KR101313809B1 - Jack-up platform - Google Patents

Abstract

PURPOSE: A jack-up platform is provided to prevent the sea-bed from being scoured and to prevent a hull from overturning due to external environmental loads by improving a gripping force about the soil of the sea-bed. CONSTITUTION: A jack-up platform comprises a hull, a plurality of jack-up leg parts (300), a spud can (400), and a scouring preventive unit (500). The jack-up leg parts are mounted on the hull. The jack-up leg parts penetrate the hull and move up and down. The spud can is positioned in the lower part of the jack-up leg part. The spud can is buried in the sea-bed when the jack-up leg part descends. The scouring preventive unit is adjacent to the lower part of the jack-up leg part. The scouring preventive unit prevents the sea-bed around the jack-up leg part from being scoured due to ocean currents when the spud can is buried in the sea-bed.

Description

Jack-up Platform {JACK-UP PLATFORM}

The present invention relates to a jack up platform, and more particularly, to a jack up platform that can prevent the hull overturning due to external environmental load.

As additional demand for oil and gas stored offshore increases, the exploration and drilling of offshore resources are increasing.

Accordingly, an approach has been taken to build a mobile jackup platform for use in offshore resource exploration and drilling.

Conventional jack-up platforms have a floating hull and a plurality of jack-up legs which are located above the hull during the movement of the hull and are embedded in the sea floor through the hull during exploration and drilling operations.

In other words, when the jack-up platform reaches a position for exploration and drilling of resources such as oil and gas, the jack-up platform is lowered so that the jack-up leg is buried on the sea floor. It is fixed to the face.

When the resource exploration and drilling is completed, the jack-up leg is raised, and the hull is floated on the sea surface to be moved to another place.

As such, the increase in exploration and drilling activities of offshore oil and gas, and the mobility of jack-up platforms increase the frequency of resource exploration and drilling in offshore.

However, in the offshore exploration and drilling activities, offshore drilling equipment such as jack-up platform is frequently damaged due to offshore environmental factors.

That is, when one or more of the jack-up legs buried in the sea floor due to wind or ocean currents buckles or suddenly digs deep into the bottom of the sea floor, or the jack-up platform is overturned by the scour phenomenon around the jack-up bridge. Are often a problem that occurs.

Thus, more stable offshore platform structures must be provided for exploration and drilling of resources offshore.

Therefore, the technical problem to be solved by the present invention is to provide a jack-up platform that can prevent the hull overturning due to the external environmental load by preventing the bottom scour and at the same time improve the gripping force on the bottom soil. .

According to an aspect of the present invention, there is provided a hull comprising: a hull; A plurality of jack-up legs mounted on the hull to move up and down through the hull; A spud can provided in a lower portion of the jack-up leg portion, the jack-up leg portion being penetrated and embedded in the sea bottom when descending; And a scrubbing prevention unit provided adjacent to a lower portion of the jack up leg part to prevent scouring of the sea bottom around the jack up leg part caused by the current when the spud can penetrates the sea bottom and is embedded. Jack up platforms may be provided.

The scour prevention unit is disposed adjacent to the side of the jack-up leg portion, and includes a base block seated on the sea bottom, the base block may include a slope that increases in height from the outside to the inside.

The scour prevention unit may be further provided on the upper side, and may further include a flap portion for converting the direction of the current flowing along the inclined portion in the reverse direction and causing a peeling phenomenon.

The spud cans, the base portion connected to the lower portion of the jack-up leg; And a gripping part connected to the base part and holding the soil of the sea bottom when the spud can penetrates the sea bottom.

The gripping portion may be formed to protrude along the base portion, and may include a plurality of protrusion pieces spaced apart from each other.

The protruding piece may have an end portion bent inward.

The gripping portion may further include a gap formed between the plurality of protruding pieces, and the gap may be a passage through which the soil deposited on the sea bottom is discharged to the top of the base as the spud can penetrates the sea bottom.

The base portion may have a conical shape that is inclined so that a thickness of the surface contacting the sea bottom surface decreases from the inner side to the outer side.

Embodiments of the present invention, by including a scour prevention unit for preventing the bottom scour phenomenon occurring around the jack-up leg, and the spud can improved the gripping force on the bottom soil, the hull overturned due to the external environmental load Can be prevented.

1 is a perspective view showing a jack-up platform in an embodiment of the present invention.
Figure 2 is a side view showing a jack-up platform according to an embodiment of the present invention.
3 is an enlarged view of portion A of FIG. 2.
4 is a partially enlarged perspective view of the spud can of FIG. 3.
5 is a partially enlarged perspective view of the scour prevention unit of FIG. 3.

In order to fully understand the present invention, operational advantages of the present invention, and objects achieved by the practice of the present invention, reference should be made to the accompanying drawings and the accompanying drawings which illustrate preferred embodiments of the present invention.

Hereinafter, the present invention will be described in detail with reference to the preferred embodiments of the present invention with reference to the accompanying drawings. Like reference symbols in the drawings denote like elements.

The jack-up platform according to the invention is not only a jack-up rig, a jack-up drilling rig, but also an offshore wind turbine. Wind floating installation vessels (WTIV), mobile offshore drilling units (MODUs), etc. include all floating offshore structures capable of lifting the hull above sea level and securing the hull to the sea floor.

1 is a perspective view showing a jack-up platform according to an embodiment of the present invention, Figure 2 is a side view showing a jack-up platform according to an embodiment of the present invention, an enlarged portion A of Figure 2 of Figure 3, Figure 4 3 is a partially enlarged perspective view of the spud can of FIG. 3, and FIG. 5 is a partially enlarged perspective view of the scour prevention unit of FIG. 3.

1 to 5, the jack-up platform 100 according to an embodiment of the present invention includes a hull 200 and a plurality of jack-up legs mounted on the hull 200 and elevating through the hull 200. Spud can (400) is provided in the lower portion of the jack-up leg (300) and the jack-up leg (300) when the jack-up leg (300) descends and is embedded in the sea floor; Is provided adjacent to the lower portion of the jack-up leg 300, but when the jack-up leg 300 is embedded in the sea bottom to prevent the seabed scour phenomenon around the jack-up leg 300 caused by the current flow Scour prevention unit 500 is included.

The jack-up platform 100 according to the present embodiment is used for offshore work for exploring or drilling a buried zone such as sea oil and gas.

On the other hand, the jack-up platform 100 according to the present embodiment may be used for floor work in rivers or ports as well as installation and maintenance of pipelines in the sea.

1 and 2, the hull 200 includes a bow portion 210 located in the front portion in the longitudinal direction, and a stern portion 230 located in the rear portion in the longitudinal direction.

The hull 200 according to the present embodiment has a larger width and lower height of the hull 200 than a general transport ship, a cargo ship, or the like.

On the other hand, the jack-up platform 100 according to the present embodiment, the jack-up leg 300 to be described later during the voyage is located on the upper portion of the hull 200, the jack-up leg 300 to the hull 200 during operation It is penetrated and embedded in the sea bottom.

That is, during the exploration and drilling of sea oil and gas, the hull 200 is lifted up to the sea surface by the jack-up leg 300 at the work place and is fixed to the sea bottom by the jack-up leg 300. .

1 and 2, the jack-up leg 300 serves to fix the hull 200 to the bottom of the sea during exploration and drilling operations as described above.

During operation of the jack-up platform 100, the jack-up platform 100 is designed so that the jack-up platform 100 can be operated while the jack-up leg 300 is raised to the upper portion of the hull 200 to the maximum.

Therefore, the jack-up platform 100 can be easily transported to the working position by using a tugboat or the like. And, when the jack-up platform 100 reaches the working position, the jack-up platform 300 is lowered until it reaches the sea bottom.

In the case where the hull 200 is fixed using the jack-up leg 300, each of the plurality of jack-up leg 300 may be maintained so that the hull 200 is balanced despite the inclination and / or bending of the sea bottom. May be driven independently to maintain the balance of the hull 200 to different locations.

On the other hand, a jacking device (not shown) is provided to raise and lower the jack-up leg 300 through the hull 200, the jacking device is a rack (not shown) and the hull 200 provided in the jack-up leg 300 The pinion (not shown) provided in the) has a structure capable of raising and lowering the jack-up leg 300 through the hull 200 in a state of being engaged with each other.

In addition, when the jack-up leg 300 fixes the hull 200 to the sea bottom, in the process of embedding the jack-up leg 300 into the sea bottom, the bottom of the jack-up leg 300 is placed on the sea bottom. In order to be easily penetrated and at the same time to prevent the jack-up leg portion 300 penetrated into the sea bottom buckling due to external environmental loads such as wind, current, and the like to cause the jack-up platform 100 to overturn, The spud can 400 is provided below the jack-up leg 300.

3 and 4, the spud can 400 is connected to the base 410 and the base 410 connected to the bottom of the jack-up leg 300, but the jack-up leg 300 is connected to the sea bottom. It includes a gripping portion 430 for gripping the soil of the seabed to prevent buckling when the jack-up leg 300 is buried when embedded.

The base portion 410 is connected to the lower portion of the jack-up leg 300 serves to support the grip portion 430 to be described later.

Base portion 410 is formed in a circular plate shape when viewed from the top, but is not limited to this may be any shape as long as it is coupled to the lower portion of the jack-up leg 300 to support the gripping portion 430.

On the other hand, the base portion 410, the jack-up leg 300 is formed to be inclined so that the thickness decreases from the inner side to the outer side so as to easily penetrate the sea bottom.

That is, the base 410 surface contacting the sea bottom has a conical shape with a sharp center in the center, as shown in FIG. 4, which is a jack up leg 300 in the process of embedding the jack up leg 300 in the sea bottom. This is to make it easy to penetrate the sea bottom.

And, the grip portion 430 is the jack-up leg 300 and when the base portion 410 connected to the lower portion of the jack-up leg 300 is embedded in the sea bottom, buried by the external environmental load such as wind, current The jack-up leg 300 is buckled or the jack-up leg 300 suddenly digs deep into the bottom of the seabed and serves to grip the soil at the bottom of the sea floor to prevent the jack-up platform 100 from overturning.

The gripping portion 430 is formed to protrude along the base portion 410, but a plurality of protrusion pieces 431 provided to be spaced apart from each other, and the soil deposited on the sea bottom as the jack-up leg portion 300 penetrates into the sea bottom. It includes a gap 433 formed between the plurality of protrusions 431 to be discharged to the upper portion 410.

The protruding piece 431 serves to grip the bottom soil.

In addition, a plurality of protrusion pieces 431 may be provided to protrude downward from the base portion 410 along the circumference of the base portion 410 having a circular plate shape.

Then, the protruding piece 431 is formed such that its end is bent inward.

Therefore, the bottom soil located inside the plurality of protrusion pieces 431 is gripped by the plurality of protrusion pieces 431.

On the other hand, the jack-up leg 300 is buried in the bottom, the base portion 410 and the plurality of protrusions 431 of the spud can 400 is squeezed deep into the bottom while pressing the soil of the bottom The bottom soil surrounded by the base 410 and the plurality of protruding pieces 431 is more tightly packed as the voids between the particles decrease.

Therefore, the jack-up leg 300 is more firmly fixed to the bottom surface, thereby preventing the jack-up platform 100 from being overturned, thereby improving the stability of the jack-up platform 100.

At this time, the bottom soil located inside the base 410 and the protrusion 431 in the process of the jack-up leg 300 is buried in the sea bottom through a gap 433 formed between the plurality of protrusions 431. It is discharged to the base 410. The size of the gap 433 is determined in consideration of the degree of cohesion of the soil according to the decrease in the pore of the sea bottom soil.

However, even when the jack-up leg 300 is firmly fixed to the sea bottom by the spud can 400 according to the present embodiment, the jack-up leg 300 may be formed due to the current flowing through the jack-up leg 300. The surrounding seabed soil is scoured downwards.

As the scour phenomenon due to the current flows slowly over a long period of time, the jack-up leg 300 sinks or buckles below the sea floor, causing the jack-up platform 100 to overturn.

This scour is due to the vortex formed around the jack-up leg 300.

The vortices generated around the jack-up leg part 300 are the vortices caused by the downflow generated on the lower portion of the jack-up leg part 300 by the current flowing through the jack-up leg part 300, and the jack-up leg part 300. It is divided into vortices occurring directly downstream.

The scour caused by the vortices as described above is generated when the amount of removed soil is greater than the amount of inflowed soil, and gradually increases as time passes to damage the jack-up leg 300 as well as the jack-up leg. The friction force between the part 300 and the sea floor soil is dropped, causing the jack-up leg 300 to buckling.

In particular, since the exploration and drilling of resources such as oil and gas through the jack-up platform 100 are performed for several months to several years, the jack-up platform 300 is exposed to the sea bottom by buckling and is buckled. May compromise the stability of).

Therefore, in the present embodiment, to prevent the scour phenomenon from occurring around the jack-up leg 300, the scour prevention unit 500 is provided adjacent to the lower portion of the jack-up leg 300.

The scrubbing prevention unit 500 is provided adjacent to the lower portion of the jack-up leg 300 to prevent the occurrence of seabed scour around the jack-up leg 300 by the current flowing through the jack-up leg 300. Play a role.

In particular, the scour prevention unit 500 according to the present embodiment, there is no fear of loss of position and positional deviation by the current, it is easy to manufacture and install.

The scour prevention unit 500 according to the present embodiment is disposed adjacent to the side of the jack-up leg 300, but is provided on the base block 510 and the base block 510, which is disposed on the bottom of the sea current. It includes a breaker block 530 to disturb the direction of.

The base block 510 is an inclined portion that increases in height from the outside to the inside so that the current flows upward to the bottom of the sea floor so as to prevent the current flowing through the sea bottom near the bottom of the jack-up leg 300 to cause scour. 511.

When the jack-up leg 300 is embedded, the base block 510 is disposed adjacent to the side of the jack-up leg 300 so as to surround the side of the jack-up leg 300 buried in the sea bottom and embedded. .

At this time, the current flowing in the direction of the jack-up leg 300 flows above the sea bottom along the inclined portion 511 of the base block 510.

Therefore, it is possible to suppress vortices occurring on the bottom of the jack up leg 300 near the bottom of the jack up leg 300 and affecting the bottom surface of the jack up leg 300, thereby suppressing the jack up leg 300. Scour can be prevented from occurring on the seabed near the bottom of the tank.

In addition, a breaker block 530 including a flap portion 531 inclined in a direction corresponding to the inclined portion 511 of the base block 510 is further provided on the base block 510.

On the other hand, when the jack-up leg 300 is formed in a lattice form as shown in FIG. May erode That is, the scour phenomenon may be generated by the vortex generated directly downstream of the jack-up leg 300.

Accordingly, in order to suppress the inflow of the current into the grating jack-up leg 300, the base block includes a flap portion 531 for changing the direction of the current flowing along the inclined portion 511 to separate the current. The breaker block 530 is further provided on the upper portion of the 510 to extend from the inclined portion 511 of the base block 510.

As shown in FIGS. 3 and 5, the flap portion 531 may adjust an angle at which the current flow is separated according to the flow velocity of the current flowing in the jack-up leg 300.

That is, when the flow velocity of the sea current is high, the angle formed with the sea bottom may be reduced, or when the flow velocity of the current flow is slow, the angle formed with the sea bottom may be increased.

As such, the current flow introduced along the inclined portion 511 of the base block 510 is changed in direction by the flap portion 531 of the breaker block 530, and is separated from the end of the flap portion 531 to be a jack-up leg portion ( The amount flowing into the inside of 300) is significantly reduced.

Therefore, it is possible to prevent the scour phenomenon caused by the eddy current generated by the downstream of the jack-up leg 300.

In addition, a load acts on the jack-up leg 300 by the current flow acting on the jack-up leg 300. According to the exemplary embodiment of the present invention, the currents acting on the jack-up leg 300 are disturbed by the inclined portion 511 or the flap portion 531 to generate vortices or cause peeling. This dissipates some energy from the currents. The load acting on the jack-up leg 300 by the dissipated energy is reduced. As the load acting on the jack-up leg 300 decreases, the scour phenomenon due to the movement of the jack-up leg 300 may be prevented, and the jack-up platform 100 may be reduced by reducing the external environmental load acting on the jack-up platform 100. You can also prevent rollover.

Referring to the operation of the jack-up platform according to an embodiment of the present invention configured as described above are as follows.

1 and 2, the jack-up platform 100 is used for exploration and drilling of resources such as crude oil and gas buried in the seabed.

In the resource exploration and drilling using the jack-up platform 100, the jack-up platform 100 is fixed to the sea bottom by the jack-up leg 300 embedded in the sea bottom.

However, the jack-up leg 300 embedded in the sea bottom is buckled by an external environmental load such as wind or current, or the sea bottom soil around the jack-up leg 300 is caused by the current flowing through the jack-up leg 300. Erosion scour may occur.

In order to prevent the buckling of the jack-up leg 300 or the scour of the sea bottom soil, in this embodiment, the spud can 400 and the scour prevention unit 500 are provided.

3 to 5, the jack-up leg 300 is embedded in the sea bottom, and the base 410 and the plurality of protrusions 431 of the spud can 400 compress the soil on the sea bottom. While digging deep into the sea floor.

At this time, the seabed soil surrounded by the base portion 410 and the plurality of protrusion pieces 431 is more tightly aggregated as the voids between the particles decrease.

Therefore, the jack-up leg 300 is more firmly fixed to the sea bottom, thereby preventing the jack-up platform 100 from being overturned, thereby improving the stability of the jack-up platform 100.

In addition, the scour prevention unit 500, the base block 510 is disposed adjacent to the side of the jack up leg portion 300, and the direction of the current flow on the upper portion of the base block 510 to change the jack up leg portion 300 Seated breaker block 530 to prevent the current flowing into the inside of).

The scour prevention unit 500 allows the current flowing into the lower portion of the jack-up leg 300 to flow upward of the base block 510 along the inclined portion 511 of the base block 510, and breaker block 530. By changing the direction of the current flow by the flap portion 531 at the same time to remove the current at the end of the flap portion 531 to prevent the current flow into the jack-up leg 300. Therefore, it is possible to prevent the scour phenomenon of the seabed around the jack-up leg 300 by the scour prevention unit 500.

In addition, the scour prevention unit 500 can dissipate energy of the sea current acting on the jack-up leg 300 by the inclined portion 511 and the flap portion 531. The load acting on the jack-up leg 300 is reduced by the dissipated energy, thereby preventing seabed scour around the jack-up leg 300 and preventing the jack-up platform 100 from overturning.

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 or scope of the invention. Accordingly, such modifications or variations are intended to fall within the scope of the appended claims.

100: jack up platform 200: hull
300: jack up leg 400: spud cans
410: base portion 430: gripping portion
431: protrusion 433: clearance
500: scour prevention unit 510: basic block
511: inclined portion 530: breaker block
531: flap portion

Claims (8)

hull;
A plurality of jack-up legs mounted on the hull to move up and down through the hull;
A spud can provided in a lower portion of the jack-up leg portion, the jack-up leg portion being penetrated and embedded in the sea bottom when descending; And
It is provided adjacent to the lower portion of the jack-up leg, the jack-up comprising a scour prevention unit for preventing the bottom surface scour around the jack-up leg generated by the current when the spud can penetrates the sea bottom platform. The method of claim 1,
The scour prevention unit,
It is disposed adjacent to the side of the jack-up leg, and includes a base block seated on the sea bottom,
The base block, jack-up platform comprising a slope that increases in height from the outside to the inside. 3. The method of claim 2,
The scour prevention unit,
The jack-up platform provided in the upper portion, further comprising a flap portion for changing the direction of the current flowing along the inclined portion and causing a peeling phenomenon. The method of claim 1,
The spud cans,
A base connected to a lower portion of the jack-up leg; And
The jack-up platform is connected to the base, the jack-up platform comprising a gripping portion for holding the soil of the sea surface when the spud can penetrates the sea bottom. 5. The method of claim 4,
The gripping portion includes:
Jack-up platform is formed to protrude along the base, and comprises a plurality of protruding pieces spaced apart from each other. The method of claim 5,
The projecting piece is a jack-up platform that is bent inward end. The method of claim 5,
The gripping portion includes:
Further comprising a gap formed between the plurality of protruding pieces,
The gap is a jack-up platform is a passage through which the soil deposited on the sea floor is discharged to the upper portion as the spud can penetrates the sea bottom. 5. The method of claim 4,
The base unit includes:
A jack-up platform having a conical shape that is inclined so that its thickness, which is in contact with the sea bottom, decreases from the inner side to the outer side.

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