RU2708330C1 - Piling wall - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention relates to hydraulic engineering and general civil engineering and can be used in marine and river construction of port facilities, construction of embankments and berths, retaining walls at shore-reinforcement grids, as well as in road construction, construction of tunnels and foundations in cramped conditions. Piling wall comprises piles of metal pipes interconnected by intermediate elements by means of welding, equipped with locking elements for connection of piles into piling wall. Line of the piling wall in the plan is formed by one of the faces of polyhedral piles and locking elements connecting the piles to each other, and each of the faces of the piles is formed by two pipes and an intermediate element installed between them. In piles with number of faces more than three between pipes of different faces there are additional intermediate elements dividing section of pile on part of triangular section.

EFFECT: increasing cross-section stiffness and stability when submerging into soil by indentation or blocking-up during the construction of the piling wall, increased reliability of connection of piles in the wall without opening of lock joints, as well as increased load capacity of piling wall with possibility of use at its construction of cheaper welded pipes rolled from roll by longitudinal rolling, reduced prime cost of construction.

1 cl, 4 tbl, 2 dwg

Description

The invention relates to hydraulic engineering and civil engineering and can be used in sea and river construction of port facilities, the construction of embankments and moorings, retaining walls during shore protection works, as well as in road construction, construction of tunnels and foundations in cramped conditions.

Known sheet pile wall for the construction of moorings, embankments, canals, retaining walls during shore protection works and other hydraulic structures, containing piles in the form of metal pipes, fully or partially immersed in the ground, and locking elements connecting them into a single wall along the construction line (RF Patent No. 2185476, IPC Е02В 3/06, published on July 20, 2002).

A disadvantage of the known sheet pile wall is that when erecting sheet pile walls with a large difference in ground level in the construction zone, expensive pipe piles with a large diameter and high moment of resistance of the pile section to bending are required. When constructing berths for servicing ships with large displacement and draft, it is necessary to ensure a very large difference in the levels of the berth and bottom of the underwater part, while the length of piles from pipes reaches 60 m. When submerging long piles with a large depth of immersion in the ground, problems arise with their deviation from the design position (fan), while there is the possibility of opening and breaking castle joints. To ensure minimal deviations from the design position, piles with a margin of safety are applied when applying a vertical load and with a diameter exceeding the diameter of commercially produced pipes with individual production at metal structures, which significantly increases the cost of construction.

Known sheet pile wall for the construction of moorings, embankments, canals, retaining walls during shore protection works and other hydraulic structures, containing piles in the form of metal pipes, fully or partially immersed in the ground, and locking elements connecting them into a single wall along the construction line. (Hot Rolled Sheet ESC Joints, p. 52 http://www.escpilehk.com/downloads/ESC_Russian_General_Catalogue_20162017_Revision_1_Q42016.pdf). The catalog shows the characteristics of pipe piles with an external diameter of 609.6-2133.6 mm and a moment of resistance of the cross-section meter of the running meter of the wall 3358-33857 cm ³ . When designing sheet pile walls that temporarily and permanently enclose a construction site and are used for shore protection and dredging works in sea and river construction of port facilities, embankments and moorings, special attention is paid to the wall's ability to absorb bending loads from water-saturated and bulk soils in the construction zone, as well as the rigidity of the piles making up the wall and their ability to immerse in soil without deformations or deviations from the design position (stability ). For hydraulic structures, tongue-and-groove walls are often used, made of large diameter cylindrical pipes with welded lock joints, which have high characteristics in terms of resistance moment and metal utilization factor. In this case, the pipes are installed along the line of the sheet pile wall and are interconnected by locking elements. Depending on the level difference and the type of soil separated by a sheet pile wall in the construction zone, typical electric-welded pipes with a diameter of 426-1420 mm and more are used.

A disadvantage of the known sheet pile wall, as in the previous known technical solution, is that when erecting sheet pile walls with a large difference in soil level in the construction zone and a large depth of immersion in the soil, it is necessary to use pipe piles with a large diameter with a high moment of resistance of the pile section to bending and high rigidity. When immersing long piles in the ground, problems arise with their deviation from the design position (fan), while there is the possibility of rupture of the castle joints. To ensure minimal deviations from the design position, piles with a margin of safety are applied when applying a vertical load and with a diameter exceeding the diameter of commercially produced pipes with individual production at metal structures, which significantly increases the cost of construction.

Known sheet pile wall closest to the claimed technical solution, mainly a berth or embankment, made of sheet piles, in which each pile consists of a pipe and a pair of locking elements rigidly fixed on its outer surface, by means of which adjacent piles are interconnected (Patent RU 37113 IPC Е02В 3/06, published on April 10, 2004). In the known technical solution, the piles are made of metal pipes and interconnected by locking elements located in the same plane, in parallel planes or in intersecting planes.

A disadvantage of the known sheet pile wall, as in previous known technical solutions, is the lack of rigidity and stability of the pile when it is driven into the ground. In the known technical solution, the rigidity of the pile is increased in only one direction (in the direction of the pipe to be joined together), which does not increase the stability of the pile when it is immersed, and it is possible to open and break the castle connection of the piles to each other and lose the tightness of the wall being constructed. Therefore, in the construction of sheet pile walls for moorings and other hydraulic structures with a large difference in the level of the soil in the construction zone and a large depth of immersion, large diameter pipes are used, including individually manufactured ones with a diameter exceeding those commercially manufactured, which significantly increases the cost of construction.

The objective of the present invention is to increase the stiffness of the cross section and the stability of piles when they are immersed in the ground by hammering the pile while constructing the sheet pile wall, increasing the reliability of the connection of piles in the wall without opening lock joints, and also increasing the load capacity of the sheet pile with the possibility of using cheaper welded walls pipes rolled from a roll by the method of longitudinal rolling, reducing the cost of construction.

The solution to this problem is achieved by the fact that in a sheet pile wall containing piles of metal pipes interconnected by intermediate elements by welding, equipped with locking elements for connecting piles to the sheet pile wall, the sheet pile wall line is formed in plan by one of the faces of polyhedral piles and locking elements, connecting the piles to each other, and each of the faces of the piles is formed by two pipes and an intermediate element installed between them, while in piles with the number of faces more than three between the pipes of different faces, additional intermediate elements are installed, dividing the pile section into parts of a triangular section. In this case, the size of the faces of polyhedral piles can be either the same or different. The tongue and groove wall can be made as a combination of multifaceted piles with the same number of faces, and a combination of multifaceted piles with a different number of faces.

The invention is illustrated by drawings, which depict:

in FIG. 1 is a transverse section of a sheet pile wall,

in FIG. 2 - section AA of the sheet pile wall, a combination of trihedral and tetrahedral piles.

The tongue wall 1 contains piles 2 of metal pipes 3, interconnected by intermediate elements 5 by welding, completely or partially immersed in the ground 4 and provided with locking elements 6 and 7 for connecting the piles 2 to the tongue wall 1. The tongue wall 1, for example, is formed a combination of faces 8 of trihedral piles 9 and faces 10 of tetrahedral piles 11. Each of faces 8 of trihedral piles 9 is formed by two pipes 3 with an outer diameter of "Dn", wall thickness "s", the distance "l" between the centers of the pipes in the corners of the pile and the intermediate ment 5, bonding them together by welding. Locking elements 6 and 7 are welded to the pipes 3 of one of the faces for connecting the piles 9 to the sheet pile wall 1. The tetrahedral pile 11 is formed by four faces 10, while each of the faces 10 is formed by two pipes 3 with an outer diameter of “Dn”, wall thickness “s ", The distance" l "between the centers of the pipes and the intermediate element 5, connecting them together. Locking elements 6 and 7 are welded to the pipes 3 of one of the faces 10 for connecting the piles 11 to the sheet pile wall 1. At the same time, two pipes 3 of the tetrahedral pile 11, located diagonally on the pile, are connected by welding with an additional intermediate element 12, dividing the section of the pile into two parts 13 and 14 of a triangular section.

Tables 1-4 show the results of computer simulation on the change in moments of inertia, stiffness and bending moments of pipe sections in a triangular and quadrangular pile depending on the distance between the centers of the pipes in piles, the outer diameter and wall thickness of the pipes (excluding intermediate elements between the pipes ) The designations in tables 1-4 and in FIG. 2 mean:

L is the distance between the centers of the pipes in the corners of the trihedral and tetrahedral piles, cm;

Dн - outer diameter of a cylindrical pipe, cm;

S is the wall thickness of the pipe, cm;

Jx3, Jx4 - moments of inertia of the sections of cylindrical pipes, respectively, of trihedral and tetrahedral piles with respect to the neutral axes x3-x3 and x4-x4 (excluding intermediate elements), cm ⁴ ;

Jx30, Jx40 - moments of inertia of the cross sections of three and, respectively, four cylindrical pipes aligned in a line x0-x0, cm ⁴ ;

Cx3, Cx4 — stiffness of the sections of cylindrical pipes of trihedral and, respectively, tetrahedral piles (Cx = Jx * E, where E is the elastic modulus, N / m ² ), N / m ² ;

Cx30, Cx40 - section stiffness of three and four cylindrical pipes, lined up in the line x0-x0, N / m ² ;

Wx3, Wx4 - moments of resistance of pipe sections of trihedral and tetrahedral piles with respect to the neutral axes x3-x3 and x4-x4, cm ³ ;

Wx30, Wx40 - moments of resistance of the sections of three and four cylindrical pipes, lined up in the line x0-x0, cm ³ ;

The values of l / Dн and s / Dн are given in relative values (fractions);

The values Jx / Jx0, Cx / Cx0 and Wx / Wx0 are given in percent.

The simulation results indicate a significant increase in the rigidity and stability of trihedral and tetrahedral piles composed of cylindrical pipes compared to piles made of cylindrical pipes and installed in one line along the sheet pile wall.

When a pile is immersed in the soil, a vertical compressive force acts on it. The critical compressive force, under the action of which the pile loses stability, is determined by the Euler formula: Fcr = π ² E J min / (μ N) ² , where E is the elastic modulus (N / m ² ); J min is the minimum moment of inertia of the pile section (cm ² ); μ is the coefficient of the reduced length; N - pile height (cm). It can be seen from the above formula that with an increase in the minimum moment of inertia of the pile (J min), the critical force (Fcr), at which the pile loses its stability, directly increases. The above confirms that in order to increase the stability of piles when immersed in the soil, it is advisable to use polyhedral piles, for example, trihedral or tetrahedral, composed of cylindrical pipes.

Analysis of tables 2, 4 shows that with increasing rigidity and stability of piles when they are immersed in the soil, the load capacity of a sheet pile wall made of trihedral or tetrahedral piles composed of cylindrical pipes also increases. It should be noted that the implementation of piles with the formation of rigid triangular joints using intermediate elements between the pipes eliminates the mutual displacement of the pipes in the section of piles.

The invention can be used in the construction of quays of embankments, embankments and other hydraulic structures with a high sheet pile wall, and also allows to reduce construction costs through the use of cheaper welded pipes of smaller diameter, made of hot-rolled strip wound into a roll.

Claims (1)

A tongue-and-groove wall containing piles of metal pipes interconnected by intermediate elements by welding, equipped with locking elements for connecting the piles to the tongue wall, characterized in that the line of the tongue wall in plan is formed by one of the faces of the many-sided piles and locking elements connecting the piles to each other , and each of the faces of the piles is formed by two pipes and an intermediate element installed between them, while in piles with a number of faces more than three between pipes of different faces are installed up to olnitelnye intermediate elements that divide the cross section of the pile on a part of triangular cross section.

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