Insulated pipework systems

Pipes and tubular conduits – Distinct layers – With intermediate insulation layer

Reexamination Certificate

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Details

C138S137000, C138SDIG009, C138S140000

Reexamination Certificate

active

06382259

ABSTRACT:

TECHNICAL FIELD OF THE INVENTION
The present invention relates to insulated pipework systems.
BACKGROUND ART
Such systems are used for transporting oil and/or gas from off-shore oil wells. They consist of a pipeline formed of a double walled pipe comprising an inner flow line within an outer sleeve. The pipes are generally coaxial, and the annulus between the two pipes contains an insulating material. Oil or gas extracted from underground reservoirs is normally at an elevated temperature and the insulation serves to maintain it in that state. If oil were to be allowed to cool then the higher melting point fractions would crystallise and could potentially block the flow line. It is therefore necessary in the design of such a pipe structure to ensure that the insulating material provides sufficient insulation to maintain an adequate temperature along the entire length of the flow line.
FIG. 1
shows a known double walled pipe structure comprising an inner flow pipe
10
held concentrically within an outer sleeve pipe
12
. Crude oil
14
flows within the flow pipe
10
. An insulating material
16
is placed in the annular region between the flow pipe
10
and the sleeve pipe
12
. The entire assembly is shown resting on the sea bed
18
.
An inevitable result of maintaining the crude oil at elevated temperature is that at least the flow pipe
10
will be subjected to thermal expansion. This will result inter alia in either an extension of the longitudinal length of the pipeline, or an increase in the longitudinal stress in the pipeline. Such stresses as may result from an increase to 190° C. are capable of causing plastic deformation in a steel pipeline. There are two generally accepted means of absorbing these thermal expansion problems; the first is to bury the pipeline beneath the seabed hence fixing it in position and preventing deformation. The other is to allow the initially straight pipeline shown in
FIG. 2
a
to adopt a meandering course as shown in
FIG. 2
b
and hence take up the increase in length. It is important that the longitudinal extension is maintained within acceptable limits, else a kink such as shown at
20
in
FIG. 2
c
can develop. Such kinks, or areas of excessively high curvature, can cause the pipeline structure to exceed its design limitations.
Double walled pipe structures are effective in limiting the overall longitudinal extension, as shown in
FIG. 3
a
. In the absence of longitudinal extension, the flow pipe
10
will be at an elevated tension shown at point
22
, whilst the sleeve pipe
12
at ambient temperature will be at zero tension, shown at point
24
. If both pipes are allowed to extend longitudinally, the composite structure will adopt a position in which the compressive tension in the flow pipe
10
balances the tensile tension in the sleeve pipe
12
, i.e. at point
26
. This point is a compromise situation in which the tension T
R
in both pipes is lower than a confined unextended pipeline, and the resultant extension is less than in an unconstrained single walled pipeline.
In order for this behaviour to be predictable, it is important that the flow and sleeve pipes
10
and
12
remain in longitudinal register, i.e. that individual elements of the pipe do not become longitudinally separated. The reason for this is shown schematically in
FIG. 3
b
, in which it has been assumed that part of the sleeve pipe
12
is constrained, for example by interaction with the seabed, and that the corresponding part of the flow pipe
10
has become free to move longitudinally relative to that part of the sleeve pipe
12
. This means that extension of the sleeve pipe
12
takes place effectively along a shorter length identified as
28
, whilst extension of the flow pipe takes place along the entire length. The result of this is that a smaller extension of the sleeve pipe
12
will cause the same increase in tension, and the balance point
26
′ is at a significantly greater tension in both pipelines. This tension is greater than the original design tension arrived at in
FIG. 3
a
and must therefore be avoided.
The maintenance of both pipelines in longitudinal register is commonly referred to as “longitudinal compliance”. It will be clear that longitudinal compliance is achieved by ensuring adequate transfer of longitudinal forces between the two pipes.
In existing pipelines, longitudinal compliance has been achieved by solid steel links between the two pipes at regular intervals. The difficulty inherent in this is that the links are an integral part of the flow line
10
which is intended to carry a fluid at an elevated temperature and pressure. This means that the entire structure must therefore meet the required design standards for the inner pipe, which requires careful control of the production conditions. This difficulty inevitably increases the cost.
In the system described in our earlier application now published as WO 96/36831, such castings were omitted and the bulkheads disclosed therein were used to seal in place hollow alumina-silicate microspheres as the insulating medium
16
. Such microspheres can, when compacted, provide a significant shear force transfer between the two pipes
10
,
12
. Hence, such a compacted insulator was capable of ensuring longitudinal compliance. The system disclosed in WO 96/36831 relied on this effect.
SUMMARY OF INVENTION
Other solid insulating materials are generally polymeric and are unable to withstand the elevated temperatures involved without degrading within the lifetime of the pipe. Fibrous insulation materials such as mineral wool have substantially no shear strength whatsoever and cannot therefore contribute to longitudinal compliance. One solid insulating material which is capable of withstanding elevated temperatures is commonly referred to as silica block. This is available in the form of a proprietary product called “Microtherm” (Registered Trade Mark) made by the company Micropore International Limited of Droitwich, England. A similar product is available as Wacker-WDS (Registered Trade Mark) from Wacker-Chemie GmbH of Munich, Germany. However, this insulating material exists as a solid block and cannot be compacted in place within the annulus. Thus, it cannot be used to transfer shear stresses or radial loads reliably.
Thus, the use of microspheres provides a significant advantage in the construction of the pipeline. However, microspheres offer only moderate thermal insulation as compared to other insulating materials. Approximate figures for the coefficient of thermal conductivity of alternative insulation materials are as follows.
Material
Conductivity Wm
−1
K
−1
Silica block
0.02
Polyurethane foam
0.03-0.06
Mineral Wool
0.04
Microspheres
0.1 
Syntactics
0.17
Thus, double walled pipe systems based on silica block, polyurethane foam and mineral wool offer the advantage that the external sleeve pipe of the double walled pipe system can be reduced in diameter in view of the lesser thickness of insulation material needed.
Where very high levels of insulation are needed, the required thickness of the microsphere insulation layer can become so great that the double walled pipe design becomes impractical. In these circumstances, therefore, alternative insulation materials are essential if a smaller practical and efficient sleeve pipe size is to be used.
The present invention therefore provides an insulated pipework system comprising an outer sleeve, an inner flow pipe and an insulating layer within the space therebetween, characterised in that the insulating layer comprises at least one discrete block of a first insulating material substantially surrounded by a second insulating material in particulate form.
This enables the discrete blocks of the first insulating material to provide the majority or all of the necessary insulation, whilst the particulate second insulating material can be packed around the first material in order to provide the necessary shear force transfer.
It is preferred if the first insulating material has a lower thermal conductivity than the second, m

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