法国专利FR3017179A1 MODULAR TRUNK FOR A WATER PIPE, WATER CONDUIT COMPRISING SUCH STRINGS AND THERMAL ENERGY SYSTEM OF T

专利PDF首页>>法国专利

专利附录

专利说明

权利要求

类似技术

同族专利

引用文献

法律状态

优先权

专利摘要:
The invention relates to a modular section (114) of water pipe comprising: - a deformable membrane (130) capable of including, in an operational state of the section, a tubular space (132) defining an axial direction (AA ') for conducting water, and - a succession (135) of rings (120, 140) extending along the axial direction (AA ') in the tubular space (132), and comprising: o two rings end (120), each being at a distinct end (116, 118) of the section (114) in the axial direction (AA '), the membrane (130) being attached to the end rings (120), at least one central ring (140), disposed between the two end rings (120), and o cables (150, 160) connecting each ring (120, 140) to the nearest ring (120, 140) according to the axial direction (AA ').
公开号:FR3017179A1
申请号:FR1400341
申请日:2014-02-06
公开日:2015-08-07
发明作者:Christophe Francois Laurent Royne
申请人:DCNS SA；
IPC主号:

专利说明:

[0001] Modular section of a water pipe, water pipe including such sections and system of thermal energy of the seas comprising such a water pipe The present invention relates to a modular section of water pipe comprising a deformable membrane capable of to encompass, in an operational state of the section, a tubular space defining an axial direction for conducting water, the membrane being able to separate the water present in the tubular space from the water present outside the the membrane. In addition, the present invention relates to a water pipe comprising a plurality of such sections. The present invention also relates to a thermal energy system of the seas comprising such a water pipe. There are marine thermal energy (ETM) systems that produce electricity, exploiting the difference in temperature between the surface and deep waters to drive a generator. For example, the temperature of the surface waters can reach or even exceed 25 degrees Celsius, while the deep waters, which are deprived of solar radiation, remain around 2 or 4 degrees Celsius. Such systems need a water pipe to draw in cold water. Cold water pipes have a significant length, for example more than 600 meters, and may have a length of more than 1000 meters. But such water pipes, for example those used on the ETM plant "Tunisia" in 1935, had problems due to significant deformation at the junction with the platform on which the ETM system was installed. The cold water pipe was steel with a diameter of about 2.5 meters and a length of 700 meters.
[0002] Recent installations use high density polyethylene for cold seawater piping. However, the diameter of high density polyethylene pipes is limited to a few meters. The cold seawater suction pipe may also be designed to withstand extreme environmental conditions, such as swell and / or currents. In cyclonic conditions, the swell and currents grow locally. The current due to the winds can thus reach 3 knots on the zone of exploitation. This surface current caused by the wind then decreases with depth to reach a zero value at about -50 meters. The first meters of the pipe and its connection with the platform are therefore critical points.
[0003] In previous systems, the problems encountered arise from an increased deformation at the connection of the cold seawater pipe to the platform, which resulted in the total or partial loss of this pipe. To overcome this problem, document FR-A-2 978 979 describes a flexible pipe which comprises a plurality of modular section, each section comprising two connecting rings, a membrane and tie rods. EP-A-2,585,677 discloses a conduit formed by a plurality of flexible modular elements connected by connecting rings. Tie rods strengthen the structure of the membrane. However, such devices are inconvenient to implement because the membranes of these pipes can be weakened by the tension of the tie rods.
[0004] There is a need for an economically cost-effective water line that is relatively convenient to fabricate, set up and dismantle, withstand extreme environmental conditions and to transfer significant seawater flows. To this end, the present invention relates to a modular water pipe section of the aforementioned type, wherein the section further comprises a succession of rings extending along the axial direction in the tubular space, the succession of rings comprising two end rings, each end ring being at a distinct end of the section in the axial direction, the deformable membrane being attached to the end rings, and at least one central ring, arranged between the two end rings, and cables connecting each ring to the nearest ring in the axial direction. The section according to the invention may comprise one or more of the following characteristics taken separately or in any technically possible combination: each cable has a first end and a second end each connected to an end ring or to a central ring, the ends being equidistributed angularly on each ring. each cable has a first end connected to a first central ring and a second end connected to an end ring or a second central ring and for each cable, the first end is angularly offset relative to the orthogonal projectile of the second end on the first central ring, of an angle less than 360 ° / n where n is the number of cables interconnecting the same first central ring and the same second central ring or the same end ring. each ring has a plurality of cable attachment points, at each point of attachment of a central ring and for each end, the ends of four cables are merged, two cables being connected to a central ring and two other cables being connected. to another central ring or to an end ring, and to each point of attachment of an end ring, the ends of two cables are merged. - The section is deformable between an operating position and a rest position and the central rings are arranged so that, when the section is in the operating position, the deformable membrane is in contact with at least one central ring, and when the section is in the rest position, at least one central ring delimits an annular space with the membrane. the cables are deformable between a stretched state and a relaxed state, and each central ring has an outer surface and when the section is in the operating position, the cables are relaxed, and each central ring is in contact with the membrane on any its outer surface. - The succession of rings comprises at least two central rings located between the two end rings and the cables are deformable between a tensioned state and a relaxed state and, when the section is in the rest position of the section, the cables connecting each central ring to the nearest central ring in the axial direction are stretched and the cables connecting a central ring to one of the two end rings are stretched. the number of cables connecting two successive rings is greater than or equal to six. the succession of rings comprises at least two central rings located between the two end rings, and the central rings are identical and the central rings have the same axis of symmetry, the direction of the axis of symmetry being the axial direction of the section. The invention also relates to a water pipe comprising a plurality of sections as previously described, the end rings of the successive sections being contiguous and fixed to each other. In addition, the subject of the invention is also a system for the thermal energy of the seas comprising at least one pipe, in particular upwelling as previously described, the pipe having a main axis in the axial direction, the axis of the pipe being arranged vertically.
[0005] The invention will be better understood on reading the description which will follow, given solely by way of example, and referring to the appended drawings, in which: FIG. 1 schematically represents an example of an ETM system in a closed cycle; - Figure 2 shows schematically, in side view, a floating platform of an ETM system according to one embodiment of the invention; - Figure 3 shows schematically, in perspective, a section of the water pipe of the platform of Figure 2 in a rest position; - Figure 4 shows schematically, in perspective, the water pipe section of Figure 3 in an operating position; FIG. 5 is a diagrammatic perspective view of the water pipe section of FIG. 3 in a folded position for storage and transport, and FIG. 6 is a schematic representation of a portion of the pipe section of FIG. above. FIG. 1 schematically represents a closed cycle ETM 1 system. The present invention is also applicable for open cycle or hybrid cycle ETM systems. The ETM system 1 comprises an evaporator 10 which is fed with a hot fluid, for example surface water, through a feed pipe 12. The hot fluid is used in the evaporator 10 to evaporate a circulating working fluid in a closed circuit 20. The working fluid, for example ammonia, is entrained in the closed circuit 20 by a working fluid pump 22. After having passed through the evaporator 10, the hot fluid is discharged into the sea by a delivery pipe 14. The discharge pipe 14 is sometimes also called the discharge pipe.
[0006] The working fluid evaporated in the evaporator 10 under high pressure is fed to an expansion turbine 30 which is connected to a current generator 32 by a shaft 34. In the turbine 30, the working fluid is expanded. Then, the working fluid is fed to a condenser 40 to be cooled and condensed and then fed by the working fluid pump 22 back to the evaporator 10. The condenser 40 is fed with a cold fluid, which is seawater of great depth raised by a cold seawater pipe 41. The cold fluid is driven by a cold fluid pump 42 which brings the fluid to the condenser 40. Then, the heated fluid is discharged into the sea by a delivery pipe 44. In the example illustrated in Figure 1, the cold fluid pump 42 is arranged at the upper part of the cold seawater pipe 41, downstream of the water pipe of cold sea 41. In this case the cold seawater pipe 41 operates in depression. FIG. 2 shows a floating platform 100 in the sea water 102. The platform 100 floats in the sea water 102 having a surface 104. An ETM system 106 is arranged on the platform 100. In a variant, the platform 100 has another shape, for example the shape of a barge. The platform 100 is held approximately in the same place by anchoring means 108, 110, which connect the platform to the seabed. A cold seawater pipe 112 is fixed to the bottom 111 of the platform 100. Driving cold seawater 112 is composed of a plurality of modular sections 114 which are fixed to each other in an axial direction AA '. Depending on the site of operation, the length of the cold seawater pipe 112 reaches a depth of about 1100 meters. In a variant, the ETM system 106 comprises several cold water pipes 112 instead of just one. Assuming there is only one cold seawater pipe 112, the diameter of the cold seawater pipe 112 is between 1 meter and 15 meters. The diameter of the cold seawater line 112 depends on the power of the ETM 106 system.
[0007] As illustrated in FIG. 2, the cold seawater line 112 is designed in a modular manner. The sections 114 of the cold seawater pipe 112 are manufactured separately on the mainland, transported to the location of the operation, and assembled and deployed from the platform 100 or from another platform, barge or boat. The sections 114 of the cold seawater pipe 112 will be described more specifically with reference to FIGS. 3 to 6. The cold seawater pipe 112 is fixed directly under the platform 100 and maintained with a minimum vertical tension to avoid the risks of relaxation in dynamic behavior in the axial direction. In addition, in one embodiment, the cold water line 112 at its lower end should be ballasted to limit deformation of the cold seawater line 112 caused by the depression and to limit the impact. of the current on the displacement of the cold seawater pipe 112. In one embodiment, the cold seawater pipe 112 is free at its end at the bottom. In what follows, the terms "upper" and "lower" refer to the direction of flow of water in the conduit formed by the modular sections when mounted on the ETM platform. Figures 3 to 6 illustrate an example of modular section 114 water pipe according to the invention. The section 114 comprises two end rings 120, a membrane 130 and a succession 135 of central rings 140 connected by cables 150, 160. In the following description, the two end rings 120 are called flanges. The section 114 is modular. This means that the arrangement of several sections 114 is able to form a pipe like the cold seawater line 112 of FIG. 2. The section 114 is generally cylindrical in shape with a circular base. Its generator is in the axial direction AA '. The section 114 extends between an upper end 116 and a lower end 118.
[0008] The section 114 is foldable in the direction AA '. The section 114 is deformable between a deployed position at rest, said rest position visible in FIG. 3, a deployed position during operation, said visible operating position in FIG. 4 and a folded position for storage, visible in FIG. The different positions of section 114 will be detailed later in the description. Each flange 120 is at a distinct end 116, 118 of the section 114 in the axial direction AA '. The flange 120 at the upper end 116 of the section 114 is called the upper flange. The flange 120 at the lower end 118 of the section 114 is called the lower flange.
[0009] The flanges 120 are annular. Advantageously, the flanges 120 have a diameter between 1 and 15 meters. The flanges 120 have the same axis of symmetry, the direction of the axis of symmetry being the axial direction AA 'of the section 114. The flanges 120 have, in one embodiment, a profile with normal profile I-beams (IPN). . For example, the flanges 120 have an IPN profile of 800 millimeters by 400 millimeters. The flanges 120 of two different sections 114 are hookable together. The assembly of the lower flange 120 of a section 114 with an upper flange 120 of another section 114 allows the formation of a pipe composed of the two sections 114. It is thus possible to choose the number of sections 114 to be assembled. to obtain the desired cold seawater pipe length 112 according to the application. The assembly of two flanges 120 is made so as to maintain a seal between the inside of the two joined sections 114 and the external water. In the example shown in Figure 2, all the flanges 120 of a cold seawater pipe 112 have the same characteristics regardless of their depth.
[0010] In another embodiment, the shape of the flanges 120 is optimized, in particular their profile, as a function of their position in the cold seawater line 112. This means that for each flange 120, the shape of the flange 120 is adapted to the depression in the cold seawater pipe 112 which decreases with the depth. The flanges 120 are infinitely rigid with respect to the membrane 130.
[0011] The flanges 120 are made of concrete. Alternatively, the flanges 120 are made of a material such as steel, titanium, a composite material or the like. The membrane 130 extends between the lower flange 120 and the upper flange 120. The membrane 130 is fixed to the flanges 120, for example in a sealed manner. The membrane 130 is generally cylindrical in shape with a circular base. Its generator is in the axial direction AA 'of the section 114. The membrane 130 includes a tubular space 132 in the direction AA'. The tubular space 132 is preferably a space of revolution around the axial direction AA '. The membrane 130 is able to conduct water inside the tubular space 132.
[0012] The membrane 130 is deformable. The membrane 130 is able to withstand the vertical forces associated with the mass of the cold seawater pipe 112. The membrane 130 is able to separate the water present in the tubular space 132 from the water present in the water. outside the membrane 130. The membrane 130 provides a sealing function. The membrane 130 is impermeable to water. The material of the membrane 130 is a textile, for example a synthetic textile. The succession of rings 135 extends along the axial direction AA 'in the tubular space 132. In the example shown, the succession of rings 135 comprises two flanges 120, four central rings 140, cables of FIG. end 150 and intermediate cables 160. The central rings 140 are located in the tubular space 132 between the two flanges 120 of the section 114. The central rings 140 have the same axis of symmetry, the direction of the axis of symmetry being the axial direction AA 'of section 114.
[0013] The central rings 140 are circular in shape. The diameter of the central rings 140 is preferably between 1 and 15 meters. In the example, the central rings 140 are identical. Each central ring 140 has an outer surface in the form of an annular surface. The central rings 140 are infinitely rigid with respect to the membrane 130.
[0014] The distance between two central rings 140 is defined as the distance between a point of the central ring 140 and its projection in the axial direction AA 'in the plane of the other central ring 140. Similarly, the distance between a central ring 140 and a flange 120 is defined as the shortest distance between a point of the central ring 140 and its projection in the axial direction AA 'in the plane of the flange 120. In the example, the distance between two central rings 140 successive succession of rings 135 and the distance between a flange 120 and the nearest central ring 140 is the same over the entire length of the section 114. The distance between two successive rings 120, 140 is advantageously between 0 , 5 and 8 meters. The central rings 140 are arranged so that when the section 114 is in the operating position, the deformable membrane 130 is in contact with at least one central ring 140, and when the section 114 is in the rest position, at least one ring central 140 defines an annular space 170 with the membrane 130. This means that the shape and the distance between the central rings 140 is adapted to the dimensions of the section 114 and the deformation of the membrane 130 in operation. In the example shown in Figure 3, the section 114 is in the rest position, each central ring 140 defining an annular space 170 with the membrane 130. Each annular space 170 completely surrounds a central ring 140. The size of the Annular space 170, i.e. the shortest radial distance between a point on the outer surface of the central ring 140 and the membrane 130 is between 10 and 200 mm. In such a situation, it should be noted the absence of direct links between the membrane 130 and the central rings 140. When the section 114 is in the operating position, all the central rings 140 are in contact with the membrane 130 on any their outer surface according to the example of Figure 4. For each flange 120, the central ring 140 closest to the flange 120 is defined as the central ring 140 for which the distance between the central ring 140 and the flange 120 in the axial direction AA 'is the weakest. Similarly, for each central ring 140, the central ring 140 closest is the central ring 140 for which the distance with the central ring 140 considered in the axial direction AA 'is the lowest.
[0015] For all following and for ease of understanding, the central rings 140 of the succession 135 are ordered. The first ring 141 is the central ring 140 closest to the upper flange 120. The second ring 142 is the lower central ring 140 closest to the first ring 141. The third ring 143 is the lower central ring 140 closest to the second ring 142. The fourth ring 144 is the central ring 140 the most close to the lower flange 120. The intermediate cables 150 connect the central rings 140 neighbors in the succession 135 between them. The arrangement of the intermediate cables 150 is visible in FIG. 3. Six intermediate cables 150 connect the first ring 141 to the second ring 142, six intermediate cables 150 connect the second ring 142 to the third ring 143, and six intermediate cables 150 connect the third ring. 143 to the fourth ring 144. Each intermediate cable 150 has a first end 151 connected to an upper central ring 140 and a second end 152 connected to a lower central ring 140.
[0016] The intermediate cables 150 are flexible. The intermediate cables 150 are deformable between a stretched state and a relaxed state. In one embodiment, the intermediate cables 150 are made of a synthetic material, including for example high-tenacity polyethylene, aramid, polyamide or the like. The end cables 160 have properties similar to the intermediate cables 150, only the differences will be detailed. Six end cables 160 connect the upper flange 120 to the first ring 141 and six end cables 160 connect the lower flange 120 to the fourth ring 144. The end cables 160 differ from the intermediate cables in that one of their ends is connected to a flange 120 instead of a central ring 140. On each central ring 140, the ends 151, 152 of the intermediate cables 152 are equidistributed angularly. For each intermediate cable 150, the first end 151 is angularly offset from the orthogonal projection of the second end 152 on the upper central ring 140. In the example shown, the angular offset is 60 ° (60 degrees). This angle offset value e is 3607n where n is the number of cables 150 interconnecting the lower ring 140 to the upper ring 140. Each central ring 140 has three cable attachment points 150, 160.
[0017] This number of attachment points is equal to n / 2 where n is the number of cables 150 interconnecting the central ring 140 to the lower or upper central ring 140. At each point of attachment of a central ring 140, ends 151, 152 of four cables 150, 160 are merged, two cables 150 being connected to a ring 120, 140 and two other cables 150, 160 being connected to another ring 120, 140.
[0018] FIG. 6 illustrates the arrangement of the attachment points of two successive central rings 142, 143. FIG. 6 represents the second ring 142 with these three fixing points represented by circles as well as the orthogonal projections of the three fixing points of the third ring. 143 on the second ring 142 represented by triangles. The attachment points of the second ring 142 are equidistantly angularly on the second ring 142 and spaced 120 °. The angular offset of the fixing points of the second ring 142 and the orthogonal projection of the fixing points of the third ring 143 is 60 °. This is in accordance with FIG. 3, namely that from each point of attachment of the second ring 142 two intermediate cables 150 are connected to the third ring 143 at adjacent attachment points and two intermediate cables 150 connected to the first ring. From each attachment point of the second ring 142 leave two cables to two adjacent points of the third ring 143 and vice versa. The disposition of the ends of the end cables 160 on each flange 120 is similar to the arrangement on a central ring 140.
[0019] Each flange 120 thus comprises three attachment points of the cables 160 equalized angularly. The attachment points are angularly offset 60 'from the orthogonal projected points of attachment of the nearest central ring 141, 144 of the flange 120 considered. From each fixing point of the upper flange 120, two cables 160 connect it to the first ring 141. Similarly, the lower flange 120 has three attachment points from which two cables 160 connect it to the fourth ring 144. This arrangement of the cables 150, 160 prevents any contact between the cables 150, 160 of the succession of rings 135 and the membrane 130 when the section 114 is in the rest position or in the operating position. The absence of contact between the membrane 130 and the cables 150, 160 prevents wear of the membrane 130 or cables 150, 160 by friction. In one embodiment, several cables 150, 160 are made by the same cable or wire that extends from the upper flange 120 to the lower flange 120 via the attachment points of the different central rings of the ring succession. 135. The cable or wire then has a zigzag shape around the circumference of the pipe section 114 112. The operation of the section 114 will now be described by detailing the different positions of the section 114, illustrated in Figures 3 to 5. The Figure 3 shows schematically, in side view, a section 114 in the rest position. The rest position corresponds to the position of the section 114 when the cold seawater line 112 is at a standstill, that is to say when there is no water flow in the pipe 112. In the rest position of the section 114, the intermediate cables 150 are stretched and the end cables 160 connected to one of the two flanges 120 are stretched. For example, when the section 114 is a module of a pipe mounted on the platform, the end cables 160 of the upper flange 120 and the intermediate cables 150 are in tension. The end cables 160 of the upper flange and the intermediate cables 150 support the weight of the ring succession 135. The tension in the cables depends solely on the weight of the rings 120, 140. There is thus no external force other elements of the section 114 on the rings 120, 140 in this situation.
[0020] In one embodiment, when the section 114 is in the rest position, the end cables 160 of the lower flange 120 are expanded to facilitate the establishment of the succession of rings 135 in the position intended for operation. . In this rest position of the section 114, the membrane 130 is stretched between the two flanges 120 and the tubular space 122 defined by the membrane 130 is cylindrical. In this rest position of the section 114, there is a space 170 between the central rings 140 and the membrane 130. In a variant, the friction force linked to the contact between the central rings 140 and the membrane 130 is small compared with the weight of the rings. central 140 when the section 114 is in the rest position. Figure 4 schematically shows, in side view, a section 114 in the operating position. The operating position is for example the position of the section 114 when the cold seawater line 112 is working in a vacuum. In this case, the cold fluid pump 42 is located in the platform 100. The pump is disposed at the top of the pipe 112 and operates in suction. The suction induces a depression in the pipe 112. The height of the section 114 in the operating position is less important than the height of the section 114 in the rest position. In this operating position of the section 114, the membrane 130 is deformed under the effect of the pressure difference between the water inside the tubular space 122 and the water outside the section 114. The membrane 130 is then in contact with the central rings 140. The contact between the central rings 140 and the membrane 130 is for example over the entire outer surface of the central rings 140.
[0021] In this operating position of the section 114, the central rings 140 are held in position by the membrane 130. So that the weight of the central rings 140 is supported by the diaphragm 130. In this operating position of the section 114, the cables end 160 and intermediate cables 150 are all relaxed.
[0022] Under the effect of the depression in operation, the membrane 130 presses on the central rings 140. The frictional forces between the membrane 130 and each central ring 140 are greater than the weight of the central rings 140 and the other external stresses (current, bending driving ...). The height of the section 114 and the distance between the rings 120, 140 decrease. The cables 150, 160 are thus relaxed.
[0023] Figure 5 shows schematically, in side view, a section 114 in the folded position for storage. The replanted position for storage corresponds to the storage position of the section 114. The height of the section 114 in the folded position for storage is less than the height of the section 114 in the operating position. The volume of the section 114 is reduced to facilitate its transport and storage. When the sections 114 are stored for transport or in anticipation of replacement, they are compacted to the maximum. The cables 150, 160 are relaxed. The distance between the rings 120, 140 is reduced from 1% to 10% with respect to the distance between the rings 120, 140 when the section 114 is in the operating position. As a variant, the addition of spacers between the flanges 120 of the section 114 in the folded position for storing the section 114 makes it possible to maintain the structure and to prevent the module from being crushed. The spacers are placed between the lower flange 120 and the upper flange 120 of each section 114. The sections 114 according to the invention are reinforced by the presence of central rings 140 in the tubular space 132 formed by the membrane 130. The succession ring 135 makes it possible to stiffen the membrane structure subjected to external pressure. The central rings 140 are held in place in the section 114, either by cables 150, 160 if the section 114 is in the rest position or by the membrane 130 if the section 114 is in the operating position or folded for storage. The membrane 130 is intact at the central rings 140. It is understood by "intact" that the membrane 130 is not affected by a seam, welding or piercing for maintaining the central rings 140 in position. Such a section 114 has an effective resistance to overpressure because the local stress between the central rings 140 and the membrane 130 is low in the rest position of the section 114. This means that the stress is low compared to a situation where the rings would be integrated into the membrane through sheaths. In summary, the invention which has just been described makes it possible to obtain a water pipe at a cost that is economically profitable, relatively convenient to manufacture, set up and dismantle, and resistant to extreme environmental conditions. In addition, this pipe makes it possible to transfer significant flows of seawater. The high flow rate of seawater makes it possible to compensate for the low efficiency and to limit the pressure drops of the ETM installations comprising such pipes. Such a pipe according to the invention can be used in the field of offshore ETM plants. The invention is also applicable to other industrial fields requiring the pumping or transport of large flow of fluids. For example, the invention is applicable to gas liquefaction plants, artificial "upwelling". Such a pipe is also used to raise cold water for the purpose of aquaculture and especially the cultivation of algae on the surface to produce food, cosmetics or biofuels. In addition to embodiments mentioned, the invention allows all variations accessible to those skilled in the art. In particular, the invention applies to a different number of central rings 140, a number of cables 150, 160 larger and a different arrangement of the cables 150, 160 on the central rings 140 or the flanges 120. Advantageously , the number of central rings 140 per section 114 is between 1 and 20.
[0024] Advantageously, the number of cables 150, 160 between two central rings 140 in succession or between a flange 120 and a central ring 140 is six in order to have a compromise between an optimization of the balancing of the ring succession 35 and a reducing the risk of contact between the cables 150, 160 and the membrane 130. In a variant, the number of cables is greater than six.15

权利要求:
Claims (11)
[0001]
CLAIMS1.- Modular section (114) of pipe (112) of water, the section (114) comprising: a deformable membrane (130) capable of including, in an operational state of the section (114), a tubular space (132) ) defining an axial direction (AA ') for conducting water, the membrane (130) being able to separate the water present in the tubular space (132) from the water present on the outside of the membrane ( 130), and the section (114) being characterized in that the section (114) further comprises: a succession (135) of rings (120, 140; 141, 142, 143, 144) extending along the axial direction (AA ') in the tubular space (132), the succession (135) of rings (120, 140; 141, 142, 143, 144) comprising: o two end rings (120), each end ring (120) being at a distinct end (116, 118) of the section (114) in the axial direction (AA '), the deformable membrane (130) being attached to the end rings (120), and oa at least one center ring (140, 141, 142, 143, 144) disposed between the two end rings (120), and cords (150, 160) connecting each ring (120, 140; 141, 142, 143, 144) to the ring (120, 140; 141, 142, 143, 144) closest in the axial direction (AA ').
[0002]
2. The section (114) according to claim 1, wherein each cable (150, 160) has a first end (151) and a second end (152) each connected to an end ring (120) or to a ring central (140; 141, 142, 143, 144), the ends (151, 152) being equally angularly distributed on each ring (120, 140; 141, 142, 143, 144).
[0003]
3. Section (114) according to claim 1 or 2, wherein: - each cable (150, 160) has a first end (151) connected to a first central ring (140; 141, 142, 143, 144) and a second end (152) connected to an end ring (120) or a second central ring (140; 141, 142, 143, 144), and- for each cable (150, 160), the first end (151) is angularly offset from the orthogonal projection of the second end (152) on the first central ring (140; 141, 142, 143, 144) by an angle less than 3607n where n is the number of cables (150, 160 ) interconnecting the same first central ring (140; 141, 142, 143, 144) and the same second central ring (140; 141, 142, 143, 144) or the same end ring (120).
[0004]
4. Section (114) according to any one of claims 1 to 3, wherein: - each ring (120, 140; 141, 142, 143, 144) comprises a plurality of cable attachment points (150, 160 ), at each point of attachment of a central ring (140; 141, 142, 143, 144), and for each end, the ends of four cables (150, 160) are merged, two cables (160) being connected to a central ring (140; 141, 142, 143, 144) and two other cables (150, 160) being connected to another central ring (140, 141, 142, 143, 144) or to an end ring ( 120), and - at each point of attachment of an end ring (120), the ends of two cables (150) are merged.
[0005]
5. A section (114) according to any one of claims 1 to 4, wherein the section (114) is deformable between an operating position and a rest position and the central rings (140, 141, 142, 143, 144) are arranged so that: - when the section (114) is in the operating position, the deformable membrane (130) is in contact with at least one central ring (140; 141, 142, 143, 144), and - when the section (114) is in the rest position, at least one central ring (140; 141, 142, 143, 144) delimits an annular space (170) with the membrane (130).
[0006]
The section (114) according to claim 5, wherein the cables (150, 160) are deformable between a stretched state and a relaxed state and each central ring (140; 141, 142, 143, 144) has an outer surface and when the section (114) is in the operating position, the cables (150, 160) are expanded, and each central ring (140; 141, 142, 143, 144) is in contact with the membrane (130) over any its external surface.
[0007]
7. Section (114) according to claim 5 or 6, wherein the succession (135) of rings comprises at least two central rings (140; 141, 142, 143, 144) located between the two end rings. (120), and the cables (150, 160) are deformable between a tensioned state and a relaxed state and, when the section (114) is in the rest position of the section (114), the cables (150) connecting each ring central (140; 141, 142, 143, 144) to the central ring (140, 141, 142, 143, 144) closest in the axial direction (AA '), are tensioned and the cables (160) connecting a central ring (140; 141, 142, 143, 144) at one of the two end rings (120) are stretched.
[0008]
8. Section (114) according to any one of claims 1 to 7, wherein the number of cables (150) connecting two rings (120, 140; 141, 142, 143, 144) successive is greater than or equal to six .
[0009]
9. Section (114) according to any one of claims 1 to 8, wherein, the succession (135) of rings comprises at least two central rings (140; 141, 142, 143, 144) located between the two end rings (120), and the central rings (140; 141, 142, 143, 144) are identical and the central rings (140; 141, 142, 143, 144) have the same axis of symmetry, the direction of rotation. the axis of symmetry being the axial direction (AA ') of the section (114).
[0010]
10. A water pipe (112) comprising a plurality of sections (114) according to any one of claims 1 to 9, the end rings (120) of successive sections (114) being contiguous and fixed to each other. other.
[0011]
11.- system for thermal energy of the seas (1, 106) comprising at least one pipe (112) including upwelling according to claim 10, the pipe having a main axis in the axial direction (AA '), l the axis of the pipe (112) being arranged vertically.

类似技术:

公开号 | 公开日 | 专利标题

WO2015118128A1|2015-08-13|Modular section of water pipe, water pipe including such sections, and ocean thermal energy system including such a water pipe

EP1073823B1|2006-04-26|Method and device for linking surface to the seabed for a submarine pipeline installed at great depth

US9022692B2|2015-05-05|System for underwater compressed fluid energy storage and method of deploying same

EP1899219B1|2012-02-15|Device for transfer of fluids between two floating supports

FR3048409A1|2017-09-08|STABILIZATION SYSTEM, ESPECIALLY FOR A FLOATING SUPPORT, WITH AT LEAST THREE LIQUID RESERVES CONNECTED THERETO

FR2850425A1|2004-07-30|Sub-sea collector for e.g. oil released from wreck, comprises modular textile column with upward and downward funneled terminations located by anchoring weights and flotation rings

FR2978979A1|2013-02-15|Modular and autonomous section for water pipe in closed cycle ocean thermal energy conversion system, has flexible membrane fixed to rigid rings, where elongated rods are connected to rigid rings and secured to flexible membrane

EP3394424A1|2018-10-31|Device for collecting energy frombroad wave spectra

EP2785952B1|2019-08-28|Flexible multiple seabed-to-surface connections facility on at least two levels

WO2005068832A1|2005-07-28|Floating device for recovery of swell energy with a spiral lift

FR3053020A1|2017-12-29|PLATFORM FOR A FLOATING WIND TURBINE, FLOATING WIND TURBINE EQUIPPED WITH SUCH A PLATFORM.

FR2916796A1|2008-12-05|BACKFILL-BOND INSTALLATION COMPRISING A FLEXIBLE LINK BETWEEN A FLOATING SUPPORT AND THE UPPER END OF A RIGID SUBSURFACE DUCT.

WO2016198250A1|2016-12-15|Assembly for drawing up water from a structure arranged on the surface of or in an expanse of water, and associated installation and manufacturing method

FR3068759A1|2019-01-11|CLEAN DRIVE TO BE MOVED BY A FLUID

FR3068761B1|2019-08-16|DEVICE FOR MOVING DECOUPLING BETWEEN A FLOATING PLATFORM AND A DRIVING

WO2013144610A2|2013-10-03|A screw device for a power generation or a material handling apparatus

WO2011124820A2|2011-10-13|Offshore installation for producing electrical energy

WO2019129804A1|2019-07-04|Fluid circulation pipe

FR3022955A1|2016-01-01|DEVICE FOR THE RECOVERY OF ENERGY ON BROAD SPARES OF HOLES

WO2019129805A1|2019-07-04|Liquid duct

FR3060096B1|2019-09-06|METHOD AND UNIT FOR HANDLING A FLUID TRANSPORT ASSEMBLY

FR2849474A3|2004-07-02|Equipment for transforming kinetic energy of water, air, etc, into electricity, has electrical energy management site distinct from collection site, and electrical/hydraulic flow producing unit and its regulation unit both installed on site

FR3078360A1|2019-08-30|CONDUIT FOR FORMED FLUID OF REVERSIBLE JUNCTION MODULES

FR2908839A1|2008-05-23|Energy producing unit, has rod provided with parasol shaped float at its lower part, where upper part of rod is ringed and comprises transversal waviness that are in form of ring and acts on links of compressors or pumps

EP3423346A1|2019-01-09|Stabilisation system, in particular for a floating support, comprising multiple u-shaped damping devices

同族专利:

公开号 | 公开日

WO2015118128A1|2015-08-13|

AU2015214113A1|2016-08-25|

FR3017179B1|2016-02-26|

JP2017512293A|2017-05-18|

US20170009750A1|2017-01-12|

KR20160119097A|2016-10-12|

AU2015214113B2|2018-03-01|

引用文献:

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

US3162214A|1963-01-16|1964-12-22|American Optical Corp|Flexible tubular structures|

GB2015689A|1978-03-03|1979-09-12|Tecnomare Spa|Flexible conduits|

DE4009339A1|1989-04-06|1990-10-11|Karl Marx Stadt Tech Textil|Flexible vacuum air guide - has outer tubular sleeve stabilising by network frame with rhomboid mesh rigid steel rings|

WO2008109187A2|2007-03-02|2008-09-12|Laura Jane Bailey|A mechanically produced thermocline based ocean temperature regulatory system|

US20100129160A1|2008-11-21|2010-05-27|Lockheed Martin Corporation|Tendon-Supported Membrane Pipe|

EP2585677A2|2010-06-23|2013-05-01|Jean-Paul Gateff|Apparatus for collecting and transporting fluids in a body of water|

FR2978979A1|2011-08-11|2013-02-15|Dcns|Modular and autonomous section for water pipe in closed cycle ocean thermal energy conversion system, has flexible membrane fixed to rigid rings, where elongated rods are connected to rigid rings and secured to flexible membrane|FR3068759A1|2017-07-06|2019-01-11|Dcns Energies|CLEAN DRIVE TO BE MOVED BY A FLUID|

FR3070467A1|2017-08-29|2019-03-01|Ets A. Deschamps Et Fils|UNIT FOR TRANSPORTING A FLUID, ESPECIALLY UNDER WATER, COMPRISING A SEALED FLEXIBLE DRIVE AND AT LEAST ONE TWO-STATE RIGIDIFICATION ELEMENT|

WO2019129805A1|2017-12-29|2019-07-04|Naval Energies|Liquid duct|

WO2019129804A1|2017-12-29|2019-07-04|Naval Energies|Fluid circulation pipe|

WO2019162517A1|2018-02-26|2019-08-29|Naval Energies|Pipe for fluid formed from reversible junction modules|US3006662A|1958-03-21|1961-10-31|Onoda Cement Co Ltd|Flexible connecting tube for conveyance|

US3406723A|1966-03-16|1968-10-22|United Aircraft Corp|Universal flexible suit joint|

US3548605A|1969-05-07|1970-12-22|Texaco Development Corp|Submergible vehicle for emergency offshore gas leakage|

US4212329A|1978-08-14|1980-07-15|Deep Oil Technology, Inc.|Pipe construction and method of making same|

FR2448650B1|1979-02-12|1986-01-31|Anvar|FLEXIBLE DEVICE FOR SUCTION OF LARGE FLOW FLUID, ESPECIALLY FOR PUMPING SEA WATER IN DEPTH|

US4497342A|1983-06-20|1985-02-05|Lockheed Missiles & Space Company, Inc.|Flexible retractable cold water pipe for an ocean thermal energy conversion system|

US4830059A|1984-08-01|1989-05-16|Silberstang A Barry|Relatively articulatable hose|

ES2222094B1|2003-07-02|2005-12-16|Jorge Perez Barril|SYSTEM FOR EXTRACTION AND COLLECTION OF FLUIDS IN SHIPS.|

DE102007009906A1|2007-02-28|2008-09-04|Veritas Ag|Charge air hose|

CA2795842C|2010-04-09|2019-05-28|Peter Andrew John May|A hose shroud|

US9051704B2|2010-06-23|2015-06-09|Jean-Paul Gateff|Cold water piping system including an articulating interface, modular elements, and strainer assembly|

DE102010049224B4|2010-10-08|2012-05-31|Mike Kersten|Device for collecting and discharging liquids and / or gases leaving a watercourse|

US8444182B2|2010-11-04|2013-05-21|Sea Energy Technology Co, Ltd.|Water intake pipe of ocean thermal energy conversion power plant|

WO2012095833A1|2011-01-14|2012-07-19|Michael Lawson|A sleeve for collecting contaminants|

US8936046B2|2012-11-09|2015-01-20|Ragner Technology Corporation|Elastic and spring biased retractable hoses|

US10359131B2|2012-12-01|2019-07-23|Ragner Technology Corporation|Collapsible hoses and pressure systems|

法律状态:
2015-02-19| PLFP| Fee payment|Year of fee payment: 2 |

2016-02-18| PLFP| Fee payment|Year of fee payment: 3 |

2017-02-08| PLFP| Fee payment|Year of fee payment: 4 |

2018-01-29| PLFP| Fee payment|Year of fee payment: 5 |

2020-01-13| PLFP| Fee payment|Year of fee payment: 7 |

2021-01-22| PLFP| Fee payment|Year of fee payment: 8 |

2022-01-12| PLFP| Fee payment|Year of fee payment: 9 |

优先权:

申请号 | 申请日 | 专利标题

FR1400341A|FR3017179B1|2014-02-06|2014-02-06|MODULAR TRUNK FOR A WATER PIPE, WATER CONDUIT COMPRISING SUCH STRINGS AND THERMAL ENERGY SYSTEM OF THE SEAS COMPRISING SUCH A WATER CONDUIT|FR1400341A| FR3017179B1|2014-02-06|2014-02-06|MODULAR TRUNK FOR A WATER PIPE, WATER CONDUIT COMPRISING SUCH STRINGS AND THERMAL ENERGY SYSTEM OF THE SEAS COMPRISING SUCH A WATER CONDUIT|

JP2016550490A| JP2017512293A|2014-02-06|2015-02-06|Modular sections comprising water pipes, water pipes with such sections and marine thermal energy systems with such water pipes|

KR1020167021545A| KR20160119097A|2014-02-06|2015-02-06|Modular section of water pipe, water pipe including such sections, and ocean thermal energy system including such a water pipe|

US15/116,295| US20170009750A1|2014-02-06|2015-02-06|Modular section of water pipe, water pipe including such sections, and ocean thermal energy system including such a water pipe|

AU2015214113A| AU2015214113B2|2014-02-06|2015-02-06|Modular section of water pipe, water pipe including such sections, and ocean thermal energy system including such a water pipe|

PCT/EP2015/052554| WO2015118128A1|2014-02-06|2015-02-06|Modular section of water pipe, water pipe including such sections, and ocean thermal energy system including such a water pipe|

[返回顶部]