RU117462U1 - COMBINED CONCRETE PILES - Google Patents

Abstract

The utility model is aimed at creating a precast concrete pile with increased impact and corrosion resistance with reduced material consumption and the possibility of using bench technology for formless molding of products. The specified technical result is achieved by the fact that a precast concrete pile of rectangular cross section contains a trunk made of concrete of a class not lower than B25 and longitudinal prestressed reinforcement 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. The prestressed reinforcement is made in the form of tape bundles or ropes woven from them, consisting of longitudinal long basalt or carbon fibers, or fiberglass with a thickness of 5-20 microns or strands of them, with a fiber density in the cross section of the tape bundle of 2-10 thousand tex and tensile strength 0.6-4.0 GPa. 13 zpf; 8 ill.

Description

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

Known prefabricated reinforced concrete prestressed piles with metal wire or rope reinforcement without transverse reinforcement / I /.

A known design of precast reinforced concrete piles of rectangular cross section, containing a trunk of concrete of class B25 or higher and longitudinal prestressed metal reinforcement located in the concrete of the trunk along opposite sides of the pile with the possibility of placing it in the manufacture of piles by formwork technology in the upper and lower peripheral zones. / 2 /

The disadvantages of the known design are reduced corrosion resistance of metal reinforcement, reduced impact resistance of piles caused by increased compressive stresses from compression of concrete by prestressed reinforcement and the absence of transverse and indirect reinforcement, increased metal consumption, especially with large lengths of piles.

The technical task is to create a precast concrete pile with increased impact and corrosion resistance, reduced material consumption with the possibility of using bench technology for formless molding of products.

The problem is solved in such a way that in a precast concrete pile of rectangular cross section, containing a trunk of concrete of a class not lower than B25 and longitudinal prestressed reinforcement 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, according to a utility model, prestressed reinforcement is made in the form of tape bundles or ropes woven from them, consisting of longitudinal long basalt or carbon, or teklovolokon 5-20 microns or filaments of them, with the density of fibers in the cross section of the belt harness thousand 2-10 tex, and a tensile strength of 0,6-4,0 GPa. Moreover, on the lateral faces of the piles, functional protrusions or depressions can be made. In addition, the pile may have at least one through longitudinal cavity of circular, elliptical or rectangular cross-section, and the cross-sectional area of the cavity is less than the cross-sectional area of the concrete pile shaft. In addition, the pile may have at least one closed longitudinal cavity of circular, or elliptical, or rectangular cross-section, with the formation of solid ends with a length of at least two diameters of the cross section of the pile. In addition, the pile may have a cross section in the form of two I-beams with the formation of a through longitudinal cavity of a rectangular or elliptical section. Or may have a cross section of an I-beam. In addition, the end part of the pile can be made with one-sided or two-sided wedge-shaped sharpening. The pile may have a rectangular cross section with an aspect ratio of 1: 1-1: 10. Tape tows may be impregnated with a water-compatible sizing agent, such as starch. In addition, the tape tows or ropes woven from them may be impregnated with a polymer binder. In addition, prestressed reinforcement can be made in the form of ropes woven from strands, impregnated with a cement or polymer binder in an extended state after tensioning the reinforcement in the manufacture of piles. The pile can be made composite of individual elements of piles, interconnected at the ends by means of embedded parts placed along the cross section of the pile and fixed in the mounting holes. The pile may additionally have transverse non-metallic reinforcement. The pile shaft can be made of heavy or fine-grained concrete, or expanded clay concrete, or fiber concrete with mineral or polymer fiber.

The proposed pile differs from the known one in that the prestressed reinforcement is made in the form of tape bundles or ropes woven from them, consisting of longitudinal long basalt, or carbon or glass fibers with a thickness of 5-20 microns or threads from them, with a fiber density in the section of the tape bundle 2 -10 thousand tex and tensile strength of 0.6-4.0 GPa.

This embodiment of the non-metallic reinforcing element is technologically advanced and does not require large expenditures for forming the element from continuous fibers emerging from the spinnerets in the production of fibers. Moreover, the use of basalt or carbon fibers, or fiberglass, as well as their unidirectional arrangement in the bundle, makes it possible to tension the reinforcing element to values close enough to their strength. The density of the tow of 2-10 thousand tex ensures the integrity of the tow and the possibility of impregnation with cement mortar during concreting to achieve reliable adhesion to the concrete matrix of the structure, as well as the possibility of impregnation of the tow with a sizing and polymer composition. In this case, after the polymer composition is impregnated with such a tape bundle with the proposed sizes and parameters, it does not become rigid, but remains a flexible long-length reinforcing element that can be wound on a spool, or wound into bobbins and can be transported in this form to the place of manufacture of concrete structures . Such bundles can be woven into ropes to obtain a periodic surface and improve manufacturability when reinforcing products. In addition, at the ends of the reinforcing element and along the length, anchor devices can be easily made or attached, both to fix the tension and to improve the adhesion of the reinforcing element to the concrete structure.

The bundle offered as a prestressed reinforcing element for concrete piles, or a rope braided from such bundles, is a flexible non-metallic, tensile reinforcing element, fire-resistant, providing increased adhesion to the concrete matrix, easily anchoring, and having a higher module compared to composite reinforcement tensile elasticity up to 100-300 GPa.

These properties are inherent in basalt fiber, carbon fiber, fiberglass tape tows, consisting of "thin, thickened and coarse" in accordance with the textile classification of fibers with a thickness of 5-50 microns.

Figure 1 shows a section of a precast concrete pile; figure 2, 3, 4 - the same as in figure 1, embodiments; 5 is a longitudinal section of the piles, an embodiment of the piles with a closed cavity; 6 is a General view of the piles with pointed wedge-shaped ends; Fig.7 is a General view of a non-metallic reinforcing element for prestressing; Fig.8 fragment of the junction of the elements of the composite piles.

The pile has a rectangular section with an aspect ratio of 1: 1-1: 10. The pile consists of a concrete trunk 1 and non-metallic prestressed reinforcement 2. The trunk 1 of the pile may be made of heavy or fine-grained concrete, expanded clay concrete or fiber concrete, with polymer or mineral fiber.

The prestressed reinforcement 2 is made of glass, basalt or carbon fiber tows 3 or ropes 4 woven from them (see Fig. 7). The main feature of such fittings is flexibility. Bending stiffness appears in the reinforcement only after concreting the product, due to the impregnation with cement or polymer-cement “milk”. Such reinforcement is not susceptible to corrosion, has high tensile strength and fire resistance.

Reinforcement 2 can be pre-stretched to stresses of 300-800 MPa, which provides compression of concrete in the range of 5-10 MPa. Reduced in comparison with metal reinforcement, the prestress increases shock resistance, while the corrosion resistance of the fiber reinforcement allows increasing the ultimate crack opening value. The pile may have indirect 5 and mounting 6 reinforcement, which according to the location in the section of the trunk 1 can be external and internal. External reinforcement 5 (longitudinal and / or transverse) is installed to absorb temporary - mounting and transport loads. External reinforcement can be made of composite reinforcement, i.e. from a tape tow or rope impregnated with a polymer or polymer-cement binder.

The pile can be made with functional protrusions 7 and depressions 8 on the side faces of the pile, to increase the lateral surface or for the convenience of joining adjacent piles in terms of the foundation (figure 2).

To increase the ultimate resistance (bearing capacity on the ground), the pile can be performed with a developed lateral surface, for example, with a cross section in the form of an I-beam (Fig. 3), and a pile with a through cavity 9 - in the form of paired I-beams (Fig. 4).

The pile can be made with a through cavity 9 (figure 4) or with solid ends 10 and a closed cavity 11 of a round, oval, or elliptical section (figure 5). Cavities can reduce concrete consumption without significantly reducing the strength of the trunks, as they are arranged in the least stressed section of the pile section. In addition, to ensure strength and impact resistance, the cavity section cannot be larger than the section of the concrete pile shaft. The cavities in the pile can be along the entire length or only in the middle part, i.e. the pile may be with solid ends 10, so as not to weaken the most stressful places of the pile.

The lower ends and heads of piles may be blunt or pointed. One-sided or two-sided wedge-shaped points 14 serve to facilitate immersion and increase impact resistance by reducing dynamic stresses in the concrete of the barrel during driving (Fig.6).

The pile can be made integral of several sections of individual concrete piles, and the individual piles are interconnected using docking embedded parts 12, which are fastened by pressing the outlets into the technological holes 13.

The technical result of the invention is the creation of prefabricated concrete solid or composite prestressed solid or hollow piles of various types of concrete with increased corrosion resistance due to the use of non-metallic reinforcement, increased impact resistance due to reduced prestressing and the use of external reinforcement, reduced material consumption due to the implementation of cavities in barrel, increased fire resistance through the use of non-combustible fiber reinforcement.

An example implementation of a method of manufacturing products such as a pile.

A feature of prefabricated concrete piles is the difference in the nature of work under the operational and installation loads of the product (when removed from the stand, transported by transport, lifted by a pile driver). Mounting loads require the use of a significant amount of longitudinal reinforcement, which is not used in further work under operational load. In this regard, some of the reinforcement in the proposed model, in particular, mounting, can be made of material that is destroyed during the long-term operation of the product in an alkaline environment of concrete, for example glass fiber, as well as in the form of external reinforcement without a protective layer.

Outdoor reinforcement 5 of the lower level is laid directly on the metal track on the prepared stand to absorb tensile stresses that arise when loading and lifting onto the pile driver, and in places of maximum effort that arise when driving piles in the head and five piles. The external reinforcement 5 is provided with bends for anchoring in concrete. Then, the longitudinal reinforcement 2 is laid out and strained and the massif is concreted with the concrete mixture.

After that, the external reinforcement 5, mounting loops 6 and embedded parts of the upper level are immersed in the freshly formed product. Then carry out heat and moisture treatment and cutting the array into products.

After the manufacture of the product, the external reinforcement does not have a protective layer, since after immersion of the pile the functions of the external reinforcement will be fulfilled.

Information sources:

1. SP 133 ---

2. RF patent No. 74644, cl. MKI E02D 5/30, publ. 07/10/2008 / prototype /.

Claims (14)

1. A precast concrete pile of rectangular cross section, containing a trunk of concrete of a class not lower than B25 and longitudinal prestressed reinforcement located in the concrete of the trunk along opposite sides of the pile with the possibility of placing it in the manufacture of the pile in the upper and lower peripheral zones, characterized in that it is prestressed the reinforcement is made in the form of tape bundles or ropes woven from them, consisting of longitudinal long basalt, or carbon, or fiberglass with a thickness of 5-20 microns or threads of them with a raft fibers in the cross section of the tape tow 2-10 thousand tex and tensile strength of 0.6-4.0 GPa. 2. Precast concrete pile according to claim 1, characterized in that on the side faces are made functional protrusions or depressions. 3. Precast 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 concrete pile shaft. 4. The precast concrete pile according to claim 1, characterized in that it has at least one closed longitudinal cavity of a circular, or elliptical, or rectangular section with the formation of solid ends with a length of at least two diameters of the cross section of the pile. 5. The precast 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 section. 6. The precast concrete pile according to claim 1, characterized in that it has a cross section of an I-beam. 7. The precast 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. 8. The precast concrete pile according to claim 1, characterized in that it has a rectangular cross section with an aspect ratio of 1: 1-1: 10. 9. The precast concrete pile according to claim 1, characterized in that the tape tows are impregnated with a water-compatible sizing agent, for example, starch. 10. Precast concrete pile according to claim 1, characterized in that the tape bundles or ropes woven from them are impregnated with a polymer binder. 11. The precast concrete pile according to claim 1, characterized in that the prestressed reinforcement is made in the form of ropes woven from bundles impregnated with a cement or polymer binder in an extended state after tensioning the reinforcement in the manufacture of piles. 12. The precast concrete pile according to claim 1, characterized in that the pile is made up of separate elements interconnected at the ends by means of embedded parts placed along the section of the pile and fixed in the mounting holes. 13. The precast concrete pile according to claim 1, characterized in that it further has transverse non-metallic reinforcement. 14. The pile according to claim 1, characterized in that it is made of heavy or fine-grained concrete, or expanded clay concrete, or fiber concrete with mineral or polymer fiber.