RU52415U1 - SCREEN TO PROTECT BUILDINGS AND STRUCTURES FROM VIBRATIONS - Google Patents

Abstract

The invention relates to the construction, namely, the construction of screens to protect the foundations and above-ground parts of buildings and structures from vibration. The screen includes the inner and outer rows of wells located near the building or structure on the side of the vibration source, filled with protective material and arranged in rows in a checkerboard pattern. The protective material is placed in an elastic shell of at least two layers. The effectiveness of protection is increased by reducing lateral resistance at the boundary of the protective material with the walls of the well by reducing contact friction and adhesion forces along the side surface of the protective material. The manufacturability of the screen is also increased due to its simplification.

Description

The technical solution relates to the construction, namely, the construction of screens to protect the foundations and aboveground parts of buildings and structures from vibration.

A known screen for protecting structures from seismic effects, for example, in the mouth of the bridge by bus. St. USSR No. 1370173, class E 01 D 19/02, publ. in BI No. 4 for 1988, which includes layers of antifriction material located on top of each other and having a curved concave outline, placed in the ground immediately in front of the protected structure. The disadvantage of the screen is that after the wave propagates during seismic action, air gaps are formed between the layers and the ground, since due to the available plasticity of the soil, its deformation from the seismic effect is partially restored. As a result, upon repeated exposure to the wave, air gaps can cause a dynamic impact of the soil, and therefore lead to the destruction of the structure. Thus, the specified screen may be ineffective with repeated seismic impact. In addition, the installation of the screen is time-consuming, since it requires a large amount of work to excavate and embed the soil.

A device for vibroacoustic isolation of an object according to ed. St. USSR No. 1675504, class E 02 D 31/08, 27/44, 27/34, publ. in BI No. 33

for 1991, including a screen made of protective material located in the ground around the protected object, made of a compacted material containing elastic-viscous fine particles with established wave resistance and surface density and placed on an elastic-viscous pillow. The screen in the specified device protects the building structure is not effective enough due to the large lateral resistance at the boundary of the protective material with the walls of the trench due to the large contact friction and adhesion. In addition, the protective material is placed in a trench, which requires a large amount of excavation and the use of powerful equipment.

The closest analogue in terms of technical nature and the combination of essential features is a screen for protecting buildings and structures from seismic influences according to ed. St. USSR No. 1629416, class E 02 D 31/08, publ. in BI No. 7 for 1991, including the internal and external rows of wells located around the building, structures, filled with vibration-absorbing material and staggered in rows. At the same time, the step between the wells of the inner row and the size of the jumper between the wells of the inner and outer rows are established, depending on the diameter of the wells. A screen of this design dampens the wave during seismic action is also not effective enough due to the large lateral resistance at the boundary of the absorbing material oscillation with the well walls due to the large contact friction and adhesion. As a result, the oscillations of the soil particles are transmitted to the particles of the specified absorbing material in the wells, then to the soil particles in the bridges and then to the second row of wells. In addition, the manufacture of the screen is not technologically advanced, since in practice it is difficult to maintain the established dimensions of the jumpers and the pitch between the wells of the inner row.

The technical task of the proposed solution is to increase the efficiency of protecting buildings and structures from vibration by reducing lateral resistance at the boundary of the protective material with the well walls by reducing contact friction and adhesion forces along the side surface of the protective material, as well as increasing the manufacturability of the screen due to its simplification.

The problem is solved in that in the screen for protecting buildings and structures from vibration, including the inner and outer rows of wells filled with protective material and arranged in staggered rows located near the building or structure from the side of the vibration source, according to the technical solution, the protective material is placed in elastic shell, at least two-layer.

The protective material, as in the prototype, is a mixture of light bulk materials with elastic - plastic properties and provides protection of buildings and structures during vibration from longitudinal waves, causing compression and stretching of the soil, due to the elasticity and internal friction of particles of light bulk materials making up the mixture . These properties of the particles of this mixture due to the relaxation of stresses at the contacts of the particles convert the vibrational energy into heat, ensuring its efficient dissipation into the surrounding space. Placing said mixture in an elastic shell of at least two layers provides a decrease in lateral resistance at the boundary of the protective material with the walls of the well by reducing contact friction and adhesion along the side surfaces of the protective material. As a result, the response of the structure to vertical (shear) vibrations from shear and surface waves is reduced, which is especially important, since the foundations of buildings and structures are located close to the soil surface. With the approach of such a wave, the screen design works as a shock absorber, and dissipates the wave energy due to the induced vibrations of the protective particles

material due to their mutual friction on the contacts. The effectiveness of protection against this is increased. The manufacturing technology of the screen is also simplified, since additional protection in the form of an elastic shell having several layers eliminates the need for strict observance of the size of jumpers and the pitch between the wells of the inner row, as is necessary in the prototype.

It is advisable to place a lubricant powder between the layers of the elastic shell. This minimizes the friction of sliding between the layers of the elastic shell, thereby increasing the effectiveness of the protection.

The essence of the technical solution is illustrated by an example of a specific embodiment and the drawings of figures 1-4, where it is shown: Fig. 1 is a longitudinal section of a screen for protecting buildings and structures from vibration along a well filled with a protective material in an elastic shell (against the background of the building); figure 2 - graphs of vibrations during vibration (above the transverse wave, below the longitudinal); figure 3 is a view a in figure 1 (cross section on the specified screen with a two-row arrangement of wells); figure 4 - experimental vibrogram of the incident wave (curve 1 - to the specified screen, curve 2 - after it, near the building).

It has been practically established that during dynamic precipitation of the foundations of buildings and structures, pressures are transferred to their foundations, which are close to the maximum permissible standards, due to the formation of plastic shifts in their thickness. Such precipitation often occurs not only in loose, but also in dense sand or clay soils (with the exception of hard). They can last for decades and reach considerable size under the influence of even relatively weak shocks, especially under the influence of vibrations, since under the influence of vibrations, as is known, the shear resistance of soils decreases. Therefore, the effective protection of buildings and structures with screens is an urgent task.

The screen for protecting buildings and structures from vibrations (hereinafter - the screen) contains, for example, the building 1 (Fig. 1) from the side of the vibration source (not shown in Fig.) The inner and outer rows of wells 2 filled with protective material 3, which placed in an elastic shell 4, for example, two-layer. The number of layers of the elastic shell 4 is determined by economic feasibility. Wells 2 are arranged in rows (Fig. 3) in a checkerboard pattern (without gaps). The elastic shell 4 is made in the form of a stocking, for example, of polyvinyl chloride, polyisobutylene, polyethylene, polyamide, fluoroplastic, etc. materials and placed in the hole 2 of circular cross section, and then filled with a protective material 3. The latter is an elastic - plastic mixture of light bulk materials. As plastic materials with internal friction and low specific gravity, foam balls are used that are not subject to decomposition and significant compression under pressure, crushed stone and / or sand from expanded clay, agloperite, vermiculite, perlite, and slag. As the elastic components of this mixture, rubber crumb or shavings, rubber rings, polyurethane balls, and the like are used. materials. Between the layers of the elastic sheath 4, a lubricating powder material, for example, talc or graphite powder, can be placed.

The screen is used as follows.

From the source of vibration propagate longitudinal and transverse waves (figure 2). In a longitudinal wave, soil particles oscillate in the direction of wave movement, and in a transverse wave, vertically with its horizontal movement, therefore, soil deformations from longitudinal waves represent only compression and tension, and from shear waves only shear deformations, which are especially dangerous. The most dangerous are surface waves that penetrate into the soil to a shallow depth (of the order of the wavelength). Foundations of buildings and structures

located relatively close to the soil surface and serve as receivers of these waves.

Building 1 is protected from longitudinal waves by protective material 3 - a mixture of light bulk materials with elasticity and internal friction. Under vibration exposure, such a mixture works as a shock absorber, and the induced vibrations of the particles of the protective material 3, due to relaxation of stresses at the contacts of the particles, turn the vibrational energy into heat and dissipate it into the surrounding space. The elastic shell 4 due to the minimum friction of its layers against each other damps the transverse waves. Thus, due to the combined action of the elastic shell 4 and the protective material 3, the vibration effect is weakened already after the outer row of wells, and after the inner row, which forms the barrier wall with the first one due to the checkerboard arrangement of the wells, it is effectively suppressed.

The experiments performed showed the following.

The sites on which the studies were conducted were composed of homogeneous soils ~ 15 m thick with a vegetative layer of insignificant thickness. The screen included 2 rows of wells with a diameter of 40 cm and a height of 8 m, staggered. A mixture of rubber and expanded clay chips with an average particle size of ~ 5 mm, in equal proportions by volume, was used as a protective material. As an elastic shell, two-layer polyethylene stockings were used, with a length and diameter equal to the size of the well. Vibration sensors for recording incoming pulses were installed directly on the ground, buried 5-10 cm below the plant layer and pressed tightly, with one vibration sensor detecting the incident wave to the screen, and the second after it passed through the screen. Elastic waves were created by single impacts of a vertically falling load on a stamp mounted on the ground. Under the influence of vertical shocks, surface waves were transmitted from their source, causing oscillations

soil. The experimental vibrogram (figure 4) shows that the amplitude A _{2 of the} displacements of the soil (curve 2) after the incident wave passes through the screen is approximately an order of magnitude smaller than the amplitude A _{1 of the} incident wave to the screen (curve 1), which confirms the effectiveness of the claimed screen.

Claims (2)

1. A screen for protecting buildings and structures from vibration, including the inner and outer rows of wells filled with protective material and arranged in staggered rows located near the building or structure from the side of the vibration source, characterized in that the protective material is placed in an elastic shell, according to at least two-layer. 2. The screen according to claim 1, characterized in that between the layers of the elastic shell is placed lubricating powder material.