RU210776U1 - facade panel - Google Patents

Abstract

The utility model relates to the field of construction. The thin-walled facade panel contains a middle part in the form of a plate with a flat front surface, made with side edges bent along its length in the direction from the front surface to the rear surface on two sides. On one side, the bent edge contains the first flat section, perpendicular to the surface of the front surface of the plate, from which the second flat section departs, perpendicular to the first and having a protrusion on the free edge, used to insert it into the cavity of one adjacent panel. On the other side, the bent edge contains the first flat section, perpendicular to the surface of the front surface of the plate, from which a curved section extends, forming a cavity directed towards the first side and used to insert a protrusion of another adjacent panel. The second flat section, having a protrusion on the free edge, at the junction with the first flat section, is made with a protrusion in the form of a continuation of the second flat section directed towards the other side and located between the first flat sections of both sides. The height of the protrusion is not less than the width of the cavity, the width of which along the length of the plate is greater than the thickness of the plate and equal to the width of the recess between the rear surface of the plate and the wall of the recess. The distance from the front surface of the plate to the second flat section on the side of the cavity is greater than the distance from the front surface of the plate to the second flat section on the side of the protrusion by the thickness of the plate, and the depth of the cavity is made at least half the length of the second flat section having a protrusion. 2 ill.

Description

The utility model relates to the field of industrial and civil construction, namely to the device of a ventilated lining of buildings and structures, hung both during the construction of new buildings and during the reconstruction of previously operated structures to give them aesthetic qualities and increase the degree of thermal insulation and protection from external atmospheric influences. In particular, the utility model relates to the arrangement of wall cladding elements, referred to as façade panels, and is intended primarily for use as an exterior façade panel on an exterior wall of a building.

Facade panels - a general capacious term denoting in international terminology (ISO 6707-1) and the current domestic standard dictionary (GOST R 58033-2017) filling on the frame (panel) of the outer wall of the house, building (facade), and in the British Encyclopedia facing facade (Paneling, or paneling - literally cladding, sheathing). Those. in fact, it is a material of any shape, size, properties, used in the outer cladding of the facade on the frame or (formally) in the screen of the hinged facade system (HFS). Within the framework of this utility model, the construction of a facade sheet panel made entirely of an aluminum alloy (aluminum-containing material) is considered.

Facade panels are a universal functional and decorative cladding material used mainly in the ventilated facade system. The panels simultaneously protect the enclosing structures from external atmospheric factors and mechanical influences and increase the presentability of the house.

Facade panels for creating ventilated cladding of the outer walls of a building are a modern technological solution that allows not only to protect the surfaces of the outer walls from the effects of the external environment, but also to decorate the building without finishing the outer walls themselves in a short time. This cost-effective technology provides a quick replacement of failed panels and has a fairly short time to create a building cladding.

The system for arranging a ventilated facade on any building consists of a frame base, which is mounted on the outer walls, and a set of facade panels, which are fixed on this frame base.

The panels themselves belong to the category of parts that are simple in design and manufacture, which, when mounted on a frame base, are joined to each other, mainly according to the principle of inserting the end protrusion of one panel into the end recess on another, adjacently fixed, panel. With this fastening, the panels are aligned with each other in a common vertically oriented plane. With small sizes of facade panels, their installation requires a compact arrangement of the frame base rails and their alignment in a common vertically oriented plane and a large number of small works associated with fixing fasteners on each rail and fastening mating fasteners on each panel. In order to reduce the time for creating a cladding on a building, facade panels of increased dimensions began to be used, in particular, panels with a length of up to 7 m with a panel width of up to 25 cm. This made it possible to reduce labor costs for mounting the frame base under the panels and the time for mounting the panels themselves. Such long panels are produced from aluminum alloys and are obtained either by bending the edge sections of a sheet panel or by powder metallurgy.

Thus, a thin-walled front panel made of an aluminum-containing alloy (Fig. 1) is known, containing a middle part in the form of a plate with bent along its length from it in the direction from the front surface of the panel to the rear side edges on two sides, while on one side it is bent the edge contains the first flat section, perpendicular to the surface of the front surface of the plate, from which the second flat section departs, perpendicular to the first and forming a protrusion for inserting it into the cavity of one adjacent panel (from this side), and on the other side, the bent edge contains the first flat a section perpendicular to the surface of the front surface of the plate, from which a curved section extends, forming a cavity for the protrusion of another adjacent panel (on the other side), and the plate of the middle part is made with a protrusion in the central zone along the entire length of the plate in the form of a panel extruded onto the front side U-shaped extrusion, in co the second length of the flange between the side walls of the protrusion is greater than the height of its side walls, and between this protrusion and the bent side edges of the panel, the sections of the middle part are made flat and lying in different parallel planes (see Fig. "Aluminum panels RWC 43" in the section "Aluminum facade structures" on the website "AFK LEADER" of the company "AFK Leader", presented on the Internet at: https://afkleader.ru/., copy is attached).

This solution is taken as a prototype.

The protrusion in the form of a U-shaped extrusion is designed to increase the spatial rigidity of the panel 7 m long. But this protrusion is functionally implemented only to reduce the deflection of the panel along its length due to the fact that the loads that cause longitudinal deflection act along the side walls of this protrusion and therefore either neutralized or significantly reduce the deflection. But such a protrusion centrally located on the plate of the middle part does not provide resistance to bending of the panel due to the fact that the bending moment acts on the areas around the protrusion in the area of the bent side edges, which leads to the angular eversion of the side walls of the protrusion and deformation of the shelf between them. The protrusion still exerts some resistance to bending, but it is insignificant in order to speak of it as a property of the panel design.

It is known from the prior art that the implementation of a thin-walled U-shaped extrusion creates a reinforcing element in the structure. But such a squeeze works as a reinforcing element (an element of resistance to any load) only on condition that the disturbing forces act on the side walls of the squeeze of this shape. In this case, each of the walls is a support for the adjacent wall, on which the force action vector passes into the plane of the wall. This makes it possible to increase the resistance of the structure as a whole to the influence of an external load.

In the case of the prototype design, the load vector leading to helical bending is located transversely to the flat sections around the protrusion and coincides with the direction of the side walls of the rectangular extrusion. As a result, the entire load is transferred to the flange between the side walls of the extrusion, which, as a flat element of the surface, begins to bend.

For long façade panels (up to 7 m long), this is expressed in the fact that the panel twists during transportation and then begins to sag (since the extrusion loses its squareness and ceases to work as an element of resistance to longitudinal bending / deflection).

This utility model is aimed at achieving a technical result, which consists in increasing the spatial strength and shape of a thin-sheet facade panel of increased length while reducing its overall height.

The specified technical result is achieved by the fact that in a thin-walled facade panel made of an aluminum-containing alloy, containing a middle part in the form of a plate with a flat front surface, made with side edges bent along its length in the direction from the front surface to the back surface on two sides, wherein

on one side, the bent edge contains the first flat section, perpendicular to the surface of the front surface of the plate, from which the second flat section departs, perpendicular to the first and having a protrusion on the free edge, used to insert it into the cavity of one adjacent panel, and on the other side, bent the edge contains the first flat section, perpendicular to the surface of the front surface of the plate, from which an isogout section extends, forming a depression directed towards the first side and used to insert a protrusion of another adjacent panel, the second flat section, having a protrusion on the free edge, at the junction with the first flat section is made with a protrusion in the form of a continuation of the second flat section directed towards the other side and located between the first flat sections of both sides, the height of the protrusion is made not less than the width of the cavity, the width of which along the length of the plate is more greater than the thickness of the plate and equal to the width of the notch between the rear surface of the plate and the wall of the notch, while the distance from the front surface of the plate to the second flat area on the side of the cavity is greater than the distance from the front surface of the plate to the second flat area on the side of the protrusion by the thickness of the plate, and the depth of the cavity made at least half the length of the second flat section having a ledge.

These features are essential and are interconnected with the formation of a stable set of essential features sufficient to obtain the desired technical result.

This utility model is illustrated by specific examples of execution, which, however, are not the only possible ones, but clearly demonstrate the possibility of achieving the required technical result.

In FIG. 1 - front panel profile;

fig. 2 - joining the panels according to FIG. one.

According to this utility model, the design of the developed facade panel used to organize the ventilated cladding of a building is considered. Within the framework of this utility model, the design of a metal facade panel made of an aluminum-containing material is considered, in particular, from an aluminum alloy of the 6xxx series in the T6 condition: 6060 (AlMgSi0.5) or A6063 (AlMgSi0.7) according to EN 573 or AD31 according to GOST 4784- 2019 (in a new modification since 2000) or aluminum alloy 606035. The choice of these alloys is due to the need to maintain the strength qualities of the panels during their thin-sheet production by pressing and the possibility of thermal hardening. Aluminum alloys of the 6xxx series are relatively easy to press and harden directly on the press to achieve the highest strength T6 condition. At the same time, the operation of hardening with separate heating is excluded from the production technology of aluminum profiles - this is a big saving for production.

Recently, facade panels with an enlarged valley, for example, up to 7 m in relation to the height/width, which, at a thickness of 2-4 mm, are approximately 180-250 mm, have been widely used. Such panels with such a length can significantly reduce the amount of work and the density of laying the laths of the frame base of the cladding system. But with such a length and small height / width, such panels are subject to bending under the load of their own weight and longitudinal deflections. Bends on the sides of the panel (forming the elements of connecting the panels to each other) are not elements that increase the rigidity of the panel. Within the framework of the present utility model, we are talking about such panels.

In the general case, the facade panel made of aluminum-containing material contains a middle part in the form of a flat plate 1 with side edges 2 and 3 bent from it in the direction from the front surface of the middle part of the panel to its back side side edges 2 and 3 on two sides (Fig. 1).

The facade panel itself is a protective and decorative element of the exterior decoration of the walls of the building (cladding). The front side of the middle part in the cladding system is turned outward and is a decorative part of the cladding. The back side of the middle part faces the walls of the building. Lateral edges 2 and 3, bent from the middle part of the plate 1, are used as elements for connecting panels in the cladding when forming a common cladding surface.

On one side, the bent edge 2 contains the first flat section 4, perpendicular to the surface of the front side of the plate (this section is bent in the direction from the front side of the panel), from which the second flat section 5 extends, perpendicular to the first. This flat area on the free edge is made with a protrusion 6, which is used to insert it into the cavity of the panel adjacent to this edge. The second flat section 5, bent away from the first section 4, is used by its location as an element for positioning the panels to be joined to each other, as shown in FIG. 2.

This second flat section 5, having a protrusion 6 on the free edge, at the junction with the first flat section 4 is made with a protrusion 7 in the form of a continuation of the second flat section 5 along its length, directed towards the other side 3 and located between the first flat sections of both sides.

On the other side of the folded edge 3 contains the first flat section 8, perpendicular to the surface of the front surface of the plate 1 (this section is bent in the direction from the front side of the panel). A second flat section 9 departs from it, perpendicular to the first one with a direction opposite to the direction of section 5 at the edge 2. At the transition point of section 8 to section 9 there is a curved section, forming a cavity 10 for the protrusion of another adjacent panel when joined.

Thus, on the edges 2 and 3 of the long panel along its entire length, a protrusion (on one edge 2) and a depression (on the other edge 3) are formed, used for joining the facade panels when organizing the cladding.

A feature of the claimed solution is that the height of the protrusion 6 is made not less than the width of the cavity 10, the width of which along the length of the plate 1 is greater than the thickness of the plate 1 and equal to the width of the recess 11 between the rear surface of the plate 1 and the adjacent wall of the recess 10. In addition, in the claimed panel the distance from the front surface of the plate 1 to the second flat section 9 on the side of the cavity is greater than the distance from the front surface of the plate 1 to the second flat section 5 on the side of the protrusion 6 by the thickness of the plate, and the depth of the cavity 10 is made at least half the length of the second flat section 5, including his performance.

These conditions make it possible to obtain a flattened version of the panel, that is, a panel with a small height. It is known that with a decrease in the height (thickness) of a thin-walled panel, its resistance to such deformations as buckling and torsion decreases sharply. Within the framework of the present utility model, the increase in resistance is structurally achieved through the use of the following techniques.

The presence at the free end of the second section 5 of the protrusion 6 leads to the fact that a force angle is formed that prevents deformation of this section in the longitudinal direction (along the length of the panel). In this case, in combination with the first section 4, a force angle is also formed. As a result, a stepped structure is formed on the edge 2, which is a support for the plate 1, which prevents its deformation in the longitudinal direction (bending). The execution of the protrusion directed towards the plate 1 makes it possible to form an unfinished U-shaped profile at the edge 2 from the load-bearing structure, in which the buckling forces are not realized in the planes of the protrusion and the first section 4. Supplying the second section 5 with the protrusion 7 allows, at the junction of the joint venture, the first section 4 to obtain a T-shaped element with high resistance to deformation, both longitudinal and bending. The design features used have provided an increase in the resistance of the edge 2, which prevents the panel from changing the shape during transportation and storage.

On the side of edge 3 of a zigzag shape, the contour of the transition from section 8 to section 9 forms a reinforced stiffener that prevents deformations of the plate from this edge 3. Selection of conditions:

- the height of the protrusion 6 is made not less than the width of the cavity 10, the width of which along the length of the plate 1 is greater than the thickness of the plate 1 and equal to the width of the recess 11 between the rear surface of the plate 1 and the nearby wall of the recess 10%

- the distance from the front surface of the plate 1 to the second flat section 9 on the side of the cavity is greater than the distance from the front surface of the plate 1 to the second flat section 5 on the side of the protrusion 6 by the thickness of the plate;

- the depth of the cavity 10 is made at least half the length of the second flat section 5, including its protrusion,

Allows you to optimize the dimensions of the panel and the consumption of material for the manufacture of the panel while maintaining high resistance to deformation and maintaining the shape of the panel.

These features made it possible to significantly increase the bending strength of the panel. In this case, the ability to resist bending can be considered as the ability of a body to leave a state of rest, in which it maintains an equilibrium stable shape. In physics, the ability of bodies to maintain a state of rest or motion in the absence of external forces is called the inertia of the body. As an example, it can be pointed out that the greater the mass, the greater the external influence is necessary to change the state of the equilibrium position in the direction of a change in shape or a change in motion. It is characterized by the moment of inertia - a measure of inertia in rotational motion around an axis, just as the mass of a body is a measure of its inertia in translational motion. It is characterized by the distribution of masses in the body: the moment of inertia is equal to the sum of the products of elementary masses and the square of their distances to the base set (point, line or plane).

(относительно продольной оси) или

(относительно поперечной оси), где b - длина стороны прямоугольника, h - высота прямоугольника. Указанные условия позволяют привести к равенству моменты инерции на краях панели. Это указывает, что заявленная фасадная панель как длинномерное плоское тонкостенное изделие если и будет винтообразно изгибаться, то это будет в диапазоне небольших изгибов и без практически без потери формы.For rectangular shapes, the axial moment of inertia is

(relative to the longitudinal axis) or

(relative to the transverse axis), where b is the length of the side of the rectangle, h is the height of the rectangle. These conditions make it possible to bring the moments of inertia at the edges of the panel to equality. This indicates that the declared facade panel as a long flat thin-walled product, if it will be helically bent, it will be in the range of small bends and without practically no loss of shape.

The claimed design of the facade panel, compared with the prototype, has sufficient resistance to both longitudinal bending and helical bending, while the panel is made flattened, which allows one installer to lift this facade panel without losing shape and put it in its seat.

Claims (1)

A thin-walled facade panel made of an aluminum-containing alloy, containing a middle part in the form of a plate with a flat front surface, made with side edges bent along its length in the direction from the front surface to the rear surface on two sides, while on one side the bent edge contains the first flat section, perpendicular to the surface of the front surface of the plate, from which the second flat section departs, perpendicular to the first and having a protrusion on the free edge, used to insert it into the cavity of one adjacent panel, and on the other side, the bent edge contains the first flat section, perpendicular to the surface of the front surface of the plate, from which a curved section extends, forming a depression directed towards the first side and used to insert a projection of another adjacent panel, characterized in that the second flat section, having a projection on the free edge, in place connection with the first flat section is made with a protrusion in the form of a continuation of the second flat section directed towards the other side and located between the first flat sections of both sides, the height of the protrusion is made not less than the width of the cavity, the width of which along the length of the plate is made greater than the thickness of the plate and equal to the width of the recess between the rear surface of the plate and the wall of the recess, while the distance from the front surface of the plate to the second flat area on the side of the cavity is greater than the distance from the front surface of the plate to the second flat area on the side of the protrusion by the thickness of the plate, and the depth of the cavity is made at least half the length the second flat section having a ledge.

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