RU120976U1 - TUBULAR PILES - Google Patents

Abstract

1. Tubular pile, including a hollow cylindrical shaft with spiral blades located flush with the lower end of the pile shaft, while the width of the blades decreases from top to bottom, coming to naught, characterized in that the number of spiral blades is at least equal to two, and the lines of connection of the blades with the pile shaft represent (1 / 4-1 / 2) part of the spiral turn, the width of the spiral blade Vlop is (0.25-1.0) Dst, the height of the spiral blade Hlop = (1-2 ) · Dstv, and the angle of inclination of the spiral blade "α" to the generatrix of the cylindrical shaft of the pile is in the range from 45 ° to 80 °. ! 2. A tubular pile according to claim 1, characterized in that the hollow cylindrical pile shaft is additionally equipped with a tapered tip, the length of which Lfin is (1.2-1.6) · Dst. ! 3. A tubular pile according to claim 1 or 2, characterized in that in the upper part of the pile there are at least two blades located diametrically opposite to the blades located in the lower part of the pile. ! 4. A tubular pile according to claim 2, characterized in that the inner cavity of the pile shaft is filled with concrete or cement-sand mortar. ! 5. A tubular pile according to claim 2, characterized in that a reinforcing cage is mounted in the inner cavity of the pile shaft. ! 6. A tubular pile according to any one of claims 1 to 5, characterized in that the pile shaft is protected with an anti-corrosion coating. ! 7. A tubular pile according to any one of claims 1 to 5, characterized in that a layer of polymer coating is additionally applied to the anti-corrosion coating.

Description

The utility model relates to construction, in particular to the construction of piles and can be used as foundations for the supports of power lines and supports of the contact network, cell towers, foundations of buildings, fences, anchors, in the supports of bridges, pipelines, moorings and other structures.

Known tubular pile [see Utility Model of the Russian Federation No. 87717, IPC E02D 5/00 (2006.01), publ. 20.10.2009], which includes a hollow cylindrical barrel, equipped with a support flange at the upper end, connected to the barrel by stiffeners, and four spiral blades in the lower part, attached to the outer surface of the barrel. The connection lines of the spiral blades with the outer surface of the trunk represent ¼ of the spiral loop. The width of all the blades located in the lower part of the trunk decreases from top to bottom and comes to naught at the lower end of the pile shaft. In the upper part, the barrel is equipped with four additional spiral blades of constant width, the connection lines of which with the outer surface of the barrel represent ¼ part of the spiral loop.

However, the known tubular pile has an unreasonably complex design (supporting flange at the upper end of the pile; stiffening ribs connecting the upper part of the pile shaft with the supporting flange; two groups of spiral blades in the upper and lower parts of the pile). As a result, the pile has 8 spiral blades. The complex, metal-intensive, heavyweight construction of the described pile creates serious limitations on the operational capabilities of the pile. To immerse such a pile into the ground, special heavy equipment installed on heavy machines is required.

The closest in its technical essence to the proposed utility model is a tubular pile [see Utility Model of the Russian Federation No. 29536, IPC 7 E02D 5/28, 5/48, publ. 05/20/2003].

The tubular pile includes a hollow cylindrical trunk, on the outer surface of which spiral blades are located. The upper part of the pile shaft with stiffeners is connected to a horizontally located supporting flange. The blades are flush with the end of the pile, while the number of blades is at least four. The blade is a plate with decreasing width. The ratio of the radius of the barrel (R _c ) to the maximum width of the blade (b) is (2.0-2.2), the height of the blade (H) is equal to (1.5-1.6) the diameter of the barrel (D _c ). The line connecting the blade with the trunk is ¼ part of the spiral loop. The blades are placed on the pile shaft in such a way that one pair of diametrically arranged blades has a section with a maximum width in the area of the pile end, and a section with a minimum width is on the other pair.

The advantages of the closest analogue include simplicity of design, lower metal consumption, and, consequently, weight compared to the analogue described above.

However, the described technical solution, selected as a prototype, has a number of disadvantages.

The disadvantages of the known tubular piles are:

1. A significant amount of soil resistance arising from the introduction (driving) of piles into the soil. This is mainly due to the large number of blades (in the prototype, at least 4 blades).

2. The low value of the bearing capacity of the pile along its axis, as well as its stability relative to the horizon. These shortcomings are due to the imperfection of the ratio of the geometric parameters of the elements of the pile, namely: the small width and height of the blade relative to the diameter of the pile shaft.

It is also necessary to consider in more detail the effect of the angle “α” formed by the spiral line of the blade and the horizon line on the bearing capacity of the pile along its axis. The magnitude of this angle is not considered at all in the technical solution selected as a prototype. However, judging by the drawing presented in the description of the patent, this angle is much larger than 45 °, which negatively affects the magnitude of the bearing capacity of the pile along its axis. This is also a significant drawback of the design of the pile selected as a prototype.

In addition, the following should be noted. For the durability of the known piles (we are talking about its stability against corrosion), the pile must have a significant wall thickness, that is, a large metal consumption and mass. This leads to the fact that for the installation of such piles in the ground requires special heavy equipment.

The tasks posed when creating the proposed utility model are: simplifying the design of piles, reducing the metal consumption and laboriousness of manufacturing a pile, its weight and cost while increasing the bearing capacity of the pile along the axis and its horizontal stability.

Another task set when creating a utility model is to increase the life of the pile.

To solve these problems, a tubular pile is proposed, which, like the pile closest to it, selected as a prototype, includes a hollow cylindrical trunk with spiral blades located flush with the lower end of the pile shaft. The width of the blades decreases in the direction from top to bottom, going "to nothing". A feature of the proposed tubular piles, distinguishing it from the known piles selected as a prototype, is that the number of spiral blades is at least two. The connection lines of the blades with the pile shaft represent (¼-½) part of the spiral loop. The width of the blades B _lop is (0.25-1.0) · D _ST ; blade height H _lop = (1-2) · D _stem , and the angle of inclination of the blade "α" to the generatrix of the cylindrical shaft of the pile is in the range from 45 ° to 80 °.

The hollow cylindrical trunk of the tubular pile can be additionally equipped with a conical tip, the length of which L _con = (1,2-1,6) · D _stem .

At least two blades can be located in the upper part of the tubular pile, diametrically opposed to the blades located in the lower part of the pile.

The internal cavity of the trunk of a tubular pile with a conical tip can be filled with concrete or cement-sand mortar, and, in addition, a reinforcing cage can be mounted in it.

The trunk of the tubular pile, both with a flat end and with a conical tip, can be protected by a corrosion-resistant coating, on which a polymer coating can be applied.

The technical result achieved in the proposed utility model is obtained due to the following.

Unlike the closest analogue containing at least four blades, the proposed pile has two blades, which greatly simplified the design and reduced the complexity of manufacturing piles. Thus, part of the tasks was solved, namely: simplifying the design, reducing the metal consumption and the complexity of manufacturing piles, its cost and weight.

Essential features of the claimed design are the ratio of the geometric parameters of the barrel and spiral blades of the claimed tubular piles. The geometrical parameters of the blades (width of blade B _LLRs, blade height H _LLR and the angle «α» blade inclination to the generatrix of the pile shaft) obtained in the course of numerous experiments have optimal ratio which provided a significant decrease in soil resistance, and as a consequence, the introduction of the blade into the soil without deformation of the material. The optimal ratios of these parameters were confirmed experimentally by test results.

Thus, despite a decrease in the number of blades, compared with the closest analogue, which, at first glance, should lead to a decrease in the efficiency of the pile, as a result of significant changes in the geometry of the blades (increasing the width of the blade to the diameter of the shaft of the pile, increasing the length of the line of connection of the blades with the pile shaft up to ½ of the spiral turn, which increases the projection area of the pile blades) the bearing capacity of the pile for loading and pulling along the axis increases, and the soil resistance when introduced into of the pile is reduced. As a result, a two-bladed pile, which is simpler in design and manufacturing technology, as well as having reduced weight and metal consumption, is effectively introduced into the soil.

To increase the bearing capacity of the tubular pile along the axis, it was proposed to additionally equip the pile with a conical tip with geometry in the claimed range: L _con = (1.2-1.6) · D _stem .

To increase the horizontal stability of the pile, which is especially important when introducing piles into thawed soils, at least two blades are installed in the upper part of the pile at a distance of 1-1.5 meters from the upper end of the pile shaft, placed diametrically opposite to the blades located at the bottom of the pile.

An additional feature regarding the protection of the pile shaft with an anti-corrosion coating (see paragraph 6 of the utility model formula) prevents the destruction of the material of which the pile is made from corrosion. This is due to the high adhesion of epoxy enamels to the metal, as well as their neutral reaction to both acidic and alkaline soil media.

In the proposed utility model, it is proposed that an additional polymer coating in the form of a protective film be applied to that part of the pile shaft that is in the area of seasonal freezing and thawing of the soil (see paragraph 7 of the utility model formula). The film protects the epoxy coating applied to the pile shaft from seasonal vertical soil movements. These additional features contribute to the implementation of such an important task as increasing the life of the pile.

Thus, the combination of the above features allows us to solve the tasks.

It should also be noted that depending on the nature and properties of the soil in which it is required to install the pile, as well as on the formulation of specific tasks, the pile may have, for example, three or more spiral blades. Moreover, in its upper part, three or more additional blades can be installed, respectively.

Below is described one of the specific examples of the implementation of the proposed utility model.

The utility model is illustrated by drawings, which depict:

figure 1 - the proposed tubular pile (General view);

figure 2 - a view of figure 1 (enlarged);

figure 3 - a tubular pile with a conical tip;

figure 4 - a tubular pile with four blades (in accordance with paragraph 3 of the proposed utility model);

5 is a view B in figure 4;

6 is a tubular pile with a reinforcing cage installed in it, filled with concrete mortar;

7 is a tubular pile with anti-corrosion and polymer coating installed in the ground.

The tubular pile (see _figure 1) is a hollow cylindrical barrel 1, the outer diameter of which D _trunk in this particular example is 108 mm. Flush with the lower end of the pile shaft, two spiral blades 2 are welded to it. The connection lines of the blades 2 with the shaft 1 of the pile are, in this specific example, 1/3 of the spiral loop.

Width B _Lop helical blade 2 which decreases in the direction from top to bottom and goes "out" is (0,25-1,0) · D _PTS and in this particular example is 80 mm.

The height of the spiral blade 2 piles H _lop = (1-2) · D _shaft , in a specific example is 162 mm

The angle α of the inclination of the spiral blade 2 of the pile to the generatrix of the cylindrical shaft 1 of the pile is in the range from 45 ° to 80 ° and is, for example, 65 ° in this case.

To increase the bearing capacity of the piles along the axis, the tubular pile is additionally equipped with a conical tip 3, the length of which L _con is in the range (1.2-1.6) · D _shaft and is, for example, 160 mm.

To increase the horizontal stability of the pile in its upper part at a distance of, for example, 1.5 meters from the upper end of the pile, two blades are installed, placed diametrically opposite to the blades located in the lower part of the pile (see figure 4 and figure 5).

To increase the service life of the piles with the conical tip shown in figure 3, its cavity is filled with concrete or cement-sand mortar 4, while in the cavity of the trunk 1 of the pile can be installed reinforcing frame 5, which, preventing deformation of the trunk, gives the pile additional rigidity (see Fig.6).

In addition, to protect the piles from corrosion (see Fig. 7), an anti-corrosion coating 6 is applied to the pile shaft 1, for example, EP-439C, TU 2312-010-73357552-2004 epoxy enamel, manufactured by SK PALMIRA, St. Petersburg, Russia. On that part of the trunk 1, which is in the area of seasonal freezing and thawing of the soil, an additional polymer coating 7 is applied, for example, a heat-shrinkable two-layer tape (with an adhesive layer) TL-450 or TL-630, TU TF. 3235-01, manufactured by CJSC TERMOFIT, St. Petersburg, Russia, forming a protective film.

The table below shows some more specific examples of the implementation of the claimed utility model for tubular piles with different diameters of the trunks.

Example 2 Example 3 Example 4 Barrel diameter D _trunk , mm 57 159 89 The width of the spiral blade B _lop , mm thirty 120 89 The height of the spiral blade H _lop , mm 90 180 160 The length of the conical tip L _to mm 75 - 140 The angle of inclination of the pile blades to the generatrix of the cylindrical shaft "α", deg 75 65 65 The connection line of the blades with the pile shaft, part of the spiral 1/2 1/3 1/2

If you go beyond the upper limits of the intervals of the declared parameters due to an increase in soil resistance, more force will be required when installing the piles in the soil. As a result, it may be necessary to use heavy equipment, which can lead to damage to the pile blades. If the declared intervals deviate to a smaller side, the bearing capacity of the pile for loading and pulling is reduced.

The immersion of a tubular pile with spiral blades is as follows.

For permafrost soils, it is first necessary to drill a borehole with a diameter equal to the diameter of the trunk D _stem using a drilling rig to a design depth that provides the required bearing capacity. Then, a vibratory hammer is installed on the pile head and the vibration-shock mode is turned on. Spiral blade piles cut into the ground. To immerse a tubular pile with spiral blades in melt soils, drilling a leader well is not required.

The above examples should not be construed as limiting the scope of patent claims of the proposed utility model. For any person skilled in the art it is clear that there is the opportunity to make many changes to the design described above without departing from the essential features of the utility model stated in the formula.

Thus, the proposed tubular pile, in contrast to the prototype, has a simpler and more technologically advanced construction, as well as reduced material and labor consumption compared to the prototype in the manufacture and installation of piles in the ground. In addition, changes in the geometry of the proposed pile provide a significant increase in bearing capacity along the axis of the pile and its horizontal stability.

Claims (7)

1. A tubular pile including a hollow cylindrical trunk with spiral blades flush with the lower end of the pile shaft, while the width of the blades decreases in the direction from top to bottom, going "to nothing", characterized in that the number of spiral blades is equal to at least two, and the line of junction of the blades to the barrel piles are (1 / 4-1 / 2) part of the spiral coil, the width of the helical blade is in _Lop (0,25-1,0) · D _PTS helical blade height H _LLR = ( 1-2) · D _stem , and the angle of inclination of the spiral blade "α" to the generatrix of the cylindrical whose trunk pile is in the range from 45 ° to 80 °. 2. The tubular pile according to claim 1, characterized in that the hollow cylindrical shaft of the pile is further provided with a conical tip, the length of which L _con is (1.2-1.6) · D _stem . 3. The tubular pile according to claim 1 or 2, characterized in that at least two blades are located in the upper part of the pile, placed diametrically opposite to the blades located in the lower part of the pile. 4. The tubular pile according to claim 2, characterized in that the internal cavity of the pile shaft is filled with concrete or cement-sand mortar. 5. The tubular pile according to claim 2, characterized in that a reinforcing cage is mounted in the inner cavity of the pile shaft. 6. Tubular pile according to any one of claims 1 to 5, characterized in that the pile shaft is protected by a corrosion-resistant coating. 7. A tubular pile according to any one of claims 1 to 5, characterized in that the polymer coating layer is additionally applied to the anti-corrosion coating.