KR100432189B1 - Z-shaped sheet file with large cross section - Google Patents

Abstract

The hot rolled Z-shaped sheet pile includes two wings 12 ', 12 "and a web 10 delimited by two substantially parallel faces 18', 18". The web 10 is at an acute angle α <75 ° with the face 16 parallel to the outer surfaces 14 ', 14 "of the wings 12', 12". In order to increase the resistivity of this sheet pile without increasing the thickness or rolling width of the wings 12 ', 12 ", each of the two wings 12', 12" has an outer surface 14 ', 14 "of each wing. And extensions 22 ', 22 "protruding with respect to imaginary surfaces 24', 24" extending the planes 18 ', 18 "of the web, which are positioned laterally. This makes it possible to roll a sheet pile having a resistance coefficient> 4800 cm 3 / m per unit length and a resistance characteristic coefficient of about 20 (cm 3 / m) (kg / m 2).

Description

Thin-walled sheet pile with large cross section

Sheet files of the Z-shape have been known for a long time. This pile has an inclined web connecting two nearly parallel flanges. Each flange mates with the gripping member and engages with the gripping member of the adjacent sheet pile to form a joint in the support wall. In these walls, the Z-shaped sheet piles are almost always arranged such that their flanges are almost parallel and at the same distance from the wall's neutral bending plane. The result obtained by multiplying the cross-sectional coefficient of the wall to this neutral plane by the maximum allowable elastic stress determines the maximum elastic moment that the wall can withstand.

The term "section modulus per unit length" of a sheet pile wall refers to the section modulus of the wall's neutral plane per running meter of the wall. The "specific section modulus" or "performance criterion" of a sheet pile wall is the section modulus per unit length divided by the mass of the wall per square meter of wall. What the sheet pile wall means here is a wall consisting of Z-shaped sheet piles which are connected such that their flanges are almost parallel and at the same distance from the neutral bending surface of the wall.

Applicant currently sells a Z-shaped sheet pile called "AZ36" with a cross-sectional coefficient of 3600 cm 3 per running meter of the wall. This AZ36 sheet pile has a mass of 194 kg / m 2 and a cross-sectional coefficient of 18.6 (cm 3 / m) (kg / m 2). The sheet pile has a LARSSEN type grip and a web made to form an acute angle of about 63 ° with a plane parallel to the flanges. Applicant also sells a Z-shaped sheet pile called "BZ42", which has a cross section modulus of 4200 cm 3 per running meter of the wall but with a mass of 271 kg / m 2, giving a cross section characteristic coefficient of 15.5 (cm 3 / m) (kg / M 2) is not very advantageous. The seat pile has a BELVAL type gripping member and a web made to form an acute angle of about 83.5 ° with a plane parallel to the flanges. Other types of Z-type pile piles currently on sale can have a cross-sectional coefficient of up to 4550 cm 3 per tread meter of wall. However, sheet piles of this type with large cross-sectional coefficients are very heavy in cross section due to their large weight per meter of wall, which leads to a very low cross-sectional characteristic coefficient. The lower the cross-sectional characteristic coefficient, the higher the cost of the wall.

The reason why Z-shaped sheet piles with a cross-sectional coefficient of more than 4550 cm 3 can not be found on the market is as follows.

a) Almost all there is a limit to the maximum thickness of the flanges. This is because in the rolling of the gripping member, in particular the lassen gripping member, it is necessary to fold the flange during the final stage of the rolling mill. This folding becomes difficult when the thickness of the flange is too thick. Therefore, when the sheet pile is provided with a lassen-type holding member, there is no industrial method for rolling a flange of more than 20 mm in thickness.

b) In addition, there is a limitation on the maximum distance (height of the section) between the maximum width of the flange and the outer surface of the flange. This is because for a given angle of inclination of the web the width of the flange and the height of the cross section determine the extent of improvement of the sheet pile and consequently the width of the roll stand roller. The width of these rollers is determined by the width of the roll stand of the sheet file rolling train. If it is necessary to roll sheet piles with large cross-sectional coefficients in current rolling trains, the degree of improvement of these sheet piles between the axes of the gripping members should be less than the value determined by the width of the roll stand of the sheet pile rolling train.

c) The reduction in rolling width can be achieved by increasing the acute angle (inclined angle of the web) of the web with a plane parallel to the flanges. However, the closer the angle of inclination of the web to 90 °, the greater the resistance generated when driving the sheet pile. Due to the causes associated with the use of a sheet pile, the recommended angle of inclination of the web is less than 75 °.

Using an optimization program and a computer, the above mentioned parameters are optimized for the AZ type sheet pile to obtain a sheet pile having a maximum cross-sectional coefficient of 4400 cm 3 per running meter of the wall. This AZ sheet pile has a mass of 229 kg / m 2 and a cross-sectional characteristic coefficient of 19.21 (cm 3 / m) (kg / m 2) for a 15 mm thick web. Therefore, if the above constraint is required, the cross-sectional coefficient of 4400 cm 3 is likely to be the limit for the Z-shaped sheet pile. Of course, it is still possible to increase the thickness of the web, but even with a slight increase in the section modulus, the increase in thickness results in a significant decrease in the section modulus of the sheet pile.

The problem to be solved by the present invention is to find a way to further increase the cross-sectional coefficient of the hot rolled Z-shaped sheet pile without reducing the cross-sectional characteristic coefficient of the sheet pile and increasing the width of the roll stand.

This problem is solved by the Z-shaped sheet file according to claim 1.

In connection with the technique of the present invention, the contents corresponding to the protrusions of the flanges of the seat piles and the webs are already disclosed in US-A-1,831,427 and FR-A-686816, but the substantial contents thereof are completely described in the present invention. Different. Document US-A-1,831,427 discloses a special Z-shaped sheet pile which can produce a continuous flat sheet pile wall in cooperation with an intermediate flat sheet. The special sheet file disclosed herein is most likely a sheet file made of cast iron. The web is at an angle close to 90 ° with a plane parallel to the outer surface of the flange. The engagement between the web and the flange has ribs, ridges, shoulders, or protrusions that are integral to the seat pile or attached to the seat pile by any means. The only purpose for these ribs, ridges, shoulders or protrusions to exist is to engage the complementary recesses formed in the mediation sheet above. In this way, they can be inserted and held in the proper position of the interventional sheet between two Z-shaped sheet piles to form a continuous flat sheet pile wall. A low height U-shaped sheet pile is disclosed in FR-A-686816, which has a reinforcing member at the position of the connection between the web and the flange. In an assembly consisting of two such seat piles, the reinforcing member, located just before the opening of the clutch in the first seat pile, to form a shape that can cooperate with the outer part of the clutch in the second seat pile. It cooperates with the inner part of the clutch of the first seat pile.

The present invention relates to a Z-shaped sheet pile having a large section modulus.

1 is a cross-sectional view of a Z-shaped sheet pile according to the present invention,

2 is an enlarged view of the flange / web connection of the seat pile of FIG.

The hot rolled Z-shaped sheet pile according to the present invention includes all similar hot rolled Z-shaped sheet piles, two flanges having almost parallel outer surfaces, and inclined webs connecting the two flanges. The web is formed to have an acute angle of no more than 75 ° with a plane parallel to the outer surface of the flange and is defined by two nearly parallel surfaces between the connections with the flange. Hot rolled sheet piles according to the present invention are conventionally hot rolled in that each of the two flanges has an extension projecting to an imaginary surface extending the plane of the web, which is located on the same side as the outer surface of each flange. It is different from the sheet file.

The hot rolled sheet pile according to the present invention has the advantage of being formed with the remaining amount of material, and thus it is recognized that the small increase in mass per square meter of the wall leads to the improvement of the cross-sectional coefficient and the improvement of the cross-sectional characteristic coefficient. . In particular, it is recognized that such advances in the section modulus can be achieved without increasing the width of the roll stand and the thickness of the flange and can advantageously increase the width of the flange. The proposed solution also reinforces the outer corners of the flange / web connection, thereby reducing damage to these parts when using the sheet pile. This reinforcement also resists accelerated corrosion at low levels because, unlike U-sheet piles, Z-sheet piles are more resistant than corrosion to web / flange connections. In addition, the flange has a larger support surface (= outer surface of the flange) relative to the walings or anchor plate, and the transfer of anchoring force from the flange to the web and vice versa is improved. There is a point.

In particular, a sheet file according to the present invention having the following characteristics can be obtained.

Thickness of the flange: about 19-20 mm

Width of Flange: ≥200mm

Sheet pile height: ≤500mm

Section modulus per unit length of wall: ≥4800 cm 3 / m

Sectional characteristic factor: about 20 (cm 3 / m) (㎏ / ㎡)

Referring to FIG. 1, the Z-shaped sheet pile includes all similar Z-shaped sheet piles, two flanges 12 ′, 12 ″ with nearly parallel outer surfaces 14 ′, 14 ″ and these two flanges 12. ', 12 ") and a sloping web 10 connecting. the web 10 has flanges (12', 12") outer surface (14 ', 14 ") parallel to the plane 16 and the α to This web is thinner than the flanges 12 ', 12 "and is bounded by two nearly parallel faces 18', 18" between the connections with the flanges 12 ', 12 ". Is determined.

Each of these flanges 12 ', 12 "fits into the gripping members 20', 20". More specifically, these members are racene and can be joined at the sheet pile wall with the gripping members of adjacent sheet piles to form a racene joint.

The dimensions of this sheet file are optimized using an optimization program and a computer to obtain large cross-sectional coefficients under various constraints mentioned in the prior art section of this specification.

This optimization is obtained with the following dimensions.

Height of the sheet pile (distance between the outer surfaces of the flanges): h = 482 mm

Width of each flange 12 ', 12 ": a ≒ 208 mm

Thickness of web 10: t ₁ = 15 mm

Thickness of each flange 12 ', 12 ": t ₂ = 19 mm

Tilt angle of web 10: α = 71 °

The above-described optimization results in a cross-sectional coefficient of 4400 cm 3 per unit length of the wall, in which case these sheet piles are almost parallel to the outer surfaces 14 ', 14 "of their flanges 12', 12". And are connected at equal distances from the wall's neutral bend. The cross-sectional characteristic coefficient of this sheet pile wall is slightly smaller than 20 (cm 3 / m) (kg / m 2).

The aim here is to further increase the section modulus of the optimized sheet pile.

This purpose is achieved by an extension (protruding against an imaginary surface 24 ', 24 "extending the planes 18', 18" of the web located on the same side as the outer surfaces 14 ', 14 "of each flange). 22 ' and 22 " to each of the two flanges 12 ', 12 ". This connecting surface 25 abuts the outer surface 14 'of the flange 12' and is connected along its tangent to the plane 18 'of the web 10.

With reference to FIG. 2, attention should be paid to the portion 26 ′ having a local extra thickness in the web 10 to prevent the formation of concave corners between the flange extension 22 ′ and the web 10. By means of which the web 10 is connected to the flange extension 22 '. This extra-thickness portion 26 'in web 10 slightly reduces the cross-sectional characteristic coefficient of the sheet pile, but facilitates rolling and prevents deformation of the flange extension 22' when nailing the pile. Let's do it. In addition, better conveyance of the anchor force is obtained from the flanges 12 ', 12 "to the web 10 and vice versa.

Also shown in FIG. 2 is a first plane 30 in which the extent of the flange extension 22 ′ extends the plane 14 ′ of the flange 12 ′, a second plane substantially perpendicular to the first plane 30 ( 34 and its first plane 30 and the convex cylindrical connecting surface 32 connecting the second plane 34 is shown. The extra-thickness portion 26 'in the web 10 then defines a concave cylindrical connection surface 36 connecting the plane 18' of the web and the flange extension 22 '. This is the configuration of the flange extensions 22 ', 22 "optimized in terms of rolling.

In the example of FIG. 1, the convex cylindrical connecting surface 32 has a radius of 15 mm and the concave cylindrical connecting surface 36 has a radius of 125 mm. The section coefficient per unit length of the optimized sheet pile with flange extensions 22 ', 22 "is 4800 cm3 / m, which is about 9 compared to the optimized sheet pile without flange extensions 22', 22". Means an increase in%. The cross-sectional characteristic coefficient of the optimized sheet pile with flange extensions 22 ', 22 "is about 20 (cm 3 / m) (kg / m 2).

Rolling of the flange extensions 22 ', 22 "does not cause a major problem and does not in particular need to increase the width of the roll stand of the rolling train, indicating that the present invention is suitable for sheet piles of large cross section coefficients.

Of course, the present invention is not limited to the above-described sheet pile, but the sheet pile having a Z-shaped sheet pile having a different dimension of cross-sectional coefficient per unit length of less than or equal to 4800 cm 3 / m and a non-lacen holding member Can be applied to

Claims (9)

Two flanges 12 ', 12 "having substantially parallel outer surfaces 14', 14", Connecting the two flanges 12 ', 12 "to form an acute angle α ≤ 75 ° with a plane 16 parallel to the outer surfaces 14', 14" of the flanges 12 ', 12 ", and Hot rolled Z-shaped sheet pile comprising a sloped web 10 whose range is defined by two parallel faces 18 ', 18 "between the connections having the flanges 12', 12". Z-shaped sheet pile, Each of the two flanges 12 ', 12 "is an imaginary surface 24' extending the planes 18 ', 18" of the web, which are located on the same side as the outer surfaces 14', 14 "of each flange. Hot rolled Z-shaped sheet pile, characterized in that it has extensions 22 ', 22 &quot; protruding with respect to 24 "). The method of claim 1, The web 10 has an extra thickness 26 'of the web 10 to prevent the formation of concave corners between the respective flange extensions 22', 22 "and the web 10. Hot rolled Z-shaped sheet pile, characterized in that it is connected to each flange extension 22 ', 22 &quot; The method of claim 2, The flange extensions 22 ', 22 "have a first plane 30 in a range extending the planes 14', 14" of each flange, a second substantially perpendicular to the first plane 30. Hot rolled Z-shaped sheet file, characterized by a plane (34) and a convex cylindrical connection surface (32) connecting said first plane (30) and said second plane (34). The method of claim 3, wherein And the second plane (34) is connected to each plane (18 ', 18 ") of the web by a concave cylindrical connection surface (36). The method according to any one of claims 1 to 4, The sheet file, a) the section modulus ≥ 4800 cm 3 / m per unit length of the wall, b) specific section modulus of about 20 (cm 3 / m) (kg / m 2) Hot rolled Z-shaped sheet pile, characterized in that determined by the parameter of. The method according to any one of claims 1 to 5, The sheet file, a) the thickness of the flanges of about 19-20 mm, b) width ≥ 200 mm of the flanges, c) the height of the sheet pile ≤500 mm Hot rolled Z-shaped sheet pile, characterized in that determined by the parameter of. The method according to any one of claims 1 to 6, And the web forms an acute angle α close to 71 ° with a plane 16 parallel to the outer surfaces 14 'and 14 "of said flange. The method according to any one of claims 1 to 7, Wherein each flange is fitted to a gripping member. The method according to any one of claims 1 to 9, Wherein each flange is fitted to a LARSSEN type gripping member.