RU229916U1 - Hexagonal profile sheet pile - Google Patents

Abstract

The utility model relates to construction, namely to metal sheet piles intended for use in hydraulic engineering, transport, industrial and civil engineering in the structures of sheet pile walls of permanent and temporary structures. In particular, the utility model can be used in the construction of berths, locks, dams, dock structures, mooring dolphins, bridge supports; the construction of retaining walls; coastal protection, water intake and drainage structures; treatment facilities, collectors, tunnels, underground structures, ring closed and open structures, fences; in the arrangement of pits, slopes, foundations, trench walls.

The tongue and groove is made with a hexagonal profile and is provided with locking elements secured to the outer surface of the hexagonal profile by means of welding, wherein the hexagonal profile is formed from two tongue and grooves connected to each other by longitudinal welds, each of which contains a shelf made of strips of structural steel and two inclined walls located at an obtuse angle to the shelf and connected to it by longitudinal welds. The main part of the flange and the main part of the inclined walls of each sheet pile are made of strips of structural steel containing carbon in the range from 0.1 to 0.2%, silicon in the range from 0.4 to 1.1%, manganese in the range from 0.4 to 1.7%, nickel in the range from 0.1 to 0.8%, chromium in the range from 0.1 to 0.9%, vanadium in the range from 0.1 to 0.15%, copper in the range from 0.2 to 0.6%, with a yield strength in the range from 265 to 400 MPa, wherein at least one end portion of the flange or inclined wall of each sheet pile is made of a reinforced strip of structural steel, transversely connected by welding to the main part of the corresponding flange or inclined wall, and the ratio of the length of the end portion of the flange or the end portion of the inclined wall made of the reinforced strip structural steel, to the length of the entire sheet pile is in the range from 0.01 to 0.25.

The technical result of the utility model consists in more efficient use of steel in the manufacture of sheet piles with a hexagonal profile while simultaneously ensuring its high reliability and low metal consumption.

Description

The utility model relates to construction, namely to metal sheet piles intended for use in hydraulic engineering, transport, industrial and civil engineering in the structures of sheet pile walls of permanent and temporary structures. In particular, the utility model can be used in the construction of berths, locks, dams, dock structures, mooring dolphins, bridge supports; the construction of retaining walls; coastal protection, water intake and drainage structures; treatment facilities, collectors, tunnels, underground structures, ring closed and open structures, fences; in the arrangement of pits, slopes, foundations, trench walls.

The immersion of sheet piles into the soil mass is usually carried out in one of three ways: vibratory driving, pressing in or driving. Pressing in is used where vibration of the soil cannot be allowed. Hammer driving is used to pass through heavy soils and for finishing. Both of these methods are quite expensive. The most common method of immersion is vibratory driving. When immersing with a vibratory driver, the sheet pile is hooked using special jaws that clamp the sheet pile shelf on both sides.

During immersion, the upper part of the sheet pile experiences increased load (impact from the hammer, compression and bending from the vibratory driver). Also, at the base of the sheet pile, there is an increased load and wear from contact of the base of the sheet pile with the soil, soil penetration during immersion. The base of the sheet pile has to be used to push stones apart in the ground, cut tree roots, etc. In this regard, as a rule, after the first immersion and removal of the sheet pile, its end parts (upper and base) are significantly deformed. It also happens that in the case of severe deformation at the base of the sheet pile, it is necessary to replace the sheet pile with a new one.

The prior art discloses a tongue and groove made with a hexagonal profile and equipped with locking elements, wherein the hexagonal profile is formed from strips of structural steel longitudinally connected to each other by welding, and the locking elements are fixed to the outer surface of the hexagonal profile by welding (Patent of the Russian Federation No. 213673, published on September 21, 2022).

For its production, structural steel grades 09G2S, 17G1S, S345 can be used, which have a yield strength of 265 to 400 MPa. In this case, the amount of metal required per linear meter of the sheet pile length to ensure the required moment of resistance with the same cross-sectional profile shape is greater, the lower the yield strength of the metal. Therefore, to prevent deformation of the end parts of this sheet pile during immersion, it is necessary to make shelves and walls forming a hexagonal profile of greater thickness, which increases the metal content and weight of the sheet pile.

Also, structural steel grades S420MC, S460MC S500MC S550MC S600MC with a yield strength in the range from 420 to 600 MPa can be used for its production. The use of special steel with a yield strength in the range from 420 to 600 MPa allows, under all equal conditions, to make the walls and shelves of the sheet pile thinner, i.e. the total volume of metal (metal consumption) required for the construction of sheet pile walls is reduced. At the same time, the sheet pile is capable of resisting loads of the same magnitude. However, the production of the entire sheet pile from steel with a tensile strength in the range from 420 to 600 MPa significantly increases the cost of the product.

The task, which the utility model is aimed at solving, is the development of a welded sheet pile with a hexagonal profile, devoid of the disadvantages of known analogues, as well as the expansion of the arsenal of technical means for the specified purpose.

The technical result of the utility model consists in more efficient use of steel in the manufacture of sheet piles with a hexagonal profile while simultaneously ensuring its high reliability and low metal consumption.

The technical result is achieved in that the tongue and groove is made with a hexagonal profile and is provided with locking elements secured to the outer surface of the hexagonal profile by means of welding, wherein the hexagonal profile is formed from two tongue and grooves connected to each other by longitudinal welds, each of which contains a shelf made of strips of structural steel and two inclined walls located at an obtuse angle to the shelf and connected to it by longitudinal welds. The main part of the flange and the main part of the inclined walls of each sheet pile are made of strips of structural steel containing carbon in the range from 0.1 to 0.2%, silicon in the range from 0.4 to 1.1%, manganese in the range from 0.4 to 1.7%, nickel in the range from 0.1 to 0.8%, chromium in the range from 0.1 to 0.9%, vanadium in the range from 0.1 to 0.15%, copper in the range from 0.2 to 0.6%, with a yield strength in the range from 265 to 400 MPa, wherein at least one end portion of the flange or inclined wall of each sheet pile is made of a reinforced strip of structural steel, transversely connected by welding to the main part of the corresponding flange or inclined wall, and the ratio of the length of the end portion of the flange or the end portion of the inclined wall made of the reinforced strip structural steel, to the length of the entire sheet pile is in the range from 0.01 to 0.25.

It is advisable that the end parts of the inclined walls of each sheet pile be made of reinforced strips of structural steel, transversely connected by welding to the main parts of the inclined walls.

It is advisable that at least one end part of the flange of each sheet pile be made from a strip of structural steel of greater thickness than in the main part of the flange.

It is advisable that the ratio of the thickness of the end part of the shelf to the thickness of the main part of the shelf be within the range from 1.1 to 2.

It is advisable that at least one end part of the flange and/or the end parts of the inclined walls of each sheet pile be made of strips of structural steel with a yield strength of at least 420 MPa.

It is advisable that the ratio of the length of the end portion of the inclined walls of each sheet pile, made from a reinforced strip of structural steel, to the length of the entire sheet pile be within the range of 0.01 to 0.25.

It is advisable that the angle between the inclined wall and the shelf be from 91° to 150°.

It is advisable that the locking elements be located on the outer surface on both sides of the hexagonal profile symmetrically relative to the central axis of the sheet pile cross-section.

It is advisable that at least one locking element be made in the form of a collar formed by an angular profile welded with the edge of one of the shelves to the wall of the hexagonal profile.

It is advisable that at least one locking element be made in the form of a strip part equipped at the free end with a cam formed by a round profile welded to the surface of the strip part, and/or a collar formed by an angular profile welded with the edge of one of the shelves to the surface of the strip part.

It is advisable that the end of the strip part of at least one locking element be connected by welding to the hexagonal profile along the lines of the welded connection between two walls of the hexagonal profile or with a wall or with a shelf of the hexagonal profile.

It is advisable for the sheet pile to have a protective paint coating.

It is advisable that the sheet pile be provided with U-shaped elements in cross-section, welded to the surface of at least one shelf and/or wall of the hexagonal profile.

The utility model is illustrated by drawings:

Fig. 1 shows the first version of the sheet pile (general view).

Fig. 2 shows the first version of the tongue and groove (top view).

Fig. 3 shows the first version of the sheet pile (cross section).

Fig. 4 shows the second version of the tongue and groove design (general view).

Fig. 5 shows the second version of the tongue and groove (top view).

Fig. 6 shows the second version of the sheet pile (cross section).

Fig. 7 shows the third version of the tongue and groove design (general view).

Fig. 8 shows the third version of the tongue and groove design (top view).

Fig. 9 shows the third version of the sheet pile (cross section).

Fig. 10 shows the fourth version of the sheet pile (general view).

Fig. 11 shows the fourth version of the tongue and groove design (top view).

Fig. 12 shows the fourth version of the sheet pile (cross section).

Fig. 13 shows the fifth version of the sheet pile (general view).

Fig. 14 shows the fifth version of the tongue and groove design (top view).

Fig. 15 shows the fifth version of the sheet pile (cross-section).

Fig. 16 shows the sixth version of the sheet pile (general view).

Fig. 17 shows the sixth version of the tongue and groove design (top view).

Fig. 18 shows the sixth version of the sheet pile (cross section).

Fig. 19 shows the seventh version of the sheet pile (general view).

Fig. 20 shows the seventh version of the tongue and groove design (top view).

Fig. 21 shows the seventh version of the sheet pile (cross section).

Fig. 22-26 - variants of sheet pile locking elements.

The tongue and groove is made with a hexagonal profile and is provided with locking elements. The hexagonal profile is formed from two mirror-symmetrical welded tongue and grooves connected to each other by longitudinal welds, each of which has a trough-shaped profile and contains a shelf 1 made of strips of structural steel and two inclined walls 2, 3 located at an obtuse angle to the shelf and connected to it by longitudinal welds. In a preferred embodiment, the tongue and groove is made with an equilateral hexagonal profile, where the widths of the shelves 1 and the walls 2, 3 are equal.

The main part 6 of the shelf 1 and the main part 7 of the inclined walls 2, 3 of each sheet pile are made of hot-rolled strips of structural steel containing carbon in the range from 0.1 to 0.2%, silicon in the range from 0.4 to 1.1%, manganese in the range from 0.4 to 1.7%, nickel in the range from 0.1 to 0.8%, chromium in the range from 0.1 to 0.9%, vanadium in the range from 0.1 to 0.15%, copper in the range from 0.2 to 0.6%, with a yield strength in the range from 265 to 400 MPa.

Preferably, for the main part 6 of the shelves 1 and the main part 7 of the inclined walls 2, 3, use corrosion-resistant steel grade 09G2S with a yield strength of 265, 295, 315, 325, 345, 355, 375 MPa, steel grade 15HSND with a yield strength of 325, 345 MPa, steel grade 10HSND with a yield strength of 345, 375, 390 MPa, steel grade 17G1S with a yield strength of 315, 325, 345, 355, 375 MPa or C390 with a yield strength of 390 MPa.

For a more rational distribution of metal in the section of the profile and to ensure the necessary strength characteristics of the sheet pile, on at least one side (Fig. 1-3, Fig. 13-15), and preferably on both sides (Fig. 10-12, Fig. 16-18) of the sheet pile, the end parts 8 of the shelves 1 are made of reinforced strips of structural steel, transversely connected by welding to the main part 6 of the shelves 1. Also, on at least one side (Fig. 7-9), and preferably on both sides (Fig. 4-6, Fig. 19-21) of each sheet pile, the end parts 9 of the inclined walls 2, 3 can be made of reinforced strips of structural steel, transversely connected by welding to the main parts 7 of the walls 2, 3.

The ratio of the length L ₁ of the end portion 8 of the shelf 1 or the length L ₂ of the end portion 9 of the inclined wall 2, 3, made of a reinforced strip of structural steel, to the length L of the entire sheet pile should be within the range from 0.01 to 0.25 for more efficient use of steel and simultaneous provision of high reliability and low metal consumption of the sheet pile.

L ₁ , m L ₂ , m L, m L ₁ /L _L2 /L Example 1 0.3 0.3 30 0.01 0.01 Example 2 1.25 1.0 25 0.05 0.04 Example 3 2.0 1.75 20 0,1 0.09 Example 4 2.1 1.85 15 0.14 0.12 Example 5 1.5 1.9 10 0.15 0.19 Example 6 1.25 1.05 5 0.25 0.21 Example 7 1.25 1.25 5 0.25 0.25

Preferably, in the case of production from a reinforced strip of structural steel and end parts 9 of inclined walls 2, 3, the difference between the lengths of the reinforced strips should be L3, with L3≥0.2 m, which is dictated by the distance between the transverse welds necessary to ensure high strength characteristics of the product.

To strengthen the end parts 8 of the shelves 1, thickened strips of structural steel containing carbon in the range from 0.1 to 0.2%, silicon in the range from 0.4 to 1.1%, manganese in the range from 0.4 to 1.7%, nickel in the range from 0.1 to 0.8%, chromium in the range from 0.1 to 0.9%, vanadium in the range from 0.1 to 0.15%, copper in the range from 0.2 to 0.6%, with a yield strength in the range from 265 to 400 MPa (Fig. 13-18) can be used.

The ratio of the thickness t ₃ of the end part 8 of the shelf 1 to the thickness t ₁ of the main part 6 of the shelf 1 may be within the range from 1.1 to 2.

To strengthen the end portions 8 of the shelves 1 and/or the end portions 9 of the inclined walls 2, 3, hot-rolled strips of structural steel can also be used, in which carbon does not exceed 0.47%, silicon does not exceed 0.7%, manganese does not exceed 2.2%, phosphorus does not exceed 0.025%, sulfur does not exceed 0.015%, aluminum does not exceed 0.015%, nickel does not exceed 2.5%, chromium does not exceed 1.5%, copper does not exceed 0.5%, niobium does not exceed 0.12%, vanadium does not exceed 0.2%, titanium does not exceed 0.22%, molybdenum does not exceed 0.7%, boron does not exceed 0.005% with a yield strength in the range of at least 420 MPa. In this embodiment, the end portions 8 of the shelves 1 and/or the end portions 9 of the inclined walls 2, 3 can have the same thickness as the main portion 6 of the shelves 1 and/or the main portion 7 of the inclined walls 2, 3 (Fig. 1-12).

For the production of end parts 8 of shelves 1 and/or end parts 9 of inclined walls 2, 3, steel grades S420MC, S460MC, S500MC, S550MC, S600MC, Hardox 400, Hardox 450, Hardox 500, Hardox 550, Hardox 600, steel of categories X70, X80, X90, X100 and others with a yield strength of 420 MPa and more can be used. When using these steel grades, which are more resistant to corrosion and have a yield strength in the range of 420 MPa and more, it is possible not to increase the thickness of the end parts 8, 9, ensuring the necessary strength characteristics.

There may also be a variant of the sheet pile design, when at least on one side, and preferably on both sides, the end parts 8 of the shelves 1 are made of strips of structural steel of greater thickness t ₃ than the thickness t ₁ of the main part 6 of the shelves 1, and the end parts 9 of the inclined walls 2, 3 are made of strips of structural steel with a yield strength of at least 420 MPa (Fig. 19-21).

It is also possible to use, for reinforcing at least on one side of the sheet pile of the end parts 8 of the shelves 1 and/or the end parts 9 of the inclined walls 2, 3, strips of structural steel with a yield strength of at least 420 MPa of greater thickness than the thickness of the main part 6 of the shelves 1 and/or the main part of the walls 2, 3, respectively.

For better penetration of the sheet pile into the ground, the shelves 1 and walls 2, 3 in the base that form the hexagonal profile can be made with one-sided or two-sided chamfers on the edges.

The locking elements can be located on the outer surface of the hexagonal profile on both sides of the hexagonal profile symmetrically relative to the central axis 4 of the transverse section of the tongue on two inclined walls 2, 3 of the hexagonal profile (Fig. 22). In this case, each locking element is made in the form of a collar 5 formed by an angular profile welded with the edge of one of the shelves to the wall 2, 3 of the hexagonal profile.

The locking element can also be made in the form of a strip part 10 equipped at the free end with a cam 11 formed by a round profile welded to the surface of the strip part 10 (Fig. 23), and/or a collar 12 (Fig. 24) formed by an angular profile welded with the edge of one of the shelves to the surface of the strip part 10 (Figs. 23-25). Such locking elements are located on the outer surface of the hexagonal profile on both sides along the lines of the welded joint between the inclined walls 2, 3 of the hexagonal profile, wherein the strip parts 10 of the locking elements are in the same plane. The collar 12 and/or the cam 11 in this case are located on the inner surface of the strip parts 10 of the locking elements so that they do not touch the external aggressive environment (water).

The tongue and groove can also be made with a double lock (according to the utility model under Russian Federation patent No. 181356) to strengthen the locking connection. In this case, the strip part 10 of each locking element is equipped at the free end with both a cam 11 and a collar 12 (Fig. 26).

By using common universal rolled steel profiles (angle and circle) as a collar 10 and a cam 9, the design of the locking elements 2 is simplified. And the location of the cam 9 and the collar 10 close to the edges of the strip parts 8 of the locking elements 2 increases the water resistance of the locking joint.

The locking elements can also be any other known locking elements for metal sheet piles from foreign or Russian manufacturers, and possible design options for the locking elements are disclosed in Russian patent No. 213673.

The locking elements may be located on two or more sides on the outer surface of the hexagonal profile and be in one or more planes. In the preferred embodiment, the locking elements are fixed on two sides of the hexagonal profile along the lines of the welded joint between the inclined walls 2, 3 of the hexagonal profile, wherein the strip parts 10 of the locking elements are in one plane. Also allowed are embodiments when at least one of the locking elements is located on the outer surface of the hexagonal profile and is connected by the end of the strip part 10 by welding to the shelf 1 or the inclined wall 2, 3. Thus, for example, the corner tongue can be made in such a way that the locking elements are located on the outer surface of the hexagonal profile, and their strip parts 10 are in two planes, the angle between which can be from 90° to 135°, wherein the end of the strip part 10 of one locking element is connected by welding to the profile along the line of the welded joint between the inclined walls 2, 3 of the hexagonal profile, and the end of the strip part 10 of the second locking element is connected by welding to the outer surface of one of the inclined walls 2, 3 or one of the shelves 1 of the hexagonal profile.

The tongue and groove can be made from 2 m to 30 m long, the thickness of the main part 6 of the shelves 1 can be in the range from 8 to 30 mm, the thickness of the main parts 7 of the walls 2, 3 is in the range from 8 to 20 mm, the height is not more than 1.5 m, the angle between the shelf 1 and the inclined walls 2, 3 is in the range from 91 to 150°, preferably 110°.

The sheet pile may have a full or partial protective paint coating on the surface, which can be applied either along the entire length or only in the place (section of the length) where the sheet pile, according to the plan, will protrude from the water (ground) and at the water-air junction, since corrosion is less intense under water and in the ground.

The protective coating (anti-corrosion, anti-friction) can be made on the basis of a polymer material or polyurethane polymer paint with sandblasting.

For ease of storage and transportation, the sheet pile may be provided with additional U-shaped cross-section support elements (not shown), which are welded to one or two shelves 1 or walls 2, 3. Each shelf 1 and/or wall 2, 3 may have two or more U-shaped elements, depending on the length and weight of the product. These elements may also be used to grip and carry the sheet pile. The implementation of U-shaped elements on shelves 1 allows fixing slinging cables and facilitates transportation, installation and storage of sheet piles.

Sheet pile walls are formed by alternately driving sheet piles with compatible interlocking elements into the ground. Before driving, the U-shaped supporting elements can be cut off to reduce resistance. Driving can be done by impact driving, vibratory driving and static pressing.

When constructing a sheet pile wall using sheet piles with a hexagonal profile and with locking elements in the form of a collar 5, symmetrically located on inclined walls 2, 3, sheet piles with a trough-shaped profile, equipped with locking elements - cams 11 on the inclined walls, can be used as adjacent sheet piles. First, a sheet pile with a hexagonal profile, equipped with locking elements in the form of angular profiles (collars) 5, is driven into the ground, and then a sheet pile equipped with locking elements in the form of round profiles (cams) 11 on the inclined walls is introduced into engagement with it and driven in, so that when the locking elements are connected, a locking connection is formed.

When constructing a sheet pile wall using sheet piles with a hexagonal profile and with locking elements in the form of a strip part 10, equipped at the free end with a cam 11 and/or a collar 12, adjacent sheet piles with a hexagonal or other profile are selected taking into account the compatibility of the locking elements and the possibility of forming a “cam-collar” locking connection.

The proposed sheet pile design allows for strengthening the upper part and/or base of the sheet pile with a hexagonal profile and thereby further increasing the strength characteristics of the sheet pile during immersion without significantly increasing its weight, which allows for its effective multiple use in the construction of various combined sheet pile walls.

Claims (13)

1. A sheet pile made with a hexagonal profile and provided with locking elements fixed to the outer surface of the hexagonal profile by welding, wherein the hexagonal profile is formed from two sheet piles connected to each other by longitudinal welds, each of which comprises a shelf made of structural steel strips and two inclined walls located at an obtuse angle to the shelf and connected to it by longitudinal welds, characterized in that the main part of the shelf of each sheet pile is made of structural steel containing carbon in the range from 0.1 to 0.2%, silicon in the range from 0.4 to 1.1%, manganese in the range from 0.4 to 1.7%, nickel in the range from 0.1 to 0.8%, chromium in the range from 0.1 to 0.9%, vanadium in the range from 0.1 to 0.15%, copper in the range from 0.2 to 0.6%, with a yield strength in the range from 265 to 400 MPa, wherein one end portion of the flange of each sheet pile is made of a reinforced strip of structural steel, transversely connected by welding to the main portion of the flange of the sheet pile, and the ratio of the length of the end portion of the flange, made of a reinforced strip of structural steel, to the length of the entire sheet pile is in the range from 0.01 to 0.25. 2. The sheet pile according to claim 1, characterized in that the second end portion of the flange of each sheet pile is also made of a reinforced strip of structural steel, transversely connected by welding to the main portion of the corresponding flange of the sheet pile, and the ratio of the length of the second end portion of the flange made of the reinforced strip of structural steel to the length of the entire sheet pile is in the range from 0.01 to 0.25, wherein the main portion of the inclined walls of each sheet pile is also made of structural steel containing carbon in the range from 0.1 to 0.2%, silicon in the range from 0.4 to 1.1%, manganese in the range from 0.4 to 1.7%, nickel in the range from 0.1 to 0.8%, chromium in the range from 0.1 to 0.9%, vanadium in the range from 0.1 to 0.15%, copper in the range from 0.2 to 0.6%, with a yield strength in the range from 265 to 400 MPa, and at least one end part of the inclined walls of each sheet pile is made of a reinforced strip of structural steel, transversely connected by welding to the main part of the inclined walls. 3. A sheet pile according to claim 1 or 2, characterized in that at least one end portion of the flange of each sheet pile is made from a strip of structural steel of greater thickness than in the main portion of the flange. 4. A tongue and groove according to item 3, characterized in that the ratio of the thickness of the end portion of the flange to the thickness of the main portion of the flange is in the range from 1.1 to 2. 5. A sheet pile according to claim 1 or 2, characterized in that at least one end portion of the flange and/or the end portion of the inclined walls of each sheet pile are made from strips of structural steel with a yield strength of at least 420 MPa. 6. A sheet pile according to item 2, characterized in that the ratio of the length of the end portion of the inclined walls of each sheet pile, made from a reinforced strip of structural steel, to the length of the entire sheet pile is in the range from 0.01 to 0.25. 7. A sheet pile according to item 1, characterized in that the angle between the inclined wall and the shelf is from 91° to 150°. 8. A sheet pile according to item 1, characterized in that the locking elements are located on the outer surface on both sides of the hexagonal profile symmetrically relative to the central axis of the sheet pile cross-section. 9. A sheet pile according to claim 1, characterized in that at least one locking element is made in the form of a collar formed by an angular profile welded with the edge of one of the shelves to the wall of the hexagonal profile. 10. A sheet pile according to claim 1, characterized in that at least one locking element is made in the form of a strip part equipped at the free end with a cam formed by a round profile welded to the surface of the strip part, and/or a collar formed by an angular profile welded with the edge of one of the shelves to the surface of the strip part. 11. The sheet pile according to claim 10, characterized in that the end of the strip portion of at least one locking element is connected by welding to the hexagonal profile along the lines of the welded connection between two walls of the hexagonal profile or with a wall or with a shelf of the hexagonal profile. 12. A sheet pile according to item 1 or 2, characterized in that it has a protective paint and varnish coating. 13. A sheet pile according to claim 1 or 2, characterized in that it is provided with U-shaped elements in cross-section, welded to the surface of at least one shelf and/or inclined wall of the hexagonal profile.