SU1483023A1 - Bed for simulating strained state of ground foundations - Google Patents

Abstract

The invention relates to construction and is intended to study the stress-strain state of the subsoil foundations of buildings and structures. The aim of the invention is to expand the imitational capabilities of the stand by specifying complex combinations of deformation of the base model. The bench for modeling the stress-strain state of the soil bases contains a cylindrical tray, a cover with a central hole in which a piston is placed, devices for creating and measuring horizontal, vertical deformations connected to sources and pressure gauges. In this case, the cylindrical tray is provided with internal horizontal annular ribs forming annular cells in which a device for creating and measuring horizontal deformations is placed, made in the form of annular elastic chambers with U-shaped tires. The lid is provided with annular vertical and intersecting radial ribs, which form sector cells, in which is placed a device for creating and measuring vertical deformation, made in the form of sector elastic chambers with segmented tires. 2 Il.

Description

The inner side is provided with annular vertical 5 and radial ribs 6 intersecting them, forming sector cells.

The device for creating and measuring horizontal deformation is made in the form of annular elastic chambers 7 with U-shaped tires 8, each of which is located in the annular cells of the tray. Some annular elastic chambers 7 are connected to a pressure source 9 by fittings 10, passed through holes in the wall of tray I, pipes 11 and a distribution pipe 12. Other ring elastic chambers 7 are connected by means of pipelines to pressure gauges 13 which include exemplary manometers 13 and volometers 14 connected to each other and to the distribution pipe 12. Volumometers 14 are connected to the reserve tank 15 by pipe 16. The reserve tank 15 is equipped with a pressure gauge 17.

The device for creating and measuring the vertical deformation is made in the form of sector elastic chambers 18 with segmented roof-reserve tank 15 and goes into oolometers 14. After the liquid level in volumeters 14 reaches zero, the taps are closed.

Tray I is filled with primer. Mount the cover 2, which is attached to the tray 1 by bolting. Wires 21 are connected to fitting 20. The taps and fluid from the reserve tank 15 are opened through pipes 24 and 21 enters chambers 18.

Then the air from the source 9 of the pressure J5 does not reach the reserve tank 15 through the dilution pipe 12, creating an overpressure in it. Under the action of this pressure, the liquid enters the volumeters 23, and when adding

When the fluid level is zero, the taps are closed. A pressure gauge 17 serves to control the pressure supplied to the reserve tank 15. Next, the liquid is evacuated into

25 pipelines, in chambers 7 and 18 and volumeters 14 and 23.

A stamp 3 is placed in the opening of the cover 2 on the surface of the ground. On the frame 26, there are two defibomers 19. Each of the sector 30, ra 25 is attached, which is connected by strings 27

By stamp 3. The stand is prepared for testing.

elastic chambers placed in the corresponding sector cells of the cover 2

concentric relative to the piston. One sector elastic cameras

483023 h

reserve tank 15 enters the gauges 14. After the liquid level in volumeters 14 reaches the zero point, the taps are closed.

Tray I is filled with primer. Mount the cover 2, which is attached to the tray 1 by bolting. Wires 21 are connected to fitting 20. The taps and fluid from the reserve tank 15 are opened through pipes 24 and 21 enters chambers 18.

Then the air from the source 9 of the pressure J5 does not reach the reserve tank 15 through the dilution pipe 12, creating an overpressure in it. Under the action of this pressure, the liquid enters the volumeters 23, and when adding

When the fluid level is zero, the taps are closed. A pressure gauge 17 serves to control the pressure supplied to the reserve tank 15. Next, the liquid is evacuated into

25 pipelines, in chambers 7 and 18 and volumeters 14 and 23.

A stamp 3 is placed in the opening of the cover 2 on the surface of the ground. On the frame 26, two deflections are fastened.

tray depends on the purpose of the simulation

18 are connected to a hydrostatic 35 source 9 of a nationally deformed state pressure by means of fittings 20 passed through openings in the lid, pipelines 21 and distribution pipe 12.

Other sector elastic chambers 40 through pipelines 21 are connected to pressure gauges, which include reference gauges 22 and volumeters 23, connected

nor; rutovy base. The soil in the tray} along its vertical boundary surface can be specified as horizontal stresses, as well as deformations, and variables according to the head. Both the stresses and displacements can be set along the horizontal upper surface of the soil, and that is very much

between each other and with the distributing pipe 45, but different within the horizontal drive 12. Volumometers 23 are connected to the reserve tank 15.

The stand is provided with pipeline 24, deflectors 25 mounted on frame 26, and a string 27 connecting die 3 to defibrometers 25.

The stand works as follows.

The annular elastic chambers 7 are filled with working fluid from the tank reservoir 15. Air from the pressure source 9 is supplied to the backup pipe 12 and the overpressure is created in it, under the action of which the liquid from

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Tray 1 Boundary Surface.

The work of the stand in setting the deformation along different boundary surfaces is as follows. The gas pressure in volumeters 14 is transmitted to the liquid and through pipelines 11 and fittings 10 to apply to annular elastic chambers 7, which, expanding in the direction of the ground, compact it. The pressure from the chambers 7 is transferred to the U-shaped tires 8, which have the ability to slide along the ribs 4, resulting in pressure from the annular elastic chambers of the foam-deformed state; The soil in the tray} along its vertical boundary surface can be set as horizontal stresses and deformations, with variables in depth. Both the stresses and displacements can be set along the horizontal upper boundary surface of the soil and, which are very significantly different within the horizontal range.

Tray 1 Boundary Surface.

The work of the stand in setting the deformation along different boundary surfaces is as follows. The gas pressure in volumeters 14 is transmitted to the liquid and through pipelines 11 and fittings 10 to apply to annular elastic chambers 7, which, expanding in the direction of the ground, compact it. The pressure from the chambers 7 is transferred to the U-shaped tires 8, which have the ability to slide along the ribs 4, as a result of which the pressure from the annular elastic chambers is transferred to the ground. Soil deformations cause an increase in the volume of the annular chambers 7, which is fixed with a sonometer 14. Using the initial geometric dimensions of the U-shaped tires (circumference and width) and the change in the volume of liquid in volumeters 14, the radial displacement of the soil is calculated.

The application of vertical normal stresses to the horizontal surface of the soil is produced both by loading the punch 3 and by creating hydrostatic pressure in the sector elastic chambers 18.

In the case of setting the ground with vertical normal stresses equal within the area of the cover 2, the gas pressure in the volumetric meters 23 is transferred to the liquid through pipelines 21 and spreads into the sector elastic chambers 18. The chambers 18 can only expand vertically downwards, since on the other sides, each of them is bounded by a lid 2, radial b and annular 5 ribs. The pressure from the chambers 18 is transmitted to the segmental tires, and from the latter to the ground. The deformation of the soil causes an increase in the volume of sector chambers 18, which are fixed with volumeters 23. By the size in terms of each sector chamber 18 and the change in its volume in the process of increasing pressure, the average soil displacement within each chamber is calculated.

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Claims (1)

The invention includes a bench for modeling the stress-strain state of soil foundations, comprising a cylindrical tray for accommodating a base model, a lid with a central hole in which a piston is placed, and a device for creating and measuring horizontal deformation connected to a source and gauge. -pressure, characterized in that, in order to expand the imitation capabilities of the stand 5 by specifying complex combinations of deformation of the base model, the stand is equipped with a device for creating and measuring vertical deformation connected to a source and a pressure gauge, a cylindrical tray with internal horizontal annular ribs forming annular cells, and a cover with vertical annular ribs intersecting with radial ribs, forming sector cells, while the device for creating and measuring horizontal deformations is made in the form of annular elastic chambers with U-shaped 0 tires, each of which is placed in annular cells, and a device for creating and measuring vertical deformation - in the form of sector elastic chambers with segmental-shaped tires, each of which is placed in the sector cells of the lid concentric with the piston.