RU2651964C1 - Earthquake resistance building with brick wall panel - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention relates to construction, namely to repair, recovery or erection of aseismic buildings and structures. Building is earthquake-proof with a brick wall panel containing a vibration-insulated foundation, horizontal and vertical bearing structures with a vibration isolation system, internal partitions, the roof of the building, as well as door and window openings with reinforcement, the base load-bearing slabs are equipped in the places of their attachment to the bearing walls of the building with a system of spatial vibration isolation, consisting of horizontally located vibration isolators, receiving vertical static and dynamic loads, as well as vertically located vibration isolators. Floor in rooms is made on elastic base and comprises mounting plate, made of reinforced vibration damping concrete material, which is set on the base plate of an inter-floor bridging with cavities through layers of vibro-damping material and hydro-insulating material with a gap relative to bearing walls of the shop. Brick wall panel is seismic resistant, containing brickwork of bricks with holes in the middle of the width and one-quarter of the length from the ends of the brick laid on the solution with the alignment of the holes in the channels, and reinforcing bars, passed through channels with rigid fixation at the ends, by means of flat stops, in thickness equal to the thickness of the mortar joint, and in the channels at the ends of the panel there are layers of the U-shaped type of vibration damping material, which perceive spatial vibration, the layers of the vibration damping material, structurally made of U-shaped type and perceiving spatial vibration, are made of ground worn out tires on a bundle in the form of rubber glue, liquid glass, or polymer binder, and hard stops are welded every 8÷10 rows of bricks laid on the solution, and the damping rods are elongated with the use of welding, and a solution is added to the channels of the middle zone with a vibration damping crumb from the crushed tires of automobile tires to form more rigid zones, reinforcing bars are made damping, the inner cavity of which is made in the form of a vibration damping insert consisting of an elastic rod coaxially and axially symmetric located inside the cylindrical damping element, on which uniformly fixed, perpendicular to its axis, damping rings made of a vibration damping material with the formation of cavities filled with a vibration damping material, for example sand.

EFFECT: reinforcement of buildings or installations, reducing their vulnerability under action of wind loads and earthquakes, improved seismic safety, durability and service life.

1 cl, 5 dwg

Description

The invention relates to the field of construction, namely to the reconstruction, restoration or construction of earthquake-resistant buildings and structures.

The closest technical solution is an earthquake-resistant building containing horizontal and vertical supporting structures, with at least one opening made in at least one vertical supporting structure, and preferably several openings, in each of which there is a damper multilayer vibration-isolating support consisting of an upper and the lower support plates and the alternating metal and elastomeric layers arranged between them, said plates being rigidly connected to the vertical by means of connecting elements or reinforcing belts located in the openings [RF patent No. 120447 for a utility model - prototype].

The disadvantage of these known technical solutions are: the technical complexity of the device of vibration isolators at high levels of loading on vertical structures (tall buildings) for reconstructed, restored objects, as well as newly constructed dangerous, technically complex and unique buildings and structures, when the use of the proposed methods is insufficiently qualified specialists lead to damage to structures, and sometimes to progressive collapse of the whole building (structure) or part thereof .

A technically achievable result is an increase in the construction of buildings or structures, a decrease in their vulnerability when exposed to wind loads and earthquakes, an increase in their seismic safety, durability and residual life.

This is achieved by the fact that in an earthquake-resistant building containing a vibration-insulated foundation, horizontal and vertical load-bearing structures with a vibration isolation system, internal partitions, the roof of the building, as well as door and window openings with reinforcement, basic load-bearing floor slabs are provided in places of their attachment to the load-bearing walls of the building spatial vibration isolation system, consisting of horizontally located vibration isolators, perceiving vertical static and dynamic loads, as well as vertically located x vibration isolators that accept horizontal static and dynamic loads, while the floor in the rooms is made on an elastic base and contains a mounting plate made of concrete reinforced with vibration damping material, which is installed on the base plate of the floor with cavities through layers of vibration damping material and waterproofing material with a gap with respect to bearing walls of the production room, and the cavity of the base plate is filled with vibration damping material, for example polymer, and the elastic base of the floor is made of a rigid porous vibration-absorbing material, for example, elastomer, or polyurethane with a degree of porosity that is in the range of optimal values: 30–45%, while the brick wall panel is made of earthquake-resistant brick containing brickwork with holes in the middle of the width and one quarter of the length from the ends of the brick laid on the mortar with the alignment of the holes in the channels, and reinforcing bars passed through the channels with their rigid fastening at the ends, in the middle a pair of flat stops equal in thickness to the thickness of the mortar seam, and in the channels at the ends of the panel there are layers of U-shaped vibration damping material that perceive spatial vibration, reinforcing bars are made damping, and each of them is a cylindrical damping element, to the ends of which are rigidly attached flat hard stops, and the inner cavity is filled with a layer of vibration-damping material, such as sand, while the density of the vibration-damping layer is less than the density of the outer cylinder a shell of a damping element, and layers of vibration damping material, structurally made of a U-shaped type and perceiving spatial vibration, made of crushed worn tire covers in the form of rubber glue, liquid glass, or a polymer binder, and every 8 ÷ 10 rows laid on the solution hard stops are welded to the bricks, and the damping rods are lengthened using welding, and a solution with vibro-damping crumb from crushed tires is poured into the channels of the middle zone vtomobilnyh tire to form a more rigid zones, reinforcing bars are made damping.

In FIG. 1 shows a general view of an earthquake-resistant building structure; FIG. 2 is a section through a floor of a building, in FIG. 3 - shows a brick (bearing element) in a perspective view with two holes; in FIG. 4 - earthquake-resistant brick wall panel, plan view, in FIG. 5 is a diagram of a damping rod of a brick wall panel.

An earthquake-resistant building with a brick wall panel (Fig. 1) contains a vibration-insulated foundation 1, horizontal 3 and vertical 2 load-bearing structures with a vibration isolation system, internal partitions 4, the roof of the building 5, as well as door 6 and window 7 openings with reinforcement. The elastic floor base is made of a rigid porous vibration-absorbing material, for example elastomer, or polyurethane with a degree of porosity in the range of optimal values: 30–45%.

The floor structure is made on an elastic foundation (Fig. 2) and contains a mounting plate 8 made of concrete reinforced with vibration damping material, which is installed on the base plate 9 of the floor with cavities 10 through layers of vibration damping material 11 and waterproofing material 12 with a gap 13 relative to the bearing walls 2 buildings. In order to ensure effective vibration isolation of the mounting plate 8 in all directions, the layers of vibration damping material 11 and waterproofing material 12 are made with a flange that is tightly adjacent to the supporting structures of the walls 2 and the base supporting plate 9 of the floor.

To increase the vibration isolation efficiency and earthquake resistance of the building, the basic floor slabs 9 (in Fig. 2 shows the floor slab 9 for only one floor of the building and on one side of the load-bearing walls 2) are equipped at the points of their attachment to the load-bearing walls of the building with a spatial vibration isolation system consisting of horizontally located vibration isolators 14 and 15, perceiving vertical static and dynamic loads, as well as vertically located vibration isolators 16, perceiving horizontal static and dynamically e load.

The earthquake-resistant building contains a brick wall panel (Fig. 3, 4, and 5), which is made of bricks 17 with two holes 18 in the middle of the width and one quarter of the length from the ends of the brick. In the combined holes 16 of the bricks 17, damping (reinforcing) rods 19 are placed, at the ends of which flat stops 21 are fixed, equal in thickness to the thickness of the mortar joints 20, 22.

A possible embodiment of the damping rods (Fig. 5), the inner cavity of which is made in the form of a vibration damping insert, consisting of an elastic rod 25, coaxially and axisymmetrically located inside the cylindrical damping element 23, on which the damping rings 26 are made uniformly fixed, perpendicular to its axis, are made from vibration damping material with the formation of cavities 24 filled with vibration damping material, such as sand.

Claims (1)

The building is earthquake-resistant with a brick wall panel containing a vibration-insulated foundation, horizontal and vertical load-bearing structures with a vibration isolation system, internal partitions, the roof of the building, as well as door and window openings with reinforcement, basic load-bearing floor slabs equipped with a spatial system in the places of their attachment to the load-bearing walls of the building vibration isolation, consisting of horizontally located vibration isolators, perceiving vertical static and dynamic loads, as well as vertically located vibration insulators that accept horizontal static and dynamic loads, while the floor in the rooms is made on an elastic base and contains a mounting plate made of concrete reinforced with vibration damping material, which is installed on the base plate of the floor with cavities through layers of vibration damping material and waterproofing material with a gap with respect to bearing walls of the production room, and the cavity of the base plate is filled with vibration damping material, for example foamed polymer, the elastic floor base is made of a rigid porous vibration-absorbing material, for example elastomer, or polyurethane with a degree of porosity in the range of optimal values: 30 ÷ 45%, characterized in that the brick wall panel is made of earthquake-resistant brick containing bricks with holes in the middle of the width and one quarter of the length from the ends of the brick laid on the mortar with a combination of holes in the channels, and reinforcing bars passed through the channels with their rigid fastening on On the other hand, by means of flat stops, equal in thickness to the thickness of the mortar seam, and in the channels at the ends of the panel, layers of a vibro-damping material of a U-shaped type are received, perceiving spatial vibration, and layers of a vibro-damping material structurally made of a U-shaped type and perceiving spatial vibration are made of crushed worn tires on a bundle in the form of rubber glue, liquid glass or a polymer binder, and every 8 ÷ 10 rows of bricks laid on the mortar are welded stiff stops, and damping rods are lengthened by welding, and a solution with vibration damping crumb from crushed tires of automobile tires is poured into the channels of the middle zone to form more rigid zones, reinforcing bars are made of damping, the internal cavity of which is made in the form of a vibration damping insert consisting of an elastic rod coaxially and axisymmetrically located inside a cylindrical damping element on which its axes are damped uniformly, perpendicular to lakes made of vibration-damping material with the formation of cavities filled with vibration-damping material, such as sand.

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