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    • 专利摘要:
    SYSTEM FOR DISPLACEMENT OF ITEMS ON A PLATFORM FLOOR, METHOD FOR SETTING ITEMS ON A PLATFORM FLOOR, PLATFORM FLOOR, PLATFORM FLOOR CART, AND DRILLING PLATFORM, comprises a system for moving items on a platform floor ( 2), said system comprising a plurality of trolleys and a network of tracks (10) for guiding the plurality of trolleys, each trolley of said plurality of trolleys for supporting an item, and each trolley including snap-together rail-locking members. at least one track of said track network (10); the platform floor (2) may be part of a drilling platform, such as a drillship (1) used in the construction of oil and natural gas wells.
    公开号:BR112017008886B1
    申请号:R112017008886-0
    申请日:2015-09-22
    公开日:2022-02-01
    发明作者:Erik Haavind
    申请人:National Oilwell Varco Norway As;
    IPC主号:
    专利说明:

    [0001] The present patent application relates to a rig floor for a drilling rig, a system for moving items over a rig floor, a method for configuring items on a rig floor a drilling rig, to trolleys for use on a rig floor and to a driller room.
    [0002] When drilling a well, a bit is positioned in a bottom composition at the lower end of a drill string. The bit is rotated to drill a well in a formation. The formation may be below water level or on dry land. An upper end of the drill string passes through an opening in a rig floor of a drilling rig. The opening is known as the center of the well. The drill string is built on a drilling rig and lowered into the hole using a steel cable inserted and removed by a winch, known as a drill winch. The wire rope passes through the drill winch, over a capping block fixed to the top of a tower, and goes down to a catarina that moves up and down inside the drill tower to raise or lower parts. of the drill pipe and/or the entire drill string.
    [0003] The bit is, at least initially, rotated by rotating the drill string. The drill string can be rotated by a turntable positioned in the center of the well on the drill floor. In this case, a swivel is coupled to the catarina, which has a coupled elevator in which the drill string is kept fixed for up and down displacement. Alternatively or additionally, the drill string can be rotated by a top drive for upward and downward movement within the drill rig. The catarina is connected to the top drive to raise and lower the top drive along the track. A top drive lift is suspended from the top drive via handles. The drill string is prevented from falling into the well by wedges positioned in a spider on the rig floor. As the well is drilled, drill pipe sections are added to the drillstring to allow the bit to drill deeper into the formation. The drill pipe sections are usually added in two-part or, more often, three-part frames. The drill pipe frames are mounted off-center of the well in a temporary pipe holder called a mouse hole. The frames are assembled using an automatic broach or a separate threader to fit threaded stud ends of an upper drill pipe section into corresponding threaded housings of a lower drill pipe section to make a connection; and a floating wrench to torque the connection. A pipe handling apparatus transports sections of pipe from a rack, warehouse, or pipe conveyor belt into alignment with the mouse hole. Another pipe handling device transports the drill pipe frame to another pipe holder or directly to the center of the well for connection to the drill string. Alternatively, the drill pipe frame is transported to the center of the well on a conveyor belt and the elevator or top drive elevator is used to lift the upper end of the drill pipe frame, over which the lower end swings to the bottom. alignment with the center of the well. A drill pipe tail operator is used to control the bottom free end of the drill pipe and align it with the center of the well. Then the drill pipe frame is connected to the drill pipe string suspended in the hole. The connection is made using an automatic racking machine or a separate tongue threader. The automatic shipyard can be supported on an arm, swiveling around a mast, in order to present mobility between the center of the well and the mouse hole (US2005/0047884). This is known to move an automatic floating wrench on wheels (US-A-5,259,275), and on a set of rails (US-B2-7,861,619) to and from a well center, suspended by a cable and inwardly oscillating (US-A-6,082,224), and using flexible chains that intertwine to form a rigid member that pushes the suspended floating wrench to and from the center of the well (US-A-5,368,113) and using a telescopic arm (WO 98/32947).
    [0004] Drilling fluid is pumped through the drill string to the bit and out through openings in or near the bit. Drill cuttings flow upwards through an annular space between the drill string and the hole wall to a runoff line on the drill rig. Equipment for solids control, such as slurry screens, centrifuges, hydrocyclones, degassers and deaerators, are positioned above a series of holding tanks known as an active sludge system. Drilling fluid in the active mud system is fed and processed continuously from the flowline, with solids removal, testing, addition of additives and return to the well through a connecting tube in the top drive or swivel through the drill string. drilling.
    [0005] To improve hole integrity, the hole may be lined with a coating. A casing string is lowered into the hole and suspended from a wellhead or mold over the surface of the formation. During casing string construction, a casing section is added to the casing string as said string is lowered into the hole. Generally, the casing is much larger in diameter than the drill pipe and therefore requires a different set of tools on the rig floor. In this way, the platform floor is freed from the tools used in the drilling operation, which are replaced by tools for the casing operation. For example: the auto shipyard is replaced by a floating cladding switch, a suitable cladding clamp or a cladding sliding tool is attached to the top drive; the drill pipe elevator is replaced by a casing elevator; a pigtail operator of the drill pipe is replaced by a pigtail operator; and the spider is replaced or adapted for coating. The casing section is aligned with the aid of a pipe handling device or a casing elevator is used to lift the upper end of a conveyor belt so that the lower end swings into alignment with the center of the well and the column. coating suspended over the hole. A casing pigtail operator takes the free lower end of casing and aligns it to the center of the well. Then the casing section is connected to the casing string suspended over the hole. Connection is made using the casing float switch and associated support float switch, suitable casing arm or casing slide tool, utilizing the top drive rotation while the casing string is held in the spider. coating on the platform floor offers torque resistance. When the casing string is complete, it is hung from the mold or wellhead. Centralizers can be used to center casing within the borehole, which can be fitted to casing sections prior to transport to the center of the well.
    [0006] The coating can be cemented in place. This is usually accomplished through a cementing operation. A cementing head is transported from where it hangs on a rack. A lower wiper plug is pushed along the casing string by the flowing cement, separating the cement from the drilling mud in the casing string. A top wiper plug follows the predetermined amount of cement. Upon reaching a casing column shoe, a rupture disc is ruptured in the lower wiper plug, allowing cement to flow out of the shoe and upward to an annular space between the casing and the hole wall. The upper wiper plug reaches the lower wiper plug when all the cement has been injected into the annular space.
    [0007] A series of safety valves (BOPs | Blow Out Preventers) can be connected to the mold to form a wellhead. On an offshore platform, a subsea conductor may not be installed between the seabed wellhead and the offshore platform. The installation of BOPs on an offshore platform is carried out from the offshore platform. Typically, the spider is removed and the BOPs, or the entire wellhead, are lowered from a floor below the rig floor using a drill winch cable. Generally, the subsea conductor is a large diameter pipe, possibly including an exoskeleton structure, which is lowered and connected using a technique similar to a drill pipe or casing, but which requires specialized tools on the rig floor.
    [0008] Then, the drilling continues through the subsea conductor and the wellhead and, in this way, the set of tools is replaced again by the set used for drilling. When the drill string is very long, it can be difficult to transfer torque from the top drive or turntable to the bit. A background engine can be used. The background engine is installed next to the background composition. Circulation of drilling mud through the bottom motor rotates the bit.
    [0009] Additional casings, with smaller diameters, can be installed and cemented in place as drilling is performed. Again, the set of tools used for drilling will be replaced by a set for casing with a smaller diameter. In addition, a casing can be placed, which is a casing that does not remain tied to the wellhead, but hangs from the lower end of a previously hoisted casing.
    [0010] Side holes can be formed from the main hole using tools such as milling machines and offset wedges. Side holes can extend for miles from the main hole.
    [0011] Specialized tools may be required during the drilling process, such as a continuous circulation tool, as shown in WO-98/16716 and WO 2009/093069. These tools are brought to the platform floor and positioned in the center of the pit. Then the continuous circulation tool is connected to the drill string between the rig floor and an upper sub connected to a top drive. These tools allow continuous circulation of drilling mud while the drill pipe is inserted or withdrawn during maneuvers, maintaining constant pressure in the wellbore.
    [0012] When the well hole is sufficiently deep, and considered in the correct place for production, the well goes through a completion stage. This step may involve placing a perforated tube. In addition, the hole can be cleaned with cleaning tools, at the tip of a drill string, and prepared to receive oil from the formation. In some circumstances, explosives may be sent down the well to induce oil flow, which involves a variety of specialized pieces of equipment on the platform floor in the center of the well. Then, the well enters the production phase.
    [0013] Several operations can be performed during the production phase, such as reconditioning operations and well stimulation, in an attempt to get more oil from the well. These operations can be carried out using flexible tubes and tools connected to these tubes. These operations can be carried out from the wellhead or from the platform floor. Thus, there is a need for a hose reel and a diversion tool to facilitate the passage of hoses through the casing of the well hole.
    [0014] Therefore, the drill string can be inserted and removed frequently between these operations.
    [0015] The inventors have noted that there is significant “inertia time” in the rig floor configuration for various rig operations such as drilling, casing, completion, production, well intervention and stimulation. In addition, the inventors have noted that there is a high inertia time in the platform floor configuration for specialized procedures such as continuous circulation, cementing, recovery of stuck tools, installation of BOPs, installation of subsea conductors, coating, completion operations, etc. This is particularly, but not exclusively, relevant in a dual derrick system where operations change from drilling to casing, to completion, etc. too quickly and with high frequency, causing large periods of “downtime”, while the tool settings are changed in one of the well centers, work in the other well center is possibly interrupted.
    [0016] The inventors also noted that in the event of a tool failure used on a platform floor, platform operations must be stopped so workers can collect and replace the defective tool. This can lead to a high downtime.
    [0017] In accordance with the present patent application, there is provided a system for moving items on a platform floor, said system comprising a plurality of trolleys and a network of rails for guiding the plurality of trolleys, each being cart of said plurality of carts for supporting an item, and each cart includes rail engagement members for engagement with at least one rail of said network of rails.
    [0018] The present patent application also provides a system for moving items on a platform floor, said system comprising a plurality of accommodation means and a network of directing means for direction of the plurality of accommodation means, each accommodating means of said plurality of accommodation means for supporting an item, and each accommodation means includes targeting means engaging members for engagement with at least one targeting means of said targeting means network. The accommodation means can accommodate any tool or item that needs to be transported across a platform floor and particularly, but not exclusively, to and from the center of the well, and may also be between the center of the well and one of a plurality of ramifications.
    [0019] The present patent application also provides a method for configuring items on a platform floor, characterized by providing a plurality of trolleys and a network of rails to guide the plurality of trolleys, each trolley including locking members. of tracks for engagement with at least one track of said network of tracks, said method comprising the steps of transporting an item on a trolley of said plurality of trolleys across at least a portion of the platform floor.
    [0020] The present patent application also provides a platform floor that includes a network of tracks and a plurality of carts, with each cart of said plurality of carts supporting an item and each of the plurality of carts including rail fitting. Each cart can include structural elements such as steel, aluminum, composite or plastic arms, baskets, steps, supports, shelves or frames to carry a specific item. Each cart can travel along the entire rail network, although each cart uses only part of the rail network. A part of the rail network near the center of the well may be the most used. The rail network may include a plurality of branches for temporary or permanent storage of a particular cart.
    [0021] The present patent application also provides a platform floor that includes a plurality of carts and a network of tracks for guiding the plurality of carts, each cart of said plurality of carts being used to support an item, and each trolley including rail engagement members for engagement with at least one rail of said rail network.
    [0022] Therefore, items such as tools and well equipment do not have a dedicated position, but are positioned in the most efficient location for the next operation. When the driller replaces tools on the platform floor, the tools can be prepared for the next operation the driller will perform.
    [0023] Optionally, the trolley has its own propulsion. Optionally, at least one of the plurality of trolleys comprises a propulsion unit for pushing the trolley along the rail network. The propulsion unit may be hydraulic and powered by a hydraulic power source located on the platform, away from the cart, or the cart may include a hydraulic compressor. Optionally, the propulsion unit may further comprise a power source which may be a battery located on the cart or on the platform, or away from the cart, for powering the hydraulic compressor. Optionally, the propulsion unit comprises a foot pedal. Optionally, the foot pedal is used to selectively move the cart forwards or backwards along the rail network. Optionally, the pedal comprises a gripping mechanism that selectively grips and releases a track from the track network. Optionally, the pedal comprises a leg with at least one articulated joint. Optionally, the pedal has hydraulic activation. Optionally, each trolley is provided with two pedals, one being optionally for driving in a first direction and the other for driving in a perpendicular direction, taken in a plane coincident with the rail network. Optionally, the trolley has a hydraulic drag line attached to feed the propulsion unit. Optionally, the trolley is supplied with a hydraulic hose reel. Optionally, the platform floor comprises a plurality of hydraulic engagement supply points within said rail network. Optionally, the hydraulic hose has a connector at one end, said carriage comprising a displacement means such as a hydraulic cylinder, a spring or an articulated arm for pushing the connector into one of said hydraulic engagement supply points. Optionally, the pedal touches the floor and reacts with it to propel the cart along at least one track. Optionally, the rail includes a top surface that is wide enough to allow the pedal to touch to propel the stroller. Optionally, the rail has an I-shaped cross section.
    [0024] Optionally, the rail network is organized in a grid, forming a rail grid. Optionally, the rail network comprises a pair of parallel rails on which said plurality of trolleys are guided. Optionally, the floor sections are positioned within the area defined by the rail grid. Optionally, the floor sections are removable. Optionally, floor sections are fixed. More optionally, the floor sections are suitable for platform workers to walk on.
    [0025] Optionally, the rail network comprises an intersection between a warp rail and a braided rail. Optionally, there is a gap in the warp track and a gap in the braid track at said intersection. Optionally, at least one track fitting member comprises a shoe with a skirt portion defining a longitudinal channel. Optionally, the skirt part further defines a transverse channel. Optionally, the skirt part comprises an engagement part for engagement with at least part of the track. Optionally, the warp rail and braid rail criss-cross at right angles, although they can also criss-cross at other angles between 10 and 80 degrees or between 25 and 65 degrees. Optionally, the shoes are slip shoes. Optionally, the sliding shoe includes a low friction lining element to facilitate trolley movement. Optionally, each cart is supplied with four units of these shoes. Optionally, the trolley is substantially square, optionally including a shoe at each corner, or close to each corner.
    [0026] Optionally, at least one rail provides support for the cart. Even more optionally, the weight of the cart and the item on the cart is supported substantially, or entirely, by at least one rail or between a pair of rails. Alternatively, all or part of the weight of the cart is supported by the platform floor and the rail used to direct the cart.
    [0027] Optionally, the rails are located on said platform floor, optionally, so that the rails are substantially in the same plane as the platform floor. This can reduce the chance of a platform worker tripping over one of the tracks. This can also reduce the impact caused by damage and wear to the rail, as the rail will remain substantially protected or enveloped by lower and side cavities.
    [0028] Optionally, the rail network further comprises at least one predetermined parking point. Optionally, the predefined parking point comprises physical means operable upon arrival at said parking point to provide physical indication that the cart is stopped. Optionally, the platform floor, having one of a locating pin and a locating hole at a predefined parking spot and at least one of the trolleys having the remainder between the locating pin and the locating hole, so that , when in use, one of the locating pin and locating hole moves to place the locating pin in the locating hole. The locating pin may be a spring-loaded toothed pin, and in place of a hole, a projecting tooth is provided on the platform floor, so that the spring-loaded toothed pin is locked to the projecting tooth when the trolley moves. into the parking spot. Optionally, a parking sensor, such as an ID tag reader, is provided to send a signal to the master control system to indicate that the cart is parked at said predetermined parking spot. Optionally, the platform floor adjacent to the locating hole is provided with an ID tag which is read by the ID tag reader on the cart. Alternatively, the ID tag is on the cart and the ID tag reader is on the platform floor at the parking spot. Said tag and identification tag reader can be: an RFID tag and an RFID reader; an optical system can be used, such as a barcode and a barcode reader or a QR code and a QR code reader; or an identification tag that uses high or low frequencies can be used with associated high and low frequency readers. ID tags can be passively powered or powered. Optionally, a predetermined parking spot is located in at least one of the following places: in the center of the pit for positioning carts containing items, such as tool carts in the center of the shaft, which may or may not retain the cart during use of the shaft item or tool; immediately adjacent to the center of the pit for unloading items from the cart to the center of the pit; close to the center of the well to facilitate the unloading of other items using a crane trolley, or for pipe, casing and subsea conductor handling tools or for pipe, casing and subsea conductor connection tools, such as an auto shipyard; on a trolley lift; in a storage area. The master control system receives an information packet from a parking point processor located on the cart. The parking control processor may be part of a cart control computer. The information packet comprises at least one of the following information: an identifier code, which identifies the type of cart, such as a diversion tool cart or spider cart; if the item in question, such as the spider or diversion tool, is on the cart; item information such as size, type, usage history, current and past failures; the direction of the cart; and location information of the parking spot where the cart is parked.
    [0029] The identifier code, which identifies the type of cart, such as a diversion tool cart or spider cart, is optionally pre-programmed into the parking control computer.
    [0030] Information regarding the item, such as whether the spider or bypass tool is inside or outside the cart; Item information such as size, type, usage history, current and past failures are optionally obtained via an RFID tag reader in the cart and at least one RFID tag and optionally a spare RFID tag on the item , containing information about the item, such as size, type, operating history, current and past faults.
    [0031] The master computer control system receives these information packets for all the trolleys on the rail network. The master computer control system is programmed with information about the configuration of tools and equipment for various standard operations, such as: drilling; column insertion; column removal; coating pass; coating cement; conclusion; and reconditioning. The master control system is then able to control all the carts using the information packets. The driller or drill foreman is provided with an interface to the master control system in the driller's room, such as a window or touch screen. The driller is given a list of buttons, each for an operation, such as drilling; column insertion; column removal; coating pass; coating cementation/completion and reconditioning. The driller presses necessary buttons, such as “drill”, and the master computer control system sends signals to the trolleys to control each trolley to travel to and out of predetermined parking positions onto the platform floor to perform the drill. drilling. For example, for drilling: the center of the well must be clean; a spider suitable for a drill pipe is needed in the center of the well and a crane trolley to move the spider to the center of the well; the crane must be removed to the storage area; an automatic dockyard trolley will be required at a predetermined parking spot in the vicinity of the center of the pit; a pipe tail operator arm trolley will be required at a predetermined parking spot in the vicinity of the center of the pit.
    [0032] Optionally, the platform floor comprises one of a locating pin and a locating hole at a predefined parking spot and at least one of the carts having the remainder between the locating pin and the locating hole, so that, when in use, one of the locating pin and locating hole moves to place the locating pin in the locating hole. When the locating pin is fitted into the locating hole, the exact location of the trolley is revealed and similarly, a tool on the trolley, such as an auto yard trolley, can operate from a predetermined position.
    [0033] Optionally, the rail network comprises at least one and, optionally, a plurality of each of: a T-junction; intersection; and curve. Optionally, the rails are all linear and straight. Optionally, the rails are curved in the horizontal plane to form curves.
    [0034] Optionally, the rail network comprises a vertically displaceable rail section. Optionally, the vertical travel rail section is sized to allow a trolley to travel between the platform floor and a level below or above it. Optionally, a liftable floor portion is positioned between, or next to, said rail.
    [0035] Optionally, the rig floor is located on an onshore or offshore drilling rig. Optionally, the platform floor is located on one of the following options: a drillship; an FPSO; offshore platform, such as a Spar-type platform, SWATH-type hull vessel, SeaStar platform and cable-legged platform; and ground probes.
    [0036] The present patent application also provides a trolley for use on the platform floor of the present patent application, the trolley comprising a base, a propulsion mechanism and a shoe for mating with a rail.
    [0037] Optionally, the trolley also comprises a hydraulic hose reel over it. Optionally, the reel has an automatic winding system so that the hydraulic hose remains tensioned between the reel and the coupling point.
    [0038] Optionally, the trolley also comprises a spool of electrical cables on top of it. Optionally, the spool has an automatic winding system so that the electrical cable remains tensioned between the spool and the hitch point. Optionally, the trolley has its own propulsion with an electric motor and the electric cables carry enough current to energize said electric motor. Optionally, the electric motor and the electrical connections used between the electric cable and the electric motor are explosion-proof, or placed in explosion-protection coatings suitable for use on drilling decks.
    [0039] Optionally, the cart is lifted using a magnetic field and a drive component induced by the magnetic field or by means of a separate drive, such as an electric motor that drives a wheel across the platform floor or track.
    [0040] Each trolley, such as a flexible pipe trolley, pipe handling arm trolley, auto shipyard trolley, subsea conductor handling arm trolley and sounder room trolley is optionally supplied with at least one of: a self-propelled system; parking system; automatic coupling system; and automatic control system. Optionally, the propulsion system is hydraulically powered, and the hydraulic power and communication lines for the drum feed rotation are provided through an auxiliary line on the cart, which derives from the combination of the hydraulic fluid supply hose and the lines. of communication; therefore, an additional hitch is not necessary.
    [0041] The driller's room is a cabin with a large window in which the driller and the rig manager control the drilling platform. The inventor has noted that it is beneficial for the driller's room to be close to the center of the well, so that the driller and rig foreman can see exactly what is happening in the center of the well. However, positioning the driller room too close to the center of the well takes up valuable space from the center of the well, so the driller room can remain close to the center of the well during certain operations, but must be farther away during other operations. In addition, if a failure occurs on a drilling rig, this failure is likely to occur in the center of the well, especially during certain operations.
    [0042] According to a second aspect of the present patent application, there is provided a drilling rig comprising a rig floor and a drill rig room, characterized in that said drill rig room comprises a movable means for moving along the drill floor. platform. Optionally, said driller room is positioned on a trolley. Optionally, the trolley is provided with propulsion means for pushing said drill room across the entire platform floor. Optionally, said platform floor is provided with a network of tracks, and said driller room can move along the entire network of tracks.
    [0043] With the fully automated system of the present patent application, it is possible to replace tools and other items and equipment, such as lifting equipment, that have suffered damage or failure, and take them back to the workshop, replacing them without the need for rig helpers over the rig floor and therefore without the need to close the entire rig floor, which is especially important, but not exclusive, in the case of a dual derrick system.
    [0044] For a better understanding of the present invention patent application, references will be made, through examples, to the attached drawings, in which:
    [0045] Figure 1 is a perspective view of part of a drillship, including a platform floor, in accordance with the present patent application.
    [0046] Figure 2 is a perspective view of the platform floor shown in figure 1, in another operating stage.
    [0047] Figure 3 is a perspective view of the platform floor shown in figure 1, in yet another operating step.
    [0048] Figure 4 is a schematic top plan view of part of the drillship shown in Figure 1, showing, inter alia, a rail network and a plurality of trolleys, in accordance with the present patent application.
    [0049] Figure 4A is an enlarged top plan schematic view of part of the platform floor showing, inter alia, a rail network shown in Figure 4.
    [0050] Figure 4B is a cross-sectional view along line 4B-4B of a rail shown in Figure 4A of the platform floor rail network.
    [0051] Figure 4C is a cross-sectional view of a rail network of rails for use on the workshop floor.
    [0052] Figure 4D is an enlarged top plan view of a woven rail crisscrossed with a braided rail.
    [0053] Figure 5 is a schematic view of a spider cart to move a spider.
    [0054] Figure 5A is an enlarged view of the spider cart shown in Figure 5.
    [0055] Figure 6 is a top plan view of the spider cart shown in Figure 5 with a spider on said cart.
    [0056] Figure 7 is a schematic side view of the spider cart shown in Figure 5 with a spider on said cart.
    [0057] Figure 7A shows part of the spider and spider cart shown in Figure 5 in a first use position on a platform floor during movement towards a parking spot (rails not shown for clarity).
    [0058] Figure 7B shows part of the spider and spider cart shown in Figure 5 in a parked position (rails not shown for clarity).
    [0059] Figure 7C shows a flow diagram of a control system according to the present patent application.
    [0060] Figure 8 is a final view of a BOP test valve cart with a BOP test valve on said cart.
    [0061] Figure 9 is a top plan view of the BOP test valve cart shown in Figure 8 with the test valve on said cart.
    [0062] Figure 10 is a side view of the BOP Test Valve Cart shown in Figure 8 with the BOP Test Valve on said cart.
    [0063] Figure 11 is a side view of a crane trolley with a crane on said trolley, in a first stage of the operation.
    [0064] Figure 12 is a top plan view of the crane cart shown in Figure 11 with the crane in the first stage of operation.
    [0065] Figure 13 is a side view of the crane trolley with the crane in a second stage of operation.
    [0066] Figure 14 is a front view of a deflection tool cart supported on said cart, showing a first and second stage of operation.
    [0067] Figure 15 is a top plan view of the deflection tool cart with the deflection tool supported on said cart.
    [0068] Figure 16 is a side view of a trolley elevator of the rail network shown in Figure 4, with a trolley elevator platform in an elevated position at the platform floor level.
    [0069] Figure 17 is a side view of the trolley lift of the rail network shown in figure 16, with the trolley elevator platform in a low position, at the workshop floor level.
    [0070] Figure 18 is a top plan view of the cart lift platform shown in Figure 16.
    [0071] Figure 18A shows a detail of part of the trolley elevator and the workshop floor.
    [0072] Figure 19 is a front view of the trolley lift shown in figure 16, with the trolley lift platform in low position, at shop floor level.
    [0073] Figure 20 shows a schematic cross-sectional side view of the drillship shown in Figure 4, along the line XX-XX.
    [0074] Figure 21 shows a schematic cross-sectional side view of the drillship shown in Figure 4, along line XXI-XXI.
    [0075] Referring to figures 1 to 4, part of the drillship, generally identified by reference numeral 1, including a platform floor 2 according to the present patent application, is shown. The perspective view is performed from the stern of drillship 1 amidships, facing bow 3. Drillship 1 has two drill rigs 4 and 5 positioned to starboard of drillship 1, each of the towers including a pit center 6 and corresponding 7, located substantially along a centerline 8 of drillship 1. A pipe handling and assembly structure 9 is positioned to port side of drillship 1. Platform floor 2 is positioned between and around the two derricks 4 and 5. The platform floor 2 surrounds the two derricks 4 and 5. A rail network 10 is positioned on the platform floor 2. The rail network 10 comprises a plurality of straight routes 11 to 19. Each of the routes 11 to 19 comprises a plurality of pairs of tracks, such as pairs of tracks 20, 21.
    [0076] A plurality of specific item trolleys of the present patent application are shown in Figures 1 to 3 in the rail network 10. A drill pipe tail operator trolley 30, a driller room trolley 31, a subsea conductor handling arm cart 21, a turntable tender 33, a hose cart 34 and a well intervention hose injector cart 35.
    [0077] Rail network 10 comprises routes 11 to 19 in a configuration suitable for a platform floor on a drillship 1. All routes 11 to 19 can be used to direct specific trolleys between destinations. However, each route 11 to 19 has a main function.
    [0078] Routes 11 and 12 lead through the rear of drill rigs 4 and 5 and pass through a lower tool storage area 22, and are used to move specific carts from a forward storage area 23 of the drillship 1 to main deck 2 floor.
    [0079] Route 13 is mainly used as storage area 40 for item carts that can be used in future operations.
    [0080] Route 14 is primarily used as an access route to direct trolleys from storage area 40 to or near well centers 6 and 7. Route 14 also leads to the Christmas tree elevator 44 located on the port side of the platform 2 floor. Christmas trees 45 are located in an area below the platform 2 floor in a Christmas tree cart 46.
    [0081] Route 15 is primarily used as an access route to direct trolleys from bow storage area 23 to or near well centers 6 and 7. Routes 14 and 15 are also used for locating a driller room trolley 31 to provide full visibility to the driller and drill foreman of well center 6 and 7.
    [0082] Route 16 is primarily used as an access route to direct trolleys from storage area 40 and bow storage area 23 to or near well centers 6 and 7. Well centers 6 and 7 are located within a pair of tracks 24 and 25 that make up Route 16. These item carts that may be needed in the center of the pit comprise: a spider cart 37, a diversion tool cart 38, a BOP test valve cart 39, a continuous circulation system cart (not shown), and a turntable cart 33.
    [0083] Route 17 is primarily used as an access route to take specific item carts to the vicinity of pit centers 6 and 7, where specific item carts generally remain on top of the carts on Route 17 while the item is is operated such as: a tube tail operator cart 30; an automatic shipyard trolley (not shown); a casing floating key cart (not shown); a crane cuddle 36 (shown in Figures 11 to 13).
    [0084] Routes 18 and 19 are used to drive item carts to a cart elevator 41. Cart elevator 41 raises and lowers item carts between platform floor 2 and workshop floor 42. Items and repair and maintenance item carts will be driven along routes 18 and 19 to trolley lift 41 and lowered to the shop floor which has its own network of rails 43 to move these item trolleys to an area of the shop floor 42 suitable for particular item cart repair and maintenance.
    [0085] A detail 50 of the rail network 10 is shown in Figure 4A. A warp route 51 is shown that intersects a braided route 52. The warp route 51 and the braided route 52 each comprise a pair of parallel rails 53, 54 and 55, 56. A cross section of the rail 53 is shown in Figure 4B. Rail 52 to 56 has a weight bearing body 57, curved shoulders 58 and a top 59 that extends over shoulders 58. Pairs of parallel rails 53, 54 and 55, 56 are optionally spaced 3.2m apart. each other, between the central lines of the tracks. At the intersections of pairs of parallel rails 53, 54 and 55, 56, the ends 59 of the rails stop just before contacting each other, leaving a gap of approximately 75 mm between them, sufficient to allow a shoe 60 (see Figure 5 ) slide between braided and warped routes 51 and 52. An island-shaped rail top 61 is provided to support shoe 60 when a trolley crosses the intersection. Wide upper surfaces of rail 62, 65 and 63, 64 are provided between the parallel rails of the warp and braid route 51, 52 respectively.
    [0086] Figure 4C shows a cross section of a rail used on the floor of workshop 42, with a slightly lower profile.
    [0087] Figure 5 shows one type of item cart, a spider cart 37. The spider cart 37 comprises a square base plate 66, with sides approximately 3.4m long, a circular opening 67 therein. and a depression 68 around the circular opening 67 sized to accommodate a spider 69. The square base plate 66 has a shoe 60 at each corner so that the distance between the centers of the shoes is 3.2m. A branch leg 70 is positioned between each corner of the square base plate 66 and the shoe 60. The shoe comprises a slider 71 with a top plate 72 sized for positioning on top of the top of the track 59, a skirt portion 73 for fit over the sides of the top of the track 59 and the hook parts 74 for fitting under the top of the track 59 and above the shoulders 58. The top plate 72, the skirt part 73 and the hook part 74 define a channel 75. A corresponding perpendicular channel (not shown) is also provided on each shoe so that the spider carriage 37 can travel along the route 51, the tracks 53, 54 pass through the pair of channels 75 and when the spider carriage 39 takes route 52, the tracks 55, 56 pass through the corresponding perpendicular channels.
    [0088] The spider carriage 37 is propelled along the rail network 10 by a propulsion system 76. The propulsion system 76 comprises a first pedal 77 positioned in line with a channel 75 and positioned in a first corner 79 and a second pedal 78 in line with one of the corresponding perpendicular channels (not shown) in a second corner 80. The first and second pedals 77, 78 include a sole plate 81 and four selectively actuatable side grips 82. The first and second pedals 77, 78 each includes a movement arm 83 with a rigid member 84 and a hydraulic ram 85. The hydraulic ram 85 is of the dual drive type. The first rigid member 84 at a proximal end is welded or otherwise attached to the respective top plates 72 of the first and second pedals 77, 78 and at a distal end attached to a cylinder end 86 of the hydraulic ram 85 and a piston end. 87 of the hydraulic ram is attached to the sole plate 81. An on-board control system 88 controls the flow of hydraulic fluid to the propulsion system 76.
    [0089] In use, the flow of hydraulic fluid to the propulsion system 76 is controlled by the on-board control system 88. The propulsion system 76 can operate in either traction or compression mode and in a first direction or a second perpendicular direction. . In the compression mode in a first direction, the hydraulic ram 85 is initially contracted and the sole plate 81 rests on a rail, for example, the rail 53 with the selectively driveable side claws 82 in an open position, in which said claws are not touch the sides of the rails 53 and remain in a plane above the rail 53. The onboard control system 88 sends a flow of hydraulic fluid so that the selectively actuatable side jaws 82 change to the closed position, in which said jaws move. downwards and inwards to grip the rail 53. The onboard control system 88 sends a further flow of hydraulic fluid to the hydraulic ram 85 to be extended. Spider cart 37 is pushed along track 53 and equally along route 51. Selectively actuated side grips 82 are then released by hydraulic fluid flow controlled by onboard control system 88, hydraulic ram 85 is contracted by the flow of hydraulic fluid controlled by the onboard control system 88, while the sole plate 81 of the first pedal 77 slides along the top of the rail 53 towards the square base plate 66. These steps are repeated to complete pedal cycle 7 to push the spider cart in a first direction. It should be noted that the second pedal 78 is not operable in this mode of operation. When spider carriage 37 reaches an intersection, T-junction or corner, the second pedal is operated to push or pull spider carriage 37. For traction mode, the cycle is reversed. The spider cart can travel at a speed between 0.3 m and 3 m per minute.
    [0090] Spider cart 37 has a parking system 90. When the spider cart is near a predetermined parking point, a locating pin 89 of a locating pin mechanism 90 on a bottom face of the base plate square 66 is activated by master control system 105, which lowers a pin onto a pin plunger 89', as shown in Figure 7A and 7B. The parking system 90 is centrally located along one end of the square base plate 66. The locating pin 89 is at this point elastically deflected downwards against the platform floor 2 by means of a means elastic, for example an 89'' spring. Spider carriage 37 continues, self-propelled, until locating pin 88 passes over locating hole 91, which is when the spring deflects locating pin 88 into locating hole 91. Control system 88 stops the flow of hydraulic fluid to the propulsion system 76, which stops moving the spider cart 37. The four selectively actuatable side grips 82 are actuated to grip the rail 53 and act as a handbrake. Alternatively or additionally, parking system 90 may also act as a handbrake to inhibit movement of spider cart 37.
    [0091] A combination of a hydraulic fluid supply hose and communication lines 100 is provided between the platform floor 2 and the spider cart 37. Hydraulic coupling points 92 and communication lines coupling points 93 are provided on the platform floor 2 between the rails and approximately 2.8 m behind each locating hole 91. Hydraulic coupling point 92 is connected to a pressurized hydraulic fluid supply (not shown), a common feature of all drilling rigs and drillships. The communication line hitch 93 is connected to the master computer control system 105 of the drilling rig. The Spider Cart 37 is also provided with an automatic coupling system. A matching latching connector mechanism 94 is provided at one end of the square base plate 66 opposite the parking mechanism 90, approximately 2.8 m away. The corresponding mating connector mechanism 94 has a connector block 99 comprising a hydraulic connector 95 and a communication line connector 96, positioned below a small self-powered ram 97. The combination of hydraulic fluid supply hose and communication lines 100 is fixedly connected to an upper surface of the connector block 99. The combination of hydraulic fluid supply hose and communication lines 100 is wound onto a self-powered spool 101 with winding mechanism (not shown), which may simply be a spring , so that when the combination of hydraulic fluid supply hose and communication lines 100 is unwound, the spring is energized. The spool 101 is mounted on a mounting frame 102. The combination of hydraulic fluid supply hose and communication lines 100 is between five and thirty meters in length and, more optionally, between ten and twenty meters in length.
    [0092] In use, when the spider cart 37 is parked, the self-powered winding spool 101 is activated to wind the combination hydraulic fluid supply hose and communication lines 100 until the connector block 99 returns to the position shown in Figures 5 and 7. Next, the self-powered small ram 97 is activated for extension. An optional cover 103 over hitch points 92 and 93 can be provided, which is automatically opened by inserting locating pin 89 into locating hole 91. The self-powered small ram 97 pushes the connector block 99 to hitch points 92 and 93 , providing the spider cart with a pressurized flow of hydraulic fluid and communication channels between the self-powered small ram 37 and a master computer control system 105 on drillship 1.
    [0093] The pin plunger 89'' is retracted to retract the pin 89 from the socket with the locating hole 91 and from contact with the platform floor 2, when the spider carriage 37 starts its movement.
    [0094] A hand control interface 115 is provided on an arm 116 movably attached to the square base plate 66. The hand control interface 115 may be used in place of control by the master computer control system 105.
    [0095] Before the spider is needed, a command is sent to workshop workers to prepare spider cart 37. Spider 69 is placed on spider cart 37 in workshop 42. Spider cart 37 will be transported by elevator of carts 41 along routes 13 and parked in buffer storage area 40.
    [0096] Referring to Figure 7C, an information packet is collected by an on-board information-gathering computer 206. A parking RFID tag reader 200 is positioned on the underside of the baseplate 66, adjacent to the parking mechanism. 90. The RFID tag reader is activated by the on-board information gathering computer 206 to read the parking point information present on the RFID tag 201 on the platform floor 2. The RFID tag reader 201 sends a point information packet information, such as location and reference number, to the on-board information-gathering computer 206. An RFID tag reader 204 is activated by the on-board information-gathering computer 206 to read spider information from the RFID tag 205. If there is no RFID tag 205 for reading, an on-board information packet is sent to the on-board computer for information collection 206, indicating that there is no spider 69 to onboard spider cart 37. Another weight sensor positioned on base plate 66 and connected to onboard information gathering computer 206 can be used to verify these situations. If the RFID tag reader 204 can read the RFID tag 205, information regarding the spider 69 will be sent to the on-board computer for information collection 206 in the form of a spider information packet. This spider information package may include data regarding the type of tube suitable for spider use, size, and present and past faults, as well as their respective rectifications. A steering information packet, e.g. cart steering, can also be obtained by the on-board computer for collecting information 206 from a steering sensor (not shown). Storage memory, e.g. RAM or EPROM (not shown) is also provided in the spider cart, containing a spider cart information packet, which includes information such as part number and description to confirm that it is a spider cart. The spider cart information package, steering information package, spider information package, on-board information package, and parking point information package are gathered into a cart information package by the on-board computer for collection 206 and sent to the master computer control system 105.
    [0097] The 105 master control system is provided with a pre-programmed feature for configuring a spider in the center of the well. The master control system 105 also has information packets from each trolley in the rail network. The master control system 105 automatically sends the spider cart to its destination when needed. For example, the driller can press an “install drill pipe spider on first well center” button on a visual interface (not shown) of the master control system from the driller room cart 31. The destination will be on route 16 at one of pit centers 6 or 7. Master computer control system 105 controls spider cart 37 to retract locating pin 89 from locating hole 91 and activating onboard control system 88 to control the propulsion system 76, so that the spider cart 37 can reach its destination. From storage area 40, the spider cart travels along route 16 to a predetermined parking spot near the pit center. Simultaneously, a crane trolley 36 (shown in Figures 11 to 13) is sent from buffer storage area 40 to a predetermined parking spot on route 17 near the center of the pit. The crane trolley has the same self-propelled system, parking system, auto hitch system and auto control system as described in reference to spider trolley 37. It should be noted that the auto hitch system spool is not shown in Figures 11 to 13 for clarity. The crane cart is parked on route 17 at the predetermined parking point using a parking mechanism (not shown), which is identical to the parking mechanism 90 shown and described with reference to spider cart 37. Next, a crane 112 at the spider trolley 36 is operated from a remote location, e.g. driller room trolley 31, utilizing an electrical cable control system (not shown) to activate the hydraulic valves on crane 112, or can be operated at automatic mode by the master computer control system 105. The computer system 105 knows the absolute location of the crane cart 36 and the spider cart 37. In automatic mode, a boom 116 is lifted using the ram 118 and extended using the ram 119 over spider 69 on spider cart 37. A hook 117 is lowered over thread 120 over spider 69 and under a spider hook receiver (not shown). ado). Hook 117 is lifted onto line 120. The crane is swung onto turntable 121 and lowered into the center of the pit. Alternatively, the master control system 105 controls the spider cart 37 to travel over the center of the pit in question 6 or 7. The spider 69 can be lifted from the spider cart 37 using a hook (not shown) hanging from the shaft. from a top drive 106, 107 (see Figure 20) on derrick 4 or 5. Next, spider cart 37 is moved along route 16, and then top drive 106, 107 is lowered by a drill winch 111 through a line 108 (not shown) passing over a capping block 109, 110 on top of the derrick 4, 5. In this way, the spider 69 is lowered into the platform floor 2 in the center of well 6, 7.
    [0098] Hydraulic power and communication lines for crane 112 are provided through an auxiliary line (not shown) on crane trolley 36, which derives from the combination of hydraulic fluid supply hose and communication lines 100. thus, an additional hitch is not necessary.
    [0099] The driller room cart 31 shown in Figures 1 to 3 comprises a cabin 47, positioned on a cart 48 that incorporates the same self-propulsion, parking, automatic coupling and automatic control systems as described in this document with reference to the cart 37. Nevertheless, a manual engagement system may be used, as in reference to the BOP Test Valve Cart 39 described below. A swivel base 49 is positioned between the trolley and the cabin 47 to enable the cabin 47 to rotate with respect to the trolley 48, allowing the driller and rig foreman to have full visibility of the floor of platform 2, including well centers 6 and 7. The driller room 31 has clear glass sides and a clear glass roof, to facilitate the driller and the drill foreman to have full visibility of the platform 2 floor.
    [0100] A BOP test valve cart is shown in Figures 8 to 10 with a BOP test valve 125 on said cart. The BOP Test Valve Cart 39 is generally similar to the Spider Cart 37 described above, except for the following differences. A base plate 126 is formed to support the BOP test valve 125. A spool 127 for combining hydraulic fluid supply hose and communication lines 129 is provided with a shield to surround an upper portion of the spool 127. The spool is provided with an automatic winding mechanism, as is the spool 101. However, a platform worker must manually connect and disconnect the connector block 129 from the coupling point 92, 93 to engage as the cart proceeds along 10. Propulsion system pedals are not shown.
    [0101] A deflection tool cart 38 is shown in Figures 14 and 15, with a deflection tool 130 on said cart. The bypass tool cart 38 is provided with the same self-propulsion, parking, automatic engagement and automatic control systems described with reference to the spider cart 37, although it may also have the manual engagement system described with reference to the test valve cart. of BOP 39. The Deviation Tool Cart 38 is therefore similar to the Spider Cart 37, except for the following differences. The deflection tool cart has a generally flat base plate 131 and a lift arm mechanism 132. The lift arm mechanism 132 comprises a pair of bent rigid arms 133 and 134 approximately 6 meters in length, each being coupled hinged at one lower end to a tongue 134' and welded (not shown) to adjacent front corners 134' and 135 of base plate 131. A ram 136 and 137 are hingedly positioned between tongues 138 and 139 welded to the adjacent back corners 140 and 141 of base plate 131 and elbows 142 and 143 of bent rigid arms 133 and 134. A energized capping block 144 is hung from an upper bar 145 which connects the tops of bent rigid arms 133 and 134 A line 146 passes between the energized capping block 144 and a small catarina 146 with a connector 147.
    [0102] In use, the master control system 105 automatically sends the offset tool cart 38 to its destination when needed. For example, the driller can press an “install diversion tool on first well center” button on a visual interface (not shown) of the master control system from the driller room cart 31. The destination will be on route 16 in one of pit centers 6 or 7. Master computer control system 105 controls diversion tool cart 38 to activate the parking system to retract the locating pin from locating hole 91 and then activate the on-board control system to control the propulsion system, so that the 38 diversion tool cart can reach its destination. From storage area 40, deflection tool cart 38 travels onto route 16 to a predetermined parking point near the pit center. Lift arm mechanism 132 is initially positioned from a first position identified by clear lines in Figure 14, with rams 136 and 137 in a substantially vertical position and with connector 147 connected to a lifting point (not shown). in the offset tool 130. The master computer control system 105: activates the energized capping block 144 to lift the offset tool 130 from the base 131; extends hydraulic rams 136 and 137 to change the position of the deflection tool over the center of well 6; to activate the energized capping block 144 to lower the offset tool 130 over the center of the well. Alternatively, lift arm mechanism 132 is operated from a remote location, such as driller room trolley 31, utilizing an electrical cable control system (not shown) to activate hydraulic valves (not shown) on the mechanism. lift arm 132. Hydraulic power and communication lines for the lift arm mechanism 132 are provided through an auxiliary line (not shown) on the deflection tool carriage 38, which derives from the supply hose combination of hydraulic fluid and communication lines 100. In this way, an additional coupling is not necessary.
    [0103] Single carts can be supplied with a single square planar base plate to transport other items across the platform 2 floor. Two or more single carts can operate simultaneously one behind the other to move long or oversized items.
    [0104] The cart elevator 41 is shown in Figures 16 to 19. The cart elevator 41 comprises an elevator floor 150 with a route 151 and a perpendicular route 152 for directing the carts to routes 13 to 19 on the platform floor 2. A locating hole 165 is provided to facilitate parking a trolley on the floor of the elevator 151. An opening 153 in the floor of platform 2 is provided, of substantially equal size to the floor of the elevator 151, so that when the floor elevator 2 is on platform floor 2, there will be a small gap of a few millimeters between the ends of adjacent tracks 154 and 155, as shown in Figure 18A. Handrails 156 are provided around elevator floor 151. Handrails 156' are provided around opening 153 of platform floor 2. Handrails 156 on sides 157 and 158 slide down when elevator floor 151 is aligned with platform 2 or with the workshop floor 42, to allow the passage of the trolleys. The floor of the elevator 151 is supported by a frame 159, slidably positioned on a pair of uprights 160. A motor 161 drives two pairs of sprockets 162 along a vertical route 163. The activation of the trolley elevator 41 is controlled by the master computer control system 105.
    [0105] The tube tail operator cart 30 shown in Figures 1 and 2 is provided with the same self-propulsion, parking, automatic engagement and automatic control systems described in reference to the spider cart 37, although it may also have the manual engagement described in reference to the BOP Test Valve Cart 39. The Pigtail Operator Cart 30 is therefore similar to the Spider Cart 37, except for the following differences. The base 167 is substantially planar with a rigid vertical column 168, on which a tube handling arm 166 with a tube gripper 169' is mounted. Tube handling arm 166 and tube gripper 169' are hydraulically driven and controlled from master computer control system 105. Hydraulic power and communication lines to tube handling arm 166 are provided through from an auxiliary line (not shown) on the tube tail operator cart 30, which derives from the combination of hydraulic fluid supply hose and communication lines 100. In this way, an additional coupling is not necessary.
    [0106] The submarine conductor handling arm cart 32 shown in Figures 1 and 3 is provided with the same self-propulsion, parking, automatic engagement and automatic control systems described in reference to the spider cart 37, although it may also have the system 39. The subsea conductor handling arm cart 32 is therefore generally similar to the spider cart 37, except for the following differences. The base 190 is formed in a structural form of X on a horizontal plane with a square planar central portion 191, with a suspended platform 192 on which a horizontal extendable underwater conductor handling arm 193 with a guide is swivel mounted. 194. The underwater conductor extendable handling arm 193 is hydraulically driven and controlled by the master computer control system 105. Hydraulic power and communication lines for the underwater conductor extendable handling arm 193 are provided through from an auxiliary line (not shown) on the subsea conductor handling arm carriage 32, which derives from the combination of hydraulic fluid supply hose and communication lines 100. In this way, an additional coupling is not necessary.
    [0107] The flexible tube trolley 34 shown in Figure 2 is provided with the same self-propulsion, parking, automatic coupling and automatic control systems described in reference to the spider cart 37, although it may also have the manual coupling system described in reference to the BOP Test Valve Cart 39. The Hose Cart 34 is therefore generally similar to the Spider Cart 37, except for the following differences. The base 195 is generally planar, with a drum frame 196 pivotally mounted on said base. The drum frame has a drum 197 mounted, with a drum including a horizontal axis. Drum frame 196 is pivotally mounted on planar base 195 so that drum frame 196 can rotate about a vertical axis to allow flexible tubes 198 on drum 197 to be unrolled perpendicular to the drum axis. , no matter where the hose trolley is located on the rail network 10. Drum 197 has a drive system (not shown) to assist in winding and unwinding. The drive system can be hydraulically driven and controlled from the master computer control system 105. Hydraulic power and communication lines for the drive system are provided through an auxiliary line (not shown) on the tube trolley. hoses 34, which derives from the combination of hydraulic fluid supply hose and communication lines 100. In this way, an additional coupling is not necessary.
    [0108] Figures 20 and 21 show parts of drillship 1. Drillship 1 has large cranes 170 used for loading and unloading equipment to a pier. They are also used for handling equipment on platform floor 2. Includes a front retainer 171 for subsea conductor sections 172. A pipe handling and assembly frame 9 provides an area for mounting drill pipe joints on brackets 173 that are configured on a retainer 174. A pipe handling arm 175 facilitates manipulation of drill pipe holders from retainer 174 to the center of well 6 or 7.
    [0109] Rail network 10 comprises routes 11 to 19 in a configuration suitable for the platform floor on a two-tower drillship. A configuration for other rig types, such as a single-drill tower drillship, will be very similar, albeit with fewer routes. A configuration for an FPSO with two rigs will be the same, or very similar. A configuration for an offshore rig with two rigs, SPAR rig, SWATH SeaStar rig or cable-legged rig will be the same, or very similar. Despite this, an expert will be able to sketch modified configurations suitable for each type of platform. The rail network can be simplified to a dirt platform, which usually has a much smaller platform floor.
    [0110] It is envisaged that the hydraulic propulsion system 76 may be replaced by a pneumatic system or a part hydraulic, part pneumatic system. It is also provided that the propulsion system may be electrically powered.
    [0111] It is anticipated that other items can be transported and used with the same trolleys of the present patent application, such as an automatic shipyard and a continuous circulation tool. Key to Figure T1) Locating pin 89 fits into locating hole 91 of the parking spot adjacent to the center of well 6. T2) RFID tag reader 200 reads RFID tag 201 on drill deck 2 for information location and parking point reference number. T3) Default cart information. T4) Heading sensor 202 activated to obtain heading information in a horizontal plane. T5) Spider RFID tag reader 204 attempts to read spider RFID tag 205 to assess whether spider 69 is on spider carriage 37 or not. T6) Spider RFID tag reader 204 reads spider RFID tag 205 to obtain information about spider 69. T7) Information gathering on-board computer 206, collecting information in an information packet. T8) Information packet sent to the master control system by computer.
    权利要求:
    Claims (16)
    [0001]
    1. "SYSTEM FOR MOVING ITEMS ON A PLATFORM FLOOR", the system having a plurality of trolleys (30, 31, 32, 33, 34, 35, 37) and a network of tracks (10) for guiding the plurality of carts, each cart of said plurality of carts for supporting an item (47, 112, 125, 130) and each cart including rail engagement members (60) for engagement with at least one rail (53) of said net of rails (10), wherein said rail network (10) further has at least one predefined parking point (91), characterized in that the system also has a master control system (105) per computer, wherein a parking sensor (200) is provided to obtain parking location information to indicate that the cart is parked at said predefined parking spot (91) and transmit the parking location information to the parking master system. control (105) by computer.
    [0002]
    2. "SYSTEM FOR DISPLACEMENT OF ITEMS ON A PLATFORM FLOOR", according to claim 1, characterized in that said cart has a propulsion unit (76) for propulsion of said cart along said network of rails (10) .
    [0003]
    3. "SYSTEM FOR DISPLACEMENT OF ITEMS ON A PLATFORM FLOOR", according to claim 2, characterized in that said propulsion unit (76) is hydraulically powered.
    [0004]
    4. "SYSTEM FOR DISPLACEMENT OF ITEMS ON A PLATFORM FLOOR", according to any one of claims 2 to 3, characterized in that it also has a propulsion control computer (206) to control the propulsion unit (76) .
    [0005]
    5. "SYSTEM FOR DISPLACEMENT OF ITEMS ON A PLATFORM FLOOR", according to any one of the preceding claims, characterized in that said predefined parking point (91) has a physical means (90) that can be activated upon arrival at said parking point to provide physical indication that the cart is parked.
    [0006]
    6. "SYSTEM FOR DISPLACEMENT OF ITEMS ON A PLATFORM FLOOR", according to any one of the preceding claims, characterized in that said predefined parking point has the platform floor (2), having one of a location pin (89). ) and a locating hole (91) at a predefined parking spot and at least one of the carts has the other between the locating pin (89) and locating hole (91), so that when in use , one of locating pin (89) and locating hole (91) moves to locate locating pin (89) in locating hole (91).
    [0007]
    7. "SYSTEM FOR DISPLACEMENT OF ITEMS ON A PLATFORM FLOOR", according to any one of the preceding claims, characterized in that it also has an identification tag (201) on said platform floor (2), and said sensor parking space being an identification tag reader (200) for reading said identification tag (201) on said platform floor (2).
    [0008]
    8. "SYSTEM FOR DISPLACEMENT OF ITEMS ON A PLATFORM FLOOR", according to any one of the previous claims 1 to 7, characterized in that it also has a memory for storing cart identification information transmitted from said cart to the said master computer control system (105).
    [0009]
    9. "SYSTEM FOR DISPLACEMENT OF ITEMS ON A PLATFORM FLOOR", according to any of the previous claims 1 to 8, characterized by also having an item sensor to identify if the item is on board the cart and to transmission of this item presence information to the master control system (105) by computer.
    [0010]
    10. "SYSTEM FOR DISPLACEMENT OF ITEMS ON A PLATFORM FLOOR", according to any of the previous claims 1 to 9, characterized in that it also has an item information sensor for reading information about the item and for transmitting this item information to the master control system (105) by computer.
    [0011]
    11. "SYSTEM FOR DISPLACEMENT OF ITEMS ON A PLATFORM FLOOR", according to claim 10, characterized in that it also has an identification tag (205) on said item, and said item information sensor being a reader of identification tags (204) for reading said identification tag (205) on said platform floor (2), said identification tag (205) containing item information.
    [0012]
    12. "SYSTEM FOR DISPLACEMENT OF ITEMS ON A PLATFORM FLOOR", according to any one of the previous claims 1 to 11, characterized in that it also has a cart orientation sensor and transmission of cart orientation information to the system- control master (105) by computer.
    [0013]
    13. "SYSTEM FOR DISPLACEMENT OF ITEMS ON A PLATFORM FLOOR", according to any one of claims 9 to 12, characterized by at least two of the parking location information, item presence information, information about item and cart guidance information are gathered by an on-board information collection computer (206), placed in a package and sent as an information package to said master control system (105) by computer.
    [0014]
    14. "SYSTEM FOR DISPLACEMENT OF ITEMS ON A PLATFORM FLOOR", according to claim 13, characterized in that the master control system (105) by computer receives said packets of information for all carts in the rail network ( 10).
    [0015]
    15. "SYSTEM FOR DISPLACEMENT OF ITEMS ON A PLATFORM FLOOR", according to claim 13, characterized in that the master control system (105) by computer is programmed with information on the design of tools and equipment for various standard operations and display a list of standard operations for a drill operator or rig foreman to choose from.
    [0016]
    16. "SYSTEM FOR DISPLACEMENT OF ITEMS ON A PLATFORM FLOOR", according to any one of the preceding claims, characterized in that said cart also has a shoe for fitting at least one said track.
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    GB201419348D0|2014-12-17|
    RU2017118445A|2018-11-30|
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    BR112017008886A2|2017-12-19|
    RU2705686C2|2019-11-11|
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    法律状态:
    2020-06-16| B06U| Preliminary requirement: requests with searches performed by other patent offices: procedure suspended [chapter 6.21 patent gazette]|
    2021-12-28| B09A| Decision: intention to grant [chapter 9.1 patent gazette]|
    2022-02-01| B16A| Patent or certificate of addition of invention granted [chapter 16.1 patent gazette]|Free format text: PRAZO DE VALIDADE: 20 (VINTE) ANOS CONTADOS A PARTIR DE 22/09/2015, OBSERVADAS AS CONDICOES LEGAIS. |
    优先权:
    申请号 | 申请日 | 专利标题
    GB1419348.6|2014-10-30|
    GB1419348.6A|GB2531781A|2014-10-30|2014-10-30|Rig floor for a drilling rig|
    PCT/GB2015/052736|WO2016066986A1|2014-10-30|2015-09-22|Rig floor for a drilling rig|
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