SU883238A1 - Unit for testing soil in stimulators - Google Patents

Description

The invention relates to the construction and is intended to determine the physico-mechanical properties of soils.

A known installation for the study of soils on models, including a tray with transparent walls mounted on the base, a frame and a loading device with a stamp of £ 1].

The disadvantage of this installation is the low accuracy of measuring the values of "10 strength properties of soils.

The closest technical solution to the proposed is the installation for the study of soils on models, including a base, a prefabricated tray with a floor, a lid and transparent walls mounted on it, a power frame with a support beam, a load device with a jack and a stamp and a measuring device with dynamometers [2] .

A disadvantage of the known installation is the low accuracy during research. high volumes of soil on the models due to possible deformation of the walls of the tray, as well as the great complexity of work when unloading the tray.

The purpose of the invention is to improve the accuracy of soil research and labor productivity.

This goal is achieved by the fact that in the known installation for the study of soils on models, which includes a base, a prefabricated tray with a floor, a lid and transparent walls mounted on it, a power frame with a support beam, a load device with a jack and a stamp and a measuring device with dynamometers, the base is made of collapsible sections and is equipped with a platform with guide racks supported on a support beam, rollers and gutters pivotally mounted under them on movable supports, and the tray is made of separate cots with a sliding floor mounted on casters, while the power frame is articulated

The yen has a base platform and is equipped with guide bolts with a plate on which the jack is mounted, and the loading device is equipped with a die holder freely mounted on the guide racks, mounted with the ability to move the die to a predetermined height, and dynamometers are installed between the die holder and the plate.

Figure 1 shows the installation, a General view in plan (top view); in FIG. 2 - section aa in figure c; in figure c; section bb in figure 1,

The installation comprises a tray 1, made of collapsible sections, with removable transparent walls made of stenite 2, mounted on a collapsible base 3, with rollers 4 mounted thereon, moving the sliding floor 5 and articulated by a trough 6 having an angle of inclination at moving the movable support 7, while the base is rigidly connected to the platform 8, on which a power hinge frame 9 is mounted, resting on a base plate 10, rigidly connected to the guide racks 11 provided with a movable die holder 12, moving which is secured by a cable 13, stored in blocks 14, attached below by a stamp 15, and on top by reinforced dynamometers 16, which take the load from the jack 17, fixed rigidly on the plate 18, moving along the guide bolts 19, which are movably connected to the cover 20, which protects against distortions during raising and lowering the jack, as well as having an opening closed by a valve 21.

Work on the installation is as follows.

The test soil is poured into the tray 1 and a stamp 15 is placed on its surface using a cable 13 and blocks 14. Then, with a jack 17, the upper end of the opera · on the support beam 10, and the lower end on the plate 18, the load is transferred through dynamometers 16 and stamp 15 and soil. Under the stamp, soil deformation occurs, according to which soil characteristics are evaluated.

Improving the accuracy of the study of simulated soils under load in comparison with the known installation is achieved by approximating the volume in the tray to the full-scale ones, the presence of a clearance surface for visual observation and measuring the movement of soil in 2 directions.

When conducting a static load test, the mechanical characteristics of the soils included in the base calculations are determined (deformation modulus (E _o \ compressibility coefficient cf, sediment modulus e ^.

Precipitation of the surface of the soil and the stamp during their loading is fixed with the help of deflection meters not associated with the tray and frame.

To identify the existence of the shape of a compacted core, as well as the development of deformations in the soil, with a gradually increasing load under the stamp, devices are provided for both stationary and fastening movable screens (not shown) that move together with the stamp 15.

A change in soil density depending on humidity, with a gradually increasing load, will be recorded by an AP-1 type acoustic densitometer.

After the test, the load and measuring devices are dismantled. The power frames 9 are pulled apart, sliding sheets (floor) 5 are opened, the movement of which is facilitated by the movable rollers 4 and the soil wakes up in the groove 6, which changes the angle of inclination with the help of the movable support 7, which serves to facilitate the complexity of cleaning the gutter from the ground.

Then, with the help of a cable 13 connecting the die holder 12 through the blocks 14, which moves along the guide racks 11, they lift the stamp 15 and at the same time lift the jack 17, mounted on the plate 18 along the guide bolts 19, into the existing hole closed by the valve 21 and the installation is brought into an inoperative position .

Tests on the installation can be carried out with different soil, changing the geometric dimensions using collapsible sections, which are dictated by the size of the stamp.

The installation will improve the accuracy of the study of simulated soils under different loads, reduce the complexity of research by 4-5%.

Claims (2)

The invention relates to construction and is intended to determine the physical and mechanical properties of soils. A known installation for investigating soils on models, comprising a tray with transparent walls, mounted on a base, a frame and a loading device with a die l}. The disadvantage of this setup is the low accuracy of measurements of the values of the strength properties of soils. The closest technical solution to the present invention is an installation for studying soils on models, including a base, a collecting tray mounted on it with a floor, a cover and transparent walls, a power frame with a beam, a load device with a jack and a stamp, and a measuring device with a dinometer 2. A disadvantage of the known installation is the low accuracy in the study of large volumes of soil in the model lx because of the possible deformation of the walls of the tray, as well as the greater complexity of work when unloading the tray. The purpose of the invention is to increase the accuracy of soil studies and labor productivity. The goal is achieved by the fact that in a well-known installation for investigating soils on models, including a base installed on it a collecting tray with a floor, a lid and transparent walls, a load frame with a support beam, a load tool with a jack and a stamp and a measuring tool with dynamometers , the base is made of collapsible sections and is equipped with a platform with KNZMI struts supported by a support beam, rollers and chutes mounted under them on movable supports, and the tray is made of The sections are mounted on rollers with a sliding floor, while the power frame is pivotally connected to the base platform and provided with guide bolts with a plate on which a jack is installed, and the loading device is provided with a stamp holder mounted on the guide racks, which is installed with the possibility of moving the stamp onto the specified height, with dynamometers mounted between the die holder and the plate. Fig. I shows the installation, a general plan view (top view;); figure 2 - section aa in figure 1 in fig.Z section bb in figure 1, the Installation includes a tray 1, made of collapsible sections, with removable transparent walls of steelstone 2, mounted on a prefab collapsible base 3, with hinged rollers 4 hinged therein, moving a sliding floor 5 and a hinged gutter 6 having an inclination angle when moving the movable support 7, while the base is rigidly connected to the platform 8 on which the force hinge frame 9 is mounted, resting on the base plate 10 rigidly connected to the guide posts 11, equipped with a movable die holder 12, moving at the expense of the cable 13, stored in bi 4, attached by a punch 15, and at the top by reinforced dynamometers 16, receiving a load from a jack 17, fixed rigidly on a plate 18, moving bolts 19 moving along 1p111M, movably connected to the lid 20, which protects from distortion when raising and lowering the jack, as well as having an opening closed by a valve 21. The work on the installation is performed as follows. Tray 1 is poured into tray 1 and a gatamp 15 is installed on its surface with the help of cable 13 and blocks 14. Then a jack 17, an upper end opera to a support beam Yu, and a lower end to a slab 18, transfer the load through dynamometers and a stamp 15 and the ground. Under the stamp, a deformation of the soil occurs, according to which the characteristics of the soil are evaluated. An increase in the study of simulated soils under load, as compared with the known installation, is achieved by approximation; volume in the tray to the field, the presence of a viewing surface for visual observation and measurement of the movement of the soil in 2 directions. When tested by static load, the mechanical characteristics of the soils, which are included in the calculation of the E1 base, are determined (deformation modulus (E, compressibility factor о, sediment modulus 6). The sediments of the soil surface and die are fixed with the help of defibomers not related to tray and frame. In order to detect the existence of a compacted core form, as well as the development of deformations in the soil, with gradually increasing load under the punch, provisions are made for both mounting fixed and dp No moving screens (not shown) moving together with the punch 15. The change in soil density depending on humidity will be recorded with an AL-1 acoustic density meter with a gradually increasing load. After the test, the load and measuring fixtures are installed. the power frames 9, the sliding sheets of pop 5 are opened, the movement of which is facilitated by the movable rollers 4 and the soil spills into the groove 6, which changes the angle of inclination with the help of the movable support 7, the complexity of the cleaning of the chute from the ground. Then, using a cable 13 connecting the punch holder 12 through the blocks 14, moving along the guide posts 1I, raise the punch 15 and at the same time raise the jack 17 fixed on the plate 18 using the guide bolts 9 into the existing hole closed by the valve 21 and the installation is brought out non-working position. Tests on the installation can be carried out with different soils, changing the geometric dimensions with the help of collapsible sections, which are dictated by the size of the stamp. The installation will improve the accuracy of the study of simulated soils under different loads, reduce the complexity of research by 4-5%. The invention The installation for the study of soil on models, including the base, mounted on it a collection tray with a floor, a cover and transparent walls, a power frame with a support beam, a load tool with a jack and a head and a measuring tool with dynamometers, different from that, in order to improve the accuracy of soil studies and labor productivity, the base is made of collapsible sections and is equipped with a platform with guide posts supported on the support beam, rollers and hinged One of them on movable supports is grooves and the tray is made of separate sections 86 with a sliding floor mounted on rollers, while the power frame is pivotally connected to the base platform and equipped with guide bolts with a plate on which a jack is installed, and the load device is freely positioned on the The racks are installed by a stamp holder mounted to move the stamp to a predetermined height, with dynamometers mounted between the stamp holder and the plate. Sources of information taken into account during the examination 1. USSR author's certificate No. 508717, кп. q 01 N 3/10, 1975. 2. Grounds, foundations and soil mechanics. M., 1973, No. 3, p.29. .. SSL h e-sag: ssrJa zg 883238 e . 6-S 20 ff