KR101640607B1 - Cooling apparatus of superconduction cable line - Google Patents

Abstract

The present invention relates to a superconducting cable line cooling apparatus. A cooling device of the present invention is a cooling device for a superconducting cable line including a reservoir tank (10) in which liquid refrigerant and gas refrigerant coexist in an inner container (14) provided inside a vacuum container (12) (100); A fluid conduit 105 extending from the heating fluid source 100; A heat exchanger tube group (200) formed to introduce the fluid duct (105) into the inner vessel (14) of the reservoir tank (10) to provide heat transfer area for heat exchange with the liquid refrigerant in the reservoir tank ); A fluid pressure transducer 110 installed in a fluid conduit 105 between the fluid supply source 100 and the reservoir tank 10 to pressurize fluid in the fluid conduit 105; And a temperature controller 130 installed in the fluid channel 105 between the fluid pressure transducer 110 and the reservoir tank 10 to regulate the temperature of the fluid inside the fluid channel 105.

Description

TECHNICAL FIELD [0001] The present invention relates to a superconducting cable,

The present invention relates to a superconducting cable line cooling apparatus, and more particularly, to a superconducting cable line cooling apparatus, in which a reservoir tank for maintaining the pressure of a refrigerant is pressurized through a separate heat exchange circuit, thereby extending the service life of the heating apparatus, To a superconducting cable line cooling apparatus.

The superconducting cable has large capacity and low loss characteristics that can increase the transmission capacity by 2 to 4 times, while being smaller in size and diameter than conventional power cables, and can transmit low voltage and large current.

Such a superconducting cable circulates the refrigerant using a separate cryogenic refrigeration cycle (mainly operated at a temperature of 77 K or less, using super-cooled liquid nitrogen as the refrigerant) to maintain the superconducting state of the superconducting conductor.

FIG. 1 shows an example of a general superconducting wire cooling apparatus.

1, the refrigerant (mainly liquid nitrogen) flows from the reservoir tank 10 to the circulation pump 20, the cryogenic freezing device 30, the inlet terminal 40, the superconducting cable line 2 ) To the recovery terminal (50) to the reservoir tank (10). The reservoir tank 10 is filled with liquid refrigerant from a liquid refrigerant tank (e.g., bomb) 60.

In the cooling of such a superconducting cable line, when the gas is mixed into the circulating liquid refrigerant, the pressure loss increases, so that it is not possible to stably circulate the liquid refrigerant in an appropriate amount required for cooling. Therefore, special measures such as preparation of a large- . Especially, superconducting cable adopts a cryogenic electrical insulation system that maintains high electrical insulation performance by impregnating liquid coolant into an insulator. Therefore, if gas or air bubbles are mixed in liquid coolant, seasonal insulation performance is significantly deteriorated.

Therefore, in the conventional cooling system, the liquid refrigerant is always kept in the supercooled state and circulated in a state of not vaporizing, so that the interior of the reservoir tank 10 is pressurized to raise the boiling point of the liquid refrigerant, Do not.

2 schematically shows the structure of a conventional reservoir tank 10 in general.

2, the conventional reservoir tank 10 is provided with an inner container 14 inside a vacuum container 12, and a vacuum is formed between the vacuum container 12 and the inner container 14 Insulation. The liquid refrigerant and the gas refrigerant coexist in the inside of the inner container 14.

The liquid refrigerant in the inner container 14 is provided with an electric heater 16 to heat and vaporize the liquid refrigerant to pressurize the liquid refrigerant by raising the pressure inside the inner container 14. [

In the conventional superconducting cable line cooling apparatus provided with the electric heater in the reservoir tank as the pressure means of the reservoir tank, the life of the electric heater is short and needs to be frequently changed. In addition, when the electric heater is replaced, power supply to the superconducting line must be interrupted to cause an interruption in the power supply.

In order to replace the electric heater, the vacuum container must be disassembled and opened, resulting in poor workability and time-consuming work.

SUMMARY OF THE INVENTION The present invention has been developed in order to solve the problems as described above, and it is an object of the present invention to provide a method of heating a liquid refrigerant through physical heat exchange by a heat transfer tube through which a working fluid flows without using an electric heater as a pressurizing means of a reservoir tank, And it is an object of the present invention to provide a superconducting cable line cooling apparatus capable of supplying power more stably by reducing replacement.

In order to achieve the above object, a superconducting cable line cooling apparatus according to the present invention is a cooling apparatus for a superconducting cable line including a reservoir tank in which liquid refrigerant and gas refrigerant coexist in an inner container provided inside a vacuum container, A fluid source for the fluid; A fluid conduit extending from the heating fluid source; A heat exchange tube group formed to introduce the fluid channel into the inner container of the reservoir tank to provide heat transfer area for heat exchange with the liquid refrigerant in the reservoir tank to vaporize the liquid refrigerant; A fluid pressure transducer installed in a fluid conduit between the fluid supply source and the reservoir tank to pressurize the fluid inside the fluid conduit; And a temperature control unit installed in a fluid channel between the fluid pressure transducer and the reservoir tank to regulate the temperature of the fluid inside the fluid channel.

In the superconducting cable line cooling apparatus of the present invention, a fluid pipe between the fluid pressure feeder and the reservoir tank is provided with an on-off valve, a water eliminator is disposed on the fluid pipe entering the reservoir tank, May be configured to pass through a separate heat load device.

According to the present invention as described above, the heat exchanger tube group in which the fluid is circulated so as to cross-flow with the liquid refrigerant is provided instead of installing the electrothermal heater in the reservoir tank as in the prior art, so that the semi-permanent use So that the life span becomes remarkably longer than that of the conventional electrothermal heater.

Therefore, there is no burden of power interruption due to the replacement of the heat exchanging means, and thus the power supply through the superconducting line can be stably performed without frequent interruption.

1 is a schematic diagram showing a conventional superconducting cable line cooling system.
2 is a view schematically showing the structure of a conventional general reservoir tank.
3 is a schematic diagram of a reservoir tank pressurizing circuit according to the present invention.

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

3 shows a schematic diagram of a reservoir tank pressurizing circuit according to the present invention. The same parts as in Fig. 1 are denoted by the same reference numerals.

As shown in FIG. 3, in the present invention, a separate fluid is circulated in the reservoir tank 10 to exchange heat with the liquid refrigerant, thereby vaporizing the liquid refrigerant, if necessary, to pressurize the interior of the reservoir tank 10.

Specifically, a fluid supply source 100 for supplying a heating fluid is provided, and the fluid channel 105 is extended from the heating fluid supply source 100 so as to flow out through the inside of the reservoir tank 10 Respectively.

The fluid channel 105 introduced into the inner vessel 14 of the reservoir tank 10 forms a heat exchange pipe bundle 200 in the inner vessel 14. The heat exchange tube group 200 provides a heat transfer area for heat exchange with the liquid refrigerant in the reservoir tank 10.

A fluid pressure transducer 110 is installed in the fluid conduit 105 between the fluid source 100 and the reservoir tank 10 to transmit the fluid in the fluid conduit 105 to the heat exchanger tube group 200. The fluid pressure transducer 110 may be a blower or a pump.

The fluid channel 105 between the fluid pressure transducer 110 and the reservoir tank 10 is further provided with a temperature controller 130. The temperature controller 130 serves to heat the fluid inside the fluid conduit 105 to maintain the temperature of the fluid within the fluid conduit 105 more accurately.

The fluid channel 105 between the fluid pressure transducer 110 and the reservoir tank 10 may be further provided with an on-off valve 140 so that the flow of the fluid can be controlled precisely and appropriately.

Here, the fluid may be air or nitrogen gas. In the case where the fluid is formed of a gas, it is preferable to further provide the water eliminator 120 on the fluid channel 105 that enters the reservoir tank 10.

The present invention thus constructed is not provided with an electrothermal heater inside the reservoir tank 10 as in the prior art but a heat exchanger tube group 200 in which fluid is circulated and thermally cross-linked with liquid refrigerant and a fluid supply circuit accompanied therewith .

That is, the fluid in the fluid supply source 100 flows through the fluid channel 105 through the fluid pressure transducer 110, and the moisture is separated from the water remover 120 and then heated via the temperature regulating device 130.

The heated fluid flows through the heat exchanger tube group 200 formed in the inner vessel 14 of the reservoir tank 10 to exchange heat with the liquid refrigerant to vaporize the liquid refrigerant and then flows out of the reservoir tank 10.

Since the fluid that has undergone the heat exchange with the liquid refrigerant through the heat exchange tube group 200 is cooled by the liquid refrigerant, the fluid that has flowed out to the outside can be directly discharged to the atmosphere or recovered separately. Or to circulate a circuit that cools the other thermal load device 150 in the machine room or facility before it is released or recovered to the atmosphere.

As described above, according to the present invention, since means for flowing fluid to the heat exchanger tube group as the pressurizing means of the reservoir tank is employed and semi-permanent use is possible, the life span is remarkably longer than that of the conventional heat transfer heater.

Therefore, there is no burden of power interruption due to the replacement of the heat exchanging means, and thus the power supply through the superconducting line can be stably performed without frequent interruption.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It will be apparent to those skilled in the art that various modifications and equivalent arrangements may be made by those skilled in the art without departing from the spirit and scope of the invention as defined by the appended claims. But fall within the scope of the appended claims of the invention.

2: superconducting cable 10: reservoir tank
12: Vacuum container 14: Inner container
16: electric heater 20: circulation pump
30: Cryogenic freezing device 40: Inflow side terminal
50: Recovering side terminal 60: Liquid refrigerant tank
100: fluid source 105: fluid channel
110: fluid feeder 120: water eliminator
130: Temperature control device 140: Open / close valve
150: Thermal load device

Claims (4)

A cooling device for a superconducting cable line comprising a reservoir tank (10) in which liquid refrigerant and gas refrigerant coexist in an inner container (14) provided inside a vacuum container (12)
A heating fluid supply source (100);
A fluid conduit 105 extending from the heating fluid source 100;
The fluid channel 105 is introduced into the inner vessel 14 of the reservoir tank 10 to be disposed in the liquid refrigerant inside the reservoir tank 10 to heat exchange with the liquid refrigerant to provide a heat transfer area for vaporizing the liquid refrigerant A heat exchange tube group 200 formed;
A fluid pressure transducer 110 installed in a fluid conduit 105 between the fluid supply source 100 and the reservoir tank 10 to pressurize fluid in the fluid conduit 105; And
And a temperature control unit 130 installed in the fluid channel 105 between the fluid pressure transducer 110 and the reservoir tank 10 to adjust the temperature of the fluid in the fluid channel 105,
Wherein an open / close valve (140) is installed in a fluid conduit (105) between the fluid pressure transducer (110) and the reservoir tank (10). delete The method according to claim 1,
And a water eliminator (120) is installed on a fluid line (105) entering the reservoir tank (10). The method according to claim 1,
Wherein the fluid channel (105) discharged through the heat exchange tube group (200) passes through a separate heat load device (150).

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