Abstract: Apparatus for laying conduit from a vessel comprises reel carrier arranged to receive a reel (202) wound with conduit (204) and capable of being reciprocated along the direction of the axis (214) of the reel as the conduit is unwound. The apparatus further comprises a straightener (208), and a control unit arranged to control the reel carrier such that the fleet angle created between the conduit and the straightener is reduced. Such an arrangement ensures that the conduit is not bent past its limit of elastic deformability while allowing the straightener to be situated relatively close to the reel.

Abstract: A pipe-laying apparatus and method for laying or raising a pipeline from a vessel. The apparatus includes a first pipe gripping assembly disposed on a pipe laying path along which pipeline passes during laying, a second pipe gripping assembly disposed on the pipe-laying path, and a drive unit for causing relative movement in a direction along the pipe-laying path between the first pipe gripping assembly and the second pipe gripping assembly. The first pipe gripping assembly includes both a pipe gripping arrangement for gripping a pipe during pipe-laying and a cable gripping arrangement for gripping a cable during an operation when a cable is connected to a length of pipeline.

Abstract: A method and apparatus for deploying a plurality of seismic sensor units into a water column is described. The method includes providing a length of flexible cable from a cable storage device disposed on a vessel to a powered sheave, the cable having a plurality of spaced apart attachment points, routing the cable from the powered sheave to pass adjacent a workstation disposed on the vessel, deploying a free end of the cable into the water column while increasing the motion of the vessel to a first speed, operating the vessel at the first speed while providing a deployment rate of the cable at a second speed, the second speed being greater than the first speed, decreasing the second speed of the cable as an attachment point approaches the work station, and attaching at least one of the plurality of seismic sensor units to the attachment point at the workstation.

Abstract: A method of deploying a seismic recorder array on a seafloor is disclosed. The seismic recorder array comprises a plurality of removable seismic data recorders. The method comprises the step of forming the seismic recorder array by connecting a plurality of recorder housings in series, wherein adjacent recorder housings are connected by a connector cable. The recorder housings are configured to retain the removable seismic data recorders. The method comprises the step of loading the plurality of removable seismic data recorders in the recorder housings, and lowering the seismic recorder array into water until the seismic recorder array is positioned on the seafloor underlying the water. The method comprises the step of operating the seismic data recorders to detect seismic signal reflections and to record seismic data representing the reflections.

Abstract: A pipeline laying vessel includes a J-lay system which defines a firing line. The J-lay system includes at least one lowering device for lowering a pipe section or pipeline in the firing line from an upper position to a lower position. The vessel further includes a first pipe-moving device and a second pipe-moving device, where the first pipe-moving device is configured for moving a pipe section from a first remote position remote from the firing line to a firing line position in the firing line, and the second pipe-moving device is configured for moving a pipe section from a second remote position remote from the firing line to the firing line position in the firing line. A method for laying a pipeline uses the above mentioned pipeline laying vessel.

Abstract: An actuating device (23) for a lay ramp (6) of a vessel (1) for laying underwater pipelines “(2) has a runner (28), and a carriage (29) connected to the lay ramp (6) and which runs along the runner (28) to lift and lower the lay ramp (6); the runner (28) being defined by a first, a second, and a third portion (31, 32, 33), of which the first and third portion (31, 33) are out of line with respect to each other, and the second portion (32) is mounted on a movable assembly (37) to selectively align the second portion (32) with the first and third portion (31, 33).

Abstract: In the marine hose of the present invention, protruded parts are provided at each axial direction end of the axial direction ends of the hose bodies, each axial direction end is located at both sides in the axial direction of the connection portion which is provided with limit mechanism. By this, when the marine hose is wound up to the reel, the protruded parts of the hose bodies contact the outer surface of the reel, the outer surface of the limit mechanism does not contact the outer surface of the reel. Thus, large amount of the bending force is not added to the limit mechanism.

Abstract: A pipelay vessel has a stinger extending along and outboard of one side of the vessel. A diverter is arranged to lead pipe onto the stinger input end through a predominantly horizontal diversion angle from a pipeline source having a substantially horizontal orientation. The vessel is selectively operable in any one of three modes, namely: (1) shallow S-lay, in which the pipe is launched over a stern-mounted stinger with a launch angle which has a predominantly horizontal component; (2) steep S-lay, in which the pipe is launched over the side-mounted stinger with a launch angle which has a predominantly vertical component; and (3) J-lay, in which the pipe is welded at and launched from a tower. The axis of the J-lay apparatus is aligned with the departure axis of the side-mounted stinger.

Abstract: A marine pipelaying vessel with a pipeline stinger connected to said vessel, preferably pivotable, and forming a downwardly directed support for pipeline to be laid. The vessel further includes a stinger suspension assembly between the stinger and the vessel from which the stinger is suspended at least during operation, preferably the stinger suspension assembly allowing to lower and raise said stinger. The stinger suspension assembly includes a sacrificial stinger impact absorber which is adapted to absorb impact energy resulting from a violent stinger motion, e.g. induced by a freak wave. Preferably, the impact absorber forms an elongatable structure, e.g. a telescopic structure, which is elongated under impact energy absorption.

Abstract: Method of positioning on the sea floor, from a floating vessel (100), an unlaid end portion (2) of a pipe that is being laid from its other end on the sea floor, comprising the steps of: (i) lowering the unlaid end portion of the pipe from a lowering device (20) on the vessel to a lowered position in the sea above the sea floor; (ii) transferring the load of the unlaid end portion of the pipe from the lowering device to means (30) for suspending the unlaid end portion of the pipe from the vessel at the lowered position in the sea; and (iii) lowering the means for suspending and the unlaid end portion of the pipe suspended thereby to the sea floor. There is also disclosed a corresponding method of recovery as well as associated apparatus. Further disclosed is a method for effecting a subsea connection between one line and an object suspended below the surface of the sea by another line, and associated apparatus.

Abstract: A pipeline laying vessel (1) for laying a pipeline (2) on a seabed, said vessel (1) comprising a J-lay system (4) defining a firing line (5) along which the pipeline (2) is laid, the J-lay system (4) comprising an alignment device (6) for aligning a pipe section (7) with the pipeline (2) suspended from the J-lay system (4) with a sufficient level of accuracy to allow the pipe section (7) to be welded to the pipeline (2), the alignment device (6) being constructed to maintain the alignment during at least a part of the welding operation of the pipe section (7) to the pipeline (2), wherein the alignment device (6) is movable between a first position (10) in the firing line (5) and a second position (11) outside the firing line (5), and the alignment device (6) is constructed to engage a pipe section (7) in the second position (11) and to be moved into the first position (10) together with the engaged pipe section (7).

Abstract: Systems and methods for marine seismic cable deployment and retrieval are described. One system comprises a plurality of portable containers, each container temporarily storing a marine seismic component, at least some of the containers able to be removably fastened to a deck of a vessel of opportunity, and at least one of the portable containers storing a main cable winch on which is wound a marine seismic cable. It is emphasized that this abstract is provided to comply with the rules requiring an abstract, which will allow a searcher or other reader to quickly ascertain the subject matter of the technical disclosure. It is submitted with the understanding that it will not be used to interpret or limit the scope or meaning of the claims.

Abstract: An offshore coiled tubing deployment system is provided, wherein the system includes a sea vessel hull configured to include a mounted coiled tubing spool; and a mast configured to guide lengths of coiled tubing received from said mounted coiled tubing spool. Methods, means and locations for the mounted coiled tubing spool are also provided, as well as lubricated coiled tubing riser assemblies which interface with self-standing riser systems. Tractors, swivel plates, buoyancy devices and positioning systems therefore; and a self-standing riser system joined with one or more of a blowout preventer, wellhead, production tree or injection tree are also disclosed.

Abstract: When laying pipe from a pipelay vessel into the sea, the pipe is subject to torsion. To relieve this torsion an apparatus to perform controlled relative rotation between the pipe and the vessel is proposed, which apparatus is also able to permit the pipelay vessel to “weather vane” about the pipe without twisting it. The apparatus comprises a hold off clamp (3) which is mounted within a housing (5) via thrust bearings (4). The housing (5) is mounted to the vessel (6), and the clamping means (3) is clamped to the pipe (1). A brake assembly (12) and a drive means (13) capable of providing predetermined rotation and torsional damping, enable controlled relative rotation of the clamping means within the housing. With the pipe secured in the clamping means controlled relative rotation can be achieved for torsion relief, or weather vaning of the pipelay vessel about the pipe can be achieved.

Abstract: The present invention relates to a marine pipeline installation system for laying an offshore pipeline and/or installing a subsea riser, said system being adapted to carry out the reel lay method and the J-lay method. The system comprises a vessel with a moonpool, a pipeline launch tower arranged on the vessel, a pipeline guide at an elevated position on said tower for guiding said pipeline to a pipeline launch trajectory along said tower, and one or more tensioners. The support assembly of at least one tensioner frame is adapted to allow for displacement of the tensioner frame between an active position, wherein the pipeline launch trajectory extends through the tensioner frame between the tracks, so that the tracks can engage on a pipeline, and a retracted and non-operable position. The system further comprises a J-Lay installation.

Abstract: Embodiments described herein relate to an apparatus and method for deployment and retrieval of one or more seismic devices in a deep water marine environment. In one embodiment, a method for deploying and positioning ocean bottom equipment is described. The method includes attaching at least one article having a negative buoyancy to a support cable, lowering the at least one article into the water column from two or more points of suspension on a surface of the water column, at least one of the two or more points of suspension being movable relative to the other point of suspension, and manipulating tension of the support cable, length of the support cable, position of the support cable, and distance between the two or more points of suspension to cause the at least one article to fall to a bottom of the water column at a predetermined location on the bottom.

Abstract: A marine vessel is provided. The marine vessel comprises a cable handling system disposed on the marine vessel between a leading end and a trailing end of the vessel. The cable handling system comprises a cable handler positioned proximate the trailing end and a cable storage device positioned forward of the cable handler, the cable storage device and the cable handler adapted to receive a flexible cable and define a portion of a cable path therebetween. The marine vessel also comprises a seismic device storage structure extending between the leading end and the trailing end and disposed substantially parallel to the cable path, a ramp coupled to a portion of the trailing end of the vessel aft of the cable handler, and a staging section disposed between the seismic device storage structure and the ramp to provide transfer of seismic devices between the seismic device storage structure and the ramp.

Abstract: A water-borne vessel for deploying a self-standing riser system is provided, wherein the vessel hull is configured to receive, transfer and deploy components of a self-standing riser system. The vessel hull includes at least a landing platform, a component transfer means, and a deployment platform suitable for deploying the riser components into associated surrounding waters. Various means of assisting the process whereby self-standing riser components are loaded onto the vessel and stored; transferred from receiving to deployment platforms; and deployed from the vessel into surrounding waters are also considered.

Abstract: Marine pipelaying method and system for installing an offshore pipeline (1) that includes one or more accessories (10). The method includes the steps of providing a vessel (2), launching the pipeline (1) in a firing line from the vessel (2) in the direction of the seabed, engaging the pipeline (1) with a clamping device (5b) that is connected to the vessel (2) and adapted to support the weight of the previously launched pipeline (1), and moving the accessory (10) into the firing line to a position above the clamping device (5b).

Abstract: The present invention relates to a method and apparatus for laying offshore pipeline from a reel lay vessel. The invention involves providing a pipeline laying tower with a travelling clamp, which can be used to suspend the pipeline from the vessel, and a tensioner apparatus on the same tower, for providing a clamping force which can be used to suspend the pipeline from the vessel. The travelling clamp and tensioner apparatus may either be used separately or in conjunction with one another during the laying operation. The invention allows pipeline to be laid in very deep water.

Abstract: A method for installing an accessory onto a pipeline to be laid on the seabed, includes launching the pipeline from a first position of a tower in which the tower is at an angle ? with respect to the vertical; stopping the launch of the pipeline, and hanging off the launched pipeline in a hang off module; positioning an accessory in a tower firing line; attaching the accessory to the launched pipeline in the hang off module and to at least one A&R cable; suspending the accessory and the launched pipeline from an A&R system; disengaging the hang off module from the launched pipeline; pivoting the pipeline launch tower to an accessory launch position in which the tower is at an angle ? that differs substantially from angle ?, such that a pipeline launch trajectory is created which is large enough to launch the accessory and the launched pipeline with the A&R system.

Abstract: The invention relates to a marine pipelaying system comprising a vessel (1) provided with a pipeline launch tower (6). The tower (6) comprises pipe laying equipment defining a tower firing line, and is adapted for launching a pipeline (20) along the firing line into the sea. The system furthermore comprises a hang off module (15) supported in the lower part of the firing line for clamping and supporting the weight of previously launched pipeline (20) as well as a stinger for guiding the launched pipeline (20). The stinger (10) is supported at its upper end in the lower part of the firing line. The stinger is displaceable from the firing line.

Abstract: Apparatus for overboarding an article from a pipe laying vessel includes a pipe laying tower (10) that is mounted above a tower supporting platform. The tower has tensioners (20) for suspending a pipeline (34) being laid from the pipelaying vessel into the sea and adjusters for adjusting inclination of the tower to align the tensioners with a departure axis of a pipeline being laid. A hoist (26, 27, 32) allows large articles (25) to be suspended from the tower. Adjusters (16) allow the tower to be angled beyond the departure axis, such that the hoist suspends the article outboard of the platform. Articles too large to pass the tower supporting platform of the vessel can be maneuvered first outboard of the tower supporting platform, then lowered and brought beneath the tower supporting platform back into line with the departure axis for connection to the pipeline. A method of laying pipe line from a vessel is also provided.

Abstract: The present invention relates to a pipeline guide assembly for a pipeline laying vessel, the pipeline guide assembly comprising:—a plurality of segments (20) pivotably interconnected via hinges (38) in an end-to-end relationship, each segment comprising at least one pipeline support (34) constructed to support a pipeline, wherein the pipeline supports provide a firing line (24) along which a pipeline can be launched,—a curvature mechanism (32) comprising at least one actuator (68, 68a, 68b, 68c, 68d), the curvature mechanism constructed for pivoting each segment relative to the next segment such that in use the segments provide a curved firing line, wherein the pipeline supports limit the curvature of the pipeline as it is launched along said curved firing line. The present invention also relates to a vessel comprising the stinger. The present invention also relates to a method of laying a pipeline utilizing the stinger of the invention.

Abstract: A pipelaying vessel comprises storage (502) for a number of pipe units to be assembled into a pipeline and S-lay apparatus (312, 314, 316) for fabricating and paying out of a pipeline by repeated addition of new sections (506). The end of said pipeline being laid is held aligned with a fabrication axis closer to horizontal than vertical, the S-lay apparatus including a stinger (312) for supporting the pipeline in an arcuate path to a departure axis which is more vertical than horizontal. Auxiliary apparatus (318/810) is provided for use in fitting singular items to one end of the pipeline. The supporting structure (320/802) of said auxiliary apparatus is located above a lower end of the stinger of the S-lay apparatus, substantially aligned with said departure axis, so as to facilitate handing over of the suspended pipeline and singular item from one of said apparatuses to the other. The auxiliary apparatus may be an A-frame (810) or a complete J-Lay apparatus (318-322) for additional laying tasks.

Abstract: A guide device for supporting an underwater pipeline along a feed path as it is being laid. The device is fitted to a laying ramp and has a cradle housing the pipeline; a frame fixed to the laying ramp; and a spacer mechanism located between the frame and the cradle to selectively adjust the distance between the cradle and frame. The device further includes a shock absorber connected to the cradle. The invention includes a method for using the device.

Abstract: A pipe handling system for handling the pipes from a cargo hull includes a gantry beam and a guide mast assembly having an essentially vertical guide mast. The guide mast assembly is moveably connected to the gantry beam, allowing movement of the guide mast assembly in a vertical direction between a lowered mast position and a lifted mast position relative to the gantry beam. A lifting part includes a device configured to engage a pipe. The lifting part is moveable by one or more hoists in a vertical direction between a lowered lifting part position for picking up the pipe and a lifted lifting part position. The lifted part engages on the guide mast assembly, such that the guide mast assembly causes vertical guidance of the lifting part when the guide mast assembly with the engaged lifting part is moved between the lowered mast position and the lifted mast position.

Abstract: A system comprising a structure defining an interior of the system; an apparatus exterior to the structure, the apparatus adapted to reduce in size when lowered into a body of water; a strap exterior to the apparatus, the strap adapted to reduce in size as the apparatus reduces in size.

Abstract: A method and apparatus for storing, deploying and retrieving a plurality of seismic devices is described. The apparatus includes a ramp device coupled to a portion of a trailing end of a vessel, a cable handling device positioned between the ramp device and a leading end of the vessel to define a cable path across the ramp device, and at least one conveyor system having a first end located adjacent the ramp device and a second end extending toward the leading end of the vessel. A deployment method includes providing nodes from a storage area to a workstation where the nodes may be attached to a cable. A retrieval method includes routing a cable through a workstation to detach nodes from the cable section and transfer the detached nodes to the storage area.

Abstract: A method of installing an underwater riser includes anchoring an installation to the seabed; coupling a tubular pipe to the installation; equipping the installation with a submersible float; submerging the float and the pipe, while the float and the pipe are being held from a surface vessel; a cable and a return device are installed on the seabed installation so that the cable can be connected to the pipe; attaching a submerged hauling buoy to the hauling cable; then removing ballast from the float in order to compensate for the tensile forces corresponding to the weight of the float and the pipe and to some of the load applied to the cable; and finally, anchoring of the hauling buoy to the installation, and gradually releasing the float.

Abstract: A marine pipelaying system and method for installing an offshore pipeline that includes one or more accessories. The system comprises a vessel (1), a pipeline launch device (10) for launching the pipeline (2) from the vessel in the direction of the seabed, and a clamping device (30) adapted to support the weight of the previously launched pipeline. The system further includes an accessory handling device, which is adapted to receive and support an accessory (40) and allow displacement thereof between an receiving position, wherein the accessory is received by the handling device and a pipeline connecting position, wherein the accessory can be connected to the pipeline (2).

Abstract: A marine J-lay pipelaying system for use on a vessel for laying an offshore pipeline has a J-lay tower, a pipe connecting station, wherein said pipe section is connected to the previously launched pipeline, and J-lay tower bearing means which allow for the pivoting of the J-lay tower with respect to the vessel. The J-lay tower has a free-pivotal mode wherein the J-lay tower is freely pivotable with respect to the vessel so that the J-lay tower has an orientation independent from sea-state induced vessel motions.

Abstract: A floating support including a retaining and holding device for retaining and holding a pipe suspended from a floating support of the type comprising a ship for laying a bottom-to-surface connection pipe. The retaining and holding device comprises at least a first collar releasably locked around an end forging of a pipe element together with a support part at the floating support, said support part including load transfer and a rotary joint enabling the inclination of the pipe to be guided and having an effect of automatically centering the pipe.

Abstract: A vessel (1) for laying a pipeline, the vessel comprising a hull structure (3) comprising one or more floaters (4), a tower (5) defining a firing line (6) when positioned in a pipelaying position, the tower (5) being pivotable relative to the hull structure (3) about a tower pivot axis (7), and an A & R means (8) for abandoning and/or recovering the pipeline, wherein the tower (5) is pivotable about said tower pivot axis (7) substantially independent from the A & R means (8) and the A & R means (8) is configured to operate while the tower (5) is pivoted about said tower pivot axis (7).

Abstract: This invention relates to apparatus and methods for laying of elongate articles from a vessel. The vessel includes a tower (2), on which is supported tensioning means (20,21), straightening means (19), and a hold-off clamp (14). The hold-off clamp (14) is mounted independently of the tower on a trolley (13) which can be moved into and out of alignment with the laying axis of the tower while supporting the elongate article under laying tension. This enables the pipe string to be moved out of the line of the tower (2) for the fitting of equipment such as mid-line connectors and PLETs. Methods are disclosed for using the apparatus for fitting a connection to the elongate article being laid using cranes etc provided on the vessel to move the trolley (13) and hold the laid pipe string or connection.

Abstract: A system for deploying a fiber optic line sensor is provided that includes a launch vehicle to which three sections are attached. The first section is a buoy antenna section. The second section is an electronics canister section having control electronics. These sections are releasably attached to the launch vehicle. The electronics canister section is in contact with the antenna section and secured to the antenna section by a spring band. A communications cable is attached between the antenna and the control electronics. The third section is a spool section containing a spool of a fiber optic line sensor. This third section is attached to the launch vehicle by a rigid mount and is in contact with the electronics canister section. The fiber optic line sensor extends from the spool section into the electronics canister section to the control electronics.

Abstract: A marine pipeline installation system for laying an offshore pipeline and/or installing a subsea riser, the system at least allowing to carry out the reel lay method, wherein the system comprises: one or more storage reels for storage of pipeline, a pipeline launch tower adapted for launching the pipeline in the direction of the sea, a pipeline guide at an elevated position for guiding said pipeline to a pipeline launch trajectory along said tower, one or more tensioners, each tensioner comprising a tensioner frame and multiple tracks supported by said tensioner frame, said tracks being adapted for engaging the pipeline and supporting at least part of the weight of the launched pipeline, the tensioner frame being supported by said tower via an associated support assembly.

Abstract: An undersea installation for transporting hydrocarbons between a seabed and a surface and to a method for installing same. The installation includes a tubular undersea pipeline, a float and a coupling device. The undersea pipeline has a rising part, a connecting part and an intermediate portion. The coupling device includes a first longitudinal part and a second part connected in a coupling region of the first part. The coupling region of the first longitudinal part and the float being configured to be connected together. The first part is configured to pivot about the coupling region while bending the intermediate portion when the rising part is unwound and tilts towards the seabed.

Abstract: An actuating device (23) for a lay ramp (6) of a vessel (1) for laying underwater pipelines “(2) has a runner (28), and a carriage (29) connected to the lay ramp (6) and which runs along the runner (28) to lift and lower the lay ramp (6); the runner (28) being defined by a first, a second, and a third portion (31, 32, 33), of which the first and third portion (31, 33) are out of line with respect to each other, and the second portion (32) is mounted on a movable assembly (37) to selectively align the second portion (32) with the first and third portion (31, 33).

Abstract: A water-borne vessel for deploying a self-standing riser system is provided, wherein the vessel hull is configured to receive, transfer and deploy components of a self-standing riser system. The vessel hull includes at least a landing platform, a component transfer means, and a deployment platform suitable for deploying the riser components into associated surrounding waters. Various means of assisting the process whereby self-standing riser components are loaded onto the vessel and stored; transferred from receiving to deployment platforms; and deployed from the vessel into surrounding waters are also considered.

Abstract: The present invention relates to an apparatus for continuously laying a pipeline on the floor of a body of water from a pipelaying vessel, said apparatus comprising: a generally cylindrical reel with an axis upon which the pipeline is wound, a stinger provided at the stern of the vessel for guiding the lowered pipeline, launch means for the controlled lowering of the pipeline over the stinger of said vessel and into the body of water. This apparatus further comprises a frame supporting the reel and the launch means, adapted to be moveable with respect to the vessel in the longitudinal direction of the pipeline, and a tension device to be mounted between the frame and the vessel, adapted to control the pipeline tension in a predetermined tension range during pipelaying.

Abstract: The present invention relates to a method for laying a pipeline using a vessel (1) comprising a crane (2) comprising the following steps lifting a new pipe section (8) using the crane, placing a new pipe section on an existing pipeline (9), lining up the new pipe section with respect to the existing pipeline, welding the new section to the existing section, lowering the joined new section and the existing pipe, supporting the joined new section so that the crane is free to lift another new section. The invention further relates to a pipe-laying vessel for carrying out such method.

Abstract: The invention provides an apparatus and a method of deploying a tubular along a predetermined path. The method includes the steps of: coiling a tubular; accommodating the tubular in a deployment unit such that at least a portion of the coiled tubular is biased radially outwardly against the deployment unit; and deploying the tubular from the deployment unit along the predetermined path. The tubular can be deployed in a fluid along a predetermined path by: independently suspending the deployment unit in the fluid; and moving the deployment unit adjacent the predetermined path and simultaneously deploying the tubular along the predetermined path. The apparatus for deploying a tubular can comprise a deployment facilitator for facilitating deployment of the coiled tubular. The tubular can be arranged to feed into the deployment facilitator in use, and the deployment facilitator can be adapted to substantially reverse the coil bend of the tubular.

Abstract: A system usable with a pipe laying vessel, includes a support frame, such as a deck frame of the vessel, and a loader arm which is movable between a loading position and an upright position. The loader arm is provided with a pipe section manipulation system. A first clamping member is provided having a substantially fixed position with respect to the support frame. The first clamping member is operable between a clamped position for supporting the weight of the pipeline, and a released position for allowing the pipeline to be lowered. A second clamping member is movable between an upper position and a lower position. The second clamping member is operable between a clamped position for supporting the weight of the pipeline during movement from the upper position to the lower position, and a released position for moving the second clamping member from the lower position to the upper position.

Abstract: The invention relates to a pipeline laying vessel (1) for laying a pipeline (2) at a seabed (3) and comprising a tower (4) comprising a firing line (5) along which in use the pipeline is laid and at least one work station (6) for connecting a pipe section (7) to a suspended pipeline and a method of laying pipeline at a sea bed with such a pipe laying vessel.

Abstract: An apparatus for controlling tension in a wireline (4), the apparatus comprising a reel (3) mounted on a vessel or surface platform for controlling a wire in a wireline operation, a primary drive means (5) between the reel and a subsea installation around which the wireline is wound and control means for synchronising the operation of the driver with the reel.

Abstract: A method of laying pipeline from a vessel (10) is disclosed. The vessel (10) includes many pipe processing stations (36, 42), arranged across the width of the vessel. In one embodiment, there are two pipe processing areas (38, 40) separated along the length of the vessel. The pipe processing stations (36, 42) may be operable in two modes of operation, for example, a first mode of operation where the vessel produces triple joint pipe strings (from three lengths of pipe section welded together) and a second mode of operation where double joint pipe strings are produced, for example, from two single length pipe sections having a significantly greater length than the single length pipe sections used in the first mode of operation. In one embodiment, a triple joint pipe section is part welded in one pipe processing area (38), then moved along the length of the vessel (10) to a different pipe processing area, where further welding operations are performed on the triple joint.

Abstract: An apparatus to be mounted on a vessel for a laying a marine pipeline having accessories on the end of the pipeline and/or at one or more intermediate locations along the pipeline, said apparatus comprising a pipeline launch ramp (1) having pipeline guide means (6) for guiding and controlling the movement of a pipeline along a pipeline firing line in the direction of the seabed, pipeline clamping means (30) downstream of the guide means for selectively clamping and supporting the launched pipeline, wherein said launch ramp is provided with an opening (30) downstream of said guide means and upstream of said clamping means for passage of an accessory between a storage position and an installation location in the pipeline firing line to allow the accessory to be connected to an end of the pipeline supported by said clamping means.

Abstract: A lay ramp for an underwater-pipeline laying vessel has an inside ramp hinged to the laying vessel; an outside ramp hinged to the inside ramp; and an actuating device having a first actuating assembly for rotating the inside ramp with respect to the laying vessel, and a second actuating assembly secured to the outside ramp and to the first actuating assembly to rotate the outside ramp with respect to the inside ramp.

Abstract: A monohull vessel for laying a pipeline includes tensioners 13 disposed along a Pipelaying path P. The pipelaying path P includes an upstream portion that is substantially horizontal and at least 10 m above the centre of rolling R of the vessel and, towards a stern end of the vessel hull, a downstream portion that is downwardly inclined and, in use, enters the water at a location inboard of the stern end of the vessel hull 1.