The present invention relates to a vertical branch inline manifold system. In particular the invention relates to a vertical branch inline manifold system for installation on a pipeline conveying hydrocarbon fluids along the seabed. The invention is particularly adapted to allow tie-in connections to vertical connectors integrated in a pipeline. The inline manifold system of the invention allows replacement of external manifolds and is a simplified method for connecting multiple wells from a reservoir to a pipeline without the use of further manifold structures.
The inline manifold is intended for one or more branches, ending in a vertical connection and with a barrier valve.
The installation method for the vertical branch inline manifold system may be similar to inline-T installation, typically equipped with hinged mudmats, bend restrictors, support frame etc.
A typical seabed pipeline laying procedure includes implementing a pipe laying vessel where sections of pipeline are welded together on-board the vessel. The vessel moves at constant speed while welding stations are moving along the vessel at the same speed as the pipeline (typical s-lay method but can also be J-lay).
At present, the normal procedure is to lay down a pipeline at the seabed that is prepared for later connection of the various production equipment of the production field, such as manifolds, control systems, wellheads and Christmas trees etc. The various production equipment is separately lowered and thereafter connected to the pipeline.
However, there is a constant request in the marked for solutions enabling improved efficiency during layout of a production field. There is also a need for simplified field solutions that combine simplicity with flexibility.
Furthermore, if the seabed and soil of the oilfield contain sand or mud lowering the weight carrying capacity of the oilfield, it is an advantage to minimize the total weight of subsea equipment. It would be an advantage in such situations of one or more production structures could be integrated in the pipeline structure.
It is thus a purpose of the present invention to provide a manifold system integrated on a pipeline at an assembly stage that allows at least one branch to be installed while at the same time the inline manifold system is allowed to be installed and launched through the tensioner system and the stinger on the pipe lying vessel. Furthermore, it is a purpose of the present invention to provide a compact system that is simple to adapt to specific needs, that include few parts, that is easy to stock, that is standardized, and that has no flowline connections. The ability to be launched from a pipeline launch vessel and through a stinger makes the manifold system of the invention particularly suited for subsea use.
The term “vertical” it is meant to describe branches arranged mainly perpendicular to the pipeline axis. In preferred embodiments the branches will also be arranged perpendicular to the seabed or standing on the pipeline structure in a vertical position. The intention of arranging the branches perpendicular to one side of the pipeline is to obtain a slender structure for the overall manifold enabling passage through pipe laying equipment such as stingers on a pipeline laying vessel. The term “vertical” is thus chosen to simplify the description and should be used in this respect and to indicate the interrelation of the components and not the actual angle of installation.
The present invention relates to a hydrocarbon production inline manifold system comprising a carrier pipe with a longitudinal carrier pipe axis. “Hydrocarbon production” is intended to cover the different processes during hydrocarbon production and includes water injection into wells. The carrier pipe is provided with a plurality of hubs each with a jumper port and a hub longitudinal axis arranged perpendicular to the carrier pipe axis. The hub longitudinal axes of the plurality of hubs are in a common plane with the carrier pipe axis. A flowline is located inside the carrier pipe. At least one valve is located in a flowpath between each of the plurality of hubs and the flowline.
Each of the plurality of hubs may be fixed to a longitudinal alignment system attached to the carrier pipe.
The longitudinal alignment system may include a common carrier frame for the plurality of hubs. A plurality of frame spacers may extend between the common carrier frame and the carrier pipe. The at least one valve of each of the plurality of hubs may then be is located between the common carrier frame and the carrier pipe.
The longitudinal alignment system may include an individual carrier frame for each hub. A plurality of frame spacers may then extend between each of the carrier frames and the carrier pipe, and the at least one valve of each of the plurality of hubs is then located between each of the carrier frames and the carrier pipe.
Hinged mudmat elements may be arranged on each side of the carrier pipe and the alignment system.
A locking arrangement may lock the mudmats in an unfolded position upon transition of the mudmats from a folded position to the unfolded position.
A bend restrictor may be fixed to each end of the carrier pipe and the flowline may run through the bend restrictor.
A plane of the hinged mudmat elements in an unfolded position may be perpendicular each of the longitudinal axes of the plurality of hubs.
The carrier pipe may include openings, and a connecting pipe forming a T-branch with the flowline may extend through each of the openings in the carrier pipe and may be in fluid connection with each of the valves.
Short description of the enclosed drawings:
Detailed description of an embodiment of the invention with reference to the enclosed drawings:
The inline vertical manifold 1 is provided with a hinged mudmat 8.
In
A jumper port 19 on each of six vertical inline branches can be closed with a valve with a torque tool bucket 5 allowing a ROV to open or close the valve. Alternatively, the torque tool bucket 5 could be substituted with an integrated, powered actuator.
Each vertical inline branch includes a vertical hub and alignment system. The hub 2 includes a flowline bore from the jumper port 19 to the flow line, a carrier frame 3 and a valve.
The hinged mudmat 8 is secured to a carrier pipe 9 through a flowline bend restrictor 6 at each side interconnected by the carrier pipe 9. The flowline bend restrictors 6 are inline with the carrier pipe 9 while the flowline 10 is entered inside the bend restrictors 6 leading to the inline manifold 1. Six connecting sleeves connect the hubs 2 to the flowline 10 with respective valves through openings in the carrier pipe 9 and further to the flowline 10.
The carrier pipe 9 accommodates the loads in the flowline 10, and the bend restrictors 6 distribute the loads on the flowline 10 and prevent stress concentrations and buckling.
Temporary mudmat locking pins and/or secure wires (not shown) may be provided to hold the two, hinged mudmat halves of the mudmat 8 in a folded position prior to installation on a seabed. A pressure or protection cap (not shown) six in total may be located on each hub 2 to provide pressure barrier or debris/impact protection.
A transponder bucket 11 is installed allowing position measurement during and after installation, as well as metrology. An ROV may remove the instrument after final measurement.
The flows from the jumper ports 19 are channelled through each vertical inline branch at the centre of the inline manifold 1 to the carrier pipe 9 and further to the flowline 10.
Each bend restrictor 6 includes a padeye 12.
A longitudinal alignment system 23 including hub carrier frames 3 is supported at a distance from the carrier pipe 9 by frame spacers 4 at each end and at the middle. The frame spacers 4 are dimensioned to allow barrier valves to be installed between the longitudinal alignment system 23 and the carrier pipe 9.
Two spring loaded locking arrangements 7 hold the mudmats 8 in the unfolded position. The jumper ports 19 connect a jumper with the flowline 10. Padeyes 12 facilitate lifting.
The
The longitudinal hub block frame 3 supported at a distance from the carrier pipe 9 includes a straight frame portion extending along the length of the system to allow the number of hubs 2 to be lined up and secured to the frame. The frame spacers 4 are arranged at each end and at the middle of the longitudinal hub block frame 3. The frame spacers 4 dimensioned to allow the barrier valves 14 to be installed between the longitudinal hub block frame 3 and the carrier pipe 9, extending perpendicularly to a longitudinal axis 39 of the carrier pipe 9 and a longitudinal axis of the longitudinal hub block frame 3. The a longitudinal axis 39 of the carrier pipe 9 is perpendicular to a hub longitudinal axis 20.
The hubs 2 are directed perpendicularly to the flowline 10, the carrier pipe 9 and to the unfolded mudmat 8 and are thus facing directly upwards when the system is installed when the inline manifold 1 is positioned at the seabed, it will provide a vertical jumper connection.
In the installation configuration the at least two mudmat parts are folded and each carrier surface define separate carrier planes.
The folded position is maintained to allow assembly of the inline manifolds and the mudmats 8 onto the flowline on a pipe laying ship during pipe laying operations. The width of the assembly is less than a maximum width the pipe laying ship allows. The assembly may be installed on the flowline during ordinary pipe laying operation without stopping the pipe laying ship. The bend restrictor 6 and the carrier pipe 9 also facilitates the assembly on the flowline assembly line.
The hubs 2 are facing towards the top of the system and is located between the folded mudmat parts.
Six clamp connectors (not shown) are located on the hubs to provide suitable connections with branch pipes/jumpers.
Telescopic arms (not shown) may extend above the two mudmat parts and secure the mudmat in the open, unfolded position. The telescopic arms may run in a direction parallel to the mudmat parts when these are unfolded and may also contribute to the unfolding of the two mudmat parts in the event the mud mat parts do not unfold completely under the effect of gravity.
The embodiment on
Number | Date | Country | Kind |
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20190828 | Jul 2019 | NO | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2020/025302 | 6/25/2020 | WO |