RU50551U1 - DEVICE FOR CREATING A PRE-LOADED PILET - Google Patents

Abstract

The invention relates to the field of foundation engineering, in particular to devices capable of forming printed piles in various soil conditions. A device for creating a stuffed pile, prestressed on the ground, including a supporting pipe, a working chamber and a high pressure chamber, mounted on the outside of the pipe one above the other and placed in the well further comprises a hydraulic tampon located in the upper part of the supporting pipe adjacent to the working chamber, and above the hydraulic tampon the supporting pipe is equipped with a clamping annular plate with stiffeners and a hydraulic jack with an annular element for fastening to the supporting pipe; moreover, the working chamber, the high pressure chamber and the hydraulic tampon are made of high strength, waterproof, flexible reinforced material with the possibility of partial stretching in the horizontal direction. Using the device allows due to the creation of prestressing material of the pile on the ground several times to increase the bearing capacity of the printed pile, reduce material consumption and at the same time increase its operational reliability. The device for creating stuffed piles, prestressed on the ground can be used in the construction of high-rise buildings and structures, the construction of reservoirs, the construction of "intelligent" objects - buildings and structures in which the bearing capacity of the foundation system depends and is centrally supported based on the magnitude of external loads, the intensity of technological flows and expected uneven deformations of the soil base.

Description

The invention relates to the field of foundation engineering, in particular to devices capable of forming printed piles in various soil conditions.

A device is known for creating bored piles of the Franca type [1], which carries a thickly coated casing with a plug of hard concrete and a hammer-tamper. The disadvantage of this device is the large material consumption of the manufactured piles, the delamination of concrete in the pile during compaction of the latter with hammer blows, the impossibility of installing the pile with a high groundwater level and the high complexity of the work during the construction of the pile in question.

Also known is a device for creating a pneumatic pile [2], including a thick-walled casing pipe, a steel thin-walled shell with a tip and a wooden core, a sleeve with a lock for supplying concrete and air or water to the pile for a single and short-term compression of concrete and surrounding soil. The disadvantage of this device is associated with the large specific material consumption of the pile per ton of its bearing capacity and relatively low bearing capacity with a significant complexity of its manufacture.

The closest to the invention in technical essence is a device for the construction of bored piles in the soil [3], including a carrier concrete pipe, two chambers made of permeable and inextensible fabric, two pipelines for creating pressure chambers in the chambers with which you can create broadening due to compression of the surrounding soil. The disadvantage of this device is the impossibility of compacting the concrete mixture during the manufacture of piles, and even more so the impossibility of creating prestressing of the material of the pile on the ground, which significantly reduces its bearing capacity with a very high material consumption per tonne of its bearing capacity, which is the main disadvantage of all packed piles and devices intended for their manufacture.

The objective of the invention is to increase the bearing capacity of a printed pile with a simultaneous decrease in its material consumption and increase operational reliability.

This object is achieved in that the device for creating a stuffed pile, prestressed on the ground, including a supporting pipe, a working chamber and a high pressure chamber, mounted on the outside of the pipe one above the other and placed in the well additionally contains a hydraulic tampon located in the upper part of the supporting pipe adjacent to the working chamber, and above the hydrotampon, the carrier pipe is equipped with a clamping annular plate with stiffeners and a hydraulic jack with an annular fastening element

to the carrier pipe; moreover, the working chamber, the high pressure chamber and the hydraulic tampon are made of high strength, waterproof, flexible reinforced material with the possibility of partial stretching in the horizontal direction.

Figure 1 and figure 2 shows a longitudinal section of a device for creating a printed pile, prestressed on the ground.

In the figures indicated: 1 - supporting pipe; 2 - flanges; 3 - high pressure chamber; 4 - a working chamber; 5 - rubber cover; 6 - hydraulic tampon; 7 - high pressure pipeline; 8 - an annular plate; 9 - stiffeners; 10 - hydraulic jack; 11 - annular fastener; P ₁ - pressure supplied to the high-pressure chamber 3 for anchoring the formed hollow piles; P ₂ - the pressure created in the annular hydraulic jack to prevent possible outburst of soil; P ₃ - the pressure created in the hydraulic pump 6, designed to prevent the exit of concrete during pile formation within the height of the working chamber 4; P ₄ - working pressure that forms the trunk of a hollow pile, prestressed on the ground; P ₅ - reactive soil pressure.

A device for creating a stuffed pile, prestressed on the ground, contains a carrier pipe 1 with flanges 2, a working chamber 4 and a high pressure chamber 3, mounted outside the pipe 1 one above the other and placed in the well, a hydraulic valve 6 located in the upper part of the carrier pipe 1 s adjacent to the working chamber 4, and above the hydraulic pump 6, the carrier pipe 1 is equipped with a clamping ring plate 8 with stiffening ribs 9 and a hydraulic jack 10 with an annular element for fastening 11 to the carrier pipe 1. The working chamber 4 and the high-pressure chamber 3 and the hydraulic valve 6 are made woven from a high-strength, waterproof, flexible reinforced material with the possibility of partial stretching in the horizontal direction (figure 1 and figure 2).

The diameter of the carrier pipe 1 is less than the diameter of the leading pile drilled in a soil base or punched by a pneumatic punch. The high-pressure chamber 3 is designed to prevent the "ascent" of the entire device to the surface of the soil base. The working chamber 4 is located within the entire middle zone of the carrier pipe 1 and is designed to create prestressing on the soil of the material formed by the printed pile (figure 2).

On top of the chambers, a rubber cover 5, partially stretched in the horizontal direction, is dressed and fixed, for example, having a transverse continuous reinforcement along the entire length. All three chambers of the device are equipped with separate high-pressure pipelines 7, through which either water or air is supplied to the chambers.

A device for creating a printed pile, prestressed on the ground works in structurally stable, for example clay soils as follows (figure 1 and figure 2).

At the first stage, with the help of a drilling rig, or a pneumatic punch, a leading well with a diameter of 200-250 mm is punched into the soil base into which the proposed device is lowered using a crane. Then, slightly raising it above the bottom of the well, sequentially, first

in chamber 3, then in chamber 4 and hydraulic tampon 6 steps a small pressure is created up to 0.2 ... 1.0 kg / cm ² , without bringing the top layer of the soil base to destruction. Then, a clamping ring plate 8 with stiffening ribs 9 and an annular hydraulic jack 10 is worn on top of the supporting pipe 1, which should be fixed to the supporting pipe 1 with an annular fastening element 11.

At the second stage, the pressure in the chamber 3 increases to a maximum and only after the deformation of the soil surrounding the chamber is stabilized, with the help of a hydraulic jack 10, the annular plate 8 is pressed with a certain force to the surface of the soil base in order to eliminate a possible outburst of the soil, when creating a "supporting body" pre-stressed stuffed pile soil.

Then, after stabilization of deformations of the surface of the soil base in the hydrotamp 6 and simultaneously with a slight delay, a working pressure of several tens kg / cm ² is created in the working chamber 4, while controlling and preventing the destruction and outburst of soil on the surface of the soil base. As a result of this, the diameter of the leading well increases to the working size due to compaction of the soil located on the side surface of the well.

In the third stage, after the compression of the soil along the length of the well and the formation of the diameter of the well to the working size, the pressure in the chamber 4 and the hydraulic pump 6 is reduced to a minimum. Then, an annular plate 8 with a hydraulic jack 10 and an annular fastening element 11 is removed from the carrier pipe 1, at the same time, the pressure in the chamber 4 and the hydrotamp 6 is reset to zero. The cavity formed between the device located in the center of the well and the side surface of the well is filled to the entire working height of the working chamber 4, for example, using a concrete pump, a moving and quick-hardening concrete mixture.

In the fourth step, an annular plate 8 with a hydraulic jack 10 and an annular fastening element 11 is put on again on top of the supporting pipe 1. After fixing all of the above elements on the supporting pipe 1, working pressure is created in the hydraulic jack 10, pressing the annular plate 8 against the surface of the soil base, simultaneously with a small being late in the hydrotamp 6 also creates a working pressure. After the completion of these operations and before the setting of concrete in order to create a prestressing of concrete over the soil in the working chamber 4, the pressure increases discretely (in steps) to a maximum (up to several tens of kg / cm ² ). In this case, the working pressure in the chamber 4 is not reduced until the concrete of the hollow pile shaft reaches the required strength. Then the pressure in the chambers 4, 3 and the hydraulic pump 6 steps decreases to zero, from the supporting pipe 1 is removed the annular mounting element 11, the annular plate 8 and the hydraulic jack 10.

At the fifth stage, with the help of a concrete pump, the lower part of the pile (i.e., the cavity formed from the chamber 3) is filled with quick-hardening concrete with subsequent compaction. Then the upper part of the pile is concreted (in the hydrotampone zone 6). After that, the entire device is removed from the educated

hollow trunk and the classic way arranged head. The result is a stuffed pile, prestressed on the ground.

Structurally, the entire device is assembled on the basis of the carrier pipe and after creating a stuffed pile, prestressed on the ground, it is removed from the internal cavity of the pile for reuse when creating new stuffed piles.

Improving the technical characteristics of the printed piles created using the proposed device is achieved by prestressing the soil along the side surface of the printed piles. The importance of the latter was revealed during the analysis of the operation of rammed and driven piles, reflected in the overview information [4].

The results of the analysis show that, in fact, in contrast to the widespread opinion, the bearing capacity of hanging printed and driven piles is ensured by friction of the lateral surface of the pile against the soil by 60-80% and only by 40-20% by supporting the tip of the pile on lower lying soil . In this case, the bearing capacity of the hanging pile along the lateral surface is provided due to the presence of tangential forces between the pile material and the surrounding soil. In turn, the values of tangential forces along the lateral surface are determined for clay and sandy soils, respectively, according to the following formulas:

where φ and c are the strength characteristics of sandy and clay soil;

F _b.p. - the surface area of the pile;

σ _n.a. - normal pressure on the side surface of the pile (it is formed only under the action of its own weight laid in a printed pile).

An analysis of the above formulas shows that the absolute value of the tangential forces along the side surface of the pile depends on both the area of the side surface of the pile and the normal pressure created on the side surface of the pile.

If we assume that the lateral surface area of the pile is constant, i.e. conditionally F _bp = const. then an increase in normal pressure view. on the lateral surface of the stuffed pile or in other words, the creation, for example, using the proposed device for prestressing the material of the pile on the ground, will allow not tens of percent, but several times (in relation to sandy soils) to increase the bearing capacity of the printed pile, which in turn leads to a decrease in material consumption the pile itself with a simultaneous increase in its overall operational reliability.

If necessary, the prestressed trunk of the stuffed pile can also be made with reinforcement to the entire working height.

In structurally unstable soils, in particular sandy soils, the formation of a prestressed pile shaft is carried out in practice in the same sequence as described above, but with the obligatory use of either a casing or clay concrete mortar.

Using the device allows due to the creation of prestressing material of the pile on the ground several times to increase the bearing capacity of the printed pile, reduce material consumption and at the same time increase its operational reliability.

It is known that today the prestressing of a stuffed pile on the ground is unknowingly created only due to the dead weight of the concrete from which the pile is made. In this case, the prestress, for example, at a depth of 10 meters (when creating a ten-meter stuffed pile) can reach only 2-2.4 kg / cm ² , and according to the hydrostatic law this pressure will decrease to zero as the selected section near the pile under consideration approaches the surface. Using the proposed device, it is possible to create a prestressing pressure of the material of the pile shaft over the soil, reaching several tens of kg / cm ² , which leads to a significant increase in the bearing capacity of the considered printed pile, prestressed over the soil.

The most rational areas of use of the device for the construction of piles, prestressed on the ground are:

- construction of high-rise buildings and structures;

- erection of supporting structures for large-span bridges;

- construction of tanks, gas tanks and bunker structures;

- arrangement of effective retaining walls;

- forced immersion of lightweight lowering wells and caissons;

- construction of “intelligent” objects - buildings and structures in which the bearing capacity of the foundation system depends and is centrally supported based on the magnitude of external loads, the intensity of the process flows and the expected uneven deformations of the soil base.

Information sources

1. Metelyuk N.S., Shishko G.F. Piles and pile foundations. Reference manual. Kiev: Budivelnik, 1977, p. 214.

2. Piling work, ed. I.I.Kosorukova. M: High School, 1974, p. 282.

3. A. S. No. 585252, BI No. 47, 1977.

4. Zhukov N.V. Calculation of short piles for axial pressing loads // Building materials and structures, buildings and structures, issue 3. - M .: VNIIITEIAK. 1989, p. 72.

Claims (1)

A device for creating a stuffed pile, prestressed over a pear, including a supporting pipe, a working chamber and a high pressure chamber, mounted outside the pipe one above the other and placed in the well, characterized in that the device further comprises a hydraulic valve located in the upper part of the supporting pipe adjacent to the working chamber, and above the hydrotampon, the carrier pipe is equipped with a clamping annular plate with stiffeners and a hydraulic jack with an annular fastening element to the carrier pipe; moreover, the working chamber, the high pressure chamber and the hydraulic tampon are made of high strength, waterproof, flexible reinforced material with the possibility of partial stretching in the horizontal direction.