EP3049576A1

EP3049576A1 - Offshore platform with clamping wedges

Info

Publication number: EP3049576A1
Application number: EP14766742.2A
Authority: EP
Inventors: Klaas OLTMANN
Original assignee: Overdick GmbH and Co KG
Current assignee: Tractebel Overdick GmbH
Priority date: 2013-09-25
Filing date: 2014-09-18
Publication date: 2016-08-03
Also published as: DE102013110599B4; SG11201602086XA; DE102013110599A1; MY178700A; CN105683448A; CN105683448B; WO2015044028A1

Abstract

The invention relates to an offshore device with a structure (2) with at least one component guide (21) with a seabed-side opening (6a) and with at least one elongate component (3) with a longitudinal direction (L) and with an outer wall which is introduced through the opening (6a) into the component guide (21) with a clearance, and with a clearance-reducing clamping device (8), wherein the clamping device (8) has clamping elements (10) and the clamping elements (10) are connected to in each case an adjusting device (11) by means of which the clamping elements (10) are movable back and forth along the longitudinal direction (L) of the elongate component (3) and can be fixed in a clamping position.

Description

Offshore platform with clamping wedges

The invention relates to an offshore device having a structural body and at least one elongated component and a method for clamping a structural body to at least one elongate component.

Offshore facilities are in the form of oil platforms, substations or the like. Of course, well-known in the art. Known offshore facilities have a platform on which structures such as derricks o. Ä. can be mounted or mounted.

The offshore facilities have one or more, preferably three or four support legs. Self-installing platforms and mobile offshore platforms continue to have support legs along which the platform can travel. At the installation location, for example, the support legs can be lowered by means of a jacking system, and the platform lifted and brought to operating height by the same jacking system from the sea on which it floats.

In DE 31 22 401 C2 discloses a fastening device for a pile-shaped element is disclosed in which two racks are arranged along a support in the longitudinal direction and rack parts are moved by contracting two opposing bevelled sides horizontally by means of screw spindles and pressed with their teeth in the racks and thus attach a platform to the support.

In this case, openings or guides are provided in the platform, along which the support legs are moved relative to the platform. Necessarily, there is some play between the openings in the platform and the outer wall of the support leg. At operating height, the load of the platform acting along the leg axis must be transferred by fasteners into the support legs. There is the problem that a clearance between the outer wall of the support leg and the opening is present, which allows a relative movement of the support leg relative to the platform despite an axial attachment. Such relative movements may be disadvantageous because shaft loads acting on the support leg are not transferred directly to the platform, but may, for example, lead to impacts of the support leg against the guide and thus to damage thereof. It is therefore an object of the invention to provide an aforementioned offshore device, which avoids the disadvantages mentioned above, and a method for To provide clamping of a building to at least one elongate member to provide the above-mentioned disadvantages.

The object is achieved in its first aspect by an offshore device having the features of claim 1.

The object is achieved by an offshore device having a structure which may be, for example, a platform, but may well assume other configurations, with at least one component guide with a sea bottom side opening and at least one elongated member, for example, a support leg, but may also be a riser or a caisson having an outer wall and which can be introduced or introduced with a game through the seabed-side opening in the component guide. The game is at least reduced by a clamping device according to the invention. By the clamping device acting on the elongated member transverse to a longitudinal direction of the component loads can be transferred directly into the building. For example, shaft loads acting on a support leg, which can have considerable orders of magnitude, can be transferred from the support leg into the structure, in particular into the platform structure. According to the invention, the clamping elements are each connected to an adjusting device with which the clamping elements can be moved back and forth along a longitudinal direction of the elongated component and can be fixed in a clamping position. Thus, the clamping elements are conveniently vertically movable in a deployed offshore platform. In a particularly favorable embodiment of the invention, the clamping device on platform inside arranged contact surfaces, which are obliquely set to the outer wall, and wedge-shaped clamping elements, which are arranged or arranged between the outer wall and the contact surfaces. This structural design of the clamping device is particularly stable and in known structures, in particular platforms, even by conversion additionally installable.

Conveniently, the contact surfaces are provided along a circumference of the component guide and particularly preferably along the circumference of the opening. The opening and / or the component guide can be circular in a horizontal cross section, in order then to receive circular support legs, in particular in cross section. But it can also square, especially triangular, square or opening cross-sections with each be provided higher number of corners and preferably corresponding support leg cross-sections.

Conveniently, the pressing surfaces extend in the direction of the outer wall to the seabed sloping down. The opening is preferably circulated along its circumference by inclined contact pressure surfaces which each have one, preferably all, the same angle with respect to the outer wall of the elongate component, preferably the support leg. The space between the contact surface and the outer wall is formed wedge-shaped tapering towards the seabed. In this space, a wedge-shaped clamping element is arranged in each case to achieve a clamping effect and to reduce the game by being pressed from Meeresbodenabseitig the contact surface in the direction of the seabed on the contact surface and the outer wall and is pressed.

The opening may but need not be recessed directly in the outer wall. The pressing surfaces can be arranged directly on the outer wall, preferably on the inside of the platform along the opening. However, the contact surfaces can also be arranged further inside the platform along the opening of an inner deck, for example of the double deck. The clamping elements are advantageously vertically movable in an offshore platform and in particular by a vertical movement between the contact surface and outer wall hineindrückbar so that a vertical clamping action can be generated by a horizontal adjusting movement. The clamping elements preferably have a coating on a side facing the outer surface. In particular, the lining has the function of counteracting forces and homogenizing a force distribution and thus improving the transmission of horizontal forces between the support legs and the platform. This may be an elastomer. However, it is also conceivable that the outer surfaces have teeth or rows of teeth that have a friction-enhancing effect.

The clamping elements may have fastening means on their side facing the interior of the structure, such as one, two or any higher number of eyelets for fastening hydraulically operated cylinders which drive a reciprocating movement of the clamping elements along the longitudinal direction and which preferably the clamping elements set in their clamping position. A setting can also be done or supported by further Festsetzmittel. The seizing agents may exert their effect in addition to or instead of the cylinders. The fixing means may be clamping screws, bolts, tie rods, etc., which fix the clamping element in the clamping position.

In a further development of the invention, guides for the clamping elements are provided laterally on the pressing surfaces, which prevent a displacement of the clamping element transversely to the adjusting movement. The lateral guides may be part of a pocket for each of the clamping elements, which is preferably waterproof.

Conveniently, the clamping elements are arranged in watertight pockets. Preferably, the clamping elements are interchangeable. For this purpose, for example, in the double deck for each clamping element an inspection opening can be provided, through which a simple revision of the clamping elements from the building out is possible.

The raising or lowering of the platform along the at least one elongate structural body, in particular in the form of at least one support leg, can take place by means of a known jacking system. In its second aspect, the object is achieved by a method having the features of claim 9.

The method is particularly suitable for implementation with one of the abovementioned offshore facilities. In this case, an elongate member is introduced with an outer wall through a seabed-side opening in at least one guide of a building, and a clearance between the elongated member and the guide is reduced by a clamping device. With this method according to the invention, it is possible initially to arrange a structure on an elongated component, in particular on a platform of an offshore device on at least one support leg in a conventional manner and after the platform is preferably arranged in the operating position on the support leg, by a clamping device , which reduces a game between the support leg and the guide by clamping elements of the clamping device are moved in the longitudinal direction of the elongated member and the clamping elements clamp the body to the elongate member in a clamping position.

Preferably, the clamping elements in each case from meeresbodenabseitig a contact surface of the building in the direction of the seabed on the contact surface and a Outside wall of the elongated member pressed. Conveniently, the clamping elements take on no vertical loads but, only horizontal loads and thereby reduce the game. Preferably, the clamping element are individually formed wedge-shaped with pointing to the seabed Keiispitze.

Conveniently, this clamping elements are pressed simultaneously on contact surfaces and the outer wall of the support leg.

The invention will be described with reference to an embodiment in eight figures. Showing:

1 is a perspective view, partially in section of an inventive offshore platform with clamping device and support leg,

2 is a perspective sea bottom side view of the offshore platform in Fig. 1,

3 is a perspective view, partially in section of arranged around the support leg clamping wedges,

4 is a perspective view obliquely from the left in Fig. 3,

5 shows a clamping position of the clamping wedges with associated adjusting device about the support leg,

6 shows an exemption of a clamping wedge,

7 a clamping wedge in a side view,

Fig. 8 shows the clamping wedge in Fig. 7 in a perspective view.

1 shows a section of an offshore device 1 according to the invention with a section of an offshore platform 2 and with a support leg 3. The offshore device 1 has a plurality of support legs 3, but only one of the support legs 3 is shown. The support legs 3 stand on a (not shown) seabed, and the offshore Platform 2 is located at a working altitude above sea level. The offshore platform 2 has a double deck 4 with a double deck opening 4a and a sea-facing outer skin 6 with an outer skin opening 6a in its sea-floor-side area in FIG.

Through the outer skin opening 6a and the double deck opening 4a, a portion of the support leg 3 is vertically introduced. The portion of the support leg 3, preferably the entire support leg 3 has along its longitudinal extent in the longitudinal direction L a same cross-section. The support leg 3 is attached to the platform 2 by fastening means, not shown, which in particular accommodate the vertical forces. The outer skin opening 6a has a substantially circular opening cross section with a diameter which is greater than a diameter of a cross section of the support leg 3. The support leg 3 thus has a play in the offshore platform 2. Due to the size difference of the cross sections, the support leg 3 in the double deck 4 and the outer skin 6 has a game. On the support leg 3 act at times and in particular when swell significant shaft loads that can lead to a horizontal relative movement of the support leg 3 relative to the platform 2. To avoid the relative movement between the support leg 3 and platform 2 by introducing horizontal shaft loads from the support leg 3 in the platform 2, a clamping device 8 according to the invention is provided. The clamping device 8 comprises a plurality of clamping wedges 10, which are each movable over two hydraulically driven cylinders 11 in the longitudinal direction L of the support leg 3 back and forth and fixed by the cylinder 11 in its respective clamping position between the outer wall of the support leg 3 and an associated contact surface 13 Each one end of the cylinder 11 is pivotally connected to the fastening means 12, in each case another end of the cylinder 11 is pivotally connected to the clamping wedge 10 associated with the cylinder. The platform 2 has between the double deck 4 and the sea-side outer skin 6, the inclined contact surfaces 13 which rotate the double deck opening 4a and the outer skin opening 6a. The pressing surfaces 13 are formed here flat, with other shapes are conceivable and inclined relative to the outer wall of the support leg 3 and in relation to the longitudinal direction L.

A relative arrangement of the outer surface of the support leg 3 and pressing surface 13 is determined so that in each case a clamping wedge 10 in the intermediate space formed between contact surface 13 and outer wall of the support leg 3 is positively and non-positively insertable. In particular, horizontal movements of the support leg 3 are thus transferred directly by the clamping wedges 10 in the platform 2. Fig. 2 shows a view of the platform 2 in Fig. 1 from below, ie from the direction of the sea level. The outer skin opening 6a is substantially circular in shape and reinforced by a ring plate 20 surrounding the outer skin opening 6a on the sea side. The platform 2 has, for each of its support legs 3, a guide in which the associated support leg 3 is guided and perpendicular to the platform 2 or at least a portion of the platform

2 runs. The cross-section of the outer skin opening 6a is greater than the cross section of the support leg 3 formed in a constant circular shape over its entire longitudinal direction L. The clamping wedges 10 which also encircle the support leg 3 are inserted into the intermediate space between the contact surfaces 3 surrounding the support leg 3 and the outer wall of the support leg 3 or prevent play of the support leg 3 with respect to the platform 2.

Fig. 3 shows the arrangement in Fig. 1 in a perspective sectional view in the region of the double decks 4. In Fig. 3, four clamping wedges 10 can be seen, which rotate the support leg 3 equidistant from each other. The support leg 3 is circulated in total by eight clamping wedges 10. The clamping wedges 10 are identical to each other and in particular have an identical in the clamping position to the sea surface pointing wedge angle α. Consequently, the angle of attack α between the contact surfaces 13 and the outer wall of the supporting leg 3 is also identical and corresponds in each case to the wedge angle α of the clamping wedges 10. FIG. 3 shows, in particular, that the clamping wedges 10 are guided by two lateral cheeks 30 which run along Run edges of the contact surfaces 13 and perpendicular to the contact surfaces 13, so that a horizontal displacement of the clamping wedges 10 perpendicular to the longitudinal direction L is prevented.

Each wedge 10 has meeresbodenabseitig, d. H. facing the interior of the platform 2, two circular eyelets 31 are formed, which are intended in pairs for attachment of the sea bottom end of one of the hydraulic or mechanical cylinder 11.

Fig. 4 shows an arrangement as shown in FIG. 3 from a different angle, wherein the cutout shown in Fig. 4 of the offshore device 1 meeresbodenabseitig more of the support leg

3 as well as from the platform 2 as the detail in Fig. 3. In particular, it can be seen in FIG. 4 that the support leg 3 is surrounded within the platform 2 at least in sections by a guide tube 21 which is similar to the cross section of the outer skin opening 6a In the region of the clamping wedges 10 has recesses to allow a direct action of the clamping wedges 10 on the outer wall of the support leg 3. The in Fig. 4 not shown hydraulic or mechanical cylinder 1 run outside of the guide tube 21. In particular, the clamping wedges 10 from the interior of the platform 2 are operated out and easily replaceable because between the two guide cheeks 30 each of the clamping wedges 10 an inspection opening 33 is formed for the respective clamping wedge 10 ,

Fig. 5 shows schematically the arrangement of the clamping wedges 10 in the clamping position on the support leg 3. The clamping wedges 10 are moved by two of the hydraulic cylinders 11. The clamping wedges 10 are in particular in the longitudinal direction L, d. H. in Fig. 5 up and down, movable, but also transversely to the longitudinal direction L movable. An associated hydraulic control is not shown. Similarly, the attachment of the hydraulic cylinder 11 to the attachment means 12 in the interior of the platform 2 is not shown.

Fig. 6 shows the position of a clamping wedge 10 in an exemption, in which the clamping wedge 0 is pulled out of the space between the contact surface 13 and outer wall of the support leg 3 in meeresbodenabseitiger direction. The platform 2 is not clamped in this position on the support leg 3.

Fig. 7 shows a clamping wedge 10 in a side view. The clamping wedge 10 may have a friction-enhancing or force-compensating coating 70 on its side facing the support leg 3. This may be a rubber coating or Kusntstoffbelag, but there are also basically rows of teeth, teeth o. Ä. as a covering 70 conceivable. 8 shows the clamping wedge 10 in a perspective view. The pressing surface 13 facing side of the clamping wedge 10 is formed of, for example, smooth steel. On the side facing away from the seabed of the clamping wedges 10 two eyelets 80 are provided for the articulated mounting each one of the cylinder 11 respectively.

LIST OF REFERENCE NUMBERS

1 offshore facility

2 offshore platform

3 support leg

4 double decks

4a double deck opening

6 seaside outer skin

6a outer skin opening

8 clamping device

10 clamping wedges

11 cylinders

12 fasteners

13 contact surfaces

20 ring plate

21 guide tube

30 lateral cheeks

31 circular eyelets

33 inspection opening

70 force-compensating surface

80 eyelets

L longitudinal direction α wedge angle, angle of attack

Claims

claims

Offshore facility with

a building body (2) with at least one component guide (21) with a

Sea bottom side opening (6a) and with

at least one elongated member (3) having a longitudinal direction (L) and an outer wall inserted into the component guide (21) with clearance through the opening (6a),

with a game-reducing clamping device (8), characterized in that the clamping device (8) clamping elements (10) and the clamping elements (10) are each connected to an adjusting device (11), with which the clamping elements (10) along the longitudinal direction (L) of the elongated member (3) are movable back and forth and can be fixed in a clamping position,

Offshore installation according to claim 1,

characterized in that the clamping device (8) arranged on the platform side pressing surfaces (13) which are obliquely set to the outer wall,

and wedge-shaped clamping elements (10), which are arrangeable between the outer wall and the contact surfaces (13).

Offshore installation according to claim 2

characterized in that the contact surfaces (13) are arranged along a circumference of the opening (6a).

Offshore installation according to claim 1, 2 or 3,

characterized in that the contact surfaces (13) in the direction of

Outer wall to the seabed sloping down.

Offshore installation according to one of claims 1 to 4,

characterized in that the clamping elements (10) on one of the outer surface side facing a power distribution homogenizing coating (70). Offshore device according to one of claims 1 to 5 S,

characterized in that the clamping elements (10) on their inside the building (2) facing side eyelets (31) for attachment of hydraulic

operated cylinders (11).

Offshore device according to one of claims 1 to 6 7-,

characterized in that laterally against the contact surfaces (13)

Clamp element guides (30) are provided.

Offshore installation according to one of the preceding claims,

characterized in that the contact surfaces (13) a double deck (4)

Limit opening side and the clamping elements (10) of the body inside the double deck (4) are interchangeable.

Method for installing a structural body (2) on at least one elongate component (3) with a longitudinal direction (L), in which the at least one elongate component (3) has an outer wall through a seabed-side opening (6a) with a play in a component guide ( 21) is introduced and the clearance between the elongate member (3) and the component guide (21) is reduced by a clamping device (8) by clamping elements (10) of the clamping device (8) in the longitudinal direction (L) of the elongate member (3) moves be and the clamping elements (10) clamp the structure (2) on the elongate member (3) in a clamping position.

Method according to claim 9,

characterized in that the clamping elements (10) each

From meeresbodenabseitig a contact surface (13) of the building (2) in the direction of the seabed on the contact surface (13) and an outer wall of the elongate member (3) are pressed.

Method according to claim 9 or 10,

characterized in that the wedge-shaped clamping elements (10) are pressed simultaneously on the contact surfaces (13) and the outer wall.