The invention relates to a drilling vessel and a method for operating a drilling vessel adapted to run large diameter casing strings.
In the drilling of boreholes in the earth such as for the production of oil and gas, it is normal practice to run a string of casing into the borehole so as to line the borehole. This primarily is to prevent caving of the borehole walls, and to prevent fluid in formations other than the productive formation from entering a string of casing, and to form a vertical passage through which to produce the desired fluid.
Normally wellbores for well and gas wells have a larger diameter casing portion at the upper end that will be cased by a first string of casing. One or more strings of casing are subsequently installed with each string of casing being smaller in diameter.
The first string of casing in a subsea well may be as large as 60 inch (152 cm) in diameter, generally between 20 inch and 60 inch (51-152 cm), in particular between 36-42 inch (91-107 cm), which may be referred to as a drive pipe or structural pile or conductor pipe or conductor casing. Typically, the first casing string is installed into the seabed to a depth of about 100-500 feet (30-152 meters).
Subsequently, surface casing is installed, having a diameter between 20-22 inch (51-56 cm). Surface casing can run several thousand feet in length. Hereafter, in some wells, protection or intermediate casing having a diameter between 7-14 inch (18-36 cm) is run to separate challenging areas or problem zones, including areas of high pressure or lost circulation.
The last type of casing string that is run into the well, and therefore the smallest in diameter, is the production casing having a diameter between 4-10 inch (10-25 cm), also referred to as an oil string. The oil string is run directly into the producing reservoir.
Casing is fabricated in sections, or joints, that are usually about 40 feet (12 meter) long. Casing joints are connected, e.g. screwed or welded together, to form longer lengths of casing, called casing strings.
Commonly, casing joints are transported by a drilling vessel to a location above the borehole. For example WO2009/102196 discloses mono-hull vessel having a hull and a pipe storage hold within the hull. It is explained that references to pipes should be understood as tubular goods normally required in off-shore drilling operations, such as drill pipes, riser pipes and casing pipes.
In WO2009/102196 a gantry crane is provided to raise and lower the pipe sections out of and into the storage hold and to place each individual pipe section onto a riser catwalk machine or to pick up a pipe section from the catwalk machine. The leading end of the pipe section is in practice connected to a lifting tool which connects the pipe section to a hoisting device of the vessel. By raising the lifting tool and operation of the catwalk machine the pipe section is brought into a vertical orientation, or upended, in line with a firing line along which the pipe is suspended into the sea. The already launched portion of the pipe string is then temporarily held by a pipe string hanger of the vessel. The new pipe section is then held in alignment above the launched pipe string and the pipes are interconnected to join the new pipe section to the pipe string. Then the pipe string is released by the pipe string hanger and lowered over the length of the newly attached section. The pipe string is then suspended again from the pipe string hanger and the process of joining a new pipe section is repeated.
Similar processes in which casing joints are lowered and connected to each other one-by-one are common practice.
It has been found that this known process to assemble a casing string is time-consuming. This is in particular a problem in areas having strong underwater currents, acting upon the suspended casing string while other casing joints are being joined to the casing string.
The present invention aims to propose a vessel and method that allows for improvements over the known approach, in view of pace with which a surface casing string can be assembled, as well as in view of the actual storing and/or handling of surface casing joints on board a vessel.
The invention proposes a drilling vessel and a method for operating such drilling vessel, adapted to run large diameter surface casing strings having a diameter of over 20 inch (51 cm).
It is noted that although the claims refer to the specific term ‘surface casing’, a skilled person will understand that the vessel and method of the invention are adapted to run any large diameter casing having a diameter of over 20 inch, also if such large diameter casing is otherwise referred to, e.g. as drive pipe or structural pile or conductor pipe or conductor casing.
A drilling vessel according to the invention comprises:
According to the invention a surface casing stand storage is provided on the main deck for storing multiple pre-assembled casing stands in a substantially horizontal position. E.g. at least 10 pre-assembled casing stands, each pre-assembled casing stand being assembled from multiple interconnected casing sections. For example, and as preferred, each casing stand consists of three or four surface casing sections.
The invention is based on the insight that the storage of pre-assembled surface casing stands in horizontal orientation allows to make up the connection between the surface casing joints that form a surface casing stand at an early stage. This approach greatly reduces, e.g. by a factor two, the amount of work to be done in the firing line when actually assembling a casing string, and thus significantly reduces time for deployment of a casing string.
The reduced time for deployment of a casing string for example reduces the risk of damage to the casing string during deployment in turbulent waters.
The horizontal storage of surface casing stands is advantageous compared to any vertical storage of pre-assembled casing stands in view of the stability of the stored casing stand, in particular in view of the large diameter and consequent large weight of the surface casing, and in view of vessel stability, in particular when the invention is implemented in a mono-hull vessel. Moreover, in view of the large diameter of the surface casing stands, vertical storage is difficult in conventional set-back or fingerboard facilities.
In embodiments, the tower is a mast and the firing line is provided parallel to and outside of a first side of the mast. Advantageously, a second hoisting device is supported by the mast and a load attachment device is displaceable along a second firing line, which extends on the outside of and adjacent to the second side of the mast, opposite the first side, wherein preferably drilling operations are performed along the second firing line. Such so-called ‘multiple firing hoist systems’ have been extensively described in previous patent applications of the same applicant and have also been realized in the ‘Globetrotter’ drilling vessels.
In embodiments, the casing stand handling system is adapted to transfer the pre-assembled surface casing stands between the casing pre-assembly installation and the surface casing stand storage. Such transfer can be achieved e.g. by one or more cranes, such as a knuckleboom crane.
In embodiments, the casing pre-assembly installation is adapted to interconnect three or more vertically oriented surface casing joints into surface casing stands. In alternative embodiments, the casing pre-assembly installation is adapted to interconnect three or more horizontally oriented surface casing joints into surface casing stands.
In embodiments, the catwalk machine includes:
The present invention also relates to a method for operating a drilling vessel adapted to run large diameters surface casing joints and build a surface casing string, comprising the steps of:
e) connecting the casing lifting tool to a surface casing stand;
f) operating the casing handling capacity hoisting device to lower relative to said tower the surface casing stand that is suspended from said casing handling capacity hoisting device in the firing line;
The surface casing stand upending process essentially corresponds to the riser stand upending process described and shown in WO2014/168471 of the same applicant.
The invention also relates to one or more of the following clauses:
1. Drilling vessel (1) adapted to run large diameter surface casing strings, comprising:
2. Drilling vessel according to clause 1, wherein the tower is a mast (10) and wherein the firing line (20) is provided parallel to and outside of a first side of the mast (10a).
3. Drilling vessel according to clause 2, comprising a second hoisting device supported by the mast and having a load attachment device (30) displaceable along a second firing line (21), which extends on the outside of and adjacent to the second side (10b) of the mast, opposite the first side (10a), wherein preferably drilling operations are performed along the second firing line.
4. Drilling vessel according to any of the preceding clauses, wherein the casing stand handling system is adapted to transfer the pre-assembled surface casing stands between the casing pre-assembly installation and the surface casing stand storage.
5. Drilling vessel according to any of the preceding clauses, wherein the casing pre-assembly installation is adapted to interconnect three or more vertically oriented surface casing joints into surface casing stands.
6. Drilling vessel according to any of the preceding clauses, wherein the casing pre-assembly installation is adapted to interconnect three or more horizontally oriented surface casing joints into surface casing stands.
7. Drilling vessel according to any of the preceding clauses, wherein the catwalk machine includes:
8. Method for operating a drilling vessel adapted to run large diameters surface casing joints and build a surface casing string, comprising the steps of:
The invention will now be described in more detail with reference to the drawings. In the drawings:
The vessel 1 is adapted to perform subsea wellbore related operations involving running large diameter surface casing strings from the vessel. Advantageously, the vessel can also perform other subsea wellbore related operations, e.g. drilling operations, in particular involving a riser string, and wellbore intervention.
In this example, the vessel 1 has an accommodation topside 6 at the bow 3, including crew quarters and a bridge.
The vessel 1 has an engine room 7, generally below the accommodation topside, with exhausts 7a extending at the rear of the topside 6, above the topside 6.
The moonpool 5 has, as is preferred, a rectangular shape with opposed lateral sides, a front side and a rear side.
A front main deck 8 extends between the moonpool 5 and the topsides.
A rear main deck 9 extends between the moonpool 5 and the stern of the vessel 4.
The vessel is equipped with a tower 10, which is, as is preferred, embodied as a hollow construction mast having a top 11 and having a base 12 that is integral with the hull 2. The base 12 extends between sections of the hull on opposed lateral sides of the moonpool 5 and the base 12 is spaced from each of the front side and the rear side of the moonpool, thereby forming a front moonpool area 5a forward of the mast 10 and a rear moonpool area 5b rearward of the mast 10.
The mast 10 has a front side 10a and an opposed rear side 10b as well as opposed lateral sides 10c, 10d.
In this example, drill pipe racks, here embodied as carrousel type racks 14, are located adjacent the lateral sides of the mast 10, as is known in the art.
At the rear moonpool area 5b, the vessel is provided with a working deck 15 arranged above the rear moonpool area 5b. As is preferred the working deck 15 is a mobile working deck, here liftable along the mast 10 to such a height that a blow-out preventer can be brought and held underneath the working deck 15 in raised position thereof at an elevated position relative to the mast 10. In a lowered, operative position, the working deck 15 preferably, as here, is level with the adjacent main deck area 9.
In view of assembly of a surface casing string along a firing line 20 through the rear moonpool area 5b the vessel is equipped with a casing string hanger 17 that is adapted to temporarily hold and suspend therefrom a surface casing string in the firing line 20 into the sea during the surface casing assembly process. As preferred, this hanger 17 is mounted on the working deck 15. Possibly, the hanger 17 is provided with a gimballing support so as to allow for angular variation between the casing string and the working deck, e.g. due to sea motion of the vessel.
The vessel 1 has a surface casing string handling capacity hoisting device including a casing string lifting tool 25, visible in
The surface casing string lifting tool 25 here is suspended from a travelling hanger device 26 that is movable up and down along the rear side of the mast 10 along one or more vertical rails 27.
The hanger device 26 is suspended by one or more cables 28 from a sheave arrangement 29 at the top of the mast, which one or more cables 28 are connected to one or more winches 29a, e.g. arranged within the mast 10 (see
It is noted that in the shown embodiment the firing line 20 is outside of the rear side 10b of the mast 10 so that the firing line 20 can be reached without hindrance in the process of upending a surface casing stand from the rear of the vessel.
The vessel further comprises a casing stand handling system that is embodied to transfer surface casing stands between the surface casing stand storage and the casing handling capacity hoisting device. Advantageously, the casing stand handling system comprises a catwalk machine known per se, which is schematically indicated with reference number 45. The casing stand handling system furthermore comprises a crane, which is not visible.
Such a catwalk machine 45 is commonly known, and comprises:
The drilling vessel further comprises a surface casing storage 60, adapted to store therein multiple surface casing joints 61 having a diameter of over 20 inch (51 cm) and a length of 30-50 feet (9-15 meters). In the shown embodiment, the surface casing storage 60 is provided in the hull of the vessel, adjacent a riser storage hold 40.
Advantageously, both the surface casing storage 60 and the riser storage hold 40 are provided below the main deck area 9. This allows the provision of a surface casing stand storage 65 on the main deck, as visible in
The surface casing storage 60 comprises one or more surface casing storage racks adapted to store therein multiple surface casing joints 61 in horizontal orientation. Similarly, the surface casing stand storage 65 also comprises one or more surface casing storage racks 63 adapted to store therein multiple surface casing stands 62 in horizontal orientation, e.g. each storage rack 63 being embodied to support a surface casing stand 62 at end portions thereof as well as at an intermediate portion thereof at or near each connection between surface casing joints of the surface casing stand 62.
In this example the surface casing stands 62 are assembled from four surface casing joints of 45 feet (14 meters), thus having a stand length of 180 feet (55 meters).
The vessel of the invention is furthermore provided with a casing pre-assembly installation 135, adapted to interconnect three or more surface casing joints 61 into surface casing stands 62 having a length of over 100 feet (30 meters). In the shown embodiment, the casing pre-assembly installation 135 is schematically indicated. It is conceivable that the casing pre-assembly installation is provided on the main deck of the drilling vessel, but alternative locations are also conceivable. Pre-assembly, also referred to as stand building, of surface casing joints may take place horizontally on deck. Alternatively, vertical stand building with a vertically orientated pre-assembly installation is conceivable as well.
In embodiments, the casing stand handling system is also adapted to transfer the pre-assembled surface casing stands between the casing pre-assembly installation and the surface casing stand storage. This can be performed by a crane.
In embodiments, the surface casing joints are interconnected in the surface casing stand storage. For example, the surface casing stand storage is provided with welding equipment to interconnect casing joints into casing stands.
Advantageously, as shown in detail in
The second firing line 21 extends through the front moonpool area 5a. Along this firing line 21 primarily drilling operations are performed.
The second hoisting device is embodied as a drilling drawworks, and is provided with a topdrive 31 suspended from the load attachment device 30 to perform drilling operations. The load attachment device 30 is preferably embodied similar as the travelling hanger device 26.
A working deck 32 is arranged above the moonpool area 5a and may include a rotary table, iron roughneck machine, etc.
Furthermore, in
The vessel 1 is thus capable of assembly of a surface casing string in firing line 20.
Advantageously, the vessel 1 is also capable of assembly of a riser string in firing line 20. For transfer of the riser string to the other firing line 21 a riser string support cart 35 is provided that is displaceable within the moonpool, e.g. skiddable over rails 36 along the lateral sides of the moonpool 5 (see
The vessel has a riser storage hold 40, here as is preferred, within the hull 2 aft of the moonpool 5. The riser storage hold 40 is embodied to store the riser stands therein in horizontal position and parallel to a longitudinal axis of the vessel 1. In
The riser storage hold 40 is adapted to store therein, or has stored therein, multiple pre-assembled riser stands 42, e.g. at least 25 riser stands 42. As is shown here, and as preferred, each riser stand 42 consists of two riser sections.
The riser storage hold 40 comprises one or more riser storage racks 41 adapted to store therein multiple riser stands 42 in horizontal orientation, e.g. each storage rack being embodied to support a riser stand at end portions thereof as well as at an intermediate portion thereof at or near each connection between riser sections of the riser stand.
In this example the riser stands 42 each have a length of 150 ft. (45.72 m).
The riser storage hold 40 has a roof 44 formed by the structure of the main deck 9.
Number | Date | Country | Kind |
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2013684 | Oct 2014 | NL | national |
Filing Document | Filing Date | Country | Kind |
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PCT/NL2015/050735 | 10/23/2015 | WO | 00 |