RU2631283C1 - Vibration-insulated foundation with pneumatic vibration insulation system - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: vibration-insulated foundation with a pneumatic vibration insulation system includes a foundation bath filled with a compressed gas, a support block arranged in the foundation bath, an elastic element made in the form of a torus filled with a compressed gas and located between the side surfaces of the foundation bath and the support block, and a supply pipeline of the compressed gas. The support block is made hollow with throttling openings communicating its cavity with the foundation bath cavity and with the torus cavity. The compressed gas supply pipeline is brought into the support block cavity and to the autoregulator for maintaining the upper surface level of the support block, an additional damping device is rigidly fixed to its lower surface, made hollow in the form of a framework having an equidistant shape with the support block, located between the support block and the foundation bath bottom, on which the framework rests through mesh washer dampers and the cavity of which is connected to the support block cavity through a throttling opening.

EFFECT: increasing the efficiency of vibration damping, reducing dynamic loads on the lower structure of the building foundation.

2 cl, 2 dwg

Description

The invention relates to means of protection from the harmful effects of vibration and can be used in construction, in particular in devices of vibration-insulated foundations for machines and equipment with dynamic loads.

The closest technical solution to the claimed object is a vibration-insulated foundation containing a bath placed in it with a gap relative to the walls and bottom of the foundation block, pivotally connected to vibration isolators installed in the bottom of the bath, according to the patent of Russian Federation No. 2281999, E02D 27/44 - (prototype) .

The disadvantages of the prototype are the relatively low efficiency of spatial vibration isolation and design complexity due to the use of roller bearings.

The technical result is an increase in the efficiency of damping oscillations and a decrease in dynamic loads on the lower structure of the foundation.

This is achieved by the fact that in a vibration-insulated foundation with a pneumatic system of vibration isolation, including a foundation bath filled with compressed gas, a support block placed in the foundation bath, an elastic element made in the form of a torus filled with compressed gas and placed between the side surfaces of the base bath and the support block and the compressed gas supply pipe, the support block is hollow with throttling holes communicating its cavity with the cavity of the foundation bath and with the torus cavity, the supply pipe with This gas is brought into the cavity of the support block, and an automatic damping device is made rigidly fixed to the lower surface of the support block to maintain the level of the upper surface of the support block, made hollow in the form of a frame having an equidistant shape with a support block located between the support block and the bottom of the base bathtub, on which the frame is supported through mesh washer dampers and the cavity of which is connected to the cavity of the support block through a throttling hole.

In FIG. 1 shows a vibration-insulated pneumatic foundation, a frontal section, in FIG. 2 - mesh washer damper 10 additional damping device.

The vibration-insulated foundation with a pneumatic vibration isolation system contains a support block 1, on the upper surface of which a vibration-insulated object (not shown) is installed and which is placed in a foundation bath 2 filled with compressed gas. The elastic element 3 of the vibration isolation system of the foundation is made in the form of a torus 3 filled with compressed gas and placed between the side surfaces of the foundation bath 2 and the support block 1.

The support block 1 is made hollow and is connected by a horizontal throttling hole 4 with a torus cavity 3 and a vertical throttling hole 5 with the cavity of an additional hollow damping device 9, made in the form of a frame having an equidistant shape with the support block 1, and rigidly connected to the bottom surface of the support block 1 , and located between the support block 1 and the bottom of the foundation bath 2, on which the frame is supported through mesh washer dampers 10. The cavity of the frame of an additional, hollow damping device State 9 is connected to the cavity of the support block 1 through a vertical throttling hole 5.

The pipeline 6 for supplying compressed gas is introduced into the cavity of the support block 1 and through the pipeline 7 to the self-regulator 8 to maintain the level of the upper surface of the support block 1.

Vibroinsulated foundation with a pneumatic system of vibration isolation works as follows.

When the equipment installed on the upper surface of the support block 1 vibrates, the compressed gas enters the cavity of the support block 1, then through the throttling hole 4 - into the cavity of the elastic element 3, which dampens lateral vibrations of the object and is made in the form of a torus, and also through the throttling hole 5 the cavity of the additional damping device 9 located in the foundation bath 2.

In this case, the oscillation energy is dissipated in the throttling holes 4 and 5. For example, in lateral vibrations, an elastic element in the form of a torus 3 works, and for vertical, the cavity of the support block 1 and the cavity formed by the side surfaces of the foundation bath 2, support block 1 and torus 3, which serves as a sealing diaphragm. The compressed gas supply pipe 6 maintains the pressure in the system and responds to a change in the weight of the installed equipment, always ensuring the same level of the support block 1 relative to the bottom of the foundation bath 2. The quality of vibration isolation is improved by two-stage dissipation of vibrational energy in the device cavities, and the expense is saved concrete is achieved by performing the supporting element hollow.

The mesh washer damper 10 of the additional damping device comprises a base 11 in the form of a plate with fixing holes 12, a main mesh elastic element 17, supported by the lower part on the base 11, and fixed by the lower washer 16, rigidly connected to the base 11, and fixed by the upper pressure washer on the upper part 15, rigidly connected to a centrally located piston 14, covered with a gap, coaxially located sleeve 13, rigidly connected to the base 11. Between the lower end 18 of the piston 14 and the bottom 19 of the sleeve 13 located n elastic element 20, for example of polyurethane.

The density of the mesh structure of the elastic mesh element is in the optimal range of values: 1.2 g / cm ³ ... 2.0 g / cm ³ , and the wire material of the elastic mesh elements is steel grade EI-708, and its diameter is in the optimal range of 0 , 09 mm ... 0.15 mm. The density of the mesh structure of the outer layers of the elastic mesh element is 1.5 times higher than the density of the mesh structure of the inner layers of the elastic mesh element.

The main elastic mesh element 17 can be made combined of a mesh frame, filled with an elastomer, for example polyurethane.

It is possible that the elastic element 20, located between the lower end face 18 of the piston 14 and the bottom 19 of the sleeve 13 is made mesh, with the same parameters of the mesh structure as the main elastic mesh element 17.

It is possible that the elastic element located between the lower end of the piston and the bottom of the sleeve is made mesh, and the density of the mesh structure is 1.5 times higher than the density of the mesh structure of the main elastic mesh element.

It is possible that the elastic element located between the lower end of the piston and the bottom of the sleeve is made combined of a mesh frame filled with an elastomer, for example polyurethane.

Vibration isolator washer mesh works as follows.

When vibrations of a vibroinsulated object (not shown in the drawing) located on the upper pressure plate 15, the elastic mesh element 17 perceives both vertical and horizontal loads, thereby weakening the dynamic effect on the vibroisolated object, i.e. spatial vibration protection and shock protection are provided.

Claims (2)

1. Vibro-insulated foundation with a pneumatic system of vibration isolation, including a foundation bath filled with compressed gas, a support block placed in a foundation bath, an elastic element made in the form of a torus filled with compressed gas and placed between the side surfaces of the foundation bath and the support block, and a supply pipe compressed gas, the support block is made hollow with throttling holes communicating its cavity with the cavity of the foundation bath and with the torus cavity, characterized in that the supply pipe is compressed gas is introduced into the cavity of the support block and onto the auto-regulator to maintain the level of the upper surface of the support block, while an additional damping device made hollow in the form of a frame having an equidistant shape with a support block located between the support block and the bottom of the foundation bath is rigidly fixed to its lower surface , on which the frame is supported through mesh washer dampers and the cavity of which is connected to the cavity of the support block through a throttling hole. 2. Vibration-insulated foundation with a pneumatic vibration isolation system according to claim 1, characterized in that the mesh washer damper of the additional damping device comprises a base, an elastic mesh element and washers interacting with the bushings, the base is made in the form of a plate with mounting holes, the main mesh elastic element, the lower part rests on the base and is fixed by the lower washer rigidly connected to the base, and the upper part is fixed by the upper pressure washer rigidly connected to the central a put piston, covered with a gap, a coaxially located sleeve rigidly connected to the base, and between the lower end of the piston and the bottom of the sleeve there is an elastic element, and the elastic element between the lower end of the piston and the bottom of the sleeve is made of a combined mesh frame filled with an elastomer, for example polyurethane, or mesh, with the parameters of the mesh structure, as in the main elastic mesh element.

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