BE1019908A4 - AVAILABLE OFFSHORE PLATFORM AND METHOD FOR SUPPRESSING LATERAL OSCILLATING MOVEMENTS. - Google Patents

Abstract

The invention relates to a jackable offshore platform. The platform comprises a working deck supported by spud poles and height-adjustable above the water surface, wherein at least one spud pole is provided with passage channels for seawater from an upstream side of the spud pole to a downstream side of the spud pole. The jackable platform can be used at larger water depths than the known platform. The invention also relates to a method for operating a jackable offshore platform in a water mass with a strong current.

Description

Jackable offshore platform and method for suppressing lateral oscillating movements thereof

The invention relates to a jackable platform comprising a working deck supported by spud poles and adjustable in height above the water surface. The invention also relates to a method for operating the platform in a water mass with a strong flow.

A jackable platform of the above type is used for carrying out work at sea. The spud poles which are usually located at the corner points of the working deck of the platform can be raised or lowered with respect to the working deck by jacks provided on the working deck. With the spud poles in the raised position, the platform can thus be easily transported to the location of the work to be performed. Once the platform has been brought to the desired position, the platform is anchored on or in the seabed by lowering the spud poles with the jacks until they are supported on or in the seabed. The working deck is then brought into a position above the water level by means of the jacks, in which the working deck is supported by the spud poles and is free from the water level. If desired, the height of the working deck above the water level can be adjusted by further jacking up the working deck relative to the spud poles (thereby raising the working deck relative to the water level) or lowering it (thereby lowering the working deck relative to the water level). water surface).

It will be clear that a jackable platform of the known type can only be used in relatively shallow waters. The maximum achievable water depth is in fact determined by the spud pile length, which must after all exceed the water depth in order to be able to bring the working deck into different heights with respect to the water level. However, the length of the spud poles is limited by structural considerations. If they are of a more robust construction, for example by increasing the wall thickness, they can become too heavy, making transport of the platform more difficult or more uneconomical.

An object of the present invention is to provide a jackable platform that can be deployed at larger water depths. An additional object of the present invention is to provide a platform that can be used in water masses with a strong flow.

This and other objects are achieved by providing a platform according to the attached main claim. In particular, according to the invention, a jack-up offshore platform is provided, comprising a working deck supported by spud poles and adjustable in height above the water level, wherein at least one spud pole is provided with passage channels for seawater from an upstream side of the spud pole to a downstream side of the spud pole. By providing at least one spud pole of the platform with such feed-through channels according to the invention, it is achieved that the spud poles can have a longer length than is the case in the known platform. This makes it possible to work at locations with a greater water depth. The transit channels are located at least in that part of the spud pole that is supposed to be in the water.

A further advantage of the invented platform is that it can be used for the same known spud length in a water mass with a strong flow, where the known platform can no longer be used in such a flow. Shutting down the work on a platform is very expensive and should therefore be avoided.

Water flowing along the platform spud poles can cause vertebrae on the downstream side of the spud pole. This swirl is periodic and causes oscillating forces in the longitudinal direction of the spud pole (these forces are relatively limited) and in the lateral direction of the spud pole (substantially perpendicular to the spud pole). The lateral forces ensure an oscillating lateral movement of the spud poles and the platform. The frequency of swirl formation is given by:

0) where: ftc = Von Karman or vortex frequency [Hz] D = external diameter of the spud pole [m] V = average velocity of the flow [m / s]

Sn = Strouhal number

The value of the Strouhal number varies slightly with the Reynolds number but is typically about 0.2.

The periodic swirling causes an oscillating lift force on the spud pole in a direction perpendicular to the flow. The maximum force is given by:

(2) where: Fk = Von Karman force [N]

Ck = force coefficient [-] V = average velocity of the flow [m / s] A = projection of the spud pile volume in a plane perpendicular to the flow [m2] p = density of the water [kg / m3] co = 2π * ίκ

These lateral movements in a direction perpendicular to the flow can prevent a strong flow with such a high frequency that they approach the natural frequency of the platform and thus cause problems. By providing a platform according to the invention, the operation of the platform and in particular of the spud poles remains substantially unaffected and lateral oscillating movements of the platform, in particular of the working deck of the platform, in particular also with strong currents suppressed better than is the case with the known platform. When running seawater strikes the spud poles, part of this sea water is admitted to the feed-through channels via the upstream side entrance openings of the feed-through channels, after which this sea water flows into the feed-through channels to the down-stream side of the spud pole and leaves the spud pole along that side through the exit openings of the passage channels. As a result, a turbulent flow is created locally at the exit openings on the downstream side of the spud pole. The created turbulence prevents or prevents swirling, whereby the oscillating movement of the spud pole is also suppressed or prevented.

A further advantage of the invention is that the height adjustment of the working deck relative to the spud poles can take place in substantially the same way as is the case with the known platform. When external swirling devices are applied to the spud poles, these may have to be temporarily removed when raising and lowering the working deck relative to the spud poles, which is cumbersome and may even be dangerous in strong currents. It would be expected that the passage channels for the seawater would weaken the strength and stiffness of the relevant spud pole. However, the passage channels have been found to effectively suppress the oscillating movements of the platform such that the average load on the spud poles can decrease to at least a level corresponding to the bearing capacity of the spud poles provided with the passage channels.

In a preferred embodiment of the platform according to the invention, the at least one spud pole comprises an internal cavity and the passage channels are in communication with the cavity. The seawater is thus admitted to the transit channels via the upstream side entrance openings of the transit channels, after which this seawater ends up in the cavity and is stopped there where additional turbulence can arise (and therefore energy dissipation), after which the seawater leaves the cavity and via the passage channels flows to the downstream side of the spud pole and leaves the spud pole along that side via the exit openings of the passage channels.

In a further preferred embodiment, the cavity comprises an internal obstruction to the seawater passing through the cavity, for example in the form of transverse bulkheads and / or partly perforated transverse bulkheads, and preferably in the form of a cylinder extending with its longitudinal axis in the longitudinal direction of the spud pole. The seawater flowing in the cavity is diverted into the cavity because it must flow around the inner cylinder. This provides additional energy dissipation.

In yet another preferred embodiment of the invention, a platform is provided in which the entrance and exit openings of the passage channels are arranged in a regular pattern in the circumferential direction of the spud pole. Not only are this lateral oscillating movements of the platform better damped, but such a spud pole also appears to be mechanically stronger. Even better results are achieved when the entrance and exit openings of the passage channels are arranged in a regular pattern in the longitudinal direction of the spud pole, and / or when the entrance and exit openings of the passage channels are arranged in a spiral pattern in the spud pole. The angle that the spiral pattern makes with the vertical (the longitudinal direction of the spud pole) can be chosen within wide limits, but is preferably included between 10 ° and 80 °, more preferably between 10 ° and 60 °, and most preferably between 15 ° and 45 °. In the context of the present application, "understood between" is understood to mean a range including the stated end values.

The total surface area of the mantle surface of the spud pole that is occupied by the entrance and exit openings of the passage channels should preferably not be taken too large because the passage channels then occupy a too large part of the spud pole volume and the spud pole is weakened too much. On the other hand, a too small total area may not sufficiently dampen the lateral oscillating movements of the spud pole. Preferably a platform is provided in which the entrance and exit openings of the passage channels have a total surface area that is less than 10% of the jacket surface of the spud pole, more preferably less than 6% and most preferably less than 4%. Preferably, a platform is provided in which the entrance and exit openings of the passage channels have a total area that is greater than 1% of the jacket surface of the spud pole, more preferably greater than 2% and most preferably greater than 3%.

In a preferred embodiment, the platform according to the invention is characterized in that the entrance and / or exit openings of the feed-through channels can be closed. By making at least a portion of the entrance and / or exit openings closable, the vertebral prevention of the spud pole described above can be adjusted in height, which can be important with a variable spud pole length or when the weather conditions - and therefore the strength of the flow - modify. Indeed, the spud pole length will depend on the specific circumstances at the site of the work. Making the entrance and / or exit openings of the feed-through channels closable can be carried out in any known manner, for example by moving slides over the openings. If desired, it is possible to provide all spud poles with feed channels or only a part thereof.

In addition to the feed-through channels, it is also possible to provide the platform, and more particularly its spud poles, with a mass which is connected to the spud pole by means of damping means. Suitable damping means comprise, for example, a spring-damping system which is arranged in or around the spud poles. In the context of the present application, a spring is understood to mean a mechanical device which resists movements. In the context of the present application, a damper is understood to mean a mechanical device which resists movements by means of viscous friction. Dampers generally comprise a cylinder in which the hydraulic fluid is located and in which a piston is movably received.

The invention also relates to a method for operating a jackable offshore platform in a strong mass of water mass, which platform comprises a working deck supported by spud poles and adjustable in height above the water level. In the method according to the invention, at least one spud pole is provided with passage channels for the seawater from an upstream side of the spud pole to a downstream side of the spud pole. The advantages of such a method have already been discussed above in the context of the device and will not be repeated here.

Preferred embodiments of the method of the invention include methods in which one or more spud poles comprise an internal cavity and the passageways are in communication with the cavity; wherein the cavity comprises an internal barrier to the seawater passing through the cavity; wherein the internal barrier comprises a cylinder extending with its longitudinal axis in the longitudinal direction of the spud pole; wherein the entrance and exit openings of the passage channels are arranged in a regular pattern in the circumferential direction of the spud pole; wherein the entrance and exit openings of the passage channels are arranged in a regular pattern in the longitudinal direction of the spud pole; wherein the entrance and exit openings of the passage channels are arranged in a spiral pattern in the spud pole; wherein the entrance and exit openings of the passage channels have a total area that is less than 10% of the jacket surface of the spud pole; and wherein a portion of the input and output openings of the feed-through channels are closed in dependence on the spud pole length and / or the strength of the flow.

The present invention is further elucidated hereinbelow with reference to the accompanying figures without being otherwise limited thereto. In the figures: figure 1 shows a schematic side view of a jackable platform according to the invention; figure 2 shows a schematic top view of an embodiment of a spud pole according to the invention; figure 3 shows a schematic side view of an embodiment of a spud pole according to the invention; figure 4 shows a schematic top view of another embodiment of a spud pole according to the invention; and figure 5 shows a schematic side view of another embodiment of a spud pole according to the invention.

With reference to figure 1, a jackable platform 1 is shown. In the embodiment shown, the jackable platform 1 essentially comprises a working deck 2 and four spud pile jacks 3 (only two of which are visible) at the corner points of the working deck 2. Each jack 3 operates a spud pole 4 which can be lowered in the vertical direction 5 until the relevant spud pole finds support on or in the seabed 6. The working deck 2 is provided, by way of example, with a crane 7 with an arm pivotable in the direction R. For the sake of clarity, a number of structures usually present on a jackable platform have been omitted from the figure. The platform 1 is anchored in the desired position on or in the seabed 6 by lowering the spud poles 4 with the jacks 3 until they are supported on or in the seabed 6. The jacks 3 are then placed in a working deck 2 by means of the jacks 3. position above the water level 8, in which the working deck 2 is supported by the spud poles 4 and is free from the water level 8, as shown in figure 1. The spud poles 4 then run partially under water and protrude for another part above the water level. Depending on the work to be performed and the environmental situation on site, the height of the working deck 2 above the water level 8 is adjusted by further jacking up the working deck 2 relative to the spud poles 4, whereby the working deck 2 is raised relative to the water level 8, or to lower it, whereby the working deck 2 is lowered relative to the water level 8. To anchor the spud poles 4 relative to the jacks 3, the spud poles are optionally provided with insertion openings 9. According to the invention, the spud poles 4 are also provided of seawater passageways (23, 24) from an upstream side of the spud pole 4 to a downstream side of the spud pole 4.

Water flowing along the spud poles 4 of the platform 1 in a flow direction 11 can cause swirls 10 on the downstream side of the spud pole 4 (see Figures 2 and 4). The periodic swirling 10 causes, among other things, oscillating forces in the lateral direction 12 of the spud pole (the direction substantially perpendicular to the flow direction 11). The lateral forces cause an oscillating lateral movement 13 of the spud poles 4 and therefore also of the working deck 2 of the platform 1, which is after all supported by the spud poles 4.

According to the invention, at least one spud pole 4 comprises passage channels (23, 24) for seawater from the upstream side of the spud pole 4 to the downstream side of the spud pole 4. The passage channels (23, 24) help suppress the above-mentioned lateral oscillating movements 13 of the platform 1. In the embodiment shown in Figure 2, the feed-through channels 23 run completely into the wall of the spud pole 4, while avoiding an internal cavity 4a of the spud pole 4. The internal cavity 4a generally extends over the entire length of the spud pole 4, but this is not necessary. When seawater flowing in the direction 11 hits the spud pole 4, a part of this seawater is admitted to the feed-through channels 23 via the upstream openings 23a. The sea water then flows in the feed channels 23 in the direction 20 to the downstream side of the spud pole 4 and leaves the spud pole 4 via the exit openings 23b of the passage channels 23. The sea water is somewhat slowed down in the passage channels 23 and creates at the level of the exit openings 23b a turbulent flow that prevents or prevents the above-mentioned swirling. As a result, the oscillating movement 13 of the spud pole 4 is suppressed or prevented.

Another embodiment of the spud pole 4 is shown in Figure 4. Herein, the spud pole 4 comprises an internal cavity 4a, the passage channels 24 being connected to the cavity 4a. In this embodiment the sea water is admitted to the feed-through channels 24 via the upstream side entrance openings 24a of the feed-through channels 24, whereafter the sea water enters the cavity 4a and is held there where additional turbulence can arise (and thus energy dissipation). The seawater leaves the cavity 4a on the downstream side of the spud pole 4 via the outlet openings 24b of the passage channels 24. An cavity 19 has been incorporated in the cavity 4a with its longitudinal axis extending in the longitudinal direction 5 of the spud pole 4. The seawater flowing into the cavity 4a is bypassed in that it has to flow around the inner cylinder 19 according to the indicated direction of flow 21.

The entrance and exit openings (23a, 23b, 24a, 24b) are preferably closable by closing means (not shown).

With reference to Figure 3, the entrance openings (23a, 24a) and the exit openings (23b, 24b) of the passage channels (23, 24) are preferably arranged in a regular pattern in the circumferential direction of the spud pole 4, and also in the longitudinal direction 5 of the spud pole 4. In the embodiment shown in figure 5, the entrance openings (23a, 24a) and exit openings (23b, 24b) of the passage channels (23, 24) are arranged in a spiral pattern in the spud pole 4. The spiral pattern in the embodiment shown an angle 25 with the vertical 5 of approximately 30 °, but other angles are possible.

The total surface area of the jacket surface of the spud pole 4 occupied by the openings (23a, 23b, 24a, 24b) should be relatively limited and is preferably below 4%, as shown in Figures 3 and 5.

Because the direction of the flow 11 around a spud pole 4 is variable, it may be desirable to pass the passage channels (23, 24) through the spud pole 4 in a number of different directions and / or to make the spud pole 4 rotatable about an axis parallel to each other. runs with the longitudinal direction 5 so that the passage channels (23, 24) run substantially parallel to the direction of flow 11.

With the device described above, it becomes possible to operate a jackable offshore platform in a water mass with a strong current. By using the spud pole 4 with passage channels (23, 24), the lateral oscillating movements of the platform 1 generated by the flow are damped in such a way that less danger arises when working under such conditions. This applies in particular to work at large water depths.

Claims (18)

A jackable offshore platform, comprising a working deck supported by spud poles and height-adjustable above the water surface, wherein at least one spud pole is provided with passage channels for seawater from an upstream side of the spud pole to a downstream side of the spud pole. The platform of claim 1, wherein the at least one spud pole comprises an interior cavity and the passageways are in communication with the cavity. The platform of claim 2, wherein the cavity comprises an internal barrier to the seawater passing through the cavity. 4. Platform as claimed in claim 3, wherein the internal obstruction comprises a cylinder which extends with its longitudinal axis in the longitudinal direction of the spud pole. 5. Platform as claimed in any of the foregoing claims, wherein the entrance and exit openings of the passage channels are arranged in a regular pattern in the circumferential direction of the spud pole. A platform according to any one of the preceding claims, wherein the entrance and exit openings of the passage channels are arranged according to a regular pattern in the longitudinal direction of the spud pole. 7. Platform as claimed in any of the foregoing claims, wherein the entrance and exit openings of the passage channels are arranged in a spiral pattern in the spud pole. A platform according to any one of the preceding claims, wherein the entrance and exit openings of the passage channels have a total area that is less than 10% of the jacket surface of the spud pole. 9. Platform as claimed in any of the foregoing claims, wherein the entrance and exit openings of the passage channels can be closed. 10. Method for operating a jackable offshore platform in a strong mass of water mass, which platform comprises a working deck supported by spud poles and adjustable in height above the water level, wherein at least one spud pole is provided with passage channels for seawater from an upstream side of the spud pole to a downstream side of the spud pole. The method of claim 10, wherein the at least one spud pole comprises an internal cavity and the passageways are in communication with the cavity. The method of claim 11, wherein the cavity comprises an internal barrier to the seawater passing through the cavity. The method of claim 12, wherein the internal barrier comprises a cylinder extending with its longitudinal axis in the longitudinal direction of the spud pole. A method according to any one of claims 10-13, wherein the entrance and exit openings of the passage channels are arranged in a regular pattern in the circumferential direction of the spud pole. A method according to any of claims 10-14, wherein the entrance and exit openings of the passage channels are arranged in a regular pattern in the longitudinal direction of the spud pole. A method according to any one of claims 10-15, wherein the entrance and exit openings of the passage channels are arranged in a spiral pattern in the spud pole. A method according to any one of claims 10-16, wherein the entrance and exit openings of the passage channels have a total area that is less than 10% of the jacket surface of the spud pole. A method according to any one of claims 10-17, wherein a part of the input and output openings of the feed-through channels are closed in dependence on the spud length and / or the strength of the flow.