Subsea tree override tool apparatus and method

Abstract

The present disclosure relates to subsea tool apparatus and methods, particularly but not exclusively tool apparatus and methods relating to subsea trees or so-called Christmas trees. The subsea tool is for reinstating the functionality of a subsea tree valve actuator, by applying a thrust force to the subsea tree valve actuator stem, characterised in that: the tool gets its power supply to provide load on the actuator stem, directly or indirectly from the subsea tree SCM (subsea control module) supply.

Claims

1. A subsea tool for permanently reinstating the functionality of a subsea tree valve actuator, by applying a thrust force to the subsea tree valve actuator stem, comprising a cylinder body which defines a fluid and pressure containing chamber, and a thrust rod for engaging with an actuator stem of the subsea tree valve actuator, wherein the tool gets its hydraulic supply to provide load on the actuator stem directly from a subsea tree SCM (subsea control module) hydraulic supply via an existing SCM hydraulic supply line to the subsea tree valve actuator stem, the subsea tool including a SCM supply line connector, wherein the hydraulic supply for the tool is shared with the existing SCM hydraulic supply line for the subsea tree valve actuator; and wherein the tool is adapted to be deployed by a remotely operated vehicle (ROV) being provided with a tool docking unit socket to enable ROV-deployment.

2. The subsea tool of claim 1 wherein the tool is installed and left connected to the actuator for any length of time, up to the maximum design life of the tool.

3. The subsea tool of claim 1 wherein the tool is connectable to an actuator body surrounding said actuator stem.

4. The subsea tool of claim 1 further incorporating a bladder system connected to the annulus and/or the cylinder side of the tool.

5. A subsea tree comprising a plurality of tools according to claim 1.

6. A method of modifying a subsea valve component by permanently reinstating the functionality of a subsea tree valve actuator comprising the steps of: deploying a tool from a remotely operated vehicle (ROV), the tool applying a thrust force to the subsea tree valve actuator stem, the tool comprising a cylinder body which defines a fluid and pressure containing chamber, and a thrust rod for engaging with an actuator stem of the subsea tree valve actuator, wherein the tool gets its hydraulic supply to provide load on the actuator stem directly from a subsea tree SCM (subsea control module) hydraulic supply via an existing SCM hydraulic supply line to the subsea tree valve actuator stem, the subsea tool including a SCM supply line connector, wherein the hydraulic supply for the tool is shared with the existing SCM hydraulic supply line for the subsea tree valve actuator, and using the subsea tree SCM (subsea control module) hydraulic supply to provide hydraulic power to the tool via an existing SCM supply line to the subsea tree valve actuator stem.

7. A subsea tree modified by the method of claim 6.

8. The method of claim 6 wherein the tool is installed and left connected to the actuator for any length of time, up to the maximum design life of the tool.

9. The method of claim 6 wherein the tool is connected to an actuator body surrounding said actuator stem.

10. The method of claim 6 wherein the tool is provided with a tool docking unit socket to enable said deployment from said ROV.

11. The method of claim 6 wherein the tool is connected to the actuator body.

12. An auxiliary skid suitable for use with a subsea tool for reinstating the functionality of a subsea tree valve actuator, the auxiliary skid being attachable to a Christmas tree or similar subsea valve arrangement, the auxiliary skid having an attachment to attach a subsea tool to it, the subsea tool comprising a cylinder body which defines a fluid and pressure containing chamber, and a thrust rod for engaging with an actuator stem of the subsea tree valve actuator, wherein the tool gets its hydraulic supply to provide load on the actuator stem directly from a subsea tree SCM (subsea control module) hydraulic supply via an existing SCM hydraulic supply line to the subsea tree valve actuator stem, the subsea tool including a SCM supply line connector, wherein the hydraulic supply for the tool is shared with the existing SCM hydraulic supply line for the subsea tree valve actuator, the auxiliary skid being able to be attached to a subsea control module, thereby allowing the subsea tool to be powered from the subsea control module.

13. The auxiliary skid of claim 12 further comprising a bridging plate.

14. The auxiliary skid of claim 13 wherein the bridging plate enables hydraulic supply pressure to be routed from a subsea control module to a subsea tool via the auxiliary skid.

15. The auxiliary skid of claim 12 further comprising one or more bladders to compensate for hydraulic volume and/or pressure.

16. The auxiliary skid of claim 12 further comprising one or more accumulators to compensate for hydraulic volume and/or pressure.

17. The auxiliary skid of claim 12 further comprising an on board hot stab.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Embodiments of the various aspects of the invention will now be described, by way of example only, with reference to the following drawings, in which:

(2) FIG. 1 is a cross-sectional elevation of a tool according to the present invention connected in situ to a subsea tree;

(3) FIG. 2 is a perspective view of the tool of FIG. 1 being brought into proximity with the subsea tree of FIG. 1 with a remotely operated vehicle (ROV);

(4) FIG. 3 is a perspective view of the tool of FIG. 1 being installed onto the subsea tree of FIG. 1 using an ROV; and

(5) FIG. 4 is an isometric view of the subsea tree, the subsea control module (SCM), the tool of FIG. 1 and an ROV used for installation of the tool.

(6) Referring to the drawings and initially to FIG. 1, an existing subsea tree 100 is depicted. The subsea tree 100 includes one or more valves (not shown). An actuator 10 is connected to and operates valve (not shown). Actuator 10 includes an actuator stem 12 and an actuator bayonet 11.

(7) A standard subsea control module (SCM) 106 is located near the subsea tree 100 and provides control power and hydraulic functions for the tree 100 in a known fashion.

(8) In the present embodiment, actuator 10 is not operating within acceptable parameters and requires modification and intervention.

(9) Tool 22 has been attached to the actuator 10. Tool 22 comprises a cylinder body 8, a cylinder cap 2 at an outboard end of the cylinder body 8, and a mating assembly 30 at an inboard end of the cylinder body 8. The skilled addressee will appreciate that use of inboard end and outboard end relate to the orientation of the tool 22 in relation to the tree 100 and actuator 10 and no further limitations are to be inferred from the use of such terminology.

(10) Cylinder cap 2 comprises a generally cylindrical plug portion 2a with a flange portion 2b provided around its outboard end. Bolt holes 2c are provided on the flange portion 2b. Bolts 4 secure the cylinder cap 2 to the cylinder body 8 via bolt holes 2c and corresponding tapped bores 8a provided on the outboard end of the cylinder body 8.

(11) A dished indentation 2d is provided on the face 2e of the plug portion 2a which is located within the cylinder body 8.

(12) A piston 5 is disposed within cylinder body 8. Piston 5 comprises piston head 5a and piston stem 5b. Piston stem 5b protrudes out of the cylinder body 8. A cylinder wall 8b partially closes the cylinder body 8 at its inboard end. A piston stem guide Sc comprising a threaded aperture 8d extending through the cylinder end-wall 8b and a piston stem collar 8e is located on the cylinder end-wall 8b. Six O-ring piston stem seals 9 are provided within the bore of the piston stem guide 8c.

(13) Piston Guide Rings 6 provides guidance for the piston 5. Similarly, seals 9 provide sealing and guidance to the piston 5 passing through the cylinder cap 2.

(14) Mating assembly 30 comprises a locking collar 1 attached around a threaded portion 8f of the cylinder body 8 located proximal the inboard end. The threaded aperture 8d is slightly greater in diameter than the cylinder body 8. A socket portion 32 is created within threaded aperture 8d and around piston stem collar 8c.

(15) Spring 21 is provided around piston stem collar 8e and within threaded portion 8f within socket portion 32.

(16) Mating assembly 30 attaches to actuator bayonet 11 held together with locking collar 1. Piston stem 5b attaches to actuator stem 12. A thrust face 20, a generally flanged disk, abuts the inboard end of the piston stem collar 8e and the outboard end of the actuator bayonet 11. An O-ring seal bayonet seal 35 radially surrounds the thrust face 20. Spring 21 urges the bayonet seal 35 against the actuator bayonet 11.

(17) In the present embodiment, a Remotely Operated Vehicle (ROV) 102 deploys tool 22 onto tree 100. However, tool 22 may be diver deployed. ROV deployment allows for greater water depths to be achieved, where tree 100 may be located beyond a depth achievable by a diver.

(18) A tool docking unit (TDU) 34 is used to enable deployment by ROV 102. An API 17H standard TDU socket 16 is provided on the tool 22, to enable compatibility with widely used industry standards.

(19) Torque tool square drive 17, drive shaft 18 and eccentric drive 19 are attached to the tool 22, and when the tool 22 is located on the tree 100, they are located on the upper surface of the tool 22.

(20) The ROV 102 engages the TDU 34 into the TDU socket 16 on the tool 22 and carries the tool 22 in into position and engages it onto the actuator stem 12. The tool 22 is fitted with a unique locking drive, designed to lock the tool 22 on the actuator 10, part of the mating assembly 30.

(21) The internal thrust face 20 of the tool 22, that engages with one side of the actuator stem is spring loaded to take up any residual clearance. The API 17H square drive 17, located inside the TDU socket 16 is attached to a rotating drive shaft 18, supported on bearings. The locking collar 1 on the tool 22 is connected to the drive shaft 18 via an eccentric lever arm 19. The locking function for the tool 22 is performed by the TDU torque tool engaged with the drive shaft 18 via the square drive 17.

(22) The torque tool rotates the shaft 18 which in turn rotates the locking collar 1 on the tool 22, via the eccentric arm. This locks the tool 22 onto the actuator stem 12. The advantage of this method in that the ROV 102 performs the tool 22 deployment installation and locking, potentially all in one operation, withhold having the need to reposition, disconnect and reconnect.

(23) The tool 22 is fitted with an ROV hot stab 3 to provide hydraulic supply to the cylinder and annulus sides. Alternatively the hydraulic connections can be made directly into the tool 22.

(24) To facilitate installation of ancillary equipment and subsequent operation, the tool 22 is provided with an auxiliary skid 23. The purpose of the auxiliary skid 23 is to enable the tool 22 to be installed in the simplest matter to the subsea tree 100 existing SCM (subsea control module) 106.

(25) The hydraulic fluid and pressure to power the tool 22 is routed from the existing subsea control module (SCM) 106 via an existing stab plate 24 located on the tree 100. All equipment necessary for effective operation of the tool 22 will be provided by the auxiliary skid 23 which will be deployed with the tool 22. To make connection with the tree stab plate 24, a bridging plate is provided from the auxiliary skid 23. The tool 22 is also connected hydraulically to the auxiliary skid 23. The auxiliary skid 23 contains all the necessary bladders, vales and hot stabs to enable direct control.

(26) An auxiliary skid connects the override tool directly with the SCM (subsea control module) on the Christmas Tree 100. Using a modified bridging plate, the hydraulic supply pressure is routed from the SCM to the override tool via the auxiliary skid.

(27) At the same time as routing the hydraulic power supply, the auxiliary skid 23 provides fluid compensation for the legacy actuator (original one on Christmas Tree 100), and an override system, using on board accumulators (not shown).

(28) The auxiliary skid 23 has finality to control override tool 22 directly from the rig/intervention vessel in a workover scenario. This is done by a using an on board hot stab.

(29) The piston 5 makes face to face contact with the actuator stem 12 and as such is able to provide the required thrust. To connect the hydraulic supply to the tool 22 the existing SCM supply line 13 to the actuator 10 is disconnected and reconnected to the tool 22. The supply cavity on the actuator 10 is rerouted to an actuator compensation bladder (not shown), to prevent seawater ingress into the actuator 10.

(30) Once installed, the tool 22 reinstates functionality to the actuator 10 and therefore tree 100.

(31) Since the SCM 106 provides power, hydraulic and control functionality to the tool 22, this may be considered a permanent modification and repair of the tree 100, and mitigates the requirement either to use the tree 100 without full functionality, or for complete replacement of the tree 100.

(32) The invention is not limited to the embodiment hereinbefore described, but may be modified in both construction and detail.