SU796306A1 - Method of investigating stress-strain state of soil block - Google Patents

Description

The invention relates to the construction, in particular, to a technique for studying stresses in a soil massif, mainly in bulk soils arising under the action of 5 natural pressures and various external loads, and can be used to study the stress-strain state of the massif when determining sediment of machines and structures Yu niy.

An optical polarization method is known for determining stresses in models made of optically active materials and then transferring the results to the soil mass. This method gives only a qualitative picture of the distribution of static stresses fl].

There is also a known method for investigating the stress-strain state of a soil massif, which includes drilling a well, immersing measuring instruments in a ground mass, measuring and recording compressive 25 stresses [2].

The compressive stresses measured by pressure transducers are used in engineering practice as calculated characteristics for determining the separation of soil sediments under natural and external loads, it is reasonably justified if only static compressive pressures act in the array. The dynamic loads recorded by the sensors cannot be taken into account in calculating soil sediments in the same way as static ones, due to the short and unstable duration of power pulses that deform the soils differently.

The purpose of the invention is to improve the measurement accuracy of the confusion to ensure the determination of both static and dynamic stresses.

This goal is achieved by the fact that in the method of research stress-strain the state of the soil mass, including well drilling, immersion in the soil mass of measuring instruments, measurement and recording of compressive stresses, a static probe is immersed in the soil mass with subsequent measurement in separate ranges of drag and selection samples from these intervals, then compress the selected samples under different stages of compressive pressures, followed by immersion in them e static probe and sample test results plotted resistivity of compressive pressure, and then the results of static sensing array, by said graphics determine total compressive stress at different points along the array depth.

To implement the method of determining stresses, the following conditions must be met: the density of the soil in passivity before exposure to the load should be less than after loading. the duration of the load action in the array and in the device must be coordinated, the dimensions of the working cylinder with the sample and the probe tip must be coordinated so that the sounding depth is 2-3 saz greater than the height of the cone tip, and the aeon of lateral pressure from the cone is 2-2 , 5 diameters of the cone did not reach the walls of the cylinder or neighboring sounding zones, the FSB diagrams) should be built for testing homogeneous soil, and with a complex structure of the array, for each soil difference, a similar gr fic.

The elastic deformations of soft rocks under average static pressures from an external load (3-5 kgf / cm ² ) can be neglected; if necessary, they should be taken into account; instead of the q, (0) plots, use the dependence q (% 6 _H ) obtained in a similar way, but at provided that the soil is probed in the device at different compaction loads (%), after partial unloading to a certain pressure (b _pln ).

In FIG. 1-3 show, respectively, the graphs of the dependences of the resistivity to the sounding of the array (q kgf / cm ² ) on the depth (Z, m); specific resistance to sounding of the sample from compressive stresses fe _; kgf / cm ² ) and the diagram of the distribution of equivalent compressive stresses along the depth of the array.

Equivalent compressive stresses are determined under the D-384A bulldozer taking into account the natural pressure of the soil, and static testing of the sand-clay dump at the track passage site is carried out, to the depth of the active compression zone, and a graph q is plotted for individual points (2). The area of the conical tip 5 cm ² ; taper angle 30 °.

Compression-sounding tests of the soil are carried out on samples taken here from the dump, by repeatedly repeating alternating operations on different samples on compaction of the soil in the odometer with different stages of compressive stress (0.5-1.0-2.0-3.0-4 , 0 kgf / cm ² -) and static sensing, through the hole in the odometer piston, with the same conical tip, after each step and build on separate points corresponding to the indicated load steps, graph q (6).

Equivalent compressive stresses are determined from the weight of the rock and the machine at different depths, using the graphs q {(?) And q (Z), 'for this, q values were found for different depths, q (z) were plotted, and then the corresponding values ύ according to the schedule q (d), and build the desired schedule (see Fig. 3)

Using the invention allows to determine the total effect of soil compaction under the influence of various combinations of static and dynamic stresses acting in the array in different directions, both under the own weight of the soil and under the influence of external loads. Using the obtained results as design characteristics allows more accurately determine the precipitation of the soil mass and the equipment and structures located on it. The method is simpler and more affordable for mass research, and also requires less time and money.

Claims (2)

(54) A METHOD FOR STUDYING A STRESSED-DEFORMABLE STATE OF SOIL MASSIVE of the same static probe, and based on the test results of the samples, a graph of resistivity versus compressive pressures is calculated, and then using the results of the static sounding of the array, using the specified graph, determine the total compressive pressure. different points along the depth of the array. In order to implement the method of determining stresses, the following conditions must be met: the density of the bulk in the passive before the influence of the load must be less than after loading. the duration of the load in the array and in the device must be matched; the dimensions of the working cylinder with the sample and the probe tip must be matched so that the sounding depth is 2-3 oas larger than the height of the cone and the end of the side pressure from the cone, 2- 2.5 diameters of a cone did not reach the walls of the cylinder or adjacent zones of sounding graphs (Sb) should be built to test a homogeneous soil, and with a complex array structure, for each difference of the soil a similar pattern should be built Fick, Elastic deformation: soft, under average static pressures from an external load (3-5 kgf / cm) can be neglected, if necessary taking into account them, instead of graphs with (6), use the dependence q (() obtained in a similar way , but under the condition that the probe is probed in the device, with different sealing loads (b)), after partial unloading to a certain pressure (6). FIG. Figures 1–3 show, respectively, the plots of the resistivity of the sounding of the array (q, kgf / cm) versus the depth (Z, m) -, the resistivity of the sounding of the sample against compressive stresses fo J kgf / cm and the distribution diagram of equivalent compressive stresses the depth of the array. Equivalent compressive stresses under the D-384A bulldozer are determined taking into account the natural pressure of the soil, while producing a static sounding of the sand-clay dump of the dump at the site of the caterpillar passage, to the depth of the active zone of compression and on individual points, plot the c: j, ( 2). The area of the conical tip 5 cm; taper angle 30 °. It carried out compression-sensing tests of the soil on samples taken here from the dump by repeatedly repeating alternate operations on different samples to soil compaction in the odometer with different steps of compressive stresses (0.5-1.0-2.0-3, 0-4,0 kgf / cm) and static sounding, through opening one meter in the piston, with the same conical tip, after each step and build on separate points corresponding to the specified step of 1 m load, CJ schedule, (6). The equivalent compressive stresses of the weight of the rock and the machine at different depths are determined using graphs C (b) and q, (2.), with q values for different depths, according to schedule I. () g and then corresponding their values of d on schedule C (, (6), and build the desired graph (see Fig. 3 i. Using the invention allows to determine the total effect of soil compaction under the action of various combinations of static and dynamic stresses acting in an array in different directions x, as under its own weight of the soil, and under the influence of external loads. The use of the obtained results as design characteristics allows more accurate determination of the sediments of the soil massif and equipment and structures located on it. The method is simpler and more accessible for mass studies, and also requires less time and money. stress-strain state of the soil massif, including drilling a well, immersing measuring instruments in the soil massif, measuring and recording compressive stresses from In order to improve measurement accuracy by ensuring that both static and dynamic stresses are determined, a static probe is immersed in a soil array, followed by measuring at individual drag intervals and sampling from these intervals, then compression is performed. samples under different pressure stages with subsequent immersion of the same static probe into them; according to the test results, the resistivity versus compression is plotted pilot pressures, and then the results of static probe array using said schedule determined cumulative compressive stress at different points along the array depth. Sources of information taken into account in the examination 1. I. Nosov. Modeling of mining processes and phenomena. - Photoelasticity method. MIRGEM. M., 1965, p.65. 2. Baranov D.S. Measuring instruments, methods and some results of pressure distribution studies in sandy soil, M., TsNIISK, 1959, no. 7, s. 48. FIG. I US 0 (.rc / cfft 0uz.2 6, frrc / eff 2.0 1.5 Z, M 3