RU161468U1 - REINFORCED CONCRETE MULTI-STOREY BUILDING - Google Patents

Abstract

The utility model relates to the field of construction and can be used in the construction of residential and public buildings with high floors.

The utility model is aimed at creating a structural frame system for the construction of buildings with high floors, using prefabricated load-bearing elements, which ensures high reliability of the frame elements, increased rigidity of the frame at the installation stage and during operation, and the aesthetic attractiveness of residential premises due to the hidden crossbar.

The result is achieved in that in the reinforced concrete frame of a multi-storey building, including prefabricated reinforced concrete columns with consoles, bearing crossbars of the T-section, having undercuts at the ends, for supporting columns on the console, dowels on the side surfaces, reinforcement outlets at the ends in the upper and lower zones and embedded parts on the side faces of the undercut, hollow core slabs with rectangular undercuts at the ends to support the crossbar and the monolithic concrete, which forms concrete dowels in hollow voids of floor slabs, there are contour beams of rectangular cross-section, which serve as load-bearing and connecting stiffeners, which are located in the direction perpendicular to the crossbars and have reinforcing joints for the device of nodal connection with the precast concrete column in the support part of the upper cutting zone, and the width of the rectangular section of contour beams does not exceed the thickness of the building envelope.

The result is also achieved by the fact that prefabricated reinforced concrete columns on two opposite sides have dowels in the level of multi-hollow floor slabs, embedded parts with holes located at the same level with the outlets of the contour beam, and the embedded parts themselves are located on the same level and in the same plane with embedded parts of the crossbar, and metal tables for installing contour beams, and after installing the crossbar on the console of the precast concrete column and contour beams on the metal table precast concrete pillars, i.e. in mutually perpendicular directions, the outlets of the two contour beams in adjacent spans are connected by a reinforcing rod passed through the column body at the location of the hole of the embedded part of the precast concrete column, and the embedded parts of the crossbar and embedded parts of the precast concrete column are connected by plates by welding.

The result is also achieved by the fact that the interface unit of the precast concrete column with the crossbar and contour beams is monolithic at the same time as the interface points of the multi-hollow floor slab with the crossbar and the precast concrete column with the crossbar, creating a rigid frame for the overlap disk formed by two mutually perpendicular contour elements: the crossbar and beam, and monolithic concrete at a distance of 1/4 span from the precast concrete column protrudes above the plane of the slab to the level of the crossbar, i.e. by the thickness of the screed, which allows to increase the reference cross-section of the crossbar, increasing its bearing capacity.

The result is also achieved by the fact that prefabricated reinforced concrete columns with consoles can be made on one or several floors and can have different cross-sectional shapes - rectangular, for lower floors, which are characterized by a high level of longitudinal forces, and square, and the joint of prefabricated reinforced concrete columns the height is made in the form of a flat joint in the middle zone of the floor section of prefabricated reinforced concrete columns.

The proposed design of a reinforced concrete frame allows, due to the introduction of additional horizontal elements, contour beams, and by monolinging the frame mating nodes, to increase the reliability and rigidity of the frame, as well as due to the possibility of increasing the cross-sectional area of the columns, significantly increase their bearing capacity and increase the number of storeys, This aesthetic appeal of the premises due to the hidden crossbar, short construction time and the possibility of manufacturing elements of the frame Asa with maximum use of the capacities of existing factories of reinforced concrete products through the use of prefabricated load-bearing elements.

Description

The utility model relates to the field of construction and can be used in the construction of residential and public buildings with high floors.

A typical communication frame of the 1.020.1 / 87 series is known, including columns with countersunk consoles, on which crossbars of the T-section are supported. Crossbars and hollow slabs are pre-stressed, and the joint of crossbars with columns is hinged.

The disadvantages are the lack of strength and rigidity of the nodal joints, the limited planning capabilities of the frame due to the protruding shelves of the crossbars.

Known prefabricated reinforced concrete frame of the building with an overlapping of multi-hollow plates, containing crossbars installed on the supporting elements of the columns with shelves for supporting the floor slabs, characterized in that the floor slabs are molded with undercuts-recesses forming two console ends on the opposite sides of the console plate for support on the crossbar shelves , while the height of the shelves of the crossbar is made commensurate with the depth in the thickness of the plate mating with the shelf undercut-notches (copyright certificate of the Russian Federation No. 47398, 04.04.2005, CL. E04B 1/00).

The disadvantages of the prefabricated reinforced concrete frame of the building with overlapping of hollow core slabs are the lack of rigid nodal joints of the frame, as well as the reduced cross-sectional area of the load-bearing beam, which leads to insufficient strength of the element and the weakened supporting section of the slab due to a decrease in the height of the supporting section by half and the area supporting the slab on the support, due to the fact that when there is a trimming-notch, the bearing of the slab falls on the hollow space.

The closest is a reinforced concrete frame with a flat ceiling, including prefabricated reinforced concrete columns with consoles, bearing crossbars of the T-section with undercuts at the ends, for supporting columns on the console, a flooring made from multi-hollow slabs and monolithic concrete. Hollow core slabs on the end faces have rectangular cuts to a height of not more than half the height of the slab. The geometric dimensions of the T-section crossbar, the shelves of which are located below, are proportional to the size of the undercuts of the multi-hollow floor slab, (copyright certificate of the Russian Federation No. 130328, 02/18/2013, Cl. E04B 1/18).

The disadvantages of this frame, discovered during the design and installation process, are:

- reduced spatial rigidity of the frame at the installation stage due to the fact that the crossbars are located in one direction, which leads to the formation of initial cracks in the nodes of the frame and as a result to a decrease in the rigidity of the frame as a whole;

- the impossibility, due to the constant size of the cross-section of the columns along the height of the building, of a significant increase in their bearing capacity, which in turn limits the number of storeys of the building.

The utility model is aimed at creating a structural frame system for the construction of buildings with high floors, using prefabricated load-bearing elements, which ensures high reliability of the frame elements, increased rigidity of the frame at the installation stage and during operation, and the aesthetic attractiveness of residential premises due to the hidden crossbar.

The result is achieved in that in the reinforced concrete frame of a multi-storey building, including prefabricated reinforced concrete columns with consoles, bearing crossbars of the T-section, having undercuts at the ends, for supporting columns on the console, dowels on the side surfaces, reinforcement outlets at the ends in the upper and lower zones and embedded parts on the side faces of the undercut, hollow core slabs with rectangular undercuts at the ends to support the crossbar and the monolithic concrete, which forms concrete dowels in hollow voids of floor slabs, there are contour beams of rectangular cross-section, which serve as load-bearing and connecting stiffeners, which are located in the direction perpendicular to the crossbars and have reinforcing joints for the device of nodal connection with the precast concrete column in the support part of the upper cutting zone, and the width of the rectangular section of contour beams does not exceed the thickness of the building envelope.

The result is also achieved by the fact that prefabricated reinforced concrete columns on two opposite sides have dowels in the level of multi-hollow floor slabs, embedded parts with holes located at the same level with the outlets of the contour beam, and the embedded parts themselves are located on the same level and in the same plane with embedded parts of the crossbar, and metal tables for installing contour beams, and after installing the crossbar on the console of the precast concrete column and contour beams on the metal table precast concrete pillars, i.e. in mutually perpendicular directions, the outlets of the two contour beams in adjacent spans are connected by a reinforcing rod passed through the column body at the location of the hole of the embedded part of the precast concrete column, and the embedded parts of the crossbar and embedded parts of the precast concrete column are connected by plates by welding.

The result is also achieved by the fact that the interface unit of the precast concrete column with the crossbar and contour beams is monolithic at the same time as the interface points of the multi-hollow floor slab with the crossbar and the precast concrete column with the crossbar, creating a rigid frame for the overlap disk formed by two mutually perpendicular contour elements: the crossbar and beam, and monolithic concrete at a distance of 1/4 span from the precast concrete column protrudes above the plane of the slab to the level of the crossbar, i.e. by the thickness of the screed, which allows to increase the reference cross-section of the crossbar, increasing its bearing capacity.

The result is also achieved by the fact that prefabricated reinforced concrete columns with consoles can be made on one or several floors and can have different cross-sectional shapes - rectangular, for lower floors, which are characterized by a high level of longitudinal forces, and square, and the joint of prefabricated reinforced concrete columns the height is made in the form of a flat joint in the middle zone of the floor section of prefabricated reinforced concrete columns.

A utility model is illustrated in the drawings. In FIG. 1 shows a fragment of the reinforced concrete frame of a multi-story building; in FIG. 2 is a section 1-1 of FIG. one; in FIG. 3 is a section 2-2 of FIG. one; in FIG. 4 shows a node for coupling a precast concrete column with a crossbar and contour beams; in FIG. 5 is a section 3-3 of FIG. 4, supporting the contour beams on the metal tables of the precast concrete column; in FIG. 6 is a section 4-4 of FIG. 4, the bearing of the supporting crossbar to the shelf of the precast concrete column.

The reinforced concrete frame of a multi-storey building includes prefabricated reinforced concrete columns 1 with consoles, bearing crossbars 2 of T-section with undercuts at the ends, contour beams 3 of rectangular section, multi-hollow floor slabs 4 and monolithic concrete 5. The bearing crossbar 2 of the T-section, the shelves of which are located below, has dowels 6 on the lateral surfaces, releases of reinforcement 7 at the ends in the upper and lower zones and embedded parts 8 on the lateral faces of the trim. Contour beams 3 of rectangular cross section have undercut in the upper zone of the support part and reinforcement outlets 9. Multihollow slabs 4 on the end faces have rectangular clippings commensurate with the geometric dimensions of the shelves of the supporting crossbar 2, and when the multihollow slab 4 is supported on the shelf of the crossbar 2, the lower face multi-hollow floor slab 4 is at the same level with the lower edge of the crossbar 2, and the upper edge of the crossbar 2 protrudes above the upper face of the multi-hollow floor slab 4 by the thickness of the screed t. Monolithic concrete 5 forms concrete keys 9 in the voids of multi-hollow floor slabs.

Prefabricated reinforced concrete columns 1 on two opposite sides have keys 11 in the level of multi-hollow floor slabs 4, embedded parts 12 with holes located at the same level with the outlets of the reinforcement 9 of the contour beam 3 and metal tables 13 for installing the contour beams 3. Outlets of the reinforcement 9 of two contour beams 3 in adjacent spans are connected by a reinforcing bar 14 passed through the body of the column at the location of the hole of the embedded part 12 of the precast concrete column 1, and the embedded parts 8 of the crossbar 2 and the embedded details 12 of the precast concrete column 1 are connected by plates by welding.

Monolithic concrete of 5 carcass mating nodes creates a rigid frame for the flooring disk formed by two mutually perpendicular elements: crossbar 2 and contour beam 3. Concrete monolithic concrete at a distance of 1/4 span L from the precast concrete column 1 protrudes above the plane of the multi-hollow floor slab 4 to the level of the crossbar 2, i.e. by the thickness of the screed t, which allows to increase the reference cross-section of the crossbar 2, increasing its bearing capacity.

The proposed design of a reinforced concrete frame allows, due to the introduction of additional horizontal elements, contour beams, and by monolinging the frame mating nodes, to increase the reliability and rigidity of the frame, as well as due to the possibility of increasing the cross-sectional area of the columns, significantly increase their bearing capacity and increase the number of storeys, This aesthetic appeal of the premises due to the hidden crossbar, short construction time and the possibility of manufacturing elements of the frame Asa with maximum use of the capacities of existing factories of reinforced concrete products through the use of prefabricated load-bearing elements.

Claims (4)

1. The reinforced concrete frame of a multi-storey building, including prefabricated reinforced concrete columns with consoles, bearing crossbars of the T-section, having trimmings at the ends, for supporting columns on the console, dowels on the side surfaces, releases of reinforcement on the ends in the upper and lower zones and embedded parts on the side cutting edges, hollow core slabs with rectangular undercuts at the ends to support the crossbar and the monolithic concrete, which forms concrete dowels in a multi-hollow floor slab, characterized in that then, to increase the spatial rigidity of the frame in the direction perpendicular to the crossbars, rectangular contour beams are located, having reinforcements and outlets in the supporting part of the upper zone, for nodal connection with a precast reinforced concrete column, the width of the rectangular section of the contour beams not exceeding the thickness of the building envelope. 2. The reinforced concrete frame of the multi-storey building according to claim 1, characterized in that the precast concrete columns on two opposite sides have dowels in the level of multi-hollow floor slabs, embedded parts with holes located at the same level with the outlets of the contour beam, and the embedded parts themselves located on the same level and in the same plane with the embedded parts of the crossbar, and metal tables for installing contour beams, and after installing the crossbar on the console of the precast concrete column and con urnyh beams on metal tables precast concrete columns, ie, in mutually perpendicular directions, the outlets of the two contour beams in adjacent spans are connected by a reinforcing rod passed through the column body at the location of the hole of the embedded part of the precast concrete column, and the embedded parts of the crossbar and embedded parts of the precast concrete column are connected by plates by welding.            3. The reinforced concrete frame of the multi-storey building according to claim 1, characterized in that the interface unit of the precast concrete column with the crossbar and contour beams is monolithic at the same time as the interface points of the multi-hollow floor slab with the crossbar and the precast concrete column with the crossbar, creating a rigid frame for the overlap disk formed two mutually perpendicular elements: a crossbar and a contour beam, and the monolithic concrete at a distance of 1/4 span from the precast concrete column protrudes above the plane of the slab Iya to the level of the crossbar, i.e. by the thickness of the screed, which allows to increase the reference cross-section of the crossbar, increasing its bearing capacity. 4. The reinforced concrete frame of the multi-storey building according to claim 1, characterized in that the precast concrete columns with consoles can be made on one or several floors and can have different cross-sectional shapes - rectangular and square, and the joint of the precast concrete columns in height is made in the form a flat joint in the middle zone of the floor section of precast concrete columns.

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