The invention relates to methods and apparatuses for deploying articles to great depth beneath the sea surface, for example to the seabed in deep waters.
Cranes and winches employing wire rope have been used to deploy loads to the seabed in modest water depth for many years. Some of these cranes and winch systems are fitted with, or used in conjunction with, heave compensators, which take-up and pay out the rope dynamically, to compensate vertical motion (heave) of the ship, barge or other platform from which the rope is supported.
As water depth increases, the weight of wire needed to lower equipment to the seabed increases until it becomes such a significant part of the total load that the method becomes impractical. Man made fibre rope can be almost neutrally buoyant and have strength and elastic characteristics similar to wire rope and is therefore potentially a suitable replacement for wire. Man made fibre rope, however, has a poor tolerance to the fatigue induced by bend cycling under load, and is thus unsuitable for use with current designs of heave compensator or with heave compensated drum winches. The same problem exists for winch systems without heave compensation, although the bend cycling will typically be less severe than in heave-compensated systems. Alternative systems can also be envisaged which do not increase bend cycling for the purpose of heave compensation, but bend cycling for the basic lifting/lowering operation is harder to avoid.
The invention aims to obtain the weight benefits of using fibre rope, while avoiding the need for bend cycling fibre rope under load, when deploying loads from a vessel at sea.
Broadly stated the invention provides equipment and method for lowering equipment to the seabed from a vessel using man made fibre rope and a winch employing wire rope, the fibre rope being paid out (or when lifting, drawn in) in sections by repeated operation of the winch and wire rope.
The fibre rope may be continuous and provided with eyes, stoppers or other attachment points at regular intervals.
The fibre rope may alternatively comprise discrete sections terminated with eyes or other attachment points, connected together to form the required length. In this case, the connections between sections may be made (or un-made) in the course of paying out (drawing in), or the entire length may be connected in advance and reeled during operation.
Each fibre rope section may be terminated by looping around a thimble comprising a body with a peripheral channel for the rope, and two distinct openings, one opening receiving a connection (directly or indirectly) to the next rope sections, the other receiving a connection (directly or indirectly) to the hoist mechanism. In a particular embodiment disclosed in detail below, the second opening receives a bolt which fixes a stopper to the thimble, the stopper being temporarily engaged by the hoist mechanism.
The stopper comprises a part-conical member formed in two halves held together by the bolt. In other arrangements, it can be envisaged that the hoist mechanism engages the thimble directly.
The thimble having two distinct apertures and optionally a stopper permanently attachable thereto is also an independent aspect of the invention, for which novelty is claimed.
The fibre rope may be provided between adjacent rope sections with stoppers engaged and released by a hoist mechanism openable by remote control to engage and release the fibre rope.
In a preferred embodiment, the wire rope is arranged to raise and lower a hoist mechanism, the hoist mechanism being operable by remote control to allow the mechanism to pass freely up and down the rope, and then to engage the rope by means of said stopper.
The fibre rope may be held at a holding means, while the wire rope is detached for connection to a next section. The holding means may be arranged to engage an attachment point between adjacent rope sections but distinct from that engaged by the hoist platform. A pair of collars or other stoppers is sufficient, spaced longitudinally to allow sufficient clearance between hoist mechanism and the holding means.
Preferably the wire rope winch is heave compensated, permitting operation in a wider range of sea states and reducing strain on the components of the apparatus.
The wire rope winch and holding means may both be heave-compensated, such that heave compensation can be maintained throughout the process of transferring the load from one to the other. The holding means and wire rope winch may be heave compensated in parallel by a common heave compensator, for example comprising a hydraulic ram.
The winch and wire rope may be arranged in a double fall arrangement, with the end of the wire rope fixed on board the vessel while a running block is lowered and raised, alternately connected to and disconnected from the fibre rope.
The invention further provides an apparatus comprising a rope store, hoist means and holding means adapted for deployment from a sea-going vessel for implementing a method of raising or lowering according to the invention as set forth above.
The invention further provides a fibre rope assembly comprising plural rope sections and load-bearing stoppers connected between the sections, the rope assembly being adapted for use with a method according to the invention as set forth above.
Embodiments of the invention will now be described, by way of example only, with reference to the accompanying drawings, in which:
General Arrangement
Load 10 is suspended chiefly on a man-made fibre rope 16, made in segments with joints 18 along its length. A drum winch 20 mounted on deck 12 stores sufficient rope 16 for the depth of operation. The length of each segment may be 50 m, 100 m, or 300 m for example.
A hoist platform 22 is suspended over the side of the vessel by a double-drop steel wire 24 a hoist winch 26 provided on deck 12 stores the wire 24. Rope 16 passes through hoist jaws 28 mounted on hoist platform 22, and engages part of a joint 18, such that the weight of the load 10 is carried by hoist platform 22 and will stop the tension caused by the weight of the load is thus not experienced by portions of rope 16 above the level of platform 22.
A hang-off platform 28 is also suspended by wires 30a and 30b hang-off platform 28 carries a latch 32 which can be opened and closed to engage another portion of the joint 18 in rope 16, which passes through an aperture in hang-off platform 28. Hang-off platform 28 acts as a holding means and is arranged to stay at a relatively fixed height in relation to this sea surface, while hoist platform 22, by operation of hoist system winch 26, travels from a level just below hang-off platform 28 to a depth at least corresponding to the length of one segment in fibre rope 16.
Finally in this embodiment,
The arrangement shown in
The various components of the lifting apparatus shown in
Hoist System
As mentioned already, hoist platform 22 is supported in operation by wire rope 24. Three sheaves 48, 50 and 52 are provided on hoist platform 22, for guiding the wire 24 from two points of suspension at either end of the platform around the area of the aperture 40. By this arrangement, vertical load on the jaws 27a, 27b acts substantially on the line between the two portions of wire 24.
Also associated with the hoist system platform and wire rope 24 are hoist winch 20 already mentioned, a strong point 53 on deck 12, first and second sheaves 54 and 56 mounted on the heave compensator cross head 36 and a fixed sheave 58 mounted on the deck. The mounting and bearings of these sheaves are omitted for clarity. The functioning of the hoist will be described later.
Holding Means/Hang-off Platform
Fibre Rope System
In the condition shown, the bulk of rope 16 including joints 18 is wound on the drum of winch 20. Winch 20, serving as a rope store rather than a hoist, is driven to take up and pay out rope 16, though not to lift the weight of load 10. Further sheaves 82 and 84 are mounted respectively on heave compensator cross head 36 and deck 12 to pass the rope 16 from drum winch 20 over the side of the vessel, with heave compensation as required. The flanges of sheaves 82 and 84 are set wide enough to allow free passage of joints 18, it being understood that the portions 16b and 16c of fibre rope 16 are, in operation, not subject to the weight of load 10 to reduce fatigue in the fibre rope as it bends.
Referring to the inset detail 80, each joint 18 in this embodiment comprises a symmetrical arrangement of components, permitting segmented rope 16 to be used without regard to the direction in which it has been wound on drum 20. At the centre of each joint 18 is a circular plate or collar 86, of a size suitable for engagement by the latched 32 of hang-off platform 28 (see detail 46 in
Each stopper 92a, 92b is formed by two halves of steel, clamped to the respective thimble 88a, 88b by a bolt 93. The lower stopper 92a is shown with one half removed, to reveal the form of the thimble 88a. This comprises a solid metal piece, with a channel guiding the rope 16 along path 16′ shown in broken lines. The rope doubles back and is spliced to itself in conventional fashion, the splice extending perhaps 3 or 4 m for security from the thimble. Unlike conventional thimbles, the thimbles 88a and 88b provide two distinct apertures in a solid body. The larger aperture allows passage of the shackle 90a, 90b which connects, via collar 86 and other parts, to the next rope segment. A smaller aperture 91 allows passage of the bolt 93 which, indirectly in this embodiment, allows connection of the rope segment 16a to the hoist platform 22. The body can be formed entirely by casting, or assembled from a split tube and other pieces.
Finally in relation to
Set-up for Lifting and Lowering
Summarising the configuration of the apparatus just described with reference to
The wire 24 is taken from the winch 26 and passed through sheave 58 on the deck. It is then reeved through first sheave 54 on the heave compensator cross head and through a lowerable block in the form of platform 22 and sheaves 48, 50, 52. The standing part is then returned to the ship and reeved through the second sheave 56 on the heave compensator and subsequently made fast to strongpoint 53 on the deck. This provides a heave compensated double-fall lowering (and lifting) system.
As described above with reference to
Man made fibre rope 16 (details in
Lowering Operation
With the complete apparatus constructed and prepared as just described, operation of the apparatus for lowering of a heavy load to the seabed proceeds as will now be described with reference to
By operation of wire winch 26 paying out wire 24, the platform 22 and load 10 are lowered to the maximum depth of the lowering system with the rope 16 attached, thus drawing the rope 16 off the reel 20.
Reaching the position shown in
Referring now to
In this manner the rope is never subjected to more than nominal load while being bend cycled through the winch, sheaves and especially the heave compensator. At the same time, all transfer operations are heave compensated.
Support for the process may be provided by a remotely operated vehicle (ROV) and/or divers, not shown. These may be stationed by the lowest position of the hoist platform 22, for example, where video observation and occasional intervention may be required to ensure reliable engagement and disengagement of the hoist from the rope stoppers 92a etc. Adequate observation may also or alternatively be provided by cameras mounted on the platform 22 and/or 28.
The method can be applied beneficially in oil & gas field development (sub-sea construction) in depths beyond 300 m. General lifting and lowering operations can also be envisaged in depths down to full oceanic depth, for example for Salvage, Oceanography, and Military purposes.
Number | Date | Country | Kind |
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0201540.2 | Jan 2002 | GB | national |
0205251.2 | Mar 2002 | GB | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/GB03/00286 | 1/23/2003 | WO | 00 | 3/8/2005 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO03/062042 | 7/31/2003 | WO | A |
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20050191165 A1 | Sep 2005 | US |