RU2630338C1 - Method for sinking screw piles into permafrost soil - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: method for sinking screw piles into permafrost soil comprises drilling a pilot hole in the ground at the target depth, screwing a screw pile with one or more blades into it. The diametre of the pilot hole is drilled a few mm more than the actual maximum size of the pile shaft. All blades are rigidly connected to the pile shaft by one screw line. The lower blade is made of two rigidly connected single-turn parts: the first (incoming) part with a thickness T, with the blade diametre increasing from the bottom upwards according to a linear dependence to the value D, and the upper part with a thickness t less than T by several mm, manufactured with a constant blade diametre d less than D by several mm, the remaining blades are made with a thickness t and a blade diametre d. After sinking the screw pile to the target mark, a narrow space between the pile shaft and the borehole walls is filled with aggregate, followed by freezing to the temperature of the surrounding natural permafrost soil. In the process of screwing, the axial load on the pile is changed so that the magnitude of the soil friction on the blade is minimal.

EFFECT: ensuring the possibility of sinking screw piles by reducing the resistance of permafrost soils to their screwing, increasing the bearing capacity of the screw pile.

5 cl, 1 dwg

Description

The invention relates to the construction of foundations and foundations in areas of permafrost distribution.

The immersion of screw piles in permafrost soils causes great difficulties due to their very high strength, significantly exceeding the strength of non-frozen soils, in which screw piles are mainly used.

A known method (prototype), which consists in pre-drilling in the permafrost soil of the leader well with a diameter equal to the diameter of the cylindrical shaft of the screw pile. The depth of the well is equal to the design depth of the screw blade at the bottom of the barrel. The lower end of the barrel is inserted into this well and a pile is screwed. It is assumed that the pile shaft passes without resistance through the leader well, and only helical blades cut through the strong frozen ground [M. Irodov. The use of screw piles in construction. Stroyizdat. M., 1968. Page fifteen.].

The advantage of the prototype is to turn off the drag of the lower end of the trunk, which makes it easier to immerse the screw piles in permafrost soil.

The disadvantages of this method:

- It is impossible to achieve equality of the diameter of the leader well with the diameter of the cylindrical shaft of the helical pile, because, for example, for steel pipes diameter deviations of up to 2.5% of the nominal size are allowed, and the pipe is oval. The larger size of the oval pile shaft with a nominal diameter D will exceed the actual diameter D of the cylindrical leader well, therefore, the soil will resist shear when screwing the trunk, and the goal of eliminating the friction of the side wall of the shaft against the soil will not be achieved.

- The friction of the surface of the helical blade on frozen ground is very high, and this significantly increases the resistance to screwing piles. However, the prototype does not provide measures to reduce the magnitude of this friction.

The aim of the invention is to increase the possibility of immersion of screw piles by reducing the resistance of permafrost soils to their screwing.

The goal is achieved in that the leader well is drilled several mm larger than the actual maximum size of the pile shaft; all blades are rigidly connected to the pile shaft along one helical line; the lower blade is made of two rigidly connected single-turn parts: the first (entry) part, thickness T, with the diameter of the blade increasing linearly from bottom to top to the value D, and the upper part, thickness t, smaller than T by several mm, made with a constant diameter blades d, smaller than D by several mm, the remaining blades are made of thickness t and the diameter of the blades d; after the screw pile has been immersed to the design level, the narrow space between the pile shaft and the borehole walls is filled with aggregate, followed by freezing to the temperature of the surrounding natural permafrost soil; while in the process of screwing the axial load on the pile is changed so that the amount of soil friction on the blade is minimal.

The purpose of the invention is also achieved by the following methods.

The upper part of the leader well, within the limits of an excessively strong upper layer of permafrost, is increased to a diameter exceeding the maximum size of the pile blades.

At a negative outside temperature immediately before immersion in the ground, the inlet of the lower blade is heated to a positive temperature.

The narrow space between the pile shaft and the walls of the leader well is filled with water with a positive temperature, and the broadening of the leader well is filled with drill cuttings removed during drilling.

The narrow space between the pile shaft and the walls of the well is filled with water vapor under pressure with a quick immersion of the steam needle to a depth of up to the upper blade of a multiblade screw pile or up to half the depth of immersion of a single-blade pile with subsequent rapid cessation of steam supply and removal of the steam needle, and then the leader well broadening fill with drill cuttings removed during drilling.

Comparative analysis with the prototype shows that the inventive method is distinguished by the totality of the above features. This allows us to conclude that the sign of "novelty."

Comparison not only with the prototype, but also with other technical solutions in the art did not allow them to identify signs that distinguish the claimed method from the prototype, which allows us to conclude that the criterion of "significant differences".

In FIG. 1A shows a screw pile with two blades, immersed in permafrost soil; in FIG. 1B shows a screw pile submerged in permafrost soil with a stepped shape of a leader well; in FIG. 1B shows a joint of two parts of a lower helical blade; in FIG. 1G shows a cross section of permafrost soil with a screw pile.

Method description

Screw piles are screwed into very strong permafrost soils in the winter, when the weak marshy soils typical of the Far North are completely frozen and can support the weight of heavy construction equipment. The temperature of the topsoil 2 during this period reaches -25 ° C and below (Fig. 1A, 1B). Screwing piles into such a layer is not possible for currently available construction equipment.

The proposed method takes into account the specific features of permafrost soils:

- preservation of the helical shape of the air voids formed in the soil after the passage of the blades, while all helical blades are rigidly connected to the pile shaft along one helical line;

- heating and local partial thawing of frozen soil during mechanical or thermal effects on it.

When screwing, it is usually necessary to overcome the resistance of very strong frozen soil under the lower end of the pile shaft, along the lateral surface of the shaft and when screw blades are introduced into the soil. In order to facilitate the process of immersion of a screw pile, the present invention proposes to carry out the following activities:

- To exclude soil resistance under the lower end of the pile shaft 1, it is proposed to pre-drill the leader well 4 in the soil along the entire length of the lateral surface of the shaft (Fig. 1A, 1B and 1G). The diameter of leader hole 4 is drilled several mm larger than the actual maximum size of pile shaft 1, because the trunk of the pipe may actually have an oval cross-sectional shape (see above). The optimum diameter is the borehole 4, determined by the formula: 1,025D _t +2 mm, where D _t - nominal diameter of the barrel.

- At a very low temperature of the upper layer 2 of frozen soil, sometimes the machine torque is not enough to screw the piles. In this case, the upper part of the leader well, within the excessively strong upper layer of permafrost soil, is increased to a diameter exceeding the maximum size of the pile blades, and screwing the piles starts from the bottom of this broadened leader well 5, lowering the lower screw blade to a depth with a higher temperature and therefore, less durable soil (Fig. 1B).

- In the initial stage of screwing screw piles 1 usually have to cut the bottom blade 7 into the most durable surface soil with the lowest temperature, so the bottom blade is made of two rigidly connected by welding single-turn parts. The first (entry) part 7 is made with the diameter of the blade increasing linearly from bottom to top to the value D, and the upper part 6 is made with a constant diameter of the blade d, less than D by a few mm. The thickness T of the lower entry part of the blade 7 is made several mm more than the upper - t (Fig. 1B). This method allows the use of a thick and wide helical track cut by the blade inlet portion 7 of thickness T and diameter D. For screwing the upper half of the lower blade into it without resistance, this part of the blade is made not only thinner, but also slightly smaller in diameter. The trace of screwing a thick screw lead-in can also be used to screw the following screw blades 8 with a smaller thickness t and a diameter d for the variant of multi-blade piles.

- The presence of a narrow gap between the shaft of the pile 1 and the well 4 and the presence of a hollow screw trace in the soil after the passage of the screw blades weaken the bearing capacity of the screw pile during operation. For this reason, after immersion of the screw pile to the design elevation, it is desirable to fill in the narrow space between the pile shaft and the walls of the well with filler. As a result, all air voids are filled, and the bearing capacity of the pile increases.

Filling can be done by pouring water into the gap between the walls of the leader hole 4 and the pile shaft 1 with a temperature that ensures its passage to freezing to the lower blade and filling the voids from the trail of screw blades.

Another filling option is to supply pressurized water vapor to the indicated air gap, with quick one-time short-term immersion of the steam needle to a depth to the upper blade of a multiblade screw pile or to half the immersion depth of a multiblade pile, followed by a quick stop of steam supply after reaching the required depth and removing the steam needle . After that, in the presence of a broadening 5 of the upper part of the leader well 4, it is filled with cuttings or sand removed during drilling. The advantage of this method is that with active steaming under pressure, the frozen ground partially thaws, the steam condenses, and the resulting liquefied water-ground mixture fills the gap around the barrel 1 and screw voids. This mixture after freezing has greater strength than ice, therefore, the bearing capacity of the pile increases to a greater extent than in the first embodiment.

- In the process of screwing a screw pile, a normal load R acts on its screw blade, leading to the appearance of very large friction forces S on the upper screw surface of the blade (Fig. 1E). It is proposed to exclude these friction forces due to the axial external load P transmitted by the machine for screwing piles. To do this, the axial load P on the pile during the pile immersion process is changed so as to compensate to a value close to zero, the action of the force R arising in the frozen ground 3 when screwing the blade 7 (Fig. 1E). This will lead to the fact that the amount of friction of the soil 3 about the blades 6 and 8 will become minimal, close to zero.

- When using machines for screwing piles with insufficient amount of forced external vertical load P, it becomes necessary to find other ways to reduce the friction forces on the surface of a helical blade. This can be achieved by the fact that when the outside temperature is negative, immediately before immersion in the ground, the inlet part of the lower blade is heated to a positive temperature. It is convenient to produce heating, for example, by supplying hot air with high temperature through the sleeve (hose) of the air heater. The warm surface of the blade allows you to create between its surface and permafrost soil a thin layer of water-saturated thawed soil with a friction coefficient of 1.5-2 times less than that of permafrost without heating. With further screwing of the pile, the elevated temperature of the blade stabilizes and remains due to the release of heat from friction when screwing the blade.

Claims (5)

1. The method of immersing screw piles in permafrost soil, which consists in drilling in the soil at the design depth of the leader well, screwing into it a screw pile with one or more blades, characterized in that the diameter of the leader well is drilled several mm larger than the actual maximum size of the pile shaft; all blades are rigidly connected to the pile shaft along one helical line; the lower blade is made of two rigidly connected single-turn parts: the first (entry) part, thickness T, with the diameter of the blade increasing linearly from bottom to top to the value D, and the upper part, thickness t, smaller than T by several mm, made with a constant diameter blades d, smaller than D by a few mm, the remaining blades are made of thickness t and the diameter of the blades d; after the screw pile has been immersed to the design level, the narrow space between the pile shaft and the borehole walls is filled with aggregate, followed by freezing to the temperature of the surrounding natural permafrost soil; while in the process of screwing the axial load on the pile is changed so that the amount of soil friction on the blade is minimal. 2. The method of immersing screw piles according to claim 1, characterized in that the upper part of the leader well, within the excessively strong upper layer of permafrost soil, is increased to a diameter exceeding the maximum size of the pile blades, and screwing starts from the bottom of this enlarged part of the leader well. 3. The method of immersion of screw piles according to claim 1, characterized in that at a negative outside temperature immediately before immersion in the ground, the inlet part of the lower blade is heated to a positive temperature. 4. The method of immersing screw piles according to claim 1, characterized in that the narrow space between the pile shaft and the walls of the leader well is filled with water at a positive temperature, and the broadening of the leader well is filled with drill cuttings or sand removed during drilling. 5. The method of immersing screw piles according to claim 1, characterized in that steam is supplied into the narrow space between the pile shaft and the walls of the well under pressure with a one-time quick immersion of the steam needle to a depth of up to the upper blade of the multiblade screw pile or to half the immersion depth of the multiblade pile followed by a rapid shutdown of the steam supply and the removal of the steam needle, and after that the broadening of the leader well is filled with drill cuttings removed during drilling.

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