RU2386765C2 - Method for construction of quakeproof structures and development of areas - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention is related to the field of civil and industrial construction. Quakeproof structure (residential building of elite class) comprises foundation, on which structure body is installed, comprising reinforced concrete frame. Structure is equipped with quakeproof frame, which comprises the following components: central bearing support, having shape of hollow truncated cone, to which at least three radial supports are connected in vertical plane, at the same time along circle from top to bottom their number increases, depending on structure earthquake resistance. Along outer contour of quakeproof frame there are outer bearing supports joined to radial bearing supports. Inside central bearing support there are the following components installed: tension rope device, shaft of lifting transport means, shaft of utility devices. Inside quakeproof frame between floors there are horizontal ceilings arranged, internal partitions are installed, and inside, along its contour, there are outer walls arranged. At the same time centre of gravity of quakeproof structure is arranged along axis of its symmetry by not more than 1/3 of its height from structure foundation. Also method is described for development of areas with quakeproof structures.

EFFECT: improved quakeproof resistance of building, its reliability, simplified mounting of unitilies.

5 cl, 12 dwg

Description

The claimed invention relates to the field of civil and industrial engineering.

In connection with the increasing incidence of earthquakes, residential buildings and industrial facilities under construction during the earthquake are subject to destruction. Residential buildings under construction and industrial facilities (structures) of frame type made of reinforced concrete do not always withstand earthquakes up to 8 points. The Southern Federal District of Russia is a seismic hazardous area, which requires the construction of structures of higher strength and earthquake resistance.

Closer to the claimed invention by essential features are residential buildings of the elite class, built in block 32-33 on Leninsky Prospekt 128-1, Moscow, Russia (Vokrug Sveta magazine, No. 10 for October 2001, p. 23 ) Houses built with the lack of increased earthquake resistance of structures are less earthquake-resistant during earthquakes.

The problem is solved in that the proposed modular earthquake-resistant construction of structures is made in the form of: a cylinder, cone, a truncated cone, a hollow volumetric cylinder, a quadrangular and triangular pyramid with the center of gravity of the structure located on the axis of symmetry at no more than 1/3 of the height from the foundation of the structure. For reduced seismic resistance of structures, it is allowed to position the center of gravity along the axis of symmetry (vertical) at no more than 1 / 3-2 / 5 from the base of the foundation of the structure.

This object is achieved in that the earthquake-resistant structure contains an earthquake-resistant frame, inside of which there is a central support bearing, in the form of a hollow truncated cone, to which at least three radial load-bearing supports are attached in the vertical plane, while their number increases from top to bottom, depending on the height of the structure upward, i.e. 3-6-9-12, etc., along the outer contour of the earthquake-resistant frame associated with the radial load-bearing bearings are placed external load-bearing supports. Inside the central bearing support are located: a tension rope device, a mine of transport vehicles, a shaft of communication devices, while the mines are separated from each other. Inside the earthquake-resistant frame horizontal floors are placed between the floors, external walls are installed, while the center of gravity is placed at no more than 1/3 of the height of the foundation of the structure.

This object is achieved in that the earthquake-resistant structure is in the form of a hollow cylinder, in which at least three interconnected earthquake-resistant frames are arranged in a circle, each containing a central bearing support, to which at least three radial load-bearing bearings are attached in the vertical plane, and from top to bottom depending on the height of the structure, their number increases in the direction of increase, i.e. 3-6-9-12, etc., along the outer contour of the earthquake-resistant frame associated with the radial load-bearing bearings are placed external load-bearing supports. Inside the central bearing support are located: tension rope device, mine truck, shaft communication devices. Inside the earthquake-resistant frame horizontal floors are placed between the floors, internal partitions are installed, and external walls are installed outside, while the center of gravity of the structure is placed on the axis of symmetry at no more than 1/3 of the foundation of the height of the structure.

This object is achieved in that the earthquake-resistant structure in the form of a tetrahedral pyramid with a center of gravity located on the axis of symmetry at no more than 1/3 of the height from its foundation contains an earthquake-resistant frame inside which contains: a central support bearing, in the form of a hollow truncated cone, to which are attached in the vertical plane of at least four radial load-bearing supports, while from top to bottom, depending on the height of the structure, their number will increase, i.e. 4-8-12, along the outer contour of the earthquake-resistant frame associated with the radial load-bearing bearings are placed external load-bearing supports. Inside the central bearing support are located: tension rope device, mine truck, shaft communication devices. Inside the earthquake-resistant frame horizontal floors are placed between the floors, internal partitions are installed, and external walls are installed outside.

The problem is solved in that an earthquake-resistant structure in the form of a trihedral pyramid with a center of gravity placed on the axis of symmetry of the structure at no more than 1/3 of the height from its foundation contains an earthquake-resistant frame, in which are located: a central support bearing, in the form of a hollow truncated cone, to which are attached in the vertical plane, at least three radial load-bearing supports, while from top to bottom, depending on the height of the structure, their number increases, i.e. 3-6-9, etc., outside the earthquake-resistant frame associated with the radial load-bearing bearings placed external load-bearing supports. Inside the central bearing support are located: a tension rope device, a mine of transport vehicles, a shaft of communication devices, while the shafts are isolated by partitions to each other.

The problem is solved in that the method of placement of earthquake-resistant structures is carried out according to the radial-ring method: public buildings are located in the center, residential buildings - around them.

In this way, pyramid-shaped structures located in the center increase the illumination of residential buildings, and the use of radial-ring roads and sidewalks reduces the flow of vehicles and pedestrians.

The author of the proposed method for the construction of earthquake-resistant structures and their placement in urban areas are not known.

Figure 1 shows the appearance of a high-rise multi-story earthquake-resistant apartment building.

Figure 2 shows a cross section AA vertical plane - the internal earthquake-resistant frame of a residential building (structure).

Figure 3 shows a section bB of figure 2, a top view.

Figure 4 - appearance of the shape of the hollow cylinder is an earthquake-resistant structure.

Figure 5 shows a section bb of figure 4 with a vertical plane, side view.

Figure 6 shows a section GG of figure 5, a top view.

Figure 7 shows the appearance of the structure in the form of a tetrahedral pyramid.

Fig - cross section DD vertical plane, side view.

In Fig.9 shows a cross-section EE of Fig.7 horizontal plane, a top view of the pyramid.

Figure 10 - appearance of the structure of the trihedral pyramid.

Figure 11 shows a section FJ of figure 10 with a horizontal plane, a top view of the pyramid.

12 is a plan for the placement of modular structures of earthquake-resistant structures in cities - a radial ring method.

The residential building (structure), figure 1, contains a foundation 1 (base), on which the housing 2 is installed, while inside the housing there is an earthquake-resistant frame 3 containing a central bearing support 4 made by a hollow truncated cone, to which are not connected in a vertical plane less than three radial load-bearing supports 5, installed depending on the height of the structure and its seismic resistance, their number increases from top to bottom, i.e. 3-6-9, etc., along the outer contour of the earthquake-resistant frame 3 connected to the radial load-bearing supports 5, the external load-bearing supports 6 are placed. Inside the central load-bearing support 4 there are: a tensioning cable device 7, a mine shaft 8, a communication shaft devices 9. Between the floors in the earthquake-resistant frame 3, horizontal ceilings 10 are installed, and external walls 11 are installed outside.

Inside the earthquake-resistant frame 3 there are internal partitions 12, which provide a free layout of the premises. The center of gravity of the apartment building is located on the vertical axis of symmetry of the apartment building at a height of no more than 1/3 of the height from its foundation 1.

Figure 4 shows an earthquake-resistant structure in the form of a hollow cylinder, comprising: a foundation 1, on which the building of structure 2 is installed, inside of which at least three earthquake-resistant frames 3 are placed, interconnected in a circle around the hollow cylinder. Each earthquake-resistant frame 3 contains: a central bearing support 4, made by a hollow truncated cone, to which at least three radial bearing supports 5 are connected in the vertical plane, while their number increases from top to bottom, i.e. 3-6-9, etc., along the outer contour of the earthquake-resistant frame 3 there are external load-bearing supports 6 connected with radial load-bearing supports 5. Inside the central load-bearing support 4 are located: tension cable device 7, mine truck 8, mine communication devices 9.

Inside the earthquake-resistant frame 3 horizontal floors 10 are placed between the floors, and external walls 11 are installed outside it. The earthquake-resistant frame 3 contains inside the partitions 12, while the center of gravity of the earthquake-resistant structure is not more than 1/3 of the height from its (base) foundation 1.

Figure 7 shows an earthquake-resistant structure in the form of a tetrahedral pyramid with a center of gravity located on the vertical axis of symmetry at no more than 1/3 of the height from its foundation 1, it contains: foundation 1, on which an earthquake-resistant frame 3 is placed, in which are located: the central bearing support 4, having the shape of a hollow truncated cone, to which at least four radial bearings 5 are attached in a vertical plane, while from top to bottom, their number increases, i.e. 4-8-12, etc. On the outer contour of the earthquake-resistant frame 3 connected with the radial load-bearing bearings 5, the external load-bearing supports 6 are placed. Inside the central load-bearing support 4 there are placed: a tensioning cable device 7, a mine shaft 8, a shaft of communication devices 9.

Inside the earthquake-resistant frame 3 horizontal floors 10 are placed between the floors, and external walls 11 are installed outside.

To perform the free layout of the premises inside the earthquake-resistant frame 3, internal partitions 12 are placed.

Figure 10 shows an earthquake-resistant structure of the shape of a trihedral pyramid with a center of gravity located on the vertical axis of symmetry at no more than 1/3 of the height from its foundation 1, it contains: foundation 1, on which the building 2 is housed, inside which the earthquake-resistant frame 3 is placed, comprising: a central bearing support 4, having the form of a hollow truncated cone, to which at least three radial bearing supports 5 are attached in a vertical plane, while their number increases from top to bottom, 3-6-9, etc. On the outer contour of the earthquake-resistant frame 3 connected with the radial load-bearing bearings 5, the external load-bearing supports 6 are placed. Inside the central load-bearing support 4 there are: a tensioning cable device 7, a shaft for hoisting vehicles 8, a shaft of communication devices 9.

Inside the earthquake-resistant frame 3 horizontal floors 10 are placed between the floors, and external walls 11 are installed outside.

To perform the free layout of the premises inside the earthquake-resistant frame 3, internal partitions 12 are placed.

12 shows a design method, i.e. placement of earthquake-resistant residential buildings and structures of newly built towns and cities. During the construction and design of cities, a radial-ring method of placing earthquake-resistant houses and structures on the newly built-up territory is used, while access roads (roads, sidewalks) are placed in a radial-ring way, which ensures free movement of vehicles and pedestrians.

On the free areas of the built-up territory, children's playgrounds are being built, trees and shrubs are planted, and temporary parking lots are being organized.

The radial-ring method of building cities with earthquake-resistant houses and structures, FIG. 12, contains: radial-ring roads 13 (sidewalks, streets), earthquake-resistant residential buildings, FIG. 1, elite class 14, earthquake-resistant sports complex 15, construction, FIG. .4, center 16, earthquake-resistant structure, FIG. 7, earthquake-resistant building 17, earthquake-resistant structure, FIG. 10, earthquake-resistant gravity power station 18, earthquake-resistant structure, FIG. 10, is allowed with FIG. 7. The center of spiritual life 19 - earthquake-resistant structure, figure 4; center of science and technical creativity 20, earthquake-resistant structure, figure 4; entertainment center 21, earthquake-resistant structure, Fig.7. On Fig shows a radial-ring method of placement of earthquake-resistant houses and structures in the city, provides maximum illumination inside the premises of houses and structures and the movement of pedestrians and vehicles.

The proposed design of earthquake-resistant structures, figure 1, 4, 7, 10, works as follows. In an earthquake (or explosion), the wave of destruction of the earthquake-resistant structures is directed perpendicular to the vertical axis of the structure and swings it, a structure built with a center of gravity placed on the vertical axis of symmetry at no more than 1/3 of the height of the foundation 1, containing: earthquake-resistant frame 3, inside of which Placed: central bearing support 4, at least three radial bearing supports 5 and external bearing supports 6, the tensioning device damps the resonant amplitude of the building’s vibrations, oscillates with different amplitude Banya, reducing the resonant amplitude of destruction.

The proposed method for the construction of earthquake-resistant structures (residential buildings) increases reliability, simplifies the installation of communications, increases the illumination of rooms, reduces expensive materials by 30-50%, and ensures the design of structures.

Claims (5)

1. An earthquake-resistant structure (an elite-class residential building) containing a foundation on which the building is housed with a reinforced concrete frame installed inside, characterized in that it is equipped with an earthquake-resistant frame, inside of which there is: a central support bearing, in the form of a hollow truncated cone, to to which at least three radial load-bearing supports are connected in the vertical plane, while in a circle from top to bottom their number increases depending on the earthquake resistance of the structure, and the outer contour is earthquake-resistant of the first frame, external load-bearing supports connected with radial load-bearing supports are placed; inside the central bearing support are located: a tension rope device, a mine of transport vehicles, a shaft of communication devices; horizontal floors are placed inside the earthquake-resistant frame between floors, internal partitions are installed, and external walls are placed along its contour, while the center of gravity of the earthquake-resistant structure is placed along its axis of symmetry no more than 1/3 of its height from the foundation of the structure. 2. The earthquake-resistant structure according to claim 1, characterized in that it has the shape of a hollow cylinder, in which at least three interconnected earthquake-resistant frames are placed in a circle inside, while in each earthquake-resistant frame there is: a central bearing support having the shape of a hollow truncated cone to which at least three radial load-bearing supports are attached in the vertical plane, while in a circle from top to bottom their number increases depending on the seismic resistance of the structure; along the outer contour of the earthquake-resistant frame placed external load-bearing supports associated with radial load-bearing supports; inside the central bearing support are located: a tension rope device, a mine of transport vehicles, a shaft of communication devices; horizontal floors are placed inside the earthquake-resistant frame between floors, internal partitions are installed, and external walls are placed along its contour, while the center of gravity of the earthquake-resistant structure is placed along its axis of symmetry no more than 1/3 of its height from the foundation of the structure. 3. The earthquake-resistant structure according to claim 1, characterized in that it has the shape of a tetrahedral pyramid with an earthquake-resistant frame located inside, inside of which there is a central support bearing, in the form of a hollow truncated cone, to which at least four radial load-bearing supports are attached in the vertical plane, while in a circle from top to bottom, their number increases depending on the seismic resistance of the structure; along the outer contour of the earthquake-resistant frame placed external load-bearing supports associated with radial load-bearing supports; inside the central bearing support are located: a tension rope device, a mine of transport vehicles, a shaft of communication devices; horizontal floors are placed inside the earthquake-resistant frame between floors, internal partitions are installed, and external walls are placed along its contour, while the center of gravity of the earthquake-resistant structure is placed on its axis of symmetry no more than 1/3 of the height from the foundation of the structure. 4. The earthquake-resistant structure according to claim 1, characterized in that it has the shape of a trihedral pyramid with an earthquake-resistant frame located inside, inside of which there is a central support bearing, in the form of a hollow truncated cone, to which at least three radial load-bearing supports are attached in the vertical plane, while in a circle from top to bottom, their number increases depending on the seismic resistance of the structure; along the outer contour of the earthquake-resistant frame placed external load-bearing supports associated with radial load-bearing supports; inside the central bearing support are located: a tension rope device, a mine of transport vehicles, a shaft of communication devices; horizontal floors are placed inside the earthquake-resistant frame between floors, internal partitions are installed, and external walls are placed along its contour, while the center of gravity of the earthquake-resistant structure is placed on its axis of symmetry no more than 1/3 of its height from the foundation of the structure. 5. The method of building up areas (territories) with earthquake-resistant structures, characterized in that the earthquake-resistant structures are placed in a radial-circular manner, while the center “Spiritual Life” is located in the center, and roads radially extend from the center along which are placed in a circle in the number of 3-6-9 residential buildings, and in the center of the circles are public facilities, while the roads are located in a radial-ring way.

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