part of the tiles. Between the shelves 11 located at a distance along the length of the profile, plates 13 with hook-like elements on the free edge, used for hanging the upper parts of the tiles on them, are bent from the side walls 8. Also, support plates 12 of rectangular shape in plan are bent from the side walls 8, which are elements supporting the tiles due to the elastic support of the back sides of the lower parts of the tiles on them. The important thing about these support plates is that they exhibit an elastic component when pressure is applied to them. Any metal strip initially has elasticity within the structure of the material. But the manifestation of spring properties depends on the length of such a strip. With a short length, as is the case in the prototype, the short plate does not exhibit elasticity due to the fact that, in fact, it has a cantilever fastening in relation to the line of its bend. Elastic deflections during cantilever fastening are minimized and when there is a load on the plate, it collapses in the bend line. As the length of the plate increases, the deformation surface of the outer layers increases, which is distributed along the length of the plate. In this case, elastic deformations of the plate begin to appear due to the possibility of bending/bending its remote end and returning to its original position. When installing façade tiles, the installer may increase pressure on the backing plate, which will cause its free end to deflect. This deviation in the elastic state of the plate material depends on its length and elastic modulus. The longer the plate, the greater the amount of deflection without loss of elasticity of the material of the deflected part of the plate. When the excessive load is removed (after hanging the tile), the free end of the plate remains resting against the back wall of the tile and thus holds it. When installing one tile on another, the ridge of the top-laid tile fits into the depression of the end protrusion of the bottom-laid tile and rests on this depression. But during gusts of wind, due to the fact that on the back side of the tiles a space is formed for ventilation of the facade, zones of high and low pressure are formed, in which the top-laid tiles can swing and hit the end projection of the bottom-laid tiles. But the presence of elastic compression from the base plate eliminates this vibration in hung façade tiles.

In the mounting profile, the support plates 12 are bent from the surface of the shelves 11 to an angle that is less than the angle of deflection from this surface of the plates 13 with hook-shaped elements. In this case, the distance from the surface of the shelf to the free edge of the bent plate 13 with hook-shaped elements is made twice as large as the distance from the same shelf 11 to the free edge of the bent support plate 12. With this ratio, the support plate will always be in a state of elastic deflection under the weight of the hung tiles .

This utility model is industrially applicable and makes it possible to increase the performance characteristics of the mounting profile by imparting an elastic component to the support plates as a result of changing the cut of the sheet blank of this profile. At the same time, in a facade system built on these profiles, shock-free placement of facade tiles is ensured, which allows reducing the cost of replacing tiles that have become substandard during operation of the facade.

Claims (1)

Mounting profile for a hinged ventilated facade system of a building wall, made of a metal sheet blank by bending its parts to obtain a box open along the length of the profile with a bottom and side walls extending from it, from which shelves are bent, lying in the same plane, parallel to the surface of the bottom of the profile, and being platforms for supporting the back upper part of the tiles, between the shelves located distantly along the length of the profile, plates with hook-shaped elements on the free edge are bent from the side walls for hanging the upper parts of the tiles on them and support plates of a rectangular shape in plan for elastically supporting the back sides of the lower ones on them parts of the tiles, while the support plates are bent from the surface of the shelves at an angle that is less than the angle of bend from this surface of the plates with hook-shaped elements, characterized in that the shelves, plates with hook-shaped elements and the support plates are made the same in height in the direction from the line of their inflection from side walls of the profile box to their free edges, while the distance from the shelf to the free edge of the bent plate with hook-shaped elements is twice as large as the distance from the shelf to the free edge of the bent support plate.