RU37114U1 - DOUBLE WALL - Google Patents

Description

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DOUBLE MOUNT

The utility model relates to sheet pile walls, mainly from steel tubular piles and can be used in hydraulic engineering for the construction of sea and river moorings, as well as in construction for the construction of retaining walls for various purposes.

Known retaining wall, including concrete piles, sheaths and elements of steel sheet pile, fixed longitudinally on their outer surfaces (Levachev S.P. Shells in hydraulic engineering. M., Stroyizdat, 1978, p. 76, Fig. 43-P).

The disadvantage of this known design is the high material consumption and the complexity of manufacturing, as well as insufficient tightness.

The closest analogue of the proposed technical solution is a sheet pile wall, mainly a berth or embankment, including piles, each pile consisting of a pipe and a pair of sheet piles rigidly fixed to its outer surface, i.e. steel sheet pile elements with locks on free edges. By means of locks adjacent piles are interconnected. Steel sheet pile elements

made L-shaped in cross section, i.e. in plan, and are located obliquely with respect to the axis of the sheet pile wall passing through the longitudinal axis of the tubular piles (RU 2010085 C1, 03.30.94).

In this well-known sheet pile wall, the locks of all sheet piles, i.e. The shaped elements of the steel sheet pile are arranged on neutral, i.e. the longitudinal axis of the sheet pile wall in the plan, and the L-shaped elements of the steel sheet pile themselves are placed alternately in opposite directions relative to the said axis of the sheet pile wall, so that the sheet pile wall has a zigzag profile in the plan. The tongue-and-groove profile of the sheet pile wall provides it with high load-bearing capacity.

However, this known sheet pile wall is laborious both in the manufacture of piles and in construction.

This is due to the fact that when fixing the L-shaped elements of a steel sheet pile to each tubular pile, it is necessary to ensure the specified orientation of each L-shaped element in opposite directions relative to the tubular pile and are skew-symmetric to each other, as a result of which the design of the stand on which the pipe is mounted with steel sheet pile elements.

in space in order to ensure pairwise connection of locks and their placement on a given project line - the neutral axis of the sheet pile wall in plan. To do this, you need a non-standard conductor of a rather complicated configuration.

When driving piles on hard ground, some deviation from the given angular orientation of the L-shaped elements is possible, which can lead either to a deviation from the design direction of the sheet pile wall, or to the inability to connect adjacent piles into a lock. When correcting a wrong, clogged pile, additional stresses arise in the locks, the likelihood of opening the locks increases, which can lead to a decrease in tightness and erosion of the soil of the enclosed space.

Another disadvantage of this known sheet pile wall is its lack of tightness in the area of castle joints, which is especially necessary in hydraulic structures and zones of sheet pile walls that are difficult to control.

Thus, the disadvantages of the known wall also include high requirements for the accuracy of driving piles during its construction and insufficient tightness.

The technical task of the proposed utility model is to create a sheet pile wall structure devoid of the above disadvantages.

The technical result is a reduction in labor costs as in the manufacture of wall elements, i.e. tubular piles with steel sheet piling elements fixed on them, as well as during the construction of the sheet piling itself, as well as increasing the tightness and soil tightness of the structure with high load-bearing ability;

The indicated technical problem is solved due to the fact that in the sheet pile wall it is mainly a berth or embankment that contains sheet piles, each of which consists of a pipe and at least one pair of steel sheet pile elements with longitudinal locks rigidly fixed on its outer surface, by means of which adjacent piles are interconnected, according to the proposed utility model, each pile is provided with an additional pair of steel sheet piling elements, the pile pipes are made of steel, the elements of the steel sheet piling are flat They are fixed and secured to the pipes by welding with stirring; they are paired in two rows in planes parallel to the plane passing through the longitudinal axis of the pipes.

The cavity between two rows of elements of a flat steel sheet pile can be filled with a seal; it can be filled with material, concrete mixes or soil.

sheet piles can be carried out on welding stands of a simple design. When welding, there is no need for complex spatial orientation of the welded flat tongue and groove elements. When erecting the proposed sheet piling wall due to the straightness in terms of the elements of the flat steel sheet piling, a standard conductor can be used to ensure high productivity and the quality of driving sheet piles; there is no need for complex spatial orientation of the sheet piles

Due to the supply of each sheet piling with an additional pair of elements of a flat steel sheet piling with their arrangement in two rows, the bearing capacity of the sheet pile wall increases, which is associated with an increase in the moment of resistance of the structure.

In the case of filling the space between two rows of elements of a flat steel sheet pile with soil, sealing materials, concrete or other mixtures (with or without reinforcement), a sharp increase in the bearing capacity, durability and soilproofness of the tongue and groove wall is achieved.

The essence of the utility model is illustrated by drawings, where:

figure 1 shows a General view of the tongue and groove wall, a cross section;

The tongue and groove wall according to the proposed utility model contains hammered piles 1 hammered into the ground and locked, interconnected into a lock. Each pile consists of a steel pipe 2 and four elements 3, 4, 5 and 6 of a flat steel sheet pile welded to its outer surface longitudinally, each of which has tongue-and-groove locks 7 on a free, non-welded edge. Through the locks 7, each pile 1 is connected “into the castle with two adjacent piles 1 of the sheet pile wall (except for the extreme piles).

Piles 1 are made on a specially equipped welding stand (not shown). When welding, the elements 3 and 4 of a flat steel sheet pile are spread out, shear in one plane parallel to the diametrical plane of the pipe, i.e. the plane passing through; through the longitudinal axis of the pipe, with the formation of the first row. Elements 5 and 6 of a flat steel sheet pile are welded to the pipe in another plane parallel to the diametrical plane of the pipe to form a second row. In this case, the locks 7 of the elements of a flat steel sheet pile sheet 1 are finished, pairwise in opposite directions from the pipe 2.

It should be noted that the term “in parallel for the purposes of this application is used not in the mathematical sense, but with reference to construction and hydraulic engineering, and means parallelism within the tolerances accepted in these branches of engineering.

The distance from the diametrical plane of the pipe 2 of each pile to the plane in which the elements 3 and 4 of the flat steel sheet pile are located may be equal to or not equal to the distance from the diametrical plane of the pipe 2 to the plane in which the elements 5 and 6 of the steel sheet sheet are located.

In the sheet pile according to the proposed utility model

the longitudinal axis of the tongue and groove wall in plan coincides with the diametrical plane of the pipes. Therefore, in the sheet pile wall elements 3, 4 and 3, 4, etc.

flat steel sheet pile are located on one side relative to the longitudinal axis of the sheet pile wall in plan, and the elements of the flat steel sheet pile 5, 6 and 5, 6, etc. - on the other side.

Piles 1, 1, etc. the proposed sheet pile wall is immersed using a conductor of simple design. After immersion of piles in the internal cavity between two rows of elements of a flat steel sheet pile, they drain, fill the soil, concrete or concrete mixtures with or without reinforcement, or other sealing mixtures. This is a guarantee of ensuring the corrosion resistance of the structure, its durability and soil resistance, especially in uncontrolled areas.

The proposed design of the sheet pile wall in addition to the above has the following advantages:

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simplified design scheme in comparison with the prototype, which ultimately leads to material savings; the convenience of transporting piles is increased, which reduces transport costs.

Claims (2)

1. A tongue-and-groove wall, mainly of a berth or embankment, made of sheet piles, in which each pile consists of a pipe and at least one pair of steel sheet piling elements with longitudinal tongue-and-groove locks rigidly fixed on its outer surface, by means of which adjacent piles are interconnected, characterized in that each pile is equipped with an additional pair of steel sheet pile elements, the pile pipes are made of steel, and the steel sheet sheet elements are made flat and fixed to the pipes by welding with by placing them in pairs in two rows in planes parallel to the plane passing through the longitudinal axis of the pipes. 2. The tongue wall according to claim 1, characterized in that the cavity between the two rows of elements of the flat steel sheet pile is filled with sealing material, concrete mixtures or soil.