JP6182566B2 - Submarine cable cooling system for offshore wind power generation facilities - Google Patents

Description

  The present invention relates to a submarine cable cooling system for offshore wind power generation facilities.

  In recent years, offshore wind power generation facilities have increased. Along with this, the number of submarine cables for offshore wind power generation facilities is also increasing. Usually, a submarine cable connected to an offshore wind power generation facility is inserted into a protective tube (for example, Patent Document 1). This protective tube is called a J tube or an I tube because of its shape. Moreover, there exists a method of arrange | positioning a heat pipe along the electric power cable in a pipe line, and cooling a submarine cable (patent document 2).

JP 2014-93902 A Japanese Patent Laid-Open No. 11-98667

  The offshore wind power generation facility is constructed as follows, for example. First, when installing the foundation of the windmill, a protection tube for the submarine cable is installed in advance. This protective tube is installed beside the foundation or inside the foundation. Submarine cables will be laid after the foundation installation is completed. At the time of this laying, a protective tube is used as a guide. With a protective tube, it is easy to fix the submarine cable to the foundation.

  However, there is a possibility that this protective tube may hinder the transmission of the submarine cable. The reason is as follows. First, submarine cables generate heat when current flows. If there is a protective tube, this heat is trapped in the protective tube. Then, the temperature of the submarine cable rises. Furthermore, if the temperature of the submarine cable rises too much, the submarine cable will be damaged. In order to prevent such destruction of the submarine cable, it has conventionally been necessary to reduce the amount of current.

  In particular, the temperature of the submarine cable was likely to rise because the aerial part of the protective tube was exposed to direct sunlight.

  On the other hand, in order to suppress damage to the submarine cable, the conductor of the submarine cable has been thickened. However, when the conductor of the submarine cable is thickened, the diameter of the submarine cable itself is thickened. Then, the weight and cost increased.

  Conventionally, the temperature of the submarine cable has not been monitored. For this reason, the temperature rise of the submarine cable could not be grasped. As a result, treatment according to the temperature rise could not be performed. For example, the amount of power transmission was adjusted and could not be kept within an acceptable temperature. Or the cooling capacity of the forced cooling system could not be adjusted.

  The present invention has been made in view of such problems. That is, it aims at providing the cooling system of the submarine cable for offshore wind power generation facilities which can suppress the temperature rise of a submarine cable.

In order to achieve the above-described object, the present invention provides a submarine cable cooling system for offshore wind power generation equipment, which is provided in the offshore wind power generation equipment, and at least a part of which is exposed to the air. A submarine cable inserted through a pipe, and a cooling device for cooling the submarine cable, wherein the cooling device can cool the submarine cable inside the protective tube at least in a portion exposed to the air. The cooling device is a pump that causes a refrigerant to flow inside the protective tube, wherein the refrigerant is seawater, and a plurality of holes are provided on an outer peripheral surface of the protective tube, and the refrigerant passes through the holes. It is a cooling system for submarine cables for offshore wind power generation facilities characterized by being able to flow out to the outside .

Further, the present invention is a cooling system for an offshore wind power generation facility for an offshore wind power generation facility, provided in the offshore wind power generation facility, an upper portion exposed in the air and a lower portion immersed in seawater, and the protection A submarine cable inserted through the pipe and a cooling device for cooling the protective tube, and the cooling device can cool the submarine cable inside the protective tube at least in a portion exposed to the air. The cooling device is a pump that causes a refrigerant to flow inside the protective tube, wherein the refrigerant is seawater, and a plurality of holes are provided on an outer peripheral surface of the protective tube, and the refrigerant passes through the holes. It is a cooling system for submarine cables for offshore wind power generation facilities characterized by being able to flow out to the outside .

Further, the present invention is a submarine cable cooling system for offshore wind power generation equipment, provided in the offshore wind power generation equipment, at least a part of the protective tube exposed to the air,
    A submarine cable inserted through the protective tube; and a cooling device that cools the submarine cable. The cooling device can cool the submarine cable inside the protective tube at least in a portion exposed to the air. The protective tube includes an inlet for flowing the refrigerant into the protective tube and an outlet for discharging the refrigerant, the refrigerant is seawater, and the outer peripheral surface of the protective tube A cooling system for a submarine cable for an offshore wind power generation facility, wherein a plurality of holes are provided, and the refrigerant can flow out from the holes.

Further, the present invention is a cooling system for an offshore wind power generation facility for an offshore wind power generation facility, provided in the offshore wind power generation facility, an upper portion exposed in the air and a lower portion immersed in seawater, and the protection A submarine cable inserted through the pipe and a cooling device for cooling the protective tube, and the cooling device can cool the submarine cable inside the protective tube at least in a portion exposed to the air. The protective tube includes an inlet for flowing the refrigerant into the protective tube, and an outlet for discharging the refrigerant, the refrigerant is seawater, and a plurality of outer peripheral surfaces of the protective tube A cooling system for a submarine cable for an offshore wind power generation facility, wherein a hole is provided and the refrigerant can flow out from the hole.

Both the inlet and the outlet may be provided on the air side.

The present invention is also a submarine cable cooling system for offshore wind power generation equipment, provided in the offshore wind power generation equipment, at least a part of which is exposed to the air, and inserted into the protection pipe A submarine cable; and a cooling device that cools the submarine cable. The cooling device can cool the submarine cable inside the protective tube at least in a portion exposed to the air. A cooling system for a submarine cable for offshore wind power generation equipment, characterized in that it is a pressure feeder for flowing a refrigerant into the protective tube, and the refrigerant is air.

Further, the present invention is a cooling system for an offshore wind power generation facility for an offshore wind power generation facility, provided in the offshore wind power generation facility, an upper portion exposed in the air and a lower portion immersed in seawater, and the protection A submarine cable inserted through the pipe and a cooling device for cooling the protective tube, and the cooling device can cool the submarine cable inside the protective tube at least in a portion exposed to the air. The cooling device is a submerged cable cooling system for offshore wind power generation equipment, wherein the cooling device is a pressure feeder for flowing a refrigerant into the protective tube, and the refrigerant is air.

The present invention is also a submarine cable cooling system for offshore wind power generation equipment, provided in the offshore wind power generation equipment, at least a part of which is exposed to the air, and inserted into the protection pipe A submarine cable; and a cooling device for cooling the submarine cable, wherein the cooling device is capable of cooling the submarine cable inside the protective tube at least in a portion exposed to the air. A submarine cable cooling system for an offshore wind power generation facility, characterized in that the flow rate of a refrigerant for cooling the protective tube is changed according to the output of the facility.

Further, the present invention is a cooling system for an offshore wind power generation facility for an offshore wind power generation facility, provided in the offshore wind power generation facility, an upper portion exposed in the air and a lower portion immersed in seawater, and the protection A submarine cable inserted through the pipe and a cooling device for cooling the protective tube, and the cooling device can cool the submarine cable inside the protective tube at least in a portion exposed to the air. The submarine cable cooling system for an offshore wind power generation facility is characterized in that the flow rate of the refrigerant that cools the protective tube is changed according to the output of the offshore wind power generation facility.

A monitoring device that measures or estimates the temperature of the protective tube or the submarine cable may be provided, and the cooling device may be capable of cooling the submarine cable inside the protective tube at least in a portion exposed to the air. .

  ADVANTAGE OF THE INVENTION According to this invention, it is a protective tube provided in an offshore installation, Comprising: The site | part exposed to air can be cooled. For this reason, the temperature rise of the submarine cable inside the protective tube can be suppressed without thickening the submarine cable.

  In particular, if a coolant such as seawater is injected into the protective tube with a pump, the protective tube and the submarine cable can be efficiently cooled.

  At this time, if the inlet and outlet for flowing the refrigerant are provided in the protective tube, the refrigerant can be reliably injected into the protective tube without interfering with the submarine cable.

  In particular, if the injection port and the discharge port are formed on the air side of the protective tube, the injection port and the discharge port are not blocked by adhesion of shellfish or the like.

  If a plurality of holes are provided on the outer peripheral surface of the protective tube, the refrigerant injected into the protective tube oozes out from the hole to the outside of the protective tube, so that the protective tube can be efficiently cooled by the heat of vaporization.

  Moreover, if the flow rate of the refrigerant is controlled according to the amount of power generated by the offshore wind power generation facility, the protective tube can be efficiently cooled.

  ADVANTAGE OF THE INVENTION According to this invention, the cooling system of the submarine cable for offshore wind power generation facilities which can suppress the temperature rise of a submarine cable can be provided.

The figure which shows the offshore wind power generation equipment. The expanded sectional view which shows the cooling method of the protective tube 3. FIG. The figure which shows the offshore wind power generation equipment 20a. The figure which shows the offshore wind power generation equipment 20b. The expanded sectional view which shows the cooling method of the other protective tube 3. FIG. The expanded sectional view which shows the cooling method of the other protective tube 3. FIG. The expanded sectional view which shows the cooling method of the other protective tube 3. FIG. The expanded sectional view which shows the cooling method of the other protective tube 3. FIG. The expanded sectional view which shows the cooling method of the other protective tube 3. FIG. The expanded sectional view which shows the cooling method of the other protective tube 3. FIG.

  Hereinafter, a cooling system for a submarine cable for offshore wind power generation equipment according to an embodiment of the present invention will be described. FIG. 1 is a diagram showing an offshore wind power generation facility 20. The offshore wind power generation facility 20 is disposed on the ocean. The offshore wind power generation facility 20 may be a floating body type. In this case, the offshore wind power generation facility 20 is floating on the ocean, and the lower part is fixed to the seabed with a mooring line.

  The submarine cable 1 is connected to the offshore wind power generation facility 20. The submarine cable 1 is inserted into a protective tube fixed to the offshore facility and connected to the offshore wind power generation facility 20 in the air. The submarine cable 1 is connected to other offshore equipment or a substation on the ground, and transmits electricity obtained by wind power generation.

  The protective tube 3 is installed outside the offshore wind power generation facility 20. As the protective tube 3, for example, a stainless steel tube coated with an anticorrosive paint can be used. Alternatively, a flexible tube made of resin can be used.

  The offshore wind power generation facility 20 is provided with a cooling device 10. The cooling device 10 includes a pump 5 and an injection pipe 7. The cooling device 10 is a device that cools the protective tube 3 and the submarine cable 1. The injection tube 7 is connected to the pump 5. The pump 5 takes in seawater with a water intake pipe immersed in the sea and discharges the seawater to the injection pipe 7. The offshore wind power generation facility 20 and the cooling device 10 that cools the submarine cable 1 connected to the offshore wind power generation facility 20 are collectively referred to as a submarine cable cooling system for the offshore wind power generation facility.

  FIG. 2 is a cross-sectional view of the protective tube 3. In addition, illustration of the pump 5 is abbreviate | omitted in the following figures. As described above, the submarine cable 1 is inserted into the protective tube 3. The protective tube 3 is provided from the sea to the air, the upper part is exposed to the air, and the lower part is immersed in seawater. That is, at least a part of the protective tube 3 is exposed to the air.

  The tip of the injection tube 7 is inserted into the upper end of the protective tube 3 and into the opening into which the submarine cable 1 is inserted. That is, the upper end of the protective tube 3 becomes the injection port 9. Seawater is discharged from the injection pipe 7 by the pump 5. That is, seawater is injected into the protective tube 3 (arrow A in the figure). Seawater injected into the protective tube 3 is discharged into the sea from the lower end of the protective tube 3 (arrow B in the figure).

  Seawater injected into the protective tube 3 functions as a refrigerant for cooling the protective tube 3 and the submarine cable 1. In particular, the temperature of the protective tube 3 exposed to the air rises due to the sun and the like, and the internal submarine cable 1 is not cooled by natural wind, so there is a concern that the temperature of the submarine cable 1 will rise. According to this embodiment, the temperature rise of the protection tube 3 exposed to the air and the submarine cable 1 inside the protection tube 3 can be suppressed.

  The pump 5 can use, for example, power generated by the offshore wind power generation facility 20. At this time, the flow rate of seawater by the pump 5 may be changed according to the power generation output of the offshore wind power generation facility 20. For example, when the amount of power generation increases, the amount of current flowing through the submarine cable 1 increases and the amount of heat generated increases. For this reason, in this case, if the flow rate of the seawater by the pump 5 is increased, the protective tube 3 and the submarine cable 1 can be cooled more reliably.

  Also, a monitor device that monitors the temperature in the submarine cable 1 or the protective tube 3 can be used. For example, a temperature monitoring device 21 for temperature measurement is disposed in the offshore wind power generation facility 20a shown in FIG. Specifically, an optical fiber or a thermocouple can be used as the temperature monitoring device 21.

  Hereinafter, an example using an optical fiber as the temperature monitoring device 21 will be described in detail. If an optical fiber is arrange | positioned inside the submarine cable 1, an optical fiber will be distorted according to temperature. Since the optical path length or the like changes according to the strain, the amount of strain can be detected by using laser light that has passed through the optical fiber. The temperature can be converted from the amount of strain. Then, the temperature distribution in the longitudinal direction of the submarine cable 1 can be directly monitored using the temperature measuring device. Further, a plurality of optical fibers may be arranged at different parts of the submarine cable 1. And you may estimate the temperature of parts other than the optical fiber of the submarine cable 1 from the difference of the temperature value detected from a plurality of optical fibers, and the structure of the submarine cable 1. For example, the temperature of a conductor or sheath in which an optical fiber cannot be arranged, or a portion that is vulnerable to high temperatures may be estimated.

  Further, the temperature monitoring device 21 may be provided in the protective tube 3 in advance. Hereinafter, details of an example in which a thermocouple is used as the temperature monitoring device 21 will be described. If the thermocouple is provided in the protective tube 3, the temperature of the protective tube 3 can be measured directly. Alternatively, the temperature of the submarine cable 1 inside the protective tube 3 can be estimated from the temperature of the protective tube 3. Further, the temperature of both the submarine cable 1 and the protective tube 3 may be measured or estimated.

  The temperature measurement result and the temperature estimation result may be stored in a recording device. At this time, both the measurement time and the estimated time may be recorded.

  You may control to change the flow volume of seawater according to these measured temperature, the estimated temperature, the recorded temperature, and the parameter (submarine cable life etc.) calculated from these temperatures. For example, when the environmental temperature rises or when the current increases, it is determined that the temperature will rise in the future, and the temperature rise may be predicted, and a corresponding amount of seawater may be injected.

  The power generation amount and power transmission amount of the offshore wind power generation facility may be controlled in accordance with these measured temperature, estimated temperature, recorded temperature, and parameters calculated from these temperatures (such as submarine cable life).

  You may acquire the temperature of the submarine cable 1 or the protection tube 3 from the several offshore wind power generation equipment 20a. The acquired temperature may be a measured temperature, an estimated temperature, or a recorded temperature. Then, the power generation amount and the power transmission amount of the plurality of offshore wind power generation facilities 20a may be controlled from those temperatures and parameters (such as submarine cable life) calculated from those temperatures. Alternatively, the power transmission path may be determined. In particular, when a plurality of offshore wind power generation facilities 20a form a wind farm and the power transmission network has a plurality of power transmission path options, the optimum option may be selected from these temperatures.

Furthermore, the future temperature change of the submarine cable 1 may be predicted from the environmental temperature of the submarine cable 1 and the current flowing through the submarine cable 1, and the flow rate of the seawater may be controlled accordingly. For example, when the environmental temperature is used above or when the current increases, it is determined that the temperature will rise in the future, and the temperature rise is predicted, and seawater corresponding to this temperature is injected.

  In addition, when the measured temperature, estimated temperature, recorded temperature, and parameters calculated from these temperatures (such as submarine cable life) exceed the specified values, the temperatures arranged in the plurality of offshore wind power generation facilities 20a An alarm can be issued by the alarm device 22. By such an alarm, for example, abnormality of the pump 5 or clogging of the injection port can be found.

  As described above, according to the present embodiment, at least the portion of the protective tube 3 exposed to the air and the submarine cable 1 inside the protective tube 3 at this portion can be reliably cooled. In particular, since the protective tube 3 exposed to the air is efficiently cooled, it is possible to cool a portion having the worst temperature condition.

  In addition, although the example which uses seawater as a refrigerant | coolant was shown, in this invention, you may blow in air in the protective tube 3, for example. FIG. 4 is a diagram illustrating the offshore wind power generation facility 20b. The offshore wind power generation facility 20 b is substantially the same as the offshore wind power generation facility 20, but a pressure feeder 5 a is arranged instead of the pump 5. In this case, what is necessary is just to inject | pour air into the protective tube 3 with the pumping machines 5a, such as an air blower, a compressor, and an air conditioner. Alternatively, air may be sucked from the protective tube 3. In this case, air may be sucked from the protective tube 3 by the pressure feeder 5a. In the following description, an example in which seawater is used as the refrigerant will be described.

  Next, a second embodiment will be described. FIG. 5 is a partial cross-sectional view of the protective tube 3 according to the second embodiment. In the following description, components having the same functions as those in the first embodiment are denoted by the same reference numerals as in FIGS.

  The second embodiment is substantially the same as the first embodiment, but a plurality of holes 11 are provided on the outer peripheral surface of the protective tube 3. The hole 11 is a through hole, and the space inside and outside the protective tube 3 communicates therewith. The hole 11 is formed at least in a range exposed to the air of the protective tube 3. The diameter of the hole 11 is, for example, about 1 mm.

  In the present embodiment, when seawater is injected into the protective tube 3 by the injection tube 7, the seawater flowing inside the protective tube 3 cools the protective tube 3 and the submarine cable 1. On the other hand, a part of the seawater oozes out to the outer peripheral surface of the protective tube 3 through the hole 11. Seawater that oozes out to the outer periphery of the protective tube 3 wets the outer peripheral surface of the protective tube 3 and lowers the temperature of the protective tube 3 by heat of vaporization when the seawater evaporates. Therefore, the protective tube 3 can be efficiently cooled.

  According to the second embodiment, the same effect as the first embodiment can be obtained. Moreover, a part of seawater oozes out to the outer peripheral surface of the protective tube 3 by the hole 11, and the protective tube 3 is cooled using vaporization heat. Then, the temperature rise of the submarine cable 1 can be suppressed more efficiently.

  In addition, you may coat | cover the outer periphery of the protective tube 3 in which the hole 11 was provided with water absorbing members, such as sponge, so that the hole 11 may not be obstruct | occluded with the salt etc. which precipitate at the time of evaporation of seawater.

  Next, a third embodiment will be described. FIG. 6 is a cross-sectional view of the protective tube 3 according to the third embodiment.

  The third embodiment is almost the same as the first embodiment. However, an inlet 9 for flowing the refrigerant into the protective tube 3 and a discharge port 13 for discharging the refrigerant are formed on the side surface of the protective tube 3. That is, the refrigerant inlet and outlet are provided separately from the opening at the end of the protective tube 3 through which the submarine cable 1 is inserted. In the illustrated example, the inlet 9 is provided on the air side, and the outlet 13 is provided on the sea side.

  Thus, when the inlet 9 and the outlet 13 are provided on the side surface of the protective tube 3, even when the gap between the protective tube 3 and the submarine cable 1 is small, the refrigerant can be reliably injected into the protective tube 3. Further, the refrigerant can be discharged from the protective tube 3.

  According to the third embodiment, the same effect as in the first embodiment can be obtained. Thus, in the present invention, the injection port 9 and the discharge port 13 can be arranged at arbitrary positions on the protective tube 3.

  Next, a fourth embodiment will be described. FIG. 7 is a cross-sectional view of the protective tube 3 according to the fourth embodiment.

  The fourth embodiment is substantially the same as the third embodiment, but the inlet 9 and the outlet 13 are formed on the air side of the protective tube 3. That is, the refrigerant inlet and outlet are provided separately from the opening at the end of the protective tube through which the submarine cable 1 is inserted, and both are arranged in the air.

  A pipe 15 is connected to the inlet 9 and the outlet 13. The pipe 15 is provided inside the protective tube 3. One end of the pipe 15 is connected to the inlet 9, is arranged downward from the inlet 9, is bent upward in the sea, and the other end is connected to the outlet 13. The pipe 15 serves as a refrigerant flow path.

  The pipe 15 does not have to be U-shaped as illustrated. For example, the pipe 15 may be formed in a spiral shape, and the pipe 15 may be disposed on the outer periphery of the submarine cable 1 in a spiral shape.

  When the refrigerant is injected from the inlet 9, when the refrigerant flows through the pipe 15, heat can be exchanged with the protective tube 3 and the submarine cable 1, and the protective tube 3 and the submarine cable 1 can be cooled. Therefore, the temperature rise of the submarine cable 1 can be suppressed efficiently.

  As shown in FIG. 8, the pipe 15 may be arranged on the outer periphery of the protective tube 3. In this case, when air is injected from the air inlet 9, the air is discharged to the air outlet 13 via the pipe 15. When the pipe 15 is disposed outside the protective tube 3, the pipe 15 does not prevent the submarine cable 1 from being inserted when the submarine cable 1 is inserted into the protective tube 3. Further, the protective tube 3 can be cooled not only by the air flowing through the protective tube 3 but also by the air flowing through the pipe 15.

  According to the fourth embodiment, the same effect as in the third embodiment can be obtained. Moreover, since both the inlet 9 and the outlet 13 are disposed in the air, the inlet 9 and the outlet 13 are not blocked by shellfish, seaweed, or the like.

  Next, a fifth embodiment will be described. FIG. 9 is a cross-sectional view of the protective tube 3 according to the fifth embodiment.

  The fifth embodiment is substantially the same as the third embodiment, but the discharge port 13 is formed on the air side of the protective tube 3. The pump 5 is directly connected to the discharge port 13. When the pump 5 is operated, the seawater inside is sucked from the discharge port 13 and discharged. In the illustrated example, seawater is sucked from the lower end of the protective tube 3, but a separate inlet 9 may be provided on the side surface of the protective tube 3 in the sea.

  According to the fifth embodiment, the same effect as in the third embodiment can be obtained. Thus, in the present invention, the direction in which the refrigerant flows may be any direction.

  Next, a sixth embodiment will be described. FIG. 10 is a cross-sectional view of the protective tube 3 according to the sixth embodiment.

  The sixth embodiment is substantially the same as the first embodiment, but instead of injecting the refrigerant into the protective tube 3, the refrigerant is injected into the outer periphery of the protective tube 3 from the outer peripheral side of the protective tube 3. Cooling is performed. In the illustrated example, the refrigerant is injected directly onto the outer peripheral surface of the protective tube 3, but a separate pipe is provided on the outer periphery of the protective tube 3, and the protective tube 3 is cooled by flowing the refrigerant into the pipe. Also good.

  According to the sixth embodiment, the same effect as in the first embodiment can be obtained. Thus, in the present invention, it is not always necessary to inject the refrigerant into the protective tube 3.

  As mentioned above, although embodiment of this invention was described referring an accompanying drawing, the technical scope of this invention is not influenced by embodiment mentioned above. It is obvious for those skilled in the art that various changes or modifications can be conceived within the scope of the technical idea described in the claims. It is understood that it belongs to the range.

1 ……… Submarine cable 3 ……… Protection tube 5 ……… Pump 7 ……… Injection tube 9 ……… Inlet 10 ……… Cooling device 11 ……… Hole 13 ……… Discharge port 15 ……… Piping 20 ... Offshore wind power generation equipment 21 ... Temperature monitor device 22 ... Temperature alarm generator

Claims (10)

A submarine cable cooling system for offshore wind power generation equipment,
A protection tube provided in the offshore wind power generation facility, at least part of which is exposed to the air;
A submarine cable inserted through the protective tube;
A cooling device for cooling the submarine cable,
The cooling device is capable of cooling the submarine cable inside the protective tube at least in a portion exposed to the air;
The cooling device is a pump that causes a refrigerant to flow inside the protective tube,
The refrigerant is sea water;
A cooling system for a submarine cable for offshore wind power generation equipment , wherein a plurality of holes are provided in an outer peripheral surface of the protective tube, and the refrigerant can flow out of the holes to the outside . A submarine cable cooling system for offshore wind power generation equipment,
A protection tube installed in an offshore wind power generation facility, with the upper part exposed to the air and the lower part immersed in sea water;
A submarine cable inserted through the protective tube;
A cooling device for cooling the protective tube,
The cooling device is capable of cooling the submarine cable inside the protective tube at least in a portion exposed to the air;
The cooling device is a pump that causes a refrigerant to flow inside the protective tube,
The refrigerant is sea water;
A cooling system for a submarine cable for offshore wind power generation equipment , wherein a plurality of holes are provided in an outer peripheral surface of the protective tube, and the refrigerant can flow out of the holes to the outside . A submarine cable cooling system for offshore wind power generation equipment,
A protection tube provided in the offshore wind power generation facility, at least part of which is exposed to the air;
A submarine cable inserted through the protective tube;
A cooling device for cooling the submarine cable,
The cooling device is capable of cooling the submarine cable inside the protective tube at least in a portion exposed to the air;
The protective tube includes an inlet for flowing the refrigerant into the protective tube, and an outlet for discharging the refrigerant,
The refrigerant is sea water;
A cooling system for a submarine cable for offshore wind power generation equipment , wherein a plurality of holes are provided in an outer peripheral surface of the protective tube, and the refrigerant can flow out of the holes to the outside . A submarine cable cooling system for offshore wind power generation equipment,
A protection tube installed in an offshore wind power generation facility, with the upper part exposed to the air and the lower part immersed in sea water;
A submarine cable inserted through the protective tube;
A cooling device for cooling the protective tube,
The cooling device is capable of cooling the submarine cable inside the protective tube at least in a portion exposed to the air;
The protective tube comprises an inlet for flowing the refrigerant into the protective tube, and an outlet for discharging the refrigerant,
The refrigerant is sea water;
A cooling system for a submarine cable for offshore wind power generation equipment , wherein a plurality of holes are provided in an outer peripheral surface of the protective tube, and the refrigerant can flow out of the holes to the outside . The cooling system for a submarine cable for offshore wind power generation equipment according to claim 3 or 4 , wherein both the inlet and the outlet are provided on the air side. A submarine cable cooling system for offshore wind power generation equipment,
A protection tube provided in the offshore wind power generation facility, at least part of which is exposed to the air;
A submarine cable inserted through the protective tube;
A cooling device for cooling the submarine cable,
The cooling device can cool the submarine cable inside the protective tube at least in a portion exposed to the air,
The cooling system is a pressure feeder for flowing a refrigerant into the protective tube, and the refrigerant is air . The cooling system for a submarine cable for offshore wind power generation equipment. A submarine cable cooling system for offshore wind power generation equipment,
A protection tube installed in an offshore wind power generation facility, with the upper part exposed to the air and the lower part immersed in sea water;
A submarine cable inserted through the protective tube;
A cooling device for cooling the protective tube,
The cooling device is capable of cooling the submarine cable inside the protective tube at least in a portion exposed to the air;
The cooling system is a pressure feeder for flowing a refrigerant into the protective tube, and the refrigerant is air . The cooling system for a submarine cable for offshore wind power generation equipment. A submarine cable cooling system for offshore wind power generation equipment,
A protection tube provided in the offshore wind power generation facility, at least part of which is exposed to the air;
A submarine cable inserted through the protective tube;
A cooling device for cooling the submarine cable,
The cooling device is capable of cooling the submarine cable inside the protective tube at least in a portion exposed to the air;
A submarine cable cooling system for an offshore wind power generation facility , wherein a flow rate of a refrigerant for cooling the protective tube is changed according to an output of the offshore wind power generation facility. A submarine cable cooling system for offshore wind power generation equipment,
A protection tube installed in an offshore wind power generation facility, with the upper part exposed to the air and the lower part immersed in sea water;
A submarine cable inserted through the protective tube;
A cooling device for cooling the protective tube,
The cooling device is capable of cooling the submarine cable inside the protective tube at least in a portion exposed to the air;
A submarine cable cooling system for an offshore wind power generation facility , wherein a flow rate of a refrigerant for cooling the protective tube is changed according to an output of the offshore wind power generation facility. Comprising a monitoring device for measuring or estimating the temperature of the protective tube or the submarine cable;
  The offshore wind power generation facility according to any one of claims 1 to 9, wherein the cooling device is capable of cooling the submarine cable inside the protective tube at least in a portion exposed to the air. Submarine cable cooling system.

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