• 专利附录
  • 专利说明
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    • 专利摘要:
    METHODS FOR MANUFACTURING A MECHANICALLY COATED PIPE, AND A MECHANICALLY COATED PIPE, TO LAY A MECHANICALLY COATED PIPING ON A COIL AND TO MANUFACTURE AND SET A MECHANICALLY, MECHANICALLY, MECHANICALLY, TESTED PIPE. A method of making a mechanically coated tube (MLP) that has an outer tube and an internol liner that comprises at least the steps of: (a) forming the outer tube as a single length; (b) forming an inner forming liner that is completely or substantially the same length as the outer tube of step (a); (c) locating the inner liner former of step (b) within the outer tube; and, (d) expand conformator of the inner liner inside the outer tube to form the MLP. In this way, the conventional need to overcome problems with welding numerous bodies of pre-formed 12 m or 24 m bimetallic tube to form a 1 km bimetallic tube is avoided, thus also avoiding weaknesses that can be part of welding processes. conventional bodies to form an MLP.
    公开号:BR112012012639B1
    申请号:R112012012639-3
    申请日:2010-12-08
    公开日:2021-02-23
    发明作者:Daniel Bertaso;John Hamilton;Sylvain Denniel;Brett Howard;Tomasz Tkaczyk;Aurélien Pepin
    申请人:Technip France;
    IPC主号:
    专利说明:

    [001] The present invention relates to a method of making a mechanically coated pipe and, optionally, laying methods, then a mechanically coated pipe formed from such pipes, particularly, but not exclusively, to supply a marine pipe.
    [002] Corrosion resistant pipes for the underwater transport or transmission of corrosive fluids such as gas or crude oil, can be supplied by pipes that have an internal metallic coating. A double-walled or bimetallic tube is generally composed of two metallic layers. The outer layer is to resist hydrostatic pressure and / or internal pressure, depending on the depth of the water, while the inner layer prevents damage to the outer layer from the chemical composition of the fluid being transported. The inner layer is sometimes also called a "coating". Since one of its main purposes is to protect the outer layer from corrosion, commonly a corrosion resistant alloy (CRA) is chosen for the coating.
    [003] One form of a bi-metallic tube is a single coated (“superimposed”) tube that has an internal CRA layer metallurgically linked to the outer layer, which could be formed from a carbon steel base metal.
    [004] A second form of bimetallic tube can be called a mechanically coated tube (MLP) formed of numerous tube bodies, in which a coating is attached to the outer layer such as carbon steel, without metallurgical connection. An economical method of forming a pipe section coated in this way uses hydraulic expansion, where the coating is inserted into the outer layer and then both parts are expanded. During expansion the inner layer undergoes a plastic deformation, while the outer layer undergoes an elastic or plastic deformation, which depends on the manufacturing process. An example of this involves inserting a 316L alloy overlay coater into a carbon steel host tube and expanding the coating radially so that it contacts the host tube, and then the outer diameter of the host tube will also be expanded along with the coating to a predetermined strain level, such that after relaxation of the internal pressure, an interference contact voltage between the coating and the host tube remains.
    [005] Such bimetallic tube bodies are generally manufactured in lengths of 12m or 24m at a manufacturing location and then then transported to a base or location by a river or sea, for welding together to conventionally standard length of 1 km.
    [006] However, corrosion can occur on the inner surface of the outer host tube layers during transport and storage of such tube bodies prior to use. Several manufacturers and suppliers of such pipe bodies have different ways of overcoming this, although the most common method involves welding each end of the inner liner to the ends of the outer tube to seal them. For example, the steel tube shown in EP0150041A2 has a double construction in which an outer carbon steel tube element is coated over its entire length with a corrosion resistant material, which consists of titanium.
    [007] Bimetallic tube bodies are conventionally transported and assembled on site, on a coil base by completing circumferentially top welds between the tube bodies. The material used to make the welds is generally the same as the material used for the internal coatings to ensure the continuity of the coating material in the region of the welds. Thus, for example, when a corrosion resistant alloy is selected for the internal coating for an application in acidic service (ie, in environments containing elemental sulfur) it is important that the property of the coating material is maintained throughout the entire process. lining length. For this reason, all welds of such 12 m or 24 m bimetallic tubes are made with consumables made of corrosion resistant alloy material.
    [008] However, such consumables have a higher cost than other types of consumables, such as those formed only of carbon steel. In addition, during the body welding process, the materials used for the inner liner and the external host tube can mix and form an alloy. Thus, the integrity of the internal coating may not be maintained at the weld locations, despite the use of consumables of the same material as the internal coating. Any loss in integrity anywhere along the pipeline is naturally catastrophic for the entire pipeline.
    [009] EP0150041A2 proposes a method of making corrosion-resistant steel tubes of “limited” lengths after fabrication and transportation of the tube to a construction site, based on using extreme tubes so that a metallic titanium is superimposed on the elements outer tubes before welding.
    [0010] GB2275639A describes welding its bimetallic tubular elements to form a tube, so that the top welds formed do not contact the outer layers, followed by the addition of welding gloves superimposed circumferentially around each weld without contacting the inner layers.
    [0011] Such welding processes still take time and involve more complicated welding processes and additional materials, such as gloves than is desired in practice to avoid one or more of the above problems.
    [0012] An object of the present invention is to provide a simpler method of making a mechanically coated tube.
    [0013] According to a first aspect of the present invention there is provided a method of making a mechanically coated tube (MLP) that has an outer tube and an inner tube that comprises, at a minimum, the steps of: (a) forming the tube external as a single length; (b) forming an inner liner former that is completely or substantially the same length as the outer tube of step (a); (c) locating the inner liner former of step (b) inside the outer tube; and (d) expanding the inner liner former within the outer tube to form the MLP.
    [0014] In this way, the conventional need to overcome problems with welding numerous bodies of pre-formed 12 m or 24 m bimetallic tube to form a 1 km bimetallic tube is also avoided, thus also preventing weakening that can be a part of conventional stretch welding processes to form an MLP.
    [0015] The method of making a mechanically coated tube (MLP) according to the present invention can provide a mechanically coated tube of any length, which is generally at least 5, 10 or 20 times longer than conventional tube bodies. 12m or 24m in length.
    [0016] Thus according to one embodiment of the present invention, the method of the present invention provides an MLP that is greater than 500 m in length, optionally in the range of 800-1200 m in length and, preferably wholly or substantially 1 km of lenght. Currently submarine tubes that are 1 km long are the standard tube generically used to subsequently form a pipe, especially a pipe for laying under water or, otherwise, for use in a marine environment and, generally, having at least several kilometers of lenght.
    [0017] Mechanically coated tubes can be formed with any number of layers, jackets, coatings, etc., known in the art, but including at least one outer layer or external tube, such as an external carbon steel tube fixed to at least one inner layer or coating, such coating preferably being formed of a corrosion resistant alloy (CRA), for example, a superposition coating such as a 316L, 825, 625 or 904L alloy, without metallurgical bonding.
    [0018] The outer tube for the MLP can be formed as a single length using numerous known processes, including continuous forming as a single piece, or by welding together a plurality of outer tube bodies. For example, carbon steel tube bodies are easily manufactured and can be easily and quickly welded together using carbon steel consumables in a manner known in the art. Welding pipe bodies made of carbon steel alone is a significantly simpler process than welding pipe bodies of bimetallic materials, especially as it avoids any mixing of different materials that form new alloys.
    [0019] Similarly, the formation of an inner liner former that is totally or substantially the same length as the outer tube, such as being more than 500 m in length, optionally in the range of 800-1200 m and preferably totally or substantially one km long, it could be provided by numerous processes known in the art, which include continuous forming.
    [0020] The location of the shaped inner liner within the outer tube can be performed as a simple mechanical step of inserting the inner liner shaper into the length of the host outer tube using one or more simple mechanical operations.
    [0021] The expansion of the inner liner former inside the outer tube to form the final form and conformation of the inner liner and hence the MLP can be provided by any of a number of conventional methods, which include one or more mechanical processes and / or a or more hydraulic processes.
    [0022] Mechanical expansion processes include passing an expander through the length of the tube, in order to expand the inner liner former to correspond to the inner surface of the external host tube. A hydraulic process can be the use of pressurized water that passes through the length of the pipe, as performed during hydraulic testing at a pressure in the range of 20-50 MPa for example, whose test is carried out according to known standard procedures.
    [0023] According to an embodiment of the present invention, the method further comprises the step of coating the MLP thus formed, in particular the outer wall of the outer host tube, with one or more coatings known in the art.
    [0024] The manufacturing method according to the present invention provides a mechanically coated tube (MLP) of a substantial length, optionally, but not limited to, 1 km in length, such that the present invention extends to a tube mechanically coated or not formed according to the method as described here above.
    [0025] The MLP is preferably formed / manufactured / assembled on a coil basis generically where the MLP is wound on a coil. Generally, that is, on the shore, or at a location on the shore, optionally where the outer tube and / or the inner liner is shaped, preferably to form an MLP that is greater than 500 m in length and is ready for laying, preferably as part of a longer pipeline (generally several kilometers).
    [0026] According to another aspect of the present invention there is provided a method of making a mechanically coated pipe (MLPL) which comprises a conjunction of a plurality of mechanically coated pipes (MLPs) as defined here above. Generally, the conjunction is provided by welding a plurality of consecutive mechanically coated tubes, for example, each being 1 km long by using one or more pipe welding processes.
    [0027] An example of a pipe welding process to provide circular welds between two consecutive MLPs, which comprises welding using consumables of the same material as the internal coating material. Although the internal coating material is usually more expensive than external pipe material, this process requires only welding at each pipe length, for example, every 1 km instead of every 12 m or 24 m in length pipe.
    [0028] A second pipe welding process involves welding together consecutive outer tubes using consumables of the same material as the outer tube, such as carbon steel, followed by welding of inner pipe with consecutive inner linings. To help avoid any mix of welding materials to form unwanted alloys, the consecutive inner tube linings could be cut to allow clean welding of the outer tube, and the inner weld can then be performed cleanly between the two inner liners to avoid welds already formed from external pipe.
    [0029] According to another aspect of the present invention, a mechanically coated pipe is provided whenever formed according to one or more of the methods of manufacturing a mechanically coated pipe as described above.
    [0030] The manufacturing methods described here are not limited to the size, shape, design, design, physical and / or chemical properties of the outer tube and / or inner liner and, currently, the maximum wall thickness of an MLP liner conventional does not exceed 3.0 mm.
    [0031] According to another embodiment of the present invention the MLP comprises an overlapping coating, and the overlapping coating has a thickness of more than 2.5 mm, preferably equal to or greater than 3 mm.
    [0032] According to a particular embodiment of the present invention, the overlapping coating has a thickness defined by formula 1: D / t + 1406 D / R = 96.1 (I) where D is the diameter of the overlapping coating; R is the smallest radius of curvature of the coil; and t is the thickness of the overlay coating.
    [0033] The bending radius of a coil can be as low as 1.5 m and up to 10 m or more. The radius of the coil and coiled tube obviously increases when the tube is coiled over the coil. A typical example of a coil for laying marine piping has a minimum coil bending radius of 8.23 m.
    [0034] According to a particular embodiment of the present invention, the superposition coating has a thickness at least equal to the minimum coating thickness "t" calculated using formula (II)
    in which the minimum coating thickness is in mm; a00, a01 are constants defined by Table 1:
    Table 1 ε is the maximum winding deformation g is the radial insertion space in mm, and D = DH -2tH is the outer diameter of the coating in mm where DH and tH are respectively the outer diameter and the wall thickness of the outer tube. host of the MLP, in mm.
    [0035] One or both of the above formulas can provide the minimum wall thickness of a liner for a given liner diameter, which is also approximately equal to the inner diameter of the outer tube or host and a coil radius. The MLP can then be designed and manufactured according to the formulas, such that it can then be loaded directly onto a coil in a conventional manner without requiring any internal pressure, either completely or in sections of it.
    [0036] There are two common methods of laying underwater or marine pipes. The so-called “kiln piping method” involves assembling pipes on a marine pipe laying vessel and then welding each one as the laying progresses. In the so-called coil-laying method the pipe is assembled on land from a number of lengths of pipe and then directly wound onto a large coil, sometimes also called a coil or storage coil. Once offshore, the tubing is unwound from the coil as a single entity and is directly available for laying, since no welding is required during offshore operation.
    [0037] The soaked laying method is faster and more economical than the “oven piping method”, so that it is preferred where possible. However, the winding process obviously generates significant pipe bending, which could cause a conventional coating on a conventional coated pipe to wrinkle and wrinkles are now considered to be harmful to an MLPL. Thus, all current methods developed to load an MLPL onto a coil were based on the idea that the formation of any wrinkles should be avoided at all costs during the winding processes.
    [0038] For this reason there are currently no actual uses or commercial applications of the coil-laying method for bimetallic tubes and any proposed methods for winding an MLPL onto a coil involve maintaining a pressure inside the pipe during the winding / unwinding process.
    [0039] For example, WO 2008/072970 A1 discloses a method for laying a pipe that has a corrosion-proof internal metallic superposition coating, which is tightly adjusted with metallic contact to an external pipe material. In this method a section of the pipe is wound on a pipe laying coil while an overpressure is maintained inside the section by means of a pressurized fluid. When the pipe has no movement, the overpressure is released, and another section of pipe is joined to the first section. A new overpressure is then applied within the sections and the additional section is wound over the pipe laying coil.
    [0040] Although this method can assist in practice to avoid deformation when the pipe sections do not have “mechanical movement” (which is defined in WO 2008/072970 A1 as meaning to roll the pipe over or unroll the pipe from the pipe laying coil ) this method requires the steps of overpressurization and pressure relief each time two sections of tube are joined. The pipe laying coil is described in WO 2008/072970 A1 as having typically installed several prefabricated sections, creating significant multiplication of the required steps of overpressurization and pressure relief.
    [0041] It is another object of the present invention to provide simpler and more practical methods of coil-laying an MLPL formed from MLPs formed as described here above.
    [0042] Thus, according to another aspect of the present invention, a method of coiling a mechanically coated pipe (MLPL) formed as described above is provided, the method comprising at least the steps of: (i) winding the MLPL on a coil in the complete or substantial absence of internal pressure above the ambient pressure in the MLPL; (ii) unwinding the MLPL from the coil; and (iii) straightening the MLPL unrolled from step (i) to provide an MLPL for settlement.
    [0043] According to yet another aspect of this monthly, a mechanically coated pipe (MLPL) formed as described here above is provided in a coil laying method, the method comprising at least the steps of: (i) wrapping the MLPL over a coil, which results in the formation of wrinkles in the rolled MLPL; (ii) unwinding the MLPL from the coil; and (iii) straightening the MLPL unrolled from step (ii) to provide an MLPL for settlement.
    [0044] After laying in step (iii), the deposited MLPL can be hydrostatically tested to provide a deposited MLPL completely or substantially having wrinkles, resulting from the manufacture or installation process, less than 2 mm in height.
    [0045] Minimizing the size of the wrinkles and / or particularly selecting the thickness of the inner liner (either as a former and / or once formed) of the MLP (and hence the MLPL formed subsequently) the coil laying methods according to with the present invention allow faster winding and unwinding to be carried out to provide faster and thus more economical coil seating of an MLPL. After the winding process (winding, unwinding and associated grinding as required), the residual wrinkles in the MLPL formed during the reel, reel removal processes can only be less than 4 mm high which can be optionally decreased to less than 1 mm or even less than 0.5 mm with pressure applied during a pre-commissioning operation, such as hydrostatic testing.
    [0046] In particular, the thickness of the inner coat is selected using formula I and / or formula II described here, to allow a thicker than conventional inner coat to be used, in which the wrinkles (formed during winding) are reduced to less than 2 mm after rectification and pre-commissioning the MLPL unrolled and deposited.
    [0047] According to an embodiment of these methods of the present invention, the step of: (iv) unwinding the MLPL from the coil in the complete or substantial absence of internal pressure above ambient pressure in the MLPL is provided.
    [0048] Thus, the present invention can provide faster winding or unwinding at ambient pressure within the MLPL without interrupting any internal pressurization steps.
    [0049] Once an MLPL is deposited, it is commonly pre-commissioned, and another embodiment of the present invention comprises the step of: (iv) pressurizing the MLPL after laying the MLPL.
    [0050] Preferably step (iv) comprises hydrotesting the MLPL, more preferably at one or the maximum hydrostatic test pressure according to DNV-OS-F101 (offshore standard, Det Norske Veritas, DNV-OS-F101, submarine piping, October 2007) and generally at a pressure in the range of 20-50 MPa, more preferably in the range of 30-40 MPa.
    [0051] The present invention extends to a method which comprises any combination of the above aspects and modalities such as even a combination of a method of making an MLP, forming an MLPL and winding and unwinding the MLPL on and of a coil followed by a pre-commissioning of the MLPL as described above.
    [0052] Thus, in accordance with a particular embodiment of the present invention, a method of fabricating and laying a mechanically coated pipe (MLPL) in a marine environment and formed of a plurality of mechanically coated pipes (MLPs) is provided, the method comprising, at a minimum, the steps of: (a) forming the outer tube of an MLP as a single length; (b) forming an inner liner former of an MLP that is completely or substantially the same length as the outer tube of step (a); (c) locating the inner liner former of step (b) inside the outer tube; (d) expanding the inner liner former within the outer tube to form an MLP with an inner liner; (e) conjugating a plurality of MLPs from step (d) to form an MLPL; (f) winding the MLPL over a coil, preferably in the complete or substantial absence of internal pressure above ambient pressure in the MLPL, (g) unrolling and straightening the rolled MLPL from step (f) to seat the MLPL in a marine environment; and optionally (h) hydrotest the MLPL deposited from step (g) to reduce any residual wrinkles in the MLPL optionally to a height of less than 6 mm, less than 4 mm, less than 2 mm, or less than 1 mm in height, preferably less than 0.5 mm in height.
    [0053] Optionally one or more wrinkle removal processes are applied to the MLPL, either before, during or after the hydrostatic test, as in step (h) above. Such processes can be provided by known methods and known apparatus, for example, the use of an internal or similar mandrel, which passes along the length of the MLPL to reduce the height of the wrinkles to one dimension, whereby subsequent hydraulic test pressure you can complete the removal of such wrinkles by generally applying a vertical force on such wrinkles to decrease their height. Internal and similar mandrels can be moved, or propelled in another way, through the MLPL using any known devices that include scraper pistons, cables, etc.
    [0054] The term "internal pressure" as used herein, refers to the pressure within the MLPL during the method of winding or unwinding such MLPL on or from a coil during its entire process or a complete process as opposed to processes of winding and / or unwinding that involve one or more stopping times or periods of time that require changes in internal pressure or internal pressure for the folding or unfolding of the MLPL.
    [0055] The term "straightening" as used herein includes one or more processes or stages of unfolding the rolled MLPL, after it leaves the coil and generally when it is distributed to its projected position and location. This can include one or more folding cycles, alignments and / or straightening steps usually before the MLPL enters the marine environment. The coil laying method generally involves at least the steps of aligning and / or straightening the MLPL through one or more chute tensioners.
    [0056] It is known that the extent of wrinkles formed in the winding of an MLPL depends on one or more of the following group: the interference contact stresses in the coating, the dimension of the coating, the space of radial insertion, the resistance to flow of the liner, the tensile hardening of the liner, the tensile response of the liner material, the applied folding deformation and the number of reverse folding cycles. There are two reverse folding cycles during a typical winding operation, and there can be as much as five folding cycles during a contingency winding operation.
    [0057] The severity of the bending deformation will depend on the diameter of the host tube and the bending radius will depend on the radius of the coil.
    [0058] A high interference contact voltage has a very beneficial effect on the coating winding and can reduce or even prevent coating wrinkling, especially in the first folding application. However, it is known that it is very difficult to control the target interference contact voltage during the manufacture of MLP and that a high variation in grip strength is expected. In addition, it is known that the grip force can be released. A reduction in the grip force can also be expected when applying the outer coating of the MLP at a temperature of 250 ° C due to the high thermal expansion coefficient of materials used for coatings, compared to that of the carbon steel used for the host pipe.
    [0059] These embodiments of the present invention have been found to be achievable based on an increased wall thickness analysis of the MLP's inner liner to determine a minimum liner wall thickness, which will result in any residual wrinkles having only a height of no more than 4 mm, such as less than 2 mm after winding (winding and unwinding) or MLPL straightening and / or pre-commissioning steps, that is, the wrinkles formed during the winding steps can be removed or their height reduced during the straightening and / or pre-commissioning of the MLPL, in particular, during hydrostatic testing.
    [0060] The present invention encompasses all combinations of the various embodiments or aspects of the invention described here. It is understood that any and all embodiments of the present invention can be taken in conjunction with any other embodiment to describe additional embodiments of the present invention. In addition, any elements of a modality can be combined with any of the other elements of any other modality, to describe additional modalities.
    [0061] Modalities of the present invention will now be described by way of example only, and with reference to the accompanying drawings, in which: Figure 1 is a diagrammatic view of a step of a method of forming a mechanically coated tube (MLP) of according to an embodiment of the present invention; Figure 2 is a diagrammatic view of a second step of a method of forming a mechanically coated tube (MLP) according to an embodiment of the present invention; Figure 3 is a schematic cross-sectional view of an MLP formed according to an embodiment of the method shown in Figures 1 and 2; Figure 4 is a schematic cross-sectional view of a first method of joining two consecutive MLPs; Figures 5a and 5b are seen in schematic cross section of the first and second stages of a second method of joining two consecutive MLPs; Figure 6 is a diagrammatic cross-sectional view of a method of winding an MLPL over a coil; and Figure 7 is a diagrammatic cross-sectional view of a method of unwinding and laying an MLPL from a coil.
    [0062] The present invention provides numerous methods for making, winding, unrolling, straightening and pre-commissioning a mechanically coated tube and piping, preferably as part of a method of making, laying and commissioning marine piping.
    [0063] Referring to the figures, figure 3 shows a schematic cross-sectional view of parts of a mechanically coated MLP 2 tube. MLP 2 generally comprises a number of layers, only two of which are shown in figure 3 for clarity, comprising an outer tube layer 4, which may be a carbon steel tube, and an inner layer or liner 6 that is formed of corrosion resistant alloy such as alloy 316L. The relative dimensions shown in figure 3 are not to scale, and are provided for clarity of representation.
    [0064] A method of making an MLP 2 that has a length of at least 500 m, preferably completely or substantially 1 km, is shown in a generic way in figures 1 and 2. Figure 1 shows a layer of shaped outer tube 4 that it could be made of carbon steel and could be supplied by welding together with numerous outer tube bodies of a shorter length, for example, the conventional length of 12 m or 24 m, made of carbon steel, and welded together using consumables carbon steel. Only welding using a material that is the same material as the outer layer 4 material significantly simplifies the conjunction of such outer layer tube bodies to provide an outer tube of the required length.
    [0065] It is emphasized that the present invention relates to the conformation and use of specific bimetallic tubes, which have a metallic coating instead of any form of plastic coating, and which have an extensive length. This denies the use of easy thermoplastic coating deformation processes to form bimetallic tubes, as well as the use of short-length fabrication processes, such as hammering and heating the outer tube.
    [0066] Figure 1 also shows an inner liner former 6a that is wholly or substantially the same length as the outer tube layer 4. Such inner liner former 6a could be formed using one or more conventional processes, and is preferably formed corrosion resistant material such as CRA. Being formed of a length that is completely or substantially the same length as the outer tube layer 4, this not only avoids the need for forming a large number of separate inner liner formers of length of the tube section, but also the need to realize a large number of welding operations to weld all of the inner coaters together. This avoids the time required for such welding operations and avoids the cost of using a large number of consumables that are higher in cost than carbon steel consumables. It also prevents any root defects that may be formed during such welding operations.
    [0067] Figure 1 shows the location of the inner liner 6a inside the outer tube 4 following the direction of arrow A.
    [0068] Figure 2 shows the application of an adequate pressure, such as water pressure, from the hydraulic test in the direction of arrow B to the internal of the inner liner 6a, in order to expand the inner liner 6a of circumferentially, and as shown generically by arrows C, to form interference contact stresses between the two formed layers 4, 6 and hence their joint connection to form a mechanically coated tube 2.
    [0069] Figure 4 shows a first method of manufacturing a mechanically coated MLPL 10 pipe which comprises joining by welding a plurality of mechanically coated MLPs pipes.
    [0070] Figure 4 shows two consecutive MLPs 12a, 12b, such as those formed as described above with respect to figures 1-3, each being 1 km long and involving an outer host tube 14 and an inner tube 16.
    [0071] The first method comprises using consumables of the same material as the inner liner material to provide a circular weld 18 between the two consecutive MLPs 12a, 12b, so that at least the inner liner material is continuous over the consecutive MLPs 12a and 12b. This process can provide an MLPL 10 that is a number of kilometers long ready for the coil laying method for laying marine piping.
    [0072] Figures 5a and 5m show a second method of manufacturing a mechanically coated MLPL 20 pipe comprising welding a plurality of mechanically MLPL pipes 22a, 22b, each having an external host pipe 24 and an internal liner 26 .
    [0073] Figure 5a shows a first step of the second method which comprises bringing together two MLPs 22a, 22b, such as those formed as described above in relation to figures 1-3, with the inner liner 26 being cut by such an amount as per 20 to 33 mm before butt welding the outer host tubes 24 circumferentially, preferably using the same material as the outer tube material, such as carbon steel consumables. This creates a carbon steel 28 weld between MLPs 22a, 22b.
    [0074] Figure 5b shows the second stage of the second method, in which a welding machine 30 is inserted into the MLPs 22a, 22b to combine the consecutive internal linings 26, generally filling the space between the two internal linings 26 preferably with the same material as the internal coating material, such as corrosion resistant alloy. Such filling can be provided by a rotating arm 32 capable of circumferentially filling the space between the liners 26, as shown in figure 5b.
    [0075] It is a particular advantage of both of these first and second methods, as shown in figures 4, 5a and 5b, that only one material is used during each welding process to minimize or avoid the possibility of mixing the external pipe material and of the material of the inner coating to form an alloy, the alloy of which could be a weakness in the MLPL which of course is not desired.
    [0076] In conventional MLP fabrication an inner layer less than 3 mm thick is provided over an outer layer and then expanded to provide an interference contact voltage between the two layers. However, the folding of a tube formed from two of the layers, such as winding or winding over a coil, has been admitted to create wrinkles that might not be removed after unwinding, and which were therefore considered to be sufficiently harmful to the finally deposited tubing that the formation of any wrinkles should be avoided at all costs.
    [0077] Thus, a high interference contact voltage is desired between the inner and outer layers, to prevent wrinkling of the inner coating compared to the outer coating. However, it is difficult to control the degree of interference contact voltage projected during the manufacture of such tubes, and a high degree of force variation occurs in practice. In addition, an interference contact voltage can be released when applying the first bend. Thus, the technique currently does not consider MLPLs formed from such MLPs to be usable in the embedding method and complicated steps and time delay and internal pressure interruption as shown in WO2008 / 072970 have been proposed.
    [0078] A surprising finding by the present Claimants is that some wrinkling (small, generally in the range of 4 to 6 mm) of the inner liner can be tolerated during folding of an MLPL formed from such MLPs, and that residual wrinkles having less than that 2 mm in height after straightening the MLPL can be reduced thereafter, preferably to less than 0.5 mm when pressure is applied to the interior of the MLPL. Such pressure could be applied during the pre-commissioning of a deposited marine pipe, for example, during its hydrostatic test.
    [0079] Thus the present invention is based on the ability to bend an MLPL, in particular on and from a coil, where at the end of the process there is often no wrinkle and or the residual wrinkles are not larger than 6 mm, often less than 6 mm in height after the subsequent steps of aligning and straightening the MLP. As the prior art methods for winding an MLP involve the use of internal pressure within the MLP, it is a surprising advantage of the present invention to be able to provide a method of winding an MLP over and from a coil in the complete or substantial absence of internal pressure above ambient pressure in the MLPL.
    [0080] Figure 6 shows a diagrammatic coil 40 that has a minimum bending radius "R", and a mechanically coated pipe MLPL skin 42 that has an outer tube diameter "D" The MLPL can be formed according to one of the methods shown in figures 4, 5a and 5b, that is, MLPL 10 or 29 and be several km long. Figure 6 shows the winding of the MLPL 42 over the coil 40.
    [0081] By way of example only, Coil 40 could have a bending radius R of 8.23 meters and or MLPL 42 could have a D diameter of 12.75 inches (323.9 mm) and a wall thickness 15.9 mm. Where the inner coating is alloy 316L, the use of formula (I): D / t + 1406 D R = 96.1 (I) as described above, provides a coating thickness of 6.3 mm.
    [0082] The formula (I) as described above, also allows calculation of a minimum coating thickness.
    [0083] The use of a 6.3 mm alloy coating such MLPL allows it to be wound directly and simply in a single section on a 8.23 m coil, in the knowledge that residual wrinkles formed between the coating and the outer layer after straightening will be less than 2 mm.
    [0084] Figure 7 shows a method of directly rolling out the rolled MLPL 42 directly from the coil 40 located on a suitable vessel 44, on a sea surface 46 to a seabed 48, generically known as the method of coil seating. According to the present invention, the method of unwinding the MLPL 42 from the coil 40 can be carried out in the complete or substantial absence of internal pressure above ambient pressure in the MLPL 42, making the process simple and relatively quick.
    [0085] Unfolded MLPL 42 provides deposited marine piping 42a after it has been straightened by passing through an aligner 50 of one or more straighteners 52, such as through tensioners before passing under vessel 44 to be deposited on the seabed 48.
    [0086] Pre-commissioning of the deposited MLPL 42 usually involves pressurizing the deposited MLPL 42a. Such pressurization can generally be provided by passing a pressurized fluid, such as water, along the deposited pipe 42a, an example being a hydrostatic test that is provided during a preconditioning process for an underwater pipe, generally at a pressure such as 30- 40 MPa, for example. If necessary or desired, pre-commissioning may also involve the passage of a wrinkle reducer such as a mandrel (not shown) along the deposited MLPL 42a to reduce the height of any wrinkles greater than 2 mm in height.
    [0087] The pre-commissioning may comprise a hydrostatic test step, in which the internal pressure applied during the hydrostatic test is in accordance with the codes. The hydrostatic test pressure can be related to the diameter of the host tube and the wall thickness of the coating. For example, a maximum hydrostatic test pressure can be calculated using the formula (III) p = 096 x 2 x SMYS x t / ID (III) where SMYS is the minimum yield stress specified at the test temperature; ID is the inner diameter of the tube; and T is the wall thickness of the coating.
    [0088] Whether after straightening and / or after such pressurization, wrinkles in the uncoiled MLPL 42 have been reduced at least, having a height of less than 0.5 mm, in order to provide a deposited MLPL 42a that has the same tension or similar interference contact voltage as the pre-wound MLPL shown in figure 3.
    [0089] Being able to wind and / or unwind an MLPL over a coil without requiring the MLPL to have an internal pressure such as that shown in WO2008 / 072970, the winding and / or unwinding process can be performed at a much faster speed faster than conventionally performed, reducing OPEX for such operations, and thus the overall time required to set up an MLPL. Where such MLPLs are several kilometers long, this provides significant savings in uptime and costs, based on significantly simpler methods, as described here above.
    [0090] Several modifications and variations to the described modalities of the invention will be evident to those skilled in the art, without departing from the scope of the invention, as defined in the appended claims. Although the invention has been described in connection with a specific preferred embodiment, it should be understood that the invention as claimed should not be unduly limited to that specific embodiment.
    权利要求:
    Claims (15)
    [0001]
    1. Method for making a mechanically coated tube (MLP) with a minimum length of 500 m having an external carbon steel tube and an internal corrosion-resistant alloy liner, characterized by the fact that it comprises at least the steps of: (a) form the outer tube as a single length; (b) forming the inner liner former with a minimum length of 500 m and the same length as the outer tube of step (a); (c) insert the inner liner former of step (b) with a minimum length of 500 m and the same length as the outer tube, into the outer tube of single length; and, (d) expanding the inner liner former into the outer tube to form the MLP.
    [0002]
    2. Method according to claim 1, characterized by the fact that the MLP is in the 800-1200 m range.
    [0003]
    3. Method according to claim 2, characterized by the fact that the MLP has a length of 1 km.
    [0004]
    Method according to any one of claims 1 to 3, characterized in that step (a) comprises welding together a plurality of outer tube bodies.
    [0005]
    5. Method according to claim 4, characterized in that it comprises welding the outer tube bodies together using consumables of the outer tube material.
    [0006]
    Method according to any one of claims 1 to 5, characterized by the fact that it still comprises the step of: (e) coating the MLP thus formed.
    [0007]
    Method according to any one of claims 1 to 6, characterized in that the MLP comprises a superposition coating.
    [0008]
    Method according to claim 7, characterized by the fact that the overlay coating has a minimum thickness of 2.5 mm, preferably greater than or equal to 3 mm.
    [0009]
    9. Method according to claim 8, characterized by the fact that the superposition coating has a minimum thickness of 3 mm.
    [0010]
    Method according to any one of claims 7 to 9, characterized by the fact that the superposition coating has a thickness defined by the formula (I) D / t + 1406 D / R = 96.1 (I) where: D is the diameter of the overlapping coating; R is the smallest radius of curvature of the coil; and t is the thickness of the overlay coating.
    [0011]
    Method according to any one of claims 7 to 9, characterized by the fact that the overlapping coating has a thickness at least equal to the minimum coating thickness "t" calculated by formula (II):
    [0012]
    Method according to any one of claims 7 to 11, characterized in that the overlapping coating is alloy 316L, 825, 625 or 904L.
    [0013]
    13. Mechanically coated tube (2), characterized by the fact that it has a minimum length of 500 m when formed according to the method as defined in any one of claims 1 to 12.
    [0014]
    14. Method for manufacturing a mechanically coated pipe, characterized by the fact that it comprises combining, by means of welding, a plurality of mechanically coated pipes, as defined in claim 13.
    [0015]
    15. Mechanically coated tubing (10, 20), characterized by the fact that it is shaped according to the method as defined in claim 14, and comprises a plurality of mechanically coated tubes (2) conjugated by means of welding.
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    同族专利:
    公开号 | 公开日
    CA2781586A1|2011-06-30|
    AU2010334603B2|2014-01-30|
    BR112012012639A2|2016-07-12|
    CA2781586C|2020-05-05|
    US8905675B2|2014-12-09|
    GB0922286D0|2010-02-03|
    EP2516909B1|2015-02-11|
    GB2476457A|2011-06-29|
    GB2476457B|2011-11-09|
    AU2010334603C1|2014-12-18|
    WO2011077110A1|2011-06-30|
    NZ600293A|2013-05-31|
    EP2516909A1|2012-10-31|
    US20130195557A1|2013-08-01|
    AU2010334603A1|2012-06-14|
    MY157043A|2016-04-15|
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    法律状态:
    2019-01-08| B06F| Objections, documents and/or translations needed after an examination request according [chapter 6.6 patent gazette]|
    2019-03-19| B06T| Formal requirements before examination [chapter 6.20 patent gazette]|
    2020-01-28| B07A| Technical examination (opinion): publication of technical examination (opinion) [chapter 7.1 patent gazette]|
    2020-07-21| B07A| Technical examination (opinion): publication of technical examination (opinion) [chapter 7.1 patent gazette]|
    2020-12-08| B09A| Decision: intention to grant [chapter 9.1 patent gazette]|
    2021-02-23| B16A| Patent or certificate of addition of invention granted|Free format text: PRAZO DE VALIDADE: 10 (DEZ) ANOS CONTADOS A PARTIR DE 23/02/2021, OBSERVADAS AS CONDICOES LEGAIS. |
    2021-06-08| B25A| Requested transfer of rights approved|Owner name: TECHNIP N-POWER (FR) |
    2021-08-31| B17A| Notification of administrative nullity (patentee has 60 days time to reply to this notification)|Free format text: REQUERENTE DA NULIDADE: SUBSEA 7 LIMITED - 870210077457 - 23/08/2021 |
    优先权:
    申请号 | 申请日 | 专利标题
    GB0922286.0|2009-12-22|
    GB0922286A|GB2476457B|2009-12-22|2009-12-22|Method of manufacturing a mechanically lined pipe|
    PCT/GB2010/052049|WO2011077110A1|2009-12-22|2010-12-08|Method of manufacturing a mechanically lined pipe|
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