Since the 1970s, offshore
oil and gas development has gradually proceeded from shallow-water
installations up to around 400 m (1,312 ft) to the ultra-deep waters around
3,000 m (9,842 ft) that represent the maximum today. The question is whether
the curve will flatten at 3,000 m, or if this is just a temporary pause on the
way to even greater depths. There have been plans for a gas trunkline from Oman
to India at 3,500 m (11,483 ft) depth, but it is yet to be seen if there will
be many such projects in the near future.
Pipe wall thickness
The main design challenge
for development beyond 3,000 m is related to the high external pressure that
may cause collapse of the pipeline. From depths of 900 m (2,953 ft) onwards,
external over-pressure is normally the most critical failure mode for
pipelines. The risk of collapse is typically most critical during installation
when the pipe is empty and external over-pressure is at its maximum.
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Many of the world's offshore
pipelines are designed and constructed to DNV's pipeline standard
DNV-OS-F101, and new concepts such as pipe-in-pipe may easily be accounted
for by adjusting the relevant failure modes. (Photo courtesy DNV)
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In addition, the pipe will
be exposed to large bending deformation in the sag bend during installation
that may trigger collapse, and collapse may also be relevant for operational
pipelines subject to significant corrosion.
The main manufacturing
processes relevant for larger-diameter, heavy-wall line pipes are UO shaped,
welded and expanded/compressed (UOE/C, JCOE) and three roll bending. These
processes provide a combination of excellent mechanical properties,
weldability, dimensional tolerances, high production capacities and relatively
low costs compared to seamless pipes.
There are at least six
pipe mills that regularly supply heavy-wall, welded line pipe for offshore
projects based on the UOE process: Tata Steel, Europipe, JFE, Nippon Steel,
Sumitomo, and Tenaris. Research into further improving manufacturing techniques
continues in the industry, and we also see several "newcomers" that
can produce good quality pipes for deepwater.
This potential failure
mode is normally dealt with by increasing the pipe wall thickness. But at
ultra-deepwater depths, this may require a very thick walled pipe that becomes
costly, difficult to manufacture, and hard to install due to its weight.
Currently, there is a practical limit on wall thickness that limits the maximum
water depth for 42-in. pipes to around 2,000 m (6,562 ft) while for a 24-in.
pipe, this limit is approximately doubled to 4,000 m (13,123 ft).
Three factors have a major
influence on the final compressive strength of the pipeline: quality of plate
feedstock, optimization of compression and expansion during pipe forming, and
light heat treatment. By focusing on these factors together with improving the
ovality of the final pipe, it is possible to obtain a collapse resistance
comparable to that of seamless pipes.
X-Stream
X-Stream is a novel
pipeline concept developed by DNV that aims to solve the collapse challenge by
limiting and controlling the external over-pressure. In a typical scenario, the
pipeline is installed partially water-filled, and is thus pressurized at large
water depths. Then, to ensure that the internal pressure does not drop below a
certain limit during the operational phase when it is filled with gas, it is
equipped with a so-called inverse HIPPS (i-HIPPS).
This system also includes
some inverse double-block-and-bleed (i-DBB) valves. It is inverse in the sense
that instead of bleeding off any leakage to avoid pressure build up in standard
DBB systems, any leakage and loss of pressure is avoided by a pressurized void
between the double blocks. This is needed to avoid unintended depressurization
by a leaking valve which may not be 100% pressure tight when the pipeline
system is shut down. Studies undertaken during the development of X-Stream show
that the weight increase due to flooding is more or less balanced by the
reduction in steel weight.
X-Stream is still at the
concept development stage. Some practical aspects need to be studied, such as
how to install large valves in ultra- deepwater. Another aspect is repair
procedures and equipment, even though that should not be much different from
normal ultra-deepwater pipelines. There are also some optimizations to be
performed with respect to pressure loss during operation and equalization of
the pressure during shutdown.
However, the potential
benefits of the X-Stream concept to gas export and trunk lines at ultra-deep
waters are quite significant, such as:
- Reduced
steel quantity and associated costs
- Use of
standard pipe dimensions, even for ultra-deepwater and large diameters,
reduces line pipe costs
- No need
for buckle arrestors
- No need
for reserve tension capacity in case of accidental flooding.
In addition, a rough cost
comparison indicates a 10-30% cost reduction (steel cost, transportation cost,
welding cost) compared with a traditional gas trunk line.
Installation methods
There are three main
methods used to install offshore pipelines: reeling, S-lay, and J-Lay. In
ultra-deep waters, the combined loading of axial force, bending, and external
over-pressure during installation can also be critical to wall thickness
design. A significant external over-pressure in ultra-deep waters sets up both a
compressive longitudinal stress and a compressive hoop stress. Both tend to
trigger local buckling at less bending compared to a pipe without the external
over-pressure.
A common challenge for all
installation methods when it comes to deep and ultra-deep waters is the tension
capacity. The catenary length before the pipeline rests at the seabed can
become quite long, due to the water depth. The pipe needs to be very thick
walled to have the necessary collapse capacity; and thus the submerged weight
can become high. It is also often required that the installation vessel be
capable of holding the pipe in case of accidental flooding (e.g. a wet buckle).
However, it is still a topic of discussion whether it is absolutely necessary
to be able to hold an accidentally flooded pipe.
The tension capacity of
current vessels limits the water depth for 18 to 24-in. pipelines to around
3,000 m, when not accounting for the accidental flooding case. The limit for
30-in. pipelines is around 2,100 to 2,500 m (6,890 to 8,202 ft). New vessels
with a tension capacity of 2,000 metric tons (2,204 tons) will be able to
install up to 24-in. or maybe 26-in. pipes at 4,000 m (13,123 ft) water depth,
while for 42-in. pipelines the maximum depth will be around 2,500 m (8,202 ft).
Another challenge related
to deepwater installation is how to detect buckles during installation.
Normally, a gauge plate is pulled through the pipeline by a wire at a certain
distance behind the touchdown point. In case of a buckle, the wire pulling
force will increase to indicate that something is wrong. However, in ultra-deep
waters, the length of the wire and the friction between the wire and the curved
pipeline may give challenges in detecting minor buckles. Having a long wire and
buckle detector inside a pipeline during installation can also be risky. If the
pipeline is lost, the water will push the wire and gauge plate inside the
pipeline and it may not be possible to get it out again.
Suspended installation
The Ormen Lange field is
located in a pre-historic slide area, with an uneven seabed at nearly 900 m
(2,953 ft) water depth. In its early development phase, a submerged, floating
pipeline concept was studied to overcome the challenging seabed conditions. By
mooring the buoyant pipeline to the seabed, no seabed intervention work would
be required. The concept was left for the benefit of a more traditional concept
with the pipeline on the seabed mainly because of the challenges with
interference between trawl gear and the mooring lines, but it is still considered
feasible both with respect to installation and operation.
Another floating pipeline
concept has been developed by Single Buoy Moorings. Here the buoyancy is
ensured by a large-diameter carrier pipe to which the smaller pipelines are
attached. Buoyancy modules, clump weights, and the end anchoring system ensure
tension in the pipeline bundle. A short bundle connecting the FPSO and the spar
has been installed at Kikeh offshore Malaysia. However, the maximum length of
this concept can be extended by use of intermediate vertical supports.
Potential challenges will be hydrodynamic forces, both the steady-state drag
and the cyclic ones, including vortex-induced vibrations. The challenge is to
balance the need for anchoring with the need for flexibility to absorb the
forces. (e.g., by making the attachment to the mooring lines in such a way that
it does not cause too concentrated bending deformations).
Spiral installation
A future solution for
ultra-deep and topologically challenging locations may be to further develop
the SpiralLay method developed by Eurospiraal. In this application, the line
pipes are joined onshore and wound into a spiral for towing offshore. The
spiral can take a quite long length of pipeline which makes it possible to
pressurize it. On location, the pipeline is un-wound and installed in a short
time. The concept involves installing a pressurized pipeline from a submerged
spiral floating at a safe distance above the seabed, thus avoiding the
challenges with the combined loading in the sag bend at deep and
ultra-deepwater depths. This is a novel concept and needs further development
and testing.
Seabed intervention
Seabed intervention and
tie-in become more challenging with increasing water depth. Some of the
equipment, such as fall pipes for rock installation vessels, have practical
limitations (e.g. the maximum length of the fall pipe). The same is the case
with ROVs and other equipment needed for installation. Some repair methods -
such as retrieving a damaged part to the surface or using subsea welding with
divers - are limited by water depth, and can only be used in 200 to 400-m (656
to 1,132-ft) waters. For deepwater, repair methods based on remotely controlled
equipment are needed.
Recently developed repair
methods for deepwater are based on different types of clamps that are fitted
over a locally damaged area; or involve cutting and replacing a section with
use of end flanges/couplings and spool pieces. In cases with extreme or
comprehensive damage, a new pipeline section may be installed. Typically, both
the clamps and the end couplings need to be sealed with grouting or metallic
seals. Examples are the Oceaneering systems based on Smart
Flange/Connector/Clamp and the Chevron deepwater repair system. These are under
development, and designed to operate down to 3,000 m water depths. The
Statoil-led PRS consortium is also developing a repair system for deepwater
based on remotely welded sleeves. This system is based on two lifting frames,
cutting the damaged part, then installing some couplings and a new spool piece.
Notation fosters
innovation
Today, 65% of the world's
offshore pipelines are designed and constructed to DNV's pipeline standard
DNV-OS-F101. It is the only internationally recognized offshore pipeline
standard that complies with the ISO codes. The ISO pipeline standard itself,
the ISO-13623, is more like a goal setting standard with basically one hoop
stress criterion and one equivalent stress criterion, and with little guidance
for engineers on how to actually design a pipeline. Here, DNV-OS-F101 has found
its niche, giving more detailed requirements in compliance with ISO-13623.
Another reason for the
standard's success is that it is based on the so-called limit state design,
where all potential failure modes have to be checked according to specific
design criteria with given safety factors. This makes it easy to apply the code
to novel designs and outside the typical application range (e.g. in deep and
ultra-deep waters, in Arctic environments).
The collapse capacity and
the fabrication factor for UOE line pipes may be taken as a good example of the
flexibility of the DNV-OS-F101 code. The code contains a clause allowing for
upgrading the fabrication factor due to different aspects such as light heat
treatment and/or compression, instead of expansion at the end of the
manufacturing process. The code is also quite transparent in the way the design
criterion is written in order to facilitate and take into account innovation
and improvements in the fabrication process. Similarly, new concepts such as
the X-stream or various pipe-in-pipe concepts may easily be accounted for by
adjusting the relevant failure modes, and adding new ones if relevant.
The most likely deep and
ultra-deep potential field development areas known today are Gulf of Mexico,
the Brazilian presalt areas, and East and West Africa. All pose challenges that
could benefit from technology development and innovation.
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