RU126343U1 - SPACE-CONSTRUCTION SYSTEM OF FRAME-PANEL BUILDING - Google Patents

Abstract

1. Spatial-structural system of a frame-panel building containing rack supports located at angular and intermediate points of the frame, longitudinal and transverse inter-support connections connecting paired rack supports, load-bearing and hinged wall panels, characterized in that said rack supports and inter-support connections structurally combined in one node in the form of a U-shaped two-post frame and a L-shaped single post frame, which are mounted on anchor bolts, monolithic with high-strength concrete in a horizontal joint frame racks with a foundation for the first floor, and these frame racks are installed on the underlying frame - for subsequent floors in various combinations of two-rack and single-rack frames in accordance with the installation diagram of the frame-panel building, and in the installed position of the frames, their racks adjacent to each other are connected between inseparable connections, and the racks are attached the aforementioned load-bearing wall panels, between which and the corresponding frames, balcony slabs are installed in the designed places, and the indicated hinged Renovated panels are installed one above the other between the lower and upper frames of adjacent floors of the frame-panel building and attached to them, while the spatial-structural system is equipped with supporting volumetric floor elements of ventilation shafts installed along the axis of the building frame, floor slabs are made beam-supported on the frames, and in the places of connection with the ventilation shafts, the floor slabs are laid on the wall of the ventilation shaft, and in the seams between adjacent floor slabs are installed

Description

The utility model relates to the field of ground construction, namely the construction of frame-panel buildings for public and civil purposes.

A well-known spatial-structural system of a frame-panel building containing rack supports located at corner and intermediate points of the frame, longitudinal and transverse inter-support connections connecting conjugate rack olors, bearing and wall panels (international application BUILDING ASSEMBLY SYSTEM PCT / MY20121 / 000182, publication W02012021055 (W02011MY00182 20110729), IPC E04B 1/343, 2011).

This technical solution is the closest to the utility model, therefore, taken as a prototype.

The disadvantages of the prototype are limited functionality and complex building technology of the building.

The technical result from the use of the claimed technical solution is to expand the functionality due to the flexible layout of the premises, to simplify the building technology of the building through the use of load-bearing concrete volumetric ventilation shafts.

Below are the general and particular essential features characterizing the causal relationship of the utility model with the specified technical result.

Spatial-structural system of a frame-panel building, containing rack supports located at corner and intermediate points of the frame, longitudinal and transverse inter-support connections connecting conjugate rack olors, bearing and wall panels. The specified rack supports and inter-support connections are structurally combined in one node in the form of a U-shaped two-rack frame and a L-shaped single rack frame, which are mounted on anchor bolts, monolithic with high-strength concrete in the horizontal joint of the frame rack with the foundation for the first floor and these frame racks are mounted on underlying frame - for subsequent floors in various combinations of two-rack and single-rack frames in accordance with the wiring diagram of a panel-frame building. In the installed position of the frames, their racks adjacent to each other are interconnected by one-piece connections, and the aforementioned load-bearing wall panels are attached to the racks, between which and the corresponding frames, balcony slabs are installed in the designed places, and these hinged wall panels are installed one above the other between the lower and upper frames of adjacent floors of the frame-panel building and are attached with ties to them. The spatial-structural system is equipped with supporting volumetric floor elements of ventilation shafts installed along the axis of the building frame, floor slabs are made with beams with the possibility of bearing on the frames. At the joints with the ventilation shafts, the floor slabs are laid on the wall of the ventilation shaft, and puffs of steel reinforcement are installed in the seams between adjacent floor slabs. In the locations of the racks of the frames, communication slabs are placed. All elements forming the building are made of reinforced concrete. The spatial-structural system is equipped with additional stiffness diaphragms in the form of flat panels that are installed in the space between the racks of the corresponding frame. In this case, additional diaphragms and frames are fixed by the corresponding connections.

The main vertical bearing structures of the system are single-story frames that are installed in the longitudinal and transverse directions within the floor, depending on the accepted dimensions of the building and the creation of sufficient floor stiffness in these directions.

To ensure architectural flexibility and expressiveness of the facades, the system of load-bearing frames can be supplemented by flat load-bearing wall panels.

In places of mutual adjacency, the frame racks are connected by bonds that prevent their mutual displacement, as well as displacement in the longitudinal direction.

Wall panels adjacent to frames have similar ties to frames.

For the arrangement of balconies, balcony slabs are provided that are located between the crossbars of the frames and are pressed against the shelves of the crossbars using a wall panel inserted into the space between the upper plane of the balcony plate and the lower surface (crossbar) of the frame.

The rigidity of the building in the longitudinal and transverse directions is provided by the rigid nodes of the frames, and in case of need to increase the rigidity, additional stiffness diaphragms are introduced into the space between the crossbars of the frames. In addition, to increase the rigidity of the floor slab in a horizontal plane, tightenings made of steel reinforcement are installed in the seams between adjacent floor slabs.

Floor slabs are made in the form of beams, rely on crossbars of frames. In the locations of the ventilation shafts, the ceilings rest on the wall of the ventilation shaft. In the locations of the frame racks, floor slabs are used.

In addition to the supporting external wall panels, external external wall panels are provided. A hinged panel is wound between the crossbars of the frames, the inner layer rests on the lower crossbar. The panel is fastened with ties to the lower and upper crossbars. The accepted method of hanging panels allows you to vary their size and shape, which allows you to vary the architecture of the facades and also replace panels in case of repair or reconstruction of the building.

The panel-frame combination under consideration, the system of load-bearing structures allows for flexible layout of rooms, as well as reconstruction of the building, taking into account the changing requirements for the composition of the premises.

For the first time, the system uses load-bearing concrete volumetric ventilation shafts. This has simplified the use of large-span multi-hollow flooring made using the formless molding technology as floors. No special plumbing plates with openings are required.

The device is illustrated by drawings, where: in Fig.1 shows a General structural diagram of a system in isometry; figure 2 is a top view; figure 3 is a view 2-2 of figure 2; figure 4 - arrangement of the balcony slab; figure 5 is a view of 1-1 in figure 2; figure 6 is a view a in figure 2; figure 7 - visible figure 2; in Fig.8 is a view 3-3 in Fig.2; figure 9 is a General view of the U-shaped frame, isometry; figure 10 is a General view of the L-shaped frame, isometry in figure 11 is a layout of balcony slabs.

The spatial-structural system of a panel-frame building includes U-shaped double-rack frames 1 and L-shaped single-rack frames 2, which are mounted on anchors 3 (anchor bolts monolithic with high-strength concrete) in the horizontal joint of 4 rack frames 1 or 2 with a foundation for ground floor.

The indicated racks of frames 1 or 2 are installed on the underlying frame (its bolt) on anchors 3 - for subsequent floors in various combinations of double-rack 1 and single-rack 2 frames in accordance with the wiring diagram of the panel-frame building.

In the installed position of the frames 1 and 2, their racks adjacent to each other are interconnected by one-piece connections 5, and the supporting wall panels 6 are attached to the racks, between which and the corresponding frames are installed in the designed places balcony plates 7.

These wall mounted wall panels 8 are installed one above the other between the lower and upper frames 1 or 2 of the adjacent floors of the frame-panel building and are attached by ties 9 to them.

The spatial-structural system is equipped with supporting volumetric floor elements of ventilation shafts 10 installed along the axis of the building frame.

The floor slabs 11 are made with beams with the possibility of support on the frames 1 or 2, and at the points of connection with the ventilation shafts 10, the floor slabs 11 are laid on the wall of the ventilation shaft 10.

Puffs of steel reinforcement (not shown) are installed in the seams between adjacent floor slabs 11, and communication floor slabs 12 are located at the locations of the racks of frames 1 or 2.

All elements forming the space-structural system of a panel-frame building are made of reinforced concrete.

The system of the panel-frame building is equipped with additional stiffness diaphragms 13 in the form of flat panels that are installed in the space between the racks of the corresponding frame 1 or 2, while the additional stiffness diaphragms 13 and frames 1 or 2 are fixed with the corresponding connections 9.

Comparison of the claimed technical solution with the prior art known from the scientific, technical and patent documentation as of the priority date in the main and related sections did not reveal a tool that has features identical to all the features contained in the utility model proposed by the applicant, including the purpose of use. That is, the set of essential features of the claimed solution was not previously known and is not identical to any known technical solutions, therefore, it meets the condition of patentability “novelty”.

This technical solution is industrially applicable, since its purpose is indicated in the description of the application and the name of the utility model, it can be manufactured industrially and used in the construction of panel-frame buildings.

The technical solution is workable, feasible and reproducible, and the distinguishing features of the device allow to obtain the desired technical result - expanding the functionality due to the flexible layout of the premises and simplifying the building technology of the building through the use of load-bearing concrete volumetric ventilation shafts, i.e. are significant.

The utility model in the form as described in each of the claims can be implemented using the tools and methods described in the prototype, which became public until the priority date of the utility model. Therefore, the claimed technical solution meets the condition of patentability "industrial applicability".

The device is implemented as follows.

The assembly of the panel-frame building using this spatial design system is as follows.

The building is going on a ready foundation. To install frames 1 and 2 in appropriate places on the foundation, anchors 3 are provided in the form of bolts. First of all, frames 1 and 2 are mounted in accordance with the wiring diagram. Racks of frames 1 and 2 are installed on anchors (bolts) 3 and quotation nuts (not shown). After alignment of the uprights vertically, and the crossbars of frames 1 and 2 horizontally, the anchors (bolts) 3 are tightened with fixing nuts (not shown).

Then, monolithing with high-strength concrete of the horizontal joint of 4 racks of frames 1 and 2 with the foundation is performed.

Further, after installing frames 1 and 2, they are connected along vertical joints by bonds 5 and concrete of vertical joints is concreted, then stiffening diaphragms 13 (if they are required by calculations) are mounted under the crossbars of frames 1 and 2. Installation of stiffening diaphragms 13 is possible with holding them on temporary braces (not shown) before the installation of frames 1 and 2. Connection of 5 stiffening diaphragms 13 and crossbars of frames 1 and 2 is carried out and the installation of load-bearing wall panels 6 and their connection with the uprights of frames 1 and 2.

Then, load-bearing volumetric ventilation shafts 10, elevator shafts, installation of staircase structures (not shown) are installed.

Thus, the installation of the vertical supporting structures of the floor is completed. In this state, the structures are in a spatially stable position and do not require additional fixation.

Next, the balcony slabs 7 and wall panels are mounted 8. The next floor is mounted according to the same scheme with the difference that the racks of frames 1 and 2 are not attached to the foundation, but to the frames 1 and 2 below the anchors 3.

Lastly, the installation of floor slabs 11 is carried out, during which the installation of reinforcing cages and puffs at the joints of floor slabs 11 and concreting of longitudinal joints between floor slabs 11, as well as between the ends of floor slabs 11 on frames 1 and 2, are performed.

The use of the utility model allows expanding the functional capabilities due to the flexible layout of the premises, simplifying the installation technology and accelerating the construction; the use of large-span multi-hollow flooring made using the formless molding technology as overlappings.

Claims (3)

1. Spatial-structural system of a frame-panel building containing rack supports located at angular and intermediate points of the frame, longitudinal and transverse inter-support connections connecting paired rack supports, load-bearing and hinged wall panels, characterized in that said rack supports and inter-support connections structurally combined in one node in the form of a U-shaped two-post frame and a L-shaped single post frame, which are mounted on anchor bolts, monolithic with high-strength concrete in a horizontal joint frame racks with a foundation for the first floor, and these frame racks are installed on the underlying frame - for subsequent floors in various combinations of two-rack and single-rack frames in accordance with the installation diagram of the frame-panel building, and in the installed position of the frames, their racks adjacent to each other are connected between inseparable connections, and the racks are attached the aforementioned load-bearing wall panels, between which and the corresponding frames, balcony slabs are installed in the designed places, and the indicated hinged Renovated panels are installed one above the other between the lower and upper frames of adjacent floors of the frame-panel building and attached to them, while the spatial-structural system is equipped with supporting volumetric floor elements of ventilation shafts installed along the axis of the building frame, floor slabs are made beam-supported on the frames, and in the places of connection with the ventilation shafts, the floor slabs are laid on the wall of the ventilation shaft, and in the seams between adjacent floor slabs are installed tightenings made of steel reinforcement, and in the locations of the racks of the frames, communication slabs are placed. 2. The spatial-structural system of the frame-panel building according to claim 1, characterized in that all the elements forming the building are made of reinforced concrete. 3. The spatial-structural system of the frame-panel building according to claim 1, characterized in that it is equipped with additional stiffness diaphragms in the form of flat panels that are installed in the space between the racks of the corresponding frame, while the additional diaphragms and frames are fixed with the corresponding connections.

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