RU2640625C1 - Method for compacting bases formed by weak mineral soils - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: method for compacting bases formed by weak mineral soils includes making a well, filling a compacting material into the well, and creating the compacting impact by a hollow tubular working tool on the compacting material to form a compacting column. Preliminarily, engineering geological survey of the base soil is carried out, and the values of the strain modulus, the Poisson's ratio, the angle of internal friction, the specific cohesion, the specific gravity, the initial porosity coefficient of the weak mineral soil are determined. Then, the effective value of the strain modulus ε_i at expanding the compacting material in the well is calculated by the initial and specified porosity coefficient of the weak mineral soil according to the given dependence. Thereinafter the column spacing pitch is defined by the selection method in a range from one to three diameters of the columns, which gives the value of the design base deformation modulus, the necessary increase of the well radius in the process of indentation is calculated by the given dependencies. The well is made by means of indenting a tool in the base soil, filling the compacting material into the well is carried out through the working tool cavity, and the compacting impact for forming a compacting column is carried out by indenting the working tool into the compacting material. Additional engineering and geological survey are carried out on the site, the deformation modulus of the compacted soil between the columns, and the actual average deformation modulus of the base as a whole is calculated according to the given dependence. Then it is compared with the design one, and if the actual average base deformation modulus does not correspond to its design value, additional columns are installed between previously installed ones.

EFFECT: increasing soil compaction productivity, reducing material consumption and labour intensity.

5 cl

Description

The invention relates to the construction, in particular, to methods for strengthening soils under the foundations and foundations of buildings and structures, including electric power facilities.

In the practice of designing the foundations and foundations of buildings and structures at a selected construction site, often weak water-saturated clay soils with low deformability and strength characteristics lie. In such cases, the transformation of a weak base is carried out by various methods, which lead to compaction and hardening of initially weak soil. The group of soil properties transformation includes compaction by rolling, tamping, injection of various compositions, arrangement of soil piles using various technologies.

A known method of strengthening the soil, including the formation of a well, loosening the soil of the walls of this well and creating a strengthening effect on this soil (copyright certificate for the invention of the USSR No. 708010, 09/30/77). In this method, a reinforcing effect is created only on the soil, which is loosened from the walls of the well. After tamping this soil, a certain degree of strengthening is obtained, which can no longer be increased.

This method does not allow to obtain the required degree of soil strengthening under the foundations for modern construction.

The closest analogue is the method of compaction of the soil (patent for the invention of the Russian Federation No. 2473741), including the implementation of the well, filling the sealing substance (material) into the well and creating a sealing effect of a thin-walled shell (hollow tubular working tool) on the sealing material to form a compaction column.

The disadvantage of the closest analogue is the lack of calculations for the selection of technological parameters for compaction of the column depending on the soil properties, reconciliation of the values obtained after compaction with design values, which leads to the need for unnecessary operations to compaction the soil, selecting the required number of wells.

The problem solved by the present invention is the implementation of compaction of the base, composed of weak mineral soils, by determining the optimal design technological parameters of the columns over the entire area of the base, their implementation in the ground, as well as reconciliation after compaction of the base of the obtained parameter of the compacted base soil as a whole with the optimal design resulting in higher productivity and lower costs.

The technical result achieved by the invention is to increase the productivity of soil compaction, reducing material consumption and complexity.

The essence of the invention lies in the fact that in the method of compaction of bases made up of weak mineral soils, including the implementation of the well, filling the sealing material into the well and creating a sealing effect with a hollow tubular working tool on the sealing material to form the sealing string, it is proposed to carry out preliminary engineering geological surveys of the soil bases and determine the values of the deformation modulus, Poisson's ratio, angle of internal friction, specific adhesion, specific gravity, n tially void ratio weak mineral soil, then calculate the current value of the modulus of deformation ε _i during the expansion of sealing material in the borehole from the initial coefficient and a predetermined porosity weak mineral soil by the formula:

, где

where

ε _i is the effective value of the deformation modulus of the column body;

e _i is the porosity coefficient of weak mineral soil around the columns with the actual value of the deformation modulus εi corresponding to the nearest value of the deformation modulus in accordance with the normative correlation dependencies;

e ₀ is the initial porosity coefficient of compacted weak mineral soil,

then, using a selection method in the range from one to three diameters of the column, it was proposed: to determine the column placement step at which the design module deformation of the base is achieved, to calculate the necessary increase in the radius of the well during indentation by the formula:

, где

where

r ₂ is the radius of the expanded column;

R is the radius of influence of one crushed stone column, equal to half the pitch of the columns;

ε is the value of the deformation modulus of the column body,

perform the well by pressing the working tool into the soil of the base, fill the sealing material into the well through the cavity of the working tool, and perform the sealing action to form the seal string by pressing the working tool into the sealing material, after which additional engineering and geological surveys at the site, determine the deformation modulus of the compacted soil between the columns and calculate the actual average deformation modulus of the base as a whole according to the formulas:

, где

where

- фактический средний модуль деформации основания в целом;

- the actual average modulus of deformation of the base as a whole;

β is the coefficient of lateral expansion equal to 0.8 for a composite soil mass;

- коэффициент относительной сжимаемости грунта;

- coefficient of relative compressibility of the soil;

m _with - the coefficient of relative compressibility of the column;

- коэффициент относительной сжимаемости рабочей ячейки (массива, состоящего из колонны и окружающего грунта) в целом;

- coefficient of relative compressibility of the working cell (array consisting of columns and surrounding soil) as a whole;

- модуль деформации окружающего колонну грунта;

- the deformation modulus of the soil surrounding the column;

E _with - the modulus of deformation of the material of the column;

λ is the coefficient of volumetric deformation of the compacted soil during the expansion of the well;

a is the final radius of the column;

b is the radius of the working cell (half the design step of the packing columns);

and then compare it with the design and if the actual average base deformation module does not match its design value, install additional columns between the previously installed ones.

It is also proposed that the lower end of the working tool is predominantly covered with a gate or a lost shoe before it is pressed into the base soil, and after filling the sealing material into the working tool cavity, open the working tool gate to spill the sealing material into the well, raise the working tool to a predetermined compaction layer height, and then to press the working tool into the sealing material, and repeat the operation of pressing the sealing material in layers for the entire length a column to achieve the desired sealing of the weak mineral soil.

It is possible to use crushed stone and / or sand, and / or gravel, and / or inert material as a sealing material, and it is proposed that the working tool be symmetrical about its central axis.

A distinctive feature of the proposed method is that, according to the results of engineering and geological surveys, the initial parameters of weak mineral soil are determined by the base area, using which calculations are made to select the technological parameters of column compaction (step and radius of the expanded column) throughout the base. Reconciliation after compaction of the base of the obtained parameter of compacted soil on the base as a whole with the design allows you to determine the adequacy of the number of installed columns. Pressing a hollow tubular working tool into the soil of the base allows the first compaction of weak mineral soil. Overlapping the lower end of the working tool with a gate or a lost shoe allows the indentation of the sealing material in the well. A layer-by-layer pressing of the working tool into the sealing material allows you to significantly expand the well, form a crushed stone column, and compact the soil around the column in the radial direction. Compaction of the soil surrounding the column also activates the consolidation process due to the appearance of excessive pore pressure. The use of crushed stone and / or sand, and / or gravel, and / or any other inert material as a sealing material makes it possible to form a compaction column with the necessary characteristics depending on the properties of the compacted weak mineral soil, so as to prevent the penetration of particles of the compacted soil through body of the column.

The use of a working tool symmetrical with respect to the central axis allows uniform radial compaction of the base soil.

The proposed method is as follows.

Preliminary, engineering and geological surveys of the soil of the base are carried out and the values of the deformation modulus, Poisson's ratio, internal friction angle, specific adhesion, specific gravity, initial porosity coefficient of weak mineral soil are determined, then the effective value of the deformation modulus ε _{i is} calculated when expanding the sealing material in the well according to the initial and a given coefficient of porosity of weak mineral soil according to the formula:

, где

where

ε _i is the effective value of the deformation modulus of the column body;

e _i is the porosity coefficient of weak mineral soil around the columns with the actual value of the deformation modulus εi corresponding to the nearest value of the deformation modulus in accordance with the normative correlation dependencies;

e ₀ - the initial coefficient of porosity of the compacted weak mineral soil,

after which, by selecting in the range from one to three diameters of the column, the column placement step is determined, at which the design modulus of the base deformation is achieved, the necessary increase in the radius of the well during indentation is calculated by the formula:

, где

where

r ₂ is the radius of the expanded column;

R is the radius of influence of one crushed stone column, equal to half the pitch of the columns;

ε is the value of the deformation modulus of the column body,

perform the well by pressing the working tool into the soil of the base.

The lower end of the working tool before it is pressed into the ground, the bases are covered with a gate, and after filling the sealing material into the cavity of the working tool, the gate of the working tool is opened to spill the sealing material into the well, the working tool is lifted to a predetermined height of the sealing layer, after which the working tool is pressed into the sealing material. The operation of pressing in the sealing material is repeated in layers throughout the entire length of the column until the desired compaction of weak mineral soil is achieved.

It is also possible overlapping the lower end of the working tool with a lost shoe.

It is possible to use crushed stone and / or sand, and / or gravel, and / or inert material as a sealing material, and the working tool used is symmetrical about its central axis.

Then make additional engineering and geological surveys at the site, determine the modulus of deformation of the compacted soil between the columns and calculate the actual average modulus of deformation of the base as a whole according to the formulas:

, где

where

- фактический средний модуль деформации основания в целом;

- the actual average modulus of deformation of the base as a whole;

β is the coefficient of lateral expansion equal to 0.8 for a composite soil mass;

- коэффициент относительной сжимаемости грунта;

- coefficient of relative compressibility of the soil;

m _with - the coefficient of relative compressibility of the column;

- коэффициент относительной сжимаемости рабочей ячейки (массива, состоящего из колонны и окружающего грунта) в целом;

- coefficient of relative compressibility of the working cell (array consisting of columns and surrounding soil) as a whole;

- модуль деформации окружающего колонну грунта;

- the deformation modulus of the soil surrounding the column;

E _with - the modulus of deformation of the material of the column;

λ is the coefficient of volumetric deformation of the compacted soil during the expansion of the well;

a is the final radius of the column;

b is the radius of the working cell (half the design step of the packing columns).

After the calculations, the actual average base deformation modulus is generally compared with the design one, and if there is a discrepancy, additional columns are installed between the previously installed ones.

Using the proposed method allows you to design and carry out compaction of the foundations of buildings and structures of increased responsibility in the selected construction site in accordance with the specified design values without additional costs.

Claims (28)

1. The method of compaction of bases made up of weak mineral soils, including the implementation of the well, filling the sealing material into the well and creating a sealing effect with a hollow tubular working tool on the sealing material to form a sealing column, characterized in that the geological engineering surveys of the base soil are preliminarily performed and determined values of the deformation modulus, Poisson's ratio, angle of internal friction, specific adhesion, specific gravity, initial porous coefficient STI weak mineral soil, then the current value of deformation ε _i is calculated modulus at expansion of the sealing material in the borehole from the initial coefficient and a predetermined porosity weak mineral soil by the formula:

Where ε _i is the effective value of the deformation modulus of the column body; e _i is the porosity coefficient of weak mineral soil around the columns with the actual value of the deformation modulus ε _i corresponding to the nearest value of the deformation modulus in accordance with the normative correlation dependencies; e ₀ - the initial coefficient of porosity of the compacted weak mineral soil, after which, by selecting in the range from one to three diameters of the column, the column placement step is determined, at which the design modulus of the base deformation is reached, the necessary increase in the radius of the well during the indentation is calculated by the formula:

where r ₂ is the radius of the expanded column; R is the radius of influence of one crushed stone column, equal to half the pitch of the columns; ε is the value of the deformation modulus of the column body, the well is carried out by pressing the working tool into the soil of the base, filling of the sealing material into the well is carried out through the cavity of the working tool, and the sealing effect for the formation of the seal string is carried out by pressing the working tool into the sealing material, after which additional engineering and geological surveys are performed on the site, the deformation modulus of the compacted the soil between the columns and calculate the actual average modulus of deformation of the base as a whole according to the formulas:

,

,

,

,

,  Where

- the actual average modulus of deformation of the base as a whole; β is the coefficient of lateral expansion equal to 0.8 for a composite soil mass; m _g - coefficient of relative compressibility of the soil; m _with - the coefficient of relative compressibility of the column;

- coefficient of relative compressibility of the working cell (array consisting of columns and surrounding soil) as a whole; E _g is the deformation modulus of the soil surrounding the column; E _with - the modulus of deformation of the material of the column; λ is the coefficient of volumetric deformation of the compacted soil during the expansion of the well; a is the final radius of the column; b is the radius of the working cell (half the design step of the packing columns); and then they compare it with the design and if the actual average base deformation module does not match its design value, additional columns are installed between the previously installed ones. 2. The method of sealing the bases according to claim 1, characterized in that the lower end of the working tool before it is pressed into the soil of the base is covered with a gate or a lost shoe. 3. The method of sealing the bases according to claim 2, characterized in that after filling the sealing material into the cavity of the working tool, open the gate of the working tool to spill the sealing material into the well, raise the working tool to a predetermined height of the sealing layer, and then press the working tool into the sealing material, and the operation of pressing in the sealing material is repeated in layers throughout the entire length of the column until the desired compaction of weak mineral soil is achieved. 4. The method of sealing the bases according to claim 1, characterized in that crushed stone and / or sand, and / or gravel, and / or inert material are used as the sealing material. 5. The method of sealing the bases according to claim 1, characterized in that the working tool is symmetrical about its central axis.