EA010319B1 - Combined structural system of earth-proof multistorey building - Google Patents

Abstract

The invention relates to structural systems of multistorey buildings of higher seismic resistance.The system comprises a centropositioned bearing structure extending for the whole buildings height, a jointed frame on reinforced concrete pillars surrounding the bearing structure and flat one-piece for storey flooring panels, wherein at each storey the bearing structure is made up from a system of cages adjoining each other having closed contours of lateral sections forming a block. Each block cage is a cast, continuous structure formed from a set of cast blocks interconnected therebetween forming a multistage closed cast structure extending for the building height.A cast block is formed by flooring panels and cast walls common for adjacent cages thus forming a closed structure.Butts of cast block walls are embodied as connecting elements reinforced by vertical reinforcement rods extending for the building height.Flexural-torsional stiffness of the structural system is enhanced.

Description

The invention relates to structural systems of multi-storey buildings erected in areas of high seismicity (9 points).

Known combined structural systems, including vertical volume-dimensional supporting structures in combination with the structures of other structural systems. In such combined structural systems, the advantages of the specified vertical volumetric-spatial structure are used, which has a closed cross-section contour and, in some cases, constructive filling.

Thus, in a combined structural system, the core of stiffness - the framework of a centrally located volume-spatial supporting structure is presented as a hollow core of stiffness with a closed cross-section contour in combination with the core columns of the hinge framework that are integral to the floor, which combine all vertical structures in one constructive system (ed. mon. 8I 853068, Е04Н 1/00, 1981).

The combined structural system of a seismic multi-storey building is also known, in which the centrally located three-dimensional supporting structure is presented in the form of a cellular structure with columns connected to each other by steel and reinforced concrete bracing in combination with the columns of the hinge frame surrounding this cellular structure (AM patent 580 A2, Е04Н 9/02, 1999).

The closest in purpose and technical nature of the claimed invention is a combined structural system of a seismic multi-storey building, in which the centrally located three-dimensional supporting structure is presented in the form of a cellular box structure composed of a set of adjacent cross-sectional outlines of cells, columns, stiffness bracing and floor slabs in combination with the columns surrounding this cellular structure we have a hinged frame (application AM P20060213, Е04Н 9/02, published 01.02.2007).

Thus, the known solutions of the combined structural system of a building are based on a generalization of the experience of using the advantages of closed-loop structures, in particular, having a cellular structure. However, in terms of their carrying capacity, they do not meet the requirements for a constructive system of a building in a city building of a higher number of floors - up to 25 floors, in the high seismicity zone - 9 points.

The present invention is to increase the resilience of the structural system of the building horizontal and vertical loads by increasing its flexural-torsional stiffness.

The essence of the invention lies in the fact that in a combined structural system of a seismic resistant multi-storey building containing a centrally located vertical space-dimensional carrier structure for the entire height of the building, a hinged frame on reinforced concrete columns surrounding the volume-spatial carrier structure and flat floor slabs that are integral to the floor, and vertical volume - the spatial bearing structure on each of the floors of the building is made up of a set of adjacent cells with a lock each of the cells of the block is made of volumetric, continuous, monolithic, height to the floor, and the vertical volume-spatial supporting structure of the building is formed of a set of interconnected monolithic solid blocks that form a multi-level closed monolithic structure height on the whole building.

The invention also consists in the fact that the volumetric continuous monolithic block is formed by upper and lower floor slabs and monolithic walls common to adjacent cells, forming a closed continuous structure, and the wall junctions of the continuous monolithic block are made in the form of connecting elements reinforced with vertical continuous reinforcement on the entire height of the building and the transverse reinforcement in the form of ring clamps.

Another essence of the invention is that in an embodiment, the vertical volume-spatial support structure has a polygon shape in cross section, and the transverse reinforcement of adjacent walls of adjacent cells is connected in the connecting element at an angle to each other that is different from the direct one.

The essence of the invention also includes the fact that the walls of the monolithic blocks above the openings form with the upper slab a Tavra cross section, and the height of the bridge above the opening includes the thickness of the overlap, and the thickness of the walls that make up the outer contour of the volume-dimensional supporting structure exceeds 1 3-2 times.

The invention also consists in the fact that flat floor slabs, one-piece on a floor, are made in monolithic reinforced concrete and are supported on columns of a hinged frame over the entire cross-sectional surface of these columns, which, in turn, are also made in monolithic reinforced concrete with upper and lower floor slabs and reinforced with continuous vertical reinforcement over the entire height of the building.

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The invention is illustrated by drawings, where:

in fig. 1 schematically shows a general view of the system at the stage of completion of the construction of the next floor;

in fig. 2 - the same is shown in the plan;

in fig. 3-5 shows cross-sections of the types of nodes of the junction of the walls of the continuous monolithic block, on which corner, intermediate and central connecting elements are presented, respectively;

in fig. 6 shows a cross-section of the connecting element of the walls of monolithic blocks for the embodiment, when the volume-spatial supporting structure has the shape of a polygon in cross section;

in fig. 7 shows a fragment of a longitudinal section of the proposed constructive system, which shows the joints of the columns of the hinge frame and the connecting elements of the walls of the continuous monolithic block with the floor slab;

in fig. 8 and 9 in two projections shows the scheme of reinforcement of a vertical supporting structure with apertures in the walls of continuous monolithic blocks;

in fig. 10 shows a cross section of a web of a T-section, above the opening in the wall of the monolithic block.

The proposed structural system contains a centrally located vertical volume-spatial supporting structure 1 for the entire height of the building, a hinged frame on reinforced concrete columns 2 surrounding the spatial-spatial supporting structure, and flat floor slabs, one piece on the floor. The vertical volume-spatial supporting structure on each of the floors of the building is made up of a set of adjacent cells 4 with closed cross-section contours forming a floor block 5. Each of cells 4 is made of solid, continuous, monolithic, height to the floor, and vertical volume the spatial bearing structure of the building is formed from a set of interconnected bulk continuous monolithic blocks 5, forming a multi-tier closed monolithic structure with a height to the whole building .

Bulk continuous monolithic block 5 is formed by plates 3 of the upper and lower ceilings and monolithic walls 6, common to adjacent cells 4, forming a closed continuous structure.

The junction of the walls of the 6 continuous monolithic block 5 is made in the form of a connecting element 7. The connecting elements 7 are reinforced with vertical continuous reinforcement 8 to the entire height of the building and the transverse reinforcement 9 in the form of ring clamps. The lower ends of the vertical reinforcement 8 are embedded in the foundation 10 of the building. The walls 6 are reinforced with vertical continuous reinforcement 11 for the entire height of the building and transverse reinforcement 12. The lower ends of the vertical reinforcement 11 are embedded in the foundation of the building. Walls 6 and connecting elements 7 are made on design marks using industrial formwork.

In embodiments of buildings, the vertical volumetric spatial structure may have a polygon shape in cross section. The corresponding polygonal shape of the supporting structure is inherent in buildings of complex, including radial configuration, where the polygon can be either convex or concave. In these cases, the transverse reinforcement 12 of the adjacent walls of 6 adjacent cells is connected in the connecting element 7 at an angle to each other that is different from the direct one (Fig. 6), which in the case of a combined column would be difficult to implement.

The openings 13 in the walls 6 necessitate the reinforcement of the bridges over the openings, as shown in FIG. 8. At the same time, the lintel above the opening includes the overlap thickness 3 and has a T-section, as shown in FIG. 10. This increases the flexural-torsional stiffness of the proposed structural system.

The thickness of the walls 6, constituting the external contour of the block 5, may exceed the thickness of the internal walls. So, if, according to current regulations, the minimum wall thickness is 16 cm, the wall entering the outer contour of the block can be up to 25 cm thick or more, i.e. exceed 1.3-2 times, depending on the required stiffness of the supporting structure.

Flat floor slabs 3, one-piece on the floor, are made in monolithic reinforced concrete, reinforced with longitudinal 14 and transverse 15 reinforcement (Fig. 7, 8 and 10) and are supported on columns 2 of the hinge frame across the entire cross-sectional surface of these columns. Floor slabs are produced at design elevations using industrial formwork.

Columns 2 of the articulated frame are made in monolithic reinforced concrete with upper and lower plates 3 floors, reinforced with transverse 16 and vertical 17 reinforcement, the lower ends of which are embedded in the foundation of the building. Columns of the hinge frame are made on the design marks with the use of industrial formwork.

Since all elements of the proposed structural system are fabricated at design marks, there is no need for measures to ensure the sustainability of the system during the construction of the building. This saves steel and speeds up the process. Saving of reinforcing and profile steel is also achieved due to the absence of holes and apertures in the floor slabs. There is also no need for a database of the construction industry for the manufacture of individual prefabricated elements.

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Due to the fact that not only vertical communications (staircases, elevator shafts, power supply, ventilation, etc.), but also useful areas of the building (living rooms, corridors, etc.) can be placed in a vertical volume-spatial carrier multi-cellular structure, it is possible to focus on the cellular structure up to 70% of the vertical loads of the building. This vertical load serves as a load on the cellular structure and facilitates the perception of a horizontal seismic load with an intensity of 9 points.

Cellular structures themselves are repeatedly statically undetectable systems, and the proposed three-dimensional monolithic supporting structure, composed of a set of adjacent cells with closed contours of cross-sections, forming a cellular block structure, has an even larger statically multiple indeterminacy and buildings based on this supporting structures are more viable in case of strong earthquakes. Impacts leading to local destruction of supporting structures, for example, in cases of fire, explosion, etc., do not lead to progressive destruction of building structures.

Flexural-torsional stiffness of the proposed structural system also increases due to the lack of compliance in the connecting nodes of the junction of the walls.

Improved dynamic characteristics of the proposed system, its increased spatial and flexural-torsional stiffness, allow it to be used in buildings of urban high-rise buildings - up to 25 floors, in the high seismicity zone - 9 points.

Claims (8)

CLAIM 1. The combined structural system of an earthquake-resistant multi-storey building, containing a centrally located vertical three-dimensional supporting structure for the entire height of the building, a hinged frame on reinforced concrete columns surrounding the three-dimensional supporting structure and one-piece flat floor slabs, with a vertical three-dimensional supporting structure on each of the floors of the building is composed of a set of adjacent to each other cells with closed contours of cross sections, about forming blocks, characterized in that each of the cells of the block is made of volumetric, continuous, monolithic, height per floor, and the vertical volumetric-spatial supporting structure is formed from a combination of volumetric continuous continuous monolithic blocks that form a multi-tiered closed monolithic structure the height of the entire building . 2. The combined structural system of the earthquake-resistant multi-storey building according to claim 1, characterized in that the three-dimensional continuous monolithic block is formed by plates of upper and lower floors and monolithic walls common to adjacent cells, forming a closed continuous structure. 3. The combined structural system of an earthquake-resistant multi-storey building according to claim 2, characterized in that the joint nodes of the walls of a continuous monolithic block are made in the form of connecting elements reinforced with vertical continuous reinforcement to the entire height of the building and cross-section reinforcement in the form of ring clamps. 4. The combined structural system of the earthquake-resistant multi-storey building according to claim 3, characterized in that for buildings of complex, including radiation, configuration, the vertical three-dimensional supporting structure has a cross-sectional polygon shape, and the transverse reinforcement of adjacent walls of adjacent cells is connected in a connecting element under angle to each other other than straight. 5. The combined structural system of an earthquake-resistant multi-storey building according to claim 2, characterized in that the thickness of the walls constituting the external contour of the three-dimensional supporting structure exceeds the thickness of the internal walls by 1.3-2 times. 6. The combined structural system of the earthquake-resistant multi-storey building according to claim 2, characterized in that the walls of the monolithic blocks above the openings form a bridge of T-section with the upper floor slab, and the height of the jumper above the opening includes the thickness of the ceiling. 7. The combined structural system of the earthquake-resistant multi-storey building according to claim 1, characterized in that the flat floor slabs integral to the floor are made in monolithic reinforced concrete and are supported on the hinged frame columns over the entire cross-sectional surface of these columns. 8. The combined structural system of the earthquake-resistant multi-storey building according to claim 7, characterized in that the hinged frame columns are made in monolithic reinforced concrete with upper and lower floor slabs and are reinforced with continuous vertical reinforcement over the entire height of the building.