RU2596228C1 - Bearing structure of multistorey building structure (versions) and method of erection of multistorey long span structure - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention relates to construction, particularly, to the bearing structure of the multistorey long span structure. Bearing frame consists of one or more two-storey bearing tiers, series-arranged one above the other as to height of the structure. On the top floor of the two-story bearing tier the bearing long span inter-floor metal structures in the form of flat combined truss systems are arranged, and at the level of the ground floor of the two-story bearing tier at the edges of spans in truss systems plane the vertical communications with a height of a floor, connected with assemblies of truss systems are performed. Upper and lower belts of truss systems are composed of the belt trusses or the belt beams, at the level of which there are inter-spanning trusses or crosswise direction beams. Reinforced-concrete inter-floorings are arranged along the upper level of the belt trusses or the beams. Other versions of bearing structures and method of their erection are suggested.

EFFECT: technical result of the invention consists in increase of free space of the structure.

4 cl, 11 dwg

Description

The invention relates to the field of construction, namely to multi-storey load-bearing structures of large-span structures, in particular to the construction of sports halls and indoor stadiums.

From the achieved level of technology, a technical solution is known for the spatial structural structure of an arch-type coating with a puff (Recommendations for the design of structural structures, river 2.14 (a), 1984, Moscow, TsNIISK im. Kucherenko).

The disadvantage of this technical solution is the fact that tightening lowers the usable height of the blocked hall.

A technical solution is known for the cantilever spatial core structure of the coating, which is made in two layers in the support zone to increase the length of the span to be covered (Utility Model of the Russian Federation N139746, IPC 7 Е04В7, 2014).

The aim of the present invention is the use of the technique of a multi-tiered spatial bar structural structure of the coating in areas with the greatest efforts in the elements of the spatial arched and frame bar structural structure of the coating.

A building with large-span rooms is known, over which the supporting floors are arranged in the form of a single integral box-section structure, the upper and lower shelves of which form the overlapping of the bearing floor, and the longitudinal and transverse walls divide the bearing floor into separate rooms.

The disadvantage of this technical solution is the high material consumption and the limited overlap span.

The closest to the proposed technical solution is a multi-story large-span industrial building with inter-truss floors, in which large spans are overlapped by large-span trusses on reinforced concrete columns, with the device of overlappings of prefabricated floor slabs at the level of the upper and lower zones of large-span trusses, and within the structural height of these trusses additional floors that house engineering equipment and communications, household, warehouse and other auxiliary premises (Ba Cove VN Sigalov EE, reinforced concrete structure, the overall rate. M .: Stroyizdat, 1976, p. 588).

The disadvantage of this technical solution for a large-span frame is the need for a frequent arrangement of frame racks and large-span trusses, which is caused by the size of the spans of floor slabs between large-span trusses.

The aim of the present invention is to increase the free usable space for multi-story large-span structures, as well as optimizing the design of large-span spatial arched and frame structural coatings based on a multi-story frame.

This technical problem is solved by carrying out the supporting structure of a multi-storey long-span structure, including vertical load-bearing supports, large-span inter-floor load-bearing structures with the device of horizontal disks of inter-floor ceilings at the level of the upper and lower zones of the large-span inter-floor load-bearing structures, the coating structure, while the supporting skeleton is constructed from one or several two-story load tiers sequentially located one above the other in height of a multi-story of a span structure, and on the upper floor of a two-story load tier, there are load-bearing large-span inter-storey metal structures in the form of flat combined truss systems, and in the level of the lower floor of a two-story load tier along the spans in the plane of the combined truss systems, vertical connections are made in the form of diagonal rod systems with a height of one floor associated with the nodes of the combined truss systems, while the upper and lower zones of the combined truss systems are made in the form clear trusses or waist beams, but at the level of waist trusses or waist beams of the upper and lower belts of combined truss systems, span trusses or span beams of transverse overlapping are installed, moreover reinforced concrete floor ceilings are arranged on the upper level of waist trusses or waist beams of upper and lower belts combined truss systems, as well as on the upper level of span trusses or span beams of overlapping transverse directions.

The coating structure of a multi-story large-span structure is made in the form of a spatial structural core arched shell, while the spatial structural core of the arched shell is supported by pyramidal core capitals on the columns of the frame at the top of the combined truss systems, and a support belt is made along the support line of the coating over the pyramidal core capitals , which is performed in the form of two or more tier structural support contour.

As an option, the coating structure of a multi-story large-span structure is made in the form of a spatial structural core frame shell, while the spatial structural core frame shell is supported by pyramidal core capitals on the columns of the frame at the top level of the combined truss systems, and along the contour of the coating supporting above the pyramidal core capitals perform a support belt, which is performed in the form of two or more tier structural op molecular circuit, together with the rigid frame nodal portions spatial structural shell erected in two or more tiers.

To achieve this goal, a method for erecting a multi-story large-span structure is proposed, including the construction of vertical supporting structures, the implementation of large-span inter-floor metal supporting structures, the installation of reinforced concrete inter-floor ceilings along the upper and lower belts of large-span inter-floor metal supporting structures in the form of rigid horizontal disks, installation of coating structures, communication device , while the supporting skeleton of a multi-story large-span structure the structures are erected in the form of one or several two-story bearing tiers, successively arranged one above the other in the height of the structure, first, columns of the frame with floor consoles are mounted, then on the upper floor of the two-story bearing tier, the supporting large-span interfloor metal structures in the form of flat combined trusses are installed on the columns of the frame systems, and on the lower floor of a two-story load tier, vertical coupling supports are mounted at the edges of the span on the edges of the span trussed systems, in the form of diagonal rod systems associated with the nodes of the combined truss systems, while the upper and lower belts of the combined truss systems are in the form of waist trusses or waist beams, moreover, in the level of waist trusses or waist beams of the upper and lower combined belts truss systems establish span trusses or span beams of overlapping transverse directions and then along the upper level of waist trusses or waist beams of the upper and lower belts of combined trusses concrete systems, as well as on the upper level of span trusses or span beams of the transverse direction, reinforced concrete floor slabs are arranged, in addition, in the transverse direction from the plane of the combined truss systems, between the columns of the frame at the upper level of the two-story load-bearing frame, bond metal trusses are arranged with a height equal to the height of long-span interfloor metal truss systems, along with this on the lower floor of the two-story load tier along the edges of the span and in flat The linkage metal trusses mount vertical linkage supports per floor in the form of diagonal rod systems connected to the nodes of the linkage metal trusses.

The illustrative examples of the application of this invention show embodiments of the supporting structure of a multi-story long-span structure:

in FIG. 1 - section A1-A1 for the version with the execution of the upper and lower belts of large-span truss systems in the form of belt trusses, coated in the form of a spatial structural core arched shell (2-span building),

in FIG. 2 - section A1-A1 for the version with the execution of the upper and lower belts of large-span truss systems in the form of waist beams, coated in the form of a spatial structural core arched shell (2-span building),

in FIG. 3 - section A2-A2 for the version with the execution of the upper and lower belts of large-span truss systems in the form of waist beams, coated in the form of a spatial structural core arched shell (2-span building),

in FIG. 4 - section A3-A3 for the version with the execution of the upper and lower belts of large-span truss systems in the form of waist beams, coated in the form of a spatial structural core arched shell (3-span building),

in FIG. 5 - section A4-A4 for the version with the execution of the upper and lower zones of the large-span truss systems in the form of waist beams, coated in the form of a spatial structural core arched shell (3-span building),

in FIG. 6 - section A1-A1 for the version with the execution of the upper and lower belts of large-span truss systems in the form of waist beams, coated in the form of a spatial structural core frame shell (2-span building),

in FIG. 7 - section A2-A2 for the version with the execution of the upper and lower zones of large-span truss systems in the form of waist beams, coated in the form of a spatial structural core frame shell (2-span building),

in FIG. 8 - section A3-A3 for the version with the execution of the upper and lower belts of large-span truss systems in the form of waist beams, coated in the form of a spatial structural core frame shell (3-span building),

in FIG. 9 - section A4-A4 for the version with the execution of the upper and lower belts of large-span truss systems in the form of waist beams, coated in the form of a spatial structural core frame shell (3-span building),

in FIG. 10 is a fragment of a plan of a 2-span building,

in FIG. 11 is a fragment of a plan of a 3-span building.

A method is proposed for erecting a multi-story large-span structure, in which the supporting frame of a multi-story large-span structure is erected in the form of one or more two-story load-bearing tiers, successively arranged one above the other in the height of the structure, with columns of the frame 1 with floor consoles 2 being mounted first, and then on the upper floor of the two-story bearing tiers along the columns of the frame 1 set supporting long-span interfloor metal structures in the form of a flat combined truss system 3, and on the lower floor of a two-story load tier, vertical connection supports 4 are mounted on the floor in the plane of the combined truss systems 3 in the form of diagonal rod systems connected to the nodes of the combined truss systems 3 at the edges of the span, while the upper and lower belts of the combined truss systems 3 are performed in the form of waist trusses 5 or waist beams 6, in addition, in the level of waist trusses 5 or waist beams 6 of the upper and lower belts of combined truss systems 3, span trusses or inter-spans are installed The beams 7 of the transverse directional ceilings and then along the upper level of the waist trusses 5 or the waist beams 6 of the upper and lower belts of the combined truss systems 3, as well as the upper level of the span trusses or the span beams 7 of the transverse direction overlap, provide reinforced concrete floor ceilings 8. In addition, in the transverse direction from the plane of the combined truss systems 3 between the columns of the carcass 1 at the upper level of the two-story load-bearing carcass arranged metal trusses 9 high equal to the height of large-span interfloor metal truss systems 3. Along with this, at the lower level of the two-story load tier along the edges of the span and in the plane of the coupled metal trusses 9, vertical coupler supports 4 of height per floor are mounted in the form of diagonal rod systems connected to the nodes of the coupled metal trusses 9 .

The supporting structure of a multi-story long-span structure includes a supporting skeleton, which consists of one or more two-story supporting tiers, successively arranged one above the other in the height of a multi-story large-span structure, and on the upper floor of a two-story bearing tier, there are supporting long-span metal structures in the form of combined flat trusses 3 systems based on the console 2 columns of the frame 1, and at the level of the lower floor of the two-story load tier n about the edges of the spans in the plane of the combined truss systems 3, vertical ties 4 are made in the form of diagonal rod systems per floor height connected with the nodes of the combined truss systems 3. The upper and lower belts of the combined truss systems 3 are made in the form of waist trusses 5 or waist beams 6 at the same time, in the level of waist trusses 5 or waist beams 6 of the upper and lower belts of combined truss systems 3, span trusses or span beams 7 of transverse directional ceilings are installed, moreover, iron ETOH intercommunication covering 8 arranged on the upper level of the waist belt or truss girders 5 6 upper and lower belts combined truss systems 3, and the upper level mezhproletnyh trusses or girders 7 mezhproletnyh transverse direction overlaps.

The coating structure of a multi-story long-span structure is made in the form of a spatial structural core arched shell 10, while the spatial structural core of the arched shell 10 is supported by pyramidal core capitals 11 on the columns of the frame 1 at the top level of the combined truss systems 3, and along the contour of the coating supporting above the pyramidal rod capitals 11 perform a support belt 12, which is made in the form of two or more tier structural support to ontura.

Alternatively, the coating structure of a multi-story large-span structure is made in the form of a spatial structural core frame shell 13, while the spatial structural core frame shell 13 is supported by pyramidal core capitals 11 on the columns of the frame 1 at the top level of the combined truss systems 3, and along the support contour coatings over the pyramidal rod capitals 11 perform a support belt 12, which is made in the form of two or more tier structures urnogo reference circuit, together with the rigid portions 14 uzlovye space frame shell structure 13 erected in two or more tiers.

The application of this technical solution to a large-span multi-story building will allow the construction of compact multifunctional, for example, sports centers, including with swimming pools, halls, indoor stadiums with parquet, lawn or ice flooring, which will allow for year-round classes for a wide range of summer and winter sports , with the autonomous functioning of each individual hall room.

Claims (4)

1. The supporting structure of a multi-story large-span structure, including vertical supporting pillars, large-span inter-floor bearing structures with horizontal discs of inter-floor ceilings at the level of the upper and lower zones of the large-span inter-floor load-bearing structures, the coating structure, characterized in that the supporting frame consists of one or more two-story supporting tiers sequentially located one above the other in height of a multi-story long-span structure, and on the upper Bearing large-span interfloor metal structures in the form of flat combined truss systems are located on the floor of the two-story load tier, and in the lower floor of the two-story load tier along the edges of the spans in the plane of the combined truss systems, vertical ties are made in the form of diagonal rod systems per floor height associated with the nodes of the combined truss systems, while the upper and lower belts of the combined truss systems are made in the form of waist trusses or waist beams, however at the level of the waist trusses or the waist beams of the upper and lower belts of the combined truss systems, span trusses or inter-span beams of the transverse direction are installed, moreover reinforced concrete floor ceilings are arranged at the upper level of the trusses or the waist beams of the upper and lower belts of the combined truss systems, as well as at the upper level span trusses or span beams of overlapping transverse directions. 2. The supporting structure of a multi-storey large-span structure, including vertical supporting supports, large-span inter-floor bearing structures with horizontal horizontal disks of floor floors at the level of the upper and lower zones of large-span multi-floor load-bearing structures, the coating structure, characterized in that the coating structure is made in the form of a spatial structural rod arch shell, while the bearing of the spatial structural core arched shell is using pyramidal rod capitals on the columns of the frame at the top of the combined truss systems, and along the contour of the support of the coating above the pyramidal rod capitals a support belt is arranged, which is made in the form of two or more tier structural support contour. 3. The supporting structure of a multi-story large-span structure, including vertical supporting pillars, large-span inter-floor supporting structures with horizontal discs of inter-floor ceilings at the level of the upper and lower belts of large-span inter-floor supporting structures, the coating structure, characterized in that the coating structure is made in the form of a spatial structural core frame shell, while the support of the spatial structural rod-shaped frame shell is carried out at n the power of the pyramidal rod capitals on the columns of the frame at the top of the combined truss systems, and along the contour of the support of the coating above the pyramidal rod capitals a support belt is arranged, which is made in the form of two or more tier structural support contour, at the same time the rigid nodal sections of the spatial frame structural shell are performed in two or more tiers. 4. A method of erecting a multi-story large-span structure, including the construction of vertical supporting structures, the implementation of large-span inter-floor load-bearing structures, the device of reinforced concrete inter-floor ceilings on the upper and lower belts of the large-span inter-floor load-bearing structures in the form of rigid horizontal disks, installation of coating structures, characterized in that the supporting skeleton of the multi-story a large-span structure is erected in the form of one or more two-story bearing tiers, followed by they are located one above the other in height of the structure, first of all, the columns of the frame with floor consoles are mounted, then on the upper floor of the two-story load tier, the supporting columns of the frame are mounted with large-span metal constructions in the form of flat combined truss systems, and on the lower floor of the two-story load tier, on the edges of the span, vertical link supports are mounted one floor high in the plane of the combined truss systems in the form of diagonal rod systems connected to nodes combined truss systems, while the upper and lower belts of the combined truss systems are in the form of waist trusses or waist beams, in addition, span trusses or span beams of the transverse direction are installed at the level of the waist trusses or waist beams of the upper and lower belts of the combined truss systems and further the upper level of the waist trusses or the waist beams of the upper and lower belts of the combined truss systems, as well as the upper level of the span trusses or the span balls reinforced concrete interfloor overlaps are arranged for the overlapping of the transverse direction, in addition, in the transverse direction from the plane of the combined truss systems, between the columns of the framework, connected metal trusses are arranged at the upper level of the two-story load-bearing frame with a height equal to the height of the large-span interfloor metal trusses, along with this on the lower floor of the two-story supporting tier at the edges of the span and in the plane of the bonded metal trusses, vertical bonded supports are mounted one floor high in the form askosnyh rod systems associated with the nodes of bond metal trusses.

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