KR101480755B1 - Supporter for electric power distribution line of submarine cable - Google Patents

Abstract

The present invention relates to an arm structure to fixate a power distribution line of a submarine cable, which can safely protect a submarine cable from fish, fishing gears, a collision or contact with an anchor of a ship, and a fish attack by making the submarine cable be installed on the seabed in a state of being combined with multiple arm units each of which comprises a cable lower cover and a cable upper cover, a cable lower support block integrated with the cable lower cover, and a cable upper support block. Since the arm units are mutually connected to be flexible along the curvature of the seabed to stably install the submarine cable, and have buoys connected thereto to float on the surface of the sea without sinking to the seabed, a cable installation ship can easily pull the submarine cable and the arm units without difficulty. Since the arm units and the submarine cable sink and are installed on the seabed if the buoys are separated from the arm units, it is possible to dispense with a separate work by a diver, thereby reducing time and costs and preventing safety accidents caused by a work process by the diver. Furthermore, the arm unit can perform the functions of protecting the submarine cable and as fishing banks since the cable lower support block constituting the arm unit includes a groove for the fishing banks.

Description

Supporter for electric power distribution line of submarine cable

The present invention relates to a structure for fixing a submarine cable distribution line, and more particularly, to a submarine cable protection means installed at the same time as a submarine cable installation operation, thereby enabling a submarine cable to be contacted and collided with an anchor of a bird, It is possible to safely protect from the attack of fish, but it is possible to save much time and cost by omitting a separate operation by the diver, and also to prevent a safety accident that may occur during the work process by the diver, Which is capable of performing a function as a reverberation, as well as a protection function of a submarine cable distribution line.

In general, submarine cables are installed on the seabed for the purpose of communication as well as between countries or between land and books.

Recently, in relation to submarine cable, it has been focused on the development of a technique of producing a necessary length of cables at a time without a short circuit.

For example, a submarine cable with a diameter of 18.2 cm, a length of 105 km, and a weight of 2,000 tons was developed as a 250 kV submarine cable.

These submarine cables are laid by landing the submarine cables on land or on the books, and by laying down the submarine cables on the seabed by moving the plumbing line connected to the one end to the opposite book or land.

As shown in Fig. 1, the submarine cable C includes a main conductor 1a, a main conductor half screen 1b surrounding the main conductor 1a, and a main conductor half-conductor layer 1b An insulation screen 1d surrounding the main pendulum 1c and a swellable tape 1e surrounding the main pendulum 1o are provided on the outer surface of the main pendant 1c, A plurality of (three in the figure) cable bodies 1 and a plurality (three in the figure) of cable bodies 1 made of a lead sheath 1f surrounding the bulging tape 1e, An inner armor 2, and an outer armor 3.

If the submarine cable is installed in a submerged state without any protective measures, it will be affected by algae and will be damaged by contact with or collision with a special fishing gear or anchor of the ship, There is a concern.

Therefore, in the past, in order to prevent the damage of the submarine cable, a submarine cable is covered with a gabion.

Covering the submarine cables with gauges can be accomplished by hanging the stone mangles on the crane installed on the construction line or barge and sinking them to the seafloor and ensuring that the gabion covers the submarine cables accurately. Then, remove the stone mangets from the crane hooks, As shown in FIG.

In this case, the separation of the stone mantahed from the crane hook is carried out by a diver in the case of the sea of less than 30m in depth, and in the case of the deep sea of more than 120m in the middle sea, It is done by robot.

However, since the gangway installation work to protect the submarine cable is carried out separately after the installation of the submarine cable, the whole process time is lengthened, and there is a problem in that it is costly and the submarine cable is covered with the gabion. Or a collision or collision with an anchor of the ship, the gaboid is detached from the submarine cable, so that the submarine cable can not be reliably protected.

As a prior art related to this, Korean Patent Registration No. 10-0913814 (Registered Aug. 18, 2009) is an undersea high-voltage cable installed on a floor formed on a sea floor, and is connected to the upper end of the undersea high- A first cable securing device; A second cable fixing device corresponding to the first cable fixing device and coupled to the lower end of the submarine high voltage cable to protect the coating of the submarine high voltage cable together with the first cable fixing device; A support structure coupled to a lower surface of the second cable securing device, the support structure being installed on the bottom of the cable securing device; And a cover structure coupled to an upper surface of the first cable fixing device so as to be coupled with the support structure, wherein the first and second cable fixing devices are provided on the first sub- And 2 cable grooves are respectively formed in the longitudinal direction so that the submarine high-voltage cable can be seated and fixed in the first and second cable grooves, and a plurality of fixing projections are formed on the opposite side of the submarine high- And the cover structure and the support structure are respectively made of a synthetic rubber material so as to protect the cover of the undersea high voltage cable and not to injure during the connection, A plurality of protrusion holes are formed on the surfaces of the first and second cable fixing devices, So that the first cable fixing device and the cover structure can be coupled and fixed to each other and the second cable fixing device and the support structure can be fixed to each other, and the submarine high-voltage cable is made of a concrete material Wherein the cover structure and the support structure each have a seating part on one side of which a first cable securing device or a second cable securing device is fitably engaged and a plurality of first and second engaging parts on both sides of the seating part, The plurality of anchor holes are respectively formed in the plurality of first coupling portions of the cover structure, and a plurality of anchor rings corresponding to the plurality of anchor holes are formed in the plurality of second coupling portions of the base structure, And an anchor ring protruding outside the cover structure, And a plurality of spaced apart and spaced apart portions are installed toward the longitudinal direction of the submarine high-voltage cable, and the plurality of submarine high-voltage cable protection facility devices are interposed between the submarine high- A submerged high-voltage cable and a submerged high-voltage cable, the submergence high-voltage cable is protected by providing a mattress mat and a mating protection mat which are sandwiched between the upper and lower surfaces of the submerged high- .

However, in the prior art "Submarine Submarine High-voltage Cable Protection Device ", since the submarine cable must be constructed in advance before the submarine cable is installed in order to install the submarine cable, the operation must be very cumbersome and time- , And the submersible should be carried out at the seabed by submersible by submersible by submersible for the installation of the supporting structure and the cover structure and the cable fixing work by the first cable fixing device and the second cable fixing device. In the case of deep sea water or above, even if the water depth is less than 30m, the working time is limited, and accordingly, a lot of time and cost are required.

As another prior art, Korean Patent Registration No. 10-0794765 (Registered on Jan. 8, 2008) discloses a waste electrolytic assembly in which a plurality of unit pulsed charges are arranged in a plurality of rows in the horizontal direction, Wherein the waste electrolytic assembly is stacked in at least two stages, and a unitary electrochemical cell of the upper electrode assembly is positioned between the unit waste electrolytic poles of the lower electrochemical cell assembly at the time of stacking. At this time, the connecting means includes a plurality of fasteners mounted on the unit pulleys and provided with at least one pair of connecting holes on the outer circumferential surface, and a pair of connecting rings, So that the cable can be prevented from being damaged by the anchor or the fishing gear of the ship by locating the unit pulses of the lower stage pulse former assembly between the unit pulses of the upper pulsed electroforming assembly. And a "submarine cable protection device using a pulsed electric pole".

However, in the above-mentioned prior art "submarine cable protection device using waste electrical pole ", a plurality of waste electrical poles are connected to each other by connecting means to manufacture a waste electroconductive assembly,

Covering the submarine cable with the waste electroconductive assembly involves suspending the waste electrolytic assembly on the crane installed on the ship or barge and allowing the waste electrolytic assembly to accurately cover the submarine cable and then removing the waste electrolytic assembly from the crane hook Since the waste electrolytic assembly must be separated to cover the submarine cable, the installation of the waste electrolytic assembly for protecting the submarine cable is performed separately after the installation of the submarine cable, so that the whole process time is long In addition to being costly, it also covers the submarine cable with the pulmonary core assembly. However, even if the submarine cable is contacted or collided with an anchor of a bird, fishing boat or ship, There is a problem that it can not be protected.

Therefore, it is possible to safely protect submarine cable from contact with or collision with algae, fish or vessel anchor, and attack of fish by installing underwater cable at the same time as submarine cable installation work, It is necessary to develop a wedge structure for fixing with a submarine cable distribution line which not only can save a lot of time and cost but also can prevent a safety accident that may occur in the course of work by a diver.

Korea Patent Registration No. 10-0913814 (Registered on Aug. 18, 2009) "Transmission and distribution submarine high-voltage cable protection facility device" Korea Patent Registration No. 10-0794765 (Registered on January 8, 2008.) "Submarine Cable Protection Device Using Waste Electrode"

Therefore, it is an object of the present invention to provide a submarine cable protection means at the same time as a submarine cable installation operation, so that the submarine cable can be safely protected from contact with or collision with an anchor of a bird or ship or an attack of a fish, Can save a lot of time and money by omitting the operation of the submarine and prevent the safety accident that may occur in the course of work by the diver. It can also protect the submarine cable and function as a reverb. And to provide an undersea cable distribution line for fixing the wedge structure.

In order to achieve the above object, the present invention provides a semiconductor device comprising a main conductor, a main conductor semiconductive layer surrounding the main conductor, a main annular member surrounding the main conductor semiconductive layer, a main annular semiconductive layer surrounding the main annular member, A pair of left and right semi-cylindrical cable lower covers surrounding an outer circumferential lower half of an undersea cable composed of an inner jacket and an outer jacket which enclose a plurality of cable bodies made of a main sheath surrounding the bulging tape; A pair of right and left semi-cylindrical cable upper covers surrounding the upper half of the outer circumferential surface of the submarine cable; A plurality of lower support blocks to which the cable lower cover is mounted, the plurality of lower support blocks being connected to each other in the longitudinal direction of the submarine cable; A pair of left and right upper support blocks to which the cable upper cover is mounted and which are vertically rotatably connected to both sides of the upper surface of the lower support block; And a buoy engaged with the upper support block,

The cable lower cover and the cable upper cover are made of synthetic resin,

The cable lower support block includes a reinforcing bar assembly comprising a plurality of longitudinal bars and transverse bars connected to each other, a concrete cover covering the reinforcing bar assembly, an upper hinge piece welded to the reinforcing bar assembly and protruding from the upper surface of the concrete cover, A front hinge piece welded to the reinforcing bar assembly and protruding from a front surface of the concrete cover, a rear hinge piece welded to the reinforcing bar assembly and protruding from the rear surface of the concrete cover, And a hinge pin,

The concrete cover further includes a semicircular cover installation groove formed on an upper surface thereof and into which the cable lower cover is inserted, and a plurality of artificial grooves formed on the lower surface,

Wherein the upper hinge piece, the front hinge piece, and the rear hinge piece are composed of a welded portion welded to the steel bar assembly, and a hinge portion integrally formed on the welded portion and protruding from the upper surface, the front surface and the rear surface of the concrete sheath,

The upper cable supporting block includes a reinforcing steel assembly including a longitudinal reinforcing bar and a transverse reinforcing bar to be coupled to each other, a concrete covering covering the reinforcing steel assembly to form an outer appearance of the upper cable supporting block, A hinge pin inserted into the upper and lower hinge pieces, an upper support block engagement piece welded to the reinforcement assembly and projecting from an upper surface of the concrete sheath, A coupling bolt passing through the upper support block coupling piece and a coupling nut fastened to the upper support block coupling piece, and a plurality of buoy connection rings welded to the reinforcing assembly and projecting from the upper surface of the concrete sheath,

The concrete block may further comprise a semicircular cover installation groove formed on a lower surface of the upper support block to which the cable upper cover is inserted,

The hinge piece is composed of a welded portion welded to the steel bar assembly and a hinge portion integrally formed on the welded portion and protruding from the lower surface of the concrete cover,

Wherein the upper supporting block connecting piece is composed of a welded portion welded to the steel bar assembly and an engaging portion integrally formed on the welded portion and protruding from the upper surface of the concrete block,

Wherein the buoy connection ring comprises a weld portion welded to the steel bar assembly and a ring portion integrally formed on the weld portion and protruding from the upper surface of the concrete cover,

The buoy body includes a buoy body and a wire rope secured to a lower surface of the buoy body and bound to a ring of the buoy connection ring.

According to the present invention, since the submarine cable is installed on the bottom surface in a state where it is coupled to a plurality of bumpy units constituted by the cable lower cover, the cable upper cover, the cable lower support block combined with the cable lower cover and the cable upper support block, The submarine cable is stably installed because it is safely protected from the contact or the collision with the anchor of the vessel, the vessel or the ship, and the attack of the fish, By connecting the unit to the buoy, the wrought iron unit floats near the sea level without sinking deeply from the sea level, it can be pulled easily without pulling large force when towing the submarine cable and the wired / When the buoy is separated, the waved-iron unit and the submarine cable are settled down, It is possible to save time and cost as well as to prevent a safety accident that may occur in the course of work by a diver. In addition, An artificial groove is formed so that the coarse iron unit can perform the function of protecting the undersea cable as well as the function of the reed.

1 is a perspective view showing a cross-sectional structure of a submarine cable,
2 to 10 show a preferred embodiment of a bare iron structure for fixing a submarine cable distribution line according to the present invention,
Figs. 2 and 3 are exploded perspective views,
4 and 5 are perspective views seen from opposite directions,
6 is a perspective view showing a process of installing a submarine cable according to the present invention,
FIG. 7 is a perspective view showing a preparation process in the installation process of FIG. 6,
FIG. 8 is a perspective view showing a state where a submarine cable is seated in the installation process of FIG. 6,
FIG. 9 is a perspective view showing a submarine cable covered with an upper support in the installation process of FIG. 6,
And,
FIG. 10 is a perspective view showing a state in which an upper support is coupled and a buoy is installed in the installation process of FIG. 6;

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

In the following description, the bolt through holes through which the bolts pass are shown in the drawing, but the reference numerals and explanations are omitted.

As shown in FIGS. 1 to 10, the present invention provides a bare steel fixing structure for a submarine cable distribution line comprising a main conductor 1a, a main conductor semiconductive layer 1b surrounding the main conductor 1a, A main pendulum layer 1c surrounding the main conductor pendant layer 1b and a pendulum pendulum layer 1d surrounding the main pendant 1c; a bulging tape 1e surrounding the main pendulum layer 1d; A submarine cable C composed of an inner enclosure 2 and an outer enclosure 3 enclosing a plurality (three in the figure) of cable main bodies 1 made of a main sheath 1f surrounding the inflated tape 1e A pair of right and left semi-cylindrical cable lower covers 10 surrounding the lower half of the outer circumferential surface; A pair of left and right semi-cylindrical cable upper covers 20 surrounding the upper half of the outer peripheral surface of the submarine cable C; A plurality of lower support blocks 30 to which the cable lower cover 10 is mounted and which are connected in the longitudinal direction of the submarine cable C in a refracting manner; A pair of left and right upper support blocks 40 to which the cable upper cover 20 is mounted and which are vertically rotatably connected to both sides of the upper surface of the lower support block 30; And a buoy (50) bound to the upper support block (40).

The cable lower cover 10 and the cable upper cover 20 are preferably formed of synthetic resin for insulation and reinforcement of the submarine cable C and are preferably formed to a length of about 1 m.

The cable lower support block 30 and the cable upper support block 40 are composed of a reinforced concrete structure.

The lower cable support block 30 includes a reinforcing steel assembly 31, a concrete covering 32 covering the reinforcing steel assembly 31, and an upper surface of the concrete covering 32 welded to the reinforcing steel assembly 31, A front hinge piece 34 protruding from the front surface of the concrete cover 32 and fixed to the reinforcing frame assembly 31 by welding A rear hinge piece 35 protruding from the rear surface of the concrete cover 32 and a hinge pin 36 inserted into the front and rear hinge pieces 34 and 35.

The reinforcing bar assembly 31 is composed of a plurality of longitudinal reinforcing bars 31a and a lateral reinforcing bar 31b joined to each other by binding or welding.

The concrete cover 32 forms an outer surface of the cable lower support block 30 and includes a semicircular cover installation groove 32a formed on the upper surface thereof and into which the cable lower cover 10 is inserted, And a plurality of artificial reed grooves 32b formed to extend in the longitudinal direction.

The upper surface hinge piece 33, the front surface hinge piece 34 and the rear surface hinge piece 35 are welded to the welded parts 33a, 34a and 35a welded to the steel assembly 31, And hinges 33b, 34b, and 35b protruding from the upper surface, the front surface, and the rear surface of the concrete cover 32, respectively.

33c is a groove formed in the concrete covering 33b corresponding to the hinge 33b of the hinge piece 33. 34c and 35c are welds 34a and 35a of the hinge pieces 34 and 35, Which is formed in the concrete cover 32 by the above-mentioned method.

The upper cable support block 40 includes a reinforcing frame assembly 41 and a concrete covering 42 covering the reinforcing frame assembly 41 to form an outer surface of the upper cable support block 40. The reinforcing frame assembly 41 includes a reinforcing frame assembly 41, A lower hinge piece 43 welded to the upper and lower hinge pieces 33 and 43 and protruding from a lower surface of the concrete cover 42 corresponding to the upper hinge pieces 33; An upper supporting block engaging piece 45 welded to the reinforcing frame assembly 41 and protruding from the upper surface of the concrete covering 42 and an engaging bolt 45 penetrating through the upper supporting block engaging piece 45 And a plurality of buoy connection rings 47 welded to the reinforcing bar assembly 41 and protruding from the upper surface of the concrete cover 42. [

The reinforcing bar assembly 41 is composed of a plurality of longitudinal reinforcing bars 41a and a transverse reinforcing bars 41b which are joined together by welding or welding.

The concrete block 42 forms an outer surface of the cable upper support block 40 and has a semicircular cover installation groove 42a formed in the lower surface thereof and into which the cable upper cover 20 is inserted.

The hinge piece 43 is composed of a welded portion 43a welded to the steel bar assembly 41 and a hinge portion 43b integrally formed with the welded portion 43a and projecting from the lower surface of the concrete jacket 42 do.

The upper supporting block engaging piece 45 includes a welding portion 45a welded to the reinforcing bar assembly 41 and an engaging portion 45a integrally formed with the welding portion 45a and projecting from the upper surface of the concrete block 42 45b.

The buoy connection ring 47 includes a welded portion 47a welded to the steel bar assembly 41 and a ring portion 47b integrally formed with the welded portion 47a and projecting from the upper surface of the concrete cover 42 .

In the figure, reference numeral 43c denotes a hinge groove formed at the lower end of the concrete block 42 corresponding to the hinge 43b of the lower hinge piece 43, 45c denotes a hinge groove formed at the lower end of the upper support block engagement piece 45 A hole formed by the welded portion 45a and 47c is a hole formed by the welded portion 47a of the buoy connection ring 47. [

The buoy 50 includes a buoy body 51 and a wire rope 52 fixed to a lower surface of the buoy body 51 and bound to a ring 47b of the buoy connection ring 47 .

The buoy 50 includes a plurality of wavy iron units U each consisting of a cable lower cover 10, a cable upper cover 20, a cable lower support block 30 and a cable upper support block 40 The vane 50 connected to one wrought iron unit U is configured such that the wrought iron unit U does not sink deeply in the sea surface in the installation process and has buoyancy that can float near the sea level do.

The hook 47b of the buoy connection ring 47 and the wire rope 52 can be connected by tying with a wire or the like or can be connected to a wire rope 52 And can be hooked to the hook portion 47b.

Hereinafter, a process of installing the submarine cable by the submarine cable distribution line according to the present invention will be described.

The cover installation groove 32a of the cable lower support block 30 and the cover installation portion 40a of the cable upper support block 40 are provided in one land or book on which the submarine cable C is to be installed, The lower cover 10 and the upper cover 20 are inserted into the groove 42a and the hinge pin 44 is fastened to the hinge portions 33b and 43b of the lower hinge piece 43 and the upper hinge piece 33 And a pair of cable upper support blocks 40 are rotatably connected at both left and right sides of the upper surface of the cable lower support block 30 to constitute a wrought iron unit U. [

The first bender unit is positioned at the "B" position of FIG. 6 and the second bender unit is located at the "A" position. The hinge part 35b of the rear hinge part 35 of the first bender unit, The hinge pin 36 is inserted into the hinge portion 34b of the front hinge piece 34 of the unit so that the first bender unit and the second bender unit are connected so as to be able to bend.

At this time, the coarse iron unit is mounted on a roller conveyor (not shown) so that it can be towed by a construction line (not shown) for towing the submarine cable C. Here, the roller conveyor may be capable of conveying the wrought iron unit by itself, but it is sufficient to pull the wrought iron unit by a laying line, so that a roller conveyor provided with a plurality of rollers can be used.

The pull rope R is bound to the hinge portion 33b of the front hinge piece 33 of the cable lower support block 30 constituting the first bumpy unit and connected to the lay line. It is a matter of course that the submarine cable (C) is connected to the laying line.

The cramped unit at the "A" position and the "B" position rotates the cable upper support block 40 outward by 90 degrees so that the cable lower cover 10 and the cable upper cover 20 are opened. Place the submarine cable (C) on the open cable lower cover (10).

The tow rope (R) connected to the first tundish unit is pulled together with the submarine cable (C) at the laying line so that the first tundish unit is located at the "C" position in FIG. 6, And the hinge portion 35b of the rear hinge piece 35 of the second bender unit and the hinge portion 35 of the front hinge piece 34 of the third bender unit 34 are positioned at the position "A" 34b to insert the hinge pin 36 so that the second wrought iron unit and the third wrought iron unit are refractably connected.

The pair of cable upper support blocks 40 constituting the first coarse unit reached the position "C " is rotated by 90 degrees inward so that the cable upper cover 20 surrounds the upper half of the outer circumferential surface of the submarine cable C .

A coupling bolt 46a is passed through the coupling portion 45b constituting the upper support block coupling piece 45 and a coupling nut 46b is fastened to the coupling bolt 46a to form a pair of cable upper support blocks 40 ).

At this time, the cable lower cover 10 and the cable upper cover 20 are brought into close contact with the lower half portion and the upper half portion of the outer circumferential surface of the submarine cable C so that the submarine cable C is routed through the cable lower cover 10 and the cable upper cover 20, To be coupled to the lower support block 30 and the cable upper support block 40.

Pull the traction rope (R) from the laying line to move the first wrought iron unit to the "D" position, the second wrought iron unit to the "C" position and the third wrought iron unit to the "B" The wire rope 52 connected to the buoy body 51 is coupled to the ring portion 47b of the buoy connecting ring 47 constituting the first bulldozer unit at the position where the buoy 50 is connected to the upper cable support block 40 To be connected.

And the hinge portion 35b of the rear hinge piece 35 of the third bender unit and the hinge portion 34b of the front hinge piece 34 of the fourth bender unit are positioned at the position "A" The pin (36) is inserted so that the third torsion coil unit and the fourth torsion coil unit are connected in a refracting manner.

This process is repeated so that the cable lower support block 30 and the cable upper support block 40 are coupled over the entire length of the submarine cable C.

The bare iron unit launched from the first boulder unit to the sea surface is towed from the laying line to the buoy 50 connected to the buoy connection ring 47 of the upper cable support block 40 It does not sink deeply at sea level, but floats near the sea level.

Therefore, it is possible to easily pull the undersea cable (C) and the bass unit by the laying line without applying great force.

The wire rope 52 connected to the buoy connection ring 47 of the coarse iron unit is separated and the buoy 50 is dismantled by the disassembly of the submarine cable C, (C) and the wrought iron unit are sedimented by their own weight and are placed on the sea floor.

The bottom surface of the cable lower support block 30 is landed on the bottom surface of the bottom surface of the bottom surface of the bottom surface of the bottom surface of the bottom surface of the bottom surface of the bottom surface of the bottom surface of the hinge pin. So that it is refracted and landed in a stable state according to the bending of the sea floor.

The submarine cable (C) laid on the seabed surface is connected to the cable lower support block (30) and the cable upper cover (20) while being in tight contact with the cable lower cover (10) Since the submarine cable C is supported in the state of being supported by the block 40, the submarine cable C is safely protected from contact with and collision with algae, fishes and ships, and attack of fishes.

In addition, in order to protect the submarine cable (C), it is possible to save a lot of time and cost by omitting a separate operation by the diver, and also to prevent a safety accident that may occur during the work process by the diver.

The wrought iron unit landed on the seabed surface is in a state in which fishes and shellfish can enter and exit through the lower surface of the concrete cover 32 constituting the lower cable support block 30 and the grooves 32b for reeds formed on the front, So that it can perform the function as a reed.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or essential characteristics thereof. Therefore, the embodiments disclosed in the present invention are not intended to limit the scope of the present invention but to limit the scope of the technical idea of the present invention. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas falling within the scope of the same shall be construed as falling within the scope of the present invention.

C: Submarine cable U: Wrought iron unit
10: Cable lower cover 20: Cable upper cover
30: Cable lower support block 31: Reinforcing assembly
32: Concrete sheath 32b:
33: upper surface hinge piece 34: front hinge piece
35: rear hinge piece 36: hinge pin
40: Upper cable support block 41: Reinforcing assembly
42: Concrete cover 43: Lower hinge piece
44: hinge pin 45: upper support block engagement piece
46a: coupling bolt 46b: coupling nut
47: Buoy connection ring 50: Buoy

Claims (1)

A main conductor layer 1b surrounding the main conductor 1a and a main conductor layer 1b surrounding the main conductor semiconductive layer 1b and a main conductor layer 1b surrounding the main conductor 1c, A plurality of (three in the figure) cable bodies 1f made of a swollen semiconductive layer 1d, a bulging tape 1e surrounding the bulletproof semiconductive layer 1d, and a main sheath 1f surrounding the bulging tape 1e, A pair of right and left semi-cylindrical cable lower covers 10 surrounding the lower half of the outer circumferential surface of a submarine cable C composed of an inner jacket 2 and an outer jacket 3 surrounding the jacket 1; A pair of left and right semi-cylindrical cable upper covers 20 surrounding the upper half of the outer peripheral surface of the submarine cable C; A plurality of cable lower support blocks 30 to which the cable lower cover 10 is mounted and is connected in a longitudinal direction of the submarine cable C in a refracting manner; A pair of left and right cable upper support blocks 40 to which the cable upper cover 20 is mounted and which is vertically rotatably connected to both upper sides of the cable lower support block 30; And a buoy (50) bound to the upper cable support block (40)
The cable lower cover 10 and the cable upper cover 20 are formed of synthetic resin,
The lower cable support block 30 includes a reinforcing bar assembly 31 composed of a plurality of longitudinal reinforcing bars 31a and transverse reinforcing bars 31b coupled to each other, a concrete covering 32 covering the reinforcing bar assembly 31, An upper hinge piece 33 welded to the reinforcing bar assembly 31 and protruding from the upper surface of the concrete cover 32 and welded to the reinforcing bar assembly 31 to protrude from the front surface of the concrete cover 32 A rear hinge piece 35 welded to the reinforcing bar assembly 31 and protruding from the rear surface of the concrete cover 32 and a front hinge piece 35 inserted into the front and rear hinge pieces 34, And a hinge pin (36)
The concrete cover 32 further includes a semicircular cover installation groove 32a formed on the upper surface thereof and into which the cable lower cover 10 is inserted and a plurality of articulating grooves 32b formed on the lower surface and the front, In addition,
The upper surface hinge piece 33, the front surface hinge piece 34 and the rear surface hinge piece 35 are welded to the welded parts 33a, 34a and 35a welded to the steel assembly 31, And hinged portions 33b, 34b and 35b protruding from the upper surface, the front surface and the rear surface of the concrete cover 32,
The upper cable support block 40 includes a reinforcing bar assembly 41 composed of a longitudinal reinforcing bar 41a and a transverse reinforcing bar 41b to be coupled to each other, A lower hinge piece 43 welded to the reinforcement assembly 41 and protruding from the lower surface of the concrete cover 42 corresponding to the upper hinge piece 33; A hinge pin 44 inserted into the upper and lower hinge pieces 33 and 43 and an upper supporting block engaging piece 45 welded to the reinforcing frame assembly 41 and protruding from the upper surface of the concrete covering 42, An engaging bolt 46a passing through the upper supporting block engaging piece 45 and an engaging nut 46b fastened to the upper supporting block engaging piece 45 and a fixing nut 46b welded to the reinforcing frame assembly 41 and projecting from the upper surface of the concrete covering 42 And a plurality of buoy connecting rings 47,
The concrete cover 42 forms an outer surface of the cable upper support block 40 and further includes a semicircular cover installation groove 42a formed on the lower surface thereof and into which the cable upper cover 20 is inserted,
The hinge piece 43 is composed of a welded portion 43a welded to the steel bar assembly 41 and a hinge portion 43b integrally formed with the welded portion 43a and projecting from the lower surface of the concrete jacket 42 And,
The upper supporting block engaging piece 45 includes a welding portion 45a welded to the reinforcing bar assembly 41 and an engaging portion 45a integrally formed with the welding portion 45a and projecting from the upper surface of the concrete covering 42 45b,
The buoy connection ring 47 includes a welded portion 47a welded to the steel bar assembly 41 and a ring portion 47b integrally formed with the welded portion 47a and projecting from the upper surface of the concrete cover 42 Respectively,
The buoy 50 includes a buoy body 51 and a wire rope 52 fixed to a lower surface of the buoy body 51 and bound to a ring 47b of the buoy connection ring 47 Submarine cable Distribution wire to fix the wire structure.

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