NO335267B1 - Penetration and fluid transfer device - Google Patents

Abstract

A penetration device (20; 2CT) comprises drilling means (25, 40; 40 ') configured to form a hole (0) in a metal plate element (H). The drilling means is movably connected to a frame (21; 21 ') and the frame is connected to a leg assembly (34) having a base (29) of a magnetic material configured for magnetic connection to the plate element; wherein the leg assembly further comprises propellant (35, 36, 37) configured to selectively connect and separate the base to and from the plate member. Preferably, the penetration device comprises three leg assemblies (34) arranged in a tripod configuration.

Description

Penetrating and fluid transfer device and method Field of the invention

The invention relates to a penetration device as presented in the preamble to claim 1, a method for installing a penetration device in a plate body, as stated in the preamble to claim 12, a method for establishing fluid flow through a plate body, as stated in the preamble to claim 17, and a method for fluid transport as stated in the introduction to claim 18.

Background for the invention

Sunken ships often contain fluids that can be harmful to the environment if released into the surrounding seawater. Examples of such fluids are cargo oil, diesel oil, toxic gases and contaminated liquids.

Various devices for extracting fluids from sunken ships are well known. For example, WO 95/15280 (Mohn) describes a device for removing oil or toxic fluid from a submerged or submerged container, e.g. a tank in a sunken ship. The device has two parts; an upper active module comprising driving means and drilling or milling means for forming an opening in the wall, and a lower passive module comprising closing means operable by mechanical connection or pneumatic means by means of the first module. The lower module is attached to the wall by means of drill bits and includes sealing elements to prevent fluids from leaking through the holes drilled by the bits. The upper and lower modules are releasably connected to each other via locking claws and can be separated by controlling the upper module. The device is moved into position using thruster drives and can be remotely controlled from a remote monitor connected to a video camera mounted on the device.

US 2010/0058967 Al describes a device and a method for cutting and opening and closing a small opening in a wall on the seabed. The device comprises a foundation which has a large opening, and anchoring devices attached to the foundation and which are suitable for reversibly anchoring the foundation to a wall and keeping the large opening at a distance from the wall. A deformable stopper is attached to the foundation and means that the large opening can be opened or closed depending on whether the stopper is in or the open or closed position on the foundation. The stopper comprises a cylindrical wall which defines a cylindrical chamber which is aligned axially relative to the large opening on the underside of the platform. The cylindrical wall comprises an upper elastomeric seal on its upper edge suitable for forming a seal between the platform and the cylindrical wall, and a lower elastomeric seal on its lower edge suitable for forming a seal between the cylindrical wall and the bottom wall. The cylindrical wall also includes a cover-forming plate. Deformation means for deforming the stopper are attached to the foundation and are independent of the anchoring devices. There is further suitable for deforming the stopper to form a seal between the large opening and the bottom wall after the foundation has been anchored to the bottom wall. Circular cutters are attached to the foundation and are suitable for (i) moving through the large opening in the foundation to cut the small opening which is circular below the large opening when the stopper is in the closed position and the foundation is anchored to the bottom wall; and (ii) disengage from the large opening to allow the first opening to be opened when the stopper is in the open position.

The method described in US 2010/0058967 comprises the placement and anchoring of the foundation on a mainly horizontal wall on the seabed, and cutting the bottom wall. When the device has been lowered and anchored to the bottom wall, the stopper is deformed in such a way that a seal is established by deformation of the stopper between the large opening and the bottom wall. The cutter is then actuated to cut an opening in the wall. Once the hole has been drilled, the cutter is moved in the opposite direction (ie retracted) while maintaining the cylindrical wall where appropriate, pressed against said bottom wall in a sealing manner while the stopper is still in a position to close the large opening. Viscous liquid from the tank in a sunken and/or damaged ship lying on the seabed is collected by a shuttle reservoir that is lowered from the surface.

One purpose of the invention is to provide a device that is more versatile, lighter and less complicated than the known devices.

Summary of the invention

The invention is presented and characterized in main claims 1, 12, 17 and 18, while the independent claims describe other properties of the invention.

A penetration device is provided, comprising

- a frame with a foundation,

- a penetrating device configured to form a hole in a plate element, and

- propellants for driving the penetration device; characterized in that the penetration device is movable in relation to the frame and comprises - a continuous fluid channel which extends between an area of a free end of the penetration device and a coupling arranged on the opposite side; - valve means arranged and configured for selective opening and closing of the fluid channel; and - coupling devices for releasable coupling to the propellants;

whereby the penetration device and the penetration device can be selectively connected and disconnected from each other.

Embodiments of the penetration device according to the invention are specified in the independent claims 2-11.

There is also provided a method for installing a penetration device in a plate body, characterized by the steps of: a) placing a penetration device on the plate body; b) operating drive means to drive the penetration device to thereby create a hole in the plate body; c) sealingly locking the penetration device in the hole; d) operate coupling means to disconnect the penetration device from said

propellants; and

e) remove the penetration device from the plate body.

Embodiments of the method according to the invention are indicated in the independent ones

requirements 13-16.

A method is also provided for establishing a fluid channel through a plate body, characterized by) installing the penetration device according to the method according to the invention for installing a penetration device; in that the penetration device comprises a continuous fluid channel which extends between an area at the free end of the penetration device and an end connection arranged at the opposite end;

b) operating valve means to selectively open and close the fluid channel.

A method for transporting fluids between a sunk is also provided

vessel with a hull comprising at least one plate body, and a second vessel, characterized by the steps to:

a) installing a penetration device (40; 40') according to the method according to the invention for installing a penetration device; b) establishing a fluid channel according to the method for establishing a fluid channel through a plate body; and c) transporting fluids from the submerged vessel to the other vessel via a fluid umbilical cord.

The invented penetrating device is useful for draining sunken ships of fuel oil and for drilling holes in pressure vessels at desired positions. The device can also be used to inject fluids (e.g. gases) into containers. The invented device is remotely operated and designed to penetrate steel or metal plates in a variety of structures and or hull configurations. With the invention, it is possible to evacuate or introduce various substances in gas or liquid form through such plates. The invented device can, for example, but not necessarily, be limited to drill holes that are from 20 - 60 mm in diameter through wall thicknesses of, for example, 30 mm.

In one embodiment, the penetration device rests on three hydraulic legs (H-legs (eng.: H-legs), with underwater hydraulic cylinders), where each is equipped with a magnetic foot base mounted in a universal joint. The drill housing and handle are supported by three arms attached to the H-legs. The H-legs can act simultaneously or individually to set up the drilling unit in the correct position for drilling.

In one embodiment, the pilot drill is a hardened steel drill with a diameter of 10 mm. A circular hard metal hole drill is mounted on (i) a hardened steel adapter designed as an open center threaded stud or (ii) an open center adapter made with circular threads. In one embodiment, the hole drill comprises spring-loaded safety pins. The hole saw comprises a hardened steel ring with fluid openings in the periphery for the fluid (e.g. oil) oil to flow behind the circular drill plug which normally attaches to the drilling unit (pilot and hole drill head) after full penetration of the hull. A safety pin device is arranged integrated in the flow ring and is pushed out automatically (spring-loaded) on the inside of the hull when the penetrification is finished. The sealing device consists of a specially designed ring mounted on the drill adapter. For both adapters, the flange will automatically seal during the drilling process. The penetration device comprises a valve (e.g. a ball valve). The ball valve preferably rotates in a closed position during drilling (ie when the penetration device rotates). The valve handle is operated by an ROV.

The motor (eg hydraulic, variable speed) is attached to the whore housing, which is attached to the hydraulic legs. The attachment plate on the drill shank engages the drill plate on top of the ball valve and holds the position by means of magnetic force during the drilling operation.

The hydraulic cylinders simultaneously lightly push the penetrator (and drill bit) through the hull until the outer seal (e.g. sealing ring) abuts the hull plate.

When the penetration is finished (valve closed) the hydraulic cylinders retract the magnets by means of simultaneous movement, the magnetic force is neutralized, and the RO V can lift off the entire housing including the legs. The penetration device (including ball valve and quick release connector for the oil recovery hose) is now ready to be connected to the transfer/pump line to the surface. The pump unit is preferably a hydraulically driven peristaltic pump (hose pump) with good suction and pressure characteristics. The pump can run dry without damaging the construction. Variable capacity can in one embodiment be in the order of 100 - 44,000 liters per hour. The pump can be placed submerged approximately 10 - 15 m below the surface or, testing the viscous nature of the fuel oil, possibly on the deck of a support vessel. The invented penetration device makes it possible to penetrate a steel plate, achieve secure attachment to the plate, control the oil/water barrier and ensure safe transfer of fluids to the surface. The invented device allows drilling, penetration and attachment to the hull with a closed valve, in line.

The drill motor, liner and thruster for rotating and attaching the penetrating device are in one retractable unit supports to create a controlled passage to the tank inside the hull. The invention uses recent developments in magnet technology, which makes it possible to use magnets in applications in highly sensitive and safety-focused operations.

The drill is a combination of drill bits (pilot drill and hole saw) and threaded pin both for penetration and attachment to the hull. The combination as such is known from various types of tapping systems (eng.: hot-tap systems).

The tripod leg configuration makes the penetration device stable and useful for various hull shapes. It is suitable for small hulls with curved surfaces and which have small dimensions.

Brief description of the drawings

These and other features of the invention will be apparent from the following description of a preferred embodiment, given as a non-limiting example, with reference to the accompanying drawings, in which: Figure 1 shows a typical situation in which the device according to the invention is useful; Figure 2 is a perspective view of a first embodiment of the device according to the invention; Figure 3 is a perspective view of a first embodiment of the penetration device according to the invention; Figure 4 is a perspective view of the penetration device in Figure 3, in an installed position in a wall structure. Figure 5 is a perspective view of a second embodiment of the device according to the invention; Figure 6 is a perspective view of a second embodiment of the penetration device according to the invention; Figure 6b is a perspective view of a third embodiment of the penetration device according to the invention; without the link; and Figure 7a and Figure 7b are respectively a side view in cross section and a perspective view in cross section of the first embodiment of the penetration device according to the invention. The figures are not necessarily to the correct scale. They are intended to illustrate the various components according to the invention and shall not be limiting in terms of size and dimensions.

Detailed description of a preferred embodiment.

With reference to Figure 1, the invented underwater universal penetration device in the illustrated embodiment is operated and controlled from a vessel 10 on the surface S. The vessel comprises a module 12 for power supply and control of the penetration device, as well as for pumping fluids between the vessel 10 and f. e.g. a sunken ship 4 on the seabed B. An umbilical cable 14 having a bulk weight 11 and buoyancy elements 13 provides electrical and fluid communication between the vessel 10 and the sunken ship 4 and/or power and steering to a remotely operated vehicle (ROV) 3 for to operate the penetration device.

Figure 2 shows an embodiment of the invented penetration device 20 placed on a wall H, for example the steel hull of a sunken ship. The penetration device 20 comprises a penetration device 40 which has a hole drill 41 and a pilot drill 42. A drive motor 25 is operable to rotate the penetration device. Hydraulics and control cables, including their connections, necessary to operate the device are not shown.

The penetration device 20 comprises a further three leg assemblies 34, each comprising a leg 35 which has a base 29. The base 29 is of a magnetic material (preferably a permanent magnet), whereby the device 20 is connected via a magnetic force to the steel wall (e.g. hull) H. Each leg assembly includes a bushing 36 which is connected to the device 20 frame 21. A hydraulic cylinder 37 extends inside each bushing (not shown in Figure 2) and is configured to extend and retract the leg 35. Hydraulic pipe 39 is indicated in Figure 2.

Figure 5 shows another embodiment of the penetration device 20'. The three leg assemblies 34 as described above are connected to each other via a base plate 21'. The base plate 21' also carries the penetration device 40'. Figure 5 shows the penetration device in place on a hull H after a hole O has been drilled by the hole drill 41. The figure illustrates a demonstration configuration where the penetration device has been withdrawn from the drilled hole. In a normal mode of operation, the penetrating device 40' is set in place in the hole, as will be described below.

The hydraulic cylinders 37 can thus be operated to lower and raise the penetration device in relation to the hull H, on which the penetration device rests. While figure 2 shows the penetrating device in place with the legs 35 extended before a drilling operation starts, figure 5 shows the legs in a retracted state, i.e. where the penetrating device has been lowered towards the hull H. The penetrating device is connected to the hull via the magnetic sockets 29. The penetrating device can be released from the hull by pulling in the legs even further than is shown in Figure 5, i.e. by pulling the sockets away from the hull and into the bushing 36, where the bushings are used as stoppers to release the magnetic sockets from the hull.

In the embodiment of the penetration device 20' illustrated in Figure 5, the penetration device 40' is connected to and operated by means of a shaft 24 which is driven by a motor 25. The motor is suspended by means of support structures 38, which in turn are supported by the above-mentioned base plate 21 '. Reference number 31 indicates hydraulic lines, connected to e.g. a surface vessel as described above.

The penetration device 40' can be connected to the shaft via a quick coupling 23', which has a coupling and lock 22' (The quick coupling 23 and the lock 22 - to rotate the hole drill 41 and the pilot drill 42 - of the embodiment illustrated in figures 2 - 4 are also shown in the figures 3 and 4). Such coupling and rotation locks are known as such in the art.

The motor is movable in relation to the base plate 21' by means of a hydraulic cylinder 30a and feed piston 30b and is guided by means of guide rods 26. When the penetration device 40' is thus connected to the motor (via the above-mentioned connections) the hydraulic cylinder 30a can move the penetration device 40 ' up and down in the penetrator 20' (indicated by the double arrow MM) and thus drill a hole in the hull H. In a similar manner, the hydraulic sewing Unders 37 which control each leg 35 can also be operated to move the penetrator up and down relative to the hull H, as indicated by the double arrow ML).

Figure 4 shows the penetrator 40 in an installed position in a hull H, after the pilot drill and hole drill have drilled a hole in the hull, and the couplings have been separated to release the motor, legs and rest of the penetrator from the penetrator. The penetration device as illustrated in Figure 4 thus serves as a baffle through which fluids inside the hull H can be evacuated (It should be understood that it is also possible to feed fluids into the hull through this penetration device). A hose can be connected to the connector 23 in a manner known in the art.

As shown in Figures 7a and 7b, an internal fluid passage, or borehole, 49 is provided from the drill bit 46 and to the outlet 23b. The flow of fluid through the penetration device 40 is controlled by an internal valve (eg a ball valve, indicated as 27 in Figure 5), which is operated by means of a pin 28 via a tool commonly known in the art. In Figures 7a and 7b, the valve has been removed; only the operating pin 28 is illustrated.

With reference to Figure 3, the hole drill 41 comprises a threaded part 45 and a plurality of fluid openings 45 arranged in the wall between the threaded part and the hole drill bit 46. When the penetration device 40 is rotated (with the help of the motor) and moved towards the hull (with the help of the motor's feed cylinder 30a) and/or the legs' hydraulic cylinders 37) the pilot drill 42 drills a pilot hole in the hull. The hole drill 41 then cuts a hole in the hull. The penetration device is moved further into the drilled hole, so that a threaded part 45 above the hole drill is screwed tightly into the drilled hole. When the penetration device is thus installed in a hull H (as shown in Figure 4), the borehole and fluid ports are arranged on the inside of the hull and thus provide fluid communication between the volume behind

hull H and outlet 23b. As shown in figures 7a and 7b, a perforated disk 47, which has a number of openings 48, is arranged in the inner borehole 49 (the pilot drill 42 can also conveniently

be attached to the disc 47). When the penetration device 40 is thus installed in a hull (eg, as shown in Figure 4), and the valve is opened, fluids can flow through the perforated disc 47 and through the borehole 49.

A common problem when a hole saw is used is that the drilled disc remains inside the hole saw, in the area near the hole drill bit. Such a disk is indicated as "D" in Figure 7b. However, the flow path through the penetration device is not closed, as the fluids can flow into the fluid openings 43 and then through the openings 48 in the perforated disk 47.

The embodiment illustrated by figures 5 and 6a comprises spring-loaded pins 32 which are pressed into the hole drill as it passes through the hull, but emerge (to a position as shown in the figures) once they have penetrated the hull. These extended pins 32 prevent the penetration device from being pulled back out of the hole. A tightening ring 33 (see also figures 5 and 6) can also be rotated to come into contact with the hull surface and thereby further seal the connection between the penetration device and the hull.

Figure 6b illustrates another embodiment of the threaded part: in this embodiment, threads 44 are arranged on a part with a truncated cone shape, whereby the penetration device is gradually tightened in the drilled hole as the device is screwed into the hole.

A buoyancy element (not shown) may be attached to the penetration device to facilitate handling in the water.

The invented penetration device can be operated according to the following procedure:

1. The penetration device 20 is connected to the manipulator device of an ROV 3 at the surface S (ie on the surface vessel 10). Hydraulic lines are connected thereto using quick couplers. Power and control cables for (possible) surveillance cameras and lights (not shown) are also connected there. 2. The movable legs 35, with their respective magnetic sockets 29, are retracted inside the respective bushing 36. The ball valve 27 in the penetration device 40 is closed. 3. The area of the sunken vessel where the hole(s) are to be formed has been prepared and the desired penetration location(s) has been marked. 4. The RO V moves over the sunken vessel, places the penetrating device at the desired location on the vessel. The hydraulic cylinders 37 are activated to extend the movable legs 35 against the hull of the sunken

the vessel until the magnetic bases 29 are in contact with the steel surface (hull,

H). The penetration is now ready to start the operation.

5. The drilling procedure is activated (clockwise rotation) and controlled from the surface vessel. Monitoring via cameras and lights (not shown) in the base plate 21. The drive motor 25 is moved towards the hull with the aid of the hydraulic feed cylinder 30a, possibly simultaneously with operation of the leg assemblies' respective hydraulic

cylinder 37.

6. The drilling procedure depends on the type of penetration device 40 used:

a. With a threaded part 44 with a truncated cone shape (see figure 6b):

When the hole saw has penetrated the hull and formed a hole O, the truncated cone-shaped threads will have formed a tight (steel-to-steel) connection between the hull and the penetration device.

b. With a cylindrical threaded part 45 (see Figure 6a):

When the hole saw has penetrated the hull and formed a hole O, the spring-loaded pins 32 unfold on the inside of the hull. On the outside of the hull, the sealing ring 33 is rotated counterclockwise until it contacts the hull H. An O-ring (not shown) is preferred

arranged between the sealing ring and the hull.

7. The quick coupling 23; 23' is released, and the movable legs 35 are retracted (while the bushings 36 abut against the hull) to pull the magnetic sockets 29 away from the hull H. The penetration device structure (e.g. socket plate 21',

leg assemblies 34, drive motor 25 and hydraulic feed cylinder 30a) - which are now separated from the penetration device 40; 40' - lifted off from the hull and left

the penetration device is in place in the hull (see figure 4).

8. A fluid hose can now be connected (e.g. by means of the RO V) to the quick-connect part 23 of the penetration device. Valve pin 28 is operated to open the ball valve and a drain sequence can begin.

When a penetration device 40; 40' has been placed as described above, the penetrating device 20; 20' can be retrieved to the surface and connected to a new penetration device. In a salvage operation, where, for example, a harmful liquid is to be evacuated from a tank in the sunken vessel, a second penetration device can serve as an inlet opening for seawater and is operated so that the liquid evacuation is offset by the inflow of seawater.

Although the invention has been described with reference to hydraulic operation (of motor and actuators), the invention shall not be limited to such means of power.

It should also be understood that the operation of the penetrating device may be accompanied by distance sensors, torque sensors, etc.

It should also be understood that although the invention has been described with reference to an underwater application, the invention may also find application in other environments, e.g. within offshore.

Claims (20)

1. Penetration device (20; 20'), comprising - a frame (21; 21') with a foundation (34), - a penetration device (40; 40') configured to form a hole (O) in a plate element (H), and - drive means (24, 25) for driving the penetration device; characterized in that the penetration device (40; 40') is movable in relation to the frame and comprises - a continuous fluid channel (49) which extends between an area of a free end of the penetration device and a coupling end (23; 23b) arranged on the opposite side; - valve means (27, 28) arranged and configured for selective opening and closing of the fluid channel; and - coupling devices (22, 23; 22', 23') for releasable connection to the propellants (24,25); whereby the penetration device and the penetration device can be selectively connected and disconnected from each other. 2. The penetration device according to claim 1, in which the penetration device (40; 40') comprises a hole saw (41) arranged in an area of the free end and the driving means are arranged to rotate the penetration device. 3. The penetration device according to claim 2, where the penetration device (40; 40') also comprises a pilot drill (42). 4. The penetration device according to any one of claims 1-3, wherein the penetration device (40; 40') comprises a threaded part (44; 45) for sealing interaction with the hole. 5. The penetration device according to claim 4, in which the threaded part (44) comprises a part with a truncated cone shape. 6. The penetration device according to claim 4, further comprising first locking means (32) which are configured to prevent the penetration device from being removed from the hole, and second locking means (33) which are configured to be brought into contact with a hull surface, thereby sealing the connection between the penetration device and the hull. 7. The penetration device according to any one of claims 1-6, where the drive means (24,25) are movably connected to the frame (21; 21') via a guide and support device (26,38) and also comprise actuation means (30a,b) ) to move the propellants along a first path (MM) relative to the frame. 8. The penetration device according to any one of claims 1-7, wherein the foundation comprises leg assemblies (34) arranged in a tripod configuration; wherein each leg assembly (34) has a base (29) comprising a magnetic material configured for magnetic connection to the plate member; wherein the leg assembly further comprises driving means (35, 36, 37) configured to move the frame along a second path (Ml) and to selectively connect and disconnect the base to and from the plate member. 9. The penetration device according to claim 8, wherein the base comprises a magnetic material configured for magnetic connection to the plate element. 10. The penetration device according to any one of claims 7-8, wherein the first path (MM) and the second path (ML) are parallel. 11. The penetration device according to claim 10, where the first path is normal to a plane defined by the plate element (H) in which the hole (O) is formed. 12. Method for installing a penetration device (40; 40') in a plate body (H), characterized by the steps of: a) placing a penetration device (20; 20') on the plate body; b) operating drive means (24,25) to drive the penetration device (40; 40') to thereby create a hole (O) in the plate body; c) sealingly locking the penetration device in the hole; d) operating coupling means (22, 23; 22', 23') to disconnect the penetration device from said drive means (24,25); and e) removing the penetrating device from the plate body. 13. Method according to claim 12, where an intermediate step comes between step a) and step b), and this intermediate step comprises arranging the penetration device so that the penetration device moves along a first path (Mm) which is normal with respect to a plane defined by the plate body (H) where the hole (O) is made. 14. Method according to claim 12 or claim 13, where step b) comprises rotation of a hole saw (41) with a threaded part (44; 45) for sealing interaction with the hole. 15. Method according to claim 14, where, if the threaded part (44) comprises a truncated cone-shaped part, step b) further comprises rotating the penetration device until the penetration device is tightened in the hole. 16. Method according to claim 14, wherein, if the threaded part (45) comprises a cylindrical part, step c) further comprises an automatic operation of first locking means (32) configured to prevent the penetration device from being removed from the hole, and operation of second locking means (33) which is configured to be brought into contact with the hole surface, thereby sealing the connection between the penetrating device and the hull. 17. Method for establishing a fluid channel through a plate body (H), characterized by) installing a penetration device (40; 40') according to any one of claims 12-16; in that the penetration device (40; 40') comprises a continuous fluid channel (49) which extends between an area at the free end of the penetration device and an end connection (23b) arranged at the opposite end; b) operating valve means (27, 28) to selectively open and close the fluid channel. 18. Method for transporting fluids between a sunken vessel (4) with a hull comprising at least one plate body (H) and a second vessel (10), characterized by the steps o a: a) installing a penetration device (40; 40') according to any one of claims 12-16; b) establish a fluid channel according to claim 17; and c) transporting fluids from the vessel (4) which has sunk to the second vessel (10) via a fluid umbilical cord (14). 19. Method according to claim 18, wherein a second penetration device is connected to the penetration device, and steps a) and b) are repeated to install the second penetration device on the hull. 20. Method according to claim 19, where seawater is injected through the second penetration device and harmful liquids are evacuated from the hull through the first penetration device.