KR101810357B1 - System and method for jointing power cable using joint box - Google Patents

Abstract

The present invention relates to a direct current power cable interface system using an interface box for a power cable with improved surface electric field properties and improved insulating performance, and a method for connecting a direct current power cable. The direct current power cable interface system comprises: a pair of direct current power cables having a conductor, an internal semiconductive layer, a cable insulating layer, and an external semiconductive layer; and the interface box for interconnecting the pair of direct current power cables.

Description

TECHNICAL FIELD The present invention relates to a DC power cable intermediate connection system and a DC power cable connection method using an intermediate connection box for a power cable,

The present invention relates to a DC power cable intermediate connection system and a DC power cable connection method using an intermediate connection box for a power cable.

Generally, a power cable is used to power a desired location through the ground, ground, or seabed using a power-supplying conductor.

The power cables are connected by a joint box at intervals of several hundred meters or tens of kilometers, and the ends of the power cables are connected to the wires by a termination connection box.

Referring to FIG. 1, when the power cable is connected to the intermediate connection box, the conductors 41A and 41B are first connected in a state in which the insulation layer of the cable is exposed, and insulating paper is applied to the surface of the insulation layer, 50, and then the outer semiconductive layer 46, the metal sheath 47, and the like are restored.

The first reinforcing insulating layer 51 may be formed up to the outer diameter of the cable insulating layer 44 and the second reinforcing insulating layer 52 may be formed at an outer diameter of the cable have. After the formation of the second reinforcing insulating layer 52, a protective copper tube 60 for protecting the inside of the intermediate connection box from the outside is covered.

In the intermediate junction box having such a structure, a large amount of insulating oil is injected into the protective copper pipe (60). When the cable connection system in which the cables are connected by the intermediate connection box operates, the cable connection system can vibrate as current flows through the cable at a high voltage. The intermediate connection box can be gripped and fixed to prevent movement of the intermediate connection box due to the vibration. In order to sufficiently grip the intermediate connection box, the length of the intermediate connection box, that is, the length of the protective copper pipe must be secured. As the length of the protective copper pipe becomes longer, the space E in which the reinforcing insulation layer is not formed increases, This empty space is filled with insulating oil. That is, in the case of holding the intermediate connection box more than when not holding the intermediate connection box, the length of the protective copper pipe 60 should be longer to hold the intermediate connection box stably, The protective copper pipe 60 is filled with a larger amount of insulating oil.

The insulating oil in the protective copper pipe 60 repeatedly expands and contracts in volume in accordance with the heating cycle of the cable connection system, thereby causing a change in the internal pressure of the intermediate connection box. If the amount of the insulating oil in the protective copper pipe 60 is increased according to the shape of the protective copper pipe 60 so as to grip the intermediate connection case as described above, the protective copper pipe 60 or the open- (61) is broken due to an increase in the internal pressure or the fatigue breakage of the copper tube (60) or the softened portion (61) due to repeated expansion and contraction of the insulating oil occurs, There is a problem that it is destroyed.

The height of the reinforcing insulating layer 50 may be lowered and the height of the protective copper pipe 60 may be lowered to reduce the amount of the insulating oil introduced into the protective copper pipe 60. However, when the reinforcing insulating layer 50 is formed to have a low height, the insulating layer 44 of the cable and the reinforcing insulating layer 50, the length of the intermediate connection box is increased.

It is an object of the present invention to provide a DC power cable intermediate connection system and a DC power cable connection method using an intermediate connection case for a power cable capable of reducing the length of the intermediate connection box while minimizing the amount of insulating oil injected into the intermediate connection box .

An intermediate junction box for a power cable according to an embodiment of the present invention includes a pair of DC power cables each having a conductor, an inner semiconductive layer, a cable insulation layer, and an outer semiconductive layer, and a pair of DC power cables In the DC power cable intermediate connection system including the intermediate connection box, the pair of DC power cables are provided such that the respective ends of the conductor, the inner semiconductive layer, the cable insulating layer and the outer semiconductive layer, which are sequentially exposed, The intermediate connection box includes: a conductor connection portion electrically and mechanically connecting the exposed pair of conductors; A first reinforcing insulating layer having an insulating paper wound around the conductor connecting portion, the exposed inner semiconductive layer and the cable insulating layer to form an outer diameter of the cable insulating layer and having inclined surfaces at both ends in the longitudinal direction; A reinforcing insulation layer and a slope portion surrounding the exposed cable insulation layer and having a straight portion having a constant width in the cable longitudinal direction and a slope portion formed at both ends of the straight portion and having a width in the cable longitudinal direction reduced in a radial direction of the cable A reinforcing insulating layer including a second reinforcing insulating layer; And a sloped portion formed along the outer surface of the sloping portion of the second reinforcing insulating layer and having a slope shape and having a semiconductive material, wherein the semiconductive outer semiconductive layer is formed between the first reinforcing insulating layer and the cable insulating layer And the second reinforcing insulating layer is composed of a plurality of insulating ground layers laminated on the first reinforcing insulating layer, and each of the insulating ground layers has at least one triple- Wherein the insulating paper wound around the first reinforcing insulating layer has a width smaller than a width of the third reinforcing insulating layer when the width of the insulating paper wound around the first reinforcing insulating layer is smaller than the width of the third reinforcing insulating layer And may be smaller than the width of the insulating paper forming the light-guiding portion of the reinforcing insulating layer.

In the present invention, the number of insulating paper layers impregnated in the first reinforcing insulating layer may be 80% or more of the number of insulating paper layers impregnated in the cable insulating layer.

In the present invention, the triple winding portion of one insulating layer in the second reinforcing insulating layer may be spaced apart from the triple winding portion of the insulating layer adjacent to the insulating layer by a predetermined distance.

In the present invention, the three-pitch winding portion of one of the insulating layers in the second reinforcing insulating layer is not overlapped with the three-width winding portions of the other insulating layer positioned in contact with the insulation layer .

In the present invention, the spaced distances from the third reinforcing insulating layer to the three-width winding portions of the other insulating ground layers located in contact with or in contact with the insulating ground layer in the third insulating layer, May be greater than or equal to a shortest distance between a contact portion formed in contact with neighboring wide-width windings in the insulating ground layer contacting the insulating ground layer and a three-dimensional winding portion of the insulating ground layer.

In the present invention, the triangular winding portion may be located in the straight portion without being located in the slope portion.

In the present invention, the slope portion may be composed of the light-spot winding portion.

In the present invention, the intermediate junction box may include: a metal shield layer formed on the semiconductive layer outside the junction box; A copper pipe surrounding the reinforcing insulation layer and a portion of the power cable and including an insulating oil therein; And a spacer for maintaining a gap between the copper tube and the metal shielding layer; . ≪ / RTI >

In the present invention, the conductor connecting portion may include a pair of conductors cut in a diagonal line and provided so that their end portions face each other; And a filler metal formed between the ends of the conductor.

In the present invention, a pair of conductors exposed in the cable so that the ends thereof face each other; And a conductor crimping sleeve surrounding the pair of conductor ends, wherein the outer diameter of the conductor crimping sleeve may be the same as the outer diameter of the conductor.

A method of connecting a DC power cable according to an embodiment of the present invention includes a conductor, an inner semiconductive layer, a cable insulation layer, and an outer semiconductive layer. The conductor, the inner semiconductive layer, the cable insulation layer, The method comprising the steps of: forming a conductor connecting portion by electrically and mechanically connecting the exposed pair of conductors to each other; Forming a first reinforcing insulating layer by winding up insulating paper to an outer diameter of the cable insulating layer so as to surround the conductor connecting portion, the exposed inner semiconductive layer and the cable insulating layer; Forming a second reinforcing insulating layer by winding insulating paper around the first reinforcing insulating layer and the exposed cable insulating layer; And forming a connection semiconductive outer layer surrounding the outer surface of the second reinforcing insulating layer, wherein the step of forming the second reinforcing insulating layer comprises: forming a third reinforcing insulating layer on the first reinforcing insulating layer, Wherein the step of forming the first reinforcing insulating layer includes a step of forming a first reinforcing insulating layer on the exposed portion of the cable insulating layer, A step of forming a single inclined surface at the end of the first reinforcing insulating layer so as to correspond to an end shape; winding an insulating paper having a width larger than that of the insulating paper of the triple winding portion and having a width smaller than that of the insulating paper of the light- . ≪ / RTI >

In the present invention, the step of forming the first reinforcing insulating layer may be a semi-oil immersion method in which the semi-oil immersion is wound at 80% or more of the number of layers of insulating paper wound around the cable insulating layer.

In the present invention, the step of forming the second reinforcing insulating layer may include the step of forming the third reinforcing insulating layer so that the third reinforcing insulating layer of the second reinforcing insulating layer has a width wider than the third width winding portion of the insulating layer adjacent to the insulating ground layer It is possible to dispose them apart.

In the present invention, the step of forming the second reinforcing insulating layer may include the step of forming the third reinforcing insulating layer in such a manner that the third reinforcing insulating layer of the second reinforcing insulating layer contacts the third insulating reinforcing layer, It can be arranged so as not to overlap.

In the present invention, the step of forming the second reinforcing insulating layer may include a step of forming the third reinforcing insulating layer so that the third reinforcing insulating layer has the third reinforcing insulating layer in contact with the insulating ground layer, The spaced distance to the winding portion of the width of the insulating layer is set so as to be greater than or equal to the shortest distance between the opposing portion formed in contact with the neighboring thin film windings in the insulating layer adjacent to the insulating layer and the winding- .

In the present invention, in the step of forming the second reinforcing insulating layer, the triangular winding portion may not be disposed in the slope portion.

In the present invention, in the step of forming the second reinforcing insulating layer, only the wide area winding portion may be disposed in the slope portion.

According to the present invention, there is provided a method of manufacturing a semiconductor device, comprising the steps of: forming a metal shielding layer to surround the connection semiconductive layer; Forming a spacer to surround a part of a straight portion of the second reinforcing insulating layer; Providing a copper tube surrounding the reinforcing insulation layer and a portion of the power cable; And impregnating the insulating paper of the reinforcing insulating layer by injecting and pressurizing the insulating oil into the copper tube.

In the present invention, the step of forming the metal shield layer may include winding the metal wire so as to surround the slope portion of the second reinforcing insulating layer, and forming the perforated metal plate so as to surround the straight portion of the second reinforcing insulating layer . ≪ / RTI >

In the step of forming the metal shielding layer, the perforated metal plate may be bonded and joined so as to surround the linear portion.

In the present invention, the step of forming the spacer may include a through hole having an inner diameter larger than the outer diameter of the second reinforcing insulating layer, and a recessed portion facing the through hole at an outer side thereof, And the insulating oil in the copper pipe can flow in the longitudinal direction of the intermediate connection box, the spacer can be disposed on the straight portion of the second reinforcing insulating layer.

In the present invention, the step of forming the conductor connection part may fill the filler metal between a pair of conductor ends exposed in the cable so that the ends thereof face each other.

In the present invention, the step of forming the conductor connecting portion may include arranging a conductor crimping sleeve so as to surround each end of a pair of conductors exposed in the cable so that their ends face each other, and pressing the outer surface of the conductor crimping sleeve And the outer diameter of the conductor compression sleeve and the outer diameter of the conductor may be the same.

According to an embodiment of the present invention, by improving the dielectric strength of the first reinforcing insulating layer, the insulating performance is secured, the height of the second reinforcing insulating layer is reduced, and the size of the copper tube is reduced to reduce the amount of the insulating oil in the protective copper pipe .

1 is a cross-sectional view schematically showing a cable connected by a conventional intermediate connection box.
2 is a perspective view showing an internal configuration of the power cable.
3 is a partial cutaway view schematically showing a cable connected by an intermediate connection box;
4 is a cross-sectional view showing the first reinforcing insulating layer and the second reinforcing insulating layer of the intermediate connection box shown in FIG. 3 in more detail.
5 is a cross-sectional view schematically showing the intermediate connection box shown in Fig.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited to the embodiments described herein but may be embodied in other forms. Rather, the embodiments disclosed herein are provided so that the disclosure can be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. Like reference numerals designate like elements throughout the specification.

Generally, the insulating oil impregnated cable is connected by an intermediate connection box at intervals of several hundred meters or several kilometers, and the end of the insulating oil impregnated cable is connected to the working line by the termination connection port. Hereinafter, the construction of the dielectric-oil-impregnated power cable will be described first, and the connection process of the connection box will be described.

2 is a partially cutaway perspective view showing an internal configuration of an ultra high voltage direct current power cable.

2, the power cable 100 includes a conductor 11, an inner semiconductive layer 12, a cable insulation layer 14, and an outer semiconductive layer 16, And the cable core portion 10 for preventing electric current from leaking in the cable radial direction.

The conductor 11 serves as a passage through which a current flows to transmit electric power and is made of a material having excellent conductivity and strength and flexibility suitable for cable manufacturing and use such as copper or aluminum ≪ / RTI >

2, the conductor 11 includes a rectangular central strand 11a and a square wire strand 11C composed of a square wire 11b stranded to surround the circular central strand 11a May be a rectangular conductor having an entirely circular cross section, and as another example, it may be a circular compression conductor in which a plurality of circular element wires are twisted and compressed in a circular shape. The rectangular conductor has an advantage that the outer diameter of the cable can be reduced because the dot rate is relatively higher than that of the circular compressed conductor.

Since the conductor 11 is formed by twisting a plurality of elemental wires, the surface of the conductor 11 may not be smooth and the electric field may be uneven, and corona discharge is likely to occur partially. In addition, when a gap is formed between the surface of the conductor 11 and the cable insulation layer 14 described later, the insulation performance may be deteriorated.

In order to solve the above-mentioned problems, an inner semiconductive layer 12 may be formed outside the conductor 11. The inner semiconductive layer 12 may have semiconducting properties by adding conductive particles such as carbon black, carbon nanotube, carbon nanoplate, or graphite to the insulating material.

The inner semiconductive layer 12 functions to stabilize the insulation performance by preventing a sudden change in the electric field between the conductor 11 and the cable insulation layer 14 described later. In addition, by suppressing the uneven distribution of electric charge on the conductor surface, it is possible to make the electric field uniform and prevent the gap between the conductor 11 and the cable insulation layer 14 from being formed, thereby suppressing the corona discharge and dielectric breakdown do.

The cable insulation layer 14 is provided on the outer side of the inner semiconductive layer 12 to electrically isolate the cable insulation layer 14 from the outside so that a current flowing along the conductor 11 does not leak to the outside.

The cable insulation layer 14 may be formed of insulating paper impregnated with insulating oil. That is, the cable insulation layer 14 may be formed by winding up insulation paper in multiple layers so as to surround the inner semiconductive layer 12 and impregnating the insulation oil after the cable core is formed. As the insulating oil is absorbed by the insulating paper, the insulating property of the cable insulating layer 14 can be improved.

The insulating oil is filled in gaps between the voids inside the insulating paper and the gap formed between the layers formed by winding the insulating paper to improve the insulating property and reduce the frictional force between the insulating paper at the time of bending the cable to improve the bending property of the cable. Although the kind of the insulating oil is not particularly limited, it should be in contact with copper or aluminum constituting the conductor 11 and not be oxidized by heat. It is preferable that the insulating paper be impregnated at an impregnation temperature, for example, It is preferable to use a medium-viscosity insulating oil having a sufficiently low viscosity and a kinematic viscosity at 60 DEG C of 10 to 500 centistokes or a high-viscosity insulating oil having a kinematic viscosity at 60 DEG C of 500 centistokes or more.

In the case of using a low-viscosity insulating oil having a relatively low viscosity, it is necessary to pressurize the insulating oil using a lubricating device or the like in order to keep the insulating paper impregnated with the insulating oil and prevent the gap from being generated in the cable insulating layer due to the flow of the insulating oil There is a need. However, when medium viscosity or high viscosity insulating oil is used, the flow of insulating oil is small, so there is no need for an oil supply device for pressurizing the insulating oil, or the number of required oil supply facilities can be reduced, thereby extending the cable extension length. For example, the insulating oil may be at least one insulating oil selected from the group consisting of naphthenic insulating oil, polystyrene insulating oil, mineral oil, alkylbenzene, polybutene-based synthetic oil, heavy alkaline,

The insulating paper may be a kraft paper in which kraft pulp is used as a raw material and an organic electrolyte in the pulp is removed, or a composite insulating paper in which a kraft paper is adhered to one side or both sides of a plastic film. The plastic film has a resistivity higher than that of the kraft paper adhered to one side or both sides thereof, so that even if bubbles are generated in the kraft paper due to the flow of the insulating oil during the impregnation process or cable operation, the voltage distributed to the bubbles can be relaxed, A polyolefin resin such as polypropylene or polybutylene, a tetrafluoroethylene-hexafluoropropylene copolymer, an ethylene-tetrafluoroethylene copolymer, an ethylene-tetrafluoroethylene copolymer, And a polypropylene homopolymer resin which is excellent in heat resistance.

Specifically, the cable insulation layer 14 can be formed by winding up a kraft and impregnating the insulation oil. In this case, the insulating oil may flow in the direction of the cable load, and the gap may be generated. On the other hand, when the composite insulating paper is wound and impregnated with the insulating oil to form the cable insulating layer 14, the thermoplastic resin such as the polypropylene resin is not impregnated with the insulating oil, and the impregnation temperature at the time of cable production, Thermal expansion is caused by operating temperature. When the thermoplastic resin thermally expands, a surface pressure is applied to the laminated kraft paper, thereby narrowing the passage of the insulating oil. Therefore, the flow of the insulating oil due to the gravity or the shrinkage / expansion of the insulating oil according to the temperature can be suppressed. In addition, the composite insulating paper has an advantage of being able to reduce the outer diameter of the cable because the dielectric insulating strength is higher than that of the craft paper.

On the other hand, when the power cable is energized, heat is generated in the conductor serving as a passage through which the current flows, and the temperature gradually decreases from the inside toward the outside in the cable radial direction, Occurs. Therefore, the insulation oil of the cable insulation layer, that is, the cable insulation layer formed on the inner semiconductive layer 12, which belongs to the conductor directly above the section, moves to the outside due to low viscosity and thermal expansion, The viscosity of the insulating oil is increased and it does not return to the original state, so that voids may be generated in the portion of the cable insulation layer in the region directly above the conductor.

In addition, a high electric field acts on the cable insulation layer, that is, the cable insulation layer formed in the direction of the outer semiconductive layer 16, which belongs to the section under the metal sheath where the electric field gradually increases due to the temperature difference. The conductor straight section and the metal sheath lower section have a high possibility of occurrence of voids and can act as an insulation weak portion which is a starting point of partial discharge and dielectric breakdown as a region where a high electric field acts in accordance with a temperature change in the cable.

In order to solve the above-described problems, only a kraft may be used as an insulating paper in the area of the cable insulation layer 14 including the insulation weak portion. That is, the cable insulation layer 14 is divided into the first cable insulation layer, the second cable insulation layer, and the third cable insulation layer in the direction of the outer semiconductive layer 16 described later from the inner semiconductive layer 12, Only the kraft may be used for the cable insulation layer and / or the third cable insulation layer, and the composite insulation paper may be used for the second cable insulation layer.

In this case, a difference in resistivity occurs between the second cable insulating layer on which the composite insulating paper is wound and the first cable insulating layer and / or the third cable insulating layer on which the kraft paper is wound, and the cable insulation layer The first cable insulation layer and / or the third cable insulation layer of the second insulation layer 14 has a relatively low resistivity and functions to alleviate an electric field shared among the insulation fragile portions. Specifically, a high electric field acts on the second cable insulating layer on which the composite insulating paper having a high resistivity is wound due to the resistive electric field distribution characteristic of the DC cable in which the electric field is distributed according to the resistivity, and the first cable insulating layer and / A relatively low electric field acts on the conductor straight section and / or the metal sheath lower section included in the insulation layer, so that the electric field acting on the insulation weak portion is relaxed and the insulation performance can be stabilized.

In addition, the cable insulation layer 14 may form the third cable insulation layer to be thicker than the first cable insulation layer. In the case of forming a metallic sheath 22 described later on the outside of the cable insulation layer 14 or restoring the metallic sheath 22 after connecting two power cables exposed sequentially from the inside of the cable core portion The second cable insulation layer may be formed to have a larger thickness than the first cable insulation layer so that the second cable insulation layer 14 may be deformed, It is preferable to protect the plastic film from heat. In this case, the thickness of the first cable insulation layer can be selected in consideration of the impulse surge voltage required for the power cable and the like.

The outer semiconductive layer 16 may be provided outside the cable insulation layer 14. The outer semiconductive layer 16 is formed of a material having semiconducting properties by adding conductive particles such as carbon black, carbon nanotube, carbon nanoplate, graphite and the like to an insulating material such as an inner semiconductive layer, Uneven charge distribution between the layer 14 and the metal sheath 22 described later is suppressed to stabilize the insulation performance. In addition, the outer semiconductive layer 16 functions to smooth the surface of the cable insulation layer 14 in the cable so as to prevent corona discharge by alleviating electric field concentration, and to physically protect the cable insulation layer 14 Can be performed. The outer semiconductive layer 16 may further include a metalized paper. The metalized sheet may be formed by laminating an aluminum foil on a kraft paper, and a plurality of perforations may be present to facilitate impregnation of the cable insulating layer 14 with insulating oil.

The cable core portion 10 may further include a water absorbing portion 21 for preventing water from penetrating into the cable. The moisture absorbing portion can be formed between the stranded strands of the conductor 11 and / or the outside of the conductor 11. The water absorbing portion can absorb the moisture penetrated into the cable at a high speed, Tape, a coating layer or a film including a super absorbent polymer (SAP) so as to prevent moisture from penetrating in the longitudinal direction of the cable. In addition, the water absorbing part may have a semiconductive property to prevent a sudden change in the electric field.

A cable protecting portion 20 is provided outside the cable core portion 10 and a power cable installed in the seabed may further include a cable covering portion 30. The cable protector and cable protector protects the core from various environmental factors such as moisture penetration, mechanical trauma, and corrosion which may affect the power transmission performance of the cable.

The cable protection portion 20 includes a metal sheath 22 and a polymer sheath 24 to protect the cable from an accident current, an external force or other external environmental factors.

The metallic sheath 22 may be formed so as to surround the core portion 10. In particular, when the power cable is installed in an environment such as a seabed, the cable core portion 10 may be sealed to prevent foreign matter such as moisture from entering the cable core portion 10, The melted metal is extruded outside the cable core portion 10 so as to have a continuous outer surface having no seams, so that the order performance can be improved. Lead or aluminum is used as the above metal. In the case of a power cable installed on the seabed, it is preferable to use lead having excellent corrosion resistance against seawater. To compensate for mechanical properties, It is more preferable to use a lead alloy. The metal sheath 22 serves as a passage through which a fault current flows when a ground fault or a short circuit occurs in the ground at a power cable end, protects the cable from external impacts, and prevents an electric field from being discharged to the outside of the cable .

The metal sheath 22 may be coated with a corrosion inhibiting compound such as a blown asphalt or the like in order to further improve the corrosion resistance, water repellency and the like of the cable and improve the adhesive strength with the polymer sheath 24 .

In addition, a copper wire-directing tape or a moisture absorbing layer 21 may be additionally provided between the metal sheath 22 and the cable core portion 10. The copper wire direct tape is composed of a copper wire and a nonwoven tape and acts to smooth electrical contact between the outer semiconductive layer 16 and the metal sheath 22. The moisture absorbing layer absorbs moisture penetrating the cable A tape, a coating layer or a film including a super absorbent polymer (SAP) excellent in the ability to maintain the absorbent state at a high speed and to prevent moisture from penetrating in the cable longitudinal direction It plays a role. The copper wire-directing tape and the water-absorbing layer preferably have a semiconducting property in order to prevent a sudden change in the electric field, and may include a copper wire in the water-absorbing layer so as to be capable of both conducting and absorbing water.

The polymer sheath 24 is formed outside the metal sheath 22 to improve the corrosion resistance and water repellency of the cable and to protect the cable from mechanical damage and other external environmental factors such as heat and ultraviolet rays . The polymer sheath 24 may be formed of a resin such as polyvinyl chloride (PVC), polyethylene or the like. In the case of a power cable installed in the seabed, it is preferable to use a polyethylene resin having excellent water repellency. In the environment, polyvinyl chloride resin is preferably used.

The power cable 100 is provided with a metal reinforcing layer 26 made of steel tape or the like galvanized on the inside or outside of the polymer sheath so that the metal sheath 22 expands due to the expansion of the insulating oil . The upper and / or lower portions of the metal reinforcing layer 26 may be provided with a bedding layer (not shown) made of a semiconductive nonwoven tape or the like to buffer an external force applied to the power cable, and may be made of polyvinyl chloride or polyethylene It is possible to further improve the corrosion resistance, water resistance and the like of the power cable, and further protect the cable from other external environmental factors such as mechanical trauma and heat and ultraviolet rays.

In addition, the power cable installed on the seabed may be easily damaged by an anchor or the like of a ship, and may be damaged by a bending force due to currents or waves, a frictional force with the sea floor, etc. Therefore, (30) may be additionally provided.

The cable sheathing may include an armor layer 34 and a covering layer 38. The armor layer 34 may be composed of at least one layer made of steel, zinc-plated steel, copper, brass, bronze, etc., And performance as well as additional protection from external forces.

Polypropylene yarn or the like is formed in one or more layers on the upper and / or lower portions of the armor layer 34 to protect the cable, and the serving layer 34 formed at the outermost portion is formed of a color Can be made of two or more different materials to ensure the visibility of the cable installed at the seabed.

3 is a partial cutaway view schematically showing an intermediate connection box according to the present invention and a DC power cable intermediate connection system connecting a pair of power cables using the same. 1 is a partial cut-away view schematically showing a state in which DC power cables 100A and 100B having the configuration shown in Fig. 1 are connected to each other by an intermediate connection box 200. Fig.

3, the ends of the pair of DC power cables 100A and 100B, in which the conductor 11A, the inner semiconductive layer 12, the cable insulation layer 14 and the outer semiconductive layer 16 are sequentially exposed, A reinforcing insulating layer 210 formed so as to surround the conductor connecting portion, and a reinforcing insulating layer formed to surround the reinforcing insulating layer. The reinforcing insulating layer 210 is formed to surround the conductor connecting portion, An intermediate connection box including a connection port outer semiconductive layer 230 electrically connected to the outer semiconductive layer 16 or the metal sheath 22 of the cable is formed.

The conductor connecting portion electrically connects the exposed pair of conductors electrically and mechanically, and connects the pair of conductor ends by filling the filler metal (M). Alternatively, the conductor connecting portion may connect the pair of conductors It is possible to grasp and connect the end of the conductor.

The filler metal M is bonded to the filler metal M by a bonding process such as brazing or arc welding between a pair of conductor ends provided so that the ends cut by the slant lines are opposed to each other, The filler metal may be melted and then machined by grinding or the like to fill the gap between the pair of conductor ends.

When the conductor compression sleeve is used, the outer diameter of the conductor compression sleeve may be a diameter compression sleeve substantially similar to the outer diameter of the exposed pair of conductors 11A and 11B, and the exposed pair of conductors 11A, and 11B, and then pressing the outer surface of the conductor crimping sleeve. After pressing the outer surface of the conductor crimping sleeve, the conductor crimping sleeve is machined by grinding or the like to smooth the outer surface . The conductor crimping sleeve fixes the ends of the pair of conductors 11A and 11B to each other so that the pair of conductors are electrically connected to each other even if tensile force acts when the power cable or the power cable intermediate connection system is installed It is firmly supported.

In the case of grinding after filling the filler metal M or finishing the surface after compressing the compacting sleeve, the conductor connecting portion has approximately the same outer diameter as the cable conductor, so that the reinforcement formed on the conductor connecting portion The thickness of the insulating layer can be reduced.

The exposed cable insulation layer 14A may be pen-sled to have a single inclined surface. As an example, as shown in Figs. 3 and 4, the cable insulation layer 14A may have a single inclined plane S whose obtuse angle with the exposed conductor 11A is obtuse.

A reinforcing insulating layer 210 for covering at least a part of the cable insulating layer 14A including the conductor connecting portion after connecting the conductors 11A and 11B of the insulating oil-impregnated cables 100A and 100B by forming the conductor connecting portion, So that a current flowing through the conductor and the conductor connecting portion flows only in the longitudinal direction of the intermediate connection system and prevents leakage in the radial direction.

The reinforcing insulating layer 210 may be formed by winding insulating paper so as to surround the conductor connecting portion, the exposed inner semiconductive layer, or the cable insulating layer. The insulating paper constituting the reinforcing insulating layer 210 may have a high dielectric strength And may further include an insulating paper such as a kraft paper having a volume resistivity lower than that of the composite insulating paper, for example, a kraft paper, so that electric field control using the difference in volume resistivity between the composite insulating paper and the kraft paper can be performed.

The reinforcing insulating layer 210 includes a first reinforcing insulating layer 2101 on which an insulating paper is wound to surround the conductor connecting portion, the exposed inner semiconductive layer to the cable insulating layer, and the outer diameter of the cable insulating layer is formed, And an insulating layer 2101 and a second reinforcing insulating layer 2102 formed to surround the first reinforcing insulating layer.

The second reinforcing insulating layer 2102 is formed to surround the first reinforcing insulating layer 2101 and the exposed cable insulating layer 14A. That is, the second reinforcing insulating layer 2102 is formed at an outer diameter or greater of the cable insulating layer to improve the insulation performance of the intermediate connection box.

The second reinforcing insulating layer 2102 has a straight portion 2102A having a width in the cable longitudinal direction that is constant in the radial direction of the cable and a second reinforcing insulating layer 2102B formed at both ends of the straight portion, And a slope portion 2102B that decreases in the radial direction of the cable.

The slope portion 2102B is formed at both ends of the rectilinear portion 2102A and functions to control an electric field by determining a shape of a connection case external semiconductive layer 230 to be described later. Specifically, the width in the cable longitudinal direction is formed so as to decrease in the radial direction of the cable, and the thickness of the slope portion increases from the end of the cable toward the end of the straight line side. Further, the rate of increase of the thickness may be increased, and in this case, the slope portion may have an outer surface formed of a curved surface. That is, the slope portion 210B can be formed such that the inclination of the outer surface of the slope portion gradually increases toward the end portions of the cable conductors 11A and 11B.

The second reinforcing insulating layer 2102 may be formed of a plurality of insulating ground layers 2102L laminated in the radial direction as shown in FIGS. 3 to 4. The insulating ground layer 2102L may be formed by winding an insulating paper Or by laminating insulation paper in the radial direction of the cable or intermediate connection box.

The plurality of insulating ground layers 2102L may be formed of an insulating ground layer that is separated from the cable or the intermediate connection port in the radial direction so that the insulating paper having a predetermined length is not continuous in the longitudinal direction. Specifically, one insulating layer can be formed by inserting insulating paper using an insulating paper roll having a predetermined length and wound in the longitudinal direction. When all the insulating paper having the predetermined length is wound, a new insulating paper roll And a plurality of insulating paper layers are formed by using a plurality of insulating paper rolls. Therefore, each of the insulating layer layers 2102L is divided into the radial direction of the cable or the intermediate connection box because the wound insulation paper is not continuous. The one insulating paper roll may have a substantially trapezoidal shape in which the width of the insulating paper roll is narrow or wide. The insulating paper making up each of the plurality of insulating paper rolls may have a different rate of change in width or a different length of insulating paper . That is, since a plurality of insulating ground layers 212L are formed by using insulating paper having various shapes, the shape of the second reinforcing insulating layer 2102, particularly, the shape of the slope portion 2102B can be precisely controlled.

The second reinforcing insulating layer 2102 may include a plurality of insulating paper take-up portions W and N that are not continuous in the longitudinal direction of the cable or the connection box in the same insulating layer. That is, one insulating layer 2102L may be divided into a plurality of insulating paper winding portions W, N in the longitudinal direction of the cable. In the second reinforcing insulating layer 2102 including insulating paper impregnated with insulating oil, the plurality of insulating paper winding portions W, N serve as an insulating oil flow path. Particularly, when the insulating paper is a composite insulating paper including a plastic film, the insulating oil can not flow through the plastic film, so that when the insulating oil is inflated upon impregnation with the insulating oil or heat, There is an advantage.

In the present invention, the insulating paper winding sections (W, N) can be in contact with other insulating paper winding sections on at least one of the upper surface, the lower surface and the side surface. Specifically, the insulator paper take-up portion can be in contact with the insulator winding portion of another insulation layer at the upper surface or lower surface, or can contact the other insulator winding portion of the same insulation layer at the side surface. At this time, the insulating paper wound portion is wound in the longitudinal direction and the radial direction of the cable so that the insulating paper winding portion having a width significantly smaller than that of the other insulating paper winding portion constituting the same layer, particularly the insulating paper winding portion contacting the side surface, (N), and includes an insulating paper having a significantly larger width than the insulating paper constituting the triple winding section (N), the insulating paper The insulating paper take-up unit can be defined as a wide-area take-up unit (W).

The second reinforcing insulating layer 2102 may include the triple winding portion N and the wide portion winding portion W to precisely shape the slope portion 2102B. In particular, among the plurality of insulating ground layers constituting the second reinforcing insulating layer 2102, each of the insulating ground layers having an outer diameter smaller than that of the insulating ground layer forming the outermost layer of the second reinforcing insulating layer, And the shape of the slope portion 2102B of the second reinforcing insulating layer 2102 can be precisely formed by the at least one triple winding winding portion N. [

Specifically, after a plurality of wafers W are formed on the slope portion and a part of the rectilinear portion by winding the wafers, the empty space formed between the wafers W is wound with a small width to form a three- The winding portion N can be formed.

The wide-width take-up portion W can be formed by winding a substantially trapezoidal wide-width paper to form a predetermined shape of the insulator paper take-up portion, in particular, a predetermined shape of the outer surface of the slope surface with a predetermined slope . Therefore, the workability is excellent, and the outer surface shape of the slope portion 2102B can be precisely controlled by forming the slope portion 2102B by winding the wide span.

However, when an error occurs in the process of winding the wide band, it is not possible to form the insulator winding portion having a predetermined shape in the empty space formed between the wide band winding portions W. Therefore, it is preferable that the thin wire winding portion N is formed by winding the thin wire in the longitudinal direction and the radial direction of the cable by horizontally inserting the thin wire in an empty space formed between the wide width winding portions W. [ That is, unlike the wide-area take-up portion W forming a predetermined type of insulated-wire take-up portion, the widthwise take-up portion N is formed by winding up an insulating paper having a small width transversely in the longitudinal direction of the cable, It is possible to precisely control the shape of the second reinforcing insulating layer by compensating an error generated in forming the wide-width winding portion (W).

The widthwise winding portion N is formed by winding up an insulating paper having a width smaller than that of the wide width paper in the longitudinal direction and the radial direction of the intermediate connection. The width of the insulating paper wound in the longitudinal direction is large, It is dense. The gap is highly likely to act as a gap which can be a point of time of dielectric breakdown. If the gap is densely packed, there is a possibility that an electric field distortion occurs due to a local change in volume resistivity. Therefore, it is preferable that the triple winding take-up portion N is formed not only on the slope portion 2102B but on the straight portion 2102A in which the insulating paper is wound up relatively thick.

In addition, each insulating layer of the slope portion 2102B may be formed of one wide-width winding portion W. That is, the slope portion 2102B may not be provided with the buttress portion C where the optical fiber winding portion W and the optical fiber winding portion W contacting the optical fiber winding portion W meet. The slope portion 2102B, The winding portion W may extend to the straight portion 2102A of the second reinforcing insulating layer 2102. [ There may be a gap between the insulating paper of the wide-width take-up portion W and the insulating paper of the wide-width paper take-up portion in contact with the insulating paper, and the gap can act as a gap, and the butt portion C is relatively thickly wound It is preferable to form only the straight portion 2102A.

As described above, the triangular winding portion N can form the shape of the second reinforcing insulating layer precisely, but may act as an insulating weak portion. Therefore, each of the insulating layer 2102L of the second reinforcing insulating layer 2102 can minimize the number of the three-corner winding portions N so that the number of the three-corner winding portions N becomes equal to or less than the number of the butted portions C. The butt portion C refers to an interface where different width wirings W contact with each other in the same insulation layer 2102L.

However, the outermost insulation layer of the second reinforcing insulating layer 2102 may not be equal to or less than the number of the counter winding portions C in the number of the winding wirings N. That is, if the length of the outermost insulating layer of the second reinforcing insulating layer 2102 is short, the insulating layer may be formed only by the wider portion W, or the two wider portions W and / And only one triangular winding portion N formed between the two wide-width winding portions.

As described above, the insulation layer 2102L is formed by minimizing the width W of the winding portion N, which is relatively weak in insulation compared with the width W of the windings W, so that the insulation performance of the second reinforcing insulation layer 2102 can be improved have.

The second reinforcing insulating layer 2102 may be formed by vertically separating the three winding cores N1 and N2 formed on the insulating layers 212L1 and 212L2 adjacent to each other by a predetermined distance D1 It is possible to prevent overlapping of air gap densities that may occur by winding the thin spun yarns, thereby further improving the insulation performance of the intermediate connection box.

More specifically, as shown in Fig. 4, the three-winding winding portion N1 of one insulating layer 2102L of the second reinforcing insulating layer 2102 and the three-winding winding portion N2 of the insulating layer 2102L2 adjacent to the one insulating layer The distance D1 between the adjacent insulation layer 2102L2 and the adjacent insulation layer 2102L2 is a distance D2 between the widthwise winding portion N1 of the insulation layer 2102L1 and the contact portions C1 and C2 of the adjacent insulation layer 2102L2, D3 of the shortest distance D2. That is, when there is one narrow width winding portion N2 and two buttress portions C1 and C2 on the insulation layer 2102L2 adjacent to the insulation layer 2102L1, The distance D1 between the winding portion N1 and the winding portion N2 of the insulating layer 2102L2 adjacent to the insulating layer 2102L1 is set such that the winding width of the winding portion N1 of the insulating paper layer 2102L1 The distance D2 between the butt portions C1 of the adjacent insulating layer 2102L2 and the distance D2 between the triple winding portion N1 of the insulating layer 2102L1 and the butt portion C2 of the adjacent insulating layer 2102L2 The distance D3 may be equal to or greater than a small distance.

In the case where only one triple winding portion and one butt portion exist in the insulating layer adjacent to any one of the insulating layers, a difference between the triple winding portions of the insulating layer and the triple winding portions of the adjacent insulating layer The distance may be greater than or equal to the distance between the triangular winding turns of any one of the insulating layers and the butt of the adjacent insulating layer.

As described above, by forming the butt portion, which can serve as the insulating oil flow, close to the triangular winding portion so that the triangular winding portions of the different insulating paper layers do not overlap with each other, the insulating oil can be impregnated well have.

The first reinforcing insulating layer 2101 is formed up to the outer diameter of the cable insulating layer so as to surround the conductor connecting portion, the exposed inner semiconductive layer and the cable insulating layer. Specifically, the first reinforcing insulating layer 2101 is formed by horizontally inserting insulating paper in a space between the cable insulating layers exposed in the pair of cables provided so as to face each other, winding the insulating paper in the longitudinal direction of the cable, And the like.

The first reinforcing insulating layer 2101 may have an inclined surface S at both ends in the longitudinal direction. Since the first reinforcing insulating layer 2101 is formed in a space between the cable insulating layers exposed in the pair of cables opposing each other, both longitudinal ends of the first reinforcing insulating layer 2101 are exposed May be formed to correspond to the end shape of the cable insulation layer. 3 and 4, when a single inclined surface is formed at the end of the cable insulation layer, a single inclined surface S is formed at the end of the first reinforcing insulation layer 2101 so as to correspond to a single inclined surface of the cable insulation layer The interfacial length between the first reinforcing insulating layer 2101 and the cable insulating layer 14A can be increased as compared with the case where there is no inclined plane, thereby improving the insulation performance.

However, when the interfacial length is increased as described above, the length of the intermediate connection box becomes long, and the length of the intermediate connection box on the demand specification or the manufacturing cost of the customer can not be made long without limitation.

In order to increase the interfacial length, the cable insulation layer is pen-sled to form a multi-stage inclined surface at the end portion as in the conventional intermediate connection box shown in Fig. 1, and a first reinforcing insulation layer having a multi- . In the case of the above-described conventional intermediate connection box having a multistage slant surface, it is preferable that the narrow width portion having a width smaller than that of the wide width portion is formed in a longitudinal direction and a radial direction of the cable The shape of the multi-tilted inclined surface can be precisely controlled by forming the wound triangular winding portion on the multi-tilted inclined surface.

However, the triple winding portion is formed by winding insulating paper having a width significantly smaller than the width of the wide wire in the longitudinal direction and the radial direction of the intermediate connection, and there are many gaps between insulating paper wound in the longitudinal direction and the gaps are densely packed . The gap is highly likely to act as a gap that can be a point of time for insulation breakdown and may become an insulation weak portion where electric field distortion may occur due to a local change in volume resistivity when the gap is dense. Therefore, in the conventional intermediate junction box, there is a difference in volume resistivity between the triangular winding portion formed along the inclined surface and the portion provided with the light guide winding portion, so that the electric field is locally distorted on the inclined surface at the multi-stage, and insulation breakdown may occur.

The intermediate junction box according to an embodiment of the present invention can be provided with an inclined surface formed precisely in the first reinforcing insulating layer without including the triangular winding portion, and the workability is also excellent. In addition, while the length of the intermediate connection box for the DC power cable is relatively short, it is possible to maintain the surface electric field characteristics of the slope, especially the interface between the cable insulation layer and the first reinforcing insulation layer at a constant level, Can be provided.

Specifically, the width of the insulating paper forming the first reinforcing insulating layer 2101 is larger than the width of the insulating paper forming the three-folded paper winding portion N of the second reinforcing insulating layer 2102, May be smaller than the width of the insulating paper forming the light guide winding portion (W) of the light guide plate (2102). Further, the insulating paper can be formed by horizontally separating the insulating paper in the longitudinal direction of the cable.

When the first reinforcing insulating layer 2101 is formed using an insulating paper having an excessively narrow width as in the winding step N of the second reinforcing insulating layer 2102, the workability of the insulating paper right is deteriorated The probability of voids is very high. The first reinforcing insulating layer 2101 is larger than the width of the insulating paper forming the triple winding winding portion N of the second reinforcing insulating layer 2102 and the width W of the second reinforcing insulating layer 2102 ), The insulation performance can be improved by reducing the possibility of occurrence of voids as compared with the case of forming a narrow width.

The first reinforcing insulating layer 2101 is larger than the width of the insulating paper forming the triple winding portion N of the second reinforcing insulating layer 2102 and the width of the second reinforcing insulating layer 2102, Insulating paper having a width smaller than the width of the insulating paper forming the wirings may be formed in the longitudinal direction and the radial direction of the cable by transversely inserting the insulating paper in the longitudinal direction of the cable. That is, a gap is formed between the insulated paper which is transversely spaced apart in the longitudinal direction of the cable, and the insulated paper is also wound in the cable radiation direction to cover the upper and / or lower portions of the gap. Therefore, since the first reinforcing insulating layer 2101 can be formed by adjusting the gap between the insulating sheets generated when the insulating paper is spaced in the longitudinal direction of the cable and horizontally wound, the shape of the first reinforcing insulating layer can be precisely It is possible to disperse the air gap without concentrating the air gap because there is not the triple winding section N, and it is possible to prevent the local field distortion and improve the insulation stability.

The number of the insulating paper layers constituting the first reinforcing insulating layer 2101 may be 90% or more of the number of insulating paper layers impregnated in the cable insulating layer 14A, and the insulating paper constituting the first reinforcing insulating layer 2101 may be inferiorly immersed . In this case, immersion immersion refers to insulating paper in which insulating paper is impregnated with insulating oil and then drain of insulating oil.

Since the intermediate connection box includes a portion having poor mechanical properties such as a soft contact formed at a portion where the metal sheath 22 of the cable contacts with a metal shielding layer which will be described later, 1 When the reinforcing insulating layer 2101 is formed, it is difficult to apply sufficient pressure for impregnating the insulating oil having a high viscosity. Insufficient pressure is applied to the reinforcing insulating layer 2101, which may cause insulation failure due to non-impregnation.

In addition, when applying the highly viscous insulating oil and inserting the dry paper or attaching the infiltrated paper, which is the insulating paper impregnated in the high viscosity insulating oil, there is a fear of bubble formation, and when the number of winded insulating paper is more than 80% There is a problem that the dielectric strength is lowered.

According to the present invention, since the first reinforcing insulating layer is formed by inserting the semi-oil impregnated paper in which the oil is primarily removed from the oil impregnated paper, there is less fear of impregnation compared with the case where the dry paper is wound, The insulation performance can be improved. Also, by increasing the dielectric strength of the first reinforcing insulating layer 2101, the height of the second reinforcing insulating layer 2102 is reduced and the size of the protective copper pipe 240 is reduced to reduce the amount of the insulating oil in the protective copper pipe 240 .

The intermediate connection box and the intermediate connection system using the intermediate connection box may further include a connection box external semiconductive layer 230. The connection box outer semiconductive layer 230 is formed to surround the reinforcing insulation layer 210 and is energized with the outer semiconductive layer 16 or the metal sheath 22 of the cable.

The connection box outer semiconductive layer 230 is formed along the outer surface of the slope portion 2102B of the second reinforcing insulating layer 2102 and has a slope shape itself, Consecutive equipotential lines may be distributed according to the geometric shape of the junction box outer semiconductive layer 230 having a slope shape. In addition, the connection box outer semiconductive layer 230 may have a lower volume resistance than the cable insulation layers 14A and 14B and the reinforcing insulation layer 210. That is, the electric field distribution can be controlled by using the slope shape and the volume resistivity of the connection box external semiconductive layer 230.

The connection box outer semiconductive layer 230 may be formed by winding a semiconductive tape around the outer surface of the slope portion 2102B of the second reinforcing insulating layer and may be energized with the outer semiconductive layer 16 of the cable. And may be formed so as to surround the straight portion 2102A of the second reinforcing insulating layer 2102. [

A metal shielding layer electrically connected to the metal sheath 22 of the cable 100A is restored on the reinforcing insulating layer 210 and the spacer 250 and the protective copper pipe 240 are covered.

The metal shielding layer is formed so as to surround the slope portion 2102B, the straight portion 2102A of the second reinforcing insulating layer, and the connection semiconductive outer layer 230 of the connection port.

The metal shielding layer formed to surround the slope portion 2102B of the second reinforcing insulating layer is preferably formed of a metal wire. The metal wire may be copper wire, peristaltic wire, tinned copper wire or the like, and the metal wire may be wound around the slope part 2102B or may be formed by winding a braid made of the metal wire. Since the slope portion 2102B has a slope-like outer surface whose slope may not be constant, the metal sheath or the braid can be used to smoothly conduct the connection between the connection semiconductive outer semiconductive layer 230 and the metal shielding layer . Further, since the insulating oil can penetrate between the metal wires, it is easy to impregnate the insulating oil, which will be described later.

5, the middle junction box may include a metal shield layer 250 formed to surround the straight line portion 2102A of the second reinforcing insulating layer, and the metal shield layer 250 may include a metal Tape or metal plate. The straight portion 2102B of the second reinforcing insulating layer having a relatively smooth outer surface can be bonded with a metal plate and bonded, or the metal tape can be wound to improve workability. However, the metal tape or the metal plate may be perforated in order to facilitate impregnation with insulating oil to be described later.

The spacer has a disk shape having a through hole therein, may be made of a metal such as aluminum, and is formed on a straight portion of the second reinforcing insulating layer. The spacer may be fitted outside the reinforcing insulating layer 210 through the through hole to maintain a gap between the copper pipe 240 and the reinforcing insulating layer 210, which will be described later. 5, the spacer 250 may have a plurality of recesses 251 spaced apart from one another in the radial direction. The insulating oil in the copper pipe 240 passes through the concave portion 251. That is, when the insulating oil is impregnated, the insulating oil injected into the copper pipe 240 can smoothly move in the longitudinal direction of the intermediate connection box 200 through the concave portion 251. In addition, metal wires may be wound on both sides of the spacer 250 to prevent the spacer 250 from moving due to the flow of the insulating oil.

A metal shield layer protecting portion 270 may be further formed between the metal shield layer 260 and the spacer 250. The metal shield layer protecting part 270 is formed by winding an insulating paper on the metal shielding layer 260 and prevents the metal shielding layer 260 from being damaged by the spacer 250. In detail, when the spacer 250 is fitted outside the reinforcing insulating layer 210, scratches may be generated on the surface of the metal shielding layer 260 formed on the reinforcing insulating layer 210, The metal shield layer 260 may be pressed by the spacer 250 to generate an edge portion. Accordingly, the metal shield layer protecting part 270 is formed between the spacer 250 and the metal layer to prevent the metal shield layer 260 from being damaged by the spacer 250, It is possible to prevent the electric field concentration by this.

The protective copper tube 240 is then covered. The protective copper pipe 240 protects the inside of the connection box from the outside and is energized with the metal sheath 22 of the cable 100 to serve as a path for the fault current.

On the other hand, the intermediate connection system needs to inject insulation oil into the intermediate connection box to ensure insulation performance. Specifically, in the case where the space between the reinforcing insulating layer and the protective copper tube is filled with insulating oil, and in particular, when the reinforcing insulating layer is formed by winding the semi-oil immersion, the reinforcing insulating layer is impregnated with insulating oil to improve the insulating performance There is a need.

The protective copper pipe 240 of the present invention may include an insulating oil inflow pipe and an insulating oil discharge pipe. The inlet pipe and the outlet pipe are formed on the outer surface of the protective copper pipe 240 in opposite directions, and serve as passages through which the insulating oil moves.

The insulating oil supplied into the protective copper pipe through the inlet pipe is discharged to the outside through the upper discharge pipe while impregnating the reinforcing insulating layer 210 through the outer semiconductive layer and the metal shielding layer. Further, by pressurizing the insulating oil using nitrogen gas or the like, the reinforcing insulating layer can be impregnated smoothly, thereby improving the insulating performance.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention.

Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments.

The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

100: Cable
11: Conductor
12: inner semiconductive layer
14: Insulating layer
16: outer semiconductive layer
200: Medium connection
210: reinforced insulation layer
230: intermediate connection box outer semiconductive layer

Claims (23)

1. A direct current power cable intermediate connection system comprising a pair of direct current power cables each having a conductor, an inner semiconductive layer, a cable insulation layer and an outer semiconductive layer, and an intermediate connection box connecting the pair of direct power cables to each other,
Wherein the pair of DC power cables are provided so that the ends of the conductor, the inner semiconductive layer, the cable insulation layer including the insulating paper impregnated in the insulating oil, and the outer semiconductive layer are sequentially exposed,
The intermediate junction box includes:
A conductor connecting portion electrically and mechanically connecting the exposed pair of conductors;
A first reinforcing insulating layer having an insulating paper wound around the conductor connecting portion, the exposed inner semiconductive layer and the cable insulating layer to form an outer diameter of the cable insulating layer and having inclined surfaces at both ends in the longitudinal direction; A reinforcing insulating layer and an insulating paper wound around the exposed cable insulating layer so as to surround the cable insulating layer, wherein the cable has a straight portion having a constant width in the cable longitudinal direction and a width formed in both ends of the straight portion, A reinforcing insulating layer including a second reinforcing insulating layer having a sloping portion decreasing radially; And
A second reinforcing insulating layer formed on the outer surface of the slope portion and having a slope shape by itself and having a connection box outer semiconductive layer made of a semiconductive material,
Wherein each of the first reinforcing insulating layer and the second reinforcing insulating layer includes a plurality of insulating ground layers in which composite insulating paper in which kraft paper is adhered to one surface or both surfaces of a plastic film is radially laminated,
And a plurality of insulating paper windings which are separated from each other in the longitudinal direction of the cable or the connection box in the same insulating paper layer among the plurality of insulating paper layers,
And an insulating oil capable of flowing between the plurality of insulating paper winding portions,
Wherein the second reinforcing insulating layer includes a wide-width winding portion formed with a wide width and a three-width winding portion made of an insulating paper having a narrower width than the insulating paper making up the wide-width winding portion,
Wherein a light guide winding portion is disposed on an upper surface and / or a lower surface of the triple winding portion,
In order to precisely control the shape of the first reinforcing insulating layer, the insulating paper having a width smaller than that of the width wider portion and a width larger than the width of the third width wider portion is horizontally spaced in the longitudinal direction of the cable, Wherein the DC power cable is connected to the DC power cable. The method according to claim 1,
Wherein the number of insulating paper layers deposited on the first reinforcing insulating layer is 80% or more of the number of insulating paper layers deposited on the cable insulating layer. The method according to claim 1,
Wherein the third reinforcing insulation layer has a triple winding portion of one of the insulation layer and the third reinforcing insulation layer is spaced apart from the triple winding winding of the insulation layer adjacent to the insulation layer by a predetermined distance. The method according to claim 1,
Wherein the third winding portion of one of the insulating layers in the second reinforcing insulating layer is not overlapped with the third winding portion of the other insulating layer located in contact with or below the insulation layer. Power cable intermediate connection system. The method according to claim 1,
Wherein a distance between the third reinforcing insulating layer and the third insulating layer in contact with the insulating layer in the third insulating layer is smaller than a distance between the second insulating layer and the third insulating layer in contact with the insulating layer, Wherein the shortest distance between the contact portions formed in contact with the neighboring wide-width windings in the ground layer and the three-fold windings of the insulation layer is equal to or greater than the shortest distance. The method according to claim 1,
Wherein the triple winding portion is located in the straight portion without being positioned in the slope portion. The method according to claim 1,
And the slope portion comprises the wide-width winding portion. The method according to claim 1,
The intermediate junction box
A metal shielding layer formed on the semi-conductive layer outside the connection box;
A copper pipe surrounding the reinforcing insulation layer and a portion of the power cable and including an insulating oil therein; And
A spacer for maintaining a gap between the copper tube and the metal shielding layer; Wherein the DC power cable intermediate connection system comprises: The method according to claim 1,
The conductor connecting portion includes:
And a filler metal is filled between a pair of conductors which are cut in an oblique direction and whose ends are opposed to each other, and are connected to each other. The method according to claim 1,
The conductor connecting portion includes:
A pair of conductors exposed from the cable and having their ends facing each other; And
And a conductor crimping sleeve surrounding the pair of conductor ends,
Wherein the conductor crimping sleeve has an outer diameter equal to the outer diameter of the conductor. A cable insulator layer including a conductor, an inner semiconductive layer, a cable insulation layer, and an outer semiconductive layer, wherein the conductor, the inner semiconductive layer, the insulating layer impregnated with the insulating oil, and the outer semiconductive layer are sequentially exposed, A method for connecting a pair of DC power cables to each other using an intermediate connection box,
Forming a conductor connecting portion by electrically and mechanically connecting the exposed pair of conductors to each other;
Forming a first reinforcing insulating layer by winding the conductor connecting portion, the exposed inner semiconductive layer, and the cable insulating layer up to the outside diameter of the cable insulating layer with kraft paper adhered to one side or both sides of the plastic film;
A composite insulating paper obtained by laminating kraft paper on one side or both sides of a plastic film so as to surround the first reinforcing insulating layer and the exposed cable insulating layer, the straight portion having a constant width in the cable longitudinal direction, Forming a second reinforcing insulating layer having slopes formed at both ends thereof and having a width in the cable longitudinal direction decreasing in a radial direction of the cable; And
Forming an outer semiconductive layer of an intermediate junction enclosing the outer surface of the second reinforcing insulating layer,
The step of forming the second reinforcing insulating layer
And a plurality of insulating ground layers including a wide-width winding portion composed of an insulating paper having a width larger than that of an insulating paper constituting the narrow-width winding portion and the insulating paper wound on the first reinforcing insulating layer,
Wherein forming the first reinforcing insulating layer comprises:
Forming a single inclined surface on the end of the first reinforcing insulating layer to correspond to an end shape of the exposed cable insulating layer;
In order to precisely control the shape of the single inclined surface, an insulating paper having a width larger than that of the insulating paper of the triple winding portion and having a width smaller than that of the insulating paper of the winder portion is used to adjust the gap between the insulating paper, And winding up to be spaced apart,
And the insulating oil can flow through the respective winding portions when the insulating paper is wound. 12. The method of claim 11,
The step of forming the first reinforcing insulating layer
The insulating paper is a semi-oil dipped paper,
Wherein the semi-oil impregnation is wound by 80% or more of the number of layers of insulating paper wound on the cable insulation layer. 12. The method of claim 11,
Wherein forming the second reinforcing insulating layer comprises:
Wherein the third reinforcing insulation layer is disposed so as to be spaced apart from the third reinforcing layer winding portion of the insulation layer adjacent to the insulation layer by a predetermined distance. 12. The method of claim 11,
Wherein forming the second reinforcing insulating layer comprises:
Wherein the third reinforcing insulation layer is disposed so that the third reinforcing layer winding portion of one of the insulation layer is not overlapped with the third reinforcing layer winding portion of another insulation layer located in contact with the insulation layer. 12. The method of claim 11,
Wherein forming the second reinforcing insulating layer comprises:
Wherein a distance between the third reinforcing insulating layer of the second reinforcing insulating layer and the third reinforcing layer winding portion of the other insulating layer located in contact with or below the insulating layer is smaller than a distance between the third insulating layer and the insulating layer Is arranged so as to be equal to or larger than a shortest distance between a contact portion formed by contacting neighboring wide-width wind-up portions and a third width-winding portion of the insulation layer. 12. The method of claim 11,
Wherein forming the second reinforcing insulating layer comprises:
Wherein the slope portion is not provided with the triangular winding portion. 12. The method of claim 11,
Wherein forming the second reinforcing insulating layer comprises:
Wherein the slope portion is provided with only the wide width winding portion. 12. The method of claim 11,
Forming a metal shielding layer to surround the outer semiconductive layer of the intermediate junction box;
Forming a spacer to surround a part of a straight portion of the second reinforcing insulating layer;
Providing a copper tube surrounding the reinforcing insulation layer and a portion of the power cable; And
And injecting insulating oil into the copper pipe and pressurizing the copper pipe to impregnate the insulating paper of the reinforcing insulating layer. 19. The method of claim 18,
The step of forming the metal shield layer may include:
And winding the metal wire so as to surround the slope portion of the second reinforcing insulating layer so that the perforated metal plate surrounds the straight portion of the second reinforcing insulating layer. 20. The method of claim 19,
The step of forming the metal shield layer may include:
Wherein the perforated metal plate is bonded and bonded so as to surround the straight portion. 19. The method of claim 18,
Wherein forming the spacers comprises:
Wherein the insulating fluid in the inside of the copper tube flows in the longitudinal direction of the intermediate connection box through the recess, the through-hole having an inside diameter larger than the outside diameter of the second reinforcing insulating layer inside, and a concave portion facing the through- Wherein the spacer is disposed on the straight portion of the second reinforcing insulating layer. 12. The method of claim 11,
The step of forming the conductor connecting portion includes:
Wherein the filler metal is filled between a pair of conductor ends exposed in the cable so that their ends are opposed to each other. 12. The method of claim 11,
The step of forming the conductor connecting portion includes:
A conductor crimp sleeve is disposed so as to surround each end of a pair of conductors exposed at the cable so that their ends are opposed to each other, and the outer surface of the conductor crimp sleeve is pressed, and the outer diameter of the conductor crimp sleeve and the outer diameter of the conductor Wherein the first and second connection terminals are formed so as to be identical to each other.

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