RU2755669C1 - Precast-monolithic reinforced concrete frame of multi-storey building - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention relates to construction, in particular to precast monolithic reinforced concrete frame buildings. The prestressed reinforcement is installed in the upper monolithic part of the girder and passes through two or more spans of the building along its entire length and is fixed on traverses resting on the edges of the precast reinforced concrete column; in the upper monolithic part of the girder, an unstressed working reinforcement is also installed, the rods of which are the same as and unstressed rods coming out of the precast part are bent crosswise down and up, respectively, and connected to the longitudinal rods of the column, in precast monolithic prestressed girders and precast reinforced concrete columns, indirect reinforcement in the form of meshes is installed.

EFFECT: creation of a frame-bar reinforced concrete frame of a multi-storey building, including prefabricated reinforced concrete columns with holes at the level of the floor disc, precast-monolithic prestressed in the lower prefabricated part of the girders, having outlets of longitudinal prestressed reinforcement and outlets of transverse reinforcement from the upper plane of the precast part, trough-shaped prefabricated profile parts of the girder and prefabricated hollow-core slabs of the floor disc with a gap between the ends of the slabs, which, together with the concrete holes in the columns, the outlets of the transverse reinforcement installed in the prefabricated part of the girder, the outlets of the longitudinal reinforcement of the girders and the space between the ends of the slabs with dowels, are monolithic at the same time.

1 cl, 7 dwg

Description

The proposed invention relates to the field of construction and is intended to create load-bearing multi-storey frames of residential and civil buildings that resist special emergency impacts and contribute to an increase in rigidity and bearing capacity in case of a sudden redistribution of power flows in the building frame.

Known prefabricated-monolithic frame of a multi-storey building (see Pat. No. 2226593, Russian Federation, IPC E04B 1/18, publ. 10.04.2004), which includes prefabricated or monolithic columns and flat precast-monolithic floor disks formed by monolithic reinforced concrete carriers and braced beams, combined in the overlap plane at the nodes of connection with the columns into closed frame cells, within which prefabricated reinforced concrete slabs are placed in groups, interconnected by inter-slab seams and resting at the ends on load-bearing beams, continuous load-bearing beams in each span between the columns are made with transverse sections of variable width, varying from the largest in the columns to the smallest in the middle of the span, and, accordingly, the prefabricated slabs within each cell are made with a length that is the smallest in the outermost slabs at the tie girders and the largest in the slabs located in the middle of each cell.

The disadvantage of such a constructive solution of the precast-monolithic frame of the building is that the outlets of the reinforcement of the load-bearing and tie beams do not have a connection with the working reinforcement of the columns, which does not provide the overall spatial flows in the wireframe elements.

Known precast-monolithic reinforced concrete frame of the multi-storey building "Kazan-XXIV" (see Pat. On PM No. 45415, Russian Federation, IPC E04B 1/20, publ. 27.12.2004), which includes prefabricated reinforced concrete columns with holes in the floor level and a curvilinear channel in the lower part of the storey section of columns, made on several storeys, having different cross-sectional shapes: square, rectangular and angular while maintaining the basic size of the core of the section, prefabricated girders with reinforcement outlets on the upper edge and at the ends, and on the upper edge of the supporting part rectangular slabs for laying mounting support reinforcement, and hollow-core floor slabs, the end surfaces of which along the entire height of the slab are made inclined to the plane of the slab without fractures with an angle of inclination of 14 ÷ 16 °, the column joint along the height is made in the form of a plug connection, while the ends of the columns have outlets fittings and grooves, which include fittings outlets.

The disadvantage of the prefabricated monolithic frame "Kazan-XXIV" is also the absence in the frame of rigid connections of the longitudinal reinforcement of the bearing girders with the working reinforcement of the columns, which, when the force flows in the frame elements are changed when one of the columns of the first floor is removed under such girders, it turns the structural system into a variable one.

The closest in purpose and achieved effect is the precast-monolithic reinforced concrete frame of the multi-storey building "Moskovia" (see Pat. No. 2250966, Russian Federation, IPC E04B 1/20, published 27.04.2005, Bul. No. 12), which includes prefabricated reinforced concrete columns with holes in the floor level, having continuous longitudinal reinforcement with prestressed reinforcement, including within the openings in the floor level, where the reinforcement is passed through thick-walled pipes with steel base plates and launched into the body for an anchorage length, prefabricated prestressed girders, having horizontal triangular recesses on the end faces, floor slabs with a gap between their ends, monolithic together with reinforcing outlets from the prefabricated frame elements released into them.

The disadvantage of this frame solution is the absence of outlets-bends of reinforcement from the girder to the column, which is why the girder-column interface cannot perceive alternating transverse forces and moments.

The technical result, which the invention is aimed at, consists in creating a precast-monolithic reinforced concrete frame of a multi-storey building that resists special emergency influences and contributes to an increase in rigidity and bearing capacity in the event of a sudden redistribution of power flows in the building frame.

The technical result is achieved by the fact that in the precast-monolithic reinforced concrete frame of a multi-storey building, including prefabricated reinforced concrete columns with holes in the level of the floor disc, precast monolithic prestressed in the lower prefabricated part of the girders having outlets of longitudinal prestressed reinforcement and outlets of transverse reinforcement from the upper plane prefabricated part, trough-shaped profile of the prefabricated part of the girder and prefabricated hollow-core slabs of the floor disc with a gap between the ends of the slabs, which, together with the concrete holes in the columns, outlets of the transverse reinforcement installed in the prefabricated part of the girder, outlets of the longitudinal reinforcement of the girders and the space between the ends of the slabs with dowels , are monolithic at the same time, prestressed reinforcement is installed in the upper monolithic part of the girder and passes through two or more spans of the building along its entire length and is fixed on traverses resting on the edges of the precast reinforced concrete column, in addition, in the upper monolith The unstressed working reinforcement is also installed in the bulkhead section of the girder, the rods of which, like the unstressed rebars coming out of the lower prefabricated part, cross bent down and up, respectively, and are connected to the longitudinal rods of the column, and in precast monolithic prestressed girders and precast reinforced concrete columns indirect reinforcement in the form of meshes is installed.

The essence of the invention is illustrated by drawings, where FIG. 1 shows a section of a precast-monolithic reinforced concrete frame of a multi-storey building, Fig. 2 shows a fragment of the plan of the building frame; Fig. 3, 4 show sections 1-1, 2-2, Fig. 5 shows the unit for supporting the bearing girders on the column, the diagram of the anchoring of the prestressed reinforcement (unit A), Fig. 6 shows section 3-3; FIG. 7 shows the junction point of precast-monolithic girders and columns of the building frame (node B).

The frame frame of the structural system of the building (Fig. 1-4) includes prefabricated reinforced concrete columns 1, 2 with holes and exposure of longitudinal reinforcing bars 3 at the level of the floor disc, precast-monolithic prestressed in the lower prefabricated part of the crossbars 4, 5, having outlets of the longitudinal pre- strained reinforcement 6, 7 and outlets of transverse reinforcement 8 from the upper plane of the precast part, trough-shaped profile of the precast part of the girder (section 2-2) and prefabricated hollow-core slabs of the floor disc 9 with a gap between the ends of the slabs, which, together with the concrete holes in the columns, outlets of the transverse reinforcement 8, installed in the prefabricated part of the girder, outlets of the longitudinal reinforcement girders 10, 11 and the space between the ends of the slabs with dowels, are monolithic at the same time.

The performance of the presented structural system of the frame frame of a multi-storey building is ensured as follows. Shutdown from work with a special emergency impact of any of the columns 2 of the first floor of the building, which leads to a sharp redistribution of power flows in the building frame and to an increase in bending moments in all load-bearing elements of the building frame. The bends of the working unstressed rods 10, 11 from the precast and monolithic parts of the girder and their combination with the working unstressed rods 3 of the column, as well as the device of prestressed reinforcement 6, 7 for two or more spans and the installation in the girder and the column of indirect reinforcement in the form of grids 12 increase the strength concrete in the junction zone of the girder and the column and ensure the continuity and joint operation of the closed loops "girder-column" in the building frame in case of a sudden change in power flows in it.

The structures of precast-monolithic girders are combined into a single frame-rod system (node A) by installing prestressed reinforcing bars 6 in the monolithic part, the tension of which is carried out on special traverses 13, resting on embedded parts in the form of corners 14, 15. Space of the trough-shaped profile prefabricated part of the girder and prefabricated hollow-core slabs of the floor disc with a gap between the ends of the slabs, which, together with the concrete holes in the columns, outlets of the transverse reinforcement 8 installed in the prefabricated part of the girder, outlets of the longitudinal reinforcement of the girders 10, 11 and the space between the ends of the slabs with dowels, monolithic at the same time. The described combinations of all elements in a single frame-rod system ensure the joint operation of all elements of the building frame with alternating shear forces and bending moments caused by a sudden change in force flows from the removal of any of the columns of the 2nd floor.

Installation of prestressed reinforcement in the building frame in the direction of load-bearing girders, mixed (unstressed and prestressed) reinforcement in the monolithic part of the girders and cross-bent unstressed reinforcing bars from the monolithic and prefabricated parts of the girders provide high overall spatial rigidity of the precast-monolithic frame and exclude its geometric invariable it contains a local collapse pattern over any of the removed columns of the first floor.

Thus, the created prefabricated monolithic frame of a multi-storey building ensures its geometric invariability and redistribution of efforts in the spatial system of the frame in the event that one of the load-bearing columns of the first floor of the building is turned off.

Claims (1)

Precast-monolithic reinforced concrete frame of a multi-storey building, including prefabricated reinforced concrete columns with holes in the level of the floor disc, precast-monolithic prestressed in the lower prefabricated part of the girders, having outlets of longitudinal prestressed reinforcement and outlets of transverse reinforcement from the upper plane of the precast part, trough-shaped profile of the prefabricated part girders and precast hollow-core slabs of the floor disc with a gap between the ends of the slabs, which, together with the concrete holes in the columns, the outlets of the transverse reinforcement installed in the prefabricated part of the girder, the outlets of the longitudinal reinforcement of the girders and the space between the ends of the slabs with dowels, are monolithic at the same time, differing in that, that prestressed reinforcement is installed in the upper monolithic part of the girder and passes through two or more spans of the building along its entire length and is fixed on traverses resting on the edges of the precast reinforced concrete column, moreover, in the upper monolithic part of the girder, t Also unstressed working reinforcement, the bars of which, like the unstressed bars coming out of the lower precast part, are cross-bent down and up, respectively, and connected to the longitudinal bars of the column, and in precast-monolithic prestressed girders and precast reinforced concrete columns, indirect reinforcement is installed in the form of grids.

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