NO332212B1 - Y compound and method for using a Y compound in underwater intervention work - Google Patents

Abstract

The present invention relates to a method for carrying out information work in an underwater well (1), connecting a riser element (8) to a wellhead (2), providing a Y-shaped connecting element (10) with devices (14,15, 16) to close and open flow paths through the connecting element. The method comprises the steps of providing displacement fluid inside the connection element (10), closing a second opening (120), connecting well operation equipment (23, 24, 25, 26) to a third opening (130), performing the operations in the well (1) through the third the opening (130), then close the well (1) at a position below the connecting element (10), open the other opening (120) towards the rising movement element (8) and again provide a displacement fluid inside the connecting element (10) and then remove the well operation equipment (23, 24, 25, 26) connected to the third opening (130). The invention also relates to a connection element that is used during intervention work in a well.

Description

The present invention relates to a method for carrying out intervention work in a well, and a device for carrying out intervention work in a well.

When carrying out intervention work in a subsea well with a horizontal Christmas tree, it is necessary to remove the so-called crown plugs to gain access to the wellbore. These crown plugs have the same outside diameter as the production pipe, normally 5 inches nominal outside diameter (OD). The operations to carry out the actual work during the intervention will not normally require such large bores since the tools normally used have a smaller outer diameter. The size of the riser (eng: the riser) used will have to be adapted to the larger crown plug instead of the smaller tools, and this gives weight to the riser in proportion to its cross-section. A riser with a larger bore that can be used to pull a crown plug can e.g. be twice as heavy as a riser required to perform coiled pipe operations. When the wells are developed at greater sea depths, the weight and size of a riser used during the intervention work becomes important and has a major impact on the requirements for the vessels to be used during the intervention work. There is therefore a need for a system to carry out the intervention work, in which the system does not require risers with large bores.

In US 6,520,262, a possible solution is described, where a riser connection is provided to connect a riser to a wellhead assembly having a bore through it. The connection includes a housing having a first and a second end. The first end of the housing has an opening and is adapted for mounting on the wellhead assembly with the opening in communication with the bore in the wellhead assembly. The other end has a first opening connectable to the riser, and having a diameter at least the same as the inner diameter of the riser, and a second opening, having a diameter at least substantially the same as the diameter of the drilling of the wellhead assembly. In use, first well operations are carried out through the riser in a conventional manner. Other well operations are performed using open water techniques and access to the wellhead assembly and the well through the second bushing in the connection, without having to disconnect the riser from the connection.

WO 2008/118680 discloses a system for underwater intervention operations using a compliant guide extending between the surface and an underwater installation.

Other examples of marine riser systems are shown in WO 2006/075181 and US 4147221.

However, there is a need to provide a system for carrying out intervention work in an active well.

One purpose of the present invention is to provide a method and a device for carrying out the intervention work in a well. This has been achieved with a method and a device according to the attached requirements.

A procedure has been provided for carrying out the intervention work in a subsea well. The method comprises the steps of connecting a riser member to the wellhead and providing a connection member comprising a first end having a first opening connected to the wellhead and a second end having at least two openings, a second opening and a third opening, flow passages through the connection connecting the first the opening having both the at least second and third openings, and means for closing and opening the flow passages through the second and third openings, and wherein the second opening is connected to the riser element.

The riser element may be a riser that extends to a floating vessel on the surface or possibly that it only extends at a distance from the wellhead. The riser element can be, and is preferably, shaped so that it can withstand pressure and hydrocarbons. The riser element is thereby equipped so that it can withstand the well fluid in an active well. The second opening, and thereby also the riser element, will normally have an inner diameter that is smaller than the flow passage in the wellhead. The third opening will normally have an inner diameter which is substantially equal to or greater than the inner diameter of the flow path in the wellhead. This gives two different possible entrances to the well, which have different internal diameters, and you can thereby use different entrances for different equipment that need different diameters. This gives the possibility, in the case when the riser extends to the surface, to use a smaller and lighter riser than if the riser had to have a diameter corresponding to the flow path in the wellhead. This in turn reduces the requirements for the vessel required to carry out the intervention work. According to one aspect of the invention, there may be further possible entrances to the well. These additional openings, by having multiple openings at the other end of the connecting element, may have similar or different diameters to the second and third openings. This will give the possibility of carrying out several different activities with different types of intervention tools.

According to the invention, the method comprises the steps of providing a displacement fluid inside the connecting member, closing the second opening, attaching well operation equipment to the third opening, performing the operation in the well through the third opening, then closing the well at a position below the connecting member, opening the second opening towards the riser element and again providing a displacement fluid inside the connection element and then removing the well operation equipment connected to the third opening.

It should be understood here that the operation will also work if the second and third openings are switched, given that there is a riser element connected to the third opening.

The steps to provide a displacement fluid inside the connecting element will, in the case when the intervention work has started, entail the supply of a displacement fluid to the connecting element and thereby displace seawater or other fluid that is inside the connecting element. There will normally be no well fluids in the connecting element since the well is closed below the connecting element, by e.g. crown plugs. If the operation is carried out after the well has been opened, i.e. after the crown plugs have been closed, the well must be closed by a valve below the connecting element to prevent the entire well being filled with a displacement fluid when a displacement fluid is provided in the connection element. A possible solution to this is to provide valve devices at the first opening of the connecting element. Another possibility is to use already existing valves in the well below the connecting element. Such valves can e.g. be a valve in the valve tree or further down the well. By limiting the space that needs to be filled with displacement fluid to fill the connecting element, one can also limit the cost and time consumption of this flushing procedure.

The indications below and above shall in this application be understood to be relative terms which give relative positions between elements during normal use of the method and the device in the case of a horizontal valve tree.

A riser element shall in this application be understood to be a riser element that does not necessarily extend all the way to the surface of the water, but possibly also a riser element that extends all the way to the surface of the water and to a floating vessel. Alternatively, the riser element can be a shorter riser element, which forms a tank for the fluid that is displaced from the connection element, when the displacement fluid is supplied to the connection element. Alternatively, the riser element may extend to another subsea installation.

According to one possibility, there are more than a second and a third opening, e.g. a fourth and a fifth opening at the other end of the connecting member. In such a case, after providing displacement fluid inside the connecting element, all openings except the opening through which well operations are to be carried out will be closed. These further openings will normally be in a closed state, as they will normally lead out into the surroundings of the wellhead. The flow paths through these openings can be closed by valve devices or plugs in the openings or in another position in the flow path or possible by tool equipment that is connected to the openings, since the tool equipment itself is closed to the surroundings. In such a case, there may be full access from the tool equipment through the openings or there may be valve devices in these connections, which can be operated independently of the attachment of the tool devices.

According to one aspect of the invention, the method may include the steps of providing a displacement fluid inside the connection element, which displacement fluid is heavier than well fluids in the riser, and where this displacement fluid is supplied at a position above the connection element. One possibility is to supply the displacement fluid in the riser element above the connection element. The displacement fluid will then, due to gravity, replace any well fluid in the connecting element. This replacement will be assisted if the second opening is open, and the fluid in the connecting element is allowed to move into the riser element. At the same time, the displacement fluid can be moved from the riser element to the connection element.

According to another aspect, the method may comprise withdrawing a unit having an outer diameter greater than the inner diameter of the riser member from the well through the third opening. This device can e.g. be a crown plug in a horizontal valve tree. This also means that the second opening can have an inner diameter that is smaller than the inner diameter of the third opening, and also the inner diameter of the flow path in the wellhead.

According to another aspect, the displacement fluid may be a hydrate inhibitor fluid such as monoethylene glycol (MEG). Another possibility is to use ethylene glycol or glycol (environmentally friendly) or triethylene glycol or alternatively salt water as a displacement fluid.

According to a further aspect, the method may comprise connecting a tool in connection with the third opening before the third opening is opened to access the well. The connection of the tool may open the third opening or there may be separate means for opening and closing the flow path through the third opening. The tool may also include means for opening the third opening after the tool is connected to the connecting element.

According to another aspect, the tool to be connected to the third opening may be a pressure control head (PCH) or a wire line operated winch equipment (ENG: wire line operated winch equipment, WL Winch) or a remote control tool. The connection of the tool to the third opening can be assisted by using a remotely controlled underwater robot (ROV, remotely operated vehicle). According to another aspect of the invention, the method may comprise providing a riser element comprising a connecting element from an upper end of a horizontal valve tree to a floating unit. The connection element may be provided between the emergency disconnect pack (EDP) and the riser element, between the emergency disconnect pack (EDP) and a voltage link connected to the riser element, between the voltage link and the riser element or the connection element may form a voltage link in the riser. By having a voltage connection between the connection element and the wellhead, unwanted voltages in the wellhead can be prevented. In this situation, the displacement fluid can be fed into the riser by the floating unit, and allowed to sink down to the connection element through the riser, thereby displacing the well fluid or other types of fluid in the case that the well is not opened, inside the connection element. The fluid that is displaced by the displacement fluid will in such a configuration be displaced up and into the riser element, thereby exchanging places with the displacement fluid.

According to one aspect of the invention, well operations through the second opening in the connecting element can be performed through an opening in the lower deck (eng: moon pool) of a floating vessel. These operations can then be carried out through a riser that extends from the connecting element up to the vessel. Alternatively, there can be a guide line operation (eng: wire line) which is carried out through the opening in the lower deck (the moon pool). The operations through the third opening of the connecting element can be carried out with the outside of the hull of the vessel. This can e.g. is done at the stern of the vessel. Another possibility is to have several openings in the lower deck (moon pooler) and perform the operations in the second and third openings in separate openings in the lower decks (moon pooler). In the case of a fourth opening, the operation in the third opening can be performed at one side of the vessel and the operation at the fourth opening at the other side of the vessel.

The invention also relates to a connection element for use in well operations. The connecting element comprises a first end with a first opening and a second end with at least a second opening and a third opening, flow paths through the connecting element connecting the first opening and the at least second and third openings, and means for closing and opening the flow paths through at least the second and third openings. According to the invention, the connection element further comprises a flow connection between a position binary to the third opening and the flow path between the first opening and the second opening.

The other end may comprise more than two openings, such as a second, third and fourth opening or a second, third, fourth and fifth opening. This will provide more access points to the well. In such a case, there will be fluid connections between these additional openings and the flow path between the first opening and the second opening.

According to a further aspect, the fluid connection may comprise devices for closing and opening the fluid connection.

According to a further aspect of the invention, the device for closing and opening the flow path through the second opening may comprise a valve device positioned in the flow path. Alternatively, the devices for closing and opening the flow path can be a common valve device and there can be valve devices in the equipment connected to the connecting element, which close and open the flow path, alternatively there can be plug devices operated from the surface through the riser element.

According to a further aspect, the fluid connection may be connected to the flow path between the first and the second opening in a position closer to the second opening than a valve device in this flow path. In normal use, this means that the fluid connection will be connected to the flow path between the first opening and the second opening in a position above a valve device inside this flow path. This fluid connection will normally have an internal diameter that is smaller than the diameters of the openings at the other end of the connecting element. By having a smaller fluid connection with a valve device in this fluid connection, one can, by opening the fluid connection valve, bleed pressure from one side of the valve in the flow path between the first and the second opening to the other side, and one can then more easily open a valve in this flow path . Alternatively, the connection point of the fluid connection can be arranged below the valve device in this flow path. In this last case, the fluid connection can be formed without a valve device in the fluid connection.

According to one aspect of the invention, the first end of the connecting element may be adapted to be connected to the wellhead. The second opening at the other end may be adapted to be connected to a riser element and the third opening of the other end may be adapted to be connected to a tool element.

According to a further aspect, the second opening may have a smaller inner diameter than the inner diameter of the third opening.

By having a connecting element with several openings at the other end, it is possible to use different types of intervention tools at the same time. One possibility is to attach driving tools with different larger diameter openings to different openings and thereby have the option to pull both plugs and install protection for the down hole safety valve (DHSF) in one operation according to the invention without having to flush the system several times . This will reduce the time and thereby the costs of the interventional operation. Some of the tools that are connected to the connecting element can be relatively short and thick, and possibly with a relatively large diameter that requires a large diameter opening, e.g. for pulling the plugs, while other tools for carrying out work down the well can be relatively long and thin and with a smaller diameter opening, e.g. guide line tool (eng: wire line) for operation in the well.

The invention will now be explained with reference to various non-limiting embodiments, with reference to the attached drawings where:

Fig. 1 is a schematic figure showing a first embodiment of the invention,

Fig. 2 is a schematic figure showing a second embodiment,

Fig. 3 is a sketch of a third embodiment of the connecting element,

Fig. 4 is a sketch of a fourth embodiment of the connecting element,

Fig. 5 is a sketch of a fifth embodiment of the connecting element,

Fig. 6 is a sketch of a sixth embodiment of the connecting element, and

Fig. 7a-f show different steps in a method according to the invention.

The present invention relates to a method and device for carrying out intervention work in a well 1 normally for the extraction of hydrocarbons, as shown in fig. 1. A wellhead 2 is connected to the well 1. This wellhead 2 may comprise a horizontal valve tree with a horizontal production outlet from the wellhead (not shown). In order to carry out the intervention work in the well, it is common to gain access to the well from the top of the wellhead 2.1 according to the invention, this can be achieved by providing a riser element 8 that extends from the flow path in the wellhead from the wellhead 2 up to a floating vessel 9. according to the invention, a connecting element 10 is provided between the riser element 8 and the wellhead 2. This connecting element 10 comprises a first end 11 with one opening 110, and this first end is connected to the wellhead 2 during use. The connecting element 10 has a second end 12. This second end 12 comprises several openings, a second opening 120 and a third opening 130. There are flow paths inside the connecting element 10 which connect the first opening 110 with the second opening 120 and the first opening 110 with the third opening 130. The second opening 120 is connected to the riser element 8 and a continuous flow path is provided from the wellhead 2 through the connection element 10 and the riser element 8 up to the vessel 9. The second opening 120 and the third opening 130 are positioned so that the connection element forms a Y shape. Depending on the use of the two openings at the other end, the orientation of these can be varied. There is also a fluid connection 13 between the third opening and the flow path between the second opening 120 and the first opening 110. This fluid connection 13 preferably has a smaller diameter than the diameter of the openings. This fluid connection 13 preferably extends either in a mainly horizontal direction or in an upward direction from the connection point towards the third opening. Coiled pipe operations in this configuration can be performed through the riser member 8 which has a diameter smaller than the opening of the flow path in the wellhead 2, while a plug in a flow path in the wellhead 2 can be pulled through the third opening 130 which has a diameter similar to the flow path in the wellhead. Operations through the third opening 130 can be performed to the side of the vessel.

In fig. 2 schematically shows a connecting element which can have more than two openings 120, 130 at the other end, with a fourth opening 140. Wire line operations can be carried out through an opening in the lower deck (moon pool) of the vessel and through the opening 140, and guide line operations from one side of the vessel through the third opening 130. There may also be a shorter riser element 8 connected to the second opening 120.

In fig. 3 shows a third embodiment where the connection element is connected to a quick release coupling 7, which is connected to the wellhead (not shown). A stress joint 6 is connected to the second opening 120 of the connecting element 10, which in turn is connected to a riser element (not shown). There is a fluid connection 13 between the third opening 130 and the flow path between the first opening 110 and the second opening 120. A first valve device 14 is positioned in the first opening 110, and a second valve device 15 is positioned in the second opening 120. The second The valve device 15 is also positioned relatively above the connection point of the fluid connection 13 to the flow path between the first opening 110 and the second opening 120. The first opening 110 has a diameter 18 that is larger than a diameter 19 of the second opening 120, but similar to a diameter 20 of the third opening 130.1 this embodiment, a winch package tool 25 is connected to the third opening 130. This tool 25 can be used to pull a plug inside e.g. the wellhead. The Winch Pack Tool

25 can be autonomous, and/or remotely controlled or controlled with lines from the vessel.

In fig. 4 a similar embodiment is shown, but in this embodiment a plug 16 is positioned as a closing device for the third opening 130. It is also indicated that a pressure control head (Pressure Control Head, PCH) 24 can be connected to the third opening 130. This PCH 24 can include equipment to pull the plug 16 and carry out the work in the well and then put the plug 16 back.

In the fifth embodiment in fig. 5, the connection element 10 is itself a load piece 6, and positioned between a riser element 8 and an emergency release coupling 7, connected to the wellhead (not shown).

In a sixth embodiment as shown in fig. 6, the connection element is connected between a load connection 6 connected to an emergency disconnect connection 7, connected to a wellhead (not shown) and a riser element 8.1 this embodiment, the fluid connection 13 between the third opening 130 and the flow path between the first opening 110 and the second opening 120 is connected to this flow path in a position above the valve element 15 in this flow path. In addition, a connection valve device 17 is positioned in the fluid connection 13, which can open or close the fluid connection 13. The fluid connection 13 is connected to the flow path between the first opening 110 and the third opening 130 close to or at the third opening 130.

In fig. 7a to 7f shows a sequence of operations according to the invention. It is in fig. 7a connected a riser element 8 to a wellhead 2 with a connection element 10 between them. A displacement fluid is provided inside the connection element 10 by supplying it in the riser element 8. This displacement fluid is prevented from moving further down the well by the crown plug 4, which also functions as a well valve in this case, since the crown plug is not pulled. A tool element is connected to the third opening 130 which is opened, and a fishing tool 23 is found positioned just below the third opening 110. In fig. 7b, the fishing tool is operated by a guide line (wire line) 26 lowered to the crown plug 4 to pick up the crown plug. The second valve device 15 for the second opening 120 is moved to a closed state, and the connection valve devices 17 inside the fluid connection 13 are moved to a closed state.

In fig. 7c, the crown plug 4 is connected to the fishing tool 23 and pulled by the operation of the guide line (wire line) 26 being pulled upwards towards the third opening 130. In this operation the well is opened, and the displacement fluid inside the connection element 10, which is heavier than the well fluid, sinks further down into the well so that it thus makes room for well fluids that fill up the connection element 10, up to the second closed opening 120 and the closed third opening 130. Then, as shown in fig. 7d, a well valve 5 in this case inside the valve tree, below the connecting element 10 is closed. A displacement fluid is then supplied again to the connection element 10 through the riser element 8 when the second valve arrangement 15 is moved to an open position. Well fluids inside the flow path between the first opening 110 and the third opening 130 moved through the fluid connection 13 to the flow path between the first opening 110 and the second opening 120 upon the opening of the connection valve device 17. This ensures that a minimal amount of well fluids is trapped inside the connection element 10. As indicated in fig. 7e, the tooling 24 is then removed from the third opening 130 and the third opening is closed. As shown in fig. 7f, the well valve 5 can then be opened again. The displacement fluid inside the connection element 10 will again sink down into the well, and be replaced by well fluids. There is then full access to the well through the second opening 120.

It will be possible to gain full access to the well through the second opening 120 in a state of the method between the steps as shown in fig. 7b and 7c, so that one gets the opportunity to carry out the work inside the well without having to lift the crown plug 4 to the surface.

The invention is now explained with non-limiting examples. A person skilled in the art will understand that modifications and changes can be made to the embodiment shown which are within the scope of the invention as defined in the following claims.

Claims (14)

1. Method for carrying out underwater intervention work in a well (1), connecting a riser member (8) to a wellhead (2), and providing a connecting member (10) comprising a first end (11) with a first opening (110) connected to the wellhead (2) and a second end (12) with at least two openings, a second opening (120) and a third opening (130), flow paths through the connecting element connecting the first opening (110) to both the second opening ( 120) and the third opening (130), and devices (14, 15, 16) for closing and opening the flow paths through the second and third openings (120, 130) and where the second opening (120) is connected to the riser element (8 ), characterized in that it comprises the steps of providing a displacement plug inside the connecting element (10), closing the second opening (120), connecting well operation equipment (23, 24, 25, 26) to the third opening (130), performing operations in the well ( 1) through the third opening (130), there ter close the well (1) at a position below the connecting element (10), open the second opening (120) towards the riser element (8) and again provide a displacement fluid inside the connecting element (10) and then remove the well operation equipment (23, 24, 25, 26 ) connected to the third opening (130). 2. Procedure according to claim 1, characterized by the step of providing a displacement fluid inside the connection element (10) comprising providing a displacement fluid that is heavier than water in the riser element (8) above the connection element (10) and which displacement fluid will displace the well fluid in the connection element (10) when the second opening is opened. 3. Procedure according to claim 1 or 2, characterized in that it comprises pulling a unit (4) with an outer diameter greater than the inner diameter of the riser element (8), from the well (1) out through the third opening 8130). 4. Method according to one of the preceding claims, characterized in that the displacement fluid is a hydrate inhibitor fluid such as monoethylene glycol (MEG). 5. Method according to one of the preceding claims, characterized in that it comprises opening the flow path between the third opening (130) and the first opening (110) after a tool equipment (23, 24, 25, 26) has been connected to it third opening. 6. Method according to one of the preceding claims, characterized in that the connection of the tool equipment (23, 24, 25, 26) to the third opening (130) opens the flow path between the third opening (130) and the first opening (110). 7. Method according to one of the preceding claims, characterized in that it comprises providing a riser (8) comprising a connecting element (10) from an upper end of a horizontal valve tree (3) to a floating unit (9), and providing displacement fluid in the riser (8) at the floating unit (9). 8. Connection element (10) for use in connection with well operations, comprising a first end (11) with a first opening (110) and a second end (12) with at least two openings, a second opening (120) and a third opening (130), flow path through the connecting element connecting the first opening (110) with both the at least second opening (120) and the third opening (130), and devices (15, 16) for closing and opening the flow paths through the at least the second opening and the third opening (120, 130), characterized in that it further comprises a fluid connection (13) between a position close to the third opening (130) and the flow path between the first opening (110) and the second opening (120). 9. Connecting element according to claim 8, characterized in that the fluid connection (13) comprises devices (17) for closing and opening the fluid connection (13). 10. Connecting element according to claim 8 or 9, characterized in that devices (15) for closing and opening the fluid flow through the second opening (120) comprise a valve device (15) positioned in the flow path. 11. Connecting element according to claim 10, characterized in that the fluid connection (13) is connected to the flow path between the first and the second opening (110, 120), in a position closer to the second opening (120) than the valve device (15) in the flow path. 12. Connecting element according to one of claims 8-11, characterized in that the first end (11) is adapted to be connected to a wellhead (2). 13. Connecting element according to one of claims 8-12, characterized in that the second opening (120) of the second end (12) is adapted to be connected to a riser element (8) and the third opening (130) of the second element (12) is adapted to be connected to a tool element (23) , 24, 25, 26). 14. Connecting element according to one of claims 8-13, characterized in that the second opening (120) has a smaller internal diameter than an internal diameter of the third opening (130).