RU2198270C1 - Process of erection, restoration or reconstruction of buildings, structures (versions ) - Google Patents

Abstract

FIELD: construction industry, erection of residential, public and administrative buildings and structures, their restoration and reconstruction. SUBSTANCE: in accordance with first variant process includes digging of foundation pit and/or trenches, preparation of bed, erection of foundation, erection or restoration or reconstruction of frame or of its part including posts, spanners and floor plates, assembly or disassembly and replacement of engineering systems. At least part of erected, restored or reconstructed frame is made of prefabricated-monolithic posts with joints and prefabricated-monolithic spanners in which only lower part is prefabricated to withstand technological loads from mounted hollow plates. Upper part of spanner is made monolithic and joined to its lower part with simultaneous formation of spanner protrusions in floor hollows with rendering supporting sections of assembled plates monolithic. Reinforced cages common for two plates and/or individual rods joining opposite floor plates in pairs and to spanner are entered into hollows of plates, continuous within limits of opposite pair of hollows of adjacent plates of monolithic unit, before formation of monolithic protrusions. Given process in agreement with second variant includes erection or restoration or reconstruction of frame or of its part including posts, spanners and floor panels, erection or replacement of structures of walls, ceiling in which at least part of erected or restored or reconstructed frame is made prefabricated-monolithic with making joints of posts monolithic and spanners prefabricated-monolithic. Only lower part of spanner designed for technological loads of supporting assembled hollow floor plates is made prefabricated and upper of spanner is joined monolithically to its lower part with simultaneous formation of spanner protrusions in plate hollows with making supporting sections and sections near them monolithic. Reinforced cages common for two plates and/or individual rods joining opposite floor plates in pairs and to spanner are entered into hollows of plates, continuous within limits of opposite pair of hollows of adjacent plates of monolithic unit, before formation of monolithic protrusions. EFFECT: possibility to execute operations under any weather conditions, predominantly in regions related to rigorous climatic zones with low negative temperatures in winter season with simultaneous reduction of time of execution of work and reduced usage of materials and labor input. 22 cl, 12 dwg

Description

 The invention relates to the field of construction and can be used in the construction of residential, public and administrative buildings and structures, as well as in their restoration or reconstruction.

 There are various methods of construction, restoration or reconstruction of buildings, structures (see, for example, RU 2107783 C1, E 04 1/35, 12/30/1996).

 The disadvantages of the known methods of erection, restoration or reconstruction of buildings and structures are the significant labor and material costs, the considerable time it takes to carry out the work and the impossibility of carrying out them regardless of weather conditions, especially in regions related to harsh climatic zones with low negative temperatures in winter.

 The objective of the present invention, both in part of the first embodiment of the method and in part of the second, is to reduce labor and material costs while reducing the time of work and making it possible to carry out them under any weather conditions, mainly in regions related to harsh climatic zones with low negative temperatures in the winter time.

 The problem in part of the first variant of the method is solved due to the fact that according to the invention in the method of construction, restoration or reconstruction of buildings, structures, including the excavation of pits and / or trenches, preparation of the foundation, construction of foundations, construction, restoration, or reconstruction of the frame or its parts, including columns, girders and floor slabs, as well as installation or disassembly and replacement of engineering systems, in which at least part of the frame being erected, or being restored, or reconstructed in they are filled with prefabricated-monolithic with monolithic joints of columns and prefabricated-monolithic crossbars, in which the teams perform only their lower part, designed for technological loads from the support of the mounted hollow core slabs, and the upper part of the crossbar is monolithic to its lower part with the simultaneous formation of protrusions of the crossbars in the voids of the plates with the monolithic of the supporting and supporting sections of the mounted plates, moreover, into the voids of the plates, before the formation of the monolithic protrusions, they lead through through within the response pair of voids of adjacent plates It monolithic site common on two plates reinforcing cages and / or individual bars, pairwise connecting with each other and with the crossbar opposite floor slabs.

 During the erection of the floor after installation of the prefabricated parts of the crossbars, laying hollow slabs supported on them, institutions in the supporting sections of the voids of the reinforcing cages and / or individual rods can lay additional core elements that are oriented along the ends of the slabs and placed in the longitudinal direction of the crossbar in its upper monolithic parts, at least partially with touching the transverse reinforcement of the monolithic part of the crossbar, and / or reinforcing cages, and / or individual rods, inserted into the voids of the floor slabs with the formation of a continuous structure in two directions of the structure - along the plates in the direction of flight of the plates, and along the crossbars - in the direction of the spans of the crossbars on which the plates are supported.

 Before inserting the reinforcing cages and / or individual rods into the supporting and supporting sections of the voids of the mounted plates in the voids at a distance from the ends of the plates, not less than 1.3 plate thickness and corresponding to the length of the protrusion of the crossbar formed in these areas, they can arrange plugs that prevent the spreading of concrete .

 They can use prefabricated monolithic columns, which are made in height composite of at least two prefabricated sections, each of which is made with concrete spaced apart from each other, sections free from concrete, outlets of working reinforcement at one end and channels for releases of the reinforcement of the adjacent section - on the other end.

 The length of the releases of the working reinforcement of the sections of the columns can be equal to 1.3-2.7 of the largest cross-sectional dimension of the column, and the depth of the channels in the sections of the columns and / or columns is more than two times the diameter of the output of the working reinforcement, and the channels are, at least part of the length of the conical, expanding upward with an angle of inclination of the generatrix of the cone to the vertical, the tangent of which is not less than 0.01, while on the walls of the channels form troughs located at least two-way spiral, which matured operate in longitudinal section in the shape of a trapezium with the larger base surface of the channel, and a smaller width of 0.1 average diameter of the channel.

 The sub-columns, and / or grillages, and / or the ends of the sections of the columns in the area of the channel can be performed with additional reinforcement, which is arranged in a spiral in the concrete body around the channels.

 The lower parts of the crossbars can be concreted in molds with tensioning reinforcement and the use of inserts that perform the corresponding voids of the slabs in shape.

 In the manufacture of the lower parts of the crossbars, metal forms can be used, which are performed at least in two rows, and the inserts are made of composite metal separating elements and disposable inserts of elastically crumpled or easily destructible material.

 The lower parts of the crossbars can be performed with the releases of the reinforcement on the surface facing the upper part that is supposed to be fixed.

 The internal walls and partitions can be made of brick, and / or expanded clay concrete stones, and / or of gypsum perlite elements with a height corresponding to the height of the floor, and / or of sheet materials, and at least part of the partitions are shot with metal brackets to the frame of the building, structure .

 Stairs can be laid on prefabricated reinforced concrete beams, which are made with cutouts for the supporting parts of the marches, and the platforms are made of floor slabs.

 At least part of the ground structures and / or foundations can be made of brick masonry and / or expanded clay concrete blocks.

 At least part of the masonry can be performed by a well, lightweight of the outer and inner layers located at a distance from each other and the insulation placed between them, while the outer layer of the masonry is made of silicate brick, the inner one is made of ordinary clay brick or expanded clay concrete blocks, and as insulation use expanded clay gravel, or ecowool, or expanded polystyrene, or mineral wool, or gernite, or polyethylene foam.

 The problem in part of the second variant of the method is solved due to the fact that according to the invention in the method of construction, restoration or reconstruction of buildings, structures, including the construction, or restoration, or reconstruction of the frame or its part, including columns, beams and slabs, construction or replacement wall structures, coatings, in which at least part of the erected, or restored, or reconstructed frame is prefabricated with monolithic joints of columns and prefabricated monolithic frames firs, in which the teams perform only their lower part, designed for technological loads from supporting the mounted hollow core slabs, and the upper part of the crossbar is monolithic to its lower part with the simultaneous formation of protrusions of the crossbar in the voids of the plates with the monolithic support and supporting sections of the mounted plates, and the voids of the plates before the formation of the monolithic protrusions lead through the reinforcing cages and / or section common to the two plates within the response pair of voids of adjacent plates of the monolithic node ln rods, pairwise connecting with each other and with a crossbar opposite overlapping plates.

 When erecting the overlap after installation of the prefabricated parts of the crossbars, laying hollow slabs supported on them, and institutions in the supporting sections of the hollows of the reinforcing cages, additional core elements can be laid that are oriented along the ends of the slabs and placed in the longitudinal direction of the crossbar in its upper monolithic part, at least least partially with regard to the transverse reinforcement of the monolithic part of the crossbar, and / or reinforcing cages, and / or individual rods, inserted into the voids of the floor slabs with the formation of continuous d in two directions of the structure - along the plates in the direction of flight of the plates, and along the crossbars - in the direction of the spans of the crossbars on which the plates are supported.

 Before inserting the reinforcing cages and / or individual rods into the supporting and supporting sections of the voids of the mounted plates in the voids at a distance from the ends of the plates, not less than 1.3 plate thickness and corresponding to the length of the protrusion of the crossbar formed in these areas, they can arrange plugs that prevent the spreading of concrete .

 They can use prefabricated monolithic columns, which are made in height by components of at least two prefabricated sections, each of which is made with concrete spaced apart from each other, sections free of concrete, outlets of working reinforcement at one end and channels for releases of the reinforcement of the adjacent section - on the other end.

 The length of the releases of the working reinforcement of the sections of the columns can be equal to 1.3-2.7 of the largest cross-sectional dimension of the column, and the depth of the channels in the sections of the columns and / or columns is more than two times the diameter of the output of the working reinforcement, and the channels are, at least part of the length of the conical, expanding upward with the angle of inclination of the generatrix of the cone to the vertical, the tangent of which is not less than 0.01, while on the walls of the channels form depressions located at least along a two-way spiral, which matured operate in longitudinal section in the shape of a trapezium with the larger base surface of the channel, and a smaller width of 0.1 average diameter of the channel.

 The sub-columns, and / or grillages, and / or the ends of the sections of the columns in the area of the channel can be performed with additional reinforcement, which is arranged in a spiral in the concrete body around the channels.

 The lower parts of the crossbars can be concreted in molds with tensioning reinforcement and the use of inserts that perform the corresponding voids of the slabs in shape.

 In the manufacture of the lower parts of the crossbars, metal forms can be used, which are performed at least in two rows, and the inserts are made of inventory metal separating elements and disposable inserts of elastically crumpled or easily destructible material, and the lower parts of the crossbars are made with releases of reinforcement on the surface facing the upper part of them.

 The internal walls and partitions can be made of brick, and / or expanded clay concrete stones, and / or of gypsum perlite elements with a height corresponding to the height of the floor, and / or of sheet materials, and at least part of the partitions are shot with metal brackets to the frame of the building, structure .

 Stairs can be laid on prefabricated reinforced concrete beams, which are made with cutouts for the supporting parts of the marches, and the platforms are made of floor slabs.

 At least a part of the ground structures and / or foundations can be made of brick masonry and / or expanded clay concrete blocks, and at least a part of the masonry is made of a well, lightened from the outer and inner layers located at a distance from each other and placed between them insulation, while the outer layer of masonry is made of silicate brick, the inner one is made of ordinary clay brick or expanded clay concrete blocks, and expanded clay is gravel, or ecowool, or foam listirol, or mineral wool, or gernit, or polyethylene foam.

 The technical result provided by the above set of essential features both in the first and in the second part of the embodiment of the invention consists in providing the ability to work under any weather conditions, mainly in regions related to harsh climatic zones with low negative temperatures in winter time while reducing the time of work and reducing labor and material costs.

The essence of the invention is illustrated by drawings, where
figure 1 shows the frame of a building, structure in cross section;
figure 2 - shows the frame of the building, structure in a perspective view;
figure 3 is the same in plan;
in FIG. 4 - connection node of floor slabs with a crossbar in a perspective view with a partial cutaway;
figure 5 is the same as in figure 4, in the context, the option of reinforcing the frame, the upper monolithic part of the crossbar is made in the form of an extended polyhedron with a cross section in the form of a rectangle;
in Fig.6 is the same as in Fig.5, the option of reinforcing with individual rods, the upper monolithic part of the crossbar is made with a cross section in the form of a quasiregular;
figure 7 - arrangement of the joints of the frame in the plan;
in Fig.8 - node C in Fig.7;
in Fig.9 - node D in Fig.7;
figure 10 - node E in figure 7;
figure 11 - butt connection of the crossbar with the column, a longitudinal section;
Fig.12 is a section aa in Fig.11.

 The method of construction, restoration or reconstruction of buildings, structures 1 according to the first embodiment includes a fragment of pits and / or trenches (not shown), preparation of the foundation, construction of foundations 2, construction or restoration, or reconstruction of the frame 3 or its part, including columns 4, crossbars 5 and slabs 6 floors 7, as well as installation or disassembly and replacement of engineering systems (not shown). In the method, at least part of the erected, or restored, or reconstructed frame 3 is made of prefabricated-monolithic with monolithic joints of 8 columns 4 and prefabricated-monolithic crossbars 5, in which prefabricated carry out only their lower part 9, designed for technological loads from support mounted plates 6 having voids 10. The upper part 11 of the crossbar 5 is monolithic to its lower part 9 with the simultaneous formation of the protrusions 12 of the crossbar 5 and the monolithic support 13 and supporting 14 sections of the voids 10 mounted plates 6. Note m into the voids of 10 slabs before the formation of monolithic protrusions, a reinforcing cage 15 and / or individual rods 16 common to two slabs is inserted through the void pair of adjacent slabs of the monolithic node, pairwise connecting the opposite slabs 6 to each other and to the crossbar 5.

 When erecting the ceiling 7 after mounting the prefabricated 9 parts of the crossbars 5, laying hollow slabs 6 based on them, institutions in the supporting sections 14 of the voids 10 of the reinforcing cages 15 and / or individual rods 16, additional core elements (not shown) are laid that are oriented along the ends of the plates and placed in the longitudinal direction of the bolt 5 in the upper monolithic part 11, at least partially touching the transverse reinforcement 17 of the monolithic part 11 of the bolt 5 and / or reinforcing cages 15, and / or individual rods 16, wound into the voids 10 of the slabs 6 of the overlap 7 with the formation of a continuous structure in two directions - along the slabs 6 in the direction of flight of the slabs 6 and on the crossbars 5 - in the direction of the spans of the crossbars 5, on which the slabs 6 are supported.

 Before the reinforcing cages 15 and / or the individual rods 16 are inserted into the supporting 13 and supporting 14 sections of the voids 10 of the mounted plates 6 in the voids 10 at a distance from the ends of the plates 6, not less than 1.3 of the thickness of the plate 6 and the corresponding length of the protrusion 12 formed on these sections crossbar 5, arrange stubs 18, preventing spreading of concrete monolithic.

 Prefabricated monolithic columns 4 are used, which are performed in height by components of at least two prefabricated sections 19, each of which is made with concrete spaced apart from each other, sections 20 free of concrete, outlets 21 of working fittings (on drawings not shown) on one end and channels (not shown) under the outlets of the reinforcement 21 of the adjacent section - on the other end.

 The length of the outlets 21 of the working reinforcement (not shown in the drawings) of the sections of the 19 columns 4 is taken equal to 1.3-2.7 of the largest cross-sectional size of the column 4, and the depth of the channels (not shown) in the sections 19 of the columns 4 and / or sub-columns 22 is greater than the length of the corresponding outlet 21 by more than two diameters of the outlet 21 of the working armature (not shown in the drawings). Channels (not shown) are performed, at least on a part of the length, conical, expanding upward with an angle of inclination of the generatrix of the cone to the vertical, whose tangent is not less than 0.01. At the same time, hollows (not shown) are formed on the walls of the channels (not shown), which are made in a longitudinal section in the form of a trapezoid with a large base on the channel surface (not shown) and a smaller width of 0.1 the average diameter of the channel (not shown in the drawings).

 The sub-columns 22, and / or grillages 23, and / or the ends of the sections 19 of the columns 4 in the zone of the channel arrangement (not shown) are made with additional reinforcement (not shown), which are arranged in a spiral in the concrete body around the channels (not shown in the drawings).

 The lower parts 9 of the crossbars 5 are concreted in molds (not shown) with tensioning of the reinforcement and the use of inserts (not shown in the drawings), which are performed according to the shape of the voids of the plates.

 In the manufacture of the lower parts 9 of the crossbars 5, metal forms (not shown) are used, which are performed at least in two rows, and the inserts (not shown) are made up of inventory metal dividing elements (not shown) and disposable inserts (not shown in the drawings) from elastically crushed or from easily destroyed material.

 The lower parts 9 of the crossbars 5 are performed with the releases 24 of the reinforcement on the surface facing the upper part of which is implanted 11.

 The inner walls (not shown) and partitions (not shown in the drawings) are made of brick, and / or expanded clay concrete stones, and / or of gypsum perlite elements with a height corresponding to the height of the floor, and / or of sheet materials, and at least part the partitions are shot with metal brackets (not shown) to the frame 3 of the building, structure.

 Stair flights (not shown) are laid on precast reinforced concrete beams (not shown), which are made with cutouts (not shown) under the supporting parts (not shown) of the marches, and platforms (not shown) are made of 6 floor slabs.

 At least part of the ground structures and / or foundations 2 are made of brick masonry and / or expanded clay concrete blocks.

 At least part of the masonry is performed by a well, lightweight of the outer and inner layers (not shown) located at a distance from each other and the insulation (not shown) located between them, while the outer layer (not shown) of the masonry is made of silicate brick, the inner (not shown) - from ordinary clay brick or expanded clay concrete blocks, and as insulation (not shown in the drawings) use expanded clay gravel, or ecowool, or expanded polystyrene, or mineral wool, or gernite, or polyethylene foam.

 The second embodiment of the method of construction, restoration or reconstruction of buildings, includes the construction, or restoration, or reconstruction of the frame 3 or its parts, including columns 4, crossbars 5 and slabs 6 of ceilings 7, construction or replacement of wall structures (not shown), coatings ( not shown in the drawings). At least part of the erected, or restored, or reconstructed frame 3 is made of prefabricated-monolithic with monolithic joints of 8 columns 4 and prefabricated-monolithic crossbars, in which prefabricated carry out only their lower part, designed for technological loads from abutment of mounted plates 6 having voids 10, and the upper part 11 of the crossbar 8 is monolithic to its lower part 9 with the simultaneous formation in the voids of the plates of the protrusions 12 of the crossbar 8 with the monolithic support 13 and support 14 sections of the mounted plates 6. Into the voids 10 plates 6 before monolithic lead through the reinforcing cages 15 and / or separate rods 16 common to two plates 6 within the monolithic unit, pairwise connecting opposite plates 6 of the floor 7 to each other and to the crossbar 5.

 During the erection of the floor 7 after installation of the prefabricated 9 parts of the crossbars 5, laying with the hollow plates 6 resting on them, the institutions in the supporting 14 sections of the voids 10 of the reinforcing cages 15 put additional rod elements (not shown) that are oriented along the ends of the plates and placed in the longitudinal direction crossbar 5 in its upper monolithic part 11, at least partially touching the transverse reinforcement 17 of monolithic part 11 of crossbar 5 and / or reinforcing cages 15, and / or individual rods 16, inserted into the voids 10 of plates 6 is closed I 7 to form a continuous structure in two directions - on the plates 6 in the direction of flight of the plates 6 and girders 5 - in the direction of flown of crossbars 5, which are simply supported plate 6.

 Before the reinforcing cages 15 and / or the individual rods 16 are inserted into the supporting 13 and supporting 14 sections of the voids 10 of the mounted plates 6 in the voids 10 at a distance from the ends of the plates 6, not less than 1.3 of the thickness of the plate 6 and the corresponding length of the protrusion 12 formed on these sections crossbar 5, arrange stubs 18, preventing spreading of concrete monolithic.

 Prefabricated monolithic columns 4 are used, which are performed in height by components of at least two prefabricated sections 19, each of which is made with concrete spaced apart from each other, sections 20 free of concrete, outlets 21 of working fittings (on drawings not shown) on one end and channels (not shown) under the outlets of the reinforcement 21 of the adjacent section - on the other end.

 The length of the outlets 21 of the working reinforcement (not shown in the drawings) of the sections of the 19 columns 4 is taken equal to 1.3-2.7 of the largest cross-sectional size of the column 4, and the depth of the channels (not shown) in the sections 19 of the columns 4 and / or sub-columns 22 is greater than the length of the corresponding outlet 21 by more than two diameters of the outlet 21 of the working armature (not shown in the drawings). Channels (not shown) are performed, at least on a part of the length, conical, expanding upward with an angle of inclination of the generatrix of the cone to the vertical, whose tangent is not less than 0.01. At the same time, hollows (not shown) are formed on the walls of the channels (not shown), which are made in a longitudinal section in the form of a trapezoid with a large base on the channel surface (not shown) and a smaller width of 0.1 the average diameter of the channel (not shown in the drawings).

 The sub-columns 22, and / or grillages 23, and / or the ends of the sections 19 of the columns 4 in the zone of the channel arrangement (not shown) are made with additional reinforcement (not shown), which are arranged in a spiral in the concrete body around the channels (not shown in the drawings).

 The lower parts 9 of the crossbars 5 are concreted in molds (not shown) with tensioning of the reinforcement and the use of inserts (not shown in the drawings), which are performed according to the shape of the voids of the plates.

 In the manufacture of the lower parts 9 of the crossbars 5, metal forms (not shown) are used, which are performed at least in two rows, and the inserts (not shown) are made up of inventory metal dividing elements (not shown) and disposable inserts (not shown in the drawings) from elastically crushed or from easily destroyed material. The lower parts 9 of the crossbars 5 are performed with the releases 24 of the reinforcement on the surface facing the upper part of which is implanted 11.

 The inner walls (not shown) and partitions (not shown in the drawings) are made of brick, and / or expanded clay concrete stones, and / or of gypsum perlite elements with a height corresponding to the height of the floor, and / or of sheet materials, and at least part the partitions are shot with metal brackets (not shown) to the frame 3 of the building, structure.

 Stair flights (not shown) are laid on precast reinforced concrete beams (not shown), which are made with cutouts (not shown) under the supporting parts (not shown) of the marches, and platforms (not shown) are made of 6 floor slabs.

 At least part of the ground structures and / or foundations 2 are made of brick masonry and / or expanded clay concrete blocks. Moreover, at least part of the masonry is performed by a well, lightweight from the outer and inner layers located at a distance from each other (not shown) and insulation placed between them (not shown), while the outer layer (not shown) of the masonry is made of silicate brick , internal (not shown) - from ordinary clay bricks or from expanded clay concrete blocks, and as insulation (not shown in the drawings) use expanded clay gravel, or ecowool, or expanded polystyrene, or mineral wool, or gernit, or expanded polystyrene Thielen.

Claims (22)

 1. The method of construction, restoration or reconstruction of buildings, including the excavation of pits and / or trenches, preparation of the foundation, construction of foundations, construction, or restoration, or reconstruction of the frame or its part, including columns, crossbars and floor slabs, as well as installation or dismantling and replacing engineering systems, in which at least part of the erected, or restored, or reconstructed frame is prefabricated-monolithic with monolithic column joints and prefabricated-monolithic crossbars, in which national teams perform only their lower part, designed for technological loads from supporting the mounted hollow core slabs, and the upper part of the crossbar is monolithic to its lower part with the simultaneous formation of protrusions of the crossbar in the voids of the plates with monolithic support and supporting sections of the mounted plates, and in the hollows of the plates before the formation of monolithic protrusions at a distance from the ends of the plates, not less than 1.3 thickness of the plate and the corresponding length of the protrusion of the crossbar formed in these sections, arrange stubs, preventing spreading concrete monolithic, and lead into the voids through reinforcing frames and / or separate rods, common on two plates, through the limits of the pair of voids of adjacent plates of the monolithic unit, that connect the opposite floor slabs in pairs with each other and with the crossbar.  2. The method according to claim 1, characterized in that during the erection of the ceiling after installation of the prefabricated parts of the crossbars, laying with the hollow plates resting on them, institutions in the supporting sections of the voids of the reinforcing cages and / or individual rods lay additional rod elements that are oriented along the ends plates and placed in the longitudinal direction of the crossbar in the upper monolithic part of it at least partially touching the transverse reinforcement of the monolithic part of the crossbar, and / or reinforcing cages, and / or individual rods x into the voids of the floor slabs with the formation of a continuous structure in two directions of the structure - along the plates in the direction of flight of the plates and along the crossbars - in the direction of the spans of the crossbars on which the plates are supported.  3. The method according to claim 1 or 2, characterized in that the use of precast-monolithic columns, which are made in height composite of at least two prefabricated sections, each of which is performed with sections located from each other at a distance equal to the height of the floor free from concrete, releases of working reinforcement at one end and channels for releases of reinforcement of an adjacent section at the other end.  4. The method according to claim 3, characterized in that the length of the releases of the working reinforcement of the column sections is assumed to be 1.3-2.7 of the largest cross-sectional dimension of the column, and the depth of the channels in the column sections and / or sub-columns is more than the length of the corresponding outlet more than on two diameters of the outlet of the working reinforcement, and the channels are made at least partly conical, expanding upward with an angle of inclination of the generatrix of the cone to a vertical whose tangent is not less than 0.01, while on the walls of the channels they form at least d uhzahodnoy spiraling depressions that operate in longitudinal section in the shape of a trapezoid with the larger base surface of the channel, and a smaller width of 0.1 average diameter of the channel.  5. The method according to any one of claims 1 to 4, characterized in that the columns, and / or grillages, and / or the ends of the sections of the columns in the area of the channels are performed with additional reinforcement, which is arranged in a spiral in the concrete body around the channels.  6. The method according to any one of claims 1 to 5, characterized in that the lower parts of the crossbars are concreted in molds with tensioning reinforcement and using inserts that perform corresponding to the shape of the voids of the plates.  7. The method according to claim 6, characterized in that in the manufacture of the lower parts of the crossbars, metal forms are used that are made at least in two rows, and the inserts are made up of inventory metal separation elements and disposable inserts of elastically crushed or easily destructible material.  8. The method according to any one of claims 1 to 7, characterized in that the lower parts of the crossbars are performed with the outlets of the reinforcement on the surface facing the upper part which is implanted.  9. The method according to any one of claims 1 to 8, characterized in that the internal walls and partitions are made of brick and / or expanded clay concrete stones and / or of gypsum perlite elements with a height corresponding to the height of the floor and / or sheet materials, at least part of the partitions is shot with metal brackets to the frame of the building or structure.  10. The method according to any one of claims 1 to 9, characterized in that the staircases are laid on precast reinforced concrete beams, which are made with cutouts for the supporting parts of the marches, and the platforms are made of floor slabs.  11. The method according to any one of claims 1 to 10, characterized in that at least part of the ground structures and / or foundations is made of brick masonry and / or expanded clay concrete blocks.  12. The method according to claim 11, characterized in that at least part of the masonry is performed by a well, lightweight from the outer and inner layers located at a distance from each other and the insulation placed between them, while the outer layer of the masonry is made of silicate brick, the inner one from ordinary clay bricks or from expanded clay concrete blocks, and as insulation use expanded clay gravel, or ecowool, or expanded polystyrene, or mineral wool, or gernite, or polyethylene foam.  13. A method of erecting, restoring or reconstructing buildings or structures, including erecting, or restoring, or reconstructing a carcass or part thereof, including columns, beams and floor slabs, erecting or replacing wall structures, coatings in which at least part of the erected, or of the restored or reconstructed frame is prefabricated-monolithic with monolithic joints of columns and prefabricated-monolithic crossbars, in which prefabricated only their lower part, designed for technological loads from supporting the mounted hollow core slabs, and the upper part of the crossbar is monolithic to the lower part with the simultaneous formation of protrusions of the crossbars in the voids of the plates with monolithic supporting and supporting sections of the mounted plates, and in the voids of the plates before the formation of monolithic protrusions at a distance of not less than 1 , 3 thicknesses of the slab and the corresponding length of the bolt protrusion formed in these areas, arrange plugs that prevent the spreading of concrete monolithing, and lead into voids through in the end ah mating pair of voids adjacent slabs concreted node shared by two plate reinforcing frames and / or individual rods, pairwise binding between themselves and with the opposed bolt slab.  14. The method according to item 13, characterized in that during the construction of the ceiling after installation of the prefabricated parts of the crossbars, laying with the hollow plates resting on them, the institutions put additional core elements in the support sections of the voids of the reinforcing frames, which are oriented along the ends of the plates and placed in the longitudinal the direction of the crossbar in the upper monolithic part of it at least partially with the touch of the transverse reinforcement of the monolithic part of the crossbar, and / or reinforcing cages, and / or individual rods inserted into the voids of the slabs with the formation of a continuous structure in two directions of the structure - along the plates in the direction of flight of the plates and along the crossbars - in the direction of the spans of the crossbars on which the plates are supported.  15. The method according to any one of paragraphs.13-14, characterized in that use precast-monolithic columns, which are performed at a height of composite of at least two precast sections, each of which is performed with spaced from each other at a distance equal to the height of the floor , areas free from concrete, releases of working reinforcement at one end and channels for releases of reinforcement of an adjacent section at the other end.  16. The method according to p. 15, characterized in that the length of the releases of the working reinforcement of the column sections is taken equal to 1.3-2.7 of the largest cross-sectional dimension of the column, and the depth of the channels in the column sections and / or sub-columns is more than the length of the corresponding outlet more than on two diameters of the outlet of the working reinforcement, and the channels are made at least partly conical, expanding upward with an angle of inclination of the generatrix of the cone to the vertical, whose tangent is not less than 0.01, while on the walls of the channels they form at least vuhzahodnoy we are spiraling depressions that operate in longitudinal section in the shape of a trapezoid with the larger base surface of the channel, and a smaller width of 0.1 average diameter of the channel.  17. The method according to any one of paragraphs.13-16, characterized in that the columns, and / or grillages, and / or the ends of the sections of the columns in the area of the channels are performed with additional reinforcement, which is arranged in a spiral in the concrete body around the channels.  18. The method according to any one of paragraphs.13-17, characterized in that the lower parts of the crossbars are concreted in molds with tensioning reinforcement and the use of inserts that perform corresponding to the shape of the voids of the plates.  19. The method according to p. 18, characterized in that in the manufacture of the lower parts of the crossbars metal forms are used that are at least double-row, and the inserts are made up of inventory metal separating elements and disposable inserts of elastically crushed or easily destructible material, the lower parts of the crossbars are performed with the releases of the reinforcement on the surface facing the upper part of which they are being monitored.  20. The method according to any one of paragraphs.13-19, characterized in that the inner walls and partitions are made of brick, and / or expanded clay stones, and / or of gypsum perlite elements with a height corresponding to the height of the floor, and / or sheet materials, and at least part of the partitions is shot with metal brackets to the frame of the building or structure.  21. The method according to any one of paragraphs.13-20, characterized in that the staircases are laid on precast reinforced concrete beams, which are made with cutouts for the supporting parts of the marches, and the platforms are made of floor slabs.  22. The method according to any one of paragraphs.13-21, characterized in that at least part of the ground structures and / or foundations is made of brick masonry and / or expanded clay concrete blocks, and at least part of the masonry is made of well, lightweight, from located at a distance from each other of the outer and inner layers and the insulation placed between them, while the outer layer of the masonry is made of silicate brick, the inner one is made of ordinary clay brick or expanded clay concrete blocks, and used as insulation eramsite gravel, or ecowool, or expanded polystyrene, or mineral wool, or gernite, or polyethylene foam.

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