RU2487218C2 - Blast resistant bearing profile structure of facade system - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: blast resistant bearing profiled structure of a facade system comprises a frame formed by vertical stand bearing profile structures and horizontal crossbar bearing profile structures. Flat elements are attached to the frame with the help of pressing profiles. Bearing profile structures are made with a solid bearing profile. In the bearing profile there is at least one energy-absorbing component for absorption of energy released in explosions. The energy-absorbing component is arranged as compressible. In the plane perpendicular to the direction of the longitudinal axis of the bearing profile, the component at all sides is surrounded with walls of the solid bearing profile.

EFFECT: prevention of structure damage.

35 cl, 12 dwg

Description

This invention relates to an explosion-proof supporting profile design of the facade system.

A facade system of a known type that does not have an explosion-proof structure is disclosed in DE 2 9 919 630 U1.

The facade system of the explosion-proof structure is disclosed in DE 20 2007007113 U1. This system has load-bearing profile structures that have a complex configuration and are less aesthetically attractive compared to the known facade systems. Similar disadvantages are inherent in the system known from DE 3744816 U1.

The objective of the invention is to eliminate this problem. The solution to this problem is disclosed in paragraph 1 of the claims.

Accordingly, the supporting profile structures preferably have a solid supporting profile in which at least one energy-absorbing component is installed, or which has a component designed to absorb the energy released during explosions.

The appearance of the proposed supporting profile design does not differ from systems that do not have an anti-explosion effect, since the cross sections of the energy-absorbing elements are perpendicular to the length

Supporting profile constructions according to any one of the preceding paragraphs, characterized in that the supporting profiles are fully integrated into the supporting profile, or are completely surrounded by the cross-section in the supporting profile, or form an invisible part of this supporting profile from the outside.

In addition, an excellent anti-explosive effect is achieved both in relation to compression that occurs first after the explosion, and preferably in relation to subsequent rarefaction. This option is not only an improvement, but also a solution, which in itself should be considered as an independent invention. Accordingly, this component is designed in order to first absorb the energy of the compression shock wave released during the explosions, and then to absorb the energy of the rarefaction shock wave, and thus it is especially effective to avoid damage.

Preferably, at least one base is present on this component. This base has the advantage that it creates a section with the possibility of reliable holding on the component, especially if the base is made in the form of at least one or more support plates.

In addition, the base is well suited for installing and executing a compressible element and / or for implementing a technique consisting in the fact that at least one protrusion is made on this element, in particular on its base, which engages with the corresponding recess on the carrier profile only in case of explosion. This allows you to easily perform the main function. It is also possible to equip this protrusion with a locking head, which enters the recess on the carrier profile only after the explosion, which ensures the following: when during the explosion, sections of the carrier profile connected to each other at predetermined weakened or weakened places of separation or kink either collide with each other, or are torn apart, the compressible element will additionally in a predetermined manner connect these areas using the fixing heads or similar means, in particular in order to first prevent crushing the supporting profile portion as a result of compression, and then to prevent detachment of said portion during the subsequent vacuum. This design, in addition, facilitates the preliminary assembly of the element. On the other hand, energy absorption is possible when the fixing head enters the recess, since deformation of the fixing head and / or recess itself is possible. In addition to this, it is advisable that the wall thickness of the supporting profile in the area containing this element is less than the thickness of its other walls extending perpendicular to the plane of the flat element.

It is advisable that said at least one protrusion be a volume part.

In accordance with one embodiment of the invention, said at least one protrusion is made in the form of a continuous jumper, along the entire length parallel to the supporting profile. However, an alternative is also possible, in which the protrusion is a jumper interrupted in some areas and running parallel to the supporting profile.

Preferred embodiments of the invention are given in the dependent claims.

Below the invention is disclosed in more detail on the examples of implementation, accompanied by drawings.

Figure 1-7 are cross-sections of various supporting structural structures for facade systems of buildings.

Figa-8d are successive sections of the supporting profile structure; which, as an example, schematically illustrate the time behavior of the supporting profile structure of FIG. 1 before and after the explosion. Fig.9 depicts a section of a section of the rack of the proposed facade system.

Figure 1-7 shows several options for supporting the profile structures of the facade system, implemented, with the exception of the supporting profile structures, for example, similarly disclosed in the document DE 2991930 U1, with a frame formed from vertical rack supporting profiles 1 (see also Fig.9 revealing the fundamentals of this design) and horizontal crossbar supporting profile structures, moreover, flat elements 4 are fixed on said frame using clamping profiles 2 through seals 3. The configurations described below are realizable as in ontalnyh transom and vertical rack bearing profile design. In the mounted state, the supporting profiles are inside, and the pressure profiles are outside the plane of the flat elements of the building.

According to Fig.9, the clamping profiles 2 have, for example, an outer contour of a trapezoidal section and are fastened with bolts 5 and grooved crackers 6 mounted on bolts 5 in dovetail grooves 7, made with undercutting on supporting profile structures, with flat elements 4 are held between the clamping profiles 2 and the supporting profiles 1. Protective covers 8 are fixed to the clamping profiles 2.

To begin with, we will open in more detail the supporting profile structure 1, with figure 1.

Preferably, the supporting profile structure 1 is mirror symmetric on both sides of the median plane M extending perpendicular to the plane of the drawing of FIG. 1. Although this condition is not mandatory, it positively affects the behavior of the structure after the explosion.

In addition, the supporting profile structure 1 preferably has a solid metal supporting profile 9, which in accordance with one embodiment of the invention contains one internal cavity (Figs. 1-3), and according to another embodiment, several internal cavities 10, 11 (Fig. 6, 7). If only one cavity is provided, it can be divided into regions 12, 13 (Figs. 1, 2, 3) with jumpers 14 (see, for example, Figs. 1, 2, 3), protruding inward from the support profile. If several cavities are provided, it is possible to separate them from each other by partitions 15 (Fig.6, 7).

According to figure 1-7, it is preferable that the supporting or supporting profile 9 was made integral.

According to FIGS. 1-7, a region 12 (FIGS. 1-3), or a cavity 10 (FIGS. 4-7), which is opposite to the relatively flat elements 4, is preferably inserted, preferably a hollow and preferably metal reinforcing profile 16 is also of rectangular cross section.

In accordance with figures 1-4 and 6-7, in the part of the region 12 formed between the jumpers 14, the reinforcing profile 16 and the region 13 or the additional region 11, in each case an energy-absorbing component 17 is installed, intended for absorption, or absorption due to deformation, kinetic energy resulting from the fact that during the explosion, the pressure profile moves relative to the facade profile. In the section with FIG. 1, that is, in a plane perpendicular to the length of the bearing profiles, the component 17 is surrounded on all sides by the bearing profile. Similarly illustrated in the drawings, it is also possible to arrange it in the form of a profile perpendicular to the plane of the drawings. In this case, both continuous and individual configurations are permissible.

The supporting profile structures 1 are made in such a way that they absorb the energy released during explosions inside or outside the building.

For this, each of the supporting profile structures 1 shown in Figs. 1-7 is equipped with at least one or more energy absorbing components 17 integrated into the supporting profiles 9 so that they are not visible from the outside. Implementation of them as a whole with the bearing profiles 9, or in the form of a separate part or several parts, with the possibility of subsequent insertion into the bearing profiles.

In this case, the energy-absorbing components 17 are made in such a way that they quench, absorb and dissipate the energy released during the explosion. If desired, it is possible to carry out at least a portion of the illustrated load-bearing profiles 9 in such a way that the absorption of energy released during the explosion also occurs by the said profiles.

According to figure 1, the components 17 have two support plates 18, 19, which in this example are parallel in parallel at some distance from each other and connected into a single part by means of one or, as in this example, several jumpers 20.

A V-shaped or curved configuration of the jumpers 20 themselves is possible, in which case a kind of predetermined bending section is made at the top V, and the angle a of the solution V is preferably more than 0 °, in particular preferably more than 30 °.

In this example, the support plates 18, 19 are oriented parallel to the plane of the flat elements 4.

The protrusions 21, forming in this example volumetric parts protruding towards the outer side of the facade, and at the top of which there is a kind of fixing head, in this example a mushroom-shaped head 19, protrude from the base plate 19, located closer to the flat elements 4.

On the inner side of each wall 24 of the supporting profiles, on which flat elements are supported through the seals in the recesses 23 and in which in this case there is a groove 7, at least one recess 25 is made, intended to be placed after the explosion, fixing or, as in this example, mushroom heads 22, but in which, in the normal state of fastening the facade on the building, these mushroom heads 22 are not included.

In the section 28, parallel to the protrusions 21, the thickness of the two walls 26, 27 of the support profile 9 extending perpendicular to the wall 24 is less than in its remaining sections, and if necessary, these walls are provided with predetermined V-shaped sections 29 bending.

In this case, for example, the protrusions 21 contain a double-walled diamond-shaped part, made in such a way as to absorb energy due to deformation after the explosions, as well as a part intended to set the direction and fixation, that is, the locking head 22. The operation of the structure of FIG. on figa - 8d.

Figa corresponds to Fig.1 and shows the state of the supporting profile structure 1 before the explosion. If the explosion occurs outside the building, the clamping profile 2 will, in particular, press through the groove cracker 6 into the groove 7 against the wall 24 with a force F directed inside the building, which will lead to deformation of the thinner sections 28 and, subject to the presence, predetermined sections 29 bends. If during the explosion there is such a relative movement between the clamping profiles 2 and the supporting profile structures 1, then the outer or supporting profiles 9 are first deformed in this area and, thus, they themselves will absorb a certain amount of energy (Fig. 8b, 8 c).

In addition, there is a relative movement between the wall 24 and the energy-absorbing component 17, which ultimately leads to the mushroom-shaped heads 22 being fixed in the recesses 25 provided for this (Fig. 8 c).

After this, or simultaneously with this, the energy-absorbing component 17 is compressed. Thus, according to Fig. 8, the jumpers 20 are deformed, as a result of which the two support plates 18, 19 move towards each other, and due to the deformation of the jumpers 20, the energy is also converted or absorbed . In addition, the protrusions 21 are also deformed, preferably made in such a way (for example, with two walls) that during the explosion they contract and deform, as a result also absorbing energy.

Finally, due to pressure differences after the explosion (due to rarefaction) there is a movement in the opposite direction, in which the jumpers 20 are stretched and, in particular, even burst. There may also be tears in the area of predetermined bending points 29 and thinner sections of the wall 28. However, as a rule or often, fixing or mushroom-shaped heads 22 prevent the wall 24 from completely tearing away from the rest of the profile. In this case, the internal jumpers or protrusions 14 hold one of the support plates 19. In addition, they themselves absorb energy due to deformation.

It is possible to perform an energy-absorbing component 17 in the form of one or more parts. Single piece performance is preferred. If necessary, it is possible on the component 17 to perform, in particular, by molding, a foamed portion or other compressible element.

Accordingly, instead of the jumpers 20, which are part of the energy-absorbing component 17, between the support plates 18, 19 it is possible to arrange (an arrangement not shown) a compressible element 30 of elastomer, cellular material, metal foam or similar material, provided that this compressible element is fixed on the support plates 18 , 19 by, for example, coextrusion. For aluminum profiles, it is advisable and preferable to use aluminum foam 30 (Fig. 5), which will make it possible to perform energy-absorbing components 17 also on sections of the profile itself.

In addition, the use of such an element 30 will dispense with one of the two support plates 18, 19 (FIG. 3) and install the element 30 directly on one remaining support plate 19.

Preferably, the support plate 19 remains adjacent to the webs 14. This arrangement is shown in FIG. 2. Otherwise, the principle of operation in general corresponds to the principle of Fig. 8, with the difference that compression occurs first and then the element 30 expands.

According to Fig. 3, instead of the locking heads 22, capable of engaging with the locking recesses 25 during the explosion, small projections 31 are made on the two supporting plates 18, 19 in the form of jumpers separated by a compressible element 30, which are not able to enter into the locking engagement with the corresponding recesses 32 in the (double) wall 24, while, however, it is possible to enter these recesses, providing directional arrangement or even clamping. As a result, this option does not provide for fixation with figure 1. In this case, through the wall 24, it is permissible to screw a screw 35 into the components 17, 30, which will allow for a fixation similar to that obtained with the use of the fixing heads 22, also during expansion similar to that shown in Fig. 8 c (see Fig. 3). This will make the use of mushroom-shaped protrusions 22 (FIG. 3) optional.

According to figure 4, the cavity 13 is filled with an energy-absorbing component 17 made of compressible material.

The use of metal foam allows you to perform an integral part of the metal profile of the foam itself (see figure 5). In addition, according to the variants of FIGS. 4 and 5, when compressing the components 17, made in this case in the form of compressible components 17, 30, the energy is absorbed first by compression. In addition, it is preferable that the metal foam used also provide protection against tearing during a rarefaction shock wave.

According to FIG. 6, an energy-absorbing component 17 or 30 is installed in the cavity 11, having protrusions or parts with fixing heads 22 directed not only toward the wall 24, but also towards the partition 15, and the fixing recesses 25 are also provided in the partition 15 so that under the action of a compression shock wave on both sides, the locking heads 22 come into engagement with the antidirectional locking recesses 25.

It is possible to make the component 17 of FIG. 6 from a compressible material and one-piece, or, similarly to that shown in FIG. 1, having two support plates 18, 19 (the latter is not shown).

Accordingly, in the example embodiment of FIG. 7, jumpers 31 and recesses 32 are provided on two opposed outer surfaces of the energy absorbing element 17, as well as on the wall 24 and the partition 15, and it is possible to additionally provide a threaded hole (not shown) in the element 17.

In addition, jumpers 33 and recesses 34 parallel to the planes of the planar element 4 mesh with each other and thus hold the energy-absorbing component 17 in the appropriate mounting position. This solution is also shown in FIG. 3 for the lower or inner support plate 19.

In all variants of the invention, there is no violation of the appearance in terms of the integrity of the supporting profile structure. At the same time, however, reliable explosion protection is provided.

Item Numbers

rack-mount profile structures one Clamping profiles 2 Seals 3 Flat elements four Screws 5 Groove crackers 6 Grooves 7 Protective covers 8 Support profile 9 Cavities 10, 11 Areas 12, 13 Jumpers fourteen Partitions fifteen Reinforcing profile 16 Component 17 Plates 18, 19 Jumpers twenty Tabs / Volumetric Parts 21 Mushroom head 22 Recesses 23 Wall 24 Recesses 25 Walls 26, 27 Wall section 28 Preset bending points 29th Element thirty Protrusions 31 Recesses 32 Jumpers 33 Recesses 34 Screw 35 Median plane M Force F

Claims (35)

1. An explosion-proof supporting profile structure of the facade system, comprising a frame formed by vertical rack-mounted supporting profile structures (1) and horizontal crossbar supporting profile structures, moreover, flat elements (4) are attached to this frame using clamping profiles (2), and the supporting profile structures contain an integral bearing profile (9), wherein at least one energy-absorbing component (17) is installed in said bearing profile (9), designed to absorb released When energy bursts, wherein the energy absorbing component (17) is compressible, characterized in that in a plane perpendicular to the longitudinal axis of the carrier profile, a component (17) is surrounded by walls integral carrier profile. 2. An explosion-proof supporting profile structure according to claim 1, characterized in that the component (17) is designed to absorb the energy of the compression shock wave released during the explosion. 3. An explosion-proof supporting profile structure according to claim 2, characterized in that the component (17) is designed to absorb the energy of the rarefaction shock wave generated during the explosion. 4. The anti-explosive supporting profile structure according to claim 1, characterized in that the component (17) is designed to first absorb the energy of the compression shock wave released during explosions, and then absorb the energy of the rarefaction shock wave. 5. An explosion-proof supporting profile structure according to any one of claims 1 to 4, characterized in that the component (17) is made integral. 6. An explosion-proof supporting profile structure according to any one of claims 1 to 4, characterized in that the component (17) contains several parts. 7. An explosion-proof supporting profile structure according to any one of claims 1 to 4, characterized in that the component (17) is made of plastic and / or metal. 8. An explosion-proof supporting profile structure according to any one of claims 1 to 4, characterized in that at least one or more bases (18, 19) are made on the component (17). 9. An explosion-proof supporting profile structure according to any one of claims 1 to 4, characterized in that the base is made in the form of at least one or more support plates (18, 19). 10. An explosion-proof supporting profile structure according to any one of claims 1 to 4, characterized in that a compressible section is made on said at least one support plate (18). 11. An explosion-proof supporting profile structure according to any one of claims 1 to 4, characterized in that a compressible element is located on said at least one support plate (18). 12. An explosion-proof supporting profile structure according to any one of claims 1 to 4, characterized in that the support plate (18, 19) and the element (30) are made by coextrusion. 13. An explosion-proof supporting profile structure according to any one of claims 1 to 4, characterized in that the support plates (18, 19) are oriented parallel to the plane of the flat element (4). 14. An explosion-proof supporting profile structure according to any one of claims 1 to 4, characterized in that at least one protrusion (21, 23, 31) is engaged on the element, in particular on the basis of (18, 19), which engages with the corresponding recess (25, 32) only after the explosion. 15. An explosion-proof supporting profile structure according to any one of claims 1 to 4, characterized in that said at least one protrusion (21) is a volumetric part. 16. An explosion-proof supporting profile structure according to any one of claims 1 to 4, characterized in that said at least one protrusion (21) is a jumper parallel to the supporting profile. 17. An explosion-proof supporting profile structure according to any one of claims 1 to 4, characterized in that said at least one protrusion (21) is a jumper interrupted in some sections and running parallel to the supporting profile. 18. Anti-explosive supporting profile structure according to any one of claims 1 to 4, characterized in that said at least one protrusion (21, 23, 31) has a locking head (23) designed to engage in locking engagement with the corresponding mating locking recesses (25) only after the explosion. 19. An explosion-proof supporting profile structure according to any one of claims 1 to 4, characterized in that there are several locking heads (22) and locking recesses (25). 20. An explosion-proof supporting profile structure according to any one of claims 1 to 4, characterized in that said at least one or more locking heads (22) are made on only one of the support plates (18, 19). 21. The anti-explosive supporting profile structure according to any one of claims 1 to 4, characterized in that in each case at least one or more protrusions, in particular with locking heads (22) and locking recesses (25), are made on two opposite each other to the other outer surfaces of the support plates (18, 19), or on the walls (24), or on the inner partition (15) of the metal profile. 22. An anti-explosive supporting profile structure according to any one of claims 1 to 4, characterized in that said at least one protrusion after the explosion enters with a clip into the corresponding mating recess (25). 23. An explosion-proof supporting profile structure according to any one of claims 1 to 4, characterized in that the component (17) is a foamed section made integrally with the supporting profile (9). 24. An explosion-proof supporting profile structure according to any one of claims 1 to 4, characterized in that said component is a foamed portion placed in the cavity of the supporting profile (9). 25. An explosion-proof supporting profile structure according to any one of claims 1 to 4, characterized in that a groove (7) is made in the supporting profile (9) to accommodate the groove cracker (6) on the screw (5) or bolt connecting the clamping profile (2 ) with the supporting profile (9). 26. An explosion-proof supporting profile structure according to any one of claims 1 to 4, characterized in that the threaded connection of the screw (35) passes into the component (17). 27. An explosion-proof supporting profile structure according to any one of claims 1 to 4, characterized in that the component (17) is attached to the supporting profile. 28. An explosion-proof supporting profile structure according to any one of claims 1 to 4, characterized in that the support plates (18, 19) are connected to each other by at least one compressible element (30). 29. An explosion-proof supporting profile structure according to any one of claims 1 to 4, characterized in that the compressible element (30) is made of foam material. 30. An explosion-proof supporting profile structure according to any one of claims 1 to 4, characterized in that the support plates (18, 19) are connected to each other by jumpers (20), made integrally with the support plates (18, 19) and having the ability explosion deformation. 31. An explosion-proof supporting profile structure according to any one of claims 1 to 4, characterized in that the jumpers (20) have a predetermined bending location. 32. An explosion-proof supporting profile structure according to any one of claims 1 to 4, characterized in that the supporting profile (9) has one or more cavities (10, 11). 33. An explosion-proof supporting profile structure according to any one of claims 1 to 4, characterized in that the supporting profile (9) has internal jumpers (14) or a partition designed to fit component (17) to them. 34. An explosion-proof supporting profile structure according to any one of claims 1 to 4, characterized in that preferably a metal reinforcing profile (16) is additionally inserted into the supporting profile (9). 35. An anti-explosive supporting profile structure according to any one of claims 1 to 4, characterized in that the wall thickness of the supporting profile (9) in the area containing the component (17) is less than the thickness of its remaining walls perpendicular to the plane of the flat elements.

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