NO328744B1 - Device for immediate node decoupling of a load, and wire cutter device and vessel including the same - Google Patents

Abstract

For instant decoupling of a load connected to a vessel by a wire, cable, chain or the like (1) carried on an upper side of an assigned portion of an open vessel deck (2), a decoupling device (100), a multiple disconnecting device - devices, and a vessel with a disconnect device or a wire cutter device installed in or under the assigned part of the vessel deck. The disconnecting means includes an elongate and longitudinally substantially rectangular outer housing (10) which contains an elongated and substantially longitudinal explosive portion (40) which includes at least one explosive unit shaped as a directed charge with a firing side, and a coupling side for firing side the elongated outer casing of the vessel deck in or below the assigned portion of the vessel deck.

Description

The invention finds particular application for cutting wire/chain in a towing or lifting operation, such as an anchor wire or an anchor chain in an anchor handling situation.

In connection with offshore operations involving towing or anchor handling, it may happen that the tow or the anchor being handled has performed unexpected or unintended maneuvers that may entail a risk of damage to or loss of a vessel involved in the towing activity or anchor handling. However, the dangerous situations have most often been averted by winching out the wire or chain that connects the vessel to the uncontrolled tow or the anchor, or by more drastic measures such as cutting the wire or chain. Unfortunately, there have nevertheless been serious incidents in similar situations where the tow or the anchor has carried out unexpected or unintentional maneuvers at such a pace that one has not had the opportunity to remove the uncontrolled load on the wire or chain quickly enough, which has thus led to serious risk or damage to the vessel or crew, and in the worst case accident with loss of vessel or life.

Similar issues have been addressed in connection with trawlers, and the published international patent application PCT/EP2007/051518 describes a system to prevent accidents, such as capsizing, which can occur as a result of high tension in trawl cables. The system comprises a tension sensor device for a trawl cable, a vessel streak detector, an alarm system and a cable cutter. The cable cutter is of the pyrotechnic type, with a housing that encloses the cable in its circumferential direction. A hole charge is placed in the housing which partially surrounds the cable. The system is designed to detect abnormal tension in the trawl cable which may lead to capsize, and upon detonation of the hollow charge to cause a point on the cable to be fired with a beam and/or exposed to heat and/or pressure which may result in the cable being cut .

The published international patent application PCT7EP2007/051572 describes a cable cutter of the pyrotechnic type, with a hollow charge placed in a housing through which the cable is passed. The hole charge is given a V-shaped cross-section, is shaped as part of a circular arc, and thus partly surrounds the cable. By being shaped as part of a circular arc, the impact from detonating the hollow charge will be focused towards a focal point. The housing includes a device for positioning a part of the cable to be cut centrally in relation to the focal point.

Patent publication US3089417 describes a pyrotechnic cable cutter for use in aircraft with an emergency release cockpit for cutting control cables between the cockpit and the aircraft's control surfaces. The cable cutter includes a device for attaching an explosive to the cable at the point of the cable where it must be cut in an emergency to ensure that the cockpit will be disconnected from the rest of the fuselage. In one embodiment, the cable cutter is formed by an annular holder that encloses the cable in its circumferential direction, and a substantially rectilinear, elongated hollow charge explosive with a detonator, attached to the attachment device in close proximity to and tangential to the cable.

Patent publication US2920532 describes a cable cutter with a V-shaped hollow charge explosive placed in a housing, and an arrangement for holding a cable to an open end of the housing where material from the explosive will flow out upon detonation. The V-shaped surface of the explosive is coated with a layer.

Patent publication US2185303 describes a pyrotechnic cable cutter where a piston is placed in a cylinder, and where the cylinder has an explosive installed at a first end which, upon detonation, drives the piston to move through the cylinder. At the other end of the cylinder, a knife device is placed in a housing which in part also encloses the cable. When the knife device is hit by the piston, it is driven against the cable so that the cable is weakened or cut.

The known cable cutters of the pyrotechnic type comprise an all-enclosing enclosure or guide designed to prevent substantially any movement of the cable across the longitudinal direction of the cable so that it is at all times in the point of action of the hollow charge explosive, or they are designed to operate at a specific point on the cable, and is unsuitable for installation or use on vessels that are hoists, towing vessels or anchor handling vessels where wire, cable or chain must be guided and winched over an open deck and where there is no suitable place for placing such enclosing installations or cable-mounted devices .

To solve the above-mentioned and other problems, the present invention provides a device for instantaneous cutting of a cable or the like according to independent patent claim 1, a wire cutter device according to claim 17, and a vessel according to claim 18.

Further advantageous features of the present invention's device for instantly cutting a cable or the like appear from the accompanying independent patent claims 2-16.

The device of the invention is adapted for installation in or under a ship's deck on a vessel that takes part in a towing or lifting operation, such as for example in a towing or anchor handling vessel used in offshore operations, immediately under the deck plate in a part of a deck such as chain, wire or similar is passed over. The device installed below the vessel's deck works by producing a cutting action which penetrates and cuts the chain, wire or similar at a point or place where it is passed over the deck. The device of the invention is preferably dimensioned so that it can cause cutting or significant weakening of a cable, chain, wire or the like, in particular a wire with dimensions up to 0=1 lOmm or a chain with dimensions up to 0=130mm. When installed under the deck plate, the device of the invention also causes a penetration of the ship's deck, is preferably dimensioned to penetrate deck plates with a thickness of around or in excess of 40mm, and with the capacity to cut or weaken wire or chain with the aforementioned dimensions.

In an advantageous embodiment of the device of the invention, it comprises an active part formed from a high-speed (i.e. fast-reacting) thermally reactive material, such as an explosive or explosive, which upon initiation (detonation) produces the intended penetration and cutting action, where this occurs at enormously high speeds and for the purposes of the invention is to be regarded as instantaneous.

The mode of operation of the device of the invention is as follows:

The thermally reactive mass is shaped and placed so that a thermal reaction develops a pressure in the direction of the aforementioned chain, wire or similar, and, if installed under a cover plate, also the cover plate, which typically leads to such stresses in the target material, and in part also such heat influence that the flow limit of the target material is exceeded. Upon impact, the target material dissolves so that, in the case of the aforementioned chain, wire or the like, the aforementioned cable, chain, wire or the like is cut almost instantly.

The thermally fast-reacting mass is arranged so that during the reaction it provides a geometric focusing towards a convergence point, a convergence line or a convergence plane of pressure, possibly also material and heat, which is launched during the reaction. The individual explosive unit exhibits a thermally reactive mass with a V-shaped, pyramidal or cone-shaped surface on the launch side and is thus arranged to launch a shock wave, material or heat in a converging flow towards a convergence area, which is adapted so that the convergence point lies in or near the center of the object to be cut. In order to enhance the aforementioned effect, metallic additives are added in such a way that a significant amplification of the effect is achieved in the convergence point of the geometric focus in the thermally reactive mass. An example of such reinforcement is described in the following text. In what follows, the term explosive is mainly used as a general term for such thermal masses which are suitable for carrying out the invention.

In the following, the invention will be explained in more detail with the help of various design examples and with references to the accompanying drawings, where: figure IA is a side view illustrating a typical vessel for raising, lifting, towing or anchor handling,

figure IB is a perspective view showing part of a stern of the vessel illustrated in figure IA and a below deck installed wire or chain cutter device according to the present invention,

Figure 1C is a longitudinal sectional view of a portion of the stern illustrated in Figure IB illustrating the below deck installation of a wire or chain cutter device according to the present invention,

Figure 2 is a perspective view showing an enlarged portion of an illustration in Figure IB of the underdeck installed wire or chain cutter device according to the present invention,

Figure 3 is a longitudinal sectional view of the stern showing an enlarged portion of the illustration in Figure 1C of the below deck installation of the wire or chain cutter device according to the present invention,

figure 4A is a schematic cross-sectional view of an installation with a first embodiment of a wire or chain cutter device according to the present invention,

figure 4B is a schematic longitudinal section view of an installation with the first embodiment of a wire or chain cutter device according to the present invention,

figure 5 is a schematic cross-sectional view of an installation with a second embodiment of a wire or chain cutter device according to the present invention,

Figure 6 is a schematic longitudinal section view of an installation with the second embodiment of a wire or chain cutter device according to the present invention,

figure 7 is a schematic cross-sectional view of an installation with a third embodiment of a wire or chain cutter device according to the present invention,

figure 8 is a schematic longitudinal section view of an installation with the third embodiment of a wire or chain cutter device according to the present invention,

Figure 9A is a schematic cross-sectional illustration of a first arrangement of individual explosives in the third embodiment of a wire or chain cutter device according to the present invention, and

Figure 9B is a schematic cross-sectional illustration of a second arrangement of single explosives in the third embodiment of a wire or chain cutter device according to the present invention.

Figure IA illustrates a typical vessel for hoisting, lifting, towing or anchor handling. The vessel has a large, open aft deck which typically has a winch arrangement on the end facing the bow, and the end facing aft is open so that objects being handled, such as anchor chain or anchor, can be winched up over the stern and possibly onto covered. Figure IB illustrates in more detail by way of example the stern of the vessel with a cable, wire or chain 1 which is in the process of being raised, lowered or lowered and which is led over the stern deck 2 towards the winch arrangement (not shown), and manipulation devices 3 which typically are in the form of shark jaws and/or rope pegs for holding cable, wire or chain, respectively guiding the aforementioned. Dashed lines illustrate a wire and chain cutter 100 according to the present invention as installed under the deck 3, or as built into the deck 3. Figure 1C shows in a longitudinal section view through the stern of the vessel, cable, wire or chain 1, manipulation devices 3 for locking or guiding said cable, wire or chain 1, the deck 2, and also in cross-section a wire and chain cutter 100 according to the present invention as installed under the deck 3, or as built into the deck 3.

In an enlarged view, figure 2 illustrates in perspective the vessel deck with manipulation devices, and in dotted line an advantageous placement of a wire and chain cutter according to the present invention, as installed under the deck, or as built into the deck. The invention thus fulfills the need for and the requirement that the deck should be free of installations other than the manipulation devices that are necessary to hold or guide the relevant cable, wire or chain that is being handled, but at the same time ensure that means are available at all times in a emergency to immediately be able to cut the relevant cable, wire or chain. As shown in the dashed line, in an advantageous arrangement of a wire and chain cutter according to the present invention, as installed below the deck, or as built into the deck, the device of the invention is arranged on the vessel immediately aft of the manipulation devices, and is provided with a length of across the longitudinal direction of the vessel which corresponds to at least the largest possible displacement of wire or chain across the longitudinal direction of the vessel at the installation location of the device.

In the enlarged view, figure 3 illustrates in a longitudinal section through the stern of the vessel also the vessel deck with manipulation devices, and some details of a pyrotechnic cutter device in an advantageous location according to the present invention, as installed under the deck, or as built into the deck. Particular reference is made to the trapezoidal cross-section of the device of the invention, which by diagonal shading indicates a housing part of the device, and by internal grid shading indicates the active parts of the device according to the invention.

For the further detailed description, the term wire will be used to indicate a cable, wire, chain or the like which must be cut instantly in an emergency situation when using the invention.

Reference is then made to figures 4A, 5 and 4B as illustrative cross-sections and top views, respectively, for the following explanation of an example of a first embodiment of the wire cutter device 100 according to the invention, and furthermore its installation or location under a vessel's deck in an area where the wire is guided. The first embodiment of the wire cutter 100 of the invention is an elongated assembly which includes an elongated, external housing 10 of a rigid and strong construction formed by a base 11 and four side walls 12,13,14,15, preferably made of steel, a layer of damping material 20, preferably made of polyurethane of uniform thickness, as a layer which mainly covers the inside bottom and side walls of the outer housing 10 and thus forms a damping intermediate housing consisting of a bottom 21 and four side walls and end walls, 22,23 and 24,25 respectively, a inner housing 30 formed by a base 31 and a total of four side walls and end walls, 32,33 and 34,25 respectively, which are shape-matched to the internal shape of the damping material layer formed by the intermediate housing and which are preferably made of steel or other strong material which can be of uniform thickness , and an explosive part 40 which consists of an elongated explosive element which exhibits a bottom surface 41, a total of four side surfaces and end surfaces, 42,43 and 44 respectively ,45, and is shaped to fill the inner housing in whole or in part and presents first and second surfaces, 46,47, in a V-shape whereby the first and second V-shaped surfaces, 46,47, provide a V-shaped cavity 60 over the explosive to form a hollow charge explosive which will cause the shock wave, material and heat from the detonating explosive to be ejected in a concentrated direction out of the V-shaped cavity. Preferably, a layer 50 is placed on the V-shaped surfaces, 46,47, of a material suitable for, upon detonation of the explosive, to provide a jet of material in the concentration area of a detonation shock wave which can cause a weakening or cutting of a wire located immediately at or above the V-shaped open area. It is thought to form the layer of copper. The V-shape appears clearly in the sectional view in Figure 4A, while the top view in Figure 4B with the line 48 in the center of the drawing indicates the bottom line of the V-shape. It is therefore a single, elongated, explosive element with a longitudinal V-shaped upper part. The terms upper or above in this description refer to the directions that apply in the figure illustrations when viewed normally.

Figure 4A also illustrates a fastening device 70 for securing the invention's device 100 to the underside of the cover plate 2. The fastening device 70 can be designed as a rectangular assembly of a total of four side walls and end walls, 71,72 and 73,74 respectively, which when using for example bolt fasteners or a welding method are connected to the upper edges of the respective side walls and end walls 11,12 and 13,14 respectively of the outer housing 10 and to the underside of the tire plate 2 with sufficient holding strength so that the outer housing 10 remains in its position and connected to the tire 2 even after that the explosive has been detonated and thus ensures a sealing of openings that are cut in the tire during the detonation against the other volume or space that exists under the tire 2. A rigid and solid anchoring of the outer housing to the underside of the tire plate 2 also ensures the maintenance of the tire construction integrity even when the device 100 upon detonation has created a significant, elongated ø opening in the tire. The height of the fastening device 70, i.e. the distance established by the fastening device between the deck plate 2 and the outer housing 10 when the device 100 is installed under the deck plate 2 is determined in part on the basis of the chosen shape and configuration of the explosive part 40 and the wire strikes the vessel must handle. In some cases, the fastening device 70 can thus be omitted, and the means for fastening the device 100 to the cover plate 2 are then directly mounted on the outer housing 10.

Reference is then made to Figures 5 and 6 for the following detailed explanation of a second embodiment of the present invention. In the second embodiment, the particular features of which are particularly apparent from Figure 6, the apparently continuous elongated V-shaped explosive is formed by a number of sections or shorter individual explosives, each of which exhibits substantially the same V-shape in cross-section and which exhibits V-shape bottom lines 48 which are substantially coincident or at least substantially parallel. The illustrative example shown in Figure 6 is formed by eight sections or juxtaposed single explosives each provided with a detonator or a detonator arrangement which provides a controlled detonation of each section or each individual explosive at different times. The sections or individual explosives are preferably separated from each other by devices 80 which ensure that the detonation of an explosive does not cause the detonation of a neighboring explosive, such as a plate or similar dividing wall that leads away or dampens a shock wave and/or heat generation.

With V-shaped explosives, the shock wave, the heat developed and the accompanying material from each individual detonating section or individual explosive will propagate out from the wire cutter device 100 mainly in a common plane of convergence 4 which lies in the longitudinal direction of the bottom line 48 of the V-shape, and which is indicated by the dotted, thick line with the reference number 4 in figure 5.

Reference is then made to figures 7, 8, 9A and 9B for the following detailed explanation of a third embodiment of the present invention. In the third embodiment, the explosive part 40 of the wire cutter device 100 is formed by a larger number of elongated, mainly circular-cylindrical or cone-shaped single explosive units 90, each of which comprises an associated explosive 91 which in an upper part in a longitudinal section exhibits a mainly V-shaped contour resulting from a cavity 60 which is cone-shaped in the upper part of the individual explosive. In the illustrative example shown in Figure 6, the explosive part 40 of the wire cutter device 100 is formed by eighty-eight (88) individual explosive units 90 which are each provided with a detonator or a detonator arrangement which provides a controlled detonation of each individual explosive at different times. The single explosive units 90 each include a cylindrical or cone-shaped housing 92 which houses the explosive 91 itself, which also forms a separation between them. Preferably, the individual explosive units 90 are also separated from each other by devices 80 which ensure that the detonation of an explosive does not cause the detonation of a neighboring explosive, such as an arrangement of plates or similar partitions, or a filling material which mainly fills the space between the explosive units 90 and which is arranged to deflect or dampen a shock wave and/or heat generation from a detonating neighboring explosive device 90 to a sufficient extent that the detonator does not cause detonation of a neighboring explosive device.

In an alternative variant (not shown in the figures) of the third embodiment of the wire cutter device 100 of the invention, at least a number of the layered single explosive units 90 are not circular-cylindrical but each cylindrical with a rectangular or square shape seen in section across its longitudinal direction, and exhibit a uniform width over their length, or they are tapered towards the bottom in a pyramidal shape, and are then provided with an explosive shaped to form a V-shaped cavity with a respective bottom line, and where this number of single explosive units 90 are placed in the interior the housing with the bottom lines of the V-shaped cavities aligned in the device's 100 longitudinal direction.

The example constellation of single explosive units 90 which is illustrated in cross-sectional view in figure 7 and in longitudinal section view in figure 8 suggests for an advantageous embodiment of the device 100 of the invention that the elongated single explosive units 90 are in identically shaped, circular-cylindrical housings 92 which are lined up side by side with essentially parallel longitudinal axes . marked with the reference number 5. With the example constellation illustrated as an example in Figures 7 and 8, a larger length of the wire can advantageously be shelled by detonating the individual explosive units 90 in the explosive part 40 collectively or successively for vessels that process wires that can with the greatest safety cut s or weakened to the point that they burst when attacked in several places over part of their length, the launch lines 5 for the respective individual explosive units 90 being essentially parallel in the sense that they do not lead to a significant and intentional collection or concentration of launched pressure waves, material or heat in an area where the cover plate or wire will be.

For vessels or work operations where wires are to be processed which, in an emergency situation with greater safety, can be cut or weakened to the point that they break in the event of a combined or concentrated attack on a smaller part of the wire that can be considered as a single location along the wire's length, a constellation is preferably used of the single explosive units 90 in the explosive part 40 such as the constellation examples which in figures 9A and 9B are illustrated by cross-sectional views and where it is shown that across the longitudinal direction of the device at most five (5) single explosive units 90 are installed. The number five which applies in particular to the ones shown examples are not limiting for similar constellations, but it is assumed that the number is at least two (2). Each of the individual explosive units 90 is in these constellations mounted in the wire cutter device 100 according to the invention which is angled differently with a mutual angle as indicated by the reference numeral 7 in a plane laid mainly across the longitudinal direction of the elongated wire cutter device 100, and so that these five individual explosive units 90 respectively launch lines 5 are gathered in a convergence point in an area at the launch line's intersection or intersection points as one common point of action or several common points of action for the shock waves, the material and the heat that are launched by detonation from each of the individual explosive units 90. The specified angles 7 between the launch lines 5 in the illustrative examples outlined in figures 9A and 9B are thus different, where the angle 7 in figure 9A is smaller than the angle 7 in figure 9B.

For the second and third embodiments, the device 100 of the invention can advantageously further include a detonation control device or a detonator arrangement which causes a controlled detonation of the explosive sections 40 of the explosive part or individual explosives 90 at different times. An advantage that is achieved by temporally separated detonation of the explosive sections or individual explosives in the second as well as the third embodiment is that the recoil impulse exhibits a lower peak value than the peak value that appears when detonating the single explosive as in the first embodiment the entire explosive part. A temporally distributed detonation can be used to reduce the requirements for the strength of the device 100's housing structure 10, intermediate housing 20 and associated damping material, and attachment device 70. Based on the cutting effect, it can still be maintained at sufficiently short intervals between the times for detonation of individual explosive sections or individual explosives . Timing of the detonation timings can be particularly beneficial in the case of the third embodiment by combining the detonation timing sequence, alignment angle of launch direction, V-shape variants and coating variants for the formation of a so-called "metal storm" aimed at the cover plate and wire, where the metal storm is created by timing management in several time phases where in a first phase, the cover plate and the outer parts of the wire are attacked, and in one or more immediately following phases, the inner parts or core parts of the wire are attacked. The time management is advantageously programmable, as a detonation sequence which determines the time relationship between the phases is programmed by distinct programs for each type of wire the vessel can be set to handle, and then selected and made ready for immediate activation before the relevant handling operation begins.

For damping, for example by absorption, of by-products of the sudden reaction in the explosive's thermally reactive mass, which are for example in the form of heat and pressure, the device 100 as indicated above is advantageously provided with single-layer or multi-layer absorbing material which is designed to absorb some or most of the by-products. As mentioned, the device advantageously also includes an enclosure arranged so that a penetration of the target material does not reduce the other structural integrity of the invention's construction or other parts of the surrounding construction, preferably also so that an initiation of the rapid thermal reaction, for example as a detonation, does not causes other effects that pose a danger to nearby objects.

When installing the device of the invention, a new arrangement is provided in a vessel deck with a single installation of the wire cutter device of the invention for instantaneous cutting of a weight-loaded or tension-loaded wire which can effectively prevent or avert the event of vessel damage, crew injury, capsize or other loss of vessel or crew as a result of the wire's weight or tensile load.

However, the nature or construction of the deck 2 may have to be taken into account when placing or installing it in the vessel. Problems that one imagines will have to be solved may be related to structural elements in or immediately below the deck, or constructional conditions at the deck plate itself, which do not allow a single wire cutter device 100 as described here to reliably provide the desired emergency cutting effect. In an inventive application of the wire cutter device of the invention, a group arrangement is provided in or under the cover plate of several wire cutter devices mainly parallel with respect to their longitudinal axes, which are advantageously angled about their longitudinal axes in relation to each other, and which are arranged by the detonation control to be triggered into detonation wholly or partly at the same time or in an advantageous sequence, to penetrate the cover plate simultaneously with the attack against the wire, respectively to first penetrate the cover plate and immediately afterwards for the attack against the wire itself. Figures 9A or 9B can, in view of such a group arrangement of several elongated wire cutter devices 100 provided by this invention, also be used to illustrate in a sectional plane across the longitudinal direction of the wire cutter devices. Examples of group arrangements of five (5) elongate wire cutter devices which in that case are indicated in this context by the reference number 90, with their respective launch planes are indicated in section by the lines pointed to by the arrow linked to the reference number 5, and where the reference number 7 in this particular context indicates the angle of each individual device about its longitudinal axis in relation to one or more of the other wire cutter devices included in the group arrangement. It should be pointed out here that in the group arrangement proposed by this invention no restriction is placed in the direction that the individual wire cutter devices must be of the same construction or design, but that an advantageous group arrangement can include different designs of the elongated wire cutter devices 100 with respective different constellations of explosive units or explosive sections. For example, in a group arrangement with a total of three (3) elongated wire cutter devices 100, it is envisaged that the middle one of the three is according to the first or the second embodiment as described above and particularly adapted for penetration of the deck plate, and that the other two are according to the third embodiment and particularly adapted for concentrating their respective and combined cutting effects against the wire. The detonation sequence is thus adapted to the configuration of the group arrangement, and is also thought to be arranged so that the sequence temporally takes into account a lifting of the wire from the deck as a result of the deck penetration that precedes the actual attack against the wire.

According to the invention, the fastening means 70 for connecting the wire cutter device 100 or a group arrangement of such can include or be made up of a deck plate part of a structure and/or a nature that exhibits the same strength and holding strength as otherwise specified for the open deck in the area as here by the invention is designated for installations of the wire cutter device 100 or a group arrangement of such. For example, for the purpose of the fastening means, an elongated part of a tire made of an ordinary tire sheet of the type mentioned at the outset can be replaced with a sandwich construction, preferably in steel and adapted to be welded in as a tire part, which in the relevant installation area gives the tire the required impact strength and load holding strength and further requires minimal of the undermount wire cutter device(s) 100 installed therein to primarily penetrate the tire or to effect both penetration of the tire and cutting of the wire. The device of the invention is primarily thought to be adapted for fixed installation, but can alternatively be realized as a separate, mobile unit.

In case of fixed installation, the device of the invention is advantageously lowered into, or, as indicated above and shown in some of the accompanying drawings, mounted immediately under the stern deck of an anchor handling vessel (AH vessel), but can alternatively, or as an addition, be included as attached to or integral part of hydraulic AH unit or similar devices.

The outer housing is preferably lined on the inside with one or more layers of a shock-absorbing or deformable material, which can be a material which, due to material properties or design, has a large deformation energy.

Inside and above the layer, or several layers, of shock-absorbing or deformable material, the device is further preferably covered with a layer of shock-resistant material, such as steel, which forms the inner housing and which in turn carries a further inner layer in the device of the thermally fast-reacting material, which is typically an explosive or explosive. Inside the device 100, the explosive or the explosive exhibits a recess, which advantageously in the case where the housing is of an elongated shape, is also correspondingly elongated. The advantageous recess shape, when the device is illustrated in a section across the longitudinal direction as illustrated in some of the accompanying figures, is a V-shape, where the bottom of the V-shape is centrally located in the aforementioned direction.

The above-mentioned inner cladding layer or coating of, for example, Cu to strengthen the directed explosive effect that the invention will provide, can be applied to the surface of the V-shaped recess, and is shaped in such a way that it preferably follows, and reproduces on the inside of the device, the interior of the explosive V shape.

Preferably, the second or third embodiment of the device 100 according to the invention comprises a rail or bracket arrangement designed to hold the individual explosive units 90, which in turn are fixed in the inner housing.

An installation of the device 100 according to the invention is preferably done transversely below deck, preferably as far aft of the ship as possible.

The cavity pos.6 above the charge pos.4 forms a "standoff" to achieve the desired acceleration and shape of the "projectile" that perforates the tire and the object to be cut.

The loads are dimensioned in relation to the deck thicknesses applicable to the various ship types.

The ship's structure is not significantly weakened transversely due to the fact that the strength of the structure is not carried by the damaged deck plates, but by the underlying structure which consists of strong support beams which are not significantly damaged. Water penetration is limited by the volume that the steel housing pos.l can accommodate. After triggered detonation, it is assumed that the ship ends the operation and goes to the quay for repair and reloading. A method of the invention includes producing the device of the invention by combining the elements of the invention to the assembly explained above.

A method of the invention includes using the device of the invention by equipping a vessel with the device of the invention as explained above.

Activation of the device of the invention, which involves initiating (detonating) the thermal rapid reaction, when installed in or immediately below the aft deck of an anchor handling vessel (AH vessel), will provide a safety barrier which acts to avoid loss of crew or ship in a case where a cargo connected to the said chain, wire or the like gets out of control in such a way as to endanger the ship or crew, and where cutting the said chain, wire or the like may contribute to avert or reduce such danger.

The device of the invention has such constructive features that it is safe to handle, and withstands great mechanical and temperature stress.

The invention may include one or more initiation mechanisms, preferably those having two or more firing barriers to eliminate inadvertent activation.

Claims (18)

1. Disconnection device (100) for immediate disconnection of a load connected to a vessel by a connecting device such as a wire, cable, chain or similar (1) which is carried on an upper side of an assigned part of an open vessel deck (2), characterized by that the device includes an elongated and in its longitudinal direction mainly rectilinear outer housing (10) which accommodates an elongated and in its longitudinal direction mainly rectilinear explosive part (40), which explosive part includes at least one explosive unit shaped as a directed charge with a launching side, and a device connection area on the launching side for connecting the elongated outer housing to the vessel deck in or below the assigned part of the vessel deck. 2. Device according to claim 2, where the explosive unit includes an explosive element which in an upper part thereof shows, in a section across the longitudinal direction of the housing, a substantially V-shaped contour to form a substantially V-shaped or cone-shaped cavity (60) immediately above the substantially V -shaped contour. 3. Device according to claim 2, where the explosive unit is arranged so that the main V-shaped or cone-shaped cavity's symmetry plane or axis of symmetry in the opening direction of the cavity determines a launch direction for a shock wave, material or heat. 4. Device according to any one of the preceding claims, where in the connection area it exhibits a connection device (70) for bolting or welding the device in or to the vessel deck. 5. Device according to claim 4, where the coupling device is formed by a rectangular assembly of four side wall elements (71,72,73,74). 6. Device according to any one of the preceding claims, including a intermediate housing (20) formed from layers of shock- or heat-absorbing material arranged between the outer housing and the explosive part. 7. Device according to claim 6, including an inner housing protective layer (30) of a mainly shock- or heat-resistant material between the layer of shock- or heat-absorbing material and the explosive element which forms the directed charge. 8. A device according to any one of the preceding claims, wherein the explosive unit in section exhibits a V-shaped contour formed by a surface forming a V-shaped or cone-shaped cavity. 9. Device according to claim 6, where the surface is covered by an active layer (50). 10. Device according to claim 9, where the working layer is formed of Cu. 11. Device according to any one of the preceding claims, where the explosive part is formed by a plurality of explosive units arranged side by side. 12. Device according to claim 11, including a barrier (80) arranged to dampen a propagation of shock wave, material or heat between respective, neighboring explosive units in the plurality of explosive units. 13. Device according to claim 11, where the explosive part with a plurality of explosive units is formed with only a single explosive unit in the widthwise direction of the device (100) and a plurality of substantially identically shaped explosive units with elongated, V-shaped surfaces in the longitudinal direction of the device (100), and where the V- the bottom lines of the shaped surfaces are mainly coincident or parallel. 14. Device according to claim 11, where the explosive part with a plurality of explosive units is formed with a plurality of explosive units both in the width and length direction of the device (100), and where essentially all of the plurality are elongated explosive units (90) with a respective cylindrical housing including an explosive that exhibits a V-shaped or cone-shaped cavity. 15. Device according to claim 14, where rows of the elongated explosive units are arranged side by side in the longitudinal direction of the device, and where the longitudinal axes, which correspond to the launch direction, of the explosive units in one row are angled in relation to the longitudinal axes of the explosive units in another row, so that these longitudinal axes intersect in an area above the launch side. 16. A device according to any one of the preceding claims, wherein the explosive unit includes a detonator arranged to be controlled by a detonation signal from a doubly safe operating means arranged on the vessel's command bridge. 17. Wire cutter device, characterized in that it includes a plurality of elongated disconnecting devices (100) according to any one of the preceding claims, where the elongated disconnecting devices are arranged with adjacent long sides and substantially parallel longitudinal axes. 18. Vessel arranged to tow or lift a load using a cable, wire or chain by guiding the cable, wire or chain over a part of an open vessel deck assigned for the purpose of guiding, characterized in that the vessel has installed in or immediately below the part of the open vessel deck allocated for guidance a disconnection device (100) as stated in any of claims 1-16 or a wire cutter device as stated in claim 17.