KR20110091929A - Superconducting Power Cable with Composite Refrigerant - Google Patents

Abstract

The present invention relates to a superconducting power cable, comprising a core part including a superconducting conductor, a heat insulating tube accommodating the core part therein, and a refrigerant such as liquid nitrogen or solid nitrogen for cooling the core part inside the heat insulating tube. A superconducting power cable having a space portion formed therein, wherein a flow path is formed to allow gas helium or liquid hydrogen to flow in the space portion or the heat insulation tube, and act as a refrigerant of the superconductor in combination with the liquid nitrogen or solid nitrogen. The superconducting power cable to which the formed complex refrigerant is applied is a technical subject matter. As a result, a flow path is formed inside the superconducting power cable so that a lower temperature gas helium or liquid hydrogen can be used as the refrigerant along with the existing liquid nitrogen or solid nitrogen, thereby increasing the temperature of the liquid nitrogen or the solid nitrogen during the superconducting operation. In addition, there is an advantage that the stable operation of the superconducting power cable can be performed by allowing the gas helium or liquid hydrogen to act as a refrigerant in combination with the liquid nitrogen or the solid nitrogen when the load fluctuates due to other causes or the increase in the current capacity is required.

Description

Superconducting power cable which is cooled by multiple cryogen}

The present invention relates to a superconducting power cable, by adding a gas helium or a liquid hydrogen flow path while using the existing liquid nitrogen or solid nitrogen as a refrigerant to the superconducting power cable to facilitate the temperature control of the refrigerant during load changes and capacity changes. It relates to a superconducting power cable to which a complex refrigerant is applied.

Recently, with the development of superconducting conductors, efforts have been made regarding the application of a superconducting power cable to the system. Superconducting power cables can transmit at least five times more power than phase-conducting cables in the same space, and have eco-friendly advantages with little fire hazard.

Such superconducting cables include single-phase superconducting cables consisting of one core, multiphase superconducting cables consisting of a plurality of cores together, and three-phase superconducting cables of three-phase batch type, in which three cores are collectively studied. The three-phase cable is composed of a vacuum insulated tube provided with a heat insulating material between the metal pipes in a double, and a core part formed by twisting three cores together in a bundle inside the heat insulating tube, and the space between the vacuum insulated tube and the core A refrigerant such as liquid nitrogen is included, and the space portion serves as a flow path to allow liquid nitrogen to flow while cooling the core portion.

The core portion is cooled by the liquid nitrogen to enable smooth operation of the superconducting power cable at cryogenic temperatures of about 77 K or less. However, in order to maintain such cryogenic temperature, liquid nitrogen must be cooled and circulated and cooled into the space by using a cryogenic freezer and a cooling system. In this case, for the stable operation of the superconducting power cable, the design of the cooling system is based on the amount of heat generated at the maximum load of the cable. Therefore, the superconducting power cable and cooling system are designed to meet the maximum load criteria regardless of the day / night load variation due to the characteristics of the system, resulting in overdesign than when considering the average load.

In addition, as the superconducting power cable is cooled to a lower temperature, the cooling cost increases, but the transmission capacity is increased. Accordingly, superconducting power cables may operate below liquid nitrogen temperatures, depending on the need for increased capacity. However, the system of cooling with liquid nitrogen requires cooling as the fluid flows continuously, and thus requires a separate system for nitrogen flow, and also cannot operate below the temperature (64K) at which liquid nitrogen is solidified. .

Therefore, even if the cooling cost is reduced due to the improved performance of the cooling system in the future, it is impossible to operate the superconducting power cable without changing the coolant, which is liquid nitrogen, below 64K. On the other hand, there is a technology that uses a solid nitrogen to operate at less than 64K, all of which is directly cooled by using the solid nitrogen, the problem that can not actively respond to the design according to the load fluctuations and capacity fluctuations of the superconducting power cable have.

The present invention is designed to solve the above problems, by using the existing liquid nitrogen or solid nitrogen as a refrigerant in the superconducting power cable as a refrigerant, adding a gas helium or liquid hydrogen flow path to control the temperature of the refrigerant according to the load fluctuations and capacity fluctuations It is an object of the present invention to provide a superconducting power cable to which a complex refrigerant is easily applied.

In order to achieve the above object, the present invention provides a core part including a superconducting conductor, a heat insulating tube accommodating the core part therein, and a refrigerant such as liquid nitrogen or solid nitrogen for cooling the core part inside the heat insulating tube. A superconducting power cable having a space portion formed therein, wherein a flow path is formed to allow gas helium or liquid hydrogen to flow in the space portion or the heat insulation tube, and act as a refrigerant of the superconductor in combination with the liquid nitrogen or solid nitrogen. The superconducting power cable to which the formed complex refrigerant is applied is a technical subject matter.

In addition, the flow path is preferably coaxially formed with the heat insulating tube is formed to include the core portion therein.

In the case of the single-phase superconducting power cable including the core part, the flow path may be a hollow part of the core part, and the flow path may be formed coaxially with the heat insulation tube to include the core part therein. .

In addition, in the case of the three-phase superconducting power cable having three core parts, the flow path is preferably coaxially formed with a heat insulating tube and formed at the center of the three core parts, and the three-phase superconducting power cable having three core parts. In this case, the flow paths are preferably formed one by one between adjacent core portions.

According to the above problem solving means, the present invention provides a liquid flow during superconducting operation by forming a flow path to use a lower temperature gas helium or liquid hydrogen as a refrigerant together with a conventional refrigerant such as liquid nitrogen or solid nitrogen in the superconducting power cable. When the temperature of nitrogen or solid nitrogen rises or the load fluctuates due to other causes, the current capacity needs to be increased, gaseous helium or liquid hydrogen together with liquid nitrogen or solid nitrogen can act as a refrigerant to stabilize the superconducting power cable. It is possible to drive.

1-A schematic diagram according to Embodiment 1 of the present invention.
Figure 2-Schematic diagram according to a second embodiment of the present invention.
3-A schematic diagram according to Embodiment 3 of the present invention.
4-Schematic diagram according to Embodiment 4 of the present invention.
5-A schematic diagram according to Embodiment 5 of the present invention.
6-Schematic diagram according to Example 6 of the present invention.

The present invention uses a conventional liquid nitrogen or solid nitrogen as a refrigerant inside the superconducting power cable, while forming a flow path through which gas helium or liquid hydrogen lower in temperature than liquid nitrogen or solid nitrogen can pass through the superconducting power cable. Accordingly, the present invention relates to a superconducting power cable using a complex refrigerant that is easy to cope with load fluctuations and capacity fluctuations by controlling the temperature of liquid nitrogen or solid nitrogen by the gas helium or liquid hydrogen.

In general, a superconducting power cable includes a core part including a superconducting conductor, a vacuum insulated tube accommodating the core part, and a space part such that a refrigerant such as liquid nitrogen or solid nitrogen for cooling the core part is included inside the insulated tube. The flow path through which the gas helium or liquid hydrogen according to the present invention can pass is formed in the space part or becomes an empty space inside the heat insulation tube, and is a refrigerant of the superconductor in combination with the liquid nitrogen or solid nitrogen. To work.

That is, the superconducting conductor of the core part is cooled by liquid nitrogen or solid nitrogen in the superconducting power cable. When the liquid nitrogen is used as the refrigerant, the cooling is performed up to 77K, and when the solid nitrogen is used as the refrigerant, the cooling is up to 64K. . Here, when the temperature of the liquid nitrogen or solid nitrogen rises, or the load fluctuation, or the current capacity is to be increased, gas helium or liquid hydrogen having a temperature lower than that of the liquid nitrogen or solid nitrogen is formed in the space inside the insulation tube. By flowing into the flow path or the heat insulating tube, the temperature of the refrigerant can be further lowered. In addition, when the existing liquid nitrogen is used, the cooling and circulation system of the liquid nitrogen is not necessary.

Hereinafter, with reference to the accompanying drawings will be described in detail an embodiment of the present invention.

≪ Example 1 >

In the first embodiment of the present invention, when the core part 10 is a single-phase superconducting power cable composed of one, the passage 100 becomes a hollow part of the core part 10. As shown in FIG. 1, the single-phase superconducting power cable including one core part 10 in the space part 30 inside the vacuum insulator tube 20 may form a hollow part inside the former 11, and separately. This portion becomes the flow path 100 of the gas helium or liquid hydrogen without formation of the flow path 100 for the gas helium or liquid hydrogen. In addition, the liquid nitrogen or the solid nitrogen is accommodated in the space portion 30 between the heat insulation tube 20 and the core portion 10, and gaseous helium or liquid hydrogen is refrigerant inside the superconducting conductor of the core portion 10. Liquid nitrogen or solid nitrogen acts as a refrigerant to the outside, thereby lowering the temperature of the core portion 10 and at the same time lowering the temperature of the liquid nitrogen or solid nitrogen, thereby increasing the temperature or varying the load. In this case, it is possible to easily cope with the fluctuation of capacity.

<Example 2>

In the second embodiment of the present invention, as shown in FIG. 2, when the core part 10 is a single-phase superconducting power cable, the channel 100 for gas helium or liquid hydrogen becomes the heat insulating tube. In this case, the outer side of the insulation tube may have a slight thickness for insulation, and the inside of the insulation tube is used as the passage 100 without forming a separate gas helium or liquid hydrogen passage 100.

<Example 3>

As shown in FIG. 3, the third embodiment combines the first and second embodiments when the core part 10 is a single-phase superconducting power cable. The flow path 100 of the gas helium or the liquid hydrogen is formed in the hollow part by the former 11 and the inside of the heat insulation tube 20.

<Example 4>

In the fourth embodiment of the present invention, as shown in FIG. 4, in the case where the core part 10 is a three-phase superconducting power cable having three, the flow path 100 for the gas helium or the liquid hydrogen is the insulation tube 20. ) Is coaxially formed with the core part 10. That is, the gas for helium or liquid hydrogen flows further by forming a pipe for the flow path 100 inside the heat insulation pipe 20, and liquid nitrogen or solid nitrogen exists in the space part 30 therein.

Example 5

In the fifth embodiment of the present invention, as shown in FIG. 5, when the core part 10 is a three-phase superconducting power cable having three parts, the three core parts include a flow path 100 for the gas helium or liquid hydrogen. (10) It is formed in the center.

<Example 6>

As shown in FIG. 6, in the sixth embodiment of the present invention, when the core part 10 is a three-phase three-phase superconducting power cable, the flow path 100 for the gas helium or liquid hydrogen is adjacent to the core part ( 10) Three are formed one by one.

As described above, the present invention is to form a flow path to use a lower temperature gas helium or liquid hydrogen as a refrigerant together with a conventional refrigerant such as liquid nitrogen or solid nitrogen inside the superconducting power cable, the flow path is a single-phase or three-phase superconducting In the case of power cables, or in the case of multiphase superconducting power cables, any thermal effects on liquid nitrogen or solid nitrogen in spaces where refrigerants such as liquid nitrogen or solid nitrogen are present, inside vacuum insulation tubes or inside superconducting power cables It is formed in a suitable space so that the temperature of liquid nitrogen or solid nitrogen during operation of superconducting power cable rises or the load fluctuates due to other causes, gas helium or liquid together with liquid nitrogen or solid nitrogen when the current capacity needs to be increased. Superconducting power by allowing hydrogen to act as a refrigerant The stable operation of the cable will have to be.

10 core part 20: heat insulation tube
30: space portion 100: euro

Claims (6)

Core part 10 including a superconducting conductor, a heat insulating tube 20 accommodating the core part 10 therein, and liquid nitrogen for cooling the core part 10 into the heat insulating tube 20. Or in the superconducting power cable in which the space portion 30 is formed to include a refrigerant such as solid nitrogen,
A channel 100 is formed to allow gas helium or liquid hydrogen to flow in the space part 30 or the heat insulating tube 20, and is formed to act as a refrigerant of the superconductor in combination with the liquid nitrogen or the solid nitrogen. Superconducting power cable with refrigerant. The superconducting power cable according to claim 1, wherein the flow path (100) is formed coaxially with the heat insulating tube (20) to include the core part (10) therein. 2. The superconducting power cable according to claim 1, wherein when the core part 10 is a single phase superconducting power cable, the flow path 100 becomes a hollow part of the core part 10. . 4. The superconducting power cable according to claim 3, wherein the flow path (100) is formed coaxially with the heat insulating tube (20) to include the core portion (10) therein. According to claim 1, wherein the core portion 10 is a three-phase superconducting power cable consisting of three, the flow path 100 is formed coaxially with the heat insulating tube 20 in the center of the three core portion (10) Superconducting power cable to which the composite refrigerant is formed, characterized in that formed. According to claim 1, wherein when the core portion 10 is a three-phase superconducting power cable consisting of three, the flow path 100 is formed by one between the adjacent core portion 10 is applied to the composite refrigerant Superconducting power cable.

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