RU2640059C1 - Method of manufacturing drill-driven pile - Google Patents

Abstract

FIELD: construction.SUBSTANCE: method of manufacturing a drill-driven pile includes drilling a leader well of radius Rin the soil, filling a part of the well with hardening grout, followed by inserting the pile in the wellbore up to the design mark. The pile is inserted under the action of a static load, and the radius of its upper part is chosen taking into account the ratio 1.2R<R<1.6R.EFFECT: increase of bearing capacity of the pile, increase of manufacturability, reducing the cost, material consumption and the foundation construction time, reducing negative impacts on the soil of the foundation and the structure of the building, increasing the accuracy of its implementation.5 cl, 4 dwg

Description

The invention relates to the field of construction, in particular to methods of construction of pile foundations.

There is a method of arrangement of pile foundations with a leader hole previously drilled in the soil [1: htpp // kommtex.ru / primenenie-lidernyh-skvazin]. This method is used in dense soils or with a long pile, to facilitate its immersion in the ground. The method is implemented as follows. A leader hole is drilled in the soil, the diameter of which is usually 0.8-0.9 of the diameter (side of the cross section) of the pile, and the depth corresponds to the length of the pile. Then, a reinforced concrete (wooden, metal) pile is inserted into the leader well and hammered with a diesel hammer or copra. Due to the leader well, the soil resistance to pile driving significantly decreases and amounts to about 10-20% of the soil resistance without a leader well.

Thus, the specified method of manufacturing a buried pile includes drilling in the soil of a leader well of radius R ₀ and subsequent immersion in the well bore of the pile to the design level, which coincides with the essential features of the proposed.

In addition, the pile in the wellbore is immersed under the action of dynamic loading.

The disadvantage of this method is the reduction of the friction of the piles along the side surface compared to conventional driven piles, which reduces its overall bearing capacity.

Closest to the proposed technical solution (prototype) is the method used for the installation of foundations in permafrost soils (the so-called drilling piles) [2: htpp // kommtex / buroopusknie-svai.html]. The essence of the method lies in the fact that a well is drilled in an array of soil, the cavity of which is partially filled with a water-cement-sand mixture. Then, reinforced concrete (metal, wooden) pile is lowered into the well under the influence of its own weight. The solidification solution displaced by the submerged pile penetrates between the pile shaft and the walls of the well and, hardening, creates a strong contact between the pile and the ground.

Thus, the specified method of manufacturing a burrowable pile includes drilling in the soil of a leader well of radius R ₀ , filling part of the well with a solution and then immersing the piles in the well bore to the design mark, which coincides with the essential features of the proposed. In addition, the wellbore is filled with a water-cement-sand mixture, and piles are immersed in the wellbore to the design elevation under the influence of its own weight.

The disadvantages of this method are similar to the previous analogue.

In order to overcome these drawbacks, a method for manufacturing a burrowable pile is proposed, which includes drilling in the soil of a leader well of radius R ₀ , filling part of the well with a hardening mortar, then immersing the piles in the well bore to the design mark, characterized in that the pile is immersed under static load, and the radius its upper part is selected taking into account the ratio 1.2R ₀ <R ₁ <1.6R ₀ .

In addition, the pile is made in the form of a cylinder, the radius of which is selected taking into account the ratio 1.2R ₀ <R ₁ <1.6R ₀ .

In addition, the pile is made in the form of a truncated cone, in which the radius of the lower part is chosen taking into account the ratio R ₁ <R ₀ .

In addition, the pile is made in the form of separate coaxial sections forming a truncated cone, in which the radius of the lower section is chosen taking into account the ratio R ₁ <R ₀ , and the height of each section decreases as it is deepened, and the sections of the cone are immersed in the form of a pusher made in the form pipes with a flange, sequentially and alternately, starting with a section of a smaller diameter.

In addition, the lower section of the conical pile has a guide pipe rigidly connected to the section, and the subsequent sections have a central hole for passing the guide pipe.

A positive result of the invention consists in increasing the bearing capacity of piles, improving manufacturability, reducing the cost, material consumption and time of construction of the foundation, as well as in reducing the negative effects on the soil of the base and structure of the structure and improving the accuracy of its implementation.

List of drawing figures:

FIG. 1. The sequence of immersion piles:

a) sinking leader leader;

b) filling the well with a liquid (cement) solution;

c) immersion reinforced concrete or a metal pile into a leader well filled with a solution;

g) the final position of the piles with the sheath from the solution,

where the following notation is used:

1 - barrel leader leader; 2 - liquid solution; 3 - reinforced concrete or metal pile.

FIG. 2. The device of piles with a leader well filled with cement mortar:

a) immersion of the injector in the leader well and filling with cement mortar;

b) general view of the pile with broadening.

FIG. 3. The sequence of the device composite conical piles, immersed in the leader well:

a) sinking leader leader;

b) filling the well with a liquid (cement) solution through an injector;

c) pushing the pusher bottom of the conical pile;

g) crushing the second section of the conical pile along the guide;

e) crushing the third section of the conical pile;

e) the final position of the pile

where the following notation is used:

1 - barrel leader leader; 2 - liquid solution; 3 - pile (conical, consisting of the first, second, third sections); 4 - injector; 5 - guide; 6 - a pusher; 7 - broadening from a cement mortar; 8 - compacted soil.

FIG. 4 Foundation of composite conical piles:

a) a general view of a sectional conical pile

b) a conical sectional pile with a guide tube;

c) a general view of a composite conical pile immersed in a leader well filled with a solution.

In FIG. 1 shows the sequence of works on the device of piles according to the proposed method.

In FIG. 2 (photo) shows the results of an experiment on a model of piles in a soil tray using the proposed technology.

In FIG. Figure 3 shows the dipping sequence of sections of a composite conical pile.

In FIG. Figure 4 shows the results of experiments on a model of a composite conical pile in a soil tray.

The proposed method is intended for use in ordinary soils and is implemented as follows. A leader hole is drilled in the soil massif, which is partially filled with a hardening solution. The radius of the well should be no more than 0.7 from the radius of the pile being piled so that the solution displaced from the cavity of the well when the pile is immersed does not break through its trunk to the mouth. This ratio follows from the condition of equality of the volume of the well cavity and the cavity filled with the solution, which is formed when the soil is compacted by the walls of the well due to the displacement of the solution by the immersed pile:

where R ₁ is the radius of the well; R ₂ is the radius of the well with compacted walls.

That is, the left side of the equality represents the volume of the concrete mixture displaced from the wellbore per unit of depth, and the right side represents the volume of the ring formed by compaction of the soil around the walls of the well per unit of depth. It follows that there is no breakthrough of the concrete mixture along the pile shaft - its diameter should be greater than the radius of the expanded well seal:

Then the pile sinks to the design depth. After hardening of the concrete mixture, such a pile will have a bearing capacity significantly greater than a conventional pile crushed into the ground. This is due to the fact that the diameter of the crushed pile, taking into account the shell of the hardened solution around it, will be:

That is, the lateral surface area of such a pile will be approximately 30% larger than that of a conventional pile. In addition, due to the greater compaction of the soil around the pile due to the fact that its radius will be 30% larger than that of a conventional pile, the friction force of the pile on the soil along the lateral surface will be significantly greater.

As an option of the proposed technology, it is proposed, in the case of loose soils, to immerse a pile in the form of a truncated cone in the leader well. The smaller radius of the top of the truncated cone should be less than or equal to the radius of the leader well, and the base of the cone (angle) is selected by calculation and depends on the soil and the power plant of the crushing device.

This form of the crushed pile will ensure the impossibility of breaking the solution located in the well cavity to its mouth, will provide more effective compaction of the soil around the pile and will increase the friction of the pile against the soil, which will significantly increase its overall bearing capacity.

In addition, to reduce the effort of crushing piles and improve the manufacturability of the process, it is proposed to make the conical pile composite, dividing it in height into several parts.

Then the sequence of work will look as follows. Initially, the leader well is drilled. Then the lower part of the well is filled with a hardening mortar and the first section of the conical pile is crushed with a static load into the well using a pusher - a metal pipe with a flange (for more uniform load transfer). In the process of crushing, the section cone compacts the soil around the well and expands it to a radius equal to the radius of the base (wide part) of the cone. When the section touches the solution in the well, pressure will be transferred to the solution, and from it to the walls of the well, creating a broadening in the soil.

After reaching the design mark of the lower part of the cone, a second section of the truncated cone is installed at the wellhead, in which the radius of the smaller (lower) part is equal to the radius of the upper (wide) part of the first section of the pile and, accordingly, the radius of the broadened leader well and is crushed using a pusher with a static load before touching the first section. Then, in a similar manner, the remaining sections are crushed.

In order to ensure that the sections are immersed strictly along the axis of the well and to avoid distortions when the sections are crushed, the guide pipe is rigidly fixed to the lower (first) section, and, accordingly, the remaining sections have holes in which the guide pipe passes when the sections are immersed.

To ensure equal efforts when immersing the sections, it is advisable to produce each subsequent section longer than the previous one.

We show that the required technical result is achieved due to significant differences of the proposed.

The fact that the proposed method carries out drilling in the soil of a leader well of radius R ₀ , filling part of the well with a hardening solution, then immersing piles in the well bore to the design level, the pile is immersed under static load, and its radius of its upper part is selected taking into account the ratio 1.2 R ₀ <R ₁ <1.6R ₀ , increases the bearing capacity of piles, reduces the cost, material consumption and time of construction of the foundation, as well as reduces the negative effects on the soil of the base and structure of the structure.

The fact that in the proposed method the pile is made in the form of a cylinder, the radius of which is selected taking into account the ratio 1.2R ₀ <R ₁ <1.6R ₀ , also increases the bearing capacity of the piles, reduces the cost, material consumption and time of construction of the foundation, and also reduces the negative impact on foundation soils and construction structures.

The fact that in the proposed method the pile is made in the form of a truncated cone, in which the radius of the lower part is selected taking into account the ratio R ₁ <R ₀ , increases the bearing capacity of the pile,

The fact that in the proposed method the pile is made in the form of separate coaxial sections forming a truncated cone, whose radius of the lower section is selected taking into account the ratio R ₁ <R ₀ , and the height of each section decreases as it is deepened, and the sections of the cone are immersed with a pusher, made in the form of a pipe with a flange, sequentially and alternately, starting from a section of a smaller diameter, also increases the manufacturability of the method, simplifies its implementation by reducing the necessary generated loads, and also increases the bearing capacity ty piles, reduces the cost of construction.

The fact that in the proposed method the lower section of the conical pile has a guide pipe rigidly connected to the section, and the subsequent sections have a central hole for passing the guide pipe, also improves the manufacturability of the method, the accuracy of its implementation, simplifies its implementation by reducing the necessary generated loads, also increases the bearing capacity of piles, reduces the cost of construction ..

As a result of the experiments, it was found that to immerse the piles according to the proposed technology, the force required is 20% higher than when crushing a conventional pile into the ground, but the bearing capacity of such a pile is 35-40% more, which indicates the consistency of the proposed technology.

Despite the simplicity of the proposed technology, as far as the authors know, it is not described in the technical and patent literature and has not been previously applied in practice. This is because for the implementation of this technology it is necessary to provide crushing piles with a static load. The driving method in this case is not applicable, since the blow of the diesel hammer has too small a pulse of force (short time of interaction with the pile). As a result of a short impulse action in the cavity of a pile filled with a liquid solution, a hydrostatic impulse occurs, but the soil does not have time to deform, and the hammer receives an elastic rebound.

Pile immersion with static load is much less frequent than driving piles with a drive or bored piles. Bulky equipment is required to immerse piles by crushing with the possibility of reactive force perception from crushing piles.

However, for special cases, for example, when replacing a building on piles during reconstruction, this technology can be very effective, since the reactive force from crushing can be perceived by the weight of the building.

To ensure equal efforts to immerse sections, the height of each subsequent section is more than 1.4 times greater than the previous one.

The proposed technology was tested in laboratory conditions and showed a fairly good efficiency.

Claims (5)

1. A method of manufacturing a drill-down pile, including drilling in the soil of a leader well of radius R ₀ , filling part of the well with a hardening mortar, subsequent immersion in the well bore of the pile to the design mark, characterized in that the pile is immersed under static load, and the radius of its upper part is selected taking into account the ratio 1.2R ₀ <R ₁ <1.6R ₀ . 2. A method of manufacturing a bored pile according to claim 1, characterized in that the pile is made in the form of a cylinder, the radius of which is selected taking into account the ratio 1.2R ₀ <R ₁ <1.6R ₀ . 3. A method of manufacturing a bored pile according to claim 1, characterized in that the pile is made in the form of a truncated cone, in which the radius of the lower part is chosen taking into account the ratio R ₁ <R ₀ . 4. A method of manufacturing a drill-down pile according to claim 1, characterized in that the pile is made in the form of separate coaxial sections forming a truncated cone, whose radius of the lower section is selected taking into account the ratio R ₁ <R ₀ , and the height of each section decreases as it deepening, and immersion of the sections of the cone is made by the pusher, made in the form of a pipe with a flange, sequentially and alternately, starting from the section of smaller diameter. 5. A method of manufacturing a bored pile according to paragraphs. 1, 3, characterized in that the lower section of the conical pile has a guide pipe rigidly connected to the section, and the subsequent sections have a Central hole for the passage of the guide pipe.

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