KR102636814B1 - Submarine cable protective equipment module for marine facilities and submarine cable installation method - Google Patents

Abstract

A purpose of the present invention is to provide a new type of submarine cable protector module for connecting offshore facilities and a submarine cable installation method for connecting marine facilities, which can easily perform cable insertion work or cable removal work and can perform cable insertion work while being less affected by offshore weather conditions or seawater movement. The submarine cable protector module for connecting marine facilities comprises a metal tube (10), a flexible protection tube (20), a bending limiter (30), and a centralizer (40). According to the present invention, the submarine cable insertion work is easily and conveniently performed, the inflow of marine organisms is prevented, the installation time and costs are reduced, and the temperature rise of the submarine cable can be prevented through the ventilation hole of the metal tube.

Description

Submarine cable protective equipment module for connecting marine facilities and submarine cable installation method for connecting marine facilities {Submarine cable protective equipment module for marine facilities and submarine cable installation method}

The present invention relates to a protection module for submarine cables connected to offshore facilities such as offshore wind power generators and offshore oilfield facilities, and to a method of installing submarine cables for connection to offshore facilities. More specifically, it relates to a bend restrictor and a flexible protection tube. , the submarine cable protected by the centraliser is fixed to the lower support structure of the offshore facility and passes through a metal tube placed above the sea surface, and the centralizer at the tip of the submarine cable is tightly coupled to the bottom entrance of the metal tube to penetrate the sea floor. It relates to a submarine cable protection module for connecting offshore facilities that provides a structure for installing cables, and a method for installing submarine cables for connecting offshore facilities.

Wind power generator facilities, oil field facilities, etc. can be installed at sea, and the main body of such offshore facilities (2) is supported on the lower support structure (3) fixed to the sea floor and installed at a set height. The lower support structure (3) is directly fixed to the seafloor, such as a jacket-type structure, tripod-type structure, or monopile-type structure, or is installed underwater, such as a semi-submersible structure or cylindrical (spar buoy) structure. It may be floating on the sea floor and connected and fixed to the sea floor with cables. In addition, various cables such as power cables and communication cables must be connected to the offshore facility (2). In the case of an offshore facility (2) installed in the middle of the sea, the lower support structure (3) of the offshore facility (2) is placed in a partial section of the underwater sea floor with the submarine cable (1) supplied from the installation ship as shown in Figure 1. After the tip of the submarine cable (1) is connected to the messenger rope (7) that is released from the winch (8) installed at the top, the submarine cable (1) is re-wound in the process of rewinding the messenger rope (7) around the winch (8). ) is induced to rise at the tip, and the submarine cable (1) is installed.

Such technologies related to submarine cable installation include Korean Patent Publication No. 10-2014-0019247, “Cable Hang-Off Device,” and Chinese registered patent CN 104037707, “Offshore wind turbine at the conduit frame on the basis of the submarine cable. Laying protection device and mounting method", Chinese published patent CN 103337825 "Submarine cable protection sleeve for offshore wind driven generator", etc. have been published.

Meanwhile, conventionally, as shown in FIG. 1, the submarine cable (1), which has passed through the inside of the bending limiter (30) and the J-tube seal (43), passes through the inside of the metal J-tube (4) again and is connected to the main body of the marine facility on the water. By being connected, it is protected from excessive bending deformation or the underwater environment, and the metal J tube (4) is welded and fixed to the lower support structure (3) to maintain the correct position.

In the case of this conventional submarine cable installation technology, it took several months or more to lay the submarine cable (1) after the installation of the lower support structure (3), and during that period, barnacles, mussels, etc. appeared inside the metal J tube (4). of marine life was introduced and attached to the internal surface, causing significant disruption to the installation work of the submarine cable (1). In addition, since the seafloor and the lower entrance of the metal J tube (4) are close to each other, the tip of the submarine cable (1) often gets stuck in the seafloor during the installation process. To prevent this, a stable It was necessary to work in weather conditions.

And even after the installation of the submarine cable (1) is completed, marine life continues to flow between the metal J tube (4) and the submarine cable (1) while the offshore facility (2) is in operation, resulting in failure of the submarine cable (1). It was very difficult to remove the submarine cable (1) from the metal J tube (4), and recovery work required a lot of time and money.

In addition, there was a problem that the power transmission capacity was reduced as the temperature of the submarine cable (1) increased due to the insulation effect of the internal air layer of the metal J tube (4).

Republic of Korea Patent Publication No. 10-2014-0019247 “Cable hang-off device” Chinese registered patent CN 104037707 "Offshore wind turbine at the conduit frame on the basis of the submarine cable laying protection device and mounting method" Chinese published patent CN 103337825 “Submarine cable protection sleeve for offshore wind driven generator”

Therefore, the present invention improves the problems of the prior art, so that the submarine cable is protected by a bend restrictor, a flexible protection tube, and a centralizer, and is fixed to the lower support structure of the marine facility and placed on the sea level. The centralizer is tightly coupled to the bottom entrance of the metal tube, and the installation structure where the submarine cable passing through the metal tube is connected to the offshore facility prevents the inflow of marine life into the metal tube, thereby preventing cable entry work or cable entry. A new type of submarine cable protection module for connecting offshore facilities and a submarine cable for connecting offshore facilities that allows removal work to be easily performed and allows cable insertion work to be performed while being less affected by marine weather conditions or seawater movement. The purpose is to provide an installation method.

In addition, the present invention provides a structure in which a ventilation hole is formed through a centralizer coupled to a metal tube to allow the introduction of external air into the metal tube, thereby reducing the internal temperature of the metal tube to prevent a decrease in transmission capacity due to an increase in the temperature of the submarine cable. The purpose is to provide a new type of submarine cable protection module for connecting offshore facilities and a method for installing submarine cables for connecting offshore facilities.

According to the characteristics of the present invention for achieving the above-described object, the present invention is coupled to the upper part of the sea level of the lower support structure (3) fixed to the sea floor and installed at a set height to support the marine facility (2), A metal tube (10) made of a metal material and forming an internal passage (11) with a horizontal cross-section size larger than that of the submarine cable (1) through which the submarine cable (1) passes; The submarine cable (1) is disposed on the lower side of the metal tube (10), is coupled to the lower support structure (3), is arranged in the vertical direction, is made of a tubular shape made of a flexible material, and passes through the interior. A flexible protective tube (20) to protect; It is connected to the lower part of the flexible protection tube (20) and placed in the water, and is made in the shape of a tubular body with a structure that bends and unfolds in a set angle range, forming a curved line between the sea bottom and the flexible protection tube (20). , a bending limiter (30) that limits and protects the bending of the submarine cable (1) passing through the interior, and provides a submarine cable protection module for connecting offshore facilities, characterized in that it includes a structure including a bending limiter (30) that limits and protects the bending of the submarine cable (1) passing through the interior.

The submarine cable protection module for connecting offshore facilities according to the present invention has a shape structure in which the horizontal cross-section size gradually increases in the downward direction, and the central hole 41 where the submarine cable 1 is placed is formed along the central axis line. It is closely connected to the lower entrance of the metal tube 10, and the submarine cable 1 passing through the central hole 41 is inserted along the central axis of the lower entrance of the metal tube 10, and the flexible It includes a centralizer (40) coupled to the upper part of the protection tube (20).

In the submarine cable protection module for connecting marine facilities according to the present invention, the centralizer 40 has a ventilation hole 42 disposed inside the lower entrance of the metal tube 10 on the radial outer side of the central hole 41. It can be formed to penetrate in the vertical direction to allow external air to flow into the interior of the metal tube 10.

The submarine cable protection module for connecting offshore facilities according to the present invention may include a clamp 50 that secures the flexible protection tube 20 to the lower support structure 3.

In the submarine cable protection module for connecting offshore facilities according to the present invention, the metal tube 10 has an upper entrance area located at the center in the width direction of the lower support structure 3 and the width of the lower support structure 3. It is disposed inclinedly with a lower entrance area located at one end of the direction, the flexible protection tube 20 is arranged vertically, and the bending limiter 30 may be arranged in a “J” shape.

According to another feature of the present invention for achieving the above-described object, the present invention provides a metal tube-coupled lower support structure in which the lower support structure (3) to which the metal tube (10) is coupled is fixed to the sea floor and installed at a set height. step; A bending limiter (30), a flexible protection tube (20), and a centralizer (40) are sequentially arranged on the submarine cable (1) in a form that surrounds the outer peripheral surface of the submarine cable (1), and the bending limiter (30) A protective gear module cable arrangement step in which the tip portion of the submarine cable (1) that has passed through the inside of the flexible protection tube (20) and the centralizer (40) is exposed to the outside; A messenger rope setting in which the messenger rope (7) released from the winch (8) installed at the top of the lower support structure (3) passes through the metal tube (10) and moves downward to the lower part of the lower support structure (3). step; The tip of the submarine cable (1) passes through the inside of the bending limiter (30), the flexible protection tube (20), and the central riser (40) on the messenger rope (7) lowered to the lower part of the lower support structure (3). Messenger rope-submarine cable connection step where the parts are connected; As the messenger rope (7) is re-wound around the winch (8), the submarine cable (1) on which the bending limiter (30), flexible protection tube (20), and centralizer (40) are disposed is attached to the lower support structure (3). ) Passing through the bottom of the submarine cable-protection module lower support structure moving upward; A submarine cable metal tube passing step in which the submarine cable (1) passes through the metal tube (10) while the messenger rope (7) continues to be wound around the winch (8); In the process of the submarine cable (1) continuing to rise through the metal tube (10), the centralizer (40) comes into close contact with the lower entrance of the metal tube (10) and then is coupled to the metal tube (10). It provides a method of installing a submarine cable for connecting marine facilities, characterized in that the submarine cable (1) is connected to the marine facility (2) through a centralizer-metal tube coupling step.

The method of installing a submarine cable for connecting offshore facilities according to the present invention may include a flexible protection tube fixing step in which the flexible protection tube 20 is fixed to the lower support structure 3 by a clamp 50. .

According to the submarine cable protection module for connecting marine facilities and the method of installing submarine cables for connecting marine facilities according to the present invention, the inflow of marine life into the metal tube that guides the submarine cable to the main body of the marine facility is prevented, thereby preventing cable insertion work or cable removal. Not only is this simple and easy to perform, but it also has the effect of reducing installation time and costs by allowing cable insertion work to be performed with less influence from marine weather conditions. In addition, according to the submarine cable protection module for connecting marine facilities according to the present invention, a ventilation hole is formed through the centralizer coupled to the metal tube, allowing the inflow of external air into the metal tube, thereby reducing the temperature inside the metal tube, thereby reducing the temperature of the submarine cable. It is possible to prevent a decrease in transmission capacity due to increase.

Figure 1 is a diagram showing a conventional submarine cable protection module for connecting offshore facilities;
Figure 2 is a diagram showing a submarine cable protection module for connecting offshore facilities according to an embodiment of the present invention.
Figure 3 is a diagram showing the combined configuration of a metal tube and a centralizer constituting a submarine cable protection module for connecting offshore facilities according to an embodiment of the present invention;
Figure 4 is a diagram showing a method of installing a submarine cable for connecting offshore facilities according to an embodiment of the present invention;
Figure 5 is a diagram showing the installation process according to the method of installing submarine cables for connecting offshore facilities according to an embodiment of the present invention;
Figure 6 is a diagram showing the installation completion state according to the installation method of submarine cables for connecting offshore facilities according to an embodiment of the present invention;
Figures 7 and 8 are diagrams showing the configuration of a bending limiter according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail based on the attached drawings. Meanwhile, in the drawings and detailed descriptions, illustrations and references to structures and operations that can be easily understood by those in the field are simplified or omitted. In particular, in the illustrations and detailed descriptions of the drawings, detailed descriptions and illustrations of specific technical configurations and operations of elements that are not directly related to the technical features of the present invention are omitted, and only the technical configurations related to the present invention are briefly shown or described. did.

The submarine cable protection module for connecting offshore facilities according to an embodiment of the present invention includes a metal tube (10), a flexible protection tube (20), a centralizer (40), a clamp (50), and a bending limiter (30) as shown in FIG. ) consists of a composition including.

As shown in Figures 5 and 6, the metal tube 10 is coupled to the lower support structure 3, which is fixed to the sea floor and installed at a set height to support the offshore facility 2, especially in the area above sea level. It is coupled to the lower support structure (3) to prevent marine life from entering the metal tube (10). This metal tube (10) is made of a metal material and forms an internal passage (11) with a horizontal cross-sectional size larger than that of the submarine cable (1). Accordingly, the submarine cable (1) passes through the internal passage (11) of the metal tube (10) and is connected to the offshore facility (2). The metal tube 10 according to an embodiment of the present invention has an upper entrance portion located at the center portion in the width direction of the lower support structure 3 and a lower entrance portion located at one end portion in the width direction of the lower support structure 3. It is placed at an angle. This is to guide the submarine cable (1) from the flexible protection tube (20) fixed to the leg located at one end of the lower support structure (3) to the upper central part of the lower support structure (3).

As the metal tube 10 is placed above the sea level as described above, a structure is induced in which the tip of the submarine cable 1 moves vertically upward and is inserted into the lower entrance of the metal tube 10. In the case as shown in FIG. 1, the sea bottom and the lower entrance of the metal J tube (4) are close to each other, so it often happens that the tip of the submarine cable (1) gets stuck in the sea floor during the installation work of the submarine cable (1). In contrast, since the tip of the submarine cable 1 does not become stuck in the seafloor, the cable insertion operation can be performed with less influence of marine weather conditions or seawater movement.

The flexible protection tube 20 is disposed on the lower side of the metal tube 10, and is coupled to the lower support structure 3 and disposed in the vertical direction. This flexible protection tube (20) is made of a flexible resin material in the shape of a tubular body and protects the submarine cable (1) passing through it. That is, the submarine cable (1) is frequently bent during the installation process and collides with the lower support structure (3). By being protected by the flexible protection tube (20), the submarine cable (1) is prevented from being excessively bent and damaged during the installation process. is prevented. In addition, after the cable installation is completed, the flexible protection tube 20 is placed vertically, and is placed below sea level except for a portion of the upper part of the flexible protection tube 20. Accordingly, the flexible protection tube 20 protects the submarine cable 1 while minimizing mechanical stress caused by currents or waves after the cable installation is completed.

Here, the flexible protection tube 20 is made of a tube made of a polymer resin material. In the case of such a polymer tube, the inflow or adhesion of marine life does not occur more easily than a metal pipe, and marine life inside is less likely to occur. Since growth is also significantly reduced, the impact of marine life during cable insertion or cable removal work is minimized, and in the event of a breakdown of the submarine cable (1), it can be removed along with the cable, making recovery work easier. do.

Accordingly, there is no influence from marine life during cable insertion or cable removal work, and when the submarine cable 1 breaks down, it can be removed along with the cable, making recovery work simpler.

The centralizer 40 is coupled to the upper part of the flexible protection tube 20, and has a shape structure in which the horizontal cross-section size gradually increases in the downward direction, and has a central axis through the central hole 41 through which the submarine cable 1 passes. Formed along the line. This centralizer 40 may be made of polyurethane material, and is closely connected to the lower entrance of the metal tube 10, as shown in FIG. 3. The centralizer (40) forms a tubular shape by combining a pair of separated segments with bolts, etc., and the pair of segments are combined with each other in close contact with both sides of the outer circumference of the submarine cable (1), thereby allowing the submarine cable (1) to become a central It is placed in the central hole 41 of the riser 40. As the submarine cable (1) is placed in the central hole (41) of the centralizer (40), the submarine cable (1) can be inserted along the central axis of the lower entrance of the metal tube (10).

In particular, the centralizer 40 according to an embodiment of the present invention forms a ventilation hole 42 disposed inside the bottom entrance of the metal tube 10 through the radial outer side of the central hole 41 in the vertical direction, thereby External air can be introduced into the interior of the metal tube 10. Here, the centralizer 40 may form a plurality of vents 42 radially around the central hole 41. An increase in the internal temperature of the metal tube 10 due to external air flowing in through the plurality of vents 42 can be suppressed.

The clamp 50 is used to fix the flexible protection tube 20 to the lower support structure 3 after the cable installation is completed. The flexible protection tube 20 is attached to the leg of the lower support structure 3 by a plurality of clamps 50. can be fixed to

The bending limiter 30 is connected to the lower part of the flexible protection tube 20 and placed in the water, and has a tubular shape that bends and unfolds within a set angle range to prevent the bending of the submarine cable 1 passing inside. limited and protected. This bending limiter 30 forms a curved line between the seafloor and the flexible protection tube 20, and after the cable installation is completed, the bending limiter 30 is arranged in a “J” shape. The bending limiter () according to an embodiment of the present invention has a structure in which a plurality of joint piece modules are connected to each other as shown in FIGS. 7 and 8, and the joint piece module has a tubular shape with an internal passage formed through it, and the joint The internal shape of the area where the modules are connected to each other has a shape structure that allows movement within a set angle range. Here, the joint piece module forms a tubular shape by combining a pair of separated parts with bolts, etc. Of course, the bending limiter 30 may have various other configurations.

Meanwhile, the method of installing a submarine cable for connecting offshore facilities according to an embodiment of the present invention includes a metal tube combination lower support structure installation step, a protective gear module cable placement step, a messenger rope setting step, a messenger rope-submarine cable connection step, The submarine cable (1) is connected to the offshore facility (2) through the step of passing through the bottom of the support structure below the submarine cable-protection module, the step of passing the submarine cable metal tube, the centralizer-metal tube coupling step, and the flexible protection tube fixation step.

In the metal tube combination lower support structure installation step, the metal tube 10 is coupled to the lower support structure 3, which is fixed to the sea floor and installed at a set height to support the offshore facility 2, and the metal tube 10 is This is the stage where the combined lower support structure (3) is installed at sea. In the manufacturing stage of the lower support structure (3) before the lower support structure (3) is installed at sea, the lower support structure (3) and the metal tube (10) are combined, and the metal tube (10) is connected to the lower support structure (3) by welding, etc. It is connected to the upper part of (3). In particular, the metal tube 10 is coupled to the upper position of the lower support structure, which is located above sea level when the lower support structure 3 is installed at sea. Accordingly, the metal tube 10 is not located underwater but above sea level. It is located.

In the protection module cable arrangement step, the bending limiter (30), flexible protection tube (20), and centralizer (40) are sequentially arranged to surround the outer peripheral surface of the submarine cable (1), and the bending limiter (30) and flexible This is the stage where the tip of the submarine cable (1) that has passed through the inside of the protection tube (20) and the centralizer (40) is exposed to the outside. Here, the bending limiter 30 is composed of a structure in which a plurality of joint piece modules are connected, and each joint piece module has a structure in which a pair of divided parts are joined by bolts or the like to form a tubular shape. In addition, the centralizer 40 also has a structure in which a pair of divided parts are joined by bolts or the like to form a tubular shape. Accordingly, the bending limiter 30 and the centralizer 40 are placed on the submarine cable 1 through an assembly operation that combines a pair of split bodies. In contrast, the flexible protection tube 20 is made of a single hollow tube shape and is placed on the submarine cable 1 by inserting the submarine cable 1 into the flexible protection tube 20.

In the messenger rope setting step, the messenger rope (7), which is released from the winch (8) installed at the top of the lower support structure (3), passes through the metal tube (10) to the lower part of the lowermost brace of the lower support structure (3). This is the stage of downward movement.

The messenger rope-subsea cable connection step involves passing the messenger rope (7) lowered to the lower part of the lower support structure (3) through the inside of the bending limiter (30), flexible protection tube (20), and centralizer (40). This is the stage where the tip of the cable (1) is connected.

In the step of passing the bottom of the submarine cable-protection module lower support structure, after the messenger rope-subsea cable connection step, the messenger rope (7) is re-wound around the winch (8) and the bending limiter (30), flexible protection tube (20), and centralizer are connected. This is the step where the submarine cable (1) on which (40) is placed moves upward from the bottom of the lowermost brace of the lower support structure (3) and passes through the lower part of the lower support structure (3).

The submarine cable metal tube passage step is a stage in which the submarine cable (1) passes through the metal tube (10) and is delivered to the upper part of the lower support structure (3) while the messenger rope (7) continues to be wound around the winch (8).

In the centralizer-metal tube coupling step, while the submarine cable (1) continues to rise through the metal tube (10), the centralizer (40) is in close contact with the bottom entrance of the metal tube (10), and then the metal tube (10) This is the stage where it is combined with.

The flexible protection tube fixing step is a step in which the flexible protection tube 20 is fixed to the lower support structure 3 by the clamp 50.

The submarine cable protection module for connecting marine facilities and the installation method for submarine cables for connecting marine facilities according to the embodiment of the present invention configured as described above are installed in such a way that the submarine cable is connected to a bend restrictor, a flexible protection tube, and a centralizer. The centralizer is tightly coupled to the bottom entrance of the metal tube, which is protected by the lower support structure of the offshore facility and placed above the sea level, and the submarine cable passing through the metal tube is connected to the offshore facility through the metal tube. It prevents the inflow of marine life, thereby making it easier to carry out cable insertion work or cable removal work, and allowing cable insertion work to be performed with less influence from marine weather conditions or seawater movement. In addition, the submarine cable protection module for connecting offshore facilities according to an embodiment of the present invention provides a structure in which a ventilation hole is formed through the centralizer coupled to the metal tube to allow the inflow of external air into the metal tube, thereby reducing the internal temperature of the metal tube. Through this, it is possible to prevent a decrease in transmission capacity due to a rise in temperature of submarine cables.

As described above, the submarine cable protection module for connecting offshore facilities and the installation method of the submarine cable for connecting offshore facilities according to the embodiment of the present invention are shown according to the above description and drawings, but this is only an example and the present invention Those skilled in the art will be able to understand that various changes and modifications are possible without departing from the technical idea of .

1: Undersea cable
2: Maritime facilities
3: Lower support structure
4: Metal J tube
5: bending limiter
6: J tube seal
7: Messenger Rope
8: winch
9: floating buoy
10: metal tube
11: Internal passage
20: Flexible protection tube
30: bending limiter
40: Centralizer
41: central hall
42: vent
50: clamp

Claims (7)

It is coupled to the upper part of the sea level of the lower support structure (3), which is fixed to the sea floor and installed at a set height to support the offshore facility (2), is made of metal, and has a horizontal cross-section size larger than that of the submarine cable (1). A metal tube (10) forming an internal passage (11) through which the submarine cable (1) passes;
The submarine cable (1) is disposed on the lower side of the metal tube (10), is coupled to the lower support structure (3) and is arranged in the vertical direction, is made of a tubular shape made of a flexible material, and passes through the interior. Flexible protective tube (20) to protect;
It is connected to the lower part of the flexible protection tube (20) and placed in the water, and is made in the shape of a tubular body with a structure that bends and unfolds in a set angle range, forming a curved line between the sea bottom and the flexible protection tube (20). , a bending limiter (30) that limits and protects the bending of the submarine cable (1) passing through the interior;
It has a shape structure in which the horizontal cross-section size gradually increases in the downward direction, and the central hole 41 where the submarine cable 1 is placed is formed along the central axis line and is closely connected to the lower entrance of the metal tube 10. , the submarine cable (1) passing through the central hole (41) is inserted along the central axis of the lower entrance of the metal tube (10), and the centralizer (40) is coupled to the upper part of the flexible protection tube (20). ); Including,
The centralizer 40 forms a ventilation hole 42 disposed inside the lower entrance of the metal tube 10 in the vertical direction through the radial outer side of the central hole 41, A submarine cable protection module for connecting offshore facilities, characterized in that it allows external air to flow into the interior. delete delete According to clause 1,
A submarine cable protection module for connecting offshore facilities, comprising a clamp (50) that secures the flexible protection tube (20) to the lower support structure (3). According to clause 1,
The metal tube 10 is disposed inclinedly, having an upper entrance portion located at the center portion in the width direction of the lower support structure 3 and a lower entrance portion located at one end portion in the width direction of the lower support structure 3. ,
The flexible protection tube (20) is arranged vertically, and the bending limiter (30) is arranged in a “J” shape. A submarine cable protection module for connecting offshore facilities. A metal tube-coupled lower support structure installation step in which the lower support structure (3) to which the metal tube (10) is coupled is fixed to the sea floor and installed at a set height;
A bending limiter (30), a flexible protection tube (20), and a centralizer (40) are sequentially arranged on the submarine cable (1) in a form that surrounds the outer peripheral surface of the submarine cable (1), and the bending limiter (30) A protective gear module cable arrangement step in which the tip portion of the submarine cable (1) that has passed through the inside of the flexible protection tube (20) and the centralizer (40) is exposed to the outside;
A messenger rope setting in which the messenger rope (7) released from the winch (8) installed at the top of the lower support structure (3) passes through the metal tube (10) and moves downward to the lower part of the lower support structure (3). step;
The tip of the submarine cable (1) passes through the inside of the bending limiter (30), the flexible protection tube (20), and the central riser (40) on the messenger rope (7) lowered to the lower part of the lower support structure (3). Messenger rope-submarine cable connection step where the parts are connected;
As the messenger rope (7) is re-wound around the winch (8), the submarine cable (1) on which the bending limiter (30), flexible protection tube (20), and centralizer (40) are disposed is attached to the lower support structure (3). ) Passing through the bottom of the submarine cable-protection module lower support structure moving upward;
A submarine cable metal tube passing step in which the submarine cable (1) passes through the metal tube (10) while the messenger rope (7) continues to be wound around the winch (8);
In the process of the submarine cable (1) continuing to rise through the metal tube (10), the centralizer (40) comes into close contact with the lower entrance of the metal tube (10) and then is coupled to the metal tube (10). A method of installing a submarine cable for connecting marine facilities, characterized in that the submarine cable (1) is connected to the marine facility (2) through a centralizer-metal tube coupling step. According to clause 6,
A method of installing a submarine cable for connecting offshore facilities, comprising a flexible protection tube fixing step in which the flexible protection tube (20) is fixed to the lower support structure (3) by a clamp (50).