EA024011B1 - Frame system of hinged ventilated facade for multi-storey building - Google Patents

Abstract

The claimed invention is related to civil engineering, in particular, to design of a frame system of a hinged ventilated facade for a multi-storey building, the frame system comprising multiple vertical guide beams fixed in respect of the building floors at preset points by means of respective support assemblies, each containing at least an Π-shaped bracket, and to different design versions of the named support assemblies. Each vertical guide beam consists of sections of single-chamber main metal shape linked in series to each other by means of a joint assembly including a joint means with an additional coupling metal shape. Vertical guides together with respective support assemblies form a beam structure of multi-span flexural continuous type with momentous longitudinally movable coupling assemblies wherein the coupling assemblies are provided in the points where the bending moment M=0. The lowermost support assembly is implemented as a longitudinally movable hinged support assembly, and the uppermost support assembly and the support assemblies located between the lowermost and the uppermost support assemblies are implemented as load-bearing hinged support assemblies. The lowermost span is designed as a single-span two-support beam with a cantilever and the lowermost longitudinally movable hinged support; the uppermost span is implemented as a beam having at its top point a hinged joint with the fixed load-carrying support, and at its bottom point a longitudinally movable momentous joint with a cantilever of an ordinary span, and ordinary spans are implemented as beams having one load-carrying hinged support linked with the base, while a longitudinally movable momentous joint with the cantilever of the lower course beam is used as the second support.

Description

The claimed invention relates to the construction, namely, to the designs of frame systems and support units of the frame system of the hinged ventilated facade of a multi-storey building, and can be used in the construction of hinged facades of multi-storey buildings. The frame system refers to the frame systems of the hinged ventilated facade (IWF) of a multi-storey building, consisting of many vertical guide rails, installed with a certain step and with a gap with respect to the plane of the ends of the floors of the building and fixed with respect to the floors of the building at the specified points using the appropriate nodes supports, each of which contains at least a U-shaped bracket.

The design of a heat-insulating NVF, in the General case, consists of a layer of insulation, mounted directly to the facade, and a power frame system, which consists of vertical and, if necessary, horizontal rails, fixed to the facade by means of brackets, and allows you to fasten the facing plate with the formation air gap between the insulation and cladding. As the facade facing materials, slabs of a wide variety of materials can be used: aluminum, steel, fiber cement, asbestos cement, granite, granite, etc.

The strength and reliability of the illegal armed forces depends on the correct choice of the mounting frame systems in relation to the facade. In this regard, for multi-storey buildings, primarily buildings of frame construction, it is advisable to transfer loads to the ceiling (from a less dense wall material to a monolithic frame). In this case, the transfer of loads should be carried out in such a way that the maximum load falls on the attachment points in the monolithic frame of the building (to solve this problem, various power brackets are designed to withstand increased loads [1]), and linear thermal expansion was compensated for the entire facade area. For the effective solution of the latter problem, accurate selection and calculation of all elements of the frame system and the relationships between them are necessary.

Modern practice shows that the installation of the system in a monolithic way only (in ceilings) leads to the need to use increased vertical guides in length. As a rule, these are sections of a profile with a length of 3.5-4 m (in accordance with the interfloor distance). At the same time, with an average temperature difference of 100 ° C (-40 ° C and + 60 ° C), significant thermal expansions occur (for aluminum structures 9.6 mm, and for steel structures 4.8 mm on a 4-meter profile) [2] . Given that the materials for the manufacture of the NVF frame system and for the manufacture of cladding plates have different coefficients of linear expansion, and also that the annual temperature difference (depending on the climatic zone) on the facade can reach 120-130 ° C, all this, if you do not calculate and structural modeling, will definitely lead to a violation of the facade geometry and will create a danger of destruction and collapse of both the facing material and the system as a whole. In addition, there is an increased load on the support nodes and connecting elements of the system, which has a negative impact on their durability. To eliminate the negative impact on the frame system of various coefficients of linear expansion of structural elements over certain distances along the facade, it is necessary to arrange expansion joints (gaps) that divide the facade into temperature blocks, within which mutual deformations of various materials do not cause damage to the lining and system. Currently, this is achieved by cutting profiles along the line of the expansion joint with the formation of a through gap of 6-10 mm. But in this case there are problems of placing additional brackets (supports), as well as the formation of communication between them and vertical guides.

Another problem that needs to be solved when designing illegal armed forces as a whole and the illegal armed forces frame system in particular is the uniform distribution of loads on the frame system (vertical guides and bearing support nodes) and structural elements (floors) of the building, and the distribution should be controlled distribution. In the general case, the load from the weight of the cladding and the wind load are transmitted through vertical guides to the brackets (support nodes) and further to the floors of the building. In this regard, the correct selection / calculation of the design of the support and bracket assembly in its composition is especially important.

In most frame systems of illegal armed groups from the prior art, the supporting brackets were L-shaped [3] or T-shaped [4].

So, the frame system is known from the RONSON NVF system, developed by the Ronson Engineering design bureau, which provides for fastening exclusively to floor floors [5]. In this frame system, the support bracket has a high bearing capacity and an adjustable extension length, a reinforced vertical profile allows you to create vertical spans for attaching the facing material up to 4 m high without additional intermediate supports. Due to the increase in the vertical pitch of the arrangement of the support brackets (bearing nodes of the support), the number of components used is reduced. This entails a reduction in the cost of installing an illegal armed formation, reduces the commissioning time of the facility, and also improves the thermal characteristics of the building due to the reduction of heat-conducting inclusions (cold bridges). However, the described system, in addition to vertical guides, contains additionally reinforced horizontal guides having increased resistance to wind loads. For this and similar systems

- 1 024011 a special vertical guide was developed for fastening the NVF facing plates [6], which consists of hollow profiles with bends installed sequentially in height with a gap between each other, each of which is rigidly connected from one end to the end of the vertical strut, which is its other end interacts on a sliding fit with the opposite end of the adjacent profile. At the end of each profile, with which the rack interacts on a sliding landing, a locking element is installed, forming together with the internal surface of the profile a closed surface, at least part of the cross section of which has the shape of the external contour of the rack. Each rack is installed with its ends inside adjacent profiles and is tightly covered by a specified closed surface. The described vertical guide allows you to significantly simplify the installation process of illegal armed forces, increase the bearing capacity and reliability of the system and improve the aesthetic quality of the cladding.

Nowadays, NVF frame systems are also known, in which the supporting bracket has a U-shape, which, in contrast to the L-shaped and T-shaped, more efficiently accepts loads. So, the RusExp system for illegal armed groups is known [7], which consists of many vertical guides fixed to the building floors at specified points using the corresponding support nodes, each of which contains a U-shaped bracket. The number of elements in such a system is minimal, which simplifies installation and storage, as well as transport costs for delivery to the facility. The design of the bracket allows leveling from 0 to 110 mm and at the same time makes it possible to move the cladding 450 mm from the wall. This makes it possible to virtually eliminate the need for detailed geodetic surveys (since the brackets cover a wider range of curvature), as well as on complex objects, it is necessary to dispense with one standard size of the brackets. In addition, the height of the bracket can vary from 75 to 150 mm, depending on the strength calculations. The bracket provides for vertical displacement relative to the guide, which avoids the installation of the bracket in the reinforcement, the seam and compensates for thermal deformation of the system. Those. the bracket has a freely articulated connection in the horizontal plane. The design of the bracket allows you to change the angle of its installation relative to the guide, which allows you to compensate for the curvature of the bearing wall at the installation location of the bracket.

Also known is the NUN i-cop system, which is intended for fastening the frame system only to reinforced concrete floors of a building [8]. The guiding profiles of the NUN system have a developed cross-section in height, which ensures their increased stiffness over large spans. The reinforced shaped bracket design allows you to fasten the ends of the profiles in one bracket, while maintaining the principle of freedom of movement of one of them to compensate for thermal expansion. To absorb tearing forces, the bracket can be attached using two or four anchor elements. The main feature of fastening two guides in one bracket is to reduce the deflection of the guide due to pinching of its ends in the slide mounted on the support bracket. In the I-kop NVF system, in general, it is mentioned that the proposed constructive solution provides for the possibility of compensating for thermal deformations of the building facade elements without destroying the cladding materials and substructure (frame system) and changing the geometry of the cladding seams. In contrast to the oval holes used in most other systems, where the strain is limited by the size of the hole, the described system excludes rigid fixation of the guide and provides a significant amount of displacement. At the same time, the slide system ensures the vertical position of the guide regardless of the position of the mounting brackets relative to the vertical axis and to each other. The gap between the ends of the rails depends on the climatic conditions of the area and is determined by calculation [9].

There is also a technical solution of the SIAL NVF system with hidden stone fastening [10]. The SIAL NVF skeleton system consists of a multitude of vertical guides installed with a certain step and with a gap with respect to the plane of the ends of the floors of the building and fixed with respect to the floors of the building at specified points using the respective support nodes, each of which contains at least a bracket U-shaped. Some of the nodes of the supports are made in the form of bearing supports. Each vertical guide consists of at least two segments of a single-chamber metal profile of the guide, each of which forms a corresponding span, connected in series with each other using the interface unit. The interface unit contains a pair of means and fasteners and is configured to compensate for deformations. Each bracket is associated with a corresponding segment of the guide profile from the side of its side walls at the design point. However, the frame system under consideration also includes horizontal guides.

The design of the frame system as a whole, as well as the design of the frame support unit proposed in the framework of the SIAL P-NK system, can be adopted as prototypes for the variants of the IHF frame system of a multi-storey building and the frame system support unit, as claimed in this application.

The analysis of the prior art showed that not one of the existing systems of illegal armed formation as a whole and not a single frame system in their composition can provide an effective solution to the problems of compensation of linear

- 2 024011 thermal expansions over the entire area of the facade, increasing the nominal values and redistributing the loads on the IWF frame system and frame building structures, thereby increasing the reliability of the IWF, for all possible use cases.

At the same time, practice shows that it is advisable to solve all of the above-mentioned problems and tasks of calculating and designing systems of illegal armed groups to achieve the optimal result. The complexity of solving problems and tasks is determined, in particular, by the fact that both a source of data and target parameters use a fairly large number of physicomechanical, geometric and other characteristics of individual structural elements and units of the frame system, structural elements (floors) of buildings, as well as the connections between them. So, some comprehensive studies of the deformability of structural solutions of elements of the frame system of illegal armed groups are known [11]. However, in this work, the main attention is paid to the calculation and modeling of the bracket for attaching the vertical rails to the floor slabs and only insignificantly to its behavior as a part of the frame system as a whole.

Thus, the objective of the invention is to develop the design of the frame system of illegal armed forces of a multi-storey building and various options for support nodes, including a U-shaped bracket, which in all possible schemes of fastening vertical guides by means of support nodes in various versions of their design should provide higher strength and higher rigidity frame system and in case of emergency lead to minimal damage to the frame system and thereby ensure a higher reliability and durability of the framing system and the entire outer finishing system (lining) of the building as a whole. In addition, the frame system and variants of the support assembly from its composition must withstand higher loads (both determined by the mass of the facing elements and the wind) and have high maintainability.

It should be noted that in the framework of the present application, the term reference node refers to all possible types of nodes for attaching a vertical rail to the elements of the interfloor floors of a multi-storey building, regardless of whether the bracket included in it is a carrier according to its function (i.e., perceives both vertical and horizontal loads on the frame system) or supporting (i.e., it accepts only horizontal loads).

In the framework of the present invention, there will be proposed a frame system of illegal armed forces and its elements (support nodes) that can be used, including as part of the currently widely used frame schemes of buildings, in which building envelopes are mounted and transfer loads to the building frame only in points of attachment to ceilings located at regular intervals equal to the height of the floor. In these cases, the basis of the enclosing structure is a frame consisting of many vertical guides made of metal profiles, fixed in relation to the ceilings. At the same time, from the point of view of modeling and calculation of the load distribution, the vertical elements form a beam structure that receives vertical and horizontal loads and transfers it to the building frame at the points of attachment to the floors.

In general, in multi-span structures (consisting of a plurality of spaced beam elements arranged consecutively in the vertical direction, referred to as beam guides in the framework of the present invention), vertical guides are possible of several guiding-beam – support-node – support node – building overlap patterns, which are shown in FIG. one:

a) simple single-span beams with articulated supports (scheme a)),

b) multi-span hinged beams of the first and second types (scheme b)),

c) multi-span continuous beams (scheme c)).

All of the above schemes have advantages and disadvantages. As applied to the frame system of ventilated facades, they are expressed as follows.

Scheme a). The main advantage is the independence of the frame system in each of the spans, since the spans do not affect each other constructively. An emergency condition or destruction in one of the spans does not affect the state of neighboring ones, thus preventing an avalanche-like destruction. In this scheme, each vertical beam-guide is a single-span hinged-supported beam with one movable support and is statically determinable, it is quite simply and unambiguously calculated, it is not affected by the settlement of supports and temperature deformations of the frame and the beam itself. In this case, the main disadvantage is the lowest load-bearing capacity both in strength and in stiffness compared to other schemes.

Scheme b). In this diagram, each vertical beam guide is a hinged beam. Hinged beams have an advantage over simple single-span, which consists in higher bearing capacity due to the unloading action of the consoles of adjacent beams. Depending on the magnitude of the hinge displacement relative to the support unit, it is possible to implement both a maximum stiffness scheme (when the hinge is shifted by 0.211 b, deflections are minimized) and a maximum strength scheme (moments are minimized at 0.147 b due to the alignment of the span moments with the supporting ones). Depending on the combination of span, load and rigidity of the beam (EC, the limiting factor can be both deflection and strength of the cross section. Joint displacement by a certain

- 3 024011 value, it is possible to optimally design a guide rail interface circuit. The main disadvantage of articulated beams is the mutual influence of spans on each other, which reduces the reliability of the structure as a whole. Moreover, the reliability of the hinge beam of the first type is significantly lower than the hinge beam of the second type, which is the alternation through the span of the main two-console and flip hinge beams. So, in the event of the destruction of the double support beam in the scheme b) of the first type, the entire remaining part of the hinged beam becomes a geometrically variable system and completely loses its bearing capacity. If any of the middle beams collapses, then the part of the structure to the right of the destroyed span becomes geometrically variable, and the span moment increases in the beam to the left, since the unloading effect of the adjacent span disappears, which also leads to sequential destruction of the whole structure if the stock is not intentionally made durability in this case. Scheme b) of the second type has higher reliability in the event of the destruction of one of the spans. So, in the event of the collapse of the flange, the remaining parts of the structure remain geometrically unchanged, only in adjacent spans the bending moments increase. If the main beam collapses, then two adjacent flip beams lose their bearing capacity, since they lose support from the side of the destroyed main beam, and then the destruction stops if the calculation takes into account the increase in bending moments in the spans.

Scheme c). Its use in the case of a continuous inextricable section of the beam along the length is limited by the amount of permissible temperature deformations, ease of installation and, as a rule, in the case of using hinged facade structures, does not exceed 6 m, which corresponds to a two-span design.

To increase the bearing capacity of the NVF frame system with fastening only in the areas of interfloor ceilings, the author has developed (simulated and calculated) schemes for connecting individual structural elements of the frame system with each other and with the base (floors of the building), combining the properties of higher bearing capacity of hinged and continuous beams and the reliability of simple single-span beams.

It was possible to achieve the necessary characteristics of bearing capacity and reliability in the claimed versions of the IWF frame systems by creating original flexural-continuous, longitudinally movable joints, as well as articulated longitudinally movable joints arranged in a certain way with the provision of measures to prevent the spread of destruction along the chain of coupled mounting elements.

Moreover, unexpectedly, the specific features of the structural elements proposed as part of the frame system provide the possibility of using the same specially designed profile for the said joints, which allows creating a momentary longitudinally movable joint with a minimum clearance in the interface;

articulated longitudinally movable joint with the desired mutual rotation angle of the mating sections;

longitudinally movable articulation of the mounting element with the bracket; increase the range of horizontal adjustment of the guide on the bracket; safety or reinforcing element to prevent the transfer of destruction along the chain of beams.

Thus, the task is solved by the claimed frame system of illegal armed groups of a multi-storey building, consisting of many vertical guides-beams installed with a certain step and with a gap with respect to the plane of the ends of the floors of the building and fixed with respect to the floors of the building at the specified points using the corresponding support nodes , each of which contains at least a U-shaped bracket, and at least one of the nodes of the supports is made in the form of a bearing support, each vertical guide-ba The flap consists of at least two segments of a single-chamber main metal profile of the guide rail, each of which forms a corresponding span, sequentially interconnected using an interface unit containing interface means and fasteners and configured to compensate for deformations, each bracket being connected to the corresponding a segment of the main profile of the guide from the side of its side walls at the calculated point. The problem is solved due to the fact that the interface for each pair of adjacent segments of the main profile of the guide is made movable, at least in the direction of the longitudinal axis of the guide and as a means of coupling contains at least an additional docking metal profile, shape and dimensions of the transverse sections of which are selected in accordance with the shape and dimensions of the cross section of the camera of the main profile of the guide and with the possibility of installing the docking profile in the cavities of the chambers of two dnih segments basic profile of the guide on their end portions with a predetermined gap and to vary the position relative thereto of at least one segment of the basic profile of the guide, at least in the direction of the longitudinal axis of the main profile. At the same time, at least one vertical guide, together with the corresponding nodes of the supports, form a beam structure according to a multi-span bending-continuous-cut scheme with momentary longitudinally movable mating nodes, in which the mating nodes are made at points at which the bending moment is M = 0. The extreme lower node of the support is made in

- 4 024011 in the form of the above-described claimed node of a longitudinally movable articulated support. The extreme upper and located between the extreme lower and extreme upper nodes of the supports are made in the form of nodes of the bearing hinged supports, the design of which is also described above. The extreme lower and upper upper spans are made in the form of segments of the main profile of the guide, the length of the cross-section of the chamber of which is greater than the length of the transverse section of the chamber of the main profile of the guide, from which the ordinary spans located between the extreme lower and extreme upper are made. The lowermost span is made in the form of a single-span double-beam with a console and an extreme lower longitudinally movable articulated support. The extreme upper span is made in the form of a beam, at the upper point having a hinge connection with a fixed bearing support (bearing hinge bearing), and at the lower point, a momentary longitudinally movable joint with the console of the ordinary span, and the ordinary spans are made in the form of beams having one bearing hinge a support associated with the base, and as a second support, a momentary longitudinally movable joint with a console located below the ordinary beam.

As already mentioned above, taking into account the original shape of the main profile of the guide, the execution form of the interface is selected from the group including a momentary longitudinally movable joint with a minimum clearance in the interface and a hinged longitudinally movable joint with a limited mutual rotation angle of the mating sections.

A momentary longitudinally movable joint connects two elements in such a way that the connection is capable of perceiving a bending moment, a transverse force, but does not interfere with the longitudinal movement of the elements relative to each other. Structurally, such a joint is most simply performed as a pipe in a pipe with some clearance. With this in mind, and also taking into account the greatest efficiency from the point of view of economical cross-section and the convenience of organizing mates, a single-chamber (tubular) profile was chosen for the vertical guide. Compounds of this type are widely used in wireframe systems (substructures) of translucent fencing, in some NVF systems, however, nowhere have such joints been considered for creating bending-continuous structures with appropriate calculations and measures to ensure the reliability of such schemes. Such decisions of the interface nodes in the calculations are made as hinged and are located close to the nodes of the supports or combined with them.

If in schemes b) of the first or second type, the articulated joints of the elements with each other are replaced by momentary longitudinally movable joints, then a system is obtained that gives the advantages of continuous beams with the possibility of compensating for temperature and sedimentary longitudinal deformations. In this case, the following problems must be solved:

the momentary longitudinally movable joint should have a minimum clearance that is quite easily achievable in practice;

it is necessary to ensure longitudinal mobility in the joint at some insignificant moment in the joint (in the case of deviation of the load from uniformly distributed) without significant longitudinal forces in the profile from temperature deformations (polymer inserts can be used for this);

the system should have the reliability of separate single-span simple beams in relation to the propagation of the destruction of spans along the chain of mates.

The need to create a minimum gap is explained by the fact that the gap gives a certain degree of articulation at the moment joint, and in this case the reliability of the circuit created by the analogue of the first type b) circuit decreases, since when one of the spans is destroyed, the system becomes geometrically variable within the angle turning in a real joint. So, with a gap of 1 mm and an additional docking profile length of approximately 300 mm, free deflection, i.e., deflection without load will be approximately 7-10 mm. In the case of dynamic wind load, there is a possibility of further destruction of the entire chain from the swinging structure.

In the inventive frame system of an illegal armed formation, various possibilities are provided for organizing connections between a segment of the main guide profile and an arm of the corresponding support assembly.

So, in a number of embodiments of the inventive NVF frame system, a segment of the main guide profile can be connected to the bracket by means of a sleeve pivotally fastened to the bracket with respect to the bracket. At the same time, the sleeve, in turn, is connected with a segment of the main profile of the guide with the possibility of a limited change in its angular position relative to the bracket, while the support assembly is made in the form of a support hinge support assembly. The fastener may be made in the form of a main bearing bolt with a nut and at least a gear washer. Moreover, the main bearing bolt connects the opposite walls of the U-shaped bracket through the cavity of the sleeve, installed, in turn, in the corresponding holes made on the opposite side walls of the corresponding section of the main profile of the guide.

In other embodiments of the inventive NVF frame system, a section of the main guide profile can be connected to the bracket by means of a slide pivotally fastened to the bracket with respect to the bracket. The slide is preferably made in the form of a segment of a single-chamber metal profile and is connected, in turn, with a segment of the main profile of the guide with the possibility of changing its position relative to the slide in the direction of the longitudinal axis

- 5 024011 by means of a fixing longitudinal groove provided on the sled. This form of communication is suitable in the case of the execution of the node support in the form of a node of a longitudinally movable support. The fastener in this case is preferably made in the form of a bolt with a nut and at least a toothed washer. Moreover, the corresponding opposite walls of the slide are provided with openings forming together a through hole, the axis of which is perpendicular to the longitudinal axis of the section of the main guide profile, and in which the sleeve is installed through the cavity which installed the bolt.

Taking into account the embodiment of the inventive frame system as a whole, the shape and dimensions of the cross section of the camera of the main profile of the guide for two adjacent sections of the main profile of the guide can either coincide (the interface contains an additional docking profile), or the cross sections of the camera of the main profile of the guide of two adjacent segments of the main guide profiles have different lengths. In the second implementation form, the interface node contains an additional docking profile installed in the chambers of the chambers of both adjacent sections of the main guide profile, and an additional insert made in the form of a single-chamber metal profile, the shape and dimensions of the cross section of which are selected with the possibility of installing the insert in the chamber cavity of the main profile section a guide with a longer cross-sectional length parallel to the additional docking profile.

In order to reduce the nomenclature and the number of sizes of structural elements included in the set of the inventive NVF frame system, a slide can be used as an additional insert.

The additional docking profile used at all junctions of the segments of the main profile of the vertical rail on at least one side of its outer surface corresponding to the width of the cross-section of the chamber of the main rail profile can be equipped with a pair of L-shaped protrusions directed towards each other, forming a fixing groove of the additional docking profile. Symmetrical L-shaped protrusions located on the opposite side of the outer surface of the additional docking profile, as a rule, are used to place and fix anti-friction inserts.

Thus, at least one anti-friction insert made of plastic is preferably installed in the gap between at least one chamber wall of a section of the main guide profile corresponding to the cross-sectional width of the chamber and the corresponding wall of the additional docking profile, preferably with fixation with respect to the additional docking profile (for example, by means of self-tapping screws in addition to fixing by means of L-shaped protrusions). Anti-friction inserts prevent the free, spontaneous sliding of the additional docking profile in the cavities of the segments of the main profile of the vertical guides.

In the framework of the present invention, for the possibility of implementing various, optimal (from the point of view of achieving the technical results defined above) schemes for constructing the inventive NVF frame system, the author has also developed variants of the original construction support nodes.

Thus, the task is also solved by the claimed node of the bearing of the articulated support of the inventive frame system, including at least a U-shaped bracket and mounting means with respect to the bracket of the single-chamber main profile of the vertical guide. The problem is solved due to the fact that the bracket is made in the form of a bearing anchor support, the base of which extends beyond the side walls with the formation of opposite supporting platforms, made with the possibility of fixed fastening through plastic thermal breaks in relation to the overlap of the building in the areas of the supporting platforms at least two horizontally opposite points. Each of the walls of the bracket contains at least one horizontally elongated hole for the fastener, forming together with the corresponding hole of the opposite wall a through hole, the axis of which is perpendicular to the longitudinal axis of the guide. At least in the zone of location of the hole for the fastener, the outer surface of the walls of the bracket is made with vertical corrugation. The fastening means with respect to the bracket of the main profile of the vertical guide include at least one main bearing bolt with a nut and at least a toothed washer and at least one metal sleeve made with the possibility of placing the guide in the corresponding through hole with the subsequent installation through plastic thermal breaks between the inner surfaces of the opposite walls of the bracket and fixation by installing the main bearing bolt in the through hole of the walls of the bracket yna with a pass through the cavity of the sleeve.

In preferred forms of implementation, each of the walls of the bracket may contain two horizontally elongated holes located one below the other for two corresponding fasteners. Moreover, each fastener is made in the form of a main bearing bolt with a nut and at least a gear washer, while the assembly contains two bushings.

The problem is also solved by the claimed node of the longitudinally movable hinge support of the inventive NVF frame system, including at least a U-shaped bracket and fastening means with respect to the single-chamber main profile bracket of the vertical guide rail 6,024,011. The problem is solved due to the fact that the bracket is made in the form of a bearing anchor support, the base of which extends beyond the side walls with the formation of opposite supporting platforms, made with the possibility of fixed fastening through plastic thermal breaks in relation to the overlap of the building in the areas of the supporting platforms at least two horizontally opposite points. Moreover, each of the walls contains at least one horizontally elongated hole for the fastener, forming, together with the corresponding hole of the opposite wall, a through hole, the axis of which is perpendicular to the longitudinal axis of the guide. At least in the zone of location of the hole for the fastener, the outer surface of the walls is made with vertical corrugation. The fastening means with respect to the bracket of the main profile of the vertical guide include a main bearing bolt with a nut and at least a gear washer, a slide made in the form of a segment of a single-chamber metal profile, in the opposite walls of which are facing the walls of the bracket, a hole is formed, forming together with a corresponding hole of the opposite wall, a through hole, the axis of which is perpendicular to the longitudinal axis of the guide, and at least one metal sleeve made with the possibility of placement in the corresponding through holes of the slide with subsequent installation through plastic thermal breaks between the inner surfaces of the opposite walls of the bracket and fixing by installing the main bearing bolt in the through hole of the walls of the bracket with a pass through the cavity of the sleeve. The slide on the surface of the wall facing the rail is provided with longitudinal curly protrusions forming engagement elements configured to reciprocate linearly in the reciprocal longitudinal grooves of the rail in the direction of the longitudinal axis of the rail. In the proposed, described above, versions of the support nodes, it is possible to compensate for multidirectional forces (stresses) that may occur in the communication zone of the support node and the vertical guide, without the risk of creating prerequisites for destruction.

The proposed design options for the support nodes in conjunction with the original solution of the interface unit of the segments of the main profile of the guide allow you to implement various schemes for constructing the inventive frame system.

In particular, within the framework of the present invention, in the frame constructions of an illegal armed formation, the aforementioned bending-continuous-cut scheme can be used, a multi-span bending-continuous-cut scheme with moment longitudinally movable joints in each span (derivative from scheme b) of the first type). This scheme can also be implemented with dividing spans, which is the subject of a separate application for the invention.

In this scheme, the torque joints are located at a distance of 0.211 b from the support node (where b is the distance between the supports) in the zone of zero moments in the case of uniform loading of spans. The circuit is a circuit of maximum rigidity.

Such a scheme is most convenient in terms of installation, contains the same profile sections of the main vertical guide (spans), the length of which is equal to the height of the floor. The joints are located at the points of zero moments. Compared with a single-span scheme, it has 5 times greater rigidity and one and a half times greater strength. The very first span from the bottom of the rail is made as a single-span two-support beam with a console. A profile of a larger cross section is used for it, since in this case there is no unloading effect of an adjacent span on one side. The increased strength of the first guide (first span) also serves the purpose of safety of the structure as a whole, since with the destruction of the double-beam, the remaining chain of beams becomes limited instantly changeable (to the extent that the moment joint has a hinge).

In addition, in case of accidental destruction of the underlying span, the remaining part of the beam, acting as a console with a large overhang, destroys the joint of the overlying span, thus forming the next console and the destruction is transmitted upward along the chain. In the case when the overlying span of the chain is destroyed, then the destruction is not transferred down if the ratio of strengths in the joint zone and the beam section at the fulcrum is such that the joint is first destroyed, excluding the transmission of the effect to the underlying span. The remaining console of the 0.211 b span does not cause destruction on the support, since the moment created by the console MK = 0.5 c (0.211 b) ² = 0.022 cb ² (where s.] Is the horizontal (wind) load) is less than the value of the reference moment equal to 0,083 cb ² , on which the beam section is selected. The wind load increases with height, and this circumstance causes a greater likelihood of destruction of the upper fragments of the structure, which, as mentioned above, eliminates the transfer of destruction along the chain down. In the absence of an adjacent span in the event of its destruction, the reference moment on the second support increases to a value of 0.106 cm ² , which exceeds the value of the calculated moment on an ordinary support of 0.083 s | k. The ratio is 1.28, which is less than the safety factor for a wind load of 1.4 . Considering that accidental destruction is unlikely, it is possible to take a value of 0.083 cb ² for the calculation. For even greater reliability, we can calculate the emergency value of the moment 0.106 cb ² . It is also additionally recommended to use the design of the support unit, in which the destruction occurs in a predetermined section at the level of the upper bolt, and after that the lower bolt is turned on, holding the guide, (unit 1c), while the destructive effect is not transmitted further.

- 7,024,011

For additional reliability of this scheme, it is recommended to introduce through a certain number of continuous spans (about 10-12) a split (dividing) span that blocks the transmission of influences.

The functionally described scheme is most acceptable when facing with granite tiles and natural stone, when, according to the conditions of vertical loads on the bracket and the requirements of minimum temperature changes in tile gaps, the length of the guide is limited to one span.

In the inventive frame system of an illegal armed formation of a multi-storey building constructed in accordance with the above scheme, the interface unit of a section of a main profile of a guide of an extreme lower and an upper upper span and a segment of a main profile of a guide of a corresponding adjacent span preferably contains an additional docking profile installed in the chamber cavities of both said adjacent segments the main profile of the guide, and an additional insert made in the form of a single-chamber metal profile, f yoke and cross-sectional dimensions of which are selected with the possibility of insertion in the cavity of the camera main profile segment guide lowermost or uppermost span parallel optional docking profile.

The above and other advantages and advantages of the claimed invention will be discussed below in more detail on some preferred, but not limiting examples of implementation and with reference to the positions in the drawings, in which are schematically represented:

in FIG. 1 - diagrams of the implementation of the connections guide - beam - support node - overlap of the building in the frame systems of illegal armed groups of a multi-storey building;

in FIG. 2 - multi-span bending-continuous circuit with momentary longitudinally movable joints in one of the forms of implementation;

in FIG. 3 is a detail general view of a node of a bearing articulated support and a moment longitudinally movable joint;

in FIG. 4 is a General view of the node of the bearing articulated support and moment longitudinal-movable joint assembly;

in FIG. 5 is a plan view of a momentary longitudinally movable joint; in FIG. 6 is a section along line 6-6 of the moment longitudinally movable joint of FIG. 5; in FIG. 7 is a section along line 7-7 of the momentary longitudinally movable joint of FIG. 5; in FIG. 8 is a section along line 8-8 of the moment longitudinally movable joint of FIG. 5; in FIG. 9 is a side view of a fragment of a frame system and a support zone;

in FIG. 10 is a plan view of a momentary longitudinally movable joint of segments of a main profile of a vertical guide with different section sizes;

in FIG. 11 is a section along line 6-6 of the momentary longitudinally movable joint of FIG. 10; in FIG. 12 is a section along line 8-8 of the momentary longitudinally movable joint of FIG. 10; in FIG. 13 is a detail general view of a node of a bearing articulated support and a moment longitudinally movable joint (profile sections with different sections);

in FIG. 14 is a general view of the bearing assembly of the articulated support and the momentary longitudinally movable joint assembly (profile sections with different sections);

in FIG. 15 is a detail view of a longitudinally movable articulated support assembly; in FIG. 16 is a general view of the longitudinally movable hinge support assembly of FIG. 15 assembly.

In FIG. Figure 1 presents the traditionally used schemes a), b), c) of the implementation of the guide-beam connections - the support node - the overlap of the building in the IWF frame systems of a multi-story building, which were discussed above in sufficient detail when describing the prior art.

In FIG. 2 shows a multi-span bending-continuous structure with momentary longitudinally moving joints of the IWF frame system according to the invention. The frame system of an illegal armed formation of a multi-storey building, in the general case, consists of many vertical guides-beams made in the form of segments of a single-chamber main metal profile of the guide, each of which forms a corresponding span 1, connected in series with each other using a pair of mates. Guide rails (spans 1) are installed with a certain step and with a gap of 3 (see Fig. 12) with respect to the plane of the ends of the floors 4 of the building (see Fig. 12) and are fixed with respect to the floors 4 of the building at specified points with corresponding nodes of the supports (bearing articulated bearings 5 and longitudinally movable articulated bearings 6). The design of the nodes of the supports 5, 6, nodes 2 mates and guide rails (spans 1) will be discussed in more detail below. In accordance with the circuit of FIG. 2, a vertical guide, consisting of many spans 1, together with the corresponding nodes of the supports 5, 6 form a beam structure according to a multi-span bending-continuous structure with momentary longitudinally movable nodes 2, in which the nodes are made at points in which the bending moment M = 0 (illustrated by dashed lines connecting the corresponding diagram of bending moments located to the left of the diagram and the point on the rail at which the interface nodes 2 are made). The extreme lower node of the support is made in the form of a node of a longitudinally movable hinged support 6. The extreme upper and located between

- 8 024011 extreme lower and extreme upper nodes of the supports are made in the form of nodes of the bearing hinged supports 5.

The extreme lower 7 and the upper upper 8 spans are made in the form of segments of the main profile of the guide, the cross-section of the chamber of which is larger than the cross-section of the chamber of the main profile of the guide, from which the row spans located between the extreme lower 7 and the upper upper 8 are made. 1. Momentary longitudinally movable joints - mating nodes 9 (10) - for guides with different cross-sectional sizes will be discussed below in more detail with reference to the positions of FIG. 13-16. The lowermost span 7 is made in the form of a single-span two-support beam with a console and the extreme lower longitudinally movable hinge support 6. The upper upper span 8 is made in the form of a beam at the upper point associated with the ceiling 4 of the building by means of the bearing hinge support 5, and at the lower point by moment longitudinal-movable joint (node 10 interface) with the console located below the ordinary beam (ordinary span 1). Ordinary spans 1 are made in the form of beams having one bearing hinged support 5 connected with the overlapping 4 of the building, and as a second support, a momentary longitudinally movable joint (interface unit 2) with the console located below the ordinary beam (ordinary span 1).

In FIG. 3 is a schematic overview of a detail view, and FIG. 4 in the assembly of the assembly of the bearing hinged support 6 and the interface assembly 2 in the form of a momentary longitudinally movable joint (corresponds to the local view, designated as 1c in Fig. 2). The assembly of the hinged support 6 includes a bracket 23 of a U-shape, made in the form of a supporting anchor support, the base 24 of which extends beyond the side walls 25 with the formation of opposite supporting platforms 26. The bracket 23 is made with the possibility of fixed fastening by means of fasteners 27 through plastic thermal breaks 28 with respect to the overlap of 4 buildings in the areas of the supporting platforms 26 in this form of implementation at four points opposite in the horizontal direction. Each of the walls 25 contains in this implementation form two horizontally elongated holes 29 for the fastener, each of which together with the corresponding hole 29 of the opposite wall 25 forms a through hole, the axis 30 of which is perpendicular to the longitudinal axis 31 of the guide 32. In the area of the holes 29 for the fastener detail the outer surface of the walls 25 is made with vertical corrugation 33. The fastening means with respect to the bracket 23 of the main profile of the vertical guide 32 is made in the form of a main carrier th bolt 34 with a nut 35, gear 36 and ordinary 37 washers, as well as a metal sleeve 38. The sleeve 38 is made with the possibility of placing in the through hole 39 of the guide 32 with subsequent installation through plastic breaks 40 between the inner surfaces of the opposite walls 25 of the bracket 23 and with fixing by installing the main bearing bolt 34 in the through hole 29 of the walls 25 of the bracket 23 with a pass through the cavity of the sleeve 38. In this form of implementation, an additional (emergency) is also provided as part of the fastening means a bolt 41 with a nut 35 and washers 36, which are installed in the lower horizontally elongated holes 29 of the walls 25 through the corresponding through hole 42 in the guide 32.

In FIG. 3 and 4, an interface unit 2 is also presented in the form of a momentary longitudinally movable joint, including an additional docking profile 43, the shape and dimensions of the cross section of which are selected in accordance with the shape and dimensions of the cross section of the camera of the main profile of the guide 32 and with the possibility of installing the docking profile 43 in the cavity of the chambers of two adjacent segments of the main profile of the guide 32 at their end sections with a given gap and with the possibility of changing relative to it the position of at least one segment of a new profile of the guide 32 (in the presented form of the implementation of the upper segment of the main profile of the guide 32), at least in the direction of the longitudinal axis 31 of the main profile of the guide 32. In the presented form of the implementation, the connecting profile 43 on each of the opposite sides of its outer surface corresponding to the width of the transverse a section of the main profile chamber of the guide 32, is provided with a pair of L-shaped protrusions 44 directed towards each other, forming a fixing groove 45 of the additional docking profile la 43. In addition, in the gap between the walls of the chamber of the segment of the main profile of the guide 32, corresponding to the width of the cross section of the chamber, and the corresponding walls of the additional docking profile 43, eight (four for each end section) anti-friction inserts 46 made of plastic. In this embodiment, the position of the anti-friction inserts 46 with respect to the additional docking profile 43 is additionally fixed by placing the inserts in the fixing groove 45, as well as by means of fasteners 47 (for example, self-tapping screws).

The position of the additional docking profile 43 with respect to the lower segment of the main profile of the guide 32 is also fixed by means of corresponding fasteners 48 (for example, self-tapping screws). In relation to the upper segment of the main profile of the guide 32, an additional docking profile 43 is installed with the possibility of changing its position relative to it in the direction of the longitudinal axis 31 of the main profile of the guide 32.

The interface unit 2 (momentary longitudinally movable joint) is also considered in more detail in FIG. 5-8, which respectively show a plan view, as well as sections along lines 6-6, 7-7, 8-8.

- 9,024,011

In FIG. 9 is a schematic side view of a fragment of a frame system in a support zone.

In FIG. 10-12 are examined in detail, respectively, in plan view and in sections along line 6-6 and along line 8-8, interface unit 9 (momentary longitudinally movable joint) of segments 49, 50 of the main profile of the vertical guide 32 with different cross-sectional sizes . Moreover, the cross-section of the additional docking profile 43, both in shape and size, corresponds to the cross-section of the chamber of the section 49 of the main profile of the guide 32, and to bring the cross-sectional size of the additional docking profile 43 into account the size of the section of the camera of the section 50 of the main profile in the corresponding section of the additional docking profile 43 to an additional insert is attached to it, in this form of implementation made in the form of a slide 51, which are fixed in the groove 45 and fixed on the corresponding wall nogo connection profile 43 by means of fasteners 52 (e.g. screws). For fixation in the groove 45, the slide 51 is provided with a pair of L-shaped protrusions 53 directed in the opposite direction, the shape, dimensions and arrangement of which are selected so that the protrusions are mating elements of the locking connection with the groove 45. This implementation form is discussed in more detail in the following drawings.

So in FIG. 13 is a schematic overview of a detail view, and FIG. 14 in assembly of the assembly of the bearing hinged support 6 and the interface assembly 9 in the form of a momentary longitudinally movable joint of segments 49 and 50 of the main profile of the rail with different section sizes (corresponds to the local view, designated as 3 in Fig. 2). In this embodiment, the construction of the articulated support assembly 6 is similar to the construction discussed above with reference to FIG. 3-8, except that there are two main load-bearing bolts 34, each with a gear washer 36, two metal bushings 38 and, respectively, two through holes 39 in the guide 32 (on a section 50 with large cross-sectional dimensions).

In addition, in FIG. 13 and 14, a coupling assembly 9 of segments 49 and 50 of the main guide profile of the guide 32, which have different cross-sectional sizes, is also presented in more detail. As already mentioned above, the cross-section of the additional docking profile 43 is selected both in shape and size in accordance with the cross-section of the chamber of the section 49 of the main profile of the guide 32. In this case, for the possibility of installing an additional docking profile 43 in the camera of the section 50 of the main profile in the corresponding section to a slide 51 is attached to it.

The position of the additional docking profile 43 with respect to the lower segment 50 (with large cross-sectional dimensions) of the main profile of the guide 32 with the slides 51 is fixed by means of corresponding fasteners 48 (for example, self-tapping screws). With respect to the upper segment 49 (with smaller cross-sectional dimensions) of the main profile of the guide 32, an additional docking profile 43 is mounted with the possibility of changing its position relative to it in the direction of the longitudinal axis 31 of the main profile of the guide 32.

In FIG. 15 is a schematic overview of a detail view, and FIG. 16 is a complete assembly view of a longitudinally movable articulated support 5 (corresponding to a local view designated as 1c in FIG. 2). The node of the longitudinally movable hinge support 5 includes a bracket 54, made in the form of a bearing anchor support, the base 55 of which extends beyond the side walls 56 with the formation of opposite supporting platforms 57, made with the possibility of fixed fastening through plastic thermal breaks 58 in relation to the overlap 4 of the building in areas of the reference areas 57 for the presented form of implementation at two opposite horizontal points. Each side wall 56 contains in this embodiment, one horizontally elongated hole 59 for the fastener 60, which forms, together with the corresponding hole 59 of the opposite wall 56, a through hole, the axis 61 of which is perpendicular to the longitudinal axis 31 of the guide 32. In the area of the hole 59 for the fastener 60 the outer surface of the walls 56 is made with vertical corrugation 62. The fastening means with respect to the bracket 54 of the main profile of the vertical guide 32 include a fastener - the main the existing bolt 60 with a nut (not shown in FIGS. 15 and 16 and not indicated), a toothed washer 63 and ordinary washers, an additional fastener 64 (for example, a self-tapping screw), a slide 51 and a metal sleeve 65. As already described above, the slide 51 is made in the form of a segment of a single-chamber metal profile, in the opposite walls of which, facing the walls 56 of the bracket 54, a hole 66 is made, forming, together with the corresponding hole of the opposite wall, a through hole, the axis 67 of which is perpendicular to the longitudinal axis 31 n ruling 32. The metal sleeve 65 is arranged to accommodate a slide in the respective through holes 66 with subsequent installation through the plastic thermal breaks 68 between the inner surfaces of the opposite walls 56 of the bracket 54 and fixing by installing the main bearing bolt 60 in the through hole 59 of the walls 56 of the bracket 54 with a passage through sleeve cavity 65. The slide 51 on the surface of the wall facing the guide 32 is provided with longitudinal figured protrusions 69 forming the locking elements of the engagement Nia. In this embodiment, the figured protrusions are made in the form of a pair of longitudinal G-shaped protrusions directed in the opposite direction, the shape, dimensions and arrangement of which are selected with the possibility of their reciprocating linear displacement in the reciprocal longitudinal grooves 70 of the guide 32 in the direction of 10,024,011 of the longitudinal axis 31 of the guide 32.

The advantages and advantages of the inventive frame system of illegal armed groups, as well as of the individual claimed elements of the system (nodes of supports and the interface node) will also be illustrated in the following description of the functioning of both the inventive frame system as a whole and its individual nodes.

As already mentioned above, the vertical guides (beams) are made according to a multi-span bending-continuous structure with momentary longitudinally movable joints in each span (Fig. 2).

In this scheme, the vertical guide 32 contains the same profile sections of the main vertical guide 32 - ordinary spans 1, the length of which is equal to the height of the floor. Joints - nodes 2 mates of ordinary spans 1 are located at the points of zero moments. The lowermost span 7 of the guide is made in the form of a single-span two-support beam with a console. Its lower end is connected to the node of the longitudinally movable hinge support 6 (see Fig. 13-14), and in the upper zone, to the node of the bearing hinge support 5 (see Fig. 15-16). For the lowermost span 7, a larger section profile is used, since in this case, on the one hand, there is no unloading effect of the adjacent span. The increased strength of the first (lowermost) span 7 also serves the purpose of safety of the structure as a whole, since with the destruction of the double-beam (extreme lower span 7), the remaining chain of beams (ordinary spans 1) becomes limited instantly variable (to the extent that the momentary the joint - node 2 interface - has a hinge). The increased strength of the lower lower span 7 is achieved, in particular, due to the increased cross-sectional size of the chamber of the section 50 of the main profile of the guide 32, in which, in addition to the additional docking profile 43, an additional insert in the form of a slide 51 is also installed, with the additional docking profile 43 and the slide 51 between themselves by means of fasteners 52, and an additional docking profile 43 is also connected with a section 50 of the main profile of the guide 32 by means of fasteners 48. A fragment in the vertical guide beam in the area of the interface unit 2 of the lower lower span 7 and the next ordinary span 1 following it is presented in more detail in a local view, designated as 3, in FIG. 10-14. This node 2 interfaces, as well as located above the nodes 2 interface is located at the point of zero moment. The bending strength over section 7-7 in FIG. 10 (the bending strength of the additional docking profile 43) is approximately half the strength of the guide along the section 4-4, which excludes the possibility of transmission of the damaging effect to the drill node 2 interface. The interface unit 2 also provides the ability to change the position of the segment 49 of the main profile of the guide 32 in the direction of the longitudinal axis 31 of the guide 32 relative to the additional connecting profile 43 and, therefore, relative to the segment 50 of the main profile of the guide 32. This possibility is provided due to the fact that the additional connecting profile 43 installed in the chamber of section 49 of the main profile of the guide 32 without any fastening (without fixing the position) and connected to the surface of the chamber of section 49 through antifree ktsionnye insert 46, fixed on the additional docking profile 43 in the locking groove 45 and by fasteners 47. Initially interface assembly 2 is mounted in such a way that between the segments 49 and 50 of the basic profile of the guide 32 is formed constructive minimum necessary clearance. Taking into account the above-described features of installing an additional docking profile 43 in the chamber of the segment 40 of the main profile of the guide 32, it is also possible to change to the desired angle of rotation of the mating segments 49, 50 of the main profile of the guide under the action of bending loads without destroying the structure. Similarly, the nodes 2 of the pair of segments of the main profile of the guide 32, having the same cross-sectional dimensions, of which the ordinary span are made, are made. in FIG. 3-9. Here, the bending strength along section 7-7 of FIG. 5 (the bending strength of the additional docking profile 43) is approximately half the strength of the guide 32 along the section 4-4, which eliminates the possibility of transmission of destructive effects from above the interface unit 2. In the case of both of the above forms of implementation of the nodes 2 interface, when the overlying ordinary span 1 is destroyed, the destruction is not transmitted down, because the strength ratio of structural elements in the area of the interface unit 2 and the guide section 32 at the point of the support unit 5 is such that at first the interface unit 2 (additional docking profile 43) is destroyed, excluding the transmission of the effect to the underlying span 1 (6). The calculation of the permissible moments and lengths of the span consoles was briefly considered in the above description.

This result is also achieved by choosing the design of the support assembly, to which the guide 32 is connected, in particular the assembly of the support hinged support 5, in which the destruction of the guide takes place in its predetermined section at the level of the upper (main bearing) bolt 34, and then to work the lower (additional emergency) bolt 41 is turned on, holding the guide 32, while the destructive effect is not transmitted further down. So, for the node of the bearing hinged support 5 (Fig. 3-9), in the area of which the reference bending moment is maximum, the destruction of the guide 32 is more likely in section 4-4 than in section 5-5, because the diameter of the through hole 39 in section 4-4 is larger than the diameter of the through hole in section 5-5. Cross section 4-4 is also perceived and transverse

- 11 024011 force (section 5-5 is not), because in the area of this section, a gear washer 36 is located. Thus, with a more probable destruction of the guide 32 along the section 4-4, the guide 32 will remain fixed by an additional emergency bolt 41 with a nut 35 and washers 37 to the vertical load, as well as to the horizontal load within the horizontal elongated holes 29 in the walls 23 of the bracket 23.

Calculations and tests showed that the inventive NVF frame system in comparison with the single-span scheme (scheme a) of FIG. 1) has 5 times greater rigidity and one and a half times greater strength.

The claimed NVF frame system considered above is most suitable for facing with ceramic granite slabs and natural stone, when, according to the conditions of vertical loads on the bracket and the requirements of minimum temperature changes in tile gaps, the length of the guide is limited to one span.

From the above description it follows that the design of the frame system of an illegal armed formation of a multistory building, as well as the design of various options for the support and interface units provide higher strength and higher rigidity of the frame system, and in case of emergency prevent significant damage to the frame system, localizing them, essentially only in the area of one ordinary passage. Due to this, the inventive NVF frame system of a multi-storey building has higher reliability and durability even with significant loads (vertical from facing elements and horizontal from wind). Localization of destruction allows the system to be repaired without dismantling the part of the frame system that has remained operational and the facing elements installed on it, which significantly reduces the cost and time of repair work. A specialist in this field of technology, on the basis of the above-described forms of implementation of the inventive frame system, can, using standard calculations in the methods, develop a frame system of an illegal armed formation of a multi-storey building in each case, practically without limiting the bearing capacity of the frame system (weight and dimensions of cladding elements), building height, total areas of illegal armed groups, etc.

Information sources

1. Patent KI No. 80177 I1, publ. January 27, 2009

2. Hinged facades on the frame - The Best Facades Magazine, No. 23 (fall) 2009 [Electronic resource] - June 13, 2011. - Access mode: Yyr: //-№№№.pauek.gi/tyeh.rby = 5syop8 & 1Y = 215 & rad_sht =

3. Substructure GTS 35 for mounting ventilated facades. Website LLC Modern facades. [Electronic resource] - June 13, 2011. - Access mode: yyr: //№№№.ее1уейса5кги/са55ейе5у51ет/1п1о/119.Тт1

4. Patent EA No. 012653 B1, publ. 12/30/2009.

5. Website of the construction company LLC SK Megastroy. [Electronic resource] - June 20, 2011. - Access mode: Yyr: //№№№.Teda51go-1gk.gi/rade.ryr? 1Y = 49

6. Patent KI No. 2381341 C1 of 02/10/2010.

7. RusExp system for ventilated facades. Site of the company Bastion. [Electronic resource] - June 20, 2011. - Access mode: Yyr: //№№№.goua151ope.gi/rada/gi5ekhr_kd

8. Granovsky A.V., Kiselev D.A. Modern ventilated facade systems: problems and solutions. Roofing magazine, Facades. Insulation, No. 3/2007, pp. 44-46.

9. Website of the company Yukon Engineering. Systems of ventilated facades I-cop. [Electronic resource] - September 23, 2011. - Access mode: yyr: //№№№.-cop.gi/gi/goi/113/7143/7372

10. Album of technical solutions. The system of ventilated facades SIAL with hidden fastening of natural stone. SIAL P-Nk, first edition, Krasnoyarsk, 2008, p. 5-7, 18.

11. Tereshkova A.V. The study of deformability and improvement of structural solutions of the elements of the frame of facade systems with a ventilated air gap. Abstract for the degree of Ph.D. Scientific and innovative portal of the Siberian Federal University [Electronic resource] - September 23, 2011.- Access mode: 1Wr: // \ y \ y \ u.ge5eag1g5Gi-kga5.gi

Claims (7)

1. The frame system of the hinged ventilated facade of a multi-storey building, consisting of many vertical guides-beams installed with a certain step and with a gap with respect to the plane of the ends of the floors of the building and fixed with respect to the floors of the building at specified points using the respective support nodes, each of which contains at least a U-shaped bracket and at least one of the nodes of the supports is made in the form of a bearing support, and each vertical guide-beam consists of at least of two segments of a single-chamber main metal profile of the guide, each of which forms a corresponding span, sequentially connected to each other of these segments of the main metal profile using the interface node containing the coupling means and fasteners, and configured to compensate for deformations, with each bracket connected to corresponding to the corresponding section of the main profile of the guide from the side of its side walls at the design point, characterized in that the node is mated for each pair of adjacent segments of the main profile of the guide made movable, at least in the direction of the longitudinal axis of the guide, while as a means of coupling contains at least an additional docking metal profile, the shape and dimensions of the cross section of which are selected in accordance with the shape and the dimensions of the cross section of the chamber of the main profile of the guide and with the possibility of installing the docking profile in the cavities of the chambers of two adjacent segments of the main profile of the guide on their end sections with a given gap between the connecting profile and the segments of the main profile to change the position relative to the connecting profile of at least one segment of the main profile of the guide, at least in the direction of the longitudinal axis of the main profile, with at least one vertical guide together with its corresponding the nodes of the supports forms a beam structure according to a multi-span bending-continuous profile with momentary longitudinally movable interface units, in which the interface units are filled at points at which the bending moment is M = 0, the extreme lower node of the support is made in the form of a node of a longitudinally movable articulated support, and the extreme upper and located between the extreme lower and extreme upper nodes of the supports are made in the form of nodes of bearing articulated supports, while the extreme lower and the extreme upper spans are made in the form of segments of the main profile of the guide, and the extreme lower span is made in the form of a single-span two-support beam with a console and an extreme lower longitudinally movable hinge support, the extreme upper span is made nen in the form of a beam, at the upper point having a hinge connection with a fixed bearing support, and at the lower point, a momentary longitudinally movable joint with the console of the ordinary span, and the ordinary spans are made in the form of beams having one bearing hinged support associated with the base of the building floor, and as a second support - a momentary longitudinally movable joint with a console located below the ordinary beam. 2. The system according to claim 1, characterized in that the node of the supporting articulated support includes at least a U-shaped bracket and mounting means with respect to the bracket of the single-chamber main profile of the vertical guide, the bracket being made in the form of a supporting anchor support, base which extends beyond the side walls with the formation of opposite supporting platforms, made with the possibility of fixed fastening through plastic thermal breaks in relation to the overlap of the building in the areas of the supporting platforms at least e at two points opposite in the horizontal direction, each wall containing at least one horizontally elongated hole for fixing the main profile to the bracket, forming, together with the corresponding hole of the opposite wall, a through hole, the axis of which is perpendicular to the longitudinal axis of the guide, and at least in the area of the hole for the indicated means of attachment, the outer surface of the walls is made with vertical corrugation, and the means of attachment to the bracket The main profile of the vertical guide includes at least one main bearing bolt with nut and toothed washer and at least one metal sleeve that can be placed in the corresponding through hole of the main profile of the vertical guide with subsequent installation through plastic thermal breaks between the inner surfaces of the opposite walls of the bracket for fixing the main profile of the vertical guide by installing the main bearing bolt in the through hole TIFA bracket wall through the sleeve cavity. 3. The system according to any one of claims 1 or 2, characterized in that the node of the longitudinally movable hinge support includes at least a U-shaped bracket and means of attachment to the bracket of the single-chamber main profile of the vertical guide, and the bracket is made in the form of a carrier anchor support, the base of which extends beyond the side walls with the formation of opposite supporting platforms, made with the possibility of fixed fastening through plastic thermal breaks in relation to the overlap of the building in the areas of the supporting areas to at least two points opposite in the horizontal direction, each wall containing at least one horizontally elongated hole for mounting the main profile to the bracket, forming together with the corresponding hole of the opposite wall a through hole, the axis of which is perpendicular to the longitudinal axis of the guide, and, at least in the area of the hole for the indicated means of fastening, the outer surface of the walls is made with vertical corrugation, and the means of cre Drinkings to the bracket of the main profile of the vertical guide include the main bearing bolt with nut and toothed washer, a slide made in the form of a segment of a single-chamber metal profile, in the opposite walls of which are facing the walls of the bracket, a hole is formed that forms a through hole with the corresponding hole of the opposite wall, the axis of which is perpendicular to the longitudinal axis of the guide, and at least one metal sleeve made with the possibility of placement in the corresponding their through holes of the sled with subsequent installation through plastic thermal breaks between the inner surfaces of the opposite walls of the bracket for fixing segments of the main profile of the vertical guide through the main bearing bolt in the through hole - 13,024,011 of the wall of the bracket with a pass through the cavity of the sleeve, and the slide on the surface of the wall facing the guide is provided with longitudinal curly protrusions forming engagement elements made with the possibility of their reciprocating linear movement in the reciprocal longitudinal grooves of the guide in the direction of the longitudinal axis of the guide. 4. The system according to any one of claims 1 to 3, characterized in that one segment of the main profile of the guide is connected to the bracket by means of a sleeve pivotally attached to the bracket of the guide, connected, in turn, to another segment of the main profile of the guide for a limited change in the angular the position of the specified segment of the main profile of the guide relative to the bracket. 5. The system according to any one of claims 1 to 3, characterized in that one segment of the main profile of the guide is connected to the bracket by means of a slide pivotally mounted to the bracket, made in the form of a segment of a single-chamber metal profile, connected, in turn, with another a segment of the main profile of the guide to change the position of the specified segment of the main profile of the guide relative to the slide in the direction of the longitudinal axis by means of a fixing longitudinal groove provided on the slide. 6. The system according to any one of claims 1 to 5, characterized in that the additional connecting profile on at least one side of its outer surface, corresponding to the width of the cross section of the chamber of the main profile of the guide, is provided with a pair of L-shaped protrusions directed towards each other, fixing groove of an additional docking profile. 7. The system according to any one of claims 1 to 6, characterized in that at least one anti-friction insert is installed in the gap between at least one chamber wall of a section of the main guide profile corresponding to the width of the cross-section of the chamber and the corresponding wall of the additional docking profile, made of plastic, preferably with fixation in relation to the additional docking profile.