KR20160056147A - Sea Water Flow Attenuation Device for Drillship - Google Patents

Abstract

A seawater flow attenuation device for a drillship is disclosed. The seawater flow attenuation device for a drillship comprises: a floating body moving along with the flow of seawater; a connection line of which one end is fixed and the other end is connected to the floating body; a tension measuring sensor which measures the size and speed of the seawater flow by measuring the size of the tension of the connection line and the change speed of the size; and a wedge member which is vertically moved along the inner wall surface of a moon pool according to the volume and speed of the seawater flow measured by the tension measuring sensor. Therefore, the present invention attenuates the seawater flow or switches the direction of the seawater as the seawater collides with the inclined surface of the wedge member.

Description

Sea Water Flow Attenuation Device for Drillship "

The present invention relates to a seawater flow damping device for a drill ship, and more particularly, to a seawater flow damping device configured to reduce the seawater flow occurring in a recess of a door.

Along with the development of submarine mining technology, drilling lines have been developed with drilling facilities suitable for marginal field or deep sea oil development. Conventional submarine drilling has been mainly used for a rig ship or a rigid platform for underwater drilling that can be sailed only by another tugboat and performs submarine drilling with anchorage at one point of the sea using a mooring device. In recent years, drillships equipped with advanced drilling equipment and manufactured in the same form as the ship have been developed and used for underwater drilling so that they can navigate by their own power.

In such an offshore structure for underwater drilling, a moon pool is formed for accessing various equipment for drilling. The moon pool is a rectangular parallelepiped or cylindrical space formed so as to penetrate vertically between the deck and the bottom of the hull. to be. In addition, a marine structure having a two-tier structure has an auxiliary space formed in the drum for temporarily lowering drilling equipment such as BOP (Blow Out Preventer), which is called a recess.

However, the conventional drill rig has a problem that the seamen working on the drilling equipment or deck installed on the top of the drum can be damaged by the seawater flow generated in the recess.

Hereinafter, referring to FIG. 1, a principle of generating a large sea water flow in the recess will be described.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a side view partially showing a drill rig with a recess in a conventional artwork. FIG.

Sea waves generated by the wind are always present outside the hull 1 and seawater in the interior of the hatchery 2 receives the energy from the sea waves outside the hull 1 to generate the wave 5a.

Sea waves can be classified into deep-sea waves and deep-sea waves depending on the relationship between depth and wavelength. Sea waves in the case where the water depth is deeper than one-half of the wavelength is called deep water waves and the sea depth is shallower than one- Is called a deep sea wave.

The deep-sea waves are also called longwaves, and water particles are subjected to elliptical motion by the frictional force of the seabed since they are affected by the seabed. The propagation velocity of the shallow wave is irrelevant to the wavelength and is related only to the depth of water. Therefore, the progressive velocity of the shallow wave is slowed down as the depth becomes shallower. As the propagation speed of the deep sea wave slows down, the kinetic energy that is reduced changes to the potential energy, so that as the coastal wave approaches the coast, the wavelength becomes shorter and the wave height becomes higher.

For example, in the case of a tsunami that has a characteristic of shallow waves, if a tsunami occurs with an extremely long wavelength of 100 to 200 kilometers in the distant sea due to an earthquake, However, as the tsunami approaches the shore, the depth of the tsunami becomes shallower, slowing down the process, reducing the wavelength to several kilometers, and increasing the tsunami to tens of meters.

When the sea waves 5a generated in the interior space 2 have a characteristic of a deep sea wave, the depth of the recess 3 becomes shallower, so that the sea wave in the recess 3 has a higher wave height . The seawater flow 5b in the recess 3 rises on the inside wall surface 2a of the interior space of the recess 3 and the sea water flow 5b in the interior of the recess 2 having the high crest causes a large sea water flow 5b, Damage to crew working on equipment (4) or hull (1).

Hereinafter, the interior wall surface 2a of the interior wall means the inner wall surface of the interior wall 2 connected to the recess 3. [

SUMMARY OF THE INVENTION The present invention has been made to solve such conventional problems and it is an object of the present invention to provide a seawater flow attenuation device for a drill rig that is operated when a sea- And the like.

According to an aspect of the present invention, there is provided a seawater flow damping apparatus installed on a drill ship, comprising: a float moving according to seawater flow; A connecting line having one end fixed and the other end connected to the float; A tension measuring sensor for measuring the magnitude and speed of the seawater flow by measuring the rate of change of the magnitude and magnitude of the tension of the connecting line; And a wedge member moving up and down along the inner side wall of the door according to the magnitude and velocity of the seawater flow measured by the tension measuring sensor, wherein the seawater flow is attenuated by the inclined surface of the wedge member, , A seawater flow damping device for a drill ship is provided.

The float may include a cushioning material capable of absorbing impacts due to seawater flow.

The fixed end of the connection line may be connected to one of the inner side wall of the template, the lower structure of the recess, and the tension measurement sensor.

The connecting line may be a cable or a spring.

The tension measuring sensor may be installed such that an upper surface of the tension sensor is positioned on the same plane as the upper surface of the recess bottom structure.

The wedge member can be lowered when the size or speed of the sea water flow measured by the tension measuring sensor is equal to or greater than a preset value and the size or speed of the sea water flow measured by the tension measuring sensor after falling is set in advance If it falls below the set value, it can rise and return to its original position.

The wedge member may have a width substantially equal to the width of the door frame and an inclined surface may be formed in a direction facing the recess.

The wedge member may include a cushioning material capable of absorbing an impact caused by the collision of the seawater flow.

And a guide member for guiding the wedge member to move up and down.

The guide member may be vertically installed on both sides of the inner side wall of the door, and the guide member may be a rail.

According to another aspect of the present invention, there is provided a door frame formed on a drill ship, including: a recess formed in a stepped shape so as to temporarily lower a drilling rig; And a wedge member moving up and down along a rail provided on the inner side wall of the door, wherein the wedge member is lowered when the seawater flow inside the recess is equal to or greater than a predetermined value.

According to the seawater flow damping apparatus of the present invention, it is possible to prevent the seawater flow from reaching the hull by switching the direction of the flow ascending on the inner side wall of the platform or attenuating the flow, It has the effect of preventing the damage to the equipment or the risk to the crew.

FIG. 1 is a side view schematically showing a drill rig with a recess in a door frame according to a conventional technique.
2 is a side view schematically illustrating a first state of a seawater flow damping device according to a preferred embodiment of the present invention.
3 is a side view schematically illustrating a second state of a seawater flow damping device according to a preferred embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In addition, the following examples can be modified in various forms, and the scope of the present invention is not limited to the following examples.

FIG. 2 is a side view schematically illustrating a first state of a seawater flow damping device according to a preferred embodiment of the present invention. FIG. 3 is a schematic view of a second state of a seawater flow damping device according to a preferred embodiment of the present invention. As shown in Fig.

2 and 3, the seawater flow damping device of the present embodiment includes a float 10 moving according to a seawater flow 5b; A connecting line 20 connected to the float 10; A tension measuring sensor 30 for measuring the tension of the connecting line 20; And a wedge member (40) moving up and down along the inner side wall surface (2a) according to the value of the tension measuring sensor (30).

The float 10 of the present embodiment is made to have a density smaller than that of sea water so that it floats on the sea surface. When the seawater flow 5b is generated, the float 10 swings up and down according to the seawater flow 5b. When the float 10 rises, the connection line 20 connected to the float 10 expands, The connecting line 20 is reduced. When the seawater flow 5b is increased, the float 10 is raised as much as it is and the tensile force applied to the connecting line 20 is also increased.

The float 10 is preferably spherical so as to maintain its original shape even if it is worn by seawater for a long time, but its shape is not limited. It is also preferable to include a cushioning material so as not to be impacted to the hull 1 even if it is shaken by the seawater flow 5b and hit the inside wall surface 2a or the recess bottom structure 3a.

The connecting line 20 of the present embodiment is connected at one end to the float 10 and at the other end to the inside wall 2a or the recess bottom 3a or directly to the tension measuring sensor 30 The other end of the connecting line 20 connected to the interior wall surface 2a of the interior wall of the door frame 2a, the recessed substructure 3a or the tension measuring sensor 30 is fixed and the other end of the connecting line 20 connected to the float 10 is fixed The part moves together with the movement of the float 10.

As the seawater flow 5b becomes larger, the float 10 moves up and down more greatly, so that the magnitude of the tension of the connecting line 20 and the speed at which the tension changes are also accelerated. The connecting line 20 may be a cable, a spring, or the like.

The tension measuring sensor 30 of the present embodiment measures the size and speed of the seawater flow 5b by measuring the magnitude and magnitude of the tension of the connecting line 20.

The tension measuring sensor 30 is installed at a position where it is less likely to be damaged by the corrosion caused by seawater and does not interfere with the movement of the drilling rig 4 and can receive less impact by the seawater flow 5b As an example, as shown in Figs. 2 and 3, the upper surface of the inside of the inside surface 2a of the interior of the interior of the interior of the interior of the interior of the interior can be provided so as to be coplanar with the upper surface of the recessed substructure 3a.

The wedge member 40 of this embodiment has a width substantially equal to the width of the door frame 2 and one side surface is formed vertically so as to be in contact with or facing the inside surface 2a of the door frame, As shown in FIG. Therefore, the seawater flow 5b generated in the recess 3 can be prevented from being diverted or attenuated to reach the hull 1 after it collides with the inclined surface of the wedge member 40.

When the hull receives a wave from the athlete, the bottom of the bow is subjected to the impact of a strong wave, and the hull is subjected to a rapid vibration in a short cycle, which is called slamming. Slamming occurs especially in the case of a high speed ship, but in order to prevent the impact force by slamming from damaging the hull, the bottom of the high speed ship is often formed into a wedge shape. This is because the impact force when the wedge shape hits the water is significantly lower than the impact force when the wedge shape hits the flat plate.

Therefore, the seawater flow damping device of the present embodiment includes the wedge member 40 which moves up and down the inside wall surface 2a of the interior space so that the seawater flow 5b can hit the slope, not the flat surface.

The wedge member 40 of the embodiment moves up and down according to the size and velocity of the seawater flow 5b measured by the tension measuring sensor 30. [ That is, the size and speed of the seawater flow 5b, which can damage the drilling equipment 4 or the crew, are set in advance in the tension measuring sensor 30, and the size and speed of the seawater flow 5b The wedge member 40 descends along the inside wall surface 2a of the inside of the door, as shown in Fig. The seawater flow 5b strikes the inclined surface of the wedge member 40 descending downward to change the direction and attenuate a part thereof. When the seawater flow 5b is kept quiet and the size and speed of the seawater flow 5b become less than the set value, the wedge member 40 ascends to the home position.

A guide member 50 such as a rail for guiding the wedge member 40 to move up and down along the inside wall surface 2a of the inside wall surface 2a can be vertically installed on both sides of the inside wall surface 2a. The wedge member 40 preferably includes a cushioning material so that the impact caused by the collision of the seawater flow 5b with the wedge member 40 is not transmitted to the hull 1.

The seawater flow damping apparatus of the present invention has an advantage that the wedge member 40 is only hindered when the seawater flow 5b is heavy, so that it does not interfere with the drilling operation.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention. It is.

1: Hull 2:
2a: Inner wall face of the interior wall 3:
3a: recesses infrastructure 4: drilling rig
5a: Sea wave 5b: Sea water flow
10: float 20: connection line
30: tension measuring sensor 40: wedge member
50: Guide member

Claims (11)

1. A seawater flow damping device installed on a drill rig,
Float moving with seawater flow;
A connecting line having one end fixed and the other end connected to the float;
A tension measuring sensor for measuring the magnitude and speed of the seawater flow by measuring the rate of change of the magnitude and magnitude of the tension of the connecting line; And
And a wedge member moving up and down along the inner side wall of the door according to the size and speed of the seawater flow measured by the tension measuring sensor,
Wherein the seawater flow is attenuated or diverted by colliding with an inclined surface of the wedge member. The method according to claim 1,
Wherein the float includes a buffer material capable of absorbing an impact due to seawater flow. The method according to claim 1,
Wherein a fixed end of the connecting line is connected to one of the inner side wall of the tabletop, the bottom structure of the recess and the tension measuring sensor. The method according to claim 1,
Wherein the connecting line is a cable or a spring. The method according to claim 1,
Wherein the tensile force measuring sensor is installed inside the inner side wall of the door so that its upper surface is coplanar with the upper surface of the recessed lower structure. The method according to claim 1,
The wedge member
When the size or speed of the sea water flow measured by the tension measuring sensor is equal to or greater than a predetermined value,
And when the magnitude or velocity of the seawater flow measured by the tension measuring sensor is lower than a predetermined value, it returns to the original position and returns to its original position. The method according to claim 1,
Wherein the wedge member has a width approximately equal to a width of the door frame and an inclined surface is formed in a direction facing the recess. The method according to claim 1,
Wherein the wedge member comprises a cushioning material capable of absorbing an impact as a seawater flow impinges upon it. The method according to claim 1,
Further comprising a guide member for guiding the wedge member to move up and down. The method of claim 9,
Wherein the guide member is vertically installed on both sides of the inner side wall of the door,
Wherein the guide member is a rail. In the case of the formwork formed on the drill ship,
A recess formed to be stepped so that the drilling rig can be temporarily lowered; And
And a wedge member moving up and down along a rail provided on the inner side wall of the door,
Wherein the wedge member descends when the seawater flow in the recess is greater than or equal to a predetermined value.

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