RU2169356C1 - Method determining strength of ground - Google Patents

Abstract

FIELD: measurement technology. SUBSTANCE: invention is intended for determination of strength of hard, medium hard and soft grounds under laboratory conditions. Sample of ground in the form of right rectangular parallelepiped is compressed longitudinally by continuously growing force or with preset velocity of longitudinal deformation of sample under uninterrupted recording of longitudinal deformation of sample, value of compressing force and lengths of traces of sliding surface formed on faces of sample and its angle of inclination. Strength of ground is calculated as arithmetic mean of group of values of limit tangential stress computed at moments of either anomalous increase of longitudinal deformation of sample or growth of traces of sliding surface or anomalous decrease of compressing force by certain formula. EFFECT: reduced material and labor input, diminished cost of test. 1 cl, 7 dwg, 1 tbl

Description

 The invention relates to the field of engineering surveys and is intended, in particular, to laboratory methods for determining the strength characteristics of solid, semi-solid and refractory soils.

 A known method for determining the strength of the soil, including compressing the cylindrical sample by all-round pressure and longitudinal force increasing in steps or continuously at a given rate of deformation of the sample until it breaks, registering longitudinal deformation of the sample at each loading stage or at predetermined time intervals, recording all-round pressure and longitudinal force at which the sample collapsed, and the calculation of the strength of the soil by the magnitude of the longitudinal force, the cross-sectional area of the sample and the magnitude not comprehensive pressure (see GOST 26518-85. Soils. Laboratory method for determining the strength and deformability under triaxial compression). The method is implemented using instruments for triaxial soil testing, called stabilometers.

 The disadvantages of this method are: low productivity due to the long duration and complexity of the test; complexity and high cost of testing; the complexity of the design of the stabilometers, providing the implementation of the method; the complexity and complexity of loading the sample into the rubber shell to isolate it from the liquid and into the working chamber; low reliability of the results due to the occurrence of a complex stress-strain state in the sample, which varies in height of the sample (see V. Mizyumsky. Patterns of rock deformation with a natural structure. - Sat. "Geotechnical issues", 1964, N 7, ed. " Transport ", pp. 32-43), and also because of the error in measuring the all-round pressure on the sample, caused by the inevitable loss of part of the liquid volume to deform the elastic element of the pressure meter (Burdot manometer tube, etc.) and the inevitable presence of air bubbles in worker her cell; the impossibility of assessing the error of the soil test results for one sample, because the method allows to obtain only one random result on one sample, and the need, due to the latter, to test several twin samples of the same soil, which significantly increases the duration and cost of determining the strength of the soil.

 Closest to the claimed invention is a method for determining soil strength, including longitudinal compression of a cylindrical soil sample with a continuously increasing force until it breaks, continuous registration of the longitudinal deformation of the sample, registration of the final value of the compressive force at which the destruction of the sample occurred, and calculation of the soil strength by the value of the final compressive force and cross-sectional area of the sample. In addition, to determine the angle of internal friction of the soil, the method includes registering the angle of inclination of the sliding platform along which the sample was destroyed (see GOST 26447-85. Rock formations. Method for determining the mechanical properties of clay rocks under uniaxial compression). The method is implemented using uniaxial compression devices or presses that meet the requirements of the method.

 The disadvantages of this method are: the calculation of the strength of the soil in relation to the force that destroys the sample to its cross-sectional area, while the destruction of the sample occurs under the action of shear stresses and along an inclined sliding platform; the impossibility of assessing the error of the results of soil tests on one sample, because The method allows to obtain only one random result on one sample, and the need, by virtue of the latter, to test several twin samples of the same soil, which requires a large number of soil samples and significantly increases the duration and cost of determining the strength of the soil.

 The purpose of the invention is to increase the reliability of the results of determining the strength of the soil and the productivity of their production.

где τ_lim.i - предельное значение максимального касательного напряжения в i-й момент или аномального увеличения продольной деформации образца, или увеличения длин следов площадки скольжения, или аномального уменьшения сжимающей силы;
ΔP_i - приращение сжимающей силы в i-й момент или аномального увеличения продольной деформации образца, или увеличения длин следов площадки скольжения, или аномального уменьшения сжимающей силы;
b - размер сечения образца в направлении, перпендикулярном распространению следов площадки скольжения;
Δl_i - среднее арифметическое значение приращений длин следов площадки скольжения в i-й момент или аномального увеличения продольной деформации образца, или увеличения длин следов площадки скольжения, или аномального уменьшения сжимающей силы
Δl_i= (Δl_L,i+Δl_R,i)/2, (2)
где Δl_L,i и Δl_R,i - приращения длин следов площадки скольжения соответственно по левой и по правой граням образца;
α - угол наклона площадки скольжения к продольной оси образца;
i - число случаев увеличения длин следов площадки скольжения с начала сжатия образца до его разрушения.This goal is achieved by the fact that, in contrast to the known method for determining the strength of the soil, in the inventive method, which includes longitudinal compression of the soil sample with a continuously increasing force until it breaks, with continuous registration of the longitudinal deformation of the sample, registration of the compressive force and angle of inclination of the sliding platform and calculation of soil strength , the soil sample has the shape of a straight rectangular parallelepiped, and its compression is produced either with a continuously increasing force, or with a given longitudinal strain rate o when continuously recording the magnitude of the compressive force and the lengths of the tracks of the slip area formed on the faces of the sample, the soil strength is calculated as the arithmetic average of the group of values of the ultimate shear stress calculated at the moments of an anomalous increase in the longitudinal deformation of the sample or increase in the lengths of the tracks of the slip platform, or an abnormal decrease in compressive strength by the formula

where τ _lim.i is the limit value of the maximum tangential stress at the i-th moment or an abnormal increase in the longitudinal deformation of the sample, or an increase in the lengths of the tracks of the sliding platform, or an abnormal decrease in compressive force;
ΔP _i - increment of the compressive force at the i-th moment or an abnormal increase in the longitudinal deformation of the sample, or an increase in the length of the tracks of the sliding platform, or an abnormal decrease in the compressive force;
b is the size of the cross section of the sample in the direction perpendicular to the propagation of traces of the slip area;
Δl _i is the arithmetic average of the increments in the lengths of the tracks of the sliding platform at the i-th moment or an abnormal increase in the longitudinal deformation of the sample, or the increase in the lengths of the tracks of the sliding platform, or the anomalous decrease in compressive force
Δl _i = (Δl _{L, i} + Δl _{R, i} ) / 2, (2)
where Δl _{L, i} and Δl _{R, i} are the increments of the lengths of the tracks of the sliding platform, respectively, along the left and right sides of the sample;
α is the angle of inclination of the sliding platform to the longitudinal axis of the sample;
i is the number of cases of increasing the lengths of traces of the sliding platform from the beginning of compression of the sample to its destruction.

 Continuous registration of the lengths of traces of the slip area formed on the faces of the sample is carried out, for example, by video recording with a large-scale grid in the camera’s lens and by applying temporary markers on the video film.

 The above set of distinguishing features of the proposed method for determining the strength of the soil distinguishes it from the prototype and determines the compliance of the proposed method with the criterion of "novelty."

 Since there are no known solutions with similar features, it can be concluded that the claimed method has significant differences and novelty and ensures the achievement of a new positive effect.

 The method is implemented using a testing device, for example, a uniaxial compression device, a press, etc., which is equipped with well-known registration units: compressive force, longitudinal deformation of the sample and the lengths of the tracks of the sliding platform.

One of the possible design options for the test device and explanations for the implementation of the method are schematically shown in the drawing, where:
FIG. 1 is a schematic block diagram of a device;
FIG. 2 - a large-scale grid in the lenses of the video cameras of the registration unit for the lengths of the tracks of the sliding platform;
FIG. 3 - section AA of a soil sample along a developing sliding platform;
FIG. 4 is a graph of an abnormal increase in the longitudinal deformation of a sample when it is compressed by a continuously increasing force;
FIG. 5 is a graph of an abnormal decrease in longitudinal compressive force during compression of a sample with a given rate of longitudinal deformation of the sample;
FIG. 6 is a diagram for calculating stresses in a sample before increasing the trace of a slip site;
FIG. 7 is a diagram for calculating stresses in a sample after increasing the trace of the slip site.

 The test device consists of a housing 1, a working table 2, a loading mechanism 3, a movable plate 4 connected to a movable rod 5 of a loading mechanism, a recording unit of compressive force 6 with a force sensor 7, a registration unit for longitudinal deformation of sample 8 with a displacement sensor 9, a recording unit the lengths of the tracks of the sliding platform 10 and the control unit 11 (Fig. 1).

 The working table 2 is intended for placement on its surface of soil samples 12.

 The loading mechanism 3 provides compression of the sample 12 or a continuously increasing force, or with a given speed of longitudinal deformation.

 The compressive force recording unit 6 provides continuous measurement and recording of the magnitude of the compressive force applied to the sample 12, for example, on the chart tape of the recorder, in electronic memory, etc.

 The longitudinal deformation registration unit of sample 8 provides continuous registration of the longitudinal deformation of the sample, for example, on the chart tape of the recorder, in electronic memory, etc.

 The registration unit for the lengths of the tracks of the sliding platform 10 can be made, for example, in the form of several cameras located at the same level above the side faces of the sample and having a large-scale grid in the lens (Fig. 2), which allows measuring the lengths of the tracks of the sliding platform and its angle of inclination relative to the longitudinal sample axis 12, and devices for applying temporary markers on videotape.

 The method is as follows.

 A soil sample 12, prepared in the form of a straight rectangular parallelepiped, is mounted on the working table 2 of the test device so that the longitudinal axis of the sample 12 is perpendicular to the working table 2 and is aligned with the movable rod 5 of the loading mechanism 3. The loading mechanism 3 is turned on and the movable plate 4 is brought up to contact with the specimen 12. From the moment the movable plate 4 contacts the specimen 12, the units for continuous recording of compressive force 6, longitudinal deformation of the specimen 8 and the lengths of the tracks of the sliding platform 10 are turned on, and -screw mechanism 3 takes a sample of the longitudinal compression 12 or continuously increasing force, or a predetermined rate of axial strain of the sample. Compression of the sample 12 is carried out before its destruction, which occurs along the sliding platform, inclined at an angle α to the longitudinal axis of the sample (Fig. 1). After the destruction of the sample, the test device is unloaded, the results of the registration of the test parameters of the sample are processed and the strength of the soil is calculated by the formula (1). When processing the results of registration of the test parameters, the values of the compressive force and longitudinal deformation of the sample are taken into account, which correspond to the lengths of the tracks of the slip area along which the sample was destroyed.

 Below is the rationale for the legality of the claimed method.

The destruction of the soil during compression occurs in certain areas of the test sample - in the region of maximum tangential stresses τ _max, when they reach the limiting value: τ _max = τ _lim. During longitudinal compression of a prismatic sample, such a zone is oriented at an angle α to the axis of the sample (Figs. 1, 6, and 7). With an increase in the longitudinal compressive force P, the values of τ _max also increase and reach the limiting value of τ _lim for a given soil _, which manifests itself in the form of traces of the sliding platform (Fig. 3) and a short-term anomalous increase in the longitudinal deformation of the sample (with a constant increase in the longitudinal force (Fig. 4)) or a short-term decrease in the longitudinal force (with an increase in the longitudinal deformation of the sample at a given speed (Fig. 5)). These short-term changes occur several times until the maximum (in this test) value of the longitudinal compressive force is reached, each time accompanied by an increase in the traces of the sliding platform.

 The lengths of the tracks of the slip site increase gradually and unevenly in time and unequally on opposite sides of the sample, which can be observed visually. The increase continues until the traces of the sliding platform occupy the entire inclined section of the sample, which corresponds to the moment of its complete destruction.

As you know (see 1) Bondarik G.K. et al. Texture and deformation of clay rocks. - M .: Nedra, 1975 .-- 168 s .; 2) Vyalov S.S. Rheological basis of soil mechanics. - M .: Higher. school, 1978. - 447 pp.), in the zone of maximum tangential stresses τ _max = τ _lim , anisotropic clay particles rotate parallel to the area where these stresses act, after which this area becomes a slip area, i.e. the tangential stresses on it are equal to zero, but it perceives larger than before normal stresses. The increment of traces of the slip area leads to a short-term anomalous increase in the longitudinal deformation of the sample or to a short-term anomalous decrease in the longitudinal compressive force. After restoration of the value of the longitudinal compressive force, the maximum tangential stresses increase along the traces of the glide pad to a value of τ _max = τ _lim, which leads to a new increase in the traces of the glide pad and an anomalous increase in the longitudinal deformation of the specimen or a short-term anomalous decrease in the longitudinal compressive force.

Assume that 1) the stresses in the sample are evenly distributed along a sliding area of length l _i (Fig. 6) —normal compressive σ ₁ and tangent τ ₁ = 0; 2) on the extension of the sliding platform of length (L -1) - normal compressive σ _lim and tangent τ _max = τ _lim. . An increase in the slip area by Δl with an increase in the longitudinal force by ΔP _i leads to a new equilibrium state with the same stress distribution.

где P_e - значение продольной силы перед увеличением площадки скольжения, P_r - то же, после увеличения.The equilibrium state can be described by equations (3) before increasing the sliding area and (4) after increasing the sliding area:

where P _e is the value of the longitudinal force before the increase of the sliding area, P _r is the same after the increase.

- нормального сжимающего напряжения на площадке скольжения
σ₁ = σ_lim+ ΔP_rcosα/bΔl; (6)
- предельного для данного грунта нормального сжимающего напряжения

Ниже в таблице, приведены результаты экспериментальной реализации способа при испытании одного образца суглинка продольным сжатием с заданной скоростью продольной деформации, равной 0,50 мм/мин. Размеры образца: высота - 110 мм, b = 42 мм, a = 35 мм.From equations (3) and (4) we obtain formulas for:
- the maximum value of the maximum tangential stress for a given soil

- normal compressive stress on the sliding platform
σ ₁ = σ _lim + ΔP _r cosα / bΔl; (6)
- limit for a given soil normal compressive stress

The table below shows the results of the experimental implementation of the method when testing one sample of loam by longitudinal compression with a given longitudinal strain rate of 0.50 mm / min. Sample dimensions: height - 110 mm, b = 42 mm, a = 35 mm.

The angle of inclination of the sliding platform to the longitudinal axis of the sample was α = 52 ^o .

 In the table, the external load is given in units of stress.

According to the results of testing one sample, we obtain the soil strength τ _lim = 144.6 kPa with a coefficient of variation k _v = 0.26, the maximum normal compressive stress for this soil σ _lim = 77.0 kPa with a coefficient of variation k _v = 0.19 and normal compressive stress on the sliding platform σ ₁ = 190.1 kPa with a coefficient of variation k _v = 0,086.

Thus, the use of τ _lim as the strength characteristic of the soil is more reasonable and gives a more reliable result than the maximum normal stress acting on the site normal to the axis of the sample.

 Using the method allows to increase the reliability of the results of determining the strength of soils when testing one sample, to increase the productivity of soil testing by reducing the number of tested samples of this soil to one and, accordingly, to reduce material and labor costs and reduce the cost of testing.

Claims (2)

1. A method for determining the strength of the soil, including longitudinal compression of the soil sample in the form of a straight rectangular parallelepiped with a continuously increasing force or with a given speed of longitudinal deformation of the sample until it collapses, continuously recording the longitudinal deformation of the sample, recording the compressive force that destroyed the sample, and the angle of inclination of the sliding platform and calculation of soil strength, characterized in that in the process of compressing the sample, the magnitude of the compressive force and the length of the tracks are continuously recorded eniya formed on the faces of the sample, the soil strength is calculated as the arithmetic mean of the group of the limiting shear stress calculated at the instants or abnormal increase of axial strain of the sample, or increasing the lengths of the traces of the sliding pad, or abnormal decrease of the pressing force by the formula

where τ _lim is the limiting value of the maximum tangential stress at the ith moment, or an abnormal increase in the longitudinal deformation of the sample, or an increase in the lengths of the tracks of the sliding platform, or an abnormal decrease in compressive force;
ΔP _i - increment of the compressive force at the i-th moment, or an abnormal increase in the longitudinal deformation of the sample, or an increase in the length of the tracks of the sliding platform, or an anomalous decrease in the compressive force;
b is the size of the cross section of the sample in the direction perpendicular to the propagation of traces of the slip area;
Δl _i is the arithmetic average of the increments in the lengths of the tracks of the sliding platform at the i-th moment, or an anomalous increase in the longitudinal deformation of the sample, or the increase in the lengths of the tracks of the sliding platform, or the anomalous decrease in compressive force; Δl _i = (Δl _{L, i} + Δl _{R, i} ) / 2, where Δl _{L, i} and Δl _{R, i} are the increments of the lengths of the tracks of the sliding platform along the left and right sides of the sample, respectively;
α is the angle of inclination of the sliding platform to the longitudinal axis of the sample;
i is the number of cases of increasing the lengths of traces of the sliding platform from the beginning of compression of the sample to its destruction.  2. The method of determining the strength of the soil according to claim 1, characterized in that the continuous registration of the lengths of the tracks of the sliding platform formed on the faces of the sample is carried out, for example, by video shooting with a large-scale grid in the camera’s lens and by applying temporary markers on the videotape.

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