NO20110567A1 - Apparatus and method for placing a hose - Google Patents

Abstract

An apparatus and method for deploying and retrieving a hose from an offshore structure or a. vessels are described. The apparatus comprises a mechanism configured to receive a hose and a load-bearing element, which are connected together to form a supported hose assembly as the hose and the load-bearing element are fed to the apparatus. In an operation mode of deployment, the coupling and disconnecting apparatus receives a hose from the first storage device and a flexible load-bearing element from the second storage device, and connects them to form a supported hose assembly. In an operation mode of retrieval, the coupling and disconnecting apparatus receives a supported hose assembly consisting of a hose and a flexible load-bearing member, and disconnects them to separate the hose and the load-bearing member before being stored.

Description

APPARATUS FOR LAYING OUT HOSE AND METHOD FOR THE SAME

The present invention relates to an apparatus and a method for laying out a hose, and in particular an apparatus and method for laying out a hose from an offshore vessel or structure to the seabed.

The background to the invention and the preferred embodiments are described in relation to offshore and marine operations, although it will also be recognized that the invention also has application to bodies of fresh water, such as lakes and rivers.

The background of the invention

The background to the invention, and the preferred embodiments thereof, will be described in relation to offshore and marine operations, although it will also be recognized that the invention also has application to bodies of fresh water, such as lakes and rivers.

In offshore and marine operations, such as in the industry related to hydrocarbon exploration and production, as well as underwater mining and dredging industries, it is often necessary to use a hose to transport fluids and/or solid materials between a vessel or a structure on the surface and down to the seabed. In this context, a hose will be a flexible channel that defines a hole, through which fluids or solids can be transferred. The flow of materials could be upward (that is, from the seabed up to the surface structure) or downward (that is, from the surface structure down to the seabed), depending on the particular operation.

Many of the hoses used for such applications have a requirement to be able to be deployed

at considerable distances, and has a considerable weight. This weight, especially when combined with the weight of a substance transported within the hose, may be too great to be supported by the inherent longitudinal strength of the hose. In such situations, supporting the hose with a load-bearing element is known. This could be a

nearby structural element, such as a platform leg or riser, where the hose is attached to the load-bearing element at regular intervals along the hose.

An alternative known approach is to deploy a load-bearing element in the form of a support wire along the hose, and secure the support wire to the hose at regular intervals. The support cable could be a dedicated support cable that is stored on and is deployed from a reel or alternatively a crane cable, which is part of the standard equipment that is on vessels and rig decks, and which can be used to support the deployment of the hose. Alternatively, an umbilical (which is a wire-shielded bundled cable that has an additional functionality, such as power supply and control of underwater equipment) could be used. Regardless of the nature of the force-carrying element, they are connected to the hose by means of bolted clamps, clips, links or wire straps, ropes or woven straps. These offshore connections are made manually by offshore personnel.

Today's practice, which involves laying out hoses and load-bearing elements, has shortcomings and disadvantages. These include health and safety risks for offshore personnel when deploying hose, and operations when retrieving, following the procedures for handling the hose, and manual deck connections on vessels or offshore structures.

Previously proposed systems also require significant deck space, with separate spools for deploying wires and hoses. This is a disadvantage, as there is not much available space on offshore vessels and structures. Existing practice also carries with it a high risk that wear and tear and weakening of hoses and cables may occur at the connections used there. In addition, manual connection of the load-bearing element and the hose will be labor-intensive and will be slow.

Among other things, the aim and purpose of the invention is to provide an apparatus for deploying a hose, and/or a method that makes it easier, or at least alleviates one or more of the disadvantages found in the conventional practice of deploying a hose.

An aim of the invention is to provide an apparatus for deploying a hose and/or a method which provides a reduced dependence on human intervention and operation, and will thus provide a reduced risk to health and safety associated with operations that concern the deployment of snakes.

Further aims and objects of the invention will become clear from reading the following description.

Summary of the invention

According to a first aspect of the invention, there is provided an apparatus for deploying and retrieving a hose from an offshore structure or a vessel, the apparatus comprising a mechanism configured to receive a hose and a flexible load-bearing element , and connect the tubing to the flexible load-bearing member to form a supported tubing assembly as the tubing and load-bearing member are fed into the apparatus.

Preferably, the apparatus is configured to disconnect the hose and the load bearing member as a supported hose assembly is fed to the apparatus.

According to a second aspect of the invention, a system is provided to be able to deploy and retrieve a hose from an offshore structure or a vessel, where the system comprises: a first storage device for a hose; a second storage device for a flexible load-bearing element; and an apparatus for connecting and disconnecting; wherein, in a deployment mode of operation, the coupling and disconnection apparatus is configured to receive a hose from the first storage device and a flexible load-bearing member from the second storage device, and couple the hose to the load-bearing member to form a supported hose assembly as the hose and load bearing member are fed into the apparatus; and wherein, in a pick-up mode of operation, the coupling and disconnection apparatus is configured to receive a supported hose assembly comprising a hose and a flexible load-bearing member, and couple the supported hose assembly to separate the hose and the load-bearing member as the supported hose assembly is fed into the apparatus.

The equipment for connection and disconnection will therefore be able to be configured to deploy a supported hose assembly from the offshore structure or vessel, and to take apart the individual components of a supported hose assembly when it is picked up.

The hose will be able to comprise a hose with a hard wall or a hose with a soft wall, and will be able to be assembled from a plurality of hose lengths which are connected together using connectors on the end of the hose.

Preferably, the load-bearing element is secured to the hose at longitudinal intervals along the hose. The load-bearing element will be able to be held under tension, and will therefore be able to support the weight of the hose.

The hose will be able to include a plurality of attachment formations that allow the hose to be connected to the load-bearing element. An attachment formation could include fastening means to secure the attachment formation to the hose, and could include that an attachment is formed upon engagement, so that it engages with a corresponding formation on the load-bearing element.

The fastening means could comprise a sleeve or a patch on the outer surface of the hose. The sleeve or patch could, for example, comprise metal, textile, polymer or woven materials. The fastener will be able to be tied or glued to the hose, or will be able to be secured to the hose with a clamping or wrapping force.

The intervention formation may include one or more loops.

Alternatively, or in addition, the fastening means could comprise a mechanical assembly that is secured to the hose. The mechanical assembly will be able to penetrate, or partially penetrate, the hose wall. In one example, the mechanical mount penetrates through the tubing wall and is secured by an internal member that provides a surface for lateral support against an internal surface of the tubing. In another embodiment, the mechanical assembly is clamped to or crimped onto the hose.

Where the hose comprises one or more connections at the end of the hose, the attachment formations will be able to be connected to or be uniformly formed together with the connections at the end. In one embodiment, the attachment formation is provided on a sub-component which is secured between adjacent lengths of hose.

In preferred embodiments, the attachment formation for the hose is chosen so that it does not prevent coiling of the hose and/or storage of the hose in the storage device. For example, the attachment formation can be chosen so that it does not significantly increase the outer diameter of the hose, or so that it is at least partially flexible and/or collapsible against the outer wall of the hose.

The load-bearing element may comprise a wire, a cable or an umbilical. In an alternative embodiment, the load-bearing element is a fiber rope. This is particularly beneficial for applications in deep water, due to the low weight and high strength of the fiber rope.

Embodiments of the invention will be able to make use of a plurality of load-bearing elements on a single hose. Thus, the supported hose assembly will be able to comprise two or more load-bearing elements, which may be at a certain distance from each other. Such a configuration will reduce a tendency for the assembly during deployment, operation and/or retrieval.

The load-bearing element could comprise a plurality of longitudinally separated attachment points which are formed integrally with the load-bearing element (for example permanently attached to a cable). In an alternative embodiment, the load-bearing element is connected to the hose via a connection component which can be removably attached to the load-bearing element. Such a configuration is preferred as the connection components can be removed from the load-carrying element before storage, so as not to impede coiling and/or storage.

The coupling component could be attached to the hose, but is preferably a separate component. The system will therefore be able to comprise a plurality of coupling components which must be operatively attached to the load-bearing element and the hose to form the supported hose assembly.

Preferably, the coupling component is attached to the hose and the load carrying member as the hose and the load carrying member are fed to the apparatus, when the system is in a mode of operation where a deployment is to be arranged.

The system may be configured to remove the coupling component from the load bearing member as the supported hose assembly is fed to the apparatus, when the system is in a mode of operation where a pickup is to be arranged.

Preferably, the system comprises one or more clamps which connect the hose to the load-bearing element. Preferably, the clamp transfers a load to the load-bearing element by clamping onto the load-bearing element. Most preferably, the clamp attachment is attached to the load-bearing element temporarily.

In one embodiment, the coupling component consists of a clamping part and an engaging part. Preferably, the clamping fixture is configured to be clamped onto the load-bearing element. The engagement portion is preferably configured to connect to the engagement formation on the hose. The engagement part may comprise a snap hook to connect with the engagement formation on the hose.

The clamp may be pre-tensioned to a state (for example in case of spring loading), where it is attached to a load-bearing element. Alternatively, or in addition, the clamp attachment can be configured to be mechanically loaded on the load-bearing element.

The system will be able to include means for storing one or more connection components, which will be a storage rack or magazine. The storage rack or magazine will be able to store a connection component in a state where it is not connected to a hose or an umbilical.

The clamp will be able to be attached to the hose. The clamping fixture will be able to be configured so that it is the weight of the hose that mechanically loads the clamping fixture in attachment to the load-bearing element.

In alternative embodiments, the hose is coupled to the load-bearing element by friction. The connection-disconnection device could be configured to use a band around the hose on the load-carrying element. The band may be such that it can be sacrificed. During a mode of operation where a pick-up is to be arranged, the tape could be cut or destroyed. Cutting or destroying the tape may be performed automatically, or may be triggered or otherwise actuated by an operator.

Alternatively, or in addition, the hose could be connected to the load-bearing element by wrapping an elongated element around the hose and the load-bearing element. The member may be of rubber or a soft woven material, or any suitable material having elastomeric properties sufficient to connect the hose to the load bearing member. A supplementary means of fastening may be provided, for example a velcro or straps.

In an alternative embodiment, the hose and the load-carrying element are connected by wrapping in a net or a similar weave, which could be tubular. The net will be able to be configured for radial tightening on longitudinal stretching of the net or the weave, for example in the same way as in a Chinese finger trap.

The hose will be able to be stored on a reel, or alternatively can be stored in a horizontal or vertical machined storage system.

Where it is necessary for the length of the hose to be longer than the length that can be stored on a storage reel, the system will be able to include one or more cassettes, which are added to the system during deployment of the hose.

Embodiments of the second aspect of the invention may include one or more features of the first aspect of the invention or its embodiments or vice versa.

According to a third aspect of the invention, a method is provided for deploying a hose from an offshore structure or vessel, where the method comprises: pulling out a hose from a first storage device;

extracting a flexible load-bearing member from a second storage device;

receive the hose and the load-bearing element in a coupling-disconnection apparatus; automatically connecting the hose to the flexible load-bearing member to form a supported hose assembly;

remove the supported hose assembly from the coupling-disconnection apparatus.

Embodiments of the third aspect of the invention may include one or more features of the first or second aspect of the invention or its embodiments or vice versa.

According to a fourth aspect of the invention, a method is provided for retrieving a hose to an offshore structure or vessel, where the method comprises: receiving a supported hose assembly comprising a hose and a flexible load-carrying element in a connection-disconnection device;

automatic disconnection of the hose from the flexible load-bearing element;

coiling the tubing onto a first storage coil;

coil the load-carrying element onto a second storage coil.

Embodiments of the fourth aspect of the invention may include one or more features of any of the first to third aspects of the invention or its embodiments or vice versa.

Brief description of the drawings

By way of example only, different embodiments of the invention will now be described with reference to the drawings, where:

Figure 1 schematically shows a system according to a first embodiment of the invention, applied to an offshore structure; Figure 2 schematically shows a connection between a hose and a wire according to an embodiment of the invention; Figure 3 is a sectional view of a hose with an attachment point that penetrates the hose wall, according to an alternative embodiment of the invention; Figure 4 is a perspective view of a system according to a second embodiment of the invention; Figures 5A and 5B are plan and side views, respectively, of a coupling device used in the embodiment of Figure 4; Figures 6A and 6B are cross-sectional views of the coupling device in Figure 5 in open and closed configuration, respectively;

Figure 7 schematically shows the system of Figure 4 in use; and

Figures 8A and 8B are respectively side views and cross-sectional views of a coupling device according to a further alternative embodiment of the invention.

Detailed description of preferred embodiments

First with reference to Figure 1, a system 100 is schematically shown according to an embodiment of the invention, applied to an offshore structure 102. The system 100 comprises a coil 104 for storing the hose, and a coil for storing a flexible load-bearing element, which in this case is a cable. The system includes an apparatus 108 for connection-disconnection, which is supported beyond the lateral extent of the offshore structure 102.

A hose drawn from the storage coil 104 is fed into the apparatus 108, and a wire 112 is drawn from the coil 106 to the apparatus. The apparatus 108 is configured to connect the hose 110 and the wire 112 together to form a supported hose assembly 114. Therefore, in a mode of operation where a deployment is to be arranged, the hose and wire are fed separately from their respective storage spools to the apparatus 108, and exits the apparatus as a combined assembly 114, which is connected at longitudinally separate points 116. The supported hose assembly 114 passes through a conduit system 118 and is deployed to the seabed.

The system 100 also operates in a retrieval mode. In this mode, the supported hose assembly 114 is retracted into the apparatus 108, and the hose and wire forming the assembly are separated into respective hoses 110 and 112 for storage on respective spools 104, 106.

By connecting the hose and the load-carrying elements together as they are fed to the apparatus 108, the requirements for manual handling of the hose and the load-carrying elements are substantially reduced or avoided entirely. This has advantages in relation to safety and efficiency in hose deployment and retrieval operations. In addition, the probability of damage to the cables is reduced, when compared to the manual offshore connections that are found when hose deployment is practiced.

Figure 2 shows an example 120 of how the connection between the hose 110 and the load-bearing element can be achieved.

The hose 110 is provided with an attachment comprising an attachment portion 122 and an engagement formation 124. The attachment portion 122 in this embodiment is in the form of a sleeve which is bonded or glued to the outer surface of the hose 110. The engagement portion 124 is in the form of an arrangement of loops 126, which together extend around the hose 110 along the circumference. The fastening part 122 has a low profile, and therefore does not provide a significant increase in the outside diameter of the hose 110. Correspondingly, the loops are flexible and collapsible, so that influences in connection with coiling and storage of the hose 110 are reduced.

The example of the arrangement 120 includes coupling component 130, which is arranged to be temporarily attached to the hose 104 and the wire 106. The coupling component 130 includes a clamping attachment portion 132, which is configured to receive and attach to the wire 106, and an engagement portion 134, which in this configuration is in the form of a snap hook. The snap hook engages the attachment formation (ie loop 126) on the hose 110. The coupling component 130 is mechanically loaded by the weight of the hose (acting in the direction indicated by arrow W) to clamp onto the wire 112. The system 100 includes a magazine of coupling components 130 which are in the apparatus 108 for attachment to the hose and the wire. The coupling components 130 engage sequentially with the hose and wire as described below.

In use, the hose 110 and the wire 112 are simultaneously fed into the apparatus 108 between the opposite elements of the clamp attachment portion 132 of the coupling component 130. As the hose passes through the apparatus 108, together with the coupling component 130, and the force transmitted to the coupling component mechanically stresses the clamp attachment into engagement with the wire 112. The hose 110 and the wire 110 are therefore coupled to form the supported hose assembly 114, which is deployed from the system 100. During a deployment operation, the wire 110 is held taut. However, the hose 110 is not held taut throughout, but is held suspended from each attachment point 116.

In a mode of operation where a pickup is to be arranged, the wire is reeled in tight to lift the supported hose assembly back towards the offshore structure, while restraining the mechanical stress on the clamping fixture 132. The assembly 114 enters the apparatus 108. The hose 110 and coupling component 130 are released, which releases the mechanical stress on the clamp 132, allowing the clamp to be released from the wire 112. Coupling components 130 are released from the supported hose assembly sequentially and stored in the magazine of the apparatus 108.

In the above-described embodiment, the coupling component 130 is a separate component that is removable from both the hose 110 and the wire 112. This is advantageous since it then avoids providing permanent attachment points on the wire 110, which could interfere with coiling and/or storage of the wire.

Alternative configurations of coupling components are within the scope of the invention. For example, alternative constructions of clamp fastening could be one where there is a mechanical load which, due to the weight of the hose, is used for a fastening engagement with the wire. The clamps will be able to be held in the apparatus 108 with the biasing means in an open position. The pre-tensioning means will be able to be released as the hose and wire pass through the apparatus, so that the clamp is loosened when engaging with the wire.

A system 400, which is in accordance with an alternative embodiment of the invention, is described with reference to Figures 4 to 7. The system 400 is similar to the system 100, and can be understood from the corresponding description. The system 400 has particular application when deploying a hose from an offshore structure or a vessel (not shown), and comprises a hose 402 which is deployed from a reel 404 which stores a hose, which is arranged horizontally on a support platform 406. The support platform 406 is arranged over a frame 408, which contains an umbilical 410 on a spool 412 for storing the umbilical. The hose 402 and umbilical 410 are fixed with a fastening part 442 on the hose, and a fastening part 444 on a connecting component for the umbilical via a strap 446.

The system also includes a support element 414, which does not fold, for a guide system 416, over which a supported hose assembly 418 is guided and deployed on the seabed.

The system 400 also includes a rack system 420 for storing, releasing and restoring coupling components in the form of clamp fasteners 422, as will be described below. The clamps 422 comprise clamp portions 424 and bearing portions 426, around a pivot pin 428, and are spring-loaded to be biased with the bearing points apart and with the clamp portions together.

Figures 5A and 5B are respectively plan and side views of the stand system 420. 1 figure 5A the stand system 420 is shown so that it houses a number of clamp fasteners 422. 1 figure 5A the stand system 420 is shown with the row of clamp fasteners and an umbilical 410 which extends through the clamp attachment portions of the clamp fasteners.

The stand system 420 comprises a pair of elongated guide elements 426 which are arranged in line with the deployment direction of the umbilical 410 (and the hose 402, not shown). The guide elements 430 define a channel to receive supporting elements 426 of the clamping fixture 422. the guiding elements are shaped to define a limited channel portion 432, where the supporting portions of the clamping fixture are pushed together, a first flaring portion 434, and a second flaring portion 436, each of which expands the channel in a direction moving away from the restricted channel portion 432. Figures 6A and 6B show the interaction of the clamp mounts 432 and the rack system 420 in more detail. Figure 6A shows a cross-section of the guide elements 430, the clamp attachment and the umbilical 410 through line A - A' in the limited channel portion 432. In this position, the bearing parts 426 of the clamp attachment 422 are pushed together, which tends to open the clamp attachment elements 424 around the pivot. The open clamp attachment elements will partially enclose the umbilical 410. Figure 6B is a cross section through the clamp attachment 422 and guide elements 430 through the flaring portion 434, at line B to B'. In this position, the channel defined by the support members is wider and the biasing means pushed the supporting portion apart and the clamping portion together. For this reason, in the part that is flared (in the position shown in Figure 6B) the clamp is clamped onto the umbilical. Figure 7 shows the system 400 in use. The hose 402 is extended from the coil and passes over the rack system 420. An operator connects a strap (not shown) which is attached to a clamp in the rack 420, to a loop 448 on a fastening portion 442 of the hose. The strap is, for example, connected with a snap connection. As the hose is pulled out, the strap clamp pulls out from the restricted channel portion of the rack. As the clamp enters the flaring portion, the bearing portions move apart and the clamp portions attach to the umbilical. This connects the tubing to the umbilical to form the supported tubing assembly. In a recovery mode of operation, the load-bearing portions of the clamps enter the flaring portion and then enter the restricted channel to release the umbilical from the clamp.

In an alternative embodiment, connecting the hose is fully automated, and no operator intervention is required. A snap coupling is arranged to automatically engage the hose to cause the hose to be withdrawn from the rack system.

In alternative embodiments, a clamp or clamps could be used to secure the hose. For example, the coupling component could include first and second clamping parts which are configured to clamp the wire and the hose respectively.

In a further alternative embodiment, an attachment point could be permanently attached to either the wire or the hose. Figure 3 shows an example 140 of an attachment point 142 which has been formed with the hose 110' in an integrated manner. The attachment point 142 penetrates into the wall 144 of the hose and comprises a safety element 146 which includes a support surface 148 against the inner side of the hose wall.

In a further alternative embodiment (not shown), the hose is provided with attachment points on sub-components which are located between corresponding end connections on the hose joining adjacent lengths of hose.

The above-described embodiments use clamps and/or attachment points to connect the wire and hose. In alternative embodiments, the hose and wire are coupled by friction. In one example, which is shown in Figures 4A and 4B at 160, a sheet or woven material 162 is applied around the outside of the hose 110 and the wire 112, to form a sacrificial band around both elements. The sacrificial cord may be damaged or cut during a retrieval operation where the hose is to be freed from the wire.

In an alternative embodiment, a sleeve of a soft woven material or rubber is wrapped around both the hose and the wire, and is attached to the wire using a Velcro fastener or straps.

A further alternative embodiment uses a tubular mesh device, through which the hose and wire extend. The tubular mesh is shaped such that stretching the mesh in a longitudinal direction tends to provide a radial seal, such as with a "Chinese finger" type device packing.

The invention provides an apparatus and a method for deploying and retrieving a hose from an offshore structure or vessel. The apparatus includes a mechanism configured to receive a hose and a flexible load-carrying member, which are coupled together to form a supported hose assembly as the hose and load-carrying member are fed to the apparatus. In a deployment mode of operation, the coupling-disconnection apparatus receives a supported hose assembly consisting of a hose and a flexible load-carrying member and disconnects them to separate the hose and the load-carrying member before being stored.

The invention, in its various embodiments, provides an apparatus and method for deploying and retrieving which is an improvement over what is considered to be conventionally correct. In particular, the present invention will reduce the necessity of manual handling or a hose and a cable and forms a manual offshore connection of the hose to a cable. This improves the safety and efficiency of hose deployment and retrieval operations. The invention has particular application for offshore industry which is linked to hydrocarbon exploration or production, mining operations on the seabed and seabed dredging. The invention also has application to freshwater systems, such as in lakes and rivers.

Various modifications could be made within the scope of the invention intended here, and embodiments of the invention could include combinations or special features that differ from those that are expressly required.

Claims (15)

1. A system for deploying and/or retrieving a hose from an offshore structure or vessel, where the system comprises: a first storage device for a hose; a second storage device for a flexible load-bearing element; and a coupling-disconnection apparatus; wherein the coupling-disconnecting apparatus, in a deployment mode of operation, is configured to receive a hose from the first storage device and a flexible load-bearing member from the second storage device, and couple the hose to the load-bearing member to form a supported hose assembly as the hose and load-bearing member are fed to the apparatus; and wherein the coupling-disconnecting apparatus, in a retrieval mode of operation, is configured to receive a supported hose assembly comprising a hose and a flexible load-bearing member, and disconnect the supported hose assembly to separate the hose and the load-bearing member as the supported tubing assembly is fed to the apparatus. 2. System according to claim 1, where the hose comprises a plurality of attachment formations that allow coupling of the hose to the load-bearing element, where an attachment formation comprises fasteners to secure the attachment formation to the hose, and comprises the formation of an engagement attachment to engage with a corresponding formation on the load-bearing element. 3. System according to claim 1 or 2, where the load-carrying element is selected from a wire, a cable, an umbilical or a fiber rope. 4. System according to any one of the preceding claims, wherein the load-bearing element is connected to the hose via a coupling component which is removably attached to the load-bearing element. 5. A system according to claim 4, which is configured to attach the coupling component to the hose and the load-bearing member as the hose and the load-bearing member are fed to the apparatus when the system is in a deployment mode of operation. 6. A system according to claim 4 or claim 5, which is configured to remove the coupling component from the load bearing member as the supported hose assembly is fed to the apparatus when the system is in a retrieval mode of operation. 7. A system according to any one of claims 4 to 6, which is configured to remove the coupling component from the hose and the load carrying member as a supported hose assembly is fed to the apparatus when the system is in a retrieval mode of operation. 8. System according to any one of the preceding claims, comprising one or more clamps which connect the hose to the load-bearing element. 9. System according to claim 8, where a clamp attachment comprises biasing means for biasing the clamp attachment to a state where it is attached to a load-bearing element. 10. System according to any one of claims 4 to 8, comprising means for storing one or more coupling components. 11. System according to any one of claims 4 to 9, wherein the coupling components comprise one or more clamping fasteners, and which further comprise means for storing one or more clamping fasteners in a state where they are held open. 12. System according to any one of claims 8 to 11, where a clamp attachment is configured so that the weight of the hose mechanically loads the clamp attachment in attachment to the load-bearing element. 13. System according to any one of the preceding claims, where the hose is connected to the load-bearing element by friction. 14. A method for deploying a hose from an offshore structure or a vessel, the method comprising: releasing a hose from a first storage device; releasing a flexible load-bearing member from a second storage device; receive the hose and the flexible load-bearing element in a coupling and disconnection apparatus; automatically connecting the hose to the flexible load-bearing member to form a supported hose assembly; remove the supported hose assembly from the coupling and disconnection apparatus. 15. A method for retrieving a hose from an offshore structure or vessel, where the method comprises: receiving a supported hose assembly comprising a hose and a flexible load-bearing element in a device for coupling and disconnection; automatically disconnect the hose from the flexible load-bearing element; winding the tubing onto a first storage coil; wind up the flexible load-carrying member onto a second storage coil.