RU2579025C1 - Earthquake-resistant building structure - Google Patents

Abstract

FIELD: acoustics.

SUBSTANCE: invention relates to industrial acoustics. Earthquake resistant building structure, comprising a frame building with foundation in basement with vibration insulation system, bearing walls with enclosures in form of floor and ceiling, which are lined with sound-absorbing structures, window and door openings, as well as custom-made absorbers containing frame in which sound-absorbing material, and arranged over noisy equipment, base bearing floor slabs have at their attachment to carrying building walls damping system consisting of horizontal vibration isolators, accepting vertical static and dynamic loads, as well as vertical vibration isolators accepting horizontal static and dynamic loads, sound-absorbing structure of building is made as a multilayer sound-absorbing element made in form of five layers, two of which, adjacent to walls are sound-absorbing layers from materials of different density, while three central layers are combined, and axial layer is sound-absorbing while two symmetrical adjoining layers are made from sound reflecting material from complex profile composed of evenly distributed hollow tetrahedrons, which enable to reflect sound waves incident in all directions.

EFFECT: technical result is increasing efficiency of seismic stability of buildings.

1 cl, 7 dwg

Description

The invention relates to industrial acoustics.

The closest technical solution to the technical nature and the achieved result is the acoustic design according to the patent of the Russian Federation No. 2425197, class. F01N 1/04, [prototype], comprising a frame on the ceiling of a building and a wall with sound-absorbing lining.

The disadvantage of the technical solution adopted as a prototype is the relatively low noise attenuation efficiency due to the relatively low coefficient of vibration damping of the floor.

The technical result is an increase in the effectiveness of earthquake resistance of the building.

This is achieved by the fact that in an earthquake-resistant building structure containing a building frame with a foundation in the basement with a vibration isolation system, load-bearing walls with fences in the form of floor and ceiling, which are lined with sound-absorbing structures, window and door openings, as well as piece sound absorbers containing a frame, in which the sound-absorbing material is located, and installed above the noisy equipment, the basic load-bearing floor slabs are equipped at the places of their attachment to the load-bearing walls of the building with a system of spatial vibration ventilation, consisting of horizontally located vibration isolators, perceiving vertical static and dynamic loads, as well as vertically located vibration isolators, perceiving 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 installed on the base plate of the interfloor overlap with cavities through layers of vibration damping material and waterproofing material with a gap relative to the bearing walls of the production room, and the cavity of the base plate is filled with vibration damping material, for example, foamed polymer.

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 - design of a false ceiling, in FIG. 4 is a diagram of the vibration isolation of the basement at the base of the building, FIG. 5 is a general view of the vibration isolator, FIG. 6 is a section AA of the vibration isolator, FIG. 7 is a diagram of a sound-absorbing wall cladding of a building.

The earthquake-resistant building structure (Fig. 1) contains the building frame with a foundation in the basement with a vibration isolation system (Fig. 4), window 9 and door 10 openings and load-bearing walls 1, 2, 3, 4 with fences 5, 6 (floor and ceiling ), which are lined with sound-absorbing structures, as well as piece sound absorbers 7 and 8, containing the frame in which the sound-absorbing material is located, and installed above the noisy equipment 11.

The floor structure on an elastic base (Fig. 2) contains a mounting plate 12 made of concrete reinforced with vibration damping material, which is installed on the base plate 15 of the floor with cavities 16 through layers of vibration damping material 14 and waterproofing material 13 with a gap 17 relative to the bearing walls 1, 2, 3, 4 production facilities. In order to ensure effective vibration isolation of the mounting plate 12 in all directions, the layers of the vibration damping material 14 and the waterproofing material 13 are made with a flange that is tightly adjacent to the supporting structures of the walls 1, 2, 3, 4 and the base supporting plate 15 of the floor.

To increase the vibration isolation and earthquake resistance of the building, the basic supporting slabs 15 of the floor (Fig. 2 shows the slab 15 of the floor for only one floor of the building and on one side of the supporting walls 1, 2, 3, 4) are equipped with a system in their places of attachment to the supporting walls of the building spatial vibration isolation, consisting of horizontally located vibration isolators 27 and 29, perceiving vertical static and dynamic loads, as well as vertically located vibration isolators 28, perceiving horizontal static and dynamo cal load. A diagram of vibration isolators made of elastomer is shown in FIG. 5-6. Each of the vibration isolators 27, 28, 29 consists of rubber plates rigidly interconnected: the upper 38 and the lower 37 (Figs. 5 and 6), in which through holes 39 are made, located on the surface of the vibration isolator in a checkerboard pattern. The shape of the vibration isolators is made square or rectangular, and their side faces can be made in the form of curved surfaces of the n-th order, ensuring the uniform frequency of the vibration isolation system as a whole. The holes 39 have a cross-sectional shape that provides equal frequency vibration isolation.

To increase the efficiency of sound insulation and sound absorption in the workshops located under the floor, the cavities 16 are filled with vibration damping material, for example, foamed polymer, for example polyethylene or polypropylene, and walls 1, 2, 3, 4 are lined with sound-absorbing structures. As sound-absorbing material of sound-absorbing structures, slabs made of rockwool basalt-based mineral wool or URSA-type mineral wool or P-75 basalt wool or glass-wool lining are used, and the sound-absorbing element is acoustically lined over its entire surface transparent material (not shown in the drawing), for example, fiberglass type E3-100 or polymer type "Poviden."

As a sound-absorbing material, a rigid porous material can also be used, for example, foam aluminum or cermets, or a shell rock with a degree of porosity in the range of optimal values: 30–45%. As a sound-absorbing material, a material in the form of crumbs from solid vibration-damping materials, for example, elastomer, or polyurethane, or plastic compound can be used, moreover, the size of the fractions of the crumb lies in the optimal range of values: 0.3 ÷ 2.5 mm (not shown in the drawing).

The ceiling 5 is made acoustic suspended and consists of a rigid frame 18, made in the form of a rectangular parallelepiped with the dimensions of the parties in the plan a × b, the ratio of which lies in the optimal range of values a: b = 1: 1 ... 2: 1, suspended from the ceiling the production building with the help of pendants 21, mounted on a rod 19, rigidly connected by means of brackets 20 to the frame 18. The frame is fixed to the ceiling using dowels (not shown). A perforated sheet 24 is attached to the frame, on which a layer of sound-absorbing material 22 is located through the layer of transparent acoustic material 23, and fixtures 26 are installed in the frame. When installing an acoustic ceiling, the optimum size ratios must be observed: d - from the point of suspension of the frame to any of its sides and c is the thickness of the layer of sound-absorbing material, and the ratio of these sizes should be in the optimal range of values: c: d = 0.1 ... 0.5. The perforated sheet 24 has the following perforation parameters: the diameter of the holes 25 - 3 ÷ 7 mm, the percentage of perforation 10 ÷ 15%, and the shape of the holes can be made in the form of holes of a round, triangular, square, rectangular or rhomboid profile (round holes are shown in the drawing ) In the case of non-circular holes, the maximum diameter of a circle inscribed in a polygon should be considered as a conditional diameter.

The vibration isolation system of the foundation 30 with the basement 31 (Fig. 4) is carried out by installing the elevated part of the building on the vibration isolators (Fig. 5-6) while cutting it with anti-seismic seams (not shown) from neighboring buildings and the surrounding soil. To protect against vertical vibrations, vibration isolators are installed in the niches of the walls of the basement 31 on sections of the strip foundation 34. Each set of vibration isolation systems consists of a metal plate, 4 vibration isolators (Figs. 5 and 6), 2 sheets of sandpaper to eliminate the possibility sliding basement elements and 2 supporting reinforced concrete blocks (not shown in the drawing).

To protect the building from horizontal vibrations propagating through the ground, a vibration isolation system is arranged along the vertical faces of the outer walls 33 of the basement floor 31 at the level of the foundation 30 and floor 15 (Fig. 2). To this end, a retaining wall is arranged around the entire building, the buttresses 32 of which are connected to the ends of the bearing walls through vibration isolators (Figs. 5 and 6), which are installed in the niches 36 of the buttresses 32. The design of the vibration-insulated building has increased rigidity.

The basement of the building is made in the form of a spatial frame structure made of monolithic reinforced concrete with overlapping and partitions included in the frame (not shown in the drawing). This design provides increased rigidity of the building, compensating for its decrease due to bearing on vibration isolators. For the same purpose, jumpers are reinforced above door and other openings (not shown in the drawing) so that the stiffness of the partitions does not change, and the foundation 30 is made in the form of a tape cross structure with a height of about 50 cm, protruding above the foundation slab.

Earthquake-resistant building construction works as follows.

Sound energy from the equipment 11 located in the room falls on the layers of sound-absorbing material of sound-absorbing structures, which are lined with load-bearing walls 1, 2, 3, 4 with fences 5, 6 (floor 6 and ceiling 5), as well as piece sound absorbers 7 and 8, containing a frame in which sound-absorbing material is located and which are installed above noisy equipment 11. The transition of sound energy into heat (dissipation, energy dissipation) occurs in the pores of the sound absorber, which are a model of Helmholtz resonators, where energy occur due to friction with the driving frequency of the oscillating mass of air located in the neck of the resonator neck wall itself, has the form of branched networks pore absorber. The perforation coefficient of the perforated wall is taken to be equal to or more than 0.25. To prevent the eruption of a soft sound absorber, a fiberglass fabric, for example, type EZ-100, is located between the sound absorber and the perforated wall.

Suspension of the suspended acoustic ceiling is carried out on the suspensions 21, which are attached to the ceiling using dowels, and the other end is fixed to the frame 18 through the rod 19 and the brackets 20.

The sound-absorbing structure for cladding the walls of the building (Fig. 7) is made in the form of a smooth, rigid wall 40 and a perforated wall 46, between which there is a multilayer sound-absorbing element made in the form of five layers, two of which adjacent to the walls 40 and 46 are sound-absorbing layers 41 and 45 of materials of different densities, and the three central layers 42, 43, 44 are combined, and the axial layer 43 is made sound-absorbing, and two symmetrically located and adjacent layers 42 and 44 are made of sound-reflecting complex profile material comprised of evenly distributed hollow tetrahedrons allowing reflect incident in all directions the sound waves. The perforated wall 46 has the following perforation parameters: diameter of the holes is 3 ÷ 7 mm, the percentage of perforation is 10 ÷ 15%, and the shape of the holes can be made in the form of holes of a round, triangular, square, rectangular or rhomboid profile, while in the case of non-circular holes as the conditional diameter should be considered the maximum diameter of the circle inscribed in the polygon.

Each of the walls 40 and 46 can be made of structural materials with a layer of soft vibration-damping material, for example, VD-17 mastic or “Gerlen-D” type material applied on one or two sides of the material, and the ratio between the thicknesses of the material and vibration-damping coating lies in the optimal range of values: 1 / (2.5 ... 3.5).

Each of the walls 40 and 46 can be made of stainless steel or galvanized sheet with a thickness of 0.7 mm with a protective and decorative polymer coating of the type “Pural” 50 μm thick or “Polyester” 25 μm thick, or an aluminum sheet 1.0 mm thick and coating thickness 25 microns. The perforation coefficient of perforated sheets is taken to be equal to or more than 0.25.

Each of the walls 40 and 46 can be made of solid decorative vibration-damping materials, such as plastic compounds such as Agate, Anti-Vibrate, Shvim, and the inner surface of the perforated surface facing the sound-absorbing structure is lined with an acoustically transparent material, such as fiberglass type EZ-100 or with a “poviden” polymer, or with non-woven materials, for example, “lutrasil”.

As a sound-reflecting material layers 42 and 44 may be applied based material alyuminesoderzhaschih alloys, followed by filling them with air or titanium hydride having a density in the range of 0.5 ... 0.9 kg / m ³ with the following strength properties: compressive strength within 5 ... 10 MPa, bending strength in the range of 10 ... 20 MPa, for example foam aluminum, or soundproof boards based on glass staple fiber of the Shumostop type with a material density of 60 ÷ 80 kg / m ^{3 were used} .

As sound-absorbing material of layers 41, 43 and 45, rockwool-type mineral wool or URSA-type mineral wool, or P-75-type basalt wool, or glass wool lined with glass wool, or foamed polymer, for example, can be used. polyethylene or polypropylene. Moreover, the sound-absorbing material is lined with an acoustically transparent material over its entire surface, for example, EZ-100 fiberglass or a “visible” polymer, or the surface of the fibrous sound absorbers is treated with special porous paints that allow air to pass through (for example, Acutex T) or coated with breathable fabrics or non-woven materials, e.g. Lutrasil. In addition, as the sound-absorbing material of the layers 41 and 43, a porous sound-absorbing material, for example, foam aluminum, or cermets, or a shell rock with a degree of porosity in the range of optimal values: 30–45%, or metal foam, or a material in the form of pressed crumbs from solid vibration-damping materials, for example elastomer, polyurethane, or plastic compound like “Agate”, “Anti-vibration”, “Shvim”, and the size of the crumbs fractions lies in the optimal range of values: 0.3 ... 2.5 mm, and they could also porous mineral piece materials were used, for example, pumice, vermiculite, kaolin, slag with cement or other binder, or synthetic fibers, while the surface of the fibrous sound absorbers is treated with special porous airborne paints, for example, Acutex T type, or coated with breathable fabrics or non-woven materials e.g. Lutrasil.

To reduce or correct the reverberation time of premises, sound-absorbing materials and structures (sound absorbers) are used in its decoration.

Porous sound absorbers are made in the form of plates that are attached to the enclosing surfaces directly or on the basis of light and porous mineral piece materials - pumice, vermiculite, kaolin, slag, etc. with cement or other binder. Such materials are strong enough and can be used to reduce noise in corridors, foyers, staircases of public and industrial buildings.

The raw materials for their production are wood fibers, mineral wool, glass wool, synthetic fibers. The surface of the fibrous sound absorbers is treated with special porous paints that allow air to pass through (for example, Acutex T), or covered with breathable fabrics or non-woven materials, such as Lutrasil.

Currently, fibrous sound absorbers are the most common in construction practice. They not only proved to be the most effective from an acoustic point of view in a wide frequency range, but also meet the increased requirements for room design.

Sound-absorbing design works as follows.

Sound energy from equipment located in the room, or another object that emits intense noise, passing through the perforated wall 46 enters the layer 45 of soft sound-absorbing material, and then encounters layers 44, 43 and 42 of complex reflective sound-reflecting material, respectively , consisting of uniformly distributed hollow tetrahedra, allowing to reflect sound waves incident in all directions, but part of the sound energy passes through layers 42 and 44 of sound-reflecting material, and interactions It interacts with the axial layer 4 of sound-absorbing material, where the final dissipation of sound energy occurs.

Layers 41 and 45 of soft sound-absorbing material of different densities can be made, for example, of basalt or glass fiber. In fibrous absorbers, the dissipation of the energy of air vibrations and its transformation into heat occurs at several physical levels. Firstly, due to the viscosity of the air, and there is a lot of it in the interfiber space, the oscillation of air particles inside the absorber leads to friction. The transition of sound energy into thermal energy (dissipation, energy dissipation) occurs in the pores of the sound absorber, which are Helmholtz resonator models, where energy losses occur due to friction of the mass of air in the resonator neck oscillating with the excitation frequency against the walls of the mouth itself, which has the form of a branched sound absorber pore network. In addition, there is air friction on the fibers, the surface of which is also large. Thirdly, the fibers rub against each other and, finally, energy dissipation occurs due to the friction of the crystals of the fibers themselves. This explains that at medium and high frequencies the sound absorption coefficient of fibrous materials is in the range of 0.4 ... 1.0.

Sound waves propagating in the production room interact with cavities filled with sound absorber.

The seams separating the retaining wall from the building and the building from neighboring buildings are arranged as anti-seismic seams (not shown in the drawing) and thoroughly cleaned from construction waste. A system is provided for their protection (not shown in the drawing) from clogging during operation of the building to exclude the penetration of vibrations into the building.

All highways, pipelines, etc. communications passing through the foundation to the building or equipment installed on it are arranged with compensators or cut off from the foundation by sliding seams (not shown in the drawing). Installation locations for ventilation, electrical, etc. equipment in the basement selected from the conditions of access to vibration isolators (not shown in the drawing), their installation and dismantling.

The interaction of sound waves with active cavities filled with a non-combustible sound absorber leads to sound attenuation in the high-frequency range, and due to the presence of cavities, the sound absorption surface increases, and, as a result, the sound absorption coefficient increases.

When installing vibroactive equipment on the plate 12, two-stage vibration protection occurs due to vibration damping inclusions in the mass of the plate 12, as well as due to the layer of vibration damping material 14, which can be used as: Vibrosil needle-punched mats based on silica or aluminoborosilicate fiber, material from solid vibration-damping materials, for example plastic compound, from soundproof plates based on glass staple fiber of the “Shumostop” type with a material density of 60 ÷ 80 kg / m ³ .

Claims (1)

An earthquake-resistant building structure containing a building frame with a basement in the basement with a vibration isolation system, load-bearing walls with fences in the form of floor and ceiling, which are lined with sound-absorbing structures, window and door openings, and piece sound absorbers containing a frame in which sound-absorbing material is located, and installed above the noisy equipment, the basic load-bearing floor slabs are equipped in places of their attachment to the load-bearing walls of the building with a spatial vibration isolation system consisting of horiz vibrational isolators located perceiving vertical static and dynamic loads, as well as vertically located vibration isolators perceiving horizontal static and dynamic loads, while the floor in the premises 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 interfloor overlapping with cavities through layers of vibration damping material and waterproofing material with a gap relative to the supporting walls of the production room, and the cavity of the base plate is filled with vibration damping material, such as foamed polymer, the elastic floor base is made of needle-punched mats of the type “Vibrosil” based on silica or aluminosilicate fiber, the ceiling is made of acoustic suspended, consisting of a rigid frame suspended from the ceiling of the production buildings with a sound-absorbing structure inside the frame made of sound-absorbing material wrapped in acoustically transparent m material, and a perforated sheet is attached to the frame, and the frame is made in the form of a rectangular parallelepiped with side dimensions in the a × b plan, the ratio of which lies in the optimal range of values a: b = 1: 1 ... 2: 1, as well as optimal aspect ratio c: d = 0.1 ... 0.5; where d is the distance from the suspension point of the frame to any of its sides; c is the thickness of the layer of sound-absorbing material, while the frame elements are fastened together by brackets rigidly connected to the bar, to which the suspensions are attached, and the perforated sheet has the following perforation parameters: perforation diameter - 3 ... 7 mm, perforation percentage 10% ... 15% moreover, luminaires are installed in the frame, the vibration isolation system of the foundation with the basement is made with simultaneous cutting of its seams of the type antiseismic from neighboring buildings and the surrounding soil, and to protect it from vertical vibrations vibration isolators are installed in niches of the walls of the basement on the sections of the strip foundation, and each set of vibration isolation system consists of a metal plate, four vibration isolators, two sheets of sandpaper to eliminate the possibility of sliding of the foundation elements and two supporting reinforced concrete blocks, while protecting the building from horizontal vibrations spreading along the ground, a vibration isolation system is arranged along the vertical faces of the outer walls of the basement floor at the level of the foundation and floor, at the same time, a retaining wall is arranged around the entire building, the buttresses of which are connected to the ends of the bearing walls through vibration isolators that are installed in the buttresses of the buttresses, the basement of the building is made in the form of a spatial frame structure made of monolithic reinforced concrete with overlapping and partitions included in the frame, as well as reinforced jumpers above door and other openings with constant stiffness of the partitions, and the foundation is made in the form of a tape cross structure with a height of about 50 cm, protruding above the foundation With a screed plate, each of the vibration isolators consists of rubber plates rigidly interconnected: upper and lower, in which through holes are made, located on the surface of the vibration isolator in a checkerboard pattern, and the shape of the vibration isolators is made square or rectangular, and their side faces are made in in the form of curved surfaces of the nth order, ensuring the equal frequency of the vibration isolation system as a whole, while the holes have a cross-sectional shape that provides equal frequency vibration isolation, while the building’s absorbing structure is made as a multilayer sound-absorbing element made in the form of five layers, two of which adjacent to the walls are sound-absorbing layers of materials of different densities, and the three central layers are combined, the axial layer being sound-absorbing and two symmetrically arranged adjacent layers to it are made of a sound-reflecting material of a complex profile, consisting of uniformly distributed hollow tetrahedrons, which allow reflecting falling in all directions sound waves, each of the perforated walls has the following perforation parameters: hole diameter - 3 ÷ 7 mm, perforation percentage 10 ÷ 15%, and the shape of the hole can be made in the form of holes of a round, triangular, square, rectangular or diamond shape, with in the case of non-circular holes, the maximum diameter of a circle inscribed in a polygon should be considered as a conditional diameter, characterized in that mineral wool slabs on ba are used as sound-absorbing material rockwool type alto base, or URSA type mineral wool, or P-75 type basalt wool, or glass wool lined with glass wool, and the sound-absorbing element is lined with an acoustically transparent material over its entire surface, such as fiberglass type E3-100 or polymer type "Visible", or as a sound-absorbing material, a porous sound-absorbing material, for example foam aluminum, or cermet, or a shell rock with a degree of porosity in the range of optimal values: 30 ÷ 45%, or less alloporolone, or material in the form of compressed crumbs from solid vibration-damping materials, for example elastomer, polyurethane, or plastic compound such as Agate, Anti-Vibrate, Shvim, and the size of the fractions of the crumb lies in the optimal range of values: 0.3 ... 2.5 mm, and also porous mineral piece materials, such as pumice, vermiculite, kaolin, slag with cement or other binder, or synthetic fibers can be used, while the surface of the fibrous absorbers is treated with special porous paints that transmit air, for example, such as Acutex T, or covered with breathable fabrics or non-woven materials, such as Lutrasil.

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