NL2016840B1 - Offshore support - Google Patents

Abstract

The present invention relates to an offshore support comprising a longitudinal body, wherein the body is provided with at least one passage along its longitudinal length. The body is preferably hollow and comprises a circumferential wall, the passage comprising at least two flow openings in the circumferential wall. The offshore support can be a monopile or be designed as an add-on that can be placed on a monopile.

Description

Offshore support

The invention relates to an offshore support comprising a longitudinal body.

An example of such an offshore support is a so-called monopile, which is installed in the seabed and acts as a support for a wind turbine. Another example of an offshore support is a so-called jacket.

Monopiles have proven to be particularly suitable for applications with a limited water depth of, for example, 25 meters.

The advantages of monopiles are the reliable and proven technology, which is also relatively easy to calculate. Manufacturing is relatively simple and fast, and the monopiles can be transported relatively compactly on a ship. Moreover, monopiles are easy to handle and easy to install with a pile driving device.

Partly in connection with the above advantages, a trend is also underway to develop monopiles for larger water depths, for example 30-60 meters water depth, i.e. a range where so-called jackets are currently widely used. However, jackets are half-timbered structures, and therefore much more complex, which means that they lack many of the advantages of monopiles mentioned above.

For the application of monopiles in the range of 30-60 meters water depth, so-called XL monopiles are being developed. Due to their greater length, these XL monopiles have a longer moment arm to the seabed in which they are mounted, and the larger diameter of up to 7 meters in diameter in the wave-loaded zone also provides them with a large frontal surface that the waves can cope with. to beat. The dynamic load due to the wave stroke exhibits a substantially quadratic relation to the diameter of the monopile.

The longer moment arm and the larger exposed surface both contribute to the dynamic loading of the XL monopile. This dynamic load is preferably kept as low as possible, because this load has a major influence on the fatigue life of the monopile.

An object of the present invention is to provide an offshore support in which the disadvantages mentioned do not occur, or at least to a lesser extent.

The said object has been achieved according to the invention with the offshore support according to the invention, wherein the body is provided with at least one passage along its longitudinal length. By providing this at least one passage at or slightly below sea level, dynamic loading of the offshore support as a result of the wave stroke will be considerably reduced. After all, the waves will partly flow through the passage instead of whipping against the offshore support.

Although an offshore support according to the invention can reduce the dynamic load of different types of supports and in different applications, such an offshore support is particularly advantageous in combination with XL monopiles at a relatively large depth, for example 30-60 meters of water depth. Due to their greater length, these XL monopiles have a longer moment arm up to the seabed in which they are mounted, and the larger diameter of up to 7 meters at sea level also provides them with a large frontal surface against which the waves can hit.

The offshore support itself can be a monopile, but it is also conceivable that the offshore support is applied as an add-on to a monopile - which itself is driven to some distance below sea level. In both cases the passages are ideally placed where the dynamic load due to the wave stroke is highest, i.e. at or just below sea level.

Although the invention is not limited thereto, the body is preferably hollow for material-saving and weight-reducing considerations, and the body comprises a circumferential wall, the passage comprising at least two flow openings in the circumferential wall. The offshore support can for instance be a monopile or an add-on that can be applied to a monopile.

According to a preferred embodiment, the flow openings extend in the longitudinal direction of the longitudinal hollow body, the flow openings having an elongated slot shape. Due to the elongated slot shape that extends in the longitudinal direction of the body, the slot-shaped passage covers a height range. The passage can thus be positioned such that the sea level in all tides (ebb and flow) is at the level of the passage. In addition, the passage can transmit waves of different heights.

In order to strengthen the offshore support, for example against torsional load, according to a further preferred embodiment, one or more than one reinforcing element is provided. The weakening caused by the passages can be at least partially compensated by the one or more than one reinforcing element.

According to a further preferred embodiment, the reinforcement element is a reinforcement profile extending in the longitudinal direction of the body and which is formed by the circumferential wall located between the through-flow openings.

According to a still further preferred embodiment, recessed wall parts of two adjacent flow openings are connected to the circumferential wall on the sides facing each other, the wall parts being bent towards each other and connected to each other, the wall parts together with the circumferential wall located between the adjacent flow openings Enclose reinforcement profile extending in longitudinal direction of the body with a substantially triangular cross-section. The wall material of the recesses is thus used to reinforce the offshore support.

In order to minimize the flow around the offshore support, it is preferable if the reinforcement element is within a volume enclosed by the longitudinal hollow body.

According to a still further preferred embodiment, the body of the offshore support comprises a first part that shows a tubular shape, a second part that forms a flow-through part, and a third part that shows a tubular or ring shape. It is noted that a ring shape is herein understood as a species of a tube, the tube having a limited length with respect to its diameter.

According to a still further preferred embodiment, the first part has a first diameter and the third part has a second diameter, and wherein the first diameter of the first part is larger than the second diameter of the third part, and the flow-through part of the first part in the towards the third part. Due to the rejuvenation, the relatively large bottom diameter of an XL monopile (of as much as 8-10 meters) can connect to a conventional turbine with a more limited diameter.

A further increase in the (torsional) stiffness can be obtained if, according to a still further preferred embodiment, at least two adjacent reinforcing elements are arranged converging or diverging with respect to each other in the longitudinal length of the body.

A further increase in the (torsional) stiffness can also be obtained if, according to a still further preferred embodiment, one or more than one reinforcing element extends between two fixing points on the circumferential wall of the body, said fixing points in a circumferential direction of the body relative to are staggered.

Because the body, more particularly in the flow-through part thereof, is provided with at least one passage along the longitudinal length of the body, the strength and stiffness of the body decreases. In order to enable the offshore support to be driven with a minimum load on the flow-through part provided with the at least one passage, according to a still further preferred embodiment, the first part is provided with a stop to which a pile-up attachment can be arranged.

According to a still further preferred embodiment, the pile-mounting piece has a shape which encloses the second part and which has such a length that the pile-fitting piece extends from the stop to at least beyond the third part of the longitudinal hollow body. A pile-driving device can drive the offshore support via the pile-mounting piece, whereby the flow-through part provided with the at least one passage is minimally loaded.

According to a still further preferred embodiment, the part of the pile attachment that encloses the second part of the offshore support has a conical shape. As a result, the pile-driving attachment can be tightly arranged around and over a rejuvenating flow-through part, while the diameter on which the pile-driving device is to grip is closer to the size of a conventional monopile with a diameter at the top of about 6.5 m can be brought.

According to a still further preferred embodiment, the at least one passage is arranged near an end of the body.

According to a still further preferred embodiment, the offshore support is a monopile and then forms an offshore foundation.

According to a still further and alternative preferred embodiment, the offshore support can be placed as an add-on on a monopile.

In the following description, preferred embodiments of the present invention are further explained with reference to the drawing, in which:

Figure 1: a sectional view of a wind turbine mounted on an offshore support according to the invention;

Figures 2 and 3: a side and perspective view of an offshore support according to a first preferred embodiment;

Figures 4 and 5: a side and perspective view of an offshore support according to a second preferred embodiment;

Figures 6 and 7: a side and perspective view of an offshore support according to a third preferred embodiment;

Figures 8 and 9: a side and perspective view of an offshore support according to a fourth preferred embodiment;

Figure 10: a perspective view of the offshore support according to Figure 8;

Figures 11 and 12: a perspective and top view of an offshore support according to a fifth preferred embodiment; and

Figures 13 and 14: a side and perspective view of an offshore support according to a sixth preferred embodiment.

The offshore support 1 shown in Figure 1 concerns a monopile 2. This offshore support 1 comprises a longitudinal body 4 which is provided with a number of passages 6 along the longitudinal length of the longitudinal body 4. A wind turbine 8 is placed on the offshore support 1 , which is mounted with its mast 10 directly (or indirectly via a so-called transition piece) on the offshore support 1.

The passages 6 in the longitudinal body 4 are arranged near one end of the body 4, more particularly at the level of the sea level 12. Because the passages 6 have an elongated slot shape, they can also with a fluctuation of the water depth, ie the distance remain between the sea level 12 and the sea floor 14 at the level of the sea level. In this way, the desired effect can be guaranteed with tidal changes (ebb and flood), and with waves of different heights.

Although in the embodiment shown the offshore support 1 is a monopile, according to an alternative embodiment the offshore support 1 can be placed on a monopile as an (not shown) add-on.

Various embodiments are shown in the following figures 2-14. Although the offshore support 1 is not necessarily limited thereto, the body 4 is hollow in all embodiments shown and the body 4 comprises a circumferential wall 16, the passage 6 comprising at least two flow openings 18 in the circumferential wall 16. These flow-through openings 18 extend in the longitudinal direction of the longitudinal hollow body 4, wherein the flow-through openings 18 have an elongated slot shape.

Because the passages 6 locally weaken the body 4 of the offshore support 1, one or more than one reinforcement element 20 is preferably provided.

Such a reinforcing element 20 can be designed, for example, as a reinforcing profile 22 extending in the longitudinal direction of the body 4 and formed by the peripheral wall 16 (Figs. 13 and 14) located between the flow openings 18, but can also comprise a separately provided reinforcing profile 22. In Figures 2-12, the reinforcement profiles 22 are embodied as tubular reinforcement elements 20 which are, as it were, integrated in the peripheral wall 16.

Figures 13 and 14 show an alternative embodiment in which recessed wall parts 22 of two adjacent flow-through openings 18 are connected to the peripheral wall 16 on the sides 24 facing each other. These wall parts 22 are bent towards each other and connected to each other, wherein the wall parts 22 together with the circumferential wall 16 located between the adjacent flow openings 18 enclose the reinforcing profile 22 extending in the longitudinal direction of the body 4. In the embodiment shown, the reinforcement profile 22 has a substantially triangular cross-section, one side of the triangle being formed by the slightly curved peripheral wall 16.

In Figures 12 and 13, the reinforcement profiles 22 are formed by folding the wall parts 22 to the volume enclosed by the hollow body 4 and connecting them together within the volume enclosed by the hollow body 4. As a result, the reinforcement profile 22 forming reinforcement element 20 is within a volume enclosed by the longitudinal hollow body 4, where it has minimal influence on the flow. An embodiment of the reinforcement profile 22 facing outside the body 4 would increase the contact surface with which the body 4 is exposed to flow and wave impact, which is disadvantageous.

In the embodiments shown, the body 4 of the offshore support 1 comprises in each case a first part 26 which has a tubular form, a second part 28 which forms a flow-through part, and a third part 30 which has a tubular or ring-shaped form (figures 2-14) . It is noted here that a ring is considered to be a species of a tube, wherein the length of the tube in a ring has a limited size relative to the diameter.

In the embodiments of figures 4-12, the first part 26 has a first diameter and the third part 30 has a second diameter, the first diameter of the first part 26 being larger than the second diameter of the third part 30, and the flow part 28 of the first part 26 in the direction of the third part 30.

The (torsional) rigidity of the offshore support 1 can be further increased by arranging, as shown in Figs. 6 and 7, adjacent reinforcing elements 20 converging or diverging with respect to each other in the longitudinal length of the body 4.

The (torsional) rigidity of the offshore support 1 can be further increased if, as shown in Figs. 11 and 12, one or more than one reinforcing element 20 extends between two fixing points on the peripheral wall 16 of the body 4, these fixing points are offset relative to each other in a circumferential direction of the body 4.

In the side view of Fig. 8, the first part 26 of the offshore support 1 is provided with a stop 32 on which a pile attachment 34 can be arranged. The pile-up attachment 34 can be fitted during pile-driving to relieve the second part 28 of the offshore support 1 in which the through-flow openings 18 are arranged during pile-driving.

The situation in which the pile attachment 34 is mounted on the stop 32 is shown in Figure 9. Because the pile attachment 34 has a shape that encloses the second part 28 of the offshore support 1 and has such a length that the pile extension piece 34 extends from the stop 32 to at least beyond the third part 30 of the longitudinal hollow body 4, a pile-driving device can transfer its force via the pile-fitting piece 34 to the first part 26 of the support 1.

Preferably, the pile attachment 34 connects substantially closely around the rejuvenating second part 28, ie the flow part with the flow openings 18. For this reason, the pile attachment 34 shows that the second part 28 of the offshore support 1 encloses in the figures 8 and 9 a conical shape.

The embodiments described above, although showing preferred embodiments of the invention, are only intended to illustrate the present invention and not to limit the description of the invention in any way.

When measures in the claims are followed by reference numerals, such reference numerals only serve to contribute to the understanding of the claims, but are in no way restrictive of the scope of protection. In particular, it is noted that a person skilled in the art can combine technical measures of the various embodiments. The rights described are defined by the following claims in the scope of which many modifications are conceivable.

Claims (17)

An offshore support, comprising a longitudinal body, characterized in that the body is provided with at least one passage along its longitudinal length. 2. Offshore support according to claim 1, wherein the body is hollow and comprises a circumferential wall, the passage comprising at least two flow openings in the circumferential wall. 3. Offshore support as claimed in claim 2, wherein the flow openings extend in the longitudinal direction of the longitudinal hollow body, and wherein the flow openings have an elongated slot shape. 4. Offshore support according to claim 2 or 3, wherein one or more than one reinforcement element is provided. 5. Offshore support as claimed in claim 4, wherein the reinforcement element is a reinforcement profile extending in longitudinal direction of the body which is formed by the circumferential wall located between the through-flow openings. 6. Offshore support as claimed in claim 5, wherein recessed wall parts of two adjacent flow openings are connected to the peripheral wall on the sides facing each other, wherein the wall parts are bent towards each other and connected to each other, the wall parts together with the between flow openings circumferential wall enclose the reinforcement profile extending in the longitudinal direction of the body with a substantially triangular cross-section. The offshore support according to any of claims 4-6, wherein the reinforcement element is within a volume enclosed by the longitudinal hollow body. 8. Offshore support as claimed in any of the foregoing claims, wherein the body comprises: - a first part that has a tubular shape; - a second part that forms a flow-through part; and - a third part that has a tubular or ring shape. The offshore support according to claim 8, wherein: the first part has a first diameter; - the third part has a second diameter; and - wherein the first diameter of the first part is larger than the second diameter of the third part, and the flow-through part of the first part rejuvenates in the direction of the third part. 10. Offshore support as claimed in any of the claims 4-9, wherein at least two adjacent reinforcement elements are arranged converging or diverging with respect to each other in the longitudinal length of the body. 11. Offshore support as claimed in any of the claims 4-10, wherein one or more than one reinforcement element extends between two fixing points on the circumferential wall of the body, said fixing points being staggered relative to each other in a circumferential direction of the body. 12. Offshore support as claimed in any of the claims 8-11, wherein the first part is provided with a stop to which a pile-driving attachment can be arranged. 13. Offshore support as claimed in claim 12, wherein the pile attachment has a shape that encloses the second part and has such a length that the pile attachment extends from the stop to at least beyond the third part of the longitudinal hollow body. 14. Offshore support according to claim 12, wherein the part of the pile attachment enclosing the second part of the offshore support has a conical shape. 15. Offshore support according to one of the preceding claims, wherein the at least one passage is arranged near an end of the body. The offshore support according to any of claims 1-15, wherein the offshore support is a monopile. 17. Offshore support according to one of claims 1-15, wherein the offshore support can be placed as an add-on on a monopile.