NO317384B1 - Method and apparatus for tool insertion in subsea oil and gas reservoir - Google Patents

Description

The present invention relates to a device for introducing tools into an oil and gas reservoir in the seabed, which reservoir is accessible via a well which is preferably terminated with a valve tree (christmas tree). In particular, the device is adapted for use on wells at particularly great sea depths, and/or wells with very high pressure where existing technical solutions have difficulties with, or do not have access to, intervening in the well or reservoir with tools. The device according to the present invention is further designed and constructed so that in a preferred embodiment it is modularly composed and by varying the composition and the number of modules, different forms of intervention tools or the like can be used in the device as desired and needed, and in this connection it will be possible to put together several different modules that allow for several types of well intervention with different types of tools.

Extraction of oil and gas from the seabed is constantly developing and as former areas become uninteresting, the extraction moves towards new areas of the seabed which often means greater sea depths and geological formations with higher pressure. This entails a number of technical challenges, including linked to the water pressure at great sea depths, high well pressure, as well as the long distance from the surface vessel to the seabed, which can make underwater operations difficult as these must be carried out remotely at all times.

Existing technical solutions also have a number of limitations in relation to operational conditions and it is therefore desirable to develop new technical solutions which essentially overcome these limitations and expand the scope of the operational conditions by allowing the solutions to be used in bad weather, greater depth, less monitoring and control etc. Such a restriction is linked to the lowering of tools at great depths along so-called guide lines/guide wires which are continuous from a vessel on the surface to an installation or construction on the seabed for the lowering of tools or work modules. The limitations when using this solution lie particularly in the operative window for the vessel on the surface in relation to wave height, wind and current conditions. In particular, wave height is a critical factor and if the wave height is too large, this solution cannot be used. One must therefore wait until satisfactory operational conditions are again achieved, or use self-propelled underwater equipment for placing work modules, intervention tools or other equipment on the seabed. It is mainly desirable to overcome this limitation by using self-propelled underwater equipment that is either placed with the help of an ROV or is self-propelled in the perspective that it can move itself from the surface (vessel) to the desired installation on the seabed.

A construction, for example, for the intervention of wells on the seabed, or other underwater work must often be specially adapted to the individual work operations where it is necessary to use a wide range of different tools to cover all needs that may arise during an operation on the seabed. This means either that a large number of special tool modules must be available on the sea surface to be able to be brought down to the well on the seabed as needed, or a total construction with the necessary tools can be placed on the seabed to carry out the necessary and desired operations there. Again, the challenge lies in moving the necessary tools from the surface to the correct location on the seabed. If a total construction is to be moved through the water, which construction must be able to cover the tool needs that arise during an operation, then this unit will be large and unwieldy, on which it will be difficult to maneuver whether it is self-propelled (with its own drive devices) or it is moved by with the help of one or more ROVs. If smaller units are used, which are only specially adapted to carry out certain operations, the challenge will again lie in being able to quickly replace the units on the seabed as the need for new tool operations changes. However, these units will be smaller and easier to place whether they are self-propelled or placed with an ROV.

Known technical solutions are documented in US 3602300 which deals with a downhole installation, retrieval and maintenance device for an underwater well. A winch drum with a motor is enclosed in a pressure chamber and is exposed to the well pressure via an introduction device. Furthermore, US 4577693 describes a wire device for introducing tools into a subsea well where a drum with tool cable is enclosed in a pressure vessel which is connected to the well. In US 5570437, a device for remote measurement of physical parameters in a well is further described.

It is a purpose of the present invention to overcome the problems that are mentioned here, by producing a device which, according to desire and need, is assembled from various units when placed on the seabed. The various units are self-propelled from the vessel to the seabed, and the unit is therefore of a size and shape that makes it easy to move it through the body of water, while the overall structure is modular so that the units can be easily put together as desired and needed on the seabed. The necessary total construction, where the right tools are present in relation to the operations to be carried out, will thereby be easily built up in each individual case, and when an intervention operation is carried out on the seabed, it will therefore not be necessary to bring down new tool units along the way.

A further challenge in well intervention today is linked to wells with high pressure. This is particularly aimed at those cases where it is necessary to intervene with a high-pressure well. Until now, this has been very complicated, and in many cases it is not possible, after which the intervention is postponed until the well's pressure is reduced for natural reasons, which again can take a very long time.

A further challenge lies in the fact that a wide range of different equipment is used on existing wells, and this particularly applies to this so-called underwater valve tree, which is a valve construction placed on a wellhead after completion of drilling to control the flow of oil and gas from the well.

On the basis of the challenges and problems identified above, it is an aim of the present invention to produce a method and device for introducing tools into an underwater well, which method and device is adapted for placement on a number of different types of underwater valve tree (christmas tree); the device must be able to be adapted to each individual operation as desired and needed for different types of intervention tools; the device must be able to be placed without the use of guideways, guides from the surface; the intervention must be able to take place through the valve tree construction without the use of coil pipes or similar to the surface; and the device and the method must be adapted to wells with high pressure and operations in deep water.

In order to meet the above-mentioned purposes, a device has been prepared in accordance with the invention for introducing tools into an underwater oil and gas reservoir, which reservoir is accessible via a well which is terminated in a valve tree preferably at the seabed. The valve tree forms at least a barrier between the formation pressure in the reservoir and the environment on the seabed. A connection is placed sealingly on the valve tree, which connection connects the interior of the well with a pressure vessel containing a cable drum with cable and further that in connection with the connection between the cable drum and the valve tree there is arranged . at least one tool introduction device from which, if necessary, at least one tool is introduced into the well via the connection between the valve tree and the cable drum and that the tool is connected to the cable on the cable drum after which the tool is lowered into the well with the cable from the cable drum.

In accordance with the present invention, a device for introducing tools into an underwater oil and gas reservoir via a well which is terminated in a valve tree on the seabed has thereby been produced, which valve tree forms at least a barrier between the formation pressure in the reservoir and the surroundings on the seabed, which device includes a pressure vessel which is connected to the interior of the well via a pressure-tight intervention pipe and which pressure vessel contains a cable drum with a coiled cable. The device is characterized by the fact that the device has a modular structure with at least one first module adapted to the upper interface of the valve tree, for connection with the valve tree, at least one second module including a closure device for blocking the well flow and one or more modules of which a tool insertion module including pressure vessel and cable drum and that the between the cable drum and the valve tree, at least one tool introduction module containing at least one tool that is introduced into the well with the cable is placed, which module includes at least one separate propulsion device that enables self-propelled module movement through the body of water between the seabed and the ship.

In different embodiments, the device can be produced in different ways. as a total unit or with a modular structure consisting of two or more modules. Regardless of the structure, the device in a number of embodiments will include a blowout preventer (BOP). Furthermore, the device will include a power supply and one or more control systems. The control systems are used to maneuver the device while in the bodies of water, to place the device and to operate the device.

In the preferred embodiment, the device includes at least one separate propulsion device for movement through the body of water. Thereby, the disadvantages attached to the use of guide wire systems are avoided. By designing the device according to the present invention with variable buoyancy bodies, the device can be adapted to movement through the water between the seabed and the ship in so-called "free flight".

In the preferred embodiment, the device according to the present invention is further composed of units (modules) with a modular structure for modular assembly of the total device. In this embodiment, each module includes at least one separate propulsion device for movement through the body of water. In this embodiment, each module has a separate control system, located in a control device for controlling the module during one or more of the phases: movement through the water, interaction between the various modules during placement, connection, operation and separation. In a further embodiment, the modules are provided with means for communication between the modules' control devices when the modules are assembled.

The modular structure of the device according to the present invention also includes the necessary options for disconnecting the module(s) with the tool insertion device(s), the control/power supply module, as well as the winch drum/pressure vessel module from the blowout protection module in an emergency. Furthermore, each unit and/or the total device can be overridden by an external ROV via an external control panel, mainly of an otherwise known type.

A tool device can also be used that allows downhole tool selection.

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The device according to the present invention can also contain various devices for manipulating the cable which is used during tool intervention, e.g. to release fixed tools etc.

In various embodiments, the device is also controlled from the surface (vessel) via an "umbilical cord" consisting of the necessary wires for the transmission of control signals.

An embodiment of a device in accordance with the present invention, with a control system according to the present invention, which device operates according to the method according to the present invention is further described in more detail in the attached figures, where;

fig. 1 schematically shows the placement of the device according to the present invention on the seabed;

fig. 2 schematically shows the structure of an embodiment of the device according to the present invention;

fig. 3 shows the power control device in the device as shown in fig. 2;

fig. 4 shows the winch housing module as shown in fig. 2;

fig. 5 shows the tool carrier as shown in fig. 2;

fig. 6 shows the blowout protection (BOP) as shown in fig. 2;

fig. 7 shows the coupling device for valve 3 as shown in fig. 2;

The different reference numbers in the figures refer to different parts in a preferred embodiment as follows:

Power steering module (PCM) (Fig 3 reference number 100)

101 Receiver for umbilical cord for lifting and electrical power/signals 102 Buoyancy blocks '

103 Motor for azimuth steering

104 Vertical engines

105 ROV override panel

106 Hydraulic power unit, with hydraulic container

107 Electronic control boxes

108 Valve block

109 Connection plates for transferring power and control between the modules 110 Guide channels for connection

111 Bumpers for launching and retrieving

112 Locking device between modules

113 Islands for surface handling

Winch housing Module (Ref. Fig.4 reference number 200)

201 Guide rods for connection

202 Connection plates for the transmission of power and control between the modules 203 Eyelets for surface handling and interlocking of modules 204 Pressure tank with access

205 Winch drum

206 Winch control system

207 Winch spool system

208 Mechanical override of winch

209 Hydraulic power unit, with hydraulic container 210 Electronic control boxes

211 Valve block

212 Guide channels for connection

213 Buoyancy blocks

214 Locking device between modules

215 Support traps for launching and retrieval 216 ROV override panel

217 Pressure seal connection

Tool carrier and bearing module (Ref. Fig 5 reference number 300) 301 Guide rods for connection

302 Connection plates for transmission of power and control between the modules 303 Buoyancy blocks

304 Engines

305 Eyelets for surface handling and interlocking of modules 306 Hydraulic power unit, with hydraulic container 307 Electronic control boxes

308 Valve blocks

309 Guide channels for connection

310 Locking device between modules

311 ROV override panel

312 Pressure seal connection

313 Emergency release valve

314 Tool hangs

315 Device for tool storage and selection 316 "Pull to release" device for fixed tools 317 System for inert gas

318 Bumpers for launching and retrieving

Mini BOP Module (Ref Fig.6 reference number 400)

401 Guide rods for connection

402 Connection plates for transmission of power and control between the modules 403 Buoyancy blocks

404 Engines

405 Eyelets for surface handling and interlocking of modules 406 Hydraulic power unit, with hydraulic container

407 Electronic control boxes

408 Valve block

409 Guide channels for connection

410 Locking device between modules

411 ROV override panel

412 Pressure seal connection

413 Bumpers for launching and retrieving

414 Wire securing device before cutting

415 Cutting pistons 416 Sealing pistons

417 Isolation valve

Valve tree interface module (Ref Fig. 7 reference number 500)

501 Guide rods for connection

502 Connection plates for transmission of power and control between the modules 503 Buoyancy blocks

504 Eyes for surface handling and interlocking of modules 505 Hydraulic power unit, with hydraulic container

506 Electronic control boxes

507 Valve block

508 Guide channels for connection

509 Locking device for wood

510 Pressure seal connection

Figure 1 schematically shows how a device 3 according to the present invention is placed on the seabed on a valve tree construction 4 of an otherwise known type. The device is controlled from a surface vessel 1 via at least one signal line 2. The device 3 according to the present invention lowers a tool 5 into the well towards the reservoir 6 via a cable contained in a pressure vessel. The device 3 is connected to the valve tree 4 in such a way that the barrier against the formation pressure is extended through a connection to the pressure vessel. The pressure vessel contains a winch with a cable (wireline) which is used when lowering tools into the well.

In accordance with the present invention, the device 3 is made up of a plurality of modules as shown in Figure 2. The bottom module 500 is adapted to the valve tree and is placed on it on the seabed. A module 400 containing a blowout fuse is then placed. The modules 400 and 500, like the other modules, are autonomous and move through the water with their own propulsion device (one or more). Furthermore, one or more tool insertion modules 300 and a winch unit 200 are placed. The uppermost module is a control and power generating module which is further connected to a surface vessel via a control line.

The modules are further shown in the other figures 3, 4, 5, 6 and 7 with reference to the above-mentioned list of elements with reference numbers.

The figures show an embodiment which is particularly preferred as it allows the modular construction of units, each of which can be moved autonomously through the water with independent propulsion. The structure can be adapted to different valve trees and different tool needs.

However, the embodiment indicated in the figures is only an example and must not be considered limiting in relation to the inventive concept which is the subject of the present invention, which is further indicated in the subsequent patent claims.

Claims (7)

1. Device for introducing tools into an underwater oil and gas reservoir via a well which is terminated in a valve tree on the seabed, which valve tree forms at least a barrier between the formation pressure in the reservoir and the surroundings on the seabed, which device includes a pressure vessel which is connected to the interior of the well via a pressure-tight intervention pipe and which pressure vessel contains a cable drum with a coiled cable, characterized in that the device is modularly constructed with at least one first module (500) adapted to the upper interface of the valve tree, for connection with the valve tree, at least one second module (400) including a closure device for blocking the well flow and one or more modules (100, 200, 300 ) of which a tool insertion module (300) including pressure vessel and cable drum as well that at least one tool introduction module containing at least one tool that is introduced into the well with the cable is placed between the cable drum and the valve tree, which module includes at least one separate propulsion device that enables self-propelled module movement through the body of water between the seabed and the ship. 2. Device according to claim 1, characterized in that the device includes a blowout protection (BOP). 3. Device according to claims 1 - 2, characterized in that the device includes a power supply. 4. Device according to claims 1-3, characterized in that the device includes one or more control systems. 5. Device according to claims 1-4, characterized in that the device is composed of units with a modular structure for modular assembly of the total device. 6. Device according to claim 5, characterized in that each module includes at least one separate propulsion device for movement through the body of water. 7. Device according to claims 5-6, characterized in that the modules are provided with means for communication between the modules' control devices when the modules are assembled.