RU74644U1 - REINFORCED CONCRETE PILES - Google Patents

Abstract

1. A precast reinforced concrete pile of rectangular cross section, containing a trunk of concrete of a class not lower than B25 and longitudinal prestressed reinforcement, characterized in that the prestressed reinforcement is located in the concrete of the trunk along opposite sides of the pile with the possibility of placing it in the manufacture of piles in the upper and lower peripheral zones while the ribs of the piles are made with mounting chamfers or mounting longitudinal sides. 2. Precast reinforced concrete pile according to claim 1, characterized in that on the side faces are made functional protrusions or depressions. Precast reinforced concrete pile according to claim 1, characterized in that it has at least one through longitudinal cavity of a circular, or elliptical, or rectangular section, and the sectional area of the cavity is less than the sectional area of the pile shaft. Precast reinforced concrete pile according to claim 1, characterized in that it has a cross section in the form of two I-beams with the formation of a through longitudinal cavity of a rectangular or elliptical cross section. Precast reinforced concrete pile according to claim 1, characterized in that it has a section of a tee or an I-beam. Precast reinforced concrete pile according to claim 1, characterized in that the end part of the pile is made with one-sided or two-sided wedge-shaped sharpening. Precast reinforced concrete pile according to claim 1, characterized in that the ends are made with chamfers. Precast reinforced concrete pile according to claim 1, characterized in that it is additionally equipped with prestressed reinforcement along the side faces. Precast concrete pile according to claim 1, characterized in that the barrel is made of polymer concrete. Precast reinforced concrete pile according to claim 1, characterized in that the barrel is made of fiber

Description

No. 2007120193

Description

Prefabricated reinforced concrete pile.

The invention relates to deep foundations, namely, to the construction of driven piles.

Known driven reinforced concrete piles of a solid square section with longitudinal prestressed reinforcement. /one/

The closest design to the proposed one is a prismatic concrete pile with a central prestressed reinforcing bar and transverse frames / 2 /.

The disadvantages of the design of such piles is that the prestressed reinforcement is located in the center of the cross section of the pile, which does not exclude the occurrence of cracks and breakdowns during transportation and installation even with additional transverse reinforcing cages, which leads to an increase in material consumption to ensure the bearing capacity of the piles, as well as the complexity of the technology of their manufacture, including hollow, and therefore to increase costs.

The technical problem is to ensure the bearing capacity of piles and manufacturability while reducing costs by eliminating transverse reinforcement, reducing material consumption and increasing crack resistance during installation.

The problem is solved in such a way that in a precast reinforced concrete pile of rectangular cross section containing a trunk of concrete of a class not lower than B25 and longitudinal prestressed reinforcement, according to the invention, prestressed reinforcement is located in the concrete of the trunk along opposite sides of the pile with the possibility of placing it in the manufacture of piles in upper and lower peripheral zones, while the ribs of the piles are made with mounting chamfers or mounting longitudinal sides. At the same time, functional protrusions or depressions can be made on the side faces. A precast reinforced concrete pile may have through longitudinal cavities of circular, or elliptical, or rectangular cross-section, and the cavity cross-sectional area is smaller than the cross-sectional area of the pile shaft. A pile may have at least one or two through longitudinal cavities. A pile may have a section in the form of two I-beams with the formation of a through longitudinal cavity of a rectangular or elliptical section, or a section of a tee or an I-beam. In this case, the end part of the pile is made with one-sided or two-sided wedge-shaped sharpening. Or on the ends of the pile is made with chamfers. In addition, the pile is additionally equipped with prestressed reinforcement along the side faces. The pile shaft can be made of polymer concrete, or fiber concrete. In this case, the pile can be equipped with mounting loops. In addition, the pile has a rectangular cross section with an aspect ratio of 1: 1-1: 10.

The proposed design of the piles differs from the known one in that the prestressed reinforcement is located in the concrete of the trunk along opposite sides of the pile with the possibility of placing it in the manufacture of piles in the upper and lower peripheral zones, and longitudinal longitudinal beams or chamfers are made on adjacent side faces. Moreover, the pile has a rectangular cross section with an aspect ratio of 1: 1-1: 10. The pile may have through longitudinal cavities of circular, or elliptical section, one or more. A precast reinforced concrete pile may have a section formed by two I-beams with one through longitudinal cavity of a prismatic or elliptical section, or a section of an I-beam. Prefabricated reinforced concrete pile as a prestressed reinforcement contains reinforcing bars, or high-strength wire, or rope reinforcement. In this case, it can be additionally equipped with prestressed reinforcement along the side faces for additional rigidity. The trunk of a precast reinforced concrete pile can be made of polymer concrete or fiber concrete, which makes it possible to exclude transverse reinforcement. In addition, the pile, if necessary, can be equipped with mounting loops at a distance from the ends equal to 0.21 of the length of the pile, which simplifies the installation of the pile in the design position before immersion. A feature of reinforced concrete piles is different work at a certain stage: the manufacture, transportation, indentation and direct operation of the pile as a supporting structure. Therefore, the developed design of the pile allows it to be a universal reinforced concrete element that can work on bending and compression, both separately and simultaneously. In the development of piling reinforcement without transverse reinforcement, a rational solution was achieved in the operation of piles in all conditions from manufacture to operation. After manufacturing, during storage and transportation to the construction site, the pile works exclusively in bending. Moreover, during transportation, it is necessary to take into account the dynamic impact in accordance with SP 52-102-2004. When immersed, the pile works in compression, while the reinforcement of the pile is partially involved in the work. The main task in the development of piles was the possibility of using the indentation technology, which, when the pile is immersed, eliminates the dynamic effect on the reinforced concrete element. The use of static force during indentation allows a gentle effect on the pile without destroying it.

One of the advantages of the proposed pile is the free use of various shapes and sizes of sections. Limitations are determined by the conditions of technological capabilities of formless molding and the technology of immersion piles by pressing. Section shapes are determined from the condition of the most efficient use of the reinforced concrete element in the operation of piles with minimal use of material resources. The design of the pile cross-section can allow the use of both symmetric and asymmetric reinforcement, depending on which loading parameter is dominant - compressive force or bending moment.

The main cross-sectional shapes of piles are rectangular in various versions. Since the molding technology does not allow transverse reinforcement to be placed, for this purpose special protrusions along the entire length are provided in the geometry of the pile — the sides that allow the piles to be moved and stored using special gripping devices.

The proposed reinforcement by prestressed reinforcement along opposite sides provides increased bending strength and crack resistance of a factory-made pile, which is transported in a horizontal position, and also eliminates transverse reinforcement. In addition, this arrangement of prestressed reinforcement allows you to perform through longitudinal cavities without concrete collapse and to form edges or chamfers, which simplify installation work, while making it possible to expand the product range with complex sections.

In FIG. 1 presents a precast reinforced concrete pile - general view; figure 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14 - section of figure 1 (options); Fig.15, 16, 17 - a fragment of the end of the pile (options); FIG. 18 is a view A of FIG. 17; Fig.19 is a cross section of Fig.1 embodiment of the location of the reinforcement on the side faces; Fig.20 is a longitudinal section of a pile (option with mounting loops); Fig.21 is a cross section of Fig.1 (option asymmetric reinforcement).

The pile consists of a concrete shaft 1 and prestressed reinforcement 2. On the sides of the pile, mounting longitudinal beams 3 or mounting chamfers are made 4. On the opposite side faces of the pile, functional (locking) depressions 5 or protrusions are made 6. The pile can be made with one through longitudinal cavity 7 or with several. If necessary, a solid pile has additional mounting loops 8.

In FIG. 2 and 3 show variants of rectangular sections of piles with mounting longitudinal sides 3 (Fig. 2) and with mounting chamfers 4 (Fig. 3). Figures 4 and 5 show cross-sections of piles with functional depressions 5 and protrusions 6 for making a locking joint and using the pile as a dowel. Figure 6-11 shows options for rectangular sections of piles with one or more longitudinal holes. On Fig, 13, 14 shows respectively a section formed by two I-beams, T-beams and I-beams. In Fig.15,16 shows embodiments of the end of the pile in the form of a one-sided and two-sided wedge-shaped sharpening. On Fig.17.18 - an embodiment of the ends with chamfers to prevent chip concrete barrel. In Fig.19 is a variant of additional prestressed reinforcement along the side faces to increase the rigidity of the structure, and in Fig.21 asymmetric reinforcement for the possibility of using the structure as a dowel with a cross-sectional dimension of more than 1: 1.5. On Fig shows the location of the mounting loops in solid piles.

Piles are made as follows.

Piles are produced by a continuous molding method, for example, by extrusion or vibrocompression, using formwork technology on long stands and contain only longitudinal working reinforcement along the entire length of the pile. A feature of reinforcing piles is the peripheral location of reinforcement placed both symmetrically and asymmetrically with respect to two opposite faces of the pile. The design of the piles implies the location of tensile reinforcement in a compressed zone of concrete. The developed design of reinforced concrete piles allows using any formless molding technology for its manufacture, which makes it universal. The peripheral location of the working fittings allows the most effective work of piles for bending during transportation, storage and installation. The optimal geometry of piles with peripherally located prestressed reinforcement can significantly reduce the cost of steel and concrete, and formless molding technology reduces the cost of reinforced concrete products up to 30%. The use of prestressed piles extends the technological capabilities of the formworkless production line. The minimum class of concrete that can be used for the production of piles is B25, which together provides the structural bearing capacity.

As prestressed reinforcement can be used:

- high-strength wire of class BP-II of any diameter;

- steel cable fittings of various classes and diameters.

Using prestressing, the crack resistance of a reinforced concrete pile is increased. The use of high-strength wire allows you to significantly reduce steel costs without affecting the work of the pile at a bending moment during transportation to the construction site. It should be noted that the main indicator is the work of the pile according to the second limiting state (1st category in crack resistance). The use of prestressing dramatically changes the operation of a reinforced concrete pile compared to its conventional counterparts. The reinforcement of the developed pile is such that the first and second ultimate state of the pile is achieved simultaneously. This means that cracking will not occur until the pile is destroyed. A complete exhaustion of the bearing capacity of the reinforcement in the pile occurs, since the second limit state (cracking) occurs later than the first. The location of the cable and wire reinforcement should be such that the molding machine does not interfere with the molding process.

Information sources:

1. "Designer Guide" edited by G.I. Berdichevsky, M. Stroyizdat, 1974, pp. 385-387.

2. RF patent No. 2049856, cl. E02D 5/30 publ. 1995.12.10 (prototype).

Claims (12)

1. A precast reinforced concrete pile of rectangular cross section, containing a trunk of concrete of a class not lower than B25 and longitudinal prestressed reinforcement, characterized in that the prestressed reinforcement is located in the concrete of the trunk along opposite sides of the pile with the possibility of placing it in the manufacture of piles in the upper and lower peripheral zones while the ribs of the piles are made with mounting chamfers or mounting longitudinal sides. 2. Precast reinforced concrete pile according to claim 1, characterized in that on the side faces are made functional protrusions or depressions. 3. The precast reinforced concrete pile according to claim 1, characterized in that it has at least one through longitudinal cavity of circular, or elliptical, or rectangular cross-section, and the cross-sectional area of the cavity is less than the cross-sectional area of the pile shaft. 4. The precast reinforced concrete pile according to claim 1, characterized in that it has a section in the form of two I-beams with the formation of a through longitudinal cavity of a rectangular or elliptical section. 5. Precast reinforced concrete pile according to claim 1, characterized in that it has a section of a tee or an I-beam. 6. The precast reinforced concrete pile according to claim 1, characterized in that the end portion of the pile is made with one-sided or two-sided wedge-shaped sharpening. 7. Precast reinforced concrete pile according to claim 1, characterized in that the ends are made with chamfers. 8. Precast reinforced concrete pile according to claim 1, characterized in that it is additionally equipped with prestressed reinforcement along the side faces. 9. Precast reinforced concrete pile according to claim 1, characterized in that the barrel is made of polymer concrete. 10. Precast reinforced concrete pile according to claim 1, characterized in that the barrel is made of fiber reinforced concrete. 11. The controversial reinforced concrete pile according to claim 1, characterized in that it is equipped with mounting loops. 12. Precast reinforced concrete pile according to claim 1, characterized in that it has a rectangular cross section with an aspect ratio of 1: 1-1: 10.