RU76656U1 - COMMUNICATED PLATE-SPACER (OPTIONS), ASSEMBLY UNIT FOR COMMUNICATED PLATE-SPACERS (OPTIONS) AND FRAMED-COMMUNICATED OR COMMUNICATED MOBILE PLATFORM - Google Patents

Abstract

To simplify the design and improve the manufacturability of the manufacture of a spacer slab (SPR), while increasing its functionality, strength and simplifying the installation technology in prefabricated and prefabricated monolithic frames (K), as well as providing the possibility of building prefabricated and prefabricated monolithic buildings (3 ) increased number of storeys and increased strength and seismic stability, while at the same time increased strength and rigidity K 3, in SPR for installation along the inner rows of K 3 columns containing those made of reinforced concrete LBW with trimmings on the end sides for the passage of columns, with reinforcement and embedded metal elements for connecting the LWB with crossbars and other LWGs in K 3, the LWR body is made with a solid central zone filled with concrete without reinforcement with the possibility of laying in the process of manufacturing the LWD, cutting or drilling during installation in the Central zone of the body SPR through holes for the passage of ventilation units and utilities 3, while SPR in cross section is made in a trapezoidal shape with parallel planes the upper and lower surfaces of the SPR, and the side and end walls of the SPR are made oblique from the bottom up towards the central part of the SPR. According to another embodiment, SPR for installation on the outer columns of K 3, containing the SPR body made of concrete with trims on the end sides for passing columns along the outer rows of K 3, with fittings and embedded metal elements for connecting the SPR with columns, crossbars and other SPR in K 3, the SPR body is made with a solid central zone filled with concrete, with a cross section in the form of a rectangular trapezoid with parallel planes of the upper and lower surfaces of the SPR, with one side perpendicular to the indicated planes and another sloping from the bottom up in the direction to the Central part of the SPR with the other side of the SPR. Variants of the SPR connection unit and the frame-coupled or connected frame of a prefabricated or precast-monolithic building include the SPR of the construction described above.

5 n.p. f-ly, 30 z.p. crystals, 1 tab., 9 ill.

Description

FIELD OF TECHNOLOGY

The utility model relates to the field of construction and can be used in the construction of multi-storey prefabricated or prefabricated monolithic buildings and structures with a frame-bond or link frame and reinforced concrete slabs of coatings and floors of public, residential or industrial purposes, erected in various areas, including seismic ones.

BACKGROUND

The well-known frame of a multi-story building of the 1.020-1 / 87 series, including reinforced concrete columns, with reinforced concrete crossbars fixed to them, onto which reinforced concrete multi-hollow slabs are stacked, joined together in flat disks of floors. This frame is constructed from typical building structures, products and units [1].

The design of the frames of these and similar buildings and the technology of their construction have a number of technical drawbacks, namely: insufficiently large column spacing (6 m or 7.2 m), high laboriousness of manufacture, insufficient rigidity and strength of the frame, which do not allow the construction of high-rise buildings, especially in seismic areas.

Particularly complex technological problems arise in the manufacture of openings for the passage of ventilation units and communications in the floors of known building structures and structures.

Known prefabricated reinforced concrete frame of the building with an overlapping of hollow core slabs containing crossbars installed on the supporting elements of the columns with shelves for supporting the floor slabs, in which the floor slabs

they are made molded with undercuts — recesses, forming cantilever plates on two opposite ends of the plate for support on the crossbars of the crossbar, while the height of the crossbars of the crossbars is made commensurate with the depth in the thickness of the plate of the undercut — the recesses interfaced with the shelf, and the console of the plates are reinforced with additional reinforcing cages made in the form of welded gratings, including rods of longitudinal reinforcement connected by transverse clamps: upper, lower and middle, made shortened and placed above the supporting surface of the console, and also an anchored rod with a limb, the gratings are vertically installed in the frontal sections of the slab in hollow spaces, with the exception of those in which the prestressed rod and the loop with the lower reinforced belt are located at the same time, while the prestressed rod is bounded by the walls of the undercut-notch. In addition, the crossbars in the frame are reinforced by the inclusion of additional rods of longitudinal working reinforcement in the reinforcing cage, and undercuts - notches are made to half the thickness of the plate [2].

To increase the strength of the frame of prefabricated buildings and to provide the possibility of erecting buildings with high floors, structures with elements of prestressed reinforcement are currently used.

In particular, constructions of reinforced concrete buildings are known, the framework of which includes columns with cross-shaped openings at the level of the floors and floor slabs, combined with columns of reinforced at the construction site reinforcement passing along the axis of the columns in the joints between the floor slabs [3, 4; 5].

There is also known a method of prestressing the floor, consisting of columns and a slab resting on them, the combination of which with the columns is performed by reinforcement being tensioned during installation, the essence of which is that mounting (inventory) spacers are installed between adjacent columns, to which the efforts of the tensioned are transmitted fittings [6].

In addition, designs are being developed and used to restore the enclosing and bearing capacity of large-panel prefabricated buildings, for example, the K-7, P-32, P-35, 1-515 series, including a steel reinforcement frame in the form of racks installed on the foundation along the vertical joints of the outer panels and connected by horizontal

stiffening belts located along the horizontal joints of the panels and solid steel strands pulled in the transverse direction of the building, passed through the inner longitudinal wall along the bottom surface of the floor slabs and fixed with ends on the horizontal stiffening belts, and in the direction of the strands between the horizontal stiffening belts there are compression limiters in the form of a packet reinforcing bars placed in a steel cage, rigidly fixed to the bottom surface of the floor slab and fixed horizontally The inner stiffness belt and the longitudinal inner wall, and the longitudinal inner wall are reinforced on both sides by prestressed struts connected to each other at the level of the ceilings and pulled together with the reinforcement frame of the end panels. The frame, ties, limiters and struts are covered with a layer of concrete and / or plaster with the formation of a single structure with external panels, an internal longitudinal wall and floor slabs, which ultimately allows to increase the bearing and enclosing ability of large-panel buildings, to carry out superstructure of buildings and redevelopment of premises, and also increase seismic stability, improve thermal and sound insulation and increase the life of the building by more than two times [7].

To increase the strength and rigidity of prefabricated buildings, floor slabs of increased strength are developed and used in practice.

In particular, ribbed floor slabs with prestressed reinforcement are known (8). They are easy to manufacture, but their strength is low, so they are used only for ceiling ceilings in industrial buildings.

For floors between residential and industrial buildings, hollow core slabs with pre-stressed lower reinforcement are usually used (9). The disadvantages of these and all other known floor slabs are their lack of strength and rigidity.

Therefore, in prefabricated and prefabricated monolithic buildings, use spacer plates of increased stiffness and strength, capable of perceiving and compensating for alternating loads in the building frame.

The closest to the invention in its essence and the achieved result (prototype) in terms of the tie-plate spacers is the sanitary-technical communication panel PS 70.12-8.12AIVt [10 (prototype)], installed in the column pitch of 6.0 and 7.2 m according to GOST 13015.0-83 *

“Reinforced concrete and concrete prefabricated structures and products”, SNiP 2.03.01.07-84 “Concrete and reinforced concrete structures” and SNiP 2.01.07.-85 “Loads and impacts” and as applied to manufacturing technology at concrete products No. 4 of the Production Association “BARRICADA” ( Applicant of the present utility model).

Typical design features of this slab (prototype) are a trough-like shape with transverse stiffening ribs oriented upwards from inside, length 5760 mm, width 6960 mm, height 220 mm, trimmings at the ends for passing columns with a cross-sectional width of up to 400 mm, as well as the bottom of the grooves with a pitch of 400 mm for possible penetration of holes of various sizes for the passage of ventilation units and utilities, the presence of dowels in the side faces, as well as the presence of embedded parts for perception, are horizontal x tensile effort.

The technical disadvantages of the prototype tie plate spacers are: the complexity of the design with not sufficiently high strength and reliability, the high complexity of manufacturing and installation, the need to fill concrete trough-like recesses during installation.

The closest to the invention in its essence and the achieved result (prototype) in the part of the connection unit and the frame is a reinforced concrete frame of a building or structure, including columns with crosswise openings at the level of the floors and a floor disk consisting of prefabricated plates, edge and cantilever elements, and prestressing reinforcement passing through the holes in the columns, and the overlapping disk consists of monolithic mutually intersecting reinforced concrete belts running along longitudinal and along erechnyh grid axes columns inside belts laid tendon tension with the efforts to transfer inventory mounting spacers mounted between adjacent columns, and prefabricated plates placed in the cell formed by monolithic belts [11 (prototype)].

The technical disadvantages of this prototype are the design complexity with insufficiently high strength and reliability, the high complexity of manufacturing and installation, the need for additional inventory equipment, the possibility of load on the overlap only after the strength of the joints after the concrete has hardened.

TASKS AND TECHNICAL RESULTS

The main technical problem (the inventive task has not been solved so far) is that the known constructions of strut plates, their joints and frames with their use are laborious and expensive to manufacture and install, but most importantly, they do not allow building prefabricated and prefabricated monolithic buildings of increased number of storeys and large sizes between the center axes of the columns.

The purpose of the utility model and the technical result achieved when using the utility model is to simplify the design and increase the manufacturability of the production of the strut plate, while increasing its functionality, strength and simplify the installation technology, simplify the design and installation of the connection nodes of the strut plate in prefabricated and prefabricated -monolithic frames, as well as providing the possibility of building prefabricated and precast-monolithic buildings of increased number of storeys and increased strength and seismic willow by providing the possibility of using columns with a cross-sectional width of up to 60 cm, the possibility of using prefabricated and prefabricated monolithic structures in the construction of residential and public buildings with the required degree of fire resistance R120, as well as providing the possibility of more free layout of premises in the building by increasing spans to 9, 0 m while increasing the strength and rigidity of the frame of the building as a whole.

DISCLOSURE OF A USEFUL MODEL

The goal, the required and obtained by using the utility model technical result is achieved by the fact that in the first embodiment of the structural design of the connection plate-spacer for installation on the inner rows of columns of a frame-connection or connection frame of a prefabricated or precast-monolithic building containing a body made of reinforced concrete bonded strut plate with trimmings on the end sides for passing columns, with fittings and embedded metal elements for bonding bonded strut plate with crossbars and other tie plates-spacers in the frame of a prefabricated or prefabricated-monolithic building, according to a useful model, the body of the tie plate-spacers is made with a solid central zone filled with concrete without reinforcement with the possibility of laying in the process of manufacturing a tie plate-spacers, cutting or drilling during installation in central area of the body of the spacer plate

through holes for the passage of ventilation units and utilities of a prefabricated or prefabricated monolithic building, while the tie plate-spacer in cross section is made in trapezoidal shape with parallel planes of the upper and lower surfaces of the tie plate-spacer, and the side and end walls of the tie plate-spacer beveled from the bottom up towards the central part of the spacer plate.

At the same time, trimming at the ends of the bonded slab for installation on the inner rows of columns of the frame-bonded or bonded frame is made with the possibility of passing columns of the frame-bonded or bonded frame of a prefabricated or precast-monolithic building with a cross-sectional width of up to 600 mm, and the bonded plate is the spacer is made long enough to be installed in a frame-coupled or connected frame of a prefabricated or prefabricated-monolithic building with a span between center axes of up to 9000 mm.

At the same time, the reinforcement of the tie-strut plate for installation along the inner rows of columns of the frame-tie or tie cage contains elements of prestressed reinforcement longitudinally located in the lateral parts of the body of the strut-plate in the form of reinforcing ropes of type ⌀12K7-1500 according to GOST 13840-68 and elements of non-tensioned reinforcement type A-III (A400) according to GOST 5781-82 *, as well as indirect reinforcement in the form of reinforcing meshes located in the body of the tie plate-spacers parallel to the planes of the upper and lower surfaces of the tie plate-spacers.

In this case, the spacer plate for installation on the inner rows of columns of the frame-link or link frame is made with a protective layer of concrete from the surface of the spacer link plate to prestressed reinforcement of at least 6 cm with the possibility of ensuring a fire resistance of up to REI 120 min.

In addition, the side walls of the tie-plate strut for installation on the inner rows of columns of the frame-tie or tie frame contain longitudinally oriented recesses made with the possibility of transferring bending loads to adjacent tie-plate spacers or adjacent cover or overlap plates in the frame-tie or tie frame prefabricated or prefabricated-monolithic building by means of a prefabricated or prefabricated-monolithic building laid in the gaps between the side walls when stacked during installation in a frame-coupled or connected frame and spacer plate

and adjacent slabs of coating or overlapping concrete mix, forming, after hardening in a gap with an adjacent slab, and a longitudinally oriented hard tongue mating with the adjacent slab.

Moreover, the spacer plate for installation on the inner rows of columns of a frame-link or link frame is made with the possibility of perception of longitudinal tensile forces of up to 30 tons, has a width of 148 to 150 cm, predominantly 49 cm, and a height of 21 to 23 cm 22 cm and is made with the possibility of perception and transmission through the metal connecting elements of the vertical loads on the crossbars, as well as with the possibility of perceiving horizontal alternating forces and transferring them through the metal connecting x elements for diaphragm stiffness and column or frame-Svjaseva Svjaseva carcass precast or prefabricated monolithic building.

In addition, parts of the bonded strut plate with embedded metal connecting elements are located on the protrusions along the edges of the end sides of the bonded strut plate for installation on the inner rows of columns of the frame-bonded or bonded frame and are made of a lower height compared to the height of the central zone of the bonded strut plate on the height necessary for the installation of metal connecting elements, welded in appropriate places to the crossbars and to the embedded metal elements of other communication strut plates, with the possibility of forming a single horizontal plane of overlapping or covering the frame-bonded or bonded frame of a prefabricated or precast-monolithic building after installation of a spacer plate.

The embedded metal elements of the bonded strut plate for installation along the inner rows of columns of the frame-bonded or bonded frame are made with the possibility of their welded connection by means of metal connecting elements with embedded mortar metal elements of the crossbars and with embedded metal elements of other bonded strut plates with the formation of a geometrically unchanged contour of a horizontal disk of overlapping or covering a frame-bonded or bonded frame of a prefabricated or precast monolithic rear In addition, the spacer bond plate is made of heavy concrete of class B40 using the bench forming method.

The goal, the required and obtained when using the utility model, the technical result is also achieved by the fact that in the second

an embodiment of a tie plate-spacer for installation on external columns of a frame-tie or tie frame of a prefabricated or prefabricated-monolithic building containing the body of a concrete tie plate with cuttings on the end sides for passing columns along the outer rows of a frame-tie or tie the frame of a prefabricated or prefabricated monolithic building, with reinforcement and embedded metal elements for connecting a tie plate-spacers with columns, crossbars and other connection plate-spacers in according to the utility model, the body of the tie plate is made with a continuous concrete-filled central zone with a cross section in the shape of a rectangular trapezoid with parallel planes of the upper and lower surfaces of the tie plate-strut, with one side perpendicular to the indicated planes and the other side beveled from the bottom up towards the central part of the strut plate with the other side of the bonded strut plate.

At the same time, trimming along the end sides of the strut plate for installation on the outer columns of the frame-bonded or bonded frame is made on one side of the bonded strut plate with the possibility of passing columns along the outer rows of the frame-bonded or bonded frame of a prefabricated or precast monolithic building with a width cross section up to 600 mm.

Moreover, the spacer plate for installation on the outer columns of the frame-link or link frame is made long enough to be installed in the frame-link or link frame of a prefabricated or prefabricated-monolithic building with a span between center axes of up to 900 cm, the reinforcement of the spreader plate contains parallel to the plane of the lower surface of the strut plate, the elements of prestressed reinforcement in the form of ⌀12K7-1500 reinforcing ropes uniformly distributed across the width of the strut plate according to GOST 13840-68 and longitudinally elements of non-tensile reinforcement type A-III (A400) located in the lateral parts of the body at the upper surface of the spacer plate according to GOST 5781-82 *, as well as indirect reinforcement in the form of reinforcing meshes parallel to the planes of the upper and lower surfaces of the spacer plate, which made with a protective layer of concrete from the surface of the spreader plate to tensile reinforcement of at least 6 cm and with a fire resistance of up to REI 120 min.

In addition, the lateral side of the spacer plate oriented to the central part of the frame-bonded or bonded frame of a prefabricated or prefabricated-monolithic building for installation on the outer columns of the frame-bonded or bonded frame contains a longitudinally oriented recess made with the possibility of transferring bending loads to an adjacent coating plate or overlapping in a frame-bonded or bonded frame of a prefabricated or precast-monolithic building by means of a bonded stacked in the gaps between the specified side wall -Spacer plate and the side wall adjacent cover plate overlapping or concrete mix, forming after curing a rigid longitudinally oriented keys.

Moreover, the spacer plate for installation on the outer columns of the frame-link or link frame is made with the possibility of perception of longitudinal tensile forces of up to 30 tons, has a width of 113 to 115 cm, mainly 114 cm, and a height of 21 to 23 cm, mainly 22 cm.

At the same time, the spacer plate for installation on the outer columns of the frame-coupled or connected frame is designed to transfer vertical loads to the crossbars and columns with the possibility of perceiving horizontal alternating forces and transferring them via metal connecting elements to the diaphragms of rigidity and columns in the frame-coupled or connected the frame of the prefabricated or prefabricated monolithic building, parts of the tie plate-spacers with embedded metal connecting elements are made of a lower height by comparison with the height of the central zone of the spacer plate to the height necessary to install metal connecting elements welded to the embedded metal elements of other bonded spacer plates with the possibility of forming a single horizontal plane of overlap or coating in the frame-bonded or bonded frame of a prefabricated or precast-monolithic building mounting plate spacers.

In addition, embedded metal connecting elements of the tie-plate struts for installation on the outer columns of the frame-tie or tie frame are made with the possibility of their welded connection by means of metal connecting elements with crossbars, columns and embedded metal elements of other tie plates-struts with the formation of a geometrically unchanged horizontal contour drive

overlapping or coating in a frame-bonded or bonded frame of a prefabricated or precast-monolithic building.

At the same time, the tie plate-spacer for installation on the outer columns of the frame-tie or tie frame is made of heavy concrete of class B 40 by the bench molding method.

The goal, the required and obtained by using the utility model technical result is also achieved by the fact that in the first embodiment of the structural embodiment of the connection unit of the connecting strut-struts along the inner rows of columns of a frame-bonded or bonded frame of a prefabricated or precast-monolithic building containing a column installed on column or rigidly connected to the column crossbars with shelves and embedded metal elements mounted on the shelves crossbars and made of reinforced concrete bond plates-p Asporka with trimmings on the end sides for the passage of the column and embedded metal elements, according to a useful model, the tie-struts on the inner rows of columns of the frame-bonded or bonded frame are made with a solid central zone filled with concrete without reinforcement with the possibility of laying during the manufacture of strut plates, cutting or drilling during installation in the central area of the body of the connecting plate-spacers through holes for the passage of ventilation units and utilities precast and a prefabricated-monolithic building, while the tie plates-spacers are installed on the shelves of the crossbars along the layer of cement-sand mortar and are connected to each other and crossbars by means of metal connecting elements, welded to the embedded metal elements of the struts and crossbars with the formation of a geometrically unchanged horizontal contour a disk of overlapping or covering in a frame-bonded or bonded frame of a prefabricated or precast-monolithic building.

At the same time, the connecting struts-spacers along the inner rows of columns of the frame-bonded or bonded frame are made of the construction described above.

At the same time, in the junction of the connecting strut plates along the inner rows of columns of the frame-bonded or bonded frame, the gaps between the end walls of the strut plates, the column and the crossbars are filled with concrete mixture to ensure that after it hardens the transfer of vertical loads to the crossbars, as well as with the possibility of perception by means of metal connecting elements of horizontal alternating

efforts and transferring them to diaphragms of rigidity and columns of a frame-bonded or bonded frame of a prefabricated or precast-monolithic building.

The goal, the required and obtained by using the utility model technical result is also achieved by the fact that in the second embodiment of the design of the connection unit of the connection plate-spacers along the outer rows of columns of the frame-link or link frame of a prefabricated or precast-monolithic building containing a column with a console or with metal support tables mounted on the sides of the column in the direction of abutment of the connecting struts, mounted on the console of the column or rigidly connected to it has a bolt with embedded metal elements installed on the shelves of the bolt and on the metal supporting tables and strut plates made of reinforced concrete with side trims for the column to pass and embedded metal elements, according to the utility model, the strut tie plates are made of solid, filled with concrete a central zone with a cross section in the form of a rectangular trapezoid with parallel planes of the upper and lower surfaces of the tie plate-spacers, with one perpendicular the indicated planes with the lateral side and another beveled upward from the bottom towards the central part of the strut plate with the other lateral side of the strut plate and end walls made beveled upward from the bottom towards the central part of the strut plate, with the column, communication strut plates and the crossbar is connected to each other by means of metal connecting elements welded to the embedded metal elements of the strut plates, the crossbar and the column with the formation of a geometrically unchanged horizontal contour ntal disk of overlapping or covering in a frame-bonded or bonded frame of a prefabricated or precast-monolithic building.

At the same time, in the connection node of the connecting strut plates along the outer rows of columns of the frame-bonded or bonded frame of a prefabricated or precast-monolithic building, the connecting strut plates are made of the design described above.

In addition, the gaps between the end walls of the connecting strut plates, the column and the crossbar are filled with concrete mixture to ensure that after it hardens the transfer of vertical loads to the crossbars, as well as with the possibility of perception through metal connecting

elements of horizontal alternating forces and transferring them to the stiffness diaphragms and columns of the frame-bonded or bonded frame of a prefabricated or precast-monolithic building, and the lateral side perpendicular to the planes of the upper and lower surfaces of the slab is located in the same plane with the outer side of the columns along the outer row of the frame-bonded or connection frame of a prefabricated or precast-monolithic building.

The goal, the required and obtained by using the utility model technical result is also achieved by the fact that in a frame-coupled or connected frame of a prefabricated or prefabricated-monolithic building, containing inner and outer rows of columns of a frame-coupled or connected frame of a prefabricated or prefabricated-monolithic building and crossbars installed on columns with embedded metal elements, as well as tie struts installed on columns and crossbars and made of reinforced concrete with trimming on the end side m for the passage of columns and embedded metal elements according to a useful model, the strut tie plates along the inner rows of columns are made with a central zone filled with concrete without reinforcement with the possibility of laying during the manufacturing of the strut plate, cutting or drilling during installation in the central area of the body of the bond plates - a spacer of through holes for the passage of ventilation units and utilities of a prefabricated or precast-monolithic building, with connection plates-spacers along the inner row columns are mounted on the shelves of the crossbars along the layer of cement-sand mortar and are connected to each other and the crossbars by means of metal connecting elements welded to the embedded metal elements of the strut plates and crossbars with the formation of a geometrically unchanged contour of the horizontal disk of overlap or coating in a frame-bonded or bonded the frame of the prefabricated or prefabricated monolithic building, and the tie plates-spacers along the outer rows of columns are made with a solid, concrete-filled central zone with a cross a section in the form of a rectangular trapezoid with parallel planes of the upper and lower surfaces of the strut plate, with one side perpendicular to the indicated planes, while the other side of the bonded strut plates and the end walls of the bonded strut plates are slanted from the bottom up towards the central parts bonded spacer plates, and bonded spacer plates on the outside

the rows of columns and crossbars are connected to each other by means of metal connecting elements welded to the embedded metal elements of strut plates, crossbars and columns with the formation of a geometrically unchanged contour of the horizontal disk of overlapping or coating in a frame-coupled or connected frame of a prefabricated or precast-monolithic building.

Moreover, in the frame-bonded or bonded frame of a prefabricated or prefabricated-monolithic building, the connecting strut plates along the inner rows of columns and the connecting strut struts along the outer rows of columns are made of the construction described above.

DESCRIPTION OF DRAWINGS

Figure 1 presents a 3D image of a tie plate-spacers on the inner rows of columns without holes for ventilation units and utilities.

Figure 2 - 3D-model of the communication plate-spacers on the inner rows of columns with a hole for ventilation units and utilities.

Figure 3 is a view A of the connecting strut plate along the inner rows of columns.

Figure 4 - section 1-1 of the connecting plate spacers on the inner rows of columns.

Figure 5 is a 3D image of a tie plate spacers on the outer rows of columns.

6 is a view G of the connecting plate spacers on the outer rows of columns.

7 is a 3D image of a fragment of the overlap and frame of the building using the tie plates-spacers.

On Fig - 3D image of the connection node of the connecting plates-spacers along the inner rows of columns with crossbars and with each other.

Figure 9 is a 3D image of the connection node of the connection plate-spacers along the outer rows of columns with crossbars, columns and with each other.

A design variant of the tie plate-spacer, intended for installation along the inner rows of columns (Figs. 1, 2), contains the body of the tie plate-spacers 1 with embedded metal parts for tight connection by welding with beams and between each other after installation in the building frame.

A tie plate-spacer, installed along the inner rows of columns, is made with trimmings 3 at the ends to pass the column with a cross-sectional width of up to 600 mm and zone 4 of possible laying holes for

technical communications.

Figure 2 shows a structural modification of a variant of the connection plate-spacers, designed for installation on the inner rows of columns, in which during its manufacture holes 5 are made for the passage of ventilation units and technical communications.

The frame using connection struts-spacers contains columns 6, crossbars 7, ordinary floor slabs multi-hollow bezopalochnogo molding 8, connection struts-spacers on the inner rows of columns 1, connection plates-spacers on the outer rows of columns 9 and metal connecting elements 10.

In the lateral parts of the strut plates mating with other plates, longitudinal recesses are made in the form of dowels 11, and the coupling strut plates themselves contain prestressed reinforcement 11 and unstressed reinforcement 12.

IMPLEMENTATION AND INDUSTRIAL IMPLEMENTATION OF A USEFUL MODEL

According to the utility model, the spacer slab according to the utility model can be used in bonded and frame-bonded frames of prefabricated or precast-monolithic buildings and structures with reinforced concrete floor slabs for public, residential or industrial purposes of increased number of storeys and increased seismic resistance.

Bonded strut plates are designed to transfer vertical loads on the crossbar in bonded and frame-bonded frames of prefabricated or precast-monolithic buildings and structures, and as part of horizontal disks of floors or coatings, to absorb horizontal alternating forces and transfer them to stiffness diaphragms and columns.

The tie struts according to the invention have welded joints with crossbars and with each other by means of metal connecting elements and together with the crossbars form a geometrically unchanged contour of the horizontal disk of overlapping or coating.

Coupling plates-spacers according to the invention are made with predominant, but not mandatory dimensions, 149 cm wide and 22 cm high, and can also be made of another predetermined size with a length sufficient for installation in building frames with column spacing up to 900 cm.

The slabs are trimmed to allow columns with a cross-sectional width of up to 600 mm, which allows them to be used in buildings with increased number of storeys and earthquake resistance.

To pass ventilation units and communications in the central zone of the plates, it is possible to lay holes directly in the process of bench forming.

Spacer plates are made primarily, but not necessarily, of heavy concrete of class B40 and reinforced with prestressed reinforcement mainly, but not necessarily, of class ⌀12K7-1500 according to GOST 13840-68 and non-tensioned reinforcement mainly, but not necessarily, of grade A-III ( 400) according to GOST 5781-82 *.

Marking of slabs is accepted in accordance with GOST 23009-78 * "Structures and products of concrete and reinforced concrete prefabricated and consists of alphabetic and digital indexes", alphabetic and digital, where alphabetic indexes indicate the type of slab for the purpose in the building frame ("PR" - struts; digital indexes mean the length, width of the plates, the bearing capacity for vertical and horizontal loads).

Comparison table of the features of the prototype plate and the tie strut according to the invention Signs Prototype plate (communication sanitary panel PS 70.12-8.12AIVt) Spacer Bond of the Invention
PR22.xxx.15 (12) -8.30K7-1 Advantages of the Spacer Bond of the Invention Maximum span between center
axes of columns up to 7200 mm up to 9000 mm in increments of 100 mm It is possible to choose the most optimal span for a particular building Plate width 1190 mm up to 1490 mm The opportunity to increase

sizes of openings for the pass of ventilation units and utilities Trimming the ends of the column with a maximum width up to 400 mm up to 600 mm Allows you to increase the number of storeys, strength and earthquake resistance of the building Organization of the passage of communications through the stove Holes for communications and make their way in place Holes for communications are laid at the factory or sawn or drilled to the size in place Excludes additional work at the construction site to fill the "trough". Emergencies associated with leaks under the filling material “trough” are excluded Maximum width of the hole for the pass communication 820 mm 950 mm Allows you to use
longer units with their installation across the plate. Degree of fire resistance, min REI 60 REI 120 Allows the use of slabs in buildings with I degree of fire resistance (schools, kindergartens, high-rise residential buildings) Manufacturing technology In forms Bench molding Allows you to change the length of the plates in increments of 100 mm and produce several plates of different lengths at the same time with a significant reduction in labor costs.

Used fittings A-III, At-IV according to GOST 5781-82 * A-III according to GOST 5781-82 *, 12K7-1500 according to GOST 13840-68 * The strength of the building is increased due to the use of reinforcing bars of increased viciousness, more resistant to voltage loss during fire exposure on the slab structure Construction and installation work after laying the slab in the ceiling It is necessary to fill the “trough” in the slab after installation with additional additional slab inserts. No such work Allows you to reduce the complexity of installation and reduce the time of construction of the building Plate longitudinal tensile forces 12.0 t 30.0 t Allows increasing building parameters without adding additional stiffness diaphragms Concrete grade B35 B40 Increases the strength and reliability of operation while at the same time reducing the consumption of concrete for manufacturing.

The spacer plate is made, and the connection unit of the spacer plate and the frame-link or connection frame of a prefabricated or precast-monolithic building with the spacer plate is mounted as follows:

Reinforcing meshes and frames, as well as separator inserts for securing end cuts and separating spreader plates on the stand, are placed on the clamps on the stand, and then prestressed reinforcement in the form of reinforcing ropes is passed through the bottom and slightly pulled to put them in the design position .

Then lay longitudinal reinforcing cages with embedded metal elements, a frame for the device of the hole, if necessary, sling loops and reinforcing mesh, fixing them in the design position. The boards are fixed in the design position and the reinforcing ropes are pulled to the value indicated in the working drawings, then the concrete mixture is poured, compacted and the upper surface of the plates is leveled. Further, they provide a set of concrete strength up to 90% of the design strength by any known methods.

After the concrete has set strength, tempering of prestressed reinforcement is performed and it is cut between the inserts and dividers, the separator inserts and frames are removed to form holes, the sides are folded and panels are removed from the stand, transporting them to the storage place.

Installation is carried out in accordance with the requirements of existing SNiPs and working drawings.

Before starting the installation of the frame ensure the completeness of the mounting equipment, fixtures and anchoring devices provided for by the project. During the installation of all frame elements, constant geodetic control is carried out to ensure that their position matches the design. The results of monitoring the installation of individual structures are drawn up by an executive scheme.

Installation of the building frame is carried out in cells consisting of four columns. It is recommended that the installation of the frame begin with a cell including stiffness diaphragms.

The columns of the frame are installed on the lower monolithic columns or in the foundation glasses using group or single conductors that ensure the design position of the columns by combining the column patterns with the alignment axes, after which they are verified by instrumental shooting and welded together, and the welded joints are accepted for hidden work .

Then, corrosion protection of the welded joints is carried out and the joints of the columns are monolithic with a plastic concrete mix of the design grade using press formwork, and the quality of the joints sealing is controlled by the laboratory.

After concrete reaches 70% of design strength, installation and welding of frame elements to the column is possible in the following required sequence: stiffness diaphragms, crossbars, tie plates, and then other floor slabs are installed and welded.

Installation and fastening of frame elements is carried out from conductors and from inventory mounting sites.

Installation of structures on the next floor is carried out only after a reliable design fixing of all elements of the previous floor.

The stiffness diaphragms of each floor are installed on the design-grade fine-grained concrete underlying the layer and welded together and with columns.

Installation of ceilings begins only after checking the geometric immutability of the mounted part of the building, and on the installation horizon they provide all auxiliary work, namely, monoling the joints and welding of the mounting elements to support the tie plates-spacers.

Installation of floor slabs is carried out according to the cells of the frame, which are alternately released from the struts of the columns.

The order of installation of the plates and the breakdown of the installation cells are provided for by the project.

The installation of floor slabs within each floor will be carried out in the following sequence: stacking communication slabs are laid, verified with each other and with columns, as well as with crossbars and stiffness diaphragms, if required in accordance with standard mounting units, and then the remaining panels are laid overlapping and monolithic all the seams between the elements of the overlap.

All floor panels are laid on the shelves of the crossbars or on the shelves of the diaphragms of stiffness through neoprene gaskets with a thickness of 10 mm along a layer of cement mortar of the M200 brand, laid out immediately before their installation.

Bond plates-spacers along the outer rows of columns from the inside are stacked on the shelves of the crossbars or the shelves of the diaphragms of stiffness through neoprene gaskets 10 mm thick along the layer of cement mortar of the M200 grade and welded together, with a stiffness diaphragm or with a crossbar.

From the outside, the tie plates-spacers on the outer rows of columns are supported by mounting tables MK-10, welded to the embedded parts of the columns.

The joints between the plates and the interface between the tie plate spacers with the diaphragms and crossbars at the columns are carefully sealed with fine-grained concrete of the design grade with the control of their filling, and the tolerances during the installation of structures must be taken in accordance with the instructions of the current Construction Norms and Regulations.

The use of tie plates-spacers, nodes of connection of tie plates-spacers and frame-link or link frame of a prefabricated or precast-monolithic building with link plates-spacers allows you to get a number of significant advantages compared with known designs, namely, they provide:

- simplicity of the geometric shape and design of the tie plate spacers.

- high performance in the manufacture of tie plates-spacers.

- modern, less labor-intensive and material-intensive production technology.

- the absence of additional finishing work after the installation of tie plates-spacers.

- increased fire resistance.

- ease of assembly.

- the absence of voids and cavities into which liquid can enter from the communications passing through the stove and cause rotting processes.

This simplifies the design and improves the manufacturability of the manufacture of tie plates-spacers while increasing their functionality, strength and simplifies the installation technology, simplifies the design and technology of mounting the nodes of the connection of tie plates-spacers in prefabricated and precast monolithic frames, as well as provides the possibility of building prefabricated and prefabricated monolithic buildings of increased number of storeys and increased strength and seismic stability due to the possibility of using columns with a width of pop river section up to 600 mm, the possibility of using prefabricated and prefabricated monolithic structures in the construction of residential and public buildings with the required degree of fire resistance R120, as well as the possibility of more free layout of premises in the building by increasing spans to 9.0 m while increasing the strength and rigidity of the building frame generally.

As materials in the manufacture of individual elements and parts as a whole, various materials and components commonly used in the production of building materials and in construction can be used.

Specific dimensions and individual design features of individual elements can be selected from standard sizes and the standards and Construction Norms and Regulations in force in construction.

INFORMATION SOURCES

1. "Series 1.020-1 / 87 Structures of interspecific use framework for multi-storey public buildings, industrial and auxiliary buildings of industrial enterprises" developed by the Central Scientific and Research Institute of Industrial and Commercial Buildings and Tourist Complexes, approved by the USSR State Construction Committee, protocol dated 12.12.1990, MA4- fifteen.

2. Patent RU 47398, Е04В 1/00, published 2005.08.27.

3. Patent SFRY 25452.

4. US patent 4.366.655.

5. Kornilov V.G. Frame-panel buildings of a new type. - Housing, 1986.10.

6. RF application No. 98106054/03 of April 9, 1998

7. Patent RU 2081274, E04G 23/00, Published: 1997.06.10.

8. Typical structures, products and units of buildings and structures. Series 1.465.1-3 / 80. Ribbed reinforced concrete coating plates, size 3x12 m. M., TsITP, 1981.

9. Emelyanov L.S., Karnet Yu.V. etc. Hollow multi-hollow prestressed floor slabs of bench formless molding. Housing, 1983, No. 2, pp. 11-13.

10. “Typical structures and details of buildings and structures for construction in Leningrad. Series 1.242.1 KL-1. Floor panels ribbed reinforced concrete bonded frame of public buildings. Issue 1-2. Leningrad, 1988 (prototype).

11. Patent 2194127 RU, E04B 1/22, published: 2002.12.10 (prototype).

Claims (35)

1. Coupling plate-spacer for installation on the inner rows of columns of a frame-bonded or bonded frame of a prefabricated or precast-monolithic building, containing the body of a reinforced concrete body of a bonded strut-plate with trimmings on the end sides for the passage of columns, with reinforcement and embedded metal elements for connection of the spacer plate with crossbars and other spacer plates in the frame of a prefabricated or prefabricated-monolithic building, characterized in that the body of the spacer plate is made of solid filled concrete without reinforcement, the central zone with the possibility of laying in the manufacturing process of the tie plate-spacers, cutting or drilling during installation in the central zone of the body of the tie plate-spacer through holes for the passage of ventilation units and utilities of a prefabricated or precast-monolithic building, while the connection plate - the spacer in cross section is made in a trapezoidal shape with parallel planes of the upper and lower surfaces of the spacer plate, and the side and end walls of the communication spacer plate are made beveled from the bottom up in the direction to the central part of the tie plate-spacers. 2. The connecting strut plate according to claim 1, characterized in that the trimming at the ends of the connecting strut plate is made with the possibility of passing columns of a frame-bonded or bonded frame of a prefabricated or precast-monolithic building with a cross-sectional width of up to 600 mm. 3. The tie plate-spacer according to claim 1, characterized in that it is manufactured in a length sufficient for installation in a frame-tie or tie frame of a prefabricated or precast-monolithic building with a span between center axes of up to 9000 mm. 4. The tie plate-spacer according to claim 1, characterized in that the reinforcement of the tie plate-spacer contains elements of prestressed reinforcement longitudinally located in the lateral parts of the body of the spacer plate in the form of reinforcing ropes of type ⌀12K7-1500 according to GOST 13840-68 and elements non-tensile reinforcement type A-III (A400) according to GOST 5781-82 *, as well as indirect reinforcement in the form of reinforcing meshes located in the body of the spacer plate parallel to the planes of the upper and lower surfaces of the spacer plate. 5. The connecting strut plate according to claim 1, characterized in that it is made with a protective layer of concrete from the surface of the strut plate to prestressed reinforcement of at least 6 cm with the possibility of ensuring a degree of fire resistance up to REI 120 min. 6. The spacer plate according to claim 1, characterized in that the side walls of the spacer plate contain longitudinally oriented recesses configured to transfer bending loads to adjacent spacer plates or adjacent coating or overlapping plates in a frame-bond or connection frame a prefabricated or prefabricated monolithic building by means of a prefabricated or prefabricated monolithic building stacked during installation in a frame-bonded or connected frame in the gaps between the side walls of the connecting strut plate and adjacent plates covering or overlapping the concrete mixture, which forms, after hardening in the gap with the adjacent slab, and a longitudinally oriented hard tongue mating with the adjacent slab. 7. The connecting plate-spacer according to claim 1, characterized in that it is made with the possibility of perception of longitudinal tensile forces up to 30 tons 8. The connecting plate-spacer according to claim 1, characterized in that it has a width of 148 to 150 cm, mainly 149 cm, and a height of 21 to 23 cm, mainly 22 cm 9. The spacer plate according to claim 1, characterized in that it is capable of perceiving and transmitting vertical loads on the crossbars by means of metal connecting elements, as well as with the possibility of perceiving horizontal alternating forces and transferring them by means of metal connecting elements to stiffness diaphragms and columns frame-bonded or bonded frame precast or precast-monolithic building. 10. The spacer plate according to claim 1, characterized in that the parts of the spacer plate with embedded metal connecting elements are located on the protrusions along the edges of the end sides of the spacer plate and are made of a lower height compared to the height of the central zone of the spacer plate to the height necessary for the installation of metal connecting elements, welded in the appropriate places to the crossbars and to the embedded metal elements of other connecting strut plates, with the possibility of forming a single mount zontally slab plane or the coating of bond-braced frame or Svjaseva precast or prefabricated monolithic structure after assembly, the spacer plate. 11. The spacer plate according to claim 1, characterized in that the embedded metal elements of the spacer plate are welded by means of metal connectors with the metal elements of the crossbars and the metal elements of the other spacer plates to form geometrically unchanged contour of a horizontal disk of overlapping or covering a frame-bonded or bonded frame of a prefabricated or precast-monolithic building. 12. The spacer plate according to claim 1, characterized in that it is made of heavy concrete of class B40. 13. The connection plate-spacer according to claim 1, characterized in that it is made by bench molding. 14. Bridging plate-spacer for installation on the outer columns of a frame-bonded or bonded frame of a prefabricated or prefabricated-monolithic building, containing a concrete body of a bonded bonded strut with undercuts on the end sides for passing columns along the outer rows of a frame-bonded or bonded frame prefabricated or prefabricated monolithic building, with reinforcement and embedded metal elements for connecting the strut plate with columns, crossbars and other strut plates in a frame-bonded or bonded frame of a prefabricated or prefabricated monolithic building, characterized in that the body of the bonded slab is made of a solid, concrete-filled central zone, with a cross section in the form of a rectangular trapezoid with parallel planes of the upper and lower surfaces of the strut, with one side perpendicular to the indicated planes and the other sloping from the bottom up towards the central part of the spacer plate with the other side of the spacer plate. 15. The spacer plate according to claim 14, characterized in that the trimming on the end sides of the spacer plate is made on one side of the spacer plate with the possibility of passing columns along the outer rows of a prefabricated or prefabricated monolithic frame buildings with a cross-sectional width of up to 600 mm. 16. The connecting plate-spacer according to 14, characterized in that it is made long enough to be installed in a frame-connected or connected frame of a prefabricated or precast-monolithic building with a span between center axes of up to 900 cm. 17. The connecting strut according to claim 14, characterized in that the reinforcement of the strut contains elements of prestressed reinforcement located parallel to the plane of the lower surface of the strut in the form of ⌀12K7-1500 reinforcing ropes uniformly distributed across the width of the strut 13840-68 and elements of non-tensile reinforcement type A-III (A400) longitudinally located in the lateral parts of the body at the upper surface of the spacer plate according to GOST 5781-82 *, as well as indirect reinforcement in the form of reinforcing meshes parallel to the plane m the upper and lower surfaces of the plate-spacers. 18. The connecting strut plate according to claim 14, characterized in that it is made with a protective layer of concrete from the surface of the strut plate to tensile reinforcement of at least 6 cm and with a fire resistance of up to REI 120 min. 19. The spacer plate according to claim 14, characterized in that the side of the spacer plate oriented towards the central part of the frame-link or connection frame of a prefabricated or prefabricated monolithic building comprises a longitudinally oriented recess configured to transmit bending loads to an adjacent a covering or overlapping plate in a frame-bonded or bonded frame of a prefabricated or prefabricated-monolithic building by means of a bonded spacer plate and side walls laid in the gaps between the specified side wall th adjacent plate overlapping or covering of the concrete mix, after forming a longitudinally oriented rigid hardening the key. 20. The connecting plate-spacer according to 14, characterized in that it is made with the possibility of perception of longitudinal tensile forces up to 30 tons 21. The spacer plate according to claim 14, characterized in that it has a width of 113 to 115 cm, preferably 114 cm, and a height of 21 to 23 cm, mainly 22 cm. 22. The spacer plate according to claim 14, characterized in that it is designed to transfer vertical loads on the crossbars and columns with the possibility of perceiving horizontal alternating forces and transferring them via metal connecting elements to the stiffness diaphragms and columns in a frame-coupled or connected assembly frame or prefabricated monolithic building. 23. The spacer plate according to claim 14, characterized in that the parts of the spacer plate with embedded metal connecting elements are made of a lower height compared to the height of the central zone of the spacer plate to the height necessary to install the metal connecting elements welded to the metal embedded elements of other bonded strut plates with the possibility of forming a single horizontal plane of overlap or coating in a frame-bonded or bonded frame of a prefabricated or precast monolithic building ia after mounting the spacer plate. 24. The spacer plate according to claim 14, characterized in that the embedded metal connecting elements of the spacer plate are welded by means of metal connecting elements with crossbars, columns and embedded metal elements of other spacer plates with the formation of a geometrically unchanged contour of a horizontal disk of overlapping or covering in a frame-coupled or connected frame of a prefabricated or precast-monolithic building. 25. The connecting strut according to claim 14, characterized in that it is made of heavy concrete of class B40. 26. The connecting plate-spacer according to 14, characterized in that it is made by bench molding. 27. A node for connecting strut struts along the inner rows of columns of a frame-bonded or bonded frame of a prefabricated or precast-monolithic building, comprising a column mounted on a column or rigidly connected to a column with crossbars with shelves and embedded metal elements, mounted on shelves with crossbars and made of reinforced concrete, strut plates with trimmings on the end sides for the passage of the column and embedded metal elements, characterized in that the bonded strut plates are made with continuous filling concrete without reinforcement by the central zone with the possibility of laying during the manufacturing of slabs, cutting or drilling during installation in the central zone of the body of the connecting slabs of the struts through holes for the passage of ventilation units and utilities of a prefabricated or precast-monolithic building - spacers are installed on the shelves of the crossbars along the layer of cement-sand mortar and are connected to each other and the crossbars by means of metal connecting elements welded to the embedded metal tallic elements plate-braces and beams to form a geometrically invariable contour horizontal disc overlap or cover in frame-Svjaseva Svjaseva frame or precast or prefabricated monolithic building. 28. The connection node of the connection plate-struts according to item 27, wherein the connection plate-struts are made according to any one of claims 1 to 13. 29. The connection node of the connecting strut struts according to claim 27, characterized in that the gaps between the end walls of the strut struts, the column and the crossbars are filled with concrete mixture, ensuring that after it hardens the transmission of vertical loads to the crossbars, as well as with the possibility of perception by means of metal connecting elements of horizontal alternating forces and transferring them to stiffness diaphragms and columns of a frame-bonded or bonded frame of a prefabricated or precast-monolithic building. 30. A node for connecting tie plates-spacers along the outer rows of columns of a frame-tie or tie frame of a prefabricated or prefabricated-monolithic building, comprising a column with a console or with metal supporting tables mounted on the sides of the column in the direction of contact of the tie plates-spacers, mounted on the cantilever of the column or a bolt rigidly connected to it with embedded metal elements mounted on the shelves of the bolt and on the metal support tables and made of reinforced concrete strut plates with trimmings on the end sides for the passage of the column and embedded metal elements, characterized in that the tie plates-spacers are made with a solid concrete-filled central zone with a cross section in the form of a rectangular trapezoid with parallel planes of the upper and lower surfaces of the connection plate-spacers, with one perpendicular to the indicated planes with the side and another beveled upward from the bottom towards the center of the spacer plate with the other side of the spacer plate and end by shafts made oblique from the bottom up towards the central part of the strut plate, while the column, tie strut plates and crossbar are connected to each other by metal connecting elements welded to the embedded metal elements of the strut plate, crossbar and column with the formation of geometrically unchanged contour of a horizontal disk of overlapping or covering in a frame-coupled or connected frame of a prefabricated or precast-monolithic building. 31. The connection node of the connection plate struts according to item 30, wherein the connection plate struts are made according to any one of paragraphs.14-26. 32. The junction plate connection struts according to claim 30, characterized in that the gaps between the end walls of the tie struts, the column and the crossbar are filled with concrete mixture, ensuring that after it hardens the transmission of vertical loads to the crossbars, as well as with the possibility of perception by metal connecting elements of horizontal alternating forces and transferring them to stiffness diaphragms and columns of a frame-bonded or bonded frame of a prefabricated or precast-monolithic building, with the side perpendicular to the planes of the upper and lower surfaces of the slab is located in the same plane with the outer side of the columns along the outer row of the frame-link or link frame of the prefabricated or precast-monolithic building. 33. Frame-bonded or bonded frame of a prefabricated or prefabricated-monolithic building, containing internal and external rows of columns of a frame-bonded or bonded frame of a prefabricated or prefabricated-monolithic building and columns mounted with columns with embedded metal elements, as well as mounted on columns and crossbars and connection plates-spacers made of reinforced concrete with trimmings on the end sides for passing columns and embedded metal elements, characterized in that the connection plates-spacers on the inner row the columns are made with a solid central zone filled with concrete without reinforcement with the possibility of laying during the manufacturing of the spacer plate, cutting or drilling during installation in the central body zone of the connecting spacer plates of the through holes for the passage of ventilation units and utilities of a prefabricated or prefabricated monolithic building, moreover, the connecting struts-spacers along the inner rows of columns are installed on the shelves of the crossbars along the layer of cement-sand mortar and are connected to each other and the crossbars by means of metallic of connecting elements welded to embedded metal elements of spacer plates and crossbars with the formation of a geometrically unchanged contour of the horizontal disk of overlapping or coating in a frame-bonded or bonded frame of a prefabricated or prefabricated-monolithic building, and bonded spacer plates along the outer rows of columns are made with solid filled with concrete with a central zone with a cross section in the form of a rectangular trapezoid with parallel planes of the upper and lower surfaces of the strut plate, with one perp sidewise to the indicated planes, while the other side of the tie struts and the end walls of the tie struts are slanted from the bottom up towards the central parts of the tie struts, the tie struts along the outer rows of columns and crossbars by means of metal connecting elements welded to embedded metal elements of strut plates, crossbars and columns with the formation of a geometrically unchanged contour of the horizontal disk overlapping or covering in or frame-Svjaseva Svjaseva frame, prefabricated or precast-monolithic building. 34. The frame-bonded or bonded frame of a prefabricated or prefabricated-monolithic building according to claim 33, characterized in that the tie struts on the inner rows of the columns are made according to any one of claims 1 to 13. 35. The frame-bonded or bonded frame of a prefabricated or prefabricated-monolithic building according to claim 33, characterized in that the tie-struts along the outer rows of columns are made according to any one of paragraphs.14-26.