阅读说明：本技术 转塔系泊浮标系统 (Turret mooring buoy system ) 是由 雷诺·达兰 泽维尔·舒特 克里斯蒂安·雷蒙德·鲍都恩 于 2018-06-21 设计创作，主要内容包括：本发明涉及用于将一个或更多立管和锚线可释放地连接至浮动结构的转塔的系泊浮标系统,其中浮标包括：浮标主体,用于承载一个或更多立管,立管延伸到海底碳氢化合物井；多个锚线连接器,用于将多个锚线连接至浮标主体,使得每个锚线的一端连接至连接器中的一个,相对端连接至海底；重新连接缆线,其特征在于,重新连接缆线延伸穿过与浮标主体的中心线重合的通道,并且在一端通过锚线连接区段在浮标主体下方相距锚线连接器一定距离处可连接至锚线中的每个,并且在另一端包括位于锚线连接器可连接的浮标主体的相对侧的挡块和绞盘缆线连接布置。本发明还涉及一种向上拉动一个或更多立管和多个锚线以将立管(3)和锚线(4)可释放地附接至船舶的船体(200)的转塔(150)中的方法。本发明还涉及一种用于构造系泊浮标的方法。(The present invention relates to a mooring buoy system for releasably connecting one or more risers and anchor lines to a turret of a floating structure, wherein the buoy comprises: a buoy body for carrying one or more risers extending to a subsea hydrocarbon well; a plurality of anchor line connectors for connecting a plurality of anchor lines to the buoy body such that one end of each anchor line is connected to one of the connectors and the opposite end is connected to the sea floor; a reconnect cable, characterized in that the reconnect cable extends through a passage coinciding with the centre line of the buoy body and is connectable at one end to each of the anchor lines by an anchor line connection section at a distance below the buoy body from the anchor line connector, and comprises at the other end a stop and winch cable connection arrangement at the opposite side of the buoy body to which the anchor line connector is connectable. The invention also relates to a method in a turret (150) for pulling one or more risers and a plurality of anchor lines upwards for releasably attaching a riser (3) and an anchor line (4) to a hull (200) of a vessel. The invention also relates to a method for constructing a mooring buoy.)

1. Mooring buoy system (100) for releasably connecting one or more risers (3) and anchor lines (4, 9) to a turret of a floating structure, wherein the buoy comprises:

-a buoy body (1) for carrying the one or more risers (3) extending to a subsea hydrocarbon well;

-a plurality of anchor line connectors (5) for connecting a plurality of anchor lines (4, 9) to the buoy body (1) such that one end of each anchor line (4, 9) is connected to one of the connectors (5) and the opposite end of each anchor line is connected to the sea floor; and

-re-connecting the cable(s),

wherein, in an equilibrium state, the buoyancy of the buoy body (1) is equal to the mass of the buoy body plus the suspended weight of the one or more risers (3) and the tension of the anchor line,

wherein the main section (2) of the reconnect cable extends through a passage (8) coinciding with the centre line (C) of the buoy body (1) and is connectable at one end to each of the anchor lines (4, 9) at a distance below the buoy body from the anchor line connector (5) by an anchor line connection section (10) of the reconnect cable, and comprises at the other end a stopper and winch cable connection arrangement (7), the stopper and winch cable connection arrangement (7) being located on the opposite side of the buoy body (1) where the anchor line connector (5) is located.

2. Mooring buoy system (100) according to claim 1, wherein the anchor line connector (5) is at a non-zero radial distance from the centre line (C) of the buoy body (1).

3. A mooring buoy system (100) according to claim 1 or 2, wherein the length of the reconnected cable is such that when the chock and winch cable connection arrangement (7) is in contact with the opposite side of one side of the buoy body (1) where the anchor line connector (5) is connected to an anchor line (4, 9), the reconnected cable anchor line connection section (10) is attached to the respective anchor line (4, 9) at a connection point (6), the anchor line connector section (10) forms slack.

4. A mooring buoy system (100) according to any of the claims 1-3, wherein said reconnect cable is connectable to said anchor line (4, 9) at a distance from the location of connection of said anchor line to said buoy body, such that when said reconnect cable (2) is pulled upwards, the shorter anchor line section (9) as between said connection point (6) and said buoy body releases tension, thereby creating a distance between said dog and winch cable connection arrangement (7) and said buoy body (1).

5. Mooring buoy system (100) according to claim 4, wherein releasing the tension on the anchor line (9) comprises removing anchor line weight from the force counteracting the buoyancy, thereby applying a reduced force on the buoy body (1).

6. A method for pulling up one or more risers and a plurality of anchor lines by means of a mooring buoy system (100) for releasably attaching the risers (3) and anchor lines (4) in a turret (150) of a hull (200) of a vessel, wherein the buoy comprises: a buoy body (1) carrying one or more risers (3) extending to a subsea hydrocarbon well; a plurality of anchor lines (4, 9) having an anchor line connector (5) connected to the buoy body (1) at one end and a seabed connection at the other end; -reconnecting a cable (2) extending through a passage (8) coinciding with the centre line (C) of the buoy body (1) and connected to each of the anchor lines (4, 9) by an anchor line connection section (10) at a connection point (6) at a distance from the anchor line connector (5) and comprising at the other end a stopper and winch cable connection arrangement (7), the stopper and winch cable connection arrangement (7) being located on the opposite side of the buoy body (1) to where the anchor line connector (5) is located, the method comprising the steps of:

-attaching a winch cable (11) from a turret mooring system (150) of the vessel to a reconnecting cable (2) of the mooring buoy system (100) when the buoy is in an equilibrium state where the buoyancy of the buoy body (1) is equal to the mass of the buoy body plus the suspended weight of the one or more risers (3) and the tension of the anchor lines;

-pulling in the winch cable (11) such that the reconnect cable (2) is pulled directly onto the anchor line (4) through the centre of the buoy body (1) such that the section of the anchor line between the reconnect cable connection and the anchor line connector (9) becomes slack, thereby reducing the hanging weight on the buoy body (1);

-reeling in said winch cable (11) such that the anchor line section (9) between said connection point (6) and said anchor line connector (5) remains slack, thereby allowing the buoy body (1) carrying said one or more risers (3) to float upwards using only the buoyancy of the buoy body (1).

7. Method according to claim 6, wherein the reel-in speed of the winch cable (11) directly controls the raising of the buoy.

8. Method for attaching one or more risers (3) into a cavity of a turret (150) of a hull (200) of a vessel by using the method according to claim 6 or 7, the method comprising the steps of:

-pulling the one or more risers (3) upwards, whereby reeling in of a winch cable (11) continues until the buoy body (1) is received in the turret structure (150);

-locking the buoy body (1) within a cavity of the turret structure (150);

-releasing the reconnect cable (2) to make it slack below the buoy body (1), wherein the reconnect cable (2) is connected to the anchor line below the buoy body (1) and slack is removed from the anchor line section (9) between the reconnect cable connection (6) and the anchor line connector (5).

9. Vessel for offshore operations and comprising a turret mooring system, wherein the turret mooring system is connected to an anchor line and one or more risers by a mooring buoy system according to any one of claims 1-5, or wherein the turret mooring system is configured for using the method according to claims 6-8.

10. A method for manufacturing a mooring buoy (100), comprising the steps of:

-providing a buoy body (1) comprising a through channel (8) in the buoy body coinciding with a centre line (C) of the buoy body;

-mounting a plurality of anchor line connectors (5) at lateral sides of the through channel (8);

-mounting one or more riser connectors on a side comprising the anchor line connector (5);

-installing a reconnect cable (2) through the through passage of the buoy body (1), whereby the reconnect cable (2) accommodates a number of cables (10) equal to the number of anchor connectors (5) at the end of the reconnect cable away from the buoy body on the side where the anchor connectors are attached, and a stopper and winch cable connector arrangement (7) is installed at the opposite end of the reconnect cable (2).

11. A method for manufacturing a mooring buoy according to claim 10, further comprising the steps of: -manufacturing the buoy body (1) and providing a through passage (8) in the buoy body coinciding with a centre line (C) of the buoy body.

Technical Field

The present invention relates to a mooring buoy system for releasably connecting one or more risers and mooring lines to a floating structure, such as a vessel, in particular an offshore vessel with an internal or external turret mooring system, and to a method for connecting a mooring line to a floating structure.

Background

The reconnect arrangement typically comprises a reconnect winch cable connected to the buoy. To reconnect the buoy to the turret of the marine vessel, the winch pulls in the winch cable to bring the buoy to the vessel until it is in the final locked position. In this arrangement, the winch cable is designed to withstand an average load corresponding to the average load expected during pulling in of the buoy, which is the increase in suspended weight between the connected draft and the disconnected draft. The suspended weight is the combined weight of the one or more risers and anchor lines depending from the buoyant body. In addition to the main loads, the winches are also subjected to dynamic loads corresponding to the inertial forces caused by the relative movement of the vessel and the buoy. Depending on the maximum reconnecting sea state, dynamic loads can produce gripping loads and very high peak loads on the winch. To reduce these loads, heave compensator systems may be introduced to reduce peak loads and thereby reduce the required winch capacity. The disadvantages of such tools are the complexity of the arrangement and the space/volume required on the turret manifold.

EP 2492183 a1 discloses a disconnectable mooring system. The known system comprises a buoy provided with a conical housing and a corresponding conical buoy receiver on the lower end of the turret structure of the vessel for detachably receiving the buoy member. The mooring system further comprises a plurality of mooring lines for transferring mooring forces, each mooring line having a lower end and an upper end connected to the seabed and the buoy member, respectively. In this publication it is shown that each mooring line comprises a first section and a second section, the second section being connected to the first section at a coupling point and to the buoy member. The length of the second section between said coupling point and its connection to the buoy member is selected such that when the buoy member is received in the buoy receiver and the first section is connected to the turret structure and in a state of transmitting a mooring force, said second section is in a relaxed state not loaded by said mooring force. This arrangement eliminates dynamic loads due to relative movement of the vessel and buoy when mooring the vessel, but it does not eliminate the need to use large capacity winches and/or heave compensation systems during (disconnect) connection operations.

EP 2303680 a2 discloses an alternative disconnectable mooring buoy system. The system comprises: a lifting device placed on the hull and having a cable extending through the cavity to a weight located below the bottom of the vessel; a mooring buoy attached to the cable, the mooring buoy carrying a mooring line connected to the seabed and receivable in the cavity for coupling with the vessel, the mooring buoy comprising a central shaft through which the cable passes, the buoy being movable in relation to the cable in a length direction of the cable, the weight of the buoy being located on the cable at or below the buoy; and a stopper provided on the cable and adapted to engage with the buoy and to prevent relative movement of the buoy and the cable, the stopper being fixed to the cable near an upper end or a lower end of the buoy.

After disconnection from the vessel, a weight added to the buoy will cause the buoy to sink to a certain predetermined depth below the water surface. Raising the buoy towards the vessel is performed via towing a weight suspended from the cable, while allowing the buoy to rise by its own buoyancy towards the cavity for connection. By only lifting the weight suspended from the buoy without exerting a direct pulling force on the buoy, the buoy will rise to the surface due to its own buoyancy as soon as the weight is lifted from the buoy via the towing of the cable connected to the winch on the vessel.

A disadvantage of this system is that due to the weight added to the buoy, a larger buoy will be required in the disconnected state to provide the required buoyancy.

It is an object of the present invention to provide a mooring buoy system in which the effect of dynamic loads on the connection process is eliminated or at least minimized, thereby reducing the required winch size and eliminating the need for a heave compensation system.

A further object of the invention is to simplify and minimize the equipment size required for disconnectable mooring of a floating structure.

Disclosure of Invention

This object is achieved by a mooring buoy system for releasably connecting one or more risers and anchor lines to a turret of a floating structure, wherein the buoy comprises: a buoy body for carrying one or more risers extending to a subsea hydrocarbon well; a plurality of anchor line connectors for connecting a plurality of anchor lines to the buoy body such that one end of each anchor line is connected to one of the plurality of anchor line connectors and the opposite end is connected to the sea floor; reconnect cables, wherein in an equilibrium state the buoyancy of the buoy body (1) is equal to the mass of the buoy body plus the suspended weight of the one or more risers (3) and the tension of the anchor lines, wherein the reconnect cables extend through a passage coinciding with the centre line of the buoy body and the anchor line connection section passing on one end is connectable to each of the anchor lines at a distance below the buoy body from the anchor line connectors and on the other end comprises a stopper and winch cable connection arrangement on the opposite side of the buoy body from the anchor line connectors.

An advantage of this configuration is that when the winch cable is connected to the reconnect cable by the winch cable connection arrangement and the anchor line is connected on the opposite side of the reconnect cable, it will be pulled directly onto the anchor line bypassing the buoy body via the reconnect cable extending through the buoy body. This will create a primary load path, limiting the effect of dynamic loads introduced on the winches due to inertial effects and dynamic amplification caused by vessel-buoy motion.

Furthermore, the present invention uses only a simple buoy body geometry without any additional added weight. This allows the need to keep risers and anchor lines available for reconnecting the buoy using a minimum size at a specific predetermined depth below the water surface.

In one embodiment, the anchor line connections are placed at a non-zero radial distance from the center line of the buoy body. Due to the distributed anchoring load when pulling the buoy onto the anchor lines, ensuring that the anchor lines are connected at the same radial distance results in a good stability of the buoy. In addition, this arrangement provides some clearance between the anchor lines and the reconnecting cable, thereby preventing them from becoming tangled.

In a preferred embodiment, the length of the reconnect cable is such that when the stop and winch cable connection arrangement are in contact on the side opposite to the side of the buoy body to which the anchor line connector is connected, the reconnect cable is slack. This results in a direct load path for the anchoring load to the buoy body when the buoy body is not lifted up to the vessel.

Furthermore, the reconnect cable may be connected to the anchor line at a distance from the anchor line connection to the buoy body, such that upon connection, when the reconnect cable is pulled upwards, the anchor line section between the reconnect cable connection and the buoy body releases tension, thereby creating a distance between the stop and winch cable connection arrangement and the buoy body. The buoy body is movable independently of the winch cable-anchor line within the length of the anchor line slack section. As a result, the dynamic loads introduced on the winches due to inertial effects and dynamic amplification caused by vessel-buoy movements are largely eliminated. The optimal winch capacity may be close to or equal to the required minimum winch capacity corresponding to the average load expected during pulling in of the buoy without the use of a heave compensation system.

When the reconnect cable is connected to the anchor line and under the pulling force of the winch, the anchor line exerts a reduced force on the buoy body. In this case the buoy body only carries the reduced mooring forces and one or more risers and will start floating upwards due to its buoyancy, wherein the rise of the buoy is directly controlled by the pull-in speed of the winch cable.

A preferred method in a turret for releasably attaching risers and anchor lines to a hull of a vessel with pulling one or more risers and anchor lines upwards comprises the steps of:

-attaching winch cables from the turret mooring system of the vessel to reconnecting cables of the mooring buoy system, as described above, so that the buoy is in a state of equilibrium where the buoyancy of the buoy body (1) is equal to the mass of the buoy body plus the suspended weight of the one or more risers (3) and the tension of the anchor lines;

-pulling in the winch cable such that the reconnect cable is pulled directly onto the anchor line through the centre of the buoy body, such that the section of the anchor line between the reconnect cable connection and the anchor line connector becomes slack, thereby reducing the hanging weight on the buoy body;

-continuously reeling in the winch cable at a controllable or predetermined speed such that the anchor line section between the reconnect cable connection and the anchor line connector remains slack, thereby allowing the buoy body carrying the one or more risers to float upwards using only the buoyancy of the buoy body.

The speed at which the winch cable is pulled in thereby directly controls the raising of the buoy.

The following steps may be performed after these steps, forming a method for attaching one or more risers in a turret of a hull of a vessel:

-pulling one or more risers upwards as described above, whereby reeling in of the winch cable continues until the buoy body is received in the turret structure;

-locking the buoy body to the turret structure;

-releasing the reconnecting cable to make slack below the buoy body connected to the anchor line, and removing slack from the anchor line section between the reconnecting cable connection and the anchor line connector (5).

When the vessel is moored, the anchoring forces are directed to the turret through the buoy body. The winch cable can be detached from the reconnect cable to release the winch for other uses on the vessel.

A preferred method of manufacturing a mooring buoy for use in the pull-up and attachment method as described in the previous paragraph comprises the steps of:

-providing a buoy body comprising a through passage coinciding with a centre line of the buoy body;

-mounting a plurality of anchor line connectors at lateral sides of the through-going passage;

-mounting one or more riser connectors at a side comprising the anchor line connectors;

-installing a reconnect cable through the through passage of the buoy body, whereby the reconnect cable accommodates a number of cables equal to the number of anchor connectors at the end of the reconnect cable exiting the buoy body on the side where the anchor connectors are attached, and a stop and winch cable connector arrangement are installed at the opposite end of the reconnect cable. Further, the method may include fabricating a float body including a through passage coincident with a centerline of the float body. The number and size of the parts used to construct this mooring buoy is comparable to the parts used to construct a conventional mooring buoy. The construction method can be completed at similar cost and time due to the minimal modifications required to construct a conventional buoy.

Drawings

The invention will be explained in more detail below with reference to the drawings, in which illustrative embodiments of the invention are shown. The drawings are intended for illustrative purposes only and are not intended to limit the inventive concepts. The scope of the invention is limited only by the definitions presented in the appended claims.

Fig. 1 shows a cross section of a mooring buoy system in a submerged equilibrium state;

fig. 2 shows a cross section of a mooring buoy system in a buoy lifted state;

fig. 3 shows a cross section of a mooring buoy system with the buoy finally raised before the connected state;

fig. 4 shows a cross section of the mooring buoy system in a connected state;

fig. 5 shows a cross-section of a vessel for offshore operations, the vessel comprising a turret mooring system moored using a mooring buoy system.

Detailed Description

Fig. 1 shows a cross section of a mooring buoy system in a balanced state, wherein the mooring buoy 100 comprises a buoy body 1, an anchor line connector 5 and a reconnecting line. The reconnecting cable includes: the main reconnect cable section 2, the reconnect cable anchor line connecting section 10 on one end thereof and the stop and winch cable connection arrangement 7 on the other end thereof. The float body 1 includes: a passage 8, extending along the centre line C, provides a through cavity through the buoy body 1 from the top side to the bottom side. The reconnect cable extends through this passage 8 so that the stop and winch cable connection arrangement 7 is located on the top side of the buoy body 1, while the anchor line connection section 10 is located at a distance from the bottom side of the buoy body 1.

Furthermore, the mooring buoy 100 is connected to one or more risers 3 and to an anchor line at an anchor line connector 5. Each anchor line comprises: the main anchor line section 4 is connected at one end to a shorter anchor line section 9. The anchor line may be a cable, wire or chain made of metal and/or polymer or a combination thereof.

One or more risers 3 are connected to the buoy body 1 at the bottom side.

The anchor line connection 5 is placed at a non-zero radial distance from the centre line C of the buoy body 1 on the same side, i.e. bottom side, as the one or more risers. This ensures that the reconnect cable anchor connecting section 10 of the reconnect cable does not become tangled with the main reconnect cable 2, the anchor line or the one or more risers 3. The anchor line connector 5 and riser connector are sufficiently spaced apart and at a sufficient distance from the centerline C where the main reconnect cable 2 is located.

The anchor line is connected to the buoy body 1 at the anchor line connector by the free end of the shorter anchor line section 9.

At a distance below the buoy body 1, the free end of the anchor line connection section 10 of the reconnected cable is attached to the anchor line at a connection point 6 where the main anchor line section 4 is connected to the shorter anchor line section 9. The non-zero radial placement of the anchor line connectors from the centre line C ensures that the anchor line connection section 10 of the reconnected cable and the shorter anchor line section 9 work in such a way that either line carries most or preferably all of the tension from the anchor line.

In this state of equilibrium, the re-connecting cable stop and winch cable connection arrangement 7 rests on top of the buoy body 1 such that the main re-connecting cable section 2 extends a distance below the buoy body 1. The reconnect cable anchor line connecting section 10 is slack so that all mooring line loads pass through the anchor line main section 4 and the shorter section 9. Equilibrium exists because the buoyancy of the buoy body 1 is equal to the buoy body mass plus the suspended weight of the one or more risers 3 and the tension of the anchor lines.

Fig. 2 shows a cross section of the mooring buoy system in a buoy lifted state. In this state, the winch cable 11 is connected to the chock and winch cable connection arrangement 7 of the mooring buoy 100 of fig. 1. The engagement of the winch cable 11 releases the stop and winch cable connection arrangement 7 from the top of the buoy body 1, the main reconnect cable section 2 displaces itself along the centre line C relative to the passage 8 of the buoy body 1, so that the reconnect cable anchor line connection section 10 on the opposite side of the buoy body 1 is tensioned, and the shorter anchor line section 9 above the pull-up line connection is released. As a result, the anchor line weight is removed from the force counteracting the buoyancy of the buoy body 1, thereby causing the mooring buoy 100 to naturally rise to the surface.

Reeling in the winch cable at a speed equal to the lifting speed of the buoy ensures that the shorter anchor line section 9 remains slack so that any heave motions of the mooring buoy 100 caused by vessel motions during the lifted state are not affected by the winch cable 11. As a result, the motions of the mooring buoy 100 and the vessel operating the winch are decoupled and therefore the winch is no longer subject to inertial and dynamic loads, allowing a safe connection in high sea conditions.

Fig. 3 shows a cross section of the mooring buoy system with the buoy finally raised before being in the connected state. Before reaching the waterline WL, the mooring buoy 100 reaches into the cavity 110 of the turret 150, which houses the winch 12 reeled in the winch cable 11. As long as the winch cables 11 remain engaged, the mooring buoy 100 remains in a raised state, exerting a pulling up force on the one or more risers 3, and the mooring buoy's raising movement is stopped only by the turret 150.

The buoy body 1 is then locked in the cavity 110 of the turret 150 and the pulling of the winch cable 11 is released from the stop and winch cable connection arrangement 7.

The resulting state is shown in fig. 4, which shows a cross section of the mooring buoy system, wherein the mooring buoy 100 is in a connected state with the vessel 200. The stop and winch cable connection arrangement 7 rests on top of the buoy body 1, which again causes the main reconnect cable section 2 to extend a distance below the buoy body 1 and the reconnect cable anchor line connection section 10 to become slack. As a result, all mooring line loads pass through the anchor line main section 4 and the shorter line section 9. The buoyancy of the buoy body 1 is less than the downward pull caused by the suspended weight of the anchor lines and risers 3, thereby transferring the combined anchoring load to the turret 150.

Fig. 5 shows a cross-section of a part of a vessel 200 for offshore operations, and the vessel comprises a turret mooring system, wherein the turret mooring system is connected to an anchor line and one or more risers by means of a mooring buoy system.

The invention has been described with reference to the preferred embodiments. Obvious modifications and alterations will occur to others upon reading and understanding the preceding detailed description. It is intended that the invention be construed as including all such modifications and alterations insofar as they come within the scope of the appended claims.