BG4513U1 - Chamber for triaxial dynamic destruction of soil samples - Google Patents

Abstract

The chamber for triaxial dynamic testing of soil samples according to the present utility model is used in laboratory practice for determining the mechanical characteristics of dispersed soils and in particular for tracking the variation of the mechanical properties (shear-strength parameters of the soil in laboratory conditions) and stiffness (deformation moduli, Poisson’s ratio, dilatancy angle) of the dispersed system under dynamic impacts with high shearing deformation values. Said chamber for triaxial dynamic testing of soil samples consists of a cylindrical case (1) which accommodates a soil sample (1a) covered with a silicone membrane (9) clamped by two sealing rings (7). Said case is closed between an upper flange (2) and a lower flange with ribbed porous surface (8), wherein under the upper flange (2) there is an upper load stamp (10) with ribbed porous surface (8) and an opening (10a). Furthermore, mounted above the upper flange is a compressive load piston (5) provided with a sealing block (3) and a retaining slot (4). The lower flange consists of a flange carrying a seal for the rotational axis (6b) and a lower movable load stamp (6a) mounted on it, wherein said stamp is connected to a bearing-supported rotary shaft (11), a rotary fork (12) and a protective cap (13), and has ribbed porous surface (8) and an opening (6c). Furthermore, the compressive load piston (5) mounted on the upper flange (2) is provided with a stop mechanism (15), and a chamber sealing block (14) is positioned at the centre of said flange carrying a seal for the rotational axis (6b).

Description

Field of technique

The chamber for triaxial dynamic testing of soil samples is used in laboratory practice to determine the mechanical characteristics of dispersed soils and, in particular, to monitor the change of mechanical parameters (parameters of soil shear strength in laboratory conditions) and stiffness (moduli of deformations) , Poisson's ratio, dilatance angle) of the dispersed system under dynamic effects with large values of the shear strains.

Prior art

A large part of the known apparatus for dynamic tests is discussed in the cited literature [1]. Anisotropic stress state tests of soil specimens in a triaxial chamber are known, performed by Broms and Casbarian 1965, later modifications of: Hight et al. (1983), Alarcon et al. (1986), Ampadu and Tatsuoka (1993), Huang et al. (1994) and others. As a result of summarizing the capabilities of the testing apparatus, the most suitable prototype turns out to be the popular three-axis Wykeham Farrance apparatus, which tests soil samples (samples) until failure by applying static loads.

The construction of the three-axis apparatus "Wykeham Farrance", consists of a hydraulic loading system, a chamber for testing soil samples and auxiliary equipment - a compressor and a distilled water system, and serves to study the mechanical parameters (modulus of deformations, Poisson's ratio, angle of internal friction and cohesion) of soil samples. This apparatus creates conditions for testing soil test specimens by pressure in the three spatial directions until their destruction, applying only a static load to the soil specimens.

During testing, the soil sample is placed in a chamber formed by a transparent cylindrical body, which is closed by an upper and lower flange. The chamber is filled with deaerated distilled water. The penetration of water into the soil sample is prevented by a silicone membrane pressed with two sealing rings. The openings of the upper load seal and the lower flange with the lower load seal serve for the installation of elements of the pipe system for monitoring the pore pressure and water saturation of the soil sample.

The actual test is carried out after the preparatory phase - filling the chamber with distilled water, sealed with the upper and lower flanges and applying pressure, which forms an all-round pressure on the test specimen. The test is carried out by applying a vertical force (increasing at a constant rate until failure of the test specimen) to the loading piston equipped with a sealing block and a counterslot. The procedure is developed according to BDS EN ISO 17892-8,9 standards.

The "Wykeham Farrance" apparatus allows in laboratory conditions to obtain mechanical soil parameters under "static" loading conditions.

The disadvantages of the "Wykeham Farrance" three-axis apparatus are that dynamic loads cannot be applied, which for natural reasons lead to a decrease in the mechanical parameters of the dispersed medium. This limits the possibility of applying the obtained mechanical parameters under specific load conditions caused by the operation of machines and conditions of seismic impacts, leading to a significant reduction of the values of the mechanical parameters of the dispersed medium.

Technical nature of the utility model

The purpose of the utility model is to create a chamber for triaxial dynamic testing of soil specimens by applying torsional cyclic loads, which allows the determination of the mechanical properties of the dispersed medium under conditions of additional cyclic deformations applied to the test specimens so as to resemble the natural dynamic loading conditions.

The task of the utility model is solved with a chamber for three-axis dynamic testing of soil samples, which consists of a cylindrical housing in which a soil sample is placed, covered by a silicone membrane, pressed with two sealing rings. The cylindrical body is closed between the upper and lower flanges, and under the upper flange is the upper load seal, equipped with a porous, ribbed surface, and above it is mounted a pressing load piston, equipped with a sealing block and a counterslot. The lower flange is divided into two elements and consists of a modified flange with a seal for the axis of rotation and a lower movable load seal located thereon, which is connected to a bearing-mounted rotary shaft, a rotary motion fork and a protective cap, and is equipped with a porous, ribbed surface, in which the pressure loading piston mounted on the upper flange is provided with a locking mechanism, and for the upper loading seal located below it, a locking mechanism is also provided. In the center of the bottom flange with the shaft seal is a chamber sealing block/including searing and stuffing box.

The openings of the upper load seal and the lower flange serve for the installation of elements of the pipe system for monitoring the pore pressure and water saturation of the soil sample.

The advantages of the useful model are expressed in the possibility to study the behavior under dynamic external loads and the tracking of a significant reduction in the values of the mechanical parameters of the dispersed medium. With this, it is possible to make reliable predictions through analytical models in the conditions of dynamic loads and seismic impacts through the parameters thus studied.

Explanation of the attached figures

Figure 1 is a longitudinal projection of the chamber for triaxial dynamic testing of soil samples;

Figure 2 depicts details of locking elements: a) on a load piston and c) on an upper load seal;

Figure 3 shows a detail of a lower cargo seal;

Figure 4 shows the construction of a lower chamber flange.

Examples of implementation of the utility model

An exemplary embodiment of the proposed chamber for three-axis dynamic testing of soil samples, improving the well-known three-axis apparatus "Wykeham Farrance", according to figure 1, includes a transparent cylindrical body 1 enclosed between an upper flange 2 and a lower flange, which to provide cyclic rotational impact is divided into two (modified) - a lower flange of the chamber with a seal for the axis of rotation 6b and a lower load seal 6a located on it. The movement of the lower load seal 6a is developed with a bearing of a rotary shaft 11, a fork for rotary movement 12 and a protective cap 13.

The soil sample 1a is placed between the upper load seal 10 and the lower movable load seal 6a and is covered by a silicone membrane 9 pressed by two sealing rings 7. On the upper load seal 10, equipped with a porous, ribbed surface 8, a pressing load piston is mounted 5, equipped with a sealing block 3 and a counter slot 4. The sealing of the chamber is solved by a sealing block 14, including a sealing and a gland joint. Stop mechanisms 15 and 16 are added, the stop mechanism 15 prevents the load piston 5 from rotating, and the stop mechanism 16 is mounted on the top load seal 10 again to prevent rotation of the top load seal 10. The holes 10a of the top load seal seal 10 and hole 6c of the lower flange with lower load seal 6a serve for installation of elements of the pipe system for monitoring the pore pressure and water saturation of the soil sample 1a.

The cyclic (dynamic) impact is applied to the lower end of the test samples by means of the lower movable load seal 6a and by means of the rotary shaft 11 and the fork 12, the soil sample 1a is torsionally affected. The drive allows modulation of the amplitude of the shear strains and the impact frequency. The loading system mechanism controls the magnitude of the force causing the twisting moment and the resulting shear stresses in the test specimen. Through a similar load simulation on the soil sample 1a, conditions close to the soil behavior under dynamic (seismic) impacts in the range of large shear deformations [from 10 ^-1 to 10], which are not covered by the known conventional apparatuses for dynamic studies, are modeled.

The actual test is carried out after the preparatory phase - filling the chamber with distilled deaerated water, sealed with flanges 2 and 6b and applying pressure that forms an all-round pressure on the test sample 1a. The test is carried out by applying a vertical force (increasing at a constant rate until the destruction of the test specimen) on the loading piston 5. By applying a static load from the piston 5, by means of the elements: the lower flange of the chamber 6b, the lower movable loading seal 6a, connected to a rotary shaft 11 (Fig. 3), rotary movement fork 12, supporting protective cap 13 and sealing block 14 (Fig. 4) dynamic cyclic impacts are applied to the studied soil sample 1a. To ensure the test conditions in order to prevent movements at the upper end of the soil sample 1a, a locking element 15 on the upper flange 2 and a locking element 16 on the upper load seal 10 (Fig. 2) are introduced.

The system creates rotational dynamic cyclic loads on the test specimen 1a, which leads to a decrease in the mechanical parameters (parameters of soil shear strength in laboratory conditions) and stiffness (moduli of deformations, Poisson's ratio, dilatancy angle) of the soil specimen 1a, which is an important prerequisite for their detailed study under conditions of dynamic loads.

Thus, the modified construction of the chamber for triaxial dynamic tests creates an opportunity to study the changes of the mechanical soil parameters at different magnitudes and amplitudes of the dynamic impact (applied with elements: 6a, 6b, 11, 12, 13 and 14). The investigated mechanical parameters can be directly used for the unambiguous definition of the constitutive models (MohrCoulomb, Hardening Soil Model, Cam-Clay, Modified Cam-Clay), which serve for analytical studies of soil environments through finite element methods.

With the proposed and described chamber for three-axis dynamic testing of soil samples, a series of tests on clays in undisturbed condition were performed and the obtained results were verified. Under the conditions thus created, a series of parameters sufficient to define "MohrCoulomb" soil models and the increasing stiffness model were measured. (HSM) as:

• Behavior of the stress deviator;

• Pore pressure;

• Deformation moduli, • Poisson's ratios, • Dilatancy angle, • Shear strength characteristics under standard conditions and under cyclic loads.

The investigated parameters were tracked both under standard conditions of the triaxial test and under conditions with additional cyclic loading on the lower end of the specimen. The change in each of the parameters was sought by comparison.

Model parameters are widely used in analytical studies and predictions (numerical studies) related to analysis of the behavior of geotechnical engineering systems (especially underground transport and technological ones) under conditions of time-varying load models - dynamic and seismic.

Claims (1)

A chamber for triaxial dynamic testing of soil samples, which consists of a cylindrical housing, in which is placed a silicone membrane for enclosing a soil sample pressed by two sealing rings and closed between an upper flange and a lower flange, provided with a porous, ribbed surface, as under the upper flange is located the upper load seal, also provided with a porous, ribbed surface and an opening, and above it is mounted a pressing load piston equipped with a sealing block and a counterslot, characterized in that the lower flange consists of a flange with a seal for the axis of rotation (6b), located on it a lower movable load seal (6a), which is connected to a bearing rotary shaft (11), a fork for rotary movement (12) and a protective cap (13), and is equipped with a porous, ribbed surface (8) and opening (6c), in which the pressure loading piston (5) mounted on the upper flange (2) is equipped with a locking mechanism (15), and the upper loading seal (10) located below it is equipped with a locking mechanism (16) ), and in the center of the lower flange with a seal for the axis of rotation (6b) is located the chamber sealing block (14)