KR101029635B1 - Cable crosslinking apparatus and crosslinking method of the cable using the same - Google Patents

Abstract

The cable crosslinking apparatus of the present invention includes: a crosslinking chamber in which hot water is stored up to a predetermined height and accommodates bobbins in which cables are wound; A rotating member installed in the crosslinking chamber to rotate the bobbin; And an injection member installed inside the crosslinking chamber and spraying hot water toward the cable wound on the bobbin.

Cable, crosslinking device, crosslinking chamber, high temperature, water

Description

Cable crosslinking apparatus and crosslinking method of cable using same {Cable crosslinking apparatus and crosslinking method of the cable using the same}

The present invention relates to a cable crosslinking device and a method for crosslinking a cable using the same, and more particularly, to a cable crosslinking device for smoothly crosslinking to a lower layer of a cable wound with a plurality of layers on a bobbin and a method for crosslinking a cable using the same. will be.

In general, an ultra-high voltage cable for supplying a large amount of electrical energy to an electronic device is composed of a wire rod through which a current flows and a polymer coated on the wire rod for insulation. The wire rod is a metal with good electrical conductivity such as copper, aluminum, and the like.

The polymer consists of crosslinked polyethylene (XLPE) and is coated in an extruder. The polymer is crosslinked, i.e., crosslinked, in order to increase the chemical, electrical, and mechanical properties of the polymer as heat is generated from the wire. The polymer before the crosslinking can withstand a temperature of approximately 60 ° C., but the crosslinking can withstand a temperature of 90 ° C. Such crosslinking includes various crosslinking methods such as irradiation crosslinking using an electron beam or UV radiation, chemical crosslinking by mixing and crosslinking a crosslinking agent, and water crosslinking by water and heat.

In the water crosslinking method, a crosslinking apparatus for supplying high temperature steam and crosslinking is shown in FIG. 1.

Referring to FIG. 1, the crosslinking device 10 supplies a crosslinking chamber 11 configured to receive a bobbin 1 wound with a cable C therein, and supplies hot steam to the inside of the crosslinking chamber 11. The steam supply unit 12, a discharge unit 14 installed to discharge steam in the crosslinking chamber 11, and a temperature and a pressure inside the crosslinking chamber 11 to control supply and discharge of steam. The control unit 16 is provided.

As for the bobbin 1 accommodated in the bridge | crosslinking chamber 11, the cable C is wound by the shaft 1 '. That is, the cable C wound from the shaft 1 'is wound in a plurality of layers. Steam is supplied into the crosslinking chamber 11 in order to crosslink the polymer of the cable C.

The steam supply unit 12 for supplying steam to the crosslinking chamber 11 includes a supply pipe 12a and a valve 12b provided in the supply pipe 12a. The supply pipe 12a is installed to extend below the inside of the crosslinking chamber 11 to discharge steam.

When the steam is supplied into the crosslinking chamber 11, heat is transferred from the surface of the cable (C) contacted with the steam, ie, the polymer, to the inside by conduction, resulting in a radical reaction, and a crosslinking reaction occurs by moisture of the steam. Done.

When the crosslinking by the steam is completed or the temperature inside the crosslinking chamber 11 rises, the steam is discharged from the discharge unit 14. The discharge unit 14 is composed of a discharge pipe 14a in communication with the crosslinking chamber 11, and a valve 14b provided in the discharge pipe 14a.

The operation of the valves 12b and 14b as described above is automatically controlled by the controller 16. The controller 16 receives the signal detected from the temperature sensor 16 ′ installed in the crosslinking chamber 11 to control the crosslinking device 10. For example, when the temperature inside the crosslinking chamber 11 detected by the sensor unit 16 'exceeds the preset temperature range, the valve 12b of the supply pipe 12a is closed to block steam supply, and the preset When the temperature is lower than the range of the temperature, the temperature in the crosslinking chamber 11 is controlled by opening the valve 12b of the supply pipe 12a to supply steam.

On the other hand, reference numeral '15', which is not described, is an auxiliary valve for adjusting the pressure inside the crosslinking chamber 11.

When the cable C is crosslinked using the crosslinking device 10 as described above, the cable at a position adjacent to the shaft 1 'of the bobbin 1 to the lower layer of the cable C wound on the bobbin 1 C) there is a problem that the degree of crosslinking is different for each location because the temperature and moisture of the steam is not supplied smoothly. That is, while the cable C of the upper portion wound on the bobbin 1 is smoothly crosslinked, the cable C of the lower portion wound on the bobbin 1 is relatively uncrosslinked and is thermally deformed by high temperature heat. There is a problem that the melting phenomenon occurs.

The present invention has been made to solve the above problems, to provide a cable crosslinking device capable of smoothly crosslinking to the lower layer of the cable wound to have a plurality of layers in the bobbin and a crosslinking method of the cable using the same. have.

In order to achieve the above object, the cable crosslinking device of the present invention, there is provided a high temperature water to a predetermined height therein, the crosslinking chamber is configured to accommodate the bobbin wound the cable; A rotating member installed in the crosslinking chamber to rotate the bobbin; And an injection member installed inside the crosslinking chamber and spraying hot water toward the cable wound on the bobbin.

Preferably, the rotating member is installed to be rotatable inside the crosslinking chamber, a pair of rollers configured to support the bobbin; And a driving motor connected to any one of the pair of rollers to rotate the rollers.

Preferably, the injection member, the injection pipe is provided on the inside of the cross-linking chamber, the predetermined space is formed so that the hot water is moved; And a plurality of nozzles installed at a predetermined interval below the injection pipe and spraying hot water toward the cable wound on the bobbin.

Preferably, the apparatus further includes a temperature control unit installed inside the crosslinking chamber to adjust an internal temperature of the crosslinking chamber, wherein the temperature control unit is controlled by a controller.

Preferably the temperature control unit, a temperature sensor for sensing the internal temperature of the crosslinking chamber; A heater member for generating heat when the temperature is lower than a predetermined temperature according to the detection of the temperature sensor; And a heat dissipation member for dissipating heat when the temperature is greater than or equal to a predetermined temperature according to the detection of the temperature sensor.

Preferably, the storage tank for supplying high temperature water in the interior of the cross-linking chamber, the supply is configured to circulate the hot water stored in the storage tank and the hot water stored in the cross-linking chamber periodically over time It further has a unit.

Preferably, the supply unit, a storage tank for storing high temperature water; A supply pipe installed in communication with the crosslinking chamber and the storage tank to supply hot water stored in the storage tank; A transfer tube configured to communicate with the crosslinking chamber so that hot water stored in the crosslinking chamber is transferred to the storage tank; And a transfer pump installed in the transfer pipe to transfer hot water to the storage tank.

Preferably, the transfer pipe is further provided with a filter, the filter unit filters the contaminants mixed in the hot water transferred through the transfer pipe to the storage tank, the filtered contaminants are discharged to the outside.

Preferably, the apparatus further includes a circulation unit for moving the hot water stored in the crosslinking chamber to the injection member.

Preferably, the circulation unit, the connection pipe is installed so as to communicate with the lower side of the cross-linking chamber and the injection member; And a circulation pump installed at the connection pipe to move hot water.

Preferably, the height of the hot water stored in the crosslinking chamber is stored up to the height at which the axis of the bobbin is located.

In another aspect of the present invention, a method of crosslinking a cable using a crosslinking device includes: (a) opening an entrance of a crosslinking chamber to seat a bobbin on which a cable is wound on a pair of rollers; (b) closing the entrance to the crosslinking chamber to seal the crosslinking chamber; (c) supplying hot water to a predetermined height inside the crosslinking chamber; (d) rotating the bobbin by rotating the pair of rollers, and spraying hot water toward the cable with an injection member installed on the upper side of the crosslinking chamber; And (e) discharging the bobbin wound around the cable crosslinked by hot water in the crosslinking chamber to the outside.

Preferably, in the step (c), the hot water is supplied to the crosslinking chamber to a height at which the axis of the bobbin is positioned.

Preferably, in the step (d), the hot water stored in the crosslinking chamber periodically circulates with the hot water stored in the external storage tank over time, so that the temperature of the hot water stored in the crosslinking chamber Keep it constant.

The cable crosslinking device and the method for crosslinking a cable using the same according to the present invention not only supply water sufficiently because the cable is immersed in high temperature water, but also prevent the saturation of water absorption in the high temperature water by rotating the cable. In addition, by spraying hot water on a cable that is not immersed in hot water and maintaining the temperature inside the crosslinking chamber at a predetermined temperature, the cable can be crosslinked stably and smoothly regardless of the position of the cable wound in the bobbin. There is. Accordingly, safety accidents due to product defects can be prevented, and reliability of the product can be improved to secure an economic advantage.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms or words used in the specification and claims should not be construed as having a conventional or dictionary meaning, and the inventors should properly explain the concept of terms in order to best explain their own invention. Based on the principle that can be defined, it should be interpreted as meaning and concept corresponding to the technical idea of the present invention. Therefore, the embodiments described in the specification and the drawings shown in the drawings are only the most preferred embodiment of the present invention and do not represent all of the technical idea of the present invention, various modifications that can be replaced at the time of the present application It should be understood that there may be equivalents and variations.

2 is a perspective view schematically showing a cable crosslinking apparatus according to a preferred embodiment of the present invention, FIG. 3 is a configuration diagram showing the cable crosslinking apparatus, and FIG. 4 is a structural diagram showing the cable crosslinking apparatus.

2 to 4, the crosslinking device 100 includes a crosslinking chamber 110 configured to receive a bobbin 1 wound around a cable C, and a rotating member configured to rotate the bobbin 1. 120, an injection member 130 for injecting high temperature water W toward the cable C wound around the bobbin 1, and supplying high temperature water W to the crosslinking chamber 110. A supply unit 150 is provided.

The crosslinking chamber 110 has a predetermined space formed therein to accommodate the bobbin 1 in which the cable C is wound, and receives and stores high-temperature water W from the supply unit 150. In this case, a door-shaped doorway (not shown) is formed in the crosslinking chamber 110 to allow the bobbin 1 to enter and exit through the doorway. It is preferable that the crosslinking chamber 110 is made to be closed when the entrance is closed.

On the other hand, when storing the water (W) of the high temperature in the interior of the crosslinking chamber 110 is made to be stored up to a predetermined height. The predetermined height means a height at which the shaft 1 ′ of the bobbin 1 accommodated in the crosslinking chamber 110 is positioned. As for the height of the hot water W stored in the crosslinking chamber 110 as described above, The crosslinking method of the cable using the crosslinking device 100 will be described in detail.

In addition, the hot water (W) is for contacting and crosslinking the polymer of the cable, it is preferable to have a temperature of 90 ℃ to 100 ℃ to supply heat and moisture to the polymer.

The rotating member 120 is connected to any one of the pair of rollers 121 and the pair of rollers 121 and 122 installed in the lower side of the cross-linking chamber 110 and the rollers 121 ( And a drive motor 124 for rotating 122.

The pair of rollers 121 and 122 are rotated while supporting the bobbin 1 spaced apart from each other by a predetermined interval. That is, the bobbin 1 is mounted between the pair of rollers 121 and 122 to be easily rotated by the rotation of the rollers 121 and 122. One of the pair of rollers 121 and 122 is rotated by receiving a driving force of the driving motor 124. Accordingly, when the one roller 122 rotates, the bobbin 1 is rotated by the rotated roller 122, and the other roller 121 in contact with the bobbin 1 is rotated in contact with the bobbin 1. .

Meanwhile, in the present specification, although one roller 122 is illustrated and described as being rotated by the one driving motor 124, the present invention is not limited thereto, and each driving motor is connected to a pair of rollers 121 and 122. It may be installed and rotated in the same direction, or a pair of rollers 121 and 122 may be connected by a chain or a belt to rotate together. That is, the rotating member 120 may be employed in any structure as long as the bobbin 1 is seated to stably rotate the bobbin 1.

Rotating the bobbin 1 by the rotating member 120 as described above is to prevent the cable (C) is locked in the high temperature water (W) stored in the cross-linking chamber (110). That is, to prevent the cable C immersed in the hot water W by rotating the bobbin 1 to prevent saturation due to excessive moisture absorption.

The injection member 130 is installed in the cross-linking chamber 110 is installed in a predetermined space formed in the injection pipe 132 and the injection pipe 132 at a predetermined interval formed a plurality of hot water (W) to be injected Nozzle 134 is provided.

The injection pipe 132 is installed inside the crosslinking chamber 110. The injection pipe 132 is preferably installed at a position opposite to the cable C wound on the bobbin 1 as a passage for moving the hot water W supplied from the outside.

The nozzle 134 is provided in plurality in the longitudinal direction of the injection pipe 132 spaced apart. At this time, the nozzle 134 is configured to spray the high temperature water (W) moved through the injection pipe 132 toward the cable (C), preferably formed below the injection pipe 132. In addition, although the nozzle 134 configured to spray the high temperature water W has been described as being installed in the injection pipe 132, the high temperature water (below the injection pipe 132 as an alternative to the nozzle 134) A hole (not shown) for injecting W may be formed.

By injecting the hot water (W) to the cable (C) that is not immersed in the hot water (W) through the injection member 130 as described above it is possible to perform a smooth crosslinking of the cable (C).

On the other hand, the crosslinking device 100 is made so that the hot water (W) stored in the crosslinking chamber 110 is transferred to the injection member 130 to supply the hot water (W) to the injection member 130 is purified. The circulation unit 140 is further provided.

The circulation unit 140 is installed in the connection pipe 142 and the connection pipe 142 installed to communicate the lower side of the cross-linking chamber 110 and the injection member 130 and the circulation pump for moving the water (W) of high temperature 144.

The connection pipe 142 serves as a passage through which the hot water W moves to the injection member 130. At this time, the installation position of the connecting pipe 142 in communication with the cross-linking chamber 110 is installed in any part of the cross-linking chamber 110, if installed in a position lower than the water surface of the high temperature water (W) stored in the cross-linking chamber 110 Can be. The hot water (W) is transferred to the injection member 130 by the pumping of the circulation pump 144 through the connection pipe 142 is injected. The injected hot water W circulates as it is stored inside the crosslinking chamber 110.

The supply unit 150 includes a storage tank 151 for supplying hot water W into the crosslinking chamber 110 to supply hot water W to the crosslinking chamber 110. The supply unit 150 serves to circulate the water W supplied to the crosslinking chamber 110.

More specifically, the supply unit 150 communicates with the storage tank 151 storing the high temperature water (W), the storage tank 151 and the crosslinking chamber 110 to the high temperature water in the crosslinking chamber 110. Supply pipe 152 is installed to supply W, the water (W) stored in the cross-linking chamber 110 is transported to be circulated to the storage tank 151, and the transport pipe 153 is installed The transfer pump 154 is provided.

The storage tank 151 is provided outside the crosslinking chamber 110 to store high temperature water (W). The hot water W stored in the storage tank 151 is transferred to the crosslinking chamber 110 through a supply pipe 152 installed to communicate the storage tank 151 with the crosslinking chamber 110. Here, the storage tank 151 is preferably provided with a heating device 156. The heating device 156 serves to heat the hot water W stored in the storage tank 151 to be maintained at a predetermined temperature. The heating device 156 is a well-known heat source for warming water such as a heater and a heating wire, and a detailed description thereof will be omitted.

On the other hand, although not shown, the supply pipe 152 may be installed to branch and communicate with the injection member 130. That is, the injection member 130 may be made to be supplied by receiving the water (W) of the high temperature from the storage tank 151.

The transfer pipe 153 communicates with the crosslinking chamber 110 to serve as a moving passage so that hot water W stored in the crosslinking chamber 110 is transferred back to the storage tank 151. The transfer pipe 153 is provided with a transfer pump 154 so that the hot water (W) is circulated to the storage tank 151 by the transfer pump 154. In other words, by reusing the hot water (W) stored in the crosslinking chamber 110, there is no waste of unnecessary water is economical.

On the other hand, the hot water (W) supplied to the crosslinking chamber 110 may be contaminants as used for crosslinking. Therefore, in order to remove contaminants when transferring the hot water W to the storage tank 151 through the transfer pipe 153, it is preferable that the filter unit 155 is further installed in the transfer pipe 153. That is, as shown, the high temperature water (W) transferred through the transfer pipe 153 is filtered by the filter unit 155 is transferred to the storage tank 151, the filtered contaminants are discharged to the outside. .

In addition, the crosslinking apparatus 100 according to the present invention further includes a temperature control unit 160 for controlling the temperature so as to easily adjust the internal temperature of the crosslinking chamber 110.

The temperature control unit 160 is controlled by a controller 165 that controls the crosslinking device 100. More specifically, the temperature control unit 160 is installed in the interior of the crosslinking chamber 110, the temperature sensor 161 for detecting the internal temperature of the crosslinking chamber 110, according to the detection of the temperature sensor 161 in advance The heater member 162 and the heat dissipation member 163 which are selectively operated by the controller 165 when the temperature is out of a specified temperature range are provided.

The internal temperature of the crosslinking chamber 110 should be maintained for smooth crosslinking during crosslinking by the hot water W stored in the crosslinking chamber 110. That is, when the internal temperature of the crosslinking chamber 110 is lower than the set temperature, the controller 165 receives the signal detected from the temperature sensor 161 to operate the heater member 162.

Therefore, the internal temperature of the crosslinking chamber 110 may be maintained at a predetermined temperature, and when the predetermined temperature is reached, the operation of the heater member 162 is stopped.

In addition, when the temperature is higher than the set temperature, the controller 165 receives a signal from the temperature sensor 161 to operate the heat radiating member 163 to release heat to the outside to maintain the internal temperature of the crosslinking chamber 110. In this case, the heat dissipation member 163 may be employed as long as the heat dissipation member 163 is formed to lower the internal temperature of the crosslinking chamber 110 such as a fan for discharging air and a refrigerant pipe installed to selectively circulate the refrigerant. .

On the other hand, it is shown and described in this specification to adjust the internal temperature of the crosslinking chamber 110 using the heater member 162 and the heat dissipation member 163 of the temperature control unit 160, but is not limited thereto. The internal temperature of the crosslinking chamber 110 may be adjusted from the supply unit 150. For example, the internal temperature of the crosslinking chamber 110 is increased as the hot water W is supplied to the crosslinking chamber 110 and purified from the storage tank 151 which is stored to maintain the high temperature water W at a preset temperature. It can be maintained at the same temperature as the hot water (W).

Then, a method of crosslinking the cable C wound on the bobbin 1 using the crosslinking device 100 as described above will be described.

First, after preparing the bobbin (1) wound around the cable (C), the entrance (not shown) of the crosslinking chamber 110 is opened to seat the bobbin (1) on a pair of rollers (121, 122). At this time, the hot water (W) is not supplied to the interior of the crosslinking chamber (110).

Next, the entrance and exit of the crosslinking chamber 110 is closed to seal the crosslinking chamber 110.

Subsequently, the hot water W is supplied and stored from the supply unit 150 to a predetermined height inside the crosslinking chamber 110. At this time, the high temperature water is preferably 90 ℃ to 100 ℃. In addition, the water level of the hot water (W) stored in the crosslinking chamber 110 is preferably stored to the position in contact with the axis (1 ') of the bobbin (1). This is for the cable C wound around the shaft 1 'of the bobbin 1 to be immersed in the hot water W. Accordingly, regardless of the position of the cable C wound on the bobbin 1, hot water W contacts the entire cable C to supply heat and moisture to the cable C.

On the other hand, when the high temperature water (W) stored in the crosslinking chamber 110 is stored to a position lower than the shaft 1 'of the bobbin, the crosslinking of the cable (C) which is not in contact with the high temperature water (W) is made smoothly. If it is not supported, it is not preferable, and if it is stored up to a position higher than the axis 1 'of the bobbin 1, hot water contacting between the cables C is stagnant and unnecessary amount of water is stored, which is not preferable.

In addition, the bridge chamber 110 may be provided with a water level sensor (not shown) for detecting the water level. That is, when the water level sensor detects that the predetermined water level is supplied to a position where the shaft 1 ′ of the bobbin 1 is installed, the water level sensor transmits the signal to the controller 165 and the controller 165. ) Closes the supply pipe 152 of the outer tank 151 to block the supply of hot water (W).

Subsequently, the bobbin 1 is rotated by rotating the pair of rollers 121 and 122, and the hot water W is sprayed toward the cable C through the injection member 130, thereby providing the cable C. Crosslink. In this process, any one of the pair of rollers 121 and 122 is rotated by the drive motor 124, the hot water (W) is injected from the injection member 130 to the circulation unit 140 By the hot water (W) stored in the crosslinking chamber 110 is supplied and sprayed. That is, the hot water W stored in the crosslinking chamber 110 is transferred and circulated by the circulation pump 144 through the connection pipe 142 connected to communicate the injection member 130 and the crosslinking chamber 110.

Rotating the bobbin 1 as described above is to prevent the cable (C) is locked in the high temperature water (W) stored in the cross-linking chamber (110). That is, to prevent the cable C immersed in the hot water W by rotating the bobbin 1 to prevent saturation due to excessive moisture absorption.

In addition, when the temperature inside the crosslinking chamber 110 changes when the cable C is crosslinked for the predetermined time, it is sensed by the temperature sensor 161 of the temperature control unit 160 and controlled by the controller 165. . For example, when the internal temperature of the crosslinking chamber 110 is lowered, the heater member 162 of the temperature control unit 160 is operated to maintain the preset temperature. In addition, when the internal temperature of the crosslinking chamber 110 increases, heat is released using the heat radiating member 163 to maintain the internal temperature of the crosslinking chamber 110 at a constant level.

On the other hand, the high temperature water (W) supplied into the crosslinking chamber 110 is heat is conducted to the cable (C) when crosslinking the cable (C), the temperature is lowered, so that the high temperature stored in the supply unit 150 It is preferable to supply the water (W) and to transfer the hot water (W) stored in the existing crosslinking chamber 110 to the storage tank.

That is, as time passes, the hot water W stored in the crosslinking chamber 110 is periodically circulated to be replaced with the hot water W stored in an external storage tank 151, thereby providing the crosslinking chamber ( The temperature of the hot water W stored in the 110 is kept constant.

Finally, when the crosslinking is completed, the crosslinked cable (C) is discharged to the bobbin (1) wound around.

As a result, it is possible to crosslink the cable (C) by repeating the above process using the crosslinking device (100) according to the present invention, which is generally good regardless of the position of the cable (C) wound on the bobbin (1). Crosslinking can be performed.

As described above, although the present invention has been described by way of limited embodiments and drawings, the present invention is not limited thereto and is intended by those skilled in the art to which the present invention pertains. Of course, various modifications and variations are possible within the scope of equivalents of the claims to be described.

1 is a perspective view schematically showing a conventional crosslinking device.

Figure 2 is a perspective view schematically showing a cable crosslinking device according to a preferred embodiment of the present invention.

3 is a block diagram showing a cable crosslinking apparatus according to a preferred embodiment of the present invention.

4 is a structural diagram showing a cable crosslinking apparatus according to a preferred embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

1: bobbin 100: crosslinking device

110: crosslinking chamber 120: rotating member

130: injection member 140: circulation unit

150: supply unit 160: temperature control unit

C: cable W: hot water

Claims (14)

A crosslinking chamber configured to store hot water up to a predetermined height therein and to accommodate bobbins in which cables are wound; A rotating member installed in the crosslinking chamber to rotate the bobbin; And And a spraying member installed inside the crosslinking chamber and spraying hot water toward the cable wound on the bobbin. The method of claim 1, The rotating member, A pair of rollers rotatably installed inside the crosslinking chamber and configured to support the bobbin; And And a drive motor connected to any one of the pair of rollers to rotate the rollers. The method of claim 1, The injection member, An injection pipe installed at an upper side of the crosslinking chamber and having a predetermined space to move hot water; And And a plurality of nozzles installed at a predetermined interval below the injection pipe and spraying hot water toward the cable wound on the bobbin. The method of claim 1, A temperature control unit installed inside the crosslinking chamber to adjust an internal temperature of the crosslinking chamber, And the temperature control unit is controlled by a controller. The method of claim 4, wherein The temperature control unit, A temperature sensor for sensing an internal temperature of the crosslinking chamber; A heater member for generating heat when the temperature is lower than a predetermined temperature according to the detection of the temperature sensor; And And a heat dissipation member for dissipating heat when a temperature is greater than or equal to a predetermined temperature according to the detection of the temperature sensor. The method of claim 1, A storage tank is provided to supply hot water to the inside of the crosslinking chamber, and a supply unit configured to circulate the hot water stored in the storage tank and the high temperature water stored in the crosslinking chamber periodically over time. Cable crosslinking apparatus characterized by including. The method of claim 6, The supply unit, A storage tank for storing hot water; A supply pipe installed in communication with the crosslinking chamber and the storage tank to supply hot water stored in the storage tank; A transfer tube configured to communicate with the crosslinking chamber so that hot water stored in the crosslinking chamber is transferred to the storage tank; And And a transfer pump installed at the transfer pipe to transfer high temperature water to the storage tank. The method of claim 7, wherein A filter unit is further provided in the transfer pipe, and the filter unit filters the contaminants mixed in the hot water transferred through the transfer pipe to the storage tank, and the filtered contaminants are discharged to the outside. Crosslinking device. The method of claim 1, And a circulation unit for moving the hot water stored in the crosslinking chamber to the injection member. 10. The method of claim 9, The circulation unit, A connecting tube installed to communicate the lower side of the crosslinking chamber and the injection member; And And a circulation pump installed at the connection pipe to move high temperature water. The method according to any one of claims 1 to 10, The height of the hot water stored in the crosslinking chamber is stored up to a height where the axis of the bobbin is located. (a) opening the entrance to the crosslinking chamber to seat the bobbin wound around the cable onto a pair of rollers; (b) closing the entrance to the crosslinking chamber to seal the crosslinking chamber; (c) supplying hot water to a predetermined height inside the crosslinking chamber; (d) rotating the bobbin by rotating the pair of rollers, and spraying hot water toward the cable with an injection member installed on the upper side of the crosslinking chamber; And (e) discharging the bobbin wound around the cable crosslinked by hot water in the crosslinking chamber to the outside. The method of claim 12, When the high temperature water is supplied to the crosslinking chamber in the step (c), the crosslinking method of the cable, characterized in that for supplying the height of the bobbin is located. The method of claim 12, In the step (d), the hot water stored in the crosslinking chamber periodically circulates with the hot water stored in the external storage tank over a predetermined time, thereby maintaining a constant temperature of the hot water stored in the crosslinking chamber. The crosslinking method of the cable characterized by holding.

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