NO20160073A1 - Coupling with reducible holding capacity and method of disconnecting a structure from a remote mount - Google Patents

Abstract

Overload releasable coupling (1) wherein a coupling pin (1) comprises a locking hook housing (21) which accommodates a plurality of locking hooks (23, 25) adapted to engage a coupling housing (3) and engaging a locking hook actuator (1). 22) provided with a first piston (221) and a locking catch (222) associated with a second piston (2222), the pistons (221, 2222) being displaceable in the axial direction of the coupling pin (2) and defining a first and a second cylinder chamber (VI), respectively. , V2), wherein several secondary locking hooks (25) are radially fixed by the first piston (221); several primary locking hooks (23) are radially displaceable into the locking housing (21); the first cylinder chamber (VI) has a larger cross-sectional area than the second cylinder chamber (V2); and the cylinder chambers (VI, V2) are in fluid communication with a hydraulic fluid source (224). A method of disconnecting a structure (4) from a remote mount (6), wherein the structure (4) is connected to the attachment (6) via an elongate body (5) and the overload releasable coupling (1). 213

Description

COUPLING WITH REDUCIBLE HOLDING CAPACITY AND PROCEDURE FOR DISCONNECTING A STRUCTURE FROM A REMOTE ATTACHMENT

The invention relates to an overload-releasable coupling connected to an elongate body which connects a structure with a remote attachment, where a coupling pin comprises a locking hook housing which accommodates several locking hooks which are arranged to engage in locking engagement with corresponding grooves inside a side wall of a coupling housing and in a locking position rests against a locking hook actuator provided with a first piston and a locking hook lock which is connected to a second piston, said pistons being displaceable in the axial direction of the coupling pin and delimiting a first, respectively a second cylinder chamber. The invention also relates to a procedure for disconnecting a structure from a remote attachment, where the structure is connected to the attachment via an elongated body and the overload-releasable coupling.

In connection with fixing large structures, for example in connection with anchor systems for floating installations on offshore oil or gas field installations, there is occasionally a need to be able to release the structure quickly if a crisis situation arises. For that purpose, couplings are often used which have a weak link that breaks when the load exceeds a certain limit value. A disadvantage of known technology is that this load limit value is far higher than the load values that the structure normally imposes on the attachment. This can lead to great stress on the structure and the attachment points, for example the anchors on the seabed, and it is difficult to dimension the weak link in the coupling so that the coupling releases at a predetermined load, while at the same time the coupling does not represent a risk of accidental release of the structure.

An example of a release coupling for use on an anchor chain for a floating drilling rig is the Rig Anchor Release (RAR) model 6600 from InterOcean systems, Inc., San Diego, CA 92123, USA.

The purpose of the invention is to remedy or to reduce at least one of the disadvantages of known technology, or at least to provide a useful alternative to known technology.

The purpose is achieved by the features indicated in the description below and in the subsequent patent claims.

An overload-releasable coupling, in particular a coupling for releasing a structure from a remote, inaccessible attachment, comprises a coupling pin provided with several locking hooks which, in an active position, engages with one or more slots in an internal side wall of a coupling housing which encloses a significant proportion of the coupling pin. One of the coupling pin and the coupling housing is fixed in a first elongated body, for example a first length of anchor chain, and the other of the coupling pin and the coupling housing is fixed in a second elongated body, for example a second length of anchor chain, or said attachment, for example an anchor. A locking hook actuator arranged in the locking hook housing prevents the locking hooks from being retracted into a locking hook housing from their active, locking position. The detent actuator can release a set of primary detents from engagement in the clutch housing by supplying a hydraulic fluid to cylinder chambers in the detent actuator. The hydraulic fluid is preferably supplied from a connected accumulator through a remote-operated valve. A set of secondary locking tabs remain engaged with the clutch housing.

The reduction in the number of detents forming the locking connection between the coupling housing and the coupling pin may be a sufficient weakening of the coupling so that the shear forces applied to the secondary detents from the tensile forces generated in the elongate body of the attached structure may be sufficient to break the connection between the coupling housing and the coupling pin.

In an advantageous embodiment of the coupling according to the invention, the actuator is provided with an actuation element which, after releasing the primary locking hooks from locking engagement with the coupling housing, the coupling pin applies a thrust relative to the coupling housing in order to thereby speed up cutting of the secondary locking hooks.

The invention is defined by the independent patent claims. The independent claims define advantageous embodiments of the invention.

In a first aspect, the invention relates more specifically to an overload-releasable coupling associated with an elongate body that connects a structure to a remote attachment, where a coupling pin comprises a locking hook housing that accommodates several locking hooks that are arranged to engage in locking engagement with corresponding grooves inside of a side wall in a coupling housing and in a locking position rests against a locking hook actuator provided with a first piston and a locking hook lock which is connected to a second piston, said pistons being displaceable in the axial direction of the coupling pin and delimiting a first, respectively a second cylinder chamber, characterized by

several secondary locking hooks are radially fixed by the first piston;

an abutment surface on each of the secondary locking hooks abuts the first piston and is displaceable in the axial direction of the coupling;

multiple primary latches upon latch latch displacement away from the first piston are radially displaceable into the latch housing;

the first cylinder chamber has a larger cross-sectional area than the second cylinder chamber; and

said first and second cylinder chambers are in closable fluid communication with a hydraulic fluid source.

The hydraulic fluid accumulator can be arranged on the locking latch, and the fluid communication with the first and second cylinder chambers can be formed by one or more hydraulic fluid channels that extend through the locking latch.

The second piston may be formed as a rod portion projecting from the locking detent into a bore extending through the first piston.

A third piston can be arranged to rest against a flat part in the coupling housing and define a third cylinder chamber in an end wall of the locking hook housing.

The third cylinder chamber may be in closable fluid communication with the first and second cylinder chambers. The third cylinder chamber can more specifically be in closable fluid communication with the first and second cylinder chambers via a hydraulic fluid passage through the end wall of the locking hook housing.

The hydraulic fluid passage can be designed to accommodate a rod portion projecting from the second piston in a fluid-tight manner.

The hydraulic fluid source can be a hydraulic fluid accumulator arranged in the coupling pin.

The third cylinder chamber may be in closable fluid communication with a hydraulic fluid source via a second hydraulic fluid channel extending through the rod portion projecting from the second piston.

The second hydraulic fluid source can be a second hydraulic fluid accumulator arranged in the coupling pin.

The hydraulic fluid accumulator may be associated with a remote control valve arranged to at least open fluid communication between the hydraulic fluid accumulator and the first and second cylinder chambers.

The second hydraulic fluid accumulator may be associated with a remotely operated second control valve arranged to open fluid communication between said hydraulic fluid accumulator and the third cylinder chamber.

The bottom part of the coupling housing can be fitted with a protruding piston system.

In a second aspect, the invention relates more specifically to a method for disconnecting a structure from a remote attachment, where the structure is connected to the attachment via an elongated body and an overload-releasable coupling as described above, characterized by the method comprising the steps

in the case of a need for quick disconnection, to activate a locking hook actuator arranged in a coupling pin which is retained in a coupling housing, by supplying hydraulic fluid to a first cylinder chamber in the locking hook

the actuator;

relieving a set of primary latches by axially displacing a first piston in the latch actuator to thereby displace a set of secondary latches in the axial direction of the coupling pin; supplying the hydraulic fluid to a second cylinder chamber in the latch actuator;

releasing the clutch housing from a set of primary locking lugs engaging the clutch housing by axially displacing a locking lug detent away from a supporting abutment against the primary locking lugs; and applying to the secondary locking hooks a shear force sufficiently large to break loose locking hook fragments from an engaging portion of the secondary locking hooks.

The method may include the further step

to supply the hydraulic fluid to a third cylinder chamber in the locking hook actuator to thereby displace a third piston into contact with a bottom portion and to apply an axially directed thrust force to the coupling pin to thereby apply an increased shear force to the secondary locking hooks.

In what follows, an example of a preferred embodiment is described which is visualized in the accompanying drawings, where: Fig. 1 shows in perspective a principle sketch of an anchoring system with a releasable coupling according to the invention; Fig. 2 shows on a larger scale a side view of the assembled coupling; Fig. 3 shows a plan view of the assembled coupling; Fig. 4 shows a side view of a coupling pin; Fig. 5 shows a plan view of the coupling pin; Fig. 6-9 shows on a larger scale axial section A-A according to figures 3 and 5 of a first embodiment of the coupling in various phases of disengagement of primary locking hooks and separation of coupling pin and coupling housing in case of breakage in secondary locking hooks; Fig 10 shows a second embodiment of the coupling in a phase of disengagement of the primary locking hooks,

where the coupling is provided with two hydraulic fluid sources (shown schematically); and

Fig. 11 shows, on a smaller scale, a partially cross-sectional side view of an embodiment of the coupling pin and the coupling housing integrated in respective housings with attachment ears for connection to a fastening element.

Reference is first made to Figure 1 where a floating structure 4, shown here as a drilling rig, is attached via attachment elements in the form of elongated bodies 5, typically anchor chains, in respective fasteners 6, typically bottom anchors. A detachable coupling 1 is arranged between the elongate body 5 and the attachment 6.

Figures 2, 3, 4 and 5 show the coupling in greater detail, as a coupling pin 2 is releasably held in a coupling housing 3 by means of several locking hooks 23, 25.

Reference is made in particular to figure 6. The central axis of the coupling 1 is indicated by the reference number 11. The coupling pin 2 comprises a locking hook housing 21 which accommodates a locking hook actuator 22.1 radial recesses 213 in the locking hook housing 21, a set of primary locking hooks 23 is arranged, in this embodiment a total of six primary locking hooks 23 grouped in pairs, and a set of secondary locking hooks 25, in this embodiment three secondary locking hooks 25 arranged between the groups of primary locking hooks 23. The locking hooks 23, 25 are fixed in the locking hook housing 21 in respective hinge joints 24, respectively 26 pivotable in the locking hook housing 21's radial direction. The hinge joints 24, 26 are formed with a radial slack that allows a vertical displacement of the locking hooks 23, 25. The locking hooks 23, 25 are in a normal state with end surfaces 233, 253 respectively supporting a locking hook system 214 which delimits the locking hook recesses 213 in the locking hook housing 21 away from the hinge joints 24, respectively 26, as shown in Figure 6.

The locking hooks 23, 25 are provided with an outside/ending engagement part 232, respectively 252 which are complementary with internal grooves 32, 33 arranged inside a side wall 31 of the coupling housing 3.

In a normal state for the coupling 1, as shown in figure 6, the locking hooks 23, 25 are engaged with the coupling housing 3's grooves 32, 33. The secondary locking hooks 25 are provided with a ridge 251 which extends towards a first piston 221 in the locking hook actuator 22 , in that a contact surface 254 in the end part of the secondary locking hook 25 is arranged to be able to rest against an annular seat surface 2211 which extends in the radial direction of the first piston 221.

In the latch housing 21, a first cylinder chamber Vi is formed between an end wall 211 and the first piston 221. The end wall 211 is provided with a projecting middle part 2111 which is enclosed by an annular end part 2213 of the first piston 221, said end part 2213 delimiting the first cylinder chamber Vi in a radial direction in a fluid-tight manner. The first piston 221 is arranged axially displaceable in the locking hook housing 21. From the annular seat surface 2211 of the first piston 221, a projecting middle part 2214 extends in the axial direction. A bore 2212, here shown as a center bore, extends through the first piston 221.

A locking detent 222 is arranged concentrically with the first piston 221 axially displaceable in the detent housing 21. A peripheral surface of the detent 222 forms an abutment surface 2225 for the ridge 231 of the primary detent 23. The abutment surface 2225 is interrupted by radial recesses 2226 arranged to accommodate the ridge 251 of the secondary detent 25 .

A ring-shaped end part 2221 of the locking detent 222 is arranged to be able to enclose the protruding central part 2214 of the first piston 221. A rod-shaped part 2222 projects in the axial direction from the detent 222 and into the central bore 2212 of the first piston 221 and forms a second piston as the rod part 2222 ends fluid-tight against the wall of the center bore 2212. A second cylinder chamber V2 is delimited by the first cylinder chamber Vi, the center bore 2212 and the second piston 2222.

A rod end portion 2223 with a reduced cross-section is arranged to be able to protrude fluid-tightly into a fluid passage, here shown as a central bore 212 in the end wall 211 of the locking hook housing 21 axially coinciding with the bore 2212 in the first piston 221.

The latch actuator 22 is connected to a hydraulic fluid, here shown as a hydraulic fluid accumulator 224 which projects from the latch latch 222 and is in fluid communication with the first cylinder chamber V1 and the second cylinder chamber V2 via hydraulic fluid channels 2224 that extend through the latch latch 222 and the second piston 2222. A control valve 225 is arranged between the hydraulic fluid accumulator 224 and the hydraulic fluid channels 2224. The control valve 225 is remotely operated, here indicated by the fact that the control valve 225 is provided with a valve actuator 2251, a transmitter/receiver 2252 and an energy source (battery) 2253.

In the shown embodiment of the coupling 1, a third cylinder chamber V3 is formed in the end wall 211 of the locking hook housing 21 in a recess 2112 opposite the protruding middle part 2111 of the end wall 211. The third cylinder chamber V3 is delimited by a third piston 215 which is axially displaceable in the recess 2112 and lies fluid-tight towards the periphery of the recess 2112. The third piston 215 is designed to be able to rest against a piston system 341 which projects from an end wall 34 in the coupling housing 3. The third cylinder chamber V3 is in shut-off fluid communication with the first and second cylinder chambers Vi, V2 through the center bore 212 in the end wall 211 Said fluid communication is controlled by the locking latch 222 through the axial position of the rod end portion 2223. A piston recess 2151 is arranged to be able to accommodate a part of the rod end part 2223.

When there is a need to break the connection between the attached structure 4 and the attachment 6, the control valve 225 of the coupling 1 is activated. Hydraulic fluid flows from the hydraulic fluid accumulator 224 and through the hydraulic fluid channels 2224 in the locking latch 222 and into the first cylinder chamber Vi and the second cylinder chamber V2. Due to the difference in cross-sectional area of said cylinder chamber Vi, V2, the first piston 221 will be displaced first. Due to the contact between the contact surface 254 and the seat surface 2211 and the radial slack in the secondary locking hook hinge joint 26, the secondary locking hooks 25 will be displaced in the axial direction of the coupling. As the secondary coupling hooks 25 are engaged in the coupling housing 3's grooves 32, 33, the coupling housing 3 is thus displaced in relation to the coupling pin 2 so that the primary locking hooks 23 are relieved. The first cylinder chamber We have now reached its maximum size. See Figure 7.

When the axial displacement of the first piston 221 has ceased, the locking detent 222 is then displaced in the axial direction away from its abutment against the primary locking jaw ridges 231 by means of the hydraulic pressure against the second piston 2222, as the secondary cylinder chamber V2 expands, and the primary locking detents 23 can thus swing freely inwards into its recesses 213. The coupling housing 3 and the coupling pin 2 are now held together by a reduced number of locking hooks 25. In this condition, the load that the structure 4 applies to the coupling 1 through the elongated body 5 can be sufficiently large that the secondary locking hooks 25 are cut off and the structure 4 is released from the attachment 6. Figure 7 shows the locking detent hook 222 in the process of being displaced, and Figure 8 shows the coupling housing 3 released from engagement with the primary locking hooks 23.

By the fact that the coupling 1 in the embodiment shown is provided with a further, third piston 215, the third piston 215 will be supplied with hydraulic fluid during the axial displacement of the locking pawl 222 in a final phase of the movement of the locking pawl actuator 22 as the rod end portion 2223 pulls out of the end wall 211's central bore 212 and opens for fluid communication between the first cylinder chamber Vi and the third cylinder chamber V3, as shown in Figure 8. When the third piston 215 abuts against the clutch housing 3 piston system 341, the load on the secondary locking hooks 25 increases, and this ensures that the secondary locking hooks 25 are cut off and the coupling 1 is released as shown in figure 9, where locking hook fragments 255 have been cut from the secondary locking hook 25.

For the purpose of joining the coupling 1, the coupling housing 3 is separable (not shown) so that at least the first piston 221 can be coupled with the rest of the locking hook actuator 22 after the secondary locking hooks 25 have engaged in the grooves 32, 33 in the coupling housing 3.

The end wall 211 in the locking hook housing 21 is preferably detachable so that the locking hook actuator 22 can be pulled out of the coupling pin 2 for adaptation of the coupling pin 2 to other load conditions, for example when replacing pistons 221, 2222 and locking hooks 23, 25.

Reference is then made to Figure 10. In a second embodiment of the coupling 1, the second piston 2222 of the locking hook actuator 22 is provided with a further hydraulic fluid channel 2227 which opens into the free end of an extended rod end portion 2223'. In this embodiment, the length of the rod end portion 2223' is so large that the hydraulic fluid channel 2227 opens into the bore 212 in the end wall 211 when the locking jaw detent 222 is displaced to its axial outer position against the locking jaw housing 21, as illustrated in figure 8.1, this embodiment is controlled by the supply of hydraulic fluid to the third cylinder chamber V3 independent of the supply to the first and second cylinder chambers Vi, V2. in that the hydraulic fluid channels 2224, 2227 are each assigned to a control valve 225, respectively 225', shown here as a three-part directional valve with a closed center. When a hydraulic fluid accumulator is used as a hydraulic fluid source, it is advantageous to arrange a hydraulic fluid accumulator 224, respectively 224' to each of the control valves 225, 225', as shown in Figure 8, to ensure that there is sufficiently large hydraulic pressure in any operational situation .

Although it is an advantage to arrange hydraulic fluid sources in the form of hydraulic fluid accumulators 224, 224' integrated into the coupling 1, it does not preclude the use of a remote hydraulic fluid source which is, for example, arranged on the fixed structure 4 and connected to the coupling 1 via a wire (not shown) which is guided along the fastening element 5. This can be particularly useful when the structure

4 is located in shallow water and there is a short distance from structure 4 to connection 1.

Figure 11 shows the coupling 1 arranged in outer housing sections 27, 35 provided with attachment ears 271, 351 for connection to the attachment element 5. The latch housing 21 is releasably attached inside a first, outer housing section 27, for example with threads (not shown). The coupling housing 3 is releasably fixed internally in a second, outer housing section 35, here by means of a locking ring 353 which rests against the end of the coupling housing 3, and is typically connected to the second, outer housing section 35 by means of threads (not shown). In order to prevent the locking hooks 23, 25 from being subjected to undue stress due to torsion via the fixing element 5, the housing sections 27, 35 are provided with engagement elements, here shown as pins 272 which extend in the axial direction of the first housing section 27 to engage in corresponding recesses 352 in the second house section 35.

It should be noted that all of the above embodiments illustrate the invention, but do not limit it, and those skilled in the art will be able to devise many alternative embodiments without departing from the scope of the appended claims. In the requirements, reference numbers in parentheses should not be seen as limiting.

The use of the verb "to comprise" and its various forms does not exclude the presence of elements or steps not mentioned in the claims. The indefinite articles "an", "ei" or "et" before an element do not exclude the presence of several such elements.

The fact that certain features are listed in mutually different dependent claims does not indicate that a combination of these features cannot be advantageously used.

Claims (15)

1. Overload-releasable coupling (1) associated with an elongated body (5) which connects a structure (4) with a remote attachment (6), where a coupling pin (1) comprises a locking hook housing (21) that accommodates several locking hooks (23, 25) which is designed to engage in locking engagement with corresponding grooves (32, 33) internally on a side wall (31) in a coupling housing (3) and in a locking position rests against a locking hook actuator (22) provided with a first piston ( 221) and a locking detent (222) which is connected to a second piston (2222), said pistons (221, 2222) being displaceable in the axial direction of the coupling pin (2) and delimiting a first, respectively a second cylinder chamber (Vi, V2), characterized moreover several secondary locking hooks (25) are radially fixed by the first piston (221); an abutment surface (254) on each of the secondary locking hooks (25) rests supportingly on the first piston (221) and is displaceable in the axial direction of the coupling (1); several primary locking hooks (23) upon displacement of the locking hook lock (222) away from the first piston (221) are radially displaceable into the locking hook housing (21); the first cylinder chamber (Vi) has a larger cross-sectional area than the second cylinder chamber (V2); and said first and second cylinder chambers (Vi, V2) are in closable fluid communication with a hydraulic fluid source (224). 2. Overload-releasable coupling (1) according to claim 1, where the hydraulic fluid accumulator (224) is arranged on the locking detent (222), and the fluid communication with the first and second cylinder chambers (Vi, V2) is formed by one or more hydraulic fluid channels (2224) which extends through the locking latch (222). 3. Overload-releasable coupling (1) according to claim 1, where the second piston (2222) is formed as a rod part that protrudes from the locking detent (222) and into a bore (2212) that extends through the first piston (221) ). 4. Overload-releasable coupling (1) according to claim 1, where a third piston (215) is arranged to rest against a bottom part (34) in the coupling housing (3) and delimits a third cylinder chamber (V3) in an end wall (211) ) in the locking hook housing (21). 5. Overload-releasable coupling (1) according to claim 4, where the third cylinder chamber (V3) is in closable fluid communication with the first and second cylinder chambers (Vi, V2). 6. Overload-releasable coupling (1) according to claim 4, where the third cylinder chamber (V3) is in closable fluid communication with the first and second cylinder chambers (Vi, V2) via a hydraulic fluid passage (212) through the end wall (211) of the latch housing (21) ). 7. Overload-releasable coupling (1) according to claim 6, where the hydraulic fluid passage (212) is designed to accommodate a rod portion (2223) projecting from the second piston (2222) in a fluid-tight manner. 8. Overload release coupling (1) according to any one of claims 1-7, where the hydraulic fluid source is a hydraulic fluid accumulator (224) arranged in the coupling pin (1). 9. Overload release coupling (1) according to claim 4, where the third cylinder chamber (V3) is in closable fluid communication with a second hydraulic fluid channel (224') via a second hydraulic fluid channel (2227) which extends through a rod portion (2223^) which projects from the second stamp (2222). 10. Overload-releasable coupling (1) according to claim 9, where the second hydraulic fluid source is a second hydraulic fluid accumulator (224') arranged in the coupling pin (1). 11. Overload release coupling (1) according to claim 8, where the hydraulic fluid accumulator (224) is connected to a remote control valve (225) arranged to at least open fluid communication between the hydraulic fluid accumulator (224) and the first and second cylinder chambers ( Vi, V2). 12. Overload release coupling (1) according to claim 10, where the second hydraulic fluid accumulator (224') is connected to a remotely operated second control valve (225') arranged to open fluid communication between said hydraulic fluid accumulator (224) and the third cylinder chamber (V3) . 13. Overload-releasable coupling (1) according to claim 4, where the bottom part (34) in the coupling housing (3) is provided with a protruding piston system (341). 14. Procedure for disconnecting a structure (4) from a remote attachment (6), where the structure (4) is connected to the attachment (6) via an elongated body (5) and an overload-releasable coupling (1) according to claim 1, characterized in that the procedure includes the steps in case of need for rapid disconnection, to activate a locking hook actuator (22) arranged in a coupling pin (2) which is retained in a coupling housing (3), by supplying hydraulic fluid to a first cylinder chamber (Vi) in the locking hook actuator (22); relieving a set of primary locking hooks (23) by axially displacing a first piston (221) in the locking hook actuator (22) to thereby displace a set of secondary locking hooks (25) in the axial direction of the coupling pin (2); supplying the hydraulic fluid to a second cylinder chamber (V2) in the locking hook actuator (22); releasing the coupling housing (3) from a set of primary locking hooks (23) engaging the coupling housing (3) by axially displacing a locking hook detent (222) away from a supporting device against the primary locking hooks; and applying to the secondary locking hooks (25) a shearing force sufficiently large to break free locking hook fragments (255) from an engaging portion (252) of the secondary locking hooks (25). 15. The method according to claim 14, where the method comprises the further step to supply the hydraulic fluid to a third cylinder chamber (V3) in the locking hook actuator (22) to thereby displace a third piston (215) into contact with a bottom part (34) and to apply an axially directed thrust to the coupling pin (2) to thereby apply the secondary locking hooks (25) an increased cutting force.