NO117070B - - Google Patents

Description

Procedure for reclamation of an underwater wellhead

assembly rig from the seabed and its return to a drilling platform or vessel.

This invention relates to a method for use after

ring of an underwater oil or gas well, and more particularly a method adapted to be carried out from a platform or a vessel on the surface of the sea whereby a well head ion t ring placed on the seabed can be recovered and brought back to the vessel.

Methods and devices have previously been developed to

drilling and completing a bridge in which both the bridge ring and then the bridgehead assembly and the casing rod assembly are placed underwater at a depth sufficient for ships to pass over them. The casing head's and wellhead's closing assembly is positioned close to the bottom of the water volume, e.g. on the seabed. To install and recover well drilling equipment located underwater at depths greater than the shallow depth at which a

divers can easily work, it has been necessary to design completely new equipment for this purpose and develop new methods.

Wells drilled in deep water are usually drilled from rigs of various types, commonly known as drill rigs, rigs or platforms. Deepwater wells are usually drilled in one of two ways.

In one, the drill string extends downward, from the drilling vessel to the drilling wellhead assembly, on the seabed, which is closed at the upper end by a circulation head with a flexible hose that runs from the aeration head back to the surface and to the drilling vessel so that drilling fluid can be circulated down the wellhead, through the drill - the tip and then upwards along the outer edge of the drilling board, out the circulation head and up the flexible hose back to the fast city. In the second method, a large diameter tube, known as a subsea tube, is assembled and arranged to extend from the tubehead assembly near the seabed to the vessel on the surface of the water. In the latter method, the drill string rotates inside the formation bed with drilling fluid circulating down through the drill bed, through the tip at the lower end of the drill bed, up the outside of the drill bed inside the well bed and then up through the annular space between the formation bed and the drill bed, and returns to the speedway on conventional way. The present invention relates to recovering, from a place on the seabed, equipment that has been used in one of the methods described above.

One of the problems when drilling underwater wells is the considerable cost of the equipment used, especially the price for a wellhead assembly placed on the seabed for drilling. Due to the high cost of drilling underwater wells and the costs of the equipment associated with the same, most pilot test wells are drilled from land on a "trial and see" basis, i.e. the well is drilled to make a pre-injection on to study the underlying geological formations with suitable drilling rigs or surveying instruments. There is thus no attempt to complete the well even if an oil or gas formation was found during drilling. After studying the formation, the well is plugged in a suitable way, e.g. by

fill cement in it.

The main purpose of the present invention is therefore to provide a method by which a drill head assembly used for drilling placed on the sea bed can be recovered and brought back to the vessel on the surface of the water.

In known methods of recovering a drill head assembly, it has been common practice to lower an explosive charge from the drilling vessel on the surface through the connecting rib to the drill head assembly on the bottom and then to a position somewhat below the drill head assembly. The explosive charge is detonated to sever the rbrstrings extending from the brbnnhead assembly - on the ship bottom and then the brbnnhead assembly can be recovered. Diverse problems arise when explosive charges are used to cut off rudders during a nuclear warhead assembly on the ship's bottom. In some cases hxor a number of "rbrstrings extending down to the bottom with considerable quantities of cement between them and beyond the outermost tube, it was not always possible to select the proper amount of explosive which would cut off all the rbrs. At other times, if a too large an explosive charge was used, components of the warhead assembly itself would be damaged or severely damaged.

A further object of the invention is therefore to provide a method by cutting off down-pulling rudders during a drilling rig head assembly at a point below the seabed, after which the entire assembly can be brought back to the drilling vessel on the surface in an undamaged condition.

A further object is to provide a method for removing a drilling well head assembly from the seabed without the use of explosives.

The present invention thus relates to a method for retrieving a tubular underwater drilling head assembly from the seabed and withdrawing this to a drilling platform or boat on the surface of the water, where the drilling head assembly is equipped with two concentric tubular strands that extend down into the seabed, the outer of the two concentric tubular strands being axially separable into two parts and the inner tube string is equipped with a valve for closing the same, and the invention is distinguished by the features of incorporating in the inner tube of the burner head assembly a cutting tool city, cutting off the tube at a place below the said valve, closing the valve and adding pressure fluid from the speed city into the inner tube string below the said valve and then, through the forming cut-off, to the space between the inner tube string and the outer tube string, bring the pressure of the fluid to axially separate the outer tube string into two parts and to. raise the tube head assembly back to the fast city by hoisting it up from fa rtbyet.

These and other purposes of the invention will be apparent from the following description with reference to the drawing where fig. 1 is a schematic longitudinal view partly in vertical section showing a floating vessel on the sea surface with an underwater drilling head assembly placed on the sea bottom, fig. 2 a longitudinal view partially in vertical section showing part of the brbnn head assembly in fig. 1 at the time when the concentric string extending downwards from the drill head assembly jig is cut off so that the assembly can be returned to the fairway on the surface, and fig. 3 a schematic longitudinal drawing showing a form of a work by soin can be used in the implementation of the method.

The present invention provides a method of recovering a tubular underwater wellhead assembly for drilling, from the seabed and feeding it back to a drilling vessel on the water surface. In most cases, the drill head assembly is equipped with two concentric strings that extend down into the seabed and at least one, often both, are cemented into it. The drill head assembly is also equipped with a valve to shut off the innermost string and a shut-off device on the outer rib string. In the method according to the invention, the inner rib string is cut off at a point below the mentioned valve, after which the inner rib string is closed by closing the valve. A pressure fluid is then fed from the ship into the innermost rib string below the valve and then through cut-off formed in the innermost rudder to the space between the inner tube string and the outer tube string to supply a vertically directed hydraulic lift to the bridge head assembly after which it can be raised back to the ship. The hydraulic lift from the underside of the bridge assembly is preferably supplied at the same time as that a lifting power is supplied from the ship itself by means of suitable lifting devices.

In fig. 1 denotes 11 a drilling vessel, barge or platform. The drilling vessel 11 is of any suitable type preferably as shown floating on the surface 12 of the water 10 and is practically fixed above a preselected drilling site by suitable vessel positioning devices or by being anchored to the bottom 13 by anchors (not shown ) connected with anchor lines lk and 15. Equipment of this type can be used when drilling operations are carried out in water depths varying from about 30 m to about 450 m or more. The drilling vessel is equipped with a suitable derrick 16 as well as other auxiliary equipment that is necessary during the drilling of a well such as a hoist system 17, rotating table 18, power vortex 19 and mud pump 20. The derrick ib can be placed over a drilling slot or

-brbnn ■) which extends vertically yjenuom the fast city li in a conventional way. When the equipment according to the present invention is used, the slot y in the speed port can be placed centrally or extend in from an edge. However, the drilling operations can be carried out over the far-toy side without the use of slots, such as e.g. ira a part of the fast city's deck that protrudes over one of the ends. It will further be understood that the equipment according to the present invention can also be used when a well is drilled from a suitable working base placed above the water surface such as e.g. from a drilling barge that has legs extending into the seabed, or from a platform permanently placed on the seabed

nen.

Kn typical underwater brbnnliodebore assembly is illustrated

in fig. 1 and comprises a base or lower part 21 which is placed on the ship's bottom and is firmly attached to a pipe lining pipe 8 with a diameter of 20 by means of a ball-and-socket joint 21). During the drilling operations, the drill head assembly is preferably loaded to the top of a furida ment pole 2k which is in turn attached to a ball joint 2'}. IN

the wellhead construction shown is the drilling wellhead assembly attached to the left end of the capsule head 23 which is in turn mounted on top of the foundation pile 2k. The combined casing pipe 8, foundation pile 2k and capsule head 23 form a continuous pipe-shaped part or tube, which extends upwards from the bottom 13, and through which the drilling operations are carried out.

The drill head assembly shown includes a removable drill head connector or drill cap 27 of any suitable known type. Above the connector 27 is attached a blow-out preventing device

het 28 of the pressure cylinder type, a similar unit 2y of the bag type,

a flexible link 30, a f

and sealing device 31, and a section-composed fbringsrbr 32 which extends to the speed city 11 on the surface 12. Down along the side of the coupling 31 (fig. 1) lines two auxiliary br 39 and ko of small diameter which can be easily disconnected at any suitable type of extraction connections, e.g. at the points kl and k2. The quick release coupling 31 is adapted to go downwards over and locks onto a tubular part 43 which is fixedly mounted over the flexible link 30 in this particular arrangement. The coupling 31 is equipped with side-directed bolts or pawls 44 adapted to be lined inside and engage the tubular part 43 which is placed inside the coupling 31, which preferably at the upper end has a

internally projecting contact surface or shoulder 45.

The drill head's drill assembly and basic construction as above

as described can be lowered as a unit from the fast city 11 on the surface

ten 12, with the large-diameter bridging board 8 projecting down below the foundation portion 21 into a hole 46 formed or drilled in the bottom 13. Usually, a certain amount of cement 47 is placed in the hole 46 to secure the foundation portion 21 to the bottom. In a typical brbnn head installation, the foundation pile 24 can be about 75 cm in diameter with the next inside rudder or brbnn capsule 22 of about 60 cm in diameter. A string of the brbnncapsule with a smaller diameter, e.g. a rbr string 50 with a diameter of approx. 33" 5 one hangs from the capsule head 25 with the lower end of the rudder or an extension thereof projecting downwards into the hole 46 in which it is cemented. When drilling wells to great depths, additional capsule strings can be placed in the capsule string 50.

To recover all the drilling equipment above the foundation section 21

after the drilling operations have been completed, the outermost brbnn liner 8 under the foundation part 21 is formed in two sections, i.e. a lower section 22 and an upper section 22a, respectively. The two bearing sections 22 and 22a are provided with a quick-detachable joint or coupling 49 which, in this particular arrangement, takes the form of a collar 51 welded to the lower section 22 while attached to the upper

section 22a by means of a series of cut-off pins 52 which extend through the collar 51 and into the upper section 22a. It must be noted that the two sections 22 and 22a are attached at a point 53 inside the collar 51. After the tabs 52 are cut off by the force applied in an upward direction, the left section 22a can be removed from the collar 51, which is normally placed at a pre-selected distance, e.g. 7"5m below the bottom 13. If desired, the lining section 22 can be equipped with a centering part 54 of the wing type to center the smaller diameter inner rib string 50 therein.

The main purpose of the present invention is to provide a method for separating the different concentric i-trtr strings at a point below the sea bed after a bridge has been plugged so that there is no construction that protrudes above the bottom 13 and becomes dangerous for fishing. Thus, according to the invention, at least one of two concentric rebar strands projecting down into the bottom 13 is equipped with a pull-separable pusher or coupling 49, while an inner concentric rebar is cut using a suitable type of rebar or capsule cutter. A suitable form of rBrskjærflWMlta-- i

nism is schematically shown in fig. 3 which illustrates; a rib cutter 55

which has radially extendable cutting elements 56. The cutter is attached to the lower end of an extended cutter string 57 which has a small diameter and which extends upwards to the speed bar 11. The cutter 55 can be automatically pivotable at the lower end of the cutter string 57 or the cutter string 57 itself can protrude through the rotating table 18 on the speed rail 11 and is rotated in a known manner. As some vertical movement of the speed city 11 will occur as a result of bubble action

at the surface 12, a stopper 58 is arranged on the rudder string 57 and adapted to be supported on the shoulder 45 above the quick release coupling 31 which is shown in fig. 1. The distance between the pipe cutter 55 and the stop part 58 must be equal to the distance between the shoulder 45 and the level at which it is desired to cut off the pipe 50 inside the pipe.

The beginning of the rib cutting operation is shown in fig. 1, where the small-diameter rib or bridging string 57 is fed through the rotatable table 18 until the stop part 58 rests on the shoulder 45. The rib 50 is then cut off by radial extension of the cutting elements 56 and rotation of the rib cutter 55. The stop part 58 remains in contact with the shoulder 45 during the cutting operation skjbnt the speed city 11 on the surface 12 can rise and fall. In this case, the right end of the bearing string 57 can freely slide up and down in a bearing in the rotary table when it is rotated.

After the inner rib string 50 is cut off at the desired height, an upward force is applied to the underwater assembly to cause the pins 52 to cut off and thereby allow the entire assembly including the foundation portion 21 to be lifted from the bottom 13t as shown in fig. 2, and is returned to the shipboard 11. The lifting operation can be carried out with the help of the shipboard 11 hoist device 17 which will lift the shipboard 32 one section at a time and dismantled at the shipboard 11 until all components of the drill assembly and the drillhead structure have been recovered and stored on the speedway 11.

Alternatively, instead of exerting drafts at the right end of the assembly from the drilling vessel 11, a fluid pressure can be used to

buoyant force to cause cutting off of the pins 52 and release the underwater structure from the bottom 13. By thus using a rib-shaped bearing string 57" which remains in place after cutting off the inner rib string 50 by means of the rotary cutter 55", the pressure cylinder 60 (cf. 2) of the blowout preventer 28 or

the bag (not shown) in the blow-out valve 29 (fig. i) is closed around the rudder shaft 57» Then hydraulic pressure fluid is supplied through the rudder shaft 57 from the speed bay 11 by means of a pump 20. With the rudder pressure cylinders 60 closed and suitable connection made through the wall of the inner rib string 50, in this case by means of

the extended cutter, the closed left end between the cap ice channels 8 and 50 and the closed rudder pressure cylinders 60 serves as a piston against which the pressure fluid can act when it is pumped down through the fbrings channel 57 • With a capsule 8 which has a diameter of one is a pump pressure of e.g. 70 kg/cni^ able to produce a pressure corresponding to 180,000 kg which tends to drive the entire underwater construction upwards to cut off the pins 52. Ettex- that the pins 52 have been cut off by this hydraulic pressure supplied by the pump 20 , the construction can be attached to the fast city 11 at the surface 12 as described above. If so desired, a combination of the hydraulic pressure force and a mechanical lifting force from the hoisting system 17 on the speedboat 11 can be used slowly to cut off the pins 52 if necessary.

The above-mentioned operations can also be carried out without using the conveyor belt 57 as a pressure line if the operations are carried out in the following manner. Instead of closing the pressure cylinders 60 on the string 57 as shown in FIG. 2, the upper pressure cylinders inside (not shown) of the blow-off controller 28 are closed after the pipe cutter 55 and the pipe string 57 have been brought back to the speed port 11. Pressure fluid is then pumped from the speed port 11 down line 39 and into the exhaust port 28 (fig. 1) under its right pressure cylinder (not shown) through the rib string 50 and through the opening cut in the rudder 50 by the cutter 55 with the result that pressurized fluid will enter the space between the two rib strings 8 and 50 and exert a force which causes the pins 52 is cut off. The operations described above can be carried out with good results if it is assumed that the remotely operable, quickly readable coupling and sealing device 31 is of the type that is positively locked at all times during the drilling operations and the subsequent recovery of the equipment. If, on the other hand, the drill head connector 31 is only a sealing element during the entire drilling operations and which can be easily pulled off under a predetermined pressure, e.g. 350 kg/cm<2>, it is clear that an upward pull on the bearing plate 32 from the surface 12 will cause the assembly to split at the coupling 31 without the equipment underneath being recovered. In the event that a bridge head connector 31 of the release type is used, it becomes necessary to equip the bearing string 57'" with another stop! 64 arranged on the rib 57 at some distance from the stop part 58 so that the distance between these two stop parts is slightly greater than the distance between the stop shoulder 45 (i'ig. 1) on which the stopper part 58 can rest and the crykksyindren 60 (fig. 2) in the blowout preventer 28.

By using a recovery rudder string or recovery string

57, as shown in fig. }', the tool can be lowered into the brake assembly to cut off the compression ring 30 by means of the pipe cutter 55, adding pressure to the space under the compression cylinders 60 (Fig. 2) after these have been closed to effect or lead to the cutting off of the studs 52 , and then be used to lift the whole assembly up from the bottom 1J with the pressure cylinders oO closed over the stop part 64, as shown in fig. 2. It will be understood that other types of stop elements for the device that intervenes in the pipe wall, such as movable sliding pieces, can be used instead of the stop part o4 so that they, together with the pipe string 57, can be used to lift the entire assembly up from the bottom l<J>' .

Claims (3)

1. Procedure for retrieving a pipe-shaped underwater drill head assembly from the seabed and withdrawing it to a drilling platform or vessel on the water surface, where the drill head assembly is equipped with two concentric pipe strings that extend down into the seabed, the outer of the two concentric pipe strings being axially separable into two parts and the inner tube is equipped with a valve for closing the same, characterized by features of inserting into the inner tube of the tube head assembly a cutting tool city, cutting the tube at a place below the said valve, closing the valve and supplying pressure fluid from the vessel into the inner tube rbrstring under the said valve and then, through the cut-off formed, to the space between the inner rbrstring and the outer rbrstring, bring the pressure of the fluid to axially separate the outer rbrstring into two parts and to raise the brabnnhead assembly back to the speed city by hoisting it up from the fast city. 2. Method according to claim 1, characterized in that they draw pressure fluid to the interior of the combustion head the assembly and hoisting the fuel head assembly up are carried out at the same time until the fuel head assembly is lifted from the seabed, after which the supply of pressure fluid is stopped while the fuel head assembly is raised to the speed bay. 3. Method according to claim 1 or 2, characterized in that the cutting of the inner tube string includes lowering a cutting tool by means of an extended tube, which carries same, from the speed city down through the rib head assembly to a predetermined position and rotate the cutting tool to make a horizontal circumferential cut through the inner rib string. k. Method according to claim 3> characterized in that the pressure fluid is supplied through the extended rudder which carries the cutting tool city.