KR20060136452A - Ballast system for tension leg platform - Google Patents

Abstract

The present invention relates to an apparatus and a method for ballasting and deballasting a vessel having several waterproof ballast sections. In the first embodiment, the pressure tank is shut off and flowable to the common sea chest, the atmosphere, the ballast compartment via the distribution manifold, and the compressed gas source. First, the pressure tank is opened and filled with water from the sea chest and then shut off. The filled tank is then connected to a ballast tank and a source of compressed gas, which pressurizes the water out of the tank into the ballast compartment. In another embodiment, ballasting emptyes or fills the ballast compartments using individual sea chests disposed within the ballast compartments or the digestive system. For deballasting, the compressed gas discharges the ballast water through an external drain, via a common tank, via a pressure tank, or through individual cigar chests placed inside the ballast compartment.

Tension Fixed Platforms, TLP, Ballast, Deballast, Sea Chest, Manifold

Description

BALLLAST SYSTEM FOR TENSIONAL PLATFORMS {BALLAST SYSTEM FOR TENSION LEG PLATFORM}

FIELD OF THE INVENTION The present invention relates generally to tension leg platforms used in the offshore oil and gas industry, and more specifically towing, installation (lock-off to tendon). A method and apparatus for ballasting and deballasting a tensioned platform for use in operation of the tensioned platform.

Tension Leg Platforms (TLPs) are commonly used in deep waters off the coast to produce hydrocarbons. Typical TLPs include a horizontal flat bottom hull structure and vertical columns supporting the platform. The hull structure provides buoyancy for the columns and platforms. The TLP is anchored to sediments of the ocean floor by tendons and is held fixed by the tendons of tendons induced by buoyancy.

The hull structure is generally divided into several waterproof compartments, thereby meeting stability requirements during installation ballasting. During installation, the TLP is deballasted to tension the tendons so that the platform is always kept within design limits. Preferably, the deballasting operation is to quickly minimize the time while the resonant frequency of the TLP is equal to the natural period of the surrounding seawater. For fast deballast, TLPs are generally equipped with one or more pump seals, including high capacity pumps. However, once installation is complete, only minor in-service trim adjustments are made, so the pump is no longer subject to high capacity requirements.

The main object of the present invention is to minimize the capital cost of a high capacity pump mounted to distribute and pump ballast water into the hull.

Another object of the present invention is to provide a method of rapidly achieving an installation draft by providing a method of rapidly filling a ballast tank.

Another object of the present invention is to provide a method for limiting the latching of the slip mechanism when securing tendons to the hull.

The above objects as well as other features of the present invention are incorporated into a method and apparatus for ballasting and deballasting a tensioned platform (TLP) or other vessel. The TLP tensions the tendon and includes a hull that provides buoyancy to support the column and the raised upper decks. The hull generally includes both permanent ballast tanks, temporary ballast tanks and devices for distributing ballast water. In the TLP used to describe the ballasting / deballasting apparatus and method, the hull tank forms a center base section extending radially outward towards the four tendon support structures. Preferably, all tanks have independent vents to the atmosphere.

In a first application, a compressed gas source is used, which preferably distributes water from the one or more high capacity air compressors to the hull tank, via a single pressure tank and manifold device included in the hull. The pressure tank is releasably connected to the sea chest and includes a vented vent and a water and air inlet to allow for filling, discharging, pressurization and depressurization of the tank. For ballasting, the pressure tank is filled with seawater by opening the vent and sea chest lines. Thus, the pressure tank provides a source of ballast water. Next, the pressure tank vent and the sea chest line are shut off and the pressure tank is aligned to fill the desired ballast compartment. High capacity air compressors move seawater from a pressure tank to a selected ballast compartment. The ballasting rate is controlled by the volume of the tank and the mass flow rate of the gas supplied to empty the tank. The apparatus may selectively discharge the ballast from the ballast compartment via a pressure tank out of the cisches via a pressure tank, or alternatively, using a compressed gas via an optional ballast gas line installed between the source of compressed gas and the ballast compartment. As an alternative, deballast and ballast movements between tanks may be performed using an optional moderate capacity centrifugal pump and independent return line.

In the case of the TLP configuration described herein, the pressure tank supplies water to the manifold with four supply headers. The feed header subdivides the ballast tank into four groups consisting of opposing tanks of each quadrant and the central base portion. Preferably, each header includes a valve that is remotely operated for shutoff, and each tank includes a ballast compartment shutoff valve that is remotely operated to block ballast flow. If the four feed headers were all manifolded together and provided to provide bilge and ballast transfer pump suction, the four feed headers were all bundled together to provide bilge and ballast transfer pump suction. Effluent from the pump may be connected to a return manifold returning to individual tanks through four return headers, or may be used to drain seawater through an external drainage device equipped with a valve.

In a second application, individual sea chests located in each ballast tank replace the single pressure tank to provide a source of bath water. The individual tanks have vents, sea chests, and air inlets provided with valves, respectively, to enable filling, discharging, pressurizing and depressurizing the tank. In addition, the ballast tanks are collected together to enable alternative methods for filling or discharging the tanks, including ballast movements between the tanks. Preferably, all tanks have independent vents to the atmosphere. For deballasting, the second application utilizes a source of compressed gas, preferably one or more high capacity air compressors, through the manifold device connected to the external exhaust or through a sieve chest located inside each tank, to obtain ballast water from the ballast tanks. Drain to the outside. The deballasting rate is controlled by the mass flow rate of the air supply to empty the tank. In the case of ballasting, the water is either directly by the sea chest under sea water pressure (simply opening the sea chest shutoff and vent valves) or by a manifold device provided by a digestion pump, sea water lift pump or similar feeder. , Each tank is fed. For example, ballast water can be supplied from an external source, such as an installation vessel. Preferably, the sea chest, manifold, air source, vent shutoff valve is remotely operable.

The invention is described below with reference to the embodiments presented in the accompanying drawings.

1 is a plan view of a TLP cut along line 1-1 of FIG. 2, showing an internal ballast tank structure of a typical TLP and a pressure tank / common ballasting sea chest according to a first embodiment of the present invention.

2 is a side view of the TLP cut along line 2-2 of FIG.

3 is a side cross-sectional view of the TLP of FIG. 2 showing a ballast device with a second gas device optional for deballasting.

4 is a schematic diagram illustrating the ballast device of FIG. 2, with an optional bilge and ballast moving device for deballasting, in accordance with a first embodiment of the present invention;

5 is a plan view of a TLP cut along line 5-5 of FIG. 6, showing an internal ballast tank structure of a typical TLP and an individual ballast tank sheath chest, in accordance with a second embodiment of the present invention.

6 is a side view of the TLP cut along line 6-6 of FIG.

FIG. 7 shows a third embodiment of the present invention in which the ballast source may comprise, for example, a digestive main or seawater lift pumps.

Preferably, as shown in FIG. 1, a first embodiment of the ballast and deballast device according to the invention comprises a plurality of pillars 1, 2 extending upwardly from the hull 102 and the hull to support the deck 104. , 3, 4) for use in a tension fixed platform (TLP) 100. The hull 102 includes any number of internal ballast tanks, but fifteen internal ballast tanks are shown. There are four permanent ballast tanks 11, 21, 31, 41, the outermost tanks of the hull 102. The eleven tanks in the hull 102 are only temporarily used during the installation and dragging of the TLP towards the tendon. Four of these temporary ballast tanks 12, 22, 32, 42 are disposed adjacent to the inside of the four permanent ballast tanks 11, 21, 31, 41. Four temporary ballast tanks 13, 23, 33, 43 are arranged at the base of the pillars 1, 2, 3, 4, respectively. The three center tanks are the base center tank 5, the east wing tank 6, and the west wing tank 7. However, ballast / deballast apparatus and methods may be used for other vessels or TLP installations.

As shown in FIG. 2, in the first embodiment, the pressure tank 205 and the compressed gas source 200 included in the hull 102 are used. The pressure tank 205 communicates with the atmosphere through the pressure tank vent fluid path 210, the pressure tank vent shutoff valve 211, and the pressure tank vent hull discharge equipment 212. The pressure tank 205 is also flow connected to the sea chest 216 via the sea chest fluid path 214 and the sea chest shutoff valve 215. The pressure tank 205 has a compressed gas flow path 220 connected to a source of compressed gas 200 and includes a gas shutoff valve 221 for the pressure tank 205. Preferably, one or more high capacity air compressors 200 supply compressed gas, although other suitable sources may be used. Preferably, the pressure tank vent shutoff valve 211, the sea chest shutoff valve 215, and the compressed gas shutoff valve (s) 221 are all remotely operable. The pressure tank 205 is connected to each ballast compartment by a ballast flow path 275 and a ballast compartment shutoff valve 400. Preferably, all ballast tanks 31, 32, 33, etc. are independently in communication with the atmosphere. For example, in FIG. 2, each ballast tank 31, 32, 33, 7, 5, 6, 3, 13, 12, 11 has a vent flow path 230, external exhaust equipment 232, remotely actuated vent block. It is shown to include a valve 231.

2, the ballasting method according to the first embodiment, after filling the pressure tank 205 with seawater, pressurizing the pressure tank 205 with the compressed gas supply source 200, the selected ballast section Move sea water. For example, to fill the ballast compartment 11, all manifold shutoff valves 400 and gas valve (s) 221 are closed and the seawater shutoff valve 215 and pressurized tank vent shutoff valve 211 are opened. . The seawater enters the pressure tank 205 through the sea chest 216 and the flow path 214 under the influence of the head of the seawater. Once the pressure tank 205 is filled with seawater, the seawater shutoff valve and the pressure tank vent shutoff valve 211 are closed and the gas supply valve 211 is opened. The air vent shutoff valve 232 and the ballast compartment shutoff valve 400 corresponding to the ballast section 11 are opened. The compressed gas discharges the seawater of the pressure tank 205 and pushes the seawater into the ballast section 11. Like the pressure tank 205, the ballast compartment may be filled with seawater only by hydraulic pressure, but by providing the extruded gas source 200 in the pressure tank 205, it is possible for the ballasting of the tank to rise above sea level. The ballasting ratio is a function of the volume of the pressure tank 200 and the mass flow rate of the gas supplied by the gas source 200 for the discharge of the pressure tank 200.

3, one possible apparatus for debalancing the vessel 100 of the first embodiment is shown. The compressed gas source 200 is selectively connected to the individual ballast sections 31, 32, 33, etc. by a second gas flow path 240 and a second gas shutoff valve 241. If desired, a portion of the second gas flow path 240 may be combined with a portion of the vent flow path 230. For example, when the deballast of the compartment 11 is desired, the gas supply valve 221 corresponding to the ballast tank 11, the pressure tank vent valve 211, and the vent valve 231 are closed, and the ballast tank is closed. The sea chest shutoff valve 215 and the ballast section shutoff valve 400 corresponding to (11) are opened. The compressed gas discharges the ballast and pushes it out of the sea chest 216 through the manifold 275 and the pressure tank 205.

4 shows another apparatus and method for debalancing a vessel of the first embodiment. During ballasting, the pressure tank 205 uses four feed headers 280, 285, 290, and 295 to supply seawater to the supply manifold 275 as described above. These feed headers 280, 285, 290, and 295 subdivide the ballast tanks into four groups of opposing tanks and center base portions 5, 6, 7 of each quadrant. Preferably, each header has a shutoff valve 300, 305, 310, 315. Preferably, each ballast tank has a ballast compartment shutoff valve 400 for blocking ballast flow. Preferably, the header valves 300, 305, 310, 315 and ballast compartment shutoff valve 400 are remotely operable.

Preferably, the ballast movement between the deballasting and ballast tanks is performed using an optional moderate capacity centrifugal pump 250 (see FIG. 4). Each of the four feed headers 280, 285, 290, 295 is recombined at the manifold 298 to suction the ballast transfer pump 250 and the bilge. Preferably, the discharge of the pump 250 is captured by a return manifold 256, which returns a return shutoff valve 405 and four return headers for each ballast section for ballast movement. It is flow connected to each ballast tank via 320, 325, 330, 335, and is also fluidly connected to the external discharge pipe 258 via an external discharge valve 260 for deballasting. Preferably, feedback shutoff valve 405 and external discharge valve 260 are remotely operable. For example, to deballast the compartment 11, all ballast compartment shutoff valves 400 except the one corresponding to the ballast tank 11 are closed. Pump 250 inlet valve 251 and external outlet valve 260 are open. The ballast compartment 11 communicates with the atmosphere and the bilge, and the ballast transfer pump 250 is started to discharge the contents of the compartment 11 to the outside. Alternatively, for example, to move the ballast from the ballast tank 11 to the ballast tank 43, the valve arrangement except for the discharge valve 260 is closed in the same manner as described above, and the tank 43 The corresponding feedback shutoff valve 205 is opened. The ballast tank 43 communicates with air. The pump 250 now moves the contents of the ballast compartment 11 into the ballast compartment 43.

As shown in FIG. 5, a second embodiment of the ballast and deballast apparatus and method according to the present invention is preferably a plurality of pillars extending up from the hull 102 and the hull and supporting the deck 104. It is used in a tension fixed platform 100 that includes (1, 2, 3, 4). The hull 102 includes any number of internal ballast tanks, but sixteen internal ballast tanks are shown. There are four permanent ballast tanks 11, 21, 31, 41, the outermost tanks in the hull 102. The twelve tanks in the hull 102 are only temporarily used during the installation and dragging of the TLP towards the tendon. Four of these temporary ballast tanks 12, 22, 32, 42 are disposed adjacent to the inside of the four permanent ballast tanks 11, 21, 31, 41. Four temporary ballast tanks 13, 23, 33, 43 are arranged at the base of the pillars 1, 2, 3, 4, respectively. The four center tanks are the center base tanks 14, 24, 34, 44. However, ballast / deballast apparatus and methods may be used for other vessels or TLP installations.

Referring to FIG. 6, the second embodiment also includes a compressed gas source 200, and preferably includes one or more high capacity air compressors. The compressed gas source 200 is flow-connected to each ballast tank 31, 32, 33, etc. by a compressed gas manifold 502 and a separate gas shutoff valve 520 individually piped to each ballast tank in turn. Preferably, all ballast tanks 31, 32, 33, etc. are independently in communication with the atmosphere. For example, in FIG. 6, several ballast tanks 31, 32, 33, 34 with a vent flow path 514 (some coupled with a compressed gas line), external exhaust equipment 501, and vent valve 515. , 14, 13, 12, 11 are shown. Vent shutoff valve 515 and gas shutoff valve 520 may be remotely operable. Preferably, each ballast tank (31, 32, 33, etc.) is provided with a sea chest 505, respectively. The sea chest 505 is shut off with a valve 510, preferably the valve 510 is remotely operable.

Ballasting is performed by opening the sheath chest valve 510 and the vent valve 515 connected to a predetermined ballast tank. Then, the seawater pressure present in the cigar chest will fill the tank. The ballasting rate is determined by the flow resistance of the vent line, sea chest line, seawater pressure (or draft).

For a given ballast tank, deballasting is performed by closing the corresponding vent valve 515 and opening the corresponding compressed air supply valve 520 and the corresponding sheath chest valve 510. If compressed air is maintained at a pressure above the hydraulic pressure in the keel, the compressed air will enter the ballast tanks and move seawater out through the sea chest 505. The deballasting rate is determined by the flow resistance and air mass flow rate of the sea chest line. Preferably, when the TLP installation is complete, the sheath chest 505 inside the temporary ballast tank is sealed. Although deballasting has been described as a ballast section disposed below the sea line being discharged out of the sea chest 505, a ballast section (not shown) disposed above the seawater line may be compressed gas or It may similarly include a side shell valve and an external outlet entrance fluidly connected to the lower position of the ballast compartment such that the tank is drained quickly by pressure below atmospheric pressure / near atmospheric pressure.

7 shows a third embodiment of the present invention. In this device, ballasting and deballasting occurs through the ballasting manifold device 730, rather than an individual sea chest. Preferably, ballasting manifold 730 is disposed close to keel height. The ballasting manifold 730 is flow connected to the individual ballast tanks 11, 12, 14, 31, 32, 34 by means of shut-off valves 735 connected therebetween so as to be selectively shut off. In addition, the ballasting manifold 730 is flow-connected to the external discharge line 740 by an external discharge valve 745, so that the ballasting manifold 730 is upstream by the seawater shutoff valve 755. It is fluidly connected to the seawater body 750. Preferably, each ballast tank communicates with the atmosphere through the discharge opening 701, the vent shutoff valve 715, and the vent pipe 716, respectively. The compressed gas source 200, preferably a high capacity air compressor, is connected to each ballast tank, preferably by a compressed gas header 702, preferably the compressed gas header 702 is provided with a ballast section and vents. Any place between the shutoff valves 715 is in turn connected to the vent pipe 716. The compressed gas source 200 is selectively shut off from the ballast compartment by the gas shutoff valve 720. Preferably, the ballast compartment shutoff valve 735, the external drain valve (s) 745, the seawater shutoff valve (s) 755, the aeration shutoff valve 715, the gas shutoff valve 720 are all remotely operable. Do.

For a given ballast tank, ballasting is performed by opening the corresponding vent valve 715, the corresponding ballast compartment shutoff valve 735, and the upper seawater shutoff valve 755. The corresponding air supply valve 720 is closed. Ballast water is supplied through the top seawater body 750 by a firewater pump, a topside seawater lift pump, and other water sources to fill the ballast tanks. The ballast ratio is a function of the mass flow rate from the feed pump (s).

Deballasting a given ballast tank closes the vent valve 715 corresponding to the seawater shutoff valve 755, the external discharge valve 745, the corresponding ballast compartment shutoff valve 735, and the corresponding air. By opening the supply valve 720. If the air supply pressure is maintained higher than the discharge line head, the ballast water will be drained out through the external discharge line 740. The deballast ratio is a function of the flow resistance and air mass flow rate of the external exhaust manifold.

The ballast / deballast apparatus and method according to one or more embodiments of the present invention, when the tendon is about to be engaged during installation of the TLP, by quickly debalancing the vessel so as to quickly obtain the tendon tension required for fixing the tendon It is also possible to limit the latching tendency of the lock mechanism or slip mechanism of the < RTI ID = 0.0 > For example, while the chest chest shutoff valve (s) in the ballast compartment located below the seawater line is opened, compressed gas is used to quickly empty the filled tank, and the side shell or external drain in the ballast compartment located above the seawater line. The valve makes it possible to quickly discharge the ballast water at or near atmospheric pressure. Rapid deballasting minimizes latching of the locking mechanism.

While some embodiments of the invention have been described in detail, the invention is not limited to the embodiments described. Modifications and variations of the embodiments described above may occur to those skilled in the art. As described herein, such changes and modifications fall within the scope and spirit of the present invention.

Claims (16)

As a method of de-ballasting the vessel 100 floated in the sea, Providing fluid communication between an interior position of a lower portion of a ballast tank 11 disposed on the hull 102 of the vessel and an exterior of the vessel; Providing fluid communication between the ballast tank and the compressed gas source 200; Discharging the liquid ballast of the ballast tank to the sea by the compressed gas How to de-ballasted a ship in the sea comprising a. The method of claim 1, wherein the step of providing fluid communication between the inner position of the lower portion of the ballast tank disposed on the hull of the vessel and the outside of the offshore platform, Between the inner position of the lower portion of the ballast tank and the sea chest carried by the hull under the waterline and open sea and in open communication, a valve for opening fluid communication. step How to de-balancing a ship that is floated in the sea. 3. The method of claim 2, wherein the sea chest (505) is disposed inside the ballast tank. 3. The sea balance vessel of claim 2 wherein the sea chest 216 is disposed outside the ballast tank and the pressure tank 205 is flow connected between the water inlet valve and the sea chest. How to Ting. The method of claim 2 wherein the step of opening the valve is performed by remote operation. The method of claim 1, wherein providing fluid communication between an inner position of a lower portion of the ballast tank and an outer portion of the vessel comprises: Opening a connected valve for fluid communication between the inner position of the lower portion of the ballast tank and an external discharge 740 exiting the hull at a point above the seawater line. How to de-balancing a ship that is floated in the sea. As a way to debalance ships in the sea, Making an upper position inside the ballast tank 11 disposed on the hull 102 of the ship communicate with the outside of the ship; Filling the pressure tank 205 with a liquid ballast, Fluidly connecting the pressure tank 205 to the compressed gas source 200; Fluidly connecting a lower position inside the pressure tank to the ballast tank; Discharging the fluid ballast of the pressure tank to the ballast tank by the compressed gas How to de-ballasted a ship in the sea comprising a. The method of claim 7, wherein the step of fluidly connecting the lower position inside the pressure tank to the ballast tank, Opening a ballast compartment shutoff valve 400 connected in fluid communication between the ballast tank and the lower position inside the pressure tank. How to de-balancing a ship that is floated in the sea. 10. The method of claim 8, wherein the step of opening the ballast compartment shutoff valve is performed by remote operation. A system comprising a hull (102) having a water resistant ballast section (11), the ballasting and deballasting a ship (100) floating in the sea, Compressed gas supply source 200 disposed on the vessel, A gas flow path connected between said compressed gas source and said ballast compartment, A gas shutoff valve connected to the gas flow path; A ballast flow path connected between a bottom location within the ballast compartment and a sea chest carried by the hull and opened out of the vessel below the seawater line, A shutoff valve connected to the ballast flow path Including; The ballasting and deballasting system uses a gas from the compressed gas source via the gas flow path to debalance the vessel so that the liquid ballast in the ballast compartment passes through the ballast flow path. A system for ballasting and deballasting a ship in a sea that is designed and arranged to be discharged to the outside of the sea. The system of claim 10, wherein the ballasting and deballasting system comprises: A ballast compartment vent flow path connecting between an upper position inside said ballast compartment and a first external release of said vessel at said position above a sea water line, A ballast compartment vent shutoff valve connected to the ballast compartment vent flow path More, The ballasting and deballasting system utilizes a liquid ballast from the sea via the ballast flow path to ballast the vessel, through which the gas in the ballast compartment flows through the ballast compartment vent flow path. A system for ballasting and deballasting a ship on the sea that is designed and arranged to be discharged to the outside. 12. The system of claim 11, wherein the sea chest (505) is disposed in the ballast compartment. The system of claim 11, wherein the ballasting and deballasting system comprises: A pressure tank 205 disposed outside the hull of the ballast section, A sea chest shutoff valve 215 connected to the ballast flow path 214 between the pressure tank and the sea chest; A pressure tank vent flow path 210 connecting between an upper position inside the pressure tank and an upper position of the second external discharge 212 opened outward from a position above the sea water line; Pressure tank vent cutoff valve 211 connected to the pressure tank vent flow path More, The pressure tank is connected to the ballast flow path between the shutoff valve 400 and the sea chest 216, and the pressure tank is connected to the flow path between the gas shutoff valve 221 and the ballast section. And a gas flow path between the pressure tank and the ballast compartment, coupled to the ballast flow path between the pressure tank and the ballast compartment, comprising a shutoff valve 400 connected thereto. Forms a path 275, The ballasting and deballasting system includes the liquid via the ballast flow path 214 between the sea chest 216 and the pressure tank 205 from the sea to debalance the vessel. By using a ballast, the gas of the pressure tank is discharged to the outside via the pressure tank vent flow path 210, the gas flow between the compressed gas supply source and the pressure tank from the compressed gas supply source 200 Using gas via path 220, ballasting and dewatering ships at sea where the liquid ballast of the pressure tank is designed and arranged to be discharged to the ballast compartment via the common flow path 275. Ballasting system. The system of claim 13, wherein the ballasting and deballasting system comprises: A second gas flow path 240 connected between the source of compressed gas and the ballast compartment and bypassing the pressure tank and the common flow path 275; A second gas shutoff valve connected to the second gas flow path More, The ballasting and deballasting system is designed such that, for deballasting, liquid ballast in the ballast compartment is discharged to the outside via the common flow path 275 using gas from the compressed gas source. And a system for ballasting and deballasting a ship in the ocean that is arranged. The system of claim 12, wherein the ballasting and deballasting system comprises: Each further comprises a plurality of ballast compartments 11, 12, 13 with a sea chest 505 disposed therein, each of the sea chests being positioned in a lower position of the ballast compartment on which it is disposed by a sea chest shutoff valve 510. A system for ballasting and deballasting vessels that are floating in the sea. 14. The system of claim 13, wherein the ballasting and deballasting system further comprises a plurality of ballast compartments (11, 12, 13), each of the plurality of ballast compartments being connected to flow connected connection ballast compartments at their lower positions. And a valve (400), each of the ballast compartment shutoff valves being ballasted and deballasted at sea, wherein the ballast compartment shutoff valve is fluidly connected to a lower position of the pressure tank (205).

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