EP3690145A1

EP3690145A1 - Double top suction pile and suction pile foundation

Info

Publication number: EP3690145A1
Application number: EP20158104.8A
Authority: EP
Inventors: Oene Jeljer DIJKSTRA
Original assignee: SPT Equipment BV
Current assignee: SPT Equipment BV
Priority date: 2012-11-29
Filing date: 2013-11-29
Publication date: 2020-08-05
Also published as: DK2925936T3; EP2925936A1; NL2011860B1; EP2925936B1; NL2011860A; WO2014084737A1; PL2925936T3

Abstract

Suction pile for installation in the seafloor to operate as a foundation or part of it to support an offshore structure resting onto the seafloor, the suction pile having internally near the top bulkhead (6) and spaced from this bulkhead (6) a load bearing surface (4) designed to keep the suction pile immovable while the offshore structure resting onto it is in full operation. The load bearing surface (4) could be the lower face of a fluid permeable slab which is in the space between the top bulkhead and the load bearing surface. Such slab could be obtained by fabrication in situ by casting a material against the top bulkhead (6).

Description

The invention relates to a suction pile, a foundation made prom one or more suction piles and an offshore structure resting on a foundation of one or more suction piles.
Suction piles and their way of installing are a.o. known from GB-B-2300661 and EP-B-0011894 , which disclosures are enclosed in here by reference. Briefly, a suction pile is a thin walled steel sleeve or pipe or cylinder, which cylinder is closed at its longitudinal top end by a bulkhead or different sealing means and which cylinder is sealingly located on the subsea bottom with the open end opposite the bulkhead since this open end penetrates the subsea bottom due to the weight of the suction pile. Thus the cavity, also called suction space, delimited by the cylinder and the bulkhead is sealed by the subsea floor such that vacuum or suction can be generated by removing water from within the suction space such that a resulting force tends to force the suction pile deeper into the subsea floor. The creation of the suction can be with the aid of a suction source, such as a pump, being on, or close to or at a distance from the suction pile and connected to the suction space. The applied level of the suction can be e.g. at least substantially constant, smoothly increase or decrease or else pulsate, for which there are convenient means . After use, the suction pile can easily be removed by creating an overpressure within the suction space, e.g. by pumping in (sea) water.
A self installing platform applying suction piles is known from e.g. WO99/51821 (SIP1) or EP-A-1 101 872 (SIP2) of the present inventor. WO 02/088.475 (Suction Pile Technology, SIP3) discloses a tower carrying a wind turbine at the top and suction piles as foundation.
US8025463 discloses an offshore foundation system having an assembly of spaced suction piles and a reaction base connecting the suction piles. The closed suction pile top projects a distance above the bottom face of the reaction base such that, in use, a gap remains between the top of a soil plug inside the suction space and the closed suction pile top.
WO 03/099646 discloses a seabed anchor provided by a suction pile having within its suction space a seabed soil retaining means embodied by a top down oriented cone with sharp angled apex. This anchor is designed for a seabed of fluent mud.
One of the benefits of suction piles is that a marine structure can be designed to be self foundating or self installing by providing it with one or more suction piles. So the hoisting device and the plant for installing the foundation, e.g. hammering device, can be eliminated.
Since the structure is provided with one or more suction piles, removal after use is made easier in that by pressing out the suction pile, the anchoring of the structure to the underwater bottom can be removed.
Preferably each suction pile has one or more of: a diameter of at least 5 metres; a height of at least 5 metres; a wall thickness of at least 1 centimetre; the longitudinal axis of the suction pile and the relevant supporting leg (of the upper structure to be supported by the suction pile) are substantially in line.

OBJECT OF THE INVENTION

The object of the invention is versatile. In an aspect the reliability and/or quality of the foundation is improved. In an aspect the installation of the foundation is facilitated. In an aspect removal of the foundation is facilitated.
The object is obtained by providing within the suction pile near the top bulkhead and spaced from this bulkhead a, e.g. pre-installed and/or fixed, load bearing surface designed to keep the suction pile immovable while the offshore structure resting onto it is in full operation and which load bearing surface preferably is fluid permeable to provide a fluid connection between the suction pile inner spaces above and below it. Thus the load bearing surface replaces the top bulkhead for the load bearing capacity it offers while used as a foundation body. The suction pile provided with the load bearing surface is e.g. a prefabricated object, thus containing the load bearing surface prior to penetration of the suction pile into the seabed.
Preferably, the load bearing surface is located within the suction space such that the suction space is present below and above the load bearing surface or, in other words, the suction spaces above and below the load bearing surface are in mutual fluid communication through the load bearing surface.
Such load bearing surface can be a flat metal sheet but also a conical shaped metal sheet or a grid or lattice of mutually crossing beams or a sheet of geotextile or geogrid (commonly named geosynthetics). A grid/lattice/geosynthetic is fluid permeable by nature. A, e.g. metal, sheet could be perforated or its outer circumference keeps a gap with the axial boundary of the suction pile. The load bearing surface could also be provided by the lower face of a fluid permeable slab which e.g. completely, fills the space between the top bulkhead and the bearing surface. Such slab could be prefabricated and subsequently mounted into the suction pile, or could be obtained by fabrication in situ by casting a material against the top bulkhead and e.g. allowing it to solidify. Such slab could also be provided by a layer of non coherent granules, e.g. stones, e.g. retained by a sheet providing the load bearing surface, e.g. a permeable structure of interweaved wires or a perforated metal sheet, such that the granules are retained between the load bearing surface and the top bulkhead. Such slab could completely fill the space captured between the top bulkhead and the load bearing surface or could leave a gap with the top bulkhead.
The bearing load from the load bearing surface could be transferred to the suction pile side wall in which case the load bearing surface preferably is inflexible or rigid, e.g. provided with or made from stiffeners, e.g. I-beams. Alternatively such load is transferred to the top bulkhead in which case incompressible elements (e.g. the slab, e.g. completely, filling the space between the load bearing surface and the top bulkhead, or girders bridging the distance between the load bearing surface and the top bulkhead) between the load bearing surface and the top bulkhead are applied which are compression loaded.
The invention is based on the recognition that transferring the required load bearing capacity from the top bulkhead to a lower level increases the stability of the foundation dramatically. With prior art suction piles the top bulkhead provides the required load bearing capacity for the suction pile to function as a foundation body and it occurred that after completion of sucking the suction pile completely into the sea floor, the suction pile was pushed deeper into the sea floor by the upper structure placed on top of the suction pile which according to the design calculations of the foundation such was impossible to occur. This made the behaviour of the foundation unpredictable. It came out that by providing the load bearing capacity at a lower level at the suction pile, such unpredictable behaviour of the foundation was eliminated. Based on speculation a reason could be that if the load bearing surface is no longer provided by the top bulkhead and provided at a level below the top bulkhead, the load distribution across such load bearing surface becomes more equal, resulting in more and immediate stability. Without to be bound by theory it is believed that remote from the top bulkhead, at the level of the inventive load bearing surface, the upright wall of the suction pile functions as a skirt which ensures complete contact between the load bearing surface and the soil plug within the suction pile.
On the other hand extraction from the seabed of the suction pile according to the invention is easier compared to the prior art suction pile, in case an overpressure within the suction space is applied to force the suction pile from the seabed opposite the way in which the suction pile penetrated the seabed by creation of suction within the suction space. Without to be bound by theory it is believed that the invention ensures equal distribution of the overpressure within the suction space, which makes extraction more reliable.
The invention is directed to suction piles for foundations, thus designed to carry the weight of an upper structure placed on top, to avoid that such upper structure sinks into the subsea bottom. Thus a foundation suction pile bears loads from the associated upper structure which tend to force the suction pile further into the ground. The, e.g. fixed, load bearing surface spaced below the top bulkhead is designed to prevent that the suction pile moves deeper into the subsea bottom due to the pushing loads generated by the weight of the upper structure. A foundation suction pile is by the nature of its loading different from a suction pile for anchoring, which anchoring suction pile must withstand pulling forces from the anchored object which tries to pull the anchoring suction pile out of the subsea bottom.
Preferably one or more of the following applies: the load bearing surface is parallel to the top bulkhead; the suction required to penetrate the suction pile into the subsea bottom during installation is generated within the suction pile above the load bearing surface, preferably since the suction side of a suction pump means is connected to the suction space above the load bearing surface, e.g. the top bulkhead is provided with a nozzle or different sealable port for fluid connection of the suction space with a suction pump means; the diameter of the suction pile is constant over its height (the height is the direction from the top bulkhead towards the opposite open end) ; from the top bulkhead the cylinder walls of the suction pile extend parallel; the open end of the suction pile, designed to be located on the sea floor first is completely open, in other words, its aperture is merely bordered by the cylinder walls; the water depth is such that the suction pile is completely below the water surface when its lower end contacts the sea floor, in other words when its lower end has not penetrated the sea floor yet; the foundation comprises one, two, three, four or more mutually spaced suction piles; the load bearing surface has a permeability of at least 10% or 20%, in other words at least 10% or 20% of the cross sectional surface area of the suction space at the level of the load bearing surface allows free passage of fluid between above and below the load bearing surface; the load bearing surface is at least 10 or 20 or 50 centimetre and/or 1 or 1.5 or 2 metre to a maximum below the top bulkhead; the cone shaped load bearing surface is shallow and the cone angle is obtuse, preferably is limited to between 180 (flat sheet) and 120 degrees; with the penetration of the suction pile into the sea floor completed, the top bulkhead is spaced from the sea floor and/or the load bearing surface bears onto the sea floor which is possibly at elevated level within the suction pile, compared to the seafloor level external from the suction pile, due to raising of the seabed plug within the suction space caused by penetration of the suction pile into the seabed;
The suction pile is also preferably provided with known as such valves and/or hatches adjacent or at its top bulkhead for selectively allowing water and air to enter or exit the suction space through the top side of the suction pile.
The invention provides an offshore foundation system or a suction pile of said system, the suction pile preferably provided by an open bottom and closed top, advantageously cylindrical, elongate shell providing a suction compartment or suction space, said closed top having an externally facing upper face and an opposite, toward the suction space facing lower face and preferably provided with one or more valves selectively allowing fluid communication between the suction space and the environment, the suction space being provided with a preferably fixedly located load bearing surface oriented perpendicular to the longitudinal axis of the shell and there is a gap between said load bearing surface and the lower face of the closed top, which gap preferably is in fluid communication with the suction space and wherein, in use, the load bearing surface bears onto a top of a soil plug inside the suction space, the load bearing surface preferably being provided by the bottom surface of a sheet or slab like element which is preferably integrally formed with the suction pile.
The invention is further illustrated by way of non-limiting, presently preferred embodiments providing the best way of carrying out the invention and shown in the drawings.

Fig. 1 shows a side view;
Fig. 2-13 show a top views, sectional side views and partly cutaway perspective views of four different embodiments of the suction pile;
Fig. 14 and 15 show marine structures in perspective view.

Fig. 1 shows three stages during penetration of the suction pile into the sea floor by suction within the suction space. The left hand stage is the initial stage in which the open bottom of the suction pile has penetrated the seabed by gravity, such that the suction space is sealed. The central stage is obtained by removing water from the suction space by pumping, such that suction is created within the suction space such that the suction pile penetrates deeper into the seabed, thus its top comes closer to the seabed. The right hand stage is the final stage in which the suction pile is penetrated to its final depth, providing its design load bearing capacity for a weight resting on top of it. The load bearing surface 4 spaced below the top bulkhead is shown. The top bulkhead 6 always is spaced from the sea floor 11. Within the suction space internal from the side wall 7, the surface 12 of the sea floor material rises due to penetration of the suction pile. Such seabed part captive within the suction space is also called soil plug.
Fig. 2-13 show suction piles having a load bearing surface 4 within the suction space 7 and spaced below the top bulkhead 6. A pipe stud 5 penetrates the top bulkhead to connect the suction space with a suction source. The suction space is bounded by the top bulkhead 6, the cylindrical side wall 7 and the open end 8. In all embodiments the distance between the top bulkhead and the load bearing surface measures 50 centimetre.
In fig. 2-4 the load bearing surface 4 is the bottom side of a flat sheet keeping at its circumference an annular air and water gap with the wall 7. Compression loaded girders 10 bridging the load bearing surface 4 and the top bulkhead 6 transfer the bearing load from the load bearing surface to the top bulkhead 6 through. As shown, the girders leave openings 13 to allow fluid to pass the girders in the direction perpendicular to the longitudinal axis 14 of the suction pile. In fig. 5-7 the load bearing surface 4 has a cone shape and also keeps an air and water gap with the wall 7 at its outer circumference. The opposite walls of the cone include an obtuse angle of 160 degrees, in other words the wall of the cone, vertically oriented resting on its apex, include an angle (referred to as a in the drawing) of 10 degrees with the horizontal. In fig. 8-10 the flat load bearing surface 4 tightly fits within the cylinder 7 thus the circumferential air and water gap is absent. In stead, the sheet 4 is perforated to be air and water permeable. In fig. 11-13 the load bearing surface is the lower face 4 of a slab 9. The slab 9 is air and water permeable and the face 4 is also air and water permeable. As an alternative the slab 9 could be replaced by a layer of incoherent gravel of same thickness, captive between the top bulkhead 6 and the face 4 provided by e.g. a perforated sheet or lattice.
Fig. 14 and 15 are examples of the upper structures to be supported by the suction piles 1. The top of the upper structures is provided by a platform 2 above water level 3.
The invention is not limited to the above described and in the drawings illustrated embodiments. E.g. the marine structure can have a different number of suction piles. The number of supporting legs by which the platform rests onto the suction piles is preferably equal to the number of suction piles, but this is not absolutely necessary. E.g. three suction piles are at the corners of a structure that is triangular in top view. It is not required that the suction piles and supporting legs are at the corners of the structure. The platform can be constructed and/or shaped differently.

Claims

Suction pile for installation in the seafloor to operate as a foundation or part of it to support an offshore structure resting onto the seafloor, the suction pile having internally near the top bulkhead and spaced from this bulkhead a load bearing surface designed to keep the suction pile immovable while the offshore structure resting onto it is in full operation.
Suction pile according to claim 1 and which load bearing surface is fluid permeable to provide a fluid connection between the suction pile inner spaces above and below it.
Suction pile according to claim 1 or 2 and which load bearing surface comprises a metal sheet and/or is pre-installed and/or is fixed.
Suction pile according to claim 1, 2 or 3, the load bearing surface is at least 10 or 20 or 50 centimetre and/or 1 or 1.5 or 2 metre to a maximum below the top bulkhead.
Suction pile according to any of claims 1-4, being a prefabricated object comprising the load bearing surface.
Offshore structure having a foundation of one or more suction piles supporting the offshore structure resting onto the seafloor,
the suction piles are each provided by a with an open bottom and a by a top bulkhead closed top provided, advantageously cylindrical, elongate shell internally providing a suction compartment or suction space, said top bulkhead having an externally facing upper face and an opposite, toward the suction space facing lower face and preferably provided with one or more valves selectively allowing fluid communication between the suction space and the environment, the suction space being provided with a preferably fixedly located load bearing surface, e.g. oriented perpendicular to the longitudinal axis of the shell, and there is a gap between said load bearing surface and the lower face of the top bulkhead, which gap preferably is in fluid communication with the suction space and wherein, in use, the load bearing surface bears onto a top of a soil plug inside the suction space, the load bearing surface preferably being provided by the bottom surface of a sheet or slab like element which is preferably integrally formed with the suction pile.
Method of installing a suction pile according to any of claims 1-5 or a structure according to claim 6 or 9 or 10, wherein the suction pile bottom (8) penetrates the seafloor (12) and fluid is removed from the suction space such that penetration proceeds by suction and the load bearing surface finally bears onto the seafloor, preventing continuation of further penetration of the seafloor by the suction pile.
Method according to claim 7, wherein the suction pile before penetrating the seafloor comprises the load bearing surface and/or at the end of the method the top bulk head is at a level above the sea floor, preferably at least 10 or 20 or 50 centimetre and/or 1 or 1.5 or 2 metre to a maximum.
Structure according to claim 6, wherein the load bearing surface is provided by the bottom surface of a slab like element, that is fluid permeable.
Structure according to claim 9, the slab like element is provided by in situ casting a material or by a layer of non coherent granules.
Method of installing according to claim 7 or 8, with the penetration of the suction pile into the sea floor completed, the top bulkhead is spaced from the sea floor and/or the load bearing surface bears onto the sea floor.