RU2549301C2 - Drilling ship with two drilling centres - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: group of inventions relates to shelf drilling. A drilling ship includes the first drilling centre including a storage for the first marine risers, the second drilling centre for drilling of the second well from the same ship, which includes a storage for the second marine risers. The latter have a diameter that is smaller than that of the first marine risers. The ship includes two blowout preventers for the second drilling centre. A drilling method provides for creation of a drilling ship with two separating and different drilling centres, each of which is capable of well drilling; provision of marine risers for each drilling centre; diameter of marine risers for one of the drilling centres is smaller than that of marine risers for the second drilling centre; provision of two blowout preventers according to the smaller diameter of a marine riser of an auxiliary drilling centre.

EFFECT: providing drilling of a well from one ship from two different drilling centres, and namely under arctic conditions.

19 cl, 5 dwg

Description

FIELD OF THE INVENTION

In General, the present invention relates to offshore drilling operations.

State of the art

Offshore drilling operations can be carried out using a number of different drilling platforms that can be attached to the bottom of the sea. Platforms of this type can be effective when drilling at relatively shallow depths. At deeper depths, however, it is advisable to use ships or semi-submersible drilling rigs to conduct such deepwater drilling operations.

Such vessels or installations can be installed exactly at the desired location, so that with the help of a drill, drill wells exactly at the desired location. With dynamic positioning, the position of the vessel or rig can be maintained even in critical marine conditions. As used herein, the term “ship” means any floating platform that can move independently, pushed, pulled, or towed. It includes semi-submersible drilling rigs and self-propelled vessels.

Thus, several exploratory wells can be drilled one after another in conditions of deep sea drilling, for example, on the continental shelf of the United States, Africa, Asia or Western Europe. However, a large number of operations that must be carried out in the successful drilling of a number of exploratory wells even in the same area can be associated with extremely time-consuming due to the complexity of the operations of deep-sea drilling.

Having a conventional vessel with one drilling platform, it is impossible to perform several drilling operations at the same time. Thus, the time periods required to complete each well can be quite long. Since, as a rule, these drilling vessels are operated on lease terms, the more time is required to drill one well, the more expensive it is.

The so-called drilling vessels with two drilling centers are known. On such vessels, two drilling rigs may be installed; the vessel thus serves as a supporting structure for the drill pipes located below. Double drilling towers can be operated to a certain extent in parallel. For example, while one operation is being conducted on one tower, another operation may be conducted on another tower. However, in any case, only one well can be drilled, only one drilling center can be used for drilling, while the other must be used to support the drilling of a single well.

Brief Description of the Drawings

Figure 1 presents a plan view of a drilling vessel in accordance with one possible embodiment of the invention.

Figure 2 shows a side view of the vessel shown in figure 1 in accordance with one of the possible embodiments of the invention.

Figure 3 presents a schematic representation of a drilling operation from one drilling center on the vessel shown in Figure 2, in accordance with one possible embodiment of the invention.

Figure 4 presents a schematic illustration of a drilling process from a second drilling center in accordance with one possible embodiment of the invention.

Figure 5 presents a diagram of the disconnection of the main drilling center from the wellhead in case of failure, in accordance with one possible embodiment of the invention.

The implementation of the invention

As shown in FIG. 1, a double drilling vessel 10 for drilling operations may be a vessel capable of performing drilling operations in deep and super deep waters. Vessel 10 may also be a semi-submersible drilling rig. This vessel can be equipped with conventional means of dynamic positioning, allowing accurate positioning of the vessel in the desired location. In addition, during drilling operations, the vessel can be held exactly in the desired position using computer control.

In some embodiments of the invention, the vessel may be equipped with a main drilling center 14 (OBC) and an auxiliary drilling center 12 (WBC). With the help of each of the aforementioned drilling centers, it is possible to carry out descent of water separation columns. In some embodiments of the invention, the main drilling center 14 is used for basic drilling operations. In the event of a failure, the main drilling center can be disconnected, the vessel can be moved to the position corresponding to the location of the auxiliary drilling center 12, and the water separating columns can be lowered from the auxiliary drilling center in order to drill a discharge well due to the inability to conduct a drilling operation from the main drilling center.

The described drilling vessels for drilling operations can have a wide range of applications. For example, during drilling operations in arctic conditions, as a rule, it is desirable to have a backup drilling vessel at the place of work. In this case, if there is a problem on the main drilling vessel, an auxiliary drilling vessel may come into operation. But, given the cost of drilling vessels, the presence of two vessels at the place of work is extremely expensive. In accordance with some embodiments of the present invention, a single drilling vessel can perform the same tasks as two drilling vessels that were previously required. It should be noted that ordinary drilling vessels for drilling operations cannot drill two wells from two different drilling centers, and the descent of water separation columns for offshore drilling from two different drilling centers is impossible.

In one embodiment, the primary and secondary drill centers may be mounted on hydraulic rams. In other embodiments, towers or deck towers may be provided. Such towers or towers can serve as a supporting structure to support pipe elements hanging from these towers.

Conversely, when using hydraulic lifts, the well pipe system can be supported directly from the deck of the vessel. This eliminates the need for expensive heavy towers to support the pipe system. However, in some embodiments of the invention, even a hydraulic system, masts or rails can be used to control the pipe system when they are in the raised position.

Thus, depending on the type of centers 12 and 14, various tube storage devices can be used. For example, when using a tower system, towers should be strong enough so that the pipes can be stored simply by leaning them against the inside of the tower. In other cases, pipe storage systems, rear-mounted skeletons and tube magazines may be used to hold assembled or partially assembled pipes.

As shown in FIG. 1, according to one possible embodiment, pipe shops 30 and 32 may be provided for the auxiliary drilling center 12, and pipe shops 34 and 36 for the main drilling center 14. The pipe shops 34 and 36 may comprise various pipe elements, including water separation columns. Similarly, pipe shops 30 and 32 associated with the auxiliary drilling center can also serve to store various pipe elements, including water separation columns. However, in some embodiments, the risers used in the auxiliary drilling center may have a smaller diameter in order to reduce the overall load on the vessel, while still providing full drilling capability with the auxiliary drilling center.

For example, a conventional water separator for drilling can have a nominal diameter of 21¼ inches (53.975 cm), while water separators stored in pipe shops 30 and 32 belonging to the auxiliary drilling center can have a smaller diameter, for example 13⅝ inches (34, 6075 cm) (water separation columns for a pressure of 10,000 psi (68.95 MPa)).

Despite the fact that, as shown in FIG. 2, pipe shops 32 and 36 are located on the left of the drill centers 12 and 14, in some possible embodiments, these pipe shops can be in front or behind, and also to the right of the drill centers. In addition, as indicated above, in some embodiments of the invention, individual tube magazines may not be needed, and if possible, the tube elements can be stored simply leaning against the inner surface of the drill centers 12 and 14.

Conventional drilling equipment can be used to move, lower, remove, lift or rotate pipes to the seabed or ultimately to the bottom of the sea. At the same time, waste, hydraulic swivels, pulleys, drawworks, rotary tables, hoist blocks, pitching compensators, hydraulic drives or any other known equipment can be used. The hydraulic drive can support the pipes on the deck, but the towers can hold the pipes above the deck. The present invention is in no way limited to any particular equipment.

As shown in FIG. 3, the main drilling center 14 includes tensioners 22 of the riser. It also includes a water separation column 24, which in one of the possible embodiments is a conventional water separation column, the nominal external diameter of which, as a rule, is 21¼ inches (53.975 cm). In the lower part of the water separation column 24, a mechanical blocking emergency disconnector 25 of the water separation column may be provided. To the disconnector 25, a bottom riser sealing device (LMRP) 26a may be connected. The bottom sealing device 26a of the riser serves to disconnect a blowout preventer (PVP) 26 connected to the bottom sealing device 26a of the riser using a brittle joint. Finally, in one possible embodiment, the PVP 26 may be a standard underwater PVP with an inner diameter of 18¾ inches (47.625 cm).

The bottom sealing device 27 of the riser is connected to a blowout preventer 26 (PP) so that the elements above can be disconnected from the underwater disconnecting device (SSA) 27 below. In one embodiment, the underwater disconnecting device 27 may include control means, independent of the control means of the PVP 26. In one embodiment, the underwater disconnect device may be a standard device with an inner diameter of 18 ¾ inch (47.625 cm).

Finally, the subsea wellhead 28 may be cemented in the seabed. In some embodiments, a given subsea wellhead may be standard wellhead equipment with an internal diameter of 18¾ inches (47.625 cm).

Thus, the wellhead 28 can be installed from the main drilling center 14, and in the absence of any problems, the auxiliary drilling center 12 may not be needed. However, in some embodiments of the invention, parallel drilling operations can be performed, so that pipes can be prepared in advance from the auxiliary drilling center 12 in order to simplify the drilling process at the main drilling center 14. In other embodiments, the auxiliary drilling center 12 is used only as a backup in case of occurrence of failure associated with the main drilling center 14.

As shown in FIG. 4, when the auxiliary drilling center 12 is activated, a blowout preventer with a thin high-pressure separation tower 40 provides a drilling process for the discharge well from the auxiliary drilling center 12. This can be useful in the event of a failure in the main drilling center when the main drilling center the center can no longer work. For safety reasons, it may be desirable to set up a discharge well as quickly as possible. However, in some embodiments, the presence of a second drilling vessel is no longer necessary since only one drilling vessel can perform the above task.

The previously mentioned riser tensioners 38 may be permanently mounted on the auxiliary drilling center 12. An upper blowout preventer 39 may be provided. In one embodiment, the PVP 39 may be a blowout preventer with an internal diameter of 13⅜ inches (33.9725 cm). The water separation column 40 may be a smaller diameter column designed for a pressure of 10,000 psi (68.95 MPa), in one embodiment, with an internal diameter of 13⅜ inches (33.9725 cm). Since the water separation column 40 has a smaller diameter, in some embodiments it is easier to transport it on the same vessel together with the water separation column 24 without overloading the vessel.

A bottom riser sealing device 42a is used to disconnect the riser 40 from the lower blowout preventer 42. In one embodiment, the lower blowout preventer 42 may be a standard PVP with an internal diameter of 13⅜ inches (33.9725 cm). A submarine wellhead 28 with a thin inner diameter may be cemented in the seabed. In one embodiment, the inner diameter of a given underwater estuary may be 13⅜ inches (33.9725 cm).

One of the possible applications of the vessel 10 may be a situation when there is an initial free exit, including the flow of hydrocarbons through the main drilling center 14a, and the well is closed using shut-off elements on an independently controlled underwater disconnecting device 27. In this worst case, the water separation column 24 cannot be disconnected from the blowout preventer 26 due to a complete failure of the control cable and acoustic disconnector on the PVP 26, as well as an independent disconnector lower sealing arrangement 27a is between the water separation column 26 and PVP underwater trip device 27. In this situation, it is necessary to make disconnection water separation column 24 immediately above the lower sealing device 26a by activation of a mechanical emergency locking otsoedinitelya 25 as shown in Figure 5. The situation shown in FIG. 5 is one example where drilling of a discharge well is required to control the internal pressure of the well or to control the uncontrolled release of hydrocarbons under conditions of underwater drilling due to gushing.

Thus, as shown in FIG. 4, the unloading well can be drilled using the same vessel 10. First, the drilling vessel 10 is moved so as to place the auxiliary drilling center 12 above the location of the unloading well. Then, the unloading well is drilled using the auxiliary drilling center 12. When the guide string and conductor are lowered and cemented, the underwater blowout preventer and water separation string can be lowered in the configuration shown in FIG. 4. Then, the suspension of the underwater blowout preventer and the water separation column, the tension of the tensioning devices 38 and the extension of the telescopic joints to the auxiliary drilling center 12 can be performed. Then, the discharge well is drilled using the auxiliary drilling center 12.

In some embodiments of the invention, the primary and secondary drilling centers may each provide a 5000 ft (1524 m) water separation column. This length of water separation column is sufficient for drilling in many offshore regions, including the Arctic, where the maximum depth is about 3,500 feet (1,066.8 m).

In this description, any reference to “one possible embodiment of the invention” or “embodiment” means that this particular distinguishing feature, design or characteristic described in connection with this embodiment is used in at least one embodiment of the present invention. Thus, the use of the expressions “possible embodiment” or “in one of the possible embodiments” is not mandatory in relation to the same embodiment. In addition, specific features, designs, or characteristics may be used in other suitable embodiments of the invention besides this particular embodiment of the invention, and all such embodiments are covered by the claims below.

Although the present invention has been described with respect to a limited number of embodiments, other various possible modifications and embodiments of the present invention will be apparent to those skilled in the art. It is intended that the appended claims cover all such modifications and variations encompassed by the true spirit and scope of this invention.

Claims (19)

1. The method of drilling, providing
creation of a drilling vessel with two separate and different drilling centers, each of which is capable of performing well drilling; and
providing water separation columns for each of said drilling centers, the diameter of water separation columns for one of the drilling centers being less than the diameter of water separation columns for the second of said drilling centers, and including
providing two blowout preventers in accordance with the smaller diameter of the water separation column of the auxiliary drilling center. 2. The method according to claim 1, comprising providing a storage location for water separation columns for each of these drilling centers. 3. The method according to claim 1, which includes providing the equipment necessary for drilling an unloading well from the same vessel from which the failed well was drilled. 4. The method according to claim 3, including the permanent installation of the tension devices of the riser at the aforementioned auxiliary drilling center. 5. The method according to claim 1, including connecting the water separation columns to the lower blowout preventer using the lower sealing device of the water separation column. 6. The method according to claim 5, comprising providing an upper blowout preventer between said tensioner and said water separation columns. 7. The method according to claim 1, comprising providing a bottom sealing device for a water separation column between a blowout preventer at said auxiliary drilling center and said water separation columns. 8. The method according to claim 1, which includes providing a mechanical interlocking emergency disconnector at the drilling center with a large diameter of water separation columns. 9. The method of claim 8, including connecting the disconnector to the bottom sealing device of the riser. 10. The method according to claim 1, which includes providing an underwater disconnecting device for a drilling center with a large diameter of water separation columns. 11. A drilling vessel containing:
a first drilling center including storage for storing the first water separation columns;
a second drilling center for drilling a second well from the same vessel, including a storage for storing second water separation columns, said second water separation columns having a smaller diameter than the first water separation columns,
the vessel contains two blowout preventers for said second drilling center. 12. The ship according to claim 11, providing the possibility of drilling an unloading well from said second auxiliary drilling center in the event of a failure of a well drilled from the first drilling center. 13. The vessel according to item 12, containing the tension device of the water separation column, permanently mounted on the specified second drilling center. 14. The vessel according to item 12, containing a lower blowout preventer connected to the water separation columns using the lower sealing device of the water separation column. 15. The ship of claim 14, comprising an upper blowout preventer between said tensioner and said water separation columns. 16. The vessel according to item 12, containing the lower sealing device of the water separation column between the blowout preventer at the specified second drilling center and the specified water separation columns. 17. The ship according to claim 11, containing a mechanical interlocking emergency disconnect at the second drilling center. 18. The ship according to 17, containing the specified disconnector connected to the lower sealing device of the water separation column. 19. The vessel according to claim 11, in which the specified second drilling center includes two blowout preventers, and the specified first drilling center includes only one blowout preventer.

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