NO20130574A1 - A suction anchor, a composite module segment for a suction anchor, and a method for assembling such segments - Google Patents

Abstract

BACKGROUND OF THE INVENTION The present invention relates to a composite suction anchor for providing a foundation or mortar attachment to a soft seabed, including an open bottom portion, a closed top portion, and a side portion defining a first outer surface (23) having a substantially constant outer circumference. The anchor includes at least two adjacent bucket module segments (4, 5) with an inner surface (22) and an outer surface (23p, 23b, 23c). Each bucket module segment (4, 5) includes at least a first and a second contact surface portion (23b, 23c) located on said outer surface (23p, 23b, 23c) on each side of an exposed outer surface portion (23p), joined by contact surfaces of at least one adjacent module segment. A bucket module segment and a method for joining such segments are also shown.

Description

The present invention relates to a modular composite suction anchor for mooring purposes.

Suction buckets, suction anchors or suction moorings are well-known technology used for mooring oil-related installations, floating wind turbines, underwater installations etc. to a soft seabed. Suction anchors are convenient as they can be removed and provide a reliable attachment point. A suction anchor includes a bucket or "canister" with an open end and a closed end, and an attachment device at the closed end. During installation, the suction anchor is lowered to the seabed and water is pumped out of the bucket so that the pressure difference between the outside and the inside of the container drives the anchor into the seabed. Similarly, the anchor can be released from the seabed by pumping water into the bucket.

Suction anchors are usually formed from large diameter steel pipes which are relatively heavy and difficult to install. Furthermore, solutions that include steel pipes are difficult to make in different sizes and must be transported in their full size.

Suction anchors can be part of uniform underwater production equipment that is lowered to the seabed from a vessel, and four suction anchors are typically used. These anchors are normally made of steel of sufficient dimension or thickness to allow corrosion, and the thickness will depend on the expected life of the installation. The anchors make up a high percentage of the installation's total weight. The installation's weight determines the vessel's required classification/permitted load.

It is an aim of the present invention to provide a suction anchor solution and an assembly method which enables simple production of suction anchors with few size limitations.

Furthermore, it is an object of the present invention to provide a modular suction anchor that is easy to transport, as the suction anchor can be transported in parts or can be filled with a buoyant medium and towed floating to the place of use.

Furthermore, it is an object of the present invention to provide a suction anchor which is cost-effective to manufacture in large numbers and in different sizes.

Furthermore, it is an object of the present invention to provide a suction anchor which is considerably lighter than a corresponding steel anchor.

Weight savings that will enable the use of a smaller vessel will result in significant installation savings and increased availability of installation vessels.

The use of composite suction anchors can reduce the weight of suction anchors to typically between half and a third of the weight of comparable steel suction anchors, and the potential for financial savings is significant. Alternatively, the weight saving can leave room for increasing the weight of more useful components on an installation where the anchor is incorporated. Furthermore, the expected lifetime of the suction anchors is independent of corrosion.

The present invention defines a suction anchor for providing a foundation or a mooring attachment on a soft seabed. The suction anchor includes a bucket with an open bottom portion, a closed top portion, and a side portion defining a first outer surface having a substantially constant outer circumference along a seabed penetration height.

The seabed penetration height is the height of the suction anchor, or the intended insertion depth of the anchor into the seabed.

The suction anchor defines an internal volume, and devices are provided to enable the pumping out of water from the internal volume. These devices may include some form of sealable opening, a valve that can be entered by an ROV, or any other structure that allows water to be pumped into or out of the volume. The suction anchor includes at least two adjacent bucket module segments with an inner surface and an outer surface that is part of the first outer surface. Each bucket module segment extends at least along the aforementioned penetration height. Each bucket module segment further includes a contact surface portion on the outer surface joined with a contact surface portion on an outer surface of an adjacent module. The bucket module segments are made of a composite material. A load connection part is attached to the closed top part.

A first and a second contact surface portion can be located on said outer surface on each side of said outer surface portion of each respective bucket module segment.

The first module contact surface portion may include a male assembly guide, and the second module contact surface portion may include a female assembly guide.

The contact surface portion may abut against a contact surface portion of an adjacent bucket module segment in a center of a stiffening rib in the suction armature.

The suction anchor can include six bucket module segments.

Furthermore, the invention relates to a composite bucket module segment for a suction anchor. The bucket module segment includes a side portion, which defines an outer surface having a substantially constant outer circumference along a subsea elevation, an inner surface and an outer surface, and a module contact surface portion on the outer surface.

A first and a second contact surface portion can be located on said outer surface on each side of said outer surface portion of each respective bucket module segment.

The first module contact surface portion may include a male assembly guide, and the second module contact surface portion may include a female assembly guide.

Furthermore, the invention relates to a method for assembling a suction anchor from composite bucket module segments, comprising the steps of providing a first composite bucket module segment with a substantially constant outer circumference along a seabed penetration height (hi), said composite bucket module segment including an inner surface and an outer surface, where the outer surface includes a first contact surface portion on a first side of an exposed surface portion and a second contact surface portion on a second side of the exposed surface portion, providing a second bucket module segment substantially similar to the first composite bucket module segment, joining the first contact surface portion of the first composite bucket module segment with the second contact surface portion on the second bucket module segment, and continue to provide bucket module segments and join first contact surface portions and second contact surface portions on adjacent bucket module segments until a complete bucket is formed.

Brief description of the attached drawings:

Figure 1 shows a suction anchor according to an embodiment of the invention; Figure 2 is a bottom view of the suction anchor in Figure 1; Figure 3 is a plan view of the suction anchor in Figure 1; Figure 4 is a plan view of a first composite bucket module segment according to the invention; Figure 5 is a plan view of a second composite bucket module segment according to the invention; Figure 6 is a cross section through a composite bucket module segment according to the invention; Figure 7 is a cross-section through a suction anchor according to the embodiment of the invention shown in Figure 1; Figure 8 shows a detail from the cross-section shown in Figure 7; Figure 9 shows a cross-section through an assembly of two bucket modules in Figure 6; and Figure 10 is a perspective view of a bucket module according to the invention.

Detailed description of an embodiment of the invention with support in the attached drawings: Figure 1 shows a suction bucket, a suction anchor or a suction mooring according to the invention, hereinafter referred to as the anchor 1. The anchor 1 includes a load connection part 2 of metal, including a fastening flange 3, attached to a modular composite share or bucket. The modular composite portion is composed of segmented bucket module segments 4, 5 joined in module joints 7. Figure 1 shows smooth bucket module segments 4 and fluid connection bucket module segments 5 with connection portions 6 for connection to a pump and for pumping water into or out of the bucket. The bucket has a cylindrical outer shape and a curved transition part 11 which forms a transition to a flat end part 10. The curved transition pan<g>11 between the cylindrical outer shape and the flat end part 10 ensures distribution of loads in the composite bucket. The flat end portion 10 provides an attachment area for the attachment flange 3. A side portion defines a first outer surface 23 with a substantially constant outer circumference along a seabed penetration height l\ The penetration height h represents the dimensioned penetration depth of the suction anchor into the seabed. A first outer surface 23 is a combination of outer surfaces on each bucket module segment 4, 5. Figure 2 shows the bucket from the underside, where the cylindrical shape is clearly visible. The open bottom of the bucket allows the anchor to fill with soft seabed when water is pumped out through at least one of the connection openings 6 in the two fluid connection bucket module segments 5. The smooth bucket module segments 4 are similar to the fluid connection bucket module segments 5 except for the missing connection openings 6. The connection openings 6 can be sealed off when not connected to a pumping unit to maintain a pressure difference between the inside and outside of the bucket when the anchor is loaded with a load. The suction anchor/bucket defines an inner volume 24. The bucket module segments define an inner surface 22. Figure 2 shows six bucket module segments assembled in module joints 8 which form the segment joints 7. Each bucket module segment 4, 5 is designed with a segment rib 12 on each side of a curved portion which is a part of the bucket's cylindrical outer shape. In the embodiment shown with six bucket module segments, each bucket module segment defines a 60° curved wall portion and segmented rib portions 12 on each side of the curved wall portion. The rib parts 12 project inwards in a radial direction in relation to the curved wall part. The rib parts 12 in each bucket module segment 4, 5 form surfaces for easy assembly, in that the rib parts on each bucket module can be joined with the adjacent bucket module. The rib sections provide ample area for binding / forming the bucket module segments and for assembling the bucket. The rib portions 12 facilitate the formation of sealed joints between the modules and increase the rigidity of the assembled bucket. Furthermore, the rib sections 12 ensure a significant increase in the seabed contact area and thus in the holding friction, which increases the suction anchor's holding capacity. Figure 2 further shows the bottom flange 9 which forms a base for bolts that lock the fastening flange to the bottom flange and for stress distribution of the load from the connection part. The bottom flange has radial incisions to enable ribs to pass through the bottom flange. Figure 3 is a plan of the anchor according to the invention. The six assembled bucket module segments 4, 5, including the fluid connection bucket module segments 5 with connection openings 6, form a cylindrical outer surface which is joined in segment joints 7. The attachment flange 3 with the load attachment portion 2 is fixed on the flat end portion 10 of the bucket. The curved transition 15 extends between the cylindrical portion and the flat end portion 10. Figure 4 and Figure 5 show a plan view respectively of a fluid connection bucket module segment 5 and a smooth bucket module segment 4. The fluid connection bucket module segment 5 includes the sealable connection opening 6. A curved transition portion 11 is formed between the arcuate portion which is part of the cylindrical bucket and the flat end portion 10. Each bucket module segment 4, 5 includes a male rib 12b with a male assembly guide 14 and a female rib 12b with a female assembly guide. The male assembly guide 14 on each bucket module is designed to protrude into the female assembly guide on the adjacent bucket module to facilitate correct assembly of the bucket. The outer surface of each module segment is divided into three separate outer surfaces 23p, 23b, 23c of which a central surface/an exposed surface portion 23p is part of the bucket's outer surface 23. The contact surface portions 23b, 23c are located on either side of the exposed outer surface portion 23p for assembly and contact with the contact surface 23b, 23c on an outer surface of an adjacent module.

The flat end portion 10 forms a flange attachment portion 16 with flange bolt holes 19 for flange bolts that stand through the bottom flange and the mounting flange. The flange attachment on all bucket module segments reduces the load on

the joining contact between the modules.

Figure 6 shows a cross-section through a bucket module according to the embodiment shown in the other figures, and clearly shows the arc-shaped outer part 21, the female segment rib 12a and the male segment rib 12b. The bucket module is shown with an arc of 60°, but this angle will depend on the number of bucket module segments that form the bucket. The inward radial ribs 12a, 12b are formed with the male assembly guide 14 and the female assembly guide 13. The male assembly guide 14 is designed and sized to protrude into the female assembly guide on the adjacent bucket module to ensure proper alignment between the adjacent modules below compilation. Figure 7 shows a cross-section through an anchor according to the invention with the fastening flange 3 with a load connection part 2 and a reinforcement joint 17 in between. The attachment flange 3 is attached to the six bucket module segments and the bottom flange 9. The segment ribs 12 are shown with dashed lines. The curved transition panel 11 between the cylindrical outer part and the flat end part 10 ensures load distribution between the flange and the bucket. Figure 8 shows a detail of the fastening flange 3 with the load connection part 2 and the bottom flange 9. The flat end part of all the bucket module segments and thus the bucket is sandwiched between the fastening flange 3 and the bottom flange 9. Flange bolts 18 stand through the flat end part of the bucket, the fastening flange 3 and the bottom flange 9. The segment ribs 12 extends towards the flat end part of the bucket and reinforces the top part. Figure 9 shows a cross-section through an assembly of two bucket modules in Figure 6 in accordance with the embodiment shown in the other figures. The arched outer portions 21 form a smooth or smooth arc and a segment rib 12 is joined by a female rib portion 12a and a male rib portion 12b, forming a double

rib 12 which is twice the wall thickness of the outer wall. This increased wall thickness also increases the stiffness of the assembly. Again, the bucket modules are shown with an arc of 60°, but this angle will depend on the number of bucket module segments that make up the bucket. The male assembly guide 14 fits into the fitted female assembly guide 13 to ensure correct alignment between neighboring modules during assembly and contributes to increased rigidity and integrity in the joining. A U-shaped locking profile 25 is threaded onto the two ribs 12 to increase rigidity, as an additional seal and to keep the two ribs in the assembled position. An adhesive, such as epoxy or polyester, may be injected into the U-shaped locking profile 25 for added integrity and to form a seal. The U-shaped locking profile 25 can typically be made of a composite material or an extruded alloy.

Figure 10 is a perspective view of a bucket module according to the invention with the part for connection of the fastening flange. The female segment rib 12a and the male segment rib 12b are shown as conical ribs of increasing width towards the top of the module. The curved transition panel 11 between the cylindrical outer part, the flat end part 10 and the conical ribs ensures the distribution of loads between the flange and the bucket. The male assembly guide 14 and the female assembly guide 13 form inverted L-shaped assembly guides to ensure correct alignment of the bucket modules in both longitudinal and radial directions. Again, the size of the ribs helps to determine the total area of the anchor that is exposed to the seabed and thus to determine the total friction between the seabed and the anchor.

The embodiment shown includes a load connection part 2 in metal, including a fastening flange 3, fixed to the suction anchor. However, the metal load connection portion 2 can be replaced with other connection elements typically for connecting the suction anchor to underwater installations. Such attachment elements may for example include a ring or cylindrical portion molded into the upper part of the bucket module segments for attachment to an associated portion of an underwater installation. Alternatively, such a ring or cylindrical part can be part of a metal attachment flange structure similar to that shown in, for example, Figure 7, but where the connection part 2 and the joint 17 have been replaced with a part for connection to an underwater installation. The fastening flange also helps to stiffen and distribute stresses from the load from the element to be anchored to the suction anchor. A metal connection structure can also improve the resistance to wear between the element to be anchored and the suction anchor itself.

In this specification, the term "composite" is intended to cover fiber-reinforced synthetic materials such as glass fibers in a polyester or epoxy matrix. Glass fibers are normally considered the most cost-effective solution, as the price of carbon fibers or Kevlar fibers can be prohibitively high.

"Composite" is not intended to cover materials such as concrete or steel.

Claims (7)

1. Suction anchor with a load attachment portion, for providing a foundation or mooring anchorage in a soft seabed, including an open bottom portion, a closed top portion, a side portion defining a first outer surface (23) having a substantially constant outer circumference along a seabed penetration height (hi ), where said suction anchor defines an inner volume (24) and devices to enable the pumping out of water from said inner volume (24), said suction anchor comprising: at least two adjacent bucket module segments (4, 5) with an inner surface (22) and a outer surface (23p, 23b, 23c), where each bucket module segment (4, 5) extends at least along said indentation height (hj); where each bucket module segment (4, 5) includes at least a first and a second contact surface portion (23b, 23c) located on said outer surface (23p, 23b, 23c) on each side of an exposed outer surface portion (23p), joined with contact surfaces of at least one adjacent module segment; and where the bucket module segments (4, 5) are made of a composite material. 2. Suction anchor according to claim 1, wherein the first module contact surface portion (23b) includes a male assembly guide (14) and the second module contact surface portion (23c) includes a female assembly guide (13). 3. Suction anchor according to claim 1, where the first contact surface part (23b) is formed as a male rib (12b) with a male assembly guide (14) and the second contact surface part (23c) is formed as a female rib (12b) with a female assembly guide (13) and the contact surface portion (23b) is adjacent to a contact surface portion (23c) on an adjacent element in the center of a stiffening rib (12) in the suction anchor. 4. Suction anchor according to claim 1, including six bucket module segments (4, 5). 5. Composite bucket module segment (4, 5) for a suction anchor with a substantially constant outer circumference along a seabed penetration height (hi), said bucket module segment (4, 5) including an inner surface (22) and an outer surface (23b, 23c, 23p), wherein the outer surface includes a first contact surface portion (23b) on a first side of an exposed surface portion (23p) and a second contact surface portion (23c) on a second side of the exposed surface portion (23p). 6. Composite bucket module segment according to claim 5, where the first contact surface portion (23b) is formed as a male rib (12b) with a male assembly guide (14) and the second contact surface portion (23c) is formed as a female rib (12b) ) with a female assembly guide (13). 7. Method for assembling a suction anchor of composite bucket module segments according to claim 4, comprising the steps of: providing a first composite bucket module segment (4, 5) with a substantially constant outer circumference along a seabed penetration height (hj), said composite bucket module segment ( 4, 5) including an inner surface (22) and an outer surface (23b, 23c, 23p), wherein the outer surface includes a first contact surface portion (23b) on a first side of an exposed surface portion (23p) and a second contact surface portion (23c) on a second side of the exposed surface portion (23p); providing a second bucket module segment (4, 5) substantially similar to the first composite bucket module segment (4, 5); joining the first contact surface portion (23b) of the first composite bucket module segment (4, 5) with the second contact surface portion (23c) of the second bucket module segment (4, 5); and continuing to provide bucket module segments (4, 5) and join the first contact surface portions (23b) with the second contact surface portions (23c) on adjacent bucket module segments (4, 5) until a complete bucket is formed.