CZ338298A3 - Z-shaped sheet pile with big cross sectional modulus - Google Patents

Abstract

A hot-rolled Z-shaped sheet-pile is comprised of two wings (12', 12'') and a web (10) delimited by two substantially planar faces (18', 18''). The web (10) defines a sharp angle alpha < 75 DEG with a plane (16) parallel to the external faces (14', 14'') of the wings (12', 12''). In order to increase the resistance modulus of said sheet-pile without having to increase the thickness of the wings (12', 12'') or the rolling width, each of the two wings (12', 12'') has an extension (22', 22'') projecting with respect to the imaginary plane (24', 24'') which prolongs the planar face (18', 18'') of the web situated on the same side as the external face (14', 14'') of the respective wing. Thereby, it is possible to roll sheet-piles having a resistance modulus per wall length unit > 4800 cm<3>/m and a specific resistance modulus of about 20 (cm<3>/m)/(kg/m<2>).

Description

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The hot-rolled Z sheet consists of two flanges (12, 12) having substantially parallel outer faces (14, 14), and an inclined web (10) connecting the two flanges (12, 12). The web forms an acute angle .alpha. With a plane (16) parallel to the outer faces (14, 14) of the flanges (12, 12). and between the joints to the flanges (12, 12) is defined by two substantially parallel planar faces (18, 18). Each of the two flanges (12, 12) has a projection (22, 22) that extends beyond the imaginary plane (24, 24) which extends the planar face (18, 18) of the web that is on the same side as the outer face. 14, 14 / respective flanges.

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Z sheet sheet with large cross-sectional module

Technical field

The invention relates to a Z-shaped sheet pile with a large cross-sectional module.

BACKGROUND OF THE INVENTION

Z-shaped sheet piles have been known for a long time. They have a sloping web that connects two substantially parallel flanges. Each flange includes a retaining element by which the sheet pile engages with the adjacent sheet pile retaining member to form a sheet wall joint. In such a wall, most of the Z-shaped sheet piles are arranged such that their flanges are substantially parallel and equidistant from the neutral bending plane of the wall. The product of the bending cross-sectional module with respect to this neutral plane and the maximum permissible elastic stress determines the maximum moment of elastic stress with which the wall can be loaded.

The quantity called the cross-sectional module per unit length of the pile wall is the cross-sectional module of the wall relative to the neutral plane per linear meter of wall. A quantity that is called a specific cross-sectional module or performance module

The pile wall criterion is given by the cross-sectional module per unit of length to the weight of one square meter of wall. In the context of the present invention, a sheet wall is to be understood to be a wall which consists of sheet piles joined together so that their flanges are substantially parallel and equidistant from the neutral bending plane of the wall.

ProfilARBED SA (Luxembourgh) is currently offering a Z-shaped sheet piling under the name AZ36, whose cross-sectional module is 3600 cm ³ per linear meter of wall. The sheet pile AZ36 has a density of 194 kg / m ² and the specific cross-sectional modulus is therefore 18.6 (cm ³ / m) (kg / m ² ). ProfilARBED SA (Luxembourgh) also offers another Z-shaped sheet pillow under the name BZ42, which has a cross-sectional modulus of 4200 cm ³ per linear meter of wall but a specific gravity of 271 kg / m ² and hence less favorable specific.

Τ, ΰ- · 3 'cross-sectional module 15.5 (cm ³ / m) (kg / m ² ). This sheet pile has retaining elements of the BELVAL type and its web forms an acute angle of approximately 83.5 ° with the plane parallel to the flanges. Other Z-shaped sheet piles with cross-sectional modules up to 4550 cm ³ per square meter of wall are also available on the market. However, these types of Z-shaped sheet piles with large cross-sectional modules are made of solid profiles with a large weight per square meter of wall and therefore with a relatively small cross-sectional modulus. The lower the cross-sectional modulus, the higher the wall cost.

The main reasons why Z 10 sheet piles with cross-sectional modules larger than 4550 cm ³ per square meter of wall are not commercially available are:

(a) most often a limitation on the maximum thickness of the flanges. The rolling of the gripping elements, especially the gripping elements of the Larssen type, requires that the flanges be folded only during the last pass through the rolling stand. And folding too thick flanges is difficult. Thus, at present there is no industrial way to roll flanges with Larssen grips that are thicker than 20 mm.

b) limiting the maximum width of the flanges and the maximum distance between the outer faces of the flanges (profile height). Given the angle of inclination of the web, the width of the flanges and the height of the profile determine the development of the sheet piles and consequently the width of the roll mill rolls. The width of the rolls is limited by the width of the rolling mill of the sheet rolling mill. If it is desired to roll sheet piles with a high cross-sectional modulus on existing rolling mills, the expansion of these sheet piles between the gripper axes must be less than a predetermined value of the width of the rolling mill mill rolls.

c) rolling width savings can be achieved by increasing the acute angle between the web and the plane parallel to the flanges (web angle). However, the closer this angle approaches 90 °, the greater the pile driving resistance. Due,

With respect to the actual use of sheet piles, it is recommended that the web angle be less than 75 °.

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The above parameters of sheet piles were optimized using the optimization program and computer. The optimization of the sheet pile with flange thickness of 15 mm, sectional modulus of 4400 cm ³ per meter of the wall, with a density of 229 kg / m ² and therefore specific sectional modulus of 19.21 (cm ³ / m) (kg / m ^2).

Thus, a 4400 cm ³ cross-sectional module appears to be a limit value for Z-shaped sheet piles that meet the above limitations. Of course, it is possible to further increase the web thickness, but such a step slightly increases the cross-sectional modulus on the one hand, but at the same time it causes a noticeable reduction in the specific cross-sectional modulus of the sheet piles.

The present invention provides a solution that makes it possible to further increase the cross-sectional modulus of Z-shaped sheet piles without reducing the specific cross-sectional modulus of the sheet piles, while maintaining the existing width of the rolling stands.

This solution is a Z-shaped sheet pile according to the first claim.

It should be noted that the protruding projections at 20 points at which the flanges and the sheet pillar web are joined have already been described in US-A-1,831,427 and FR-A-686816, but in a completely different context from the invention. US-A-1,831,427 discloses special Z-shaped sheet piles which, together with flat intermediate panels, make it possible to form a sheet wall with a continuous planar surface. Special sheet piles according to this document are more than probably cast from steel. Their web forms an angle close to 90 ° with the plane parallel to the outer surfaces of the flanges. In the joints between the web and the flanges, they have ribs, ridges, shoulders, or protrusions that are either integral with the sheet pile or are fastened to it by some means. The only purpose of these ribs, ridges, shoulders or protrusions is to fit into the recesses

0 complementary shapes in intermediate panels. In this way, it is possible to form a sheet wall with a continuous planar surface by inserting between the two Z-shaped sheet piles and securing the intermediate panels. Small sheet pile

Height is known from document FR-A-686816. Such sheet piles have a thickened portion at the flange contact with the web. In an assembly of two such sheet piles, said thickened portion, which is located immediately in front of the connector opening of the first sheet pile, together with the inner portion of the sheet pile, forms a formation capable of cooperating with the outer portion of the connector on the second sheet pile.

SUMMARY OF THE INVENTION

The hot-rolled Z-shaped sheet piles according to the invention consists, like all hot-rolled Z-piles, of two flanges having substantially parallel outer faces and an inclined web joining the two flanges. The web makes an acute angle less than or equal to 75 ° with a plane parallel to the outer faces of the flanges and is defined by substantially planar faces between the flange connections. The hot-rolled Z-shaped sheet piles according to the invention differ from conventional hot-rolled Z-sheet piles mainly in that the two flanges have protrusions that extend beyond the imaginary plane which extends to the planar face of the web which is on the same side as flange.

Advantageously, the production of the hot-rolled sheet pile according to the invention requires little more material, which results in a slight increase

However, the improvement of the cross-sectional modulus and consequently the specific cross-sectional modulus is significant. Further, an increase in the cross-sectional module is achieved without increasing the width of the mill stand, without increasing the thickness of the flanges, and in addition it is possible to increase the useful width of the flanges. The proposed solution also leads to the reinforcement of the corners at which the flanges are joined to the web, thereby reducing the risk of damage to these critical points when using sheet piles. This reinforcement is also advantageous in terms of improved resistance to accelerated corrosion at low water levels, since the Z-shaped sheet piles, in contrast to the U-sheet piles, are susceptible to corrosion in flange / web joints. The last advantage is that the flanges have larger bearing surfaces (= outer faces of the flanges) for expansion and anchor plates and transfer of the anchoring forces from the flanges to the web and vice versa is therefore easier.

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It is particularly advantageous that according to the invention it is possible to obtain sheet piles having the following parameters:

flange thickness 19 to 20 mm; flange width> 200 mm;

sheet pile height <500 mm;

cross-sectional module per running meter of wall> 4800 cm ³ ; cross-sectional modulus of approximately 20 (cm ³ / m) (kg / m ² ).

Overview of pictures

A preferred embodiment of a sheet pile according to the invention will be described below with reference to the accompanying drawings, in which:

Fig. 1 is a cross-sectional view of a sheet pile;

Fig. 2 shows a detail of the flange / web connection of the sheet piles according to Fig. 1.

DETAILED DESCRIPTION OF THE INVENTION

The Z-shaped sheet pile of FIG. 1 consists, like all hot-rolled Z-sheets, of two flanges 12 '

The parallel outer faces 14 ', 14, and the inclined web 10, which both flanges 12'. 12 connects. The web 10 forms a plane 16 which is parallel to the outer faces 14 ', 14 of the flanges 12'. The flange 10 is weaker than the flange 12 '. 12 and between the connections to the flanges 12 '. 12 is defined by two substantially planar and parallel faces 18 ', 18.

Both flanges 12 ', 12 are provided with a catch element 20'. 20. More precisely, they are fitted with Larssen-type retaining elements which, by engagement with the retaining elements of adjacent sheet piles, form Larssen-type joints in the sheet wall.

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The dimensions of the sheet pile described have been optimized by means of an optimization program and a computer to obtain a large cross-sectional module while meeting the various above-mentioned limitations.

Optimization has led to the following dimensions:

pile profile height (distance between outer flange faces): h = 482 mm width of each flange 12. 12: a «208 mm web thickness 10: h = 15 mm o thickness of each flange 12, 12: t ₂ = 19 mm angle web inclination 10: a = 71 °

By optimizing the above dimensions, a cross-sectional modulus of 4400 cm ³ per unit length of wall has been obtained such that the sheet piles 14 ', 14 of the flanges 12, 12 are substantially parallel to and equidistant from the neutral bending. planes of the wall. The specific cross-sectional modulus of such sheet piles is just below 20 (cm ³ / m) (kg / m ² ).

The aim was to further improve the cross-sectional modulus of such an optimized sheet pile.

This object is achieved by the addition of a projection 22 ', 22 which extends beyond the imaginary plane 24', 24 which is an extension of the planar face 18 ', 18 of the web which is on the same side as the outer face 14', 14 of the respective flange. The transition surface 25, which would terminate the flange 12 'in a conventional Z-shaped sheet pile, is indicated in dashed lines in FIG. This transition surface 25 would tangentially adjoin the outer face 14} of the flange 12 'and the face 18} of the web 10.

As can be seen in FIG. 2, the web 10 adjoins the projection 22 'of the flange with a locally increased thickness 26' of the web 10 such that between the projection 22 and the web 10

0 no concave corner. The increased thickness 26 'of the web 10 slightly reduces the specific cross-sectional modulus of the sheet pile, on the other hand facilitates rolling and prevents

deformation of the flange protrusion 22 'during punching. In addition, a better transmission of the anchoring forces between the flanges 12 ', 12 and the web 10 is achieved.

It is further evident from FIG. 2 that the protrusion 22 'is delimited by a first planar surface 5 that is an extension of the planar face 14' of the flange 12 ', a second planar surface 34 that is substantially perpendicular to the first planar surface.

30 and a convex cylindrical surface 32 that connects the first planar surface 30 with the second planar surface 34. The increased thickness 26 'of the web 10 thus defines a concave transition surface 36 that connects the body 18' of the web 10 with the projection 22 '.

which is optimized for rolling.

In the example of FIG. 1, the convex cylindrical transition surface 32 has a radius of 15 mm and the concave cylindrical transition surface 36 has a radius of 125 mm. The cross-sectional module per unit length of the optimized sheet pile with projections 22 ', 22 is 4800 cm ³ / m, which represents an increase of about 9% over the optimized sheet pile without projections 22', 22. The cross-sectional modulus of the optimized sheet pile with projections 22 ', 22 is about 20 (cm ³ / m) (kg / m ² ).

Rolling of the projections 22 ', 22 does not cause any major problems.

It does not require an increase in the width of the rolling mill stands of the rolling mill, which makes the invention particularly attractive for sheet piles of large cross sections.

It remains to be noted that the invention is of course not limited to the above-described sheet pile design, but is also applicable to Z sheet piling sheets having a cross-sectional module per unit length less than or greater than 4800 cm ³ / m and substantially different dimensions. as well as sheet piles with non-Larssen grips.

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PATENT CLAIMS

Claims (9)

A hot-rolled Z sheet comprising two flanges (12 ', 12) having substantially parallel outer faces (14', 14) and an inclined web (10); 5 which connects the two flanges (12 ', 12) by clamping with a plane (16) parallel to the outer faces (14', 14) of the flanges (12 ', 12), an acute angle α <75 °, between the joints to the flanges (12 ', 12) defined by two substantially parallel planar faces (18', 18), characterized in that each of the two flanges (12 ', 12) has a projection (22', 22) that extends beyond the imaginary plane (24 ', 24) that 10, this extends the planar face (18 ', 18) of the web that is located on the same side as the outer face (14', 14) of the respective flange. Sheet pile according to claim 1, characterized in that the web (10) adjoins the two flange projections (22 ', 22) by means of an increased thickness (26', 26) 15 of a web (10) for preventing the formation of a concave corner between the respective projection (22 ', 22) of the flange and the web (10). Sheet pile according to claim 2, characterized in that the projection (22 ', 22) of the flange is bounded by a first planar surface (30) which extends the planar 20 of the respective flange face (14 ', 14), a second planar surface (34) that is substantially perpendicular to the first planar surface (30), and a convex cylindrical transition surface (32) that connects the first planar surface (30) with a second planar surface (34). 25 Sheet pile according to claim 3, characterized in that the second planar surface (34) is connected to the respective planar web face (18 ', 18) by a concave cylindrical transition surface (36). Sheet pile according to one of Claims 1 to 4, characterized in that it has 30 cross-sectional module per running wall meter> 4800 cm ³ , specific cross-sectional module about 20 (cm ³ / m) (kg / m ² ). ·· · · Sheet pile according to one of Claims 1 to 5, characterized in that it has a flange thickness of about 19 to 20 mm, a flange width of> 200 mm and a sheet pile height of <500 mm. Sheet pile according to one of Claims 1 to 6, characterized in that the web forms an acute angle α which is substantially 71 ° with the plane (16) parallel to the outer faces (14 ', 14) of the flanges. 10 Sheet pile according to one of Claims 1 to 7, characterized in that both flanges are fitted with a retaining element. Sheet pile according to one of Claims 1 to 8, characterized in that both flanges are fitted with a gripping element of the Larssen type.