WO 2014/178721 PCT/N02014/000032 1 Field of invention The present invention relates to offshore mooring systems. More specifically it relates 5 to a subsea, remotely operated tension adjusting system for mooring lines where the lines comprise chain sections. Introduction and background Definitions and Abbreviations 10 The abbreviations used in this document are: DFF Design Fatigue Factor EOL End of Life ESD Emergency Shut Down FPSO Floating Production Storage and Offloading 15 FSO Floating Storage and Offloading FSU Floating Storage Unit HPU High Pressure Unit HS Hot Spot MBL Minimum Breaking Load 20 MLBE Mooring Line Buoyancy Element MSL Mean Seawater Line MTF Mechanical Transfer Function ROV Remotely Operated Vehicle STL Submerged Turret Loading 25 STP Submerged Turret Production SWL Safe Working Load TBD To Be Determined WROV Work ROV 30 The definitions used in this document shall be understood as follows: Buoy: Complete STL / STP Buoy comprising: WO 2014/178721 PCT/N02014/000032 2 Buoyancy Cone, Bearings, Turret, ESD valves, Buoy part of Hydraulic and Signal Connectors, Riser hang-offs and connections, Mooring connections and Pick-up Assembly. Connecting device: Chain connecting device that is permanently/fixed located in the 5 mooring line; also simply 'Connector' Operating device: Tool to operate the connecting device during tension adjusting operation; attachable to and detachable from the connecting device. Tensioning system: System comprising connecting device and operating device; also 10 called 'tensioner'. Mooring System: Complete mooring system comprising: Anchors, Chain, Wire, Polyster Rope, Mooring Line Buoyancy Elements and Connections. Riser System: Flexible riser and umbilical system from seabed to vessel. 15 Riser: Flexible riser for transfer of liquids and gases. Subsea System: Field related system comprising: Mooring, Buoy and Riser/umbilical System. Umbilical: Flexible umbilical for power/hydraulic and signal lines. 20 Mooring systems in deep and ultradeep waters often require use of polyester ropes, because of weight issues and vessel offset limitations. One drawback with polyester ropes is however that it creeps over time when subject to continuous loading. It also creeps when it experiences loads higher than it has seen earlier. Part of this creep can be mitigated by stretching the rope to a high tension during the offshore installation 25 campaign, but for practical reasons (installation vessel capabilities and safety) there is an upper limit on how much tension that can be applied. Hence, re-tensioning of polyester systems will most likely be required regularly over the design life of the field. Buoys do often not have any re-tensioning possibility, because that feature would grow 30 the size and the complexity of the Buoy. Re-tensioning has therefore been done as a combination of tensioning during installation (to typically 20-30% of the MBL for the WO 2014/178721 PCT/N02014/000032 3 polyester rope), and by opening the line, cutting chain and closing the line again, if later re-tensioning is required. The latter operation may however be expensive, as it typically requires large vessel(s) with significant winch/crane capacity, ROV, weather limitations, long planning due to limited number of vessels that can do the operation, 5 etc. There exists thus a need for a new tensioning system in order to simplify and reduce the cost/risk of the present tension adjusting methodology. 10 Summary The present invention is a mooring line tension adjusting system comprises a connecting device, connecting and locking two adjacent chain sections of a mooring line, and an operating device, moving one of the chain sections inside the connecting device to change the tension of the mooring line. The system has the inventive feature 15 that the operating device is remotely attachable to the connecting device before a tensioning operation and detachable from the connecting device after the tensioning operation. One of the parts comprised in the system is a connecting device, comprising a first 20 connection arrangement for a first chain and a second connection arrangement for a second chain wherein the first connection arrangement provides a permanently fixed connection of said first chain and the second connection arrangement provides a connection which can be modified by an operating device. The connecting device com prises a first docking element - for instance a pin - enabling the operating device to 25 firmly attach to the connecting device prior to performing a tension adjusting operation. The second part of the system is an operating device with a second docking element being compatible with the first docking element, enabling the operating device to 30 firmly attach to the connecting device to perform a tension adjustment operation.
WO 2014/178721 PCT/N02014/000032 4 A further aspect of the invention is a method for tensioning the mooring line with the tension adjusting system disclosed above. The method comprises a. positioning a surface vessel above the mooring line, slightly to the side of a connecting device, where two sections of the mooring line are connected by the 5 connecting device; b. attaching one end of a first chain or similar elongated element to one of two attachment points provided on a guide at an lower end of the operating device and attaching a first weight bar to the second end of the first chain; c. attaching a second chain or similar element, longer than the first chain to a second 10 attachment point on the guide at the lower end of the operating device and attaching a second weight bar to the second end of the second chain; d. attaching a lifting/handling equipment to a third attachment point at an upper end of the operating device; e. connecting an umbilical to a power system of the operating device, and to an power 15 supply system on board of the surface vessel; f. overboarding the operating device with the umbilical and accessories and lower it slightly above the same depth as the connecting device mounted into the mooring line; g. moving the vessel such that the second chain hits the connecting device, and by 20 moving the vessel slightly passed but without the second chain jumping over the operating device should rotate such that it orients correctly relative to the connecting device; h. lowering the operating device such that the connecting device is between the first and the second chain; 25 i. continuing to lower the operating device until it sits on top of the connecting device; j. after the lower end of the operating device has docked onto the connecting device sliding it down along the connecting device until it stops against a first docking element, a second docking element on the operating device connecting around the 30 first docking element; WO 2014/178721 PCT/N02014/000032 5 k. operating the operating device via the umbilical for pushing the mooring line in a tensioning direction; repeating this step until a requested tension is achieved; 1. lifting the operating device off the connecting device, unhooking from the first docking element. 5 Brief description of the drawings Below the invention will be described in detail with reference to the attached figures. Contents of the figures as follows: Figure 0.1 Typical mooring line composition including both rope and chain 10 parts. The inventive tensioning system may replace OS, UCS2 and SP Figure 0.2 Location of the tensioning system/connector in the mooring system Figure 0.3 Assembly of the connecting device and the operating device of the 15 tensioning system Figure 0.4 Fixed tensioner part with illustration of force direction from chain onto locking elements Figure 0.5 Connecting device of tensioning system Figure 0.6 General arrangement of the connecting device of the tensioning 20 system Figure 0.7 Operating device of the tensioning system Figure 0.8 General arrangement of operating device of tensioning system Figure 0.9 Docking of operating device onto connecting device Figure 0.10 Illustration of fixed and operating device including tensioned 25 chain and free end Figure 0.11 Illustration of docking of operating device onto connecting device Figure 0.12 Tensioning operation Figure 0.13 Slackening operation Figure 4.1 Mid Line Tensioning system 30 Figure 4.2 Mid Line Tensioner Connecting device Figure 4.3 Mid Line Removable Tool WO 2014/178721 PCT/N02014/000032 6 Figure 4.4 Locking Element in Connecting device Figure 4.5 Pushing Element in Operating device Detailed description 5 Main goal of this inventive concept is to manage regular tensioning adjustments of mooring lines - both tensioning and relaxing, in order to stay within the design envelope of the mooring system. The tensioning system shall not require a huge offshore campaign, and the operation shall be done with a relatively small vessel in combination with an ROV, without opening the mooring line. The re-tensioning 10 operation is planned conducted with a vessel with minimum crane or A-frame capacity, but equipped with an ROV/WROV that can observe the operation as well as operate the power (normally hydraulics) of the tensioning system. Alternatively, the power can be operated via an umbilical between the tensioner and the vessel. 15 The inventive tensioning system comprises two main parts; confer Figure 2.1 for a general illustration and figures 4.1, 4.2, 4.3, 4.4, 4.5 for details: - Connecting device; this component becomes a permanent/fixed part in the mooring line 20 - Operating device; this is a tool, used (only temporary) for the tensioning/slacking process, also called 'removable part' The operating device of the tensioner can be mounted/docked on top of the connecting device through a hook or similar arrangement at the lower end. During the tensioning 25 process the pushing element of the operating device pushes the upper chain towards the lower end of the connector. The movement of the chain unlocks the locking element of the connecting device, which remains unlocked until the chain has moved far enough for the locking element to drop down by gravity and thereby lock the chain again. The pushing element can then be retreated such that it can take a new grip and repeat the 30 sequence until the mooring line has been shortened to the desired length. Each cycle will typically move two chain links.
WO 2014/178721 PCT/N02014/000032 7 A corresponding operation can also be used to lengthen the mooring line thus reducing the tension, but this requires that the locking elements of the connecting device are lifted by the ROV when the pushing element has off-loaded the contact between the chain and the locking elements. Otherwise it will lock the chain from being moved 5 backwards. The tensioner will most likely be located above or below the Mooring Line Buoyancy Element (MLBE), as shown in Figure 1.1 and Figure 1.2. 10 The reason for dividing the tensioner into a fixed and a removable part is to minimize the permanent weight in the mooring system and thereby minimize the required buoyancy of the MLBE and the STL/STP Buoy. It will also reduce the overall cost since the same removable part can be used for all mooring lines, and maintenance of the hydraulic parts and the mechanical components will be easier. 15 A fixed weight for instance a hinged rod is attached to the connecting device in order to lower the overall centre of gravity and thus ensure that the connecting device is always upright. This weight may not be required. 20 The locking elements for the chain can be kept in place by plates on each side as well as a one-sided bolt with threads on one side and threadless and headless on the other side. This bolt is entered through the outer tensioner wall into the locking element and locked inside the element preferably with a ZipNut; see Figure 2.6. 25 When the bolt is fully fixed it is flush with the outer tensioner wall and free to rotate inside the hole in the wall. There is clearance between the wall opening and the bolt such that the load from the chain into the locking element and further into the support structure does not stress the bolt. Main reason for using the ZipNut technology is to be able to relatively easily replace the locking element with a WROV. 30 WO 2014/178721 PCT/N02014/000032 8 Hydraulically operated cylinders f. inst can be mounted on the operating device, preferably one on each side of the tool, in order to provide the required force to push the chain. Total available force from two hydraulic cylinders could be 150 tonnes, which means that each unit would have to provide minimum 75 tonnes. The cylinder 5 units will be connected together such that they provide the same push at the same time. Hydraulic pressure could be provided via a WROV or directly via an umbilical from the surface. The tensionadjusting system can be protected against corrosion in order to avoid any 10 degradation of the functionality due to the marine environment. However, since the operating device typical is only used temporarily, this protection needs only be considered to be applied to the connecting device. Operation procedure 15 The following provides a possible high level description of the tensioning operation. The main steps in the tensioning operation would be: 1) Position a surface vessel above the mooring line, slightly to the side of the connecting device. 20 2) Attach a chain or similar to one of the padeyes on the V-shaped guide at the end of the operating device. Attach a weight bar to the end of the chain. 3) Attach a longer chain or similar to the other padeye on the V-shaped guide at the end of the operating device. Attach a weight bar to the end of the chain. 4) Attach a lifting/handling wire to the padeye at the upper end of the operating 25 device. 5) Connect the (typically hydraulic) umbilical to the power system of the operating device, and to power providing unit on board the surface vessel. 6) Overboard the operating device with the umbilical and the chain accessories and weight bars and lower it to almost the same depth as the connecting device 30 mounted on the mooring line. Pay out the umbilical accordingly. The operating device should now be positioned slightly to the side (the side depends on which WO 2014/178721 PCT/N02014/000032 9 side of the operating device the longer chain is connected) of the connecting device, with the lower end of the weight bar connected to the short end above the connecting device and the other bar below the fixed bar. 7) Move the vessel such that the longer chain hits the connecting device. By moving 5 the vessel slightly passed but without the long chain jumping over the operating device should rotate such that it orients correctly relative the connecting device. 8) Lower the operating device such that the connecting device is between the two chain segments; confer Figure 3.1 and Figure 3.3. Continue to lower it until the operating device sits on top of the connecting device. After the lower end of the 10 operating device has docked onto the connecting device it will slide down the connecting device until it stops against the pin, which the hook shall connect to. Continue to pay out until the operating device has fully docked, and the hook is fully engaged around the pin. The hook will connect to the pin at a relative angle of 30 to 45 degrees between the fixed and operating device; 0 degrees is when 15 they are fully latched together. 9) With the supervision of an ROV, operate the hydraulic units via the umbilical to the surface vessel for the pushing the chain. Number of cycles of 2-link pushes depends on how much total length adjustment that is required, confer the pushing sequence shown in Figure 3.4 20 10) When the tensioning has been completed the operating device is lifted off the connecting device, and either lifted onboard the surface vessel or moved to the next mooring line. For slackening the system the same procedure can be used, but the cylinder pistons are 25 operated in the opposite direction, confer Figure 3.5. Another difference is that when the pushing segment release the stresses on the locking elements by pushing at the far end of the 2-link grip the locking elements on the connecting device must be lifted/opened by the ROV; otherwise the locking elements will prevent the chain from being moved backwards. The ROV will let the locking elements engage with the 30 mooring chain as soon as the first link has passed underneath the element.