Tc 67/sc 4 n date: 2005-03-9 iso/wd XXXXXX ISO tc 67/sc 4/wg 6 Secretariat: Design of dynamic risers for offshore production systems Élément introductif — Élément central — Élément complémentaire  Warning

Riser component descriptions

1. Components for fluid transfer

   1. Riser segments

Metal-pipe riser segments are joined together to make up a complete riser. A metal-pipe riser segment is typically constructed using a steel tube.

Individual riser segments may differ. The lowermost segment may contain a tapered stress joint section or a flex joint. It may also have a different end connection designed to transfer structural loads into the riser end termination rather than have the same connection used to connect the intermediate segments. The uppermost joints normally contain an attachment for the surface completion and for a load ring for the riser devices that tension or restrain the riser. Some intermediate joints may contain buoyancy or have buoyancy components attached to reduce the weight of the riser string in water. Some intermediate joints may also be design to accommodate interaction with the vessel, e.g. keel joints in Spar risers.

Riser joints may incorporate several tubulars, rigidly connected. This is often referred to as an integral riser joint. An example is a multi-bore hybrid riser joint discussed in above subsection.

Because of environmental conditions and installation or space limitation around the FPS, it may be advantageous to bundle several lines together. As shown in Figure 13, an Integrated Service Umbilical (ISU) consists of wrapping the control hydraulic hoses and electrical cables around the service line, instead of having a separate umbilical. It is also possible to bundle several flexible pipes or ISUs together, as in a multi-bore flexible riser consisting of one production line and an ISU that services more than one subsea well (Figure 14).

2. Fluid conduit interfaces

Flexible risers are connected at the upper end to the FPS and at the bottom end to either a flexible or metal pipeline or flowline, a subsea production tree, or some other subsea hardware (e.g. pipe line end manifold (PLEM)).

Couplings may provide attachment points for separate fluid lines. These lines must also contain seals at their connection interfaces. The design of these seals depends on the type of riser to which they are attached. There may be a requirement to connect to the mating member at the same time the riser segments are made up. If fluid lines are run independently, they can be attached separately. Additionally, the coupling type may vary along the length of the riser to accommodate variations in the riser segments themselves, such as in a tapered bottom segment.

The break-away flowline coupling (Figure 15) protects templates, satellite trees and flowlines from stress caused by external forces. It is preset to a desired breaking force. If a drift-off, drive-off or other emergency situation occurs, the break-away flowline coupling separates without damage to other riser components.

End Connectors – End connectors for a metal pipe must provide an attachment to equipment that interfaces with the top and bottom ends of the riser. This attachment must provide a means of containing the riser fluid at this interface under all loading conditions.

The top end connector of a metal pipe riser provides fluid containment in the connection to the surface production equipment. The top riser segment serves as part of the connection and contains the fluid seal. This segment also provides the attachment point for the tensioner system or hard tie-off depending on the configuration of the riser system.

The top end connector seal, like those of the couplings, may either be integral or non-integral. The integral seal forms part of the top riser segment. The connection mates to it and is non-replaceable. The non-integral seal configuration involves a replaceable seal housed in the top end connector, and is the type most commonly used.

The configuration of the top connector is dependent on the overall configuration of the riser system. This includes the tensioner or tie-off type, surface completion configuration, additional fluid line configuration and handling equipment, as well as the overall configuration of the FPS.

The bottom connector must provide the fluid containment seal between the riser and sea-floor equipment. The bottom connector differs from the other connectors (coupling and top connector) in that it usually must provide for remote makeup at the sea-floor. For this reason, the bottom connector uses a replaceable seal assembly and a latching mechanism that is capable of being operated remotely via a control system or ROV.

The bottom connector of a metal-pipe riser in an FPS is subject to tension and bending loads induced in the riser from the motions of the structure and other environmental loads. The connector must have adequate strength and rigidity to resist these loads while maintaining seal integrity.

• 
  an end connector that connects the flexible pipe conduit at a top, bottom or intermediate interface or a coupling that couples segments of flexible pipe;
  
• 
  an end termination that provides the connection between the flexible pipe and the metal end-connector or coupling.
  

End fittings should be designed to withstand the loads resulting from the flexible riser installation and operation. These loads include tension, pressure, shear, thermal loads and bending moments. The end termination should be designed in such a way that the flexible line, in no case, will be divorced from the coupling or end-connector. Couplings and end-connectors may be an integral part of, or attached to, the end termination to complete the end fitting.

End fittings may be installed on the pipe at the completion of pipe manufacture or installed in the field.

The flexible pipe manufacturer should be responsible for the method and design of the end termination so that it meets or exceeds the performance requirements.

The type of coupling or end-connector should be specified by the operator. A variety of couplings exists, such as bolted flanges, clamp hubs, threaded connections and welded joints. A discussion of pertinent types of couplings and end-connectors can be found in API RP 17A and API Spec 17D.

3. Fluid control and fluid isolation

Sales risers that connect the FPS to the subsea pipelines have isolation valves in the surface equipment and may have them in the sea bed equipment. The surface isolation is usually a ball or gate valve just upstream of the riser or a number of valves that isolate a manifold that co-mingles the flow going into the riser. The subsea equipment can be a ball or gate valve or a check valve. Large check valves with pigging capability have been introduced as isolation equipment in subsea pipelines.

2. Components for stability and external load control

   1. Tensioning and heave motion compensating systems

During drilling or workover operations, tubulars may be hung off at the top of the riser. However, the added weight of the tubulars below the mud line does not contribute to global buckling of the riser. Therefore, it is not necessary to increase the capacity of the tensioner for the below-mud line weight. Nevertheless, local stresses in the riser should be checked for this load case.

The tensioner system provides the full range of tension required during inspection and maintenance program activities. The tensioner system design must meet minimum tension requirement in the event of individual component failure during normal operations and during inspection and maintenance activities.

Structural design of the tensioner follows the latest edition of API RP 16F. Electrical design conforms to class and division requirements of the operating area on the FPS. The tensioner design load considers the normal operating load and any normal additional loads during operation that are incurred in standard operations. (An example of a normal additional operating load is additional load during drilling or workover operations).

2. Supplemental buoyancy

1. Distributed buoyancy

Closed cell foam is a type of buoyancy material that is usually produced by mixing two or more liquids that, when mixed, expand and fill the area into which they are poured. While expanding, the mixture creates vapor bubbles that give it buoyancy. This foam usually cannot withstand external hydrostatic pressures as high as syntactic foams.

Air cans are structures that provide a net buoyant force by displacing water with a gas in a confined reservoir space attached to or surrounding the riser. Air cans can be either configured with open bottoms such that the gas pressure equals the surrounding ambient pressure or be completely enclosed with an internal pressure significantly different than the surrounding ambient pressure.

Other buoyant materials can be used. The amount of buoyancy provided, the length of time the buoyancy must be present, the water depth, and the cost usually determine the adequacy of the material chosen.

2. Concentrated buoyancy

When concentrated buoyancy is used as a tensioner for spars, stops to limit vertical motion of the buoyancy cans may be provided. The lower stops limit buckling of the riser caused by excessive loss of buoyancy and the upper stops protect the deck area from upward motion of the buoyancy cans caused by a parted riser.

3. Flexure controlling devices

1. Metal pipe

One or more metal-elastomer bearings are used in flex joints such that tension and pressure loads through the joint produce compression in the bearing. Angular offsets of the tubular ends of the joint, such as those induced by offset and pitch and roll of the FPS vessel, produce minimal bending moments. Therefore, flex joints are used to allow large angular deflections in risers without producing large moments near the end connector. Because of the lack of parts that move relative to one another by sliding, flex elements have an inherent advantage of extended service life and require minimal maintenance when compared to ball joints.

2. Flexible Pipe

Another type of bend restrictor consists of a device with a tapered conical inner surface through which the flexible pipe passes. The bending radius of the pipe is restricted by contact with the surface.

4. Stabilizing structures

5. Centralizing devices

6. Devices for reduction of hydrodynamic loading effects

Currents may induce the periodic shedding of vortices in the wake of the riser, which may induce a vibrational response known as vortex induced vibration (VIV). Normally a fatigue assessment is made to determine if a vortex suppression device is required. Various types of vortex suppression equipment have been used. Attaching fairings in the shape of a hydrofoil have been used on some risers. The foils must rotate to align with the current. The foils are made of metal or composite structural material.

Attached streamers have been used on some small diameter risers. The width and length of the streamers determine their effectiveness. The streamers are made of fibers that can withstand the sea water environment.

Flow disrupters have been used on all sizes of risers. The shape of the disrupter determines its effectiveness. Locating smaller cylinders around the cylinder to be protected, wrapping the riser with helical strakes, varying the outside diameter of the riser by adding material and changing the surface shape, i.e., dimples or bumps, have all been used as flow disrupters. The specific application usually determines which flow disrupter is used.

Equipment that disrupts the coherence of the flow, such as helical strakes, reduces the VIV effects. Figure 20 shows a typical strake pattern. Parameters governing the effectiveness of the strakes to reduce VIV are strake height, usually specified as a fraction of the riser diameter, strake pitch, and number of strakes (typically three).

Both hybrid production risers and SCRs have used strakes as VIV suppression devices. Strakes can be manufactured using a variety of materials and shapes. The first hybrid riser installed in the Gulf of Mexico used fiberglass composite material reinforced with plastic and molded in a “T” cross section shape with a wide base and a raised center leg. Fixation of the strakes is either to the outer surface of the riser joint or to foam buoyancy material surrounding the riser.

3. Monitoring and control systems

Sensors and actuators mounted on the FPS or on the riser may use hydraulic, electrical, or optical signals carried via appropriate umbilicals or may use acoustic signals carried through the water. Subsea control systems available at this time utilize direct hydraulic control, piloted hydraulic control, electro-hydraulic/multiplex control, and acoustic-hydraulic/multiplex control. Umbilicals may need to be attached to the riser for support and protection.

4. Fluid purge and containment

   1. Planned disconnect

2. Unplanned disconnect

3. Quick disconnect for flexible risers

Individual hydraulic controlled conduit and multi-port systems are currently available. They consist of: a remote connector, an alignment frame and usually (depending on the application and the transported fluid) one or two valves, one on the flexible riser side, the other on the platform piping side. The control sequence allows for automatically closing the two valves prior to releasing the connector.

When released, the riser is dropped into the water in a controlled or uncontrolled fashion, depending on the project requirements and the type of emergency.

Alternative designs, known as quick connect/disconnect connectors (QCDC) provide a quicker way to perform the initial connection, or re-connection after abandonment of the flexible pipe to the platform.

5. Guidance (re-entry) equipment

• 
  guideline systems employ wire ropes (guidelines) and funnels or other guides to control the motion and position of equipment as it is run from the vessel to the sea floor;
  
• 
  guidelineless systems employ television, acoustics or other remote sensing systems to monitor the position of equipment as it is deployed. Controlling vessel position and/or ROVs align the equipment as necessary.
  

6. Anti-fouling equipment

Coatings have been used to reduce or eliminate certain types of marine growth. Many coatings are being investigated to determine their overall effect on the marine environment. Coatings are expected to remain a viable means of reducing marine growth on risers if their interaction with the environment is minimal. See Section xx.

7. Damage limitation measures

   1. Fire protection

Protection can be provided by active or passive means. Active fire protection involves the extinguishing of fires by dispensing proper fluids in sufficient quantity. Passive protection utilizes enclosures to impede the heat flow of the fire to the equipment to slow the temperature rise. Fire protection requirements for equipment Mechanical damage protection

The objective of these devices is to limit progressive damage to risers. Any technique that will address the problem can be considered. Some that have been use are: riser protection nets, bumpers, frames and coverings including buoyancy tanks/foams.

8. Insulation

7. 
   
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