KR20100041299A - Drillilng platform - Google Patents

Abstract

PURPOSE: A drilling platform is provided to compensate for various directions of fluctuations through efficient down motion of a riser. CONSTITUTION: A drilling platform comprises a riser tensioner and a down tension application structure. The riser tensioner is arranged around a drilling pipe(28). The down tension application structure is coupled with a riser(22) and applies the force in a drilling direction to the riser, as a result of which the down tension application structure enables the riser to be displaced in the drilling direction or the rotational fluctuation of a ship to be compensated. The down tension application structure comprises wires(20,36) coupled with the riser and a winch which winds or unwinds the wires to apply the force in the drilling direction to the riser.

Description

Drilling platform {DRILLILNG PLATFORM}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to drilling platforms for use in drilling ships, and more particularly to drilling platforms having increased freedom of movement to compensate for movement in various directions of the platform or vessel.

Drilling pipes or drilling vessels (hereinafter collectively referred to as "drilling platforms") use drilling pipes for drilling. While the drilling pipe is drilling the sea floor, a mud or oily fluid (drilling fluid) is generated, which surrounds the drilling pipe to prevent it from being exposed to the sea and causing contamination. A riser, which is a shaped structure, is disposed. The riser includes a riser holder to control the position of the riser, which will be described with reference to FIG. 1.

Referring to FIG. 1, a conventional drilling platform includes a drilling pipe 108 for drilling and a riser 102 arranged to surround the drilling pipe 108. Drilling pipes 108 and risers 102, in the case of ships, are arranged in moon pools 106 and applied to the drilling position. The drilling pipe 108 is also fixed by a derrick 130.

During drilling, the ship or platform on which the derrick 130 is installed may be rocked by blue or wind. In spite of this rocking, the riser 102 must be kept in a constant position to cause leakage of the drilling and drilling fluid by the drilling pipe 108. Prevention can be made smoothly. To this end, a wire 120 supported by the pulleys 110, 112, 114 is fixed to the riser holder 104 included in the riser 102. The pulley 110 of one of the pulleys 110, 112, 114 is fixed to the platform by a hydraulic cylinder 116. Thus, if the platform swings, the swing can be compensated for by contracting or expanding the hydraulic cylinder 116 in the opposite direction of the swing. Thus, riser 102 may be maintained in a position controlled by wire 120.

However, the conventional drilling platform has a problem that the downward movement of the riser 102 cannot be easily performed. For example, if it is necessary to move the riser 102 downward to compensate for the platform to heave upwards, the drilling platform of FIG. 1 simply pulls the pulley 110 by contracting the hydraulic cylinder 116. By moving downward, the tension of the wire 120 is reduced. However, since the downward movement of the riser 102 following the wire 120 tension reduction is made only by the load of the riser 102, it is difficult to control the rapid and accurate downward movement. In particular, since the drilling fluid is filled inside the riser 102, the buoyancy force of the riser 102 actually reduces the load on the wire 120, which makes the riser 102 more difficult to move downward.

In addition, the conventional drilling platform cannot control the movement of the riser 102 with respect to the bow to lateral rotational fluctuation (roll, lateral rotational fluctuation: pitch) of the vessel, and thus the rotation of such a vessel There is a problem that fluctuations cannot be compensated.

The present invention has been made in view of the above-described problems, and an object of the present invention is to provide a drilling platform that can more efficiently perform the downward movement of the riser.

It is also an object of the present invention to provide a drilling platform with increased freedom of movement to compensate for platform swing in various directions.

In order to achieve the above object, according to one aspect of the present invention, in a drilling platform comprising a riser-tensioner disposed around a drilling pipe for drilling, a riser is drilled. In order to displace in the plane direction or to compensate for the rotational fluctuation of the vessel, a drilling platform is provided that is coupled to the riser and includes a downward tension applying structure for applying a force in the drilling surface direction to the riser.

In one embodiment, the downward tension applying structure may comprise a wire coupled to the riser and a winch that may wind or unwind the wire to apply a force in the drilling surface direction to the riser.

In another embodiment, the downward tension applying structure includes a wire coupled to the riser, an anchor to secure the wire, and a pulley supporting the wire between the anchor and the riser, wherein the pulley is in motion. A force can be applied to the riser by this. Preferably, the pulley is moved by a hydraulic cylinder.

The riser tensioner includes two or more of the downward tension applying structures, and each downward tension applying structure can be controlled to apply a different strength of force to the riser.

According to the present invention, it is possible to more efficiently perform the downward movement of the riser, thereby making it possible to compensate for platform fluctuations in various directions and to increase the stability of the drilling.

EMBODIMENT OF THE INVENTION Hereinafter, specific embodiment of this invention is described with reference to attached drawing. In this specification, the term “drilling platform” is used to include vessels and other equipment in which drilling pipes and risers are installed to perform drilling.

2 shows a drilling platform according to one embodiment of the invention. The drilling platform of this embodiment includes a drilling pipe 28 for drilling and a riser 22 having a pipe shape surrounding the drilling pipe 28 and preventing leakage of the drilling fluid. Typically, one riser 22 has a length of 75 to 90 ft (about 23 to 27 m) and may have a load of 200 kg / m. Multiple risers may be used in connection. In addition, the drilling platform of the present embodiment includes the swing of the platform (up and down swing: heave, bow swing: surge, side swing: sway, upward swing: yaw, bow swing: roll, lateral swing: pitch) It includes a structure for moving the riser 22 to compensate for all.

Specifically, the drilling platform includes a wire 20 and pulleys 10, 12, 14 supporting the wire 20 to apply tension upwardly (ie, opposite the drilling surface) to the riser 22. do. The wire 20 is fixed to the drilling floor by an anchor (not shown) and at the same time to the riser holder 24 installed in the riser 22. In addition, the wire 20 is displaced by the pulleys 10, 12, 14 so that the tension is transmitted to the riser holder 24. At this time, the pulley 10 may be coupled to the hydraulic cylinder 16 to move up and down. The length of the wire between the pulley 12 and the anchor is changed by the vertical movement of the pulley 10, which in turn causes tension to be applied to the riser 22. In particular, when the riser 22 needs to move upward, the pulley 10 is also displaced upward to apply tension to the riser 22. The displacement range of the wire 20 may be about 15 m (50 ft), thereby applying a force of about 1,400 tons (3,200,000 lbs) to the riser 22.

On the other hand, the drilling platform includes a downward tension applying structure for displacing the riser 22 in the drilling surface direction or applying downward force (ie, drilling surface direction) to the riser 22 to compensate for the rotational fluctuation of the vessel. do. The downward tension applying structure of the present embodiment includes a wire 36 coupled to the riser 22, and a winch 32 which can wind or unwind the wire to apply a force in the drilling surface direction to the riser 22. Include.

Wire 36 is coupled to riser 22 through riser holder 24 similar to wire 20. The wire 36 is also arranged to be wound around the winch 32. In the case of a ship, the winch 32 can wind or unwind the wire 36 by being fixed by the support part 34 fixed to the door pull 26. Therefore, when the riser 22 needs to move downward, the winch 32 winds up the wire 36, and the downward tension acts on the riser 22. As shown in FIG.

According to this embodiment, when the riser must move upwards (for example, when the drilling platform swings downward), the hydraulic cylinder 16 expands and displaces the pulley 10 upwards. Thus, the length of the wire 20 between the anchor and the pulley 12 becomes long, and upward tension acts on the riser 22 through the pulley 14 and the riser holder 24. At the same time, winch 32 releases wire 36 to allow upward movement of riser 22. The winch 32 unwinding the wire 36 may be powered or passive, simply by the movement of the riser 22.

On the contrary, when the riser 22 must move downwards (for example, when the drilling platform swings upward), the winch 32 winds the wire 36 and applies downward tension to the riser 22. At the same time, the hydraulic cylinder 16 contracts, the pulley 10 is displaced downward, and the length of the wire 20 between the anchor and the pulley 12 is shortened, so that the upward tension applied to the riser 22 is released. do. Although the contraction of the hydraulic cylinder 16 may be active by control, the downward tension exerted by the wire 36 may be transmitted to the wire 20 to be manually contracted.

Thus, unlike the prior art, since the downward movement of the riser 22 is made not only by the load of the riser 22 itself but also by the tension of the wire 36 by the winch 32, Downward movement can be made quickly and accurately.

On the other hand, in this embodiment, the winch 32 and the wire 36 which are the downward tension application structure can be arrange | positioned at two or more around the riser 22, and two pairs can be arranged in the figure at right and left. By controlling each winch 32 to apply different tension to the riser 22, not only the simple downward movement of the riser 22 but also fine displacement can compensate for the rotational fluctuation of the ship, thereby increasing the stability of the ship. You can do it.

In other words, the fluctuations of the drilling platform in various directions, in the case of ships, the up and down fluctuations, the bow side surge, the side swing, as well as the forward roll and the lateral pivot ) Or upward rotation oscillation (yaw), it is possible to precisely compensate for the fluctuations in various directions and to maintain the riser 22 in a constant position. In particular, it is also possible to accurately compensate for all the fluctuations of the ship by precisely compensating the bow roll and the lateral pitch.

Specifically, in two or more downward tension applying structures arranged in engagement with the outer circumferential surface of the riser, the respective downward tension applying structures are controlled differently from each other, whereby different tensions are applied to each riser 22, thereby raising the riser ( By allowing 22 to be rotated finely, it is possible to compensate for rotational fluctuation of the ship.

Additionally or alternatively, two or more hydraulic cylinders 16 may be arranged and each hydraulic cylinder 16 may be independently controlled to help fine tune the riser 22.

Meanwhile, although the winch 32 is illustrated as being fixed to the door pool 26 in FIG. 2, this is only an example, and another fixing position may be further provided by installing a plurality of pulleys and fixing the winch 32 to the drilling floor. It is also possible to use.

3 shows a drilling platform according to another embodiment of the invention. In the present embodiment, the same reference numerals are used for the same components as in the previous embodiment, and detailed description thereof is omitted.

The drilling platform includes a drilling pipe 28 and a riser 22 for drilling. In addition, the drilling platform of the present embodiment includes a structure for moving the riser 22 to compensate for rocking of the platform. The drilling platform includes a wire 20 and pulleys 10, 12, 14 supporting the wire 20 to apply upward tension to the riser 22. The pulley 10 may be coupled to the hydraulic cylinder 16 to move up and down, thereby applying tension to the riser 22.

The drilling platform includes a downward tension applying structure coupled to the riser to apply downward force (ie, drilling surface direction) to the riser to displace the riser in the drilling surface direction or to compensate for the rotational movement of the vessel. The downward tension applying structure of the present embodiment includes a wire 36 coupled to the riser 22, an anchor 38 for fixing the wire, and a pulley for supporting the wire 36 between the anchor 38 and the riser 22. (42). The tension is applied to the riser 22 by the movement of the pulley 42. In this embodiment, the pulley 42 is moved left and right by the hydraulic cylinder 44. As shown in FIG. On the other hand, the pulleys 46 and 48 are further provided to transfer the tension to the riser 22 by the movement of the pulley 42. These pulleys 42, 46, 28 and the hydraulic cylinder 44, in the case of a ship can be fixed to the inner wall of the door pool 26. However, it will be apparent to those skilled in the art that the position of the fixed installation may differ depending on the field of application or the number of pulleys and the like. With this configuration, the up-and-down movement of the pulley 42 changes the length of the wire 36 between the anchor 38 and the pulley 46, thereby tensioning the riser 22 through the pulley 48. Is applied.

According to this embodiment, when the riser must move upwards (for example, when the drilling platform swings downward), the hydraulic cylinder 16 expands and displaces the pulley 10 upwards. On the contrary, when riser 22 must move downwards (for example, when the drilling platform swings upward), hydraulic cylinder 44 expands to direct pulley 42 toward riser 22 in the drawing. Move it. Accordingly, the length of the wire 36 between the anchor 38 and the pulley 46 becomes long, and downward tension acts on the riser 22 through the pulley 48.

Thus, unlike the prior art, since the downward movement of the riser 22 is made not only by the load of the riser 22 itself but also by the tension of the wire 36 by the movement of the pulley 42, the riser 22 The downward movement of can be made quickly and accurately.

On the other hand, in the present embodiment, the downward tension applying structure including the hydraulic cylinder 44, the pulley 42 and the wire 36 can be arranged at least two around the riser 22, two pairs on the left and right in the drawing. have. As a result, in two or more downward tension applying structures which are disposed in engagement with the outer circumferential surface of the riser, the respective downward tension applying structures are controlled differently from each other, whereby different tensions are applied to the respective risers 22, thereby raising the riser 22. By allowing to rotate finely, it is possible to compensate for the rotational fluctuation of the ship.

The present invention has been described above with reference to specific embodiments of the present invention, but this is only illustrative and does not limit the scope of the present invention. Those skilled in the art can change or modify the described embodiments without departing from the scope of the present invention. Each component described herein may be implemented or replaced by a variety of known elements, each may be implemented separately, or two or more may be integrated into one. For example, the pulley described in the present specification may be implemented in various forms, such as a feed pulley, a movable pulley, and a double pulley. It is also possible to be replaced by known power transmission means as necessary. Therefore, the scope of the invention should be defined by the appended claims and their equivalents, rather than by the described embodiments.

1 shows a conventional drilling platform.

2 shows a drilling platform according to one embodiment of the invention.

3 shows a drilling platform according to another embodiment of the invention.

<Explanation of symbols for the main parts of the drawings>

10, 12, 14, 42, 46, 48: pulley 16, 44: hydraulic cylinder

20, 36: wire 22: riser

24: riser holder 28: drilling pipe

Claims (5)

In a drilling platform comprising a riser-tensioner disposed around a drilling pipe for drilling, One or more downward tension applying structures coupled to the riser for applying a force in the drilling surface direction to the riser to displace the riser in the drilling surface direction or to compensate for the rotational fluctuation of the vessel. Drilling platform. The method of claim 1, The downward tension applying structure is A wire coupled to the riser, A winch for winding or unwinding the wire to apply a force in the direction of the drilling surface to the riser; Drilling platform. The method of claim 1, The downward tension applying structure is A wire coupled to the riser, An anchor for fixing the wire, A pulley for supporting the wire between the anchor and the riser, Force is applied to the riser by the movement of the pulley Drilling platform. The method of claim 3, wherein The pulley is moved by a hydraulic cylinder Drilling platform. The method of claim 1, At least two downward tension application structures, each downward tension application structure being controllable to apply a different strength of force to the riser. Drilling platform.

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