RU2629508C2 - Pile bearing capacity determination method - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: pile bearing capacity determination method includes piles immersion by the static load, measuring the piles immersion depth and vertical displacement, as well as the pressed load value, the separate determination according to the resistance measurements of the lateral surface and under the pile lower end. The pressed load value increasing is stopped after reaching the designed mark by the lower end pile, then the pile is tested in the creep-relaxation mode and judged on the bearing capacity according to the stabilized value of the vertical load.

EFFECT: increase of the efficiency, accuracy, reliability and manufacturability of measurements, dematerialization of testings.

3 cl, 5 dwg

Description

The invention relates to the field of construction and can be used in the construction of pile foundations of buildings.

From the technical literature (updated version of SNiP 2.02.03-85), the following methods are known for determining the bearing capacity of piles on the ground:

- test of piles with a static load;

- dynamic load test of piles (trial driving);

- determination of the bearing capacity of piles by sounding method (using special installations that simulate the operation of piles, allowing to separately determine the soil resistance under the lower end of the pile and resistance due to friction on the side surface);

- determination of the bearing capacity of piles by calculation (according to the formulas SNiP 2.02.03-85).

The test of piles with a static load consists in loading the pile immersed (in any way) to the design level in the pile with a stepwise increasing vertical load (P), measuring the vertical movements of the pile (S) and plotting the dependence of the stabilized pile movements (St) on the load. By the characteristic fracture of the graph of the dependence St = f (p), which consists of two sections - linear and nonlinear, one judges the magnitude of the bearing capacity of the pile, as shown in FIG. 1. At the same time, a constant load value is maintained at each stage.

In the practice of geomechanical testing, methods are known where the test object is not subjected to a stepwise increasing load with constant values at each stage, but is tested in the creep-relaxation mode. For example, in the dynamometric method of testing samples to determine the long-term strength of S.S. Vyalova (S. S. Vyalov "Rheological foundations of soil mechanics" M .: "Higher school", 1978).

The method is implemented in two versions. In the first embodiment, a soil sample tested for uniaxial compression is loaded once with a load exceeding its long-term strength using a dynamometer with a screw. Next, the sample is tested in the creep-relaxation mode. To do this, stop tightening the load screw. The sample undergoes creep strains, and the dynamometer expands and the load relaxes. The stabilized value of the relaxing load, which occurs after some time, can be considered as achieving a state of equilibrium between the external load and the internal resistance forces of the soil, that is, equal to the long-term strength of the specimen under uniaxial compression. The complexity of the implementation of this method lies in the fact that it is necessary to know the approximate values of long-term and conditionally instantaneous strength in advance in order to assign a load level greater than long-term and less than conditional instant strength in tests.

In the second version of the method, the sample is loaded with a stepwise increasing load, and each stage is tested in the creep-relaxation mode. The value of the stabilized load from step to step will increase until it becomes constant. The maximum value of the stabilized load is taken as the value of the ultimate strength. However, this method was not used to test piles.

The closest analogue (prototype) of the present invention is a method for determining the bearing capacity of piles by sensing [1. Alekseev S.I. Foundations and foundations: a textbook for university students / S.I. Alekseev. - St. Petersburg: Petersburg State University of Railway Engineering, 2007. - 111 p.], In which a rod imitating the work of a pile is immersed with a static load, the depth of immersion and vertical movement of the pile, as well as the magnitude of the applied load are measured, which is the most consistent with significant signs of the proposed.

In addition, the magnitude of friction is measured at various sites, as well as the value of drag, and, using empirical coefficients, the results of the experiment are recounted on the bearing capacity of a real pile, taking into account its dimensions. The rod is equipped with devices that allow you to determine the amount of friction on the side surface of the pile (special couplings) in various sections of its length and to determine the forces arising under its lower end.

The disadvantage of this method is the decrease in accuracy, reliability due to the fact that the test is not a real pile, but a special probe that simulates the operation of a pile.

A positive result of the invention consists in increasing the efficiency, accuracy, reliability and manufacturability, as well as reducing the cost of testing to determine the bearing capacity of piles.

List of drawing figures:

FIG. 1 a) Standard test design for piles with static load; b) a graph of the draft S of the pile from the load R.

FIG. 2 a) Scheme of testing piles crushed into the ground by a static load; b) a graph of the dependence of the vertical load on the test time in the creep-relaxation mode (curve AB) according to claim 1 of the formula.

FIG. 3 Scheme of testing piles for pulling out of the soil by a static load and a graph of the dependence of the vertical load on the test time in creep-relaxation mode (curve AB) according to claim 1 of the formula.

FIG. 4 Scheme of sequential immersion of piles using static load with tests at various depths (h1, h2, h3, h4) for pressing and pulling in the creep-relaxation mode according to claim 3 of the formula.

FIG. 5 Graph of the compressive and pulling load versus time (h1, h2, h3, h4) when tested in the creep-relaxation mode according to claim 3 of the formula.

In FIG. 1 a) a standard test design of a pile with a static load P is presented, in which counter friction forces f and a drag reaction of compressed soil R arise.

b) In FIG. 1 b) it is shown that the non-linear graph of the dependence of the draft S of the pile on the load P can be approximated by two intersecting straight lines, at the intersection of which the limit value of the load capacity of the pile is established.

In FIG. 2 a) a test scheme of a pile crushed into the ground by a static load P is presented, at which counter friction forces f and a drag reaction of compressed soil R arise.

In FIG. 2 b) it is shown that after applying a vertical load, crushing the pile to the required depth, after the relaxation process (curve AB), the load is set at the level P _{pr of the} limit value of the load capacity.

In FIG. 3 a) a test diagram of a pile with a static load P pulled out of the soil is presented, at which counter friction forces f arise.

In FIG. 3 b) it is shown that after applying a vertical load pulling out a pile, after the relaxation process (curve AB), the load is set at the level P ^{* of} the friction force along the lateral surface.

In FIG. Figure 4 shows the scheme of sequentially dipping piles using a static load with tests for pushing and pulling in the creep-relaxation mode at each of the achieved depths (h1, h2, h3, h4).

In FIG. Figure 5 shows the cycles of compressive and pulling loads produced at various piling depths.

In order to overcome these drawbacks, a method is proposed for determining the bearing capacity of piles, including immersion of piles with a static load, measuring the depth of immersion and vertical movements of the piles, as well as the magnitude of the pressing load, separate determination according to the results of measurements of resistance along the side surface and under the lower end of the pile, characterized in that the value of the pressing load ceases to increase after the lower end of the pile reaches the design level, after which the pile is tested in crawl mode honor-relaxation and the stabilized value of the load judge the bearing capacity of the piles.

In addition, after stabilization of the vertical compressive load, a stepwise increasing pulling load is applied to the pile and each step is tested in the creep-relaxation mode, after the termination of the increase in the stabilized load value by its maximum value, the pile resistance along the lateral surface is judged, and by the difference between the stabilized compressive values and tensile loads judge the soil resistance under the lower end of the pile.

In addition, design marks are assigned at different points in depth, so that test cycles of piles with crushing and pulling loads are performed several times during the process of immersing the piles to the required depth.

The proposed method is as follows.

In the first version, the pile is immersed in the ground with a static load to the design level (or clogged), then they stop pumping oil into the hydraulic cylinders and begin to test the pile in a creep-relaxation mode. As a result, the pile receives vertical movements, but at the same time the pressure in the hydraulic cylinders drops (due to relaxation). After some time, the system "pile-soil-external load" comes into equilibrium. By the value of the stabilized pressure, the bearing capacity of the piles is judged.

To separately determine the drag and friction along the side surface of the pile, the pile tested by the above method is subjected to “pulling”. With such loading, the pile resists only due to the resistance force along the lateral surface. To do this, a stepwise increasing pulling load is applied to the pile and each step is tested in the creep-relaxation mode. After the values of the stabilized pulling load cease to grow, the maximum resistance of the pile along the lateral surface is determined by its maximum value, and the frontal resistance of the pile is judged by the difference in load during crushing and pulling.

In the second test variant, the pile is immersed not to the design level, but to a certain depth, where the crushing and pulling test is carried out in the modes described above. Next, the pile is immersed to a certain depth and the operation is repeated. By testing the pile in this way, it is possible to obtain the resistance values of the pile below the lower end and along the side surface at various depths.

Moreover, in the proposed method is tested not inventory, but a real pile. The test is carried out during the production of work without interruption and use the same equipment as for immersion piles.

The achievement of the load-bearing capacity limit of piles is judged not by the fracture of the graph of the dependence of pile settlement on the compressive load S = f (p) (according to SNiP formulas 2.02.03-85) (Fig. 1), but by the value of the stabilized load when testing it in creep mode relaxation.

In addition to the compressive load test, a tensile load is applied to the pile, which makes it possible to separately determine the resistance of the pile under the lower end and on the side surface.

In the process of immersion, it is possible to test the piles at different depths, which makes it possible to determine the change in the bearing capacity of the pile, the resistance under the lower end and along the side surface, depending on the depth of its immersion. All piles in a row are tested, and not selective, as in other methods, since this test does not require additional labor and a long time (stabilization of deformations and stresses in the creep-relaxation mode, as is known, occurs much faster than in the creep mode).

The positive effect and economic advantages of the proposed method are achieved due to the fact that

- during the course of works on crushing piles, each pile can be tested, which allows you to accurately know the bearing capacity of the foundation and, therefore, makes it possible to make the foundation more economical;

- the test process of piles in the creep-relaxation mode is characterized by increased efficiency, because takes significantly less time than a test with a constant stepwise increasing load;

- the testing process can be carried out in parallel during the continuation of construction work on the installation of upper structures, etc. The same equipment is used for testing as for piling. The process of crushing and testing is carried out without technological pauses, which reduces the time of work and increases the economic performance of construction.

In order to verify the operability of the proposed method, a series of model experiments was conducted comparing the bearing capacity of small-scale pile models determined by the traditional method (static stepwise increasing constant load) and by the proposed method in the creep-relaxation mode. The experiments showed a fairly good convergence of the results obtained by different methods, which confirms the feasibility of the proposed object of the invention.

As follows from the above analysis, the required technical result is achieved due to significant differences of the proposed.

Claims (4)

1. The method of determining the bearing capacity of piles, including immersion of the pile with a static load, measuring the depth of immersion and vertical movements of the pile, as well as the magnitude of the pressing load, separate determination by the results of measurements of resistance along the side surface and under the lower end of the pile, characterized in that: the magnitude of the pressing load ceases to increase after the lower end of the pile reaches the design level, after which the pile is tested in the creep-relaxation mode and the stabilized value of the vertical load is used to judge the load-bearing capacity of the pile. 2. The method according to p. 1, characterized in that after stabilizing the vertical compressive load, a stepwise increasing pulling load is applied to the pile and each step is tested in the creep-relaxation mode, after stopping the increase in the value of the stabilized load, it is judged by the maximum lateral resistance of the pile surface, and the difference between the stabilized values of the compressive and tensile loads judge the resistance of the soil under the lower end of the pile. 3. The method according to PP. 1 and 2, characterized in that the design elevations are located at different points in depth, so that the test cycles of piles with crushing and pulling loads produce several times in the process of immersion piles.

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