Classifications

• • E—FIXED CONSTRUCTIONS
  • E21—EARTH OR ROCK DRILLING; MINING
  • E21B—EARTH OR ROCK DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
  • E21B17/00—Drilling rods or pipes; Flexible drill strings; Kellies; Drill collars; Sucker rods; Cables; Casings; Tubings
  • E21B17/20—Flexible or articulated drilling pipes, e.g. flexible or articulated rods, pipes or cables
  • E21B17/203—Flexible or articulated drilling pipes, e.g. flexible or articulated rods, pipes or cables with plural fluid passages
• • E—FIXED CONSTRUCTIONS
  • E02—HYDRAULIC ENGINEERING; FOUNDATIONS; SOIL SHIFTING
  • E02F—DREDGING; SOIL-SHIFTING
  • E02F3/00—Dredgers; Soil-shifting machines
  • E02F3/04—Dredgers; Soil-shifting machines mechanically-driven
  • E02F3/88—Dredgers; Soil-shifting machines mechanically-driven with arrangements acting by a sucking or forcing effect, e.g. suction dredgers
  • E02F3/8833—Floating installations
  • E02F3/885—Floating installations self propelled, e.g. ship
• • E—FIXED CONSTRUCTIONS
  • E02—HYDRAULIC ENGINEERING; FOUNDATIONS; SOIL SHIFTING
  • E02F—DREDGING; SOIL-SHIFTING
  • E02F3/00—Dredgers; Soil-shifting machines
  • E02F3/04—Dredgers; Soil-shifting machines mechanically-driven
  • E02F3/88—Dredgers; Soil-shifting machines mechanically-driven with arrangements acting by a sucking or forcing effect, e.g. suction dredgers
  • E02F3/90—Component parts, e.g. arrangement or adaptation of pumps
  • E02F3/92—Digging elements, e.g. suction heads
  • E02F3/9243—Passive suction heads with no mechanical cutting means
• • E—FIXED CONSTRUCTIONS
  • E02—HYDRAULIC ENGINEERING; FOUNDATIONS; SOIL SHIFTING
  • E02F—DREDGING; SOIL-SHIFTING
  • E02F7/00—Equipment for conveying or separating excavated material
  • E02F7/005—Equipment for conveying or separating excavated material conveying material from the underwater bottom
• • E—FIXED CONSTRUCTIONS
  • E02—HYDRAULIC ENGINEERING; FOUNDATIONS; SOIL SHIFTING
  • E02F—DREDGING; SOIL-SHIFTING
  • E02F7/00—Equipment for conveying or separating excavated material
  • E02F7/10—Pipelines for conveying excavated materials
• • E—FIXED CONSTRUCTIONS
  • E21—EARTH OR ROCK DRILLING; MINING
  • E21B—EARTH OR ROCK DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
  • E21B19/00—Handling rods, casings, tubes or the like outside the borehole, e.g. in the derrick; Apparatus for feeding the rods or cables
  • E21B19/22—Handling reeled pipe or rod units, e.g. flexible drilling pipes
• • E—FIXED CONSTRUCTIONS
  • E21—EARTH OR ROCK DRILLING; MINING
  • E21C—MINING OR QUARRYING
  • E21C50/00—Obtaining minerals from underwater, not otherwise provided for

Definitions

• the present invention relates to a device for extracting a material situated at the bottom of a body of water, of the type comprising: a surface installation intended to extend at least partially above the surface of the body of water ;
• a bottom assembly comprising means for sampling the material on the bottom of the body of water
• a material transport pipe connecting a first point located on the surface installation to a second point located on the bottom assembly, the transport pipe delimiting at least one circulation passage of the material;
• the functional line being capable of transmitting electrical or hydraulic power, information or a fluid between the installation surface and the bottom assembly, the surface installation comprising at least one winding drum of the or each functional line.
• This system applies, for example, to the mining of submarine bottoms, or the earthworks of submarine soils for the setting up of hydrocarbon production facilities.
• FR-A-2 467 283 discloses a device of the aforementioned type.
• This device comprises a surface installation carried by a ship, and a bottom assembly.
• This set includes a base station and an extraction vehicle traveling on the seabed and connected to the base station by a flexible link designated by the English term "jumper".
• the bottom assembly is lowered into the water using a string of rigid rods that connects the base station to the surface installation.
• the drill string internally delimits a circulation passage of material taken from the bottom, to convey it to the surface.
• a gas injection line in the drill string and electric power transfer lines forming a link termed "umbilical” have descended into the sea to the intermediate station from the ship.
• An example of an umbilical is described in GB 2 395 539. To deploy the device, it is necessary to successively mount each stem of the drill string on the surface ship during the descent of the bottom assembly, then to simultaneously lower the gas injection line and the umbilical including the power lines, assembling them on each rod.
• the ship must have a very large storage space for the assembly and storage of rigid tubes and the umbilical.
• An object of the invention is to obtain a device for extracting a material located at the bottom of a body of water that is simple to implement and not very bulky.
• the invention relates to a device of the aforementioned type, characterized in that the transport pipe is flexible over substantially its entire length, the or each functional line being arranged around the transport pipe to form a flexible conduit the conveying conduit and the or each functional line being jointly deployable between a rest configuration wound on the winding drum and a deployed configuration towards the bottom of the water body.
• the device according to the invention may comprise one or more of the following characteristics, taken in isolation or according to any technically possible combination (s):
• the flexible duct comprises an annular ply surrounding the transport duct, the ply delimiting longitudinal passages for receiving the or each functional line in which the or each functional line is inserted;
• the surface installation comprises a ship, the drum being rotatably mounted on a platform of the ship;
• the ship delimits a lateral edge, the flexible duct being deployed transversely towards the outside of the ship facing the lateral edge;
• the flexible duct comprises a plurality of sections assembled end to end;
• each section comprises a tubular part and, at each end of the tubular part, a connection flange to an adjacent section of transverse dimension greater than that of the central part, and the drum delimits:
• At least one groove for receiving the connecting flanges of at least two adjacent sections, movable around the bearing surface, said flanges being inserted into the groove when the flexible duct occupies its wound configuration;
• the bottom assembly comprises a base, and an extractor vehicle connected to the base by a flexible link delimiting a material transport light, the opening opening in the flow passage and facing the sampling means;
• the surface installation comprises a gas / liquid / solid separator delimiting a separation chamber connected to the circulation passage;
• the separation chamber comprises:
• the flexible duct comprises at least one gas injection line of the material, the gas injection line opening into the circulation passage away from the surface installation, the surface installation comprising a compressor having an input connected to the separator and an output connected to the gas injection line; in the deployed configuration, the flexible duct comprises at least one unit for injecting liquid under pressure into the circulation passage, the pressurized liquid being able to drive the material towards the surface installation;
• the winding drum defines an interior volume, the separation chamber being disposed at least partially in the interior volume; the bottom assembly comprises an extractor vehicle provided with sampling means; and
• the bottom assembly comprises a material collection support, connected to the flexible conduit, the collection support being intended to be placed on the bottom for collecting the material taken by the sampling means, the sampling means being deployable from the surface installation independently of the collection medium.
• the invention furthermore relates to a process for extracting a material situated at the bottom of a body of water, using a device as defined above, the process being of the type comprising the following steps:
• FIG. 1 is a schematic side view and in partial perspective a first extraction device according to the invention, with its flexible conduit deployed;
• FIG. 2 is a schematic partial sectional view of a marked detail II of Figure 1;
• - Figure 3 is a partially exploded perspective view of the flexible conduit of the first device according to the invention;
• FIG. 4 is a partial diagrammatic perspective view of three-quarter faces of the winding drum of the flexible pipe of FIG. 1, the flexible pipe being partially wound around the drum;
• - Figure 5 is a view similar to Figure 4 of the drum without the conduit;
• FIG. 6 is an end view taken along the arrow V1 of Figure 4.
• FIG. 7 is a view taken in partial section along the longitudinal vertical plane VII of FIG. 4;
• - Figure 8 is a view similar to Figure 2 of a second device according to the invention comprising a pumping unit by water injection;
• FIG. 9 is a view similar to FIG. 8 of a third device according to the invention.
• - Figure 10 is a cross-sectional view along the X-X plane of Figure 9;
• FIG. 11 is a view similar to Figure 1 of a fourth device according to the invention.
• FIG. 1 to 10 An extraction device 10 according to the invention is shown in Figures 1 to 10.
• This device 10 is intended to collect materials located at the bottom of a body of water 12 such as a sea, an ocean or a lake.
• the body of water 12 rests on a bottom 14 delimited by solid material comprising rocks and / or sediments.
• the purpose of the device 10 is to carry out, for example, earthworks on the bottom 14 with a view to setting up a hydrocarbon exploitation facility, or to withdraw ores deposited on the bottom 14 in order to from their subsequent exploitation on the surface 16 of the body of water 12.
• the device 10 comprises a surface installation 18 carried by a ship 20, a bottom assembly 22 for taking the material on the bottom 14 of the body of water 12, and, according to the invention, a flexible duct 24 of the "integrated production beam” type, or "Integrated Production
• the bottom assembly 22 comprises a base station 26 attached to the lower end of the conduit 24, an excavating vehicle 28, placed in contact with the bottom 14 of the water body 12, and a flexible link 30 connecting the vehicle 28 at base station 26.
• the base station 26 is intended to be placed in the vicinity of the bottom 14, away from it during the exploitation of materials.
• the base station 26 comprises equipment (not shown) for pumping and treating the sampled material, such as, for example, pumps or filters, and control means for the excavating vehicle 28.
• the excavating vehicle 28 is intended to come into contact with the bottom 14 to collect material on the bottom 14. It comprises the means 32 for moving the on the bottom 14 and means 34 for sampling the material, able to dig, scrape or drill the material constituting the bottom 14 and transport it to the flexible link 30.
• the bottom of the base station 26 is provided with a flap (26A ( Figure 1) which is pivotal by appropriate means, not shown.
• This flap 26A makes it possible, in its open position, to evacuate the materials blocked in the station. In this case, the excavating vehicle 28 is placed below the base station 26 and these materials fall into the vehicle 26 where they are ground.
• the flexible link 30 is sometimes referred to as the "jumper". It is formed of a hollow and flexible pipe having an upper end connected to the base station 26 and a lower end connected to the vehicle 28, to take the material from the sampling means 34.
• the flexible pipe 36 internally delimits a light 37 of material flow opening opposite the sampling means 34 and in the base station 26.
• the flexibility of the flexible link 30 is greater than that of the flexible conduit 24.
• the vehicle 28 is mobile with respect to the base station 26, in particular on the bottom 14, up to a maximum distance from the base station 26 substantially. equal to the length of the flexible hose 36. This maximum distance is between 10 m and 40 m and preferably less than 50 m.
• the flexible duct 24 extends between a first point 38 located at its upper end on the surface installation 18, and a second point 40 located at its lower end on the base station 26.
• the duct 24 is flexible over its entire length, taken between the points 38, 40.
• the duct 24 is adapted to be wound on a rotating drum between an unwrapped configuration and a helically wound configuration in which it occupies a radius of curvature of between 12 m and 15 m and preferably less than 20 m.
• the flexible duct 24 comprises a central pipe 42 for transporting the material taken from the bottom 14, from the base station 26 to the surface installation 18.
• the duct 24 further comprises, around the duct 42, an outer functional sheet 43 receiving functional lines 44 able to transmit electrical or hydraulic power, information and / or fluids from the surface installation 18 to the bottom assembly 22, the lines 44 being arranged in the outer ply 43 around the transport pipe 42.
• the duct 24 also comprises a line 46 for injecting gas for driving the material in the transport pipe 42, disposed in the web 43 and an outer protection sheath 47 disposed around the web 43.
• the transport pipe 42 is generally in accordance with the API standard.
• 17J It is flexible throughout its length. It comprises, for example, from the inside to the outside, an internal tubular metal casing 47A for the resistance to pressure, a gas-tight plastic sheath 47B, an outer casing 47C and two layers of armor wires 47D to ensure tensile strength.
• the conveying line 42 delimits internally a passage 48 for circulation of sampled material which opens on the one hand, at the first point 38, and on the other hand, at the second point 40.
• the transport pipe 42 is connected in series with the tube flexible 36, so that the inner lumen 37 opens into the passage 48.
• the sheet 43 is of generally annular shape. It is arranged externally around the transport pipe 42 and internally delimits longitudinal passages 48A for receiving lines 44, 46 in which lines 44, 46 are inserted.
• the functional lines 44 comprise, for example, a connecting electric power transfer line. electrically supplying the base station 26 and the vehicle 28.
• the lines 44 further comprise an information transport line connecting the surface installation 18 to the means of transporting the base station 26 and the vehicle 28. control on the base station 26 for controlling the vehicle 28.
• the length of the flexible duct 24, taken between the first point 38 and the second point 40, is variable depending on the depth at which the seabed is located and preferably greater than 1000 m.
• the flexible duct 24 is formed by the end-to-end assembly of a plurality of flexible unitary sections 50 of length preferably between 300 m and 400 m.
• Each section 50 thus comprises a tubular central portion 52 and at each end a fastening flange 54 to an adjacent section 50.
• the flanges 54A, 54B of two adjacent sections 50 are fixed against each other for example by screwing.
• the flanges 54A, 54B protrude radially outwardly relative to the central portion 52. They have an outside diameter greater than the average outside diameter of the central portion 52.
• Each unit section 50 delimits a portion of the inner passage 48 and carries a unitary section of the lines 44 and 46 which are interconnected through the attachment flanges 54A, 54B.
• the ship 20 delimits a platform 60 supporting the surface installation 18 extending between two side edges 62 of the ship.
• the ship 20 further comprises a work station 63 provided with a clamp 64 for selectively retaining the conduit 24 which protrudes from a lateral edge 62.
• the conduit 24 is engaged vertically through the clamp 64 above and below. With regard to a lateral edge 62.
• the surface installation 18 comprises a winding drum 68 of the flexible duct 24, means 70 for rotating the drum 68, a separator 72 for processing the sampled material disposed in the drum 68, and a compressor 74 for injecting gas into the inner passage 48 through the gas injection line 46.
• the work station 63 moves on a rail 64A disposed on a side of the ship 20.
• the surface installation 18 further comprises control means 76 and electrical supply means 78.
• the winding drum 68 extends along a substantially horizontal longitudinal axis XX 'of the ship 20.
• the drum 68 comprises a hollow cylinder 80, which has at its left and right ends transverse locking flanges 82 of the flexible duct 24.
• the cylinder 80 delimits an outer cylindrical surface 84 intended to support the wound conduit 24, and a cylindrical internal volume 86 into which the separator 72 is inserted.
• the drum 68 also has, on at least one circumference taken along the outer surface 84, two support wedges 88 for supporting two adjacent sections 50 of the duct.
• the shims 88 protrude from the outer surface 84 and delimit between them a longitudinal groove 90 for receiving the flanges 54 for fixing two adjacent sections 50.
• the shims 88 are movable jointly about the X-X 'axis on at least one periphery of the surface 84.
• drum 68 could be used to wind any flexible conduit.
• the diameter of the drum 68 is between 12 m and 15 m and in any case less than 20 m.
• the drum 68 is further provided, in the inner volume 86, rollers 92 which are located in the vicinity of the end flanges 82 and which are distributed around the axis X-X '.
• the rollers 92 are placed in abutment on an outer surface of the separator, to allow, as will be seen below, the rotation of the drum 68 about the axis X-X 'by rolling on the separator 72.
• the means 70 for rotating the drum comprise, at each end of the rotary cylinder 80, a toothed outer ring 94 and two motorized drive wheels 96 meshing with the ring gear 94.
• Each ring 94 extends from the outer surface 84 on a periphery about the X-X 'axis. It is integral with the cylinder 80.
• the wheels 96 are rotatably mounted on the platform 60 on either side of a vertical plane passing through the axis XX 'of rotation of the cylinder.
• the drive wheels are adapted to rotate the drum 68 about the axis XX 'in two distinct directions of rotation to wind or unwind the flexible conduit 24.
• the separator 72 comprises a cylindrical tank 100 disposed in the internal volume 86, a tank 102 for retaining the separated material in the cylindrical tank 100, means 104 for discharging the separated material into the tank towards the retention tank 102, and means 106 for pressurizing the tank 100.
• the tank 100 of the separator 72 can be placed in the interior volume delimited by any winding drum present on the vessel 20.
• the vessel 100 is generally cylindrical in shape and of slightly smaller diameter than the cylinder 80 in which it is placed. It has a cylindrical peripheral wall 108 closed transversely with respect to the axis X-X 'by first and second end walls 110, 112.
• the walls 108, 110, 112 internally delimit a cavity 114 for separating the material brought up to the surface by the flexible conduit 24.
• the tank 100 is fixedly mounted on the platform 60 by means of fixing arms 116. Each arm 116 is attached to an end wall 110, 112 and on the platform 60.
• the peripheral wall 108 is cylindrical in shape of axis X-X '.
• the rollers 92 of the drum 68 roll on an outer surface of this wall 108 during the rotation of the drum 68 about its axis X-X '.
• the left end wall 110 has three nozzles 118 for connection to the flexible conduit 24 distributed around the axis X-X '.
• Each nozzle 118 comprises a head 120 for connection to a flange 54 of an end section of the flexible duct 24.
• Each nozzle 118 further comprises an injection member 122 of the material coming from the duct 24 inside the chamber 114 of separation.
• the injection member 122 is helically curved toward the wall 108 to tangentially direct the flow of material from the nozzle 118 onto the peripheral wall 108 of the nozzle. the tank 100. This avoids the deterioration of the equipment present in the separation chamber 114.
• the left wall 110 comprises three connection nozzles 118, which makes it possible to adapt to different positions of the end section 50 of the duct 24 when it is wound on the drum 68.
• the left wall 110 further comprises an upper outlet 123 of gas discharge connected to the compressor 74.
• the compressor 74 is thus connected at the inlet, at the gas evacuation outlet 123 and at the outlet, to the injection line. gas in the inner passage 48, as shown in Figure 2.
• the right end wall 112 comprises, in its upper part, a pressurized fluid injection inlet 124, and in its lower part, an outlet 126 for discharging a separated material into the separator, connected to the retention tank 102 through an intermediate conduit 128.
• the retention tank 102 is disposed on the platform 60. It is intended to be maintained at atmospheric pressure for the recovery of solid materials from the separator 72.
• the evacuation means 104 comprise a worm 130 disposed in the separation chamber 114, and a controllable pressurization valve 132 disposed on the intermediate duct 128, between the chamber 114 and the retention tank 102.
• the worm 130 is placed in a lower part of the chamber 114 near its bottom. It extends parallel to the axis XX 'and has an end facing the discharge outlet 126.
• the worm 130 is motorized to allow the conveying of a solid material and / or liquid to the intermediate conduit 128 when the valve 132 is open.
• a guide plate 130A is placed above the worm 130 to channel the sediments to the intermediate conduit 128.
• the valve 132 is controllable to be open when the material is discharged out of the chamber 114 and closed to maintain the chamber 114 under pressure during the separation of the material from the pipe 42, as will be seen below.
• the pressurizing means 106 comprise a compressed water source 134 connected to the inlet 124.
• the flexible duct 24 is assembled by end-to-end assembly of the different unit sections 50 by means of their fixing flanges 54.
• This assembly can be performed on the ground, or directly on the ship 20.
• the lines 44, 46 are assembled by end-to-end connection of the line sections present on a unit section 50.
• the interior passage 48 is continuous between the first point 38 and the second point 40.
• the motorized wheels 96 are activated to wind the duct 24 helically around the outer surface 84 over substantially its entire length.
• the conduit 24 is thus stored in a simple and space-saving manner on the ship 20. It is furthermore ready to be deployed rapidly and at a lower cost when a material exploitation operation is to be carried out.
• the surface installation 18 on the ship 20 is placed in relation to the bottom region on which material is to be taken.
• the bottom assembly 22 is extracted from the holds of the vessel 20 and the lower end of the flexible conduit 24 is connected to the base station 26.
• the conduit 24 is engaged through the selective clamp 64 on the edge 62 of the vessel. Then, the bottom assembly 22 is immersed under water by being retained at the lower end 40 of the conduit 24 and by an auxiliary winch 140 mounted on the platform 60. The assembly 22 is lowered to the bottom 14 by release of the clamp 64 and progressive unwinding of the conduit 24 out of the drum 68, and the winch 140. If necessary, the course of the conduit 24 is stopped and the conduit 24 is held in position by clamping the retaining clip 64.
• the base station 26 When the excavating vehicle 28 touches the bottom 14, the base station 26 is kept away from the bottom 14. The flexible conduit 24 is then stretched substantially linearly between the retaining clip 64 and the base station 26.
• the upper end of the duct 24 is fixed on a connection nozzle 118.
• the lumen 37 inside the flexible pipe is connected to the internal passage 48, which opens into the separation chamber 114 of the separator 72.
• the conduit 24 is deployed over the side edge 62 of the vessel 20 outwardly overlapping this edge 62. It is therefore not necessary to have a vessel 20 comprising a central well for deploying the device. extraction 10.
• the functional lines 44 are connected to the control means 76 and the power supply means 78 on the surface installation 18 and to the base station 26 and the vehicle 28.
• the vehicle 28 and the base station 26 are electrically powered from the surface installation 18 through the lines 44 to propel the vehicle 28 and activate the pickup means 34.
• the movement of the vehicle 28 and the start of the sampling means 34 by the control means 76 are controlled from the surface installation 18 through the lines 44.
• the inlet of the compressor 74 is connected to the gas discharge outlet of the tank 100 and the outlet of the compressor 74 is connected to the gas injection line 46.
• control means 76 send an activation signal to the base station 26 and the vehicle 28 to electrically power the sampling means 34 and control the movement of the vehicle 28 on the bottom 14.
• the sampling means 34 take the material located on the bottom and bring it to the entrance of the light 37.
• the pumping means present on the base station 26 initiate the ascent of the material to the installation 18 consisting of a liquid / solid mixture.
• the compressor 74 is started.
• the compressor 74 then injects gas into the passage 48, for example compressed air at about 100 bar, into an injection point 142 situated between the first point 38 and the second point 40.
• This injection point 142 is for example located at a depth of about
• a continuous flow of sampled material is then established between the sampling means 34 and the separation chamber 114 through successively the light
• the mixture collected at the nozzle 118 consists of liquid, solid and gas flowing at a suitable speed preferably between 15 and 20 m per second.
• the outlet valve 132 of the separator 72 is kept closed, so that the pressure in the separation chamber 114 is greater than the atmospheric pressure.
• This pressure is for example between 15 and 30 bar.
• the liquid / solid / gas mixture then enters the chamber 114 where it undergoes separation by gravity.
• the gas collected in the upper part of the chamber 114 is reinjected into the compressor 74 through the outlet 123, which limits the pressure drop and the size of the compressor 74.
• the solid material accumulates in the bottom of the chamber 114 around the worm 130.
• the valve 132 is opened and the worm 130 is activated to evacuate the solid material and a part of the liquid, through the intermediate pipe 128 to the retention tank 102.
• pressurized water is injected through the inlet 124.
• the bottom assembly 22 is mounted to the surface by winding the conduit 24 around the drum 68 as previously described.
• the flexible conduit 24 does not have an electric power transfer line.
• An umbilical with power lines that is lowered simultaneously during the descent of the flexible conduit 24 to provide power to the excavating vehicle 28.
• the separation chamber is not maintained under pressure when unloading the material therein.
• the size of the compressor 74 is greater and the injection point is lower than in the first device 10 according to the invention.
• the bottom assembly does not have a base station 26.
• the flexible link 30 is connected directly to the flexible conduit 24 via an adapter nozzle.
• a second device 210 according to the invention is partially shown in FIG. 8. Unlike the first device 10, the second device 210 comprises, in the deployed configuration of the flexible conduit 24, a plurality of injection units 212. a pressurized liquid in the circulation passage 48, for conveying the material to the surface installation 18.
• Each injection unit 212 is for example mounted between two fixing flanges 54A, 54B of two adjacent sections 50 during the deployment of the flexible duct 24 out of the drum 68.
• the units 212 are for example mounted by operators placed on the mounting station 63 and these units 212 are held on the flanges 54A, 54B by respective fixing clamps 213.
• Each pumping unit 212 thus comprises a sleeve 214 internally defining a portion of the flow passage 48, a nozzle 216 for taking water from the body of water 12, and a distribution in the passage 48, and a hydraulic turbine 218 for pumping and pressurizing the injected water.
• the nozzle 216 defines a generally transverse lumen 230 which opens outwardly into the body of water 12 through a strainer 222, and inclined axially upwards in the passage 48.
• the hydraulic turbine 218 is fixed on the sleeve 214.
• the turbine 218 is fed hydraulically through a tapping 224 on a functional line 44A coming from the installation 18.
• the tapping 224 opens into the water body 12 by an evacuation 226 after passing through the turbine 218, without being connected to a lower part of the line 44A located in the section 50 under the sleeve 214.
• the sleeve 214 further delimits at least one section 228 of another functional line 44B intended to feed another pumping unit located under the unit 212.
• the turbine 218 is supplied with hydraulic fluid from the surface installation 18 via the line 44A and the tapping 224.
• the feed of the turbine 118 causes water to be drawn into the lumen 230 through the strainer 222, then the pressurization of the water sucked into the light 230.
• the pressurized water thus obtained is injected into the passage 48 to drive the material flowing in this passage 48 to the surface installation 18.
• the presence of units injection nozzle 212 distributed along the flexible conduit 24 allows to remove the pump on the base station 26 and the injection of transport gas in the passage 48. This particularly simplifies the installation of surface 18 which is free of compressor.
• the turbines 218 are powered electrically by a functional line placed in the flexible conduit or by an outer umbilical.
• the third device 250 shown in Figures 9 and 10 differs from the second device 210 in that the injection units 212 are devoid of hydraulic turbines.
• the pressurized liquid to be injected into the circulation passage 48 is stored in a pressurized reservoir disposed on the vessel 20 in the surface plant 18.
• Each unit 212 comprises an annular distributor 252 of liquid under pressure disposed around the sleeve 214.
• the annular distributor 252 delimits a peripheral cavity 254, of toric shape around the axis of the duct 24.
• the cavity 254 is connected to the surface pressure liquid reservoir via the functional line 44A. It is connected to the passage 48 by four radial injection orifices 256 distributed angularly around the axis of the duct 24, as illustrated by FIG. 10.
• Each injection orifice 256 opens axially upwards into the passage 48.
• the pressurized water is fed into the cavity 254 of the distributor 252 from the reservoir of the surface installation 18, through the functional line 44A. . It is distributed uniformly in the cavity 254 to be injected through each orifice 256. More generally, such pumping units could be used on a flexible conduit of any installation.
• sampling means 34 comprise an excavation crane 312, deployable and operable from the surface installation 18 independently of the flexible conduit 24.
• the bottom assembly 22 further comprises means 314 for receiving and treating the material, placed on the bottom 14 of the body of water 16 while being connected to the flexible conduit 24.
• the crane 312 comprises a gripper 316 for sampling material on the bottom 14, and a cable 318 for deploying the clamp 316, to descend the clamp 316 from the vessel 20 to the bottom 14.
• the receiving means 314 comprise an adjustable support support 320 placed on the bottom 14 and a crusher / crusher 322 mounted in the support 320.
• the support 320 defines a funnel 324 for receiving the material taken by the clamp 316 open upwards. and opening towards the mill / crusher 322.
• the support 320 is deployable from the surface installation 18 to the bottom 14, by deployment means (not shown) independent of the crane 312.
• the support 320 has adjustable feet to maintain it substantially horizontally and fix on the bottom 14.
• the support 320 and the crusher / crusher 322 are connected to a free end of the flexible link 30, to connect the hose 36 to the crusher / crusher 322.
• the receiving means 314 and the flexible conduit 24 are lowered towards the bottom 14, until the support 320 is placed on the bottom 14 while being immobilized on the bottom 14.
• the crane 312 is then manceuvrée to bring the gripper 316 in contact with the bottom 14.
• the gripper 316 is then activated to take material on the bottom 14, then is moved next to the funnel 324 to deposit the material taken by the clamp 316 in the crusher / crusher 322.
• the material processed in the crusher / crusher 322 is then reassembled at the surface installation 18 through the hose 36 and the flexible conduit 24, as previously described.

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• Engineering & Computer Science (AREA)
• Mining & Mineral Resources (AREA)
• Mechanical Engineering (AREA)
• Life Sciences & Earth Sciences (AREA)
• Geology (AREA)
• Structural Engineering (AREA)
• General Engineering & Computer Science (AREA)
• Civil Engineering (AREA)
• General Life Sciences & Earth Sciences (AREA)
• Geochemistry & Mineralogy (AREA)
• Fluid Mechanics (AREA)
• Environmental & Geological Engineering (AREA)
• Physics & Mathematics (AREA)
• Ocean & Marine Engineering (AREA)
• Sampling And Sample Adjustment (AREA)
• Drilling And Exploitation, And Mining Machines And Methods (AREA)
• Separation Of Solids By Using Liquids Or Pneumatic Power (AREA)
• Other Liquid Machine Or Engine Such As Wave Power Use (AREA)
• Laying Of Electric Cables Or Lines Outside (AREA)

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• 2007
  • 2007-07-18 FR FR0756579A patent/FR2919015B1/fr active Active
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• 2008
  • 2008-07-17 BR BRPI0814574-1A patent/BRPI0814574B1/pt active IP Right Grant
  • 2008-07-17 WO PCT/FR2008/051346 patent/WO2009013434A2/fr active Application Filing
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  • 2008-07-17 EP EP08826537.6A patent/EP2171163B1/de active Active
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