RU90091U1 - FACADE SYSTEM WITH VENTILATED AIR GAP, ADJUSTING BRACKET, STAND AND CLAMMER INCLUDED IN IT - Google Patents

Abstract

1. The facade system with a ventilated air gap, comprising a base and supporting brackets connected to it at one end, in turn connected to additional brackets, cladding plates fixed with clamps, characterized in that the clamps are mounted on the working element of the additional bracket. ! 2. The facade system with a ventilated air gap according to claim 1, characterized in that it contains racks installed with the possibility of contact with the working element of the other end of the additional bracket and acting as a sealant. ! 3. The facade system with a ventilated air gap according to claim 1, characterized in that the clamps are installed with the ability to adjust their position on the working element of the additional bracket. ! 4. The facade system with a ventilated air gap according to claim 1, characterized in that at least one transverse groove is made on the holder of the additional bracket, forming a floating point with a longitudinal groove of the bearing bracket. ! 5. The facade system with a ventilated air gap according to claim 2, characterized in that the rack is connected to the additional bracket with at least one fastener in a floating or reference point. ! 6. An extension bracket comprising a holder and a working element connected at an angle to each other, characterized in that the working element has means for receiving the clamps or is made integrally with the clamp. ! 7. The extension bracket according to claim 6, characterized in that the working element has mounting slots. ! 8. The extension bracket according to claim 6, characterized in that the working element has mounting grooves. ! 9. An additional bracket according to claim 6, characterized in that on the reverse side

Description

The proposed utility models relate to the construction of buildings for various purposes, but mainly to outdoor fencing devices with a ventilated air gap for facade decoration and insulation of buildings under construction and reconstructed.

It is known to fasten protective and decorative facing panels with the help of clamps having a U-shape with ends bent at right angles, inserted into the slots of the guides, the lower end presses the installed panel, and the upper end is a support for the next panel (analogue is a useful model of the Russian Federation No. 33382 dated January 8, 2002)

The disadvantages of the analogue are:

- the presence of a discrepancy in the movement of the guide profile caused by thermal expansions, relative to the "fixed" base (building wall), and relatively "not expanding" facing panels;

- implementation requires high costs and the involvement of highly qualified specialists both to control the assembly process of the well-known facade system with a ventilated air gap, and to implement the assembly process itself;

- requires reinforcing the wall thickness of the guide profile, because slots reduce the load capacity from both vertical loads (panel weight) and horizontal loads - wind load.

- not evenly distributed wind load on the structure.

A known system of insulation of external fencing of buildings, consisting of fasteners made in the form of unequal reinforced corners, fixed to the wall of the building with dowel anchors, a layer of insulation, horizontal angles mounted on fasteners, vertical racks connected to horizontal corners, facing panels installed on vertical racks, and the fasteners are attached to the wall with the outer surface of the greater side of the corner up, and the upper surface of the fastener with abzhena bent tongue. The vertical struts in the section are in the form of a trapezoid and they are installed using self-tapping screws with clamps. The clamps are made in the form of plates in the body of which the tongues are cut out and bent at a right angle — stops for installing facing panels (analogue is the utility model of the Russian Federation No. 26803 dated July 10, 2002).

The disadvantages of the analogue are:

- the presence of a discrepancy in the movement of the guide profile caused by thermal expansions, relative to the "fixed" base (building wall), and relatively "not expanding" facing panels;

- racks that functionally provide sealing, being also decorative and bearing, carry an excessive vertical load, because almost the entire weight of the panels is transferred to them through fasteners, and only when the rack is deformed (usually the lower part) is the load transferred to the brackets associated with struts with fasteners at one end, and the other fixed at the base (wall). And the brackets and their fasteners (usually dowels), the parameters of which are calculated on the basis of the building height and wind load standards, usually remain underloaded.

A facade system with a ventilated air gap is known, comprising a base and a frame connected to it, bearing tiles mounted on it with the help of clamps installed on it, and having brackets located perpendicular to the base and connected to this base at one end and the other connected to guide profiles that are installed perpendicular to them, with each guide profile having an extended skeleton, which has a working plane on the outside and a rib on the inside bones, and the clammers that capture the facing plates are placed on the outer side of the working plane of the guide profiles, with each guide profile on the inner side of its skeleton and on one of its edges there is an additional stiffening rib, which on the outside is perpendicular to the working plane formed on the outer side of the core, an additional working plane is formed, and the first stiffener is parallel to the additional stiffener on the inner side of the core and in the area of its opposite edge, and, on the inside of the stiffeners in the nodes of their connection with the core, profile protrusions are formed, and longitudinal grooves are formed under them, and each guide profile on the inside of its core is connected to the respective brackets by means of a corresponding additional bracket, while on the working The planes of the guide profile are equipped with clamps, each of which has a base, and on it, at a distance from each other, at least two petals bent from it are located, having effective with elasticity and having a geometric shape that enhances the manifestation of the effect of elasticity, and between the petals at the base there are elements with which it is attached to the working surface of the said guide profile with the possibility of grasping the facing tile with the petal of another clammer fixed next to it on the same surface said guide profile, wherein at least two of the additional brackets are adjacent and connected at the same end to the corresponding brackets nami, and from the opposite end they are connected in different ways to the corresponding guide profile, while the first of the additional brackets is installed in the said grooves of the core of the guide profile with the possibility of vertical movement in them, and the second of the additional brackets is mounted motionless in the mentioned grooves of the core of the guide profile. The guide profile may consist of at least two parts, which are connected in series using an insert having parts on the longitudinal edges corresponding to said grooves of the guide profile.

The extension bracket is T-shaped.

The guide profile contains a longitudinal skeleton, on which a working plane is formed on one side, and a stiffener located perpendicular to the working plane on the other hand, and the skeleton has an additional stiffener, in which another working plane is formed on the outside, perpendicular to the working plane, having a width less than the width of the working plane, but greater than the width of the main stiffening rib, and the said stiffening ribs are located on opposite edges of the working plane of the core, and from the inside side connection angle with the inner side edges of the core along its entire length on the edges of the protrusions are formed, and below them - formed profiled grooves. The skeleton may be prefabricated of at least two parts arranged in series and connected by an insert located on the inside of the skeleton, while the components of the skeleton have the same profile, and along the edges of the insert there are parts corresponding to the profile grooves of the skeleton that interact with them and with protrusions above them, made on stiffeners (prototype - utility model of the Russian Federation No. 45418 from 12/30/2004).

However, the prototype has significant disadvantages, namely:

- racks (guide profiles), which functionally provide structural rigidity, being also decorative and load-bearing, carry excessive vertical load in the case when the additional bracket is mounted motionless in the grooves of the rack, because Almost the entire weight of the panels is transferred to the racks through the fasteners of the clamps, and the wind load also affects them. And the brackets and their fasteners (usually dowels), the parameters of which are calculated on the basis of the building height and wind load standards, usually remain underloaded;

- in the case when the additional bracket is installed in the grooves of the rack with the possibility of vertical movement in them, even with deformation of the rack (usually the lower part), the load is practically not transferred to the brackets, which is unacceptable.

Known additional bracket having the ability to smoothly move in the "clip" of the supporting bracket. This feature, combined with the possibility of combinations of various lengths of additional brackets, allows the installation of the facing material, compensating for unevenness of the wall surface and its vertical deviation. An additional bracket having a T-shape provides movements of the guide profile caused by thermal expansions relative to other “supporting” brackets (prototype is a utility model of the Russian Federation No. 45418 dated December 30, 2004).

A disadvantage of the known additional bracket is that it does not provide a uniform load of the constituent elements of the system depending on their functions and their rapid collection.

Known rack (guide profile) used in the aforementioned known facade system with a ventilated air gap. It contains an extended skeleton, on which the working plane is formed on the outside, and on the other, a stiffener, located perpendicular to the working plane of the skeleton and located in the middle of the skeleton (prototype — utility model of the Russian Federation No. 45418 of December 30, 2004).

However, the prototype has a significant drawback, which consists in the fact that this known rack has a high material consumption to ensure rigidity of the entire structure, and can only be technologically made of aluminum alloy, the melting temperature of which is much lower than the temperature in the fire, which will inevitably lead to collapse racks and immediate destruction of the entire structure in case of fire.

Known clammer made in the form of a U-shaped or L-shaped figures (prototype - Recommendations for the design and use for construction and reconstruction of buildings in Moscow "FACADE SYSTEM WITH VENTILATED AIR GAP" GRANITOGRES ", Department of Economic Research, Information and Coordination of Project GUN "NIAC", 2002, Fig.3.7 p.14).

However, the prototype has a significant drawback, which lies in the fact that this known clamp does not constructively ensure its quick installation on a bearing surface.

The first task is to eliminate the previously noted deficiencies in the well-known facade system and create its new best option, which could be implemented from a limited number of universal components with a lower total weight, and would not need to introduce special separate elements for compensating for temperature deformations necessary, as for taking into account the movements of the rack (guide profile) caused by thermal expansions relative to the “non-expanding” facing panels, so to compensate for the temperature tural deformation brackets and clamps relative to the stationary base construction.

The second task is to create a mounting unit for facing panels (additional bracket), suitable for use in a facade system with a ventilated air gap during installation of its various parts and providing load-bearing capacity from current operating loads, quick assembly, a wide range of adjustment of the distance of the cladding from the building base, and also a uniform load of the constituent elements depending on their functions.

The third task is to create options for the guide rack (guide profiles), suitable for use in a facade system with a ventilated air gap during installation of its various parts, including angular transitions, which serves as a seal.

The fourth task is to create options for a new clamp, which allows for high operational reliability and fast installation and dismantling on bearing surfaces for visible and invisible fastening of cladding panels with the selected installation method: on a finished building base and joint installation of the system and the building base.

The first problem is solved as follows. In the known facade system with a ventilated air gap containing a base and supporting brackets connected to it at one end, in turn connected to additional brackets, cladding plates fixed with clamps, according to the proposed utility model, the clamps are mounted on the working element of the additional bracket.

The system may include a stand installed with the possibility of contact with the working element of the other end of the additional bracket and acting as a sealant.

Klyammery installed with the ability to adjust their position on the working element of the additional bracket.

At least one vertical groove is made on the holder of the additional bracket, forming a floating point with a horizontal groove of the supporting bracket.

The rack is connected to the additional bracket with at least one fastener at a floating or anchor point.

The technical result from the use of the utility model is that such a new technical solution, with all its essential features, allows you to create a system that uses a limited number of universal components with a lower total weight, and does not require the introduction of special separate compensation elements necessary to account for movements racks (guide profile) caused by thermal expansions. At the same time, it is possible to change the working length of the bracket in a wide range, vertically adjust the position of the cladding plates, quickly install and disassemble them, compensate for temperature deformations of the entire structure and prevent moisture from entering the insulation located behind the cladding plates.

In addition, the new technical solution, with its whole set of essential features, allows you to create a system in which temperature deformations are perceived by the movable joints of the additional bracket and rack, additional bracket and clammer, clammer and facing panel.

The second problem is solved as follows. In the well-known additional bracket containing the holder and the working element connected at an angle to each other, according to the present utility model, the working element has means for receiving clamps.

The working element has installation slots.

The working element has installation grooves.

On the reverse side of the working element, adjustment elements are installed.

The working element has a cross-section in a C-shaped profile.

The holder has at least one vertical groove.

The technical result from the use of the utility model consists in the fact that the new technical solution, with its entire set of essential features, allows you to create a mounting unit for the cladding panels (additional bracket), suitable for use in the facade system with a ventilated air gap during installation of its various parts and providing load-bearing capacity from current operating loads, quick collectability, a wide range of adjustment of the distance of the cladding from the building base, uniform load the constituent elements according to their functions. When using an additional bracket in the system, it is possible to change the working length of the connected brackets in a wide range, to vertically adjust the position of the facing plates, and quickly install the structure on the finished building base.

The third problem is solved as follows. In a known rack containing a longitudinal skeleton, which has an internal mounting surface, as well as an external decorative and at the same time working surface, according to a utility model, the rack is provided with a vertically oriented holder located at an angle to the skeleton, made in the form of a gasket between the facing plates and the additional bracket.

The working surface has a C-shaped section in cross section.

The technical result from the use of the utility model consists in the fact that the technical solution, with its whole set of essential features, allows to reduce the loads transmitted to the rack, to create a sealing element between the cladding panels and the additional bracket, which prevents moisture from entering the insulation located in the space behind the cladding cookers.

The fourth problem is solved as follows. In the known clammer containing a base, an L-shaped lobe and fixing means, according to the present utility model, at least two opposite ends of the base serve for its fastening to the corresponding supporting structure.

Opposing vertically oriented ends of the base of the clammer are bent at a right angle.

The ends of the base of the clamp have an additional adjusting emphasis.

The clamp clamp is made in the form of a vertical extension of the upper end of the base with the possibility of covering it with an element of the supporting structure.

Such a new technical solution, with its entire set of essential features, allows you to create a new clamp that allows for high operational reliability and quick installation and dismantling on bearing surfaces for visible and invisible fastening of cladding panels with the selected installation method: on the finished building base and joint installation of the system and the building grounds

The essence of the proposed utility models is illustrated by drawings, where:

Figure 1 - part of the facade system with a ventilated air gap with a visible mount;

Figure 2 - part of the facade system with a ventilated air gap with invisible fastening;

Figure 3 (a, b) is a fragment of the system consisting of an additional bracket (two options) assembled with a stand and a clamp (outside view);

Figure 4, 5, 6 - embodiments of the additional bracket and its connection with the clamp;

7 is an embodiment of an additional bracket with a working element in the form of a fixed clamp;

Figs. 8, 9 show embodiments of a clamp;

The practical implementation of the proposed utility models is explained below by the following description of the facade system with a ventilated air gap, revealing the design of the additional bracket, stand and clamp.

The facade system with a ventilated air gap is installed on the basis of 1 (for example, the wall of a building). Perpendicular to the base 1 are the supporting brackets 2, which are connected to it by one end, and the other end is connected by an additional bracket 3.

The additional bracket 3 includes a holder 4 and a working element 5, rigidly connected at an angle to each other. The working element 5 has means for receiving the clamps 6. Means for receiving the clamps can be made in the form of mounting slots 7 (see Fig. 1, 4, 5, 6) or in the form of mounting grooves 8 (see Fig. 2, 3) . On the reverse side of the working element 5 can be made adjusting elements 9 (see Fig.5, 6).

When using the system to design the corner sections of structures, the working element 5 has a C-shaped profile in cross section (see Figs. 1, 3).

Perpendicular to the additional bracket 3, a stand 10 is installed, mounted with the possibility of contact with the working element 5 of the additional bracket 3 (see Figs. 1, 2, 3, 4). Moreover, each rack is made in the form of an extended skeleton with an internal mounting surface 11 and with a working and at the same time decorative surface 12 (see, Figs. 1, 7). The frame of the rack is a sealing gasket between the facing plates 13 and the additional bracket 3 and performs the function of a sealing windproof element of the system (see figures 1, 2). If there is a horizontal seal 14 (see figure 2) located between the facing plates, together with the stand 10 provides sealing. The stand can be equipped with a vertically oriented holder 15, located at an angle to the core.

When using the system to design the corner sections of structures, the working surface 12 of the rack 10 has a C-shaped section in cross section (see Fig. 1).

The stand 10 (guide profile) is pressed against the working element 5 of the additional bracket, which ensures its free vertical movement under temperature effects, because the fastening element 16 connecting them passes through a vertically elongated groove 17 (floating point) made on the holder 4 (see FIGS. 5, 7).

Guide profiles (racks 10) during the construction of high-rise buildings can be interconnected (vertically) through connecting inserts (not shown) or through an additional bracket. In this case, the upper point of each rack 10 is connected rigidly with the additional bracket 3 and has a thermal break with the next rack. A supporting structure thus secured transfers the vertical loads (the weight of the panels) mainly to the additional bracket 3 and, to a minimum, to the rack 10. Wind loads affect the rack 10 only as a gasket between the facing plates and the additional brackets and are transmitted through the fastener to the brackets (additional 3 and bearing 2).

Clammers 6, holding the facing plates 13 are placed on the working element 5 of the additional brackets 3. The clamps are mounted either in the mounting slots 7 (embodiments of the clamps for this type of connection are shown in Fig. 8 - a, b, d, e, g and Fig. 9 - and). Or in the installation grooves 8 (embodiments of the clamps for this type of connection are shown in Figs. 8 - c, d and Fig. 9 - h). It is possible that the working element 5 of the additional bracket can be made in the form of a fixed clamp 6 (see Fig. 7).

Clammer 6 is made in the form of a base 18 and an L-shaped lobe 19 (see Fig. 8, 9). The base of the clammer has at least two opposite vertically oriented ends 20 for attaching it to the corresponding supporting structure, in this case, to the working element 5 of the additional bracket 3.

To increase the range of vertical adjustment, the base of the clammer in the vertical direction can be asymmetrical with respect to the petals 19 (see Fig. 6), which allows you to set its optimum position for further fine adjustment by turning the clammer through 180 degrees.

The clamping means 6 can be made in the form of a vertical extension of the upper end 21 of the base 18 with the possibility of covering it with an element of the supporting structure, for example, by bending the upper end 21 of the base around the upper part of the working element 5 of the additional bracket (see Figs. 3, 4, 5 )

When using clammer 6 for installation in the slot 7 of the working element of the additional bracket, the vertically oriented ends 20 of the base are bent at a right angle to the base 18, pass through the slots 7 and bent again at an angle close to 90 degrees on the back of the working element 5 . If necessary, at the ends 20 form an adjustment stop 22.

The vertical displacement of the clamp (adjustment of its position relative to the working element 5 of the additional bracket) can be accomplished by using a special locking element 23 with an adjusting screw 24, which rests on the adjusting element 9 of the working element 5 of the additional bracket (see Fig. 6). The second option is due to the presence of the adjusting screw 23 passing through the hole in the upper end 21 of the clamp in combination with the adjusting element 9 of the working element of the additional bracket (see figure 5).

The horizontal movement of the clamp in the direction of the base 1 and thereby ensuring the pressing of the facing plate to the outer surface of the working element 5 of the additional bracket can be achieved through the use of additional fasteners - wedges or a rod with rubber rings passing through holes made on the ends 20 (conventionally given solution not shown).

In order to increase aesthetics, a hidden connection of the clamps with the facing plate is possible (see figure 2).

In fact, the supporting brackets 2, the length of which is set in advance, can be an unequal corner. The brackets 2 are attached to the base 1 (wall of the structure) using anchor dowels (depicted in figure 1, 7 conditionally). Type of anchors, their diameter, installation depth are selected depending on the applied load and wall material. Prevention of the formation of cold bridges is carried out by installing paronite gaskets 25 (see figure 1). Or the supporting brackets 2 can be embedded in the wall during its construction, in this case, the shape and design of the supporting bracket can be very diverse (an example is shown in figure 2).

It should be noted that it is possible to smoothly move the additional bracket 3 relative to the supporting bracket by almost the sum of the lengths of the additional and supporting brackets. Such adjustment is possible due to the presence of a horizontal groove 26 on the supporting bracket 2 (see Fig. 1, 2, 7). This feature allows you to change the total length of the assembly in a wide range, thereby reducing the number of standard sizes of additional brackets, and allows you to install the facing material, compensating for unevenness of the wall surface and its vertical deviation.

In this case, it is also possible to vertically adjust the position of the additional bracket 3 both relative to the supporting bracket 2 and relative to the rack 10, which is achieved by performing vertical grooves 27 on the holder 4 of the additional bracket 3 (see Figs. 1, 3, 4, 5, 6, 7).

In the system between the base 1 and the facing plates 13 can be installed insulation (conditionally not shown).

The elements of the supporting frame used in the system are mainly made of galvanized steel sheet materials, or from an aluminum profile. In the manufacture of these elements can also be used the latest materials developed recently and acceptable in terms of existing requirements for building structures.

The stand, which is a seal, can be made of both steel and materials with a melting point below 1000 degrees (temperature in the ignition zone), and when it is destroyed, it does not entail the destruction of the entire system.

A distinctive feature of the claimed system is the fastening of the decorative facing plate with the help of stainless steel fastening clamps, which are easily installed in a special groove (or slot) on the working element of the additional bracket, which makes it possible to unload the racks and give them the function of a sealant.

The proposed system and its constituent elements makes it possible to ensure a uniform load of constituent elements depending on their functions and their rapid collection.

All elements of the system can be manufactured using known technologies and known equipment.

Claims (17)

1. The facade system with a ventilated air gap, comprising a base and supporting brackets connected to it at one end, in turn connected to additional brackets, cladding plates fixed with clamps, characterized in that the clamps are mounted on the working element of the additional bracket. 2. The facade system with a ventilated air gap according to claim 1, characterized in that it contains racks installed with the possibility of contact with the working element of the other end of the additional bracket and acting as a sealant. 3. The facade system with a ventilated air gap according to claim 1, characterized in that the clamps are installed with the ability to adjust their position on the working element of the additional bracket. 4. The facade system with a ventilated air gap according to claim 1, characterized in that at least one transverse groove is made on the holder of the additional bracket, forming a floating point with a longitudinal groove of the bearing bracket. 5. The facade system with a ventilated air gap according to claim 2, characterized in that the rack is connected to the additional bracket with at least one fastener in a floating or reference point. 6. An extension bracket comprising a holder and a working element connected at an angle to each other, characterized in that the working element has means for receiving the clamps or is made integrally with the clamp. 7. The extension bracket according to claim 6, characterized in that the working element has mounting slots. 8. The extension bracket according to claim 6, characterized in that the working element has mounting grooves. 9. The extension bracket according to claim 6, characterized in that on the reverse side of the working element, adjusting elements are installed. 10. An additional bracket according to claim 6, characterized in that the working element has a C-shaped section in cross section. 11. The extension bracket according to claim 6, characterized in that the holder has at least one vertical groove. 12. A stand containing a longitudinal skeleton, which has an internal mounting surface, as well as an external decorative and at the same time working surface, characterized in that the stand is provided with a vertically oriented holder located at an angle to the skeleton, which is a sealing gasket between the facing plates and the additional bracket. 13. The rack according to item 12, wherein the working surface has a C-shaped profile in cross section. 14. Klyammer containing the base and the L-shaped petal, characterized in that the base has at least two opposite ends for attachment to the corresponding supporting structure and means of fixation. 15. Clammer according to 14, characterized in that the opposing vertically oriented ends of the base of the clammer are bent at a right angle. 16. Klyammer p. 15, characterized in that the ends of the base of the clamp have an additional adjusting emphasis. 17. Klyammer according to clause 15, characterized in that the means for fixing the clamp is made in the form of a vertical extension of the upper end of the base with the possibility of covering them with an element of the supporting structure.