SU1567921A1 - Device for checking bound ground - Google Patents

Abstract

The invention relates to soil mechanics and can be used to determine the strength and deformation characteristics of a soil. The aim of the invention is to improve the accuracy in determining the deformation characteristics of soils in their various layers under the conditions of a complex triaxial stress state. In the high-pressure chamber 1, the clamps 5 and 6 are placed, to which the walls 3 and 4 of the annular cylindrical shell are tightly attached, in the cavity of which the soil sample 22 is placed. The cavity of the shell is communicated with the sensor 19 of the threshold pressure with the help of tubular probes 18, perforated, the telescopic ends of which are placed in the cavity of the shell. Measuring the magnitude of the force (tensile or compressive), torque, external pressures, and pore pressure in different sections of the soil sample, determine its deformation characteristics under conditions of a complex stress state. 1 il.

Description

The invention relates to soil mechanics and is intended to determine the strength and deformation characteristics of the soil in a complex stress state.

The purpose of the invention is to improve the accuracy in determining the deformation characteristics of soils in their various layers in a complex triaxial stress state.

The drawing shows a structural diagram of the device.

A device for testing cohesive soil contains a high-pressure chamber 1 made of organic glass, a cover 2, a cylindrical shell made annular with the outer 3 and inner 4 walls. The walls 3 and 4 of the shell are hermetically attached to the grippers 5 and 6, while this forms an annular cavity, which is designed to accommodate the sample. The loading unit consists of a loader 7 with an axial force, made in the form of a block system, rigidly connected to the gripper 5 by the rod 8. and the loader 9 with a torque rigidly connected to the gripper 6 by the rod 10. The grips 5 and 6 are made of internal parts 11 and 12 and the outer parts 13 and 14 to ensure sealing of the ends of the shell. Perforated plates 15 and 16 are installed in the grippers 5 and 6, and the gripper 6 also contains an annular stop 17, in which tubular probes 18 with perforated telescopic ends located in the cavity between the walls 3 and 4 of the shell are installed. Using tubular probes 18, the shell cavity is in communication with a pore pressure sensor 19, the sensing element of which is made in the form of an annular membrane 20. A pressure source (not shown) is in communication with the chamber cavity 1, as well as with the cavity formed by the inner wall 4 of the annular shell with a hole 21 in stock 8.

The device operates as follows.

A ring-shaped soil sample 22 is mounted in a cavity formed by the walls 3 and 4 of the shell. The perforated ends of the probes 18 are introduced into the sample to a predetermined depth. The sample 22 is loaded by tensile or compressive force, torque, and also pressure in the chamber 1 and in the cavity formed by the wall 4 of the shell. Since the annular sample 22 is tested in the device, all the main stresses arising in it will be independent, while the stress state in it will be uniform in different sections. By measuring the magnitude of the force (tensile or compressive) torque, external pressures. as well as pore pressure in various sections of the soil sample 22, determine its deformation characteristics under conditions of a complex stress state.

Claims (1)

Claim A device for testing cohesive soil, containing a high-pressure chamber, grips placed in the chamber, a cylindrical shell whose ends are hermetically attached to the grippers, a loading unit associated with one of the grippers, a pressure source in communication with the chamber, and a pore pressure sensor in communication with the hull of the cylindrical shell, characterized in that, in order to improve accuracy, the cylindrical shell is made annular, and the device is equipped with tubular probes, one end of which is connected to a pore pressure sensor and the other is perforated and telescopic and installed in the cavity of the shell, and the cavity formed by the inner wall of the shell is in communication with a pressure source.