The invention is generally related to the disconnection of moored floating offshore structures from mooring buoys while under environmental loads.
In the offshore industry of drilling for and producing oil and natural gas, bottom founded and floating moored structures are used. There are times when floating structures that are moored in place must be released from their moorings and moved due to high environmental forces such as sea ice or storms such as hurricanes.
When it becomes necessary to disconnect a floating structure due to the eminent danger of high environmental forces it is preferable that the mooring arrangements remain intact for reattachment at a later time.
Current existing and proposed arrangements for disconnecting a floating structure from their mooring arrangements are based on two basic approaches.
One approach is to disconnect each mooring line individually. This can result in the individual lines becoming entangled. The mooring arrangement must then be recovered and reinstalled line-by-line. The risks associated with this approach are 1) recoil of the mooring lines when released under tension striking and causing damage to the floating structure and 2) being very time consuming to recover each line and reconnect individually. This approach is especially not practical in ice covered waters.
A second approach is the use of a buoy that supports a mooring spread and keeps all lines attached to the disconnected buoy for subsequent reconnection as a group. This approach is typically based on a conical shaped buoy arrangement that drops away from the floating structure and facilitates all of the mooring lines remaining connected to the disconnected buoy, This keeps the lines together in a group, as compared to individual line disconnect, but the height of the buoy being released is constrained by the beam dimension of the floating vessel being released. This can result in a longer time duration for the buoy to clear the disconnected floating structure.
The objectives of mooring systems that may he disconnected for this purpose are a quick release and quickly increasing the distance between the mooring and the floating offshore structure.
In general, the risks or problems that occur with these disconnectable arrangements are 1) binding between the mooring and floating structure when the mechanism is expected to release and 2) contact interaction between the mooring and floating structure that results in damage to one or both structures after the mooring system is released.
Binding may occur because the surfaces that are supposed to separate have been in contact for a number of years prior to the first disconnect attempt. The two bodies can he forced apart by mechanical devices, but these devices must be released as soon as separation occurs to prevent damage to the releasing device. Another major risk is that, due to the two bodies moving independently after release, but still in the same proximity, they can collide causing damage to one or both structures.
When the release mechanism is based on a conical buoy supporting the moorings, lower profiles of the buoy facilitate a quicker release and clearance growth. The load from the floating structure is transferred to the mooring arrangement through the contact area between the floating structure and the buoy. For a given design load, this area will be the same for any buoy shape. This area can be developed by making the disconnectable buoy high with a relatively small diameter (
Therefore, it can be seen there is a need for an improved means of releasing a floating offshore structure from its mooring while under environmental loads.
The present invention addresses the above need and is drawn to a mooring disconnect arrangement for a floating offshore structure and a mooring buoy. At least one high pressure water jet is positioned to direct water between the floating offshore structure and the mooring buoy. The floating offshore structure and mooring buoy are also provided with specially shaped complementary surfaces to assist in disconnection and separation. One or more mechanical restraining devices may be used to retain the floating offshore structure and mooring buoy connected together during normal drilling or production operations.
The various features of novelty which characterize the invention are pointed out with particularity in the claims annexed to and forming part of this disclosure. For a better understanding of the present invention, and the operating advantages attained by its use, reference is made to the accompanying drawings and descriptive matter, forming a part of this disclosure, in which a preferred embodiment of the invention is illustrated.
In the accompanying drawings, forming a part of this specification, and in which reference numerals shown in the drawings designate like or corresponding parts throughout the same:
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It should be understood that only the lower portion of the floating offshore structure 16 is shown which is normally well below the surface of the water. Thus, the water surface is not shown in relation to the invention and it is to be understood that the connection and disconnection sequences happen below the water surface.
The water jets 12 are preferably provided on the hull of the floating offshore structure 16. The water capacity and pressure, number of water jets 12, and spacing between the water jets 12 is determined by the size of the floating offshore structure 16 and mooring buoy 18.
During normal offshore operations of drilling for or producing oil and natural gas, mechanical connection or restraining devices 20 are used to restrain the floating offshore structure 16 and mooring buoy 18 locked together. Any suitable connection devices such as hydraulic rams or rack and pinion jacking arrangements may be used as the mechanical connection devices 20.
Ballasting force may also be used to force the floating offshore structure and mooring buoy together.
A downward facing cone shape 22 on the floating offshore structure 16 is preferably used in conjunction with a complementary shape 24 on the mooring buoy 18 for receiving the cone shape 22. As seen in the drawings, the cone shape 22 and its complementary shaped receiver 24 are preferably designed to have a low profile height that is less than currently existing designs.
In operation, the floating offshore structure 16 and mooring buoy 18 are held together during drilling or production operations by mechanical restraining devices 20. When environmental forces cause the need to disconnect, the mechanical restraining devices 20 are released and high pressure water jets 12 are activated to help initiate separation of the floating offshore structure 16 from the mooring buoy 18.
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The invention provides several advantages over the previously used means of disconnecting the mooring system.
It allows a floating structure to be disconnected from the mooring while under environmental loads, such as sea ice, and the upper section of the floating structure to be removed from the continued threat while keeping the mooring arrangement intact for reattachment to the floating structure.
The invention solves the problem of binding and maintains a safe distance between the floating structure and the buoy supporting the mooring arrangement.
The invention facilitates a quicker release than the prior art and thus reduces the risk of damage to the offshore structure and mooring due to contact during the release.
The method of release of the invention helps to prevent binding between the buoy carrying the mooring lines and the floating structure.
While specific embodiments and/or details of the invention have been shown and described above to illustrate the application of the principles of the invention, it is understood that this invention may be embodied as more fully described in the claims, or as otherwise known by those skilled in the art (including any and all equivalents), without departing from such principles.