RU2315839C1 - Method for building or building structure erection (variants) - Google Patents

Abstract

FIELD: construction, particularly methods for complex land building-up with buildings of different types.

SUBSTANCE: method involves constructing foundation; assembling at least part of lower floor structure; erecting at least one stiffening core; connecting building members with the stiffening core. At least some connections of building or building structure members have fastening members made as extension and socket, which are oriented in the line of force field or force field combination providing dominating forced in area of member to be installed location or in building to be erected zone. Said connections are formed during building erection.

EFFECT: simplified building erection of prefabricated members, increased spatial rigidity and building stability, possibility to use standard members, provision of different building types construction of limited number of standard members and simplified member transportation.

25 cl, 37 dwg

Description

The invention relates to construction and can be used in all sectors of the economy for the integrated development of populated areas with buildings and structures of various functional purposes.

A known method of construction of a collapsible building, structures, assembled from horizontal floor panels with couplings in the corners and vertical load-bearing elements equipped with spikes installed in the clutch of the floor panels (FR 2252462, ЕВВ 1/18, 06/20/1975). The disadvantages of this method are the complexity of the installation and the lack of rigidity and reliability of the joints.

A known method of erecting a collapsible structure, comprising a supporting frame with fixed couplings and spikes, a set of floor panels with couplings in the corners to accommodate the spikes of the frame and the fence panel with couplings and spikes for mounting on vertical frame elements (SU 1347525 E04B 1/343, 12.12 .1985)

The disadvantages of this method are the lack of unification of the elements and the lack of the possibility of interfacing with the buildings of the cell structure, which significantly complicates the installation of the building, structure.

The prior art also known a method of construction of a building, structure (SU 817166, E04B 1/343, 05.17.1979). A prefabricated collapsible building, the construction includes floor panels with couplings located at the corners and on the sides, vertical bearing and enclosing elements equipped with wedge-shaped spikes installed in the couplings.

The disadvantages of this method are the lack of unification of the building elements, the absence of collapsible stiffeners providing stability and rigidity of the supporting skeleton of the building, which limits the range of buildings being constructed.

The objective of the present invention is to simplify the installation of buildings and structures from elements of high factory readiness, increase the spatial stiffness and stability of buildings, structures, unification of constituent elements, provide the possibility of creating buildings and structures for various purposes from a limited range of elements and simplify their transportation.

The problem in part of the first variant of the method of construction of a building, construction, is solved due to the fact that the method includes the construction of a foundation or platform, installation of at least part of the lower floor and the construction of at least one core of rigidity, at least within the height of the erected floors and subsequent attachment to it with attachment at least two points of power, enclosing and / or combined, including with a hidden frame of mounted building elements, spaced apart within the length and / or height of the core, components that are attached to the core and / or attached to it with the formation of a rigid system of elements such as volumetric blocks and / or panels, and / or extended structures - struts, crossbars and / or struts, and at least part of the connections are made by a pair of fixing elements of the protrusion-socket type, with one of the components of such a connection, the protrusion and / or socket provide each mounted element, respectively, in at least one of the points spaced apart within the length, or height, or area of the mounted element, and forming e compound fasteners protrusion jack having a longitudinal axis coaxial or parallel to each other, oriented when mounting building constructions into the lines of force direction of the force field or combination of fields of force, creating a dominant force in the zone of placement of the mounted item or in the environment of the building construction, building.

A building, structure may be constructed at least partially on one-story, small or medium floors, or a building, structure may be constructed at least partially on a middle or raised floors.

The building can be constructed from various elements - volumetric blocks, wall panels, floor panels, frame elements, while at least one structural element of the building is made immediately before installation or during installation.

To connect the building elements, bolting, screw, nail, screw and rivet joints are used as fasteners.

In fasteners of the protrusion-socket type, the protrusion can be made in the form of a spike.

The connecting elements can be made split with a slot on the spike and / or socket, while the fasteners - spikes - are removable or installed before installation.

Spike-socket type connecting elements can be made with round or elongated holes so that after assembling the elements these holes are aligned and allow the spike and socket to be fixed to each other with an additional locking element in the form of a stud, screw or screw.

At least part of the spike and socket type fasteners can be made compatible with the cross section normal to their longitudinal axis, at least in the section normal to the longitudinal axis of the connection, while forming the inner surface of the socket oriented in the direction of the longitudinal axis of the connection , made in a straightforward, linear, broken, curved or composite configuration, at least on the part of the length of the spike-socket connection, with the formation of at least one conical, pyramidal, barrel-shaped silt and the prismatic portion of the nest, at least at part of the joint height.

Spike-socket type connectors or their block can be made with at least one hole with an axis parallel to the longitudinal axes of the fasteners, while at least one strained strand is predominantly aligned with it in the holes.

Strained cords of at least one joint can be placed outside the zone of the fastening elements of the spike socket.

The longitudinal axis of the fasteners of the protrusion-socket type joints can be oriented in the direction of the lines of force of the natural or artificial gravitational field or the resulting addition of the lines of force of the static gravitational and calculated aero- and / or hydrodynamic, including one-sided asymmetric effects, the linear dimensions of the elements are taken as multiple or fractionally multiple to a given module, and the distances between the centers of adjacent fasteners are made satisfying the above relation them with a given module, and at least part of the adjacent fasteners of one mounted structural element can be attached to one or to other mounted structural elements of the building, structure.

The problem in part of the second variant of the method is solved due to the fact that the method of construction of a building, structure includes the construction of a foundation, installation of at least part of the lower floor and the construction of at least one core of rigidity and the subsequent attachment of mounted elements of the building, structure, and at least a part of the connections of the building elements, structures are performed by a pair of fasteners of the protrusion-socket type, and at least a part of the protrusions-protrusion-socket orientations forming the connection during installation of a building, structure in the direction of the force lines of the force field or a combination of force fields, which creates dominant forces in the area of the mounted element or in the building environment of the building.

The stiffness core can be performed at least within the height of the floor being erected, and the mounted elements of a building, structure - in the form of power, enclosing and / or combined elements, including with a hidden frame, are attached to the stiffness core with at least two attachments spaced within the length and / or height of the core points.

Elements of a building or structure may be attached to the core of rigidity and / or to elements previously attached to form a rigid system, such as three-dimensional blocks and / or panels, and / or extended structures - struts, crossbars and / or struts.

The elements of the fastening connection of the protrusion-socket can be placed on the mounted elements in at least two points spaced apart within the length, or height, or area of the mounted element.

A building, a structure can be constructed from various elements - volumetric blocks, wall panels, floor panels, frame elements, while at least one building structure element, structures are made immediately before installation or during installation.

To connect the elements of the building as fasteners can use bolt, screw, nail, screw and rivet connections.

In fasteners of the protrusion-socket type, the protrusion can be made in the form of a spike.

The connecting elements can be made split with a slot on the spike and / or socket, while the fasteners - spikes - are removable or installed before installation.

Spike-socket type connecting elements can be made with round or elongated holes so that after assembling the elements these holes are aligned and allow the spike and socket to be fixed to each other with an additional locking element in the form of a stud, screw or screw.

At least part of the fasteners of the spike and socket type can be made along the normal section of their longitudinal axis compatible in shape, at least in a section normal to the longitudinal axis of the connection, while forming an inner surface of the socket oriented in the direction of the longitudinal axis of the connection, made straightforward, linear, broken, curved or composite configuration, at least on the part of the length of the thorn-socket connection, with the formation of at least one conical, pyramidal, barrel-shaped and whether the prismatic portion of the nest is at least part of the joint height.

The connecting elements of the spike-socket type or their block can be made with at least one hole with an axis parallel to the longitudinal axes of the fastening elements, while at least one tensile strand is predominantly aligned with it in the holes.

Strained cords of at least one joint can be placed outside the zone of the fastening elements of the spike socket.

The longitudinal axis of the fasteners of the protrusion-socket type connections can be oriented in the direction of the lines of force of the natural or artificial gravitational field or the resulting addition of the lines of force of the static gravitational and calculated aerodynamic and / or hydrodynamic, including unilaterally asymmetric, effects, the linear dimensions of the elements are accepted multiple or fractional multiple of a given module, and the distances between the centers of adjacent fasteners are made satisfying the above ratio NIJ them with a given modulus, wherein at least a portion of one of adjacent fasteners mounted component may be attached both to one and to the other structural members mounted a building, structure.

The technical result achieved in both versions of the method consists in simplifying the installation of buildings and structures from elements of high factory readiness, increasing the spatial rigidity and stability of buildings, structures, unifying the constituent elements, providing the possibility of creating buildings and structures for various purposes from a limited range of elements and simplifying their transportation.

Both variants of the invention are illustrated by drawings and examples, which do not cover and, moreover, do not limit the entire scope of the claims of this invention.

Figure 1-14 shows a perspective view of the phased construction of a building, a structure with a hall room and a core of rigidity in the form of a volume unit;

on Fig-23 - in a perspective view of the phased construction of a building, structures with a prefabricated core rigidity;

on Fig.24-25 is a perspective view of a building with stiffness cores;

in Fig.26 is a perspective view of one building with stiffness cores and another building with stiffness cores in the context;

in Fig.27 is a perspective view of the precast core of the building;

on Fig - temporary fixation of the corner wall panels;

on Fig - temporary fixation of ordinary wall panels;

on Fig - mounting the rack to the wall panel;

on Fig - options for foundation elements with fasteners in the form of plates with spikes;

in Fig.32 is an embodiment of a docking unit for a floor panel to a stiffness core with a rack;

Fig.33 is an embodiment of a docking unit for a floor panel to a stiffness core with an assembly table;

on Fig-36 - embodiments of fasteners of the type protrusion-socket in a perspective view;

on Fig - fasteners of the type protrusion-socket in the context.

The method of construction of a building, structure includes the construction of a foundation 1 or platform on a prepared foundation, installation of a part of the lower floor 2 and the construction of one core of rigidity 3 within the height of the floor being erected. This is followed by joining to the core of rigidity 3 with attachment at two points of power, enclosing or combined, including with a hidden frame of mounted elements 4 of the building, structure, spaced apart within the length and / or height of the core. These elements 4 are attached to the core and / or attached to it with the formation of a rigid system of elements such as volumetric blocks, and / or panels, and / or extended structures - struts, crossbars and / or struts. In this case, part of the connections is performed by a pair of fasteners 5 of the type protrusion-socket. Moreover, one of the components of such a connection with a protrusion and / or socket is provided with each mounted element 4, respectively, at least at one of the points spaced within the length, or height, or area of the mounted element. At the same time, the fastening elements 5 protrusion-socket forming the joints, having longitudinal axes that are coaxial or parallel to each other, are oriented during the installation of a building, structure in the direction of the force lines of the force field or a combination of force fields, which creates dominant forces in the area of the mounted element or in the building environment buildings, structures (in Fig.27-29, the indicated direction is indicated by an arrow).

The building, construction is being erected at least partially by one-story, small or medium-story buildings.

Or a building, a structure is being erected, at least in part, of medium or high storeys.

The building is erected from various elements - volume blocks, wall panels, floor panels, frame elements, while at least one structural element of the building is made immediately before installation or during installation.

To connect the building elements, bolting, screw, nail, screw and rivet joints are used as fasteners.

And in the fasteners 5 type protrusion-socket protrusion is made in the form of a spike 6. In this case, the fasteners are split with a slot 8 on the spike 6 and / or socket 7. The spikes can be removable or installed before installation.

The spike-type connecting elements 5 can be made with round or elongated holes so that after assembling the elements these holes are aligned and allow the spike 6 and socket 7 to be fixed to each other with an additional fixing element in the form of a stud, screw or screw (not shown in the drawings shown).

At least part of the fasteners of the type spike 6 and socket 7 are made along a section normal to their longitudinal axis compatible in shape, at least in a section normal to the longitudinal axis of the joint. Moreover, the generatrix of the inner surface of the nest, oriented in the direction of the longitudinal axis of the connection, is made in a straightforward, linear, broken, curved or composite configuration, at least on a part of the length of the spike-nest connection, with the formation of at least one conical, pyramidal, a barrel-shaped or prismatic portion of the nest, at least at part of the joint height.

The connecting elements 4 of the spike-socket type or their block are made with at least one hole with an axis parallel to the longitudinal axes of the fastening elements 4, while at least one strained strand is predominantly aligned with it in the holes.

Strained cords of at least one connection are placed outside the area of the fastening elements of the spike socket.

The longitudinal axis of the fasteners of the 5 protrusion-socket type joints are oriented in the direction of the lines of force of the natural or artificial gravitational field or the resulting addition of the lines of force of the static gravitational and calculated aero- and / or hydrodynamic, including one-sided asymmetric effects, the linear dimensions of the elements are assumed to be multiple or fractionally multiple to a given module, and the distances between the centers of adjacent fasteners are made satisfying the aforementioned ratio of them to this module, wherein at least part fasteners adjacent one mounted component, can be attached both to one and to the other structural members mounted a building, structure.

To create a core of rigidity 3 of a building, structure, assembled, for example, from panel elements (not shown in the drawings), at least one tenon of different vertical or inclined elements is placed in at least one socket in at least one socket. In this case, the spikes and nests on the structural elements of the building, structures can be made different in shape and size, which are determined by both the transmitted loads and the working conditions of the structures and tolerances determined depending on the materials used, the manufacturing method and installation conditions, and the building elements, forming a core of rigidity 3 and perceiving loads to ensure the rigidity of a building, a structure is oriented in different directions.

In this case, one of the components of such a connection with a fastening element - a spike 6 and / or socket 7 - is provided with each mounted element 4, at least two points spaced apart within the length, or height, or area of the mounted element.

When creating a stiffness core 3 of a building on the basis of a fully prefabricated volume unit, in which, if necessary, both communication means and equipment difficult for installation at the construction site and transportation are placed, at least one volume unit is placed on one floor or at least one unit in every building.

To the core of rigidity 3 of the building based on the volumetric block is connected, at least in part, to the location of the elements of the frame of the volumetric unit, multiple or fractional to the height of the floor of the building, floor panels 9, inclined elements 10 and / or frame elements 11. At the same time, they adjoin at least one face or one corner with the support of at least one opposite face or other angles either on the rack 12, or on the frame elements 11, or on the wall panel 13, while the length of the stiffness core 3 - volume unit and wall panel 13 - in terms of equal to or a multiple of the corresponding dimensions of the adjacent floor panels 9, and the height of the stiffness core 3 or at least one of its building block is equal to or a multiple or fractional multiple of the floor height of the building. The connection of the floor panels 9 or inclined elements 10, containing sockets 7, with the elements of the stiffness core 3 of the building is carried out using spikes 6 placed on the supporting tables or racks 12 attached to the volume unit, while the racks 12 are fixed to the stiffness core to increase them sustainability.

In order to use unified building elements, structures, wall panels 13, both absorbing vertical loads and self-supporting, use a single standard size, and they are strengthened to absorb vertical loads by attaching vertical supporting elements 11 of the frame equipped with spikes 6, while increasing the stability of these vertical supporting elements 11 of their frame are fixed rigidly to the structures of the wall panels 13.

For the same purpose, the vertical supporting elements of the frame 11 are provided with as many studs 6 at each level as the number of floor panels 9 rests on this element in a given connection node or how many vertical floor elements 11 are supported by this frame element in a given connection node.

In order to simplify the installation of the building, the construction and reduce the mounting fixtures, the spikes 6 of the vertical frame supporting elements 11 are combined with a washer 14 from above with at least one hole or sleeve when mounting the building.

To increase the reliability of the building, structure, including under dynamic loads, after assembling the corresponding tier, the spikes 6 located in their respective slots 7 are fixed, if necessary, using fasteners or substances, for example, hardening mixtures.

The building is a cell type, with prefabricated panels of the core rigidity 3, assembled as follows.

The foundation elements 1 are mounted on the prepared base and fasteners are fixed on them in the form of plates 15 with spikes b; the lower floor panels 9 are mounted at least partially on the foundation elements so that the spikes 6 previously mounted enter the slots 7 located in the corners and on the faces of the floor panels 9. Then the first wall panel 13 is exposed, usually angular and temporarily unfastened. In this case, the studs 6, mounted on the wall panel 13 from below, are placed in the mating slots 7 of the floor panel 9. The second wall panel 13 is mounted adjacent to the first so that one of the lower studs 6 is located in the same slot 7 of the floor panel 9 as the stud mounted wall panel, and the second spike 6 is located in another slot 7 on the same floor panel 9. Before releasing the second wall panel 13 from the holding slings of the lifting device, the adjacent studs 6 located in the upper zone of the wall panels are put on This washer 14 or sleeve, which holds these panels from displacement during installation. Further, the wall panels 13 can be freed from lifting and mounting devices, and their stability is ensured by fixing four points belonging to two wall panels 13 and one floor panel 9 in such a way that each of the three panels included in this assembly are fixed to each other by three dots. After that, either the posts 12 or the wall panel 13 are installed, while the wall panel 13 installed adjacent to one of the previously mounted ones is also fixed from displacements by means of the washer 14, like the previous wall panels. Then, at least three vertical elements 11 of the frame and / or rack 12 are mounted corner panel overlap 9 so that in its nests 7 are the spikes 6 of the wall panels 13 or rack 12 of the first floor. Then sequentially, in the same way, the vertical elements 11 of the frame and the rack 12 of the first floor and the floor panel 9 of the first floor are mounted.

Installation of subsequent floors is carried out in a similar way.

When used as a core of rigidity 3 of a building of a volume unit, the installation of the building is performed as follows.

The foundation elements 1 are mounted on the prepared base and fasteners are fixed on them in the form of plates 15 with spikes 6; foundation elements 1 are mounted at least partially lower floor 2 - floor panels 9 and at least one volumetric block so that the previously mounted spikes 6 fit into slots 7 located in the corners and on the faces of the floor panels 9 and volumetric block - stiffness core 3 Then, the racks 12 are fixed on the volumetric block so that the lower studs 6 of the racks are located in the slots 7 of the lower overlapping panels 9, or the mounting tables (not shown in the drawings) are fixed in the appropriate places. After that, the racks 12 or the wall panel 13 are installed with the placement of their lower spikes 6 in the corresponding slots 7 of the floor panels 9, and the ceiling panel 9 is mounted on top so that the spikes 6 of the lower vertical supporting elements 11 of the frame or racks 12 are located in the slots 7 of the floor panel 9. The remaining vertical and horizontal or inclined building elements are mounted in the same way.

When installing a building with hall rooms between the elements of the foundation 1, a lower crossbar 16 is installed, then two racks 12 of the corresponding height are fixed to the stiffness core 3 in the previously described way, then two racks 12 are mounted and temporarily fastened on the foundation elements, between these racks 12 and the racks 12, mounted on the stiffness core, the crossbar 16 is mounted so that the studs 6 of the uprights 12 are located in the corresponding sockets 7 of the crossbar 16, then the wall panel 13 is mounted on the crossbar and the panel is mounted on the crossbar 16 and the wall panel 13 l floor 9, in the slots 7 of which are placed the spikes 6 of the crossbar 18 and the wall panel 13. Next, mount the next wall panel 13 and the next floor panel 9 in the same way.

Then the crossbar is mounted between the end elements of the foundation, the wall panels 13 and the racks 12 of the end row are installed, and the final floor panel 9 is mounted on the crossbars 16 and the wall panels 13, in the slots 7 of which are placed the spikes 6 of the crossbars 16 and the wall panels 13.

In other spans, installation is carried out in a similar manner.

Claims (25)

1. A method of constructing a building, structure, characterized in that it includes the construction of a foundation or platform, the installation of at least part of the lower floor and the construction of at least one core of rigidity, at least within the height of the floor to be built and subsequent connection to it with by attaching at least two points of power, enclosing and / or combined, including with a hidden frame of mounted building elements, structures that are attached to the core and / or attached, spaced at least two spaced apart within the length and / or height of the core to it with the formation of a rigid system of elements such as three-dimensional blocks and / or panels, and / or extended structures - struts, crossbars and / or struts, and at least some of the connections are made by a pair of fastening elements of the protrusion-socket type, with one of the components of such a connection, a protrusion and / or socket provide each mounted element, respectively, at least at one of the points spaced apart within the length, height or area of the mounted element, and the protruding-socket fastening elements forming the connections, and eyuschie longitudinal axis coaxial or parallel to each other, oriented when mounting building constructions into the direction of lines of force of the force field or combination of fields of force, creating a dominant force in the zone where the element or mounted in a building environment, buildings, construction. 2. The method according to claim 1, characterized in that the building, structure is erected at least partially single-storey, low or medium floors. 3. The method according to claim 1, characterized in that the building, structure is erected, at least partially medium or high floors. 4. The method according to claim 1, characterized in that the building is erected from various elements - volumetric blocks, wall panels, floor panels, frame elements, while at least one structural element of the building is made immediately before installation or during installation. 5. The method according to claim 1, characterized in that for connecting the building elements, bolting, screw, nail, screw and rivet joints are used as fasteners. 6. The method according to claim 1, characterized in that in the fasteners of the protrusion-socket type, the protrusion is in the form of a spike. 7. The method according to claim 6, characterized in that the fasteners are split with a slot on the spike and / or socket, while the fasteners - spikes are removable or installed before installation. 8. The method according to claim 1, characterized in that the fasteners of the spike-socket type are made with round or elongated holes so that after assembly of the elements, these holes are aligned and allow the spike and socket to be fixed between themselves with an additional locking element in the form of a stud screw or screw. 9. The method according to claim 6, characterized in that at least part of the fasteners of the spike and socket type are performed along a section normal to their longitudinal axis, compatible in shape, at least in a section normal to the longitudinal axis of the joint, wherein the generatrix of the inner surface of the socket, oriented in the direction of the longitudinal axis of the connection, is made in a straight, linear, broken, curved, or composite configuration, at least on a part of the length of the spike-socket connection, with the formation of at least one conical, pi amidalnogo, barrel-shaped or prismatic socket portion at least part of the joint height. 10. The method according to claim 6, characterized in that the fasteners of the spike-socket type or their block are performed with at least one hole with an axis parallel to the longitudinal axes of the fasteners, while at least one tensioned predominantly coaxially with it is placed in the holes heavy. 11. The method according to claim 10, characterized in that the tensile strands of at least one connection are placed outside the zone of the spike-socket fasteners. 12. The method according to claim 1, characterized in that the longitudinal axis of the fasteners of the protrusion-socket type connections are oriented in the direction of the lines of force of the natural or artificial gravitational field or the resulting addition of the lines of force of the static gravitational and calculated aerodynamic and / or hydrodynamic, the number of one-way asymmetric influences, the linear dimensions of the elements are taken as multiple or fractional multiple of a given module, and the distances between the centers of adjacent fasteners are satisfied which correspond to the aforementioned relationship with a given module, and at least a portion of the adjacent fasteners of one mounted structural element can be connected to one or other mounted structural elements of the building or structure. 13. The method of construction of a building, structure, characterized in that it includes the construction of the foundation, installation of at least part of the lower floor and the construction of at least one core of rigidity and the subsequent attachment of the mounted elements of the building, structure, and at least part the connections of the building elements, structures are performed by a pair of fasteners of the protrusion-socket type, and at least part of the protrusions-nest-forming fasteners forming the joints are oriented during installation of the building, the structure force lines of a force field or a combination of force fields that creates dominant efforts in the area of the mounted element or in the building environment of a building or structure. 14. The method according to item 13, wherein the stiffness core is performed at least within the height of the floor being erected, and the mounted building elements, structures in the form of power, enclosing and / or combined elements, including with a hidden frame of elements, are attached to stiffness core with attachment at least two points spaced apart within the length and / or height of the core. 15. The method according to 14, characterized in that the elements of the building, structures are attached to the core of rigidity and / or to elements previously attached to form a rigid system, such as three-dimensional blocks and / or panels, and / or extended structures - racks, crossbars and / or struts. 16. The method according to p. 13, characterized in that the elements of the fastening connection of the protrusion-socket are placed on the mounted elements in at least two points spaced apart within the length or height or area of the mounted element. 17. The method according to p. 13, characterized in that the building, structure is constructed from various elements - volumetric blocks, wall panels, floor panels, frame elements, while at least one structural element of the building, structures are made immediately before installation or during installation. 18. The method according to item 13, characterized in that to connect the elements of the building as fasteners use bolt, screw, nail, screw and rivet connections. 19. The method according to p. 13, characterized in that in the fasteners of the type protrusion-socket protrusion is performed in the form of a spike. 20. The method according to claim 19, characterized in that the fasteners are split with a slot on the spike and / or socket, while the fasteners - spikes are removable or installed before installation. 21. The method according to item 13, wherein the tenon-type fasteners are made with round or elongated holes so that after assembling the elements, these holes are aligned and allow the spike and socket to be fixed to each other with an additional locking element in the form of a stud screw or screw. 22. The method according to claim 19, characterized in that at least part of the fastening elements of the spike and socket type are performed along a section normal to their longitudinal axis, compatible in shape, at least in a section normal to the longitudinal axis of the joint, the generatrix of the inner surface of the socket, oriented in the direction of the longitudinal axis of the connection, is made in a rectilinear, linear, broken, curved or composite configuration, at least on a part of the length of the spike-socket connection, with the formation of at least one conical ramidalnogo, barrel-shaped or prismatic socket portion at least part of the joint height. 23. The method according to claim 19, characterized in that the fasteners of the spike-socket type or their block are performed with at least one hole with an axis parallel to the longitudinal axes of the fasteners, while at least one tensioned predominantly coaxially with it is placed in the holes heavy. 24. The method according to p. 23, characterized in that the tensile strands of at least one connection are placed outside the zone of the fastening elements of the spike socket. 25. The method according to item 13, wherein the longitudinal axis of the fasteners of the protrusion-socket type connections are oriented in the direction of the lines of force of a natural or artificial gravitational field or the resulting addition of vectors of lines of static gravity and calculated aerodynamic and / or hydrodynamic, the number of one-sided asymmetric actions, the linear dimensions of the elements are taken as multiple or fractional multiple of a given module, and the distances between the centers of adjacent fasteners are satisfied said conductive relation with their given modulus, wherein at least a portion of one of adjacent fasteners mounted component may be attached both to one and to the other structural members mounted a building, structure.

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