KR101140789B1 - Sea-bottom cable laying apparatus - Google Patents

Abstract

PURPOSE: An apparatus for laying a submarine and laying a submarine cable are provided to minimize cable cut by allowing a cable to the inclined angle between a bed rock and a cable laid beside the bedrock to be gentle. CONSTITUTION: A wheel part(110) is composed of a wheel(111) and a shaft(112). A fork(122) is formed to dig a trough to a forward direction. A prong portion(120) is connected to both sides of the shaft by a hinge. A guidance track(134) is composed to guide so that a cable is laid under the bottom of the sea. A cable guide portion(130) is connected to the both sides of the shaft by hinge.

Description

Subsea cable laying apparatus {Sea-bottom cable laying apparatus}

The present invention relates to a submarine cable embedding apparatus, and more particularly, to a submarine cable embedding apparatus capable of embedding a cable including a communication cable and a power line by excavating the underwater ground of the seabed.

A buried device for embedding submarine cables is a device used for laying communication or power lines on land and islands, or for laying long distance communication cables and power lines through the sea.

The open cut method is mainly used as a method of embedding various cables by using a submarine cable buried device, and the open cut method is an excavation section by digging an underwater ground at an excavation position with an underwater excavator (Grab, etc.). As the method of laying and refilling the structure in the structure, this open cut method not only causes poor construction quality, but also requires a long construction period, resulting in high construction costs and environmental effects due to the benthic ecological environment and floating materials. .

Underwater excavation and embedding apparatus of the conventional buried method configured as described above excavates the first seabed surface with a plow provided in the submersible, and break through the seabed surface excavated with a strong blowing force through a hydraulic spray nozzle connected to the underwater pump, the spot Bury cables, etc.

Such underwater excavation and embedding apparatus should be seated on the excavation section after the completion of the excavation process from the initial construction time to the end point, and at the end of the excavation, part of the excavation will be backfilled due to the flow rate of the previous excavation cross section. Therefore, there is a problem in that the structure can not be accurately seated in the desired position.

In addition, in the process of dropping off the structure at the end of the excavation, it is impossible to settle the exact position of the excavation section due to the flow rate, so it is required to move the underwater structure by divers, which requires excessive labor and time costs. There is a problem that is a very troublesome and a lot of risk of moving the above operation.

In addition, this excavation method is part of the excavated excavation cross-section due to the flow rate as the structure is installed after the excavation, so that not only can not accurately place the structure in the desired position, but also due to the wide excavation cross-section Since it is impossible to completely backfill by the natural flow rate, a separate artificial backfill process is required, and there is an uneconomical problem that the cost required for the artificial backfill process is excessive.

In order to overcome the above problems, Korean Patent Publication No. 91-0006816 is towed through a laying ship, and in addition to a submersible equipped with a plow and a heavy body, a screw is provided with a cutting bit, a hydraulic motor for rotating operation of the screw, and a spray nozzle. There has been proposed a trough and backfilling device for subsea cable embedding machines consisting of an excavator equipped with a cable guide tube for refilling the cable laid into the discharged soil while simultaneously discharging the soil excavated by the hydraulic pipe and screw.

However, the above structure also, since the structure is first part after the excavation, because part of the excavation cross-section due to the flow rate of the excavated excavation cross-section will not be able to accurately seat the structure in the desired position, provided in the submersible Due to the wide excavation cross-section excavated by the old excavator, it is impossible to completely backfill due to the natural flow rate, so a separate artificial backfilling process is required, and the time and cost required for the artificial backfilling process are excessively uneconomical. There was a problem in the environmental aspects, such as seafloor flotation occurs by the use of injection nozzles.

In addition, when the cable is installed on the sea bed or the like, since the soil next to the rock is removed, the cable next to the rock and the rock is sharply inclined and the cable is cut due to the load generated accordingly. there was.

Therefore, it is required to develop a subsea cable laying device that can minimize damage to the cable cutting, not only reduce the time and cost in the construction, but also minimize the occurrence of seafloor debris in terms of environment.

In order to solve the above problems, an object of the present invention is to provide a subsea cable embedding device that can minimize the damage to the cable cutting after installing the cable or the like on the seabed.

In addition, it is an object of the present invention to provide a subsea cable embedding device that can help in terms of environment by minimizing the occurrence of seafloor flotation as well as shortening the time and cost in the construction.

In order to achieve the above object, the present invention is connected to the connection rope of the floating barge in the submarine cable buried apparatus, the wheel portion configured to move forward consisting of a wheel and a shaft; A rake portion hinged to both sides of the shaft, including a rake for digging bone in a forward direction; And it includes a guide line for guiding the cable is embedded in the seabed and provides a subsea cable embedding device consisting of a cable guide portion hinged to both sides of the shaft.

In another aspect, the present invention further comprises a balance maintaining portion connected to the shaft of the wheel portion, the balance maintaining portion is a subsea cable laying device, characterized in that consisting of a balance means for maintaining the balance of the device and a connecting bar connecting the balance means to the shaft To provide.

In another aspect, the present invention provides a subsea cable laying device further comprises a buoy as a means for maintaining the balance.

In another aspect, the present invention provides a subsea cable embedding device, characterized in that the rake is formed of one or more plow-shaped rake.

In another aspect, the present invention provides a subsea cable embedding apparatus, characterized in that the roller is formed so that the cable is easily guided to the guide line of the cable guide portion, the guide ring is formed at both ends of the guide line.

Submarine cable embedding apparatus according to the present invention when the cable is installed on the seabed when installed on the rock bed because the cable is buried next to the rock and rock because the soil is not removed much because only the required part is not dug Therefore, there is an effect that can minimize the damage that the cable is cut.

In addition, the subsea cable embedding apparatus according to the present invention not only shortens the time and cost in the construction surface, but also minimizes the digging portion of the sea bottom to minimize the impact on benthic organisms and minimizes the occurrence of suspended matters in terms of environmental aspects. Can also help.

1 is a perspective view of a submarine cable laying device according to an embodiment of the present invention.
Figure 2 is an exploded perspective view of the submarine cable laying device according to an embodiment of the present invention.
Figure 3 is a side view of the submarine cable laying device according to an embodiment of the present invention.
Figure 4 is a front view of the submarine cable laying device according to an embodiment of the present invention.
Figure 5 shows the state when the submarine cable laying device according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. First, it should be noted that, in the drawings, the same components or parts have the same reference numerals as much as possible. In describing the present invention, detailed descriptions of related well-known functions or configurations are omitted in order not to obscure the subject matter of the present invention.

The terms " about ", " substantially ", etc. used to the extent that they are used herein are intended to be taken to mean an approximation to or in the numerical value of the manufacturing and material tolerances inherent in the meanings mentioned, Accurate or absolute numbers are used to help prevent unauthorized exploitation by unauthorized intruders of the referenced disclosure.

In the present specification, the front means the forward direction of the embedding device, the rear means the opposite direction of the forward direction.

The present invention relates to a submarine cable embedding apparatus, which is a submarine cable embedding apparatus for constructing a communication cable, a power line, and the like for a smart grid that can solve a critical problem of energy security crisis and global warming.

The present invention is towing by connecting the connection rope to the floating barge floating in the water can be carried out without power to save the cost and reduced the possibility of the operation is stopped during the buried.

1 to 4 show a submarine cable embedding apparatus according to an embodiment of the present invention.

The configuration of the present invention may be composed of the wheel unit 110, the rake unit 120 and the cable guide 130, the balance maintaining unit 140 and buoy 150 may be additionally formed.

The wheel unit 110 according to an embodiment of the present invention is composed of a wheel 111 and the shaft 112, the wheel 111 can be made to facilitate the embedding device of the present invention forward, If you encounter a rock on the way forward, you can ride over it.

In addition, the bone itself may be formed on the sea bottom by the weight of the wheel unit 110, and because the rake unit 120 to be described later to form additional bone, the submarine cable is embedded in the formed bone do.

The wheel unit 110 is preferably composed of a metal having a specific gravity so as to sink to the sea floor. By the weight of the buried device can be penetrated to a certain depth into the deposit can form a bone.

In addition, the wheel unit 110 serves to allow the wheel 111 to move forward due to the cloud while the buoy pulls the connection rope while supporting the buried device. The wheel unit 110 is composed of a wheel 111 and the shaft 112, the shaft 112 is hinged so that the rake 120 and the cable guide 130 is independently rotatable.

The diameter of the wheel 111 of the wheel unit 110 is not particularly limited, but may be formed about 2m to 15m, the width of the wheel 111 is preferably 10 ~ 20cm. The width of the wheel 111 has a sharp V-shape in the middle so that the wheel 111 can more easily enter the sea bottom when a load is applied.

In addition, a shaft 112 penetrated in the center of the circle of the wheel 111 is configured, the shaft 112 is a rake portion 120 and the cable guide 130 and the like so that the wheel 111 is rotatable Allow hinges to be connected.

In addition, in the embedding device of the present invention, the rake portion 120 is composed of a support 121 and a rake 122, the rake portion 120 serves to dig a depth and width to bury the cable. There is a load only in the configuration of the present invention, and as a result of pulling the buried device entered into the sea floor, the wheel 111 can be rotated by the rake 122 to excavate the sea floor sediment by a certain depth and a certain width.

Since it is difficult to dig a width and depth of the desired range on the bottom of the sea bottom only by the weight of the wheel 111, the rake portion 120 to sell more than a certain width and depth on the bottom.

The support 121 of the rake 120 is configured to be rotatable by hinged to the shaft 112 on both sides of the wheel 110, the support 121 is a towing means of the cable guide 130 ( 131 is preferably maintained to rotate within a certain range.

The support 121 is connected to the connecting rope of the barge with the towing means 131 of the cable guide 130 to tow the buried device.

In addition, the support 121 is preferably to be rotatable within the range of 0 ~ 45 ° with the traction means 131. Because freely moving independently of the support 121 may be difficult to move in the forward direction during towing and the connection rope can be tangled. When the towing using the connecting rope while maintaining the above range, the opening angle of the support 121 and the towing means 131 is narrowed, the support 121 is lowered down, the towing means 131 is raised up The buried means 133 located on the opposite side of the towing means 131 is narrowed to reach the bottom of the sea bottom.

In addition, the rake 122 is formed on the support 121, one or more rakes 122 may be formed on one support 121, preferably 2-5 rakes 122 are supported ( 121 to reduce the resistance of the sediment on the bottom when digging the bottom of the seabed with the rake 122. That is, it is composed of a plurality of rakes 122 to be overlapped in various positions of the support 121 to reduce the resistance with the bottom sediment so that it can be easily sold.

The rake 122 may be formed in a plow type, and the blade is formed to serve to sell the bottom of the sea bottom in the forward direction so that the supplied cable is buried under the sea bottom well. The blade direction of the rake 122 may be directed toward the front of the forward direction to dig a side portion of the wheel 111 at a depth entered by the weight of the wheel 111.

The length of the rake 122 in the rake 120 may vary depending on the position attached to the support 121, the diameter of the wheel 111 in the rake 122 rotates around the wheel 111 Do not leave the range. If the rake 122 is out of the range of the diameter of the wheel 111, the pie will be more than the intended depth, which may make it difficult to advance the buried device.

In addition, when there is a large attachment such as a rock on the seabed, if the rake 122 is out of the range of the diameter of the wheel 111, the rake 122 is caught on the rock may be difficult to move forward.

Therefore, the rake 122 is formed on both supports 121 connected to the shaft 112 so as not to deviate from the diameter of the wheel 111 so as to sell a predetermined depth. In addition, it is preferable to dig to form a width of about 30 ~ 60cm to dig both sides of the wheel (111).

In addition, the rake portion 120 of the present invention can sell the bottom surface only as necessary depth can minimize the damage that the cable is cut when the cable is installed on the rock. In other words, when the cable is buried by the existing waterjet or airlift, all the rock is exposed and all the soil next to the rock is removed, so that the cable on the rock and the cable next to the rock are steeply inclined. Often the cable was cut due to the load of the filled soil. However, the embedding apparatus of the present invention solves the problems of the prior art and minimizes the damage to the cable because the cable is embedded by removing only the required depth and not the soil of the sea bottom.

In addition, in the submarine cable embedding apparatus according to the present invention, the cable guide unit 130 is a towing means 131 capable of towing the entire buried device and a guide line 134 and a guide to guide the cable to the sea bottom The wheel receiving means 132 and the embedding means 133 connect the means 131 and the guide line 134 and allow the guide line 134 to be positioned above the embedding apparatus.

The towing means 131 is connected to the connecting rope of the barge serves to pull the buried device. That is, by connecting the rope to the end of the towing means 131 can tow the buried device according to the present invention, the towing means 131 is the front of the buried device in the form of a bar as shown in Figures 1 to 3 The other end of the towing means 131, which is located at and not connected to the rope, is connected to the wheel receiving means 132 and rotates independently of the wheel part 110 such that the shaft of the wheel part 110 is rotated. 112 is hinged.

The wheel receiving means 132 is connected to the towing means 131, and serves to support the guide line 134 and at the same time to allow the wheel to roll well while surrounding the outside of the wheel portion (110). . In addition, as the wheel 111 moves forward, the wheel receiving means 132 may form an attachment remover 135 to prevent the mud and the like from being attached to the wheel 111 to rotate.

In addition, the embedding means 133 may be configured so that the rear of the cable guide 130 is in contact with the bottom of the sea bottom.

The towing means 131 is connected to the connecting rope of the barge with the support 121 of the rake 120 to tow the buried device, as described above the towing means 131 and the support 121 is 0 ~ It is desirable to be rotatable in the range of 45 °.

In addition, when the burying device is towed, the connecting rope is connected to the towing means 131 and the support 121 to be towed. When the towing is carried out, the opening angle of the towing means 131 and the support 121 is narrowed. The support 121 comes down, the towing means 131 goes up while the angle is narrowed and the buried means 133 located on the opposite side is in contact with the bottom of the sea floor.

On the wheel receiving means 132 and the embedding means 133, there is a guide line 134 for guiding the cable to be embedded in the sea bottom. That is, the guide line 134 is located at the upper portion of the embedding device and serves to allow the submarine cable to be buried along the guide line 134.

Guide rings may be formed at both ends of the guide line 134, and the guide ring serves to prevent the guide line 134 from leaving the submarine cable while moving.

In addition, the guide line 134 is configured with a roller so that the cable can be easily moved when moving along the guide line 134. That is, the roller is configured in the guide line 134 so that when the cable passes over the roller, the roller is rolled so that the cable can be easily moved.

That is, as the embedding apparatus of the present invention is advanced, the submarine cable is supplied onto the guide line 134 and the submarine cable supplied may be easily moved by a roller on the guide line 134 and supplied to the bone to be located. .

In addition, in the present invention, the balance maintaining unit 140 may be connected to both sides of the shaft 112. The balance maintaining unit 140 may be composed of a connection bar (first connection bar 141, a second connection bar 143) and a balance means (first balance means 142, second balance means 144). Can be.

The connecting bar serves to connect the balance means to the shaft (112). Portions of the connecting bar connected to the shaft 112 may be hinged to the shaft 112 to enable rotation.

The first balancing means 142 is preferably located in front of the shaft 112 of the wheel unit 110, that is, the forward direction. To this end, the rotation of the first connection bar 141 connecting the first balancing means 142 is limited so as not to move to the rear side of the shaft 112. In addition, the second balancing means 144 is preferably located behind the shaft 112 of the wheel unit (110). To this end, the rotation of the second connecting bar 143 connecting the second balancing means 144 is limited so as not to move forward of the shaft 112.

In addition, the first balancing means 142 and the second balancing means 144 is formed in a plate shape to support the bottom of the seam, so that the front and rear end can form a curved surface so as not to be caught on the sea bottom during the forward movement.

In addition, the method of connecting to the connecting bar is characterized in that the first balancing means 142 and the second balancing means 144 is hinged to be rotated up and down. To this end, the first balancing means 142 and the second balancing means 144 may be hinged to the connection bar at the intermediate point of one side.

In addition, buried 150 in the submarine cable laying device according to an embodiment of the present invention may be additionally formed. The buoy 150 is for balancing the embedding device, and prevents the wheel 111 from falling deeply into the sea bottom and at the same time prevents the embedding device from tilting left and right.

The buoy 150 may be connected to the shaft 112 of the wheel unit 110, it may be hinged to be rotatable.

Figure 5 shows the state when the submarine cable laying device according to an embodiment of the present invention.

When the submarine cable embedding apparatus according to the present invention reaches the sea bottom, it is dug to a certain depth due to the weight of the embedding device and the sharp shape (V-shape) of the wheel 111. When the connection rope connected to the barge is connected to the support 121 and the towing means 131 and forwards while towing it, the rake 122 further digs the depth and at the same time digging the side of the wheel 111. Go forward.

In this case, the first balancing means 142 and the second balancing means 144 of the balance maintaining part 140 may be positioned on the bottom of the sea to maintain the balance of the embedding apparatus and additionally have a buoy 150 to maintain the balance. .

The gap between the support 121 and the towing means 131 connected to the connecting rope is narrowed while the buried device is advanced, and the connecting means 131 of the cable guide part 130 is raised upward, and the burial is located on the opposite side. The means 133 descends and comes into contact with the grooved portion so that the cable is supplied through the guide line 134 of the cable guide 130. After the supplied cable is buried inside the seabed, the cable supplied by the seabed flow rate is buried by the surrounding soil.

The present invention described above is not limited to the above-described embodiment and the accompanying drawings, and various substitutions, modifications, and changes are possible within the scope without departing from the technical spirit of the present invention. It will be evident to those who have knowledge of.

110: wheel 111: wheel 112: shaft
120: rake 121: support 122: rake
130: cable guide 131: towing means 132: wheel receiving means 133: buried means 134: guide line
140: balance maintaining unit 141: first connecting bar 142: first balancing means 143: second connecting bar (141) 144: second balancing means
150: buoy

Claims (5)

In the submarine cable laying device connected to the connecting rope of the barge floating in the water,
A wheel unit configured to move forward with a wheel and a shaft;
A rake portion hinged to both sides of the shaft, including a rake for digging bone in a forward direction; And
Submarine cable embedding apparatus comprising a guide line for guiding the cable to be embedded in the seabed and consisting of a cable guide hinged to both sides of the shaft.
The method of claim 1,
Further comprising a balance maintaining portion connected to the axis of the wheel,
The balance maintaining unit is a subsea cable laying device, characterized in that consisting of a connecting means for connecting the balance means and the balance means for maintaining the balance of the device.
The method of claim 1,
Submarine cable laying device further comprises a buoy as a means for maintaining the balance.
The method of claim 1,
The rake portion submarine cable embedding device, characterized in that one or more plow-shaped rake is formed.
The method of claim 1,
Rollers are formed so that the cable is easily guided to the guide line of the cable guide portion, submarine cable laying device characterized in that the guide ring is formed on both ends of the guide line.

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