KR102020108B1 - Tidal Current Power Generator Construction System With Easy Submarine Cable Installation - Google Patents

Abstract

After installing the substructure on the seabed, connecting one end of the submarine cable through the substructure to the turbine for tidal current, and then install the tidal turbine for the substructure by completing the construction of the tidal current generator A construction system, comprising: a work vessel located at sea near a point where the tidal current generator is constructed; A crane installed on the work ship to move the substructure and the turbine for tidal current underwater; And a cable pulling means for pulling the submarine cable toward the substructure in the course of moving the turbine for tidal current underwater, providing a tidal current generator construction system, by moving the turbine for tidal current underwater. By pulling the submarine cable connected to the tidal power turbine by the cable pulling means in the process of approaching to the lower structure side, minimizing diver input for work, shortening construction time, minimizing cost, and It can be easy to install the submarine cable which can be secured.

Description

Tidal Current Power Generator Construction System With Easy Submarine Cable Installation}

The present invention relates to a tidal current generator construction system and a tidal current generator construction method using the same, and more specifically, by connecting the submarine cable to the turbine for tidal power generation in advance on the working ship, by moving the turbine for tidal power underwater In the process of approaching the substructure, the cable pull means pulls the submarine cable connected to the turbine for tidal current generation toward the substructure, thereby minimizing divers input, shortening construction time, minimizing costs, and ensuring work safety. The present invention relates to an algae generator installation system that can be easily installed undersea cables, and a tidal wave generator construction method using the same.

Algae power generation, unlike tidal power generation, in which a breakwater is installed on the coast and exploits the difference between tides, uses ocean currents without dams or breakwaters in the sea where rapid seawater flows. It is a power generation method to turn a turbine installed in the sea.

This tidal power generation is regarded as environmentally friendly because it does not need to build breakwater, so it is less expensive than tidal power generation, does not limit the movement of ships, does not disturb the movement of fish and does not affect the surrounding ecosystem. have.

In such tidal power generation, a tidal wave turbine is used to obtain energy from a tidal flow, and the tidal wave turbine is a nacelle portion corresponding to a body and a propeller-type aberration rotatably installed therein. It is generally configured to include.

On the other hand, the turbine for tidal current is constructed in this way must be large in size for the efficient use of the tidal flow, the installation is very heavy due to the heavy weight and the nature of the installation position that must be installed in a quick position It can only be difficult.

For this reason, a method of installing a turbine for tidal current generation in a substructure installed after the substructure is fixedly installed on the sea floor is generally used.

On the other hand, for the transmission of electricity produced through the turbine for tidal power generation, the submarine cable should be connected to the turbine for tidal power generation.

In order to connect the submarine cable for this purpose to the turbine for tidal power generation, after completing the installation of the tidal turbine for the substructure installed in the seabed, a method of connecting the submarine cable to the tidal turbine by introducing a diver is mainly used. Has been used.

However, this conventional method of injecting divers, since the installation of the turbine for tidal current on the lower structure, because the submarine cable connection work must be made separately, not only the construction time is long, but also the installation cost increases accordingly, It may be a problem to secure work safety by divers.

Korean Patent Registration No. 10-1720758 (2017.03.22)

The present invention has been made to solve the above-mentioned problems, by connecting the submarine cable to the turbine for tidal power generation in advance on the working ship, and the tidal current by the cable pulling means in the process of moving the turbine for tidal power underwater to approach the substructure The tide generator is easy to install the submarine cable that minimizes divers input, shortens the construction time, minimizes costs, and secures work safety by pulling the submarine cable connected to the turbine for power generation to the lower structure side. It is an object of the present invention to provide a construction system and a method for constructing a tidal current generator using the same.

In the tidal current generator construction system according to the present invention, by installing a substructure on the seabed, connecting one end of the submarine cable passed through the substructure to the turbine for tidal current generation, and then installing the turbine for tidal current generation to the substructure An algae power generation system for completing a construction of an algae power generation device, comprising: a work vessel located at a sea near a point where the algae power generation device is constructed; A crane installed on the work ship to move the substructure and the turbine for tidal current underwater; And cable pulling means for pulling the submarine cable toward the substructure in the course of moving the tidal current turbine underwater.

In the tidal current generator construction system according to the present invention, the cable pulling means may be provided by towing a first buoy floating on the sea by fixing a predetermined point of the other end side of the submarine cable.

In the tidal current generator construction system according to the present invention, the substructure includes a J-Tube, the submarine cable may pass through the J-Tube.

The tidal current generator construction system according to the present invention further includes a second buoy floating on the sea and connected to one end of the submarine cable, before the turbine for tidal current is moved underwater. One end of the submarine cable may be separated from the second buoy and connected to the turbine for tidal current generation.

In the tidal current generator construction system according to the present invention, the cable pulling means may be a cable automatic winding device installed on the substructure to wind the submarine cable.

In the tidal current generator construction system according to the present invention, the cable automatic winding device, by providing a cylindrical winding portion in which the submarine cable is wound by the rotation and the elastic force for the rotation of the winding portion automatically the submarine cable is automatically It may be provided with elastic means to be wound.

In the tidal current generator construction system according to the present invention, one end of the submarine cable is connected to the turbine for tidal current generation before the substructure is moved underwater and installed in the seabed, and when the substructure is moved underwater By the tension acting on the submarine cable, the submarine cable wound on the cable self-winding device is gradually released, and when the tidal current turbine is moved underwater and approaches the substructure, the elastic means provides By rotating the winding part by the elastic force it is possible to rewind the submarine cable to the automatic winding device.

According to the present invention, a tidal current generator construction method includes constructing a substructure on a seabed, connecting a subsea cable to a turbine for tidal current generation, and then installing the turbine for tidal current generation on the substructure. An algae power plant construction method for completing a construction, comprising: a subsea cable preparation step of connecting one end of the submarine cable having a middle portion fixedly connected to a first buoy to a second buoy via the substructure; A substructure construction step of installing the substructure on the sea floor; A subsea cable connection step of disconnecting one end of the submarine cable from the second buoy to connect to the turbine for tidal current generation; By pulling the submarine cable by pulling the first buoy to reduce the length of the submarine cable between the tidal turbine and the substructure, while moving the tidal turbine underwater and moving to the substructure side. Turbine moving step; A turbine coupling step of connecting the tidal turbine and the substructure; And a subsea cable fixing step of fixing the submarine cable to a seabed.

In the tidal current generator construction method according to the present invention, the submarine cable preparation step, after passing through the submarine cable to the J-tube provided in the lower structure, one end of the submarine cable to the second buoy It may be a step of connecting.

According to the present invention, a tidal current generator construction method includes constructing a substructure on a seabed, connecting a subsea cable to a turbine for tidal current generation, and then installing the turbine for tidal current generation on the substructure. An algae power generation device construction method for completing a construction, the submarine cable preparation step of winding the submarine cable in the cable automatic winding device provided in the lower structure; A subsea cable connection step of connecting one end of the submarine cable to the turbine for tidal current generation; A substructure construction step of constructing the substructure on a seabed; A turbine moving step of starting the turbine for tidal current underwater and moving it toward the substructure; A turbine coupling step of connecting the tidal turbine and the substructure; And a subsea cable fixing step of fixing the submarine cable to a seabed. In the substructure construction step, the submarine cable wound around the cable automatic winding device is released, and the submarine cable released in the turbine moving step. This can again be wound around the cable rewinder.

In the tidal current generator construction method according to the present invention, the cable automatic winding device, by the rotation of the submarine cable is wound around the cylindrical portion and the elastic force for the rotation of the winding portion by providing the resilient cable automatically It may be provided with elastic means to be wound.

According to the tidal current generator construction system according to the present invention and a tidal current generator construction method using the same, the submarine cable is connected to the turbine for tidal current generation in advance on the working ship, and the turbine for tidal current is moved underwater to approach the substructure. By pulling the submarine cable connected to the turbine for tidal power generation by the cable pulling means in the lower structure side, minimizing diver input for work, shortening construction time, minimizing cost, and ensuring work safety. It is easy to install submarine cable.

1 is a schematic side view for explaining a tidal current generator construction system according to an embodiment of the present invention.
Figure 2 is a schematic front view for explaining a tidal current generator construction system according to an embodiment of the present invention.
Figure 3 is a schematic plan view for explaining a tidal current generator construction system according to an embodiment of the present invention.
Figure 4 is a flow chart of a tidal current generator construction method according to an embodiment of the present invention.
5 to 13 is a reference diagram for explaining a construction method of a tidal current generator according to an embodiment of the present invention.
14 is a schematic side view for explaining a tidal current generator construction system according to another embodiment of the present invention.
15 is a schematic front view for explaining an algae power generation apparatus ball system according to another embodiment of the present invention.
16 is a flow chart of a tidal current generator construction method according to another embodiment of the present invention.
17 to 20 is a reference diagram for explaining a construction method of a tidal current generator according to another embodiment of the present invention.

Hereinafter, with reference to the drawings will be described in detail a specific embodiment of the present invention. However, the spirit of the present invention is not limited to the embodiments presented, and those skilled in the art who understand the spirit of the present invention may deteriorate other inventions or the present invention by adding, modifying, or deleting other elements within the scope of the same idea. Other embodiments that fall within the scope of the spirit of the invention may be easily proposed, but this will also be included within the scope of the spirit of the present invention.

In addition, components with the same functions within the scope of the same idea shown in the drawings of the embodiments will be described using the same reference numerals.

1 is a schematic side view for explaining a tidal current generator construction system 100 according to an embodiment of the present invention, Figure 2 is a view for explaining a tidal current generator construction system 100 according to an embodiment of the present invention Figure 3 is a schematic front view, Figure 3 is a schematic plan view for explaining the tidal current generator construction system 100 according to an embodiment of the present invention.

1 to 3, the tidal current generator construction system 100 according to an embodiment of the present invention, the work line 110, the crane 120 is installed on the work line 110, the work line A pair of winches 130 provided in the pair, a pair of guide wires 140 respectively wound around the pair of winches 130, the working line 110 is provided on a predetermined point of the guide wire 140 A pair of fairleads 150 supporting the guide wires 140 to be bent, J-Tubes 160 provided in the substructure 910, and first buoys floating on the sea. And a second buoy 180 floating on the sea.

Meanwhile, the tidal current generator construction system 100 according to an embodiment of the present invention includes a tidal current generator 900 including a lower structure 910, a tidal wave turbine 920, and a submarine cable 930. It may be a tidal current generator construction system to be seated on the sea floor.

In more detail, the tidal current generator construction system 100 according to an embodiment of the present invention is to install the lower structure 910 on the seabed (sea), the submarine cable 930 through the substructure 910 After connecting one end of the tidal current turbine 920, the tidal current turbine 920 is installed on the lower structure 910 by completing the construction of the tidal current generator 900, the tidal current generator construction system Can be.

In this case, the lower structure 910 may include a base 911 seated on the seabed and a columnar connecting portion 912 extending upward of the base.

The connecting part 912 may include a pair of guide wire fixing parts 912a on both sides of the upper end.

In addition, the tidal wave turbine 920 is a blade that is rotatably connected to one side of the nussel portion 921, the coupling portion 922 provided on the lower portion of the nussel portion 921, and the nussel portion 921. 923 may be provided.

Here, the nussel part 921 may be a part that generates electricity through the rotation of the blade 922 with a generator (not shown) therein.

In addition, the nussel part 921 may include guide wire through holes 921a through which a pair of guide wires 140 pass.

In this case, the pair of guide wire through holes 921a may be provided at both sides of a position corresponding to the coupling part 922.

At least a portion of the coupling part 922 may be inserted into and fixed to the connecting part 912.

In other words, the tidal wave turbine 920 may be installed in the substructure 910 by inserting and fixing at least a portion of the coupling portion 922 to the connecting portion 912.

At this time, the lower end of the coupling portion 922 may have a conical shape in which the diameter decreases downward.

Through this, the coupling part 922 may be easily inserted into the connecting part 912.

The submarine cable 930 may be connected to one end of the tidal wave turbine 920 so that the electricity generated by the tidal wave turbine 920 is supplied to a demand destination (not shown).

That is, one end of the submarine cable 930 is connected to the turbine for tidal current generation, and the other end is connected to a demand destination (not shown), so that the electricity produced by the tidal turbine 920 is supplied to the demand destination ( (Not shown).

The working ship 110 may be a barge that is a barge without a power device.

In this case, the working ship 110 may be towed by a tugboat (not shown).

The crane 120 may be installed on the work line 110, and may move the substructure 910 and the tidal wave turbine 920 underwater.

More specifically, the crane 120 is provided as an overhead type (overhead type) may be installed on the upper portion of the work line 110, the lower structure 910 located on the upper surface of the work line 110 ) And the algae turbine 920 is lifted and moved to the sea side, and then the substructure 910 and the algae turbine 920 can be moved to the installation point of the seabed.

At this time, the crane 120 may be provided as a pair of overhead type crane (pair overhead) having the same lifting capacity.

For example, the crane 120 may be provided in pairs each having a lifting capacity of 175t, and may have a lifting capacity of 350t in total.

The winch 130 may be provided as a pair located at both the left and right sides of the working line 110, respectively.

Guide wire 140 may be provided with a pair so that one end is wound around the pair of winches, respectively.

In addition, the pair of guide wires 140 may pass through a specific portion of the turbine for tidal current generation and the other end may be connected to the substructure 910.

In more detail, the pair of guide wires 140 penetrate through the pair of guide wire through holes 921a provided at both sides of the nussel part 921 to both sides of the upper end of the connecting part 912. The other end may be respectively fixed to a pair of guide wire fixing parts 912a provided.

The pair of fair leads 150 may be provided on both sides of the working line 110.

In this case, as shown in FIG. 3, the fairlead 150 supports a predetermined point of the guide wire 140 between the winch 130 and the guide wire through-hole 921a to support the winch. The guide wire 140 released from 130 may be bent toward the guide wire through hole 921a.

J-tube (J-tube) 160 may be provided in the form of a tube formed in the letter J shape, it may be fixedly mounted via the connecting portion 912 and the base portion 911 of the substructure 910.

In addition, the J-tube 160 may be provided to penetrate the submarine cable 930 therein.

As a result, the submarine cable 930 is gently bent through the curved portion of the J-Tube 160 to prevent damage to the submarine cable 930 due to sudden bending.

The first buoy 170 floats on the sea to hold a predetermined point in the middle of the submarine cable 930 between the J-tube 160 and the other end side of the submarine cable 930. Can be.

In other words, the first buoy 170 may grip a predetermined point of the submarine cable 930 between the J-tube 160 and the customer.

Here, in the process of approaching the substructure 910 is moved to the underwater by the crane 120, the tidal power generation turbine 920 by towing the first buoy 170 to the demand side of the submarine cable ( 930, the length of the subsea cable 930 between the tidal turbine 920 and the substructure 910 may be reduced.

In other words, the tidal current generator construction system 100 according to an embodiment of the present invention, the first buoy (floating) floating on the sea by fixing a predetermined point of the other end side of the submarine cable 930 ( The cable pulling means can be provided by towing 170 to the demand side.

The second buoy 180 may float on the sea, and one end of the submarine cable 930 may be connected.

Meanwhile, one end of the submarine cable 930 connected to the second buoy 180 is separated from the second buoy 180 before the tidal wave turbine 920 is moved underwater. It may be connected to the turbine 920 for power generation.

As such, one end of the subsea cable 930 is connected to the tide turbine 920 before the tide turbine 920 is moved underwater, so the connection work is underwater. It is not made, it is made on the work line 110 can minimize the work by the diver.

Hereinafter, with reference to the drawings will be described in detail the algae generator construction method (S100) according to an embodiment of the present invention.

4 is a flow chart of a tidal current generator construction method (S100) according to an embodiment of the present invention, Figures 5 to 13 is a reference for explaining a tidal current generator construction method (S100) according to an embodiment of the present invention. It is also.

Referring to Figure 4, the tidal current generator construction method according to an embodiment of the present invention (S100) is a submarine cable preparation step (S110), the substructure construction step (S120), the submarine cable connection step (S130), through the guide wire It may include a step (S140), a guide wire connection step (S150), a turbine moving step (S160), a turbine coupling step (S170), and a subsea cable fixing step (S180).

On the other hand, the tidal current generator construction method (S100) according to an embodiment of the present invention, the tidal current generator 900 including a lower structure 910, a tidal wave turbine 920, and a submarine cable 930. It may be a method for constructing a tidal current generator to be seated on the sea floor.

In more detail, the tidal current generator construction method according to an embodiment of the present invention (S100) is a substructure 910 is installed on the seabed (sea), the submarine cable 930 through the substructure 910 After connecting one end of the tidal current generation turbine 920, the tidal current generation turbine 920 is installed on the lower structure 910 by completing the construction of the tidal current generation unit 900 construction method Can be.

Subsea cable preparation step (S110), through the substructure 910, the submarine cable 930, the middle portion of which is fixedly connected to the first buoy 170 floating on the sea (sea) through the sea ( It may be a step of connecting to the second buoy 180 floating in the sea (180).

More specifically, the subsea cable preparation step (S110), as shown in FIG. 5, the one end of the submarine cable 930 fixedly connected to the middle portion of the first buoy 170 to the lower structure 910. After passing through the J-tube (160) provided in the) may be a step of connecting to the second buoy 180.

The lower structure construction step (S120) may be a step of installing the lower structure 910 on the sea floor.

In other words, the substructure construction step (S120) is to move the substructure 910 in the water by a crane 120 installed on the work line 110, fixed installation of the substructure 910 on the seabed (海底) It may be a step.

As such, when the lower structure construction step (S120) is in progress, as shown in FIG. 6, one end of the submarine cable 930 is connected to the second buoy 180 and installed on the seabed. An intermediate portion of the J-tube 160 provided in the lower structure 910 may be connected to the first portion 170.

Subsea cable connection step (S130) may be a step of connecting one end of the subsea cable 930 to the turbine for tidal power generation (920).

That is, in the step of connecting the submarine cable (S130) after separating one end of the submarine cable 930 connected to the second buoy 180 from the second buoy 180, as shown in FIG. One end of the submarine cable 930 may be connected to the turbine for tidal current generation (920).

Guide wire penetrating step (S140), one end may be a step of penetrating the other end of the guide wire 140 wound on the winch 130 to a specific portion of the turbine for tidal power generation (920).

In more detail, the guide wire penetrating step (S140), as shown in FIG. 8, pairs the guide wires 140 wound around the pair of winches 130, respectively, and the pair of pairs. Each of the guide wire through-holes 921a provided at both sides of the nussel portion 921 of the tidal wave turbine 920 may be passed through the leads 150, respectively.

Guide wire connection step (S150), may be a step of fixing the other end of the guide wire 140 to the lower structure (910).

In other words, the guide wire connection step (S150), as shown in Figure 9, the connecting portion of the lower structure 910 is fixed to the sea bottom (other) the other end of the pair of the guide wire 140 ( 912 may be connected to both sides of the upper end to be fixed.

Turbine movement step (S160) may be a step of moving to the undercarriage 910 side by moving the turbine for tidal current 920 in the water by using the crane 120.

At this time, by pulling the submarine cable 930 by towing the first buoy 170, as the tidal turbine 920 approaches the substructure 910, the tidal turbine 920 ) And the length of the submarine cable 930 between the substructure 910.

That is, the turbine moving step (S160), as shown in Figures 10 and 11, by pulling the submarine cable 930 by towing the first buoy 170 and the turbine for tidal current generation (920) and While reducing the length of the submarine cable 930 between the substructure 910, it may be a step of moving to the substructure 910 side by moving the turbine for power generation 920 in the water.

In addition, in the turbine movement step (S160), the winch 130 may be operated so that the guide wire 140 maintains an appropriate tensile force.

By doing so, in the turbine movement step (S160), the tidal wave turbine 920 is lowered along the pair of guide wires 140 maintaining proper tensile force to be seated at the correct position of the substructure 910. can do.

The turbine coupling step S170 may be a step of connecting the tidal power generation turbine 920 to the substructure 910.

In more detail, the turbine coupling step (S170), as shown in FIG. 12, connects the coupling part 922 of the tidal wave turbine 920 and the connecting part 912 of the substructure 910. It may be a step of connecting.

In this case, at least a portion of the coupling part 922 may be inserted into the connecting part 912 such that the tidal power turbine 920 and the substructure 910 may be connected to each other. The lower end portion is formed in a conical shape, the diameter of which decreases downward, so that it can be inserted into the position more smoothly.

Subsea cable fixing step (S180) may be a step of fixing the submarine cable 930 to the seabed (sea).

In other words, the subsea cable fixing step (S180), as shown in FIG. 13, separates the submarine cable 930 from the first buoy 170, and the substructure cable 910 is directed to the demand destination. The subsea cable 930 may be fixed to a seabed.

Hereinafter, a tidal current generator construction system 200 according to another embodiment of the present invention will be described in detail.

However, the same components as those described above are shown in the drawings using the reference numerals used above, and detailed description thereof will be omitted.

14 is a schematic side view for explaining the tidal current generator construction system 200 according to another embodiment of the present invention, Figure 15 is a view for explaining the tidal current generator empty system 200 according to another embodiment of the present invention It is a schematic front view.

14 and 15, the tidal current generator construction system 200 according to another embodiment of the present invention, the work line 110, the crane 120 installed on the work line 110, the work line A pair of winches 130 provided in the pair, a pair of guide wires 140 respectively wound around the pair of winches 130, the working line 110 is provided on a predetermined point of the guide wire 140 A pair of fairleads 150 for supporting the guide wire 140 to be bent and a cable auto-winding device 260 installed in the substructure 910 may be included.

The cable automatic winding device 260 provides a resilient force by rotation of the cylindrical winding portion 261 and the winding portion 261 in which the submarine cable 930 is wound by rotation, and thus the submarine cable 930. It may be provided with an elastic means 262 to be automatically wound.

That is, the cable automatic winding device 260, when a tensile force is applied to one end of the submarine cable 930 is wound, the winding portion 261 is rotated in one direction so that the submarine cable 930 is the winding portion ( When the tension is removed and the tension is removed, the winding part 261 is rotated in the opposite direction by the elastic force provided by the elastic means 262 so that the submarine cable 930 is again wound on the winding part 261. It can be wound up.

Through this, the submarine cable 930 wound around the cable automatic winding device 260 is one end to the tide turbine 920 in the process in which the lower structure 910 is moved and installed in the seabed (sea 底) Since it is connected to the tension force is released from the cable automatic winding device (260).

In addition, in the process of moving the tidal current turbine 920 to approach the lower structure 910, the winding section 261 is rotated by the elastic force by the elastic means 262, the submarine cable 930 ) Is wound around the cable automatic winding device (260).

As such, in the tidal current generator construction system 200 according to another embodiment of the present invention, the cable automatic winding device 260 may be provided as a cable pulling means.

Hereinafter, with reference to the drawings will be described in detail the algae generator construction method (S200) according to another embodiment of the present invention.

However, the same components as those described above are shown in the drawings using the reference numerals used above, and detailed description thereof will be omitted.

16 is a flow chart of a tidal current generator construction method (S200) according to another embodiment of the present invention, Figures 17 to 20 is a reference for explaining a tidal current generator construction method (S200) according to another embodiment of the present invention. It is also.

Referring to Figure 16, the tide generator installation method (S100) according to another embodiment of the present invention, the submarine cable preparation step (S210), the submarine cable connection step (S220), the lower structure construction step (S230), through the guide wire It may include a step (S140), a guide wire connection step (S150), a turbine moving step (S260), a turbine coupling step (S170), and a subsea cable fixing step (S180).

The subsea cable preparation step (S210) may be a step of winding the submarine cable 930 in the cable automatic winding device 260 provided in the lower structure 910.

At this time, the cable automatic winding device 260 is a tension force acts on one end of the submarine cable 930 is wound, the winding unit 261 is rotated in one direction, the submarine cable 930 is the winding unit ( When the tension is removed and the tension is removed, the winding part 261 is rotated in the opposite direction by the elastic force provided by the elastic means 262 so that the submarine cable 930 is again wound on the winding part 261. It can be wound up.

Subsea cable connection step (S220) may be a step of connecting one end of the submarine cable 930 to the turbine for tidal current generation (920).

17 is a view showing a state in which the subsea cable preparation step (S210) and the subsea cable connection step (S220) is completed.

Substructure construction step (S230) may be a step of installing the substructure 910 to the seabed (sea).

Referring to FIG. 18, the substructure construction step (S230) moves the substructure 910 in water by a crane 120 installed on a work line 110, and moves the substructure 910 to the seabed. It may be a step of fixed installation.

At this time, the subsea cable 930 wound on the cable automatic winding device 260 is a tension force acts as the distance between the tidal turbine 920 and the substructure 910 is far, the winding It can be unwound at the mounting 261.

The turbine movement step (S260) may be a step of moving the turbine for tidal current 920 underwater by using the crane 120 to move toward the lower structure 910.

At this time, the winding portion 261 is rotated by the elastic force provided by the elastic means 262 of the cable automatic winding device 260 so that the submarine cable 930 is automatically wound on the cable automatic winding device. Can be.

That is, the turbine movement step (S260), as shown in Figure 19, by causing the submarine cable 930 is automatically wound on the cable automatic winding device 260 and the turbine for tidal power generation 920 and the While reducing the length of the submarine cable 930 between the substructures 910, it may be a step of moving to the substructure 910 by moving the turbine for tidal current 920 in water.

In addition, the turbine movement step (S260), by operating the winch 130 may be to maintain the guide wire 140 to the appropriate tensile force.

Through this, in the turbine movement step (S260) so that the tidal wave turbine 920 is lowered along the pair of guide wires 140 to maintain a proper tensile force to be seated in the correct position of the lower structure (910). can do.

As described above, according to the tidal current generator construction system according to an embodiment of the present invention and the tidal current generator construction method using the same, the submarine cable is connected to the turbine for tidal current generation in advance on the working ship, and the turbine for tidal current is underwater In the process of approaching the substructure, the cable pull means pulls the submarine cable connected to the turbine for tidal current generation toward the substructure, minimizing the diver's input for the work, shortening the construction time and minimizing the cost. In addition, it is easy to install the submarine cable to ensure the work safety.

In addition, according to the tidal current generator construction system according to an embodiment of the present invention and a tidal current generator construction method using the same, the tidal power generation turbine along the guide wire 140 in the course of the movement of the tidal turbine (920) ( By allowing the 920 to descend, it is possible to install a turbine for tidal flow without any other control means stably and accurately.

In the above, one embodiment of the present invention has been described in detail, but the scope of the present invention is not limited thereto, and various modifications and variations are possible without departing from the technical spirit of the present invention described in the claims. It will be apparent to those of ordinary skill in the art.

100: tidal current generator construction system according to an embodiment of the present invention
110: working ship 120: crane
130: winch 140: guide wire
150: Fairlead 160: J-tube
170: first buoy 180: second buoy
200: tidal current generator construction system according to another embodiment of the present invention
260: cable automatic winding device
910: Substructure 920: tidal turbine
930: submarine cable
S100: tidal current generator construction system according to an embodiment of the present invention
S110: Subsea cable preparation step S120: Substructure construction step
S130: Subsea cable connection step S140: Guide wire through step
S150: guide wire connection step S160: turbine moving step
S170: turbine joining step S180: submarine cable fixing step
S200: tidal current generator construction system according to another embodiment of the present invention
S210: Subsea cable preparation step S220: Submarine cable connection step
S230: substructure construction step S260: turbine moving step

Claims (11)

After installing the substructure on the seabed, connecting one end of the submarine cable through the substructure to the turbine for tidal current, and then install the tidal turbine for the substructure by completing the construction of the tidal current generator In the construction system,
A work vessel located at sea near a point where the tidal current generator is constructed;
A crane installed on the work ship to move the substructure and the turbine for tidal current underwater;
Cable pulling means for pulling the submarine cable toward the substructure in the course of the underwater turbine for tidal current generation;
A winch provided as a pair located on both left and right sides of the work line;
One end side is wound around the pair of winches, respectively, through a pair of guide wire through holes respectively provided on both sides of the turbine for tidal power generation, the other end is provided with a pair of guide wires to be connected to the lower structure, respectively ; And
A pair of fairleads provided on the work line to support a predetermined point of the guide wire between the winch and the guide wire through hole so that the guide wire released from the winch can be bent toward the turbine for tidal current generation; Including,
The cable pulling means is provided by towing a first buoy floating on the sea by fixing a predetermined point on the other end side of the submarine cable,
The substructure includes a J-Tube,
The submarine cable installation system, characterized in that penetrating through the J-Tube (J-Tube).
delete delete The method of claim 1,
A second buoy floating on the sea and connected to one end of the submarine cable;
One end of the subsea cable is separated from the second buoy before the tide turbine is moved underwater, the tide generator installation system, characterized in that connected to the tide turbine.
After installing the substructure on the seabed, connecting one end of the submarine cable through the substructure to the turbine for tidal current, and then install the tidal turbine for the substructure by completing the construction of the tidal current generator In the construction system,
A work vessel located at sea near a point where the tidal current generator is constructed;
A crane installed on the work ship to move the substructure and the turbine for tidal current underwater;
Cable pulling means for pulling the submarine cable toward the substructure in the course of the underwater turbine for tidal current generation;
A winch provided as a pair located on both left and right sides of the work line;
One end side is wound around the pair of winches, respectively, through a pair of guide wire through holes respectively provided on both sides of the turbine for tidal power generation, the other end is provided with a pair of guide wires to be connected to the lower structure, respectively ; And
A pair of fairleads provided on the work line to support a predetermined point of the guide wire between the winch and the guide wire through hole so that the guide wire released from the winch can be bent toward the turbine for tidal current generation; Including,
The cable pulling means is installed on the lower structure, the tidal current generator construction system, characterized in that the cable automatic winding device for winding the submarine cable.
The method of claim 5,
The cable automatic winding device includes a cylindrical winding portion in which the submarine cable is wound by rotation, and elastic means for automatically winding the submarine cable by providing an elastic force against rotation of the winding portion. Tidal current generator construction system.
The method of claim 6,
One end of the submarine cable is connected to the turbine for tidal current generation before the substructure is moved underwater and installed on the seabed.
When the substructure is moved underwater, the submarine cable wound by the cable automatic winding device is gradually released by the tension acting on the submarine cable,
When the tidal power turbine is moved underwater, and close to the lower structure, the winding portion is rotated by the elastic force provided by the elastic means to rewind the submarine cable to the automatic winding device. Algae Generator System.
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