KR101408050B1 - Fixing Flange Assembly of Submarine Power Cable for Transmission-Distribution and Method of Installing thereof - Google Patents

Abstract

The present invention relates to a fixing flange assembly which is installed at the end part of a submarine power cable passing through the sea bottom and put ashore and, more specifically, to a fixing flange assembly capable of preventing the submarine cable from pulling to the sea and blocking vibration delivered through the submarine power cable by fixing the submarine cable before connecting the submarine power cable to a cylindrical pole, a marine tower, a wind generator, or a manhole while grounding the submarine cable; increasing grounding efficiency; and shortening a construction time and a construction method thereof.

Description

Technical Field [0001] The present invention relates to a flange assembly for a submarine power cable for transmission and distribution,

The present invention relates to an instrumentation flange assembly installed at the end of a submarine power cable that has been taken over the sea floor, and more particularly, to an instrumentation flange assembly installed on an end of a submarine power cable, And the earth is cut off from the jacket at the end of the submarine power cable so that the armor wire is exposed to the curved surface. Increase the grounding area by making the fixation while bending backward to have the same radius of curvature as the formed instrument flange, and strengthening the durability of the connecting part by fixing the collapsed armor wire by the tightening clamp. And a method of manufacturing the same.

Submarine power cables are power lines that are installed to power the islands or to transmit power across the seabed at marine wind turbines. The distribution submarine power cable 50 constitutes a three-phase cable 54 with a cable formed by a conductor 541, a cable inner skin layer 542, a shield layer 543 and a cable outer skin layer 544 as shown in FIG. 1 The three-phase cable 54 and the optical cable 55 are sequentially wrapped with the inner layer 53, the armor wire 52 and the outer layer 51 and the inner layer and the outer layer are formed in multiple layers .

General power cables are grounded for many safety purposes such as prevention of electric shock, suppression of rise of electric potential in case of abnormality, prevention of trouble due to high frequency noise, securing of reference potential and prevention of dielectric breakdown at abnormal voltage. And has a structure that can not easily be grounded due to the specificity of the environment. In addition to the above discussion, the purpose of grounding is many, but it will be less related to the flange assembly of this subsea power cable.

In other words, grounding is provided for safety of life and property, and for the stable operation of various electric and electronic equipments. However, there is no place where the intermediate connection section of the submarine power cable minimizes potential or potential difference like earth, Since the ground current is continuously supplied to the outside of the wire and the three-phase power cable, the potential of the circulating current or the ground current at the last end point is high. It can be seen that the high-potential circulating current or ground current of such a submarine power cable does not flow uniformly in various directions, and the convergence phenomenon that occurs at irregularly flowing points occurs and the electric phase becomes unstable.

The instrument flange assembly, which is the connecting device of the submarine power cable end which is currently used in Korea, is mostly imported from Japan and Holland. The connection methods of these imported products are different, and the grounding efficiency is reduced, shortening the insulation life of the submarine power cable, It is one of the main causes of the accident.

Instrument flange assemblies are not environmentally sensitive, such as underwater cabling, but require continuous tensile strength and weather protection to ensure grounding efficiency. Typical factors for improving the grounding efficiency of the submarine power cable are the connection cross-sectional area and the electrical conductivity.

The connecting cross-sectional area in the present invention is the contact area for how much ground current such as an abnormal current flowing in armor wire and three-phase cable or induction current generated in magnetic field can flow to the instrumentation flange of the instrumentation flange assembly and the ground wire .

Equation (1) is a formula for expressing the ground wire running according to the current. It can be seen that the current (I) is proportional to the cross-sectional area (A). This is because the contact area of the armature wire and the connection flange is increased so that the flow of the ground current can be smoothly performed.

[Equation 1]

A = cross-sectional area of ground wire,

I = current flowing through the ground line (KA),

Tm = maximum allowable current (C),

Ta = ambient temperature (캜),

Tr = reference temperature (° C) of physical constant,

the thermal resistivity of the conductor at α 0 = 0 (° C.)

the thermal resistivity of the conductor when? r = Tr,

the resistivity (μΩ / cm 3) of the conductor when ρr = Tr,

K ₀ = 1 / 留 0,

tc = energization time (s),

TCAP = heat capacity coefficient (J / cm3. C)

The conventional instrumentation flange assembly 120 of FIG. 2A has two stainless steel ring-shaped instrument flanges 121 and 122, and has a cylindrical shape that does not consider the curvature of the armor wire 123, so that the connecting cross-sectional area is extremely limited. Also, since the grounding method of the three-phase cable 124 also has a reduced grounding function and there is no separate connection enclosure, the function of the enclosure is added to the heat-shrinkable tube. This requires taping using a rubber tape and an insulating tape and a long time of construction because the repeated heat shrinking tube must be covered.

FIG. 2B illustrates another type of conventional instrumentation flange assembly 130 that uses an enclosure to reduce grounding efficiency and time of construction. Since the total weight of the enclosure is 80 kg or more, it is difficult to perform work in a manhole near the sea . In addition, since the conventional instrumentation flange assembly has a large volume, most of the assembly is assembled in left and right symmetrical shapes, but this causes the grounding efficiency to be lower than that of the single integral type. Therefore, there is a problem that grounding can not be performed inside and the grounding work must be performed again, and there is also a limit to the pulling of the submarine power cable toward the sea side.

Conductivity is an indicator of how well a conductor is to flow electricity. The conductor has to have a good electric conductivity (6.17 * 10 ^7), copper (5.80 × 10 ^7), gold (4.10 * 10 ^7), chromium (3.85 * 10 ^7), aluminum (3.82 × 10 ^7), tungsten ( 1.82 * 10 ^7), and zinc (1.67 * 10 ^7), brass (1.50 * 10 ⁷⁾ nickel (1.45 * 10 ^7), iron (1.03 * 10 ^7), bronze (1.00 × 10 ^6), platinum (9.52 * 10 ⁶ ), solder (7.00 x 10 ⁶ ), lead (4.56 x 10 ⁶ ), germanium (2.20 x 10 ⁶ ), steel (2.00 x 10 ⁶ ), and stainless steel (1.10 x 10 ⁶ ).

The conventional instrumentation flange assembly of FIG. 2A is made of stainless steel (ST 304), which is good for rust prevention, but has a lower conductivity than iron. In addition, tensile strength is also limited by the fact that the armor wire is pressed with two clamps.

Next, the conventional instrumentation flange assembly of FIG. 2B is made of iron as a base material and can contaminate the environment by forming zinc plating thereon. Since it is not semi-permanent, rapid corrosion occurs after a certain period of time. In addition, the size of the enclosure of the instrument flange assembly has become larger than necessary because the top plate size has been extended to the length of the wire (200 mm) to increase the contact cross-sectional area.

As described above, a method of increasing the size of the instrument flange assembly to increase the contact area between the submarine power cable and the instrument flange assembly has been proposed, but this increases the manufacturing cost of the instrument flange assembly and, due to the increased weight and volume, This is a disadvantage in that the construction time is increased.

Accordingly, the present invention provides a flange assembly for a submarine power cable system,

The instrument flange of the instrumentation flange assembly is formed as a curved surface and the armature wire of the submarine power cable is bent to the rear while being curved so as to be fixed to the tightening clamp so that the grounding efficiency is increased by increasing the contact area .

Further, according to the present invention, the outer casing installed on the submarine power cable and the tightening clamp are brought into contact with each other by the tapered surface, so that even if tensile force acts on the armor wire in the sea direction, the submarine power cable is strongly gripped to prevent pulling, So as to enable safe transmission of electric power.

It is another object of the present invention to improve the workability of the instrumentation flange assembly by selectively replacing the upper portion of the submarine power cable in contact with the three-phase cable in the instrument flange assembly so as to replace the upper enclosure according to the size of the cable.

According to an aspect of the present invention, there is provided a submarine power cable system flange assembly for a transmission /

A submarine power cable, through which the power supply and communication connection between the land and marine structures is made to pass through the seabed, is fixed to the land or marine structure and the grounding current generated in the submarine power cable is grounded externally. Wherein the instrument flange is divided into an upper flange and a lower flange so as to be fastened by a bolt and each has a through hole at the center thereof to allow a submarine power cable to be inserted therethrough, A grounding current is transmitted through the armor wire cut off to expose the outer surface of the submarine power cable between the flange and the lower flange, and a grounding bolt is connected to one side of the upper flange and the lower flange, Three-phase cable of armor wire and submarine power cable Wherein the lower flange is formed as an elliptical sphere and the lower surface of the upper flange is formed as an elliptical groove corresponding to the upper surface of the lower flange to increase the contact area with the armor wire .

And a tightening clamp is further provided at a lower portion of the instrumentation flange to fix the armature wire end portion to a submarine power cable at a position spaced apart by a certain distance.

An enclosure flange having a through hole through which a submarine power cable is inserted at the center and a coupling hole fixed at a lower portion of the enclosure; An outlet tube portion having a reduced diameter so as to allow only the three-phase cable to pass through and a grounding hole to which an external grounding wire is connected is formed at an upper end thereof; And a body.

According to the present invention, there is provided a flange assembly for a transmission /

The instrument flange is formed as a curved surface, and the armor wire is bent in the opposite direction to be in continuous contact with the instrument flange, thereby increasing the contact area and increasing the grounding efficiency.

In addition, when the tightening clamp for fixing the armor wire is coupled to the outer flange by the tapered surface so that the tensile force pulling the submarine power cable in the marine direction acts, the tightening portion of the tightening clamp is moved along the tapered surface of the outer flange Pressurization can be done to offset the tensile force, thus enhancing durability and keeping the submarine power cable safe.

In addition, the main body of the enclosure may be constructed by separating the upper enclosure body from which the three-phase cable is to be discharged, thereby replacing only the upper enclosure main body so as to correspond to the diameters of various submarine power cables. It is possible to provide a useful device and a construction method which can shorten the overall construction time by saving the time required for taping by integrally solidifying the inside of the enclosure by injecting a hardener.

1 is a schematic cross-sectional view showing the structure of a general submarine power cable;
Figures 2a and 2b are schematic diagrams and photographs showing a conventional instrument flange;
Figure 3 is an installation cross-sectional view of a submarine power cable with the instrument flange and tightening clamp of the present invention.
4A is a top view and cross-sectional view of an upper flange of a instrument flange in accordance with the present invention.
Figure 4b is a top view and a cross-sectional view of the lower flange of the instrument flange according to the present invention.
Figure 4c is an assembled cross-sectional view of a instrument flange comprised of an upper flange and a lower flange in accordance with the present invention;
4D is a schematic view showing an upper flange formed with a non-slip groove or a non-slip projection according to the present invention.
5 is a top view and front view of a tightening clamp of a instrumentation flange assembly in accordance with the present invention.
6A is an exploded cross-sectional view of an enclosure according to the present invention.
FIG. 6B is an enlarged view of a part of the connecting flange and tightening clamp according to the present invention. FIG.
7 is an installation cross-sectional view showing a mounted state of the instrumentation flange assembly according to the present invention.
8 is a schematic view showing an example of mounting a detachable enclosure main body according to the present invention.
9A to 10 are a plan view, a side view, and an operation state view showing another embodiment of the enclosure main body according to the present invention.

The instrumentation flange assembly according to the present invention is characterized in that a submarine power cable through which a power supply and a communication connection are made between land and sea structures through the seabed is fixed to a land or sea structure, A device flange assembly comprising a device flange for grounding and an enclosure enclosing the device flange, wherein the device flange is separated into an upper flange and a lower flange to be fastened by bolts, each having a through- And a ground current is transmitted through the armor wire cut to expose a certain length, and one side of the upper flange and the lower flange are connected to the outside A grounding bolt is connected to the ground wire, And the grounding current received from the three-phase cable of the submarine power cable is grounded to the outside, wherein the lower flange is formed as an ellipse, and the lower surface of the upper flange is formed as an elliptical groove corresponding to the upper surface of the lower flange, Is increased.

In addition, a plurality of anti-slip grooves or anti-slip projections may be formed concentrically on either or both of the lower surface of the upper flange and the upper surface of the lower flange.

Further, a tightening clamp for fixing the end of the armature wire to the submarine power cable is provided at a position spaced by a certain distance from the bottom of the instrumentation flange so that the armor wire folded in the reverse direction is brought into close contact with the outer surface of the lower flange of the instrumentation flange, Can be increased.

Also, the enclosure may include: an enclosure flange having a through hole through which a submarine power cable is inserted at a center thereof and a coupling hole fixed to the facility at a lower portion thereof; An outlet tube portion having a reduced diameter so as to allow only the three-phase cable to pass through and a grounding hole to which an external grounding wire is connected is formed at an upper end thereof; And a body.

Wherein the tightening clamp is formed with a plurality of tightening portions extending downward to surround the submarine power cable, the extended outer portions being formed with tapered surfaces inclined in the center direction, the outer flange being protruded upward at the center portion, Wherein an inner surface of the annular protrusion forms a tapered surface corresponding to a tapered surface of the clamping clamp so that a tensile force acting on the submarine power cable is applied to the tapered surface of the clamping clamp and the flange of the enclosure So that it can act as a clamping force to the tightening clamp.

Such an enclosure main body may be divided into an upper enclosure main body having a discharge pipe portion and a lower enclosure main body containing a device flange so that only the upper enclosure main body having various diameters of the discharge pipe portion can be replaced to accommodate various sizes of three-

In addition, in the method using the instrument flange assembly of the present invention,

Detaching the shell from a point spaced a certain distance from the end of the submarine power cable to expose the armor wire; Calculating the distance to be connected to the tightening clamp through the instrument flange by cutting out the expressed armor wire; Inserting the enclosure flange and the sealing ring into the submarine power cable first; Installing a lower flange of the instrument flange while preventing a portion of the submarine power cable where the lower flange is to be installed is wound and backed by a self-adhesive tape; Bending the armor wires one by one to come in contact with the outer surface of the lower flange and removing the endothelium; Inserting and mounting an upper flange on an armor wire folded in a reverse direction, tightening the upper flange and the lower flange by tightening them with bolts; Securing the armor wire end to the shell of the submarine power cable using a tightening clamp; Connecting a grounding clamp to the exposed shielding layer and connecting the grounding wire to the grounding bolt fixed to the upper flange with an inner grounding line; Connecting an external ground wire to the ground bolt of the upper flange; Moving the enclosure flange to engage with the tightening portion of the tightening clamp in the annular protrusion and fixing the tightening portion of the tightening clamp with a sealing ring, and fastening the enclosure main body with the submarine power cable and bolting with an outer flange; And injecting a hardening agent into the inner space through the injection port on one side of the enclosure main body to integrate the same.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail with reference to the accompanying drawings. It should be understood, however, that the appended drawings illustrate only the contents and scope of technology of the present invention, and the technical scope of the present invention is not limited thereto. It will be apparent to those skilled in the art that various changes and modifications can be made within the scope of the technical idea of the present invention based on these examples.

The instrumentation flange assembly used in the present invention is designed to secure the undersea power cable, which is connected to the power supply and communication connection between the land and sea structures through the sea bed, to the land or sea structure, The position is fixed to prevent the transmission of vibration due to tension or wave. In addition, the ground current from the three-phase cable improves the conductivity by increasing the cross-sectional area of connection with the instrument flange so that it can be grounded to the outside, and the taping process of the three-phase cable is eliminated by injecting the hardener by the enclosure. . Where the instrument refers to the portion where the submarine power cable is raised above sea level and grounded and secured.

The instrument flange assembly installed at the end of the submarine power cable according to the present invention includes a instrument flange for wrapping and fixing the armor wire of the submarine power cable in the reverse direction.

Figure 4 is a top view and a cross-sectional view of the upper flange of the instrument flange according to the present invention, Figure 4b is a side view of the lower flange of the instrument flange according to the invention, And FIG. 4C is an assembled cross-sectional view of a metering flange comprised of an upper flange and a lower flange in accordance with the present invention.

As noted, the instrumentation flange 20 is configured as an upper flange 21 and a lower flange 22 in the form of a ring with a through hole through which a submarine power cable 50 is inserted into the center.

An armor wire 52 of a submarine power cable is interposed between the upper flange 21 and the lower flange 22. The lower flange 22 is curved so as to have an ellipsoidal shape on its outer surface as shown in FIG. So that the armor wire 52 bent in a direction opposite to the advancing direction is bent while contacting the upper and side surfaces of the lower flange 22. Further, the upper flange 21 is provided on the lower flange, and is closely attached to the lower flange by bolt fastening. The lower surface of the upper flange is formed into an elliptical groove corresponding to the curved surface of the lower flange so that the armor wire interposed between the upper flange and the lower flange is tightly pressed when the bolt is fastened. At this time, the bolts of the upper flange and the lower flange are formed by a plurality of bolt holes 23 as shown in the figure, and they are formed in various patterns such as an inner arrangement having a concentric circle and an outer arrangement, .

The instrumentation flange 20 is formed of a conductive metal material to improve the grounding efficiency by increasing the contact area with the armor wire 52 so that the earthing current is quickly transmitted through the armor wire and is grounded to the outside. Therefore, the instrumentation flange 20 is integrally formed with a grounding bolt 26 on one side of the upper flange 21 so as to be connected to an external grounding line 263, and the grounding bolt 26 is connected to a three- And an internal ground line 262 so as to be grounded to the outside.

As shown in FIG. 4D, on either or both of the lower surface of the upper flange 21 and the upper surface of the lower flange 22, a plurality of non-slidable grooves 24 or non-slip projections 25 So that the armor wire 52 can be more firmly fixed to the instrument flange 20. At this time, the upper flange 21 and the lower flange may be formed to have a slip prevention groove on one side and a non-slip protrusion on the other side to engage with each other.

Figure 5 is a top view and front view of a tightening clamp of a instrument flange assembly in accordance with the present invention.

As shown in the drawings, the tightening clamp 30 according to the present invention may be formed into a semicircular shape and may be formed into a circular shape having one pair of openings or a pair of openings. This tightening clamp secures the armor wire and the submarine power cable together by fastening the submarine power cable 50 and the armor wire 52 closely attached to the outer surface of the submarine power cable.

The tightening clamp 30 may further include a downwardly extending throttle portion 31 to be coupled to an enclosure flange 41 described later. The throttle portion 31 of the tightening clamp is inserted into the annular protruding portion 412 formed on the outer flange 41 by protruding from the band-shaped main body in two or more in the downward direction where the outer flange is engaged. Here, the throttle portion 31 may be formed as a tapered surface 311 having a concave conical shape with an outer surface tilted in the center direction, so that a tightening force toward the center can be generated as it is inserted into the annular protruding portion 412 of the enclosure flange .

The instrument flange 20 and the tightening clamp 30 may be coated with a nanomaterial coating agent or a rust preventive agent on the outer surface of the instrument flange 20 to prevent corrosion and be used semi-permanently.

6A is an exploded cross-sectional view illustrating an enclosure containing a instrument flange and a tightening clamp according to the present invention.

The enclosure 40 includes an enclosure flange 41 formed with a through hole through which the undersea power cable 50 is inserted at the center and a coupling hole fixed to the facility at a lower portion thereof and an enclosure flange 41 having the instrumentation flange 20 and the tightening clamps And an outer casing main body 42 which is connected to the outer casing flange.

A plurality of bolt fastening holes 411 are formed on the outside of the housing flange 41 to form a bolt fastening with the housing body 42. An annular protruding portion 412 protruding upward is formed at an inner center portion .

The annular protrusion 412 is formed along the outer surface of the submarine power cable inserted with reference to FIG. 6B, and an extended groove portion 413 is formed at the lower portion to prevent a gap between the submarine power cable and the outer flange from being generated So that the enclosure flange is prevented from being pushed downward by the inserting sealing ring.

A tapered surface 414 corresponding to the tapered surface 311 of the tightening clamp throttle portion is formed on the upper portion of the annular protrusion 412 so that the tapered surface 311 of the tightening clamp throttle portion protrudes from the annular protrusion tapered surface 414, To tighten inward so that stronger tightening forces can be generated in the direction of the submarine power cable.

Further, the outer flange 41 may be formed to have a larger diameter than the enclosure body, and a plurality of bolt fastening holes may be formed on the outer side to fasten bolts to the facility to fix the flange 41. Alternatively, as shown in the figure, And a bolt fastening hole 411 is formed in the annular protrusion protruding downward to bolt the bolt to the facility. At this time, the fastening with the facility can be made such that the bottom of the facility and the flange of the enclosure are spaced apart from each other by a certain distance, thereby preventing the enclosure from being exposed to the water flowing on the floor of the facility.

In addition, a finishing cap 415 may be fixed to the lower end of the annular protrusion protruded to the lower portion, and then the coupling with the facility may be performed. At this time, the fitting of the enclosure flange can be made such that the bolt engages with the finishing cap so that the fitting of the enclosure flange and the facility can be performed, and the combination of the finishing cap and the facility can be alternately performed.

Next, the enclosure main body 42 is formed with a discharge tube portion 421 through which the shell and the inner skin of the submarine power cable are detached and the three-phase cable 54 exposed with the armor wire removed, A ground hole 422 into which the ground wire 263 is inserted is formed.

The diameter of the discharge tube portion 421 is formed to be a tube having a diameter smaller than the diameter of a portion enclosing the instrumentation flange so as to pass through only the three-phase cable and the optical communication cable. And a finishing cap may be coupled to the upper end of the discharge pipe portion to maintain the airtightness of the inner space of the enclosure.

In addition, one or a plurality of hardening agent injection ports 423 may be formed in the discharge pipe portion 421 of the enclosure main body 42 to inject the hardener into the inner space of the enclosure completed in the final assembly, and the peeled portion of the submarine power cable may be separately taped Thereby enabling rapid construction.

8, the enclosure main body 42 is divided into an upper enclosure main body 44 formed with a discharge pipe portion and a lower enclosure main body 45 enclosing a device flange, and the upper enclosure main body 42 and the lower enclosure main body 45, And a flange may be formed at the end portion so as to be integrally formed by bolt fastening.

The separation of the upper enclosure main body 44 having the discharge tube portion 421 in order to facilitate replacement of the discharge tube portion according to the three-phase cable of various diameters. That is, since the three-phase cable of the submarine power cable has various cross-sectional areas of 60, 200, 400, 500, and 1000 mm2, an enclosure main body having a discharge pipe portion having a corresponding diameter should be installed. However, in the method of replacing the entire body of the enclosure due to the diameter of the exhaust pipe, it is necessary to prepare a plurality of enclosure bodies which occupy a large volume for each exhaust pipe size, so that an excessive cost is incurred in preparation of parts, and storage and transportability are also lowered. Accordingly, only the upper enclosure main body 44 provided with the discharge pipe portion is prepared in various sizes, and the lower enclosure main body 45 is used in a unified form, thereby minimizing the deformation portion, thereby improving the component storage and transportability while reducing component preparation cost. . The separation structure of the enclosure main body may be provided in a form in which only the discharge pipe portion is detached in addition to the form shown in the figures.

In another embodiment of the enclosure main body according to the present invention, as shown in Figs. 9A, 9B and 10, the lower part may be formed in a cone shape.

The enclosure main body 46 includes a discharge pipe portion 461 through which a trunk cable is inserted, a horizontal expansion portion 462 extending outward from the lower end of the discharge pipe portion to increase the diameter, And a lower end flange portion 464 extending horizontally outward from the lower end of the main body receiving portion to be coupled with the outer flange portion. And a vertical flange portion 465 is formed at the separated end portion so as to be provided in a form of joining the two divided enclosure bodies.

In other words, the enclosure main body 46 is divided into two parts on the basis of the vertical direction, and a pair of enclosure main bodies 46, which are divided into left and right parts in a state where the armor wires are completely fixed, It can be tightened after making contact from both sides of the instrument flange.

The upper portion of the enclosure main body 46 where the instrumentation flange 20 is located is formed to have a larger diameter and the lower portion of the enclosure body 46 is reduced in diameter to minimize the internal void space so that the filling amount of the hardener .

In addition, a plurality of bolt fastening holes 467 may be formed in the horizontal expanding portion 462 of the housing body so as to be bolted to the instrument flange. 10, the length of the bolt 27 connecting the instrumentation flange 20 is extended so as to be exposed to the outside through the bolt fastening hole 467 of the body of the enclosure, and the nut is coupled to the instrument flange 20 The enclosure main body 46 can be integrated. That is, the bolt 27 connecting the instrument flange and the enclosure main body is inserted upward from the lower end of the lower flange 22, the lower flange 22 and the upper flange 21 are sequentially inserted, Thereby fixing the upper flange and the lower flange.

The bolts 27 projecting upward from the upper flange 21 are engaged with the outer casing main body 46 so that the ends of the bolts are inserted into the bolt fastening holes 467 of the casing main body, And the second nut is fastened to the end of the bolt so that the instrument flange 20 and the enclosure main body 46 can be integrated at a constant interval. And the vertical flange () between the pair of outer casing bodies which are in contact with each other at the same time as the second nut tightening is fastened by bolts. Here, the upper flange 21 and the enclosure main body 46 are fastened to each other by fastening and fixing the pair of enclosure main bodies to the enclosure flange 41, and then fastening the bolts 27 protruded to the upper portion of the enclosure main body with the second nut The upper flange and the enclosure main body can be integrally fixed at a predetermined distance.

The instrument flange assembly 10 composed of the instrument flange 20 and the tightening clamp 30 and the enclosure 40 has the armor wire 52 brought into contact with the upper flange 21 of the instrumentation flange, The ground wire 263 is grounded by the grounding bolt 26 and the three-phase cable 54 is grounded to some length as shown in FIG. 3 to connect the inner ground wire 262 to the ground clamp 261 And one end of the internal ground wire is connected to the upper flange grounding bolt to ground the external ground wire so that the ground current of the submarine power cable 50 is grounded by the external ground wire 263 to ensure stable power supply.

7, the armor wire 52 is bent in the reverse direction by the instrumentation flange 20 to be fixed to the tightening clamp 30, and the tightening clamp 30, The flange 31 is fixedly coupled to the annular protrusion 412 of the flange by means of tapered surfaces 311 and 414 and the flange body 42 includes the flange 20 and the clamping clamp 30, 41). In addition, the three-phase cable 54 and the grounding bolt 26 are connected to each other by the inner ground wire 262 and the ground clamp 261 to ground the three-phase cable to the outside. In such a structure, a hardening agent is injected into the inside of the enclosure 40 to cover the empty space, so that the instrumentation flange assembly can be integrally formed without additional taping work on the cable.

In a method of constructing a instrumentation flange assembly according to the present invention,

A step of calculating the distance from the position where the instrumentation flange assembly is installed to the standing edge and cutting the seabed power cable laid out first and then breaking off the shell from a point spaced a certain distance from the end of the seabed power cable to expose the armor wire .

The exposed armor wire cuts off by calculating the distance to be coupled to the tightening clamp through the instrument flange. Approximately 500 mm of armor wire should be left.

Insert the enclosure flange and sealing ring into the submarine power cable first.

In the submarine power cable, the part where the lower flange is to be installed is wound 8 ~ 15 times with self-adhesive tape to prevent the lower flange from being pushed back in the construction process, and the lower flange of the instrument flange is inserted. In this step, a step of removing the asphalt layer, which is a foreign material on the surface of the armor wire, is performed using a knife or a solvent, and a rubber tape is applied to the skin of the submarine power cable from 300 to 400 mm in length, To protect the epidermis.

Next, the remaining foreign matter adhered to the surface of the armor wire is removed, and the armor wire is bent in the reverse direction one by one so as to contact the outer surface of the lower flange, and the endothelium is removed. Here, before the armor wire is completely bent, a point 300 mm from the lower end flange is marked and cut by a cutter is included.

Next, the upper flange is inserted and seated on the armor wire folded in the reverse direction, and the upper flange and the lower flange are fastened with bolts to closely contact the armor wire so as to be fixed so as not to move.

When the coupling of the instrument flange is completed, the armature wire end is fixed tightly to the shell of the submarine power cable using a tightening clamp. The end of the fixed armor wire can be wrapped with insulating tape or rubber tape.

Next, the outer shell of the three-phase cable is peeled off and a grounding clamp is connected to the exposed shielding layer, and the inner grounding wire is connected to the grounding bolt fixed to the upper flange. Here, the sheath of the three-phase cable is peeled by about 50 mm, and the ground clamp is joined to the exposed shield layer.

Further, an external ground wire is connected to the ground bolt of the upper flange to ground the upper flange to the outside.

When the connection of the grounding wire is completed, the flange is moved to fit the tightening portion of the tightening clamp into the annular protrusion. At this time, the sealing ring is fitted and fixed in the lower groove of the flange of the housing. Also, by inserting the enclosure main body into the submarine power cable and inserting the external ground wire to the outside of the enclosure main body, enclose the instrument flange inside the enclosure main body and bolt the bottom of the enclosure main body and the enclosure flange.

When the installation of the enclosure is completed, the hardening agent is injected into the inner space of the enclosure through the injection port formed at one side of the enclosure main body so that the inside of the enclosure is filled with the hardening agent. In this case, the injection port is formed in a plurality, and the hardening agent is injected through one injection port in a state where the enclosure is vertically installed, so that the air inside the enclosure is discharged to the other injection port, so that the hardening agent can be easily injected into the enclosure And the internal construction is integrated by solidification of the injected hardener, thereby completing the construction of the instrument flange assembly.

10: Instrument flange assembly
20: Instrument flange
21: upper flange 22: lower flange
23: bolt hole 24: non-slip groove
25: Slip prevention projection 26: Grounding bolt
27: Bolt
261: Ground clamp 262: Internal ground wire
263: External ground wire
30: Fastening clamp
31: Tightening part 311: Tapered surface
40: Enclosure
41: enclosure flange 42,46: enclosure body
43: sealing ring 44: upper enclosure body
45: Lower enclosure body
411, 467: bolt fastening hole 412:
413: groove portion 414: tapered surface
415: Finishing cap 421, 461:
422: grounding hole 423:
462: Horizontal expansion part 463: Main body accommodating part
464: lower flange portion 465: horizontal flange portion
50: Submarine power cable
51: envelope 52: armor wire
53: inner skin 54: three-phase cable
55: Optical cable
541: conductor 542: cable inner layer
543: Shielding layer 544: Cable sheath layer

Claims (9)

A submarine power cable, through which the power supply and communication connection between the land and marine structures is made to pass through the seabed, is fixed to the land or marine structure and the grounding current generated in the submarine power cable is grounded externally. And an enclosure enclosing the instrument flange assembly,
The instrumentation flange is divided into an upper flange and a lower flange so as to be fastened by bolts and each has a through hole formed at the center thereof to allow a submarine power cable to be inserted therein. And a grounding bolt is connected to one side of the upper flange and the lower flange so as to be connected to the armature wire and the three-phase cable of the submarine power cable Wherein the lower flange is formed in an elliptical shape and the lower surface of the upper flange is formed into an elliptical groove corresponding to the upper surface of the lower flange so as to increase a contact area with the armor wire,
And a tightening clamp for fixing the armature end of the armature wire to the submarine power cable at a position spaced by a predetermined distance from the bottom of the instrumentation flange so that the armor wire folded in the reverse direction is brought into close contact with the outer surface of the lower flange of the instrumentation flange, A featured instrument flange assembly. The method according to claim 1,
Wherein a plurality of anti-slip grooves or non-slip projections are formed concentrically on either or both of the lower surface of the upper flange and the upper surface of the lower flange. delete The method according to claim 1,
The enclosure
An enclosure flange having a through hole through which a submarine power cable is inserted at the center and a coupling hole fixed at a lower portion thereof;
And an enclosure main body enclosing the instrumentation flange and the tightening clamp to be coupled to the enclosure flange and having an outlet tube portion having a reduced diameter to allow the exposed three- . 5. The method of claim 4,
Wherein the tightening clamps are formed with a plurality of fastening portions extending downward so as to surround the submarine power cable, the extended outer surfaces being formed with tapered surfaces inclined in the center direction,
Wherein the outer flange has an annular protrusion protruding upward at a central portion thereof to receive a throttle portion of the tightening clamp, wherein an inner surface of the annular protrusion forms a tapered surface corresponding to a tapered surface of the tightening clamp,
Wherein the tension force acting on the submarine power cable acts as a clamping force on the tightening clamp by the tightening clamp and the tapered surface of the enclosure flange. The method according to claim 4 or 5,
The enclosure main body
Characterized in that the upper enclosure main body having a discharge pipe portion and the lower enclosure main body containing the instrumentation flange are separated from each other so that only the upper enclosure main body having various diameters of the discharge pipe portion can be replaced, Flange assembly. The method according to claim 4 or 5,
The enclosure main body
A drain pipe portion through which the trunk cable is inserted; a horizontal pipe portion extending outward from the lower end of the pipe pipe portion to increase the diameter; a cone-shaped body portion extending downward from the edge of the horizontal pipe portion, And a lower flange portion extending horizontally outwardly from the lower end of the main body receiving portion to be coupled with the outer flange,
Wherein the enclosure body is configured to be vertically bisected and a vertical flange portion is formed at the separated end to engage the two enclosure bodies that are bisected. 8. The method of claim 7,
Wherein a plurality of bolt fastening holes are formed in the horizontal expanding portion of the enclosure main body and are bolted to the instrumentation flange. An instrument flange according to the present invention comprising an upper flange and a lower flange, the instrument flange having a curved contact surface, a clamping clamp for fixing the armor wire end, and an enclosure comprising an enclosure flange enclosing the instrument flange and an enclosure body. In a method of constructing an assembly,
Detaching the shell from a point spaced a certain distance from the end of the submarine power cable to expose the armor wire;
Calculating the distance to be connected to the tightening clamp through the instrument flange by cutting out the expressed armor wire;
Inserting the enclosure flange and the sealing ring into the submarine power cable first;
Installing a lower flange of the instrument flange while preventing a portion of the submarine power cable where the lower flange is to be installed is wound and backed by a self-adhesive tape;
Bending the armor wires one by one to come in contact with the outer surface of the lower flange and removing the endothelium;
Inserting and mounting an upper flange on an armor wire folded in a reverse direction, tightening the upper flange and the lower flange by tightening them with bolts;
Securing the armor wire end to the shell of the submarine power cable using a tightening clamp;
Connecting a grounding clamp to the exposed shielding layer and connecting the grounding wire to the grounding bolt fixed to the upper flange with an inner grounding line;
Connecting an external ground wire to the ground bolt of the upper flange;
Moving the enclosure flange to engage with the tightening portion of the tightening clamp in the annular protrusion and fixing the tightening portion of the tightening clamp with a sealing ring, and fastening the enclosure main body with the submarine power cable and bolting with an outer flange;
And injecting a hardening agent into the inner space through the injection port on one side of the enclosure main body to integrate the assembly.

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